1 .. This work is licensed under a Creative Commons Attribution 4.0 International License.
2 .. http://creativecommons.org/licenses/by/4.0
16 .. container:: paragraph
18 APEX offers a lot of flexibility for defining, deploying, and executing policies. Based on a theoretic model, it
19 supports virtually any policy model and supports translation of legacy policies into the APEX execution format.
20 However, the most important aspect for using APEX is to decide what policy is needed, what underlying policy concepts
21 should be used, and how the decision logic should be realized. Once these aspects are decided, APEX can be used to
22 execute the policies. If the policy evolves, say from a simple decision table to a fully adaptable policy, only the
23 policy definition requires change. APEX supports all of that.
25 .. container:: paragraph
27 The figure below shows a (non-exhaustive) matrix, which will help to decide what policy is required to solve your
28 problem. Read the matrix from left to right choosing one cell in each column.
30 .. container:: imageblock
32 .. container:: content
38 Figure 1. APEX Policy Matrix
40 .. container:: paragraph
42 The policy can support one of a number of stimuli with an associated purpose/model of the policy, for instance:
46 - Configuration, i.e. what should happen. An example is an event that states an intended network configuration
47 and the policy should provide the detailed actions for it. The policy can be realized for instance as an
48 obligation policy, a promise or an intent.
50 - Report, i.e. something did happen. An example is an event about an error or fault and the policy needs to
51 repair that problem. The policy would usually be an obligation, utility function, or goal policy.
53 - Monitoring, i.e. something does happen. An example is a notification about certain network conditions, to
54 which the policy might (or might not) react. The policy will mitigate the monitored events or permit (deny)
55 related actions as an obligation or authorization.
57 - Analysis, i.e. why did something happen. An example is an analytic component sends insights of a situation
58 requiring a policy to act on it. The policy can solve the problem, escalate it, or delegate it as a refrain or
61 - Prediction, i.e. what will happen next. An example are events that a policy uses to predict a future network
62 condition. The policy can prevent or enforce the prediction as an adaptive policy, a utility function, or a goal.
64 - Feedback, i.e. why did something happen or not happen. Similar to analysis, but here the feedback will be in
65 the input event and the policy needs to something with that information. Feedback can be related to history or
66 experience, for instance a previous policy execution. The policy needs to be context-aware or be a meta-policy.
68 .. container:: paragraph
70 Once the purpose of the policy is decided, the next step is to look into what context information the policy will
71 require to do its job. This can range from very simple to a lot of different information, for instance:
75 - No context, nothing but a trigger event, e.g. a string or a number, is required
77 - Event context, the incoming event provides all information (more than a string or number) for the policy
79 - Policy context (read only), the policy has access to additional information related to its class but cannot
82 - Policy context (read and write), the policy has access to additional information related to its class and can
83 alter this information (for instance to record historic information)
85 - Global context (read only), the policy has access to additional information of any kind but cannot
88 - Global context (read and write), the policy the policy has access to additional information of any kind and
89 can alter this information (for instance to record historic information)
91 .. container:: paragraph
93 The next step is to decide how the policy should do its job, i.e. what flavor it has, how many states are needed,
94 and how many tasks. There are many possible combinations, for instance:
98 - Simple / God: a simple policy with 1 state and 1 task, which is doing everything for the decision-making. This
99 is the ideal policy for simple situation, e.g. deciding on configuration parameters or simple access control.
101 - Simple sequence: a simple policy with a number of states each having a single task. This is a very good policy
102 for simple decision-making with different steps. For instance, a classic action policy (ECA) would have 3 states
103 (E, C, and A) with some logic (1 task) in each state.
105 - Simple selective: a policy with 1 state but more than one task. Here, the appropriate task (and it’s logic)
106 will be selected at execution time. This policy is very good for dealing with similar (or the same) situation in
107 different contexts. For instance, the tasks can be related to available external software, or to current work load
108 on the compute node, or to time of day.
110 - Selective: any number of states having any number of tasks (usually more than 1 task). This is a combination
111 of the two policies above, for instance an ECA policy with more than one task in E, C, and A.
113 - Classic directed: a policy with more than one state, each having one task, but a non-sequential execution.
114 This means that the sequence of the states is not pre-defined in the policy (as would be for all cases above) but
115 calculated at runtime. This can be good to realize decision trees based on contextual information.
117 - Super Adaptive: using the full potential of the APEX policy model, states and tasks and state execution are
118 fully flexible and calculated at runtime (per policy execution). This policy is very close to a general
119 programming system (with only a few limitations), but can solve very hard problems.
121 .. container:: paragraph
123 The final step is to select a response that the policy creates. Possible responses have been discussed in the
124 literature for a very long time. A few examples are:
128 - Obligation (deontic for what should happen)
130 - Authorization (e.g. for rule-based or other access control or security systems)
132 - Intent (instead of providing detailed actions the response is an intent statement and a further system
135 - Delegation (hand the problem over to someone else, possibly with some information or instructions)
137 - Fail / Error (the policy has encountered a problem, and reports it)
139 - Feedback (why did the policy make a certain decision)
145 .. container:: paragraph
147 The APEX policy model is shown in UML notation in the figure below. A policy model can be stored in JSON or XML
148 format in a file or can be held in a database. The APEX editor creates and modifies APEX policy models. APEX
149 deployment deploys policy models, and a policy model is loaded into APEX engines so that the engines can run the
150 policies in the policy model.
152 .. container:: paragraph
154 The figure shows four different views of the policy model:
158 - The general model view shows the main parts of a policy: state, state output, event, and task. A task can also
159 have parameters. Data types can be defined on a per-model basis using either standard atomic types (such as
160 character, string, numbers) or complex types from a policy domain.
162 - The logic model view emphasizes how decision-making logic is injected into a policy. There are essentially
163 three different types of logic: task logic (for decision making in a task), task selection logic (to select a task
164 if more than one is defined in a state), and state finalizer logic (to compute the final output event of a state
165 and select an appropriate next state from the policy model).
167 - The context model view shows how context is injected into a policy. States collect all context from their
168 tasks. A task can define what context it requires for the decision making, i.e. what context the task logic will
169 process. Context itself is a collection of items (individual context information) with data types. Context can be
172 - The event and field model view shows the events in the policy model. Tasks define what information they
173 consume (input) and produce (output). This information is modeled as fields, essentially a key/type tuple in the
174 model and a key/type/value triple at execution. Events then are collection of fields.
176 .. container:: imageblock
178 .. container:: content
180 |APEX Policy Model for Execution|
184 Figure 2. APEX Policy Model for Execution
189 .. container:: paragraph
191 Each element of the policy model is called a *concept*. Each *concept* is a subclass of the abstract *Concept*
192 class, as shown in the next figure. Every concept implements the following abstract methods:
194 .. container:: imageblock
196 .. container:: content
202 Figure 3. Concepts and Keys
206 - ``getKey()`` - gets the unique key for this concept instance in the system
208 - ``validate()`` - validates the structure of this concept, its sub-concepts and its relationships
210 - ``clean()`` - carries out housekeeping on the concept such as trimming strings, remove any hanging references
212 - ``clone()`` - creates a deep copy of an instance of this concept
214 - ``equals()`` - checks if two instances of this concept are equal
216 - ``toString()`` - returns a string representation of the concept
218 - ``hashCode()`` - returns a hash code for the concept
220 - ``copyTo()`` - carries out a deep copy of one instance of the concept to another instance, overwriting the
223 .. container:: paragraph
225 All concepts must have a *key*, which uniquely identifies a concept instance. The *key* of a subclass of an *Concept*
226 must either be an ``ArtifactKey`` or an ``ReferenceKey``. Concepts that have a stand-alone independent existence such
227 as *Policy*, *Task*, and *Event* must have an ``ArtifctKey`` key. Concepts that are contained in other concepts, that
228 do not exist as stand-alone concepts must have an ``ReferenceKey`` key. Examples of such concepts are *State* and
231 .. container:: paragraph
233 An ``ArticactKey`` has two fields; the *Name* of the concept it is the key for and the concept’s *Version*. A
234 concept’s name must be unique in a given PolicyModel. A concept version is represented using the well known
235 *major.minor.path* scheme as used in semantic versioning.
237 .. container:: paragraph
239 A ``ReferenceKey`` has three fields. The *UserKeyName* and *UserKeyVersion* fields identify the ``ArtifactKey`` of
240 the concept in which the concept keyed by the ``ReferenceKey`` is contained. The *LocalName* field identifies the
241 contained concept instance. The *LocalName* must be unique in the concepts of a given type contained by a parent.
243 .. container:: paragraph
245 For example, a policy called ``SalesPolicy`` with a Version of ``1.12.4`` has a state called ``Decide``. The
246 ``Decide`` state is linked to the ``SalesPolicy`` with a ``ReferenceKey`` with fields *UserKeyName* of
247 ``SalesPolicy``, *UserKeyVersion* of ``1.12.4``, and *LocalName* of ``Decide``. There must not be another state
248 called ``Decide`` in the policy ``SalesPolicy``. However, there may well be a state called ``Decide`` in some other
249 policy called ``PurchasingPolicy``.
251 .. container:: paragraph
253 Each concept in the model is also a JPA
254 (`Java Persistence API <https://en.wikipedia.org/wiki/Java_Persistence_API>`__) Entity. This means that every concept
255 can be individually persisted or the entire model can be persisted en-bloc to any persistence mechanism using an JPA
256 framework such as `Hibernate <http://hibernate.org/>`__ or `EclipseLink <http://www.eclipse.org/eclipselink/>`__.
261 .. container:: paragraph
263 The *PolicyModel* concept is a container that holds the definition of a set of policies and their associated events,
264 context maps, and tasks. A *PolicyModel* is implemented as four maps for policies, events, context maps, and tasks.
265 Each map is indexed by the key of the policy, event, context map, or task. Any non-empty policy model must have at
266 least one entry in its policy, event, and task map because all policies must have at least one input and output event
267 and must execute at least one task.
269 .. container:: paragraph
271 A *PolicyModel* concept is keyed with an ``ArtifactKey key``. Because a *PolicyModel* is an ``AxConcept``, calling
272 the ``validate()`` method on a policy model validates the concepts, structure, and relationships of the entire policy
278 .. container:: paragraph
280 Data types are tightly controlled in APEX in order to provide a very high degree of consistency in policies and to
281 facilitate tracking of changes to context as policies execute. All context is modeled as a *DataType* concept. Each
282 DataType concept instance is keyed with an ``ArtifactKey`` key. The DataType field identifies the Java class of
283 objects that is used to represent concept instances that use this data type. All context has a *DataType*; incoming
284 and outgoing context is represented by *EventField* concepts and all other context is represented by *ContextItem*
290 .. container:: paragraph
292 An *Event* defines the structure of a message that passes into or out of an APEX engine or that passes between two
293 states in an APEX engine. APEX supports message reception and sending in many formats and all messages are translated
294 into an *Event* prior to processing by an APEX engine. Event concepts are keyed with an ``ArtifactKey`` key. The
295 parameters of an event are held as a map of *EventField* concept instances with each parameter indexed by the
296 *LocalName* of its ``ReferenceKey``. An *Event* has three fields:
300 - The *NameSpace* identifies the domain of application of the event
302 - The *Source* of the event identifies the system that emitted the event
304 - The *Target* of the event identifies the system that the event was sent to
306 .. container:: paragraph
308 A *PolicyModel* contains a map of all the events known to a given policy model. Although an empty model may have no
309 events in its event map, any sane policy model must have at least one *Event* defined.
314 .. container:: paragraph
316 The incoming context and outgoing context of an event are the fields of the event. Each field representing a single
317 piece of incoming or outgoing context. Each field of an *Event* is represented by an instance of the *EventField*
318 concept. Each *EventField* concept instance in an event is keyed with a ``ReferenceKey`` key, which references the
319 event. The *LocalName* field of the ``ReferenceKey`` holds the name of the field A reference to a *DataType* concept
320 defines the data type that values of this parameter have at run time.
325 .. container:: paragraph
327 The set of context that is available for use by the policies of a *PolicyModel* is defined as *ContextMap* concept
328 instances. The *PolicyModel* holds a map of all the *ContextMap* definitions. A *ContextMap* is itself a container
329 for a group of related context items, each of which is represented by a *ContextItem* concept instance. *ContextMap*
330 concepts are keyed with an ``ArtifactKey`` key. A developer can use the APEX Policy Editor to create context maps for
331 their application domain.
333 .. container:: paragraph
335 A *ContextMap* uses a map to hold the context items. The ContextItem concept instances in the map are indexed by the
336 *LocalName* of their ``ReferenceKey``.
338 .. container:: paragraph
340 The *ContextMapType* field of a *ContextMap* defines the type of a context map. The type can have either of two
345 - A *BAG* context map is a context map with fixed content. Each possible context item in the context map is
346 defined at design time and is held in the *ContextMap* context instance as *ContextItem* concept definitions and
347 only the values of the context items in the context map can be changed at run time. The context items in a *BAG*
348 context map have mixed types and distinct *ContextItem* concept instances of the same type can be defined. A *BAG*
349 context map is convenient for defining a group of context items that are diverse but are related by domain, such as
350 the characteristics of a device. A fully defined *BAG* context map has a fully populated *ContextItem* map but its
351 *ContextItemTemplate* reference is not defined.
353 - A *SAMETYPE* context map is used to represent a group of *ContextItem* instances of the same type. Unlike a
354 *BAG* context map, the *ContextItem* concept instances of a *SAMETYPE* context map can be added, modified, and
355 deleted at runtime. All *ContextItem* concept instances in a *SAMETYPE* context map must be of the same type, and
356 that context item is defined as a single *ContextItemTemplate* concept instances at design time. At run time, the
357 *ContextItemTemplate* definition is used to create new *ContextItem* concept instances for the context map on
358 demand. A fully defined *SAMETYPE context map has an empty ContextItem map and its ContextItemTemplate\_*
359 reference is defined.
361 .. container:: paragraph
363 The *Scope* of a *ContextMap* defines the range of applicability of a context map in APEX. The following scopes of
364 applicability are defined:
368 - *EPHEMERAL* scope means that the context map is owned, used, and modified by a single application but the
369 context map only exists while that application is running
371 - *APPLICATION* scope specifies that the context map is owned, used, and modified by a single application, the
372 context map is persistent
374 - *GLOBAL* scope specifies that the context map is globally owned and is used and modified by any application,
375 the context map is persistent
377 - *EXTERNAL* scope specifies that the context map is owned by an external system and may be used in a read-only
378 manner by any application, the context map is persistent
380 .. container:: paragraph
382 A much more sophisticated scoping mechanism for context maps is envisaged for Apex in future work. In such a
383 mechanism, the scope of a context map would work somewhat like the way roles work in security authentication systems.
388 .. container:: paragraph
390 Each piece of context in a *ContextMap* is represented by an instance of the *ContextItem* concept. Each
391 *ContextItem* concept instance in a context map keyed with a ``ReferenceKey`` key, which references the context map
392 of the context item. The *LocalName* field of the ``ReferenceKey`` holds the name of the context item in the context
393 map A reference to a *DataType* concept defines the data type that values of this context item have at run time. The
394 *WritableFlag* indicates if the context item is read only or read-write at run time.
396 Concept: ContextItemTemplate
397 ============================
399 .. container:: paragraph
401 In a *SAMETYPE* *ContextMap*, the *ContextItemTemplate* definition provides a template for the *ContextItem*
402 instances that will be created on the context map at run time. Each *ContextItem* concept instance in the context map
403 is created using the *ContextItemTemplate* template. It is keyed with a ``ReferenceKey`` key, which references the
404 context map of the context item. The *LocalName* field of the ``ReferenceKey``, supplied by the creator of the
405 context item at run time, holds the name of the context item in the context map. A reference to a *DataType* concept
406 defines the data type that values of this context item have at run time. The *WritableFlag* indicates if the context
407 item is read only or read-write at run time.
412 .. container:: paragraph
414 The smallest unit of logic in a policy is a *Task*. A task encapsulates a single atomic unit of logic, and is
415 designed to be a single indivisible unit of execution. A task may be invoked by a single policy or by many policies.
416 A task has a single trigger event, which is sent to the task when it is invoked. Tasks emit one or more outgoing
417 events, which carry the result of the task execution. Tasks may use or modify context as they execute.
419 .. container:: paragraph
421 The Task concept definition captures the definition of an APEX task. Task concepts are keyed with an ``ArtifactKey``
422 key. The Trigger of the task is a reference to the *Event* concept that triggers the task. The *OutgoingEvents* of a
423 task are a set of references to *Event* concepts that may be emitted by the task.
425 .. container:: paragraph
427 All tasks have logic, some code that is programmed to execute the work of the task. The *Logic* concept of the task
428 holds the definition of that logic.
430 .. container:: paragraph
432 The *Task* definition holds a set of *ContextItem* and *ContextItemTemplate* context items that the task is allow to
433 access, as defined by the task developer at design time. The type of access (read-only or read write) that a task has
434 is determined by the *WritableFlag* flag on the individual context item definitions. At run time, a task may only
435 access the context items specified in its context item set, the APEX engine makes only the context items in the task
436 context item set is available to the task.
438 .. container:: paragraph
440 A task can be configured with startup parameters. The set of parameters that can be configured on a task are defined
441 as a set of *TaskParameter* concept definitions.
443 Concept: TaskParameter
444 ======================
446 .. container:: paragraph
448 Each configuration parameter of a task are represented as a *Taskparameter* concept keyed with a ``ReferenceKey``
449 key, which references the task. The *LocalName* field of the ``ReferenceKey`` holds the name of the parameter. The
450 *DefaultValue* field defines the default value that the task parameter is set to. The value of *TaskParameter*
451 instances can be overridden at deployment time by specifying their values in the configuration information passed to
454 .. container:: paragraph
456 The *taskParameters* field is specified under *engineParameters* in the ApexConfig. It can contain one or more task
457 parameters, where each item can contain the parameter key, value as well as the taskId to which it is associated. If
458 the taskId is not specified, then the parameters are added to all tasks.
463 .. container:: paragraph
465 The *Logic* concept instance holds the actual programmed task logic for a task defined in a *Task* concept or the
466 programmed task selection logic for a state defined in a *State* concept. It is keyed with a ``ReferenceKey`` key,
467 which references the task or state that owns the logic. The *LocalName* field of the Logic concept is the name of the
470 .. container:: paragraph
472 The *LogicCode* field of a Logic concept definition is a string that holds the program code that is to be executed
473 at run time. The *LogicType* field defines the language of the code. The standard values are the logic languages
474 supported by APEX: `JAVASCRIPT <https://en.wikipedia.org/wiki/JavaScript>`__, `JAVA <https://java.com/en/>`__,
475 `JYTHON <http://www.jython.org/>`__, `JRUBY <http://jruby.org/>`__, or
476 `MVEL <https://en.wikibooks.org/wiki/Transwiki:MVEL_Language_Guide>`__.
478 .. container:: paragraph
480 The APEX engine uses the *LogicType* field value to decide which language interpreter to use for a task and then
481 sends the logic defined in the *LogicCode* field to that interpreter.
486 .. container:: paragraph
488 The *Policy* concept defines a policy in APEX. The definition is rather straightforward. A policy is made up of a
489 set of states with the flavor of the policy determining the structure of the policy states and the first state
490 defining what state in the policy executes first. *Policy* concepts are keyed with an ``ArtifactKey`` key.
492 .. container:: paragraph
494 The *PolicyFlavour* of a *Policy* concept specifies the structure that will be used for the states in the policy. A
495 number of commonly used policy patterns are supported as APEX policy flavors. The standard policy flavors are:
499 - The *MEDA* flavor supports policies written to the
500 `MEDA policy pattern <https://www.researchgate.net/publication/282576518_Dynamically_Adaptive_Policies_for_Dynamically_Adaptive_Telecommunications_Networks>`__
501 and require a sequence of four states: namely *Match*, *Establish*, *Decide* and *Act*.
503 - The *OODA* flavor supports policies written to the
504 `OODA loop pattern <https://en.wikipedia.org/wiki/OODA_loop>`__ and require a sequence of four states: namely
505 *Observe*, *Orient*, *Decide* and *Act*.
507 - The *ECA* flavor supports policies written to the
508 `ECA active rule pattern <https://en.wikipedia.org/wiki/Event_condition_action>`__ and require a sequence of three
509 states: namely *Event*, *Condition* and *Action*
511 - The *XACML* flavor supports policies written in `XACML <https://en.wikipedia.org/wiki/XACML>`__ and require a
512 single state: namely *XACML*
514 - The *FREEFORM* flavor supports policies written in an arbitrary style. A user can define a *FREEFORM* policy
515 as an arbitrarily long chain of states.
517 .. container:: paragraph
519 The *FirstState* field of a *Policy* definition is the starting point for execution of a policy. Therefore, the
520 trigger event of the state referenced in the *FirstState* field is also the trigger event for the entire policy.
525 .. container:: paragraph
527 The *State* concept represents a phase or a stage in a policy, with a policy being composed of a series of states.
528 Each state has at least one but may have many tasks and, on each run of execution, a state executes one and only one
529 of its tasks. If a state has more than one task, then its task selection logic is used to select which task to
530 execute. Task selection logic is programmable logic provided by the state designer. That logic can use incoming,
531 policy, global, and external context to select which task best accomplishes the purpose of the state in a give
532 situation if more than one task has been specified on a state. A state calls one and only one task when it is
535 .. container:: paragraph
537 Each state is triggered by an event, which means that all tasks of a state must also be triggered by that same
538 event. The set of output events for a state is the union of all output events from all tasks for that task. In
539 practice at the moment, because a state can only have a single input event, a state that is not the final state of a
540 policy may only output a single event and all tasks of that state may also only output that single event. In future
541 work, the concept of having a less restrictive trigger pattern will be examined.
543 .. container:: paragraph
545 A state that is the final state of a policy may output multiple events, and the task associated with the final state
546 outputs those events.
548 .. container:: paragraph
550 A *State* concept is keyed with a ``ReferenceKey`` key, which references the *Policy* concept that owns the state.
551 The *LocalName* field of the ``ReferenceKey`` holds the name of the state. As a state is part of a chain of states,
552 the *NextState* field of a state holds the ``ReferenceKey`` key of the state in the policy to execute after this
555 .. container:: paragraph
557 The *Trigger* field of a state holds the ``ArtifactKey`` of the event that triggers this state. The *OutgoingEvents*
558 field holds the ``ArtifactKey`` references of all possible events that may be output from the state. This is a set
559 that is the union of all output events of all tasks of the state.
561 .. container:: paragraph
563 The *Task* concepts that hold the definitions of the task for the state are held as a set of ``ArtifactKey``
564 references in the state. The *DefaultTask* field holds a reference to the default task for the state, a task that is
565 executed if no task selection logic is specified. If the state has only one task, that task is the default task.
567 .. container:: paragraph
569 The *Logic* concept referenced by a state holds the task selection logic for a state. The task selection logic uses
570 the incoming context (parameters of the incoming event) and other context to determine the best task to use to
571 execute its goals. The state holds a set of references to *ContextItem* and *ContextItemTemplate* definitions for the
572 context used by its task selection logic.
578 Writing APEX Task Logic
579 =======================
581 .. container:: paragraph
583 Task logic specifies the behavior of an Apex Task. This logic can be specified in a number of ways, exploiting
584 Apex’s plug-in architecture to support a range of logic executors. In Apex scripted Task Logic can be written in any
589 - ```MVEL`` <https://en.wikipedia.org/wiki/MVEL>`__,
591 - ```JavaScript`` <https://en.wikipedia.org/wiki/JavaScript>`__,
593 - ```JRuby`` <https://en.wikipedia.org/wiki/JRuby>`__ or
595 - ```Jython`` <https://en.wikipedia.org/wiki/Jython>`__.
597 .. container:: paragraph
599 These languages were chosen because the scripts can be compiled into Java bytecode at runtime and then efficiently
600 executed natively in the JVM. Task Logic an also be written directly in Java but needs to be compiled, with the
601 resulting classes added to the classpath. There are also a number of other Task Logic types (e.g. Fuzzy Logic), but
602 these are not supported as yet. This guide will focus on the scripted Task Logic approaches, with MVEL and JavaScript
603 being our favorite languages. In particular this guide will focus on the Apex aspects of the scripts. However, this
604 guide does not attempt to teach you about the scripting languages themselves …​ that is up to you!
607 JVM-based scripting languages For more more information on scripting for the Java platform see:
608 https://docs.oracle.com/javase/8/docs/technotes/guides/scripting/prog_guide/index.html
611 What do Tasks do? The function of an Apex Task is to provide the logic that can be executed for an Apex State as one
612 of the steps in an Apex Policy. Each task receives some *incoming fields*, executes some logic (e.g: make a decision
613 based on *shared state* or *context*, *incoming fields*, *external context*, etc.), perhaps set some *shared state*
614 or *context* and then emits *outgoing fields* (in case of a single outgoing event), or a set of *outgoing fields*
615 (in case of multiple outgoing events). The state that uses the task is responsible for extracting the
616 *incoming fields* from the state input event. The state also has an *output mapper* associated with the task, and
617 this *output mapper* is responsible for mapping the *outgoing fields* from the task into an appropriate output event
620 .. container:: paragraph
622 First lets start with a sample task, drawn from the "My First Apex Policy" example: The task "MorningBoozeCheck"
623 from the "My First Apex Policy" example is available in both MVEL and JavaScript:
625 .. container:: listingblock
629 Javascript code for the ``MorningBoozeCheck`` task
631 .. container:: content
637 * ============LICENSE_START=======================================================
638 * Copyright (C) 2016-2018 Ericsson. All rights reserved.
639 * Modifications Copyright (C) 2020 Nordix Foundation.
640 * ================================================================================
641 * Licensed under the Apache License, Version 2.0 (the "License");
642 * you may not use this file except in compliance with the License.
643 * You may obtain a copy of the License at
645 * http://www.apache.org/licenses/LICENSE-2.0
647 * Unless required by applicable law or agreed to in writing, software
648 * distributed under the License is distributed on an "AS IS" BASIS,
649 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
650 * See the License for the specific language governing permissions and
651 * limitations under the License.
653 * SPDX-License-Identifier: Apache-2.0
654 * ============LICENSE_END=========================================================
657 executor.logger.info("Task Execution: '"+executor.subject.id+"'. Input Fields: '"+executor.inFields+"'");
659 executor.outFields.put("amount" , executor.inFields.get("amount"));
660 executor.outFields.put("assistant_ID", executor.inFields.get("assistant_ID"));
661 executor.outFields.put("notes" , executor.inFields.get("notes"));
662 executor.outFields.put("quantity" , executor.inFields.get("quantity"));
663 executor.outFields.put("branch_ID" , executor.inFields.get("branch_ID"));
664 executor.outFields.put("item_ID" , executor.inFields.get("item_ID"));
665 executor.outFields.put("time" , executor.inFields.get("time"));
666 executor.outFields.put("sale_ID" , executor.inFields.get("sale_ID"));
668 item_id = executor.inFields.get("item_ID");
670 //All times in this script are in GMT/UTC since the policy and events assume time is in GMT.
671 var timenow_gmt = new Date(Number(executor.inFields.get("time")));
673 var midnight_gmt = new Date(Number(executor.inFields.get("time")));
674 midnight_gmt.setUTCHours(0,0,0,0);
676 var eleven30_gmt = new Date(Number(executor.inFields.get("time")));
677 eleven30_gmt.setUTCHours(11,30,0,0);
679 var timeformatter = new java.text.SimpleDateFormat("HH:mm:ss z");
681 var itemisalcohol = false;
682 if(item_id != null && item_id >=1000 && item_id < 2000)
683 itemisalcohol = true;
686 && timenow_gmt.getTime() >= midnight_gmt.getTime()
687 && timenow_gmt.getTime() < eleven30_gmt.getTime()) {
689 executor.outFields.put("authorised", false);
690 executor.outFields.put("message", "Sale not authorised by policy task " +
691 executor.subject.taskName+ " for time " + timeformatter.format(timenow_gmt.getTime()) +
692 ". Alcohol can not be sold between " + timeformatter.format(midnight_gmt.getTime()) +
693 " and " + timeformatter.format(eleven30_gmt.getTime()));
696 executor.outFields.put("authorised", true);
697 executor.outFields.put("message", "Sale authorised by policy task " +
698 executor.subject.taskName + " for time "+timeformatter.format(timenow_gmt.getTime()));
702 This task checks if a sale request is for an item that is an alcoholic drink.
703 If the local time is between 00:00:00 GMT and 11:30:00 GMT then the sale is not
704 authorised. Otherwise the sale is authorised.
705 In this implementation we assume that items with item_ID value between 1000 and
706 2000 are all alcoholic drinks :-)
711 .. container:: listingblock
715 MVEL code for the ``MorningBoozeCheck`` task
717 .. container:: content
723 * ============LICENSE_START=======================================================
724 * Copyright (C) 2016-2018 Ericsson. All rights reserved.
725 * Modifications Copyright (C) 2020 Nordix Foundation.
726 * ================================================================================
727 * Licensed under the Apache License, Version 2.0 (the "License");
728 * you may not use this file except in compliance with the License.
729 * You may obtain a copy of the License at
731 * http://www.apache.org/licenses/LICENSE-2.0
733 * Unless required by applicable law or agreed to in writing, software
734 * distributed under the License is distributed on an "AS IS" BASIS,
735 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
736 * See the License for the specific language governing permissions and
737 * limitations under the License.
739 * SPDX-License-Identifier: Apache-2.0
740 * ============LICENSE_END=========================================================
742 import java.util.Date;
743 import java.util.Calendar;
744 import java.util.TimeZone;
745 import java.text.SimpleDateFormat;
747 logger.info("Task Execution: '"+subject.id+"'. Input Fields: '"+inFields+"'");
749 outFields.put("amount" , inFields.get("amount"));
750 outFields.put("assistant_ID", inFields.get("assistant_ID"));
751 outFields.put("notes" , inFields.get("notes"));
752 outFields.put("quantity" , inFields.get("quantity"));
753 outFields.put("branch_ID" , inFields.get("branch_ID"));
754 outFields.put("item_ID" , inFields.get("item_ID"));
755 outFields.put("time" , inFields.get("time"));
756 outFields.put("sale_ID" , inFields.get("sale_ID"));
758 item_id = inFields.get("item_ID");
760 //The events used later to test this task use GMT timezone!
761 gmt = TimeZone.getTimeZone("GMT");
762 timenow = Calendar.getInstance(gmt);
763 df = new SimpleDateFormat("HH:mm:ss z");
765 timenow.setTimeInMillis(inFields.get("time"));
767 midnight = timenow.clone();
769 timenow.get(Calendar.YEAR),timenow.get(Calendar.MONTH),
770 timenow.get(Calendar.DATE),0,0,0);
771 eleven30 = timenow.clone();
773 timenow.get(Calendar.YEAR),timenow.get(Calendar.MONTH),
774 timenow.get(Calendar.DATE),11,30,0);
776 itemisalcohol = false;
777 if(item_id != null && item_id >=1000 && item_id < 2000)
778 itemisalcohol = true;
781 && timenow.after(midnight) && timenow.before(eleven30)){
782 outFields.put("authorised", false);
783 outFields.put("message", "Sale not authorised by policy task "+subject.taskName+
784 " for time "+df.format(timenow.getTime())+
785 ". Alcohol can not be sold between "+df.format(midnight.getTime())+
786 " and "+df.format(eleven30.getTime()));
790 outFields.put("authorised", true);
791 outFields.put("message", "Sale authorised by policy task "+subject.taskName+
792 " for time "+df.format(timenow.getTime()));
797 This task checks if a sale request is for an item that is an alcoholic drink.
798 If the local time is between 00:00:00 GMT and 11:30:00 GMT then the sale is not
799 authorised. Otherwise the sale is authorised.
800 In this implementation we assume that items with item_ID value between 1000 and
801 2000 are all alcoholic drinks :-)
804 .. container:: paragraph
806 The role of the task in this simple example is to copy the values in the incoming fields into the outgoing
807 fields, then examine the values in some incoming fields (``item_id`` and ``time``), then set the values in some
808 other outgoing fields (``authorised`` and ``message``).
810 .. container:: paragraph
812 Both MVEL and JavaScript like most JVM-based scripting languages can use standard Java libraries to perform
813 complex tasks. Towards the top of the scripts you will see how to import Java classes and packages to be used
814 directly in the logic. Another thing to notice is that Task Logic should return a ``java.lang.Boolean`` value
815 ``true`` if the logic executed correctly. If the logic fails for some reason then ``false`` can be returned, but
816 this will cause the policy invoking this task will fail and exit.
819 How to return a value from task logic
820 Some languages explicitly support returning values from the script (e.g. MVEL and JRuby) using an explicit
821 return statement (e.g. ``return true``), other languages do not (e.g. Jython). For
822 languages that do not support the ``return`` statement, a special field called ``returnValue`` must be
823 created to hold the result of the task logic operation (i.e. assign a ``java.lang.Boolean``
824 value to the ``returnValue`` field before completing the task).
825 Also, in MVEL if there is no explicit return statement then the return value of the last executed statement will
826 return (e.g. the statement a=(1+2) will return the value 3).
828 For Javascript, the last statement of a script must be a statement that evaluates to *true* or *false*, indicating
829 whether the script executed correctly or not. In the case where the script always executes to compeletion
830 sucessfully, simply add a last line with the statement *true'*. In cases where success or failure is assessed in the
831 script, create a boolean
832 local variable with a name such as ``returnvalue``. In the execution of the script, set ``returnValue`` to be ``true``
833 or ``false`` as appropriate. The last line of the scritp tehn should simply be ``returnValue;``, which returns the
834 value of ``returnValue``.
836 .. container:: paragraph
838 Besides these imported classes and normal language features Apex provides some natively available parameters
839 and functions that can be used directly. At run-time these parameters are populated by the Apex execution
840 environment and made natively available to logic scripts each time the logic script is invoked. (These can be
841 accessed using the ``executor`` keyword for most languages, or can be accessed directly without the
842 ``executor`` keyword in MVEL):
844 Table 1. The ``executor`` Fields / Methods
846 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
847 | Name | Type | Java type | Description |
848 +=====================================================+==========================================================================+===============================+==================================================================================+
849 | inFields | Fields | java.util.Map <String,Object> |The incoming task fields, implemented as a standard Java (unmodifiable) Map |
851 | | | |**Example:** |
853 | | | |.. code:: javascript |
855 | | | | executor.logger.debug("Incoming fields: " +executor.inFields.entrySet()); |
856 | | | | var item_id = executor.incomingFields["item_ID"]; |
857 | | | | if (item_id >=1000) { ... } |
858 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
859 | outFields | Fields | java.util.Map <String,Object> |The outgoing task fields. This is implemented as a standard initially empty Java |
860 | | | |(modifiable) Map. To create a new schema-compliant instance of a field object |
861 | | | |see the utility method subject.getOutFieldSchemaHelper() below that takes the |
862 | | | |fieldName as an argument. |
864 | | | |**Example:** |
866 | | | |.. code:: javascript |
868 | | | | executor.outFields["authorised"] = false; |
869 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
870 | outFieldsList | Fields | java.util.Collection |The collection of outgoing task fields when there are multiple outputs from the |
871 | | | <Map<String, Object>> |final state. To create a new schema-compliant instance of a field, see the |
872 | | | |utility method subject.getOutFieldSchemaHelper() below that takes eventName and |
873 | | | |fieldName as arguments. |
874 | | | |To add the set of output fields to the outFieldsList, the utility method |
875 | | | |executor.addFieldsToOutput can be used as shown below. |
876 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
877 | void addFieldsToOutput(Map<String, Object> fields) |A utility method to add fields to outgoing fields. | | |
878 | |When there are multiple output events emitted from the task associated | | |
879 | |with a final state, this utility method can be used to add the | | |
880 | |corresponding fields to the outFieldsList. | | |
882 | |**Example:** | | |
884 | |.. code:: javascript | | |
886 | | var cdsRequestEventFields = java.util.HashMap(); | | |
887 | | var actionIdentifiers = executor.subject.getOutFieldSchemaHelper | | |
888 | | ("CDSRequestEvent","actionIdentifiers").createNewInstance(); | | |
889 | | cdsRequestEventFields.put("actionIdentifiers", actionIdentifiers); | | |
890 | | executor.addFieldsToOutput(cdsRequestEventFields); | | |
892 | | var logEventFields = java.util.HashMap(); | | |
893 | | logEventFields.put("status", "FINAL_SUCCESS"); | | |
894 | | executor.addFieldsToOutput(logEventFields); | | |
895 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
896 | logger | Logger | org.slf4j.ext.XLogger |A helpful logger |
898 | | | |**Example:** |
900 | | | |.. code:: javascript |
902 | | | | executor.logger.info("Executing task: " +executor.subject.id); |
903 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
904 | TRUE/FALSE | boolean | java.lang.Boolean |2 helpful constants. These are useful to retrieve correct return values for the |
907 | | | |**Example:** |
909 | | | |.. code:: javascript |
911 | | | | var returnValue = executor.isTrue; |
912 | | | | var returnValueType = Java.type("java.lang.Boolean"); |
913 | | | | var returnValue = new returnValueType(true); |
914 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
915 | subject | Task | TaskFacade |This provides some useful information about the task that contains this task |
916 | | | |logic. This object has some useful fields and methods : |
918 | | | |.. container:: ulist |
920 | | | | - **AxTask task** to get access to the full task definition of the host task |
922 | | | | - **String getTaskName()** to get the name of the host task |
924 | | | | - **String getId()** to get the ID of the host task |
926 | | | | - **SchemaHelper getInFieldSchemaHelper( String fieldName )** to |
927 | | | | get a ``SchemaHelper`` helper object to manipulate incoming |
928 | | | | task fields in a schema-aware manner |
930 | | | | - **SchemaHelper getOutFieldSchemaHelper( String fieldName )** to |
931 | | | | get a ``SchemaHelper`` helper object to manipulate outgoing |
932 | | | | task fields in a schema-aware manner, e.g. to instantiate new |
933 | | | | schema-compliant field objects to populate the |
934 | | | | ``executor.outFields`` outgoing fields map. This can be used only when there |
935 | | | | is a single outgoing event from a task. |
937 | | | | - **SchemaHelper getOutFieldSchemaHelper( String eventname, String fieldName )**|
938 | | | | to get a ``SchemaHelper`` helper object to manipulate outgoing |
939 | | | | task fields in a schema-aware manner, e.g. to instantiate new |
940 | | | | schema-compliant field objects to populate the |
941 | | | | ``executor.outFieldsList`` collection of outgoing fields map. This must be |
942 | | | | used in case of multiple outgoing events from a task, as the intention is to |
943 | | | | fetch the schema of a field associated to one of the expected events. |
944 | | | | This method works fine in case of single outgoing event too, but the previous |
945 | | | | method is enough as the field anyway belongs to the single event. |
947 | | | |**Example:** |
949 | | | |.. code:: javascript |
951 | | | | executor.logger.info("Task name: " + executor.subject.getTaskName()); |
952 | | | | executor.logger.info("Task id: " + executor.subject.getId()); |
953 | | | | executor.outFields["authorised"] = executor.subject |
954 | | | | .getOutFieldSchemaHelper("authorised").createNewInstance("false"); |
956 | | | | var actionIdentifiers = executor.subject.getOutFieldSchemaHelper |
957 | | | | ("CDSRequestEvent","actionIdentifiers").createNewInstance(); |
958 | | | | actionIdentifiers.put("blueprintName", "sample-bp"); |
959 | | | | var cdsRequestEventFields = java.util.HashMap(); |
960 | | | | cdsRequestEventFields.put("actionIdentifiers", actionIdentifiers); |
961 | | | | executor.addFieldsToOutput(cdsRequestEventFields); |
962 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
963 | ContextAlbum getContextAlbum(String ctxtAlbumName ) |A utility method to retrieve a ``ContextAlbum`` for use in the task. | | |
964 | |This is how you access the context used by the task. The returned | | |
965 | |``ContextAlbum`` implements the ``java.util.Map <String,Object>`` | | |
966 | |interface to get and set context as appropriate. The returned | | |
967 | |``ContextAlbum`` also has methods to lock context albums, get | | |
968 | |information about the schema of the items to be stored in a context | | |
969 | |album, and get a ``SchemaHelper`` to manipulate context album items. How | | |
970 | |to define and use context in a task is described in the Apex | | |
971 | |Programmer’s Guide and in the My First Apex Policy guide. | | |
973 | |**Example:** | | |
975 | |.. code:: javascript | | |
977 | | var bkey = executor.inFields.get("branch_ID"); | | |
978 | | var cnts = executor.getContextMap("BranchCounts"); | | |
979 | | cnts.lockForWriting(bkey); | | |
980 | | cnts.put(bkey, cnts.get(bkey) + 1); | | |
981 | | cnts.unlockForWriting(bkey); | | |
982 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
984 Writing APEX Task Selection Logic
985 =================================
987 .. container:: paragraph
989 The function of Task Selection Logic is to choose which task should be executed for an Apex State as one of
990 the steps in an Apex Policy. Since each state must define a default task there is no need for Task Selection
991 Logic unless the state uses more than one task. This logic can be specified in a number of ways, exploiting
992 Apex’s plug-in architecture to support a range of logic executors. In Apex scripted Task Selection Logic can be
993 written in any of these languages:
997 - ```MVEL`` <https://en.wikipedia.org/wiki/MVEL>`__,
999 - ```JavaScript`` <https://en.wikipedia.org/wiki/JavaScript>`__,
1001 - ```JRuby`` <https://en.wikipedia.org/wiki/JRuby>`__ or
1003 - ```Jython`` <https://en.wikipedia.org/wiki/Jython>`__.
1005 .. container:: paragraph
1007 These languages were chosen because the scripts can be compiled into Java bytecode at runtime and then
1008 efficiently executed natively in the JVM. Task Selection Logic an also be written directly in Java but needs to
1009 be compiled, with the resulting classes added to the classpath. There are also a number of other Task Selection
1010 Logic types but these are not supported as yet. This guide will focus on the scripted Task Selection Logic
1011 approaches, with MVEL and JavaScript being our favorite languages. In particular this guide will focus on the
1012 Apex aspects of the scripts. However, this guide does not attempt to teach you about the scripting languages
1013 themselves …​ that is up to you!
1016 JVM-based scripting languages
1017 For more more information on Scripting for the Java platform see:
1018 https://docs.oracle.com/javase/8/docs/technotes/guides/scripting/prog_guide/index.html
1021 What does Task Selection Logic do?
1022 When an Apex state references multiple tasks, there must be a way to dynamically decide
1023 which task should be chosen and executed. This can depend on the many factors, e.g. the
1024 *incoming event for the state*, *shared state* or *context*, *external context*,
1025 etc.. This is the function of a state’s Task Selection Logic. Obviously, if there is
1026 only one task then Task only one task then Task Selection Logic is not needed.
1027 Each state must also select one of the tasks a the *default state*. If the Task
1028 Selection Logic is unable to select an appropriate task, then it should select the
1029 *default task*. Once the task has been selected the Apex Engine will then execute that task.
1031 .. container:: paragraph
1033 First lets start with some simple Task Selection Logic, drawn from the "My First Apex Policy" example: The Task
1034 Selection Logic from the "My First Apex Policy" example is specified in JavaScript here:
1036 .. container:: listingblock
1038 .. container:: title
1040 Javascript code for the "My First Policy" Task Selection Logic
1042 .. container:: content
1044 .. code:: javascript
1047 * ============LICENSE_START=======================================================
1048 * Copyright (C) 2016-2018 Ericsson. All rights reserved.
1049 * Modifications Copyright (C) 2020 Nordix Foundation.
1050 * ================================================================================
1051 * Licensed under the Apache License, Version 2.0 (the "License");
1052 * you may not use this file except in compliance with the License.
1053 * You may obtain a copy of the License at
1055 * http://www.apache.org/licenses/LICENSE-2.0
1057 * Unless required by applicable law or agreed to in writing, software
1058 * distributed under the License is distributed on an "AS IS" BASIS,
1059 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
1060 * See the License for the specific language governing permissions and
1061 * limitations under the License.
1063 * SPDX-License-Identifier: Apache-2.0
1064 * ============LICENSE_END=========================================================
1067 executor.logger.info("Task Selection Execution: '"+executor.subject.id+
1068 "'. Input Event: '"+executor.inFields+"'");
1070 branchid = executor.inFields.get("branch_ID");
1071 taskorig = executor.subject.getTaskKey("MorningBoozeCheck");
1072 taskalt = executor.subject.getTaskKey("MorningBoozeCheckAlt1");
1073 taskdef = executor.subject.getDefaultTaskKey();
1075 if(branchid >=0 && branchid <1000){
1076 taskorig.copyTo(executor.selectedTask);
1078 else if (branchid >=1000 && branchid <2000){
1079 taskalt.copyTo(executor.selectedTask);
1082 taskdef.copyTo(executor.selectedTask);
1086 This task selection logic selects task "MorningBoozeCheck" for branches with
1087 0<=branch_ID<1000 and selects task "MorningBoozeCheckAlt1" for branches with
1088 1000<=branch_ID<2000. Otherwise the default task is selected.
1089 In this case the default task is also "MorningBoozeCheck"
1094 .. container:: paragraph
1096 The role of the Task Selection Logic in this simple example is to examine the value in one incoming field
1097 (``branchid``), then depending on that field’s value set the value for the selected task to the appropriate task
1098 (``MorningBoozeCheck``, ``MorningBoozeCheckAlt1``, or the default task).
1100 .. container:: paragraph
1102 Another thing to notice is that Task Selection Logic should return a ``java.lang.Boolean`` value ``true`` if
1103 the logic executed correctly. If the logic fails for some reason then ``false`` can be returned, but this will
1104 cause the policy invoking this task will fail and exit.
1107 How to return a value from Task Selection Logic
1108 Some languages explicitly support returning values from the script (e.g. MVEL and
1109 JRuby) using an explicit return statement (e.g. ``return true``), other languages do not (e.g.
1110 JavaScript and Jython). For languages that do not support the ``return`` statement, a special field called
1111 ``returnValue`` must be created to hold the result of the task logic operation (i.e. assign a ``java.lang.Boolean``
1112 value to the ``returnValue`` field before completing the task).
1113 Also, in MVEL if there is not explicit return statement then the return value of the last executed statement will
1114 return (e.g. the statement a=(1+2) will return the value 3).
1116 .. container:: paragraph
1118 Each of the scripting languages used in Apex can import and use standard Java libraries to perform complex tasks.
1119 Besides imported classes and normal language features Apex provides some natively available parameters and functions
1120 that can be used directly. At run-time these parameters are populated by the Apex execution environment and made
1121 natively available to logic scripts each time the logic script is invoked. (These can be accessed using the
1122 ``executor`` keyword for most languages, or can be accessed directly without the ``executor`` keyword in MVEL):
1124 Table 2. The ``executor`` Fields / Methods
1125 +-----------------------------------+------------------------------------+
1126 | Unix, Cygwin | Windows |
1127 +===================================+====================================+
1128 |.. container:: content |.. container:: content |
1130 | .. code:: bash | .. code:: bash |
1131 | :number-lines: | :number-lines: |
1133 | >c: | # cd /usr/local/src/apex-pdp |
1134 | >cd \dev\apex | # mvn clean install -DskipTests |
1135 | >mvn clean install -DskipTests | |
1136 +-----------------------------------+------------------------------------+
1138 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1139 | Name | Type | Java type | Description |
1140 +=====================================================+==========================================================================+===============================+==================================================================================+
1141 | inFields | Fields | java.util.Map <String,Object> | All fields in the state’s incoming event. This is implemented as a standard Java |
1142 | | | | Java (unmodifiable) Map |
1144 | | | | **Example:** |
1146 | | | | .. code:: javascript |
1148 | | | | executor.logger.debug("Incoming fields: " + executor.inFields.entrySet()); |
1149 | | | | var item_id = executor.incomingFields["item_ID"]; |
1150 | | | | if (item_id >=1000) { ... } |
1151 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1152 | outFields | Fields | java.util.Map <String,Object> | The outgoing task fields. This is implemented as a standard initially empty Java |
1153 | | | | (modifiable) Map. To create a new schema-compliant instance of a field object |
1154 | | | | see the utility method subject.getOutFieldSchemaHelper() below |
1156 | | | | **Example:** |
1158 | | | | .. code:: javascript |
1160 | | | | executor.outFields["authorised"] = false; |
1161 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1162 | logger | Logger | org.slf4j.ext.XLogger | A helpful logger |
1164 | | | | **Example:** |
1166 | | | | .. code:: javascript |
1168 | | | | executor.logger.info("Executing task: " |
1169 | | | | +executor.subject.id); |
1170 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1171 | TRUE/FALSE | boolean | java.lang.Boolean | 2 helpful constants. These are useful to retrieve correct return values for the |
1172 | | | | task logic |
1174 | | | | **Example:** |
1176 | | | | .. code:: javascript |
1178 | | | | var returnValue = executor.isTrue; |
1179 | | | | var returnValueType = Java.type("java.lang.Boolean"); |
1180 | | | | var returnValue = new returnValueType(true); |
1181 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1182 | subject | Task | TaskFacade | This provides some useful information about the task that contains this task |
1183 | | | | logic. This object has some useful fields and methods : |
1185 | | | | .. container:: ulist |
1187 | | | | - **AxTask task** to get access to the full task definition of the host task |
1189 | | | | - **String getTaskName()** to get the name of the host task |
1191 | | | | - **String getId()** to get the ID of the host task |
1193 | | | | - **SchemaHelper getInFieldSchemaHelper( String fieldName )** to |
1194 | | | | get a ``SchemaHelper`` helper object to manipulate incoming |
1195 | | | | task fields in a schema-aware manner |
1197 | | | | - **SchemaHelper getOutFieldSchemaHelper( String fieldName )** to |
1198 | | | | get a ``SchemaHelper`` helper object to manipulate outgoing |
1199 | | | | task fields in a schema-aware manner, e.g. to instantiate new |
1200 | | | | schema-compliant field objects to populate the |
1201 | | | | ``executor.outFields`` outgoing fields map |
1203 | | | | **Example:** |
1205 | | | | .. code:: javascript |
1207 | | | | executor.logger.info("Task name: " + executor.subject.getTaskName()); |
1208 | | | | executor.logger.info("Task id: " + executor.subject.getId()); |
1209 | | | | executor.outFields["authorised"] = executor.subject |
1210 | | | | .getOutFieldSchemaHelper("authorised") |
1211 | | | | .createNewInstance("false"); |
1212 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1213 | parameters | Fields | java.util.Map <String,String> | All parameters in the current task. This is implemented as a standard Java Map. |
1215 | | | | **Example:** |
1217 | | | | .. code:: javascript |
1219 | | | | executor.parameters.get("ParameterKey1")) |
1220 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1221 | ContextAlbum getContextAlbum(String ctxtAlbumName ) | A utility method to retrieve a ``ContextAlbum`` for use in the task. | | |
1222 | | This is how you access the context used by the task. The returned | | |
1223 | | ``ContextAlbum`` implements the ``java.util.Map <String,Object>`` | | |
1224 | | interface to get and set context as appropriate. The returned | | |
1225 | | ``ContextAlbum`` also has methods to lock context albums, get | | |
1226 | | information about the schema of the items to be stored in a context | | |
1227 | | album, and get a ``SchemaHelper`` to manipulate context album items. How | | |
1228 | | to define and use context in a task is described in the Apex | | |
1229 | | Programmer’s Guide and in the My First Apex Policy guide. | | |
1231 | | **Example:** | | |
1233 | | .. code:: javascript | | |
1235 | | var bkey = executor.inFields.get("branch_ID"); | | |
1236 | | var cnts = executor.getContextMap("BranchCounts"); | | |
1237 | | cnts.lockForWriting(bkey); | | |
1238 | | cnts.put(bkey, cnts.get(bkey) + 1); | | |
1239 | | cnts.unlockForWriting(bkey); | | |
1240 +-----------------------------------------------------+--------------------------------------------------------------------------+-------------------------------+----------------------------------------------------------------------------------+
1245 .. container:: paragraph
1247 Examples given here use Javascript (if not stated otherwise), other execution environments will be similar.
1249 Finish Logic with Success or Error
1250 ----------------------------------
1252 .. container:: paragraph
1254 To finish logic, i.e. return to APEX, with success use the following line close to the end of the logic.
1256 .. container:: listingblock
1258 .. container:: title
1262 .. container:: content
1264 .. code:: javascript
1268 .. container:: paragraph
1270 To notify a problem, finish with an error.
1272 .. container:: listingblock
1274 .. container:: title
1278 .. container:: content
1280 .. code:: javascript
1287 .. container:: paragraph
1289 Logging can be made easy using a local variable for the logger. Line 1 below does that. Then we start
1290 with a trace log with the task (or task logic) identifier followed by the infields.
1292 .. container:: listingblock
1294 .. container:: title
1298 .. container:: content
1300 .. code:: javascript
1302 var logger = executor.logger;
1303 logger.trace("start: " + executor.subject.id);
1304 logger.trace("-- infields: " + executor.inFields);
1306 .. container:: paragraph
1308 For larger logging blocks you can use the standard logging API to detect log levels, for instance:
1310 .. container:: listingblock
1312 .. container:: title
1316 .. container:: content
1318 .. code:: javascript
1320 if(logger.isTraceEnabled()){
1321 // trace logging block here
1324 .. container:: paragraph
1326 Note: the shown logger here logs to ``org.onap.policy.apex.executionlogging``. The behavior of the actual logging can
1327 be specified in the ``$APEX_HOME/etc/logback.xml``.
1329 .. container:: paragraph
1331 If you want to log into the APEX root logger (which is sometimes necessary to report serious logic errors to the top),
1332 then import the required class and use this logger.
1334 .. container:: listingblock
1336 .. container:: title
1340 .. container:: content
1342 .. code:: javascript
1344 var rootLogger = LoggerFactory.getLogger(logger.ROOT_LOGGER_NAME);
1345 rootLogger.error("Serious error in logic detected: " + executor.subject.id);
1347 Accessing TaskParameters
1348 ------------------------
1350 .. container:: paragraph
1352 TaskParameters available in a Task can be accessed in the logic. The parameters in each task are made
1353 available at the executor level. This example assumes a parameter with key ``ParameterKey1``.
1355 .. container:: listingblock
1357 .. container:: title
1359 JS TaskParameter value
1361 .. container:: content
1363 .. code:: javascript
1365 executor.parameters.get("ParameterKey1"))
1367 .. container:: paragraph
1369 Alternatively, the task parameters can also be accessed from the task object.
1371 .. container:: listingblock
1373 .. container:: title
1375 JS TaskParameter value using task object
1377 .. container:: content
1379 .. code:: javascript
1381 executor.subject.task.getTaskParameters.get("ParameterKey1").getTaskParameterValue()
1383 Local Variable for Infields
1384 ---------------------------
1386 .. container:: paragraph
1388 It is a good idea to use local variables for ``infields``. This avoids long code lines and policy
1389 evolution. The following example assumes infields named ``nodeName`` and ``nodeAlias``.
1391 .. container:: listingblock
1393 .. container:: title
1395 JS Infields Local Var
1397 .. container:: content
1399 .. code:: javascript
1401 var ifNodeName = executor.inFields["nodeName"];
1402 var ifNodeAlias = executor.inFields["nodeAlias"];
1404 Local Variable for Context Albums
1405 ---------------------------------
1407 .. container:: paragraph
1409 Similar to the ``infields`` it is good practice to use local variables for context albums as well. The
1410 following example assumes that a task can access a context album ``albumTopoNodes``. The second line gets a
1411 particular node from this context album.
1413 .. container:: listingblock
1415 .. container:: title
1417 JS Infields Local Var
1419 .. container:: content
1421 .. code:: javascript
1423 var albumTopoNodes = executor.getContextAlbum("albumTopoNodes");
1424 var ctxtNode = albumTopoNodes.get(ifNodeName);
1426 Set Outfields in Logic
1427 ----------------------
1429 .. container:: paragraph
1431 The task logic needs to set outfields with content generated. The exception are outfields that are a
1432 direct copy from an infield of the same name, APEX does that autmatically.
1434 .. container:: listingblock
1436 .. container:: title
1440 .. container:: content
1442 .. code:: javascript
1444 executor.outFields["report"] = "node ctxt :: added node " + ifNodeName;
1446 Create a instance of an Outfield using Schemas
1447 ----------------------------------------------
1449 .. container:: paragraph
1451 If an outfield is not an atomic type (string, integer, etc.) but uses a complex schema (with a Java or
1452 Avro backend), APEX can help to create new instances. The ``executor`` provides a field called ``subject``,
1453 which provides a schem helper with an API for this. The complete API of the schema helper is documented here:
1454 `API Doc: SchemaHelper <https://ericsson.github.io/apex-docs/javadocs/index.html>`__.
1456 .. container:: paragraph
1458 If the backend is Java, then the Java class implementing the schema needs to be imported.
1460 *Single outgoing event*
1462 .. container:: paragraph
1464 When there is a single outgoing event associated with a task, the fieldName alone is enough to fetch its schema.
1465 The following example assumes an outfield ``situation``. The ``subject`` method ``getOutFieldSchemaHelper()`` is used
1466 to create a new instance.
1468 .. container:: listingblock
1470 .. container:: title
1472 JS Outfield Instance with Schema
1474 .. container:: content
1476 .. code:: javascript
1478 var situation = executor.subject.getOutFieldSchemaHelper("situation").createNewInstance();
1480 .. container:: paragraph
1482 If the schema backend is Java, the new instance will be as implemented in the Java class. If the schema backend is
1483 Avro, the new instance will have all fields from the Avro schema specification, but set to ``null``. So any entry here
1484 needs to be done separately. For instance, the ``situation`` schema has a field ``problemID`` which we set.
1486 .. container:: listingblock
1488 .. container:: title
1490 JS Outfield Instance with Schema, set
1492 .. container:: content
1494 .. code:: javascript
1496 situation.put("problemID", "my-problem");
1498 *Multiple outgoing events*
1500 .. container:: paragraph
1502 When there are multiple outgoing events associated with a task, the fieldName along with the eventName it belongs to
1503 are needed to fetch its schema.
1504 The following example assumes an outfield ``actionIdentifiers`` which belongs to ``CDSRequestEvent``.
1505 The ``subject`` method ``getOutFieldSchemaHelper()`` is used to create a new instance.
1507 .. container:: listingblock
1509 .. container:: content
1511 .. code:: javascript
1513 var actionIdentifiers = executor.subject.getOutFieldSchemaHelper("CDSRequestEvent", "actionIdentifiers").createNewInstance();
1515 Create a instance of an Context Album entry using Schemas
1516 ---------------------------------------------------------
1518 .. container:: paragraph
1520 Context album instances can be created using very similar to the outfields. Here, the schema helper
1521 comes from the context album directly. The API of the schema helper is the same as for outfields, see
1522 `API Doc: SchemaHelper <https://ericsson.github.io/apex-docs/javadocs/index.html>`__.
1524 .. container:: paragraph
1526 If the backend is Java, then the Java class implementing the schema needs to be imported.
1528 .. container:: paragraph
1530 The following example creates a new instance of a context album instance named ``albumProblemMap``.
1532 .. container:: listingblock
1534 .. container:: title
1536 JS Outfield Instance with Schema
1538 .. container:: content
1540 .. code:: javascript
1542 var albumProblemMap = executor.getContextAlbum("albumProblemMap");
1543 var linkProblem = albumProblemMap.getSchemaHelper().createNewInstance();
1545 .. container:: paragraph
1547 This can of course be also done in a single call without the local variable for the context album.
1549 .. container:: listingblock
1551 .. container:: title
1553 JS Outfield Instance with Schema, one line
1555 .. container:: content
1557 .. code:: javascript
1559 var linkProblem = executor.getContextAlbum("albumProblemMap").getSchemaHelper().createNewInstance();
1561 .. container:: paragraph
1563 If the schema backend is Java, the new instance will be as implemented in the Java class. If the schema backend is
1564 Avro, the new instance will have all fields from the Avro schema specification, but set to ``null``. So any entry here
1565 needs to be done separately (see above in outfields for an example).
1570 .. container:: paragraph
1572 When dealing with enumerates (Avro or Java defined), it is sometimes and in some execution
1573 environments necessary to convert them to a string. For example, assume an Avro enumerate schema as:
1575 .. container:: listingblock
1577 .. container:: title
1579 Avro Enumerate Schema
1581 .. container:: content
1583 .. code:: javascript
1586 "type": "enum", "name": "Status", "symbols" : [
1591 .. container:: paragraph
1593 Using a switch over a field initialized with this enumerate in Javascript will fail. Instead, use the ``toString`` method, for example:
1595 .. container:: listingblock
1597 .. container:: title
1599 JS Outfield Instance with Schema, one line
1601 .. container:: content
1603 .. code:: javascript
1605 var switchTest = executor.inFields["status"]; switch(switchTest.toString()){
1606 case "UP": ...; break; case "DOWN": ...; break; default: ...;
1609 MVEL Initialize Outfields First!
1610 --------------------------------
1612 .. container:: paragraph
1614 In MVEL, we observed a problem when accessing (setting) outfields without a prior access to them. So
1615 in any MVEL task logic, before setting any outfield, simply do a get (with any string), to load the outfields
1616 into the MVEL cache.
1618 .. container:: listingblock
1620 .. container:: title
1622 MVEL Outfield Initialization
1624 .. container:: content
1626 .. code:: javascript
1628 outFields.get("initialize outfields");
1630 Using Java in Scripting Logic
1631 -----------------------------
1633 .. container:: paragraph
1635 Since APEX executes the logic inside a JVM, most scripting languages provide access to all standard
1636 Java classes. Simply add an import for the required class and then use it as in actual Java.
1638 .. container:: paragraph
1640 The following example imports ``java.util.arraylist`` into a Javascript logic, and then creates a new
1643 .. container:: listingblock
1645 .. container:: title
1649 .. container:: content
1651 .. code:: javascript
1653 var myList = new ArrayList();
1655 Converting Javascript scripts from Nashorn to Rhino dialects
1656 ------------------------------------------------------------
1658 The Nashorn Javascript engine was removed from Java in the Java 11 release. Java 11 was introduced into
1659 the Policy Framework in the Frankfurt release, so from Frankfurt on, APEX Javascript scripts use the Rhino
1660 Javascript engine and scripts must be in the Rhino dialect.
1662 There are some minor but important differences between the dialects that users should be aware of so
1663 that they can convert their scripts into the Rhino dialect.
1668 APEX scripts must always return a value of ``true`` indicating that the script executed correctly or ``false``
1669 indicating that there was an error in script execution.
1673 In Nashorn dialect scripts, the user had to create a special variable called ``returnValue`` and set the value of
1674 that variable to be the return value for the script.
1676 *Frankfurt and Later*
1678 In Rhino dialect scripts, the return value of the script is the logical result of the last statement. Therefore the
1679 last line of the script must evaluate to either ``true`` or ``false``.
1681 .. container:: listingblock
1683 .. container:: title
1685 JS Rhino script last executed line examples
1687 .. container:: content
1689 .. code:: javascript
1693 returnValue; // Where returnValue is assigned earlier in the script
1695 someValue == 1; // Where the value of someValue is assigned earlier in the script
1700 The ``return`` statement is not supported from the main script called in the Rhino interpreter.
1704 In Nashorn dialect scripts, the user could return a value of ``true`` or ``false`` at any point in their script.
1706 .. container:: listingblock
1708 .. container:: title
1710 JS Nashorn main script returning ``true`` and ``false``
1712 .. container:: content
1714 .. code:: javascript
1718 // some code assigns n a value
1726 *Frankfurt and Later*
1728 In Rhino dialect scripts, the ``return`` statement cannot be used in the main method, but it can still be used in
1729 functions. If you want to have a ``return`` statement in your code prior to the last statement, encapsulate your code
1732 .. container:: listingblock
1734 .. container:: title
1736 JS Rhino script with ``return`` statements in a function
1738 .. container:: content
1740 .. code:: javascript
1744 function someFunction() {
1747 // some code assigns n a value
1756 Compatibility Script
1757 ^^^^^^^^^^^^^^^^^^^^
1759 For Nashorn, the user had to call a compatibility script at the beginning of their Javascript script. This is not
1764 In Nashorn dialect scripts, the compatibility script must be loaded.
1766 .. container:: listingblock
1768 .. container:: title
1770 Nashorn compatability script loading
1772 .. container:: content
1774 .. code:: javascript
1776 load("nashorn:mozilla_compat.js");
1778 *Frankfurt and Later*
1782 Import of Java classes
1783 ^^^^^^^^^^^^^^^^^^^^^^
1785 For Nashorn, the user had explicitly import all the Java packages and classes they wished to use in their Javascript
1786 script. In Rhino, all Java classes on the classpath are available for use.
1790 In Nashorn dialect scripts, Java classes must be imported.
1792 .. container:: listingblock
1794 .. container:: title
1796 Importation of Java packages and classes
1798 .. container:: content
1800 .. code:: javascript
1802 importPackage(java.text);
1803 importClass(java.text.SimpleDateFormat);
1805 *Frankfurt and Later*
1809 Using Java Classes and Objects as Variables
1810 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
1812 Setting a Javascript variable to hold a Java class or a Java object is more straightforward in Rhino than it is in
1813 Nashorn. The examples below show how to instantiate a Javascript variable as a Java class and how to use that variable
1814 to create an instance of the Java class in another Javascript variable in both dialects.
1819 .. container:: listingblock
1821 .. container:: title
1823 Create Javascript variables to hold a Java class and instance
1825 .. container:: content
1827 .. code:: javascript
1829 var webClientClass = Java.type("org.onap.policy.apex.examples.bbs.WebClient");
1830 var webClientObject = new webClientClass();
1832 *Frankfurt and Later*
1834 .. container:: listingblock
1836 .. container:: title
1838 Create Javascript variables to hold a Java class and instance
1840 .. container:: content
1842 .. code:: javascript
1844 var webClientClass = org.onap.policy.apex.examples.bbs.WebClient;
1845 var webClientObject = new webClientClass();
1847 Equal Value and Equal Type operator ``===``
1848 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
1850 The *Equal Value and Equal Type* operator ``===`` is not supported in Rhino. Developers must use the Equal To
1851 operator ``==`` instead. To check types, they may need to explicitly find and check the type of the variables
1854 *************************************************
1855 Writing Multiple Output Events from a Final State
1856 *************************************************
1858 .. container:: paragraph
1860 APEX-PDP now supports sending multiple events from a final state in a Policy. The task assocaiated with the final
1861 state can populate the fields of multiple events, and then they can be passed over as the output events from the final
1865 inputfields and outputfields are not needed as part of the task definition anymore. Fields of an event are already
1866 defined as part of the event definition. Input event (single trigger event) and output event/events can be populated
1867 to a task as part of the policy/state definition because the event tagging is done there anyway.
1869 .. container:: paragraph
1871 Consider a simple example where a policy *CDSActionPolicy* has a state *MakeCDSRequestState* which is also a final
1872 state. The state is triggered by an event *AAIEvent*. A task called *HandleCDSActionTask* is associated with
1873 *MakeCDSRequestState*.There are two output events expected from *MakeCDSRequestState* which are *CDSRequestEvent*
1874 (request event sent to CDS) and *LogEvent* (log event sent to DMaaP).
1875 Writing an APEX policy with this example will involve the below changes.
1879 .. container:: listingblock
1881 .. container:: title
1883 Define all the concepts in the Policy. Only relevant parts for the multiple output support are shown.
1885 .. container:: content
1890 event create name=AAIEvent version=0.0.1 nameSpace=org.onap.policy.apex.test source=AAI target=APEX
1892 event create name=CDSRequestEvent version=0.0.1 nameSpace=org.onap.policy.apex.test source=APEX target=CDS
1893 event parameter create name=CDSRequestEvent parName=actionIdentifiers schemaName=CDSActionIdentifiersType
1895 event create name=LogEvent version=0.0.1 nameSpace=org.onap.policy.apex.test source=APEX target=DMaaP
1896 event parameter create name=LogEvent parName=status schemaName=SimpleStringType
1900 task create name=HandleCDSActionTask
1901 task contextref create name=HandleCDSActionTask albumName=EventDetailsAlbum
1902 task logic create name=HandleCDSActionTask logicFlavour=JAVASCRIPT logic=LS
1903 #MACROFILE:"src/main/resources/logic/HandleCDSActionTask.js"
1907 ## Define Policies and States
1908 policy create name=CDSActionPolicy template=Freestyle firstState=MakeCDSRequestState
1909 policy state create name=CDSActionPolicy stateName=MakeCDSRequestState triggerName=AAIEvent defaultTaskName=HandleCDSActionTask
1910 # Specify CDSRequestEvent as output
1911 policy state output create name=CDSActionPolicy stateName=MakeCDSRequestState outputName=CDSActionStateOutput eventName=CDSRequestEvent
1912 # Specify LogEvent as output
1913 policy state output create name=CDSActionPolicy stateName=MakeCDSRequestState outputName=CDSActionStateOutput eventName=LogEvent
1914 policy state taskref create name=CDSActionPolicy stateName=MakeCDSRequestState taskName=HandleCDSActionTask outputType=DIRECT outputName=CDSActionStateOutput
1918 .. container:: listingblock
1920 .. container:: title
1922 Create outfields' instance if required, populate and add them the output events
1924 .. container:: content
1926 .. code:: javascript
1929 var cdsRequestEventFields = java.util.HashMap();
1930 var actionIdentifiers = executor.subject.getOutFieldSchemaHelper("CDSRequestEvent","actionIdentifiers").createNewInstance();
1931 actionIdentifiers.put("blueprintName", "sample-bp");
1932 cdsRequestEventFields.put("actionIdentifiers", actionIdentifiers);
1933 executor.addFieldsToOutput(cdsRequestEventFields);
1935 var logEventFields = java.util.HashMap();
1936 logEventFields.put("status", "FINAL_SUCCESS");
1937 executor.addFieldsToOutput(logEventFields);
1939 .. container:: paragraph
1941 With the above changes, the task populates the fields for both the expected events, and the corresponding state which
1942 is *MakeCDSRequestState* outputs both *CDSRequestEvent* and *LogEvent*
1944 .. |APEX Policy Matrix| image:: images/apex-intro/ApexPolicyMatrix.png
1945 .. |APEX Policy Model for Execution| image:: images/apex-policy-model/UmlPolicyModels.png
1946 .. |Concepts and Keys| image:: images/apex-policy-model/ConceptsKeys.png