# This file contains ShowAttendTell and AllImg model # ShowAttendTell is from Show, Attend and Tell: Neural Image Caption Generation with Visual Attention # https://arxiv.org/abs/1502.03044 # AllImg is a model where # img feature is concatenated with word embedding at every time step as the input of lstm from __future__ import absolute_import from __future__ import division from __future__ import print_function import torch import torch.nn as nn import torch.nn.functional as F from torch.autograd import * # import misc.utils as utils # import utils as utils from . import utils from .CaptionModel import CaptionModel class OldModel(CaptionModel): def __init__(self, opt): super(OldModel, self).__init__() self.vocab_size = opt.vocab_size self.input_encoding_size = opt.input_encoding_size self.rnn_type = opt.rnn_type self.rnn_size = opt.rnn_size self.num_layers = opt.num_layers self.drop_prob_lm = opt.drop_prob_lm self.seq_length = opt.seq_length self.fc_feat_size = opt.fc_feat_size self.att_feat_size = opt.att_feat_size self.ss_prob = 0.0 # Schedule sampling probability self.linear = nn.Linear(self.fc_feat_size, self.num_layers * self.rnn_size) # feature to rnn_size self.embed = nn.Embedding(self.vocab_size + 1, self.input_encoding_size) self.logit = nn.Linear(self.rnn_size, self.vocab_size + 1) self.dropout = nn.Dropout(self.drop_prob_lm) self.init_weights() def init_weights(self): initrange = 0.1 self.embed.weight.data.uniform_(-initrange, initrange) self.logit.bias.data.fill_(0) self.logit.weight.data.uniform_(-initrange, initrange) def init_hidden(self, fc_feats): image_map = self.linear(fc_feats).view(-1, self.num_layers, self.rnn_size).transpose(0, 1) if self.rnn_type == 'lstm': return (image_map, image_map) else: return image_map def forward(self, fc_feats, att_feats, seq): batch_size = fc_feats.size(0) state = self.init_hidden(fc_feats) outputs = [] for i in range(seq.size(1) - 1): if self.training and i >= 1 and self.ss_prob > 0.0: # otherwiste no need to sample sample_prob = fc_feats.data.new(batch_size).uniform_(0, 1) sample_mask = sample_prob < self.ss_prob if sample_mask.sum() == 0: it = seq[:, i].clone() else: sample_ind = sample_mask.nonzero().view(-1) it = seq[:, i].data.clone() # prob_prev = torch.exp(outputs[-1].data.index_select(0, sample_ind)) # fetch prev distribution: shape Nx(M+1) # it.index_copy_(0, sample_ind, torch.multinomial(prob_prev, 1).view(-1)) prob_prev = torch.exp(outputs[-1].data) # fetch prev distribution: shape Nx(M+1) it.index_copy_(0, sample_ind, torch.multinomial(prob_prev, 1).view(-1).index_select(0, sample_ind)) it = Variable(it, requires_grad=False) else: it = seq[:, i].clone() # break if all the sequences end if i >= 1 and seq[:, i].data.sum() == 0: break xt = self.embed(it) output, state = self.core(xt, fc_feats, att_feats, state) output = F.log_softmax(self.logit(self.dropout(output))) outputs.append(output) return torch.cat([_.unsqueeze(1) for _ in outputs], 1) def get_logprobs_state(self, it, tmp_fc_feats, tmp_att_feats, state): # 'it' is Variable contraining a word index xt = self.embed(it) output, state = self.core(xt, tmp_fc_feats, tmp_att_feats, state) logprobs = F.log_softmax(self.logit(self.dropout(output))) return logprobs, state def sample_beam(self, fc_feats, att_feats, opt={}): beam_size = opt.get('beam_size', 10) batch_size = fc_feats.size(0) assert beam_size <= self.vocab_size + 1, 'lets assume this for now, otherwise this corner case causes a few headaches down the road. can be dealt with in future if needed' seq = torch.LongTensor(self.seq_length, batch_size).zero_() seqLogprobs = torch.FloatTensor(self.seq_length, batch_size) # lets process every image independently for now, for simplicity self.done_beams = [[] for _ in range(batch_size)] for k in range(batch_size): tmp_fc_feats = fc_feats[k:k + 1].expand(beam_size, self.fc_feat_size) tmp_att_feats = att_feats[k:k + 1].expand(*((beam_size,) + att_feats.size()[1:])).contiguous() state = self.init_hidden(tmp_fc_feats) beam_seq = torch.LongTensor(self.seq_length, beam_size).zero_() beam_seq_logprobs = torch.FloatTensor(self.seq_length, beam_size).zero_() beam_logprobs_sum = torch.zeros(beam_size) # running sum of logprobs for each beam done_beams = [] for t in range(1): if t == 0: # input it = fc_feats.data.new(beam_size).long().zero_() xt = self.embed(Variable(it, requires_grad=False)) output, state = self.core(xt, tmp_fc_feats, tmp_att_feats, state) logprobs = F.log_softmax(self.logit(self.dropout(output))) self.done_beams[k] = self.beam_search(state, logprobs, tmp_fc_feats, tmp_att_feats, opt=opt) seq[:, k] = self.done_beams[k][0]['seq'] # the first beam has highest cumulative score seqLogprobs[:, k] = self.done_beams[k][0]['logps'] # return the samples and their log likelihoods return seq.transpose(0, 1), seqLogprobs.transpose(0, 1) def sample(self, fc_feats, att_feats, opt={}): sample_max = opt.get('sample_max', 1) beam_size = opt.get('beam_size', 1) temperature = opt.get('temperature', 1.0) if beam_size > 1: return self.sample_beam(fc_feats, att_feats, opt) batch_size = fc_feats.size(0) state = self.init_hidden(fc_feats) seq = [] seqLogprobs = [] for t in range(self.seq_length + 1): if t == 0: # input it = fc_feats.data.new(batch_size).long().zero_() elif sample_max: sampleLogprobs, it = torch.max(logprobs.data, 1) it = it.view(-1).long() else: if temperature == 1.0: prob_prev = torch.exp(logprobs.data).cpu() # fetch prev distribution: shape Nx(M+1) else: # scale logprobs by temperature prob_prev = torch.exp(torch.div(logprobs.data, temperature)).cpu() it = torch.multinomial(prob_prev, 1).cuda() sampleLogprobs = logprobs.gather(1, Variable(it, requires_grad=False)) # gather the logprobs at sampled positions it = it.view(-1).long() # and flatten indices for downstream processing xt = self.embed(Variable(it, requires_grad=False)) if t >= 1: # stop when all finished if t == 1: unfinished = it > 0 else: unfinished = unfinished * (it > 0) if unfinished.sum() == 0: break it = it * unfinished.type_as(it) seq.append(it) # seq[t] the input of t+2 time step seqLogprobs.append(sampleLogprobs.view(-1)) output, state = self.core(xt, fc_feats, att_feats, state) logprobs = F.log_softmax(self.logit(self.dropout(output)), -1) return torch.cat([_.unsqueeze(1) for _ in seq], 1), torch.cat([_.unsqueeze(1) for _ in seqLogprobs], 1) class ShowAttendTellCore(nn.Module): def __init__(self, opt): super(ShowAttendTellCore, self).__init__() self.input_encoding_size = opt.input_encoding_size self.rnn_type = opt.rnn_type self.rnn_size = opt.rnn_size self.num_layers = opt.num_layers self.drop_prob_lm = opt.drop_prob_lm self.fc_feat_size = opt.fc_feat_size self.att_feat_size = opt.att_feat_size self.att_hid_size = opt.att_hid_size self.rnn = getattr(nn, self.rnn_type.upper())(self.input_encoding_size + self.att_feat_size, self.rnn_size, self.num_layers, bias=False, dropout=self.drop_prob_lm) if self.att_hid_size > 0: self.ctx2att = nn.Linear(self.att_feat_size, self.att_hid_size) self.h2att = nn.Linear(self.rnn_size, self.att_hid_size) self.alpha_net = nn.Linear(self.att_hid_size, 1) else: self.ctx2att = nn.Linear(self.att_feat_size, 1) self.h2att = nn.Linear(self.rnn_size, 1) def forward(self, xt, fc_feats, att_feats, state): att_size = att_feats.numel() // att_feats.size(0) // self.att_feat_size att = att_feats.view(-1, self.att_feat_size) if self.att_hid_size > 0: att = self.ctx2att(att) # (batch * att_size) * att_hid_size att = att.view(-1, att_size, self.att_hid_size) # batch * att_size * att_hid_size att_h = self.h2att(state[0][-1]) # batch * att_hid_size att_h = att_h.unsqueeze(1).expand_as(att) # batch * att_size * att_hid_size dot = att + att_h # batch * att_size * att_hid_size dot = torch.tanh(dot) # batch * att_size * att_hid_size dot = dot.view(-1, self.att_hid_size) # (batch * att_size) * att_hid_size dot = self.alpha_net(dot) # (batch * att_size) * 1 dot = dot.view(-1, att_size) # batch * att_size else: att = self.ctx2att(att)(att) # (batch * att_size) * 1 att = att.view(-1, att_size) # batch * att_size att_h = self.h2att(state[0][-1]) # batch * 1 att_h = att_h.expand_as(att) # batch * att_size dot = att_h + att # batch * att_size weight = F.softmax(dot, -1) att_feats_ = att_feats.view(-1, att_size, self.att_feat_size) # batch * att_size * att_feat_size att_res = torch.bmm(weight.unsqueeze(1), att_feats_).squeeze(1) # batch * att_feat_size output, state = self.rnn(torch.cat([xt, att_res], 1).unsqueeze(0), state) return output.squeeze(0), state class AllImgCore(nn.Module): def __init__(self, opt): super(AllImgCore, self).__init__() self.input_encoding_size = opt.input_encoding_size self.rnn_type = opt.rnn_type self.rnn_size = opt.rnn_size self.num_layers = opt.num_layers self.drop_prob_lm = opt.drop_prob_lm self.fc_feat_size = opt.fc_feat_size self.rnn = getattr(nn, self.rnn_type.upper())(self.input_encoding_size + self.fc_feat_size, self.rnn_size, self.num_layers, bias=False, dropout=self.drop_prob_lm) def forward(self, xt, fc_feats, att_feats, state): output, state = self.rnn(torch.cat([xt, fc_feats], 1).unsqueeze(0), state) return output.squeeze(0), state class ShowAttendTellModel(OldModel): def __init__(self, opt): super(ShowAttendTellModel, self).__init__(opt) self.core = ShowAttendTellCore(opt) class AllImgModel(OldModel): def __init__(self, opt): super(AllImgModel, self).__init__(opt) self.core = AllImgCore(opt)