Demonstrates how to scalably initiate out-of-transaction processing from an apex trigger using Platform Events
- Avoid restricting DML to synchronous-only contexts.
- Allow callouts or limit-consuming processing on record changes.
- Ensure records are processed in a single-threaded manner (avoid race conditions and reduce record locking issues).
An apex trigger processes record creation, update, delete, undelete operations (or a subset thereof) for a given object. These are great for reacting to these changes to validate the records, apply further updates to these records, to (directly or indirectly) related records or to perform other operations. They have specific limitations because they execute synchronously, as part of a DML operation. A major limitation is the inability to perform a callout from within a trigger; callouts are used to initiate communication with (typically) external systems and are a common integration mechanism with off-platform software or systems.
Salesforce generally recommends performing callouts in a future method called from a trigger, but futures cannot be called when the initiating transaction itself is already asynchronous. That means it becomes impossible to make these callouts initiate from the trigger in a robust way that works in all contexts where that trigger could be called.
The above issue, and a whole bunch of other use cases are addressed by changing the approach and using Platform Events. Other important use cases are where you need to perform some specific processing, perhaps that is too costly in terms of CPU or other limits to include in the trigger, when a record is updated to meet certain criteria and where this processing must only be applied at most once for any given record change.
This repo contains code that addresses the callout and/or governor limit related use cases in an elegant and robust manner.
This demonstration does not include any unit tests, but shows how you can use timestamp fields and a platform event to safely and robustly process records in a separate transaction to the one that detected a need for the processing.
The key parts of this solution are:
| Component | Description |
|---|---|
| Example__c | The custom object for which processing is required in this demo. Contains data fields plus the processing control fields. |
| Example.trigger ExampleHandler |
The DML trigger and trigger handler for Example__c. |
| EventProcessor | The interface that represents processors for types of event. |
| ExampleProcessor | The EventProcessor implementation for handling Example__c records that need it. This does the "callout and/or governor limit consuming processing", as required. Here it simply does some simple data manipulation. |
| TriggeredEvent__e | The platform event published when an Example__c needs processing. Could be used for other objects too. Holds the type name for the processor that should be instantiated and run. |
| TriggeredEvent.trigger TriggeredEventHandler |
The trigger-based Platform Event subscriber and handler for TriggeredEvent__e. Ensures that events for unique types of processor are consumed, executing a single EventProcessor for the first type and re-publishing unconsumed types. If the current type needs further processing, an additional event is published for this type in order to ensure it gets chained (after any unconsumed types). |
Note:
- Changes to the
Account__cor theDatetime__cfield values inExample__crecords initiate the processing which (for demo purposes) is simply the need to update theDescription__cfield. This field is suffixed by the ID of the Platform Event that represents the processing execution so you can see which records get processed together. This is most interesting when you limit theExampleProcessorto only process a few records together. - The
TriggeredEvent__eplatform eventType__cfield selects the processor to be run by being the type name for theEventProcessorto be instantiated. - Additional implementations of the
EventProcessorcould easily be created if other types of processing was needed against theExample__cobject, or even other object(s), in different situations. - The Platform Event processing is single threaded, meaning there is no worry that the
Example__cprocessing might face race conditions (a problem withQueueableandBatchableimplementations where two or more instances of the same code can run concurrently and interfere with each other).
In terms of the general processing flow:
- The
Example__cobject's trigger detects the scenario where the processing is required and marks the record(s) that need to be processed. It ensures that at most one Platform Event is published for theExampleProcessorin a given transaction when record(s) get marked for processing. This published event will be processed in a subsequent transaction. - The
TriggeredEvent__eevent's trigger determines the type(s) of processing that are required and ensures that the first of these types gets executed. If that type cannot be fully executed in the trigger an appropriate event gets published to allow the trigger to be called again, for that type, in a subsequent transaction. - Field history tracking has been enabled against
Example__c'sAccount__c,Datetime__candDescription__cfields so you can see "who" is doing what changes.
Take a look at sf-async-callout which takes the approach of creating a separate "command" object instead of updating the originating record. This alternative also covers how to actually perform the callout itself (by getting into a context where callouts are permitted; they cannot yet be done directly from a Platform Event apex trigger subscriber).
After deployment, assign the Example permission set to your user then access the Examples tab to start playing. You might also like to bulk create Example records to allow use of bulk updates in the Examples "All" list view to see how the processing behaves. Note how the processing encapsulated in the ExampleProcessor is attributed to the Automated Process user, while your changes are attributed to your user.
The records updated by the processor are marked as Last Modified By the Automated Process user too. This can be a good thing - you can see they have been processed by automation. If this is a significant problem, it is actually possible to engineer a flow-based Platform Event subscriber to replace this apex version. In this case the changes actually get attributed to the contextual user that caused the Platform Event to be published.