388 lines
14 KiB
Rust
388 lines
14 KiB
Rust
use ethers::{contract::ContractFactory, types::H256};
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mod common;
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pub use common::*;
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#[cfg(not(feature = "celo"))]
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mod eth_tests {
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use super::*;
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use ethers::{
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contract::Multicall,
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providers::{Http, Provider, StreamExt},
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signers::Client,
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types::{Address, U256},
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utils::Ganache,
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};
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use std::{convert::TryFrom, sync::Arc};
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#[tokio::test]
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async fn deploy_and_call_contract() {
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let (abi, bytecode) = compile_contract("SimpleStorage", "SimpleStorage.sol");
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// launch ganache
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let ganache = Ganache::new().spawn();
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// Instantiate the clients. We assume that clients consume the provider and the wallet
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// (which makes sense), so for multi-client tests, you must clone the provider.
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let client = connect(&ganache, 0);
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let client2 = connect(&ganache, 1);
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// create a factory which will be used to deploy instances of the contract
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let factory = ContractFactory::new(abi, bytecode, client.clone());
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// `send` consumes the deployer so it must be cloned for later re-use
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// (practically it's not expected that you'll need to deploy multiple instances of
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// the _same_ deployer, so it's fine to clone here from a dev UX vs perf tradeoff)
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let deployer = factory.deploy("initial value".to_string()).unwrap();
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let contract = deployer.clone().send().await.unwrap();
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let get_value = contract.method::<_, String>("getValue", ()).unwrap();
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let last_sender = contract.method::<_, Address>("lastSender", ()).unwrap();
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// the initial value must be the one set in the constructor
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let value = get_value.clone().call().await.unwrap();
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assert_eq!(value, "initial value");
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// need to declare the method first, and only then send it
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// this is because it internally clones an Arc which would otherwise
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// get immediately dropped
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let _tx_hash = contract
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.connect(client2.clone())
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.method::<_, H256>("setValue", "hi".to_owned())
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.unwrap()
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.send()
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.await
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.unwrap();
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assert_eq!(last_sender.clone().call().await.unwrap(), client2.address());
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assert_eq!(get_value.clone().call().await.unwrap(), "hi");
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// we can also call contract methods at other addresses with the `at` call
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// (useful when interacting with multiple ERC20s for example)
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let contract2_addr = deployer.send().await.unwrap().address();
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let contract2 = contract.at(contract2_addr);
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let init_value: String = contract2
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.method::<_, String>("getValue", ())
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.unwrap()
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.call()
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.await
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.unwrap();
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let init_address = contract2
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.method::<_, Address>("lastSender", ())
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.unwrap()
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.call()
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.await
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.unwrap();
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assert_eq!(init_address, Address::zero());
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assert_eq!(init_value, "initial value");
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// methods with multiple args also work
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let _tx_hash = contract
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.method::<_, H256>("setValues", ("hi".to_owned(), "bye".to_owned()))
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.unwrap()
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.send()
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.await
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.unwrap();
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}
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#[tokio::test]
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async fn get_past_events() {
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let (abi, bytecode) = compile_contract("SimpleStorage", "SimpleStorage.sol");
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let ganache = Ganache::new().spawn();
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let client = connect(&ganache, 0);
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let contract = deploy(client.clone(), abi, bytecode).await;
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// make a call with `client2`
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let _tx_hash = contract
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.method::<_, H256>("setValue", "hi".to_owned())
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.unwrap()
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.send()
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.await
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.unwrap();
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// and we can fetch the events
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let logs: Vec<ValueChanged> = contract
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.event("ValueChanged")
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.unwrap()
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.from_block(0u64)
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.topic1(client.address()) // Corresponds to the first indexed parameter
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.query()
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.await
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.unwrap();
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assert_eq!(logs[0].new_value, "initial value");
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assert_eq!(logs[1].new_value, "hi");
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assert_eq!(logs.len(), 2);
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}
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#[tokio::test]
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async fn watch_events() {
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let (abi, bytecode) = compile_contract("SimpleStorage", "SimpleStorage.sol");
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let ganache = Ganache::new().spawn();
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let client = connect(&ganache, 0);
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let contract = deploy(client, abi, bytecode).await;
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// We spawn the event listener:
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let mut stream = contract
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.event::<ValueChanged>("ValueChanged")
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.unwrap()
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.stream()
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.await
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.unwrap();
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let num_calls = 3u64;
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// and we make a few calls
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for i in 0..num_calls {
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let tx_hash = contract
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.method::<_, H256>("setValue", i.to_string())
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.unwrap()
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.send()
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.await
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.unwrap();
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let _receipt = contract.pending_transaction(tx_hash).await.unwrap();
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}
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for i in 0..num_calls {
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// unwrap the option of the stream, then unwrap the decoding result
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let log = stream.next().await.unwrap().unwrap();
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assert_eq!(log.new_value, i.to_string());
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}
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}
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#[tokio::test]
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async fn signer_on_node() {
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let (abi, bytecode) = compile_contract("SimpleStorage", "SimpleStorage.sol");
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// spawn ganache
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let ganache = Ganache::new().spawn();
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// connect
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let provider = Provider::<Http>::try_from(ganache.endpoint())
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.unwrap()
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.interval(std::time::Duration::from_millis(50u64));
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// get the first account
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let deployer = provider.get_accounts().await.unwrap()[0];
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let client = Arc::new(Client::from(provider).with_sender(deployer));
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let contract = deploy(client, abi, bytecode).await;
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// make a call without the signer
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let tx_hash = contract
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.method::<_, H256>("setValue", "hi".to_owned())
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.unwrap()
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.send()
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.await
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.unwrap();
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let _receipt = contract.pending_transaction(tx_hash).await.unwrap();
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let value: String = contract
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.method::<_, String>("getValue", ())
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.unwrap()
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.call()
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.await
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.unwrap();
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assert_eq!(value, "hi");
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}
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#[tokio::test]
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async fn multicall_aggregate() {
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// get ABI and bytecode for the Multcall contract
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let (multicall_abi, multicall_bytecode) = compile_contract("Multicall", "Multicall.sol");
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// get ABI and bytecode for the NotSoSimpleStorage contract
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let (not_so_simple_abi, not_so_simple_bytecode) =
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compile_contract("NotSoSimpleStorage", "NotSoSimpleStorage.sol");
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// get ABI and bytecode for the SimpleStorage contract
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let (abi, bytecode) = compile_contract("SimpleStorage", "SimpleStorage.sol");
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// launch ganache
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let ganache = Ganache::new().spawn();
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// Instantiate the clients. We assume that clients consume the provider and the wallet
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// (which makes sense), so for multi-client tests, you must clone the provider.
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// `client` is used to deploy the Multicall contract
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// `client2` is used to deploy the first SimpleStorage contract
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// `client3` is used to deploy the second SimpleStorage contract
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// `client4` is used to make the aggregate call
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let client = connect(&ganache, 0);
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let client2 = connect(&ganache, 1);
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let client3 = connect(&ganache, 2);
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let client4 = connect(&ganache, 3);
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// create a factory which will be used to deploy instances of the contract
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let multicall_factory =
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ContractFactory::new(multicall_abi, multicall_bytecode, client.clone());
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let simple_factory = ContractFactory::new(abi.clone(), bytecode.clone(), client2.clone());
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let not_so_simple_factory =
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ContractFactory::new(not_so_simple_abi, not_so_simple_bytecode, client3.clone());
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let multicall_contract = multicall_factory.deploy(()).unwrap().send().await.unwrap();
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let addr = multicall_contract.address();
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let simple_contract = simple_factory
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.deploy("the first one".to_string())
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.unwrap()
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.send()
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.await
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.unwrap();
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let not_so_simple_contract = not_so_simple_factory
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.deploy("the second one".to_string())
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.unwrap()
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.send()
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.await
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.unwrap();
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// Client2 and Client3 broadcast txs to set the values for both contracts
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simple_contract
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.connect(client2.clone())
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.method::<_, H256>("setValue", "reset first".to_owned())
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.unwrap()
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.send()
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.await
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.unwrap();
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not_so_simple_contract
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.connect(client3.clone())
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.method::<_, H256>("setValue", "reset second".to_owned())
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.unwrap()
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.send()
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.await
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.unwrap();
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// get the calls for `value` and `last_sender` for both SimpleStorage contracts
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let value = simple_contract.method::<_, String>("getValue", ()).unwrap();
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let value2 = not_so_simple_contract
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.method::<_, (String, Address)>("getValues", ())
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.unwrap();
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let last_sender = simple_contract
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.method::<_, Address>("lastSender", ())
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.unwrap();
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let last_sender2 = not_so_simple_contract
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.method::<_, Address>("lastSender", ())
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.unwrap();
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// initiate the Multicall instance and add calls one by one in builder style
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let multicall = Multicall::new(client4.clone(), Some(addr))
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.await
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.unwrap()
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.add_call(value)
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.add_call(value2)
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.add_call(last_sender)
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.add_call(last_sender2);
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let return_data: (String, (String, Address), Address, Address) =
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multicall.call().await.unwrap();
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assert_eq!(return_data.0, "reset first");
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assert_eq!((return_data.1).0, "reset second");
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assert_eq!((return_data.1).1, client3.address());
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assert_eq!(return_data.2, client2.address());
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assert_eq!(return_data.3, client3.address());
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// construct broadcast transactions that will be batched and broadcast via Multicall
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let broadcast = simple_contract
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.connect(client4.clone())
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.method::<_, H256>("setValue", "first reset again".to_owned())
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.unwrap();
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let broadcast2 = not_so_simple_contract
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.connect(client4.clone())
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.method::<_, H256>("setValue", "second reset again".to_owned())
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.unwrap();
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// use the already initialised Multicall instance, clearing the previous calls and adding
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// new calls. Previously we used the `.call()` functionality to do a batch of calls in one
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// go. Now we will use the `.send()` functionality to broadcast a batch of transactions
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// in one go
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let multicall_send = multicall
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.clone()
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.clear_calls()
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.add_call(broadcast)
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.add_call(broadcast2);
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// broadcast the transaction and wait for it to be mined
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let tx_hash = multicall_send.send().await.unwrap();
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let _tx_receipt = client4.pending_transaction(tx_hash).await.unwrap();
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// Do another multicall to check the updated return values
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// The `getValue` calls should return the last value we set in the batched broadcast
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// The `lastSender` calls should return the address of the Multicall contract, as it is
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// the one acting as proxy and calling our SimpleStorage contracts (msg.sender)
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let return_data: (String, (String, Address), Address, Address) =
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multicall.call().await.unwrap();
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assert_eq!(return_data.0, "first reset again");
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assert_eq!((return_data.1).0, "second reset again");
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assert_eq!((return_data.1).1, multicall_contract.address());
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assert_eq!(return_data.2, multicall_contract.address());
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assert_eq!(return_data.3, multicall_contract.address());
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// query ETH balances of multiple addresses
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// these keys haven't been used to do any tx
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// so should have 100 ETH
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let multicall = multicall
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.clear_calls()
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.eth_balance_of(Address::from(&ganache.keys()[4]))
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.eth_balance_of(Address::from(&ganache.keys()[5]))
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.eth_balance_of(Address::from(&ganache.keys()[6]));
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let balances: (U256, U256, U256) = multicall.call().await.unwrap();
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assert_eq!(balances.0, U256::from(100000000000000000000u128));
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assert_eq!(balances.1, U256::from(100000000000000000000u128));
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assert_eq!(balances.2, U256::from(100000000000000000000u128));
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}
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}
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#[cfg(feature = "celo")]
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mod celo_tests {
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use super::*;
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use ethers::{
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providers::{Http, Provider},
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signers::Wallet,
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types::BlockNumber,
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};
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use std::{convert::TryFrom, sync::Arc, time::Duration};
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#[tokio::test]
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async fn deploy_and_call_contract() {
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let (abi, bytecode) = compile_contract("SimpleStorage", "SimpleStorage.sol");
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// Celo testnet
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let provider =
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Provider::<Http>::try_from("https://alfajores-forno.celo-testnet.org").unwrap();
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// Funded with https://celo.org/developers/faucet
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let client = "d652abb81e8c686edba621a895531b1f291289b63b5ef09a94f686a5ecdd5db1"
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.parse::<Wallet>()
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.unwrap()
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.connect(provider)
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.interval(Duration::from_millis(6000));
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let client = Arc::new(client);
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let factory = ContractFactory::new(abi, bytecode, client);
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let deployer = factory.deploy("initial value".to_string()).unwrap();
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let contract = deployer.block(BlockNumber::Pending).send().await.unwrap();
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let value: String = contract
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.method("getValue", ())
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.unwrap()
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.call()
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.await
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.unwrap();
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assert_eq!(value, "initial value");
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// make a state mutating transaction
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let tx_hash = contract
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.method::<_, H256>("setValue", "hi".to_owned())
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.unwrap()
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.send()
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.await
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.unwrap();
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let _receipt = contract.pending_transaction(tx_hash).await.unwrap();
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let value: String = contract
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.method("getValue", ())
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.unwrap()
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.call()
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.await
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.unwrap();
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assert_eq!(value, "hi");
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}
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}
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