use beacon_chain::test_utils::RelativeSyncCommittee; use beacon_chain::{ test_utils::{AttestationStrategy, BeaconChainHarness, BlockStrategy, EphemeralHarnessType}, BeaconChain, StateSkipConfig, WhenSlotSkipped, MAXIMUM_GOSSIP_CLOCK_DISPARITY, }; use environment::null_logger; use eth2::{ mixin::{RequestAccept, ResponseForkName, ResponseOptional}, reqwest::RequestBuilder, types::{BlockId as CoreBlockId, ForkChoiceNode, StateId as CoreStateId, *}, BeaconNodeHttpClient, Error, StatusCode, Timeouts, }; use execution_layer::test_utils::TestingBuilder; use execution_layer::test_utils::DEFAULT_BUILDER_THRESHOLD_WEI; use execution_layer::test_utils::{ Operation, DEFAULT_BUILDER_PAYLOAD_VALUE_WEI, DEFAULT_MOCK_EL_PAYLOAD_VALUE_WEI, }; use futures::stream::{Stream, StreamExt}; use futures::FutureExt; use http_api::{ test_utils::{create_api_server, create_api_server_on_port, ApiServer}, BlockId, StateId, }; use lighthouse_network::{Enr, EnrExt, PeerId}; use network::NetworkReceivers; use proto_array::ExecutionStatus; use sensitive_url::SensitiveUrl; use slot_clock::SlotClock; use state_processing::per_block_processing::get_expected_withdrawals; use state_processing::per_slot_processing; use std::convert::TryInto; use std::sync::Arc; use tokio::sync::oneshot; use tokio::time::Duration; use tree_hash::TreeHash; use types::application_domain::ApplicationDomain; use types::{ AggregateSignature, BitList, Domain, EthSpec, ExecutionBlockHash, Hash256, Keypair, MainnetEthSpec, RelativeEpoch, SelectionProof, SignedRoot, Slot, }; type E = MainnetEthSpec; const SECONDS_PER_SLOT: u64 = 12; const SLOTS_PER_EPOCH: u64 = 32; const VALIDATOR_COUNT: usize = SLOTS_PER_EPOCH as usize; const CHAIN_LENGTH: u64 = SLOTS_PER_EPOCH * 5 - 1; // Make `next_block` an epoch transition const JUSTIFIED_EPOCH: u64 = 4; const FINALIZED_EPOCH: u64 = 3; const EXTERNAL_ADDR: &str = "/ip4/0.0.0.0/tcp/9000"; /// Skipping the slots around the epoch boundary allows us to check that we're obtaining states /// from skipped slots for the finalized and justified checkpoints (instead of the state from the /// block that those roots point to). const SKIPPED_SLOTS: &[u64] = &[ JUSTIFIED_EPOCH * SLOTS_PER_EPOCH - 1, JUSTIFIED_EPOCH * SLOTS_PER_EPOCH, FINALIZED_EPOCH * SLOTS_PER_EPOCH - 1, FINALIZED_EPOCH * SLOTS_PER_EPOCH, ]; struct ApiTester { harness: Arc>>, chain: Arc>>, client: BeaconNodeHttpClient, next_block: SignedBeaconBlock, reorg_block: SignedBeaconBlock, attestations: Vec>, contribution_and_proofs: Vec>, attester_slashing: AttesterSlashing, proposer_slashing: ProposerSlashing, voluntary_exit: SignedVoluntaryExit, _server_shutdown: oneshot::Sender<()>, network_rx: NetworkReceivers, local_enr: Enr, external_peer_id: PeerId, mock_builder: Option>>, } struct ApiTesterConfig { spec: ChainSpec, builder_threshold: Option, } impl Default for ApiTesterConfig { fn default() -> Self { let mut spec = E::default_spec(); spec.shard_committee_period = 2; Self { spec, builder_threshold: None, } } } impl ApiTester { pub async fn new() -> Self { // This allows for testing voluntary exits without building out a massive chain. Self::new_from_config(ApiTesterConfig::default()).await } pub async fn new_with_hard_forks(altair: bool, bellatrix: bool) -> Self { let mut config = ApiTesterConfig::default(); // Set whether the chain has undergone each hard fork. if altair { config.spec.altair_fork_epoch = Some(Epoch::new(0)); } if bellatrix { config.spec.bellatrix_fork_epoch = Some(Epoch::new(0)); } Self::new_from_config(config).await } pub async fn new_from_config(config: ApiTesterConfig) -> Self { // Get a random unused port let spec = config.spec; let port = unused_port::unused_tcp4_port().unwrap(); let beacon_url = SensitiveUrl::parse(format!("http://127.0.0.1:{port}").as_str()).unwrap(); let harness = Arc::new( BeaconChainHarness::builder(MainnetEthSpec) .spec(spec.clone()) .logger(logging::test_logger()) .deterministic_keypairs(VALIDATOR_COUNT) .fresh_ephemeral_store() .mock_execution_layer_with_builder(beacon_url.clone(), config.builder_threshold) .build(), ); harness.advance_slot(); for _ in 0..CHAIN_LENGTH { let slot = harness.chain.slot().unwrap().as_u64(); if !SKIPPED_SLOTS.contains(&slot) { harness .extend_chain( 1, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ) .await; } harness.advance_slot(); } let head = harness.chain.head_snapshot(); assert_eq!( harness.chain.slot().unwrap(), head.beacon_block.slot() + 1, "precondition: current slot is one after head" ); let (next_block, _next_state) = harness .make_block(head.beacon_state.clone(), harness.chain.slot().unwrap()) .await; // `make_block` adds random graffiti, so this will produce an alternate block let (reorg_block, _reorg_state) = harness .make_block(head.beacon_state.clone(), harness.chain.slot().unwrap()) .await; let head_state_root = head.beacon_state_root(); let attestations = harness .get_unaggregated_attestations( &AttestationStrategy::AllValidators, &head.beacon_state, head_state_root, head.beacon_block_root, harness.chain.slot().unwrap(), ) .into_iter() .flat_map(|vec| vec.into_iter().map(|(attestation, _subnet_id)| attestation)) .collect::>(); assert!( !attestations.is_empty(), "precondition: attestations for testing" ); let current_epoch = harness .chain .slot() .expect("should get current slot") .epoch(E::slots_per_epoch()); let is_altair = spec .altair_fork_epoch .map(|epoch| epoch <= current_epoch) .unwrap_or(false); let contribution_and_proofs = if is_altair { harness .make_sync_contributions( &head.beacon_state, head_state_root, harness.chain.slot().unwrap(), RelativeSyncCommittee::Current, ) .into_iter() .filter_map(|(_, contribution)| contribution) .collect::>() } else { vec![] }; let attester_slashing = harness.make_attester_slashing(vec![0, 1]); let proposer_slashing = harness.make_proposer_slashing(2); let voluntary_exit = harness.make_voluntary_exit(3, harness.chain.epoch().unwrap()); let chain = harness.chain.clone(); assert_eq!( chain .canonical_head .cached_head() .finalized_checkpoint() .epoch, 2, "precondition: finality" ); assert_eq!( chain .canonical_head .cached_head() .justified_checkpoint() .epoch, 3, "precondition: justification" ); let log = null_logger().unwrap(); let ApiServer { server, listening_socket: _, shutdown_tx, network_rx, local_enr, external_peer_id, } = create_api_server_on_port(chain.clone(), log, port).await; harness.runtime.task_executor.spawn(server, "api_server"); let client = BeaconNodeHttpClient::new( beacon_url, Timeouts::set_all(Duration::from_secs(SECONDS_PER_SLOT)), ); let builder_ref = harness.mock_builder.as_ref().unwrap().clone(); harness.runtime.task_executor.spawn( async move { builder_ref.run().await }, "mock_builder_server", ); let mock_builder = harness.mock_builder.clone(); Self { harness, chain, client, next_block, reorg_block, attestations, contribution_and_proofs, attester_slashing, proposer_slashing, voluntary_exit, _server_shutdown: shutdown_tx, network_rx, local_enr, external_peer_id, mock_builder, } } pub async fn new_from_genesis() -> Self { let harness = Arc::new( BeaconChainHarness::builder(MainnetEthSpec) .default_spec() .deterministic_keypairs(VALIDATOR_COUNT) .fresh_ephemeral_store() .build(), ); harness.advance_slot(); let head = harness.chain.head_snapshot(); let (next_block, _next_state) = harness .make_block(head.beacon_state.clone(), harness.chain.slot().unwrap()) .await; // `make_block` adds random graffiti, so this will produce an alternate block let (reorg_block, _reorg_state) = harness .make_block(head.beacon_state.clone(), harness.chain.slot().unwrap()) .await; let head_state_root = head.beacon_state_root(); let attestations = harness .get_unaggregated_attestations( &AttestationStrategy::AllValidators, &head.beacon_state, head_state_root, head.beacon_block_root, harness.chain.slot().unwrap(), ) .into_iter() .flat_map(|vec| vec.into_iter().map(|(attestation, _subnet_id)| attestation)) .collect::>(); let attester_slashing = harness.make_attester_slashing(vec![0, 1]); let proposer_slashing = harness.make_proposer_slashing(2); let voluntary_exit = harness.make_voluntary_exit(3, harness.chain.epoch().unwrap()); let chain = harness.chain.clone(); let log = null_logger().unwrap(); let ApiServer { server, listening_socket, shutdown_tx, network_rx, local_enr, external_peer_id, } = create_api_server(chain.clone(), log).await; harness.runtime.task_executor.spawn(server, "api_server"); let client = BeaconNodeHttpClient::new( SensitiveUrl::parse(&format!( "http://{}:{}", listening_socket.ip(), listening_socket.port() )) .unwrap(), Timeouts::set_all(Duration::from_secs(SECONDS_PER_SLOT)), ); Self { harness, chain, client, next_block, reorg_block, attestations, contribution_and_proofs: vec![], attester_slashing, proposer_slashing, voluntary_exit, _server_shutdown: shutdown_tx, network_rx, local_enr, external_peer_id, mock_builder: None, } } fn validator_keypairs(&self) -> &[Keypair] { &self.harness.validator_keypairs } pub async fn new_mev_tester() -> Self { let tester = Self::new_with_hard_forks(true, true) .await .test_post_validator_register_validator() .await; // Make sure bids always meet the minimum threshold. tester .mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_BUILDER_THRESHOLD_WEI, ))); tester } pub async fn new_mev_tester_no_builder_threshold() -> Self { let mut config = ApiTesterConfig { builder_threshold: Some(0), spec: E::default_spec(), }; config.spec.altair_fork_epoch = Some(Epoch::new(0)); config.spec.bellatrix_fork_epoch = Some(Epoch::new(0)); let tester = Self::new_from_config(config) .await .test_post_validator_register_validator() .await; tester .mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_BUILDER_PAYLOAD_VALUE_WEI, ))); tester } fn skip_slots(self, count: u64) -> Self { for _ in 0..count { self.chain .slot_clock .set_slot(self.chain.slot().unwrap().as_u64() + 1); } self } fn interesting_state_ids(&self) -> Vec { let mut ids = vec![ StateId(CoreStateId::Head), StateId(CoreStateId::Genesis), StateId(CoreStateId::Finalized), StateId(CoreStateId::Justified), StateId(CoreStateId::Slot(Slot::new(0))), StateId(CoreStateId::Slot(Slot::new(32))), StateId(CoreStateId::Slot(Slot::from(SKIPPED_SLOTS[0]))), StateId(CoreStateId::Slot(Slot::from(SKIPPED_SLOTS[1]))), StateId(CoreStateId::Slot(Slot::from(SKIPPED_SLOTS[2]))), StateId(CoreStateId::Slot(Slot::from(SKIPPED_SLOTS[3]))), StateId(CoreStateId::Root(Hash256::zero())), ]; ids.push(StateId(CoreStateId::Root( self.chain.canonical_head.cached_head().head_state_root(), ))); ids } fn interesting_block_ids(&self) -> Vec { let mut ids = vec![ BlockId(CoreBlockId::Head), BlockId(CoreBlockId::Genesis), BlockId(CoreBlockId::Finalized), BlockId(CoreBlockId::Justified), BlockId(CoreBlockId::Slot(Slot::new(0))), BlockId(CoreBlockId::Slot(Slot::new(32))), BlockId(CoreBlockId::Slot(Slot::from(SKIPPED_SLOTS[0]))), BlockId(CoreBlockId::Slot(Slot::from(SKIPPED_SLOTS[1]))), BlockId(CoreBlockId::Slot(Slot::from(SKIPPED_SLOTS[2]))), BlockId(CoreBlockId::Slot(Slot::from(SKIPPED_SLOTS[3]))), BlockId(CoreBlockId::Root(Hash256::zero())), ]; ids.push(BlockId(CoreBlockId::Root( self.chain.canonical_head.cached_head().head_block_root(), ))); ids } pub async fn test_beacon_genesis(self) -> Self { let result = self.client.get_beacon_genesis().await.unwrap().data; let state = &self.chain.head_snapshot().beacon_state; let expected = GenesisData { genesis_time: state.genesis_time(), genesis_validators_root: state.genesis_validators_root(), genesis_fork_version: self.chain.spec.genesis_fork_version, }; assert_eq!(result, expected); self } // finalization tests pub async fn test_beacon_states_root_finalized(self) -> Self { for state_id in self.interesting_state_ids() { let state_root = state_id.root(&self.chain); let state = state_id.state(&self.chain); // if .root or .state fail, skip the test. those would be errors outside the scope // of this test, here we're testing the finalized field assuming the call to .is_finalized_state // occurs after the state_root and state calls, and that the state_root and state calls // were correct. if state_root.is_err() || state.is_err() { continue; } // now that we know the state is valid, we can unwrap() everything we need let result = self .client .get_beacon_states_root(state_id.0) .await .unwrap() .unwrap() .finalized .unwrap(); let (state_root, _, _) = state_root.unwrap(); let (state, _, _) = state.unwrap(); let state_slot = state.slot(); let expected = self .chain .is_finalized_state(&state_root, state_slot) .unwrap(); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_beacon_states_fork_finalized(self) -> Self { for state_id in self.interesting_state_ids() { let state_root = state_id.root(&self.chain); let state = state_id.state(&self.chain); // if .root or .state fail, skip the test. those would be errors outside the scope // of this test, here we're testing the finalized field assuming the call to .is_finalized_state // occurs after the state_root and state calls, and that the state_root and state calls // were correct. if state_root.is_err() || state.is_err() { continue; } // now that we know the state is valid, we can unwrap() everything we need let result = self .client .get_beacon_states_fork(state_id.0) .await .unwrap() .unwrap() .finalized .unwrap(); let (state_root, _, _) = state_root.unwrap(); let (state, _, _) = state.unwrap(); let state_slot = state.slot(); let expected = self .chain .is_finalized_state(&state_root, state_slot) .unwrap(); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_beacon_states_finality_checkpoints_finalized(self) -> Self { for state_id in self.interesting_state_ids() { let state_root = state_id.root(&self.chain); let state = state_id.state(&self.chain); // if .root or .state fail, skip the test. those would be errors outside the scope // of this test, here we're testing the finalized field assuming the call to .is_finalized_state // occurs after the state_root and state calls, and that the state_root and state calls // were correct. if state_root.is_err() || state.is_err() { continue; } // now that we know the state is valid, we can unwrap() everything we need let result = self .client .get_beacon_states_finality_checkpoints(state_id.0) .await .unwrap() .unwrap() .finalized .unwrap(); let (state_root, _, _) = state_root.unwrap(); let (state, _, _) = state.unwrap(); let state_slot = state.slot(); let expected = self .chain .is_finalized_state(&state_root, state_slot) .unwrap(); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_beacon_headers_block_id_finalized(self) -> Self { for block_id in self.interesting_block_ids() { let block_root = block_id.root(&self.chain); let block = block_id.full_block(&self.chain).await; // if .root or .state fail, skip the test. those would be errors outside the scope // of this test, here we're testing the finalized field assuming the call to .is_finalized_state // occurs after the state_root and state calls, and that the state_root and state calls // were correct. if block_root.is_err() || block.is_err() { continue; } // now that we know the block is valid, we can unwrap() everything we need let result = self .client .get_beacon_headers_block_id(block_id.0) .await .unwrap() .unwrap() .finalized .unwrap(); let (block_root, _, _) = block_root.unwrap(); let (block, _, _) = block.unwrap(); let block_slot = block.slot(); let expected = self .chain .is_finalized_block(&block_root, block_slot) .unwrap(); assert_eq!(result, expected, "{:?}", block_id); } self } pub async fn test_beacon_blocks_finalized(self) -> Self { for block_id in self.interesting_block_ids() { let block_root = block_id.root(&self.chain); let block = block_id.full_block(&self.chain).await; // if .root or .full_block fail, skip the test. those would be errors outside the scope // of this test, here we're testing the finalized field assuming the call to .is_finalized_block // occurs after those calls, and that they were correct. if block_root.is_err() || block.is_err() { continue; } // now that we know the block is valid, we can unwrap() everything we need let result = self .client .get_beacon_blocks::(block_id.0) .await .unwrap() .unwrap() .finalized .unwrap(); let (block_root, _, _) = block_root.unwrap(); let (block, _, _) = block.unwrap(); let block_slot = block.slot(); let expected = self .chain .is_finalized_block(&block_root, block_slot) .unwrap(); assert_eq!(result, expected, "{:?}", block_id); } self } pub async fn test_beacon_blinded_blocks_finalized(self) -> Self { for block_id in self.interesting_block_ids() { let block_root = block_id.root(&self.chain); let block = block_id.full_block(&self.chain).await; // if .root or .full_block fail, skip the test. those would be errors outside the scope // of this test, here we're testing the finalized field assuming the call to .is_finalized_block // occurs after those calls, and that they were correct. if block_root.is_err() || block.is_err() { continue; } // now that we know the block is valid, we can unwrap() everything we need let result = self .client .get_beacon_blinded_blocks::(block_id.0) .await .unwrap() .unwrap() .finalized .unwrap(); let (block_root, _, _) = block_root.unwrap(); let (block, _, _) = block.unwrap(); let block_slot = block.slot(); let expected = self .chain .is_finalized_block(&block_root, block_slot) .unwrap(); assert_eq!(result, expected, "{:?}", block_id); } self } pub async fn test_debug_beacon_states_finalized(self) -> Self { for state_id in self.interesting_state_ids() { let state_root = state_id.root(&self.chain); let state = state_id.state(&self.chain); // if .root or .state fail, skip the test. those would be errors outside the scope // of this test, here we're testing the finalized field assuming the call to .is_finalized_state // occurs after the state_root and state calls, and that the state_root and state calls // were correct. if state_root.is_err() || state.is_err() { continue; } // now that we know the state is valid, we can unwrap() everything we need let result = self .client .get_debug_beacon_states::(state_id.0) .await .unwrap() .unwrap() .finalized .unwrap(); let (state_root, _, _) = state_root.unwrap(); let (state, _, _) = state.unwrap(); let state_slot = state.slot(); let expected = self .chain .is_finalized_state(&state_root, state_slot) .unwrap(); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_beacon_states_root(self) -> Self { for state_id in self.interesting_state_ids() { let result = self .client .get_beacon_states_root(state_id.0) .await .unwrap() .map(|res| res.data.root); let expected = state_id .root(&self.chain) .ok() .map(|(root, _execution_optimistic, _finalized)| root); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_beacon_states_fork(self) -> Self { for state_id in self.interesting_state_ids() { let result = self .client .get_beacon_states_fork(state_id.0) .await .unwrap() .map(|res| res.data); let expected = state_id.fork(&self.chain).ok(); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_beacon_states_finality_checkpoints(self) -> Self { for state_id in self.interesting_state_ids() { let result = self .client .get_beacon_states_finality_checkpoints(state_id.0) .await .unwrap() .map(|res| res.data); let expected = state_id.state(&self.chain).ok().map( |(state, _execution_optimistic, _finalized)| FinalityCheckpointsData { previous_justified: state.previous_justified_checkpoint(), current_justified: state.current_justified_checkpoint(), finalized: state.finalized_checkpoint(), }, ); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_beacon_states_validator_balances(self) -> Self { for state_id in self.interesting_state_ids() { for validator_indices in self.interesting_validator_indices() { let state_opt = state_id.state(&self.chain).ok(); let validators: Vec = match state_opt.as_ref() { Some((state, _execution_optimistic, _finalized)) => { state.validators().clone().into() } None => vec![], }; let validator_index_ids = validator_indices .iter() .cloned() .map(|i| ValidatorId::Index(i)) .collect::>(); let validator_pubkey_ids = validator_indices .iter() .cloned() .map(|i| { ValidatorId::PublicKey( validators .get(i as usize) .map_or(PublicKeyBytes::empty(), |val| val.pubkey.clone()), ) }) .collect::>(); let result_index_ids = self .client .get_beacon_states_validator_balances( state_id.0, Some(validator_index_ids.as_slice()), ) .await .unwrap() .map(|res| res.data); let result_pubkey_ids = self .client .get_beacon_states_validator_balances( state_id.0, Some(validator_pubkey_ids.as_slice()), ) .await .unwrap() .map(|res| res.data); let expected = state_opt.map(|(state, _execution_optimistic, _finalized)| { let mut validators = Vec::with_capacity(validator_indices.len()); for i in validator_indices { if i < state.balances().len() as u64 { validators.push(ValidatorBalanceData { index: i as u64, balance: state.balances()[i as usize], }); } } validators }); assert_eq!(result_index_ids, expected, "{:?}", state_id); assert_eq!(result_pubkey_ids, expected, "{:?}", state_id); } } self } pub async fn test_beacon_states_validators(self) -> Self { for state_id in self.interesting_state_ids() { for statuses in self.interesting_validator_statuses() { for validator_indices in self.interesting_validator_indices() { let state_opt = state_id .state(&self.chain) .ok() .map(|(state, _execution_optimistic, _finalized)| state); let validators: Vec = match state_opt.as_ref() { Some(state) => state.validators().clone().into(), None => vec![], }; let validator_index_ids = validator_indices .iter() .cloned() .map(|i| ValidatorId::Index(i)) .collect::>(); let validator_pubkey_ids = validator_indices .iter() .cloned() .map(|i| { ValidatorId::PublicKey( validators .get(i as usize) .map_or(PublicKeyBytes::empty(), |val| val.pubkey.clone()), ) }) .collect::>(); let result_index_ids = self .client .get_beacon_states_validators( state_id.0, Some(validator_index_ids.as_slice()), None, ) .await .unwrap() .map(|res| res.data); let result_pubkey_ids = self .client .get_beacon_states_validators( state_id.0, Some(validator_pubkey_ids.as_slice()), None, ) .await .unwrap() .map(|res| res.data); let expected = state_opt.map(|state| { let epoch = state.current_epoch(); let far_future_epoch = self.chain.spec.far_future_epoch; let mut validators = Vec::with_capacity(validator_indices.len()); for i in validator_indices { if i >= state.validators().len() as u64 { continue; } let validator = state.validators()[i as usize].clone(); let status = ValidatorStatus::from_validator( &validator, epoch, far_future_epoch, ); if statuses.contains(&status) || statuses.is_empty() || statuses.contains(&status.superstatus()) { validators.push(ValidatorData { index: i as u64, balance: state.balances()[i as usize], status, validator, }); } } validators }); assert_eq!(result_index_ids, expected, "{:?}", state_id); assert_eq!(result_pubkey_ids, expected, "{:?}", state_id); } } } self } pub async fn test_beacon_states_validator_id(self) -> Self { for state_id in self.interesting_state_ids() { let state_opt = state_id .state(&self.chain) .ok() .map(|(state, _execution_optimistic, _finalized)| state); let validators = match state_opt.as_ref() { Some(state) => state.validators().clone().into(), None => vec![], }; for (i, validator) in validators.into_iter().enumerate() { let validator_ids = &[ ValidatorId::PublicKey(validator.pubkey.clone()), ValidatorId::Index(i as u64), ]; for validator_id in validator_ids { let result = self .client .get_beacon_states_validator_id(state_id.0, validator_id) .await .unwrap() .map(|res| res.data); if result.is_none() && state_opt.is_none() { continue; } let state = state_opt.as_ref().expect("result should be none"); let expected = { let epoch = state.current_epoch(); let far_future_epoch = self.chain.spec.far_future_epoch; ValidatorData { index: i as u64, balance: state.balances()[i], status: ValidatorStatus::from_validator( &validator, epoch, far_future_epoch, ), validator: validator.clone(), } }; assert_eq!(result, Some(expected), "{:?}, {:?}", state_id, validator_id); } } } self } pub async fn test_beacon_states_committees(self) -> Self { for state_id in self.interesting_state_ids() { let mut state_opt = state_id .state(&self.chain) .ok() .map(|(state, _execution_optimistic, _finalized)| state); let epoch_opt = state_opt.as_ref().map(|state| state.current_epoch()); let results = self .client .get_beacon_states_committees(state_id.0, None, None, epoch_opt) .await .unwrap() .map(|res| res.data); if results.is_none() && state_opt.is_none() { continue; } let state = state_opt.as_mut().expect("result should be none"); state.build_all_committee_caches(&self.chain.spec).unwrap(); let committees = state .get_beacon_committees_at_epoch(RelativeEpoch::Current) .unwrap(); for (i, result) in results.unwrap().into_iter().enumerate() { let expected = &committees[i]; assert_eq!(result.index, expected.index, "{}", state_id); assert_eq!(result.slot, expected.slot, "{}", state_id); assert_eq!( result .validators .into_iter() .map(|i| i as usize) .collect::>(), expected.committee.to_vec(), "{}", state_id ); } } self } pub async fn test_beacon_states_randao(self) -> Self { for state_id in self.interesting_state_ids() { let mut state_opt = state_id .state(&self.chain) .ok() .map(|(state, _execution_optimistic, _finalized)| state); let epoch_opt = state_opt.as_ref().map(|state| state.current_epoch()); let result = self .client .get_beacon_states_randao(state_id.0, epoch_opt) .await .unwrap() .map(|res| res.data); if result.is_none() && state_opt.is_none() { continue; } let state = state_opt.as_mut().expect("result should be none"); let randao_mix = state .get_randao_mix(state.slot().epoch(E::slots_per_epoch())) .unwrap(); assert_eq!(result.unwrap().randao, *randao_mix); } self } pub async fn test_beacon_headers_all_slots(self) -> Self { for slot in 0..CHAIN_LENGTH { let slot = Slot::from(slot); let result = self .client .get_beacon_headers(Some(slot), None) .await .unwrap() .map(|res| res.data); let root = self .chain .block_root_at_slot(slot, WhenSlotSkipped::None) .unwrap(); if root.is_none() && result.is_none() { continue; } let root = root.unwrap(); let block = self .chain .block_at_slot(slot, WhenSlotSkipped::Prev) .unwrap() .unwrap(); let header = BlockHeaderData { root, canonical: true, header: BlockHeaderAndSignature { message: block.message().block_header(), signature: block.signature().clone().into(), }, }; let expected = vec![header]; assert_eq!(result.unwrap(), expected, "slot {:?}", slot); } self } pub async fn test_beacon_headers_all_parents(self) -> Self { let mut roots = self .chain .forwards_iter_block_roots(Slot::new(0)) .unwrap() .map(Result::unwrap) .map(|(root, _slot)| root) .collect::>(); // The iterator natively returns duplicate roots for skipped slots. roots.dedup(); for i in 1..roots.len() { let parent_root = roots[i - 1]; let child_root = roots[i]; let result = self .client .get_beacon_headers(None, Some(parent_root)) .await .unwrap() .unwrap() .data; assert_eq!(result.len(), 1, "i {}", i); assert_eq!(result[0].root, child_root, "i {}", i); } self } pub async fn test_beacon_headers_block_id(self) -> Self { for block_id in self.interesting_block_ids() { let result = self .client .get_beacon_headers_block_id(block_id.0) .await .unwrap() .map(|res| res.data); let block_root_opt = block_id .root(&self.chain) .ok() .map(|(root, _execution_optimistic, _finalized)| root); if let CoreBlockId::Slot(slot) = block_id.0 { if block_root_opt.is_none() { assert!(SKIPPED_SLOTS.contains(&slot.as_u64())); } else { assert!(!SKIPPED_SLOTS.contains(&slot.as_u64())); } } let block_opt = block_id .full_block(&self.chain) .await .ok() .map(|(block, _execution_optimistic, _finalized)| block); if block_opt.is_none() && result.is_none() { continue; } let result = result.unwrap(); let block = block_opt.unwrap(); let block_root = block_root_opt.unwrap(); let canonical = self .chain .block_root_at_slot(block.slot(), WhenSlotSkipped::None) .unwrap() .map_or(false, |canonical| block_root == canonical); assert_eq!(result.canonical, canonical, "{:?}", block_id); assert_eq!(result.root, block_root, "{:?}", block_id); assert_eq!( result.header.message, block.message().block_header(), "{:?}", block_id ); assert_eq!( result.header.signature, block.signature().clone().into(), "{:?}", block_id ); } self } pub async fn test_beacon_blocks_root(self) -> Self { for block_id in self.interesting_block_ids() { let result = self .client .get_beacon_blocks_root(block_id.0) .await .unwrap() .map(|res| res.data.root); let expected = block_id .root(&self.chain) .ok() .map(|(root, _execution_optimistic, _finalized)| root); if let CoreBlockId::Slot(slot) = block_id.0 { if expected.is_none() { assert!(SKIPPED_SLOTS.contains(&slot.as_u64())); } else { assert!(!SKIPPED_SLOTS.contains(&slot.as_u64())); } } assert_eq!(result, expected, "{:?}", block_id); } self } pub async fn test_post_beacon_blocks_valid(mut self) -> Self { let next_block = &self.next_block; self.client.post_beacon_blocks(next_block).await.unwrap(); assert!( self.network_rx.network_recv.recv().await.is_some(), "valid blocks should be sent to network" ); self } pub async fn test_post_beacon_blocks_invalid(mut self) -> Self { let mut next_block = self.next_block.clone(); *next_block.message_mut().proposer_index_mut() += 1; assert!(self.client.post_beacon_blocks(&next_block).await.is_err()); assert!( self.network_rx.network_recv.recv().await.is_some(), "invalid blocks should be sent to network" ); self } pub async fn test_beacon_blocks(self) -> Self { for block_id in self.interesting_block_ids() { let expected = block_id .full_block(&self.chain) .await .ok() .map(|(block, _execution_optimistic, _finalized)| block); if let CoreBlockId::Slot(slot) = block_id.0 { if expected.is_none() { assert!(SKIPPED_SLOTS.contains(&slot.as_u64())); } else { assert!(!SKIPPED_SLOTS.contains(&slot.as_u64())); } } // Check the JSON endpoint. let json_result = self.client.get_beacon_blocks(block_id.0).await.unwrap(); if let (Some(json), Some(expected)) = (&json_result, &expected) { assert_eq!(&json.data, expected.as_ref(), "{:?}", block_id); assert_eq!( json.version, Some(expected.fork_name(&self.chain.spec).unwrap()) ); } else { assert_eq!(json_result, None); assert_eq!(expected, None); } // Check the SSZ endpoint. let ssz_result = self .client .get_beacon_blocks_ssz(block_id.0, &self.chain.spec) .await .unwrap(); assert_eq!( ssz_result.as_ref(), expected.as_ref().map(|b| b.as_ref()), "{:?}", block_id ); // Check that the legacy v1 API still works but doesn't return a version field. let v1_result = self.client.get_beacon_blocks_v1(block_id.0).await.unwrap(); if let (Some(v1_result), Some(expected)) = (&v1_result, &expected) { assert_eq!(v1_result.version, None); assert_eq!(&v1_result.data, expected.as_ref()); } else { assert_eq!(v1_result, None); assert_eq!(expected, None); } // Check that version headers are provided. let url = self.client.get_beacon_blocks_path(block_id.0).unwrap(); let builders: Vec RequestBuilder> = vec![ |b| b, |b| b.accept(Accept::Ssz), |b| b.accept(Accept::Json), |b| b.accept(Accept::Any), ]; for req_builder in builders { let raw_res = self .client .get_response(url.clone(), req_builder) .await .optional() .unwrap(); if let (Some(raw_res), Some(expected)) = (&raw_res, &expected) { assert_eq!( raw_res.fork_name_from_header().unwrap(), Some(expected.fork_name(&self.chain.spec).unwrap()) ); } else { assert!(raw_res.is_none()); assert_eq!(expected, None); } } } self } pub async fn test_beacon_blinded_blocks(self) -> Self { for block_id in self.interesting_block_ids() { let expected = block_id .blinded_block(&self.chain) .ok() .map(|(block, _execution_optimistic, _finalized)| block); if let CoreBlockId::Slot(slot) = block_id.0 { if expected.is_none() { assert!(SKIPPED_SLOTS.contains(&slot.as_u64())); } else { assert!(!SKIPPED_SLOTS.contains(&slot.as_u64())); } } // Check the JSON endpoint. let json_result = self .client .get_beacon_blinded_blocks(block_id.0) .await .unwrap(); if let (Some(json), Some(expected)) = (&json_result, &expected) { assert_eq!(&json.data, expected, "{:?}", block_id); assert_eq!( json.version, Some(expected.fork_name(&self.chain.spec).unwrap()) ); } else { assert_eq!(json_result, None); assert_eq!(expected, None); } // Check the SSZ endpoint. let ssz_result = self .client .get_beacon_blinded_blocks_ssz(block_id.0, &self.chain.spec) .await .unwrap(); assert_eq!(ssz_result.as_ref(), expected.as_ref(), "{:?}", block_id); // Check that version headers are provided. let url = self .client .get_beacon_blinded_blocks_path(block_id.0) .unwrap(); let builders: Vec RequestBuilder> = vec![ |b| b, |b| b.accept(Accept::Ssz), |b| b.accept(Accept::Json), |b| b.accept(Accept::Any), ]; for req_builder in builders { let raw_res = self .client .get_response(url.clone(), req_builder) .await .optional() .unwrap(); if let (Some(raw_res), Some(expected)) = (&raw_res, &expected) { assert_eq!( raw_res.fork_name_from_header().unwrap(), Some(expected.fork_name(&self.chain.spec).unwrap()) ); } else { assert!(raw_res.is_none()); assert_eq!(expected, None); } } } self } pub async fn test_beacon_blocks_attestations(self) -> Self { for block_id in self.interesting_block_ids() { let result = self .client .get_beacon_blocks_attestations(block_id.0) .await .unwrap() .map(|res| res.data); let expected = block_id.full_block(&self.chain).await.ok().map( |(block, _execution_optimistic, _finalized)| { block.message().body().attestations().clone().into() }, ); if let CoreBlockId::Slot(slot) = block_id.0 { if expected.is_none() { assert!(SKIPPED_SLOTS.contains(&slot.as_u64())); } else { assert!(!SKIPPED_SLOTS.contains(&slot.as_u64())); } } assert_eq!(result, expected, "{:?}", block_id); } self } pub async fn test_post_beacon_pool_attestations_valid(mut self) -> Self { self.client .post_beacon_pool_attestations(self.attestations.as_slice()) .await .unwrap(); assert!( self.network_rx.network_recv.recv().await.is_some(), "valid attestation should be sent to network" ); self } pub async fn test_post_beacon_pool_attestations_invalid(mut self) -> Self { let mut attestations = Vec::new(); for attestation in &self.attestations { let mut invalid_attestation = attestation.clone(); invalid_attestation.data.slot += 1; // add both to ensure we only fail on invalid attestations attestations.push(attestation.clone()); attestations.push(invalid_attestation); } let err = self .client .post_beacon_pool_attestations(attestations.as_slice()) .await .unwrap_err(); match err { Error::ServerIndexedMessage(IndexedErrorMessage { code, message: _, failures, }) => { assert_eq!(code, 400); assert_eq!(failures.len(), self.attestations.len()); } _ => panic!("query did not fail correctly"), } assert!( self.network_rx.network_recv.recv().await.is_some(), "if some attestations are valid, we should send them to the network" ); self } pub async fn test_get_beacon_pool_attestations(self) -> Self { let result = self .client .get_beacon_pool_attestations(None, None) .await .unwrap() .data; let mut expected = self.chain.op_pool.get_all_attestations(); expected.extend(self.chain.naive_aggregation_pool.read().iter().cloned()); assert_eq!(result, expected); self } pub async fn test_post_beacon_pool_attester_slashings_valid(mut self) -> Self { self.client .post_beacon_pool_attester_slashings(&self.attester_slashing) .await .unwrap(); assert!( self.network_rx.network_recv.recv().await.is_some(), "valid attester slashing should be sent to network" ); self } pub async fn test_post_beacon_pool_attester_slashings_invalid(mut self) -> Self { let mut slashing = self.attester_slashing.clone(); slashing.attestation_1.data.slot += 1; self.client .post_beacon_pool_attester_slashings(&slashing) .await .unwrap_err(); assert!( self.network_rx.network_recv.recv().now_or_never().is_none(), "invalid attester slashing should not be sent to network" ); self } pub async fn test_get_beacon_pool_attester_slashings(self) -> Self { let result = self .client .get_beacon_pool_attester_slashings() .await .unwrap() .data; let expected = self.chain.op_pool.get_all_attester_slashings(); assert_eq!(result, expected); self } pub async fn test_post_beacon_pool_proposer_slashings_valid(mut self) -> Self { self.client .post_beacon_pool_proposer_slashings(&self.proposer_slashing) .await .unwrap(); assert!( self.network_rx.network_recv.recv().await.is_some(), "valid proposer slashing should be sent to network" ); self } pub async fn test_post_beacon_pool_proposer_slashings_invalid(mut self) -> Self { let mut slashing = self.proposer_slashing.clone(); slashing.signed_header_1.message.slot += 1; self.client .post_beacon_pool_proposer_slashings(&slashing) .await .unwrap_err(); assert!( self.network_rx.network_recv.recv().now_or_never().is_none(), "invalid proposer slashing should not be sent to network" ); self } pub async fn test_get_beacon_pool_proposer_slashings(self) -> Self { let result = self .client .get_beacon_pool_proposer_slashings() .await .unwrap() .data; let expected = self.chain.op_pool.get_all_proposer_slashings(); assert_eq!(result, expected); self } pub async fn test_post_beacon_pool_voluntary_exits_valid(mut self) -> Self { self.client .post_beacon_pool_voluntary_exits(&self.voluntary_exit) .await .unwrap(); assert!( self.network_rx.network_recv.recv().await.is_some(), "valid exit should be sent to network" ); self } pub async fn test_post_beacon_pool_voluntary_exits_invalid(mut self) -> Self { let mut exit = self.voluntary_exit.clone(); exit.message.epoch += 1; self.client .post_beacon_pool_voluntary_exits(&exit) .await .unwrap_err(); assert!( self.network_rx.network_recv.recv().now_or_never().is_none(), "invalid exit should not be sent to network" ); self } pub async fn test_get_beacon_pool_voluntary_exits(self) -> Self { let result = self .client .get_beacon_pool_voluntary_exits() .await .unwrap() .data; let expected = self.chain.op_pool.get_all_voluntary_exits(); assert_eq!(result, expected); self } pub async fn test_get_config_fork_schedule(self) -> Self { let result = self.client.get_config_fork_schedule().await.unwrap().data; let expected: Vec = ForkName::list_all() .into_iter() .filter_map(|fork| self.chain.spec.fork_for_name(fork)) .collect(); assert_eq!(result, expected); self } pub async fn test_get_config_spec(self) -> Self { let result = self .client .get_config_spec::() .await .map(|res| ConfigAndPreset::Capella(res.data)) .unwrap(); let expected = ConfigAndPreset::from_chain_spec::(&self.chain.spec, None); assert_eq!(result, expected); self } pub async fn test_get_config_deposit_contract(self) -> Self { let result = self .client .get_config_deposit_contract() .await .unwrap() .data; let expected = DepositContractData { address: self.chain.spec.deposit_contract_address, chain_id: self.chain.spec.deposit_chain_id, }; assert_eq!(result, expected); self } pub async fn test_get_node_version(self) -> Self { let result = self.client.get_node_version().await.unwrap().data; let expected = VersionData { version: lighthouse_version::version_with_platform(), }; assert_eq!(result, expected); self } pub async fn test_get_node_syncing(self) -> Self { let result = self.client.get_node_syncing().await.unwrap().data; let head_slot = self.chain.canonical_head.cached_head().head_slot(); let sync_distance = self.chain.slot().unwrap() - head_slot; let expected = SyncingData { is_syncing: false, is_optimistic: Some(false), // these tests run without the Bellatrix fork enabled el_offline: Some(true), head_slot, sync_distance, }; assert_eq!(result, expected); self } pub async fn test_get_node_identity(self) -> Self { let result = self.client.get_node_identity().await.unwrap().data; let expected = IdentityData { peer_id: self.local_enr.peer_id().to_string(), enr: self.local_enr.clone(), p2p_addresses: self.local_enr.multiaddr_p2p_tcp(), discovery_addresses: self.local_enr.multiaddr_p2p_udp(), metadata: eth2::types::MetaData { seq_number: 0, attnets: "0x0000000000000000".to_string(), syncnets: "0x00".to_string(), }, }; assert_eq!(result, expected); self } pub async fn test_get_node_health(self) -> Self { let status = self.client.get_node_health().await.unwrap(); assert_eq!(status, StatusCode::OK); self } pub async fn test_get_node_peers_by_id(self) -> Self { let result = self .client .get_node_peers_by_id(self.external_peer_id.clone()) .await .unwrap() .data; let expected = PeerData { peer_id: self.external_peer_id.to_string(), enr: None, last_seen_p2p_address: EXTERNAL_ADDR.to_string(), state: PeerState::Connected, direction: PeerDirection::Inbound, }; assert_eq!(result, expected); self } pub async fn test_get_node_peers(self) -> Self { let peer_states: Vec> = vec![ Some(&[PeerState::Connected]), Some(&[PeerState::Connecting]), Some(&[PeerState::Disconnected]), Some(&[PeerState::Disconnecting]), None, Some(&[PeerState::Connected, PeerState::Connecting]), ]; let peer_dirs: Vec> = vec![ Some(&[PeerDirection::Outbound]), Some(&[PeerDirection::Inbound]), Some(&[PeerDirection::Inbound, PeerDirection::Outbound]), None, ]; for states in peer_states { for dirs in peer_dirs.clone() { let result = self.client.get_node_peers(states, dirs).await.unwrap(); let expected_peer = PeerData { peer_id: self.external_peer_id.to_string(), enr: None, last_seen_p2p_address: EXTERNAL_ADDR.to_string(), state: PeerState::Connected, direction: PeerDirection::Inbound, }; let state_match = states.map_or(true, |states| states.contains(&PeerState::Connected)); let dir_match = dirs.map_or(true, |dirs| dirs.contains(&PeerDirection::Inbound)); let mut expected_peers = Vec::new(); if state_match && dir_match { expected_peers.push(expected_peer); } assert_eq!( result, PeersData { meta: PeersMetaData { count: expected_peers.len() as u64 }, data: expected_peers, } ); } } self } pub async fn test_get_node_peer_count(self) -> Self { let result = self.client.get_node_peer_count().await.unwrap().data; assert_eq!( result, PeerCount { connected: 1, connecting: 0, disconnected: 0, disconnecting: 0, } ); self } pub async fn test_get_debug_beacon_states(self) -> Self { for state_id in self.interesting_state_ids() { let result_json = self .client .get_debug_beacon_states(state_id.0) .await .unwrap(); let mut expected = state_id .state(&self.chain) .ok() .map(|(state, _execution_optimistic, _finalized)| state); expected.as_mut().map(|state| state.drop_all_caches()); if let (Some(json), Some(expected)) = (&result_json, &expected) { assert_eq!(json.data, *expected, "{:?}", state_id); assert_eq!( json.version, Some(expected.fork_name(&self.chain.spec).unwrap()) ); } else { assert_eq!(result_json, None); assert_eq!(expected, None); } // Check SSZ API. let result_ssz = self .client .get_debug_beacon_states_ssz(state_id.0, &self.chain.spec) .await .unwrap(); assert_eq!(result_ssz, expected, "{:?}", state_id); // Check that version headers are provided. let url = self .client .get_debug_beacon_states_path(state_id.0) .unwrap(); let builders: Vec RequestBuilder> = vec![|b| b, |b| b.accept(Accept::Ssz)]; for req_builder in builders { let raw_res = self .client .get_response(url.clone(), req_builder) .await .optional() .unwrap(); if let (Some(raw_res), Some(expected)) = (&raw_res, &expected) { assert_eq!( raw_res.fork_name_from_header().unwrap(), Some(expected.fork_name(&self.chain.spec).unwrap()) ); } else { assert!(raw_res.is_none()); assert_eq!(expected, None); } } } self } pub async fn test_get_debug_beacon_heads(self) -> Self { let result = self .client .get_debug_beacon_heads() .await .unwrap() .data .into_iter() .map(|head| (head.root, head.slot)) .collect::>(); let expected = self.chain.heads(); assert_eq!(result, expected); self } pub async fn test_get_debug_fork_choice(self) -> Self { let result = self.client.get_debug_fork_choice().await.unwrap(); let beacon_fork_choice = self.chain.canonical_head.fork_choice_read_lock(); let expected_proto_array = beacon_fork_choice.proto_array().core_proto_array(); assert_eq!( result.justified_checkpoint, expected_proto_array.justified_checkpoint ); assert_eq!( result.finalized_checkpoint, expected_proto_array.finalized_checkpoint ); let expected_fork_choice_nodes: Vec = expected_proto_array .nodes .iter() .map(|node| { let execution_status = if node.execution_status.is_execution_enabled() { Some(node.execution_status.to_string()) } else { None }; ForkChoiceNode { slot: node.slot, block_root: node.root, parent_root: node .parent .and_then(|index| expected_proto_array.nodes.get(index)) .map(|parent| parent.root), justified_epoch: node.justified_checkpoint.epoch, finalized_epoch: node.finalized_checkpoint.epoch, weight: node.weight, validity: execution_status, execution_block_hash: node .execution_status .block_hash() .map(|block_hash| block_hash.into_root()), } }) .collect(); assert_eq!(result.fork_choice_nodes, expected_fork_choice_nodes); // need to drop beacon_fork_choice here, else borrow checker will complain // that self cannot be moved out since beacon_fork_choice borrowed self.chain // and might still live after self is moved out drop(beacon_fork_choice); self } fn validator_count(&self) -> usize { self.chain.head_snapshot().beacon_state.validators().len() } fn interesting_validator_indices(&self) -> Vec> { let validator_count = self.validator_count() as u64; let mut interesting = vec![ vec![], vec![0], vec![0, 1], vec![0, 1, 3], vec![validator_count], vec![validator_count, 1], vec![validator_count, 1, 3], vec![u64::max_value()], vec![u64::max_value(), 1], vec![u64::max_value(), 1, 3], ]; interesting.push((0..validator_count).collect()); interesting } fn interesting_validator_statuses(&self) -> Vec> { let interesting = vec![ vec![], vec![ValidatorStatus::Active], vec![ ValidatorStatus::PendingInitialized, ValidatorStatus::PendingQueued, ValidatorStatus::ActiveOngoing, ValidatorStatus::ActiveExiting, ValidatorStatus::ActiveSlashed, ValidatorStatus::ExitedUnslashed, ValidatorStatus::ExitedSlashed, ValidatorStatus::WithdrawalPossible, ValidatorStatus::WithdrawalDone, ValidatorStatus::Active, ValidatorStatus::Pending, ValidatorStatus::Exited, ValidatorStatus::Withdrawal, ], ]; interesting } pub async fn test_get_validator_duties_attester(self) -> Self { let current_epoch = self.chain.epoch().unwrap().as_u64(); let half = current_epoch / 2; let first = current_epoch - half; let last = current_epoch + half; for epoch in first..=last { for indices in self.interesting_validator_indices() { let epoch = Epoch::from(epoch); // The endpoint does not allow getting duties past the next epoch. if epoch > current_epoch + 1 { assert_eq!( self.client .post_validator_duties_attester(epoch, indices.as_slice()) .await .unwrap_err() .status() .map(Into::into), Some(400) ); continue; } let results = self .client .post_validator_duties_attester(epoch, indices.as_slice()) .await .unwrap(); let dependent_root = self .chain .block_root_at_slot( (epoch - 1).start_slot(E::slots_per_epoch()) - 1, WhenSlotSkipped::Prev, ) .unwrap() .unwrap_or(self.chain.head_beacon_block_root()); assert_eq!(results.dependent_root, dependent_root); let result_duties = results.data; let mut state = self .chain .state_at_slot( epoch.start_slot(E::slots_per_epoch()), StateSkipConfig::WithStateRoots, ) .unwrap(); state .build_committee_cache(RelativeEpoch::Current, &self.chain.spec) .unwrap(); let expected_len = indices .iter() .filter(|i| **i < state.validators().len() as u64) .count(); assert_eq!(result_duties.len(), expected_len); for (indices_set, &i) in indices.iter().enumerate() { if let Some(duty) = state .get_attestation_duties(i as usize, RelativeEpoch::Current) .unwrap() { let expected = AttesterData { pubkey: state.validators()[i as usize].pubkey.clone().into(), validator_index: i, committees_at_slot: duty.committees_at_slot, committee_index: duty.index, committee_length: duty.committee_len as u64, validator_committee_index: duty.committee_position as u64, slot: duty.slot, }; let result = result_duties .iter() .find(|duty| duty.validator_index == i) .unwrap(); assert_eq!( *result, expected, "epoch: {}, indices_set: {}", epoch, indices_set ); } else { assert!( !result_duties.iter().any(|duty| duty.validator_index == i), "validator index should not exist in response" ); } } } } self } pub async fn test_get_validator_duties_proposer(self) -> Self { let current_epoch = self.chain.epoch().unwrap(); for epoch in 0..=self.chain.epoch().unwrap().as_u64() + 1 { let epoch = Epoch::from(epoch); let dependent_root = self .chain .block_root_at_slot( epoch.start_slot(E::slots_per_epoch()) - 1, WhenSlotSkipped::Prev, ) .unwrap() .unwrap_or(self.chain.head_beacon_block_root()); // Presently, the beacon chain harness never runs the code that primes the proposer // cache. If this changes in the future then we'll need some smarter logic here, but // this is succinct and effective for the time being. assert!( self.chain .beacon_proposer_cache .lock() .get_epoch::(dependent_root, epoch) .is_none(), "the proposer cache should miss initially" ); let result = self .client .get_validator_duties_proposer(epoch) .await .unwrap(); // Check that current-epoch requests prime the proposer cache, whilst non-current // requests don't. if epoch == current_epoch { assert!( self.chain .beacon_proposer_cache .lock() .get_epoch::(dependent_root, epoch) .is_some(), "a current-epoch request should prime the proposer cache" ); } else { assert!( self.chain .beacon_proposer_cache .lock() .get_epoch::(dependent_root, epoch) .is_none(), "a non-current-epoch request should not prime the proposer cache" ); } let mut state = self .chain .state_at_slot( epoch.start_slot(E::slots_per_epoch()), StateSkipConfig::WithStateRoots, ) .unwrap(); state .build_committee_cache(RelativeEpoch::Current, &self.chain.spec) .unwrap(); let expected_duties = epoch .slot_iter(E::slots_per_epoch()) .map(|slot| { let index = state .get_beacon_proposer_index(slot, &self.chain.spec) .unwrap(); let pubkey = state.validators()[index].pubkey.clone().into(); ProposerData { pubkey, validator_index: index as u64, slot, } }) .collect::>(); let expected = DutiesResponse { data: expected_duties, execution_optimistic: Some(false), dependent_root, }; assert_eq!(result, expected); // If it's the current epoch, check the function with a primed proposer cache. if epoch == current_epoch { // This is technically a double-check, but it's defensive. assert!( self.chain .beacon_proposer_cache .lock() .get_epoch::(dependent_root, epoch) .is_some(), "the request should prime the proposer cache" ); let result = self .client .get_validator_duties_proposer(epoch) .await .unwrap(); assert_eq!(result, expected); } } // Requests to the epochs after the next epoch should fail. self.client .get_validator_duties_proposer(current_epoch + 2) .await .unwrap_err(); self } pub async fn test_get_validator_duties_early(self) -> Self { let current_epoch = self.chain.epoch().unwrap(); let next_epoch = current_epoch + 1; let current_epoch_start = self .chain .slot_clock .start_of(current_epoch.start_slot(E::slots_per_epoch())) .unwrap(); self.chain.slot_clock.set_current_time( current_epoch_start - MAXIMUM_GOSSIP_CLOCK_DISPARITY - Duration::from_millis(1), ); let dependent_root = self .chain .block_root_at_slot( current_epoch.start_slot(E::slots_per_epoch()) - 1, WhenSlotSkipped::Prev, ) .unwrap() .unwrap_or(self.chain.head_beacon_block_root()); self.client .get_validator_duties_proposer(current_epoch) .await .expect("should get proposer duties for the next epoch outside of tolerance"); assert!( self.chain .beacon_proposer_cache .lock() .get_epoch::(dependent_root, current_epoch) .is_none(), "should not prime the proposer cache outside of tolerance" ); assert_eq!( self.client .post_validator_duties_attester(next_epoch, &[0]) .await .unwrap_err() .status() .map(Into::into), Some(400), "should not get attester duties outside of tolerance" ); self.chain .slot_clock .set_current_time(current_epoch_start - MAXIMUM_GOSSIP_CLOCK_DISPARITY); self.client .get_validator_duties_proposer(current_epoch) .await .expect("should get proposer duties within tolerance"); assert!( self.chain .beacon_proposer_cache .lock() .get_epoch::(dependent_root, current_epoch) .is_some(), "should prime the proposer cache inside the tolerance" ); self.client .post_validator_duties_attester(next_epoch, &[0]) .await .expect("should get attester duties within tolerance"); self } pub async fn test_block_production(self) -> Self { let fork = self.chain.canonical_head.cached_head().head_fork(); let genesis_validators_root = self.chain.genesis_validators_root; for _ in 0..E::slots_per_epoch() * 3 { let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let proposer_pubkey_bytes = self .client .get_validator_duties_proposer(epoch) .await .unwrap() .data .into_iter() .find(|duty| duty.slot == slot) .map(|duty| duty.pubkey) .unwrap(); let proposer_pubkey = (&proposer_pubkey_bytes).try_into().unwrap(); let sk = self .validator_keypairs() .iter() .find(|kp| kp.pk == proposer_pubkey) .map(|kp| kp.sk.clone()) .unwrap(); let randao_reveal = { let domain = self.chain.spec.get_domain( epoch, Domain::Randao, &fork, genesis_validators_root, ); let message = epoch.signing_root(domain); sk.sign(message).into() }; let block = self .client .get_validator_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data; let signed_block = block.sign(&sk, &fork, genesis_validators_root, &self.chain.spec); self.client.post_beacon_blocks(&signed_block).await.unwrap(); assert_eq!(self.chain.head_beacon_block().as_ref(), &signed_block); self.chain.slot_clock.set_slot(slot.as_u64() + 1); } self } pub async fn test_block_production_no_verify_randao(self) -> Self { for _ in 0..E::slots_per_epoch() { let slot = self.chain.slot().unwrap(); let block = self .client .get_validator_blocks_modular::>( slot, &Signature::infinity().unwrap().into(), None, SkipRandaoVerification::Yes, ) .await .unwrap() .data; assert_eq!(block.slot(), slot); self.chain.slot_clock.set_slot(slot.as_u64() + 1); } self } pub async fn test_block_production_verify_randao_invalid(self) -> Self { let fork = self.chain.canonical_head.cached_head().head_fork(); let genesis_validators_root = self.chain.genesis_validators_root; for _ in 0..E::slots_per_epoch() { let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let proposer_pubkey_bytes = self .client .get_validator_duties_proposer(epoch) .await .unwrap() .data .into_iter() .find(|duty| duty.slot == slot) .map(|duty| duty.pubkey) .unwrap(); let proposer_pubkey = (&proposer_pubkey_bytes).try_into().unwrap(); let sk = self .validator_keypairs() .iter() .find(|kp| kp.pk == proposer_pubkey) .map(|kp| kp.sk.clone()) .unwrap(); let bad_randao_reveal = { let domain = self.chain.spec.get_domain( epoch, Domain::Randao, &fork, genesis_validators_root, ); let message = (epoch + 1).signing_root(domain); sk.sign(message).into() }; // Check failure with no `skip_randao_verification` passed. self.client .get_validator_blocks::>(slot, &bad_randao_reveal, None) .await .unwrap_err(); // Check failure with `skip_randao_verification` (requires infinity sig). self.client .get_validator_blocks_modular::>( slot, &bad_randao_reveal, None, SkipRandaoVerification::Yes, ) .await .unwrap_err(); self.chain.slot_clock.set_slot(slot.as_u64() + 1); } self } pub async fn test_blinded_block_production>(&self) { let fork = self.chain.canonical_head.cached_head().head_fork(); let genesis_validators_root = self.chain.genesis_validators_root; for _ in 0..E::slots_per_epoch() * 3 { let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let proposer_pubkey_bytes = self .client .get_validator_duties_proposer(epoch) .await .unwrap() .data .into_iter() .find(|duty| duty.slot == slot) .map(|duty| duty.pubkey) .unwrap(); let proposer_pubkey = (&proposer_pubkey_bytes).try_into().unwrap(); let sk = self .validator_keypairs() .iter() .find(|kp| kp.pk == proposer_pubkey) .map(|kp| kp.sk.clone()) .unwrap(); let randao_reveal = { let domain = self.chain.spec.get_domain( epoch, Domain::Randao, &fork, genesis_validators_root, ); let message = epoch.signing_root(domain); sk.sign(message).into() }; let block = self .client .get_validator_blinded_blocks::(slot, &randao_reveal, None) .await .unwrap() .data; let signed_block = block.sign(&sk, &fork, genesis_validators_root, &self.chain.spec); self.client .post_beacon_blinded_blocks(&signed_block) .await .unwrap(); // This converts the generic `Payload` to a concrete type for comparison. let head_block = SignedBeaconBlock::from(signed_block.clone()); assert_eq!(head_block, signed_block); self.chain.slot_clock.set_slot(slot.as_u64() + 1); } } pub async fn test_blinded_block_production_no_verify_randao>( self, ) -> Self { for _ in 0..E::slots_per_epoch() { let slot = self.chain.slot().unwrap(); let block = self .client .get_validator_blinded_blocks_modular::( slot, &Signature::infinity().unwrap().into(), None, SkipRandaoVerification::Yes, ) .await .unwrap() .data; assert_eq!(block.slot(), slot); self.chain.slot_clock.set_slot(slot.as_u64() + 1); } self } pub async fn test_blinded_block_production_verify_randao_invalid< Payload: AbstractExecPayload, >( self, ) -> Self { let fork = self.chain.canonical_head.cached_head().head_fork(); let genesis_validators_root = self.chain.genesis_validators_root; for _ in 0..E::slots_per_epoch() { let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let proposer_pubkey_bytes = self .client .get_validator_duties_proposer(epoch) .await .unwrap() .data .into_iter() .find(|duty| duty.slot == slot) .map(|duty| duty.pubkey) .unwrap(); let proposer_pubkey = (&proposer_pubkey_bytes).try_into().unwrap(); let sk = self .validator_keypairs() .iter() .find(|kp| kp.pk == proposer_pubkey) .map(|kp| kp.sk.clone()) .unwrap(); let bad_randao_reveal = { let domain = self.chain.spec.get_domain( epoch, Domain::Randao, &fork, genesis_validators_root, ); let message = (epoch + 1).signing_root(domain); sk.sign(message).into() }; // Check failure with full randao verification enabled. self.client .get_validator_blinded_blocks::(slot, &bad_randao_reveal, None) .await .unwrap_err(); // Check failure with `skip_randao_verification` (requires infinity sig). self.client .get_validator_blinded_blocks_modular::( slot, &bad_randao_reveal, None, SkipRandaoVerification::Yes, ) .await .unwrap_err(); self.chain.slot_clock.set_slot(slot.as_u64() + 1); } self } pub async fn test_get_validator_attestation_data(self) -> Self { let mut state = self.chain.head_beacon_state_cloned(); let slot = state.slot(); state .build_committee_cache(RelativeEpoch::Current, &self.chain.spec) .unwrap(); for index in 0..state.get_committee_count_at_slot(slot).unwrap() { let result = self .client .get_validator_attestation_data(slot, index) .await .unwrap() .data; let expected = self .chain .produce_unaggregated_attestation(slot, index) .unwrap() .data; assert_eq!(result, expected); } self } pub async fn test_get_validator_aggregate_attestation(self) -> Self { let attestation = self .chain .head_beacon_block() .message() .body() .attestations()[0] .clone(); let result = self .client .get_validator_aggregate_attestation( attestation.data.slot, attestation.data.tree_hash_root(), ) .await .unwrap() .unwrap() .data; let expected = attestation; assert_eq!(result, expected); self } pub async fn get_aggregate(&mut self) -> SignedAggregateAndProof { let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let mut head = self.chain.head_snapshot().as_ref().clone(); while head.beacon_state.current_epoch() < epoch { per_slot_processing(&mut head.beacon_state, None, &self.chain.spec).unwrap(); } head.beacon_state .build_committee_cache(RelativeEpoch::Current, &self.chain.spec) .unwrap(); let committee_len = head.beacon_state.get_committee_count_at_slot(slot).unwrap(); let fork = head.beacon_state.fork(); let genesis_validators_root = self.chain.genesis_validators_root; let duties = self .client .post_validator_duties_attester( epoch, (0..self.validator_keypairs().len() as u64) .collect::>() .as_slice(), ) .await .unwrap() .data; let (i, kp, duty, proof) = self .validator_keypairs() .iter() .enumerate() .find_map(|(i, kp)| { let duty = duties[i].clone(); let proof = SelectionProof::new::( duty.slot, &kp.sk, &fork, genesis_validators_root, &self.chain.spec, ); if proof .is_aggregator(committee_len as usize, &self.chain.spec) .unwrap() { Some((i, kp, duty, proof)) } else { None } }) .expect("there is at least one aggregator for this epoch") .clone(); if duty.slot > slot { self.chain.slot_clock.set_slot(duty.slot.into()); } let attestation_data = self .client .get_validator_attestation_data(duty.slot, duty.committee_index) .await .unwrap() .data; let mut attestation = Attestation { aggregation_bits: BitList::with_capacity(duty.committee_length as usize).unwrap(), data: attestation_data, signature: AggregateSignature::infinity(), }; attestation .sign( &kp.sk, duty.validator_committee_index as usize, &fork, genesis_validators_root, &self.chain.spec, ) .unwrap(); SignedAggregateAndProof::from_aggregate( i as u64, attestation, Some(proof), &kp.sk, &fork, genesis_validators_root, &self.chain.spec, ) } pub async fn test_get_validator_aggregate_and_proofs_valid(mut self) -> Self { let aggregate = self.get_aggregate().await; self.client .post_validator_aggregate_and_proof::(&[aggregate]) .await .unwrap(); assert!(self.network_rx.network_recv.recv().await.is_some()); self } pub async fn test_get_validator_aggregate_and_proofs_invalid(mut self) -> Self { let mut aggregate = self.get_aggregate().await; aggregate.message.aggregate.data.slot += 1; self.client .post_validator_aggregate_and_proof::(&[aggregate]) .await .unwrap_err(); assert!(self.network_rx.network_recv.recv().now_or_never().is_none()); self } pub async fn test_get_validator_beacon_committee_subscriptions(mut self) -> Self { let subscription = BeaconCommitteeSubscription { validator_index: 0, committee_index: 0, committees_at_slot: 1, slot: Slot::new(1), is_aggregator: true, }; self.client .post_validator_beacon_committee_subscriptions(&[subscription]) .await .unwrap(); self.network_rx .validator_subscription_recv .recv() .now_or_never() .unwrap(); self } pub async fn test_post_validator_register_validator(self) -> Self { let mut registrations = vec![]; let mut fee_recipients = vec![]; let genesis_epoch = self.chain.spec.genesis_slot.epoch(E::slots_per_epoch()); let fork = Fork { current_version: self.chain.spec.genesis_fork_version, previous_version: self.chain.spec.genesis_fork_version, epoch: genesis_epoch, }; let expected_gas_limit = 11_111_111; for (val_index, keypair) in self.validator_keypairs().iter().enumerate() { let pubkey = keypair.pk.compress(); let fee_recipient = Address::from_low_u64_be(val_index as u64); let data = ValidatorRegistrationData { fee_recipient, gas_limit: expected_gas_limit, timestamp: 0, pubkey, }; let domain = self.chain.spec.get_domain( genesis_epoch, Domain::ApplicationMask(ApplicationDomain::Builder), &fork, Hash256::zero(), ); let message = data.signing_root(domain); let signature = keypair.sk.sign(message); let signed = SignedValidatorRegistrationData { message: data, signature, }; fee_recipients.push(fee_recipient); registrations.push(signed); } self.client .post_validator_register_validator(®istrations) .await .unwrap(); for (val_index, (_, fee_recipient)) in self .chain .head_snapshot() .beacon_state .validators() .into_iter() .zip(fee_recipients.into_iter()) .enumerate() { let actual = self .chain .execution_layer .as_ref() .unwrap() .get_suggested_fee_recipient(val_index as u64) .await; assert_eq!(actual, fee_recipient); } self } pub async fn test_post_validator_register_validator_slashed(self) -> Self { // slash a validator self.client .post_beacon_pool_attester_slashings(&self.attester_slashing) .await .unwrap(); self.harness .extend_chain( 1, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ) .await; let mut registrations = vec![]; let mut fee_recipients = vec![]; let genesis_epoch = self.chain.spec.genesis_slot.epoch(E::slots_per_epoch()); let fork = Fork { current_version: self.chain.spec.genesis_fork_version, previous_version: self.chain.spec.genesis_fork_version, epoch: genesis_epoch, }; let expected_gas_limit = 11_111_111; for (val_index, keypair) in self.validator_keypairs().iter().enumerate() { let pubkey = keypair.pk.compress(); let fee_recipient = Address::from_low_u64_be(val_index as u64); let data = ValidatorRegistrationData { fee_recipient, gas_limit: expected_gas_limit, timestamp: 0, pubkey, }; let domain = self.chain.spec.get_domain( genesis_epoch, Domain::ApplicationMask(ApplicationDomain::Builder), &fork, Hash256::zero(), ); let message = data.signing_root(domain); let signature = keypair.sk.sign(message); let signed = SignedValidatorRegistrationData { message: data, signature, }; fee_recipients.push(fee_recipient); registrations.push(signed); } self.client .post_validator_register_validator(®istrations) .await .unwrap(); for (val_index, (_, fee_recipient)) in self .chain .head_snapshot() .beacon_state .validators() .into_iter() .zip(fee_recipients.into_iter()) .enumerate() { let actual = self .chain .execution_layer .as_ref() .unwrap() .get_suggested_fee_recipient(val_index as u64) .await; if val_index == 0 || val_index == 1 { assert_eq!(actual, Address::from_low_u64_be(val_index as u64)); } else { assert_eq!(actual, fee_recipient); } } self } // Helper function for tests that require a valid RANDAO signature. async fn get_test_randao(&self, slot: Slot, epoch: Epoch) -> (u64, SignatureBytes) { let fork = self.chain.canonical_head.cached_head().head_fork(); let genesis_validators_root = self.chain.genesis_validators_root; let (proposer_pubkey_bytes, proposer_index) = self .client .get_validator_duties_proposer(epoch) .await .unwrap() .data .into_iter() .find(|duty| duty.slot == slot) .map(|duty| (duty.pubkey, duty.validator_index)) .unwrap(); let proposer_pubkey = (&proposer_pubkey_bytes).try_into().unwrap(); let sk = self .validator_keypairs() .iter() .find(|kp| kp.pk == proposer_pubkey) .map(|kp| kp.sk.clone()) .unwrap(); let randao_reveal = { let domain = self.chain .spec .get_domain(epoch, Domain::Randao, &fork, genesis_validators_root); let message = epoch.signing_root(domain); sk.sign(message).into() }; (proposer_index, randao_reveal) } pub async fn test_payload_respects_registration(self) -> Self { let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (proposer_index, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); let expected_fee_recipient = Address::from_low_u64_be(proposer_index as u64); assert_eq!(payload.fee_recipient(), expected_fee_recipient); assert_eq!(payload.gas_limit(), 11_111_111); // If this cache is empty, it indicates fallback was not used, so the payload came from the // mock builder. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_none()); self } pub async fn test_payload_accepts_mutated_gas_limit(self) -> Self { // Mutate gas limit. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::GasLimit(30_000_000)); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (proposer_index, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); let expected_fee_recipient = Address::from_low_u64_be(proposer_index as u64); assert_eq!(payload.fee_recipient(), expected_fee_recipient); assert_eq!(payload.gas_limit(), 30_000_000); // This cache should not be populated because fallback should not have been used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_none()); self } pub async fn test_payload_accepts_changed_fee_recipient(self) -> Self { let test_fee_recipient = "0x4242424242424242424242424242424242424242" .parse::
() .unwrap(); // Mutate fee recipient. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::FeeRecipient(test_fee_recipient)); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); assert_eq!(payload.fee_recipient(), test_fee_recipient); // This cache should not be populated because fallback should not have been used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_none()); self } pub async fn test_payload_rejects_invalid_parent_hash(self) -> Self { let invalid_parent_hash = "0x4242424242424242424242424242424242424242424242424242424242424242" .parse::() .unwrap(); // Mutate parent hash. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::ParentHash(invalid_parent_hash)); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let expected_parent_hash = self .chain .head_snapshot() .beacon_state .latest_execution_payload_header() .unwrap() .block_hash(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); assert_eq!(payload.parent_hash(), expected_parent_hash); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_payload_rejects_invalid_prev_randao(self) -> Self { let invalid_prev_randao = "0x4242424242424242424242424242424242424242424242424242424242424242" .parse::() .unwrap(); // Mutate prev randao. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::PrevRandao(invalid_prev_randao)); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let expected_prev_randao = self .chain .canonical_head .cached_head() .head_random() .unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); assert_eq!(payload.prev_randao(), expected_prev_randao); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_payload_rejects_invalid_block_number(self) -> Self { let invalid_block_number = 2; // Mutate block number. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::BlockNumber(invalid_block_number)); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let expected_block_number = self .chain .head_snapshot() .beacon_state .latest_execution_payload_header() .unwrap() .block_number() + 1; let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); assert_eq!(payload.block_number(), expected_block_number); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_payload_rejects_invalid_timestamp(self) -> Self { let invalid_timestamp = 2; // Mutate timestamp. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Timestamp(invalid_timestamp)); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let min_expected_timestamp = self .chain .head_snapshot() .beacon_state .latest_execution_payload_header() .unwrap() .timestamp(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); assert!(payload.timestamp() > min_expected_timestamp); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_payload_rejects_invalid_signature(self) -> Self { self.mock_builder .as_ref() .unwrap() .builder .invalid_signatures(); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_builder_chain_health_skips(self) -> Self { let slot = self.chain.slot().unwrap(); // Since we are proposing this slot, start the count from the previous slot. let prev_slot = slot - Slot::new(1); let head_slot = self.chain.canonical_head.cached_head().head_slot(); let epoch = self.chain.epoch().unwrap(); // Inclusive here to make sure we advance one slot past the threshold. for _ in (prev_slot - head_slot).as_usize()..=self.chain.config.builder_fallback_skips { self.harness.advance_slot(); } let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_builder_chain_health_skips_per_epoch(self) -> Self { // Fill an epoch with `builder_fallback_skips_per_epoch` skip slots. for i in 0..E::slots_per_epoch() { if i == 0 || i as usize > self.chain.config.builder_fallback_skips_per_epoch { self.harness .extend_chain( 1, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ) .await; } self.harness.advance_slot(); } let next_slot = self.chain.slot().unwrap(); let (_, randao_reveal) = self .get_test_randao(next_slot, next_slot.epoch(E::slots_per_epoch())) .await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(next_slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // This cache should not be populated because fallback should not have been used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_none()); // Without proposing, advance into the next slot, this should make us cross the threshold // number of skips, causing us to use the fallback. self.harness.advance_slot(); let next_slot = self.chain.slot().unwrap(); let (_, randao_reveal) = self .get_test_randao(next_slot, next_slot.epoch(E::slots_per_epoch())) .await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(next_slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_builder_chain_health_epochs_since_finalization(self) -> Self { let skips = E::slots_per_epoch() * self.chain.config.builder_fallback_epochs_since_finalization as u64; for _ in 0..skips { self.harness.advance_slot(); } // Fill the next epoch with blocks, should be enough to justify, not finalize. for _ in 0..E::slots_per_epoch() { self.harness .extend_chain( 1, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ) .await; self.harness.advance_slot(); } let next_slot = self.chain.slot().unwrap(); let (_, randao_reveal) = self .get_test_randao(next_slot, next_slot.epoch(E::slots_per_epoch())) .await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(next_slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); // Fill another epoch with blocks, should be enough to finalize. (Sneaky plus 1 because this // scenario starts at an epoch boundary). for _ in 0..E::slots_per_epoch() + 1 { self.harness .extend_chain( 1, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ) .await; self.harness.advance_slot(); } let next_slot = self.chain.slot().unwrap(); let (_, randao_reveal) = self .get_test_randao(next_slot, next_slot.epoch(E::slots_per_epoch())) .await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(next_slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // This cache should not be populated because fallback should not have been used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_none()); self } pub async fn test_builder_chain_health_optimistic_head(self) -> Self { // Make sure the next payload verification will return optimistic before advancing the chain. self.harness.mock_execution_layer.as_ref().map(|el| { el.server.all_payloads_syncing(true); el }); self.harness .extend_chain( 1, BlockStrategy::OnCanonicalHead, AttestationStrategy::AllValidators, ) .await; self.harness.advance_slot(); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (proposer_index, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); let expected_fee_recipient = Address::from_low_u64_be(proposer_index as u64); assert_eq!(payload.fee_recipient(), expected_fee_recipient); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_payload_rejects_inadequate_builder_threshold(self) -> Self { // Mutate value. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_BUILDER_THRESHOLD_WEI - 1, ))); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // If this cache is populated, it indicates fallback to the local EE was correctly used. assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_builder_payload_chosen_when_more_profitable(self) -> Self { // Mutate value. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_MOCK_EL_PAYLOAD_VALUE_WEI + 1, ))); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // The builder's payload should've been chosen, so this cache should not be populated assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_none()); self } pub async fn test_local_payload_chosen_when_equally_profitable(self) -> Self { // Mutate value. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_MOCK_EL_PAYLOAD_VALUE_WEI, ))); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // The local payload should've been chosen, so this cache should be populated assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_local_payload_chosen_when_more_profitable(self) -> Self { // Mutate value. self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_MOCK_EL_PAYLOAD_VALUE_WEI - 1, ))); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // The local payload should've been chosen, so this cache should be populated assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } pub async fn test_builder_works_post_capella(self) -> Self { // Ensure builder payload is chosen self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_MOCK_EL_PAYLOAD_VALUE_WEI + 1, ))); let slot = self.chain.slot().unwrap(); let propose_state = self .harness .chain .state_at_slot(slot, StateSkipConfig::WithoutStateRoots) .unwrap(); let withdrawals = get_expected_withdrawals(&propose_state, &self.chain.spec).unwrap(); let withdrawals_root = withdrawals.tree_hash_root(); // Set withdrawals root for builder self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::WithdrawalsRoot(withdrawals_root)); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // The builder's payload should've been chosen, so this cache should not be populated assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_none()); self } pub async fn test_lighthouse_rejects_invalid_withdrawals_root(self) -> Self { // Ensure builder payload *would be* chosen self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::Value(Uint256::from( DEFAULT_MOCK_EL_PAYLOAD_VALUE_WEI + 1, ))); // Set withdrawals root to something invalid self.mock_builder .as_ref() .unwrap() .builder .add_operation(Operation::WithdrawalsRoot(Hash256::repeat_byte(0x42))); let slot = self.chain.slot().unwrap(); let epoch = self.chain.epoch().unwrap(); let (_, randao_reveal) = self.get_test_randao(slot, epoch).await; let payload: BlindedPayload = self .client .get_validator_blinded_blocks::>(slot, &randao_reveal, None) .await .unwrap() .data .body() .execution_payload() .unwrap() .into(); // The local payload should've been chosen because the builder's was invalid assert!(self .chain .execution_layer .as_ref() .unwrap() .get_payload_by_root(&payload.tree_hash_root()) .is_some()); self } #[cfg(target_os = "linux")] pub async fn test_get_lighthouse_health(self) -> Self { self.client.get_lighthouse_health().await.unwrap(); self } #[cfg(not(target_os = "linux"))] pub async fn test_get_lighthouse_health(self) -> Self { self.client.get_lighthouse_health().await.unwrap_err(); self } pub async fn test_get_lighthouse_syncing(self) -> Self { self.client.get_lighthouse_syncing().await.unwrap(); self } pub async fn test_get_lighthouse_proto_array(self) -> Self { self.client.get_lighthouse_proto_array().await.unwrap(); self } pub async fn test_get_lighthouse_validator_inclusion_global(self) -> Self { let epoch = self.chain.epoch().unwrap() - 1; self.client .get_lighthouse_validator_inclusion_global(epoch) .await .unwrap(); self } pub async fn test_get_lighthouse_validator_inclusion(self) -> Self { let epoch = self.chain.epoch().unwrap() - 1; self.client .get_lighthouse_validator_inclusion(epoch, ValidatorId::Index(0)) .await .unwrap(); self } pub async fn test_get_lighthouse_eth1_syncing(self) -> Self { self.client.get_lighthouse_eth1_syncing().await.unwrap(); self } pub async fn test_get_lighthouse_eth1_block_cache(self) -> Self { let blocks = self.client.get_lighthouse_eth1_block_cache().await.unwrap(); assert!(blocks.data.is_empty()); self } pub async fn test_get_lighthouse_eth1_deposit_cache(self) -> Self { let deposits = self .client .get_lighthouse_eth1_deposit_cache() .await .unwrap(); assert!(deposits.data.is_empty()); self } pub async fn test_get_lighthouse_beacon_states_ssz(self) -> Self { for state_id in self.interesting_state_ids() { let result = self .client .get_lighthouse_beacon_states_ssz(&state_id.0, &self.chain.spec) .await .unwrap(); let mut expected = state_id .state(&self.chain) .ok() .map(|(state, _execution_optimistic, _finalized)| state); expected.as_mut().map(|state| state.drop_all_caches()); assert_eq!(result, expected, "{:?}", state_id); } self } pub async fn test_get_lighthouse_staking(self) -> Self { let result = self.client.get_lighthouse_staking().await.unwrap(); assert_eq!(result, self.chain.eth1_chain.is_some()); self } pub async fn test_get_lighthouse_database_info(self) -> Self { let info = self.client.get_lighthouse_database_info().await.unwrap(); assert_eq!(info.anchor, self.chain.store.get_anchor_info()); assert_eq!(info.split, self.chain.store.get_split_info()); assert_eq!( info.schema_version, store::metadata::CURRENT_SCHEMA_VERSION.as_u64() ); self } pub async fn test_post_lighthouse_database_reconstruct(self) -> Self { let response = self .client .post_lighthouse_database_reconstruct() .await .unwrap(); assert_eq!(response, "success"); self } pub async fn test_post_lighthouse_liveness(self) -> Self { let epoch = self.chain.epoch().unwrap(); let head_state = self.chain.head_beacon_state_cloned(); let indices = (0..head_state.validators().len()) .map(|i| i as u64) .collect::>(); // Construct the expected response let expected: Vec = head_state .validators() .iter() .enumerate() .map(|(index, _)| LivenessResponseData { index: index as u64, is_live: false, epoch, }) .collect(); let result = self .client .post_lighthouse_liveness(indices.as_slice(), epoch) .await .unwrap() .data; assert_eq!(result, expected); // Attest to the current slot self.client .post_beacon_pool_attestations(self.attestations.as_slice()) .await .unwrap(); let result = self .client .post_lighthouse_liveness(indices.as_slice(), epoch) .await .unwrap() .data; let committees = head_state .get_beacon_committees_at_slot(self.chain.slot().unwrap()) .unwrap(); let attesting_validators: Vec = committees .into_iter() .flat_map(|committee| committee.committee.iter().cloned()) .collect(); // All attesters should now be considered live let expected = expected .into_iter() .map(|mut a| { if attesting_validators.contains(&(a.index as usize)) { a.is_live = true; } a }) .collect::>(); assert_eq!(result, expected); self } pub async fn test_get_events(self) -> Self { // Subscribe to all events let topics = vec![ EventTopic::Attestation, EventTopic::VoluntaryExit, EventTopic::Block, EventTopic::Head, EventTopic::FinalizedCheckpoint, ]; let mut events_future = self .client .get_events::(topics.as_slice()) .await .unwrap(); let expected_attestation_len = self.attestations.len(); self.client .post_beacon_pool_attestations(self.attestations.as_slice()) .await .unwrap(); let attestation_events = poll_events( &mut events_future, expected_attestation_len, Duration::from_millis(10000), ) .await; assert_eq!( attestation_events.as_slice(), self.attestations .clone() .into_iter() .map(|attestation| EventKind::Attestation(Box::new(attestation))) .collect::>() .as_slice() ); // Produce a voluntary exit event self.client .post_beacon_pool_voluntary_exits(&self.voluntary_exit) .await .unwrap(); let exit_events = poll_events(&mut events_future, 1, Duration::from_millis(10000)).await; assert_eq!( exit_events.as_slice(), &[EventKind::VoluntaryExit(self.voluntary_exit.clone())] ); // Submit the next block, which is on an epoch boundary, so this will produce a finalized // checkpoint event, head event, and block event let block_root = self.next_block.canonical_root(); // current_duty_dependent_root = block root because this is the first slot of the epoch let current_duty_dependent_root = self.chain.head_beacon_block_root(); let current_slot = self.chain.slot().unwrap(); let next_slot = self.next_block.slot(); let finalization_distance = E::slots_per_epoch() * 2; let expected_block = EventKind::Block(SseBlock { block: block_root, slot: next_slot, execution_optimistic: false, }); let expected_head = EventKind::Head(SseHead { block: block_root, slot: next_slot, state: self.next_block.state_root(), current_duty_dependent_root, previous_duty_dependent_root: self .chain .block_root_at_slot(current_slot - E::slots_per_epoch(), WhenSlotSkipped::Prev) .unwrap() .unwrap(), epoch_transition: true, execution_optimistic: false, }); let finalized_block_root = self .chain .block_root_at_slot(next_slot - finalization_distance, WhenSlotSkipped::Prev) .unwrap() .unwrap(); let finalized_block = self .chain .get_blinded_block(&finalized_block_root) .unwrap() .unwrap(); let finalized_state_root = finalized_block.state_root(); let expected_finalized = EventKind::FinalizedCheckpoint(SseFinalizedCheckpoint { block: finalized_block_root, state: finalized_state_root, epoch: Epoch::new(3), execution_optimistic: false, }); self.client .post_beacon_blocks(&self.next_block) .await .unwrap(); let block_events = poll_events(&mut events_future, 3, Duration::from_millis(10000)).await; assert_eq!( block_events.as_slice(), &[expected_block, expected_head, expected_finalized] ); // Test a reorg event let mut chain_reorg_event_future = self .client .get_events::(&[EventTopic::ChainReorg]) .await .unwrap(); let expected_reorg = EventKind::ChainReorg(SseChainReorg { slot: self.next_block.slot(), depth: 1, old_head_block: self.next_block.canonical_root(), old_head_state: self.next_block.state_root(), new_head_block: self.reorg_block.canonical_root(), new_head_state: self.reorg_block.state_root(), epoch: self.next_block.slot().epoch(E::slots_per_epoch()), execution_optimistic: false, }); self.client .post_beacon_blocks(&self.reorg_block) .await .unwrap(); let reorg_event = poll_events( &mut chain_reorg_event_future, 1, Duration::from_millis(10000), ) .await; assert_eq!(reorg_event.as_slice(), &[expected_reorg]); self } pub async fn test_get_events_altair(self) -> Self { let topics = vec![EventTopic::ContributionAndProof]; let mut events_future = self .client .get_events::(topics.as_slice()) .await .unwrap(); let expected_contribution_len = self.contribution_and_proofs.len(); self.client .post_validator_contribution_and_proofs(self.contribution_and_proofs.as_slice()) .await .unwrap(); let contribution_events = poll_events( &mut events_future, expected_contribution_len, Duration::from_millis(10000), ) .await; assert_eq!( contribution_events.as_slice(), self.contribution_and_proofs .clone() .into_iter() .map(|contribution| EventKind::ContributionAndProof(Box::new(contribution))) .collect::>() .as_slice() ); self } pub async fn test_get_events_from_genesis(self) -> Self { let topics = vec![EventTopic::Block, EventTopic::Head]; let mut events_future = self .client .get_events::(topics.as_slice()) .await .unwrap(); let block_root = self.next_block.canonical_root(); let next_slot = self.next_block.slot(); let expected_block = EventKind::Block(SseBlock { block: block_root, slot: next_slot, execution_optimistic: false, }); let expected_head = EventKind::Head(SseHead { block: block_root, slot: next_slot, state: self.next_block.state_root(), current_duty_dependent_root: self.chain.genesis_block_root, previous_duty_dependent_root: self.chain.genesis_block_root, epoch_transition: false, execution_optimistic: false, }); self.client .post_beacon_blocks(&self.next_block) .await .unwrap(); let block_events = poll_events(&mut events_future, 2, Duration::from_millis(10000)).await; assert_eq!(block_events.as_slice(), &[expected_block, expected_head]); self } pub async fn test_check_optimistic_responses(&mut self) { // Check responses are not optimistic. let result = self .client .get_beacon_headers_block_id(CoreBlockId::Head) .await .unwrap() .unwrap(); assert_eq!(result.execution_optimistic, Some(false)); // Change head to be optimistic. self.chain .canonical_head .fork_choice_write_lock() .proto_array_mut() .core_proto_array_mut() .nodes .last_mut() .map(|head_node| { head_node.execution_status = ExecutionStatus::Optimistic(ExecutionBlockHash::zero()) }); // Check responses are now optimistic. let result = self .client .get_beacon_headers_block_id(CoreBlockId::Head) .await .unwrap() .unwrap(); assert_eq!(result.execution_optimistic, Some(true)); } } async fn poll_events, eth2::Error>> + Unpin, T: EthSpec>( stream: &mut S, num_events: usize, timeout: Duration, ) -> Vec> { let mut events = Vec::new(); let collect_stream_fut = async { loop { if let Some(result) = stream.next().await { events.push(result.unwrap()); if events.len() == num_events { return; } } } }; tokio::select! { _ = collect_stream_fut => {events} _ = tokio::time::sleep(timeout) => { return events; } } } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_events() { ApiTester::new().await.test_get_events().await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_events_altair() { let mut config = ApiTesterConfig::default(); config.spec.altair_fork_epoch = Some(Epoch::new(0)); ApiTester::new_from_config(config) .await .test_get_events_altair() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_events_from_genesis() { ApiTester::new_from_genesis() .await .test_get_events_from_genesis() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_get() { ApiTester::new() .await .test_beacon_genesis() .await .test_beacon_states_root_finalized() .await .test_beacon_states_fork_finalized() .await .test_beacon_states_finality_checkpoints_finalized() .await .test_beacon_headers_block_id_finalized() .await .test_beacon_blocks_finalized::() .await .test_beacon_blinded_blocks_finalized::() .await .test_debug_beacon_states_finalized() .await .test_beacon_states_root() .await .test_beacon_states_fork() .await .test_beacon_states_finality_checkpoints() .await .test_beacon_states_validators() .await .test_beacon_states_validator_balances() .await .test_beacon_states_committees() .await .test_beacon_states_validator_id() .await .test_beacon_states_randao() .await .test_beacon_headers_all_slots() .await .test_beacon_headers_all_parents() .await .test_beacon_headers_block_id() .await .test_beacon_blocks() .await .test_beacon_blinded_blocks() .await .test_beacon_blocks_attestations() .await .test_beacon_blocks_root() .await .test_get_beacon_pool_attestations() .await .test_get_beacon_pool_attester_slashings() .await .test_get_beacon_pool_proposer_slashings() .await .test_get_beacon_pool_voluntary_exits() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn post_beacon_blocks_valid() { ApiTester::new().await.test_post_beacon_blocks_valid().await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn post_beacon_blocks_invalid() { ApiTester::new() .await .test_post_beacon_blocks_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_attestations_valid() { ApiTester::new() .await .test_post_beacon_pool_attestations_valid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_attestations_invalid() { ApiTester::new() .await .test_post_beacon_pool_attestations_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_attester_slashings_valid() { ApiTester::new() .await .test_post_beacon_pool_attester_slashings_valid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_attester_slashings_invalid() { ApiTester::new() .await .test_post_beacon_pool_attester_slashings_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_proposer_slashings_valid() { ApiTester::new() .await .test_post_beacon_pool_proposer_slashings_valid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_proposer_slashings_invalid() { ApiTester::new() .await .test_post_beacon_pool_proposer_slashings_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_voluntary_exits_valid() { ApiTester::new() .await .test_post_beacon_pool_voluntary_exits_valid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn beacon_pools_post_voluntary_exits_invalid() { ApiTester::new() .await .test_post_beacon_pool_voluntary_exits_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn config_get() { ApiTester::new() .await .test_get_config_fork_schedule() .await .test_get_config_spec() .await .test_get_config_deposit_contract() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn debug_get() { ApiTester::new() .await .test_get_debug_beacon_states() .await .test_get_debug_beacon_heads() .await .test_get_debug_fork_choice() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn node_get() { ApiTester::new() .await .test_get_node_version() .await .test_get_node_syncing() .await .test_get_node_identity() .await .test_get_node_health() .await .test_get_node_peers_by_id() .await .test_get_node_peers() .await .test_get_node_peer_count() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_duties_early() { ApiTester::new() .await .test_get_validator_duties_early() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_duties_attester() { ApiTester::new() .await .test_get_validator_duties_attester() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_duties_attester_with_skip_slots() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_get_validator_duties_attester() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_duties_proposer() { ApiTester::new() .await .test_get_validator_duties_proposer() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_duties_proposer_with_skip_slots() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_get_validator_duties_proposer() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn block_production() { ApiTester::new().await.test_block_production().await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn block_production_with_skip_slots() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_block_production() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn block_production_no_verify_randao() { ApiTester::new() .await .test_block_production_no_verify_randao() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn block_production_verify_randao_invalid() { ApiTester::new() .await .test_block_production_verify_randao_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_full_payload_premerge() { ApiTester::new() .await .test_blinded_block_production::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_with_skip_slots_full_payload_premerge() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_blinded_block_production::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_no_verify_randao_full_payload_premerge() { ApiTester::new() .await .test_blinded_block_production_no_verify_randao::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_verify_randao_invalid_full_payload_premerge() { ApiTester::new() .await .test_blinded_block_production_verify_randao_invalid::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_blinded_payload_premerge() { ApiTester::new() .await .test_blinded_block_production::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_with_skip_slots_blinded_payload_premerge() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_blinded_block_production::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_no_verify_randao_blinded_payload_premerge() { ApiTester::new() .await .test_blinded_block_production_no_verify_randao::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn blinded_block_production_verify_randao_invalid_blinded_payload_premerge() { ApiTester::new() .await .test_blinded_block_production_verify_randao_invalid::>() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_attestation_data() { ApiTester::new() .await .test_get_validator_attestation_data() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_attestation_data_with_skip_slots() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_get_validator_attestation_data() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_aggregate_attestation() { ApiTester::new() .await .test_get_validator_aggregate_attestation() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_aggregate_attestation_with_skip_slots() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_get_validator_aggregate_attestation() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_aggregate_and_proofs_valid() { ApiTester::new() .await .test_get_validator_aggregate_and_proofs_valid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_aggregate_and_proofs_valid_with_skip_slots() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_get_validator_aggregate_and_proofs_valid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_aggregate_and_proofs_invalid() { ApiTester::new() .await .test_get_validator_aggregate_and_proofs_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_aggregate_and_proofs_invalid_with_skip_slots() { ApiTester::new() .await .skip_slots(E::slots_per_epoch() * 2) .test_get_validator_aggregate_and_proofs_invalid() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_validator_beacon_committee_subscriptions() { ApiTester::new() .await .test_get_validator_beacon_committee_subscriptions() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn post_validator_register_validator() { ApiTester::new() .await .test_post_validator_register_validator() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn post_validator_register_validator_slashed() { ApiTester::new() .await .test_post_validator_register_validator_slashed() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn post_validator_register_valid() { ApiTester::new_mev_tester() .await .test_payload_respects_registration() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn post_validator_register_gas_limit_mutation() { ApiTester::new_mev_tester() .await .test_payload_accepts_mutated_gas_limit() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn post_validator_register_fee_recipient_mutation() { ApiTester::new_mev_tester() .await .test_payload_accepts_changed_fee_recipient() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_blinded_block_invalid_parent_hash() { ApiTester::new_mev_tester() .await .test_payload_rejects_invalid_parent_hash() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_blinded_block_invalid_prev_randao() { ApiTester::new_mev_tester() .await .test_payload_rejects_invalid_prev_randao() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_blinded_block_invalid_block_number() { ApiTester::new_mev_tester() .await .test_payload_rejects_invalid_block_number() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_blinded_block_invalid_timestamp() { ApiTester::new_mev_tester() .await .test_payload_rejects_invalid_timestamp() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn get_blinded_block_invalid_signature() { ApiTester::new_mev_tester() .await .test_payload_rejects_invalid_signature() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn builder_chain_health_skips() { ApiTester::new_mev_tester() .await .test_builder_chain_health_skips() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn builder_chain_health_skips_per_epoch() { ApiTester::new_mev_tester() .await .test_builder_chain_health_skips_per_epoch() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn builder_chain_health_epochs_since_finalization() { ApiTester::new_mev_tester() .await .test_builder_chain_health_epochs_since_finalization() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn builder_chain_health_optimistic_head() { ApiTester::new_mev_tester() .await .test_builder_chain_health_optimistic_head() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn builder_inadequate_builder_threshold() { ApiTester::new_mev_tester() .await .test_payload_rejects_inadequate_builder_threshold() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn builder_payload_chosen_by_profit() { ApiTester::new_mev_tester_no_builder_threshold() .await .test_builder_payload_chosen_when_more_profitable() .await .test_local_payload_chosen_when_equally_profitable() .await .test_local_payload_chosen_when_more_profitable() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn builder_works_post_capella() { let mut config = ApiTesterConfig { builder_threshold: Some(0), spec: E::default_spec(), }; config.spec.altair_fork_epoch = Some(Epoch::new(0)); config.spec.bellatrix_fork_epoch = Some(Epoch::new(0)); config.spec.capella_fork_epoch = Some(Epoch::new(0)); ApiTester::new_from_config(config) .await .test_post_validator_register_validator() .await .test_builder_works_post_capella() .await .test_lighthouse_rejects_invalid_withdrawals_root() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn lighthouse_endpoints() { ApiTester::new() .await .test_get_lighthouse_health() .await .test_get_lighthouse_syncing() .await .test_get_lighthouse_proto_array() .await .test_get_lighthouse_validator_inclusion() .await .test_get_lighthouse_validator_inclusion_global() .await .test_get_lighthouse_eth1_syncing() .await .test_get_lighthouse_eth1_block_cache() .await .test_get_lighthouse_eth1_deposit_cache() .await .test_get_lighthouse_beacon_states_ssz() .await .test_get_lighthouse_staking() .await .test_get_lighthouse_database_info() .await .test_post_lighthouse_database_reconstruct() .await .test_post_lighthouse_liveness() .await; } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn optimistic_responses() { ApiTester::new_with_hard_forks(true, true) .await .test_check_optimistic_responses() .await; }