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Lisa Cantin
Lisa Cantin

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How do Solana’s smart contracts work?

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Maria Hover • Edited

Solana’s smart contracts operate differently from those found on traditional blockchain platforms like Ethereum. They are designed to leverage Solana’s unique architecture to provide fast, scalable, and cost-efficient transactions, which makes them suitable for various decentralized applications (dApps).

What Are Solana Smart Contracts?

Smart contracts are self-executing programs that run on the blockchain, enabling the automation of various actions like token transfers, data management, and more. On Solana, these smart contracts are called "programs" rather than smart contracts, and they operate in a distinct manner that takes advantage of Solana's unique consensus and scalability model.

Solana's Architecture: How It Differs

The architecture of Solana is distinct in several important ways:

  • Proof of History (PoH): Solana employs a consensus algorithm known as Proof of History, which is a mechanism that creates a historical record to prove that an event has occurred at a specific time. This is combined with Proof of Stake (PoS) to enhance scalability. Proof of History ensures a more efficient ordering of transactions, allowing smart contracts to execute much faster.
  • Parallel Processing (Sealevel): Solana uses a unique parallel processing mechanism called Sealevel. Unlike Ethereum, which executes transactions sequentially, Solana can execute thousands of smart contracts in parallel. Sealevel allows different smart contracts to run at the same time, as long as they do not require the same resources. This boosts performance and allows for high throughput, making Solana one of the fastest blockchains in terms of transaction processing.
  • Accounts Model: Solana's smart contract structure utilizes an accounts-based model that separates code and data. Unlike Ethereum, where both code and state are integrated into a single contract, Solana’s programs are stateless, and the data is stored in separate accounts. This approach allows for more efficient execution and helps achieve better scalability.

How Do Solana Smart Contracts Work?

Solana smart contracts or programs are written in the programming language Rust or C, which are compiled to a bytecode format for deployment. These smart contracts are then executed by the Solana runtime environment, following the architectural principles mentioned above.

Key Components:

  • Programs: Smart contracts on Solana are called "programs." These are pieces of executable code that perform specific tasks, such as managing token transfers or implementing a decentralized exchange.
  • Accounts: Solana uses "accounts" to store data. Each account holds data relevant to a particular program, and the account’s data can be accessed or modified when the program is executed. Accounts may contain SOL (the native token), and they represent a crucial aspect of how the state is maintained on Solana.

Steps of Execution:

  • Deployment: Developers write the program in Rust or C and deploy it onto the Solana blockchain. Once deployed, the program receives a unique address that can be used to interact with it.
  • Interaction: Users interact with the smart contract by sending transactions that reference the program. Each transaction can interact with multiple programs at once, and the execution is managed by the Solana runtime to ensure efficiency.
  • Transaction Processing: With Solana’s Sealevel, the blockchain processes multiple transactions in parallel, which significantly boosts the throughput compared to sequential processing on other blockchains.

Example: Token Swap Smart Contract

Suppose there is a decentralized exchange (DEX) built on Solana that allows users to swap tokens. Here's how a Solana smart contract for a token swap might work:

  • Initiate Transaction: The user submits a request to swap Token A for Token B.
  • Access Accounts: The program references the user’s account and the pool’s liquidity account.
  • Execute in Parallel: Since Solana uses parallel transaction processing, multiple users can swap tokens simultaneously, provided they don’t need to access the same liquidity pool. This allows the DEX to handle a large number of swaps with low latency.
  • Complete Swap: The program updates the balances in each relevant account and completes the transaction, which is recorded on the blockchain.

Benefits of Solana Smart Contracts

  • High Scalability: Solana’s parallel processing and Proof of History mechanism allow the execution of up to 65,000 transactions per second with low fees, making it one of the most scalable blockchains available.
  • Low Transaction Costs: Unlike Ethereum, which often faces high gas fees during times of network congestion, Solana's smart contract interactions cost a fraction of a cent, making it highly attractive for developers and users.
  • Efficient Execution: The separation of code (programs) and state (accounts) enables more efficient execution, leading to faster smart contract interactions and reducing the risk of network bottlenecks.

Ethereum vs. Solana Smart Contracts

Feature Ethereum Solana
Programming Language Solidity Rust, C
Consensus Mechanism Proof of Stake (PoS) Proof of History + Proof of Stake
Transaction Processing Sequential (EVM) Parallel (Sealevel)
Average Fees High (depending on gas prices) Very Low
Scalability Limited to ~30 TPS Up to 65,000 TPS

Conclusion

Solana’s smart contracts are uniquely designed to address the scalability issues faced by older blockchain networks like Ethereum. By employing a combination of Proof of History, Sealevel parallel processing, and an efficient accounts model, Solana enables high-speed and low-cost smart contract interactions. These features make Solana an appealing choice for dApp developers looking for a highly scalable blockchain environment with reduced operational costs and enhanced efficiency.