use nssa_core::{ account::{Account, AccountId, AccountWithMetadata, Data}, program::{ProgramId, ProgramInput, ChainedCall, read_nssa_inputs, write_nssa_outputs_with_chained_call}, }; //TODO update comments // The AMM program has five functions (four directly accessible via instructions): // 1. New AMM definition. // Arguments to this function are: // * Seven **default** accounts: [amm_pool, vault_holding_a, vault_holding_b, pool_lp, user_holding_a, user_holding_b, user_holding_lp]. // amm_pool is a default account that will initiate the amm definition account values // vault_holding_a is a token holding account for token a // vault_holding_b is a token holding account for token b // pool_lp is a token holding account for the pool's lp token // user_holding_a is a token holding account for token a // user_holding_b is a token holding account for token b // user_holding_lp is a token holding account for lp token // TODO: ideally, vault_holding_a, vault_holding_b, pool_lp and user_holding_lp are uninitated. // * An instruction data of 65-bytes, indicating the initial amm reserves' balances and token_program_id with // the following layout: // [0x00 || array of balances (little-endian 16 bytes) || TOKEN_PROGRAM_ID)] // 2. Swap assets // Arguments to this function are: // * Two accounts: [amm_pool, vault_holding_1, vault_holding_2, user_holding_a, user_holding_b]. // * An instruction data byte string of length 49, indicating which token type to swap and maximum amount with the following layout // [0x01 || amount (little-endian 16 bytes) || TOKEN_DEFINITION_ID]. // 3. Add liquidity // Arguments to this function are: // * Two accounts: [amm_pool, vault_holding_a, vault_holding_b, pool_lp, user_holding_a, user_holding_b, user_holding_lp]. // * An instruction data byte string of length 65, amounts to add // [0x02 || array of max amounts (little-endian 16 bytes) || TOKEN_DEFINITION_ID (for primary)]. // 4. Remove liquidity // * Input instruction set [0x03]. // - Swap logic // Arguments of this function are: // * Four accounts: [user_deposit_tx, vault_deposit_tx, vault_withdraw_tx, user_withdraw_tx]. // user_deposit_tx and vault_deposit_tx define deposit transaction. // vault_withdraw_tx and user_withdraw_tx define withdraw transaction. // * deposit_amount is the amount for user_deposit_tx -> vault_deposit_tx transfer. // * reserve_amounts is the pool's reserves; used to compute the withdraw amount. // * Outputs the token transfers as a Vec and the withdraw amount. const POOL_DEFINITION_DATA_SIZE: usize = 225; const MAX_NUMBER_POOLS: usize = 31; const AMM_DEFINITION_DATA_SIZE: usize = 1024; struct AMMDefinition { name: [u8;32], pool_ids: Vec, } impl AMMDefinition { fn new(name: &[u8;32]) -> Vec { let mut bytes = [0; AMM_DEFINITION_DATA_SIZE]; bytes[0..32].copy_from_slice(name); bytes.into() } fn into_data(self) -> Vec { let size_of_pool: usize = self.pool_ids.len(); let mut bytes = [0; AMM_DEFINITION_DATA_SIZE]; for i in 0..size_of_pool-1 { bytes[32*i..32*(i+1)].copy_from_slice(&self.pool_ids[i].to_bytes()) } for i in size_of_pool..MAX_NUMBER_POOLS { bytes[32*i..32*(i+1)].copy_from_slice(&AccountId::default().to_bytes()) } bytes.into() } fn parse(data: &[u8]) -> Option { if data.len() % 32 != 0 { panic!("AMM data should be divisible by 32 (number of bytes per of AccountId"); } let size_of_pool = data.len()/32; let mut name: [u8;32] = [0;32]; name.copy_from_slice(&data[0..32]); let mut pool_ids = Vec::::new(); for i in 1..size_of_pool+1 { pool_ids.push( AccountId::new(data[i*32..(i+1)*32].try_into().expect("Parse data: The AMM program must be provided a valid AccountIds")) ); } for _ in size_of_pool..MAX_NUMBER_POOLS { pool_ids.push( AccountId::default() ); } Some( Self{ name, pool_ids }) } } struct PoolDefinition{ definition_token_a_id: AccountId, definition_token_b_id: AccountId, vault_a_addr: AccountId, vault_b_addr: AccountId, liquidity_pool_id: AccountId, liquidity_pool_supply: u128, reserve_a: u128, reserve_b: u128, fees: u128, active: bool } impl PoolDefinition { fn into_data(self) -> Vec { let mut bytes = [0; POOL_DEFINITION_DATA_SIZE]; bytes[0..32].copy_from_slice(&self.definition_token_a_id.to_bytes()); bytes[32..64].copy_from_slice(&self.definition_token_b_id.to_bytes()); bytes[64..96].copy_from_slice(&self.vault_a_addr.to_bytes()); bytes[96..128].copy_from_slice(&self.vault_b_addr.to_bytes()); bytes[128..160].copy_from_slice(&self.liquidity_pool_id.to_bytes()); bytes[160..176].copy_from_slice(&self.liquidity_pool_supply.to_le_bytes()); bytes[176..192].copy_from_slice(&self.reserve_a.to_le_bytes()); bytes[192..208].copy_from_slice(&self.reserve_b.to_le_bytes()); bytes[208..224].copy_from_slice(&self.fees.to_le_bytes()); bytes[224] = self.active as u8; bytes.into() } fn parse(data: &[u8]) -> Option { if data.len() != POOL_DEFINITION_DATA_SIZE { None } else { let definition_token_a_id = AccountId::new(data[0..32].try_into().expect("Parse data: The AMM program must be provided a valid AccountId for Token A definition")); let definition_token_b_id = AccountId::new(data[32..64].try_into().expect("Parse data: The AMM program must be provided a valid AccountId for Vault B definition")); let vault_a_addr = AccountId::new(data[64..96].try_into().expect("Parse data: The AMM program must be provided a valid AccountId for Vault A")); let vault_b_addr = AccountId::new(data[96..128].try_into().expect("Parse data: The AMM program must be provided a valid AccountId for Vault B")); let liquidity_pool_id = AccountId::new(data[128..160].try_into().expect("Parse data: The AMM program must be provided a valid AccountId for Token liquidity pool definition")); let liquidity_pool_supply = u128::from_le_bytes(data[160..176].try_into().expect("Parse data: The AMM program must be provided a valid u128 for liquidity cap")); let reserve_a = u128::from_le_bytes(data[176..192].try_into().expect("Parse data: The AMM program must be provided a valid u128 for reserve A balance")); let reserve_b = u128::from_le_bytes(data[192..208].try_into().expect("Parse data: The AMM program must be provided a valid u128 for reserve B balance")); let fees = u128::from_le_bytes(data[208..224].try_into().expect("Parse data: The AMM program must be provided a valid u128 for fees")); let active = match data[224] { 0 => false, 1 => true, _ => panic!("Parse data: The AMM program must be provided a valid bool for active"), }; Some(Self { definition_token_a_id, definition_token_b_id, vault_a_addr, vault_b_addr, liquidity_pool_id, liquidity_pool_supply, reserve_a, reserve_b, fees, active, }) } } } //TODO: remove repeated code for Token_Definition and TokenHoldling const TOKEN_DEFINITION_TYPE: u8 = 0; const TOKEN_DEFINITION_DATA_SIZE: usize = 23; const TOKEN_HOLDING_TYPE: u8 = 1; const TOKEN_HOLDING_DATA_SIZE: usize = 49; struct TokenDefinition { account_type: u8, name: [u8; 6], total_supply: u128, } struct TokenHolding { account_type: u8, definition_id: AccountId, balance: u128, } impl TokenDefinition { fn into_data(self) -> Vec { let mut bytes = [0; TOKEN_DEFINITION_DATA_SIZE]; bytes[0] = self.account_type; bytes[1..7].copy_from_slice(&self.name); bytes[7..].copy_from_slice(&self.total_supply.to_le_bytes()); bytes.into() } fn parse(data: &[u8]) -> Option { if data.len() != TOKEN_DEFINITION_DATA_SIZE || data[0] != TOKEN_DEFINITION_TYPE { None } else { let account_type = data[0]; let name = data[1..7].try_into().unwrap(); let total_supply = u128::from_le_bytes( data[7..] .try_into() .expect("Total supply must be 16 bytes little-endian"), ); Some(Self { account_type, name, total_supply, }) } } } impl TokenHolding { fn new(definition_id: &AccountId) -> Self { Self { account_type: TOKEN_HOLDING_TYPE, definition_id: definition_id.clone(), balance: 0, } } fn parse(data: &[u8]) -> Option { if data.len() != TOKEN_HOLDING_DATA_SIZE || data[0] != TOKEN_HOLDING_TYPE { None } else { let account_type = data[0]; let definition_id = AccountId::new( data[1..33] .try_into() .expect("Defintion ID must be 32 bytes long"), ); let balance = u128::from_le_bytes( data[33..] .try_into() .expect("balance must be 16 bytes little-endian"), ); Some(Self { definition_id, balance, account_type, }) } } fn into_data(self) -> Data { let mut bytes = [0; TOKEN_HOLDING_DATA_SIZE]; bytes[0] = self.account_type; bytes[1..33].copy_from_slice(&self.definition_id.to_bytes()); bytes[33..].copy_from_slice(&self.balance.to_le_bytes()); bytes.into() } } type Instruction = Vec; fn main() { let ProgramInput { pre_states, instruction, } = read_nssa_inputs::(); match instruction[0] { 0 => { let balance_a: u128 = u128::from_le_bytes(instruction[1..17].try_into().expect("New definition: AMM Program expects u128 for balance a")); let balance_b: u128 = u128::from_le_bytes(instruction[17..33].try_into().expect("New definition: AMM Program expects u128 for balance b")); // Convert Vec to ProgramId ([u32;8]) let mut token_program_id: [u32;8] = [0;8]; token_program_id[0] = u32::from_le_bytes(instruction[33..37].try_into().expect("New definition: AMM Program expects valid u32")); token_program_id[1] = u32::from_le_bytes(instruction[37..41].try_into().expect("New definition: AMM Program expects valid u32")); token_program_id[2] = u32::from_le_bytes(instruction[41..45].try_into().expect("New definition: AMM Program expects valid u32")); token_program_id[3] = u32::from_le_bytes(instruction[45..49].try_into().expect("New definition: AMM Program expects valid u32")); token_program_id[4] = u32::from_le_bytes(instruction[49..53].try_into().expect("New definition: AMM Program expects valid u32")); token_program_id[5] = u32::from_le_bytes(instruction[53..57].try_into().expect("New definition: AMM Program expects valid u32")); token_program_id[6] = u32::from_le_bytes(instruction[57..61].try_into().expect("New definition: AMM Program expects valid u32")); token_program_id[7] = u32::from_le_bytes(instruction[61..65].try_into().expect("New definition: AMM Program expects valid u32")); let (post_states, chained_call) = new_pool(&pre_states, &[balance_a, balance_b], token_program_id ); write_nssa_outputs_with_chained_call(pre_states, post_states, chained_call); } 1 => { let mut token_addr: [u8;32] = [0;32]; token_addr[0..].copy_from_slice(&instruction[33..65]); let token_addr = AccountId::new(token_addr); let amount_in = u128::from_le_bytes(instruction[1..17].try_into().expect("Swap: AMM Program expects valid u128 for balance to move")); let min_amount_out = u128::from_le_bytes(instruction[17..33].try_into().expect("Swap: AMM Program expects valid u128 for balance to move")); let (post_states, chained_call) = swap(&pre_states, &[amount_in, min_amount_out], token_addr); write_nssa_outputs_with_chained_call(pre_states, post_states, chained_call); } 2 => { let min_amount_lp = u128::from_le_bytes(instruction[1..17].try_into().expect("Add liquidity: AMM Program expects valid u128 for min amount lp")); let max_amount_a = u128::from_le_bytes(instruction[17..33].try_into().expect("Add liquidity: AMM Program expects valid u128 for max amount a")); let max_amount_b = u128::from_le_bytes(instruction[33..49].try_into().expect("Add liquidity: AMM Program expects valid u128 for max amount b")); let (post_states, chained_call) = add_liquidity(&pre_states, &[min_amount_lp, max_amount_a, max_amount_b]); write_nssa_outputs_with_chained_call(pre_states, post_states, chained_call); } 3 => { let balance_lp = u128::from_le_bytes(instruction[1..17].try_into().expect("Remove liquidity: AMM Program expects valid u128 for balance liquidity")); let balance_a = u128::from_le_bytes(instruction[17..33].try_into().expect("Remove liquidity: AMM Program expects valid u128 for balance a")); let balance_b = u128::from_le_bytes(instruction[33..49].try_into().expect("Remove liquidity: AMM Program expects valid u128 for balance b")); let (post_states, chained_call) = remove_liquidity(&pre_states, &[balance_lp, balance_a, balance_b]); write_nssa_outputs_with_chained_call(pre_states, post_states, chained_call); } _ => panic!("Invalid instruction"), }; } //TODO: test //add access to fn new_definition ( pre_states: &[AccountWithMetadata], name: &[u8;32], ) -> Vec { if pre_states.len() != 1 { panic!("Invalid number of input accounts"); } let mut new_amm_post = pre_states[0].account.clone(); new_amm_post.data = AMMDefinition::new(name); vec![new_amm_post] } //TODO: fix this fn new_pool ( pre_states: &[AccountWithMetadata], balance_in: &[u128], token_program: ProgramId, ) -> (Vec, Vec) { //Pool accounts: pool itself, and its 2 vaults and LP token //2 accounts for funding tokens //initial funder's LP account //TODO: update this test if pre_states.len() != 8 { panic!("Invalid number of input accounts") } if balance_in.len() != 2 { panic!("Invalid number of balance") } let amm = &pre_states[0]; let pool = &pre_states[1]; let vault_a = &pre_states[2]; let vault_b = &pre_states[3]; let pool_lp = &pre_states[4]; let user_holding_a = &pre_states[5]; let user_holding_b = &pre_states[6]; let user_holding_lp = &pre_states[7]; if amm.account == Account::default() { panic!("AMM is not initialized"); } //TODO: ignore inactive for now. if !pool.is_authorized { panic!("Pool account is not authorized"); } // TODO: temporary band-aid to prevent vault's from being // owned by the amm program. if vault_a.account == Account::default() || vault_b.account == Account::default() { panic!("Vault accounts uninitialized") } let amount_a = balance_in[0]; let amount_b = balance_in[1]; // Prevents pool constant coefficient (k) from being 0. if amount_a == 0 || amount_b == 0 { panic!("Balances must be nonzero") } // Verify token_a and token_b are different let definition_token_a_id = TokenHolding::parse(&user_holding_a.account.data).expect("New definition: AMM Program expects valid Token Holding account for Token A").definition_id; let definition_token_b_id = TokenHolding::parse(&user_holding_b.account.data).expect("New definition: AMM Program expects valid Token Holding account for Token B").definition_id; if definition_token_a_id == definition_token_b_id { panic!("Cannot set up a swap for a token with itself.") } let amm_data = AMMDefinition::parse(&amm.account.data).expect("AMM program expects a valid AMM account definition"); /* for i in 0..MAX_NUMBER_POOLS { if( amm_d ) } */ //pool data // 5. Update pool account let mut pool_post = Account::default(); let pool_post_definition = PoolDefinition { definition_token_a_id, definition_token_b_id, vault_a_addr: vault_a.account_id.clone(), vault_b_addr: vault_b.account_id.clone(), liquidity_pool_id: TokenHolding::parse(&pool_lp.account.data).expect("New definition: AMM Program expects valid Token Holding account for liquidity pool").definition_id, liquidity_pool_supply: amount_a, reserve_a: amount_a, reserve_b: amount_b, fees: 0u128, //TODO: we assume all fees are 0 for now. active: true, }; pool_post.data = pool_post_definition.into_data(); let mut chained_call = Vec::new(); //Chain call for Token A (user_holding_a -> Vault_A) let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice(&amount_a.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("New definition: AMM Program expects valid instruction_data"); let call_token_a = ChainedCall{ program_id: token_program, instruction_data: instruction_data, pre_states: vec![user_holding_a.clone(), vault_a.clone()] }; //Chain call for Token B (user_holding_b -> Vault_B) instruction[1..17].copy_from_slice(&amount_b.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("New definition: AMM Program expects valid instruction_data"); let call_token_b = ChainedCall{ program_id: token_program, instruction_data: instruction_data, pre_states: vec![user_holding_b.clone(), vault_b.clone()] }; //Chain call for LP (Pool_LP -> user_holding_lp) instruction[1..17].copy_from_slice(&amount_a.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("New definition: AMM Program expects valid instruction_data"); let call_token_lp = ChainedCall{ program_id: token_program, instruction_data: instruction_data, pre_states: vec![pool_lp.clone(), user_holding_lp.clone()] }; chained_call.push(call_token_lp); chained_call.push(call_token_b); chained_call.push(call_token_a); let post_states = vec![ pool_post.clone(), pre_states[1].account.clone(), pre_states[2].account.clone(), pre_states[3].account.clone(), pre_states[4].account.clone(), pre_states[5].account.clone(), pre_states[6].account.clone()]; (post_states.clone(), chained_call) } fn swap( pre_states: &[AccountWithMetadata], amounts: &[u128], token_id: AccountId, ) -> (Vec, Vec) { if pre_states.len() != 5 { panic!("Invalid number of input accounts"); } if amounts.len() != 2 { panic!("Invalid number of amounts provided"); } let amount_in = amounts[0]; let min_amount_out = amounts[1]; let pool = &pre_states[0]; let vault_a = &pre_states[1]; let vault_b = &pre_states[2]; let user_holding_a = &pre_states[3]; let user_holding_b = &pre_states[4]; // Verify vaults are in fact vaults let pool_def_data = PoolDefinition::parse(&pool.account.data).expect("Swap: AMM Program expects a valid Pool Definition Account"); if !pool_def_data.active { panic!("Pool is inactive"); } if vault_a.account_id != pool_def_data.vault_a_addr { panic!("Vault A was not provided"); } if vault_b.account_id != pool_def_data.vault_b_addr { panic!("Vault B was not provided"); } // fetch pool reserves // validates reserves is at least the vaults' balances if TokenHolding::parse(&vault_a.account.data).expect("Swap: AMM Program expects a valid Token Holding Account for Vault A").balance < pool_def_data.reserve_a { panic!("Reserve for Token A exceeds vault balance"); } if TokenHolding::parse(&vault_b.account.data).expect("Swap: AMM Program expects a valid Token Holding Account for Vault B").balance < pool_def_data.reserve_b { panic!("Reserve for Token B exceeds vault balance"); } let (chained_call, [deposit_a, withdraw_a], [deposit_b, withdraw_b]) = if token_id == pool_def_data.definition_token_a_id { let (chained_call, withdraw_b) = swap_logic(&[user_holding_a.clone(), vault_a.clone(), vault_b.clone(), user_holding_b.clone()], amount_in, &[pool_def_data.reserve_a, pool_def_data.reserve_b], min_amount_out); (chained_call, [amount_in, 0], [0, withdraw_b]) } else if token_id == pool_def_data.definition_token_b_id { let (chained_call, withdraw_a) = swap_logic(&[user_holding_b.clone(), vault_b.clone(), vault_a.clone(), user_holding_a.clone()], amount_in, &[pool_def_data.reserve_b, pool_def_data.reserve_a], min_amount_out); (chained_call, [0, withdraw_a], [amount_in, 0]) } else { panic!("AccountId is not a token type for the pool"); }; // Update pool account let mut pool_post = pool.account.clone(); let pool_post_definition = PoolDefinition { definition_token_a_id: pool_def_data.definition_token_a_id.clone(), definition_token_b_id: pool_def_data.definition_token_b_id.clone(), vault_a_addr: pool_def_data.vault_a_addr.clone(), vault_b_addr: pool_def_data.vault_b_addr.clone(), liquidity_pool_id: pool_def_data.liquidity_pool_id.clone(), liquidity_pool_supply: pool_def_data.liquidity_pool_supply.clone(), reserve_a: pool_def_data.reserve_a + deposit_a - withdraw_a, reserve_b: pool_def_data.reserve_b + deposit_b - withdraw_b, fees: 0u128, active: true, }; pool_post.data = pool_post_definition.into_data(); let post_states = vec![ pool_post.clone(), pre_states[1].account.clone(), pre_states[2].account.clone(), pre_states[3].account.clone(), pre_states[4].account.clone()]; (post_states.clone(), chained_call) } fn swap_logic( pre_states: &[AccountWithMetadata], deposit_amount: u128, reserve_amounts: &[u128], min_amount_out: u128, ) -> (Vec, u128) { let user_deposit_tx = pre_states[0].clone(); let vault_deposit_tx = pre_states[1].clone(); let vault_withdraw_tx = pre_states[2].clone(); let user_withdraw_tx = pre_states[3].clone(); let reserve_deposit_vault_amount = reserve_amounts[0]; let reserve_withdraw_vault_amount = reserve_amounts[1]; // Compute withdraw amount // Compute pool's exchange constant // let k = pool_def_data.reserve_a * pool_def_data.reserve_b; let withdraw_amount = (reserve_withdraw_vault_amount * deposit_amount)/(reserve_deposit_vault_amount + deposit_amount); //Slippage check if min_amount_out > withdraw_amount { panic!("Withdraw amount is less than minimal amount out"); } if withdraw_amount == 0 { panic!("Withdraw amount should be nonzero"); } let mut chained_call = Vec::new(); let mut instruction_data = [0;23]; instruction_data[0] = 1; instruction_data[1..17].copy_from_slice(&deposit_amount.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction_data).expect("Swap Logic: AMM Program expects valid transaction instruction data"); chained_call.push( ChainedCall{ program_id: vault_deposit_tx.account.program_owner, instruction_data: instruction_data, pre_states: vec![user_deposit_tx.clone(), vault_deposit_tx.clone()] } ); let mut instruction_data = [0;23]; instruction_data[0] = 1; instruction_data[1..17].copy_from_slice(&withdraw_amount.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction_data).expect("Swap Logic: AMM Program expects valid transaction instruction data"); chained_call.push( ChainedCall{ program_id: vault_deposit_tx.account.program_owner, instruction_data: instruction_data, pre_states: vec![vault_withdraw_tx.clone(), user_withdraw_tx.clone()] } ); (chained_call, withdraw_amount) } fn add_liquidity(pre_states: &[AccountWithMetadata], balances: &[u128]) -> (Vec, Vec) { if pre_states.len() != 7 { panic!("Invalid number of input accounts"); } let pool = &pre_states[0]; let vault_a = &pre_states[1]; let vault_b = &pre_states[2]; let pool_definition_lp = &pre_states[3]; let user_holding_a = &pre_states[4]; let user_holding_b = &pre_states[5]; let user_holding_lp = &pre_states[6]; // Verify vaults are in fact vaults let pool_def_data = PoolDefinition::parse(&pool.account.data).expect("Add liquidity: AMM Program expects valid Pool Definition Account"); if vault_a.account_id != pool_def_data.vault_a_addr { panic!("Vault A was not provided"); } if pool_def_data.liquidity_pool_id != pool_definition_lp.account_id { panic!("LP definition mismatch"); } if vault_b.account_id != pool_def_data.vault_b_addr { panic!("Vault B was not provided"); } if balances.len() != 3 { panic!("Invalid number of input balances"); } let min_amount_lp = balances[0]; let max_amount_a = balances[1]; let max_amount_b = balances[2]; if max_amount_a == 0 || max_amount_b == 0 { panic!("Both max-balances must be nonzero"); } if min_amount_lp == 0 { panic!("Min-lp must be nonzero"); } // 2. Determine deposit amount let vault_b_balance = TokenHolding::parse(&vault_b.account.data).expect("Add liquidity: AMM Program expects valid Token Holding Account for Vault B").balance; let vault_a_balance = TokenHolding::parse(&vault_a.account.data).expect("Add liquidity: AMM Program expects valid Token Holding Account for Vault A").balance; if pool_def_data.reserve_a == 0 || pool_def_data.reserve_b == 0 { panic!("Reserves must be nonzero"); } if vault_a_balance < pool_def_data.reserve_a || vault_b_balance < pool_def_data.reserve_b { panic!("Vaults' balances must be at least the reserve amounts"); } // Calculate actual_amounts let ideal_a: u128 = (pool_def_data.reserve_a*max_amount_b)/pool_def_data.reserve_b; let ideal_b: u128 = (pool_def_data.reserve_b*max_amount_a)/pool_def_data.reserve_a; let actual_amount_a = if ideal_a > max_amount_a { max_amount_a } else { ideal_a }; let actual_amount_b = if ideal_b > max_amount_b { max_amount_b } else { ideal_b }; // 3. Validate amounts if max_amount_a < actual_amount_a || max_amount_b < actual_amount_b { panic!("Actual trade amounts cannot exceed max_amounts"); } if actual_amount_a == 0 || actual_amount_b == 0 { panic!("A trade amount is 0"); } // 4. Calculate LP to mint let delta_lp = std::cmp::min(pool_def_data.liquidity_pool_supply * actual_amount_a/pool_def_data.reserve_a, pool_def_data.liquidity_pool_supply * actual_amount_b/pool_def_data.reserve_b); if delta_lp == 0 { panic!("Payable LP must be nonzero"); } if delta_lp < min_amount_lp { panic!("Payable LP is less than provided minimum LP amount"); } // 5. Update pool account let mut pool_post = pool.account.clone(); let pool_post_definition = PoolDefinition { definition_token_a_id: pool_def_data.definition_token_a_id.clone(), definition_token_b_id: pool_def_data.definition_token_b_id.clone(), vault_a_addr: pool_def_data.vault_a_addr.clone(), vault_b_addr: pool_def_data.vault_b_addr.clone(), liquidity_pool_id: pool_def_data.liquidity_pool_id.clone(), liquidity_pool_supply: pool_def_data.liquidity_pool_supply + delta_lp, reserve_a: pool_def_data.reserve_a + actual_amount_a, reserve_b: pool_def_data.reserve_b + actual_amount_b, fees: 0u128, active: true, }; pool_post.data = pool_post_definition.into_data(); let mut chained_call = Vec::new(); // Chain call for Token A (user_holding_a -> Vault_A) let mut instruction_data = [0; 23]; instruction_data[0] = 1; instruction_data[1..17].copy_from_slice(&actual_amount_a.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction_data).expect("Add liquidity: AMM Program expects valid token transfer instruction data"); let call_token_a = ChainedCall{ program_id: vault_a.account.program_owner, instruction_data: instruction_data, pre_states: vec![user_holding_a.clone(), vault_a.clone()] }; // Chain call for Token B (user_holding_b -> Vault_B) let mut instruction_data = [0; 23]; instruction_data[0] = 1; instruction_data[1..17].copy_from_slice(&actual_amount_b.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction_data).expect("Add liquidity: AMM Program expects valid token transfer instruction data"); let call_token_b = ChainedCall{ program_id: vault_b.account.program_owner, instruction_data: instruction_data, pre_states: vec![user_holding_b.clone(), vault_b.clone()] }; // Chain call for LP (mint new tokens for user_holding_lp) let mut instruction_data = [0; 23]; instruction_data[0] = 4; instruction_data[1..17].copy_from_slice(&delta_lp.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction_data).expect("Add liquidity: AMM Program expects valid token transfer instruction data"); let call_token_lp = ChainedCall{ program_id: pool_definition_lp.account.program_owner, instruction_data: instruction_data, pre_states: vec![pool_definition_lp.clone(), user_holding_lp.clone()] }; chained_call.push(call_token_lp); chained_call.push(call_token_b); chained_call.push(call_token_a); let post_states = vec![ pool_post.clone(), pre_states[1].account.clone(), pre_states[2].account.clone(), pre_states[3].account.clone(), pre_states[4].account.clone(), pre_states[5].account.clone(), pre_states[6].account.clone(),]; (post_states.clone(), chained_call) } fn remove_liquidity(pre_states: &[AccountWithMetadata], amounts: &[u128] ) -> (Vec, Vec) { if pre_states.len() != 7 { panic!("Invalid number of input accounts"); } let pool = &pre_states[0]; let vault_a = &pre_states[1]; let vault_b = &pre_states[2]; let pool_definition_lp = &pre_states[3]; let user_holding_a = &pre_states[4]; let user_holding_b = &pre_states[5]; let user_holding_lp = &pre_states[6]; if amounts.len() != 3 { panic!("Invalid number of balances"); } let amount_lp = amounts[0]; let amount_min_a = amounts[1]; let amount_min_b = amounts[2]; // Verify vaults are in fact vaults let pool_def_data = PoolDefinition::parse(&pool.account.data).expect("Remove liquidity: AMM Program expects a valid Pool Definition Account"); if !pool_def_data.active { panic!("Pool is inactive"); } if pool_def_data.liquidity_pool_id != pool_definition_lp.account_id { panic!("LP definition mismatch"); } if vault_a.account_id != pool_def_data.vault_a_addr { panic!("Vault A was not provided"); } if vault_b.account_id != pool_def_data.vault_b_addr { panic!("Vault B was not provided"); } if amount_min_a == 0 || amount_min_b == 0 { panic!("Minimum withdraw amount must be nonzero"); } if amount_lp == 0 { panic!("Liquidity amount must be nonzero"); } // 2. Compute withdrawal amounts let user_holding_lp_data = TokenHolding::parse(&user_holding_lp.account.data).expect("Remove liquidity: AMM Program expects a valid Token Account for liquidity token"); if user_holding_lp_data.balance > pool_def_data.liquidity_pool_supply || user_holding_lp_data.definition_id != pool_def_data.liquidity_pool_id { panic!("Invalid liquidity account provided"); } let withdraw_amount_a = (pool_def_data.reserve_a * amount_lp)/pool_def_data.liquidity_pool_supply; let withdraw_amount_b = (pool_def_data.reserve_b * amount_lp)/pool_def_data.liquidity_pool_supply; // 3. Validate and slippage check if withdraw_amount_a < amount_min_a { panic!("Insufficient minimal withdraw amount (Token A) provided for liquidity amount"); } if withdraw_amount_b < amount_min_b { panic!("Insufficient minimal withdraw amount (Token B) provided for liquidity amount"); } // 4. Calculate LP to reduce cap by let delta_lp : u128 = (pool_def_data.liquidity_pool_supply*amount_lp)/pool_def_data.liquidity_pool_supply; let active: bool = if pool_def_data.liquidity_pool_supply - delta_lp == 0 { false } else { true }; // 5. Update pool account let mut pool_post = pool.account.clone(); let pool_post_definition = PoolDefinition { definition_token_a_id: pool_def_data.definition_token_a_id.clone(), definition_token_b_id: pool_def_data.definition_token_b_id.clone(), vault_a_addr: pool_def_data.vault_a_addr.clone(), vault_b_addr: pool_def_data.vault_b_addr.clone(), liquidity_pool_id: pool_def_data.liquidity_pool_id.clone(), liquidity_pool_supply: pool_def_data.liquidity_pool_supply - delta_lp, reserve_a: pool_def_data.reserve_a - withdraw_amount_a, reserve_b: pool_def_data.reserve_b - withdraw_amount_b, fees: 0u128, active, }; pool_post.data = pool_post_definition.into_data(); let mut chained_call = Vec::new(); //Chaincall for Token A withdraw let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice(&withdraw_amount_a.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("Remove liquidity: AMM Program expects valid token transfer instruction data"); let call_token_a = ChainedCall{ program_id: vault_a.account.program_owner, instruction_data: instruction_data, pre_states: vec![vault_a.clone(), user_holding_a.clone()] }; //Chaincall for Token B withdraw let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice(&withdraw_amount_b.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("Remove liquidity: AMM Program expects valid token transfer instruction data"); let call_token_b = ChainedCall{ program_id: vault_b.account.program_owner, instruction_data: instruction_data, pre_states: vec![vault_b.clone(), user_holding_b.clone()] }; //Chaincall for LP adjustment let mut instruction: [u8;23] = [0; 23]; instruction[0] = 3; instruction[1..17].copy_from_slice(&delta_lp.to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("Remove liquidity: AMM Program expects valid token transfer instruction data"); let call_token_lp = ChainedCall{ program_id: pool_definition_lp.account.program_owner, instruction_data: instruction_data, pre_states: vec![pool_definition_lp.clone(), user_holding_lp.clone()] }; chained_call.push(call_token_lp); chained_call.push(call_token_b); chained_call.push(call_token_a); let post_states = vec! [ pool_post.clone(), pre_states[1].account.clone(), pre_states[2].account.clone(), pre_states[3].account.clone(), pre_states[4].account.clone(), pre_states[5].account.clone(), pre_states[6].account.clone()]; (post_states, chained_call) } #[cfg(test)] mod tests { use nssa_core::{{account::{Account, AccountId, AccountWithMetadata}, program::ChainedCall}, program::ProgramId}; use crate::{PoolDefinition, TokenDefinition, TokenHolding, add_liquidity, new_pool, remove_liquidity, swap}; const TOKEN_PROGRAM_ID: ProgramId = [15;8]; enum AccountEnum { user_holding_b, user_holding_a, vault_a_uninit, vault_b_uninit, vault_a_init, vault_b_init, vault_a_init_high, vault_b_init_high, vault_a_init_low, vault_b_init_low, vault_a_init_zero, vault_b_init_zero, vault_a_wrong_acc_id, vault_b_wrong_acc_id, pool_lp_uninit, pool_lp_init, pool_lp_wrong_acc_id, user_holding_lp_uninit, user_holding_lp_init, pool_definition_uninit, pool_definition_init, pool_definition_init_reserve_a_zero, pool_definition_init_reserve_b_zero, pool_definition_init_reserve_a_low, pool_definition_init_reserve_b_low, pool_definition_unauth, pool_definition_swap_test_1, pool_definition_swap_test_2, pool_definition_add_zero_lp, pool_definition_add_successful, pool_definition_remove_successful, } enum BalanceEnum { vault_a_reserve_init, vault_b_reserve_init, vault_a_reserve_low, vault_b_reserve_low, vault_a_reserve_high, vault_b_reserve_high, user_token_a_bal, user_token_b_bal, user_token_lp_bal, remove_min_amount_a, remove_min_amount_b, remove_actual_a_successful, remove_min_amount_b_low, remove_min_amount_a_low, remove_amount_lp, remove_amount_lp_1, add_max_amount_a_low, add_max_amount_b_low, add_max_amount_b_high, add_max_amount_a, add_max_amount_b, add_min_amount_lp, vault_a_swap_test_1, vault_a_swap_test_2, vault_b_swap_test_1, vault_b_swap_test_2, min_amount_out, vault_a_add_successful, vault_b_add_successful, add_successful_amount_a_lp, add_successful_amount_b, vault_a_remove_successful, vault_b_remove_successful, } fn helper_balance_constructor(selection: BalanceEnum) -> u128 { match selection { BalanceEnum::vault_a_reserve_init => 1_000, BalanceEnum::vault_b_reserve_init => 500, BalanceEnum::vault_a_reserve_low => 10, BalanceEnum::vault_b_reserve_low => 10, BalanceEnum::vault_a_reserve_high => 500_000, BalanceEnum::vault_b_reserve_high => 500_000, BalanceEnum::user_token_a_bal => 1_000, BalanceEnum::user_token_b_bal => 500, BalanceEnum::user_token_lp_bal => 100, BalanceEnum::remove_min_amount_a => 50, BalanceEnum::remove_min_amount_b => 100, BalanceEnum::remove_actual_a_successful => 100, BalanceEnum::remove_min_amount_b_low => 50, BalanceEnum::remove_min_amount_a_low => 10, BalanceEnum::remove_amount_lp => 100, BalanceEnum::remove_amount_lp_1 => 30, BalanceEnum::add_max_amount_a => 500, BalanceEnum::add_max_amount_b => 200, BalanceEnum::add_max_amount_b_high => 20_000, BalanceEnum::add_max_amount_a_low => 10, BalanceEnum::add_max_amount_b_low => 10, BalanceEnum::add_min_amount_lp => 20, BalanceEnum::vault_a_swap_test_1 => 1_500, BalanceEnum::vault_a_swap_test_2 => 715, BalanceEnum::vault_b_swap_test_1 => 334, BalanceEnum::vault_b_swap_test_2 => 700, BalanceEnum::min_amount_out => 200, BalanceEnum::vault_a_add_successful => 1_400, BalanceEnum::vault_b_add_successful => 700, BalanceEnum::add_successful_amount_a_lp => 400, BalanceEnum::add_successful_amount_b => 200, BalanceEnum::vault_a_remove_successful => 900, BalanceEnum::vault_b_remove_successful => 450, _ => panic!("Invalid selection") } } enum IdEnum { token_a_definition_id, token_b_definition_id, token_lp_definition_id, user_token_a_id, user_token_b_id, user_token_lp_id, pool_definition_id, vault_a_id, vault_b_id, pool_lp_id, } enum ChainedCallsEnum { cc_token_a_initialization, cc_token_b_initialization, cc_pool_lp_initialization, cc_swap_token_a_test_1, cc_swap_token_b_test_1, cc_swap_token_a_test_2, cc_swap_token_b_test_2, cc_add_token_a, cc_add_token_b, cc_add_pool_lp, cc_remove_token_a, cc_remove_token_b, cc_remove_pool_lp, } fn helper_chained_call_constructor(selection: ChainedCallsEnum) -> ChainedCall { match selection { ChainedCallsEnum::cc_token_a_initialization => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::user_token_a_bal) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::vault_a_uninit)], } } ChainedCallsEnum::cc_token_b_initialization => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::user_token_b_bal) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::vault_b_uninit)], } } ChainedCallsEnum::cc_pool_lp_initialization => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::user_token_a_bal) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_lp_uninit)], } } ChainedCallsEnum::cc_swap_token_a_test_1 => { let mut instruction_data: [u8;23] = [0; 23]; instruction_data[0] = 1; instruction_data[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::add_max_amount_a) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction_data).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::vault_a_init)], } } ChainedCallsEnum::cc_swap_token_b_test_1 => { let swap_amount: u128 = 166; let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &swap_amount .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_b)], } } ChainedCallsEnum::cc_swap_token_a_test_2 => { let swap_amount: u128 = 285; let mut instruction_data: [u8;23] = [0; 23]; instruction_data[0] = 1; instruction_data[1..17].copy_from_slice( &swap_amount .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction_data).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::user_holding_a)], } } ChainedCallsEnum::cc_swap_token_b_test_2 => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::add_max_amount_b) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::vault_b_init)], } } ChainedCallsEnum::cc_add_token_a => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::add_successful_amount_a_lp) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::vault_a_init)], } } ChainedCallsEnum::cc_add_token_b => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::add_successful_amount_b) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("Swap Logic: AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::vault_b_init)], } } ChainedCallsEnum::cc_add_pool_lp => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 4; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::add_successful_amount_a_lp) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("Swap Logic: AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_lp_init)], } } ChainedCallsEnum::cc_remove_token_a => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::remove_actual_a_successful) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::user_holding_a),], } } ChainedCallsEnum::cc_remove_token_b => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 1; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::remove_min_amount_b_low) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_b),], } } ChainedCallsEnum::cc_remove_pool_lp => { let mut instruction: [u8;23] = [0; 23]; instruction[0] = 3; instruction[1..17].copy_from_slice( &helper_balance_constructor(BalanceEnum::remove_actual_a_successful) .to_le_bytes()); let instruction_data = risc0_zkvm::serde::to_vec(&instruction).expect("AMM Program expects valid transaction instruction data"); ChainedCall{ program_id: TOKEN_PROGRAM_ID, instruction_data, pre_states: vec![ helper_account_constructor(AccountEnum::user_holding_lp_init), helper_account_constructor(AccountEnum::pool_lp_init),], } } _ => panic!("Invalid selection") } } fn helper_id_constructor(selection: IdEnum) -> AccountId { match selection { IdEnum::token_a_definition_id => AccountId::new([42;32]), IdEnum::token_b_definition_id => AccountId::new([43;32]), IdEnum::token_lp_definition_id => AccountId::new([44;32]), IdEnum::user_token_a_id => AccountId::new([45;32]), IdEnum::user_token_b_id => AccountId::new([46;32]), IdEnum::user_token_lp_id => AccountId::new([47;32]), IdEnum::pool_definition_id => AccountId::new([48;32]), IdEnum::vault_a_id => AccountId::new([45;32]), IdEnum::vault_b_id => AccountId::new([46;32]), IdEnum::pool_lp_id => AccountId::new([47;32]), _ => panic!("Invalid selection") } } fn helper_account_constructor(selection: AccountEnum) -> AccountWithMetadata { match selection { AccountEnum::user_holding_a => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_a_definition_id), balance: helper_balance_constructor(BalanceEnum::user_token_a_bal), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::user_token_a_id), }, AccountEnum::user_holding_b => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_b_definition_id), balance: helper_balance_constructor(BalanceEnum::user_token_b_bal), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::user_token_b_id), }, AccountEnum::vault_a_uninit => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_a_definition_id), balance: 0, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_a_id), }, AccountEnum::vault_b_uninit => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_b_definition_id), balance: 0, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_b_id), }, AccountEnum::vault_a_init => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_a_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_a_id), }, AccountEnum::vault_b_init => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_b_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_b_reserve_init), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_b_id), }, AccountEnum::vault_a_init_high => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_a_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_a_reserve_high), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_a_id), }, AccountEnum::vault_b_init_high => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_b_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_b_reserve_high), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_b_id), }, AccountEnum::vault_a_init_low => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_a_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_a_reserve_low), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_a_id), }, AccountEnum::vault_b_init_low => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_b_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_b_reserve_low), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_b_id), }, AccountEnum::vault_a_init_zero => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_a_definition_id), balance: 0, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_a_id), }, AccountEnum::vault_b_init_zero => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_b_definition_id), balance: 0, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_b_id), }, AccountEnum::vault_a_wrong_acc_id => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_a_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_b_id), }, AccountEnum::vault_b_wrong_acc_id => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_b_definition_id), balance: helper_balance_constructor(BalanceEnum::vault_b_reserve_init), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_a_id), }, AccountEnum::pool_lp_uninit => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenDefinition::into_data( TokenDefinition{ account_type: 0u8, name: [1;6], total_supply: 0u128, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::token_lp_definition_id), }, AccountEnum::pool_lp_init => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenDefinition::into_data( TokenDefinition{ account_type: 0u8, name: [1;6], total_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::token_lp_definition_id), }, AccountEnum::pool_lp_wrong_acc_id => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenDefinition::into_data( TokenDefinition{ account_type: 0u8, name: [1;6], total_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::vault_a_id), }, AccountEnum::user_holding_lp_uninit => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_lp_definition_id), balance: 0, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::user_token_lp_id), }, AccountEnum::user_holding_lp_init => AccountWithMetadata { account: Account { program_owner: TOKEN_PROGRAM_ID, balance: 0u128, data: TokenHolding::into_data( TokenHolding{ account_type: 1u8, definition_id: helper_id_constructor(IdEnum::token_lp_definition_id), balance: helper_balance_constructor(BalanceEnum::user_token_lp_bal), }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::user_token_lp_id), }, AccountEnum::pool_definition_uninit => AccountWithMetadata { account: Account::default(), is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_init => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_reserve_init), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_init_reserve_a_zero => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_a: 0, reserve_b: helper_balance_constructor(BalanceEnum::vault_b_reserve_init), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_init_reserve_b_zero => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_b: 0, fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_init_reserve_a_low => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_low), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_reserve_low), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_reserve_high), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_init_reserve_b_low => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_high), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_reserve_high), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_reserve_low), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_unauth => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_reserve_init), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: false, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_swap_test_1 => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_swap_test_1), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_swap_test_1), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_swap_test_2 => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_swap_test_2), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_swap_test_2), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_add_zero_lp => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_reserve_low), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_reserve_init), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_reserve_init), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_add_successful => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_add_successful), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_add_successful), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_add_successful), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, AccountEnum::pool_definition_remove_successful => AccountWithMetadata { account: Account { program_owner: ProgramId::default(), balance: 0u128, data: PoolDefinition::into_data( PoolDefinition { definition_token_a_id: helper_id_constructor(IdEnum::token_a_definition_id), definition_token_b_id: helper_id_constructor(IdEnum::token_b_definition_id), vault_a_addr: helper_id_constructor(IdEnum::vault_a_id), vault_b_addr: helper_id_constructor(IdEnum::vault_b_id), liquidity_pool_id: helper_id_constructor(IdEnum::token_lp_definition_id), liquidity_pool_supply: helper_balance_constructor(BalanceEnum::vault_a_remove_successful), reserve_a: helper_balance_constructor(BalanceEnum::vault_a_remove_successful), reserve_b: helper_balance_constructor(BalanceEnum::vault_b_remove_successful), fees: 0u128, active: true, }), nonce: 0, }, is_authorized: true, account_id: helper_id_constructor(IdEnum::pool_definition_id), }, _ => panic!("Invalid selection"), } } /*/ #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_new_pool_with_invalid_number_of_accounts_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit),] ; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_new_pool_with_invalid_number_of_accounts_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_new_pool_with_invalid_number_of_accounts_3() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_new_pool_with_invalid_number_of_accounts_4() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_new_pool_with_invalid_number_of_accounts_5() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_new_pool_with_invalid_number_of_accounts_6() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Invalid number of balance")] #[test] fn test_call_new_pool_with_invalid_number_of_balances_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Pool account is initiated or not authorized")] #[test] fn test_call_new_pool_with_initiated_pool() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Pool account is initiated or not authorized")] #[test] fn test_call_new_pool_with_unauthorized_pool() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_unauth), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Balances must be nonzero")] #[test] fn test_call_new_pool_with_balance_zero_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_uninit), ]; let _post_states = new_pool(&pre_states, &[0, helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Balances must be nonzero")] #[test] fn test_call_new_pool_with_balance_zero_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), 0], TOKEN_PROGRAM_ID); } #[should_panic(expected = "Cannot set up a swap for a token with itself.")] #[test] fn test_call_new_pool_same_token() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_lp_uninit), ]; let _post_states = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); } #[test] fn test_call_new_pool_chain_call_success() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_uninit), helper_account_constructor(AccountEnum::vault_a_uninit), helper_account_constructor(AccountEnum::vault_b_uninit), helper_account_constructor(AccountEnum::pool_lp_uninit), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_uninit), ]; let (post_states, chained_calls) = new_pool(&pre_states, &[helper_balance_constructor(BalanceEnum::user_token_a_bal), helper_balance_constructor(BalanceEnum::user_token_b_bal)], TOKEN_PROGRAM_ID); let pool_post = post_states[0].clone(); let pool_data = PoolDefinition::parse(&pool_post.data).unwrap(); assert!(helper_account_constructor(AccountEnum::pool_definition_init).account == pool_post); let chained_call_lp = chained_calls[0].clone(); let chained_call_b = chained_calls[1].clone(); let chained_call_a = chained_calls[2].clone(); assert!(chained_call_lp == helper_chained_call_constructor(ChainedCallsEnum::cc_pool_lp_initialization)); assert!(chained_call_a == helper_chained_call_constructor(ChainedCallsEnum::cc_token_a_initialization)); assert!(chained_call_b == helper_chained_call_constructor(ChainedCallsEnum::cc_token_b_initialization)); } */ #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_remove_liquidity_with_invalid_number_of_accounts_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_remove_liquidity_with_invalid_number_of_accounts_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_remove_liquidity_with_invalid_number_of_accounts_3() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_remove_liquidity_with_invalid_number_of_accounts_4() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_remove_liquidity_with_invalid_number_of_accounts_5() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_remove_liquidity_with_invalid_number_of_accounts_6() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Vault A was not provided")] #[test] fn test_call_remove_liquidity_vault_a_omitted() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_wrong_acc_id), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Vault B was not provided")] #[test] fn test_call_remove_liquidity_vault_b_omitted() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_wrong_acc_id), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "LP definition mismatch")] #[test] fn test_call_remove_liquidity_lp_def_mismatch() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_wrong_acc_id), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Invalid liquidity account provided")] #[test] fn test_call_remove_liquidity_insufficient_liquidity_amount() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_a), //different token account than lp to create desired error ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Insufficient minimal withdraw amount (Token A) provided for liquidity amount")] #[test] fn test_call_remove_liquidity_insufficient_balance_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp_1), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Insufficient minimal withdraw amount (Token B) provided for liquidity amount")] #[test] fn test_call_remove_liquidity_insufficient_balance_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Minimum withdraw amount must be nonzero")] #[test] fn test_call_remove_liquidity_min_bal_zero_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), 0, helper_balance_constructor(BalanceEnum::remove_min_amount_b)], ); } #[should_panic(expected = "Minimum withdraw amount must be nonzero")] #[test] fn test_call_remove_liquidity_min_bal_zero_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), 0], ); } #[should_panic(expected = "Liquidity amount must be nonzero")] #[test] fn test_call_remove_liquidity_lp_bal_zero() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = remove_liquidity(&pre_states, &[0, helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b),], ); } #[test] fn test_call_remove_liquidity_chained_call_successful() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let (post_states, chained_calls) = remove_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::remove_amount_lp), helper_balance_constructor(BalanceEnum::remove_min_amount_a), helper_balance_constructor(BalanceEnum::remove_min_amount_b_low),], ); let pool_post = post_states[0].clone(); assert!(helper_account_constructor(AccountEnum::pool_definition_remove_successful).account == pool_post); let chained_call_lp = chained_calls[0].clone(); let chained_call_b = chained_calls[1].clone(); let chained_call_a = chained_calls[2].clone(); assert!(chained_call_a == helper_chained_call_constructor(ChainedCallsEnum::cc_remove_token_a)); assert!(chained_call_b == helper_chained_call_constructor(ChainedCallsEnum::cc_remove_token_b)); assert!(chained_call_lp.instruction_data == helper_chained_call_constructor(ChainedCallsEnum::cc_remove_pool_lp).instruction_data); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_add_liquidity_with_invalid_number_of_accounts_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_add_liquidity_with_invalid_number_of_accounts_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_add_liquidity_with_invalid_number_of_accounts_3() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_add_liquidity_with_invalid_number_of_accounts_4() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_add_liquidity_with_invalid_number_of_accounts_5() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_add_liquidity_with_invalid_number_of_accounts_6() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Invalid number of input balances")] #[test] fn test_call_add_liquidity_invalid_number_of_balances_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a),], ); } #[should_panic(expected = "Vault A was not provided")] #[test] fn test_call_add_liquidity_vault_a_omitted() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_wrong_acc_id), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Vault B was not provided")] #[test] fn test_call_add_liquidity_vault_b_omitted() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_wrong_acc_id), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "LP definition mismatch")] #[test] fn test_call_add_liquidity_lp_def_mismatch() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_wrong_acc_id), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Both max-balances must be nonzero")] #[test] fn test_call_add_liquidity_zero_balance_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_min_amount_lp), 0, helper_balance_constructor(BalanceEnum::add_max_amount_b),], ); } #[should_panic(expected = "Both max-balances must be nonzero")] #[test] fn test_call_add_liquidity_zero_balance_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), 0, helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Min-lp must be nonzero")] #[test] fn test_call_add_liquidity_zero_min_lp() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[0, helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b),],); } #[should_panic(expected = "Vaults' balances must be at least the reserve amounts")] #[test] fn test_call_add_liquidity_vault_insufficient_balance_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init_zero), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Vaults' balances must be at least the reserve amounts")] #[test] fn test_call_add_liquidity_vault_insufficient_balance_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init_zero), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "A trade amount is 0")] #[test] fn test_call_add_liquidity_actual_amount_zero_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init_reserve_a_low), helper_account_constructor(AccountEnum::vault_a_init_low), helper_account_constructor(AccountEnum::vault_b_init_high), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "A trade amount is 0")] #[test] fn test_call_add_liquidity_actual_amount_zero_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init_reserve_b_low), helper_account_constructor(AccountEnum::vault_a_init_high), helper_account_constructor(AccountEnum::vault_b_init_low), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a_low), helper_balance_constructor(BalanceEnum::add_max_amount_b_low), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Reserves must be nonzero")] #[test] fn test_call_add_liquidity_reserves_zero_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init_reserve_a_zero), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Reserves must be nonzero")] #[test] fn test_call_add_liquidity_reserves_zero_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init_reserve_b_zero), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[should_panic(expected = "Payable LP must be nonzero")] #[test] fn test_call_add_liquidity_payable_lp_zero() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_add_zero_lp), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let _post_states = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a_low), helper_balance_constructor(BalanceEnum::add_max_amount_b_low), helper_balance_constructor(BalanceEnum::add_min_amount_lp),], ); } #[test] fn test_call_add_liquidity_successful_chain_call() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::pool_lp_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), helper_account_constructor(AccountEnum::user_holding_lp_init), ]; let (post_states, chained_calls) = add_liquidity(&pre_states, &[helper_balance_constructor(BalanceEnum::add_min_amount_lp), helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_b),], ); let pool_post = post_states[0].clone(); assert!(helper_account_constructor(AccountEnum::pool_definition_add_successful).account == pool_post); let chained_call_lp = chained_calls[0].clone(); let chained_call_b = chained_calls[1].clone(); let chained_call_a = chained_calls[2].clone(); assert!(chained_call_a == helper_chained_call_constructor(ChainedCallsEnum::cc_add_token_a)); assert!(chained_call_b == helper_chained_call_constructor(ChainedCallsEnum::cc_add_token_b)); assert!(chained_call_lp == helper_chained_call_constructor(ChainedCallsEnum::cc_add_pool_lp)); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_swap_with_invalid_number_of_accounts_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_swap_with_invalid_number_of_accounts_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_swap_with_invalid_number_of_accounts_3() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Invalid number of input accounts")] #[test] fn test_call_swap_with_invalid_number_of_accounts_4() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Invalid number of amounts provided")] #[test] fn test_call_swap_with_invalid_number_of_amounts() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a)], helper_id_constructor(IdEnum::token_lp_definition_id), ); } #[should_panic(expected = "AccountId is not a token type for the pool")] #[test] fn test_call_swap_incorrect_token_type() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_lp_definition_id), ); } #[should_panic(expected = "Vault A was not provided")] #[test] fn test_call_swap_vault_a_omitted() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_wrong_acc_id), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Vault B was not provided")] #[test] fn test_call_swap_vault_b_omitted() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_wrong_acc_id), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Reserve for Token A exceeds vault balance")] #[test] fn test_call_swap_reserves_vault_mismatch_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init_low), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Reserve for Token B exceeds vault balance")] #[test] fn test_call_swap_reserves_vault_misatch_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init_low), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[should_panic(expected = "Withdraw amount is less than minimal amount out")] #[test] fn test_call_swap_below_min_out() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let _post_states = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_a_definition_id), ); } #[test] fn test_call_swap_successful_chain_call_1() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let (post_states, chained_calls) = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_a), helper_balance_constructor(BalanceEnum::add_max_amount_a_low)], helper_id_constructor(IdEnum::token_a_definition_id), ); let pool_post = post_states[0].clone(); assert!(helper_account_constructor(AccountEnum::pool_definition_swap_test_1).account == pool_post); let chained_call_a = chained_calls[0].clone(); let chained_call_b = chained_calls[1].clone(); assert!(chained_call_a == helper_chained_call_constructor(ChainedCallsEnum::cc_swap_token_a_test_1)); assert!(chained_call_b == helper_chained_call_constructor(ChainedCallsEnum::cc_swap_token_b_test_1)); } #[test] fn test_call_swap_successful_chain_call_2() { let pre_states = vec![ helper_account_constructor(AccountEnum::pool_definition_init), helper_account_constructor(AccountEnum::vault_a_init), helper_account_constructor(AccountEnum::vault_b_init), helper_account_constructor(AccountEnum::user_holding_a), helper_account_constructor(AccountEnum::user_holding_b), ]; let (post_states, chained_calls) = swap(&pre_states, &[helper_balance_constructor(BalanceEnum::add_max_amount_b), helper_balance_constructor(BalanceEnum::min_amount_out)], helper_id_constructor(IdEnum::token_b_definition_id), ); let pool_post = post_states[0].clone(); assert!(helper_account_constructor(AccountEnum::pool_definition_swap_test_2).account == pool_post); let chained_call_a = chained_calls[1].clone(); let chained_call_b = chained_calls[0].clone(); assert!(chained_call_a == helper_chained_call_constructor(ChainedCallsEnum::cc_swap_token_a_test_2)); assert!(chained_call_b == helper_chained_call_constructor(ChainedCallsEnum::cc_swap_token_b_test_2)); } }