Skip to main content

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

Project description

Unit-tests Nightly Documentation Benchmarks CI Timing 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-2026.7.18-cp314-cp314-win_amd64.whl (3.0 MB view details)

Uploaded CPython 3.14Windows x86-64

torchrl_nightly-2026.7.18-cp314-cp314-macosx_10_15_universal2.whl (3.2 MB view details)

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

torchrl_nightly-2026.7.18-cp313-cp313-win_amd64.whl (3.0 MB view details)

Uploaded CPython 3.13Windows x86-64

torchrl_nightly-2026.7.18-cp313-cp313-macosx_10_13_universal2.whl (3.2 MB view details)

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

torchrl_nightly-2026.7.18-cp312-cp312-win_amd64.whl (3.0 MB view details)

Uploaded CPython 3.12Windows x86-64

torchrl_nightly-2026.7.18-cp312-cp312-macosx_10_13_universal2.whl (3.2 MB view details)

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

torchrl_nightly-2026.7.18-cp311-cp311-win_amd64.whl (3.0 MB view details)

Uploaded CPython 3.11Windows x86-64

torchrl_nightly-2026.7.18-cp311-cp311-macosx_10_9_universal2.whl (3.2 MB view details)

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

torchrl_nightly-2026.7.18-cp310-cp310-win_amd64.whl (3.0 MB view details)

Uploaded CPython 3.10Windows x86-64

torchrl_nightly-2026.7.18-cp310-cp310-macosx_10_9_universal2.whl (3.2 MB view details)

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

File details

Details for the file torchrl_nightly-2026.7.18-cp314-cp314-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp314-cp314-win_amd64.whl
Algorithm Hash digest
SHA256 1f39f836406b1d805ffa519466b667e631c2c4cd1afb678530d5890e44b726d7
MD5 36710bec60a63c475c45d76edeb07f68
BLAKE2b-256 d312c10bc89cd857238cab350b2eaddab473157bf1e4b87f19a83eaed0cbdfd6

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp314-cp314-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp314-cp314-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 bb4e92d6702b216a4ceedba64414d3e35eefbd61fbec523d3057330f5bfb5f67
MD5 1a0ca46ce0cc3940135b23c5ab8a06e1
BLAKE2b-256 7162a186c7e19e65e6ed0724a37c8f3a6615d303a094e38d7e2f7cafa52b2ef0

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp314-cp314-macosx_10_15_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp314-cp314-macosx_10_15_universal2.whl
Algorithm Hash digest
SHA256 ca184756fc62e4bfa3154f7cabd250d048b733f0ab61452c11c04da46c3dbae6
MD5 3f633c7a167fb7065e7840203a843bb3
BLAKE2b-256 bb763bc0292dd5ad84910f56438a406429d09a8101b89b9920a6e2542793dc9a

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp313-cp313-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp313-cp313-win_amd64.whl
Algorithm Hash digest
SHA256 febbf099417ed964951fedd4f8e9e517e97d15f3276cb61f9d22d9abc7a4374a
MD5 12a8e5aa12f3c06c771c996790bcace8
BLAKE2b-256 d0c504894727e937fd41dfd3895ba30bcc20f066f8253f3b98c501cfceda2565

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp313-cp313-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp313-cp313-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 d8c9b8e50945d3fc9bfa054d3d351863046fab7dd169eba5c5480bb0ca800022
MD5 975d546f1c6d996a988feb9d484cdc35
BLAKE2b-256 af0c10b7696a3619dc304d519ec0c2dfcf33b18ed2b6bedbbd381ca6de602059

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp313-cp313-macosx_10_13_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp313-cp313-macosx_10_13_universal2.whl
Algorithm Hash digest
SHA256 bbbb96472db5b4940cd967580d1cbf750273934ba92920fcd205ffd57fa246d9
MD5 7c7b2b42b450d1fd5c00fcfc65dd19bb
BLAKE2b-256 18e123f9b8fb631c4f1dfca99b4b1290243b50c3e13640a7cd61927e1db774c9

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp312-cp312-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp312-cp312-win_amd64.whl
Algorithm Hash digest
SHA256 0f881f63b4a98d500b56b652f26b4dbb124fed03dbbb5b285b702669f364d8e4
MD5 31b6ab4629042c94f081fe3c83a8663b
BLAKE2b-256 19c4d9002dfef8b12276719829d991e1f639e589643e4b72b83a9e0ef82b1bc2

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp312-cp312-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp312-cp312-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 1be8535a906fc681ebc7bd31a4c3e7a207b37bde3a47770a54268f94a8fa8aed
MD5 c4468ebc9782974c944d61811ed84406
BLAKE2b-256 b3608ae2794c752d1037cfd12df5bd4db44b4458fbef3e42fcef03793a705b96

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp312-cp312-macosx_10_13_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp312-cp312-macosx_10_13_universal2.whl
Algorithm Hash digest
SHA256 0364e2e6087f67adbe6cdd3ae7bb088777b110dee3633a468ce8f503c5dccc92
MD5 bf65ca727a1981244c55c50729cc2d40
BLAKE2b-256 365c785d3765eb5e605c0d9cd86aa61e56cd35fff422f2aabf1c53407383d86a

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp311-cp311-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp311-cp311-win_amd64.whl
Algorithm Hash digest
SHA256 25cde59807dae49228443f04f5da04b112efe5205c8cf9b3c8186937c8545f9c
MD5 0b6e701ae71c92963001f57c6b964201
BLAKE2b-256 6d1e03830e2c7df18bd14a197aacf1bdad9ce70badec7260c3b26245a8370a63

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp311-cp311-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp311-cp311-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 53bb72f228fac363d189242f354f09732f9de16a0dc8dda463d9071c83fbccef
MD5 b9dba9056ac2b9c2706940866c64380d
BLAKE2b-256 49965e089a5253868494a423c936f011a08c2aae1e8f20462abf12635769adac

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp311-cp311-macosx_10_9_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp311-cp311-macosx_10_9_universal2.whl
Algorithm Hash digest
SHA256 1f2320edd65567ed1a6411fd779a37b778cfe827b47f73560a3da1fdef988b69
MD5 b6aa01b7d66473da6ef6e2ba563f6f4e
BLAKE2b-256 0b1574d8953fbdd2f2ab85ab2864452f0cd1328a22829ecb07cb870c33614c3e

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp310-cp310-win_amd64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp310-cp310-win_amd64.whl
Algorithm Hash digest
SHA256 968494e704466579a77ac2d7ea4548e2d0f5cfb266a71b834ee3866b88765c56
MD5 14be3583a867324c90f693f32feac107
BLAKE2b-256 d3c12c65ed8c4aa67b5e42f58a65d41734fa5f470098f61c5fef167e1518e84b

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp310-cp310-manylinux1_x86_64.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp310-cp310-manylinux1_x86_64.whl
Algorithm Hash digest
SHA256 cb2b0adea99cd489d0fa0c7bbb59364d1663827656848ac65e2dfa941b746c49
MD5 cc8ff111943d3a1dc00fe7681c742fd7
BLAKE2b-256 bfd59ceba575aa1e781dcab500516fc68a59963c7d31fa8ee54af434ce059a96

See more details on using hashes here.

File details

Details for the file torchrl_nightly-2026.7.18-cp310-cp310-macosx_10_9_universal2.whl.

File metadata

File hashes

Hashes for torchrl_nightly-2026.7.18-cp310-cp310-macosx_10_9_universal2.whl
Algorithm Hash digest
SHA256 7f84d8f51f10dfb5eedefcadfbb4a45b8b3e6c0436e912e23a23d556c74b01db
MD5 42d550a3b6baed3cd1864c27c4cca05f
BLAKE2b-256 052e3791de4720f50ddcc3a8142077acb690a0570933f0ea5ace0bb6bb059516

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