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-//
-// ============LICENSE_START=======================================================
-//  Copyright (C) 2016-2018 Ericsson. All rights reserved.
-// ================================================================================
-// This file is licensed under the CREATIVE COMMONS ATTRIBUTION 4.0 INTERNATIONAL LICENSE
-// Full license text at https://creativecommons.org/licenses/by/4.0/legalcode
-// 
-// SPDX-License-Identifier: CC-BY-4.0
-// ============LICENSE_END=========================================================
-//
-// @author Sven van der Meer (sven.van.der.meer@ericsson.com)
-//
-
-== APEX Policy Matrix
-
-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.
-
-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.
-
-.APEX Policy Matrix
-image::apex-intro/ApexPolicyMatrix.png[APEX Policy Matrix]
-
-The policy can support one of a number of stimuli with an associated purpose/model of the policy, for instance:
-
-* 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.
-
-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:
-
-* 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)
-
-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:
-
-* 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.
-
-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:
-
-* 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)