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Go implementation of the Ethereum protocol

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Quick Overview

Go Ethereum (geth) is the official Go implementation of the Ethereum protocol. It is a command-line interface and node implementation that facilitates interaction with the Ethereum network, allowing users to mine ether, transfer funds, deploy smart contracts, and explore the blockchain.

Pros

  • Robust and well-maintained: As the official Go implementation, it receives regular updates and has strong community support.
  • Versatile: Can be used as a full node, light node, or for development purposes.
  • Extensive documentation: Provides comprehensive guides and API references for developers.
  • Cross-platform compatibility: Runs on various operating systems, including Windows, macOS, and Linux.

Cons

  • Resource-intensive: Running a full node requires significant disk space and processing power.
  • Steep learning curve: May be challenging for beginners to set up and use effectively.
  • Synchronization time: Initial blockchain synchronization can take a considerable amount of time.

Code Examples

  1. Connecting to an Ethereum node:
import "github.com/ethereum/go-ethereum/ethclient"

client, err := ethclient.Dial("https://mainnet.infura.io/v3/YOUR-PROJECT-ID")
if err != nil {
    log.Fatal(err)
}
  1. Retrieving the latest block number:
header, err := client.HeaderByNumber(context.Background(), nil)
if err != nil {
    log.Fatal(err)
}
fmt.Println("Latest block number:", header.Number.String())
  1. Sending a transaction:
privateKey, err := crypto.HexToECDSA("your-private-key")
if err != nil {
    log.Fatal(err)
}

nonce, err := client.PendingNonceAt(context.Background(), crypto.PubkeyToAddress(privateKey.PublicKey))
if err != nil {
    log.Fatal(err)
}

gasPrice, err := client.SuggestGasPrice(context.Background())
if err != nil {
    log.Fatal(err)
}

tx := types.NewTransaction(nonce, toAddress, value, gasLimit, gasPrice, nil)
signedTx, err := types.SignTx(tx, types.NewEIP155Signer(chainID), privateKey)
if err != nil {
    log.Fatal(err)
}

err = client.SendTransaction(context.Background(), signedTx)
if err != nil {
    log.Fatal(err)
}

Getting Started

  1. Install Go (version 1.16 or later)
  2. Clone the repository: 
    git clone https://github.com/ethereum/go-ethereum.git
  3. Build geth: 
    cd go-ethereum
make geth
  4. Run geth: 
    ./build/bin/geth

For development, add the following import to your Go file:

import "github.com/ethereum/go-ethereum"

Then, use go get to fetch the package:

go get github.com/ethereum/go-ethereum

Competitor Comparisons

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Pros of Bitcoin

  • Simpler codebase, focused solely on cryptocurrency functionality
  • Longer history and more battle-tested security
  • Larger and more diverse developer community

Cons of Bitcoin

  • Less flexible for building complex applications
  • Slower transaction processing times
  • Limited smart contract capabilities

Code Comparison

Bitcoin (C++):

CAmount GetBlockSubsidy(int nHeight, const Consensus::Params& consensusParams)
{
    int halvings = nHeight / consensusParams.nSubsidyHalvingInterval;
    // Force block reward to zero when right shift is undefined.
    if (halvings >= 64)
        return 0;

    CAmount nSubsidy = 50 * COIN;
    // Subsidy is cut in half every 210,000 blocks which will occur approximately every 4 years.
    nSubsidy >>= halvings;
    return nSubsidy;
}

Go-Ethereum (Go):

func (c *ChainConfig) GetBlockReward(header *types.Header) *big.Int {
	era := (header.Number.Uint64() / c.ECIP1017EraRounds) + 1
	reward := new(big.Int).Set(c.BlockReward)
	for i := 1; i < int(era); i++ {
		reward.Mul(reward, big.NewInt(4))
		reward.Div(reward, big.NewInt(5))
	}
	return reward
}

The Bitcoin code calculates block rewards using halvings, while Go-Ethereum uses a more complex era-based system with gradual reductions. This reflects the different approaches to monetary policy in each project.

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Pros of Fabric

  • Designed for enterprise use with modular architecture and pluggable components
  • Supports private and confidential transactions, ideal for business applications
  • Offers flexible consensus mechanisms and customizable smart contracts (chaincode)

Cons of Fabric

  • Steeper learning curve due to complex architecture and multiple components
  • Smaller developer community compared to Ethereum's ecosystem
  • Less decentralized, typically deployed in permissioned networks

Code Comparison

Fabric (Chaincode in Go):

func (s *SmartContract) CreateAsset(ctx contractapi.TransactionContextInterface, id string, value int) error {
    asset := Asset{ID: id, Value: value}
    assetJSON, err := json.Marshal(asset)
    if err != nil {
        return err
    }
    return ctx.GetStub().PutState(id, assetJSON)
}

go-ethereum (Solidity Smart Contract):

pragma solidity ^0.8.0;

contract SimpleStorage {
    uint256 private storedData;

    function set(uint256 x) public {
        storedData = x;
    }

    function get() public view returns (uint256) {
        return storedData;
    }
}

The code examples showcase the different approaches to smart contract development in Fabric (using chaincode) and Ethereum (using Solidity). Fabric's chaincode offers more flexibility in programming languages, while Ethereum's Solidity is purpose-built for smart contracts on the Ethereum blockchain.

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substrate

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Pros of Substrate

  • More flexible and customizable blockchain framework
  • Designed for easier upgrades and forkless runtime upgrades
  • Better suited for building application-specific blockchains

Cons of Substrate

  • Steeper learning curve due to its modular architecture
  • Smaller ecosystem and community compared to Ethereum
  • Less battle-tested in production environments

Code Comparison

go-ethereum (Geth):

func (s *Ethereum) Start() error {
    // Start the various components
    if err := s.startEthService(); err != nil {
        return err
    }
    return nil
}

Substrate:

impl<T: Config> Pallet<T> {
    pub fn do_something(origin: OriginFor<T>, something: u32) -> DispatchResult {
        let who = ensure_signed(origin)?;
        // Perform some action
        Ok(())
    }
}

The go-ethereum code shows a typical service start function in Go, while the Substrate code demonstrates a pallet implementation in Rust, highlighting the different approaches and languages used in these projects.

Substrate offers more flexibility for custom blockchain development, but requires a deeper understanding of its modular architecture. go-ethereum provides a more established ecosystem for Ethereum-compatible blockchains but may be less adaptable for specialized use cases.

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stellar-core

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Reference implementation for the peer-to-peer agent that manages the Stellar network.

Pros of stellar-core

  • Faster transaction processing and lower fees
  • More energy-efficient consensus mechanism (Stellar Consensus Protocol)
  • Simpler smart contract system, reducing potential vulnerabilities

Cons of stellar-core

  • Less flexible and feature-rich compared to Ethereum's Turing-complete smart contracts
  • Smaller developer ecosystem and fewer third-party tools
  • Limited support for complex decentralized applications (dApps)

Code Comparison

go-ethereum (Ethereum):

func (s *Ethereum) Start() error {
    // Start up the various services
    if err := s.startEthServices(); err != nil {
        return err
    }
    return nil
}

stellar-core (Stellar):

void
Application::start()
{
    CLOG_INFO(Ledger, "Starting stellar-core {}", STELLAR_CORE_VERSION);
    mStarted = true;
    generateLoad(mConfig.ARTIFICIALLY_GENERATE_LOAD_FOR_TESTING);
}

The code snippets show the start functions for both projects. go-ethereum uses Go and has a more modular approach, while stellar-core is written in C++ and has a more straightforward initialization process. Both handle starting their respective blockchain networks, but the implementation details differ due to their distinct architectures and design philosophies.

XRPLF logo

rippled

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Decentralized cryptocurrency blockchain daemon implementing the XRP Ledger protocol in C++

Pros of rippled

  • Faster transaction processing and lower fees
  • Built-in decentralized exchange functionality
  • More energy-efficient consensus mechanism (XRP Ledger Consensus Protocol)

Cons of rippled

  • Less widespread adoption and smaller developer community
  • Limited smart contract capabilities compared to Ethereum
  • Centralization concerns due to Ripple's influence on the network

Code Comparison

rippled (C++):

bool
shouldCloseLedger(
    bool anyTransactions,
    std::size_t prevProposers,
    std::size_t proposersClosed,
    std::size_t proposersValidated,
    std::chrono::milliseconds prevRoundTime,
    std::chrono::milliseconds timeSincePrevClose,
    std::chrono::milliseconds openTime,
    std::chrono::milliseconds idleInterval)
{
    // ... (implementation)
}

go-ethereum (Go):

func (w *worker) commitTransaction(tx *types.Transaction, coinbase common.Address) ([]*types.Log, error) {
    snap := w.current.state.Snapshot()

    receipt, err := core.ApplyTransaction(w.config, w.chain, &coinbase, w.current.gasPool, w.current.state, w.current.header, tx, &w.current.header.GasUsed, *w.chain.GetVMConfig())
    if err != nil {
        w.current.state.RevertToSnapshot(snap)
        return nil, err
    }
    w.current.txs = append(w.current.txs, tx)
    w.current.receipts = append(w.current.receipts, receipt)

    return receipt.Logs, nil
}

Both codebases are well-structured and follow best practices for their respective languages. The rippled codebase is primarily in C++, while go-ethereum is written in Go, reflecting different design philosophies and performance characteristics.

cosmos logo

cosmos-sdk

6,240

:chains: A Framework for Building High Value Public Blockchains :sparkles:

Pros of Cosmos SDK

  • Modular architecture allows for easier customization and development of blockchain applications
  • Supports interoperability between different blockchains through the Inter-Blockchain Communication (IBC) protocol
  • Faster transaction processing and higher throughput compared to Ethereum

Cons of Cosmos SDK

  • Smaller developer community and ecosystem compared to Ethereum
  • Less battle-tested in production environments
  • Limited support for complex smart contracts compared to Ethereum's Solidity

Code Comparison

Cosmos SDK (Go):

func (app *SimApp) InitChainer(ctx sdk.Context, req abci.RequestInitChain) abci.ResponseInitChain {
    var genesisState GenesisState
    if err := tmjson.Unmarshal(req.AppStateBytes, &genesisState); err != nil {
        panic(err)
    }
    return app.mm.InitGenesis(ctx, app.appCodec, genesisState)
}

Go-Ethereum (Go):

func (eth *Ethereum) Init(stack *node.Node) error {
    if err := eth.EthAPI.Start(stack); err != nil {
        return err
    }
    return nil
}

The Cosmos SDK code snippet shows the initialization of a blockchain application, while the Go-Ethereum code demonstrates the initialization of an Ethereum node. Cosmos SDK's modular approach is evident in its use of the InitGenesis function, which initializes multiple modules at once.

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README

Go Ethereum

Golang execution layer implementation of the Ethereum protocol.

API Reference Go Report Card Travis Discord

Automated builds are available for stable releases and the unstable master branch. Binary archives are published at https://geth.ethereum.org/downloads/.

Building the source

For prerequisites and detailed build instructions please read the Installation Instructions.

Building geth requires both a Go (version 1.22 or later) and a C compiler. You can install them using your favourite package manager. Once the dependencies are installed, run

make geth

or, to build the full suite of utilities:

make all

Executables

The go-ethereum project comes with several wrappers/executables found in the cmd directory.

CommandDescription
gethOur main Ethereum CLI client. It is the entry point into the Ethereum network (main-, test- or private net), capable of running as a full node (default), archive node (retaining all historical state) or a light node (retrieving data live). It can be used by other processes as a gateway into the Ethereum network via JSON RPC endpoints exposed on top of HTTP, WebSocket and/or IPC transports. geth --help and the CLI page for command line options.
clefStand-alone signing tool, which can be used as a backend signer for geth.
devp2pUtilities to interact with nodes on the networking layer, without running a full blockchain.
abigenSource code generator to convert Ethereum contract definitions into easy-to-use, compile-time type-safe Go packages. It operates on plain Ethereum contract ABIs with expanded functionality if the contract bytecode is also available. However, it also accepts Solidity source files, making development much more streamlined. Please see our Native DApps page for details.
bootnodeStripped down version of our Ethereum client implementation that only takes part in the network node discovery protocol, but does not run any of the higher level application protocols. It can be used as a lightweight bootstrap node to aid in finding peers in private networks.
evmDeveloper utility version of the EVM (Ethereum Virtual Machine) that is capable of running bytecode snippets within a configurable environment and execution mode. Its purpose is to allow isolated, fine-grained debugging of EVM opcodes (e.g. evm --code 60ff60ff --debug run).
rlpdumpDeveloper utility tool to convert binary RLP (Recursive Length Prefix) dumps (data encoding used by the Ethereum protocol both network as well as consensus wise) to user-friendlier hierarchical representation (e.g. rlpdump --hex CE0183FFFFFFC4C304050583616263).

Running geth

Going through all the possible command line flags is out of scope here (please consult our CLI Wiki page), but we've enumerated a few common parameter combos to get you up to speed quickly on how you can run your own geth instance.

Hardware Requirements

Minimum:

  • CPU with 2+ cores
  • 4GB RAM
  • 1TB free storage space to sync the Mainnet
  • 8 MBit/sec download Internet service

Recommended:

  • Fast CPU with 4+ cores
  • 16GB+ RAM
  • High-performance SSD with at least 1TB of free space
  • 25+ MBit/sec download Internet service

Full node on the main Ethereum network

By far the most common scenario is people wanting to simply interact with the Ethereum network: create accounts; transfer funds; deploy and interact with contracts. For this particular use case, the user doesn't care about years-old historical data, so we can sync quickly to the current state of the network. To do so:

$ geth console

This command will:

  • Start geth in snap sync mode (default, can be changed with the --syncmode flag), causing it to download more data in exchange for avoiding processing the entire history of the Ethereum network, which is very CPU intensive.
  • Start the built-in interactive JavaScript console, (via the trailing console subcommand) through which you can interact using web3 methods (note: the web3 version bundled within geth is very old, and not up to date with official docs), as well as geth's own management APIs. This tool is optional and if you leave it out you can always attach it to an already running geth instance with geth attach.

A Full node on the Holesky test network

Transitioning towards developers, if you'd like to play around with creating Ethereum contracts, you almost certainly would like to do that without any real money involved until you get the hang of the entire system. In other words, instead of attaching to the main network, you want to join the test network with your node, which is fully equivalent to the main network, but with play-Ether only.

$ geth --holesky console

The console subcommand has the same meaning as above and is equally useful on the testnet too.

Specifying the --holesky flag, however, will reconfigure your geth instance a bit:

  • Instead of connecting to the main Ethereum network, the client will connect to the Holesky test network, which uses different P2P bootnodes, different network IDs and genesis states.
  • Instead of using the default data directory (~/.ethereum on Linux for example), geth will nest itself one level deeper into a holesky subfolder (~/.ethereum/holesky on Linux). Note, on OSX and Linux this also means that attaching to a running testnet node requires the use of a custom endpoint since geth attach will try to attach to a production node endpoint by default, e.g., geth attach <datadir>/holesky/geth.ipc. Windows users are not affected by this.

Note: Although some internal protective measures prevent transactions from crossing over between the main network and test network, you should always use separate accounts for play and real money. Unless you manually move accounts, geth will by default correctly separate the two networks and will not make any accounts available between them.

Configuration

As an alternative to passing the numerous flags to the geth binary, you can also pass a configuration file via:

$ geth --config /path/to/your_config.toml

To get an idea of how the file should look like you can use the dumpconfig subcommand to export your existing configuration:

$ geth --your-favourite-flags dumpconfig

Note: This works only with geth v1.6.0 and above.

Docker quick start

One of the quickest ways to get Ethereum up and running on your machine is by using Docker:

docker run -d --name ethereum-node -v /Users/alice/ethereum:/root \
           -p 8545:8545 -p 30303:30303 \
           ethereum/client-go

This will start geth in snap-sync mode with a DB memory allowance of 1GB, as the above command does. It will also create a persistent volume in your home directory for saving your blockchain as well as map the default ports. There is also an alpine tag available for a slim version of the image.

Do not forget --http.addr 0.0.0.0, if you want to access RPC from other containers and/or hosts. By default, geth binds to the local interface and RPC endpoints are not accessible from the outside.

Programmatically interfacing geth nodes

As a developer, sooner rather than later you'll want to start interacting with geth and the Ethereum network via your own programs and not manually through the console. To aid this, geth has built-in support for a JSON-RPC based APIs (standard APIs and geth specific APIs). These can be exposed via HTTP, WebSockets and IPC (UNIX sockets on UNIX based platforms, and named pipes on Windows).

The IPC interface is enabled by default and exposes all the APIs supported by geth, whereas the HTTP and WS interfaces need to manually be enabled and only expose a subset of APIs due to security reasons. These can be turned on/off and configured as you'd expect.

HTTP based JSON-RPC API options:

  • --http Enable the HTTP-RPC server
  • --http.addr HTTP-RPC server listening interface (default: localhost)
  • --http.port HTTP-RPC server listening port (default: 8545)
  • --http.api API's offered over the HTTP-RPC interface (default: eth,net,web3)
  • --http.corsdomain Comma separated list of domains from which to accept cross origin requests (browser enforced)
  • --ws Enable the WS-RPC server
  • --ws.addr WS-RPC server listening interface (default: localhost)
  • --ws.port WS-RPC server listening port (default: 8546)
  • --ws.api API's offered over the WS-RPC interface (default: eth,net,web3)
  • --ws.origins Origins from which to accept WebSocket requests
  • --ipcdisable Disable the IPC-RPC server
  • --ipcapi API's offered over the IPC-RPC interface (default: admin,debug,eth,miner,net,personal,txpool,web3)
  • --ipcpath Filename for IPC socket/pipe within the datadir (explicit paths escape it)

You'll need to use your own programming environments' capabilities (libraries, tools, etc) to connect via HTTP, WS or IPC to a geth node configured with the above flags and you'll need to speak JSON-RPC on all transports. You can reuse the same connection for multiple requests!

Note: Please understand the security implications of opening up an HTTP/WS based transport before doing so! Hackers on the internet are actively trying to subvert Ethereum nodes with exposed APIs! Further, all browser tabs can access locally running web servers, so malicious web pages could try to subvert locally available APIs!

Operating a private network

Maintaining your own private network is more involved as a lot of configurations taken for granted in the official networks need to be manually set up.

Defining the private genesis state

First, you'll need to create the genesis state of your networks, which all nodes need to be aware of and agree upon. This consists of a small JSON file (e.g. call it genesis.json):

{
  "config": {
    "chainId": <arbitrary positive integer>,
    "homesteadBlock": 0,
    "eip150Block": 0,
    "eip155Block": 0,
    "eip158Block": 0,
    "byzantiumBlock": 0,
    "constantinopleBlock": 0,
    "petersburgBlock": 0,
    "istanbulBlock": 0,
    "berlinBlock": 0,
    "londonBlock": 0
  },
  "alloc": {},
  "coinbase": "0x0000000000000000000000000000000000000000",
  "difficulty": "0x20000",
  "extraData": "",
  "gasLimit": "0x2fefd8",
  "nonce": "0x0000000000000042",
  "mixhash": "0x0000000000000000000000000000000000000000000000000000000000000000",
  "parentHash": "0x0000000000000000000000000000000000000000000000000000000000000000",
  "timestamp": "0x00"
}

The above fields should be fine for most purposes, although we'd recommend changing the nonce to some random value so you prevent unknown remote nodes from being able to connect to you. If you'd like to pre-fund some accounts for easier testing, create the accounts and populate the alloc field with their addresses.

"alloc": {
  "0x0000000000000000000000000000000000000001": {
    "balance": "111111111"
  },
  "0x0000000000000000000000000000000000000002": {
    "balance": "222222222"
  }
}

With the genesis state defined in the above JSON file, you'll need to initialize every geth node with it prior to starting it up to ensure all blockchain parameters are correctly set:

$ geth init path/to/genesis.json

Creating the rendezvous point

With all nodes that you want to run initialized to the desired genesis state, you'll need to start a bootstrap node that others can use to find each other in your network and/or over the internet. The clean way is to configure and run a dedicated bootnode:

$ bootnode --genkey=boot.key
$ bootnode --nodekey=boot.key

With the bootnode online, it will display an enode URL that other nodes can use to connect to it and exchange peer information. Make sure to replace the displayed IP address information (most probably [::]) with your externally accessible IP to get the actual enode URL.

Note: You could also use a full-fledged geth node as a bootnode, but it's the less recommended way.

Starting up your member nodes

With the bootnode operational and externally reachable (you can try telnet <ip> <port> to ensure it's indeed reachable), start every subsequent geth node pointed to the bootnode for peer discovery via the --bootnodes flag. It will probably also be desirable to keep the data directory of your private network separated, so do also specify a custom --datadir flag.

$ geth --datadir=path/to/custom/data/folder --bootnodes=<bootnode-enode-url-from-above>

Note: Since your network will be completely cut off from the main and test networks, you'll also need to configure a miner to process transactions and create new blocks for you.

Running a private miner

In a private network setting a single CPU miner instance is more than enough for practical purposes as it can produce a stable stream of blocks at the correct intervals without needing heavy resources (consider running on a single thread, no need for multiple ones either). To start a geth instance for mining, run it with all your usual flags, extended by:

$ geth <usual-flags> --mine --miner.threads=1 --miner.etherbase=0x0000000000000000000000000000000000000000

Which will start mining blocks and transactions on a single CPU thread, crediting all proceedings to the account specified by --miner.etherbase. You can further tune the mining by changing the default gas limit blocks converge to (--miner.targetgaslimit) and the price transactions are accepted at (--miner.gasprice).

Contribution

Thank you for considering helping out with the source code! We welcome contributions from anyone on the internet, and are grateful for even the smallest of fixes!

If you'd like to contribute to go-ethereum, please fork, fix, commit and send a pull request for the maintainers to review and merge into the main code base. If you wish to submit more complex changes though, please check up with the core devs first on our Discord Server to ensure those changes are in line with the general philosophy of the project and/or get some early feedback which can make both your efforts much lighter as well as our review and merge procedures quick and simple.

Please make sure your contributions adhere to our coding guidelines:

  • Code must adhere to the official Go formatting guidelines (i.e. uses gofmt).
  • Code must be documented adhering to the official Go commentary guidelines.
  • Pull requests need to be based on and opened against the master branch.
  • Commit messages should be prefixed with the package(s) they modify.
    • E.g. "eth, rpc: make trace configs optional"

Please see the Developers' Guide for more details on configuring your environment, managing project dependencies, and testing procedures.

Contributing to geth.ethereum.org

For contributions to the go-ethereum website, please checkout and raise pull requests against the website branch. For more detailed instructions please see the website branch README or the contributing page of the website.

License

The go-ethereum library (i.e. all code outside of the cmd directory) is licensed under the GNU Lesser General Public License v3.0, also included in our repository in the COPYING.LESSER file.

The go-ethereum binaries (i.e. all code inside of the cmd directory) are licensed under the GNU General Public License v3.0, also included in our repository in the COPYING file.