3 releases

0.0.8 Nov 6, 2024
0.0.7 Nov 6, 2024

#957 in Magic Beans

Download history 358/week @ 2024-11-04 14/week @ 2024-11-11

372 downloads per month
Used in 3 crates (2 directly)

MIT license

7KB

Mollusk

SVM program test harness.

Harness

The harness is designed to directly invoke the loaded executable program using the BPF Loader, bypassing any transaction sanitization and runtime checks, and instead directly processing the instruction with the BPF Loader.

let program_id = Pubkey::new_unique();
let key1 = Pubkey::new_unique();
let key2 = Pubkey::new_unique();

let instruction = Instruction::new_with_bytes(
    program_id,
    &[],
    vec![
        AccountMeta::new(key1, false),
        AccountMeta::new_readonly(key2, false),
    ],
);

let accounts = vec![
    (key1, AccountSharedData::new(10_000, 0, &system_program::id())),
    (key2, AccountSharedData::new(10_000, 0, &system_program::id())),
];

let mollusk = Mollusk::new(program_id, "my_program");

let result = mollusk.process_instruction(&instruction, &accounts);

You can also use the Checks API provided by Mollusk for easy post-execution checks, rather than writing them manually. The API method process_and_validate_instruction will still return the result, allowing you to perform further checks if you desire.

Note: Mollusk::default() will use the System program as the program to invoke.

let sender = Pubkey::new_unique();
let recipient = Pubkey::new_unique();

let base_lamports = 100_000_000u64;
let transfer_amount = 42_000u64;

let instruction = system_instruction::transfer(&sender, &recipient, transfer_amount);
let accounts = [
    (
        sender,
        AccountSharedData::new(base_lamports, 0, &system_program::id()),
    ),
    (
        recipient,
        AccountSharedData::new(base_lamports, 0, &system_program::id()),
    ),
];
let checks = vec![
    Check::success(),
    Check::compute_units(system_processor::DEFAULT_COMPUTE_UNITS),
    Check::account(&sender)
        .lamports(base_lamports - transfer_amount)
        .build(),
    Check::account(&recipient)
        .lamports(base_lamports + transfer_amount)
        .build(),
];

Mollusk::default().process_and_validate_instruction(&instruction, &accounts, &checks);

Bencher

Mollusk also offers a compute unit usage bencher for profiling a program's compute unit usage.

Example:

// If using with `cargo bench`, tell Mollusk where to find the program.
std::env::set_var("SBF_OUT_DIR", "../target/deploy");

// Optionally disable logging.
solana_logger::setup_with("");

/* Instruction & accounts setup ... */

let mollusk = Mollusk::new(&program_id, "my_program");

MolluskComputeUnitBencher::new(mollusk)
    .bench(("bench0", &instruction0, &accounts0))
    .bench(("bench1", &instruction1, &accounts1))
    .bench(("bench2", &instruction2, &accounts2))
    .bench(("bench3", &instruction3, &accounts3))
    .must_pass(true)
    .out_dir("../target/benches")
    .execute();

You can invoke this benchmark test with cargo bench. Don't forget to add a bench to your project's Cargo.toml.

[[bench]]
name = "compute_units"
harness = false

Mollusk will output bench details to the output directory in Markdown.

Note: Delta is the change since the last time the bench was run.

Name CUs Delta
bench0 450 --
bench1 579 -129
bench2 1,204 +754
bench3 2,811 +2,361

Dependencies

~13–22MB
~340K SLoC