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metadata
license: bigscience-bloom-rail-1.0
datasets:
  - cmarkea/mmarco-contrastive
language:
  - fr
  - en
pipeline_tag: feature-extraction
base_model:
  - cmarkea/bloomz-3b-dpo-chat

Bloomz-3b-retriever-v2

Presentation

We introduce the Bloomz-3b-retriever-v2 model, based on the Bloomz-3b-dpo-chat model. This bi-encoder projects articles and queries into the same vector space, ensuring the proximity of queries to related articles. The model is language-agnostic for French and English, meaning a query in either language will be close to an article regardless of whether it is in French or English. This model is ideal for Open Domain Question Answering (ODQA) and can be complemented by the rerankers Bloomz-560m-reranking or Bloomz-3b-reranking.

Training

The training dataset used is a variant of mMARCO enabling contrastive learning and filtering out false negatives. The filtering threshold was set at 0.8, and a positive observation is confronted with 10 hard negatives, ordered by decreasing score (the 10 hardest). The model was trained on a uniform distribution of languages (1/4 French-French, 1/4 French-English, 1/4 English-French, 1/4 English-English). The learning objective is of the InfoNCE type with a trainable temperature parameter as presented for the CLIP model.

Note

Unlike the Bloomz-3b-retriever, this much more efficient model uses cosine distance as its metric (instead of L2 distance as previously).

Benchmark

The performance evaluation is based on the evaluation portion of SQuAD (5921 queries over 1204 articles across 35 different topics). One interesting aspect of this dataset is having multiple articles associated with a single theme, representing challenging contexts where a query may be close to several relevant articles. On average, there are about thirty articles per theme (see Bloomz-3b-reranking for the exact distribution).

We compare the performances using the average top rank of the articles targeted by a query (Top-mean), the standard deviation of the top ranks (Top-std), the percentage of correct articles within Top-1, Top-5, and Top-10, and finally, the mean reciprocal rank (MRR) across the 1204 articles.

Model (FR/FR) Top-mean Top-std Top-1 (%) Top-5 (%) Top-10 (%) MRR (%)
BM25 16.8 100.8 71.7 88.3 91.8 79.2
CamemBERT 269.6 303.0 5.6 12.5 16.5 9.7
STS-CamemBERT 23.1 85.5 36.0 63.0 74.0 48.5
Sentence-BERT 10.2 40.1 43.9 73.9 84.0 57.3
E5-base 6.1 29.7 59.9 84.9 91.0 71.1
E5-large 5.2 29.2 67.0 89.2 93.7 76.7
Bloomz-560m-retriever 10.2 46.6 51.5 78.1 86.2 63.5
Bloomz-3b-retriever 8.8 36.4 49.2 77.5 86.1 62.0
Bloomz-560m-retriever-v2 4.0 17.1 68.0 89.9 94.4 77.7
Bloomz-3b-retriever-v2 2.8 14.8 76.5 94.4 97.2 84.4
Model (EN/FR) Top-mean Top-std Top-1 (%) Top-5 (%) Top-10 (%) MRR (%)
BM25 280.7 371.8 23.9 37.4 43.3 30.4
CamemBERT 355.0 328.3 0.9 3.7 6.4 3.13
STS-CamemBERT 102.2 196.9 13.1 30.5 40.7 22.1
Sentence-BERT 10.6 41.2 43.3 72.4 82.7 56.5
E5-base 9.9 38.1 49.8 77.2 85.4 62.6
E5-large 5.6 26.9 62.9 86.9 92.5 73.8
Bloomz-560m-retriever 11.0 47.8 48.3 75.7 84.7 60.4
Bloomz-3b-retriever 8.9 37.6 48.8 77.4 86.1 61.6
Bloomz-560m-retriever-v2 4.4 18.9 66.6 89.3 94.1 76.6
Bloomz-3b-retriever-v2 2.7 14.2 75.7 94.5 97.1 83.9

How to Use Bloomz-3b-retriever-v2

With Transformers API:

from typing import Union, List

import numpy as np
import torch
from transformers import AutoTokenizer, AutoModel
from scipy.spatial.distance import cdist

tokenizer = AutoTokenizer.from_pretrained('cmarkea/bloomz-3b-retriever-v2')
model = AutoModel.from_pretrained('cmarkea/bloomz-3b-retriever-v2')

def infer(txt: Union[str, List[str]]):
    tok = tokenizer(txt, padding=True, return_tensors='pt')
    with torch.no_grad():
        embedding = model(**tok)
    # Inportant: take only last token!
    return embedding.get('last_hidden_state')[:,-1,:].numpy()

list_of_contexts: List[str] = [...]
emb_contexts = infer(list_of_contexts)
list_of_queries: List[str] = [...]
emb_queries = infer(list_of_queries)

# Important: take cosine distance!
dist = cdist(emb_queries, emb_contexts, 'cosine')
top_k = lambda x: [
    [list_of_contexts[qq] for qq in ii]
    for ii in dist.argsort(axis=-1)[:,:x]
]

# top 5 nearest contexts for each queries
top_contexts = top_k(5)

With Pipeline API:

import numpy as np
from transformers import pipeline
from scipy.spatial.distance import cdist

retriever = pipeline('feature-extraction', 'cmarkea/bloomz-3b-retriever-v2')

# Inportant: take only last token!
infer = lambda x: [ii[0][-1] for ii in retriever(x)]

list_of_contexts: List[str] = [...]
emb_contexts = np.concatenate(infer(list_of_contexts), axis=0)
list_of_queries: List[str] = [...]
emb_queries = np.concatenate(infer(list_of_queries), axis=0)

# Important: take cosine distance!
dist = cdist(emb_queries, emb_contexts, 'cosine')
top_k = lambda x: [
    [list_of_contexts[qq] for qq in ii]
    for ii in dist.argsort(axis=-1)[:,:x]
]

# top 5 nearest contexts for each queries
top_contexts = top_k(5)

Citation

@online{DeBloomzRetv2,
  AUTHOR = {Cyrile Delestre},
  ORGANIZATION = {Cr{\'e}dit Mutuel Ark{\'e}a},
  URL = {https://huggingface.co/cmarkea/bloomz-3b-retriever-v2},
  YEAR = {2024},
  KEYWORDS = {NLP ; Transformers ; LLM ; Bloomz},
}