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analyze-codebase-for-mcp

pjt222
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Esta habilidad analiza bases de código existentes para identificar funciones, APIs y fuentes de datos que pueden exponerse como herramientas del Model Context Protocol (MCP), generando un documento de especificación. Se utiliza al planificar un servidor MCP, auditar una base de código para superficies de herramientas accesibles por IA, o comparar capacidades existentes con la exposición actual en MCP. El resultado es una especificación de herramientas adecuada para transferir a utilidades de andamiaje.

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Documentación

Analyze Codebase for MCP

Scan codebase to discover functions, REST endpoints, CLI commands, data access patterns. Good candidates for MCP tool exposure. Produce structured tool specification document.

When Use

  • Planning MCP server for existing project, need to know what to expose
  • Auditing codebase before wrapping as AI-accessible tool surface
  • Comparing what codebase can do versus what already exposed via MCP
  • Generating tool specification document to hand off to scaffold-mcp-server
  • Evaluating whether third-party library worth wrapping as MCP tools

Inputs

  • Required: Path to codebase root directory
  • Required: Target language(s) of codebase (e.g., TypeScript, Python, R, Go)
  • Optional: Existing MCP server code to compare against (gap analysis)
  • Optional: Domain focus (e.g., "data analysis", "file operations", "API integration")
  • Optional: Maximum number of tools to recommend (default: 20)

Steps

Step 1: Scan Codebase Structure

1.1. Use Glob to map directory tree, focusing on source directories:

  • src/**/*.{ts,js,py,R,go,rs} for source files
  • **/routes/**, **/api/**, **/controllers/** for endpoint definitions
  • **/cli/**, **/commands/** for CLI entry points
  • **/package.json, **/setup.py, **/DESCRIPTION for dependency metadata

1.2. Categorize files by role:

  • Entry points: main files, route handlers, CLI commands
  • Core logic: business logic functions, algorithms, data transformers
  • Data access: database queries, file I/O, API clients
  • Utilities: helpers, formatters, validators

1.3. Count total files, lines of code, exported symbols to gauge project size.

Got: Categorized file inventory with role annotations.

If fail: Codebase too large (>10,000 files)? Narrow scan to specific directories or modules using domain focus input. No source files found? Verify root path and language parameters.

Step 2: Identify Exposed Functions and Endpoints

2.1. Use Grep to find exported functions and public APIs:

  • TypeScript/JavaScript: export (async )?function, export default, module.exports
  • Python: functions not prefixed with _, @app.route, @router
  • R: functions listed in NAMESPACE or #' @export roxygen tags
  • Go: capitalized function names (exported by convention)

2.2. For each candidate function, extract:

  • Name: function or endpoint name
  • Signature: parameters with types and defaults
  • Return type: what function produces
  • Documentation: docstrings, JSDoc, roxygen, godoc
  • Location: file path and line number

2.3. For REST APIs, additionally extract:

  • HTTP method and route pattern
  • Request body schema
  • Response shape
  • Authentication requirements

2.4. Build candidate list sorted by potential utility (public, documented, well-typed functions first).

Got: List of 20-100 candidate functions/endpoints with extracted metadata.

If fail: Few candidates found? Broaden search to include internal functions could be made public. Documentation sparse? Flag as risk in output.

Step 3: Evaluate MCP Suitability

3.1. For each candidate, assess against MCP tool criteria:

  • Input contract clarity: Parameters well-typed and documented? Can they be described in JSON Schema?
  • Output predictability: Function returns structured data (JSON-serializable)? Return shape consistent?
  • Side effects: Function modifies state (files, database, external services)? Side effects must be clearly labeled.
  • Idempotency: Operation safe to retry? Non-idempotent tools need explicit warnings.
  • Execution time: Will complete within reasonable timeout (< 30 seconds)? Long-running operations need async patterns.
  • Error handling: Throws structured errors or fails silently?

3.2. Score each candidate on 1-5 scale:

  • 5: Pure function, typed I/O, documented, fast, no side effects
  • 4: Well-typed, documented, minor side effects (e.g., logging)
  • 3: Reasonable I/O contract but needs wrapping (e.g., returns raw objects)
  • 2: Significant side effects or unclear contract, needs substantial adaptation
  • 1: Not suitable without major refactoring

3.3. Filter candidates to those scoring 3 or above. Flag score-2 items as "future candidates" requiring refactoring.

Got: Scored and filtered candidate list with suitability rationale for each.

If fail: Most candidates score below 3? Codebase may need refactoring before MCP exposure. Document gaps and recommend specific improvements (add types, extract pure functions, wrap side effects).

Step 4: Design Tool Specifications

4.1. For each selected candidate (score >= 3), draft tool specification:

- name: tool_name
  description: >
    One-line description of what the tool does.
  source_function: module.function_name
  source_file: src/path/to/file.ts:42
  parameters:
    param_name:
      type: string | number | boolean | object | array
      description: What this parameter controls
      required: true | false
      default: value_if_optional
  returns:
    type: string | object | array
    description: What the tool returns
  side_effects:
    - description of any side effect
  estimated_latency: fast | medium | slow
  suitability_score: 5

4.2. Group tools into logical categories (e.g., "Data Queries", "File Operations", "Analysis", "Configuration").

4.3. Identify dependencies between tools (e.g., "list_datasets" should be called before "query_dataset").

4.4. Determine if any tools need wrappers to:

  • Simplify complex parameter objects into flat inputs
  • Convert raw return values to structured text or JSON
  • Add safety guards (e.g., read-only wrappers for database functions)

Got: Complete YAML tool specification with categories, dependencies, wrapper notes.

If fail: Tool specifications ambiguous? Revisit Step 2 to extract more detail from source code. Parameter types cannot be inferred? Flag for manual review.

Step 5: Generate Tool Spec Document

5.1. Write final specification document with these sections:

  • Summary: Codebase overview, language, size, analysis date
  • Recommended Tools: Full specifications from Step 4, grouped by category
  • Future Candidates: Score-2 items with refactoring recommendations
  • Excluded Items: Score-1 items with exclusion rationale
  • Dependencies: Tool dependency graph
  • Implementation Notes: Wrapper requirements, authentication needs, transport recommendations

5.2. Save as mcp-tool-spec.yml (machine-readable) and optionally mcp-tool-spec.md (human-readable summary).

5.3. Existing MCP server provided? Include gap analysis section:

  • Tools in spec but not yet implemented
  • Implemented tools not in spec (possibly stale)
  • Tools with specification drift (implementation diverges from spec)

Got: Complete tool specification document ready for consumption by scaffold-mcp-server.

If fail: Document exceeds reasonable size (>200 tools)? Split into modules with cross-references. Codebase has no suitable candidates? Produce "readiness assessment" document with refactoring recommendations instead.

Checks

  • All source files in target codebase scanned
  • Candidate functions have extracted names, signatures, return types
  • Each candidate has suitability score with written rationale
  • Tool specifications include complete parameter schemas with types
  • Side effects explicitly documented for every tool
  • Output document is valid YAML (parseable by any YAML library)
  • Tool names follow MCP conventions (snake_case, descriptive, unique)
  • Categories and dependencies form coherent tool surface
  • Gap analysis included when existing MCP server provided
  • Future candidates section lists refactoring steps needed for score-2 items

Pitfalls

  • Exposing too many tools: AI assistants work best with 10-30 focused tools. Prioritize breadth of capability over depth. Resist exposing every public function.
  • Ignoring side effects: Function that "just reads" but also writes to log or cache still has side effects. Audit careful with Grep for file writes, network calls, database mutations.
  • Assuming type safety: Dynamic languages (Python, R, JavaScript) may have functions with no type annotations. Infer types from usage patterns and tests, but flag uncertainty in spec.
  • Missing authentication context: Functions work in authenticated web request may fail when called via MCP without session context. Check for implicit auth dependencies such as session cookies, JWT tokens, environment-injected credentials.
  • Over-engineering wrappers: Function needs 50-line wrapper to be MCP-compatible? May not be good candidate. Prefer functions map naturally to tool interfaces.
  • Neglecting error paths: MCP tools must return structured errors. Functions throw untyped exceptions need error-handling wrappers.
  • Conflating internal and external APIs: Internal helper functions called by other internal code are poor MCP candidates. Focus on functions designed for external consumption or clear boundary APIs.
  • Skipping gap analysis: Existing MCP server provided? Always compare spec against current implementation. Without gap analysis, risk duplicating work or missing stale tools.

See Also

  • scaffold-mcp-server - use output spec to generate working MCP server
  • build-custom-mcp-server - manual server implementation reference
  • configure-mcp-server - connect resulting server to Claude Code/Desktop
  • troubleshoot-mcp-connection - debug connectivity after deploying server
  • review-software-architecture - architecture review for tool surface design
  • security-audit-codebase - security audit before exposing functions externally

Repositorio GitHub

pjt222/agent-almanac
Ruta: i18n/caveman/skills/analyze-codebase-for-mcp
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