Trailmark

Parses source code into a directed graph of functions, classes, calls, and semantic metadata for security analysis. Supports 16 languages.

When to Use

• Mapping call paths from user input to sensitive functions

• Finding complexity hotspots for audit prioritization

• Identifying attack surface and entrypoints

• Understanding call relationships in unfamiliar codebases

• Security review or audit preparation across polyglot projects

• Adding LLM-inferred annotations (assumptions, preconditions) to code units

• Pre-analysis before mutation testing (genotoxic skill) or diagramming

When NOT to Use

• Single-file scripts where call graph adds no value (read the file directly)

• Architecture diagrams not derived from code (use the diagramming-code skill or draw by hand)

• Mutation testing triage (use the genotoxic skill, which calls trailmark internally)

• Runtime behavior analysis (trailmark is static, not dynamic)

Rationalizations to Reject

Rationalization Why It's Wrong Required Action

"I'll just read the source files manually" Manual reading misses call paths, blast radius, and taint data Install trailmark and use the API

"Pre-analysis isn't needed for a quick query" Blast radius, taint, and privilege data are only available after preanalysis()

Always run engine.preanalysis() before handing off to other skills

"The graph is too large, I'll sample" Sampling misses cross-module attack paths Build the full graph; use subgraph queries to focus

"Uncertain edges don't matter" Dynamic dispatch is where type confusion bugs hide Account for uncertain edges in security claims

"Single-language analysis is enough" Polyglot repos have FFI boundaries where bugs cluster Use the correct --language flag per component

"Complexity hotspots are the only thing worth checking" Low-complexity functions on tainted paths are high-value targets Combine complexity with taint and blast radius data

Installation

MANDATORY: If uv run trailmark fails (command not found, import error, ModuleNotFoundError), install trailmark before doing anything else:

uv pip install trailmark

DO NOT fall back to "manual verification", "manual analysis", or reading source files by hand as a substitute for running trailmark. The tool must be installed and used programmatically. If installation fails, report the error to the user instead of silently switching to manual code reading.

Quick Start

Python (default)

uv run trailmark analyze --summary {targetDir}

Other languages

uv run trailmark analyze --language rust {targetDir} uv run trailmark analyze --language javascript {targetDir} uv run trailmark analyze --language go --summary {targetDir}

Complexity hotspots

uv run trailmark analyze --complexity 10 {targetDir}

Programmatic API

from trailmark.query.api import QueryEngine

Specify language (defaults to "python")

engine = QueryEngine.from_directory("{targetDir}", language="rust")

engine.callers_of("function_name") engine.callees_of("function_name") engine.paths_between("entry_func", "db_query") engine.complexity_hotspots(threshold=10) engine.attack_surface() engine.summary() engine.to_json()

Run pre-analysis (blast radius, entrypoints, privilege

boundaries, taint propagation)

result = engine.preanalysis()

Query subgraphs created by pre-analysis

engine.subgraph_names() engine.subgraph("tainted") engine.subgraph("high_blast_radius") engine.subgraph("privilege_boundary") engine.subgraph("entrypoint_reachable")

Add LLM-inferred annotations

from trailmark.models import AnnotationKind

engine.annotate("function_name", AnnotationKind.ASSUMPTION, "input is URL-encoded", source="llm")

Query annotations (including pre-analysis results)

engine.annotations_of("function_name") engine.annotations_of("function_name", kind=AnnotationKind.BLAST_RADIUS) engine.annotations_of("function_name", kind=AnnotationKind.TAINT_PROPAGATION)

Pre-Analysis Passes

Always run engine.preanalysis() before handing off to genotoxic or diagramming-code skills. Pre-analysis enriches the graph with four passes:

• Blast radius estimation — counts downstream and upstream nodes per function, identifies critical high-complexity descendants

• Entry point enumeration — maps entrypoints by trust level, computes reachable node sets

• Privilege boundary detection — finds call edges where trust levels change (untrusted -> trusted)

• Taint propagation — marks all nodes reachable from untrusted entrypoints

Results are stored as annotations and named subgraphs on the graph.

For detailed documentation, see references/preanalysis-passes.md.

Supported Languages

Language --language value Extensions

Python python

.py

JavaScript javascript

.js , .jsx

TypeScript typescript

.ts , .tsx

PHP php

.php

Ruby ruby

.rb

C c

.c , .h

C++ cpp

.cpp , .hpp , .cc , .hh , .cxx , .hxx

C# c_sharp

.cs

Java java

.java

Go go

.go

Rust rust

.rs

Solidity solidity

.sol

Cairo cairo

.cairo

Haskell haskell

.hs

Circom circom

.circom

Erlang erlang

.erl

Graph Model

Node kinds: function , method , class , module , struct , interface , trait , enum , namespace , contract , library

Edge kinds: calls , inherits , implements , contains , imports

Edge confidence: certain (direct call, self.method() ), inferred

(attribute access on non-self object), uncertain (dynamic dispatch)

Per Code Unit

• Parameters with types, return types, exception types

• Cyclomatic complexity and branch metadata

• Docstrings

• Annotations: assumption , precondition , postcondition , invariant , blast_radius , privilege_boundary , taint_propagation

Per Edge

• Source/target node IDs, edge kind, confidence level

Project Level

• Dependencies (imported packages)

• Entrypoints with trust levels and asset values

• Named subgraphs (populated by pre-analysis)

Key Concepts

Declared contract vs. effective input domain: Trailmark separates what a function declares it accepts from what can actually reach it via call paths. Mismatches are where vulnerabilities hide:

• Widening: Unconstrained data reaches a function that assumes validation

• Safe by coincidence: No validation, but only safe callers exist today

Edge confidence: Dynamic dispatch produces uncertain edges. Account for confidence when making security claims.

Subgraphs: Named collections of node IDs produced by pre-analysis. Query with engine.subgraph("name") . Available after engine.preanalysis() .

Query Patterns

See references/query-patterns.md for common security analysis patterns.

See references/preanalysis-passes.md for pre-analysis pass documentation.