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deconv.py
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deconv.py
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# -*- coding: utf-8 -*-
"""
.. invisible:
_ _ _____ _ _____ _____
| | | | ___| | | ___/ ___|
| | | | |__ | | | |__ \ `--.
| | | | __|| | | __| `--. \
\ \_/ / |___| |___| |___/\__/ /
\___/\____/\_____|____/\____/
Created on Jul 1, 2014
Deconvolutional layer.
███████████████████████████████████████████████████████████████████████████████
Licensed to the Apache Software Foundation (ASF) under one
or more contributor license agreements. See the NOTICE file
distributed with this work for additional information
regarding copyright ownership. The ASF licenses this file
to you 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
http://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.
███████████████████████████████████████████████████████████████████████████████
"""
from __future__ import division
import cuda4py.blas as cublas
import numpy
from zope.interface import implementer
from veles.config import root
from veles.compat import from_none
from veles.accelerated_units import IOpenCLUnit, ICUDAUnit, INumpyUnit
from veles.memory import Array
import veles.ocl_blas as ocl_blas
from veles.znicz.conv import ConvolutionalBase
import veles.znicz.nn_units as nn_units
from veles.distributable import TriviallyDistributable
@implementer(IOpenCLUnit, ICUDAUnit, INumpyUnit)
class Deconv(TriviallyDistributable, ConvolutionalBase, nn_units.Forward):
# TriviallyDistributable overrides nn_units.Forward IDistributable
"""Deconvolutional layer for simple convolutional layer
with linear activation and without bias.
Must be assigned before initialize():
input
weights
output_shape_source
Updates after run():
output
Creates within initialize():
output
Attributes:
input: input as batch of multichannel interleaved images.
output: output as batch of multichannel interleaved images.
weights: matrix of weights.
output_shape_source: Array to get output shape from.
n_kernels: number of convolutional kernels
in the corresponding convolutional layer.
kx: kernel width.
ky: kernel height.
sliding: tuple of kernel sliding (by x-axis, by y-axis),
kx, ky MUST be a multiple of sliding to avoid irregularities.
padding: tuple of virtual sample padding (left, top, right, bottom),
will be computed automatically based on sliding.
weights_transposed: assume weights matrix as a transposed one.
unsafe_padding: flag to enable unsafe padding and/or sliding.
"""
MAPPING = {"deconv"}
@staticmethod
def compute_padding(sx, sy, kx, ky, sliding):
"""Computes required padding.
"""
return (kx - sliding[1], ky - sliding[0],
kx - sx % sliding[1] if sx % sliding[1] != 0
else kx - sliding[1],
ky - sy % sliding[0] if sy % sliding[0] != 0
else ky - sliding[0])
@staticmethod
def check_padding_is_safe(kx, ky, sliding):
if sliding[0] > (ky >> 1) or sliding[1] > (kx >> 1):
raise ValueError(
"sliding should not be greater than half of the kernel size")
if kx % sliding[0] != 0 or kx % sliding[1] != 0:
raise ValueError(
"Kernel size should be multiple of sliding")
def __init__(self, workflow, **kwargs):
super(Deconv, self).__init__(workflow, **kwargs)
self.unsafe_padding = kwargs.get("unsafe_padding", False)
self.hits = Array()
self.krn_clear_output_ = None
self._global_size = None
self._local_size = None
del self.bias
self.demand("n_kernels", "kx", "ky", "padding", "sliding",
"input", "weights", "output_shape_source")
def init_unpickled(self):
super(Deconv, self).init_unpickled()
self.sources_["deconv/forward"] = {}
def initialize(self, device, **kwargs):
super(Deconv, self).initialize(device, **kwargs)
self._dtype = self.input.dtype
self.weights_shape = (tuple(reversed(self.weights.shape))
if self.weights_transposed
else self.weights.shape)
if hasattr(self, "bias"):
raise ValueError("bias should not be set")
if (len(self.input.shape) != 4 or
self.input.shape[3] != self.n_kernels):
raise ValueError("Incorrectly shaped input encountered")
if (len(self.weights_shape) != 2 or
self.weights_shape[0] != self.n_kernels or
self.weights_shape[1] % (self.kx * self.ky) != 0):
raise ValueError("Incorrectly shaped weights encountered")
output_shape = tuple(self.output_shape_source.shape)
if len(output_shape) != 4:
raise ValueError("Incorrect output_shape_source shape")
if output_shape[0] != self.input.shape[0]:
raise ValueError(
"output_shape_source.shape[0] != input.shape[0]")
try:
self.check_padding_is_safe(self.kx, self.ky, self.sliding)
except ValueError as e:
if not self.unsafe_padding:
raise from_none(e)
self.warning("The padding will be unsafe")
self._create_hits(output_shape)
padding = Deconv.compute_padding(
output_shape[2], output_shape[1], self.kx, self.ky, self.sliding)
if self.padding is None: # pylint: disable=E0203
self.padding = padding
elif self.padding != padding:
if not self.unsafe_padding:
raise ValueError(
"Expected padding %s but got %s" % (padding, self.padding))
self._create_hits(output_shape)
if self.output:
assert self.output.shape[1:] == output_shape[1:]
if not self.output or self.output.shape[0] != output_shape[0]:
self.output.reset(numpy.zeros(output_shape,
dtype=self._dtype))
self._output_shape = output_shape
self._sy, self._sx, self._n_channels = self._output_shape[1:]
self._kernel_size = self.kx * self.ky * self._n_channels
self._kernel_app_per_image = self.input.sample_size // self.n_kernels
self._kernel_app_total = (self._kernel_app_per_image *
self.input.shape[0])
self.init_vectors(self.input, self.weights, self.output, self.hits)
def _create_hits(self, output_shape):
if not self.hits:
self.hits.reset(
numpy.zeros(output_shape, dtype=numpy.int32))
else:
assert self.hits.size == int(numpy.prod(output_shape))
def _gpu_init(self, blas_class):
defines = {
"USE_ATOMICS": 1,
"WEIGHTS_TRANSPOSED": int(self.weights_transposed),
"BATCH": self._output_shape[0],
"SX": self._sx,
"SY": self._sy,
"N_CHANNELS": self._n_channels,
"KX": self.kx,
"KY": self.ky,
"N_KERNELS": self.n_kernels,
"PAD_LEFT": self.padding[0],
"PAD_TOP": self.padding[1],
"PAD_RIGHT": self.padding[2],
"PAD_BOTTOM": self.padding[3],
"SLIDE_X": self.sliding[0],
"SLIDE_Y": self.sliding[1],
"USE_HITS": int(bool(self.hits)),
"DECONV_MODE": int(bool(self.hits)) + 1,
"OUTPUT_SIZE": self.output.size
}
self.build_program(
defines, "%s/%s_%d_%dx%dx%d_%dx%d_%d" % (
root.common.dirs.cache, self.__class__.__name__,
self.input.shape[0],
self._output_shape[2], self._output_shape[1],
self._output_shape[3],
self.kx, self.ky, self.n_kernels), dtype=self._dtype)
self.krn_pack_ = self.get_kernel("DirectPack")
unpack_bytes = (self._kernel_app_per_image * self.unpack_size *
self._kernel_size * self.input.itemsize)
self.device.request_temp_buffer(unpack_bytes)
if self.hits:
self.krn_pack_.set_arg(3, self.hits.devmem)
self.krn_apply_hits_ = self.get_kernel("apply_hits")
self.krn_apply_hits_.set_args(self.output.devmem, self.hits.devmem)
self.gemm_ = blas_class.gemm(self._dtype)
self.np_one = numpy.ones(1, dtype=self._dtype)
self.np_zero = numpy.zeros(1, dtype=self._dtype)
self._const_i = numpy.zeros(1, dtype=numpy.int64)
def ocl_init(self):
ocl_blas.OCLBLAS.attach_to_device(self.device)
self._gpu_init(ocl_blas.OCLBLAS)
self._global_size_pack = lambda size: (size,)
self._local_size_pack = None
if self.hits:
self.krn_clear_hits_ = self.get_kernel("clear_hits")
self.krn_clear_hits_.set_arg(0, self.hits.devmem)
self._global_size_hits = (self.output.size,)
self._local_size_hits = None
self.krn_clear_output_ = self.get_kernel("clear_output")
self.krn_clear_output_.set_arg(0, self.output.devmem)
self._clear_output = lambda: (
self.execute_kernel((self.output.size,), None,
self.krn_clear_output_))
self._clear_hits = lambda: (
self.execute_kernel((self.hits.size,), None, self.krn_clear_hits_))
self._process_subblock = self._ocl_process_subblock
self.krn_pack_.set_arg(1, self.output.devmem)
def cuda_init(self):
self._gpu_init(cublas.CUBLAS)
block_size = self.device.suggest_block_size(self.krn_pack_)
self._global_size_pack = (
lambda size: (int(numpy.ceil(size / block_size)), 1, 1))
self._local_size_pack = (block_size, 1, 1)
if self.hits:
block_size = self.device.suggest_block_size(self.krn_apply_hits_)
self._global_size_hits = (
int(numpy.ceil(self.output.size / block_size)), 1, 1)
self._local_size_hits = (block_size, 1, 1)
self._clear_output = lambda: self.output.devmem.memset32_async()
self._clear_hits = lambda: self.hits.devmem.memset32_async()
self._process_subblock = self._cuda_process_subblock
def ocl_run(self):
self.gpu_run()
def cuda_run(self):
self.gpu_run()
def gpu_run(self):
self.unmap_vectors(self.output, self.input, self.weights)
unpack_data = self.device.get_temp_buffer()
self._clear_output()
if self.hits:
self.hits.unmap()
self._clear_hits()
batch_size = self.output.shape[0]
for i in range(0, batch_size, self.unpack_size):
self._process_subblock(i, min(batch_size - i, self.unpack_size),
unpack_data)
if self.hits:
self.execute_kernel(self._global_size_hits, self._local_size_hits,
self.krn_apply_hits_)
def _cuda_process_subblock(self, start_image, image_count, unpack_data):
output_offs = (start_image * self.input.sample_size *
self.input.itemsize)
unpack_side = self._kernel_app_per_image * image_count
self.gemm_(
self.device.blas, cublas.CUBLAS_OP_T if self.weights_transposed
else cublas.CUBLAS_OP_N, cublas.CUBLAS_OP_N,
self._kernel_size, unpack_side, self.weights_shape[0],
self.np_one, self.weights.devmem,
int(self.input.devmem) + output_offs,
self.np_zero, unpack_data)
self.krn_pack_.set_arg(0, unpack_data)
self.krn_pack_.set_arg(
1, int(self.output.devmem) +
start_image * self.output.sample_size * self.output.itemsize)
limit = unpack_side * self._kernel_size
self._const_i[0] = limit
self.krn_pack_.set_arg(2, self._const_i)
self.execute_kernel(self._global_size_pack(limit),
self._local_size_pack, self.krn_pack_)
def _ocl_process_subblock(self, start_image, image_count, unpack_data):
output_offs = start_image * self.input.sample_size
unpack_side = self._kernel_app_per_image * image_count
self.gemm_(
self.device.blas, cublas.CUBLAS_OP_T if self.weights_transposed
else cublas.CUBLAS_OP_N, cublas.CUBLAS_OP_N,
self._kernel_size, unpack_side, self.weights_shape[0],
self.np_one, self.weights.devmem,
self.input.devmem,
self.np_zero, unpack_data, offsetB=output_offs)
self.krn_pack_.set_arg(0, unpack_data)
self._const_i[0] = start_image * self.output.sample_size
self.krn_pack_.set_arg(2, self._const_i)
limit = unpack_side * self._kernel_size
self.execute_kernel(self._global_size_pack(limit),
self._local_size_pack, self.krn_pack_)
def numpy_run(self):
raise NotImplementedError()