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import torch |
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import torch.nn as nn |
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import torch.nn.functional as F |
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from openrec.modeling.decoders.nrtr_decoder import PositionalEncoding, TransformerBlock |
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class BCNLanguage(nn.Module): |
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def __init__( |
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self, |
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d_model=512, |
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nhead=8, |
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num_layers=4, |
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dim_feedforward=2048, |
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dropout=0.0, |
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max_length=25, |
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detach=True, |
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num_classes=37, |
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): |
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super().__init__() |
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self.d_model = d_model |
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self.detach = detach |
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self.max_length = max_length + 1 |
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self.proj = nn.Linear(num_classes, d_model, False) |
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self.token_encoder = PositionalEncoding(dropout=0.1, |
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dim=d_model, |
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max_len=self.max_length) |
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self.pos_encoder = PositionalEncoding(dropout=0, |
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dim=d_model, |
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max_len=self.max_length) |
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self.decoder = nn.ModuleList([ |
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TransformerBlock( |
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d_model=d_model, |
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nhead=nhead, |
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dim_feedforward=dim_feedforward, |
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attention_dropout_rate=dropout, |
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residual_dropout_rate=dropout, |
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with_self_attn=False, |
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with_cross_attn=True, |
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) for i in range(num_layers) |
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]) |
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self.cls = nn.Linear(d_model, num_classes) |
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def forward(self, tokens, lengths): |
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""" |
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Args: |
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tokens: (N, T, C) where T is length, N is batch size and C is classes number |
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lengths: (N,) |
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""" |
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if self.detach: |
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tokens = tokens.detach() |
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embed = self.proj(tokens) |
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embed = self.token_encoder(embed) |
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mask = _get_mask(lengths, self.max_length) |
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zeros = embed.new_zeros(*embed.shape) |
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qeury = self.pos_encoder(zeros) |
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for decoder_layer in self.decoder: |
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qeury = decoder_layer(qeury, embed, cross_mask=mask) |
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output = qeury |
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logits = self.cls(output) |
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return output, logits |
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def encoder_layer(in_c, out_c, k=3, s=2, p=1): |
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return nn.Sequential(nn.Conv2d(in_c, out_c, k, s, p), |
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nn.BatchNorm2d(out_c), nn.ReLU(True)) |
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class DecoderUpsample(nn.Module): |
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def __init__(self, in_c, out_c, k=3, s=1, p=1, mode='nearest') -> None: |
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super().__init__() |
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self.align_corners = None if mode == 'nearest' else True |
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self.mode = mode |
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self.w = nn.Sequential( |
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nn.Conv2d(in_c, out_c, k, s, p), |
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nn.BatchNorm2d(out_c), |
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nn.ReLU(True), |
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) |
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def forward(self, x, size): |
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x = F.interpolate(x, |
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size=size, |
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mode=self.mode, |
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align_corners=self.align_corners) |
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return self.w(x) |
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class PositionAttention(nn.Module): |
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def __init__(self, |
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max_length, |
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in_channels=512, |
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num_channels=64, |
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mode='nearest', |
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**kwargs): |
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super().__init__() |
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self.max_length = max_length |
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self.k_encoder = nn.Sequential( |
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encoder_layer(in_channels, num_channels, s=(1, 2)), |
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encoder_layer(num_channels, num_channels, s=(2, 2)), |
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encoder_layer(num_channels, num_channels, s=(2, 2)), |
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encoder_layer(num_channels, num_channels, s=(2, 2)), |
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) |
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self.k_decoder = nn.ModuleList([ |
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DecoderUpsample(num_channels, num_channels, mode=mode), |
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DecoderUpsample(num_channels, num_channels, mode=mode), |
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DecoderUpsample(num_channels, num_channels, mode=mode), |
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DecoderUpsample(num_channels, in_channels, mode=mode), |
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]) |
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self.pos_encoder = PositionalEncoding(dropout=0, |
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dim=in_channels, |
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max_len=max_length) |
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self.project = nn.Linear(in_channels, in_channels) |
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def forward(self, x, query=None): |
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N, E, H, W = x.size() |
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k, v = x, x |
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features = [] |
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size_decoder = [] |
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for i in range(0, len(self.k_encoder)): |
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size_decoder.append(k.shape[2:]) |
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k = self.k_encoder[i](k) |
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features.append(k) |
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for i in range(0, len(self.k_decoder) - 1): |
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k = self.k_decoder[i](k, size=size_decoder[-(i + 1)]) |
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k = k + features[len(self.k_decoder) - 2 - i] |
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k = self.k_decoder[-1](k, size=size_decoder[0]) |
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zeros = x.new_zeros( |
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(N, self.max_length, E)) if query is None else query |
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q = self.pos_encoder(zeros) |
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q = self.project(q) |
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attn_scores = torch.bmm(q, k.flatten(2, 3)) |
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attn_scores = attn_scores / (E**0.5) |
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attn_scores = F.softmax(attn_scores, dim=-1) |
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v = v.permute(0, 2, 3, 1).view(N, -1, E) |
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attn_vecs = torch.bmm(attn_scores, v) |
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return attn_vecs, attn_scores.view(N, -1, H, W) |
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class ABINetDecoder(nn.Module): |
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def __init__(self, |
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in_channels, |
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out_channels, |
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nhead=8, |
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num_layers=3, |
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dim_feedforward=2048, |
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dropout=0.1, |
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max_length=25, |
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iter_size=3, |
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**kwargs): |
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super().__init__() |
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self.max_length = max_length + 1 |
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d_model = in_channels |
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self.pos_encoder = PositionalEncoding(dropout=0.1, dim=d_model) |
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self.encoder = nn.ModuleList([ |
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TransformerBlock( |
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d_model=d_model, |
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nhead=nhead, |
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dim_feedforward=dim_feedforward, |
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attention_dropout_rate=dropout, |
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residual_dropout_rate=dropout, |
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with_self_attn=True, |
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with_cross_attn=False, |
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) for _ in range(num_layers) |
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]) |
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self.decoder = PositionAttention( |
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max_length=self.max_length, |
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in_channels=d_model, |
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num_channels=d_model // 8, |
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mode='nearest', |
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) |
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self.out_channels = out_channels |
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self.cls = nn.Linear(d_model, self.out_channels) |
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self.iter_size = iter_size |
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if iter_size > 0: |
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self.language = BCNLanguage( |
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d_model=d_model, |
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nhead=nhead, |
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num_layers=4, |
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dim_feedforward=dim_feedforward, |
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dropout=dropout, |
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max_length=max_length, |
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num_classes=self.out_channels, |
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) |
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self.w_att_align = nn.Linear(2 * d_model, d_model) |
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self.cls_align = nn.Linear(d_model, self.out_channels) |
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def forward(self, x, data=None): |
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x = x.permute([0, 2, 3, 1]) |
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_, H, W, C = x.shape |
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feature = x.flatten(1, 2) |
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feature = self.pos_encoder(feature) |
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for encoder_layer in self.encoder: |
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feature = encoder_layer(feature) |
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feature = feature.reshape([-1, H, W, C]).permute(0, 3, 1, |
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2) |
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v_feature, _ = self.decoder(feature) |
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vis_logits = self.cls(v_feature) |
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align_lengths = _get_length(vis_logits) |
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align_logits = vis_logits |
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all_l_res, all_a_res = [], [] |
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for _ in range(self.iter_size): |
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tokens = F.softmax(align_logits, dim=-1) |
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lengths = torch.clamp( |
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align_lengths, 2, |
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self.max_length) |
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l_feature, l_logits = self.language(tokens, lengths) |
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all_l_res.append(l_logits) |
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fuse = torch.cat((l_feature, v_feature), -1) |
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f_att = torch.sigmoid(self.w_att_align(fuse)) |
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output = f_att * v_feature + (1 - f_att) * l_feature |
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align_logits = self.cls_align(output) |
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align_lengths = _get_length(align_logits) |
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all_a_res.append(align_logits) |
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if self.training: |
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return { |
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'align': all_a_res, |
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'lang': all_l_res, |
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'vision': vis_logits |
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} |
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else: |
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return F.softmax(align_logits, -1) |
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def _get_length(logit): |
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"""Greed decoder to obtain length from logit.""" |
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out = logit.argmax(dim=-1) == 0 |
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non_zero_mask = out.int() != 0 |
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mask_max_values, mask_max_indices = torch.max(non_zero_mask.int(), dim=-1) |
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mask_max_indices[mask_max_values == 0] = -1 |
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out = mask_max_indices + 1 |
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return out |
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def _get_mask(length, max_length): |
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"""Generate a square mask for the sequence. |
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The masked positions are filled with float('-inf'). Unmasked positions are |
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filled with float(0.0). |
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""" |
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length = length.unsqueeze(-1) |
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N = length.size(0) |
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grid = torch.arange(0, max_length, device=length.device).unsqueeze(0) |
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zero_mask = torch.zeros([N, max_length], |
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dtype=torch.float32, |
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device=length.device) |
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inf_mask = torch.full([N, max_length], |
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float('-inf'), |
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dtype=torch.float32, |
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device=length.device) |
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diag_mask = torch.diag( |
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torch.full([max_length], |
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float('-inf'), |
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dtype=torch.float32, |
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device=length.device), |
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diagonal=0, |
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) |
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mask = torch.where(grid >= length, inf_mask, zero_mask) |
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mask = mask.unsqueeze(1) + diag_mask |
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return mask.unsqueeze(1) |
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