Struct solana_program::message::legacy::Message

pub struct Message {
    pub header: MessageHeader,
    pub account_keys: Vec<Pubkey>,
    pub recent_blockhash: Hash,
    pub instructions: Vec<CompiledInstruction>,
}

A Solana transaction message (legacy).

See the message module documentation for further description.

Some constructors accept an optional payer, the account responsible for paying the cost of executing a transaction. In most cases, callers should specify the payer explicitly in these constructors. In some cases though, the caller is not required to specify the payer, but is still allowed to: in the Message structure, the first account is always the fee-payer, so if the caller has knowledge that the first account of the constructed transaction’s Message is both a signer and the expected fee-payer, then redundantly specifying the fee-payer is not strictly required.

Fields

header: MessageHeader

The message header, identifying signed and read-only account_keys.

account_keys: Vec<Pubkey>

All the account keys used by this transaction.

recent_blockhash: Hash

The id of a recent ledger entry.

instructions: Vec<CompiledInstruction>

Programs that will be executed in sequence and committed in one atomic transaction if all succeed.

Implementations

impl Message

pub fn new(instructions: &[Instruction], payer: Option<&Pubkey>) -> Self

Create a new Message.

Examples

This example uses the solana_sdk, solana_rpc_client and anyhow crates.

use anyhow::Result;
use borsh::{BorshSerialize, BorshDeserialize};
use solana_rpc_client::rpc_client::RpcClient;
use solana_sdk::{
    instruction::Instruction,
    message::Message,
    pubkey::Pubkey,
    signature::{Keypair, Signer},
    transaction::Transaction,
};

// A custom program instruction. This would typically be defined in
// another crate so it can be shared between the on-chain program and
// the client.
#[derive(BorshSerialize, BorshDeserialize)]
enum BankInstruction {
    Initialize,
    Deposit { lamports: u64 },
    Withdraw { lamports: u64 },
}

fn send_initialize_tx(
    client: &RpcClient,
    program_id: Pubkey,
    payer: &Keypair
) -> Result<()> {

    let bank_instruction = BankInstruction::Initialize;

    let instruction = Instruction::new_with_borsh(
        program_id,
        &bank_instruction,
        vec![],
    );

    let message = Message::new(
        &[instruction],
        Some(&payer.pubkey()),
    );

    let blockhash = client.get_latest_blockhash()?;
    let mut tx = Transaction::new(&[payer], message, blockhash);
    client.send_and_confirm_transaction(&tx)?;

    Ok(())
}

pub fn new_with_blockhash( instructions: &[Instruction], payer: Option<&Pubkey>, blockhash: &Hash ) -> Self

Create a new message while setting the blockhash.

Examples

This example uses the solana_sdk, solana_rpc_client and anyhow crates.

use anyhow::Result;
use borsh::{BorshSerialize, BorshDeserialize};
use solana_rpc_client::rpc_client::RpcClient;
use solana_sdk::{
    instruction::Instruction,
    message::Message,
    pubkey::Pubkey,
    signature::{Keypair, Signer},
    transaction::Transaction,
};

// A custom program instruction. This would typically be defined in
// another crate so it can be shared between the on-chain program and
// the client.
#[derive(BorshSerialize, BorshDeserialize)]
enum BankInstruction {
    Initialize,
    Deposit { lamports: u64 },
    Withdraw { lamports: u64 },
}

fn send_initialize_tx(
    client: &RpcClient,
    program_id: Pubkey,
    payer: &Keypair
) -> Result<()> {

    let bank_instruction = BankInstruction::Initialize;

    let instruction = Instruction::new_with_borsh(
        program_id,
        &bank_instruction,
        vec![],
    );

    let blockhash = client.get_latest_blockhash()?;

    let message = Message::new_with_blockhash(
        &[instruction],
        Some(&payer.pubkey()),
        &blockhash,
    );

    let mut tx = Transaction::new_unsigned(message);
    tx.sign(&[payer], tx.message.recent_blockhash);
    client.send_and_confirm_transaction(&tx)?;

    Ok(())
}

pub fn new_with_nonce( instructions: Vec<Instruction>, payer: Option<&Pubkey>, nonce_account_pubkey: &Pubkey, nonce_authority_pubkey: &Pubkey ) -> Self

Create a new message for a nonced transaction.

In this type of transaction, the blockhash is replaced with a durable transaction nonce, allowing for extended time to pass between the transaction’s signing and submission to the blockchain.

Examples

This example uses the solana_sdk, solana_rpc_client and anyhow crates.

use anyhow::Result;
use borsh::{BorshSerialize, BorshDeserialize};
use solana_rpc_client::rpc_client::RpcClient;
use solana_sdk::{
    hash::Hash,
    instruction::Instruction,
    message::Message,
    nonce,
    pubkey::Pubkey,
    signature::{Keypair, Signer},
    system_instruction,
    transaction::Transaction,
};

// A custom program instruction. This would typically be defined in
// another crate so it can be shared between the on-chain program and
// the client.
#[derive(BorshSerialize, BorshDeserialize)]
enum BankInstruction {
    Initialize,
    Deposit { lamports: u64 },
    Withdraw { lamports: u64 },
}

// Create a nonced transaction for later signing and submission,
// returning it and the nonce account's pubkey.
fn create_offline_initialize_tx(
    client: &RpcClient,
    program_id: Pubkey,
    payer: &Keypair
) -> Result<(Transaction, Pubkey)> {

    let bank_instruction = BankInstruction::Initialize;
    let bank_instruction = Instruction::new_with_borsh(
        program_id,
        &bank_instruction,
        vec![],
    );

    // This will create a nonce account and assign authority to the
    // payer so they can sign to advance the nonce and withdraw its rent.
    let nonce_account = make_nonce_account(client, payer)?;

    let mut message = Message::new_with_nonce(
        vec![bank_instruction],
        Some(&payer.pubkey()),
        &nonce_account,
        &payer.pubkey()
    );

    // This transaction will need to be signed later, using the blockhash
    // stored in the nonce account.
    let tx = Transaction::new_unsigned(message);

    Ok((tx, nonce_account))
}

fn make_nonce_account(client: &RpcClient, payer: &Keypair)
    -> Result<Pubkey>
{
    let nonce_account_address = Keypair::new();
    let nonce_account_size = nonce::State::size();
    let nonce_rent = client.get_minimum_balance_for_rent_exemption(nonce_account_size)?;

    // Assigning the nonce authority to the payer so they can sign for the withdrawal,
    // and we can throw away the nonce address secret key.
    let create_nonce_instr = system_instruction::create_nonce_account(
        &payer.pubkey(),
        &nonce_account_address.pubkey(),
        &payer.pubkey(),
        nonce_rent,
    );

    let mut nonce_tx = Transaction::new_with_payer(&create_nonce_instr, Some(&payer.pubkey()));
    let blockhash = client.get_latest_blockhash()?;
    nonce_tx.sign(&[&payer, &nonce_account_address], blockhash);
    client.send_and_confirm_transaction(&nonce_tx)?;

    Ok(nonce_account_address.pubkey())
}

pub fn new_with_compiled_instructions( num_required_signatures: u8, num_readonly_signed_accounts: u8, num_readonly_unsigned_accounts: u8, account_keys: Vec<Pubkey>, recent_blockhash: Hash, instructions: Vec<CompiledInstruction> ) -> Self

pub fn hash(&self) -> Hash

Compute the blake3 hash of this transaction’s message.

pub fn hash_raw_message(message_bytes: &[u8]) -> Hash

Compute the blake3 hash of a raw transaction message.

pub fn compile_instruction(&self, ix: &Instruction) -> CompiledInstruction

pub fn serialize(&self) -> Vec<u8>

pub fn program_id(&self, instruction_index: usize) -> Option<&Pubkey>

pub fn program_index(&self, instruction_index: usize) -> Option<usize>

pub fn program_ids(&self) -> Vec<&Pubkey>

pub fn is_key_passed_to_program(&self, key_index: usize) -> bool

pub fn is_key_called_as_program(&self, key_index: usize) -> bool

pub fn is_non_loader_key(&self, key_index: usize) -> bool

pub fn program_position(&self, index: usize) -> Option<usize>

pub fn maybe_executable(&self, i: usize) -> bool

pub fn demote_program_id(&self, i: usize) -> bool

pub fn is_writable(&self, i: usize) -> bool

pub fn is_signer(&self, i: usize) -> bool

pub fn get_account_keys_by_lock_type(&self) -> (Vec<&Pubkey>, Vec<&Pubkey>)

👎Deprecated

pub fn deserialize_instruction( index: usize, data: &[u8] ) -> Result<Instruction, SanitizeError>

👎Deprecated

pub fn signer_keys(&self) -> Vec<&Pubkey>

pub fn has_duplicates(&self) -> bool

Returns true if account_keys has any duplicate keys.

pub fn is_upgradeable_loader_present(&self) -> bool

Returns true if any account is the BPF upgradeable loader.

Trait Implementations

impl AbiExample for Message

fn example() -> Self

impl Clone for Message

fn clone(&self) -> Message

Returns a copy of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl Debug for Message

fn fmt(&self, f: &mut Formatter<'_>) -> Result

Formats the value using the given formatter.

impl Default for Message

fn default() -> Message

Returns the “default value” for a type.

impl<'de> Deserialize<'de> for Message

fn deserialize<__D>(__deserializer: __D) -> Result<Self, __D::Error>where __D: Deserializer<'de>,

Deserialize this value from the given Serde deserializer.

impl From<Message> for JsValue

fn from(value: Message) -> Self

Converts to this type from the input type.

impl FromWasmAbi for Message

type Abi = u32

The wasm ABI type that this converts from when coming back out from the ABI boundary.

unsafe fn from_abi(js: u32) -> Self

Recover a Self from Self::Abi.

impl IntoWasmAbi for Message

type Abi = u32

The wasm ABI type that this converts into when crossing the ABI boundary.

fn into_abi(self) -> u32

Convert self into Self::Abi so that it can be sent across the wasm ABI boundary.

impl LongRefFromWasmAbi for Message

type Abi = u32

Same as RefFromWasmAbi::Abi

type Anchor = Ref<'static, Message>

Same as RefFromWasmAbi::Anchor

unsafe fn long_ref_from_abi(js: Self::Abi) -> Self::Anchor

Same as RefFromWasmAbi::ref_from_abi

impl OptionFromWasmAbi for Message

fn is_none(abi: &Self::Abi) -> bool

Tests whether the argument is a “none” instance. If so it will be deserialized as None, and otherwise it will be passed to FromWasmAbi.

impl OptionIntoWasmAbi for Message

fn none() -> Self::Abi

Returns an ABI instance indicating “none”, which JS will interpret as the None branch of this option.

impl PartialEq<Message> for Message

fn eq(&self, other: &Message) -> bool

This method tests for self and other values to be equal, and is used by ==.

fn ne(&self, other: &Rhs) -> bool

This method tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.

impl RefFromWasmAbi for Message

type Abi = u32

The wasm ABI type references to Self are recovered from.

type Anchor = Ref<'static, Message>

The type that holds the reference to Self for the duration of the invocation of the function that has an &Self parameter. This is required to ensure that the lifetimes don’t persist beyond one function call, and so that they remain anonymous.

unsafe fn ref_from_abi(js: Self::Abi) -> Self::Anchor

Recover a Self::Anchor from Self::Abi.

impl RefMutFromWasmAbi for Message

type Abi = u32

Same as RefFromWasmAbi::Abi

type Anchor = RefMut<'static, Message>

Same as RefFromWasmAbi::Anchor

unsafe fn ref_mut_from_abi(js: Self::Abi) -> Self::Anchor

Same as RefFromWasmAbi::ref_from_abi

impl Sanitize for Message

fn sanitize(&self) -> Result<(), SanitizeError>

impl Serialize for Message

fn serialize<__S>(&self, __serializer: __S) -> Result<__S::Ok, __S::Error>where __S: Serializer,

Serialize this value into the given Serde serializer.

impl TryFrom<Message> for SanitizedMessage

type Error = SanitizeMessageError

The type returned in the event of a conversion error.

fn try_from(message: Message) -> Result<Self, Self::Error>

Performs the conversion.

impl WasmDescribe for Message

fn describe()

impl Eq for Message

impl StructuralEq for Message

impl StructuralPartialEq for Message