Focused Fix
Use when the user asks to fix, debug, or make a specific feature/module/area work end-to-end. Triggers: 'make X work', 'fix the Y feature', 'the Z module is broken', 'focus on [area]'. Not for quic...
Use when the user asks to fix, debug, or make a specific feature/module/area work end-to-end. Triggers: 'make X work', 'fix the Y feature', 'the Z module is broken', 'focus on [area]'. Not for quick single-bug fixes — this is for systematic deep-dive repair across all files and dependencies.
Install
Quick install
npx skills add https://github.com/alirezarezvani/claude-skills/tree/main/engineering/skills/focused-fixnpx skills add alirezarezvani/claude-skills --skill focused-fix --agent claude-codenpx skills add alirezarezvani/claude-skills --skill focused-fix --agent cursornpx skills add alirezarezvani/claude-skills --skill focused-fix --agent codexnpx skills add alirezarezvani/claude-skills --skill focused-fix --agent opencodenpx skills add alirezarezvani/claude-skills --skill focused-fix --agent github-copilotnpx skills add alirezarezvani/claude-skills --skill focused-fix --agent windsurfMore install options
Shorthand — useful for multi-skill repos:
npx skills add alirezarezvani/claude-skills --skill focused-fixManual — clone the repo and drop the folder into your agent's skills directory:
git clone https://github.com/alirezarezvani/claude-skills.gitcp -r claude-skills/engineering/skills/focused-fix ~/.claude/skills/Focused Fix — Deep-Dive Feature Repair
When to Use
Activate when the user asks to fix, debug, or make a specific feature/module/area work. Key triggers:
- "make X work"
- "fix the Y feature"
- "the Z module is broken"
- "focus on [area]"
- "this feature needs to work properly"
This is NOT for quick single-bug fixes (use systematic-debugging for that). This is for when an entire feature or module needs systematic repair — tracing every dependency, reading logs, checking tests, mapping the full dependency graph.
digraph when_to_use {
"User reports feature broken" [shape=diamond];
"Single bug or symptom?" [shape=diamond];
"Use systematic-debugging" [shape=box];
"Entire feature/module needs repair?" [shape=diamond];
"Use focused-fix" [shape=box];
"Something else" [shape=box];
"User reports feature broken" -> "Single bug or symptom?";
"Single bug or symptom?" -> "Use systematic-debugging" [label="yes"];
"Single bug or symptom?" -> "Entire feature/module needs repair?" [label="no"];
"Entire feature/module needs repair?" -> "Use focused-fix" [label="yes"];
"Entire feature/module needs repair?" -> "Something else" [label="no"];
}The Iron Law
NO FIXES WITHOUT COMPLETING SCOPE → TRACE → DIAGNOSE FIRSTIf you haven't finished Phase 3, you cannot propose fixes. Period.
Violating the letter of these phases is violating the spirit of focused repair.
Protocol — STRICTLY follow these 5 phases IN ORDER
digraph phases {
rankdir=LR;
SCOPE [shape=box, label="Phase 1\nSCOPE"];
TRACE [shape=box, label="Phase 2\nTRACE"];
DIAGNOSE [shape=box, label="Phase 3\nDIAGNOSE"];
FIX [shape=box, label="Phase 4\nFIX"];
VERIFY [shape=box, label="Phase 5\nVERIFY"];
SCOPE -> TRACE -> DIAGNOSE -> FIX -> VERIFY;
FIX -> DIAGNOSE [label="fix broke\nsomething else"];
FIX -> ESCALATE [label="3+ fixes\ncreate new issues"];
ESCALATE [shape=doubleoctagon, label="STOP\nQuestion Architecture\nDiscuss with User"];
}Phase 1: SCOPE — Map the Feature Boundary
Before touching any code, understand the full scope of the feature.
- Ask the user: "Which feature/folder should I focus on?" if not already clear
- Identify the PRIMARY folder/files for this feature
- Map EVERY file in that folder — read each one, understand its purpose
- Create a feature manifest:
FEATURE SCOPE:
Primary path: src/features/auth/
Entry points: [files that are imported by other parts of the app]
Internal files: [files only used within this feature]
Total files: N
Total lines: NPhase 2: TRACE — Map All Dependencies (Inside AND Outside)
Trace every connection this feature has to the rest of the codebase.
INBOUND (what this feature imports):
- For every import statement in every file in the feature folder:
- Trace it to its source
- Verify the source file exists
- Verify the imported entity (function, type, component) exists and is exported
- Check if the types/signatures match what the feature expects
- Check for:
- Environment variables used (grep for process.env, import.meta.env, os.environ, etc.)
- Config files referenced
- Database models/schemas used
- API endpoints called
- Third-party packages imported
OUTBOUND (what imports this feature):
- Search the entire codebase for imports from this feature folder
- For each consumer:
- Verify they're importing entities that actually exist
- Check if they're using the correct API/interface
- Note if any consumers are using deprecated patterns
Output format:
DEPENDENCY MAP:
Inbound (this feature depends on):
src/lib/db.ts → used in auth/repository.ts (getUserById, createUser)
src/lib/jwt.ts → used in auth/service.ts (signToken, verifyToken)
@prisma/client → used in auth/repository.ts
process.env.JWT_SECRET → used in auth/service.ts
process.env.DATABASE_URL → used via prisma
Outbound (depends on this feature):
src/app/api/login/route.ts → imports { login } from auth/service
src/app/api/register/route.ts → imports { register } from auth/service
src/middleware.ts → imports { verifyToken } from auth/service
Env vars required: JWT_SECRET, DATABASE_URL
Config files: prisma/schema.prisma (User model)Phase 3: DIAGNOSE — Find Every Issue
Systematically check for problems. Run ALL of these checks:
CODE QUALITY:
- [ ] Every import resolves to a real file/export
- [ ] No circular dependencies within the feature
- [ ] Types are consistent across boundaries (no
anyat interfaces) - [ ] Error handling exists for all async operations
- [ ] No TODO/FIXME/HACK comments indicating known issues
RUNTIME:
- [ ] All required environment variables are set (check .env)
- [ ] Database migrations are up to date (if applicable)
- [ ] API endpoints return expected shapes
- [ ] No hardcoded values that should be configurable
TESTS:
- [ ] Run ALL tests related to this feature: find them by searching for imports from the feature folder
- [ ] Record every failure with full error output
- [ ] Check test coverage — are there untested code paths?
LOGS & ERRORS:
- [ ] Search for any log files, error reports, or Sentry-style error tracking
- [ ] Check git log for recent changes to this feature:
git log --oneline -20 -- <feature-path> - [ ] Check if any recent commits might have broken something:
git log --oneline -5 --all -- <files that this feature depends on>
CONFIGURATION:
- [ ] Verify all config files this feature depends on are valid
- [ ] Check for mismatches between development and production configs
- [ ] Verify third-party service credentials are valid (if testable)
ROOT-CAUSE CONFIRMATION:
For each CRITICAL issue found, confirm root cause before adding it to the fix list:
- State clearly: "I think X is the root cause because Y"
- Trace the data/control flow backward to verify — don't trust surface-level symptoms
- If the issue spans multiple components, add diagnostic logging at each boundary to identify which layer fails
- REQUIRED SUB-SKILL: For complex bugs found during diagnosis, apply
superpowers:systematic-debuggingPhase 1 (Root Cause Investigation) to confirm before proceeding
RISK LABELING:
Assign each issue a risk label:
| Risk | Criteria |
|---|---|
| HIGH | Public API surface / breaking interface contract / DB schema / auth or security logic / widely imported module (>3 callers) / git hotspot |
| MED | Internal module with tests / shared utility / config with runtime impact / internal callers of changed functions |
| LOW | Leaf module / isolated file / test-only change / single-purpose helper with no callers |
Output format:
DIAGNOSIS REPORT:
Issues found: N
CRITICAL:
1. [HIGH] [file:line] — description of issue. Root cause: [confirmed explanation]
2. [HIGH] [file:line] — description of issue. Root cause: [confirmed explanation]
WARNINGS:
1. [MED] [file:line] — description of issue
2. [LOW] [file:line] — description of issue
TESTS:
Ran: N tests
Passed: N
Failed: N
[list each failure with one-line summary]Phase 4: FIX — Repair Everything Systematically
Fix issues in this EXACT order:
- DEPENDENCIES FIRST — fix broken imports, missing packages, wrong versions
- TYPES SECOND — fix type mismatches at feature boundaries
- LOGIC THIRD — fix actual business logic bugs
- TESTS FOURTH — fix or create tests for each fix
- INTEGRATION LAST — verify the feature works end-to-end with its consumers
Rules:
- Fix ONE issue at a time
- After each fix, run the related test to confirm it works
- If a fix breaks something else, STOP and re-evaluate (go back to DIAGNOSE)
- Keep a running log of every change made
- Never change code outside the feature folder without explicitly stating why
- Fix HIGH-risk issues before MED, MED before LOW
ESCALATION RULE — 3-Strike Architecture Check:
If 3+ fixes in this phase create NEW issues (not pre-existing ones), STOP immediately.
This pattern indicates an architectural problem, not a bug collection:
- Each fix reveals new shared state / coupling / problem in a different place
- Fixes require "massive refactoring" to implement
- Each fix creates new symptoms elsewhere
Action: Stop fixing. Tell the user: "3+ fixes have cascaded into new issues. This suggests the feature's architecture may need rethinking, not patching. Here's what I've found: [summary]. Should we continue fixing symptoms or discuss restructuring?"
Do NOT attempt fix #4 without this discussion.
Output after each fix:
FIX #1:
File: auth/service.ts:45
Issue: signToken called with wrong argument order
Change: swapped (expiresIn, payload) to (payload, expiresIn)
Test: auth.test.ts → PASSESPhase 5: VERIFY — Confirm Everything Works
After all fixes are applied:
- Run ALL tests in the feature folder — every single one must pass
- Run ALL tests in files that IMPORT from this feature — must pass
- Run the full test suite if available — check for regressions
- If the feature has a UI, describe how to manually verify it
- Summarize all changes made
Final output:
FOCUSED FIX COMPLETE:
Feature: auth
Files changed: 4
Total fixes: 7
Tests: 23/23 passing
Regressions: 0
Changes:
1. auth/service.ts — fixed token signing argument order
2. auth/repository.ts — added null check for user lookup
3. auth/middleware.ts — fixed async error handling
4. auth/types.ts — aligned UserResponse type with actual DB schema
Consumers verified:
- src/app/api/login/route.ts ✅
- src/app/api/register/route.ts ✅
- src/middleware.ts ✅Red Flags — STOP and Return to Current Phase
If you catch yourself thinking any of these, you are skipping phases:
- "I can see the bug, let me just fix it" → STOP. You haven't traced dependencies yet.
- "Scoping is overkill, it's obviously just this file" → STOP. That's always wrong for feature-level fixes.
- "I'll map dependencies after I fix the obvious stuff" → STOP. You'll miss root causes.
- "The user said fix X, so I only need to look at X" → STOP. Features have dependencies.
- "Tests are passing so I'm done" → STOP. Did you run consumer tests too?
- "I don't need to check env vars for this" → STOP. Config issues masquerade as code bugs.
- "One more fix should do it" (after 2+ cascading failures) → STOP. Escalate.
- "I'll skip the diagnosis report, the fixes are obvious" → STOP. Write it down.
ALL of these mean: Return to the phase you're supposed to be in.
Common Rationalizations
| Excuse | Reality |
|---|---|
| "The feature is small, I don't need all 5 phases" | Small features have dependencies too. Phases 1-2 take minutes for small features — do them. |
| "I already know this codebase" | Knowledge decays. Trace the actual imports, don't rely on memory. |
| "The user wants speed, not process" | Skipping phases causes rework. Systematic is faster than thrashing. |
| "Only one file is broken" | If only one file were broken, the user would say "fix this bug", not "make the feature work." |
| "I fixed the tests, so it works" | Tests can pass while consumers are broken. Verify Phase 5 fully. |
| "The dependency map is too big to trace" | Then the feature is too big to fix without tracing. That's exactly why you need it. |
| "Root cause is obvious, I don't need to confirm" | "Obvious" root causes are wrong 40% of the time. Confirm with evidence. |
| "3 cascading failures is normal for a big fix" | 3 cascading failures means you're patching symptoms of an architectural problem. |
Anti-Patterns — NEVER do these
| Anti-Pattern | Why It's Wrong |
|---|---|
| Starting to fix code before mapping all dependencies | You'll miss root causes and create whack-a-mole fixes |
| Fixing only the file the user mentioned | Related files likely have issues too |
| Ignoring environment variables and configuration | Many "code bugs" are actually config issues |
| Skipping the test run phase | You can't verify fixes without running tests |
| Making changes outside the feature folder without explaining why | Unexpected side effects confuse the user |
| Fixing symptoms in consumer files instead of root cause in feature | Band-aids that break when the next consumer appears |
| Declaring "done" without running verification tests | Untested fixes are unverified fixes |
| Changing the public API without updating all consumers | Breaks everything that depends on the feature |
Related Skills
superpowers:systematic-debugging— Use within Phase 3 for root-cause tracing of individual complex bugssuperpowers:verification-before-completion— Use within Phase 5 before claiming the feature is fixedscope— If you need to understand blast radius before starting, run scope first then focused-fix
Quick Reference
| Phase | Key Action | Output |
|---|---|---|
| SCOPE | Read every file, map entry points | Feature manifest |
| TRACE | Map inbound + outbound dependencies | Dependency map |
| DIAGNOSE | Check code, runtime, tests, logs, config | Diagnosis report |
| FIX | Fix in order: deps → types → logic → tests → integration | Fix log per issue |
| VERIFY | Run all tests, check consumers, summarize | Completion report |
SKILL.md source
---
name: focused-fix
description: Use when the user asks to fix, debug, or make a specific feature/module/area work end-to-end. Triggers: 'make X work', 'fix the Y feature', 'the Z module is broken', 'focus on [area]'. Not for quic...
---
# Focused Fix — Deep-Dive Feature Repair
## When to Use
Activate when the user asks to fix, debug, or make a specific feature/module/area work. Key triggers:
- "make X work"
- "fix the Y feature"
- "the Z module is broken"
- "focus on [area]"
- "this feature needs to work properly"
This is NOT for quick single-bug fixes (use systematic-debugging for that). This is for when an entire feature or module needs systematic repair — tracing every dependency, reading logs, checking tests, mapping the full dependency graph.
```dot
digraph when_to_use {
"User reports feature broken" [shape=diamond];
"Single bug or symptom?" [shape=diamond];
"Use systematic-debugging" [shape=box];
"Entire feature/module needs repair?" [shape=diamond];
"Use focused-fix" [shape=box];
"Something else" [shape=box];
"User reports feature broken" -> "Single bug or symptom?";
"Single bug or symptom?" -> "Use systematic-debugging" [label="yes"];
"Single bug or symptom?" -> "Entire feature/module needs repair?" [label="no"];
"Entire feature/module needs repair?" -> "Use focused-fix" [label="yes"];
"Entire feature/module needs repair?" -> "Something else" [label="no"];
}
```
## The Iron Law
```
NO FIXES WITHOUT COMPLETING SCOPE → TRACE → DIAGNOSE FIRST
```
If you haven't finished Phase 3, you cannot propose fixes. Period.
**Violating the letter of these phases is violating the spirit of focused repair.**
## Protocol — STRICTLY follow these 5 phases IN ORDER
```dot
digraph phases {
rankdir=LR;
SCOPE [shape=box, label="Phase 1\nSCOPE"];
TRACE [shape=box, label="Phase 2\nTRACE"];
DIAGNOSE [shape=box, label="Phase 3\nDIAGNOSE"];
FIX [shape=box, label="Phase 4\nFIX"];
VERIFY [shape=box, label="Phase 5\nVERIFY"];
SCOPE -> TRACE -> DIAGNOSE -> FIX -> VERIFY;
FIX -> DIAGNOSE [label="fix broke\nsomething else"];
FIX -> ESCALATE [label="3+ fixes\ncreate new issues"];
ESCALATE [shape=doubleoctagon, label="STOP\nQuestion Architecture\nDiscuss with User"];
}
```
### Phase 1: SCOPE — Map the Feature Boundary
Before touching any code, understand the full scope of the feature.
1. Ask the user: "Which feature/folder should I focus on?" if not already clear
2. Identify the PRIMARY folder/files for this feature
3. Map EVERY file in that folder — read each one, understand its purpose
4. Create a feature manifest:
```
FEATURE SCOPE:
Primary path: src/features/auth/
Entry points: [files that are imported by other parts of the app]
Internal files: [files only used within this feature]
Total files: N
Total lines: N
```
### Phase 2: TRACE — Map All Dependencies (Inside AND Outside)
Trace every connection this feature has to the rest of the codebase.
**INBOUND (what this feature imports):**
1. For every import statement in every file in the feature folder:
- Trace it to its source
- Verify the source file exists
- Verify the imported entity (function, type, component) exists and is exported
- Check if the types/signatures match what the feature expects
2. Check for:
- Environment variables used (grep for process.env, import.meta.env, os.environ, etc.)
- Config files referenced
- Database models/schemas used
- API endpoints called
- Third-party packages imported
**OUTBOUND (what imports this feature):**
1. Search the entire codebase for imports from this feature folder
2. For each consumer:
- Verify they're importing entities that actually exist
- Check if they're using the correct API/interface
- Note if any consumers are using deprecated patterns
Output format:
```
DEPENDENCY MAP:
Inbound (this feature depends on):
src/lib/db.ts → used in auth/repository.ts (getUserById, createUser)
src/lib/jwt.ts → used in auth/service.ts (signToken, verifyToken)
@prisma/client → used in auth/repository.ts
process.env.JWT_SECRET → used in auth/service.ts
process.env.DATABASE_URL → used via prisma
Outbound (depends on this feature):
src/app/api/login/route.ts → imports { login } from auth/service
src/app/api/register/route.ts → imports { register } from auth/service
src/middleware.ts → imports { verifyToken } from auth/service
Env vars required: JWT_SECRET, DATABASE_URL
Config files: prisma/schema.prisma (User model)
```
### Phase 3: DIAGNOSE — Find Every Issue
Systematically check for problems. Run ALL of these checks:
**CODE QUALITY:**
- [ ] Every import resolves to a real file/export
- [ ] No circular dependencies within the feature
- [ ] Types are consistent across boundaries (no `any` at interfaces)
- [ ] Error handling exists for all async operations
- [ ] No TODO/FIXME/HACK comments indicating known issues
**RUNTIME:**
- [ ] All required environment variables are set (check .env)
- [ ] Database migrations are up to date (if applicable)
- [ ] API endpoints return expected shapes
- [ ] No hardcoded values that should be configurable
**TESTS:**
- [ ] Run ALL tests related to this feature: find them by searching for imports from the feature folder
- [ ] Record every failure with full error output
- [ ] Check test coverage — are there untested code paths?
**LOGS & ERRORS:**
- [ ] Search for any log files, error reports, or Sentry-style error tracking
- [ ] Check git log for recent changes to this feature: `git log --oneline -20 -- <feature-path>`
- [ ] Check if any recent commits might have broken something: `git log --oneline -5 --all -- <files that this feature depends on>`
**CONFIGURATION:**
- [ ] Verify all config files this feature depends on are valid
- [ ] Check for mismatches between development and production configs
- [ ] Verify third-party service credentials are valid (if testable)
**ROOT-CAUSE CONFIRMATION:**
For each CRITICAL issue found, confirm root cause before adding it to the fix list:
- State clearly: "I think X is the root cause because Y"
- Trace the data/control flow backward to verify — don't trust surface-level symptoms
- If the issue spans multiple components, add diagnostic logging at each boundary to identify which layer fails
- **REQUIRED SUB-SKILL:** For complex bugs found during diagnosis, apply `superpowers:systematic-debugging` Phase 1 (Root Cause Investigation) to confirm before proceeding
**RISK LABELING:**
Assign each issue a risk label:
| Risk | Criteria |
|---|---|
| HIGH | Public API surface / breaking interface contract / DB schema / auth or security logic / widely imported module (>3 callers) / git hotspot |
| MED | Internal module with tests / shared utility / config with runtime impact / internal callers of changed functions |
| LOW | Leaf module / isolated file / test-only change / single-purpose helper with no callers |
Output format:
```
DIAGNOSIS REPORT:
Issues found: N
CRITICAL:
1. [HIGH] [file:line] — description of issue. Root cause: [confirmed explanation]
2. [HIGH] [file:line] — description of issue. Root cause: [confirmed explanation]
WARNINGS:
1. [MED] [file:line] — description of issue
2. [LOW] [file:line] — description of issue
TESTS:
Ran: N tests
Passed: N
Failed: N
[list each failure with one-line summary]
```
### Phase 4: FIX — Repair Everything Systematically
Fix issues in this EXACT order:
1. **DEPENDENCIES FIRST** — fix broken imports, missing packages, wrong versions
2. **TYPES SECOND** — fix type mismatches at feature boundaries
3. **LOGIC THIRD** — fix actual business logic bugs
4. **TESTS FOURTH** — fix or create tests for each fix
5. **INTEGRATION LAST** — verify the feature works end-to-end with its consumers
Rules:
- Fix ONE issue at a time
- After each fix, run the related test to confirm it works
- If a fix breaks something else, STOP and re-evaluate (go back to DIAGNOSE)
- Keep a running log of every change made
- Never change code outside the feature folder without explicitly stating why
- Fix HIGH-risk issues before MED, MED before LOW
**ESCALATION RULE — 3-Strike Architecture Check:**
If 3+ fixes in this phase create NEW issues (not pre-existing ones), STOP immediately.
This pattern indicates an architectural problem, not a bug collection:
- Each fix reveals new shared state / coupling / problem in a different place
- Fixes require "massive refactoring" to implement
- Each fix creates new symptoms elsewhere
**Action:** Stop fixing. Tell the user: "3+ fixes have cascaded into new issues. This suggests the feature's architecture may need rethinking, not patching. Here's what I've found: [summary]. Should we continue fixing symptoms or discuss restructuring?"
Do NOT attempt fix #4 without this discussion.
Output after each fix:
```
FIX #1:
File: auth/service.ts:45
Issue: signToken called with wrong argument order
Change: swapped (expiresIn, payload) to (payload, expiresIn)
Test: auth.test.ts → PASSES
```
### Phase 5: VERIFY — Confirm Everything Works
After all fixes are applied:
1. Run ALL tests in the feature folder — every single one must pass
2. Run ALL tests in files that IMPORT from this feature — must pass
3. Run the full test suite if available — check for regressions
4. If the feature has a UI, describe how to manually verify it
5. Summarize all changes made
Final output:
```
FOCUSED FIX COMPLETE:
Feature: auth
Files changed: 4
Total fixes: 7
Tests: 23/23 passing
Regressions: 0
Changes:
1. auth/service.ts — fixed token signing argument order
2. auth/repository.ts — added null check for user lookup
3. auth/middleware.ts — fixed async error handling
4. auth/types.ts — aligned UserResponse type with actual DB schema
Consumers verified:
- src/app/api/login/route.ts ✅
- src/app/api/register/route.ts ✅
- src/middleware.ts ✅
```
## Red Flags — STOP and Return to Current Phase
If you catch yourself thinking any of these, you are skipping phases:
- "I can see the bug, let me just fix it" → STOP. You haven't traced dependencies yet.
- "Scoping is overkill, it's obviously just this file" → STOP. That's always wrong for feature-level fixes.
- "I'll map dependencies after I fix the obvious stuff" → STOP. You'll miss root causes.
- "The user said fix X, so I only need to look at X" → STOP. Features have dependencies.
- "Tests are passing so I'm done" → STOP. Did you run consumer tests too?
- "I don't need to check env vars for this" → STOP. Config issues masquerade as code bugs.
- "One more fix should do it" (after 2+ cascading failures) → STOP. Escalate.
- "I'll skip the diagnosis report, the fixes are obvious" → STOP. Write it down.
**ALL of these mean: Return to the phase you're supposed to be in.**
## Common Rationalizations
| Excuse | Reality |
|---|---|
| "The feature is small, I don't need all 5 phases" | Small features have dependencies too. Phases 1-2 take minutes for small features — do them. |
| "I already know this codebase" | Knowledge decays. Trace the actual imports, don't rely on memory. |
| "The user wants speed, not process" | Skipping phases causes rework. Systematic is faster than thrashing. |
| "Only one file is broken" | If only one file were broken, the user would say "fix this bug", not "make the feature work." |
| "I fixed the tests, so it works" | Tests can pass while consumers are broken. Verify Phase 5 fully. |
| "The dependency map is too big to trace" | Then the feature is too big to fix without tracing. That's exactly why you need it. |
| "Root cause is obvious, I don't need to confirm" | "Obvious" root causes are wrong 40% of the time. Confirm with evidence. |
| "3 cascading failures is normal for a big fix" | 3 cascading failures means you're patching symptoms of an architectural problem. |
## Anti-Patterns — NEVER do these
| Anti-Pattern | Why It's Wrong |
|---|---|
| Starting to fix code before mapping all dependencies | You'll miss root causes and create whack-a-mole fixes |
| Fixing only the file the user mentioned | Related files likely have issues too |
| Ignoring environment variables and configuration | Many "code bugs" are actually config issues |
| Skipping the test run phase | You can't verify fixes without running tests |
| Making changes outside the feature folder without explaining why | Unexpected side effects confuse the user |
| Fixing symptoms in consumer files instead of root cause in feature | Band-aids that break when the next consumer appears |
| Declaring "done" without running verification tests | Untested fixes are unverified fixes |
| Changing the public API without updating all consumers | Breaks everything that depends on the feature |
## Related Skills
- **`superpowers:systematic-debugging`** — Use within Phase 3 for root-cause tracing of individual complex bugs
- **`superpowers:verification-before-completion`** — Use within Phase 5 before claiming the feature is fixed
- **`scope`** — If you need to understand blast radius before starting, run scope first then focused-fix
## Quick Reference
| Phase | Key Action | Output |
|---|---|---|
| SCOPE | Read every file, map entry points | Feature manifest |
| TRACE | Map inbound + outbound dependencies | Dependency map |
| DIAGNOSE | Check code, runtime, tests, logs, config | Diagnosis report |
| FIX | Fix in order: deps → types → logic → tests → integration | Fix log per issue |
| VERIFY | Run all tests, check consumers, summarize | Completion report |
Related skills 6
caveman
Ultra-compressed communication mode. Cuts token usage ~75% by speaking like caveman while keeping full technical accuracy. Supports intensity levels: lite, full (default), ultra, wenyan-lite, wenyan-full, wenyan-ultra. Use when user says "caveman mode", "talk like caveman", "use caveman", "less tokens", "be brief", or invokes /caveman. Also auto-triggers when token efficiency is requested.
secure-linux-web-hosting
Use when setting up, hardening, or reviewing a cloud server for self-hosting, including DNS, SSH, firewalls, Nginx, static-site hosting, reverse-proxying an app, HTTPS with Let's Encrypt or ACME clients, safe HTTP-to-HTTPS redirects, or optional post-launch network tuning such as BBR.
readme-i18n
Use when the user wants to translate a repository README, make a repo multilingual, localize docs, add a language switcher, internationalize the README, or update localized README variants in a GitHub-style repository.
lark-shared
Use when first setting up lark-cli, running auth login, switching user/bot identity (--as), handling permission denied or scope errors, needing to update lark-cli, or seeing _notice in JSON output.
improve-codebase-architecture
Find deepening opportunities in a codebase, informed by the domain language in CONTEXT.md and the decisions in docs/adr/. Use when the user wants to improve architecture, find refactoring opportunities, consolidate tightly-coupled modules, or make a codebase more testable and AI-navigable.
paper-context-resolver
Optional RigorPilot helper for README-first deep learning repo reproduction. Use only when the README and repository files leave a narrow reproduction-critical gap and the task is to resolve a specific paper detail such as dataset split, preprocessing, evaluation protocol, checkpoint mapping, or runtime assumption from primary paper sources while recording conflicts. Do not use for general paper summary, repo scanning, environment setup, command execution, title-only paper lookup, or replacin...