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BNB Smart Chain (BSC) Quick Start

SubQuery TeamAbout 4 min

BNB Smart Chain (BSC) Quick Start

The goal of this quick start guide is to index all deposits and withdrawls to MOBOX pools. MOBOXopen in new window has built a unique infrastructure that builds on the growing DeFi ecosystem and combines it with Gaming through unique NFTs. Using Liquidity Pools, Yield Farming, and NFTs, the GameFi infrastructure will not just find the best yield strategies for users but also generate unique NFTs that can be used across a multitude of games.

In the earlier Quickstart section , you should have taken note of three crucial files. To initiate the setup of a project from scratch, you can proceed to follow the steps outlined in the initialisation description.

As a prerequisite, you will need to generate types from the ABI files of each smart contract. Additionally, you can kickstart your project by using the EVM Scaffolding approach (detailed here). You'll find all the relevant events to be scaffolded in the documentation for each type of smart contract.

Note

The final code of this project can be found hereopen in new window.

Check out how to get the BSC starter project running

Your Project Manifest File

The Project Manifest file is an entry point to your project. It defines most of the details on how SubQuery will index and transform the chain data.

For EVM chains, there are three types of mapping handlers (and you can have more than one in each project):

  • BlockHanders: On each and every block, run a mapping function
  • TransactionHandlers: On each and every transaction that matches optional filter criteria, run a mapping function
  • LogHanders: On each and every log that matches optional filter criteria, run a mapping function

Important

We use Ethereum packages, runtimes, and handlers (e.g. @subql/node-ethereum, ethereum/Runtime, and ethereum/*Handler) for BNB Smart Chain (BSC). Since BSC is a layer-2 scaling solution, we can use the core Ethereum framework to index it.

Note that the manifest file has already been set up correctly and doesn’t require significant changes, but you need to import the correct contract definitions and update the datasource handlers.

We are indexing actions from the MOBOX Farming contract, first you will need to import the contract abi definition from hereopen in new window. You can copy the entire JSON and save as a file mobox.abi.json in the root directory.

This section in the Project Manifest now imports all the correct definitions and lists the triggers that we look for on the blockchain when indexing.

Since you are going to index all MOBOX Deposits and Withdrawls, you need to update the datasources section as follows:

{
  dataSources: [
    {
      kind: EthereumDatasourceKind.Runtime,
      startBlock: 17047980, //The block on which the Mobox Farming contract was deployed

      options: {
        // Must be a key of assets
        abi: "mobox_abi",
        // this is the contract address for Mobox Farming contract https://bscscan.com/address/0xa5f8c5dbd5f286960b9d90548680ae5ebff07652#code
        address: "0xa5f8c5dbd5f286960b9d90548680ae5ebff07652",
      },
      assets: new Map([["mobox_abi", { file: "mobox.abi.json" }]]),
      mapping: {
        file: "./dist/index.js",
        handlers: [
          {
            kind: EthereumHandlerKind.Event,
            handler: "handleDeposit",
            filter: {
              topics: [
                "Deposit(address indexed user, uint256 indexed pid, uint256 amount)",
              ],
            },
          },
          {
            kind: EthereumHandlerKind.Event,
            handler: "handleWithdraw",
            filter: {
              topics: [
                "Withdraw(address indexed user, uint256 indexed pid, uint256 amount)",
              ],
            },
          },
        ],
      },
    },
  ],
}

The above code indicates that you will be running a handleDeposit mapping function whenever there is an Deposit log on any transaction from the MOBOX Farming contractopen in new window. Simarly, you'll be running a handleWithdraw mapping function whenever there is an Withdraw logs.

Check out our Manifest File documentation to get more information about the Project Manifest (project.ts) file.

Update Your GraphQL Schema File

The schema.graphql file determines the shape of your data from SubQuery due to the mechanism of the GraphQL query language. Hence, updating the GraphQL Schema file is the perfect place to start. It allows you to define your end goal right at the start.

Remove all existing entities and update the schema.graphql file as follows. Here you can see we are indexing three entities, a Deposit and a Withdrawl each with a foreign key relationship to the User.

type PoolEvent @entity {
  id: ID! # Transaction_hash-log_index
  user: String!
  pool: Pool! # Foreign key
  type: String! # WITHDRAW or DEPOSIT
  value: BigInt!
  block: BigInt!
  timestamp: BigInt!
}

type Pool @entity {
  id: ID! # Pool ID
  totalSize: BigInt!
}

Note

Importantly, these relationships can not only establish one-to-many connections but also extend to include many-to-many associations. To delve deeper into entity relationships, you can refer to this section. If you prefer a more example-based approach, our dedicated Hero Course Module can provide further insights.

SubQuery simplifies and ensures type-safety when working with GraphQL entities, smart contracts, events, transactions, and logs. The SubQuery CLI will generate types based on your project's GraphQL schema and any contract ABIs included in the data sources.

yarn
yarn codegen

This action will generate a new directory (or update the existing one) named src/types. Inside this directory, you will find automatically generated entity classes corresponding to each type defined in your schema.graphql. These classes facilitate type-safe operations for loading, reading, and writing entity fields. You can learn more about this process in the GraphQL Schema section.

It will also generate a class for every contract event, offering convenient access to event parameters, as well as information about the block and transaction from which the event originated. You can find detailed information on how this is achieved in the EVM Codegen from ABIs section. All of these types are stored in the src/types/abi-interfaces and src/types/contracts directories.

You can conveniently import all these types:

In the example BSC SubQuery project, you would import these types like so.

import { DepositLog, WithdrawLog } from "../types/abi-interfaces/MoboxAbi";

Check out the GraphQL Schema documentation to get in-depth information on schema.graphql file.

Now that you have made essential changes to the GraphQL Schema file, let’s proceed ahead with the Mapping Function’s configuration.

Add a Mapping Function

Mapping functions define how blockchain data is transformed into the optimised GraphQL entities that we previously defined in the schema.graphql file.

Navigate to the default mapping function in the src/mappings directory. You will be able to see three exported functions: handleBlock, handleLog, and handleTransaction. Replace these functions with the following code (note the additional imports):

import { Pool, PoolEvent } from "../types";
import { DepositLog, WithdrawLog } from "../types/abi-interfaces/MoboxAbi";

async function checkGetPool(id: string): Promise<Pool> {
  // Try get an existing Pool record first by ID
  let poolRecord = await Pool.get(id);
  if (!poolRecord) {
    // Pool record does not exist, create one
    poolRecord = Pool.create({
      id: id,
      totalSize: BigInt(0),
    });
    await poolRecord.save();
  }
  return poolRecord;
}

export async function handleDeposit(deposit: DepositLog): Promise<void> {
  logger.info(`New deposit transaction log at block ${deposit.blockNumber}`);
  const poolId = deposit.args[1].toString();

  // Check and get the pool record from the store
  const poolRecord = await checkGetPool(poolId);

  const poolEventRecord = PoolEvent.create({
    id: `${deposit.transactionHash}-${deposit.logIndex}`,
    user: deposit.args[0],
    poolId,
    type: "DEPOSIT",
    value: deposit.args[2].toBigInt(),
    block: BigInt(deposit.blockNumber),
    timestamp: deposit.block.timestamp,
  });
  await poolEventRecord.save();

  // Increase the total pool size by the new deposit value
  poolRecord.totalSize += poolEventRecord.value;
  await poolRecord.save();
}

export async function handleWithdraw(withdraw: WithdrawLog): Promise<void> {
  logger.info(`New withdraw transaction log at block ${withdraw.blockNumber}`);
  const poolId = withdraw.args[1].toString();

  // Check and get the pool record from the store
  const poolRecord = await checkGetPool(poolId);

  const poolEventRecord = PoolEvent.create({
    id: `${withdraw.transactionHash}-${withdraw.logIndex}`,
    user: withdraw.args[0],
    poolId,
    type: "WITHDRAW",
    value: withdraw.args[2].toBigInt(),
    block: BigInt(withdraw.blockNumber),
    timestamp: withdraw.block.timestamp,
  });
  await poolEventRecord.save();

  // Decrease the total pool size by the new withdrawl value
  poolRecord.totalSize -= poolEventRecord.value;
  await poolRecord.save();
}

Let’s understand how the above code works.

For handleDeposit, the function here receives an DepositLog which includes transaction log data in the payload. We extract this data and first confirm if we have a Pool record via the checkGetPool function. We then create a new PoolEvent entity that we defined in our schema.graphql and then save this to the store using the .save() function (Note that SubQuery will automatically save this to the database). We also increase the total pool size by the new deposit value.

For handleWithdraw, the function here receives an WithdrawLog which includes transaction log data in the payload. We extract this data and first confirm if we have a Pool record via checkGetPool. We then create a new PoolEvent entity that we defined in our schema.graphql and then save this to the store using the .save() function (Note that SubQuery will automatically save this to the database). We also decrease the total pool size by the new withdraw value.

Note

For more information on mapping functions, please refer to our Mappings documentation.

Build Your Project

Next, build your work to run your new SubQuery project. Run the build command from the project's root directory as given here:

yarn
yarn build

Important

Whenever you make changes to your mapping functions, you must rebuild your project.

Now, you are ready to run your first SubQuery project. Let’s check out the process of running your project in detail.

Whenever you create a new SubQuery Project, first, you must run it locally on your computer and test it and using Docker is the easiest and quickiest way to do this.

Run Your Project Locally with Docker

The docker-compose.yml file defines all the configurations that control how a SubQuery node runs. For a new project, which you have just initialised, you won't need to change anything.

However, visit the Running SubQuery Locally to get more information on the file and the settings.

Run the following command under the project directory:

yarn
yarn start:docker

Note

It may take a few minutes to download the required images and start the various nodes and Postgres databases.

Query your Project

Next, let's query our project. Follow these three simple steps to query your SubQuery project:

  1. Open your browser and head to http://localhost:3000.

  2. You will see a GraphQL playground in the browser and the schemas which are ready to query.

  3. Find the Docs tab on the right side of the playground which should open a documentation drawer. This documentation is automatically generated and it helps you find what entities and methods you can query.

Try the following queries to understand how it works for your new SubQuery starter project. Don’t forget to learn more about the GraphQL Query language.

query {
  pools(first: 5, orderBy: TOTAL_SIZE_DESC) {
    nodes {
      id
      totalSize

      poolEvents(first: 5, orderBy: BLOCK_DESC) {
        nodes {
          id
          user
          type
          value
          block
          timestamp
        }
      }
    }
  }

  poolEvents(
    first: 5
    orderBy: VALUE_DESC
    filter: { type: { equalTo: "DEPOSIT" } }
  ) {
    nodes {
      id
      user
      type
      value
      block
      timestamp
    }
  }
}

You will see the result similar to below:

{
  "data": {
    "pools": {
      "nodes": [
        {
          "id": "81",
          "totalSize": "13939264748979290786527",
          "poolEvents": {
            "nodes": [
              {
                "id": "0x59226923047c9b8735432c8fbb9a5d7e1cfc6c6d68dafda4c53d1a7a11245de4-179",
                "user": "0x0D609B116F522e2aA4c81E71C019e3f72e5b84D3",
                "type": "DEPOSIT",
                "value": "13939264748979290786527",
                "block": "27271611",
                "timestamp": "1681267330"
              }
            ]
          }
        },
        {
          "id": "151",
          "totalSize": "75132986946987564601",
          "poolEvents": {
            "nodes": [
              {
                "id": "0xf2b3573544c13984145ca60906af3e41939445be435899a87ffe2e790d305446-73",
                "user": "0xBC02786613fFeE0CE5463E75f2F4064242B426d3",
                "type": "DEPOSIT",
                "value": "75132986946987564601",
                "block": "27272165",
                "timestamp": "1681268992"
              }
            ]
          }
        },
        {
          "id": "146",
          "totalSize": "52930427574604055961",
          "poolEvents": {
            "nodes": [
              {
                "id": "0xcd041afa3d59664c83a2e625339cb2e380f41cfd649b37894937335722851b9a-200",
                "user": "0x0D609B116F522e2aA4c81E71C019e3f72e5b84D3",
                "type": "DEPOSIT",
                "value": "52930427574604055961",
                "block": "27271989",
                "timestamp": "1681268464"
              }
            ]
          }
        },
        {
          "id": "163",
          "totalSize": "51987044530503846595",
          "poolEvents": {
            "nodes": [
              {
                "id": "0x9c4f9d3033addb662f755ce4c805a0710fcc0ef992963e65e4fca600d16575db-196",
                "user": "0xB5C0D7272591f148F0BD75b1cCD33B6955aA0C62",
                "type": "DEPOSIT",
                "value": "51987044530503846595",
                "block": "27271638",
                "timestamp": "1681267411"
              }
            ]
          }
        },
        {
          "id": "156",
          "totalSize": "9489053677969718728",
          "poolEvents": {
            "nodes": [
              {
                "id": "0x6a60d52fc81026f0ec4d20a16e9e0c3bb574bf9f758f8dc712e78101fff1b203-156",
                "user": "0x6de5F722870a06fe1a0811D5947fefD762CF748b",
                "type": "DEPOSIT",
                "value": "9489053677969718728",
                "block": "27271740",
                "timestamp": "1681267717"
              },
              {
                "id": "0x8c4e211e4f8347818d2a09743ecd3513261bfa1fea1d4717e7ff9935df9cbe04-151",
                "user": "0xc597CefF4AC988D5fAc9863d68458D7EBe1a7de7",
                "type": "DEPOSIT",
                "value": "0",
                "block": "27271220",
                "timestamp": "1681266142"
              }
            ]
          }
        }
      ]
    },
    "poolEvents": {
      "nodes": [
        {
          "id": "0x1c18697f1ba02f646ca5aa07fb7463b55500ac0d3f6c91bc880be0aff3a47730-313",
          "user": "0x83A5d5c54Ad83bBeA8667B3B95d7610E16e52723",
          "type": "DEPOSIT",
          "value": "93987418736549051250510",
          "block": "27271662",
          "timestamp": "1681267483"
        },
        {
          "id": "0x1c18697f1ba02f646ca5aa07fb7463b55500ac0d3f6c91bc880be0aff3a47730-277",
          "user": "0x4b70c41F514FBBEa718234Ac72f36c1b077a4162",
          "type": "DEPOSIT",
          "value": "69556634968703436638903",
          "block": "27271662",
          "timestamp": "1681267483"
        },
        {
          "id": "0x59226923047c9b8735432c8fbb9a5d7e1cfc6c6d68dafda4c53d1a7a11245de4-179",
          "user": "0x0D609B116F522e2aA4c81E71C019e3f72e5b84D3",
          "type": "DEPOSIT",
          "value": "13939264748979290786527",
          "block": "27271611",
          "timestamp": "1681267330"
        },
        {
          "id": "0xf2b3573544c13984145ca60906af3e41939445be435899a87ffe2e790d305446-73",
          "user": "0xBC02786613fFeE0CE5463E75f2F4064242B426d3",
          "type": "DEPOSIT",
          "value": "75132986946987564601",
          "block": "27272165",
          "timestamp": "1681268992"
        },
        {
          "id": "0xcd041afa3d59664c83a2e625339cb2e380f41cfd649b37894937335722851b9a-200",
          "user": "0x0D609B116F522e2aA4c81E71C019e3f72e5b84D3",
          "type": "DEPOSIT",
          "value": "52930427574604055961",
          "block": "27271989",
          "timestamp": "1681268464"
        }
      ]
    }
  }
}

Note

The final code of this project can be found hereopen in new window.

What's next?

Congratulations! You have now a locally running SubQuery project that accepts GraphQL API requests for transferring data.

Tip

Find out how to build a performant SubQuery project and avoid common mistakes in Project Optimisation.

Click here to learn what should be your next step in your SubQuery journey.