论文链接：https://www.arxiv.org/abs/2408.08872
代码链接：https://github.com/salesforce/LAVIS/tree/xgen-mm

本次解读xGen-MM (BLIP-3): A Family of Open Large Multimodal Models
可以看作是
[1] Blip: Bootstrapping language-image pre-training for unified vision-language understanding and generation
[2] BLIP-2: Bootstrapping Language-Image Pre-training with Frozen Image Encoders and Large Language Models
的后继版本

前言

没看到Blip和Blip2的一作Junnan Li，不知道为啥不参与Blip3
整体pipeline服从工业界的一贯做法，加数据，加显卡，模型、训练方式简单，疯狂scale up

创新点

• 开源模型在模型权重、训练数据、训练方法上做的不好
• Blip2用的数据不够多、质量不够高；Blip2用的Q-Former、训练Loss不方便scale up；Blip2仅支持单图输入，不支持多图输入
• Blip3收集超大规模数据集，并且用相对简单的训练方式，实现多图、文本的交互。
• 开放两个数据集：BLIP3-OCR-200M（大规模OCR标注数据集）,BLIP3-GROUNDING-50M（大规模visual grounding数据集）

具体细节

模型结构

整体结构非常简单

• 图像经过ViT得到patch embedding，再经过token sampler得到vision token。（先经过Token Sampler，得到视觉embedding，而后经过VL connector，得到vision token）
• 文本通过tokenizer获得text token
• 文本、图像输入均送到LLM中，并且仅对本文加next prediction loss
• 注意：ViT参数冻结，其他参数可训练
• 注意：支持图像和文本交替输入，支持多图，任意分辨率图像
• ViT：所用模型有DFN、SigLIP，在不同任务上，效果不同，如下：
  
• LLM：所用模型为phi3-mini
• 模型结构代码见https://github.com/salesforce/LAVIS/blob/xgen-mm/open_flamingo/src/factory.py
• token Sampler代码见https://github.com/salesforce/LAVIS/blob/xgen-mm/open_flamingo/src/vlm.py
• VL connector代码见https://github.com/salesforce/LAVIS/blob/xgen-mm/open_flamingo/src/helpers.py

Token Sampler

详见博客https://blog.csdn.net/weixin_40779727/article/details/142019977，就不赘述了

VL Connector

整体结构如下：

class PerceiverAttention(nn.Module):def __init__(self, *, dim, dim_head=64, heads=8):super().__init__()self.scale = dim_head**-0.5self.heads = headsinner_dim = dim_head * headsself.norm_media = nn.LayerNorm(dim)self.norm_latents = nn.LayerNorm(dim)self.to_q = nn.Linear(dim, inner_dim, bias=False)self.to_kv = nn.Linear(dim, inner_dim * 2, bias=False)self.to_out = nn.Linear(inner_dim, dim, bias=False)def forward(self, x, latents, vision_attn_masks=None):"""Args:x (torch.Tensor): image featuresshape (b, T, n1, D)latent (torch.Tensor): latent featuresshape (b, T, n2, D)"""x = self.norm_media(x)latents = self.norm_latents(latents)h = self.headsq = self.to_q(latents)kv_input = torch.cat((x, latents), dim=-2) # TODO: Change the shape of vision attention mask according to this.if vision_attn_masks is not None:vision_attn_masks = torch.cat((vision_attn_masks, torch.ones((latents.shape[0], latents.shape[-2]), dtype=latents.dtype, device=latents.device)),dim=-1)k, v = self.to_kv(kv_input).chunk(2, dim=-1)q, k, v = rearrange_many((q, k, v), "b t n (h d) -> b h t n d", h=h)q = q * self.scale# attentionsim = einsum("... i d, ... j d  -> ... i j", q, k)# Apply vision attention mask here.# Reference: https://pytorch.org/docs/stable/generated/torch.nn.functional.scaled_dot_product_attention.html#torch.nn.functional.scaled_dot_product_attentionif vision_attn_masks is not None:attn_bias = torch.zeros((q.size(0), 1, 1, q.size(-2), k.size(-2)), dtype=q.dtype, device=q.device)vision_attn_masks = repeat(vision_attn_masks, 'b n -> b 1 1 l n', l=q.size(-2))attn_bias.masked_fill_(vision_attn_masks.logical_not(), float("-inf"))sim += attn_biassim = sim - sim.amax(dim=-1, keepdim=True).detach()attn = sim.softmax(dim=-1)out = einsum("... i j, ... j d -> ... i d", attn, v)out = rearrange(out, "b h t n d -> b t n (h d)", h=h)return self.to_out(out)class PerceiverResampler(VisionTokenizer):def __init__(self,*,dim,dim_inner=None,depth=6,dim_head=96,heads=16,num_latents=128,max_num_media=None,max_num_frames=None,ff_mult=4,):"""Perceiver module which takes in image features and outputs image tokens.Args:dim (int): dimension of the incoming image featuresdim_inner (int, optional): final dimension to project the incoming image features to;also the final dimension of the outputted features. If None, no projection is used, and dim_inner = dim.depth (int, optional): number of layers. Defaults to 6.dim_head (int, optional): dimension of each head. Defaults to 64.heads (int, optional): number of heads. Defaults to 8.num_latents (int, optional): number of latent tokens to use in the Perceiver;also corresponds to number of tokens per sequence to output. Defaults to 64.max_num_media (int, optional): maximum number of media per sequence to input into the Perceiverand keep positional embeddings for. If None, no positional embeddings are used.max_num_frames (int, optional): maximum number of frames to input into the Perceiverand keep positional embeddings for. If None, no positional embeddings are used.ff_mult (int, optional): dimension multiplier for the feedforward network. Defaults to 4."""if dim_inner is not None:projection = nn.Linear(dim, dim_inner)else:projection = Nonedim_inner = dimsuper().__init__(dim_media=dim, num_tokens_per_media=num_latents)self.projection = projectionself.latents = nn.Parameter(torch.randn(num_latents, dim))# positional embeddingsself.frame_embs = (nn.Parameter(torch.randn(max_num_frames, dim))if exists(max_num_frames)else None)self.media_time_embs = (nn.Parameter(torch.randn(max_num_media, 1, dim))if exists(max_num_media)else None)self.layers = nn.ModuleList([])for _ in range(depth):self.layers.append(nn.ModuleList([PerceiverAttention(dim=dim, dim_head=dim_head, heads=heads),FeedForward(dim=dim, mult=ff_mult),]))self.norm = nn.LayerNorm(dim)def forward(self, x, vision_attn_masks):"""Args:x (torch.Tensor): image featuresshape (b, T, F, v, D)vision_attn_masks (torch.Tensor): attention masks for padded visiont tokens (i.e., x)shape (b, v)Returns:shape (b, T, n, D) where n is self.num_latents"""b, T, F, v = x.shape[:4]# frame and media time embeddingsif exists(self.frame_embs):frame_embs = repeat(self.frame_embs[:F], "F d -> b T F v d", b=b, T=T, v=v)x = x + frame_embsx = rearrange(x, "b T F v d -> b T (F v) d")  # flatten the frame and spatial dimensionsif exists(self.media_time_embs):x = x + self.media_time_embs[:T]# blockslatents = self.latentslatents = repeat(latents, "n d -> b T n d", b=b, T=T)for attn, ff in self.layers:latents = attn(x, latents, vision_attn_masks) + latentslatents = ff(latents) + latentsif exists(self.projection):return self.projection(self.norm(latents)) else:return self.norm(latents)

训练及数据

预训练

• 训练数据：
  
  用了0.1T token的多模态数据训练，和一些知名的MLLM相比，例如Qwen2VL 0.6T，还是不太够
• 训练方式：针对文本的next token prediction方式训练，图像输入为384x384

有监督微调（SFT）

• 训练数据：从不同领域（multi-modal conversation、 image captioning、chart/document understanding、science、math），收集一堆开源数据。从中采样1百万，包括图文指令+文本指令数据。
  训练1epoch
• 训练方式：针对文本的next token prediction方式训练

交互式多图有监督微调（Interleaved Multi-Image Supervised Fine-tuning）

• 训练数据：首先，收集多图指令微调数据（MANTIS和Mmdu）。为避免模型过拟合到多图数据，选择上一阶段的单图指令微调数据子集，与收集的多图指令微调数据合并，构成新的训练集合。
• 训练方式：针对文本的next token prediction方式训练

后训练（Post-training）

DPO提升Truthfulness

part1

• 训练数据：利用开源的VLFeedback数据集。VLFeedback数据集构造方式：输入指令，让多个VLM模型做生成，随后GPT4-v从helpfulness, visual faithfulness, ethics三个维度对生成结果打分。分值高的输出作为preferred responses，分值低的输出作为dispreferred responses。BLIP3进一步过滤掉一部分样本，最终得到62.6K数据。
• 训练方式：DPO为训练目标，用LoRA微调LLM 2.5%参数，总共训练1 epoch

part2

• 训练数据：根据该工作，生成一组额外responses。该responses能够捕捉LLM的内在幻觉，作为额外dispreferred responses，采用DPO训练。
• 训练方式：同part1，再次训练1 epoch

Safety微调（Safety Fine-tuning）提升Harmlessness

• 训练数据：用2k的VLGua数据集+随机5K SFT数据集。VLGuard包括两个部分：
  这段话可以翻译为：
  (1) 恶心图配上安全指示及安全回应
  (2) 安全图配上安全回应及不安全回应
• 训练方式：用上述7k数据，训练目标为next token prediction，用LoRA微调LLM 2.5%参数，总共训练1 epoch

实验效果

预训练

对比类似于预训练任务的VQA、Captioning任务，效果在使用小参数量LLM的MLLM里，效果不错。

有监督微调（SFT）

交互式多图有监督微调（Interleaved Multi-Image Supervised Fine-tuning）

后训练（Post-training）

消融实验

预训练

预训练数据量

预训练数据配比

视觉backbone

有监督微调（SFT）

视觉Token Sampler对比

base resolution：直接把图片resize到目标大小
anyres-fixed-sampling (ntok=128)：把所有图像patch的表征concat起来，经过perceiver resampler，得到128个vision token
anyres-fixed-sampling (ntok=256)：把所有图像patch的表征concat起来，经过perceiver resampler，得到256个vision token
anyres-patch-sampling：本文采用的方法

Instruction-Aware Vision Token Sampling.

XGen-MM：输入图像，获取vision token
XGen-MM（instruction-aware）：同时输入图像+指令，获取vision token

Quality of the Text-only Instruction Data.

仅利用文本指令数据，训练SFT模型，对比效果

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https://blog.csdn.net/weixin_40779727/article/details/142019977