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author | ramverma <ram.krishna.verma@est.tech> | 2019-07-11 16:24:18 +0000 |
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committer | ramverma <ram.krishna.verma@est.tech> | 2019-07-11 16:24:18 +0000 |
commit | ec485111483f1ffca0bc65d12ce461df3d595169 (patch) | |
tree | 1a96b1b5f65dc2ebf2f0bc70691494214d59058e /docs/APEX-Policy-Guide.rst | |
parent | 45d7389dacffb824b66e8a7c43583dc0212cb7d5 (diff) |
Removing docs from apex-pdp repo
The documents are moved to policy/parent and hence removing them from
apex-pdp repo.
Change-Id: I479cf477e953049292dc9681f960ca965b90d591
Issue-ID: POLICY-1898
Signed-off-by: ramverma <ram.krishna.verma@est.tech>
Diffstat (limited to 'docs/APEX-Policy-Guide.rst')
-rw-r--r-- | docs/APEX-Policy-Guide.rst | 2133 |
1 files changed, 0 insertions, 2133 deletions
diff --git a/docs/APEX-Policy-Guide.rst b/docs/APEX-Policy-Guide.rst deleted file mode 100644 index 392f31c7b..000000000 --- a/docs/APEX-Policy-Guide.rst +++ /dev/null @@ -1,2133 +0,0 @@ -.. This work is licensed under a Creative Commons Attribution 4.0 International License. -.. http://creativecommons.org/licenses/by/4.0 - - -APEX Policy Guide -***************************** - -.. contents:: - :depth: 3 - -APEX Policy Matrix -^^^^^^^^^^^^^^^^^^ - -APEX Policy Matrix ------------------- - - .. container:: paragraph - - APEX offers a lot of flexibility for defining, deploying, - and executing policies. Based on a theoretic model, it - supports virtually any policy model and allows to - translate legacy policies into the APEX execution format. - However, the most important aspect for using APEX is to - decide what policy is needed, what underlying policy - concepts should be used, and how the decision logic - should be realized. Once these aspects are decided, APEX - can be used to execute the policies. If the policy - evolves, say from a simple decision table to a fully - adaptable policy, only the policy definition requires - change. APEX supports all of that. - - .. container:: paragraph - - The figure below shows a (non-exhaustive) matrix, which - will help to decide what policy is required to solve your - problem. Read the matrix from left to right choosing one - cell in each column. - - .. container:: imageblock - - .. container:: content - - |APEX Policy Matrix| - - .. container:: title - - Figure 1. APEX Policy Matrix - - .. container:: paragraph - - The policy can support one of a number of stimuli with an - associated purpose/model of the policy, for instance: - - .. container:: ulist - - - Configuration, i.e. what should happen. An example is - an event that states an intended network configuration - and the policy should provide the detailed actions for - it. The policy can be realized for instance as an - obligation policy, a promise or an intent. - - - Report, i.e. something did happen. An example is an - event about an error or fault and the policy needs to - repair that problem. The policy would usually be an - obligation, utility function, or goal policy. - - - Monitoring, i.e. something does happen. An example is - a notification about certain network conditions, to - which the policy might (or might not) react. The - policy will mitigate the monitored events or permit - (deny) related actions as an obligation or - authorization. - - - Analysis, i.e. why did something happen. An example is - an analytic component sends insights of a situation - requiring a policy to act on it. The policy can solve - the problem, escalate it, or delegate it as a refrain - or delegation policy. - - - Prediction, i.e. what will happen next. An example are - events that a policy uses to predict a future network - condition. The policy can prevent or enforce the - prediction as an adaptive policy, a utility function, - or a goal. - - - Feedback, i.e. why did something happen or not happen. - Similar to analysis, but here the feedback will be in - the input event and the policy needs to something with - that information. Feedback can be related to history - or experience, for instance a previous policy - execution. The policy needs to be context-aware or be - a meta-policy. - - .. container:: paragraph - - Once the purpose of the policy is decided, the next step - is to look into what context information the policy will - require to do its job. This can range from very simple to - a lot of different information, for instance: - - .. container:: ulist - - - No context, nothing but a trigger event, e.g. a string - or a number, is required - - - Event context, the incoming event provides all - information (more than a string or number) for the - policy - - - Policy context (read only), the policy has access to - additional information related to its class but cannot - change/alter them - - - Policy context (read and write), the policy has access - to additional information related to its class and can - alter this information (for instance to record - historic information) - - - Global context (read only), the policy has access to - additional information of any kind but cannot - change/alter them - - - Global context (read and write), the policy the policy - has access to additional information of any kind and - can alter this information (for instance to record - historic information) - - .. container:: paragraph - - The next step is to decide how the policy should do its - job, i.e. what flavor it has, how many states are needed, - and how many tasks. There are many possible combinations, - for instance: - - .. container:: ulist - - - Simple / God: a simple policy with 1 state and 1 task, - which is doing everything for the decision-making. - This is the ideal policy for simple situation, e.g. - deciding on configuration parameters or simple access - control. - - - Simple sequence: a simple policy with a number of - states each having a single task. This is a very good - policy for simple decision-making with different - steps. For instance, a classic action policy (ECA) - would have 3 states (E, C, and A) with some logic (1 - task) in each state. - - - Simple selective: a policy with 1 state but more than - one task. Here, the appropriate task (and it’s logic) - will be selected at execution time. This policy is - very good for dealing with similar (or the same) - situation in different contexts. For instance, the - tasks can be related to available external software, - or to current work load on the compute node, or to - time of day. - - - Selective: any number of states having any number of - tasks (usually more than 1 task). This is a - combination of the two policies above, for instance an - ECA policy with more than one task in E, C, and A. - - - Classic directed: a policy with more than one state, - each having one task, but a non-sequential execution. - This means that the sequence of the states is not - pre-defined in the policy (as would be for all cases - above) but calculated at runtime. This can be good to - realize decision trees based on contextual - information. - - - Super Adaptive: using the full potential of the APEX - policy model, states and tasks and state execution are - fully flexible and calculated at runtime (per policy - execution). This policy is very close to a general - programming system (with only a few limitations), but - can solve very hard problems. - - .. container:: paragraph - - The final step is to select a response that the policy - creates. Possible responses have been discussed in the - literature for a very long time. A few examples are: - - .. container:: ulist - - - Obligation (deontic for what should happen) - - - Authorization (e.g. for rule-based or other access - control or security systems) - - - Intent (instead of providing detailed actions the - response is an intent statement and a further system - processes that) - - - Delegation (hand the problem over to someone else, - possibly with some information or instructions) - - - Fail / Error (the policy has encountered a problem, - and reports it) - - - Feedback (why did the policy make a certain decision) - -APEX Policy Model -^^^^^^^^^^^^^^^^^ - -Introduction ------------- - - .. container:: paragraph - - The APEX policy model is shown in UML notation in the - figure below. A policy model can be stored in JSON or XML - format in a file or can be held in a database. The APEX - editor creates and modifies APEX policy models. APEX - deployment deploys policy models, and a policy model is - loaded into APEX engines so that the engines can run the - policies in the policy model. - - .. container:: paragraph - - The figure shows four different views of the policy - model: - - .. container:: ulist - - - The general model view shows the main parts of a - policy: state, state output, event, and task. A task - can also have parameters. Data types can be defined on - a per-model basis using either standard atomic types - (such as character, string, numbers) or complex types - from a policy domain. - - - The logic model view emphasizes how decision-making - logic is injected into a policy. There are essentially - three different types of logic: task logic (for - decision making in a task), task selection logic (to - select a task if more than one is defined in a state), - and state finalizer logic (to compute the final output - event of a state and select an appropriate next state - from the policy model). - - - The context model view shows how context is injected - into a policy. States collect all context from their - tasks. A task can define what context it requires for - the decision making, i.e. what context the task logic - will process. Context itself is a collection of items - (individual context information) with data types. - Context can be templated. - - - The event and field model view shows the events in the - policy model. Tasks define what information they - consume (input) and produce (output). This information - is modeled as fields, essentially a key/type tuple in - the model and a key/type/value triple at execution. - Events then are collection of fields. - - .. container:: imageblock - - .. container:: content - - |APEX Policy Model for Execution| - - .. container:: title - - Figure 2. APEX Policy Model for Execution - -Concepts and Keys -################# - - .. container:: paragraph - - Each element of the policy model is called a - *concept*. Each *concept* is a subclass of the - abstract *Concept* class, as shown in the next figure. - Every concept implements the following abstract - methods: - - .. container:: imageblock - - .. container:: content - - |Concepts and Keys| - - .. container:: title - - Figure 3. Concepts and Keys - - .. container:: ulist - - - ``getKey()`` - gets the unique key for this concept - instance in the system - - - ``validate()`` - validates the structure of this - concept, its sub-concepts and its relationships - - - ``clean()`` - carries out housekeeping on the - concept such as trimming strings, remove any - hanging references - - - ``clone()`` - creates a deep copy of an instance of - this concept - - - ``equals()`` - checks if two instances of this - concept are equal - - - ``toString()`` - returns a string representation of - the concept - - - ``hashCode()`` - returns a hash code for the - concept - - - ``copyTo()`` - carries out a deep copy of one - instance of the concept to another instance, - overwriting the target fields. - - .. container:: paragraph - - All concepts must have a *key*, which uniquely - identifies a concept instance. The *key* of a subclass - of an *Concept* must either be an ``ArtifactKey`` or - an ``ReferenceKey``. Concepts that have a stand-alone - independent existence such as *Policy*, *Task*, and - *Event* must have an ``ArtifctKey`` key. Concepts that - are contained in other concepts, that do not exist as - stand-alone concepts must have an ``ReferenceKey`` - key. Examples of such concepts are *State* and - *EventParameter*. - - .. container:: paragraph - - An ``ArticactKey`` has two fields; the *Name* of the - concept it is the key for and the concept’s *Version*. - A concept’s name must be unique in a given - PolicyModel. A concept version is represented using - the well known *major.minor.path* scheme as used in - semantic versioning. - - .. container:: paragraph - - A ``ReferenceKey`` has three fields. The *UserKeyName* - and *UserKeyVersion* fields identify the - ``ArtifactKey`` of the concept in which the concept - keyed by the ``ReferenceKey`` is contained. The - *LocalName* field identifies the contained concept - instance. The *LocalName* must be unique in the - concepts of a given type contained by a parent. - - .. container:: paragraph - - For example, a policy called ``SalesPolicy`` with a - Version of ``1.12.4`` has a state called ``Decide``. - The ``Decide`` state is linked to the ``SalesPolicy`` - with a ``ReferenceKey`` with fields *UserKeyName* of - ``SalesPolicy``, *UserKeyVersion* of ``1.12.4``, and - *LocalName* of ``Decide``. There must not be another - state called ``Decide`` in the policy ``SalesPolicy``. - However, there may well be a state called ``Decide`` - in some other policy called ``PurchasingPolicy``. - - .. container:: paragraph - - Each concept in the model is also a JPA (`Java - Persistence - API <https://en.wikipedia.org/wiki/Java_Persistence_API>`__) - Entity. This means that every concept can be - individually persisted or the entire model can be - persisted en-bloc to any persistence mechanism using - an JPA framework such as - `Hibernate <http://hibernate.org/>`__ or - `EclipseLink <http://www.eclipse.org/eclipselink/>`__. - -Concept: PolicyModel -#################### - - .. container:: paragraph - - The *PolicyModel* concept is a container that holds - the definition of a set of policies and their - associated events, context maps, and tasks. A - *PolicyModel* is implemented as four maps for - policies, events, context maps, and tasks. Each map is - indexed by the key of the policy, event, context map, - or task. Any non-empty policy model must have at least - one entry in its policy, event, and task map because - all policies must have at least one input and output - event and must execute at least one task. - - .. container:: paragraph - - A *PolicyModel* concept is keyed with an - ``ArtifactKey key``. Because a *PolicyModel* is an - ``AxConcept``, calling the ``validate()`` method on a - policy model validates the concepts, structure, and - relationships of the entire policy model. - -Concept: DataType -################# - - .. container:: paragraph - - Data types are tightly controlled in APEX in order to - provide a very high degree of consistency in policies - and to facilitate tracking of changes to context as - policies execute. All context is modeled as a - *DataType* concept. Each DataType concept instance is - keyed with an ``ArtifactKey`` key. The DataType field - identifies the Java class of objects that is used to - represent concept instances that use this data type. - All context has a *DataType*; incoming and outgoing - context is represented by *EventField* concepts and - all other context is represented by *ContextItem* - concepts. - -Concept: Event -############## - - .. container:: paragraph - - An *Event* defines the structure of a message that - passes into or out of an APEX engine or that passes - between two states in an APEX engine. APEX supports - message reception and sending in many formats and all - messages are translated into an *Event* prior to - processing by an APEX engine. Event concepts are keyed - with an ``ArtifactKey`` key. The parameters of an - event are held as a map of *EventField* concept - instances with each parameter indexed by the - *LocalName* of its ``ReferenceKey``. An *Event* has - three fields: - - .. container:: ulist - - - The *NameSpace* identifies the domain of - application of the event - - - The *Source* of the event identifies the system - that emitted the event - - - The *Target* of the event identifies the system - that the event was sent to - - .. container:: paragraph - - A *PolicyModel* contains a map of all the events known - to a given policy model. Although an empty model may - have no events in its event map, any sane policy model - must have at least one *Event* defined. - -Concept: EventField -################### - - .. container:: paragraph - - The incoming context and outgoing context of an event - are the fields of the event. Each field representing a - single piece of incoming or outgoing context. Each - field of an *Event* is represented by an instance of - the *EventField* concept. Each *EventField* concept - instance in an event is keyed with a ``ReferenceKey`` - key, which references the event. The *LocalName* field - of the ``ReferenceKey`` holds the name of the field A - reference to a *DataType* concept defines the data - type that values of this parameter have at run time. - -Concept: ContextMap -################### - - .. container:: paragraph - - The set of context that is available for use by the - policies of a *PolicyModel* is defined as *ContextMap* - concept instances. The *PolicyModel* holds a map of - all the *ContextMap* definitions. A *ContextMap* is - itself a container for a group of related context - items, each of which is represented by a *ContextItem* - concept instance. *ContextMap* concepts are keyed with - an ``ArtifactKey`` key. A developer can use the APEX - Policy Editor to create context maps for their - application domain. - - .. container:: paragraph - - A *ContextMap* uses a map to hold the context items. - The ContextItem concept instances in the map are - indexed by the *LocalName* of their ``ReferenceKey``. - - .. container:: paragraph - - The *ContextMapType* field of a *ContextMap* defines - the type of a context map. The type can have either of - two values: - - .. container:: ulist - - - A *BAG* context map is a context map with fixed - content. Each possible context item in the context - map is defined at design time and is held in the - *ContextMap* context instance as *ContextItem* - concept definitions and only the values of the - context items in the context map can be changed at - run time. The context items in a *BAG* context map - have mixed types and distinct *ContextItem* concept - instances of the same type can be defined. A *BAG* - context map is convenient for defining a group of - context items that are diverse but are related by - domain, such as the characteristics of a device. A - fully defined *BAG* context map has a fully - populated *ContextItem* map but its - *ContextItemTemplate* reference is not defined. - - - A *SAMETYPE* context map is used to represent a - group of *ContextItem* instances of the same type. - Unlike a *BAG* context map, the *ContextItem* - concept instances of a *SAMETYPE* context map can - be added, modified, and deleted at runtime. All - *ContextItem* concept instances in a *SAMETYPE* - context map must be of the same type, and that - context item is defined as a single - *ContextItemTemplate* concept instances at design - time. At run time, the *ContextItemTemplate* - definition is used to create new *ContextItem* - concept instances for the context map on demand. A - fully defined *SAMETYPE context map has an empty - ContextItem map and its ContextItemTemplate\_* - reference is defined. - - .. container:: paragraph - - The *Scope* of a *ContextMap* defines the range of - applicability of a context map in APEX. The following - scopes of applicability are defined: - - .. container:: ulist - - - *EPHEMERAL* scope means that the context map is - owned, used, and modified by a single application, - but the context map only exists while that - application is running - - - *APPLICATION* scope specifies that the context map - is owned, used, and modified by a single - application, the context map is persistent - - - *GLOBAL* scope specifies that the context map is - globally owned and is used and modified by any - application, the context map is persistent - - - *EXTERNAL* scope specifies that the context map is - owned by an external system and may be used in a - read-only manner by any application, the context - map is persistent - - .. container:: paragraph - - A much more sophisticated scoping mechanism for - context maps is envisaged for Apex in future work. In - such a mechanism, the scope of a context map would - work somewhat like the way roles work in security - authentication systems. - -Concept: ContextItem -#################### - - .. container:: paragraph - - Each piece of context in a *ContextMap* is represented - by an instance of the *ContextItem* concept. Each - *ContextItem* concept instance in a context map keyed - with a ``ReferenceKey`` key, which references the - context map of the context item. The *LocalName* field - of the ``ReferenceKey`` holds the name of the context - item in the context map A reference to a *DataType* - concept defines the data type that values of this - context item have at run time. The *WritableFlag* - indicates if the context item is read only or - read-write at run time. - -Concept: ContextItemTemplate -############################ - - .. container:: paragraph - - In a *SAMETYPE* *ContextMap*, the - *ContextItemTemplate* definition provides a template - for the *ContextItem* instances that will be created - on the context map at run time. Each *ContextItem* - concept instance in the context map is created using - the *ContextItemTemplate* template. It is keyed with a - ``ReferenceKey`` key, which references the context map - of the context item. The *LocalName* field of the - ``ReferenceKey``, supplied by the creator of the - context item at run time, holds the name of the - context item in the context map. A reference to a - *DataType* concept defines the data type that values - of this context item have at run time. The - *WritableFlag* indicates if the context item is read - only or read-write at run time. - -Concept: Task -############# - - .. container:: paragraph - - The smallest unit of logic in a policy is a *Task*. A - task encapsulates a single atomic unit of logic, and - is designed to be a single indivisible unit of - execution. A task may be invoked by a single policy or - by many policies. A task has a single trigger event, - which is sent to the task when it is invoked. Tasks - emit one or more outgoing events, which carry the - result of the task execution. Tasks may use or modify - context as they execute. - - .. container:: paragraph - - The Task concept definition captures the definition of - an APEX task. Task concepts are keyed with an - ``ArtifactKey`` key. The Trigger of the task is a - reference to the *Event* concept that triggers the - task. The *OutgoingEvents* of a task are a set of - references to *Event* concepts that may be emitted by - the task. - - .. container:: paragraph - - All tasks have logic, some code that is programmed to - execute the work of the task. The *Logic* concept of - the task holds the definition of that logic. - - .. container:: paragraph - - The *Task* definition holds a set of *ContextItem* and - *ContextItemTemplate* context items that the task is - allow to access, as defined by the task developer at - design time. The type of access (read-only or read - write) that a task has is determined by the - *WritableFlag* flag on the individual context item - definitions. At run time, a task may only access the - context items specified in its context item set, the - APEX engine makes only the context items in the task - context item set is available to the task. - - .. container:: paragraph - - A task can be configured with startup parameters. The - set of parameters that can be configured on a task are - defined as a set of *TaskParameter* concept - definitions. - -Concept: TaskParameter -###################### - - .. container:: paragraph - - Each configuration parameter of a task are represented - as a *Taskparameter* concept keyed with a - ``ReferenceKey`` key, which references the task. The - *LocalName* field of the ``ReferenceKey`` holds the - name of the parameter. The *DefaultValue* field - defines the default value that the task parameter is - set to. The value of *TaskParameter* instances can be - overridden at deployment time by specifying their - values in the configuration information passed to APEX - engines. - -Concept: Logic -############## - - .. container:: paragraph - - The *Logic* concept instance holds the actual - programmed task logic for a task defined in a *Task* - concept or the programmed task selection logic for a - state defined in a *State* concept. It is keyed with a - ``ReferenceKey`` key, which references the task or - state that owns the logic. The *LocalName* field of - the Logic concept is the name of the logic. - - .. container:: paragraph - - The *LogicCode* field of a Logic concept definition is - a string that holds the program code that is to be - executed at run time. The *LogicType* field defines - the language of the code. The standard values are the - logic languages supported by APEX: - `JAVASCRIPT <https://en.wikipedia.org/wiki/JavaScript>`__, - `JAVA <https://java.com/en/>`__, - `JYTHON <http://www.jython.org/>`__, - `JRUBY <http://jruby.org/>`__, or - `MVEL <https://en.wikibooks.org/wiki/Transwiki:MVEL_Language_Guide>`__. - - .. container:: paragraph - - The APEX engine uses the *LogicType* field value to - decide which language interpreter to use for a task - and then sends the logic defined in the *LogicCode* - field to that interpreter. - -Concept: Policy -############### - - .. container:: paragraph - - The *Policy* concept defines a policy in APEX. The - definition is rather straightforward. A policy is made - up of a set of states with the flavor of the policy - determining the structure of the policy states and the - first state defining what state in the policy executes - first. *Policy* concepts are keyed with an - ``ArtifactKey`` key. - - .. container:: paragraph - - The *PolicyFlavour* of a *Policy* concept specifies - the structure that will be used for the states in the - policy. A number of commonly used policy patterns are - supported as APEX policy flavors. The standard policy - flavors are: - - .. container:: ulist - - - The *MEDA* flavor supports policies written to the - `MEDA policy - pattern <https://www.researchgate.net/publication/282576518_Dynamically_Adaptive_Policies_for_Dynamically_Adaptive_Telecommunications_Networks>`__ - and require a sequence of four states: namely - *Match*, *Establish*, *Decide* and *Act*. - - - The *OODA* flavor supports policies written to the - `OODA loop - pattern <https://en.wikipedia.org/wiki/OODA_loop>`__ - and require a sequence of four states: namely - *Observe*, *Orient*, *Decide* and *Act*. - - - The *ECA* flavor supports policies written to the - `ECA active rule - pattern <https://en.wikipedia.org/wiki/Event_condition_action>`__ - and require a sequence of three states: namely - *Event*, *Condition* and *Action* - - - The *XACML* flavor supports policies written in - `XACML <https://en.wikipedia.org/wiki/XACML>`__ and - require a single state: namely *XACML* - - - The *FREEFORM* flavor supports policies written in - an arbitrary style. A user can define a *FREEFORM* - policy as an arbitrarily long chain of states. - - .. container:: paragraph - - The *FirstState* field of a *Policy* definition is the - starting point for execution of a policy. Therefore, - the trigger event of the state referenced in the - *FirstState* field is also the trigger event for the - entire policy. - -Concept: State -############## - - .. container:: paragraph - - The *State* concept represents a phase or a stage in a - policy, with a policy being composed of a series of - states. Each state has at least one but may have many - tasks and, on each run of execution, a state executes - one and only one of its tasks. If a state has more - than one task, then its task selection logic is used - to select which task to execute. Task selection logic - is programmable logic provided by the state designer. - That logic can use incoming, policy, global, and - external context to select which task best - accomplishes the purpose of the state in a give - situation if more than one task has been specified on - a state. A state calls one and only one task when it - is executed. - - .. container:: paragraph - - Each state is triggered by an event, which means that - all tasks of a state must also be triggered by that - same event. The set of output events for a state is - the union of all output events from all tasks for that - task. In practice at the moment, because a state can - only have a single input event, a state that is not - the final state of a policy may only output a single - event and all tasks of that state may also only output - that single event. In future work, the concept of - having a less restrictive trigger pattern will be - examined. - - .. container:: paragraph - - A *State* concept is keyed with a ``ReferenceKey`` - key, which references the *Policy* concept that owns - the state. The *LocalName* field of the - ``ReferenceKey`` holds the name of the state. As a - state is part of a chain of states, the *NextState* - field of a state holds the ``ReferenceKey`` key of the - state in the policy to execute after this state. - - .. container:: paragraph - - The *Trigger* field of a state holds the - ``ArtifactKey`` of the event that triggers this state. - The *OutgoingEvents* field holds the ``ArtifactKey`` - references of all possible events that may be output - from the state. This is a set that is the union of all - output events of all tasks of the state. - - .. container:: paragraph - - The *Task* concepts that hold the definitions of the - task for the state are held as a set of - ``ArtifactKey`` references in the state. The - *DefaultTask* field holds a reference to the default - task for the state, a task that is executed if no task - selection logic is specified. If the state has only - one task, that task is the default task. - - .. container:: paragraph - - The *Logic* concept referenced by a state holds the - task selection logic for a state. The task selection - logic uses the incoming context (parameters of the - incoming event) and other context to determine the - best task to use to execute its goals. The state holds - a set of references to *ContextItem* and - *ContextItemTemplate* definitions for the context used - by its task selection logic. - -Writing Logic -^^^^^^^^^^^^^ - -Writing APEX Task Logic ------------------------ - - .. container:: paragraph - - Task logic specifies the behavior of an Apex Task. This - logic can be specified in a number of ways, exploiting - Apex’s plug-in architecture to support a range of logic - executors. In Apex scripted Task Logic can be written in - any of these languages: - - .. container:: ulist - - - ```MVEL`` <https://en.wikipedia.org/wiki/MVEL>`__, - - - ```JavaScript`` <https://en.wikipedia.org/wiki/JavaScript>`__, - - - ```JRuby`` <https://en.wikipedia.org/wiki/JRuby>`__ or - - - ```Jython`` <https://en.wikipedia.org/wiki/Jython>`__. - - .. container:: paragraph - - These languages were chosen because the scripts can be - compiled into Java bytecode at runtime and then - efficiently executed natively in the JVM. Task Logic an - also be written directly in Java but needs to be - compiled, with the resulting classes added to the - classpath. There are also a number of other Task Logic - types (e.g. Fuzzy Logic), but these are not supported as - yet. This guide will focus on the scripted Task Logic - approaches, with MVEL and JavaScript being our favorite - languages. In particular this guide will focus on the - Apex aspects of the scripts. However, this guide does not - attempt to teach you about the scripting languages - themselves … that is up to you! - - .. tip:: - JVM-based scripting languages - For more more information on scripting for the Java platform see: https://docs.oracle.com/javase/8/docs/technotes/guides/scripting/prog_guide/index.html - - .. note:: - 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 of the steps in - an Apex Policy. Each task receives some *incoming fields*, executes some logic (e.g: make a decision based on - *shared state* or *context*, *incoming fields*, *external context*, etc.), perhaps set some *shared state* or - *context* and then emits *outgoing fields*. The state that uses the task is responsible for extracting the - *incoming fields* from the state input event. The state also has an *output mapper* associated with the task, and - this *output mapper* is responsible for mapping the *outgoing fields* from the task into an appropriate - output event for the state. - - .. container:: paragraph - - First lets start with a sample task, drawn from the "My - First Apex Policy" example: The task "MorningBoozeCheck" - from the "My First Apex Policy" example is available in - both MVEL and JavaScript: - - .. container:: listingblock - - .. container:: title - - Javascript code for the ``MorningBoozeCheck`` task - - .. container:: content - - .. code:: javascript - :number-lines: - - /* - * ============LICENSE_START======================================================= - * Copyright (C) 2016-2018 Ericsson. All rights reserved. - * ================================================================================ - * Licensed under the Apache License, Version 2.0 (the "License"); - * you may not use this file except in compliance with the License. - * You may obtain a copy of the License at - * - * http://www.apache.org/licenses/LICENSE-2.0 - * - * Unless required by applicable law or agreed to in writing, software - * distributed under the License is distributed on an "AS IS" BASIS, - * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. - * See the License for the specific language governing permissions and - * limitations under the License. - * - * SPDX-License-Identifier: Apache-2.0 - * ============LICENSE_END========================================================= - */ - - var returnValueType = Java.type("java.lang.Boolean"); - var returnValue = new returnValueType(true); - - // Load compatibility script for imports etc - load("nashorn:mozilla_compat.js"); - importPackage(java.text); - importClass(java.text.SimpleDateFormat); - - executor.logger.info("Task Execution: '"+executor.subject.id+"'. Input Fields: '"+executor.inFields+"'"); - - executor.outFields.put("amount" , executor.inFields.get("amount")); - executor.outFields.put("assistant_ID", executor.inFields.get("assistant_ID")); - executor.outFields.put("notes" , executor.inFields.get("notes")); - executor.outFields.put("quantity" , executor.inFields.get("quantity")); - executor.outFields.put("branch_ID" , executor.inFields.get("branch_ID")); - executor.outFields.put("item_ID" , executor.inFields.get("item_ID")); - executor.outFields.put("time" , executor.inFields.get("time")); - executor.outFields.put("sale_ID" , executor.inFields.get("sale_ID")); - - item_id = executor.inFields.get("item_ID"); - - //All times in this script are in GMT/UTC since the policy and events assume time is in GMT. - var timenow_gmt = new Date(Number(executor.inFields.get("time"))); - - var midnight_gmt = new Date(Number(executor.inFields.get("time"))); - midnight_gmt.setUTCHours(0,0,0,0); - - var eleven30_gmt = new Date(Number(executor.inFields.get("time"))); - eleven30_gmt.setUTCHours(11,30,0,0); - - var timeformatter = new java.text.SimpleDateFormat("HH:mm:ss z"); - - var itemisalcohol = false; - if(item_id != null && item_id >=1000 && item_id < 2000) - itemisalcohol = true; - - if( itemisalcohol - && timenow_gmt.getTime() >= midnight_gmt.getTime() - && timenow_gmt.getTime() < eleven30_gmt.getTime()) { - - executor.outFields.put("authorised", false); - executor.outFields.put("message", "Sale not authorised by policy task " + - executor.subject.taskName+ " for time " + timeformatter.format(timenow_gmt.getTime()) + - ". Alcohol can not be sold between " + timeformatter.format(midnight_gmt.getTime()) + - " and " + timeformatter.format(eleven30_gmt.getTime())); - } - else{ - executor.outFields.put("authorised", true); - executor.outFields.put("message", "Sale authorised by policy task " + - executor.subject.taskName + " for time "+timeformatter.format(timenow_gmt.getTime())); - } - - /* - This task checks if a sale request is for an item that is an alcoholic drink. - If the local time is between 00:00:00 GMT and 11:30:00 GMT then the sale is not - authorised. Otherwise the sale is authorised. - In this implementation we assume that items with item_ID value between 1000 and - 2000 are all alcoholic drinks :-) - */ - - .. container:: listingblock - - .. container:: title - - MVEL code for the ``MorningBoozeCheck`` task - - .. container:: content - - .. code:: javascript - :number-lines: - - /* - * ============LICENSE_START======================================================= - * Copyright (C) 2016-2018 Ericsson. All rights reserved. - * ================================================================================ - * Licensed under the Apache License, Version 2.0 (the "License"); - * you may not use this file except in compliance with the License. - * You may obtain a copy of the License at - * - * http://www.apache.org/licenses/LICENSE-2.0 - * - * Unless required by applicable law or agreed to in writing, software - * distributed under the License is distributed on an "AS IS" BASIS, - * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. - * See the License for the specific language governing permissions and - * limitations under the License. - * - * SPDX-License-Identifier: Apache-2.0 - * ============LICENSE_END========================================================= - */ - import java.util.Date; - import java.util.Calendar; - import java.util.TimeZone; - import java.text.SimpleDateFormat; - - logger.info("Task Execution: '"+subject.id+"'. Input Fields: '"+inFields+"'"); - - outFields.put("amount" , inFields.get("amount")); - outFields.put("assistant_ID", inFields.get("assistant_ID")); - outFields.put("notes" , inFields.get("notes")); - outFields.put("quantity" , inFields.get("quantity")); - outFields.put("branch_ID" , inFields.get("branch_ID")); - outFields.put("item_ID" , inFields.get("item_ID")); - outFields.put("time" , inFields.get("time")); - outFields.put("sale_ID" , inFields.get("sale_ID")); - - item_id = inFields.get("item_ID"); - - //The events used later to test this task use GMT timezone! - gmt = TimeZone.getTimeZone("GMT"); - timenow = Calendar.getInstance(gmt); - df = new SimpleDateFormat("HH:mm:ss z"); - df.setTimeZone(gmt); - timenow.setTimeInMillis(inFields.get("time")); - - midnight = timenow.clone(); - midnight.set( - timenow.get(Calendar.YEAR),timenow.get(Calendar.MONTH), - timenow.get(Calendar.DATE),0,0,0); - eleven30 = timenow.clone(); - eleven30.set( - timenow.get(Calendar.YEAR),timenow.get(Calendar.MONTH), - timenow.get(Calendar.DATE),11,30,0); - - itemisalcohol = false; - if(item_id != null && item_id >=1000 && item_id < 2000) - itemisalcohol = true; - - if( itemisalcohol - && timenow.after(midnight) && timenow.before(eleven30)){ - outFields.put("authorised", false); - outFields.put("message", "Sale not authorised by policy task "+subject.taskName+ - " for time "+df.format(timenow.getTime())+ - ". Alcohol can not be sold between "+df.format(midnight.getTime())+ - " and "+df.format(eleven30.getTime())); - return true; - } - else{ - outFields.put("authorised", true); - outFields.put("message", "Sale authorised by policy task "+subject.taskName+ - " for time "+df.format(timenow.getTime())); - return true; - } - - /* - This task checks if a sale request is for an item that is an alcoholic drink. - If the local time is between 00:00:00 GMT and 11:30:00 GMT then the sale is not - authorised. Otherwise the sale is authorised. - In this implementation we assume that items with item_ID value between 1000 and - 2000 are all alcoholic drinks :-) - */ - - .. container:: paragraph - - The role of the task in this simple example is to copy - the values in the incoming fields into the outgoing - fields, then examine the values in some incoming fields - (``item_id`` and ``time``), then set the values in some - other outgoing fields (``authorised`` and ``message``). - - .. container:: paragraph - - Both MVEL and JavaScript like most JVM-based scripting - languages can use standard Java libraries to perform - complex tasks. Towards the top of the scripts you will - see how to import Java classes and packages to be used - directly in the logic. Another thing to notice is that - Task Logic should return a ``java.lang.Boolean`` value - ``true`` if the logic executed correctly. If the logic - fails for some reason then ``false`` can be returned, but - this will cause the policy invoking this task will fail - and exit. - - .. note:: - How to return a value from task logic - Some languages explicitly support returning values from the script (e.g. MVEL and JRuby) using an explicit - return statement (e.g. ``return true``), other languages do not (e.g. JavaScript and Jython). For - languages that do not support the ``return`` statement, a special field called ``returnValue`` must be - created to hold the result of the task logic operation (i.e. assign a ``java.lang.Boolean`` - value to the ``returnValue`` field before completing the task). - Also, in MVEL if there is no explicit return statement then the return value of the last executed statement will return - (e.g. the statement a=(1+2) will return the value 3). - - .. container:: paragraph - - Besides these imported classes and normal language - features Apex provides some natively available parameters - and functions that can be used directly. At run-time - these parameters are populated by the Apex execution - environment and made natively available to logic scripts - each time the logic script is invoked. (These can be - accessed using the ``executor`` keyword for most - languages, or can be accessed directly without the - ``executor`` keyword in MVEL): - - Table 1. The ``executor`` Fields / Methods - -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| Name | Type | Java type | Description | -+============+=============+================================+=====================================================================================+ -| inFields | Fields | java.util.Map <String,Object> | .. container:: paragraph | -| | | | | -| | | | The incoming task fields. This is implemented as a standard Java | -| | | | Java (unmodifiable) Map | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.logger.debug("Incoming fields: " | -| | | | +executor.inFields.entrySet()); | -| | | | var item_id = executor.incomingFields["item_ID"]; | -| | | | if (item_id >=1000) { ... } | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| outFields | Fields | java.util.Map <String,Object> | .. container:: paragraph | -| | | | | -| | | | The outgoing task fields. This is implemented as a standard initially empty Java | -| | | | (modifiable) Map. To create a new schema-compliant instance of a field object | -| | | | see the utility method subject.getOutFieldSchemaHelper() below | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.outFields["authorised"] = false; | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| logger | Logger | org.slf4j.ext.XLogger | .. container:: paragraph | -| | | | | -| | | | A helpful logger | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.logger.info("Executing task: " | -| | | | +executor.subject.id); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| TRUE/FALSE | boolean | java.lang.Boolean | .. container:: paragraph | -| | | | | -| | | | 2 helpful constants. These are useful to retrieve correct return values for the | -| | | | task logic | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | var returnValue = executor.isTrue; | -| | | | var returnValueType = Java.type("java.lang.Boolean"); | -| | | | var returnValue = new returnValueType(true); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| subject | Task | TaskFacade | .. container:: paragraph | -| | | | | -| | | | This provides some useful information about the task that contains this task | -| | | | logic. This object has some useful fields and methods : | -| | | | | -| | | | .. container:: ulist | -| | | | | -| | | | - **AxTask task** to get access to the full task definition of | -| | | | the host task | -| | | | | -| | | | - **String getTaskName()** to get the name of the host task | -| | | | | -| | | | - **String getId()** to get the ID of the host task | -| | | | | -| | | | - **SchemaHelper getInFieldSchemaHelper( String fieldName )** to | -| | | | get a ``SchemaHelper`` helper object to manipulate incoming | -| | | | task fields in a schema-aware manner | -| | | | | -| | | | - **SchemaHelper getOutFieldSchemaHelper( String fieldName )** to | -| | | | get a ``SchemaHelper`` helper object to manipulate outgoing | -| | | | task fields in a schema-aware manner, e.g. to instantiate new | -| | | | schema-compliant field objects to populate the | -| | | | ``executor.outFields`` outgoing fields map | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.logger.info("Task name: " | -| | | | +executor.subject.getTaskName()); | -| | | | executor.logger.info("Task id: " | -| | | | +executor.subject.getId()); | -| | | | executor.logger.info("Task inputs definitions: " | -| | | | +"executor.subject.task.getInputFieldSet()); | -| | | | executor.logger.info("Task outputs definitions: " | -| | | | +"executor.subject.task.getOutputFieldSet()); | -| | | | executor.outFields["authorised"] = executor.subject | -| | | | .getOutFieldSchemaHelper("authorised") | -| | | | .createNewInstance("false"); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| ContextAlbum getContextAlbum(String ctxtAlbumName ) | .. container:: paragraph | -| | | -| | A utility method to retrieve a ``ContextAlbum`` for use in the task. | -| | This is how you access the context used by the task. The returned | -| | ``ContextAlbum`` implements the ``java.util.Map <String,Object>`` | -| | interface to get and set context as appropriate. The returned | -| | ``ContextAlbum`` also has methods to lock context albums, get | -| | information about the schema of the items to be stored in a context | -| | album, and get a ``SchemaHelper`` to manipulate context album items. How | -| | to define and use context in a task is described in the Apex | -| | Programmer’s Guide and in the My First Apex Policy guide. | -| | | -| | .. container:: | -| | | -| | .. container:: content | -| | | -| | .. container:: paragraph | -| | | -| | **Example:** | -| | | -| | .. code:: javascript | -| | | -| | var bkey = executor.inFields.get("branch_ID"); | -| | var cnts = executor.getContextMap("BranchCounts"); | -| | cnts.lockForWriting(bkey); | -| | cnts.put(bkey, cnts.get(bkey) + 1); | -| | cnts.unlockForWriting(bkey); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ - -Writing APEX Task Selection Logic ---------------------------------- - - .. container:: paragraph - - The function of Task Selection Logic is to choose which task - should be executed for an Apex State as one of the steps in an - Apex Policy. Since each state must define a default task there is - no need for Task Selection Logic unless the state uses more than - one task. This logic can be specified in a number of ways, - exploiting Apex’s plug-in architecture to support a range of logic - executors. In Apex scripted Task Selection Logic can be written in - any of these languages: - - .. container:: ulist - - - ```MVEL`` <https://en.wikipedia.org/wiki/MVEL>`__, - - - ```JavaScript`` <https://en.wikipedia.org/wiki/JavaScript>`__, - - - ```JRuby`` <https://en.wikipedia.org/wiki/JRuby>`__ or - - - ```Jython`` <https://en.wikipedia.org/wiki/Jython>`__. - - .. container:: paragraph - - These languages were chosen because the scripts can be compiled - into Java bytecode at runtime and then efficiently executed - natively in the JVM. Task Selection Logic an also be written - directly in Java but needs to be compiled, with the resulting - classes added to the classpath. There are also a number of other - Task Selection Logic types but these are not supported as yet. - This guide will focus on the scripted Task Selection Logic - approaches, with MVEL and JavaScript being our favorite languages. - In particular this guide will focus on the Apex aspects of the - scripts. However, this guide does not attempt to teach you about - the scripting languages themselves … that is up to you! - - .. tip:: - JVM-based scripting languages - For more more information on Scripting for the Java platform see: - https://docs.oracle.com/javase/8/docs/technotes/guides/scripting/prog_guide/index.html - - .. note:: - What does Task Selection Logic do? - When an Apex state references multiple tasks, there must be a way to dynamically decide - which task should be chosen and executed. This can depend on the many factors, e.g. the - *incoming event for the state*, *shared state* or *context*, *external context*, - etc.. This is the function of a state’s Task Selection Logic. Obviously, if there is - only one task then Task only one task then Task Selection Logic is not needed. - Each state must also select one of the tasks a the *default state*. If the Task - Selection Logic is unable to select an appropriate task, then it should select the - *default task*. Once the task has been selected the Apex Engine will then execute that - task. - - .. container:: paragraph - - First lets start with some simple Task Selection Logic, drawn from - the "My First Apex Policy" example: The Task Selection Logic from - the "My First Apex Policy" example is specified in JavaScript - here: - - .. container:: listingblock - - .. container:: title - - Javascript code for the "My First Policy" Task Selection Logic - - .. container:: content - - .. code:: javascript - - /* - * ============LICENSE_START======================================================= - * Copyright (C) 2016-2018 Ericsson. All rights reserved. - * ================================================================================ - * Licensed under the Apache License, Version 2.0 (the "License"); - * you may not use this file except in compliance with the License. - * You may obtain a copy of the License at - * - * http://www.apache.org/licenses/LICENSE-2.0 - * - * Unless required by applicable law or agreed to in writing, software - * distributed under the License is distributed on an "AS IS" BASIS, - * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. - * See the License for the specific language governing permissions and - * limitations under the License. - * - * SPDX-License-Identifier: Apache-2.0 - * ============LICENSE_END========================================================= - */ - - - var returnValueType = Java.type("java.lang.Boolean"); - var returnValue = new returnValueType(true); - - executor.logger.info("Task Selection Execution: '"+executor.subject.id+ - "'. Input Event: '"+executor.inFields+"'"); - - branchid = executor.inFields.get("branch_ID"); - taskorig = executor.subject.getTaskKey("MorningBoozeCheck"); - taskalt = executor.subject.getTaskKey("MorningBoozeCheckAlt1"); - taskdef = executor.subject.getDefaultTaskKey(); - - if(branchid >=0 && branchid <1000){ - taskorig.copyTo(executor.selectedTask); - } - else if (branchid >=1000 && branchid <2000){ - taskalt.copyTo(executor.selectedTask); - } - else{ - taskdef.copyTo(executor.selectedTask); - } - - /* - This task selection logic selects task "MorningBoozeCheck" for branches with - 0<=branch_ID<1000 and selects task "MorningBoozeCheckAlt1" for branches with - 1000<=branch_ID<2000. Otherwise the default task is selected. - In this case the default task is also "MorningBoozeCheck" - */ - - .. container:: paragraph - - The role of the Task Selection Logic in this simple example is to - examine the value in one incoming field (``branchid``), then - depending on that field’s value set the value for the selected - task to the appropriate task (``MorningBoozeCheck``, - ``MorningBoozeCheckAlt1``, or the default task). - - .. container:: paragraph - - Another thing to notice is that Task Selection Logic should return - a ``java.lang.Boolean`` value ``true`` if the logic executed - correctly. If the logic fails for some reason then ``false`` can - be returned, but this will cause the policy invoking this task - will fail and exit. - - .. note:: - How to return a value from Task Selection Logic - Some languages explicitly support returning values from the script (e.g. MVEL and - JRuby) using an explicit return statement (e.g. ``return true``), other languages do not (e.g. - JavaScript and Jython). For languages that do not support the ``return`` statement, a special field called - ``returnValue`` must be created to hold the result of the task logic operation (i.e. assign a ``java.lang.Boolean`` - value to the ``returnValue`` field before completing the task). - Also, in MVEL if there is not explicit return statement then the return value of the last executed statement will - return (e.g. the statement a=(1+2) will return the value 3). - - .. container:: paragraph - - Each of the scripting languages used in Apex can import and use - standard Java libraries to perform complex tasks. Besides imported - classes and normal language features Apex provides some natively - available parameters and functions that can be used directly. At - run-time these parameters are populated by the Apex execution - environment and made natively available to logic scripts each time - the logic script is invoked. (These can be accessed using the - ``executor`` keyword for most languages, or can be accessed - directly without the ``executor`` keyword in MVEL): - - Table 2. The ``executor`` Fields / Methods - +-------------------------------------------------------+--------------------------------------------------------+ - | Unix, Cygwin | Windows | - +=======================================================+========================================================+ - | .. container:: | .. container:: | - | | | - | .. container:: content | .. container:: content | - | | | - | .. code:: bash | .. code:: bash | - | :number-lines: | :number-lines: | - | | | - | >c: | # cd /usr/local/src/apex-pdp | - | >cd \dev\apex | # mvn clean install -DskipTest | - | >mvn clean install -DskipTests | | - +-------------------------------------------------------+--------------------------------------------------------+ - -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| Name | Type | Java type | Description | -+============+=============+================================+=====================================================================================+ -| inFields | Fields | java.util.Map <String,Object> | .. container:: paragraph | -| | | | | -| | | | All fields in the state’s incoming event. This is implemented as a standard Java | -| | | | Java (unmodifiable) Map | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.logger.debug("Incoming fields: " | -| | | | +executor.inFields.entrySet()); | -| | | | var item_id = executor.incomingFields["item_ID"]; | -| | | | if (item_id >=1000) { ... } | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| outFields | Fields | java.util.Map <String,Object> | .. container:: paragraph | -| | | | | -| | | | The outgoing task fields. This is implemented as a standard initially empty Java | -| | | | (modifiable) Map. To create a new schema-compliant instance of a field object | -| | | | see the utility method subject.getOutFieldSchemaHelper() below | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.outFields["authorised"] = false; | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| logger | Logger | org.slf4j.ext.XLogger | .. container:: paragraph | -| | | | | -| | | | A helpful logger | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.logger.info("Executing task: " | -| | | | +executor.subject.id); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| TRUE/FALSE | boolean | java.lang.Boolean | .. container:: paragraph | -| | | | | -| | | | 2 helpful constants. These are useful to retrieve correct return values for the | -| | | | task logic | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | var returnValue = executor.isTrue; | -| | | | var returnValueType = Java.type("java.lang.Boolean"); | -| | | | var returnValue = new returnValueType(true); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| subject | Task | TaskFacade | .. container:: paragraph | -| | | | | -| | | | This provides some useful information about the task that contains this task | -| | | | logic. This object has some useful fields and methods : | -| | | | | -| | | | .. container:: ulist | -| | | | | -| | | | - **AxTask task** to get access to the full task definition of | -| | | | the host task | -| | | | | -| | | | - **String getTaskName()** to get the name of the host task | -| | | | | -| | | | - **String getId()** to get the ID of the host task | -| | | | | -| | | | - **SchemaHelper getInFieldSchemaHelper( String fieldName )** to | -| | | | get a ``SchemaHelper`` helper object to manipulate incoming | -| | | | task fields in a schema-aware manner | -| | | | | -| | | | - **SchemaHelper getOutFieldSchemaHelper( String fieldName )** to | -| | | | get a ``SchemaHelper`` helper object to manipulate outgoing | -| | | | task fields in a schema-aware manner, e.g. to instantiate new | -| | | | schema-compliant field objects to populate the | -| | | | ``executor.outFields`` outgoing fields map | -| | | | | -| | | | .. container:: | -| | | | | -| | | | .. container:: content | -| | | | | -| | | | .. container:: paragraph | -| | | | | -| | | | **Example:** | -| | | | | -| | | | .. code:: javascript | -| | | | | -| | | | executor.logger.info("Task name: " | -| | | | +executor.subject.getTaskName()); | -| | | | executor.logger.info("Task id: " | -| | | | +executor.subject.getId()); | -| | | | executor.logger.info("Task inputs definitions: " | -| | | | +"executor.subject.task.getInputFieldSet()); | -| | | | executor.logger.info("Task outputs definitions: " | -| | | | +"executor.subject.task.getOutputFieldSet()); | -| | | | executor.outFields["authorised"] = executor.subject | -| | | | .getOutFieldSchemaHelper("authorised") | -| | | | .createNewInstance("false"); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ -| ContextAlbum getContextAlbum(String ctxtAlbumName ) | .. container:: paragraph | -| | | -| | A utility method to retrieve a ``ContextAlbum`` for use in the task. | -| | This is how you access the context used by the task. The returned | -| | ``ContextAlbum`` implements the ``java.util.Map <String,Object>`` | -| | interface to get and set context as appropriate. The returned | -| | ``ContextAlbum`` also has methods to lock context albums, get | -| | information about the schema of the items to be stored in a context | -| | album, and get a ``SchemaHelper`` to manipulate context album items. How | -| | to define and use context in a task is described in the Apex | -| | Programmer’s Guide and in the My First Apex Policy guide. | -| | | -| | .. container:: | -| | | -| | .. container:: content | -| | | -| | .. container:: paragraph | -| | | -| | **Example:** | -| | | -| | .. code:: javascript | -| | | -| | var bkey = executor.inFields.get("branch_ID"); | -| | var cnts = executor.getContextMap("BranchCounts"); | -| | cnts.lockForWriting(bkey); | -| | cnts.put(bkey, cnts.get(bkey) + 1); | -| | cnts.unlockForWriting(bkey); | -+------------+-------------+--------------------------------+-------------------------------------------------------------------------------------+ - -Logic Cheatsheet ----------------- - - .. container:: paragraph - - Examples given here use Javascript (if not stated otherwise), - other execution environments will be similar. - -Add Nashorn -########### - - .. container:: paragraph - - First line in the logic use this import. - - .. container:: listingblock - - .. container:: title - - JS Nashorn - - .. container:: content - - .. code:: javascript - - load("nashorn:mozilla_compat.js"); - -Finish Logic with Success or Error -################################## - - .. container:: paragraph - - To finish logic, i.e. return to APEX, with success use the - following lines close to the end of the logic. - - .. container:: listingblock - - .. container:: title - - JS Success - - .. container:: content - - .. code:: javascript - - var returnValueType = Java.type("java.lang.Boolean"); - var returnValue = new returnValueType(true); - - .. container:: paragraph - - To notify a problem, finish with an error. - - .. container:: listingblock - - .. container:: title - - JS Fail - - .. container:: content - - .. code:: javascript - - var returnValueType = Java.type("java.lang.Boolean"); - var returnValue = new returnValueType(false); - -Logic Logging -############# - - .. container:: paragraph - - Logging can be made easy using a local variable for the logger. - Line 1 below does that. Then we start with a trace log with the - task (or task logic) identifier followed by the infields. - - .. container:: listingblock - - .. container:: title - - JS Logging - - .. container:: content - - .. code:: javascript - - var logger = executor.logger; - logger.trace("start: " + executor.subject.id); - logger.trace("-- infields: " + executor.inFields); - - .. container:: paragraph - - For larger logging blocks you can use the standard logging API - to detect log levels, for instance: - - .. container:: listingblock - - .. container:: title - - JS Logging Blocks - - .. container:: content - - .. code:: javascript - - if(logger.isTraceEnabled()){ - // trace logging block here - } - - .. container:: paragraph - - Note: the shown logger here logs to - ``org.onap.policy.apex.executionlogging``. The behavior of the - actual logging can be specified in the - ``$APEX_HOME/etc/logback.xml``. - - .. container:: paragraph - - If you want to log into the APEX root logger (which is - sometimes necessary to report serious logic errors to the top), - then import the required class and use this logger. - - .. container:: listingblock - - .. container:: title - - JS Root Logger - - .. container:: content - - .. code:: javascript - - importClass(org.slf4j.LoggerFactory); - var rootLogger = LoggerFactory.getLogger(logger.ROOT_LOGGER_NAME); - - rootLogger.error("Serious error in logic detected: " + executor.subject.id); - -Local Variable for Infields -########################### - - .. container:: paragraph - - It is a good idea to use local variables for ``infields``. This - avoids long code lines and policy evolution. The following - example assumes infields named ``nodeName`` and ``nodeAlias``. - - .. container:: listingblock - - .. container:: title - - JS Infields Local Var - - .. container:: content - - .. code:: javascript - - var ifNodeName = executor.inFields["nodeName"]; - var ifNodeAlias = executor.inFields["nodeAlias"]; - -Local Variable for Context Albums -################################# - - .. container:: paragraph - - Similar to the ``infields`` it is good practice to use local - variables for context albums as well. The following example - assumes that a task can access a context album - ``albumTopoNodes``. The second line gets a particular node from - this context album. - - .. container:: listingblock - - .. container:: title - - JS Infields Local Var - - .. container:: content - - .. code:: javascript - - var albumTopoNodes = executor.getContextAlbum("albumTopoNodes"); - var ctxtNode = albumTopoNodes.get(ifNodeName); - -Set Outfields in Logic -###################### - - .. container:: paragraph - - The task logic needs to set outfields with content generated. - The exception are outfields that are a direct copy from an - infield of the same name, APEX does that autmatically. - - .. container:: listingblock - - .. container:: title - - JS Set Outfields - - .. container:: content - - .. code:: javascript - - executor.outFields["report"] = "node ctxt :: added node " + ifNodeName; - -Create a instance of an Outfield using Schemas -############################################## - - .. container:: paragraph - - If an outfield is not an atomic type (string, integer, etc.) - but uses a complex schema (with a Java or Avro backend), APEX - can help to create new instances. The ``executor`` provides a - field called ``subject``, which provides a schem helper with an - API for this. The complete API of the schema helper is - documented here: `API Doc: - SchemaHelper <https://ericsson.github.io/apex-docs/javadocs/index.html>`__. - - .. container:: paragraph - - If the backend is Avro, then an import of the Avro schema - library is required: - - .. container:: listingblock - - .. container:: title - - JS Import Avro - - .. container:: content - - .. code:: javascript - - importClass(org.apache.avro.generic.GenericData.Array); - importClass(org.apache.avro.generic.GenericRecord); - importClass(org.apache.avro.Schema); - - .. container:: paragraph - - If the backend is Java, then the Java class implementing the - schema needs to be imported. - - .. container:: paragraph - - The following example assumes an outfield ``situation``. The - ``subject`` method ``getOutFieldSchemaHelper()`` is used to - create a new instance. - - .. container:: listingblock - - .. container:: title - - JS Outfield Instance with Schema - - .. container:: content - - .. code:: javascript - - var situation = executor.subject.getOutFieldSchemaHelper("situation").createNewInstance(); - - .. container:: paragraph - - If the schema backend is Java, the new instance will be as - implemented in the Java class. If the schema backend is Avro, - the new instance will have all fields from the Avro schema - specification, but set to ``null``. So any entry here needs to - be done separately. For instance, the ``situation`` schema has - a field ``problemID`` which we set. - - .. container:: listingblock - - .. container:: title - - JS Outfield Instance with Schema, set - - .. container:: content - - .. code:: javascript - - situation.put("problemID", "my-problem"); - -Create a instance of an Context Album entry using Schemas -######################################################### - - .. container:: paragraph - - Context album instances can be created using very similar to - the outfields. Here, the schema helper comes from the context - album directly. The API of the schema helper is the same as for - outfields, see `API Doc: - SchemaHelper <https://ericsson.github.io/apex-docs/javadocs/index.html>`__. - - .. container:: paragraph - - If the backend is Avro, then an import of the Avro schema - library is required: - - .. container:: listingblock - - .. container:: title - - JS Import Avro - - .. container:: content - - .. code:: javascript - - importClass(org.apache.avro.generic.GenericData.Array); - importClass(org.apache.avro.generic.GenericRecord); - importClass(org.apache.avro.Schema); - - .. container:: paragraph - - If the backend is Java, then the Java class implementing the - schema needs to be imported. - - .. container:: paragraph - - The following example creates a new instance of a context album - instance named ``albumProblemMap``. - - .. container:: listingblock - - .. container:: title - - JS Outfield Instance with Schema - - .. container:: content - - .. code:: javascript - - var albumProblemMap = executor.getContextAlbum("albumProblemMap"); - var linkProblem = albumProblemMap.getSchemaHelper().createNewInstance(); - - .. container:: paragraph - - This can of course be also done in a single call without the - local variable for the context album. - - .. container:: listingblock - - .. container:: title - - JS Outfield Instance with Schema, one line - - .. container:: content - - .. code:: javascript - - var linkProblem = executor.getContextAlbum("albumProblemMap").getSchemaHelper().createNewInstance(); - - .. container:: paragraph - - If the schema backend is Java, the new instance will be as - implemented in the Java class. If the schema backend is Avro, - the new instance will have all fields from the Avro schema - specification, but set to ``null``. So any entry here needs to - be done separately (see above in outfields for an example). - -Enumerates -########## - - .. container:: paragraph - - When dealing with enumerates (Avro or Java defined), it is - sometimes and in some execution environments necessary to - convert them to a string. For example, assume an Avro enumerate - schema as: - - .. container:: listingblock - - .. container:: title - - Avro Enumerate Schema - - .. container:: content - - .. code:: javascript - - { - "type": "enum", - "name": "Status", - "symbols" : [ - "UP", - "DOWN" - ] - } - - .. container:: paragraph - - Using a switch over a field initialized with this enumerate in - Javascript will fail. Instead, use the ``toString`` method, for - example: - - .. container:: listingblock - - .. container:: title - - JS Outfield Instance with Schema, one line - - .. container:: content - - .. code:: javascript - - var switchTest = executor.inFields["status"]; - switch(switchTest.toString()){ - case "UP": ...; break; - case "DOWN": ...; break; - default: ...; - } - -MVEL Initialize Outfields First! -################################ - - .. container:: paragraph - - In MVEL, we observed a problem when accessing (setting) - outfields without a prior access to them. So in any MVEL task - logic, before setting any outfield, simply do a get (with any - string), to load the outfields into the MVEL cache. - - .. container:: listingblock - - .. container:: title - - MVEL Outfield Initialization - - .. container:: content - - .. code:: javascript - - outFields.get("initialize outfields"); - -Using Java in Scripting Logic -############################# - - .. container:: paragraph - - Since APEX executes the logic inside a JVM, most scripting - languages provide access to all standard Java classes. Simply - add an import for the required class and then use it as in - actual Java. - - .. container:: paragraph - - The following example imports ``java.util.arraylist`` into a - Javascript logic, and then creates a new list. - - .. container:: listingblock - - .. container:: title - - JS Import ArrayList - - .. container:: content - - .. code:: javascript - - importClass(java.util.ArrayList); - var myList = new ArrayList(); - -Policy Examples -^^^^^^^^^^^^^^^ - -My First Policy ---------------- - - .. container:: paragraph - - A good starting point is the ``My First Policy`` example. It - describes a sales problem, to which policy can be applied. - The example details the policy background, shows how to use - the REST Editor to create a policy, and provides details for - running the policies. The documentation can be found: - - .. container:: ulist - - - `My-First-Policy on the APEX - site <https://ericsson.github.io/apex-docs/modules/examples/examples-myfirstpolicy/MyFirstPolicyHowto.html>`__ - - - `Stand-alone - HTML <https://ericsson.github.io/apex-docs/docs-apex/html/HowTo-MyFirstPolicy.html>`__ - - - `Stand-alone - PDF <https://ericsson.github.io/apex-docs/docs-apex/pdf/HowTo-MyFirstPolicy.pdf>`__ - -VPN SLA -------- - - .. container:: paragraph - - The domain Policy-controlled Video Streaming (PCVS) contains - a policy for controlling video streams with different - strategies. It also provides details for installing an - actual testbed with off-the-shelve software (Mininet, - Floodlight, Kafka, Zookeeper). The policy model here - demonstrates virtually all APEX features: local context and - policies controlling it, task selection logic and multiple - tasks in a single state, AVRO schemas for context, AVOR - schemas for events (trigger and local), and a CLI editor - specification of the policy. The documentation can be found: - - .. container:: ulist - - - `VPN SLA Policy on the APEX - site <https://ericsson.github.io/apex-docs/modules/examples/examples-pcvs/vpnsla/policy.html>`__ - -Decision Maker --------------- - - .. container:: paragraph - - The domain Decision Maker shows a very simple policy for - decisions. Interesting here is that the it creates a Docker - image to run the policy and that it uses the APEX REST - applications to update the policy on the-fly. It also has - local context to remember past decisions, and shows how to - use that to no make the same decision twice in a row. The - documentation can be found: - - .. container:: ulist - - - `Decision Maker on APEX - site <https://ericsson.github.io/apex-docs/modules/examples/examples-decisionmaker/index.html>`__ - -.. container:: - :name: footer - - .. container:: - :name: footer-text - - 2.0.0-SNAPSHOT - Last updated 2018-09-04 16:04:24 IST - -.. |APEX Policy Matrix| image:: images/apex-intro/ApexPolicyMatrix.png -.. |APEX Policy Model for Execution| image:: images/apex-policy-model/UmlPolicyModels.png -.. |Concepts and Keys| image:: images/apex-policy-model/ConceptsKeys.png - |