Skip to content

Official implementation of the Ferrum Network protocol

License

Notifications You must be signed in to change notification settings

3ierratango/ferrum-network

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

Substrate Frontier Node Template

A FRAME-based Substrate node with the Ethereum RPC support, ready for hacking :rocket:

Generation & Upstream

This template is maintained in the Frontier project repository, and can be used to generate a stand-alone template for use in an independent project via the included template generation script.

A ready-to-use template generated this way is hosted for each Frontier release on the substrate-developer-hub/frontier-node-template repository.

This template was originally forked from the Substrate Node Template. You can find more information on features on this template there, and more detailed usage on the Substrate Developer Hub Tutorials that use this heavily.

Build & Run

To build the chain, execute the following commands from the project root:

$ cargo build --release

To execute the chain, run:

$ ./target/debug/frontier-template-node --dev

The node also supports to use manual seal (to produce block manually through RPC).
This is also used by the ts-tests:

$ ./target/debug/frontier-template-node --dev --manual-seal

Docker Based Development

Optionally, You can build and run the frontier node within Docker directly.
The Dockerfile is optimized for development speed.
(Running the docker run... command will recompile the binaries but not the dependencies)

Building (takes 5-10 min):

docker build -t frontier-node-dev .

Running (takes 1 min to rebuild binaries):

docker run -t frontier-node-dev

Genesis Configuration

The development chain spec included with this project defines a genesis block that has been pre-configured with an EVM account for Alice. When a development chain is started, Alice's EVM account will be funded with a large amount of Ether. The Polkadot UI can be used to see the details of Alice's EVM account. In order to view an EVM account, use the Developer tab of the Polkadot UI Settings app to define the EVM Account type as below. It is also necessary to define the Address and LookupSource to send transaction, and Transaction and Signature to be able to inspect blocks:

{
	"Address": "MultiAddress",
	"LookupSource": "MultiAddress",
	"Account": {
		"nonce": "U256",
		"balance": "U256"
	},
	"Transaction": {
		"nonce": "U256",
		"action": "String",
		"gas_price": "u64",
		"gas_limit": "u64",
		"value": "U256",
		"input": "Vec<u8>",
		"signature": "Signature"
	},
	"Signature": {
		"v": "u64",
		"r": "H256",
		"s": "H256"
	}
}

Use the Developer app's RPC calls tab to query eth > getBalance(address, number) with Alice's EVM account ID (0xd43593c715fdd31c61141abd04a99fd6822c8558); the value that is returned should be:

x: eth.getBalance
340,282,366,920,938,463,463,374,607,431,768,211,455

Further reading: EVM accounts

Alice's EVM account ID was calculated using an included utility script.

Example 1: ERC20 Contract Deployment using EVM dispatchable

The following steps are also available as a Typescript script using Polkadot JS SDK

Step 1: Contract creation

The truffle directory contains a Truffle project that defines an ERC-20 token. For convenience, this repository also contains the compiled bytecode of this token contract, which can be used to deploy it to the Substrate blockchain.

Further reading: the ERC-20 token standard

Use the Polkadot UI Extrinsics app to deploy the contract from Alice's account (submit the extrinsic as a signed transaction) using evm > create with the following parameters:

source: 0xd43593c715fdd31c61141abd04a99fd6822c8558
init: <raw contract bytecode, a very long hex value>
value: 0
gas_limit: 4294967295
gas_price: 1
nonce: <empty> {None}

The values for gas_limit and gas_price were chosen for convenience and have little inherent or special meaning. Note that None for the nonce will increment the known nonce for the source account, starting from 0x0, you may manually set this but will get an "evm.InvalidNonce" error if not set correctly.

Once the extrinsic is in a block, navigate to the Network -> Explorer tab in the UI, or open up the browser console to see that the EVM pallet has fired a Created event with an address field that provides the address of the newly-created contract:

# console:
... {"phase":{"applyExtrinsic":2},"event":{"index":"0x0901","data":["0x8a50db1e0f9452cfd91be8dc004ceb11cb08832f"]} ...

# UI:
evm.Created
A contract has been created at given [address]
   H160: 0x8a50db1e0f9452cfd91be8dc004ceb11cb08832f

In this case, however, it is trivial to calculate this value: 0x8a50db1e0f9452cfd91be8dc004ceb11cb08832f. That is because EVM contract account IDs are determined solely by the ID and nonce of the contract creator's account and, in this case, both of those values are well-known (0xd43593c715fdd31c61141abd04a99fd6822c8558 and 0x0, respectively).

Step 2: Check Contract Storage

Use the Chain State UI tab to queryevm > accountCodes for both Alice's and the contract's account IDs; notice that Alice's account code is empty and the contract's is equal to the bytecode of the Solidity contract.

The ERC-20 contract that was deployed inherits from the OpenZeppelin ERC-20 implementation and extends its capabilities by adding a constructor that mints a maximum amount of tokens to the contract creator. Use the Chain State app to query evm > accountStorage and view the value associated with Alice's account in the _balances map of the ERC-20 contract; use the ERC-20 contract address (0x8a50db1e0f9452cfd91be8dc004ceb11cb08832f) as the first parameter and the storage slot to read as the second parameter (0x045c0350b9cf0df39c4b40400c965118df2dca5ce0fbcf0de4aafc099aea4a14). The value that is returned should be 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff.

The storage slot was calculated using a provided utility. (Slot 0 and alice address: 0xd43593c715fdd31c61141abd04a99fd6822c8558)

Further reading: EVM layout of state variables in storage

Step 3: Contract Usage

Use the Developer -> Extrinsics tab to invoke the transfer(address, uint256) function on the ERC-20 contract with evm > call and transfer some of the ERC-20 tokens from Alice to Bob.

target: 0x8a50db1e0f9452cfd91be8dc004ceb11cb08832f
source: 0xd43593c715fdd31c61141abd04a99fd6822c8558
input: 0xa9059cbb0000000000000000000000008eaf04151687736326c9fea17e25fc528761369300000000000000000000000000000000000000000000000000000000000000dd
value: 0
gas_limit: 4294967295
gas_price: 1

The value of the input parameter is an EVM ABI-encoded function call that was calculated using the Remix web IDE; it consists of a function selector (0xa9059cbb) and the arguments to be used for the function invocation. In this case, the arguments correspond to Bob's EVM account ID (0x8eaf04151687736326c9fea17e25fc5287613693) and the number of tokens to be transferred (0xdd, or 221 in hex).

Further reading: the EVM ABI specification

Step 4: Check Bob Contract Storage

After the extrinsic has finalized, use the Chain State app to query evm > accountStorage to see the ERC-20 balances for both Alice and Bob.

About

Official implementation of the Ferrum Network protocol

Resources

License

Stars

Watchers

Forks

Packages

No packages published

Languages

  • Rust 98.2%
  • Other 1.8%