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@salutejs/client

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Модуль взаимодействия с виртуальным ассистентом

github.com/salute-developers/salutejs-client

salute-developers/salutejs-client

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JavaScript

import { _ as __assign, a as __rest, b as __awaiter, c as __generator, d as createNanoEvents, e as __spreadArray } from './common-ba25e019.js'; var commonjsGlobal = typeof globalThis !== 'undefined' ? globalThis : typeof window !== 'undefined' ? window : typeof global !== 'undefined' ? global : typeof self !== 'undefined' ? self : {}; function getDefaultExportFromCjs (x) { return x && x.__esModule && Object.prototype.hasOwnProperty.call(x, 'default') ? x['default'] : x; } function commonjsRequire(path) { throw new Error('Could not dynamically require "' + path + '". Please configure the dynamicRequireTargets or/and ignoreDynamicRequires option of @rollup/plugin-commonjs appropriately for this require call to work.'); } var proto = {exports: {}}; var indexMinimal = {}; var minimal$1 = {}; var aspromise; var hasRequiredAspromise; function requireAspromise () { if (hasRequiredAspromise) return aspromise; hasRequiredAspromise = 1; aspromise = asPromise; /** * Callback as used by {@link util.asPromise}. * @typedef asPromiseCallback * @type {function} * @param {Error|null} error Error, if any * @param {...*} params Additional arguments * @returns {undefined} */ /** * Returns a promise from a node-style callback function. * @memberof util * @param {asPromiseCallback} fn Function to call * @param {*} ctx Function context * @param {...*} params Function arguments * @returns {Promise<*>} Promisified function */ function asPromise(fn, ctx/*, varargs */) { var params = new Array(arguments.length - 1), offset = 0, index = 2, pending = true; while (index < arguments.length) params[offset++] = arguments[index++]; return new Promise(function executor(resolve, reject) { params[offset] = function callback(err/*, varargs */) { if (pending) { pending = false; if (err) reject(err); else { var params = new Array(arguments.length - 1), offset = 0; while (offset < params.length) params[offset++] = arguments[offset]; resolve.apply(null, params); } } }; try { fn.apply(ctx || null, params); } catch (err) { if (pending) { pending = false; reject(err); } } }); } return aspromise; } var base64 = {}; var hasRequiredBase64; function requireBase64 () { if (hasRequiredBase64) return base64; hasRequiredBase64 = 1; (function (exports) { /** * A minimal base64 implementation for number arrays. * @memberof util * @namespace */ var base64 = exports; /** * Calculates the byte length of a base64 encoded string. * @param {string} string Base64 encoded string * @returns {number} Byte length */ base64.length = function length(string) { var p = string.length; if (!p) return 0; var n = 0; while (--p % 4 > 1 && string.charAt(p) === "=") ++n; return Math.ceil(string.length * 3) / 4 - n; }; // Base64 encoding table var b64 = new Array(64); // Base64 decoding table var s64 = new Array(123); // 65..90, 97..122, 48..57, 43, 47 for (var i = 0; i < 64;) s64[b64[i] = i < 26 ? i + 65 : i < 52 ? i + 71 : i < 62 ? i - 4 : i - 59 | 43] = i++; /** * Encodes a buffer to a base64 encoded string. * @param {Uint8Array} buffer Source buffer * @param {number} start Source start * @param {number} end Source end * @returns {string} Base64 encoded string */ base64.encode = function encode(buffer, start, end) { var parts = null, chunk = []; var i = 0, // output index j = 0, // goto index t; // temporary while (start < end) { var b = buffer[start++]; switch (j) { case 0: chunk[i++] = b64[b >> 2]; t = (b & 3) << 4; j = 1; break; case 1: chunk[i++] = b64[t | b >> 4]; t = (b & 15) << 2; j = 2; break; case 2: chunk[i++] = b64[t | b >> 6]; chunk[i++] = b64[b & 63]; j = 0; break; } if (i > 8191) { (parts || (parts = [])).push(String.fromCharCode.apply(String, chunk)); i = 0; } } if (j) { chunk[i++] = b64[t]; chunk[i++] = 61; if (j === 1) chunk[i++] = 61; } if (parts) { if (i) parts.push(String.fromCharCode.apply(String, chunk.slice(0, i))); return parts.join(""); } return String.fromCharCode.apply(String, chunk.slice(0, i)); }; var invalidEncoding = "invalid encoding"; /** * Decodes a base64 encoded string to a buffer. * @param {string} string Source string * @param {Uint8Array} buffer Destination buffer * @param {number} offset Destination offset * @returns {number} Number of bytes written * @throws {Error} If encoding is invalid */ base64.decode = function decode(string, buffer, offset) { var start = offset; var j = 0, // goto index t; // temporary for (var i = 0; i < string.length;) { var c = string.charCodeAt(i++); if (c === 61 && j > 1) break; if ((c = s64[c]) === undefined) throw Error(invalidEncoding); switch (j) { case 0: t = c; j = 1; break; case 1: buffer[offset++] = t << 2 | (c & 48) >> 4; t = c; j = 2; break; case 2: buffer[offset++] = (t & 15) << 4 | (c & 60) >> 2; t = c; j = 3; break; case 3: buffer[offset++] = (t & 3) << 6 | c; j = 0; break; } } if (j === 1) throw Error(invalidEncoding); return offset - start; }; /** * Tests if the specified string appears to be base64 encoded. * @param {string} string String to test * @returns {boolean} `true` if probably base64 encoded, otherwise false */ base64.test = function test(string) { return /^(?:[A-Za-z0-9+/]{4})*(?:[A-Za-z0-9+/]{2}==|[A-Za-z0-9+/]{3}=)?$/.test(string); }; } (base64)); return base64; } var eventemitter; var hasRequiredEventemitter; function requireEventemitter () { if (hasRequiredEventemitter) return eventemitter; hasRequiredEventemitter = 1; eventemitter = EventEmitter; /** * Constructs a new event emitter instance. * @classdesc A minimal event emitter. * @memberof util * @constructor */ function EventEmitter() { /** * Registered listeners. * @type {Object.<string,*>} * @private */ this._listeners = {}; } /** * Registers an event listener. * @param {string} evt Event name * @param {function} fn Listener * @param {*} [ctx] Listener context * @returns {util.EventEmitter} `this` */ EventEmitter.prototype.on = function on(evt, fn, ctx) { (this._listeners[evt] || (this._listeners[evt] = [])).push({ fn : fn, ctx : ctx || this }); return this; }; /** * Removes an event listener or any matching listeners if arguments are omitted. * @param {string} [evt] Event name. Removes all listeners if omitted. * @param {function} [fn] Listener to remove. Removes all listeners of `evt` if omitted. * @returns {util.EventEmitter} `this` */ EventEmitter.prototype.off = function off(evt, fn) { if (evt === undefined) this._listeners = {}; else { if (fn === undefined) this._listeners[evt] = []; else { var listeners = this._listeners[evt]; for (var i = 0; i < listeners.length;) if (listeners[i].fn === fn) listeners.splice(i, 1); else ++i; } } return this; }; /** * Emits an event by calling its listeners with the specified arguments. * @param {string} evt Event name * @param {...*} args Arguments * @returns {util.EventEmitter} `this` */ EventEmitter.prototype.emit = function emit(evt) { var listeners = this._listeners[evt]; if (listeners) { var args = [], i = 1; for (; i < arguments.length;) args.push(arguments[i++]); for (i = 0; i < listeners.length;) listeners[i].fn.apply(listeners[i++].ctx, args); } return this; }; return eventemitter; } var float; var hasRequiredFloat; function requireFloat () { if (hasRequiredFloat) return float; hasRequiredFloat = 1; float = factory(factory); /** * Reads / writes floats / doubles from / to buffers. * @name util.float * @namespace */ /** * Writes a 32 bit float to a buffer using little endian byte order. * @name util.float.writeFloatLE * @function * @param {number} val Value to write * @param {Uint8Array} buf Target buffer * @param {number} pos Target buffer offset * @returns {undefined} */ /** * Writes a 32 bit float to a buffer using big endian byte order. * @name util.float.writeFloatBE * @function * @param {number} val Value to write * @param {Uint8Array} buf Target buffer * @param {number} pos Target buffer offset * @returns {undefined} */ /** * Reads a 32 bit float from a buffer using little endian byte order. * @name util.float.readFloatLE * @function * @param {Uint8Array} buf Source buffer * @param {number} pos Source buffer offset * @returns {number} Value read */ /** * Reads a 32 bit float from a buffer using big endian byte order. * @name util.float.readFloatBE * @function * @param {Uint8Array} buf Source buffer * @param {number} pos Source buffer offset * @returns {number} Value read */ /** * Writes a 64 bit double to a buffer using little endian byte order. * @name util.float.writeDoubleLE * @function * @param {number} val Value to write * @param {Uint8Array} buf Target buffer * @param {number} pos Target buffer offset * @returns {undefined} */ /** * Writes a 64 bit double to a buffer using big endian byte order. * @name util.float.writeDoubleBE * @function * @param {number} val Value to write * @param {Uint8Array} buf Target buffer * @param {number} pos Target buffer offset * @returns {undefined} */ /** * Reads a 64 bit double from a buffer using little endian byte order. * @name util.float.readDoubleLE * @function * @param {Uint8Array} buf Source buffer * @param {number} pos Source buffer offset * @returns {number} Value read */ /** * Reads a 64 bit double from a buffer using big endian byte order. * @name util.float.readDoubleBE * @function * @param {Uint8Array} buf Source buffer * @param {number} pos Source buffer offset * @returns {number} Value read */ // Factory function for the purpose of node-based testing in modified global environments function factory(exports) { // float: typed array if (typeof Float32Array !== "undefined") (function() { var f32 = new Float32Array([ -0 ]), f8b = new Uint8Array(f32.buffer), le = f8b[3] === 128; function writeFloat_f32_cpy(val, buf, pos) { f32[0] = val; buf[pos ] = f8b[0]; buf[pos + 1] = f8b[1]; buf[pos + 2] = f8b[2]; buf[pos + 3] = f8b[3]; } function writeFloat_f32_rev(val, buf, pos) { f32[0] = val; buf[pos ] = f8b[3]; buf[pos + 1] = f8b[2]; buf[pos + 2] = f8b[1]; buf[pos + 3] = f8b[0]; } /* istanbul ignore next */ exports.writeFloatLE = le ? writeFloat_f32_cpy : writeFloat_f32_rev; /* istanbul ignore next */ exports.writeFloatBE = le ? writeFloat_f32_rev : writeFloat_f32_cpy; function readFloat_f32_cpy(buf, pos) { f8b[0] = buf[pos ]; f8b[1] = buf[pos + 1]; f8b[2] = buf[pos + 2]; f8b[3] = buf[pos + 3]; return f32[0]; } function readFloat_f32_rev(buf, pos) { f8b[3] = buf[pos ]; f8b[2] = buf[pos + 1]; f8b[1] = buf[pos + 2]; f8b[0] = buf[pos + 3]; return f32[0]; } /* istanbul ignore next */ exports.readFloatLE = le ? readFloat_f32_cpy : readFloat_f32_rev; /* istanbul ignore next */ exports.readFloatBE = le ? readFloat_f32_rev : readFloat_f32_cpy; // float: ieee754 })(); else (function() { function writeFloat_ieee754(writeUint, val, buf, pos) { var sign = val < 0 ? 1 : 0; if (sign) val = -val; if (val === 0) writeUint(1 / val > 0 ? /* positive */ 0 : /* negative 0 */ 2147483648, buf, pos); else if (isNaN(val)) writeUint(2143289344, buf, pos); else if (val > 3.4028234663852886e+38) // +-Infinity writeUint((sign << 31 | 2139095040) >>> 0, buf, pos); else if (val < 1.1754943508222875e-38) // denormal writeUint((sign << 31 | Math.round(val / 1.401298464324817e-45)) >>> 0, buf, pos); else { var exponent = Math.floor(Math.log(val) / Math.LN2), mantissa = Math.round(val * Math.pow(2, -exponent) * 8388608) & 8388607; writeUint((sign << 31 | exponent + 127 << 23 | mantissa) >>> 0, buf, pos); } } exports.writeFloatLE = writeFloat_ieee754.bind(null, writeUintLE); exports.writeFloatBE = writeFloat_ieee754.bind(null, writeUintBE); function readFloat_ieee754(readUint, buf, pos) { var uint = readUint(buf, pos), sign = (uint >> 31) * 2 + 1, exponent = uint >>> 23 & 255, mantissa = uint & 8388607; return exponent === 255 ? mantissa ? NaN : sign * Infinity : exponent === 0 // denormal ? sign * 1.401298464324817e-45 * mantissa : sign * Math.pow(2, exponent - 150) * (mantissa + 8388608); } exports.readFloatLE = readFloat_ieee754.bind(null, readUintLE); exports.readFloatBE = readFloat_ieee754.bind(null, readUintBE); })(); // double: typed array if (typeof Float64Array !== "undefined") (function() { var f64 = new Float64Array([-0]), f8b = new Uint8Array(f64.buffer), le = f8b[7] === 128; function writeDouble_f64_cpy(val, buf, pos) { f64[0] = val; buf[pos ] = f8b[0]; buf[pos + 1] = f8b[1]; buf[pos + 2] = f8b[2]; buf[pos + 3] = f8b[3]; buf[pos + 4] = f8b[4]; buf[pos + 5] = f8b[5]; buf[pos + 6] = f8b[6]; buf[pos + 7] = f8b[7]; } function writeDouble_f64_rev(val, buf, pos) { f64[0] = val; buf[pos ] = f8b[7]; buf[pos + 1] = f8b[6]; buf[pos + 2] = f8b[5]; buf[pos + 3] = f8b[4]; buf[pos + 4] = f8b[3]; buf[pos + 5] = f8b[2]; buf[pos + 6] = f8b[1]; buf[pos + 7] = f8b[0]; } /* istanbul ignore next */ exports.writeDoubleLE = le ? writeDouble_f64_cpy : writeDouble_f64_rev; /* istanbul ignore next */ exports.writeDoubleBE = le ? writeDouble_f64_rev : writeDouble_f64_cpy; function readDouble_f64_cpy(buf, pos) { f8b[0] = buf[pos ]; f8b[1] = buf[pos + 1]; f8b[2] = buf[pos + 2]; f8b[3] = buf[pos + 3]; f8b[4] = buf[pos + 4]; f8b[5] = buf[pos + 5]; f8b[6] = buf[pos + 6]; f8b[7] = buf[pos + 7]; return f64[0]; } function readDouble_f64_rev(buf, pos) { f8b[7] = buf[pos ]; f8b[6] = buf[pos + 1]; f8b[5] = buf[pos + 2]; f8b[4] = buf[pos + 3]; f8b[3] = buf[pos + 4]; f8b[2] = buf[pos + 5]; f8b[1] = buf[pos + 6]; f8b[0] = buf[pos + 7]; return f64[0]; } /* istanbul ignore next */ exports.readDoubleLE = le ? readDouble_f64_cpy : readDouble_f64_rev; /* istanbul ignore next */ exports.readDoubleBE = le ? readDouble_f64_rev : readDouble_f64_cpy; // double: ieee754 })(); else (function() { function writeDouble_ieee754(writeUint, off0, off1, val, buf, pos) { var sign = val < 0 ? 1 : 0; if (sign) val = -val; if (val === 0) { writeUint(0, buf, pos + off0); writeUint(1 / val > 0 ? /* positive */ 0 : /* negative 0 */ 2147483648, buf, pos + off1); } else if (isNaN(val)) { writeUint(0, buf, pos + off0); writeUint(2146959360, buf, pos + off1); } else if (val > 1.7976931348623157e+308) { // +-Infinity writeUint(0, buf, pos + off0); writeUint((sign << 31 | 2146435072) >>> 0, buf, pos + off1); } else { var mantissa; if (val < 2.2250738585072014e-308) { // denormal mantissa = val / 5e-324; writeUint(mantissa >>> 0, buf, pos + off0); writeUint((sign << 31 | mantissa / 4294967296) >>> 0, buf, pos + off1); } else { var exponent = Math.floor(Math.log(val) / Math.LN2); if (exponent === 1024) exponent = 1023; mantissa = val * Math.pow(2, -exponent); writeUint(mantissa * 4503599627370496 >>> 0, buf, pos + off0); writeUint((sign << 31 | exponent + 1023 << 20 | mantissa * 1048576 & 1048575) >>> 0, buf, pos + off1); } } } exports.writeDoubleLE = writeDouble_ieee754.bind(null, writeUintLE, 0, 4); exports.writeDoubleBE = writeDouble_ieee754.bind(null, writeUintBE, 4, 0); function readDouble_ieee754(readUint, off0, off1, buf, pos) { var lo = readUint(buf, pos + off0), hi = readUint(buf, pos + off1); var sign = (hi >> 31) * 2 + 1, exponent = hi >>> 20 & 2047, mantissa = 4294967296 * (hi & 1048575) + lo; return exponent === 2047 ? mantissa ? NaN : sign * Infinity : exponent === 0 // denormal ? sign * 5e-324 * mantissa : sign * Math.pow(2, exponent - 1075) * (mantissa + 4503599627370496); } exports.readDoubleLE = readDouble_ieee754.bind(null, readUintLE, 0, 4); exports.readDoubleBE = readDouble_ieee754.bind(null, readUintBE, 4, 0); })(); return exports; } // uint helpers function writeUintLE(val, buf, pos) { buf[pos ] = val & 255; buf[pos + 1] = val >>> 8 & 255; buf[pos + 2] = val >>> 16 & 255; buf[pos + 3] = val >>> 24; } function writeUintBE(val, buf, pos) { buf[pos ] = val >>> 24; buf[pos + 1] = val >>> 16 & 255; buf[pos + 2] = val >>> 8 & 255; buf[pos + 3] = val & 255; } function readUintLE(buf, pos) { return (buf[pos ] | buf[pos + 1] << 8 | buf[pos + 2] << 16 | buf[pos + 3] << 24) >>> 0; } function readUintBE(buf, pos) { return (buf[pos ] << 24 | buf[pos + 1] << 16 | buf[pos + 2] << 8 | buf[pos + 3]) >>> 0; } return float; } var inquire_1; var hasRequiredInquire; function requireInquire () { if (hasRequiredInquire) return inquire_1; hasRequiredInquire = 1; inquire_1 = inquire; /** * Requires a module only if available. * @memberof util * @param {string} moduleName Module to require * @returns {?Object} Required module if available and not empty, otherwise `null` */ function inquire(moduleName) { try { var mod = eval("quire".replace(/^/,"re"))(moduleName); // eslint-disable-line no-eval if (mod && (mod.length || Object.keys(mod).length)) return mod; } catch (e) {} // eslint-disable-line no-empty return null; } return inquire_1; } var utf8 = {}; var hasRequiredUtf8; function requireUtf8 () { if (hasRequiredUtf8) return utf8; hasRequiredUtf8 = 1; (function (exports) { /** * A minimal UTF8 implementation for number arrays. * @memberof util * @namespace */ var utf8 = exports; /** * Calculates the UTF8 byte length of a string. * @param {string} string String * @returns {number} Byte length */ utf8.length = function utf8_length(string) { var len = 0, c = 0; for (var i = 0; i < string.length; ++i) { c = string.charCodeAt(i); if (c < 128) len += 1; else if (c < 2048) len += 2; else if ((c & 0xFC00) === 0xD800 && (string.charCodeAt(i + 1) & 0xFC00) === 0xDC00) { ++i; len += 4; } else len += 3; } return len; }; /** * Reads UTF8 bytes as a string. * @param {Uint8Array} buffer Source buffer * @param {number} start Source start * @param {number} end Source end * @returns {string} String read */ utf8.read = function utf8_read(buffer, start, end) { var len = end - start; if (len < 1) return ""; var parts = null, chunk = [], i = 0, // char offset t; // temporary while (start < end) { t = buffer[start++]; if (t < 128) chunk[i++] = t; else if (t > 191 && t < 224) chunk[i++] = (t & 31) << 6 | buffer[start++] & 63; else if (t > 239 && t < 365) { t = ((t & 7) << 18 | (buffer[start++] & 63) << 12 | (buffer[start++] & 63) << 6 | buffer[start++] & 63) - 0x10000; chunk[i++] = 0xD800 + (t >> 10); chunk[i++] = 0xDC00 + (t & 1023); } else chunk[i++] = (t & 15) << 12 | (buffer[start++] & 63) << 6 | buffer[start++] & 63; if (i > 8191) { (parts || (parts = [])).push(String.fromCharCode.apply(String, chunk)); i = 0; } } if (parts) { if (i) parts.push(String.fromCharCode.apply(String, chunk.slice(0, i))); return parts.join(""); } return String.fromCharCode.apply(String, chunk.slice(0, i)); }; /** * Writes a string as UTF8 bytes. * @param {string} string Source string * @param {Uint8Array} buffer Destination buffer * @param {number} offset Destination offset * @returns {number} Bytes written */ utf8.write = function utf8_write(string, buffer, offset) { var start = offset, c1, // character 1 c2; // character 2 for (var i = 0; i < string.length; ++i) { c1 = string.charCodeAt(i); if (c1 < 128) { buffer[offset++] = c1; } else if (c1 < 2048) { buffer[offset++] = c1 >> 6 | 192; buffer[offset++] = c1 & 63 | 128; } else if ((c1 & 0xFC00) === 0xD800 && ((c2 = string.charCodeAt(i + 1)) & 0xFC00) === 0xDC00) { c1 = 0x10000 + ((c1 & 0x03FF) << 10) + (c2 & 0x03FF); ++i; buffer[offset++] = c1 >> 18 | 240; buffer[offset++] = c1 >> 12 & 63 | 128; buffer[offset++] = c1 >> 6 & 63 | 128; buffer[offset++] = c1 & 63 | 128; } else { buffer[offset++] = c1 >> 12 | 224; buffer[offset++] = c1 >> 6 & 63 | 128; buffer[offset++] = c1 & 63 | 128; } } return offset - start; }; } (utf8)); return utf8; } var pool_1; var hasRequiredPool; function requirePool () { if (hasRequiredPool) return pool_1; hasRequiredPool = 1; pool_1 = pool; /** * An allocator as used by {@link util.pool}. * @typedef PoolAllocator * @type {function} * @param {number} size Buffer size * @returns {Uint8Array} Buffer */ /** * A slicer as used by {@link util.pool}. * @typedef PoolSlicer * @type {function} * @param {number} start Start offset * @param {number} end End offset * @returns {Uint8Array} Buffer slice * @this {Uint8Array} */ /** * A general purpose buffer pool. * @memberof util * @function * @param {PoolAllocator} alloc Allocator * @param {PoolSlicer} slice Slicer * @param {number} [size=8192] Slab size * @returns {PoolAllocator} Pooled allocator */ function pool(alloc, slice, size) { var SIZE = size || 8192; var MAX = SIZE >>> 1; var slab = null; var offset = SIZE; return function pool_alloc(size) { if (size < 1 || size > MAX) return alloc(size); if (offset + size > SIZE) { slab = alloc(SIZE); offset = 0; } var buf = slice.call(slab, offset, offset += size); if (offset & 7) // align to 32 bit offset = (offset | 7) + 1; return buf; }; } return pool_1; } var longbits; var hasRequiredLongbits; function requireLongbits () { if (hasRequiredLongbits) return longbits; hasRequiredLongbits = 1; longbits = LongBits; var util = requireMinimal$1(); /** * Constructs new long bits. * @classdesc Helper class for working with the low and high bits of a 64 bit value. * @memberof util * @constructor * @param {number} lo Low 32 bits, unsigned * @param {number} hi High 32 bits, unsigned */ function LongBits(lo, hi) { // note that the casts below are theoretically unnecessary as of today, but older statically // generated converter code might still call the ctor with signed 32bits. kept for compat. /** * Low bits. * @type {number} */ this.lo = lo >>> 0; /** * High bits. * @type {number} */ this.hi = hi >>> 0; } /** * Zero bits. * @memberof util.LongBits * @type {util.LongBits} */ var zero = LongBits.zero = new LongBits(0, 0); zero.toNumber = function() { return 0; }; zero.zzEncode = zero.zzDecode = function() { return this; }; zero.length = function() { return 1; }; /** * Zero hash. * @memberof util.LongBits * @type {string} */ var zeroHash = LongBits.zeroHash = "\0\0\0\0\0\0\0\0"; /** * Constructs new long bits from the specified number. * @param {number} value Value * @returns {util.LongBits} Instance */ LongBits.fromNumber = function fromNumber(value) { if (value === 0) return zero; var sign = value < 0; if (sign) value = -value; var lo = value >>> 0, hi = (value - lo) / 4294967296 >>> 0; if (sign) { hi = ~hi >>> 0; lo = ~lo >>> 0; if (++lo > 4294967295) { lo = 0; if (++hi > 4294967295) hi = 0; } } return new LongBits(lo, hi); }; /** * Constructs new long bits from a number, long or string. * @param {Long|number|string} value Value * @returns {util.LongBits} Instance */ LongBits.from = function from(value) { if (typeof value === "number") return LongBits.fromNumber(value); if (util.isString(value)) { /* istanbul ignore else */ if (util.Long) value = util.Long.fromString(value); else return LongBits.fromNumber(parseInt(value, 10)); } return value.low || value.high ? new LongBits(value.low >>> 0, value.high >>> 0) : zero; }; /** * Converts this long bits to a possibly unsafe JavaScript number. * @param {boolean} [unsigned=false] Whether unsigned or not * @returns {number} Possibly unsafe number */ LongBits.prototype.toNumber = function toNumber(unsigned) { if (!unsigned && this.hi >>> 31) { var lo = ~this.lo + 1 >>> 0, hi = ~this.hi >>> 0; if (!lo) hi = hi + 1 >>> 0; return -(lo + hi * 4294967296); } return this.lo + this.hi * 4294967296; }; /** * Converts this long bits to a long. * @param {boolean} [unsigned=false] Whether unsigned or not * @returns {Long} Long */ LongBits.prototype.toLong = function toLong(unsigned) { return util.Long ? new util.Long(this.lo | 0, this.hi | 0, Boolean(unsigned)) /* istanbul ignore next */ : { low: this.lo | 0, high: this.hi | 0, unsigned: Boolean(unsigned) }; }; var charCodeAt = String.prototype.charCodeAt; /** * Constructs new long bits from the specified 8 characters long hash. * @param {string} hash Hash * @returns {util.LongBits} Bits */ LongBits.fromHash = function fromHash(hash) { if (hash === zeroHash) return zero; return new LongBits( ( charCodeAt.call(hash, 0) | charCodeAt.call(hash, 1) << 8 | charCodeAt.call(hash, 2) << 16 | charCodeAt.call(hash, 3) << 24) >>> 0 , ( charCodeAt.call(hash, 4) | charCodeAt.call(hash, 5) << 8 | charCodeAt.call(hash, 6) << 16 | charCodeAt.call(hash, 7) << 24) >>> 0 ); }; /** * Converts this long bits to a 8 characters long hash. * @returns {string} Hash */ LongBits.prototype.toHash = function toHash() { return String.fromCharCode( this.lo & 255, this.lo >>> 8 & 255, this.lo >>> 16 & 255, this.lo >>> 24 , this.hi & 255, this.hi >>> 8 & 255, this.hi >>> 16 & 255, this.hi >>> 24 ); }; /** * Zig-zag encodes this long bits. * @returns {util.LongBits} `this` */ LongBits.prototype.zzEncode = function zzEncode() { var mask = this.hi >> 31; this.hi = ((this.hi << 1 | this.lo >>> 31) ^ mask) >>> 0; this.lo = ( this.lo << 1 ^ mask) >>> 0; return this; }; /** * Zig-zag decodes this long bits. * @returns {util.LongBits} `this` */ LongBits.prototype.zzDecode = function zzDecode() { var mask = -(this.lo & 1); this.lo = ((this.lo >>> 1 | this.hi << 31) ^ mask) >>> 0; this.hi = ( this.hi >>> 1 ^ mask) >>> 0; return this; }; /** * Calculates the length of this longbits when encoded as a varint. * @returns {number} Length */ LongBits.prototype.length = function length() { var part0 = this.lo, part1 = (this.lo >>> 28 | this.hi << 4) >>> 0, part2 = this.hi >>> 24; return part2 === 0 ? part1 === 0 ? part0 < 16384 ? part0 < 128 ? 1 : 2 : part0 < 2097152 ? 3 : 4 : part1 < 16384 ? part1 < 128 ? 5 : 6 : part1 < 2097152 ? 7 : 8 : part2 < 128 ? 9 : 10; }; return longbits; } var hasRequiredMinimal$1; function requireMinimal$1 () { if (hasRequiredMinimal$1) return minimal$1; hasRequiredMinimal$1 = 1; (function (exports) { var util = exports; // used to return a Promise where callback is omitted util.asPromise = requireAspromise(); // converts to / from base64 encoded strings util.base64 = requireBase64(); // base class of rpc.Service util.EventEmitter = requireEventemitter(); // float handling accross browsers util.float = requireFloat(); // requires modules optionally and hides the call from bundlers util.inquire = requireInquire(); // converts to / from utf8 encoded strings util.utf8 = requireUtf8(); // provides a node-like buffer pool in the browser util.pool = requirePool(); // utility to work with the low and high bits of a 64 bit value util.LongBits = requireLongbits(); /** * Whether running within node or not. * @memberof util * @type {boolean} */ util.isNode = Boolean(typeof commonjsGlobal !== "undefined" && commonjsGlobal && commonjsGlobal.process && commonjsGlobal.process.versions && commonjsGlobal.process.versions.node); /** * Global object reference. * @memberof util * @type {Object} */ util.global = util.isNode && commonjsGlobal || typeof window !== "undefined" && window || typeof self !== "undefined" && self || commonjsGlobal; // eslint-disable-line no-invalid-this /** * An immuable empty array. * @memberof util * @type {Array.<*>} * @const */ util.emptyArray = Object.freeze ? Object.freeze([]) : /* istanbul ignore next */ []; // used on prototypes /** * An immutable empty object. * @type {Object} * @const */ util.emptyObject = Object.freeze ? Object.freeze({}) : /* istanbul ignore next */ {}; // used on prototypes /** * Tests if the specified value is an integer. * @function * @param {*} value Value to test * @returns {boolean} `true` if the value is an integer */ util.isInteger = Number.isInteger || /* istanbul ignore next */ function isInteger(value) { return typeof value === "number" && isFinite(value) && Math.floor(value) === value; }; /** * Tests if the specified value is a string. * @param {*} value Value to test * @returns {boolean} `true` if the value is a string */ util.isString = function isString(value) { return typeof value === "string" || value instanceof String; }; /** * Tests if the specified value is a non-null object. * @param {*} value Value to test * @returns {boolean} `true` if the value is a non-null object */ util.isObject = function isObject(value) { return value && typeof value === "object"; }; /** * Checks if a property on a message is considered to be present. * This is an alias of {@link util.isSet}. * @function * @param {Object} obj Plain object or message instance * @param {string} prop Property name * @returns {boolean} `true` if considered to be present, otherwise `false` */ util.isset = /** * Checks if a property on a message is considered to be present. * @param {Object} obj Plain object or message instance * @param {string} prop Property name * @returns {boolean} `true` if considered to be present, otherwise `false` */ util.isSet = function isSet(obj, prop) { var value = obj[prop]; if (value != null && obj.hasOwnProperty(prop)) // eslint-disable-line eqeqeq, no-prototype-builtins return typeof value !== "object" || (Array.isArray(value) ? value.length : Object.keys(value).length) > 0; return false; }; /** * Any compatible Buffer instance. * This is a minimal stand-alone definition of a Buffer instance. The actual type is that exported by node's typings. * @interface Buffer * @extends Uint8Array */ /** * Node's Buffer class if available. * @type {Constructor<Buffer>} */ util.Buffer = (function() { try { var Buffer = util.inquire("buffer").Buffer; // refuse to use non-node buffers if not explicitly assigned (perf reasons): return Buffer.prototype.utf8Write ? Buffer : /* istanbul ignore next */ null; } catch (e) { /* istanbul ignore next */ return null; } })(); // Internal alias of or polyfull for Buffer.from. util._Buffer_from = null; // Internal alias of or polyfill for Buffer.allocUnsafe. util._Buffer_allocUnsafe = null; /** * Creates a new buffer of whatever type supported by the environment. * @param {number|number[]} [sizeOrArray=0] Buffer size or number array * @returns {Uint8Array|Buffer} Buffer */ util.newBuffer = function newBuffer(sizeOrArray) { /* istanbul ignore next */ return typeof sizeOrArray === "number" ? util.Buffer ? util._Buffer_allocUnsafe(sizeOrArray) : new util.Array(sizeOrArray) : util.Buffer ? util._Buffer_from(sizeOrArray) : typeof Uint8Array === "undefined" ? sizeOrArray : new Uint8Array(sizeOrArray); }; /** * Array implementation used in the browser. `Uint8Array` if supported, otherwise `Array`. * @type {Constructor<Uint8Array>} */ util.Array = typeof Uint8Array !== "undefined" ? Uint8Array /* istanbul ignore next */ : Array; /** * Any compatible Long instance. * This is a minimal stand-alone definition of a Long instance. The actual type is that exported by long.js. * @interface Long * @property {number} low Low bits * @property {number} high High bits * @property {boolean} unsigned Whether unsigned or not */ /** * Long.js's Long class if available. * @type {Constructor<Long>} */ util.Long = /* istanbul ignore next */ util.global.dcodeIO && /* istanbul ignore next */ util.global.dcodeIO.Long || /* istanbul ignore next */ util.global.Long || util.inquire("long"); /** * Regular expression used to verify 2 bit (`bool`) map keys. * @type {RegExp} * @const */ util.key2Re = /^true|false|0|1$/; /** * Regular expression used to verify 32 bit (`int32` etc.) map keys. * @type {RegExp} * @const */ util.key32Re = /^-?(?:0|[1-9][0-9]*)$/; /** * Regular expression used to verify 64 bit (`int64` etc.) map keys. * @type {RegExp} * @const */ util.key64Re = /^(?:[\\x00-\\xff]{8}|-?(?:0|[1-9][0-9]*))$/; /** * Converts a number or long to an 8 characters long hash string. * @param {Long|number} value Value to convert * @returns {string} Hash */ util.longToHash = function longToHash(value) { return value ? util.LongBits.from(value).toHash() : util.LongBits.zeroHash; }; /** * Converts an 8 characters long hash string to a long or number. * @param {string} hash Hash * @param {boolean} [unsigned=false] Whether unsigned or not * @returns {Long|number} Original value */ util.longFromHash = function longFromHash(hash, unsigned) { var bits = util.LongBits.fromHash(hash); if (util.Long) return util.Long.fromBits(bits.lo, bits.hi, unsigned); return bits.toNumber(Boolean(unsigned)); }; /** * Merges the properties of the source object into the destination object. * @memberof util * @param {Object.<string,*>} dst Destination object * @param {Object.<string,*>} src Source object * @param {boolean} [ifNotSet=false] Merges only if the key is not already set * @returns {Object.<string,*>} Destination object */ function merge(dst, src, ifNotSet) { // used by converters for (var keys = Object.keys(src), i = 0; i < keys.length; ++i) if (dst[keys[i]] === undefined || !ifNotSet) dst[keys[i]] = src[keys[i]]; return dst; } util.merge = merge; /** * Converts the first character of a string to lower case. * @param {string} str String to convert * @returns {string} Converted string */ util.lcFirst = function lcFirst(str) { return str.charAt(0).toLowerCase() + str.substring(1); }; /** * Creates a custom error constructor. * @memberof util * @param {string} name Error name * @returns {Constructor<Error>} Custom error constructor */ function newError(name) { function CustomError(message, properties) { if (!(this instanceof CustomError)) return new CustomError(message, properties); // Error.call(this, message); // ^ just returns a new error instance because the ctor can be called as a function Object.defineProperty(this, "message", { get: function() { return message; } }); /* istanbul ignore next */ if (Error.captureStackTrace) // node Error.captureStackTrace(this, CustomError); else Object.defineProperty(this, "stack", { value: new Error().stack || "" }); if (properties) merge(this, properties); } CustomError.prototype = Object.create(Error.prototype, { constructor: { value: CustomError, writable: true, enumerable: false, configurable: true, }, name: { get: function get() { return name; }, set: undefined, enumerable: false, // configurable: false would accurately preserve the behavior of // the original, but I'm guessing that was not intentional. // For an actual error subclass, this property would // be configurable. configurable: true, }, toString: { value: function value() { return this.name + ": " + this.message; }, writable: true, enumerable: false, configurable: true, }, }); return CustomError; } util.newError = newError; /** * Constructs a new protocol error. * @classdesc Error subclass indicating a protocol specifc error. * @memberof util * @extends Error * @template T extends Message<T> * @constructor * @param {string} message Error message * @param {Object.<string,*>} [properties] Additional properties * @example * try { * MyMessage.decode(someBuffer); // throws if required fields are missing * } catch (e) { * if (e instanceof ProtocolError && e.instance) * console.log("decoded so far: " + JSON.stringify(e.instance)); * } */ util.ProtocolError = newError("ProtocolError"); /** * So far decoded message instance. * @name util.ProtocolError#instance * @type {Message<T>} */ /** * A OneOf getter as returned by {@link util.oneOfGetter}. * @typedef OneOfGetter * @type {function} * @returns {string|undefined} Set field name, if any */ /** * Builds a getter for a oneof's present field name. * @param {string[]} fieldNames Field names * @returns {OneOfGetter} Unbound getter */ util.oneOfGetter = function getOneOf(fieldNames) { var fieldMap = {}; for (var i = 0; i < fieldNames.length; ++i) fieldMap[fieldNames[i]] = 1; /** * @returns {string|undefined} Set field name, if any * @this Object * @ignore */ return function() { // eslint-disable-line consistent-return for (var keys = Object.keys(this), i = keys.length - 1; i > -1; --i) if (fieldMap[keys[i]] === 1 && this[keys[i]] !== undefined && this[keys[i]] !== null) return keys[i]; }; }; /** * A OneOf setter as returned by {@link util.oneOfSetter}. * @typedef OneOfSetter * @type {function} * @param {string|undefined} value Field name * @returns {undefined} */ /** * Builds a setter for a oneof's present field name. * @param {string[]} fieldNames Field names * @returns {OneOfSetter} Unbound setter */ util.oneOfSetter = function setOneOf(fieldNames) { /** * @param {string} name Field name * @returns {undefined} * @this Object * @ignore */ return function(name) { for (var i = 0; i < fieldNames.length; ++i) if (fieldNames[i] !== name) delete this[fieldNames[i]]; }; }; /** * Default conversion options used for {@link Message#toJSON} implementations. * * These options are close to proto3's JSON mapping with the exception that internal types like Any are handled just like messages. More precisely: * * - Longs become strings * - Enums become string keys * - Bytes become base64 encoded strings * - (Sub-)Messages become plain objects * - Maps become plain objects with all string keys * - Repeated fields become arrays * - NaN and Infinity for float and double fields become strings * * @type {IConversionOptions} * @see https://developers.google.com/protocol-buffers/docs/proto3?hl=en#json */ util.toJSONOptions = { longs: String, enums: String, bytes: String, json: true }; // Sets up buffer utility according to the environment (called in index-minimal) util._configure = function() { var Buffer = util.Buffer; /* istanbul ignore if */ if (!Buffer) { util._Buffer_from = util._Buffer_allocUnsafe = null; return; } // because node 4.x buffers are incompatible & immutable // see: https://github.com/dcodeIO/protobuf.js/pull/665 util._Buffer_from = Buffer.from !== Uint8Array.from && Buffer.from || /* istanbul ignore next */ function Buffer_from(value, encoding) { return new Buffer(value, encoding); }; util._Buffer_allocUnsafe = Buffer.allocUnsafe || /* istanbul ignore next */ function Buffer_allocUnsafe(size) { return new Buffer(size); }; }; } (minimal$1)); return minimal$1; } var writer; var hasRequiredWriter; function requireWriter () { if (hasRequiredWriter) return writer; hasRequiredWriter = 1; writer = Writer; var util = requireMinimal$1(); var BufferWriter; // cyclic var LongBits = util.LongBits, base64 = util.base64, utf8 = util.utf8; /** * Constructs a new writer operation instance. * @classdesc Scheduled writer operation. * @constructor * @param {function(*, Uint8Array, number)} fn Function to call * @param {number} len Value byte length * @param {*} val Value to write * @ignore */ function Op(fn, len, val) { /** * Function to call. * @type {function(Uint8Array, number, *)} */ this.fn = fn; /** * Value byte length. * @type {number} */ this.len = len; /** * Next operation. * @type {Writer.Op|undefined} */ this.next = undefined; /** * Value to write. * @type {*} */ this.val = val; // type varies } /* istanbul ignore next */ function noop() {} // eslint-disable-line no-empty-function /** * Constructs a new writer state instance. * @classdesc Copied writer state. * @memberof Writer * @constructor * @param {Writer} writer Writer to copy state from * @ignore */ function State(writer) { /** * Current head. * @type {Writer.Op} */ this.head = writer.head; /** * Current tail. * @type {Writer.Op} */ this.tail = writer.tail; /** * Current buffer length. * @type {number} */ this.len = writer.len; /** * Next state. * @type {State|null} */ this.next = writer.states; } /** * Constructs a new writer instance. * @classdesc Wire format writer using `Uint8Array` if available, otherwise `Array`. * @constructor */ function Writer() { /** * Current length. * @type {number} */ this.len = 0; /** * Operations head. * @type {Object} */ this.head = new Op(noop, 0, 0); /** * Operations tail * @type {Object} */ this.tail = this.head; /** * Linked forked states. * @type {Object|null} */ this.states = null; // When a value is written, the writer calculates its byte length and puts it into a linked // list of operations to perform when finish() is called. This both allows us to allocate // buffers of the exact required size and reduces the amount of work we have to do compared // to first calculating over objects and then encoding over objects. In our case, the encoding // part is just a linked list walk calling operations with already prepared values. } var create = function create() { return util.Buffer ? function create_buffer_setup() { return (Writer.create = function create_buffer() { return new BufferWriter(); })(); } /* istanbul ignore next */ : function create_array() { return new Writer(); }; }; /** * Creates a new writer. * @function * @ret