765379a662
* fix nonce issues by locking populate and send transaction Concurrent asynchronous population of transactions cause issues with nonces not being in sync with the transaction count for an account on chain. This was being mitigated by tracking a "last seen" nonce and locking inside of `populateTransaction` so that the nonce could be populated in a concurrent fashion. However, if there was an async cancellation before the transaction was sent, then the nonce would become out of sync. One solution was to decrease the nonce if a cancellation occurred. The other solution, in this commit, is simply to lock the populate and sendTransaction calls together, so that there will not be concurrent nonce discrepancies. This removes the need for "lastSeenNonce" and is overall more simple. * remove lastSeenNonce Internal nonce tracking is no longer needed since populate/sendTransaction is now locked. Even if cancelled midway, the nonce will get a refreshed value from the number of transactions from chain. * chronos v4 exception tracking * Add tests |
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.github/workflows | ||
ethers | ||
testmodule | ||
testnode | ||
.editorconfig | ||
.gitignore | ||
License.md | ||
Readme.md | ||
config.nims | ||
ethers.nim | ||
ethers.nimble | ||
nim.cfg |
Readme.md
Nim Ethers
A port of the ethers.js library to Nim. Allows you to connect to an Ethereum node.
This is very much a work in progress; expect to see many things that are incomplete or wrong. Use at your own risk.
Installation
Use the Nimble package manager to add ethers
to an existing
project. Add the following to its .nimble file:
requires "ethers >= 0.9.0 & < 0.10.0"
Usage
To connect to an Ethereum node, you require a Provider
. Currently, only a
JSON-RPC provider is supported:
import ethers
import chronos
let provider = JsonRpcProvider.new("ws://localhost:8545")
let accounts = await provider.listAccounts()
To interact with a smart contract, you need to define the contract functions in Nim. For example, to interact with an ERC20 token, you could define the following:
type Erc20 = ref object of Contract
proc totalSupply(token: Erc20): UInt256 {.contract, view.}
proc balanceOf(token: Erc20, account: Address): UInt256 {.contract, view.}
proc transfer(token: Erc20, recipient: Address, amount: UInt256) {.contract.}
proc allowance(token: Erc20, owner, spender: Address): UInt256 {.contract, view.}
proc approve(token: Erc20, spender: Address, amount: UInt256) {.contract.}
proc transferFrom(token: Erc20, sender, recipient: Address, amount: UInt256) {.contract.}
Notice how some functions are annotated with a {.view.}
pragma. This indicates
that the function does not modify the blockchain. See also the Solidity
documentation on state mutability
Now that you've defined the contract interface, you can create an instance of it using its deployed address:
let address = Address.init("0x.....")
let token = Erc20.new(address, provider)
The functions that you defined earlier can now be called asynchronously:
let supply = await token.totalSupply()
let balance = await token.balanceOf(accounts[0])
These invocations do not yet change the state of the blockchain, even when we
invoke those functions that lack a {.view.}
pragma. To allow these changes to
happen, we require an instance of a Signer
first.
For example, to use the 4th account on the Ethereum node to sign transactions, you'd instantiate the signer as follows:
let signer = provider.getSigner(accounts[3])
And then connect the contract and signer:
let writableToken = token.connect(signer)
This allows you to make changes to the state of the blockchain:
await writableToken.transfer(accounts[7], 42.u256)
Which transfers 42 tokens from account 3 to account 7
And lastly, don't forget to close the provider when you're done:
await provider.close()
Events
You can subscribe to events that are emitted by a smart contract. For instance,
to get notified about token transfers you define the Transfer
event:
type Transfer = object of Event
sender {.indexed.}: Address
receiver {.indexed.}: Address
value: UInt256
Notice that Transfer
inherits from Event
, and that some event parameters are
marked with {.indexed.}
to match the definition in Solidity.
Note that valid types of indexed parameters are:
uint8 | uint16 | uint32 | uint64 | UInt256 | UInt128 |
int8 | int16 | int32 | int64 | Int256 | Int128 |
bool | Address | array[ 1..32, byte]
Distinct types of valid types are also supported for indexed fields, eg:
type
DistinctAlias = distinct array[32, byte]
MyEvent = object of Event
a {.indexed.}: DistinctAlias
b: DistinctAlias # also allowed for non-indexed fields
You can now subscribe to Transfer events by calling subscribe
on the contract
instance.
proc handleTransfer(transfer: Transfer) =
echo "received transfer: ", transfer
let subscription = await token.subscribe(Transfer, handleTransfer)
When a Transfer event is emitted, the handleTransfer
proc that you just
defined will be called.
When you're no longer interested in these events, you can unsubscribe:
await subscription.unsubscribe()
Custom errors
Solidity's custom errors are supported. To use them, you declare their type and indicate in which contract functions they can occur. For instance, this is how you would define the "InsufficientBalance" error to match the definition in this Solidity example:
type
InsufficientBalance = object of SolidityError
arguments: tuple[available: UInt256, required: UInt256]
Notice that InsufficientBalance
inherits from SoldityError
, and that it has
an arguments
tuple whose fields match the definition in Solidity.
You can use the {.errors.}
pragma to declare that this error may occur in a
contract function:
proc transfer*(token: Erc20Token, recipient: Address, amount: UInt256)
{.contract, errors:[InsufficientBalance].}
This allows you to write error handling code for the transfer
function like
this:
try:
await token.transfer(recipient, 100.u256)
except InsufficientBalance as error:
echo "insufficient balance"
echo "available balance: ", error.arguments.available
echo "required balance: ", error.arguments.required
Utilities
This library ships with some optional modules that provides convenience utilities for you such as:
ethers/erc20
module provides you with ERC20 token implementation and its events
Contribution
If you want to run the tests, then before running nimble test
, you have to
have installed NodeJS and started a testing node:
$ cd testnode
$ npm ci
$ npm start
If you need to use different port for the RPC node, then you can start with npm start -- --port 1111
and
then run the tests with ETHERS_TEST_PROVIDER=1111 nimble test
.
Thanks
This library is inspired by the great work done by the ethers.js (no affiliation) and nim-web3 developers.