Hyperlane Tokens and Warp Routes
This repo contains contracts and SDK tooling for Hyperlane-connected ERC20 and ERC721 tokens. The contracts herein can be used to create Hyperlane Warp Routes across different chains.
For instructions on deploying Warp Routes, see the deployment documentation and the Hyperlane-Deploy repository.
Warp Route Architecture
A Warp Route is a collection of TokenRouter contracts deployed across a set of Hyperlane chains. These contracts leverage the Router pattern to implement access control and routing logic for remote token transfers. These contracts send and receive Messages which encode payloads containing a transfer amount and recipient address.
%%{ init: {
"theme": "neutral",
"themeVariables": {
"mainBkg": "#025AA1",
"textColor": "white",
"clusterBkg": "white"
},
"themeCSS": ".edgeLabel { color: black }"
}}%%
graph LR
subgraph "Ethereum"
HYP_E[TokenRouter]
style HYP_E fill:orange
Mailbox_E[(Mailbox)]
end
subgraph "Polygon"
HYP_P[TokenRouter]
style HYP_P fill:orange
Mailbox_P[(Mailbox)]
end
subgraph "Gnosis"
HYP_G[TokenRouter]
style HYP_G fill:orange
Mailbox_G[(Mailbox)]
end
HYP_E -. "router" .- HYP_P -. "router" .- HYP_G
The Token Router contract comes in several flavors and a warp route can be composed of a combination of these flavors.
-
Native- for warping native assets (e.g. ETH) from the canonical chain -
Collateral- for warping tokens, ERC20 or ERC721, from the canonical chain -
Synthetic- for representing tokens, Native/ERC20 or ERC721, on a non-canonical chain
Interchain Security Models
Warp routes are unique amongst token bridging solutions because they provide modular security. Because the TokenRouter implements the IMessageRecipient interface, it can be configured with a custom interchain security module. Please refer to the relevant guide to specifying interchain security modules on the Messaging API receive docs.
Remote Transfer Lifecycle Diagrams
To initiate a remote transfer, users call the TokenRouter.transferRemote function with the destination chain ID, recipient address, and transfer amount.
interface TokenRouter {
function transferRemote(
uint32 destination,
bytes32 recipient,
uint256 amount
) public returns (bytes32 messageId);
}
NOTE: The Relayer shown below must be compensated. Please refer to the relevant guide on paying for interchain gas on the messageID returned from the transferRemote call.
Depending on the flavor of TokenRouter on the source and destination chain, this flow looks slightly different. The following diagrams illustrate these differences.
Transfer Alice's amount native ETH from Ethereum to Bob on Polygon
%%{ init: {
"theme": "neutral",
"themeVariables": {
"mainBkg": "#025AA1",
"textColor": "white",
"clusterBkg": "white"
},
"themeCSS": ".edgeLabel { color: black }"
}}%%
graph TB
Bob((Bob))
style Bob fill:black
Alice((Alice))
style Alice fill:black
Relayer([Relayer])
subgraph "Ethereum"
HYP_E[NativeTokenRouter]
style HYP_E fill:orange
Mailbox_E[(Mailbox)]
end
Alice == "transferRemote(Polygon, Bob, amount)\n{value: amount}" ==> HYP_E
linkStyle 0 color:green;
HYP_E -- "dispatch(Polygon, (Bob, amount))" --> Mailbox_E
subgraph "Polygon"
HYP_P[SyntheticTokenRouter]
style HYP_P fill:orange
Mailbox_P[(Mailbox)]
end
Mailbox_E -. "indexing" .-> Relayer
Relayer == "process(Ethereum, (Bob, amount))" ==> Mailbox_P
Mailbox_P -- "handle(Ethereum, (Bob, amount))" --> HYP_P
HYP_E -. "router" .- HYP_P
HYP_P -- "mint(Bob, amount)" --> Bob
linkStyle 6 color:green;Transfer Alice's ERC20 amount from Ethereum to Bob on Polygon
%%{ init: {
"theme": "neutral",
"themeVariables": {
"mainBkg": "#025AA1",
"textColor": "white",
"clusterBkg": "white"
},
"themeCSS": ".edgeLabel { color: black }"
}}%%
graph TB
Alice((Alice))
Bob((Bob))
style Alice fill:black
style Bob fill:black
Relayer([Relayer])
subgraph "Ethereum"
Token_E[ERC20]
style Token_E fill:green
HYP_E[CollateralTokenRouter]
style HYP_E fill:orange
Mailbox_E[(Mailbox)]
end
Alice == "approve(CollateralTokenRouter, infinity)" ==> Token_E
Alice == "transferRemote(Polygon, Bob, amount)" ==> HYP_E
Token_E -- "transferFrom(Alice, amount)" --> HYP_E
linkStyle 2 color:green;
HYP_E -- "dispatch(Polygon, (Bob, amount))" --> Mailbox_E
subgraph "Polygon"
HYP_P[SyntheticRouter]
style HYP_P fill:orange
Mailbox_P[(Mailbox)]
end
Mailbox_E -. "indexing" .-> Relayer
Relayer == "process(Ethereum, (Bob, amount))" ==> Mailbox_P
Mailbox_P -- "handle(Ethereum, (Bob, amount))" --> HYP_P
HYP_E -. "router" .- HYP_P
HYP_P -- "mint(Bob, amount)" --> Bob
linkStyle 8 color:green;Transfer Alice's amount synthetic MATIC from Ethereum back to Bob as native MATIC on Polygon
%%{ init: {
"theme": "neutral",
"themeVariables": {
"mainBkg": "#025AA1",
"textColor": "white",
"clusterBkg": "white"
},
"themeCSS": ".edgeLabel { color: black }"
}}%%
graph TB
Bob((Bob))
style Bob fill:black
Alice((Alice))
style Alice fill:black
Relayer([Relayer])
subgraph "Ethereum"
HYP_E[SyntheticTokenRouter]
style HYP_E fill:orange
Mailbox_E[(Mailbox)]
end
Alice == "transferRemote(Polygon, Bob, amount)" ==> HYP_E
Alice -- "burn(Alice, amount)" --> HYP_E
linkStyle 1 color:green;
HYP_E -- "dispatch(Polygon, (Bob, amount))" --> Mailbox_E
subgraph "Polygon"
HYP_P[NativeTokenRouter]
style HYP_P fill:orange
Mailbox_P[(Mailbox)]
end
Mailbox_E -. "indexing" .-> Relayer
Relayer == "process(Ethereum, (Bob, amount))" ==> Mailbox_P
Mailbox_P -- "handle(Ethereum, (Bob, amount))" --> HYP_P
HYP_E -. "router" .- HYP_P
HYP_P -- "transfer(){value: amount}" --> Bob
linkStyle 7 color:green;NOTE: ERC721 collateral variants are assumed to enumerable and metadata compliant.
Versions
| Git Ref | Release Date | Notes |
|---|---|---|
| audit-v2-remediation | 2023-02-15 | Hyperlane V2 Audit remediation |
| main | ~ | Bleeding edge |
Setup for local development
# Install dependencies
yarn
# Build source and generate types
yarn build:devUnit testing
# Run all unit tests
yarn test
# Lint check code
yarn lintLearn more
For more information, see the Hyperlane introduction documentation or the details about Warp Routes.