// Copyright 2021 The Aigc Developers // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. pub mod common; use self::core::consensus; use self::core::core::hash::Hashed; use self::core::core::{HeaderVersion, KernelFeatures, NRDRelativeHeight, TxKernel}; use self::core::global; use self::core::libtx::aggsig; use self::keychain::{BlindingFactor, ExtKeychain, Keychain}; use self::pool::types::PoolError; use crate::common::*; use aigc_core as core; use aigc_keychain as keychain; use aigc_pool as pool; use aigc_util as util; use std::sync::Arc; #[test] fn test_nrd_kernel_relative_height() -> Result<(), PoolError> { util::init_test_logger(); global::set_local_chain_type(global::ChainTypes::AutomatedTesting); global::set_local_accept_fee_base(10); global::set_local_nrd_enabled(true); let keychain: ExtKeychain = Keychain::from_random_seed(false).unwrap(); let db_root = "target/.nrd_kernel_relative_height"; clean_output_dir(db_root.into()); let genesis = genesis_block(&keychain); let chain = Arc::new(init_chain(db_root, genesis)); // Initialize a new pool with our chain adapter. let mut pool = init_transaction_pool(Arc::new(ChainAdapter { chain: chain.clone(), })); add_some_blocks(&chain, 3, &keychain); let header_1 = chain.get_header_by_height(1).unwrap(); // Now create tx to spend an early coinbase (now matured). // Provides us with some useful outputs to test with. let initial_tx = test_transaction_spending_coinbase(&keychain, &header_1, vec![1_000, 2_000, 3_000, 4_000]); // Mine that initial tx so we can spend it with multiple txs. add_block(&chain, &[initial_tx], &keychain); // mine past HF4 to see effect of set_local_accept_fee_base add_some_blocks(&chain, 8, &keychain); let header = chain.head_header().unwrap(); assert_eq!(header.height, 4 * consensus::TESTING_HARD_FORK_INTERVAL); assert_eq!(header.version, HeaderVersion(5)); let (tx1, tx2, tx3) = { let mut kernel = TxKernel::with_features(KernelFeatures::NoRecentDuplicate { fee: 600.into(), relative_height: NRDRelativeHeight::new(2)?, }); let msg = kernel.msg_to_sign().unwrap(); // Generate a kernel with public excess and associated signature. let excess = BlindingFactor::rand(&keychain.secp()); let skey = excess.secret_key(&keychain.secp()).unwrap(); kernel.excess = keychain.secp().commit(0, skey).unwrap(); let pubkey = &kernel.excess.to_pubkey(&keychain.secp()).unwrap(); kernel.excess_sig = aggsig::sign_with_blinding(&keychain.secp(), &msg, &excess, Some(&pubkey)).unwrap(); kernel.verify().unwrap(); // Generate a 2nd NRD kernel sharing the same excess commitment but with different signature. let mut kernel2 = kernel.clone(); kernel2.excess_sig = aggsig::sign_with_blinding(&keychain.secp(), &msg, &excess, Some(&pubkey)).unwrap(); kernel2.verify().unwrap(); let tx1 = test_transaction_with_kernel( &keychain, vec![1_000, 2_000], vec![2_400], kernel.clone(), excess.clone(), ); let tx2 = test_transaction_with_kernel( &keychain, vec![2_400], vec![1_800], kernel2.clone(), excess.clone(), ); // Now reuse kernel excess for tx3 but with NRD relative_height=1 (and different fee). let mut kernel_short = TxKernel::with_features(KernelFeatures::NoRecentDuplicate { fee: 300.into(), relative_height: NRDRelativeHeight::new(1)?, }); let msg_short = kernel_short.msg_to_sign().unwrap(); kernel_short.excess = kernel.excess; kernel_short.excess_sig = aggsig::sign_with_blinding(&keychain.secp(), &msg_short, &excess, Some(&pubkey)) .unwrap(); kernel_short.verify().unwrap(); let tx3 = test_transaction_with_kernel( &keychain, vec![1_800], vec![1_500], kernel_short.clone(), excess.clone(), ); (tx1, tx2, tx3) }; // Confirm we can successfully add tx1 with NRD kernel to stempool. assert_eq!( pool.add_to_pool(test_source(), tx1.clone(), true, &header), Ok(()), ); assert_eq!(pool.stempool.size(), 1); // Confirm we cannot add tx2 to stempool while tx1 is in there (duplicate NRD kernels). assert_eq!( pool.add_to_pool(test_source(), tx2.clone(), true, &header), Err(PoolError::NRDKernelRelativeHeight) ); // Confirm we can successfully add tx1 with NRD kernel to txpool, // removing existing instance of tx1 from stempool in the process. assert_eq!( pool.add_to_pool(test_source(), tx1.clone(), false, &header), Ok(()), ); assert_eq!(pool.txpool.size(), 1); assert_eq!(pool.stempool.size(), 0); // Confirm we cannot add tx2 to stempool while tx1 is in txpool (duplicate NRD kernels). assert_eq!( pool.add_to_pool(test_source(), tx2.clone(), true, &header), Err(PoolError::NRDKernelRelativeHeight) ); // Confirm we cannot add tx2 to txpool while tx1 is in there (duplicate NRD kernels). assert_eq!( pool.add_to_pool(test_source(), tx2.clone(), false, &header), Err(PoolError::NRDKernelRelativeHeight) ); assert_eq!(pool.total_size(), 1); assert_eq!(pool.txpool.size(), 1); assert_eq!(pool.stempool.size(), 0); let txs = pool.prepare_mineable_transactions().unwrap(); assert_eq!(txs.len(), 1); // Mine block containing tx1 from the txpool. add_block(&chain, &txs, &keychain); let header = chain.head_header().unwrap(); let block = chain.get_block(&header.hash()).unwrap(); // Confirm the stempool/txpool is empty after reconciling the new block. pool.reconcile_block(&block)?; assert_eq!(pool.total_size(), 0); assert_eq!(pool.txpool.size(), 0); assert_eq!(pool.stempool.size(), 0); // Confirm we cannot add tx2 to stempool with tx1 in previous block (NRD relative_height=2) assert_eq!( pool.add_to_pool(test_source(), tx2.clone(), true, &header), Err(PoolError::NRDKernelRelativeHeight) ); // Confirm we cannot add tx2 to txpool with tx1 in previous block (NRD relative_height=2) assert_eq!( pool.add_to_pool(test_source(), tx2.clone(), false, &header), Err(PoolError::NRDKernelRelativeHeight) ); // Add another block so NRD relative_height rule is now met. add_block(&chain, &[], &keychain); let header = chain.head_header().unwrap(); // Confirm we can now add tx2 to stempool with NRD relative_height rule met. assert_eq!( pool.add_to_pool(test_source(), tx2.clone(), true, &header), Ok(()) ); assert_eq!(pool.total_size(), 0); assert_eq!(pool.txpool.size(), 0); assert_eq!(pool.stempool.size(), 1); // Confirm we cannot yet add tx3 to stempool (NRD relative_height=1) assert_eq!( pool.add_to_pool(test_source(), tx3.clone(), true, &header), Err(PoolError::NRDKernelRelativeHeight) ); // Confirm we can now add tx2 to txpool with NRD relative_height rule met. assert_eq!( pool.add_to_pool(test_source(), tx2.clone(), false, &header), Ok(()) ); // Confirm we cannot yet add tx3 to txpool (NRD relative_height=1) assert_eq!( pool.add_to_pool(test_source(), tx3.clone(), false, &header), Err(PoolError::NRDKernelRelativeHeight) ); assert_eq!(pool.total_size(), 1); assert_eq!(pool.txpool.size(), 1); assert_eq!(pool.stempool.size(), 0); let txs = pool.prepare_mineable_transactions().unwrap(); assert_eq!(txs.len(), 1); // Mine block containing tx2 from the txpool. add_block(&chain, &txs, &keychain); let header = chain.head_header().unwrap(); let block = chain.get_block(&header.hash()).unwrap(); pool.reconcile_block(&block)?; assert_eq!(pool.total_size(), 0); assert_eq!(pool.txpool.size(), 0); assert_eq!(pool.stempool.size(), 0); // Confirm we can now add tx3 to stempool with tx2 in immediate previous block (NRD relative_height=1) assert_eq!( pool.add_to_pool(test_source(), tx3.clone(), true, &header), Ok(()) ); assert_eq!(pool.total_size(), 0); assert_eq!(pool.txpool.size(), 0); assert_eq!(pool.stempool.size(), 1); // Confirm we can now add tx3 to txpool with tx2 in immediate previous block (NRD relative_height=1) assert_eq!( pool.add_to_pool(test_source(), tx3.clone(), false, &header), Ok(()) ); assert_eq!(pool.total_size(), 1); assert_eq!(pool.txpool.size(), 1); assert_eq!(pool.stempool.size(), 0); // Cleanup db directory clean_output_dir(db_root.into()); Ok(()) }