// 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 caddyhttp import ( "encoding/json" "fmt" "net/http" "github.com/caddyserver/caddy/v2" ) // Route consists of a set of rules for matching HTTP requests, // a list of handlers to execute, and optional flow control // parameters which customize the handling of HTTP requests // in a highly flexible and performant manner. type Route struct { // Group is an optional name for a group to which this // route belongs. Grouping a route makes it mutually // exclusive with others in its group; if a route belongs // to a group, only the first matching route in that group // will be executed. Group string `json:"group,omitempty"` // The matcher sets which will be used to qualify this // route for a request (essentially the "if" statement // of this route). Each matcher set is OR'ed, but matchers // within a set are AND'ed together. MatcherSetsRaw RawMatcherSets `json:"match,omitempty" caddy:"namespace=http.matchers"` // The list of handlers for this route. Upon matching a request, they are chained // together in a middleware fashion: requests flow from the first handler to the last // (top of the list to the bottom), with the possibility that any handler could stop // the chain and/or return an error. Responses flow back through the chain (bottom of // the list to the top) as they are written out to the client. // // Not all handlers call the next handler in the chain. For example, the reverse_proxy // handler always sends a request upstream or returns an error. Thus, configuring // handlers after reverse_proxy in the same route is illogical, since they would never // be executed. You will want to put handlers which originate the response at the very // end of your route(s). The documentation for a module should state whether it invokes // the next handler, but sometimes it is common sense. // // Some handlers manipulate the response. Remember that requests flow down the list, and // responses flow up the list. // // For example, if you wanted to use both `templates` and `encode` handlers, you would // need to put `templates` after `encode` in your route, because responses flow up. // Thus, `templates` will be able to parse and execute the plain-text response as a // template, and then return it up to the `encode` handler which will then compress it // into a binary format. // // If `templates` came before `encode`, then `encode` would write a compressed, // binary-encoded response to `templates` which would not be able to parse the response // properly. // // The correct order, then, is this: // // [ // {"handler": "encode"}, // {"handler": "templates"}, // {"handler": "file_server"} // ] // // The request flows ⬇️ DOWN (`encode` -> `templates` -> `file_server`). // // 1. First, `encode` will choose how to `encode` the response and wrap the response. // 2. Then, `templates` will wrap the response with a buffer. // 3. Finally, `file_server` will originate the content from a file. // // The response flows ⬆️ UP (`file_server` -> `templates` -> `encode`): // // 1. First, `file_server` will write the file to the response. // 2. That write will be buffered and then executed by `templates`. // 3. Lastly, the write from `templates` will flow into `encode` which will compress the stream. // // If you think of routes in this way, it will be easy and even fun to solve the puzzle of writing correct routes. HandlersRaw []json.RawMessage `json:"handle,omitempty" caddy:"namespace=http.handlers inline_key=handler"` // If true, no more routes will be executed after this one. Terminal bool `json:"terminal,omitempty"` // decoded values MatcherSets MatcherSets `json:"-"` Handlers []MiddlewareHandler `json:"-"` middleware []Middleware } // Empty returns true if the route has all zero/default values. func (r Route) Empty() bool { return len(r.MatcherSetsRaw) == 0 && len(r.MatcherSets) == 0 && len(r.HandlersRaw) == 0 && len(r.Handlers) == 0 && !r.Terminal && r.Group == "" } func (r Route) String() string { handlersRaw := "[" for _, hr := range r.HandlersRaw { handlersRaw += " " + string(hr) } handlersRaw += "]" return fmt.Sprintf(`{Group:"%s" MatcherSetsRaw:%s HandlersRaw:%s Terminal:%t}`, r.Group, r.MatcherSetsRaw, handlersRaw, r.Terminal) } // Provision sets up both the matchers and handlers in the route. func (r *Route) Provision(ctx caddy.Context, metrics *Metrics) error { err := r.ProvisionMatchers(ctx) if err != nil { return err } return r.ProvisionHandlers(ctx, metrics) } // ProvisionMatchers sets up all the matchers by loading the // matcher modules. Only call this method directly if you need // to set up matchers and handlers separately without having // to provision a second time; otherwise use Provision instead. func (r *Route) ProvisionMatchers(ctx caddy.Context) error { // matchers matchersIface, err := ctx.LoadModule(r, "MatcherSetsRaw") if err != nil { return fmt.Errorf("loading matcher modules: %v", err) } err = r.MatcherSets.FromInterface(matchersIface) if err != nil { return err } return nil } // ProvisionHandlers sets up all the handlers by loading the // handler modules. Only call this method directly if you need // to set up matchers and handlers separately without having // to provision a second time; otherwise use Provision instead. func (r *Route) ProvisionHandlers(ctx caddy.Context, metrics *Metrics) error { handlersIface, err := ctx.LoadModule(r, "HandlersRaw") if err != nil { return fmt.Errorf("loading handler modules: %v", err) } for _, handler := range handlersIface.([]any) { r.Handlers = append(r.Handlers, handler.(MiddlewareHandler)) } // Make ProvisionHandlers idempotent by clearing the middleware field r.middleware = []Middleware{} // pre-compile the middleware handler chain for _, midhandler := range r.Handlers { r.middleware = append(r.middleware, wrapMiddleware(ctx, midhandler, metrics)) } return nil } // Compile prepares a middleware chain from the route list. // This should only be done once during the request, just // before the middleware chain is executed. func (r Route) Compile(next Handler) Handler { return wrapRoute(r)(next) } // RouteList is a list of server routes that can // create a middleware chain. type RouteList []Route // Provision sets up both the matchers and handlers in the routes. func (routes RouteList) Provision(ctx caddy.Context) error { err := routes.ProvisionMatchers(ctx) if err != nil { return err } return routes.ProvisionHandlers(ctx, nil) } // ProvisionMatchers sets up all the matchers by loading the // matcher modules. Only call this method directly if you need // to set up matchers and handlers separately without having // to provision a second time; otherwise use Provision instead. func (routes RouteList) ProvisionMatchers(ctx caddy.Context) error { for i := range routes { err := routes[i].ProvisionMatchers(ctx) if err != nil { return fmt.Errorf("route %d: %v", i, err) } } return nil } // ProvisionHandlers sets up all the handlers by loading the // handler modules. Only call this method directly if you need // to set up matchers and handlers separately without having // to provision a second time; otherwise use Provision instead. func (routes RouteList) ProvisionHandlers(ctx caddy.Context, metrics *Metrics) error { for i := range routes { err := routes[i].ProvisionHandlers(ctx, metrics) if err != nil { return fmt.Errorf("route %d: %v", i, err) } } return nil } // Compile prepares a middleware chain from the route list. // This should only be done either once during provisioning // for top-level routes, or on each request just before the // middleware chain is executed for subroutes. func (routes RouteList) Compile(next Handler) Handler { mid := make([]Middleware, 0, len(routes)) for _, route := range routes { mid = append(mid, wrapRoute(route)) } stack := next for i := len(mid) - 1; i >= 0; i-- { stack = mid[i](stack) } return stack } // wrapRoute wraps route with a middleware and handler so that it can // be chained in and defer evaluation of its matchers to request-time. // Like wrapMiddleware, it is vital that this wrapping takes place in // its own stack frame so as to not overwrite the reference to the // intended route by looping and changing the reference each time. func wrapRoute(route Route) Middleware { return func(next Handler) Handler { return HandlerFunc(func(rw http.ResponseWriter, req *http.Request) error { // TODO: Update this comment, it seems we've moved the copy into the handler? // copy the next handler (it's an interface, so it's just // a very lightweight copy of a pointer); this is important // because this is a closure to the func below, which // re-assigns the value as it compiles the middleware stack; // if we don't make this copy, we'd affect the underlying // pointer for all future request (yikes); we could // alternatively solve this by moving the func below out of // this closure and into a standalone package-level func, // but I just thought this made more sense nextCopy := next // route must match at least one of the matcher sets if !route.MatcherSets.AnyMatch(req) { // allow matchers the opportunity to short circuit // the request and trigger the error handling chain err, ok := GetVar(req.Context(), MatcherErrorVarKey).(error) if ok { // clear out the error from context, otherwise // it will cascade to the error routes (#4916) SetVar(req.Context(), MatcherErrorVarKey, nil) // return the matcher's error return err } // call the next handler, and skip this one, // since the matcher didn't match return nextCopy.ServeHTTP(rw, req) } // if route is part of a group, ensure only the // first matching route in the group is applied if route.Group != "" { groups := req.Context().Value(routeGroupCtxKey).(map[string]struct{}) if _, ok := groups[route.Group]; ok { // this group has already been // satisfied by a matching route return nextCopy.ServeHTTP(rw, req) } // this matching route satisfies the group groups[route.Group] = struct{}{} } // make terminal routes terminate if route.Terminal { if _, ok := req.Context().Value(ErrorCtxKey).(error); ok { nextCopy = errorEmptyHandler } else { nextCopy = emptyHandler } } // compile this route's handler stack for i := len(route.middleware) - 1; i >= 0; i-- { nextCopy = route.middleware[i](nextCopy) } return nextCopy.ServeHTTP(rw, req) }) } } // wrapMiddleware wraps mh such that it can be correctly // appended to a list of middleware in preparation for // compiling into a handler chain. We can't do this inline // inside a loop, because it relies on a reference to mh // not changing until the execution of its handler (which // is deferred by multiple func closures). In other words, // we need to pull this particular MiddlewareHandler // pointer into its own stack frame to preserve it so it // won't be overwritten in future loop iterations. func wrapMiddleware(ctx caddy.Context, mh MiddlewareHandler, metrics *Metrics) Middleware { handlerToUse := mh if metrics != nil { // wrap the middleware with metrics instrumentation handlerToUse = newMetricsInstrumentedHandler(ctx, caddy.GetModuleName(mh), mh, metrics) } return func(next Handler) Handler { // copy the next handler (it's an interface, so it's // just a very lightweight copy of a pointer); this // is a safeguard against the handler changing the // value, which could affect future requests (yikes) nextCopy := next return HandlerFunc(func(w http.ResponseWriter, r *http.Request) error { // EXPERIMENTAL: Trace each module that gets invoked if server, ok := r.Context().Value(ServerCtxKey).(*Server); ok && server != nil { server.logTrace(handlerToUse) } return handlerToUse.ServeHTTP(w, r, nextCopy) }) } } // MatcherSet is a set of matchers which // must all match in order for the request // to be matched successfully. type MatcherSet []RequestMatcher // Match returns true if the request matches all // matchers in mset or if there are no matchers. func (mset MatcherSet) Match(r *http.Request) bool { for _, m := range mset { if !m.Match(r) { return false } } return true } // RawMatcherSets is a group of matcher sets // in their raw, JSON form. type RawMatcherSets []caddy.ModuleMap // MatcherSets is a group of matcher sets capable // of checking whether a request matches any of // the sets. type MatcherSets []MatcherSet // AnyMatch returns true if req matches any of the // matcher sets in ms or if there are no matchers, // in which case the request always matches. func (ms MatcherSets) AnyMatch(req *http.Request) bool { for _, m := range ms { if m.Match(req) { return true } } return len(ms) == 0 } // FromInterface fills ms from an 'any' value obtained from LoadModule. func (ms *MatcherSets) FromInterface(matcherSets any) error { for _, matcherSetIfaces := range matcherSets.([]map[string]any) { var matcherSet MatcherSet for _, matcher := range matcherSetIfaces { reqMatcher, ok := matcher.(RequestMatcher) if !ok { return fmt.Errorf("decoded module is not a RequestMatcher: %#v", matcher) } matcherSet = append(matcherSet, reqMatcher) } *ms = append(*ms, matcherSet) } return nil } // TODO: Is this used? func (ms MatcherSets) String() string { result := "[" for _, matcherSet := range ms { for _, matcher := range matcherSet { result += fmt.Sprintf(" %#v", matcher) } } return result + " ]" } var routeGroupCtxKey = caddy.CtxKey("route_group")