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SSTORE2

The cost of executing transactions on the Ethereum network can be very high, especially when interacting with smart contract storage using the SSTORE opcode. To mitigate these costs, developers can leverage alternative methods like SSTORE2 for more efficient data handling.

Note: While the following discusses the use of SSTORE2 in the context of Ethereum's standard execution environment, it's important to note that in the Conflux Core Space, the storage and pricing models differ significantly from those described below. Although the techniques described can be applied in Core Space, the cost implications may vary.

The SSTORE opcode is used to store data in Ethereum's contract storage. It writes data to a specific location identified by a key. Both the key and value are 32 bytes. However, this operation is costly in terms of gas:

  • Writing: 22,100 gas for 32 bytes, approximately 690 gas per byte.
  • Reading: The SLOAD opcode is similarly expensive.

SSTORE2 is not a new opcode, its a more gas effective method of storing information on Ethereum. SSTORE2 optimizes data storage by leveraging the immutability of contract bytecode. Instead of using standard contract storage, it stores data as part of a contract's bytecode. The key features of SSTORE2 are as follows:

  • Single Write: Data is written once using the CREATE opcode instead of SSTORE.
  • Reading: Uses the EXTCODECOPY opcode to extract data from the bytecode.

Demo Code

The following example demonstrates how to store data using SSTORE2.

  1. Modify the contract creation bytecode to include the size of the data.
  2. Deploy the contract, which stores the data as bytecode.
// Solidity pseudo-code to demonstrate SSTORE2 usage
function deployDataStorageContract(bytes memory data) public returns (address) {
    uint256 dataSize = data.length;
    // Replace placeholder with data size
    bytes memory bytecode = hex"61000080600a3d393df300";
    bytecode[2] = byte(uint8(dataSize));
    bytecode[3] = byte(uint8(dataSize >> 8));

    address deployedAddress;
    assembly {
        deployedAddress := create(0, add(bytecode, 32), mload(bytecode))
    }
    // Data is prefixed with STOP to prevent execution
    return deployedAddress;
}

To read the stored data, determine the deployed address and extract the bytecode.

function readStoredData(address dataAddress) public view returns (bytes memory) {
    uint256 codeSize;
    assembly {
        codeSize := extcodesize(dataAddress)
    }
    bytes memory data = new bytes(codeSize - 1);
    assembly {
        extcodecopy(dataAddress, add(data, 32), 1, sub(codeSize, 1))
    }
    return data;
}
  • You can find out more details here
  • You can read more about the gas costs savings here

Recommendations for gas optimization:

🌟 Using SSTORE2 reduce the gas costs associated with storing and retrieving large data sets in Ethereum smart contracts.