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//! 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 [derive 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 [`postcard`].
//!
//! 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\>
//! - Cow\<'a, T\>
//! - Cell\<T\>
//! - RefCell\<T\>
//! - Mutex\<T\>
//! - RwLock\<T\>
//! - Rc\<T\> *(if* features = \["rc"\] *is enabled)*
//! - Arc\<T\> *(if* features = \["rc"\] *is enabled)*
//! - **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\>
//! - RangeInclusive\<T\>
//! - Bound\<T\>
//! - num::NonZero*
//! - `!` *(unstable)*
//! - **Net types**:
//! - IpAddr
//! - Ipv4Addr
//! - Ipv6Addr
//! - SocketAddr
//! - SocketAddrV4
//! - SocketAddrV6
//!
//! [`Deserialize`]: ../trait.Deserialize.html
//! [`Deserializer`]: ../trait.Deserializer.html
//! [`LinkedHashMap<K, V>`]: https://docs.rs/linked-hash-map/*/linked_hash_map/struct.LinkedHashMap.html
use crate::lib::*;
////////////////////////////////////////////////////////////////////////////////
pub mod value;
mod ignored_any;
mod impls;
pub(crate) mod size_hint;
pub use self::ignored_any::IgnoredAny;
#[cfg(all(not(feature = "std"), no_core_error))]
#[doc(no_inline)]
pub use crate::std_error::Error as StdError;
#[cfg(not(any(feature = "std", no_core_error)))]
#[doc(no_inline)]
pub use core::error::Error as StdError;
#[cfg(feature = "std")]
#[doc(no_inline)]
pub use std::error::Error as StdError;
////////////////////////////////////////////////////////////////////////////////
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.
///
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.
///
/// ```edition2021
/// # 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 = 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 + StdError);
#[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.
///
/// ```edition2021
/// # 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) -> fmt::Result {
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 `{}`", WithDecimalPoint(f)),
Char(c) => write!(formatter, "character `{}`", c),
Str(s) => write!(formatter, "string {:?}", s),
Bytes(_) => formatter.write_str("byte array"),
Unit => formatter.write_str("unit value"),
Option => formatter.write_str("Option value"),
NewtypeStruct => formatter.write_str("newtype struct"),
Seq => formatter.write_str("sequence"),
Map => formatter.write_str("map"),
Enum => formatter.write_str("enum"),
UnitVariant => formatter.write_str("unit variant"),
NewtypeVariant => formatter.write_str("newtype variant"),
TupleVariant => formatter.write_str("tuple variant"),
StructVariant => formatter.write_str("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.
///
/// ```edition2021
/// # use serde::de::{self, Unexpected, Visitor};
/// # use std::fmt;
/// #
/// # 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.
///
/// ```edition2021
/// # 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][crate::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 [derive section of the manual][derive] 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.
///
///
/// # 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.
///
#[cfg_attr(
not(no_diagnostic_namespace),
diagnostic::on_unimplemented(
note = "for local types consider adding `#[derive(serde::Deserialize)]` to your `{Self}` type",
note = "for types from other crates check whether the crate offers a `serde` feature flag",
)
)]
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.
///
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 = tri!(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.
///
/// ```edition2021
/// # 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].
///
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:
///
/// ```edition2021
/// # 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:
///
/// ```edition2021
/// # 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.
///
///
/// # 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.
///
/// ```edition2021
/// use serde::de::{Deserialize, DeserializeSeed, Deserializer, SeqAccess, Visitor};
/// use std::fmt;
/// use std::marker::PhantomData;
///
/// // 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>,
/// {
/// // Decrease the number of reallocations if there are many elements
/// if let Some(size_hint) = seq.size_hint() {
/// self.0.reserve(size_hint);
/// }
///
/// // 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 `Deserializer` 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_any` 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
/// Postcard 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 Postcard and many
/// others.
///
///
/// # 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.
///
///
/// # Example implementation
///
/// The [example data format] presented on the website contains example code for
/// a basic JSON `Deserializer`.
///
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 Postcard 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>;
/// Hint that the `Deserialize` type is expecting an `i128` value.
///
/// 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>;
/// Hint that the `Deserialize` type is expecting an `u128` value.
///
/// 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,
/// indicate 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 Postcard will prefer the
/// compact one.
///
/// ```edition2021
/// # 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
}
// Not public API.
#[cfg(all(not(no_serde_derive), any(feature = "std", feature = "alloc")))]
#[doc(hidden)]
fn __deserialize_content<V>(
self,
_: crate::actually_private::T,
visitor: V,
) -> Result<crate::__private::de::Content<'de>, Self::Error>
where
V: Visitor<'de, Value = crate::__private::de::Content<'de>>,
{
self.deserialize_any(visitor)
}
}
////////////////////////////////////////////////////////////////////////////////
/// 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.
///
///
/// # Example
///
/// ```edition2021
/// # use serde::de::{self, Unexpected, Visitor};
/// # use std::fmt;
/// #
/// /// 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.
///
/// ```edition2021
/// # 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))
}
/// The input contains a `i128`.
///
/// The default implementation fails with a type error.
fn visit_i128<E>(self, v: i128) -> Result<Self::Value, E>
where
E: Error,
{
let mut buf = [0u8; 58];
let mut writer = crate::format::Buf::new(&mut buf);
fmt::Write::write_fmt(&mut writer, format_args!("integer `{}` as i128", v)).unwrap();
Err(Error::invalid_type(
Unexpected::Other(writer.as_str()),
&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))
}
/// The input contains a `u128`.
///
/// The default implementation fails with a type error.
fn visit_u128<E>(self, v: u128) -> Result<Self::Value, E>
where
E: Error,
{
let mut buf = [0u8; 57];
let mut writer = crate::format::Buf::new(&mut buf);
fmt::Write::write_fmt(&mut writer, format_args!("integer `{}` as u128", v)).unwrap();
Err(Error::invalid_type(
Unexpected::Other(writer.as_str()),
&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(v.encode_utf8(&mut [0u8; 4]))
}
/// 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"))]
#[cfg_attr(docsrs, doc(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,
{
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 Postcard 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"))]
#[cfg_attr(docsrs, doc(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.
///
///
/// # Example implementation
///
/// The [example data format] presented on the website demonstrates an
/// implementation of `SeqAccess` for a basic JSON data format.
///
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: ?Sized + 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.
///
///
/// # Example implementation
///
/// The [example data format] presented on the website demonstrates an
/// implementation of `MapAccess` for a basic JSON data format.
///
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 tri!(self.next_key_seed(kseed)) {
Some(key) => {
let value = tri!(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: ?Sized + 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.
///
///
/// # Example implementation
///
/// The [example data format] presented on the website demonstrates an
/// implementation of `EnumAccess` for a basic JSON data format.
///
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.
///
///
/// # Example implementation
///
/// The [example data format] presented on the website demonstrates an
/// implementation of `VariantAccess` for a basic JSON data format.
///
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:
///
/// ```edition2021
/// # 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:
///
/// ```edition2021
/// # 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:
///
/// ```edition2021
/// # 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:
///
/// ```edition2021
/// # 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.
///
///
/// # Example
///
/// ```edition2021
/// use serde::de::{value, Deserialize, IntoDeserializer};
/// use serde_derive::Deserialize;
/// use std::str::FromStr;
///
/// #[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())
/// }
/// }
/// ```
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]),
_ => {
tri!(formatter.write_str("one of "));
for (i, alt) in self.names.iter().enumerate() {
if i > 0 {
tri!(formatter.write_str(", "));
}
tri!(write!(formatter, "`{}`", alt));
}
Ok(())
}
}
}
}
struct WithDecimalPoint(f64);
impl Display for WithDecimalPoint {
fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
struct LookForDecimalPoint<'f, 'a> {
formatter: &'f mut fmt::Formatter<'a>,
has_decimal_point: bool,
}
impl<'f, 'a> fmt::Write for LookForDecimalPoint<'f, 'a> {
fn write_str(&mut self, fragment: &str) -> fmt::Result {
self.has_decimal_point |= fragment.contains('.');
self.formatter.write_str(fragment)
}
fn write_char(&mut self, ch: char) -> fmt::Result {
self.has_decimal_point |= ch == '.';
self.formatter.write_char(ch)
}
}
if self.0.is_finite() {
let mut writer = LookForDecimalPoint {
formatter,
has_decimal_point: false,
};
tri!(write!(writer, "{}", self.0));
if !writer.has_decimal_point {
tri!(formatter.write_str(".0"));
}
} else {
tri!(write!(formatter, "{}", self.0));
}
Ok(())
}
}