#[cfg(not(feature = "ink-as-dependency"))]

use ink_storage::{

collections::HashMap as StorageHashMap,

lazy::Lazy,

};

/// A simple ERC-20 contract.

#[ink(storage)]

pub struct Erc20 {

/// Total token supply.

total_supply: Lazy<Balance>,

/// Mapping from owner to number of owned token.

balances: StorageHashMap<AccountId, Balance>,

/// Mapping of the token amount which an account is allowed to withdraw

/// from another account.

allowances: StorageHashMap<(AccountId, AccountId), Balance>,

}

/// Event emitted when a token transfer occurs.

#[ink(event)]

pub struct Transfer {

#[ink(topic)]

from: Option<AccountId>,

#[ink(topic)]

to: Option<AccountId>,

value: Balance,

}

/// Event emitted when an approval occurs that `spender` is allowed to withdraw

/// up to the amount of `value` tokens from `owner`.

#[ink(event)]

pub struct Approval {

#[ink(topic)]

owner: AccountId,

#[ink(topic)]

spender: AccountId,

value: Balance,

}

/// The ERC-20 error types.

#[derive(Debug, PartialEq, Eq, scale::Encode, scale::Decode)]

#[cfg_attr(feature = "std", derive(scale_info::TypeInfo))]

pub enum Error {

/// Returned if not enough balance to fulfill a request is available.

InsufficientBalance,

/// Returned if not enough allowance to fulfill a request is available.

InsufficientAllowance,

}

/// The ERC-20 result type.

pub type Result<T> = core::result::Result<T, Error>;

impl Erc20 {

/// Creates a new ERC-20 contract with the specified initial supply.

#[ink(constructor)]

pub fn new(initial_supply: Balance) -> Self {

let caller = Self::env().caller();

let mut balances = StorageHashMap::new();

balances.insert(caller, initial_supply);

let instance = Self {

total_supply: Lazy::new(initial_supply),

balances,

allowances: StorageHashMap::new(),

};

Self::env().emit_event(Transfer {

from: None,

to: Some(caller),

value: initial_supply,

});

instance

}

/// Returns the total token supply.

#[ink(message)]

pub fn total_supply(&self) -> Balance {

*self.total_supply

}

/// Returns the account balance for the specified `owner`.

///

/// Returns `0` if the account is non-existent.

#[ink(message)]

pub fn balance_of(&self, owner: AccountId) -> Balance {

self.balances.get(&owner).copied().unwrap_or(0)

}

/// Returns the amount which `spender` is still allowed to withdraw from `owner`.

///

/// Returns `0` if no allowance has been set `0`.

#[ink(message)]

pub fn allowance(&self, owner: AccountId, spender: AccountId) -> Balance {

self.allowances.get(&(owner, spender)).copied().unwrap_or(0)

}

/// Transfers `value` amount of tokens from the caller's account to account `to`.

///

/// On success a `Transfer` event is emitted.

///

/// # Errors

///

/// Returns `InsufficientBalance` error if there are not enough tokens on

/// the caller's account balance.

#[ink(message)]

pub fn transfer(&mut self, to: AccountId, value: Balance) -> Result<()> {

let from = self.env().caller();

self.transfer_from_to(from, to, value)

}

/// Allows `spender` to withdraw from the caller's account multiple times, up to

/// the `value` amount.

///

/// If this function is called again it overwrites the current allowance with `value`.

///

/// An `Approval` event is emitted.

#[ink(message)]

pub fn approve(&mut self, spender: AccountId, value: Balance) -> Result<()> {

let owner = self.env().caller();

self.allowances.insert((owner, spender), value);

self.env().emit_event(Approval {

owner,

spender,

value,

});

Ok(())

}

/// Transfers `value` tokens on the behalf of `from` to the account `to`.

///

/// This can be used to allow a contract to transfer tokens on ones behalf and/or

/// to charge fees in sub-currencies, for example.

///

/// On success a `Transfer` event is emitted.

///

/// # Errors

///

/// Returns `InsufficientAllowance` error if there are not enough tokens allowed

/// for the caller to withdraw from `from`.

///

/// Returns `InsufficientBalance` error if there are not enough tokens on

/// the account balance of `from`.

#[ink(message)]

pub fn transfer_from(

&mut self,

from: AccountId,

to: AccountId,

value: Balance,

) -> Result<()> {

let caller = self.env().caller();

let allowance = self.allowance(from, caller);

if allowance < value {

return Err(Error::InsufficientAllowance)

}

self.transfer_from_to(from, to, value)?;

self.allowances.insert((from, caller), allowance - value);

Ok(())

}

/// Transfers `value` amount of tokens from the caller's account to account `to`.

///

/// On success a `Transfer` event is emitted.

///

/// # Errors

///

/// Returns `InsufficientBalance` error if there are not enough tokens on

/// the caller's account balance.

fn transfer_from_to(

&mut self,

from: AccountId,

to: AccountId,

value: Balance,

) -> Result<()> {

let from_balance = self.balance_of(from);

if from_balance < value {

return Err(Error::InsufficientBalance)

}

self.balances.insert(from, from_balance - value);

let to_balance = self.balance_of(to);

self.balances.insert(to, to_balance + value);

self.env().emit_event(Transfer {

from: Some(from),

to: Some(to),

value,

});

Ok(())

}

}

/// Unit tests.

#[cfg(not(feature = "ink-experimental-engine"))]

#[cfg(test)]

mod tests {

/// Imports all the definitions from the outer scope so we can use them here.

use super::*;

type Event = <Erc20 as ::ink_lang::BaseEvent>::Type;

use ink_lang as ink;

fn assert_transfer_event(

event: &ink_env::test::EmittedEvent,

expected_from: Option<AccountId>,

expected_to: Option<AccountId>,

expected_value: Balance,

) {

let decoded_event = <Event as scale::Decode>::decode(&mut &event.data[..])

.expect("encountered invalid contract event data buffer");

if let Event::Transfer(Transfer { from, to, value }) = decoded_event {

assert_eq!(from, expected_from, "encountered invalid Transfer.from");

assert_eq!(to, expected_to, "encountered invalid Transfer.to");

assert_eq!(value, expected_value, "encountered invalid Trasfer.value");

} else {

panic!("encountered unexpected event kind: expected a Transfer event")

}

let expected_topics = vec![

encoded_into_hash(&PrefixedValue {

value: b"Erc20::Transfer",

prefix: b"",

}),

encoded_into_hash(&PrefixedValue {

prefix: b"Erc20::Transfer::from",

value: &expected_from,

}),

encoded_into_hash(&PrefixedValue {

prefix: b"Erc20::Transfer::to",

value: &expected_to,

}),

encoded_into_hash(&PrefixedValue {

prefix: b"Erc20::Transfer::value",

value: &expected_value,

}),

];

for (n, (actual_topic, expected_topic)) in

event.topics.iter().zip(expected_topics).enumerate()

{

let topic = actual_topic

.decode::<Hash>()

.expect("encountered invalid topic encoding");

assert_eq!(topic, expected_topic, "encountered invalid topic at {}", n);

}

}

/// The default constructor does its job.

#[ink::test]

fn new_works() {

// Constructor works.

let _erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(1, emitted_events.len());

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

}

/// The total supply was applied.

#[ink::test]

fn total_supply_works() {

// Constructor works.

let erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

// Get the token total supply.

assert_eq!(erc20.total_supply(), 100);

}

/// Get the actual balance of an account.

#[ink::test]

fn balance_of_works() {

// Constructor works

let erc20 = Erc20::new(100);

// Transfer event triggered during initial construction

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>()

.expect("Cannot get accounts");

// Alice owns all the tokens on deployment

assert_eq!(erc20.balance_of(accounts.alice), 100);

// Bob does not owns tokens

assert_eq!(erc20.balance_of(accounts.bob), 0);

}

#[ink::test]

fn transfer_works() {

// Constructor works.

let mut erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>()

.expect("Cannot get accounts");

assert_eq!(erc20.balance_of(accounts.bob), 0);

// Alice transfers 10 tokens to Bob.

assert_eq!(erc20.transfer(accounts.bob, 10), Ok(()));

// Bob owns 10 tokens.

assert_eq!(erc20.balance_of(accounts.bob), 10);

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(emitted_events.len(), 2);

// Check first transfer event related to ERC-20 instantiation.

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

// Check the second transfer event relating to the actual trasfer.

assert_transfer_event(

&emitted_events[1],

Some(AccountId::from([0x01; 32])),

Some(AccountId::from([0x02; 32])),

10,

);

}

#[ink::test]

fn invalid_transfer_should_fail() {

// Constructor works.

let mut erc20 = Erc20::new(100);

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>()

.expect("Cannot get accounts");

assert_eq!(erc20.balance_of(accounts.bob), 0);

// Get contract address.

let callee = ink_env::account_id::<ink_env::DefaultEnvironment>()

.unwrap_or_else(|_| [0x0; 32].into());

// Create call

let mut data =

ink_env::test::CallData::new(ink_env::call::Selector::new([0x00; 4])); // balance_of

data.push_arg(&accounts.bob);

// Push the new execution context to set Bob as caller

ink_env::test::push_execution_context::<ink_env::DefaultEnvironment>(

accounts.bob,

callee,

1000000,

1000000,

data,

);

// Bob fails to transfers 10 tokens to Eve.

assert_eq!(

erc20.transfer(accounts.eve, 10),

Err(Error::InsufficientBalance)

);

// Alice owns all the tokens.

assert_eq!(erc20.balance_of(accounts.alice), 100);

assert_eq!(erc20.balance_of(accounts.bob), 0);

assert_eq!(erc20.balance_of(accounts.eve), 0);

// Transfer event triggered during initial construction.

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(emitted_events.len(), 1);

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

}

#[ink::test]

fn transfer_from_works() {

// Constructor works.

let mut erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>()

.expect("Cannot get accounts");

// Bob fails to transfer tokens owned by Alice.

assert_eq!(

erc20.transfer_from(accounts.alice, accounts.eve, 10),

Err(Error::InsufficientAllowance)

);

// Alice approves Bob for token transfers on her behalf.

assert_eq!(erc20.approve(accounts.bob, 10), Ok(()));

// The approve event takes place.

assert_eq!(ink_env::test::recorded_events().count(), 2);

// Get contract address.

let callee = ink_env::account_id::<ink_env::DefaultEnvironment>()

.unwrap_or_else(|_| [0x0; 32].into());

// Create call.

let mut data =

ink_env::test::CallData::new(ink_env::call::Selector::new([0x00; 4])); // balance_of

data.push_arg(&accounts.bob);

// Push the new execution context to set Bob as caller.

ink_env::test::push_execution_context::<ink_env::DefaultEnvironment>(

accounts.bob,

callee,

1000000,

1000000,

data,

);

// Bob transfers tokens from Alice to Eve.

assert_eq!(

erc20.transfer_from(accounts.alice, accounts.eve, 10),

Ok(())

);

// Eve owns tokens.

assert_eq!(erc20.balance_of(accounts.eve), 10);

// Check all transfer events that happened during the previous calls:

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(emitted_events.len(), 3);

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

// The second event `emitted_events[1]` is an Approve event that we skip checking.

assert_transfer_event(

&emitted_events[2],

Some(AccountId::from([0x01; 32])),

Some(AccountId::from([0x05; 32])),

10,

);

}

#[ink::test]

fn allowance_must_not_change_on_failed_transfer() {

let mut erc20 = Erc20::new(100);

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>()

.expect("Cannot get accounts");

// Alice approves Bob for token transfers on her behalf.

let alice_balance = erc20.balance_of(accounts.alice);

let initial_allowance = alice_balance + 2;

assert_eq!(erc20.approve(accounts.bob, initial_allowance), Ok(()));

// Get contract address.

let callee = ink_env::account_id::<ink_env::DefaultEnvironment>()

.unwrap_or_else(|_| [0x0; 32].into());

// Create call.

let mut data =

ink_env::test::CallData::new(ink_env::call::Selector::new([0x00; 4])); // balance_of

data.push_arg(&accounts.bob);

// Push the new execution context to set Bob as caller.

ink_env::test::push_execution_context::<ink_env::DefaultEnvironment>(

accounts.bob,

callee,

1000000,

1000000,

data,

);

// Bob tries to transfer tokens from Alice to Eve.

let emitted_events_before = ink_env::test::recorded_events();

assert_eq!(

erc20.transfer_from(accounts.alice, accounts.eve, alice_balance + 1),

Err(Error::InsufficientBalance)

);

// Allowance must have stayed the same

assert_eq!(

erc20.allowance(accounts.alice, accounts.bob),

initial_allowance

);

// No more events must have been emitted

let emitted_events_after = ink_env::test::recorded_events();

assert_eq!(emitted_events_before.count(), emitted_events_after.count());

}

}

/// For calculating the event topic hash.

struct PrefixedValue<'a, 'b, T> {

pub prefix: &'a [u8],

pub value: &'b T,

}

impl<X> scale::Encode for PrefixedValue<'_, '_, X>

where

X: scale::Encode,

{

#[inline]

fn size_hint(&self) -> usize {

self.prefix.size_hint() + self.value.size_hint()

}

#[inline]

fn encode_to<T: scale::Output + ?Sized>(&self, dest: &mut T) {

self.prefix.encode_to(dest);

self.value.encode_to(dest);

}

}

#[cfg(feature = "ink-experimental-engine")]

#[cfg(test)]

mod tests_experimental_engine {

use super::*;

use ink_env::Clear;

use ink_lang as ink;

type Event = <Erc20 as ::ink_lang::BaseEvent>::Type;

fn assert_transfer_event(

event: &ink_env::test::EmittedEvent,

expected_from: Option<AccountId>,

expected_to: Option<AccountId>,

expected_value: Balance,

) {

let decoded_event = <Event as scale::Decode>::decode(&mut &event.data[..])

.expect("encountered invalid contract event data buffer");

if let Event::Transfer(Transfer { from, to, value }) = decoded_event {

assert_eq!(from, expected_from, "encountered invalid Transfer.from");

assert_eq!(to, expected_to, "encountered invalid Transfer.to");

assert_eq!(value, expected_value, "encountered invalid Trasfer.value");

} else {

panic!("encountered unexpected event kind: expected a Transfer event")

}

let expected_topics = vec![

encoded_into_hash(&PrefixedValue {

value: b"Erc20::Transfer",

prefix: b"",

}),

encoded_into_hash(&PrefixedValue {

prefix: b"Erc20::Transfer::from",

value: &expected_from,

}),

encoded_into_hash(&PrefixedValue {

prefix: b"Erc20::Transfer::to",

value: &expected_to,

}),

encoded_into_hash(&PrefixedValue {

prefix: b"Erc20::Transfer::value",

value: &expected_value,

}),

];

let topics = event.topics.clone();

for (n, (actual_topic, expected_topic)) in

topics.iter().zip(expected_topics).enumerate()

{

let mut topic_hash = Hash::clear();

let len = actual_topic.len();

topic_hash.as_mut()[0..len].copy_from_slice(&actual_topic[0..len]);

assert_eq!(

topic_hash, expected_topic,

"encountered invalid topic at {}",

n

);

}

}

/// The default constructor does its job.

#[ink::test]

fn new_works() {

// Constructor works.

let _erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(1, emitted_events.len());

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

}

/// The total supply was applied.

#[ink::test]

fn total_supply_works() {

// Constructor works.

let erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

// Get the token total supply.

assert_eq!(erc20.total_supply(), 100);

}

/// Get the actual balance of an account.

#[ink::test]

fn balance_of_works() {

// Constructor works

let erc20 = Erc20::new(100);

// Transfer event triggered during initial construction

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>();

// Alice owns all the tokens on deployment

assert_eq!(erc20.balance_of(accounts.alice), 100);

// Bob does not owns tokens

assert_eq!(erc20.balance_of(accounts.bob), 0);

}

#[ink::test]

fn transfer_works() {

// Constructor works.

let mut erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>();

assert_eq!(erc20.balance_of(accounts.bob), 0);

// Alice transfers 10 tokens to Bob.

assert_eq!(erc20.transfer(accounts.bob, 10), Ok(()));

// Bob owns 10 tokens.

assert_eq!(erc20.balance_of(accounts.bob), 10);

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(emitted_events.len(), 2);

// Check first transfer event related to ERC-20 instantiation.

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

// Check the second transfer event relating to the actual trasfer.

assert_transfer_event(

&emitted_events[1],

Some(AccountId::from([0x01; 32])),

Some(AccountId::from([0x02; 32])),

10,

);

}

#[ink::test]

fn invalid_transfer_should_fail() {

// Constructor works.

let mut erc20 = Erc20::new(100);

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>();

assert_eq!(erc20.balance_of(accounts.bob), 0);

// Set the contract as callee and Bob as caller.

let contract = ink_env::account_id::<ink_env::DefaultEnvironment>()?;

ink_env::test::set_callee::<ink_env::DefaultEnvironment>(contract);

ink_env::test::set_caller::<ink_env::DefaultEnvironment>(accounts.bob);

// Bob fails to transfers 10 tokens to Eve.

assert_eq!(

erc20.transfer(accounts.eve, 10),

Err(Error::InsufficientBalance)

);

// Alice owns all the tokens.

assert_eq!(erc20.balance_of(accounts.alice), 100);

assert_eq!(erc20.balance_of(accounts.bob), 0);

assert_eq!(erc20.balance_of(accounts.eve), 0);

// Transfer event triggered during initial construction.

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(emitted_events.len(), 1);

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

}

#[ink::test]

fn transfer_from_works() {

// Constructor works.

let mut erc20 = Erc20::new(100);

// Transfer event triggered during initial construction.

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>();

// Bob fails to transfer tokens owned by Alice.

assert_eq!(

erc20.transfer_from(accounts.alice, accounts.eve, 10),

Err(Error::InsufficientAllowance)

);

// Alice approves Bob for token transfers on her behalf.

assert_eq!(erc20.approve(accounts.bob, 10), Ok(()));

// The approve event takes place.

assert_eq!(ink_env::test::recorded_events().count(), 2);

// Set the contract as callee and Bob as caller.

let contract = ink_env::account_id::<ink_env::DefaultEnvironment>()?;

ink_env::test::set_callee::<ink_env::DefaultEnvironment>(contract);

ink_env::test::set_caller::<ink_env::DefaultEnvironment>(accounts.bob);

// Bob transfers tokens from Alice to Eve.

assert_eq!(

erc20.transfer_from(accounts.alice, accounts.eve, 10),

Ok(())

);

// Eve owns tokens.

assert_eq!(erc20.balance_of(accounts.eve), 10);

// Check all transfer events that happened during the previous calls:

let emitted_events = ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(emitted_events.len(), 3);

assert_transfer_event(

&emitted_events[0],

None,

Some(AccountId::from([0x01; 32])),

100,

);

// The second event `emitted_events[1]` is an Approve event that we skip checking.

assert_transfer_event(

&emitted_events[2],

Some(AccountId::from([0x01; 32])),

Some(AccountId::from([0x05; 32])),

10,

);

}

#[ink::test]

fn allowance_must_not_change_on_failed_transfer() {

let mut erc20 = Erc20::new(100);

let accounts =

ink_env::test::default_accounts::<ink_env::DefaultEnvironment>();

// Alice approves Bob for token transfers on her behalf.

let alice_balance = erc20.balance_of(accounts.alice);

let initial_allowance = alice_balance + 2;

assert_eq!(erc20.approve(accounts.bob, initial_allowance), Ok(()));

// Get contract address.

let callee = ink_env::account_id::<ink_env::DefaultEnvironment>()?;

ink_env::test::set_callee::<ink_env::DefaultEnvironment>(callee);

ink_env::test::set_caller::<ink_env::DefaultEnvironment>(accounts.bob);

// Bob tries to transfer tokens from Alice to Eve.

let emitted_events_before =

ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(

erc20.transfer_from(accounts.alice, accounts.eve, alice_balance + 1),

Err(Error::InsufficientBalance)

);

// Allowance must have stayed the same

assert_eq!(

erc20.allowance(accounts.alice, accounts.bob),

initial_allowance

);

// No more events must have been emitted

let emitted_events_after =

ink_env::test::recorded_events().collect::<Vec<_>>();

assert_eq!(emitted_events_before.len(), emitted_events_after.len());

}

}

#[cfg(test)]

fn encoded_into_hash<T>(entity: &T) -> Hash

where

T: scale::Encode,

{

use ink_env::{

hash::{

Blake2x256,

CryptoHash,

HashOutput,

},

Clear,

};

let mut result = Hash::clear();

let len_result = result.as_ref().len();

let encoded = entity.encode();

let len_encoded = encoded.len();

if len_encoded <= len_result {

result.as_mut()[..len_encoded].copy_from_slice(&encoded);

return result

}

let mut hash_output = <<Blake2x256 as HashOutput>::Type as Default>::default();

<Blake2x256 as CryptoHash>::hash(&encoded, &mut hash_output);

let copy_len = core::cmp::min(hash_output.len(), len_result);

result.as_mut()[0..copy_len].copy_from_slice(&hash_output[0..copy_len]);

result

}