The transactions on zkSync can be initiated not only on L2, but also on L1. There are two types of transactions that can be initiated on L1:
- Priority operations. These are the kind of operations that any user can create.
- Upgrade transactions. These can be created only during upgrades.
Please read the full article on the general system contracts / bootloader structure as well as the pubdata structure with Boojum system to understand the difference between system and user logs.
A new priority operation can be appended by calling the requestL2Transaction method on L1. This method will perform several checks for the transaction, making sure that it is processable and provides enough fee to compensate the operator for this transaction. Then, this transaction will be appended to the priority queue.
Whenever an operator sees a priority operation, it can include the transaction into the batch. While for normal L2
transaction the account abstraction protocol will ensure that the msg.sender has indeed agreed to start a transaction
out of this name, for L1→L2 transactions there is no signature verification. In order to verify that the operator
includes only transactions that were indeed requested on L1, the bootloader
maintains
two variables:
numberOfPriorityTransactions(maintained atPRIORITY_TXS_L1_DATA_BEGIN_BYTEof bootloader memory)priorityOperationsRollingHash(maintained atPRIORITY_TXS_L1_DATA_BEGIN_BYTE + 32of the bootloader memory)
Whenever a priority transaction is processed, the numberOfPriorityTransactions gets incremented by 1, while
priorityOperationsRollingHash is assigned to keccak256(priorityOperationsRollingHash, processedPriorityOpHash),
where processedPriorityOpHash is the hash of the priority operations that has been just processed.
Also, for each priority transaction, we emit a user L2→L1 log with its hash and result, which basically means that it will get Merklized and users will be able to prove on L1 that a certain priority transaction has succeeded or failed (which can be helpful to reclaim your funds from bridges if the L2 part of the deposit has failed).
Then, at the end of the batch, we submit and 2 L2→L1 log system log with these values.
During block commit, the contract will remember those values, but not validate them in any way.
During batch execution, we would pop numberOfPriorityTransactions from the top of priority queue and
verify
that their rolling hash does indeed equal to priorityOperationsRollingHash.
Upgrade transactions can only be created during a system upgrade. It is done if the DiamondProxy delegatecalls to the
implementation that manually puts this transaction into the storage of the DiamondProxy. Note, that since it happens
during the upgrade, there is no “real” checks on the structure of this transaction. We do have
some validation,
but it is purely on the side of the implementation which the DiamondProxy delegatecalls to and so may be lifted if the
implementation is changed.
The hash of the currently required upgrade transaction is
stored
under l2SystemContractsUpgradeTxHash.
We will also track the batch where the upgrade has been committed in the l2SystemContractsUpgradeBatchNumber
variable.
We can not support multiple upgrades in parallel, i.e. the next upgrade should start only after the previous one has been complete.
The upgrade transactions are processed just like with priority transactions, with only the following differences:
- We can have only one upgrade transaction per batch & this transaction must be the first transaction in the batch.
- The system contracts upgrade transaction is not appended to
priorityOperationsRollingHashand doesn't incrementnumberOfPriorityTransactions. Instead, its hash is calculated via a system L2→L1 log before it gets executed. Note, that it is an important property. More on it below.
After an upgrade has been initiated, it will be required that the next commit batches operation already contains the system upgrade transaction. It is checked by verifying the corresponding L2→L1 log.
We also remember that the upgrade transaction has been processed in this batch (by amending the
l2SystemContractsUpgradeBatchNumber variable).
In a very rare event when the team needs to revert the batch with the upgrade on zkSync, the
l2SystemContractsUpgradeBatchNumber is
reset.
Note, however, that we do not “remember” that certain batches had a version before the upgrade, i.e. if the reverted batches will have to be re-executed, the upgrade transaction must still be present there, even if some of the deleted batches were committed before the upgrade and thus didn’t contain the transaction.
Once batch with the upgrade transaction has been executed, we delete them from storage for efficiency to signify that the upgrade has been fully processed and that a new upgrade can be initiated.
Since the operator can put any data into the bootloader memory and for L1→L2 transactions the bootloader has to blindly trust it and rely on L1 contracts to validate it, it may be a very powerful tool for a malicious operator. Note, that while the governance mechanism is generally trusted, we try to limit our trust for the operator as much as possible, since in the future anyone would be able to become an operator.
Some time ago, we used to have a system where the upgrades could be done via L1→L2 transactions, i.e. the
implementation of the DiamondProxy upgrade would
include
a priority transaction (with from equal to for instance FORCE_DEPLOYER) with all the upgrade params.
In the Boojum though having such logic would be dangerous and would allow for the following attack:
- Let’s say that we have at least 1 priority operations in the priority queue. This can be any operation, initiated by anyone.
- The operator puts a malicious priority operation with an upgrade into the bootloader memory. This operation was never included in the priority operations queue / and it is not an upgrade transaction. However, as already mentioned above the bootloader has no idea what priority / upgrade transactions are correct and so this transaction will be processed.
The most important caveat of this malicious upgrade is that it may change implementation of the Keccak256 precompile
to return any values that the operator needs.
- When the
priorityOperationsRollingHashwill be updated, instead of the “correct” rolling hash of the priority transactions, the one which would appear with the correct topmost priority operation is returned. The operator can’t amend the behaviour ofnumberOfPriorityTransactions, but it won’t help much, since the thepriorityOperationsRollingHashwill match on L1 on the execution step.
That’s why the concept of the upgrade transaction is needed: this is the only transaction that can initiate transactions out of the kernel space and thus change bytecodes of system contracts. That’s why it must be the first one and that’s why emit its hash via a system L2→L1 log before actually processing it.
This section is not required for Boojum understanding but for those willing to analyze the production system that is deployed at the time of this writing.
Note that the hash of the transaction is calculated before the transaction is executed: https://github.com/matter-labs/era-system-contracts/blob/3e954a629ad8e01616174bde2218241b360fda0a/bootloader/bootloader.yul#L1055
And then we publish its hash on L1 via a system L2→L1 log: https://github.com/matter-labs/era-system-contracts/blob/3e954a629ad8e01616174bde2218241b360fda0a/bootloader/bootloader.yul#L1133
In the new upgrade system, the priorityOperationsRollingHash is calculated on L2 and so if something in the middle
changes the implementation of Keccak256, it may lead to the full priorityOperationsRollingHash be maliciously
crafted. In the pre-Boojum system, we publish all the hashes of the priority transactions via system L2→L1 and then the
rolling hash is calculated on L1. This means that if at least one of the hash is incorrect, then the entire rolling hash
will not match also.