277 lines
8.9 KiB
Python
277 lines
8.9 KiB
Python
# Licensed to the Apache Software Foundation (ASF) under one
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# or more contributor license agreements. See the NOTICE file
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# distributed with this work for additional information
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# regarding copyright ownership. The ASF licenses this file
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# to you under the Apache License, Version 2.0 (the
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# "License"); you may not use this file except in compliance
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# with the License. You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing,
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# software distributed under the License is distributed on an
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# "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
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# KIND, either express or implied. See the License for the
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# specific language governing permissions and limitations
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# under the License.
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# pylint: disable=invalid-name, too-many-locals, too-many-arguments
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# pylint: disable=unused-argument, redefined-builtin
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"""Bitserial Conv2D operators"""
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import tvm
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from tvm import te
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from ..utils import get_const_tuple
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from .bitserial_util import bitpack
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from .pad import pad
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from .utils import get_pad_tuple
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def bitserial_conv2d_nchw(
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data,
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kernel,
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stride,
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padding,
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activation_bits,
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weight_bits,
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pack_dtype="uint32",
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out_dtype="int16",
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unipolar=True,
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):
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"""Bitserial Conv2D operator.
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Parameters
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----------
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data : tvm.te.Tensor
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4-D with shape [batch, in_channel, in_height, in_width]
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kernel : tvm.te.Tensor
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4-D with shape [num_filter, in_channel, filter_height, filter_width]
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stride : int or a list/tuple of two ints
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stride size, or [stride_height, stride_width]
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padding : int or a list/tuple of two or four ints
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padding size, [pad_height, pad_width], [pad_top, pad_left, pad_down, pad_right]
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activation_bits: int
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number of bits used for activations/input elements
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weight_bits: int
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number of bits used for weight elements
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out_dtype: str
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return type of convolution
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pack_dtype: str
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bit packing type
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unipolar: bool
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if binarization style is in unipolar 1/0 format, instead of bipolar -1/+1 format
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Returns
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-------
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output : tvm.te.Tensor
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4-D with shape [batch, out_channel, out_height, out_width]
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"""
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assert isinstance(stride, int) or len(stride) == 2
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Input_q = bitpack(data, activation_bits, pack_axis=1, bit_axis=2, pack_type=pack_dtype)
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if len(kernel.shape) == 4:
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Filter_q = bitpack(kernel, weight_bits, pack_axis=1, bit_axis=4, pack_type=pack_dtype)
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else:
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Filter_q = kernel
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batch, in_channel, activation_bits, in_height, in_width = Input_q.shape
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num_filter, _, kernel_h, kernel_w, weight_bits = Filter_q.shape
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if isinstance(padding, int) or (isinstance(padding, tuple | list) and len(padding) == 2):
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TPAD, LPAD, DPAD, RPAD = get_pad_tuple(padding, kernel)
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else:
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TPAD, LPAD, DPAD, RPAD = padding
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pad_before = [0, 0, 0, TPAD, LPAD]
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pad_after = [0, 0, 0, DPAD, RPAD]
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PadInput_q = pad(Input_q, pad_before, pad_after, name="pad_temp")
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# compute the output shape
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if isinstance(stride, int):
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stride_h = stride_w = stride
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else:
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stride_h, stride_w = stride
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out_channel = num_filter
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out_height = (in_height - kernel_h + TPAD + DPAD) // stride_h + 1
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out_width = (in_width - kernel_w + LPAD + RPAD) // stride_w + 1
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rc = te.reduce_axis((0, in_channel), name="rc")
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ry = te.reduce_axis((0, kernel_h), name="ry")
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rx = te.reduce_axis((0, kernel_w), name="rx")
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b1 = te.reduce_axis((0, activation_bits), name="b1")
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b2 = te.reduce_axis((0, weight_bits), name="b2")
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if unipolar:
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def _conv(nn, ff, yy, xx):
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b1b2 = (b1 + b2).astype(out_dtype)
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return te.sum(
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(
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(
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tvm.tirx.popcount(
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PadInput_q[nn, rc, b1, yy * stride_h + ry, xx * stride_w + rx]
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& Filter_q[ff, rc, ry, rx, b2]
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)
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- tvm.tirx.popcount(
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PadInput_q[nn, rc, b1, yy * stride_h + ry, xx * stride_w + rx]
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& ~Filter_q[ff, rc, ry, rx, b2]
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)
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)
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<< (b1b2)
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).astype(out_dtype),
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axis=[rc, ry, rx, b2, b1],
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).astype(out_dtype)
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else:
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def _conv(nn, ff, yy, xx):
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b1b2 = (b1 + b2).astype(out_dtype)
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return te.sum(
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(
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tvm.tirx.popcount(
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PadInput_q[nn, rc, b1, yy * stride_h + ry, xx * stride_w + rx]
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& Filter_q[ff, rc, ry, rx, b2]
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)
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<< (b1b2)
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).astype(out_dtype),
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axis=[rc, ry, rx, b2, b1],
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).astype(out_dtype)
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return te.compute(
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(batch, out_channel, out_height, out_width),
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_conv,
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name="Conv2dOutput",
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tag="bitserial_conv2d_nchw",
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)
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def bitserial_conv2d_nhwc(
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data,
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kernel,
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stride,
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padding,
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activation_bits,
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weight_bits,
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pack_dtype="uint32",
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out_dtype="int16",
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unipolar=True,
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):
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"""Bitserial Conv2D operator.
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Parameters
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----------
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data : tvm.te.Tensor
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4-D with shape [batch, in_height, in_width, in_channel]
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kernel : tvm.te.Tensor
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4-D with shape [filter_height, filter_width, in_channel, num_filter]
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stride : int or a list/tuple of two ints
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stride size, or [stride_height, stride_width]
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padding : int or a list/tuple of two or four ints
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padding size, [pad_height, pad_width], [pad_top, pad_left, pad_down, pad_right]
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activation_bits: int
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number of bits used for activations/input elements
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weight_bits: int
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number of bits used for weight elements
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out_dtype: str
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return type of convolution
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pack_dtype: str
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bit packing type
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unipolar: bool
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if binarization style is in unipolar 1/0 format, instead of bipolar -1/+1 format
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Returns
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-------
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output : tvm.te.Tensor
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4-D with shape [batch, out_height, out_width, out_channel]
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"""
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assert isinstance(stride, int) or len(stride) == 2
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Input_q = bitpack(data, activation_bits, pack_axis=3, bit_axis=4, pack_type=pack_dtype)
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if len(kernel.shape) == 4:
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Filter_q = bitpack(kernel, weight_bits, pack_axis=2, bit_axis=4, pack_type=pack_dtype)
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kernel_h, kernel_w, _, num_filter, _ = get_const_tuple(Filter_q.shape)
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else:
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Filter_q = kernel
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kernel_h, kernel_w, _, _, num_filter = get_const_tuple(Filter_q.shape)
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batch, in_height, in_width, in_channel_q, _ = get_const_tuple(Input_q.shape)
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if isinstance(padding, int) or (isinstance(padding, tuple | list) and len(padding) == 2):
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TPAD, LPAD, DPAD, RPAD = get_pad_tuple(padding, kernel)
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else:
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TPAD, LPAD, DPAD, RPAD = padding
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pad_before = [0, TPAD, LPAD, 0, 0]
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pad_after = [0, DPAD, RPAD, 0, 0]
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# compute the output shape
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if isinstance(stride, int):
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stride_h = stride_w = stride
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else:
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stride_h, stride_w = stride
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out_channel = num_filter
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out_height = (in_height - kernel_h + TPAD + DPAD) // stride_h + 1
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out_width = (in_width - kernel_w + LPAD + RPAD) // stride_w + 1
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PadInput_q = pad(Input_q, pad_before, pad_after, name="PaddedInput")
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rc = te.reduce_axis((0, in_channel_q), name="rc")
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ry = te.reduce_axis((0, kernel_h), name="ry")
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rx = te.reduce_axis((0, kernel_w), name="rx")
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b1 = te.reduce_axis((0, activation_bits), name="b1")
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b2 = te.reduce_axis((0, weight_bits), name="b2")
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if unipolar:
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def _conv(nn, yy, xx, ff):
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b1b2 = (b1 + b2).astype(out_dtype)
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return te.sum(
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(
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(
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tvm.tirx.popcount(
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PadInput_q[nn, yy * stride_h + ry, xx * stride_w + rx, rc, b1]
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& Filter_q[ry, rx, rc, ff, b2]
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)
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- tvm.tirx.popcount(
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PadInput_q[nn, yy * stride_h + ry, xx * stride_w + rx, rc, b1]
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& ~Filter_q[ry, rx, rc, ff, b2]
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)
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)
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<< b1b2
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).astype(out_dtype),
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axis=[rc, ry, rx, b2, b1],
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)
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else:
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def _conv(nn, yy, xx, ff):
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b1b2 = (b1 + b2).astype(out_dtype)
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return te.sum(
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(
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tvm.tirx.popcount(
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PadInput_q[nn, yy * stride_h + ry, xx * stride_w + rx, rc, b1]
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& Filter_q[ry, rx, rc, ff, b2]
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)
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<< b1b2
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).astype(out_dtype),
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axis=[rc, ry, rx, b2, b1],
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)
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conv = te.compute(
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(batch, out_height, out_width, out_channel),
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_conv,
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name="Conv2dOutput",
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tag="bitserial_conv2d_nhwc",
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)
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return conv
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