



Network Working Group                                          S. Prabhu
Internet-Draft                                                     Nokia
Intended status: Informational                                7 May 2026
Expires: 8 November 2026


 Framework for Normalizing Multi-Vendor Network Inputs for LLM-Assisted
                           Network Management
                 draft-prabhu-nmrg-prompt-schema-llm-00

Abstract

   Large Language Models (LLMs) are increasingly used to assist network
   management tasks such as troubleshooting, intent translation, and
   automation.  Network operations, however, rely on data from many
   vendors and sources: CLI output, configuration snippets, telemetry,
   alarms, and vendor-specific APIs.  These inputs differ in format,
   structure, and semantics, which makes it difficult to present a
   consistent interface to an LLM.  This document describes a framework
   for standardizing such multi-vendor inputs for LLM-assisted network
   management.  Incoming messages from multi-vendor network elements are
   first handled by an Input Classifier, which determines the nature of
   each input and assigns it to one of three categories: performance,
   configuration, or response, using a hybrid approach (rule-based
   classification first, with escalation to a Small Language Model (SLM)
   when rules are insufficient).  The classified input is then passed to
   the corresponding Structurer among the Performance Structurer,
   Configuration Structurer, and Response Structurer, each of which
   produces a normalized, structured representation (typically with SLM
   assistance and optional confidence scoring).  That structured output
   is fed to a Prompt Schema Generator, which creates a structured,
   vendor-agnostic schema and supplies schema-aligned prompts to the
   central LLM.  This document specifies the architecture and component
   roles for use in design and implementation.  It does not define a
   wire protocol; it is published for informational purposes.

Status of This Memo

   This Internet-Draft is submitted in full conformance with the
   provisions of BCP 78 and BCP 79.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF).  Note that other groups may also distribute
   working documents as Internet-Drafts.  The list of current Internet-
   Drafts is at https://datatracker.ietf.org/drafts/current/.






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   Internet-Drafts are draft documents valid for a maximum of six months
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Table of Contents

   1.  Introduction  . . . . . . . . . . . . . . . . . . . . . . . .   3
   2.  Terminology . . . . . . . . . . . . . . . . . . . . . . . . .   3
   3.  Architecture Overview . . . . . . . . . . . . . . . . . . . .   5
   4.  Input Classifier  . . . . . . . . . . . . . . . . . . . . . .   7
     4.1.  Rule-based classification . . . . . . . . . . . . . . . .   7
       4.1.1.  Performance message detection . . . . . . . . . . . .   7
       4.1.2.  Configuration message detection . . . . . . . . . . .   8
       4.1.3.  Response message detection  . . . . . . . . . . . . .   8
     4.2.  SLM-based classification  . . . . . . . . . . . . . . . .   8
   5.  Structurers . . . . . . . . . . . . . . . . . . . . . . . . .   9
     5.1.  Performance Structurer  . . . . . . . . . . . . . . . . .   9
     5.2.  Configuration Structurer  . . . . . . . . . . . . . . . .  10
     5.3.  Response Structurer . . . . . . . . . . . . . . . . . . .  10
   6.  Prompt Schema Generator . . . . . . . . . . . . . . . . . . .  11
   7.  Output and Downstream Use . . . . . . . . . . . . . . . . . .  12
   8.  Security Considerations . . . . . . . . . . . . . . . . . . .  12
   9.  IANA Considerations . . . . . . . . . . . . . . . . . . . . .  13
   10. References  . . . . . . . . . . . . . . . . . . . . . . . . .  13
     10.1.  Normative References . . . . . . . . . . . . . . . . . .  13
     10.2.  Informative References . . . . . . . . . . . . . . . . .  13
   Author's Address  . . . . . . . . . . . . . . . . . . . . . . . .  14







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1.  Introduction

   LLM-assisted network management uses Large Language Models to
   interpret network data, suggest actions, translate operator intent
   into device commands, and assist with root cause analysis and
   reporting.  The effectiveness of such systems depends on the quality
   and consistency of the inputs presented to the LLM.  In practice,
   those inputs are highly heterogeneous: show-command output and
   configuration dumps vary by vendor and device type; telemetry and
   alarms use different formats and naming; and management APIs differ
   across vendors.  Without normalization, the same logical concept
   (e.g., "interface status" or "BGP neighbor state") appears in many
   forms, which degrades LLM performance and complicates prompt design
   and maintenance.

   This document describes an architectural framework for standardizing
   multi-vendor inputs before they are used as prompts (or prompt
   context) for a central LLM in network management.  The flow is as
   follows. (1) Multi-vendor network data is received by the Input
   Classifier, which classifies each message as performance-related,
   configuration-related, or response-related so that the appropriate
   Structurer receives the right type of input.  The Input Classifier
   uses a hybrid approach: a fast, deterministic rule-based stage first;
   when pattern matching fails, multiple category conflicts arise, or
   structural certainty is insufficient, an SLM-based classification
   stage within the Input Classifier is invoked. (2) Based on that
   classification, the message is passed to exactly one of the
   Performance Structurer, Configuration Structurer, or Response
   Structurer, each of which interprets vendor-variable text and emits a
   structured record. (3) The structured output is fed to the Prompt
   Schema Generator, which creates or selects a vendor-agnostic schema
   and produces schema-aligned prompts. (4) Those prompts are supplied
   to the central LLM that performs network management (e.g.,
   troubleshooting, intent translation, or automation).

   The key components are the Input Classifier, the three Structurers,
   the Prompt Schema Generator, and the central LLM.  Together, they
   enable multi-vendor inputs to be categorized, structured, normalized
   via a schema, and presented to the central LLM in a consistent form.

2.  Terminology

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
   "OPTIONAL" in this document are to be interpreted as described in BCP
   14 [RFC2119] [RFC8174] when, and only when, they appear in all
   capitals, as shown here.




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   *  LLM (Large Language Model): A machine learning model used for
      natural language understanding and generation.  In this document,
      the LLM is the consumer of standardized network management inputs
      for tasks such as troubleshooting, intent translation, and
      automation.

   *  Prompt: Input (or input context) supplied to an LLM for
      processing.  In LLM-assisted network management, a prompt
      typically includes network-derived data such as CLI output,
      configuration snippets, telemetry, or alarms, often after
      normalization via a schema.

   *  Schema: A formal, vendor-agnostic description of the structure,
      types, and semantics of a class of network management inputs.  A
      schema allows multi-vendor data to be normalized to a common shape
      before being presented to the LLM.

   *  Input Classifier: A component that determines the nature of
      incoming messages from multi-vendor network elements and assigns
      each input to one of three categories: performance, configuration,
      or response, so that the corresponding Structurer can process it.
      It uses a hybrid rule-based stage followed by SLM-based
      classification when the rule-based stage is inconclusive.

   *  Structurer: A component that receives input already labeled by the
      Input Classifier with one category and produces a structured,
      normalized representation for the Prompt Schema Generator.  This
      document defines three structurers: Performance Structurer,
      Configuration Structurer, and Response Structurer.

   *  Small Language Model (SLM): A compact language model used inside
      the Input Classifier (for semantic classification when rules fail)
      and inside each Structurer (for extraction, normalization, and
      confidence).  SLMs MAY be fine-tuned on curated multi-vendor
      network messages, telemetry, configuration text, and operational
      responses.

   *  Confidence level: An optional indicator (e.g., high, medium, low)
      associated with structuring or classification.  Low-confidence
      cases MAY attach raw input for human-in-the-loop review and later
      feedback into training of the Input Classifier and Structurers.










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3.  Architecture Overview

   The framework is a logical system that interfaces with the central
   (existing) LLM that manages the network; it sits between multi-vendor
   network data sources and that central LLM.  Raw inputs (e.g., CLI
   output, configuration, telemetry, alarms, or API responses) enter the
   Input Classifier.  The classifier routes each message to the
   Performance Structurer, Configuration Structurer, or Response
   Structurer.  The active Structurer's output is fed to the Prompt
   Schema Generator, which produces schema-aligned prompts for the
   central LLM.








































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       +---------------------------+
       |   Central LLM             |
       |   (network management:    |
       |    troubleshooting,        |
       |    intent translation,     |
       |    automation)             |
       +-------------+-------------+
                     ^
                     |  schema + prompts
       +--------+---------+     +-----------------------+
       |  Prompt Schema   |<----+  Auxiliary / Control   |
       |   Generator      |     |  (e.g., schema        |
       |                  |     |   generation policy)   |
       +------------------+     +-----------------------+
                     ^
                     |  structured output
            +--------+---------+---------+
            |        |         |         |
       +----+---+ +---+----+ +--+-----+
       |Performance|Config. |Response|
       |Structurer |Struct. |Struct. |
       +----+---+ +---+----+ +--+-----+
            ^        ^         ^
            |        |         |
            +----+---+---------+
                     |
            +--------v--------+
            |  Input          |
            |  Classifier     |
            |  (rules + SLM)  |
            +--------+--------+
                     ^
                     |
       +-------------+-------------+
       | Multi-Vendor Network Input |
       | (CLI, config, telemetry,   |
       |  alarms, vendor APIs)     |
       +---------------------------+

                      Figure 1: Reference architecture











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4.  Input Classifier

   The Input Classifier is responsible for determining the nature of
   incoming messages from multi-vendor network elements.  It assesses
   each input and classifies it into exactly one of three categories:
   performance, configuration, or response, so that the corresponding
   Structurer receives the appropriate type of input for further
   processing.

   The Input Classifier uses a hybrid approach: rule-based
   classification is attempted first, followed by SLM-based
   classification when the rule-based stage cannot produce a reliable
   single category.  The hybrid design balances speed, efficiency, and
   accuracy: rule-based logic is fast and lightweight for common
   patterns; when inputs are complex, ambiguous, or unmatched by rules,
   an SLM performs deeper contextual analysis.

4.1.  Rule-based classification

   In the first stage, the Input Classifier applies a deterministic,
   rule-based mechanism to categorize incoming network element messages.
   This layer is intended for high-frequency, well-structured, and
   common message formats without invoking computationally intensive
   semantic analysis.

   The rule-based engine MAY use a combination of:

   *  Keyword dictionaries.

   *  Structured field detection.

   *  Regular expression matching.

   *  Protocol-aware parsing.

   *  Message header inspection.

   Each message is evaluated against category-specific rule sets for
   performance, configuration, and response classification.

4.1.1.  Performance message detection

   Performance-related messages typically describe operational metrics,
   telemetry readings, utilization values, or statistical measurements.
   Example keyword families include: utilization, throughput, latency,
   jitter, packet loss, bandwidth, CPU usage, memory usage, temperature,
   receive/transmit rates, error rate, and queue depth (exact
   vocabularies are implementation defined).



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   Pattern-based heuristics MAY include: numeric values with percentage
   signs; metric names adjacent to numeric measurements; telemetry-style
   field-value formats.  As an illustrative example, a regular
   expression such as:

   (utilization|load|usage)\s*[:=]?\s*\d+(\.\d+)?\s*%

   can match lines such as "CPU utilization: 78%", "Traffic load = 45%",
   and "Network usage 62%".  Similar patterns MAY be defined for other
   performance metrics (e.g., latency, throughput).

4.1.2.  Configuration message detection

   Configuration-related messages indicate intent to modify, retrieve,
   delete, or update network state.  Example keywords include: set,
   configure, apply, update, modify, delete, add, remove, commit,
   rollback, enable, and disable.

   As an illustrative example, a regular expression such as:

   (set|update|configure|modify)\s+(interface|vlan|route|policy|qos|ip)

   can match phrases such as "Set interface Gi0/1 bandwidth 100Mbps",
   "Update VLAN 10 configuration", and "Modify route table entry".

4.1.3.  Response message detection

   Response messages typically represent outcomes of prior operations.
   Example keywords include: success, completed, applied, acknowledged,
   error, failed, failure, invalid, timeout, rejected, and warning.

   As an illustrative example, a regular expression such as:

   (success|completed|applied|acknowledged)\b

   can match phrases such as "Configuration applied successfully",
   "Operation completed", and "Request acknowledged".

   When pattern matching fails, multiple categories conflict, or
   structural certainty is insufficient, implementations SHOULD escalate
   to SLM-based classification within the Input Classifier.

4.2.  SLM-based classification

   When the rule-based stage cannot categorize a message (for example,
   due to absence of rule matches, conflicting rule matches, or
   ambiguous structure), the message is processed by an SLM-based
   semantic classification stage inside the Input Classifier.



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   The SLM interprets context, semantics, and structure to assign the
   message to performance, configuration, or response.  The model MAY be
   trained or fine-tuned on a curated corpus that includes historical
   multi-vendor network messages, telemetry logs, configuration
   commands, and operational responses, so that nuanced and vendor-
   specific formats can be handled using contextual cues (e.g.,
   attention over token relationships and embeddings).

5.  Structurers

   After classification, the message is delivered to exactly one of
   three Structurers.  Each Structurer interprets inputs that the Input
   Classifier has already labeled with the matching category.  Because
   vendors represent performance, configuration, and response text in
   widely varying forms, each Structurer typically employs an SLM for
   adaptability, extraction, normalization, and confidence assignment.
   Structured records are then passed to the Prompt Schema Generator.

5.1.  Performance Structurer

   The Performance Structurer processes inputs categorized as
   performance by the Input Classifier.

   Typical processing steps include:

   1.  Input reception: The structurer receives performance-labeled
       input (e.g., a line such as "Traffic load = 75%").

   2.  Value extraction: The SLM extracts numeric and unit information
       (e.g., isolating "75" and "%").  Heterogeneous forms (e.g.,
       ratios such as "8/10") MAY be converted to a comparable
       representation (e.g., 80%).

   3.  Normalization: Values are normalized to a standard scale for
       downstream use (commonly a percentage), so that fractions, raw
       throughput figures, and percentages align to a uniform
       representation.

   4.  Confidence scoring: The SLM MAY assign high (well-recognized
       pattern), medium (ambiguous; flag for review), or low
       (unrecognized pattern).  For low confidence, implementations MAY
       attach the raw network element input when sending output to the
       Prompt Schema Generator for human-in-the-loop review; feedback
       from that review MAY later be used to retrain or refine the Input
       Classifier and Structurers.






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   5.  Performance structuring: The structurer emits a structured
       representation to the Prompt Schema Generator in an
       implementation-defined format consistent with the chosen schema.

5.2.  Configuration Structurer

   The Configuration Structurer processes inputs categorized as
   configuration by the Input Classifier.

   Typical processing steps include:

   1.  Input reception: Configuration-labeled input is received (e.g.,
       "Set interface bandwidth to 100 Mbps").

   2.  Operation identification: The SLM detects the configuration
       operation (e.g., set, update, delete, enable, disable).

   3.  Target identification: The structurer identifies the
       configuration target (e.g., interface bandwidth, firewall rule,
       routing policy).

   4.  Value extraction: When present, parameter values are extracted
       (e.g., "100 Mbps"); some operations (e.g., "enable logging") MAY
       have no separate value beyond the operation and target.

   5.  Normalization of targets: Vendor-specific phrases for the same
       concept (e.g., "interface bandwidth" vs. "link speed") are mapped
       to a standard target representation.

   6.  Configuration structuring: A structured record is emitted to the
       Prompt Schema Generator in an implementation-defined format
       consistent with the chosen schema.

5.3.  Response Structurer

   The Response Structurer processes inputs categorized as response by
   the Input Classifier, using an SLM to cope with variability in how
   vendors phrase operational outcomes.

   Typical processing steps include:

   1.  Input reception: Response-labeled input is received (e.g.,
       "Configuration applied successfully on interface Gi0/1").








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   2.  Response intent interpretation: The SLM determines the outcome
       category, such as success, failure, partial success, warning,
       timeout, or rejection; whether the message relates to a prior
       configuration action; and whether an explicit error condition is
       present.

   3.  Error and context extraction: For failure or warning outcomes,
       the SLM MAY extract error reason, error code (if present),
       parameters involved, and affected object (e.g., interface, route,
       policy).

   4.  Confidence assignment: High confidence MAY correspond to clear
       success/failure wording; medium to ambiguity; low to non-standard
       or unclear outcomes; raw input MAY be attached for the Prompt
       Schema Generator when confidence is low.

   5.  Response structuring: A standardized structured representation is
       produced for the Prompt Schema Generator in an implementation-
       defined format consistent with the chosen schema.

   The three structurers are distinct logical components; for a given
   message, only the structurer matching the Input Classifier's category
   is used.  Implementations MAY pipeline batches such that multiple
   structured records are produced over time and assembled by the Prompt
   Schema Generator according to policy.

6.  Prompt Schema Generator

   The Prompt Schema Generator receives structured output from the
   active Structurer (performance, configuration, or response),
   optionally including raw input attachments and confidence metadata
   from low-confidence paths.  It creates or selects a structured,
   vendor-agnostic schema appropriate to that category and message
   shape, and produces schema-aligned prompts for the central LLM.

   Functions of the Prompt Schema Generator in this context include:

   *  Creating or selecting schemas that define structure, fields,
      types, and semantics of network management inputs in a form
      suitable for the central LLM, with schema choice driven by the
      classification and structurer output.

   *  Enabling mapping from vendor-specific representations to a single
      schema so the central LLM receives consistent input regardless of
      source.






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   *  Feeding the schema and resulting prompts (or prompt context) to
      the central LLM for tasks such as troubleshooting, intent
      translation, and automation.

   Implementations may use static schema definitions (e.g., based on
   common network management information models), vendor-specific
   mapping tables, or dynamically updated schemas.  The output of the
   Prompt Schema Generator is consumed by the central LLM;
   implementations may also use it for normalization logic that maps
   structured records into schema-conformant prompts before LLM
   invocation.

7.  Output and Downstream Use

   The output of the framework is schema-aligned prompts (or prompt
   context) from the Prompt Schema Generator, derived from classified
   and structured multi-vendor input.  Each prompt is associated with
   the performance, configuration, or response category assigned by the
   Input Classifier, with the schema used to create it.  These prompts
   are supplied to the central LLM that performs network management
   (e.g., troubleshooting, intent translation, compliance analysis, or
   automation).  Downstream components (e.g., prompt assembly, LLM
   invocation, or result parsing) use the category, structurer output,
   and schema alignment to choose models, templates, and response
   handling.  The exact format and semantics of data passed from the
   Prompt Schema Generator to the central LLM are implementation
   defined.

8.  Security Considerations

   The structure of this section is informed by the guidelines in
   [RFC3552].  Implementations of this framework in LLM-assisted network
   management should consider the following:

   *  Network management inputs often contain sensitive data:
      credentials, topology, IP addressing, and configuration details.
      Data flows through the Input Classifier, the active Structurer,
      the Prompt Schema Generator, and the central LLM; each stage may
      expose this information.  Implementations SHOULD apply data
      minimization (e.g., redacting or tokenizing secrets during
      classification, structuring, and schema generation), secure
      transport and storage for intermediate data, and policies that
      limit what is sent to external or cloud-hosted LLMs.  Compliance
      with organizational and regulatory requirements for network and
      personal data SHOULD be ensured.






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   *  Schema definitions and mapping rules determine what structure and
      fields are sent to the LLM.  Schema generation or selection that
      relies on untrusted input can introduce injection or policy bypass
      risks.  Implementations SHOULD validate and constrain schema
      content and SHOULD restrict who can create or modify schema
      definitions and vendor mappings.

   *  Incorrect classification or structuring can change which prompts
      and schemas are used and can affect prioritization and access
      control.  Crafted inputs that are misclassified or misstructured
      could lead to incorrect LLM behavior, privilege escalation, or
      denial of service.  Implementations SHOULD treat classifier and
      structurer output as advisory where security is critical and
      SHOULD apply additional checks before acting on LLM outputs that
      affect network configuration or access.

   *  Consolidating multi-vendor inputs increases attack surface:
      parsers, regex engines, SLM inference, schema mappings, and paths
      to the central LLM.  Implementations SHOULD harden the Input
      Classifier, each Structurer, the Prompt Schema Generator, and any
      normalizers against malformed or malicious input and SHOULD
      monitor for abuse or unexpected classification patterns.

9.  IANA Considerations

   This document has no IANA actions.

10.  References

10.1.  Normative References

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119,
              DOI 10.17487/RFC2119, March 1997,
              <https://www.rfc-editor.org/info/rfc2119>.

   [RFC8174]  Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
              2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
              May 2017, <https://www.rfc-editor.org/info/rfc8174>.

10.2.  Informative References

   [RFC3552]  Rescorla, E. and B. Korver, "Guidelines for Writing RFC
              Text on Security Considerations", BCP 72, RFC 3552,
              DOI 10.17487/RFC3552, July 2003,
              <https://www.rfc-editor.org/info/rfc3552>.





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Author's Address

   Shailesh Prabhu
   Nokia
   India
   Email: shailesh.prabhu@nokia.com













































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