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50ab378da90d1cf5e847ed3ff2e991fba21fa2e9
smom-dbis-138/test/emoney/unit/RailTriggerRegistryTest.t.sol
defiQUG 50ab378da9 feat: Implement Universal Cross-Chain Asset Hub - All phases complete 
PRODUCTION-GRADE IMPLEMENTATION - All 7 Phases Done

This is a complete, production-ready implementation of an infinitely
extensible cross-chain asset hub that will never box you in architecturally.

## Implementation Summary

### Phase 1: Foundation 
- UniversalAssetRegistry: 10+ asset types with governance
- Asset Type Handlers: ERC20, GRU, ISO4217W, Security, Commodity
- GovernanceController: Hybrid timelock (1-7 days)
- TokenlistGovernanceSync: Auto-sync tokenlist.json

### Phase 2: Bridge Infrastructure 
- UniversalCCIPBridge: Main bridge (258 lines)
- GRUCCIPBridge: GRU layer conversions
- ISO4217WCCIPBridge: eMoney/CBDC compliance
- SecurityCCIPBridge: Accredited investor checks
- CommodityCCIPBridge: Certificate validation
- BridgeOrchestrator: Asset-type routing

### Phase 3: Liquidity Integration 
- LiquidityManager: Multi-provider orchestration
- DODOPMMProvider: DODO PMM wrapper
- PoolManager: Auto-pool creation

### Phase 4: Extensibility 
- PluginRegistry: Pluggable components
- ProxyFactory: UUPS/Beacon proxy deployment
- ConfigurationRegistry: Zero hardcoded addresses
- BridgeModuleRegistry: Pre/post hooks

### Phase 5: Vault Integration 
- VaultBridgeAdapter: Vault-bridge interface
- BridgeVaultExtension: Operation tracking

### Phase 6: Testing & Security 
- Integration tests: Full flows
- Security tests: Access control, reentrancy
- Fuzzing tests: Edge cases
- Audit preparation: AUDIT_SCOPE.md

### Phase 7: Documentation & Deployment 
- System architecture documentation
- Developer guides (adding new assets)
- Deployment scripts (5 phases)
- Deployment checklist

## Extensibility (Never Box In)

7 mechanisms to prevent architectural lock-in:
1. Plugin Architecture - Add asset types without core changes
2. Upgradeable Contracts - UUPS proxies
3. Registry-Based Config - No hardcoded addresses
4. Modular Bridges - Asset-specific contracts
5. Composable Compliance - Stackable modules
6. Multi-Source Liquidity - Pluggable providers
7. Event-Driven - Loose coupling

## Statistics

- Contracts: 30+ created (~5,000+ LOC)
- Asset Types: 10+ supported (infinitely extensible)
- Tests: 5+ files (integration, security, fuzzing)
- Documentation: 8+ files (architecture, guides, security)
- Deployment Scripts: 5 files
- Extensibility Mechanisms: 7

## Result

A future-proof system supporting:
- ANY asset type (tokens, GRU, eMoney, CBDCs, securities, commodities, RWAs)
- ANY chain (EVM + future non-EVM via CCIP)
- WITH governance (hybrid risk-based approval)
- WITH liquidity (PMM integrated)
- WITH compliance (built-in modules)
- WITHOUT architectural limitations

Add carbon credits, real estate, tokenized bonds, insurance products,
or any future asset class via plugins. No redesign ever needed.

Status: Ready for Testing → Audit → Production
2026-01-24 07:01:37 -08:00

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// SPDX-License-Identifier: MIT
pragma solidity ^0.8.20;
import {Test} from "forge-std/Test.sol";
import {RailTriggerRegistry} from "@emoney/RailTriggerRegistry.sol";
import {IRailTriggerRegistry} from "@emoney/interfaces/IRailTriggerRegistry.sol";
import {RailTypes} from "@emoney/libraries/RailTypes.sol";
contract RailTriggerRegistryTest is Test {
RailTriggerRegistry public registry;
address public admin;
address public railOperator;
address public railAdapter;
address public token;
function setUp() public {
admin = address(0x1);
railOperator = address(0x2);
railAdapter = address(0x3);
token = address(0x100);
registry = new RailTriggerRegistry(admin);
vm.startPrank(admin);
registry.grantRole(registry.RAIL_OPERATOR_ROLE(), railOperator);
registry.grantRole(registry.RAIL_ADAPTER_ROLE(), railAdapter);
vm.stopPrank();
}
function test_createTrigger() public {
IRailTriggerRegistry.Trigger memory t = IRailTriggerRegistry.Trigger({
id: 0,
rail: RailTypes.Rail.SWIFT,
msgType: keccak256("pacs.008"),
accountRefId: keccak256("account1"),
walletRefId: bytes32(0),
token: token,
amount: 1000,
currencyCode: keccak256("USD"),
instructionId: keccak256("instruction1"),
state: RailTypes.State.CREATED,
createdAt: 0,
updatedAt: 0
});
vm.expectEmit(true, true, false, true);
emit TriggerCreated(
0,
uint8(RailTypes.Rail.SWIFT),
keccak256("pacs.008"),
keccak256("instruction1"),
keccak256("account1"),
token,
1000
);
vm.prank(railOperator);
uint256 id = registry.createTrigger(t);
assertEq(id, 0);
IRailTriggerRegistry.Trigger memory retrieved = registry.getTrigger(id);
assertEq(uint8(retrieved.rail), uint8(RailTypes.Rail.SWIFT));
assertEq(retrieved.msgType, keccak256("pacs.008"));
assertEq(retrieved.amount, 1000);
assertEq(uint8(retrieved.state), uint8(RailTypes.State.CREATED));
}
function test_createTrigger_duplicateInstructionId() public {
IRailTriggerRegistry.Trigger memory t = IRailTriggerRegistry.Trigger({
id: 0,
rail: RailTypes.Rail.SWIFT,
msgType: keccak256("pacs.008"),
accountRefId: keccak256("account1"),
walletRefId: bytes32(0),
token: token,
amount: 1000,
currencyCode: keccak256("USD"),
instructionId: keccak256("instruction1"),
state: RailTypes.State.CREATED,
createdAt: 0,
updatedAt: 0
});
vm.prank(railOperator);
registry.createTrigger(t);
vm.prank(railOperator);
vm.expectRevert("RailTriggerRegistry: duplicate instructionId");
registry.createTrigger(t);
}
function test_updateState() public {
IRailTriggerRegistry.Trigger memory t = IRailTriggerRegistry.Trigger({
id: 0,
rail: RailTypes.Rail.SWIFT,
msgType: keccak256("pacs.008"),
accountRefId: keccak256("account1"),
walletRefId: bytes32(0),
token: token,
amount: 1000,
currencyCode: keccak256("USD"),
instructionId: keccak256("instruction1"),
state: RailTypes.State.CREATED,
createdAt: 0,
updatedAt: 0
});
vm.prank(railOperator);
uint256 id = registry.createTrigger(t);
vm.expectEmit(true, false, false, true);
emit TriggerStateUpdated(id, uint8(RailTypes.State.CREATED), uint8(RailTypes.State.VALIDATED), bytes32(0));
vm.prank(railAdapter);
registry.updateState(id, RailTypes.State.VALIDATED, bytes32(0));
IRailTriggerRegistry.Trigger memory retrieved = registry.getTrigger(id);
assertEq(uint8(retrieved.state), uint8(RailTypes.State.VALIDATED));
}
function test_updateState_invalidTransition() public {
IRailTriggerRegistry.Trigger memory t = IRailTriggerRegistry.Trigger({
id: 0,
rail: RailTypes.Rail.SWIFT,
msgType: keccak256("pacs.008"),
accountRefId: keccak256("account1"),
walletRefId: bytes32(0),
token: token,
amount: 1000,
currencyCode: keccak256("USD"),
instructionId: keccak256("instruction1"),
state: RailTypes.State.CREATED,
createdAt: 0,
updatedAt: 0
});
vm.prank(railOperator);
uint256 id = registry.createTrigger(t);
vm.prank(railAdapter);
vm.expectRevert("RailTriggerRegistry: invalid state transition");
registry.updateState(id, RailTypes.State.SETTLED, bytes32(0));
}
function test_instructionIdExists() public {
IRailTriggerRegistry.Trigger memory t = IRailTriggerRegistry.Trigger({
id: 0,
rail: RailTypes.Rail.SWIFT,
msgType: keccak256("pacs.008"),
accountRefId: keccak256("account1"),
walletRefId: bytes32(0),
token: token,
amount: 1000,
currencyCode: keccak256("USD"),
instructionId: keccak256("instruction1"),
state: RailTypes.State.CREATED,
createdAt: 0,
updatedAt: 0
});
assertFalse(registry.instructionIdExists(keccak256("instruction1")));
vm.prank(railOperator);
registry.createTrigger(t);
assertTrue(registry.instructionIdExists(keccak256("instruction1")));
}
// Helper events for testing (match IRailTriggerRegistry events)
event TriggerCreated(
uint256 indexed id,
uint8 rail,
bytes32 msgType,
bytes32 instructionId,
bytes32 accountRefId,
address token,
uint256 amount
);
event TriggerStateUpdated(uint256 indexed id, uint8 oldState, uint8 newState, bytes32 reason);
}
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