#![feature(test)] extern crate bincode; extern crate rand; extern crate rayon; extern crate solana; extern crate solana_sdk; extern crate test; use rand::{thread_rng, Rng}; use rayon::prelude::*; use solana::bank::{Bank, MAX_ENTRY_IDS}; use solana::banking_stage::{BankingStage, NUM_THREADS}; use solana::entry::Entry; use solana::mint::Mint; use solana::packet::to_packets_chunked; use solana_sdk::hash::hash; use solana_sdk::pubkey::Pubkey; use solana_sdk::signature::{KeypairUtil, Signature}; use solana_sdk::system_transaction::SystemTransaction; use solana_sdk::transaction::Transaction; use std::iter; use std::sync::mpsc::{channel, Receiver}; use std::sync::Arc; use std::time::Duration; use test::Bencher; fn check_txs(receiver: &Receiver>, ref_tx_count: usize) { let mut total = 0; loop { let entries = receiver.recv_timeout(Duration::new(1, 0)); if let Ok(entries) = entries { for entry in &entries { total += entry.transactions.len(); } } else { break; } if total >= ref_tx_count { break; } } assert_eq!(total, ref_tx_count); } #[bench] fn bench_banking_stage_multi_accounts(bencher: &mut Bencher) { let txes = 1000 * NUM_THREADS; let mint_total = 1_000_000_000_000; let mint = Mint::new(mint_total); let (verified_sender, verified_receiver) = channel(); let bank = Arc::new(Bank::new(&mint)); let dummy = Transaction::system_move( &mint.keypair(), mint.keypair().pubkey(), 1, mint.last_id(), 0, ); let transactions: Vec<_> = (0..txes) .into_par_iter() .map(|_| { let mut new = dummy.clone(); let from: Vec = (0..64).map(|_| thread_rng().gen()).collect(); let to: Vec = (0..64).map(|_| thread_rng().gen()).collect(); let sig: Vec = (0..64).map(|_| thread_rng().gen()).collect(); new.account_keys[0] = Pubkey::new(&from[0..32]); new.account_keys[1] = Pubkey::new(&to[0..32]); new.signatures = vec![Signature::new(&sig[0..64])]; new }).collect(); // fund all the accounts transactions.iter().for_each(|tx| { let fund = Transaction::system_move( &mint.keypair(), tx.account_keys[0], mint_total / txes as u64, mint.last_id(), 0, ); let x = bank.process_transaction(&fund); assert!(x.is_ok()); }); //sanity check, make sure all the transactions can execute sequentially transactions.iter().for_each(|tx| { let res = bank.process_transaction(&tx); assert!(res.is_ok(), "sanity test transactions"); }); bank.clear_signatures(); //sanity check, make sure all the transactions can execute in parallel let res = bank.process_transactions(&transactions); for r in res { assert!(r.is_ok(), "sanity parallel execution"); } bank.clear_signatures(); let verified: Vec<_> = to_packets_chunked(&transactions.clone(), 192) .into_iter() .map(|x| { let len = x.read().unwrap().packets.len(); (x, iter::repeat(1).take(len).collect()) }).collect(); let (_stage, signal_receiver) = BankingStage::new( &bank, verified_receiver, Default::default(), &mint.last_id(), None, ); let mut id = mint.last_id(); for _ in 0..MAX_ENTRY_IDS { id = hash(&id.as_ref()); bank.register_tick(&id); } bencher.iter(move || { // make sure the tx last id is still registered if bank.count_valid_ids(&[mint.last_id()]).len() == 0 { bank.register_tick(&mint.last_id()); } for v in verified.chunks(verified.len() / NUM_THREADS) { verified_sender.send(v.to_vec()).unwrap(); } check_txs(&signal_receiver, txes); bank.clear_signatures(); }); } #[bench] fn bench_banking_stage_multi_programs(bencher: &mut Bencher) { let progs = 4; let txes = 1000 * NUM_THREADS; let mint_total = 1_000_000_000_000; let mint = Mint::new(mint_total); let (verified_sender, verified_receiver) = channel(); let bank = Arc::new(Bank::new(&mint)); let dummy = Transaction::system_move( &mint.keypair(), mint.keypair().pubkey(), 1, mint.last_id(), 0, ); let transactions: Vec<_> = (0..txes) .into_par_iter() .map(|_| { let mut new = dummy.clone(); let from: Vec = (0..32).map(|_| thread_rng().gen()).collect(); let sig: Vec = (0..64).map(|_| thread_rng().gen()).collect(); let to: Vec = (0..32).map(|_| thread_rng().gen()).collect(); new.account_keys[0] = Pubkey::new(&from[0..32]); new.account_keys[1] = Pubkey::new(&to[0..32]); let prog = new.instructions[0].clone(); for i in 1..progs { //generate programs that spend to random keys let to: Vec = (0..32).map(|_| thread_rng().gen()).collect(); let to_key = Pubkey::new(&to[0..32]); new.account_keys.push(to_key); assert_eq!(new.account_keys.len(), i + 2); new.instructions.push(prog.clone()); assert_eq!(new.instructions.len(), i + 1); new.instructions[i].accounts[1] = 1 + i as u8; assert_eq!(new.key(i, 1), Some(&to_key)); assert_eq!( new.account_keys[new.instructions[i].accounts[1] as usize], to_key ); } assert_eq!(new.instructions.len(), progs); new.signatures = vec![Signature::new(&sig[0..64])]; new }).collect(); transactions.iter().for_each(|tx| { let fund = Transaction::system_move( &mint.keypair(), tx.account_keys[0], mint_total / txes as u64, mint.last_id(), 0, ); assert!(bank.process_transaction(&fund).is_ok()); }); //sanity check, make sure all the transactions can execute sequentially transactions.iter().for_each(|tx| { let res = bank.process_transaction(&tx); assert!(res.is_ok(), "sanity test transactions"); }); bank.clear_signatures(); //sanity check, make sure all the transactions can execute in parallel let res = bank.process_transactions(&transactions); for r in res { assert!(r.is_ok(), "sanity parallel execution"); } bank.clear_signatures(); let verified: Vec<_> = to_packets_chunked(&transactions.clone(), 96) .into_iter() .map(|x| { let len = x.read().unwrap().packets.len(); (x, iter::repeat(1).take(len).collect()) }).collect(); let (_stage, signal_receiver) = BankingStage::new( &bank, verified_receiver, Default::default(), &mint.last_id(), None, ); let mut id = mint.last_id(); for _ in 0..MAX_ENTRY_IDS { id = hash(&id.as_ref()); bank.register_tick(&id); } bencher.iter(move || { // make sure the transactions are still valid if bank.count_valid_ids(&[mint.last_id()]).len() == 0 { bank.register_tick(&mint.last_id()); } for v in verified.chunks(verified.len() / NUM_THREADS) { verified_sender.send(v.to_vec()).unwrap(); } check_txs(&signal_receiver, txes); bank.clear_signatures(); }); }