Gelato-automations/test_temp/3_Partial-Refinance-External-Provider.test.js

const {expect} = require("chai");
const hre = require("hardhat");
const {ethers} = hre;
const GelatoCoreLib = require("@gelatonetwork/core");

// #region Contracts ABI and Constants

const InstaIndex = require("../pre-compiles/InstaIndex.json");
const InstaList = require("../pre-compiles/InstaList.json");
const InstaAccount = require("../pre-compiles/InstaAccount.json");
const ConnectGelato = require("../pre-compiles/ConnectGelato.json");
const ConnectMaker = require("../pre-compiles/ConnectMaker.json");
const ConnectCompound = require("../pre-compiles/ConnectCompound.json");
const ConnectInstaPool = require("../pre-compiles/ConnectInstaPool.json");
const ConnectAuth = require("../pre-compiles/ConnectAuth.json");
const ConnectGelatoDebtBridgeFromMakerABI = require("../artifacts/contracts/connectors/ConnectGelatoDebtBridgeFromMaker.sol/ConnectGelatoDebtBridgeFromMaker.json")
  .abi;
const ConnectGelatoProviderPaymentABI = require("../artifacts/contracts/connectors/ConnectGelatoProviderPayment.sol/ConnectGelatoProviderPayment.json")
  .abi;
const InstaConnector = require("../pre-compiles/InstaConnectors.json");
const DssCdpManager = require("../pre-compiles/DssCdpManager.json");
const GetCdps = require("../pre-compiles/GetCdps.json");
const IERC20 = require("../pre-compiles/IERC20.json");
const CTokenInterface = require("../pre-compiles/CTokenInterface.json");
const CompoundResolver = require("../pre-compiles/InstaCompoundResolver.json");
const PriceOracleResolverABI = require("../artifacts/contracts/resolvers/PriceOracleResolver.sol/PriceOracleResolver.json")
  .abi;

const ETH = "0xEeeeeEeeeEeEeeEeEeEeeEEEeeeeEeeeeeeeEEeE";
const GAS_LIMIT = "4000000";
const GAS_PRICE_CEIL = ethers.utils.parseUnits("1000", "gwei");
const WAD = ethers.utils.parseUnits("1", 18);

// const ORACLE_MAKER_ETH_USD = "ETH/USD-Maker-v1";
// const ORACLE_MAKER_ETH_USD_ADDR = "0x729D19f657BD0614b4985Cf1D82531c67569197B";
// const PRICE_ORACLE_MAKER_PAYLOAD = "0x57de26a4"; // IMakerOracle.read()

const MIN_COL_RATIO_MAKER = ethers.utils.parseUnits("3", 18);
const MIN_COL_RATIO_B = ethers.utils.parseUnits("19", 17);

// TO DO: make dynamic based on real time Collateral Price and Ratios
const MAKER_INITIAL_ETH = ethers.utils.parseEther("10");
const MAKER_INITIAL_DEBT = ethers.utils.parseUnits("1000", 18);

// #endregion

//#region Mock Math Function

function wdiv(x, y) {
  return x.mul(WAD).add(y.div(2)).div(y);
}

function wmul(x, y) {
  return x.mul(y).add(WAD.div(2)).div(WAD);
}

function wCalcCollateralToWithdraw(
  minColRatioOnMaker,
  minColRatioOnPositionB,
  collateralPrice,
  pricedCollateral,
  daiDebtOnMaker
) {
  //#region CALCULATION REPLICATION

  let expectedColToWithdraw = wmul(
    wmul(minColRatioOnMaker, minColRatioOnPositionB),
    daiDebtOnMaker
  ); // doc ref : c_r x comp_r x d_2
  expectedColToWithdraw = expectedColToWithdraw.sub(
    wmul(minColRatioOnMaker, pricedCollateral)
  ); // doc ref : c_r x comp_r x d_2 - c_r x e_2
  expectedColToWithdraw = wdiv(
    expectedColToWithdraw,
    minColRatioOnPositionB.sub(minColRatioOnMaker)
  ); // doc ref : (c_r x comp_r x d_2 - c_r x e_2)/ (comp_r - c_r)
  expectedColToWithdraw = pricedCollateral.sub(expectedColToWithdraw); // doc ref : e_2 - ((c_r x comp_r x d_2 - c_r x e_2)/ (comp_r - c_r))

  // Extra step to convert back to col type
  expectedColToWithdraw = wdiv(expectedColToWithdraw, collateralPrice);

  //#endregion
  return expectedColToWithdraw;
}

function wCalcDebtToRepay(
  minColRatioOnMaker,
  minColRatioOnPositionB,
  pricedCollateral,
  daiDebtOnMaker
) {
  //#region CALCULATION REPLICATION

  let expectedBorToPayBack = wmul(
    wmul(minColRatioOnMaker, minColRatioOnPositionB),
    daiDebtOnMaker
  ); // doc ref : c_r x comp_r x d_2
  expectedBorToPayBack = expectedBorToPayBack.sub(
    wmul(minColRatioOnMaker, pricedCollateral)
  ); // doc ref : c_r x comp_r x d_2 - c_r x e_2
  expectedBorToPayBack = wdiv(
    expectedBorToPayBack,
    minColRatioOnPositionB.sub(minColRatioOnMaker)
  ); // doc ref : (c_r x comp_r x d_2 - c_r x e_2)/ (comp_r - c_r)
  expectedBorToPayBack = wmul(
    wdiv(ethers.utils.parseUnits("1", 18), minColRatioOnMaker),
    expectedBorToPayBack
  ); // doc ref : (1/c_r)((c_r x comp_r x d_2 - c_r x e_2)/ (comp_r - c_r))
  expectedBorToPayBack = daiDebtOnMaker.sub(expectedBorToPayBack); // doc ref : d_2 - (1/c_r)((c_r x comp_r x d_2 - c_r x e_2)/ (comp_r - c_r))

  //#endregion
  return expectedBorToPayBack;
}

//#endregion

describe("Debt Bridge with External Provider", function () {
  this.timeout(0);
  if (hre.network.name !== "hardhat") {
    console.error("Test Suite is meant to be run on hardhat only");
    process.exit(1);
  }

  // Wallet to use for local testing
  let userWallet;
  let userAddress;
  let providerWallet;
  let providerAddress;
  let executorWallet;
  let executorAddress;

  // Deployed instances
  let connectGelato;
  let connectMaker;
  let connectInstaPool;
  let connectCompound;
  let instaIndex;
  let instaList;
  let dssCdpManager;
  let getCdps;
  let daiToken;
  let gelatoCore;
  let cDaiToken;
  let cEthToken;
  let instaMaster;
  let instaConnectors;
  let compoundResolver;

  // Contracts to deploy and use for local testing
  let conditionMakerVaultUnsafe;
  let connectGelatoDebtBridgeFromMaker;
  let connectGelatoProviderPayment;
  let priceOracleResolver;
  let dsaProviderModule;

  // Creation during test
  let dsa;

  // Payload Params for ConnectGelatoDebtBridgeFromMaker and ConditionMakerVaultUnsafe
  let vaultId;

  // For TaskSpec and for Task
  let spells = [];

  before(async function () {
    // Get Test Wallet for local testnet
    [userWallet, providerWallet, executorWallet] = await ethers.getSigners();
    userAddress = await userWallet.getAddress();
    providerAddress = await providerWallet.getAddress();
    executorAddress = await executorWallet.getAddress();

    instaMaster = await ethers.provider.getSigner(
      hre.network.config.InstaMaster
    );

    // Hardhat default accounts prefilled with 100 ETH
    expect(await userWallet.getBalance()).to.be.gt(
      ethers.utils.parseEther("10")
    );

    // ===== Get Deployed Contract Instance ==================
    instaIndex = await ethers.getContractAt(
      InstaIndex.abi,
      hre.network.config.InstaIndex
    );
    instaList = await ethers.getContractAt(
      InstaList.abi,
      hre.network.config.InstaList
    );
    connectGelato = await ethers.getContractAt(
      ConnectGelato.abi,
      hre.network.config.ConnectGelato
    );
    connectMaker = await ethers.getContractAt(
      ConnectMaker.abi,
      hre.network.config.ConnectMaker
    );
    connectInstaPool = await ethers.getContractAt(
      ConnectInstaPool.abi,
      hre.network.config.ConnectInstaPool
    );
    connectCompound = await ethers.getContractAt(
      ConnectCompound.abi,
      hre.network.config.ConnectCompound
    );
    dssCdpManager = await ethers.getContractAt(
      DssCdpManager.abi,
      hre.network.config.DssCdpManager
    );
    getCdps = await ethers.getContractAt(
      GetCdps.abi,
      hre.network.config.GetCdps
    );
    daiToken = await ethers.getContractAt(IERC20.abi, hre.network.config.DAI);
    gelatoCore = await ethers.getContractAt(
      GelatoCoreLib.GelatoCore.abi,
      hre.network.config.GelatoCore
    );
    cDaiToken = await ethers.getContractAt(
      CTokenInterface.abi,
      hre.network.config.CDAI
    );
    cEthToken = await ethers.getContractAt(
      CTokenInterface.abi,
      hre.network.config.CETH
    );
    instaConnectors = await ethers.getContractAt(
      InstaConnector.abi,
      hre.network.config.InstaConnectors
    );
    compoundResolver = await ethers.getContractAt(
      CompoundResolver.abi,
      hre.network.config.CompoundResolver
    );
    // instaEvent = await ethers.getContractAt(
    //     InstaEvent.abi,
    //     hre.network.config.InstaEvent
    // )

    // ===== Deploy Needed Contract ==================

    const PriceOracleResolver = await ethers.getContractFactory(
      "PriceOracleResolver"
    );
    priceOracleResolver = await PriceOracleResolver.deploy();
    await priceOracleResolver.deployed();

    const ConditionMakerVaultUnsafe = await ethers.getContractFactory(
      "ConditionMakerVaultUnsafe"
    );
    conditionMakerVaultUnsafe = await ConditionMakerVaultUnsafe.deploy();
    await conditionMakerVaultUnsafe.deployed();

    const ConnectGelatoDebtBridgeFromMaker = await ethers.getContractFactory(
      "ConnectGelatoDebtBridgeFromMaker"
    );
    connectGelatoDebtBridgeFromMaker = await ConnectGelatoDebtBridgeFromMaker.deploy(
      (await instaConnectors.connectorLength()).add(1)
    );
    await connectGelatoDebtBridgeFromMaker.deployed();

    const ConnectGelatoProviderPayment = await ethers.getContractFactory(
      "ConnectGelatoProviderPayment"
    );
    connectGelatoProviderPayment = await ConnectGelatoProviderPayment.deploy(
      (await instaConnectors.connectorLength()).add(2)
    );
    await connectGelatoProviderPayment.deployed();

    const ProviderModuleDSA = await ethers.getContractFactory(
      "ProviderModuleDSA"
    );
    dsaProviderModule = await ProviderModuleDSA.deploy(
      hre.network.config.GelatoCore,
      connectGelatoProviderPayment.address
    );
    await dsaProviderModule.deployed();

    ///////////////////////////////////////////////////////////////////////////////////////////////////
    ///////////////////////////////////////////////////////////////////////////////////////////////////
    ///////////////////////////////   After Contracts Deployement : Setup   ///////////////////////////
    ///////////////////////////////////////////////////////////////////////////////////////////////////
    ///////////////////////////////////////////////////////////////////////////////////////////////////

    // Gelato Testing environment setup.
    // Step 1 : Add EUR/USD Maker Medianizer in the PriceOracleResolver
    // Step 2 : Enable Debt Bridge Connector and Gelato Provider Payment Connector
    // Step 3 : Executor Staking on Gelato
    // Step 4 : Provider put some fund on gelato for paying future tasks executions
    // Step 5 : Provider choose a executor
    // Step 6 : Provider will add a module
    // Step 7 : User create a DeFi Smart Account
    // Step 8 : User open a Vault, put some ether on it and borrow some dai
    // Step 9 : User give authorization to gelato to use his DSA on his behalf.
    // Step 10 : Provider should whitelist task

    //#region Step 1 Add EUR/USD Maker Medianizer in the PriceOracleResolver

    // PriceOracleResolver is a price feeder aggregator
    // You will be able to query price from multiple source through this aggregator
    // For the demo we add the ETH/USD Medianizer to the aggregator
    // MakerDAO price oracle are called Medianizer

    // await priceOracleResolver.addOracle(
    //   ORACLE_MAKER_ETH_USD,
    //   ORACLE_MAKER_ETH_USD_ADDR,
    //   PRICE_ORACLE_MAKER_PAYLOAD
    // );

    //#endregion

    //#region Step 2 Enable Debt Bridge Connector and Gelato Provider Payment Connector

    // Debt Bridge Connector is used during refinancing of debt
    // This Connect help the user to split a position in one protocol.
    // to 2 protocol in a safe way. Both debt position will be safe.

    // Gelato Provider Payment Connector is used for paying the provider
    // for task execution. So when futur task will be executed, through a self financing
    // transaction (user will pay during the execution of the task) task will
    // be executed. Improvind user experience.

    await userWallet.sendTransaction({
      to: hre.network.config.InstaMaster,
      value: ethers.utils.parseEther("0.1"),
    });

    await hre.network.provider.request({
      method: "hardhat_impersonateAccount",
      params: [await instaMaster.getAddress()],
    });

    await instaConnectors
      .connect(instaMaster)
      .enable(connectGelatoDebtBridgeFromMaker.address);

    await instaConnectors
      .connect(instaMaster)
      .enable(connectGelatoProviderPayment.address);

    await hre.network.provider.request({
      method: "hardhat_stopImpersonatingAccount",
      params: [await instaMaster.getAddress()],
    });

    expect(
      await instaConnectors.isConnector([
        connectGelatoDebtBridgeFromMaker.address,
      ])
    ).to.be.true;
    expect(
      await instaConnectors.isConnector([connectGelatoProviderPayment.address])
    ).to.be.true;

    //#endregion

    //#region Step 3  Executor Staking on Gelato

    // For task execution provider will ask a executor to watch the
    // blockchain for possible execution autorization given by
    // the condition that user choose when submitting the task.
    // And if all condition are meet executor will execute the task.
    // For safety measure Gelato ask the executor to stake a minimum
    // amount.

    await gelatoCore.connect(executorWallet).stakeExecutor({
      value: await gelatoCore.minExecutorStake(),
    });

    expect(await gelatoCore.isExecutorMinStaked(executorAddress)).to.be.true;

    //#endregion

    //#region Step 4 Provider put some fund on gelato for paying future tasks executions

    // Provider put some funds in gelato system for paying the
    // Executor when this one will execute task on behalf of the
    // Provider. At each provider's task execution, some funds (approximatively
    // the gas cost value) will be transfered to the Executor stake.

    const TASK_AUTOMATION_FUNDS = await gelatoCore.minExecProviderFunds(
      GAS_LIMIT,
      GAS_PRICE_CEIL
    );

    await expect(
      gelatoCore.connect(providerWallet).provideFunds(providerAddress, {
        value: TASK_AUTOMATION_FUNDS,
      })
    ).to.emit(gelatoCore, "LogFundsProvided");

    expect(await gelatoCore.providerFunds(providerAddress)).to.be.equal(
      TASK_AUTOMATION_FUNDS
    );

    //#endregion

    //#region Step 5 Provider choose a executor

    // Provider choose a executor who will execute futur task
    // for the provider, it will be compensated by the provider.

    await expect(
      gelatoCore
        .connect(providerWallet)
        .providerAssignsExecutor(executorAddress)
    ).to.emit(gelatoCore, "LogProviderAssignedExecutor");

    expect(await gelatoCore.executorByProvider(providerAddress)).to.be.equal(
      executorAddress
    );

    //#endregion

    //#region Step 6 Provider will add a module

    // By adding a module the provider will format future task's
    // payload by adding some specificity like his address to the
    // Payment connector for receiving payment of User.

    await expect(
      gelatoCore
        .connect(providerWallet)
        .addProviderModules([dsaProviderModule.address])
    ).to.emit(gelatoCore, "LogProviderModuleAdded");

    expect(
      await gelatoCore
        .connect(providerWallet)
        .isModuleProvided(providerAddress, dsaProviderModule.address)
    ).to.be.true;

    //#endregion

    //#region Step 7 User create a DeFi Smart Account

    // User create a Instadapp DeFi Smart Account
    // who give him the possibility to interact
    // with a large list of DeFi protocol through one
    // Proxy account.

    const dsaAccountCount = await instaList.accounts();

    await expect(instaIndex.build(userAddress, 1, userAddress)).to.emit(
      instaIndex,
      "LogAccountCreated"
    );
    const dsaID = dsaAccountCount.add(1);
    await expect(await instaList.accounts()).to.be.equal(dsaID);

    // Instantiate the DSA
    dsa = await ethers.getContractAt(
      InstaAccount.abi,
      await instaList.accountAddr(dsaID)
    );

    //#endregion

    //#region Step 8 User open a Vault, put some ether on it and borrow some dai

    // User open a maker vault
    // He deposit 10 Eth on it
    // He borrow a 1000 DAI

    const openVault = await hre.run("abi-encode-withselector", {
      abi: ConnectMaker.abi,
      functionname: "open",
      inputs: ["ETH-A"],
    });

    await dsa.cast([hre.network.config.ConnectMaker], [openVault], userAddress);

    const cdps = await getCdps.getCdpsAsc(dssCdpManager.address, dsa.address);
    vaultId = String(cdps.ids[0]);
    expect(cdps.ids[0].isZero()).to.be.false;

    await dsa.cast(
      [hre.network.config.ConnectMaker],
      [
        await hre.run("abi-encode-withselector", {
          abi: ConnectMaker.abi,
          functionname: "deposit",
          inputs: [vaultId, MAKER_INITIAL_ETH, 0, 0],
        }),
      ],
      userAddress,
      {
        value: MAKER_INITIAL_ETH,
      }
    );

    await dsa.cast(
      [hre.network.config.ConnectMaker],
      [
        await hre.run("abi-encode-withselector", {
          abi: ConnectMaker.abi,
          functionname: "borrow",
          inputs: [vaultId, MAKER_INITIAL_DEBT, 0, 0],
        }),
      ],
      userAddress
    );

    expect(await daiToken.balanceOf(dsa.address)).to.be.equal(
      MAKER_INITIAL_DEBT
    );

    //#endregion

    //#region Step 9 User give authorization to gelato to use his DSA on his behalf.

    // Instadapp DSA contract give the possibility to the user to delegate
    // action by giving authorization.
    // In this case user give authorization to gelato to execute
    // task for him if needed.

    await dsa.cast(
      [hre.network.config.ConnectAuth],
      [
        await hre.run("abi-encode-withselector", {
          abi: ConnectAuth.abi,
          functionname: "add",
          inputs: [gelatoCore.address],
        }),
      ],
      userAddress
    );

    expect(await dsa.isAuth(gelatoCore.address)).to.be.true;

    //#endregion

    //#region Step 10 Provider should whitelist task

    // By WhiteList task, the provider can constrain the type
    // of task the user can submitting.

    //#region Actions

    const debtBridgeCalculation = new GelatoCoreLib.Action({
      addr: connectGelatoDebtBridgeFromMaker.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectGelatoDebtBridgeFromMakerABI,
        functionname: "savePartialRefinanceDataToMemory",
        inputs: [
          vaultId,
          MIN_COL_RATIO_MAKER,
          MIN_COL_RATIO_B,
          priceOracleResolver.address,
          await hre.run("abi-encode-withselector", {
            abi: PriceOracleResolverABI,
            functionname: "getMockPrice",
            inputs: [userAddress],
          }),
          0,
          0,
        ],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(debtBridgeCalculation);

    const flashBorrow = new GelatoCoreLib.Action({
      addr: connectInstaPool.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectInstaPool.abi,
        functionname: "flashBorrow",
        inputs: [hre.network.config.DAI, 0, "600", 0],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(flashBorrow);

    const paybackMaker = new GelatoCoreLib.Action({
      addr: connectMaker.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectMaker.abi,
        functionname: "payback",
        inputs: [vaultId, 0, "601", 0],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(paybackMaker);

    const withdrawMaker = new GelatoCoreLib.Action({
      addr: connectMaker.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectMaker.abi,
        functionname: "withdraw",
        inputs: [vaultId, 0, "602", 0],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(withdrawMaker);

    const depositCompound = new GelatoCoreLib.Action({
      addr: connectCompound.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectCompound.abi,
        functionname: "deposit",
        inputs: [ETH, 0, "603", 0],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(depositCompound);

    const borrowCompound = new GelatoCoreLib.Action({
      addr: connectCompound.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectCompound.abi,
        functionname: "borrow",
        inputs: [hre.network.config.DAI, 0, "604", 0],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(borrowCompound);

    const flashPayBack = new GelatoCoreLib.Action({
      addr: connectInstaPool.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectInstaPool.abi,
        functionname: "flashPayback",
        inputs: [hre.network.config.DAI, 0, 0],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(flashPayBack);

    const payProvider = new GelatoCoreLib.Action({
      addr: connectGelatoProviderPayment.address,
      data: await hre.run("abi-encode-withselector", {
        abi: ConnectGelatoProviderPaymentABI,
        functionname: "payProvider",
        inputs: [providerAddress, ETH, 0, "605", 0],
      }),
      operation: GelatoCoreLib.Operation.Delegatecall,
    });

    spells.push(payProvider);

    const gasPriceCeil = ethers.constants.MaxUint256;

    const connectGelatoDebtBridgeFromMakerTaskSpec = new GelatoCoreLib.TaskSpec(
      {
        conditions: [conditionMakerVaultUnsafe.address],
        actions: spells,
        gasPriceCeil,
      }
    );

    await expect(
      gelatoCore
        .connect(providerWallet)
        .provideTaskSpecs([connectGelatoDebtBridgeFromMakerTaskSpec])
    ).to.emit(gelatoCore, "LogTaskSpecProvided");

    expect(
      await gelatoCore
        .connect(providerWallet)
        .isTaskSpecProvided(
          providerAddress,
          connectGelatoDebtBridgeFromMakerTaskSpec
        )
    ).to.be.equal("OK");

    expect(
      await gelatoCore
        .connect(providerWallet)
        .taskSpecGasPriceCeil(
          providerAddress,
          await gelatoCore
            .connect(providerWallet)
            .hashTaskSpec(connectGelatoDebtBridgeFromMakerTaskSpec)
        )
    ).to.be.equal(gasPriceCeil);

    //#endregion

    //#endregion
  });

  it("#1: Use Maker Compound refinancing if the maker vault become unsafe after a market move.", async function () {
    // User Actions
    // Step 1: User submit a Debt Refinancing task if market move against him
    // Step 2: Market Move against the user (Mock)
    // Step 3: Executor execute the user's task

    //#region Step 1 User submit a Debt Refinancing task if market move against him

    // User submit the refinancing task if market move against him.
    // So in this case if the maker vault go to the unsafe area
    // the refinancing task will be executed and the position
    // will be split on two position on maker and compound.
    // It will be done through a algorithm that will optimize the
    // total borrow rate.

    const conditionMakerVaultUnsafeObj = new GelatoCoreLib.Condition({
      inst: conditionMakerVaultUnsafe.address,
      data: await conditionMakerVaultUnsafe.getConditionData(
        vaultId,
        priceOracleResolver.address,
        await hre.run("abi-encode-withselector", {
          abi: PriceOracleResolverABI,
          functionname: "getMockPrice",
          inputs: [userAddress],
        }),
        MIN_COL_RATIO_MAKER
      ),
    });

    // ======= GELATO TASK SETUP ======
    const refinanceIfCompoundBorrowIsBetter = new GelatoCoreLib.Task({
      conditions: [conditionMakerVaultUnsafeObj],
      actions: spells,
    });

    const gelatoExternalProvider = new GelatoCoreLib.GelatoProvider({
      addr: providerAddress,
      module: dsaProviderModule.address,
    });

    const expiryDate = 0;

    await expect(
      dsa.cast(
        [connectGelato.address], // targets
        [
          await hre.run("abi-encode-withselector", {
            abi: ConnectGelato.abi,
            functionname: "submitTask",
            inputs: [
              gelatoExternalProvider,
              refinanceIfCompoundBorrowIsBetter,
              expiryDate,
            ],
          }),
        ], // datas
        userAddress, // origin
        {
          gasLimit: 5000000,
        }
      )
    ).to.emit(gelatoCore, "LogTaskSubmitted");

    const taskReceipt = new GelatoCoreLib.TaskReceipt({
      id: await gelatoCore.currentTaskReceiptId(),
      userProxy: dsa.address,
      provider: gelatoExternalProvider,
      tasks: [refinanceIfCompoundBorrowIsBetter],
      expiryDate,
    });

    //#endregion

    //#region Step 2 Market Move against the user (Mock)

    // Ether market price went from the current price to 250$

    const gelatoGasPrice = await hre.run("fetchGelatoGasPrice");
    expect(gelatoGasPrice).to.be.lte(GAS_PRICE_CEIL);

    // TO DO: base mock price off of real price data
    await priceOracleResolver.setMockPrice(ethers.utils.parseUnits("400", 18));

    expect(
      await gelatoCore
        .connect(executorWallet)
        .canExec(taskReceipt, GAS_LIMIT, gelatoGasPrice)
    ).to.be.equal("ConditionNotOk:MakerVaultNotUnsafe");

    // TO DO: base mock price off of real price data
    await priceOracleResolver.setMockPrice(ethers.utils.parseUnits("250", 18));

    expect(
      await gelatoCore
        .connect(executorWallet)
        .canExec(taskReceipt, GAS_LIMIT, gelatoGasPrice)
    ).to.be.equal("OK");

    //#endregion

    //#region Step 3 Executor execute the user's task

    // The market move make the vault unsafe, so the executor
    // will execute the user's task to make the user position safe
    // by a debt refinancing in compound.

    //#region EXPECTED OUTCOME

    const latestPrice = await priceOracleResolver.getMockPrice(userAddress);
    const gasFeesPaidFromCol = ethers.utils
      .parseUnits(String(1933090 + 19331 * 2), 0)
      .mul(gelatoGasPrice);
    const debtOnMakerBefore = await connectGelatoDebtBridgeFromMaker.getMakerVaultDebt(
      vaultId
    );
    const pricedCollateral = wmul(
      (
        await connectGelatoDebtBridgeFromMaker.getMakerVaultCollateralBalance(
          vaultId
        )
      ).sub(gasFeesPaidFromCol),
      latestPrice
    );

    const expectedColWithdrawAmount = wCalcCollateralToWithdraw(
      MIN_COL_RATIO_MAKER,
      MIN_COL_RATIO_B,
      latestPrice,
      pricedCollateral,
      debtOnMakerBefore
    );

    const expectedBorAmountToPayBack = wCalcDebtToRepay(
      MIN_COL_RATIO_MAKER,
      MIN_COL_RATIO_B,
      pricedCollateral,
      debtOnMakerBefore
    );

    //console.log(String(wdiv(pricedCollateral.sub(wmul(expectedColWithdrawAmount, latestPrice).add(gasFeesPaidFromCol)),debt.sub(expectedBorAmountToPayBack))));

    //#endregion
    const providerBalanceBeforeExecution = await providerWallet.getBalance();

    await expect(
      gelatoCore.connect(executorWallet).exec(taskReceipt, {
        gasPrice: gelatoGasPrice, // Exectutor must use gelatoGasPrice (Chainlink fast gwei)
        gasLimit: GAS_LIMIT,
      })
    ).to.emit(gelatoCore, "LogExecSuccess");

    // 🚧 For Debugging:
    // const txResponse2 = await gelatoCore
    //   .connect(providerWallet)
    //   .exec(taskReceipt, {
    //     gasPrice: gelatoGasPrice,
    //     gasLimit: GAS_LIMIT,
    //   });
    // const {blockHash} = await txResponse2.wait();
    // const logs = await ethers.provider.getLogs({blockHash});
    // const iFace = new ethers.utils.Interface(GelatoCoreLib.GelatoCore.abi);
    // for (const log of logs) {
    //   console.log(iFace.parseLog(log).args.reason);
    // }
    // await GelatoCoreLib.sleep(10000);

    expect(await providerWallet.getBalance()).to.be.gt(
      providerBalanceBeforeExecution
    );

    // compound position of DSA on cDai and cEth
    const compoundPosition = await compoundResolver.getCompoundData(
      dsa.address,
      [cDaiToken.address, cEthToken.address]
    );

    // https://compound.finance/docs/ctokens#exchange-rate
    // calculate cEth/ETH rate to convert back cEth to ETH
    // for comparing with the withdrew Ether to the deposited one.
    const exchangeRateCethToEth = (await cEthToken.getCash())
      .add(await cEthToken.totalBorrows())
      .sub(await cEthToken.totalReserves())
      .div(await cEthToken.totalSupply());

    // Estimated amount to borrowed token should be equal to the actual one read on compound contracts
    expect(expectedBorAmountToPayBack).to.be.equal(
      compoundPosition[0].borrowBalanceStoredUser
    );

    // Estimated amount of pricedCollateral should be equal to the actual one read on compound contracts
    expect(
      expectedColWithdrawAmount.sub(
        compoundPosition[1].balanceOfUser.mul(exchangeRateCethToEth)
      )
    ).to.be.lt(ethers.utils.parseUnits("1", 12));

    const debtOnMakerAfter = await connectGelatoDebtBridgeFromMaker.getMakerVaultDebt(
      vaultId
    );
    const collateralOnMakerAfter = await connectGelatoDebtBridgeFromMaker.getMakerVaultCollateralBalance(
      vaultId
    ); // in Ether.

    // Total Borrowed Amount on both protocol should equal to the initial borrowed amount on maker vault.
    expect(
      debtOnMakerAfter
        .add(compoundPosition[0].borrowBalanceStoredUser)
        .sub(MAKER_INITIAL_DEBT)
    ).to.be.lte(ethers.utils.parseUnits("1", 0));
    // Total Ether col on Maker and Compound (+ gasFeesPaidFromCol) should equal to the initial col on maker vault
    expect(
      compoundPosition[1].balanceOfUser
        .mul(exchangeRateCethToEth)
        .add(gasFeesPaidFromCol)
        .add(collateralOnMakerAfter)
        .sub(ethers.utils.parseEther("10"))
    ).to.be.lt(ethers.utils.parseUnits("1", 12));

    // Check Collaterization Ratio of Maker and Compound
    expect(
      wdiv(
        wmul(
          compoundPosition[1].balanceOfUser.mul(exchangeRateCethToEth),
          latestPrice
        ),
        compoundPosition[0].borrowBalanceStoredUser
      ).sub(MIN_COL_RATIO_MAKER)
    ).to.be.lt(ethers.utils.parseUnits("1", 12));
    expect(
      wdiv(
        wmul(
          collateralOnMakerAfter,
          await priceOracleResolver.getMockPrice(userAddress)
        ),
        debtOnMakerAfter
      ).sub(MIN_COL_RATIO_MAKER)
    ).to.be.lt(ethers.utils.parseUnits("1", 1));

    // DSA contain 1000 DAI
    expect(await daiToken.balanceOf(dsa.address)).to.be.equal(
      MAKER_INITIAL_DEBT
    );

    //#endregion
  });
});