// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license. use aes_kw::KekAes128; use aes_kw::KekAes192; use aes_kw::KekAes256; use deno_core::error::custom_error; use deno_core::error::not_supported; use deno_core::error::type_error; use deno_core::error::AnyError; use deno_core::include_js_files; use deno_core::op; use deno_core::Extension; use deno_core::OpState; use deno_core::ZeroCopyBuf; use serde::Deserialize; use shared::operation_error; use p256::elliptic_curve::sec1::FromEncodedPoint; use p256::pkcs8::DecodePrivateKey; use rand::rngs::OsRng; use rand::rngs::StdRng; use rand::thread_rng; use rand::Rng; use rand::SeedableRng; use ring::digest; use ring::hkdf; use ring::hmac::Algorithm as HmacAlgorithm; use ring::hmac::Key as HmacKey; use ring::pbkdf2; use ring::rand as RingRand; use ring::signature::EcdsaKeyPair; use ring::signature::EcdsaSigningAlgorithm; use ring::signature::EcdsaVerificationAlgorithm; use ring::signature::KeyPair; use rsa::padding::PaddingScheme; use rsa::pkcs1::der::Decode; use rsa::pkcs1::der::Encode; use rsa::pkcs1::DecodeRsaPrivateKey; use rsa::pkcs1::DecodeRsaPublicKey; use rsa::pkcs8::der::asn1; use rsa::PublicKey; use rsa::RsaPrivateKey; use rsa::RsaPublicKey; use sha1::Sha1; use sha2::Digest; use sha2::Sha256; use sha2::Sha384; use sha2::Sha512; use std::convert::TryFrom; use std::num::NonZeroU32; use std::path::PathBuf; pub use rand; // Re-export rand mod decrypt; mod encrypt; mod export_key; mod generate_key; mod import_key; mod key; mod shared; pub use crate::decrypt::op_crypto_decrypt; pub use crate::encrypt::op_crypto_encrypt; pub use crate::export_key::op_crypto_export_key; pub use crate::generate_key::op_crypto_generate_key; pub use crate::import_key::op_crypto_import_key; use crate::key::Algorithm; use crate::key::CryptoHash; use crate::key::CryptoNamedCurve; use crate::key::HkdfOutput; use crate::shared::RawKeyData; use crate::shared::ID_MFG1; use crate::shared::ID_P_SPECIFIED; use crate::shared::ID_SHA1_OID; use once_cell::sync::Lazy; pub fn init(maybe_seed: Option) -> Extension { Extension::builder() .js(include_js_files!( prefix "deno:ext/crypto", "00_crypto.js", "01_webidl.js", )) .ops(vec![ op_crypto_get_random_values::decl(), op_crypto_generate_key::decl(), op_crypto_sign_key::decl(), op_crypto_verify_key::decl(), op_crypto_derive_bits::decl(), op_crypto_import_key::decl(), op_crypto_export_key::decl(), op_crypto_encrypt::decl(), op_crypto_decrypt::decl(), op_crypto_subtle_digest::decl(), op_crypto_random_uuid::decl(), op_crypto_wrap_key::decl(), op_crypto_unwrap_key::decl(), ]) .state(move |state| { if let Some(seed) = maybe_seed { state.put(StdRng::seed_from_u64(seed)); } Ok(()) }) .build() } #[op] pub fn op_crypto_get_random_values( state: &mut OpState, mut zero_copy: ZeroCopyBuf, ) -> Result<(), AnyError> { if zero_copy.len() > 65536 { return Err( deno_web::DomExceptionQuotaExceededError::new(&format!("The ArrayBufferView's byte length ({}) exceeds the number of bytes of entropy available via this API (65536)", zero_copy.len())) .into(), ); } let maybe_seeded_rng = state.try_borrow_mut::(); if let Some(seeded_rng) = maybe_seeded_rng { seeded_rng.fill(&mut *zero_copy); } else { let mut rng = thread_rng(); rng.fill(&mut *zero_copy); } Ok(()) } #[derive(Deserialize)] #[serde(rename_all = "lowercase")] pub enum KeyFormat { Raw, Pkcs8, Spki, } #[derive(Deserialize)] #[serde(rename_all = "lowercase")] pub enum KeyType { Secret, Private, Public, } #[derive(Deserialize)] #[serde(rename_all = "lowercase")] pub struct KeyData { r#type: KeyType, data: ZeroCopyBuf, } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct SignArg { key: KeyData, algorithm: Algorithm, salt_length: Option, hash: Option, named_curve: Option, } #[op] pub async fn op_crypto_sign_key( args: SignArg, zero_copy: ZeroCopyBuf, ) -> Result { let data = &*zero_copy; let algorithm = args.algorithm; let signature = match algorithm { Algorithm::RsassaPkcs1v15 => { let private_key = RsaPrivateKey::from_pkcs1_der(&*args.key.data)?; let (padding, hashed) = match args .hash .ok_or_else(|| type_error("Missing argument hash".to_string()))? { CryptoHash::Sha1 => { let mut hasher = Sha1::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA1), }, hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha256 => { let mut hasher = Sha256::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA2_256), }, hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha384 => { let mut hasher = Sha384::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA2_384), }, hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha512 => { let mut hasher = Sha512::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA2_512), }, hasher.finalize()[..].to_vec(), ) } }; private_key.sign(padding, &hashed)? } Algorithm::RsaPss => { let private_key = RsaPrivateKey::from_pkcs1_der(&*args.key.data)?; let salt_len = args .salt_length .ok_or_else(|| type_error("Missing argument saltLength".to_string()))? as usize; let rng = OsRng; let (padding, digest_in) = match args .hash .ok_or_else(|| type_error("Missing argument hash".to_string()))? { CryptoHash::Sha1 => { let mut hasher = Sha1::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha256 => { let mut hasher = Sha256::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha384 => { let mut hasher = Sha384::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha512 => { let mut hasher = Sha512::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } }; // Sign data based on computed padding and return buffer private_key.sign(padding, &digest_in)? } Algorithm::Ecdsa => { let curve: &EcdsaSigningAlgorithm = args.named_curve.ok_or_else(not_supported)?.try_into()?; let key_pair = EcdsaKeyPair::from_pkcs8(curve, &*args.key.data)?; // We only support P256-SHA256 & P384-SHA384. These are recommended signature pairs. // https://briansmith.org/rustdoc/ring/signature/index.html#statics if let Some(hash) = args.hash { match hash { CryptoHash::Sha256 | CryptoHash::Sha384 => (), _ => return Err(type_error("Unsupported algorithm")), } }; let rng = RingRand::SystemRandom::new(); let signature = key_pair.sign(&rng, data)?; // Signature data as buffer. signature.as_ref().to_vec() } Algorithm::Hmac => { let hash: HmacAlgorithm = args.hash.ok_or_else(not_supported)?.into(); let key = HmacKey::new(hash, &*args.key.data); let signature = ring::hmac::sign(&key, data); signature.as_ref().to_vec() } _ => return Err(type_error("Unsupported algorithm".to_string())), }; Ok(signature.into()) } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct VerifyArg { key: KeyData, algorithm: Algorithm, salt_length: Option, hash: Option, signature: ZeroCopyBuf, named_curve: Option, } #[op] pub async fn op_crypto_verify_key( args: VerifyArg, zero_copy: ZeroCopyBuf, ) -> Result { let data = &*zero_copy; let algorithm = args.algorithm; let verification = match algorithm { Algorithm::RsassaPkcs1v15 => { let public_key = read_rsa_public_key(args.key)?; let (padding, hashed) = match args .hash .ok_or_else(|| type_error("Missing argument hash".to_string()))? { CryptoHash::Sha1 => { let mut hasher = Sha1::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA1), }, hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha256 => { let mut hasher = Sha256::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA2_256), }, hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha384 => { let mut hasher = Sha384::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA2_384), }, hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha512 => { let mut hasher = Sha512::new(); hasher.update(&data); ( PaddingScheme::PKCS1v15Sign { hash: Some(rsa::hash::Hash::SHA2_512), }, hasher.finalize()[..].to_vec(), ) } }; public_key .verify(padding, &hashed, &*args.signature) .is_ok() } Algorithm::RsaPss => { let salt_len = args .salt_length .ok_or_else(|| type_error("Missing argument saltLength".to_string()))? as usize; let public_key = read_rsa_public_key(args.key)?; let rng = OsRng; let (padding, hashed) = match args .hash .ok_or_else(|| type_error("Missing argument hash".to_string()))? { CryptoHash::Sha1 => { let mut hasher = Sha1::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha256 => { let mut hasher = Sha256::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha384 => { let mut hasher = Sha384::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } CryptoHash::Sha512 => { let mut hasher = Sha512::new(); hasher.update(&data); ( PaddingScheme::new_pss_with_salt::(rng, salt_len), hasher.finalize()[..].to_vec(), ) } }; public_key .verify(padding, &hashed, &*args.signature) .is_ok() } Algorithm::Hmac => { let hash: HmacAlgorithm = args.hash.ok_or_else(not_supported)?.into(); let key = HmacKey::new(hash, &*args.key.data); ring::hmac::verify(&key, data, &*args.signature).is_ok() } Algorithm::Ecdsa => { let signing_alg: &EcdsaSigningAlgorithm = args.named_curve.ok_or_else(not_supported)?.try_into()?; let verify_alg: &EcdsaVerificationAlgorithm = args.named_curve.ok_or_else(not_supported)?.try_into()?; let private_key; let public_key_bytes = match args.key.r#type { KeyType::Private => { private_key = EcdsaKeyPair::from_pkcs8(signing_alg, &*args.key.data)?; private_key.public_key().as_ref() } KeyType::Public => &*args.key.data, _ => return Err(type_error("Invalid Key format".to_string())), }; let public_key = ring::signature::UnparsedPublicKey::new(verify_alg, public_key_bytes); public_key.verify(data, &*args.signature).is_ok() } _ => return Err(type_error("Unsupported algorithm".to_string())), }; Ok(verification) } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct DeriveKeyArg { key: KeyData, algorithm: Algorithm, hash: Option, length: usize, iterations: Option, // ECDH public_key: Option, named_curve: Option, // HKDF info: Option, } #[op] pub async fn op_crypto_derive_bits( args: DeriveKeyArg, zero_copy: Option, ) -> Result { let algorithm = args.algorithm; match algorithm { Algorithm::Pbkdf2 => { let zero_copy = zero_copy.ok_or_else(not_supported)?; let salt = &*zero_copy; // The caller must validate these cases. assert!(args.length > 0); assert!(args.length % 8 == 0); let algorithm = match args.hash.ok_or_else(not_supported)? { CryptoHash::Sha1 => pbkdf2::PBKDF2_HMAC_SHA1, CryptoHash::Sha256 => pbkdf2::PBKDF2_HMAC_SHA256, CryptoHash::Sha384 => pbkdf2::PBKDF2_HMAC_SHA384, CryptoHash::Sha512 => pbkdf2::PBKDF2_HMAC_SHA512, }; // This will never panic. We have already checked length earlier. let iterations = NonZeroU32::new(args.iterations.ok_or_else(not_supported)?).unwrap(); let secret = args.key.data; let mut out = vec![0; args.length / 8]; pbkdf2::derive(algorithm, iterations, salt, &secret, &mut out); Ok(out.into()) } Algorithm::Ecdh => { let named_curve = args .named_curve .ok_or_else(|| type_error("Missing argument namedCurve".to_string()))?; let public_key = args .public_key .ok_or_else(|| type_error("Missing argument publicKey"))?; match named_curve { CryptoNamedCurve::P256 => { let secret_key = p256::SecretKey::from_pkcs8_der(&args.key.data) .map_err(|_| type_error("Unexpected error decoding private key"))?; let public_key = match public_key.r#type { KeyType::Private => { p256::SecretKey::from_pkcs8_der(&public_key.data) .map_err(|_| { type_error("Unexpected error decoding private key") })? .public_key() } KeyType::Public => { let point = p256::EncodedPoint::from_bytes(public_key.data) .map_err(|_| { type_error("Unexpected error decoding private key") })?; let pk = p256::PublicKey::from_encoded_point(&point); // pk is a constant time Option. if pk.is_some().into() { pk.unwrap() } else { return Err(type_error( "Unexpected error decoding private key", )); } } _ => unreachable!(), }; let shared_secret = p256::elliptic_curve::ecdh::diffie_hellman( secret_key.to_nonzero_scalar(), public_key.as_affine(), ); // raw serialized x-coordinate of the computed point Ok(shared_secret.raw_secret_bytes().to_vec().into()) } CryptoNamedCurve::P384 => { let secret_key = p384::SecretKey::from_pkcs8_der(&args.key.data) .map_err(|_| type_error("Unexpected error decoding private key"))?; let public_key = match public_key.r#type { KeyType::Private => { p384::SecretKey::from_pkcs8_der(&public_key.data) .map_err(|_| { type_error("Unexpected error decoding private key") })? .public_key() } KeyType::Public => { let point = p384::EncodedPoint::from_bytes(public_key.data) .map_err(|_| { type_error("Unexpected error decoding private key") })?; let pk = p384::PublicKey::from_encoded_point(&point); // pk is a constant time Option. if pk.is_some().into() { pk.unwrap() } else { return Err(type_error( "Unexpected error decoding private key", )); } } _ => unreachable!(), }; let shared_secret = p384::elliptic_curve::ecdh::diffie_hellman( secret_key.to_nonzero_scalar(), public_key.as_affine(), ); // raw serialized x-coordinate of the computed point Ok(shared_secret.raw_secret_bytes().to_vec().into()) } } } Algorithm::Hkdf => { let zero_copy = zero_copy.ok_or_else(not_supported)?; let salt = &*zero_copy; let algorithm = match args.hash.ok_or_else(not_supported)? { CryptoHash::Sha1 => hkdf::HKDF_SHA1_FOR_LEGACY_USE_ONLY, CryptoHash::Sha256 => hkdf::HKDF_SHA256, CryptoHash::Sha384 => hkdf::HKDF_SHA384, CryptoHash::Sha512 => hkdf::HKDF_SHA512, }; let info = args .info .ok_or_else(|| type_error("Missing argument info".to_string()))?; // IKM let secret = args.key.data; // L let length = args.length / 8; let salt = hkdf::Salt::new(algorithm, salt); let prk = salt.extract(&secret); let info = &[&*info]; let okm = prk.expand(info, HkdfOutput(length)).map_err(|_e| { custom_error( "DOMExceptionOperationError", "The length provided for HKDF is too large", ) })?; let mut r = vec![0u8; length]; okm.fill(&mut r)?; Ok(r.into()) } _ => Err(type_error("Unsupported algorithm".to_string())), } } fn read_rsa_public_key(key_data: KeyData) -> Result { let public_key = match key_data.r#type { KeyType::Private => { RsaPrivateKey::from_pkcs1_der(&*key_data.data)?.to_public_key() } KeyType::Public => RsaPublicKey::from_pkcs1_der(&*key_data.data)?, KeyType::Secret => unreachable!("unexpected KeyType::Secret"), }; Ok(public_key) } // The parameters field associated with OID id-RSASSA-PSS // Defined in RFC 3447, section A.2.3 // // RSASSA-PSS-params ::= SEQUENCE { // hashAlgorithm [0] HashAlgorithm DEFAULT sha1, // maskGenAlgorithm [1] MaskGenAlgorithm DEFAULT mgf1SHA1, // saltLength [2] INTEGER DEFAULT 20, // trailerField [3] TrailerField DEFAULT trailerFieldBC // } pub struct PssPrivateKeyParameters<'a> { pub hash_algorithm: rsa::pkcs8::AlgorithmIdentifier<'a>, pub mask_gen_algorithm: rsa::pkcs8::AlgorithmIdentifier<'a>, pub salt_length: u32, } // Context-specific tag number for hashAlgorithm. const HASH_ALGORITHM_TAG: rsa::pkcs8::der::TagNumber = rsa::pkcs8::der::TagNumber::new(0); // Context-specific tag number for maskGenAlgorithm. const MASK_GEN_ALGORITHM_TAG: rsa::pkcs8::der::TagNumber = rsa::pkcs8::der::TagNumber::new(1); // Context-specific tag number for saltLength. const SALT_LENGTH_TAG: rsa::pkcs8::der::TagNumber = rsa::pkcs8::der::TagNumber::new(2); // Context-specific tag number for pSourceAlgorithm const P_SOURCE_ALGORITHM_TAG: rsa::pkcs8::der::TagNumber = rsa::pkcs8::der::TagNumber::new(2); // Default HashAlgorithm for RSASSA-PSS-params (sha1) // // sha1 HashAlgorithm ::= { // algorithm id-sha1, // parameters SHA1Parameters : NULL // } // // SHA1Parameters ::= NULL static SHA1_HASH_ALGORITHM: Lazy> = Lazy::new(|| { rsa::pkcs8::AlgorithmIdentifier { // id-sha1 oid: ID_SHA1_OID, // NULL parameters: Some(asn1::AnyRef::from(asn1::Null)), } }); // TODO(@littledivy): `pkcs8` should provide AlgorithmIdentifier to Any conversion. static ENCODED_SHA1_HASH_ALGORITHM: Lazy> = Lazy::new(|| SHA1_HASH_ALGORITHM.to_vec().unwrap()); // Default MaskGenAlgrithm for RSASSA-PSS-params (mgf1SHA1) // // mgf1SHA1 MaskGenAlgorithm ::= { // algorithm id-mgf1, // parameters HashAlgorithm : sha1 // } static MGF1_SHA1_MASK_ALGORITHM: Lazy< rsa::pkcs8::AlgorithmIdentifier<'static>, > = Lazy::new(|| { rsa::pkcs8::AlgorithmIdentifier { // id-mgf1 oid: ID_MFG1, // sha1 parameters: Some( asn1::AnyRef::from_der(&ENCODED_SHA1_HASH_ALGORITHM).unwrap(), ), } }); // Default PSourceAlgorithm for RSAES-OAEP-params // The default label is an empty string. // // pSpecifiedEmpty PSourceAlgorithm ::= { // algorithm id-pSpecified, // parameters EncodingParameters : emptyString // } // // emptyString EncodingParameters ::= ''H static P_SPECIFIED_EMPTY: Lazy> = Lazy::new(|| { rsa::pkcs8::AlgorithmIdentifier { // id-pSpecified oid: ID_P_SPECIFIED, // EncodingParameters parameters: Some(asn1::AnyRef::from( asn1::OctetStringRef::new(b"").unwrap(), )), } }); fn decode_content_tag<'a, T>( decoder: &mut rsa::pkcs8::der::SliceReader<'a>, tag: rsa::pkcs8::der::TagNumber, ) -> rsa::pkcs8::der::Result> where T: rsa::pkcs8::der::Decode<'a>, { Ok( rsa::pkcs8::der::asn1::ContextSpecific::::decode_explicit(decoder, tag)? .map(|field| field.value), ) } impl<'a> TryFrom> for PssPrivateKeyParameters<'a> { type Error = rsa::pkcs8::der::Error; fn try_from( any: rsa::pkcs8::der::asn1::AnyRef<'a>, ) -> rsa::pkcs8::der::Result> { any.sequence(|decoder| { let hash_algorithm = decode_content_tag::( decoder, HASH_ALGORITHM_TAG, )? .map(TryInto::try_into) .transpose()? .unwrap_or(*SHA1_HASH_ALGORITHM); let mask_gen_algorithm = decode_content_tag::< rsa::pkcs8::AlgorithmIdentifier, >(decoder, MASK_GEN_ALGORITHM_TAG)? .map(TryInto::try_into) .transpose()? .unwrap_or(*MGF1_SHA1_MASK_ALGORITHM); let salt_length = decode_content_tag::(decoder, SALT_LENGTH_TAG)? .map(TryInto::try_into) .transpose()? .unwrap_or(20); Ok(Self { hash_algorithm, mask_gen_algorithm, salt_length, }) }) } } // The parameters field associated with OID id-RSAES-OAEP // Defined in RFC 3447, section A.2.1 // // RSAES-OAEP-params ::= SEQUENCE { // hashAlgorithm [0] HashAlgorithm DEFAULT sha1, // maskGenAlgorithm [1] MaskGenAlgorithm DEFAULT mgf1SHA1, // pSourceAlgorithm [2] PSourceAlgorithm DEFAULT pSpecifiedEmpty // } pub struct OaepPrivateKeyParameters<'a> { pub hash_algorithm: rsa::pkcs8::AlgorithmIdentifier<'a>, pub mask_gen_algorithm: rsa::pkcs8::AlgorithmIdentifier<'a>, pub p_source_algorithm: rsa::pkcs8::AlgorithmIdentifier<'a>, } impl<'a> TryFrom> for OaepPrivateKeyParameters<'a> { type Error = rsa::pkcs8::der::Error; fn try_from( any: rsa::pkcs8::der::asn1::AnyRef<'a>, ) -> rsa::pkcs8::der::Result> { any.sequence(|decoder| { let hash_algorithm = decode_content_tag::( decoder, HASH_ALGORITHM_TAG, )? .map(TryInto::try_into) .transpose()? .unwrap_or(*SHA1_HASH_ALGORITHM); let mask_gen_algorithm = decode_content_tag::< rsa::pkcs8::AlgorithmIdentifier, >(decoder, MASK_GEN_ALGORITHM_TAG)? .map(TryInto::try_into) .transpose()? .unwrap_or(*MGF1_SHA1_MASK_ALGORITHM); let p_source_algorithm = decode_content_tag::< rsa::pkcs8::AlgorithmIdentifier, >(decoder, P_SOURCE_ALGORITHM_TAG)? .map(TryInto::try_into) .transpose()? .unwrap_or(*P_SPECIFIED_EMPTY); Ok(Self { hash_algorithm, mask_gen_algorithm, p_source_algorithm, }) }) } } #[op] pub fn op_crypto_random_uuid(state: &mut OpState) -> Result { let maybe_seeded_rng = state.try_borrow_mut::(); let uuid = if let Some(seeded_rng) = maybe_seeded_rng { let mut bytes = [0u8; 16]; seeded_rng.fill(&mut bytes); uuid::Builder::from_bytes(bytes) .with_version(uuid::Version::Random) .into_uuid() } else { uuid::Uuid::new_v4() }; Ok(uuid.to_string()) } #[op] pub async fn op_crypto_subtle_digest( algorithm: CryptoHash, data: ZeroCopyBuf, ) -> Result { let output = tokio::task::spawn_blocking(move || { digest::digest(algorithm.into(), &data) .as_ref() .to_vec() .into() }) .await?; Ok(output) } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct WrapUnwrapKeyArg { key: RawKeyData, algorithm: Algorithm, } #[op] pub fn op_crypto_wrap_key( args: WrapUnwrapKeyArg, data: ZeroCopyBuf, ) -> Result { let algorithm = args.algorithm; match algorithm { Algorithm::AesKw => { let key = args.key.as_secret_key()?; if data.len() % 8 != 0 { return Err(type_error("Data must be multiple of 8 bytes")); } let wrapped_key = match key.len() { 16 => KekAes128::new(key.into()).wrap_vec(&data), 24 => KekAes192::new(key.into()).wrap_vec(&data), 32 => KekAes256::new(key.into()).wrap_vec(&data), _ => return Err(type_error("Invalid key length")), } .map_err(|_| operation_error("encryption error"))?; Ok(wrapped_key.into()) } _ => Err(type_error("Unsupported algorithm")), } } #[op] pub fn op_crypto_unwrap_key( args: WrapUnwrapKeyArg, data: ZeroCopyBuf, ) -> Result { let algorithm = args.algorithm; match algorithm { Algorithm::AesKw => { let key = args.key.as_secret_key()?; if data.len() % 8 != 0 { return Err(type_error("Data must be multiple of 8 bytes")); } let unwrapped_key = match key.len() { 16 => KekAes128::new(key.into()).unwrap_vec(&data), 24 => KekAes192::new(key.into()).unwrap_vec(&data), 32 => KekAes256::new(key.into()).unwrap_vec(&data), _ => return Err(type_error("Invalid key length")), } .map_err(|_| { operation_error("decryption error - integrity check failed") })?; Ok(unwrapped_key.into()) } _ => Err(type_error("Unsupported algorithm")), } } pub fn get_declaration() -> PathBuf { PathBuf::from(env!("CARGO_MANIFEST_DIR")).join("lib.deno_crypto.d.ts") }