Lilly Makkos

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	#ConvLSTM definition


	import torch.nn as nn
	import torch


	class ConvLSTMCell(nn.Module):

	def __init__(self, input_dim, hidden_dim, kernel_size, bias):
	#Input_um is the number of channels per input tensor, hidden_dim is the numer of channels of hidden state, bias is a booleam, wehther or not to add a bias

	super(ConvLSTMCell, self).__init__()

	self.input_dim = input_dim
	self.hidden_dim = hidden_dim

	self.kernel_size = kernel_size
	self.padding = (kernel_size[0])// 2, (kernel_size[1]) // 2
	self.bias = bias

	self.conv = nn.Conv2d(in_channels=self.input_dim + self.hidden_dim,
	out_channels=4 * self.hidden_dim,
	kernel_size=self.kernel_size,
	padding=self.padding,
	bias=self.bias)

	def forward(self, input_tensor, cur_state):
	h_cur, c_cur = cur_state

	combined = torch.cat([input_tensor, h_cur], dim=1) # concatenate along channel axis

	combined_conv = self.conv(combined)
	cc_i, cc_f, cc_o, cc_g = torch.split(combined_conv, self.hidden_dim, dim=1)
	i = torch.sigmoid(cc_i)
	f = torch.sigmoid(cc_f)
	o = torch.sigmoid(cc_o)
	g = torch.tanh(cc_g)

	c_next = f * c_cur + i * g
	h_next = o * torch.tanh(c_next)

	return h_next, c_next

	def init_hidden(self, batch_size, image_size):
	height, width = image_size
	return (torch.zeros(batch_size, self.hidden_dim, height, width, device=self.conv.weight.device),
	torch.zeros(batch_size, self.hidden_dim, height, width, device=self.conv.weight.device))


	class ConvLSTM(nn.Module):

	"""

	Parameters:
	input_dim: Number of channels in input
	hidden_dim: Number of hidden channels
	kernel_size: Size of kernel in convolutions
	num_layers: Number of LSTM layers stacked on each other
	batch_first: Whether or not dimension 0 is the batch or not
	bias: Bias or no bias in Convolution
	return_all_layers: Return the list of computations for all layers
	Note: Will do same padding.

	Input:
	A tensor of size B, T, C, H, W or T, B, C, H, W
	Output:
	A tuple of two lists of length num_layers (or length 1 if return_all_layers is False).
	0 - layer_output_list is the list of lists of length T of each output
	1 - last_state_list is the list of last states
	each element of the list is a tuple (h, c) for hidden state and memory
	Example:
	>> x = torch.rand((32, 10, 64, 128, 128))
	>> convlstm = ConvLSTM(64, 16, 3, 1, True, True, False)
	>> _, last_states = convlstm(x)
	>> h = last_states[0][0] # 0 for layer index, 0 for h index
	"""

	def __init__(self, input_dim, hidden_dim, kernel_size, num_layers,
	batch_first=False, bias=True, return_all_layers=False):
	super(ConvLSTM, self).__init__()

	self._check_kernel_size_consistency(kernel_size)

	# Make sure that both `kernel_size` and `hidden_dim` are lists having len == num_layers
	kernel_size = self._extend_for_multilayer(kernel_size, num_layers)
	hidden_dim = self._extend_for_multilayer(hidden_dim, num_layers)
	if not len(kernel_size) == len(hidden_dim) == num_layers:
	raise ValueError('Inconsistent list length.')

	self.input_dim = input_dim
	self.hidden_dim = hidden_dim
	self.kernel_size = kernel_size
	self.num_layers = num_layers
	self.batch_first = batch_first
	self.bias = bias
	self.return_all_layers = return_all_layers

	cell_list = []
	for i in range(0, self.num_layers):
	cur_input_dim = self.input_dim if i == 0 else self.hidden_dim[i - 1]
	# print(f"Layer {i}: input_dim={cur_input_dim}, hidden_dim={self.hidden_dim[i]}")
	cell_list.append(ConvLSTMCell(input_dim=cur_input_dim,
	hidden_dim=self.hidden_dim[i],
	kernel_size=self.kernel_size[i],
	bias=self.bias))

	self.cell_list = nn.ModuleList(cell_list)

	def forward(self, input_tensor, hidden_state=None):
	"""

	Parameters
	----------
	input_tensor: todo
	5-D Tensor either of shape (t, b, c, h, w) or (b, t, c, h, w)
	hidden_state: todo
	None. todo implement stateful

	Returns
	-------
	last_state_list, layer_output
	"""
	if not self.batch_first:
	# (t, b, c, h, w) -> (b, t, c, h, w)
	input_tensor = input_tensor.permute(1, 0, 2, 3, 4)

	b, _, _, h, w = input_tensor.size()

	# Implement stateful ConvLSTM
	if hidden_state is not None:
	raise NotImplementedError()
	else:
	# Since the init is done in forward. Can send image size here
	hidden_state = self._init_hidden(batch_size=b,
	image_size=(h, w))

	layer_output_list = []
	last_state_list = []

	seq_len = input_tensor.size(1)
	cur_layer_input = input_tensor

	for layer_idx in range(self.num_layers):

	h, c = hidden_state[layer_idx]
	output_inner = []
	for t in range(seq_len):
	# print(f"Layer {layer_idx}, Time {t}, Input shape: {cur_layer_input[:, t, :, :, :].shape}")
	h, c = self.cell_list[layer_idx](input_tensor=cur_layer_input[:, t, :, :, :],
	cur_state=[h, c])
	output_inner.append(h)

	layer_output = torch.stack(output_inner, dim=1)
	cur_layer_input = layer_output

	# print(f"ConvLSTM Layer {layer_idx} output shape: {cur_layer_input.shape}")

	layer_output_list.append(layer_output)
	last_state_list.append([h, c])

	if not self.return_all_layers:
	layer_output_list = layer_output_list[-1:]
	last_state_list = last_state_list[-1:]

	return layer_output_list, last_state_list

	def _init_hidden(self, batch_size, image_size):
	init_states = []
	for i in range(self.num_layers):
	init_states.append(self.cell_list[i].init_hidden(batch_size, image_size))
	return init_states

	@staticmethod
	def _check_kernel_size_consistency(kernel_size):
	if not (isinstance(kernel_size, tuple) or
	(isinstance(kernel_size, list) and all([isinstance(elem, tuple) for elem in kernel_size]))):
	raise ValueError('`kernel_size` must be tuple or list of tuples')

	@staticmethod
	def _extend_for_multilayer(param, num_layers):
	if not isinstance(param, list):
	param = [param] * num_layers
	return param