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| """This code is taken from <https://github.com/alexandre01/deepsvg> | |
| by Alexandre Carlier, Martin Danelljan, Alexandre Alahi and Radu Timofte | |
| from the paper >https://arxiv.org/pdf/2007.11301.pdf> | |
| """ | |
| from src.preprocessing.deepsvg.deepsvg_difflib.tensor import SVGTensor | |
| from src.preprocessing.deepsvg.deepsvg_utils.utils import _pack_group_batch, _unpack_group_batch, _make_seq_first, _make_batch_first | |
| from .layers.transformer import * | |
| from .layers.improved_transformer import * | |
| from .layers.positional_encoding import * | |
| from .basic_blocks import FCN, HierarchFCN, ResNet | |
| from .model_config import _DefaultConfig | |
| from .model_utils import (_get_padding_mask, _get_key_padding_mask, _get_group_mask, _get_visibility_mask, | |
| _get_key_visibility_mask, _generate_square_subsequent_mask, _sample_categorical, _threshold_sample) | |
| from torch.nn.utils.rnn import pad_packed_sequence, pack_padded_sequence | |
| from scipy.optimize import linear_sum_assignment | |
| class SVGEmbedding(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig, seq_len, rel_args=False, use_group=True, group_len=None): | |
| super().__init__() | |
| self.cfg = cfg | |
| self.command_embed = nn.Embedding(cfg.n_commands, cfg.d_model) | |
| args_dim = 2 * cfg.args_dim if rel_args else cfg.args_dim + 1 | |
| self.arg_embed = nn.Embedding(args_dim, 64) | |
| self.embed_fcn = nn.Linear(64 * cfg.n_args, cfg.d_model) | |
| self.use_group = use_group | |
| if use_group: | |
| if group_len is None: | |
| group_len = cfg.max_num_groups | |
| self.group_embed = nn.Embedding(group_len+2, cfg.d_model) | |
| self.pos_encoding = PositionalEncodingLUT(cfg.d_model, max_len=seq_len+2) | |
| self._init_embeddings() | |
| def _init_embeddings(self): | |
| nn.init.kaiming_normal_(self.command_embed.weight, mode="fan_in") | |
| nn.init.kaiming_normal_(self.arg_embed.weight, mode="fan_in") | |
| nn.init.kaiming_normal_(self.embed_fcn.weight, mode="fan_in") | |
| if self.use_group: | |
| nn.init.kaiming_normal_(self.group_embed.weight, mode="fan_in") | |
| def forward(self, commands, args, groups=None): | |
| S, GN = commands.shape | |
| src = self.command_embed(commands.long()) + \ | |
| self.embed_fcn(self.arg_embed((args + 1).long()).view(S, GN, -1)) # shift due to -1 PAD_VAL | |
| if self.use_group: | |
| src = src + self.group_embed(groups.long()) | |
| src = self.pos_encoding(src) | |
| return src | |
| class ConstEmbedding(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig, seq_len): | |
| super().__init__() | |
| self.cfg = cfg | |
| self.seq_len = seq_len | |
| self.PE = PositionalEncodingLUT(cfg.d_model, max_len=seq_len) | |
| def forward(self, z): | |
| N = z.size(1) | |
| src = self.PE(z.new_zeros(self.seq_len, N, self.cfg.d_model)) | |
| return src | |
| class LabelEmbedding(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig): | |
| super().__init__() | |
| self.label_embedding = nn.Embedding(cfg.n_labels, cfg.dim_label) | |
| self._init_embeddings() | |
| def _init_embeddings(self): | |
| nn.init.kaiming_normal_(self.label_embedding.weight, mode="fan_in") | |
| def forward(self, label): | |
| src = self.label_embedding(label) | |
| return src | |
| class Encoder(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig): | |
| super().__init__() | |
| self.cfg = cfg | |
| seq_len = cfg.max_seq_len if cfg.encode_stages == 2 else cfg.max_total_len | |
| self.use_group = cfg.encode_stages == 1 | |
| self.embedding = SVGEmbedding(cfg, seq_len, use_group=self.use_group) | |
| if cfg.label_condition: | |
| self.label_embedding = LabelEmbedding(cfg) | |
| dim_label = cfg.dim_label if cfg.label_condition else None | |
| if cfg.model_type == "transformer": | |
| encoder_layer = TransformerEncoderLayerImproved(cfg.d_model, cfg.n_heads, cfg.dim_feedforward, cfg.dropout, d_global2=dim_label) | |
| encoder_norm = LayerNorm(cfg.d_model) | |
| self.encoder = TransformerEncoder(encoder_layer, cfg.n_layers, encoder_norm) | |
| else: # "lstm" | |
| self.encoder = nn.LSTM(cfg.d_model, cfg.d_model // 2, dropout=cfg.dropout, bidirectional=True) | |
| if cfg.encode_stages == 2: | |
| if not cfg.self_match: | |
| self.hierarchical_PE = PositionalEncodingLUT(cfg.d_model, max_len=cfg.max_num_groups) | |
| hierarchical_encoder_layer = TransformerEncoderLayerImproved(cfg.d_model, cfg.n_heads, cfg.dim_feedforward, cfg.dropout, d_global2=dim_label) | |
| hierarchical_encoder_norm = LayerNorm(cfg.d_model) | |
| self.hierarchical_encoder = TransformerEncoder(hierarchical_encoder_layer, cfg.n_layers, hierarchical_encoder_norm) | |
| def forward(self, commands, args, label=None): | |
| S, G, N = commands.shape | |
| l = self.label_embedding(label).unsqueeze(0).unsqueeze(0).repeat(1, commands.size(1), 1, 1) if self.cfg.label_condition else None | |
| if self.cfg.encode_stages == 2: | |
| visibility_mask, key_visibility_mask = _get_visibility_mask(commands, seq_dim=0), _get_key_visibility_mask(commands, seq_dim=0) | |
| commands, args, l = _pack_group_batch(commands, args, l) | |
| padding_mask, key_padding_mask = _get_padding_mask(commands, seq_dim=0), _get_key_padding_mask(commands, seq_dim=0) | |
| group_mask = _get_group_mask(commands, seq_dim=0) if self.use_group else None | |
| src = self.embedding(commands, args, group_mask) | |
| if self.cfg.model_type == "transformer": | |
| memory = self.encoder(src, mask=None, src_key_padding_mask=key_padding_mask, memory2=l) | |
| z = (memory * padding_mask).sum(dim=0, keepdim=True) / padding_mask.sum(dim=0, keepdim=True) | |
| else: # "lstm" | |
| hidden_cell = (src.new_zeros(2, N, self.cfg.d_model // 2), | |
| src.new_zeros(2, N, self.cfg.d_model // 2)) | |
| sequence_lengths = padding_mask.sum(dim=0).squeeze(-1) | |
| x = pack_padded_sequence(src, sequence_lengths, enforce_sorted=False) | |
| packed_output, _ = self.encoder(x, hidden_cell) | |
| memory, _ = pad_packed_sequence(packed_output) | |
| idx = (sequence_lengths - 1).long().view(1, -1, 1).repeat(1, 1, self.cfg.d_model) | |
| z = memory.gather(dim=0, index=idx) | |
| z = _unpack_group_batch(N, z) | |
| if self.cfg.encode_stages == 2: | |
| src = z.transpose(0, 1) | |
| src = _pack_group_batch(src) | |
| l = self.label_embedding(label).unsqueeze(0) if self.cfg.label_condition else None | |
| if not self.cfg.self_match: | |
| src = self.hierarchical_PE(src) | |
| memory = self.hierarchical_encoder(src, mask=None, src_key_padding_mask=key_visibility_mask, memory2=l) | |
| z = (memory * visibility_mask).sum(dim=0, keepdim=True) / visibility_mask.sum(dim=0, keepdim=True) | |
| z = _unpack_group_batch(N, z) | |
| return z | |
| class VAE(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig): | |
| super(VAE, self).__init__() | |
| self.enc_mu_fcn = nn.Linear(cfg.d_model, cfg.dim_z) | |
| self.enc_sigma_fcn = nn.Linear(cfg.d_model, cfg.dim_z) | |
| self._init_embeddings() | |
| def _init_embeddings(self): | |
| nn.init.normal_(self.enc_mu_fcn.weight, std=0.001) | |
| nn.init.constant_(self.enc_mu_fcn.bias, 0) | |
| nn.init.normal_(self.enc_sigma_fcn.weight, std=0.001) | |
| nn.init.constant_(self.enc_sigma_fcn.bias, 0) | |
| def forward(self, z): | |
| mu, logsigma = self.enc_mu_fcn(z), self.enc_sigma_fcn(z) | |
| sigma = torch.exp(logsigma / 2.) | |
| z = mu + sigma * torch.randn_like(sigma) | |
| return z, mu, logsigma | |
| class Bottleneck(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig): | |
| super(Bottleneck, self).__init__() | |
| self.bottleneck = nn.Linear(cfg.d_model, cfg.dim_z) | |
| def forward(self, z): | |
| return self.bottleneck(z) | |
| class Decoder(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig): | |
| super(Decoder, self).__init__() | |
| self.cfg = cfg | |
| if cfg.label_condition: | |
| self.label_embedding = LabelEmbedding(cfg) | |
| dim_label = cfg.dim_label if cfg.label_condition else None | |
| if cfg.decode_stages == 2: | |
| self.hierarchical_embedding = ConstEmbedding(cfg, cfg.num_groups_proposal) | |
| hierarchical_decoder_layer = TransformerDecoderLayerGlobalImproved(cfg.d_model, cfg.dim_z, cfg.n_heads, cfg.dim_feedforward, cfg.dropout, d_global2=dim_label) | |
| hierarchical_decoder_norm = LayerNorm(cfg.d_model) | |
| self.hierarchical_decoder = TransformerDecoder(hierarchical_decoder_layer, cfg.n_layers_decode, hierarchical_decoder_norm) | |
| self.hierarchical_fcn = HierarchFCN(cfg.d_model, cfg.dim_z) | |
| if cfg.pred_mode == "autoregressive": | |
| self.embedding = SVGEmbedding(cfg, cfg.max_total_len, rel_args=cfg.rel_targets, use_group=True, group_len=cfg.max_total_len) | |
| square_subsequent_mask = _generate_square_subsequent_mask(self.cfg.max_total_len+1) | |
| self.register_buffer("square_subsequent_mask", square_subsequent_mask) | |
| else: # "one_shot" | |
| seq_len = cfg.max_seq_len+1 if cfg.decode_stages == 2 else cfg.max_total_len+1 | |
| self.embedding = ConstEmbedding(cfg, seq_len) | |
| if cfg.model_type == "transformer": | |
| decoder_layer = TransformerDecoderLayerGlobalImproved(cfg.d_model, cfg.dim_z, cfg.n_heads, cfg.dim_feedforward, cfg.dropout, d_global2=dim_label) | |
| decoder_norm = LayerNorm(cfg.d_model) | |
| self.decoder = TransformerDecoder(decoder_layer, cfg.n_layers_decode, decoder_norm) | |
| else: # "lstm" | |
| self.fc_hc = nn.Linear(cfg.dim_z, 2 * cfg.d_model) | |
| self.decoder = nn.LSTM(cfg.d_model, cfg.d_model, dropout=cfg.dropout) | |
| args_dim = 2 * cfg.args_dim if cfg.rel_targets else cfg.args_dim + 1 | |
| self.fcn = FCN(cfg.d_model, cfg.n_commands, cfg.n_args, args_dim) | |
| def _get_initial_state(self, z): | |
| hidden, cell = torch.split(torch.tanh(self.fc_hc(z)), self.cfg.d_model, dim=2) | |
| hidden_cell = hidden.contiguous(), cell.contiguous() | |
| return hidden_cell | |
| def forward(self, z, commands, args, label=None, hierarch_logits=None, return_hierarch=False): | |
| N = z.size(2) | |
| l = self.label_embedding(label).unsqueeze(0) if self.cfg.label_condition else None | |
| if hierarch_logits is None: | |
| z = _pack_group_batch(z) | |
| if self.cfg.decode_stages == 2: | |
| if hierarch_logits is None: | |
| src = self.hierarchical_embedding(z) | |
| out = self.hierarchical_decoder(src, z, tgt_mask=None, tgt_key_padding_mask=None, memory2=l) | |
| hierarch_logits, z = self.hierarchical_fcn(out) | |
| if self.cfg.label_condition: l = l.unsqueeze(0).repeat(1, z.size(1), 1, 1) | |
| hierarch_logits, z, l = _pack_group_batch(hierarch_logits, z, l) | |
| if return_hierarch: | |
| return _unpack_group_batch(N, hierarch_logits, z) | |
| if self.cfg.pred_mode == "autoregressive": | |
| S = commands.size(0) | |
| commands, args = _pack_group_batch(commands, args) | |
| group_mask = _get_group_mask(commands, seq_dim=0) | |
| src = self.embedding(commands, args, group_mask) | |
| if self.cfg.model_type == "transformer": | |
| key_padding_mask = _get_key_padding_mask(commands, seq_dim=0) | |
| out = self.decoder(src, z, tgt_mask=self.square_subsequent_mask[:S, :S], tgt_key_padding_mask=key_padding_mask, memory2=l) | |
| else: # "lstm" | |
| hidden_cell = self._get_initial_state(z) | |
| out, _ = self.decoder(src, hidden_cell) | |
| else: # "one_shot" | |
| src = self.embedding(z) | |
| out = self.decoder(src, z, tgt_mask=None, tgt_key_padding_mask=None, memory2=l) | |
| command_logits, args_logits = self.fcn(out) | |
| out_logits = (command_logits, args_logits) + ((hierarch_logits,) if self.cfg.decode_stages == 2 else ()) | |
| return _unpack_group_batch(N, *out_logits) | |
| class SVGTransformer(nn.Module): | |
| def __init__(self, cfg: _DefaultConfig): | |
| super(SVGTransformer, self).__init__() | |
| self.cfg = cfg | |
| self.args_dim = 2 * cfg.args_dim if cfg.rel_targets else cfg.args_dim + 1 | |
| if self.cfg.encode_stages > 0: | |
| self.encoder = Encoder(cfg) | |
| if cfg.use_resnet: | |
| self.resnet = ResNet(cfg.d_model) | |
| if cfg.use_vae: | |
| self.vae = VAE(cfg) | |
| else: | |
| self.bottleneck = Bottleneck(cfg) | |
| self.decoder = Decoder(cfg) | |
| self.register_buffer("cmd_args_mask", SVGTensor.CMD_ARGS_MASK) | |
| def perfect_matching(self, command_logits, args_logits, hierarch_logits, tgt_commands, tgt_args): | |
| with torch.no_grad(): | |
| N, G, S, n_args = tgt_args.shape | |
| visibility_mask = _get_visibility_mask(tgt_commands, seq_dim=-1) | |
| padding_mask = _get_padding_mask(tgt_commands, seq_dim=-1, extended=True) * visibility_mask.unsqueeze(-1) | |
| # Unsqueeze | |
| tgt_commands, tgt_args, tgt_hierarch = tgt_commands.unsqueeze(2), tgt_args.unsqueeze(2), visibility_mask.unsqueeze(2) | |
| command_logits, args_logits, hierarch_logits = command_logits.unsqueeze(1), args_logits.unsqueeze(1), hierarch_logits.unsqueeze(1).squeeze(-2) | |
| # Loss | |
| tgt_hierarch, hierarch_logits = tgt_hierarch.repeat(1, 1, self.cfg.num_groups_proposal), hierarch_logits.repeat(1, G, 1, 1) | |
| tgt_commands, command_logits = tgt_commands.repeat(1, 1, self.cfg.num_groups_proposal, 1), command_logits.repeat(1, G, 1, 1, 1) | |
| tgt_args, args_logits = tgt_args.repeat(1, 1, self.cfg.num_groups_proposal, 1, 1), args_logits.repeat(1, G, 1, 1, 1, 1) | |
| padding_mask, mask = padding_mask.unsqueeze(2).repeat(1, 1, self.cfg.num_groups_proposal, 1), self.cmd_args_mask[tgt_commands.long()] | |
| loss_args = F.cross_entropy(args_logits.reshape(-1, self.args_dim), tgt_args.reshape(-1).long() + 1, reduction="none").reshape(N, G, self.cfg.num_groups_proposal, S, n_args) # shift due to -1 PAD_VAL | |
| loss_cmd = F.cross_entropy(command_logits.reshape(-1, self.cfg.n_commands), tgt_commands.reshape(-1).long(), reduction="none").reshape(N, G, self.cfg.num_groups_proposal, S) | |
| loss_hierarch = F.cross_entropy(hierarch_logits.reshape(-1, 2), tgt_hierarch.reshape(-1).long(), reduction="none").reshape(N, G, self.cfg.num_groups_proposal) | |
| loss_args = (loss_args * mask).sum(dim=[-1, -2]) / mask.sum(dim=[-1, -2]) | |
| loss_cmd = (loss_cmd * padding_mask).sum(dim=-1) / padding_mask.sum(dim=-1) | |
| loss = 2.0 * loss_args + 1.0 * loss_cmd + 1.0 * loss_hierarch | |
| # Iterate over the batch-dimension | |
| assignment_list = [] | |
| full_set = set(range(self.cfg.num_groups_proposal)) | |
| for i in range(N): | |
| costs = loss[i] | |
| mask = visibility_mask[i] | |
| _, assign = linear_sum_assignment(costs[mask].cpu()) | |
| assign = assign.tolist() | |
| assignment_list.append(assign + list(full_set - set(assign))) | |
| assignment = torch.tensor(assignment_list, device=command_logits.device) | |
| return assignment.unsqueeze(-1).unsqueeze(-1) | |
| def forward(self, commands_enc, args_enc, commands_dec, args_dec, label=None, | |
| z=None, hierarch_logits=None, | |
| return_tgt=True, params=None, encode_mode=False, return_hierarch=False): | |
| commands_enc, args_enc = _make_seq_first(commands_enc, args_enc) # Possibly None, None | |
| commands_dec_, args_dec_ = _make_seq_first(commands_dec, args_dec) | |
| if z is None: | |
| z = self.encoder(commands_enc, args_enc, label) | |
| if self.cfg.use_resnet: | |
| z = self.resnet(z) | |
| if self.cfg.use_vae: | |
| z, mu, logsigma = self.vae(z) | |
| else: | |
| z = self.bottleneck(z) | |
| else: | |
| z = _make_seq_first(z) | |
| if encode_mode: return z | |
| if return_tgt: # Train mode | |
| commands_dec_, args_dec_ = commands_dec_[:-1], args_dec_[:-1] | |
| out_logits = self.decoder(z, commands_dec_, args_dec_, label, hierarch_logits=hierarch_logits, | |
| return_hierarch=return_hierarch) | |
| if return_hierarch: | |
| return out_logits | |
| out_logits = _make_batch_first(*out_logits) | |
| if return_tgt and self.cfg.self_match: # Assignment | |
| assert self.cfg.decode_stages == 2 # Self-matching expects two-stage decoder | |
| command_logits, args_logits, hierarch_logits = out_logits | |
| assignment = self.perfect_matching(command_logits, args_logits, hierarch_logits, commands_dec[..., 1:], args_dec[..., 1:, :]) | |
| command_logits = torch.gather(command_logits, dim=1, index=assignment.expand_as(command_logits)) | |
| args_logits = torch.gather(args_logits, dim=1, index=assignment.unsqueeze(-1).expand_as(args_logits)) | |
| hierarch_logits = torch.gather(hierarch_logits, dim=1, index=assignment.expand_as(hierarch_logits)) | |
| out_logits = (command_logits, args_logits, hierarch_logits) | |
| res = { | |
| "command_logits": out_logits[0], | |
| "args_logits": out_logits[1] | |
| } | |
| if self.cfg.decode_stages == 2: | |
| res["visibility_logits"] = out_logits[2] | |
| if return_tgt: | |
| res["tgt_commands"] = commands_dec | |
| res["tgt_args"] = args_dec | |
| if self.cfg.use_vae: | |
| res["mu"] = _make_batch_first(mu) | |
| res["logsigma"] = _make_batch_first(logsigma) | |
| return res | |
| def greedy_sample(self, commands_enc=None, args_enc=None, commands_dec=None, args_dec=None, label=None, | |
| z=None, hierarch_logits=None, | |
| concat_groups=True, temperature=0.0001): | |
| if self.cfg.pred_mode == "one_shot": | |
| res = self.forward(commands_enc, args_enc, commands_dec, args_dec, label=label, z=z, hierarch_logits=hierarch_logits, return_tgt=False) | |
| commands_y, args_y = _sample_categorical(temperature, res["command_logits"], res["args_logits"]) | |
| args_y -= 1 # shift due to -1 PAD_VAL | |
| visibility_y = _threshold_sample(res["visibility_logits"], threshold=0.7).bool().squeeze(-1) if self.cfg.decode_stages == 2 else None | |
| commands_y, args_y = self._make_valid(commands_y, args_y, visibility_y) | |
| else: | |
| if z is None: | |
| z = self.forward(commands_enc, args_enc, None, None, label=label, encode_mode=True) | |
| PAD_VAL = -1 | |
| commands_y, args_y = z.new_zeros(1, 1, 1).fill_(SVGTensor.COMMANDS_SIMPLIFIED.index("SOS")).long(), z.new_ones(1, 1, 1, self.cfg.n_args).fill_(PAD_VAL).long() | |
| for i in range(self.cfg.max_total_len): | |
| res = self.forward(None, None, commands_y, args_y, label=label, z=z, hierarch_logits=hierarch_logits, return_tgt=False) | |
| commands_new_y, args_new_y = _sample_categorical(temperature, res["command_logits"], res["args_logits"]) | |
| args_new_y -= 1 # shift due to -1 PAD_VAL | |
| _, args_new_y = self._make_valid(commands_new_y, args_new_y) | |
| commands_y, args_y = torch.cat([commands_y, commands_new_y[..., -1:]], dim=-1), torch.cat([args_y, args_new_y[..., -1:, :]], dim=-2) | |
| commands_y, args_y = commands_y[..., 1:], args_y[..., 1:, :] # Discard SOS token | |
| if self.cfg.rel_targets: | |
| args_y = self._make_absolute(commands_y, args_y) | |
| if concat_groups: | |
| N = commands_y.size(0) | |
| padding_mask_y = _get_padding_mask(commands_y, seq_dim=-1).bool() | |
| commands_y, args_y = commands_y[padding_mask_y].reshape(N, -1), args_y[padding_mask_y].reshape(N, -1, self.cfg.n_args) | |
| return commands_y, args_y | |
| def _make_valid(self, commands_y, args_y, visibility_y=None, PAD_VAL=-1): | |
| if visibility_y is not None: | |
| S = commands_y.size(-1) | |
| commands_y[~visibility_y] = commands_y.new_tensor([SVGTensor.COMMANDS_SIMPLIFIED.index("m"), *[SVGTensor.COMMANDS_SIMPLIFIED.index("EOS")] * (S - 1)]) | |
| args_y[~visibility_y] = PAD_VAL | |
| mask = self.cmd_args_mask[commands_y.long()].bool() | |
| args_y[~mask] = PAD_VAL | |
| return commands_y, args_y | |
| def _make_absolute(self, commands_y, args_y): | |
| mask = self.cmd_args_mask[commands_y.long()].bool() | |
| args_y[mask] -= self.cfg.args_dim - 1 | |
| real_commands = commands_y < SVGTensor.COMMANDS_SIMPLIFIED.index("EOS") | |
| args_real_commands = args_y[real_commands] | |
| end_pos = args_real_commands[:-1, SVGTensor.IndexArgs.END_POS].cumsum(dim=0) | |
| args_real_commands[1:, SVGTensor.IndexArgs.CONTROL1] += end_pos | |
| args_real_commands[1:, SVGTensor.IndexArgs.CONTROL2] += end_pos | |
| args_real_commands[1:, SVGTensor.IndexArgs.END_POS] += end_pos | |
| args_y[real_commands] = args_real_commands | |
| _, args_y = self._make_valid(commands_y, args_y) | |
| return args_y | |