use std::{collections::HashMap, str::FromStr}; use alloy::{ primitives::{Address, Bytes as AlloyBytes, U8}, sol_types::SolValue, }; use serde_json::from_str; use tycho_common::Bytes; use crate::encoding::{ errors::EncodingError, evm::{ approvals::protocol_approvals_manager::ProtocolApprovalsManager, utils::{bytes_to_address, get_static_attribute, pad_to_fixed_size}, }, models::{Chain, EncodingContext, Swap}, swap_encoder::SwapEncoder, }; /// Encodes a swap on a Uniswap V2 pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. #[derive(Clone)] pub struct UniswapV2SwapEncoder { executor_address: String, } impl UniswapV2SwapEncoder { fn get_zero_to_one(sell_token_address: Address, buy_token_address: Address) -> bool { sell_token_address < buy_token_address } } impl SwapEncoder for UniswapV2SwapEncoder { fn new( executor_address: String, _chain: Chain, _config: Option>, ) -> Result { Ok(Self { executor_address }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { let token_in_address = bytes_to_address(&swap.token_in)?; let token_out_address = bytes_to_address(&swap.token_out)?; let zero_to_one = Self::get_zero_to_one(token_in_address, token_out_address); let component_id = Address::from_str(&swap.component.id) .map_err(|_| EncodingError::FatalError("Invalid USV2 component id".to_string()))?; // Token in address is always needed to perform a manual transfer from the router, // since no optimizations are performed that send from one pool to the next let args = ( token_in_address, component_id, bytes_to_address(&encoding_context.receiver)?, zero_to_one, (encoding_context.transfer_type as u8).to_be_bytes(), ); Ok(args.abi_encode_packed()) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } /// Encodes a swap on a Uniswap V3 pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. #[derive(Clone)] pub struct UniswapV3SwapEncoder { executor_address: String, } impl UniswapV3SwapEncoder { fn get_zero_to_one(sell_token_address: Address, buy_token_address: Address) -> bool { sell_token_address < buy_token_address } } impl SwapEncoder for UniswapV3SwapEncoder { fn new( executor_address: String, _chain: Chain, _config: Option>, ) -> Result { Ok(Self { executor_address }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { let token_in_address = bytes_to_address(&swap.token_in)?; let token_out_address = bytes_to_address(&swap.token_out)?; let zero_to_one = Self::get_zero_to_one(token_in_address, token_out_address); let component_id = Address::from_str(&swap.component.id) .map_err(|_| EncodingError::FatalError("Invalid USV3 component id".to_string()))?; let pool_fee_bytes = get_static_attribute(swap, "fee")?; let pool_fee_u24 = pad_to_fixed_size::<3>(&pool_fee_bytes) .map_err(|_| EncodingError::FatalError("Failed to extract fee bytes".to_string()))?; let args = ( token_in_address, token_out_address, pool_fee_u24, bytes_to_address(&encoding_context.receiver)?, component_id, zero_to_one, (encoding_context.transfer_type as u8).to_be_bytes(), ); Ok(args.abi_encode_packed()) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } /// Encodes a swap on a Uniswap V4 pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. #[derive(Clone)] pub struct UniswapV4SwapEncoder { executor_address: String, } impl UniswapV4SwapEncoder { fn get_zero_to_one(sell_token_address: Address, buy_token_address: Address) -> bool { sell_token_address < buy_token_address } } impl SwapEncoder for UniswapV4SwapEncoder { fn new( executor_address: String, _chain: Chain, _config: Option>, ) -> Result { Ok(Self { executor_address }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { let fee = get_static_attribute(swap, "key_lp_fee")?; let pool_fee_u24 = pad_to_fixed_size::<3>(&fee) .map_err(|_| EncodingError::FatalError("Failed to pad fee bytes".to_string()))?; let tick_spacing = get_static_attribute(swap, "tick_spacing")?; let pool_tick_spacing_u24 = pad_to_fixed_size::<3>(&tick_spacing).map_err(|_| { EncodingError::FatalError("Failed to pad tick spacing bytes".to_string()) })?; // Early check if this is not the first swap if encoding_context.group_token_in != swap.token_in { return Ok((bytes_to_address(&swap.token_out)?, pool_fee_u24, pool_tick_spacing_u24) .abi_encode_packed()); } // This is the first swap, compute all necessary values let token_in_address = bytes_to_address(&swap.token_in)?; let token_out_address = bytes_to_address(&swap.token_out)?; let group_token_in_address = bytes_to_address(&encoding_context.group_token_in)?; let group_token_out_address = bytes_to_address(&encoding_context.group_token_out)?; let zero_to_one = Self::get_zero_to_one(token_in_address, token_out_address); let pool_params = (token_out_address, pool_fee_u24, pool_tick_spacing_u24).abi_encode_packed(); let args = ( group_token_in_address, group_token_out_address, zero_to_one, (encoding_context.transfer_type as u8).to_be_bytes(), bytes_to_address(&encoding_context.receiver)?, pool_params, ); Ok(args.abi_encode_packed()) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } /// Encodes a swap on a Balancer V2 pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. /// * `vault_address` - The address of the vault contract that will perform the swap. #[derive(Clone)] pub struct BalancerV2SwapEncoder { executor_address: String, vault_address: String, } impl SwapEncoder for BalancerV2SwapEncoder { fn new( executor_address: String, _chain: Chain, config: Option>, ) -> Result { let config = config.ok_or(EncodingError::FatalError( "Missing balancer v2 specific addresses in config".to_string(), ))?; let vault_address = config .get("vault_address") .ok_or(EncodingError::FatalError( "Missing balancer v2 vault address in config".to_string(), ))? .to_string(); Ok(Self { executor_address, vault_address }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { let token_approvals_manager = ProtocolApprovalsManager::new()?; let token = bytes_to_address(&swap.token_in)?; let approval_needed: bool; if let Some(router_address) = &encoding_context.router_address { let tycho_router_address = bytes_to_address(router_address)?; approval_needed = token_approvals_manager.approval_needed( token, tycho_router_address, Address::from_str(&self.vault_address) .map_err(|_| EncodingError::FatalError("Invalid vault address".to_string()))?, )?; } else { approval_needed = true; } let component_id = AlloyBytes::from_str(&swap.component.id) .map_err(|_| EncodingError::FatalError("Invalid component ID".to_string()))?; let args = ( bytes_to_address(&swap.token_in)?, bytes_to_address(&swap.token_out)?, component_id, bytes_to_address(&encoding_context.receiver)?, approval_needed, (encoding_context.transfer_type as u8).to_be_bytes(), ); Ok(args.abi_encode_packed()) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } /// Encodes a swap on an Ekubo pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. #[derive(Clone, Debug, PartialEq, Eq)] pub struct EkuboSwapEncoder { executor_address: String, } impl SwapEncoder for EkuboSwapEncoder { fn new( executor_address: String, _chain: Chain, _config: Option>, ) -> Result { Ok(Self { executor_address }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { if encoding_context.exact_out { return Err(EncodingError::InvalidInput("exact out swaps not implemented".to_string())); } let fee = u64::from_be_bytes( get_static_attribute(swap, "fee")? .try_into() .map_err(|_| EncodingError::FatalError("fee should be an u64".to_string()))?, ); let tick_spacing = u32::from_be_bytes( get_static_attribute(swap, "tick_spacing")? .try_into() .map_err(|_| { EncodingError::FatalError("tick_spacing should be an u32".to_string()) })?, ); let extension: Address = get_static_attribute(swap, "extension")? .as_slice() .try_into() .map_err(|_| EncodingError::FatalError("extension should be an address".to_string()))?; let mut encoded = vec![]; if encoding_context.group_token_in == swap.token_in { encoded.extend((encoding_context.transfer_type as u8).to_be_bytes()); encoded.extend(bytes_to_address(&encoding_context.receiver)?); encoded.extend(bytes_to_address(&swap.token_in)?); } encoded.extend(bytes_to_address(&swap.token_out)?); encoded.extend((extension, fee, tick_spacing).abi_encode_packed()); Ok(encoded) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } /// Encodes a swap on a Curve pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. /// * `meta_registry_address` - The address of the Curve meta registry contract. Used to get coin /// indexes. /// * `native_token_curve_address` - The address used as native token in curve pools. /// * `native_token_address` - The address of the native token. #[derive(Clone)] pub struct CurveSwapEncoder { executor_address: String, native_token_curve_address: String, native_token_address: Bytes, wrapped_native_token_address: Bytes, } impl CurveSwapEncoder { fn get_pool_type(&self, pool_id: &str, factory_address: &str) -> Result { match pool_id { // TriPool "0xbEbc44782C7dB0a1A60Cb6fe97d0b483032FF1C7" => Ok(U8::from(1)), // STETHPool "0xDC24316b9AE028F1497c275EB9192a3Ea0f67022" => Ok(U8::from(1)), // TriCryptoPool "0xD51a44d3FaE010294C616388b506AcdA1bfAAE46" => Ok(U8::from(3)), // SUSDPool "0xA5407eAE9Ba41422680e2e00537571bcC53efBfD" => Ok(U8::from(1)), // FRAXUSDCPool "0xDcEF968d416a41Cdac0ED8702fAC8128A64241A2" => Ok(U8::from(1)), _ => match factory_address { // CryptoSwapNG factory "0x6A8cbed756804B16E05E741eDaBd5cB544AE21bf" => Ok(U8::from(1)), // Metapool factory "0xB9fC157394Af804a3578134A6585C0dc9cc990d4" => Ok(U8::from(1)), // CryptoPool factory "0xF18056Bbd320E96A48e3Fbf8bC061322531aac99" => Ok(U8::from(2)), // Tricrypto factory "0x0c0e5f2fF0ff18a3be9b835635039256dC4B4963" => Ok(U8::from(3)), // Twocrypto factory "0x98EE851a00abeE0d95D08cF4CA2BdCE32aeaAF7F" => Ok(U8::from(2)), // StableSwap factory "0x4F8846Ae9380B90d2E71D5e3D042dff3E7ebb40d" => Ok(U8::from(1)), _ => Err(EncodingError::FatalError(format!( "Unsupported curve factory address: {factory_address}" ))), }, } } // Some curve pools support both ETH and WETH as tokens. // They do the wrapping/unwrapping inside the pool fn normalize_token(&self, token: Address, coins: &[Address]) -> Result { let native_token_address = bytes_to_address(&self.native_token_address)?; let wrapped_native_token_address = bytes_to_address(&self.wrapped_native_token_address)?; if token == native_token_address && !coins.contains(&token) { Ok(wrapped_native_token_address) } else if token == wrapped_native_token_address && !coins.contains(&token) { Ok(native_token_address) } else { Ok(token) } } fn get_coin_indexes( &self, swap: &Swap, token_in: Address, token_out: Address, ) -> Result<(U8, U8), EncodingError> { let coins_bytes = get_static_attribute(swap, "coins")?; let coins: Vec
= from_str(std::str::from_utf8(&coins_bytes)?)?; let token_in = self.normalize_token(token_in, &coins)?; let token_out = self.normalize_token(token_out, &coins)?; let i = coins .iter() .position(|&addr| addr == token_in) .ok_or(EncodingError::FatalError(format!( "Token in address {token_in} not found in curve pool coins" )))?; let j = coins .iter() .position(|&addr| addr == token_out) .ok_or(EncodingError::FatalError(format!( "Token in address {token_out} not found in curve pool coins" )))?; Ok((U8::from(i), U8::from(j))) } } impl SwapEncoder for CurveSwapEncoder { fn new( executor_address: String, chain: Chain, config: Option>, ) -> Result { let config = config.ok_or(EncodingError::FatalError( "Missing curve specific addresses in config".to_string(), ))?; let native_token_curve_address = config .get("native_token_address") .ok_or(EncodingError::FatalError( "Missing native token curve address in config".to_string(), ))? .to_string(); Ok(Self { executor_address, native_token_address: chain.native_token()?, native_token_curve_address, wrapped_native_token_address: chain.wrapped_token()?, }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { let token_approvals_manager = ProtocolApprovalsManager::new()?; let native_token_curve_address = Address::from_str(&self.native_token_curve_address) .map_err(|_| { EncodingError::FatalError("Invalid Curve native token curve address".to_string()) })?; let token_in = if swap.token_in == self.native_token_address { native_token_curve_address } else { bytes_to_address(&swap.token_in)? }; let token_out = if swap.token_out == self.native_token_address { native_token_curve_address } else { bytes_to_address(&swap.token_out)? }; let approval_needed: bool; let component_address = Address::from_str(&swap.component.id) .map_err(|_| EncodingError::FatalError("Invalid curve pool address".to_string()))?; if let Some(router_address) = &encoding_context.router_address { if token_in != native_token_curve_address { let tycho_router_address = bytes_to_address(router_address)?; approval_needed = token_approvals_manager.approval_needed( token_in, tycho_router_address, component_address, )?; } else { approval_needed = false; } } else { approval_needed = true; } let factory_bytes = get_static_attribute(swap, "factory")?.to_vec(); // the conversion to Address is necessary to checksum the address let factory_address = Address::from_str(std::str::from_utf8(&factory_bytes).map_err(|_| { EncodingError::FatalError( "Failed to convert curve factory address to string".to_string(), ) })?) .map_err(|_| EncodingError::FatalError("Invalid curve factory address".to_string()))?; let pool_address = Address::from_str(&swap.component.id) .map_err(|_| EncodingError::FatalError("Invalid curve pool address".to_string()))?; let pool_type = self.get_pool_type(&pool_address.to_string(), &factory_address.to_string())?; let (i, j) = self.get_coin_indexes(swap, token_in, token_out)?; let args = ( token_in, token_out, component_address, pool_type.to_be_bytes::<1>(), i.to_be_bytes::<1>(), j.to_be_bytes::<1>(), approval_needed, (encoding_context.transfer_type as u8).to_be_bytes(), bytes_to_address(&encoding_context.receiver)?, ); Ok(args.abi_encode_packed()) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } /// Encodes a swap on a Maverick V2 pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. #[derive(Clone)] pub struct MaverickV2SwapEncoder { executor_address: String, } impl SwapEncoder for MaverickV2SwapEncoder { fn new( executor_address: String, _chain: Chain, _config: Option>, ) -> Result { Ok(Self { executor_address }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { let component_id = AlloyBytes::from_str(&swap.component.id) .map_err(|_| EncodingError::FatalError("Invalid component ID".to_string()))?; let args = ( bytes_to_address(&swap.token_in)?, component_id, bytes_to_address(&encoding_context.receiver)?, (encoding_context.transfer_type as u8).to_be_bytes(), ); Ok(args.abi_encode_packed()) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } /// Encodes a swap on a Balancer V3 pool through the given executor address. /// /// # Fields /// * `executor_address` - The address of the executor contract that will perform the swap. #[derive(Clone)] pub struct BalancerV3SwapEncoder { executor_address: String, } impl SwapEncoder for BalancerV3SwapEncoder { fn new( executor_address: String, _chain: Chain, _config: Option>, ) -> Result { Ok(Self { executor_address }) } fn encode_swap( &self, swap: &Swap, encoding_context: &EncodingContext, ) -> Result, EncodingError> { let pool = Address::from_str(&swap.component.id).map_err(|_| { EncodingError::FatalError("Invalid pool address for Balancer v3".to_string()) })?; let args = ( bytes_to_address(&swap.token_in)?, bytes_to_address(&swap.token_out)?, pool, (encoding_context.transfer_type as u8).to_be_bytes(), bytes_to_address(&encoding_context.receiver)?, ); Ok(args.abi_encode_packed()) } fn executor_address(&self) -> &str { &self.executor_address } fn clone_box(&self) -> Box { Box::new(self.clone()) } } #[cfg(test)] mod tests { use std::collections::HashMap; use alloy::hex::encode; use num_bigint::BigInt; use tycho_common::{ models::{protocol::ProtocolComponent, Chain as TychoCoreChain}, Bytes, }; use super::*; use crate::encoding::{evm::utils::write_calldata_to_file, models::TransferType}; mod uniswap_v2 { use super::*; #[test] fn test_encode_uniswap_v2() { let usv2_pool = ProtocolComponent { id: String::from("0xA478c2975Ab1Ea89e8196811F51A7B7Ade33eB11"), ..Default::default() }; let token_in = Bytes::from("0xc02aaa39b223fe8d0a0e5c4f27ead9083c756cc2"); let token_out = Bytes::from("0x6b175474e89094c44da98b954eedeac495271d0f"); let swap = Swap { component: usv2_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { receiver: Bytes::from("0x1D96F2f6BeF1202E4Ce1Ff6Dad0c2CB002861d3e"), // BOB exact_out: false, router_address: Some(Bytes::zero(20)), group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::Transfer, }; let encoder = UniswapV2SwapEncoder::new( String::from("0x543778987b293C7E8Cf0722BB2e935ba6f4068D4"), TychoCoreChain::Ethereum.into(), None, ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // in token "c02aaa39b223fe8d0a0e5c4f27ead9083c756cc2", // component id "a478c2975ab1ea89e8196811f51a7b7ade33eb11", // receiver "1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e", // zero for one "00", // transfer type Transfer "01", )) ); write_calldata_to_file("test_encode_uniswap_v2", hex_swap.as_str()); } } mod uniswap_v3 { use super::*; #[test] fn test_encode_uniswap_v3() { let fee = BigInt::from(500); let encoded_pool_fee = Bytes::from(fee.to_signed_bytes_be()); let mut static_attributes: HashMap = HashMap::new(); static_attributes.insert("fee".into(), Bytes::from(encoded_pool_fee.to_vec())); let usv3_pool = ProtocolComponent { id: String::from("0x88e6A0c2dDD26FEEb64F039a2c41296FcB3f5640"), static_attributes, ..Default::default() }; let token_in = Bytes::from("0xc02aaa39b223fe8d0a0e5c4f27ead9083c756cc2"); let token_out = Bytes::from("0x6b175474e89094c44da98b954eedeac495271d0f"); let swap = Swap { component: usv3_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { receiver: Bytes::from("0x0000000000000000000000000000000000000001"), exact_out: false, router_address: Some(Bytes::zero(20)), group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::Transfer, }; let encoder = UniswapV3SwapEncoder::new( String::from("0x543778987b293C7E8Cf0722BB2e935ba6f4068D4"), TychoCoreChain::Ethereum.into(), None, ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // in token "c02aaa39b223fe8d0a0e5c4f27ead9083c756cc2", // out token "6b175474e89094c44da98b954eedeac495271d0f", // fee "0001f4", // receiver "0000000000000000000000000000000000000001", // pool id "88e6a0c2ddd26feeb64f039a2c41296fcb3f5640", // zero for one "00", // transfer type Transfer "01", )) ); } } mod balancer_v2 { use super::*; #[test] fn test_encode_balancer_v2() { let balancer_pool = ProtocolComponent { id: String::from( "0x5c6ee304399dbdb9c8ef030ab642b10820db8f56000200000000000000000014", ), protocol_system: String::from("vm:balancer_v2"), ..Default::default() }; let token_in = Bytes::from("0xc02aaa39b223fe8d0a0e5c4f27ead9083c756cc2"); let token_out = Bytes::from("0xba100000625a3754423978a60c9317c58a424e3D"); let swap = Swap { component: balancer_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { // The receiver was generated with `makeAddr("bob") using forge` receiver: Bytes::from("0x1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e"), exact_out: false, router_address: Some(Bytes::zero(20)), group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::None, }; let encoder = BalancerV2SwapEncoder::new( String::from("0x543778987b293C7E8Cf0722BB2e935ba6f4068D4"), TychoCoreChain::Ethereum.into(), Some(HashMap::from([( "vault_address".to_string(), "0xba12222222228d8ba445958a75a0704d566bf2c8".to_string(), )])), ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // token in "c02aaa39b223fe8d0a0e5c4f27ead9083c756cc2", // token out "ba100000625a3754423978a60c9317c58a424e3d", // pool id "5c6ee304399dbdb9c8ef030ab642b10820db8f56000200000000000000000014", // receiver "1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e", // approval needed "01", // transfer type None "02" )) ); write_calldata_to_file("test_encode_balancer_v2", hex_swap.as_str()); } } mod uniswap_v4 { use super::*; use crate::encoding::evm::utils::write_calldata_to_file; #[test] fn test_encode_uniswap_v4_simple_swap() { let fee = BigInt::from(100); let tick_spacing = BigInt::from(1); let token_in = Bytes::from("0x4c9EDD5852cd905f086C759E8383e09bff1E68B3"); // USDE let token_out = Bytes::from("0xdAC17F958D2ee523a2206206994597C13D831ec7"); // USDT let mut static_attributes: HashMap = HashMap::new(); static_attributes.insert("key_lp_fee".into(), Bytes::from(fee.to_signed_bytes_be())); static_attributes .insert("tick_spacing".into(), Bytes::from(tick_spacing.to_signed_bytes_be())); let usv4_pool = ProtocolComponent { // Pool manager id: String::from("0x000000000004444c5dc75cB358380D2e3dE08A90"), static_attributes, ..Default::default() }; let swap = Swap { component: usv4_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { // The receiver is ALICE to match the solidity tests receiver: Bytes::from("0xcd09f75E2BF2A4d11F3AB23f1389FcC1621c0cc2"), exact_out: false, // Same as the executor address router_address: Some(Bytes::from("0x5615deb798bb3e4dfa0139dfa1b3d433cc23b72f")), group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::Transfer, }; let encoder = UniswapV4SwapEncoder::new( String::from("0xF62849F9A0B5Bf2913b396098F7c7019b51A820a"), TychoCoreChain::Ethereum.into(), None, ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // group token in "4c9edd5852cd905f086c759e8383e09bff1e68b3", // group token out "dac17f958d2ee523a2206206994597c13d831ec7", // zero for one "01", // transfer type Transfer "01", // receiver "cd09f75e2bf2a4d11f3ab23f1389fcc1621c0cc2", // pool params: // - intermediary token "dac17f958d2ee523a2206206994597c13d831ec7", // - fee "000064", // - tick spacing "000001" )) ); write_calldata_to_file("test_encode_uniswap_v4_simple_swap", hex_swap.as_str()); } #[test] fn test_encode_uniswap_v4_second_swap() { let fee = BigInt::from(3000); let tick_spacing = BigInt::from(60); let group_token_in = Bytes::from("0x4c9EDD5852cd905f086C759E8383e09bff1E68B3"); // USDE let token_in = Bytes::from("0xdAC17F958D2ee523a2206206994597C13D831ec7"); // USDT let token_out = Bytes::from("0x2260FAC5E5542a773Aa44fBCfeDf7C193bc2C599"); // WBTC let mut static_attributes: HashMap = HashMap::new(); static_attributes.insert("key_lp_fee".into(), Bytes::from(fee.to_signed_bytes_be())); static_attributes .insert("tick_spacing".into(), Bytes::from(tick_spacing.to_signed_bytes_be())); let usv4_pool = ProtocolComponent { id: String::from("0x000000000004444c5dc75cB358380D2e3dE08A90"), static_attributes, ..Default::default() }; let swap = Swap { component: usv4_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { receiver: Bytes::from("0x0000000000000000000000000000000000000001"), exact_out: false, router_address: Some(Bytes::zero(20)), group_token_in: group_token_in.clone(), // Token out is the same as the group token out group_token_out: token_out.clone(), transfer_type: TransferType::Transfer, }; let encoder = UniswapV4SwapEncoder::new( String::from("0x543778987b293C7E8Cf0722BB2e935ba6f4068D4"), TychoCoreChain::Ethereum.into(), None, ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // pool params: // - intermediary token (20 bytes) "2260fac5e5542a773aa44fbcfedf7c193bc2c599", // - fee (3 bytes) "000bb8", // - tick spacing (3 bytes) "00003c" )) ); } #[test] fn test_encode_uniswap_v4_sequential_swap() { let usde_address = Bytes::from("0x4c9EDD5852cd905f086C759E8383e09bff1E68B3"); let usdt_address = Bytes::from("0xdAC17F958D2ee523a2206206994597C13D831ec7"); let wbtc_address = Bytes::from("0x2260FAC5E5542a773Aa44fBCfeDf7C193bc2C599"); let router_address = Bytes::from("0x5615deb798bb3e4dfa0139dfa1b3d433cc23b72f"); // The context is the same for both swaps, since the group token in and out are the same let context = EncodingContext { // The receiver is ALICE to match the solidity tests receiver: Bytes::from("0xcd09f75E2BF2A4d11F3AB23f1389FcC1621c0cc2"), exact_out: false, router_address: Some(router_address.clone()), group_token_in: usde_address.clone(), group_token_out: wbtc_address.clone(), transfer_type: TransferType::Transfer, }; // Setup - First sequence: USDE -> USDT let usde_usdt_fee = BigInt::from(100); let usde_usdt_tick_spacing = BigInt::from(1); let mut usde_usdt_static_attributes: HashMap = HashMap::new(); usde_usdt_static_attributes .insert("key_lp_fee".into(), Bytes::from(usde_usdt_fee.to_signed_bytes_be())); usde_usdt_static_attributes.insert( "tick_spacing".into(), Bytes::from(usde_usdt_tick_spacing.to_signed_bytes_be()), ); let usde_usdt_component = ProtocolComponent { id: String::from("0x000000000004444c5dc75cB358380D2e3dE08A90"), static_attributes: usde_usdt_static_attributes, ..Default::default() }; // Setup - Second sequence: USDT -> WBTC let usdt_wbtc_fee = BigInt::from(3000); let usdt_wbtc_tick_spacing = BigInt::from(60); let mut usdt_wbtc_static_attributes: HashMap = HashMap::new(); usdt_wbtc_static_attributes .insert("key_lp_fee".into(), Bytes::from(usdt_wbtc_fee.to_signed_bytes_be())); usdt_wbtc_static_attributes.insert( "tick_spacing".into(), Bytes::from(usdt_wbtc_tick_spacing.to_signed_bytes_be()), ); let usdt_wbtc_component = ProtocolComponent { id: String::from("0x000000000004444c5dc75cB358380D2e3dE08A90"), static_attributes: usdt_wbtc_static_attributes, ..Default::default() }; let initial_swap = Swap { component: usde_usdt_component, token_in: usde_address.clone(), token_out: usdt_address.clone(), split: 0f64, user_data: None, }; let second_swap = Swap { component: usdt_wbtc_component, token_in: usdt_address, token_out: wbtc_address.clone(), split: 0f64, user_data: None, }; let encoder = UniswapV4SwapEncoder::new( String::from("0xF62849F9A0B5Bf2913b396098F7c7019b51A820a"), TychoCoreChain::Ethereum.into(), None, ) .unwrap(); let initial_encoded_swap = encoder .encode_swap(&initial_swap, &context) .unwrap(); let second_encoded_swap = encoder .encode_swap(&second_swap, &context) .unwrap(); let combined_hex = format!("{}{}", encode(&initial_encoded_swap), encode(&second_encoded_swap)); assert_eq!( combined_hex, String::from(concat!( // group_token in "4c9edd5852cd905f086c759e8383e09bff1e68b3", // group_token out "2260fac5e5542a773aa44fbcfedf7c193bc2c599", // zero for one "01", // transfer type Transfer "01", // receiver "cd09f75e2bf2a4d11f3ab23f1389fcc1621c0cc2", // pool params: // - intermediary token USDT "dac17f958d2ee523a2206206994597c13d831ec7", // - fee "000064", // - tick spacing "000001", // - intermediary token WBTC "2260fac5e5542a773aa44fbcfedf7c193bc2c599", // - fee "000bb8", // - tick spacing "00003c" )) ); write_calldata_to_file("test_encode_uniswap_v4_sequential_swap", combined_hex.as_str()); } } mod ekubo { use super::*; use crate::encoding::evm::utils::write_calldata_to_file; const RECEIVER: &str = "ca4f73fe97d0b987a0d12b39bbd562c779bab6f6"; // Random address #[test] fn test_encode_swap_simple() { let token_in = Bytes::from(Address::ZERO.as_slice()); let token_out = Bytes::from("0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48"); // USDC let static_attributes = HashMap::from([ ("fee".to_string(), Bytes::from(0_u64)), ("tick_spacing".to_string(), Bytes::from(0_u32)), ( "extension".to_string(), Bytes::from("0x51d02a5948496a67827242eabc5725531342527c"), ), // Oracle ]); let component = ProtocolComponent { static_attributes, ..Default::default() }; let swap = Swap { component, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { receiver: RECEIVER.into(), group_token_in: token_in.clone(), group_token_out: token_out.clone(), exact_out: false, router_address: Some(Bytes::default()), transfer_type: TransferType::Transfer, }; let encoder = EkuboSwapEncoder::new(String::default(), TychoCoreChain::Ethereum.into(), None) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, concat!( // transfer type Transfer "01", // receiver "ca4f73fe97d0b987a0d12b39bbd562c779bab6f6", // group token in "0000000000000000000000000000000000000000", // token out 1st swap "a0b86991c6218b36c1d19d4a2e9eb0ce3606eb48", // pool config 1st swap "51d02a5948496a67827242eabc5725531342527c000000000000000000000000", ), ); } #[test] fn test_encode_swap_multi() { let group_token_in = Bytes::from(Address::ZERO.as_slice()); let group_token_out = Bytes::from("0xdAC17F958D2ee523a2206206994597C13D831ec7"); // USDT let intermediary_token = Bytes::from("0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48"); // USDC let encoder = EkuboSwapEncoder::new(String::default(), TychoCoreChain::Ethereum.into(), None) .unwrap(); let encoding_context = EncodingContext { receiver: RECEIVER.into(), group_token_in: group_token_in.clone(), group_token_out: group_token_out.clone(), exact_out: false, router_address: Some(Bytes::default()), transfer_type: TransferType::Transfer, }; let first_swap = Swap { component: ProtocolComponent { static_attributes: HashMap::from([ ("fee".to_string(), Bytes::from(0_u64)), ("tick_spacing".to_string(), Bytes::from(0_u32)), ( "extension".to_string(), Bytes::from("0x51d02a5948496a67827242eabc5725531342527c"), ), // Oracle ]), ..Default::default() }, token_in: group_token_in.clone(), token_out: intermediary_token.clone(), split: 0f64, user_data: None, }; let second_swap = Swap { component: ProtocolComponent { // 0.0025% fee & 0.005% base pool static_attributes: HashMap::from([ ("fee".to_string(), Bytes::from(461168601842738_u64)), ("tick_spacing".to_string(), Bytes::from(50_u32)), ("extension".to_string(), Bytes::zero(20)), ]), ..Default::default() }, token_in: intermediary_token.clone(), token_out: group_token_out.clone(), split: 0f64, user_data: None, }; let first_encoded_swap = encoder .encode_swap(&first_swap, &encoding_context) .unwrap(); let second_encoded_swap = encoder .encode_swap(&second_swap, &encoding_context) .unwrap(); let combined_hex = format!("{}{}", encode(first_encoded_swap), encode(second_encoded_swap)); assert_eq!( combined_hex, // transfer type concat!( // transfer type Transfer "01", // receiver "ca4f73fe97d0b987a0d12b39bbd562c779bab6f6", // group token in "0000000000000000000000000000000000000000", // token out 1st swap "a0b86991c6218b36c1d19d4a2e9eb0ce3606eb48", // pool config 1st swap "51d02a5948496a67827242eabc5725531342527c000000000000000000000000", // token out 2nd swap "dac17f958d2ee523a2206206994597c13d831ec7", // pool config 2nd swap "00000000000000000000000000000000000000000001a36e2eb1c43200000032", ), ); write_calldata_to_file("test_ekubo_encode_swap_multi", combined_hex.as_str()); } } mod curve { use rstest::rstest; use super::*; fn curve_config() -> Option> { Some(HashMap::from([ ( "native_token_address".to_string(), "0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE".to_string(), ), ( "meta_registry_address".to_string(), "0xF98B45FA17DE75FB1aD0e7aFD971b0ca00e379fC".to_string(), ), ])) } #[rstest] #[case( "0x5b22307838363533373733363730353435313665313730313463636465643165376438313465646339636534222c22307861353538386637636466353630383131373130613264383264336339633939373639646231646362225d", "0x865377367054516e17014CcdED1e7d814EDC9ce4", "0xA5588F7cdf560811710A2D82D3C9c99769DB1Dcb", 0, 1 )] #[case( "0x5b22307836623137353437346538393039346334346461393862393534656564656163343935323731643066222c22307861306238363939316336323138623336633164313964346132653965623063653336303665623438222c22307864616331376639353864326565353233613232303632303639393435393763313364383331656337222c22307835376162316563323864313239373037303532646634646634313864353861326434366435663531225d", "0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48", "0x57Ab1ec28D129707052df4dF418D58a2D46d5f51", 1, 3 )] #[case( "0x5b22307864616331376639353864326565353233613232303632303639393435393763313364383331656337222c22307832323630666163356535353432613737336161343466626366656466376331393362633263353939222c22307863303261616133396232323366653864306130653563346632376561643930383363373536636332225d", "0xC02aaA39b223FE8D0A0e5C4F27eAD9083C756Cc2", "0x2260FAC5E5542a773Aa44fBCfeDf7C193bc2C599", 2, 1 )] #[case( "0x5b22307861306238363939316336323138623336633164313964346132653965623063653336303665623438222c22307832323630666163356535353432613737336161343466626366656466376331393362633263353939222c22307865656565656565656565656565656565656565656565656565656565656565656565656565656565225d", "0xeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeee", "0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48", 2, 0 )] // Pool that holds ETH but coin is WETH #[case( "0x5b22307861306238363939316336323138623336633164313964346132653965623063653336303665623438222c22307832323630666163356535353432613737336161343466626366656466376331393362633263353939222c22307865656565656565656565656565656565656565656565656565656565656565656565656565656565225d", "0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE", "0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48", 2, 0 )] // Pool that holds ETH but coin is WETH #[case( "0x5b22307861306238363939316336323138623336633164313964346132653965623063653336303665623438222c22307832323630666163356535353432613737336161343466626366656466376331393362633263353939222c22307865656565656565656565656565656565656565656565656565656565656565656565656565656565225d", "0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48", "0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE", 0, 2 )] fn test_curve_get_coin_indexes( #[case] coins: &str, #[case] token_in: &str, #[case] token_out: &str, #[case] expected_i: u64, #[case] expected_j: u64, ) { let mut static_attributes: HashMap = HashMap::new(); static_attributes.insert("coins".into(), Bytes::from_str(coins).unwrap()); let swap = Swap { component: ProtocolComponent { id: "pool-id".into(), protocol_system: String::from("vm:curve"), static_attributes, ..Default::default() }, token_in: Bytes::from(token_in), token_out: Bytes::from(token_out), split: 0f64, user_data: None, }; let encoder = CurveSwapEncoder::new( String::default(), TychoCoreChain::Ethereum.into(), curve_config(), ) .unwrap(); let (i, j) = encoder .get_coin_indexes( &swap, Address::from_str(token_in).unwrap(), Address::from_str(token_out).unwrap(), ) .unwrap(); assert_eq!(i, U8::from(expected_i)); assert_eq!(j, U8::from(expected_j)); } #[test] fn test_curve_encode_tripool() { let mut static_attributes: HashMap = HashMap::new(); static_attributes.insert( "factory".into(), Bytes::from( "0x0000000000000000000000000000000000000000" .as_bytes() .to_vec(), ), ); static_attributes.insert("coins".into(), Bytes::from_str("0x5b22307836623137353437346538393039346334346461393862393534656564656163343935323731643066222c22307861306238363939316336323138623336633164313964346132653965623063653336303665623438222c22307864616331376639353864326565353233613232303632303639393435393763313364383331656337225d").unwrap()); let curve_tri_pool = ProtocolComponent { id: String::from("0xbEbc44782C7dB0a1A60Cb6fe97d0b483032FF1C7"), protocol_system: String::from("vm:curve"), static_attributes, ..Default::default() }; let token_in = Bytes::from("0x6B175474E89094C44Da98b954EedeAC495271d0F"); let token_out = Bytes::from("0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48"); let swap = Swap { component: curve_tri_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { // The receiver was generated with `makeAddr("bob") using forge` receiver: Bytes::from("0x1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e"), exact_out: false, router_address: None, group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::None, }; let encoder = CurveSwapEncoder::new( String::from("0x5615dEB798BB3E4dFa0139dFa1b3D433Cc23b72f"), TychoCoreChain::Ethereum.into(), curve_config(), ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // token in "6b175474e89094c44da98b954eedeac495271d0f", // token out "a0b86991c6218b36c1d19d4a2e9eb0ce3606eb48", // pool address "bebc44782c7db0a1a60cb6fe97d0b483032ff1c7", // pool type 1 "01", // i index "00", // j index "01", // approval needed "01", // transfer type None "02", // receiver, "1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e", )) ); } #[test] fn test_curve_encode_factory() { let mut static_attributes: HashMap = HashMap::new(); static_attributes.insert( "factory".into(), Bytes::from( "0x6A8cbed756804B16E05E741eDaBd5cB544AE21bf" .as_bytes() .to_vec(), ), ); static_attributes.insert("coins".into(), Bytes::from_str("0x5b22307834633965646435383532636439303566303836633735396538333833653039626666316536386233222c22307861306238363939316336323138623336633164313964346132653965623063653336303665623438225d").unwrap()); let curve_pool = ProtocolComponent { id: String::from("0x02950460E2b9529D0E00284A5fA2d7bDF3fA4d72"), protocol_system: String::from("vm:curve"), static_attributes, ..Default::default() }; let token_in = Bytes::from("0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48"); let token_out = Bytes::from("0x4c9EDD5852cd905f086C759E8383e09bff1E68B3"); let swap = Swap { component: curve_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { // The receiver was generated with `makeAddr("bob") using forge` receiver: Bytes::from("0x1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e"), exact_out: false, router_address: None, group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::None, }; let encoder = CurveSwapEncoder::new( String::from("0x5615dEB798BB3E4dFa0139dFa1b3D433Cc23b72f"), TychoCoreChain::Ethereum.into(), curve_config(), ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // token in "a0b86991c6218b36c1d19d4a2e9eb0ce3606eb48", // token out "4c9edd5852cd905f086c759e8383e09bff1e68b3", // pool address "02950460e2b9529d0e00284a5fa2d7bdf3fa4d72", // pool type 1 "01", // i index "01", // j index "00", // approval needed "01", // transfer type None "02", // receiver "1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e", )) ); } #[test] fn test_curve_encode_st_eth() { // This test is for the stETH pool, which is a special case in Curve // where the token in is ETH but not as the zero address. let mut static_attributes: HashMap = HashMap::new(); static_attributes.insert( "factory".into(), Bytes::from( "0x0000000000000000000000000000000000000000" .as_bytes() .to_vec(), ), ); static_attributes.insert("coins".into(), Bytes::from_str("0x5b22307865656565656565656565656565656565656565656565656565656565656565656565656565656565222c22307861653761623936353230646533613138653565313131623565616162303935333132643766653834225d").unwrap()); let curve_pool = ProtocolComponent { id: String::from("0xDC24316b9AE028F1497c275EB9192a3Ea0f67022"), protocol_system: String::from("vm:curve"), static_attributes, ..Default::default() }; let token_in = Bytes::from("0x0000000000000000000000000000000000000000"); let token_out = Bytes::from("0xae7ab96520DE3A18E5e111B5EaAb095312D7fE84"); let swap = Swap { component: curve_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { // The receiver was generated with `makeAddr("bob") using forge` receiver: Bytes::from("0x1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e"), exact_out: false, router_address: None, group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::None, }; let encoder = CurveSwapEncoder::new( String::from("0x5615dEB798BB3E4dFa0139dFa1b3D433Cc23b72f"), TychoCoreChain::Ethereum.into(), Some(HashMap::from([ ( "native_token_address".to_string(), "0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE".to_string(), ), ( "meta_registry_address".to_string(), "0xF98B45FA17DE75FB1aD0e7aFD971b0ca00e379fC".to_string(), ), ])), ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // token in "eeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeee", // token out "ae7ab96520de3a18e5e111b5eaab095312d7fe84", // pool address "dc24316b9ae028f1497c275eb9192a3ea0f67022", // pool type 1 "01", // i index "00", // j index "01", // approval needed "01", // transfer type None "02", // receiver "1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e", )) ); } } mod balancer_v3 { use super::*; #[test] fn test_encode_balancer_v3() { let balancer_pool = ProtocolComponent { id: String::from("0x85b2b559bc2d21104c4defdd6efca8a20343361d"), protocol_system: String::from("vm:balancer_v3"), ..Default::default() }; let token_in = Bytes::from("0x7bc3485026ac48b6cf9baf0a377477fff5703af8"); let token_out = Bytes::from("0xc71ea051a5f82c67adcf634c36ffe6334793d24c"); let swap = Swap { component: balancer_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { // The receiver was generated with `makeAddr("bob") using forge` receiver: Bytes::from("0x1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e"), exact_out: false, router_address: Some(Bytes::zero(20)), group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::Transfer, }; let encoder = BalancerV3SwapEncoder::new( String::from("0x543778987b293C7E8Cf0722BB2e935ba6f4068D4"), TychoCoreChain::Ethereum.into(), None, ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // token in "7bc3485026ac48b6cf9baf0a377477fff5703af8", // token out "c71ea051a5f82c67adcf634c36ffe6334793d24c", // pool id "85b2b559bc2d21104c4defdd6efca8a20343361d", // transfer type None "01", // receiver "1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e", )) ); write_calldata_to_file("test_encode_balancer_v3", hex_swap.as_str()); } } mod maverick_v2 { use super::*; #[test] fn test_encode_maverick_v2() { // GHO -> (maverick) -> USDC let maverick_pool = ProtocolComponent { id: String::from("0x14Cf6D2Fe3E1B326114b07d22A6F6bb59e346c67"), protocol_system: String::from("vm:maverick_v2"), ..Default::default() }; let token_in = Bytes::from("0x40D16FC0246aD3160Ccc09B8D0D3A2cD28aE6C2f"); let token_out = Bytes::from("0xA0b86991c6218b36c1d19D4a2e9Eb0cE3606eB48"); let swap = Swap { component: maverick_pool, token_in: token_in.clone(), token_out: token_out.clone(), split: 0f64, user_data: None, }; let encoding_context = EncodingContext { // The receiver was generated with `makeAddr("bob") using forge` receiver: Bytes::from("0x1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e"), exact_out: false, router_address: Some(Bytes::default()), group_token_in: token_in.clone(), group_token_out: token_out.clone(), transfer_type: TransferType::Transfer, }; let encoder = MaverickV2SwapEncoder::new( String::from("0x543778987b293C7E8Cf0722BB2e935ba6f4068D4"), TychoCoreChain::Ethereum.into(), None, ) .unwrap(); let encoded_swap = encoder .encode_swap(&swap, &encoding_context) .unwrap(); let hex_swap = encode(&encoded_swap); assert_eq!( hex_swap, String::from(concat!( // token in "40D16FC0246aD3160Ccc09B8D0D3A2cD28aE6C2f", // pool "14Cf6D2Fe3E1B326114b07d22A6F6bb59e346c67", // receiver "1d96f2f6bef1202e4ce1ff6dad0c2cb002861d3e", // transfer true "01", )) .to_lowercase() ); write_calldata_to_file("test_encode_maverick_v2", hex_swap.as_str()); } } }