// Copyright (c) 2021 Uber Technologies, Inc. // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. package dig import ( "fmt" "math/rand" "reflect" "go.uber.org/dig/internal/dot" ) const ( _optionalTag = "optional" _nameTag = "name" _ignoreUnexportedTag = "ignore-unexported" ) // Unique identification of an object in the graph. type key struct { t reflect.Type // Only one of name or group will be set. name string group string } func (k key) String() string { if k.name != "" { return fmt.Sprintf("%v[name=%q]", k.t, k.name) } if k.group != "" { return fmt.Sprintf("%v[group=%q]", k.t, k.group) } return k.t.String() } // Option configures a Container. It's included for future functionality; // currently, there are no concrete implementations. type Option interface { applyOption(*Container) } // Container is a directed acyclic graph of types and their dependencies. // A Container is the root Scope that represents the top-level scoped // directed acyclic graph of the dependencies. type Container struct { // this is the "root" Scope that represents the // root of the scope tree. scope *Scope } // containerWriter provides write access to the Container's underlying data // store. type containerWriter interface { // setValue sets the value with the given name and type in the container. // If a value with the same name and type already exists, it will be // overwritten. setValue(name string, t reflect.Type, v reflect.Value) // setDecoratedValue sets a decorated value with the given name and type // in the container. If a decorated value with the same name and type already // exists, it will be overwritten. setDecoratedValue(name string, t reflect.Type, v reflect.Value) // submitGroupedValue submits a value to the value group with the provided // name. submitGroupedValue(name string, t reflect.Type, v reflect.Value) // submitDecoratedGroupedValue submits a decorated value to the value group // with the provided name. submitDecoratedGroupedValue(name string, t reflect.Type, v reflect.Value) } // containerStore provides access to the Container's underlying data store. type containerStore interface { containerWriter // Adds a new graph node to the Container newGraphNode(w interface{}, orders map[*Scope]int) // Returns a slice containing all known types. knownTypes() []reflect.Type // Retrieves the value with the provided name and type, if any. getValue(name string, t reflect.Type) (v reflect.Value, ok bool) // Retrieves a decorated value with the provided name and type, if any. getDecoratedValue(name string, t reflect.Type) (v reflect.Value, ok bool) // Retrieves all values for the provided group and type. // // The order in which the values are returned is undefined. getValueGroup(name string, t reflect.Type) []reflect.Value // Retrieves all decorated values for the provided group and type, if any. getDecoratedValueGroup(name string, t reflect.Type) (reflect.Value, bool) // Returns the providers that can produce a value with the given name and // type. getValueProviders(name string, t reflect.Type) []provider // Returns the providers that can produce values for the given group and // type. getGroupProviders(name string, t reflect.Type) []provider // Returns the providers that can produce a value with the given name and // type across all the Scopes that are in effect of this containerStore. getAllValueProviders(name string, t reflect.Type) []provider // Returns the decorator that can decorate values for the given name and // type. getValueDecorator(name string, t reflect.Type) (decorator, bool) // Reutrns the decorator that can decorate values for the given group and // type. getGroupDecorator(name string, t reflect.Type) (decorator, bool) // Reports a list of stores (starting at this store) up to the root // store. storesToRoot() []containerStore createGraph() *dot.Graph // Returns invokerFn function to use when calling arguments. invoker() invokerFn } // New constructs a Container. func New(opts ...Option) *Container { s := newScope() c := &Container{scope: s} for _, opt := range opts { opt.applyOption(c) } return c } // DeferAcyclicVerification is an Option to override the default behavior // of container.Provide, deferring the dependency graph validation to no longer // run after each call to container.Provide. The container will instead verify // the graph on first `Invoke`. // // Applications adding providers to a container in a tight loop may experience // performance improvements by initializing the container with this option. func DeferAcyclicVerification() Option { return deferAcyclicVerificationOption{} } type deferAcyclicVerificationOption struct{} func (deferAcyclicVerificationOption) String() string { return "DeferAcyclicVerification()" } func (deferAcyclicVerificationOption) applyOption(c *Container) { c.scope.deferAcyclicVerification = true } // Changes the source of randomness for the container. // // This will help provide determinism during tests. func setRand(r *rand.Rand) Option { return setRandOption{r: r} } type setRandOption struct{ r *rand.Rand } func (o setRandOption) String() string { return fmt.Sprintf("setRand(%p)", o.r) } func (o setRandOption) applyOption(c *Container) { c.scope.rand = o.r } // DryRun is an Option which, when set to true, disables invocation of functions supplied to // Provide and Invoke. Use this to build no-op containers. func DryRun(dry bool) Option { return dryRunOption(dry) } type dryRunOption bool func (o dryRunOption) String() string { return fmt.Sprintf("DryRun(%v)", bool(o)) } func (o dryRunOption) applyOption(c *Container) { if o { c.scope.invokerFn = dryInvoker } else { c.scope.invokerFn = defaultInvoker } } // invokerFn specifies how the container calls user-supplied functions. type invokerFn func(fn reflect.Value, args []reflect.Value) (results []reflect.Value) func defaultInvoker(fn reflect.Value, args []reflect.Value) []reflect.Value { return fn.Call(args) } // Generates zero values for results without calling the supplied function. func dryInvoker(fn reflect.Value, _ []reflect.Value) []reflect.Value { ft := fn.Type() results := make([]reflect.Value, ft.NumOut()) for i := 0; i < ft.NumOut(); i++ { results[i] = reflect.Zero(fn.Type().Out(i)) } return results } // String representation of the entire Container func (c *Container) String() string { return c.scope.String() } // Scope creates a child scope of the Container with the given name. func (c *Container) Scope(name string, opts ...ScopeOption) *Scope { return c.scope.Scope(name, opts...) } type byTypeName []reflect.Type func (bs byTypeName) Len() int { return len(bs) } func (bs byTypeName) Less(i int, j int) bool { return fmt.Sprint(bs[i]) < fmt.Sprint(bs[j]) } func (bs byTypeName) Swap(i int, j int) { bs[i], bs[j] = bs[j], bs[i] } func shuffledCopy(rand *rand.Rand, items []reflect.Value) []reflect.Value { newItems := make([]reflect.Value, len(items)) for i, j := range rand.Perm(len(items)) { newItems[i] = items[j] } return newItems }