Erigon is an implementation of Ethereum (aka "Ethereum client"), on the efficiency frontier, written in Go.
NB! In-depth links are marked by the microscope sign (π¬)
Disclaimer: this software is currently a tech preview. We will do our best to keep it stable and make no breaking changes but we don't guarantee anything. Things can and will break.
Recommend 2Tb storage space on a single partition: 1.6Tb state, 200GB temp files (can symlink or mount
folder <datadir>/etl-tmp
to another disk).
RAM: 16GB, 64-bit architecture, Golang version >= 1.16, GCC 10+
π¬ more info on disk storage is here)
git clone --recurse-submodules -j8 https://github.com/ledgerwatch/erigon.git
cd erigon
make erigon
./build/bin/erigon
If you would like to give Erigon a try, but do not have spare 2Tb on your driver, a good option is to start syncing one of the public testnets, GΓΆrli. It syncs much quicker, and does not take so much disk space:
git clone --recurse-submodules -j8 https://github.com/ledgerwatch/erigon.git
cd erigon
make erigon
./build/bin/erigon --datadir goerli --chain goerli
Please note the --datadir
option that allows you to store Erigon files in a non-default location, in this example,
in goerli
subdirectory of the current directory. Name of the directory --datadir
does not have to match the name of
the chain in --chain
.
Support only remote-miners.
- To enable, add
--mine --miner.etherbase=...
or--mine --miner.miner.sigkey=...
flags. - Other supported options:
--miner.extradata
,--miner.notify
,--miner.gaslimit
,--miner.gasprice
,--miner.gastarget
- RPCDaemon supports methods: eth_coinbase , eth_hashrate, eth_mining, eth_getWork, eth_submitWork, eth_submitHashrate
- RPCDaemon supports websocket methods: newPendingTransaction
- TODO:
- we don't broadcast mined blocks to p2p-network yet, but it's easy to accomplish
- eth_newPendingTransactionFilter
- eth_newBlockFilter
- eth_newFilter
- websocket Logs
π¬ Detailed mining explanation is here.
Windows users may run erigon in 3 possible ways:
-
Build executable binaries natively for Windows using provided
wmake.ps1
PowerShell script. Usage syntax is the same asmake
command so you have to run.\wmake.ps1 [-target] <targetname>
. Example:.\wmake.ps1 erigon
builds erigon executable. All binaries are placed in.\build\bin\
subfolder. There are some requirements for a successful native build on windows :- Git for Windows must be installed. If you're cloning this repository is very likely you already have it
- GO Programming Language must be installed. Minimum required version is 1.16
- GNU CC Compiler at least version 10 (is highly suggested that you install
chocolatey
package manager - see following point) - If you need to build MDBX tools (i.e.
.\wmake.ps1 db-tools
) then Chocolatey package manager for Windows must be installed. By Chocolatey you need to install the following components :cmake
,make
,mingw
bychoco install cmake make mingw
.
Important note about Anti-Viruses During MinGW's compiler detection phase some temporary executables are generated to test compiler capabilities. It's been reported some anti-virus programs detect those files as possibly infected by
Win64/Kryptic.CIS
trojan horse (or a variant of it). Although those are false positives we have no control over 100+ vendors of security products for Windows and their respective detection algorythms and we understand this might make your experience with Windows builds uncomfortable. To workaround the issue you might either set exlusions for your antivirus specifically forbuild\bin\mdbx\CMakeFiles
sub-folder of the cloned repo or you can run erigon using the following other two options -
Use Docker : see docker-compose.yml
-
Use WSL (Windows Subsystem for Linux) strictly on version 2. Under this option you can build Erigon just as you would on a regular Linux distribution. You can point your data also to any of the mounted Windows partitions ( eg.
/mnt/c/[...]
,/mnt/d/[...]
etc) but in such case be advised performance is impacted: this is due to the fact those mount points useDrvFS
which is a network file system and, additionally, MDBX locks the db for exclusive access which implies only one process at a time can access data. This has consequences on the running ofrpcdaemon
which has to be configured as Remote DB even if it is executed on the very same computer. If instead your data is hosted on the native Linux filesystem non limitations apply. Please also note the default WSL2 environment has its own IP address which does not match the one of the network interface of Windows host: take this into account when configuring NAT for port 30303 on your router.
Erigon can be used as an execution-layer for beacon chain consensus clients (Eth2). Default configuration is ok. Eth2
relies on availability of receipts - don't prune them: don't add character r
to --prune
flag. However, old receipes are not needed for Eth2 and you can safely prune them with --prune.r.before=11184524
in combination with --prune htc
.
You must run the JSON-RPC daemon in addition to the Erigon.
If beacon chain client on a different device: add --http.addr 0.0.0.0
(JSON-RPC daemon listen on localhost by default)
.
Once the JSON-RPC daemon is running, all you need to do is point your beacon chain client to <ip address>:8545
,
where is either localhost or the IP address of the device running the JSON-RPC daemon.
Erigon has been tested with Lighthouse however all other clients that support JSON-RPC should also work.
π¬ Detailed explanation is DEV_CHAIN.
π¬ See more
detailed overview of functionality and current limitations. It
is being updated on recurring basis.
Flat KV storage. Erigon uses a key-value database and storing accounts and storage in a simple way.
π¬ See our detailed DB walkthrough here.
Preprocessing. For some operations, Erigon uses temporary files to preprocess data before inserting it into the main DB. That reduces write amplification and DB inserts are orders of magnitude quicker.
π¬ See our detailed ETL explanation here.
Plain state.
Single accounts/state trie. Erigon uses a single Merkle trie for both accounts and the storage.
Erigon uses a rearchitected full sync algorithm from Go-Ethereum that is split into "stages".
π¬ See more detailed explanation in the Staged Sync Readme
It uses the same network primitives and is compatible with regular go-ethereum nodes that are using full sync, you do not need any special sync capabilities for Erigon to sync.
When reimagining the full sync, with focus on batching data together and minimize DB overwrites. That makes it possible to sync Ethereum mainnet in under 2 days if you have a fast enough network connection and an SSD drive.
Examples of stages are:
-
Downloading headers;
-
Downloading block bodies;
-
Recovering senders' addresses;
-
Executing blocks;
-
Validating root hashes and building intermediate hashes for the state Merkle trie;
-
[...]
In Erigon RPC calls are extracted out of the main binary into a separate daemon. This daemon can use both local or remote DBs. That means, that this RPC daemon doesn't have to be running on the same machine as the main Erigon binary or it can run from a snapshot of a database for read-only calls.
π¬ See RPC-Daemon docs
This is only possible if RPC daemon runs on the same computer as Erigon. This mode uses shared memory access to the
database of Erigon, which has better performance than accessing via TPC socket (see "For remote DB" section below).
Provide both --datadir
and --private.api.addr
options:
make erigon
./build/bin/erigon --private.api.addr=localhost:9090
make rpcdaemon
./build/bin/rpcdaemon --datadir=<your_data_dir> --private.api.addr=localhost:9090 --http.api=eth,erigon,web3,net,debug,trace,txpool
This works regardless of whether RPC daemon is on the same computer with Erigon, or on a different one. They use TPC socket connection to pass data between them. To use this mode, run Erigon in one terminal window
make erigon
./build/bin/erigon --private.api.addr=localhost:9090
make rpcdaemon
./build/bin/rpcdaemon --private.api.addr=localhost:9090 --http.api=eth,erigon,web3,net,debug,trace,txpool
gRPC ports: 9090
erigon, 9091
sentry, 9092
consensus engine, 9093
snapshot downloader, 9094
TxPool
Supported JSON-RPC calls (eth, debug , net, web3):
For a details on the implementation status of each command, see this table.
Next command starts: Erigon on port 30303, rpcdaemon 8545, prometheus 9090, grafana 3000
make docker-compose
# or
XDG_DATA_HOME=/preferred/data/folder make docker-compose
Makefile creates the initial directories for erigon, prometheus and grafana. The PID namespace is shared between erigon and rpcdaemon which is required to open Erigon's DB from another process (RPCDaemon local-mode). See: https://github.com/ledgerwatch/erigon/pull/2392/files
Windows support for docker-compose is not ready yet. Please help us with .ps1 port
docker-compose up prometheus grafana
, detailed docs.
Disabled by default. To enable see ./build/bin/erigon --help
for flags --prune
- Baseline (ext4 SSD): 16Gb RAM sync takes 6 days, 32Gb - 5 days, 64Gb - 4 days
- +1 day on "zfs compression=off". +2 days on "zfs compression=on" (2x compression ratio). +3 days on btrfs.
- -1 day on NVMe
Detailed explanation: ./docs/programmers_guide/db_faq.md
Port | Protocol | Purpose | Expose |
---|---|---|---|
30303 | TCP & UDP | eth/66 peering | Public |
9090 | TCP | gRPC Connections | Private |
Typically 30303 and 30304 are exposed to the internet to allow incoming peering connections. 9090 is exposed only internally for rpcdaemon or other connections, (e.g. rpcdaemon -> erigon)
Port | Protocol | Purpose | Expose |
---|---|---|---|
8545 | TCP | HTTP & WebSockets | Private |
Typically 8545 is exposed only interally for JSON-RPC queries. Both HTTP and WebSocket connections are on the same port.
Port | Protocol | Purpose | Expose |
---|---|---|---|
30303 | TCP & UDP | Peering | Public |
9091 | TCP | gRPC Connections | Private |
Typically a sentry process will run one eth/xx protocl (e.g. eth/66) and will be exposed to the internet on 30303. Port 9091 is for internal gRCP connections (e.g erigon -> sentry)
Port | Protocol | Purpose | Expose |
---|---|---|---|
6060 | TCP | pprof | Private |
6060 | TCP | metrics | Private |
Optional flags can be enabled that enable pprof or metrics (or both) - however, they both run on 6060 by default, so
you'll have to change one if you want to run both at the same time. use --help
with the binary for more info.
Reserved for future use: gRPC ports: 9092
consensus engine, 9093
snapshot downloader, 9094
TxPool
- Get stack trace:
kill -SIGUSR1 <pid>
, get trace and stop:kill -6 <pid>
- Get CPU profiling: add
--pprof flag
rungo tool pprof -png http://127.0.0.1:6060/debug/pprof/profile\?seconds\=20 > cpu.png
- Get RAM profiling: add
--pprof flag
rungo tool pprof -inuse_space -png http://127.0.0.1:6060/debug/pprof/heap > mem.png
π¬ Detailed explanation is here.
The main discussions are happening on our Discord server. To get an invite, send an email to tg [at] torquem.ch
with
your name, occupation, a brief explanation of why you want to join the Discord, and how you heard about Erigon.
Send an email to security [at] torquem.ch
.
Core contributors (in alpabetical order of first names):
-
Alex Sharov (AskAlexSharov)
-
Alexey Akhunov (@realLedgerwatch)
-
Andrea Lanfranchi(@AndreaLanfranchi)
-
Andrew Ashikhmin (yperbasis)
-
Artem Vorotnikov (vorot93)
-
Boris Petrov (b00ris)
-
Eugene Danilenko (JekaMas)
-
Igor Mandrigin (@mandrigin)
-
Giulio Rebuffo (Giulio2002)
-
Thomas Jay Rush (@tjayrush)
Thanks to:
-
All contributors of Erigon
-
All contributors of Go-Ethereum
-
Our special respect and graditude is to the core team of Go-Ethereum. Keep up the great job!
Happy testing! π₯€
Erigon's internal DB (MDBX) using MemoryMap
- when OS does manage all read, write, cache
operations instead of
Application
(linux
, windows)
htop
on column res
shows memory of "App + OS used to hold page cache for given App", but it's not informative,
because if htop
says that app using 90% of memory you still can run 3 more instances of app on the same machine -
because most of that 90%
is "OS pages cache".
OS automatically free this cache any time it needs memory. Smaller "page cache size" may not impact performance of
Erigon at all.
Next tools show correct memory usage of Erigon:
vmmap -summary PID | grep -i "Physical footprint"
. Withoutgrep
you can see detailssection MALLOC ZONE column Resident Size
shows App memory usage,section REGION TYPE column Resident Size
shows OS pages cache size.
Prometheus
dashboard shows memory of Go app without OS pages cache (make prometheus
, open in browserlocalhost:3000
, credentialsadmin/admin
)cat /proc/<PID>/smaps
Erigon uses ~4Gb of RAM during genesis sync and ~1Gb during normal work. OS pages cache can utilize unlimited amount of memory.
Warning: Multiple instances of Erigon on same machine will touch Disk concurrently, it impacts performance - one of main Erigon optimisations: "reduce Disk random access". "Blocks Execution stage" still does much random reads - this is reason why it's slowest stage. We do not recommend run multiple genesis syncs on same Disk. If genesis sync passed, then it's fine to run multiple Erigon on same Disk.
Please read erigontech/erigon#1516 (comment) In short: network-disks are bad for blocks execution - because blocks execution reading data from db non-parallel non-batched way.
For example: btrfs's autodefrag option - may increase write IO 100x times
Gnome Tracker - detecting miners and kill them.