NanoRPCProxy is a relay and protection system that operates between a client and a Nano node RPC interface. It makes it possible to set the RPC interface public to the Internet without compromising the security of the node itself. The Nano node has no built-in functionality for user authentication, rate-limiting or caching which makes it dangerous to open up without protection as this proxy provides. With NanoRPCProxy you can, for example, serve a mobile app or web frontend with indirect node calls.
In reality, it can be used for Nano wallets, exchanges, block explorers, public APIs, monitor systems, Point of Sale or anything that communicates with a node.
The built-in token system makes it possible to serve requests beyond the default limits and monetize your backend via direct Nano token purchases. More info in the token section.
Demo clients/code for Curl, JS, REACT, Python and Flask are available to test your own server.
Public API demo client with token support: https://api.nanos.cc
In addition to the RPC interface, NanoRPCProxy also has built-in support for certain websocket subscriptions offered by the Nano node, for example block confirmations. Similar to the RPC, the websocket is DDOS protected and acts as a secure layer between the client and the node. This allows, for example, a public websocket open to everyone who needs to track certain accounts in real-time, without the need to set up their own node. That could be, but not limited to:
- Microprocessors controlling hardware (IoT) like animal feeder, beer dispenser, door locks, arcade machines, exhibition demos, hobby projects, etc
- Web apps with features activated by payments, wallet alert/tracking, payment listener, games, etc
Demo clients for websocket is available for JS (web) and Node.js. More info in the websocket section.
Public websocket demo: https://api.nanos.cc/socket
Apart from increased security, NanoRPCProxy solves the scalability issue where a node can't serve too many clients and lets the node do what it's supposed to do, ie. process blocks as fast as possible. The system can be scaled up to serve thousands of clients with only one connection to the node per proxy server.
- Fully customizable via a settings file
- Supports any RPC command for any remote client; like wallets, exchanges, apps, games, bots or public API
- Supports websocket subscriptions for block confirmations; like account tracking (multiple accounts allowed) and public endpoint
- Caching of certain request actions to lower the RPC burden
- Limits the number of response objects, like the number of pending transactions
- Slows down IPs that doing requests above limit (Overridden by purchased tokens)
- IP filter for max allowed requests per time window (Overridden by purchased tokens)
- Extra DDOS protection layer (defaults to max 100 requests/ 10sec, also for purchased tokens)
- IP black list (also for purchased tokens)
- Supports basic authentication (username / password) (also for purchased tokens)
- Supports multiple users via authentication
- User-specific settings override
- Optional token system for requests with built-in Nano purchases => independent of any 3rd party payment processors => unlimited implementation possibilities
- Supports POST requests like the RPC, ie. payload = {"action":"block_count"}
- Supports GET requests, ie. URL query = /proxy/?action=block_count
- Both RPC and websocket support http and/or https with your own SSL cert (or use another proxy like Cloudflare to serve https)
- Works with both beta and main Nano network
- Support for both delegated PoW (dPoW) and BoomPoW (bPoW)
- Multiple demo clients for developers
- Available as docker container https://hub.docker.com/r/nanojson/nanorpcproxy
- Built-in support for Prometheus data scraping that can be visualized with Grafana
- Install and run the proxy server
- How to customize the proxy server
- How to use the proxy server
- How to install and test the demo clients
- Developer Donations
- Make sure you have node.js installed. Windows Guide | Ubuntu Guide
- Copy the default setting files to your own editable ones:
These will not be affected if later updating the server via git pull
cp creds.json.default creds.json
cp settings.json.default settings.json
cp user_settings.json.default user_settings.json
cp token_settings.json.default token_settings.json
- Install required libraries: npm install
- Build Typescript sources: npm run build
- Start and test the server: node dist/proxy.js
https://pm2.keymetrics.io/docs/usage/quick-start/
Make sure you have build the project (npm run build) first as specified in the Setup nodejs and test server
section.
Setting files need to be in the dist
folder for the proxy to read them properly.
- Locate the directory ./dist
- Install pm2: npm install pm2@latest -g
- Start the server: pm2 start proxy.js
- pm2 restart proxy.js, pm2 stop proxy.js, pm2 delete proxy.js
- Make pm2 auto-boot at server restart: pm2 startup
- Realtime online monitor: pm2 monitor
- Status: pm2 status
- Realtime logs: pm2 logs (or specifically for this app: pm2 logs proxy.js)
- Terminal dashboard: pm2 monit
Before making changes, stop any running servers with "pm2 stop dist/proxy.js" and delete the process with "pm delete proxy.js"
- Specify log location: pm2 start dist/proxy.js --log ~/NanoRPCProxy.log
- Restart app when file changes: pm2 start proxy.js --watch
- npm install pm2@latest -g
- pm2 update
Example of PM2 web monitor. Can track all your apps and with realtime logs.
https://expeditedsecurity.com/blog/deploy-node-on-linux/#node-linux-service-systemd
Make sure you have build the project (npm run build) first as specified in the Setup nodejs and test server
section.
Setting files need to be in the dist
folder for the proxy to read them properly.
- Create a file /etc/systemd/system/nanorpcproxy.service
- Paste this
change to your actual location of proxy.js
[Unit]
Description=NanoRPCProxy
After=network.target
[Service]
ExecStart=/usr/local/bin/node /home/NanoRPCProxy/dist/proxy.js
Restart=always
RestartSec=10 #wait 10sec before restart
#User=nobody
#Group=nogroup
Environment=PATH=/usr/bin:/usr/local/bin
Environment=NODE_ENV=production
WorkingDirectory=/home/NanoRPCProxy/
[Install]
WantedBy=multi-user.target
- Make the file executable: sudo chmod +x /home/NanoRPCProxy/dist/proxy.js
- Make systemd aware: sudo systemctl daemon-reload
- Test the service: sudo systemctl start nanorpcproxy
- Check status: sudo systemctl status nanorpcproxy
- Start service on boot: sudo systemctl enable nanorpcproxy.service
- Follow logs in realtime: sudo journalctl --follow -u nanorpcproxy
- Go to the root folder -> git pull
- Update dependencies -> npm install
- Build sources -> npm run build
- Restart the proxy.js
It may happen that the settings files are expanded. In that case, you need to do this again in order for the new variables to be modified by you (or insert them manually). Save your old settings first!
cp settings.json.default settings.json
cp user_settings.json.default user_settings.json
cp token_settings.json.default token_settings.json
The docker image is available publicly on nanojson/nanorpcproxy but if you want to build it yourself:
Ensure that Docker is installed.
In order to run the latest stable image with default (no) config:
$ docker run -it nanojson/nanorpcproxy:latest
You can also pull the master branch (:master) or previous release tags. To build and run from source:
$ docker build . -t nanorpcproxy
Then run it without the public "nanojson" registry
$ docker run -it nanorpcproxy:latest
To run with configuration, first copy default settings:
$ cp creds.json.default creds.json
$ cp settings.json.default settings.json
$ cp user_settings.json.default user_settings.json
$ cp token_settings.json.default token_settings.json
To run the docker container with configuration you have to map the configuration files inside the container to /root
.
Here's an example mounting settings.json
from the current work directory, to /root/settings.json
in the container:
$ docker run -it -p 9950:9950 -v $(pwd)/:/root nanojson/nanorpcproxy:latest
The same goes for rest of the settings files. You can place them in a separate folder (settings) if you like and map that instead of the base folder.
$ docker run -it -p 9950:9950 -v $(pwd)/settings:/root nanojson/nanorpcproxy:latest
Here is an example how to run it indefinitely in the background and restart on fail or machine boot (with the name rpcproxy):
$ docker run -d --restart unless-stopped --name rpcproxy -p 9950:9950 -v $(pwd)/:/root nanojson/nanorpcproxy:latest
There's also a docker-compose.yml
file present. To run with docker compose,
first copy files as above. Then run image with:
$ docker-compose up
All files but settings.json is disabled in the docker-compose file by default.
- Copy the settings.json.default to a new folder nano_proxy/settings.json (or other setting files mentioned above)
- Edit settings.json and make sure "node_url":"http://node:7076" and "node_ws_url":"ws://node:7078". That means the proxy will connect to the node service (name=node) internally.
- Create a docker-compose.yml and paste this (at the root of the nano_proxy folder). It will download the latest node and proxy. Then forward the node port 7075, RPC port 9950 and Websocket port 9952. Those will be the ones exposed.
docker-compose.yml
version: "3"
services:
node:
image: "nanocurrency/nano:latest"
restart: "unless-stopped"
ports:
- "7075:7075"
volumes:
- "./nano_node:/root"
nanorpcproxy:
image: "nanojson/nanorpcproxy:latest"
restart: "unless-stopped"
ports:
- "9950:9950"
- "9952:9952"
volumes:
- ./:/root
- Create a folder called nano_node (same level as the settings folder)
- Run this in the same folder as the docker-compose.yml
Terminal
$ docker-compose up
- Now in the nano_node folder the node will start saving the ledger, logs and settings. You can alter the config-node.toml or config-rpc.toml and just restart the compose. For example, you want the RPC and websocket to be enabled. And if you are going to request node PoW (not using dpow or bpow), you also need enable_control in the config-rpc.toml (if not using work_peers) and in the settings/settings.json you will need "work_generate" as an "allowed command".
Example of config-node.toml
[node.websocket]
address = "::ffff:0.0.0.0"
enable = true
[rpc]
enable = true
- When everything is up and running you can for example connect Nault to it via the app settings. Using http://127.0.0.1:9950/proxy and ws://127.0.0.1:9952
To upgrade you need to first turn off running container ("docker stop xxx", or "docker-compose down"). Also remove the container if you want to keep the same name (label)
- Normal container: docker pull nanojson/nanorpcproxy:latest
- Composer: docker-compose pull
If you used docker compose to build from local source (nanorpcproxy:latest) you will have to rebuild:
- docker-compose build
The proxy server is configured via the settings.json file found in the server folder
- node_url: Nano node RPC url (default for main network is 'http://[::1]:7076' and for beta network 'http://[::1]:55000') [url]
- node_ws_url: Nano node websocket url (default for main network is 'http://[::1]:7078' and for beta network 'http://[::1]:57000') [url]
- http_port: Port to listen on for http (requires <use_http>) [number]
- https_port: Port to listen on for https (requires <use_https>) [number]
- websocket_http_port: Port to listen on for http websocket connection (requires <use_http> and <use_websocket>) [number]
- websocket_https_port: Port to listen on for https websocket connection (requires <use_https> and <use_websocket>) [number]
- use_auth: If require username and password when connecting to the proxy. Defined in creds.json [true/false]
- use_slow_down: If slowing down requests for IPs doing above set limit (defined in <slow_down>) [true/false]
- use_rate_limiter: If blocking IPs for a certain amount of time when they request above set limit (defined in <rate_limiter>). This request limit, requests remaining and timestamp for reset will also be included in the response header as "X-RateLimit-Limit", "X-RateLimit-Remaining", and "X-RateLimit-Reset". Additionally included in the json response as well as "requestsLimit", "requestsRemaining" and "requestLimitReset". For example if 1000 / day is allowed for free, the user will see how many are left to use. This filter is skipped when using tokens. [true/false]
- use_cache: If caching certain commands set in <cached_commands> [true/false]
- use_http: Listen on http [true/false]
- use_https: Listen on https (a valid cert and key file is needed via <https_cert> and <https_key>) [true/false]
- use_output_limiter: If limiting number of response objects, like pending transactions, to a certain max amount set in <limited_commands>. Only valid for RPC actions that have a "count" key [true/false] [true/false]
- use_ip_blacklist: If always blocking certain IPs set in <ip_blacklist> [true/false]
- use_tokens If activating the token system for purchase via Nano [true/false] (more information further down)
- use_websocket If activating the websocket system [true/false] (more information further down)
- allow_websocket_all If allowing users to subscribe to ALL accounts (more traffic) [true/false]
- use_cors If handling cors policy here, if not taken care of in upstream proxy (cors_whitelist=[] means allow ANY ORIGIN)
- use_dpow If allow work_generate to be done by dPoW instead of local node. Work will consume 10 token points. If "difficulty" is not provided with the work_generate request the "default send difficulty" will be used. (The priority order is bpow > dpow > work server. If all three are set to false, it will use the node to generate work) (requires work_generate in allowed_commands and credentials to be set in pow_creds.json)
- use_bpow If allow work_generate to be done by BoomPoW intead of local node. Work will consume 10 token points. If "difficulty" is not provided with the work_generate request the "default send difficulty" will be used. (The priority order is bpow > dpow > work server. If all three are set to false, it will use the node to generate work) (requires work_generate in allowed_commands and credentials to be set in pow_creds.json)
- use_work_server If allow work_generate to be done by an external work server intead of local node. Work will consume 10 token points. If "difficulty" is not provided with the work_generate request the "default send difficulty" will be used. (The priority order is bpow > dpow > work server. If all three are set to false, it will use the node to generate work) (requires work_generate in allowed_commands and url to be set in pow_creds.json). [true/false]
- use_work_peers If the node is used to generate work (dpow, bpow and work server all set to false) this will set the "use_peers" to true and let the node use its internally configured work peers [true/false]
- disable_watch_work Forcefully set watch_work=false for process calls (to block node from doing rework). Deprecated since node v22. [true/false]
- https_cert: File path for pub cert file (requires <use_https>) [absolute path string]
- https_key: File path for private key file (requires <use_https>) [absolute path string]
- enable_prometheus_for_ips: IP addresses to enable prometheus for. Typically ["127.0.0.1"] but can also be a combination of ipv4/ipv6 CIDR subnets like ["127.0.0.1", "::1/128", "172.16.0.0/12"] [comma separated list]
- allowed_commands: A list of RPC actions to allow [list]
- cached_commands: A list of commands [key] that will be cached for corresponding duration in seconds as [value]
- limited_commands: A list of commands [key] to limit the output response for with max count as [value]. Also limits account arrays such as accounts_pending, which also limit the pending count per account as value*10.
- ip_blacklist: A list of IPs to always block. Also supports CIDR like ["172.16.0.0/12"]. If calling from localhost you can test this with ["127.0.0.1"] (::ffff:127.0.0.1 for ipv6) [comma separated list]
- slow_down: Contains the settings for slowing down requests. The rolling time slot is defined with <time_window> [ms]. When number of requests in that slot is exceeding <request_limit> it will start slowing down requests with increments of <delay_increment> [ms] with a maximum total delay defined in <max_delay> [ms]
- rate_limiter: Contains the settings for the rate limiter. The rolling time slot is defined with <time_window> [ms]. When number of requests in that slot is exceeding <request_limit> it will block the IP until the time slot has passed. Then the IP can start requesting again. To permanently ban IPs they have to be manually added to <ip_blacklist> and activating <use_ip_blacklist>.
- proxy_hops If the NanoRPCProxy is behind other proxies such as apache or cloudflare the source IP will be wrongly detected and the filters will not work as intended. Enter the number of additional proxies here. Example: api.example.com is proxied through Cloudflare to IP 1.1.1.1 and then local Nginx server is proxying api.example.com to localhost:9950. Proxyhops will be 2.
- websocket_max_accounts Maximum number of accounts per IP allowed for block confirmation subscription [number]
- cors_whitelist Whitelist requester ORIGIN header or IP for example "https://mywallet.com", "http://localhost:8080" or "8.8.8.8" (requires use_cors) [comma separated list of hostnames]
- log_level: It can be set to either "info" which will output all logs, "warning" which will only output warning messages or "none" which will only log the initial settings.
The following parameters can be set in user_settings.json to override the default ones for specific users defined in creds.json. Anything in this file will override even if there are less sub entries like only 1 allowed command or 2 limited commands.
- use_cache
- use_output_limiter
- allowed_commands
- cached_commands
- limited_commands
- log_level
The following parameters can be set in token_settings.json for configuration of the token system. The system require the <use_tokens> to be active in settings.json
More info about the token system in this section
- work_server Source for calculating PoW. Can be a node (http://[::1]:7076) (with enable_control active) or a work server which can be run as "./nano-work-server --gpu 0:0 -l 127.0.0.1:7000" and then set work_server to http://127.0.0.1:7000. Also available pre-compiled here. To use bpow or dpow, just point the server to itself such as http://127.0.0.1:9950/proxy (requires bpow/dpow to be configured and work_generate as allowed command)
- token_price: Purchase price per token [Nano]
- payment_timeout: Payment window before timeout and cancelled [seconds]
- pending_interval: How often to check for deposit during the payment window (may be removed if websocket is implemented)
- pending_threshold: Skip processing pending transactions below this raw amount
- pending_count: The maximum number of pending transactions to process each time a new order comes in
- difficulty_multiplier: The PoW multiplier from base difficulty
- payment_receive_account: The account to send the incoming money
- min_token_amount: The minimum amount of tokens to allow for purchase
- max_token_amount: The maximum amount of tokens to allow for purchase
- log_level: It can be set to either "info" which will output all logs, "warning" which will only output warning messages or "none" which will only log the initial settings.
You call the proxy server just like you would call the node RPC. It's a normal POST request to "/proxy" with json formatted data. The node commands are found here: https://docs.nano.org/commands/rpc-protocol/
It also support URL queries via GET request, which means you can even run the commands from a web browser via links such as "/proxy/?action=block_count" and get a json response. However, if authentication is activated in the server settings, basic auth headers are needed so that won't work in a browser.
The proxy server also support special commands not supported in the Nano RPC. They need to be listed in the settings.json under "allowed_commands"
- {"action":"price"}
Returns the latest Nano price quote from Coinpaprika. Will always be cached for 10sec.
{
"id": "nano-nano",
"name": "Nano",
"symbol": "NANO",
"rank": 62,
"circulating_supply": 133248297,
"total_supply": 133248297,
"max_supply": 133248290,
"beta_value": 0.975658,
"last_updated": "2020-05-28T12:34:54Z",
"quotes": {
"USD": {
"price": 0.86498056,
"volume_24h": 5450637.5460105,
"volume_24h_change_24h": 12,
"market_cap": 115257186,
"market_cap_change_24h": -5.21,
"percent_change_1h": -0.59,
"percent_change_12h": -5.67,
"percent_change_24h": -5.21,
"percent_change_7d": -6.96,
"percent_change_30d": 45.21,
"percent_change_1y": -49.99,
"ath_price": 37.6212,
"ath_date": "2018-01-02T06:39:00Z",
"percent_from_price_ath": -97.7
}
}
}
- {"action":"verified_accounts"}
Returns a list of verified accounts from https://mynano.ninja/. These can be used as suggestions for representative accounts. This response is cached for 1 minute:
[
{
"votingweight": 7.231803912122739e+35,
"delegators": 1359,
"uptime": 99.72967712635973,
"score": 99,
"account": "nano_33ad5app7jeo6jfe9ure6zsj8yg7knt6c1zrr5yg79ktfzk5ouhmpn6p5d7p",
"alias": "warai"
},
...
]
- {"action":"mnano_to_raw","amount":"1"}
Converts NANO to raw
{
"amount": "1000000000000000000000000000000"
}
- {"action":"mnano_from_raw","amount":"1"}
Converts raw to NANO
{
"amount": "0.000000000000000000000000000001"
}
The curl command looks just a tiny bit different than for a direct node request. You just have to define it with a json content type. You can also use the -i flag to include response headers.
POST: No authentication
curl -d '{"action":"block_count"}' http://localhost:9950/proxy
POST: With authentication
curl --user user1:user1 -d '{"action":"block_count"}' http://127.0.0.1:9950/proxy
GET: No authentication
curl http://localhost:9950/proxy?action=block_count
GET: With authentication
curl --user user1:user1 http://localhost:9950/proxy?action=block_count
Using Windows Powershell 7 - Escape quotes
curl -d '{\"action\":\"block_count\"}' http://localhost:9950/proxy
POST: No authentication
import requests
import json
try:
r = requests.post("http://localhost:9950/proxy", json={"action":"block_count"})
status = r.status_code
print("Status code: ", status)
if (status == 200):
print("Success!")
try:
print(r.json())
except:
print(r)
except Exception as e:
print("Fatal error", e)
POST: With authentication Note: verify=False means we ignore possible SSL certificate errors. Recommended to set to True
r = requests.post('http://localhost:9950/proxy', json={"action":"block_count"}, verify=False, auth=HTTPBasicAuth(username, password))
GET: With authentication
r = requests.get('http://localhost:9950/proxy?action=block_count', auth=HTTPBasicAuth(username, password))
POST: Async with authentication (Without: remove the Authorization header)
See the js demo client for full example with error handling
For html file: <script src="https://cdn.jsdelivr.net/npm/[email protected]/base64.min.js"></script>
async function postData(data = {}, server='http://localhost:9950/proxy') {
const response = await fetch(server, {
method: 'POST',
cache: 'no-cache',
headers: {
'Authorization': 'Basic ' + Base64.encode('user1:user1')
},
body: JSON.stringify(data)
})
return await response.json()
}
postData({"action":"block_count"})
.then((data) => {
console.log(JSON.stringify(data, null, 2))
})
.catch(function(error) {
console.log(error)
})
GET: No authentication using jquery
$.get("http://localhost:9950/proxy?action=block_count", function(data, status){
console.log(data)
})
GET: Authentication using jquery and ajax
$.ajax({
url: "http://localhost:9950/proxy?action=block_count",
type: "GET",
beforeSend: function(xhr){xhr.setRequestHeader('Authorization', 'Basic ' + Base64.encode('user1:user1'))},
success: function(data, status) {console.log(data)}
})
Only a certain amount of requests per time period is allowed and configured in the settings. Users who need more requests (however still affected by the "slow down rate limiter") can purchase tokens with Nano. The system requires the <use_tokens> to be active in settings.json. The system will also check orders older than 1h one time per hour and repair broken orders (by assigning tokens for any pending found), also removing unprocessed and empty orders older than one month.
- {"action":"block_count","token_key":"815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74"}
Any RPC command can be made by including a request key. For each request 1 token will be deducted and the total left will be included in each response as tokens_total.
{
"count": "24613996",
"unchecked": "0",
"cemented": "24613996",
"tokens_total": 4999
}
As an alternative, it's also valid to include the token key via the header "Token: xyz".
curl -H "Token: 815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74" -d '{"action":"block_count"}' http://127.0.0.1:9950/proxy
- {"action":"tokens_buy","token_amount":10}
Initiates a new order of 10 tokens and respond with a deposit account, a token key and the amount of Nano to pay
{
"address": "nano_3m497b1ghppe316aiu4o5eednfyueemzjf7a8wye3gi5rjrkpk1p59okghwb",
"token_key": "815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74",
"payment_amount": 0.001
}
- {"action":"tokens_buy","token_amount":10,"token_key":"815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74"}
Initiates a refill order of existing key for 10 tokens
{
"address": "nano_3m497b1ghppe316aiu4o5eednfyueemzjf7a8wye3gi5rjrkpk1p59okghwb",
"token_key": "815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74",
"payment_amount": 0.001
}
- {"action":"tokenorder_check","token_key":"815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74"}
Check status of initiated order. Either the time left to pay the order:
{
"token_key": "741eb3ad2df88427e19c9b01ec326c36c184fbcbd0bf25004982e9bb223e1acf",
"order_time_left": 135
}
Or status:
{
"error": "Order timed out for key: 741eb3ad2df88427e19c9b01ec326c36c184fbcbd0bf25004982e9bb223e1acf"
}
Or final tokens bought based on the amount paid:
{
"token_key": "741eb3ad2df88427e19c9b01ec326c36c184fbcbd0bf25004982e9bb223e1acf",
"tokens_ordered": 1000,
"tokens_total": 2000
}
- {"action":"tokenorder_cancel","token_key":"815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74"}
Reset the deposit account and return last private key to be used for recovery
{
"priv_key": "2aad399e19f926c7358a2d21d3c320e32bfedb774e0a43dba684853a1ca2cf56",
"status": "Order canceled and account replaced. You can use the private key to claim any leftover funds."
}
- {"action":"tokens_check","token_key":"815c8c736756da0965ca0994e9ac59a0da7f635aa0675184eff96a3146c49d74"}
Returns the total amount of tokens bound to the key and status of last order
{
"tokens_total": 10,
"status": "OK"
}
- {"action":"tokenprice_check"}
Returns the current price set by the server
{
"token_price": 0.0001
}
Demo of purchasing tokens using the React demo client:
A Nano node provides a websocket that can be subscribed to for real-time messages, for example block confirmation, voting analysis and telemetry. More info can be found here. Like with the RPC interface, NanoRPCProxy provides a websocket server with blacklist / DDOS protection and bandwidth limitation by only allowing certain subscriptions and data amount. It subscribes to the Nano node locally with the clients subscribing to the proxy itself to act as a secure layer and protect the node. This means only one node subscription is needed to serve all clients and several clients can listen on the same account with no increase in node communication. Thus, the node websocket does not need to be exposed publicly.
The supported messages are shown below:
Subscribe to block confirmations Just like the node you can subscribe to confirmed blocks on the network. However, one exception is you MUST specify a list of accounts. The maximum allowed number is defined in the settings parameter <websocket_max_accounts>. The account is tracked based on both "account" or "link_as_account" which means it can be used also to detect pending transactions (which would be subtype=send and the tracked account as "link_as_account").
{
"action": "subscribe",
"topic": "confirmation",
"options": {
"accounts": [<account1>,<account2>]
}
}
Response
{
"topic": "confirmation",
"time": "1590331435605",
"message": {
"account": "nano_3jsonxwips1auuub94kd3osfg98s6f4x35ksshbotninrc1duswrcauidnue",
"amount": "10000000",
"hash": "2B779B43B3CF95AFAA63AD696E6546DB7945BCE5CC5A78F670FFD41BCA998D1E",
"confirmation_type": "active_quorum",
"block": {
"type": "state",
"account": "nano_3jsonxwips1auuub94kd3osfg98s6f4x35ksshbotninrc1duswrcauidnue",
"previous": "FC5AE29E3BD13A5D8D26EA2632871D2CFE7856BF4E83E75FA90B72AC95054635",
"representative": "nano_3jsonxwips1auuub94kd3osfg98s6f4x35ksshbotninrc1duswrcauidnue",
"balance": "946740088999999996972769989996",
"link": "90A12364A96F6F31EDC3ADA115E88B3AEAEA05C6A78A79023CFDEFB4D901FCD6",
"link_as_account": "nano_36736fkckuuh89pw9df34qnapgqcxa4wfbwch635szhhpmei5z8pttkxawk1",
"signature": "9C6A45460C946387A267EE6B5AEFE17C4C036C7B5E10239BC492CAAD180B4E0AD42A02875DC7B4FEF52B5FE8FD73BA3D28E0CCF8FDCFF86AA2938822E88A600B",
"work": "bed7a7d8ab438039",
"subtype": "send"
}
}
}
If error or warnings occurs in the server when calling it the client will need to handle that. The response is (along with a http status code != 200):
The server will write a standard log depending on the "log_level" in settings.json and token_settings.json. Additionally, a request-stat.log is written in the server dir every day at midnight with a daily request count and timestamp.
The proxy server can be tested and experimented with using provided demo clients. They can also help you getting starting with your own setup.
- Locate the directory demo_clients/python/
- If you haven't, install pipenv to run the app in a virtual environment: pip install pipenv for Linux or py -m pip install --user pipenv for Windows. To call "pipenv" in Windows instead of "py -m pipenv" you can add the python script folder (provided by the installation log) to your environment PATH.
- Start the environment: pipenv shell
- Install the packages required: pipenv sync
- Test a request with "python client.py --c 1" where 1 means command example 1. Run "python client.py --help" to find out more. In windows you use "py client.py".
- To test a server that is using authentication: "python client.py --c 1 --a"
Exit pipenv: exit
- Locate the directory demo_clients/js
- Open index.html in a browser
Note: The credentials for authentication is hard coded in the javascript and to my knowledge it's not possible to hide. However, the reactjs client is compiled and thus have the creds hidden inside the app. As far as I know, that should be safe as long as the source code cred file is not shared publicly.
The only demo client that has full functionality for purchasing request tokens
To run the pre-built app:
- Locate the directory demo_clients/reactjs/build
- Open index.html in a browser (Chrome/Firefox recommended)
- If you change the user credentials in the server <creds.json> you will also need to change the reactjs/src/rpc.js credentials and re-build the app from source (instructions below). Don't share your creds file if you are going to make it live!
To run or build the app from source
- Make sure you have node.js (and react) installed. Windows Guide | Ubuntu Guide
- Locate the directory demo_clients/reactjs
- Install required libraries: "npm install" or "yarn install"
- Test the app in development mode: "npm start" or "yarn start"
- Navigate to http://localhost:3000/
- To build from source: "npm run-script build"
- The final build is located in clients/reactjs/build
- Locate the directory demo_clients/python/
- If you haven't, install pipenv to run the app in a virtual environment: pip install pipenv for Linux or py -m pip install --user pipenv for Windows. To call "pipenv" in Windows instead of "py -m pipenv" you can add the python script folder (provided by the installation log) to your environment PATH.
- Start the environment: pipenv shell
- Install the packages required: pipenv sync
- Test the app: python client.py (In windows you use "py client.py")
- Open in browser: http://127.0.0.1:5000/ (If site not reachable in Windows, you may have to disable third party firewall)
Exit pipenv: exit
- Locate the directory demo_clients/websocket_js
- Open index.html in a browser
- Locate the directory demo_clients/websocket_nodejs
- Install required libraries: "npm install"
- Open client.js and edit the accounts to track (and possibly the ws_host url)
- Test the app in development mode: "node client.js"
- Watch the console when the Nano network detects a new confirmed block
- Locate the directory demo_clients/websocket_python/
- If you haven't, install pipenv to run the app in a virtual environment: pip install pipenv for Linux or py -m pip install --user pipenv for Windows. To call "pipenv" in Windows instead of "py -m pipenv" you can add the python script folder (provided by the installation log) to your environment PATH.
- Start the environment: pipenv shell
- Install the packages required: pipenv sync
- Open client.js and edit the accounts to track (and possibly the ws_host url)
- Test the subscription with "python client.py --a nano_xxx nano_yyy". In windows you use "py client.py".
Exit pipenv: exit
The proxy allows data scraping using Prometheus. That can for example be visualized in Grafana in your browser.
The following data points are enabled (prom-client.ts):
- process_request: Counts processRequest per IP address and action
- log: Counts number of logged events
- user_rate_limited: Counts number of times an IP address is rate limited
- user_slow_down: Counts number of times an IP address is rate limited with slow down
- user_ddos: Counts number of times an IP address is rate limited from DDOS
- websocket_subscription: Counts number of times an IP has subscribed to websocket
- websocket_message: Counts number of times an IP has received a websocket message
- time_rpc_call: Times RPC calls to the Nano backend
- time_price_call: Times external call to get price information
- time_verified_call: Times external call to get verified accounts
You can whitelist Prometheus per IP or subnet via the setting: "enable_prometheus_for_ips" If you are using docker it's recommended to whitelist the whole docker subnet since a container IP can change.
Easiest way to get started with Prometheus and Grafana is to use docker-compose. That works fine together with other node or RPCProxy containers you may be running. You can put them all in the same composer or you can use a local network as shown below called "mynet" that allow different containers to talk to each other. For example several other proxy servers running in different containers.
For persistant storage you can use docker volumes or local data folders (prom_data and graf_data) as shown below (you need to create them first). For access rights in this case you need your user ID, which was "0" in this example. To get ID you can run "id -u in linux".
More info in the section about docker
Node + proxy + prometheus + grafana: docker-compose.yml.
version: "3.7"
services:
node:
image: "nanocurrency/nano:latest"
restart: "unless-stopped"
ports:
- "7075:7075"
volumes:
- "./nano_node:/root"
nanorpcproxy:
image: "nanojson/nanorpcproxy:latest"
restart: "unless-stopped"
ports:
- "9950:9950"
- "9952:9952"
volumes:
- ./:/root
prometheus:
image: prom/prometheus
user: "0"
volumes:
- ./prom_data:/prometheus
- ./prometheus.yml:/etc/prometheus/prometheus.yml
depends_on:
- nanorpcproxy
ports:
- 9090:9090
grafana:
image: grafana/grafana:latest
user: "0"
volumes:
- ./graf_data:/var/lib/grafana
depends_on:
- prometheus
ports:
- 3000:3000
prometheus + grafana using a docker network: docker-compose.yml.
version: '3.7'
services:
prometheus:
image: prom/prometheus
user: "0"
volumes:
- ./prom_data:/prometheus
- ./prometheus.yml:/etc/prometheus/prometheus.yml
ports:
- 9090:9090
grafana:
image: grafana/grafana:latest
user: "0"
volumes:
- ./graf_data:/var/lib/grafana
depends_on:
- prometheus
ports:
- 3000:3000
networks:
default:
external:
name: mynet
Before you start prometheus you also need a config file. You can have as many different jobs or targets as you like. That can be filtered later in grafana:
prometheus.yml
global:
scrape_interval: 30s
scrape_timeout: 10s
scrape_configs:
- job_name: proxy
metrics_path: /prometheus
static_configs:
- targets:
- 'nanorpcproxy:9950'
- Prometheus frontend can be accessed at http://localhost:9090
- Grafana frontend can be accessed at http://localhost:3000
- Once in grafana you can add the prometheus data source at "http://prometheus:9090"
Then you can add panels and attach to the prometheus data points that are measured by the RPCproxy. Some examples below:
- Requests per hour (1h average) grouped by RPC action (Bar gauge panel):
sum by (action)(round(rate(process_request{job="proxy"}[1h])*3600))
- Requests per hour stacked by RPC action (Graph with bars, stacked):
sum by (action)(increase(process_request{job="proxy"}[1h]))
- Total RPC requests per hour (Graph):
sum(rate(process_request{job="proxy"}[1h])*3600)
- RPC delays per RPC action (Graph):
sum by (action)(rate(time_rpc_call_sum{job="proxy"}[1h]) / rate(time_rpc_call_count{job="proxy"}[1h]))
- Websocket messages per hour (Graph):
sum(rate(websocket_message{job="proxy"}[1h])) * 3600
- Most active IPs requesting PoW with a threshold of 100 (Graph):
sum by (ip)(round(increase(process_request{job="proxy", action="work_generate"}[1d]))) > 100
- IPs DDOSed per hour grouped by IP with threshold of 1 (Graph):
sum by (ip)(round(rate(user_ddos{job="proxy"}[1h])*3600 + 1)) > 1
- Top 20 most active IPs counted as requests per day (Bar gauge, instant, horizontal):
topk(20,sum by (ip)(increase(process_request{job="proxy"}[1d])))
- Top 20 most slowed downed IPs per week (Bar gauge, instant, horizontal):
topk(20,sum by (ip)(max_over_time(user_slow_down{job="proxy"}[1w])))
Find this useful? Consider sending me a Nano donation at nano_1gur37mt5cawjg5844bmpg8upo4hbgnbbuwcerdobqoeny4ewoqshowfakfo
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