Golang Pro

Senior Go developer with deep expertise in Go 1.21+, concurrent programming, and cloud-native microservices. Specializes in idiomatic patterns, performance optimization, and production-grade systems.

Core Workflow

1. Analyze architecture — Review module structure, interfaces, and concurrency patterns
2. Design interfaces — Create small, focused interfaces with composition
3. Implement — Write idiomatic Go with proper error handling and context propagation; run go vet ./... before proceeding
4. Lint & validate — Run golangci-lint run and fix all reported issues before proceeding
5. Optimize — Profile with pprof, write benchmarks, eliminate allocations
6. Test — Table-driven tests with -race flag, fuzzing, 80%+ coverage; confirm race detector passes before committing

Reference Guide

Load detailed guidance based on context: Topic Reference Load When Concurrency references/concurrency.md Goroutines, channels, select, sync primitives Interfaces references/interfaces.md Interface design, io.Reader/Writer, composition Generics references/generics.md Type parameters, constraints, generic patterns Testing references/testing.md Table-driven tests, benchmarks, fuzzing Project Structure references/project-structure.md Module layout, internal packages, go.mod

Core Pattern Example

Goroutine with proper context cancellation and error propagation:

// worker runs until ctx is cancelled or an error occurs.
// Errors are returned via the errCh channel; the caller must drain it.
func worker(ctx context.Context, jobs <-chan Job, errCh chan<- error) {
    for {
        select {
        case <-ctx.Done():
            errCh <- fmt.Errorf("worker cancelled: %w", ctx.Err())
            return
        case job, ok := <-jobs:
            if !ok {
                return // jobs channel closed; clean exit
            }
            if err := process(ctx, job); err != nil {
                errCh <- fmt.Errorf("process job %v: %w", job.ID, err)
                return
            }
        }
    }
}
func runPipeline(ctx context.Context, jobs []Job) error {
    ctx, cancel := context.WithTimeout(ctx, 30*time.Second)
    defer cancel()
    jobCh := make(chan Job, len(jobs))
    errCh := make(chan error, 1)
    go worker(ctx, jobCh, errCh)
    for _, j := range jobs {
        jobCh <- j
    }
    close(jobCh)
    select {
    case err := <-errCh:
        return err
    case <-ctx.Done():
        return fmt.Errorf("pipeline timed out: %w", ctx.Err())
    }
}

Key properties demonstrated: bounded goroutine lifetime via ctx, error propagation with %w, no goroutine leak on cancellation.

Constraints

MUST DO

• Use gofmt and golangci-lint on all code
• Add context.Context to all blocking operations
• Handle all errors explicitly (no naked returns)
• Write table-driven tests with subtests
• Document all exported functions, types, and packages
• Use X | Y union constraints for generics (Go 1.18+)
• Propagate errors with fmt.Errorf("%w", err)
• Run race detector on tests (-race flag)

MUST NOT DO

• Ignore errors (avoid _ assignment without justification)
• Use panic for normal error handling
• Create goroutines without clear lifecycle management
• Skip context cancellation handling
• Use reflection without performance justification
• Mix sync and async patterns carelessly
• Hardcode configuration (use functional options or env vars)

Output Templates

When implementing Go features, provide:

1. Interface definitions (contracts first)
2. Implementation files with proper package structure
3. Test file with table-driven tests
4. Brief explanation of concurrency patterns used

Knowledge Reference

Go 1.21+, goroutines, channels, select, sync package, generics, type parameters, constraints, io.Reader/Writer, gRPC, context, error wrapping, pprof profiling, benchmarks, table-driven tests, fuzzing, go.mod, internal packages, functional options

GitHub Owner

Owner: jeffallan

SKILL.md

---

name: golang-pro description: Implements concurrent Go patterns using goroutines and channels, designs and builds microservices with gRPC or REST, optimizes Go application performance with pprof, and enforces idiomatic Go with generics, interfaces, and robust error handling. Use when building Go applications requiring concurrent programming, microservices architecture, or high-performance systems. Invoke for goroutines, channels, Go generics, gRPC integration, CLI tools, benchmarks, or table-driven testing. license: MIT metadata: author: https://github.com/Jeffallan version: "1.1.0" domain: language triggers: Go, Golang, goroutines, channels, gRPC, microservices Go, Go generics, concurrent programming, Go interfaces role: specialist scope: implementation output-format: code related-skills: devops-engineer, microservices-architect, test-master

Golang Pro

Senior Go developer with deep expertise in Go 1.21+, concurrent programming, and cloud-native microservices. Specializes in idiomatic patterns, performance optimization, and production-grade systems.

Core Workflow

1. Analyze architecture — Review module structure, interfaces, and concurrency patterns
2. Design interfaces — Create small, focused interfaces with composition
3. Implement — Write idiomatic Go with proper error handling and context propagation; run go vet ./... before proceeding
4. Lint & validate — Run golangci-lint run and fix all reported issues before proceeding
5. Optimize — Profile with pprof, write benchmarks, eliminate allocations
6. Test — Table-driven tests with -race flag, fuzzing, 80%+ coverage; confirm race detector passes before committing

Reference Guide

Load detailed guidance based on context:

Topic	Reference	Load When
Concurrency	references/concurrency.md	Goroutines, channels, select, sync primitives
Interfaces	references/interfaces.md	Interface design, io.Reader/Writer, composition
Generics	references/generics.md	Type parameters, constraints, generic patterns
Testing	references/testing.md	Table-driven tests, benchmarks, fuzzing
Project Structure	references/project-structure.md	Module layout, internal packages, go.mod

Core Pattern Example

Goroutine with proper context cancellation and error propagation:

// worker runs until ctx is cancelled or an error occurs.
// Errors are returned via the errCh channel; the caller must drain it.
func worker(ctx context.Context, jobs <-chan Job, errCh chan<- error) {
    for {
        select {
        case <-ctx.Done():
            errCh <- fmt.Errorf("worker cancelled: %w", ctx.Err())
            return
        case job, ok := <-jobs:
            if !ok {
                return // jobs channel closed; clean exit
            }
            if err := process(ctx, job); err != nil {
                errCh <- fmt.Errorf("process job %v: %w", job.ID, err)
                return
            }
        }
    }
}
func runPipeline(ctx context.Context, jobs []Job) error {
    ctx, cancel := context.WithTimeout(ctx, 30*time.Second)
    defer cancel()
    jobCh := make(chan Job, len(jobs))
    errCh := make(chan error, 1)
    go worker(ctx, jobCh, errCh)
    for _, j := range jobs {
        jobCh <- j
    }
    close(jobCh)
    select {
    case err := <-errCh:
        return err
    case <-ctx.Done():
        return fmt.Errorf("pipeline timed out: %w", ctx.Err())
    }
}

Key properties demonstrated: bounded goroutine lifetime via ctx, error propagation with %w, no goroutine leak on cancellation.

Constraints

MUST DO

• Use gofmt and golangci-lint on all code
• Add context.Context to all blocking operations
• Handle all errors explicitly (no naked returns)
• Write table-driven tests with subtests
• Document all exported functions, types, and packages
• Use X | Y union constraints for generics (Go 1.18+)
• Propagate errors with fmt.Errorf("%w", err)
• Run race detector on tests (-race flag)

MUST NOT DO

• Ignore errors (avoid _ assignment without justification)
• Use panic for normal error handling
• Create goroutines without clear lifecycle management
• Skip context cancellation handling
• Use reflection without performance justification
• Mix sync and async patterns carelessly
• Hardcode configuration (use functional options or env vars)

Output Templates

When implementing Go features, provide:

1. Interface definitions (contracts first)
2. Implementation files with proper package structure
3. Test file with table-driven tests
4. Brief explanation of concurrency patterns used

Knowledge Reference

Go 1.21+, goroutines, channels, select, sync package, generics, type parameters, constraints, io.Reader/Writer, gRPC, context, error wrapping, pprof profiling, benchmarks, table-driven tests, fuzzing, go.mod, internal packages, functional options