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Aptos Fungible Asset Standard

The Aptos Fungible Asset Standard (also known as Fungible Asset or FA) is a core framework component within Aptos that enables the tokenization of various assets, including commodities, real estate, and financial instruments. This standard facilitates the creation of decentralized financial applications.

The tokenization of securities and commodities provides fractional ownership, making these markets more accessible to a broader range of investors. Fungible tokens can also represent real estate ownership, enabling fractional ownership and providing liquidity to a traditionally illiquid market. In-game assets such as virtual currencies and characters can be tokenized, enabling players to own and trade their assets and creating new revenue streams for game developers and players.

Besides the aforementioned features, Fungible Asset (FA) is a superset of cryptocurrency, as coin is just one type of Fungible Asset. The Fungible Asset framework could replace the coin module in Move.

The Fungible Asset module provides a standard, type-safe framework for defining FAs within the Aptos Move ecosystem.

The standard is built upon Aptos object model, so all the resources defined here are included in the object resource group and stored inside objects. There are two types of objects related to FA:

  • Object<Metadata>: include information about the FA, such as name, symbol, and decimals.
  • Object<FungibleStore>: store a specific amount of FA units. FAs are units that are interchangeable with others of the same metadata. They can be stored in objects that contain a FungibleStore resource. These store objects can be freely created, and FAs can be moved, split, and combined between them easily.

The standard also supports minting new units and burning existing units with appropriate controls.

The different objects involved - Object<Metadata> and Object<FungibleStore> objects, and their relationships to accounts are shown in the diagram below:

fungible asset architecturefungible asset architecture

Difference with Aptos Coin​

FA is a broader category than just coins. While fungible coins are just one possible use case of FA, it can represent a wider range of fungible items, such as in-game assets like gems or rocks, event tickets, and partial ownership of real-world assets. FA provides the flexibility for customizable, detailed management and offers a new programming model based on objects. For Aptos coin, a Coin uses a generic, or the CoinType, to support distinct typing within the Coin framework. For example, Coin<A> and Coin<B> are two distinct coins, if A != B. In contrast, FA does not have a generic in struct definition but uses the metadata reference to distinguish the type, which will be further explained later. Minimally, Aptos coin should be interchangeable with FA. The migration plan is under discussion.

Structures​

Metadata Object​

Metadata objects with unique addresses define the type of the FAs. Even if Metadata structs of two Object<Metadata> are exactly the same, as long as their addresses are different, the FAs points to them would be different. In short, the address of the metadata object can be used as unique identifier of the FA type.

#[resource_group_member(group = aptos_framework::object::ObjectGroup)]
struct Metadata has key {
supply: Option<Supply>,
/// Name of the fungible metadata, i.e., "USDT".
name: String,
/// Symbol of the fungible metadata, usually a shorter version of the name.
/// For example, Singapore Dollar is SGD.
symbol: String,
/// Number of decimals used for display purposes.
/// For example, if `decimals` equals `2`, a balance of `505` coins should
/// be displayed to a user as `5.05` (`505 / 10 ** 2`).
decimals: u8,
}

Fungible Asset and Fungible Store​

FA allows typing by allocating an object reference that points to the metadata. Hence, a set of units of FA is represented as an amount and a reference to the metadata, as shown:

struct FungibleAsset {
metadata: Object<Metadata>,
amount: u64,
}

The FAs is a struct representing the type and the amount of units held. As the struct does not have either key or store abilities, it can only be passed from one function to another but must be consumed by the end of a transaction. Specifically, it must be deposited back into a fungible store at the end of the transaction, which is defined as:

#[resource_group_member(group = aptos_framework::object::ObjectGroup)]
struct FungibleStore has key {
/// The address of the base metadata object.
metadata: Object<Metadata>,
/// The balance of the fungible metadata.
balance: u64,
/// FAs transferring is a common operation, this allows for freezing/unfreezing accounts.
frozen: bool,
}
tip

FAs are always stored in the top-level FungibleStore resource. This makes it much easier to find, analyze, and control.

The only extra field added here is frozen. if it is true, this object is frozen, i.e., deposit and withdraw are both disabled without using TransferRef in the next section.

References​

Reference (ref) is the means to implement granular permission control across different standards in Aptos. In different contexts, it may be called capabilities. The FA standard has three distinct refs for minting, transferring, and burning FA: MintRef, TransferRef, and BurnRef. Each ref contains a reference to the FA metadata:

struct MintRef has drop, store {
metadata: Object<Metadata>
}

struct TransferRef has drop, store {
metadata: Object<Metadata>
}

struct BurnRef has drop, store {
metadata: Object<Metadata>
}

Ref owners can do the following operations depending on the refs they own:

  • MintRef offers the capability to mint new FA units.
  • TransferRef offers the capability to mutate the value of freeze in any FungibleStore of the same metadata or transfer FA by ignoring freeze.
  • BurnRef offers the capability to burn or delete FA units.

The three refs collectively act as the building blocks of various permission control systems as they have store so can be passed around and stored anywhere. Please refer to the source file for mint(), mint_to(), burn(), burn_from(), withdraw_with_ref(), deposit_with_ref(), and transfer_with_ref(): These functions are used to mint, burn, withdraw, deposit, and transfer FA using the MintRef, BurnRef, and TransferRef.

Note, these are framework functions and must be combined with business logic to produce a usable system. Developers who want to use these functions should familiarize themselves with the concepts of Aptos object model and understand how the reference system enables extensible designs within Aptos move.

Creators​

A Fungible Asset creator can add fungibility to any non-deletable object at creation by taking &ConstructorRef with the required information to make that object a metadata of the associated FA. Then FA of this metadata can be minted and used. It is noted here that non-deletable means the can_delete field of &ConstructorRef has to be false.

public fun add_fungibility(
constructor_ref: &ConstructorRef,
maximum_supply: Option<u128>,
name: String,
symbol: String,
decimals: u8,
icon_uri: String,
project_uri: String,
): Object<Metadata>

The creator has the opportunity to define a name, symbol, decimals, icon URI, project URI, and whether the total supply for the FA has a maximum. The following applies:

  • The first three of the above (name, symbol, decimals, icon_uri, project_uri) are purely metadata and have no impact for on-chain applications. Some applications may use decimals to equate a single Coin from a fractional coin.
  • Maximum supply (maximum_supply) helps check the total supply does not exceed a maximum value. However, due to the way the parallel executor works, setting the maximum supply will prevent any parallel execution of mint and burn.

Users​

Users are FA holders, who can:

  • Merge two FAs of the same metadata object.
  • Extract FA partially from another.
  • Deposit to and withdraw from a FungibleStore and emit events as a result.

Primitives​

At creation, the creator has the option to generate refs from the same &ConstructorRef to manage FA. These will need to be stored in global storage to be used later.

Mint​

If the manager would like to mint FA, they must retrieve a reference to MintRef and call:

public fun mint(ref: &MintRef, amount: u64): FungibleAsset

This will produce a new FA of the metadata in the ref, containing a value as dictated by the amount. The supply will also be adjusted. Also, there is a mint_to function that deposits to a FungibleStore after minting as a helper.

Burn​

The opposite operation of minting. Likewise, a reference to BurnRef is required and call:

public fun burn(ref: &BurnRef, fa: FungibleAsset)

This will reduce the passed-in fa to ashes and adjust the supply. There is also a burn_from function that forcibly withdraws FA from an account first and then burns the withdrawn FA as a helper.

Transfer and Freeze/Unfreeze​

TransferRef has two functions:

  • Flip frozen in FungibleStore holding FA of the same metadata in the TransferRef. if it is true, the store is "frozen" that nobody can deposit to or withdraw from this store without using the ref.
  • Withdraw from or deposit to a store ignoring frozen field.

To change frozen, call:

public fun set_frozen_flag<T: key>(
ref: &TransferRef,
store: Object<T>,
frozen: bool,
)
tip

This function will emit a FrozenEvent.

To forcibly withdraw, call:

public fun withdraw_with_ref<T: key>(
ref: &TransferRef,
store: Object<T>,
amount: u64
): FungibleAsset
tip

This function will emit a WithdrawEvent.

To forcibly deposit, call:

public fun deposit_with_ref<T: key>(
ref: &TransferRef,
store: Object<T>,
fa: FungibleAsset
)
tip

This function will emit a DepositEvent.

There is a function named transfer_with_ref that combining withdraw_with_ref and deposit_with_ref together as a helper.

Merging Fungible Assets​

Two FAs of the same type can be merged into a single struct that represents the accumulated value of the two
independently by calling:

public fun merge(dst_fungible_asset: &mut FungibleAsset, src_fungible_asset: FungibleAsset)

After merging, dst_fungible_asset will have all the amounts.

Extracting Fungible Asset​

A Fungible Asset can have amount deducted to create another FA by calling:

public fun extract(fungible_asset: &mut FungibleAsset, amount: u64): FungibleAsset
tip

This function may produce FA with 0 amount, which is not usable. It is supposed to be merged with other FA or destroyed through destroy_zero() in the module.

Withdraw​

The owner of a FungibleStore object that is not frozen can extract FA with a specified amount, by calling:

public fun withdraw<T: key>(owner: &signer, store: Object<T>, amount: u64): FungibleAsset
tip

This function will emit a WithdrawEvent.

Deposit​

Any entity can deposit FA into a FungibleStore object that is not frozen, by calling:

public fun deposit<T: key>(store: Object<T>, fa: FungibleAsset)
tip

This function will emit a DepositEvent.

Transfer​

The owner of a FungibleStore can directly transfer FA from that store to another if neither is frozen by calling:

public entry fun transfer<T: key>(sender: &signer, from: Object<T>, to: Object<T>, amount: u64)
tip

This will emit both WithdrawEvent and DepositEvent on the respective Fungibletores.

Events​

  • DepositEvent: Emitted when FAs are deposited into a store.
  • WithdrawEvent: Emitted when FAs are withdrawn from a store.
  • FrozenEvent: Emitted when the frozen status of a fungible store is updated.
struct DepositEvent has drop, store {
amount: u64,
}
struct WithdrawEvent has drop, store {
amount: u64,
}
struct FrozenEvent has drop, store {
frozen: bool,
}

Primary and secondary FungibleStores

Each FungibleStore object has an owner. However, an owner may possess more than one store. When Alice sends FA to Bob, how does she determine the correct destination? Additionally, what happens if Bob doesn't have a store yet?

To address these questions, the standard has been expanded to define primary and secondary stores.

  • Each account owns only one non-deletable primary store for each type of FA, the address of which is derived in a deterministic manner from the account address and metadata object address. If primary store does not exist, it will be created if FA is going to be deposited by calling functions defined in primary_fungible_store.move
  • Secondary stores do not have deterministic addresses and are theoretically deletable. Users are able to create as many secondary stores as they want using the provided functions but there is a caveat that addressing secondary stores on-chain may need extra work.

The vast majority of users will have primary store as their only store for a specific type of FAs. It is expected that secondary stores would be useful in complicated defi or other asset management contracts that will be introduced in other tutorials using FA.

How to enable Primary FungibleStore?​

To add primary store support, when creating a metadata object, instead of the aforementioned add_fungibility(), the creator has to call:

public fun create_primary_store_enabled_fungible_asset(
constructor_ref: &ConstructorRef,
maximum_supply: Option<u128>,
name: String,
symbol: String,
decimals: u8,
icon_uri: String,
project_uri: String,
)

The parameters are the same as those of add_fungibility().

Primitives​

Get Primary FungibleStore​

To get the primary store object of a metadata object belonging to an account, call:

public fun primary_store<T: key>(owner: address, metadata: Object<T>): Object<FungibleStore>
tip

There are other utility functions. primary_store_address returns the deterministic address the primary store, and primary_store_exists checks the existence, etc.

Manually Create Primary FungibleStore​

If a primary store does not exist, any entity is able to create it by calling:

public fun create_primary_store<T: key>(owner_addr: address, metadata: Object<T>): Object<FungibleStore>

Check Balance and Frozen Status​

To check the balance of a primary store, call:

public fun balance<T: key>(account: address, metadata: Object<T>): u64

To check whether the given account's primary store is frozen, call:

public fun is_frozen<T: key>(account: address, metadata: Object<T>): bool

Withdraw​

An owner can withdraw FA from their primary store by calling:

public fun withdraw<T: key>(owner: &signer, metadata: Object<T>, amount: u64): FungibleAsset

Deposit​

An owner can deposit FA to their primary store by calling:

public fun deposit(owner: address, fa: FungibleAsset)

Transfer​

An owner can deposit FA from their primary store to that of another account by calling:

public entry fun transfer<T: key>(sender: &signer, metadata: Object<T>, recipient: address, amount: u64)

Secondary FungibleStore​

Secondary stores are not commonly used by normal users but prevailing for smart contracts to manage assets owned by contracts. For example, an asset pool may have to manage multiple fungible stores for one or more types of FA. Those stores do not necessarily have to have deterministic addresses and a user may have multiple stores for a given kind of FA. So primary fungible store is not a good fit for the needs where secondary store plays a vital role.

The way to create secondary store is to create an object first and get its ConstructorRef. Then call:

public fun create_store<T: key>(
constructor_ref: &ConstructorRef,
metadata: Object<T>,
): Object<FungibleStore>

It will turn make the newly created object a FungibleStore. Sometimes an object can be reused as a store. For example, a metadata object can also be a store to hold some FA of its own type or a liquidity pool object can be a store of the issued liquidity pool's token/coin.

Ownership of FungibleStore​

It is crucial to set correct owner of a FungibleStore object for managing the FA stored inside. By default, the owner of a newly created object is the creator whose signer is passed into the creation function. For FungibleStore objects managed by smart contract itself, usually they shouldn't have an owner out of the control of this contract. For those cases, those objects could make themselves as their owners and keep their object ExtendRef at the proper place to create signer as needed by the contract logic.

Migration from Coin to FA

The Aptos framework now facilitates automatic creation of a FA (Fungible Asset) for each coin type as needed. For instance, when a user without a CoinStore<CoinType> receives a Coin<CoinType>, the framework seamlessly converts the coin to its corresponding FA and deposits it into the user's PrimaryFungibleStore. As assets may exist in both coin and FA forms, dapps require updates to ensure smooth and transparent migration for users.

Smart Contract Migration​

Projects utilizing the coin module need not modify their contracts. The coin module has been enhanced to handle migration automatically. Whenever a paired FA is required for a coin, it will be automatically created if it doesn't already exist. The mapping between coins and FAs is immutable and stored in an on-chain table:

struct CoinConversionMap has key {
coin_to_fungible_asset_map: Table<TypeInfo, address>,
}

A #[view] function is available to retrieve metadata for the paired FA if it exists:

#[view]
public fun paired_metadata<CoinType>(): Option<Object<Metadata>>

Similarly, a function exists for reverse lookup:

#[view]
public fun paired_coin(metadata: Object<Metadata>): Option<TypeInfo>

Off-chain Migration​

Since paired FAs are integrated into the coin module, off-chain migration involves two aspects:

Balance​

If a coin has a paired FA, a user may possess both as the same asset. So the balance has to be updated from coin balance only to the sum of coin balance and its paired FA balance.

  • For Aptos Indexer users, utilize a new table called current_unified_fungible_asset_balances to obtain the latest sum of coin balance and FA balance representing the same asset type.
  • For users employing Node API or other customized indexing, they should add the balance of the paired FA in users' FungibleStore and ConcurrentFungibleBalance if any of them exists to the coin balance.

To retrieve the balance of the PrimaryFungibleStore of the paired FA of coin type CoinType for a user:

  1. Call paired_metadata<CoinType>() to obtain the paired FA metadata object address, which is immutable, allowing for storage or caching to enhance performance.
  2. Retrieve the balance of the paired FA:
    • Call getCurrentFungibleAssetBalances;
    • Alternatively, determine the address of the primary FungibleStore, which is deterministic as sha3_256(32-byte account address | 32-byte metadata object address | 0xFC), and obtain the FungibleStore resource at this address to fetch the balance. If it is non-zero, this is the final balance of this FA. Otherwise, try to get ConcurrentFungibleBalance resource at the same address and get the balance there instead or 0 If ConcurrentFungibleBalance does not exist.

Event​

Post-migration, both coin events and FA events could be emitted for an activity, depending on whether the user has migrated or not. Dapps relying on events should update their business logic accordingly. If a dapp relies on the events, the business logic should be updated properly.