Ovis1.5-Llama3-8B / modeling_ovis.py
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import os
from importlib import import_module
from typing import List, Callable, Union, Optional
import PIL.Image
import torch
import torch.nn.functional as F
from torch import LongTensor, IntTensor, Tensor
from transformers import CLIPImageProcessor, CLIPVisionModel, SiglipImageProcessor, SiglipVisionModel
from transformers import PreTrainedModel, AutoModel, AutoTokenizer, AutoModelForCausalLM, AutoImageProcessor
from transformers.generation.utils import GenerateOutput
from .configuration_ovis import BaseVisualTokenizerConfig, ClipVisualTokenizerConfig, SiglipVisualTokenizerConfig
from .configuration_ovis import OvisConfig, ConversationFormatter, IGNORE_INDEX, IMAGE_TOKEN_INDEX
# ----------------------------------------------------------------------
# Visual Tokenizer
# ----------------------------------------------------------------------
class BaseVisualTokenizer(PreTrainedModel):
base_model_prefix = "backbone"
main_input_name = None
_image_processor_class = None
_image_processor_kwargs = {}
_backbone_class = None
_backbone_name_or_path = None
def __init__(self, config: BaseVisualTokenizerConfig, *inputs, **kwargs):
super().__init__(config, *inputs, **kwargs)
if kwargs.get('train_from_scratch'):
self.image_processor = self._image_processor_class.from_pretrained(
self._backbone_name_or_path, **self._image_processor_kwargs)
self.backbone = self._backbone_class.from_pretrained(
self._backbone_name_or_path, **self.config.backbone_kwargs)
self.config.backbone_config = self.backbone.config
else:
self.image_processor = AutoImageProcessor.from_pretrained(
kwargs['image_processor_name_or_path'])
self.backbone = AutoModel.from_config(self.config.backbone_config)
self.head = None
assert all((self.image_processor.do_resize,
not getattr(self.image_processor, 'do_center_crop', False),
self.image_processor.do_rescale,
self.image_processor.do_normalize
)), f"image_processor `{self.image_processor}` is not supported currently"
def get_backbone(self):
return self.backbone
def get_image_processor(self):
return self.image_processor
def get_zero_pixel_values(self, n=1):
height, width = self.get_image_size()
if self.config.hd_booster is None:
return torch.zeros(n, 3, height, width)
elif self.config.hd_booster in ['s2wrapper', 's2wrapper-adaptive']:
return torch.zeros(n, 3 * 5, height, width)
else:
raise ValueError(f'Unsupported hd_booster {self.config.hd_booster}')
def get_head(self):
return self.head
def get_image_size(self):
raise NotImplementedError
def preprocess_image(self, image: PIL.Image.Image, convert_to_rgb=True):
def _preprocess(img: PIL.Image.Image):
# first resize and preprocess
sides = self.get_image_size()
if sides[0] != sides[1]:
raise ValueError('get_image_size() returns non-square size')
side = sides[0]
w, h = img.size
if w == h:
new_width = new_height = side
elif w > h:
new_width = side
new_height = int(h / w * new_width)
else:
new_height = side
new_width = int(w / h * new_height)
new_size = dict(height=new_height, width=new_width)
pixel_values = self.image_processor.preprocess(
img, size=new_size, return_tensors='pt')['pixel_values']
# then pad to square
square_values = torch.zeros(
[1, 3, side, side], dtype=pixel_values.dtype, device=pixel_values.device)
new_height, new_width = pixel_values.shape[2:]
if new_height == new_width:
square_values[:, :, :, :] = pixel_values
elif new_height > new_width:
from_index = (side - new_width) // 2
square_values[:, :, :, from_index:from_index + new_width] = pixel_values
else:
from_index = (side - new_height) // 2
square_values[:, :, from_index:from_index + new_height, :] = pixel_values
return square_values
if convert_to_rgb and image.mode != 'RGB':
image = image.convert('RGB')
if self.config.hd_booster is None:
return _preprocess(image) # [1, 3, side, side]
elif self.config.hd_booster in ['s2wrapper', 's2wrapper-adaptive']:
width, height = image.size
is_low_resolution = (height < self.get_image_size()[0] * 1.5 or
width < self.get_image_size()[1] * 1.5)
if self.config.hd_booster == 's2wrapper-adaptive' and is_low_resolution:
values = self.get_zero_pixel_values() + torch.inf
values[0][:3] = _preprocess(image)[0]
else:
center_x, center_y = width // 2, height // 2
image_top_left = image.crop((0, 0, center_x, center_y))
image_top_right = image.crop((center_x, 0, width, center_y))
image_bottom_left = image.crop((0, center_y, center_x, height))
image_bottom_right = image.crop((center_x, center_y, width, height))
imgs = [image, image_top_left, image_top_right, image_bottom_left, image_bottom_right]
values = torch.cat([_preprocess(img) for img in imgs], dim=1)
return values # [1, 3*5, side, side]
else:
raise ValueError(f'Unsupported hd_booster {self.config.hd_booster}')
def get_backbone_layer(self, index):
return self.backbone.vision_model.encoder.layers[index]
def tokenize(self, logits):
def st_argmax(y_soft, dim): # straight-through softmax
index = y_soft.max(dim, keepdim=True)[1]
y_hard = torch.zeros_like(
y_soft, memory_format=torch.legacy_contiguous_format).scatter_(dim, index, 1.0)
ret = y_hard - y_soft.detach() + y_soft
return ret
if self.config.tokenize_function == 'softmax':
tokens = F.softmax(logits, dim=-1)
elif self.config.tokenize_function == 'gumbel_argmax':
tokens = F.gumbel_softmax(logits, tau=self.config.tau, hard=True)
elif self.config.tokenize_function == 'st_argmax':
tokens = st_argmax(logits, dim=-1)
else:
raise ValueError(
f'Invalid `max_type`, expected softmax or gumbel_argmax or st_argmax,'
f' but got {self.config.tokenize_function}')
return tokens
class ClipVisualTokenizer(BaseVisualTokenizer):
config_class = ClipVisualTokenizerConfig
supports_gradient_checkpointing = True
_no_split_modules = ["CLIPEncoderLayer"]
_image_processor_class = CLIPImageProcessor
_image_processor_kwargs = dict(do_center_crop=False)
_backbone_class = CLIPVisionModel
_backbone_name_or_path = "openai/clip-vit-large-patch14-336"
def __init__(self, config: ClipVisualTokenizerConfig = None, *inputs, **kwargs):
super().__init__(config, *inputs, **kwargs)
head_dim = self.config.vocab_size
if self.config.use_indicators:
head_dim -= 2 # reserved for two image indicator tokens
if self.config.hd_booster is None:
self.head = torch.nn.Sequential(
torch.nn.Linear(self.backbone.config.hidden_size, head_dim, bias=False),
torch.nn.LayerNorm(head_dim)
)
elif self.config.hd_booster in ['s2wrapper', 's2wrapper-adaptive']:
self.head = torch.nn.Sequential(
torch.nn.Linear(self.backbone.config.hidden_size * 2, head_dim, bias=False),
torch.nn.LayerNorm(head_dim)
)
else:
raise ValueError(f'Unsupported hd_booster {self.config.hd_booster}')
def get_image_size(self):
height = self.image_processor.crop_size["height"]
width = self.image_processor.crop_size["width"]
return height, width
def encode(self, pixel_values):
if self.config.hd_booster is None:
output = self.backbone(pixel_values, output_hidden_states=True, return_dict=True)
features = output.hidden_states[-1]
if self.config.drop_cls_token:
features = features[:, 1:, :]
elif self.config.hd_booster in ['s2wrapper', 's2wrapper-adaptive']:
n, c, side, _ = pixel_values.shape
if self.config.hd_booster == 's2wrapper-adaptive':
pixel_values_mask = torch.isinf(pixel_values) # [n, c, side, side]
pixel_values = torch.masked_fill(pixel_values, pixel_values_mask, 0.0)
pixel_values = pixel_values.reshape(n * 5, c // 5, side, side)
output = self.backbone(pixel_values, output_hidden_states=True, return_dict=True)
features = output.hidden_states[-1]
if self.config.drop_cls_token:
features = features[:, 1:, :]
_, l, d = features.shape
features = features.reshape(n, 5, l, d)
features_overall = features[:, 0, :, :] # [n, l, d]
features_parts = features[:, 1:, :, :] # [n, 4, l, d]
sqrt_l = int(l ** 0.5)
assert sqrt_l ** 2 == l, "The token sequence length should be a perfect square."
features_parts = features_parts.reshape(n, 4, sqrt_l, sqrt_l, d) # [n, 4, sqrt(l), sqrt(l), d]
features_top = torch.concat(
[features_parts[:, 0, :, :, :], features_parts[:, 1, :, :, :]], dim=-2) # [n, sqrt(l), sqrt(l)*2, d]
features_bottom = torch.concat(
[features_parts[:, 2, :, :, :], features_parts[:, 3, :, :, :]], dim=-2) # [n, sqrt(l), sqrt(l)*2, d]
features_merge = torch.concat([features_top, features_bottom], dim=-3) # [n, sqrt(l)*2, sqrt(l)*2, d]
features_pool = F.interpolate(
features_merge.permute(0, 3, 1, 2).to(torch.float32),
size=sqrt_l,
mode='area'
) # [n, d, sqrt_l, sqrt_l]
features_pool = features_pool.flatten(2).permute(0, 2, 1).to(features.dtype) # [n, l, d]
if self.config.hd_booster == 's2wrapper-adaptive':
features_pool_mask = torch.unsqueeze(
torch.unsqueeze(pixel_values_mask[:, -1, -1, -1], dim=-1), dim=-1) # [n, 1, 1]
features_pool = torch.masked_fill(features_pool, features_pool_mask, 0.0)
features = torch.cat([features_overall, features_pool], dim=-1) # [n, l, 2*d]
else:
raise ValueError(f'Unsupported hd_booster {self.config.hd_booster}')
return features
def forward(self, pixel_values) -> Tensor: # [BatchSize, ImageShape] -> [BatchSize, #Token, VocabSize]
features = self.encode(pixel_values)
logits = self.head(features)
tokens = self.tokenize(logits)
if self.config.use_indicators:
# tokens' shape is [BatchSize, #Token, VocabSize-2], so padding with [BatchSize, #Token, 2],
# after which, tokens' shape should become [BatchSize, #Token, VocabSize]
batch_size, token_len, _ = tokens.shape
padding_tensor = torch.zeros(
size=(batch_size, token_len, 2),
dtype=tokens.dtype,
device=tokens.device,
layout=tokens.layout,
requires_grad=False
)
tokens = torch.cat((tokens, padding_tensor), dim=2)
# adding indicator tokens, after which tokens' shape should become [BatchSize, 1+#Token+1, VocabSize]
begin_indicator = torch.zeros(
size=(batch_size, 1),
dtype=torch.long,
device=tokens.device,
requires_grad=False
) + self.config.vocab_size - 2
begin_indicator_token = F.one_hot(
begin_indicator, num_classes=self.config.vocab_size).to(dtype=tokens.dtype)
end_indicator = torch.zeros(
size=(batch_size, 1),
dtype=torch.long,
device=tokens.device,
requires_grad=False
) + self.config.vocab_size - 1
end_indicator_token = F.one_hot(
end_indicator, num_classes=self.config.vocab_size).to(dtype=tokens.dtype)
tokens = torch.cat((begin_indicator_token, tokens, end_indicator_token), dim=1)
return tokens
class SiglipVisualTokenizer(BaseVisualTokenizer):
config_class = SiglipVisualTokenizerConfig
supports_gradient_checkpointing = True
_no_split_modules = ["SiglipVisionTransformer"]
_image_processor_class = SiglipImageProcessor
_image_processor_kwargs = {}
_backbone_class = SiglipVisionModel
_backbone_name_or_path = "google/siglip-so400m-patch14-384"
def __init__(self, config: SiglipVisualTokenizerConfig = None, *inputs, **kwargs):
super().__init__(config, *inputs, **kwargs)
head_dim = self.config.vocab_size
if self.config.use_indicators:
head_dim -= 2 # reserved for two image indicator tokens
if self.config.hd_booster is None:
self.head = torch.nn.Sequential(
torch.nn.Linear(
self.backbone.config.hidden_size * self.config.hidden_stride * self.config.hidden_stride,
head_dim,
bias=False
),
torch.nn.LayerNorm(head_dim)
)
elif self.config.hd_booster in ['s2wrapper', 's2wrapper-adaptive']:
self.head = torch.nn.Sequential(
torch.nn.Linear(
self.backbone.config.hidden_size * self.config.hidden_stride * self.config.hidden_stride * 2,
head_dim,
bias=False
),
torch.nn.LayerNorm(head_dim)
)
else:
raise ValueError(f'Unsupported hd_booster {self.config.hd_booster}')
def get_image_size(self):
height = self.image_processor.size["height"]
width = self.image_processor.size["width"]
return height, width
def encode(self, pixel_values):
if self.config.hd_booster is None:
output = self.backbone(pixel_values, output_hidden_states=True, return_dict=True)
features = output.hidden_states[-1]
if self.config.drop_cls_token:
features = features[:, 1:, :]
elif self.config.hd_booster in ['s2wrapper', 's2wrapper-adaptive']:
n, c, side, _ = pixel_values.shape
if self.config.hd_booster == 's2wrapper-adaptive':
pixel_values_mask = torch.isinf(pixel_values) # [n, c, side, side]
pixel_values = torch.masked_fill(pixel_values, pixel_values_mask, 0.0)
pixel_values = pixel_values.reshape(n * 5, c // 5, side, side)
output = self.backbone(pixel_values, output_hidden_states=True, return_dict=True)
features = output.hidden_states[-1]
if self.config.drop_cls_token:
features = features[:, 1:, :]
_, l, d = features.shape
features = features.reshape(n, 5, l, d)
features_overall = features[:, 0, :, :] # [n, l, d]
features_parts = features[:, 1:, :, :] # [n, 4, l, d]
sqrt_l = int(l ** 0.5)
assert sqrt_l ** 2 == l, "The token sequence length should be a perfect square."
features_parts = features_parts.reshape(n, 4, sqrt_l, sqrt_l, d) # [n, 4, sqrt(l), sqrt(l), d]
features_top = torch.concat(
[features_parts[:, 0, :, :, :], features_parts[:, 1, :, :, :]], dim=-2) # [n, sqrt(l), sqrt(l)*2, d]
features_bottom = torch.concat(
[features_parts[:, 2, :, :, :], features_parts[:, 3, :, :, :]], dim=-2) # [n, sqrt(l), sqrt(l)*2, d]
features_merge = torch.concat([features_top, features_bottom], dim=-3) # [n, sqrt(l)*2, sqrt(l)*2, d]
features_pool = F.interpolate(
features_merge.permute(0, 3, 1, 2).to(torch.float32),
size=sqrt_l,
mode='area'
) # [n, d, sqrt_l, sqrt_l]
features_pool = features_pool.flatten(2).permute(0, 2, 1).to(features.dtype) # [n, l, d]
if self.config.hd_booster == 's2wrapper-adaptive':
features_pool_mask = torch.unsqueeze(
torch.unsqueeze(pixel_values_mask[:, -1, -1, -1], dim=-1), dim=-1) # [n, 1, 1]
features_pool = torch.masked_fill(features_pool, features_pool_mask, 0.0)
features = torch.cat([features_overall, features_pool], dim=-1) # [n, l, 2*d]
else:
raise ValueError(f'Unsupported hd_booster {self.config.hd_booster}')
# merge number of `hidden_stride * hidden_stride` hidden states together to reduce token sequence length
# e.g., for hidden_stride=3, this leads to a token length reduction: 729 -> 81
if self.config.hidden_stride > 1:
n, l, d = features.shape # this `d` maybe different from the above `d
sqrt_l = int(l ** 0.5)
assert sqrt_l ** 2 == l, "The token sequence length should be a perfect square."
assert l % (self.config.hidden_stride ** 2) == 0, \
"The token sequence length should be divisible by `hidden_stride**2`."
features = features.reshape(n, sqrt_l, sqrt_l, d)
features = features.reshape(n, sqrt_l // self.config.hidden_stride, self.config.hidden_stride,
sqrt_l // self.config.hidden_stride, self.config.hidden_stride, d)
features = features.permute(0, 1, 3, 2, 4, 5) # [n, sqrt_l/hs, sqrt_l/hs, hs, hs, d]
features = features.flatten(3) # [n, sqrt_l/hs, sqrt_l/hs, hs*hs*d]
features = features.reshape(n, l // (self.config.hidden_stride * self.config.hidden_stride),
self.config.hidden_stride * self.config.hidden_stride * d)
return features
def forward(self, pixel_values) -> Tensor: # [BatchSize, ImageShape] -> [BatchSize, #Token, VocabSize]
features = self.encode(pixel_values)
logits = self.head(features)
tokens = self.tokenize(logits)
if self.config.use_indicators:
# tokens' shape is [BatchSize, #Token, VocabSize-2], so padding with [BatchSize, #Token, 2], after
# which, tokens' shape should become [BatchSize, #Token, VocabSize]
batch_size, token_len, _ = tokens.shape
padding_tensor = torch.zeros(
size=(batch_size, token_len, 2),
dtype=tokens.dtype,
device=tokens.device,
layout=tokens.layout,
requires_grad=False
)
tokens = torch.cat((tokens, padding_tensor), dim=2)
# adding indicator tokens, after which tokens' shape should become [BatchSize, 1+#Token+1, VocabSize]
begin_indicator = torch.zeros(
size=(batch_size, 1),
dtype=torch.long,
device=tokens.device,
requires_grad=False
) + self.config.vocab_size - 2
begin_indicator_token = F.one_hot(
begin_indicator, num_classes=self.config.vocab_size).to(dtype=tokens.dtype)
end_indicator = torch.zeros(
size=(batch_size, 1),
dtype=torch.long,
device=tokens.device,
requires_grad=False
) + self.config.vocab_size - 1
end_indicator_token = F.one_hot(
end_indicator, num_classes=self.config.vocab_size).to(dtype=tokens.dtype)
tokens = torch.cat((begin_indicator_token, tokens, end_indicator_token), dim=1)
return tokens
AutoModel.register(ClipVisualTokenizerConfig, ClipVisualTokenizer)
AutoModel.register(SiglipVisualTokenizerConfig, SiglipVisualTokenizer)
# ----------------------------------------------------------------------
# Ovis
# ----------------------------------------------------------------------
class VisualEmbedding(torch.nn.Embedding):
def forward(self, input: Tensor) -> Tensor:
if any((isinstance(input, LongTensor), isinstance(input, IntTensor))):
return super().forward(input)
return torch.matmul(input, self.weight)
class OvisPreTrainedModel(PreTrainedModel):
config_class = OvisConfig
base_model_prefix = "ovis"
class Ovis(OvisPreTrainedModel):
def __init__(self, config: OvisConfig, *inputs, **kwargs):
super().__init__(config, *inputs, **kwargs)
self.llm = AutoModelForCausalLM.from_config(self.config.llm_config)
assert self.config.hidden_size == self.llm.config.hidden_size, "hidden size mismatch"
self.text_tokenizer = AutoTokenizer.from_pretrained(self.config.name_or_path)
self.visual_tokenizer = AutoModel.from_config(
self.config.visual_tokenizer_config,
image_processor_name_or_path=self.config.name_or_path
)
self.vte = VisualEmbedding(
self.config.visual_tokenizer_config.vocab_size,
self.config.hidden_size,
device=self.visual_tokenizer.device,
dtype=self.visual_tokenizer.dtype
)
def _merge_modules(modules_list: tuple):
merged_modules = []
for modules in modules_list:
merged_modules.extend(modules if modules else [])
return merged_modules
self._no_split_modules = _merge_modules(
(self.llm._no_split_modules, self.visual_tokenizer._no_split_modules))
self._skip_keys_device_placement = self.llm._skip_keys_device_placement
self._keep_in_fp32_modules = _merge_modules(
(self.llm._keep_in_fp32_modules, self.visual_tokenizer._keep_in_fp32_modules))
self.is_parallelizable = all((self.llm.is_parallelizable, self.visual_tokenizer.is_parallelizable))
self.supports_gradient_checkpointing = all(
(self.llm.supports_gradient_checkpointing, self.visual_tokenizer.supports_gradient_checkpointing))
self._supports_flash_attn_2 = all(
(self.llm._supports_flash_attn_2, self.visual_tokenizer._supports_flash_attn_2))
self._supports_sdpa = all((self.llm._supports_sdpa, self.visual_tokenizer._supports_sdpa))
def get_text_tokenizer(self):
return self.text_tokenizer
def get_visual_tokenizer(self):
return self.visual_tokenizer
def get_llm(self):
return self.llm
def get_vte(self):
return self.vte
def get_wte(self):
return self.llm.get_input_embeddings()
def get_conversation_formatter(self) -> ConversationFormatter:
if getattr(self, 'conversation_formatter', None) is None:
self.conversation_formatter = getattr(
import_module(".configuration_ovis", __package__),
self.config.conversation_formatter_class
)(self.text_tokenizer)
return self.conversation_formatter
def forward(
self,
input_ids: torch.Tensor,
attention_mask: torch.Tensor,
labels: Optional[torch.Tensor],
pixel_values: List[Optional[torch.Tensor]],
**kwargs
):
assert self.training, "`forward` can only be used in training. For inference, use `generate`."
_, inputs_embeds, labels, attention_mask = self.merge_multimodal(
text_input_ids=input_ids,
text_attention_masks=attention_mask,
text_labels=labels,
pixel_values=pixel_values
)
return self.llm(inputs_embeds=inputs_embeds, labels=labels, attention_mask=attention_mask, **kwargs)
def merge_multimodal(
self,
text_input_ids: torch.Tensor,
text_attention_masks: torch.Tensor,
text_labels: Optional[torch.Tensor],
pixel_values: List[Optional[torch.Tensor]]
):
input_device = text_input_ids.device
if self.training:
# When training, to be compatible with deepspeed zero, each sample has to include pixel_value tensor.
# For text-only sample, one can simply use a full zero tensor as pixel_value, which will be ignored
# (see below in this function); so, the gradient will not be affected.
num_images = [x.shape[0] for x in pixel_values]
visual_tokens = self.visual_tokenizer(torch.cat([x for x in pixel_values], dim=0))
visual_embeds = torch.split(
self.get_vte()(visual_tokens).to(dtype=self.dtype, device=input_device),
split_size_or_sections=num_images,
dim=0
)
visual_input_ids = torch.split(
torch.argmax(visual_tokens, dim=-1).to(device=input_device),
split_size_or_sections=num_images,
dim=0
)
visual_labels = [
torch.full(
x.shape, IGNORE_INDEX, dtype=torch.long, device=input_device
) for x in visual_input_ids
]
else:
# When inference, sample can include only text with `None` pixel_value
num_images = [x.shape[0] if x is not None else 0 for x in pixel_values]
if sum(num_images) > 0:
visual_tokens = self.visual_tokenizer(torch.cat([x for x in pixel_values if x is not None], dim=0))
visual_embeds = torch.split(
self.get_vte()(visual_tokens).to(dtype=self.dtype, device=input_device),
split_size_or_sections=num_images,
dim=0
)
visual_input_ids = torch.split(
torch.argmax(visual_tokens, dim=-1).to(device=input_device),
split_size_or_sections=num_images,
dim=0
)
visual_labels = [
torch.full(
x.shape, IGNORE_INDEX, dtype=torch.long, device=input_device
) for x in visual_input_ids
]
else:
# just placeholders
visual_embeds = [None] * len(num_images)
visual_input_ids = [None] * len(num_images)
visual_labels = [None] * len(num_images)
# just placeholders
text_labels = torch.full(text_input_ids.shape, IGNORE_INDEX, dtype=torch.long, device=input_device)
input_embeds = []
attention_masks = []
labels = []
for text_input_id, text_label, text_attention_mask, visual_embed, visual_input_id, visual_label in zip(
text_input_ids, text_labels, text_attention_masks, visual_embeds, visual_input_ids, visual_labels
):
image_token_mask = torch.eq(text_input_id, IMAGE_TOKEN_INDEX)
text_embed = self.get_wte()(torch.masked_fill(text_input_id, image_token_mask, 0))
image_token_positions = torch.where(image_token_mask)[0].tolist()
if len(image_token_positions) > 0:
input_embed_parts = []
attention_mask_parts = []
label_parts = []
prev_image_token_position = -1
for index, image_token_position in enumerate(image_token_positions):
input_embed_parts.append(
text_embed[prev_image_token_position + 1:image_token_position, :])
label_parts.append(
text_label[prev_image_token_position + 1:image_token_position])
attention_mask_parts.append(
text_attention_mask[prev_image_token_position + 1:image_token_position])
input_embed_parts.append(visual_embed[index])
attention_mask_parts.append(
torch.ones_like(visual_label[index], dtype=torch.bool))
label_parts.append(visual_label[index])
prev_image_token_position = image_token_position
if prev_image_token_position + 1 < text_input_id.shape[0]:
input_embed_parts.append(
text_embed[prev_image_token_position + 1:, :])
attention_mask_parts.append(
text_attention_mask[prev_image_token_position + 1:])
label_parts.append(
text_label[prev_image_token_position + 1:])
input_embed = torch.cat(input_embed_parts, dim=0)
attention_mask = torch.cat(attention_mask_parts, dim=0)
label = torch.cat(label_parts, dim=0)
else:
input_embed = text_embed
attention_mask = text_attention_mask
label = text_label
if self.training:
# Make visual_embed involved in the backward graph,
# to be compatible with deepspeed zero and ddp.
input_embed += torch.sum(visual_embed * 0.0)
input_embeds.append(input_embed)
attention_masks.append(attention_mask)
labels.append(label)
batch_input_embeds = torch.nn.utils.rnn.pad_sequence(
input_embeds, batch_first=True, padding_value=0.0)[:, :self.config.multimodal_max_length, :]
batch_attention_mask = torch.nn.utils.rnn.pad_sequence(
attention_masks, batch_first=True, padding_value=False)[:, :self.config.multimodal_max_length]
batch_labels = torch.nn.utils.rnn.pad_sequence(
labels, batch_first=True, padding_value=IGNORE_INDEX)[:, :self.config.multimodal_max_length]
return visual_input_ids, batch_input_embeds, batch_labels, batch_attention_mask
def save_pretrained(
self,
save_directory: Union[str, os.PathLike],
is_main_process: bool = True,
state_dict: Optional[dict] = None,
save_function: Callable = torch.save,
push_to_hub: bool = False,
max_shard_size: Union[int, str] = "5GB",
safe_serialization: bool = True,
variant: Optional[str] = None,
token: Optional[Union[str, bool]] = None,
save_peft_format: bool = True,
**kwargs
):
super().save_pretrained(save_directory,
is_main_process=is_main_process,
state_dict=state_dict,
save_function=save_function,
safe_serialization=safe_serialization)
self.get_text_tokenizer().save_pretrained(save_directory)
self.get_visual_tokenizer().get_image_processor().save_pretrained(save_directory)
# uncomment the following will additionally save a separate visual tokenizer
# visual_tokenizer_directory = os.path.join(save_directory, 'visual_tokenizer')
# self.get_visual_tokenizer().save_pretrained(visual_tokenizer_directory,
# is_main_process=is_main_process,
# state_dict=None,
# save_function=save_function,
# safe_serialization=safe_serialization)
# self.get_visual_tokenizer().get_image_processor().save_pretrained(visual_tokenizer_directory)
# TODO: support batch generation
def generate(
self,
inputs: Optional[torch.Tensor] = None,
**kwargs
) -> Union[GenerateOutput, torch.LongTensor]:
assert inputs.shape[0] == 1, 'Currently, only support `batch_size=1`'
_, inputs_embeds, labels, attention_mask = self.merge_multimodal(
text_input_ids=inputs,
text_attention_masks=kwargs.pop('attention_mask'),
text_labels=None,
pixel_values=kwargs.pop('pixel_values')
)
if getattr(self.generation_config, 'cache_implementation') == 'hybrid': # mainly for Gemma2
kwargs['past_key_values'] = self.get_llm()._get_cache(
'hybrid', getattr(kwargs, "num_beams", 1), kwargs['max_new_tokens'] + inputs_embeds.shape[-2]
)
self.get_llm()._supports_cache_class = True
kwargs['cache_implementation'] = None
return self.llm.generate(inputs=None, inputs_embeds=inputs_embeds, attention_mask=attention_mask, **kwargs)