DataTrove is a library to process, filter and deduplicate text data at a very large scale. It provides a set of prebuilt commonly used processing blocks with a framework to easily add custom functionality.
DataTrove processing pipelines are platform-agnostic, running out of the box locally or on a slurm cluster. Its (relatively) low memory usage and multiple step design makes it ideal for large workloads, such as to process an LLM's training data.
Local, remote and other file systems are supported through fsspec.
- Installation
- Quickstart examples
- Terminology
- Pipeline
- Executors
- Logging
- DataFolder / paths
- Practical guides
- Contributing
- Citation
pip install datatrove[FLAVOUR]
Available flavours (combine them with ,
i.e. [processing,s3]
):
all
installs everything:pip install datatrove[all]
io
dependencies to readwarc/arc/wet
files and arrow/parquet formats:pip install datatrove[io]
processing
dependencies for text extraction, filtering and tokenization:pip install datatrove[processing]
s3
s3 support:pip install datatrove[s3]
cli
for command line tools:pip install datatrove[cli]
You can check the following examples:
- fineweb.py full reproduction of the FineWeb dataset
- process_common_crawl_dump.py full pipeline to read commoncrawl warc files, extract their text content, filters and save the resulting data to s3. Runs on slurm
- tokenize_c4.py reads data directly from huggingface's hub to tokenize the english portion of the C4 dataset using the
gpt2
tokenizer - minhash_deduplication.py full pipeline to run minhash deduplication of text data
- sentence_deduplication.py example to run sentence level exact deduplication
- exact_substrings.py example to run ExactSubstr (requires this repo)
pipeline
: a list of processing steps to execute (read data, filter, write to disk, etc)executor
: runs a specific pipeline on a given execution environment (slurm, multi cpu machine, etc)job
: the execution of a pipeline on a given executortask
: ajob
is comprised of multipletasks
, and these are used to parallelize execution, usually by having eachtask
process ashard
of data. Datatrove keeps track of which tasks have completed and when you relaunch only incomplete tasks will run.file
: an individual input file (.json, .csv, etc).
Tip
Note that each file will be processed by a single task
. Datatrove does not automatically split a file into multiple parts, so to fully parallelize you should have multiple medium sized files rather than a single large file)
shard
: a group of input data (usually a group offile
s), which will be assigned to a specifictask
. Eachtask
will process a different non overlappingshard
of data, from the full list of input filesworker
: compute resource that will execute a single task at a time, e.g., if you have 50 cpu cores you can run a LocalPipelineExecutor withworkers=50
, to execute 50tasks
simultaneously (one per cpu). Once aworker
is done with atask
, it will start processing another waitingtask
Tip
Your number of tasks
controls how much you can parallelize and also how much time each individual processing unit will take. If you have a small number of tasks (and they each therefore have to process a large number of files) and they fail, you will have to restart from scratch, whereas if you have a larger number of small tasks each failed task will take way less time to rerun.
Caution
If your tasks
> files
, some tasks will not process any data, so there usually isn't a point in setting tasks
to a number larger than `files.
Running a job
to process 10000 files
, on a machine with 100 cpu cores (workers
). If we choose to use 1000 tasks, each one will process a shard
of 10 files. workers=100
means that we can process 100 tasks at a time.
Each pipeline block processes data in the datatrove Document
format:
text
the actual text content for each sampleid
a unique id (string) for this samplemetadata
a dictionary where any additional info may be stored
Each pipeline block takes a generator of Document
as input and returns another generator of Document
.
- readers read data from different formats and yield
Document
- writers save
Document
to disk/cloud in different formats - extractors extract text content from raw formats (such as webpage html)
- filters filter out (remove) some
Document
s based on specific rules/criteria - stats blocks to collect statistics on the dataset
- tokens blocks to tokenize data or count tokens
- dedup blocks for deduplication
A pipeline is defined as a list of pipeline blocks. As an example, the following pipeline would read data from disk, randomly filter (remove) some documents and write them back to disk:
from datatrove.pipeline.readers import CSVReader
from datatrove.pipeline.filters import SamplerFilter
from datatrove.pipeline.writers import JsonlWriter
pipeline = [
CSVReader(
data_folder="/my/input/path"
),
SamplerFilter(rate=0.5),
JsonlWriter(
output_folder="/my/output/path"
)
]
Pipelines are platform-agnostic, which means that the same pipeline can smoothly run on different execution environments without any changes to its steps. Each environment has its own PipelineExecutor.
Some options common to all executors:
pipeline
a list consisting of the pipeline steps that should be runlogging_dir
a datafolder where log files, statistics and more should be saved. Do not reuse folders for different pipelines/jobs as this will overwrite your stats, logs and completions.skip_completed
(bool,True
by default) datatrove keeps track of completed tasks so that when you relaunch a job they can be skipped. Set this toFalse
to disable this behaviourrandomize_start_duration
(int,0
by default) the maximum number of seconds to delay the start of each task to prevent all tasks from starting simultaneously and potentially overloading the system.
Call an executor's run
method to execute its pipeline.
Tip
Datatrove keeps track of which tasks successfully completed by creating a marker (an empty file) in the ${logging_dir}/completions
folder. Once the job finishes, if some of its tasks have failed, you can simply relaunch the exact same executor and datatrove will check and only run the tasks that were not previously completed.
Caution
If you relaunch a pipeline because some tasks failed, do not change the total number of tasks as this will affect the distribution of input files/sharding.
This executor will launch a pipeline on a local machine. Options:
tasks
total number of tasks to runworkers
how many tasks to run simultaneously. If-1
, no limit. Anything> 1
will use multiprocessing to execute the tasks.start_method
method to use to spawn a multiprocessing Pool. Ignored ifworkers
is 1
Example executor
from datatrove.executor import LocalPipelineExecutor
executor = LocalPipelineExecutor(
pipeline=[
...
],
logging_dir="logs/",
tasks=10,
workers=5
)
executor.run()
Multi-node parallelism
You can have different nodes/machines process different parts of the total tasks by using the local_tasks
and local_rank_offset
. For each node/instance/machine, launch with the following options:
tasks
the total tasks to be executed (across all machines). This value must be the same on each machine or the input file distribution may overlap! Example: 500local_tasks
how many tasks of the total will be executed on this particular machine. Note that you can use different values for each machine. Example: 100local_rank_offset
the rank of the first task to be executed on this machine. If this is the 3rd machine where you are launching a job, and the 2 previous machines each ran 250 and 150 jobs, this would be400
for the current machine.
To get final merged stats you will have to invoke the merge_stats
script manually on a path containing the stats from all machines.
This executor will launch a pipeline on a slurm cluster, using slurm job arrays to group and manage tasks. Options:
tasks
total number of tasks to run. requiredtime
slurm time limit string. requiredpartition
slurm partition. requiredworkers
how many tasks to run simultaneously. If-1
, no limit. Slurm will runworkers
tasks at a time. (default:-1
)job_name
slurm job name (default: "data_processing)depends
another SlurmPipelineExecutor instance, which will be a dependency of this pipeline (current pipeline will only start executing after the depended on pipeline successfully completes)sbatch_args
dictionary with any other arguments you would like to pass to sbatchslurm_logs_folder
where to save the slurm log files. If using a local path forlogging_dir
, they will be saved onlogging_dir/slurm_logs
. If not, they will be saved as a subdir of the current directory.
Other options
cpus_per_task
how many cpus to give each task (default:1
)qos
slurm qos (default: "normal")mem_per_cpu_gb
memory per cpu, in GB (default: 2)env_command
custom command to activate a python environment, if neededcondaenv
conda environment to activatevenv_path
path to a python environment to activatemax_array_size
the MaxArraySize value in$ scontrol show config
. If number of tasks exceeds this number, it will split into multiple array jobs (default: 1001)max_array_launch_parallel
if we need multiple jobs due to max_array_size, whether to launch them all in one go (parallel) or sequentially (default:False
)stagger_max_array_jobs
when max_array_launch_parallel is True, this determines how many seconds to wait between launching each of the parallel jobs (default:0
)run_on_dependency_fail
start executing when a job we depend on finishes even if it has failed (default:False
)randomize_start
randomize the start of each task in a job in a ~3 min window. Useful when heavily hitting an s3 bucket for example. (default:False
)
Example executor
from datatrove.executor import SlurmPipelineExecutor
executor1 = SlurmPipelineExecutor(
pipeline=[
...
],
job_name="my_cool_job1",
logging_dir="logs/job1",
tasks=500,
workers=100, # omit to run all at once
time="10:00:00", # 10 hours
partition="hopper-cpu"
)
executor2 = SlurmPipelineExecutor(
pipeline=[
...
],
job_name="my_cool_job2",
logging_dir="logs/job2",
tasks=1,
time="5:00:00", # 5 hours
partition="hopper-cpu",
depends=executor1 # this pipeline will only be launched after executor1 successfully completes
)
# executor1.run()
executor2.run() # this will actually launch executor1, as it is a dependency, so no need to launch it explicitly
For a pipeline with logging_dir
mylogspath/exp1, the following folder structure would be created:
See folder structure
└── mylogspath/exp1
│── executor.json ⟵ json dump of the executor options and pipeline steps
│── launch_script.slurm ⟵ the slurm config created and used to launch this job (if running on slurm)
│── executor.pik ⟵ the slurm config created and used to launch this job (if running on slurm)
│── ranks_to_run.json ⟵ list of tasks that are being run
│── logs/
│ └──[task_00000.log, task_00001.log, task_00002.log, ...] ⟵ individual logging files for each task
│── completions/
│ └──[00004, 00007, 00204, ...] ⟵ empty files marking a task as completed. Using when relaunching/resuming a job (only unfinished tasks will be run)
│── stats/
│ └──[00000.json, 00001.json, 00002.json, ...] ⟵ individual stats for each task (number of samples processed, filtered, removed, etc)
└── stats.json ⟵ global stats from all tasks
Log messages support colorization. By default, colorization will be auto detected for console messages and disabled for log files (logs/task_XXXXX.log). To explicitly enable or disable colorization, you may set the following environment variables:
DATATROVE_COLORIZE_LOGS
"1" to add ANSI colors to console log messages and "0" to disable colorization.DATATROVE_COLORIZE_LOG_FILES
set to "1" to add ANSI colors to log messages saved to logs/task_XXXXX.log.
Datatrove supports a wide variety of input/output sources through fsspec.
There are a few ways to provide a path to a datatrove block (for input_folder
, logging_dir
, data_folder
and so on arguments):
-
str
: the simplest way is to pass a single string. Example:/home/user/mydir
,s3://mybucket/myinputdata
,hf://datasets/allenai/c4/en/
-
(str, fsspec filesystem instance)
: a string path and a fully initialized filesystem object. Example:("s3://mybucket/myinputdata", S3FileSystem(client_kwargs={"endpoint_url": endpoint_uri}))
-
(str, dict)
: a string path and a dictionary with options to initialize a fs. Example (equivalent to the previous line):("s3://mybucket/myinputdata", {"client_kwargs": {"endpoint_url": endpoint_uri}})
-
DataFolder
: you can initialize a DataFolder object directly and pass it as an argument
Under the hood these argument combinations are parsed by get_datafolder
.
Usually, pipelines will start with a Reader block.
Most readers take a data_folder
argument — a path to a folder containing the data to be read.
These files will be distributed across each task. If you have N
tasks, task with rank i
(0-based) will process files i, i+N, i+2N, i+3N,...
.
Internally, each reader reads data and converts it into a dictionary before creating a Document
object.
Some options common to most readers:
text_key
the dictionary key containing the text content for each sample. Default:text
id_key
the dictionary key containing the id for each sample. Default:id
default_metadata
a dictionary for any default metadata values you would like to add (such as their source, for example)recursive
whether to look for files recursively indata_folder
's subdirectoriesglob_pattern
use this field to match specific files. For instance,glob_pattern="*/warc/*.warc.gz"
will match files with a.warc.gz
file extension on thewarc/
folder of each of thedata_folder
's subdirectoriesadapter
this function takes the raw dictionary obtained from the reader and returns a dictionary withDocument
's field names. You may overwrite this function (_default_adapter) if you would like.limit
read only a certain number of samples. Useful for testing/debugging
You can use extractors to extract text content from raw html. The most commonly used extractor in datatrove is Trafilatura, which uses the trafilatura library.
Filters are some of the most important blocks of any data processing pipeline. Datatrove's filter blocks take a Document
and return a boolean (True
to keep a document, False
to remove it). Removed samples do not continue to the next pipeline stage. You can also save the removed samples to disk by passing a Writer to the exclusion_writer
parameter.
Once you are done processing your data you will probably want to save it somewhere. For this you can use a writer.
Writers require an output_folder
(the path where data should be saved). You can choose the compression
to use (default: gzip
) and the filename to save each file as.
For the output_filename
, a template is applied using the following arguments:
${rank}
replaced with the current task's rank. Note that if this tag isn't present, different tasks may try to write to the same location${id}
replaced with the sample id- metadata: any other
${tag}
will be replaced with the correspondingdocument.metadata['tag']
value
An example to separate samples by language based on their lang
metadata field:
JsonlWriter(
f"{MAIN_OUTPUT_PATH}/non_english/",
output_filename="${language}/" + DUMP + "/${rank}.jsonl.gz", # folder structure: language/dump/file
)
For deduplication check the examples minhash_deduplication.py, sentence_deduplication.py and exact_substrings.py.
For summary statistics on your data you can use the Stats blocks. These blocks provide an easy way to collect data-profiles on your dataset in a distributed manner. It's a two step process in which you first:
- For each shard iterate over documents and collect stats into of the following groupings
summary
(all docs counted to "summary" key),fqdn
(fully qualified domain name grouping),suffix
(the last part of the url path grouping) orhistogram
(value based grouping). - Merge the stats from different shards into a single file. See the summary_stats.py for more details.
Each resulting stat is saved in a separate file with following structure: output_folder/{fqdn,suffix,summary,histogram}/{stat_name}/metric.json
Each such file is a MetricStatsDict
object, which you can easily load using:
from datatrove.pipeline.stats.summary_stats import MetricStatsDict
import json
stats = MetricStatsDict.from_dict(json.load(open("fqdn/length/metric.json")))
# E.g for total length of nytimes.com docs
stats["nytimes.com"].total
# Or for mean of cnn.com docs
stats["cnn.com"].mean
Following stats are available:
contamination_stats.py
:word_contamination_{words[0]}
: Frequency of words contamination in the document.doc_stats.py
:length
: Length of the document,white_space_ratio
: Ratio of whitespace characters,non_alpha_digit_ratio
: Ratio of non-alphabetic and non-digit characters,digit_ratio
: Ratio of digits,uppercase_ratio
: Ratio of uppercase letters,elipsis_ratio
: Ratio of elipsis characters,punctuation_ratio
: Punctuation ratiolang_stats.py
:fasttext_{language}
: Score of document being written inlanguage
. Score is computed using FastText model.line_stats.py
:n_lines
: Number of lines per doc,avg_line_length
: Average length of line per doc,long_line_ratio_chars_{chars}
: Ratio of lines with more than k chars,short_line_ratio_chars_{chars}
: Ratio of lines with less than k chars,bullet_point_lines_ratio
: Ratio of line starting with bullet point,line_duplicates
: Ratio of lines that are duplicates,line_char_duplicates
: Ratio of chars in duplicated lines to all chars.paragraph_stats.py
:n_paragraphs
: Number of paragraphs,avg_paragraph_length
: Average paragraph length,short_paragraph_ratio_{chars}
: Ratio of short paragraphs (<{chars}
chars),long_paragraph_ratio_{chars}
: Ratio of long paragraphs (>{chars}
chars)perplexity_stats.py
:ccnet_perplexity_{model_dataset}_{language}
: Perplexity of the document using the CCNet model for{model}
on{dataset}
in{language}
sentence_stats.py
:n_sentences
: Number of sentences,avg_sentence_length
: Average sentence length,short_sentence_ratio_{chars}
: Ratio of short sentences (<{chars}
chars),long_sentence_ratio_{chars}
: Ratio of long sentences (>{chars}
chars)token_stats.py
:token_count
: Number of tokens in the documentword_stats.py
:n_words
: Number of words in the document,avg_word_length
: Average length of words in the document,avg_words_per_line
: Average number of words per line in the document,short_word_ratio_{chars}
: Ratio of words shorter than{chars}
characters,stop_word_ratio
: Ratio of stop words,long_word_ratio_{chars}
: Ratio of words longer than{chars}
characters,type_token_ratio
: Number of unique words / Number of tokens,capitalized_word_ratio
: Ratio of capitalized words,uppercase_word_ratio
: Ratio of uppercase words
You can pass an iterable of Document
directly as a pipeline block like so:
from datatrove.data import Document
from datatrove.pipeline.filters import SamplerFilter
from datatrove.pipeline.writers import JsonlWriter
pipeline = [
[
Document(text="some data", id="0"),
Document(text="some more data", id="1"),
Document(text="even more data", id="2"),
],
SamplerFilter(rate=0.5),
JsonlWriter(
output_folder="/my/output/path"
)
]
Do note, however, that this iterable will not be sharded (if you launch more than 1 task they will all get the full iterable). This is usually useful for small workloads/testing.
For simple processing you can simply pass in a custom function with the following signature:
from datatrove.data import DocumentsPipeline
def uppercase_everything(data: DocumentsPipeline, rank: int = 0, world_size: int = 1) -> DocumentsPipeline:
"""
`data` is a generator of Document. You must also return a generator of Document (yield)
You can optionally use `rank` and `world_size` for sharding
"""
for document in data:
document.text = document.text.upper()
yield document
pipeline = [
...,
uppercase_everything,
...
]
Tip
You might have some pickling issues due to the imports. If this happens, simply move whatever imports you need inside the function body.
You can also define a full block inheriting from PipelineStep
or one of its subclasses:
from datatrove.pipeline.base import PipelineStep
from datatrove.data import DocumentsPipeline
from datatrove.io import DataFolderLike, get_datafolder
class UppercaserBlock(PipelineStep):
def __init__(self, some_folder: DataFolderLike, some_param: int = 5):
super().__init__()
# you can take whatever parameters you need and save them here
self.some_param = some_param
# to load datafolders use get_datafolder()
self.some_folder = get_datafolder(some_folder)
def run(self, data: DocumentsPipeline, rank: int = 0, world_size: int = 1) -> DocumentsPipeline:
# you could also load data from the `some_folder`:
for filepath in self.some_folder.get_shard(rank, world_size): # it also accepts a glob pattern, among other things
with self.some_folder.open(filepath, "rt") as f:
# do something
...
yield doc
#
# OR process data from previous blocks (`data`)
#
for doc in data:
with self.track_time():
# you can wrap the main processing code in `track_time` to know how much each document took to process
nr_uppercase_letters = sum(map(lambda c: c.isupper(), doc.text))
# you can also keep track of stats per document using stat_update
self.stat_update("og_upper_letters", value=nr_uppercase_letters)
doc.text = doc.text.upper()
# make sure you keep the yield outside the track_time block, or it will affect the time calculation
yield doc
#
# OR save data to disk
#
with self.some_folder.open("myoutput", "wt") as f:
for doc in data:
f.write(doc...)
pipeline = [
...,
UppercaserBlock("somepath"),
...
]
You could also inherit from BaseExtractor
, BaseFilter
, BaseReader
/BaseDiskReader
, or DiskWriter
.
git clone git@github.com:huggingface/datatrove.git && cd datatrove
pip install -e ".[dev]"
Install pre-commit code style hooks:
pre-commit install
Run the tests:
pytest -sv ./tests/
@misc{penedo2024datatrove,
author = {Penedo, Guilherme and Kydlíček, Hynek and Cappelli, Alessandro and Sasko, Mario and Wolf, Thomas},
title = {DataTrove: large scale data processing},
year = {2024},
publisher = {GitHub},
journal = {GitHub repository},
url = {https://github.com/huggingface/datatrove}
}