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Name: Dependency
Author: duc01226

// [Project Management] Use when you need to map and visualize feature dependencies between modules, services, and work items.

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updated:May 6, 2026 at 08:19

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name	dependency
description	[Project Management] Use when you need to map and visualize feature dependencies between modules, services, and work items.

Codex compatibility note:

Invoke repository skills with $skill-name in Codex; this mirrored copy rewrites legacy Claude /skill-name references.

Prefer the plan-hard skill for planning guidance in this Codex mirror.

Task tracker mandate: BEFORE executing any workflow or skill step, create/update task tracking for all steps and keep it synchronized as progress changes.

User-question prompts mean to ask the user directly in Codex.

Ignore Claude-specific mode-switch instructions when they appear.

Strict execution contract: when a user explicitly invokes a skill, execute that skill protocol as written.

Subagent authorization: when a skill is user-invoked or AI-detected and its protocol requires subagents, that skill activation authorizes use of the required spawn_agent subagent(s) for that task.

Do not skip, reorder, or merge protocol steps unless the user explicitly approves the deviation first.

For workflow skills, execute each listed child-skill step explicitly and report step-by-step evidence.

If a required step/tool cannot run in this environment, stop and ask the user before adapting.

Codex Project-Reference Loading (No Hooks)

Codex does not receive Claude hook-based doc injection. When coding, planning, debugging, testing, or reviewing, open project docs explicitly using this routing.

Always read:

docs/project-config.json (project-specific paths, commands, modules, and workflow/test settings)
docs/project-reference/docs-index-reference.md (routes to the full docs/project-reference/* catalog)
docs/project-reference/lessons.md (always-on guardrails and anti-patterns)

Situation-based docs:

Backend/CQRS/API/domain/entity changes: backend-patterns-reference.md, domain-entities-reference.md, project-structure-reference.md
Frontend/UI/styling/design-system: frontend-patterns-reference.md, scss-styling-guide.md, design-system/README.md
Spec/test-case planning or TC mapping: feature-docs-reference.md
Integration test implementation/review: integration-test-reference.md
E2E test implementation/review: e2e-test-reference.md
Code review/audit work: code-review-rules.md plus domain docs above based on changed files

Do not read all docs blindly. Start from docs-index-reference.md, then open only relevant files for the task.

Quick Summary

Goal: Analyze and visualize dependencies between features, services, or work items to identify blockers and critical paths.

Workflow:

Identify Scope — Single feature, module, or full release
Classify Dependencies — Data, Service, UI, or Infrastructure types
Build Graph — Create Mermaid dependency diagram
Find Critical Path — Longest blocking chain; mark ready-to-start items
Deliver Report — Summary, graph, critical path, risks

Key Rules:

Respect microservice boundaries (cross-service = message bus only)
Flag circular dependencies as errors
Not for package/npm upgrades (use package-upgrade instead)

Be skeptical. Apply critical thinking, sequential thinking. Every claim needs traced proof, confidence percentages (Idea should be more than 80%).

Dependency Mapping

Purpose

Analyze and visualize dependencies between features, services, modules, or work items to identify blockers, critical paths, and safe execution order.

When to Use

Planning feature implementation sequence across modules
Identifying what blocks a specific feature or work item
Mapping cross-service dependencies (backend-to-backend, frontend-to-backend)
Understanding critical path for a release or milestone
Analyzing impact of changing a shared module or entity

When NOT to Use

Single-service code changes with no cross-boundary impact -- just implement directly
Performance analysis -- use arch-performance-optimization instead
Security dependency auditing -- use arch-security-review instead
Package/npm dependency upgrades -- use package-upgrade instead

Prerequisites

Read the feature/PBI/plan files to understand scope
Access to docs/project-reference/project-structure-reference.md for service boundary reference
Understand the project's microservice boundaries (search src/Services/ for service list)

Workflow

Step 1: Identify Scope

Determine what to map:

Single feature: Find all files, services, and entities it touches
Module/service: Map all inbound and outbound dependencies
Release/milestone: Map all features and their inter-dependencies

Step 2: Classify Dependencies

For each dependency found, classify by type:

Type	Direction	Description	Example
Data	Entity A requires Entity B	Foreign key, navigation property, shared ID	Employee requires Company
Service	Service A calls Service B	Message bus, API call, event consumer	Service A consumes entity events from Service B
UI	Component A embeds Component B	Shared component, library dependency	Feature form uses shared component library select
Infrastructure	Feature needs infra change	Database migration, config, new queue	New feature needs Redis cache key

Step 3: Build Dependency Graph

Use Mermaid syntax for visualization:

graph TD
    A[Feature A] -->|data| B[Feature B]
    A -->|service| C[Feature C]
    B -->|blocks| D[Feature D]
    C -->|blocks| D
    style D fill:#f96,stroke:#333

Step 4: Identify Critical Path

Find the longest chain of blocking dependencies
Mark items with no blockers as "ready to start"
Flag circular dependencies as errors

Step 5: Deliver Report

Output structured dependency report (see Output Format).

Output Format

## Dependency Map: [Feature/Module Name]

### Summary

- Total items: N
- Ready to start: N (no blockers)
- Blocked: N
- Critical path length: N steps

### Dependency Graph

[Mermaid diagram]

### Critical Path

1. [Item A] -- no blockers, estimated: Xd
2. [Item B] -- blocked by: A, estimated: Xd
3. [Item C] -- blocked by: B, estimated: Xd

### Dependency Details

| Item | Type                  | Depends On | Blocks | Status        |
| ---- | --------------------- | ---------- | ------ | ------------- |
| ...  | data/service/UI/infra | ...        | ...    | ready/blocked |

### Risks

- [Circular dependency / tight coupling / single point of failure]

Examples

Example 1: Backend Cross-Service Feature

Input: "Map dependencies for adding a new Coaching feature in {ServiceA}"

Analysis:

graph TD
    E[Employee Entity - ServiceA] -->|data| C[Coaching Entity]
    U[User Entity - AuthService] -->|service| C
    C -->|service| N[Notification - ServiceB]
    C -->|UI| CF[Coaching Form Component]
    CF -->|UI| BC[shared-components select]

Critical path: Employee Entity -> Coaching Entity -> Coaching API -> Coaching Form Ready to start: Employee Entity already exists, shared component select exists Blocked: Coaching Entity creation, then API, then UI

Example 2: Frontend Module Dependency

Input: "What blocks the new Dashboard widget in {AnalyticsService}?"

Analysis:

graph TD
    GA[Source API - ServiceA] -->|service| GE[Event Bus Message]
    GE -->|service| GC[Consumer - AnalyticsService]
    GC -->|data| GS[Summary Entity]
    GS -->|UI| GW[Dashboard Widget]
    GW -->|UI| DC[Dashboard Container]

Blockers identified:

Event Bus Message producer must exist in ServiceA (exists: yes)
Consumer must be created in AnalyticsService (exists: no -- BLOCKER)
Summary Entity for aggregated data (exists: no -- BLOCKER)

Related Skills

project-manager -- for sprint planning and status tracking
feature-implementation -- for implementing features after dependency analysis
arch-cross-service-integration -- for designing cross-service communication
package-upgrade -- for npm/NuGet package dependency upgrades

[IMPORTANT] Use task tracking to break ALL work into small tasks BEFORE starting — including tasks for each file read. This prevents context loss from long files. For simple tasks, AI MUST ATTENTION ask user whether to skip.

Prerequisites: MUST ATTENTION READ before executing:

AI Mistake Prevention — Failure modes to avoid on every task:

Check downstream references before deleting. Deleting components causes documentation and code staleness cascades. Map all referencing files before removal. Verify AI-generated content against actual code. AI hallucinates APIs, class names, and method signatures. Always grep to confirm existence before documenting or referencing. Trace full dependency chain after edits. Changing a definition misses downstream variables and consumers derived from it. Always trace the full chain. Trace ALL code paths when verifying correctness. Confirming code exists is not confirming it executes. Always trace early exits, error branches, and conditional skips — not just happy path. When debugging, ask "whose responsibility?" before fixing. Trace whether bug is in caller (wrong data) or callee (wrong handling). Fix at responsible layer — never patch symptom site. Assume existing values are intentional — ask WHY before changing. Before changing any constant, limit, flag, or pattern: read comments, check git blame, examine surrounding code. Verify ALL affected outputs, not just the first. Changes touching multiple stacks require verifying EVERY output. One green check is not all green checks. Holistic-first debugging — resist nearest-attention trap. When investigating any failure, list EVERY precondition first (config, env vars, DB names, endpoints, DI registrations, data preconditions), then verify each against evidence before forming any code-layer hypothesis. Surgical changes — apply the diff test. Bug fix: every changed line must trace directly to the bug. Don't restyle or improve adjacent code. Enhancement task: implement improvements AND announce them explicitly. Surface ambiguity before coding — don't pick silently. If request has multiple interpretations, present each with effort estimate and ask. Never assume all-records, file-based, or more complex path.

Critical Thinking Mindset — Apply critical thinking, sequential thinking. Every claim needs traced proof, confidence >80% to act. Anti-hallucination: Never present guess as fact — cite sources for every claim, admit uncertainty freely, self-check output for errors, cross-reference independently, stay skeptical of own confidence — certainty without evidence root of all hallucination.

Understand Code First — HARD-GATE: Do NOT write, plan, or fix until you READ existing code.

Search 3+ similar patterns (grep/glob) — cite file:line evidence

Read existing files in target area — understand structure, base classes, conventions

Run python .claude/scripts/code_graph trace <file> --direction both --json when .code-graph/graph.db exists

Map dependencies via connections or callers_of — know what depends on your target

Write investigation to .ai/workspace/analysis/ for non-trivial tasks (3+ files)

Re-read analysis file before implementing — never work from memory alone

NEVER invent new patterns when existing ones work — match exactly or document deviation

BLOCKED until: - [ ] Read target files - [ ] Grep 3+ patterns - [ ] Graph trace (if graph.db exists) - [ ] Assumptions verified with evidence

MANDATORY IMPORTANT MUST ATTENTION search 3+ existing patterns and read code BEFORE any modification. Run graph trace when graph.db exists.

MUST ATTENTION apply critical thinking — every claim needs traced proof, confidence >80% to act. Anti-hallucination: never present guess as fact.

MUST ATTENTION apply AI mistake prevention — holistic-first debugging, fix at responsible layer, surface ambiguity before coding, re-read files after compaction.

Closing Reminders

MANDATORY IMPORTANT MUST ATTENTION break work into small todo tasks using task tracking BEFORE starting
MANDATORY IMPORTANT MUST ATTENTION search codebase for 3+ similar patterns before creating new code
MANDATORY IMPORTANT MUST ATTENTION cite file:line evidence for every claim (confidence >80% to act)
MANDATORY IMPORTANT MUST ATTENTION add a final review todo task to verify work quality MANDATORY IMPORTANT MUST ATTENTION READ the following files before starting:

[TASK-PLANNING] Before acting, analyze task scope and systematically break it into small todo tasks and sub-tasks using task tracking.

Hookless Prompt Protocol Mirror (Auto-Synced)

Source: .claude/hooks/lib/prompt-injections.cjs + .claude/.ck.json

[WORKFLOW-EXECUTION-PROTOCOL] [BLOCKING] Workflow Execution Protocol — MANDATORY IMPORTANT MUST CRITICAL. Do not skip for any reason.

DETECT: Match prompt against workflow catalog
ANALYZE: Find best-match workflow AND evaluate if a custom step combination would fit better
ASK (REQUIRED FORMAT): Use a direct user question with this structure:
- Question: "Which workflow do you want to activate?"
- Option 1: "Activate [BestMatch Workflow] (Recommended)"
- Option 2: "Activate custom workflow: [step1 → step2 → ...]" (include one-line rationale)
ACTIVATE (if confirmed): Call $workflow-start <workflowId> for standard; sequence custom steps manually
CREATE TASKS: task tracking for ALL workflow steps
EXECUTE: Follow each step in sequence [CRITICAL-THINKING-MINDSET] Apply critical thinking, sequential thinking. Every claim needs traced proof, confidence >80% to act. Anti-hallucination principle: Never present guess as fact — cite sources for every claim, admit uncertainty freely, self-check output for errors, cross-reference independently, stay skeptical of own confidence — certainty without evidence root of all hallucination. AI Attention principle (Primacy-Recency): Put the 3 most critical rules at both top and bottom of long prompts/protocols so instruction adherence survives long context windows.

Learned Lessons

Lessons Learned

[CRITICAL] Hard-won project debugging/architecture rules. MUST ATTENTION apply BEFORE forming hypothesis or writing code.

Quick Summary

Goal: Prevent recurrence of known failure patterns — debugging, architecture, naming, AI orchestration, environment.

Top Rules (apply always):

MUST ATTENTION verify ALL preconditions (config, env, DB names, DI regs) BEFORE code-layer hypothesis
MUST ATTENTION fix responsible layer — NEVER patch symptom sites with caller-specific defensive code
MUST ATTENTION use ExecuteInjectScopedAsync for parallel async + repo/UoW — NEVER ExecuteUowTask
MUST ATTENTION name by PURPOSE not CONTENT — adding member forces rename = abstraction broken
MUST ATTENTION persist sub-agent findings incrementally after each file — NEVER batch at end
MUST ATTENTION Windows bash: verify Python alias (where python/where py) — NEVER assume python/python3 resolves

Debugging & Root Cause Reasoning

[2026-04-11] Holistic-first: verify environment before code. Failure → list ALL preconditions (config, env vars, DB names, endpoints, DI regs, credentials, permissions, data prerequisites) → verify each via evidence (grep/cat/query) BEFORE code-layer hypothesis. Worst rabbit holes: diving nearest layer while bug sits elsewhere — e.g., hours debugging "sync timeout", real cause: test appsettings pointing wrong DB. Cheapest check first.
[2026-04-01] Ask "whose responsibility?" before fixing. Trace: bug in caller (wrong data) or callee (wrong handling)? Fix responsible layer — NEVER patch symptom site masking real issue.
[2026-04-01] Trace data lifecycle, not error site. Follow data: creation → transformation → consumption. Bug usually where data created wrong, not consumed.
[2026-04-01] Code is caller-agnostic. Functions/handlers/consumers don't know who invokes them. Comments/guards/messages describe business intent — NEVER reference specific callers (tests, seeders, scripts).

Architecture Invariants

[2026-03-31] ParallelAsync + repo/UoW MUST use ExecuteInjectScopedAsync, NEVER ExecuteUowTask. ExecuteUowTask creates new UoW but reuses outer DI scope (same DbContext) — parallel iterations sharing non-thread-safe DbContext silently corrupt data. ExecuteInjectScopedAsync creates new UoW + new DI scope (fresh repo per iteration).
[2026-03-31] Bus message naming MUST include service name prefix — core services NEVER consume feature events. Prefix declares schema ownership (AccountUserEntityEventBusMessage = Accounts owns). Core services (Accounts, Communication) are leaders. Feature services (Growth, Talents) sending to core MUST use {CoreServiceName}...RequestBusMessage — never define own event for core to consume.

Naming & Abstraction

[2026-04-12] Name PURPOSE not CONTENT — "OrXxx" anti-pattern. HrManagerOrHrOrPayrollHrOperationsPolicy names set members, not what it guards. Add role → rename = broken abstraction. Rule: names express DOES/GUARDS, not CONTAINS. Test: adding/removing member forces rename? YES = content-driven = bad → rename to purpose (e.g., HrOperationsAccessPolicy). Nuance: "Or" fine in behavioral idioms (FirstOrDefault, SuccessOrThrow) — expresses HAPPENS, not membership.

Environment & Tooling

[2026-04-20] Windows bash: NEVER assume python/python3 resolves — verify alias first. Python may not be in bash PATH under those names. Check: where python / where py. Prefer py (Windows Python Launcher) for one-liners, node if JS alternative exists.

Test-specific lessons → docs/project-reference/integration-test-reference.md Lessons Learned section. Production-code anti-patterns → docs/project-reference/backend-patterns-reference.md Anti-Patterns section. Generic debugging/refactoring reminders → System Lessons in .claude/hooks/lib/prompt-injections.cjs.

Closing Reminders

IMPORTANT MUST ATTENTION holistic-first: verify ALL preconditions (config, env, DB names, endpoints, DI regs) BEFORE code-layer hypothesis — cheapest check first
IMPORTANT MUST ATTENTION fix responsible layer — NEVER patch symptom site; trace caller (wrong data) vs callee (wrong handling), fix root owner
IMPORTANT MUST ATTENTION parallel async + repo/UoW → ALWAYS ExecuteInjectScopedAsync, NEVER ExecuteUowTask (shared DbContext = silent data corruption)
IMPORTANT MUST ATTENTION bus message prefix = schema ownership; feature services NEVER define events for core services — use {CoreServiceName}...RequestBusMessage
IMPORTANT MUST ATTENTION name by PURPOSE — adding/removing member forces rename = broken abstraction
IMPORTANT MUST ATTENTION sub-agents MUST write findings after each file/section — NEVER batch all findings into one final write
IMPORTANT MUST ATTENTION Windows bash: NEVER assume python/python3 resolves — run where python/where py first, use py launcher or node

[LESSON-LEARNED-REMINDER] [BLOCKING] Task Planning & Continuous Improvement — MANDATORY. Do not skip.

Break work into small tasks (task tracking) before starting. Add final task: "Analyze AI mistakes & lessons learned".

Extract lessons — ROOT CAUSE ONLY, not symptom fixes:

Name the FAILURE MODE (reasoning/assumption failure), not symptom — "assumed API existed without reading source" not "used wrong enum value".
Generality test: does this failure mode apply to ≥3 contexts/codebases? If not, abstract one level up.
Write as a universal rule — strip project-specific names/paths/classes. Useful on any codebase.
Consolidate: multiple mistakes sharing one failure mode → ONE lesson.
Recurrence gate: "Would this recur in future session WITHOUT this reminder?" — No → skip $learn.
Auto-fix gate: "Could $code-review/$code-simplifier/$security/$lint catch this?" — Yes → improve review skill instead.
BOTH gates pass → ask user to run $learn. [TASK-PLANNING] [MANDATORY] BEFORE executing any workflow or skill step, create/update task tracking for all planned steps, then keep it synchronized as each step starts/completes.

name	dependency
description	[Project Management] Use when you need to map and visualize feature dependencies between modules, services, and work items.

Codex compatibility note:

Invoke repository skills with $skill-name in Codex; this mirrored copy rewrites legacy Claude /skill-name references.

Prefer the plan-hard skill for planning guidance in this Codex mirror.

Task tracker mandate: BEFORE executing any workflow or skill step, create/update task tracking for all steps and keep it synchronized as progress changes.

User-question prompts mean to ask the user directly in Codex.

Ignore Claude-specific mode-switch instructions when they appear.

Strict execution contract: when a user explicitly invokes a skill, execute that skill protocol as written.

Subagent authorization: when a skill is user-invoked or AI-detected and its protocol requires subagents, that skill activation authorizes use of the required spawn_agent subagent(s) for that task.

Do not skip, reorder, or merge protocol steps unless the user explicitly approves the deviation first.

For workflow skills, execute each listed child-skill step explicitly and report step-by-step evidence.

If a required step/tool cannot run in this environment, stop and ask the user before adapting.

Codex Project-Reference Loading (No Hooks)

Codex does not receive Claude hook-based doc injection. When coding, planning, debugging, testing, or reviewing, open project docs explicitly using this routing.

Always read:

docs/project-config.json (project-specific paths, commands, modules, and workflow/test settings)
docs/project-reference/docs-index-reference.md (routes to the full docs/project-reference/* catalog)
docs/project-reference/lessons.md (always-on guardrails and anti-patterns)

Situation-based docs:

Backend/CQRS/API/domain/entity changes: backend-patterns-reference.md, domain-entities-reference.md, project-structure-reference.md
Frontend/UI/styling/design-system: frontend-patterns-reference.md, scss-styling-guide.md, design-system/README.md
Spec/test-case planning or TC mapping: feature-docs-reference.md
Integration test implementation/review: integration-test-reference.md
E2E test implementation/review: e2e-test-reference.md
Code review/audit work: code-review-rules.md plus domain docs above based on changed files

Do not read all docs blindly. Start from docs-index-reference.md, then open only relevant files for the task.

Quick Summary

Goal: Analyze and visualize dependencies between features, services, or work items to identify blockers and critical paths.

Workflow:

Identify Scope — Single feature, module, or full release
Classify Dependencies — Data, Service, UI, or Infrastructure types
Build Graph — Create Mermaid dependency diagram
Find Critical Path — Longest blocking chain; mark ready-to-start items
Deliver Report — Summary, graph, critical path, risks

Key Rules:

Respect microservice boundaries (cross-service = message bus only)
Flag circular dependencies as errors
Not for package/npm upgrades (use package-upgrade instead)

Be skeptical. Apply critical thinking, sequential thinking. Every claim needs traced proof, confidence percentages (Idea should be more than 80%).

Dependency Mapping

Purpose

Analyze and visualize dependencies between features, services, modules, or work items to identify blockers, critical paths, and safe execution order.

When to Use

Planning feature implementation sequence across modules
Identifying what blocks a specific feature or work item
Mapping cross-service dependencies (backend-to-backend, frontend-to-backend)
Understanding critical path for a release or milestone
Analyzing impact of changing a shared module or entity

When NOT to Use

Single-service code changes with no cross-boundary impact -- just implement directly
Performance analysis -- use arch-performance-optimization instead
Security dependency auditing -- use arch-security-review instead
Package/npm dependency upgrades -- use package-upgrade instead

Prerequisites

Read the feature/PBI/plan files to understand scope
Access to docs/project-reference/project-structure-reference.md for service boundary reference
Understand the project's microservice boundaries (search src/Services/ for service list)

Workflow

Step 1: Identify Scope

Determine what to map:

Single feature: Find all files, services, and entities it touches
Module/service: Map all inbound and outbound dependencies
Release/milestone: Map all features and their inter-dependencies

Step 2: Classify Dependencies

For each dependency found, classify by type:

Type	Direction	Description	Example
Data	Entity A requires Entity B	Foreign key, navigation property, shared ID	Employee requires Company
Service	Service A calls Service B	Message bus, API call, event consumer	Service A consumes entity events from Service B
UI	Component A embeds Component B	Shared component, library dependency	Feature form uses shared component library select
Infrastructure	Feature needs infra change	Database migration, config, new queue	New feature needs Redis cache key

Step 3: Build Dependency Graph

Use Mermaid syntax for visualization:

graph TD
    A[Feature A] -->|data| B[Feature B]
    A -->|service| C[Feature C]
    B -->|blocks| D[Feature D]
    C -->|blocks| D
    style D fill:#f96,stroke:#333

Step 4: Identify Critical Path

Find the longest chain of blocking dependencies
Mark items with no blockers as "ready to start"
Flag circular dependencies as errors

Step 5: Deliver Report

Output structured dependency report (see Output Format).

Output Format

## Dependency Map: [Feature/Module Name]

### Summary

- Total items: N
- Ready to start: N (no blockers)
- Blocked: N
- Critical path length: N steps

### Dependency Graph

[Mermaid diagram]

### Critical Path

1. [Item A] -- no blockers, estimated: Xd
2. [Item B] -- blocked by: A, estimated: Xd
3. [Item C] -- blocked by: B, estimated: Xd

### Dependency Details

| Item | Type                  | Depends On | Blocks | Status        |
| ---- | --------------------- | ---------- | ------ | ------------- |
| ...  | data/service/UI/infra | ...        | ...    | ready/blocked |

### Risks

- [Circular dependency / tight coupling / single point of failure]

Examples

Example 1: Backend Cross-Service Feature

Input: "Map dependencies for adding a new Coaching feature in {ServiceA}"

Analysis:

graph TD
    E[Employee Entity - ServiceA] -->|data| C[Coaching Entity]
    U[User Entity - AuthService] -->|service| C
    C -->|service| N[Notification - ServiceB]
    C -->|UI| CF[Coaching Form Component]
    CF -->|UI| BC[shared-components select]

Example 2: Frontend Module Dependency

Input: "What blocks the new Dashboard widget in {AnalyticsService}?"

Analysis:

graph TD
    GA[Source API - ServiceA] -->|service| GE[Event Bus Message]
    GE -->|service| GC[Consumer - AnalyticsService]
    GC -->|data| GS[Summary Entity]
    GS -->|UI| GW[Dashboard Widget]
    GW -->|UI| DC[Dashboard Container]

Blockers identified:

Event Bus Message producer must exist in ServiceA (exists: yes)
Consumer must be created in AnalyticsService (exists: no -- BLOCKER)
Summary Entity for aggregated data (exists: no -- BLOCKER)

Related Skills

project-manager -- for sprint planning and status tracking
feature-implementation -- for implementing features after dependency analysis
arch-cross-service-integration -- for designing cross-service communication
package-upgrade -- for npm/NuGet package dependency upgrades

[IMPORTANT] Use task tracking to break ALL work into small tasks BEFORE starting — including tasks for each file read. This prevents context loss from long files. For simple tasks, AI MUST ATTENTION ask user whether to skip.

Prerequisites: MUST ATTENTION READ before executing:

AI Mistake Prevention — Failure modes to avoid on every task:

Check downstream references before deleting. Deleting components causes documentation and code staleness cascades. Map all referencing files before removal. Verify AI-generated content against actual code. AI hallucinates APIs, class names, and method signatures. Always grep to confirm existence before documenting or referencing. Trace full dependency chain after edits. Changing a definition misses downstream variables and consumers derived from it. Always trace the full chain. Trace ALL code paths when verifying correctness. Confirming code exists is not confirming it executes. Always trace early exits, error branches, and conditional skips — not just happy path. When debugging, ask "whose responsibility?" before fixing. Trace whether bug is in caller (wrong data) or callee (wrong handling). Fix at responsible layer — never patch symptom site. Assume existing values are intentional — ask WHY before changing. Before changing any constant, limit, flag, or pattern: read comments, check git blame, examine surrounding code. Verify ALL affected outputs, not just the first. Changes touching multiple stacks require verifying EVERY output. One green check is not all green checks. Holistic-first debugging — resist nearest-attention trap. When investigating any failure, list EVERY precondition first (config, env vars, DB names, endpoints, DI registrations, data preconditions), then verify each against evidence before forming any code-layer hypothesis. Surgical changes — apply the diff test. Bug fix: every changed line must trace directly to the bug. Don't restyle or improve adjacent code. Enhancement task: implement improvements AND announce them explicitly. Surface ambiguity before coding — don't pick silently. If request has multiple interpretations, present each with effort estimate and ask. Never assume all-records, file-based, or more complex path.

Critical Thinking Mindset — Apply critical thinking, sequential thinking. Every claim needs traced proof, confidence >80% to act. Anti-hallucination: Never present guess as fact — cite sources for every claim, admit uncertainty freely, self-check output for errors, cross-reference independently, stay skeptical of own confidence — certainty without evidence root of all hallucination.

Understand Code First — HARD-GATE: Do NOT write, plan, or fix until you READ existing code.

Search 3+ similar patterns (grep/glob) — cite file:line evidence

Read existing files in target area — understand structure, base classes, conventions

Run python .claude/scripts/code_graph trace <file> --direction both --json when .code-graph/graph.db exists

Map dependencies via connections or callers_of — know what depends on your target

Write investigation to .ai/workspace/analysis/ for non-trivial tasks (3+ files)

Re-read analysis file before implementing — never work from memory alone

NEVER invent new patterns when existing ones work — match exactly or document deviation

BLOCKED until: - [ ] Read target files - [ ] Grep 3+ patterns - [ ] Graph trace (if graph.db exists) - [ ] Assumptions verified with evidence

MANDATORY IMPORTANT MUST ATTENTION search 3+ existing patterns and read code BEFORE any modification. Run graph trace when graph.db exists.

MUST ATTENTION apply critical thinking — every claim needs traced proof, confidence >80% to act. Anti-hallucination: never present guess as fact.

MUST ATTENTION apply AI mistake prevention — holistic-first debugging, fix at responsible layer, surface ambiguity before coding, re-read files after compaction.

Closing Reminders

MANDATORY IMPORTANT MUST ATTENTION break work into small todo tasks using task tracking BEFORE starting
MANDATORY IMPORTANT MUST ATTENTION search codebase for 3+ similar patterns before creating new code
MANDATORY IMPORTANT MUST ATTENTION cite file:line evidence for every claim (confidence >80% to act)
MANDATORY IMPORTANT MUST ATTENTION add a final review todo task to verify work quality MANDATORY IMPORTANT MUST ATTENTION READ the following files before starting:

[TASK-PLANNING] Before acting, analyze task scope and systematically break it into small todo tasks and sub-tasks using task tracking.

Hookless Prompt Protocol Mirror (Auto-Synced)

Source: .claude/hooks/lib/prompt-injections.cjs + .claude/.ck.json

[WORKFLOW-EXECUTION-PROTOCOL] [BLOCKING] Workflow Execution Protocol — MANDATORY IMPORTANT MUST CRITICAL. Do not skip for any reason.

DETECT: Match prompt against workflow catalog
ANALYZE: Find best-match workflow AND evaluate if a custom step combination would fit better
ASK (REQUIRED FORMAT): Use a direct user question with this structure:
- Question: "Which workflow do you want to activate?"
- Option 1: "Activate [BestMatch Workflow] (Recommended)"
- Option 2: "Activate custom workflow: [step1 → step2 → ...]" (include one-line rationale)
ACTIVATE (if confirmed): Call $workflow-start <workflowId> for standard; sequence custom steps manually
CREATE TASKS: task tracking for ALL workflow steps
EXECUTE: Follow each step in sequence [CRITICAL-THINKING-MINDSET] Apply critical thinking, sequential thinking. Every claim needs traced proof, confidence >80% to act. Anti-hallucination principle: Never present guess as fact — cite sources for every claim, admit uncertainty freely, self-check output for errors, cross-reference independently, stay skeptical of own confidence — certainty without evidence root of all hallucination. AI Attention principle (Primacy-Recency): Put the 3 most critical rules at both top and bottom of long prompts/protocols so instruction adherence survives long context windows.

Learned Lessons

Lessons Learned

[CRITICAL] Hard-won project debugging/architecture rules. MUST ATTENTION apply BEFORE forming hypothesis or writing code.

Quick Summary

Goal: Prevent recurrence of known failure patterns — debugging, architecture, naming, AI orchestration, environment.

Top Rules (apply always):

MUST ATTENTION verify ALL preconditions (config, env, DB names, DI regs) BEFORE code-layer hypothesis
MUST ATTENTION fix responsible layer — NEVER patch symptom sites with caller-specific defensive code
MUST ATTENTION use ExecuteInjectScopedAsync for parallel async + repo/UoW — NEVER ExecuteUowTask
MUST ATTENTION name by PURPOSE not CONTENT — adding member forces rename = abstraction broken
MUST ATTENTION persist sub-agent findings incrementally after each file — NEVER batch at end
MUST ATTENTION Windows bash: verify Python alias (where python/where py) — NEVER assume python/python3 resolves

Debugging & Root Cause Reasoning

[2026-04-11] Holistic-first: verify environment before code. Failure → list ALL preconditions (config, env vars, DB names, endpoints, DI regs, credentials, permissions, data prerequisites) → verify each via evidence (grep/cat/query) BEFORE code-layer hypothesis. Worst rabbit holes: diving nearest layer while bug sits elsewhere — e.g., hours debugging "sync timeout", real cause: test appsettings pointing wrong DB. Cheapest check first.
[2026-04-01] Ask "whose responsibility?" before fixing. Trace: bug in caller (wrong data) or callee (wrong handling)? Fix responsible layer — NEVER patch symptom site masking real issue.
[2026-04-01] Trace data lifecycle, not error site. Follow data: creation → transformation → consumption. Bug usually where data created wrong, not consumed.
[2026-04-01] Code is caller-agnostic. Functions/handlers/consumers don't know who invokes them. Comments/guards/messages describe business intent — NEVER reference specific callers (tests, seeders, scripts).

Architecture Invariants

[2026-03-31] ParallelAsync + repo/UoW MUST use ExecuteInjectScopedAsync, NEVER ExecuteUowTask. ExecuteUowTask creates new UoW but reuses outer DI scope (same DbContext) — parallel iterations sharing non-thread-safe DbContext silently corrupt data. ExecuteInjectScopedAsync creates new UoW + new DI scope (fresh repo per iteration).
[2026-03-31] Bus message naming MUST include service name prefix — core services NEVER consume feature events. Prefix declares schema ownership (AccountUserEntityEventBusMessage = Accounts owns). Core services (Accounts, Communication) are leaders. Feature services (Growth, Talents) sending to core MUST use {CoreServiceName}...RequestBusMessage — never define own event for core to consume.

Naming & Abstraction

[2026-04-12] Name PURPOSE not CONTENT — "OrXxx" anti-pattern. HrManagerOrHrOrPayrollHrOperationsPolicy names set members, not what it guards. Add role → rename = broken abstraction. Rule: names express DOES/GUARDS, not CONTAINS. Test: adding/removing member forces rename? YES = content-driven = bad → rename to purpose (e.g., HrOperationsAccessPolicy). Nuance: "Or" fine in behavioral idioms (FirstOrDefault, SuccessOrThrow) — expresses HAPPENS, not membership.

Environment & Tooling

[2026-04-20] Windows bash: NEVER assume python/python3 resolves — verify alias first. Python may not be in bash PATH under those names. Check: where python / where py. Prefer py (Windows Python Launcher) for one-liners, node if JS alternative exists.

Test-specific lessons → docs/project-reference/integration-test-reference.md Lessons Learned section. Production-code anti-patterns → docs/project-reference/backend-patterns-reference.md Anti-Patterns section. Generic debugging/refactoring reminders → System Lessons in .claude/hooks/lib/prompt-injections.cjs.

Closing Reminders

IMPORTANT MUST ATTENTION holistic-first: verify ALL preconditions (config, env, DB names, endpoints, DI regs) BEFORE code-layer hypothesis — cheapest check first
IMPORTANT MUST ATTENTION fix responsible layer — NEVER patch symptom site; trace caller (wrong data) vs callee (wrong handling), fix root owner
IMPORTANT MUST ATTENTION parallel async + repo/UoW → ALWAYS ExecuteInjectScopedAsync, NEVER ExecuteUowTask (shared DbContext = silent data corruption)
IMPORTANT MUST ATTENTION bus message prefix = schema ownership; feature services NEVER define events for core services — use {CoreServiceName}...RequestBusMessage
IMPORTANT MUST ATTENTION name by PURPOSE — adding/removing member forces rename = broken abstraction
IMPORTANT MUST ATTENTION sub-agents MUST write findings after each file/section — NEVER batch all findings into one final write
IMPORTANT MUST ATTENTION Windows bash: NEVER assume python/python3 resolves — run where python/where py first, use py launcher or node

[LESSON-LEARNED-REMINDER] [BLOCKING] Task Planning & Continuous Improvement — MANDATORY. Do not skip.

Break work into small tasks (task tracking) before starting. Add final task: "Analyze AI mistakes & lessons learned".

Extract lessons — ROOT CAUSE ONLY, not symptom fixes:

Name the FAILURE MODE (reasoning/assumption failure), not symptom — "assumed API existed without reading source" not "used wrong enum value".
Generality test: does this failure mode apply to ≥3 contexts/codebases? If not, abstract one level up.
Write as a universal rule — strip project-specific names/paths/classes. Useful on any codebase.
Consolidate: multiple mistakes sharing one failure mode → ONE lesson.
Recurrence gate: "Would this recur in future session WITHOUT this reminder?" — No → skip $learn.
Auto-fix gate: "Could $code-review/$code-simplifier/$security/$lint catch this?" — Yes → improve review skill instead.
BOTH gates pass → ask user to run $learn. [TASK-PLANNING] [MANDATORY] BEFORE executing any workflow or skill step, create/update task tracking for all planned steps, then keep it synchronized as each step starts/completes.