Single-threaded by default with explicit background offloading via @concurrent and isolated protocol conformances.
Works with
Async functions stay on the calling actor by default, eliminating implicit background offloading that caused data-race errors in Swift 6.1 and earlier
Isolated conformances allow MainActor types to safely conform to non-isolated protocols without unsafe workarounds
@concurrent attribute explicitly offloads CPU-intensive work to background threads; requires nonisolated ty
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Before installing skills in Cursor, ensure your development environment meets these requirements:
node --versionswift-concurrency-6-2Execute the skills CLI command in your project's root directory to begin installation:
Fetches swift-concurrency-6-2 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-concurrency-6-2. Access via /swift-concurrency-6-2 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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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
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Patterns for adopting Swift 6.2's concurrency model where code runs single-threaded by default and concurrency is introduced explicitly. Eliminates common data-race errors without sacrificing performance.
In Swift 6.1 and earlier, async functions could be implicitly offloaded to background threads, causing data-race errors even in seemingly safe code:
// Swift 6.1: ERROR
@MainActor
final class StickerModel {
let photoProcessor = PhotoProcessor()
func extractSticker(_ item: PhotosPickerItem) async throws -> Sticker? {
guard let data = try await item.loadTransferable(type: Data.self) else { return nil }
// Error: Sending 'self.photoProcessor' risks causing data races
return await photoProcessor.extractSticker(data: data, with: item.itemIdentifier)
}
}
Swift 6.2 fixes this: async functions stay on the calling actor by default.
// Swift 6.2: OK — async stays on MainActor, no data race
@MainActor
final class StickerModel {
let photoProcessor = PhotoProcessor()
func extractSticker(_ item: PhotosPickerItem) async throws -> Sticker? {
guard let data = try await item.loadTransferable(type: Data.self) else { return nil }
return await photoProcessor.extractSticker(data: data, with: item.itemIdentifier)
}
}
MainActor types can now conform to non-isolated protocols safely:
protocol Exportable {
func export()
}
// Swift 6.1: ERROR — crosses into main actor-isolated code
// Swift 6.2: OK with isolated conformance
extension StickerModel: @MainActor Exportable {
func export() {
photoProcessor.exportAsPNG()
}
}
The compiler ensures the conformance is only used on the main actor:
// OK — ImageExporter is also @MainActor
@MainActor
struct ImageExporter {
var items: [any Exportable]
mutating func add(_ item: StickerModel) {
items.append(item) // Safe: same actor isolation
}
}
// ERROR — nonisolated context can't use MainActor conformance
nonisolated struct ImageExporter {
var items: [any Exportable]
mutating func add(_ item: StickerModel) {
items.append(item) // Error: Main actor-isolated conformance cannot be used here
}
}
Protect global/static state with MainActor:
// Swift 6.1: ERROR — non-Sendable type may have shared mutable state
final class StickerLibrary {
static let shared: StickerLibrary = .init() // Error
}
// Fix: Annotate with @MainActor
@MainActor
final class StickerLibrary {
static let shared: StickerLibrary = .init() // OK
}
Swift 6.2 introduces a mode where MainActor is inferred by default — no manual annotations needed:
// With MainActor default inference enabled:
final class StickerLibrary {
static let shared: StickerLibrary = .init() // Implicitly @MainActor
}
final class StickerModel {
let photoProcessor: PhotoProcessor
var selection: [PhotosPickerItem] // Implicitly @MainActor
}
extension StickerModel: Exportable { // Implicitly @MainActor conformance
func export() {
photoProcessor.exportAsPNG()
}
}
This mode is opt-in and recommended for apps, scripts, and other executable targets.
When you need actual parallelism, explicitly offload with @concurrent:
Important: This example requires Approachable Concurrency build settings — SE-0466 (MainActor default isolation) and SE-0461 (NonisolatedNonsendingByDefault). With these enabled,
extractStickerstays on the caller's actor, making mutable state access safe. Without these settings, this code has a data race — the compiler will flag it.
nonisolated final class PhotoProcessor {
private var cachedStickers: [String: Sticker] = [:]
func extractSticker(data: Data, with id: String) async -> Sticker {
if let sticker = cachedStickers[id] {
return sticker
}
let sticker = await Self.extractSubject(from: data)
cachedStickers[id] = sticker
return sticker
}
// Offload expensive work to concurrent thread pool
@concurrent
static func extractSubject(from data: Data) async -> Sticker { /* ... */ }
}
// Callers must await
let processor = PhotoProcessor()
processedPhotos[item.id] = await processor.extractSticker(data: data, with: item.id)
To use @concurrent:
nonisolated@concurrent to the functionasync if not already asynchronousawait at call sites| Decision | Rationale |
|---|---|
| Single-threaded by default | Most natural code is data-race free; concurrency is opt-in |
| Async stays on calling actor | Eliminates implicit offloading that caused data-race errors |
| Isolated conformances | MainActor types can conform to protocols without unsafe workarounds |
@concurrent explicit opt-in |
Background execution is a deliberate performance choice, not accidental |
| MainActor default inference | Reduces boilerplate @MainActor annotations for app targets |
| Opt-in adoption | Non-breaking migration path — enable features incrementally |
SwiftSettings API in package manifest@concurrent where needed: Profile first, then offload hot pathsMake 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-concurrency-6-2 has been reliable in day-to-day use. Documentation quality is above average for community skills.
Useful defaults in swift-concurrency-6-2 — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
I recommend swift-concurrency-6-2 for anyone iterating fast on agent tooling; clear intent and a small, reviewable surface area.
Solid pick for teams standardizing on skills: swift-concurrency-6-2 is focused, and the summary matches what you get after install.
I recommend swift-concurrency-6-2 for anyone iterating fast on agent tooling; clear intent and a small, reviewable surface area.
Useful defaults in swift-concurrency-6-2 — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
swift-concurrency-6-2 has been reliable in day-to-day use. Documentation quality is above average for community skills.
Solid pick for teams standardizing on skills: swift-concurrency-6-2 is focused, and the summary matches what you get after install.
swift-concurrency-6-2 has been reliable in day-to-day use. Documentation quality is above average for community skills.
Useful defaults in swift-concurrency-6-2 — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
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