use crate::{ AuthenticatedTransferProgram, address::Address, execute_public, public_transaction::PublicTransaction, }; use nssa_core::{ account::{Account, AccountWithMetadata}, program::{Program, validate_constraints}, }; use std::collections::{HashMap, HashSet}; pub struct V01State { public_state: HashMap, } impl V01State { pub fn new_with_genesis_accounts(initial_data: &[([u8; 32], u128)]) -> Self { // TODO:: remove this assert? let public_state = initial_data .to_owned() .into_iter() .map(|(address_value, balance)| { let mut account = Account::default(); account.balance = balance; account.program_owner = AuthenticatedTransferProgram::PROGRAM_ID; let address = Address::new(address_value); (address, account) }) .collect(); Self { public_state } } pub fn transition_from_public_transaction(&mut self, tx: &PublicTransaction) -> Result<(), ()> { let state_diff = self .execute_and_verify_public_transaction(&tx) .map_err(|_| ())?; for (address, post) in state_diff.into_iter() { let current_account = self.get_account_by_address_mut(address); *current_account = post; } for address in tx.signer_addresses() { let current_account = self.get_account_by_address_mut(address); current_account.nonce += 1; } Ok(()) } fn get_account_by_address_mut(&mut self, address: Address) -> &mut Account { self.public_state .entry(address) .or_insert_with(Account::default) } pub fn get_account_by_address(&self, address: &Address) -> Account { self.public_state .get(address) .cloned() .unwrap_or(Account::default()) } fn execute_and_verify_public_transaction( &mut self, tx: &PublicTransaction, ) -> Result, ()> { let message = tx.message(); let witness_set = tx.witness_set(); // All addresses must be different if message.addresses.iter().collect::>().len() != message.addresses.len() { return Err(()); } if message.nonces.len() != witness_set.signatures_and_public_keys.len() { return Err(()); } let mut authorized_addresses = Vec::new(); for ((signature, public_key), nonce) in witness_set .signatures_and_public_keys .iter() .zip(message.nonces.iter()) { // Check the signature is valid if !signature.is_valid_for(message, public_key) { return Err(()); } // Check the nonce corresponds to the current nonce on the public state. let address = Address::from_public_key(public_key); let current_nonce = self.get_account_by_address(&address).nonce; if current_nonce != *nonce { return Err(()); } authorized_addresses.push(address); } // Build pre_states for execution let pre_states: Vec<_> = message .addresses .iter() .map(|address| AccountWithMetadata { account: self.get_account_by_address(address), is_authorized: authorized_addresses.contains(address), }) .collect(); // Check the `program_id` corresponds to a built-in program // Only allowed program so far is the authenticated transfer program if message.program_id != AuthenticatedTransferProgram::PROGRAM_ID { return Err(()); } // // Execute program let post_states = execute_public::(&pre_states, message.instruction_data) .map_err(|_| ())?; // Verify execution corresponds to a well-behaved program. // See the # Programs section for the definition of the `validate_constraints` method. validate_constraints(&pre_states, &post_states, message.program_id).map_err(|_| ())?; if (post_states.len() != message.addresses.len()) { return Err(()); } Ok(message .addresses .iter() .cloned() .zip(post_states.into_iter()) .collect()) } } #[cfg(test)] mod tests { use super::*; use crate::{public_transaction, signature::PrivateKey}; fn transfer_transaction_for_tests( from: Address, from_key: PrivateKey, nonce: u128, to: Address, balance: u128, ) -> PublicTransaction { let addresses = vec![from, to]; let nonces = vec![nonce]; let program_id = AuthenticatedTransferProgram::PROGRAM_ID; let message = public_transaction::Message::new(program_id, addresses, nonces, balance); let witness_set = public_transaction::WitnessSet::for_message(&message, &[from_key]); PublicTransaction::new(message, witness_set) } #[test] fn test_1() { let initial_data = [([1; 32], 100)]; let mut genesis_state = V01State::new_with_genesis_accounts(&initial_data); let from = Address::new(initial_data[0].0.clone()); let from_key = PrivateKey(1); let to = Address::new([2; 32]); let balance_to_move = 5; let tx = transfer_transaction_for_tests(from.clone(), from_key, 0, to.clone(), balance_to_move); let _ = genesis_state.transition_from_public_transaction(&tx); assert_eq!( genesis_state.get_account_by_address(&to).balance, balance_to_move ); assert_eq!( genesis_state.get_account_by_address(&from).balance, initial_data[0].1 - balance_to_move ); assert_eq!(genesis_state.get_account_by_address(&from).nonce, 1); assert_eq!(genesis_state.get_account_by_address(&to).nonce, 0); } #[test] fn test_2() { let initial_data = [([1; 32], 100), ([99; 32], 200)]; let mut genesis_state = V01State::new_with_genesis_accounts(&initial_data); let from = Address::new(initial_data[1].0.clone()); let from_key = PrivateKey(99); let to = Address::new(initial_data[0].0.clone()); let balance_to_move = 8; let to_previous_balance = genesis_state.get_account_by_address(&to).balance; let tx = transfer_transaction_for_tests(from.clone(), from_key, 0, to.clone(), balance_to_move); let _ = genesis_state.transition_from_public_transaction(&tx); assert_eq!(genesis_state.get_account_by_address(&to).balance, 108); assert_eq!( genesis_state.get_account_by_address(&from).balance, initial_data[1].1 - balance_to_move ); assert_eq!(genesis_state.get_account_by_address(&from).nonce, 1); assert_eq!(genesis_state.get_account_by_address(&to).nonce, 0); } }