golang-samber-lo

tarafından samber

Golang için samber/lo kullanan fonksiyonel programlama yardımcıları — dilimler, haritalar, kanallar, dizeler, matematik, demetler ve eşzamanlılık için 500'den fazla tür güvenli genel fonksiyon (Map, Filter, Reduce, GroupBy, Chunk, Flatten, Find, Uniq vb.). Çekirdek değişmez paket (lo), eşzamanlı varyantlar (lo/parallel yani lop), yerinde mutasyonlar (lo/mutable yani lom), tembel yineleyiciler (lo/it yani loi, Go 1.23+ için) ve deneysel SIMD (lo/exp/simd). samber/lo kullanırken veya benimserken, kod tabanı içe aktardığında uygulayın...

npx skills add https://github.com/samber/cc-skills-golang --skill golang-samber-lo

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Persona: You are a Go engineer who prefers declarative collection transforms over manual loops. You reach for lo to eliminate boilerplate, but you know when the stdlib is enough and when to upgrade to lop, lom, or loi.

samber/lo — Functional Utilities for Go

Lodash-inspired, generics-first utility library with 500+ type-safe helpers for slices, maps, strings, math, channels, tuples, and concurrency. Zero external dependencies. Immutable by default.

Official Resources:

This skill is not exhaustive. Please refer to library documentation and code examples for more information. Context7 can help as a discoverability platform.

Why samber/lo

Go's stdlib slices and maps packages cover ~10 basic helpers (sort, contains, keys). Everything else — Map, Filter, Reduce, GroupBy, Chunk, Flatten, Zip — requires manual for-loops. lo fills this gap:

Type-safe generics — no interface{} casts, no reflection, compile-time checking, no interface boxing overhead
Immutable by default — returns new collections, safe for concurrent reads, easier to reason about
Composable — functions take and return slices/maps, so they chain without wrapper types
Zero dependencies — only Go stdlib, no transitive dependency risk
Progressive complexity — start with lo, upgrade to lop/lom/loi only when profiling demands it
Error variants — most functions have Err suffixes (MapErr, FilterErr, ReduceErr) that stop on first error

Installation

go get github.com/samber/lo

Package	Import	Alias	Go version
Core (immutable)	`github.com/samber/lo`	`lo`	1.18+
Parallel	`github.com/samber/lo/parallel`	`lop`	1.18+
Mutable	`github.com/samber/lo/mutable`	`lom`	1.18+
Iterator	`github.com/samber/lo/it`	`loi`	1.23+
SIMD (experimental)	`github.com/samber/lo/exp/simd`	—	1.25+ (amd64 only)

Choose the Right Package

Start with lo. Move to other packages only when profiling shows a bottleneck or when lazy evaluation is explicitly needed.

Package	Use when	Trade-off
`lo`	Default for all transforms	Allocates new collections (safe, predictable)
`lop`	CPU-bound work on large datasets (1000+ items)	Goroutine overhead; not for I/O or small slices
`lom`	Hot path confirmed by `pprof -alloc_objects`	Mutates input — caller must understand side effects
`loi`	Large datasets with chained transforms (Go 1.23+)	Lazy evaluation saves memory but adds iterator complexity
`simd`	Numeric bulk ops after benchmarking (experimental)	Unstable API, may break between versions

Key rules:

lop is for CPU parallelism, not I/O concurrency — for I/O fan-out, use errgroup instead
lom breaks immutability — only use when allocation pressure is measured, never assumed
loi eliminates intermediate allocations in chains like Map → Filter → Take by evaluating lazily
For reactive/streaming pipelines over infinite event streams, → see samber/cc-skills-golang@golang-samber-ro skill + samber/ro package

For detailed package comparison and decision flowchart, see Package Guide.

Core Patterns

Transform a slice

// ✓ lo — declarative, type-safe
names := lo.Map(users, func(u User, _ int) string {
    return u.Name
})

// ✗ Manual — boilerplate, error-prone
names := make([]string, 0, len(users))
for _, u := range users {
    names = append(names, u.Name)
}

Filter + Reduce

total := lo.Reduce(
    lo.Filter(orders, func(o Order, _ int) bool {
        return o.Status == "paid"
    }),
    func(sum float64, o Order, _ int) float64 {
        return sum + o.Amount
    },
    0,
)

GroupBy

byStatus := lo.GroupBy(tasks, func(t Task, _ int) string {
    return t.Status
})
// map[string][]Task{"open": [...], "closed": [...]}

Error variant — stop on first error

results, err := lo.MapErr(urls, func(url string, _ int) (Response, error) {
    return http.Get(url)
})

Common Mistakes

Mistake	Why it fails	Fix
Using `lo.Contains` when `slices.Contains` exists	Unnecessary dependency for a stdlib-covered op	Prefer `slices.Contains`/`slices.Sort` since Go 1.21+ and `slices.Collect(maps.Keys(m))` since Go 1.23+ when a key slice is needed
Using `lop.Map` on 10 items	Goroutine creation overhead exceeds transform cost	Use `lo.Map` — `lop` benefits start at ~1000+ items for CPU-bound work
Assuming `lo.Filter` modifies the input	`lo` is immutable by default — it returns a new slice	Use `lom.Filter` if you explicitly need in-place mutation
Using `lo.Must` in production code paths	`Must` panics on error — fine in tests and init, dangerous in request handlers	Use the non-Must variant and handle the error
Chaining many eager transforms on large data	Each step allocates an intermediate slice	Use `loi` (lazy iterators) to avoid intermediate allocations

Best Practices

Prefer stdlib when available — slices.Contains and slices.Sort (Go 1.21+) carry no dependency; maps.Keys is Go 1.23+ and returns an iterator, so use slices.Collect(maps.Keys(m)) when you need a slice. Use lo for transforms the stdlib doesn't offer (Map, Filter, Reduce, GroupBy, Chunk, Flatten)
Compose lo functions — chain lo.Filter → lo.Map → lo.GroupBy instead of writing nested loops. Each function is a building block
Profile before optimizing — switch from lo to lom/lop only after go tool pprof confirms allocation or CPU as the bottleneck
Use error variants — prefer lo.MapErr over lo.Map + manual error collection. Error variants stop early and propagate cleanly
Use lo.Must only in tests and init — in production, handle errors explicitly

Quick Reference

Function	What it does
`lo.Map`	Transform each element
`lo.Filter` / `lo.Reject`	Keep / remove elements matching predicate
`lo.Reduce`	Fold elements into a single value
`lo.ForEach`	Side-effect iteration
`lo.GroupBy`	Group elements by key
`lo.Chunk`	Split into fixed-size batches
`lo.Flatten`	Flatten nested slices one level
`lo.Uniq` / `lo.UniqBy`	Remove duplicates
`lo.Find` / `lo.FindOrElse`	First match or default
`lo.Contains` / `lo.Every` / `lo.Some`	Membership tests
`lo.Keys` / `lo.Values`	Extract map keys or values
`lo.PickBy` / `lo.OmitBy`	Filter map entries
`lo.Zip2` / `lo.Unzip2`	Pair/unpair two slices
`lo.Range` / `lo.RangeFrom`	Generate number sequences
`lo.Ternary` / `lo.If`	Inline conditionals
`lo.ToPtr` / `lo.FromPtr`	Pointer helpers
`lo.Must` / `lo.Try`	Panic-on-error / recover-as-bool
`lo.Async` / `lo.Attempt`	Async execution / retry with backoff
`lo.Debounce` / `lo.Throttle`	Rate limiting
`lo.ChannelDispatcher`	Fan-out to multiple channels

For the complete function catalog (300+ functions), see API Reference.

For composition patterns, stdlib interop, and iterator pipelines, see Advanced Patterns.

If you encounter a bug or unexpected behavior in samber/lo, open an issue at github.com/samber/lo/issues.

Cross-References

→ See samber/cc-skills-golang@golang-samber-ro skill for reactive/streaming pipelines over infinite event streams (samber/ro package)
→ See samber/cc-skills-golang@golang-samber-mo skill for monadic types (Option, Result, Either) that compose with lo transforms
→ See samber/cc-skills-golang@golang-data-structures skill for choosing the right underlying data structure
→ See samber/cc-skills-golang@golang-performance skill for profiling methodology before switching to lom/lop