Skip to main content

A modular, primitive-first, python-first PyTorch library for Reinforcement Learning

Project description

Unit-tests Nightly Documentation Benchmarks codecov Flaky Tests X / Twitter Follow Python version GitHub license pypi version pypi nightly version Downloads Downloads Discord Shield

TorchRL

TorchRL logo

TorchRL is a PyTorch-native toolkit for reinforcement learning, decision making, robotics, and simulation. It is not a single algorithm implementation or a narrow benchmark suite: it is a collection of composable pieces for building RL systems while keeping the code close to the PyTorch programming model. Recent work has made this especially strong for recurrent RL, MuJoCo-based control, multi-agent training, replay-buffer and collector infrastructure, and reusable loss/value-estimation components.

The library is built around three ideas:

  1. Data should have names, structure, batch dimensions, and devices all the way through the training loop.
  2. Environments, policies, replay buffers, objectives, and collectors should be independent modules that can be swapped without rewriting the rest of the stack.
  3. Research code should scale from a local prototype to vectorized, multiprocess, distributed, compiled, recurrent, multi-agent, model-based, or offline workflows without changing the data model.

That common data model is TensorDict, a dictionary-like tensor container with PyTorch operations, device transfers, shared-memory support, memmaps, lazy views, and nn.Module wrappers.

Getting started | API reference | Tutorials | Knowledge base | Examples | SOTA implementations

Recent highlights

TorchRL 0.13 and the preceding development cycle bring several user-visible improvements that are worth surfacing up front:

  • faster recurrent RL paths, including scan and Triton GRU/LSTM reset handling;
  • custom MuJoCo environments, satellite examples, and macro-control policies;
  • stronger multi-agent coverage through MAPPO, IPPO, MultiAgentGAE, value-normalization utilities, and mixer configs;
  • better collector and replay-buffer ergonomics, including async prioritized writes, ordered storage access, compact observations, HER, and optional CUDA wheels for CUDA-based prioritized replay-buffer kernels;
  • new transforms and value-estimator improvements such as ActionScaling, FlattenAction, NextObservationDelta, compact shifted estimators, and chunked forwards.

A quick mental model

TorchRL represents an RL interaction as a TensorDict that moves through a small number of reusable components:

TensorDict
  -> policy module writes actions and log-probs
  -> environment reads actions and writes next observations, rewards, done flags
  -> collector batches trajectories from one or many workers
  -> replay buffer stores, samples, prioritizes, and transforms data
  -> loss module reads named keys and writes differentiable losses
  -> optimizer updates ordinary PyTorch parameters

The same object can carry observations, pixels, actions, rewards, masks, recurrent states, agent groups, sampled indices, priorities, or custom task fields. The result is less glue code and fewer hidden assumptions about what each algorithm or environment returns.

Quick demo

A local rollout is just a TensorDict passed between a PyTorch module and an environment:

import torch
from tensordict.nn import TensorDictModule
from torch import nn

from torchrl.envs import PendulumEnv, StepCounter, TransformedEnv

# A PyTorch-native environment with an ordinary transform stack.
env = TransformedEnv(PendulumEnv(), StepCounter(max_steps=200))

# Policies are regular nn.Modules wrapped with explicit TensorDict keys.
policy = TensorDictModule(
    nn.Sequential(
        nn.LazyLinear(64),
        nn.Tanh(),
        nn.Linear(64, 1),
        nn.Tanh(),
    ),
    in_keys=["observation"],
    out_keys=["action"],
)

rollout = env.rollout(max_steps=32, policy=policy)
assert rollout.batch_size == torch.Size([32])
assert rollout["next", "reward"].shape[:1] == torch.Size([32])

Nothing in this pattern is specific to Pendulum. The same keys-and-TensorDict interface is used by batched environments, multi-agent tasks, collectors, replay buffers, recurrent modules, transforms, and losses.

What TorchRL is today

TensorDict-first pipelines

RL code tends to accumulate special cases: tuples from one environment, dicts from another, separate arrays for recurrent states, masks next to data rather than inside it, and losses that silently assume a particular batch layout. TorchRL uses TensorDict to make those assumptions explicit.

TensorDict supports common tensor operations while preserving named fields:

# These operations preserve the structure and operate on every compatible value.
batch = torch.stack(list_of_tensordicts, dim=0)
batch = batch.reshape(-1)
batch = batch.to("cuda")
mini_batch = batch[:128]

# Nested keys make multi-agent, recurrent, and next-state data explicit.
reward = batch["next", "reward"]
agent_obs = batch["agents", "observation"]
hidden = batch["recurrent_state", "h"]

This is the reason TorchRL components compose: a collector can emit a TensorDict, a replay buffer can store it without losing structure, a transform can add or remove keys, and a loss can read exactly the keys it needs.

Environments and transforms

TorchRL includes native environments, wrappers for popular environment libraries, and vectorized containers for running many environments at once. The environment API exposes specs for observations, actions, rewards, and done flags, so policies and transforms can check shapes, devices, dtypes, and bounds before a training job runs for hours.

Environment support includes:

  • PyTorch-native environments such as PendulumEnv and custom MuJoCo tasks.
  • Wrappers for Gymnasium, Gym, DM Control, Brax, Jumanji, PettingZoo, VMAS, OpenSpiel, Safety-Gymnasium, Isaac Lab, and other optional libraries.
  • SerialEnv, ParallelEnv, and batched wrappers for local vectorization and multiprocessing.
  • Environment transforms for observation normalization, image conversion, reward transforms, action masking, action scaling, auto-reset, frame stacking, state reconstruction, and more.

Transforms are first-class TorchRL modules. They can run on-device, participate in specs, and be inserted, removed, or composed without wrapping the whole environment in opaque adapter layers.

from torchrl.envs import Compose, DoubleToFloat, ObservationNorm, TransformedEnv
from torchrl.envs.libs.gym import GymEnv

base_env = GymEnv("HalfCheetah-v4", device="cuda:0")
env = TransformedEnv(
    base_env,
    Compose(
        ObservationNorm(in_keys=["observation"]),
        DoubleToFloat(),
    ),
)

Collectors and execution models

Collectors are the bridge between policies and environments. A collector owns the execution loop, batches trajectories, handles devices, and can update policy weights while environments keep running.

TorchRL includes single-process, async, multiprocess, and distributed collectors. This lets the same policy and loss code be used across small smoke tests, GPU-heavy simulation, CPU environment farms, or asynchronous evaluation setups.

from torchrl.collectors import Collector

collector = Collector(
    create_env_fn=env,
    policy=policy,
    frames_per_batch=1024,
    total_frames=1_000_000,
)

for data in collector:
    # data is a TensorDict with time, environment, and key structure preserved.
    train_step(data)

For larger jobs, the collector family adds async execution, multiple worker processes, weight updaters, evaluator loops, profiling hooks, and fake-data helpers for testing downstream code without stepping an expensive environment.

Replay buffers and offline data

TorchRL replay buffers are modular: storage, sampler, writer, collate function, transforms, prefetching, priority updates, and device movement are separate pieces. That makes it possible to use the same interface for simple in-memory replay, memmap-backed storage, prioritized replay, CUDA-aware sampling, offline datasets, HER, or custom storage layouts.

from torchrl.data import LazyMemmapStorage, TensorDictPrioritizedReplayBuffer

buffer = TensorDictPrioritizedReplayBuffer(
    storage=LazyMemmapStorage(1_000_000),
    alpha=0.7,
    beta=0.5,
    batch_size=256,
    prefetch=2,
)

buffer.extend(collector_batch)
sample = buffer.sample()

Replay buffers understand TensorDict structure, so they can store trajectories, nested agent data, recurrent states, HER relabeling metadata, or offline datasets without flattening everything into parallel Python containers.

Modules, distributions, and policies

TorchRL modules are ordinary PyTorch modules with explicit input and output keys. The library provides actors, critics, actor-critic operators, recurrent modules, distribution wrappers, exploration modules, world models, decision transformers, robot-learning models, and helper utilities for inferring specs from environments.

A stochastic actor can be assembled from familiar PyTorch layers:

from tensordict.nn import TensorDictModule
from tensordict.nn.distributions import NormalParamExtractor
from torch import nn
from torchrl.modules import ProbabilisticActor, TanhNormal

params = TensorDictModule(
    nn.Sequential(
        nn.LazyLinear(256),
        nn.Tanh(),
        nn.Linear(256, 2),
        NormalParamExtractor(),
    ),
    in_keys=["observation"],
    out_keys=["loc", "scale"],
)

actor = ProbabilisticActor(
    params,
    in_keys=["loc", "scale"],
    out_keys=["action"],
    distribution_class=TanhNormal,
    distribution_kwargs={"low": -1.0, "high": 1.0},
    return_log_prob=True,
)

The explicit key contract makes it clear what data a module consumes and produces, and it allows losses, collectors, and transforms to be reconfigured without editing the model itself.

Objectives, returns, and trainers

TorchRL objectives are loss modules that read TensorDict keys, compute losses, and expose configurable key mappings. They cover policy-gradient methods, actor-critic algorithms, Q-learning, offline RL, imitation learning, model-based RL, and multi-agent RL.

Examples include PPO, SAC, DQN, TD3, REDQ, IQL, CQL, Decision Transformer, Dreamer, CrossQ, GAIL, behavior cloning, ACT, MAPPO, IPPO, and QMIX/VDN. Value-estimator utilities provide GAE, TD(lambda), V-trace, lambda returns, multi-agent advantages, and vectorized return computation.

from torchrl.objectives import ClipPPOLoss
from torchrl.objectives.value import GAE

loss = ClipPPOLoss(actor_network=actor, critic_network=critic)
advantage = GAE(value_network=critic, gamma=0.99, lmbda=0.95)

data = advantage(data)
losses = loss(data)
loss_value = losses["loss_objective"] + losses["loss_critic"] + losses["loss_entropy"]

For higher-level workflows, TorchRL also provides trainer utilities and Hydra configuration dataclasses that assemble environments, networks, collectors, losses, optimizers, loggers, hooks, and schedules into reproducible recipes.

Multi-agent, model-based, and imitation learning

Multi-agent data is represented as TensorDict structure rather than a separate parallel convention. Agent observations, actions, rewards, masks, and shared state can live under nested keys such as ("agents", "observation"), while losses and modules declare which keys they use.

TorchRL supports multi-agent environments and algorithms through VMAS, PettingZoo, Melting Pot, SMACv2, OpenSpiel, multi-agent trainers, and dedicated objectives. The 0.13 line adds MAPPO, IPPO, MultiAgentGAE, ValueNorm, PopArtValueNorm, RunningValueNorm, and cross-agent critic utilities.

The same component style also covers model-based and imitation-learning work: Dreamer/DreamerV3 objectives and RSSM modules, Decision Transformer components, behavior cloning losses, and ACT-style action chunking all share the same TensorDict and key-dispatch conventions as the online RL algorithms.

Additional specialized workflows

TorchRL also includes support for specialized workflows, including LLM post-training experiments. The LLM stack provides conversation containers, Hugging Face/vLLM/SGLang integration points, GRPO and SFT objectives, async collectors, weight-update helpers, and tool-use transforms. Entry points include the LLM reference and the GRPO implementation.

Performance and PyTorch integration

TorchRL is designed to stay close to PyTorch execution. Components are TensorDict-aware, vectorized where possible, and increasingly friendly to torch.compile, CUDA, shared memory, memmaps, and distributed execution.

Performance-sensitive areas include:

  • vectorized return and advantage computation;
  • recurrent GRU/LSTM reset handling with scan and Triton backends;
  • compact sequence layouts for recurrent value estimation;
  • async collectors and policy weight synchronization;
  • prioritized replay and CUDA-aware replay-buffer paths;
  • memmap-backed data movement for large offline or distributed jobs.

What is new in TorchRL 0.13

TorchRL 0.13 is a broad release. The most impactful changes are in recurrent RL performance, MuJoCo-native workflows, multi-agent training, model-based and imitation-learning components, replay/collector throughput, and compatibility with old or optional dependency stacks.

Recurrent RL

  • Triton and scan recurrent backends for GRU/LSTM reset handling.
  • Recurrent integration tests and a recurrent state lifecycle guide.
  • Compact and shifted value-estimator improvements, chunked forwards, and a dynamic value-estimator registry across loss modules.
  • Recurrent matmul precision controls exposed through public module utilities.

MuJoCo, robotics, and macro control

  • Custom MuJoCo environments with selectable physics backends.
  • New MujocoEnv task base plus locomotion tasks, SatelliteEnv, and CubeBowlEnv.
  • Satellite MuJoCo SAC examples.
  • Macro-control primitives and tutorials for low-frequency semantic actions expanded into multi-step low-level control sequences.

Multi-agent, imitation, and model-based RL

  • MAPPO and IPPO losses.
  • MultiAgentGAE and value-normalization utilities.
  • DreamerV3 losses and RSSM V3 modules.
  • BCLoss, ACTLoss, and ACTModel for behavior cloning and action chunking.
  • QMIX/VDN trainer configuration support and improved multi-agent trainer ergonomics.

Data, transforms, and compatibility

  • HER support through HERReplayBuffer and HindsightStrategy.
  • Action and observation transforms such as ActionScaling, FlattenAction, ExpandAs, NextObservationDelta, NextStateReconstructor, and TerminateTransform.
  • Async prioritized replay-buffer writes, ordered read/write APIs, optional trajectory IDs, compact observations, and safer collector weight syncs.
  • Compatibility fixes across Gym/Atari, PettingZoo, Robohive, optional dependency, setup, documentation, vLLM, and SGLang workflows.

Where to start

If you want to... Start with...
Learn the basic environment and TensorDict loop Getting started and the quick demo above
Train a classic continuous-control agent PPO, SAC, or TD3 implementations
Build custom environment preprocessing Environment transforms
Scale data collection Collectors and distributed collectors
Store large or prioritized data Replay buffers
Work with recurrent policies Recurrent modules and state lifecycle docs
Train multi-agent systems Multi-agent objectives and multi-agent examples
Explore MuJoCo macro policies Macro primitives and MuJoCo tutorials
Try language-model post-training experiments LLM reference and GRPO

Installation

TorchRL 0.13 targets Python 3.10+, PyTorch 2.1+, and TensorDict 0.13.x.

Install the stable release:

pip install torchrl

This standard PyPI wheel is the right default for most users, including CPU prioritized replay buffers and workloads that do not use prioritized replay. Starting with TorchRL 0.13, Linux CUDA wheels are also published for users who want the CUDA-based prioritized replay-buffer implementations. Install the CUDA wheel from the PyTorch wheel index that matches your PyTorch CUDA runtime (replace cu128 with the CUDA build you use):

pip install "torchrl==0.13.0+cu128" --extra-index-url https://download.pytorch.org/whl/cu128

The CUDA wheel is optional: if you do not need CUDA prioritized replay buffers, or if your prioritized replay buffers run on CPU, keep using pip install torchrl.

Install common optional dependencies:

pip install "torchrl[utils]"              # Hydra, logging, and development utilities
pip install "torchrl[gym_continuous]"     # Gymnasium continuous-control environments
pip install "torchrl[atari]"              # Atari support
pip install "torchrl[offline-data]"       # Offline datasets and data helpers
pip install "torchrl[marl]"               # Multi-agent environment libraries
pip install "torchrl[llm-vllm]"           # LLM API with vLLM backend on Linux
pip install "torchrl[llm-sglang]"         # LLM API with SGLang backend on Linux

Some optional libraries are platform- or Python-version-specific. If you are building a reproducible environment, install PyTorch first from the appropriate PyTorch installation selector, then install TorchRL and the optional extras you need.

Install the nightly builds when working against nightly PyTorch:

pip install --pre tensordict-nightly torchrl-nightly

For local development, keep the TorchRL and TensorDict checkouts on compatible branches and avoid re-resolving an already selected PyTorch build:

git clone https://github.com/pytorch/tensordict
git clone https://github.com/pytorch/rl
uv pip install --no-deps -e tensordict
uv pip install --no-deps -e rl

The C++ extension paths used by prioritized replay buffers require a compatible PyTorch version. If you see undefined-symbol errors, consult the versioning issues guide.

Documentation and learning resources

Introductory material:

Examples, tutorials, and implementations

TorchRL ships examples for small features and complete training recipes:

  • SOTA implementations for PPO, SAC, DQN, TD3, REDQ, Decision Transformer, Dreamer, CrossQ, GAIL, IMPALA, multi-agent algorithms, GRPO, and more.
  • Examples for distributed collectors, replay buffers, RLHF, MuJoCo satellite control, and other focused workflows.
  • Tutorials for environment design, transforms, collectors, losses, recurrent state handling, MuJoCo macros, and end-to-end training.

The implementations are meant to be readable starting points, not black-box benchmarks. They show how TorchRL components fit together and can be copied into research code when a full trainer abstraction is not the right fit.

Ecosystem and publications

TorchRL is domain-agnostic and is used across robotics, control, simulation, drug discovery, multi-agent RL, combinatorial optimization, and research infrastructure. Selected projects and papers include:

  • ACEGEN: Reinforcement learning of generative chemical agents for drug discovery.
  • BenchMARL: Benchmarking multi-agent reinforcement learning.
  • BricksRL: A platform for democratizing robotics and reinforcement learning research and education with LEGO.
  • OmniDrones: An efficient and flexible platform for reinforcement learning in drone control.
  • RL4CO: Reinforcement learning for combinatorial optimization.
  • Robohive: A unified framework for robot learning.

Citation

If you use TorchRL, please cite:

@misc{bou2023torchrl,
      title={TorchRL: A data-driven decision-making library for PyTorch},
      author={Albert Bou and Matteo Bettini and Sebastian Dittert and Vikash Kumar and Shagun Sodhani and Xiaomeng Yang and Gianni De Fabritiis and Vincent Moens},
      year={2023},
      eprint={2306.00577},
      archivePrefix={arXiv},
      primaryClass={cs.LG}
}

Asking questions

If you find a bug, please open an issue in this repository. For broader RL in PyTorch questions, use the PyTorch reinforcement learning forum.

Contributing

Contributions are welcome. See CONTRIBUTING.md for the full contribution guide and the call for contributions for open areas where help is especially useful.

For local development, install pre-commit hooks with:

pre-commit install

Status and license

TorchRL is released as a PyTorch beta feature. Breaking changes can happen, but TorchRL aims to introduce them with deprecation warnings over multiple release cycles.

TorchRL is licensed under the MIT License. See LICENSE for details.

Project details


Download files

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

Source Distributions

No source distribution files available for this release.See tutorial on generating distribution archives.

Built Distributions

If you're not sure about the file name format, learn more about wheel file names.

torchrl_nightly-2026.6.14-cp314-cp314-win_amd64.whl (2.6 MB view details)

Uploaded CPython 3.14Windows x86-64

torchrl_nightly-2026.6.14-cp314-cp314-macosx_10_15_universal2.whl (2.8 MB view details)

Uploaded CPython 3.14macOS 10.15+ universal2 (ARM64, x86-64)

torchrl_nightly-2026.6.14-cp313-cp313-win_amd64.whl (2.6 MB view details)

Uploaded CPython 3.13Windows x86-64

torchrl_nightly-2026.6.14-cp313-cp313-macosx_10_13_universal2.whl (2.8 MB view details)

Uploaded CPython 3.13macOS 10.13+ universal2 (ARM64, x86-64)

torchrl_nightly-2026.6.14-cp312-cp312-win_amd64.whl (2.6 MB view details)

Uploaded CPython 3.12Windows x86-64

torchrl_nightly-2026.6.14-cp312-cp312-macosx_10_13_universal2.whl (2.8 MB view details)

Uploaded CPython 3.12macOS 10.13+ universal2 (ARM64, x86-64)

torchrl_nightly-2026.6.14-cp311-cp311-win_amd64.whl (2.6 MB view details)

Uploaded CPython 3.11Windows x86-64

torchrl_nightly-2026.6.14-cp311-cp311-macosx_10_9_universal2.whl (2.8 MB view details)

Uploaded CPython 3.11macOS 10.9+ universal2 (ARM64, x86-64)

torchrl_nightly-2026.6.14-cp310-cp310-win_amd64.whl (2.6 MB view details)

Uploaded CPython 3.10Windows x86-64

torchrl_nightly-2026.6.14-cp310-cp310-macosx_10_9_universal2.whl (2.8 MB view details)

Uploaded CPython 3.10macOS 10.9+ universal2 (ARM64, x86-64)

File details

Details for the file torchrl_nightly-2026.6.14-cp314-cp314-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp314-cp314-win_amd64.whl
Algorithm Hash digest
SHA256 c960e02c4bdafd6b119d5fbcf57b74d3d299de86c884e0f28c8269f97ca82b87
MD5 d9d85feccd5509a81c01a9216d70ca99
BLAKE2b-256 d509040bdefe20a6a5ce8be7702bef7a8f28ff0c0fc26fa19b1e45168b586fb4

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp314-cp314-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp314-cp314-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 c5e9b0c92fbf72299d2c9ad225be9293d192c9026c9b5d9d59f18b0f5907e9d1
MD5 e755a4b606b1985b6d1d9fb072e7b330
BLAKE2b-256 e1f9fccfb2b73b1ec1f306254b6bae0dd5d905136ee78232e57114d9365d729a

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp314-cp314-macosx_10_15_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp314-cp314-macosx_10_15_universal2.whl
Algorithm Hash digest
SHA256 488eb8bda17428307f6138066b2164b0c7f75fdd69a066535808b3e879d66c3d
MD5 8fc4ef53737c135fe2f36b6f491e5997
BLAKE2b-256 39942a12e303db377372fe539702efb64097a7f83539073275b33f2fd0dfc326

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp313-cp313-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp313-cp313-win_amd64.whl
Algorithm Hash digest
SHA256 eba57a9db2f2335ece57867160c08446d17b3f2fc9ff578db0956a28e91bee85
MD5 fb3e8e22ba056c9fb4bd02ed505aeab8
BLAKE2b-256 fb2b5b62a452a6b5df2fb6e6e75d0cb9e02f13bd086c505d0f92e009b91ba66c

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp313-cp313-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp313-cp313-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 2773245570b7d125e3ce60afe063183ddf532aff0b1af90bb790f5df5f11afb0
MD5 4e2773da596579b575f1f018196af930
BLAKE2b-256 e337cfffc5927106e8219662154833b739ec767dfb6c80e02a35058025357ae5

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp313-cp313-macosx_10_13_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp313-cp313-macosx_10_13_universal2.whl
Algorithm Hash digest
SHA256 8d19d899a9abf27ab57272260b8522baef9124c0002d42cefd0492ce1407bd21
MD5 3822b3fcda2219262859f1cad049ec0d
BLAKE2b-256 53556a79721463ea2a7b040021a9266f37803d818fd460539d8aff53a3700196

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp312-cp312-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp312-cp312-win_amd64.whl
Algorithm Hash digest
SHA256 2df25478e792fbe9db6cab29b66be9b7f47c82dca9685d3b32b8bc0e81825b65
MD5 fe98df90b15feff746e62b097dee5fcb
BLAKE2b-256 3a46a49596aa5bea45c405899441c3aa5cfe2b07ffdcf3100f1e875c2061bf12

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp312-cp312-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp312-cp312-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 2e6c669619734187a0f69be6427811ad02c082aa6768a51b77454ace984567eb
MD5 650a2d62fd4d22a59a5b7a447a81d455
BLAKE2b-256 edd72b64eed8dda8341aade9cb5c09d11190abbf927a501de8d2df8aae249524

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp312-cp312-macosx_10_13_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp312-cp312-macosx_10_13_universal2.whl
Algorithm Hash digest
SHA256 9540b5b98a35f2780c8887b97feb680dc3385de47ad40315d66e823fb480a794
MD5 3b5a2d08fe81c490d63aee64ff1438fd
BLAKE2b-256 3e73ebc5fa3a72a2354cdb22beebdf930b2041cb382c41c18140cbdd8f6123ee

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp311-cp311-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp311-cp311-win_amd64.whl
Algorithm Hash digest
SHA256 b345599d6660a1f7bd1b82f5f20bac380a43202e5f331b69ec92ddd99b58bcee
MD5 459bd581ce441d8592252eafa7e43ff5
BLAKE2b-256 211474742e1838f4ee0ea0b0b5c31a0e57adccc5492db39d07f05f8fe8dccee4

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp311-cp311-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp311-cp311-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 fde547f0d6a2b25269563246229817aa3ee8b2c1187611416a71c5a28b3fbe71
MD5 c02714ce9826d1667de367290531f693
BLAKE2b-256 602a4c30a52e075cd265978a50efd36ba8e974604ff84da79830ad238a7cd3de

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp311-cp311-macosx_10_9_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp311-cp311-macosx_10_9_universal2.whl
Algorithm Hash digest
SHA256 7e2f8204e8fc8ff60326b3ac0c548d252283870894608b698579daca83fea19b
MD5 d36e1a38d122662655420151c0ff9031
BLAKE2b-256 9e7606059422191b0bcb5b6e6fb0a8479033746abce396fb88d96cff7f70ec16

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp310-cp310-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp310-cp310-win_amd64.whl
Algorithm Hash digest
SHA256 3e4668c92dcfc7d1a2f12cfaf812337d4663ba56a732d1b0c8852cce6670bfda
MD5 f6ddd74d6f3537a860ae32022b7ff27a
BLAKE2b-256 3f48f1f7db3bec2f51d7820ecb2323aed92b844cd0224d28513c85ec194d0bcf

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp310-cp310-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp310-cp310-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 736ff78b21931212e021026bfd53b3e304987cdeb171c1ab22c233629c581647
MD5 d96d20606a07a7291c430b1792724760
BLAKE2b-256 cf6491abe94a7d0cce0bc3b1660d98b34ac14fc91e87bfdb5bd574200eefe698

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.6.14-cp310-cp310-macosx_10_9_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.6.14-cp310-cp310-macosx_10_9_universal2.whl
Algorithm Hash digest
SHA256 7ebc9e2f1914416172c59f1b612e254ba1556ea533fb8681931518810582d016
MD5 70c7a654f83302ed659decf93abd71af
BLAKE2b-256 ef3f2815ce8a19f639b4fb7184a9212c8055192acfa96c1966abe6d9ab0362c0

See more details on using hashes here.

Supported by

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