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[Feature] Upgrade the needle-in-a-haystack experiment to Needlebench (#913)

Browse Source 
* add needlebench

* simplify needlebench 32k, 128k, 200k for eval

* update act prompt

* fix bug in needlebench summarizer

* add needlebench intro, fix summarizer

* lint summarizer

* fix linting error

* move readme.md

* update readme for needlebench

* update docs of needlebench

* simplify needlebench summarizers
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40 changed files with 5055 additions and 729 deletions
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111
configs/datasets/cdme/cdme200k.py
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.cdme.cdme import CDMEDataset
from opencompass.datasets.cdme.cdme import CDMEEvaluator
from opencompass.datasets.cdme.cdme import cdme_postprocess
from opencompass.datasets.cdme.cdme import cdme_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
cdme_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
cdme_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template='''{prompt}'''),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer, max_out_len=512))
cdme_eval_cfg = dict(
evaluator=dict(type=CDMEEvaluator),
pred_postprocessor=dict(type=cdme_postprocess),
dataset_postprocessor=dict(type=cdme_dataset_postprocess),
pred_role='BOT')
cdme_trim_eval_cfg = dict(
evaluator=dict(type=CDMEEvaluator, use_trim=True),
pred_postprocessor=dict(type=cdme_postprocess),
dataset_postprocessor=dict(type=cdme_dataset_postprocess),
pred_role='BOT')
#context_lengths = list(range(1000, 201000, 1000))
context_lengths = [16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000, 144000, 160000, 176000, 192000, 200000]
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/CDME'
file_list = ['zh_finance.jsonl']
cdme_datasets = []
cdme_trim_datasets = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'CDME_Length{original_context_length}'
f'Depth{int(depth_percent)}',
'type': CDMEDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle': '\n小明最喜欢的实习的地点就是上海人工智能实验室。\n',
'retrieval_question': '小明最喜欢的实习地点是哪里?请按照'
'“小明最喜欢的实习地点就是________。”的格式回答。\n',
'reader_cfg': cdme_reader_cfg,
'infer_cfg': cdme_infer_cfg,
'eval_cfg': cdme_eval_cfg
}
cdme_datasets.append(dataset_dict)
trim_dataset_dict = {
'abbr': f'CDME_Length{original_context_length}'
f'Depth{int(depth_percent)}',
'type': CDMEDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle': '\n小明最喜欢的实习的地点就是上海人工智能实验室。\n',
'retrieval_question': '小明最喜欢的实习地点是哪里?请按照'
'“小明最喜欢的实习地点就是________。”的格式回答。\n',
'reader_cfg': cdme_reader_cfg,
'infer_cfg': cdme_infer_cfg,
'eval_cfg': cdme_trim_eval_cfg
}
cdme_trim_datasets.append(trim_dataset_dict)

81
configs/datasets/cdme/cdme32k.py
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.cdme.cdme import CDMEDataset
from opencompass.datasets.cdme.cdme import CDMEEvaluator
from opencompass.datasets.cdme.cdme import cdme_postprocess
from opencompass.datasets.cdme.cdme import cdme_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
cdme_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
cdme_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template='''{prompt}'''),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer, max_out_len=512))
cdme_eval_cfg = dict(
evaluator=dict(type=CDMEEvaluator),
pred_postprocessor=dict(type=cdme_postprocess),
dataset_postprocessor=dict(type=cdme_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(1000, 33000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/CDME'
file_list = ['zh_finance.jsonl']
cdme_datasets = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'CDME_Length{original_context_length}'
f'Depth{int(depth_percent)}',
'type': CDMEDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle': '\n小明最喜欢的实习的地点就是上海人工智能实验室。\n',
'retrieval_question': '小明最喜欢的实习地点是哪里?请按照'
'“小明最喜欢的实习地点就是________。”的格式回答。',
'reader_cfg': cdme_reader_cfg,
'infer_cfg': cdme_infer_cfg,
'eval_cfg': cdme_eval_cfg
}
cdme_datasets.append(dataset_dict)

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configs/datasets/cdme/cdme8k.py
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.cdme.cdme import CDMEDataset
from opencompass.datasets.cdme.cdme import CDMEEvaluator
from opencompass.datasets.cdme.cdme import cdme_postprocess
from opencompass.datasets.cdme.cdme import cdme_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
cdme_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
cdme_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template='''{prompt}'''),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer, max_out_len=512))
cdme_eval_cfg = dict(
evaluator=dict(type=CDMEEvaluator),
pred_postprocessor=dict(type=cdme_postprocess),
dataset_postprocessor=dict(type=cdme_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(1000, 9000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/CDME'
file_list = ['zh_finance.jsonl']
cdme_datasets = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'CDME_Length{original_context_length}'
f'Depth{int(depth_percent)}',
'type': CDMEDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle': '\n小明最喜欢的实习的地点就是上海人工智能实验室。\n',
'retrieval_question': '小明最喜欢的实习地点是哪里?请按照'
'“小明最喜欢的实习地点就是________。”的格式回答。',
'reader_cfg': cdme_reader_cfg,
'infer_cfg': cdme_infer_cfg,
'eval_cfg': cdme_eval_cfg
}
cdme_datasets.append(dataset_dict)

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configs/datasets/cdme/multi_needle/cdme8k_cot2_italy.py
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.cdme.cdme_multi import CDMEDataset
from opencompass.datasets.cdme.cdme_multi import CDMEEvaluator
from opencompass.datasets.cdme.cdme_multi import cdme_postprocess
from opencompass.datasets.cdme.cdme_multi import cdme_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
cdme_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
cdme_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template='''{prompt}'''),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer, max_out_len=512))
cdme_eval_cfg = dict(
evaluator=dict(type=CDMEEvaluator),
pred_postprocessor=dict(type=cdme_postprocess),
dataset_postprocessor=dict(type=cdme_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(1000, 9000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/CDME'
file_list = ['zh_finance.jsonl']
cdme_datasets = []
needles = ['\n意大利的佛罗伦萨有一家名为"La Giostra"的餐馆,是整个佛罗伦萨中排行第一的餐馆。\n',
'"La Giostra"餐馆的特色菜肴是松露奶酪通心粉。']
retrieval_question = ("佛罗伦萨中排行第一的餐馆的特色菜肴是?"
"请按照'佛罗伦萨中排行第一的餐馆的特色菜肴是______。'的格式回答。")
answer = "佛罗伦萨中排行第一的餐馆的特色菜肴是松露奶酪通心粉。"
keyword = "松露奶酪通心粉"
diff = 25
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'CDME_Length{original_context_length}'
f'Depth{int(depth_percent)}',
'type': CDMEDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needles': needles,
'diff': diff,
'retrieval_question': retrieval_question,
'answer': answer,
'keyword': keyword,
'reader_cfg': cdme_reader_cfg,
'infer_cfg': cdme_infer_cfg,
'eval_cfg': cdme_eval_cfg
}
cdme_datasets.append(dataset_dict)

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configs/datasets/cdme/multi_needle/cdme8k_cot3_italy.py
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.cdme.cdme_multi import CDMEDataset
from opencompass.datasets.cdme.cdme_multi import CDMEEvaluator
from opencompass.datasets.cdme.cdme_multi import cdme_postprocess
from opencompass.datasets.cdme.cdme_multi import cdme_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
cdme_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
cdme_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template='''{prompt}'''),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer, max_out_len=512))
cdme_eval_cfg = dict(
evaluator=dict(type=CDMEEvaluator),
pred_postprocessor=dict(type=cdme_postprocess),
dataset_postprocessor=dict(type=cdme_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(1000, 9000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/CDME'
file_list = ['zh_finance.jsonl']
cdme_datasets = []
needles = ['\n意大利的佛罗伦萨有一家名为"La Giostra"的餐馆,是整个佛罗伦萨中排行第一的餐馆。\n',
'"La Giostra"餐馆的特色菜肴是松露奶酪通心粉。',
'松露奶酪通心粉是该家餐馆的有着意大利皇室烹饪血统的大厨Jack制作',]
retrieval_question = ("制作佛罗伦萨中排行第一的餐馆的特色菜肴的人叫什么?"
"请按照'制作佛罗伦萨中排行第一的餐馆的特色菜肴的人叫______。'的格式回答。")
answer = "制作佛罗伦萨中排行第一的餐馆的特色菜肴的人叫Jack"
keyword = "Jack"
diff = 25
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'CDME_Length{original_context_length}'
f'Depth{int(depth_percent)}',
'type': CDMEDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needles': needles,
'diff': diff,
'retrieval_question': retrieval_question,
'answer': answer,
'keyword': keyword,
'reader_cfg': cdme_reader_cfg,
'infer_cfg': cdme_infer_cfg,
'eval_cfg': cdme_eval_cfg
}
cdme_datasets.append(dataset_dict)

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configs/datasets/needlebench/atc/atc.py Normal file
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.atc import NeedleBenchATCOrderedDataset
from opencompass.datasets.needlebench.atc import NeedleBenchATCDataset
from opencompass.datasets.needlebench.origin import NeedleBenchOriginEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchOriginEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
needle_num_list = list(range(2, 100, 3))
document_depth_percent_intervals = 20
repeats = 30
names_path = './data/needlebench/names.json'
needlebench_atc_datasets_zh = []
needlebench_atc_datasets_en = []
needlebench_atc_datasets_zh_ordered = []
needlebench_atc_datasets_en_ordered = []
for num_needles in needle_num_list:
# ordered English version
dataset_dict = {
'abbr': f'needlebench_atc_challenge'
f'needle_{num_needles}_en_ordered',
'type': NeedleBenchATCOrderedDataset,
'path': names_path,
'num_needles': num_needles,
'language': 'English',
'repeats': repeats,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_atc_datasets_en_ordered.append(dataset_dict)
for num_needles in needle_num_list:
# ordered Chinese version
dataset_dict = {
'abbr': f'needlebench_atc_challenge'
f'needle_{num_needles}_zh_ordered',
'type': NeedleBenchATCOrderedDataset,
'path': names_path,
'num_needles': num_needles,
'language': 'Chinese',
'repeats': repeats,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_atc_datasets_zh_ordered.append(dataset_dict)
for num_needles in needle_num_list:
# standard English version
dataset_dict = {
'abbr': f'needlebench_atc_challenge'
f'needle_{num_needles}_en',
'type': NeedleBenchATCDataset,
'path': names_path,
'num_needles': num_needles,
'language': 'English',
'repeats': repeats,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_atc_datasets_en.append(dataset_dict)
for num_needles in needle_num_list:
# standard Chinese version
dataset_dict = {
'abbr': f'needlebench_atc_challenge'
f'needle_{num_needles}_zh',
'type': NeedleBenchATCDataset,
'path': names_path,
'num_needles': num_needles,
'language': 'Chinese',
'repeats': repeats,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_atc_datasets_zh.append(dataset_dict)

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configs/datasets/needlebench/needlebench.py Normal file
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from mmengine.config import read_base
with read_base():
from .needlebench_4k.needlebench import needlebench_datasets as needlebench_datasets_4k
from .needlebench_8k.needlebench import needlebench_datasets as needlebench_datasets_8k
from .needlebench_32k.needlebench import needlebench_datasets as needlebench_datasets_32k
from .needlebench_128k.needlebench import needlebench_datasets as needlebench_datasets_128k
from .needlebench_200k.needlebench import needlebench_datasets as needlebench_datasets_200k
needlebench_datasets = sum((v for k, v in locals().items() if k.endswith('_datasets')), [])

18
configs/datasets/needlebench/needlebench_128k/needlebench.py Normal file
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from mmengine.config import read_base
with read_base():
from .needlebench_multi_reasoning import needlebench_datasets_2needle_en as needlebench_multi_2needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_en as needlebench_multi_3needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_en as needlebench_multi_4needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_en as needlebench_multi_5needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_2needle_zh as needlebench_multi_2needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_zh as needlebench_multi_3needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_zh as needlebench_multi_4needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_zh as needlebench_multi_5needle_zh_datasets
from .needlebench_single import needlebench_datasets_en as needlebench_origin_en_datasets
from .needlebench_single import needlebench_datasets_zh as needlebench_origin_zh_datasets
from .needlebench_multi_retrieval import needlebench_datasets_en as needlebench_parallel_en_datasets
from .needlebench_multi_retrieval import needlebench_datasets_zh as needlebench_parallel_zh_datasets
needlebench_datasets = sum((v for k, v in locals().items() if k.endswith('_datasets')), [])

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.multi import NeedleBenchMultiDataset
from opencompass.datasets.needlebench.multi import NeedleBenchMultiEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchMultiEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list([16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000])
depths_list = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
# ----------English Version----------
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needle_file_name = 'multi_needle_reasoning_en.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_en = []
language = 'English'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_en.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_en.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_en.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_en.append(dataset_dict)
# ----------Chinese Version----------
base_path = './data/needlebench'
file_list = ['zh_finance.jsonl']
needle_file_name = 'multi_needle_reasoning_zh.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_zh = []
language = 'Chinese'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_zh.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_zh.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_zh.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_128k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelDataset
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchParallelEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list([16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000])
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
depths = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_en_128k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 3000,
'guide': True,
'language': 'English',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_zh_128k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.origin import NeedleBenchOriginDataset
from opencompass.datasets.needlebench.origin import NeedleBenchOriginEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchOriginEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list([16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000])
depths_list = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_en_128k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': 'English',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_zh_128k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from mmengine.config import read_base
with read_base():
from .needlebench_multi_reasoning import needlebench_datasets_2needle_en as needlebench_multi_2needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_en as needlebench_multi_3needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_en as needlebench_multi_4needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_en as needlebench_multi_5needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_2needle_zh as needlebench_multi_2needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_zh as needlebench_multi_3needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_zh as needlebench_multi_4needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_zh as needlebench_multi_5needle_zh_datasets
from .needlebench_single import needlebench_datasets_en as needlebench_origin_en_datasets
from .needlebench_single import needlebench_datasets_zh as needlebench_origin_zh_datasets
from .needlebench_multi_retrieval import needlebench_datasets_en as needlebench_parallel_en_datasets
from .needlebench_multi_retrieval import needlebench_datasets_zh as needlebench_parallel_zh_datasets
needlebench_datasets = sum((v for k, v in locals().items() if k.endswith('_datasets')), [])

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.multi import NeedleBenchMultiDataset
from opencompass.datasets.needlebench.multi import NeedleBenchMultiEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchMultiEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
# context_lengths = list([16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000, 144000, 160000, 176000, 192000, 200000])
context_lengths = [16000, 48000, 80000, 112000, 128000, 144000, 176000, 200000]
depths_list = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
# ----------English Version----------
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needle_file_name = 'multi_needle_reasoning_en.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_en = []
language = 'English'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_en.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_en.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_en.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_en.append(dataset_dict)
# ----------Chinese Version----------
base_path = './data/needlebench'
file_list = ['zh_finance.jsonl']
needle_file_name = 'multi_needle_reasoning_zh.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_zh = []
language = 'Chinese'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_zh.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_zh.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_zh.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_200k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_zh.append(dataset_dict)

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configs/datasets/needlebench/needlebench_200k/needlebench_multi_retrieval.py Normal file
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelDataset
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchParallelEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
# context_lengths = list([16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000, 144000, 160000, 176000, 192000, 200000])
context_lengths = list([16000, 48000, 80000, 112000, 128000, 144000, 176000, 200000])
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
depths = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_en_200k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 3000,
'guide': True,
'language': 'English',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_zh_200k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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configs/datasets/needlebench/needlebench_200k/needlebench_single.py Normal file
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.origin import NeedleBenchOriginDataset
from opencompass.datasets.needlebench.origin import NeedleBenchOriginEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchOriginEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
# context_lengths = list([16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000, 144000, 160000, 176000, 192000, 200000])
context_lengths = [16000, 48000, 80000, 112000, 128000, 144000, 176000, 200000]
depths_list = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_en_200k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': 'English',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_zh_200k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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configs/datasets/needlebench/needlebench_32k/needlebench.py Normal file
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from mmengine.config import read_base
with read_base():
from .needlebench_multi_reasoning import needlebench_datasets_2needle_en as needlebench_multi_2needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_en as needlebench_multi_3needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_en as needlebench_multi_4needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_en as needlebench_multi_5needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_2needle_zh as needlebench_multi_2needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_zh as needlebench_multi_3needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_zh as needlebench_multi_4needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_zh as needlebench_multi_5needle_zh_datasets
from .needlebench_single import needlebench_datasets_en as needlebench_origin_en_datasets
from .needlebench_single import needlebench_datasets_zh as needlebench_origin_zh_datasets
from .needlebench_multi_retrieval import needlebench_datasets_en as needlebench_parallel_en_datasets
from .needlebench_multi_retrieval import needlebench_datasets_zh as needlebench_parallel_zh_datasets
needlebench_datasets = sum((v for k, v in locals().items() if k.endswith('_datasets')), [])

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configs/datasets/needlebench/needlebench_32k/needlebench_multi_reasoning.py Normal file
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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.multi import NeedleBenchMultiDataset
from opencompass.datasets.needlebench.multi import NeedleBenchMultiEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchMultiEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list([9000, 13000, 17000, 21000, 25000, 29000, 31000, 32000])
depths_list = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
# ----------English Version----------
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needle_file_name = 'multi_needle_reasoning_en.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_en = []
language = 'English'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 3000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_en.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 3000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_en.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 3000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_en.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_en = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 3000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_en.append(dataset_dict)
# ----------Chinese Version----------
base_path = './data/needlebench'
file_list = ['zh_finance.jsonl']
needle_file_name = 'multi_needle_reasoning_zh.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_zh = []
language = 'Chinese'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_zh.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_zh.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_zh.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_zh = []
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_32k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelDataset
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchParallelEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list([9000, 13000, 17000, 21000, 25000, 29000, 31000, 32000])
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
depths = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_en_32k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 3000,
'guide': True,
'language': 'English',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_zh_32k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.origin import NeedleBenchOriginDataset
from opencompass.datasets.needlebench.origin import NeedleBenchOriginEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchOriginEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list([9000, 13000, 17000, 21000, 25000, 29000, 31000, 32000])
depths_list = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_en_32k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 3000,
'guide': True,
'language': 'English',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in depths_list:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_zh_32k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from mmengine.config import read_base
with read_base():
from .needlebench_multi_reasoning import needlebench_datasets_2needle_en as needlebench_multi_2needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_en as needlebench_multi_3needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_en as needlebench_multi_4needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_en as needlebench_multi_5needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_2needle_zh as needlebench_multi_2needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_zh as needlebench_multi_3needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_zh as needlebench_multi_4needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_zh as needlebench_multi_5needle_zh_datasets
from .needlebench_single import needlebench_datasets_en as needlebench_origin_en_datasets
from .needlebench_single import needlebench_datasets_zh as needlebench_origin_zh_datasets
from .needlebench_multi_retrieval import needlebench_datasets_en as needlebench_parallel_en_datasets
from .needlebench_multi_retrieval import needlebench_datasets_zh as needlebench_parallel_zh_datasets
needlebench_datasets = sum((v for k, v in locals().items() if k.endswith('_datasets')), [])

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.multi import NeedleBenchMultiDataset
from opencompass.datasets.needlebench.multi import NeedleBenchMultiEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchMultiEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(1000, 5000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
# ----------English Version----------
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needle_file_name = 'multi_needle_reasoning_en.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_en = []
language = 'English'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_en.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_en = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_en.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_en = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_en.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_en = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_en.append(dataset_dict)
# ----------Chinese Version----------
base_path = './data/needlebench'
file_list = ['zh_finance.jsonl']
needle_file_name = 'multi_needle_reasoning_zh.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_zh = []
language = 'Chinese'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_zh.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_zh = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_zh.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_zh = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_zh.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_zh = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_4k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelDataset
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchParallelEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(1000, 5000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
depths_float = generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type)
depths = [int(depth) for depth in depths_float]
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_en_4k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 1000,
'guide': True,
'language': 'English',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_zh_4k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.origin import NeedleBenchOriginDataset
from opencompass.datasets.needlebench.origin import NeedleBenchOriginEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchOriginEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(1000, 5000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_en_4k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 600,
'guide': True,
'language': 'English',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_zh_4k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from mmengine.config import read_base
with read_base():
from .needlebench_multi_reasoning import needlebench_datasets_2needle_en as needlebench_multi_2needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_en as needlebench_multi_3needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_en as needlebench_multi_4needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_en as needlebench_multi_5needle_en_datasets
from .needlebench_multi_reasoning import needlebench_datasets_2needle_zh as needlebench_multi_2needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_3needle_zh as needlebench_multi_3needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_4needle_zh as needlebench_multi_4needle_zh_datasets
from .needlebench_multi_reasoning import needlebench_datasets_5needle_zh as needlebench_multi_5needle_zh_datasets
from .needlebench_single import needlebench_datasets_en as needlebench_origin_en_datasets
from .needlebench_single import needlebench_datasets_zh as needlebench_origin_zh_datasets
from .needlebench_multi_retrieval import needlebench_datasets_en as needlebench_parallel_en_datasets
from .needlebench_multi_retrieval import needlebench_datasets_zh as needlebench_parallel_zh_datasets
needlebench_datasets = sum((v for k, v in locals().items() if k.endswith('_datasets')), [])

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.multi import NeedleBenchMultiDataset
from opencompass.datasets.needlebench.multi import NeedleBenchMultiEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchMultiEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(5000, 9000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
# ----------English Version----------
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needle_file_name = 'multi_needle_reasoning_en.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_en = []
language = 'English'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 1000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_en.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_en = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 1000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_en.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_en = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 1000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_en.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_en = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_en_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 1000,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_en.append(dataset_dict)
# ----------Chinese Version----------
base_path = './data/needlebench'
file_list = ['zh_finance.jsonl']
needle_file_name = 'multi_needle_reasoning_zh.json'
diff = 10
num_needles = 2
needlebench_datasets_2needle_zh = []
language = 'Chinese'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_2needle_zh.append(dataset_dict)
num_needles = 3
needlebench_datasets_3needle_zh = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_3needle_zh.append(dataset_dict)
num_needles = 4
needlebench_datasets_4needle_zh = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_4needle_zh.append(dataset_dict)
num_needles = 5
needlebench_datasets_5needle_zh = []
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_{num_needles}needle_zh_8k',
'type': NeedleBenchMultiDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': language,
'needle_file_name': needle_file_name,
'num_needles': num_needles,
'diff': diff,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_5needle_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelDataset
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchParallelEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(5000, 9000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
depths_float = generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type)
depths = [int(depth) for depth in depths_float]
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_en_8k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 1300,
'guide': True,
'language': 'English',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_zh_8k',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 25,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelDataset
from opencompass.datasets.needlebench.parallel import NeedleBenchParallelEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchParallelEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(5000, 9000, 1000))
document_depth_percent_intervals_list = [1, 5, 10, 15, 20]
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
for document_depth_percent_intervals in document_depth_percent_intervals_list:
depths_float = generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type)
depths = [int(depth) for depth in depths_float]
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_en_8k_batch{document_depth_percent_intervals}',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 50,
'length_buffer': 1300,
'guide': True,
'language': 'English',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
needle_file_name = 'needles.jsonl'
for document_depth_percent_intervals in document_depth_percent_intervals_list:
depths_float = generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type)
depths = [int(depth) for depth in depths_float]
for original_context_length in context_lengths:
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'_parallel_zh_8k_batch{document_depth_percent_intervals}',
'type': NeedleBenchParallelDataset,
'path': base_path,
'needle_file_name': needle_file_name,
'length': original_context_length,
'depths': depths,
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 50,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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from opencompass.openicl.icl_prompt_template import PromptTemplate
from opencompass.openicl.icl_retriever import ZeroRetriever
from opencompass.openicl.icl_inferencer import GenInferencer
from opencompass.datasets.needlebench.origin import NeedleBenchOriginDataset
from opencompass.datasets.needlebench.origin import NeedleBenchOriginEvaluator
from opencompass.datasets.needlebench.origin import needlebench_postprocess
from opencompass.datasets.needlebench.origin import needlebench_dataset_postprocess
import math
def logistic(x, L=100, x0=50, k=0.1):
return round(L / (1 + math.exp(-k * (x - x0))), 3)
def generate_linear_space(start, end, num):
if num == 1:
return [start]
elif num < 1:
raise ValueError("num must be at least 1.")
step = (end - start) / (num - 1)
return [start + step * i for i in range(num)]
def generate_depth_percents(intervals, interval_type):
if interval_type == 'linear':
return generate_linear_space(0, 100, intervals)
elif interval_type == 'sigmoid':
linear_space = generate_linear_space(0, 100, intervals)
return [logistic(x) for x in linear_space]
else:
raise ValueError('Unsupported interval type')
needlebench_reader_cfg = dict(input_columns=['prompt'], output_column='answer')
needlebench_infer_cfg = dict(
prompt_template=dict(
type=PromptTemplate,
template=dict(
round=[
dict(role='HUMAN', prompt='{prompt}'),
dict(role='BOT', prompt='{answer}\n'),
]
)
),
retriever=dict(type=ZeroRetriever),
inferencer=dict(type=GenInferencer))
needlebench_eval_cfg = dict(
evaluator=dict(type=NeedleBenchOriginEvaluator),
pred_postprocessor=dict(type=needlebench_postprocess),
dataset_postprocessor=dict(type=needlebench_dataset_postprocess),
pred_role='BOT')
context_lengths = list(range(5000, 9000, 1000))
document_depth_percent_intervals = 20
document_depth_percent_interval_type = "linear"
base_path = './data/needlebench'
file_list = ['PaulGrahamEssays.jsonl']
needlebench_datasets_en = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_en_8k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 800,
'guide': True,
'language': 'English',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_en.append(dataset_dict)
file_list = ['zh_finance.jsonl']
needlebench_datasets_zh = []
needle_file_name = 'needles.jsonl'
for original_context_length in context_lengths:
for depth_percent in generate_depth_percents(
document_depth_percent_intervals,
document_depth_percent_interval_type):
dataset_dict = {
'abbr': f'Length{original_context_length}'
f'Depth{int(depth_percent)}_origin_zh_8k',
'type': NeedleBenchOriginDataset,
'path': base_path,
'length': original_context_length,
'depth': int(depth_percent),
'tokenizer_model': 'gpt-4',
'file_list': file_list,
'num_repeats_per_file': 10,
'length_buffer': 200,
'guide': True,
'language': 'Chinese',
'needle_file_name': needle_file_name,
'reader_cfg': needlebench_reader_cfg,
'infer_cfg': needlebench_infer_cfg,
'eval_cfg': needlebench_eval_cfg
}
needlebench_datasets_zh.append(dataset_dict)

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# Needlebench: A Benchmark for Needle-In-A-Haystack Evaluations
English | [简体中文](readme_zh-CN.md)
## Overview
Needlebench is an exhaustive benchmark designed to rigorously assess the information retrieval and reasoning capabilities of large language models (LLMs). Drawing inspiration from the NeedleInAHaystack experiment, Needlebench broadens the scope to include a variety of tasks, each aimed at testing different facets of LLMs' abilities in long-context scenarios.
### Directory Structure
```
configs/datasets/needlebench/
├── atc
├── needlebench_4k
├── needlebench_8k
├── needlebench_32k
├── needlebench_128k
├── needlebench_200k
├── needlebench.py
├── readme.md
└── readme_zh-CN.md
```
Within each configuration directory (e.g., `needlebench_4k`), there are scripts tailored for testing within that specific length setting:
```
needlebench_4k/
├── needlebench_multi_reasoning.py
├── needlebench_multi_retrieval.py
├── needlebench.py
└── needlebench_single.py
```
## Task Descriptions and Length Configurations
Needlebench offers tasks in various length configurations, such as 4k, 8k, etc., to accommodate different scales of language model evaluation needs. Each length configuration provides specialized test scripts for the following tasks:
### Single-Needle Retrieval (`needlebench_single.py`)
The Single-Needle Retrieval task evaluates the LLMs' ability to recall a single piece of crucial information from a haystack text of a specific length. This task mirrors the original NeedleInAHaystack test's objective, assessing the model's precision in identifying and recalling specific information from extended texts.
### Multi-Needle Retrieval (`needlebench_multi_retrieval.py`)
The Multi-Needle Retrieval task challenges the LLMs' ability to identify and extract multiple key information points from extensive texts. It simulates real-world scenarios where multiple data points, facts, or figures need to be retrieved from documents or reports, evaluating the model's efficiency in navigating and extracting relevant information from dense texts.
### Multi-Needle Reasoning (`needlebench_multi_reasoning.py`)
Building on the retrieval tasks, the Multi-Needle Reasoning task emphasizes the LLMs' capacity for complex reasoning with the retrieved information. The model must not only recall multiple pieces of information but also engage in logical reasoning, synthesizing answers that reflect an understanding of the intricate relationships between various information points.
### Ancestral Trace Challenge (ATC)
The Ancestral Trace Challenge is Needlebench's most complex task, requiring models to recall and analyze every detail in long texts for problem-solving that demands an understanding of complex relationships, such as genealogical inquiries or detailed case analysis. This task highlights the need for models to process and reason with information at a granular level, mirroring the demands of sophisticated real-world analytical tasks.

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# Needlebench大海捞针测试评估基准
[English](readme.md) | 简体中文
## 概览
Needlebench是一个全面的基准测试旨在严格评估大型语言模型LLMs的信息检索和推理能力。借鉴了NeedleInAHaystack实验的灵感Needlebench扩展了范围包括多种任务每个任务都旨在测试LLMs处理长文本中关键信息的不同方面的能力。
### 目录结构
```
configs/datasets/needlebench/
├── atc
├── needlebench_4k
├── needlebench_8k
├── needlebench_32k
├── needlebench_128k
├── needlebench_200k
├── needlebench.py
├── readme.md
└── readme_zh-CN.md
```
在每个长度配置目录下(如 `needlebench_4k`),包含了专门针对该长度设置的测试任务脚本:
```
needlebench_4k/
├── needlebench_multi_reasoning.py
├── needlebench_multi_retrieval.py
├── needlebench.py
└── needlebench_single.py
```
## 任务描述与长度配置
Needlebench提供了不同长度配置的任务如4k、8k等以适应不同规模的语言模型评估需求。每种长度配置针对以下任务提供了专门的测试脚本
### 单针信息检索 (`needlebench_single.py`)
单针信息检索任务评估LLMs从特定长度的无关信息文本中回忆单个重要信息的能力。这个任务反映了原始的NeedleInAHaystack测试的目标评估模型长文本中识别和回忆特定信息的精确性。
### 多针信息检索 (`needlebench_multi_retrieval.py`)
多针信息检索任务挑战LLMs识别和提取广泛文本中的多个关键信息点的能力。它模拟了现实世界中的场景其中需要从文档或报告中检索多个数据点、事实或数字评估模型在浏览和从密集文本中提取相关信息的效率。
### 多针信息推理 (`needlebench_multi_reasoning.py`)
在检索任务的基础上多针信息推理任务强调LLMs使用检索到的信息进行复杂推理的能力。模型不仅需要回忆多个信息点还需要进行逻辑推理综合回答反映对不同信息点之间复杂关系理解的答案。
### 祖源追溯挑战 (ATC)
祖源追溯挑战是Needlebench中最复杂的任务要求模型回忆和分析长文本中的每个细节以解决需要理解复杂关系的问题如家谱查询或详细案例分析。这个任务突出了模型处理和推理详细信息的需要反映了现实世界中对复杂实际任务的要求。

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from opencompass.models import HuggingFaceCausalLM
from opencompass.models.turbomind import TurboMindModel
from opencompass.runners import SlurmSequentialRunner
from opencompass.partitioners import SizePartitioner, NaivePartitioner
from opencompass.tasks import OpenICLInferTask, OpenICLEvalTask
from mmengine.config import read_base
with read_base():
# eval needlebench_4k
from .datasets.needlebench.needlebench_4k.needlebench import needlebench_datasets
from .summarizers.needlebench import needlebench_4k_summarizer as summarizer
# only eval original "needle in a haystack test" in needlebench_4k
# from .datasets.needlebench.needlebench_4k.needlebench_single import needlebench_datasets_zh, needlebench_datasets_en
# from .summarizers.needlebench import needlebench_4k_summarizer as summarizer
# eval Ancestral Tracing Challenge(ATC)
# from .datasets.needlebench.atc.atc import needlebench_atc_datasets_zh, needlebench_atc_datasets_en
# from .summarizers.needlebench import needlebench_atc_summarizer as summarizer
datasets = sum([v for k, v in locals().items() if ('datasets' in k)], [])
hf_internlm2_chat_7b_model_meta_template = dict(
round=[
dict(role='HUMAN',
begin='<|im_start|>user\n', end='<|im_end|>\n'),
dict(role='BOT', begin='<|im_start|>assistant\n',
end='<|im_end|>\n', generate=True),
],
)
hf_internlm2_chat_7b = dict(
type=HuggingFaceCausalLM,
abbr='internlm2-chat-7b-hf',
path="internlm/internlm2-chat-7b",
tokenizer_path='internlm/internlm2-chat-7b',
model_kwargs=dict(
trust_remote_code=True,
device_map='auto',
),
tokenizer_kwargs=dict(
padding_side='left',
truncation_side='left',
use_fast=False,
trust_remote_code=True,
),
max_out_len=2000,
max_seq_len=32768,
batch_size=8,
meta_template=hf_internlm2_chat_7b_model_meta_template,
run_cfg=dict(num_gpus=1, num_procs=1),
end_str='<|im_end|>',
)
internlm2_chat_7b_200k = dict(
type=TurboMindModel,
abbr='internlm2-chat-7b-200k',
path="internlm/internlm2-chat-7b",
meta_template=hf_internlm2_chat_7b_model_meta_template,
engine_config=dict(session_len=210000,
max_batch_size=8,
rope_scaling_factor=2.0,
model_name="internlm2-chat-7b"),
gen_config=dict(top_k=1, top_p=0.8,
temperature=1.0,
max_new_tokens=2000),
max_out_len=2000,
max_seq_len=210000,
batch_size=8,
concurrency=8,
run_cfg=dict(num_gpus=1, num_procs=1),
)
models = [
# hf_internlm2_chat_7b,
internlm2_chat_7b_200k,
]
work_dir = './outputs/needlebench'

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configs/eval_needleinahaystack.py
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from opencompass.models import HuggingFaceCausalLM
from mmengine.config import read_base
with read_base():
from .datasets.cdme.cdme8k import cdme_datasets
datasets = [*cdme_datasets]
_meta_template = dict(
round=[
dict(role='HUMAN', begin='<|User|>:', end='\n'),
dict(role='BOT', begin='<|Bot|>:', end='<eoa>\n', generate=True),
],
)
models = [
dict(
type=HuggingFaceCausalLM,
abbr='internlm-chat-20b-hf',
path="internlm/internlm-chat-20b",
tokenizer_path='internlm/internlm-chat-20b',
model_kwargs=dict(
trust_remote_code=True,
device_map='auto',
),
tokenizer_kwargs=dict(
padding_side='left',
truncation_side='left',
use_fast=False,
trust_remote_code=True,
),
max_out_len=100,
max_seq_len=8192,
batch_size=8,
meta_template=_meta_template,
run_cfg=dict(num_gpus=2, num_procs=1),
end_str='<eoa>',
)
]

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configs/eval_needleinahaystack_turbomind.py
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from opencompass.models.turbomind import TurboMindModel
from mmengine.config import read_base
with read_base():
from .datasets.cdme.cdme200k import cdme_datasets
datasets = [*cdme_datasets]
internlm_meta_template = dict(round=[
dict(role='HUMAN', begin='<|User|>:', end='\n'),
dict(role='BOT', begin='<|Bot|>:', end='<eoa>\n', generate=True),
],
eos_token_id=103028)
models = [
# config for internlm-chat-20b
dict(
type=TurboMindModel,
abbr='internlm-chat-20b-turbomind',
path='./turbomind',
max_out_len=100,
max_seq_len=201000,
batch_size=8,
concurrency=8,
meta_template=internlm_meta_template,
run_cfg=dict(num_gpus=1, num_procs=1),
)
]

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from opencompass.summarizers.needlebench import NeedleBenchSummarizer
from opencompass.summarizers.needlebench import NeedleBenchATCSummarizer
# ----------NeedleBench-4k-summarizer----------
context_lengths_4k = list(range(1000, 5000, 1000))
depths = [0, 5, 10, 15, 21, 26, 31, 36, 42, 47, 52, 57, 63, 68, 73, 78, 84, 89, 94, 100]
depths_list_sparse = [0, 10, 21, 31, 42, 52, 63, 73, 84, 94, 100]
# Initialize the lists
_needlebench_4k_2needle_en = []
_needlebench_4k_3needle_en = []
_needlebench_4k_4needle_en = []
_needlebench_4k_5needle_en = []
_needlebench_4k_2needle_zh = []
_needlebench_4k_3needle_zh = []
_needlebench_4k_4needle_zh = []
_needlebench_4k_5needle_zh = []
_needlebench_4k_origin_en = []
_needlebench_4k_origin_zh = []
# Fill the lists using nested loops
for original_context_length in context_lengths_4k:
for depth_percent in depths:
_needlebench_4k_2needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_en_4k')
_needlebench_4k_3needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_en_4k')
_needlebench_4k_4needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_en_4k')
_needlebench_4k_5needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_en_4k')
_needlebench_4k_2needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_zh_4k')
_needlebench_4k_3needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_zh_4k')
_needlebench_4k_4needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_zh_4k')
_needlebench_4k_5needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_zh_4k')
_needlebench_4k_origin_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_en_4k')
_needlebench_4k_origin_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_zh_4k')
# Concatenate the multi-needle and origin lists
_needlebench_4k_multi_needle_en = _needlebench_4k_2needle_en + _needlebench_4k_3needle_en + _needlebench_4k_4needle_en + _needlebench_4k_5needle_en
_needlebench_4k_multi_needle_zh = _needlebench_4k_2needle_zh + _needlebench_4k_3needle_zh + _needlebench_4k_4needle_zh + _needlebench_4k_5needle_zh
_needlebench_4k_origin = _needlebench_4k_origin_en + _needlebench_4k_origin_zh
_needlebench_4k_multi_needle = _needlebench_4k_multi_needle_en + _needlebench_4k_multi_needle_zh
# Repeating the same process for parallel (assuming it's similar to origin_en)
_needlebench_4k_parallel_en = []
_needlebench_4k_parallel_zh = []
for original_context_length in context_lengths_4k:
_needlebench_4k_parallel_en.append(f'Length{original_context_length}_parallel_en_4k')
for original_context_length in context_lengths_4k:
_needlebench_4k_parallel_zh.append(f'Length{original_context_length}_parallel_zh_4k')
_needlebench_4k_parallel = _needlebench_4k_parallel_en + _needlebench_4k_parallel_zh
needlebench_summary_groups = [
{'name': 'original_version', 'subsets': _needlebench_4k_origin},
{'name': 'original_version_zh', 'subsets': _needlebench_4k_origin_zh},
{'name': 'original_version_en', 'subsets': _needlebench_4k_origin_en},
{'name': 'multi_needle_en', 'subsets': _needlebench_4k_multi_needle_en},
{'name': 'multi_needle2_en', 'subsets': _needlebench_4k_2needle_en},
{'name': 'multi_needle3_en', 'subsets': _needlebench_4k_3needle_en},
{'name': 'multi_needle4_en', 'subsets': _needlebench_4k_4needle_en},
{'name': 'multi_needle5_en', 'subsets': _needlebench_4k_5needle_en},
{'name': 'multi_needle_zh', 'subsets': _needlebench_4k_multi_needle_zh},
{'name': 'multi_needle2_zh', 'subsets': _needlebench_4k_2needle_zh},
{'name': 'multi_needle3_zh', 'subsets': _needlebench_4k_3needle_zh},
{'name': 'multi_needle4_zh', 'subsets': _needlebench_4k_4needle_zh},
{'name': 'multi_needle5_zh', 'subsets': _needlebench_4k_5needle_zh},
{'name': 'multi_needle', 'subsets': _needlebench_4k_multi_needle},
{'name': 'parallel_version', 'subsets': _needlebench_4k_parallel},
{'name': 'parallel_version_zh', 'subsets': _needlebench_4k_parallel_zh},
{'name': 'parallel_version_en', 'subsets': _needlebench_4k_parallel_en},
{'name': 'overall',
'subsets': [['original_version', 'naive_average'],
['multi_needle', 'naive_average'],
['parallel_version', 'average_score']],
'weights': {'original_version': 0.4,
'multi_needle': 0.3,
'parallel_version': 0.3}},
]
needlebench_4k_summarizer = dict(
type=NeedleBenchSummarizer,
dataset_abbrs=[
'overall',
'--------- NeedleBench-4k Single-Needle ---------', # category
'original_version',
'original_version_zh',
'original_version_en',
'--------- NeedleBench-4k Parallel-Needles ---------', # category
'parallel_version',
'parallel_version_zh',
'parallel_version_en',
'--------- NeedleBench-4k Multi-Needles ---------', # category
'multi_needle',
'multi_needle_en',
'multi_needle_zh',
'multi_needle2_en',
'multi_needle3_en',
'multi_needle4_en',
'multi_needle5_en',
'multi_needle2_zh',
'multi_needle3_zh',
'multi_needle4_zh',
'multi_needle5_zh',
# *_needlebench_4k_origin, *_needlebench_4k_multi_needle, *_needlebench_4k_parallel,
],
summary_groups=needlebench_summary_groups,
)
# ----------NeedleBench-8k-summarizer----------
context_lengths_8k = list(range(5000, 9000, 1000))
# Initialize the lists
_needlebench_8k_2needle_en = []
_needlebench_8k_3needle_en = []
_needlebench_8k_4needle_en = []
_needlebench_8k_5needle_en = []
_needlebench_8k_2needle_zh = []
_needlebench_8k_3needle_zh = []
_needlebench_8k_4needle_zh = []
_needlebench_8k_5needle_zh = []
_needlebench_8k_origin_en = []
_needlebench_8k_origin_zh = []
# Fill the lists using nested loops
for original_context_length in context_lengths_8k:
for depth_percent in depths:
_needlebench_8k_2needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_en_8k')
_needlebench_8k_3needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_en_8k')
_needlebench_8k_4needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_en_8k')
_needlebench_8k_5needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_en_8k')
_needlebench_8k_2needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_zh_8k')
_needlebench_8k_3needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_zh_8k')
_needlebench_8k_4needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_zh_8k')
_needlebench_8k_5needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_zh_8k')
_needlebench_8k_origin_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_en_8k')
_needlebench_8k_origin_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_zh_8k')
# Concatenate the multi-needle and origin lists
_needlebench_8k_multi_needle_en = _needlebench_8k_2needle_en + _needlebench_8k_3needle_en + _needlebench_8k_4needle_en + _needlebench_8k_5needle_en
_needlebench_8k_multi_needle_zh = _needlebench_8k_2needle_zh + _needlebench_8k_3needle_zh + _needlebench_8k_4needle_zh + _needlebench_8k_5needle_zh
_needlebench_8k_origin = _needlebench_8k_origin_en + _needlebench_8k_origin_zh
_needlebench_8k_multi_needle = _needlebench_8k_multi_needle_en + _needlebench_8k_multi_needle_zh
# Repeating the same process for parallel (assuming it's similar to origin_en)
_needlebench_8k_parallel_en = []
_needlebench_8k_parallel_zh = []
for original_context_length in context_lengths_8k:
_needlebench_8k_parallel_en.append(f'Length{original_context_length}_parallel_en_8k')
for original_context_length in context_lengths_8k:
_needlebench_8k_parallel_zh.append(f'Length{original_context_length}_parallel_zh_8k')
_needlebench_8k_parallel = _needlebench_8k_parallel_en + _needlebench_8k_parallel_zh
needlebench_summary_groups = [
{'name': 'original_version', 'subsets': _needlebench_8k_origin},
{'name': 'original_version_zh', 'subsets': _needlebench_8k_origin_zh},
{'name': 'original_version_en', 'subsets': _needlebench_8k_origin_en},
{'name': 'multi_needle_en', 'subsets': _needlebench_8k_multi_needle_en},
{'name': 'multi_needle2_en', 'subsets': _needlebench_8k_2needle_en},
{'name': 'multi_needle3_en', 'subsets': _needlebench_8k_3needle_en},
{'name': 'multi_needle4_en', 'subsets': _needlebench_8k_4needle_en},
{'name': 'multi_needle5_en', 'subsets': _needlebench_8k_5needle_en},
{'name': 'multi_needle_zh', 'subsets': _needlebench_8k_multi_needle_zh},
{'name': 'multi_needle2_zh', 'subsets': _needlebench_8k_2needle_zh},
{'name': 'multi_needle3_zh', 'subsets': _needlebench_8k_3needle_zh},
{'name': 'multi_needle4_zh', 'subsets': _needlebench_8k_4needle_zh},
{'name': 'multi_needle5_zh', 'subsets': _needlebench_8k_5needle_zh},
{'name': 'multi_needle', 'subsets': _needlebench_8k_multi_needle},
{'name': 'parallel_version', 'subsets': _needlebench_8k_parallel},
{'name': 'parallel_version_zh', 'subsets': _needlebench_8k_parallel_zh},
{'name': 'parallel_version_en', 'subsets': _needlebench_8k_parallel_en},
{'name': 'overall',
'subsets': [['original_version', 'naive_average'],
['multi_needle', 'naive_average'],
['parallel_version', 'average_score']],
'weights': {'original_version': 0.4,
'multi_needle': 0.3,
'parallel_version': 0.3}},
]
needlebench_8k_summarizer = dict(
type=NeedleBenchSummarizer,
dataset_abbrs=[
'overall',
'--------- NeedleBench-8k Single-Needle ---------', # category
'original_version',
'original_version_zh',
'original_version_en',
'--------- NeedleBench-8k Parallel-Needles ---------', # category
'parallel_version',
'parallel_version_zh',
'parallel_version_en',
'--------- NeedleBench-8k Multi-Needles ---------', # category
'multi_needle',
'multi_needle_en',
'multi_needle_zh',
'multi_needle2_en',
'multi_needle3_en',
'multi_needle4_en',
'multi_needle5_en',
'multi_needle2_zh',
'multi_needle3_zh',
'multi_needle4_zh',
'multi_needle5_zh',
# *_needlebench_8k_origin, *_needlebench_8k_multi_needle, *_needlebench_8k_parallel,
],
summary_groups=needlebench_summary_groups,
)
# ----------NeedleBench-32k-summarizer----------
context_lengths_32k = [9000, 13000, 17000, 21000, 25000, 29000, 31000, 32000]
# Initialize the lists
_needlebench_32k_2needle_en = []
_needlebench_32k_3needle_en = []
_needlebench_32k_4needle_en = []
_needlebench_32k_5needle_en = []
_needlebench_32k_2needle_zh = []
_needlebench_32k_3needle_zh = []
_needlebench_32k_4needle_zh = []
_needlebench_32k_5needle_zh = []
_needlebench_32k_origin_en = []
_needlebench_32k_origin_zh = []
# Fill the lists using nested loops
for original_context_length in context_lengths_32k:
for depth_percent in depths_list_sparse:
_needlebench_32k_2needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_en_32k')
_needlebench_32k_3needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_en_32k')
_needlebench_32k_4needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_en_32k')
_needlebench_32k_5needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_en_32k')
_needlebench_32k_2needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_zh_32k')
_needlebench_32k_3needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_zh_32k')
_needlebench_32k_4needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_zh_32k')
_needlebench_32k_5needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_zh_32k')
_needlebench_32k_origin_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_en_32k')
_needlebench_32k_origin_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_zh_32k')
# Concatenate the multi-needle and origin lists
_needlebench_32k_multi_needle_en = _needlebench_32k_2needle_en + _needlebench_32k_3needle_en + _needlebench_32k_4needle_en + _needlebench_32k_5needle_en
_needlebench_32k_multi_needle_zh = _needlebench_32k_2needle_zh + _needlebench_32k_3needle_zh + _needlebench_32k_4needle_zh + _needlebench_32k_5needle_zh
_needlebench_32k_origin = _needlebench_32k_origin_en + _needlebench_32k_origin_zh
_needlebench_32k_multi_needle = _needlebench_32k_multi_needle_en + _needlebench_32k_multi_needle_zh
# Repeating the same process for parallel (assuming it's similar to origin_en)
_needlebench_32k_parallel_en = []
_needlebench_32k_parallel_zh = []
for original_context_length in context_lengths_32k:
_needlebench_32k_parallel_en.append(f'Length{original_context_length}_parallel_en_32k')
for original_context_length in context_lengths_32k:
_needlebench_32k_parallel_zh.append(f'Length{original_context_length}_parallel_zh_32k')
_needlebench_32k_parallel = _needlebench_32k_parallel_en + _needlebench_32k_parallel_zh
needlebench_summary_groups = [
{'name': 'original_version', 'subsets': _needlebench_32k_origin},
{'name': 'original_version_zh', 'subsets': _needlebench_32k_origin_zh},
{'name': 'original_version_en', 'subsets': _needlebench_32k_origin_en},
{'name': 'multi_needle_en', 'subsets': _needlebench_32k_multi_needle_en},
{'name': 'multi_needle2_en', 'subsets': _needlebench_32k_2needle_en},
{'name': 'multi_needle3_en', 'subsets': _needlebench_32k_3needle_en},
{'name': 'multi_needle4_en', 'subsets': _needlebench_32k_4needle_en},
{'name': 'multi_needle5_en', 'subsets': _needlebench_32k_5needle_en},
{'name': 'multi_needle_zh', 'subsets': _needlebench_32k_multi_needle_zh},
{'name': 'multi_needle2_zh', 'subsets': _needlebench_32k_2needle_zh},
{'name': 'multi_needle3_zh', 'subsets': _needlebench_32k_3needle_zh},
{'name': 'multi_needle4_zh', 'subsets': _needlebench_32k_4needle_zh},
{'name': 'multi_needle5_zh', 'subsets': _needlebench_32k_5needle_zh},
{'name': 'multi_needle', 'subsets': _needlebench_32k_multi_needle},
{'name': 'parallel_version', 'subsets': _needlebench_32k_parallel},
{'name': 'parallel_version_zh', 'subsets': _needlebench_32k_parallel_zh},
{'name': 'parallel_version_en', 'subsets': _needlebench_32k_parallel_en},
{'name': 'overall',
'subsets': [['original_version', 'naive_average'],
['multi_needle', 'naive_average'],
['parallel_version', 'average_score']],
'weights': {'original_version': 0.4,
'multi_needle': 0.3,
'parallel_version': 0.3}},
]
needlebench_32k_summarizer = dict(
type=NeedleBenchSummarizer,
dataset_abbrs=[
'overall',
'--------- NeedleBench-32k Single-Needle ---------', # category
'original_version',
'original_version_zh',
'original_version_en',
'--------- NeedleBench-32k Parallel-Needles ---------', # category
'parallel_version',
'parallel_version_zh',
'parallel_version_en',
'--------- NeedleBench-32k Multi-Needles ---------', # category
'multi_needle',
'multi_needle_en',
'multi_needle_zh',
'multi_needle2_en',
'multi_needle3_en',
'multi_needle4_en',
'multi_needle5_en',
'multi_needle2_zh',
'multi_needle3_zh',
'multi_needle4_zh',
'multi_needle5_zh',
# *_needlebench_32k_origin, *_needlebench_32k_multi_needle, *_needlebench_32k_parallel,
],
summary_groups=needlebench_summary_groups,
)
# ----------NeedleBench-128k-summarizer----------
context_lengths_128k = list([16000, 32000, 48000, 64000, 80000, 96000, 112000, 128000])
# Initialize the lists
_needlebench_128k_2needle_en = []
_needlebench_128k_3needle_en = []
_needlebench_128k_4needle_en = []
_needlebench_128k_5needle_en = []
_needlebench_128k_2needle_zh = []
_needlebench_128k_3needle_zh = []
_needlebench_128k_4needle_zh = []
_needlebench_128k_5needle_zh = []
_needlebench_128k_origin_en = []
_needlebench_128k_origin_zh = []
# Fill the lists using nested loops
for original_context_length in context_lengths_128k:
for depth_percent in depths_list_sparse:
_needlebench_128k_2needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_en_128k')
_needlebench_128k_3needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_en_128k')
_needlebench_128k_4needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_en_128k')
_needlebench_128k_5needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_en_128k')
_needlebench_128k_2needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_zh_128k')
_needlebench_128k_3needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_zh_128k')
_needlebench_128k_4needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_zh_128k')
_needlebench_128k_5needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_zh_128k')
_needlebench_128k_origin_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_en_128k')
_needlebench_128k_origin_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_zh_128k')
# Concatenate the multi-needle and origin lists
_needlebench_128k_multi_needle_en = _needlebench_128k_2needle_en + _needlebench_128k_3needle_en + _needlebench_128k_4needle_en + _needlebench_128k_5needle_en
_needlebench_128k_multi_needle_zh = _needlebench_128k_2needle_zh + _needlebench_128k_3needle_zh + _needlebench_128k_4needle_zh + _needlebench_128k_5needle_zh
_needlebench_128k_origin = _needlebench_128k_origin_en + _needlebench_128k_origin_zh
_needlebench_128k_multi_needle = _needlebench_128k_multi_needle_en + _needlebench_128k_multi_needle_zh
# Repeating the same process for parallel (assuming it's similar to origin_en)
_needlebench_128k_parallel_en = []
_needlebench_128k_parallel_zh = []
for original_context_length in context_lengths_128k:
_needlebench_128k_parallel_en.append(f'Length{original_context_length}_parallel_en_128k')
for original_context_length in context_lengths_128k:
_needlebench_128k_parallel_zh.append(f'Length{original_context_length}_parallel_zh_128k')
_needlebench_128k_parallel = _needlebench_128k_parallel_en + _needlebench_128k_parallel_zh
needlebench_summary_groups = [
{'name': 'original_version', 'subsets': _needlebench_128k_origin},
{'name': 'original_version_zh', 'subsets': _needlebench_128k_origin_zh},
{'name': 'original_version_en', 'subsets': _needlebench_128k_origin_en},
{'name': 'multi_needle_en', 'subsets': _needlebench_128k_multi_needle_en},
{'name': 'multi_needle2_en', 'subsets': _needlebench_128k_2needle_en},
{'name': 'multi_needle3_en', 'subsets': _needlebench_128k_3needle_en},
{'name': 'multi_needle4_en', 'subsets': _needlebench_128k_4needle_en},
{'name': 'multi_needle5_en', 'subsets': _needlebench_128k_5needle_en},
{'name': 'multi_needle_zh', 'subsets': _needlebench_128k_multi_needle_zh},
{'name': 'multi_needle2_zh', 'subsets': _needlebench_128k_2needle_zh},
{'name': 'multi_needle3_zh', 'subsets': _needlebench_128k_3needle_zh},
{'name': 'multi_needle4_zh', 'subsets': _needlebench_128k_4needle_zh},
{'name': 'multi_needle5_zh', 'subsets': _needlebench_128k_5needle_zh},
{'name': 'multi_needle', 'subsets': _needlebench_128k_multi_needle},
{'name': 'parallel_version', 'subsets': _needlebench_128k_parallel},
{'name': 'parallel_version_zh', 'subsets': _needlebench_128k_parallel_zh},
{'name': 'parallel_version_en', 'subsets': _needlebench_128k_parallel_en},
{'name': 'overall',
'subsets': [['original_version', 'naive_average'],
['multi_needle', 'naive_average'],
['parallel_version', 'average_score']],
'weights': {'original_version': 0.4,
'multi_needle': 0.3,
'parallel_version': 0.3}},
]
needlebench_128k_summarizer = dict(
type=NeedleBenchSummarizer,
dataset_abbrs=[
'overall',
'--------- NeedleBench-128k Single-Needle ---------', # category
'original_version',
'original_version_zh',
'original_version_en',
'--------- NeedleBench-128k Parallel-Needles ---------', # category
'parallel_version',
'parallel_version_zh',
'parallel_version_en',
'--------- NeedleBench-128k Multi-Needles ---------', # category
'multi_needle',
'multi_needle_en',
'multi_needle_zh',
'multi_needle2_en',
'multi_needle3_en',
'multi_needle4_en',
'multi_needle5_en',
'multi_needle2_zh',
'multi_needle3_zh',
'multi_needle4_zh',
'multi_needle5_zh',
# *_needlebench_128k_origin, *_needlebench_128k_multi_needle, *_needlebench_128k_parallel,
],
summary_groups=needlebench_summary_groups,
)
# ----------NeedleBench-200k-summarizer----------
context_lengths_200k = list([16000, 48000, 80000, 112000, 128000, 144000, 176000, 200000])
# Initialize the lists
_needlebench_200k_2needle_en = []
_needlebench_200k_3needle_en = []
_needlebench_200k_4needle_en = []
_needlebench_200k_5needle_en = []
_needlebench_200k_2needle_zh = []
_needlebench_200k_3needle_zh = []
_needlebench_200k_4needle_zh = []
_needlebench_200k_5needle_zh = []
_needlebench_200k_origin_en = []
_needlebench_200k_origin_zh = []
# Fill the lists using nested loops
for original_context_length in context_lengths_200k:
for depth_percent in depths_list_sparse:
_needlebench_200k_2needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_en_200k')
_needlebench_200k_3needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_en_200k')
_needlebench_200k_4needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_en_200k')
_needlebench_200k_5needle_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_en_200k')
_needlebench_200k_2needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_2needle_zh_200k')
_needlebench_200k_3needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_3needle_zh_200k')
_needlebench_200k_4needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_4needle_zh_200k')
_needlebench_200k_5needle_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_5needle_zh_200k')
_needlebench_200k_origin_en.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_en_200k')
_needlebench_200k_origin_zh.append(f'Length{original_context_length}Depth{int(depth_percent)}_origin_zh_200k')
# Concatenate the multi-needle and origin lists
_needlebench_200k_multi_needle_en = _needlebench_200k_2needle_en + _needlebench_200k_3needle_en + _needlebench_200k_4needle_en + _needlebench_200k_5needle_en
_needlebench_200k_multi_needle_zh = _needlebench_200k_2needle_zh + _needlebench_200k_3needle_zh + _needlebench_200k_4needle_zh + _needlebench_200k_5needle_zh
_needlebench_200k_origin = _needlebench_200k_origin_en + _needlebench_200k_origin_zh
_needlebench_200k_multi_needle = _needlebench_200k_multi_needle_en + _needlebench_200k_multi_needle_zh
# Repeating the same process for parallel (assuming it's similar to origin_en)
_needlebench_200k_parallel_en = []
_needlebench_200k_parallel_zh = []
for original_context_length in context_lengths_200k:
_needlebench_200k_parallel_en.append(f'Length{original_context_length}_parallel_en_200k')
for original_context_length in context_lengths_200k:
_needlebench_200k_parallel_zh.append(f'Length{original_context_length}_parallel_zh_200k')
_needlebench_200k_parallel = _needlebench_200k_parallel_en + _needlebench_200k_parallel_zh
needlebench_summary_groups = [
{'name': 'original_version', 'subsets': _needlebench_200k_origin},
{'name': 'original_version_zh', 'subsets': _needlebench_200k_origin_zh},
{'name': 'original_version_en', 'subsets': _needlebench_200k_origin_en},
{'name': 'multi_needle_en', 'subsets': _needlebench_200k_multi_needle_en},
{'name': 'multi_needle2_en', 'subsets': _needlebench_200k_2needle_en},
{'name': 'multi_needle3_en', 'subsets': _needlebench_200k_3needle_en},
{'name': 'multi_needle4_en', 'subsets': _needlebench_200k_4needle_en},
{'name': 'multi_needle5_en', 'subsets': _needlebench_200k_5needle_en},
{'name': 'multi_needle_zh', 'subsets': _needlebench_200k_multi_needle_zh},
{'name': 'multi_needle2_zh', 'subsets': _needlebench_200k_2needle_zh},
{'name': 'multi_needle3_zh', 'subsets': _needlebench_200k_3needle_zh},
{'name': 'multi_needle4_zh', 'subsets': _needlebench_200k_4needle_zh},
{'name': 'multi_needle5_zh', 'subsets': _needlebench_200k_5needle_zh},
{'name': 'multi_needle', 'subsets': _needlebench_200k_multi_needle},
{'name': 'parallel_version', 'subsets': _needlebench_200k_parallel},
{'name': 'parallel_version_zh', 'subsets': _needlebench_200k_parallel_zh},
{'name': 'parallel_version_en', 'subsets': _needlebench_200k_parallel_en},
{'name': 'overall',
'subsets': [['original_version', 'naive_average'],
['multi_needle', 'naive_average'],
['parallel_version', 'average_score']],
'weights': {'original_version': 0.4,
'multi_needle': 0.3,
'parallel_version': 0.3}},
]
needlebench_200k_summarizer = dict(
type=NeedleBenchSummarizer,
dataset_abbrs=[
'overall',
'--------- NeedleBench-200k Single-Needle ---------', # category
'original_version',
'original_version_zh',
'original_version_en',
'--------- NeedleBench-200k Parallel-Needles ---------', # category
'parallel_version',
'parallel_version_zh',
'parallel_version_en',
'--------- NeedleBench-200k Multi-Needles ---------', # category
'multi_needle',
'multi_needle_en',
'multi_needle_zh',
'multi_needle2_en',
'multi_needle3_en',
'multi_needle4_en',
'multi_needle5_en',
'multi_needle2_zh',
'multi_needle3_zh',
'multi_needle4_zh',
'multi_needle5_zh',
# *_needlebench_200k_origin, *_needlebench_200k_multi_needle, *_needlebench_200k_parallel,
],
summary_groups=needlebench_summary_groups,
)
context_lengths_8k = list(range(5000, 9000, 1000))
# Repeating the same process for parallel (assuming it's similar to origin_en)
_needlebench_8k_parallel_en_batch1 = []
_needlebench_8k_parallel_en_batch5 = []
_needlebench_8k_parallel_en_batch10 = []
_needlebench_8k_parallel_en_batch15 = []
_needlebench_8k_parallel_en_batch20 = []
_needlebench_8k_parallel_zh_batch1 = []
_needlebench_8k_parallel_zh_batch5 = []
_needlebench_8k_parallel_zh_batch10 = []
_needlebench_8k_parallel_zh_batch15 = []
_needlebench_8k_parallel_zh_batch20 = []
for original_context_length in context_lengths_8k:
_needlebench_8k_parallel_en_batch1.append(f'Length{original_context_length}_parallel_en_8k_batch1')
_needlebench_8k_parallel_en_batch5.append(f'Length{original_context_length}_parallel_en_8k_batch5')
_needlebench_8k_parallel_en_batch10.append(f'Length{original_context_length}_parallel_en_8k_batch10')
_needlebench_8k_parallel_en_batch15.append(f'Length{original_context_length}_parallel_en_8k_batch15')
_needlebench_8k_parallel_en_batch20.append(f'Length{original_context_length}_parallel_en_8k_batch20')
_needlebench_8k_parallel_zh_batch1.append(f'Length{original_context_length}_parallel_zh_8k_batch1')
_needlebench_8k_parallel_zh_batch5.append(f'Length{original_context_length}_parallel_zh_8k_batch5')
_needlebench_8k_parallel_zh_batch10.append(f'Length{original_context_length}_parallel_zh_8k_batch10')
_needlebench_8k_parallel_zh_batch15.append(f'Length{original_context_length}_parallel_zh_8k_batch15')
_needlebench_8k_parallel_zh_batch20.append(f'Length{original_context_length}_parallel_zh_8k_batch20')
_needlebench_8k_parallel_batch1 = _needlebench_8k_parallel_en_batch1 + _needlebench_8k_parallel_zh_batch1
_needlebench_8k_parallel_batch5 = _needlebench_8k_parallel_en_batch5 + _needlebench_8k_parallel_zh_batch5
_needlebench_8k_parallel_batch10 = _needlebench_8k_parallel_en_batch10 + _needlebench_8k_parallel_zh_batch10
_needlebench_8k_parallel_batch15 = _needlebench_8k_parallel_en_batch15 + _needlebench_8k_parallel_zh_batch15
_needlebench_8k_parallel_batch20 = _needlebench_8k_parallel_en_batch20 + _needlebench_8k_parallel_zh_batch20
needlebench_summary_groups = [
{'name': 'parallel_version_batch1', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_batch1]},
{'name': 'parallel_version_zh_batch1', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_zh_batch1]},
{'name': 'parallel_version_en_batch1', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_en_batch1]},
{'name': 'parallel_version_batch5', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_batch5]},
{'name': 'parallel_version_zh_batch5', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_zh_batch5]},
{'name': 'parallel_version_en_batch5', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_en_batch5]},
{'name': 'parallel_version_batch10', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_batch10]},
{'name': 'parallel_version_zh_batch10', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_zh_batch10]},
{'name': 'parallel_version_en_batch10', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_en_batch10]},
{'name': 'parallel_version_batch15', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_batch15]},
{'name': 'parallel_version_zh_batch15', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_zh_batch15]},
{'name': 'parallel_version_en_batch15', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_en_batch15]},
{'name': 'parallel_version_batch20', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_batch20]},
{'name': 'parallel_version_zh_batch20', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_zh_batch20]},
{'name': 'parallel_version_en_batch20', 'subsets': [[_dataset, "average_score"] for _dataset in _needlebench_8k_parallel_en_batch20]},
]
needlebench_8k_batch_overall_summarizer = dict(
dataset_abbrs=[
'--------- NeedleBench-8k Parallel-Needles ---------', # category
'parallel_version_batch1',
'parallel_version_batch5',
'parallel_version_batch10',
'parallel_version_batch15',
'parallel_version_batch20',
'parallel_version_zh_batch1',
'parallel_version_en_batch1',
'parallel_version_zh_batch5',
'parallel_version_en_batch5',
'parallel_version_zh_batch10',
'parallel_version_en_batch10',
'parallel_version_zh_batch15',
'parallel_version_en_batch15',
'parallel_version_zh_batch20',
'parallel_version_en_batch20',
# *_needlebench_8k_origin, *_needlebench_8k_multi_needle, *_needlebench_8k_parallel,
],
summary_groups=needlebench_summary_groups,
)
needlebench_summary_groups = [
{'name': 'parallel_version_batch1', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_batch1]},
{'name': 'parallel_version_zh_batch1', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_zh_batch1]},
{'name': 'parallel_version_en_batch1', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_en_batch1]},
{'name': 'parallel_version_batch5', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_batch5]},
{'name': 'parallel_version_zh_batch5', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_zh_batch5]},
{'name': 'parallel_version_en_batch5', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_en_batch5]},
{'name': 'parallel_version_batch10', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_batch10]},
{'name': 'parallel_version_zh_batch10', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_zh_batch10]},
{'name': 'parallel_version_en_batch10', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_en_batch10]},
{'name': 'parallel_version_batch15', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_batch15]},
{'name': 'parallel_version_zh_batch15', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_zh_batch15]},
{'name': 'parallel_version_en_batch15', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_en_batch15]},
{'name': 'parallel_version_batch20', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_batch20]},
{'name': 'parallel_version_zh_batch20', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_zh_batch20]},
{'name': 'parallel_version_en_batch20', 'subsets': [[_dataset, "Depth0"] for _dataset in _needlebench_8k_parallel_en_batch20]},
]
needlebench_8k_batch_depth0_summarizer = dict(
dataset_abbrs=[
'--------- NeedleBench-8k Parallel-Needles ---------', # category
'parallel_version_batch1',
'parallel_version_batch5',
'parallel_version_batch10',
'parallel_version_batch15',
'parallel_version_batch20',
'parallel_version_zh_batch1',
'parallel_version_en_batch1',
'parallel_version_zh_batch5',
'parallel_version_en_batch5',
'parallel_version_zh_batch10',
'parallel_version_en_batch10',
'parallel_version_zh_batch15',
'parallel_version_en_batch15',
'parallel_version_zh_batch20',
'parallel_version_en_batch20',
# *_needlebench_8k_origin, *_needlebench_8k_multi_needle, *_needlebench_8k_parallel,
],
summary_groups=needlebench_summary_groups,
)
needlebench_atc_summarizer = dict(
type=NeedleBenchATCSummarizer,
)

247
opencompass/datasets/needlebench/atc.py Normal file
View File

@ -0,0 +1,247 @@
# flake8: noqa
import json
import random
from datasets import Dataset
from opencompass.datasets.base import BaseDataset
from opencompass.registry import LOAD_DATASET
@LOAD_DATASET.register_module()
class NeedleBenchATCDataset(BaseDataset):
@staticmethod
def load(
path,
num_needles: int,
language: str,
repeats: int,
):
data = {'prompt': [], 'answer': []}
with open(path, 'r', encoding='utf-8') as file:
names_data = json.load(file)
all_names = names_data[language].split(',')
for _ in range(repeats):
names = random.sample(all_names, num_needles)
if language == 'Chinese':
relationship_terms = [
'父亲', '母亲', '爸爸', '妈妈', '爷爷', '奶奶', '姥姥', '姥爷', '外公', '外婆'
]
relationship_templates = [
'{A}{B}{relationship}',
'{B}{relationship}{A}',
'{A}作为{B}{relationship},对{B}的成长有重要影响。',
'{A}不仅是{B}{relationship},还是{B}的榜样。',
'{B}{A}所生的孩子。',
'{A}{B}来说,不只是一个{relationship},还是一个朋友。',
'{A}{B}的生命中扮演着{relationship}的角色。',
'{B}{A}视为其{relationship}',
]
elif language == 'English':
relationship_terms = [
'father', 'mother', 'dad', 'mom', 'grandfather',
'grandmother', 'maternal grandmother',
'maternal grandfather', 'paternal grandfather',
'paternal grandmother'
]
relationship_templates = [
"{A} is {B}'s {relationship}.",
"{B}'s {relationship} is {A}.",
("{A}, as {B}'s {relationship}, "
"has a significant impact on {B}'s upbringing."),
("{A} is not only {B}'s {relationship} "
"but also {B}'s role model."),
'{B} is the child of {A}.',
('For {B}, {A} is not just a {relationship}, '
'but also a friend.'),
("{A} plays the role of {B}'s {relationship} "
"in {B}'s life."),
'{B} considers {A} as their {relationship}.',
]
def generate_chain_family_story(names, templates,
relationship_terms):
story = ''
for i in range(len(names) - 1):
template = random.choice(templates)
relation_term = random.choice(relationship_terms)
relation = template.format(A=names[i],
B=names[i + 1],
relationship=relation_term)
story += f'{relation}*'
return story
chain_story = generate_chain_family_story(names,
relationship_templates,
relationship_terms)
# Splitting the chain_story into a list of fragments
family_story_fragments = chain_story.split('*')
# Shuffling the list of fragments
random.shuffle(family_story_fragments)
# Joining the shuffled fragments back into a string
shuffled_story = ''.join(family_story_fragments)
last_person = names[-1]
# Generating the prompt based on the language
if language == 'Chinese':
prompt = (f"""
在上面提供的打乱的家族关系文本中'{last_person}'的能够向上追溯到的最年长的亲人是谁
例如
例子1.如果张强的父亲是马克除此以外提供的文本中没有更多关于亲属关系的信息那么在提供的文本中张强能够向上追溯到的最年长的亲人就是马克
例子2.如果李明的姥姥是张红而张红的父亲是张强除此以外提供的文本中没有更多关于亲属关系的信息那么在提供的文本中李明能够向上追溯到的最年长的亲人就是张强
例子3.如果小明是张红的曾孙女张红的祖母是王华王华的父亲是王刚除此以外提供的文本中没有更多关于亲属关系的信息那么小明能够向上追溯到的最年长的亲人就是王刚
""")
elif language == 'English':
prompt = (f"""
Given the scrambled family relationships described above, who is the eldest relative that '{last_person}' can trace back to in the context?
For example:
Example 1: If Zhang Qiang's father is Mark, and no further information about familial relationships is provided in the text, then the oldest relative Zhang Qiang can trace back to in the provided text is Mark.
Example 2: If Li Ming's grandmother is Zhang Hong, and Zhang Hong's father is Zhang Qiang, and no further information about familial relationships is provided in the text, then the oldest relative Li Ming can trace back to in the provided text is Zhang Qiang.
Example 3: If Xiao Ming is Zhang Hong's great-granddaughter, Zhang Hong's grandmother is Wang Hua, and Wang Hua's father is Wang Gang, and no further information about familial relationships is provided in the text, then the oldest relative Xiao Ming can trace back to in the provided text is Wang Gang."""
)
else:
prompt = 'Language not supported.'
raise Exception('Unsupported language specified. '
"Please choose either 'Chinese' or 'English'.")
# Combine story and prompt
shuffled_story_with_prompt = shuffled_story + ' ' + prompt
data['prompt'].append(shuffled_story_with_prompt)
data['answer'].append(names[0] + '*' + names[0])
dataset = Dataset.from_dict({
'prompt': data['prompt'],
'answer': data['answer'],
})
return dataset
@LOAD_DATASET.register_module()
class NeedleBenchATCOrderedDataset(BaseDataset):
@staticmethod
def load(
path,
num_needles: int,
language: str,
repeats: int,
):
data = {'prompt': [], 'answer': []}
with open(path, 'r', encoding='utf-8') as file:
names_data = json.load(file)
all_names = names_data[language].split(',')
for _ in range(repeats):
names = random.sample(all_names, num_needles)
if language == 'Chinese':
relationship_terms = [
'父亲', '母亲', '爸爸', '妈妈', '爷爷', '奶奶', '姥姥', '姥爷', '外公', '外婆'
]
relationship_templates = [
'{A}{B}{relationship}',
'{B}{relationship}{A}',
'{A}作为{B}{relationship},对{B}的成长有重要影响。',
'{A}不仅是{B}{relationship},还是{B}的榜样。',
'{B}{A}所生的孩子。',
'{A}{B}来说,不只是一个{relationship},还是一个朋友。',
'{A}{B}的生命中扮演着{relationship}的角色。',
'{B}{A}视为其{relationship}',
]
elif language == 'English':
relationship_terms = [
'father', 'mother', 'dad', 'mom', 'grandfather',
'grandmother', 'maternal grandmother',
'maternal grandfather', 'paternal grandfather',
'paternal grandmother'
]
relationship_templates = [
"{A} is {B}'s {relationship}.",
"{B}'s {relationship} is {A}.",
("{A}, as {B}'s {relationship}, "
"has a significant impact on {B}'s upbringing."),
("{A} is not only {B}'s {relationship} "
"but also {B}'s role model."),
'{B} is the child of {A}.',
('For {B}, {A} is not just a {relationship}, '
'but also a friend.'),
("{A} plays the role of {B}'s {relationship} "
"in {B}'s life."),
'{B} considers {A} as their {relationship}.',
]
def generate_chain_family_story(names, templates,
relationship_terms):
story = ''
for i in range(len(names) - 1):
template = random.choice(templates)
relation_term = random.choice(relationship_terms)
relation = template.format(A=names[i],
B=names[i + 1],
relationship=relation_term)
story += f'{relation}*'
return story
chain_story = generate_chain_family_story(names,
relationship_templates,
relationship_terms)
# Splitting the chain_story into a list of fragments
family_story_fragments = chain_story.split('*')
# Joining the shuffled fragments back into a string
shuffled_story = ''.join(family_story_fragments)
last_person = names[-1]
# Generating the prompt based on the language
if language == 'Chinese':
prompt = (f"""
在上面提供的打乱的家族关系文本中'{last_person}'的能够向上追溯到的最年长的亲人是谁
例如
例子1.如果张强的父亲是马克除此以外提供的文本中没有更多关于亲属关系的信息那么在提供的文本中张强能够向上追溯到的最年长的亲人就是马克
例子2.如果李明的姥姥是张红而张红的父亲是张强除此以外提供的文本中没有更多关于亲属关系的信息那么在提供的文本中李明能够向上追溯到的最年长的亲人就是张强
例子3.如果小明是张红的曾孙女张红的祖母是王华王华的父亲是王刚除此以外提供的文本中没有更多关于亲属关系的信息那么小明能够向上追溯到的最年长的亲人就是王刚
""")
elif language == 'English':
prompt = (f"""
Given the scrambled family relationships described above, who is the eldest relative that '{last_person}' can trace back to in the context?
For example:
Example 1: If Zhang Qiang's father is Mark, and no further information about familial relationships is provided in the text, then the oldest relative Zhang Qiang can trace back to in the provided text is Mark.
Example 2: If Li Ming's grandmother is Zhang Hong, and Zhang Hong's father is Zhang Qiang, and no further information about familial relationships is provided in the text, then the oldest relative Li Ming can trace back to in the provided text is Zhang Qiang.
Example 3: If Xiao Ming is Zhang Hong's great-granddaughter, Zhang Hong's grandmother is Wang Hua, and Wang Hua's father is Wang Gang, and no further information about familial relationships is provided in the text, then the oldest relative Xiao Ming can trace back to in the provided text is Wang Gang."""
)
else:
prompt = 'Language not supported.'
raise Exception('Unsupported language specified. '
"Please choose either 'Chinese' or 'English'.")
# Combine story and prompt
shuffled_story_with_prompt = shuffled_story + ' ' + prompt
data['prompt'].append(shuffled_story_with_prompt)
data['answer'].append(names[0] + '*' + names[0])
dataset = Dataset.from_dict({
'prompt': data['prompt'],
'answer': data['answer'],
})
return dataset

108
opencompass/datasets/cdme/cdme_multi.py → opencompass/datasets/needlebench/multi.py
View File

@ -1,6 +1,6 @@
import json
import os
import random
import re
from pathlib import Path
import tiktoken
@ -8,11 +8,31 @@ from datasets import Dataset
from opencompass.datasets.base import BaseDataset
from opencompass.openicl import BaseEvaluator
from opencompass.registry import LOAD_DATASET, TEXT_POSTPROCESSORS
from opencompass.registry import LOAD_DATASET
def get_random_needles(file_path, needle_count):
with open(file_path, 'r', encoding='utf-8') as file:
data = json.load(file)
matching_records = [
record for record in data
if record.get('derivation_count') == needle_count
]
if matching_records:
random_record = random.choice(matching_records)
return {
'needles': random_record['derivations'],
'answer': random_record['answer'],
'retrieval_question': random_record['question']
}
else:
return None
@LOAD_DATASET.register_module()
class CDMEDataset(BaseDataset):
class NeedleBenchMultiDataset(BaseDataset):
@staticmethod
def load(
@ -25,11 +45,9 @@ class CDMEDataset(BaseDataset):
length_buffer: int,
guide: bool,
language: str,
needles: 'list[str]',
needle_file_name: str,
num_needles: int,
diff: int,
retrieval_question: str,
answer: str,
keyword: str,
):
data = {'prompt': [], 'answer': []}
tokenizer = tiktoken.encoding_for_model(tokenizer_model)
@ -73,16 +91,14 @@ class CDMEDataset(BaseDataset):
def _modify_retrieval_question(retrieval_question):
if language == 'Chinese':
parts = retrieval_question.split('请按照')
guide_retrieval_question = (parts[0] + '在回答之前,请思考文档中与此问题'
'最相关的内容是什么。请按照' + parts[1])
guide_retrieval_question = (retrieval_question +
'在回答之前,请思考文档中与此问题'
'最相关的内容是什么。')
return guide_retrieval_question
elif language == 'English':
parts = retrieval_question.split('Please answer in the format')
guide_retrieval_question = (
parts[0] + 'Before answering, please consider'
' what in the document is most relevant to this question.'
' Please answer in the format' + parts[1])
retrieval_question + 'Before answering, please consider'
' what in the document is most relevant to this question.')
return guide_retrieval_question
else:
raise ValueError(f"Language '{language}' is not supported.")
@ -112,6 +128,7 @@ class CDMEDataset(BaseDataset):
return prompt
files = Path(path).glob('*.jsonl')
needle_file_path = os.path.join(path, needle_file_name)
for file in files:
if file.name not in file_list:
continue
@ -122,12 +139,20 @@ class CDMEDataset(BaseDataset):
for counter in range(num_repeats_per_file):
random.seed(counter)
random.shuffle(lines)
random_needle_data = get_random_needles(
needle_file_path, num_needles)
needles = [
'\n' + needle + '\n'
for needle in random_needle_data['needles']
]
answer = random_needle_data['answer']
keyword = answer
retrieval_question = random_needle_data['retrieval_question']
context_length = length - length_buffer
target_length_per_record = context_length - \
sum(len(tokens) for tokens
in _get_tokens_from_context(needles))
target_length_per_record = max(target_length_per_record, 0)
accumulated_tokens = []
for line in lines:
tokens_current_line = _get_tokens_from_context(
@ -154,7 +179,7 @@ class CDMEDataset(BaseDataset):
return dataset
class CDMEEvaluator(BaseEvaluator):
class NeedleBenchMultiEvaluator(BaseEvaluator):
def levenshtein_distance(self, s1, s2):
if len(s1) < len(s2):
@ -175,50 +200,33 @@ class CDMEEvaluator(BaseEvaluator):
return previous_row[-1]
def score(self, predictions, references):
if len(predictions) != len(references):
return {
'error': 'predictions and references have different lengths'
}
def score(self, predictions, gold):
if len(predictions) != len(gold):
return {'error': 'predictions and gold have different lengths'}
total_score = 0
details = []
for prediction, reference in zip(predictions, references):
keyword = reference.split('*')[1]
reference = reference.split('*')[0]
prediction = re.sub(r'\s+', '', prediction)
reference = re.sub(r'\s+', '', reference)
edit_distance = self.levenshtein_distance(prediction, reference)
max_len = max(len(prediction), len(reference))
score = 100 * (1 -
edit_distance / max_len) if max_len != 0 else 100
if keyword in prediction:
print(f'{keyword} is in {prediction}')
score = 100
else:
print(f'{keyword} is not in {prediction}')
score = 0.2 * score
for prediction, reference in zip(predictions, gold):
answer, keyword = reference.split('*')
keywords = keyword.lower().split()
prediction = prediction.lower()
keyword_score = 100 / len(keywords) if keywords else 0
matched_keywords = sum(1 for kword in keywords
if kword in prediction)
score = matched_keywords * keyword_score
detail = {
'pred': prediction,
'answer': reference,
'edit_distance': edit_distance,
'matched_keywords': matched_keywords,
'score': score
}
total_score += score
details.append(detail)
average_score = total_score / len(predictions) if predictions else 0
result = {'score': average_score, 'details': details}
return result
@TEXT_POSTPROCESSORS.register_module('cdme')
def cdme_postprocess(text: str) -> str:
return text
@TEXT_POSTPROCESSORS.register_module('cdme_dataset')
def cdme_dataset_postprocess(text: str) -> str:
return text
return {'score': average_score, 'details': details}

67
opencompass/datasets/cdme/cdme.py → opencompass/datasets/needlebench/origin.py
View File

@ -1,4 +1,5 @@
import json
import os
import random
import re
from pathlib import Path
@ -11,8 +12,26 @@ from opencompass.openicl import BaseEvaluator
from opencompass.registry import LOAD_DATASET, TEXT_POSTPROCESSORS
def get_random_line_by_language(file_path, language):
with open(file_path, 'r', encoding='utf-8') as file:
lines = [
json.loads(line.strip()) for line in file
if json.loads(line.strip())['language'] == language
]
if lines:
random_line = random.choice(lines)
return {
'needle': random_line['needle'],
'retrieval_question': random_line['retrieval_question'],
'keyword': random_line['arg2']
}
else:
return None
@LOAD_DATASET.register_module()
class CDMEDataset(BaseDataset):
class NeedleBenchOriginDataset(BaseDataset):
@staticmethod
def load(
@ -25,8 +44,7 @@ class CDMEDataset(BaseDataset):
length_buffer: int,
guide: bool,
language: str,
needle: str,
retrieval_question: str,
needle_file_name: str,
):
data = {'prompt': [], 'answer': []}
tokenizer = tiktoken.encoding_for_model(tokenizer_model)
@ -96,11 +114,17 @@ class CDMEDataset(BaseDataset):
for counter in range(num_repeats_per_file):
random.seed(counter)
random.shuffle(lines)
needle_file_path = os.path.join(path, needle_file_name)
random_needle = get_random_line_by_language(
needle_file_path, language)
needle = '\n' + random_needle['needle'] + '\n'
retrieval_question = random_needle['retrieval_question']
keyword = random_needle['keyword']
context_length = length - length_buffer
target_length_per_record = context_length - len(
_get_tokens_from_context(needle))
target_length_per_record = max(target_length_per_record, 0)
accumulated_tokens = []
for line in lines:
tokens_current_line = _get_tokens_from_context(
@ -118,7 +142,7 @@ class CDMEDataset(BaseDataset):
retrieval_question)
data['prompt'].append(processed_prompt)
data['answer'].append(needle)
data['answer'].append(needle + '*' + keyword)
dataset = Dataset.from_dict({
'prompt': data['prompt'],
@ -127,7 +151,7 @@ class CDMEDataset(BaseDataset):
return dataset
class CDMEEvaluator(BaseEvaluator):
class NeedleBenchOriginEvaluator(BaseEvaluator):
def __init__(self, use_trim=False):
self.use_trim = use_trim
@ -174,20 +198,22 @@ class CDMEEvaluator(BaseEvaluator):
return previous_row[-1]
def score(self, predictions, references):
if len(predictions) != len(references):
return {
'error': 'predictions and references have different lengths'
}
def score(self, predictions, gold):
if len(predictions) != len(gold):
return {'error': 'predictions and gold have different lengths'}
total_score = 0
details = []
for prediction, reference in zip(predictions, references):
for prediction, reference in zip(predictions, gold):
keyword = reference.split('*')[1]
reference = reference.split('*')[0]
raw_prediction = prediction
prediction = re.sub(r'\s+', '', prediction)
reference = re.sub(r'\s+', '', reference)
if self.use_trim:
prediction = CDMEEvaluator._trim_prediction(
prediction = NeedleBenchOriginEvaluator._trim_prediction(
prediction, reference)
edit_distance = self.levenshtein_distance(prediction, reference)
@ -195,6 +221,13 @@ class CDMEEvaluator(BaseEvaluator):
score = 100 * (1 -
edit_distance / max_len) if max_len != 0 else 100
if keyword in raw_prediction:
print(f'{keyword} is in {prediction}')
score = 100
else:
print(f'{keyword} is not in {prediction}')
score = 0.2 * score
detail = {
'pred': prediction,
'answer': reference,
@ -209,11 +242,11 @@ class CDMEEvaluator(BaseEvaluator):
return result
@TEXT_POSTPROCESSORS.register_module('cdme')
def cdme_postprocess(text: str) -> str:
@TEXT_POSTPROCESSORS.register_module('needlebench')
def needlebench_postprocess(text: str) -> str:
return text
@TEXT_POSTPROCESSORS.register_module('cdme_dataset')
def cdme_dataset_postprocess(text: str) -> str:
@TEXT_POSTPROCESSORS.register_module('needlebench_dataset')
def needlebench_dataset_postprocess(text: str) -> str:
return text

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import json
import random
from pathlib import Path
import tiktoken
from datasets import Dataset
from opencompass.datasets.base import BaseDataset
from opencompass.openicl import BaseEvaluator
from opencompass.registry import LOAD_DATASET
def get_unique_entries(file_path,
n,
language,
unique_arg1=False,
unique_arg2=False,
unique_combination=False):
seen_arg1 = set()
seen_arg2 = set()
seen_combinations = set()
results = []
with open(file_path, 'r', encoding='utf-8') as file:
lines = file.readlines()
random.shuffle(lines)
for line in lines:
try:
entry = json.loads(line.strip())
except json.JSONDecodeError:
continue
if entry.get('language') != language:
continue
key1 = entry.get('arg1', '') if unique_arg1 else ''
key2 = entry.get('arg2', '') if unique_arg2 else ''
combination = (key1, key2) if unique_combination else ''
if (key1 not in seen_arg1 or not unique_arg1) and \
(key2 not in seen_arg2 or not unique_arg2) and \
(combination not in seen_combinations or not unique_combination):
seen_arg1.add(key1)
seen_arg2.add(key2)
seen_combinations.add(combination)
results.append(entry)
if len(results) == n:
break
return results
@LOAD_DATASET.register_module()
class NeedleBenchParallelDataset(BaseDataset):
@staticmethod
def load(
path: str,
needle_file_name: str,
length: int,
depths: list[int],
tokenizer_model: str,
file_list: list[str],
num_repeats_per_file: int,
length_buffer: int,
guide: bool,
language: str,
):
data = {'prompt': [], 'answer': []}
tokenizer = tiktoken.encoding_for_model(tokenizer_model)
files = Path(path).glob('*.jsonl')
for file in files:
if file.name == needle_file_name:
needle_file_path = file
predefined_needles_bak = get_unique_entries(needle_file_path,
len(depths),
language,
unique_arg1=True,
unique_arg2=True,
unique_combination=True)
def _generate_context(tokens_context, depths, needles):
insertion_points = [
int(len(tokens_context) * (depth / 100)) for depth in depths
]
cumulative_inserted_length = 0
for i, needle in enumerate(needles):
needle_tokens = _get_tokens_from_context(needle)
current_insertion_point = min(
insertion_points[i] + cumulative_inserted_length,
len(tokens_context))
tokens_context = tokens_context[:current_insertion_point] + \
needle_tokens + tokens_context[current_insertion_point:]
cumulative_inserted_length += len(needle_tokens)
new_context = _decode_tokens(tokens_context)
return new_context
def _get_tokens_from_context(context):
if isinstance(context, list):
return [tokenizer.encode(item) for item in context]
else:
return tokenizer.encode(context)
def _decode_tokens(tokens):
return tokenizer.decode(tokens)
def _modify_retrieval_question(retrieval_question):
if language == 'Chinese':
parts = retrieval_question.split('请按照')
guide_retrieval_question = (parts[0] + '在回答之前,请思考文档中与此问题'
'最相关的内容是什么。请按照' + parts[1])
return guide_retrieval_question
elif language == 'English':
parts = retrieval_question.split('Please answer in the format')
guide_retrieval_question = (
parts[0] + 'Before answering, please consider'
' what in the document is most relevant to this question.'
' Please answer in the format' + parts[1])
return guide_retrieval_question
else:
raise ValueError(f"Language '{language}' is not supported.")
def _generate_prompt(context, retrieval_question):
if guide:
retrieval_question = _modify_retrieval_question(
retrieval_question)
if language == 'Chinese':
prompt = ('你是一个善于回答用户问题的智能AI助手\n'
'请保持你的回答简洁清楚。不要说和下面文档中的无关的话'
',或重复你的回答\n请先仔细阅读下面的文档再依次回答'
f'最后提出的问题\n用户现在给你的文档是{context}\n\n'
f'现在请问:{retrieval_question}\n')
elif language == 'English':
prompt = (
'You are an intelligent AI assistant skilled in '
'answering user questions.\n'
'Please keep your answers concise and clear. Do not'
' talk about irrelevant topics or repeat your '
'answers.\n'
f'The document given to you by the user is {context}'
f'\n\nNow, the questions are: {retrieval_question}\n')
else:
raise ValueError(f"Language '{language}' is not supported.")
return prompt
files = Path(path).glob('*.jsonl')
for file in files:
if file.name not in file_list:
continue
with open(file, 'r', encoding='utf-8') as f:
lines_bak = [json.loads(line.strip()) for line in f]
lines = lines_bak.copy()
for counter in range(num_repeats_per_file):
random.seed(counter)
random.shuffle(lines)
predefined_needles = predefined_needles_bak.copy()
random.shuffle(predefined_needles)
needles = [
'\n' + item['needle'] + '\n' for item in predefined_needles
]
keywords = [item['arg2'] for item in predefined_needles]
if language == 'Chinese':
questions = ''.join([
item['retrieval_question'].split('')[0] + ''
for item in predefined_needles
])
answers_format = ''.join([
item['retrieval_question'].split("'")[1].split('')[0]
for item in predefined_needles
])
retrieval_question = questions + "请按照'" + \
answers_format + "'的格式回答。"
elif language == 'English':
questions = ''.join([
item['retrieval_question'].split('?')[0] + '?'
for item in predefined_needles
])
answers_format = ''.join([
item['retrieval_question'].split("'")[1].split('.')[0]
for item in predefined_needles
])
retrieval_question = questions + \
"Please answer in the format of '" + \
answers_format + "'"
context_length = length - length_buffer
target_length_per_record = context_length - \
sum(len(tokens) for tokens
in _get_tokens_from_context(needles))
target_length_per_record = max(target_length_per_record, 0)
accumulated_tokens = []
for line in lines:
tokens_current_line = _get_tokens_from_context(
line['text'])
accumulated_tokens.extend(tokens_current_line)
if len(accumulated_tokens) >= target_length_per_record:
break
processed_text = _generate_context(
accumulated_tokens[:target_length_per_record], depths,
needles)
processed_prompt = _generate_prompt(processed_text,
retrieval_question)
data['prompt'].append(processed_prompt)
data['answer'].append('*'.join(keywords) + '#' +
'*'.join(map(str, depths)))
dataset = Dataset.from_dict({
'prompt': data['prompt'],
'answer': data['answer'],
})
return dataset
class NeedleBenchParallelEvaluator(BaseEvaluator):
def levenshtein_distance(self, s1, s2):
if len(s1) < len(s2):
return self.levenshtein_distance(s2, s1)
if len(s2) == 0:
return len(s1)
previous_row = range(len(s2) + 1)
for i, c1 in enumerate(s1):
current_row = [i + 1]
for j, c2 in enumerate(s2):
insertions = previous_row[j + 1] + 1
deletions = current_row[j] + 1
substitutions = previous_row[j] + (c1 != c2)
current_row.append(min(insertions, deletions, substitutions))
previous_row = current_row
return previous_row[-1]
def score(self, predictions, gold):
if len(predictions) != len(gold):
return {'error': 'predictions and gold have different lengths'}
print('predictions:', predictions)
print('gold:', gold)
details = []
depths = [int(i) for i in gold[0].split('#')[1].split('*')]
scores_by_depth = {depth: 0 for depth in depths}
for prediction, reference in zip(predictions, gold):
print(reference)
keywords = reference.split('#')[0].split('*')
print(keywords)
for keyword, depth in zip(keywords, depths):
print('iterating:', keyword, depth)
if keyword in prediction:
print(f'{keyword} at depth {depth} is in {prediction}')
scores_by_depth[depth] += 100 / (len(predictions))
average_score = sum(scores_by_depth.values()) / len(scores_by_depth)
flattened_scores = {
'Depth' + str(depth): score
for depth, score in scores_by_depth.items()
}
result = {
**flattened_scores, 'details': details,
'average_score': average_score
}
return result

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# flake8: noqa
# yapf: disable
import functools
import getpass
import math
import os
import os.path as osp
from datetime import datetime
from typing import Any, Dict, List, Optional
import matplotlib.pyplot as plt
import mmengine
import numpy as np
import pandas as pd
import seaborn as sns
import tabulate
from matplotlib.colors import LinearSegmentedColormap
from mmengine import ConfigDict
from tqdm import tqdm
from opencompass.summarizers.default import (
METRIC_BLACKLIST, METRIC_WHITELIST, DefaultSummarizer,
model_abbr_from_cfg_used_in_summarizer)
from opencompass.utils import (LarkReporter, dataset_abbr_from_cfg,
get_infer_output_path, get_logger,
model_abbr_from_cfg)
from opencompass.utils.prompt import get_prompt_hash
def read_after_specific_line_except_last(file_name, keyword, offset):
with open(file_name, 'r', encoding='utf-8') as file:
lines = file.readlines()
for index, line in enumerate(lines):
if keyword in line:
start_index = index + offset + 1
break
else:
return ''
return ''.join(lines[start_index:-1])
def create_model_dataframe(nested_dict, model_name, dataset_abbr, parallel=False):
if model_name not in nested_dict:
print(f'Model {model_name} not found in the provided data.')
return pd.DataFrame()
model_data = nested_dict[model_name]
data = []
for key, value in model_data.items():
if parallel:
if dataset_abbr in key:
new_key_base = key.replace(dataset_abbr, '').strip('_')
for depth_key, score in value.items():
new_key = f'{new_key_base}{depth_key}'
if 'average_score' not in new_key:
data.append([new_key, score])
else:
if dataset_abbr in key:
score = value.get('score', None)
new_key = key.replace(dataset_abbr, '').strip('_')
data.append([new_key, score])
df = pd.DataFrame(data, columns=['dataset', model_name])
return df
def parse_model_scores(text):
lines = text.split('\n')
result_dict = {}
current_model = None
for line in lines:
if line.startswith('Model:'):
current_model = line.split('Model:')[1].strip()
result_dict[current_model] = {}
elif current_model and ':' in line:
dataset, score_str = line.split(':', 1)
score_dict = eval(score_str.strip())
result_dict[current_model][dataset] = score_dict
return result_dict
def visualize(df_raw, save_path: str,model_name: str ,dataset_type:str):
df = df_raw.copy()
df['Context Length'] = df['dataset'].apply(
lambda x: int(x.split('Length')[1].split('Depth')[0]))
df['Document Depth'] = df['dataset'].apply(
lambda x: float(x.split('Depth')[1].split('_')[0]))
model_columns = [
col for col in df.columns
if col not in ['Context Length', 'Document Depth']
]
for model_name in model_columns[1:]:
model_df = df[['Document Depth', 'Context Length',
model_name]].copy()
model_df.rename(columns={model_name: 'Score'}, inplace=True)
# Create pivot table
pivot_table = pd.pivot_table(model_df,
values='Score',
index=['Document Depth'],
columns=['Context Length'],
aggfunc='mean')
# Calculate mean scores
mean_scores = pivot_table.mean().values
# Calculate overall score
overall_score = mean_scores.mean()
# Create heatmap and line plot
plt.figure(figsize=(15.5, 8))
ax = plt.gca()
cmap = LinearSegmentedColormap.from_list(
'custom_cmap', ['#F0496E', '#EBB839', '#0CD79F'])
# Draw heatmap
sns.heatmap(pivot_table,
cmap=cmap,
ax=ax,
cbar_kws={'label': 'Score'},
vmin=0,
vmax=100)
# Set line plot data
x_data = [i + 0.5 for i in range(len(mean_scores))]
y_data = mean_scores
# Create twin axis for line plot
ax2 = ax.twinx()
# Draw line plot
ax2.plot(x_data,
y_data,
color='white',
marker='o',
linestyle='-',
linewidth=2,
markersize=8,
label='Average Depth Score')
# Set y-axis range
ax2.set_ylim(0, 100)
# Hide original y-axis ticks and labels
ax2.set_yticklabels([])
ax2.set_yticks([])
# Add legend
ax2.legend(loc='upper left')
# Set chart title and labels
ax.set_title(f'{model_name} {dataset_type} Context '
'Performance\nFact Retrieval Across '
'Context Lengths ("Needle In A Haystack")')
ax.set_xlabel('Token Limit')
ax.set_ylabel('Depth Percent')
ax.set_xticklabels(pivot_table.columns.values, rotation=45)
ax.set_yticklabels(pivot_table.index.values, rotation=0)
# Add overall score as a subtitle
plt.text(0.5,
-0.13, f'Overall Score for {model_name}: '
f'{overall_score:.2f}',
ha='center',
va='center',
transform=ax.transAxes,
fontsize=13)
plt.tight_layout()
plt.subplots_adjust(right=1)
plt.draw()
plt.savefig(save_path)
print(f'Saved :{save_path}')
plt.close() # Close figure to prevent memory leaks
return overall_score
def save_results_to_plots(txt_results_save_path):
content = read_after_specific_line_except_last(txt_results_save_path, 'raw format', 2)
parsed_data = parse_model_scores(content)
model_names = get_dict_model_names(parsed_data)
numbers = [2, 3, 4, 5]
languages = ['en', 'zh']
size_exists = []
sizes_origin = ['_4k', '_8k', '_32k', '_128k', '_200k']
for size in sizes_origin:
if size in content:
size_exists.append(size)
multi_dataset_abbrs = [f'{num}needle_{lang}{size}' for num in numbers for lang in languages for size in size_exists]
origin_dataset_abbrs = [f'origin_{lang}{size}' for lang in languages for size in size_exists]
parallel_dataset_abbrs = [f'parallel_{lang}{size}' for lang in languages for size in size_exists]
dataset_abbrs = multi_dataset_abbrs + origin_dataset_abbrs + \
parallel_dataset_abbrs
base_path = os.path.dirname(txt_results_save_path)
plot_path = os.path.join(base_path, 'plots')
model_scores = {}
for model_name in tqdm(model_names):
model_datasets_scores = {} # Dictionary to store scores for each dataset for the current model
for dataset_abbr in dataset_abbrs:
parallel_flag = 'parallel' in dataset_abbr
# Create a directory for each dataset_abbr
folder_path = os.path.join(plot_path, dataset_abbr)
ensure_directory(folder_path)
# Construct the full path to save the image
save_path = os.path.join(folder_path, f'{model_name}.png')
# Create DataFrame for the model and dataset
df = create_model_dataframe(parsed_data, model_name, dataset_abbr, parallel=parallel_flag)
# Generate visualization and get the score
score = visualize(df, save_path, model_name, dataset_abbr)
# Store the score in the dictionary
model_datasets_scores[dataset_abbr] = '{:.02f}'.format(score)
# Process and visualize the overall score
overall_score_pic_path = os.path.join(plot_path, f'{model_name}_overall.png')
merged_df = merge_dataframes(model_name, dataset_abbrs, parsed_data)
print(merge_dataframes)
averaged_df = calculate_elementwise_average(merged_df)
# Assume visualize returns the average score for the overall visualization
overall_score = visualize(averaged_df, overall_score_pic_path, 'weighted_average_score', 'Overall Score')
# Add the overall score to the dictionary
model_datasets_scores['Overall'] = '{:.02f}'.format(overall_score)
# Add the model's scores to the main dictionary
model_scores[model_name] = model_datasets_scores
def ensure_directory(path):
if not os.path.exists(path):
os.makedirs(path)
def get_dict_model_names(nested_dict):
model_names = []
for first_level_key in nested_dict:
model_names.append(first_level_key)
return model_names
def merge_dataframes(model_name, dataset_abbrs, parsed_data):
dfs = []
for dataset_abbr in dataset_abbrs:
parallel_flag = 'parallel' in dataset_abbr
df = create_model_dataframe(parsed_data, model_name, dataset_abbr, parallel=parallel_flag)
if not df.empty and len(df.columns) > 1:
score_column = df.columns[-1]
df.rename(columns={score_column: dataset_abbr}, inplace=True)
dfs.append(df)
from functools import reduce
merged_df = reduce(lambda left, right: pd.merge(left, right, on='dataset', how='outer'), dfs)
if merged_df.isnull().any().any():
print('Warning: Some rows were filtered out due to NaN values. This is often due to mismatched row counts among DataFrames.')
merged_df = merged_df.dropna()
return merged_df
def calculate_elementwise_average(merged_df):
score_columns = [col for col in merged_df.columns if col != 'dataset']
origin_columns = [col for col in score_columns if 'origin' in col]
parallel_columns = [col for col in score_columns if 'parallel' in col]
multi_columns = [col for col in score_columns if 'needle' in col]
if origin_columns and parallel_columns and multi_columns:
origin_avg = merged_df[origin_columns].mean(axis=1) * 0.4
parallel_avg = merged_df[parallel_columns].mean(axis=1) * 0.3
multi_avg = merged_df[multi_columns].mean(axis=1) * 0.3
merged_df['weighted_average_score'] = origin_avg + parallel_avg + multi_avg
else:
merged_df['weighted_average_score'] = pd.Series([0] * len(merged_df))
return merged_df.iloc[:, [0, -1]]
class NeedleBenchSummarizer(DefaultSummarizer):
"""NeedleBench summarizer in OpenCompass.
Args:
config (ConfigDict): The configuration object of the evaluation task. It's expected to be filled out at runtime.
dataset_abbrs (list[str], optional): Dataset abbreviations to be listed in the summary.
summary_groups (list): The dataset groups whose results need to be averaged out. For example, mmlu. Each item it a dict with
'name' (str) and 'subsets' (list of dataset abbrs), and optionally
'weights' if weighted average is needed.
prompt_db: A deprecated field.
"""
def _format_table(self, parsed_results, dataset_metrics, dataset_eval_mode):
dataset_abbrs = [dataset_abbr_from_cfg(dataset) for dataset in self.dataset_cfgs]
prompt_version = {dataset_abbr_from_cfg(d): get_prompt_hash(d)[:6] for d in self.dataset_cfgs}
summarizer_dataset_abbrs = []
if self.dataset_abbrs is None:
# display all dataset metrics included in the config
for dataset_abbr in dataset_abbrs:
if dataset_abbr in dataset_metrics:
for metric in dataset_metrics[dataset_abbr]:
summarizer_dataset_abbrs.append((dataset_abbr, metric))
else:
summarizer_dataset_abbrs.append((dataset_abbr, None))
# along with all possible group metrics
for dataset_abbr in dataset_metrics:
for metric in dataset_metrics[dataset_abbr]:
if (dataset_abbr, metric) not in summarizer_dataset_abbrs:
summarizer_dataset_abbrs.append((dataset_abbr, metric))
else:
# follow the required order
for item in self.dataset_abbrs:
if isinstance(item, str):
summarizer_dataset_abbrs.append((item, None))
elif isinstance(item, (list, tuple)):
summarizer_dataset_abbrs.append((item[0], item[1]))
table = []
header = ['dataset', 'version', 'metric', 'mode'] + self.model_abbrs
table.append(header)
for key in dataset_metrics:
dataset_metrics[key] = list(set(dataset_metrics[key]))
for dataset_abbr, metric in summarizer_dataset_abbrs:
if dataset_abbr not in dataset_metrics:
table.append([dataset_abbr, '-', '-', '-'] + ['-'] * len(self.model_abbrs))
table.append(header)
continue
if len(dataset_metrics[dataset_abbr]) >= 10:
metric = 'average_score'
if metric is None:
metric = dataset_metrics[dataset_abbr][0]
elif metric in dataset_metrics[dataset_abbr]:
pass
else:
table.append([dataset_abbr, '-', '-', '-'] + ['-'] * len(self.model_abbrs))
continue
row = [dataset_abbr, prompt_version.get(dataset_abbr, '-'), metric, dataset_eval_mode.get(dataset_abbr, '-')]
for model_abbr in self.model_abbrs:
if dataset_abbr in parsed_results[model_abbr]:
row.append('{:.02f}'.format(parsed_results[model_abbr][dataset_abbr][metric]))
else:
row.append('-')
table.append(row)
for i in range(len(table)):
if i == 0 or table[i][0].startswith('---------'):
table[i] = [table[i][0]] + table[i][4:]
else:
table[i] = [table[i][0]] + table[i][4:]
return table
def _format_raw_txt(self, raw_results):
raw_dataset_abbrs = []
for model_abbr in self.model_abbrs:
for dataset_abbr in raw_results[model_abbr]:
if dataset_abbr not in raw_dataset_abbrs:
raw_dataset_abbrs.append(dataset_abbr)
raw_txts = []
for model_abbr in self.model_abbrs:
raw_txts.append('-------------------------------')
raw_txts.append(f'Model: {model_abbr}')
for dataset_abbr in raw_dataset_abbrs:
result = raw_results[model_abbr].get(dataset_abbr, '{}')
raw_txts.append(f'{dataset_abbr}: {result}')
raw_txts = '\n'.join(raw_txts)
return raw_txts
def _read_and_sort_dataframe(self, file_path):
# Read the file without treating the first row as a header
df = pd.read_csv(file_path, header=None)
# Function to sort columns based on the value of a specific row, excluding the first column
def sort_columns_based_on_row_corrected(df, base_row_idx, start_row_idx, end_row_idx):
# Extract the rows for sorting
sort_values_row = df.iloc[base_row_idx, 1:].replace('-', np.nan).apply(pd.to_numeric, errors='coerce')
# Handle NaNs by setting them to a value less than the minimum or using a method to keep them at the end
min_possible_value = sort_values_row.min(skipna=True) - 1 # Use min value in the row minus 1 or another method
sort_values_row_filled = sort_values_row.fillna(min_possible_value)
# Get the sorted order of indices, excluding the first column
sorted_col_indices = sort_values_row_filled.sort_values(ascending=False).index
# Apply the sorted column indices to the whole DataFrame, adjusting for Python's 0-based index
df.iloc[start_row_idx:end_row_idx+1] = df.iloc[start_row_idx:end_row_idx+1, [0] + sorted_col_indices.tolist()]
# Apply the corrected sorting function based on the description
sort_columns_based_on_row_corrected(df, 1, 0, 2) # For rows 1-2 based on row 2's values
sort_columns_based_on_row_corrected(df, 4, 3, 7) # For rows 4-7 based on row 5's values
sort_columns_based_on_row_corrected(df, 9, 8, 12) # For rows 9-12 based on row 10's values
sort_columns_based_on_row_corrected(df, 14, 13, 25) # For rows 14-25 based on row 15's values
# Return the sorted DataFrame
return df
def _output_to_file(self, output_path, time_str, table, raw_txts):
# output to file
if output_path is None:
output_path = osp.join(self.work_dir, 'summary', f'summary_{time_str}.txt')
output_csv_path = osp.join(self.work_dir, 'summary', f'summary_{time_str}.csv')
else:
output_csv_path = output_path.replace('.txt', '.csv')
output_dir = osp.split(output_path)[0]
mmengine.mkdir_or_exist(output_dir)
with open(output_path, 'w', encoding='utf-8') as f:
text = f'{time_str}\n' + \
'tabulate format\n' + \
'^' * 128 + '\n' + \
tabulate.tabulate(table, headers='firstrow') + '\n' + \
'$' * 128 + '\n\n' + \
'-' * 128 + ' THIS IS A DIVIDER ' + '-' * 128 + '\n\n' + \
'csv format\n' + \
'^' * 128 + '\n' + \
'\n'.join([','.join(row) for row in table]) + '\n' + \
'$' * 128 + '\n\n' + \
'-' * 128 + ' THIS IS A DIVIDER ' + '-' * 128 + '\n\n' + \
'raw format\n' + \
'^' * 128 + '\n' + \
raw_txts + '\n' + \
'$' * 128 + '\n'
f.write(text)
self.logger.info(f'write summary to {osp.abspath(output_path)}')
with open(output_csv_path, 'w', encoding='utf-8') as f:
f.write('\n'.join([','.join(row) for row in table]) + '\n')
self.logger.info(f'write csv to {osp.abspath(output_csv_path)}')
df_sorted = self._read_and_sort_dataframe(output_csv_path)
sorted_file_path = osp.abspath(output_csv_path).split('.')[0] + '_sorted.csv'
df_sorted.to_csv(sorted_file_path, index=False, header=False)
self.logger.info(f'write sorted csv to {sorted_file_path}')
def summarize(
self,
output_path: str = None,
time_str: str = datetime.now().strftime('%Y%m%d_%H%M%S')): # noqa
# pick up results
raw_results, parsed_results, dataset_metrics, dataset_eval_mode = self._pick_up_results()
# calculate group metrics
raw_results, parsed_results, dataset_metrics, dataset_eval_mode = \
self._calculate_group_metrics(raw_results, parsed_results, dataset_metrics, dataset_eval_mode)
# format table
table = self._format_table(parsed_results, dataset_metrics, dataset_eval_mode)
# format raw txt
raw_txts = self._format_raw_txt(raw_results)
# output to screen
print(tabulate.tabulate(table, headers='firstrow'))
# output to .text / .csv files
self._output_to_file(output_path, time_str, table, raw_txts)
if self.lark_reporter:
content = f'{getpass.getuser()}'
content += f'详细评测汇总已输出至 {osp.abspath(output_path)}'
self.lark_reporter.post(content)
if output_path is None:
output_path = osp.join(self.work_dir, 'summary', f'summary_{time_str}.txt')
# plot to show visualize results
save_results_to_plots(output_path)
class NeedleBenchATCSummarizer(DefaultSummarizer):
"""NeedleBench-ATC summarizer in OpenCompass.
Args:
config (ConfigDict): The configuration object of the evaluation task. It's expected to be filled out at runtime.
dataset_abbrs (list[str], optional): Dataset abbreviations to be listed in the summary.
summary_groups (list): The dataset groups whose results need to be averaged out. For example, mmlu. Each item it a dict with
'name' (str) and 'subsets' (list of dataset abbrs), and optionally
'weights' if weighted average is needed.
prompt_db: A deprecated field.
"""
def _format_table(self, parsed_results, dataset_metrics, dataset_eval_mode):
dataset_abbrs = [dataset_abbr_from_cfg(dataset) for dataset in self.dataset_cfgs]
prompt_version = {dataset_abbr_from_cfg(d): get_prompt_hash(d)[:6] for d in self.dataset_cfgs}
summarizer_dataset_abbrs = []
if self.dataset_abbrs is None:
# display all dataset metrics included in the config
for dataset_abbr in dataset_abbrs:
if dataset_abbr in dataset_metrics:
for metric in dataset_metrics[dataset_abbr]:
summarizer_dataset_abbrs.append((dataset_abbr, metric))
else:
summarizer_dataset_abbrs.append((dataset_abbr, None))
# along with all possible group metrics
for dataset_abbr in dataset_metrics:
for metric in dataset_metrics[dataset_abbr]:
if (dataset_abbr, metric) not in summarizer_dataset_abbrs:
summarizer_dataset_abbrs.append((dataset_abbr, metric))
else:
# follow the required order
for item in self.dataset_abbrs:
if isinstance(item, str):
summarizer_dataset_abbrs.append((item, None))
elif isinstance(item, (list, tuple)):
summarizer_dataset_abbrs.append((item[0], item[1]))
table = []
header = ['dataset', 'version', 'metric', 'mode'] + self.model_abbrs
table.append(header)
for key in dataset_metrics:
dataset_metrics[key] = list(set(dataset_metrics[key]))
for dataset_abbr, metric in summarizer_dataset_abbrs:
if dataset_abbr not in dataset_metrics:
table.append([dataset_abbr, '-', '-', '-'] + ['-'] * len(self.model_abbrs))
table.append(header)
continue
if len(dataset_metrics[dataset_abbr]) >= 10:
metric = 'average_score'
if metric is None:
metric = dataset_metrics[dataset_abbr][0]
elif metric in dataset_metrics[dataset_abbr]:
pass
else:
table.append([dataset_abbr, '-', '-', '-'] + ['-'] * len(self.model_abbrs))
continue
row = [dataset_abbr, prompt_version.get(dataset_abbr, '-'), metric, dataset_eval_mode.get(dataset_abbr, '-')]
for model_abbr in self.model_abbrs:
if dataset_abbr in parsed_results[model_abbr]:
row.append('{:.02f}'.format(parsed_results[model_abbr][dataset_abbr][metric]))
else:
row.append('-')
table.append(row)
for i in range(len(table)):
if i == 0 or table[i][0].startswith('---------'):
table[i] = [table[i][0]] + table[i][4:]
else:
table[i] = [table[i][0]] + table[i][4:]
return table
def _read_and_sort_dataframe(self, file_path):
# Read the file without treating the first row as a header
data = pd.read_csv(file_path)
# print(data)
# Correct the extraction of needle counts for all settings
data['needle_count'] = data['dataset'].str.extract(r'needle_(\d+)_').astype(float)
data['needle_count'] = data['needle_count'].astype(int)
# Define experimental settings groups
experimental_settings = {
'en': '_en$',
'zh': '_zh$',
'en_ordered': '_en_ordered',
'zh_ordered': '_zh_ordered',
}
# Function to calculate maximum needles
def calculate_max_needles(dataset):
max_needles = {model: None for model in dataset.columns if 'b' in model}
for model in max_needles.keys():
consecutive_low_scores = 0
previous_needle_count = 0
for index, row in dataset.sort_values(by='needle_count').iterrows():
try:
score = float(row[model])
except ValueError as e:
score = -1
if score < 60:
consecutive_low_scores += 1
if consecutive_low_scores == 1:
max_needles[model] = previous_needle_count
else:
consecutive_low_scores = 0
previous_needle_count = row['needle_count']
max_needle_count_seen = dataset['needle_count'].max()
max_needles[model] = max_needle_count_seen if max_needles[model] is None else max_needles[model]
return max_needles
# Calculate max needles for each group and organize results in a DataFrame
results = {}
for setting, regex in experimental_settings.items():
filtered_data = data[data['dataset'].str.contains(regex)]
results[setting] = calculate_max_needles(filtered_data)
# Convert results to DataFrame and transpose it
results_df = pd.DataFrame(results).transpose()
# Return the sorted DataFrame
results_df.index.name = 'ATC Experiment Type'
return results_df
def _output_to_file(self, output_path, time_str, table, raw_txts):
# output to file
if output_path is None:
output_path = osp.join(self.work_dir, 'summary', f'summary_{time_str}.txt')
output_csv_path = osp.join(self.work_dir, 'summary', f'summary_{time_str}.csv')
else:
output_csv_path = output_path.replace('.txt', '.csv')
output_dir = osp.split(output_path)[0]
mmengine.mkdir_or_exist(output_dir)
with open(output_path, 'w', encoding='utf-8') as f:
text = f'{time_str}\n' + \
'tabulate format\n' + \
'^' * 128 + '\n' + \
tabulate.tabulate(table, headers='firstrow') + '\n' + \
'$' * 128 + '\n\n' + \
'-' * 128 + ' THIS IS A DIVIDER ' + '-' * 128 + '\n\n' + \
'csv format\n' + \
'^' * 128 + '\n' + \
'\n'.join([','.join(row) for row in table]) + '\n' + \
'$' * 128 + '\n\n' + \
'-' * 128 + ' THIS IS A DIVIDER ' + '-' * 128 + '\n\n' + \
'raw format\n' + \
'^' * 128 + '\n' + \
raw_txts + '\n' + \
'$' * 128 + '\n'
f.write(text)
self.logger.info(f'write summary to {osp.abspath(output_path)}')
with open(output_csv_path, 'w', encoding='utf-8') as f:
f.write('\n'.join([','.join(row) for row in table]) + '\n')
# self.logger.info(f'write csv to {osp.abspath(output_csv_path)}')
df_sorted = self._read_and_sort_dataframe(output_csv_path)
df_sorted.to_csv(output_csv_path)
self.logger.info(f'write sorted csv to {output_csv_path}')
def summarize(
self,
output_path: str = None,
time_str: str = datetime.now().strftime('%Y%m%d_%H%M%S')): # noqa
# pick up results
raw_results, parsed_results, dataset_metrics, dataset_eval_mode = self._pick_up_results()
# calculate group metrics
raw_results, parsed_results, dataset_metrics, dataset_eval_mode = \
self._calculate_group_metrics(raw_results, parsed_results, dataset_metrics, dataset_eval_mode)
# format table
table = self._format_table(parsed_results, dataset_metrics, dataset_eval_mode)
# format raw txt
raw_txts = self._format_raw_txt(raw_results)
# output to .text / .csv files
self._output_to_file(output_path, time_str, table, raw_txts)
if self.lark_reporter:
content = f'{getpass.getuser()}'
content += f'详细评测汇总已输出至 {osp.abspath(output_path)}'
self.lark_reporter.post(content)
if output_path is None:
output_path = osp.join(self.work_dir, 'summary', f'summary_{time_str}.txt')

136
tools/tools_needleinahaystack.py
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@ -1,136 +0,0 @@
import argparse
import matplotlib.pyplot as plt
import pandas as pd
import seaborn as sns
from matplotlib.colors import LinearSegmentedColormap
class CDMEDataset():
@staticmethod
def visualize(path: str, dataset_length: str):
for file_path in path:
df = pd.read_csv(file_path)
df['Context Length'] = df['dataset'].apply(
lambda x: int(x.split('Length')[1].split('Depth')[0]))
df['Document Depth'] = df['dataset'].apply(
lambda x: float(x.split('Depth')[1].split('_')[0]))
# Exclude 'Context Length' and 'Document Depth' columns
model_columns = [
col for col in df.columns
if col not in ['Context Length', 'Document Depth']
]
for model_name in model_columns[4:]:
model_df = df[['Document Depth', 'Context Length',
model_name]].copy()
model_df.rename(columns={model_name: 'Score'}, inplace=True)
# Create pivot table
pivot_table = pd.pivot_table(model_df,
values='Score',
index=['Document Depth'],
columns=['Context Length'],
aggfunc='mean')
# Calculate mean scores
mean_scores = pivot_table.mean().values
# Calculate overall score
overall_score = mean_scores.mean()
# Create heatmap and line plot
plt.figure(figsize=(15.5, 8))
ax = plt.gca()
cmap = LinearSegmentedColormap.from_list(
'custom_cmap', ['#F0496E', '#EBB839', '#0CD79F'])
# Draw heatmap
sns.heatmap(pivot_table,
cmap=cmap,
ax=ax,
cbar_kws={'label': 'Score'},
vmin=0,
vmax=100)
# Set line plot data
x_data = [i + 0.5 for i in range(len(mean_scores))]
y_data = mean_scores
# Create twin axis for line plot
ax2 = ax.twinx()
# Draw line plot
ax2.plot(x_data,
y_data,
color='white',
marker='o',
linestyle='-',
linewidth=2,
markersize=8,
label='Average Depth Score')
# Set y-axis range
ax2.set_ylim(0, 100)
# Hide original y-axis ticks and labels
ax2.set_yticklabels([])
ax2.set_yticks([])
# Add legend
ax2.legend(loc='upper left')
# Set chart title and labels
ax.set_title(f'{model_name} {dataset_length} Context '
'Performance\nFact Retrieval Across '
'Context Lengths ("Needle In A Haystack")')
ax.set_xlabel('Token Limit')
ax.set_ylabel('Depth Percent')
ax.set_xticklabels(pivot_table.columns.values, rotation=45)
ax.set_yticklabels(pivot_table.index.values, rotation=0)
# Add overall score as a subtitle
plt.text(0.5,
-0.13, f'Overall Score for {model_name}: '
f'{overall_score:.2f}',
ha='center',
va='center',
transform=ax.transAxes,
fontsize=13)
# Save heatmap as PNG
png_file_path = file_path.replace('.csv', f'_{model_name}.png')
plt.tight_layout()
plt.subplots_adjust(right=1)
plt.draw()
plt.savefig(png_file_path)
plt.show()
plt.close() # Close figure to prevent memory leaks
# Print saved PNG file path
print(f'Heatmap for {model_name} saved as: {png_file_path}')
def main():
parser = argparse.ArgumentParser(description='Generate NeedleInAHaystack'
'Test Plots')
parser.add_argument('--path',
nargs='*',
default=['path/to/your/result.csv'],
help='Paths to CSV files for visualization')
parser.add_argument('--dataset_length',
default='8K',
type=str,
help='Dataset_length for visualization')
args = parser.parse_args()
if not args.path:
print("Error: '--path' is required for visualization.")
exit(1)
CDMEDataset.visualize(args.path, args.dataset_length)
if __name__ == '__main__':
main()