多图理解,更懂中文,支持function call的Phi-3.5来了!

简介: 微软继今年4月推出Phi-3系列小型语言模型后,又一鼓作气三连发布并开源其「小而美」系列 Phi-3.5模型!

引言

微软继今年4月推出Phi-3系列小型语言模型后,又一鼓作气三连发布并开源其「小而美」系列 Phi-3.5模型!

本次发布的三个模型各有特色:

Mini型:Phi-3.5-mini-instruct(3.8B)

Phi-3.5 mini 具有 38 亿个参数,基于Phi-3 的数据集(合成数据和经过筛选的公开网站)构建,重点关注高质量、推理密集的数据。该模型属于 Phi-3 模型系列,支持 128K 令牌上下文长度。该模型经过了严格的增强过程,结合了监督微调、近端策略优化和直接偏好优化,以确保精确遵守指令和强大的安全措施。Phi-3.5 mini 在中文场景有所增强,但是受限于模型的大小,依然会有较多的事实错误,通过RAG的方式可以有效降低错误。

MoE型:Phi-3.5-MoE-instruct  (16x3.8B)

Phi-3.5-MoE-instruct是一个MoE模型,有 16x3.8B 个参数,使用 2 位专家时有 6.6B 个活动参数。该模型使用词汇量为 32,064 的标记器。Phi-3.5-MoE-instruct在推理能力上大大增强(尤其是数学和逻辑),也非常适用于function call的场景。

多模态:Phi-3.5-vision-instruct (4.2B)

Phi-3.5-vision-instruct 多模态版本可支持 128K 上下文长度(以 token 为单位)有 4.2B 参数,主要包含图像编码器和 Phi-3 Mini 语言模型。本次Phi-3.5-vision-instruct 支持多图理解,在如下场景上有较好的效果:

  • 一般图像理解;
  • 光学字符识别 (OCR)
  • 图表和表格理解;
  • 多幅图像比较;
  • 多图像或视频片段摘要

同时魔搭社区已经上线Phi-3.5-mini-instruct-GGUF,可更加方便的使用ollama,llama.cpp,lmstudio等工具运行。

模型链接:

Phi-3.5-mini-instruct:

https://modelscope.cn/models/LLM-Research/Phi-3.5-mini-instruct

Phi-3.5-MoE-instruct:

https://modelscope.cn/models/LLM-Research/Phi-3.5-MoE-instruct

Phi-3.5-vision-instruct :

https://modelscope.cn/models/LLM-Research/Phi-3.5-vision-instruct

Phi-3.5-mini-instruct-GGUF:

https://modelscope.cn/models/LLM-Research/Phi-3.5-mini-instruct-GGUF

cookbook链接:

https://github.com/microsoft/Phi-3CookBook

模型推理

Phi-3.5-mini-instruct

小模型Phi-3.5-mini-instruct在中文能力上有更好的支持。

import torch
from modelscope import AutoModelForCausalLM, AutoTokenizer
from transformers import pipeline
torch.random.manual_seed(0)
model = AutoModelForCausalLM.from_pretrained(
    "LLM-Research/Phi-3.5-mini-instruct", 
    device_map="cuda", 
    torch_dtype="auto", 
    trust_remote_code=True, 
)
tokenizer = AutoTokenizer.from_pretrained("LLM-Research/Phi-3.5-mini-instruct")
messages = "<|system|>\n 你是我的人工智能助手,协助我用中文解答问题.\n<|end|><|user|>\n 你知道长沙吗?? \n<|end|><|assistant|>"
pipe = pipeline(
    "text-generation",
    model=model,
    tokenizer=tokenizer,
)
generation_args = {
    "max_new_tokens": 500,
    "return_full_text": False,
    "temperature": 0.0,
    "do_sample": False,
}
output = pipe(messages, **generation_args)
print(output[0]['generated_text'])

image.png

Phi-3.5-vision-instruct

多模态模型Phi-3.5-vision-instruct支持了多图理解

from PIL import Image 
import requests 
from transformers import AutoModelForCausalLM 
from transformers import AutoProcessor 
from modelscope import snapshot_download
model_id = snapshot_download("LLM-Research/Phi-3.5-vision-instruct")
# Note: set _attn_implementation='eager' if you don't have flash_attn installed
model = AutoModelForCausalLM.from_pretrained(
  model_id, 
  device_map="cuda", 
  trust_remote_code=True, 
  torch_dtype="auto", 
  _attn_implementation='flash_attention_2'    
)
# for best performance, use num_crops=4 for multi-frame, num_crops=16 for single-frame.
processor = AutoProcessor.from_pretrained(model_id, 
  trust_remote_code=True, 
  num_crops=4
) 
images = []
placeholder = ""
# Note: if OOM, you might consider reduce number of frames in this example.
for i in range(1,20):
    url = f"https://modelscope.oss-cn-beijing.aliyuncs.com/resource/Introduction-to-Microsoft-Azure-Cloud-{i}-2048.webp" 
    images.append(Image.open(requests.get(url, stream=True).raw))
    placeholder += f"<|image_{i}|>\n"
messages = [
    {"role": "user", "content": placeholder+"Summarize the deck of slides."},
]
prompt = processor.tokenizer.apply_chat_template(
  messages, 
  tokenize=False, 
  add_generation_prompt=True
)
inputs = processor(prompt, images, return_tensors="pt").to("cuda:0") 
generation_args = { 
    "max_new_tokens": 1000, 
    "temperature": 0.0, 
    "do_sample": False, 
} 
generate_ids = model.generate(**inputs, 
  eos_token_id=processor.tokenizer.eos_token_id, 
  **generation_args
)
# remove input tokens 
generate_ids = generate_ids[:, inputs['input_ids'].shape[1]:]
response = processor.batch_decode(generate_ids, 
  skip_special_tokens=True, 
  clean_up_tokenization_spaces=False)[0] 
print(response)

image.png

Phi-3.5-MoE-instruct

Phi-3.5-MoE-instruct模型推理能力更强,本文演示的为agent场景

import torch
from transformers import AutoModelForCausalLM, AutoTokenizer, pipeline 
from modelscope import snapshot_download
model_dir = snapshot_download("LLM-Research/Phi-3.5-MoE-instruct")
torch.random.manual_seed(0) 
model = AutoModelForCausalLM.from_pretrained( 
    model_dir,  
    device_map="cuda",  
    torch_dtype="auto",  
    trust_remote_code=True,  
) 
tokenizer = AutoTokenizer.from_pretrained(model_dir) 
pipe = pipeline( 
    "text-generation", 
    model=model, 
    tokenizer=tokenizer, 
) 
generation_args = { 
    "max_new_tokens": 500, 
    "return_full_text": False, 
    "temperature": 0.0, 
    "do_sample": False, 
}

设置system message

sys_msg = """You are a helpful AI assistant, you are an agent capable of using a variety of tools to answer a question. Here are a few of the tools available to you:
- Blog: This tool helps you describe a certain knowledge point and content, and finally write it into Twitter or Facebook style content
- Translate: This is a tool that helps you translate into any language, using plain language as required
To use these tools you must always respond in JSON format containing `"tool_name"` and `"input"` key-value pairs. For example, to answer the question, "Build Muliti Agents with MOE models" you must use the calculator tool like so:
```json
{
    "tool_name": "Blog",
    "input": "Build Muliti Agents with MOE models"
}
```
Or to translate the question "can you introduce yourself in Chinese" you must respond:
```json
{
    "tool_name": "Search",
    "input": "can you introduce yourself in Chinese"
}
```
Remember just output the final result, ouput in JSON format containing `"agentid"`,`"tool_name"` , `"input"` and `"output"`  key-value pairs .:
```json
[
{   "agentid": "step1",
    "tool_name": "Blog",
    "input": "Build Muliti Agents with MOE models",
    "output": "........."
},
{   "agentid": "step2",
    "tool_name": "Search",
    "input": "can you introduce yourself in Chinese",
    "output": "........."
},
{
    "agentid": "final"
    "tool_name": "Result,
    "output": "........."
}
]
```
The users answer is as follows.
"""
def instruction_format(sys_message: str, query: str):
    # note, don't "</s>" to the end
    return f'<|system|> {sys_message} <|end|>\n<|user|> {query} <|end|>\n<|assistant|>'
query ='Write something about Generative AI with MOE , translate it to Chinese'
input_prompt = instruction_format(sys_msg, query)
import os
os.environ["PYTORCH_CUDA_ALLOC_CONF"] = "expandable_segments:True "
output = pipe(input_prompt, **generation_args)
output[0]['generated_text']

显存占用:

image.png

Phi-3.5-mini-instruct-GGUF

使用Ollama本地运行Phi-3.5-mini-instruct-GGUF

Linux环境使用

下载GGUF模型:

modelscope download --model=LLM-Research/Phi-3.5-mini-instruct-GGUF --local_dir . Phi-3.5-mini-instruct-Q5_K_M.gguf

Liunx用户可使用魔搭镜像环境安装【推荐】

modelscope download --model=modelscope/ollama-linux --local_dir ./ollama-linux
cd ollama-linux
sudo chmod 777 ./ollama-modelscope-install.sh
./ollama-modelscope-install.sh

启动Ollama服务

ollama serve

创建ModelFile

复制模型路径,创建名为“ModelFile”的meta文件,内容如下:

FROM /mnt/workspace/Phi-3.5-mini-instruct-Q5_K_M.gguf
TEMPLATE """
{{ if .System }}<|system|>
{{ .System }}<|end|>
{{ end }}{{ if .Prompt }}<|user|>
{{ .Prompt }}<|end|>
{{ end }}<|assistant|>
{{ .Response }}<|end|>"""

创建自定义模型

使用ollama create命令创建自定义模型

ollama create myphi3_5 --file ./Modelfile

运行模型

ollama run myphi3_5

显存占用:

image.png

模型微调

我们使用ms-swift对LLM: Phi-3.5-mini-instruct, VLM: Phi-3.5-vision-instruct进行微调。swift是魔搭社区官方提供的大模型与多模态大模型微调推理框架。

ms-swift开源地址:https://github.com/modelscope/ms-swift

环境准备

git clone https://github.com/modelscope/swift.git
cd swift
pip install -e .[llm]
# 可选, 对phi3_5-mini-instruct进行推理加速.
pip install vllm

LLM微调

这里我们使用alpaca-zh, alpaca-en作为示例数据集,展示可运行的demo。

您可以在modelscope上这两个数据集:

  • alpaca-zh:

https://modelscope.cn/datasets/AI-ModelScope/alpaca-gpt4-data-zh

  • alpaca-en:

https://modelscope.cn/datasets/AI-ModelScope/alpaca-gpt4-data-en

自定义数据集参考:https://swift.readthedocs.io/zh-cn/latest/LLM/%E8%87%AA%E5%AE%9A%E4%B9%89%E4%B8%8E%E6%8B%93%E5%B1%95.html

微调脚本:

# 显存占用: 4 * 11GB
# 以下脚本分别采样alpaca-zh, alpaca-en数据集20000条
# 更多超参数含义可以查看文档
CUDA_VISIBLE_DEVICES=0,1,2,3 NPROC_PER_NODE=4 swift sft \
  --model_type phi3_5-mini-instruct \
  --model_id_or_path LLM-Research/Phi-3.5-mini-instruct \
  --sft_type lora \
  --learning_rate 1e-4 \
  --output_dir output \
  --dataset alpaca-zh#20000 alpaca-en#20000 \
  --lora_target_modules ALL \
  --deepspeed default-zero2

微调后推理脚本:

# 推理
CUDA_VISIBLE_DEVICES=0 swift infer \
    --ckpt_dir output/phi3_5-mini-instruct/vx-xxx/checkpoint-xxx \
    --load_dataset_config true
# merge-lora 并使用vllm进行加速
CUDA_VISIBLE_DEVICES=0 swift infer \
    --ckpt_dir output/phi3_5-mini-instruct/vx-xxx/checkpoint-xxx \
    --load_dataset_config true --merge_lora true \
    --infer_backend vllm

VLM微调

这里我们使用coco-en-mini作为示例数据集,该数据集的任务是对图片内容进行描述,展示可运行的demo。

您可以在 modelscope上找到该数据集:https://modelscope.cn/datasets/modelscope/coco_2014_caption/summary

自定义数据集格式如下(单图、多图和无图):

{"query": "<image>55555", "response": "66666", "images": ["image_path"]}
{"query": "eeeee<image>eeeee<image>eeeee", "response": "fffff", "history": [], "images": ["image_path1", "image_path2"]}
{"query": "EEEEE", "response": "FFFFF", "history": [["query1", "response2"], ["query2", "response2"]], "images": []}

微调脚本:

# 显存占用: 4 * 12GB
# 默认会将lora_target_modules设置为llm和projector所有的linear
CUDA_VISIBLE_DEVICES=0,1,2,3 NPROC_PER_NODE=4 swift sft \
  --model_type phi3_5-vision-instruct \
  --model_id_or_path LLM-Research/Phi-3.5-vision-instruct \
  --sft_type lora \
  --dataset coco-en-mini#20000 \
  --deepspeed default-zero2

如果要使用自定义数据集,只需按以下方式进行指定:

--dataset train.jsonl \
  --val_dataset val.jsonl \

显存占用:

image.png

训练loss图(时间原因,只训练了450个step):

image.png

微调后推理脚本如下:

# 推理
CUDA_VISIBLE_DEVICES=0 swift infer \
    --ckpt_dir output/phi3_5-vision-instruct/vx-xxx/checkpoint-xxx \
    --load_dataset_config true
# merge-lora并推理
CUDA_VISIBLE_DEVICES=0 swift infer \
    --ckpt_dir output/phi3_5-vision-instruct/vx-xxx/checkpoint-xxx \
    --load_dataset_config true --merge_lora true \
    --safe_serialization false

微调后模型对验证集进行推理的示例:

image.png

点击链接👇跳转Phi-3.5模型合集页~

https://www.modelscope.cn/models?name=Phi-3.5&page=1?from=alizishequ__text

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