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HDM-interaction-recon / model /simple /simple_model_utils.py

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	from typing import Any, Callable, Iterable, List, Optional, Union

	import torch
	import torch.jit as jit
	import torch.nn as nn
	import torch.nn.functional as F
	from torch import Size, Tensor, nn
	from torch.nn import LayerNorm

	from model.pvcnn.pvcnn_utils import get_timestep_embedding


	def sample_b(size: Size, sigma: float) -> Tensor:
	"""Sample b matrix for fourier features

	Arguments:
	size (Size): b matrix size
	sigma (float): std of the gaussian

	Returns:
	b (Tensor): b matrix
	"""
	return torch.randn(size) * sigma


	@jit.script
	def map_positional_encoding(v: Tensor, freq_bands: Tensor) -> Tensor:
	"""Map v to positional encoding representation phi(v)

	Arguments:
	v (Tensor): input features (B, IFeatures)
	freq_bands (Tensor): frequency bands (N_freqs, )

	Returns:
	phi(v) (Tensor): fourrier features (B, 3 + (2 * N_freqs) * 3)
	"""
	pe = [v]
	for freq in freq_bands:
	fv = freq * v
	pe += [torch.sin(fv), torch.cos(fv)]
	return torch.cat(pe, dim=-1)


	@jit.script
	def map_fourier_features(v: Tensor, b: Tensor) -> Tensor:
	"""Map v to fourier features representation phi(v)

	Arguments:
	v (Tensor): input features (B, IFeatures)
	b (Tensor): b matrix (OFeatures, IFeatures)

	Returns:
	phi(v) (Tensor): fourrier features (B, 2 * Features)
	"""
	PI = 3.141592653589793
	a = 2 * PI * v @ b.T
	return torch.cat((torch.sin(a), torch.cos(a)), dim=-1)


	class FeatureMapping(nn.Module):
	"""FeatureMapping nn.Module

	Maps v to features following transformation phi(v)

	Arguments:
	i_dim (int): input dimensions
	o_dim (int): output dimensions
	"""

	def __init__(self, i_dim: int, o_dim: int) -> None:
	super().__init__()
	self.i_dim = i_dim
	self.o_dim = o_dim

	def forward(self, v: Tensor) -> Tensor:
	"""FeratureMapping forward pass

	Arguments:
	v (Tensor): input features (B, IFeatures)

	Returns:
	phi(v) (Tensor): mapped features (B, OFeatures)
	"""
	raise NotImplementedError("Forward pass not implemented yet!")


	class PositionalEncoding(FeatureMapping):
	"""PositionalEncoding module

	Maps v to positional encoding representation phi(v)

	Arguments:
	i_dim (int): input dimension for v
	N_freqs (int): #frequency to sample (default: 10)
	"""

	def __init__(
	self,
	i_dim: int,
	N_freqs: int = 10,
	) -> None:
	super().__init__(i_dim, 3 + (2 * N_freqs) * 3)
	self.N_freqs = N_freqs

	a, b = 1, self.N_freqs - 1
	freq_bands = 2 ** torch.linspace(a, b, self.N_freqs)
	self.register_buffer("freq_bands", freq_bands)

	def forward(self, v: Tensor) -> Tensor:
	"""Map v to positional encoding representation phi(v)

	Arguments:
	v (Tensor): input features (B, IFeatures)

	Returns:
	phi(v) (Tensor): fourrier features (B, 3 + (2 * N_freqs) * 3)
	"""
	return map_positional_encoding(v, self.freq_bands)


	class FourierFeatures(FeatureMapping):

	"""Fourier Features module

	Maps v to fourier features representation phi(v)

	Arguments:
	i_dim (int): input dimension for v
	features (int): output dimension (default: 256)
	sigma (float): std of the gaussian (default: 26.)
	"""

	def __init__(
	self,
	i_dim: int,
	features: int = 256,
	sigma: float = 26.,
	) -> None:
	super().__init__(i_dim, 2 * features)
	self.features = features
	self.sigma = sigma

	self.size = Size((self.features, self.i_dim))
	self.register_buffer("b", sample_b(self.size, self.sigma))

	def forward(self, v: Tensor) -> Tensor:
	"""Map v to fourier features representation phi(v)

	Arguments:
	v (Tensor): input features (B, IFeatures)

	Returns:
	phi(v) (Tensor): fourrier features (B, 2 * Features)
	"""
	return map_fourier_features(v, self.b)


	class FeedForward(nn.Module):
	""" Adapted from the FeedForward layer from labmlai """

	def __init__(
	self,
	d_in: int,
	d_hidden: int,
	d_out: int,
	activation: Callable = nn.ReLU(),
	is_gated: bool = False,
	bias1: bool = True,
	bias2: bool = True,
	bias_gate: bool = True,
	dropout: float = 0.1,
	use_layernorm: bool = False,
	):
	super().__init__()
	# Layer one parameterized by weight $W_1$ and bias $b_1$
	self.layer1 = nn.Linear(d_in, d_hidden, bias=bias1)
	# Layer one parameterized by weight $W_1$ and bias $b_1$
	self.layer2 = nn.Linear(d_hidden, d_out, bias=bias2)
	# Hidden layer dropout
	self.dropout = nn.Dropout(dropout)
	# Activation function $f$
	self.activation = activation
	# Whether there is a gate
	self.is_gated = is_gated
	if is_gated:
	# If there is a gate the linear layer to transform inputs to
	# be multiplied by the gate, parameterized by weight $V$ and bias $c$
	self.linear_v = nn.Linear(d_in, d_hidden, bias=bias_gate)
	# Whether to add a layernorm layer
	self.use_layernorm = use_layernorm
	if use_layernorm:
	self.layernorm = LayerNorm(d_in)

	def forward(self, x: Tensor, coords: Tensor = None) -> Tensor:
	"""Applies a simple feed forward layer"""
	x = self.layernorm(x) if self.use_layernorm else x
	g = self.activation(self.layer1(x))
	x = (g * self.linear_v(x)) if self.is_gated else g
	x = self.dropout(x)
	x = self.layer2(x)
	return x


	class BasePointModel(nn.Module):
	""" A base class providing useful methods for point cloud processing. """

	def __init__(
	self,
	*,
	num_classes,
	embed_dim,
	extra_feature_channels,
	dim: int = 128,
	num_layers: int = 6
	):

	super().__init__()
	self.extra_feature_channels = extra_feature_channels
	self.timestep_embed_dim = embed_dim
	self.output_dim = num_classes
	self.dim = dim
	self.num_layers = num_layers

	# Time embedding function
	self.timestep_projection = nn.Sequential(
	nn.Linear(embed_dim, embed_dim),
	nn.LeakyReLU(0.1, inplace=True),
	nn.Linear(embed_dim, embed_dim),
	)

	# Positional encoding
	self.positional_encoding = PositionalEncoding(i_dim=3, N_freqs=10)
	positional_encoding_d_out = 3 + (2 * 10) * 3

	# Input projection (point coords, point coord encodings, other features, and timestep embeddings)
	self.input_projection = nn.Linear(
	in_features=(3 + positional_encoding_d_out + extra_feature_channels + self.timestep_embed_dim),
	out_features=self.dim
	)

	# Transformer layers
	self.layers = self.get_layers()

	# Output projection
	self.output_projection = nn.Linear(self.dim, self.output_dim)

	def get_layers(self):
	raise NotImplementedError('This method should be implemented by subclasses')

	def prepare_inputs(self, inputs: torch.Tensor, t: torch.Tensor) -> torch.Tensor:
	"""
	The inputs have size (B, 3 + S, N), where S is the number of additional
	feature channels and N is the number of points. The timesteps t can be either
	continuous or discrete. This model has a sort of U-Net-like structure I think,
	which is why it first goes down and then up in terms of resolution (?)
	"""

	# Embed and project timesteps
	t_emb = get_timestep_embedding(self.timestep_embed_dim, t, inputs.device)
	t_emb = self.timestep_projection(t_emb)[:, None, :].expand(-1, inputs.shape[-1], -1) # (B, N, D_t_emb)

	# Separate input coordinates and features
	x = torch.transpose(inputs, -2, -1) # -> (B, N, 3 + S)
	coords = x[:, :, :3] # (B, N, 3), point coordinates

	# Positional encoding of point coords
	coords_posenc = self.positional_encoding(coords) # (B, N, D_p_enc)

	# Project
	x = torch.cat((x, coords_posenc, t_emb), dim=2) # (B, N, 3 + S + D_p_enc + D_t_emb)
	x = self.input_projection(x) # (B, N, D_model)

	return x, coords

	def get_global_tensors(self, x: Tensor):
	B, N, D = x.shape
	x_pool_max = torch.max(x, dim=1, keepdim=True).values.repeat(1, N, 1) # (B, 1, D)
	x_pool_std = torch.std(x, dim=1, keepdim=True).repeat(1, N, 1) # (B, 1, D)
	return x_pool_max, x_pool_std

	def forward(self, inputs: torch.Tensor, t: torch.Tensor):
	raise NotImplementedError('This method should be implemented by subclasses')