Skip to main content

The Deep Learning framework to train, deploy, and ship AI products Lightning fast.

Project description

LitData

   

Transform datasets at scale.
Optimize data for fast AI model training.

Transform                              Optimize
  
✅ Parallelize data processing       ✅ Stream large cloud datasets          
✅ Create vector embeddings          ✅ Accelerate training by 20x           
✅ Run distributed inference         ✅ Pause and resume data streaming      
✅ Scrape websites at scale          ✅ Use remote data without local loading

PyPI Downloads License Discord

Lightning AIQuick startOptimize dataTransform dataFeaturesBenchmarksTemplatesCommunity

 

Get started

 

Transform data at scale. Optimize for fast model training.

LitData scales data processing tasks (data scraping, image resizing, distributed inference, embedding creation) on local or cloud machines. It also enables optimizing datasets to accelerate AI model training and work with large remote datasets without local loading.

 

Quick start

First, install LitData:

pip install litdata

Choose your workflow:

🚀 Speed up model training
🚀 Transform datasets

 

Advanced install

Install all the extras

pip install 'litdata[extras]'

 


Speed up model training

Accelerate model training (20x faster) by optimizing datasets for streaming directly from cloud storage. Work with remote data without local downloads with features like loading data subsets, accessing individual samples, and resumable streaming.

Step 1: Optimize the data This step will format the dataset for fast loading. The data will be written in a chunked binary format.

import numpy as np
from PIL import Image
import litdata as ld

def random_images(index):
    fake_images = Image.fromarray(np.random.randint(0, 256, (32, 32, 3), dtype=np.uint8))
    fake_labels = np.random.randint(10)

    # You can use any key:value pairs. Note that their types must not change between samples, and Python lists must
    # always contain the same number of elements with the same types.
    data = {"index": index, "image": fake_images, "class": fake_labels}

    return data

if __name__ == "__main__":
    # The optimize function writes data in an optimized format.
    ld.optimize(
        fn=random_images,                   # the function applied to each input
        inputs=list(range(1000)),           # the inputs to the function (here it's a list of numbers)
        output_dir="my_optimized_dataset",  # optimized data is stored here
        num_workers=4,                      # The number of workers on the same machine
        chunk_bytes="64MB"                  # size of each chunk
    )

Step 2: Put the data on the cloud

Upload the data to a Lightning Studio (backed by S3) or your own S3 bucket:

aws s3 cp --recursive my_optimized_dataset s3://my-bucket/my_optimized_dataset

Step 3: Stream the data during training

Load the data by replacing the PyTorch DataSet and DataLoader with the StreamingDataset and StreamingDataloader

import litdata as ld

dataset = ld.StreamingDataset('s3://my-bucket/my_optimized_dataset', shuffle=True)
dataloader = ld.StreamingDataLoader(dataset)

for sample in dataloader:
    img, cls = sample['image'], sample['class']

Key benefits:

✅ Accelerate training: Optimized datasets load 20x faster.
✅ Stream cloud datasets: Work with cloud data without downloading it.
✅ Pytorch-first: Works with PyTorch libraries like PyTorch Lightning, Lightning Fabric, Hugging Face.
✅ Easy collaboration: Share and access datasets in the cloud, streamlining team projects.
✅ Scale across GPUs: Streamed data automatically scales to all GPUs.
✅ Flexible storage: Use S3, GCS, Azure, or your own cloud account for data storage.
✅ Compression: Reduce your data footprint by using advanced compression algorithms.
✅ Run local or cloud: Run on your own machines or auto-scale to 1000s of cloud GPUs with Lightning Studios.
✅ Enterprise security: Self host or process data on your cloud account with Lightning Studios.

 


Transform datasets

Accelerate data processing tasks (data scraping, image resizing, embedding creation, distributed inference) by parallelizing (map) the work across many machines at once.

Here's an example that resizes and crops a large image dataset:

from PIL import Image
import litdata as ld

# use a local or S3 folder
input_dir = "my_large_images"     # or "s3://my-bucket/my_large_images"
output_dir = "my_resized_images"  # or "s3://my-bucket/my_resized_images"

inputs = [os.path.join(input_dir, f) for f in os.listdir(input_dir)]

# resize the input image
def resize_image(image_path, output_dir):
  output_image_path = os.path.join(output_dir, os.path.basename(image_path))
  Image.open(image_path).resize((224, 224)).save(output_image_path)

ld.map(
    fn=resize_image,
    inputs=inputs,
    output_dir="output_dir",
)

Key benefits:

✅ Parallelize processing: Reduce processing time by transforming data across multiple machines simultaneously.
✅ Scale to large data: Increase the size of datasets you can efficiently handle.
✅ Flexible usecases: Resize images, create embeddings, scrape the internet, etc...
✅ Run local or cloud: Run on your own machines or auto-scale to 1000s of cloud GPUs with Lightning Studios.
✅ Enterprise security: Self host or process data on your cloud account with Lightning Studios.

 


Key Features

Features for optimizing and streaming datasets for model training

✅ Stream large cloud datasets  

Use data stored on the cloud without needing to download it all to your computer, saving time and space.

Imagine you're working on a project with a huge amount of data stored online. Instead of waiting hours to download it all, you can start working with the data almost immediately by streaming it.

Once you've optimized the dataset with LitData, stream it as follows:

from litdata import StreamingDataset, StreamingDataLoader

dataset = StreamingDataset('s3://my-bucket/my-data', shuffle=True)
dataloader = StreamingDataLoader(dataset, batch_size=64)

for batch in dataloader:
    process(batch)  # Replace with your data processing logic

Additionally, you can inject client connection settings for S3 or GCP when initializing your dataset. This is useful for specifying custom endpoints and credentials per dataset.

from litdata import StreamingDataset

storage_options = {
    "endpoint_url": "your_endpoint_url",
    "aws_access_key_id": "your_access_key_id",
    "aws_secret_access_key": "your_secret_access_key",
}

dataset = StreamingDataset('s3://my-bucket/my-data', storage_options=storage_options)
✅ Streams on multi-GPU, multi-node

 

Data optimized and loaded with Lightning automatically streams efficiently in distributed training across GPUs or multi-node.

The StreamingDataset and StreamingDataLoader automatically make sure each rank receives the same quantity of varied batches of data, so it works out of the box with your favorite frameworks (PyTorch Lightning, Lightning Fabric, or PyTorch) to do distributed training.

Here you can see an illustration showing how the Streaming Dataset works with multi node / multi gpu under the hood.

An illustration showing how the Streaming Dataset works with multi node.

✅ Stream from multiple cloud providers

 

The StreamingDataset supports reading optimized datasets from common cloud providers.

import os
import litdata as ld

# Read data from AWS S3
aws_storage_options={
    "AWS_ACCESS_KEY_ID": os.environ['AWS_ACCESS_KEY_ID'],
    "AWS_SECRET_ACCESS_KEY": os.environ['AWS_SECRET_ACCESS_KEY'],
}
dataset = ld.StreamingDataset("s3://my-bucket/my-data", storage_options=aws_storage_options)

# Read data from GCS
gcp_storage_options={
    "project": os.environ['PROJECT_ID'],
}
dataset = ld.StreamingDataset("gcp://my-bucket/my-data", storage_options=gcp_storage_options)

# Read data from Azure
azure_storage_options={
    "account_url": f"https://{os.environ['AZURE_ACCOUNT_NAME']}.blob.core.windows.net",
    "credential": os.environ['AZURE_ACCOUNT_ACCESS_KEY']
}
dataset = ld.StreamingDataset("azure://my-bucket/my-data", storage_options=azure_storage_options)
✅ Pause, resume data streaming  

Stream data during long training, if interrupted, pick up right where you left off without any issues.

LitData provides a stateful Streaming DataLoader e.g. you can pause and resume your training whenever you want.

Info: The Streaming DataLoader was used by Lit-GPT to pretrain LLMs. Restarting from an older checkpoint was critical to get to pretrain the full model due to several failures (network, CUDA Errors, etc..).

import os
import torch
from litdata import StreamingDataset, StreamingDataLoader

dataset = StreamingDataset("s3://my-bucket/my-data", shuffle=True)
dataloader = StreamingDataLoader(dataset, num_workers=os.cpu_count(), batch_size=64)

# Restore the dataLoader state if it exists
if os.path.isfile("dataloader_state.pt"):
    state_dict = torch.load("dataloader_state.pt")
    dataloader.load_state_dict(state_dict)

# Iterate over the data
for batch_idx, batch in enumerate(dataloader):

    # Store the state every 1000 batches
    if batch_idx % 1000 == 0:
        torch.save(dataloader.state_dict(), "dataloader_state.pt")
✅ LLM Pre-training  

LitData is highly optimized for LLM pre-training. First, we need to tokenize the entire dataset and then we can consume it.

import json
from pathlib import Path
import zstandard as zstd
from litdata import optimize, TokensLoader
from tokenizer import Tokenizer
from functools import partial

# 1. Define a function to convert the text within the jsonl files into tokens
def tokenize_fn(filepath, tokenizer=None):
    with zstd.open(open(filepath, "rb"), "rt", encoding="utf-8") as f:
        for row in f:
            text = json.loads(row)["text"]
            if json.loads(row)["meta"]["redpajama_set_name"] == "RedPajamaGithub":
                continue  # exclude the GitHub data since it overlaps with starcoder
            text_ids = tokenizer.encode(text, bos=False, eos=True)
            yield text_ids

if __name__ == "__main__":
    # 2. Generate the inputs (we are going to optimize all the compressed json files from SlimPajama dataset )
    input_dir = "./slimpajama-raw"
    inputs = [str(file) for file in Path(f"{input_dir}/SlimPajama-627B/train").rglob("*.zst")]

    # 3. Store the optimized data wherever you want under "/teamspace/datasets" or "/teamspace/s3_connections"
    outputs = optimize(
        fn=partial(tokenize_fn, tokenizer=Tokenizer(f"{input_dir}/checkpoints/Llama-2-7b-hf")), # Note: You can use HF tokenizer or any others
        inputs=inputs,
        output_dir="./slimpajama-optimized",
        chunk_size=(2049 * 8012),
        # This is important to inform LitData that we are encoding contiguous 1D array (tokens). 
        # LitData skips storing metadata for each sample e.g all the tokens are concatenated to form one large tensor.
        item_loader=TokensLoader(),
    )
import os
from litdata import StreamingDataset, CombinedStreamingDataset, StreamingDataLoader, TokensLoader
from tqdm import tqdm

# Increase by one because we need the next word as well
dataset = StreamingDataset(
  input_dir=f"./slimpajama-optimized/train",
  item_loader=TokensLoader(block_size=2048 + 1),
  shuffle=True,
  drop_last=True,
)

train_dataloader = StreamingDataLoader(dataset, batch_size=8, pin_memory=True, num_workers=os.cpu_count())

# Iterate over the SlimPajama dataset
for batch in tqdm(train_dataloader):
    pass
✅ Combine datasets  

Mix and match different sets of data to experiment and create better models.

Combine datasets with CombinedStreamingDataset. As an example, this mixture of Slimpajama & StarCoder was used in the TinyLLAMA project to pretrain a 1.1B Llama model on 3 trillion tokens.

from litdata import StreamingDataset, CombinedStreamingDataset, StreamingDataLoader, TokensLoader
from tqdm import tqdm
import os

train_datasets = [
    StreamingDataset(
        input_dir="s3://tinyllama-template/slimpajama/train/",
        item_loader=TokensLoader(block_size=2048 + 1), # Optimized loader for tokens used by LLMs
        shuffle=True,
        drop_last=True,
    ),
    StreamingDataset(
        input_dir="s3://tinyllama-template/starcoder/",
        item_loader=TokensLoader(block_size=2048 + 1), # Optimized loader for tokens used by LLMs
        shuffle=True,
        drop_last=True,
    ),
]

# Mix SlimPajama data and Starcoder data with these proportions:
weights = (0.693584, 0.306416)
combined_dataset = CombinedStreamingDataset(datasets=train_datasets, seed=42, weights=weights, iterate_over_all=False)

train_dataloader = StreamingDataLoader(combined_dataset, batch_size=8, pin_memory=True, num_workers=os.cpu_count())

# Iterate over the combined datasets
for batch in tqdm(train_dataloader):
    pass
✅ Split datasets for train, val, test

 

Split a dataset into train, val, test splits with train_test_split.

from litdata import StreamingDataset, train_test_split

dataset = StreamingDataset("s3://my-bucket/my-data") # data are stored in the cloud

print(len(dataset)) # display the length of your data
# out: 100,000

train_dataset, val_dataset, test_dataset = train_test_split(dataset, splits=[0.3, 0.2, 0.5])

print(train_dataset)
# out: 30,000

print(val_dataset)
# out: 20,000

print(test_dataset)
# out: 50,000
✅ Load a subset of the remote dataset

  Work on a smaller, manageable portion of your data to save time and resources.

from litdata import StreamingDataset, train_test_split

dataset = StreamingDataset("s3://my-bucket/my-data", subsample=0.01) # data are stored in the cloud

print(len(dataset)) # display the length of your data
# out: 1000
✅ Easily modify optimized cloud datasets  

Add new data to an existing dataset or start fresh if needed, providing flexibility in data management.

LitData optimized datasets are assumed to be immutable. However, you can make the decision to modify them by changing the mode to either append or overwrite.

from litdata import optimize, StreamingDataset

def compress(index):
    return index, index**2

if __name__ == "__main__":
    # Add some data
    optimize(
        fn=compress,
        inputs=list(range(100)),
        output_dir="./my_optimized_dataset",
        chunk_bytes="64MB",
    )

    # Later on, you add more data
    optimize(
        fn=compress,
        inputs=list(range(100, 200)),
        output_dir="./my_optimized_dataset",
        chunk_bytes="64MB",
        mode="append",
    )

    ds = StreamingDataset("./my_optimized_dataset")
    assert len(ds) == 200
    assert ds[:] == [(i, i**2) for i in range(200)]

The overwrite mode will delete the existing data and start from fresh.

✅ Use compression  

Reduce your data footprint by using advanced compression algorithms.

import litdata as ld

def compress(index):
    return index, index**2

if __name__ == "__main__":
    # Add some data
    ld.optimize(
        fn=compress,
        inputs=list(range(100)),
        output_dir="./my_optimized_dataset",
        chunk_bytes="64MB",
        num_workers=1,
        compression="zstd"
    )

Using zstd, you can achieve high compression ratio like 4.34x for this simple example.

Without With
2.8kb 646b
✅ Access samples without full data download  

Look at specific parts of a large dataset without downloading the whole thing or loading it on a local machine.

from litdata import StreamingDataset

dataset = StreamingDataset("s3://my-bucket/my-data") # data are stored in the cloud

print(len(dataset)) # display the length of your data

print(dataset[42]) # show the 42th element of the dataset
✅ Use any data transforms  

Customize how your data is processed to better fit your needs.

Subclass the StreamingDataset and override its __getitem__ method to add any extra data transformations.

from litdata import StreamingDataset, StreamingDataLoader
import torchvision.transforms.v2.functional as F

class ImagenetStreamingDataset(StreamingDataset):

    def __getitem__(self, index):
        image = super().__getitem__(index)
        return F.resize(image, (224, 224))

dataset = ImagenetStreamingDataset(...)
dataloader = StreamingDataLoader(dataset, batch_size=4)

for batch in dataloader:
    print(batch.shape)
    # Out: (4, 3, 224, 224)
✅ Profile data loading speed  

Measure and optimize how fast your data is being loaded, improving efficiency.

The StreamingDataLoader supports profiling of your data loading process. Simply use the profile_batches argument to specify the number of batches you want to profile:

from litdata import StreamingDataset, StreamingDataLoader

StreamingDataLoader(..., profile_batches=5)

This generates a Chrome trace called result.json. Then, visualize this trace by opening Chrome browser at the chrome://tracing URL and load the trace inside.

✅ Reduce memory use for large files  

Handle large data files efficiently without using too much of your computer's memory.

When processing large files like compressed parquet files, use the Python yield keyword to process and store one item at the time, reducing the memory footprint of the entire program.

from pathlib import Path
import pyarrow.parquet as pq
from litdata import optimize
from tokenizer import Tokenizer
from functools import partial

# 1. Define a function to convert the text within the parquet files into tokens
def tokenize_fn(filepath, tokenizer=None):
    parquet_file = pq.ParquetFile(filepath)
    # Process per batch to reduce RAM usage
    for batch in parquet_file.iter_batches(batch_size=8192, columns=["content"]):
        for text in batch.to_pandas()["content"]:
            yield tokenizer.encode(text, bos=False, eos=True)

# 2. Generate the inputs
input_dir = "/teamspace/s3_connections/tinyllama-template"
inputs = [str(file) for file in Path(f"{input_dir}/starcoderdata").rglob("*.parquet")]

# 3. Store the optimized data wherever you want under "/teamspace/datasets" or "/teamspace/s3_connections"
outputs = optimize(
    fn=partial(tokenize_fn, tokenizer=Tokenizer(f"{input_dir}/checkpoints/Llama-2-7b-hf")), # Note: Use HF tokenizer or any others
    inputs=inputs,
    output_dir="/teamspace/datasets/starcoderdata",
    chunk_size=(2049 * 8012), # Number of tokens to store by chunks. This is roughly 64MB of tokens per chunk.
)
✅ Limit local cache space  

Limit the amount of disk space used by temporary files, preventing storage issues.

Adapt the local caching limit of the StreamingDataset. This is useful to make sure the downloaded data chunks are deleted when used and the disk usage stays low.

from litdata import StreamingDataset

dataset = StreamingDataset(..., max_cache_size="10GB")
✅ Change cache directory path  

Specify the directory where cached files should be stored, ensuring efficient data retrieval and management. This is particularly useful for organizing your data storage and improving access times.

from litdata import StreamingDataset
from litdata.streaming.cache import Dir

cache_dir = "/path/to/your/cache"
data_dir = "s3://my-bucket/my_optimized_dataset"

dataset = StreamingDataset(input_dir=Dir(path=cache_dir, url=data_dir))
✅ Optimize loading on networked drives  

Optimize data handling for computers on a local network to improve performance for on-site setups.

On-prem compute nodes can mount and use a network drive. A network drive is a shared storage device on a local area network. In order to reduce their network overload, the StreamingDataset supports caching the data chunks.

from litdata import StreamingDataset

dataset = StreamingDataset(input_dir="local:/data/shared-drive/some-data")
✅ Optimize dataset in distributed environment  

Lightning can distribute large workloads across hundreds of machines in parallel. This can reduce the time to complete a data processing task from weeks to minutes by scaling to enough machines.

To apply the optimize operator across multiple machines, simply provide the num_nodes and machine arguments to it as follows:

import os
from litdata import optimize, Machine

def compress(index):
    return (index, index ** 2)

optimize(
    fn=compress,
    inputs=list(range(100)),
    num_workers=2,
    output_dir="my_output",
    chunk_bytes="64MB",
    num_nodes=2,
    machine=Machine.DATA_PREP, # You can select between dozens of optimized machines
)

If the output_dir is a local path, the optimized dataset will be present in: /teamspace/jobs/{job_name}/nodes-0/my_output. Otherwise, it will be stored in the specified output_dir.

Read the optimized dataset:

from litdata import StreamingDataset

output_dir = "/teamspace/jobs/litdata-optimize-2024-07-08/nodes.0/my_output"

dataset = StreamingDataset(output_dir)

print(dataset[:])

 

Features for transforming datasets

✅ Parallelize data transformations (map)  

Apply the same change to different parts of the dataset at once to save time and effort.

The map operator can be used to apply a function over a list of inputs.

Here is an example where the map operator is used to apply a resize_image function over a folder of large images.

from litdata import map
from PIL import Image

# Note: Inputs could also refer to files on s3 directly.
input_dir = "my_large_images"
inputs = [os.path.join(input_dir, f) for f in os.listdir(input_dir)]

# The resize image takes one of the input (image_path) and the output directory.
# Files written to output_dir are persisted.
def resize_image(image_path, output_dir):
  output_image_path = os.path.join(output_dir, os.path.basename(image_path))
  Image.open(image_path).resize((224, 224)).save(output_image_path)

map(
    fn=resize_image,
    inputs=inputs,
    output_dir="s3://my-bucket/my_resized_images",
)
✅ Support S3-Compatible cloud object storage  

Use different cloud storage services, offering data storage flexibility and cost-saving options.

Integrate S3-compatible object storage servers like MinIO with litdata, ideal for on-premises infrastructure setups. Configure the endpoint and credentials using environment variables or configuration files.

Set up the environment variables to connect to MinIO:

export AWS_ACCESS_KEY_ID=access_key
export AWS_SECRET_ACCESS_KEY=secret_key
export AWS_ENDPOINT_URL=http://localhost:9000  # MinIO endpoint

Alternatively, configure credentials and endpoint in ~/.aws/{credentials,config}:

mkdir -p ~/.aws && \
cat <<EOL >> ~/.aws/credentials
[default]
aws_access_key_id = access_key
aws_secret_access_key = secret_key
EOL

cat <<EOL >> ~/.aws/config
[default]
endpoint_url = http://localhost:9000  # MinIO endpoint
EOL

Explore an example setup of litdata with MinIO in the LitData with MinIO repository for practical implementation details.

✅ Supports encryption and decryption of data at chunk/sample level  

Secure your data by applying encryption to individual samples or chunks, ensuring sensitive information is protected during storage.

This example demonstrates how to use the FernetEncryption class for sample-level encryption with a data optimization function.

from litdata import optimize
from litdata.utilities.encryption import FernetEncryption
import numpy as np
from PIL import Image

# Initialize FernetEncryption with a password for sample-level encryption
fernet = FernetEncryption(password="your_secure_password", level="sample")
data_dir = "s3://my-bucket/optimized_data"

def random_image(index):
    """Generate a random image for demonstration purposes."""
    fake_img = Image.fromarray(np.random.randint(0, 255, (32, 32, 3), dtype=np.uint8))
    return {"image": fake_img, "class": index}

# Optimize data while applying encryption
optimize(
    fn=random_image,
    inputs=list(range(5)),  # Example inputs: [0, 1, 2, 3, 4]
    num_workers=1,
    output_dir=data_dir,
    chunk_bytes="64MB",
    encryption=fernet,
)

# Save the encryption key to a file for later use
fernet.save("fernet.pem")

You can load the encrypted data using the StreamingDataset class as follows:

from litdata import StreamingDataset
from litdata.utilities.encryption import FernetEncryption

# Load the encryption key
fernet = FernetEncryption(password="your_secure_password", level="sample")
fernet.load("fernet.pem")

# Create a streaming dataset for reading the encrypted samples
ds = StreamingDataset(input_dir=data_dir, encryption=fernet)

If you want to implement your own encryption method, you can subclass the Encryption class and define the necessary methods:

from litdata.utilities.encryption import Encryption

class CustomEncryption(Encryption):
    def encrypt(self, data):
        # Implement your custom encryption logic here
        return data

    def decrypt(self, data):
        # Implement your custom decryption logic here
        return data

With this setup, you can ensure that your data remains secure while maintaining flexibility in how you handle encryption.

 


Benchmarks

In this section we show benchmarks for speed to optimize a dataset and the resulting streaming speed (Reproduce the benchmark).

Streaming speed

Data optimized and streamed with LitData achieves a 20x speed up over non optimized data and 2x speed up over other streaming solutions.

Speed to stream Imagenet 1.2M from AWS S3:

Framework Images / sec 1st Epoch (float32) Images / sec 2nd Epoch (float32) Images / sec 1st Epoch (torch16) Images / sec 2nd Epoch (torch16)
PL Data 5800 6589 6282 7221
Web Dataset 3134 3924 3343 4424
Mosaic ML 2898 5099 2809 5158
Benchmark details  
  • Imagenet-1.2M dataset contains 1,281,167 images.
  • To align with other benchmarks, we measured the streaming speed (images per second) loaded from AWS S3 for several frameworks.

 

Time to optimize data

LitData optimizes the Imagenet dataset for fast training 3-5x faster than other frameworks:

Time to optimize 1.2 million ImageNet images (Faster is better):

Framework Train Conversion Time Val Conversion Time Dataset Size # Files
PL Data 10:05 min 00:30 min 143.1 GB 2.339
Web Dataset 32:36 min 01:22 min 147.8 GB 1.144
Mosaic ML 49:49 min 01:04 min 143.1 GB 2.298

 


Parallelize transforms and data optimization on cloud machines

Lightning

Parallelize data transforms

Transformations with LitData are linearly parallelizable across machines.

For example, let's say that it takes 56 hours to embed a dataset on a single A10G machine. With LitData, this can be speed up by adding more machines in parallel

Number of machines Hours
1 56
2 28
4 14
... ...
64 0.875

To scale the number of machines, run the processing script on Lightning Studios:

from litdata import map, Machine

map(
  ...
  num_nodes=32,
  machine=Machine.DATA_PREP, # Select between dozens of optimized machines
)

Parallelize data optimization

To scale the number of machines for data optimization, use Lightning Studios:

from litdata import optimize, Machine

optimize(
  ...
  num_nodes=32,
  machine=Machine.DATA_PREP, # Select between dozens of optimized machines
)

 

Example: Process the LAION 400 million image dataset in 2 hours on 32 machines, each with 32 CPUs.

 


Start from a template

Below are templates for real-world applications of LitData at scale.

Templates: Transform datasets

Studio Data type Time (minutes) Machines Dataset
Download LAION-400MILLION dataset Image & Text 120 32 LAION-400M
Tokenize 2M Swedish Wikipedia Articles Text 7 4 Swedish Wikipedia
Embed English Wikipedia under 5 dollars Text 15 3 English Wikipedia

Templates: Optimize + stream data

Studio Data type Time (minutes) Machines Dataset
Benchmark cloud data-loading libraries Image & Label 10 1 Imagenet 1M
Optimize GeoSpatial data for model training Image & Mask 120 32 Chesapeake Roads Spatial Context
Optimize TinyLlama 1T dataset for training Text 240 32 SlimPajama & StarCoder
Optimize parquet files for model training Parquet Files 12 16 Randomly Generated data

 


Community

LitData is a community project accepting contributions - Let's make the world's most advanced AI data processing framework.

💬 Get help on Discord
📋 License: Apache 2.0

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

litdata-0.2.22.tar.gz (125.5 kB view details)

Uploaded Source

Built Distribution

litdata-0.2.22-py3-none-any.whl (127.9 kB view details)

Uploaded Python 3

File details

Details for the file litdata-0.2.22.tar.gz.

File metadata

  • Download URL: litdata-0.2.22.tar.gz
  • Upload date:
  • Size: 125.5 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/5.1.0 CPython/3.12.4

File hashes

Hashes for litdata-0.2.22.tar.gz
Algorithm Hash digest
SHA256 4a99ca60c2fd12f10e1041c371118e16e91816c9e407ef04b196309b1c921cf2
MD5 863665a82e457b86388a55b8bff8ef00
BLAKE2b-256 ce03da34d549f838ca767281d761ff2c96e275e6e189c1bbab6648be2d429b09

See more details on using hashes here.

File details

Details for the file litdata-0.2.22-py3-none-any.whl.

File metadata

  • Download URL: litdata-0.2.22-py3-none-any.whl
  • Upload date:
  • Size: 127.9 kB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/5.1.0 CPython/3.12.4

File hashes

Hashes for litdata-0.2.22-py3-none-any.whl
Algorithm Hash digest
SHA256 1479f38baa47509798bdef6c197c674478dc498da08c2fd777d38b4d2048cf7a
MD5 60e0193d4b9ff95c4cb3922dc4197b92
BLAKE2b-256 8878792c2cbc11c1d59f52b37e323ba3e0b79be9e1dc6febf52e09a8f9f70f5b

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page