Skip to main content

Low-level Pythonic bindings for AWS EFA (SRD RDMA via libibverbs/libefa), with GPUDirect support

Project description

efa

Low-level Python bindings for AWS Elastic Fabric Adapter (EFA), including Scalable Reliable Datagram (SRD), one-sided RDMA, and GPUDirect transfers to and from torch CUDA tensors.

The package wraps libibverbs and EFA's libefa direct-verbs API in Cython. Its data path calls the provider's inline verbs directly, releases the GIL around blocking and posting operations, and does not import torch or link against CUDA.

  • No Python runtime dependencies.
  • SRD and UD queue pairs with SEND, RDMA read, and RDMA write operations.
  • Host buffers, CUDA device pointers, and dma-buf memory registration.
  • Classic and extended CQs, sender GID and unsolicited-write metadata, and direct EFA CQ, SQ, RQ, MR, and AH queries.
  • One Linux abi3 wheel for CPython 3.9 and newer.

Requirements

  • Linux on an AWS instance with one or more EFA devices attached.
  • libibverbs.so.1 and libefa.so.1 at runtime. The AWS EFA installer and current rdma-core distributions provide both.
  • The EFA device nodes available inside the process or container, normally /dev/infiniband/uverbs*.
  • A C compiler, Cython, and the rdma-core development headers only when building from source.

For GPUDirect, the EFA device and instance type must support RDMA read/write, and the NVIDIA driver must support dma-buf export or nvidia_peermem.

Install

pip install efa

To build from this checkout:

pip install "Cython>=3.0" "setuptools>=77" wheel
pip install ./efa

SRD Quickstart

SRD is reliable and connectionless. Each process creates a ready-to-send QP, exchanges a 24-byte EndpointInfo out of band, and resolves the remote GID to an address handle:

import numpy as np
import efa

dev = efa.get_efa_device_list()[0]
ctx = dev.open()
pd = ctx.alloc_pd()
cq = ctx.create_cq(256)
qp = pd.create_qp(
    efa.QPInitAttr(send_cq=cq, recv_cq=cq)
).prepare(qkey=0x1234)

local_info = efa.local_endpoint_info(qp, qkey=0x1234)
# Exchange local_info.to_bytes() with the other process.
remote_info = efa.EndpointInfo.from_bytes(remote_bytes)
peer = remote_info.peer(pd)

buf = np.zeros(4096, dtype=np.uint8)
access = (
    efa.AccessFlags.LOCAL_WRITE
    | efa.AccessFlags.REMOTE_WRITE
    | efa.AccessFlags.REMOTE_READ
)
mr = efa.reg_tensor(pd, buf, access)

qp.post_send(efa.SendWR(
    wr_id=1,
    sg_list=[mr.sge()],
    opcode=efa.WROpcode.SEND,
    send_flags=efa.SendFlags.SIGNALED,
    dest=peer,
))
for wc in cq.poll(16):
    wc.raise_for_status()

Every handle is an idempotent context manager. A QP retains its PD and CQs, an MR retains its PD and backing tensor, and an SGE retains the MR it addresses.

One-sided RDMA

EFA requires the responder to have an address handle for the requester before it accepts RDMA reads or writes. Both processes should therefore resolve the other process's EndpointInfo, even if traffic is currently one-way. A missing reverse AH completes with REM_OP_ERR and EFA vendor status 0x0e (REMOTE_ERROR_UNKNOWN_PEER).

Large buffers can be split at the device's max_rdma_size:

wrs = efa.write_wrs(local_mr, peer, remote_addr, remote_rkey)
qp.post_send(wrs)

read_wrs provides the corresponding RDMA-read operation. Every generated WR is signaled, as required by EFA.

GPUDirect With Torch

The optional efa.cuda module is torch-free and duck-types objects exposing data_ptr(), numel(), and element_size(). For torch's dma-buf path, enable VMM-backed allocations before CUDA initializes:

import os
os.environ["PYTORCH_CUDA_ALLOC_CONF"] = "expandable_segments:True"

import torch
import efa
import efa.cuda

src = torch.arange(1 << 20, dtype=torch.float32, device="cuda:0")
dst = torch.zeros_like(src)

src_mr = efa.cuda.register_tensor(pd, src, access)
dst_mr = efa.cuda.register_tensor(pd, dst, access)

torch.cuda.synchronize(src.device)
qp.post_send(efa.SendWR(
    wr_id=2,
    sg_list=[src_mr.sge()],
    opcode=efa.WROpcode.RDMA_WRITE,
    send_flags=efa.SendFlags.SIGNALED,
    remote_addr=remote_dst_addr,
    rkey=remote_dst_rkey,
    dest=peer,
))

After the receiver observes a completion or protocol-level write notification, it must order inbound NIC writes before CUDA consumes the destination:

with torch.cuda.device(dst.device):
    efa.cuda.flush_gpudirect_writes()

register_tensor first exports a dma-buf fd and calls ibv_reg_dmabuf_mr. If that path is unavailable, it falls back to ibv_reg_mr, which requires nvidia_peermem. The returned GpuMR retains the tensor allocation and keeps the actual CUDA virtual address because ibv_mr.addr is not meaningful for a dma-buf MR.

Direct EFA API

Area API
Device capabilities Context.query_efa_device
EFA CQ creation Context.create_cq_ex
Sender and unsolicited metadata CQEx.poll, WC.sgid, WC.unsolicited
CQ layout CQ.query_efa, CQEx.query_efa
SQ/RQ layout QP.query_wqs
MR interconnect IDs MR.query_efa
Address-handle number AH.ahn
SRD QP creation PD.create_qp with QPType.SRD

When using unsolicited RDMA write-with-immediate completions, create every communicating QP with QPInitAttr(..., unsolicited_write_recv=True) and use an extended CQ created with unsolicited=True. EFA requires peers to negotiate the same QP feature set.

The direct layout queries expose process-local addresses for advanced consumers. They do not transfer ownership of provider memory.

Testing

pip install -e "./efa[test,gpu]"
cd efa
pytest -rs

Tests marked integration exercise real EFA hardware. Tests marked gpu perform torch-verified GPU-to-GPU, GPU-to-host, and host-to-GPU transfers. Unavailable hardware capabilities are skipped explicitly.

License

BSD-3-Clause. See LICENSE.

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

efa-2026.7.18.tar.gz (354.9 kB view details)

Uploaded Source

Built Distributions

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

efa-2026.7.18-cp39-abi3-manylinux2014_aarch64.manylinux_2_17_aarch64.manylinux_2_28_aarch64.whl (1.2 MB view details)

Uploaded CPython 3.9+manylinux: glibc 2.17+ ARM64manylinux: glibc 2.28+ ARM64

efa-2026.7.18-cp39-abi3-manylinux1_x86_64.manylinux_2_28_x86_64.manylinux_2_5_x86_64.whl (1.2 MB view details)

Uploaded CPython 3.9+manylinux: glibc 2.28+ x86-64manylinux: glibc 2.5+ x86-64

File details

Details for the file efa-2026.7.18.tar.gz.

File metadata

  • Download URL: efa-2026.7.18.tar.gz
  • Upload date:
  • Size: 354.9 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? Yes
  • Uploaded via: twine/6.1.0 CPython/3.13.12

File hashes

Hashes for efa-2026.7.18.tar.gz
Algorithm Hash digest
SHA256 3cdc63896b1dc61f3802db219512af20764bf4dd7edb6b22cb8dab55cfe2a3be
MD5 3744c99131a4f4d4a3d62ce34f7fd509
BLAKE2b-256 2f341c7087a281052f03bc761bec81b699ed842aea6e1f8dbf53b2e84532f69b

See more details on using hashes here.

Provenance

The following attestation bundles were made for efa-2026.7.18.tar.gz:

Publisher: publish_efa.yml on d4l3k/rdma4py

Attestations: Values shown here reflect the state when the release was signed and may no longer be current.

File details

Details for the file efa-2026.7.18-cp39-abi3-manylinux2014_aarch64.manylinux_2_17_aarch64.manylinux_2_28_aarch64.whl.

File metadata

File hashes

Hashes for efa-2026.7.18-cp39-abi3-manylinux2014_aarch64.manylinux_2_17_aarch64.manylinux_2_28_aarch64.whl
Algorithm Hash digest
SHA256 086216dcb0664c1d4ce4de5f725fde6dd272aec4ff25ab2f359e85cfa4682fd8
MD5 44cf1437c5035a308ec3738605acf2fc
BLAKE2b-256 6f47fba98f495f12df2344a331aa6e2f15d2b239e7974c5639611ca09adab4d3

See more details on using hashes here.

Provenance

The following attestation bundles were made for efa-2026.7.18-cp39-abi3-manylinux2014_aarch64.manylinux_2_17_aarch64.manylinux_2_28_aarch64.whl:

Publisher: publish_efa.yml on d4l3k/rdma4py

Attestations: Values shown here reflect the state when the release was signed and may no longer be current.

File details

Details for the file efa-2026.7.18-cp39-abi3-manylinux1_x86_64.manylinux_2_28_x86_64.manylinux_2_5_x86_64.whl.

File metadata

File hashes

Hashes for efa-2026.7.18-cp39-abi3-manylinux1_x86_64.manylinux_2_28_x86_64.manylinux_2_5_x86_64.whl
Algorithm Hash digest
SHA256 b98808d651edb240b710655e605f5cb24ee9bee2cd9bf29b972df5a5e90b4b0e
MD5 a47ddd98835a10d201ec71b2cf1510c0
BLAKE2b-256 df534bf136a1a8e095a9490d73f0943a176fe863659b2af2869cf6d7abec4565

See more details on using hashes here.

Provenance

The following attestation bundles were made for efa-2026.7.18-cp39-abi3-manylinux1_x86_64.manylinux_2_28_x86_64.manylinux_2_5_x86_64.whl:

Publisher: publish_efa.yml on d4l3k/rdma4py

Attestations: Values shown here reflect the state when the release was signed and may no longer be current.

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