Callbacks
Super App callbacks play a pivotal role in how Super Apps interact with the Superfluid Protocol. These callbacks are invoked in response to specific events related to Super Agreements.
Callback Invocation Conditions
Depending on the Super Agreement involved, the callbacks are triggered under different scenarios. The following table outlines these conditions:
| Agreement | Callback | Condition |
|---|---|---|
| CFAv1 | beforeAgreementCreated, afterAgreementCreated | A stream to a Super App is created. |
| CFAv1 | beforeAgreementUpdated, afterAgreementUpdated | A stream to a Super App is updated. |
| CFAv1 | beforeAgreementTerminated, afterAgreementTerminated | A stream to a Super App is deleted. |
| IDAv1 | beforeAgreementCreated, afterAgreementCreated | A subscription (with zero units) to an index published by a Super App is approved. |
| IDAv1 | beforeAgreementUpdated, afterAgreementUpdated | A subscription (with units) to an index published by a Super App is approved. |
| IDAv1 | beforeAgreementTerminated, afterAgreementTerminated | A subscription to an index published by a Super App is revoked. |
| IDAv1 | beforeAgreementUpdated, afterAgreementUpdated | A subscription to an index published by a Super App is claimed |
| IDAv1 | beforeAgreementCreated, afterAgreementCreated | Units of an index are issued to a Super App if the units were previously zero. |
| IDAv1 | beforeAgreementUpdated, afterAgreementUpdated | Units of an index are issued to a Super App if the units were previously non-zero. |
| IDAv1 | beforeAgreementTerminated, afterAgreementTerminated | Units of an index issued to a Super App are deleted. |
Callback Origin
The Superfluid protocol itself triggers these callbacks on-chain in response to various actions performed within the Constant Flow Agreement contract. The protocol checks if a Super App is involved in a transaction and, if so, executes the relevant callbacks.
Anatomy of Super App Callbacks
Below are examples of Super App callbacks and their structure:
function beforeAgreementCreated(
ISuperToken /*superToken*/,
address /*agreementClass*/,
bytes32 /*agreementId*/,
bytes calldata /*agreementData*/,
bytes calldata /*ctx*/
) external view virtual override returns (bytes memory /*cbdata*/) {
revert("Unsupported callback - Before Agreement Created");
}
function afterAgreementCreated(
ISuperToken /*superToken*/,
address /*agreementClass*/,
bytes32 /*agreementId*/,
bytes calldata /*agreementData*/,
bytes calldata /*cbdata*/,
bytes calldata /*ctx*/
) external virtual override returns (bytes memory /*newCtx*/) {
revert("Unsupported callback - After Agreement Created");
}
Callback Execution
beforeAgreementcallbacks are executed before the corresponding agreement contract action. They areviewfunctions and can return data to be used inafterAgreementcallbacks.afterAgreementcallbacks are executed after the agreement contract action. They can implement logic based on the outcome of the agreement action and the data returned frombeforeAgreementcallbacks.
Callback Parameters
ISuperToken: The Super Token used in the transaction.address: Address of the Constant Flow Agreement contract.agreementId: A unique identifier for the agreement.agreementData: Encoded data of the agreement details.cbdata: Data returned frombeforeAgreementcallbacks (applicable toafterAgreementcallbacks).ctx: Context of the transaction, essential for understanding the background of the callback invocation.
Utilizing Callbacks
Understanding and effectively using these callbacks is crucial for Super App developers. Each callback serves a specific purpose and offers the flexibility to execute custom logic in response to changes in Super Agreements.
CallAgreement vs CallAgreementWithContext
If you're making a call to a Superfluid agreement inside of a Super App callback, you should remember that you need to "receive a context, and return a context" by using the callAgreementWithContext function. If you're not making this call inside of a Super App callback, you should use callAgreement.
Note that this is a highly technical section for those looking to understand lower level features of the protocol. If you're looking to create, update, and delete streams or work with the instant distribution agreement in your super app callbacks, you can refer to the SuperTokenV1Library to perform these operations in a single line of code.
In Depth
When calling the host contract to trigger actions related to the constant flow agreement (CFA) or instant distribution agreement (IDA), you may use either callAgreement or callAgreementWithContext. Both of these functions allow you to pass in an encoded call to the agreement you'd like to interact with, as well as an optional userData value. The callAgreementWithContext function will perform the same actions as the callAgreement function, but it also enables you to pass in a new context value (abbreviated ctx ) to your function call.
Keep in mind that callAgreementWithContext is designed for use within Super Apps - if this function is run outside of a Super App, then callAgreementWithContext will fail due to this statement:
require(
context.appAddress == msg.sender,
"SF: callAgreementWithContext from wrong address"
);
callAgreementWithContext is primarily meant for use within Super App callbacks. Each Super App callback will be passed a context value (ctx) from the host contract (as the Superfluid host contract is the caller of each callback). This ctx value is what needs to be passed to any call you want to make to the Superfluid host contract inside of your callback (this goes for all operations which create, update, and delete flows in these callbacks). As a reminder, the logic within the 'host' contract can be found in Superfluid.sol.
The process looks like this:
Click here to show the code
//a function which we'll use to create a flow within a callback
function _createFlowInCallback(
bytes calldata ctx,
ISuperfluid _host,
IConstantFlowAgreementV1 _cfa,
ISuperfluidToken _acceptedToken,
address _receiver,
int96 _flowRate
)
private
returns (bytes memory newCtx)
{
newCtx = ctx;
(newCtx,) = _host.callAgreementwithContext(
_cfa,
abi.encodeWithSelector(
_cfa.deleteFlow.selector,
_acceptedToken,
address(this),
_receiver,
new bytes(0) // placeholder
),
"0x", //placeholder userdata value
newCtx //passing in the context from the super app callback
);
}
function afterAgreementCreated(
ISuperToken _superToken,
address _agreementClass,
bytes32, // _agreementId,
bytes calldata /*_agreementData*/,
bytes calldata ,// _cbdata,
bytes calldata _ctx
)
external override
onlyExpected(_superToken, _agreementClass)
onlyHost
returns (bytes memory newCtx)
{
//passing in the ctx which is sent to the callback here
return _createFlowInCallback(_ctx, _host, _cfa, _acceptedToken, _receiver, _flowrate);
}
You can also do this in a much easier way by using our new CFA Library, which abstracts away the need to use host.callAgreement or host.callAgreementWithContext directly.
Click here to show the code
using CFALibraryV1 for CFALibraryV1.InitData;
//initialize cfaV1 variable
CFALibraryV1.InitData public cfaV1;
constructor(
ISuperfluid host
) {
//initialize InitData struct, and set equal to cfaV1
cfaV1 = CFALibraryV1.InitData(
host,
IConstantFlowAgreementV1(
address(host.getAgreementClass(
keccak256("org.superfluid-finance.agreements.ConstantFlowAgreement.v1")
))
)
);
}
function afterAgreementCreated(
ISuperToken _superToken,
address _agreementClass,
bytes32, // _agreementId,
bytes calldata /*_agreementData*/,
bytes calldata ,// _cbdata,
bytes calldata _ctx
)
external override
onlyExpected(_superToken, _agreementClass)
onlyHost
returns (bytes memory newCtx)
{
//passing in the ctx which is sent to the callback here
//createFlowWithCtx makes use of callAgreementWithContext
return cfaV1.createFlowWithCtx(_ctx, receiver, token, flowRate);
}
You may have another scenario in which you want to make additional calls to the host contract after you first run callAgreementWithContext. If you do this, you can save the value returned by the first callAgreementWithContext function to a new variable, then pass this value to your next call to callAgreementWithContext . The takeaway here is that you need to pass the most recent iteration of ctx when creating, updating, or deleting flows inside Super App callbacks. You can see this done here with the CFA Library:
Click here to show the code
using CFALibraryV1 for CFALibraryV1.InitData;
//initialize cfaV1 variable
CFALibraryV1.InitData public cfaV1;
constructor(
ISuperfluid host
) {
//initialize InitData struct, and set equal to cfaV1
cfaV1 = CFALibraryV1.InitData(
host,
IConstantFlowAgreementV1(
address(host.getAgreementClass(
keccak256("org.superfluid-finance.agreements.ConstantFlowAgreement.v1")
))
)
);
}
function afterAgreementCreated(
ISuperToken _superToken,
address _agreementClass,
bytes32, // _agreementId,
bytes calldata /*_agreementData*/,
bytes calldata ,// _cbdata,
bytes calldata _ctx
)
external override
onlyExpected(_superToken, _agreementClass)
onlyHost
returns (bytes memory newCtx)
{
newCtx = cfaV1.createFlowWithCtx(_ctx, receiver, token, flowRate); //passing in the ctx which is sent to the callback here
newCtx = cfaV1.createFlowWithCtx(newCtx, receiver, token, flowRate); //passing in the ctx which is returned from the first call here
}
One final item to note is to not manually change the value of ctx when it's used within a Super App. Ctx is formatted in a very specific way within a struct that is compiled to bytecode by the protocol, and it's not meant to be manipulated directly. If you wish to pass in userData to your function call, this can be done by simply adding the userData value in as a parameter:
Click here to show the code
//using the CFA Library:
function afterAgreementCreated(
ISuperToken _superToken,
address _agreementClass,
bytes32, // _agreementId,
bytes calldata /*_agreementData*/,
bytes calldata ,// _cbdata,
bytes calldata _ctx
)
external override
onlyExpected(_superToken, _agreementClass)
onlyHost
returns (bytes memory newCtx)
{
//passing in the ctx which is sent to the callback here
//createFlowWithCtx makes use of callAgreementWithContext
return cfaV1.createFlowWithCtx(_ctx, receiver, token, flowRate, userData);
}
//using a low level call
function afterAgreementCreated(
ISuperToken _superToken,
address _agreementClass,
bytes32, // _agreementId,
bytes calldata /*_agreementData*/,
bytes calldata ,// _cbdata,
bytes calldata _ctx
)
external override
onlyExpected(_superToken, _agreementClass)
onlyHost
returns (bytes memory newCtx)
{
newCtx = _ctx;
(newCtx,) = _host.callAgreementwithContext(
_cfa,
abi.encodeWithSelector(
_cfa.deleteFlow.selector,
_acceptedToken,
address(this),
_receiver,
new bytes(0) // placeholder
),
userData, //userData goes here
newCtx //passing in the context from the super app callback
);
}
If you read through the Superfluid codebase, you'll see that nearly every state changing operation will return a context value. This ctx value helps to provide additional internal accounting for the protocol to enhance security, and it allows you to decode it and make use of values like userData inside Super Apps. When making calls within your Super Apps, keep in mind that you need to pass in updated context values if you want to make use of the callbacks properly. Remember: if you need to run callAgreement within a Super App callback, you'll need to use callAgreementWithContext and pass in ctx.