2022-09-05 23:57:11 +03:00
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"use strict";
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2023-02-13 06:14:26 +03:00
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/**
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* Add details about signing here.
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*
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* @_subsection: api/crypto:Signing [about-signing]
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*/
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2022-09-05 23:57:11 +03:00
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Object.defineProperty(exports, "__esModule", { value: true });
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exports.SigningKey = void 0;
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2023-04-25 14:04:48 +03:00
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const tslib_1 = require("tslib");
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const secp256k1 = tslib_1.__importStar(require("@noble/secp256k1"));
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2022-09-05 23:57:11 +03:00
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const index_js_1 = require("../utils/index.js");
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const hmac_js_1 = require("./hmac.js");
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const signature_js_1 = require("./signature.js");
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//const N = BigInt("0xfffffffffffffffffffffffffffffffebaaedce6af48a03bbfd25e8cd0364141");
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// Make noble-secp256k1 sync
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secp256k1.utils.hmacSha256Sync = function (key, ...messages) {
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2022-09-16 05:58:45 +03:00
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return (0, index_js_1.getBytes)((0, hmac_js_1.computeHmac)("sha256", key, (0, index_js_1.concat)(messages)));
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2022-09-05 23:57:11 +03:00
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};
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2022-12-03 05:27:06 +03:00
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/**
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* A **SigningKey** provides high-level access to the elliptic curve
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* cryptography (ECC) operations and key management.
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*/
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2022-09-05 23:57:11 +03:00
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class SigningKey {
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#privateKey;
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2022-12-03 05:27:06 +03:00
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/**
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* Creates a new **SigningKey** for %%privateKey%%.
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*/
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2022-09-05 23:57:11 +03:00
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constructor(privateKey) {
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2022-11-30 23:44:23 +03:00
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(0, index_js_1.assertArgument)((0, index_js_1.dataLength)(privateKey) === 32, "invalid private key", "privateKey", "[REDACTED]");
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2022-09-05 23:57:11 +03:00
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this.#privateKey = (0, index_js_1.hexlify)(privateKey);
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}
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2022-12-03 05:27:06 +03:00
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/**
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* The private key.
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*/
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2022-09-05 23:57:11 +03:00
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get privateKey() { return this.#privateKey; }
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2022-12-03 05:27:06 +03:00
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/**
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* The uncompressed public key.
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*
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* This will always begin with the prefix ``0x04`` and be 132
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* characters long (the ``0x`` prefix and 130 hexadecimal nibbles).
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*/
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2022-09-05 23:57:11 +03:00
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get publicKey() { return SigningKey.computePublicKey(this.#privateKey); }
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2022-12-03 05:27:06 +03:00
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/**
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* The compressed public key.
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*
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* This will always begin with either the prefix ``0x02`` or ``0x03``
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* and be 68 characters long (the ``0x`` prefix and 33 hexadecimal
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* nibbles)
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*/
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2022-09-05 23:57:11 +03:00
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get compressedPublicKey() { return SigningKey.computePublicKey(this.#privateKey, true); }
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2022-12-03 05:27:06 +03:00
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/**
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* Return the signature of the signed %%digest%%.
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*/
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sign(digest) {
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2022-10-20 12:03:32 +03:00
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(0, index_js_1.assertArgument)((0, index_js_1.dataLength)(digest) === 32, "invalid digest length", "digest", digest);
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2022-09-16 05:58:45 +03:00
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const [sigDer, recid] = secp256k1.signSync((0, index_js_1.getBytesCopy)(digest), (0, index_js_1.getBytesCopy)(this.#privateKey), {
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2022-09-05 23:57:11 +03:00
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recovered: true,
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canonical: true
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});
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const sig = secp256k1.Signature.fromHex(sigDer);
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return signature_js_1.Signature.from({
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2022-12-10 02:24:58 +03:00
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r: (0, index_js_1.toBeHex)("0x" + sig.r.toString(16), 32),
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s: (0, index_js_1.toBeHex)("0x" + sig.s.toString(16), 32),
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v: (recid ? 0x1c : 0x1b)
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2022-11-30 23:44:23 +03:00
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});
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}
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2022-12-03 05:27:06 +03:00
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/**
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* Returns the [[link-wiki-ecdh]] shared secret between this
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* private key and the %%other%% key.
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*
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* The %%other%% key may be any type of key, a raw public key,
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* a compressed/uncompressed pubic key or aprivate key.
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*
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* Best practice is usually to use a cryptographic hash on the
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* returned value before using it as a symetric secret.
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2022-12-10 02:24:58 +03:00
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*
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* @example:
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* sign1 = new SigningKey(id("some-secret-1"))
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* sign2 = new SigningKey(id("some-secret-2"))
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*
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* // Notice that privA.computeSharedSecret(pubB)...
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* sign1.computeSharedSecret(sign2.publicKey)
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* //_result:
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*
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* // ...is equal to privB.computeSharedSecret(pubA).
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* sign2.computeSharedSecret(sign1.publicKey)
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* //_result:
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*/
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computeSharedSecret(other) {
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const pubKey = SigningKey.computePublicKey(other);
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2022-12-10 02:24:58 +03:00
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console.log(pubKey);
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return (0, index_js_1.hexlify)(secp256k1.getSharedSecret((0, index_js_1.getBytesCopy)(this.#privateKey), (0, index_js_1.getBytes)(pubKey)));
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}
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2022-12-03 05:27:06 +03:00
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/**
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* Compute the public key for %%key%%, optionally %%compressed%%.
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*
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* The %%key%% may be any type of key, a raw public key, a
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* compressed/uncompressed public key or private key.
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2022-12-10 02:24:58 +03:00
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*
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* @example:
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* sign = new SigningKey(id("some-secret"));
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*
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* // Compute the uncompressed public key for a private key
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* SigningKey.computePublicKey(sign.privateKey)
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* //_result:
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*
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* // Compute the compressed public key for a private key
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* SigningKey.computePublicKey(sign.privateKey, true)
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* //_result:
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*
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* // Compute the uncompressed public key
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* SigningKey.computePublicKey(sign.publicKey, false);
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* //_result:
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*
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* // Compute the Compressed a public key
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* SigningKey.computePublicKey(sign.publicKey, true);
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* //_result:
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2022-12-03 05:27:06 +03:00
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*/
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static computePublicKey(key, compressed) {
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2022-09-16 05:58:45 +03:00
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let bytes = (0, index_js_1.getBytes)(key, "key");
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2023-01-23 00:47:02 +03:00
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// private key
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2022-09-05 23:57:11 +03:00
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if (bytes.length === 32) {
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const pubKey = secp256k1.getPublicKey(bytes, !!compressed);
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return (0, index_js_1.hexlify)(pubKey);
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}
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2023-01-23 00:47:02 +03:00
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// raw public key; use uncompressed key with 0x04 prefix
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2022-09-05 23:57:11 +03:00
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if (bytes.length === 64) {
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const pub = new Uint8Array(65);
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pub[0] = 0x04;
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pub.set(bytes, 1);
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bytes = pub;
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}
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const point = secp256k1.Point.fromHex(bytes);
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return (0, index_js_1.hexlify)(point.toRawBytes(compressed));
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}
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2022-12-03 05:27:06 +03:00
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/**
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* Returns the public key for the private key which produced the
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* %%signature%% for the given %%digest%%.
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2022-12-10 02:24:58 +03:00
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*
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* @example:
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* key = new SigningKey(id("some-secret"))
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* digest = id("hello world")
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* sig = key.sign(digest)
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*
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* // Notice the signer public key...
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* key.publicKey
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* //_result:
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*
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* // ...is equal to the recovered public key
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* SigningKey.recoverPublicKey(digest, sig)
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* //_result:
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*
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*/
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static recoverPublicKey(digest, signature) {
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(0, index_js_1.assertArgument)((0, index_js_1.dataLength)(digest) === 32, "invalid digest length", "digest", digest);
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2022-09-05 23:57:11 +03:00
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const sig = signature_js_1.Signature.from(signature);
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2022-09-16 05:58:45 +03:00
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const der = secp256k1.Signature.fromCompact((0, index_js_1.getBytesCopy)((0, index_js_1.concat)([sig.r, sig.s]))).toDERRawBytes();
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const pubKey = secp256k1.recoverPublicKey((0, index_js_1.getBytesCopy)(digest), der, sig.yParity);
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2023-03-20 19:53:37 +03:00
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(0, index_js_1.assertArgument)(pubKey != null, "invalid signautre for digest", "signature", signature);
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return (0, index_js_1.hexlify)(pubKey);
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2022-09-05 23:57:11 +03:00
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}
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2022-12-03 05:27:06 +03:00
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/**
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* Returns the point resulting from adding the ellipic curve points
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* %%p0%% and %%p1%%.
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*
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* This is not a common function most developers should require, but
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* can be useful for certain privacy-specific techniques.
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*
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* For example, it is used by [[HDNodeWallet]] to compute child
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* addresses from parent public keys and chain codes.
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*/
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static addPoints(p0, p1, compressed) {
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const pub0 = secp256k1.Point.fromHex(SigningKey.computePublicKey(p0).substring(2));
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const pub1 = secp256k1.Point.fromHex(SigningKey.computePublicKey(p1).substring(2));
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return "0x" + pub0.add(pub1).toHex(!!compressed);
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}
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}
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exports.SigningKey = SigningKey;
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//# sourceMappingURL=signing-key.js.map
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