// Copyright 2015 Matthew Holt and The Caddy Authors // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package caddy import ( "context" "encoding/json" "fmt" "log" "reflect" "github.com/caddyserver/certmagic" "go.uber.org/zap" ) // Context is a type which defines the lifetime of modules that // are loaded and provides access to the parent configuration // that spawned the modules which are loaded. It should be used // with care and wrapped with derivation functions from the // standard context package only if you don't need the Caddy // specific features. These contexts are canceled when the // lifetime of the modules loaded from it is over. // // Use NewContext() to get a valid value (but most modules will // not actually need to do this). type Context struct { context.Context moduleInstances map[string][]Module cfg *Config ancestry []Module cleanupFuncs []func() // invoked at every config unload exitFuncs []func(context.Context) // invoked at config unload ONLY IF the process is exiting (EXPERIMENTAL) } // NewContext provides a new context derived from the given // context ctx. Normally, you will not need to call this // function unless you are loading modules which have a // different lifespan than the ones for the context the // module was provisioned with. Be sure to call the cancel // func when the context is to be cleaned up so that // modules which are loaded will be properly unloaded. // See standard library context package's documentation. func NewContext(ctx Context) (Context, context.CancelFunc) { newCtx := Context{moduleInstances: make(map[string][]Module), cfg: ctx.cfg} c, cancel := context.WithCancel(ctx.Context) wrappedCancel := func() { cancel() for _, f := range ctx.cleanupFuncs { f() } for modName, modInstances := range newCtx.moduleInstances { for _, inst := range modInstances { if cu, ok := inst.(CleanerUpper); ok { err := cu.Cleanup() if err != nil { log.Printf("[ERROR] %s (%p): cleanup: %v", modName, inst, err) } } } } } newCtx.Context = c return newCtx, wrappedCancel } // OnCancel executes f when ctx is canceled. func (ctx *Context) OnCancel(f func()) { ctx.cleanupFuncs = append(ctx.cleanupFuncs, f) } // OnExit executes f when the process exits gracefully. // The function is only executed if the process is gracefully // shut down while this context is active. // // EXPERIMENTAL API: subject to change or removal. func (ctx *Context) OnExit(f func(context.Context)) { ctx.exitFuncs = append(ctx.exitFuncs, f) } // LoadModule loads the Caddy module(s) from the specified field of the parent struct // pointer and returns the loaded module(s). The struct pointer and its field name as // a string are necessary so that reflection can be used to read the struct tag on the // field to get the module namespace and inline module name key (if specified). // // The field can be any one of the supported raw module types: json.RawMessage, // []json.RawMessage, map[string]json.RawMessage, or []map[string]json.RawMessage. // ModuleMap may be used in place of map[string]json.RawMessage. The return value's // underlying type mirrors the input field's type: // // json.RawMessage => any // []json.RawMessage => []any // [][]json.RawMessage => [][]any // map[string]json.RawMessage => map[string]any // []map[string]json.RawMessage => []map[string]any // // The field must have a "caddy" struct tag in this format: // // caddy:"key1=val1 key2=val2" // // To load modules, a "namespace" key is required. For example, to load modules // in the "http.handlers" namespace, you'd put: `namespace=http.handlers` in the // Caddy struct tag. // // The module name must also be available. If the field type is a map or slice of maps, // then key is assumed to be the module name if an "inline_key" is NOT specified in the // caddy struct tag. In this case, the module name does NOT need to be specified in-line // with the module itself. // // If not a map, or if inline_key is non-empty, then the module name must be embedded // into the values, which must be objects; then there must be a key in those objects // where its associated value is the module name. This is called the "inline key", // meaning the key containing the module's name that is defined inline with the module // itself. You must specify the inline key in a struct tag, along with the namespace: // // caddy:"namespace=http.handlers inline_key=handler" // // This will look for a key/value pair like `"handler": "..."` in the json.RawMessage // in order to know the module name. // // To make use of the loaded module(s) (the return value), you will probably want // to type-assert each 'any' value(s) to the types that are useful to you // and store them on the same struct. Storing them on the same struct makes for // easy garbage collection when your host module is no longer needed. // // Loaded modules have already been provisioned and validated. Upon returning // successfully, this method clears the json.RawMessage(s) in the field since // the raw JSON is no longer needed, and this allows the GC to free up memory. func (ctx Context) LoadModule(structPointer any, fieldName string) (any, error) { val := reflect.ValueOf(structPointer).Elem().FieldByName(fieldName) typ := val.Type() field, ok := reflect.TypeOf(structPointer).Elem().FieldByName(fieldName) if !ok { panic(fmt.Sprintf("field %s does not exist in %#v", fieldName, structPointer)) } opts, err := ParseStructTag(field.Tag.Get("caddy")) if err != nil { panic(fmt.Sprintf("malformed tag on field %s: %v", fieldName, err)) } moduleNamespace, ok := opts["namespace"] if !ok { panic(fmt.Sprintf("missing 'namespace' key in struct tag on field %s", fieldName)) } inlineModuleKey := opts["inline_key"] var result any switch val.Kind() { case reflect.Slice: if isJSONRawMessage(typ) { // val is `json.RawMessage` ([]uint8 under the hood) if inlineModuleKey == "" { panic("unable to determine module name without inline_key when type is not a ModuleMap") } val, err := ctx.loadModuleInline(inlineModuleKey, moduleNamespace, val.Interface().(json.RawMessage)) if err != nil { return nil, err } result = val } else if isJSONRawMessage(typ.Elem()) { // val is `[]json.RawMessage` if inlineModuleKey == "" { panic("unable to determine module name without inline_key because type is not a ModuleMap") } var all []any for i := 0; i < val.Len(); i++ { val, err := ctx.loadModuleInline(inlineModuleKey, moduleNamespace, val.Index(i).Interface().(json.RawMessage)) if err != nil { return nil, fmt.Errorf("position %d: %v", i, err) } all = append(all, val) } result = all } else if typ.Elem().Kind() == reflect.Slice && isJSONRawMessage(typ.Elem().Elem()) { // val is `[][]json.RawMessage` if inlineModuleKey == "" { panic("unable to determine module name without inline_key because type is not a ModuleMap") } var all [][]any for i := 0; i < val.Len(); i++ { innerVal := val.Index(i) var allInner []any for j := 0; j < innerVal.Len(); j++ { innerInnerVal, err := ctx.loadModuleInline(inlineModuleKey, moduleNamespace, innerVal.Index(j).Interface().(json.RawMessage)) if err != nil { return nil, fmt.Errorf("position %d: %v", j, err) } allInner = append(allInner, innerInnerVal) } all = append(all, allInner) } result = all } else if isModuleMapType(typ.Elem()) { // val is `[]map[string]json.RawMessage` var all []map[string]any for i := 0; i < val.Len(); i++ { thisSet, err := ctx.loadModulesFromSomeMap(moduleNamespace, inlineModuleKey, val.Index(i)) if err != nil { return nil, err } all = append(all, thisSet) } result = all } case reflect.Map: // val is a ModuleMap or some other kind of map result, err = ctx.loadModulesFromSomeMap(moduleNamespace, inlineModuleKey, val) if err != nil { return nil, err } default: return nil, fmt.Errorf("unrecognized type for module: %s", typ) } // we're done with the raw bytes; allow GC to deallocate val.Set(reflect.Zero(typ)) return result, nil } // loadModulesFromSomeMap loads modules from val, which must be a type of map[string]any. // Depending on inlineModuleKey, it will be interpreted as either a ModuleMap (key is the module // name) or as a regular map (key is not the module name, and module name is defined inline). func (ctx Context) loadModulesFromSomeMap(namespace, inlineModuleKey string, val reflect.Value) (map[string]any, error) { // if no inline_key is specified, then val must be a ModuleMap, // where the key is the module name if inlineModuleKey == "" { if !isModuleMapType(val.Type()) { panic(fmt.Sprintf("expected ModuleMap because inline_key is empty; but we do not recognize this type: %s", val.Type())) } return ctx.loadModuleMap(namespace, val) } // otherwise, val is a map with modules, but the module name is // inline with each value (the key means something else) return ctx.loadModulesFromRegularMap(namespace, inlineModuleKey, val) } // loadModulesFromRegularMap loads modules from val, where val is a map[string]json.RawMessage. // Map keys are NOT interpreted as module names, so module names are still expected to appear // inline with the objects. func (ctx Context) loadModulesFromRegularMap(namespace, inlineModuleKey string, val reflect.Value) (map[string]any, error) { mods := make(map[string]any) iter := val.MapRange() for iter.Next() { k := iter.Key() v := iter.Value() mod, err := ctx.loadModuleInline(inlineModuleKey, namespace, v.Interface().(json.RawMessage)) if err != nil { return nil, fmt.Errorf("key %s: %v", k, err) } mods[k.String()] = mod } return mods, nil } // loadModuleMap loads modules from a ModuleMap, i.e. map[string]any, where the key is the // module name. With a module map, module names do not need to be defined inline with their values. func (ctx Context) loadModuleMap(namespace string, val reflect.Value) (map[string]any, error) { all := make(map[string]any) iter := val.MapRange() for iter.Next() { k := iter.Key().Interface().(string) v := iter.Value().Interface().(json.RawMessage) moduleName := namespace + "." + k if namespace == "" { moduleName = k } val, err := ctx.LoadModuleByID(moduleName, v) if err != nil { return nil, fmt.Errorf("module name '%s': %v", k, err) } all[k] = val } return all, nil } // LoadModuleByID decodes rawMsg into a new instance of mod and // returns the value. If mod.New is nil, an error is returned. // If the module implements Validator or Provisioner interfaces, // those methods are invoked to ensure the module is fully // configured and valid before being used. // // This is a lower-level method and will usually not be called // directly by most modules. However, this method is useful when // dynamically loading/unloading modules in their own context, // like from embedded scripts, etc. func (ctx Context) LoadModuleByID(id string, rawMsg json.RawMessage) (any, error) { modulesMu.RLock() modInfo, ok := modules[id] modulesMu.RUnlock() if !ok { return nil, fmt.Errorf("unknown module: %s", id) } if modInfo.New == nil { return nil, fmt.Errorf("module '%s' has no constructor", modInfo.ID) } val := modInfo.New() // value must be a pointer for unmarshaling into concrete type, even if // the module's concrete type is a slice or map; New() *should* return // a pointer, otherwise unmarshaling errors or panics will occur if rv := reflect.ValueOf(val); rv.Kind() != reflect.Ptr { log.Printf("[WARNING] ModuleInfo.New() for module '%s' did not return a pointer,"+ " so we are using reflection to make a pointer instead; please fix this by"+ " using new(Type) or &Type notation in your module's New() function.", id) val = reflect.New(rv.Type()).Elem().Addr().Interface().(Module) } // fill in its config only if there is a config to fill in if len(rawMsg) > 0 { err := StrictUnmarshalJSON(rawMsg, &val) if err != nil { return nil, fmt.Errorf("decoding module config: %s: %v", modInfo, err) } } if val == nil { // returned module values are almost always type-asserted // before being used, so a nil value would panic; and there // is no good reason to explicitly declare null modules in // a config; it might be because the user is trying to achieve // a result the developer isn't expecting, which is a smell return nil, fmt.Errorf("module value cannot be null") } ctx.ancestry = append(ctx.ancestry, val) if prov, ok := val.(Provisioner); ok { err := prov.Provision(ctx) if err != nil { // incomplete provisioning could have left state // dangling, so make sure it gets cleaned up if cleanerUpper, ok := val.(CleanerUpper); ok { err2 := cleanerUpper.Cleanup() if err2 != nil { err = fmt.Errorf("%v; additionally, cleanup: %v", err, err2) } } return nil, fmt.Errorf("provision %s: %v", modInfo, err) } } if validator, ok := val.(Validator); ok { err := validator.Validate() if err != nil { // since the module was already provisioned, make sure we clean up if cleanerUpper, ok := val.(CleanerUpper); ok { err2 := cleanerUpper.Cleanup() if err2 != nil { err = fmt.Errorf("%v; additionally, cleanup: %v", err, err2) } } return nil, fmt.Errorf("%s: invalid configuration: %v", modInfo, err) } } ctx.moduleInstances[id] = append(ctx.moduleInstances[id], val) return val, nil } // loadModuleInline loads a module from a JSON raw message which decodes to // a map[string]any, where one of the object keys is moduleNameKey // and the corresponding value is the module name (as a string) which can // be found in the given scope. In other words, the module name is declared // in-line with the module itself. // // This allows modules to be decoded into their concrete types and used when // their names cannot be the unique key in a map, such as when there are // multiple instances in the map or it appears in an array (where there are // no custom keys). In other words, the key containing the module name is // treated special/separate from all the other keys in the object. func (ctx Context) loadModuleInline(moduleNameKey, moduleScope string, raw json.RawMessage) (any, error) { moduleName, raw, err := getModuleNameInline(moduleNameKey, raw) if err != nil { return nil, err } val, err := ctx.LoadModuleByID(moduleScope+"."+moduleName, raw) if err != nil { return nil, fmt.Errorf("loading module '%s': %v", moduleName, err) } return val, nil } // App returns the configured app named name. If that app has // not yet been loaded and provisioned, it will be immediately // loaded and provisioned. If no app with that name is // configured, a new empty one will be instantiated instead. // (The app module must still be registered.) This must not be // called during the Provision/Validate phase to reference a // module's own host app (since the parent app module is still // in the process of being provisioned, it is not yet ready). // // We return any type instead of the App type because it is NOT // intended for the caller of this method to be the one to start // or stop App modules. The caller is expected to assert to the // concrete type. func (ctx Context) App(name string) (any, error) { if app, ok := ctx.cfg.apps[name]; ok { return app, nil } appRaw := ctx.cfg.AppsRaw[name] modVal, err := ctx.LoadModuleByID(name, appRaw) if err != nil { return nil, fmt.Errorf("loading %s app module: %v", name, err) } if appRaw != nil { ctx.cfg.AppsRaw[name] = nil // allow GC to deallocate } ctx.cfg.apps[name] = modVal.(App) return modVal, nil } // AppIfConfigured returns an app by its name if it has been // configured. Can be called instead of App() to avoid // instantiating an empty app when that's not desirable. If // the app has not been loaded, nil is returned. // // We return any type instead of the App type because it is not // intended for the caller of this method to be the one to start // or stop App modules. The caller is expected to assert to the // concrete type. func (ctx Context) AppIfConfigured(name string) any { if ctx.cfg == nil { // this can happen if the currently-active context // is being accessed, but no config has successfully // been loaded yet return nil } return ctx.cfg.apps[name] } // Storage returns the configured Caddy storage implementation. func (ctx Context) Storage() certmagic.Storage { return ctx.cfg.storage } // Logger returns a logger that is intended for use by the most // recent module associated with the context. Callers should not // pass in any arguments unless they want to associate with a // different module; it panics if more than 1 value is passed in. // // Originally, this method's signature was `Logger(mod Module)`, // requiring that an instance of a Caddy module be passed in. // However, that is no longer necessary, as the closest module // most recently associated with the context will be automatically // assumed. To prevent a sudden breaking change, this method's // signature has been changed to be variadic, but we may remove // the parameter altogether in the future. Callers should not // pass in any argument. If there is valid need to specify a // different module, please open an issue to discuss. // // PARTIALLY DEPRECATED: The Logger(module) form is deprecated and // may be removed in the future. Do not pass in any arguments. func (ctx Context) Logger(module ...Module) *zap.Logger { if len(module) > 1 { panic("more than 1 module passed in") } if ctx.cfg == nil { // often the case in tests; just use a dev logger l, err := zap.NewDevelopment() if err != nil { panic("config missing, unable to create dev logger: " + err.Error()) } return l } mod := ctx.Module() if len(module) > 0 { mod = module[0] } if mod == nil { return Log() } return ctx.cfg.Logging.Logger(mod) } // Modules returns the lineage of modules that this context provisioned, // with the most recent/current module being last in the list. func (ctx Context) Modules() []Module { mods := make([]Module, len(ctx.ancestry)) copy(mods, ctx.ancestry) return mods } // Module returns the current module, or the most recent one // provisioned by the context. func (ctx Context) Module() Module { if len(ctx.ancestry) == 0 { return nil } return ctx.ancestry[len(ctx.ancestry)-1] }