ethereum

README

Erigon

Documentation: erigon.gitbook.io Blog: erigon.substack.com Twitter: x.com/ErigonEth

Erigon is an implementation of Ethereum (execution layer with embeddable consensus layer), on the efficiency frontier. Archive Node by default.

• Erigon
• System Requirements
• Usage
  • Getting Started
  • Datadir structure
  • History on cheap disk
  • Erigon3 datadir size
  • Erigon3 changes from Erigon2
  • Logging
  • Modularity
  • Embedded Consensus Layer
  • Testnets
  • Block Production (PoS Validator)
  • Config Files TOML
  • Beacon Chain (Consensus Layer)
  • Caplin
    • Caplin's Usage
  • Multiple Instances / One Machine
  • Dev Chain
• Key features
  • Faster Initial Sync
  • More Efficient State Storage
  • JSON-RPC daemon
  • Grafana dashboard
• FAQ
  • How much RAM do I need
  • Default Ports and Firewalls
    • erigon ports
    • caplin ports
    • beaconAPI ports
    • shared ports
    • other ports
    • Hetzner expecting strict firewall rules
  • Run as a separate user - systemd example
  • How to get diagnostic for bug report?
  • How to run local devnet?
  • Docker permissions error
  • How to run public RPC api
  • RaspberyPI
  • Run all components by docker-compose
    • Optional: Setup dedicated user
    • Environment Variables
    • Run
  • How to change db pagesize
  • Erigon3 perf tricks
  • Windows
• Getting in touch
  • Erigon Discord Server
  • Blog
  • Twitter
  • Reporting security issues/concerns
• Known issues
  • htop shows incorrect memory usage
  • Cloud network drives
  • Filesystem's background features are expensive
  • Gnome Tracker can kill Erigon
  • the --mount option requires BuildKit error

Important defaults: Erigon is an Archive Node by default: use --prune.mode if need make it smaller (not allowed to change after first start)

In-depth links are marked by the microscope sign (🔬)

System Requirements

RAM: >=32GB, Golang >= 1.22; GCC 10+ or Clang; On Linux: kernel > v4. 64-bit architecture.

• ArchiveNode Ethereum Mainnet: 2TB (April 2024). FullNode: 1.1TB (June 2024)
• ArchiveNode Gnosis: 1.7TB (March 2024). FullNode: 300GB (June 2024)
• ArchiveNode Polygon Mainnet: 4.1TB (April 2024). FullNode: 2Tb (April 2024)

SSD or NVMe. Do not recommend HDD - on HDD Erigon will always stay N blocks behind chain tip, but not fall behind. Bear in mind that SSD performance deteriorates when close to capacity. CloudDrives (like gp3): Blocks Execution is slow on cloud-network-drives

🔬 More details on Erigon3 datadir size

🔬 More details on what type of data stored here

Usage

Getting Started

Release Notes and Binaries

Build latest release (this will be suitable for most users just wanting to run a node):

git clone --branch release/<x.xx> --single-branch https://github.com/erigontech/erigon.git
cd erigon
make erigon
./build/bin/erigon

Increase download speed by --torrent.download.rate=20mb. 🔬 See Downloader docs

Use --datadir to choose where to store data.

Use --chain=gnosis for Gnosis Chain, --chain=bor-mainnet for Polygon Mainnet, and --chain=amoy for Polygon Amoy. For Gnosis Chain you need a Consensus Layer client alongside Erigon (https://docs.gnosischain.com/category/step--3---run-consensus-client).

Running make help will list and describe the convenience commands available in the Makefile.

Datadir structure

datadir        
    chaindata     # "Recently-updated Latest State", "Recent History", "Recent Blocks"
    snapshots     # contains `.seg` files - it's old blocks
        domain    # Latest State
        history   # Historical values 
        idx       # InvertedIndices: can search/filtering/union/intersect them - to find historical data. like eth_getLogs or trace_transaction
        accessors # Additional (generated) indices of history - have "random-touch" read-pattern. They can serve only `Get` requests (no search/filters).
    txpool        # pending transactions. safe to remove.
    nodes         # p2p peers. safe to remove.
    temp          # used to sort data bigger than RAM. can grow to ~100gb. cleaned at startup.
   
# There is 4 domains: account, storage, code, commitment 

History on cheap disk

If you can afford store datadir on 1 nvme-raid - great. If can't - it's possible to store history on cheap drive.

# place (or ln -s) `datadir` on slow disk. link some sub-folders to fast (low-latency) disk.
# Example: what need link to fast disk to speedup execution
datadir        
    chaindata   # link to fast disk
    snapshots   
        domain    # link to fast disk
        history   
        idx       
        accessors 
    temp # buffers to sort data >> RAM. sequential-buffered IO - is slow-disk-friendly   

# Example: how to speedup history access: 
#   - go step-by-step - first try store `accessors` on fast disk
#   - if speed is not good enough: `idx`
#   - if still not enough: `history` 

Erigon3 datadir size

# eth-mainnet - archive - April 2024

du -hsc /erigon/* 
6G  	/erigon/caplin
50G 	/erigon/chaindata
1.8T	/erigon/snapshots
1.9T	total

du -hsc /erigon/snapshots/* 
100G 	/erigon/snapshots/accessor
240G	/erigon/snapshots/domain
260G	/erigon/snapshots/history
410G	/erigon/snapshots/idx
1.7T	/erigon/snapshots

# bor-mainnet - archive - Jun 2024

du -hsc /erigon/* 

160M	/erigon/bor
50G 	/erigon/chaindata
3.7T	/erigon/snapshots
3.8T	total

du -hsc /erigon/snapshots/* 
260G	/erigon-data/snapshots/accessor
850G	/erigon-data/snapshots/domain
650G	/erigon-data/snapshots/history
1.4T	/erigon-data/snapshots/idx
4.1T	/erigon/snapshots

Erigon3 changes from Erigon2

• Sync from scratch doesn't require re-exec all history. Latest state and it's history are in snapshots - can download.
• ExecutionStage - now including many E2 stages: stage_hash_state, stage_trie, stage_log_index, stage_history_index, stage_trace_index
• E3 can execute 1 historical transaction - without executing it's block - because history/indices have transaction-granularity, instead of block-granularity.
• E3 doesn't store Logs (aka Receipts) - it always re-executing historical txn (but it's cheaper then in E2 - see point above).
• --sync.loop.block.limit is enabled by default. (Default: 5_000. Set --sync.loop.block.limit=10_000 --batchSize=2g to increase sync speed on good hardware).
• datadir/chaindata is small now - to prevent it's grow: we recommend set --batchSize <= 2G. And it's fine to rm -rf chaindata
• can symlink/mount latest state to fast drive and history to cheap drive
• Archive Node is default. Full Node: --prune.mode=full, Minimal Node (EIP-4444): --prune.mode=minimal

Logging

Flags:

• verbosity
• log.console.verbosity (overriding alias for verbosity)
• log.json
• log.console.json (alias for log.json)
• log.dir.path
• log.dir.prefix
• log.dir.verbosity
• log.dir.json

In order to log only to the stdout/stderr the --verbosity (or log.console.verbosity) flag can be used to supply an int value specifying the highest output log level:

  LvlCrit = 0
  LvlError = 1
  LvlWarn = 2
  LvlInfo = 3
  LvlDebug = 4
  LvlTrace = 5

To set an output dir for logs to be collected on disk, please set --log.dir.path If you want to change the filename produced from erigon you should also set the --log.dir.prefix flag to an alternate name. The flag --log.dir.verbosity is also available to control the verbosity of this logging, with the same int value as above, or the string value e.g. ' debug' or 'info'. Default verbosity is 'debug' (4), for disk logging.

Log format can be set to json by the use of the boolean flags log.json or log.console.json, or for the disk output --log.dir.json.

Modularity

Erigon by default is "all in one binary" solution, but it's possible start TxPool as separated processes. Same true about: JSON RPC layer (RPCDaemon), p2p layer (Sentry), history download layer (Downloader), consensus. Don't start services as separated processes unless you have clear reason for it: resource limiting, scale, replace by your own implementation, security. How to start Erigon's services as separated processes, see in docker-compose.yml. Each service has own ./cmd/*/README.md file. Erigon Blog.

Embedded Consensus Layer

Built-in consensus for Ethereum Mainnet, Sepolia, Holesky, Gnosis. To use external Consensus Layer: --externalcl.

Testnets

If you would like to give Erigon a try: a good option is to start syncing one of the public testnets, Holesky (or Amoy). It syncs much quicker, and does not take so much disk space:

git clone https://github.com/erigontech/erigon.git
cd erigon
make erigon
./build/bin/erigon --datadir=<your_datadir> --chain=holesky --prune.mode=full

Please note the --datadir option that allows you to store Erigon files in a non-default location. Name of the directory --datadir does not have to match the name of the chain in --chain.

Block Production (PoS Validator)

Block production is fully supported for Ethereum & Gnosis Chain. It is still experimental for Polygon.

Config Files TOML

You can set Erigon flags through a TOML configuration file with the flag --config. The flags set in the configuration file can be overwritten by writing the flags directly on Erigon command line

./build/bin/erigon --config ./config.toml --chain=sepolia

Assuming we have chain : "mainnet" in our configuration file, by adding --chain=sepolia allows the overwrite of the flag inside of the toml configuration file and sets the chain to sepolia

datadir = 'your datadir'
port = 1111
chain = "mainnet"
http = true
"private.api.addr"="localhost:9090"

"http.api" = ["eth","debug","net"]

Beacon Chain (Consensus Layer)

Erigon can be used as an Execution Layer (EL) for Consensus Layer clients (CL). Default configuration is OK.

If your CL client is on a different device, add --authrpc.addr 0.0.0.0 (Engine API listens on localhost by default) as well as --authrpc.vhosts <CL host> where <CL host> is your source host or any.

In order to establish a secure connection between the Consensus Layer and the Execution Layer, a JWT secret key is automatically generated.

The JWT secret key will be present in the datadir by default under the name of jwt.hex and its path can be specified with the flag --authrpc.jwtsecret.

This piece of info needs to be specified in the Consensus Layer as well in order to establish connection successfully. More information can be found here.

Once Erigon is running, you need to point your CL client to <erigon address>:8551, where <erigon address> is either localhost or the IP address of the device running Erigon, and also point to the JWT secret path created by Erigon.

Caplin

Caplin is a full-fledged validating Consensus Client like Prysm, Lighthouse, Teku, Nimbus and Lodestar. Its goal is:

• provide better stability
• Validation of the chain
• Stay in sync
• keep the execution of blocks on chain tip
• serve the Beacon API using a fast and compact data model alongside low CPU and memory usage.

The main reason why developed a new Consensus Layer is to experiment with the possible benefits that could come with it. For example, The Engine API does not work well with Erigon. The Engine API sends data one block at a time, which does not suit how Erigon works. Erigon is designed to handle many blocks simultaneously and needs to sort and process data efficiently. Therefore, it would be better for Erigon to handle the blocks independently instead of relying on the Engine API.

Caplin's Usage

Caplin is be enabled by default. to disable it and enable the Engine API, use the --externalcl flag. from that point on, an external Consensus Layer will not be need anymore.

Caplin also has an archivial mode for historical states and blocks. it can be enabled through the --caplin.archive flag. In order to enable the caplin's Beacon API, the flag --beacon.api=<namespaces> must be added. e.g: --beacon.api=beacon,builder,config,debug,node,validator,lighthouse will enable all endpoints. **NOTE: Caplin is not staking-ready so aggregation endpoints are still to be implemented. Additionally enabling the Beacon API will lead to a 6 GB higher RAM usage.

Multiple Instances / One Machine

Define 6 flags to avoid conflicts: --datadir --port --http.port --authrpc.port --torrent.port --private.api.addr. Example of multiple chains on the same machine:

# mainnet
./build/bin/erigon --datadir="<your_mainnet_data_path>" --chain=mainnet --port=30303 --http.port=8545 --authrpc.port=8551 --torrent.port=42069 --private.api.addr=127.0.0.1:9090 --http --ws --http.api=eth,debug,net,trace,web3,erigon


# sepolia
./build/bin/erigon --datadir="<your_sepolia_data_path>" --chain=sepolia --port=30304 --http.port=8546 --authrpc.port=8552 --torrent.port=42068 --private.api.addr=127.0.0.1:9091 --http --ws --http.api=eth,debug,net,trace,web3,erigon

Quote your path if it has spaces.

Dev Chain

🔬 Detailed explanation is DEV_CHAIN.

Key features

Faster Initial Sync

On good network bandwidth EthereumMainnet FullNode syncs in 3 hours: OtterSync can sync

More Efficient State Storage

Flat KV storage. Erigon uses a key-value database and storing accounts and storage in a simple way.

🔬 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.

🔬 See our detailed ETL explanation here.

Plain state

Single accounts/state trie. Erigon uses a single Merkle trie for both accounts and the storage.

🔬 Staged Sync Readme

JSON-RPC daemon

Most of Erigon's components (txpool, rpcdaemon, snapshots downloader, sentry, ...) can work inside Erigon and as independent process on same Server (or another Server). Example

make erigon rpcdaemon
./build/bin/erigon --datadir=/my --http=false
# To run RPCDaemon as separated process: use same `--datadir` as Erigon
./build/bin/rpcdaemon --datadir=/my --http.api=eth,erigon,web3,net,debug,trace,txpool --ws

Supported JSON-RPC calls (eth, debug , net, web3):

🔬 See RPC-Daemon docs

Grafana dashboard

docker compose up prometheus grafana, detailed docs.

FAQ

How much RAM do I need

• 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

Default Ports and Firewalls

erigon ports

Component	Port	Protocol	Purpose	Should Expose
engine	9090	TCP	gRPC Server	Private
engine	42069	TCP & UDP	Snap sync (Bittorrent)	Public
engine	8551	TCP	Engine API (JWT auth)	Private
sentry	30303	TCP & UDP	eth/68 peering	Public
sentry	30304	TCP & UDP	eth/67 peering	Public
sentry	9091	TCP	incoming gRPC Connections	Private
rpcdaemon	8545	TCP	HTTP & WebSockets & GraphQL	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 8551 (JWT authenticated) is exposed only internally for Engine API JSON-RPC queries from the Consensus Layer node.

caplin ports

Component	Port	Protocol	Purpose	Should Expose
sentinel	4000	UDP	Peering	Public
sentinel	4001	TCP	Peering	Public

In order to configure the ports, use:

   --caplin.discovery.addr value                                                    Address for Caplin DISCV5 protocol (default: "127.0.0.1")
   --caplin.discovery.port value                                                    Port for Caplin DISCV5 protocol (default: 4000)
   --caplin.discovery.tcpport value                                                 TCP Port for Caplin DISCV5 protocol (default: 4001)

beaconAPI ports

Component	Port	Protocol	Purpose	Should Expose
REST	5555	TCP	REST	Public

shared ports

Component	Port	Protocol	Purpose	Should Expose
all	6060	TCP	pprof	Private
all	6061	TCP	metrics	Private

Optional flags can be enabled that enable pprof or metrics (or both). Use --help with the binary for more info.

other ports

Reserved for future use: gRPC ports: 9092 consensus engine, 9093 snapshot downloader, 9094 TxPool

Hetzner expecting strict firewall rules

0.0.0.0/8             "This" Network             RFC 1122, Section 3.2.1.3
10.0.0.0/8            Private-Use Networks       RFC 1918
100.64.0.0/10         Carrier-Grade NAT (CGN)    RFC 6598, Section 7
127.16.0.0/12         Private-Use Networks       RFC 1918
169.254.0.0/16        Link Local                 RFC 3927
172.16.0.0/12         Private-Use Networks       RFC 1918
192.0.0.0/24          IETF Protocol Assignments  RFC 5736
192.0.2.0/24          TEST-NET-1                 RFC 5737
192.88.99.0/24        6to4 Relay Anycast         RFC 3068
192.168.0.0/16        Private-Use Networks       RFC 1918
198.18.0.0/15         Network Interconnect
Device Benchmark Testing   RFC 2544
198.51.100.0/24       TEST-NET-2                 RFC 5737
203.0.113.0/24        TEST-NET-3                 RFC 5737
224.0.0.0/4           Multicast                  RFC 3171
240.0.0.0/4           Reserved for Future Use    RFC 1112, Section 4
255.255.255.255/32    Limited Broadcast          RFC 919, Section 7
RFC 922, Section 7

Same in IpTables syntax

Run as a separate user - systemd example

Running erigon from build/bin as a separate user might produce an error:

error while loading shared libraries: libsilkworm_capi.so: cannot open shared object file: No such file or directory

The library needs to be installed for another user using make DIST=<path> install. You could use $HOME/erigon or /opt/erigon as the installation path, for example:

make DIST=/opt/erigon install

How to get diagnostic for bug report?

• Get stack trace: kill -SIGUSR1 <pid>, get trace and stop: kill -6 <pid>
• Get CPU profiling: add --pprof flag and run
  go tool pprof -png http://127.0.0.1:6060/debug/pprof/profile\?seconds\=20 > cpu.png
• Get RAM profiling: add --pprof flag and run
  go tool pprof -inuse_space -png http://127.0.0.1:6060/debug/pprof/heap > mem.png

How to run local devnet?

🔬 Detailed explanation is here.

Docker permissions error

Docker uses user erigon with UID/GID 1000 (for security reasons). You can see this user being created in the Dockerfile. Can fix by giving a host's user ownership of the folder, where the host's user UID/GID is the same as the docker's user UID/GID (1000). More details in post

How to run public RPC api

• --txpool.nolocals=true
• don't add admin in --http.api list
• to increase throughput may need increase/decrease: --db.read.concurrency, --rpc.batch.concurrency, --rpc.batch.limit

RaspberyPI

https://github.com/mathMakesArt/Erigon-on-RPi-4

Run all components by docker-compose

Docker allows for building and running Erigon via containers. This alleviates the need for installing build dependencies onto the host OS.

Optional: Setup dedicated user

User UID/GID need to be synchronized between the host OS and container so files are written with correct permission.

You may wish to setup a dedicated user/group on the host OS, in which case the following make targets are available.

# create "erigon" user
make user_linux
# or
make user_macos

Environment Variables

There is a .env.example file in the root of the repo.

• DOCKER_UID - The UID of the docker user
• DOCKER_GID - The GID of the docker user
• XDG_DATA_HOME - The data directory which will be mounted to the docker containers

If not specified, the UID/GID will use the current user.

A good choice for XDG_DATA_HOME is to use the ~erigon/.ethereum directory created by helper targets make user_linux or make user_macos.

Run

Check permissions: In all cases, XDG_DATA_HOME (specified or default) must be writeable by the user UID/GID in docker, which will be determined by the DOCKER_UID and DOCKER_GID at build time. If a build or service startup is failing due to permissions, check that all the directories, UID, and GID controlled by these environment variables are correct.

Next command starts: Erigon on port 30303, rpcdaemon on port 8545, prometheus on port 9090, and grafana on port 3000.

#
# Will mount ~/.local/share/erigon to /home/erigon/.local/share/erigon inside container
#
make docker-compose

#
# or
#
# if you want to use a custom data directory
# or, if you want to use different uid/gid for a dedicated user
#
# To solve this, pass in the uid/gid parameters into the container.
#
# DOCKER_UID: the user id
# DOCKER_GID: the group id
# XDG_DATA_HOME: the data directory (default: ~/.local/share)
#
# Note: /preferred/data/folder must be read/writeable on host OS by user with UID/GID given
#       if you followed above instructions
#
# Note: uid/gid syntax below will automatically use uid/gid of running user so this syntax
#       is intended to be run via the dedicated user setup earlier
#
DOCKER_UID=$(id -u) DOCKER_GID=$(id -g) XDG_DATA_HOME=/preferred/data/folder DOCKER_BUILDKIT=1 COMPOSE_DOCKER_CLI_BUILD=1 make docker-compose

#
# if you want to run the docker, but you are not logged in as the $ERIGON_USER
# then you'll need to adjust the syntax above to grab the correct uid/gid
#
# To run the command via another user, use
#
ERIGON_USER=erigon
sudo -u ${ERIGON_USER} DOCKER_UID=$(id -u ${ERIGON_USER}) DOCKER_GID=$(id -g ${ERIGON_USER}) XDG_DATA_HOME=~${ERIGON_USER}/.ethereum DOCKER_BUILDKIT=1 COMPOSE_DOCKER_CLI_BUILD=1 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/erigontech/erigon/pull/2392/files

If your docker installation requires the docker daemon to run as root (which is by default), you will need to prefix the command above with sudo. However, it is sometimes recommended running docker (and therefore its containers) as a non-root user for security reasons. For more information about how to do this, refer to this article.

How to change db pagesize

post

Erigon3 perf tricks

• --sync.loop.block.limit=10_000 --batchSize=2g - likely will help for sync speed.
• on cloud-drives (good throughput, bad latency) - can enable OS's brain to pre-fetch: SNAPSHOT_MADV_RND=false
• can lock latest state in RAM - to prevent from eviction (node may face high historical RPC traffic without impacting Chain-Tip perf):

vmtouch -vdlw /mnt/erigon/snapshots/domain/*bt
ls /mnt/erigon/snapshots/domain/*.kv | parallel vmtouch -vdlw

# if it failing with "can't allocate memory", try: 
sync && sudo sysctl vm.drop_caches=3
echo 1 > /proc/sys/vm/compact_memory

Windows

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 as make 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 1.22
  • GNU CC Compiler at least version 13 (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 by choco install cmake make mingw. Make sure Windows System "Path" variable has: C:\ProgramData\chocolatey\lib\mingw\tools\install\mingw64\bin

  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 algorithms and we understand this might make your experience with Windows builds uncomfortable. To workaround the issue you might either set exclusions for your antivirus specifically for build\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 use DrvFS 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 of rpcdaemon 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.

Getting in touch

Erigon Discord Server

The main discussions are happening on our Discord server. To get an invite, send an email to bloxster [at] proton.me with your name, occupation, a brief explanation of why you want to join the Discord, and how you heard about Erigon.

Blog

erigon.substack.com

Twitter

x.com/ErigonEth

Reporting security issues/concerns

Send an email to security [at] torquem.ch.

Known issues

htop shows incorrect memory usage

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 frees 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". Without grep you can see details
  • section 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 browser localhost:3000, credentials admin/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 many random reads - this is reason why it's slowest stage. We do not recommend running multiple genesis syncs on same Disk. If genesis sync passed, then it's fine to run multiple Erigon instances on same Disk.

Cloud network drives

(Like gp3) You may read: https://github.com/erigontech/erigon/issues/1516#issuecomment-811958891 In short: network-disks are bad for blocks execution - because blocks execution reading data from db non-parallel non-batched way. Tricks: if you throw anough RAM and set env variable ERIGON_SNAPSHOT_MADV_RND=false - then Erigon will work good-enough on Cloud drives - in cost of higher IO.

Filesystem's background features are expensive

For example: btrfs's autodefrag option - may increase write IO 100x times

Gnome Tracker can kill Erigon

Gnome Tracker - detecting miners and kill them.

the --mount option requires BuildKit error

For anyone else that was getting the BuildKit error when trying to start Erigon the old way you can use the below...

XDG_DATA_HOME=/preferred/data/folder DOCKER_BUILDKIT=1 COMPOSE_DOCKER_CLI_BUILD=1 make docker-compose

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Documentation

Overview

Package ethereum defines interfaces for interacting with Ethereum.

Index

• Variables
• type CallMsg
• type ChainReader
• type ChainStateReader
• type ChainSyncReader
• type ContractCaller
• type FilterQuery
• type GasEstimator
• type GasPricer
• type LogFilterer
• type PendingContractCaller
• type PendingStateEventer
• type PendingStateReader
• type Subscription
• type SyncProgress
• type TransactionReader
• type TransactionSender

Variables

var NotFound = errors.New("not found")

NotFound is returned by API methods if the requested item does not exist.

Types

type CallMsg

type CallMsg struct {
	From             libcommon.Address  // the sender of the 'transaction'
	To               *libcommon.Address // the destination contract (nil for contract creation)
	Gas              uint64             // if 0, the call executes with near-infinite gas
	MaxFeePerBlobGas *uint256.Int       // EIP-4844 max_fee_per_blob_gas
	GasPrice         *uint256.Int       // wei <-> gas exchange ratio
	Value            *uint256.Int       // amount of wei sent along with the call
	Data             []byte             // input data, usually an ABI-encoded contract method invocation

	FeeCap         *uint256.Int          // EIP-1559 fee cap per gas.
	Tip            *uint256.Int          // EIP-1559 tip per gas.
	AccessList     types2.AccessList     // EIP-2930 access list.
	BlobHashes     []libcommon.Hash      // EIP-4844 versioned blob hashes.
	Authorizations []types.Authorization // EIP-3074 authorizations.
}

CallMsg contains parameters for contract calls.

type ChainReader

type ChainReader interface {
	BlockByHash(ctx context.Context, hash libcommon.Hash) (*types.Block, error)
	BlockByNumber(ctx context.Context, number *big.Int) (*types.Block, error)
	HeaderByHash(ctx context.Context, hash libcommon.Hash) (*types.Header, error)
	HeaderByNumber(ctx context.Context, number *big.Int) (*types.Header, error)
	TransactionCount(ctx context.Context, blockHash libcommon.Hash) (uint, error)
	TransactionInBlock(ctx context.Context, blockHash libcommon.Hash, index uint) (*types.Transaction, error)

	// This method subscribes to notifications about changes of the head block of
	// the canonical chain.
	SubscribeNewHead(ctx context.Context, ch chan<- *types.Header) (Subscription, error)
}

ChainReader provides access to the blockchain. The methods in this interface access raw data from either the canonical chain (when requesting by block number) or any blockchain fork that was previously downloaded and processed by the node. The block number argument can be nil to select the latest canonical block. Reading block headers should be preferred over full blocks whenever possible.

The returned error is NotFound if the requested item does not exist.

type ChainStateReader

type ChainStateReader interface {
	BalanceAt(ctx context.Context, account libcommon.Address, blockNumber *big.Int) (*big.Int, error)
	StorageAt(ctx context.Context, account libcommon.Address, key libcommon.Hash, blockNumber *big.Int) ([]byte, error)
	CodeAt(ctx context.Context, account libcommon.Address, blockNumber *big.Int) ([]byte, error)
	NonceAt(ctx context.Context, account libcommon.Address, blockNumber *big.Int) (uint64, error)
}

ChainStateReader wraps access to the state trie of the canonical blockchain. Note that implementations of the interface may be unable to return state values for old blocks. In many cases, using CallContract can be preferable to reading raw contract storage.

type ChainSyncReader

type ChainSyncReader interface {
	SyncProgress(ctx context.Context) (*SyncProgress, error)
}

ChainSyncReader wraps access to the node's current sync status. If there's no sync currently running, it returns nil.

type ContractCaller

type ContractCaller interface {
	CallContract(ctx context.Context, call CallMsg, blockNumber *big.Int) ([]byte, error)
}

A ContractCaller provides contract calls, essentially transactions that are executed by the EVM but not mined into the blockchain. ContractCall is a low-level method to execute such calls. For applications which are structured around specific contracts, the abigen tool provides a nicer, properly typed way to perform calls.

type FilterQuery

type FilterQuery struct {
	BlockHash *libcommon.Hash     // used by eth_getLogs, return logs only from block with this hash
	FromBlock *big.Int            // beginning of the queried range, nil means genesis block
	ToBlock   *big.Int            // end of the range, nil means latest block
	Addresses []libcommon.Address // restricts matches to events created by specific contracts

	// The Topic list restricts matches to particular event topics. Each event has a list
	// of topics. Topics matches a prefix of that list. An empty element slice matches any
	// topic. Non-empty elements represent an alternative that matches any of the
	// contained topics.
	//
	// Examples:
	// {} or nil          matches any topic list
	// {{A}}              matches topic A in first position
	// {{}, {B}}          matches any topic in first position AND B in second position
	// {{A}, {B}}         matches topic A in first position AND B in second position
	// {{A, B}, {C, D}}   matches topic (A OR B) in first position AND (C OR D) in second position
	Topics [][]libcommon.Hash
}

FilterQuery contains options for contract log filtering.

type GasEstimator

type GasEstimator interface {
	EstimateGas(ctx context.Context, call CallMsg) (uint64, error)
}

GasEstimator wraps EstimateGas, which tries to estimate the gas needed to execute a specific transaction based on the pending state. There is no guarantee that this is the true gas limit requirement as other transactions may be added or removed by miners, but it should provide a basis for setting a reasonable default.

type GasPricer

type GasPricer interface {
	SuggestGasPrice(ctx context.Context) (*big.Int, error)
}

GasPricer wraps the gas price oracle, which monitors the blockchain to determine the optimal gas price given current fee market conditions.

type LogFilterer

type LogFilterer interface {
	FilterLogs(ctx context.Context, q FilterQuery) ([]types.Log, error)
	SubscribeFilterLogs(ctx context.Context, q FilterQuery, ch chan<- types.Log) (Subscription, error)
}

LogFilterer provides access to contract log events using a one-off query or continuous event subscription.

Logs received through a streaming query subscription may have Removed set to true, indicating that the log was reverted due to a chain reorganisation.

type PendingContractCaller

type PendingContractCaller interface {
	PendingCallContract(ctx context.Context, call CallMsg) ([]byte, error)
}

PendingContractCaller can be used to perform calls against the pending state.

type PendingStateEventer

type PendingStateEventer interface {
	SubscribePendingTransactions(ctx context.Context, ch chan<- *types.Transaction) (Subscription, error)
}

A PendingStateEventer provides access to real time notifications about changes to the pending state.

type PendingStateReader

type PendingStateReader interface {
	PendingBalanceAt(ctx context.Context, account libcommon.Address) (*big.Int, error)
	PendingStorageAt(ctx context.Context, account libcommon.Address, key libcommon.Hash) ([]byte, error)
	PendingCodeAt(ctx context.Context, account libcommon.Address) ([]byte, error)
	PendingNonceAt(ctx context.Context, account libcommon.Address) (uint64, error)
	PendingTransactionCount(ctx context.Context) (uint, error)
}

A PendingStateReader provides access to the pending state, which is the result of all known executable transactions which have not yet been included in the blockchain. It is commonly used to display the result of ’unconfirmed’ actions (e.g. wallet value transfers) initiated by the user. The PendingNonceAt operation is a good way to retrieve the next available transaction nonce for a specific account.

type Subscription

type Subscription interface {
	// Unsubscribe cancels the sending of events to the data channel
	// and closes the error channel.
	Unsubscribe()
	// Err returns the subscription error channel. The error channel receives
	// a value if there is an issue with the subscription (e.g. the network connection
	// delivering the events has been closed). Only one value will ever be sent.
	// The error channel is closed by Unsubscribe.
	Err() <-chan error
}

Subscription represents an event subscription where events are delivered on a data channel.

type SyncProgress

type SyncProgress struct {
	StartingBlock uint64 // Block number where sync began
	CurrentBlock  uint64 // Current block number where sync is at
	HighestBlock  uint64 // Highest alleged block number in the chain
	PulledStates  uint64 // Number of state trie entries already downloaded
	KnownStates   uint64 // Total number of state trie entries known about
}

SyncProgress gives progress indications when the node is synchronising with the Ethereum network.

type TransactionReader

type TransactionReader interface {
	// TransactionByHash checks the pool of pending transactions in addition to the
	// blockchain. The isPending return value indicates whether the transaction has been
	// mined yet. Note that the transaction may not be part of the canonical chain even if
	// it's not pending.
	TransactionByHash(ctx context.Context, txHash libcommon.Hash) (tx *types.Transaction, isPending bool, err error)
	// TransactionReceipt returns the receipt of a mined transaction. Note that the
	// transaction may not be included in the current canonical chain even if a receipt
	// exists.
	TransactionReceipt(ctx context.Context, txHash libcommon.Hash) (*types.Receipt, error)
}

TransactionReader provides access to past transactions and their receipts. Implementations may impose arbitrary restrictions on the transactions and receipts that can be retrieved. Historic transactions may not be available.

Avoid relying on this interface if possible. Contract logs (through the LogFilterer interface) are more reliable and usually safer in the presence of chain reorganisations.

The returned error is NotFound if the requested item does not exist.

type TransactionSender

type TransactionSender interface {
	SendTransaction(ctx context.Context, txn *types.Transaction) error
}

TransactionSender wraps transaction sending. The SendTransaction method injects a signed transaction into the pending transaction pool for execution. If the transaction was a contract creation, the TransactionReceipt method can be used to retrieve the contract address after the transaction has been mined.

The transaction must be signed and have a valid nonce to be included. Consumers of the API can use package accounts to maintain local private keys and need can retrieve the next available nonce using PendingNonceAt.