From security-hardening
Hardens applications against vulnerabilities with threat modeling, input validation, secure authentication, and authorization. Relevant when handling untrusted input, user sessions, or third-party integrations.
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/security-hardening:security-and-hardeningThe summary Claude sees in its skill listing — used to decide when to auto-load this skill
Security-first development practices for web applications. Treat every external input as hostile, every secret as sacred, and every authorization check as mandatory. Security isn't a phase — it's a constraint on every line of code that touches user data, authentication, or external systems.
Security-first development practices for web applications. Treat every external input as hostile, every secret as sacred, and every authorization check as mandatory. Security isn't a phase — it's a constraint on every line of code that touches user data, authentication, or external systems.
Controls bolted on without a threat model are guesses. Before hardening, spend five minutes thinking like an attacker:
| Threat | Ask | Typical mitigation |
|---|---|---|
| Spoofing | Can someone impersonate a user/service? | Authentication, signature verification |
| Tampering | Can data be altered in transit or at rest? | Integrity checks, parameterized queries, HTTPS |
| Repudiation | Can an action be denied later? | Audit logging of security events |
| Information disclosure | Can data leak? | Encryption, field allowlists, generic errors |
| Denial of service | Can it be overwhelmed? | Rate limiting, input size caps, timeouts |
| Elevation of privilege | Can a user gain rights they shouldn't? | Authorization checks, least privilege |
If you can't name the trust boundaries for a feature, you're not ready to secure it. This is OWASP A04: Insecure Design — most breaches begin in design, not code.
eval() or innerHTML with user-provided dataThese are prevention patterns, not a ranking. For the 2021 ordering, see the quick-reference table in references/security-checklist.md.
// BAD: SQL injection via string concatenation
const query = `SELECT * FROM users WHERE id = '${userId}'`;
// GOOD: Parameterized query
const user = await db.query('SELECT * FROM users WHERE id = $1', [userId]);
// GOOD: ORM with parameterized input
const user = await prisma.user.findUnique({ where: { id: userId } });
// Password hashing
import { hash, compare } from 'bcrypt';
const SALT_ROUNDS = 12;
const hashedPassword = await hash(plaintext, SALT_ROUNDS);
const isValid = await compare(plaintext, hashedPassword);
// Session management
app.use(session({
secret: process.env.SESSION_SECRET, // From environment, not code
resave: false,
saveUninitialized: false,
cookie: {
httpOnly: true, // Not accessible via JavaScript
secure: true, // HTTPS only
sameSite: 'lax', // CSRF protection
maxAge: 24 * 60 * 60 * 1000, // 24 hours
},
}));
// BAD: Rendering user input as HTML
element.innerHTML = userInput;
// GOOD: Use framework auto-escaping (React does this by default)
return <div>{userInput}</div>;
// If you MUST render HTML, sanitize first
import DOMPurify from 'dompurify';
const clean = DOMPurify.sanitize(userInput);
// Always check authorization, not just authentication
app.patch('/api/tasks/:id', authenticate, async (req, res) => {
const task = await taskService.findById(req.params.id);
// Check that the authenticated user owns this resource
if (task.ownerId !== req.user.id) {
return res.status(403).json({
error: { code: 'FORBIDDEN', message: 'Not authorized to modify this task' }
});
}
// Proceed with update
const updated = await taskService.update(req.params.id, req.body);
return res.json(updated);
});
// Security headers (use helmet for Express)
import helmet from 'helmet';
app.use(helmet());
// Content Security Policy
app.use(helmet.contentSecurityPolicy({
directives: {
defaultSrc: ["'self'"],
scriptSrc: ["'self'"],
styleSrc: ["'self'", "'unsafe-inline'"], // Tighten if possible
imgSrc: ["'self'", 'data:', 'https:'],
connectSrc: ["'self'"],
},
}));
// CORS — restrict to known origins
app.use(cors({
origin: process.env.ALLOWED_ORIGINS?.split(',') || 'http://localhost:3000',
credentials: true,
}));
// Never return sensitive fields in API responses
function sanitizeUser(user: UserRecord): PublicUser {
const { passwordHash, resetToken, ...publicFields } = user;
return publicFields;
}
// Use environment variables for secrets
const API_KEY = process.env.STRIPE_API_KEY;
if (!API_KEY) throw new Error('STRIPE_API_KEY not configured');
Any time the server fetches a URL the user influenced — webhooks, "import from URL", image proxies, link previews — an attacker can aim it at internal services (cloud metadata, localhost, private IPs).
// BAD: fetch whatever the user gives you
await fetch(req.body.webhookUrl);
// GOOD: allowlist scheme + host, reject if ANY resolved IP is private, forbid redirects
import { lookup } from 'node:dns/promises';
import ipaddr from 'ipaddr.js';
const ALLOWED_HOSTS = new Set(['hooks.example.com']);
async function assertSafeUrl(raw: string): Promise<URL> {
const url = new URL(raw);
if (url.protocol !== 'https:') throw new Error('https only');
if (!ALLOWED_HOSTS.has(url.hostname)) throw new Error('host not allowed');
// Resolve ALL records; a single private/reserved address fails the check.
const addrs = await lookup(url.hostname, { all: true });
if (addrs.some((a) => ipaddr.parse(a.address).range() !== 'unicast')) {
throw new Error('private/reserved IP');
}
return url;
}
await fetch(await assertSafeUrl(req.body.webhookUrl), { redirect: 'error' });
The range() !== 'unicast' check covers loopback, link-local 169.254.169.254 (cloud metadata, the #1 SSRF target), private, and unique-local ranges across IPv4 and IPv6.
Caveat — this still has a TOCTOU gap. fetch resolves DNS again after the check, so an attacker using a short-TTL record can rebind to an internal IP between validation and connection. For high-risk surfaces, resolve once and connect to the pinned IP, or put a filtering agent in front (request-filtering-agent / ssrf-req-filter).
import { z } from 'zod';
const CreateTaskSchema = z.object({
title: z.string().min(1).max(200).trim(),
description: z.string().max(2000).optional(),
priority: z.enum(['low', 'medium', 'high']).default('medium'),
dueDate: z.string().datetime().optional(),
});
// Validate at the route handler
app.post('/api/tasks', async (req, res) => {
const result = CreateTaskSchema.safeParse(req.body);
if (!result.success) {
return res.status(422).json({
error: {
code: 'VALIDATION_ERROR',
message: 'Invalid input',
details: result.error.flatten(),
},
});
}
// result.data is now typed and validated
const task = await taskService.create(result.data);
return res.status(201).json(task);
});
// Restrict file types and sizes
const ALLOWED_TYPES = ['image/jpeg', 'image/png', 'image/webp'];
const MAX_SIZE = 5 * 1024 * 1024; // 5MB
function validateUpload(file: UploadedFile) {
if (!ALLOWED_TYPES.includes(file.mimetype)) {
throw new ValidationError('File type not allowed');
}
if (file.size > MAX_SIZE) {
throw new ValidationError('File too large (max 5MB)');
}
// Don't trust the file extension — check magic bytes if critical
}
Package-manager audits report known advisories; they do not prove a package is trustworthy or that vulnerable code is reachable. Use this decision tree:
The native package-manager audit reports a vulnerability
├── Severity: critical or high
│ ├── Is the vulnerable code reachable in runtime, build, test, or deployment paths?
│ │ ├── YES --> Fix immediately (update, patch, or replace the dependency)
│ │ └── NO (confirmed unused across those paths) --> Fix soon, but not a blocker
│ └── Is a fix available?
│ ├── YES --> Update to the patched version
│ └── NO --> Check for workarounds, consider replacing the dependency, or add to allowlist with a review date
├── Severity: moderate
│ ├── Reachable in production? --> Fix in the next release cycle
│ └── Dev-only? --> Fix when convenient, track in backlog
└── Severity: low
└── Track and fix during regular dependency updates
Key questions:
When you defer a fix, document the reason and set a review date.
Do not assume npm or treat the nearest manifest as the install root. Apply this order:
packageManager (when present), the lockfile, and CI; stop on disagreement or competing lockfiles. Pin the manager version and use the matrix in references/security-checklist.md.Audits only find known advisories; they do not catch a newly malicious or typosquatted package. Therefore:
npm audit fix --force or equivalent). Preview the remediation, read changelogs, and test each resulting upgrade; forced fixes may cross declared dependency ranges.npm audit signatures, pnpm audit signatures) and treat absence as a signal to investigate, not automatic proof of compromise.cross-env vs crossenv (OWASP A06, LLM03).import rateLimit from 'express-rate-limit';
// General API rate limit
app.use('/api/', rateLimit({
windowMs: 15 * 60 * 1000, // 15 minutes
max: 100, // 100 requests per window
standardHeaders: true,
legacyHeaders: false,
}));
// Stricter limit for auth endpoints
app.use('/api/auth/', rateLimit({
windowMs: 15 * 60 * 1000,
max: 10, // 10 attempts per 15 minutes
}));
.env files:
├── .env.example → Committed (template with placeholder values)
├── .env → NOT committed (contains real secrets)
└── .env.local → NOT committed (local overrides)
.gitignore must include:
.env
.env.local
.env.*.local
*.pem
*.key
Always check before committing:
# Check for accidentally staged secrets
git diff --cached | grep -i "password\|secret\|api_key\|token"
If a secret is ever committed, rotate it. Deleting the line or rewriting history is not enough — assume it's compromised the moment it reaches a remote. Revoke and reissue the key first, then purge it from history.
If your app calls an LLM — chatbots, summarizers, agents, RAG — it inherits a new attack surface. Map it to the OWASP Top 10 for LLM Applications (2025):
eval, SQL, a shell, innerHTML, or a file path. Validate and encode it exactly as you would raw user input.// BAD: trusting model output as a command or as markup
const sql = await llm.generate(`Write SQL for: ${userQuestion}`);
await db.query(sql); // arbitrary query execution
container.innerHTML = await llm.reply(userMessage); // stored XSS, via the model
// GOOD: model output is data — parse defensively, then validate, then encode
let intent;
try {
intent = CommandSchema.parse(JSON.parse(await llm.replyJson(userMessage)));
} catch {
throw new ValidationError('unexpected model output'); // JSON.parse or schema failed
}
await runAllowlistedAction(intent.action, intent.params);
container.textContent = await llm.reply(userMessage);
### Authentication
- [ ] Passwords hashed with bcrypt/scrypt/argon2 (salt rounds ≥ 12)
- [ ] Session tokens are httpOnly, secure, sameSite
- [ ] Login has rate limiting
- [ ] Password reset tokens expire
### Authorization
- [ ] Every endpoint checks user permissions
- [ ] Users can only access their own resources
- [ ] Admin actions require admin role verification
### Input
- [ ] All user input validated at the boundary
- [ ] SQL queries are parameterized
- [ ] HTML output is encoded/escaped
- [ ] Server-side URL fetches are allowlisted (no SSRF to internal services)
### Data
- [ ] No secrets in code or version control
- [ ] Sensitive fields excluded from API responses
- [ ] PII encrypted at rest (if applicable)
### Infrastructure
- [ ] Security headers configured (CSP, HSTS, etc.)
- [ ] CORS restricted to known origins
- [ ] Dependencies audited for vulnerabilities
- [ ] Error messages don't expose internals
### Supply Chain
- [ ] One authoritative lockfile committed; CI uses that manager's frozen/immutable install
- [ ] Native audit triaged by reachability and fix risk; dependency install scripts blocked unless explicitly approved
- [ ] New dependencies reviewed (ownership, provenance, release age, transitive graph)
### AI / LLM (if used)
- [ ] Model output treated as untrusted (no eval/SQL/innerHTML/shell)
- [ ] Secrets and other users' data kept out of prompts
- [ ] Tool/agent permissions scoped; destructive actions require confirmation
For detailed security checklists and pre-commit verification steps, see references/security-checklist.md.
| Rationalization | Reality |
|---|---|
| "This is an internal tool, security doesn't matter" | Internal tools get compromised. Attackers target the weakest link. |
| "We'll add security later" | Security retrofitting is 10x harder than building it in. Add it now. |
| "No one would try to exploit this" | Automated scanners will find it. Security by obscurity is not security. |
| "The framework handles security" | Frameworks provide tools, not guarantees. You still need to use them correctly. |
| "It's just a prototype" | Prototypes become production. Security habits from day one. |
| "Threat modeling is overkill here" | Five minutes of "how would I attack this?" prevents the design flaws no control can patch later. |
| "It's just LLM output, it's only text" | That "text" can be a SQL statement, a script tag, or a shell command. Treat it like any untrusted input. |
| "The audit passed, so the dependency is safe" | Audits match known advisories. They do not detect a newly malicious package or make unreviewed install scripts safe to execute. |
*) originsevalAfter implementing security-relevant code:
npx claudepluginhub p/addyosmani-security-hardening-skills-security-and-hardening2plugins reuse this skill
First indexed Jul 12, 2026
Hardens applications against vulnerabilities with threat modeling, input validation, secure authentication, and authorization. Relevant when handling untrusted input, user sessions, or third-party integrations.
Guides developers through threat modeling and security hardening for web applications handling user input, authentication, sensitive data, or external integrations.
Hardens code against vulnerabilities by applying threat modeling (STRIDE) and input validation, authentication, and data storage best practices.