#![crate_type = "lib"]
#![crate_type = "rlib"]
#![crate_type = "dylib"]
#![crate_name = "secp256k1"]
#![deny(non_upper_case_globals)]
#![deny(non_camel_case_types)]
#![deny(non_snake_case)]
#![deny(unused_mut)]
#![warn(missing_docs)]
#![allow(bare_trait_objects)]
#![allow(ellipsis_inclusive_range_patterns)]
#![cfg_attr(feature = "dev", allow(unstable_features))]
#![cfg_attr(feature = "dev", feature(plugin))]
#![cfg_attr(feature = "dev", plugin(clippy))]
#![cfg_attr(all(not(test), not(fuzztarget), not(feature = "std")), no_std)]
#![cfg_attr(all(test, feature = "unstable"), feature(test))]
#[macro_use]
pub extern crate secp256k1_sys;
pub use secp256k1_sys as ffi;
#[cfg(feature = "bitcoin_hashes")] extern crate bitcoin_hashes;
#[cfg(all(test, feature = "unstable"))] extern crate test;
#[cfg(any(test, feature = "rand"))] pub extern crate rand;
#[cfg(any(test))] extern crate rand_core;
#[cfg(feature = "serde")] pub extern crate serde;
#[cfg(all(test, feature = "serde"))] extern crate serde_test;
#[cfg(any(test, feature = "rand"))] use rand::Rng;
#[cfg(any(test, feature = "std"))] extern crate core;
use core::{fmt, ptr, str};
#[macro_use]
mod macros;
mod context;
pub mod constants;
pub mod ecdh;
pub mod key;
#[cfg(feature = "recovery")]
pub mod recovery;
pub use key::SecretKey;
pub use key::PublicKey;
pub use context::*;
use core::marker::PhantomData;
use core::ops::Deref;
use ffi::CPtr;
#[cfg(feature = "global-context")]
pub use context::global::SECP256K1;
#[cfg(feature = "bitcoin_hashes")]
use bitcoin_hashes::Hash;
#[derive(Copy, Clone, PartialEq, Eq)]
pub struct Signature(ffi::Signature);
#[derive(Copy, Clone)]
pub struct SerializedSignature {
data: [u8; 72],
len: usize,
}
impl fmt::Debug for Signature {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
fmt::Display::fmt(self, f)
}
}
impl fmt::Display for Signature {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let sig = self.serialize_der();
for v in sig.iter() {
write!(f, "{:02x}", v)?;
}
Ok(())
}
}
impl str::FromStr for Signature {
type Err = Error;
fn from_str(s: &str) -> Result<Signature, Error> {
let mut res = [0; 72];
match from_hex(s, &mut res) {
Ok(x) => Signature::from_der(&res[0..x]),
_ => Err(Error::InvalidSignature),
}
}
}
pub trait ThirtyTwoByteHash {
fn into_32(self) -> [u8; 32];
}
#[cfg(feature = "bitcoin_hashes")]
impl ThirtyTwoByteHash for bitcoin_hashes::sha256::Hash {
fn into_32(self) -> [u8; 32] {
self.into_inner()
}
}
#[cfg(feature = "bitcoin_hashes")]
impl ThirtyTwoByteHash for bitcoin_hashes::sha256d::Hash {
fn into_32(self) -> [u8; 32] {
self.into_inner()
}
}
#[cfg(feature = "bitcoin_hashes")]
impl<T: bitcoin_hashes::sha256t::Tag> ThirtyTwoByteHash for bitcoin_hashes::sha256t::Hash<T> {
fn into_32(self) -> [u8; 32] {
self.into_inner()
}
}
impl SerializedSignature {
pub(crate) fn get_data_mut_ptr(&mut self) -> *mut u8 {
self.data.as_mut_ptr()
}
pub fn capacity(&self) -> usize {
self.data.len()
}
pub fn len(&self) -> usize {
self.len
}
pub(crate) fn set_len(&mut self, len: usize) {
self.len = len;
}
pub fn to_signature(&self) -> Result<Signature, Error> {
Signature::from_der(&self)
}
pub fn from_signature(sig: &Signature) -> SerializedSignature {
sig.serialize_der()
}
pub fn is_empty(&self) -> bool { self.len() == 0 }
}
impl Signature {
#[inline]
pub fn from_der(data: &[u8]) -> Result<Signature, Error> {
if data.is_empty() {return Err(Error::InvalidSignature);}
let mut ret = ffi::Signature::new();
unsafe {
if ffi::secp256k1_ecdsa_signature_parse_der(
ffi::secp256k1_context_no_precomp,
&mut ret,
data.as_c_ptr(),
data.len() as usize,
) == 1
{
Ok(Signature(ret))
} else {
Err(Error::InvalidSignature)
}
}
}
pub fn from_compact(data: &[u8]) -> Result<Signature, Error> {
let mut ret = ffi::Signature::new();
if data.len() != 64 {
return Err(Error::InvalidSignature)
}
unsafe {
if ffi::secp256k1_ecdsa_signature_parse_compact(
ffi::secp256k1_context_no_precomp,
&mut ret,
data.as_c_ptr(),
) == 1
{
Ok(Signature(ret))
} else {
Err(Error::InvalidSignature)
}
}
}
pub fn from_der_lax(data: &[u8]) -> Result<Signature, Error> {
if data.is_empty() {return Err(Error::InvalidSignature);}
unsafe {
let mut ret = ffi::Signature::new();
if ffi::ecdsa_signature_parse_der_lax(
ffi::secp256k1_context_no_precomp,
&mut ret,
data.as_c_ptr(),
data.len() as usize,
) == 1
{
Ok(Signature(ret))
} else {
Err(Error::InvalidSignature)
}
}
}
pub fn normalize_s(&mut self) {
unsafe {
ffi::secp256k1_ecdsa_signature_normalize(
ffi::secp256k1_context_no_precomp,
self.as_mut_c_ptr(),
self.as_c_ptr(),
);
}
}
#[inline]
pub fn as_ptr(&self) -> *const ffi::Signature {
&self.0 as *const _
}
#[inline]
pub fn as_mut_ptr(&mut self) -> *mut ffi::Signature {
&mut self.0 as *mut _
}
#[inline]
pub fn serialize_der(&self) -> SerializedSignature {
let mut ret = SerializedSignature::default();
let mut len: usize = ret.capacity();
unsafe {
let err = ffi::secp256k1_ecdsa_signature_serialize_der(
ffi::secp256k1_context_no_precomp,
ret.get_data_mut_ptr(),
&mut len,
self.as_c_ptr(),
);
debug_assert!(err == 1);
ret.set_len(len);
}
ret
}
#[inline]
pub fn serialize_compact(&self) -> [u8; 64] {
let mut ret = [0; 64];
unsafe {
let err = ffi::secp256k1_ecdsa_signature_serialize_compact(
ffi::secp256k1_context_no_precomp,
ret.as_mut_c_ptr(),
self.as_c_ptr(),
);
debug_assert!(err == 1);
}
ret
}
}
impl CPtr for Signature {
type Target = ffi::Signature;
fn as_c_ptr(&self) -> *const Self::Target {
self.as_ptr()
}
fn as_mut_c_ptr(&mut self) -> *mut Self::Target {
self.as_mut_ptr()
}
}
impl From<ffi::Signature> for Signature {
#[inline]
fn from(sig: ffi::Signature) -> Signature {
Signature(sig)
}
}
#[cfg(feature = "serde")]
impl ::serde::Serialize for Signature {
fn serialize<S: ::serde::Serializer>(&self, s: S) -> Result<S::Ok, S::Error> {
if s.is_human_readable() {
s.collect_str(self)
} else {
s.serialize_bytes(&self.serialize_der())
}
}
}
#[cfg(feature = "serde")]
impl<'de> ::serde::Deserialize<'de> for Signature {
fn deserialize<D: ::serde::Deserializer<'de>>(d: D) -> Result<Signature, D::Error> {
use ::serde::de::Error;
use str::FromStr;
if d.is_human_readable() {
let sl: &str = ::serde::Deserialize::deserialize(d)?;
Signature::from_str(sl).map_err(D::Error::custom)
} else {
let sl: &[u8] = ::serde::Deserialize::deserialize(d)?;
Signature::from_der(sl).map_err(D::Error::custom)
}
}
}
pub struct Message([u8; constants::MESSAGE_SIZE]);
impl_array_newtype!(Message, u8, constants::MESSAGE_SIZE);
impl_pretty_debug!(Message);
impl Message {
#[inline]
pub fn from_slice(data: &[u8]) -> Result<Message, Error> {
match data.len() {
constants::MESSAGE_SIZE => {
let mut ret = [0; constants::MESSAGE_SIZE];
ret[..].copy_from_slice(data);
Ok(Message(ret))
}
_ => Err(Error::InvalidMessage)
}
}
#[cfg(feature = "bitcoin_hashes")]
pub fn from_hashed_data<H: ThirtyTwoByteHash + bitcoin_hashes::Hash>(data: &[u8]) -> Self {
<H as bitcoin_hashes::Hash>::hash(data).into()
}
}
impl<T: ThirtyTwoByteHash> From<T> for Message {
fn from(t: T) -> Message {
Message(t.into_32())
}
}
#[derive(Copy, PartialEq, Eq, Clone, Debug)]
pub enum Error {
IncorrectSignature,
InvalidMessage,
InvalidPublicKey,
InvalidSignature,
InvalidSecretKey,
InvalidRecoveryId,
InvalidTweak,
NotEnoughMemory,
}
impl Error {
fn as_str(&self) -> &str {
match *self {
Error::IncorrectSignature => "secp: signature failed verification",
Error::InvalidMessage => "secp: message was not 32 bytes (do you need to hash?)",
Error::InvalidPublicKey => "secp: malformed public key",
Error::InvalidSignature => "secp: malformed signature",
Error::InvalidSecretKey => "secp: malformed or out-of-range secret key",
Error::InvalidRecoveryId => "secp: bad recovery id",
Error::InvalidTweak => "secp: bad tweak",
Error::NotEnoughMemory => "secp: not enough memory allocated",
}
}
}
impl fmt::Display for Error {
fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> {
f.write_str(self.as_str())
}
}
#[cfg(feature = "std")]
impl std::error::Error for Error {
fn description(&self) -> &str { self.as_str() }
}
pub struct Secp256k1<C: Context> {
ctx: *mut ffi::Context,
phantom: PhantomData<C>,
buf: *mut [u8],
}
unsafe impl<C: Context> Send for Secp256k1<C> {}
unsafe impl<C: Context> Sync for Secp256k1<C> {}
impl<C: Context> PartialEq for Secp256k1<C> {
fn eq(&self, _other: &Secp256k1<C>) -> bool { true }
}
impl Default for SerializedSignature {
fn default() -> SerializedSignature {
SerializedSignature {
data: [0u8; 72],
len: 0,
}
}
}
impl PartialEq for SerializedSignature {
fn eq(&self, other: &SerializedSignature) -> bool {
self.data[..self.len] == other.data[..other.len]
}
}
impl AsRef<[u8]> for SerializedSignature {
fn as_ref(&self) -> &[u8] {
&self.data[..self.len]
}
}
impl Deref for SerializedSignature {
type Target = [u8];
fn deref(&self) -> &[u8] {
&self.data[..self.len]
}
}
impl Eq for SerializedSignature {}
impl<C: Context> Eq for Secp256k1<C> { }
impl<C: Context> Drop for Secp256k1<C> {
fn drop(&mut self) {
unsafe {
ffi::secp256k1_context_preallocated_destroy(self.ctx);
C::deallocate(self.buf);
}
}
}
impl<C: Context> fmt::Debug for Secp256k1<C> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "<secp256k1 context {:?}, {}>", self.ctx, C::DESCRIPTION)
}
}
impl<C: Context> Secp256k1<C> {
pub fn ctx(&self) -> &*mut ffi::Context {
&self.ctx
}
pub fn preallocate_size_gen() -> usize {
unsafe { ffi::secp256k1_context_preallocated_size(C::FLAGS) }
}
#[cfg(any(test, feature = "rand"))]
pub fn randomize<R: Rng + ?Sized>(&mut self, rng: &mut R) {
let mut seed = [0; 32];
rng.fill_bytes(&mut seed);
unsafe {
let err = ffi::secp256k1_context_randomize(self.ctx, seed.as_c_ptr());
assert!(err == 1);
}
}
}
impl<C: Signing> Secp256k1<C> {
pub fn sign(&self, msg: &Message, sk: &key::SecretKey)
-> Signature {
let mut ret = ffi::Signature::new();
unsafe {
assert_eq!(ffi::secp256k1_ecdsa_sign(self.ctx, &mut ret, msg.as_c_ptr(),
sk.as_c_ptr(), ffi::secp256k1_nonce_function_rfc6979,
ptr::null()), 1);
}
Signature::from(ret)
}
#[inline]
#[cfg(any(test, feature = "rand"))]
pub fn generate_keypair<R: Rng + ?Sized>(&self, rng: &mut R)
-> (key::SecretKey, key::PublicKey) {
let sk = key::SecretKey::new(rng);
let pk = key::PublicKey::from_secret_key(self, &sk);
(sk, pk)
}
}
impl<C: Verification> Secp256k1<C> {
#[inline]
pub fn verify(&self, msg: &Message, sig: &Signature, pk: &key::PublicKey) -> Result<(), Error> {
unsafe {
if ffi::secp256k1_ecdsa_verify(self.ctx, sig.as_c_ptr(), msg.as_c_ptr(), pk.as_c_ptr()) == 0 {
Err(Error::IncorrectSignature)
} else {
Ok(())
}
}
}
}
fn from_hex(hex: &str, target: &mut [u8]) -> Result<usize, ()> {
if hex.len() % 2 == 1 || hex.len() > target.len() * 2 {
return Err(());
}
let mut b = 0;
let mut idx = 0;
for c in hex.bytes() {
b <<= 4;
match c {
b'A'...b'F' => b |= c - b'A' + 10,
b'a'...b'f' => b |= c - b'a' + 10,
b'0'...b'9' => b |= c - b'0',
_ => return Err(()),
}
if (idx & 1) == 1 {
target[idx / 2] = b;
b = 0;
}
idx += 1;
}
Ok(idx / 2)
}
#[cfg(test)]
mod tests {
use rand::{RngCore, thread_rng};
use std::str::FromStr;
use std::marker::PhantomData;
use key::{SecretKey, PublicKey};
use super::from_hex;
use super::constants;
use super::{Secp256k1, Signature, Message};
use super::Error::{InvalidMessage, IncorrectSignature, InvalidSignature};
use ffi;
use context::*;
macro_rules! hex {
($hex:expr) => ({
let mut result = vec![0; $hex.len() / 2];
from_hex($hex, &mut result).expect("valid hex string");
result
});
}
#[test]
fn test_manual_create_destroy() {
let ctx_full = unsafe { ffi::secp256k1_context_create(AllPreallocated::FLAGS) };
let ctx_sign = unsafe { ffi::secp256k1_context_create(SignOnlyPreallocated::FLAGS) };
let ctx_vrfy = unsafe { ffi::secp256k1_context_create(VerifyOnlyPreallocated::FLAGS) };
let buf: *mut [u8] = &mut [0u8;0] as _;
let full: Secp256k1<AllPreallocated> = Secp256k1{ctx: ctx_full, phantom: PhantomData, buf};
let sign: Secp256k1<SignOnlyPreallocated> = Secp256k1{ctx: ctx_sign, phantom: PhantomData, buf};
let vrfy: Secp256k1<VerifyOnlyPreallocated> = Secp256k1{ctx: ctx_vrfy, phantom: PhantomData, buf};
let (sk, pk) = full.generate_keypair(&mut thread_rng());
let msg = Message::from_slice(&[2u8; 32]).unwrap();
assert_eq!(sign.sign(&msg, &sk), full.sign(&msg, &sk));
let sig = full.sign(&msg, &sk);
assert!(vrfy.verify(&msg, &sig, &pk).is_ok());
assert!(full.verify(&msg, &sig, &pk).is_ok());
drop(full);drop(sign);drop(vrfy);
unsafe { ffi::secp256k1_context_destroy(ctx_vrfy) };
unsafe { ffi::secp256k1_context_destroy(ctx_sign) };
unsafe { ffi::secp256k1_context_destroy(ctx_full) };
}
#[test]
fn test_raw_ctx() {
let ctx_full = Secp256k1::new();
let ctx_sign = Secp256k1::signing_only();
let ctx_vrfy = Secp256k1::verification_only();
let full = unsafe {Secp256k1::from_raw_all(ctx_full.ctx)};
let sign = unsafe {Secp256k1::from_raw_signining_only(ctx_sign.ctx)};
let vrfy = unsafe {Secp256k1::from_raw_verification_only(ctx_vrfy.ctx)};
let (sk, pk) = full.generate_keypair(&mut thread_rng());
let msg = Message::from_slice(&[2u8; 32]).unwrap();
assert_eq!(sign.sign(&msg, &sk), full.sign(&msg, &sk));
let sig = full.sign(&msg, &sk);
assert!(vrfy.verify(&msg, &sig, &pk).is_ok());
assert!(full.verify(&msg, &sig, &pk).is_ok());
drop(full);drop(sign);drop(vrfy);
drop(ctx_full);drop(ctx_sign);drop(ctx_vrfy);
}
#[test]
#[should_panic]
fn test_panic_raw_ctx() {
let ctx_vrfy = Secp256k1::verification_only();
let raw_ctx_verify_as_full = unsafe {Secp256k1::from_raw_all(ctx_vrfy.ctx)};
let (sk, _) = raw_ctx_verify_as_full.generate_keypair(&mut thread_rng());
let msg = Message::from_slice(&[2u8; 32]).unwrap();
raw_ctx_verify_as_full.sign(&msg, &sk);
}
#[test]
fn test_preallocation() {
let mut buf_ful = vec![0u8; Secp256k1::preallocate_size()];
let mut buf_sign = vec![0u8; Secp256k1::preallocate_signing_size()];
let mut buf_vfy = vec![0u8; Secp256k1::preallocate_verification_size()];
let full = Secp256k1::preallocated_new(&mut buf_ful).unwrap();
let sign = Secp256k1::preallocated_signing_only(&mut buf_sign).unwrap();
let vrfy = Secp256k1::preallocated_verification_only(&mut buf_vfy).unwrap();
let (sk, pk) = full.generate_keypair(&mut thread_rng());
let msg = Message::from_slice(&[2u8; 32]).unwrap();
assert_eq!(sign.sign(&msg, &sk), full.sign(&msg, &sk));
let sig = full.sign(&msg, &sk);
assert!(vrfy.verify(&msg, &sig, &pk).is_ok());
assert!(full.verify(&msg, &sig, &pk).is_ok());
}
#[test]
fn capabilities() {
let sign = Secp256k1::signing_only();
let vrfy = Secp256k1::verification_only();
let full = Secp256k1::new();
let mut msg = [0u8; 32];
thread_rng().fill_bytes(&mut msg);
let msg = Message::from_slice(&msg).unwrap();
let (sk, pk) = full.generate_keypair(&mut thread_rng());
assert_eq!(sign.sign(&msg, &sk), full.sign(&msg, &sk));
let sig = full.sign(&msg, &sk);
assert!(vrfy.verify(&msg, &sig, &pk).is_ok());
assert!(full.verify(&msg, &sig, &pk).is_ok());
let (pk_slice, sk_slice) = (&pk.serialize(), &sk[..]);
let new_pk = PublicKey::from_slice(pk_slice).unwrap();
let new_sk = SecretKey::from_slice(sk_slice).unwrap();
assert_eq!(sk, new_sk);
assert_eq!(pk, new_pk);
}
#[test]
fn signature_serialize_roundtrip() {
let mut s = Secp256k1::new();
s.randomize(&mut thread_rng());
let mut msg = [0; 32];
for _ in 0..100 {
thread_rng().fill_bytes(&mut msg);
let msg = Message::from_slice(&msg).unwrap();
let (sk, _) = s.generate_keypair(&mut thread_rng());
let sig1 = s.sign(&msg, &sk);
let der = sig1.serialize_der();
let sig2 = Signature::from_der(&der[..]).unwrap();
assert_eq!(sig1, sig2);
let compact = sig1.serialize_compact();
let sig2 = Signature::from_compact(&compact[..]).unwrap();
assert_eq!(sig1, sig2);
assert!(Signature::from_compact(&der[..]).is_err());
assert!(Signature::from_compact(&compact[0..4]).is_err());
assert!(Signature::from_der(&compact[..]).is_err());
assert!(Signature::from_der(&der[0..4]).is_err());
}
}
#[test]
fn signature_display() {
let hex_str = "3046022100839c1fbc5304de944f697c9f4b1d01d1faeba32d751c0f7acb21ac8a0f436a72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45";
let byte_str = hex!(hex_str);
assert_eq!(
Signature::from_der(&byte_str).expect("byte str decode"),
Signature::from_str(&hex_str).expect("byte str decode")
);
let sig = Signature::from_str(&hex_str).expect("byte str decode");
assert_eq!(&sig.to_string(), hex_str);
assert_eq!(&format!("{:?}", sig), hex_str);
assert!(Signature::from_str(
"3046022100839c1fbc5304de944f697c9f4b1d01d1faeba32d751c0f7acb21ac8a0f436a\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab4"
).is_err());
assert!(Signature::from_str(
"3046022100839c1fbc5304de944f697c9f4b1d01d1faeba32d751c0f7acb21ac8a0f436a\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab"
).is_err());
assert!(Signature::from_str(
"3046022100839c1fbc5304de944f697c9f4b1d01d1faeba32d751c0f7acb21ac8a0f436a\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eabxx"
).is_err());
assert!(Signature::from_str(
"3046022100839c1fbc5304de944f697c9f4b1d01d1faeba32d751c0f7acb21ac8a0f436a\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45\
72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45"
).is_err());
let hex_str = "30450221009d0bad576719d32ae76bedb34c774866673cbde3f4e12951555c9408e6ce774b02202876e7102f204f6bfee26c967c3926ce702cf97d4b010062e193f763190f6776";
let sig = Signature::from_str(&hex_str).expect("byte str decode");
assert_eq!(&format!("{}", sig), hex_str);
}
#[test]
fn signature_lax_der() {
macro_rules! check_lax_sig(
($hex:expr) => ({
let sig = hex!($hex);
assert!(Signature::from_der_lax(&sig[..]).is_ok());
})
);
check_lax_sig!("304402204c2dd8a9b6f8d425fcd8ee9a20ac73b619906a6367eac6cb93e70375225ec0160220356878eff111ff3663d7e6bf08947f94443845e0dcc54961664d922f7660b80c");
check_lax_sig!("304402202ea9d51c7173b1d96d331bd41b3d1b4e78e66148e64ed5992abd6ca66290321c0220628c47517e049b3e41509e9d71e480a0cdc766f8cdec265ef0017711c1b5336f");
check_lax_sig!("3045022100bf8e050c85ffa1c313108ad8c482c4849027937916374617af3f2e9a881861c9022023f65814222cab09d5ec41032ce9c72ca96a5676020736614de7b78a4e55325a");
check_lax_sig!("3046022100839c1fbc5304de944f697c9f4b1d01d1faeba32d751c0f7acb21ac8a0f436a72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45");
check_lax_sig!("3046022100eaa5f90483eb20224616775891397d47efa64c68b969db1dacb1c30acdfc50aa022100cf9903bbefb1c8000cf482b0aeeb5af19287af20bd794de11d82716f9bae3db1");
check_lax_sig!("3045022047d512bc85842ac463ca3b669b62666ab8672ee60725b6c06759e476cebdc6c102210083805e93bd941770109bcc797784a71db9e48913f702c56e60b1c3e2ff379a60");
check_lax_sig!("3044022023ee4e95151b2fbbb08a72f35babe02830d14d54bd7ed1320e4751751d1baa4802206235245254f58fd1be6ff19ca291817da76da65c2f6d81d654b5185dd86b8acf");
}
#[test]
fn sign_and_verify() {
let mut s = Secp256k1::new();
s.randomize(&mut thread_rng());
let mut msg = [0; 32];
for _ in 0..100 {
thread_rng().fill_bytes(&mut msg);
let msg = Message::from_slice(&msg).unwrap();
let (sk, pk) = s.generate_keypair(&mut thread_rng());
let sig = s.sign(&msg, &sk);
assert_eq!(s.verify(&msg, &sig, &pk), Ok(()));
}
}
#[test]
fn sign_and_verify_extreme() {
let mut s = Secp256k1::new();
s.randomize(&mut thread_rng());
let mut wild_keys = [[0; 32]; 2];
let mut wild_msgs = [[0; 32]; 2];
wild_keys[0][0] = 1;
wild_msgs[0][0] = 1;
use constants;
wild_keys[1][..].copy_from_slice(&constants::CURVE_ORDER[..]);
wild_msgs[1][..].copy_from_slice(&constants::CURVE_ORDER[..]);
wild_keys[1][0] -= 1;
wild_msgs[1][0] -= 1;
for key in wild_keys.iter().map(|k| SecretKey::from_slice(&k[..]).unwrap()) {
for msg in wild_msgs.iter().map(|m| Message::from_slice(&m[..]).unwrap()) {
let sig = s.sign(&msg, &key);
let pk = PublicKey::from_secret_key(&s, &key);
assert_eq!(s.verify(&msg, &sig, &pk), Ok(()));
}
}
}
#[test]
fn sign_and_verify_fail() {
let mut s = Secp256k1::new();
s.randomize(&mut thread_rng());
let mut msg = [0u8; 32];
thread_rng().fill_bytes(&mut msg);
let msg = Message::from_slice(&msg).unwrap();
let (sk, pk) = s.generate_keypair(&mut thread_rng());
let sig = s.sign(&msg, &sk);
let mut msg = [0u8; 32];
thread_rng().fill_bytes(&mut msg);
let msg = Message::from_slice(&msg).unwrap();
assert_eq!(s.verify(&msg, &sig, &pk), Err(IncorrectSignature));
}
#[test]
fn test_bad_slice() {
assert_eq!(Signature::from_der(&[0; constants::MAX_SIGNATURE_SIZE + 1]),
Err(InvalidSignature));
assert_eq!(Signature::from_der(&[0; constants::MAX_SIGNATURE_SIZE]),
Err(InvalidSignature));
assert_eq!(Message::from_slice(&[0; constants::MESSAGE_SIZE - 1]),
Err(InvalidMessage));
assert_eq!(Message::from_slice(&[0; constants::MESSAGE_SIZE + 1]),
Err(InvalidMessage));
assert!(Message::from_slice(&[0; constants::MESSAGE_SIZE]).is_ok());
assert!(Message::from_slice(&[1; constants::MESSAGE_SIZE]).is_ok());
}
#[test]
fn test_low_s() {
let sig = hex!("3046022100839c1fbc5304de944f697c9f4b1d01d1faeba32d751c0f7acb21ac8a0f436a72022100e89bd46bb3a5a62adc679f659b7ce876d83ee297c7a5587b2011c4fcc72eab45");
let pk = hex!("031ee99d2b786ab3b0991325f2de8489246a6a3fdb700f6d0511b1d80cf5f4cd43");
let msg = hex!("a4965ca63b7d8562736ceec36dfa5a11bf426eb65be8ea3f7a49ae363032da0d");
let secp = Secp256k1::new();
let mut sig = Signature::from_der(&sig[..]).unwrap();
let pk = PublicKey::from_slice(&pk[..]).unwrap();
let msg = Message::from_slice(&msg[..]).unwrap();
assert_eq!(secp.verify(&msg, &sig, &pk), Err(IncorrectSignature));
sig.normalize_s();
assert_eq!(secp.verify(&msg, &sig, &pk), Ok(()));
}
#[cfg(feature = "serde")]
#[test]
fn test_signature_serde() {
use serde_test::{Configure, Token, assert_tokens};
let s = Secp256k1::new();
let msg = Message::from_slice(&[1; 32]).unwrap();
let sk = SecretKey::from_slice(&[2; 32]).unwrap();
let sig = s.sign(&msg, &sk);
static SIG_BYTES: [u8; 71] = [
48, 69, 2, 33, 0, 157, 11, 173, 87, 103, 25, 211, 42, 231, 107, 237,
179, 76, 119, 72, 102, 103, 60, 189, 227, 244, 225, 41, 81, 85, 92, 148,
8, 230, 206, 119, 75, 2, 32, 40, 118, 231, 16, 47, 32, 79, 107, 254,
226, 108, 150, 124, 57, 38, 206, 112, 44, 249, 125, 75, 1, 0, 98, 225,
147, 247, 99, 25, 15, 103, 118
];
static SIG_STR: &'static str = "\
30450221009d0bad576719d32ae76bedb34c774866673cbde3f4e12951555c9408e6ce77\
4b02202876e7102f204f6bfee26c967c3926ce702cf97d4b010062e193f763190f6776\
";
assert_tokens(&sig.compact(), &[Token::BorrowedBytes(&SIG_BYTES[..])]);
assert_tokens(&sig.readable(), &[Token::BorrowedStr(SIG_STR)]);
}
#[cfg(feature = "global-context")]
#[test]
fn test_global_context() {
use super::SECP256K1;
let sk_data = hex!("e6dd32f8761625f105c39a39f19370b3521d845a12456d60ce44debd0a362641");
let sk = SecretKey::from_slice(&sk_data).unwrap();
let msg_data = hex!("a4965ca63b7d8562736ceec36dfa5a11bf426eb65be8ea3f7a49ae363032da0d");
let msg = Message::from_slice(&msg_data).unwrap();
let pk = PublicKey::from_secret_key(&SECP256K1, &sk);
let sig = SECP256K1.sign(&msg, &sk);
assert!(SECP256K1.verify(&msg, &sig, &pk).is_ok());
}
#[cfg(target_arch = "wasm32")]
extern crate wasm_bindgen_test;
#[cfg(target_arch = "wasm32")]
use self::wasm_bindgen_test::*;
#[cfg(target_arch = "wasm32")]
#[wasm_bindgen_test]
fn stuff() {
test_manual_create_destroy();
test_raw_ctx();
test_preallocation();
capabilities();
signature_serialize_roundtrip();
signature_display();
signature_lax_der();
sign_and_verify();
sign_and_verify_extreme();
sign_and_verify_fail();
test_bad_slice();
test_low_s();
}
#[cfg(feature = "bitcoin_hashes")]
#[test]
fn test_from_hash() {
use bitcoin_hashes;
use bitcoin_hashes::Hash;
let test_bytes = "Hello world!".as_bytes();
let hash = bitcoin_hashes::sha256::Hash::hash(test_bytes);
let msg = Message::from(hash);
assert_eq!(msg.0, hash.into_inner());
assert_eq!(
msg,
Message::from_hashed_data::<bitcoin_hashes::sha256::Hash>(test_bytes)
);
let hash = bitcoin_hashes::sha256d::Hash::hash(test_bytes);
let msg = Message::from(hash);
assert_eq!(msg.0, hash.into_inner());
assert_eq!(
msg,
Message::from_hashed_data::<bitcoin_hashes::sha256d::Hash>(test_bytes)
);
}
}
#[cfg(all(test, feature = "unstable"))]
mod benches {
use rand::{thread_rng, RngCore};
use test::{Bencher, black_box};
use super::{Secp256k1, Message};
#[bench]
pub fn generate(bh: &mut Bencher) {
struct CounterRng(u64);
impl RngCore for CounterRng {
fn next_u32(&mut self) -> u32 {
self.next_u64() as u32
}
fn next_u64(&mut self) -> u64 {
self.0 += 1;
self.0
}
fn fill_bytes(&mut self, dest: &mut [u8]) {
for chunk in dest.chunks_mut(64/8) {
let rand: [u8; 64/8] = unsafe {std::mem::transmute(self.next_u64())};
chunk.copy_from_slice(&rand[..chunk.len()]);
}
}
fn try_fill_bytes(&mut self, dest: &mut [u8]) -> Result<(), rand::Error> {
Ok(self.fill_bytes(dest))
}
}
let s = Secp256k1::new();
let mut r = CounterRng(0);
bh.iter( || {
let (sk, pk) = s.generate_keypair(&mut r);
black_box(sk);
black_box(pk);
});
}
#[bench]
pub fn bench_sign(bh: &mut Bencher) {
let s = Secp256k1::new();
let mut msg = [0u8; 32];
thread_rng().fill_bytes(&mut msg);
let msg = Message::from_slice(&msg).unwrap();
let (sk, _) = s.generate_keypair(&mut thread_rng());
bh.iter(|| {
let sig = s.sign(&msg, &sk);
black_box(sig);
});
}
#[bench]
pub fn bench_verify(bh: &mut Bencher) {
let s = Secp256k1::new();
let mut msg = [0u8; 32];
thread_rng().fill_bytes(&mut msg);
let msg = Message::from_slice(&msg).unwrap();
let (sk, pk) = s.generate_keypair(&mut thread_rng());
let sig = s.sign(&msg, &sk);
bh.iter(|| {
let res = s.verify(&msg, &sig, &pk).unwrap();
black_box(res);
});
}
}