The Wormhole Typescript SDK is useful for interacting with the chains Wormhole supports and the protocols built on top of Wormhole.
Install the (meta) package
npm install @wormhole-foundation/sdk
This package combines all the individual packages in a way that makes setup easier while still allowing for tree shaking.
Alternatively, for an advanced user, install a specific set of the packages published.
# constants
npm install @wormhole-foundation/sdk-base
# contract interfaces, basic types, vaa payload definitions
npm install @wormhole-foundation/sdk-definitions
# Evm specific utilities
npm install @wormhole-foundation/sdk-evm
# Evm TokenBridge protocol client
npm install @wormhole-foundation/sdk-evm-tokenbridge
Getting started is simple, just import the 'meta' Wormhole package, that makes sure all Platform modules are installed.
import { wormhole } from "@wormhole-foundation/sdk";
See example here
And pass those to the Wormhole constructor to make them available for use
const wh = await wormhole("Testnet", [evm, solana, aptos, algorand, cosmwasm, sui]);
See example here
With a configured Wormhole object, we have the ability to do things like; parse addresses for the platforms we passed, get a ChainContext object, or fetch VAAs.
// Grab a ChainContext object from our configured Wormhole instance
const ctx = wh.getChain("Solana");
See example here
// Get the VAA from the wormhole message id
const vaa = await wh.getVaa(
// Wormhole Message ID
whm!,
// Protocol:Payload name to use for decoding the VAA payload
"TokenBridge:Transfer",
// Timeout in milliseconds, depending on the chain and network, the VAA may take some time to be available
60_000,
);
See example here
Optionally, the default configuration may be overriden in the case that you want to support, eg a different RPC endpoint.
// Pass a partial WormholeConfig object to override specific
// fields in the default config
const wh = await wormhole("Testnet", [solana], {
chains: {
Solana: {
contracts: {
coreBridge: "11111111111111111111111111111",
},
rpc: "https://api.devnet.solana.com",
},
},
});
See example here
Understanding several higher level concepts of the SDK will help in using it effectively.
Every chain is its own special snowflake but many of them share similar functionality. The Platform
modules provide a consistent interface for interacting with the chains that share a platform.
Each platform can be installed separately so that dependencies can stay as slim as possible.
See all supported platforms here
The Wormhole
class provides a getChain
method that returns a ChainContext
object for a given chain. This object provides access to the chain specific methods and utilities. Much of the functionality in the ChainContext
is provided by the Platform
methods but the specific chain may have overridden methods.
The ChainContext object is also responsible for holding a cached rpc client and protocol clients.
// Get the chain context for the source and destination chains
// This is useful to grab direct clients for the protocols
const srcChain = wh.getChain(senderAddress.chain);
const dstChain = wh.getChain(receiverAddress.chain);
const tb = await srcChain.getTokenBridge(); // => TokenBridge<'Evm'>
srcChain.getRpcClient(); // => RpcClient<'Evm'>
Within the Wormhole context, addresses are often normalized to 32 bytes and referred to in this SDK as a UniversalAddresses
.
Each platform comes with an address type that understands the native address formats, unsurprisingly referred to as NativeAddress. This abstraction allows the SDK to work with addresses in a consistent way regardless of the underlying chain.
// Its possible to convert a string address to its Native address
const ethAddr: NativeAddress<"Evm"> = toNative("Ethereum", "0xbeef...");
// A common type in the SDK is the `ChainAddress` which provides
// the additional context of the `Chain` this address is relevant for.
const senderAddress: ChainAddress = Wormhole.chainAddress("Ethereum","0xbeef...");
const receiverAddress: ChainAddress = Wormhole.chainAddress("Solana","Sol1111...");
// Convert the ChainAddress back to its canonical string address format
const strAddress = Wormhole.canonicalAddress(senderAddress); // => '0xbeef...'
// Or if the ethAddr above is for an emitter and you need the UniversalAddress
const emitterAddr = ethAddr.toUniversalAddress().toString()
Similar to the ChainAddress
type, the TokenId
type provides the Chain and Address of a given Token.
// Returns a TokenId
const sourceToken: TokenId = Wormhole.tokenId("Ethereum","0xbeef...");
// Whereas the ChainAddress is limited to valid addresses, a TokenId may
// have the string literal 'native' to consistently denote the native
// gas token of the chain
const gasToken: TokenId = Wormhole.tokenId("Ethereum","native");
// the same method can be used to convert the TokenId back to its canonical string address format
const strAddress = Wormhole.canonicalAddress(senderAddress); // => '0xbeef...'
In order to sign transactions, an object that fulfils the Signer
interface is required. This is a simple interface that can be implemented by wrapping a web wallet or other signing mechanism.
// A Signer is an interface that must be provided to certain methods
// in the SDK to sign transactions. It can be either a SignOnlySigner
// or a SignAndSendSigner depending on circumstances.
// A Signer can be implemented by wrapping an existing offline wallet
// or a web wallet
export type Signer = SignOnlySigner | SignAndSendSigner;
// A SignOnlySender is for situations where the signer is not
// connected to the network or does not wish to broadcast the
// transactions themselves
export interface SignOnlySigner {
chain(): ChainName;
address(): string;
// Accept an array of unsigned transactions and return
// an array of signed and serialized transactions.
// The transactions may be inspected or altered before
// signing.
// Note: The serialization is chain specific, if in doubt,
// see the example implementations linked below
sign(tx: UnsignedTransaction[]): Promise<SignedTx[]>;
}
// A SignAndSendSigner is for situations where the signer is
// connected to the network and wishes to broadcast the
// transactions themselves
export interface SignAndSendSigner {
chain(): ChainName;
address(): string;
// Accept an array of unsigned transactions and return
// an array of transaction ids in the same order as the
// UnsignedTransactions array.
signAndSend(tx: UnsignedTransaction[]): Promise<TxHash[]>;
}
See the testing signers (Evm, Solana, ...) for an example of how to implement a signer for a specific chain or platform.
Working with VAAs directly may be necessary. The SDK includes an entire layouting package to define the structure of a VAA payload and provides the ability to easily serialize and deserialize the VAAs or VAA payloads.
Using Uint8Array
as the paylaod type will always work:
// Create a fake vaa and serialize it to bytes
// the first argument to `createVAA` describes the payload type
// in this case, just a Uint8Array of bytes
const fakeVaaBytes = serialize(
createVAA("Uint8Array", {
guardianSet: 0,
timestamp: 0,
nonce: 0,
emitterChain: "Solana",
emitterAddress: new UniversalAddress(new Uint8Array(32)),
sequence: 0n,
consistencyLevel: 0,
signatures: [],
payload: encoding.bytes.encode("hi"),
}),
);
// Deserialize the VAA back into a data structure, in this case
// decoding the payload back into bytes.
// Using Uint8Array will always work but you can use a more specific payload layout type
console.log(deserialize("Uint8Array", fakeVaaBytes));
See example here
But more specific types can be used
// Create a token bridge VAA and serialize it
// The payload type argument here is "TokenBridge:Transfer"
// which is defined in the the TokenBridge protocol definition
const tokenBridgeVaaBytes = serialize(
createVAA("TokenBridge:Transfer", {
guardianSet: 0,
timestamp: 0,
nonce: 0,
emitterChain: "Solana",
emitterAddress: new UniversalAddress(new Uint8Array(32)),
sequence: 0n,
consistencyLevel: 0,
signatures: [],
payload: {
fee: 0n,
token: {
amount: 0n,
address: new UniversalAddress(new Uint8Array(32)),
chain: "Solana",
},
to: {
chain: "Ethereum",
address: new UniversalAddress(new Uint8Array(32)),
},
},
}),
);
// Although we know the payload type is "TokenBridge:Transfer",
// we can still deserialize it as a Uint8Array
console.log(deserialize("Uint8Array", tokenBridgeVaaBytes));
// Or use the correct payload type to get a more specific data structure
console.log(deserialize("TokenBridge:Transfer", tokenBridgeVaaBytes));
See example here
Or define your own
// First define a custom payload layout
const customPayloadLayout = [
// 2 byte integer
{ name: "bar", binary: "uint", size: 2 },
// arbitrary bytes, note this will take the rest of the payload
{ name: "foo", binary: "bytes" },
] as const satisfies Layout;
// Now serialize a VAA with the custom payload layout
const customVaaBytes = serialize(
createVAA("Uint8Array", {
guardianSet: 0,
timestamp: 0,
nonce: 0,
emitterChain: "Solana",
emitterAddress: new UniversalAddress(new Uint8Array(32)),
sequence: 0n,
consistencyLevel: 0,
signatures: [],
// Using `serializeLayout` with the custom layout we created above
payload: serializeLayout(customPayloadLayout, {
bar: 42,
foo: new Uint8Array([1, 2, 3]),
}),
}),
);
// Deserialize the VAA to get the custom payload
const vaa = deserialize("Uint8Array", customVaaBytes);
console.log(encoding.hex.encode(vaa.payload));
console.log(deserializeLayout(customPayloadLayout, vaa.payload));
See example here
While Wormhole itself is a Generic Message Passing protocol, a number of protocols have been built on top of it to provide specific functionality.
Each Protocol, if available, will have a Platform specific implementation. These implementations provide methods to generate transactions or read state from the contract on-chain.
The protocol that underlies all Wormhole activity is the Core protocol. This protocol is responsible for emitting the message containing the information necessary to perform bridging including Emitter address, the Sequence number for the message and the Payload of the message itself.
const wh = await wormhole("Testnet", [solana, evm]);
const chain = wh.getChain("Avalanche");
const { signer, address } = await getSigner(chain);
// Get a reference to the core messaging bridge
const coreBridge = await chain.getWormholeCore();
// Generate transactions, sign and send them
const publishTxs = coreBridge.publishMessage(
// Address of sender (emitter in VAA)
address.address,
// Message to send (payload in VAA)
encoding.bytes.encode("lol"),
// Nonce (user defined, no requirement for a specific value, useful to provide a unique identifier for the message)
0,
// ConsistencyLevel (ie finality of the message, see wormhole docs for more)
0,
);
// Send the transaction(s) to publish the message
const txids = await signSendWait(chain, publishTxs, signer);
// Take the last txid in case multiple were sent
// the last one should be the one containing the relevant
// event or log info
const txid = txids[txids.length - 1];
// Grab the wormhole message id from the transaction logs or storage
const [whm] = await chain.parseTransaction(txid!.txid);
// Or pull the full message content as an Unsigned VAA
// console.log(await coreBridge.parseMessages(txid!.txid));
// Wait for the vaa to be signed and available with a timeout
const vaa = await wh.getVaa(whm!, "Uint8Array", 60_000);
console.log(vaa);
// Also possible to search by txid but it takes longer to show up
// console.log(await wh.getVaaByTxHash(txid!.txid, "Uint8Array"));
// Note: calling verifyMessage manually is typically not a useful thing to do
// as the VAA is typically submitted to the counterpart contract for
// a given protocol and the counterpart contract will verify the VAA
// this is simply for demo purposes
const verifyTxs = coreBridge.verifyMessage(address.address, vaa!);
console.log(await signSendWait(chain, verifyTxs, signer));
See example here
Within the payload is the information necessary to perform whatever action is required based on the Protocol that uses it.
The most familiar protocol built on Wormhole is the Token Bridge.
Every chain has a TokenBridge
protocol client that provides a consistent interface for interacting with the Token Bridge. This includes methods to generate the transactions required to transfer tokens, as well as methods to generate and redeem attestations.
Using the WormholeTransfer
abstractions is the recommended way to interact with these protocols but it is possible to use them directly
import { signSendWait } from "@wormhole-foundation/sdk";
// ...
const tb = await srcChain.getTokenBridge(); // => TokenBridge<'Evm'>
const token = "0xdeadbeef...";
const txGenerator = tb.createAttestation(token); // => AsyncGenerator<UnsignedTransaction, ...>
const txids = await signSendWait(srcChain, txGenerator, src.signer); // => TxHash[]
Supported protocols are defined in the definitions module.
While using the ChainContext and Protocol clients directly is possible, to do things like transfer tokens, the SDK provides some helpful abstractions.
The WormholeTransfer
interface provides a convenient abstraction to encapsulate the steps involved in a cross-chain transfer.
Performing a Token Transfer is trivial for any source and destination chains.
We can create a new Wormhole
object and use it to to create TokenTransfer
, CircleTransfer
, GatewayTransfer
, etc. objects to transfer tokens between chains. The transfer object is responsible for tracking the transfer through the process and providing updates on its status.
// Create a TokenTransfer object to track the state of the transfer over time
const xfer = await wh.tokenTransfer(
route.token,
route.amount,
route.source.address,
route.destination.address,
route.delivery?.automatic ?? false,
route.payload,
route.delivery?.nativeGas,
);
const quote = await TokenTransfer.quoteTransfer(
wh,
route.source.chain,
route.destination.chain,
xfer.transfer,
);
console.log(quote);
if (xfer.transfer.automatic && quote.destinationToken.amount < 0)
throw "The amount requested is too low to cover the fee and any native gas requested.";
// 1) Submit the transactions to the source chain, passing a signer to sign any txns
console.log("Starting transfer");
const srcTxids = await xfer.initiateTransfer(route.source.signer);
console.log(`Started transfer: `, srcTxids);
// If automatic, we're done
if (route.delivery?.automatic) return xfer;
// 2) Wait for the VAA to be signed and ready (not required for auto transfer)
console.log("Getting Attestation");
const attestIds = await xfer.fetchAttestation(60_000);
console.log(`Got Attestation: `, attestIds);
// 3) Redeem the VAA on the dest chain
console.log("Completing Transfer");
const destTxids = await xfer.completeTransfer(route.destination.signer);
console.log(`Completed Transfer: `, destTxids);
See example here
Internally, this uses the TokenBridge protocol client to transfer tokens. The TokenBridge
protocol, like other Protocols, provides a consistent set of methods across all chains to generate a set of transactions for that specific chain.
We can also transfer native USDC using Circle's CCTP
const xfer = await wh.circleTransfer(
// amount as bigint (base units)
req.amount,
// sender chain/address
src.address,
// receiver chain/address
dst.address,
// automatic delivery boolean
req.automatic,
// payload to be sent with the transfer
undefined,
// If automatic, native gas can be requested to be sent to the receiver
req.nativeGas,
);
// Note, if the transfer is requested to be Automatic, a fee for performing the relay
// will be present in the quote. The fee comes out of the amount requested to be sent.
// If the user wants to receive 1.0 on the destination, the amount to send should be 1.0 + fee.
// The same applies for native gas dropoff
const quote = await CircleTransfer.quoteTransfer(src.chain, dst.chain, xfer.transfer);
console.log("Quote", quote);
console.log("Starting Transfer");
const srcTxids = await xfer.initiateTransfer(src.signer);
console.log(`Started Transfer: `, srcTxids);
// Note: Depending on chain finality, this timeout may need to be increased.
// See https://developers.circle.com/stablecoin/docs/cctp-technical-reference#mainnet for more
console.log("Waiting for Attestation");
const attestIds = await xfer.fetchAttestation(60_000);
console.log(`Got Attestation: `, attestIds);
console.log("Completing Transfer");
const dstTxids = await xfer.completeTransfer(dst.signer);
console.log(`Completed Transfer: `, dstTxids);
See example here
Gateway transfers are transfers that are passed through the Wormhole Gateway to or from Cosmos chains.
A transfer into Cosmos from outside cosmos will be automatically delivered to the destination via IBC from the Gateway chain (fka Wormchain)
console.log(
`Beginning transfer into Cosmos from ${src.chain.chain}:${src.address.address.toString()} to ${
dst.chain.chain
}:${dst.address.address.toString()}`,
);
const xfer = await GatewayTransfer.from(wh, {
token: token,
amount: amount,
from: src.address,
to: dst.address,
} as GatewayTransferDetails);
console.log("Created GatewayTransfer: ", xfer.transfer);
const srcTxIds = await xfer.initiateTransfer(src.signer);
console.log("Started transfer on source chain", srcTxIds);
const attests = await xfer.fetchAttestation(600_000);
console.log("Got Attestations", attests);
See example here
A transfer within Cosmos will use IBC to transfer from the origin to the Gateway chain, then out from the Gateway to the destination chain
console.log(
`Beginning transfer within cosmos from ${
src.chain.chain
}:${src.address.address.toString()} to ${dst.chain.chain}:${dst.address.address.toString()}`,
);
const xfer = await GatewayTransfer.from(wh, {
token: token,
amount: amount,
from: src.address,
to: dst.address,
} as GatewayTransferDetails);
console.log("Created GatewayTransfer: ", xfer.transfer);
const srcTxIds = await xfer.initiateTransfer(src.signer);
console.log("Started transfer on source chain", srcTxIds);
const attests = await xfer.fetchAttestation(60_000);
console.log("Got attests: ", attests);
See example here
A transfer leaving Cosmos will produce a VAA from the Gateway that must be manually redeemed on the destination chain
console.log(
`Beginning transfer out of cosmos from ${
src.chain.chain
}:${src.address.address.toString()} to ${dst.chain.chain}:${dst.address.address.toString()}`,
);
const xfer = await GatewayTransfer.from(wh, {
token: token,
amount: amount,
from: src.address,
to: dst.address,
} as GatewayTransferDetails);
console.log("Created GatewayTransfer: ", xfer.transfer);
const srcTxIds = await xfer.initiateTransfer(src.signer);
console.log("Started transfer on source chain", srcTxIds);
const attests = await xfer.fetchAttestation(600_000);
console.log("Got attests", attests);
// Since we're leaving cosmos, this is required to complete the transfer
const dstTxIds = await xfer.completeTransfer(dst.signer);
console.log("Completed transfer on destination chain", dstTxIds);
See example here
It may be necessary to recover a transfer that was abandoned before being completed. This can be done by instantiating the Transfer class with the from
static method and passing one of several types of identifiers.
A TransactionId
or WormholeMessageId
may be used to recover the transfer
// Rebuild the transfer from the source txid
const xfer = await CircleTransfer.from(wh, txid);
const attestIds = await xfer.fetchAttestation(60 * 60 * 1000);
console.log("Got attestation: ", attestIds);
const dstTxIds = await xfer.completeTransfer(signer);
console.log("Completed transfer: ", dstTxIds);
See example here
While a specific WormholeTransfer
may be used (TokenTransfer, CCTPTransfer, ...), it requires the developer know exactly which transfer type to use for a given request.
To provide a more flexible and generic interface, the Wormhole
class provides a method to produce a RouteResolver
that can be configured with a set of possible routes to be supported.
// create new resolver, passing the set of routes to consider
const resolver = wh.resolver([
routes.TokenBridgeRoute, // manual token bridge
routes.AutomaticTokenBridgeRoute, // automatic token bridge
routes.CCTPRoute, // manual CCTP
routes.AutomaticCCTPRoute, // automatic CCTP
routes.AutomaticPorticoRoute, // Native eth transfers
]);
See example here
Once created, the resolver can be used to provide a list of input and possible output tokens.
// what tokens are available on the source chain?
const srcTokens = await resolver.supportedSourceTokens(sendChain);
console.log(
"Allowed source tokens: ",
srcTokens.map((t) => canonicalAddress(t)),
);
// Grab the first one for the example
// const sendToken = srcTokens[0]!;
const sendToken = Wormhole.tokenId(sendChain.chain, "native");
// given the send token, what can we possibly get on the destination chain?
const destTokens = await resolver.supportedDestinationTokens(sendToken, sendChain, destChain);
console.log(
"For the given source token and routes configured, the following tokens may be receivable: ",
destTokens.map((t) => canonicalAddress(t)),
);
//grab the first one for the example
const destinationToken = destTokens[0]!;
See example here
Once the tokens are selected, a RouteTransferRequest
may be created to provide a list of routes that can fulfil the request
// creating a transfer request fetches token details
// since all routes will need to know about the tokens
const tr = await routes.RouteTransferRequest.create(wh, {
source: sendToken,
destination: destinationToken,
});
// resolve the transfer request to a set of routes that can perform it
const foundRoutes = await resolver.findRoutes(tr);
console.log("For the transfer parameters, we found these routes: ", foundRoutes);
See example here
Choosing the best route is currently left to the developer but strategies might include sorting by output amount or expected time to complete the transfer (no estimate currently provided).
After choosing the best route, extra parameters like amount
, nativeGasDropoff
, and slippage
can be passed, depending on the specific route selected and a quote can be retrieved with the validated request.
console.log("This route offers the following default options", bestRoute.getDefaultOptions());
// Specify the amount as a decimal string
const amt = "0.001";
// Create the transfer params for this request
const transferParams = { amount: amt, options: { nativeGas: 0 } };
// validate the transfer params passed, this returns a new type of ValidatedTransferParams
// which (believe it or not) is a validated version of the input params
// this new var must be passed to the next step, quote
const validated = await bestRoute.validate(tr, transferParams);
if (!validated.valid) throw validated.error;
console.log("Validated parameters: ", validated.params);
// get a quote for the transfer, this too returns a new type that must
// be passed to the next step, execute (if you like the quote)
const quote = await bestRoute.quote(tr, validated.params);
if (!quote.success) throw quote.error;
console.log("Best route quote: ", quote);
See example here
Finally, assuming the quote looks good, the route can initiate the request with the quote and the signer
// Now the transfer may be initiated
// A receipt will be returned, guess what you gotta do with that?
const receipt = await bestRoute.initiate(tr, sender.signer, quote, receiver.address);
console.log("Initiated transfer with receipt: ", receipt);
See example here
Note: See the router.ts
example in the examples directory for a full working example
The tsdoc is available here