Delay-Tolerant Networking | E. Birrane |
Internet-Draft | Johns Hopkins Applied Physics Laboratory |
Intended status: Informational | June 21, 2016 |
Expires: December 23, 2016 |
Asynchronous Management Architecture
draft-birrane-dtn-ama-03
This document describes the motivation, desirable properties, system model, roles/responsibilities, and component models associated with an asynchronous management architecture (AMA) suitable for providing application-level network management services in a challenged networking environment. Challenged networks are those that require fault protection, configuration, and performance reporting while unable to provide human-in-the-loop operations centers with synchronous feedback in the context of administrative sessions. In such a context, networks must exhibit behavior that is both determinable and autonomous while maintaining compatibility with existing network management protocols and operational concepts.
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This document presents an Asynchronous Management Architecture (AMA) providing application-layer network management services over links where delivery delays prevent timely communications between a network operator and a managed device. These delays may be caused by long signal propagations or frequent link disruptions (such as described in [RFC4838]) or by non-environmental factors such as unavailability of network operators, administrative delays, or delays caused by quality-of-service prioritizations and service-level agreements.
This document describes the motivation, rationale, desirable properties, and roles/responsibilities associated with an asynchronous management architecture (AMA) suitable for providing network management services in a challenged networking environment. These descriptions should be of sufficient specificity that an implementing Asynchronous Management Protocol (AMP) in conformance with this architecture will operate successfully in a challenged networking environment.
An AMA is necessary as the assumptions inherent to the architecture and design of synchronous management tools and techniques are not valid in challenged network scenarios. In these scenarios, synchronous approaches either patiently wait for periods of bi-directional connectivity or require the investment of significant time and resources to evolve a challenged network into a well-connected, low-latency network. In some cases such evolution is merely a costly way to over-resource a network. In other cases, such evolution is impossible given physical limitations imposed by signal propagation delays, power, transmission technologies, and other phenomena. Asynchronous management of asynchronous networks enables large-scale deployments, distributed technical capabilities, and reduced deployment and operations costs.
It is assumed that any challenged network where network management would be usefully applied supports basic services (where necessary) such as naming, addressing, integrity, confidentiality, authentication, fragmentation, and traditional network/session layer functions. Therefore, these items are outside of the scope of the AMA and not covered in this document.
While likely that a challenged network will eventually interface with an unchallenged network, this document does not address the concept of network management compatibility with synchronous approaches. An AMP in conformance with this architecture should examine compatibility with existing approaches as part of supporting nodes acting as gateways between network types.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119].
The remainder of this document is organizaed into seven sections that, together, describe an AMA suitable for enterprise management of asynchronous networks: terminology, motivation, service definitions, desirable properties, roles/responsibilities, system model, and logical component model. The description of each section is as follows.
This section identifies those terms critical to understanding the proper operation of the AMA. Whenever possible, these terms align in both word selection and meaning with their analogs from other management protocols.
Challenged networks, to include networks challenged by administrative or policy delays, cannot guarantee capabilities required to enable synchronous management techniques. These capabilities include high-rate, highly-available data, round-trip data exchange, and operators "in-the-loop". The inability of current approaches to provide network management services in a challenged network motivates the need for a new network management architecture focused on asynchronous, open-loop, autonomous control of network components.
A growing variety of link-challenged networks support packetization to increase data communications reliability without otherwise guaranteeing a simultaneous end-to-end path. Examples of such networks include Mobile Ad-Hoc Networks (MANets), Vehicular Ad-Hoc Networks (VANets), Space-Terrestrial Internetworks (STINTs), and heterogeneous networking overlays. Links in such networks are often unavailable due to attenuations, propagation delays, occultation, and other limitations imposed by energy and mass considerations. Data communications in such networks rely on store-and-forward and other queueing strategies to wait for the connectivity necessary to usefully advance a packet along its route.
Similarly, there also exist well-resourced networks that incur high message delivery delays due to non-environmental limitations. For example, networks whose operations centers are understaffed or where data volume and management requirements exceed the real-time cognitive load of operators or the associated operations console software support. Also, networks where policy restricts user access to existing bandwidth creates situations functionally similar to link disruption and delay.
Independent of the reason, when a node experiences an inability to communicate it must rely on autonomous mechanisms to ensure its safe operation and ability to usefully re-join the network at a later time. In cases of sparsely-populated networks, there may never be a practical concept of "the connected network" as most nodes may be disconnected most of the time. In such environments, defining a network in terms of instantaneous connectivity becomes impractical or impossible.
Specifically, challenged networks exhibit the following properties that may violate assumptions built into current approaches to synchronous network management.
Network management tools in unchallenged networks provide mechanisms for communicating locally-collected data from Agents to Managers, typically using a "pull" mechanism where data must be explicitly requested by a Manager in order to be transmitted by an Agent.
A near ubiquitous method for management in unchallenged networks today is the Simple Network Management Protocol (SNMP) [RFC3416]. SNMP utilizes a request/response model to set and retrieve data values such as host identifiers, link utilizations, error rates, and counters between application software on Agents and Managers. Data may be directly sampled or consolidated into representative statistics. Additionally, SNMP supports a model for asynchronous notification messages, called traps, based on predefined triggering events. Thus, Managers can query Agents for status information, send new configurations, and be informed when specific events have occurred. Traps and queryable data are defined in one or more Managed Information Bases (MIBs) which define the information for a particular data standard, protocol, device, or application.
In challenged networks, the request/response method of data collection is neither efficient nor, at times, possible as it relies on sessions, round-trip latency, message retransmission, and ordered delivery. Adaptive modifications to SNMP to support challenged networks would alter the basic function of the protocol (data models, control flows, and syntax) so as to be functionally incompatible with existing SNMP installations.
The Network Configuration Protocol (NETCONF) provides device-level configuration capabilities [RFC6241] to replace vendor-specific command line interface (CLI) configuration software. The XML-based protocol provides a remote procedure call (RPC) syntax such that any exposed functionality on an Agent can be exercised via a software application interface. NETCONF places no specific functional requirements or constraints on the capabilities of the Agent, which makes it a very flexible tool for configuring a homogeneous network of devices. However, NETCONF does place specific constraints on any underlying transport protocol: namely, a long-lived, reliable, low-latency sequenced data delivery session. This is a fundamental requirement given the RPC-nature of the operating concept, and it is unsustainable in a challenged network.
Management approaches that rely on timely data exchange, such as those that rely on negotiated sessions or other synchronized acknowledgment, do not function in challenged network environments. Familiar examples of TCP/IP based management via closed-loop, synchronous messaging does not work when network disruptions increase in frequency and severity. While no protocol delivers data in the absence of a networking link, protocols that eliminate or drastically reduce overhead and end-point coordination require smaller transmission windows and continue to function when confronted with scaling delays and disruptions in the network.
Just as the concept of a loosely-confederated set of nodes changes the definition of a network, it also changes the operational concept of what it means to manage a network. When a network stops being a single entity exhibiting a single behavior, "network management" becomes large-scale "node management". Individual nodes must share the burden of implementing desirable behavior without reliance on a single oracle of configuration or other coordinating function such as an operator-in-the-loop.
This section identifies the services that must exist between Managers and Agents within an AMA. These services include configuration, reporting, parameterized control, and administration.
Configuration services update local Agent information relating to managed applications and protocols. This information may be configured from ADMs, the specification of parameters associated with these models, and as defined by operators in the network.
New configurations received by a node must be validated to ensure that they do not conflict with other configurations at the node, or prevent the node from effectively working with other nodes in its region. With no guarantee of round-trip data exchange, Agents cannot rely on remote Managers to correct erroneous or stale configurations from harming the flow of data through a challenged network.
Examples of configuration service behavior include the following.
Reporting services populate pre-defined Report Templates with values collected or computed by an Agent. The resultant Report Entries are sent to one or more Managers by the Agent. The term "reporting" is used in place of the term "monitoring", as monitoring implies a timeliness and regularity that cannot be guaranteed by a challenged network. Report Entries sent by an Agent provide best-effort information to receiving Managers.
Since a Manager is not actively "monitoring" an Agent, the Agent must make its own determination on when to send what Report Entries based on its own local time and state information. Agents should produce Report Entries of varying fidelity and with varying frequency based on thresholds and other information set as part of configuration services.
Examples of reporting service behavior include the following.
Controls represent a function that can be run by an Agent to affect its behavior or otherwise change its internal state. In this context, a Control may refer to a single function or an ordered set of functions run in sequence (e.g., a macro). The set of Controls understood by an Agent define the functions available to affect the behavior of applications and protocols managed by the Agent.
Since there is no guarantee that a Manager will be in contact with an Agent at any given time, the decisions of whether and when a Control should be run must be made locally and autonomously by the Agent. Two types of automation triggers are identified in the AMA: triggers based on the general state of the Agent and, more specifically, triggers based on an Agent's notion of time. As such, the autonomous execution of Controls can be viewed as a stimulus-response system, where the stimulus is the positive evaluation of a state or time based predicate and the response is the Control to be executed.
The autonomous nature of Control execution by an Agent implies that the full suite of information necessary to run a Control may not be known by a Manager in advance of running the Control on an Agent. To address this situation, Controls in the AMA MUST support a parmeterization mechanism so that required data can be provided at the time of execution on the Agent rather than at the time of definition/configuration by the Manager.
Autonomous, parameterized control provides a powerful mechanism for Managers to "manage" an Agent asynchronously during periods of no communication by pre-configuring responses to events that may be encountered by the Agent at a future time.
Examples of potential control service behavior include the following.
Administration services enforce the potentially complex mapping of configuration, reporting, and control services amongst Agents and Managers in the network. Fine-grained access control specifying which Managers may apply which services to which Agents may be necessary in networks dealing with multiple administrative entities or overlay networks crossing multiple administrative boundaries. Whitelists, blacklists, key-based infrastructures, or other schemes may be used for this purpose.
Examples of administration service behavior include the following.
Note that the administrative enforcement of access control is different from security services provided by the networking stack carrying AMP messages.
This section describes those design properties that are desireable when defining an architecture that must operate across challenged links in a network. These properties ensure that network management capabilities are retained even as delays and disruptions in the network scale. Ultimately, these properties are the driving design principles for the AMA.
Pull management mechanisms require that a Manager send a query to an Agent and then wait for the response to that query. This practice implies a control-session between entities and increases the overall message traffic in the network. Challenged networks cannot guarantee timely roundtrip data-exchange and, in extreme cases, are comprised solely of uni-directional links. Therefore, pull mechanisms must be avoided in favor of push mechanisms.
Push mechanisms, in this context, refer to Agents making their own determinations relating to the information that should be sent to Managers. Such mechanisms do not require round-trip communications as Managers do not request each reporting instance; Managers need only request once, in advance, that information be produced in accordance with a pre-determined schedule or in response to a pre-defined state on the Agent. In this way information is "pushed" from Agents to Managers and the push is "intelligent" because it is based on some internal evaluation performed by the Agent.
Protocol designers must balance message size versus message processing time at sending and receiving nodes. Verbose representations of data simplify node processing whereas compact representations require additional activities to generate/parse the compacted message. There is no asynchronous management advantage to minimizing node processing time in a challenged network. However, there is a significant advantage to smaller message sizes in such networks. Compact messages require smaller periods of viable transmission for communication, incur less re-transmission cost, and consume less resources when persistently stored en-route in the network. AMPs should minimize PDUs whenever practical, to include packing and unpacking binary data, variable-length fields, and pre-configured data definitions.
Elements within the management system must be uniquely identifiable so that they can be individually manipulated. Identification schemes that are relative to system configuration make data exchange between Agents and Managers difficult as system configurations may change faster than nodes can communicate.
Consider the following SNMP technique for approximating an associative array lookup. A manager wishing to do an associative lookup for some key K1 will (1) query a list of array keys from the agent, (2) find the key that matched K1 and infer the index of K1 from the returned key list, and (3) query the discovered index on the agent to retrieve the desired data.
Ignoring the inefficiency of two pull requests, this mechanism fails when the Agent changes its key-index mapping between the first and second query. Rather than construting an artificial mapping from K1 to an index, an AMP must provide an absolute mechanism to lookup the value K1 without an abstraction between the Agent and Manager.
Custom definition of new data from existing data (such as through data fusion, averaging, sampling, or other mechanisms) provides the ability to communicate desired information in as compact a form as possible. Specifically, an Agent should not be required to transmit a large data set for a Manager that only wishes to calculate a smaller, inferred data set. The Agent should calculate the smaller data set on its own and transmit that instead. Since the identification of custom data sets is likely to occur in the context of a specific network deployment, AMPs must provide a mechanism for their definition.
AMA network functions must be achievable using only knowledge local to the Agent. Rather than directly controlling an Agent, a Manager configures the autonomy engine of the Agent to take its own action under the appropriate conditions in accordance with the Agent's notion of local state and time.
By definition, Agents reside on managed devices and Managers reside on managing devices. This section describes how these roles participate in the network management functions outlined in the prior section.
This section describes the notional data flows and control flows that illustrate how Managers and Agents within an AMA cooperate to perform network management services.
The AMA identifies three significant data flows: control flows from Managers to Agents, reports flows from Agents to Managers, and fusion reports from Managers to other Managers. These data flows are illustrated in Figure 1.
AMA Control and Data Flows
+---------+ +------------------------+ +---------+ | Node A | | Node B | | Node C | | | | | | | |+-------+| |+-------+ +-------+| |+-------+| || ||=====>>||Manager|====>>| ||====>>|| || || ||<<=====|| B |<<====|Agent B||<<====|| || || || |+--++---+ +-------+| ||Manager|| || Agent || +---||-------------------+ || C || || A || || || || || ||<<=========||==========================|| || || ||===========++========================>>|| || |+-------+| |+-------+| +---------+ +---------+
Figure 1
In this data flow, the Agent on node A receives Controls from Managers on nodes B and C, and replies with Reports back to these Managers. Similarly, the Agent on node B interacts with the local Manager on node B and the remote Manager on node C. Finally, the Manager on node B may fuse Reports received from Agents at nodes A and B and send these fused Reports back to the Manager on node C.
From this figure it is clear that there exist many-to-many relationships amongst Managers, amongst Agents, and between Agents and Managers. Note that Agents and Managers are roles, not necessarily differing software applications. Node A may represent a single software application fulfilling only the Agent role, whereas node B may have a single software application fulfilling both the Agent and Manager roles. The specifics of how these roles are realized is an implementation matter.
This section describes three common configurations of Agents and Managers and the flow of messages between them. These configurations involve local and remote management and data fusion.
The notation outlined in Table 1 describes the types of control messages exchanged between Agents and Managers.
Term | Definition | Example |
---|---|---|
AD# | Atomic data definition, from ADM. | AD1 |
CD# | Custom data definition. | CD1 = AD1 + CD0. |
DEF([ACL], ID,EXPR) | Define id from expression. Allow managers in access control list (ACL) to request this id. | DEF([*], CD1, AD1 + AD2) |
PROD(P,ID) | Produce ID according to predicate P. P may be a time period (1s) or an expression (AD1 > 10). | PROD(1s, AD1) |
RPT(ID) | A report identified by ID. | RPT(AD1) |
This is a nominal configuration of network management where a Manager interacts with a set of Agents. The control flows for this are outlined in Figure 2.
Serialized Management Control Flow
+----------+ +---------+ +---------+ | Manager | | Agent A | | Agent B | +----+-----+ +----+----+ +----+----+ | | | |-----PROD(1s, AD1)---->| | (1) |----------------------------PROD(1s, AD1)--->| | | | | | | |<-------RPT(AD1)-------| | (2) |<-----------------------------RPT(AD1)-------| | | | | | | |<-------RPT(AD1)-------| | |<-----------------------------RPT(AD1)-------| | | | | | | |<-------RPT(AD1)-------| | |<-----------------------------RPT(AD1)-------| | | |
In a simple network, a Manager interacts with multiple Agents.
Figure 2
In this figure, the Manager configures Agents A and B to produce Atomic Data AD1 every second in (1). At some point in the future, upon receiving and configuring this message, Agents A and B then build a Report containing AD1 and send those reports back to the Manager in (2).
Networks spanning multiple administrative domains may require multiple Managers (for example, one per domain). When a Manager defines custom Reports/Data to an Agent, that definition may be tagged with an access control list (ACL) to limit what other Managers will be privy to this information. Managers in such networks should synchronize with those other Managers granted access to their custom data definitions. When Agents generate messages, they MUST only send messages to Managers according to these ACLs, if present. The control flows in this scenario are outlined in Figure 3.
Multiplexed Management Control Flow
+-----------+ +-------+ +-----------+ | Manager A | | Agent | | Manager B | +-----+-----+ +---+---+ +-----+-----+ | | | |--DEF(A,CD1,AD1*2)--->|<--DEF(B, CD2, AD2*2)-| (1) | | | |---PROD(1s, CD1)----->|<---PROD(1s, CD2)-----| (2) | | | |<-------RPT(CD1)------| | (3) | |--------RPT(CD2)----->| |<-------RPT(CD1)------| | | |--------RPT(CD2)----->| | | | | |<---PROD(1s, CD1)-----| (4) | | | | |--ERR(CD1 no perm.)-->| | | | |--DEF(*,CD3,AD3*3)--->| | (5) | | | |---PROD(1s, CD3)----->| | (6) | | | | |<---PROD(1s, CD3)-----| | | | |<-------RPT(CD3)------|--------RPT(CD3)----->| (7) |<-------RPT(CD1)------| | | |--------RPT(CD2)----->| |<-------RPT(CD3)------|--------RPT(CD3)----->| |<-------RPT(CD1)------| | | |--------RPT(CD2)----->|
Complex networks require multiple Managers interfacing with Agents.
Figure 3
In more complex networks, any Manager may choose to define custom Reports and Computed Data, and Agents may need to accept such definitions from multiple Managers. Computed Data definitions may include an ACL that describes who may query and otherwise understand these definitions. In (1), Manager A defines CD1 only for A while Manager B defines CD2 only for B. Managers may, then, request the production of Reports containing these definitions, as shown in (2). Agents produce different data for different Managers in accordance with configured production rules, as shown in (3). If a Manager requests the production of a custom definition for which the Manager has no permissions, a response consistent with the configured logging policy on the Agent should be implemented, as shown in (4). Alternatively, as shown in (5), a Manager may define custom data with no restrictions allowing all other Managers to request and use this definition. This allows all Managers to request the production of Reports containing this definition, shown in (6) and have all Managers receive this and other data going forward, as shown in (7).
In some networks, Agents do not individually transmit their data to a Manager, preferring instead to fuse reporting data with local nodes prior to transmission. This approach reduces the number and size of messages in the network and reduces overall transmission energy expenditure. The AMA supports fusion of NM reports by co-locating Agents and Managers on nodes and offloading fusion activities to the Manager. This process is illustrated in Figure 4.
Data Fusion Control Flow
+-----------+ +-----------+ +---------+ +---------+ | Manager A | | Manager B | | Agent B | | Agent C | +---+-------+ +-----+-----+ +----+----+ +----+----+ | | | | |--DEF(A,CD0,AD1+AD2)->| | | (1) |--PROD(AD1&AD2, CD0)->| | | | | | | | |--PROD(1s,AD1)-->| | (2) | |-------------------PROD(1s, AD2)->| | | | | | |<---RPT(AD1)-----| | (3) | |<-------------------RPT(AD2)------| | | | | |<-----RPT(A,CD0)------| | | (4) | | | |
Data fusion occurs amongst Managers in the network.
Figure 4
In this example, Manager A requires the production of a Computed Data set, CD0, from node B, as shown in (1). The Manager role understands what data is available from what agents in the subnetwork local to B, understanding that AD1 is available locally and AD2 is available remotely. Production messages are produced in (2) and data collected in (3). This allows the Manager at node B to fuse the collected Reports into CD0 and return it in (4). While a trivial example, the mechanism of associating fusion with the Manager function rather than the Agent function scales with fusion complexity, though it is important to reiterate that Agent and Manager designations are roles, not individual software components. There may be a single software application running on node B implementing both Manager B and Agent B roles.
This section identifies the different kinds of information present in an asynchronously-managed network and describes how this information should be communicated in the context of an ADM.
The AMA supports four basic groups of information: Data, Actions, Literals, and Operators:
The AMA defines three levels that describe the origins and multiplicity of data groups within the system. These classifications are atomic, computed, and collection.
Each component of the AMA data model can be identified as a combination of group and level, as illustrated in Table 2. In this table, group/level combinations that are unsupported are listed as N/A. In this context, N/A indicates that the AMA does not require support for groups of data at a particular level for compliance.
Data | Action | Literals | Operator | |
---|---|---|---|---|
Atomic | Primitive Value | Control | Literal | Operator |
Computed | Computed Value | Rule | N/A | N/A |
Collection | Report | Macro | N/A | N/A |
The eight elements of the AMA logical data model are described as follows.
Fundamental to any performance reporting function is the ability to measure the state of the Agent. Measurement may be accomplished through direct sampling of hardware, query against in-situ data stores, or other mechanisms that provide the initial quantification of state.
Primitive values serve as the "lingua franca" of the management system: the unit of information that cannot be otherwise created. As such, this information serves as the basis for any user-defined (computed) values in the system.
AMPs MAY consider the concept of the confidence of the primitive value as a function of time. For example, to understand at which point a measurement should be considered stale and need to be re-measured before acting on the associated data.
While primitives provide the full, raw set of information available to Managers and Agents there is a performance optimization to pre-computed re-used combinations of these values. Computing new values as a function of measured values simplifies operator specifications and prevents Agent implementations from continuously re-calculating the same value each time it is used in a given time period.
For example, consider a sensor node which wishes to report a temperature averaged over the past 10 measurements. An Agent may either transmit all 10 measurements to a Manager, or calculate locally the average measurement and transmit the "fused" data. Clearly, the decision to reduce data volume is highly coupled to the nature of the science and the resources of the network. For this reason, the ability to define custom computations per deployment is necessary.
Periodically, or in accordance with local state changes, Agents must collect a series of measured values and computed values and communicate them back to Managers. This ordered collection of value information is noted in this architecture as a Report. In support of hierarchical definitions, Reports may, themselves, contain other Reports. It would be incumbent on an AMP implementation to guard against circular reference in Report definitions.
Just as traditional network management approaches provide well-known identifiers for values, the AMA provides well-known identifiers for Actions. Whereas several low-latency, high-availability approaches in networks can use approaches such as remote procedure calls (RPCs), challenged networks cannot provide a similar function - Managers cannot be in the processing loop of an Agent when the Agent is not in communication with the Manager.
Controls in a system are the combination of a well-known operation that can be taken by an Agent as well as any parameters that are necessary for the proper execution of that function. For specific applications or protocols, a control specification (as a series of opcodes) can be published such that any implementing AMP accepts these opcodes and understands that sending the opcodes to an Agent supporting the application or protocol will properly execute the associated function. Parameters to such functions are provided in real-time by either Managers requesting that a control be run, pre-configured, or auto-populated by the Agent in-situ.
Often, a series of controls must be executed in concert to achieve a particular function, especially when controls represent more primitive operations for a particular application/protocol. In such scenarios, an ordered collection of controls can be specified as a Macro. In support of the hierarchical build-up of functionality, Macros may, themselves, contain other Macros, through it would be incumbent on an AMP implementation to guard against excessive recursion or other resource-intensive nesting.
Stimulus-response autonomy systems provide a way to pre-configure responses to anticipated events. Such a mapping from responses to events is advantageous in a challenged network for a variety of reasons, as listed below.
The logical unit of stimulus-response autonomy proposed in the AMA is a Rule of the form:
IF stimulus THEN response
Where the set of such rules, when evaluated in some prioritized sequence, provides the full set of autonomous behavior for an Agent. Stimulus in such a system would either be a function of relative time, absolute time, or some mathematical expression comprising one or more values (measurement values or computed values).
Notably, in such a system, stimuli and responses from multiple applications and protocols may be combined to provide an expressive capability.
Computing values or evaluating expressions requires applying mathematical operations to data known to the management system.
Operators in the AMA represent enumerated mathematical operations applied to primitive and computed values in the AMA for the purpose of creating new values. Operations may be simple binary operations such as "A + B" or more complex functions such as sin(A) or avg(A,B,C,D).
Literals represent pre-configured constants in the AMA, such as well-known mathematical numbers (e.g., PI, E), or other useful data such as Epoch times. Literals also represent asserted Primitive Values used in expressions. For example, considering the expression (A = B + 10), A would be a Computed Value, B would be either Computed Value or a Primitive Value, + would be an Operator, and 10 would be a Literal.
Application data models (ADMs) specify the data associated with a particular application/protocol. The purpose of the ADM is to provide a published interface for the management of an application or protocol independent of the nuances of its software implementation. In this respect, the ADM is conceptually similar to the Managed Information Base (MIB) used by SNMP, but contains additional information relating to command opcodes and more expressive syntax for automated behavior.
An ADM MUST define all well-known items necessary to manage the specific application or protocol. This includes the definitions of Primitive Values, Computed Values, Reports, Controls, Macros, Rules, Literals, and Operators.
At this time, this protocol has no fields registered by IANA.
Security within an AMA MUST exist in two layers: transport layer security and access control.
Transport-layer security addresses the questions of authentication, integrity, and confidentiality associated with the transport of messages between and amongst Managers and Agents in the AMA. This security is applied before any particular Actor in the system receives data and, therefore, is outside of the scope of this document.
Finer grain application security is done via ACLs which are defined via configuration messages and implementation specific.