This is a description of the Flow standard for fungible token contracts. It is meant to contain the minimum requirements to implement a safe, secure, easy to understand, and easy to use fungible token contract. It also includes an example implementation to show how a concrete smart contract would actually implement the interface.
Flow is a new blockchain for open worlds. Read more about it here.
Cadence is a new Resource-oriented programming language for developing smart contracts for the Flow Blockchain. Read more about it here and see its implementation here
We recommend that anyone who is reading this should have already completed the Cadence Tutorials so they can build a basic understanding of the programming language.
Resource-oriented programming, and by extension Cadence, is the perfect programming environment for currencies, because users are able to store their tokens directly in their accounts and transact peer-to-peer. Please see the blog post about resources to understand why they are perfect for digital assets.
Flow and Cadence are both still in development, so this standard will still be going through a lot of changes as the protocol and language evolves, and as we receive feedback from the community about the standard.
We'd love to hear from anyone who has feedback. Main feedback we are looking for is:
The feedback we are looking for is:
- Are there any features that are missing from the standard?
- Are the features that we have included defined in the best way possible?
- Are there any pre and post conditions for functions that are missing?
- Are the pre and post conditions defined well enough? Error messages?
- Are there any other actions that need an event defined for them?
- Are the current event definitions clear enough and do they provide enough information for apps and other actors a clear look into what is happening?
- Are the variable, function, and parameter names descriptive enough?
- Are there any openings for bugs or vulnerabilities that we are not noticing?
- Is the documentation/comments clear and concise and organized in a coherent manner?
The code for the standard is in contracts/FungibleToken.cdc
. An example implementation of the standard that simulates what a simple token would be like is in contracts/ExampleToken.cdc
.
The exact smart contract that is used for the official Flow Network Token is in contracts/FlowToken.cdc
Example transactions that users could use to interact with fungible tokens are located in the transactions/
directory. These templates are mostly generic and can be used with any fungible token implementation by providing the correct addresses, names, and values.
The standard consists of a contract interface called FungibleToken
that requires implementing contracts to define a Vault
resource that represents the tokens that an account owns. Each account that owns tokens will have a Vault
stored in its account storage. Users call functions on each other's Vault
s to send and receive tokens.
Right now we are using unsigned 64-bit fixed point numbers UFix64
as the type to represent token balance information. This type has 8 decimal places and cannot represent negative numbers.
1- Getting metadata for the token smart contract via the fields of the contract:
pub var totalSupply: UFix64
- The only required field of the contract. It would be incremented when new tokens are minted and decremented when they are destroyed.
- Event that gets emitted when the contract is initialized
pub event TokensInitialized(initialSupply: UFix64)
2- Retrieving the token fields of a Vault
in an account that owns tokens.
- Balance interface
pub var balance: UFix64
- The only required field of the
Vault
type
- The only required field of the
3- Withdrawing a specific amount of tokens amount using the withdraw function of the owner's Vault
- Provider interface
pub fun withdraw(amount: UFix64): @FungibleToken.Vault
- Conditions
- the returned Vault's balance must equal the amount withdrawn
- The amount withdrawn must be less than or equal to the balance
- The resulting balance must equal the initial balance - amount
- Conditions
- Users can give other accounts a reference to their
Vault
cast as aProvider
to allow them to withdraw and send tokens for them. A contract can define any custom logic to govern the amount of tokens that can be withdrawn at a time with aProvider
. This can mimic theapprove
,transferFrom
functionality of ERC20.
- withdraw event
- Indicates how much was withdrawn and from what account the
Vault
is stored in. If theVault
is not in account storage when the event is emitted,from
will benil
. pub event TokensWithdrawn(amount: UFix64, from: Address?)
- Indicates how much was withdrawn and from what account the
4 - Depositing a specific amount of tokens from using the deposit function of the recipient's Vault
-
Receiver
interfacepub fun deposit(from: @FungibleToken.Vault)
- Conditions
from
balance must be non-zero- The resulting balance must be equal to the initial balance + the balance of
from
-
deposit event
- Indicates how much was deposited and to what account the
Vault
is stored in. If theVault
is not in account storage when the event is emitted,to
will benil
. pub event TokensDeposited(amount: UFix64, to: Address?)
- Indicates how much was deposited and to what account the
-
Users could create custom
Receiver
s to trigger special code when transfers to them happen, like forwarding the tokens to another account, splitting them up, and much more. -
It is important that if you are making your own implementation of the fungible token interface that you cast the input to
deposit
as the type of your token.let vault <- from as! @ExampleToken.Vault
The interface specifies the argument as@FungibleToken.Vault
, any resource that satisfies this can be sent to the deposit function. The interface checks that the concrete types match, but you'll still need to cast theVault
before storing it.
5 - Creating an empty Vault resource
pub fun createEmptyVault(): @FungibleToken.Vault
- Defined in the contract
To create an empty
Vault
, the caller calls the function in the contract and stores the Vault in their storage. - Conditions:
- the balance of the returned Vault must be 0
6 - Destroying a Vault
If a Vault
is explicitly destroyed using Cadence's destroy
keyword, the balance of the destroyed vault must be subtracted from the total supply.
7 - Standard for Token Metadata
- not sure what this should be yet
- Could be a dictionary, could be an IPFS hash, could be json, etc.
- need suggestions!
This spec covers much of the same ground that a spec like ERC-20 covers, but without most of the downsides.
- Tokens cannot be sent to accounts or contracts that don't have owners or don't understand how to use them, because an account has to have a
Vault
in its storage to receive tokens. Nosafetransfer
is needed. - If the recipient is a contract that has a stored
Vault
, the tokens can just be deposited to that Vault without having to do a clunkyapprove
,transferFrom
- Events are defined in the contract for withdrawing and depositing, so a recipient will always be notified that someone has sent them tokens with the deposit event.
- The
approve
,transferFrom
pattern is not included, so double spends are not permitted - Transfers can trigger actions because users can define custom
Receivers
to execute certain code when a token is sent. - Cadence integer types protect against overflow and underflow, so a
SafeMath
-equivalent library is not needed.
FT Metadata is represented in a flexible and modular way using both the standard proposed in FLIP-0636 and the standard proposed in FLIP-1087.
When writing an NFT contract, you should implement the MetadataViews.Resolver
interface, which allows your Vault
resource to implement one or more metadata types called views.
Views do not specify or require how to store your metadata, they only specify the format to query and return them, so projects can still be flexible with how they store their data.
The Example Token contract defines three new views that can used to communicate any fungible token information:
FTView
A view that wraps the two other views that actually contain the data.FTDisplay
The view that contains all the information that will be needed by other dApps to display the fungible token: name, symbol, description, external URL, logos and links to social media.FTVaultData
The view that can be used by other dApps to interact programmatically with the fungible token, providing the information about the public and private paths used by default by the token, the public and private linked types for exposing capabilities and the function for creating new empty vaults. You can use this view to setup an account using the vault stored in other account without the need of importing the actual token contract.
The Example Token contract shows how to implement metadata views for fungible tokens.
In this repository you can find examples on how to read metadata, accessing the ExampleToken
display (name, symbol, logos, etc.) and its vault data (paths, linked types and the method to create a new vault).
First step will be to borrow a reference to the token's vault stored in some account:
let vaultRef = account
.getCapability(ExampleToken.VaultPublicPath)
.borrow<&{MetadataViews.Resolver}>()
?? panic("Could not borrow a reference to the vault resolver")
Latter using that reference you can call methods defined in the Fungible Token Metadata Views contract that will return you the structure containing the desired information:
let ftView = FungibleTokenMetadataViews.getFTView(viewResolver: vaultRef)
Alternatively you could call directly the resolveView(_ view: Type): AnyStruct?
method on the ExampleToken.Vault
, but the getFTView(viewResolver: &{MetadataViews.Resolver}): FTView
, getFTDisplay(_ viewResolver: &{MetadataViews.Resolver}): FTDisplay?
and getFTVaultData(_ viewResolver: &{MetadataViews.Resolver}): FTVaultData?
defined on the FungibleMetadataViews
contract will ease the process of dealing with optional types when retrieving this views.
Finally you can return the whole of structure or just log some values from the views depending on what you are aiming for:
return ftView
/*
When you retrieve a FTView both the FTDisplay and the FTVaultData views contained on it are optional values, meaning that the token could not be implementing then.
*/
log(ftView.ftDisplay!.symbol)
Minting and Burning are not included in the standard but are included in the FlowToken example contract to illustrate what minting and burning might look like for a token in Flow.
8 - Minting or Burning a specific amount of tokens using a specific minter resource that an owner can control
MintandBurn
Resource- function to mintTokens
- tokens minted event
- Each minter has a set amount of tokens that they are allowed to mint. This cannot be changed and a new minter needs to be created to add more allowance.
- function to burnTokens
- tokens Burnt event
- Each time tokens are minted or burnt, that value is added or subtracted to or from the total supply.
The following features could each be defined as a separate interface. It would be good to make standards for these, but not necessary to include in the main standard interface and are not currently defined in this example.
9 - Withdrawing a specific amount of tokens from someone else's Vault
by using their provider
reference.
- approved withdraw event
- Providing a resource that only approves an account to send a specific amount per transaction or per day/month/etc.
- Returning the amount of tokens that an account can send for another account.
- Reading the balance of the account that you have permission to send tokens for
- Owner is able to increase and decrease the approval at will, or revoke it completely
- This is much harder than anticipated
11 - Pausing Token transfers (maybe a way to prevent the contract from being imported)
12 - Cloning the token to create a new token with the same distribution
13 - Restricted ownership (For accredited investors and such)
- allowlisting
- denylisting
To use the Flow Token contract as is, you need to follow these steps:
- If you are using the Playground, you need to deploy the
FungibleToken
definition to account 1 yourself and import it inExampleToken
. It is a pre-deployed interface in the emulator, testnet, and mainnet and you can import definition from those accounts:0xee82856bf20e2aa6
on emulator0x9a0766d93b6608b7
on testnet0xf233dcee88fe0abe
on mainnet
- Deploy the
ExampleToken
definition - You can use the
get_balance.cdc
orget_supply.cdc
scripts to read the balance of a user'sVault
or the total supply of all tokens, respectively. - Use the
setupAccount.cdc
on any account to set up the account to be able to useFlowTokens
. - Use the
transfer_tokens.cdc
transaction file to send tokens from one user with aVault
in their account storage to another user with aVault
in their account storage. - Use the
mint_tokens.cdc
transaction with the admin account to mint new tokens. - Use the
burn_tokens.cdc
transaction with the admin account to burn tokens. - Use the
create_minter.cdc
transaction to create a new MintandBurn resource and store it in a new Admin's account.
FungibleTokenSwitchboard.cdc
, allows users to receive payments in different fungible tokens using a single &{FungibleToken.Receiver}
placed in a standard receiver path /public/GenericFTReceiver
.
Users willing to use the Fungible Token Switchboard will need to setup their accounts by creating a new FungibleTokenSwitchboard.Switchboard
resource and saving it to their accounts at the FungibleTokenSwitchboard.StoragePath
path.
This can be accomplished by executing the transaction found in this repository transactions/switchboard/setup_account.cdc
. This transaction will create and save a Switchboard resource to the signer's account,
and it also will create the needed public capabilities to access it. After setting up their switchboard, in order to make it support receiving a certain token, users will need to add the desired token's receiver capability to their switchboard resource.
When a user wants to receive a new fungible token through their switchboard, they will need to add a new public capability linked to said FT to their switchboard resource. This can be accomplished in two different ways:
-
Adding a single capability using
addNewVault(capability: Capability<&{FungibleToken.Receiver}>)
- Before calling this method on a transaction you should first retrieve the capability to the token's vault you are
willing to add to the switchboard, as is done in the template transaction
transactions/switchboard/add_vault_capability.cdc
.
transaction { let exampleTokenVaultCapabilty: Capability<&{FungibleToken.Receiver}> let switchboardRef: &FungibleTokenSwitchboard.Switchboard prepare(signer: AuthAccount) { // Get the example token vault capability from the signer's account self.exampleTokenVaultCapability = signer.getCapability<&{FungibleToken.Receiver}> (ExampleToken.ReceiverPublicPath) // Get a reference to the signers switchboard self.switchboardRef = signer.borrow<&FungibleTokenSwitchboard.Switchboard> (from: FungibleTokenSwitchboard.StoragePath) ?? panic("Could not borrow reference to switchboard") } execute { // Add the capability to the switchboard using addNewVault method self.switchboardRef.addNewVault(capability: self.exampleTokenVaultCapability) } }
This function will panic if is not possible to
.borrow()
a reference to a&{FungibleToken.Receiver}
from the passed capability. It will also panic if there is already a capability stored for the sameType
of resource exposed by the capability. - Before calling this method on a transaction you should first retrieve the capability to the token's vault you are
willing to add to the switchboard, as is done in the template transaction
-
Adding one or more capabilities using the paths where they are stored using
addNewVaultsByPath(paths: [PublicPath], address: Address)
- When using this method, an array of
PublicPath
objects should be passed along with theAddress
of the account from where the vaults' capabilities should be retrieved.
transaction (address: Address) { let exampleTokenVaultPath: PublicPath let vaultPaths: [PublicPath] let switchboardRef: &FungibleTokenSwitchboard.Switchboard prepare(signer: AuthAccount) { // Get the example token vault path from the contract self.exampleTokenVaultPath = ExampleToken.ReceiverPublicPath // And store it in the array of public paths that will be passed to the // switchboard method self.vaultPaths = [] self.vaultPaths.append(self.exampleTokenVaultPath) // Get a reference to the signers switchboard self.switchboardRef = signer.borrow<&FungibleTokenSwitchboard.Switchboard> (from: FungibleTokenSwitchboard.StoragePath) ?? panic("Could not borrow reference to switchboard") } execute { // Add the capability to the switchboard using addNewVault method self.switchboardRef.addNewVaultsByPath(paths: self.vaultPaths, address: address) } }
This function won't panic, instead it will just not add to the
@Switchboard
any capability which can not be retrieved from any of the providedPublicPath
s. It will also ignore any type of&{FungibleToken.Receiver}
that is already present on the@Switchboard
- When using this method, an array of
If a user no longer wants to be able to receive deposits from a certain FT, or if they want to update the provided capability for one of them, they will need to remove the vault from the switchboard.
This can be accomplished by using removeVault(capability: Capability<&{FungibleToken.Receiver}>)
.
This can be observed in the template transaction transactions/switchboard/remove_vault_capability.cdc
:
transaction {
let exampleTokenVaultCapabilty: Capability<&{FungibleToken.Receiver}>
let switchboardRef: &FungibleTokenSwitchboard.Switchboard
prepare(signer: AuthAccount) {
// Get the example token vault capability from the signer's account
self.exampleTokenVaultCapability = signer.getCapability
<&{FungibleToken.Receiver}>(ExampleToken.ReceiverPublicPath)
// Get a reference to the signers switchboard
self.switchboardRef = signer.borrow<&FungibleTokenSwitchboard.Switchboard>
(from: FungibleTokenSwitchboard.StoragePath)
?? panic("Could not borrow reference to switchboard")
}
execute {
// Remove the capability from the switchboard using the
// removeVault method
self.switchboardRef.removeVault(capability: self.exampleTokenVaultCapability)
}
}
This function will panic if is not possible to .borrow()
a reference to a &{FungibleToken.Receiver}
from the passed capability.
The Fungible Token Switchboard provides two different ways of depositing tokens to it, using the deposit(from: @FungibleToken.Vault)
method enforced by the {FungibleToken.Receiver}
or using the safeDeposit(from: @FungibleToken.Vault): @FungibleToken
:
- Using the first method will be just the same as depositing to
&{FungibleToken.Receiver}
. The path for the Switchboard receiver is defined inFungibleTokenSwitchboard.ReceiverPublicPath
, the generic receiver path/public/GenericFTReceiver
that can also be obtained from the NFT MetadataViews contract. An example of how to do this can be found in the transaction template on this repotransactions/switchboard/transfer_tokens.cdc
transaction(to: Address, amount: UFix64) {
// The Vault resource that holds the tokens that are being transferred
let sentVault: @FungibleToken.Vault
prepare(signer: AuthAccount) {
// Get a reference to the signer's stored vault
let vaultRef = signer.borrow<&ExampleToken.Vault>
(from: ExampleToken.VaultStoragePath)
?? panic("Could not borrow reference to the owner's Vault!")
// Withdraw tokens from the signer's stored vault
self.sentVault <- vaultRef.withdraw(amount: amount)
}
execute {
// Get the recipient's public account object
let recipient = getAccount(to)
// Get a reference to the recipient's Switchboard Receiver
let switchboardRef = recipient.getCapability
(FungibleTokenSwitchboard.ReceiverPublicPath)
.borrow<&{FungibleToken.Receiver}>()
?? panic("Could not borrow receiver reference to switchboard!")
// Deposit the withdrawn tokens in the recipient's switchboard receiver
switchboardRef.deposit(from: <-self.sentVault)
}
}
- The
safeDeposit(from: @FungibleToken.Vault): @FungibleToken
works in a similar way, with the difference that it will not panic if the desired FT Vault can not be obtained from the Switchboard. The method will return the passed vault, empty if the funds were deposited successfully or still containing the funds if the transfer of the funds was not possible. Keep in mind that when using this method on a transaction you will always have to deal with the returned resource. An example of this can be found ontransactions/switchboard/safe_transfer_tokens.cdc
:
transaction(to: Address, amount: UFix64) {
// The reference to the vault from the payer's account
let vaultRef: &ExampleToken.Vault
// The Vault resource that holds the tokens that are being transferred
let sentVault: @FungibleToken.Vault
prepare(signer: AuthAccount) {
// Get a reference to the signer's stored vault
self.vaultRef = signer.borrow<&ExampleToken.Vault>(from: ExampleToken.VaultStoragePath)
?? panic("Could not borrow reference to the owner's Vault!")
// Withdraw tokens from the signer's stored vault
self.sentVault <- self.vaultRef.withdraw(amount: amount)
}
execute {
// Get the recipient's public account object
let recipient = getAccount(to)
// Get a reference to the recipient's Switchboard Receiver
let switchboardRef = recipient.getCapability(FungibleTokenSwitchboard.PublicPath)
.borrow<&FungibleTokenSwitchboard.Switchboard{FungibleTokenSwitchboard.SwitchboardPublic}>()
?? panic("Could not borrow receiver reference to switchboard!")
// Deposit the withdrawn tokens in the recipient's switchboard receiver,
// then deposit the returned vault in the signer's vault
self.vaultRef.deposit(from: <- switchboardRef.safeDeposit(from: <-self.sentVault))
}
}
You can find automated tests in the lib/go/test/token_test.go
file. It uses the transaction templates that are contained in the lib/go/templates/transaction_templates.go
file. Currently, these rely on a dependency from a private dapper labs repository to run, so external users will not be able to run them. We are working on making all of this public so anyone can run tests, but haven't completed this work yet.
The works in these folders are under the Unlicense: