import type { Jwk, Hasher, Signer, SignParams, DigestParams, VerifyParams, GenerateKeyParams, GetPublicKeyParams, KmsGetKeyUriParams, AsymmetricKeyGenerator, } from '@web5/crypto'; import { CryptoAlgorithm, Sha2Algorithm, computeJwkThumbprint } from '@web5/crypto'; import type { DsaApi } from './types/crypto-api.js'; import type { AsymmetricKeyConverter, KeyConverter } from './types/key-converter.js'; import type { BytesToPrivateKeyParams, BytesToPublicKeyParams, PrivateKeyToBytesParams, PublicKeyToBytesParams } from './types/params-direct.js'; import { EcdsaAlgorithm } from './algorithms/ecdsa.js'; import { EdDsaAlgorithm } from './algorithms/eddsa.js'; import { CryptoError, CryptoErrorCode } from './crypto-error.js'; export interface DsaBytesToPrivateKeyParams extends BytesToPrivateKeyParams { algorithm: KeyConversionAlgorithm; } export interface DsaBytesToPublicKeyParams extends BytesToPublicKeyParams { algorithm: AsymmetricKeyConversionAlgorithm; } /** * The `DsaDigestParams` interface defines the algorithm-specific parameters that should * be passed into the {@link AgentDsa.digest | `AgentDsa.digest()`} method. */ export interface DsaDigestParams extends DigestParams { /** * A string defining the name of hash function to use. The value must be one of the following: * - `"SHA-256"`: Generates a 256-bit digest. */ algorithm: DigestAlgorithm; } export interface DsaGenerateKeyParams extends GenerateKeyParams { algorithm: KeyGenerationAlgorithm; } /** * `supportedAlgorithms` is an object mapping algorithm names to their respective implementations * Each entry in this map specifies the algorithm name and its associated properties, including the * implementation class and any relevant names or identifiers for the algorithm. This structure * allows for easy retrieval and instantiation of algorithm implementations based on the algorithm * name or key specification. It facilitates the support of multiple algorithms within the * `LocalKeyManager` class. */ const supportedAlgorithms = { 'Ed25519': { implementation : EdDsaAlgorithm, names : ['Ed25519'], operations : ['bytesToPrivateKey', 'bytesToPublicKey', 'generateKey', 'sign', 'verify'], }, 'secp256k1': { implementation : EcdsaAlgorithm, names : ['ES256K', 'secp256k1'], operations : ['bytesToPrivateKey', 'bytesToPublicKey', 'generateKey', 'sign', 'verify'], }, 'secp256r1': { implementation : EcdsaAlgorithm, names : ['ES256', 'secp256r1'], operations : ['bytesToPrivateKey', 'bytesToPublicKey', 'generateKey', 'sign', 'verify'], }, 'SHA-256': { implementation : Sha2Algorithm, names : ['SHA-256'], operations : ['digest'], } } as const; /* Helper types for `supportedAlgorithms`. */ type SupportedAlgorithm = keyof typeof supportedAlgorithms; type SupportedAlgorithms = typeof supportedAlgorithms; /* Helper type for `supportedAlgorithms` implementations. */ type AlgorithmConstructor = typeof supportedAlgorithms[SupportedAlgorithm]['implementation']; type DigestAlgorithms = { [K in keyof SupportedAlgorithms]: 'digest' extends SupportedAlgorithms[K]['operations'][number] ? K : never }[keyof SupportedAlgorithms]; type DigestAlgorithm = typeof supportedAlgorithms[DigestAlgorithms]['names'][number]; type KeyConversionAlgorithms = { [K in keyof SupportedAlgorithms]: 'bytesToPrivateKey' extends SupportedAlgorithms[K]['operations'][number] ? K : never }[keyof SupportedAlgorithms]; type KeyConversionAlgorithm = typeof supportedAlgorithms[KeyConversionAlgorithms]['names'][number]; type AsymmetricKeyConversionAlgorithms = { [K in keyof SupportedAlgorithms]: 'bytesToPublicKey' extends SupportedAlgorithms[K]['operations'][number] ? K : never }[keyof SupportedAlgorithms]; type AsymmetricKeyConversionAlgorithm = typeof supportedAlgorithms[AsymmetricKeyConversionAlgorithms]['names'][number]; type KeyGenerationAlgorithms = { [K in keyof SupportedAlgorithms]: 'generateKey' extends SupportedAlgorithms[K]['operations'][number] ? K : never }[keyof SupportedAlgorithms]; type KeyGenerationAlgorithm = typeof supportedAlgorithms[KeyGenerationAlgorithms]['names'][number]; export class Dsa implements DsaApi< DsaGenerateKeyParams, Jwk, GetPublicKeyParams, DsaDigestParams, SignParams, VerifyParams > { /** * A private map that stores instances of cryptographic algorithm implementations. Each key in * this map is an `AlgorithmConstructor`, and its corresponding value is an instance of a class * that implements a specific cryptographic algorithm. This map is used to cache and reuse * instances for performance optimization, ensuring that each algorithm is instantiated only once. */ private _algorithmInstances: Map> = new Map(); public async bytesToPrivateKey({ algorithm: algorithmIdentifier, privateKeyBytes }: DsaBytesToPrivateKeyParams ): Promise { // Determine the algorithm name based on the given algorithm identifier. const algorithm = this.getAlgorithmName({ algorithm: algorithmIdentifier }); // Get the key converter based on the algorithm name. const keyConverter = this.getAlgorithm({ algorithm }) as KeyConverter; // Convert the byte array to a JWK. const privateKey = await keyConverter.bytesToPrivateKey({ algorithm: algorithmIdentifier, privateKeyBytes }); return privateKey; } public async bytesToPublicKey({ algorithm: algorithmIdentifier, publicKeyBytes }: DsaBytesToPublicKeyParams ): Promise { // Determine the algorithm name based on the given algorithm identifier. const algorithm = this.getAlgorithmName({ algorithm: algorithmIdentifier }); // Get the key converter based on the algorithm name. const keyConverter = this.getAlgorithm({ algorithm }) as AsymmetricKeyConverter; // Convert the byte array to a JWK. const publicKey = await keyConverter.bytesToPublicKey({ algorithm: algorithmIdentifier, publicKeyBytes }); return publicKey; } /** * Generates a hash digest of the provided data. * * @remarks * A digest is the output of the hash function. It's a fixed-size string of bytes that uniquely * represents the data input into the hash function. The digest is often used for data integrity * checks, as any alteration in the input data results in a significantly different digest. * * It takes the algorithm identifier of the hash function and data to digest as input and returns * the digest of the data. * * @example * ```ts * const Dsa = new AgentDsa(); * const data = new Uint8Array([...]); * const digest = await Dsa.digest({ algorithm: 'SHA-256', data }); * ``` * * @param params - The parameters for the digest operation. * @param params.algorithm - The name of hash function to use. * @param params.data - The data to digest. * * @returns A Promise which will be fulfilled with the hash digest. */ public async digest({ algorithm, data }: DsaDigestParams ): Promise { // Get the hash function implementation based on the specified `algorithm` parameter. const hasher = this.getAlgorithm({ algorithm }) as Hasher; // Compute the hash. const hash = await hasher.digest({ algorithm, data }); return hash; } public async generateKey(params: DsaGenerateKeyParams): Promise { // Determine the algorithm name based on the given algorithm identifier. const algorithm = this.getAlgorithmName({ algorithm: params.algorithm }); // Get the key generator implementation based on the algorithm. const keyGenerator = this.getAlgorithm({ algorithm }) as AsymmetricKeyGenerator; // Generate the key. const privateKey = await keyGenerator.generateKey({ algorithm: params.algorithm }); // If the key ID is undefined, set it to the JWK thumbprint. privateKey.kid ??= await computeJwkThumbprint({ jwk: privateKey }); return privateKey; } // ! TODO: Remove this once the `Dsa` interface is updated in @web5/crypto to remove KMS-specific methods. public async getKeyUri(_params: KmsGetKeyUriParams): Promise { throw new Error('Method not implemented.'); } public async getPublicKey({ key }: GetPublicKeyParams ): Promise { // Determine the algorithm name based on the JWK's `alg` and `crv` properties. const algorithm = this.getAlgorithmName({ key }); // Get the key generator based on the algorithm name. const keyGenerator = this.getAlgorithm({ algorithm }) as AsymmetricKeyGenerator; // Get the public key properties from the private JWK. const publicKey = await keyGenerator.getPublicKey({ key }); return publicKey; } public async privateKeyToBytes({ privateKey }: { privateKey: Jwk; }): Promise { // Determine the algorithm name based on the JWK's `alg` property. const algorithm = this.getAlgorithmName({ key: privateKey }); // Get the key converter based on the algorithm name. const keyConverter = this.getAlgorithm({ algorithm }) as KeyConverter; // Convert the JWK to a byte array. const privateKeyBytes = await keyConverter.privateKeyToBytes({ privateKey }); return privateKeyBytes; } public async publicKeyToBytes({ publicKey }: { publicKey: Jwk; }): Promise { // Determine the algorithm name based on the JWK's `alg` property. const algorithm = this.getAlgorithmName({ key: publicKey }); // Get the key converter based on the algorithm name. const keyConverter = this.getAlgorithm({ algorithm }) as AsymmetricKeyConverter; // Convert the JWK to a byte array. const publicKeyBytes = await keyConverter.publicKeyToBytes({ publicKey }); return publicKeyBytes; } public async sign({ key, data }: SignParams ): Promise { // Determine the algorithm name based on the JWK's `alg` and `crv` properties. const algorithm = this.getAlgorithmName({ key }); // Get the signature algorithm based on the algorithm name. const signer = this.getAlgorithm({ algorithm }) as Signer; // Sign the data. const signature = signer.sign({ data, key }); return signature; } public async verify({ key, signature, data }: VerifyParams ): Promise { // Determine the algorithm name based on the JWK's `alg` and `crv` properties. const algorithm = this.getAlgorithmName({ key }); // Get the signature algorithm based on the algorithm name. const signer = this.getAlgorithm({ algorithm }) as Signer; // Verify the signature. const isSignatureValid = signer.verify({ key, signature, data }); return isSignatureValid; } /** * Retrieves an algorithm implementation instance based on the provided algorithm name. * * @remarks * This method checks if the requested algorithm is supported and returns a cached instance * if available. If an instance does not exist, it creates and caches a new one. This approach * optimizes performance by reusing algorithm instances across cryptographic operations. * * @example * ```ts * const signer = this.getAlgorithm({ algorithm: 'Ed25519' }); * ``` * * @param params - The parameters for retrieving the algorithm implementation. * @param params.algorithm - The name of the algorithm to retrieve. * * @returns An instance of the requested algorithm implementation. * * @throws Error if the requested algorithm is not supported. */ private getAlgorithm({ algorithm }: { algorithm: SupportedAlgorithm; }): InstanceType { // Check if algorithm is supported. const AlgorithmImplementation = supportedAlgorithms[algorithm]?.['implementation']; if (!AlgorithmImplementation) { throw new CryptoError(CryptoErrorCode.AlgorithmNotSupported, `Algorithm not supported: ${algorithm}`); } // Check if instance already exists for the `AlgorithmImplementation`. if (!this._algorithmInstances.has(AlgorithmImplementation)) { // If not, create a new instance and store it in the cache this._algorithmInstances.set(AlgorithmImplementation, new AlgorithmImplementation()); } // Return the cached instance return this._algorithmInstances.get(AlgorithmImplementation)!; } /** * Determines the algorithm name based on the key's properties. * * @remarks * This method facilitates the identification of the correct algorithm for cryptographic * operations based on the `alg` or `crv` properties of a {@link Jwk | JWK}. * * @example * ```ts * const key = { ... }; // Public key in JWK format * const algorithm = this.getAlgorithmName({ key }); * ``` * * @example * ```ts * const algorithm = this.getAlgorithmName({ algorithm: 'ES256' }); * ``` * * @param params - The parameters for determining the algorithm name. * @param params.key - A JWK containing the `alg` or `crv` properties. * * @returns The algorithm name associated with the key. * * @throws Error if the algorithm name cannot be determined from the provided input. */ private getAlgorithmName({ key }: { key: Jwk }): SupportedAlgorithm; private getAlgorithmName({ algorithm }: { algorithm: string }): SupportedAlgorithm; private getAlgorithmName({ algorithm, key }: { algorithm?: string; key?: { alg?: string, crv?: string }; }): SupportedAlgorithm { const algProperty = key?.alg ?? algorithm; const crvProperty = key?.crv; for (const algorithmIdentifier of Object.keys(supportedAlgorithms) as SupportedAlgorithm[]) { const algorithmNames = supportedAlgorithms[algorithmIdentifier].names as readonly string[]; if (algProperty && algorithmNames.includes(algProperty)) { return algorithmIdentifier; } else if (crvProperty && algorithmNames.includes(crvProperty)) { return algorithmIdentifier; } } throw new CryptoError(CryptoErrorCode.AlgorithmNotSupported, `Algorithm not supported based on provided input: alg=${algProperty}, crv=${crvProperty}. ` + 'Please check the documentation for the list of supported algorithms.' ); } }