# Stages
The `stages` lib plays a central role in syncing the node, maintaining state, updating the database and more. The stages involved in the Reth pipeline are the `HeaderStage`, `BodyStage`, `SenderRecoveryStage`, and `ExecutionStage` (note that this list is non-exhaustive, and more pipeline stages will be added in the near future). Each of these stages are queued up and stored within the Reth pipeline.
When the node is first started, a new `Pipeline` is initialized and all of the stages are added into `Pipeline.stages`. Then, the `Pipeline::run` function is called, which starts the pipeline, executing all of the stages continuously in an infinite loop. This process syncs the chain, keeping everything up to date with the chain tip.
Each stage within the pipeline implements the `Stage` trait which provides function interfaces to get the stage id, execute the stage and unwind the changes to the database if there was an issue during the stage execution.
To get a better idea of what is happening at each part of the pipeline, let's walk through what is going on under the hood when a stage is executed, starting with `HeaderStage`.
## HeaderStage
The `HeaderStage` is responsible for syncing the block headers, validating the header integrity and writing the headers to the database. When the `execute()` function is called, the local head of the chain is updated to the most recent block height previously executed by the stage. At this point, the node status is also updated with that block's height, hash and total difficulty. These values are used during any new eth/65 handshakes. After updating the head, a stream is established with other peers in the network to sync the missing chain headers between the most recent state stored in the database and the chain tip. The `HeaderStage` contains a `downloader` attribute, which is a type that implements the `HeaderDownloader` trait. A `HeaderDownloader` is a `Stream` that returns batches of headers.
The `HeaderStage` relies on the downloader stream to return the headers in descending order starting from the chain tip down to the latest block in the database. While other stages in the `Pipeline` start from the most recent block in the database up to the chain tip, the `HeaderStage` works in reverse to avoid [long-range attacks](https://messari.io/report/long-range-attack). When a node downloads headers in ascending order, it will not know if it is being subjected to a long-range attack until it reaches the most recent blocks. To combat this, the `HeaderStage` starts by getting the chain tip from the Consensus Layer, verifies the tip, and then walks backwards by the parent hash.
Each header is then validated to ensure that it has the proper parent. Note that this is only a basic response validation, and the `HeaderDownloader` uses the `validate` method during the `stream`, so that each header is validated according to the consensus specification before the header is yielded from the stream. After this, each header is then written to the database. If a header is not valid or the stream encounters any other error, the error is propagated up through the stage execution, the changes to the database are unwound and the stage is resumed from the most recent valid state.
This process continues until all of the headers have been downloaded and written to the database. Finally, the total difficulty of the chain's head is updated and the function returns `Ok(ExecOutput { stage_progress, done: true })`, signaling that the header sync has been completed successfully.
## BodyStage
Once the `HeaderStage` completes successfully, the `BodyStage` will start execution. The body stage downloads block bodies for all of the new block headers that were stored locally in the database. The `BodyStage` first determines which block bodies to download by checking if the block body has an ommers hash and transaction root.
An ommers hash is the Keccak 256-bit hash of the ommers list portion of the block. If you are unfamiliar with ommers blocks, you can [click here to learn more](https://ethereum.org/en/glossary/#ommer). Note that while ommers blocks were important for new blocks created during Ethereum's proof of work chain, Ethereum's proof of stake chain selects exactly one block proposer at a time, causing ommers blocks not to be needed in post-merge Ethereum.
The transactions root is a value that is calculated based on the transactions included in the block. To derive the transactions root, a [merkle tree](https://blog.ethereum.org/2015/11/15/merkling-in-ethereum) is created from the block's transactions list. The transactions root is then derived by taking the Keccak 256-bit hash of the root node of the merkle tree.
When the `BodyStage` is looking at the headers to determine which block to download, it will skip the blocks where the `header.ommers_hash` and the `header.transaction_root` are empty, denoting that the block is empty as well.
Once the `BodyStage` determines which block bodies to fetch, a new `bodies_stream` is created which downloads all of the bodies from the `starting_block`, up until the `target_block` specified. Each time the `bodies_stream` yields a value, a `SealedBlock` is created using the block header, the ommers hash and the newly downloaded block body.
The new block is then pre-validated, checking that the ommers hash and transactions root in the block header are the same in the block body. Following a successful pre-validation, the `BodyStage` loops through each transaction in the `block.body`, adding the transaction to the database. This process is repeated for every downloaded block body, with the `BodyStage` returning `Ok(ExecOutput { stage_progress, done: true })` signaling it successfully completed.
## SenderRecoveryStage
Following a successful `BodyStage`, the `SenderRecoveryStage` starts to execute. The `SenderRecoveryStage` is responsible for recovering the transaction sender for each of the newly added transactions to the database. At the beginning of the execution function, all of the transactions are first retrieved from the database. Then the `SenderRecoveryStage` goes through each transaction and recovers the signer from the transaction signature and hash. The transaction hash is derived by taking the Keccak 256-bit hash of the RLP encoded transaction bytes. This hash is then passed into the `recover_signer` function.
In an [ECDSA (Elliptic Curve Digital Signature Algorithm) signature](https://wikipedia.org/wiki/Elliptic_Curve_Digital_Signature_Algorithm), the "r", "s", and "v" values are three pieces of data that are used to mathematically verify the authenticity of a digital signature. ECDSA is a widely used algorithm for generating and verifying digital signatures, and it is often used in cryptocurrencies like Ethereum.
The "r" is the x-coordinate of a point on the elliptic curve that is calculated as part of the signature process. The "s" is the s-value that is calculated during the signature process. It is derived from the private key and the message being signed. Lastly, the "v" is the "recovery value" that is used to recover the public key from the signature, which is derived from the signature and the message that was signed. Together, the "r", "s", and "v" values make up an ECDSA signature, and they are used to verify the authenticity of the signed transaction.
Once the transaction signer has been recovered, the signer is then added to the database. This process is repeated for every transaction that was retrieved, and similarly to previous stages, `Ok(ExecOutput { stage_progress, done: true })` is returned to signal a successful completion of the stage.
## ExecutionStage
Finally, after all headers, bodies and senders are added to the database, the `ExecutionStage` starts to execute. This stage is responsible for executing all of the transactions and updating the state stored in the database.
After all headers and their corresponding transactions have been executed, all of the resulting state changes are applied to the database, updating account balances, account bytecode and other state changes. After applying all of the execution state changes, if there was a block reward, it is applied to the validator's account.
At the end of the `execute()` function, a familiar value is returned, `Ok(ExecOutput { stage_progress, done: true })` signaling a successful completion of the `ExecutionStage`.
## MerkleUnwindStage
The `MerkleUnwindStage` is responsible for unwinding the Merkle Patricia trie state when a reorg occurs or when there's a need to rollback state changes. This stage ensures that the state trie remains consistent with the chain's canonical history by reverting any state changes that need to be undone. It works closely with the `MerkleExecuteStage` to maintain state integrity.
## AccountHashingStage
The `AccountHashingStage` handles the computation of account state hashes. It processes all accounts in the state and computes their cryptographic hashes, which are essential for building the state trie. This stage is crucial for maintaining the integrity of the state and enabling efficient state proof verification.
## StorageHashingStage
The `StorageHashingStage` is responsible for computing hashes of contract storage. Similar to the `AccountHashingStage`, it processes storage slots of smart contracts and generates cryptographic hashes that are used in the state trie. This stage ensures that contract storage can be efficiently verified and proven.
## MerkleExecuteStage
The `MerkleExecuteStage` handles the construction and updates of the Merkle Patricia trie, which is Ethereum's core data structure for storing state. This stage processes state changes from executed transactions and builds the corresponding branches in the state trie. It's responsible for maintaining the state root that's included in block headers.
## TransactionLookupStage
The `TransactionLookupStage` builds and maintains transaction lookup indices. These indices enable efficient querying of transactions by hash or block position. This stage is crucial for RPC functionality, allowing users to quickly retrieve transaction information without scanning the entire blockchain.
## IndexStorageHistoryStage
The `IndexStorageHistoryStage` creates indices for historical contract storage states. It tracks how contract storage values change over time, enabling historical state queries. This is essential for features like state debugging, transaction tracing, and historical state access.
## IndexAccountHistoryStage
The `IndexAccountHistoryStage` builds indices for account history, tracking how account states (balance, nonce, code) change over time. Similar to the storage history stage, this enables historical queries of account states at any block height, which is crucial for debugging and analysis tools.
## FinishStage
The `FinishStage` is the final stage in the pipeline that performs cleanup and verification tasks. It ensures that all previous stages have completed successfully and that the node's state is consistent. This stage may also update various metrics and status indicators to reflect the completion of a sync cycle.
# Next Chapter
Now that we have covered all of the stages that are currently included in the `Pipeline`, you know how the Reth client stays synced with the chain tip and updates the database with all of the new headers, bodies, senders and state changes. While this chapter provides an overview on how the pipeline stages work, the following chapters will dive deeper into the database, the networking stack and other exciting corners of the Reth codebase. Feel free to check out any parts of the codebase mentioned in this chapter, and when you are ready, the next chapter will dive into the `database`.
[Next Chapter]()