"use strict"; import { Block, BlockTag, BlockWithTransactions, EventType, Filter, FilterByBlockHash, ForkEvent, Listener, Log, Provider, TransactionReceipt, TransactionRequest, TransactionResponse } from "@ethersproject/abstract-provider"; import { Base58 } from "@ethersproject/basex"; import { BigNumber, BigNumberish } from "@ethersproject/bignumber"; import { arrayify, BytesLike, concat, hexConcat, hexDataLength, hexDataSlice, hexlify, hexValue, hexZeroPad, isHexString } from "@ethersproject/bytes"; import { HashZero } from "@ethersproject/constants"; import { dnsEncode, namehash } from "@ethersproject/hash"; import { getNetwork, Network, Networkish } from "@ethersproject/networks"; import { Deferrable, defineReadOnly, getStatic, resolveProperties } from "@ethersproject/properties"; import { Transaction } from "@ethersproject/transactions"; import { sha256 } from "@ethersproject/sha2"; import { toUtf8Bytes, toUtf8String } from "@ethersproject/strings"; import { fetchJson, poll } from "@ethersproject/web"; import bech32 from "bech32"; import { Logger } from "@ethersproject/logger"; import { version } from "./_version"; const logger = new Logger(version); import { Formatter } from "./formatter"; const MAX_CCIP_REDIRECTS = 10; ////////////////////////////// // Event Serializeing function checkTopic(topic: string): string { if (topic == null) { return "null"; } if (hexDataLength(topic) !== 32) { logger.throwArgumentError("invalid topic", "topic", topic); } return topic.toLowerCase(); } function serializeTopics(topics: Array>): string { // Remove trailing null AND-topics; they are redundant topics = topics.slice(); while (topics.length > 0 && topics[topics.length - 1] == null) { topics.pop(); } return topics.map((topic) => { if (Array.isArray(topic)) { // Only track unique OR-topics const unique: { [ topic: string ]: boolean } = { } topic.forEach((topic) => { unique[checkTopic(topic)] = true; }); // The order of OR-topics does not matter const sorted = Object.keys(unique); sorted.sort(); return sorted.join("|"); } else { return checkTopic(topic); } }).join("&"); } function deserializeTopics(data: string): Array> { if (data === "") { return [ ]; } return data.split(/&/g).map((topic) => { if (topic === "") { return [ ]; } const comps = topic.split("|").map((topic) => { return ((topic === "null") ? null: topic); }); return ((comps.length === 1) ? comps[0]: comps); }); } function getEventTag(eventName: EventType): string { if (typeof(eventName) === "string") { eventName = eventName.toLowerCase(); if (hexDataLength(eventName) === 32) { return "tx:" + eventName; } if (eventName.indexOf(":") === -1) { return eventName; } } else if (Array.isArray(eventName)) { return "filter:*:" + serializeTopics(eventName); } else if (ForkEvent.isForkEvent(eventName)) { logger.warn("not implemented"); throw new Error("not implemented"); } else if (eventName && typeof(eventName) === "object") { return "filter:" + (eventName.address || "*") + ":" + serializeTopics(eventName.topics || []); } throw new Error("invalid event - " + eventName); } ////////////////////////////// // Helper Object function getTime() { return (new Date()).getTime(); } function stall(duration: number): Promise { return new Promise((resolve) => { setTimeout(resolve, duration); }); } ////////////////////////////// // Provider Object /** * EventType * - "block" * - "poll" * - "didPoll" * - "pending" * - "error" * - "network" * - filter * - topics array * - transaction hash */ const PollableEvents = [ "block", "network", "pending", "poll" ]; export class Event { readonly listener: Listener; readonly once: boolean; readonly tag: string; _lastBlockNumber: number _inflight: boolean; constructor(tag: string, listener: Listener, once: boolean) { defineReadOnly(this, "tag", tag); defineReadOnly(this, "listener", listener); defineReadOnly(this, "once", once); this._lastBlockNumber = -2; this._inflight = false; } get event(): EventType { switch (this.type) { case "tx": return this.hash; case "filter": return this.filter; } return this.tag; } get type(): string { return this.tag.split(":")[0] } get hash(): string { const comps = this.tag.split(":"); if (comps[0] !== "tx") { return null; } return comps[1]; } get filter(): Filter { const comps = this.tag.split(":"); if (comps[0] !== "filter") { return null; } const address = comps[1]; const topics = deserializeTopics(comps[2]); const filter: Filter = { }; if (topics.length > 0) { filter.topics = topics; } if (address && address !== "*") { filter.address = address; } return filter; } pollable(): boolean { return (this.tag.indexOf(":") >= 0 || PollableEvents.indexOf(this.tag) >= 0); } } export interface EnsResolver { // Name this Resolver is associated with readonly name: string; // The address of the resolver readonly address: string; // Multichain address resolution (also normal address resolution) // See: https://eips.ethereum.org/EIPS/eip-2304 getAddress(coinType?: 60): Promise // Contenthash field // See: https://eips.ethereum.org/EIPS/eip-1577 getContentHash(): Promise; // Storage of text records // See: https://eips.ethereum.org/EIPS/eip-634 getText(key: string): Promise; }; export interface EnsProvider { resolveName(name: string): Promise; lookupAddress(address: string): Promise; getResolver(name: string): Promise; } type CoinInfo = { symbol: string, ilk?: string, // General family prefix?: string, // Bech32 prefix p2pkh?: number, // Pay-to-Public-Key-Hash Version p2sh?: number, // Pay-to-Script-Hash Version }; // https://github.com/satoshilabs/slips/blob/master/slip-0044.md const coinInfos: { [ coinType: string ]: CoinInfo } = { "0": { symbol: "btc", p2pkh: 0x00, p2sh: 0x05, prefix: "bc" }, "2": { symbol: "ltc", p2pkh: 0x30, p2sh: 0x32, prefix: "ltc" }, "3": { symbol: "doge", p2pkh: 0x1e, p2sh: 0x16 }, "60": { symbol: "eth", ilk: "eth" }, "61": { symbol: "etc", ilk: "eth" }, "700": { symbol: "xdai", ilk: "eth" }, }; function bytes32ify(value: number): string { return hexZeroPad(BigNumber.from(value).toHexString(), 32); } // Compute the Base58Check encoded data (checksum is first 4 bytes of sha256d) function base58Encode(data: Uint8Array): string { return Base58.encode(concat([ data, hexDataSlice(sha256(sha256(data)), 0, 4) ])); } export interface Avatar { url: string; linkage: Array<{ type: string, content: string }>; } const matcherIpfs = new RegExp("^(ipfs):/\/(.*)$", "i"); const matchers = [ new RegExp("^(https):/\/(.*)$", "i"), new RegExp("^(data):(.*)$", "i"), matcherIpfs, new RegExp("^eip155:[0-9]+/(erc[0-9]+):(.*)$", "i"), ]; function _parseString(result: string, start: number): null | string { try { return toUtf8String(_parseBytes(result, start)); } catch(error) { } return null; } function _parseBytes(result: string, start: number): null | string { if (result === "0x") { return null; } const offset = BigNumber.from(hexDataSlice(result, start, start + 32)).toNumber(); const length = BigNumber.from(hexDataSlice(result, offset, offset + 32)).toNumber(); return hexDataSlice(result, offset + 32, offset + 32 + length); } // Trim off the ipfs:// prefix and return the default gateway URL function getIpfsLink(link: string): string { if (link.match(/^ipfs:\/\/ipfs\//i)) { link = link.substring(12); } else if (link.match(/^ipfs:\/\//i)) { link = link.substring(7); } else { logger.throwArgumentError("unsupported IPFS format", "link", link); } return `https:/\/gateway.ipfs.io/ipfs/${ link }`; } function numPad(value: number): Uint8Array { const result = arrayify(value); if (result.length > 32) { throw new Error("internal; should not happen"); } const padded = new Uint8Array(32); padded.set(result, 32 - result.length); return padded; } function bytesPad(value: Uint8Array): Uint8Array { if ((value.length % 32) === 0) { return value; } const result = new Uint8Array(Math.ceil(value.length / 32) * 32); result.set(value); return result; } // ABI Encodes a series of (bytes, bytes, ...) function encodeBytes(datas: Array) { const result: Array = [ ]; let byteCount = 0; // Add place-holders for pointers as we add items for (let i = 0; i < datas.length; i++) { result.push(null); byteCount += 32; } for (let i = 0; i < datas.length; i++) { const data = arrayify(datas[i]); // Update the bytes offset result[i] = numPad(byteCount); // The length and padded value of data result.push(numPad(data.length)); result.push(bytesPad(data)); byteCount += 32 + Math.ceil(data.length / 32) * 32; } return hexConcat(result); } export class Resolver implements EnsResolver { readonly provider: BaseProvider; readonly name: string; readonly address: string; readonly _resolvedAddress: null | string; // For EIP-2544 names, the ancestor that provided the resolver _supportsEip2544: null | Promise; // The resolvedAddress is only for creating a ReverseLookup resolver constructor(provider: BaseProvider, address: string, name: string, resolvedAddress?: string) { defineReadOnly(this, "provider", provider); defineReadOnly(this, "name", name); defineReadOnly(this, "address", provider.formatter.address(address)); defineReadOnly(this, "_resolvedAddress", resolvedAddress); } supportsWildcard(): Promise { if (!this._supportsEip2544) { // supportsInterface(bytes4 = selector("resolve(bytes,bytes)")) this._supportsEip2544 = this.provider.call({ to: this.address, data: "0x01ffc9a79061b92300000000000000000000000000000000000000000000000000000000" }).then((result) => { return BigNumber.from(result).eq(1); }).catch((error) => { if (error.code === Logger.errors.CALL_EXCEPTION) { return false; } // Rethrow the error: link is down, etc. Let future attempts retry. this._supportsEip2544 = null; throw error; }); } return this._supportsEip2544; } async _fetch(selector: string, parameters?: string): Promise { // e.g. keccak256("addr(bytes32,uint256)") const tx = { to: this.address, ccipReadEnabled: true, data: hexConcat([ selector, namehash(this.name), (parameters || "0x") ]) }; // Wildcard support; use EIP-2544 to resolve the request let parseBytes = false; if (await this.supportsWildcard()) { parseBytes = true; // selector("resolve(bytes,bytes)") tx.data = hexConcat([ "0x9061b923", encodeBytes([ dnsEncode(this.name), tx.data ]) ]); } try { let result = await this.provider.call(tx); if ((arrayify(result).length % 32) === 4) { logger.throwError("resolver threw error", Logger.errors.CALL_EXCEPTION, { transaction: tx, data: result }); } if (parseBytes) { result = _parseBytes(result, 0); } return result; } catch (error) { if (error.code === Logger.errors.CALL_EXCEPTION) { return null; } throw error; } } async _fetchBytes(selector: string, parameters?: string): Promise { const result = await this._fetch(selector, parameters); if (result != null) { return _parseBytes(result, 0); } return null; } _getAddress(coinType: number, hexBytes: string): string { const coinInfo = coinInfos[String(coinType)]; if (coinInfo == null) { logger.throwError(`unsupported coin type: ${ coinType }`, Logger.errors.UNSUPPORTED_OPERATION, { operation: `getAddress(${ coinType })` }); } if (coinInfo.ilk === "eth") { return this.provider.formatter.address(hexBytes); } const bytes = arrayify(hexBytes); // P2PKH: OP_DUP OP_HASH160 OP_EQUALVERIFY OP_CHECKSIG if (coinInfo.p2pkh != null) { const p2pkh = hexBytes.match(/^0x76a9([0-9a-f][0-9a-f])([0-9a-f]*)88ac$/); if (p2pkh) { const length = parseInt(p2pkh[1], 16); if (p2pkh[2].length === length * 2 && length >= 1 && length <= 75) { return base58Encode(concat([ [ coinInfo.p2pkh ], ("0x" + p2pkh[2]) ])); } } } // P2SH: OP_HASH160 OP_EQUAL if (coinInfo.p2sh != null) { const p2sh = hexBytes.match(/^0xa9([0-9a-f][0-9a-f])([0-9a-f]*)87$/); if (p2sh) { const length = parseInt(p2sh[1], 16); if (p2sh[2].length === length * 2 && length >= 1 && length <= 75) { return base58Encode(concat([ [ coinInfo.p2sh ], ("0x" + p2sh[2]) ])); } } } // Bech32 if (coinInfo.prefix != null) { const length = bytes[1]; // https://github.com/bitcoin/bips/blob/master/bip-0141.mediawiki#witness-program let version = bytes[0]; if (version === 0x00) { if (length !== 20 && length !== 32) { version = -1; } } else { version = -1; } if (version >= 0 && bytes.length === 2 + length && length >= 1 && length <= 75) { const words = bech32.toWords(bytes.slice(2)); words.unshift(version); return bech32.encode(coinInfo.prefix, words); } } return null; } async getAddress(coinType?: number): Promise { if (coinType == null) { coinType = 60; } // If Ethereum, use the standard `addr(bytes32)` if (coinType === 60) { try { // keccak256("addr(bytes32)") const result = await this._fetch("0x3b3b57de"); // No address if (result === "0x" || result === HashZero) { return null; } return this.provider.formatter.callAddress(result); } catch (error) { if (error.code === Logger.errors.CALL_EXCEPTION) { return null; } throw error; } } // keccak256("addr(bytes32,uint256") const hexBytes = await this._fetchBytes("0xf1cb7e06", bytes32ify(coinType)); // No address if (hexBytes == null || hexBytes === "0x") { return null; } // Compute the address const address = this._getAddress(coinType, hexBytes); if (address == null) { logger.throwError(`invalid or unsupported coin data`, Logger.errors.UNSUPPORTED_OPERATION, { operation: `getAddress(${ coinType })`, coinType: coinType, data: hexBytes }); } return address; } async getAvatar(): Promise { const linkage: Array<{ type: string, content: string }> = [ { type: "name", content: this.name } ]; try { // test data for ricmoo.eth //const avatar = "eip155:1/erc721:0x265385c7f4132228A0d54EB1A9e7460b91c0cC68/29233"; const avatar = await this.getText("avatar"); if (avatar == null) { return null; } for (let i = 0; i < matchers.length; i++) { const match = avatar.match(matchers[i]); if (match == null) { continue; } const scheme = match[1].toLowerCase(); switch (scheme) { case "https": linkage.push({ type: "url", content: avatar }); return { linkage, url: avatar }; case "data": linkage.push({ type: "data", content: avatar }); return { linkage, url: avatar }; case "ipfs": linkage.push({ type: "ipfs", content: avatar }); return { linkage, url: getIpfsLink(avatar) }; case "erc721": case "erc1155": { // Depending on the ERC type, use tokenURI(uint256) or url(uint256) const selector = (scheme === "erc721") ? "0xc87b56dd": "0x0e89341c"; linkage.push({ type: scheme, content: avatar }); // The owner of this name const owner = (this._resolvedAddress || await this.getAddress()); const comps = (match[2] || "").split("/"); if (comps.length !== 2) { return null; } const addr = await this.provider.formatter.address(comps[0]); const tokenId = hexZeroPad(BigNumber.from(comps[1]).toHexString(), 32); // Check that this account owns the token if (scheme === "erc721") { // ownerOf(uint256 tokenId) const tokenOwner = this.provider.formatter.callAddress(await this.provider.call({ to: addr, data: hexConcat([ "0x6352211e", tokenId ]) })); if (owner !== tokenOwner) { return null; } linkage.push({ type: "owner", content: tokenOwner }); } else if (scheme === "erc1155") { // balanceOf(address owner, uint256 tokenId) const balance = BigNumber.from(await this.provider.call({ to: addr, data: hexConcat([ "0x00fdd58e", hexZeroPad(owner, 32), tokenId ]) })); if (balance.isZero()) { return null; } linkage.push({ type: "balance", content: balance.toString() }); } // Call the token contract for the metadata URL const tx = { to: this.provider.formatter.address(comps[0]), data: hexConcat([ selector, tokenId ]) }; let metadataUrl = _parseString(await this.provider.call(tx), 0); if (metadataUrl == null) { return null; } linkage.push({ type: "metadata-url-base", content: metadataUrl }); // ERC-1155 allows a generic {id} in the URL if (scheme === "erc1155") { metadataUrl = metadataUrl.replace("{id}", tokenId.substring(2)); linkage.push({ type: "metadata-url-expanded", content: metadataUrl }); } // Transform IPFS metadata links if (metadataUrl.match(/^ipfs:/i)) { metadataUrl = getIpfsLink(metadataUrl); } linkage.push({ type: "metadata-url", content: metadataUrl }); // Get the token metadata const metadata = await fetchJson(metadataUrl); if (!metadata) { return null; } linkage.push({ type: "metadata", content: JSON.stringify(metadata) }); // Pull the image URL out let imageUrl = metadata.image; if (typeof(imageUrl) !== "string") { return null; } if (imageUrl.match(/^(https:\/\/|data:)/i)) { // Allow } else { // Transform IPFS link to gateway const ipfs = imageUrl.match(matcherIpfs); if (ipfs == null) { return null; } linkage.push({ type: "url-ipfs", content: imageUrl }); imageUrl = getIpfsLink(imageUrl); } linkage.push({ type: "url", content: imageUrl }); return { linkage, url: imageUrl }; } } } } catch (error) { } return null; } async getContentHash(): Promise { // keccak256("contenthash()") const hexBytes = await this._fetchBytes("0xbc1c58d1"); // No contenthash if (hexBytes == null || hexBytes === "0x") { return null; } // IPFS (CID: 1, Type: DAG-PB) const ipfs = hexBytes.match(/^0xe3010170(([0-9a-f][0-9a-f])([0-9a-f][0-9a-f])([0-9a-f]*))$/); if (ipfs) { const length = parseInt(ipfs[3], 16); if (ipfs[4].length === length * 2) { return "ipfs:/\/" + Base58.encode("0x" + ipfs[1]); } } // IPNS (CID: 1, Type: libp2p-key) const ipns = hexBytes.match(/^0xe5010172(([0-9a-f][0-9a-f])([0-9a-f][0-9a-f])([0-9a-f]*))$/); if (ipns) { const length = parseInt(ipns[3], 16); if (ipns[4].length === length * 2) { return "ipns:/\/" + Base58.encode("0x" + ipns[1]); } } // Swarm (CID: 1, Type: swarm-manifest; hash/length hard-coded to keccak256/32) const swarm = hexBytes.match(/^0xe40101fa011b20([0-9a-f]*)$/) if (swarm) { if (swarm[1].length === (32 * 2)) { return "bzz:/\/" + swarm[1] } } return logger.throwError(`invalid or unsupported content hash data`, Logger.errors.UNSUPPORTED_OPERATION, { operation: "getContentHash()", data: hexBytes }); } async getText(key: string): Promise { // The key encoded as parameter to fetchBytes let keyBytes = toUtf8Bytes(key); // The nodehash consumes the first slot, so the string pointer targets // offset 64, with the length at offset 64 and data starting at offset 96 keyBytes = concat([ bytes32ify(64), bytes32ify(keyBytes.length), keyBytes ]); // Pad to word-size (32 bytes) if ((keyBytes.length % 32) !== 0) { keyBytes = concat([ keyBytes, hexZeroPad("0x", 32 - (key.length % 32)) ]) } const hexBytes = await this._fetchBytes("0x59d1d43c", hexlify(keyBytes)); if (hexBytes == null || hexBytes === "0x") { return null; } return toUtf8String(hexBytes); } } let defaultFormatter: Formatter = null; let nextPollId = 1; export class BaseProvider extends Provider implements EnsProvider { _networkPromise: Promise; _network: Network; _events: Array; formatter: Formatter; // To help mitigate the eventually consistent nature of the blockchain // we keep a mapping of events we emit. If we emit an event X, we expect // that a user should be able to query for that event in the callback, // if the node returns null, we stall the response until we get back a // meaningful value, since we may be hitting a re-org, or a node that // has not indexed the event yet. // Events: // - t:{hash} - Transaction hash // - b:{hash} - BlockHash // - block - The most recent emitted block _emitted: { [ eventName: string ]: number | "pending" }; _pollingInterval: number; _poller: NodeJS.Timer; _bootstrapPoll: NodeJS.Timer; _lastBlockNumber: number; _maxFilterBlockRange: number; _fastBlockNumber: number; _fastBlockNumberPromise: Promise; _fastQueryDate: number; _maxInternalBlockNumber: number; _internalBlockNumber: Promise<{ blockNumber: number, reqTime: number, respTime: number }>; readonly anyNetwork: boolean; disableCcipRead: boolean; /** * ready * * A Promise that resolves only once the provider is ready. * * Sub-classes that call the super with a network without a chainId * MUST set this. Standard named networks have a known chainId. * */ constructor(network: Networkish | Promise) { super(); // Events being listened to this._events = []; this._emitted = { block: -2 }; this.disableCcipRead = false; this.formatter = new.target.getFormatter(); // If network is any, this Provider allows the underlying // network to change dynamically, and we auto-detect the // current network defineReadOnly(this, "anyNetwork", (network === "any")); if (this.anyNetwork) { network = this.detectNetwork(); } if (network instanceof Promise) { this._networkPromise = network; // Squash any "unhandled promise" errors; that do not need to be handled network.catch((error) => { }); // Trigger initial network setting (async) this._ready().catch((error) => { }); } else { const knownNetwork = getStatic<(network: Networkish) => Network>(new.target, "getNetwork")(network); if (knownNetwork) { defineReadOnly(this, "_network", knownNetwork); this.emit("network", knownNetwork, null); } else { logger.throwArgumentError("invalid network", "network", network); } } this._maxInternalBlockNumber = -1024; this._lastBlockNumber = -2; this._maxFilterBlockRange = 10; this._pollingInterval = 4000; this._fastQueryDate = 0; } async _ready(): Promise { if (this._network == null) { let network: Network = null; if (this._networkPromise) { try { network = await this._networkPromise; } catch (error) { } } // Try the Provider's network detection (this MUST throw if it cannot) if (network == null) { network = await this.detectNetwork(); } // This should never happen; every Provider sub-class should have // suggested a network by here (or have thrown). if (!network) { logger.throwError("no network detected", Logger.errors.UNKNOWN_ERROR, { }); } // Possible this call stacked so do not call defineReadOnly again if (this._network == null) { if (this.anyNetwork) { this._network = network; } else { defineReadOnly(this, "_network", network); } this.emit("network", network, null); } } return this._network; } // This will always return the most recently established network. // For "any", this can change (a "network" event is emitted before // any change is reflected); otherwise this cannot change get ready(): Promise { return poll(() => { return this._ready().then((network) => { return network; }, (error) => { // If the network isn't running yet, we will wait if (error.code === Logger.errors.NETWORK_ERROR && error.event === "noNetwork") { return undefined; } throw error; }); }); } // @TODO: Remove this and just create a singleton formatter static getFormatter(): Formatter { if (defaultFormatter == null) { defaultFormatter = new Formatter(); } return defaultFormatter; } // @TODO: Remove this and just use getNetwork static getNetwork(network: Networkish): Network { return getNetwork((network == null) ? "homestead": network); } async ccipReadFetch(tx: Transaction, calldata: string, urls: Array): Promise { if (this.disableCcipRead || urls.length === 0) { return null; } const sender = tx.to.toLowerCase(); const data = calldata.toLowerCase(); const errorMessages: Array = [ ]; for (let i = 0; i < urls.length; i++) { const url = urls[i]; // URL expansion const href = url.replace("{sender}", sender).replace("{data}", data); // If no {data} is present, use POST; otherwise GET const json: string | null = (url.indexOf("{data}") >= 0) ? null: JSON.stringify({ data, sender }); const result = await fetchJson({ url: href, errorPassThrough: true }, json, (value, response) => { value.status = response.statusCode; return value; }); if (result.data) { return result.data; } const errorMessage = (result.message || "unknown error"); // 4xx indicates the result is not present; stop if (result.status >= 400 && result.status < 500) { return logger.throwError(`response not found during CCIP fetch: ${ errorMessage }`, Logger.errors.SERVER_ERROR, { url, errorMessage }); } // 5xx indicates server issue; try the next url errorMessages.push(errorMessage); } return logger.throwError(`error encountered during CCIP fetch: ${ errorMessages.map((m) => JSON.stringify(m)).join(", ") }`, Logger.errors.SERVER_ERROR, { urls, errorMessages }); } // Fetches the blockNumber, but will reuse any result that is less // than maxAge old or has been requested since the last request async _getInternalBlockNumber(maxAge: number): Promise { await this._ready(); // Allowing stale data up to maxAge old if (maxAge > 0) { // While there are pending internal block requests... while (this._internalBlockNumber) { // ..."remember" which fetch we started with const internalBlockNumber = this._internalBlockNumber; try { // Check the result is not too stale const result = await internalBlockNumber; if ((getTime() - result.respTime) <= maxAge) { return result.blockNumber; } // Too old; fetch a new value break; } catch(error) { // The fetch rejected; if we are the first to get the // rejection, drop through so we replace it with a new // fetch; all others blocked will then get that fetch // which won't match the one they "remembered" and loop if (this._internalBlockNumber === internalBlockNumber) { break; } } } } const reqTime = getTime(); const checkInternalBlockNumber = resolveProperties({ blockNumber: this.perform("getBlockNumber", { }), networkError: this.getNetwork().then((network) => (null), (error) => (error)) }).then(({ blockNumber, networkError }) => { if (networkError) { // Unremember this bad internal block number if (this._internalBlockNumber === checkInternalBlockNumber) { this._internalBlockNumber = null; } throw networkError; } const respTime = getTime(); blockNumber = BigNumber.from(blockNumber).toNumber(); if (blockNumber < this._maxInternalBlockNumber) { blockNumber = this._maxInternalBlockNumber; } this._maxInternalBlockNumber = blockNumber; this._setFastBlockNumber(blockNumber); // @TODO: Still need this? return { blockNumber, reqTime, respTime }; }); this._internalBlockNumber = checkInternalBlockNumber; // Swallow unhandled exceptions; if needed they are handled else where checkInternalBlockNumber.catch((error) => { // Don't null the dead (rejected) fetch, if it has already been updated if (this._internalBlockNumber === checkInternalBlockNumber) { this._internalBlockNumber = null; } }); return (await checkInternalBlockNumber).blockNumber; } async poll(): Promise { const pollId = nextPollId++; // Track all running promises, so we can trigger a post-poll once they are complete const runners: Array> = []; let blockNumber: number = null; try { blockNumber = await this._getInternalBlockNumber(100 + this.pollingInterval / 2); } catch (error) { this.emit("error", error); return; } this._setFastBlockNumber(blockNumber); // Emit a poll event after we have the latest (fast) block number this.emit("poll", pollId, blockNumber); // If the block has not changed, meh. if (blockNumber === this._lastBlockNumber) { this.emit("didPoll", pollId); return; } // First polling cycle, trigger a "block" events if (this._emitted.block === -2) { this._emitted.block = blockNumber - 1; } if (Math.abs(((this._emitted.block)) - blockNumber) > 1000) { logger.warn(`network block skew detected; skipping block events (emitted=${ this._emitted.block } blockNumber${ blockNumber })`); this.emit("error", logger.makeError("network block skew detected", Logger.errors.NETWORK_ERROR, { blockNumber: blockNumber, event: "blockSkew", previousBlockNumber: this._emitted.block })); this.emit("block", blockNumber); } else { // Notify all listener for each block that has passed for (let i = (this._emitted.block) + 1; i <= blockNumber; i++) { this.emit("block", i); } } // The emitted block was updated, check for obsolete events if ((this._emitted.block) !== blockNumber) { this._emitted.block = blockNumber; Object.keys(this._emitted).forEach((key) => { // The block event does not expire if (key === "block") { return; } // The block we were at when we emitted this event const eventBlockNumber = this._emitted[key]; // We cannot garbage collect pending transactions or blocks here // They should be garbage collected by the Provider when setting // "pending" events if (eventBlockNumber === "pending") { return; } // Evict any transaction hashes or block hashes over 12 blocks // old, since they should not return null anyways if (blockNumber - eventBlockNumber > 12) { delete this._emitted[key]; } }); } // First polling cycle if (this._lastBlockNumber === -2) { this._lastBlockNumber = blockNumber - 1; } // Find all transaction hashes we are waiting on this._events.forEach((event) => { switch (event.type) { case "tx": { const hash = event.hash; let runner = this.getTransactionReceipt(hash).then((receipt) => { if (!receipt || receipt.blockNumber == null) { return null; } this._emitted["t:" + hash] = receipt.blockNumber; this.emit(hash, receipt); return null; }).catch((error: Error) => { this.emit("error", error); }); runners.push(runner); break; } case "filter": { // We only allow a single getLogs to be in-flight at a time if (!event._inflight) { event._inflight = true; // Filter from the last known event; due to load-balancing // and some nodes returning updated block numbers before // indexing events, a logs result with 0 entries cannot be // trusted and we must retry a range which includes it again const filter = event.filter; filter.fromBlock = event._lastBlockNumber + 1; filter.toBlock = blockNumber; // Prevent fitler ranges from growing too wild if (filter.toBlock - this._maxFilterBlockRange > filter.fromBlock) { filter.fromBlock = filter.toBlock - this._maxFilterBlockRange; } const runner = this.getLogs(filter).then((logs) => { // Allow the next getLogs event._inflight = false; if (logs.length === 0) { return; } logs.forEach((log: Log) => { // Only when we get an event for a given block number // can we trust the events are indexed if (log.blockNumber > event._lastBlockNumber) { event._lastBlockNumber = log.blockNumber; } // Make sure we stall requests to fetch blocks and txs this._emitted["b:" + log.blockHash] = log.blockNumber; this._emitted["t:" + log.transactionHash] = log.blockNumber; this.emit(filter, log); }); }).catch((error: Error) => { this.emit("error", error); // Allow another getLogs (the range was not updated) event._inflight = false; }); runners.push(runner); } break; } } }); this._lastBlockNumber = blockNumber; // Once all events for this loop have been processed, emit "didPoll" Promise.all(runners).then(() => { this.emit("didPoll", pollId); }).catch((error) => { this.emit("error", error); }); return; } // Deprecated; do not use this resetEventsBlock(blockNumber: number): void { this._lastBlockNumber = blockNumber - 1; if (this.polling) { this.poll(); } } get network(): Network { return this._network; } // This method should query the network if the underlying network // can change, such as when connected to a JSON-RPC backend async detectNetwork(): Promise { return logger.throwError("provider does not support network detection", Logger.errors.UNSUPPORTED_OPERATION, { operation: "provider.detectNetwork" }); } async getNetwork(): Promise { const network = await this._ready(); // Make sure we are still connected to the same network; this is // only an external call for backends which can have the underlying // network change spontaneously const currentNetwork = await this.detectNetwork(); if (network.chainId !== currentNetwork.chainId) { // We are allowing network changes, things can get complex fast; // make sure you know what you are doing if you use "any" if (this.anyNetwork) { this._network = currentNetwork; // Reset all internal block number guards and caches this._lastBlockNumber = -2; this._fastBlockNumber = null; this._fastBlockNumberPromise = null; this._fastQueryDate = 0; this._emitted.block = -2; this._maxInternalBlockNumber = -1024; this._internalBlockNumber = null; // The "network" event MUST happen before this method resolves // so any events have a chance to unregister, so we stall an // additional event loop before returning from /this/ call this.emit("network", currentNetwork, network); await stall(0); return this._network; } const error = logger.makeError("underlying network changed", Logger.errors.NETWORK_ERROR, { event: "changed", network: network, detectedNetwork: currentNetwork }); this.emit("error", error); throw error; } return network; } get blockNumber(): number { this._getInternalBlockNumber(100 + this.pollingInterval / 2).then((blockNumber) => { this._setFastBlockNumber(blockNumber); }, (error) => { }); return (this._fastBlockNumber != null) ? this._fastBlockNumber: -1; } get polling(): boolean { return (this._poller != null); } set polling(value: boolean) { if (value && !this._poller) { this._poller = setInterval(() => { this.poll(); }, this.pollingInterval); if (!this._bootstrapPoll) { this._bootstrapPoll = setTimeout(() => { this.poll(); // We block additional polls until the polling interval // is done, to prevent overwhelming the poll function this._bootstrapPoll = setTimeout(() => { // If polling was disabled, something may require a poke // since starting the bootstrap poll and it was disabled if (!this._poller) { this.poll(); } // Clear out the bootstrap so we can do another this._bootstrapPoll = null; }, this.pollingInterval); }, 0); } } else if (!value && this._poller) { clearInterval(this._poller); this._poller = null; } } get pollingInterval(): number { return this._pollingInterval; } set pollingInterval(value: number) { if (typeof(value) !== "number" || value <= 0 || parseInt(String(value)) != value) { throw new Error("invalid polling interval"); } this._pollingInterval = value; if (this._poller) { clearInterval(this._poller); this._poller = setInterval(() => { this.poll(); }, this._pollingInterval); } } _getFastBlockNumber(): Promise { const now = getTime(); // Stale block number, request a newer value if ((now - this._fastQueryDate) > 2 * this._pollingInterval) { this._fastQueryDate = now; this._fastBlockNumberPromise = this.getBlockNumber().then((blockNumber) => { if (this._fastBlockNumber == null || blockNumber > this._fastBlockNumber) { this._fastBlockNumber = blockNumber; } return this._fastBlockNumber; }); } return this._fastBlockNumberPromise; } _setFastBlockNumber(blockNumber: number): void { // Older block, maybe a stale request if (this._fastBlockNumber != null && blockNumber < this._fastBlockNumber) { return; } // Update the time we updated the blocknumber this._fastQueryDate = getTime(); // Newer block number, use it if (this._fastBlockNumber == null || blockNumber > this._fastBlockNumber) { this._fastBlockNumber = blockNumber; this._fastBlockNumberPromise = Promise.resolve(blockNumber); } } async waitForTransaction(transactionHash: string, confirmations?: number, timeout?: number): Promise { return this._waitForTransaction(transactionHash, (confirmations == null) ? 1: confirmations, timeout || 0, null); } async _waitForTransaction(transactionHash: string, confirmations: number, timeout: number, replaceable: { data: string, from: string, nonce: number, to: string, value: BigNumber, startBlock: number }): Promise { const receipt = await this.getTransactionReceipt(transactionHash); // Receipt is already good if ((receipt ? receipt.confirmations: 0) >= confirmations) { return receipt; } // Poll until the receipt is good... return new Promise((resolve, reject) => { const cancelFuncs: Array<() => void> = []; let done = false; const alreadyDone = function() { if (done) { return true; } done = true; cancelFuncs.forEach((func) => { func(); }); return false; }; const minedHandler = (receipt: TransactionReceipt) => { if (receipt.confirmations < confirmations) { return; } if (alreadyDone()) { return; } resolve(receipt); } this.on(transactionHash, minedHandler); cancelFuncs.push(() => { this.removeListener(transactionHash, minedHandler); }); if (replaceable) { let lastBlockNumber = replaceable.startBlock; let scannedBlock: number = null; const replaceHandler = async (blockNumber: number) => { if (done) { return; } // Wait 1 second; this is only used in the case of a fault, so // we will trade off a little bit of latency for more consistent // results and fewer JSON-RPC calls await stall(1000); this.getTransactionCount(replaceable.from).then(async (nonce) => { if (done) { return; } if (nonce <= replaceable.nonce) { lastBlockNumber = blockNumber; } else { // First check if the transaction was mined { const mined = await this.getTransaction(transactionHash); if (mined && mined.blockNumber != null) { return; } } // First time scanning. We start a little earlier for some // wiggle room here to handle the eventually consistent nature // of blockchain (e.g. the getTransactionCount was for a // different block) if (scannedBlock == null) { scannedBlock = lastBlockNumber - 3; if (scannedBlock < replaceable.startBlock) { scannedBlock = replaceable.startBlock; } } while (scannedBlock <= blockNumber) { if (done) { return; } const block = await this.getBlockWithTransactions(scannedBlock); for (let ti = 0; ti < block.transactions.length; ti++) { const tx = block.transactions[ti]; // Successfully mined! if (tx.hash === transactionHash) { return; } // Matches our transaction from and nonce; its a replacement if (tx.from === replaceable.from && tx.nonce === replaceable.nonce) { if (done) { return; } // Get the receipt of the replacement const receipt = await this.waitForTransaction(tx.hash, confirmations); // Already resolved or rejected (prolly a timeout) if (alreadyDone()) { return; } // The reason we were replaced let reason = "replaced"; if (tx.data === replaceable.data && tx.to === replaceable.to && tx.value.eq(replaceable.value)) { reason = "repriced"; } else if (tx.data === "0x" && tx.from === tx.to && tx.value.isZero()) { reason = "cancelled" } // Explain why we were replaced reject(logger.makeError("transaction was replaced", Logger.errors.TRANSACTION_REPLACED, { cancelled: (reason === "replaced" || reason === "cancelled"), reason, replacement: this._wrapTransaction(tx), hash: transactionHash, receipt })); return; } } scannedBlock++; } } if (done) { return; } this.once("block", replaceHandler); }, (error) => { if (done) { return; } this.once("block", replaceHandler); }); }; if (done) { return; } this.once("block", replaceHandler); cancelFuncs.push(() => { this.removeListener("block", replaceHandler); }); } if (typeof(timeout) === "number" && timeout > 0) { const timer = setTimeout(() => { if (alreadyDone()) { return; } reject(logger.makeError("timeout exceeded", Logger.errors.TIMEOUT, { timeout: timeout })); }, timeout); if (timer.unref) { timer.unref(); } cancelFuncs.push(() => { clearTimeout(timer); }); } }); } async getBlockNumber(): Promise { return this._getInternalBlockNumber(0); } async getGasPrice(): Promise { await this.getNetwork(); const result = await this.perform("getGasPrice", { }); try { return BigNumber.from(result); } catch (error) { return logger.throwError("bad result from backend", Logger.errors.SERVER_ERROR, { method: "getGasPrice", result, error }); } } async getBalance(addressOrName: string | Promise, blockTag?: BlockTag | Promise): Promise { await this.getNetwork(); const params = await resolveProperties({ address: this._getAddress(addressOrName), blockTag: this._getBlockTag(blockTag) }); const result = await this.perform("getBalance", params); try { return BigNumber.from(result); } catch (error) { return logger.throwError("bad result from backend", Logger.errors.SERVER_ERROR, { method: "getBalance", params, result, error }); } } async getTransactionCount(addressOrName: string | Promise, blockTag?: BlockTag | Promise): Promise { await this.getNetwork(); const params = await resolveProperties({ address: this._getAddress(addressOrName), blockTag: this._getBlockTag(blockTag) }); const result = await this.perform("getTransactionCount", params); try { return BigNumber.from(result).toNumber(); } catch (error) { return logger.throwError("bad result from backend", Logger.errors.SERVER_ERROR, { method: "getTransactionCount", params, result, error }); } } async getCode(addressOrName: string | Promise, blockTag?: BlockTag | Promise): Promise { await this.getNetwork(); const params = await resolveProperties({ address: this._getAddress(addressOrName), blockTag: this._getBlockTag(blockTag) }); const result = await this.perform("getCode", params); try { return hexlify(result); } catch (error) { return logger.throwError("bad result from backend", Logger.errors.SERVER_ERROR, { method: "getCode", params, result, error }); } } async getStorageAt(addressOrName: string | Promise, position: BigNumberish | Promise, blockTag?: BlockTag | Promise): Promise { await this.getNetwork(); const params = await resolveProperties({ address: this._getAddress(addressOrName), blockTag: this._getBlockTag(blockTag), position: Promise.resolve(position).then((p) => hexValue(p)) }); const result = await this.perform("getStorageAt", params); try { return hexlify(result); } catch (error) { return logger.throwError("bad result from backend", Logger.errors.SERVER_ERROR, { method: "getStorageAt", params, result, error }); } } // This should be called by any subclass wrapping a TransactionResponse _wrapTransaction(tx: Transaction, hash?: string, startBlock?: number): TransactionResponse { if (hash != null && hexDataLength(hash) !== 32) { throw new Error("invalid response - sendTransaction"); } const result = tx; // Check the hash we expect is the same as the hash the server reported if (hash != null && tx.hash !== hash) { logger.throwError("Transaction hash mismatch from Provider.sendTransaction.", Logger.errors.UNKNOWN_ERROR, { expectedHash: tx.hash, returnedHash: hash }); } result.wait = async (confirms?: number, timeout?: number) => { if (confirms == null) { confirms = 1; } if (timeout == null) { timeout = 0; } // Get the details to detect replacement let replacement = undefined; if (confirms !== 0 && startBlock != null) { replacement = { data: tx.data, from: tx.from, nonce: tx.nonce, to: tx.to, value: tx.value, startBlock }; } const receipt = await this._waitForTransaction(tx.hash, confirms, timeout, replacement); if (receipt == null && confirms === 0) { return null; } // No longer pending, allow the polling loop to garbage collect this this._emitted["t:" + tx.hash] = receipt.blockNumber; if (receipt.status === 0) { logger.throwError("transaction failed", Logger.errors.CALL_EXCEPTION, { transactionHash: tx.hash, transaction: tx, receipt: receipt }); } return receipt; }; return result; } async sendTransaction(signedTransaction: string | Promise): Promise { await this.getNetwork(); const hexTx = await Promise.resolve(signedTransaction).then(t => hexlify(t)); const tx = this.formatter.transaction(signedTransaction); if (tx.confirmations == null) { tx.confirmations = 0; } const blockNumber = await this._getInternalBlockNumber(100 + 2 * this.pollingInterval); try { const hash = await this.perform("sendTransaction", { signedTransaction: hexTx }); return this._wrapTransaction(tx, hash, blockNumber); } catch (error) { (error).transaction = tx; (error).transactionHash = tx.hash; throw error; } } async _getTransactionRequest(transaction: Deferrable): Promise { const values: any = await transaction; const tx: any = { }; ["from", "to"].forEach((key) => { if (values[key] == null) { return; } tx[key] = Promise.resolve(values[key]).then((v) => (v ? this._getAddress(v): null)) }); ["gasLimit", "gasPrice", "maxFeePerGas", "maxPriorityFeePerGas", "value"].forEach((key) => { if (values[key] == null) { return; } tx[key] = Promise.resolve(values[key]).then((v) => (v ? BigNumber.from(v): null)); }); ["type"].forEach((key) => { if (values[key] == null) { return; } tx[key] = Promise.resolve(values[key]).then((v) => ((v != null) ? v: null)); }); if (values.accessList) { tx.accessList = this.formatter.accessList(values.accessList); } ["data"].forEach((key) => { if (values[key] == null) { return; } tx[key] = Promise.resolve(values[key]).then((v) => (v ? hexlify(v): null)); }); return this.formatter.transactionRequest(await resolveProperties(tx)); } async _getFilter(filter: Filter | FilterByBlockHash | Promise): Promise { filter = await filter; const result: any = { }; if (filter.address != null) { result.address = this._getAddress(filter.address); } ["blockHash", "topics"].forEach((key) => { if ((filter)[key] == null) { return; } result[key] = (filter)[key]; }); ["fromBlock", "toBlock"].forEach((key) => { if ((filter)[key] == null) { return; } result[key] = this._getBlockTag((filter)[key]); }); return this.formatter.filter(await resolveProperties(result)); } async _call(transaction: TransactionRequest, blockTag: BlockTag, attempt: number): Promise { if (attempt >= MAX_CCIP_REDIRECTS) { logger.throwError("CCIP read exceeded maximum redirections", Logger.errors.SERVER_ERROR, { redirects: attempt, transaction }); } const txSender = transaction.to; const result = await this.perform("call", { transaction, blockTag }); // CCIP Read request via OffchainLookup(address,string[],bytes,bytes4,bytes) if (attempt >= 0 && blockTag === "latest" && txSender != null && result.substring(0, 10) === "0x556f1830" && (hexDataLength(result) % 32 === 4)) { try { const data = hexDataSlice(result, 4); // Check the sender of the OffchainLookup matches the transaction const sender = hexDataSlice(data, 0, 32); if (!BigNumber.from(sender).eq(txSender)) { logger.throwError("CCIP Read sender did not match", Logger.errors.CALL_EXCEPTION, { name: "OffchainLookup", signature: "OffchainLookup(address,string[],bytes,bytes4,bytes)", transaction, data: result }); } // Read the URLs from the response const urls: Array = []; const urlsOffset = BigNumber.from(hexDataSlice(data, 32, 64)).toNumber(); const urlsLength = BigNumber.from(hexDataSlice(data, urlsOffset, urlsOffset + 32)).toNumber(); const urlsData = hexDataSlice(data, urlsOffset + 32); for (let u = 0; u < urlsLength; u++) { const url = _parseString(urlsData, u * 32); if (url == null) { logger.throwError("CCIP Read contained corrupt URL string", Logger.errors.CALL_EXCEPTION, { name: "OffchainLookup", signature: "OffchainLookup(address,string[],bytes,bytes4,bytes)", transaction, data: result }); } urls.push(url); } // Get the CCIP calldata to forward const calldata = _parseBytes(data, 64); // Get the callbackSelector (bytes4) if (!BigNumber.from(hexDataSlice(data, 100, 128)).isZero()) { logger.throwError("CCIP Read callback selector included junk", Logger.errors.CALL_EXCEPTION, { name: "OffchainLookup", signature: "OffchainLookup(address,string[],bytes,bytes4,bytes)", transaction, data: result }); } const callbackSelector = hexDataSlice(data, 96, 100); // Get the extra data to send back to the contract as context const extraData = _parseBytes(data, 128); const ccipResult = await this.ccipReadFetch(transaction, calldata, urls); if (ccipResult == null) { logger.throwError("CCIP Read disabled or provided no URLs", Logger.errors.CALL_EXCEPTION, { name: "OffchainLookup", signature: "OffchainLookup(address,string[],bytes,bytes4,bytes)", transaction, data: result }); } const tx = { to: txSender, data: hexConcat([ callbackSelector, encodeBytes([ ccipResult, extraData ]) ]) }; return this._call(tx, blockTag, attempt + 1); } catch (error) { if (error.code === Logger.errors.SERVER_ERROR) { throw error; } } } try { return hexlify(result); } catch (error) { return logger.throwError("bad result from backend", Logger.errors.SERVER_ERROR, { method: "call", params: { transaction, blockTag }, result, error }); } } async call(transaction: Deferrable, blockTag?: BlockTag | Promise): Promise { await this.getNetwork(); const resolved = await resolveProperties({ transaction: this._getTransactionRequest(transaction), blockTag: this._getBlockTag(blockTag), ccipReadEnabled: Promise.resolve(transaction.ccipReadEnabled) }); return this._call(resolved.transaction, resolved.blockTag, resolved.ccipReadEnabled ? 0: -1); } async estimateGas(transaction: Deferrable): Promise { await this.getNetwork(); const params = await resolveProperties({ transaction: this._getTransactionRequest(transaction) }); const result = await this.perform("estimateGas", params); try { return BigNumber.from(result); } catch (error) { return logger.throwError("bad result from backend", Logger.errors.SERVER_ERROR, { method: "estimateGas", params, result, error }); } } async _getAddress(addressOrName: string | Promise): Promise { addressOrName = await addressOrName; if (typeof(addressOrName) !== "string") { logger.throwArgumentError("invalid address or ENS name", "name", addressOrName); } const address = await this.resolveName(addressOrName); if (address == null) { logger.throwError("ENS name not configured", Logger.errors.UNSUPPORTED_OPERATION, { operation: `resolveName(${ JSON.stringify(addressOrName) })` }); } return address; } async _getBlock(blockHashOrBlockTag: BlockTag | string | Promise, includeTransactions?: boolean): Promise { await this.getNetwork(); blockHashOrBlockTag = await blockHashOrBlockTag; // If blockTag is a number (not "latest", etc), this is the block number let blockNumber = -128; const params: { [key: string]: any } = { includeTransactions: !!includeTransactions }; if (isHexString(blockHashOrBlockTag, 32)) { params.blockHash = blockHashOrBlockTag; } else { try { params.blockTag = await this._getBlockTag(blockHashOrBlockTag); if (isHexString(params.blockTag)) { blockNumber = parseInt(params.blockTag.substring(2), 16); } } catch (error) { logger.throwArgumentError("invalid block hash or block tag", "blockHashOrBlockTag", blockHashOrBlockTag); } } return poll(async () => { const block = await this.perform("getBlock", params); // Block was not found if (block == null) { // For blockhashes, if we didn't say it existed, that blockhash may // not exist. If we did see it though, perhaps from a log, we know // it exists, and this node is just not caught up yet. if (params.blockHash != null) { if (this._emitted["b:" + params.blockHash] == null) { return null; } } // For block tags, if we are asking for a future block, we return null if (params.blockTag != null) { if (blockNumber > this._emitted.block) { return null; } } // Retry on the next block return undefined; } // Add transactions if (includeTransactions) { let blockNumber: number = null; for (let i = 0; i < block.transactions.length; i++) { const tx = block.transactions[i]; if (tx.blockNumber == null) { tx.confirmations = 0; } else if (tx.confirmations == null) { if (blockNumber == null) { blockNumber = await this._getInternalBlockNumber(100 + 2 * this.pollingInterval); } // Add the confirmations using the fast block number (pessimistic) let confirmations = (blockNumber - tx.blockNumber) + 1; if (confirmations <= 0) { confirmations = 1; } tx.confirmations = confirmations; } } const blockWithTxs: any = this.formatter.blockWithTransactions(block); blockWithTxs.transactions = blockWithTxs.transactions.map((tx: TransactionResponse) => this._wrapTransaction(tx)); return blockWithTxs; } return this.formatter.block(block); }, { oncePoll: this }); } getBlock(blockHashOrBlockTag: BlockTag | string | Promise): Promise { return >(this._getBlock(blockHashOrBlockTag, false)); } getBlockWithTransactions(blockHashOrBlockTag: BlockTag | string | Promise): Promise { return >(this._getBlock(blockHashOrBlockTag, true)); } async getTransaction(transactionHash: string | Promise): Promise { await this.getNetwork(); transactionHash = await transactionHash; const params = { transactionHash: this.formatter.hash(transactionHash, true) }; return poll(async () => { const result = await this.perform("getTransaction", params); if (result == null) { if (this._emitted["t:" + transactionHash] == null) { return null; } return undefined; } const tx = this.formatter.transactionResponse(result); if (tx.blockNumber == null) { tx.confirmations = 0; } else if (tx.confirmations == null) { const blockNumber = await this._getInternalBlockNumber(100 + 2 * this.pollingInterval); // Add the confirmations using the fast block number (pessimistic) let confirmations = (blockNumber - tx.blockNumber) + 1; if (confirmations <= 0) { confirmations = 1; } tx.confirmations = confirmations; } return this._wrapTransaction(tx); }, { oncePoll: this }); } async getTransactionReceipt(transactionHash: string | Promise): Promise { await this.getNetwork(); transactionHash = await transactionHash; const params = { transactionHash: this.formatter.hash(transactionHash, true) }; return poll(async () => { const result = await this.perform("getTransactionReceipt", params); if (result == null) { if (this._emitted["t:" + transactionHash] == null) { return null; } return undefined; } // "geth-etc" returns receipts before they are ready if (result.blockHash == null) { return undefined; } const receipt = this.formatter.receipt(result); if (receipt.blockNumber == null) { receipt.confirmations = 0; } else if (receipt.confirmations == null) { const blockNumber = await this._getInternalBlockNumber(100 + 2 * this.pollingInterval); // Add the confirmations using the fast block number (pessimistic) let confirmations = (blockNumber - receipt.blockNumber) + 1; if (confirmations <= 0) { confirmations = 1; } receipt.confirmations = confirmations; } return receipt; }, { oncePoll: this }); } async getLogs(filter: Filter | FilterByBlockHash | Promise): Promise> { await this.getNetwork(); const params = await resolveProperties({ filter: this._getFilter(filter) }); const logs: Array = await this.perform("getLogs", params); logs.forEach((log) => { if (log.removed == null) { log.removed = false; } }); return Formatter.arrayOf(this.formatter.filterLog.bind(this.formatter))(logs); } async getEtherPrice(): Promise { await this.getNetwork(); return this.perform("getEtherPrice", { }); } async _getBlockTag(blockTag: BlockTag | Promise): Promise { blockTag = await blockTag; if (typeof(blockTag) === "number" && blockTag < 0) { if (blockTag % 1) { logger.throwArgumentError("invalid BlockTag", "blockTag", blockTag); } let blockNumber = await this._getInternalBlockNumber(100 + 2 * this.pollingInterval); blockNumber += blockTag; if (blockNumber < 0) { blockNumber = 0; } return this.formatter.blockTag(blockNumber) } return this.formatter.blockTag(blockTag); } async getResolver(name: string): Promise { let currentName = name; while (true) { if (currentName === "" || currentName === ".") { return null; } // Optimization since the eth node cannot change and does // not have a wildcard resolver if (name !== "eth" && currentName === "eth") { return null; } // Check the current node for a resolver const addr = await this._getResolver(currentName, "getResolver"); // Found a resolver! if (addr != null) { const resolver = new Resolver(this, addr, name); // Legacy resolver found, using EIP-2544 so it isn't safe to use if (currentName !== name && !(await resolver.supportsWildcard())) { return null; } return resolver; } // Get the parent node currentName = currentName.split(".").slice(1).join("."); } } async _getResolver(name: string, operation?: string): Promise { if (operation == null) { operation = "ENS"; } const network = await this.getNetwork(); // No ENS... if (!network.ensAddress) { logger.throwError( "network does not support ENS", Logger.errors.UNSUPPORTED_OPERATION, { operation, network: network.name } ); } try { // keccak256("resolver(bytes32)") const addrData = await this.call({ to: network.ensAddress, data: ("0x0178b8bf" + namehash(name).substring(2)) }); return this.formatter.callAddress(addrData); } catch (error) { // ENS registry cannot throw errors on resolver(bytes32) } return null; } async resolveName(name: string | Promise): Promise { name = await name; // If it is already an address, nothing to resolve try { return Promise.resolve(this.formatter.address(name)); } catch (error) { // If is is a hexstring, the address is bad (See #694) if (isHexString(name)) { throw error; } } if (typeof(name) !== "string") { logger.throwArgumentError("invalid ENS name", "name", name); } // Get the addr from the resolver const resolver = await this.getResolver(name); if (!resolver) { return null; } return await resolver.getAddress(); } async lookupAddress(address: string | Promise): Promise { address = await address; address = this.formatter.address(address); const node = address.substring(2).toLowerCase() + ".addr.reverse"; const resolverAddr = await this._getResolver(node, "lookupAddress"); if (resolverAddr == null) { return null; } // keccak("name(bytes32)") const name = _parseString(await this.call({ to: resolverAddr, data: ("0x691f3431" + namehash(node).substring(2)) }), 0); const addr = await this.resolveName(name); if (addr != address) { return null; } return name; } async getAvatar(nameOrAddress: string): Promise { let resolver: Resolver = null; if (isHexString(nameOrAddress)) { // Address; reverse lookup const address = this.formatter.address(nameOrAddress); const node = address.substring(2).toLowerCase() + ".addr.reverse"; const resolverAddress = await this._getResolver(node, "getAvatar"); if (!resolverAddress) { return null; } // Try resolving the avatar against the addr.reverse resolver resolver = new Resolver(this, resolverAddress, node); try { const avatar = await resolver.getAvatar(); if (avatar) { return avatar.url; } } catch (error) { if (error.code !== Logger.errors.CALL_EXCEPTION) { throw error; } } // Try getting the name and performing forward lookup; allowing wildcards try { // keccak("name(bytes32)") const name = _parseString(await this.call({ to: resolverAddress, data: ("0x691f3431" + namehash(node).substring(2)) }), 0); resolver = await this.getResolver(name); } catch (error) { if (error.code !== Logger.errors.CALL_EXCEPTION) { throw error; } return null; } } else { // ENS name; forward lookup with wildcard resolver = await this.getResolver(nameOrAddress); if (!resolver) { return null; } } const avatar = await resolver.getAvatar(); if (avatar == null) { return null; } return avatar.url; } perform(method: string, params: any): Promise { return logger.throwError(method + " not implemented", Logger.errors.NOT_IMPLEMENTED, { operation: method }); } _startEvent(event: Event): void { this.polling = (this._events.filter((e) => e.pollable()).length > 0); } _stopEvent(event: Event): void { this.polling = (this._events.filter((e) => e.pollable()).length > 0); } _addEventListener(eventName: EventType, listener: Listener, once: boolean): this { const event = new Event(getEventTag(eventName), listener, once) this._events.push(event); this._startEvent(event); return this; } on(eventName: EventType, listener: Listener): this { return this._addEventListener(eventName, listener, false); } once(eventName: EventType, listener: Listener): this { return this._addEventListener(eventName, listener, true); } emit(eventName: EventType, ...args: Array): boolean { let result = false; let stopped: Array = [ ]; let eventTag = getEventTag(eventName); this._events = this._events.filter((event) => { if (event.tag !== eventTag) { return true; } setTimeout(() => { event.listener.apply(this, args); }, 0); result = true; if (event.once) { stopped.push(event); return false; } return true; }); stopped.forEach((event) => { this._stopEvent(event); }); return result; } listenerCount(eventName?: EventType): number { if (!eventName) { return this._events.length; } let eventTag = getEventTag(eventName); return this._events.filter((event) => { return (event.tag === eventTag); }).length; } listeners(eventName?: EventType): Array { if (eventName == null) { return this._events.map((event) => event.listener); } let eventTag = getEventTag(eventName); return this._events .filter((event) => (event.tag === eventTag)) .map((event) => event.listener); } off(eventName: EventType, listener?: Listener): this { if (listener == null) { return this.removeAllListeners(eventName); } const stopped: Array = [ ]; let found = false; let eventTag = getEventTag(eventName); this._events = this._events.filter((event) => { if (event.tag !== eventTag || event.listener != listener) { return true; } if (found) { return true; } found = true; stopped.push(event); return false; }); stopped.forEach((event) => { this._stopEvent(event); }); return this; } removeAllListeners(eventName?: EventType): this { let stopped: Array = [ ]; if (eventName == null) { stopped = this._events; this._events = [ ]; } else { const eventTag = getEventTag(eventName); this._events = this._events.filter((event) => { if (event.tag !== eventTag) { return true; } stopped.push(event); return false; }); } stopped.forEach((event) => { this._stopEvent(event); }); return this; } }