JavaScript Client for Solana
What is Solana-Web3.js? #
The Solana-Web3.js library aims to provide complete coverage of Solana. The library was built on top of the Solana JSON RPC API.
You can find the full documentation for the @solana/web3.js
library
here.
Common Terminology #
Term | Definition |
---|---|
Program | Stateless executable code written to interpret instructions. Programs are capable of performing actions based on the instructions provided. |
Instruction | The smallest unit of a program that a client can include in a transaction. Within its processing code, an instruction may contain one or more cross-program invocations. |
Transaction | One or more instructions signed by the client using one or more Keypairs and executed atomically with only two possible outcomes: success or failure. |
For the full list of terms, see Solana terminology
Getting Started #
Installation #
yarn #
yarn add @solana/web3.js
npm #
npm install --save @solana/web3.js
Bundle #
<script src="https://unpkg.com/@solana/web3.js@latest/lib/index.iife.js">
</script>
<script src="https://unpkg.com/@solana/web3.js@latest/lib/index.iife.min.js">
</script>
Usage #
Javascript #
const solanaWeb3 = require("@solana/web3.js");
console.log(solanaWeb3);
ES6 #
import * as solanaWeb3 from "@solana/web3.js";
console.log(solanaWeb3);
Browser Bundle #
// solanaWeb3 is provided in the global namespace by the bundle script
console.log(solanaWeb3);
Quickstart #
Connecting to a Wallet #
To allow users to use your dApp or application on Solana, they will need to get access to their Keypair. A Keypair is a private key with a matching public key, used to sign transactions.
There are two ways to obtain a Keypair:
- Generate a new Keypair
- Obtain a Keypair using the secret key
You can obtain a new Keypair with the following:
const { Keypair } = require("@solana/web3.js");
let keypair = Keypair.generate();
This will generate a brand new Keypair for a user to fund and use within your application.
You can allow entry of the secretKey using a textbox, and obtain the Keypair
with Keypair.fromSecretKey(secretKey)
.
const { Keypair } = require("@solana/web3.js");
let secretKey = Uint8Array.from([
202, 171, 192, 129, 150, 189, 204, 241, 142, 71, 205, 2, 81, 97, 2, 176, 48,
81, 45, 1, 96, 138, 220, 132, 231, 131, 120, 77, 66, 40, 97, 172, 91, 245, 84,
221, 157, 190, 9, 145, 176, 130, 25, 43, 72, 107, 190, 229, 75, 88, 191, 136,
7, 167, 109, 91, 170, 164, 186, 15, 142, 36, 12, 23,
]);
let keypair = Keypair.fromSecretKey(secretKey);
Many wallets today allow users to bring their Keypair using a variety of extensions or web wallets. The general recommendation is to use wallets, not Keypairs, to sign transactions. The wallet creates a layer of separation between the dApp and the Keypair, ensuring that the dApp never has access to the secret key. You can find ways to connect to external wallets with the wallet-adapter library.
Creating and Sending Transactions #
To interact with programs on Solana, you create, sign, and send transactions to the network. Transactions are collections of instructions with signatures. The order that instructions exist in a transaction determines the order they are executed.
A transaction in Solana-Web3.js is created using the
Transaction
object and adding
desired messages, addresses, or instructions.
Take the example of a transfer transaction:
const {
Keypair,
Transaction,
SystemProgram,
LAMPORTS_PER_SOL,
} = require("@solana/web3.js");
let fromKeypair = Keypair.generate();
let toKeypair = Keypair.generate();
let transaction = new Transaction();
transaction.add(
SystemProgram.transfer({
fromPubkey: fromKeypair.publicKey,
toPubkey: toKeypair.publicKey,
lamports: LAMPORTS_PER_SOL,
}),
);
The above code achieves creating a transaction ready to be signed and
broadcasted to the network. The SystemProgram.transfer
instruction was added
to the transaction, containing the amount of lamports to send, and the to
and
from
public keys.
All that is left is to sign the transaction with keypair and send it over the
network. You can accomplish sending a transaction by using
sendAndConfirmTransaction
if you wish to alert the user or do something after
a transaction is finished, or use sendTransaction
if you don't need to wait
for the transaction to be confirmed.
const {
sendAndConfirmTransaction,
clusterApiUrl,
Connection,
} = require("@solana/web3.js");
let keypair = Keypair.generate();
let connection = new Connection(clusterApiUrl("testnet"));
sendAndConfirmTransaction(connection, transaction, [keypair]);
The above code takes in a TransactionInstruction
using SystemProgram
,
creates a Transaction
, and sends it over the network. You use Connection
in
order to define which Solana network you are connecting to, namely
mainnet-beta
, testnet
, or devnet
.
Interacting with Custom Programs #
The previous section visits sending basic transactions. In Solana everything you do interacts with different programs, including the previous section's transfer transaction. At the time of writing programs on Solana are either written in Rust or C.
Let's look at the SystemProgram
. The method signature for allocating space in
your account on Solana in Rust looks like this:
pub fn allocate(
pubkey: &Pubkey,
space: u64
) -> Instruction
In Solana when you want to interact with a program you must first know all the accounts you will be interacting with.
You must always provide every account that the program will be interacting
within the instruction. Not only that, but you must provide whether or not the
account is isSigner
or isWritable
.
In the allocate
method above, a single account pubkey
is required, as well
as an amount of space
for allocation. We know that the allocate
method
writes to the account by allocating space within it, making the pubkey
required to be isWritable
. isSigner
is required when you are designating the
account that is running the instruction. In this case, the signer is the account
calling to allocate space within itself.
Let's look at how to call this instruction using solana-web3.js:
let keypair = web3.Keypair.generate();
let payer = web3.Keypair.generate();
let connection = new web3.Connection(web3.clusterApiUrl("testnet"));
let airdropSignature = await connection.requestAirdrop(
payer.publicKey,
web3.LAMPORTS_PER_SOL,
);
await connection.confirmTransaction({ signature: airdropSignature });
First, we set up the account Keypair and connection so that we have an account to make allocate on the testnet. We also create a payer Keypair and airdrop some sol so we can pay for the allocate transaction.
let allocateTransaction = new web3.Transaction({
feePayer: payer.publicKey,
});
let keys = [{ pubkey: keypair.publicKey, isSigner: true, isWritable: true }];
let params = { space: 100 };
We create the transaction allocateTransaction
, keys, and params objects.
feePayer
is an optional field when creating a transaction that specifies who
is paying for the transaction, defaulting to the pubkey of the first signer in
the transaction. keys
represents all accounts that the program's allocate
function will interact with. Since the allocate
function also required space,
we created params
to be used later when invoking the allocate
function.
let allocateStruct = {
index: 8,
layout: struct([u32("instruction"), ns64("space")]),
};
The above is created using u32
and ns64
from @solana/buffer-layout
to
facilitate the payload creation. The allocate
function takes in the parameter
space
. To interact with the function we must provide the data as a Buffer
format. The buffer-layout
library helps with allocating the buffer and
encoding it correctly for Rust programs on Solana to interpret.
Let's break down this struct.
{
index: 8, /* <-- */
layout: struct([
u32('instruction'),
ns64('space'),
])
}
index
is set to 8 because the function allocate
is in the 8th position in
the instruction enum for SystemProgram
.
/* https://github.com/solana-labs/solana/blob/21bc43ed58c63c827ba4db30426965ef3e807180/sdk/program/src/system_instruction.rs#L142-L305 */
pub enum SystemInstruction {
/** 0 **/CreateAccount {/**/},
/** 1 **/Assign {/**/},
/** 2 **/Transfer {/**/},
/** 3 **/CreateAccountWithSeed {/**/},
/** 4 **/AdvanceNonceAccount,
/** 5 **/WithdrawNonceAccount(u64),
/** 6 **/InitializeNonceAccount(Pubkey),
/** 7 **/AuthorizeNonceAccount(Pubkey),
/** 8 **/Allocate {/**/},
/** 9 **/AllocateWithSeed {/**/},
/** 10 **/AssignWithSeed {/**/},
/** 11 **/TransferWithSeed {/**/},
/** 12 **/UpgradeNonceAccount,
}
Next up is u32('instruction')
.
{
index: 8,
layout: struct([
u32('instruction'), /* <-- */
ns64('space'),
])
}
The layout
in the allocate struct must always have u32('instruction')
first
when you are using it to call an instruction.
{
index: 8,
layout: struct([
u32('instruction'),
ns64('space'), /* <-- */
])
}
ns64('space')
is the argument for the allocate
function. You can see in the
original allocate
function in Rust that space was of the type u64
. u64
is
an unsigned 64bit integer. Javascript by default only provides up to 53bit
integers. ns64
comes from @solana/buffer-layout
to help with type
conversions between Rust and Javascript. You can find more type conversions
between Rust and Javascript at
solana-labs/buffer-layout.
let data = Buffer.alloc(allocateStruct.layout.span);
let layoutFields = Object.assign({ instruction: allocateStruct.index }, params);
allocateStruct.layout.encode(layoutFields, data);
Using the previously created bufferLayout, we can allocate a data buffer. We
then assign our params { space: 100 }
so that it maps correctly to the layout,
and encode it to the data buffer. Now the data is ready to be sent to the
program.
allocateTransaction.add(
new web3.TransactionInstruction({
keys,
programId: web3.SystemProgram.programId,
data,
}),
);
await web3.sendAndConfirmTransaction(connection, allocateTransaction, [
payer,
keypair,
]);
Finally, we add the transaction instruction with all the account keys, payer, data, and programId and broadcast the transaction to the network.
The full code can be found below.
const { struct, u32, ns64 } = require("@solana/buffer-layout");
const { Buffer } = require("buffer");
const web3 = require("@solana/web3.js");
let keypair = web3.Keypair.generate();
let payer = web3.Keypair.generate();
let connection = new web3.Connection(web3.clusterApiUrl("testnet"));
let airdropSignature = await connection.requestAirdrop(
payer.publicKey,
web3.LAMPORTS_PER_SOL,
);
await connection.confirmTransaction({ signature: airdropSignature });
let allocateTransaction = new web3.Transaction({
feePayer: payer.publicKey,
});
let keys = [{ pubkey: keypair.publicKey, isSigner: true, isWritable: true }];
let params = { space: 100 };
let allocateStruct = {
index: 8,
layout: struct([u32("instruction"), ns64("space")]),
};
let data = Buffer.alloc(allocateStruct.layout.span);
let layoutFields = Object.assign({ instruction: allocateStruct.index }, params);
allocateStruct.layout.encode(layoutFields, data);
allocateTransaction.add(
new web3.TransactionInstruction({
keys,
programId: web3.SystemProgram.programId,
data,
}),
);
await web3.sendAndConfirmTransaction(connection, allocateTransaction, [
payer,
keypair,
]);