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| import torch | |
| import torch.nn as nn | |
| import torch.nn.functional as F | |
| from torch.nn.utils.weight_norm import weight_norm | |
| import math | |
| import numpy as np | |
| class cross_attn_block(nn.Module): | |
| def __init__(self, embed_dim, n_heads, dropout): | |
| super().__init__() | |
| self.heads = n_heads | |
| self.mha = nn.MultiheadAttention(embed_dim, n_heads, dropout, batch_first=True) | |
| self.ln_apt = nn.LayerNorm(embed_dim) | |
| self.ln_prot = nn.LayerNorm(embed_dim) | |
| self.ln_out = nn.LayerNorm(embed_dim) | |
| self.linear = nn.Linear(embed_dim, embed_dim) | |
| def forward(self, embeddings_x, embeddings_y, x_t, y_t): | |
| # compute attention masks | |
| attn_mask = generate_3d_mask(y_t, x_t, self.heads) | |
| # apply layer norms | |
| embeddings_x_n = self.ln_apt(embeddings_x) | |
| embeddings_y_n = self.ln_prot(embeddings_y) | |
| # perform cross-attention | |
| reps = embeddings_y + self.mha(embeddings_y_n, embeddings_x_n, embeddings_x_n, attn_mask=attn_mask)[0] | |
| return reps + self.linear(self.ln_out(reps)) | |
| class self_attn_block(nn.Module): | |
| def __init__(self, d_embed, heads, dropout): | |
| super().__init__() | |
| # self.l1 = nn.Linear(d_linear, d_linear) | |
| self.heads = heads | |
| self.ln1 = nn.LayerNorm(d_embed) | |
| self.ln2 = nn.LayerNorm(d_embed) | |
| self.mha = nn.MultiheadAttention(d_embed, self.heads, dropout, batch_first=True) | |
| self.linear = nn.Linear(d_embed, d_embed) | |
| def forward(self, embeddings_x, x_t): | |
| # compute attention masks | |
| # attn_mask = generate_3d_mask(x_t, x_t, self.heads) | |
| # apply layer norm | |
| embeddings_x_n = self.ln1(embeddings_x) | |
| reps = embeddings_x + self.mha(embeddings_x_n, embeddings_x_n, embeddings_x_n, key_padding_mask=~x_t)[0] | |
| return reps + self.linear(self.ln2(reps)) | |
| class AptaBLE(nn.Module): | |
| def __init__(self, apta_encoder, prot_encoder, dropout): | |
| super(AptaBLE, self).__init__() | |
| #hyperparameters | |
| self.apta_encoder = apta_encoder | |
| self.prot_encoder = prot_encoder | |
| self.flatten = nn.Flatten() | |
| self.prot_reshape = nn.Linear(1280, 512) | |
| self.apta_keep = nn.Linear(512, 512) | |
| self.l1 = nn.Linear(1024, 1024) | |
| self.l2 = nn.Linear(1024, 512) | |
| self.l3 = nn.Linear(512, 256) | |
| self.l4 = nn.Linear(256, 1) | |
| self.can = CAN(512, 8, 1, 'mean_all_tok') | |
| self.bn1 = nn.BatchNorm1d(1024) | |
| self.bn2 = nn.BatchNorm1d(512) | |
| self.bn3 = nn.BatchNorm1d(256) | |
| self.relu = nn.ReLU() | |
| def forward(self, apta_in, esm_prot, apta_attn, prot_attn): | |
| apta = self.apta_encoder(apta_in, apta_attn, apta_attn, output_hidden_states=True)['hidden_states'][-1] # output: (BS X #apt_toks x apt_embed_dim), encoder outputs (BS x MLM & sec. structure feature embeddings) | |
| prot = self.prot_encoder(esm_prot, repr_layers=[33], return_contacts=False)['representations'][33] | |
| prot = self.prot_reshape(prot) | |
| apta = self.apta_keep(apta) | |
| output, cross_map, prot_map, apta_map = self.can(prot, apta, prot_attn, apta_attn) | |
| output = self.relu(self.l1(output)) | |
| output = self.bn1(output) | |
| output = self.relu(self.l2(output)) | |
| output = self.bn2(output) | |
| output = self.relu(self.l3(output)) | |
| output = self.bn3(output) | |
| output = self.l4(output) | |
| output = torch.sigmoid(output) | |
| return output, cross_map, prot_map, apta_map | |
| def find_opt_threshold(target, pred): | |
| result = 0 | |
| best = 0 | |
| for i in range(0, 1000): | |
| pred_threshold = np.where(pred > i/1000, 1, 0) | |
| now = f1_score(target, pred_threshold) | |
| if now > best: | |
| result = i/1000 | |
| best = now | |
| return result | |
| def argument_seqset(seqset): | |
| arg_seqset = [] | |
| for s, ss in seqset: | |
| arg_seqset.append([s, ss]) | |
| arg_seqset.append([s[::-1], ss[::-1]]) | |
| return arg_seqset | |
| def augment_apis(apta, prot, ys): | |
| aug_apta = [] | |
| aug_prot = [] | |
| aug_y = [] | |
| for a, p, y in zip(apta, prot, ys): | |
| aug_apta.append(a) | |
| aug_prot.append(p) | |
| aug_y.append(y) | |
| aug_apta.append(a[::-1]) | |
| aug_prot.append(p) | |
| aug_y.append(y) | |
| aug_apta.append(a) | |
| aug_prot.append(p[::-1]) | |
| aug_y.append(y) | |
| aug_apta.append(a[::-1]) | |
| aug_prot.append(p[::-1]) | |
| aug_y.append(y) | |
| return np.array(aug_apta), np.array(aug_prot), np.array(aug_y) | |
| def generate_3d_mask(batch1, batch2, heads): | |
| # Ensure the batches are tensors | |
| batch1 = torch.tensor(batch1, dtype=torch.bool) | |
| batch2 = torch.tensor(batch2, dtype=torch.bool) | |
| # Validate that the batches have the same length | |
| if batch1.size(0) != batch2.size(0): | |
| raise ValueError("The batches must have the same number of vectors") | |
| # Generate the 3D mask for each pair of vectors | |
| out_mask = [] | |
| masks = torch.stack([torch.ger(vec1, vec2) for vec1, vec2 in zip(batch1, batch2)]) | |
| for j in range(masks.shape[0]): | |
| out_mask.append(torch.stack([masks[j] for i in range(heads)])) | |
| # out_mask = torch.tensor(out_mask, dtype=bool) | |
| out_mask = torch.cat(out_mask) | |
| # Replace False with -inf and True with 0 | |
| out_mask = out_mask.float() # Convert to float to allow -inf | |
| out_mask[out_mask == 0] = -1e9 | |
| out_mask[out_mask == 1] = 0 | |
| return out_mask | |
| class CAN(nn.Module): | |
| def __init__(self, hidden_dim, num_heads, group_size, aggregation): | |
| super(CAN, self).__init__() | |
| self.aggregation = aggregation | |
| self.group_size = group_size | |
| self.hidden_dim = hidden_dim | |
| self.num_heads = num_heads | |
| self.head_dim = hidden_dim // num_heads | |
| # Protein weights | |
| self.prot_query = nn.Linear(hidden_dim, hidden_dim, bias=False) | |
| self.prot_key = nn.Linear(hidden_dim, hidden_dim, bias=False) | |
| self.prot_val = nn.Linear(hidden_dim, hidden_dim, bias=False) | |
| # Aptamer weights | |
| self.apta_query = nn.Linear(hidden_dim, hidden_dim, bias=False) | |
| self.apta_key = nn.Linear(hidden_dim, hidden_dim, bias=False) | |
| self.apta_val = nn.Linear(hidden_dim, hidden_dim, bias=False) | |
| # linear | |
| self.lp = nn.Linear(hidden_dim, hidden_dim) | |
| def mask_logits(self, logits, mask_row, mask_col, inf=1e6): | |
| N, L1, L2, H = logits.shape | |
| mask_row = mask_row.view(N, L1, 1).repeat(1, 1, H) | |
| mask_col = mask_col.view(N, L2, 1).repeat(1, 1, H) | |
| # Ignore all padding tokens across both embeddings | |
| mask_pair = torch.einsum('blh, bkh->blkh', mask_row, mask_col) | |
| # Set logit to -1e6 if masked | |
| logits = torch.where(mask_pair, logits, logits - inf) | |
| alpha = torch.softmax(logits, dim=2) | |
| mask_row = mask_row.view(N, L1, 1, H).repeat(1, 1, L2, 1) | |
| alpha = torch.where(mask_row, alpha, torch.zeros_like(alpha)) | |
| return alpha | |
| def rearrange_heads(self, x, n_heads, n_ch): | |
| # rearrange embedding for MHA | |
| s = list(x.size())[:-1] + [n_heads, n_ch] | |
| return x.view(*s) | |
| def grouped_embeddings(self, x, mask, group_size): | |
| N, L, D = x.shape | |
| groups = L // group_size | |
| # Average embeddings within each group | |
| x_grouped = x.view(N, groups, group_size, D).mean(dim=2) | |
| # Ignore groups without any non-padding tokens | |
| mask_grouped = mask.view(N, groups, group_size).any(dim=2) | |
| return x_grouped, mask_grouped | |
| def forward(self, protein, aptamer, mask_prot, mask_apta): | |
| # Group embeddings before applying multi-head attention | |
| protein_grouped, mask_prot_grouped = self.grouped_embeddings(protein, mask_prot, self.group_size) | |
| apta_grouped, mask_apta_grouped = self.grouped_embeddings(aptamer, mask_apta, self.group_size) | |
| # Compute queries, keys, values for both protein and aptamer after grouping | |
| query_prot = self.rearrange_heads(self.prot_query(protein_grouped), self.num_heads, self.head_dim) | |
| key_prot = self.rearrange_heads(self.prot_key(protein_grouped), self.num_heads, self.head_dim) | |
| value_prot = self.rearrange_heads(self.prot_val(protein_grouped), self.num_heads, self.head_dim) | |
| query_apta = self.rearrange_heads(self.apta_query(apta_grouped), self.num_heads, self.head_dim) | |
| key_apta = self.rearrange_heads(self.apta_key(apta_grouped), self.num_heads, self.head_dim) | |
| value_apta = self.rearrange_heads(self.apta_val(apta_grouped), self.num_heads, self.head_dim) | |
| # Compute attention scores | |
| logits_pp = torch.einsum('blhd, bkhd->blkh', query_prot, key_prot) | |
| logits_pa = torch.einsum('blhd, bkhd->blkh', query_prot, key_apta) | |
| logits_ap = torch.einsum('blhd, bkhd->blkh', query_apta, key_prot) | |
| logits_aa = torch.einsum('blhd, bkhd->blkh', query_apta, key_apta) | |
| ml_pp = self.mask_logits(logits_pp, mask_prot_grouped, mask_prot_grouped) | |
| ml_pa = self.mask_logits(logits_pa, mask_prot_grouped, mask_apta_grouped) | |
| ml_ap = self.mask_logits(logits_ap, mask_apta_grouped, mask_prot_grouped) | |
| ml_aa = self.mask_logits(logits_aa, mask_apta_grouped, mask_apta_grouped) | |
| # Combine heads, combine self-attended and cross-attended representations (via avg) | |
| prot_embedding = (torch.einsum('blkh, bkhd->blhd', ml_pp, value_prot).flatten(-2) + | |
| torch.einsum('blkh, bkhd->blhd', ml_pa, value_apta).flatten(-2)) / 2 | |
| apta_embedding = (torch.einsum('blkh, bkhd->blhd', ml_ap, value_prot).flatten(-2) + | |
| torch.einsum('blkh, bkhd->blhd', ml_aa, value_apta).flatten(-2)) / 2 | |
| prot_embedding += protein | |
| apta_embedding += aptamer | |
| # Aggregate token representations | |
| if self.aggregation == "cls": | |
| prot_embed = prot_embedding[:, 0] # query : [batch_size, hidden] | |
| apta_embed = apta_embedding[:, 0] # query : [batch_size, hidden] | |
| elif self.aggregation == "mean_all_tok": | |
| prot_embed = prot_embedding.mean(1) # query : [batch_size, hidden] | |
| apta_embed = apta_embedding.mean(1) # query : [batch_size, hidden] | |
| elif self.aggregation == "mean": | |
| prot_embed = (prot_embedding * mask_prot_grouped.unsqueeze(-1)).sum(1) / mask_prot_grouped.sum(-1).unsqueeze(-1) | |
| apta_embed = (apta_embedding * mask_apta_grouped.unsqueeze(-1)).sum(1) / mask_apta_grouped.sum(-1).unsqueeze(-1) | |
| else: | |
| raise NotImplementedError() | |
| embed = torch.cat([prot_embed, apta_embed], dim=1) | |
| return embed, ml_pa, ml_pp, ml_aa | |