Thread-safe data persistence in Swift using actors with in-memory cache and file-backed storage.
Works with
Implements an actor-based repository pattern that eliminates data races at compile time, replacing manual synchronization with Swift's actor model
Combines fast O(1) in-memory lookups with atomic file persistence, supporting any Codable & Identifiable model type
Provides synchronous initialization to avoid async complexity, with automatic await enforcement on all public API calls
AI-first code editor with Composer
Before installing skills in Cursor, ensure your development environment meets these requirements:
node --versionswift-actor-persistenceExecute the skills CLI command in your project's root directory to begin installation:
Fetches swift-actor-persistence from affaan-m/everything-claude-code 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 swift-actor-persistence. Access via /swift-actor-persistence 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.
Skills execute code in your environment. Always review source, verify the publisher, and test in isolation before production.
Submit your Claude Code skill and start earning
Create detailed user stories, acceptance criteria, and feature specs
Example
Generate user stories for 'password reset feature' with acceptance criteria, edge cases, and test scenarios
Reduce spec writing time by 50%, ensure comprehensive coverage
Research competitors, compare features, identify gaps
Example
Analyze 5 competitor products, create feature comparison matrix, suggest differentiation opportunities
Complete competitive research in 2 hours instead of 2 days
Evaluate features using frameworks (RICE, ICE, Kano) and create prioritized backlogs
Example
Score 20 feature ideas using RICE framework, generate prioritized roadmap with rationale
0
total installs
0
this week
142.9K
GitHub stars
0
upvotes
Run in your terminal
0
installs
0
this week
142.9K
stars
Patterns for building thread-safe data persistence layers using Swift actors. Combines in-memory caching with file-backed storage, leveraging the actor model to eliminate data races at compile time.
The actor model guarantees serialized access — no data races, enforced by the compiler.
public actor LocalRepository<T: Codable & Identifiable> where T.ID == String {
private var cache: [String: T] = [:]
private let fileURL: URL
public init(directory: URL = .documentsDirectory, filename: String = "data.json") {
self.fileURL = directory.appendingPathComponent(filename)
// Synchronous load during init (actor isolation not yet active)
self.cache = Self.loadSynchronously(from: fileURL)
}
// MARK: - Public API
public func save(_ item: T) throws {
cache[item.id] = item
try persistToFile()
}
public func delete(_ id: String) throws {
cache[id] = nil
try persistToFile()
}
public func find(by id: String) -> T? {
cache[id]
}
public func loadAll() -> [T] {
Array(cache.values)
}
// MARK: - Private
private func persistToFile() throws {
let data = try JSONEncoder().encode(Array(cache.values))
try data.write(to: fileURL, options: .atomic)
}
private static func loadSynchronously(from url: URL) -> [String: T] {
guard let data = try? Data(contentsOf: url),
let items = try? JSONDecoder().decode([T].self, from: data) else {
return [:]
}
return Dictionary(uniqueKeysWithValues: items.map { ($0.id, $0) })
}
}
All calls are automatically async due to actor isolation:
let repository = LocalRepository<Question>()
// Read — fast O(1) lookup from in-memory cache
let question = await repository.find(by: "q-001")
let allQuestions = await repository.loadAll()
// Write — updates cache and persists to file atomically
try await repository.save(newQuestion)
try await repository.delete("q-001")
@Observable
final class QuestionListViewModel {
private(set) var questions: [Question] = []
private let repository: LocalRepository<Question>
init(repository: LocalRepository<Question> = LocalRepository()) {
self.repository = repository
}
func load() async {
questions = await repository.loadAll()
}
func add(_ question: Question) async throws {
try await repository.save(question)
questions = await repository.loadAll()
}
}
| Decision | Rationale |
|---|---|
| Actor (not class + lock) | Compiler-enforced thread safety, no manual synchronization |
| In-memory cache + file persistence | Fast reads from cache, durable writes to disk |
| Synchronous init loading | Avoids async initialization complexity |
| Dictionary keyed by ID | O(1) lookups by identifier |
Generic over Codable & Identifiable |
Reusable across any model type |
Atomic file writes (.atomic) |
Prevents partial writes on crash |
Sendable types for all data crossing actor boundaries.atomic writes to prevent data corruption if the app crashes mid-writeinit — async initializers add complexity with minimal benefit for local files@Observable ViewModels for reactive UI updatesDispatchQueue or NSLock instead of actors for new Swift concurrency codeawait — callers must handle async contextnonisolated to bypass actor isolation (defeats the purpose)DispatchQueue-based thread safety with modern Swift concurrencyMake data-driven prioritization decisions faster
Draft PRDs, status updates, and stakeholder presentations
Example
Create executive summary of Q3 roadmap, monthly progress report, feature launch announcement
Save 3-5 hours/week on communication overhead
Prerequisites
Time Estimate
30-60 minutes to see productivity improvements
Steps
Common Pitfalls
✓ Do
✗ Don't
💡 Pro Tips
✓ Use when
Use for user story writing, competitive research, roadmap prioritization, stakeholder communication, and PRD drafting. Best for reducing repetitive documentation and research work.
✗ Avoid when
Avoid for strategic product vision (requires deep customer empathy), pricing decisions (needs market and financial expertise), or when face-to-face customer discovery is more valuable than speed.
mattpocock/skills
parcadei/continuous-claude-v3
cursor/plugins
ailabs-393/ai-labs-claude-skills
pproenca/dot-skills
mattpocock/skills
swift-actor-persistence reduced setup friction for our internal harness; good balance of opinion and flexibility.
I recommend swift-actor-persistence for anyone iterating fast on agent tooling; clear intent and a small, reviewable surface area.
Useful defaults in swift-actor-persistence — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
swift-actor-persistence reduced setup friction for our internal harness; good balance of opinion and flexibility.
Keeps context tight: swift-actor-persistence is the kind of skill you can hand to a new teammate without a long onboarding doc.
I recommend swift-actor-persistence for anyone iterating fast on agent tooling; clear intent and a small, reviewable surface area.
swift-actor-persistence has been reliable in day-to-day use. Documentation quality is above average for community skills.
I recommend swift-actor-persistence for anyone iterating fast on agent tooling; clear intent and a small, reviewable surface area.
swift-actor-persistence reduced setup friction for our internal harness; good balance of opinion and flexibility.
Registry listing for swift-actor-persistence matched our evaluation — installs cleanly and behaves as described in the markdown.
showing 1-10 of 75