Crates.io | neptune |
lib.rs | neptune |
version | 13.0.0 |
source | src |
created_at | 2020-01-06 21:30:53.291794 |
updated_at | 2023-11-08 19:41:05.990908 |
description | Poseidon hashing over BLS12-381 for Filecoin. |
homepage | |
repository | https://github.com/lurk-lab/neptune |
max_upload_size | |
id | 195942 |
size | 6,197,274 |
Neptune is a Rust implementation of the Poseidon hash function tuned for Filecoin.
Neptune has been audited by ADBK Consulting and deemed fully compliant with the paper (Starkad and Poseidon: New Hash Functions for Zero Knowledge Proof Systems).
Neptune was initially specialized to the BLS12-381 curve. Although the API allows for type specialization to other fields, the round numbers, constants, and s-box selection may not be correct. As long as the alternate field is a prime field of ~256 bits, the 128-bit security Neptune targets will apply. There is a run-time assertion which will fail if constants are generated for a field whose elements do not have a representation of exactly 32 byte. The Pasta Curves meet these criteria and are explicitly supported by Neptune.
At the time of the 1.0.0 release, Neptune on RTX 2080Ti GPU can build 8-ary Merkle trees for 4GiB of input in 16 seconds.
Filecoin's Poseidon specification is published in the Filecoin specification document here. Additionally, Markdown and PDF versions are mirrored in this repo in the spec
directory.
The spec's PDF is rendered using Typora. Download the spec's Markdown file here, open the file in Typora, make and save your changes, then export the file as a PDF.
When making changes to the spec documents in neptune
, make sure that the spec's PDF file poseidon_spec.pdf
is the PDF rendering of the Markdown spec poseidon_spec.md
.
If you make changes to the spec in neptune
, you must make those same changes to the Filecoin spec here, thus ensuring all three document's (one Markdown+Latex and one PDF in neptune
and one Markdown+MathJax in filecoin-project/specs
) stay in sync.
EC_GPU_FRAMEWORK=<cuda | opencl>
allows to select whether the CUDA or OpenCL implementation should be used. If not set, cuda
will be used if available.
EC_GPU_CUDA_NVCC_ARGS
By default the CUDA kernel is compiled for several architectures, which may take a long time. EC_GPU_CUDA_NVCC_ARGS
can be used to override those arguments. The input and output file will still be automatically set.
// Example for compiling the kernel for only the Turing architecture
EC_GPU_CUDA_NVCC_ARGS="--fatbin --gpu-architecture=sm_75 --generate-code=arch=compute_75,code=sm_75"
Neptune also supports batch hashing and tree building, which can be performed on a GPU. GPU batch hashing is implemented in pure CUDA/OpenCL. The pure CUDA/OpenCL batch hashing is provided by the internal proteus
module. To use proteus
, compile neptune
with the opencl
and/or cuda
feature.
The cuda
and opencl
feature can be used independently or together. If both cuda
and opencl
are used, you can also select which implementation to use via the NEPTUNE_GPU_FRAMEWORK
environment variable.
The CUDA/OpenCL kernel (enabled with the cuda/opencl
feature) is generated with specific arities. Those arities need to be specified at compile-time via Rust feature flags. Available features are arity2
, arity4
, arity8
, arity11
, arity16
, arity24
, arity36
. When the strengthened
feature is enables, there will be an additional strengthened version available for each arity.
When using the cuda
feature, the kernel is generated at compile-time. The more arities are used, the longer is the compile time. Hence, by default there are no specific arities enabled. You need to set at least one yourself.
The CUDA/OpenCL kernel (enabled with the cuda/opencl
feature) is generated for specific fields. Those fields need to be specified at compile-time via Rust feature flags. Available features are bls
for BLS12-381 and pasta
for the Pallas and Vesta curves' scalar fields.
As the compile-time of the kernel depends on how many arities are used, there are no arities enabled by default. In order to run the test, all arities need to explicitly be enabled. To run all tests on e.g. the CUDA implementation, run:
cargo test --no-default-features --features cuda,bls,pasta,arity2,arity4,arity8,arity11,arity16,arity24,arity36
Benchmark Poseidon over the BLS12-381, Pallas, and Vesta scalar fields for preimages of length 2
, 4
, 8
, or 11
using:
cargo bench arity-<preimage len>
Benchmark Poseidon over a specific field (bls
, pallas
, or vesta
) and preimage length using:
cargo bench arity-<preimage len>/<field name>
Neptune implements the Secure Sponge API for Field Elements and serves as its reference implementation. The SpongeAPI
trait defines the relevant API methods. See tests in source for simple examples of API usage with circuits and without circuits.
Neptune was originally bootstrapped from Dusk's reference implementation.
MIT or Apache 2.0