Crates.io | ed25519-dalek-blake2-feeless |
lib.rs | ed25519-dalek-blake2-feeless |
version | 1.0.1 |
source | src |
created_at | 2021-02-08 23:22:08.236206 |
updated_at | 2021-02-08 23:22:08.236206 |
description | A fork of ed25519-dalek specifically for the feeless (Nano cryptocurrency) crate, supporting blake2b in some functions. |
homepage | https://dalek.rs |
repository | https://github.com/gak/ed25519-dalek/tree/blake2b |
max_upload_size | |
id | 352544 |
size | 122,588 |
Fast and efficient Rust implementation of ed25519 key generation, signing, and verification in Rust.
Documentation is available here.
To install, add the following to your project's Cargo.toml
:
[dependencies.ed25519-dalek]
version = "1"
On an Intel Skylake i9-7900X running at 3.30 GHz, without TurboBoost, this code achieves the following performance benchmarks:
∃!isisⒶmistakenot:(master *=)~/code/rust/ed25519-dalek ∴ cargo bench
Compiling ed25519-dalek v0.7.0 (file:///home/isis/code/rust/ed25519-dalek)
Finished release [optimized] target(s) in 3.11s
Running target/release/deps/ed25519_benchmarks-721332beed423bce
Ed25519 signing time: [15.617 us 15.630 us 15.647 us]
Ed25519 signature verification time: [45.930 us 45.968 us 46.011 us]
Ed25519 keypair generation time: [15.440 us 15.465 us 15.492 us]
By enabling the avx2 backend (on machines with compatible microarchitectures), the performance for signature verification is greatly improved:
∃!isisⒶmistakenot:(master *=)~/code/rust/ed25519-dalek ∴ export RUSTFLAGS=-Ctarget_cpu=native
∃!isisⒶmistakenot:(master *=)~/code/rust/ed25519-dalek ∴ cargo bench --features=avx2_backend
Compiling ed25519-dalek v0.7.0 (file:///home/isis/code/rust/ed25519-dalek)
Finished release [optimized] target(s) in 4.28s
Running target/release/deps/ed25519_benchmarks-e4866664de39c84d
Ed25519 signing time: [15.923 us 15.945 us 15.967 us]
Ed25519 signature verification time: [33.382 us 33.411 us 33.445 us]
Ed25519 keypair generation time: [15.246 us 15.260 us 15.275 us]
In comparison, the equivalent package in Golang performs as follows:
∃!isisⒶmistakenot:(master *=)~/code/go/src/github.com/agl/ed25519 ∴ go test -bench .
BenchmarkKeyGeneration 30000 47007 ns/op
BenchmarkSigning 30000 48820 ns/op
BenchmarkVerification 10000 119701 ns/op
ok github.com/agl/ed25519 5.775s
Making key generation and signing a rough average of 2x faster, and verification 2.5-3x faster depending on the availability of avx2. Of course, this is just my machine, and these results—nowhere near rigorous—should be taken with a handful of salt.
Translating to a rough cycle count: we multiply by a factor of 3.3 to convert nanoseconds to cycles per second on a 3300 Mhz CPU, that's 110256 cycles for verification and 52618 for signing, which is competitive with hand-optimised assembly implementations.
Additionally, if you're using a CSPRNG from the rand
crate, the nightly
feature will enable u128
/i128
features there, resulting in potentially
faster performance.
If your protocol or application is able to batch signatures for verification,
the verify_batch()
function has greatly improved performance. On the
aforementioned Intel Skylake i9-7900X, verifying a batch of 96 signatures takes
1.7673ms. That's 18.4094us, or roughly 60750 cycles, per signature verification,
more than double the speed of batch verification given in the original paper
(this is likely not a fair comparison as that was a Nehalem machine).
The numbers after the /
in the test name refer to the size of the batch:
∃!isisⒶmistakenot:(master *=)~/code/rust/ed25519-dalek ∴ export RUSTFLAGS=-Ctarget_cpu=native
∃!isisⒶmistakenot:(master *=)~/code/rust/ed25519-dalek ∴ cargo bench --features=avx2_backend batch
Compiling ed25519-dalek v0.8.0 (file:///home/isis/code/rust/ed25519-dalek)
Finished release [optimized] target(s) in 34.16s
Running target/release/deps/ed25519_benchmarks-cf0daf7d68fc71b6
Ed25519 batch signature verification/4 time: [105.20 us 106.04 us 106.99 us]
Ed25519 batch signature verification/8 time: [178.66 us 179.01 us 179.39 us]
Ed25519 batch signature verification/16 time: [325.65 us 326.67 us 327.90 us]
Ed25519 batch signature verification/32 time: [617.96 us 620.74 us 624.12 us]
Ed25519 batch signature verification/64 time: [1.1862 ms 1.1900 ms 1.1943 ms]
Ed25519 batch signature verification/96 time: [1.7611 ms 1.7673 ms 1.7742 ms]
Ed25519 batch signature verification/128 time: [2.3320 ms 2.3376 ms 2.3446 ms]
Ed25519 batch signature verification/256 time: [5.0124 ms 5.0290 ms 5.0491 ms]
As you can see, there's an optimal batch size for each machine, so you'll likely want to test the benchmarks on your target CPU to discover the best size. For this machine, around 100 signatures per batch is the optimum:
Additionally, thanks to Rust, this implementation has both type and memory safety. It's also easily readable by a much larger set of people than those who can read qhasm, making it more readily and more easily auditable. We're of the opinion that, ultimately, these features—combined with speed—are more valuable than simply cycle counts alone.
The signatures produced by this library are malleable, as discussed in the original paper:
While the scalar component of our Signature
struct is strictly not
malleable, because reduction checks are put in place upon Signature
deserialisation from bytes, for all types of signatures in this crate,
there is still the question of potential malleability due to the group
element components.
We could eliminate the latter malleability property by multiplying by the curve cofactor, however, this would cause our implementation to not match the behaviour of every other implementation in existence. As of this writing, RFC 8032, "Edwards-Curve Digital Signature Algorithm (EdDSA)," advises that the stronger check should be done. While we agree that the stronger check should be done, it is our opinion that one shouldn't get to change the definition of "ed25519 verification" a decade after the fact, breaking compatibility with every other implementation.
However, if you require this, please see the documentation for the
verify_strict()
function, which does the full checks for the group elements.
This functionality is available by default.
If for some reason—although we strongely advise you not to—you need to conform
to the original specification of ed25519 signatures as in the excerpt from the
paper above, you can disable scalar malleability checking via
--features='legacy_compatibility'
. WE STRONGLY ADVISE AGAINST THIS.
legacy_compatibility
FeatureBy default, this library performs a stricter check for malleability in the
scalar component of a signature, upon signature deserialisation. This stricter
check, that s < \ell
where \ell
is the order of the basepoint, is
mandated by RFC8032.
However, that RFC was standardised a decade after the original paper, which, as
described above, (usually, falsely) stated that malleability was inconsequential.
Because of this, most ed25519 implementations only perform a limited, hackier check that the most significant three bits of the scalar are unset. If you need compatibility with legacy implementations, including:
-DED25519_COMPAT
)then enable ed25519-dalek
's legacy_compatibility
feature. Please note and
be forewarned that doing so allows for signature malleability, meaning that
there may be two different and "valid" signatures with the same key for the same
message, which is obviously incredibly dangerous in a number of contexts,
including—but not limited to—identification protocols and cryptocurrency
transactions.
verify_strict()
FunctionThe scalar component of a signature is not the only source of signature malleability, however. Both the public key used for signature verification and the group element component of the signature are malleable, as they may contain a small torsion component as a consquence of the curve25519 group not being of prime order, but having a small cofactor of 8.
If you wish to also eliminate this source of signature malleability, please
review the
documentation for the verify_strict()
function.
The original paper's specification and the standarisation of RFC8032 do not specify precisely how randomness is to be generated, other than using a CSPRNG (Cryptographically Secure Random Number Generator). Particularly in the case of signature verification, where the security proof relies on the uniqueness of the blinding factors/nonces, it is paramount that these samples of randomness be unguessable to an adversary. Because of this, a current growing belief among cryptographers is that it is safer to prefer synthetic randomness.
To explain synthetic randomness, we should first explain how ed25519-dalek
handles generation of deterministic randomness. This mode is disabled by
default due to a tiny-but-not-nonexistent chance that this mode will open users
up to fault attacks, wherein an adversary who controls all of the inputs to
batch verification (i.e. the public keys, signatures, and messages) can craft
them in a specialised manner such as to induce a fault (e.g. causing a
mistakenly flipped bit in RAM, overheating a processor, etc.). In the
deterministic mode, we seed the PRNG which generates our blinding factors/nonces
by creating
a PRNG based on the Fiat-Shamir transform of the public inputs.
This mode is potentially useful to protocols which require strong auditability
guarantees, as well as those which do not have access to secure system-/chip-
provided randomness. This feature can be enabled via
--features='batch_deterministic'
. Note that we do not support deterministic
signing, due to the numerous pitfalls therein, including a re-used nonce
accidentally revealing the secret key.
In the default mode, we do as above in the fully deterministic mode, but we ratchet the underlying keccak-f1600 function (used for the provided transcript-based PRNG) forward additionally based on some system-/chip- provided randomness. This provides synthetic randomness, that is, randomness based on both deterministic and undeterinistic data. The reason for doing this is to prevent badly seeded system RNGs from ruining the security of the signature verification scheme.
This library aims to be #![no_std]
compliant. If batch verification is
required (--features='batch'
), please enable either of the std
or alloc
features.
To cause your application to build ed25519-dalek
with the nightly feature
enabled by default, instead do:
[dependencies.ed25519-dalek]
version = "1"
features = ["nightly"]
To cause your application to instead build with the nightly feature enabled
when someone builds with cargo build --features="nightly"
add the following
to the Cargo.toml
:
[features]
nightly = ["ed25519-dalek/nightly"]
To enable serde support, build ed25519-dalek
with the
serde
feature.
By default, ed25519-dalek
builds against curve25519-dalek
's u64_backend
feature, which uses Rust's i128
feature to achieve roughly double the speed as
the u32_backend
feature. When targetting 32-bit systems, however, you'll
likely want to compile with cargo build --no-default-features --features="u32_backend"
. If you're building for a machine with avx2
instructions, there's also the experimental simd_backend
s, currently
comprising either avx2 or avx512 backends. To use them, compile with
RUSTFLAGS="-C target_cpu=native" cargo build --no-default-features --features="simd_backend"
The standard variants of batch signature verification (i.e. many signatures made
with potentially many different public keys over potentially many different
message) is available via the batch
feature. It uses synthetic randomness, as
noted above.
The same notion of batch signature verification as above, but with purely
deterministic randomness can be enabled via the batch_deterministic
feature.