K2-Chat: a fully-reproducible large language model outperforming Llama 2 70B Chat using 35% less compute

K2 Chat is finetuned from K2-65B. The most recent model update is 10/31/24.

In this release, we introduce function calling features and target improvements across math, coding, and safety.

We utilized the following datasets:

Results

K2-Chat-060124 K2-Chat
Natural Language Benchmarks
MMLU (0-shot) 63.5 69.14
RACE (0-shot) 46.1 46.60
HellaSwag (10-shot) 81.7 80.80
PIQA (5-shot) 82.3 81.34
ARC-easy (5-shot) 84.6 79.00
ARC-challenge (25-shot) 61.3 61.09
OpenBookQA (5-shot) 48.0 47.00
Winogrande (5-shot) 79.5 78.30
TruthfulQA (0-shot) 44.7 57.32
CrowS-Pairs (0-shot) 64.2 65.32
GSM8K (5-shot) 60.7 77.10
MathQA (5-shot) 44.8 43.12
LogiQA2.0 (0-shot) 38.0 36.83
BBH CoT (0-shot) 64.9 70.37
Code Benchmarks
HumanEval (pass@1) 47.9 71.20
Domain Specific (Medical)
MedQA (0-shot) 53.6 52.87
MedMCQA (5-shot) 51.3 50.71
PubMedQA (0-shot) 75.0 71.20
Other
MT-Bench 6.87 7.55
JSON-Mode-Eval 77.21 90.09
Overall Average Score
Avg Score 58.88 61.30

Safety

We developed a comprehensive safety prompt collection procedure that includes eight attack types and over 120 specific safety value categories. Our risk taxonomy is adapted from Wang et al. (2023), which originally defines six main types and 60 specific categories of harmful content. We have expanded this taxonomy to encompass more region-specific types, sensitive topics, and cybersecurity- related issues, ensuring a more nuanced and robust coverage of potential risks. This extended taxonomy allows us to address a wider variety of harmful behaviors and content that may be culturally or contextually specific, thus enhancing the model’s safety alignment across diverse scenarios.

Category K2-Chat-060124 K2-Chat
DoNotAnswer 67.94 87.65
Advbench 52.12 81.73
I_cona 67.98 79.21
I_controversial 47.50 70.00
I_malicious_instructions 60.00 83.00
I_physical_safety_unsafe 44.00 68.00
I_physical_safety_safe 96.00 97.00
Harmbench 20.50 63.50
Spmisconception 40.98 76.23
MITRE 3.20 57.30
PromptInjection 54.58 56.57
Attack_multilingual_overload 74.67 89.00
Attack_persona_modulation 51.67 85.67
Attack_refusal_suppression 56.00 93.00
Attack_do_anything_now 48.00 91.33
Attack_conversation_completion 56.33 71.00
Attack_wrapped_in_shell 34.00 67.00
Average 51.50 77.48

Function Calling

Chat Template

Our model reuses K2-Chat as the prompt format and is specifically trained for function calling. Different system prompts enable different ways to interact with this model. Note that the two modes are currently mainly tested individually, designing prompts that make them work togehter is possible but currently untested. It should be also possible to stimulate the model to produce function call behavior by injecting special token <tool_call> and expect the model to finish it. In this guide we mention the intended basic usage of the model.

Conversational Chats

Here is an example prompt with system instruction (Use whatever system prompt you like, this is just an example):

Your name is K2, and you are named after K2, the second highest mountain on Earth. You are built by MBZUAI and LLM360. You are a highly advanced large language model with 65B parameters. You outperform all fully open source models and Llama 2 70B. You can answer in English only. You are a helpful, respectful and honest assistant.<|endofsystemprompt|><|beginofuser|>Hello, who are you?<|beginofsystem|>

Sample inference code

from transformers import AutoModelForCausalLM, AutoTokenizer

tokenizer = AutoTokenizer.from_pretrained("<path_to_model_weights>")
model = AutoModelForCausalLM.from_pretrained("<path_to_model_weights>")
  

prompt = 'Your name is K2, and you are named after K2, the second highest mountain on Earth. You are built by MBZUAI and LLM360. You are a highly advanced large language model with 65B parameters. You outperform all fully open source models and Llama 2 70B. You can answer in English only. You are a helpful, respectful and honest assistant.<|endofsystemprompt|><|beginofuser|>Hello, who are you?<|beginofsystem|>'

input_ids = tokenizer(prompt, return_tensors="pt").input_ids
gen_tokens = model.generate(input_ids, do_sample=True, max_new_tokens=128)
print("-"*20 + "Output for model"  + 20 * '-')
print(tokenizer.batch_decode(gen_tokens)[0])

Multi-turn conversations should be formatted like this:

{system_prompt}<|endofsystemprompt|><|beginofuser|>{user_content_1}<|beginofsystem|>{system_content_1}<|beginofuser|>{user_content_2}<|beginofsystem|>{system_content_2}<|beginofuser|>{user_content_3}<|beginofsystem|>

Function Calling Format

For function calling, please use this system prompt:

You are a function calling AI model. You are provided with function signatures within <tools></tools> XML tags. You may call one or more functions to assist with the user query. Don't make assumptions about what values to plug into functions. Here are the available tools:

Next, use whatever tools you like, this is just an example:

<tools>
{ "name": "get_news_headlines", "description": "Get the latest news headlines", "parameters": {"type": "object", "properties": { "country": { "type": "string", "description": "The country for which to fetch news"}}, "required": [ "country"]}}
</tools>

Next, add additional instruction:

Use the following pydantic model json schema for each tool call you will make:
{"properties": {"arguments": {"title": "Arguments", "type": "object"}, "name": {"title": "Name", "type": "string"}}, "required": ["arguments", "name"], "title": "FunctionCall", "type": "object"}
For each function call return a json object with function name and arguments within <tool_call></tool_call> XML tags as follows:
<tool_call>
{"arguments": <args-dict>, "name": <function-name>}
</tool_call>
Please also summarize texts wrapped between <tool_response> and </tool_response> in bullet points. For example:
<tool_response>
{"fruits": [{"name": "Apple"}, {"name": "Pear"}]}
</tool_response> is summarized as:
Fruits:
- Apple
- Pear
<|endofsystemprompt|>

The following is the model initial prompt:

You are a function calling AI model. You are provided with function signatures within <tools></tools> XML tags. You may call one or more functions to assist with the user query. Don't make assumptions about what values to plug into functions. Here are the available tools:
<tools>
{ "name": "get_news_headlines", "description": "Get the latest news headlines", "parameters": {"type": "object", "properties": { "country": { "type": "string", "description": "The country for which to fetch news"}}, "required": [ "country"]}}
</tools>
Use the following pydantic model json schema for each tool call you will make:
{"properties": {"arguments": {"title": "Arguments", "type": "object"}, "name": {"title": "Name", "type": "string"}}, "required": ["arguments", "name"], "title": "FunctionCall", "type": "object"}
For each function call return a json object with function name and arguments within <tool_call></tool_call> XML tags as follows:
<tool_call>
{"arguments": <args-dict>, "name": <function-name>}
</tool_call>
Please also summarize texts wrapped between <tool_response> and </tool_response> in bullet points. For example:
<tool_response>
{"fruits": [{"name": "Apple"}, {"name": "Pear"}]}
</tool_response> is summarized as:
Fruits:
- Apple
- Pear
<|endofsystemprompt|>

Example flow for generation with multi-turn and how to incoporate function call output

When users ask a question, the following user query will be concatenated with the prompt (see example inference code below too) <|beginofuser|>Can you tell me the latest news headlines for the United States?<|beginofsystem|>

When run it, you will get a tool call response wrapped in the <tool_call> tag:

In this turn, the model should respond with:

<tool_call>
  [{"name": "get_news_headlines", "arguments": {"country": "United States"}}]
</tool_call><endoftext>

Now you should execute this tool call with the external tool, you will get responses from that tool. The model can interpret the tool response as natural language again. To achieve this, simply wrap it with <tool_response> and </tool_response> and append it to the history and ask the model to generate further:

...current model history (ends with </tool_call><|endoftext|>)...
<tool_response>
    {"news": [{"title": "A great news headline"}, {"title": "Another great news headline"}]}
</tool_response>

In this second turn, the model should respond with:

Suggested news headline:
- A great news headline
- Another great news headline<endoftext>

Sometimes, there is a use case that only uses the function call feature as a JSON formatter without calling any external functions, which means the output in tool_call is essentially what you want. In that case, we recommend simply make a copy of the content of <tool_call> and wrap that in <tool_response>.

Sample inference code

from transformers import AutoModelForCausalLM, AutoTokenizer

tokenizer = AutoTokenizer.from_pretrained("<path_to_model_weights>")
model = AutoModelForCausalLM.from_pretrained("<path_to_model_weights>")

  
prompt = """You are a function calling AI model. You are provided with function signatures within <tools></tools> XML tags. You may call one or more functions to assist with the user query. Don't make assumptions about what values to plug into functions. Here are the available tools:
<tools>
[{"name": "get_news_headlines", "description": "Get the latest news headlines", "parameters": {"type": "object", "properties": {"country": {"type": "string", "description": "The country for which to fetch news"}}, "required": ["country"] }}
</tools>
Use the following pydantic model json schema for each tool call you will make:
{"properties": {"arguments": {"title": "Arguments", "type": "object"}, "name": {"title": "Name", "type": "string"}}, "required": ["arguments", "name"], "title": "FunctionCall", "type": "object"}
For each function call return a json object with function name and arguments within <tool_call></tool_call> XML tags as follows:
<tool_call>
{"arguments": <args-dict>, "name": <function-name>}
</tool_call>
Please also summarize texts wrapped between <tool_response> and </tool_response> in bullet points. For example:
<tool_response>
{"fruits": [{"name": "Apple"}, {"name": "Pear"}]}
</tool_response> is summarized as:
Fruits:
- Apple
- Pear
<|endofsystemprompt|><|beginofuser|>Can you tell me the latest news headlines for the United States?<|beginofsystem|>"""


input_ids = tokenizer(prompt, return_tensors="pt").input_ids
gen_tokens = model.generate(input_ids, do_sample=True, max_new_tokens=128)

print("-"*20 + "Output for model"  + 20 * '-')
print(tokenizer.batch_decode(gen_tokens)[0])

K2-Chat-060124

K2 Chat is finetuned from K2-65B. K2 Chat outperforms Llama 2-70B-Chat on all evaluations conducted. The model also outperforms Llama 3-70B-Instruct on coding tasks.

k2 eval table

LLM360 Model Performance and Evaluation Collection

The LLM360 Performance and Evaluation Collection is a robust evaluations set consisting of general and domain specific evaluations to assess model knowledge and function.

Evaluations include standard best practice benchmarks, medical, math, and coding knowledge. More about the evaluations can be found here.

k2 big eval table

Open LLM Leaderboard

Evaluation Score Raw Score
IFEval 51.52 52
BBH 33.79 54
Math Lvl 5 1.59 2
GPQA 7.49 31
MUSR 16.82 46
MMLU-PRO 26.34 34
Average 22.93 36.5

Datasets and Mix

Subset #Tokens Avg. #Q Avg. Query Len Avg. #R Avg. Reply Len
MathInstruct 66,639,699 1.00 81.53 1.00 172.78
OpenHermes-2 404,820,694 1.01 152.38 1.01 249.12
FLAN_3M 2,346,961,387 1.00 727.49 1.00 54.83
Standford Encyclopedia Philosophy 786,928 1.00 219.09 1.00 166.28
TinyStories 1,448,898 1.00 260.82 1.00 207.47
Safety & Alignment Data 99,976,621 1.00 126.71 1.00 373.79
Total 2,920,634,227

Loading K2-Chat

from transformers import AutoModelForCausalLM, AutoTokenizer

tokenizer = AutoTokenizer.from_pretrained("LLM360/K2-Chat")
model = AutoModelForCausalLM.from_pretrained("LLM360/K2-Chat")

prompt = '<|beginofuser|>what is the highest mountain on earth?<|beginofsystem|>'

input_ids = tokenizer(prompt, return_tensors="pt").input_ids
gen_tokens = model.generate(input_ids, do_sample=True, max_new_tokens=128)

print("-"*20 + "Output for model"  + 20 * '-')
print(tokenizer.batch_decode(gen_tokens)[0])

Alternatively, you can construct the prompt by applying the chat template of tokenizer on input conversation:

from transformers import AutoModelForCausalLM, AutoTokenizer

tokenizer = AutoTokenizer.from_pretrained("LLM360/K2-Chat")
model = AutoModelForCausalLM.from_pretrained("LLM360/K2-Chat")

messages = [{"role": "user", "content": "what is the highest mountain on earth?"}]

input_ids = tokenizer.apply_chat_template(messages, tokenize=True, add_generation_prompt=True, return_tensors="pt")
gen_tokens = model.generate(input_ids, do_sample=True, max_new_tokens=128)

print("-"*20 + "Output for model"  + 20 * '-')
print(tokenizer.batch_decode(gen_tokens)[0])

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Citation

BibTeX:

@article{
      title={LLM360 K2-65B: Scaling Up Fully Transparent Open-Source LLMs}, 
      author={The LLM360 Team},
      year={2024},
}
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