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import math
from typing import List, Optional
import json
import torch
import torchvision
from copy import deepcopy
from PIL import Image
from timm.data import IMAGENET_INCEPTION_MEAN, IMAGENET_INCEPTION_STD
from torchvision import transforms
from transformers import LlamaTokenizer, LlamaPreTrainedModel, LlamaForCausalLM, AutoModel, PreTrainedTokenizerFast
from transformers.models.idefics2.modeling_idefics2 import Idefics2VisionTransformer
from .configuration_minicpm import MiniCPMVConfig
from .resampler import Resampler
class MiniCPMVPreTrainedModel(LlamaPreTrainedModel):
config_class = MiniCPMVConfig
class MiniCPMV(MiniCPMVPreTrainedModel):
def __init__(self, config):
super().__init__(config)
self.llm = LlamaForCausalLM(config)
self.vpm = self.init_vision_module()
self.vision_dim = self.vpm.embed_dim
self.embed_dim = self.llm.config.hidden_size
self.resampler = self.init_resampler(self.embed_dim, self.vision_dim)
self.transform = self.init_transform()
def init_vision_module(self):
# same as HuggingFaceM4/siglip-so400m-14-980-flash-attn2-navit
model = Idefics2VisionTransformer(self.config.vision_config)
if self.config.drop_vision_last_layer:
model.encoder.layers = model.encoder.layers[:-1]
setattr(model, 'embed_dim', model.embeddings.embed_dim)
setattr(model, 'patch_size', model.embeddings.patch_size)
return model
def init_resampler(self, embed_dim, vision_dim):
return Resampler(
num_queries=self.config.query_num,
embed_dim=embed_dim,
num_heads=embed_dim // 128,
kv_dim=vision_dim,
adaptive=True
)
def init_transform(self):
return transforms.Compose(
[
transforms.ToTensor(),
transforms.Normalize(
mean=IMAGENET_INCEPTION_MEAN, std=IMAGENET_INCEPTION_STD
),
]
)
def get_vllm_embedding(self, data):
if 'vision_hidden_states' not in data:
dtype = self.vpm.embeddings.position_embedding.weight.dtype
device = self.vpm.embeddings.position_embedding.weight.device
tgt_sizes = data['tgt_sizes']
pixel_values_list = data['pixel_values']
vision_hidden_states = []
all_pixel_values = []
img_cnt = []
for pixel_values in pixel_values_list:
img_cnt.append(len(pixel_values))
all_pixel_values.extend([i.flatten(end_dim=1).permute(1, 0) for i in pixel_values])
# exist image
if all_pixel_values:
tgt_sizes = torch.vstack(tgt_sizes).type(torch.int32)
if self.config.batch_vision_input:
max_patches = torch.max(tgt_sizes[:, 0] * tgt_sizes[:, 1])
all_pixel_values = torch.nn.utils.rnn.pad_sequence(all_pixel_values, batch_first=True,
padding_value=0.0)
B, L, _ = all_pixel_values.shape
all_pixel_values = all_pixel_values.permute(0, 2, 1).reshape(B, 3, -1, L)
patch_attn_mask = torch.zeros((B, 1, max_patches), dtype=torch.bool, device=device)
for i in range(B):
patch_attn_mask[i, :tgt_sizes[i][0] * tgt_sizes[i][1]] = True
vision_embedding = self.vpm(all_pixel_values.type(dtype), patch_attention_mask=patch_attn_mask).last_hidden_state
vision_embedding = self.resampler(vision_embedding, tgt_sizes)
else:
# get vision_embedding foreach
vision_embedding = []
for single_tgt_size, single_pixel_values in zip(tgt_sizes, all_pixel_values):
single_pixel_values = single_pixel_values.unsqueeze(0)
B, L, _ = single_pixel_values.shape
single_pixel_values = single_pixel_values.permute(0, 2, 1).reshape(B, 3, -1, L)
single_vision_embedding = self.vpm(single_pixel_values.type(dtype)).last_hidden_state
single_vision_embedding = self.resampler(single_vision_embedding, single_tgt_size.unsqueeze(0))
vision_embedding.append(single_vision_embedding)
vision_embedding = torch.vstack(vision_embedding)
start = 0
for pixel_values in pixel_values_list:
img_cnt = len(pixel_values)
if img_cnt > 0:
vision_hidden_states.append(vision_embedding[start: start + img_cnt])
start += img_cnt
else:
vision_hidden_states.append([])
else: # no image
if self.training:
dummy_image = torch.zeros(
(1, 3, 224, 224),
device=device, dtype=dtype
)
tgt_sizes = torch.Tensor([[(224 // self.config.patch_size), math.ceil(224 / self.config.patch_size)]]).type(torch.int32)
dummy_feature = self.resampler(self.vpm(dummy_image).last_hidden_state, tgt_sizes)
else:
dummy_feature = []
for _ in range(len(pixel_values_list)):
vision_hidden_states.append(dummy_feature)
else:
vision_hidden_states = data['vision_hidden_states']
if hasattr(self.llm.config, 'scale_emb'):
vllm_embedding = self.llm.model.embed_tokens(data['input_ids']) * self.llm.config.scale_emb
else:
vllm_embedding = self.llm.model.embed_tokens(data['input_ids'])
vision_hidden_states = [i.type(vllm_embedding.dtype) if isinstance(
i, torch.Tensor) else i for i in vision_hidden_states]
bs = len(data['input_ids'])
for i in range(bs):
cur_vs_hs = vision_hidden_states[i]
if len(cur_vs_hs) > 0:
cur_vllm_emb = vllm_embedding[i]
cur_image_bound = data['image_bound'][i]
if len(cur_image_bound) > 0:
image_indices = torch.stack(
[torch.arange(r[0], r[1], dtype=torch.long) for r in cur_image_bound]
).to(vllm_embedding.device)
cur_vllm_emb.scatter_(0, image_indices.view(-1, 1).repeat(1, cur_vllm_emb.shape[-1]),
cur_vs_hs.view(-1, cur_vs_hs.shape[-1]))
elif self.training:
cur_vllm_emb += cur_vs_hs[0].mean() * 0
return vllm_embedding, vision_hidden_states
def forward(self, data, **kwargs):
vllm_embedding, vision_hidden_states = self.get_vllm_embedding(data)
position_ids = data["position_ids"]
if position_ids.dtype != torch.int64:
position_ids = position_ids.long()
return self.llm(
input_ids=None,
position_ids=position_ids,
inputs_embeds=vllm_embedding,
**kwargs
)
def _convert_to_tensors(
self, tokenizer, input_ids, max_inp_length: Optional[int] = None
):
if max_inp_length is not None:
input_ids = input_ids[:max_inp_length]
input_ids = torch.tensor(input_ids, dtype=torch.int32)
image_start_tokens = torch.where(input_ids == tokenizer.im_start_id)[0]
# 跳过 im_start
image_start_tokens += 1
image_end_tokens = torch.where(input_ids == tokenizer.im_end_id)[0]
valid_image_nums = max(len(image_start_tokens), len(image_end_tokens))
image_bound = torch.hstack(
[
image_start_tokens[:valid_image_nums].unsqueeze(-1),
image_end_tokens[:valid_image_nums].unsqueeze(-1),
]
)
model_input = {}
model_input["input_ids"] = input_ids.unsqueeze(0).to(self.device)
model_input["image_bound"] = image_bound
return model_input
def _process_list(
self, tokenizer, input_id_list, max_inp_length: Optional[int] = None
):
pad_keys = ["input_ids"]
input_tensors = []
for input_ids in input_id_list:
input_tensors.append(
self._convert_to_tensors(tokenizer, input_ids, max_inp_length)
)
padded = {}
for key in pad_keys:
padded[key] = pad(input_tensors, key, padding_side="left").to(self.device)
padded["image_bound"] = [i["image_bound"] for i in input_tensors]
return padded
def _decode(self, inputs_embeds, tokenizer, **kwargs):
terminators = [
tokenizer.eos_token_id,
tokenizer.convert_tokens_to_ids("<|eot_id|>")
]
output = self.llm.generate(
inputs_embeds=inputs_embeds,
pad_token_id=0,
eos_token_id=terminators,
**kwargs
)
return self._decode_text(output, tokenizer)
def _decode_text(self, result_ids, tokenizer):
result_text = []
for result in result_ids:
result = result[result != 0]
if result[0] == tokenizer.bos_id:
result = result[1:]
if result[-1] == tokenizer.eos_id or result[-1] == tokenizer.eot_id:
result = result[:-1]
result_text.append(tokenizer.decode(result).strip())
return result_text
def slice_image(self, image):
return slice_image(
image,
self.config.slice_config.max_slice_nums,
self.config.slice_config.scale_resolution,
self.config.slice_config.patch_size,
)
def get_slice_image_placeholder(self, image, tokenizer):
image_placeholder = (
tokenizer.im_start
+ tokenizer.unk_token * self.config.query_num
+ tokenizer.im_end
)
slice_images = []
source_image, patches, best_grid = slice_image(
image,
self.config.slice_config.max_slice_nums,
self.config.slice_config.scale_resolution,
self.config.slice_config.patch_size,
)
slice_images.append(source_image)
final_placeholder = image_placeholder
if len(patches) > 0:
for i in range(len(patches)):
for j in range(len(patches[0])):
slice_images.append(patches[i][j])
final_placeholder += get_grid_placeholder(
tokenizer, best_grid, self.config.query_num
)
return slice_images, final_placeholder
def reshape_by_patch(self, image_tensor):
"""
:param image_tensor: shape [3, H, W]
:param patch_size:
:return: [3, patch_size, HW/patch_size]
"""
patch_size = self.config.patch_size
patches = torch.nn.functional.unfold(
image_tensor,
(patch_size, patch_size),
stride=(patch_size, patch_size)
)
patches = patches.reshape(image_tensor.size(0), patch_size, patch_size, -1)
patches = patches.permute(0, 1, 3, 2).reshape(image_tensor.size(0), patch_size, -1)
return patches
def generate(
self,
input_id_list=None,
img_list=None,
tgt_sizes=None,
tokenizer=None,
max_inp_length: Optional[int] = None,
vision_hidden_states=None,
return_vision_hidden_states=False,
**kwargs
):
assert input_id_list is not None
bs = len(input_id_list)
if img_list == None:
img_list = [[] for i in range(bs)]
assert bs == len(img_list)
model_inputs = self._process_list(tokenizer, input_id_list, max_inp_length)
if vision_hidden_states is None:
pixel_values = []
for i in range(bs):
img_inps = []
for img in img_list[i]:
img_inps.append(img.to(self.device))
if img_inps:
pixel_values.append(img_inps)
else:
pixel_values.append([])
model_inputs["pixel_values"] = pixel_values
model_inputs['tgt_sizes'] = tgt_sizes
else:
model_inputs["vision_hidden_states"] = vision_hidden_states
with torch.inference_mode():
(
model_inputs["inputs_embeds"],
vision_hidden_states,
) = self.get_vllm_embedding(model_inputs)
result = self._decode(model_inputs["inputs_embeds"], tokenizer, **kwargs)
if return_vision_hidden_states:
return result, vision_hidden_states
return result
def chat(
self,
image,
msgs,
tokenizer,
vision_hidden_states=None,
max_new_tokens=1024,
sampling=True,
max_inp_length=2048,
**kwargs
):
if isinstance(msgs, str):
msgs = json.loads(msgs)
copy_msgs = deepcopy(msgs)
assert len(copy_msgs) > 0, 'msgs is empty'
if image is not None and isinstance(copy_msgs[0]['content'], str):
copy_msgs[0]['content'] = [image, copy_msgs[0]['content']]
for i, msg in enumerate(copy_msgs):
role = msg["role"]
content = msg["content"]
assert role in ["user", "assistant"]
if i == 0:
assert role == "user", "The role of first msg should be user"
if isinstance(content, str):
content = [content]
images = []
tgt_sizes = []
cur_msgs = []
for c in content:
if isinstance(c, Image.Image):
image = c
if self.config.slice_mode:
slice_images, image_placeholder = self.get_slice_image_placeholder(
image, tokenizer
)
cur_msgs.append(image_placeholder)
for slice_image in slice_images:
slice_image = self.transform(slice_image)
H, W = slice_image.shape[1:]
images.append(self.reshape_by_patch(slice_image))
tgt_sizes.append(torch.Tensor([H // self.config.patch_size, W // self.config.patch_size]).type(torch.int32))
else:
images.append(self.transform(image))
cur_msgs.append(
tokenizer.im_start
+ tokenizer.unk_token * self.config.query_num
+ tokenizer.im_end
)
elif isinstance(c, str):
cur_msgs.append(c)
if tgt_sizes:
tgt_sizes = torch.vstack(tgt_sizes)
msg['content'] = '\n'.join(cur_msgs)
input_ids = tokenizer.apply_chat_template(copy_msgs, tokenize=True, add_generation_prompt=False)
if sampling:
generation_config = {
"top_p": 0.8,
"top_k": 100,
"temperature": 0.7,
"do_sample": True,
"repetition_penalty": 1.05
}
else:
generation_config = {
"num_beams": 3,
"repetition_penalty": 1.2,
}
generation_config.update(
(k, kwargs[k]) for k in generation_config.keys() & kwargs.keys()
)
with torch.inference_mode():
res, vision_hidden_states = self.generate(
input_id_list=[input_ids],
max_inp_length=max_inp_length,
img_list=[images],
tgt_sizes=[tgt_sizes],
tokenizer=tokenizer,
max_new_tokens=max_new_tokens,
vision_hidden_states=vision_hidden_states,
return_vision_hidden_states=True,
**generation_config
)
answer = res[0]
return answer
class PreTrainedTokenizerFastWrapper(PreTrainedTokenizerFast):
def __init__(self, **kwargs):
super().__init__(**kwargs)
self.eot_token = "<|eot_id|>"
self.im_start = "<image>"
self.im_end = "</image>"
self.ref_start = "<ref>"
self.ref_end = "</ref>"
self.box_start = "<box>"
self.box_end = "</box>"
self.quad_start = "<quad>"
self.quad_end = "</quad>"
self.slice_start = "<slice>"
self.slice_end = "</slice>"
@property
def eos_id(self):
return self.eos_token_id
@property
def bos_id(self):
return self.bos_token_id
@property
def unk_id(self):
return self.unk_token_id
@property
def eot_id(self):
return self.convert_tokens_to_ids(self.eot_token)
@property
def im_start_id(self):
return self.convert_tokens_to_ids(self.im_start)
@property
def im_end_id(self):
return self.convert_tokens_to_ids(self.im_end)
@staticmethod
def escape(text: str) -> str:
return text
@staticmethod
def unescape(text: str) -> str:
return text
def pad(orig_items, key, max_length=None, padding_value=0, padding_side="left"):
items = []
if isinstance(orig_items[0][key], list):
assert isinstance(orig_items[0][key][0], torch.Tensor)
for it in orig_items:
for tr in it[key]:
items.append({key: tr})
else:
assert isinstance(orig_items[0][key], torch.Tensor)
items = orig_items
batch_size = len(items)
shape = items[0][key].shape
dim = len(shape)
assert dim <= 3
if max_length is None:
max_length = 0
max_length = max(max_length, max(item[key].shape[-1] for item in items))
min_length = min(item[key].shape[-1] for item in items)
dtype = items[0][key].dtype
if dim == 1:
return torch.cat([item[key] for item in items], dim=0)
elif dim == 2:
if max_length == min_length:
return torch.cat([item[key] for item in items], dim=0)
tensor = torch.zeros((batch_size, max_length), dtype=dtype) + padding_value
else:
tensor = (
torch.zeros((batch_size, max_length, shape[-1]), dtype=dtype)
+ padding_value
)
for i, item in enumerate(items):
if dim == 2:
if padding_side == "left":
tensor[i, -len(item[key][0]) :] = item[key][0].clone()
else:
tensor[i, : len(item[key][0])] = item[key][0].clone()
elif dim == 3:
if padding_side == "left":
tensor[i, -len(item[key][0]) :, :] = item[key][0].clone()
else:
tensor[i, : len(item[key][0]), :] = item[key][0].clone()
return tensor
def slice_image(
image, max_slice_nums=9, scale_resolution=448, patch_size=14, never_split=False
):
original_size = image.size
original_width, original_height = original_size
log_ratio = math.log(original_width / original_height)
ratio = original_width * original_height / (scale_resolution * scale_resolution)
multiple = min(math.ceil(ratio), max_slice_nums)
source_image = None
best_grid = None
patches = []
if multiple <= 1 or never_split:
# dont need to slice, upsample
best_size = find_best_resize(
original_size, scale_resolution, patch_size, allow_upscale=True
)
source_image = image.resize(best_size, Image.Resampling.BICUBIC)
else:
candidate_split_grids_nums = []
for i in [multiple - 1, multiple, multiple + 1]:
if i == 1 or i > max_slice_nums:
continue
candidate_split_grids_nums.append(i)
# source image, down-sampling and ensure divided by patch_size
best_resize = find_best_resize(original_size, scale_resolution, patch_size)
source_image = image.copy().resize(best_resize, Image.Resampling.BICUBIC)
candidate_grids = []
# find best grid
for split_grids_nums in candidate_split_grids_nums:
m = 1
while m <= split_grids_nums:
if split_grids_nums % m == 0:
candidate_grids.append([m, split_grids_nums // m])
m += 1
best_grid = [1, 1]
min_error = float("inf")
for grid in candidate_grids:
error = abs(log_ratio - math.log(grid[0] / grid[1]))
if error < min_error:
best_grid = grid
min_error = error
refine_size = get_refine_size(
original_size, best_grid, scale_resolution, patch_size, allow_upscale=True
)
refine_image = image.resize(refine_size, Image.Resampling.BICUBIC)
patches = split_to_patches(refine_image, best_grid)
return source_image, patches, best_grid
def ensure_divide(length, patch_size):
return max(round(length / patch_size) * patch_size, patch_size)
def find_best_resize(original_size, scale_resolution, patch_size, allow_upscale=False):
width, height = original_size
if (width * height > scale_resolution * scale_resolution) or allow_upscale:
r = width / height
height = int(scale_resolution / math.sqrt(r))
width = int(height * r)
best_width = ensure_divide(width, patch_size)
best_height = ensure_divide(height, patch_size)
return (best_width, best_height)
def get_refine_size(
original_size, grid, scale_resolution, patch_size, allow_upscale=False
):
width, height = original_size
grid_x, grid_y = grid
refine_width = ensure_divide(width, grid_x)
refine_height = ensure_divide(height, grid_y)
grid_width = refine_width / grid_x
grid_height = refine_height / grid_y
best_grid_size = find_best_resize(
(grid_width, grid_height),
scale_resolution,
patch_size,
allow_upscale=allow_upscale,
)
refine_size = (best_grid_size[0] * grid_x, best_grid_size[1] * grid_y)
return refine_size
def split_to_patches(image, grid):
patches = []
width, height = image.size
grid_x = int(width / grid[0])
grid_y = int(height / grid[1])
for i in range(0, height, grid_y):
images = []
for j in range(0, width, grid_x):
box = (j, i, j + grid_x, i + grid_y)
patch = image.crop(box)
images.append(patch)
patches.append(images)
return patches
def get_grid_placeholder(tokenizer, grid, query_num):
image_placeholder = (
tokenizer.im_start + tokenizer.unk_token * query_num + tokenizer.im_end
)
cols = grid[0]
rows = grid[1]
slices = []
for i in range(rows):
lines = []
for j in range(cols):
lines.append(image_placeholder)
slices.append("".join(lines))
slice_placeholder = tokenizer.slice_start + "\n".join(slices) + tokenizer.slice_end
return slice_placeholder
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