package context import ( "bytes" "encoding/json" "encoding/xml" "fmt" "io" "io/ioutil" "mime" "mime/multipart" "net" "net/http" "net/url" "os" "path" "path/filepath" "reflect" "regexp" "runtime" "strconv" "strings" "time" "github.com/fatih/structs" "github.com/iris-contrib/form-binder" "github.com/json-iterator/go" "github.com/microcosm-cc/bluemonday" "github.com/russross/blackfriday" "github.com/kataras/iris/core/errors" "github.com/kataras/iris/core/memstore" ) type ( // BodyDecoder is an interface which any struct can implement in order to customize the decode action // from ReadJSON and ReadXML // // Trivial example of this could be: // type User struct { Username string } // // func (u *User) Decode(data []byte) error { // return json.Unmarshal(data, u) // } // // the 'context.ReadJSON/ReadXML(&User{})' will call the User's // Decode option to decode the request body // // Note: This is totally optionally, the default decoders // for ReadJSON is the encoding/json and for ReadXML is the encoding/xml. BodyDecoder interface { Decode(data []byte) error } // Unmarshaler is the interface implemented by types that can unmarshal any raw data // TIP INFO: Any v object which implements the BodyDecoder can be override the unmarshaler. Unmarshaler interface { Unmarshal(data []byte, v interface{}) error } // UnmarshalerFunc a shortcut for the Unmarshaler interface // // See 'Unmarshaler' and 'BodyDecoder' for more. UnmarshalerFunc func(data []byte, v interface{}) error ) // Unmarshal parses the X-encoded data and stores the result in the value pointed to by v. // Unmarshal uses the inverse of the encodings that Marshal uses, allocating maps, // slices, and pointers as necessary. func (u UnmarshalerFunc) Unmarshal(data []byte, v interface{}) error { return u(data, v) } // RequestParams is a key string - value string storage which context's request params should implement. // RequestValues is for communication between middleware, RequestParams cannot be changed, are setted at the routing // time, stores the dynamic named parameters, can be empty if the route is static. type RequestParams struct { store memstore.Store } // Set shouldn't be used as a local storage, context's values store // is the local storage, not params. func (r *RequestParams) Set(key, value string) { r.store.Set(key, value) } // Visit accepts a visitor which will be filled // by the key-value params. func (r *RequestParams) Visit(visitor func(key string, value string)) { r.store.Visit(func(k string, v interface{}) { visitor(k, v.(string)) // always string here. }) } // Get returns a path parameter's value based on its route's dynamic path key. func (r RequestParams) Get(key string) string { return r.store.GetString(key) } // GetInt returns the param's value as int, based on its key. func (r RequestParams) GetInt(key string) (int, error) { return r.store.GetInt(key) } // GetInt64 returns the user's value as int64, based on its key. func (r RequestParams) GetInt64(key string) (int64, error) { return r.store.GetInt64(key) } // GetDecoded returns the url-query-decoded user's value based on its key. func (r RequestParams) GetDecoded(key string) string { return DecodeQuery(DecodeQuery(r.Get(key))) } // GetIntUnslashed same as Get but it removes the first slash if found. // Usage: Get an id from a wildcard path. // // Returns -1 with an error if the parameter couldn't be found. func (r RequestParams) GetIntUnslashed(key string) (int, error) { v := r.Get(key) if v != "" { if len(v) > 1 { if v[0] == '/' { v = v[1:] } } return strconv.Atoi(v) } return -1, memstore.ErrIntParse.Format(v) } // Len returns the full length of the parameters. func (r RequestParams) Len() int { return r.store.Len() } // Context is the midle-man server's "object" for the clients. // // A New context is being acquired from a sync.Pool on each connection. // The Context is the most important thing on the iris's http flow. // // Developers send responses to the client's request through a Context. // Developers get request information from the client's request a Context. // // This context is an implementation of the context.Context sub-package. // context.Context is very extensible and developers can override // its methods if that is actually needed. type Context interface { // BeginRequest is executing once for each request // it should prepare the (new or acquired from pool) context's fields for the new request. // // To follow the iris' flow, developer should: // 1. reset handlers to nil // 2. reset values to empty // 3. reset sessions to nil // 4. reset response writer to the http.ResponseWriter // 5. reset request to the *http.Request // and any other optional steps, depends on dev's application type. BeginRequest(http.ResponseWriter, *http.Request) // EndRequest is executing once after a response to the request was sent and this context is useless or released. // // To follow the iris' flow, developer should: // 1. flush the response writer's result // 2. release the response writer // and any other optional steps, depends on dev's application type. EndRequest() // ResponseWriter returns an http.ResponseWriter compatible response writer, as expected. ResponseWriter() ResponseWriter // ResetResponseWriter should change or upgrade the Context's ResponseWriter. ResetResponseWriter(ResponseWriter) // Request returns the original *http.Request, as expected. Request() *http.Request // SetCurrentRouteName sets the route's name internally, // in order to be able to find the correct current "read-only" Route when // end-developer calls the `GetCurrentRoute()` function. // It's being initialized by the Router, if you change that name // manually nothing really happens except that you'll get other // route via `GetCurrentRoute()`. // Instead, to execute a different path // from this context you should use the `Exec` function // or change the handlers via `SetHandlers/AddHandler` functions. SetCurrentRouteName(currentRouteName string) // GetCurrentRoute returns the current registered "read-only" route that // was being registered to this request's path. GetCurrentRoute() RouteReadOnly // Do calls the SetHandlers(handlers) // and executes the first handler, // handlers should not be empty. // // It's used by the router, developers may use that // to replace and execute handlers immediately. Do(Handlers) // AddHandler can add handler(s) // to the current request in serve-time, // these handlers are not persistenced to the router. // // Router is calling this function to add the route's handler. // If AddHandler called then the handlers will be inserted // to the end of the already-defined route's handler. // AddHandler(...Handler) // SetHandlers replaces all handlers with the new. SetHandlers(Handlers) // Handlers keeps tracking of the current handlers. Handlers() Handlers // HandlerIndex sets the current index of the // current context's handlers chain. // If -1 passed then it just returns the // current handler index without change the current index.rns that index, useless return value. // // Look Handlers(), Next() and StopExecution() too. HandlerIndex(n int) (currentIndex int) // HandlerName returns the current handler's name, helpful for debugging. HandlerName() string // Next calls all the next handler from the handlers chain, // it should be used inside a middleware. // // Note: Custom context should override this method in order to be able to pass its own context.Context implementation. Next() // NextHandler returns(but it is NOT executes) the next handler from the handlers chain. // // Use .Skip() to skip this handler if needed to execute the next of this returning handler. NextHandler() Handler // Skip skips/ignores the next handler from the handlers chain, // it should be used inside a middleware. Skip() // StopExecution if called then the following .Next calls are ignored. StopExecution() // IsStopped checks and returns true if the current position of the Context is 255, // means that the StopExecution() was called. IsStopped() bool // +------------------------------------------------------------+ // | Current "user/request" storage | // | and share information between the handlers - Values(). | // | Save and get named path parameters - Params() | // +------------------------------------------------------------+ // Params returns the current url's named parameters key-value storage. // Named path parameters are being saved here. // This storage, as the whole Context, is per-request lifetime. Params() *RequestParams // Values returns the current "user" storage. // Named path parameters and any optional data can be saved here. // This storage, as the whole Context, is per-request lifetime. // // You can use this function to Set and Get local values // that can be used to share information between handlers and middleware. Values() *memstore.Store // Translate is the i18n (localization) middleware's function, // it calls the Get("translate") to return the translated value. // // Example: https://github.com/kataras/iris/tree/master/_examples/miscellaneous/i18n Translate(format string, args ...interface{}) string // +------------------------------------------------------------+ // | Path, Host, Subdomain, IP, Headers etc... | // +------------------------------------------------------------+ // Method returns the request.Method, the client's http method to the server. Method() string // Path returns the full request path, // escaped if EnablePathEscape config field is true. Path() string // RequestPath returns the full request path, // based on the 'escape'. RequestPath(escape bool) string // Host returns the host part of the current url. Host() string // Subdomain returns the subdomain of this request, if any. // Note that this is a fast method which does not cover all cases. Subdomain() (subdomain string) // RemoteAddr tries to parse and return the real client's request IP. // // Based on allowed headers names that can be modified from Configuration.RemoteAddrHeaders. // // If parse based on these headers fail then it will return the Request's `RemoteAddr` field // which is filled by the server before the HTTP handler. // // Look `Configuration.RemoteAddrHeaders`, // `Configuration.WithRemoteAddrHeader(...)`, // `Configuration.WithoutRemoteAddrHeader(...)` for more. RemoteAddr() string // GetHeader returns the request header's value based on its name. GetHeader(name string) string // IsAjax returns true if this request is an 'ajax request'( XMLHttpRequest) // // There is no a 100% way of knowing that a request was made via Ajax. // You should never trust data coming from the client, they can be easily overcome by spoofing. // // Note that "X-Requested-With" Header can be modified by any client(because of "X-"), // so don't rely on IsAjax for really serious stuff, // try to find another way of detecting the type(i.e, content type), // there are many blogs that describe these problems and provide different kind of solutions, // it's always depending on the application you're building, // this is the reason why this `IsAjax`` is simple enough for general purpose use. // // Read more at: https://developer.mozilla.org/en-US/docs/AJAX // and https://xhr.spec.whatwg.org/ IsAjax() bool // +------------------------------------------------------------+ // | Response Headers helpers | // +------------------------------------------------------------+ // Header adds a header to the response writer. Header(name string, value string) // ContentType sets the response writer's header key "Content-Type" to the 'cType'. ContentType(cType string) // GetContentType returns the response writer's header value of "Content-Type" // which may, setted before with the 'ContentType'. GetContentType() string // StatusCode sets the status code header to the response. // Look .GetStatusCode too. StatusCode(statusCode int) // GetStatusCode returns the current status code of the response. // Look StatusCode too. GetStatusCode() int // Redirect redirect sends a redirect response the client // accepts 2 parameters string and an optional int // first parameter is the url to redirect // second parameter is the http status should send, default is 302 (StatusFound), // you can set it to 301 (Permant redirect), if that's nessecery Redirect(urlToRedirect string, statusHeader ...int) // +------------------------------------------------------------+ // | Various Request and Post Data | // +------------------------------------------------------------+ // URLParam returns the get parameter from a request , if any. URLParam(name string) string // URLParamInt returns the url query parameter as int value from a request, // returns an error if parse failed. URLParamInt(name string) (int, error) // URLParamInt64 returns the url query parameter as int64 value from a request, // returns an error if parse failed. URLParamInt64(name string) (int64, error) // URLParams returns a map of GET query parameters separated by comma if more than one // it returns an empty map if nothing found. URLParams() map[string]string // FormValue returns a single form value by its name/key FormValue(name string) string // FormValues returns all post data values with their keys // form data, get, post & put query arguments // // NOTE: A check for nil is necessary. FormValues() map[string][]string // PostValue returns a form's only-post value by its name, // same as Request.PostFormValue. PostValue(name string) string // FormFile returns the first file for the provided form key. // FormFile calls ctx.Request.ParseMultipartForm and ParseForm if necessary. // // same as Request.FormFile. FormFile(key string) (multipart.File, *multipart.FileHeader, error) // +------------------------------------------------------------+ // | Custom HTTP Errors | // +------------------------------------------------------------+ // NotFound emits an error 404 to the client, using the specific custom error error handler. // Note that you may need to call ctx.StopExecution() if you don't want the next handlers // to be executed. Next handlers are being executed on iris because you can alt the // error code and change it to a more specific one, i.e // users := app.Party("/users") // users.Done(func(ctx context.Context){ if ctx.StatusCode() == 400 { /* custom error code for /users */ }}) NotFound() // +------------------------------------------------------------+ // | Body Readers | // +------------------------------------------------------------+ // SetMaxRequestBodySize sets a limit to the request body size // should be called before reading the request body from the client. SetMaxRequestBodySize(limitOverBytes int64) // UnmarshalBody reads the request's body and binds it to a value or pointer of any type // Examples of usage: context.ReadJSON, context.ReadXML. UnmarshalBody(v interface{}, unmarshaler Unmarshaler) error // ReadJSON reads JSON from request's body and binds it to a value of any json-valid type. ReadJSON(jsonObject interface{}) error // ReadXML reads XML from request's body and binds it to a value of any xml-valid type. ReadXML(xmlObject interface{}) error // ReadForm binds the formObject with the form data // it supports any kind of struct. ReadForm(formObject interface{}) error // +------------------------------------------------------------+ // | Body (raw) Writers | // +------------------------------------------------------------+ // Write writes the data to the connection as part of an HTTP reply. // // If WriteHeader has not yet been called, Write calls // WriteHeader(http.StatusOK) before writing the data. If the Header // does not contain a Content-Type line, Write adds a Content-Type set // to the result of passing the initial 512 bytes of written data to // DetectContentType. // // Depending on the HTTP protocol version and the client, calling // Write or WriteHeader may prevent future reads on the // Request.Body. For HTTP/1.x requests, handlers should read any // needed request body data before writing the response. Once the // headers have been flushed (due to either an explicit Flusher.Flush // call or writing enough data to trigger a flush), the request body // may be unavailable. For HTTP/2 requests, the Go HTTP server permits // handlers to continue to read the request body while concurrently // writing the response. However, such behavior may not be supported // by all HTTP/2 clients. Handlers should read before writing if // possible to maximize compatibility. Write(body []byte) (int, error) // Writef formats according to a format specifier and writes to the response. // // Returns the number of bytes written and any write error encountered. Writef(format string, args ...interface{}) (int, error) // WriteString writes a simple string to the response. // // Returns the number of bytes written and any write error encountered. WriteString(body string) (int, error) // WriteWithExpiration like Write but it sends with an expiration datetime // which is refreshed every package-level `StaticCacheDuration` field. WriteWithExpiration(body []byte, modtime time.Time) (int, error) // StreamWriter registers the given stream writer for populating // response body. // // Access to context's and/or its' members is forbidden from writer. // // This function may be used in the following cases: // // * if response body is too big (more than iris.LimitRequestBodySize(if setted)). // * if response body is streamed from slow external sources. // * if response body must be streamed to the client in chunks. // (aka `http server push`). // // receives a function which receives the response writer // and returns false when it should stop writing, otherwise true in order to continue StreamWriter(writer func(w io.Writer) bool) // +------------------------------------------------------------+ // | Body Writers with compression | // +------------------------------------------------------------+ // ClientSupportsGzip retruns true if the client supports gzip compression. ClientSupportsGzip() bool // WriteGzip accepts bytes, which are compressed to gzip format and sent to the client. // returns the number of bytes written and an error ( if the client doesn' supports gzip compression) // // This function writes temporary gzip contents, the ResponseWriter is untouched. WriteGzip(b []byte) (int, error) // TryWriteGzip accepts bytes, which are compressed to gzip format and sent to the client. // If client does not supprots gzip then the contents are written as they are, uncompressed. // // This function writes temporary gzip contents, the ResponseWriter is untouched. TryWriteGzip(b []byte) (int, error) // GzipResponseWriter converts the current response writer into a response writer // which when its .Write called it compress the data to gzip and writes them to the client. // // Can be also disabled with its .Disable and .ResetBody to rollback to the usual response writer. GzipResponseWriter() *GzipResponseWriter // Gzip enables or disables (if enabled before) the gzip response writer,if the client // supports gzip compression, so the following response data will // be sent as compressed gzip data to the client. Gzip(enable bool) // +------------------------------------------------------------+ // | Rich Body Content Writers/Renderers | // +------------------------------------------------------------+ // ViewLayout sets the "layout" option if and when .View // is being called afterwards, in the same request. // Useful when need to set or/and change a layout based on the previous handlers in the chain. // // Note that the 'layoutTmplFile' argument can be setted to iris.NoLayout || view.NoLayout // to disable the layout for a specific view render action, // it disables the engine's configuration's layout property. // // Look .ViewData and .View too. // // Example: https://github.com/kataras/iris/tree/master/_examples/view/context-view-data/ ViewLayout(layoutTmplFile string) // ViewData saves one or more key-value pair in order to be passed if and when .View // is being called afterwards, in the same request. // Useful when need to set or/and change template data from previous hanadlers in the chain. // // If .View's "binding" argument is not nil and it's not a type of map // then these data are being ignored, binding has the priority, so the main route's handler can still decide. // If binding is a map or context.Map then these data are being added to the view data // and passed to the template. // // After .View, the data are not destroyed, in order to be re-used if needed (again, in the same request as everything else), // to clear the view data, developers can call: // ctx.Set(ctx.Application().ConfigurationReadOnly().GetViewDataContextKey(), nil) // // If 'key' is empty then the value is added as it's (struct or map) and developer is unable to add other value. // // Look .ViewLayout and .View too. // // Example: https://github.com/kataras/iris/tree/master/_examples/view/context-view-data/ ViewData(key string, value interface{}) // GetViewData returns the values registered by `context#ViewData`. // The return value is `map[string]interface{}`, this means that // if a custom struct registered to ViewData then this function // will try to parse it to map, if failed then the return value is nil // A check for nil is always a good practise if different // kind of values or no data are registered via `ViewData`. // // Similarly to `viewData := ctx.Values().Get("iris.viewData")` or // `viewData := ctx.Values().Get(ctx.Application().ConfigurationReadOnly().GetViewDataContextKey())`. GetViewData() map[string]interface{} // View renders templates based on the adapted view engines. // First argument accepts the filename, relative to the view engine's Directory, // i.e: if directory is "./templates" and want to render the "./templates/users/index.html" // then you pass the "users/index.html" as the filename argument. // // Look: .ViewData and .ViewLayout too. // // Examples: https://github.com/kataras/iris/tree/master/_examples/view/ View(filename string) error // Binary writes out the raw bytes as binary data. Binary(data []byte) (int, error) // Text writes out a string as plain text. Text(text string) (int, error) // HTML writes out a string as text/html. HTML(htmlContents string) (int, error) // JSON marshals the given interface object and writes the JSON response. JSON(v interface{}, options ...JSON) (int, error) // JSONP marshals the given interface object and writes the JSON response. JSONP(v interface{}, options ...JSONP) (int, error) // XML marshals the given interface object and writes the XML response. XML(v interface{}, options ...XML) (int, error) // Markdown parses the markdown to html and renders to client. Markdown(markdownB []byte, options ...Markdown) (int, error) // +------------------------------------------------------------+ // | Serve files | // +------------------------------------------------------------+ // ServeContent serves content, headers are autoset // receives three parameters, it's low-level function, instead you can use .ServeFile(string,bool)/SendFile(string,string) // // You can define your own "Content-Type" header also, after this function call // Doesn't implements resuming (by range), use ctx.SendFile instead ServeContent(content io.ReadSeeker, filename string, modtime time.Time, gzipCompression bool) error // ServeFile serves a view file, to send a file ( zip for example) to the client you should use the SendFile(serverfilename,clientfilename) // receives two parameters // filename/path (string) // gzipCompression (bool) // // You can define your own "Content-Type" header also, after this function call // This function doesn't implement resuming (by range), use ctx.SendFile instead // // Use it when you want to serve css/js/... files to the client, for bigger files and 'force-download' use the SendFile. ServeFile(filename string, gzipCompression bool) error // SendFile sends file for force-download to the client // // Use this instead of ServeFile to 'force-download' bigger files to the client. SendFile(filename string, destinationName string) error // +------------------------------------------------------------+ // | Cookies | // +------------------------------------------------------------+ // SetCookie adds a cookie SetCookie(cookie *http.Cookie) // SetCookieKV adds a cookie, receives just a name(string) and a value(string) // // If you use this method, it expires at 2 hours // use ctx.SetCookie or http.SetCookie if you want to change more fields. SetCookieKV(name, value string) // GetCookie returns cookie's value by it's name // returns empty string if nothing was found. GetCookie(name string) string // RemoveCookie deletes a cookie by it's name. RemoveCookie(name string) // VisitAllCookies takes a visitor which loops // on each (request's) cookies' name and value. VisitAllCookies(visitor func(name string, value string)) // MaxAge returns the "cache-control" request header's value // seconds as int64 // if header not found or parse failed then it returns -1. MaxAge() int64 // +------------------------------------------------------------+ // | Advanced: Response Recorder and Transactions | // +------------------------------------------------------------+ // Record transforms the context's basic and direct responseWriter to a ResponseRecorder // which can be used to reset the body, reset headers, get the body, // get & set the status code at any time and more. Record() // Recorder returns the context's ResponseRecorder // if not recording then it starts recording and returns the new context's ResponseRecorder Recorder() *ResponseRecorder // IsRecording returns the response recorder and a true value // when the response writer is recording the status code, body, headers and so on, // else returns nil and false. IsRecording() (*ResponseRecorder, bool) // BeginTransaction starts a scoped transaction. // // You can search third-party articles or books on how Business Transaction works (it's quite simple, especially here). // // Note that this is unique and new // (=I haver never seen any other examples or code in Golang on this subject, so far, as with the most of iris features...) // it's not covers all paths, // such as databases, this should be managed by the libraries you use to make your database connection, // this transaction scope is only for context's response. // Transactions have their own middleware ecosystem also, look iris.go:UseTransaction. // // See https://github.com/kataras/iris/tree/master/_examples/ for more BeginTransaction(pipe func(t *Transaction)) // SkipTransactions if called then skip the rest of the transactions // or all of them if called before the first transaction SkipTransactions() // TransactionsSkipped returns true if the transactions skipped or canceled at all. TransactionsSkipped() bool // Exec calls the framewrok's ServeCtx // based on this context but with a changed method and path // like it was requested by the user, but it is not. // // Offline means that the route is registered to the iris and have all features that a normal route has // BUT it isn't available by browsing, its handlers executed only when other handler's context call them // it can validate paths, has sessions, path parameters and all. // // You can find the Route by app.GetRoute("theRouteName") // you can set a route name as: myRoute := app.Get("/mypath", handler)("theRouteName") // that will set a name to the route and returns its RouteInfo instance for further usage. // // It doesn't changes the global state, if a route was "offline" it remains offline. // // app.None(...) and app.GetRoutes().Offline(route)/.Online(route, method) // // Example: https://github.com/kataras/iris/tree/master/_examples/routing/route-state // // User can get the response by simple using rec := ctx.Recorder(); rec.Body()/rec.StatusCode()/rec.Header(). // // Context's Values and the Session are kept in order to be able to communicate via the result route. // // It's for extreme use cases, 99% of the times will never be useful for you. Exec(method string, path string) // Application returns the iris app instance which belongs to this context. // Worth to notice that this function returns an interface // of the Application, which contains methods that are safe // to be executed at serve-time. The full app's fields // and methods are not available here for the developer's safety. Application() Application // +--------------------------------------------------------------+ // | https://github.com/golang/net/blob/master/context/context.go | | // +--------------------------------------------------------------+ // Deadline returns the time when work done on behalf of this context // should be canceled. Deadline returns ok==false when no deadline is // set. Successive calls to Deadline return the same results. Deadline() (deadline time.Time, ok bool) // Done returns a channel that's closed when work done on behalf of this // context should be canceled. Done may return nil if this context can // never be canceled. Successive calls to Done return the same value. // // WithCancel arranges for Done to be closed when cancel is called; // WithDeadline arranges for Done to be closed when the deadline // expires; WithTimeout arranges for Done to be closed when the timeout // elapses. // // Done is provided for use in select statements: // // // Stream generates values with DoSomething and sends them to out // // until DoSomething returns an error or ctx.Done is closed. // func Stream(ctx context.Context, out chan<- Value) error { // for { // v, err := DoSomething(ctx) // if err != nil { // return err // } // select { // case <-ctx.Done(): // return ctx.Err() // case out <- v: // } // } // } // // See http://blog.golang.org/pipelines for more examples of how to use // a Done channel for cancelation. Done() <-chan struct{} // Err returns a non-nil error value after Done is closed. Err returns // Canceled if the context was canceled or DeadlineExceeded if the // context's deadline passed. No other values for Err are defined. // After Done is closed, successive calls to Err return the same value. Err() error // Value returns the value associated with this context for key, or nil // if no value is associated with key. Successive calls to Value with // the same key returns the same result. // // Use context values only for request-scoped data that transits // processes and API boundaries, not for passing optional parameters to // functions. // // A key identifies a specific value in a Context. Functions that wish // to store values in Context typically allocate a key in a global // variable then use that key as the argument to context.WithValue and // Context.Value. A key can be any type that supports equality; // packages should define keys as an unexported type to avoid // collisions. // // Packages that define a Context key should provide type-safe accessors // for the values stores using that key: // // // Package user defines a User type that's stored in Contexts. // package user // // import "golang.org/x/net/context" // // // User is the type of value stored in the Contexts. // type User struct {...} // // // key is an unexported type for keys defined in this package. // // This prevents collisions with keys defined in other packages. // type key int // // // userKey is the key for user.User values in Contexts. It is // // unexported; clients use user.NewContext and user.FromContext // // instead of using this key directly. // var userKey key = 0 // // // NewContext returns a new Context that carries value u. // func NewContext(ctx context.Context, u *User) context.Context { // return context.WithValue(ctx, userKey, u) // } // // // FromContext returns the User value stored in ctx, if any. // func FromContext(ctx context.Context) (*User, bool) { // u, ok := ctx.Value(userKey).(*User) // return u, ok // } Value(key interface{}) interface{} } // Next calls all the next handler from the handlers chain, // it should be used inside a middleware. func Next(ctx Context) { if ctx.IsStopped() { return } if n, handlers := ctx.HandlerIndex(-1)+1, ctx.Handlers(); n < len(handlers) { ctx.HandlerIndex(n) handlers[n](ctx) } } // Do calls the SetHandlers(handlers) // and executes the first handler, // handlers should not be empty. // // It's used by the router, developers may use that // to replace and execute handlers immediately. func Do(ctx Context, handlers Handlers) { if len(handlers) > 0 { ctx.SetHandlers(handlers) handlers[0](ctx) } } // LimitRequestBodySize is a middleware which sets a request body size limit // for all next handlers in the chain. var LimitRequestBodySize = func(maxRequestBodySizeBytes int64) Handler { return func(ctx Context) { ctx.SetMaxRequestBodySize(maxRequestBodySizeBytes) ctx.Next() } } // Gzip is a middleware which enables writing // using gzip compression, if client supports. var Gzip = func(ctx Context) { ctx.Gzip(true) ctx.Next() } // Map is just a shortcut of the map[string]interface{}. type Map map[string]interface{} // +------------------------------------------------------------+ // | Context Implementation | // +------------------------------------------------------------+ type context struct { // the http.ResponseWriter wrapped by custom writer writer ResponseWriter // the original http.Request request *http.Request // the current route's name registered to this request path. currentRouteName string // the local key-value storage params RequestParams // url named parameters values memstore.Store // generic storage, middleware communication // the underline application app app Application // the route's handlers handlers Handlers // the current position of the handler's chain currentHandlerIndex int } // NewContext returns the default, internal, context implementation. // You may use this function to embed the default context implementation // to a custom one. // // This context is received by the context pool. func NewContext(app Application) Context { return &context{app: app} } // BeginRequest is executing once for each request // it should prepare the (new or acquired from pool) context's fields for the new request. // // To follow the iris' flow, developer should: // 1. reset handlers to nil // 2. reset store to empty // 3. reset sessions to nil // 4. reset response writer to the http.ResponseWriter // 5. reset request to the *http.Request // and any other optional steps, depends on dev's application type. func (ctx *context) BeginRequest(w http.ResponseWriter, r *http.Request) { ctx.handlers = nil // will be filled by router.Serve/HTTP ctx.values = ctx.values[0:0] // >> >> by context.Values().Set ctx.params.store = ctx.params.store[0:0] ctx.request = r ctx.currentHandlerIndex = 0 ctx.writer = AcquireResponseWriter() ctx.writer.BeginResponse(w) } // EndRequest is executing once after a response to the request was sent and this context is useless or released. // // To follow the iris' flow, developer should: // 1. flush the response writer's result // 2. release the response writer // and any other optional steps, depends on dev's application type. func (ctx *context) EndRequest() { if ctx.GetStatusCode() >= 400 && !ctx.Application().ConfigurationReadOnly().GetDisableAutoFireStatusCode() { // author's note: // if recording, the error handler can handle // the rollback and remove any response written before, // we don't have to do anything here, written is -1 when Recording // because we didn't flush the response yet // if !recording then check if the previous handler didn't send something // to the client if ctx.writer.Written() == -1 { ctx.Application().FireErrorCode(ctx) } } ctx.writer.FlushResponse() ctx.writer.EndResponse() } // ResponseWriter returns an http.ResponseWriter compatible response writer, as expected. func (ctx *context) ResponseWriter() ResponseWriter { return ctx.writer } // ResetResponseWriter should change or upgrade the context's ResponseWriter. func (ctx *context) ResetResponseWriter(newResponseWriter ResponseWriter) { ctx.writer = newResponseWriter } // Request returns the original *http.Request, as expected. func (ctx *context) Request() *http.Request { return ctx.request } // SetCurrentRouteName sets the route's name internally, // in order to be able to find the correct current "read-only" Route when // end-developer calls the `GetCurrentRoute()` function. // It's being initialized by the Router, if you change that name // manually nothing really happens except that you'll get other // route via `GetCurrentRoute()`. // Instead, to execute a different path // from this context you should use the `Exec` function // or change the handlers via `SetHandlers/AddHandler` functions. func (ctx *context) SetCurrentRouteName(currentRouteName string) { ctx.currentRouteName = currentRouteName } // GetCurrentRoute returns the current registered "read-only" route that // was being registered to this request's path. func (ctx *context) GetCurrentRoute() RouteReadOnly { return ctx.app.GetRouteReadOnly(ctx.currentRouteName) } // Do calls the SetHandlers(handlers) // and executes the first handler, // handlers should not be empty. // // It's used by the router, developers may use that // to replace and execute handlers immediately. func (ctx *context) Do(handlers Handlers) { Do(ctx, handlers) } // AddHandler can add handler(s) // to the current request in serve-time, // these handlers are not persistenced to the router. // // Router is calling this function to add the route's handler. // If AddHandler called then the handlers will be inserted // to the end of the already-defined route's handler. // func (ctx *context) AddHandler(handlers ...Handler) { ctx.handlers = append(ctx.handlers, handlers...) } // SetHandlers replaces all handlers with the new. func (ctx *context) SetHandlers(handlers Handlers) { ctx.handlers = handlers } // Handlers keeps tracking of the current handlers. func (ctx *context) Handlers() Handlers { return ctx.handlers } // HandlerIndex sets the current index of the // current context's handlers chain. // If -1 passed then it just returns the // current handler index without change the current index.rns that index, useless return value. // // Look Handlers(), Next() and StopExecution() too. func (ctx *context) HandlerIndex(n int) (currentIndex int) { if n < 0 || n > len(ctx.handlers)-1 { return ctx.currentHandlerIndex } ctx.currentHandlerIndex = n return n } // HandlerName returns the current handler's name, helpful for debugging. func (ctx *context) HandlerName() string { return runtime.FuncForPC(reflect.ValueOf(ctx.handlers[ctx.currentHandlerIndex]).Pointer()).Name() } // Do sets the handler index to zero, executes the first handler // and the rest of the Handlers if ctx.Next() was called. // func (ctx *context) Do() { // ctx.currentHandlerIndex = 0 // ctx.handlers[0](ctx) // it calls this *context // } // -> replaced with inline on router.go // Next calls all the next handler from the handlers chain, // it should be used inside a middleware. // // Note: Custom context should override this method in order to be able to pass its own context.context implementation. func (ctx *context) Next() { // or context.Next(ctx) Next(ctx) } // NextHandler returns, but it doesn't executes, the next handler from the handlers chain. // // Use .Skip() to skip this handler if needed to execute the next of this returning handler. func (ctx *context) NextHandler() Handler { if ctx.IsStopped() { return nil } nextIndex := ctx.currentHandlerIndex + 1 // check if it has a next middleware if nextIndex < len(ctx.handlers) { return ctx.handlers[nextIndex] } return nil } // Skip skips/ignores the next handler from the handlers chain, // it should be used inside a middleware. func (ctx *context) Skip() { ctx.HandlerIndex(ctx.currentHandlerIndex + 1) } const stopExecutionIndex = -1 // I don't set to a max value because we want to be able to reuse the handlers even if stopped with .Skip // StopExecution if called then the following .Next calls are ignored. func (ctx *context) StopExecution() { ctx.currentHandlerIndex = stopExecutionIndex } // IsStopped checks and returns true if the current position of the context is -1, // means that the StopExecution() was called. func (ctx *context) IsStopped() bool { return ctx.currentHandlerIndex == stopExecutionIndex } // +------------------------------------------------------------+ // | Current "user/request" storage | // | and share information between the handlers - Values(). | // | Save and get named path parameters - Params() | // +------------------------------------------------------------+ // Params returns the current url's named parameters key-value storage. // Named path parameters are being saved here. // This storage, as the whole context, is per-request lifetime. func (ctx *context) Params() *RequestParams { return &ctx.params } // Values returns the current "user" storage. // Named path parameters and any optional data can be saved here. // This storage, as the whole context, is per-request lifetime. // // You can use this function to Set and Get local values // that can be used to share information between handlers and middleware. func (ctx *context) Values() *memstore.Store { return &ctx.values } // Translate is the i18n (localization) middleware's function, // it calls the Get("translate") to return the translated value. // // Example: https://github.com/kataras/iris/tree/master/_examples/miscellaneous/i18n func (ctx *context) Translate(format string, args ...interface{}) string { if cb, ok := ctx.values.Get(ctx.Application().ConfigurationReadOnly().GetTranslateFunctionContextKey()).(func(format string, args ...interface{}) string); ok { return cb(format, args...) } return "" } // +------------------------------------------------------------+ // | Path, Host, Subdomain, IP, Headers etc... | // +------------------------------------------------------------+ // Method returns the request.Method, the client's http method to the server. func (ctx *context) Method() string { return ctx.request.Method } // Path returns the full request path, // escaped if EnablePathEscape config field is true. func (ctx *context) Path() string { return ctx.RequestPath(ctx.Application().ConfigurationReadOnly().GetEnablePathEscape()) } // DecodeQuery returns the uri parameter as url (string) // useful when you want to pass something to a database and be valid to retrieve it via context.Param // use it only for special cases, when the default behavior doesn't suits you. // // http://www.blooberry.com/indexdot/html/topics/urlencoding.htm // it uses just the url.QueryUnescape func DecodeQuery(path string) string { if path == "" { return "" } encodedPath, err := url.QueryUnescape(path) if err != nil { return path } return encodedPath } // DecodeURL returns the decoded uri // useful when you want to pass something to a database and be valid to retrieve it via context.Param // use it only for special cases, when the default behavior doesn't suits you. // // http://www.blooberry.com/indexdot/html/topics/urlencoding.htm // it uses just the url.Parse func DecodeURL(uri string) string { u, err := url.Parse(uri) if err != nil { return uri } return u.String() } // RequestPath returns the full request path, // based on the 'escape'. func (ctx *context) RequestPath(escape bool) string { if escape { return DecodeQuery(ctx.request.URL.EscapedPath()) } return ctx.request.URL.Path // RawPath returns empty, requesturi can be used instead also. } // PathPrefixMap accepts a map of string and a handler. // The key of "m" is the key, which is the prefix, regular expressions are not valid. // The value of "m" is the handler that will be executed if HasPrefix(context.Path). // func (ctx *context) PathPrefixMap(m map[string]context.Handler) bool { // path := ctx.Path() // for k, v := range m { // if strings.HasPrefix(path, k) { // v(ctx) // return true // } // } // return false // } no, it will not work because map is a random peek data structure. // Host returns the host part of the current url. func (ctx *context) Host() string { h := ctx.request.URL.Host if h == "" { h = ctx.request.Host } return h } // Subdomain returns the subdomain of this request, if any. // Note that this is a fast method which does not cover all cases. func (ctx *context) Subdomain() (subdomain string) { host := ctx.Host() if index := strings.IndexByte(host, '.'); index > 0 { subdomain = host[0:index] } // listening on mydomain.com:80 // subdomain = mydomain, but it's wrong, it should return "" vhost := ctx.Application().ConfigurationReadOnly().GetVHost() if strings.Contains(vhost, subdomain) { // then it's not subdomain return "" } return } // RemoteAddr tries to parse and return the real client's request IP. // // Based on allowed headers names that can be modified from Configuration.RemoteAddrHeaders. // // If parse based on these headers fail then it will return the Request's `RemoteAddr` field // which is filled by the server before the HTTP handler. // // Look `Configuration.RemoteAddrHeaders`, // `Configuration.WithRemoteAddrHeader(...)`, // `Configuration.WithoutRemoteAddrHeader(...)` for more. func (ctx *context) RemoteAddr() string { remoteHeaders := ctx.Application().ConfigurationReadOnly().GetRemoteAddrHeaders() for headerName, enabled := range remoteHeaders { if enabled { headerValue := ctx.GetHeader(headerName) // exception needed for 'X-Forwarded-For' only , if enabled. if headerName == "X-Forwarded-For" { idx := strings.IndexByte(headerValue, ',') if idx >= 0 { headerValue = headerValue[0:idx] } } realIP := strings.TrimSpace(headerValue) if realIP != "" { return realIP } } } addr := strings.TrimSpace(ctx.request.RemoteAddr) if addr != "" { // if addr has port use the net.SplitHostPort otherwise(error occurs) take as it is if ip, _, err := net.SplitHostPort(addr); err == nil { return ip } } return addr } // GetHeader returns the request header's value based on its name. func (ctx *context) GetHeader(name string) string { return ctx.request.Header.Get(name) } // IsAjax returns true if this request is an 'ajax request'( XMLHttpRequest) // // There is no a 100% way of knowing that a request was made via Ajax. // You should never trust data coming from the client, they can be easily overcome by spoofing. // // Note that "X-Requested-With" Header can be modified by any client(because of "X-"), // so don't rely on IsAjax for really serious stuff, // try to find another way of detecting the type(i.e, content type), // there are many blogs that describe these problems and provide different kind of solutions, // it's always depending on the application you're building, // this is the reason why this `IsAjax`` is simple enough for general purpose use. // // Read more at: https://developer.mozilla.org/en-US/docs/AJAX // and https://xhr.spec.whatwg.org/ func (ctx *context) IsAjax() bool { return ctx.GetHeader("X-Requested-With") == "XMLHttpRequest" } // +------------------------------------------------------------+ // | Response Headers helpers | // +------------------------------------------------------------+ // Header adds a header to the response, if value is empty // it removes the header by its name. func (ctx *context) Header(name string, value string) { if value == "" { ctx.writer.Header().Del(name) return } ctx.writer.Header().Add(name, value) } const contentTypeHeaderKey = "Content-Type" // ContentType sets the response writer's header key "Content-Type" to the 'cType'. func (ctx *context) ContentType(cType string) { if cType == "" { return } // 1. if it's path or a filename or an extension, // then take the content type from that if strings.Contains(cType, ".") { ext := filepath.Ext(cType) cType = mime.TypeByExtension(ext) } // if doesn't contain a charset already then append it if !strings.Contains(cType, "charset") { if cType != contentBinaryHeaderValue { charset := ctx.Application().ConfigurationReadOnly().GetCharset() cType += "; charset=" + charset } } ctx.writer.Header().Set(contentTypeHeaderKey, cType) } // GetContentType returns the response writer's header value of "Content-Type" // which may, setted before with the 'ContentType'. func (ctx *context) GetContentType() string { return ctx.writer.Header().Get(contentTypeHeaderKey) } // StatusCode sets the status code header to the response. // Look .GetStatusCode & .FireStatusCode too. // // Remember, the last one before .Write matters except recorder and transactions. func (ctx *context) StatusCode(statusCode int) { ctx.writer.WriteHeader(statusCode) } // NotFound emits an error 404 to the client, using the specific custom error error handler. // Note that you may need to call ctx.StopExecution() if you don't want the next handlers // to be executed. Next handlers are being executed on iris because you can alt the // error code and change it to a more specific one, i.e // users := app.Party("/users") // users.Done(func(ctx context.Context){ if ctx.StatusCode() == 400 { /* custom error code for /users */ }}) func (ctx *context) NotFound() { ctx.StatusCode(http.StatusNotFound) } // GetStatusCode returns the current status code of the response. // Look StatusCode too. func (ctx *context) GetStatusCode() int { return ctx.writer.StatusCode() } // +------------------------------------------------------------+ // | Various Request and Post Data | // +------------------------------------------------------------+ // URLParam returns the get parameter from a request , if any. func (ctx *context) URLParam(name string) string { return ctx.request.URL.Query().Get(name) } // URLParamInt returns the url query parameter as int value from a request, // returns an error if parse failed. func (ctx *context) URLParamInt(name string) (int, error) { return strconv.Atoi(ctx.URLParam(name)) } // URLParamInt64 returns the url query parameter as int64 value from a request, // returns an error if parse failed. func (ctx *context) URLParamInt64(name string) (int64, error) { return strconv.ParseInt(ctx.URLParam(name), 10, 64) } // URLParams returns a map of GET query parameters separated by comma if more than one // it returns an empty map if nothing found. func (ctx *context) URLParams() map[string]string { values := map[string]string{} q := ctx.request.URL.Query() if q != nil { for k, v := range q { values[k] = strings.Join(v, ",") } } return values } func (ctx *context) askParseForm() error { if ctx.request.Form == nil { if err := ctx.request.ParseForm(); err != nil { return err } } return nil } // FormValue returns a single form value by its name/key func (ctx *context) FormValue(name string) string { return ctx.request.FormValue(name) } // FormValues returns all post data values with their keys // form data, get, post & put query arguments // // NOTE: A check for nil is necessary. func (ctx *context) FormValues() map[string][]string { // we skip the check of multipart form, takes too much memory, if user wants it can do manually now. if err := ctx.askParseForm(); err != nil { return nil } return ctx.request.Form // nothing more to do, it's already contains both query and post & put args. } // PostValue returns a form's only-post value by its name, // same as Request.PostFormValue. func (ctx *context) PostValue(name string) string { return ctx.request.PostFormValue(name) } // FormFile returns the first file for the provided form key. // FormFile calls ctx.request.ParseMultipartForm and ParseForm if necessary. // // same as Request.FormFile. func (ctx *context) FormFile(key string) (multipart.File, *multipart.FileHeader, error) { return ctx.request.FormFile(key) } // Redirect redirect sends a redirect response the client // accepts 2 parameters string and an optional int // first parameter is the url to redirect // second parameter is the http status should send, default is 302 (StatusFound), // you can set it to 301 (Permant redirect), if that's nessecery func (ctx *context) Redirect(urlToRedirect string, statusHeader ...int) { ctx.StopExecution() httpStatus := http.StatusFound // a 'temporary-redirect-like' which works better than for our purpose if len(statusHeader) > 0 && statusHeader[0] > 0 { httpStatus = statusHeader[0] } http.Redirect(ctx.writer, ctx.request, urlToRedirect, httpStatus) } // +------------------------------------------------------------+ // | Body Readers | // +------------------------------------------------------------+ // SetMaxRequestBodySize sets a limit to the request body size // should be called before reading the request body from the client. func (ctx *context) SetMaxRequestBodySize(limitOverBytes int64) { ctx.request.Body = http.MaxBytesReader(ctx.writer, ctx.request.Body, limitOverBytes) } // UnmarshalBody reads the request's body and binds it to a value or pointer of any type // Examples of usage: context.ReadJSON, context.ReadXML. func (ctx *context) UnmarshalBody(v interface{}, unmarshaler Unmarshaler) error { if ctx.request.Body == nil { return errors.New("unmarshal: empty body") } rawData, err := ioutil.ReadAll(ctx.request.Body) if err != nil { return err } if ctx.Application().ConfigurationReadOnly().GetDisableBodyConsumptionOnUnmarshal() { // * remember, Request.Body has no Bytes(), we have to consume them first // and after re-set them to the body, this is the only solution. ctx.request.Body = ioutil.NopCloser(bytes.NewBuffer(rawData)) } // check if the v contains its own decode // in this case the v should be a pointer also, // but this is up to the user's custom Decode implementation* // // See 'BodyDecoder' for more if decoder, isDecoder := v.(BodyDecoder); isDecoder { return decoder.Decode(rawData) } // check if v is already a pointer, if yes then pass as it's if reflect.TypeOf(v).Kind() == reflect.Ptr { return unmarshaler.Unmarshal(rawData, v) } // finally, if the v doesn't contains a self-body decoder and it's not a pointer // use the custom unmarshaler to bind the body return unmarshaler.Unmarshal(rawData, &v) } func (ctx *context) shouldOptimize() bool { return ctx.Application().ConfigurationReadOnly().GetEnableOptimizations() } // ReadJSON reads JSON from request's body and binds it to a value of any json-valid type. func (ctx *context) ReadJSON(jsonObject interface{}) error { var unmarshaler = json.Unmarshal if ctx.shouldOptimize() { unmarshaler = jsoniter.Unmarshal } return ctx.UnmarshalBody(jsonObject, UnmarshalerFunc(unmarshaler)) } // ReadXML reads XML from request's body and binds it to a value of any xml-valid type. func (ctx *context) ReadXML(xmlObject interface{}) error { return ctx.UnmarshalBody(xmlObject, UnmarshalerFunc(xml.Unmarshal)) } var ( errReadBody = errors.New("while trying to read %s from the request body. Trace %s") ) // ReadForm binds the formObject with the form data // it supports any kind of struct. func (ctx *context) ReadForm(formObject interface{}) error { values := ctx.FormValues() if values == nil { return errors.New("An empty form passed on ReadForm") } // or dec := formbinder.NewDecoder(&formbinder.DecoderOptions{TagName: "form"}) // somewhere at the app level. I did change the tagName to "form" // inside its source code, so it's not needed for now. return errReadBody.With(formbinder.Decode(values, formObject)) } // +------------------------------------------------------------+ // | Body (raw) Writers | // +------------------------------------------------------------+ // Write writes the data to the connection as part of an HTTP reply. // // If WriteHeader has not yet been called, Write calls // WriteHeader(http.StatusOK) before writing the data. If the Header // does not contain a Content-Type line, Write adds a Content-Type set // to the result of passing the initial 512 bytes of written data to // DetectContentType. // // Depending on the HTTP protocol version and the client, calling // Write or WriteHeader may prevent future reads on the // Request.Body. For HTTP/1.x requests, handlers should read any // needed request body data before writing the response. Once the // headers have been flushed (due to either an explicit Flusher.Flush // call or writing enough data to trigger a flush), the request body // may be unavailable. For HTTP/2 requests, the Go HTTP server permits // handlers to continue to read the request body while concurrently // writing the response. However, such behavior may not be supported // by all HTTP/2 clients. Handlers should read before writing if // possible to maximize compatibility. func (ctx *context) Write(rawBody []byte) (int, error) { return ctx.writer.Write(rawBody) } // Writef formats according to a format specifier and writes to the response. // // Returns the number of bytes written and any write error encountered. func (ctx *context) Writef(format string, a ...interface{}) (n int, err error) { return ctx.writer.Writef(format, a...) } // WriteString writes a simple string to the response. // // Returns the number of bytes written and any write error encountered. func (ctx *context) WriteString(body string) (n int, err error) { return ctx.writer.WriteString(body) } var ( // StaticCacheDuration expiration duration for INACTIVE file handlers, it's the only one global configuration // which can be changed. StaticCacheDuration = 20 * time.Second lastModifiedHeaderKey = "Last-Modified" ifModifiedSinceHeaderKey = "If-Modified-Since" contentDispositionHeaderKey = "Content-Disposition" cacheControlHeaderKey = "Cache-Control" contentEncodingHeaderKey = "Content-Encoding" acceptEncodingHeaderKey = "Accept-Encoding" varyHeaderKey = "Vary" ) // staticCachePassed checks the IfModifiedSince header and // returns true if (client-side) duration has expired func (ctx *context) staticCachePassed(modtime time.Time) bool { if t, err := time.Parse(ctx.Application().ConfigurationReadOnly().GetTimeFormat(), ctx.GetHeader(ifModifiedSinceHeaderKey)); err == nil && modtime.Before(t.Add(StaticCacheDuration)) { ctx.writer.Header().Del(contentTypeHeaderKey) ctx.writer.Header().Del(contentLengthHeaderKey) ctx.StatusCode(http.StatusNotModified) return true } return false } // WriteWithExpiration like Write but it sends with an expiration datetime // which is refreshed every package-level `StaticCacheDuration` field. func (ctx *context) WriteWithExpiration(body []byte, modtime time.Time) (int, error) { if ctx.staticCachePassed(modtime) { return 0, nil } modtimeFormatted := modtime.UTC().Format(ctx.Application().ConfigurationReadOnly().GetTimeFormat()) ctx.Header(lastModifiedHeaderKey, modtimeFormatted) return ctx.writer.Write(body) } // StreamWriter registers the given stream writer for populating // response body. // // Access to context's and/or its' members is forbidden from writer. // // This function may be used in the following cases: // // * if response body is too big (more than iris.LimitRequestBodySize(if setted)). // * if response body is streamed from slow external sources. // * if response body must be streamed to the client in chunks. // (aka `http server push`). // // receives a function which receives the response writer // and returns false when it should stop writing, otherwise true in order to continue func (ctx *context) StreamWriter(writer func(w io.Writer) bool) { w := ctx.writer notifyClosed := w.CloseNotify() for { select { // response writer forced to close, exit. case <-notifyClosed: return default: shouldContinue := writer(w) w.Flush() if !shouldContinue { return } } } } // +------------------------------------------------------------+ // | Body Writers with compression | // +------------------------------------------------------------+ // ClientSupportsGzip retruns true if the client supports gzip compression. func (ctx *context) ClientSupportsGzip() bool { if h := ctx.GetHeader(acceptEncodingHeaderKey); h != "" { for _, v := range strings.Split(h, ";") { if strings.Contains(v, "gzip") { // we do Contains because sometimes browsers has the q=, we don't use it atm. || strings.Contains(v,"deflate"){ return true } } } return false } var ( errClientDoesNotSupportGzip = errors.New("client doesn't supports gzip compression") ) // WriteGzip accepts bytes, which are compressed to gzip format and sent to the client. // returns the number of bytes written and an error ( if the client doesn' supports gzip compression) // // This function writes temporary gzip contents, the ResponseWriter is untouched. func (ctx *context) WriteGzip(b []byte) (int, error) { if ctx.ClientSupportsGzip() { ctx.writer.Header().Add(varyHeaderKey, acceptEncodingHeaderKey) gzipWriter := acquireGzipWriter(ctx.writer) defer releaseGzipWriter(gzipWriter) n, err := gzipWriter.Write(b) if err == nil { ctx.Header(contentEncodingHeaderKey, "gzip") } // else write the contents as it is? no let's create a new func for this return n, err } return 0, errClientDoesNotSupportGzip } // TryWriteGzip accepts bytes, which are compressed to gzip format and sent to the client. // If client does not supprots gzip then the contents are written as they are, uncompressed. // // This function writes temporary gzip contents, the ResponseWriter is untouched. func (ctx *context) TryWriteGzip(b []byte) (int, error) { n, err := ctx.WriteGzip(b) if err != nil { // check if the error came from gzip not allowed and not the writer itself if _, ok := err.(*errors.Error); ok { // client didn't supported gzip, write them uncompressed: return ctx.writer.Write(b) } } return n, err } // GzipResponseWriter converts the current response writer into a response writer // which when its .Write called it compress the data to gzip and writes them to the client. // // Can be also disabled with its .Disable and .ResetBody to rollback to the usual response writer. func (ctx *context) GzipResponseWriter() *GzipResponseWriter { // if it's already a gzip response writer then just return it if gzipResWriter, ok := ctx.writer.(*GzipResponseWriter); ok { return gzipResWriter } // if it's not acquire a new from a pool // and register that as the ctx.ResponseWriter. gzipResWriter := AcquireGzipResponseWriter() gzipResWriter.BeginGzipResponse(ctx.writer) ctx.ResetResponseWriter(gzipResWriter) return gzipResWriter } // Gzip enables or disables (if enabled before) the gzip response writer,if the client // supports gzip compression, so the following response data will // be sent as compressed gzip data to the client. func (ctx *context) Gzip(enable bool) { if enable { if ctx.ClientSupportsGzip() { _ = ctx.GzipResponseWriter() } } else { if gzipResWriter, ok := ctx.writer.(*GzipResponseWriter); ok { gzipResWriter.Disable() } } } // +------------------------------------------------------------+ // | Rich Body Content Writers/Renderers | // +------------------------------------------------------------+ const ( // NoLayout to disable layout for a particular template file NoLayout = "iris.nolayout" ) // ViewLayout sets the "layout" option if and when .View // is being called afterwards, in the same request. // Useful when need to set or/and change a layout based on the previous handlers in the chain. // // Note that the 'layoutTmplFile' argument can be setted to iris.NoLayout || view.NoLayout || context.NoLayout // to disable the layout for a specific view render action, // it disables the engine's configuration's layout property. // // Look .ViewData and .View too. // // Example: https://github.com/kataras/iris/tree/master/_examples/view/context-view-data/ func (ctx *context) ViewLayout(layoutTmplFile string) { ctx.values.Set(ctx.Application().ConfigurationReadOnly().GetViewLayoutContextKey(), layoutTmplFile) } // ViewData saves one or more key-value pair in order to be passed if and when .View // is being called afterwards, in the same request. // Useful when need to set or/and change template data from previous hanadlers in the chain. // // If .View's "binding" argument is not nil and it's not a type of map // then these data are being ignored, binding has the priority, so the main route's handler can still decide. // If binding is a map or context.Map then these data are being added to the view data // and passed to the template. // // After .View, the data are not destroyed, in order to be re-used if needed (again, in the same request as everything else), // to clear the view data, developers can call: // ctx.Set(ctx.Application().ConfigurationReadOnly().GetViewDataContextKey(), nil) // // If 'key' is empty then the value is added as it's (struct or map) and developer is unable to add other value. // // Look .ViewLayout and .View too. // // Example: https://github.com/kataras/iris/tree/master/_examples/view/context-view-data/ func (ctx *context) ViewData(key string, value interface{}) { viewDataContextKey := ctx.Application().ConfigurationReadOnly().GetViewDataContextKey() if key == "" { ctx.values.Set(viewDataContextKey, value) return } v := ctx.values.Get(viewDataContextKey) if v == nil { ctx.values.Set(viewDataContextKey, Map{key: value}) return } if data, ok := v.(map[string]interface{}); ok { data[key] = value } else if data, ok := v.(Map); ok { data[key] = value } } // GetViewData returns the values registered by `context#ViewData`. // The return value is `map[string]interface{}`, this means that // if a custom struct registered to ViewData then this function // will try to parse it to map, if failed then the return value is nil // A check for nil is always a good practise if different // kind of values or no data are registered via `ViewData`. // // Similarly to `viewData := ctx.Values().Get("iris.viewData")` or // `viewData := ctx.Values().Get(ctx.Application().ConfigurationReadOnly().GetViewDataContextKey())`. func (ctx *context) GetViewData() map[string]interface{} { viewDataContextKey := ctx.Application().ConfigurationReadOnly().GetViewDataContextKey() v := ctx.Values().Get(viewDataContextKey) // if no values found, then return nil if v == nil { return nil } // if struct, convert it to map[string]interface{} if structs.IsStruct(v) { return structs.Map(v) } // if pure map[string]interface{} if viewData, ok := v.(map[string]interface{}); ok { return viewData } // if context#Map if viewData, ok := v.(Map); ok { return viewData } // if failure, then return nil return nil } // View renders templates based on the adapted view engines. // First argument accepts the filename, relative to the view engine's Directory, // i.e: if directory is "./templates" and want to render the "./templates/users/index.html" // then you pass the "users/index.html" as the filename argument. // // Look: .ViewData and .ViewLayout too. // // Examples: https://github.com/kataras/iris/tree/master/_examples/view/ func (ctx *context) View(filename string) error { ctx.ContentType(contentHTMLHeaderValue) cfg := ctx.Application().ConfigurationReadOnly() layout := ctx.values.GetString(cfg.GetViewLayoutContextKey()) bindingData := ctx.values.Get(cfg.GetViewDataContextKey()) err := ctx.Application().View(ctx.writer, filename, layout, bindingData) if err != nil { ctx.StatusCode(http.StatusInternalServerError) ctx.StopExecution() } return err } const ( // contentBinaryHeaderValue header value for binary data. contentBinaryHeaderValue = "application/octet-stream" // contentHTMLHeaderValue is the string of text/html response header's content type value. contentHTMLHeaderValue = "text/html" // ContentJSON header value for JSON data. contentJSONHeaderValue = "application/json" // ContentJSONP header value for JSONP & Javascript data. contentJavascriptHeaderValue = "application/javascript" // contentTextHeaderValue header value for Text data. contentTextHeaderValue = "text/plain" // contentXMLHeaderValue header value for XML data. contentXMLHeaderValue = "text/xml" // contentMarkdownHeaderValue custom key/content type, the real is the text/html. contentMarkdownHeaderValue = "text/markdown" ) // Binary writes out the raw bytes as binary data. func (ctx *context) Binary(data []byte) (int, error) { ctx.ContentType(contentBinaryHeaderValue) return ctx.Write(data) } // Text writes out a string as plain text. func (ctx *context) Text(text string) (int, error) { ctx.ContentType(contentTextHeaderValue) return ctx.writer.WriteString(text) } // HTML writes out a string as text/html. func (ctx *context) HTML(htmlContents string) (int, error) { ctx.ContentType(contentHTMLHeaderValue) return ctx.writer.WriteString(htmlContents) } // JSON contains the options for the JSON (Context's) Renderer. type JSON struct { // http-specific StreamingJSON bool // content-specific UnescapeHTML bool Indent string Prefix string } // JSONP contains the options for the JSONP (Context's) Renderer. type JSONP struct { // content-specific Indent string Callback string } // XML contains the options for the XML (Context's) Renderer. type XML struct { // content-specific Indent string Prefix string } // Markdown contains the options for the Markdown (Context's) Renderer. type Markdown struct { // content-specific Sanitize bool } var ( newLineB = []byte("\n") // the html codes for unescaping ltHex = []byte("\\u003c") lt = []byte("<") gtHex = []byte("\\u003e") gt = []byte(">") andHex = []byte("\\u0026") and = []byte("&") ) // WriteJSON marshals the given interface object and writes the JSON response to the 'writer'. // Ignores StatusCode, Gzip, StreamingJSON options. func WriteJSON(writer io.Writer, v interface{}, options JSON, enableOptimization ...bool) (int, error) { var ( result []byte err error optimize = len(enableOptimization) > 0 && enableOptimization[0] ) if indent := options.Indent; indent != "" { marshalIndent := json.MarshalIndent if optimize { marshalIndent = jsoniter.ConfigCompatibleWithStandardLibrary.MarshalIndent } result, err = marshalIndent(v, "", indent) result = append(result, newLineB...) } else { marshal := json.Marshal if optimize { marshal = jsoniter.ConfigCompatibleWithStandardLibrary.Marshal } result, err = marshal(v) } if err != nil { return 0, err } if options.UnescapeHTML { result = bytes.Replace(result, ltHex, lt, -1) result = bytes.Replace(result, gtHex, gt, -1) result = bytes.Replace(result, andHex, and, -1) } if prefix := options.Prefix; prefix != "" { result = append([]byte(prefix), result...) } return writer.Write(result) } var defaultJSONOptions = JSON{} // JSON marshals the given interface object and writes the JSON response to the client. func (ctx *context) JSON(v interface{}, opts ...JSON) (n int, err error) { options := defaultJSONOptions if len(opts) > 0 { options = opts[0] } optimize := ctx.shouldOptimize() ctx.ContentType(contentJSONHeaderValue) if options.StreamingJSON { if optimize { var jsoniterConfig = jsoniter.Config{ EscapeHTML: !options.UnescapeHTML, IndentionStep: 4, }.Froze() enc := jsoniterConfig.NewEncoder(ctx.writer) err = enc.Encode(v) } else { enc := json.NewEncoder(ctx.writer) enc.SetEscapeHTML(!options.UnescapeHTML) enc.SetIndent(options.Prefix, options.Indent) err = enc.Encode(v) } if err != nil { ctx.StatusCode(http.StatusInternalServerError) // it handles the fallback to normal mode here which also removes the gzip headers. return 0, err } return ctx.writer.Written(), err } n, err = WriteJSON(ctx.writer, v, options, optimize) if err != nil { ctx.StatusCode(http.StatusInternalServerError) return 0, err } return n, err } var ( finishCallbackB = []byte(");") ) // WriteJSONP marshals the given interface object and writes the JSON response to the writer. func WriteJSONP(writer io.Writer, v interface{}, options JSONP, enableOptimization ...bool) (int, error) { if callback := options.Callback; callback != "" { writer.Write([]byte(callback + "(")) defer writer.Write(finishCallbackB) } optimize := len(enableOptimization) > 0 && enableOptimization[0] if indent := options.Indent; indent != "" { marshalIndent := json.MarshalIndent if optimize { marshalIndent = jsoniter.ConfigCompatibleWithStandardLibrary.MarshalIndent } result, err := marshalIndent(v, "", indent) if err != nil { return 0, err } result = append(result, newLineB...) return writer.Write(result) } marshal := json.Marshal if optimize { marshal = jsoniter.ConfigCompatibleWithStandardLibrary.Marshal } result, err := marshal(v) if err != nil { return 0, err } return writer.Write(result) } var defaultJSONPOptions = JSONP{} // JSONP marshals the given interface object and writes the JSON response to the client. func (ctx *context) JSONP(v interface{}, opts ...JSONP) (int, error) { options := defaultJSONPOptions if len(opts) > 0 { options = opts[0] } ctx.ContentType(contentJavascriptHeaderValue) n, err := WriteJSONP(ctx.writer, v, options, ctx.shouldOptimize()) if err != nil { ctx.StatusCode(http.StatusInternalServerError) return 0, err } return n, err } // WriteXML marshals the given interface object and writes the XML response to the writer. func WriteXML(writer io.Writer, v interface{}, options XML) (int, error) { if prefix := options.Prefix; prefix != "" { writer.Write([]byte(prefix)) } if indent := options.Indent; indent != "" { result, err := xml.MarshalIndent(v, "", indent) if err != nil { return 0, err } result = append(result, newLineB...) return writer.Write(result) } result, err := xml.Marshal(v) if err != nil { return 0, err } return writer.Write(result) } var defaultXMLOptions = XML{} // XML marshals the given interface object and writes the XML response to the client. func (ctx *context) XML(v interface{}, opts ...XML) (int, error) { options := defaultXMLOptions if len(opts) > 0 { options = opts[0] } ctx.ContentType(contentXMLHeaderValue) n, err := WriteXML(ctx.writer, v, options) if err != nil { ctx.StatusCode(http.StatusInternalServerError) return 0, err } return n, err } // WriteMarkdown parses the markdown to html and renders these contents to the writer. func WriteMarkdown(writer io.Writer, markdownB []byte, options Markdown) (int, error) { buf := blackfriday.Run(markdownB) if options.Sanitize { buf = bluemonday.UGCPolicy().SanitizeBytes(buf) } return writer.Write(buf) } var defaultMarkdownOptions = Markdown{} // Markdown parses the markdown to html and renders to the client. func (ctx *context) Markdown(markdownB []byte, opts ...Markdown) (int, error) { options := defaultMarkdownOptions if len(opts) > 0 { options = opts[0] } ctx.ContentType(contentHTMLHeaderValue) n, err := WriteMarkdown(ctx.writer, markdownB, options) if err != nil { ctx.StatusCode(http.StatusInternalServerError) return 0, err } return n, err } // +------------------------------------------------------------+ // | Serve files | // +------------------------------------------------------------+ var ( errServeContent = errors.New("while trying to serve content to the client. Trace %s") ) const ( // contentLengthHeaderKey represents the header["Content-Length"] contentLengthHeaderKey = "Content-Length" ) // ServeContent serves content, headers are autoset // receives three parameters, it's low-level function, instead you can use .ServeFile(string,bool)/SendFile(string,string) // // You can define your own "Content-Type" header also, after this function call // Doesn't implements resuming (by range), use ctx.SendFile instead func (ctx *context) ServeContent(content io.ReadSeeker, filename string, modtime time.Time, gzipCompression bool) error { if t, err := time.Parse(ctx.Application().ConfigurationReadOnly().GetTimeFormat(), ctx.GetHeader(ifModifiedSinceHeaderKey)); err == nil && modtime.Before(t.Add(1*time.Second)) { ctx.writer.Header().Del(contentTypeHeaderKey) ctx.writer.Header().Del(contentLengthHeaderKey) ctx.StatusCode(http.StatusNotModified) return nil } ctx.ContentType(filename) ctx.writer.Header().Set(lastModifiedHeaderKey, modtime.UTC().Format(ctx.Application().ConfigurationReadOnly().GetTimeFormat())) ctx.StatusCode(http.StatusOK) var out io.Writer if gzipCompression && ctx.ClientSupportsGzip() { ctx.writer.Header().Add(varyHeaderKey, acceptEncodingHeaderKey) ctx.Header(contentEncodingHeaderKey, "gzip") gzipWriter := acquireGzipWriter(ctx.writer) defer releaseGzipWriter(gzipWriter) out = gzipWriter } else { out = ctx.writer } _, err := io.Copy(out, content) return errServeContent.With(err) } // ServeFile serves a view file, to send a file ( zip for example) to the client you should use the SendFile(serverfilename,clientfilename) // receives two parameters // filename/path (string) // gzipCompression (bool) // // You can define your own "Content-Type" header also, after this function call // This function doesn't implement resuming (by range), use ctx.SendFile instead // // Use it when you want to serve css/js/... files to the client, for bigger files and 'force-download' use the SendFile. func (ctx *context) ServeFile(filename string, gzipCompression bool) error { f, err := os.Open(filename) if err != nil { return fmt.Errorf("%d", 404) } defer f.Close() fi, _ := f.Stat() if fi.IsDir() { filename = path.Join(filename, "index.html") f, err = os.Open(filename) if err != nil { return fmt.Errorf("%d", 404) } fi, _ = f.Stat() } return ctx.ServeContent(f, fi.Name(), fi.ModTime(), gzipCompression) } // SendFile sends file for force-download to the client // // Use this instead of ServeFile to 'force-download' bigger files to the client. func (ctx *context) SendFile(filename string, destinationName string) error { ctx.writer.Header().Set(contentDispositionHeaderKey, "attachment;filename="+destinationName) return ctx.ServeFile(filename, false) } // +------------------------------------------------------------+ // | Cookies, Session and Flashes | // +------------------------------------------------------------+ // SetCookie adds a cookie func (ctx *context) SetCookie(cookie *http.Cookie) { http.SetCookie(ctx.writer, cookie) } var ( // SetCookieKVExpiration is 2 hours by-default // you can change it or simple, use the SetCookie for more control. SetCookieKVExpiration = time.Duration(120) * time.Minute ) // SetCookieKV adds a cookie, receives just a name(string) and a value(string) // // If you use this method, it expires at 2 hours // use ctx.SetCookie or http.SetCookie if you want to change more fields. func (ctx *context) SetCookieKV(name, value string) { c := &http.Cookie{} c.Name = name c.Value = value c.HttpOnly = true c.Expires = time.Now().Add(SetCookieKVExpiration) c.MaxAge = int(SetCookieKVExpiration.Seconds()) ctx.SetCookie(c) } // GetCookie returns cookie's value by it's name // returns empty string if nothing was found. func (ctx *context) GetCookie(name string) string { cookie, err := ctx.request.Cookie(name) if err != nil { return "" } return cookie.Value } // RemoveCookie deletes a cookie by it's name. func (ctx *context) RemoveCookie(name string) { c := &http.Cookie{} c.Name = name c.Value = "" c.Path = "/" c.HttpOnly = true // RFC says 1 second, but let's do it 1 minute to make sure is working exp := time.Now().Add(-time.Duration(1) * time.Minute) c.Expires = exp c.MaxAge = -1 ctx.SetCookie(c) // delete request's cookie also, which is temporary available ctx.request.Header.Set("Cookie", "") } // VisitAllCookies takes a visitor which loops // on each (request's) cookies' name and value. func (ctx *context) VisitAllCookies(visitor func(name string, value string)) { for _, cookie := range ctx.request.Cookies() { visitor(cookie.Name, cookie.Value) } } var maxAgeExp = regexp.MustCompile(`maxage=(\d+)`) // MaxAge returns the "cache-control" request header's value // seconds as int64 // if header not found or parse failed then it returns -1. func (ctx *context) MaxAge() int64 { header := ctx.GetHeader(cacheControlHeaderKey) if header == "" { return -1 } m := maxAgeExp.FindStringSubmatch(header) if len(m) == 2 { if v, err := strconv.Atoi(m[1]); err == nil { return int64(v) } } return -1 } // +------------------------------------------------------------+ // | Advanced: Response Recorder and Transactions | // +------------------------------------------------------------+ // Record transforms the context's basic and direct responseWriter to a *ResponseRecorder // which can be used to reset the body, reset headers, get the body, // get & set the status code at any time and more. func (ctx *context) Record() { if w, ok := ctx.writer.(*responseWriter); ok { recorder := AcquireResponseRecorder() recorder.BeginRecord(w) ctx.ResetResponseWriter(recorder) } } // Recorder returns the context's ResponseRecorder // if not recording then it starts recording and returns the new context's ResponseRecorder func (ctx *context) Recorder() *ResponseRecorder { ctx.Record() return ctx.writer.(*ResponseRecorder) } // IsRecording returns the response recorder and a true value // when the response writer is recording the status code, body, headers and so on, // else returns nil and false. func (ctx *context) IsRecording() (*ResponseRecorder, bool) { //NOTE: // two return values in order to minimize the if statement: // if (Recording) then writer = Recorder() // instead we do: recorder,ok = Recording() rr, ok := ctx.writer.(*ResponseRecorder) return rr, ok } // non-detailed error log for transacton unexpected panic var errTransactionInterrupted = errors.New("transaction interrupted, recovery from panic:\n%s") // BeginTransaction starts a scoped transaction. // // Can't say a lot here because it will take more than 200 lines to write about. // You can search third-party articles or books on how Business Transaction works (it's quite simple, especially here). // // Note that this is unique and new // (=I haver never seen any other examples or code in Golang on this subject, so far, as with the most of iris features...) // it's not covers all paths, // such as databases, this should be managed by the libraries you use to make your database connection, // this transaction scope is only for context's response. // Transactions have their own middleware ecosystem also, look iris.go:UseTransaction. // // See https://github.com/kataras/iris/tree/master/_examples/ for more func (ctx *context) BeginTransaction(pipe func(t *Transaction)) { // do NOT begin a transaction when the previous transaction has been failed // and it was requested scoped or SkipTransactions called manually. if ctx.TransactionsSkipped() { return } // start recording in order to be able to control the full response writer ctx.Record() t := newTransaction(ctx) // it calls this *context, so the overriding with a new pool's New of context.Context wil not work here. defer func() { if err := recover(); err != nil { ctx.Application().Logger().Warn(errTransactionInterrupted.Format(err).Error()) // complete (again or not , doesn't matters) the scope without loud t.Complete(nil) // we continue as normal, no need to return here* } // write the temp contents to the original writer t.Context().ResponseWriter().WriteTo(ctx.writer) // give back to the transaction the original writer (SetBeforeFlush works this way and only this way) // this is tricky but nessecery if we want ctx.FireStatusCode to work inside transactions t.Context().ResetResponseWriter(ctx.writer) }() // run the worker with its context clone inside. pipe(t) } // skipTransactionsContextKey set this to any value to stop executing next transactions // it's a context-key in order to be used from anywhere, set it by calling the SkipTransactions() const skipTransactionsContextKey = "@transictions_skipped" // SkipTransactions if called then skip the rest of the transactions // or all of them if called before the first transaction func (ctx *context) SkipTransactions() { ctx.values.Set(skipTransactionsContextKey, 1) } // TransactionsSkipped returns true if the transactions skipped or canceled at all. func (ctx *context) TransactionsSkipped() bool { if n, err := ctx.values.GetInt(skipTransactionsContextKey); err == nil && n == 1 { return true } return false } // Exec calls the framewrok's ServeCtx // based on this context but with a changed method and path // like it was requested by the user, but it is not. // // Offline means that the route is registered to the iris and have all features that a normal route has // BUT it isn't available by browsing, its handlers executed only when other handler's context call them // it can validate paths, has sessions, path parameters and all. // // You can find the Route by app.GetRoute("theRouteName") // you can set a route name as: myRoute := app.Get("/mypath", handler)("theRouteName") // that will set a name to the route and returns its RouteInfo instance for further usage. // // It doesn't changes the global state, if a route was "offline" it remains offline. // // app.None(...) and app.GetRoutes().Offline(route)/.Online(route, method) // // Example: https://github.com/kataras/iris/tree/master/_examples/routing/route-state // // User can get the response by simple using rec := ctx.Recorder(); rec.Body()/rec.StatusCode()/rec.Header(). // // context's Values and the Session are kept in order to be able to communicate via the result route. // // It's for extreme use cases, 99% of the times will never be useful for you. func (ctx *context) Exec(method string, path string) { if path != "" { if method == "" { method = "GET" } // backup the handlers backupHandlers := ctx.Handlers()[0:] backupPos := ctx.HandlerIndex(-1) // backup the request path information backupPath := ctx.Path() bakcupMethod := ctx.Method() // don't backupValues := ctx.Values().ReadOnly() // [sessions stays] // [values stays] // reset handlers ctx.SetHandlers(nil) req := ctx.Request() // set the request to be align with the 'againstRequestPath' req.RequestURI = path req.URL.Path = path req.Method = method // execute the route from the (internal) context router // this way we keep the sessions and the values ctx.Application().ServeHTTPC(ctx) // set back the old handlers and the last known index ctx.SetHandlers(backupHandlers) ctx.HandlerIndex(backupPos) // set the request back to its previous state req.RequestURI = backupPath req.URL.Path = backupPath req.Method = bakcupMethod // don't fill the values in order to be able to communicate from and to. // // fill the values as they were before // backupValues.Visit(func(key string, value interface{}) { // ctx.Values().Set(key, value) // }) } } // Application returns the iris app instance which belongs to this context. // Worth to notice that this function returns an interface // of the Application, which contains methods that are safe // to be executed at serve-time. The full app's fields // and methods are not available here for the developer's safety. func (ctx *context) Application() Application { return ctx.app } // +--------------------------------------------------------------+ // | https://github.com/golang/net/blob/master/context/context.go | | // +--------------------------------------------------------------+ // Deadline returns the time when work done on behalf of this context // should be canceled. Deadline returns ok==false when no deadline is // set. Successive calls to Deadline return the same results. func (ctx *context) Deadline() (deadline time.Time, ok bool) { return } // Done returns a channel that's closed when work done on behalf of this // context should be canceled. Done may return nil if this context can // never be canceled. Successive calls to Done return the same value. // // WithCancel arranges for Done to be closed when cancel is called; // WithDeadline arranges for Done to be closed when the deadline // expires; WithTimeout arranges for Done to be closed when the timeout // elapses. // // Done is provided for use in select statements: // // // Stream generates values with DoSomething and sends them to out // // until DoSomething returns an error or ctx.Done is closed. // func Stream(ctx context.Context, out chan<- Value) error { // for { // v, err := DoSomething(ctx) // if err != nil { // return err // } // select { // case <-ctx.Done(): // return ctx.Err() // case out <- v: // } // } // } // // See http://blog.golang.org/pipelines for more examples of how to use // a Done channel for cancelation. func (ctx *context) Done() <-chan struct{} { return nil } // Err returns a non-nil error value after Done is closed. Err returns // Canceled if the context was canceled or DeadlineExceeded if the // context's deadline passed. No other values for Err are defined. // After Done is closed, successive calls to Err return the same value. func (ctx *context) Err() error { return nil } // Value returns the value associated with this context for key, or nil // if no value is associated with key. Successive calls to Value with // the same key returns the same result. // // Use context values only for request-scoped data that transits // processes and API boundaries, not for passing optional parameters to // functions. // // A key indentifies a specific value in a context. Functions that wish // to store values in context typically allocate a key in a global // variable then use that key as the argument to context.WithValue and // context.Value. A key can be any type that supports equality; // packages should define keys as an unexported type to avoid // collisions. // // Packages that define a context key should provide type-safe accessors // for the values stores using that key: // // // Package user defines a User type that's stored in Contexts. // package user // // import "golang.org/x/net/context" // // // User is the type of value stored in the Contexts. // type User struct {...} // // // key is an unexported type for keys defined in this package. // // This prevents collisions with keys defined in other packages. // type key int // // // userKey is the key for user.User values in Contexts. It is // // unexported; clients use user.NewContext and user.FromContext // // instead of using this key directly. // var userKey key = 0 // // // NewContext returns a new context that carries value u. // func NewContext(ctx context.Context, u *User) context.Context { // return context.WithValue(ctx, userKey, u) // } // // // FromContext returns the User value stored in ctx, if any. // func FromContext(ctx context.Context) (*User, bool) { // u, ok := ctx.Value(userKey).(*User) // return u, ok // } func (ctx *context) Value(key interface{}) interface{} { if key == 0 { return ctx.request } if k, ok := key.(string); ok { return ctx.values.GetString(k) } return nil }