IDM Model Interface Introduction

Last modified 15 Nov 2021 14:24 +01:00



IDM Model Interface Concepts

Working With Objects

This interface mostly work with midPoint objects as described in our Data Model. Please see the Basic Data Model page for a quick introduction to the data model. The Data Model page expands on that and provides more details. Almost all state and configuration changes in midPoint are done by creating, modifying and deleting midPoint objects.

Each midPoint objects has a type and an OID. These two pieces of information are all you need to read a midPoint object. This is what identifies an object. And both type and OID are immutable. Once set these cannot be changed. The type is represented as Java class in this interface. The OID is a string, usually in a form of UUID.

This interface provides a unified view of the objects. It means that the user of IDM Model Interface does not need to care about where the data resides. Some data reside in the midPoint repository (e.g. relational database). These are typically objects that represent users or configuration objects. Other objects reside partially in midPoint repository and partially on remote resources (e.g. Shadow Objects). However this distinction is mostly hidden from the user of IDM Model Interface. This interface provides uniform access to all objects regardless of how and where are they stored. You can simply read an object and the implementation will figure out how to do that. And the implementation will take care of merging the data from several sources, process meta-data, data caching, type conversion and any other mechanism that needs to take place to work with the data.

Prism Objects and Deltas

Almost all business data are represented in midPoint in a form of Prism Objects. Prism is somehow lightweight and very powerful data representation framework. It can be used to access the data using a variety of interfaces, parse and serialize using multiple data formats (e.g. XML and JSON) and so on. This is the basic framework of midPoint data therefore it is also used in all midPoint Java interfaces. Please have a look at Prism page to get a generic introduction to the framework.

MidPoint is designed to work with relative change model. This model is built deeply into the basic midPoint functionality. Therefore it is obvious that also midPoint interfaces will work with deltas. Similarly to the objects the Java interfaces to midPoint are using deltas provided by prism framework. Prism deltas are designed especially to work with prism objects and together they work a complete and elegant data representation and management solution.

As midPoint is heavily relying on prism framework an instance of prism context is sometimes needed to complete some tasks. One of the important responsibilities of prism context is to maintain pre-parsed schemas of all midPoint objects and also schemas of user extensions. MidPoint is internally a fully type-based system which provides very powerful features such as transparent type checking and conversion. Therefore an instance of prism context is needed to complete some operations (e.g. creating new object or delta). Similarly to other such instances also the prism context is managed by Spring framework. Therefore instance of prism context can be obtained by using Spring dependency injection, e.g. using the @Autowire annotation.

Please note that most objects are using PolyString instead of plain strings for some attributes. The use of PolyString provides important advantage in internationalized environment. E.g. it provides ability for database-independent searches that are quite close to an internationalized full-text search. While PolyString values are almost transparent when used for reading they require some attention when constructing objects and deltas.

Interface and Implementation

MidPoint follows established practice of separating the interface (abstract definition) and implementation (concrete algorithms). Therefore all major midPoint interfaces are provided in a form of Java interface constructs. There is no implementation code directly associated with such interface. However an "instance" of the interface needs to be retrieved for the code to be practical. MidPoint is using Spring framework to manage component dependencies and to inject implementations where they are needed (a.k.a. "wiring" the components).

All samples assume that the instance of ModelService is in the variable modelService. This instance can be obtained by using Spring, e.g. using autowiring

import com.evolveum.midpoint.model.api.ModelService;

private ModelService modelService;

Operational Status, Security Context and Error Handling

MidPoint is a sophisticated system that is supposed to be secure and auditable and easy to diagnose. Therefore each operation has to know a security context in which it runs to be able to properly process authorization and auditing. The Task data structure is designed for this responsibility. It contains the identity of the user and security context. But the task has much more capabilities. It can be also used for run control, e.g. midPoint has the ability to switch the execution to asynchronous if needed. The Task data structure mains information about the context and the state of operation execution. Therefore it needs to be provided as an argument in each invocation.

Error reporting and handling is a very important concern in integration systems such as midPoint. The interface provide two mechanisms to describe errors and error conditions:

  • Java Exceptions indicate severe errors that cause whole operation to fail. The capabilities of exceptions as error indication technique are very limited. E.g. they cannot provide track of the complete operation or cannot indicate partial success. Therefore the use of exceptions is limited only the most severe cases and an additional error indication mechanism is needed.

  • Operation Result is used as a rich data structure that describe useful information about the whole operation and its suboperations. It describes what parts of the operation failed and provides a rich diagnostics information to display to user. The operation result is used to indicate both fatal (complete) and partial failures. The analysis of the operation result may also provide debugging data about the operation itself (e.g. for debugging the policies and configuration).

The exceptions are "standardized" through the system. A common set of exceptions is defined in the Infrastructure Subsystem and these exceptions are reused by all midPoint interfaces if possible. Most of the exceptions are checked exceptions that define a specific circumstances (semantics) of the error. Therefore it is usually sufficient to react to (catch) a specific exception to handle the error. However the exception is only thrown if the whole operation fails or if an unexpected situation with unpredictable results occurs (e.g. out of memory error). More sophisticated error handling is possible by inspecting the Operation Result. E.g. if a user is modified, the modification is reflected to several accounts using mappings, some of account modification succeed and one of the account modification fails then an exception is not thrown. In such case the the operation returns as in it would after a successful operation. Operation result structure will be filled with details of every significant sub-operation. The overall status will indicate partial error and one of the sub-operations will be set to fatal error. As this structure is intended for human readability and machine processability it can be used for variety of purposes. It can be used to display detailed error information to the user, to automatically react to certain situation or for any similar purpose.

Reading Objects

Reading objects is the simplest and perhaps also the most often used operation. As midPoint objects are identified by OID it is also the most important parameter in the invocation:

PrismObject<UserType> user = modelService.getObject(UserType.class, "6bb5c524-5c18-11e3-979a-001e8c717e5b", null, task, result);

Once retrieved the object can be manipulated using any of the prism "facets":

String empNo = user.asObjectable().getEmployeeNumber(); // returns the value of user's employeeNumber property

This works for any object of any type as long as you know OID:

PrismObject<ResourceType> resource = modelService.getObject(ResourceType.class, "750e4d3a-5c18-11e3-8174-001e8c717e5b", null, task, result);
PrismObject<ShadowType> account = modelService.getObject(ShadowType.class, "399e161c-5c19-11e3-9cd0-001e8c717e5b", null, task, result);

Searching Objects

If you want to do anything interesting with a midPoint object you need to know its OID. Most methods need an OID to be able to work properly. Perhaps the only real exception are search methods. These methods are designed to obtain midPoint objects even without knowing their OID. In fact these methods are often used to find out OID of an object to be used in other midPoint operations.

The key to search methods is midPoint query language. This query language is specific to midPoint and it describes an abstract tree of search criteria. It may be slightly complex to construct but there are convenient factory methods that can be used for this purpose. The following example shows how a simple query is constructed and used in a search. Factory methods createObjectQuery and createEqual are used to construct a simple query. The query describes objects for which the name property (specified as ResourceType.F_NAME) equals to xref:/midpoint/reference/concepts/polystring/"My Resource`". Once executed this will return all such ResourceType objects (which obviously is at most one object as `name property is unique across all the resources).

ObjectQuery query = ObjectQuery.createObjectQuery(
        EqualsFilter.createEqual(ResourceType.class, prismContext, ResourceType.F_NAME, new PolyString("My Resource")));
Collection<PrismObject<ResourceType>> resources = modelService.searchObjects(ResourceType.class, query, null, task, result);

There are two versions of the search methods: plain and iterative. The plain method (searchObjects) stores all the results in a collection that it returns. This is easy-to-use version for a very small queries such as the one above (which cannot return more than one object). But the plain search method does not scale well. Therefore there is an iterative search method (searchObjectsIterative) is not storing the objects at all. This method is using a callback handler to process each object as it is fetched from the repository (or resource). Following example show how it is used:

ResultHandler<UserType> handler = new ResultHandler<UserType>() {
        public boolean handle(PrismObject<UserType> user, OperationResult parentResult) {
            // do something with user here
            return true; // true indicates that we want to continue
modelService.searchObjectsIterative(UserType.class, query, handler, null, task, result);

Creating, Modifying and Deleting Objects

Unlike other interfaces the MidPoint Java API uses a single method for all changes. The method is called executeChanges and it takes a collection of deltas as its argument. The trick is to correctly construct the deltas. Deltas are part of the Prism framework that is used in midPoint to represent data.

Creating Objects

To create an object in midPoint you need to do the following

  1. Create a prism object

  2. Create an ADD delta from the object

  3. Put the delta into a collection

  4. invoke executeChanges

The following example demonstrates this process. It creates a new user.

PrismObject<UserType> user = .... // parse or instantiate the user
ObjectDelta<UserType> userAddDelta = ObjectDelta.createAddDelta(user);
Collection<ObjectDelta<? extends ObjectType>> deltas = MiscSchemaUtil.createCollection(userAddDelta);
modelService.executeChanges(deltas, null, task, result);

If you need an OID of a newly created object then have a look at the delta after the operation. The OID will be set back to the original (input) delta.

Modifying Objects

Object modification is also using similar process, just the delta construction is different:

  1. Create a MODIFY delta using appropriate factory methods

  2. Put the delta into a collection

  3. invoke executeChanges

The following example demonstrates this process. It modifies existing user. The user’s employeeType property will be set to a new value Pirate.

String oid = "2cd99790-47be-11e3-a71a-3c970e467874";
ObjectDelta<UserType> userModifyDelta = ObjectDelta.createModificationAddProperty(UserType.class, oid, UserType.F_EMPLOYEE_TYPE, "Pirate");
Collection<ObjectDelta<? extends ObjectType>> deltas = MiscSchemaUtil.createCollection(userModifyDelta);
modelService.executeChanges(deltas, null, task, result);

The modification is much more powerful than just this simple example. A modify delta can contain several modifications of various modify types (see Deltas). There may also be more than one object delta in the collection, e.g. to modify user and its accounts in a single midPoint operation (but see limitations below).

Deleting Objects

Object deletion is quite simple and it is also using similar process:

  1. Create a DELETE delta using a factory method

  2. Put the delta into a collection

  3. invoke executeChanges

The following example demonstrates this process. Essentially all you need to create a delete delta is an OID. Following code deletes a user:

String oid = "2cd99790-47be-11e3-a71a-3c970e467874";
ObjectDelta<UserType> userDeleteDelta = ObjectDelta.createDeleteDelta(UserType.class, oid, prismContext);
Collection<ObjectDelta<? extends ObjectType>> deltas = MiscSchemaUtil.createCollection(userDeleteDelta);
modelService.executeChanges(deltas, null, task, result);

Limitations and Misc Notes

The executeChanges method can take several deltas at once. This is a powerful feature. The deltas may influence each other (e.g. through mappings) and processing them all together provides more reliable results and especially better error messages. However the deltas that are places in a single executeChanges invocation must be related. They need to correspond to a user and his accounts. Or to other focus-projection pairs. But there cannot be unrelated deltas. E.g. an attempt to provide two user deltas to a single executeChanges invocation will fail.

This Java API and especially the executeChanges method is very powerful. It is almost impossible to describe the full power of this method on a single page. If you are interested in more examples than midPoint integration tests are perhaps a good place to look. These tests are using a fully initialized midPoint instance in unit test framework (Test NG). The tests are accessing the instance using the same Java API as is described here. Therefore you can find a lot more examples of the API usage by looking at the tests. The test reside in model/model-intest component of the midPoint source code. Especially TestModelServiceContract is a nice comprehensive test that provides a good overview of basic API operations.

Misc Operations

TODO: findShadowOwner, countObjects, testResource

Advanced Features

TODO: options: partial reads, resolve, paging, …​

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