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Version: FireSquid

Run squids with Ganache or Hardhat


This tutorial will show you how it's possible to start using Subsquid from the very early stages of development. Simply by using a pre-built docker image of Subsquid's EVM Archive, you'll be able to index your Ethereum development node running locally.

This way, it's possible to start developing a squid ETL or API in the same local development environment where your smart contract or frontend is being developed, without waiting for the contract to be deployed to a testnet.



For the purpose of this tutorial, we are going to start with a squid project, then add a Hardhat/Ganache setup to the same folder. This is done only for keeping this tutorial simple. For more complicated projects you would probably want to separate those two.


In order to create a new squid project, open a terminal and launch the command:

sqd init ethereum-local-indexing -t evm

Here, ethereum-local-indexing is the project name we chose and -t evm tells sqd init to use the evm template.

The next two sections are instructions dedicated to the two main options for local Ethereum development: Hardhat and Ganache. Choose according to your preference and follow only one of the two setups.


In order to start working with Hardhat, it's necessary to install the package.

1. Create project

In a terminal, navigate to the squid project root folder. Prepare it by running

mv tsconfig.json

This will prevent collisions between Subsquid and Hardhat files.

Next, run

npx hardhat

to initialize the Hardhat project. When prompted, choose TypeScript project and keep all other options at defaults. Finally, overwrite tsconfig.json provided by Hardhat:

mv tsconfig.json

2. Configure Hardhat automining

Then, open the hardhat.config.ts and add this in the HardhatUserConfig object:

const config: HardhatUserConfig = {
defaultNetwork: "hardhat",
networks: {
hardhat: {
chainId: 1337,
mining: {
auto: false,
interval: [4800, 5200]
solidity: "0.8.17",

The mining configuration will continuously mine blocks, even if no events or transactions are executed. This can be useful for debugging. You can read more about it on hardhat official documentation.

3. Sample contract

There should be a contracts subfolder in the project folder now, with a sample contract named Lock.sol. To compile this contract and verify its correctness, run

npx hardhat compile

You should find the contract's ABI at artifacts/contracts/Lock.sol/Lock.json. This file will be useful in squid development.

4. Launch hardhat node

From the project root folder, run

npx hardhat node

5. Deploy the contract

The node will keep the console window busy. In a different terminal, run this command:

npx hardhat run scripts/deploy.ts --network localhost
Lock with 1 ETH and unlock timestamp 1704810454 deployed to 0x5FbDB2315678afecb367f032d93F642f64180aa3

You should see a log file confirming the successful deployment, like the second line in the code box above. Take note of the contract address, you'll need it later.


In order to start working with Ganache node, it's necessary to Install Truffle and Ganache packages.

1. Truffle project, sample contract

Let's create a new truffle project with a sample contract. In a terminal navigate to the project's main folder and run

truffle unbox metacoin

To compile the contracts, launch this command in the same console window:

truffle compile

You should find the contract's ABI at the location: build/contracts/MetaCoin.json, it will be useful for indexing.

2. Create a workspace

Launch the Ganache tool and select the New Workspace (Ethereum) option.

Create workspace

Next, provide a name for the workspace and link the Truffle project we just created to it. To do that, click Add project and select the truffle-config.js file in the project root folder. Finally, select the Server tab at the top.

Provide name

In this window, change the server configuration to the exact values reported in this image.

Server configuration


Note: It is not mandatory to change PORT NUMBER or NETWORK ID, but they are set to the same value as Hardhat, so the rest of the Tutorial will look the same.

The AUTOMINE option is disabled to ease the debugging, same as in the Hardhat section of this tutorial.

Finally, click "Save Workspace" to launch the blockchain emulator.

3. Deploy smart contract

Configure Truffle by uncommenting the development section in truffle-config.js and setting its properties as follows:

    development: {
host: "", // Localhost (default: none)
port: 8545, // Standard Ethereum port (default: none)
network_id: "1337", // Any network (default: none)

Deploy the sample smart contract by running

truffle migrate

Log information similar to this should be displayed:

   Deploying 'MetaCoin'
> transaction hash: 0xcdb820827306ebad7c6905d750d07536c3db93f4ef76fd777180bdac16eaa2ca
> Blocks: 1 Seconds: 4
> contract address: 0xd095211a90268241D75919f12397b389b1062f6F
> block number: 329
> block timestamp: 1673277461
> account: 0x131D37F433BAf649111278c1d6E59843fFB26D28
> balance: 99.98855876
> gas used: 414494 (0x6531e)
> gas price: 20 gwei
> value sent: 0 ETH
> total cost: 0.00828988 ETH

> Saving artifacts
> Total cost: 0.01144124 ETH

Take note of the contract address, you'll need it later.

Archive Docker image

In order to index the local Ethereum node, we need to use a pre-built Docker image of Subsquid's Ethereum Archive. You can do it, by creating a docker-compose.archive.yml file, and paste this:

version: "3"

image: subsquid/eth-archive-worker:latest
RUST_LOG: "info"
- 8080:8080
command: [
"--server-addr", "",
"--db-path", "/data/db",
"--request-timeout-secs", "300",
"--connect-timeout-ms", "1000",
"--block-batch-size", "10",
"--http-req-concurrency", "10",
"--best-block-offset", "10",
"--rpc-urls", "http://host.docker.internal:8545/",
"--max-resp-body-size", "30",
"--resp-time-limit", "5000",
"--query-concurrency", "16",
- db:/data/db
- "host.docker.internal:host-gateway"


Then start the service by opening the terminal and launching the command:

docker compose -f docker-compose.archive.yml up -d

Squid development

Now you can poke your smart contract however you please, and index events or transactions with Subsquid's SDK. Use the contract's ABI (here or here) and contract address (here and here) from previous steps.

To develop your squid ETL, indexing events of your smart contract, please head over to the dedicated tutorial. Just be mindful that the data source of the processor class needs to be set to the local endpoints:

// ...

const processor = new EvmBatchProcessor()
chain: "localhost:8545",
archive: "localhost:8080",

// ...

You can also use environment variables, just like shown in this complete end-to-end project example. This will make sure the project code stays the same and only the environment variables change depending on where the project is deployed.