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The home for Hyperlane core contracts, sdk packages, and other infrastructure
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hyperlane-monorepo/solidity/optics-core/contracts/Replica.sol

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// SPDX-License-Identifier: MIT OR Apache-2.0
pragma solidity >=0.6.11;
import "@summa-tx/memview-sol/contracts/TypedMemView.sol";
import "./Common.sol";
import "./Merkle.sol";
import "./Queue.sol";
import {OpticsHandlerI} from "./UsingOptics.sol";
abstract contract Replica is Common, QueueManager {
using QueueLib for QueueLib.Queue;
uint32 public immutable ownDomain;
uint256 public optimisticSeconds;
mapping(bytes32 => uint256) public confirmAt;
constructor(
uint32 _originDomain,
uint32 _ownDomain,
address _updater,
uint256 _optimisticSeconds,
bytes32 _current
) Common(_originDomain, _updater, _current) QueueManager() {
ownDomain = _ownDomain;
optimisticSeconds = _optimisticSeconds;
current = _current;
}
function fail() internal override {
_setFailed();
}
/// Hook for tasks
function _beforeConfirm() internal virtual;
/// Hook for tasks
function _beforeUpdate() internal virtual;
function nextPending()
external
view
returns (bytes32 _pending, uint256 _confirmAt)
{
if (queue.length() != 0) {
_pending = queue.peek();
_confirmAt = confirmAt[_pending];
}
}
// TODO: refactor to queue
function update(
bytes32 _oldRoot,
bytes32 _newRoot,
bytes memory _signature
) external notFailed {
if (queue.length() > 0) {
require(_oldRoot == queue.lastItem(), "not end of queue");
} else {
require(current == _oldRoot, "not current update");
}
require(Common.checkSig(_oldRoot, _newRoot, _signature), "bad sig");
_beforeUpdate();
confirmAt[_newRoot] = block.timestamp + optimisticSeconds;
queue.enqueue(_newRoot);
emit Update(originDomain, _oldRoot, _newRoot, _signature);
}
function canConfirm() external view returns (bool) {
return
queue.length() != 0 && block.timestamp >= confirmAt[queue.peek()];
}
function confirm() external notFailed {
require(queue.length() != 0, "no pending");
bytes32 _pending;
uint256 _now = block.timestamp;
uint256 _remaining = queue.length();
while (_remaining > 0 && _now >= confirmAt[queue.peek()]) {
_pending = queue.dequeue();
delete confirmAt[_pending];
_remaining -= 1;
}
// This condition is hit if the while loop is never executed, because
// the first queue item has not hit its timer yet
require(_pending != bytes32(0), "not time");
_beforeConfirm();
current = _pending;
}
}
contract ProcessingReplica is Replica {
using MerkleLib for MerkleLib.Tree;
using TypedMemView for bytes;
using TypedMemView for bytes29;
using Message for bytes29;
// minimum gas for message processing
uint256 public constant PROCESS_GAS = 500000;
// reserved gas (to ensure tx completes in case message processing runs out)
uint256 public constant RESERVE_GAS = 10000;
bytes32 public previous; // to smooth over witness invalidation
uint256 public lastProcessed;
mapping(bytes32 => MessageStatus) public messages;
enum MessageStatus {None, Pending, Processed}
constructor(
uint32 _originDomain,
uint32 _ownDomain,
address _updater,
uint256 _optimisticSeconds,
bytes32 _start,
uint256 _lastProcessed
) Replica(_originDomain, _ownDomain, _updater, _optimisticSeconds, _start) {
lastProcessed = _lastProcessed;
}
function _beforeConfirm() internal override {
previous = current;
}
function _beforeUpdate() internal override {}
function process(bytes memory _message)
public
returns (bool _success, bytes memory _result)
{
bytes29 _m = _message.ref(0);
uint32 _sequence = _m.sequence();
require(_m.destination() == ownDomain, "!destination");
require(_sequence == lastProcessed + 1, "!sequence");
require(
messages[keccak256(_message)] == MessageStatus.Pending,
"not pending"
);
// Set the state now. We will set lastProcessed later. This prevents
// re-entry as one of the two require statements above will definitely
// fail.
messages[_m.keccak()] = MessageStatus.Processed;
// TODO: assembly this to avoid the clone?
bytes memory payload = _m.body().clone();
address recipient = _m.recipientAddress();
// NB:
// A call running out of gas TYPICALLY errors the whole tx. We want to
// a) ensure the call has a sufficient amount of gas to make a
// meaningful state change.
// b) ensure that if the subcall runs out of gas, that the tx as a whole
// does not revert (i.e. we still mark the message processed)
// To do this, we require that we have enough gas to process
// and still return. We then delegate only the minimum processing gas.
require(gasleft() >= PROCESS_GAS + RESERVE_GAS, "!gas");
// transparently return.
try
OpticsHandlerI(recipient).handle{gas: PROCESS_GAS}(
_m.origin(),
_m.sender(),
payload
)
returns (bytes memory _response) {
_success = true;
_result = _response;
} catch (bytes memory _err) {
_success = false;
_result = _err;
}
// (_success, _ret) = recipient.call{gas: PROCESS_GAS}(payload);
lastProcessed = _sequence;
}
function prove(
bytes32 leaf,
bytes32[32] calldata proof,
uint256 index
) public returns (bool) {
bytes32 actual = MerkleLib.branchRoot(leaf, proof, index);
// NB:
// For convenience, we allow proving against the previous root.
// This means that witnesses don't need to be updated for the new root
if (actual == current || actual == previous) {
messages[leaf] = MessageStatus.Pending;
return true;
}
return false;
}
function proveAndProcess(
bytes memory message,
bytes32[32] calldata proof,
uint256 index
) external {
require(prove(keccak256(message), proof, index), "!prove");
process(message);
}
}