Skip to main content

Cross-VM Bridge

Flow provides the Cross-VM Bridge which enables the movement of fungible and non-fungible tokens between Cadence & EVM. The Cross-VM Bridge is a contract-based protocol enabling the automated and atomic bridging of tokens from Cadence into EVM with their corresponding ERC-20 and ERC-721 token types. In the opposite direction, it supports bridging of arbitrary ERC-20 and ERC-721 tokens from EVM to Cadence as their corresponding FT or NFT token types.

The Cross-VM Bridge internalizes the capabilities to deploy new token contracts in either VM state as needed, resolving access to, and maintaining links between associated contracts. It additionally automates account and contract calls to enforce source VM asset burn or lock, and target VM token mint or unlock.

Developers wishing to use the Cross-VM Bridge will be required to use a Cadence transaction. Cross-VM bridging functionality is not currently available natively in EVM on Flow. By extension, this means that the EVM account bridging from EVM to Cadence must be a CadenceOwnedAccount (COA) as this is the only EVM account type that can be controlled from the Cadence runtime.

This FLIP outlines the architecture and implementation of the VM bridge. This document will focus on how to use the Cross-VM Bridge and considerations for fungible and non-fungible token projects deploying to either Cadence or EVM.

Deployments

The core bridge contracts can be found at the following addresses:

ContractsTestnetMainnet
All Cadence Bridge contracts0xdfc20aee650fcbdf0x1e4aa0b87d10b141
FlowEVMBridgeFactory.sol0xf8146b4aef631853f0eb98dbe28706d029e52c520x1c6dea788ee774cf15bcd3d7a07ede892ef0be40
FlowEVMBridgeDeploymentRegistry.sol0x8781d15904d7e161f421400571dea24cc0db69380x8fdec2058535a2cb25c2f8cec65e8e0d0691f7b0
FlowEVMBridgedERC20Deployer.sol0x4d45CaD104A71D19991DE3489ddC5C7B284cf2630x49631Eac7e67c417D036a4d114AD9359c93491e7
FlowEVMBridgedERC721Deployer.sol0x1B852d242F9c4C4E9Bb91115276f659D1D1f7c560xe7c2B80a9de81340AE375B3a53940E9aeEAd79Df

And below are the bridge escrow's EVM addresses. These addresses are COAs and are stored stored in the same Flow account as you'll find the Cadence contracts (see above).

NetworkAddress
Testnet0x0000000000000000000000023f946ffbc8829bfd
Mainnet0x00000000000000000000000249250a5c27ecab3b

Interacting With the Bridge

info

All bridging activity in either direction is orchestrated via Cadence on COA EVM accounts. This means that all bridging activity must be initiated via a Cadence transaction, not an EVM transaction regardless of the directionality of the bridge request. For more information on the interplay between Cadence and EVM, see How EVM on Flow Works.

Overview

The Flow EVM bridge allows both fungible and non-fungible tokens to move atomically between Cadence and EVM. In the context of EVM, fungible tokens are defined as ERC20 tokens, and non-fungible tokens as ERC721 tokens. In Cadence, fungible tokens are defined by contracts implementing the FungibleToken interface and non-fungible tokens implement the NonFungibleToken interface.

Like all operations on Flow, there are native fees associated with both computation and storage. To prevent spam and sustain the bridge account's storage consumption, fees are charged for both onboarding assets and bridging assets. In the case where storage consumption is expected, fees are charged based on the storage consumed at the current network storage rate.

Onboarding

Since a contract must define the asset in the target VM, an asset must be "onboarded" to the bridge before requests can be fulfilled.

Moving from Cadence to EVM, onboarding can occur on the fly, deploying a template contract in the same transaction as the asset is bridged to EVM if the transaction so specifies.

Moving from EVM to Cadence, however, requires that onboarding occur in a separate transaction due to the fact that a Cadence contract is initialized at the end of a transaction and isn't available in the runtime until after the transaction has executed.

Below are transactions relevant to onboarding assets:

onboard_by_type.cdc
onboard_by_type.cdc

_56
import "FungibleToken"
_56
import "FlowToken"
_56
_56
import "ScopedFTProviders"
_56
_56
import "EVM"
_56
_56
import "FlowEVMBridge"
_56
import "FlowEVMBridgeConfig"
_56
_56
/// This transaction onboards the asset type to the bridge, configuring the bridge to move assets between environments
_56
/// NOTE: This must be done before bridging a Cadence-native asset to EVM
_56
///
_56
/// @param type: The Cadence type of the bridgeable asset to onboard to the bridge
_56
///
_56
transaction(type: Type) {
_56
_56
let scopedProvider: @ScopedFTProviders.ScopedFTProvider
_56
_56
prepare(signer: auth(CopyValue, BorrowValue, IssueStorageCapabilityController, PublishCapability, SaveValue) &Account) {
_56
_56
/* --- Configure a ScopedFTProvider --- */
_56
//
_56
// Issue and store bridge-dedicated Provider Capability in storage if necessary
_56
if signer.storage.type(at: FlowEVMBridgeConfig.providerCapabilityStoragePath) == nil {
_56
let providerCap = signer.capabilities.storage.issue<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>(
_56
/storage/flowTokenVault
_56
)
_56
signer.storage.save(providerCap, to: FlowEVMBridgeConfig.providerCapabilityStoragePath)
_56
}
_56
// Copy the stored Provider capability and create a ScopedFTProvider
_56
let providerCapCopy = signer.storage.copy<Capability<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>>(
_56
from: FlowEVMBridgeConfig.providerCapabilityStoragePath
_56
) ?? panic("Invalid Provider Capability found in storage.")
_56
let providerFilter = ScopedFTProviders.AllowanceFilter(FlowEVMBridgeConfig.onboardFee)
_56
self.scopedProvider <- ScopedFTProviders.createScopedFTProvider(
_56
provider: providerCapCopy,
_56
filters: [ providerFilter ],
_56
expiration: getCurrentBlock().timestamp + 1.0
_56
)
_56
}
_56
_56
execute {
_56
// Onboard the asset Type
_56
FlowEVMBridge.onboardByType(
_56
type,
_56
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_56
)
_56
destroy self.scopedProvider
_56
}
_56
_56
post {
_56
FlowEVMBridge.typeRequiresOnboarding(type) == false:
_56
"Asset ".concat(type.identifier).concat(" was not onboarded to the bridge.")
_56
}
_56
}

onboard_by_evm_address.cdc
onboard_by_evm_address.cdc

_55
import "FungibleToken"
_55
import "FlowToken"
_55
_55
import "ScopedFTProviders"
_55
_55
import "EVM"
_55
_55
import "FlowEVMBridge"
_55
import "FlowEVMBridgeConfig"
_55
_55
/// This transaction onboards the NFT type to the bridge, configuring the bridge to move NFTs between environments
_55
/// NOTE: This must be done before bridging a Cadence-native NFT to EVM
_55
///
_55
/// @param contractAddressHex: The EVM address of the contract defining the bridgeable asset to be onboarded
_55
///
_55
transaction(contractAddressHex: String) {
_55
_55
let contractAddress: EVM.EVMAddress
_55
let scopedProvider: @ScopedFTProviders.ScopedFTProvider
_55
_55
prepare(signer: auth(CopyValue, BorrowValue, IssueStorageCapabilityController, PublishCapability, SaveValue) &Account) {
_55
/* --- Construct EVMAddress from hex string (no leading `"0x"`) --- */
_55
//
_55
self.contractAddress = EVM.addressFromString(contractAddressHex)
_55
_55
/* --- Configure a ScopedFTProvider --- */
_55
//
_55
// Issue and store bridge-dedicated Provider Capability in storage if necessary
_55
if signer.storage.type(at: FlowEVMBridgeConfig.providerCapabilityStoragePath) == nil {
_55
let providerCap = signer.capabilities.storage.issue<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>(
_55
/storage/flowTokenVault
_55
)
_55
signer.storage.save(providerCap, to: FlowEVMBridgeConfig.providerCapabilityStoragePath)
_55
}
_55
// Copy the stored Provider capability and create a ScopedFTProvider
_55
let providerCapCopy = signer.storage.copy<Capability<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>>(
_55
from: FlowEVMBridgeConfig.providerCapabilityStoragePath
_55
) ?? panic("Invalid Provider Capability found in storage.")
_55
let providerFilter = ScopedFTProviders.AllowanceFilter(FlowEVMBridgeConfig.onboardFee)
_55
self.scopedProvider <- ScopedFTProviders.createScopedFTProvider(
_55
provider: providerCapCopy,
_55
filters: [ providerFilter ],
_55
expiration: getCurrentBlock().timestamp + 1.0
_55
)
_55
}
_55
_55
execute {
_55
// Onboard the EVM contract
_55
FlowEVMBridge.onboardByEVMAddress(
_55
self.contractAddress,
_55
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_55
)
_55
destroy self.scopedProvider
_55
}
_55
}

Bridging

Once an asset has been onboarded, either by its Cadence type or EVM contract address, it can be bridged in either direction, referred to by its Cadence type. For Cadence-native assets, this is simply its native type. For EVM-native assets, this is in most cases a templated Cadence contract deployed to the bridge account, the name of which is derived from the EVM contract address. For instance, an ERC721 contract at address 0x1234 would be onboarded to the bridge as EVMVMBridgedNFT_0x1234, making its type identifier A.<BRIDGE_ADDRESS>.EVMVMBridgedNFT_0x1234.NFT.

To get the type identifier for a given NFT, you can use the following code:


_10
// Where `nft` is either a @{NonFungibleToken.NFT} or &{NonFungibleToken.NFT}
_10
nft.getType().identifier

You may also retrieve the type associated with a given EVM contract address using the following script:

get_associated_type.cdc
get_associated_type.cdc

_16
import "EVM"
_16
_16
import "FlowEVMBridgeConfig"
_16
_16
/// Returns the Cadence Type associated with the given EVM address (as its hex String)
_16
///
_16
/// @param evmAddressHex: The hex-encoded address of the EVM contract as a String
_16
///
_16
/// @return The Cadence Type associated with the EVM address or nil if the address is not onboarded. `nil` may also be
_16
/// returned if the address is not a valid EVM address.
_16
///
_16
access(all)
_16
fun main(addressHex: String): Type? {
_16
let address = EVM.addressFromString(addressHex)
_16
return FlowEVMBridgeConfig.getTypeAssociated(with: address)
_16
}

Alternatively, given some onboarded Cadence type, you can retrieve the associated EVM address using the following script:

get_associated_address.cdc
get_associated_address.cdc

_19
import "EVM"
_19
_19
import "FlowEVMBridgeConfig"
_19
_19
/// Returns the EVM address associated with the given Cadence type (as its identifier String)
_19
///
_19
/// @param typeIdentifier: The Cadence type identifier String
_19
///
_19
/// @return The EVM address as a hex string if the type has an associated EVMAddress, otherwise nil
_19
///
_19
access(all)
_19
fun main(identifier: String): String? {
_19
if let type = CompositeType(identifier) {
_19
if let address = FlowEVMBridgeConfig.getEVMAddressAssociated(with: type) {
_19
return address.toString()
_19
}
_19
}
_19
return nil
_19
}

NFTs

Any Cadence NFTs bridging to EVM are escrowed in the bridge account and either minted in a bridge-deployed ERC721 contract or transferred from escrow to the calling COA in EVM. On the return trip, NFTs are escrowed in EVM - owned by the bridge's COA - and either unlocked from escrow if locked or minted from a bridge-owned NFT contract.

Below are transactions relevant to bridging NFTs:

bridge_nft_to_evm.cdc
bridge_nft_to_evm.cdc

_118
import "FungibleToken"
_118
import "NonFungibleToken"
_118
import "ViewResolver"
_118
import "MetadataViews"
_118
import "FlowToken"
_118
_118
import "ScopedFTProviders"
_118
_118
import "EVM"
_118
_118
import "FlowEVMBridge"
_118
import "FlowEVMBridgeConfig"
_118
import "FlowEVMBridgeUtils"
_118
_118
/// Bridges an NFT from the signer's collection in Cadence to the signer's COA in FlowEVM
_118
///
_118
/// NOTE: This transaction also onboards the NFT to the bridge if necessary which may incur additional fees
_118
/// than bridging an asset that has already been onboarded.
_118
///
_118
/// @param nftIdentifier: The Cadence type identifier of the NFT to bridge - e.g. nft.getType().identifier
_118
/// @param id: The Cadence NFT.id of the NFT to bridge to EVM
_118
///
_118
transaction(nftIdentifier: String, id: UInt64) {
_118
_118
let nft: @{NonFungibleToken.NFT}
_118
let coa: auth(EVM.Bridge) &EVM.CadenceOwnedAccount
_118
let requiresOnboarding: Bool
_118
let scopedProvider: @ScopedFTProviders.ScopedFTProvider
_118
_118
prepare(signer: auth(CopyValue, BorrowValue, IssueStorageCapabilityController, PublishCapability, SaveValue) &Account) {
_118
/* --- Reference the signer's CadenceOwnedAccount --- */
_118
//
_118
// Borrow a reference to the signer's COA
_118
self.coa = signer.storage.borrow<auth(EVM.Bridge) &EVM.CadenceOwnedAccount>(from: /storage/evm)
_118
?? panic("Could not borrow COA from provided gateway address")
_118
_118
/* --- Construct the NFT type --- */
_118
//
_118
// Construct the NFT type from the provided identifier
_118
let nftType = CompositeType(nftIdentifier)
_118
?? panic("Could not construct NFT type from identifier: ".concat(nftIdentifier))
_118
// Parse the NFT identifier into its components
_118
let nftContractAddress = FlowEVMBridgeUtils.getContractAddress(fromType: nftType)
_118
?? panic("Could not get contract address from identifier: ".concat(nftIdentifier))
_118
let nftContractName = FlowEVMBridgeUtils.getContractName(fromType: nftType)
_118
?? panic("Could not get contract name from identifier: ".concat(nftIdentifier))
_118
_118
/* --- Retrieve the NFT --- */
_118
//
_118
// Borrow a reference to the NFT collection, configuring if necessary
_118
let viewResolver = getAccount(nftContractAddress).contracts.borrow<&{ViewResolver}>(name: nftContractName)
_118
?? panic("Could not borrow ViewResolver from NFT contract")
_118
let collectionData = viewResolver.resolveContractView(
_118
resourceType: nftType,
_118
viewType: Type<MetadataViews.NFTCollectionData>()
_118
) as! MetadataViews.NFTCollectionData? ?? panic("Could not resolve NFTCollectionData view")
_118
let collection = signer.storage.borrow<auth(NonFungibleToken.Withdraw) &{NonFungibleToken.Collection}>(
_118
from: collectionData.storagePath
_118
) ?? panic("Could not access signer's NFT Collection")
_118
_118
// Withdraw the requested NFT & calculate the approximate bridge fee based on NFT storage usage
_118
let currentStorageUsage = signer.storage.used
_118
self.nft <- collection.withdraw(withdrawID: id)
_118
let withdrawnStorageUsage = signer.storage.used
_118
var approxFee = FlowEVMBridgeUtils.calculateBridgeFee(
_118
bytes: currentStorageUsage - withdrawnStorageUsage
_118
) * 1.10
_118
// Determine if the NFT requires onboarding - this impacts the fee required
_118
self.requiresOnboarding = FlowEVMBridge.typeRequiresOnboarding(self.nft.getType())
_118
?? panic("Bridge does not support this asset type")
_118
if self.requiresOnboarding {
_118
approxFee = approxFee + FlowEVMBridgeConfig.onboardFee
_118
}
_118
_118
/* --- Configure a ScopedFTProvider --- */
_118
//
_118
// Issue and store bridge-dedicated Provider Capability in storage if necessary
_118
if signer.storage.type(at: FlowEVMBridgeConfig.providerCapabilityStoragePath) == nil {
_118
let providerCap = signer.capabilities.storage.issue<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>(
_118
/storage/flowTokenVault
_118
)
_118
signer.storage.save(providerCap, to: FlowEVMBridgeConfig.providerCapabilityStoragePath)
_118
}
_118
// Copy the stored Provider capability and create a ScopedFTProvider
_118
let providerCapCopy = signer.storage.copy<Capability<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>>(
_118
from: FlowEVMBridgeConfig.providerCapabilityStoragePath
_118
) ?? panic("Invalid Provider Capability found in storage.")
_118
let providerFilter = ScopedFTProviders.AllowanceFilter(approxFee)
_118
self.scopedProvider <- ScopedFTProviders.createScopedFTProvider(
_118
provider: providerCapCopy,
_118
filters: [ providerFilter ],
_118
expiration: getCurrentBlock().timestamp + 1.0
_118
)
_118
}
_118
_118
pre {
_118
self.nft.getType().identifier == nftIdentifier:
_118
"Attempting to send invalid nft type - requested: ".concat(nftIdentifier)
_118
.concat(", sending: ").concat(self.nft.getType().identifier)
_118
}
_118
_118
execute {
_118
if self.requiresOnboarding {
_118
// Onboard the NFT to the bridge
_118
FlowEVMBridge.onboardByType(
_118
self.nft.getType(),
_118
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_118
)
_118
}
_118
// Execute the bridge
_118
self.coa.depositNFT(
_118
nft: <-self.nft,
_118
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_118
)
_118
// Destroy the ScopedFTProvider
_118
destroy self.scopedProvider
_118
}
_118
}

bridge_nft_from_evm.cdc
bridge_nft_from_evm.cdc

_106
import "FungibleToken"
_106
import "NonFungibleToken"
_106
import "ViewResolver"
_106
import "MetadataViews"
_106
import "FlowToken"
_106
_106
import "ScopedFTProviders"
_106
_106
import "EVM"
_106
_106
import "FlowEVMBridge"
_106
import "FlowEVMBridgeConfig"
_106
import "FlowEVMBridgeUtils"
_106
_106
/// This transaction bridges an NFT from EVM to Cadence assuming it has already been onboarded to the FlowEVMBridge
_106
/// NOTE: The ERC721 must have first been onboarded to the bridge. This can be checked via the method
_106
/// FlowEVMBridge.evmAddressRequiresOnboarding(address: self.evmContractAddress)
_106
///
_106
/// @param nftIdentifier: The Cadence type identifier of the NFT to bridge - e.g. nft.getType().identifier
_106
/// @param id: The ERC721 id of the NFT to bridge to Cadence from EVM
_106
///
_106
transaction(nftIdentifier: String, id: UInt256) {
_106
_106
let nftType: Type
_106
let collection: &{NonFungibleToken.Collection}
_106
let scopedProvider: @ScopedFTProviders.ScopedFTProvider
_106
let coa: auth(EVM.Bridge) &EVM.CadenceOwnedAccount
_106
_106
prepare(signer: auth(BorrowValue, CopyValue, IssueStorageCapabilityController, PublishCapability, SaveValue, UnpublishCapability) &Account) {
_106
/* --- Reference the signer's CadenceOwnedAccount --- */
_106
//
_106
// Borrow a reference to the signer's COA
_106
self.coa = signer.storage.borrow<auth(EVM.Bridge) &EVM.CadenceOwnedAccount>(from: /storage/evm)
_106
?? panic("Could not borrow COA from provided gateway address")
_106
_106
/* --- Construct the NFT type --- */
_106
//
_106
// Construct the NFT type from the provided identifier
_106
self.nftType = CompositeType(nftIdentifier)
_106
?? panic("Could not construct NFT type from identifier: ".concat(nftIdentifier))
_106
// Parse the NFT identifier into its components
_106
let nftContractAddress = FlowEVMBridgeUtils.getContractAddress(fromType: self.nftType)
_106
?? panic("Could not get contract address from identifier: ".concat(nftIdentifier))
_106
let nftContractName = FlowEVMBridgeUtils.getContractName(fromType: self.nftType)
_106
?? panic("Could not get contract name from identifier: ".concat(nftIdentifier))
_106
_106
/* --- Reference the signer's NFT Collection --- */
_106
//
_106
// Borrow a reference to the NFT collection, configuring if necessary
_106
let viewResolver = getAccount(nftContractAddress).contracts.borrow<&{ViewResolver}>(name: nftContractName)
_106
?? panic("Could not borrow ViewResolver from NFT contract")
_106
let collectionData = viewResolver.resolveContractView(
_106
resourceType: self.nftType,
_106
viewType: Type<MetadataViews.NFTCollectionData>()
_106
) as! MetadataViews.NFTCollectionData? ?? panic("Could not resolve NFTCollectionData view")
_106
if signer.storage.borrow<&{NonFungibleToken.Collection}>(from: collectionData.storagePath) == nil {
_106
signer.storage.save(<-collectionData.createEmptyCollection(), to: collectionData.storagePath)
_106
signer.capabilities.unpublish(collectionData.publicPath)
_106
let collectionCap = signer.capabilities.storage.issue<&{NonFungibleToken.Collection}>(collectionData.storagePath)
_106
signer.capabilities.publish(collectionCap, at: collectionData.publicPath)
_106
}
_106
self.collection = signer.storage.borrow<&{NonFungibleToken.Collection}>(from: collectionData.storagePath)
_106
?? panic("Could not borrow collection from storage path")
_106
_106
/* --- Configure a ScopedFTProvider --- */
_106
//
_106
// Calculate the bridge fee - bridging from EVM consumes no storage, so flat fee
_106
let approxFee = FlowEVMBridgeUtils.calculateBridgeFee(bytes: 0)
_106
// Issue and store bridge-dedicated Provider Capability in storage if necessary
_106
if signer.storage.type(at: FlowEVMBridgeConfig.providerCapabilityStoragePath) == nil {
_106
let providerCap = signer.capabilities.storage.issue<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>(
_106
/storage/flowTokenVault
_106
)
_106
signer.storage.save(providerCap, to: FlowEVMBridgeConfig.providerCapabilityStoragePath)
_106
}
_106
// Copy the stored Provider capability and create a ScopedFTProvider
_106
let providerCapCopy = signer.storage.copy<Capability<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>>(
_106
from: FlowEVMBridgeConfig.providerCapabilityStoragePath
_106
) ?? panic("Invalid Provider Capability found in storage.")
_106
let providerFilter = ScopedFTProviders.AllowanceFilter(approxFee)
_106
self.scopedProvider <- ScopedFTProviders.createScopedFTProvider(
_106
provider: providerCapCopy,
_106
filters: [ providerFilter ],
_106
expiration: getCurrentBlock().timestamp + 1.0
_106
)
_106
}
_106
_106
execute {
_106
// Execute the bridge
_106
let nft: @{NonFungibleToken.NFT} <- self.coa.withdrawNFT(
_106
type: self.nftType,
_106
id: id,
_106
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_106
)
_106
// Ensure the bridged nft is the correct type
_106
assert(
_106
nft.getType() == self.nftType,
_106
message: "Bridged nft type mismatch - requeswted: ".concat(self.nftType.identifier)
_106
.concat(", received: ").concat(nft.getType().identifier)
_106
)
_106
// Deposit the bridged NFT into the signer's collection
_106
self.collection.deposit(token: <-nft)
_106
// Destroy the ScopedFTProvider
_106
destroy self.scopedProvider
_106
}
_106
}

Fungible Tokens

Any Cadence fungible tokens bridging to EVM are escrowed in the bridge account only if they are Cadence-native. If the bridge defines the tokens, they are burned. On the return trip the pattern is similar, with the bridge burning bridge-defined tokens or escrowing them if they are EVM-native. In all cases, if the bridge has authority to mint on one side, it must escrow on the other as the native VM contract is owned by an external party.

With fungible tokens in particular, there may be some cases where the Cadence contract is not deployed to the bridge account, but the bridge still follows a mint/burn pattern in Cadence. These cases are handled via TokenHandler implementations. Also know that moving $FLOW to EVM is built into the EVMAddress object so any requests bridging $FLOW to EVM will simply leverage this interface; however, moving $FLOW from EVM to Cadence must be done through the COA resource.

Below are transactions relevant to bridging fungible tokens:

bridge_tokens_to_evm.cdc
bridge_tokens_to_evm.cdc

_119
import "FungibleToken"
_119
import "ViewResolver"
_119
import "FungibleTokenMetadataViews"
_119
import "FlowToken"
_119
_119
import "ScopedFTProviders"
_119
_119
import "EVM"
_119
_119
import "FlowEVMBridge"
_119
import "FlowEVMBridgeConfig"
_119
import "FlowEVMBridgeUtils"
_119
_119
/// Bridges a Vault from the signer's storage to the signer's COA in EVM.Account.
_119
///
_119
/// NOTE: This transaction also onboards the Vault to the bridge if necessary which may incur additional fees
_119
/// than bridging an asset that has already been onboarded.
_119
///
_119
/// @param vaultIdentifier: The Cadence type identifier of the FungibleToken Vault to bridge
_119
/// - e.g. vault.getType().identifier
_119
/// @param amount: The amount of tokens to bridge from EVM
_119
///
_119
transaction(vaultIdentifier: String, amount: UFix64) {
_119
_119
let sentVault: @{FungibleToken.Vault}
_119
let coa: auth(EVM.Bridge) &EVM.CadenceOwnedAccount
_119
let requiresOnboarding: Bool
_119
let scopedProvider: @ScopedFTProviders.ScopedFTProvider
_119
_119
prepare(signer: auth(CopyValue, BorrowValue, IssueStorageCapabilityController, PublishCapability, SaveValue) &Account) {
_119
/* --- Reference the signer's CadenceOwnedAccount --- */
_119
//
_119
// Borrow a reference to the signer's COA
_119
self.coa = signer.storage.borrow<auth(EVM.Bridge) &EVM.CadenceOwnedAccount>(from: /storage/evm)
_119
?? panic("Could not borrow COA from provided gateway address")
_119
_119
/* --- Construct the Vault type --- */
_119
//
_119
// Construct the Vault type from the provided identifier
_119
let vaultType = CompositeType(vaultIdentifier)
_119
?? panic("Could not construct Vault type from identifier: ".concat(vaultIdentifier))
_119
// Parse the Vault identifier into its components
_119
let tokenContractAddress = FlowEVMBridgeUtils.getContractAddress(fromType: vaultType)
_119
?? panic("Could not get contract address from identifier: ".concat(vaultIdentifier))
_119
let tokenContractName = FlowEVMBridgeUtils.getContractName(fromType: vaultType)
_119
?? panic("Could not get contract name from identifier: ".concat(vaultIdentifier))
_119
_119
/* --- Retrieve the funds --- */
_119
//
_119
// Borrow a reference to the FungibleToken Vault
_119
let viewResolver = getAccount(tokenContractAddress).contracts.borrow<&{ViewResolver}>(name: tokenContractName)
_119
?? panic("Could not borrow ViewResolver from FungibleToken contract")
_119
let vaultData = viewResolver.resolveContractView(
_119
resourceType: vaultType,
_119
viewType: Type<FungibleTokenMetadataViews.FTVaultData>()
_119
) as! FungibleTokenMetadataViews.FTVaultData? ?? panic("Could not resolve FTVaultData view")
_119
let vault = signer.storage.borrow<auth(FungibleToken.Withdraw) &{FungibleToken.Vault}>(
_119
from: vaultData.storagePath
_119
) ?? panic("Could not access signer's FungibleToken Vault")
_119
_119
// Withdraw the requested balance & calculate the approximate bridge fee based on storage usage
_119
let currentStorageUsage = signer.storage.used
_119
self.sentVault <- vault.withdraw(amount: amount)
_119
let withdrawnStorageUsage = signer.storage.used
_119
// Approximate the bridge fee based on the difference in storage usage with some buffer
_119
var approxFee = FlowEVMBridgeUtils.calculateBridgeFee(
_119
bytes: currentStorageUsage - withdrawnStorageUsage
_119
) * 1.10
_119
// Determine if the Vault requires onboarding - this impacts the fee required
_119
self.requiresOnboarding = FlowEVMBridge.typeRequiresOnboarding(self.sentVault.getType())
_119
?? panic("Bridge does not support this asset type")
_119
if self.requiresOnboarding {
_119
approxFee = approxFee + FlowEVMBridgeConfig.onboardFee
_119
}
_119
_119
/* --- Configure a ScopedFTProvider --- */
_119
//
_119
// Issue and store bridge-dedicated Provider Capability in storage if necessary
_119
if signer.storage.type(at: FlowEVMBridgeConfig.providerCapabilityStoragePath) == nil {
_119
let providerCap = signer.capabilities.storage.issue<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>(
_119
/storage/flowTokenVault
_119
)
_119
signer.storage.save(providerCap, to: FlowEVMBridgeConfig.providerCapabilityStoragePath)
_119
}
_119
// Copy the stored Provider capability and create a ScopedFTProvider
_119
let providerCapCopy = signer.storage.copy<Capability<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>>(
_119
from: FlowEVMBridgeConfig.providerCapabilityStoragePath
_119
) ?? panic("Invalid Provider Capability found in storage.")
_119
let providerFilter = ScopedFTProviders.AllowanceFilter(approxFee)
_119
self.scopedProvider <- ScopedFTProviders.createScopedFTProvider(
_119
provider: providerCapCopy,
_119
filters: [ providerFilter ],
_119
expiration: getCurrentBlock().timestamp + 1.0
_119
)
_119
}
_119
_119
pre {
_119
self.sentVault.getType().identifier == vaultIdentifier:
_119
"Attempting to send invalid vault type - requested: ".concat(vaultIdentifier)
_119
.concat(", sending: ").concat(self.sentVault.getType().identifier)
_119
}
_119
_119
execute {
_119
if self.requiresOnboarding {
_119
// Onboard the Vault to the bridge
_119
FlowEVMBridge.onboardByType(
_119
self.sentVault.getType(),
_119
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_119
)
_119
}
_119
// Execute the bridge
_119
self.coa.depositTokens(
_119
vault: <-self.sentVault,
_119
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_119
)
_119
// Destroy the ScopedFTProvider
_119
destroy self.scopedProvider
_119
}
_119
}

bridge_tokens_from_evm.cdc
bridge_tokens_from_evm.cdc

_112
import "FungibleToken"
_112
import "FungibleTokenMetadataViews"
_112
import "ViewResolver"
_112
import "MetadataViews"
_112
import "FlowToken"
_112
_112
import "ScopedFTProviders"
_112
_112
import "EVM"
_112
_112
import "FlowEVMBridge"
_112
import "FlowEVMBridgeConfig"
_112
import "FlowEVMBridgeUtils"
_112
_112
/// This transaction bridges fungible tokens from EVM to Cadence assuming it has already been onboarded to the
_112
/// FlowEVMBridge.
_112
///
_112
/// NOTE: The ERC20 must have first been onboarded to the bridge. This can be checked via the method
_112
/// FlowEVMBridge.evmAddressRequiresOnboarding(address: self.evmContractAddress)
_112
///
_112
/// @param vaultIdentifier: The Cadence type identifier of the FungibleToken Vault to bridge
_112
/// - e.g. vault.getType().identifier
_112
/// @param amount: The amount of tokens to bridge from EVM
_112
///
_112
transaction(vaultIdentifier: String, amount: UInt256) {
_112
_112
let vaultType: Type
_112
let receiver: &{FungibleToken.Vault}
_112
let scopedProvider: @ScopedFTProviders.ScopedFTProvider
_112
let coa: auth(EVM.Bridge) &EVM.CadenceOwnedAccount
_112
_112
prepare(signer: auth(BorrowValue, CopyValue, IssueStorageCapabilityController, PublishCapability, SaveValue, UnpublishCapability) &Account) {
_112
/* --- Reference the signer's CadenceOwnedAccount --- */
_112
//
_112
// Borrow a reference to the signer's COA
_112
self.coa = signer.storage.borrow<auth(EVM.Bridge) &EVM.CadenceOwnedAccount>(from: /storage/evm)
_112
?? panic("Could not borrow COA from provided gateway address")
_112
_112
/* --- Construct the Vault type --- */
_112
//
_112
// Construct the Vault type from the provided identifier
_112
self.vaultType = CompositeType(vaultIdentifier)
_112
?? panic("Could not construct Vault type from identifier: ".concat(vaultIdentifier))
_112
// Parse the Vault identifier into its components
_112
let tokenContractAddress = FlowEVMBridgeUtils.getContractAddress(fromType: self.vaultType)
_112
?? panic("Could not get contract address from identifier: ".concat(vaultIdentifier))
_112
let tokenContractName = FlowEVMBridgeUtils.getContractName(fromType: self.vaultType)
_112
?? panic("Could not get contract name from identifier: ".concat(vaultIdentifier))
_112
_112
/* --- Reference the signer's Vault --- */
_112
//
_112
// Borrow a reference to the FungibleToken Vault, configuring if necessary
_112
let viewResolver = getAccount(tokenContractAddress).contracts.borrow<&{ViewResolver}>(name: tokenContractName)
_112
?? panic("Could not borrow ViewResolver from FungibleToken contract")
_112
let vaultData = viewResolver.resolveContractView(
_112
resourceType: self.vaultType,
_112
viewType: Type<FungibleTokenMetadataViews.FTVaultData>()
_112
) as! FungibleTokenMetadataViews.FTVaultData? ?? panic("Could not resolve FTVaultData view")
_112
// If the vault does not exist, create it and publish according to the contract's defined configuration
_112
if signer.storage.borrow<&{FungibleToken.Vault}>(from: vaultData.storagePath) == nil {
_112
signer.storage.save(<-vaultData.createEmptyVault(), to: vaultData.storagePath)
_112
_112
signer.capabilities.unpublish(vaultData.receiverPath)
_112
signer.capabilities.unpublish(vaultData.metadataPath)
_112
_112
let receiverCap = signer.capabilities.storage.issue<&{FungibleToken.Vault}>(vaultData.storagePath)
_112
let metadataCap = signer.capabilities.storage.issue<&{FungibleToken.Vault}>(vaultData.storagePath)
_112
_112
signer.capabilities.publish(receiverCap, at: vaultData.receiverPath)
_112
signer.capabilities.publish(metadataCap, at: vaultData.metadataPath)
_112
}
_112
self.receiver = signer.storage.borrow<&{FungibleToken.Vault}>(from: vaultData.storagePath)
_112
?? panic("Could not borrow Vault from storage path")
_112
_112
/* --- Configure a ScopedFTProvider --- */
_112
//
_112
// Calculate the bridge fee - bridging from EVM consumes no storage, so flat fee
_112
let approxFee = FlowEVMBridgeUtils.calculateBridgeFee(bytes: 0)
_112
// Issue and store bridge-dedicated Provider Capability in storage if necessary
_112
if signer.storage.type(at: FlowEVMBridgeConfig.providerCapabilityStoragePath) == nil {
_112
let providerCap = signer.capabilities.storage.issue<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>(
_112
/storage/flowTokenVault
_112
)
_112
signer.storage.save(providerCap, to: FlowEVMBridgeConfig.providerCapabilityStoragePath)
_112
}
_112
// Copy the stored Provider capability and create a ScopedFTProvider
_112
let providerCapCopy = signer.storage.copy<Capability<auth(FungibleToken.Withdraw) &{FungibleToken.Provider}>>(
_112
from: FlowEVMBridgeConfig.providerCapabilityStoragePath
_112
) ?? panic("Invalid Provider Capability found in storage.")
_112
let providerFilter = ScopedFTProviders.AllowanceFilter(approxFee)
_112
self.scopedProvider <- ScopedFTProviders.createScopedFTProvider(
_112
provider: providerCapCopy,
_112
filters: [ providerFilter ],
_112
expiration: getCurrentBlock().timestamp + 1.0
_112
)
_112
}
_112
_112
execute {
_112
// Execute the bridge request
_112
let vault: @{FungibleToken.Vault} <- self.coa.withdrawTokens(
_112
type: self.vaultType,
_112
amount: amount,
_112
feeProvider: &self.scopedProvider as auth(FungibleToken.Withdraw) &{FungibleToken.Provider}
_112
)
_112
// Ensure the bridged vault is the correct type
_112
assert(vault.getType() == self.vaultType, message: "Bridged vault type mismatch")
_112
// Deposit the bridged token into the signer's vault
_112
self.receiver.deposit(from: <-vault)
_112
// Destroy the ScopedFTProvider
_112
destroy self.scopedProvider
_112
}
_112
}

Prep Your Assets for Bridging

Context

To maximize utility to the ecosystem, this bridge is permissionless and open to any fungible or non-fungible token as defined by the respective Cadence standards and limited to ERC20 and ERC721 Solidity standards. Ultimately, a project does not have to do anything for users to be able to bridge their assets between VMs. However, there are some considerations developers may take to enhance the representation of their assets in non-native VMs. These largely relate to asset metadata and ensuring that bridging does not compromise critical user assumptions about asset ownership.

EVMBridgedMetadata

Proposed in @onflow/flow-nft/pull/203, the EVMBridgedMetadata view presents a mechanism to both represent metadata from bridged EVM assets as well as enable Cadence-native projects to specify the representation of their assets in EVM. Implementing this view is not required for assets to be bridged, but the bridge does default to it when available as a way to provide projects greater control over their EVM asset definitions within the scope of ERC20 and ERC721 standards.

The interface for this view is as follows:


_20
access(all) struct URI: MetadataViews.File {
_20
/// The base URI prefix, if any. Not needed for all URIs, but helpful
_20
/// for some use cases For example, updating a whole NFT collection's
_20
/// image host easily
_20
access(all) let baseURI: String?
_20
/// The URI string value
_20
/// NOTE: this is set on init as a concatenation of the baseURI and the
_20
/// value if baseURI != nil
_20
access(self) let value: String
_20
_20
access(all) view fun uri(): String
_20
_20
}
_20
_20
access(all) struct EVMBridgedMetadata {
_20
access(all) let name: String
_20
access(all) let symbol: String
_20
_20
access(all) let uri: {MetadataViews.File}
_20
}

This uri value could be a pointer to some offchain metadata if you expect your metadata to be static. Or you could couple the uri() method with the utility contract below to serialize the onchain metadata on the fly. Alternatively, you may choose to host a metadata proxy which serves the requested token URI content.

SerializeMetadata

The key consideration with respect to metadata is the distinct metadata storage patterns between ecosystem. It's critical for NFT utility that the metadata be bridged in addition to the representation of the NFTs ownership. However, it's commonplace for Cadence NFTs to store metadata onchain while EVM NFTs often store an onchain pointer to metadata stored offchain. In order for Cadence NFTs to be properly represented in EVM platforms, the metadata must be bridged in a format expected by those platforms and be done in a manner that also preserves the atomicity of bridge requests. The path forward on this was decided to be a commitment of serialized Cadence NFT metadata into formats popular in the EVM ecosystem.

For assets that do not implement EVMBridgedMetadata, the bridge will attempt to serialize the metadata of the asset as a JSON data URL string. This is done via the SerializeMetadata contract which serializes metadata values into a JSON blob compatible with the OpenSea metadata standard. The serialized metadata is then committed as the ERC721 tokenURI upon bridging Cadence-native NFTs to EVM. Since Cadence NFTs can easily update onchain metadata either by field or by the ownership of sub-NFTs, this serialization pattern enables token URI updates on subsequent bridge requests.

Opting Out

It's also recognized that the logic of some use cases may actually be compromised by the act of bridging, particularly in such a unique partitioned runtime environment. Such cases might include those that do not maintain ownership assumptions implicit to ecosystem standards.

For instance, an ERC721 implementation may reclaim a user's assets after a month of inactivity. In such a case, bridging that ERC721 to Cadence would decouple the representation of ownership of the bridged NFT from the actual ownership in the defining ERC721 contract after the token had been reclaimed - there would be no NFT in escrow for the bridge to transfer on fulfillment of the NFT back to EVM. In such cases, projects may choose to opt-out of bridging, but importantly must do so before the asset has been onboarded to the bridge.

For Solidity contracts, opting out is as simple as extending the BridgePermissions.sol abstract contract which defaults allowsBridging() to false. The bridge explicitly checks for the implementation of IBridgePermissions and the value of allowsBridging() to validate that the contract has not opted out of bridging.

Similarly, Cadence contracts can implement the IBridgePermissions.cdc contract interface. This contract has a single method allowsBridging() with a default implementation returning false. Again, the bridge explicitly checks for the implementation of IBridgePermissions and the value of allowsBridging() to validate that the contract has not opted out of bridging. Should you later choose to enable bridging, you can simply override the default implementation and return true.

In both cases, allowsBridging() gates onboarding to the bridge. Once onboarded - a permissionless operation anyone can execute - the value of allowsBridging() is irrelevant and assets can move between VMs permissionlessly.

Under the Hood

For an in-depth look at the high-level architecture of the bridge, see FLIP #237

Additional Resources

For the current state of Flow EVM across various task paths, see the following resources: