id: vm-runtime title: MoveVM Runtime custom_edit_url: https://github.com/aptos-labs/aptos-core/edit/main/language/move-binary-format/vm-runtime/README.md
MoveVM Runtime
The MoveVM runtime is the verification and execution engine for the Move bytecode format. The runtime is imported and loaded in 2 modes: verification mode (by the admission control and mempool components) and execution mode (by the execution component).
Overview
The MoveVM runtime is a stack machine. The VM runtime receives as input a block which is a list of transaction scripts and a data view. The data view is a read only snapshot of the data and code in the blockchain at a given version (i.e., block height). At the time of startup, the runtime does not have any code or data loaded. It is effectively “empty”.
Every transaction executes within the context of a Aptos account---specifically the transaction submitter's account. The execution of every transaction consists of three parts: the account prologue, the transaction itself, and the account epilogue. This is the only transaction flow known to the runtime, and it is the only flow the runtime executes. The runtime is responsible to load the individual transaction from the block and execute the transaction flow:
- Transaction Prologue - in verification mode the runtime runs the
bytecode verifier over the transaction script and executes the
prologue defined in the Aptos account
module. The prologue is responsible
for checking the structure of the transaction and
rejecting obviously bad transactions. In verification mode, the runtime
returns a status of either
success
orfailure
depending upon the result of running the prologue. No updates to the blockchain state are ever performed by the prologue. - Transaction Execution - in execution mode, and after verification, the runtime starts executing transaction-specific/client code. A typical code performs updates to data in the blockchain. Execution of the transaction by the VM runtime produces a write set that acts as an atomic state change from the current state of the blockchain---received via the data view---to a new version that is the result of applying the write set. Importantly, on-chain data is never changed during the execution of the transaction. Further, while the write set is produced as the result of executing the bytecode, the changes are not applied to the global blockchain state by the VM---this is the responsibility of the execution module.
- Transaction Epilogue - in execution mode the epilogue defined in the Aptos account module is executed to perform actions based upon the result of the execution of the user-submitted transaction. One example of such an action is debiting the gas fee for the transaction from the submitting account's balance.
During execution, the runtime resolves references to code by loading the referenced code via the data view. One can think of this process as similar to linking. Then, within the context of a block of transactions---a list of transactions coupled with a data view---the runtime caches code and linked and imported modules across transactions within the block. The runtime tracks state changes (data updates) from one transaction to the next within each block of transactions; the semantics of the execution of a block specify that transactions are sequentially executed and, as a consequence, state changes of previous transactions must be visible to subsequent transactions within each block.
Implementation Details
- The runtime top level structs are in
runtime
anddiem vm
related code. - The transaction flow is implemented in the
process_txn
module. - Code caching logic and policies are defined under the code cache directory.
- Runtime loaded code and the type system view for the runtime is defined under the loaded data directory.
- The data representation of values, and logic for write set generation can be found under the value and data cache files.
Folder Structure
.
├── src # VM Runtime files
│ ├── code_cache # VM Runtime code cache
│ ├── loaded_data # VM Runtime loaded data types, runtime caches over code
│ ├── unit_tests # unit tests
├── vm-cache-map # abstractions for the code cache
This Module Interacts With
This crate is mainly used in two parts: AC and mempool use it to determine if it should accept a transaction or not; the Executor runs the MoveVM runtime to execute the program field in a SignedTransaction and convert it into a TransactionOutput, which contains a writeset that the executor need to patch to the blockchain as a side effect of this transaction.