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denoland-deno/ext/node/ops/crypto/mod.rs
Luca Casonato 4fa8869f24
feat(ext/node): rewrite crypto keys (#24463) 
This completely rewrites how we handle key material in ext/node. Changes
in this
PR:

- **Signing**
  - RSA
  - RSA-PSS 🆕
  - DSA 🆕
  - EC
  - ED25519 🆕
- **Verifying**
  - RSA
  - RSA-PSS 🆕
  - DSA 🆕
  - EC 🆕
  - ED25519 🆕
- **Private key import**
  - Passphrase encrypted private keys 🆕
  - RSA
    - PEM
    - DER (PKCS#1) 🆕
    - DER (PKCS#8) 🆕
  - RSA-PSS
    - PEM
    - DER (PKCS#1) 🆕
    - DER (PKCS#8) 🆕
  - DSA 🆕
  - EC
    - PEM
    - DER (SEC1) 🆕
    - DER (PKCS#8) 🆕
  - X25519 🆕
  - ED25519 🆕
  - DH
- **Public key import**
  - RSA
    - PEM
    - DER (PKCS#1) 🆕
    - DER (PKCS#8) 🆕
  - RSA-PSS 🆕
  - DSA 🆕
  - EC 🆕
  - X25519 🆕
  - ED25519 🆕
  - DH 🆕
- **Private key export**
  - RSA 🆕
  - DSA 🆕
  - EC 🆕
  - X25519 🆕
  - ED25519 🆕
  - DH 🆕
- **Public key export**
  - RSA
  - DSA 🆕
  - EC 🆕
  - X25519 🆕
  - ED25519 🆕
  - DH 🆕
- **Key pair generation**
  - Overhauled, but supported APIs unchanged

This PR adds a lot of new individual functionality. But most importantly
because
of the new key material representation, it is now trivial to add new
algorithms
(as shown by this PR).

Now, when adding a new algorithm, it is also widely supported - for
example
previously we supported ED25519 key pair generation, but we could not
import,
export, sign or verify with ED25519. We can now do all of those things.
2024-08-07 08:43:58 +02:00

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use deno_core::error::generic_error;
use deno_core::error::type_error;
use deno_core::error::AnyError;
use deno_core::op2;
use deno_core::unsync::spawn_blocking;
use deno_core::JsBuffer;
use deno_core::OpState;
use deno_core::StringOrBuffer;
use deno_core::ToJsBuffer;
use elliptic_curve::sec1::ToEncodedPoint;
use hkdf::Hkdf;
use keys::KeyObjectHandle;
use num_bigint::BigInt;
use num_bigint_dig::BigUint;
use rand::distributions::Distribution;
use rand::distributions::Uniform;
use rand::Rng;
use std::future::Future;
use std::rc::Rc;
use p224::NistP224;
use p256::NistP256;
use p384::NistP384;
use rsa::pkcs8::DecodePrivateKey;
use rsa::pkcs8::DecodePublicKey;
use rsa::Oaep;
use rsa::Pkcs1v15Encrypt;
use rsa::RsaPrivateKey;
use rsa::RsaPublicKey;
mod cipher;
mod dh;
mod digest;
pub mod keys;
mod md5_sha1;
mod primes;
mod sign;
pub mod x509;
use self::digest::match_fixed_digest_with_eager_block_buffer;
#[op2(fast)]
pub fn op_node_check_prime(
#[bigint] num: i64,
#[number] checks: usize,
) -> bool {
primes::is_probably_prime(&BigInt::from(num), checks)
}
#[op2]
pub fn op_node_check_prime_bytes(
#[anybuffer] bytes: &[u8],
#[number] checks: usize,
) -> Result<bool, AnyError> {
let candidate = BigInt::from_bytes_be(num_bigint::Sign::Plus, bytes);
Ok(primes::is_probably_prime(&candidate, checks))
}
#[op2(async)]
pub async fn op_node_check_prime_async(
#[bigint] num: i64,
#[number] checks: usize,
) -> Result<bool, AnyError> {
// TODO(@littledivy): use rayon for CPU-bound tasks
Ok(
spawn_blocking(move || {
primes::is_probably_prime(&BigInt::from(num), checks)
})
.await?,
)
}
#[op2(async)]
pub fn op_node_check_prime_bytes_async(
#[anybuffer] bytes: &[u8],
#[number] checks: usize,
) -> Result<impl Future<Output = Result<bool, AnyError>>, AnyError> {
let candidate = BigInt::from_bytes_be(num_bigint::Sign::Plus, bytes);
// TODO(@littledivy): use rayon for CPU-bound tasks
Ok(async move {
Ok(
spawn_blocking(move || primes::is_probably_prime(&candidate, checks))
.await?,
)
})
}
#[op2]
#[cppgc]
pub fn op_node_create_hash(
#[string] algorithm: &str,
output_length: Option<u32>,
) -> Result<digest::Hasher, AnyError> {
digest::Hasher::new(algorithm, output_length.map(|l| l as usize))
}
#[op2]
#[serde]
pub fn op_node_get_hashes() -> Vec<&'static str> {
digest::Hash::get_hashes()
}
#[op2(fast)]
pub fn op_node_hash_update(
#[cppgc] hasher: &digest::Hasher,
#[buffer] data: &[u8],
) -> bool {
hasher.update(data)
}
#[op2(fast)]
pub fn op_node_hash_update_str(
#[cppgc] hasher: &digest::Hasher,
#[string] data: &str,
) -> bool {
hasher.update(data.as_bytes())
}
#[op2]
#[buffer]
pub fn op_node_hash_digest(
#[cppgc] hasher: &digest::Hasher,
) -> Option<Box<[u8]>> {
hasher.digest()
}
#[op2]
#[string]
pub fn op_node_hash_digest_hex(
#[cppgc] hasher: &digest::Hasher,
) -> Option<String> {
let digest = hasher.digest()?;
Some(faster_hex::hex_string(&digest))
}
#[op2]
#[cppgc]
pub fn op_node_hash_clone(
#[cppgc] hasher: &digest::Hasher,
output_length: Option<u32>,
) -> Result<Option<digest::Hasher>, AnyError> {
hasher.clone_inner(output_length.map(|l| l as usize))
}
#[op2]
#[serde]
pub fn op_node_private_encrypt(
#[serde] key: StringOrBuffer,
#[serde] msg: StringOrBuffer,
#[smi] padding: u32,
) -> Result<ToJsBuffer, AnyError> {
let key = RsaPrivateKey::from_pkcs8_pem((&key).try_into()?)?;
let mut rng = rand::thread_rng();
match padding {
1 => Ok(
key
.as_ref()
.encrypt(&mut rng, Pkcs1v15Encrypt, &msg)?
.into(),
),
4 => Ok(
key
.as_ref()
.encrypt(&mut rng, Oaep::new::<sha1::Sha1>(), &msg)?
.into(),
),
_ => Err(type_error("Unknown padding")),
}
}
#[op2]
#[serde]
pub fn op_node_private_decrypt(
#[serde] key: StringOrBuffer,
#[serde] msg: StringOrBuffer,
#[smi] padding: u32,
) -> Result<ToJsBuffer, AnyError> {
let key = RsaPrivateKey::from_pkcs8_pem((&key).try_into()?)?;
match padding {
1 => Ok(key.decrypt(Pkcs1v15Encrypt, &msg)?.into()),
4 => Ok(key.decrypt(Oaep::new::<sha1::Sha1>(), &msg)?.into()),
_ => Err(type_error("Unknown padding")),
}
}
#[op2]
#[serde]
pub fn op_node_public_encrypt(
#[serde] key: StringOrBuffer,
#[serde] msg: StringOrBuffer,
#[smi] padding: u32,
) -> Result<ToJsBuffer, AnyError> {
let key = RsaPublicKey::from_public_key_pem((&key).try_into()?)?;
let mut rng = rand::thread_rng();
match padding {
1 => Ok(key.encrypt(&mut rng, Pkcs1v15Encrypt, &msg)?.into()),
4 => Ok(
key
.encrypt(&mut rng, Oaep::new::<sha1::Sha1>(), &msg)?
.into(),
),
_ => Err(type_error("Unknown padding")),
}
}
#[op2(fast)]
#[smi]
pub fn op_node_create_cipheriv(
state: &mut OpState,
#[string] algorithm: &str,
#[buffer] key: &[u8],
#[buffer] iv: &[u8],
) -> u32 {
state.resource_table.add(
match cipher::CipherContext::new(algorithm, key, iv) {
Ok(context) => context,
Err(_) => return 0,
},
)
}
#[op2(fast)]
pub fn op_node_cipheriv_set_aad(
state: &mut OpState,
#[smi] rid: u32,
#[buffer] aad: &[u8],
) -> bool {
let context = match state.resource_table.get::<cipher::CipherContext>(rid) {
Ok(context) => context,
Err(_) => return false,
};
context.set_aad(aad);
true
}
#[op2(fast)]
pub fn op_node_cipheriv_encrypt(
state: &mut OpState,
#[smi] rid: u32,
#[buffer] input: &[u8],
#[buffer] output: &mut [u8],
) -> bool {
let context = match state.resource_table.get::<cipher::CipherContext>(rid) {
Ok(context) => context,
Err(_) => return false,
};
context.encrypt(input, output);
true
}
#[op2]
#[serde]
pub fn op_node_cipheriv_final(
state: &mut OpState,
#[smi] rid: u32,
#[buffer] input: &[u8],
#[buffer] output: &mut [u8],
) -> Result<Option<Vec<u8>>, AnyError> {
let context = state.resource_table.take::<cipher::CipherContext>(rid)?;
let context = Rc::try_unwrap(context)
.map_err(|_| type_error("Cipher context is already in use"))?;
context.r#final(input, output)
}
#[op2(fast)]
#[smi]
pub fn op_node_create_decipheriv(
state: &mut OpState,
#[string] algorithm: &str,
#[buffer] key: &[u8],
#[buffer] iv: &[u8],
) -> u32 {
state.resource_table.add(
match cipher::DecipherContext::new(algorithm, key, iv) {
Ok(context) => context,
Err(_) => return 0,
},
)
}
#[op2(fast)]
pub fn op_node_decipheriv_set_aad(
state: &mut OpState,
#[smi] rid: u32,
#[buffer] aad: &[u8],
) -> bool {
let context = match state.resource_table.get::<cipher::DecipherContext>(rid) {
Ok(context) => context,
Err(_) => return false,
};
context.set_aad(aad);
true
}
#[op2(fast)]
pub fn op_node_decipheriv_decrypt(
state: &mut OpState,
#[smi] rid: u32,
#[buffer] input: &[u8],
#[buffer] output: &mut [u8],
) -> bool {
let context = match state.resource_table.get::<cipher::DecipherContext>(rid) {
Ok(context) => context,
Err(_) => return false,
};
context.decrypt(input, output);
true
}
#[op2(fast)]
pub fn op_node_decipheriv_final(
state: &mut OpState,
#[smi] rid: u32,
#[buffer] input: &[u8],
#[buffer] output: &mut [u8],
#[buffer] auth_tag: &[u8],
) -> Result<(), AnyError> {
let context = state.resource_table.take::<cipher::DecipherContext>(rid)?;
let context = Rc::try_unwrap(context)
.map_err(|_| type_error("Cipher context is already in use"))?;
context.r#final(input, output, auth_tag)
}
#[op2]
#[buffer]
pub fn op_node_sign(
#[cppgc] handle: &KeyObjectHandle,
#[buffer] digest: &[u8],
#[string] digest_type: &str,
) -> Result<Box<[u8]>, AnyError> {
handle.sign_prehashed(digest_type, digest)
}
#[op2(fast)]
pub fn op_node_verify(
#[cppgc] handle: &KeyObjectHandle,
#[buffer] digest: &[u8],
#[string] digest_type: &str,
#[buffer] signature: &[u8],
) -> Result<bool, AnyError> {
handle.verify_prehashed(digest_type, digest, signature)
}
fn pbkdf2_sync(
password: &[u8],
salt: &[u8],
iterations: u32,
algorithm_name: &str,
derived_key: &mut [u8],
) -> Result<(), AnyError> {
match_fixed_digest_with_eager_block_buffer!(
algorithm_name,
fn <D>() {
pbkdf2::pbkdf2_hmac::<D>(password, salt, iterations, derived_key);
Ok(())
},
_ => {
Err(type_error(format!(
"unsupported digest: {}",
algorithm_name
)))
}
)
}
#[op2]
pub fn op_node_pbkdf2(
#[serde] password: StringOrBuffer,
#[serde] salt: StringOrBuffer,
#[smi] iterations: u32,
#[string] digest: &str,
#[buffer] derived_key: &mut [u8],
) -> bool {
pbkdf2_sync(&password, &salt, iterations, digest, derived_key).is_ok()
}
#[op2(async)]
#[serde]
pub async fn op_node_pbkdf2_async(
#[serde] password: StringOrBuffer,
#[serde] salt: StringOrBuffer,
#[smi] iterations: u32,
#[string] digest: String,
#[number] keylen: usize,
) -> Result<ToJsBuffer, AnyError> {
spawn_blocking(move || {
let mut derived_key = vec![0; keylen];
pbkdf2_sync(&password, &salt, iterations, &digest, &mut derived_key)
.map(|_| derived_key.into())
})
.await?
}
#[op2(fast)]
pub fn op_node_fill_random(#[buffer] buf: &mut [u8]) {
rand::thread_rng().fill(buf);
}
#[op2(async)]
#[serde]
pub async fn op_node_fill_random_async(#[smi] len: i32) -> ToJsBuffer {
spawn_blocking(move || {
let mut buf = vec![0u8; len as usize];
rand::thread_rng().fill(&mut buf[..]);
buf.into()
})
.await
.unwrap()
}
fn hkdf_sync(
digest_algorithm: &str,
handle: &KeyObjectHandle,
salt: &[u8],
info: &[u8],
okm: &mut [u8],
) -> Result<(), AnyError> {
let Some(ikm) = handle.as_secret_key() else {
return Err(type_error("expected secret key"));
};
match_fixed_digest_with_eager_block_buffer!(
digest_algorithm,
fn <D>() {
let hk = Hkdf::<D>::new(Some(salt), ikm);
hk.expand(info, okm)
.map_err(|_| type_error("HKDF-Expand failed"))
},
_ => {
Err(type_error(format!("Unsupported digest: {}", digest_algorithm)))
}
)
}
#[op2(fast)]
pub fn op_node_hkdf(
#[string] digest_algorithm: &str,
#[cppgc] handle: &KeyObjectHandle,
#[buffer] salt: &[u8],
#[buffer] info: &[u8],
#[buffer] okm: &mut [u8],
) -> Result<(), AnyError> {
hkdf_sync(digest_algorithm, handle, salt, info, okm)
}
#[op2(async)]
#[serde]
pub async fn op_node_hkdf_async(
#[string] digest_algorithm: String,
#[cppgc] handle: &KeyObjectHandle,
#[buffer] salt: JsBuffer,
#[buffer] info: JsBuffer,
#[number] okm_len: usize,
) -> Result<ToJsBuffer, AnyError> {
let handle = handle.clone();
spawn_blocking(move || {
let mut okm = vec![0u8; okm_len];
hkdf_sync(&digest_algorithm, &handle, &salt, &info, &mut okm)?;
Ok(okm.into())
})
.await?
}
#[op2]
#[serde]
pub fn op_node_dh_compute_secret(
#[buffer] prime: JsBuffer,
#[buffer] private_key: JsBuffer,
#[buffer] their_public_key: JsBuffer,
) -> Result<ToJsBuffer, AnyError> {
let pubkey: BigUint = BigUint::from_bytes_be(their_public_key.as_ref());
let privkey: BigUint = BigUint::from_bytes_be(private_key.as_ref());
let primei: BigUint = BigUint::from_bytes_be(prime.as_ref());
let shared_secret: BigUint = pubkey.modpow(&privkey, &primei);
Ok(shared_secret.to_bytes_be().into())
}
#[op2(fast)]
#[smi]
pub fn op_node_random_int(
#[smi] min: i32,
#[smi] max: i32,
) -> Result<i32, AnyError> {
let mut rng = rand::thread_rng();
// Uniform distribution is required to avoid Modulo Bias
// https://en.wikipedia.org/wiki/FisherYates_shuffle#Modulo_bias
let dist = Uniform::from(min..max);
Ok(dist.sample(&mut rng))
}
#[allow(clippy::too_many_arguments)]
fn scrypt(
password: StringOrBuffer,
salt: StringOrBuffer,
keylen: u32,
cost: u32,
block_size: u32,
parallelization: u32,
_maxmem: u32,
output_buffer: &mut [u8],
) -> Result<(), AnyError> {
// Construct Params
let params = scrypt::Params::new(
cost as u8,
block_size,
parallelization,
keylen as usize,
)
.unwrap();
// Call into scrypt
let res = scrypt::scrypt(&password, &salt, &params, output_buffer);
if res.is_ok() {
Ok(())
} else {
// TODO(lev): key derivation failed, so what?
Err(generic_error("scrypt key derivation failed"))
}
}
#[allow(clippy::too_many_arguments)]
#[op2]
pub fn op_node_scrypt_sync(
#[serde] password: StringOrBuffer,
#[serde] salt: StringOrBuffer,
#[smi] keylen: u32,
#[smi] cost: u32,
#[smi] block_size: u32,
#[smi] parallelization: u32,
#[smi] maxmem: u32,
#[anybuffer] output_buffer: &mut [u8],
) -> Result<(), AnyError> {
scrypt(
password,
salt,
keylen,
cost,
block_size,
parallelization,
maxmem,
output_buffer,
)
}
#[op2(async)]
#[serde]
pub async fn op_node_scrypt_async(
#[serde] password: StringOrBuffer,
#[serde] salt: StringOrBuffer,
#[smi] keylen: u32,
#[smi] cost: u32,
#[smi] block_size: u32,
#[smi] parallelization: u32,
#[smi] maxmem: u32,
) -> Result<ToJsBuffer, AnyError> {
spawn_blocking(move || {
let mut output_buffer = vec![0u8; keylen as usize];
let res = scrypt(
password,
salt,
keylen,
cost,
block_size,
parallelization,
maxmem,
&mut output_buffer,
);
if res.is_ok() {
Ok(output_buffer.into())
} else {
// TODO(lev): rethrow the error?
Err(generic_error("scrypt failure"))
}
})
.await?
}
#[op2]
#[buffer]
pub fn op_node_ecdh_encode_pubkey(
#[string] curve: &str,
#[buffer] pubkey: &[u8],
compress: bool,
) -> Result<Vec<u8>, AnyError> {
use elliptic_curve::sec1::FromEncodedPoint;
match curve {
"secp256k1" => {
let pubkey =
elliptic_curve::PublicKey::<k256::Secp256k1>::from_encoded_point(
&elliptic_curve::sec1::EncodedPoint::<k256::Secp256k1>::from_bytes(
pubkey,
)?,
);
// CtOption does not expose its variants.
if pubkey.is_none().into() {
return Err(type_error("Invalid public key"));
}
let pubkey = pubkey.unwrap();
Ok(pubkey.to_encoded_point(compress).as_ref().to_vec())
}
"prime256v1" | "secp256r1" => {
let pubkey = elliptic_curve::PublicKey::<NistP256>::from_encoded_point(
&elliptic_curve::sec1::EncodedPoint::<NistP256>::from_bytes(pubkey)?,
);
// CtOption does not expose its variants.
if pubkey.is_none().into() {
return Err(type_error("Invalid public key"));
}
let pubkey = pubkey.unwrap();
Ok(pubkey.to_encoded_point(compress).as_ref().to_vec())
}
"secp384r1" => {
let pubkey = elliptic_curve::PublicKey::<NistP384>::from_encoded_point(
&elliptic_curve::sec1::EncodedPoint::<NistP384>::from_bytes(pubkey)?,
);
// CtOption does not expose its variants.
if pubkey.is_none().into() {
return Err(type_error("Invalid public key"));
}
let pubkey = pubkey.unwrap();
Ok(pubkey.to_encoded_point(compress).as_ref().to_vec())
}
"secp224r1" => {
let pubkey = elliptic_curve::PublicKey::<NistP224>::from_encoded_point(
&elliptic_curve::sec1::EncodedPoint::<NistP224>::from_bytes(pubkey)?,
);
// CtOption does not expose its variants.
if pubkey.is_none().into() {
return Err(type_error("Invalid public key"));
}
let pubkey = pubkey.unwrap();
Ok(pubkey.to_encoded_point(compress).as_ref().to_vec())
}
&_ => Err(type_error("Unsupported curve")),
}
}
#[op2(fast)]
pub fn op_node_ecdh_generate_keys(
#[string] curve: &str,
#[buffer] pubbuf: &mut [u8],
#[buffer] privbuf: &mut [u8],
#[string] format: &str,
) -> Result<(), AnyError> {
let mut rng = rand::thread_rng();
let compress = format == "compressed";
match curve {
"secp256k1" => {
let privkey =
elliptic_curve::SecretKey::<k256::Secp256k1>::random(&mut rng);
let pubkey = privkey.public_key();
pubbuf.copy_from_slice(pubkey.to_encoded_point(compress).as_ref());
privbuf.copy_from_slice(privkey.to_nonzero_scalar().to_bytes().as_ref());
Ok(())
}
"prime256v1" | "secp256r1" => {
let privkey = elliptic_curve::SecretKey::<NistP256>::random(&mut rng);
let pubkey = privkey.public_key();
pubbuf.copy_from_slice(pubkey.to_encoded_point(compress).as_ref());
privbuf.copy_from_slice(privkey.to_nonzero_scalar().to_bytes().as_ref());
Ok(())
}
"secp384r1" => {
let privkey = elliptic_curve::SecretKey::<NistP384>::random(&mut rng);
let pubkey = privkey.public_key();
pubbuf.copy_from_slice(pubkey.to_encoded_point(compress).as_ref());
privbuf.copy_from_slice(privkey.to_nonzero_scalar().to_bytes().as_ref());
Ok(())
}
"secp224r1" => {
let privkey = elliptic_curve::SecretKey::<NistP224>::random(&mut rng);
let pubkey = privkey.public_key();
pubbuf.copy_from_slice(pubkey.to_encoded_point(compress).as_ref());
privbuf.copy_from_slice(privkey.to_nonzero_scalar().to_bytes().as_ref());
Ok(())
}
&_ => Err(type_error(format!("Unsupported curve: {}", curve))),
}
}
#[op2]
pub fn op_node_ecdh_compute_secret(
#[string] curve: &str,
#[buffer] this_priv: Option<JsBuffer>,
#[buffer] their_pub: &mut [u8],
#[buffer] secret: &mut [u8],
) -> Result<(), AnyError> {
match curve {
"secp256k1" => {
let their_public_key =
elliptic_curve::PublicKey::<k256::Secp256k1>::from_sec1_bytes(
their_pub,
)
.expect("bad public key");
let this_private_key =
elliptic_curve::SecretKey::<k256::Secp256k1>::from_slice(
&this_priv.expect("must supply private key"),
)
.expect("bad private key");
let shared_secret = elliptic_curve::ecdh::diffie_hellman(
this_private_key.to_nonzero_scalar(),
their_public_key.as_affine(),
);
secret.copy_from_slice(shared_secret.raw_secret_bytes());
Ok(())
}
"prime256v1" | "secp256r1" => {
let their_public_key =
elliptic_curve::PublicKey::<NistP256>::from_sec1_bytes(their_pub)
.expect("bad public key");
let this_private_key = elliptic_curve::SecretKey::<NistP256>::from_slice(
&this_priv.expect("must supply private key"),
)
.expect("bad private key");
let shared_secret = elliptic_curve::ecdh::diffie_hellman(
this_private_key.to_nonzero_scalar(),
their_public_key.as_affine(),
);
secret.copy_from_slice(shared_secret.raw_secret_bytes());
Ok(())
}
"secp384r1" => {
let their_public_key =
elliptic_curve::PublicKey::<NistP384>::from_sec1_bytes(their_pub)
.expect("bad public key");
let this_private_key = elliptic_curve::SecretKey::<NistP384>::from_slice(
&this_priv.expect("must supply private key"),
)
.expect("bad private key");
let shared_secret = elliptic_curve::ecdh::diffie_hellman(
this_private_key.to_nonzero_scalar(),
their_public_key.as_affine(),
);
secret.copy_from_slice(shared_secret.raw_secret_bytes());
Ok(())
}
"secp224r1" => {
let their_public_key =
elliptic_curve::PublicKey::<NistP224>::from_sec1_bytes(their_pub)
.expect("bad public key");
let this_private_key = elliptic_curve::SecretKey::<NistP224>::from_slice(
&this_priv.expect("must supply private key"),
)
.expect("bad private key");
let shared_secret = elliptic_curve::ecdh::diffie_hellman(
this_private_key.to_nonzero_scalar(),
their_public_key.as_affine(),
);
secret.copy_from_slice(shared_secret.raw_secret_bytes());
Ok(())
}
&_ => todo!(),
}
}
#[op2(fast)]
pub fn op_node_ecdh_compute_public_key(
#[string] curve: &str,
#[buffer] privkey: &[u8],
#[buffer] pubkey: &mut [u8],
) -> Result<(), AnyError> {
match curve {
"secp256k1" => {
let this_private_key =
elliptic_curve::SecretKey::<k256::Secp256k1>::from_slice(privkey)
.expect("bad private key");
let public_key = this_private_key.public_key();
pubkey.copy_from_slice(public_key.to_sec1_bytes().as_ref());
Ok(())
}
"prime256v1" | "secp256r1" => {
let this_private_key =
elliptic_curve::SecretKey::<NistP256>::from_slice(privkey)
.expect("bad private key");
let public_key = this_private_key.public_key();
pubkey.copy_from_slice(public_key.to_sec1_bytes().as_ref());
Ok(())
}
"secp384r1" => {
let this_private_key =
elliptic_curve::SecretKey::<NistP384>::from_slice(privkey)
.expect("bad private key");
let public_key = this_private_key.public_key();
pubkey.copy_from_slice(public_key.to_sec1_bytes().as_ref());
Ok(())
}
"secp224r1" => {
let this_private_key =
elliptic_curve::SecretKey::<NistP224>::from_slice(privkey)
.expect("bad private key");
let public_key = this_private_key.public_key();
pubkey.copy_from_slice(public_key.to_sec1_bytes().as_ref());
Ok(())
}
&_ => todo!(),
}
}
#[inline]
fn gen_prime(size: usize) -> ToJsBuffer {
primes::Prime::generate(size).0.to_bytes_be().into()
}
#[op2]
#[serde]
pub fn op_node_gen_prime(#[number] size: usize) -> ToJsBuffer {
gen_prime(size)
}
#[op2(async)]
#[serde]
pub async fn op_node_gen_prime_async(
#[number] size: usize,
) -> Result<ToJsBuffer, AnyError> {
Ok(spawn_blocking(move || gen_prime(size)).await?)
}
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