pezkuwi-subxt/bridges/bin/runtime-common

Helpers for Messages Module Integration

The messages module of this crate contains a bunch of helpers for integrating messages module into your runtime. Basic prerequisites of these helpers are:

• we're going to bridge Substrate-based chain with another Substrate-based chain;
• both chains have messages module, Substrate bridge module and the call dispatch module;
• all message lanes are identical and may be used to transfer the same messages;
• the messages sent over the bridge are dispatched using call dispatch module;
• the messages are pallet_bridge_dispatch::MessagePayload structures, where call field is encoded Call of the target chain. This means that the Call is opaque to the messages module instance at the source chain. It is pre-encoded by the message submitter;
• all proofs in the messages module transactions are based on the storage proofs from the bridged chain: storage proof of the outbound message (value from the pallet_bridge_messages::Store::MessagePayload map), storage proof of the outbound lane state (value from the pallet_bridge_messages::Store::OutboundLanes map) and storage proof of the inbound lane state (value from the pallet_bridge_messages::Store::InboundLanes map);
• storage proofs are built at the finalized headers of the corresponding chain. So all message lane transactions with proofs are verifying storage proofs against finalized chain headers from Substrate bridge module.

IMPORTANT NOTE: after reading this document, you may refer to our test runtimes (rialto_messages.rs and/or millau_messages.rs) to see how to use these helpers.

Contents

• MessageBridge Trait
• ChainWithMessages Trait
• Helpers for the Source Chain
• Helpers for the Target Chain

MessageBridge Trait

The essence of your integration will be a struct that implements a MessageBridge trait. It has single method (MessageBridge::bridged_balance_to_this_balance), used to convert from bridged chain tokens into this chain tokens. The bridge also requires two associated types to be specified - ThisChain and BridgedChain.

Worth to say that if you're going to use hardcoded constant (conversion rate) in the MessageBridge::bridged_balance_to_this_balance method (or in any other method of ThisChainWithMessages or BridgedChainWithMessages traits), then you should take a look at the messages parameters functionality. They allow pallet owner to update constants more frequently than runtime upgrade happens.

ChainWithMessages Trait

The trait is quite simple and can easily be implemented - you just need to specify types used at the corresponding chain. There is single exception, though (it may be changed in the future):

• ChainWithMessages::MessagesInstance: this is used to compute runtime storage keys. There may be several instances of messages pallet, included in the Runtime. Every instance stores messages and these messages stored under different keys. When we are verifying storage proofs from the bridged chain, we should know which instance we're talking to. This is fine, but there's significant inconvenience with that - this chain runtime must have the same messages pallet instance. This does not necessarily mean that we should use the same instance on both chains - this instance may be used to bridge with another chain/instance, or may not be used at all.

ThisChainWithMessages Trait

This trait represents this chain from bridge point of view. Let's review every method of this trait:

• ThisChainWithMessages::is_outbound_lane_enabled: is used to check whether given lane accepts outbound messages.

• ThisChainWithMessages::maximal_pending_messages_at_outbound_lane: you should return maximal number of pending (undelivered) messages from this function. Returning small values would require relayers to operate faster and could make message sending logic more complicated. On the other hand, returning large values could lead to chain state growth.

• ThisChainWithMessages::estimate_delivery_confirmation_transaction: you'll need to return estimated size and dispatch weight of the delivery confirmation transaction (that happens on this chain) from this function.

• ThisChainWithMessages::transaction_payment: you'll need to return fee that the submitter must pay for given transaction on this chain. Normally, you would use transaction payment pallet for this. However, if your chain has non-zero fee multiplier set, this would mean that the payment will be computed using current value of this multiplier. But since this transaction will be submitted in the future, you may want to choose other value instead. Otherwise, non-altruistic relayer may choose not to submit this transaction until number of transactions will decrease.

BridgedChainWithMessages Trait

This trait represents this chain from bridge point of view. Let's review every method of this trait:

• BridgedChainWithMessages::maximal_extrinsic_size: you will need to return the maximal extrinsic size of the target chain from this function.

• MessageBridge::message_weight_limits: you'll need to return a range of dispatch weights that the outbound message may take at the target chain. Please keep in mind that our helpers assume that the message is an encoded call of the target chain. But we never decode this call at the source chain. So you can't simply get dispatch weight from pre-dispatch information. Instead there are two options to prepare this range: if you know which calls are to be sent over your bridge, then you may just return weight ranges for these particular calls. Otherwise, if you're going to accept all kinds of calls, you may just return range [0; maximal incoming message dispatch weight]. If you choose the latter, then you shall remember that the delivery transaction itself has some weight, so you can't accept messages with weight equal to maximal weight of extrinsic at the target chain. In our test chains, we reject all messages that have declared dispatch weight larger than 50% of the maximal bridged extrinsic weight.

• MessageBridge::estimate_delivery_transaction: you will need to return estimated dispatch weight and size of the delivery transaction that delivers a given message to the target chain.

• MessageBridge::transaction_payment: you'll need to return fee that the submitter must pay for given transaction on bridged chain. The best case is when you have the same conversion formula on both chains - then you may just reuse the ThisChainWithMessages::transaction_payment implementation. Otherwise, you'll need to hardcode this formula into your runtime.

Helpers for the Source Chain

The helpers for the Source Chain reside in the source submodule of the messages module. The structs are: FromThisChainMessagePayload, FromBridgedChainMessagesDeliveryProof, FromThisChainMessageVerifier. And the helper functions are: maximal_message_size, verify_chain_message, verify_messages_delivery_proof and estimate_message_dispatch_and_delivery_fee.

FromThisChainMessagePayload is a message that the sender sends through our bridge. It is the pallet_bridge_dispatch::MessagePayload, where call field is encoded target chain call. So at this chain we don't see internals of this call - we just know its size.

FromThisChainMessageVerifier is an implementation of bp_messages::LaneMessageVerifier. It has following checks in its verify_message method:

1. it'll verify that the used outbound lane is enabled in our runtime;

2. it'll reject messages if there are too many undelivered outbound messages at this lane. The sender need to wait while relayers will do their work before sending the message again;

3. it'll reject a message if it has the wrong dispatch origin declared. Like if the submitter is not the root of this chain, but it tries to dispatch the message at the target chain using pallet_bridge_dispatch::CallOrigin::SourceRoot origin. Or he has provided wrong signature in the pallet_bridge_dispatch::CallOrigin::TargetAccount origin;

4. it'll reject a message if the delivery and dispatch fee that the submitter wants to pay is lesser than the fee that is computed using the estimate_message_dispatch_and_delivery_fee function.

estimate_message_dispatch_and_delivery_fee returns a minimal fee that the submitter needs to pay for sending a given message. The fee includes: payment for the delivery transaction at the target chain, payment for delivery confirmation transaction on this chain, payment for Call dispatch at the target chain and relayer interest.

FromBridgedChainMessagesDeliveryProof holds the lane identifier and the storage proof of this inbound lane state at the bridged chain. This also holds the hash of the target chain header, that was used to generate this storage proof. The proof is verified by the verify_messages_delivery_proof, which simply checks that the target chain header is finalized (using Substrate bridge module) and then reads the inbound lane state from the proof.

verify_chain_message function checks that the message may be delivered to the bridged chain. There are two main checks:

1. that the message size is less than or equal to the 2/3 of maximal extrinsic size at the target chain. We leave 1/3 for signed extras and for the storage proof overhead;

2. that the message dispatch weight is less than or equal to the 1/2 of maximal normal extrinsic weight at the target chain. We leave 1/2 for the delivery transaction overhead.

Helpers for the Target Chain

The helpers for the target chain reside in the target submodule of the messages module. The structs are: FromBridgedChainMessagePayload, FromBridgedChainMessagesProof, FromBridgedChainMessagesProof. And the helper functions are: maximal_incoming_message_dispatch_weight, maximal_incoming_message_size and verify_messages_proof.

FromBridgedChainMessagePayload corresponds to the FromThisChainMessagePayload at the bridged chain. We expect that messages with this payload are stored in the OutboundMessages storage map of the messages module. This map is used to build FromBridgedChainMessagesProof. The proof holds the lane id, range of message nonces included in the proof, storage proof of OutboundMessages entries and the hash of bridged chain header that has been used to build the proof. Additionally, there's storage proof may contain the proof of outbound lane state. It may be required to prune relayers entries at this chain (see messages module documentation for details). This proof is verified by the verify_messages_proof function.