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// Copyright 2017 Serde Developers // // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Generic data structure deserialization framework. //! //! The two most important traits in this module are [`Deserialize`] and //! [`Deserializer`]. //! //! - **A type that implements `Deserialize` is a data structure** that can be //! deserialized from any data format supported by Serde, and conversely //! - **A type that implements `Deserializer` is a data format** that can //! deserialize any data structure supported by Serde. //! //! # The Deserialize trait //! //! Serde provides [`Deserialize`] implementations for many Rust primitive and //! standard library types. The complete list is below. All of these can be //! deserialized using Serde out of the box. //! //! Additionally, Serde provides a procedural macro called [`serde_derive`] to //! automatically generate [`Deserialize`] implementations for structs and enums //! in your program. See the [codegen section of the manual] for how to use //! this. //! //! In rare cases it may be necessary to implement [`Deserialize`] manually for //! some type in your program. See the [Implementing `Deserialize`] section of //! the manual for more about this. //! //! Third-party crates may provide [`Deserialize`] implementations for types //! that they expose. For example the [`linked-hash-map`] crate provides a //! [`LinkedHashMap<K, V>`] type that is deserializable by Serde because the //! crate provides an implementation of [`Deserialize`] for it. //! //! # The Deserializer trait //! //! [`Deserializer`] implementations are provided by third-party crates, for //! example [`serde_json`], [`serde_yaml`] and [`bincode`]. //! //! A partial list of well-maintained formats is given on the [Serde //! website][data formats]. //! //! # Implementations of Deserialize provided by Serde //! //! This is a slightly different set of types than what is supported for //! serialization. Some types can be serialized by Serde but not deserialized. //! One example is `OsStr`. //! //! - **Primitive types**: //! - bool //! - i8, i16, i32, i64, i128, isize //! - u8, u16, u32, u64, u128, usize //! - f32, f64 //! - char //! - **Compound types**: //! - \[T; 0\] through \[T; 32\] //! - tuples up to size 16 //! - **Common standard library types**: //! - String //! - Option\<T\> //! - Result\<T, E\> //! - PhantomData\<T\> //! - **Wrapper types**: //! - Box\<T\> //! - Box\<\[T\]\> //! - Box\<str\> //! - Rc\<T\> //! - Arc\<T\> //! - Cow\<'a, T\> //! - Cell\<T\> //! - RefCell\<T\> //! - Mutex\<T\> //! - RwLock\<T\> //! - **Collection types**: //! - BTreeMap\<K, V\> //! - BTreeSet\<T\> //! - BinaryHeap\<T\> //! - HashMap\<K, V, H\> //! - HashSet\<T, H\> //! - LinkedList\<T\> //! - VecDeque\<T\> //! - Vec\<T\> //! - **Zero-copy types**: //! - &str //! - &\[u8\] //! - **FFI types**: //! - CString //! - Box\<CStr\> //! - OsString //! - **Miscellaneous standard library types**: //! - Duration //! - SystemTime //! - Path //! - PathBuf //! - Range\<T\> //! - num::NonZero* //! - `!` *(unstable)* //! - **Net types**: //! - IpAddr //! - Ipv4Addr //! - Ipv6Addr //! - SocketAddr //! - SocketAddrV4 //! - SocketAddrV6 //! //! [Implementing `Deserialize`]: https://serde.rs/impl-deserialize.html //! [`Deserialize`]: ../trait.Deserialize.html //! [`Deserializer`]: ../trait.Deserializer.html //! [`LinkedHashMap<K, V>`]: https://docs.rs/linked-hash-map/*/linked_hash_map/struct.LinkedHashMap.html //! [`bincode`]: https://github.com/TyOverby/bincode //! [`linked-hash-map`]: https://crates.io/crates/linked-hash-map //! [`serde_derive`]: https://crates.io/crates/serde_derive //! [`serde_json`]: https://github.com/serde-rs/json //! [`serde_yaml`]: https://github.com/dtolnay/serde-yaml //! [codegen section of the manual]: https://serde.rs/codegen.html //! [data formats]: https://serde.rs/#data-formats use lib::*; //////////////////////////////////////////////////////////////////////////////// pub mod value; mod from_primitive; mod ignored_any; mod impls; mod utf8; pub use self::ignored_any::IgnoredAny; //////////////////////////////////////////////////////////////////////////////// macro_rules! declare_error_trait { (Error: Sized $(+ $($supertrait:ident)::+)*) => { /// The `Error` trait allows `Deserialize` implementations to create descriptive /// error messages belonging to the `Deserializer` against which they are /// currently running. /// /// Every `Deserializer` declares an `Error` type that encompasses both /// general-purpose deserialization errors as well as errors specific to the /// particular deserialization format. For example the `Error` type of /// `serde_json` can represent errors like an invalid JSON escape sequence or an /// unterminated string literal, in addition to the error cases that are part of /// this trait. /// /// Most deserializers should only need to provide the `Error::custom` method /// and inherit the default behavior for the other methods. /// /// # Example implementation /// /// The [example data format] presented on the website shows an error /// type appropriate for a basic JSON data format. /// /// [example data format]: https://serde.rs/data-format.html pub trait Error: Sized $(+ $($supertrait)::+)* { /// Raised when there is general error when deserializing a type. /// /// The message should not be capitalized and should not end with a period. /// /// ```rust /// # use std::str::FromStr; /// # /// # struct IpAddr; /// # /// # impl FromStr for IpAddr { /// # type Err = String; /// # /// # fn from_str(_: &str) -> Result<Self, String> { /// # unimplemented!() /// # } /// # } /// # /// use serde::de::{self, Deserialize, Deserializer}; /// /// impl<'de> Deserialize<'de> for IpAddr { /// fn deserialize<D>(deserializer: D) -> Result<Self, D::Error> /// where /// D: Deserializer<'de>, /// { /// let s = try!(String::deserialize(deserializer)); /// s.parse().map_err(de::Error::custom) /// } /// } /// ``` fn custom<T>(msg: T) -> Self where T: Display; /// Raised when a `Deserialize` receives a type different from what it was /// expecting. /// /// The `unexp` argument provides information about what type was received. /// This is the type that was present in the input file or other source data /// of the Deserializer. /// /// The `exp` argument provides information about what type was being /// expected. This is the type that is written in the program. /// /// For example if we try to deserialize a String out of a JSON file /// containing an integer, the unexpected type is the integer and the /// expected type is the string. #[cold] fn invalid_type(unexp: Unexpected, exp: &Expected) -> Self { Error::custom(format_args!("invalid type: {}, expected {}", unexp, exp)) } /// Raised when a `Deserialize` receives a value of the right type but that /// is wrong for some other reason. /// /// The `unexp` argument provides information about what value was received. /// This is the value that was present in the input file or other source /// data of the Deserializer. /// /// The `exp` argument provides information about what value was being /// expected. This is the type that is written in the program. /// /// For example if we try to deserialize a String out of some binary data /// that is not valid UTF-8, the unexpected value is the bytes and the /// expected value is a string. #[cold] fn invalid_value(unexp: Unexpected, exp: &Expected) -> Self { Error::custom(format_args!("invalid value: {}, expected {}", unexp, exp)) } /// Raised when deserializing a sequence or map and the input data contains /// too many or too few elements. /// /// The `len` argument is the number of elements encountered. The sequence /// or map may have expected more arguments or fewer arguments. /// /// The `exp` argument provides information about what data was being /// expected. For example `exp` might say that a tuple of size 6 was /// expected. #[cold] fn invalid_length(len: usize, exp: &Expected) -> Self { Error::custom(format_args!("invalid length {}, expected {}", len, exp)) } /// Raised when a `Deserialize` enum type received a variant with an /// unrecognized name. #[cold] fn unknown_variant(variant: &str, expected: &'static [&'static str]) -> Self { if expected.is_empty() { Error::custom(format_args!("unknown variant `{}`, there are no variants", variant)) } else { Error::custom(format_args!("unknown variant `{}`, expected {}", variant, OneOf { names: expected })) } } /// Raised when a `Deserialize` struct type received a field with an /// unrecognized name. #[cold] fn unknown_field(field: &str, expected: &'static [&'static str]) -> Self { if expected.is_empty() { Error::custom(format_args!("unknown field `{}`, there are no fields", field)) } else { Error::custom(format_args!("unknown field `{}`, expected {}", field, OneOf { names: expected })) } } /// Raised when a `Deserialize` struct type expected to receive a required /// field with a particular name but that field was not present in the /// input. #[cold] fn missing_field(field: &'static str) -> Self { Error::custom(format_args!("missing field `{}`", field)) } /// Raised when a `Deserialize` struct type received more than one of the /// same field. #[cold] fn duplicate_field(field: &'static str) -> Self { Error::custom(format_args!("duplicate field `{}`", field)) } } } } #[cfg(feature = "std")] declare_error_trait!(Error: Sized + error::Error); #[cfg(not(feature = "std"))] declare_error_trait!(Error: Sized + Debug + Display); /// `Unexpected` represents an unexpected invocation of any one of the `Visitor` /// trait methods. /// /// This is used as an argument to the `invalid_type`, `invalid_value`, and /// `invalid_length` methods of the `Error` trait to build error messages. /// /// ```rust /// # use std::fmt; /// # /// # use serde::de::{self, Unexpected, Visitor}; /// # /// # struct Example; /// # /// # impl<'de> Visitor<'de> for Example { /// # type Value = (); /// # /// # fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// # write!(formatter, "definitely not a boolean") /// # } /// # /// fn visit_bool<E>(self, v: bool) -> Result<Self::Value, E> /// where /// E: de::Error, /// { /// Err(de::Error::invalid_type(Unexpected::Bool(v), &self)) /// } /// # } /// ``` #[derive(Copy, Clone, PartialEq, Debug)] pub enum Unexpected<'a> { /// The input contained a boolean value that was not expected. Bool(bool), /// The input contained an unsigned integer `u8`, `u16`, `u32` or `u64` that /// was not expected. Unsigned(u64), /// The input contained a signed integer `i8`, `i16`, `i32` or `i64` that /// was not expected. Signed(i64), /// The input contained a floating point `f32` or `f64` that was not /// expected. Float(f64), /// The input contained a `char` that was not expected. Char(char), /// The input contained a `&str` or `String` that was not expected. Str(&'a str), /// The input contained a `&[u8]` or `Vec<u8>` that was not expected. Bytes(&'a [u8]), /// The input contained a unit `()` that was not expected. Unit, /// The input contained an `Option<T>` that was not expected. Option, /// The input contained a newtype struct that was not expected. NewtypeStruct, /// The input contained a sequence that was not expected. Seq, /// The input contained a map that was not expected. Map, /// The input contained an enum that was not expected. Enum, /// The input contained a unit variant that was not expected. UnitVariant, /// The input contained a newtype variant that was not expected. NewtypeVariant, /// The input contained a tuple variant that was not expected. TupleVariant, /// The input contained a struct variant that was not expected. StructVariant, /// A message stating what uncategorized thing the input contained that was /// not expected. /// /// The message should be a noun or noun phrase, not capitalized and without /// a period. An example message is "unoriginal superhero". Other(&'a str), } impl<'a> fmt::Display for Unexpected<'a> { fn fmt(&self, formatter: &mut fmt::Formatter) -> Result<(), fmt::Error> { use self::Unexpected::*; match *self { Bool(b) => write!(formatter, "boolean `{}`", b), Unsigned(i) => write!(formatter, "integer `{}`", i), Signed(i) => write!(formatter, "integer `{}`", i), Float(f) => write!(formatter, "floating point `{}`", f), Char(c) => write!(formatter, "character `{}`", c), Str(s) => write!(formatter, "string {:?}", s), Bytes(_) => write!(formatter, "byte array"), Unit => write!(formatter, "unit value"), Option => write!(formatter, "Option value"), NewtypeStruct => write!(formatter, "newtype struct"), Seq => write!(formatter, "sequence"), Map => write!(formatter, "map"), Enum => write!(formatter, "enum"), UnitVariant => write!(formatter, "unit variant"), NewtypeVariant => write!(formatter, "newtype variant"), TupleVariant => write!(formatter, "tuple variant"), StructVariant => write!(formatter, "struct variant"), Other(other) => formatter.write_str(other), } } } /// `Expected` represents an explanation of what data a `Visitor` was expecting /// to receive. /// /// This is used as an argument to the `invalid_type`, `invalid_value`, and /// `invalid_length` methods of the `Error` trait to build error messages. The /// message should be a noun or noun phrase that completes the sentence "This /// Visitor expects to receive ...", for example the message could be "an /// integer between 0 and 64". The message should not be capitalized and should /// not end with a period. /// /// Within the context of a `Visitor` implementation, the `Visitor` itself /// (`&self`) is an implementation of this trait. /// /// ```rust /// # use std::fmt; /// # /// # use serde::de::{self, Unexpected, Visitor}; /// # /// # struct Example; /// # /// # impl<'de> Visitor<'de> for Example { /// # type Value = (); /// # /// # fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// # write!(formatter, "definitely not a boolean") /// # } /// # /// fn visit_bool<E>(self, v: bool) -> Result<Self::Value, E> /// where /// E: de::Error, /// { /// Err(de::Error::invalid_type(Unexpected::Bool(v), &self)) /// } /// # } /// ``` /// /// Outside of a `Visitor`, `&"..."` can be used. /// /// ```rust /// # use serde::de::{self, Unexpected}; /// # /// # fn example<E>() -> Result<(), E> /// # where /// # E: de::Error, /// # { /// # let v = true; /// return Err(de::Error::invalid_type(Unexpected::Bool(v), &"a negative integer")); /// # } /// ``` pub trait Expected { /// Format an explanation of what data was being expected. Same signature as /// the `Display` and `Debug` traits. fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result; } impl<'de, T> Expected for T where T: Visitor<'de>, { fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { self.expecting(formatter) } } impl<'a> Expected for &'a str { fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { formatter.write_str(self) } } impl<'a> Display for Expected + 'a { fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { Expected::fmt(self, formatter) } } //////////////////////////////////////////////////////////////////////////////// /// A **data structure** that can be deserialized from any data format supported /// by Serde. /// /// Serde provides `Deserialize` implementations for many Rust primitive and /// standard library types. The complete list is [here][de]. All of these can /// be deserialized using Serde out of the box. /// /// Additionally, Serde provides a procedural macro called `serde_derive` to /// automatically generate `Deserialize` implementations for structs and enums /// in your program. See the [codegen section of the manual][codegen] for how to /// use this. /// /// In rare cases it may be necessary to implement `Deserialize` manually for /// some type in your program. See the [Implementing /// `Deserialize`][impl-deserialize] section of the manual for more about this. /// /// Third-party crates may provide `Deserialize` implementations for types that /// they expose. For example the `linked-hash-map` crate provides a /// `LinkedHashMap<K, V>` type that is deserializable by Serde because the crate /// provides an implementation of `Deserialize` for it. /// /// [de]: https://docs.serde.rs/serde/de/index.html /// [codegen]: https://serde.rs/codegen.html /// [impl-deserialize]: https://serde.rs/impl-deserialize.html /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed by `Self` when deserialized. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html pub trait Deserialize<'de>: Sized { /// Deserialize this value from the given Serde deserializer. /// /// See the [Implementing `Deserialize`][impl-deserialize] section of the /// manual for more information about how to implement this method. /// /// [impl-deserialize]: https://serde.rs/impl-deserialize.html fn deserialize<D>(deserializer: D) -> Result<Self, D::Error> where D: Deserializer<'de>; /// Deserializes a value into `self` from the given Deserializer. /// /// The purpose of this method is to allow the deserializer to reuse /// resources and avoid copies. As such, if this method returns an error, /// `self` will be in an indeterminate state where some parts of the struct /// have been overwritten. Although whatever state that is will be /// memory-safe. /// /// This is generally useful when repeatedly deserializing values that /// are processed one at a time, where the value of `self` doesn't matter /// when the next deserialization occurs. /// /// If you manually implement this, your recursive deserializations should /// use `deserialize_in_place`. /// /// This method is stable and an official public API, but hidden from the /// documentation because it is almost never what newbies are looking for. /// Showing it in rustdoc would cause it to be featured more prominently /// than it deserves. #[doc(hidden)] fn deserialize_in_place<D>(deserializer: D, place: &mut Self) -> Result<(), D::Error> where D: Deserializer<'de>, { // Default implementation just delegates to `deserialize` impl. *place = Deserialize::deserialize(deserializer)?; Ok(()) } } /// A data structure that can be deserialized without borrowing any data from /// the deserializer. /// /// This is primarily useful for trait bounds on functions. For example a /// `from_str` function may be able to deserialize a data structure that borrows /// from the input string, but a `from_reader` function may only deserialize /// owned data. /// /// ```rust /// # use serde::de::{Deserialize, DeserializeOwned}; /// # use std::io::{Read, Result}; /// # /// # trait Ignore { /// fn from_str<'a, T>(s: &'a str) -> Result<T> /// where /// T: Deserialize<'a>; /// /// fn from_reader<R, T>(rdr: R) -> Result<T> /// where /// R: Read, /// T: DeserializeOwned; /// # } /// ``` /// /// # Lifetime /// /// The relationship between `Deserialize` and `DeserializeOwned` in trait /// bounds is explained in more detail on the page [Understanding deserializer /// lifetimes]. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html pub trait DeserializeOwned: for<'de> Deserialize<'de> {} impl<T> DeserializeOwned for T where T: for<'de> Deserialize<'de>, { } /// `DeserializeSeed` is the stateful form of the `Deserialize` trait. If you /// ever find yourself looking for a way to pass data into a `Deserialize` impl, /// this trait is the way to do it. /// /// As one example of stateful deserialization consider deserializing a JSON /// array into an existing buffer. Using the `Deserialize` trait we could /// deserialize a JSON array into a `Vec<T>` but it would be a freshly allocated /// `Vec<T>`; there is no way for `Deserialize` to reuse a previously allocated /// buffer. Using `DeserializeSeed` instead makes this possible as in the /// example code below. /// /// The canonical API for stateless deserialization looks like this: /// /// ```rust /// # use serde::Deserialize; /// # /// # enum Error {} /// # /// fn func<'de, T: Deserialize<'de>>() -> Result<T, Error> /// # { /// # unimplemented!() /// # } /// ``` /// /// Adjusting an API like this to support stateful deserialization is a matter /// of accepting a seed as input: /// /// ```rust /// # use serde::de::DeserializeSeed; /// # /// # enum Error {} /// # /// fn func_seed<'de, T: DeserializeSeed<'de>>(seed: T) -> Result<T::Value, Error> /// # { /// # let _ = seed; /// # unimplemented!() /// # } /// ``` /// /// In practice the majority of deserialization is stateless. An API expecting a /// seed can be appeased by passing `std::marker::PhantomData` as a seed in the /// case of stateless deserialization. /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed by `Self::Value` when deserialized. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example /// /// Suppose we have JSON that looks like `[[1, 2], [3, 4, 5], [6]]` and we need /// to deserialize it into a flat representation like `vec![1, 2, 3, 4, 5, 6]`. /// Allocating a brand new `Vec<T>` for each subarray would be slow. Instead we /// would like to allocate a single `Vec<T>` and then deserialize each subarray /// into it. This requires stateful deserialization using the `DeserializeSeed` /// trait. /// /// ```rust /// use std::fmt; /// use std::marker::PhantomData; /// /// use serde::de::{Deserialize, DeserializeSeed, Deserializer, Visitor, SeqAccess}; /// /// // A DeserializeSeed implementation that uses stateful deserialization to /// // append array elements onto the end of an existing vector. The preexisting /// // state ("seed") in this case is the Vec<T>. The `deserialize` method of /// // `ExtendVec` will be traversing the inner arrays of the JSON input and /// // appending each integer into the existing Vec. /// struct ExtendVec<'a, T: 'a>(&'a mut Vec<T>); /// /// impl<'de, 'a, T> DeserializeSeed<'de> for ExtendVec<'a, T> /// where /// T: Deserialize<'de>, /// { /// // The return type of the `deserialize` method. This implementation /// // appends onto an existing vector but does not create any new data /// // structure, so the return type is (). /// type Value = (); /// /// fn deserialize<D>(self, deserializer: D) -> Result<Self::Value, D::Error> /// where /// D: Deserializer<'de>, /// { /// // Visitor implementation that will walk an inner array of the JSON /// // input. /// struct ExtendVecVisitor<'a, T: 'a>(&'a mut Vec<T>); /// /// impl<'de, 'a, T> Visitor<'de> for ExtendVecVisitor<'a, T> /// where /// T: Deserialize<'de>, /// { /// type Value = (); /// /// fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// write!(formatter, "an array of integers") /// } /// /// fn visit_seq<A>(self, mut seq: A) -> Result<(), A::Error> /// where /// A: SeqAccess<'de>, /// { /// // Visit each element in the inner array and push it onto /// // the existing vector. /// while let Some(elem) = seq.next_element()? { /// self.0.push(elem); /// } /// Ok(()) /// } /// } /// /// deserializer.deserialize_seq(ExtendVecVisitor(self.0)) /// } /// } /// /// // Visitor implementation that will walk the outer array of the JSON input. /// struct FlattenedVecVisitor<T>(PhantomData<T>); /// /// impl<'de, T> Visitor<'de> for FlattenedVecVisitor<T> /// where /// T: Deserialize<'de>, /// { /// // This Visitor constructs a single Vec<T> to hold the flattened /// // contents of the inner arrays. /// type Value = Vec<T>; /// /// fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// write!(formatter, "an array of arrays") /// } /// /// fn visit_seq<A>(self, mut seq: A) -> Result<Vec<T>, A::Error> /// where /// A: SeqAccess<'de>, /// { /// // Create a single Vec to hold the flattened contents. /// let mut vec = Vec::new(); /// /// // Each iteration through this loop is one inner array. /// while let Some(()) = seq.next_element_seed(ExtendVec(&mut vec))? { /// // Nothing to do; inner array has been appended into `vec`. /// } /// /// // Return the finished vec. /// Ok(vec) /// } /// } /// /// # fn example<'de, D>(deserializer: D) -> Result<(), D::Error> /// # where /// # D: Deserializer<'de>, /// # { /// let visitor = FlattenedVecVisitor(PhantomData); /// let flattened: Vec<u64> = deserializer.deserialize_seq(visitor)?; /// # Ok(()) /// # } /// ``` pub trait DeserializeSeed<'de>: Sized { /// The type produced by using this seed. type Value; /// Equivalent to the more common `Deserialize::deserialize` method, except /// with some initial piece of data (the seed) passed in. fn deserialize<D>(self, deserializer: D) -> Result<Self::Value, D::Error> where D: Deserializer<'de>; } impl<'de, T> DeserializeSeed<'de> for PhantomData<T> where T: Deserialize<'de>, { type Value = T; #[inline] fn deserialize<D>(self, deserializer: D) -> Result<T, D::Error> where D: Deserializer<'de>, { T::deserialize(deserializer) } } //////////////////////////////////////////////////////////////////////////////// /// A **data format** that can deserialize any data structure supported by /// Serde. /// /// The role of this trait is to define the deserialization half of the [Serde /// data model], which is a way to categorize every Rust data type into one of /// 29 possible types. Each method of the `Serializer` trait corresponds to one /// of the types of the data model. /// /// Implementations of `Deserialize` map themselves into this data model by /// passing to the `Deserializer` a `Visitor` implementation that can receive /// these various types. /// /// The types that make up the Serde data model are: /// /// - **14 primitive types** /// - bool /// - i8, i16, i32, i64, i128 /// - u8, u16, u32, u64, u128 /// - f32, f64 /// - char /// - **string** /// - UTF-8 bytes with a length and no null terminator. /// - When serializing, all strings are handled equally. When deserializing, /// there are three flavors of strings: transient, owned, and borrowed. /// - **byte array** - \[u8\] /// - Similar to strings, during deserialization byte arrays can be transient, /// owned, or borrowed. /// - **option** /// - Either none or some value. /// - **unit** /// - The type of `()` in Rust. It represents an anonymous value containing no /// data. /// - **unit_struct** /// - For example `struct Unit` or `PhantomData<T>`. It represents a named value /// containing no data. /// - **unit_variant** /// - For example the `E::A` and `E::B` in `enum E { A, B }`. /// - **newtype_struct** /// - For example `struct Millimeters(u8)`. /// - **newtype_variant** /// - For example the `E::N` in `enum E { N(u8) }`. /// - **seq** /// - A variably sized heterogeneous sequence of values, for example `Vec<T>` or /// `HashSet<T>`. When serializing, the length may or may not be known before /// iterating through all the data. When deserializing, the length is determined /// by looking at the serialized data. /// - **tuple** /// - A statically sized heterogeneous sequence of values for which the length /// will be known at deserialization time without looking at the serialized /// data, for example `(u8,)` or `(String, u64, Vec<T>)` or `[u64; 10]`. /// - **tuple_struct** /// - A named tuple, for example `struct Rgb(u8, u8, u8)`. /// - **tuple_variant** /// - For example the `E::T` in `enum E { T(u8, u8) }`. /// - **map** /// - A heterogeneous key-value pairing, for example `BTreeMap<K, V>`. /// - **struct** /// - A heterogeneous key-value pairing in which the keys are strings and will be /// known at deserialization time without looking at the serialized data, for /// example `struct S { r: u8, g: u8, b: u8 }`. /// - **struct_variant** /// - For example the `E::S` in `enum E { S { r: u8, g: u8, b: u8 } }`. /// /// The `Deserializer` trait supports two entry point styles which enables /// different kinds of deserialization. /// /// 1. The `deserialize` method. Self-describing data formats like JSON are able /// to look at the serialized data and tell what it represents. For example /// the JSON deserializer may see an opening curly brace (`{`) and know that /// it is seeing a map. If the data format supports /// `Deserializer::deserialize_any`, it will drive the Visitor using whatever /// type it sees in the input. JSON uses this approach when deserializing /// `serde_json::Value` which is an enum that can represent any JSON /// document. Without knowing what is in a JSON document, we can deserialize /// it to `serde_json::Value` by going through `Deserializer::deserialize_any`. /// /// 2. The various `deserialize_*` methods. Non-self-describing formats like /// Bincode need to be told what is in the input in order to deserialize it. /// The `deserialize_*` methods are hints to the deserializer for how to /// interpret the next piece of input. Non-self-describing formats are not /// able to deserialize something like `serde_json::Value` which relies on /// `Deserializer::deserialize_any`. /// /// When implementing `Deserialize`, you should avoid relying on /// `Deserializer::deserialize_any` unless you need to be told by the Deserializer /// what type is in the input. Know that relying on `Deserializer::deserialize_any` /// means your data type will be able to deserialize from self-describing /// formats only, ruling out Bincode and many others. /// /// [Serde data model]: https://serde.rs/data-model.html /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed from the input when deserializing. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example implementation /// /// The [example data format] presented on the website contains example code for /// a basic JSON `Deserializer`. /// /// [example data format]: https://serde.rs/data-format.html pub trait Deserializer<'de>: Sized { /// The error type that can be returned if some error occurs during /// deserialization. type Error: Error; /// Require the `Deserializer` to figure out how to drive the visitor based /// on what data type is in the input. /// /// When implementing `Deserialize`, you should avoid relying on /// `Deserializer::deserialize_any` unless you need to be told by the /// Deserializer what type is in the input. Know that relying on /// `Deserializer::deserialize_any` means your data type will be able to /// deserialize from self-describing formats only, ruling out Bincode and /// many others. fn deserialize_any<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a `bool` value. fn deserialize_bool<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting an `i8` value. fn deserialize_i8<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting an `i16` value. fn deserialize_i16<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting an `i32` value. fn deserialize_i32<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting an `i64` value. fn deserialize_i64<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; serde_if_integer128! { /// Hint that the `Deserialize` type is expecting an `i128` value. /// /// This method is available only on Rust compiler versions >=1.26. The /// default behavior unconditionally returns an error. fn deserialize_i128<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de> { let _ = visitor; Err(Error::custom("i128 is not supported")) } } /// Hint that the `Deserialize` type is expecting a `u8` value. fn deserialize_u8<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a `u16` value. fn deserialize_u16<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a `u32` value. fn deserialize_u32<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a `u64` value. fn deserialize_u64<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; serde_if_integer128! { /// Hint that the `Deserialize` type is expecting an `u128` value. /// /// This method is available only on Rust compiler versions >=1.26. The /// default behavior unconditionally returns an error. fn deserialize_u128<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de> { let _ = visitor; Err(Error::custom("u128 is not supported")) } } /// Hint that the `Deserialize` type is expecting a `f32` value. fn deserialize_f32<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a `f64` value. fn deserialize_f64<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a `char` value. fn deserialize_char<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a string value and does /// not benefit from taking ownership of buffered data owned by the /// `Deserializer`. /// /// If the `Visitor` would benefit from taking ownership of `String` data, /// indiciate this to the `Deserializer` by using `deserialize_string` /// instead. fn deserialize_str<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a string value and would /// benefit from taking ownership of buffered data owned by the /// `Deserializer`. /// /// If the `Visitor` would not benefit from taking ownership of `String` /// data, indicate that to the `Deserializer` by using `deserialize_str` /// instead. fn deserialize_string<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a byte array and does not /// benefit from taking ownership of buffered data owned by the /// `Deserializer`. /// /// If the `Visitor` would benefit from taking ownership of `Vec<u8>` data, /// indicate this to the `Deserializer` by using `deserialize_byte_buf` /// instead. fn deserialize_bytes<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a byte array and would /// benefit from taking ownership of buffered data owned by the /// `Deserializer`. /// /// If the `Visitor` would not benefit from taking ownership of `Vec<u8>` /// data, indicate that to the `Deserializer` by using `deserialize_bytes` /// instead. fn deserialize_byte_buf<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting an optional value. /// /// This allows deserializers that encode an optional value as a nullable /// value to convert the null value into `None` and a regular value into /// `Some(value)`. fn deserialize_option<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a unit value. fn deserialize_unit<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a unit struct with a /// particular name. fn deserialize_unit_struct<V>( self, name: &'static str, visitor: V, ) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a newtype struct with a /// particular name. fn deserialize_newtype_struct<V>( self, name: &'static str, visitor: V, ) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a sequence of values. fn deserialize_seq<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a sequence of values and /// knows how many values there are without looking at the serialized data. fn deserialize_tuple<V>(self, len: usize, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a tuple struct with a /// particular name and number of fields. fn deserialize_tuple_struct<V>( self, name: &'static str, len: usize, visitor: V, ) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a map of key-value pairs. fn deserialize_map<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting a struct with a particular /// name and fields. fn deserialize_struct<V>( self, name: &'static str, fields: &'static [&'static str], visitor: V, ) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting an enum value with a /// particular name and possible variants. fn deserialize_enum<V>( self, name: &'static str, variants: &'static [&'static str], visitor: V, ) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type is expecting the name of a struct /// field or the discriminant of an enum variant. fn deserialize_identifier<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Hint that the `Deserialize` type needs to deserialize a value whose type /// doesn't matter because it is ignored. /// /// Deserializers for non-self-describing formats may not support this mode. fn deserialize_ignored_any<V>(self, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Determine whether `Deserialize` implementations should expect to /// deserialize their human-readable form. /// /// Some types have a human-readable form that may be somewhat expensive to /// construct, as well as a binary form that is compact and efficient. /// Generally text-based formats like JSON and YAML will prefer to use the /// human-readable one and binary formats like Bincode will prefer the /// compact one. /// /// ``` /// # use std::ops::Add; /// # use std::str::FromStr; /// # /// # struct Timestamp; /// # /// # impl Timestamp { /// # const EPOCH: Timestamp = Timestamp; /// # } /// # /// # impl FromStr for Timestamp { /// # type Err = String; /// # fn from_str(_: &str) -> Result<Self, Self::Err> { /// # unimplemented!() /// # } /// # } /// # /// # struct Duration; /// # /// # impl Duration { /// # fn seconds(_: u64) -> Self { unimplemented!() } /// # } /// # /// # impl Add<Duration> for Timestamp { /// # type Output = Timestamp; /// # fn add(self, _: Duration) -> Self::Output { /// # unimplemented!() /// # } /// # } /// # /// use serde::de::{self, Deserialize, Deserializer}; /// /// impl<'de> Deserialize<'de> for Timestamp { /// fn deserialize<D>(deserializer: D) -> Result<Self, D::Error> /// where /// D: Deserializer<'de>, /// { /// if deserializer.is_human_readable() { /// // Deserialize from a human-readable string like "2015-05-15T17:01:00Z". /// let s = String::deserialize(deserializer)?; /// Timestamp::from_str(&s).map_err(de::Error::custom) /// } else { /// // Deserialize from a compact binary representation, seconds since /// // the Unix epoch. /// let n = u64::deserialize(deserializer)?; /// Ok(Timestamp::EPOCH + Duration::seconds(n)) /// } /// } /// } /// ``` /// /// The default implementation of this method returns `true`. Data formats /// may override this to `false` to request a compact form for types that /// support one. Note that modifying this method to change a format from /// human-readable to compact or vice versa should be regarded as a breaking /// change, as a value serialized in human-readable mode is not required to /// deserialize from the same data in compact mode. #[inline] fn is_human_readable(&self) -> bool { true } } //////////////////////////////////////////////////////////////////////////////// /// This trait represents a visitor that walks through a deserializer. /// /// # Lifetime /// /// The `'de` lifetime of this trait is the requirement for lifetime of data /// that may be borrowed by `Self::Value`. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example /// /// ```rust /// # use std::fmt; /// # /// # use serde::de::{self, Unexpected, Visitor}; /// # /// /// A visitor that deserializes a long string - a string containing at least /// /// some minimum number of bytes. /// struct LongString { /// min: usize, /// } /// /// impl<'de> Visitor<'de> for LongString { /// type Value = String; /// /// fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// write!(formatter, "a string containing at least {} bytes", self.min) /// } /// /// fn visit_str<E>(self, s: &str) -> Result<Self::Value, E> /// where /// E: de::Error, /// { /// if s.len() >= self.min { /// Ok(s.to_owned()) /// } else { /// Err(de::Error::invalid_value(Unexpected::Str(s), &self)) /// } /// } /// } /// ``` pub trait Visitor<'de>: Sized { /// The value produced by this visitor. type Value; /// Format a message stating what data this Visitor expects to receive. /// /// This is used in error messages. The message should complete the sentence /// "This Visitor expects to receive ...", for example the message could be /// "an integer between 0 and 64". The message should not be capitalized and /// should not end with a period. /// /// ```rust /// # use std::fmt; /// # /// # struct S { /// # max: usize, /// # } /// # /// # impl<'de> serde::de::Visitor<'de> for S { /// # type Value = (); /// # /// fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// write!(formatter, "an integer between 0 and {}", self.max) /// } /// # } /// ``` fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result; /// The input contains a boolean. /// /// The default implementation fails with a type error. fn visit_bool<E>(self, v: bool) -> Result<Self::Value, E> where E: Error, { Err(Error::invalid_type(Unexpected::Bool(v), &self)) } /// The input contains an `i8`. /// /// The default implementation forwards to [`visit_i64`]. /// /// [`visit_i64`]: #method.visit_i64 fn visit_i8<E>(self, v: i8) -> Result<Self::Value, E> where E: Error, { self.visit_i64(v as i64) } /// The input contains an `i16`. /// /// The default implementation forwards to [`visit_i64`]. /// /// [`visit_i64`]: #method.visit_i64 fn visit_i16<E>(self, v: i16) -> Result<Self::Value, E> where E: Error, { self.visit_i64(v as i64) } /// The input contains an `i32`. /// /// The default implementation forwards to [`visit_i64`]. /// /// [`visit_i64`]: #method.visit_i64 fn visit_i32<E>(self, v: i32) -> Result<Self::Value, E> where E: Error, { self.visit_i64(v as i64) } /// The input contains an `i64`. /// /// The default implementation fails with a type error. fn visit_i64<E>(self, v: i64) -> Result<Self::Value, E> where E: Error, { Err(Error::invalid_type(Unexpected::Signed(v), &self)) } serde_if_integer128! { /// The input contains a `i128`. /// /// This method is available only on Rust compiler versions >=1.26. The /// default implementation fails with a type error. fn visit_i128<E>(self, v: i128) -> Result<Self::Value, E> where E: Error, { let _ = v; Err(Error::invalid_type(Unexpected::Other("i128"), &self)) } } /// The input contains a `u8`. /// /// The default implementation forwards to [`visit_u64`]. /// /// [`visit_u64`]: #method.visit_u64 fn visit_u8<E>(self, v: u8) -> Result<Self::Value, E> where E: Error, { self.visit_u64(v as u64) } /// The input contains a `u16`. /// /// The default implementation forwards to [`visit_u64`]. /// /// [`visit_u64`]: #method.visit_u64 fn visit_u16<E>(self, v: u16) -> Result<Self::Value, E> where E: Error, { self.visit_u64(v as u64) } /// The input contains a `u32`. /// /// The default implementation forwards to [`visit_u64`]. /// /// [`visit_u64`]: #method.visit_u64 fn visit_u32<E>(self, v: u32) -> Result<Self::Value, E> where E: Error, { self.visit_u64(v as u64) } /// The input contains a `u64`. /// /// The default implementation fails with a type error. fn visit_u64<E>(self, v: u64) -> Result<Self::Value, E> where E: Error, { Err(Error::invalid_type(Unexpected::Unsigned(v), &self)) } serde_if_integer128! { /// The input contains a `u128`. /// /// This method is available only on Rust compiler versions >=1.26. The /// default implementation fails with a type error. fn visit_u128<E>(self, v: u128) -> Result<Self::Value, E> where E: Error, { let _ = v; Err(Error::invalid_type(Unexpected::Other("u128"), &self)) } } /// The input contains an `f32`. /// /// The default implementation forwards to [`visit_f64`]. /// /// [`visit_f64`]: #method.visit_f64 fn visit_f32<E>(self, v: f32) -> Result<Self::Value, E> where E: Error, { self.visit_f64(v as f64) } /// The input contains an `f64`. /// /// The default implementation fails with a type error. fn visit_f64<E>(self, v: f64) -> Result<Self::Value, E> where E: Error, { Err(Error::invalid_type(Unexpected::Float(v), &self)) } /// The input contains a `char`. /// /// The default implementation forwards to [`visit_str`] as a one-character /// string. /// /// [`visit_str`]: #method.visit_str #[inline] fn visit_char<E>(self, v: char) -> Result<Self::Value, E> where E: Error, { self.visit_str(utf8::encode(v).as_str()) } /// The input contains a string. The lifetime of the string is ephemeral and /// it may be destroyed after this method returns. /// /// This method allows the `Deserializer` to avoid a copy by retaining /// ownership of any buffered data. `Deserialize` implementations that do /// not benefit from taking ownership of `String` data should indicate that /// to the deserializer by using `Deserializer::deserialize_str` rather than /// `Deserializer::deserialize_string`. /// /// It is never correct to implement `visit_string` without implementing /// `visit_str`. Implement neither, both, or just `visit_str`. fn visit_str<E>(self, v: &str) -> Result<Self::Value, E> where E: Error, { Err(Error::invalid_type(Unexpected::Str(v), &self)) } /// The input contains a string that lives at least as long as the /// `Deserializer`. /// /// This enables zero-copy deserialization of strings in some formats. For /// example JSON input containing the JSON string `"borrowed"` can be /// deserialized with zero copying into a `&'a str` as long as the input /// data outlives `'a`. /// /// The default implementation forwards to `visit_str`. #[inline] fn visit_borrowed_str<E>(self, v: &'de str) -> Result<Self::Value, E> where E: Error, { self.visit_str(v) } /// The input contains a string and ownership of the string is being given /// to the `Visitor`. /// /// This method allows the `Visitor` to avoid a copy by taking ownership of /// a string created by the `Deserializer`. `Deserialize` implementations /// that benefit from taking ownership of `String` data should indicate that /// to the deserializer by using `Deserializer::deserialize_string` rather /// than `Deserializer::deserialize_str`, although not every deserializer /// will honor such a request. /// /// It is never correct to implement `visit_string` without implementing /// `visit_str`. Implement neither, both, or just `visit_str`. /// /// The default implementation forwards to `visit_str` and then drops the /// `String`. #[inline] #[cfg(any(feature = "std", feature = "alloc"))] fn visit_string<E>(self, v: String) -> Result<Self::Value, E> where E: Error, { self.visit_str(&v) } /// The input contains a byte array. The lifetime of the byte array is /// ephemeral and it may be destroyed after this method returns. /// /// This method allows the `Deserializer` to avoid a copy by retaining /// ownership of any buffered data. `Deserialize` implementations that do /// not benefit from taking ownership of `Vec<u8>` data should indicate that /// to the deserializer by using `Deserializer::deserialize_bytes` rather /// than `Deserializer::deserialize_byte_buf`. /// /// It is never correct to implement `visit_byte_buf` without implementing /// `visit_bytes`. Implement neither, both, or just `visit_bytes`. fn visit_bytes<E>(self, v: &[u8]) -> Result<Self::Value, E> where E: Error, { let _ = v; Err(Error::invalid_type(Unexpected::Bytes(v), &self)) } /// The input contains a byte array that lives at least as long as the /// `Deserializer`. /// /// This enables zero-copy deserialization of bytes in some formats. For /// example Bincode data containing bytes can be deserialized with zero /// copying into a `&'a [u8]` as long as the input data outlives `'a`. /// /// The default implementation forwards to `visit_bytes`. #[inline] fn visit_borrowed_bytes<E>(self, v: &'de [u8]) -> Result<Self::Value, E> where E: Error, { self.visit_bytes(v) } /// The input contains a byte array and ownership of the byte array is being /// given to the `Visitor`. /// /// This method allows the `Visitor` to avoid a copy by taking ownership of /// a byte buffer created by the `Deserializer`. `Deserialize` /// implementations that benefit from taking ownership of `Vec<u8>` data /// should indicate that to the deserializer by using /// `Deserializer::deserialize_byte_buf` rather than /// `Deserializer::deserialize_bytes`, although not every deserializer will /// honor such a request. /// /// It is never correct to implement `visit_byte_buf` without implementing /// `visit_bytes`. Implement neither, both, or just `visit_bytes`. /// /// The default implementation forwards to `visit_bytes` and then drops the /// `Vec<u8>`. #[cfg(any(feature = "std", feature = "alloc"))] fn visit_byte_buf<E>(self, v: Vec<u8>) -> Result<Self::Value, E> where E: Error, { self.visit_bytes(&v) } /// The input contains an optional that is absent. /// /// The default implementation fails with a type error. fn visit_none<E>(self) -> Result<Self::Value, E> where E: Error, { Err(Error::invalid_type(Unexpected::Option, &self)) } /// The input contains an optional that is present. /// /// The default implementation fails with a type error. fn visit_some<D>(self, deserializer: D) -> Result<Self::Value, D::Error> where D: Deserializer<'de>, { let _ = deserializer; Err(Error::invalid_type(Unexpected::Option, &self)) } /// The input contains a unit `()`. /// /// The default implementation fails with a type error. fn visit_unit<E>(self) -> Result<Self::Value, E> where E: Error, { Err(Error::invalid_type(Unexpected::Unit, &self)) } /// The input contains a newtype struct. /// /// The content of the newtype struct may be read from the given /// `Deserializer`. /// /// The default implementation fails with a type error. fn visit_newtype_struct<D>(self, deserializer: D) -> Result<Self::Value, D::Error> where D: Deserializer<'de>, { let _ = deserializer; Err(Error::invalid_type(Unexpected::NewtypeStruct, &self)) } /// The input contains a sequence of elements. /// /// The default implementation fails with a type error. fn visit_seq<A>(self, seq: A) -> Result<Self::Value, A::Error> where A: SeqAccess<'de>, { let _ = seq; Err(Error::invalid_type(Unexpected::Seq, &self)) } /// The input contains a key-value map. /// /// The default implementation fails with a type error. fn visit_map<A>(self, map: A) -> Result<Self::Value, A::Error> where A: MapAccess<'de>, { let _ = map; Err(Error::invalid_type(Unexpected::Map, &self)) } /// The input contains an enum. /// /// The default implementation fails with a type error. fn visit_enum<A>(self, data: A) -> Result<Self::Value, A::Error> where A: EnumAccess<'de>, { let _ = data; Err(Error::invalid_type(Unexpected::Enum, &self)) } // Used when deserializing a flattened Option field. Not public API. #[doc(hidden)] fn __private_visit_untagged_option<D>(self, _: D) -> Result<Self::Value, ()> where D: Deserializer<'de>, { Err(()) } } //////////////////////////////////////////////////////////////////////////////// /// Provides a `Visitor` access to each element of a sequence in the input. /// /// This is a trait that a `Deserializer` passes to a `Visitor` implementation, /// which deserializes each item in a sequence. /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed by deserialized sequence elements. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example implementation /// /// The [example data format] presented on the website demonstrates an /// implementation of `SeqAccess` for a basic JSON data format. /// /// [example data format]: https://serde.rs/data-format.html pub trait SeqAccess<'de> { /// The error type that can be returned if some error occurs during /// deserialization. type Error: Error; /// This returns `Ok(Some(value))` for the next value in the sequence, or /// `Ok(None)` if there are no more remaining items. /// /// `Deserialize` implementations should typically use /// `SeqAccess::next_element` instead. fn next_element_seed<T>(&mut self, seed: T) -> Result<Option<T::Value>, Self::Error> where T: DeserializeSeed<'de>; /// This returns `Ok(Some(value))` for the next value in the sequence, or /// `Ok(None)` if there are no more remaining items. /// /// This method exists as a convenience for `Deserialize` implementations. /// `SeqAccess` implementations should not override the default behavior. #[inline] fn next_element<T>(&mut self) -> Result<Option<T>, Self::Error> where T: Deserialize<'de>, { self.next_element_seed(PhantomData) } /// Returns the number of elements remaining in the sequence, if known. #[inline] fn size_hint(&self) -> Option<usize> { None } } impl<'de, 'a, A> SeqAccess<'de> for &'a mut A where A: SeqAccess<'de>, { type Error = A::Error; #[inline] fn next_element_seed<T>(&mut self, seed: T) -> Result<Option<T::Value>, Self::Error> where T: DeserializeSeed<'de>, { (**self).next_element_seed(seed) } #[inline] fn next_element<T>(&mut self) -> Result<Option<T>, Self::Error> where T: Deserialize<'de>, { (**self).next_element() } #[inline] fn size_hint(&self) -> Option<usize> { (**self).size_hint() } } //////////////////////////////////////////////////////////////////////////////// /// Provides a `Visitor` access to each entry of a map in the input. /// /// This is a trait that a `Deserializer` passes to a `Visitor` implementation. /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed by deserialized map entries. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example implementation /// /// The [example data format] presented on the website demonstrates an /// implementation of `MapAccess` for a basic JSON data format. /// /// [example data format]: https://serde.rs/data-format.html pub trait MapAccess<'de> { /// The error type that can be returned if some error occurs during /// deserialization. type Error: Error; /// This returns `Ok(Some(key))` for the next key in the map, or `Ok(None)` /// if there are no more remaining entries. /// /// `Deserialize` implementations should typically use /// `MapAccess::next_key` or `MapAccess::next_entry` instead. fn next_key_seed<K>(&mut self, seed: K) -> Result<Option<K::Value>, Self::Error> where K: DeserializeSeed<'de>; /// This returns a `Ok(value)` for the next value in the map. /// /// `Deserialize` implementations should typically use /// `MapAccess::next_value` instead. /// /// # Panics /// /// Calling `next_value_seed` before `next_key_seed` is incorrect and is /// allowed to panic or return bogus results. fn next_value_seed<V>(&mut self, seed: V) -> Result<V::Value, Self::Error> where V: DeserializeSeed<'de>; /// This returns `Ok(Some((key, value)))` for the next (key-value) pair in /// the map, or `Ok(None)` if there are no more remaining items. /// /// `MapAccess` implementations should override the default behavior if a /// more efficient implementation is possible. /// /// `Deserialize` implementations should typically use /// `MapAccess::next_entry` instead. #[inline] fn next_entry_seed<K, V>( &mut self, kseed: K, vseed: V, ) -> Result<Option<(K::Value, V::Value)>, Self::Error> where K: DeserializeSeed<'de>, V: DeserializeSeed<'de>, { match try!(self.next_key_seed(kseed)) { Some(key) => { let value = try!(self.next_value_seed(vseed)); Ok(Some((key, value))) } None => Ok(None), } } /// This returns `Ok(Some(key))` for the next key in the map, or `Ok(None)` /// if there are no more remaining entries. /// /// This method exists as a convenience for `Deserialize` implementations. /// `MapAccess` implementations should not override the default behavior. #[inline] fn next_key<K>(&mut self) -> Result<Option<K>, Self::Error> where K: Deserialize<'de>, { self.next_key_seed(PhantomData) } /// This returns a `Ok(value)` for the next value in the map. /// /// This method exists as a convenience for `Deserialize` implementations. /// `MapAccess` implementations should not override the default behavior. /// /// # Panics /// /// Calling `next_value` before `next_key` is incorrect and is allowed to /// panic or return bogus results. #[inline] fn next_value<V>(&mut self) -> Result<V, Self::Error> where V: Deserialize<'de>, { self.next_value_seed(PhantomData) } /// This returns `Ok(Some((key, value)))` for the next (key-value) pair in /// the map, or `Ok(None)` if there are no more remaining items. /// /// This method exists as a convenience for `Deserialize` implementations. /// `MapAccess` implementations should not override the default behavior. #[inline] fn next_entry<K, V>(&mut self) -> Result<Option<(K, V)>, Self::Error> where K: Deserialize<'de>, V: Deserialize<'de>, { self.next_entry_seed(PhantomData, PhantomData) } /// Returns the number of entries remaining in the map, if known. #[inline] fn size_hint(&self) -> Option<usize> { None } } impl<'de, 'a, A> MapAccess<'de> for &'a mut A where A: MapAccess<'de>, { type Error = A::Error; #[inline] fn next_key_seed<K>(&mut self, seed: K) -> Result<Option<K::Value>, Self::Error> where K: DeserializeSeed<'de>, { (**self).next_key_seed(seed) } #[inline] fn next_value_seed<V>(&mut self, seed: V) -> Result<V::Value, Self::Error> where V: DeserializeSeed<'de>, { (**self).next_value_seed(seed) } #[inline] fn next_entry_seed<K, V>( &mut self, kseed: K, vseed: V, ) -> Result<Option<(K::Value, V::Value)>, Self::Error> where K: DeserializeSeed<'de>, V: DeserializeSeed<'de>, { (**self).next_entry_seed(kseed, vseed) } #[inline] fn next_entry<K, V>(&mut self) -> Result<Option<(K, V)>, Self::Error> where K: Deserialize<'de>, V: Deserialize<'de>, { (**self).next_entry() } #[inline] fn next_key<K>(&mut self) -> Result<Option<K>, Self::Error> where K: Deserialize<'de>, { (**self).next_key() } #[inline] fn next_value<V>(&mut self) -> Result<V, Self::Error> where V: Deserialize<'de>, { (**self).next_value() } #[inline] fn size_hint(&self) -> Option<usize> { (**self).size_hint() } } //////////////////////////////////////////////////////////////////////////////// /// Provides a `Visitor` access to the data of an enum in the input. /// /// `EnumAccess` is created by the `Deserializer` and passed to the /// `Visitor` in order to identify which variant of an enum to deserialize. /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed by the deserialized enum variant. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example implementation /// /// The [example data format] presented on the website demonstrates an /// implementation of `EnumAccess` for a basic JSON data format. /// /// [example data format]: https://serde.rs/data-format.html pub trait EnumAccess<'de>: Sized { /// The error type that can be returned if some error occurs during /// deserialization. type Error: Error; /// The `Visitor` that will be used to deserialize the content of the enum /// variant. type Variant: VariantAccess<'de, Error = Self::Error>; /// `variant` is called to identify which variant to deserialize. /// /// `Deserialize` implementations should typically use `EnumAccess::variant` /// instead. fn variant_seed<V>(self, seed: V) -> Result<(V::Value, Self::Variant), Self::Error> where V: DeserializeSeed<'de>; /// `variant` is called to identify which variant to deserialize. /// /// This method exists as a convenience for `Deserialize` implementations. /// `EnumAccess` implementations should not override the default behavior. #[inline] fn variant<V>(self) -> Result<(V, Self::Variant), Self::Error> where V: Deserialize<'de>, { self.variant_seed(PhantomData) } } /// `VariantAccess` is a visitor that is created by the `Deserializer` and /// passed to the `Deserialize` to deserialize the content of a particular enum /// variant. /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed by the deserialized enum variant. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example implementation /// /// The [example data format] presented on the website demonstrates an /// implementation of `VariantAccess` for a basic JSON data format. /// /// [example data format]: https://serde.rs/data-format.html pub trait VariantAccess<'de>: Sized { /// The error type that can be returned if some error occurs during /// deserialization. Must match the error type of our `EnumAccess`. type Error: Error; /// Called when deserializing a variant with no values. /// /// If the data contains a different type of variant, the following /// `invalid_type` error should be constructed: /// /// ```rust /// # use serde::de::{self, value, DeserializeSeed, Visitor, VariantAccess, Unexpected}; /// # /// # struct X; /// # /// # impl<'de> VariantAccess<'de> for X { /// # type Error = value::Error; /// # /// fn unit_variant(self) -> Result<(), Self::Error> { /// // What the data actually contained; suppose it is a tuple variant. /// let unexp = Unexpected::TupleVariant; /// Err(de::Error::invalid_type(unexp, &"unit variant")) /// } /// # /// # fn newtype_variant_seed<T>(self, _: T) -> Result<T::Value, Self::Error> /// # where /// # T: DeserializeSeed<'de>, /// # { unimplemented!() } /// # /// # fn tuple_variant<V>(self, _: usize, _: V) -> Result<V::Value, Self::Error> /// # where /// # V: Visitor<'de>, /// # { unimplemented!() } /// # /// # fn struct_variant<V>(self, _: &[&str], _: V) -> Result<V::Value, Self::Error> /// # where /// # V: Visitor<'de>, /// # { unimplemented!() } /// # } /// ``` fn unit_variant(self) -> Result<(), Self::Error>; /// Called when deserializing a variant with a single value. /// /// `Deserialize` implementations should typically use /// `VariantAccess::newtype_variant` instead. /// /// If the data contains a different type of variant, the following /// `invalid_type` error should be constructed: /// /// ```rust /// # use serde::de::{self, value, DeserializeSeed, Visitor, VariantAccess, Unexpected}; /// # /// # struct X; /// # /// # impl<'de> VariantAccess<'de> for X { /// # type Error = value::Error; /// # /// # fn unit_variant(self) -> Result<(), Self::Error> { /// # unimplemented!() /// # } /// # /// fn newtype_variant_seed<T>(self, _seed: T) -> Result<T::Value, Self::Error> /// where /// T: DeserializeSeed<'de>, /// { /// // What the data actually contained; suppose it is a unit variant. /// let unexp = Unexpected::UnitVariant; /// Err(de::Error::invalid_type(unexp, &"newtype variant")) /// } /// # /// # fn tuple_variant<V>(self, _: usize, _: V) -> Result<V::Value, Self::Error> /// # where /// # V: Visitor<'de>, /// # { unimplemented!() } /// # /// # fn struct_variant<V>(self, _: &[&str], _: V) -> Result<V::Value, Self::Error> /// # where /// # V: Visitor<'de>, /// # { unimplemented!() } /// # } /// ``` fn newtype_variant_seed<T>(self, seed: T) -> Result<T::Value, Self::Error> where T: DeserializeSeed<'de>; /// Called when deserializing a variant with a single value. /// /// This method exists as a convenience for `Deserialize` implementations. /// `VariantAccess` implementations should not override the default /// behavior. #[inline] fn newtype_variant<T>(self) -> Result<T, Self::Error> where T: Deserialize<'de>, { self.newtype_variant_seed(PhantomData) } /// Called when deserializing a tuple-like variant. /// /// The `len` is the number of fields expected in the tuple variant. /// /// If the data contains a different type of variant, the following /// `invalid_type` error should be constructed: /// /// ```rust /// # use serde::de::{self, value, DeserializeSeed, Visitor, VariantAccess, Unexpected}; /// # /// # struct X; /// # /// # impl<'de> VariantAccess<'de> for X { /// # type Error = value::Error; /// # /// # fn unit_variant(self) -> Result<(), Self::Error> { /// # unimplemented!() /// # } /// # /// # fn newtype_variant_seed<T>(self, _: T) -> Result<T::Value, Self::Error> /// # where /// # T: DeserializeSeed<'de>, /// # { unimplemented!() } /// # /// fn tuple_variant<V>( /// self, /// _len: usize, /// _visitor: V, /// ) -> Result<V::Value, Self::Error> /// where /// V: Visitor<'de>, /// { /// // What the data actually contained; suppose it is a unit variant. /// let unexp = Unexpected::UnitVariant; /// Err(de::Error::invalid_type(unexp, &"tuple variant")) /// } /// # /// # fn struct_variant<V>(self, _: &[&str], _: V) -> Result<V::Value, Self::Error> /// # where /// # V: Visitor<'de>, /// # { unimplemented!() } /// # } /// ``` fn tuple_variant<V>(self, len: usize, visitor: V) -> Result<V::Value, Self::Error> where V: Visitor<'de>; /// Called when deserializing a struct-like variant. /// /// The `fields` are the names of the fields of the struct variant. /// /// If the data contains a different type of variant, the following /// `invalid_type` error should be constructed: /// /// ```rust /// # use serde::de::{self, value, DeserializeSeed, Visitor, VariantAccess, Unexpected}; /// # /// # struct X; /// # /// # impl<'de> VariantAccess<'de> for X { /// # type Error = value::Error; /// # /// # fn unit_variant(self) -> Result<(), Self::Error> { /// # unimplemented!() /// # } /// # /// # fn newtype_variant_seed<T>(self, _: T) -> Result<T::Value, Self::Error> /// # where /// # T: DeserializeSeed<'de>, /// # { unimplemented!() } /// # /// # fn tuple_variant<V>(self, _: usize, _: V) -> Result<V::Value, Self::Error> /// # where /// # V: Visitor<'de>, /// # { unimplemented!() } /// # /// fn struct_variant<V>( /// self, /// _fields: &'static [&'static str], /// _visitor: V, /// ) -> Result<V::Value, Self::Error> /// where /// V: Visitor<'de>, /// { /// // What the data actually contained; suppose it is a unit variant. /// let unexp = Unexpected::UnitVariant; /// Err(de::Error::invalid_type(unexp, &"struct variant")) /// } /// # } /// ``` fn struct_variant<V>( self, fields: &'static [&'static str], visitor: V, ) -> Result<V::Value, Self::Error> where V: Visitor<'de>; } //////////////////////////////////////////////////////////////////////////////// /// Converts an existing value into a `Deserializer` from which other values can /// be deserialized. /// /// # Lifetime /// /// The `'de` lifetime of this trait is the lifetime of data that may be /// borrowed from the resulting `Deserializer`. See the page [Understanding /// deserializer lifetimes] for a more detailed explanation of these lifetimes. /// /// [Understanding deserializer lifetimes]: https://serde.rs/lifetimes.html /// /// # Example /// /// ```rust /// #[macro_use] /// extern crate serde_derive; /// /// extern crate serde; /// /// use std::str::FromStr; /// use serde::de::{value, Deserialize, IntoDeserializer}; /// /// #[derive(Deserialize)] /// enum Setting { /// On, /// Off, /// } /// /// impl FromStr for Setting { /// type Err = value::Error; /// /// fn from_str(s: &str) -> Result<Self, Self::Err> { /// Self::deserialize(s.into_deserializer()) /// } /// } /// # /// # fn main() {} /// ``` pub trait IntoDeserializer<'de, E: Error = value::Error> { /// The type of the deserializer being converted into. type Deserializer: Deserializer<'de, Error = E>; /// Convert this value into a deserializer. fn into_deserializer(self) -> Self::Deserializer; } //////////////////////////////////////////////////////////////////////////////// /// Used in error messages. /// /// - expected `a` /// - expected `a` or `b` /// - expected one of `a`, `b`, `c` /// /// The slice of names must not be empty. struct OneOf { names: &'static [&'static str], } impl Display for OneOf { fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { match self.names.len() { 0 => panic!(), // special case elsewhere 1 => write!(formatter, "`{}`", self.names[0]), 2 => write!(formatter, "`{}` or `{}`", self.names[0], self.names[1]), _ => { try!(write!(formatter, "one of ")); for (i, alt) in self.names.iter().enumerate() { if i > 0 { try!(write!(formatter, ", ")); } try!(write!(formatter, "`{}`", alt)); } Ok(()) } } } }