use std::{collections::HashMap, path::Path}; use serde::{Deserialize, Serialize}; use ethers_core::abi::{Abi, Address}; use crate::{ source_tree::{SourceTree, SourceTreeEntry}, Client, EtherscanError, Response, Result, }; /// Arguments for verifying contracts #[derive(Debug, Clone, Serialize, Deserialize)] pub struct VerifyContract { #[serde(rename = "contractaddress")] pub address: Address, #[serde(rename = "sourceCode")] pub source: String, #[serde(rename = "codeformat")] pub code_format: CodeFormat, /// if codeformat=solidity-standard-json-input, then expected as /// `erc20.sol:erc20` #[serde(rename = "contractname")] pub contract_name: String, #[serde(rename = "compilerversion")] pub compiler_version: String, /// applicable when codeformat=solidity-single-file #[serde(rename = "optimizationUsed", skip_serializing_if = "Option::is_none")] pub optimization_used: Option, /// applicable when codeformat=solidity-single-file #[serde(skip_serializing_if = "Option::is_none")] pub runs: Option, /// NOTE: there is a typo in the etherscan API `constructorArguements` #[serde(rename = "constructorArguements", skip_serializing_if = "Option::is_none")] pub constructor_arguments: Option, /// applicable when codeformat=solidity-single-file #[serde(rename = "evmversion", skip_serializing_if = "Option::is_none")] pub evm_version: Option, #[serde(flatten)] pub other: HashMap, } impl VerifyContract { pub fn new( address: Address, contract_name: String, source: String, compiler_version: String, ) -> Self { Self { address, source, code_format: Default::default(), contract_name, compiler_version, optimization_used: None, runs: None, constructor_arguments: None, evm_version: None, other: Default::default(), } } #[must_use] pub fn runs(mut self, runs: u32) -> Self { self.runs = Some(format!("{}", runs)); self } #[must_use] pub fn optimization(self, optimization: bool) -> Self { if optimization { self.optimized() } else { self.not_optimized() } } #[must_use] pub fn optimized(mut self) -> Self { self.optimization_used = Some("1".to_string()); self } #[must_use] pub fn not_optimized(mut self) -> Self { self.optimization_used = Some("0".to_string()); self } #[must_use] pub fn code_format(mut self, code_format: CodeFormat) -> Self { self.code_format = code_format; self } #[must_use] pub fn evm_version(mut self, evm_version: impl Into) -> Self { self.evm_version = Some(evm_version.into()); self } #[must_use] pub fn constructor_arguments( mut self, constructor_arguments: Option>, ) -> Self { self.constructor_arguments = constructor_arguments.map(|s| { s.into() .trim() // TODO is this correct? .trim_start_matches("0x") .to_string() }); self } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Serialize, Deserialize)] pub enum CodeFormat { #[serde(rename = "solidity-single-file")] SingleFile, #[serde(rename = "solidity-standard-json-input")] StandardJsonInput, } impl AsRef for CodeFormat { fn as_ref(&self) -> &str { match self { CodeFormat::SingleFile => "solidity-single-file", CodeFormat::StandardJsonInput => "solidity-standard-json-input", } } } impl Default for CodeFormat { fn default() -> Self { CodeFormat::StandardJsonInput } } #[derive(Debug, Serialize, Deserialize)] #[serde(transparent)] pub struct ContractMetadata { pub items: Vec, } impl IntoIterator for ContractMetadata { type Item = Metadata; type IntoIter = std::vec::IntoIter; fn into_iter(self) -> Self::IntoIter { self.items.into_iter() } } #[derive(Deserialize)] struct EtherscanSourceEntry { content: String, } #[derive(Deserialize)] struct EtherscanSourceJsonMetadata { sources: HashMap, } impl ContractMetadata { /// All ABI from all contracts in the source file pub fn abis(&self) -> Result> { let mut abis = Vec::with_capacity(self.items.len()); for item in &self.items { abis.push(serde_json::from_str(&item.abi)?); } Ok(abis) } /// Combined source code of all contracts pub fn source_code(&self) -> String { self.items.iter().map(|c| c.source_code.as_str()).collect::>().join("\n") } /// Etherscan can either return one raw string that includes all of the solidity for a verified /// contract or a json struct surrounded in an extra set of {} that includes a directory /// structure with paths and source code. fn get_sources_from_etherscan_source_value( contract_name: &str, etherscan_source: &str, ) -> Result> { if etherscan_source.starts_with("{{") && etherscan_source.ends_with("}}") { let json = ðerscan_source[1..etherscan_source.len() - 1]; let parsed: EtherscanSourceJsonMetadata = serde_json::from_str(json)?; Ok(parsed .sources .into_iter() .map(|(path, source_struct)| (path, source_struct.content)) .collect()) } else { Ok(vec![(contract_name.to_string(), etherscan_source.to_string())]) } } pub fn source_tree(&self) -> Result { let mut entries = vec![]; for item in &self.items { let contract_root = Path::new(&item.contract_name); let source_paths = Self::get_sources_from_etherscan_source_value( &item.contract_name, &item.source_code, )?; for (path, contents) in source_paths { let joined = contract_root.join(&path); entries.push(SourceTreeEntry { path: joined, contents }); } } Ok(SourceTree { entries }) } } /// Etherscan contract metadata #[derive(Debug, Serialize, Deserialize)] pub struct Metadata { #[serde(rename = "SourceCode")] pub source_code: String, #[serde(rename = "ABI")] pub abi: String, #[serde(rename = "ContractName")] pub contract_name: String, #[serde(rename = "CompilerVersion")] pub compiler_version: String, #[serde(rename = "OptimizationUsed")] pub optimization_used: String, #[serde(rename = "Runs")] pub runs: String, #[serde(rename = "ConstructorArguments")] pub constructor_arguments: String, #[serde(rename = "EVMVersion")] pub evm_version: String, #[serde(rename = "Library")] pub library: String, #[serde(rename = "LicenseType")] pub license_type: String, #[serde(rename = "Proxy")] pub proxy: String, #[serde(rename = "Implementation")] pub implementation: String, #[serde(rename = "SwarmSource")] pub swarm_source: String, } impl Client { /// Submit Source Code for Verification pub async fn submit_contract_verification( &self, contract: &VerifyContract, ) -> Result> { let body = self.create_query("contract", "verifysourcecode", contract); self.post_form(&body).await } /// Check Source Code Verification Status with receipt received from /// `[Self::submit_contract_verification]` pub async fn check_contract_verification_status( &self, guid: impl AsRef, ) -> Result> { let body = self.create_query( "contract", "checkverifystatus", HashMap::from([("guid", guid.as_ref())]), ); self.post_form(&body).await } /// Returns the contract ABI of a verified contract /// /// ```no_run /// # use ethers_etherscan::Client; /// # use ethers_core::types::Chain; /// /// # #[tokio::main] /// # async fn main() { /// let client = Client::new(Chain::Mainnet, "API_KEY").unwrap(); /// let abi = client /// .contract_abi("0xBB9bc244D798123fDe783fCc1C72d3Bb8C189413".parse().unwrap()) /// .await.unwrap(); /// # } /// ``` pub async fn contract_abi(&self, address: Address) -> Result { // apply caching if let Some(ref cache) = self.cache { // If this is None, then we have a cache miss if let Some(src) = cache.get_abi(address) { // If this is None, then the contract is not verified return match src { Some(src) => Ok(src), None => Err(EtherscanError::ContractCodeNotVerified(address)), } } } let query = self.create_query("contract", "getabi", HashMap::from([("address", address)])); let resp: Response = self.get_json(&query).await?; if resp.result.starts_with("Max rate limit reached") { return Err(EtherscanError::RateLimitExceeded) } if resp.result.starts_with("Contract source code not verified") { if let Some(ref cache) = self.cache { cache.set_abi(address, None); } return Err(EtherscanError::ContractCodeNotVerified(address)) } let abi = serde_json::from_str(&resp.result)?; if let Some(ref cache) = self.cache { cache.set_abi(address, Some(&abi)); } Ok(abi) } /// Get Contract Source Code for Verified Contract Source Codes /// ```no_run /// # use ethers_etherscan::Client; /// # use ethers_core::types::Chain; /// /// # #[tokio::main] /// # async fn main() { /// let client = Client::new(Chain::Mainnet, "API_KEY").unwrap(); /// let meta = client /// .contract_source_code("0xBB9bc244D798123fDe783fCc1C72d3Bb8C189413".parse().unwrap()) /// .await.unwrap(); /// let code = meta.source_code(); /// # } /// ``` pub async fn contract_source_code(&self, address: Address) -> Result { // apply caching if let Some(ref cache) = self.cache { // If this is None, then we have a cache miss if let Some(src) = cache.get_source(address) { // If this is None, then the contract is not verified return match src { Some(src) => Ok(src), None => Err(EtherscanError::ContractCodeNotVerified(address)), } } } let query = self.create_query("contract", "getsourcecode", HashMap::from([("address", address)])); let response: Response> = self.get_json(&query).await?; if response.result.iter().any(|item| item.abi == "Contract source code not verified") { if let Some(ref cache) = self.cache { cache.set_source(address, None); } return Err(EtherscanError::ContractCodeNotVerified(address)) } let res = ContractMetadata { items: response.result }; if let Some(ref cache) = self.cache { cache.set_source(address, Some(&res)); } Ok(res) } } #[cfg(test)] mod tests { use crate::{contract::VerifyContract, tests::run_at_least_duration, Client, EtherscanError}; use ethers_core::types::Chain; use ethers_solc::{Project, ProjectPathsConfig}; use serial_test::serial; use std::{path::PathBuf, time::Duration}; #[allow(unused)] fn init_tracing() { tracing_subscriber::fmt() .with_env_filter(tracing_subscriber::EnvFilter::from_default_env()) .init(); } #[tokio::test] #[serial] #[ignore] async fn can_fetch_ftm_contract_abi() { init_tracing(); run_at_least_duration(Duration::from_millis(250), async { let client = Client::new_from_env(Chain::Fantom).unwrap(); let _abi = client .contract_abi("0x80AA7cb0006d5DDD91cce684229Ac6e398864606".parse().unwrap()) .await .unwrap(); }) .await; } #[tokio::test] #[serial] #[ignore] async fn can_fetch_contract_abi() { run_at_least_duration(Duration::from_millis(250), async { let client = Client::new_from_env(Chain::Mainnet).unwrap(); let _abi = client .contract_abi("0xBB9bc244D798123fDe783fCc1C72d3Bb8C189413".parse().unwrap()) .await .unwrap(); }) .await; } #[tokio::test] #[serial] #[ignore] async fn can_fetch_contract_source_code() { run_at_least_duration(Duration::from_millis(250), async { let client = Client::new_from_env(Chain::Mainnet).unwrap(); let _meta = client .contract_source_code("0xBB9bc244D798123fDe783fCc1C72d3Bb8C189413".parse().unwrap()) .await .unwrap(); }) .await } #[tokio::test] #[serial] #[ignore] async fn can_get_error_on_unverified_contract() { run_at_least_duration(Duration::from_millis(250), async { let client = Client::new_from_env(Chain::Mainnet).unwrap(); let unverified_addr = "0xb5c31a0e22cae98ac08233e512bd627885aa24e5".parse().unwrap(); let result = client.contract_source_code(unverified_addr).await; match result.err() { Some(error) => match error { EtherscanError::ContractCodeNotVerified(addr) => { assert_eq!(addr, unverified_addr); } _ => panic!("Invalid EtherscanError type"), }, None => panic!("Result should contain ContractCodeNotVerified error"), } }) .await } /// Query a contract that has a single string source entry instead of underlying JSON metadata. #[tokio::test] #[serial] #[ignore] async fn can_fetch_contract_source_tree_for_singleton_contract() { run_at_least_duration(Duration::from_millis(250), async { let client = Client::new_from_env(Chain::Mainnet).unwrap(); let meta = client .contract_source_code("0xBB9bc244D798123fDe783fCc1C72d3Bb8C189413".parse().unwrap()) .await .unwrap(); let source_tree = meta.source_tree().unwrap(); assert_eq!(source_tree.entries.len(), 1); }) .await } /// Query a contract that has many source entries as JSON metadata and ensure they are /// reflected. #[tokio::test] #[serial] #[ignore] async fn can_fetch_contract_source_tree_for_multi_entry_contract() { run_at_least_duration(Duration::from_millis(250), async { let client = Client::new_from_env(Chain::Mainnet).unwrap(); let meta = client .contract_source_code("0x8d04a8c79cEB0889Bdd12acdF3Fa9D207eD3Ff63".parse().unwrap()) .await .unwrap(); let source_tree = meta.source_tree().unwrap(); assert_eq!(source_tree.entries.len(), 15); }) .await } #[tokio::test] #[serial] async fn can_flatten_and_verify_contract() { run_at_least_duration(Duration::from_millis(250), async { let root = PathBuf::from(env!("CARGO_MANIFEST_DIR")).join("resources"); let paths = ProjectPathsConfig::builder() .sources(&root) .build() .expect("failed to resolve project paths"); let project = Project::builder() .paths(paths) .build() .expect("failed to build the project"); let address = "0x9e744c9115b74834c0f33f4097f40c02a9ac5c33".parse().unwrap(); let compiler_version = "v0.5.17+commit.d19bba13"; let constructor_args = "0x000000000000000000000000000000000000000000000000000000000000006000000000000000000000000000000000000000000000000000000000000000a00000000000000000000000000000000000000000000000000000000005f5e1000000000000000000000000000000000000000000000000000000000000000007596179537761700000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000035941590000000000000000000000000000000000000000000000000000000000"; let contract = project.flatten(&root.join("UniswapExchange.sol")).expect("failed to flatten contract"); let contract_name = "UniswapExchange".to_owned(); let client = Client::new_from_env(Chain::Mainnet).unwrap(); let contract = VerifyContract::new(address, contract_name, contract, compiler_version.to_string()) .constructor_arguments(Some(constructor_args)) .optimization(true) .runs(200); let resp = client.submit_contract_verification(&contract).await.expect("failed to send the request"); assert_ne!(resp.result, "Error!"); // `Error!` result means that request was malformatted }) .await } }