use std::slice::Iter; use std::borrow::Cow; use std::ops::{Deref, DerefMut}; use serde_urlencoded; use serde::de::{self, Deserializer, DeserializeOwned, Visitor, Error as DeError}; use futures::future::{FutureResult, result}; use error::Error; use handler::FromRequest; use httprequest::HttpRequest; /// Extract typed information from the request's path. /// /// `S` - application state type /// /// ## Example /// /// ```rust /// # extern crate bytes; /// # extern crate actix_web; /// # extern crate futures; /// #[macro_use] extern crate serde_derive; /// # use actix_web::*; /// use actix_web::Path; /// /// /// Application state /// struct State {} /// /// /// extract path info using serde /// fn index(info: Path<(String, u32), State>) -> Result { /// Ok(format!("Welcome {}! {}", info.0, info.1)) /// } /// /// fn main() { /// let app = Application::with_state(State{}).resource( /// "/{username}/{count}/?index.html", // <- define path parameters /// |r| r.method(Method::GET).with(index)); // <- use `with` extractor /// } /// ``` /// /// It is possible to extract path information to a specific type that implements /// `Deserialize` trait from *serde*. /// /// ```rust /// # extern crate bytes; /// # extern crate actix_web; /// # extern crate futures; /// #[macro_use] extern crate serde_derive; /// # use actix_web::*; /// use actix_web::Path; /// /// /// Application state /// struct State {} /// /// #[derive(Deserialize)] /// struct Info { /// username: String, /// } /// /// /// extract path info using serde /// fn index(info: Path) -> Result { /// Ok(format!("Welcome {}!", info.username)) /// } /// /// fn main() { /// let app = Application::with_state(State{}).resource( /// "/{username}/index.html", // <- define path parameters /// |r| r.method(Method::GET).with(index)); // <- use `with` extractor /// } /// ``` pub struct Path{ item: T, req: HttpRequest, } impl Deref for Path { type Target = T; fn deref(&self) -> &T { &self.item } } impl DerefMut for Path { fn deref_mut(&mut self) -> &mut T { &mut self.item } } impl Path { /// Shared application state #[inline] pub fn state(&self) -> &S { self.req.state() } /// Incoming request #[inline] pub fn request(&self) -> &HttpRequest { &self.req } /// Deconstruct instance into parts pub fn into(self) -> (T, HttpRequest) { (self.item, self.req) } } impl FromRequest for Path where T: DeserializeOwned, S: 'static { type Result = FutureResult; #[inline] fn from_request(req: &HttpRequest) -> Self::Result { let req = req.clone(); result(de::Deserialize::deserialize(PathDeserializer{req: &req}) .map_err(|e| e.into()) .map(|item| Path{item, req})) } } /// Extract typed information from from the request's query. /// /// `S` - application state type /// /// ## Example /// /// ```rust /// # extern crate bytes; /// # extern crate actix_web; /// # extern crate futures; /// #[macro_use] extern crate serde_derive; /// # use actix_web::*; /// use actix_web::Query; /// /// /// Application state /// struct State {} /// /// #[derive(Deserialize)] /// struct Info { /// username: String, /// } /// /// // use `with` extractor for query info /// // this handler get called only if request's query contains `username` field /// fn index(info: Query) -> Result { /// Ok(format!("Welcome {}!", info.username)) /// } /// /// fn main() { /// let app = Application::with_state(State{}).resource( /// "/index.html", /// |r| r.method(Method::GET).with(index)); // <- use `with` extractor /// } /// ``` pub struct Query{ item: T, req: HttpRequest, } impl Deref for Query { type Target = T; fn deref(&self) -> &T { &self.item } } impl DerefMut for Query { fn deref_mut(&mut self) -> &mut T { &mut self.item } } impl Query { /// Shared application state #[inline] pub fn state(&self) -> &S { self.req.state() } /// Incoming request #[inline] pub fn request(&self) -> &HttpRequest { &self.req } /// Deconstruct instance into parts pub fn into(self) -> (T, HttpRequest) { (self.item, self.req) } } impl FromRequest for Query where T: de::DeserializeOwned, S: 'static { type Result = FutureResult; #[inline] fn from_request(req: &HttpRequest) -> Self::Result { let req = req.clone(); result(serde_urlencoded::from_str::(req.query_string()) .map_err(|e| e.into()) .map(|item| Query{ item, req})) } } macro_rules! unsupported_type { ($trait_fn:ident, $name:expr) => { fn $trait_fn(self, _: V) -> Result where V: Visitor<'de> { Err(de::value::Error::custom(concat!("unsupported type: ", $name))) } }; } pub struct PathDeserializer<'de, S: 'de> { req: &'de HttpRequest } impl<'de, S: 'de> Deserializer<'de> for PathDeserializer<'de, S> { type Error = de::value::Error; fn deserialize_map(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_map(ParamsDeserializer{ params: self.req.match_info().iter(), current: None, }) } fn deserialize_struct(self, _: &'static str, _: &'static [&'static str], visitor: V) -> Result where V: Visitor<'de>, { self.deserialize_map(visitor) } fn deserialize_unit(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_unit() } fn deserialize_unit_struct(self, _: &'static str, visitor: V) -> Result where V: Visitor<'de> { self.deserialize_unit(visitor) } fn deserialize_newtype_struct(self, _: &'static str, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_newtype_struct(self) } fn deserialize_tuple(self, len: usize, visitor: V) -> Result where V: Visitor<'de> { if self.req.match_info().len() < len { Err(de::value::Error::custom( format!("wrong number of parameters: {} expected {}", self.req.match_info().len(), len).as_str())) } else { visitor.visit_seq(ParamsSeq{params: self.req.match_info().iter()}) } } fn deserialize_tuple_struct(self, _: &'static str, _: usize, visitor: V) -> Result where V: Visitor<'de> { visitor.visit_seq(ParamsSeq{params: self.req.match_info().iter()}) } fn deserialize_enum(self, _: &'static str, _: &'static [&'static str], _: V) -> Result where V: Visitor<'de> { Err(de::value::Error::custom("unsupported type: enum")) } unsupported_type!(deserialize_any, "'any'"); unsupported_type!(deserialize_bool, "bool"); unsupported_type!(deserialize_i8, "i8"); unsupported_type!(deserialize_i16, "i16"); unsupported_type!(deserialize_i32, "i32"); unsupported_type!(deserialize_i64, "i64"); unsupported_type!(deserialize_u8, "u8"); unsupported_type!(deserialize_u16, "u16"); unsupported_type!(deserialize_u32, "u32"); unsupported_type!(deserialize_u64, "u64"); unsupported_type!(deserialize_f32, "f32"); unsupported_type!(deserialize_f64, "f64"); unsupported_type!(deserialize_char, "char"); unsupported_type!(deserialize_str, "str"); unsupported_type!(deserialize_string, "String"); unsupported_type!(deserialize_bytes, "bytes"); unsupported_type!(deserialize_byte_buf, "byte buf"); unsupported_type!(deserialize_option, "Option"); unsupported_type!(deserialize_seq, "sequence"); unsupported_type!(deserialize_identifier, "identifier"); unsupported_type!(deserialize_ignored_any, "ignored_any"); } struct ParamsDeserializer<'de> { params: Iter<'de, (Cow<'de, str>, Cow<'de, str>)>, current: Option<(&'de str, &'de str)>, } impl<'de> de::MapAccess<'de> for ParamsDeserializer<'de> { type Error = de::value::Error; fn next_key_seed(&mut self, seed: K) -> Result, Self::Error> where K: de::DeserializeSeed<'de>, { self.current = self.params.next().map(|&(ref k, ref v)| (k.as_ref(), v.as_ref())); match self.current { Some((key, _)) => Ok(Some(seed.deserialize(Key{key})?)), None => Ok(None), } } fn next_value_seed(&mut self, seed: V) -> Result where V: de::DeserializeSeed<'de>, { if let Some((_, value)) = self.current.take() { seed.deserialize(Value { value }) } else { Err(de::value::Error::custom("unexpected item")) } } } struct Key<'de> { key: &'de str, } impl<'de> Deserializer<'de> for Key<'de> { type Error = de::value::Error; fn deserialize_identifier(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_str(self.key) } fn deserialize_any(self, _visitor: V) -> Result where V: Visitor<'de>, { Err(de::value::Error::custom("Unexpected")) } forward_to_deserialize_any! { bool i8 i16 i32 i64 u8 u16 u32 u64 f32 f64 char str string bytes byte_buf option unit unit_struct newtype_struct seq tuple tuple_struct map struct enum ignored_any } } macro_rules! parse_value { ($trait_fn:ident, $visitor_fn:ident, $tp:tt) => { fn $trait_fn(self, visitor: V) -> Result where V: Visitor<'de> { let v = self.value.parse().map_err( |_| de::value::Error::custom( format!("can not parse {:?} to a {}", self.value, $tp)))?; visitor.$visitor_fn(v) } } } struct Value<'de> { value: &'de str, } impl<'de> Deserializer<'de> for Value<'de> { type Error = de::value::Error; parse_value!(deserialize_bool, visit_bool, "bool"); parse_value!(deserialize_i8, visit_i8, "i8"); parse_value!(deserialize_i16, visit_i16, "i16"); parse_value!(deserialize_i32, visit_i32, "i16"); parse_value!(deserialize_i64, visit_i64, "i64"); parse_value!(deserialize_u8, visit_u8, "u8"); parse_value!(deserialize_u16, visit_u16, "u16"); parse_value!(deserialize_u32, visit_u32, "u32"); parse_value!(deserialize_u64, visit_u64, "u64"); parse_value!(deserialize_f32, visit_f32, "f32"); parse_value!(deserialize_f64, visit_f64, "f64"); parse_value!(deserialize_string, visit_string, "String"); parse_value!(deserialize_byte_buf, visit_string, "String"); parse_value!(deserialize_char, visit_char, "char"); fn deserialize_ignored_any(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_unit() } fn deserialize_unit(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_unit() } fn deserialize_unit_struct( self, _: &'static str, visitor: V) -> Result where V: Visitor<'de> { visitor.visit_unit() } fn deserialize_bytes(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_borrowed_bytes(self.value.as_bytes()) } fn deserialize_str(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_borrowed_str(self.value) } fn deserialize_option(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_some(self) } fn deserialize_enum(self, _: &'static str, _: &'static [&'static str], visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_enum(ValueEnum {value: self.value}) } fn deserialize_newtype_struct(self, _: &'static str, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_newtype_struct(self) } fn deserialize_tuple(self, _: usize, _: V) -> Result where V: Visitor<'de> { Err(de::value::Error::custom("unsupported type: tuple")) } fn deserialize_struct(self, _: &'static str, _: &'static [&'static str], _: V) -> Result where V: Visitor<'de> { Err(de::value::Error::custom("unsupported type: struct")) } fn deserialize_tuple_struct(self, _: &'static str, _: usize, _: V) -> Result where V: Visitor<'de> { Err(de::value::Error::custom("unsupported type: tuple struct")) } unsupported_type!(deserialize_any, ""); unsupported_type!(deserialize_seq, "seq"); unsupported_type!(deserialize_map, "map"); unsupported_type!(deserialize_identifier, "identifier"); } struct ParamsSeq<'de> { params: Iter<'de, (Cow<'de, str>, Cow<'de, str>)>, } impl<'de> de::SeqAccess<'de> for ParamsSeq<'de> { type Error = de::value::Error; fn next_element_seed(&mut self, seed: T) -> Result, Self::Error> where T: de::DeserializeSeed<'de>, { match self.params.next() { Some(item) => Ok(Some(seed.deserialize(Value { value: item.1.as_ref() })?)), None => Ok(None), } } } struct ValueEnum<'de> { value: &'de str, } impl<'de> de::EnumAccess<'de> for ValueEnum<'de> { type Error = de::value::Error; type Variant = UnitVariant; fn variant_seed(self, seed: V) -> Result<(V::Value, Self::Variant), Self::Error> where V: de::DeserializeSeed<'de>, { Ok((seed.deserialize(Key { key: self.value })?, UnitVariant)) } } struct UnitVariant; impl<'de> de::VariantAccess<'de> for UnitVariant { type Error = de::value::Error; fn unit_variant(self) -> Result<(), Self::Error> { Ok(()) } fn newtype_variant_seed(self, _seed: T) -> Result where T: de::DeserializeSeed<'de>, { Err(de::value::Error::custom("not supported")) } fn tuple_variant(self, _len: usize, _visitor: V) -> Result where V: Visitor<'de>, { Err(de::value::Error::custom("not supported")) } fn struct_variant(self, _: &'static [&'static str], _: V) -> Result where V: Visitor<'de>, { Err(de::value::Error::custom("not supported")) } } #[cfg(test)] mod tests { use futures::{Async, Future}; use super::*; use router::{Router, Pattern}; use resource::Resource; use test::TestRequest; use server::ServerSettings; #[derive(Deserialize)] struct MyStruct { key: String, value: String, } #[derive(Deserialize)] struct Id { id: String, } #[derive(Deserialize)] struct Test2 { key: String, value: u32, } #[test] fn test_request_extract() { let mut req = TestRequest::with_uri("/name/user1/?id=test").finish(); let mut resource = Resource::<()>::default(); resource.name("index"); let mut routes = Vec::new(); routes.push((Pattern::new("index", "/{key}/{value}/"), Some(resource))); let (router, _) = Router::new("", ServerSettings::default(), routes); assert!(router.recognize(&mut req).is_some()); match Path::::from_request(&req).poll().unwrap() { Async::Ready(s) => { assert_eq!(s.key, "name"); assert_eq!(s.value, "user1"); }, _ => unreachable!(), } match Path::<(String, String), _>::from_request(&req).poll().unwrap() { Async::Ready(s) => { assert_eq!(s.0, "name"); assert_eq!(s.1, "user1"); }, _ => unreachable!(), } match Query::::from_request(&req).poll().unwrap() { Async::Ready(s) => { assert_eq!(s.id, "test"); }, _ => unreachable!(), } let mut req = TestRequest::with_uri("/name/32/").finish(); assert!(router.recognize(&mut req).is_some()); match Path::::from_request(&req).poll().unwrap() { Async::Ready(s) => { assert_eq!(s.key, "name"); assert_eq!(s.value, 32); }, _ => unreachable!(), } match Path::<(String, u8), _>::from_request(&req).poll().unwrap() { Async::Ready(s) => { assert_eq!(s.0, "name"); assert_eq!(s.1, 32); }, _ => unreachable!(), } } }