rwightman/median_pool.py

## median_pool.py
import math
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch.nn.modules.utils import _pair, _quadruple


class MedianPool2d(nn.Module):
    """ Median pool (usable as median filter when stride=1) module.

    Args:
         kernel_size: size of pooling kernel, int or 2-tuple
         stride: pool stride, int or 2-tuple
         padding: pool padding, int or 4-tuple (l, r, t, b) as in pytorch F.pad
         same: override padding and enforce same padding, boolean
    """
    def __init__(self, kernel_size=3, stride=1, padding=0, same=False):
        super(MedianPool2d, self).__init__()
        self.k = _pair(kernel_size)
        self.stride = _pair(stride)
        self.padding = _quadruple(padding)  # convert to l, r, t, b
        self.same = same

    def _padding(self, x):
        if self.same:
            ih, iw = x.size()[2:]
            if ih % self.stride[0] == 0:
                ph = max(self.k[0] - self.stride[0], 0)
            else:
                ph = max(self.k[0] - (ih % self.stride[0]), 0)
            if iw % self.stride[1] == 0:
                pw = max(self.k[1] - self.stride[1], 0)
            else:
                pw = max(self.k[1] - (iw % self.stride[1]), 0)
            pl = pw // 2
            pr = pw - pl
            pt = ph // 2
            pb = ph - pt
            padding = (pl, pr, pt, pb)
        else:
            padding = self.padding
        return padding

    def forward(self, x):
        # using existing pytorch functions and tensor ops so that we get autograd,
        # would likely be more efficient to implement from scratch at C/Cuda level
        x = F.pad(x, self._padding(x), mode='reflect')
        x = x.unfold(2, self.k[0], self.stride[0]).unfold(3, self.k[1], self.stride[1])
        x = x.contiguous().view(x.size()[:4] + (-1,)).median(dim=-1)[0]
        return x
	import math
	import torch
	import torch.nn as nn
	import torch.nn.functional as F
	from torch.nn.modules.utils import _pair, _quadruple


	class MedianPool2d(nn.Module):
	""" Median pool (usable as median filter when stride=1) module.

	Args:
	kernel_size: size of pooling kernel, int or 2-tuple
	stride: pool stride, int or 2-tuple
	padding: pool padding, int or 4-tuple (l, r, t, b) as in pytorch F.pad
	same: override padding and enforce same padding, boolean
	"""
	def __init__(self, kernel_size=3, stride=1, padding=0, same=False):
	super(MedianPool2d, self).__init__()
	self.k = _pair(kernel_size)
	self.stride = _pair(stride)
	self.padding = _quadruple(padding) # convert to l, r, t, b
	self.same = same

	def _padding(self, x):
	if self.same:
	ih, iw = x.size()[2:]
	if ih % self.stride[0] == 0:
	ph = max(self.k[0] - self.stride[0], 0)
	else:
	ph = max(self.k[0] - (ih % self.stride[0]), 0)
	if iw % self.stride[1] == 0:
	pw = max(self.k[1] - self.stride[1], 0)
	else:
	pw = max(self.k[1] - (iw % self.stride[1]), 0)
	pl = pw // 2
	pr = pw - pl
	pt = ph // 2
	pb = ph - pt
	padding = (pl, pr, pt, pb)
	else:
	padding = self.padding
	return padding

	def forward(self, x):
	# using existing pytorch functions and tensor ops so that we get autograd,
	# would likely be more efficient to implement from scratch at C/Cuda level
	x = F.pad(x, self._padding(x), mode='reflect')
	x = x.unfold(2, self.k[0], self.stride[0]).unfold(3, self.k[1], self.stride[1])
	x = x.contiguous().view(x.size()[:4] + (-1,)).median(dim=-1)[0]
	return x