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model.py
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model.py
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import math
from math import pi
from typing import Optional, Tuple
import torch
from torch import nn
from torch.nn import Embedding
from torch_geometric.nn import radius_graph
from torch_geometric.nn.conv import MessagePassing
from torch_scatter import scatter
def nan_to_num(vec, num=0.0):
idx = torch.isnan(vec)
vec[idx] = num
return vec
def _normalize(vec, dim=-1):
return nan_to_num(
torch.div(vec, torch.norm(vec, dim=dim, keepdim=True)))
def swish(x):
return x * torch.sigmoid(x)
## radial basis function to embed distances
class rbf_emb(nn.Module):
def __init__(self, num_rbf, soft_cutoff_upper, rbf_trainable=False):
super().__init__()
self.soft_cutoff_upper = soft_cutoff_upper
self.soft_cutoff_lower = 0
self.num_rbf = num_rbf
self.rbf_trainable = rbf_trainable
means, betas = self._initial_params()
self.register_buffer("means", means)
self.register_buffer("betas", betas)
def _initial_params(self):
start_value = torch.exp(torch.scalar_tensor(-self.soft_cutoff_upper))
end_value = torch.exp(torch.scalar_tensor(-self.soft_cutoff_lower))
means = torch.linspace(start_value, end_value, self.num_rbf)
betas = torch.tensor([(2 / self.num_rbf * (end_value - start_value))**-2] *
self.num_rbf)
return means, betas
def reset_parameters(self):
means, betas = self._initial_params()
self.means.data.copy_(means)
self.betas.data.copy_(betas)
def forward(self, dist):
dist=dist.unsqueeze(-1)
soft_cutoff = 0.5 * \
(torch.cos(dist * pi / self.soft_cutoff_upper) + 1.0)
soft_cutoff = soft_cutoff * (dist < self.soft_cutoff_upper).float()
return soft_cutoff*torch.exp(-self.betas * torch.square((torch.exp(-dist) - self.means)))
class NeighborEmb(MessagePassing):
def __init__(self, hid_dim: int):
super(NeighborEmb, self).__init__(aggr='add')
self.embedding = nn.Embedding(95, hid_dim)
self.hid_dim = hid_dim
def forward(self, z, s, edge_index, embs):
s_neighbors = self.embedding(z)
s_neighbors = self.propagate(edge_index, x=s_neighbors, norm=embs)
s = s + s_neighbors
return s
def message(self, x_j, norm):
return norm.view(-1, self.hid_dim) * x_j
class S_vector(MessagePassing):
def __init__(self, hid_dim: int):
super(S_vector, self).__init__(aggr='add')
self.hid_dim = hid_dim
self.lin1 = nn.Sequential(
nn.Linear(hid_dim, hid_dim),
nn.SiLU())
def forward(self, s, v, edge_index, emb):
s = self.lin1(s)
emb = emb.unsqueeze(1) * v
v = self.propagate(edge_index, x=s, norm=emb)
return v.view(-1, 3, self.hid_dim)
def message(self, x_j, norm):
x_j = x_j.unsqueeze(1)
a = norm.view(-1, 3, self.hid_dim) * x_j
return a.view(-1, 3 * self.hid_dim)
class EquiMessagePassing(MessagePassing):
def __init__(
self,
hidden_channels,
num_radial,
):
super(EquiMessagePassing, self).__init__(aggr="add", node_dim=0)
self.hidden_channels = hidden_channels
self.num_radial = num_radial
self.inv_proj = nn.Sequential(
nn.Linear(3 * self.hidden_channels + self.num_radial, self.hidden_channels * 3), nn.SiLU(inplace=True),
nn.Linear(self.hidden_channels * 3, self.hidden_channels * 3), )
self.x_proj = nn.Sequential(
nn.Linear(hidden_channels, hidden_channels),
nn.SiLU(),
nn.Linear(hidden_channels, hidden_channels * 3),
)
self.rbf_proj = nn.Linear(num_radial, hidden_channels * 3)
self.inv_sqrt_3 = 1 / math.sqrt(3.0)
self.inv_sqrt_h = 1 / math.sqrt(hidden_channels)
self.reset_parameters()
def reset_parameters(self):
nn.init.xavier_uniform_(self.x_proj[0].weight)
self.x_proj[0].bias.data.fill_(0)
nn.init.xavier_uniform_(self.x_proj[2].weight)
self.x_proj[2].bias.data.fill_(0)
nn.init.xavier_uniform_(self.rbf_proj.weight)
self.rbf_proj.bias.data.fill_(0)
def forward(self, x, vec, edge_index, edge_rbf, weight, edge_vector):
xh = self.x_proj(x)
rbfh = self.rbf_proj(edge_rbf)
weight = self.inv_proj(weight)
rbfh = rbfh * weight
# propagate_type: (xh: Tensor, vec: Tensor, rbfh_ij: Tensor, r_ij: Tensor)
dx, dvec = self.propagate(
edge_index,
xh=xh,
vec=vec,
rbfh_ij=rbfh,
r_ij=edge_vector,
size=None,
)
return dx, dvec
def message(self, xh_j, vec_j, rbfh_ij, r_ij):
x, xh2, xh3 = torch.split(xh_j * rbfh_ij, self.hidden_channels, dim=-1)
xh2 = xh2 * self.inv_sqrt_3
vec = vec_j * xh2.unsqueeze(1) + xh3.unsqueeze(1) * r_ij.unsqueeze(2)
vec = vec * self.inv_sqrt_h
return x, vec
def aggregate(
self,
features: Tuple[torch.Tensor, torch.Tensor],
index: torch.Tensor,
ptr: Optional[torch.Tensor],
dim_size: Optional[int],
) -> Tuple[torch.Tensor, torch.Tensor]:
x, vec = features
x = scatter(x, index, dim=self.node_dim, dim_size=dim_size)
vec = scatter(vec, index, dim=self.node_dim, dim_size=dim_size)
return x, vec
def update(
self, inputs: Tuple[torch.Tensor, torch.Tensor]
) -> Tuple[torch.Tensor, torch.Tensor]:
return inputs
class FTE(nn.Module):
def __init__(self, hidden_channels):
super().__init__()
self.hidden_channels = hidden_channels
self.equi_proj = nn.Linear(
hidden_channels, hidden_channels * 2, bias=False
)
self.xequi_proj = nn.Sequential(
nn.Linear(hidden_channels * 2, hidden_channels),
nn.SiLU(),
nn.Linear(hidden_channels, hidden_channels * 3),
)
self.inv_sqrt_2 = 1 / math.sqrt(2.0)
self.inv_sqrt_h = 1 / math.sqrt(hidden_channels)
self.reset_parameters()
def reset_parameters(self):
nn.init.xavier_uniform_(self.equi_proj.weight)
nn.init.xavier_uniform_(self.xequi_proj[0].weight)
self.xequi_proj[0].bias.data.fill_(0)
nn.init.xavier_uniform_(self.xequi_proj[2].weight)
self.xequi_proj[2].bias.data.fill_(0)
def forward(self, x, vec, node_frame):
vec = self.equi_proj(vec)
vec1,vec2 = torch.split(
vec, self.hidden_channels, dim=-1
)
scalrization = torch.sum(vec1.unsqueeze(2) * node_frame.unsqueeze(-1), dim=1)
scalrization[:, 1, :] = torch.abs(scalrization[:, 1, :].clone())
scalar = torch.norm(vec1, dim=-2) # torch.sqrt(torch.sum(vec1 ** 2, dim=-2))
vec_dot = (vec1 * vec2).sum(dim=1)
vec_dot = vec_dot * self.inv_sqrt_h
x_vec_h = self.xequi_proj(
torch.cat(
[x, scalar], dim=-1
)
)
xvec1, xvec2, xvec3 = torch.split(
x_vec_h, self.hidden_channels, dim=-1
)
dx = xvec1 + xvec2 + vec_dot
dx = dx * self.inv_sqrt_2
dvec = xvec3.unsqueeze(1) * vec2
return dx, dvec
class aggregate_pos(MessagePassing):
def __init__(self, aggr='mean'):
super(aggregate_pos, self).__init__(aggr=aggr)
def forward(self, vector, edge_index):
v = self.propagate(edge_index, x=vector)
return v
class EquiOutput(nn.Module):
def __init__(self, hidden_channels):
super().__init__()
self.hidden_channels = hidden_channels
self.output_network = nn.ModuleList(
[
# GatedEquivariantBlock(
# hidden_channels,
# hidden_channels // 2,
# ),
GatedEquivariantBlock(hidden_channels, 1),
]
)
self.reset_parameters()
def reset_parameters(self):
for layer in self.output_network:
layer.reset_parameters()
def forward(self, x, vec):
for layer in self.output_network:
x, vec = layer(x, vec)
return vec.squeeze()
# Borrowed from TorchMD-Net
class GatedEquivariantBlock(nn.Module):
"""Gated Equivariant Block as defined in Schütt et al. (2021):
Equivariant message passing for the prediction of tensorial properties and molecular spectra
"""
def __init__(
self,
hidden_channels,
out_channels,
):
super(GatedEquivariantBlock, self).__init__()
self.out_channels = out_channels
self.vec1_proj = nn.Linear(
hidden_channels, hidden_channels, bias=False
)
self.vec2_proj = nn.Linear(hidden_channels, out_channels, bias=False)
self.update_net = nn.Sequential(
nn.Linear(hidden_channels * 2, hidden_channels),
nn.SiLU(),
nn.Linear(hidden_channels, out_channels * 2),
)
self.act = nn.SiLU()
def reset_parameters(self):
nn.init.xavier_uniform_(self.vec1_proj.weight)
nn.init.xavier_uniform_(self.vec2_proj.weight)
nn.init.xavier_uniform_(self.update_net[0].weight)
self.update_net[0].bias.data.fill_(0)
nn.init.xavier_uniform_(self.update_net[2].weight)
self.update_net[2].bias.data.fill_(0)
def forward(self, x, v):
vec1 = torch.norm(self.vec1_proj(v), dim=-2)
vec2 = self.vec2_proj(v)
x = torch.cat([x, vec1], dim=-1)
x, v = torch.split(self.update_net(x), self.out_channels, dim=-1)
v = v.unsqueeze(1) * vec2
x = self.act(x)
return x, v
class LEFTNet(torch.nn.Module):
r"""
LEFTNet
Args:
pos_require_grad (bool, optional): If set to :obj:`True`, will require to take derivative of model output with respect to the atomic positions. (default: :obj:`False`)
cutoff (float, optional): Cutoff distance for interatomic interactions. (default: :obj:`5.0`)
num_layers (int, optional): Number of building blocks. (default: :obj:`4`)
hidden_channels (int, optional): Hidden embedding size. (default: :obj:`128`)
num_radial (int, optional): Number of radial basis functions. (default: :obj:`32`)
y_mean (float, optional): Mean value of the labels of training data. (default: :obj:`0`)
y_std (float, optional): Standard deviation of the labels of training data. (default: :obj:`1`)
"""
def __init__(
self, pos_require_grad=False, cutoff=5.0, num_layers=4,
hidden_channels=128, num_radial=32, y_mean=0, y_std=1, **kwargs):
super(LEFTNet, self).__init__()
self.y_std = y_std
self.y_mean = y_mean
self.num_layers = num_layers
self.hidden_channels = hidden_channels
self.cutoff = cutoff
self.pos_require_grad = pos_require_grad
self.z_emb = Embedding(95, hidden_channels)
self.radial_emb = rbf_emb(num_radial, self.cutoff)
self.radial_lin = nn.Sequential(
nn.Linear(num_radial, hidden_channels),
nn.SiLU(inplace=True),
nn.Linear(hidden_channels, hidden_channels))
self.neighbor_emb = NeighborEmb(hidden_channels)
self.S_vector = S_vector(hidden_channels)
self.lin = nn.Sequential(
nn.Linear(3, hidden_channels // 4),
nn.SiLU(inplace=True),
nn.Linear(hidden_channels // 4, 1))
self.message_layers = nn.ModuleList()
self.FTEs = nn.ModuleList()
for _ in range(num_layers):
self.message_layers.append(
EquiMessagePassing(hidden_channels, num_radial).jittable()
)
self.FTEs.append(FTE(hidden_channels))
self.last_layer = nn.Linear(hidden_channels, 1)
if self.pos_require_grad:
self.out_forces = EquiOutput(hidden_channels)
# for node-wise frame
self.mean_neighbor_pos = aggregate_pos(aggr='mean')
self.inv_sqrt_2 = 1 / math.sqrt(2.0)
self.reset_parameters()
def reset_parameters(self):
self.radial_emb.reset_parameters()
for layer in self.message_layers:
layer.reset_parameters()
for layer in self.FTEs:
layer.reset_parameters()
self.last_layer.reset_parameters()
for layer in self.radial_lin:
if hasattr(layer, 'reset_parameters'):
layer.reset_parameters()
for layer in self.lin:
if hasattr(layer, 'reset_parameters'):
layer.reset_parameters()
def forward(self, batch_data):
z, pos, batch = batch_data.z, batch_data.posc, batch_data.batch
if self.pos_require_grad:
pos.requires_grad_()
# embed z
z_emb = self.z_emb(z)
# construct edges based on the cutoff value
edge_index = radius_graph(pos, r=self.cutoff, batch=batch)
i, j = edge_index
# embed pair-wise distance
dist = torch.norm(pos[i]-pos[j], dim=-1)
# radial_emb shape: (num_edges, num_radial), radial_hidden shape: (num_edges, hidden_channels)
radial_emb = self.radial_emb(dist)
radial_hidden = self.radial_lin(radial_emb)
soft_cutoff = 0.5 * (torch.cos(dist * pi / self.cutoff) + 1.0)
radial_hidden = soft_cutoff.unsqueeze(-1) * radial_hidden
# init invariant node features
# shape: (num_nodes, hidden_channels)
s = self.neighbor_emb(z, z_emb, edge_index, radial_hidden)
# init equivariant node features
# shape: (num_nodes, 3, hidden_channels)
vec = torch.zeros(s.size(0), 3, s.size(1), device=s.device)
# bulid edge-wise frame
edge_diff = pos[i] - pos[j]
edge_diff = _normalize(edge_diff)
edge_cross = torch.cross(pos[i], pos[j])
edge_cross = _normalize(edge_cross)
edge_vertical = torch.cross(edge_diff, edge_cross)
# edge_frame shape: (num_edges, 3, 3)
edge_frame = torch.cat((edge_diff.unsqueeze(-1), edge_cross.unsqueeze(-1), edge_vertical.unsqueeze(-1)), dim=-1)
# build node-wise frame
mean_neighbor_pos = self.mean_neighbor_pos(pos, edge_index)
node_diff = pos - mean_neighbor_pos
node_diff = _normalize(node_diff)
node_cross = torch.cross(pos, mean_neighbor_pos)
node_cross = _normalize(node_cross)
node_vertical = torch.cross(node_diff, node_cross)
# node_frame shape: (num_nodes, 3, 3)
node_frame = torch.cat((node_diff.unsqueeze(-1), node_cross.unsqueeze(-1), node_vertical.unsqueeze(-1)), dim=-1)
# LSE: local 3D substructure encoding
# S_i_j shape: (num_nodes, 3, hidden_channels)
S_i_j = self.S_vector(s, edge_diff.unsqueeze(-1), edge_index, radial_hidden)
scalrization1 = torch.sum(S_i_j[i].unsqueeze(2) * edge_frame.unsqueeze(-1), dim=1)
scalrization2 = torch.sum(S_i_j[j].unsqueeze(2) * edge_frame.unsqueeze(-1), dim=1)
scalrization1[:, 1, :] = torch.abs(scalrization1[:, 1, :].clone())
scalrization2[:, 1, :] = torch.abs(scalrization2[:, 1, :].clone())
scalar3 = (self.lin(torch.permute(scalrization1, (0, 2, 1))) + torch.permute(scalrization1, (0, 2, 1))[:, :,
0].unsqueeze(2)).squeeze(-1)
scalar4 = (self.lin(torch.permute(scalrization2, (0, 2, 1))) + torch.permute(scalrization2, (0, 2, 1))[:, :,
0].unsqueeze(2)).squeeze(-1)
A_i_j = torch.cat((scalar3, scalar4), dim=-1) * soft_cutoff.unsqueeze(-1)
A_i_j = torch.cat((A_i_j, radial_hidden, radial_emb), dim=-1)
for i in range(self.num_layers):
# equivariant message passing
ds, dvec = self.message_layers[i](
s, vec, edge_index, radial_emb, A_i_j, edge_diff
)
s = s + ds
vec = vec + dvec
# FTE: frame transition encoding
ds, dvec = self.FTEs[i](s, vec, node_frame)
s = s + ds
vec = vec + dvec
if self.pos_require_grad:
forces = self.out_forces(s, vec)
s = self.last_layer(s)
s = scatter(s, batch, dim=0)
s = s * self.y_std + self.y_mean
if self.pos_require_grad:
return s, forces
return s
@property
def num_params(self):
return sum(p.numel() for p in self.parameters())