NEW

CCIP is now live for all developers. See what's new.

Optimizing Gas Limit Settings in CCIP Messages

When constructing a CCIP message, it's crucial to set the gas limit accurately. The gas limit represents the maximum amount of gas consumed to execute the ccipReceive function on the CCIP Receiver, which influences the transaction fees for sending a CCIP message. Notably, unused gas is not reimbursed, making it essential to estimate the gas limit carefully:

  • Setting the gas limit too low will cause the transaction to revert when CCIP calls ccipReceive on the CCIP Receiver, which requires a manual re-execution with an increased gas limit. For more details about this scenario, read the Manual Execution guide.
  • Conversely, an excessively high gas limit leads to higher fees.

This tutorial shows you how to estimate the gas limit for the ccipReceive function using various methods. You will learn how to use a CCIP Receiver where the gas consumption of the ccipReceive function varies based on the input data. This example emphasizes the need for testing under diverse conditions. This tutorial includes tasks for the following environments:

  1. Local Environment: Using Hardhat and Foundry on a local blockchain provides a swift initial gas estimate. However, different frameworks can yield different results and the local environment will not always be representative of your destination blockchain. Consider these figures to be preliminary estimates. Then, incorporate a buffer and conduct subsequent validations on a testnet.
  2. Testnet: You can precisely determine the required gas limit by deploying your CCIP Sender and Receiver on a testnet and transmitting several CCIP messages with the previously estimated gas. Although this approach is more time-intensive, especially if testing across multiple blockchains, it offers enhanced accuracy.
  3. Offchain Methods: Estimating gas with an offchain Web3 provider or tools like Tenderly offers the most accurate and swift way to determine the needed gas limit.

These approaches will give you insights into accurately estimating the gas limit for the ccipReceive function, ensuring cost-effective CCIP transactions.

Before you begin, open a terminal, clone the smart-contract-examples repository, and navigate to the smart-contract-examples/ccip/estimate-gas directory.

git clone https://github.com/smartcontractkit/smart-contract-examples.git && \
cd smart-contract-examples/ccip/estimate-gas

Examine the code

The source code for the CCIP Sender and Receiver is located in the contracts directory for Hardhat projects and in the src directory for Foundry projects. The code includes detailed comments for clarity and is designed to ensure self-explanatory functionality. This section focuses on the _ccipReceive function:

function _ccipReceive(Client.Any2EVMMessage memory any2EvmMessage) internal override {
  uint256 iterations = abi.decode(any2EvmMessage.data, (uint256));

  uint256 result = iterations;
  uint256 maxIterations = iterations % 100;
  for (uint256 i = 0; i < maxIterations; i++) {
    result += i;
  }

  emit MessageReceived(
    any2EvmMessage.messageId,
    any2EvmMessage.sourceChainSelector,
    abi.decode(any2EvmMessage.sender, (address)),
    iterations,
    maxIterations,
    result
  );
}

The _ccipReceive function operates as follows:

  1. Input Processing: The function accepts a Client.Any2EVMMessage. The first step involves decoding the number of iterations from the message's data using ABI decoding.
  2. Logic Execution: It initializes the result variable with the number of iterations. The function calculates maxIterations by taking the modulo of iterations with 100, which sets an upper limit for iteration. This step is a safeguard to ensure that the function does not run out of gas.
  3. Iteration: The function executes a loop from 0 to maxIterations, simulating variable computational work based on the input data. This variability directly influences gas consumption.
  4. Event Emission: Finally, an event MessageReceived is emitted.

This code shows how gas consumption for the _ccipReceive function can fluctuate in response to the input data, highlighting the necessity for thorough testing under different scenarios to determine the correct gasLimit.

Gas estimation in a local environment

To facilitate testing within a local environment, you will use the MockCCIPRouter contract. This contract serves as a mock implementation of the CCIP Router contract, enabling the local testing of CCIP Sender and Receiver contracts. A notable feature of the MockCCIPRouter contract is its ability to emit a MsgExecuted event:

event MsgExecuted(bool success, bytes retData, uint256 gassed))

This event reports the amount of gas consumed by the ccipReceive function.

Foundry

Prerequisites

  1. In your terminal, change to the foundry directory:

    cd foundry
    
  2. Ensure Foundry is installed.

  3. Check the Foundry version:

    forge --version
    

    The output should be similar to the following:

    forge 0.2.0 (545cd0b 2024-03-14T00:20:00.210934000Z)
    

    You need version 0.2.0 or above. Run foundryup to update Foundry if necessary.

  4. Build your project:

    forge build
    

    The output should be similar to:

    [ā Š] Compiling...
    [ā ”] Compiling 52 files with 0.8.19
    [ā ‘] Solc 0.8.19 finished in 2.55s
    Compiler run successful!
    

Estimate gas

Located in the test directory, the SendReceive.t.sol test file assesses the gas consumption of the ccipReceive function. This file features a test case that sends a CCIP message to the MockCCIPRouter contract, which triggers the MsgExecuted event. This event provides insights into the gas requirements of the ccipReceive function by detailing the amount of gas consumed. The test case explores three scenarios to examine gas usage comprehensively across various operational conditions:

  • Baseline gas consumption: This scenario runs 0 iteration to determine the baseline gas consumption, representing the least amount of gas required.
  • Average gas consumption: This scenario runs 50 iterations to estimate the gas consumption under average operational conditions.
  • Peak gas consumption: This scenario runs 99 iterations to estimate the peak gas consumption, marking the upper limit of gas usage.

To run the test, execute the following command:

forge test -vv --isolate

Output example:

[ā Š] Compiling...
[ā ˜] Compiling 52 files with 0.8.19
[ā ƒ] Solc 0.8.19 finished in 2.72s
Compiler run successful!

Ran 3 tests for test/SendReceive.t.sol:SenderReceiverTest
[PASS] test_SendReceiveAverage() (gas: 125166)
Logs:
  Number of iterations 50 - Gas used: 14740

[PASS] test_SendReceiveMax() (gas: 134501)
Logs:
  Number of iterations 99 - Gas used: 24099

[PASS] test_SendReceiveMin() (gas: 115581)
Logs:
  Number of iterations 0 - Gas used: 5190

Suite result: ok. 3 passed; 0 failed; 0 skipped; finished in 10.84ms (5.28ms CPU time)

Ran 1 test suite in 188.81ms (10.84ms CPU time): 3 tests passed, 0 failed, 0 skipped (3 total tests)

This table summarizes the gas usage for different iterations:

ScenarioNumber of iterationsGas used
Baseline gas consumption05190
Average gas consumption5014740
Peak gas consumption9924099

The output demonstrates that gas consumption increases with the number of iterations, peaking when the iteration count reaches 99. In the next section, you will compare these results with those obtained from a local Hardhat environment.

Hardhat

Prerequisites

  1. In your terminal, navigate to the hardhat directory:

    cd ../hardhat
    
  2. Install the dependencies:

    npm install
    
  3. Set the password to encrypt your environment variables using the following command:

    npx env-enc set-pw
    
  4. Set the following environment variables to deploy contracts on testnets:

    • PRIVATE_KEY: The private key for your testnet wallet. If you use MetaMask, follow the instructions to Export a Private Key. Note: Your private key is needed to sign any transactions you make such as making requests.
    • ETHEREUM_SEPOLIA_RPC_URL: The RPC URL for Ethereum Sepolia testnet. You can sign up for a personal endpoint from Alchemy, Infura, or another node provider service.
    • AVALANCHE_FUJI_RPC_URL: The RPC URL for Avalanche Fuji testnet. You can sign up for a personal endpoint from Infura or another node provider service.
    • ETHERSCAN_API_KEY: An Ethereum explorer API key, used to verify your contract. Follow this guide to get one from Etherscan.

    Input these variables using the following command:

    npx env-enc set
    
  5. Compile the contracts:

    npx hardhat compile
    

    The output should be similar to:

    Generating typings for: 31 artifacts in dir: typechain-types for target: ethers-v6
    Successfully generated 114 typings!
    Compiled 33 Solidity files successfully (evm target: paris).
    

Estimate gas

Located in the test directory, the Send-Receive.ts test file is designed to evaluate the gas usage of the ccipReceive function. This file employs the same logic as the Foundry test file, featuring three scenarios varying by the number of iterations. The test case transmits a CCIP message to the MockCCIPRouter contract, triggering the MsgExecuted event. This event provides insights into the gas requirements of the ccipReceive function by detailing the amount of gas used.

To run the test, execute the following command:

npx hardhat test

Example of the output:

  Sender and Receiver
Final Gas Usage Report:
Number of iterations 0 - Gas used: 5168
Number of iterations 50 - Gas used: 14718
Number of iterations 99 - Gas used: 24077
    āœ” should CCIP message from sender to receiver (1716ms)


  1 passing (2s)

This table summarizes the gas usage across different iterations:

ScenarioNumber of iterationsGas used
Baseline gas consumption05168
Average gas consumption5014718
Peak gas consumption9924077

The output demonstrates that gas consumption increases with the number of iterations, peaking when the iteration count reaches 99.

Compare the results from Foundry and Hardhat

This table summarizes the gas usage for different iterations from both Foundry and Hardhat:

ScenarioNumber of iterationsGas used (Foundry)Gas used (Hardhat)
Baseline gas consumption051905168
Average gas consumption501474014718
Peak gas consumption992409924077

Gas usage trends across different iterations are consistent between Foundry and Hardhat and increase with the number of iterations, reaching a peak at 99. However, slight variations in gas usage between the two environments at each iteration level demonstrate the importance of extending gas usage estimation beyond local environment testing. To accurately determine the appropriate gas limit, it is recommended to conduct additional validations on the target blockchain. Setting the gas limit with a buffer is advisable to account for differences between local environment estimations and actual gas usage on the target blockchain.

Estimate gas usage on your local environment

Now that you've locally estimated the gas usage of the ccipReceive function using the provided projects, you can apply the same approach to your own Foundry or Hardhat project. This section will guide you through estimating gas usage in your Foundry or Hardhat project.

Estimate ccipReceive gas usage locally in your Foundry project

To estimate the gas usage of the ccipReceive function within your own Foundry project, follow these steps:

  1. Create a testing file in the test directory of your project and import the MockCCIPRouter contract:

    import { MockCCIPRouter } from "@chainlink/contracts-ccip/src/v0.8/ccip/test/mocks/MockRouter.sol";
    

    Note: The MockCCIPRouter receives the CCIP message from your CCIP Sender, calls the ccipReceive function on your CCIP Receiver, and emits the MsgExecuted event with the gas used.

  2. Inside the setUp function, deploy the MockCCIPRouter contract, and use its address to deploy your CCIP Sender and CCIP Receiver contracts. For more details, check this example.

  3. In your test cases:

    1. Before transmitting any CCIP messages, use vm.recordLogs() to start capturing events. For more details, check this example.

    2. After sending the CCIP message, use vm.getRecordedLogs() to collect the recorded logs. For more details, check this example.

    3. Parse the logs to find the MsgExecuted(bool,bytes,uint256) event and extract the gas used. For more details, check this example.

Estimate ccipReceive gas usage locally in your Hardhat project

To estimate the gas usage of the ccipReceive function within your own Hardhat project, follow these steps:

  1. Create a Solidity file in the contracts directory of your project and import the MockCCIPRouter contract:

    import { MockCCIPRouter } from "@chainlink/contracts-ccip/src/v0.8/ccip/test/mocks/MockRouter.sol";
    

    Note: The MockCCIPRouter receives the CCIP message from your CCIP Sender, calls the ccipReceive function on your CCIP Receiver, and emits the MsgExecuted event with the gas used.

  2. Create a testing file in your project's test directory.

  3. Inside the deployFixture function, deploy the MockCCIPRouter contract and use its address to deploy your CCIP Sender and CCIP Receiver contracts. For more details, check this example.

  4. In your test cases:

    1. Send the CCIP message to the MockCCIPRouter contract. For more details, check this example.
    2. Parse the logs to find the MsgExecuted(bool,bytes,uint256) event and extract the gas used. For more details, check this example.

Gas estimation on a testnet

To accurately validate your local environment's gas usage estimations, follow these steps:

  1. Deploy and configure the CCIP Sender contract on the Avalanche Fuji testnet and the CCIP Receiver contract on the Ethereum Sepolia testnet.

  2. Send several CCIP messages with the same number of iterations used in your local testing. For this purpose, use the sendCCIPMessage.ts script in the scripts/testing directory. This script includes a 10% buffer over the estimated gas usage to ensure a sufficient gas limit. Refer to the table below for the buffered gas limits for each iteration:

    ScenarioNumber of iterationsEstimated gas usage (Hardhat)Buffered gas limit (+10%)
    Baseline gas consumption051685685
    Average gas consumption501471816190
    Peak gas consumption992407726485
  3. Use Tenderly to monitor and confirm that the transactions execute successfully within the buffered gas limits. Subsequently, compare the actual gas usage of the ccipReceive function on the Ethereum Sepolia testnet against the buffered limits to fine-tune the final gas limit.

This approach ensures that your gas limit settings are validated against real-world conditions on testnets, providing a more accurate and reliable estimation for deploying on live blockchains.

Deploy and configure the contracts

To deploy and configure the CCIP Sender contract on the Avalanche Fuji testnet and the CCIP Receiver contract on the Ethereum Sepolia testnet, follow the steps below. Note: Your account must have some ETH tokens on Ethereum Sepolia and AVAX tokens on Avalanche Fuji.

  1. Deploy the CCIP Sender on the Avalanche Fuji testnet:

    npx hardhat run scripts/deployment/deploySender.ts --network avalancheFuji
    
  2. Deploy the CCIP Receiver on the Ethereum Sepolia testnet:

    npx hardhat run scripts/deployment/deployReceiver.ts --network ethereumSepolia
    
  3. Authorize the Sender to send messages to Ethereum Sepolia:

    npx hardhat run scripts/configuration/allowlistingForSender.ts --network avalancheFuji
    
  4. Authorize the Receiver to receive messages from the Sender:

    npx hardhat run scripts/configuration/allowlistingForReceiver.ts --network ethereumSepolia
    

Upon completion, you will find the CCIP Sender and Receiver contracts deployed and configured on their respective testnets. Contract addresses are available in the scripts/generatedData.json file.

Send CCIP Messages

  1. Send three CCIP messages with different numbers of iterations:

    npx hardhat run scripts/testing/sendCCIPMessages.ts --network avalancheFuji
    

    Example output:

    $ npx hardhat run scripts/testing/sendCCIPMessages.ts --network avalancheFuji
    Approving 0x0b9d5D9136855f6FEc3c0993feE6E9CE8a297846 for 0x32A24e40851E19d1eD2a7E697d1a38228e9388a3. Allowance is 115792089237316195423570985008687907853269984665640564039457584007913129639935. Signer 0x9d087fC03ae39b088326b67fA3C788236645b717...
    115792089237316195423570985008687907853269984665640564039457584007913129639935n
    
    Number of iterations 0 - Gas limit: 5685 - Message Id: 0xf23b17366d69159ea7d502835c4178a1c1d1d6325edf3d91dca08f2c7a2900f7
    Number of iterations 50 - Gas limit: 16190 - Message Id: 0x4b3a97f6ac959f67d769492ab3e0414e87fdd9c143228f9c538b22bb695ca728
    Number of iterations 99 - Gas limit: 26485 - Message Id: 0x37d1867518c0f8c54ceb0c5507b46b8d44c6c53864218f448cba0234f8de867a
    
  2. Open the CCIP explorer, search each message by its ID, and wait for each message to be successfully transmitted (Status in the explorer: Success).

For the example above, here are the destination transaction hashes:

Message idEthereum Sepolia transaction hash
0xf23b17366d69159ea7d502835c4178a1c1d1d6325edf3d91dca08f2c7a2900f70xf004eb6dab30b3cfb9d1d631c3f9832410b8d4b3179e65b85730563b67b1e689
0x4b3a97f6ac959f67d769492ab3e0414e87fdd9c143228f9c538b22bb695ca7280xf004eb6dab30b3cfb9d1d631c3f9832410b8d4b3179e65b85730563b67b1e689
0x37d1867518c0f8c54ceb0c5507b46b8d44c6c53864218f448cba0234f8de867a0xf004eb6dab30b3cfb9d1d631c3f9832410b8d4b3179e65b85730563b67b1e689

Note that the Ethereum Sepolia transaction hash is the same for all the messages. This is because CCIP batched the messages.

Check the actual gas usage

  1. Open Tenderly and search for the destination transaction hash.

  2. Search for _callWithExactGasSafeReturnData with a payload containing your messageId (without 0x). Example for 0xf23b17366d69159ea7d502835c4178a1c1d1d6325edf3d91dca08f2c7a2900f7.

  3. Below the payload with your messageId, you will find the call trace from the Router to your Receiver contract. Call trace example.

  4. Click on the Debugger tab and you'll get the gas details:

    "gas":{
    "gas_left":5685
    "gas_used":5031
    "total_gas_used":7994315
    }
    
  5. Note the gas_left is equal to the limit that is set in the sendCCIPMessages.ts script: 5685. The gas_used is the actual gas used by the Receiver contract to process the message.

  6. Repeating the same steps for the other two messages, we can summarize the output:

    ScenarioNumber of iterationsEstimated gas usage (Hardhat)Buffered gas limit (+10%)Gas used on testnet
    Baseline gas consumption0516856855031
    Average gas consumption50147181619014581
    Peak gas consumption99240772648523940

Testing on testnets has confirmed that a gas limit of 26,485 is adequate for the ccipReceive function to execute successfully under various conditions. However, it is important to note that gas usage may differ across testnets. Therefore, it is advisable to conduct similar validation efforts on the blockchain where you intend to deploy. Deploying and validating contracts across multiple testnets can be time-consuming. For efficiency, consider using offchain methods to estimate gas usage.

Offchain methods

This section guides you through estimating gas usage using two different offchain methods:

These methods provide the most accurate and rapid means to determine the necessary gas limit for the ccipReceive function. You will use the same CCIP Receiver contract deployed on the Ethereum Sepolia testnet in the previous section.

Prerequisites

  1. In your terminal, navigate to the offchain directory:

    cd ../offchain
    
  2. Modify the data.json file to insert the deployed addresses of your Sender and Receiver contracts.

  3. Install the dependencies:

    npm install
    
  4. Set the password to encrypt your environment variables:

    npx env-enc set-pw
    
  5. Set up the following environment variables:

    Input these variables using the following command:

    npx env-enc set
    
  6. Generate Typechain typings for the Receiver contract:

    npm run generate-types
    

Introduction of the scripts

The scripts are located in the src directory. Each script is self-explanatory and includes comprehensive comments to explain its functionality and usage. There are three scripts:

  • estimateGasProvider.ts: This script uses the eth_estimateGas Ethereum API to estimate the gas usage of the ccipReceive function. It simulates sending three CCIP messages to the Receiver contract with a varying number of iterations and estimates the gas usage using the ethers.js estimateGas function.

  • estimateGasTenderly.ts: This script leverages the Tenderly simulate API to estimate the gas usage of the ccipReceive function. Similar to the previous script, it simulates sending three CCIP messages to the Receiver contract with different numbers of iterations and estimates the gas usage using the Tenderly simulate API.

  • helper.ts: This script contains helper functions used by the other scripts. The two main functions are:

    • buildTransactionData: This function constructs a CCIP message for a specified number of iterations and then returns the transaction data.
    • estimateIntrinsicGas: Exclusively called by the estimateGasProvider.ts script, this function estimates the intrinsic gas of a transaction. The intrinsic gas represents the minimum amount of gas required before executing a transaction. It is determined by the transaction data and the type of transaction. Since this gas is paid by the initiator of the transaction, we use this function to estimate the intrinsic gas and then deduct it from the total gas used to isolate the gas consumed by the ccipReceive function.

Estimate gas using a Web3 provider

Ethereum nodes implement the eth_estimateGas Ethereum API to predict the gas required for a transaction's successful execution. To estimate the gas usage of the ccipReceive function, you can directly call the eth_estimateGas API via a Web3 provider or leverage a library like ethers.js, simplifying this interaction. This guide focuses on the ethers.js estimateGas function for gas estimation. To estimate the gas usage, execute the following command in your terminal:

npm run estimate-gas-provider

Example output:

$ npm run estimate-gas-provider

> offchain-simulator@1.0.0 estimate-gas-provider
> ts-node src/estimateGasProvider.ts

Final Gas Usage Report:
Number of iterations 0 - Gas used: 5377
Number of iterations 50 - Gas used: 14946
Number of iterations 99 - Gas used: 24324

The estimate may exceed the actual gas used by the transaction for various reasons, including differences in node performance and EVM mechanics. For a more precise estimation, consider using Tenderly (see the next section for details).

Estimate gas using Tenderly

To estimate the gas usage of the ccipReceive function using Tenderly, execute the following command:

npm run estimate-gas-tenderly

Example output:

$ npm run estimate-gas-tenderly

> offchain-simulator@1.0.0 estimate-gas-tenderly
> ts-node src/estimateGasTenderly.ts

Final Gas Usage Report:
Number of iterations 0 - Gas used: 5031
Number of iterations 50 - Gas used: 14581
Number of iterations 99 - Gas used: 23940

Comparison

The table below summarizes the gas estimations for different iterations using both Web3 provider and Tenderly:

ScenarioNumber of iterationsGas estimated (Web3 provider)Gas estimated (Tenderly)
Baseline gas consumption053775031
Average gas consumption501494614581
Peak gas consumption992432423940

The gas estimations from both Web3 provider and Tenderly are consistent across different iterations and align with actual testnet results. This demonstrates the accuracy and reliability of these offchain methods in estimating gas usage. However, you can notice that Tenderly provides more accurate results.

Conclusion

This tutorial has guided you through estimating the gas limit for the ccipReceive function using various methods. You have learned how to estimate gas usage in a local environment using Hardhat and Foundry, validate these estimations on testnets, and use offchain methods to estimate gas usage.

As we have explored various methods for estimating gas for the ccipReceive function, it is crucial to apply this knowledge effectively. Here are some targeted recommendations to enhance your approach to gas estimation:

  1. Comprehensive Testing: Emphasize testing under diverse scenarios to ensure your gas estimations are robust. Different conditions can significantly affect gas usage, so covering as many cases as possible in your tests is crucial.
  2. Preliminary Local Estimates: Local testing is a critical first step for estimating gas and ensuring your contracts function correctly under various scenarios. While Hardhat and Foundry facilitate development and testing, it's key to remember that these environments may not perfectly mirror your target blockchain's conditions. These initial estimates serve as valuable insights, guiding you toward more accurate gas limit settings when you proceed to testnet validations. Incorporating a buffer based on these preliminary results can help mitigate the risks of underestimating gas requirements due to environmental differences.
  3. Efficiency with Offchain Methods: Since testing across different blockchains can be resource-intensive, leaning on offchain methods for gas estimation is invaluable. Tools such as Tenderly not only facilitate rapid and accurate gas usage insights on your target blockchains but also enable you to simulate the execution of the ccipReceive function on actual contracts deployed on mainnets. If Tenderly doesn't support a particular blockchain, a practical alternative is to use a Web3 provider that does support that chain, as illustrated in the Estimate gas using a Web3 provider section. This is particularly helpful when considering the diversity in gas metering rules across blockchains. This approach saves time and enhances the precision of your gas limit estimations, allowing for more cost-effective transactions from your dApp.

Stay updated on the latest Chainlink news