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# Copyright (C) 2020-2021 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:
# Generate a high-level command stream from a schedule
from .high_level_command_stream import Box
from .high_level_command_stream import DMA
from .high_level_command_stream import NpuStripe
from .numeric_util import round_up_divide
from .operation import create_activation_function
from .operation import NpuBlockType
from .operation import Op
from .shape4d import Shape4D
from .tensor import TensorPurpose
def dma_if_necessary(ps, box, tensor):
src_tensor = tensor.src_tensor
if src_tensor and tensor.mem_area != src_tensor.mem_area:
yield DMA(ps, src_tensor, tensor, box)
def generate_high_level_command_stream_for_schedule(nng, sg, arch, verbose_high_level_command_stream):
res = []
# sg.sched_ops are ordered by execution
processed_cascades = set()
for sched_op in sg.sched_ops:
op_info = sg.schedule.cost_map[sched_op]
if op_info.cascade in processed_cascades:
# This cascade has already been processed
continue
if op_info.cascade == 0:
# Generate high-level commands for this Op in isolation
res += list(generate_high_level_commands_for_sched_op(sched_op, sg.schedule))
else:
# Generate high-level commands for the whole cascade
cascade_info = sg.schedule.cascades[op_info.cascade]
# Start from the last Op in the cascade
res += list(generate_high_level_commands_for_sched_op(sg.sched_ops[cascade_info.end], sg.schedule))
processed_cascades.add(op_info.cascade)
sg.high_level_command_stream = res
if verbose_high_level_command_stream:
sg.print_high_level_command_stream()
def generate_high_level_commands_for_sched_op(sched_op, schedule):
op_info = schedule.cost_map[sched_op]
cascade_info = schedule.cascades.get(op_info.cascade)
npu_block_type = sched_op.parent_ps.npu_block_type
block_config = op_info.block_config
ps = sched_op.parent_ps
parent_op = sched_op.parent_op
ofm_tensor = ps.ofm_tensor
# Get Tensors and Full Shapes
(
ifm_tensor,
ifm2_tensor,
uncomp_weight_tensor,
_,
_,
) = parent_op.get_ifm_ifm2_weights_biases_ofm()
ifm = sched_op.ifm
ifm2 = sched_op.ifm2
ofm_shape = sched_op.ofm.shape
# Get Kernel strides and upscaling factor
kernel_stride = sched_op.kernel.stride
strides = [1, kernel_stride.y, kernel_stride.x, 1]
skirt = parent_op.attrs.get("skirt", None)
upscaling = 1
if sched_op.op_type == Op.Conv2DBackpropInputSwitchedBias:
upscaling = ofm_shape.height // ifm.shape.height
elif sched_op.op_type == Op.ResizeBilinear:
upscaling = round_up_divide(ofm_shape.height, ifm.shape.height)
# Get kernel height and height dilation
k_height = 1
if npu_block_type in (NpuBlockType.Pooling, NpuBlockType.ReduceSum):
if parent_op is not None:
k_height = parent_op.attrs["ksize"][1]
else:
if uncomp_weight_tensor is not None:
k_height = uncomp_weight_tensor.shape[0]
k_height_dilation = parent_op.attrs.get("dilation", (_, 1, _, _))[-3]
# Calculate dilated kernel height
k_dilated_height = k_height_dilation * (k_height - 1) + 1
# Define Start and End coordinates for the OFM
ofm_start = Shape4D(0, 0, 0, op_info.ofm_depth_slices[0])
ofm_end = ofm_shape
ofm_depth_slices = op_info.ofm_depth_slices
# Read/Write offsets
read_offsets = list(parent_op.read_offsets) # offset for [ifm, ifm2]
read_shapes = list(parent_op.read_shapes) # read shapes for [ifm, ifm2]
write_offset = Shape4D(0, 0, 0, 0)
if parent_op.write_offset is not None:
write_offset = parent_op.write_offset
ofm_start = write_offset
ofm_end = parent_op.write_offset + parent_op.write_shape
# Create activation function if needed
for op in ps.ops:
if op.type.is_relu_op() or op.type in (Op.Tanh, Op.Sigmoid):
ps.primary_op.activation = create_activation_function(
op.type, min=op.attrs.get("min", None), max=op.attrs.get("max", None)
)
# Generate commands for the Op that produces this Op's IFM, if applicable
if cascade_info is None or cascade_info.start == sched_op.index:
# Lone Op or First Op in cascade - all IFM data is present
ifm_present = Box([0, 0, 0, 0], ifm.shape.as_list())
producer_op = None
prev_cmd_gen = []
else:
ifm_present = Box([0, 0, 0, 0], [0, 0, 0, 0])
producer_op = sched_op.ifm.connection.producers[0]
prev_cmd_gen = generate_high_level_commands_for_sched_op(producer_op, schedule)
ofm_step = op_info.stripe
for start_height in range(ofm_start.height, ofm_end.height, ofm_step.height):
end_height = min(start_height + ofm_step.height, ofm_end.height)
for start_width in range(ofm_start.width, ofm_end.width, ofm_step.width):
end_width = min(start_width + ofm_step.width, ofm_end.width)
lut_dma_done = False
for depth_idx, start_channel in enumerate(ofm_depth_slices[:-1]):
start_channel = max(start_channel, ofm_start.depth)
end_channel = min(ofm_depth_slices[depth_idx + 1], ofm_end.depth)
# Construct the OFM box for the current stripe
ofm_box_start = Shape4D(ofm_start.batch, start_height, start_width, start_channel)
ofm_box_end = Shape4D(ofm_end.batch, end_height, end_width, end_channel)
ofm_box = Box(ofm_box_start.as_list(), ofm_box_end.as_list())
ifm_box = Box([], [])
ifm2_box = Box([], [])
# Calculate IFM input box based on the OFM box
if ifm:
ifm_box, pad_top, pad_bottom = ofm_box.transform_with_strides_and_skirt(
strides,
skirt,
ifm.shape,
npu_block_type,
write_offset.as_list(),
k_dilated_height,
read_offsets[0],
read_shapes[0],
upscaling,
)
# Calculate IFM2 input box based on the OFM box
if ifm2:
ifm2_box, pad_top, pad_bottom = ofm_box.transform_with_strides_and_skirt(
strides,
skirt,
ifm2.shape,
npu_block_type,
write_offset.as_list(),
k_dilated_height,
read_offsets[1],
read_shapes[1],
upscaling,
)
ifm_required = ifm_box
# Get the Op that produces this Op's IFM data - only applicable within cascades
if producer_op:
assert op_info.cascade != 0
assert op_info.cascade == schedule.cost_map[producer_op].cascade
for prev_cmd in prev_cmd_gen:
yield prev_cmd
if prev_cmd.is_npu_pass_command() and prev_cmd.ps == producer_op.parent_ps:
ifm_present.end_coord = prev_cmd.ofm_box.end_coord
if ifm_required.is_subbox_of(ifm_present):
# There is enough IFM data - exit loop
break
# Information about the current stripe's location in the cascade
is_first_h_stripe = ofm_box_start.height == ofm_start.height
is_last_h_stripe = ofm_box_end.height >= ofm_end.height
# Calculate the weight box - i.e. the subshape of weights needed for this NpuStripe command
weight_tensor = op_info.npu_weights_tensor
scale_tensor = op_info.npu_scales_tensor
if op_info.npu_weights_tensor:
weight_box = Box([0, 0, 0, start_channel], [1, 1, 1, end_channel])
if op_info.buffered_weight_tensors and is_first_h_stripe:
idx = depth_idx % len(op_info.buffered_weight_tensors)
yield from dma_if_necessary(
sched_op.parent_ps, weight_box, op_info.buffered_weight_tensors[idx]
)
weight_tensor = op_info.buffered_weight_tensors[idx]
else:
weight_box = None
# Should only be done once per loop but not before weights above
if parent_op.activation_lut and not lut_dma_done:
lut_tensor = [tens for tens in parent_op.inputs if tens.purpose == TensorPurpose.LUT][0]
lut_box = Box([0] * len(lut_tensor.shape), list(lut_tensor.shape))
lut_dma_done = True
yield from dma_if_necessary(sched_op.parent_ps, lut_box, lut_tensor)
yield NpuStripe(
sched_op.parent_ps,
block_config.old_style_representation(),
is_first_h_stripe,
is_last_h_stripe,
ifm_tensor,
ifm_box,
ofm_tensor,
ofm_box,
weight_tensor,
weight_box,
scale_tensor,
ifm2_tensor=ifm2_tensor,
ifm2_box=ifm2_box,
pad_top=pad_top,
pad_bottom=pad_bottom,
)
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