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solana-multi-wallet-kit

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Universal Solana Wallet Kit for React Native, Web, and Node.js

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'use strict'; var web3_js = require('@solana/web3.js'); var bs58 = require('bs58'); var require$$0$1 = require('crypto'); const createWallet = () => { const keypair = web3_js.Keypair.generate(); return { publicKey: keypair.publicKey.toBase58(), secretKey: bs58.encode(keypair.secretKey), }; }; const sendSol = async ({ fromSecretKey, toPublicKey, amount, rpcUrl = 'https://api.mainnet-beta.solana.com', }) => { const connection = new web3_js.Connection(rpcUrl); const from = web3_js.Keypair.fromSecretKey(bs58.decode(fromSecretKey)); const to = new web3_js.PublicKey(toPublicKey); const transaction = new web3_js.Transaction().add(web3_js.SystemProgram.transfer({ fromPubkey: from.publicKey, toPubkey: to, lamports: amount * web3_js.LAMPORTS_PER_SOL, })); const signature = await web3_js.sendAndConfirmTransaction(connection, transaction, [from]); return signature; }; const getBalance = async (publicKey, rpcUrl = 'https://api.mainnet-beta.solana.com') => { const connection = new web3_js.Connection(rpcUrl); const balance = await connection.getBalance(new web3_js.PublicKey(publicKey)); return balance / 1e9; // lamports → SOL }; function getDefaultExportFromCjs (x) { return x && x.__esModule && Object.prototype.hasOwnProperty.call(x, 'default') ? x['default'] : x; } var src = {}; var sha256 = {}; var sha2 = {}; var _md = {}; var utils$1 = {}; var crypto = {}; var hasRequiredCrypto; function requireCrypto () { if (hasRequiredCrypto) return crypto; hasRequiredCrypto = 1; Object.defineProperty(crypto, "__esModule", { value: true }); crypto.crypto = void 0; crypto.crypto = typeof globalThis === 'object' && 'crypto' in globalThis ? globalThis.crypto : undefined; return crypto; } var hasRequiredUtils$1; function requireUtils$1 () { if (hasRequiredUtils$1) return utils$1; hasRequiredUtils$1 = 1; (function (exports) { /** * Utilities for hex, bytes, CSPRNG. * @module */ /*! noble-hashes - MIT License (c) 2022 Paul Miller (paulmillr.com) */ Object.defineProperty(exports, "__esModule", { value: true }); exports.wrapXOFConstructorWithOpts = exports.wrapConstructorWithOpts = exports.wrapConstructor = exports.Hash = exports.nextTick = exports.swap32IfBE = exports.byteSwapIfBE = exports.swap8IfBE = exports.isLE = void 0; exports.isBytes = isBytes; exports.anumber = anumber; exports.abytes = abytes; exports.ahash = ahash; exports.aexists = aexists; exports.aoutput = aoutput; exports.u8 = u8; exports.u32 = u32; exports.clean = clean; exports.createView = createView; exports.rotr = rotr; exports.rotl = rotl; exports.byteSwap = byteSwap; exports.byteSwap32 = byteSwap32; exports.bytesToHex = bytesToHex; exports.hexToBytes = hexToBytes; exports.asyncLoop = asyncLoop; exports.utf8ToBytes = utf8ToBytes; exports.bytesToUtf8 = bytesToUtf8; exports.toBytes = toBytes; exports.kdfInputToBytes = kdfInputToBytes; exports.concatBytes = concatBytes; exports.checkOpts = checkOpts; exports.createHasher = createHasher; exports.createOptHasher = createOptHasher; exports.createXOFer = createXOFer; exports.randomBytes = randomBytes; // We use WebCrypto aka globalThis.crypto, which exists in browsers and node.js 16+. // node.js versions earlier than v19 don't declare it in global scope. // For node.js, package.json#exports field mapping rewrites import // from `crypto` to `cryptoNode`, which imports native module. // Makes the utils un-importable in browsers without a bundler. // Once node.js 18 is deprecated (2025-04-30), we can just drop the import. const crypto_1 = requireCrypto(); /** Checks if something is Uint8Array. Be careful: nodejs Buffer will return true. */ function isBytes(a) { return a instanceof Uint8Array || (ArrayBuffer.isView(a) && a.constructor.name === 'Uint8Array'); } /** Asserts something is positive integer. */ function anumber(n) { if (!Number.isSafeInteger(n) || n < 0) throw new Error('positive integer expected, got ' + n); } /** Asserts something is Uint8Array. */ function abytes(b, ...lengths) { if (!isBytes(b)) throw new Error('Uint8Array expected'); if (lengths.length > 0 && !lengths.includes(b.length)) throw new Error('Uint8Array expected of length ' + lengths + ', got length=' + b.length); } /** Asserts something is hash */ function ahash(h) { if (typeof h !== 'function' || typeof h.create !== 'function') throw new Error('Hash should be wrapped by utils.createHasher'); anumber(h.outputLen); anumber(h.blockLen); } /** Asserts a hash instance has not been destroyed / finished */ function aexists(instance, checkFinished = true) { if (instance.destroyed) throw new Error('Hash instance has been destroyed'); if (checkFinished && instance.finished) throw new Error('Hash#digest() has already been called'); } /** Asserts output is properly-sized byte array */ function aoutput(out, instance) { abytes(out); const min = instance.outputLen; if (out.length < min) { throw new Error('digestInto() expects output buffer of length at least ' + min); } } /** Cast u8 / u16 / u32 to u8. */ function u8(arr) { return new Uint8Array(arr.buffer, arr.byteOffset, arr.byteLength); } /** Cast u8 / u16 / u32 to u32. */ function u32(arr) { return new Uint32Array(arr.buffer, arr.byteOffset, Math.floor(arr.byteLength / 4)); } /** Zeroize a byte array. Warning: JS provides no guarantees. */ function clean(...arrays) { for (let i = 0; i < arrays.length; i++) { arrays[i].fill(0); } } /** Create DataView of an array for easy byte-level manipulation. */ function createView(arr) { return new DataView(arr.buffer, arr.byteOffset, arr.byteLength); } /** The rotate right (circular right shift) operation for uint32 */ function rotr(word, shift) { return (word << (32 - shift)) | (word >>> shift); } /** The rotate left (circular left shift) operation for uint32 */ function rotl(word, shift) { return (word << shift) | ((word >>> (32 - shift)) >>> 0); } /** Is current platform little-endian? Most are. Big-Endian platform: IBM */ exports.isLE = (() => new Uint8Array(new Uint32Array([0x11223344]).buffer)[0] === 0x44)(); /** The byte swap operation for uint32 */ function byteSwap(word) { return (((word << 24) & 0xff000000) | ((word << 8) & 0xff0000) | ((word >>> 8) & 0xff00) | ((word >>> 24) & 0xff)); } /** Conditionally byte swap if on a big-endian platform */ exports.swap8IfBE = exports.isLE ? (n) => n : (n) => byteSwap(n); /** @deprecated */ exports.byteSwapIfBE = exports.swap8IfBE; /** In place byte swap for Uint32Array */ function byteSwap32(arr) { for (let i = 0; i < arr.length; i++) { arr[i] = byteSwap(arr[i]); } return arr; } exports.swap32IfBE = exports.isLE ? (u) => u : byteSwap32; // Built-in hex conversion https://caniuse.com/mdn-javascript_builtins_uint8array_fromhex const hasHexBuiltin = /* @__PURE__ */ (() => // @ts-ignore typeof Uint8Array.from([]).toHex === 'function' && typeof Uint8Array.fromHex === 'function')(); // Array where index 0xf0 (240) is mapped to string 'f0' const hexes = /* @__PURE__ */ Array.from({ length: 256 }, (_, i) => i.toString(16).padStart(2, '0')); /** * Convert byte array to hex string. Uses built-in function, when available. * @example bytesToHex(Uint8Array.from([0xca, 0xfe, 0x01, 0x23])) // 'cafe0123' */ function bytesToHex(bytes) { abytes(bytes); // @ts-ignore if (hasHexBuiltin) return bytes.toHex(); // pre-caching improves the speed 6x let hex = ''; for (let i = 0; i < bytes.length; i++) { hex += hexes[bytes[i]]; } return hex; } // We use optimized technique to convert hex string to byte array const asciis = { _0: 48, _9: 57, A: 65, F: 70, a: 97, f: 102 }; function asciiToBase16(ch) { if (ch >= asciis._0 && ch <= asciis._9) return ch - asciis._0; // '2' => 50-48 if (ch >= asciis.A && ch <= asciis.F) return ch - (asciis.A - 10); // 'B' => 66-(65-10) if (ch >= asciis.a && ch <= asciis.f) return ch - (asciis.a - 10); // 'b' => 98-(97-10) return; } /** * Convert hex string to byte array. Uses built-in function, when available. * @example hexToBytes('cafe0123') // Uint8Array.from([0xca, 0xfe, 0x01, 0x23]) */ function hexToBytes(hex) { if (typeof hex !== 'string') throw new Error('hex string expected, got ' + typeof hex); // @ts-ignore if (hasHexBuiltin) return Uint8Array.fromHex(hex); const hl = hex.length; const al = hl / 2; if (hl % 2) throw new Error('hex string expected, got unpadded hex of length ' + hl); const array = new Uint8Array(al); for (let ai = 0, hi = 0; ai < al; ai++, hi += 2) { const n1 = asciiToBase16(hex.charCodeAt(hi)); const n2 = asciiToBase16(hex.charCodeAt(hi + 1)); if (n1 === undefined || n2 === undefined) { const char = hex[hi] + hex[hi + 1]; throw new Error('hex string expected, got non-hex character "' + char + '" at index ' + hi); } array[ai] = n1 * 16 + n2; // multiply first octet, e.g. 'a3' => 10*16+3 => 160 + 3 => 163 } return array; } /** * There is no setImmediate in browser and setTimeout is slow. * Call of async fn will return Promise, which will be fullfiled only on * next scheduler queue processing step and this is exactly what we need. */ const nextTick = async () => { }; exports.nextTick = nextTick; /** Returns control to thread each 'tick' ms to avoid blocking. */ async function asyncLoop(iters, tick, cb) { let ts = Date.now(); for (let i = 0; i < iters; i++) { cb(i); // Date.now() is not monotonic, so in case if clock goes backwards we return return control too const diff = Date.now() - ts; if (diff >= 0 && diff < tick) continue; await (0, exports.nextTick)(); ts += diff; } } /** * Converts string to bytes using UTF8 encoding. * @example utf8ToBytes('abc') // Uint8Array.from([97, 98, 99]) */ function utf8ToBytes(str) { if (typeof str !== 'string') throw new Error('string expected'); return new Uint8Array(new TextEncoder().encode(str)); // https://bugzil.la/1681809 } /** * Converts bytes to string using UTF8 encoding. * @example bytesToUtf8(Uint8Array.from([97, 98, 99])) // 'abc' */ function bytesToUtf8(bytes) { return new TextDecoder().decode(bytes); } /** * Normalizes (non-hex) string or Uint8Array to Uint8Array. * Warning: when Uint8Array is passed, it would NOT get copied. * Keep in mind for future mutable operations. */ function toBytes(data) { if (typeof data === 'string') data = utf8ToBytes(data); abytes(data); return data; } /** * Helper for KDFs: consumes uint8array or string. * When string is passed, does utf8 decoding, using TextDecoder. */ function kdfInputToBytes(data) { if (typeof data === 'string') data = utf8ToBytes(data); abytes(data); return data; } /** Copies several Uint8Arrays into one. */ function concatBytes(...arrays) { let sum = 0; for (let i = 0; i < arrays.length; i++) { const a = arrays[i]; abytes(a); sum += a.length; } const res = new Uint8Array(sum); for (let i = 0, pad = 0; i < arrays.length; i++) { const a = arrays[i]; res.set(a, pad); pad += a.length; } return res; } function checkOpts(defaults, opts) { if (opts !== undefined && {}.toString.call(opts) !== '[object Object]') throw new Error('options should be object or undefined'); const merged = Object.assign(defaults, opts); return merged; } /** For runtime check if class implements interface */ class Hash { } exports.Hash = Hash; /** Wraps hash function, creating an interface on top of it */ function createHasher(hashCons) { const hashC = (msg) => hashCons().update(toBytes(msg)).digest(); const tmp = hashCons(); hashC.outputLen = tmp.outputLen; hashC.blockLen = tmp.blockLen; hashC.create = () => hashCons(); return hashC; } function createOptHasher(hashCons) { const hashC = (msg, opts) => hashCons(opts).update(toBytes(msg)).digest(); const tmp = hashCons({}); hashC.outputLen = tmp.outputLen; hashC.blockLen = tmp.blockLen; hashC.create = (opts) => hashCons(opts); return hashC; } function createXOFer(hashCons) { const hashC = (msg, opts) => hashCons(opts).update(toBytes(msg)).digest(); const tmp = hashCons({}); hashC.outputLen = tmp.outputLen; hashC.blockLen = tmp.blockLen; hashC.create = (opts) => hashCons(opts); return hashC; } exports.wrapConstructor = createHasher; exports.wrapConstructorWithOpts = createOptHasher; exports.wrapXOFConstructorWithOpts = createXOFer; /** Cryptographically secure PRNG. Uses internal OS-level `crypto.getRandomValues`. */ function randomBytes(bytesLength = 32) { if (crypto_1.crypto && typeof crypto_1.crypto.getRandomValues === 'function') { return crypto_1.crypto.getRandomValues(new Uint8Array(bytesLength)); } // Legacy Node.js compatibility if (crypto_1.crypto && typeof crypto_1.crypto.randomBytes === 'function') { return Uint8Array.from(crypto_1.crypto.randomBytes(bytesLength)); } throw new Error('crypto.getRandomValues must be defined'); } } (utils$1)); return utils$1; } var hasRequired_md; function require_md () { if (hasRequired_md) return _md; hasRequired_md = 1; Object.defineProperty(_md, "__esModule", { value: true }); _md.SHA512_IV = _md.SHA384_IV = _md.SHA224_IV = _md.SHA256_IV = _md.HashMD = void 0; _md.setBigUint64 = setBigUint64; _md.Chi = Chi; _md.Maj = Maj; /** * Internal Merkle-Damgard hash utils. * @module */ const utils_ts_1 = /*@__PURE__*/ requireUtils$1(); /** Polyfill for Safari 14. https://caniuse.com/mdn-javascript_builtins_dataview_setbiguint64 */ function setBigUint64(view, byteOffset, value, isLE) { if (typeof view.setBigUint64 === 'function') return view.setBigUint64(byteOffset, value, isLE); const _32n = BigInt(32); const _u32_max = BigInt(0xffffffff); const wh = Number((value >> _32n) & _u32_max); const wl = Number(value & _u32_max); const h = isLE ? 4 : 0; const l = isLE ? 0 : 4; view.setUint32(byteOffset + h, wh, isLE); view.setUint32(byteOffset + l, wl, isLE); } /** Choice: a ? b : c */ function Chi(a, b, c) { return (a & b) ^ (~a & c); } /** Majority function, true if any two inputs is true. */ function Maj(a, b, c) { return (a & b) ^ (a & c) ^ (b & c); } /** * Merkle-Damgard hash construction base class. * Could be used to create MD5, RIPEMD, SHA1, SHA2. */ class HashMD extends utils_ts_1.Hash { constructor(blockLen, outputLen, padOffset, isLE) { super(); this.finished = false; this.length = 0; this.pos = 0; this.destroyed = false; this.blockLen = blockLen; this.outputLen = outputLen; this.padOffset = padOffset; this.isLE = isLE; this.buffer = new Uint8Array(blockLen); this.view = (0, utils_ts_1.createView)(this.buffer); } update(data) { (0, utils_ts_1.aexists)(this); data = (0, utils_ts_1.toBytes)(data); (0, utils_ts_1.abytes)(data); const { view, buffer, blockLen } = this; const len = data.length; for (let pos = 0; pos < len;) { const take = Math.min(blockLen - this.pos, len - pos); // Fast path: we have at least one block in input, cast it to view and process if (take === blockLen) { const dataView = (0, utils_ts_1.createView)(data); for (; blockLen <= len - pos; pos += blockLen) this.process(dataView, pos); continue; } buffer.set(data.subarray(pos, pos + take), this.pos); this.pos += take; pos += take; if (this.pos === blockLen) { this.process(view, 0); this.pos = 0; } } this.length += data.length; this.roundClean(); return this; } digestInto(out) { (0, utils_ts_1.aexists)(this); (0, utils_ts_1.aoutput)(out, this); this.finished = true; // Padding // We can avoid allocation of buffer for padding completely if it // was previously not allocated here. But it won't change performance. const { buffer, view, blockLen, isLE } = this; let { pos } = this; // append the bit '1' to the message buffer[pos++] = 0b10000000; (0, utils_ts_1.clean)(this.buffer.subarray(pos)); // we have less than padOffset left in buffer, so we cannot put length in // current block, need process it and pad again if (this.padOffset > blockLen - pos) { this.process(view, 0); pos = 0; } // Pad until full block byte with zeros for (let i = pos; i < blockLen; i++) buffer[i] = 0; // Note: sha512 requires length to be 128bit integer, but length in JS will overflow before that // You need to write around 2 exabytes (u64_max / 8 / (1024**6)) for this to happen. // So we just write lowest 64 bits of that value. setBigUint64(view, blockLen - 8, BigInt(this.length * 8), isLE); this.process(view, 0); const oview = (0, utils_ts_1.createView)(out); const len = this.outputLen; // NOTE: we do division by 4 later, which should be fused in single op with modulo by JIT if (len % 4) throw new Error('_sha2: outputLen should be aligned to 32bit'); const outLen = len / 4; const state = this.get(); if (outLen > state.length) throw new Error('_sha2: outputLen bigger than state'); for (let i = 0; i < outLen; i++) oview.setUint32(4 * i, state[i], isLE); } digest() { const { buffer, outputLen } = this; this.digestInto(buffer); const res = buffer.slice(0, outputLen); this.destroy(); return res; } _cloneInto(to) { to || (to = new this.constructor()); to.set(...this.get()); const { blockLen, buffer, length, finished, destroyed, pos } = this; to.destroyed = destroyed; to.finished = finished; to.length = length; to.pos = pos; if (length % blockLen) to.buffer.set(buffer); return to; } clone() { return this._cloneInto(); } } _md.HashMD = HashMD; /** * Initial SHA-2 state: fractional parts of square roots of first 16 primes 2..53. * Check out `test/misc/sha2-gen-iv.js` for recomputation guide. */ /** Initial SHA256 state. Bits 0..32 of frac part of sqrt of primes 2..19 */ _md.SHA256_IV = Uint32Array.from([ 0x6a09e667, 0xbb67ae85, 0x3c6ef372, 0xa54ff53a, 0x510e527f, 0x9b05688c, 0x1f83d9ab, 0x5be0cd19, ]); /** Initial SHA224 state. Bits 32..64 of frac part of sqrt of primes 23..53 */ _md.SHA224_IV = Uint32Array.from([ 0xc1059ed8, 0x367cd507, 0x3070dd17, 0xf70e5939, 0xffc00b31, 0x68581511, 0x64f98fa7, 0xbefa4fa4, ]); /** Initial SHA384 state. Bits 0..64 of frac part of sqrt of primes 23..53 */ _md.SHA384_IV = Uint32Array.from([ 0xcbbb9d5d, 0xc1059ed8, 0x629a292a, 0x367cd507, 0x9159015a, 0x3070dd17, 0x152fecd8, 0xf70e5939, 0x67332667, 0xffc00b31, 0x8eb44a87, 0x68581511, 0xdb0c2e0d, 0x64f98fa7, 0x47b5481d, 0xbefa4fa4, ]); /** Initial SHA512 state. Bits 0..64 of frac part of sqrt of primes 2..19 */ _md.SHA512_IV = Uint32Array.from([ 0x6a09e667, 0xf3bcc908, 0xbb67ae85, 0x84caa73b, 0x3c6ef372, 0xfe94f82b, 0xa54ff53a, 0x5f1d36f1, 0x510e527f, 0xade682d1, 0x9b05688c, 0x2b3e6c1f, 0x1f83d9ab, 0xfb41bd6b, 0x5be0cd19, 0x137e2179, ]); return _md; } var _u64 = {}; var hasRequired_u64; function require_u64 () { if (hasRequired_u64) return _u64; hasRequired_u64 = 1; Object.defineProperty(_u64, "__esModule", { value: true }); _u64.toBig = _u64.shrSL = _u64.shrSH = _u64.rotrSL = _u64.rotrSH = _u64.rotrBL = _u64.rotrBH = _u64.rotr32L = _u64.rotr32H = _u64.rotlSL = _u64.rotlSH = _u64.rotlBL = _u64.rotlBH = _u64.add5L = _u64.add5H = _u64.add4L = _u64.add4H = _u64.add3L = _u64.add3H = void 0; _u64.add = add; _u64.fromBig = fromBig; _u64.split = split; /** * Internal helpers for u64. BigUint64Array is too slow as per 2025, so we implement it using Uint32Array. * @todo re-check https://issues.chromium.org/issues/42212588 * @module */ const U32_MASK64 = /* @__PURE__ */ BigInt(2 ** 32 - 1); const _32n = /* @__PURE__ */ BigInt(32); function fromBig(n, le = false) { if (le) return { h: Number(n & U32_MASK64), l: Number((n >> _32n) & U32_MASK64) }; return { h: Number((n >> _32n) & U32_MASK64) | 0, l: Number(n & U32_MASK64) | 0 }; } function split(lst, le = false) { const len = lst.length; let Ah = new Uint32Array(len); let Al = new Uint32Array(len); for (let i = 0; i < len; i++) { const { h, l } = fromBig(lst[i], le); [Ah[i], Al[i]] = [h, l]; } return [Ah, Al]; } const toBig = (h, l) => (BigInt(h >>> 0) << _32n) | BigInt(l >>> 0); _u64.toBig = toBig; // for Shift in [0, 32) const shrSH = (h, _l, s) => h >>> s; _u64.shrSH = shrSH; const shrSL = (h, l, s) => (h << (32 - s)) | (l >>> s); _u64.shrSL = shrSL; // Right rotate for Shift in [1, 32) const rotrSH = (h, l, s) => (h >>> s) | (l << (32 - s)); _u64.rotrSH = rotrSH; const rotrSL = (h, l, s) => (h << (32 - s)) | (l >>> s); _u64.rotrSL = rotrSL; // Right rotate for Shift in (32, 64), NOTE: 32 is special case. const rotrBH = (h, l, s) => (h << (64 - s)) | (l >>> (s - 32)); _u64.rotrBH = rotrBH; const rotrBL = (h, l, s) => (h >>> (s - 32)) | (l << (64 - s)); _u64.rotrBL = rotrBL; // Right rotate for shift===32 (just swaps l&h) const rotr32H = (_h, l) => l; _u64.rotr32H = rotr32H; const rotr32L = (h, _l) => h; _u64.rotr32L = rotr32L; // Left rotate for Shift in [1, 32) const rotlSH = (h, l, s) => (h << s) | (l >>> (32 - s)); _u64.rotlSH = rotlSH; const rotlSL = (h, l, s) => (l << s) | (h >>> (32 - s)); _u64.rotlSL = rotlSL; // Left rotate for Shift in (32, 64), NOTE: 32 is special case. const rotlBH = (h, l, s) => (l << (s - 32)) | (h >>> (64 - s)); _u64.rotlBH = rotlBH; const rotlBL = (h, l, s) => (h << (s - 32)) | (l >>> (64 - s)); _u64.rotlBL = rotlBL; // JS uses 32-bit signed integers for bitwise operations which means we cannot // simple take carry out of low bit sum by shift, we need to use division. function add(Ah, Al, Bh, Bl) { const l = (Al >>> 0) + (Bl >>> 0); return { h: (Ah + Bh + ((l / 2 ** 32) | 0)) | 0, l: l | 0 }; } // Addition with more than 2 elements const add3L = (Al, Bl, Cl) => (Al >>> 0) + (Bl >>> 0) + (Cl >>> 0); _u64.add3L = add3L; const add3H = (low, Ah, Bh, Ch) => (Ah + Bh + Ch + ((low / 2 ** 32) | 0)) | 0; _u64.add3H = add3H; const add4L = (Al, Bl, Cl, Dl) => (Al >>> 0) + (Bl >>> 0) + (Cl >>> 0) + (Dl >>> 0); _u64.add4L = add4L; const add4H = (low, Ah, Bh, Ch, Dh) => (Ah + Bh + Ch + Dh + ((low / 2 ** 32) | 0)) | 0; _u64.add4H = add4H; const add5L = (Al, Bl, Cl, Dl, El) => (Al >>> 0) + (Bl >>> 0) + (Cl >>> 0) + (Dl >>> 0) + (El >>> 0); _u64.add5L = add5L; const add5H = (low, Ah, Bh, Ch, Dh, Eh) => (Ah + Bh + Ch + Dh + Eh + ((low / 2 ** 32) | 0)) | 0; _u64.add5H = add5H; // prettier-ignore const u64 = { fromBig, split, toBig, shrSH, shrSL, rotrSH, rotrSL, rotrBH, rotrBL, rotr32H, rotr32L, rotlSH, rotlSL, rotlBH, rotlBL, add, add3L, add3H, add4L, add4H, add5H, add5L, }; _u64.default = u64; return _u64; } var hasRequiredSha2; function requireSha2 () { if (hasRequiredSha2) return sha2; hasRequiredSha2 = 1; Object.defineProperty(sha2, "__esModule", { value: true }); sha2.sha512_224 = sha2.sha512_256 = sha2.sha384 = sha2.sha512 = sha2.sha224 = sha2.sha256 = sha2.SHA512_256 = sha2.SHA512_224 = sha2.SHA384 = sha2.SHA512 = sha2.SHA224 = sha2.SHA256 = void 0; /** * SHA2 hash function. A.k.a. sha256, sha384, sha512, sha512_224, sha512_256. * SHA256 is the fastest hash implementable in JS, even faster than Blake3. * Check out [RFC 4634](https://datatracker.ietf.org/doc/html/rfc4634) and * [FIPS 180-4](https://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.180-4.pdf). * @module */ const _md_ts_1 = /*@__PURE__*/ require_md(); const u64 = /*@__PURE__*/ require_u64(); const utils_ts_1 = /*@__PURE__*/ requireUtils$1(); /** * Round constants: * First 32 bits of fractional parts of the cube roots of the first 64 primes 2..311) */ // prettier-ignore const SHA256_K = /* @__PURE__ */ Uint32Array.from([ 0x428a2f98, 0x71374491, 0xb5c0fbcf, 0xe9b5dba5, 0x3956c25b, 0x59f111f1, 0x923f82a4, 0xab1c5ed5, 0xd807aa98, 0x12835b01, 0x243185be, 0x550c7dc3, 0x72be5d74, 0x80deb1fe, 0x9bdc06a7, 0xc19bf174, 0xe49b69c1, 0xefbe4786, 0x0fc19dc6, 0x240ca1cc, 0x2de92c6f, 0x4a7484aa, 0x5cb0a9dc, 0x76f988da, 0x983e5152, 0xa831c66d, 0xb00327c8, 0xbf597fc7, 0xc6e00bf3, 0xd5a79147, 0x06ca6351, 0x14292967, 0x27b70a85, 0x2e1b2138, 0x4d2c6dfc, 0x53380d13, 0x650a7354, 0x766a0abb, 0x81c2c92e, 0x92722c85, 0xa2bfe8a1, 0xa81a664b, 0xc24b8b70, 0xc76c51a3, 0xd192e819, 0xd6990624, 0xf40e3585, 0x106aa070, 0x19a4c116, 0x1e376c08, 0x2748774c, 0x34b0bcb5, 0x391c0cb3, 0x4ed8aa4a, 0x5b9cca4f, 0x682e6ff3, 0x748f82ee, 0x78a5636f, 0x84c87814, 0x8cc70208, 0x90befffa, 0xa4506ceb, 0xbef9a3f7, 0xc67178f2 ]); /** Reusable temporary buffer. "W" comes straight from spec. */ const SHA256_W = /* @__PURE__ */ new Uint32Array(64); class SHA256 extends _md_ts_1.HashMD { constructor(outputLen = 32) { super(64, outputLen, 8, false); // We cannot use array here since array allows indexing by variable // which means optimizer/compiler cannot use registers. this.A = _md_ts_1.SHA256_IV[0] | 0; this.B = _md_ts_1.SHA256_IV[1] | 0; this.C = _md_ts_1.SHA256_IV[2] | 0; this.D = _md_ts_1.SHA256_IV[3] | 0; this.E = _md_ts_1.SHA256_IV[4] | 0; this.F = _md_ts_1.SHA256_IV[5] | 0; this.G = _md_ts_1.SHA256_IV[6] | 0; this.H = _md_ts_1.SHA256_IV[7] | 0; } get() { const { A, B, C, D, E, F, G, H } = this; return [A, B, C, D, E, F, G, H]; } // prettier-ignore set(A, B, C, D, E, F, G, H) { this.A = A | 0; this.B = B | 0; this.C = C | 0; this.D = D | 0; this.E = E | 0; this.F = F | 0; this.G = G | 0; this.H = H | 0; } process(view, offset) { // Extend the first 16 words into the remaining 48 words w[16..63] of the message schedule array for (let i = 0; i < 16; i++, offset += 4) SHA256_W[i] = view.getUint32(offset, false); for (let i = 16; i < 64; i++) { const W15 = SHA256_W[i - 15]; const W2 = SHA256_W[i - 2]; const s0 = (0, utils_ts_1.rotr)(W15, 7) ^ (0, utils_ts_1.rotr)(W15, 18) ^ (W15 >>> 3); const s1 = (0, utils_ts_1.rotr)(W2, 17) ^ (0, utils_ts_1.rotr)(W2, 19) ^ (W2 >>> 10); SHA256_W[i] = (s1 + SHA256_W[i - 7] + s0 + SHA256_W[i - 16]) | 0; } // Compression function main loop, 64 rounds let { A, B, C, D, E, F, G, H } = this; for (let i = 0; i < 64; i++) { const sigma1 = (0, utils_ts_1.rotr)(E, 6) ^ (0, utils_ts_1.rotr)(E, 11) ^ (0, utils_ts_1.rotr)(E, 25); const T1 = (H + sigma1 + (0, _md_ts_1.Chi)(E, F, G) + SHA256_K[i] + SHA256_W[i]) | 0; const sigma0 = (0, utils_ts_1.rotr)(A, 2) ^ (0, utils_ts_1.rotr)(A, 13) ^ (0, utils_ts_1.rotr)(A, 22); const T2 = (sigma0 + (0, _md_ts_1.Maj)(A, B, C)) | 0; H = G; G = F; F = E; E = (D + T1) | 0; D = C; C = B; B = A; A = (T1 + T2) | 0; } // Add the compressed chunk to the current hash value A = (A + this.A) | 0; B = (B + this.B) | 0; C = (C + this.C) | 0; D = (D + this.D) | 0; E = (E + this.E) | 0; F = (F + this.F) | 0; G = (G + this.G) | 0; H = (H + this.H) | 0; this.set(A, B, C, D, E, F, G, H); } roundClean() { (0, utils_ts_1.clean)(SHA256_W); } destroy() { this.set(0, 0, 0, 0, 0, 0, 0, 0); (0, utils_ts_1.clean)(this.buffer); } } sha2.SHA256 = SHA256; class SHA224 extends SHA256 { constructor() { super(28); this.A = _md_ts_1.SHA224_IV[0] | 0; this.B = _md_ts_1.SHA224_IV[1] | 0; this.C = _md_ts_1.SHA224_IV[2] | 0; this.D = _md_ts_1.SHA224_IV[3] | 0; this.E = _md_ts_1.SHA224_IV[4] | 0; this.F = _md_ts_1.SHA224_IV[5] | 0; this.G = _md_ts_1.SHA224_IV[6] | 0; this.H = _md_ts_1.SHA224_IV[7] | 0; } } sha2.SHA224 = SHA224; // SHA2-512 is slower than sha256 in js because u64 operations are slow. // Round contants // First 32 bits of the fractional parts of the cube roots of the first 80 primes 2..409 // prettier-ignore const K512 = /* @__PURE__ */ (() => u64.split([ '0x428a2f98d728ae22', '0x7137449123ef65cd', '0xb5c0fbcfec4d3b2f', '0xe9b5dba58189dbbc', '0x3956c25bf348b538', '0x59f111f1b605d019', '0x923f82a4af194f9b', '0xab1c5ed5da6d8118', '0xd807aa98a3030242', '0x12835b0145706fbe', '0x243185be4ee4b28c', '0x550c7dc3d5ffb4e2', '0x72be5d74f27b896f', '0x80deb1fe3b1696b1', '0x9bdc06a725c71235', '0xc19bf174cf692694', '0xe49b69c19ef14ad2', '0xefbe4786384f25e3', '0x0fc19dc68b8cd5b5', '0x240ca1cc77ac9c65', '0x2de92c6f592b0275', '0x4a7484aa6ea6e483', '0x5cb0a9dcbd41fbd4', '0x76f988da831153b5', '0x983e5152ee66dfab', '0xa831c66d2db43210', '0xb00327c898fb213f', '0xbf597fc7beef0ee4', '0xc6e00bf33da88fc2', '0xd5a79147930aa725', '0x06ca6351e003826f', '0x142929670a0e6e70', '0x27b70a8546d22ffc', '0x2e1b21385c26c926', '0x4d2c6dfc5ac42aed', '0x53380d139d95b3df', '0x650a73548baf63de', '0x766a0abb3c77b2a8', '0x81c2c92e47edaee6', '0x92722c851482353b', '0xa2bfe8a14cf10364', '0xa81a664bbc423001', '0xc24b8b70d0f89791', '0xc76c51a30654be30', '0xd192e819d6ef5218', '0xd69906245565a910', '0xf40e35855771202a', '0x106aa07032bbd1b8', '0x19a4c116b8d2d0c8', '0x1e376c085141ab53', '0x2748774cdf8eeb99', '0x34b0bcb5e19b48a8', '0x391c0cb3c5c95a63', '0x4ed8aa4ae3418acb', '0x5b9cca4f7763e373', '0x682e6ff3d6b2b8a3', '0x748f82ee5defb2fc', '0x78a5636f43172f60', '0x84c87814a1f0ab72', '0x8cc702081a6439ec', '0x90befffa23631e28', '0xa4506cebde82bde9', '0xbef9a3f7b2c67915', '0xc67178f2e372532b', '0xca273eceea26619c', '0xd186b8c721c0c207', '0xeada7dd6cde0eb1e', '0xf57d4f7fee6ed178', '0x06f067aa72176fba', '0x0a637dc5a2c898a6', '0x113f9804bef90dae', '0x1b710b35131c471b', '0x28db77f523047d84', '0x32caab7b40c72493', '0x3c9ebe0a15c9bebc', '0x431d67c49c100d4c', '0x4cc5d4becb3e42b6', '0x597f299cfc657e2a', '0x5fcb6fab3ad6faec', '0x6c44198c4a475817' ].map(n => BigInt(n))))(); const SHA512_Kh = /* @__PURE__ */ (() => K512[0])(); const SHA512_Kl = /* @__PURE__ */ (() => K512[1])(); // Reusable temporary buffers const SHA512_W_H = /* @__PURE__ */ new Uint32Array(80); const SHA512_W_L = /* @__PURE__ */ new Uint32Array(80); class SHA512 extends _md_ts_1.HashMD { constructor(outputLen = 64) { super(128, outputLen, 16, false); // We cannot use array here since array allows indexing by variable // which means optimizer/compiler cannot use registers. // h -- high 32 bits, l -- low 32 bits this.Ah = _md_ts_1.SHA512_IV[0] | 0; this.Al = _md_ts_1.SHA512_IV[1] | 0; this.Bh = _md_ts_1.SHA512_IV[2] | 0; this.Bl = _md_ts_1.SHA512_IV[3] | 0; this.Ch = _md_ts_1.SHA512_IV[4] | 0; this.Cl = _md_ts_1.SHA512_IV[5] | 0; this.Dh = _md_ts_1.SHA512_IV[6] | 0; this.Dl = _md_ts_1.SHA512_IV[7] | 0; this.Eh = _md_ts_1.SHA512_IV[8] | 0; this.El = _md_ts_1.SHA512_IV[9] | 0; this.Fh = _md_ts_1.SHA512_IV[10] | 0; this.Fl = _md_ts_1.SHA512_IV[11] | 0; this.Gh = _md_ts_1.SHA512_IV[12] | 0; this.Gl = _md_ts_1.SHA512_IV[13] | 0; this.Hh = _md_ts_1.SHA512_IV[14] | 0; this.Hl = _md_ts_1.SHA512_IV[15] | 0; } // prettier-ignore get() { const { Ah, Al, Bh, Bl, Ch, Cl, Dh, Dl, Eh, El, Fh, Fl, Gh, Gl, Hh, Hl } = this; return [Ah, Al, Bh, Bl, Ch, Cl, Dh, Dl, Eh, El, Fh, Fl, Gh, Gl, Hh, Hl]; } // prettier-ignore set(Ah, Al, Bh, Bl, Ch, Cl, Dh, Dl, Eh, El, Fh, Fl, Gh, Gl, Hh, Hl) { this.Ah = Ah | 0; this.Al = Al | 0; this.Bh = Bh | 0; this.Bl = Bl | 0; this.Ch = Ch | 0; this.Cl = Cl | 0; this.Dh = Dh | 0; this.Dl = Dl | 0; this.Eh = Eh | 0; this.El = El | 0; this.Fh = Fh | 0; this.Fl = Fl | 0; this.Gh = Gh | 0; this.Gl = Gl | 0; this.Hh = Hh | 0; this.Hl = Hl | 0; } process(view, offset) { // Extend the first 16 words into the remaining 64 words w[16..79] of the message schedule array for (let i = 0; i < 16; i++, offset += 4) { SHA512_W_H[i] = view.getUint32(offset); SHA512_W_L[i] = view.getUint32((offset += 4)); } for (let i = 16; i < 80; i++) { // s0 := (w[i-15] rightrotate 1) xor (w[i-15] rightrotate 8) xor (w[i-15] rightshift 7) const W15h = SHA512_W_H[i - 15] | 0; const W15l = SHA512_W_L[i - 15] | 0; const s0h = u64.rotrSH(W15h, W15l, 1) ^ u64.rotrSH(W15h, W15l, 8) ^ u64.shrSH(W15h, W15l, 7); const s0l = u64.rotrSL(W15h, W15l, 1) ^ u64.rotrSL(W15h, W15l, 8) ^ u64.shrSL(W15h, W15l, 7); // s1 := (w[i-2] rightrotate 19) xor (w[i-2] rightrotate 61) xor (w[i-2] rightshift 6) const W2h = SHA512_W_H[i - 2] | 0; const W2l = SHA512_W_L[i - 2] | 0; const s1h = u64.rotrSH(W2h, W2l, 19) ^ u64.rotrBH(W2h, W2l, 61) ^ u64.shrSH(W2h, W2l, 6); const s1l = u64.rotrSL(W2h, W2l, 19) ^ u64.rotrBL(W2h, W2l, 61) ^ u64.shrSL(W2h, W2l, 6); // SHA256_W[i] = s0 + s1 + SHA256_W[i - 7] + SHA256_W[i - 16]; const SUMl = u64.add4L(s0l, s1l, SHA512_W_L[i - 7], SHA512_W_L[i - 16]); const SUMh = u64.add4H(SUMl, s0h, s1h, SHA512_W_H[i - 7], SHA512_W_H[i - 16]); SHA512_W_H[i] = SUMh | 0; SHA512_W_L[i] = SUMl | 0; } let { Ah, Al, Bh, Bl, Ch, Cl, Dh, Dl, Eh, El, Fh, Fl, Gh, Gl, Hh, Hl } = this; // Compression function main loop, 80 rounds for (let i = 0; i < 80; i++) { // S1 := (e rightrotate 14) xor (e rightrotate 18) xor (e rightrotate 41) const sigma1h = u64.rotrSH(Eh, El, 14) ^ u64.rotrSH(Eh, El, 18) ^ u64.rotrBH(Eh, El, 41); const sigma1l = u64.rotrSL(Eh, El, 14) ^ u64.rotrSL(Eh, El, 18) ^ u64.rotrBL(Eh, El, 41); //const T1 = (H + sigma1 + Chi(E, F, G) + SHA256_K[i] + SHA256_W[i]) | 0; const CHIh = (Eh & Fh) ^ (~Eh & Gh); const CHIl = (El & Fl) ^ (~El & Gl); // T1 = H + sigma1 + Chi(E, F, G) + SHA512_K[i] + SHA512_W[i] // prettier-ignore const T1ll = u64.add5L(Hl, sigma1l, CHIl, SHA512_Kl[i], SHA512_W_L[i]); const T1h = u64.add5H(T1ll, Hh, sigma1h, CHIh, SHA512_Kh[i], SHA512_W_H[i]); const T1l = T1ll | 0; // S0 := (a rightrotate 28) xor (a rightrotate 34) xor (a rightrotate 39) const sigma0h = u64.rotrSH(Ah, Al, 28) ^ u64.rotrBH(Ah, Al, 34) ^ u64.rotrBH(Ah, Al, 39); const sigma0l = u64.rotrSL(Ah, Al, 28) ^ u64.rotrBL(Ah, Al, 34) ^ u64.rotrBL(Ah, Al, 39); const MAJh = (Ah & Bh) ^ (Ah & Ch) ^ (Bh & Ch); const MAJl = (Al & Bl) ^ (Al & Cl) ^ (Bl & Cl); Hh = Gh | 0; Hl = Gl | 0; Gh = Fh | 0; Gl = Fl | 0; Fh = Eh | 0; Fl = El | 0; ({ h: Eh, l: El } = u64.add(Dh | 0, Dl | 0, T1h | 0, T1l | 0)); Dh = Ch | 0; Dl = Cl | 0; Ch = Bh | 0; Cl = Bl | 0; Bh = Ah | 0; Bl = Al | 0; const All = u64.add3L(T1l, sigma0l, MAJl); Ah = u64.add3H(All, T1h, sigma0h, MAJh); Al = All | 0; } // Add the compressed chunk to the current hash value ({ h: Ah, l: Al } = u64.add(this.Ah | 0, this.Al | 0, Ah | 0, Al | 0)); ({ h: Bh, l: Bl } = u64.add(this.Bh | 0, this.Bl | 0, Bh | 0, Bl | 0)); ({ h: Ch, l: Cl } = u64.add(this.Ch | 0, this.Cl | 0, Ch | 0, Cl | 0)); ({ h: Dh, l: Dl } = u64.add(this.Dh | 0, this.Dl | 0, Dh | 0, Dl | 0)); ({ h: Eh, l: El } = u64.add(this.Eh | 0, this.El | 0, Eh | 0, El | 0)); ({ h: Fh, l: Fl } = u64.add(this.Fh | 0, this.Fl | 0, Fh | 0, Fl | 0)); ({ h: Gh, l: Gl } = u64.add(this.Gh | 0, this.Gl | 0, Gh | 0, Gl | 0)); ({ h: Hh, l: Hl } = u64.add(this.Hh | 0, this.Hl | 0, Hh | 0, Hl | 0)); this.set(Ah, Al, Bh, Bl, Ch, Cl, Dh, Dl, Eh, El, Fh, Fl, Gh, Gl, Hh, Hl); } roundClean() { (0, utils_ts_1.clean)(SHA512_W_H, SHA512_W_L); } destroy() { (0, utils_ts_1.clean)(this.buffer); this.set(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0); } } sha2.SHA512 = SHA512; class SHA384 extends SHA512 { constructor() { super(48); this.Ah = _md_ts_1.SHA384_IV[0] | 0; this.Al = _md_ts_1.SHA384_IV[1] | 0; this.Bh = _md_ts_1.SHA384_IV[2] | 0; this.Bl = _md_ts_1.SHA384_IV[3] | 0; this.Ch = _md_ts_1.SHA384_IV[4] | 0; this.Cl = _md_ts_1.SHA384_IV[5] | 0; this.Dh = _md_ts_1.SHA384_IV[6] | 0; this.Dl = _md_ts_1.SHA384_IV[7] | 0; this.Eh = _md_ts_1.SHA384_IV[8] | 0; this.El = _md_ts_1.SHA384_IV[9] | 0; this.Fh = _md_ts_1.SHA384_IV[10] | 0; this.Fl = _md_ts_1.SHA384_IV[11] | 0; this.Gh = _md_ts_1.SHA384_IV[12] | 0; this.Gl = _md_ts_1.SHA384_IV[13] | 0; this.Hh = _md_ts_1.SHA384_IV[14] | 0; this.Hl = _md_ts_1.SHA384_IV[15] | 0; } } sha2.SHA384 = SHA384; /** * Truncated SHA512/256 and SHA512/224. * SHA512_IV is XORed with 0xa5a5a5a5a5a5a5a5, then used as "intermediary" IV of SHA512/t. * Then t hashes string to produce result IV. * See `test/misc/sha2-gen-iv.js`. */ /** SHA512/224 IV */ const T224_IV = /* @__PURE__ */ Uint32Array.from([ 0x8c3d37c8, 0x19544da2, 0x73e19966, 0x89dcd4d6, 0x1dfab7ae, 0x32ff9c82, 0x679dd514, 0x582f9fcf, 0x0f6d2b69, 0x7bd44da8, 0x77e36f73, 0x04c48942, 0x3f9d85a8, 0x6a1d36c8, 0x1112e6ad, 0x91d692a1, ]); /** SHA512/256 IV */ const T256_IV = /* @__PURE__ */ Uint32Array.from([ 0x22312194, 0xfc2bf72c, 0x9f555fa3, 0xc84c64c2, 0x2393b86b, 0x6f53b151, 0x96387719, 0x5940eabd, 0x96283ee2, 0xa88effe3, 0xbe5e1e25, 0x53863992, 0x2b0199fc, 0x2c85b8aa, 0x0eb72ddc, 0x81c52ca2, ]); class SHA512_224 extends SHA512 { constructor() { super(28); this.Ah = T224_IV[0] | 0; this.Al = T224_IV[1] | 0; this.Bh = T224_IV[2] | 0; this.Bl = T224_IV[3] | 0; this.Ch = T224_IV[4] | 0; this.Cl = T224_IV[5] | 0; this.Dh = T224_IV[6] | 0; this.Dl = T224_IV[7] | 0; this.Eh = T224_IV[8] | 0; this.El = T224_IV[9] | 0; this.Fh = T224_IV[10] | 0; this.Fl = T224_IV[11] | 0; this.Gh = T224_IV[12] | 0; this.Gl = T224_IV[13] | 0; this.Hh = T224_IV[14] | 0; this.Hl = T224_IV[15] | 0; } } sha2.SHA512_224 = SHA512_224; class SHA512_256 extends SHA512 { constructor() { super(32); this.Ah = T256_IV[0] | 0; this.Al = T256_IV[1] | 0; this.Bh = T256_IV[2] | 0; this.Bl = T256_IV[3] | 0; this.Ch = T256_IV[4] | 0; this.Cl = T256_IV[5] | 0; this.Dh = T256_IV[6] | 0; this.Dl = T256_IV[7] | 0; this.Eh = T256_IV[8] | 0; this.El = T256_IV[9] | 0; this.Fh = T256_IV[10] | 0; this.Fl = T256_IV[11] | 0; this.Gh = T256_IV[12] | 0; this.Gl = T256_IV[13] | 0; this.Hh = T256_IV[14] | 0; this.Hl = T256_IV[15] | 0; } } sha2.SHA512_256 = SHA512_256; /** * SHA2-256 hash function from RFC 4634. * * It is the fastest JS hash, even faster than Blake3. * To break sha256 using birthday attack, attackers need to try 2^128 hashes. * BTC network is doing 2^70 hashes/sec (2^95 hashes/year) as per 2025. */ sha2.sha256 = (0, utils_ts_1.createHasher)(() => new SHA256()); /** SHA2-224 hash function from RFC 4634 */ sha2.sha224 = (0, utils_ts_1.createHasher)(() => new SHA224()); /** SHA2-512 hash function from RFC 4634. */ sha2.sha512 = (0, utils_ts_1.createHasher)(() => new SHA512()); /** SHA2-384 hash function from RFC 4634. */ sha2.sha384 = (0, utils_ts_1.createHasher)(() => new SHA384()); /** * SHA2-512/256 "truncated" hash function, with improved resistance to length extension attacks. * See the paper on [truncated SHA512](https://eprint.iacr.org/2010/548.pdf). */ sha2.sha512_256 = (0, utils_ts_1.createHasher)(() => new SHA512_256()); /** * SHA2-512/224 "truncated" hash function, with improved resistance to length extension attacks. * See the paper on [truncated SHA512](https://eprint.iacr.org/2010/548.pdf). */ sha2.sha512_224 = (0, utils_ts_1.createHasher)(() => new SHA512_224()); return sha2; } var hasRequiredSha256; function requireSha256 () { if (hasRequiredSha256) return sha256; hasRequiredSha256 = 1; Object.defineProperty(sha256, "__esModule", { value: true }); sha256.sha224 = sha256.SHA224 = sha256.sha256 = sha256.SHA256 = void 0; /** * SHA2-256 a.k.a. sha256. In JS, it is the fastest hash, even faster than Blake3. * * To break sha256 using birthday attack, attackers need to try 2^128 hashes. * BTC network is doing 2^70 hashes/sec (2^95 hashes/year) as per 2025. * * Check out [FIPS 180-4](https://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.180-4.pdf). * @module * @deprecated */ const sha2_ts_1 = /*@__PURE__*/ requireSha2(); /** @deprecated Use import from `noble/hashes/sha2` module */ sha256.SHA256 = sha2_ts_1.SHA256; /** @deprecated Use import from `noble/hashes/sha2` module */ sha256.sha256 = sha2_ts_1.sha256; /** @deprecated Use import from `noble/hashes/sha2` module */ sha256.SHA224 = sha2_ts_1.SHA224; /** @deprecated Use import from `noble/hashes/sha2` module */ sha256.sha224 = sha2_ts_1.sha224; return sha256; } var sha512 = {}; var hasRequiredSha512; function requireSha512 () { if (hasRequiredSha512) return sha512; hasRequiredSha512 = 1; Object.defineProperty(sha512, "__esModule", { value: true }); sha512.sha512_256 = sha512.SHA512_256 = sha512.sha512_224 = sha512.SHA512_224 = sha512.sha384 = sha512.SHA384 = sha512.sha512 = sha512.SHA512 = void 0; /** * SHA2-512 a.k.a. sha512 and sha384. It is slower than sha256 in js because u64 operations are slow. * * Check out [RFC 4634](https://datatracker.ietf.org/doc/html/rfc4634) and * [the paper on truncated SHA512/256](https://eprint.iacr.org/2010/548.pdf). * @module * @deprecated */ const sha2_ts_1 = /*@__PURE__*/ requireSha2(); /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.SHA512 = sha2_ts_1.SHA512; /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.sha512 = sha2_ts_1.sha512; /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.SHA384 = sha2_ts_1.SHA384; /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.sha384 = sha2_ts_1.sha384; /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.SHA512_224 = sha2_ts_1.SHA512_224; /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.sha512_224 = sha2_ts_1.sha512_224; /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.SHA512_256 = sha2_ts_1.SHA512_256; /** @deprecated Use import from `noble/hashes/sha2` module */ sha512.sha512_256 = sha2_ts_1.sha512_256; return sha512; } var pbkdf2 = {}; var hmac = {}; var hasRequiredHmac; function requireHmac () { if (hasRequiredHmac) return hmac; hasRequiredHmac = 1; (function (exports) { Object.defineProperty(exports, "__esModule", { value: true }); exports.hmac = exports.HMAC = void 0; /** * HMAC: RFC2104 message authentication code. * @module */ const utils_ts_1 = /*@__PURE__*/ requireUtils$1(); class HMAC extends utils_ts_1.Hash { constructor(hash, _key) { super(); this.finished = false; this.destroyed = false; (0, utils_ts_1.ahash)(hash); const key = (0, utils_ts_1.toBytes)(_key); this.iHash = hash.create(); if (typeof this.iHash.update !== 'function') throw new Error('Expected instance of class which extends utils.Hash'); this.blockLen = this.iHash.blockLen; this.outputLen = this.iHash.outputLen; const blockLen = this.blockLen; const pad = new Uint8Array(blockLen); // blockLen can be bigger than outputLen pad.set(key.length > blockLen ? hash.create().update(key).digest() : key); for (let i = 0; i < pad.length; i++) pad[i] ^= 0x36; this.iHash.update(pad); // By doing update (processing of first block) of outer hash here we can re-use it between multiple calls via clone this.oHash = hash.create(); // Undo internal XOR && apply outer XOR for (let i = 0; i < pad.length; i++) pad[i] ^= 0x36 ^ 0x5c; this.oHash.update(pad); (0, utils_ts_1.clean)(pad); } update(buf) { (0, utils_ts_1.aexists)(this); this.iHash.update(buf); return this; } digestInto(out) { (0, utils_ts_1.aexists)(this); (0, utils_ts_1.abytes)(out, this.outputLen); this.finished = true; this.iHash.digestInto(out); this.oHash.update(out); this.oHash.digestInto(out); this.destroy(); } digest() { const out = new Uint8Array(this.oHash.outputLen); this.digestInto(out); return out; } _cloneInto(to) { // Create new instance without calling constructor since key already in state and we don't know it. to || (to = Object.create(Object.getPrototypeOf(this), {})); const { oHash, iHash, finished, destroyed, blockLen, outputLen } = this; to = to; to.finished = finished; to.destroyed = destroyed; to.blockLen = blockLen; to.outputLen = outputLen; to.oHash = oHash._cloneInto(to.oHash); to.iHash = iHash._cloneInto(to.iHash); return to; } clone() { return this._cloneInto(); } destroy() { this.destroyed = true; this.oHash.destroy(); this.iHash.destroy(); } } exports.HMAC = HMAC; /** * HMAC: RFC2104 message authentication code. * @param hash - function that would be used e.g. sha256 * @param key - message key * @param message - message data * @example * import { hmac } from '@noble/hashes/hmac'; * import { sha256 } from '@noble/hashes/sha2'; * const mac1 = hmac(sha256, 'key', 'message'); */ const hmac = (hash, key, message) => new HMAC(hash, key).update(message).digest(); exports.hmac = hmac; exports.hmac.create = (hash, key) => new HMAC(hash, key); } (hmac)); return hmac; } var hasRequiredPbkdf2; function requirePbkdf2 () { if (hasRequiredPbkdf2) return pbkdf2; hasRequiredPbkdf2 = 1; Object.defineProperty(pbkdf2, "__esModule", { value: true }); pbkdf2.pbkdf2 = pbkdf2$1; pbkdf2.pbkdf2Async = pbkdf2Async; /** * PBKDF (RFC 2898). Can be used to create a key from password and salt. * @module */ const hmac_ts_1 = /*@__PURE__*/ requireHmac(); // prettier-ignore const utils_ts_1 = /*@__PURE__*/ requireUtils$1(); // Common prologue and epilogue for sync/async functions function pbkdf2Init(hash, _password, _salt, _opts) { (0, utils_ts_1.ahash)(hash); const opts = (0, utils_ts_1.checkOpts)({ dkLen: 32, asyncTick: 10 }, _opts); const { c, dkLen, asyncTick } = opts; (0, utils_ts_1.anumber)(c); (0, utils_ts_1.anumber)(dkLen); (0, utils_ts_1.anumber)(asyncTick); if (c < 1) throw new Error('iterations (c) should be >= 1'); const password = (0, utils_ts_1.kdfInputToBytes)(_password); con