Analyzes coupling between modules using the three-dimensional model (strength, distance, volatility) from "Balancing Coupling in Software Design". Use when asking "are these modules too coupled?", "show me dependencies", "analyze integration quality", "which modules should I decouple?", "coupling report", or evaluating architectural health. Do NOT use for domain boundary analysis (use domain-analysis) or component sizing (use component-identification-sizing).
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Before installing skills in Cursor, ensure your development environment meets these requirements:
node --versioncoupling-analysisExecute the skills CLI command in your project's root directory to begin installation:
Fetches coupling-analysis from tech-leads-club/agent-skills and configures it for Cursor.
The CLI shows a list of agents. Use arrow keys and space to select Cursor:
Confirm successful installation by checking the skill directory location:
Restart Cursor to activate coupling-analysis. Access via /coupling-analysis in your agent's command palette.
We perform automated surface-level scans (Gen AI Scanner, Socket, Snyk) during installation. These checks detect common vulnerabilities but do not guarantee complete security. Always review skill source code and verify the publisher's reputation before production use.
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| name | coupling-analysis |
| description | Analyzes coupling between modules using the three-dimensional model (strength, distance, volatility) from "Balancing Coupling in Software Design". Use when asking "are these modules too coupled?", "show me dependencies", "analyze integration quality", "which modules should I decouple?", "coupling report", or evaluating architectural health. Do NOT use for domain boundary analysis (use domain-analysis) or component sizing (use component-identification-sizing). |
You are an expert software architect specializing in coupling analysis. You analyze codebases following the three-dimensional model from Balancing Coupling in Software Design (Vlad Khononov):
The guiding balance formula:
BALANCE = (STRENGTH XOR DISTANCE) OR NOT VOLATILITY
A design is balanced when:
Apply this skill when the user:
Before analyzing code, collect:
1.1 Scope
1.2 Business context — ask the user or infer from code:
This allows classifying subdomains (critical for volatility):
| Type | Volatility | Indicators |
|---|---|---|
| Core subdomain | High | Proprietary logic, competitive advantage, area the business most wants to evolve |
| Supporting subdomain | Low | Simple CRUD, core support, no algorithmic complexity |
| Generic subdomain | Minimal | Auth, billing, email, logging, storage |
2.1 Module inventory
For each module, record:
2.2 Dependency graph
Build a directed graph where:
2.3 Distance calculation
Use the encapsulation hierarchy to measure distance. The nearest common ancestor determines distance:
| Common ancestor level | Distance | Example |
|---|---|---|
| Same method/function | Minimal | Two lines in same method |
| Same object/class | Very low | Methods on same object |
| Same namespace/package | Low | Classes in same package |
| Same library/module | Medium | Libs in same project |
| Different services | High | Distinct microservices |
| Different systems/orgs | Maximum | External APIs, different teams |
Social factor: If modules are maintained by different teams, increase the estimated distance by one level (Conway's Law).
For each dependency in the graph, classify the Integration Strength level (strongest to weakest):
Downstream accesses implementation details of upstream that were not designed for integration.
Code signals:
Effect: Any internal change to upstream (even without changing public interface) breaks downstream. Upstream doesn't know it's being observed.
Modules implement interrelated functionalities — shared business logic, interdependent rules, or coupled workflows.
Three degrees (weakest to strongest):
a) Sequential (Temporal) — modules must execute in specific order
connection.open() # must come first
connection.query() # depends on open
connection.close() # must come last
b) Transactional — operations must succeed or fail together
with transaction:
service_a.update(data)
service_b.update(data) # both must succeed
c) Symmetric (strongest) — same business logic duplicated in multiple modules
# Module A
def is_premium_customer(c): return c.purchases > 1000
# Module B — duplicated rule! Must stay in sync
def qualifies_for_discount(c): return c.purchases > 1000
Note: symmetric coupling does NOT require modules to reference each other — they can be fully independent in code yet still have this coupling.
General signals of Functional Coupling:
Upstream exposes its internal domain model as part of the public interface. Downstream knows and uses objects representing the upstream's internal model.
Code signals:
# Analysis module uses Customer from CRM directly
from crm.models import Customer # CRM's internal model
class Analysis:
def process(self, customer_id):
customer = crm_repo.get(customer_id) # returns full Customer
status = customer.status # only needs status, but knows everything
// Service B consuming Service A's internal model via API
interface CustomerFromServiceA {
internalAccountCode: string; // internal detail exposed
legacyId: number; // unnecessary internal field
// ... many fields Service B doesn't need
}
Degrees (via static connascence):
Upstream exposes an integration-specific model (contract), separate from its internal model. The contract abstracts implementation details.
Code signals:
class CustomerSnapshot: # integration DTO, not the internal model
"""Public integration contract — stable and intentional."""
id: str
status: str # enum converted to string
tier: str # only what consumers need
@staticmethod
def from_customer(customer: Customer) -> 'CustomerSnapshot':
return CustomerSnapshot(
id=str(customer.id),
status=customer.status.value,
tier=customer.loyalty_tier.display_name
)
Characteristics of good Contract Coupling:
For each module, estimate volatility based on:
4.1 Subdomain type (preferred) — see table in Phase 1
4.2 Git analysis (when available):
# Commits per file in the last 6 months
git log --since="6 months ago" --format="" --name-only | sort | uniq -c | sort -rn | head -20
# Files that change together frequently (temporal coupling)
# High co-change = possible undeclared functional coupling
4.3 Code signals:
4.4 Inferred volatility
Even a supporting subdomain module may have high volatility if:
For each coupled pair (A → B):
Simplified scale (0 = low, 1 = high):
| Dimension | 0 (Low) | 1 (High) |
|---|---|---|
| Strength | Contract coupling | Intrusive coupling |
| Distance | Same object/namespace | Different services |
| Volatility | Generic/Supporting subdomain | Core subdomain |
Maintenance effort formula:
MAINTENANCE_EFFORT = STRENGTH × DISTANCE × VOLATILITY
(0 in any dimension = low effort)
Classification table:
| Strength | Distance | Volatility | Diagnosis |
|---|---|---|---|
| High | High | High | 🔴 CRITICAL — Global complexity + high change cost |
| High | High | Low | 🟡 ACCEPTABLE — Strong but stable (e.g. legacy integration) |
| High | Low | High | 🟢 GOOD — High cohesion (change together, live together) |
| High | Low | Low | 🟢 GOOD — Strong but static |
| Low | High | High | 🟢 GOOD — Loose coupling (separate and independent) |
| Low | High | Low | 🟢 GOOD — Loose coupling and stable |
| Low | Low | High | 🟠 ATTENTION — Local complexity (mixes unrelated components) |
| Low | Low | Low | 🟡 ACCEPTABLE — May generate noise, but low cost |
Structure the report in sections:
CODEBASE: [name]
MODULES ANALYZED: N
DEPENDENCIES MAPPED: N
CRITICAL ISSUES: N
MODERATE ISSUES: N
OVERALL HEALTH SCORE: [Healthy / Attention / Critical]
Present the annotated graph:
[ModuleA] --[INTRUSIVE]-----------> [ModuleB]
[ModuleC] --[CONTRACT]------------> [ModuleD]
[ModuleE] --[FUNCTIONAL:symmetric]-> [ModuleF]
For each critical or moderate issue:
ISSUE: [descriptive name]
────────────────────────────────────────
Modules involved: A → B
Coupling type: Functional Coupling (symmetric)
Connascence level: Connascence of Value
Evidence in code:
[snippet or description of found pattern]
Dimensions:
• Strength: HIGH (Functional - symmetric)
• Distance: HIGH (separate services)
• Volatility: HIGH (core subdomain)
Balance Score: CRITICAL 🔴
Maintenance: High — frequent changes propagate over long distance
Impact: Any change to business rule [X] requires simultaneous
update in [A] and [B], which belong to different teams.
Recommendation:
→ Extract shared logic to a dedicated module that both can
reference (DRY + contract coupling)
→ Or: Accept duplication and explicitly document the coupling
(if volatility is lower than it appears)
✅ [ModuleX] uses dedicated integration DTOs — contract coupling well implemented
✅ [ServiceY] exposes only necessary data via API — minimizes model coupling
✅ [PackageZ] encapsulates its internal model well — low implementation leakage
High priority (high impact, blocking evolution):
Medium priority (improve architectural health): 2. ...
Low priority (incremental improvements): 3. ...
| Pattern found | Integration Strength | Action |
|---|---|---|
| Reflection to access private members | Intrusive | Refactor urgently |
| Reading another service's DB | Intrusive | Refactor urgently |
| Duplicated business logic | Functional (symmetric) | Extract to shared module |
| Distributed transaction / Saga | Functional (transactional) | Evaluate if cohesion would be better |
| Mandatory execution order | Functional (sequential) | Document protocol or encapsulate |
| Rich domain object returned | Model coupling | Create integration DTO |
| Internal enum shared externally | Model coupling | Create public contract enum |
| Use-case-specific DTO | Contract coupling | ✅ Correct pattern |
| Versioned public interface/protocol | Contract coupling | ✅ Correct pattern |
| Anti-Corruption Layer | Contract coupling | ✅ Correct pattern |
For Integration Strength:
For Distance:
For Volatility:
For Balance:
These concepts are based on Balancing Coupling in Software Design by Vlad Khononov (Addison-Wesley).
Prerequisites
Time Estimate
15-45 minutes depending on use case complexity
Steps
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Use when skill capabilities match your task, clear ROI on time saved, and you can validate outputs. Best for repetitive tasks, learning, and quality improvement.
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Avoid when task requires deep expertise you can't validate, involves sensitive decisions, or when learning process is more valuable than speed of completion.
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We added coupling-analysis from the explainx registry; install was straightforward and the SKILL.md answered most questions upfront.
We added coupling-analysis from the explainx registry; install was straightforward and the SKILL.md answered most questions upfront.
Solid pick for teams standardizing on skills: coupling-analysis is focused, and the summary matches what you get after install.
coupling-analysis reduced setup friction for our internal harness; good balance of opinion and flexibility.
coupling-analysis fits our agent workflows well — practical, well scoped, and easy to wire into existing repos.
Registry listing for coupling-analysis matched our evaluation — installs cleanly and behaves as described in the markdown.
We added coupling-analysis from the explainx registry; install was straightforward and the SKILL.md answered most questions upfront.
Useful defaults in coupling-analysis — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
coupling-analysis fits our agent workflows well — practical, well scoped, and easy to wire into existing repos.
coupling-analysis fits our agent workflows well — practical, well scoped, and easy to wire into existing repos.
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