The runtime is a concurrent transaction processor. Transactions specify their data dependencies upfront and dynamic memory allocation is explicit. By separating program code from the state it operates on, the runtime is able to choreograph concurrent access. Transactions accessing only credit-only accounts are executed in parallel whereas transactions accessing writable accounts are serialized. The runtime interacts with the program through an entrypoint with a well-defined interface. The data stored in an account is an opaque type, an array of bytes. The program has full control over its contents.
The transaction structure specifies a list of public keys and signatures for those keys and a sequential list of instructions that will operate over the states associated with the account keys. For the transaction to be committed all the instructions must execute successfully; if any abort the whole transaction fails to commit.
Accounts maintain a lamport balance and program-specific memory.
The engine maps public keys to accounts and routes them to the program's entrypoint.
Transactions are batched and processed in a pipeline. The TPU and TVU follow a slightly different path. The TPU runtime ensures that PoH record occurs before memory is committed.
The TVU runtime ensures that PoH verification occurs before the runtime processes any transactions.
At the execute stage, the loaded accounts have no data dependencies, so all the programs can be executed in parallel.
The runtime enforces the following rules:
Only the owner program may modify the contents of an account. This means that upon assignment data vector is guaranteed to be zero.
Total balances on all the accounts is equal before and after execution of a transaction.
After the transaction is executed, balances of credit-only accounts must be greater than or equal to the balances before the transaction.
All instructions in the transaction executed atomically. If one fails, all account modifications are discarded.
Execution of the program involves mapping the program's public key to an entrypoint which takes a pointer to the transaction, and an array of loaded accounts.
The interface is best described by the
Instruction::data that the user
CreateAccount- This allows the user to create an account with an allocated data array and assign it to a Program.
Assign- Allows the user to assign an existing account to a program.
Transfer- Transfers lamports between accounts.
For blockchain to function correctly, the program code must be resilient to user
inputs. That is why in this design the program specific code is the only code
that can change the state of the data byte array in the Accounts that are
assigned to it. It is also the reason why
CreateAccount must zero
out the data. Otherwise there would be no possible way for the program to
distinguish the recently assigned account data from a natively generated
state transition without some additional metadata from the runtime to indicate
that this memory is assigned instead of natively generated.
To pass messages between programs, the receiving program must accept the message and copy the state over. But in practice a copy isn't needed and is undesirable. The receiving program can read the state belonging to other Accounts without copying it, and during the read it has a guarantee of the sender program's state.
There is no dynamic memory allocation. Client's need to use
CreateAccountinstructions to create memory before passing it to another program. This instruction can be composed into a single transaction with the call to the program itself.
Assignguarantee that when account is assigned to the program, the Account's data is zero initialized.
Once assigned to program an Account cannot be reassigned.
Runtime guarantees that a program's code is the only code that can modify Account data that the Account is assigned to.
Runtime guarantees that the program can only spend lamports that are in accounts that are assigned to it.
Runtime guarantees the balances belonging to accounts are balanced before and after the transaction.
Runtime guarantees that instructions all executed successfully when a transaction is committed.