Features

Public keys and Signers

On this page, we'll see how to manage public keys and signers in Umi which is partially made possible by the EdDSA interface.

The EdDSA interface is used to create keypairs, find PDAs and sign/verify messages using the EdDSA algorithm. We can either use this interface directly and/or use helper methods that delegate to this interface to provide a better developer experience.

Let's tackle this on a per-use case basis.

Looking for a snippet to use the Wallet Adapter or a Filesystem wallet? Check out the Getting Started Page!

Public keys

In Umi, a public key is a simple base58 string representing a 32-byte array. We use an opaque type to tell TypeScript that the given public key has been verified and is valid. We also use a type parameter to offer more granular type safety.

// In short:
type PublicKey = string;

// In reality:
type PublicKey<TAddress extends string = string> = TAddress & { __publicKey: unique symbol };

We can create a new valid public key from a variety of inputs using the publicKey helper method. If the provided input cannot be converted to a valid public key, an error will be thrown.

// From a base58 string.
publicKey('LorisCg1FTs89a32VSrFskYDgiRbNQzct1WxyZb7nuA');

// From a 32-byte buffer.
publicKey(new Uint8Array(32));

// From a PublicKey or Signer type.
publicKey(someWallet as PublicKey | Signer);

It is possible to convert a public key to a Uint8Array using the publicKeyBytes helper method.

publicKeyBytes(myPublicKey);
// -> Uint8Array(32)

Additional helper methods are also available to help manage public keys.

// Check if the provided value is a valid public key.
isPublicKey(myPublicKey);

// Assert the provided value is a valid public key and fail otherwise.
assertPublicKey(myPublicKey);

// Deduplicate an array of public keys.
uniquePublicKeys(myPublicKeys);

// Create the default public key which is a 32-bytes array of zeros.
defaultPublicKey();

PDAs

A PDA — or Program-Derived Address — is a public key that is derived from a program ID and an array of predefined seeds. A bump number ranging from 0 to 255 is required to ensure the PDA does not live on the EdDSA elliptic curve and therefore does not conflict with cryptographically generated public keys.

In Umi, PDAs are represented as a tuple composed of the derived public key and the bump number. Similarly to public keys, it uses opaque types and type parameters.

// In short:
type Pda = [PublicKey, number];

// In reality:
export type Pda<
  TAddress extends string = string,
  TBump extends number = number
> = [PublicKey<TAddress>, TBump] & { readonly __pda: unique symbol };

To derive a new PDA, we can use the findPda method of the EdDSA interface.

const pda = umi.eddsa.findPda(programId, seeds);

Each seed must be serialized as a Uint8Array. You can learn more about serializers on the Serializers page but here is a quick example showing how to find the metadata PDA of a given mint address.

import { publicKey } from '@metaplex-foundation/umi';
import { publicKey as publicKeySerializer, string } from '@metaplex-foundation/umi/serializers';

const tokenMetadataProgramId = publicKey('metaqbxxUerdq28cj1RbAWkYQm3ybzjb6a8bt518x1s');
const metadata = umi.eddsa.findPda(tokenMetadataProgramId, [
  string({ size: 'variable' }).serialize('metadata'),
  publicKeySerializer().serialize(tokenMetadataProgramId),
  publicKeySerializer().serialize(mint),
]);

Note that in most cases, programs will provide helper methods to find specific PDAs. For instance, the code snippet above can be simplified to the following using the findMetadataPda method of the @metaplex-foundation/mpl-token-metadata Kinobi-generated library.

import { findMetadataPda } from '@metaplex-foundation/mpl-token-metadata';

const metadata = findMetadataPda(umi, { mint })

The following helper methods are also available to help manage PDAs.

// Check if the provided value is a Pda.
isPda(myPda);

// Check if the provided public key is on the EdDSA elliptic curve.
umi.eddsa.isOnCurve(myPublicKey);

Signers

A signer is a public key that can sign transactions and messages. This enables transactions to be signed by the required accounts and wallets to prove their identity by signing messages. In Umi, it is represented by the following interface.

interface Signer {
  publicKey: PublicKey;
  signMessage(message: Uint8Array): Promise<Uint8Array>;
  signTransaction(transaction: Transaction): Promise<Transaction>;
  signAllTransactions(transactions: Transaction[]): Promise<Transaction[]>;
}

You may generate a new signer cryptographically using the generateSigner helper method. Under the hood, this method uses the generateKeypair method of the EdDSA interface as described in the next section.

const mySigner = generateSigner(umi);

The following helper functions can also be used to manage signers.

// Check if the provided value is a Signer.
isSigner(mySigner);

// Deduplicate an array of signers by public key.
uniqueSigners(mySigners);

As mentioned in the Umi interfaces page, the Umi interface stores two instances of Signer: The identity using the app and the payer paying for transaction and storage fees. Umi provides plugins to quickly assign new signers to these attributes. The signerIdentity and signerPayer plugins are available for this purpose. Note that, by default, the signerIdentity method will also update the payer attribute since, in most cases, the identity is also the payer.

umi.use(signerIdentity(mySigner));
// Is equivalent to:
umi.identity = mySigner;
umi.payer = mySigner;

umi.use(signerIdentity(mySigner, false));
// Is equivalent to:
umi.identity = mySigner;

umi.use(signerPayer(mySigner));
// Is equivalent to:
umi.payer = mySigner;

You may also use the generatedSignerIdentity and generatedSignerPayer plugins to generate a new signer and immediately assign it to the identity and/or payer attributes.

umi.use(generatedSignerIdentity());
umi.use(generatedSignerPayer());

In some cases, a library may require a Signer to be provided but the current environment does not have access to this wallet as a signer. For instance, this can happen if a transaction is being created on the client but will be later on signed on a private server. It's for that reason that Umi provides a createNoopSigner helper that creates a new signer from the given public key and simply ignores any signing request. It is then your responsibility to ensure that the transaction is signed before being sent to the blockchain.

const mySigner = createNoopSigner(myPublicKey);

Keypairs

Whilst Umi only relies on the Signer interface to request signatures from a wallet, it also defines a Keypair type and a KeypairSigner type that are explicitly aware of their secret key.

type KeypairSigner = Signer & Keypair;
type Keypair = {
  publicKey: PublicKey;
  secretKey: Uint8Array;
};

The generateKeypair, createKeypairFromSeed and createKeypairFromSecretKey methods of the EdDSA interface can be used to generate new Keypair objects.

// Generate a new random keypair.
const myKeypair = umi.eddsa.generateKeypair();

// Restore a keypair using a seed.
const myKeypair = umi.eddsa.createKeypairFromSeed(mySeed);

// Restore a keypair using its secret key.
const myKeypair = umi.eddsa.createKeypairFromSecretKey(mySecretKey);

In order to use these keypairs as signers throughout your application, you can use the createSignerFromKeypair helper method. This method will return an instance of KeypairSigner to ensure that we can access the secret key when needed.

const myKeypair = umi.eddsa.generateKeypair();
const myKeypairSigner = createSignerFromKeypair(umi, myKeypair);

Note that the code snippet above is equivalent to using the generateSigner helper method described in the previous section.

Helper functions and plugins also exist to manage keypairs.

// Check if the provided signer is a KeypairSigner object.
isKeypairSigner(mySigner);

// Register a new keypair as the identity and payer.
umi.use(keypairIdentity(myKeypair));

// Register a new keypair as the payer only.
umi.use(keypairPayer(myKeypair));

Signing messages

The Signer object and the EdDSA interface can be used together to sign and verify messages like so.

const myMessage = utf8.serialize('Hello, world!');
const mySignature = await mySigner.signMessage(myMessage)
const mySignatureIsCorrect = umi.eddsa.verify(myMessage, mySignature, mySigner.publicKey);

Signing transactions

Once we have a Signer instance, signing a transaction or a set of transactions is as simple as calling the signTransaction or signAllTransactions methods.

const mySignedTransaction = await mySigner.signTransaction(myTransaction);
const mySignedTransactions = await mySigner.signAllTransactions(myTransactions);

If you need multiple signers to all sign the same transaction, you may use the signTransaction helper method like so.

const mySignedTransaction = await signTransaction(myTransaction, mySigners);

Going one step further, if you have multiple transactions that each need to be signed by one or more signers, the signAllTransactions function can help you with that. It will even ensure that, if a signer is required to sign more than one transaction, it will use the signer.signAllTransactions method on all of them at once.

// In this example, mySigner2 will sign both transactions
// using the signAllTransactions method.
const mySignedTransactions = await signAllTransactions([
  { transaction: myFirstTransaction, signers: [mySigner1, mySigner2] },
  { transaction: mySecondTransaction, signers: [mySigner2, mySigner3] }
]);

If you are creating a Signer manually and therefore implementing its signTransaction method, you may want to use the addTransactionSignature helper function to add the signature to the transaction. This will ensure the provided signature is required by the transaction and pushed at the right index of the transaction's signatures array.

const mySignedTransaction = addTransactionSignature(myTransaction, mySignature, myPublicKey);
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