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// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// 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.
//! Support code for encoding and decoding types.
//!
//! In order to allow extensibility in both what types can be encoded and how
//! they are encoded, encoding and decoding are split into two part each. An
//! implementation of the Encodable trait knows how to turn a specific type into
//! a generic form, and then uses an implementation of the Encoder trait to turn
//! this into concrete output (such as a JSON string). Decoder and Decodable do
//! the same for decoding.
/*
Core encoding and decoding interfaces.
*/
use std::cell::{Cell, RefCell};
use std::ffi::OsString;
use std::path;
use std::rc::Rc;
use std::sync::Arc;
use std::marker::PhantomData;
use std::borrow::Cow;
use cap_capacity;
/// Trait for writing out an encoding when serializing.
///
/// This trait provides methods to encode basic types and generic forms of
/// collections. Implementations of `Encodable` use it to perform the actual
/// encoding of a type.
///
/// It is unspecified what is done with the encoding - it could be stored in a
/// variable, or written directly to a file, for example.
///
/// Encoders can expect to only have a single "root" method call made on this
/// trait. Non-trivial types will call one of the collection-emitting methods,
/// passing a function that may call other methods on the trait, but once the
/// collection-emitting method has returned, encoding should be complete.
pub trait Encoder {
/// The error type for method results.
type Error;
// Primitive types:
/// Emit a nil value.
///
/// For example, this might be stored as the null keyword in JSON.
fn emit_nil(&mut self) -> Result<(), Self::Error>;
/// Emit a usize value.
fn emit_usize(&mut self, v: usize) -> Result<(), Self::Error>;
/// Emit a u64 value.
fn emit_u64(&mut self, v: u64) -> Result<(), Self::Error>;
/// Emit a u32 value.
fn emit_u32(&mut self, v: u32) -> Result<(), Self::Error>;
/// Emit a u16 value.
fn emit_u16(&mut self, v: u16) -> Result<(), Self::Error>;
/// Emit a u8 value.
fn emit_u8(&mut self, v: u8) -> Result<(), Self::Error>;
/// Emit a isize value.
fn emit_isize(&mut self, v: isize) -> Result<(), Self::Error>;
/// Emit a i64 value.
fn emit_i64(&mut self, v: i64) -> Result<(), Self::Error>;
/// Emit a i32 value.
fn emit_i32(&mut self, v: i32) -> Result<(), Self::Error>;
/// Emit a i16 value.
fn emit_i16(&mut self, v: i16) -> Result<(), Self::Error>;
/// Emit a i8 value.
fn emit_i8(&mut self, v: i8) -> Result<(), Self::Error>;
/// Emit a bool value.
///
/// For example, this might be stored as the true and false keywords in
/// JSON.
fn emit_bool(&mut self, v: bool) -> Result<(), Self::Error>;
/// Emit a f64 value.
fn emit_f64(&mut self, v: f64) -> Result<(), Self::Error>;
/// Emit a f32 value.
fn emit_f32(&mut self, v: f32) -> Result<(), Self::Error>;
/// Emit a char value.
///
/// Note that strings should be emitted using `emit_str`, not as a sequence
/// of `emit_char` calls.
fn emit_char(&mut self, v: char) -> Result<(), Self::Error>;
/// Emit a string value.
fn emit_str(&mut self, v: &str) -> Result<(), Self::Error>;
// Compound types:
/// Emit an enumeration value.
///
/// * `name` indicates the enumeration type name.
/// * `f` is a function that will call `emit_enum_variant` or
/// `emit_enum_struct_variant` as appropriate to write the actual value.
fn emit_enum<F>(&mut self, name: &str, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a enumeration variant value with no or unnamed data.
///
/// This should only be called from a function passed to `emit_enum`.
/// Variants with named data should use `emit_enum_struct_variant`.
///
/// * `v_name` is the variant name
/// * `v_id` is the numeric identifier for the variant.
/// * `len` is the number of data items associated with the variant.
/// * `f` is a function that will call `emit_enum_variant_arg` for each data
/// item. It may not be called if len is 0.
///
/// # Examples
///
/// ```
/// use rustc_serialize::Encodable;
/// use rustc_serialize::Encoder;
///
/// enum Message {
/// Quit,
/// ChangeColor(i32, i32, i32),
/// }
///
/// impl Encodable for Message {
/// fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
/// s.emit_enum("Message", |s| {
/// match *self {
/// Message::Quit => {
/// s.emit_enum_variant("Quit", 0, 0, |s| Ok(()))
/// }
/// Message::ChangeColor(r, g, b) => {
/// s.emit_enum_variant("ChangeColor", 1, 3, |s| {
/// try!(s.emit_enum_variant_arg(0, |s| {
/// s.emit_i32(r)
/// }));
/// try!(s.emit_enum_variant_arg(1, |s| {
/// s.emit_i32(g)
/// }));
/// try!(s.emit_enum_variant_arg(2, |s| {
/// s.emit_i32(b)
/// }));
/// Ok(())
/// })
/// }
/// }
/// })
/// }
/// }
/// ```
fn emit_enum_variant<F>(&mut self, v_name: &str,
v_id: usize,
len: usize,
f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit an unnamed data item for an enumeration variant.
///
/// This should only be called from a function passed to
/// `emit_enum_variant`.
///
/// * `a_idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate emit method to encode
/// the data object.
///
/// Note that variant data items must be emitted in order - starting with
/// index `0` and finishing with index `len-1`.
fn emit_enum_variant_arg<F>(&mut self, a_idx: usize, f: F)
-> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a enumeration variant value with no or named data.
///
/// This should only be called from a function passed to `emit_enum`.
/// Variants with unnamed data should use `emit_enum_variant`.
///
/// * `v_name` is the variant name.
/// * `v_id` is the numeric identifier for the variant.
/// * `len` is the number of data items associated with the variant.
/// * `f` is a function that will call `emit_enum_struct_variant_field` for
/// each data item. It may not be called if `len` is `0`.
///
/// # Examples
///
/// ```
/// use rustc_serialize::Encodable;
/// use rustc_serialize::Encoder;
///
/// enum Message {
/// Quit,
/// Move { x: i32, y: i32 },
/// }
///
/// impl Encodable for Message {
/// fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
/// s.emit_enum("Message", |s| {
/// match *self {
/// Message::Quit => {
/// s.emit_enum_struct_variant("Quit", 0, 0, |s| Ok(()))
/// }
/// Message::Move { x: x, y: y } => {
/// s.emit_enum_struct_variant("Move", 1, 2, |s| {
/// try!(s.emit_enum_struct_variant_field("x", 0, |s| {
/// s.emit_i32(x)
/// }));
/// try!(s.emit_enum_struct_variant_field("y", 1, |s| {
/// s.emit_i32(y)
/// }));
/// Ok(())
/// })
/// }
/// }
/// })
/// }
/// }
/// ```
fn emit_enum_struct_variant<F>(&mut self, v_name: &str,
v_id: usize,
len: usize,
f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a named data item for an enumeration variant.
///
/// This should only be called from a function passed to
/// `emit_enum_struct_variant`.
///
/// * `f_name` is the name of the data item field.
/// * `f_idx` is its (zero-based) index.
/// * `f` is a function that will call the appropriate emit method to encode
/// the data object.
///
/// Note that fields must be emitted in order - starting with index `0` and
/// finishing with index `len-1`.
fn emit_enum_struct_variant_field<F>(&mut self,
f_name: &str,
f_idx: usize,
f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a struct value.
///
/// * `name` is the name of the struct.
/// * `len` is the number of members.
/// * `f` is a function that calls `emit_struct_field` for each member.
///
/// # Examples
///
/// ```
/// use rustc_serialize::Encodable;
/// use rustc_serialize::Encoder;
///
/// struct Point {
/// x: i32,
/// y: i32,
/// }
///
/// impl Encodable for Point {
/// fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
/// s.emit_struct("Point", 2, |s| {
/// try!(s.emit_struct_field("x", 0, |s| {
/// s.emit_i32(self.x)
/// }));
/// try!(s.emit_struct_field("y", 1, |s| {
/// s.emit_i32(self.y)
/// }));
/// Ok(())
/// })
/// }
/// }
/// ```
fn emit_struct<F>(&mut self, name: &str, len: usize, f: F)
-> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a field item for a struct.
///
/// This should only be called from a function passed to `emit_struct`.
///
/// * `f_name` is the name of the data item field.
/// * `f_idx` is its (zero-based) index.
/// * `f` is a function that will call the appropriate emit method to encode
/// the data object.
///
/// Note that fields must be emitted in order - starting with index `0` and
/// finishing with index `len-1`.
fn emit_struct_field<F>(&mut self, f_name: &str, f_idx: usize, f: F)
-> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a tuple value.
///
/// * `len` is the number of items in the tuple.
/// * `f` is a function that calls `emit_tuple_arg` for each member.
///
/// Note that external `Encodable` implementations should not normally need
/// to use this method directly; it is meant for the use of this module's
/// own implementation of `Encodable` for tuples.
fn emit_tuple<F>(&mut self, len: usize, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a data item for a tuple.
///
/// This should only be called from a function passed to `emit_tuple`.
///
/// * `idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate emit method to encode
/// the data object.
///
/// Note that tuple items must be emitted in order - starting with index `0`
/// and finishing with index `len-1`.
fn emit_tuple_arg<F>(&mut self, idx: usize, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a tuple struct value.
///
/// * `name` is the name of the tuple struct.
/// * `len` is the number of items in the tuple struct.
/// * `f` is a function that calls `emit_tuple_struct_arg` for each member.
///
/// # Examples
///
/// ```
/// use rustc_serialize::Encodable;
/// use rustc_serialize::Encoder;
///
/// struct Pair(i32,i32);
///
/// impl Encodable for Pair {
/// fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
/// let Pair(first,second) = *self;
/// s.emit_tuple_struct("Pair", 2, |s| {
/// try!(s.emit_tuple_arg(0, |s| {
/// s.emit_i32(first)
/// }));
/// try!(s.emit_tuple_arg(1, |s| {
/// s.emit_i32(second)
/// }));
/// Ok(())
/// })
/// }
/// }
/// ```
fn emit_tuple_struct<F>(&mut self, name: &str, len: usize, f: F)
-> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a data item for a tuple struct.
///
/// This should only be called from a function passed to
/// `emit_tuple_struct`.
///
/// * `f_idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate emit method to encode
/// the data object.
///
/// Note that tuple items must be emitted in order - starting with index `0`
/// and finishing with index `len-1`.
fn emit_tuple_struct_arg<F>(&mut self, f_idx: usize, f: F)
-> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
// Specialized types:
/// Emit an optional value.
///
/// `f` is a function that will call either `emit_option_none` or
/// `emit_option_some` as appropriate.
///
/// This method allows encoders to handle `Option<T>` values specially,
/// rather than using the generic enum methods, because many encoding
/// formats have a built-in "optional" concept.
///
/// Note that external `Encodable` implementations should not normally need
/// to use this method directly; it is meant for the use of this module's
/// own implementation of `Encodable` for `Option<T>`.
fn emit_option<F>(&mut self, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit the `None` optional value.
///
/// This should only be called from a function passed to `emit_option`.
fn emit_option_none(&mut self) -> Result<(), Self::Error>;
/// Emit the `Some(x)` optional value.
///
/// `f` is a function that will call the appropriate emit method to encode
/// the data object.
///
/// This should only be called from a function passed to `emit_option`.
fn emit_option_some<F>(&mut self, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit a sequence of values.
///
/// This should be used for both array-like ordered sequences and set-like
/// unordered ones.
///
/// * `len` is the number of values in the sequence.
/// * `f` is a function that will call `emit_seq_elt` for each value in the
/// sequence.
fn emit_seq<F>(&mut self, len: usize, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit an element in a sequence.
///
/// This should only be called from a function passed to `emit_seq`.
///
/// * `idx` is the (zero-based) index of the value in the sequence.
/// * `f` is a function that will call the appropriate emit method to encode
/// the data object.
///
/// Note that sequence elements must be emitted in order - starting with
/// index `0` and finishing with index `len-1`.
fn emit_seq_elt<F>(&mut self, idx: usize, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit an associative container (map).
///
/// * `len` is the number of entries in the map.
/// * `f` is a function that will call `emit_map_elt_key` and
/// `emit_map_elt_val` for each entry in the map.
///
/// # Examples
///
/// ```
/// use rustc_serialize::Encodable;
/// use rustc_serialize::Encoder;
///
/// struct SimpleMap<K,V> {
/// entries: Vec<(K,V)>,
/// }
///
/// impl<K:Encodable,V:Encodable> Encodable for SimpleMap<K,V> {
/// fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
/// s.emit_map(self.entries.len(), |s| {
/// for (i, e) in self.entries.iter().enumerate() {
/// let (ref k, ref v) = *e;
/// try!(s.emit_map_elt_key(i, |s| k.encode(s)));
/// try!(s.emit_map_elt_val(i, |s| v.encode(s)));
/// }
/// Ok(())
/// })
/// }
/// }
/// ```
fn emit_map<F>(&mut self, len: usize, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit the key for an entry in a map.
///
/// This should only be called from a function passed to `emit_map`.
///
/// * `idx` is the (zero-based) index of the entry in the map
/// * `f` is a function that will call the appropriate emit method to encode
/// the key.
///
/// Note that map entries must be emitted in order - starting with index `0`
/// and finishing with index `len-1` - and for each entry, the key should be
/// emitted followed immediately by the value.
fn emit_map_elt_key<F>(&mut self, idx: usize, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
/// Emit the value for an entry in a map.
///
/// This should only be called from a function passed to `emit_map`.
///
/// * `idx` is the (zero-based) index of the entry in the map
/// * `f` is a function that will call the appropriate emit method to encode
/// the value.
///
/// Note that map entries must be emitted in order - starting with index `0`
/// and finishing with index `len-1` - and for each entry, the key should be
/// emitted followed immediately by the value.
fn emit_map_elt_val<F>(&mut self, idx: usize, f: F) -> Result<(), Self::Error>
where F: FnOnce(&mut Self) -> Result<(), Self::Error>;
}
/// Trait for reading in an encoding for deserialization.
///
/// This trait provides methods to decode basic types and generic forms of
/// collections. Implementations of `Decodable` use it to perform the actual
/// decoding of a type.
///
/// Note that, as is typical with deserialization, the design of this API
/// assumes you know in advance the form of the data you are decoding (ie: what
/// type is encoded).
///
/// Decoders can expect to only have a single "root" method call made on this
/// trait. Non-trivial types will call one of the collection-reading methods,
/// passing a function that may call other methods on the trait, but once the
/// collection-reading method has returned, decoding should be complete.
pub trait Decoder {
/// The error type for method results.
type Error;
// Primitive types:
/// Read a nil value.
fn read_nil(&mut self) -> Result<(), Self::Error>;
/// Read a usize value.
fn read_usize(&mut self) -> Result<usize, Self::Error>;
/// Read a u64 value.
fn read_u64(&mut self) -> Result<u64, Self::Error>;
/// Read a u32 value.
fn read_u32(&mut self) -> Result<u32, Self::Error>;
/// Read a u16 value.
fn read_u16(&mut self) -> Result<u16, Self::Error>;
/// Read a u8 value.
fn read_u8(&mut self) -> Result<u8, Self::Error>;
/// Read a isize value.
fn read_isize(&mut self) -> Result<isize, Self::Error>;
/// Read a i64 value.
fn read_i64(&mut self) -> Result<i64, Self::Error>;
/// Read a i32 value.
fn read_i32(&mut self) -> Result<i32, Self::Error>;
/// Read a i16 value.
fn read_i16(&mut self) -> Result<i16, Self::Error>;
/// Read a i8 value.
fn read_i8(&mut self) -> Result<i8, Self::Error>;
/// Read a bool value.
fn read_bool(&mut self) -> Result<bool, Self::Error>;
/// Read a f64 value.
fn read_f64(&mut self) -> Result<f64, Self::Error>;
/// Read a f32 value.
fn read_f32(&mut self) -> Result<f32, Self::Error>;
/// Read a char value.
fn read_char(&mut self) -> Result<char, Self::Error>;
/// Read a string value.
fn read_str(&mut self) -> Result<String, Self::Error>;
// Compound types:
/// Read an enumeration value.
///
/// * `name` indicates the enumeration type name. It may be used to
/// sanity-check the data being read.
/// * `f` is a function that will call `read_enum_variant` (or
/// `read_enum_struct_variant`) to read the actual value.
fn read_enum<T, F>(&mut self, name: &str, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read an enumeration value.
///
/// * `names` is a list of the enumeration variant names.
/// * `f` is a function that will call `read_enum_variant_arg` or
/// `read_enum_struct_variant_field` as appropriate to read the
/// associated values. It will be passed the index into `names` for the
/// variant that is encoded.
fn read_enum_variant<T, F>(&mut self, names: &[&str], f: F)
-> Result<T, Self::Error>
where F: FnMut(&mut Self, usize) -> Result<T, Self::Error>;
/// Read an unnamed data item for an enumeration variant.
///
/// This should only be called from a function passed to `read_enum_variant`
/// or `read_enum_struct_variant`, and only when the index provided to that
/// function indicates that the variant has associated unnamed data. It
/// should be called once for each associated data item.
///
/// * `a_idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate read method to deocde
/// the data object.
///
/// Note that variant data items must be read in order - starting with index
/// `0` and finishing with index `len-1`. Implementations may use `a_idx`,
/// the call order or both to select the correct data to decode.
fn read_enum_variant_arg<T, F>(&mut self, a_idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read an enumeration value.
///
/// This is identical to `read_enum_variant`, and is only provided for
/// symmetry with the `Encoder` API.
fn read_enum_struct_variant<T, F>(&mut self, names: &[&str], f: F)
-> Result<T, Self::Error>
where F: FnMut(&mut Self, usize) -> Result<T, Self::Error>;
/// Read a named data item for an enumeration variant.
///
/// This should only be called from a function passed to `read_enum_variant`
/// or `read_enum_struct_variant`, and only when the index provided to that
/// function indicates that the variant has associated named data. It should
/// be called once for each associated field.
///
/// * `f_name` is the name of the field.
/// * `f_idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate read method to deocde
/// the data object.
///
/// Note that fields must be read in order - starting with index `0` and
/// finishing with index `len-1`. Implementations may use `f_idx`, `f_name`,
/// the call order or any combination to choose the correct data to decode,
/// and may (but are not required to) return an error if these are
/// inconsistent.
fn read_enum_struct_variant_field<T, F>(&mut self,
f_name: &str,
f_idx: usize,
f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read an struct value.
///
/// * `s_name` indicates the struct type name. It may be used to
/// sanity-check the data being read.
/// * `len` indicates the number of fields in the struct.
/// * `f` is a function that will call `read_struct_field` for each field in
/// the struct.
fn read_struct<T, F>(&mut self, s_name: &str, len: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read a field for a struct value.
///
/// This should only be called from a function passed to `read_struct`. It
/// should be called once for each associated field.
///
/// * `f_name` is the name of the field.
/// * `f_idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate read method to deocde
/// the data object.
///
/// Note that fields must be read in order - starting with index `0` and
/// finishing with index `len-1`. Implementations may use `f_idx`, `f_name`,
/// the call order or any combination to choose the correct data to decode,
/// and may (but are not required to) return an error if these are
/// inconsistent.
fn read_struct_field<T, F>(&mut self,
f_name: &str,
f_idx: usize,
f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read a tuple value.
///
/// * `len` is the number of items in the tuple.
/// * `f` is a function that will call `read_tuple_arg` for each item in the
/// tuple.
///
/// Note that external `Decodable` implementations should not normally need
/// to use this method directly; it is meant for the use of this module's
/// own implementation of `Decodable` for tuples.
fn read_tuple<T, F>(&mut self, len: usize, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read a data item for a tuple.
///
/// This should only be called from a function passed to `read_tuple`.
///
/// * `a_idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate read method to encode
/// the data object.
///
/// Note that tuple items must be read in order - starting with index `0`
/// and finishing with index `len-1`.
fn read_tuple_arg<T, F>(&mut self, a_idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read a tuple struct value.
///
/// * `s_name` is the name of the tuple struct.
/// * `len` is the number of items in the tuple struct.
/// * `f` is a function that calls `read_tuple_struct_arg` for each member.
fn read_tuple_struct<T, F>(&mut self, s_name: &str, len: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read a data item for a tuple struct.
///
/// This should only be called from a function passed to
/// `read_tuple_struct`.
///
/// * `a_idx` is the (zero-based) index of the data item.
/// * `f` is a function that will call the appropriate read method to encode
/// the data object.
///
/// Note that tuple struct items must be read in order - starting with index
/// `0` and finishing with index `len-1`.
fn read_tuple_struct_arg<T, F>(&mut self, a_idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
// Specialized types:
/// Read an optional value.
///
/// `f` is a function that will will be passed be passed `false` if the
/// value is unset, and `true` if it is set. If the function is passed
/// `true`, it will call the appropriate read methods to read the associated
/// data type.
///
/// This method allows decoders to handle `Option<T>` values specially,
/// rather than using the generic enum methods, because many encoding
/// formats have a built-in "optional" concept.
///
/// Note that external `Decodable` implementations should not normally need
/// to use this method directly; it is meant for the use of this module's
/// own implementation of `Decodable` for `Option<T>`.
fn read_option<T, F>(&mut self, f: F) -> Result<T, Self::Error>
where F: FnMut(&mut Self, bool) -> Result<T, Self::Error>;
/// Read a sequence of values.
///
/// This should be used for both array-like ordered sequences and set-like
/// unordered ones.
///
/// * `f` is a function that will be passed the length of the sequence, and
/// will call `read_seq_elt` for each value in the sequence.
fn read_seq<T, F>(&mut self, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self, usize) -> Result<T, Self::Error>;
/// Read an element in the sequence.
///
/// This should only be called from a function passed to `read_seq`.
///
/// * `idx` is the (zero-based) index of the value in the sequence.
/// * `f` is a function that will call the appropriate read method to decode
/// the data object.
///
/// Note that sequence elements must be read in order - starting with index
/// `0` and finishing with index `len-1`.
fn read_seq_elt<T, F>(&mut self, idx: usize, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read an associative container (map).
///
/// * `f` is a function that will be passed the number of entries in the
/// map, and will call `read_map_elt_key` and `read_map_elt_val` to decode
/// each entry.
fn read_map<T, F>(&mut self, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self, usize) -> Result<T, Self::Error>;
/// Read the key for an entry in a map.
///
/// This should only be called from a function passed to `read_map`.
///
/// * `idx` is the (zero-based) index of the entry in the map
/// * `f` is a function that will call the appropriate read method to decode
/// the key.
///
/// Note that map entries must be read in order - starting with index `0`
/// and finishing with index `len-1` - and for each entry, the key should be
/// read followed immediately by the value.
fn read_map_elt_key<T, F>(&mut self, idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
/// Read the value for an entry in a map.
///
/// This should only be called from a function passed to `read_map`.
///
/// * `idx` is the (zero-based) index of the entry in the map
/// * `f` is a function that will call the appropriate read method to decode
/// the value.
///
/// Note that map entries must be read in order - starting with index `0`
/// and finishing with index `len-1` - and for each entry, the key should be
/// read followed immediately by the value.
fn read_map_elt_val<T, F>(&mut self, idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error>;
// Failure
/// Record a decoding error.
///
/// This allows `Decodable` implementations to report an error using a
/// `Decoder` implementation's error type when inconsistent data is read.
/// For example, when reading a fixed-length array and the wrong length is
/// given by `read_seq`.
fn error(&mut self, err: &str) -> Self::Error;
}
/// Trait for serializing a type.
///
/// This can be implemented for custom data types to allow them to be encoded
/// with `Encoder` implementations. Most of Rust's built-in or standard data
/// types (like `i32` and `Vec<T>`) have `Encodable` implementations provided by
/// this module.
///
/// Note that, in general, you should let the compiler implement this for you by
/// using the `derive(RustcEncodable)` attribute.
///
/// # Examples
///
/// ```rust
/// extern crate rustc_serialize;
///
/// #[derive(RustcEncodable)]
/// struct Point {
/// x: i32,
/// y: i32,
/// }
/// # fn main() {}
/// ```
///
/// This generates code equivalent to:
///
/// ```rust
/// extern crate rustc_serialize;
/// use rustc_serialize::Encodable;
/// use rustc_serialize::Encoder;
///
/// struct Point {
/// x: i32,
/// y: i32,
/// }
///
/// impl Encodable for Point {
/// fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
/// s.emit_struct("Point", 2, |s| {
/// try!(s.emit_struct_field("x", 0, |s| {
/// s.emit_i32(self.x)
/// }));
/// try!(s.emit_struct_field("y", 1, |s| {
/// s.emit_i32(self.y)
/// }));
/// Ok(())
/// })
/// }
/// }
/// # fn main() {}
/// ```
pub trait Encodable {
/// Serialize a value using an `Encoder`.
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error>;
}
/// Trait for deserializing a type.
///
/// This can be implemented for custom data types to allow them to be decoded
/// with `Decoder` implementations. Most of Rust's built-in or standard data
/// types (like `i32` and `Vec<T>`) have `Decodable` implementations provided by
/// this module.
///
/// Note that, in general, you should let the compiler implement this for you by
/// using the `derive(RustcDecodable)` attribute.
///
/// # Examples
///
/// ```rust
/// extern crate rustc_serialize;
///
/// #[derive(RustcDecodable)]
/// struct Point {
/// x: i32,
/// y: i32,
/// }
/// # fn main() {}
/// ```
///
/// This generates code equivalent to:
///
/// ```rust
/// extern crate rustc_serialize;
/// use rustc_serialize::Decodable;
/// use rustc_serialize::Decoder;
///
/// struct Point {
/// x: i32,
/// y: i32,
/// }
///
/// impl Decodable for Point {
/// fn decode<D: Decoder>(d: &mut D) -> Result<Point, D::Error> {
/// d.read_struct("Point", 2, |d| {
/// let x = try!(d.read_struct_field("x", 0, |d| { d.read_i32() }));
/// let y = try!(d.read_struct_field("y", 1, |d| { d.read_i32() }));
/// Ok(Point{ x: x, y: y })
/// })
/// }
/// }
/// # fn main() {}
/// ```
pub trait Decodable: Sized {
/// Deserialize a value using a `Decoder`.
fn decode<D: Decoder>(d: &mut D) -> Result<Self, D::Error>;
}
impl Encodable for usize {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_usize(*self)
}
}
impl Decodable for usize {
fn decode<D: Decoder>(d: &mut D) -> Result<usize, D::Error> {
d.read_usize()
}
}
impl Encodable for u8 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_u8(*self)
}
}
impl Decodable for u8 {
fn decode<D: Decoder>(d: &mut D) -> Result<u8, D::Error> {
d.read_u8()
}
}
impl Encodable for u16 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_u16(*self)
}
}
impl Decodable for u16 {
fn decode<D: Decoder>(d: &mut D) -> Result<u16, D::Error> {
d.read_u16()
}
}
impl Encodable for u32 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_u32(*self)
}
}
impl Decodable for u32 {
fn decode<D: Decoder>(d: &mut D) -> Result<u32, D::Error> {
d.read_u32()
}
}
impl Encodable for u64 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_u64(*self)
}
}
impl Decodable for u64 {
fn decode<D: Decoder>(d: &mut D) -> Result<u64, D::Error> {
d.read_u64()
}
}
impl Encodable for isize {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_isize(*self)
}
}
impl Decodable for isize {
fn decode<D: Decoder>(d: &mut D) -> Result<isize, D::Error> {
d.read_isize()
}
}
impl Encodable for i8 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_i8(*self)
}
}
impl Decodable for i8 {
fn decode<D: Decoder>(d: &mut D) -> Result<i8, D::Error> {
d.read_i8()
}
}
impl Encodable for i16 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_i16(*self)
}
}
impl Decodable for i16 {
fn decode<D: Decoder>(d: &mut D) -> Result<i16, D::Error> {
d.read_i16()
}
}
impl Encodable for i32 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_i32(*self)
}
}
impl Decodable for i32 {
fn decode<D: Decoder>(d: &mut D) -> Result<i32, D::Error> {
d.read_i32()
}
}
impl Encodable for i64 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_i64(*self)
}
}
impl Decodable for i64 {
fn decode<D: Decoder>(d: &mut D) -> Result<i64, D::Error> {
d.read_i64()
}
}
impl Encodable for str {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_str(self)
}
}
impl Encodable for String {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_str(self)
}
}
impl Decodable for String {
fn decode<D: Decoder>(d: &mut D) -> Result<String, D::Error> {
d.read_str()
}
}
impl Encodable for f32 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_f32(*self)
}
}
impl Decodable for f32 {
fn decode<D: Decoder>(d: &mut D) -> Result<f32, D::Error> {
d.read_f32()
}
}
impl Encodable for f64 {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_f64(*self)
}
}
impl Decodable for f64 {
fn decode<D: Decoder>(d: &mut D) -> Result<f64, D::Error> {
d.read_f64()
}
}
impl Encodable for bool {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_bool(*self)
}
}
impl Decodable for bool {
fn decode<D: Decoder>(d: &mut D) -> Result<bool, D::Error> {
d.read_bool()
}
}
impl Encodable for char {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_char(*self)
}
}
impl Decodable for char {
fn decode<D: Decoder>(d: &mut D) -> Result<char, D::Error> {
d.read_char()
}
}
impl Encodable for () {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_nil()
}
}
impl Decodable for () {
fn decode<D: Decoder>(d: &mut D) -> Result<(), D::Error> {
d.read_nil()
}
}
impl<'a, T: ?Sized + Encodable> Encodable for &'a T {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
(**self).encode(s)
}
}
impl<T: ?Sized + Encodable> Encodable for Box<T> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
(**self).encode(s)
}
}
impl< T: Decodable> Decodable for Box<T> {
fn decode<D: Decoder>(d: &mut D) -> Result<Box<T>, D::Error> {
Ok(Box::new(try!(Decodable::decode(d))))
}
}
impl< T: Decodable> Decodable for Box<[T]> {
fn decode<D: Decoder>(d: &mut D) -> Result<Box<[T]>, D::Error> {
let v: Vec<T> = try!(Decodable::decode(d));
Ok(v.into_boxed_slice())
}
}
impl<T:Encodable> Encodable for Rc<T> {
#[inline]
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
(**self).encode(s)
}
}
impl<T:Decodable> Decodable for Rc<T> {
#[inline]
fn decode<D: Decoder>(d: &mut D) -> Result<Rc<T>, D::Error> {
Ok(Rc::new(try!(Decodable::decode(d))))
}
}
impl<'a, T:Encodable + ToOwned + ?Sized> Encodable for Cow<'a, T> {
#[inline]
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
(**self).encode(s)
}
}
impl<'a, T: ?Sized> Decodable for Cow<'a, T>
where T: ToOwned, T::Owned: Decodable
{
#[inline]
fn decode<D: Decoder>(d: &mut D) -> Result<Cow<'a, T>, D::Error> {
Ok(Cow::Owned(try!(Decodable::decode(d))))
}
}
impl<T:Encodable> Encodable for [T] {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_seq(self.len(), |s| {
for (i, e) in self.iter().enumerate() {
try!(s.emit_seq_elt(i, |s| e.encode(s)))
}
Ok(())
})
}
}
impl<T:Encodable> Encodable for Vec<T> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_seq(self.len(), |s| {
for (i, e) in self.iter().enumerate() {
try!(s.emit_seq_elt(i, |s| e.encode(s)))
}
Ok(())
})
}
}
impl<T:Decodable> Decodable for Vec<T> {
fn decode<D: Decoder>(d: &mut D) -> Result<Vec<T>, D::Error> {
d.read_seq(|d, len| {
let mut v = Vec::with_capacity(cap_capacity::<T>(len));
for i in 0..len {
v.push(try!(d.read_seq_elt(i, |d| Decodable::decode(d))));
}
Ok(v)
})
}
}
impl<T:Encodable> Encodable for Option<T> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_option(|s| {
match *self {
None => s.emit_option_none(),
Some(ref v) => s.emit_option_some(|s| v.encode(s)),
}
})
}
}
impl<T:Decodable> Decodable for Option<T> {
fn decode<D: Decoder>(d: &mut D) -> Result<Option<T>, D::Error> {
d.read_option(|d, b| {
if b {
Ok(Some(try!(Decodable::decode(d))))
} else {
Ok(None)
}
})
}
}
impl<T:Encodable, E:Encodable> Encodable for Result<T, E> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_enum("Result", |s| {
match *self {
Ok(ref v) => {
s.emit_enum_variant("Ok", 0, 1, |s| {
try!(s.emit_enum_variant_arg(0, |s| {
v.encode(s)
}));
Ok(())
})
}
Err(ref v) => {
s.emit_enum_variant("Err", 1, 1, |s| {
try!(s.emit_enum_variant_arg(0, |s| {
v.encode(s)
}));
Ok(())
})
}
}
})
}
}
impl<T: Decodable, E: Decodable> Decodable for Result<T, E> {
fn decode<D: Decoder>(d: &mut D) -> Result<Result<T, E>, D::Error> {
d.read_enum("Result", |d| {
d.read_enum_variant(&["Ok", "Err"], |d, idx| {
match idx {
0 => {
d.read_enum_variant_arg(0, |d| {
T::decode(d)
}).map(|v| Ok(v))
}
1 => {
d.read_enum_variant_arg(0, |d| {
E::decode(d)
}).map(|v| Err(v))
}
_ => panic!("Internal error"),
}
})
})
}
}
impl<T> Encodable for PhantomData<T> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_nil()
}
}
impl<T> Decodable for PhantomData<T> {
fn decode<D: Decoder>(_d: &mut D) -> Result<PhantomData<T>, D::Error> {
Ok(PhantomData)
}
}
macro_rules! peel {
($name:ident, $($other:ident,)*) => (tuple! { $($other,)* })
}
/// Evaluates to the number of identifiers passed to it, for example:
/// `count_idents!(a, b, c) == 3
macro_rules! count_idents {
() => { 0 };
($_i:ident, $($rest:ident,)*) => { 1 + count_idents!($($rest,)*) }
}
macro_rules! tuple {
() => ();
( $($name:ident,)+ ) => (
impl<$($name:Decodable),*> Decodable for ($($name,)*) {
fn decode<D: Decoder>(d: &mut D) -> Result<($($name,)*), D::Error> {
let len: usize = count_idents!($($name,)*);
d.read_tuple(len, |d| {
let mut i = 0;
let ret = ($(try!(d.read_tuple_arg({ i+=1; i-1 },
|d| -> Result<$name,D::Error> {
Decodable::decode(d)
})),)*);
return Ok(ret);
})
}
}
impl<$($name:Encodable),*> Encodable for ($($name,)*) {
#[allow(non_snake_case)]
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
let ($(ref $name,)*) = *self;
let mut n = 0;
$(let $name = $name; n += 1;)*
s.emit_tuple(n, |s| {
let mut i = 0;
$(try!(s.emit_tuple_arg({ i+=1; i-1 }, |s| $name.encode(s)));)*
Ok(())
})
}
}
peel! { $($name,)* }
)
}
tuple! { T0, T1, T2, T3, T4, T5, T6, T7, T8, T9, T10, T11, }
macro_rules! array {
() => ();
($len:expr, $($idx:expr,)*) => {
impl<T:Decodable> Decodable for [T; $len] {
fn decode<D: Decoder>(d: &mut D) -> Result<[T; $len], D::Error> {
d.read_seq(|d, len| {
if len != $len {
return Err(d.error("wrong array length"));
}
Ok([$(
try!(d.read_seq_elt($len - $idx - 1,
|d| Decodable::decode(d)))
),*])
})
}
}
impl<T:Encodable> Encodable for [T; $len] {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
s.emit_seq($len, |s| {
for i in 0..$len {
try!(s.emit_seq_elt(i, |s| self[i].encode(s)));
}
Ok(())
})
}
}
array! { $($idx,)* }
}
}
array! {
32, 31, 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, 20, 19, 18, 17, 16,
15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0,
}
impl Encodable for path::Path {
#[cfg(target_os = "redox")]
fn encode<S: Encoder>(&self, e: &mut S) -> Result<(), S::Error> {
self.as_os_str().to_str().unwrap().encode(e)
}
#[cfg(unix)]
fn encode<S: Encoder>(&self, e: &mut S) -> Result<(), S::Error> {
use std::os::unix::prelude::*;
self.as_os_str().as_bytes().encode(e)
}
#[cfg(windows)]
fn encode<S: Encoder>(&self, e: &mut S) -> Result<(), S::Error> {
use std::os::windows::prelude::*;
let v = self.as_os_str().encode_wide().collect::<Vec<_>>();
v.encode(e)
}
}
impl Encodable for path::PathBuf {
fn encode<S: Encoder>(&self, e: &mut S) -> Result<(), S::Error> {
(**self).encode(e)
}
}
impl Decodable for path::PathBuf {
#[cfg(target_os = "redox")]
fn decode<D: Decoder>(d: &mut D) -> Result<path::PathBuf, D::Error> {
let string: String = try!(Decodable::decode(d));
let s: OsString = OsString::from(string);
let mut p = path::PathBuf::new();
p.push(s);
Ok(p)
}
#[cfg(unix)]
fn decode<D: Decoder>(d: &mut D) -> Result<path::PathBuf, D::Error> {
use std::os::unix::prelude::*;
let bytes: Vec<u8> = try!(Decodable::decode(d));
let s: OsString = OsStringExt::from_vec(bytes);
let mut p = path::PathBuf::new();
p.push(s);
Ok(p)
}
#[cfg(windows)]
fn decode<D: Decoder>(d: &mut D) -> Result<path::PathBuf, D::Error> {
use std::os::windows::prelude::*;
let bytes: Vec<u16> = try!(Decodable::decode(d));
let s: OsString = OsStringExt::from_wide(&bytes);
let mut p = path::PathBuf::new();
p.push(s);
Ok(p)
}
}
impl<T: Encodable + Copy> Encodable for Cell<T> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
self.get().encode(s)
}
}
impl<T: Decodable + Copy> Decodable for Cell<T> {
fn decode<D: Decoder>(d: &mut D) -> Result<Cell<T>, D::Error> {
Ok(Cell::new(try!(Decodable::decode(d))))
}
}
// FIXME: #15036
// Should use `try_borrow`, returning a
// `encoder.error("attempting to Encode borrowed RefCell")`
// from `encode` when `try_borrow` returns `None`.
impl<T: Encodable> Encodable for RefCell<T> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
self.borrow().encode(s)
}
}
impl<T: Decodable> Decodable for RefCell<T> {
fn decode<D: Decoder>(d: &mut D) -> Result<RefCell<T>, D::Error> {
Ok(RefCell::new(try!(Decodable::decode(d))))
}
}
impl<T:Encodable> Encodable for Arc<T> {
fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
(**self).encode(s)
}
}
impl<T:Decodable+Send+Sync> Decodable for Arc<T> {
fn decode<D: Decoder>(d: &mut D) -> Result<Arc<T>, D::Error> {
Ok(Arc::new(try!(Decodable::decode(d))))
}
}
// ___________________________________________________________________________
// Helper routines
/// Trait with helper functions for implementing `Encodable`.
///
/// This trait is implemented for everything that implements `Encoder`.
/// `Encodable` implementations can make use of it to make their implementations
/// easier.
pub trait EncoderHelpers: Encoder {
/// Emit a vector as a sequence.
///
/// Storing sequences as vectors is a common pattern. This method makes
/// encoding such sequences easier by wrapping the calls to
/// `Encoder::emit_seq` and `Encoder::emit_seq_elt`.
///
/// # Examples
///
/// ```
/// use rustc_serialize::Encodable;
/// use rustc_serialize::Encoder;
/// use rustc_serialize::EncoderHelpers;
///
/// struct NumberSequence {
/// elements: Vec<i32>,
/// }
///
/// impl Encodable for NumberSequence {
/// fn encode<S: Encoder>(&self, s: &mut S) -> Result<(), S::Error> {
/// s.emit_struct("NumberSequence", 1, |s| {
/// s.emit_struct_field("elements", 0, |s| {
/// s.emit_from_vec(&self.elements, |s,e| {
/// s.emit_i32(*e)
/// })
/// })
/// })
/// }
/// }
/// ```
fn emit_from_vec<T, F>(&mut self, v: &[T], f: F)
-> Result<(), <Self as Encoder>::Error>
where F: FnMut(&mut Self, &T) -> Result<(), <Self as Encoder>::Error>;
}
impl<S:Encoder> EncoderHelpers for S {
fn emit_from_vec<T, F>(&mut self, v: &[T], mut f: F) -> Result<(), S::Error> where
F: FnMut(&mut S, &T) -> Result<(), S::Error>,
{
self.emit_seq(v.len(), |this| {
for (i, e) in v.iter().enumerate() {
try!(this.emit_seq_elt(i, |this| {
f(this, e)
}));
}
Ok(())
})
}
}
/// Trait with helper functions for implementing `Decodable`.
///
/// This trait is implemented for everything that implements `Decoder`.
/// `Decodable` implementations can make use of it to make their implementations
/// easier.
pub trait DecoderHelpers: Decoder {
/// Read a sequence into a vector.
///
/// Storing sequences as vectors is a common pattern. This method makes
/// deserializing such sequences easier by wrapping the calls to
/// `Decoder::read_seq` and `Decoder::read_seq_elt`.
///
/// # Examples
///
/// ```
/// use rustc_serialize::Decodable;
/// use rustc_serialize::Decoder;
/// use rustc_serialize::DecoderHelpers;
///
/// struct NumberSequence {
/// elements: Vec<i32>,
/// }
///
/// impl Decodable for NumberSequence {
/// fn decode<D: Decoder>(d: &mut D) -> Result<NumberSequence, D::Error> {
/// d.read_struct("NumberSequence", 2, |d| {
/// Ok(NumberSequence{
/// elements: try!(d.read_struct_field("elements", 0, |d| {
/// d.read_to_vec(|d| { d.read_i32() })
/// }))
/// })
/// })
/// }
/// }
/// ```
fn read_to_vec<T, F>(&mut self, f: F)
-> Result<Vec<T>, <Self as Decoder>::Error> where
F: FnMut(&mut Self) -> Result<T, <Self as Decoder>::Error>;
}
impl<D: Decoder> DecoderHelpers for D {
fn read_to_vec<T, F>(&mut self, mut f: F) -> Result<Vec<T>, D::Error> where F:
FnMut(&mut D) -> Result<T, D::Error>,
{
self.read_seq(|this, len| {
let mut v = Vec::with_capacity(cap_capacity::<T>(len));
for i in 0..len {
v.push(try!(this.read_seq_elt(i, |this| f(this))));
}
Ok(v)
})
}
}
#[test]
#[allow(unused_variables)]
fn capacity_rules() {
use std::usize::MAX;
use std::collections::{HashMap, HashSet};
struct MyDecoder;
impl Decoder for MyDecoder {
type Error = ();
// Primitive types:
fn read_nil(&mut self) -> Result<(), Self::Error> { Err(()) }
fn read_usize(&mut self) -> Result<usize, Self::Error> { Err(()) }
fn read_u64(&mut self) -> Result<u64, Self::Error> { Err(()) }
fn read_u32(&mut self) -> Result<u32, Self::Error> { Err(()) }
fn read_u16(&mut self) -> Result<u16, Self::Error> { Err(()) }
fn read_u8(&mut self) -> Result<u8, Self::Error> { Err(()) }
fn read_isize(&mut self) -> Result<isize, Self::Error> { Err(()) }
fn read_i64(&mut self) -> Result<i64, Self::Error> { Err(()) }
fn read_i32(&mut self) -> Result<i32, Self::Error> { Err(()) }
fn read_i16(&mut self) -> Result<i16, Self::Error> { Err(()) }
fn read_i8(&mut self) -> Result<i8, Self::Error> { Err(()) }
fn read_bool(&mut self) -> Result<bool, Self::Error> { Err(()) }
fn read_f64(&mut self) -> Result<f64, Self::Error> { Err(()) }
fn read_f32(&mut self) -> Result<f32, Self::Error> { Err(()) }
fn read_char(&mut self) -> Result<char, Self::Error> { Err(()) }
fn read_str(&mut self) -> Result<String, Self::Error> { Err(()) }
// Compound types:
fn read_enum<T, F>(&mut self, name: &str, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_enum_variant<T, F>(&mut self, names: &[&str], f: F)
-> Result<T, Self::Error>
where F: FnMut(&mut Self, usize) -> Result<T, Self::Error> { Err(()) }
fn read_enum_variant_arg<T, F>(&mut self, a_idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_enum_struct_variant<T, F>(&mut self, names: &[&str], f: F)
-> Result<T, Self::Error>
where F: FnMut(&mut Self, usize) -> Result<T, Self::Error> { Err(()) }
fn read_enum_struct_variant_field<T, F>(&mut self,
f_name: &str,
f_idx: usize,
f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_struct<T, F>(&mut self, s_name: &str, len: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_struct_field<T, F>(&mut self,
f_name: &str,
f_idx: usize,
f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_tuple<T, F>(&mut self, len: usize, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_tuple_arg<T, F>(&mut self, a_idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_tuple_struct<T, F>(&mut self, s_name: &str, len: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_tuple_struct_arg<T, F>(&mut self, a_idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
// Specialized types:
fn read_option<T, F>(&mut self, f: F) -> Result<T, Self::Error>
where F: FnMut(&mut Self, bool) -> Result<T, Self::Error> { Err(()) }
fn read_seq<T, F>(&mut self, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self, usize) -> Result<T, Self::Error> {
f(self, MAX)
}
fn read_seq_elt<T, F>(&mut self, idx: usize, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_map<T, F>(&mut self, f: F) -> Result<T, Self::Error>
where F: FnOnce(&mut Self, usize) -> Result<T, Self::Error> {
f(self, MAX)
}
fn read_map_elt_key<T, F>(&mut self, idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
fn read_map_elt_val<T, F>(&mut self, idx: usize, f: F)
-> Result<T, Self::Error>
where F: FnOnce(&mut Self) -> Result<T, Self::Error> { Err(()) }
// Failure
fn error(&mut self, err: &str) -> Self::Error { () }
}
let mut dummy = MyDecoder;
let vec_result: Result<Vec<u8>, ()> = Decodable::decode(&mut dummy);
assert!(vec_result.is_err());
let map_result: Result<HashMap<u8, u8>, ()> = Decodable::decode(&mut dummy);
assert!(map_result.is_err());
let set_result: Result<HashSet<u8>, ()> = Decodable::decode(&mut dummy);
assert!(set_result.is_err());
}