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chore: import upstream snapshot with attribution
2026-07-13 13:37:14 +08:00

347 lines
14 KiB
Python

# Copyright (c) 2025 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import json
import numpy as np
import paddle
import paddle.distributed as dist
from tqdm import tqdm
from paddlenlp.transformers import AutoConfig, AutoModel, AutoTokenizer
class Embedding_Evaluation:
def __init__(
self,
model_path,
tokenizer_path,
query_pos_passage_path,
neg_passage_path,
template="{text}",
dimension=1024,
max_src_len=8192,
normalize=True,
dtype=None,
):
# initialize the tokenizer
self.tokenizer = AutoTokenizer.from_pretrained(
tokenizer_path,
padding_side="right",
truncation_side="right",
)
self.config = AutoConfig.from_pretrained(model_path)
self.config.embedding_negatives_cross_device = False
self.dtype = dtype if dtype else self.config.dtype
# Initialize the distributed environment
dist.init_parallel_env()
world_size = dist.get_world_size()
if world_size > 1:
print(f"Running in multi-GPU mode with {world_size} GPUs.")
else:
print("Running in single-GPU or CPU mode.")
# Initialize the embedding model
self.model = AutoModel.from_pretrained(
model_path, config=self.config, dtype=self.dtype, low_cpu_mem_usage=False
)
self.model.eval()
self.query_pos_passage_path = query_pos_passage_path
self.neg_passage_path = neg_passage_path
self.template = template
self.dimension = dimension
self.max_src_len = max_src_len
self.normalize = normalize
def _preprocess(self, texts):
"""Pre-process inputs."""
template_prefix, template_suffix = self.template.split("{text}")
prefix_tokens = self.tokenizer(template_prefix, add_special_tokens=False).input_ids
suffix_tokens = self.tokenizer(template_suffix, add_special_tokens=False).input_ids
# If the template does not contain a suffix token, add the EOS token
if len(suffix_tokens) == 0:
suffix_tokens = [self.tokenizer.eos_token_id]
# If the template does not contain a prefix token, add the BOS token
if len(prefix_tokens) == 0:
prefix_tokens = [self.tokenizer.bos_token_id]
available_len = self.max_src_len - len(prefix_tokens) - len(suffix_tokens)
truncated_token_ids = self._batch_truncate_and_tokenize(texts, available_len)
complete_token_ids = [prefix_tokens + tid + suffix_tokens for tid in truncated_token_ids]
position_ids = [list(range(len(cid))) for cid in complete_token_ids]
max_len = max([len(cid) for cid in complete_token_ids])
embedding_indices = [[idx, len(cid) - 1] for idx, cid in enumerate(complete_token_ids)]
inputs = self.tokenizer.pad(
{
"input_ids": complete_token_ids,
"position_ids": position_ids,
"embedding_indices": embedding_indices,
},
padding="max_length",
return_attention_mask=True,
max_length=max_len,
return_tensors="pd",
)
return inputs
def _batch_truncate_and_tokenize(self, texts, available_len):
"""Tokenize the batch of texts."""
batch_tokenized = self.tokenizer(
texts, add_special_tokens=False, padding=False, truncation=True, max_length=available_len
)
truncated_token_ids = [token_ids for token_ids in batch_tokenized["input_ids"]]
return truncated_token_ids
def _forward(self, inputs, dimension):
"""Run model forward."""
input_type = type(inputs["input_ids"])
outputs = self.model(**inputs)
if isinstance(outputs, input_type):
hidden_states = outputs
else:
hidden_states = outputs[0]
last_hidden_state = hidden_states[:, 0]
if dimension > self.config.hidden_size:
raise ValueError(
f"Dimension ({dimension}) cannot be greater than hidden_size ({self.config.hidden_size})."
)
elif dimension != self.config.hidden_size:
last_hidden_state = last_hidden_state[:, :dimension]
if self.normalize:
last_hidden_state = paddle.nn.functional.normalize(last_hidden_state, axis=-1)
last_hidden_state = last_hidden_state.astype("float16").tolist()
return last_hidden_state
@paddle.no_grad()
def get_embedding(self, texts, dimension=None):
"""Get inference sequence."""
if dimension is None:
dimension = self.dimension
inputs = self._preprocess(texts)
if self.config.model_type in ["xlm-roberta"]:
del inputs["embedding_indices"]
del inputs["position_ids"]
outputs = self._forward(inputs, dimension)
return outputs
def evaluate(self):
query_data_list = []
pos_passage_data_list = []
with open(self.query_pos_passage_path, "r") as f:
for line in f:
single_data = json.loads(line)
query_data_list.append(single_data["query"])
pos_passage_data_list.append(single_data["pos_passage"][0])
neg_passage_data_list = []
with open(self.neg_passage_path, "r") as f:
for line in f:
single_data = json.loads(line)
neg_passage_data_list.append(single_data["neg_passage"][0])
passage_data_list = pos_passage_data_list + neg_passage_data_list
world_size = paddle.distributed.get_world_size()
rank = paddle.distributed.get_rank()
query_chunk_size = len(query_data_list) // world_size
passage_chunk_size = len(passage_data_list) // world_size
if rank == world_size - 1:
# The last process handles the remaining data
query_data_chunk = query_data_list[rank * query_chunk_size :]
passage_data_chunk = passage_data_list[rank * passage_chunk_size :]
else:
query_data_chunk = query_data_list[rank * query_chunk_size : (rank + 1) * query_chunk_size]
passage_data_chunk = passage_data_list[rank * passage_chunk_size : (rank + 1) * passage_chunk_size]
batch_size = 4 # Adjust batch size according to your hardware and needs
local_p_vecs = []
local_q_vecs = []
# Use tqdm to iterate over query_data_chunk and get embeddings in batches
for batch in tqdm(range(0, len(passage_data_chunk), batch_size), desc="Processing passage embeddings"):
batch_start = batch
batch_end = min(batch_start + batch_size, len(passage_data_chunk))
batch_texts = passage_data_chunk[batch_start:batch_end]
# Call get_embedding to obtain embeddings for the current batch
batch_embeddings = self.get_embedding(batch_texts)
local_p_vecs.extend(batch_embeddings)
for batch in tqdm(range(0, len(query_data_chunk), batch_size), desc="Processing query embeddings"):
batch_start = batch
batch_end = min(batch_start + batch_size, len(query_data_chunk))
batch_texts = query_data_chunk[batch_start:batch_end]
batch_embeddings = self.get_embedding(batch_texts)
local_q_vecs.extend(batch_embeddings)
local_p_vecs_file = f"local_p_vecs_rank_{rank}.npy"
local_q_vecs_file = f"local_q_vecs_rank_{rank}.npy"
np.save(local_p_vecs_file, local_p_vecs)
np.save(local_q_vecs_file, local_q_vecs)
dist.barrier() # Ensure all cards have reached this point before continuing
if rank == 0:
all_p_vecs_list = []
all_q_vecs_list = []
world_size = paddle.distributed.get_world_size()
for i in range(world_size):
local_p_vecs_file = f"local_p_vecs_rank_{i}.npy"
local_q_vecs_file = f"local_q_vecs_rank_{i}.npy"
# Load the embedding vector file from each process
local_p_vecs = np.load(local_p_vecs_file)
local_q_vecs = np.load(local_q_vecs_file)
all_p_vecs_list.append(local_p_vecs)
all_q_vecs_list.append(local_q_vecs)
all_q_vecs = []
for q_vecs in all_q_vecs_list:
all_q_vecs.extend(q_vecs)
q_vecs = np.asarray(all_q_vecs, dtype=np.float32)
all_p_vecs = []
for p_vecs in all_p_vecs_list:
all_p_vecs.extend(p_vecs)
p_vecs = np.asarray(all_p_vecs, dtype=np.float32)
query_embedding_tensor = paddle.to_tensor(q_vecs, dtype=self.dtype)
passage_embedding_tensor = paddle.to_tensor(p_vecs, dtype=self.dtype)
similarity_matrix = self.calculate_cosine_similarity_matrix(
query_embedding_tensor, passage_embedding_tensor
)
query_num = len(query_data_list)
true_answers = [i for i in range(query_num)]
hit_count_10, hit_coun_5, hit_count_3, hit_count_1 = 0, 0, 0, 0
reciprocal_rank_sum_10, reciprocal_rank_sum_5, reciprocal_rank_sum_3 = 0, 0, 0
ndcg_10, ndcg_5, ndcg_3 = 0.0, 0.0, 0.0
for i in range(query_num):
similarities = similarity_matrix[i]
# get the sorted indices
sorted_indices = paddle.argsort(-similarities)
# find the index of the true answer
true_answer_index = true_answers[i]
rank = paddle.where(sorted_indices == true_answer_index)[0][0] + 1 # rank starts from 1
if rank <= 10:
hit_count_10 += 1
reciprocal_rank_sum_10 += 1.0 / rank
if rank <= 5:
hit_coun_5 += 1
reciprocal_rank_sum_5 += 1.0 / rank
if rank <= 3:
hit_count_3 += 1
reciprocal_rank_sum_3 += 1.0 / rank
if rank <= 1:
hit_count_1 += 1
relevance_scores = [0] * 10
if rank <= 10:
relevance_scores[rank - 1] = 1
ndcg_10 += self.calculate_ndcg(relevance_scores[:10], k=10)
ndcg_5 += self.calculate_ndcg(relevance_scores[:5], k=5)
ndcg_3 += self.calculate_ndcg(relevance_scores[:3], k=3)
print(f"Hit rate when recall Top 10: ({hit_count_10*100./query_num:.2f}%)\n")
print(f"Hit rate when recall Top 5: ({hit_coun_5*100./query_num:.2f}%)\n")
print(f"Hit rate when recall Top 3: ({hit_count_3*100./query_num:.2f}%)\n")
print(f"Hit rate when recall Top 1: ({hit_count_1*100./query_num:.2f}%)\n")
print(f"MRR when recall Top 10: ({reciprocal_rank_sum_10.item() / query_num:.4f})\n")
print(f"MRR when recall Top 5: ({reciprocal_rank_sum_5.item() / query_num:.4f})\n")
print(f"MRR when recall Top 3: ({reciprocal_rank_sum_3.item() / query_num:.4f})\n")
print(f"NDCG@10: ({ndcg_10/ query_num:.4f})\n")
print(f"NDCG@5: ({ndcg_5/ query_num:.4f})\n")
print(f"NDCG@3: ({ndcg_3/ query_num:.4f})\n")
eval_result_dict = {
"hit_rate@10": hit_count_10 / query_num,
"hit_rate@5": hit_coun_5 / query_num,
"hit_rate@3": hit_count_3 / query_num,
"hit_rate@1": hit_count_1 / query_num,
"mrr@10": reciprocal_rank_sum_10.item() / query_num,
"mrr@5": reciprocal_rank_sum_5.item() / query_num,
"mrr@3": reciprocal_rank_sum_3.item() / query_num,
"ndcg@10": ndcg_10 / query_num,
"ndcg@5": ndcg_5 / query_num,
"ndcg@3": ndcg_3 / query_num,
}
return eval_result_dict
def calculate_cosine_similarity_matrix(self, query_matrix, answer_matrix):
"""Calculate the cosine similarity between two matrices by processing query vectors one by one."""
num_queries = query_matrix.shape[0]
num_answers = answer_matrix.shape[0]
# Precompute the norms of answer vectors to save computation
answer_norms = paddle.linalg.norm(answer_matrix, axis=1, keepdim=True)
# Initialize the similarity matrix with zeros
similarity_matrix = paddle.zeros((num_queries, num_answers))
# Process each query vector one by one
for i in tqdm(range(num_queries)):
query_vector = query_matrix[i : i + 1] # Extract the i-th query vector
# Calculate the norm of the query vector
query_norm = paddle.linalg.norm(query_vector, axis=1, keepdim=True)
# Calculate the dot product between the query vector and all answer vectors
dot_product = paddle.matmul(query_vector, answer_matrix, transpose_y=True)
# Calculate the cosine similarity for the i-th query vector
similarity_vector = dot_product / (query_norm * answer_norms.transpose((1, 0)))
# Update the similarity matrix with the computed similarity vector
similarity_matrix[i] = similarity_vector
return similarity_matrix
def calculate_ndcg(self, relevance_scores, k):
"""Calculate NDCG@k for a given set of relevance scores"""
# Calculate DCG
dcg = sum((rel) / np.log2(i + 2) for i, rel in enumerate(relevance_scores[:k]))
# Calculate IDCG (Ideal DCG)
ideal_relevance_scores = sorted(relevance_scores, reverse=True)
idcg = sum((rel) / np.log2(i + 2) for i, rel in enumerate(ideal_relevance_scores[:k]))
# Avoid division by zero
if idcg == 0:
return 0.0
# Calculate NDCG
ndcg = dcg / idcg
return ndcg
if __name__ == "__main__":
model_path = "BAAI/bge-m3"
tokenizer_path = "BAAI/bge-m3"
query_pos_passage_path = "./toy_data/toy_dev.json"
neg_passage_path = "./toy_data/toy_dev_neg.json"
eval = Embedding_Evaluation(model_path, tokenizer_path, query_pos_passage_path, neg_passage_path)
print(eval.evaluate())