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hyperlane-monorepo/solidity/test/CheckpointFraudProofs.t.sol

295 lines
9.2 KiB

// SPDX-License-Identifier: Apache-2.0
pragma solidity ^0.8.13;
import "forge-std/Test.sol";
import "@openzeppelin/contracts/utils/cryptography/ECDSA.sol";
import "../contracts/libs/TypeCasts.sol";
import "../contracts/test/TestMailbox.sol";
import "../contracts/CheckpointFraudProofs.sol";
import "../contracts/test/TestMerkleTreeHook.sol";
import "../contracts/test/TestPostDispatchHook.sol";
// must have keys ordered alphabetically
struct Proof {
uint32 index;
bytes32 leaf;
bytes32[] path; // cannot be static length or json parsing breaks
}
// must have keys ordered alphabetically
struct Fixture {
bytes32 expectedRoot;
string[] leaves;
Proof[] proofs;
string testName;
}
uint8 constant FIXTURE_COUNT = 5;
contract CheckpointFraudProofsTest is Test {
using TypeCasts for address;
using stdJson for string;
uint32 localDomain = 1000;
uint32 remoteDomain = 2000;
string json = vm.readFile("../vectors/merkle.json");
TestMailbox mailbox;
TestMerkleTreeHook merkleTreeHook;
CheckpointFraudProofs cfp;
function setUp() public {
mailbox = new TestMailbox(localDomain);
cfp = new CheckpointFraudProofs();
}
function loadFixture(
uint32 fixtureIndex
)
internal
returns (
Checkpoint[] memory checkpoints,
bytes32[TREE_DEPTH][] memory proofs
)
{
bytes memory data = json.parseRaw(
string.concat(".[", vm.toString(fixtureIndex), "]")
);
Fixture memory fixture = abi.decode(data, (Fixture));
console.log(fixture.testName);
merkleTreeHook = new TestMerkleTreeHook(address(mailbox));
bytes32 merkleBytes = address(merkleTreeHook).addressToBytes32();
checkpoints = new Checkpoint[](fixture.leaves.length);
proofs = new bytes32[TREE_DEPTH][](fixture.proofs.length);
for (uint32 index = 0; index < fixture.leaves.length; index++) {
bytes32 leaf = ECDSA.toEthSignedMessageHash(
abi.encodePacked(fixture.leaves[index])
);
merkleTreeHook.insert(leaf);
checkpoints[index] = Checkpoint(
localDomain,
merkleBytes,
merkleTreeHook.root(),
index,
leaf
);
proofs[index] = parseProof(fixture.proofs[index]);
}
assert(fixture.expectedRoot == merkleTreeHook.root());
}
function parseProof(
Proof memory proof
) internal pure returns (bytes32[TREE_DEPTH] memory path) {
for (uint8 i = 0; i < proof.path.length; i++) {
path[i] = proof.path[i];
}
}
function test_isLocal(uint8 fixtureIndex) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(Checkpoint[] memory checkpoints, ) = loadFixture(fixtureIndex);
for (uint32 i = 0; i < checkpoints.length; i++) {
assertTrue(cfp.isLocal(checkpoints[i]));
checkpoints[i].origin = remoteDomain;
assertFalse(cfp.isLocal(checkpoints[i]));
}
}
function test_isPremature(uint8 fixtureIndex) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(Checkpoint[] memory checkpoints, ) = loadFixture(fixtureIndex);
for (uint32 i = 0; i < checkpoints.length; i++) {
assertFalse(cfp.isPremature(checkpoints[i]));
}
Checkpoint memory prematureCheckpoint = Checkpoint(
localDomain,
address(merkleTreeHook).addressToBytes32(),
0,
merkleTreeHook.count(),
0
);
assertTrue(cfp.isPremature(prematureCheckpoint));
merkleTreeHook.insert(bytes32("0xdeadbeef"));
assertFalse(cfp.isPremature(prematureCheckpoint));
}
function test_RevertWhenNotLocal_isPremature(uint8 fixtureIndex) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(Checkpoint[] memory checkpoints, ) = loadFixture(fixtureIndex);
for (uint32 i = 0; i < checkpoints.length; i++) {
checkpoints[i].origin = remoteDomain;
vm.expectRevert("must be local checkpoint");
cfp.isPremature(checkpoints[i]);
}
}
function test_isFraudulentMessageId(uint8 fixtureIndex) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(
Checkpoint[] memory checkpoints,
bytes32[32][] memory proofs
) = loadFixture(fixtureIndex);
// cannot store checkpoint when count is 0
if (checkpoints.length != 0) {
cfp.storeLatestCheckpoint(address(merkleTreeHook));
}
for (uint32 i = 0; i < checkpoints.length; i++) {
assertFalse(
cfp.isFraudulentMessageId(
checkpoints[i],
proofs[i],
checkpoints[i].messageId
)
);
bytes32 actualMessageId = checkpoints[i].messageId;
checkpoints[i].messageId = ~actualMessageId;
assertTrue(
cfp.isFraudulentMessageId(
checkpoints[i],
proofs[i],
actualMessageId
)
);
}
}
function test_RevertWhenNotStored_isFraudulentMessageId(
uint8 fixtureIndex
) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(
Checkpoint[] memory checkpoints,
bytes32[32][] memory proofs
) = loadFixture(fixtureIndex);
for (uint32 index = 0; index < checkpoints.length; index++) {
vm.expectRevert("message must be member of stored checkpoint");
cfp.isFraudulentMessageId(
checkpoints[index],
proofs[index],
checkpoints[index].messageId
);
}
// cannot store checkpoint when count is 0
if (checkpoints.length != 0) {
cfp.storeLatestCheckpoint(address(merkleTreeHook));
}
// providing an invalid merkle proof should revert with not stored
for (uint32 index = 0; index < checkpoints.length; index++) {
proofs[index][0] = ~proofs[index][0];
vm.expectRevert("message must be member of stored checkpoint");
cfp.isFraudulentMessageId(
checkpoints[index],
proofs[index],
checkpoints[index].messageId
);
}
}
function test_RevertWhenNotLocal_isFraudulentMessageId(
uint8 fixtureIndex
) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(
Checkpoint[] memory checkpoints,
bytes32[32][] memory proofs
) = loadFixture(fixtureIndex);
for (uint32 i = 0; i < checkpoints.length; i++) {
checkpoints[i].origin = remoteDomain;
vm.expectRevert("must be local checkpoint");
cfp.isFraudulentMessageId(
checkpoints[i],
proofs[i],
checkpoints[i].messageId
);
}
}
function test_IsFraudulentRoot(uint8 fixtureIndex) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(
Checkpoint[] memory checkpoints,
bytes32[32][] memory proofs
) = loadFixture(fixtureIndex);
// cannot store checkpoint when count is 0
if (checkpoints.length != 0) {
cfp.storeLatestCheckpoint(address(merkleTreeHook));
}
// check all messages against latest stored checkpoint
for (uint32 i = 0; i < checkpoints.length; i++) {
assertFalse(cfp.isFraudulentRoot(checkpoints[i], proofs[i]));
checkpoints[i].root = ~checkpoints[i].root;
assertTrue(cfp.isFraudulentRoot(checkpoints[i], proofs[i]));
}
}
function test_RevertWhenNotStored_isFraudulentRoot(
uint8 fixtureIndex
) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(
Checkpoint[] memory checkpoints,
bytes32[32][] memory proofs
) = loadFixture(fixtureIndex);
for (uint32 index = 0; index < checkpoints.length; index++) {
vm.expectRevert("message must be member of stored checkpoint");
cfp.isFraudulentRoot(checkpoints[index], proofs[index]);
}
// cannot store checkpoint when count is 0
if (checkpoints.length != 0) {
cfp.storeLatestCheckpoint(address(merkleTreeHook));
}
// providing an invalid merkle proof should revert with not stored
for (uint32 index = 0; index < checkpoints.length; index++) {
proofs[index][0] = ~proofs[index][0];
vm.expectRevert("message must be member of stored checkpoint");
cfp.isFraudulentRoot(checkpoints[index], proofs[index]);
}
}
function test_RevertWhenNotLocal_isFraudulentRoot(
uint8 fixtureIndex
) public {
vm.assume(fixtureIndex < FIXTURE_COUNT);
(
Checkpoint[] memory checkpoints,
bytes32[32][] memory proofs
) = loadFixture(fixtureIndex);
for (uint32 i = 0; i < checkpoints.length; i++) {
checkpoints[i].origin = remoteDomain;
vm.expectRevert("must be local checkpoint");
cfp.isFraudulentRoot(checkpoints[i], proofs[i]);
}
}
}