Components: Lego-Like Building Blocks for Smart Contracts

Developing contracts sharing a common logic and storage can be painful and bug-prone, as this logic can hardly be reused and needs to be reimplemented in each contract. But what if there was a way to snap in just the extra functionality you need inside your contract, separating the core logic of your contract from the rest?

Components provide exactly that. They are modular add-ons encapsulating reusable logic, storage, and events that can be incorporated into multiple contracts. They can be used to extend a contract's functionality, without having to reimplement the same logic over and over again.

Think of components as Lego blocks. They allow you to enrich your contracts by plugging in a module that you or someone else wrote. This module can be a simple one, like an ownership component, or more complex like a full-fledged ERC20 token.

A component is a separate module that can contain storage, events, and functions. Unlike a contract, a component cannot be declared or deployed. Its logic will eventually be part of the contract’s bytecode it has been embedded in.

What's in a Component?

组件与合约非常相似。它可以包含:

  • Storage variables
  • Events
  • External and internal functions

Unlike a contract, a component cannot be deployed on its own. The component's code becomes part of the contract it's embedded to.

Creating Components

To create a component, first define it in its own module decorated with a #[starknet::component] attribute. Within this module, you can declare a Storage struct and Event enum, as usually done in contracts.

The next step is to define the component interface, containing the signatures of the functions that will allow external access to the component's logic. You can define the interface of the component by declaring a trait with the #[starknet::interface] attribute, just as you would with contracts. This interface will be used to enable external access to the component's functions using the dispatcher pattern.

The actual implementation of the component's external logic is done in an impl block marked as #[embeddable_as(name)]. Usually, this impl block will be an implementation of the trait defining the interface of the component.

Note: name is the name that we’ll be using in the contract to refer to the component. It is different than the name of your impl.

You can also define internal functions that will not be accessible externally, by simply omitting the #[embeddable_as(name)] attribute above the internal impl block. You will be able to use these internal functions inside the contract you embed the component in, but not interact with it from outside, as they're not a part of the abi of the contract.

Functions within these impl block expect arguments like ref self: ComponentState<TContractState> (for state-modifying functions) or self: @ComponentState<TContractState> (for view functions). This makes the impl generic over TContractState, allowing us to use this component in any contract.

Example: an Ownable Component

⚠️ The example shown below has not been audited and is not intended for production use. The authors are not responsible for any damages caused by the use of this code.

The interface of the Ownable component, defining the methods available externally to manage ownership of a contract, would look like this:

#[starknet::interface]
trait IOwnable<TContractState> {
    fn owner(self: @TContractState) -> ContractAddress;
    fn transfer_ownership(ref self: TContractState, new_owner: ContractAddress);
    fn renounce_ownership(ref self: TContractState);
}

组件本身定义为:

#[starknet::component]
pub mod ownable_component {
    use core::starknet::{ContractAddress, get_caller_address};
    use core::starknet::storage::{StoragePointerReadAccess, StoragePointerWriteAccess};
    use super::Errors;
    use core::num::traits::Zero;

    #[storage]
    pub struct Storage {
        owner: ContractAddress,
    }

    #[event]
    #[derive(Drop, starknet::Event)]
    pub enum Event {
        OwnershipTransferred: OwnershipTransferred,
    }

    #[derive(Drop, starknet::Event)]
    struct OwnershipTransferred {
        previous_owner: ContractAddress,
        new_owner: ContractAddress,
    }

    #[embeddable_as(Ownable)]
    impl OwnableImpl<
        TContractState, +HasComponent<TContractState>,
    > of super::IOwnable<ComponentState<TContractState>> {
        fn owner(self: @ComponentState<TContractState>) -> ContractAddress {
            self.owner.read()
        }

        fn transfer_ownership(
            ref self: ComponentState<TContractState>, new_owner: ContractAddress,
        ) {
            assert(!new_owner.is_zero(), Errors::ZERO_ADDRESS_OWNER);
            self.assert_only_owner();
            self._transfer_ownership(new_owner);
        }

        fn renounce_ownership(ref self: ComponentState<TContractState>) {
            self.assert_only_owner();
            self._transfer_ownership(Zero::zero());
        }
    }

    #[generate_trait]
    pub impl InternalImpl<
        TContractState, +HasComponent<TContractState>,
    > of InternalTrait<TContractState> {
        fn initializer(ref self: ComponentState<TContractState>, owner: ContractAddress) {
            self._transfer_ownership(owner);
        }

        fn assert_only_owner(self: @ComponentState<TContractState>) {
            let owner: ContractAddress = self.owner.read();
            let caller: ContractAddress = get_caller_address();
            assert(!caller.is_zero(), Errors::ZERO_ADDRESS_CALLER);
            assert(caller == owner, Errors::NOT_OWNER);
        }

        fn _transfer_ownership(
            ref self: ComponentState<TContractState>, new_owner: ContractAddress,
        ) {
            let previous_owner: ContractAddress = self.owner.read();
            self.owner.write(new_owner);
            self
                .emit(
                    OwnershipTransferred { previous_owner: previous_owner, new_owner: new_owner },
                );
        }
    }
}

This syntax is actually quite similar to the syntax used for contracts. The only differences relate to the #[embeddable_as] attribute above the impl and the genericity of the impl block that we will dissect in details.

As you can see, our component has two impl blocks: one corresponding to the implementation of the interface trait, and one containing methods that should not be exposed externally and are only meant for internal use. Exposing the assert_only_owner as part of the interface wouldn't make sense, as it's only meant to be used internally by a contract embedding the component.

A Closer Look at the impl Block

    #[embeddable_as(Ownable)]
    impl OwnableImpl<
        TContractState, +HasComponent<TContractState>,
    > of super::IOwnable<ComponentState<TContractState>> {

The #[embeddable_as] attribute is used to mark the impl as embeddable inside a contract. It allows us to specify the name of the impl that will be used in the contract to refer to this component. In this case, the component will be referred to as Ownable in contracts embedding it.

The implementation itself is generic over ComponentState<TContractState>, with the added restriction that TContractState must implement the HasComponent<T> trait. This allows us to use the component in any contract, as long as the contract implements the HasComponent trait. Understanding this mechanism in details is not required to use components, but if you're curious about the inner workings, you can read more in the "Components Under the Hood" section.

One of the major differences from a regular smart contract is that access to storage and events is done via the generic ComponentState<TContractState> type and not ContractState. Note that while the type is different, accessing storage or emitting events is done similarly via self.storage_var_name.read() or self.emit(...).

Note: To avoid the confusion between the embeddable name and the impl name, we recommend keeping the suffix Impl in the impl name.

Migrating a Contract to a Component

Since both contracts and components share a lot of similarities, it's actually very easy to migrate from a contract to a component. The only changes required are:

  • Adding the #[starknet::component] attribute to the module.
  • Adding the #[embeddable_as(name)] attribute to the impl block that will be embedded in another contract.
  • Adding generic parameters to the impl block:
    • Adding TContractState as a generic parameter.
    • Adding +HasComponent<TContractState> as an impl restriction.
  • Changing the type of the self argument in the functions inside the impl block to ComponentState<TContractState> instead of ContractState.

For traits that do not have an explicit definition and are generated using #[generate_trait], the logic is the same - but the trait is generic over TContractState instead of ComponentState<TContractState>, as demonstrated in the example with the InternalTrait.

Using Components Inside a Contract

The major strength of components is how it allows reusing already built primitives inside your contracts with a restricted amount of boilerplate. To integrate a component into your contract, you need to:

  1. Declare it with the component!() macro, specifying

    1. The path to the component path::to::component.
    2. The name of the variable in your contract's storage referring to this component's storage (e.g. ownable).
    3. The name of the variant in your contract's event enum referring to this component's events (e.g. OwnableEvent).
  2. Add the path to the component's storage and events to the contract's Storage and Event. They must match the names provided in step 1 (e.g. ownable: ownable_component::Storage and OwnableEvent: ownable_component::Event).

    The storage variable MUST be annotated with the #[substorage(v0)] attribute.

  3. Embed the component's logic defined inside your contract, by instantiating the component's generic impl with a concrete ContractState using an impl alias. This alias must be annotated with #[abi(embed_v0)] to externally expose the component's functions.

    As you can see, the InternalImpl is not marked with #[abi(embed_v0)]. Indeed, we don't want to expose externally the functions defined in this impl. However, we might still want to access them internally.

For example, to embed the Ownable component defined above, we would do the following:

#[starknet::contract]
mod OwnableCounter {
    use listing_01_ownable::component::ownable_component;
    use core::starknet::storage::{StoragePointerReadAccess, StoragePointerWriteAccess};

    component!(path: ownable_component, storage: ownable, event: OwnableEvent);

    #[abi(embed_v0)]
    impl OwnableImpl = ownable_component::Ownable<ContractState>;

    impl OwnableInternalImpl = ownable_component::InternalImpl<ContractState>;

    #[storage]
    struct Storage {
        counter: u128,
        #[substorage(v0)]
        ownable: ownable_component::Storage,
    }


    #[event]
    #[derive(Drop, starknet::Event)]
    enum Event {
        OwnableEvent: ownable_component::Event,
    }


    #[abi(embed_v0)]
    fn foo(ref self: ContractState) {
        self.ownable.assert_only_owner();
        self.counter.write(self.counter.read() + 1);
    }
}

The component's logic is now seamlessly part of the contract! We can interact with the components functions externally by calling them using the IOwnableDispatcher instantiated with the contract's address.

#[starknet::interface]
trait IOwnable<TContractState> {
    fn owner(self: @TContractState) -> ContractAddress;
    fn transfer_ownership(ref self: TContractState, new_owner: ContractAddress);
    fn renounce_ownership(ref self: TContractState);
}

Stacking Components for Maximum Composability

The composability of components really shines when combining multiple of them together. Each adds its features onto the contract. You can rely on Openzeppelin's implementation of components to quickly plug-in all the common functionalities you need a contract to have.

Developers can focus on their core contract logic while relying on battle-tested and audited components for everything else.

Components can even depend on other components by restricting the TContractstate they're generic on to implement the trait of another component. Before we dive into this mechanism, let's first look at how components work under the hood.