golang-google-wire
samber/cc-skills-golang
Compile-time dependency injection for Go using google/wire — resolve dependencies at build time, not runtime.
What is golang-google-wire?
google/wire is a code-generation toolkit that resolves Go dependency graphs at compile time and emits plain constructor calls. Use it when adopting compile-time DI, working with codebases that import github.com/google/wire, or when you want the compiler to catch missing dependencies before runtime.
- Generate injector functions from wire.Build declarations into wire_gen.go
- Define reusable provider sets with wire.NewSet for organizing constructors
- Bind interfaces to concrete types explicitly with wire.Bind to prevent ambiguity
- Support cleanup functions (deferred in reverse order) for resource teardown
- Inject struct fields directly via wire.Struct without manual constructors
- Disambiguate duplicate types using named type wrappers
How to install golang-google-wire
npx skills add https://github.com/samber/cc-skills-golang --skill golang-google-wire- Go 1.11 or later
- wire CLI: go install github.com/google/wire/cmd/wire@latest
- wire package: go get github.com/google/wire
How to use golang-google-wire
- 1.Create provider functions (constructors) that return the types you need to inject
- 2.Group related providers into wire.NewSet declarations in package-level wire.go files
- 3.Write an injector function with //go:build wireinject tag and wire.Build call listing your provider sets
- 4.Run wire ./... to generate wire_gen.go with the resolved dependency graph
- 5.Call the generated injector function in main() or initialization code to instantiate your application graph
- 6.Re-run wire ./... whenever you add, remove, or change constructor signatures
Use cases
- Initialize application dependency graphs at startup with compile-time safety
- Organize multi-package Go services with separate provider sets per package
- Manage database connections, caches, and other resources with automatic cleanup
- Validate the entire dependency graph before deployment via wire check ./...
- Replace runtime reflection-based DI (dig, fx) when compile-time guarantees are preferred
- Go backend developers building modular applications
- Teams wanting compile-time dependency validation instead of runtime errors
- Architects designing multi-service systems with clear dependency boundaries
- Projects already using google/wire or evaluating compile-time DI approaches
golang-google-wire FAQ
wire resolves dependencies at compile time via code generation, catching missing dependencies when you run wire ./... rather than at first request. Runtime DI (dig, fx) uses reflection and a container at startup. wire produces plain Go code with no runtime overhead; dig/fx offer lifecycle hooks and lazy loading.
This build tag prevents the stub function from being compiled into your binary. Without it, both the stub and wire_gen.go define the same function, causing a duplicate-symbol error. Only wire_gen.go (which lacks the tag) is included in the final build.
Yes. Treat wire_gen.go as a committed build artifact. It must stay in sync with your provider and injector files for CI builds to work. Never edit it manually — it is regenerated on every wire ./... run.
Define distinct named types wrapping the underlying type: type PrimaryDSN string and type ReplicaDSN string. Wire enforces one provider per type; named types let you have multiple providers for logically different values.
Yes. Provider functions can return (value, cleanup func, error). Wire chains cleanup functions and calls them in reverse order. Return the cleanup function as the second return value.
Full instructions (SKILL.md)
Source of truth, from samber/cc-skills-golang.
name: golang-google-wire
description: "Compile-time dependency injection in Golang using google/wire — wire.NewSet, wire.Build, wire.Bind (interface→concrete), wire.Struct, wire.Value, wire.InterfaceValue, wire.FieldsOf, cleanup functions, //go:build wireinject injector files, and generated wire_gen.go. Apply when using or adopting google/wire, when the codebase imports github.com/google/wire, or when wiring an application graph at compile time via wire.Build. For runtime DI with reflection, see samber/cc-skills-golang@golang-uber-dig skill."
user-invocable: true
license: MIT
compatibility: Designed for Claude Code or similar AI coding agents, and for projects using Golang.
metadata:
author: samber
version: "1.0.4"
openclaw:
emoji: "🪡"
homepage: https://github.com/samber/cc-skills-golang
requires:
bins:
- go
- wire
install:
- kind: go
package: github.com/google/wire/cmd/wire@latest
bins: [wire]
skill-library-version: "0.7.0"
allowed-tools: Read Edit Write Glob Grep Bash(go:) Bash(golangci-lint:) Bash(git:) Agent WebFetch mcp__context7__resolve-library-id mcp__context7__query-docs Bash(wire:)
Persona: You are a Go architect using wire for compile-time DI. You let the compiler catch missing dependencies, treat wire_gen.go as committed source, and re-run wire ./... after every graph change.
Dependencies:
- wire:
go install github.com/google/wire/cmd/wire@latest
Using google/wire for Compile-Time Dependency Injection in Go
Code-generation DI toolkit. Wire resolves the dependency graph at compile time and emits plain Go constructor calls — no runtime container, no reflection. Errors appear when you run wire ./..., not at first request.
Note: google/wire was archived in August 2025 (feature-complete; bug fixes still accepted).
Official Resources: pkg.go.dev · github.com/google/wire · User Guide · Best Practices
This skill is not exhaustive. Please refer to library documentation and code examples for more information. Context7 can help as a discoverability platform. For Go package docs, versions, symbols, and known vulnerabilities, → See samber/cc-skills-golang@golang-pkg-go-dev skill.
go get -tool github.com/google/wire/cmd/wire@latest
go get github.com/google/wire
wire vs. Runtime DI
| Concern | wire | dig / fx / samber/do |
|---|---|---|
| Resolution | Compile time (codegen) | Runtime (reflection) |
| Error detection | wire ./... fails | First Invoke/startup |
| Runtime container | None — plain Go calls | Present |
| Lifecycle hooks | Not built in | fx: OnStart/OnStop |
| Generated files | wire_gen.go (committed) | None |
For lifecycle, lazy loading, and a full matrix see samber/cc-skills-golang@golang-dependency-injection.
Providers
A provider is any Go function — inputs are dependencies, outputs are provided types. Three return forms:
func NewConfig() *Config { return &Config{Addr: ":8080"} }
func NewDB(cfg *Config) (*sql.DB, error) { return sql.Open("postgres", cfg.DSN) }
func NewRedis(cfg *Config) (*redis.Client, func(), error) { // cleanup chained in reverse order
c := redis.NewClient(&redis.Options{Addr: cfg.RedisAddr})
return c, func() { c.Close() }, nil
}
Provider Sets
wire.NewSet groups providers for reuse. Sets can reference other sets.
// infra/wire.go
var InfraSet = wire.NewSet(
NewConfig,
NewDB,
NewRedis,
)
// service/wire.go
var ServiceSet = wire.NewSet(
NewUserRepo,
NewUserService,
wire.Bind(new(UserStore), new(*UserRepo)), // interface binding
)
Keep sets small: library sets expose a stable surface (adding inputs or removing outputs breaks downstream injectors). One set per package is a useful default.
Injectors and //go:build wireinject
The injector file declares the initialization function. Wire generates its body into wire_gen.go and replaces the stub.
//go:build wireinject
package main
import "github.com/google/wire"
// Wire generates the body of this function.
func InitApp() (*App, func(), error) {
wire.Build(InfraSet, ServiceSet, NewApp)
return nil, nil, nil // replaced by codegen
}
The //go:build wireinject tag prevents the stub from being compiled into the binary — only wire_gen.go (which has no such tag) makes it through go build. Without this tag, both files define the same function, causing a compile error.
Alternative syntax when a dummy return is inconvenient:
func InitApp() (*App, func(), error) {
panic(wire.Build(InfraSet, ServiceSet, NewApp))
}
Interface Bindings
Wire forbids implicit interface satisfaction — you must declare bindings explicitly so the graph is unambiguous when multiple types implement the same interface.
var Set = wire.NewSet(
NewPostgresUserRepo,
wire.Bind(new(UserStore), new(*PostgresUserRepo)), // tell wire: *PostgresUserRepo satisfies UserStore
)
Explicit bindings prevent graph breakage when a new type implementing the same interface is added elsewhere.
Struct Providers and Values
wire.Struct fills struct fields from the graph without a manual constructor. Tag fields wire:"-" to exclude them.
wire.Struct(new(Server), "Logger", "DB") // inject named fields
wire.Struct(new(Server), "*") // inject all non-excluded fields
wire.Value(Foo{X: 42}) // constant expression (no fn calls / channels)
wire.InterfaceValue(new(io.Reader), os.Stdin) // interface-typed literal
wire.FieldsOf(new(Config), "DSN", "Addr") // promote struct fields as graph nodes
See advanced.md for the wire:"-" exclusion tag and wire.FieldsOf details.
Disambiguating Duplicate Types
Wire forbids two providers for the same type. Wrap the underlying type in distinct named types so each has exactly one provider:
type PrimaryDSN string
type ReplicaDSN string
Full Application Example
// wire.go — injector, excluded from binary via build tag
//go:build wireinject
package main
func InitApp() (*App, func(), error) {
wire.Build(config.ConfigSet, infra.InfraSet, service.ServiceSet, NewApp)
return nil, nil, nil
}
// main.go
func main() {
app, cleanup, err := InitApp()
if err != nil { log.Fatal(err) }
defer cleanup()
app.Run()
}
Wire generates wire_gen.go (plain Go, committed, DO NOT EDIT). For a full example with per-package sets, cleanup-heavy graphs, and generated output, see recipes.md.
Codegen Workflow
wire ./... # regenerate all injectors in the module
wire check ./... # validate graph without regenerating (fast CI check)
Run wire ./... after every constructor signature change. Add //go:generate go run github.com/google/wire/cmd/wire to injector files so go generate ./... also works. Commit wire_gen.go — it must stay in sync for CI builds.
Best Practices
- Never edit
wire_gen.go— it is overwritten on everywire ./...run. Treat it as a build artifact that happens to be committed; source of truth is the provider and injector files. - Always add
//go:build wireinjectto injector files — omitting it causes duplicate-symbol compile errors because both the stub and the generated file define the same function. - Use named types to distinguish values of the same underlying type — wire enforces one provider per type; named types like
type DSN stringlet you havePrimaryDSNandReplicaDSNcoexist. - Keep library provider sets minimal and backward-compatible — adding new required inputs breaks downstream injectors; removing outputs does too. Introduce only newly-created types in the same release.
- Return
(T, func(), error)from cleanup providers and let wire chain them — wire generates the correct reverse-order cleanup and handles partial failures (if construction fails midway, only already-built cleanups run). - Keep injector files focused — one function per file, one package import at a time. Fat injectors with dozens of
wire.Buildarguments are hard to reason about; delegate to per-package sets.
Common Mistakes
| Mistake | Fix |
|---|---|
Editing wire_gen.go manually | Never edit it. Change providers or injectors and re-run wire ./.... |
Missing //go:build wireinject | Add the tag as the very first line of every injector file. |
Two providers returning *sql.DB | Wrap with a named struct type: type PrimaryDB struct { *sql.DB } — Wire does not distinguish pointer type aliases. |
Injecting an interface without wire.Bind | Add wire.Bind(new(MyInterface), new(*MyImpl)) to the provider set. |
Forgetting to re-run wire ./... after changes | Run wire before go build; add it to go generate or a Makefile target. |
Calling cleanup() without guarding for nil | Wire returns nil cleanup on construction error; guard with if cleanup != nil { defer cleanup() }. |
Testing
Wire generates plain Go constructors, so unit tests use manual injection — no container to clone or reset. For testing patterns (test injectors swapping real providers for fakes, CI stale-check for wire_gen.go), see testing.md.
Further Reading
- advanced.md — cleanup chains, multiple injectors, set nesting, error catalogue, codegen flags, quick reference
- recipes.md — HTTP server, multi-injector build, cleanup-heavy graph, CLI embedding
- testing.md — test injectors, fake bindings, CI stale check
Cross-References
- → See
samber/cc-skills-golang@golang-dependency-injectionskill for DI concepts and library comparison - → See
samber/cc-skills-golang@golang-uber-digskill for runtime reflection-based DI without lifecycle - → See
samber/cc-skills-golang@golang-uber-fxskill for runtime DI with lifecycle hooks, modules, and signal-aware Run() - → See
samber/cc-skills-golang@golang-samber-doskill for generics-based DI without reflection - → See
samber/cc-skills-golang@golang-structs-interfacesskill for interface design patterns - → See
samber/cc-skills-golang@golang-testingskill for general testing patterns
If you encounter a bug or unexpected behavior in google/wire, open an issue at https://github.com/google/wire/issues.
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