pair-preference-model-LLaMA3-8B-GGUF

This is quantized version of RLHFlow/pair-preference-model-LLaMA3-8B created using llama.cpp

Model Description

This preference model is trained from LLaMA3-8B-it with the training script at Reward Modeling.

The dataset is RLHFlow/pair_preference_model_dataset. It achieves Chat-98.6, Char-hard 65.8, Safety 89.6, and reasoning 94.9 in reward bench.

See our paper RLHF Workflow: From Reward Modeling to Online RLHF for more details of this model.

Service the RM

Here is an example to use the Preference Model to rank a pair. For n>2 responses, it is recommened to use the tournament style ranking strategy to get the best response so that the complexity is linear in n.

device = 0

model = AutoModelForCausalLM.from_pretrained(script_args.preference_name_or_path,
                                             torch_dtype=torch.bfloat16, attn_implementation="flash_attention_2").cuda()
tokenizer = AutoTokenizer.from_pretrained(script_args.preference_name_or_path, use_fast=True)
tokenizer_plain = AutoTokenizer.from_pretrained(script_args.preference_name_or_path, use_fast=True)
tokenizer_plain.chat_template = "\n{% for message in messages %}{% if loop.index0 % 2 == 0 %}\n\n<turn> user\n {{ message['content'] }}{% else %}\n\n<turn> assistant\n {{ message['content'] }}{% endif %}{% endfor %}\n\n\n"

prompt_template = "[CONTEXT] {context} [RESPONSE A] {response_A} [RESPONSE B] {response_B} \n"
token_id_A = tokenizer.encode("A", add_special_tokens=False)
token_id_B = tokenizer.encode("B", add_special_tokens=False)
assert len(token_id_A) == 1 and len(token_id_B) == 1
token_id_A = token_id_A[0]
token_id_B = token_id_B[0]
temperature = 1.0


model.eval()
response_chosen = "BBBB"
response_rejected = "CCCC"

## We can also handle multi-turn conversation.
instruction = [{"role": "user", "content": ...},
{"role": "assistant", "content": ...},
{"role": "user", "content": ...},
]
context = tokenizer_plain.apply_chat_template(instruction, tokenize=False)
responses = [response_chosen, response_rejected]
probs_chosen = []
    
for chosen_position in [0, 1]:
    # we swap order to mitigate position bias
    response_A = responses[chosen_position]
    response_B = responses[1 - chosen_position]
    prompt = prompt_template.format(context=context, response_A=response_A, response_B=response_B)
    message = [
        {"role": "user", "content": prompt},
    ]

    input_ids = tokenizer.encode(tokenizer.apply_chat_template(message, tokenize=False).replace(tokenizer.bos_token, ""), return_tensors='pt', add_special_tokens=False).cuda() 

    with torch.no_grad():
        output = model(input_ids)
    logit_A = output.logits[0, -1, token_id_A].item()
    logit_B = output.logits[0, -1, token_id_B].item()
    # take softmax to get the probability; using numpy
    Z = np.exp(logit_A / temperature) + np.exp(logit_B / temperature)
    logit_chosen = [logit_A, logit_B][chosen_position]
    prob_chosen = np.exp(logit_chosen / temperature) / Z
    probs_chosen.append(prob_chosen)

avg_prob_chosen = np.mean(probs_chosen)
correct = 0.5 if avg_prob_chosen == 0.5 else float(avg_prob_chosen > 0.5)
print(correct)