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Introduction

Erigon's rpcdaemon runs in its own separate process.

This brings many benefits including easier development, the ability to run multiple daemons at once, and the ability to run the daemon remotely. It is possible to run the daemon locally as well (read-only) if both processes have access to the data folder.

Getting Started

The rpcdaemon gets built as part of the main erigon build process, but you can build it directly with this command:

make rpcdaemon

Running locally

Run rpcdaemon on same computer with Erigon. It's default option because it using Shared Memory access to Erigon's db - it's much faster than TCP access. Provide both --datadir and --private.api.addr flags:

make erigon
./build/bin/erigon --datadir=<your_data_dir> --private.api.addr=localhost:9090
make rpcdaemon
./build/bin/rpcdaemon --datadir=<your_data_dir> --txpool.api.addr=localhost:9090 --private.api.addr=localhost:9090 --http.api=eth,erigon,web3,net,debug,trace,txpool

Note that we've also specified which RPC namespaces to enable in the above command by --http.api flag.

Running remotely

To start the daemon remotely - just don't set --datadir flag:

make erigon
./build/bin/erigon --datadir=<your_data_dir> --private.api.addr=0.0.0.0:9090
make rpcdaemon
./build/bin/rpcdaemon --private.api.addr=<erigon_ip>:9090 --txpool.api.addr=localhost:9090 --http.api=eth,erigon,web3,net,debug,trace,txpool

The daemon should respond with something like:

INFO [date-time] HTTP endpoint opened url=localhost:8545...

When RPC daemon runs remotely, by default it maintains a state cache, which is updated every time when Erigon imports a new block. When state cache is reasonably warm, it allows such remote RPC daemon to execute queries related to latest block (i.e. to current state) with comparable performance to a local RPC daemon (around 2x slower vs 10x slower without state cache). Since there can be multiple such RPC daemons per one Erigon node, it may scale well for some workloads that are heavy on the current state queries.

Healthcheck

There are 2 options for running healtchecks, POST request, or GET request with custom headers. Both options are available at the /health endpoint.

POST request

If the health check is successful it returns 200 OK.

If the health check fails it returns 500 Internal Server Error.

Configuration of the health check is sent as POST body of the method.

{
   "min_peer_count": <minimal number of the node peers>,
   "known_block": <number_of_block_that_node_should_know>
}

Not adding a check disables that.

min_peer_count -- checks for minimum of healthy node peers. Requires net namespace to be listed in http.api.

known_block -- sets up the block that node has to know about. Requires eth namespace to be listed in http.api.

Example request http POST http://localhost:8545/health --raw '{"min_peer_count": 3, "known_block": "0x1F"}' Example response

{
    "check_block": "HEALTHY",
    "healthcheck_query": "HEALTHY",
    "min_peer_count": "HEALTHY"
}

GET with headers

If the healthcheck is successful it will return a 200 status code.

If the healthcheck fails for any reason a status 500 will be returned. This is true if one of the criteria requested fails its check.

You can set any number of values on the X-ERIGON-HEALTHCHECK header. Ones that are not included are skipped in the checks.

Available Options:

  • synced - will check if the node has completed syncing
  • min_peer_count<count> - will check that the node has at least <count> many peers
  • check_block<block> - will check that the node is at least ahead of the <block> specified
  • max_seconds_behind<seconds> - will check that the node is no more than <seconds> behind from its latest block

Example Request

curl --location --request GET 'http://localhost:8545/health' \
--header 'X-ERIGON-HEALTHCHECK: min_peer_count1' \
--header 'X-ERIGON-HEALTHCHECK: synced' \
--header 'X-ERIGON-HEALTHCHECK: max_seconds_behind600'

Example Response

{
    "check_block":"DISABLED",
    "max_seconds_behind":"HEALTHY",
    "min_peer_count":"HEALTHY",
    "synced":"HEALTHY"
}

Testing

By default, the rpcdaemon serves data from localhost:8545. You may send curl commands to see if things are working.

Try eth_blockNumber for example. In a third terminal window enter this command:

curl -X POST -H "Content-Type: application/json" --data '{"jsonrpc": "2.0", "method": "eth_blockNumber", "params": [], "id":1}' localhost:8545

This should return something along the lines of this (depending on how far your Erigon node has synced):

{
    "jsonrpc": "2.0",
    "id": 1,
    "result":" 0xa5b9ba"
}

Also, there are extensive instructions for using Postman to test the RPC.

Debugging

To print more detailed logs for 1 request - add --rpc.dbg.single=true flag. Then can send HTTP header "dbg: true":

curl -X POST -H "dbg: true" -H "Content-Type: application/json" --data '{"jsonrpc": "2.0", "method": "eth_blockNumber", "params": [], "id":1}' localhost:8545

FAQ

Relations between prune options and RPC methods

Next options available (by --prune flag):

* h - prune history (ChangeSets, HistoryIndices - used to access historical state, like eth_getStorageAt, eth_getBalanceAt, debug_traceTransaction, trace_block, trace_transaction, etc.)
* r - prune receipts (Receipts, Logs, LogTopicIndex, LogAddressIndex - used by eth_getLogs and similar RPC methods)
* t - prune txn lookup (used to get transaction by hash)
* c - prune call traces (used by trace_filter method)

By default data pruned after 90K blocks, can change it by flags like --prune.history.after=100_000

Some methods, if not found historical data in DB, can fallback to old blocks re-execution - but it requires h.

The --http.url flag

the --http.url flag is an optional flag which allows one to bind the HTTP server to a socket, for example, tcp6://:8545 or unix:///erigon_http.socket

If the --http.url flag is set, then --http.addr and --http.port with both be ignored.

note that this is NOT geth-style IPC. for that, read the next section, IPC endpoint(geth-compatible)

HTTPS, HTTP2, and H2C

Erigon supports HTTPS, HTTP2, and H2C out of the box. H2C is served by the default HTTP handler.

To enable the HTTPS+HTTP2 server, add flag --https.enabled, along with providing flags -https.cert="/path/to.cert" and --https.key=/path/to.key

By default, the HTTPS server will run on the HTTP port + 363. use flag --https.port to set the port

The HTTPS server will inherit all other configuration parameters from http, for instance, enabling the websocket server, cors domains, or enabled namespaces

If the --https.url flag is set, then --https.addr and --https.port with both be ignored.

IPC endpoint (geth compatible)

erigon supports the geth-style unix socket IPC. you can enable this with --socket.enabled flag, and setting the --socket.url flag. For instance, if you wanted the socket to exist at /var/run/erigon.ipc, you would do --socket.url=unix:///var/run/erigon.ipc

you can also use --socket.url=tcp://<addr>:<port> to serve the raw jsonrpc2 protocol over tcp

the socket will inherit the namespaces from http.api

RPC Implementation Status

Label "remote" means: --private.api.addr flag is required.

The following table shows the current implementation status of Erigon's RPC daemon.

Command Avail Notes
admin_nodeInfo Yes
admin_peers Yes
admin_addPeer Yes
web3_clientVersion Yes
web3_sha3 Yes
net_listening HC (remote hard coded returns true)
net_peerCount Limited internal sentries only
net_version Yes remote.
eth_blockNumber Yes
eth_chainID/eth_chainId Yes
eth_protocolVersion Yes
eth_syncing Yes
eth_gasPrice Yes
eth_maxPriorityFeePerGas Yes
eth_feeHistory Yes
eth_getBlockByHash Yes
eth_getBlockByNumber Yes
eth_getBlockTransactionCountByHash Yes
eth_getBlockTransactionCountByNumber Yes
eth_getUncleByBlockHashAndIndex Yes
eth_getUncleByBlockNumberAndIndex Yes
eth_getUncleCountByBlockHash Yes
eth_getUncleCountByBlockNumber Yes
eth_getTransactionByHash Yes
eth_getRawTransactionByHash Yes
eth_getTransactionByBlockHashAndIndex Yes
eth_retRawTransactionByBlockHashAndIndex Yes
eth_getTransactionByBlockNumberAndIndex Yes
eth_retRawTransactionByBlockNumberAndIndex Yes
eth_getTransactionReceipt Yes
eth_getBlockReceipts Yes
eth_estimateGas Yes
eth_getBalance Yes
eth_getCode Yes
eth_getTransactionCount Yes
eth_getStorageAt Yes
eth_call Yes
eth_callMany Yes Erigon Method PR#4567
eth_callBundle Yes
eth_createAccessList Yes
eth_newFilter Yes Added by PR#4253
eth_newBlockFilter Yes
eth_newPendingTransactionFilter Yes
eth_getFilterLogs Yes Added by PR#6514
eth_getFilterChanges Yes
eth_uninstallFilter Yes
eth_getLogs Yes
interned spe
eth_accounts No deprecated
eth_sendRawTransaction Yes remote.
eth_sendTransaction - not yet implemented
eth_sign No deprecated
eth_signTransaction - not yet implemented
eth_signTypedData - ????
eth_getProof Yes Limited to last 100000 blocks
eth_mining Yes returns true if --mine flag provided
eth_coinbase Yes
eth_hashrate Yes
eth_submitHashrate Yes
eth_getWork Yes
eth_submitWork Yes
eth_subscribe Limited Websock Only - newHeads,
newPendingTransactionsWithBody,
newPendingTransactions,
newPendingBlock
logs
eth_unsubscribe Yes Websock Only
engine_newPayloadV1 Yes
engine_newPayloadV2 Yes
engine_newPayloadV3 Yes
engine_forkchoiceUpdatedV1 Yes
engine_forkchoiceUpdatedV2 Yes
engine_forkchoiceUpdatedV3 Yes
engine_getPayloadV1 Yes
engine_getPayloadV2 Yes
engine_getPayloadV3 Yes
debug_accountRange Yes Private Erigon debug module
debug_accountAt Yes Private Erigon debug module
debug_getModifiedAccountsByNumber Yes
debug_getModifiedAccountsByHash Yes
debug_storageRangeAt Yes
debug_traceBlockByHash Yes Streaming (can handle huge results)
debug_traceBlockByNumber Yes Streaming (can handle huge results)
debug_traceTransaction Yes Streaming (can handle huge results)
debug_traceCall Yes Streaming (can handle huge results)
debug_traceCallMany Yes Erigon Method PR#4567.
trace_call Yes
trace_callMany Yes
trace_rawTransaction - not yet implemented (come help!)
trace_replayBlockTransactions yes stateDiff only (come help!)
trace_replayTransaction yes stateDiff only (come help!)
trace_block Yes
trace_filter Yes no pagination, but streaming
trace_get Yes
trace_transaction Yes
txpool_content Yes remote
txpool_contentFrom Yes remote
txpool_status Yes remote
eth_getCompilers No deprecated
eth_compileLLL No deprecated
eth_compileSolidity No deprecated
eth_compileSerpent No deprecated
db_putString No deprecated
db_getString No deprecated
db_putHex No deprecated
db_getHex No deprecated
erigon_getHeaderByHash Yes Erigon only
erigon_getBlockReceiptsByBlockHash Yes Erigon only
erigon_getHeaderByNumber Yes Erigon only
erigon_getLogsByHash Yes Erigon only
erigon_forks Yes Erigon only
erigon_getBlockByTimestamp Yes Erigon only
erigon_BlockNumber Yes Erigon only
erigon_getLatestLogs Yes Erigon only
bor_getSnapshot Yes Bor only
bor_getAuthor Yes Bor only
bor_getSnapshotAtHash Yes Bor only
bor_getSigners Yes Bor only
bor_getSignersAtHash Yes Bor only
bor_getCurrentProposer Yes Bor only
bor_getCurrentValidators Yes Bor only
bor_getSnapshotProposerSequence Yes Bor only
bor_getRootHash Yes Bor only
bor_getVoteOnHash Yes Bor only

GraphQL

Command Avail Notes
GetBlockDetails Yes
GetChainID Yes

This table is constantly updated. Please visit again.

Securing the communication between RPC daemon and Erigon instance via TLS and authentication

In some cases, it is useful to run Erigon nodes in a different network (for example, in a Public cloud), but RPC daemon locally. To ensure the integrity of communication and access control to the Erigon node, TLS authentication can be enabled. On the high level, the process consists of these steps (this process needs to be done for any "cluster" of Erigon and RPC daemon nodes that are supposed to work together):

  1. Generate key pair for the Certificate Authority (CA). The private key of CA will be used to authorise new Erigon instances as well as new RPC daemon instances, so that they can mutually authenticate.
  2. Create CA certificate file that needs to be deployed on any Erigon instance and any RPC daemon. This CA cerf file is used as a "root of trust", whatever is in it, will be trusted by the participants when they authenticate their counterparts.
  3. For each Erigon instance and each RPC daemon instance, generate a key pair. If you are lazy, you can generate one pair for all Erigon nodes, and one pair for all RPC daemons, and copy these keys around.
  4. Using the CA private key, create certificate file for each public key generated on the previous step. This effectively "inducts" these keys into the "cluster of trust".
  5. On each instance, deploy 3 files - CA certificate, instance key, and certificate signed by CA for this instance key.

Following is the detailed description of how it can be done using openssl suite of tools.

Generate CA key pair using Elliptic Curve (as opposed to RSA). The generated CA key will be in the file CA-key.pem. Access to this file will allow anyone to later include any new instance key pair into the "cluster of trust", so keep it secure.

openssl ecparam -name prime256v1 -genkey -noout -out CA-key.pem

Create CA self-signed certificate (this command will ask questions, answers aren't important for now). The file created by this command is CA-cert.pem

openssl req -x509 -new -nodes -key CA-key.pem -sha256 -days 3650 -out CA-cert.pem

For Erigon node, generate a key pair:

openssl ecparam -name prime256v1 -genkey -noout -out erigon-key.pem

Also, generate one for the RPC daemon:

openssl ecparam -name prime256v1 -genkey -noout -out RPC-key.pem

Now create certificate signing request for Erigon key pair:

openssl req -new -key erigon-key.pem -out erigon.csr

And from this request, produce the certificate (signed by CA), proving that this key is now part of the "cluster of trust"

openssl x509 -req -in erigon.csr -CA CA-cert.pem -CAkey CA-key.pem -CAcreateserial -out erigon.crt -days 3650 -sha256

Then, produce the certificate signing request for RPC daemon key pair:

openssl req -new -key RPC-key.pem -out RPC.csr

And from this request, produce the certificate (signed by CA), proving that this key is now part of the "cluster of trust"

openssl x509 -req -in RPC.csr -CA CA-cert.pem -CAkey CA-key.pem -CAcreateserial -out RPC.crt -days 3650 -sha256

When this is all done, these three files need to be placed on the machine where Erigon is running: CA-cert.pem , erigon-key.pem, erigon.crt. And Erigon needs to be run with these extra options:

--tls --tls.cacert CA-cert.pem --tls.key erigon-key.pem --tls.cert erigon.crt

On the RPC daemon machine, these three files need to be placed: CA-cert.pem, RPC-key.pem, and RPC.crt. And RPC daemon needs to be started with these extra options:

--tls.key RPC-key.pem --tls.cacert CA-cert.pem --tls.cert RPC.crt

WARNING Normally, the "client side" (which in our case is RPC daemon), verifies that the host name of the server matches the "Common Name" attribute of the "server" certificate. At this stage, this verification is turned off, and it will be turned on again once we have updated the instruction above on how to properly generate certificates with "Common Name".

When running Erigon instance in the Google Cloud, for example, you need to specify the Internal IP in the --private.api.addr option. And, you will need to open the firewall on the port you are using, to that connection to the Erigon instances can be made.

Ethstats

This version of the RPC daemon is compatible with ethstats-client.

To run ethstats, run the RPC daemon remotely and open some of the APIs.

./build/bin/rpcdaemon --private.api.addr=localhost:9090 --http.api=net,eth,web3

Then update your app.json for ethstats-client like that:

[
  {
    "name": "ethstats",
    "script": "app.js",
    "log_date_format": "YYYY-MM-DD HH:mm Z",
    "merge_logs": false,
    "watch": false,
    "max_restarts": 10,
    "exec_interpreter": "node",
    "exec_mode": "fork_mode",
    "env": {
      "NODE_ENV": "production",
      "RPC_HOST": "localhost",
      "RPC_PORT": "8545",
      "LISTENING_PORT": "30303",
      "INSTANCE_NAME": "Erigon node",
      "CONTACT_DETAILS": "<your twitter handle>",
      "WS_SERVER": "wss://ethstats.net/api",
      "WS_SECRET": "<put your secret key here>",
      "VERBOSITY": 2
    }
  }
]

Run ethstats-client through pm2 as usual.

You will see these warnings in the RPC daemon output, but they are expected

WARN [11-05|09:03:47.911] Served                                   conn=127.0.0.1:59753 method=eth_newBlockFilter reqid=5 t="21.194µs" err="the method eth_newBlockFilter does not exist/is not available"
WARN [11-05|09:03:47.911] Served                                   conn=127.0.0.1:59754 method=eth_newPendingTransactionFilter reqid=6 t="9.053µs"  err="the method eth_newPendingTransactionFilter does not exist/is not available"

Allowing only specific methods (Allowlist)

In some cases you might want to only allow certain methods in the namespaces and hide others. That is possible with rpc.accessList flag.

  1. Create a file, say, rules.json

  2. Add the following content

{
  "allow": ["net_version", "web3_eth_getBlockByHash"]
}
  1. Provide this file to the rpcdaemon using --rpc.accessList flag
> rpcdaemon --private.api.addr=localhost:9090 --http.api=eth,debug,net,web3 --rpc.accessList=rules.json

Now only these two methods are available.

Clients getting timeout, but server load is low

In this case: increase default rate-limit - amount of requests server handle simultaneously - requests over this limit will wait. Increase it - if your 'hot data' is small or have much RAM or see "request timeout" while server load is low.

./build/bin/erigon --private.api.addr=localhost:9090 --private.api.ratelimit=1024

Server load too high

Reduce --private.api.ratelimit

Read DB directly without Json-RPC/Graphql

./../../docs/programmers_guide/db_faq.md

Faster Batch requests

Currently batch requests are spawn multiple goroutines and process all sub-requests in parallel. To limit impact of 1 huge batch to other users - added flag --rpc.batch.concurrency (default: 2). Increase it to process large batches faster.

Known Issue: if at least 1 request is "streamable" (has parameter of type *jsoniter.Stream) - then whole batch will processed sequentially (on 1 goroutine).

For Developers

Code generation

go.mod stores right version of generators, use make grpc to install it and generate code (it also installs protoc into ./build/bin folder).