pub trait Encoder: Sized {
Show 53 associated items
type Cx: Context<Error = Self::Error, Mode = Self::Mode> + ?Sized;
type Ok;
type Error;
type Mode;
type WithContext<'this, U: 'this + Context>: Encoder<Cx = U, Ok = Self::Ok, Error = <U as Context>::Error, Mode = <U as Context>::Mode>;
type EncodePack: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>;
type EncodeSome: Encoder<Cx = Self::Cx, Ok = Self::Ok, Error = Self::Error, Mode = Self::Mode>;
type EncodeSequence: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>;
type EncodeMap: MapEncoder<Cx = Self::Cx, Ok = Self::Ok>;
type EncodeMapEntries: EntriesEncoder<Cx = Self::Cx, Ok = Self::Ok>;
type EncodeVariant: VariantEncoder<Cx = Self::Cx, Ok = Self::Ok>;
type EncodeSequenceVariant: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>;
type EncodeMapVariant: MapEncoder<Cx = Self::Cx, Ok = Self::Ok>;
// Required methods
fn cx(&self) -> &Self::Cx;
fn expecting(&self, f: &mut Formatter<'_>) -> Result<(), Error>;
fn encode<T>(self, value: T) -> Result<Self::Ok, Self::Error>
where T: Encode<Self::Mode>;
// Provided methods
fn with_context<U>(
self,
_: &U
) -> Result<Self::WithContext<'_, U>, <Self::Cx as Context>::Error>
where U: Context { ... }
fn encode_empty(self) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_bool(
self,
v: bool
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_char(
self,
v: char
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_u8(self, v: u8) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_u16(
self,
v: u16
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_u32(
self,
v: u32
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_u64(
self,
v: u64
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_u128(
self,
v: u128
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_i8(self, v: i8) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_i16(
self,
v: i16
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_i32(
self,
v: i32
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_i64(
self,
v: i64
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_i128(
self,
v: i128
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_usize(
self,
v: usize
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_isize(
self,
v: isize
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_f32(
self,
v: f32
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_f64(
self,
v: f64
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_array<const N: usize>(
self,
array: &[u8; N]
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_bytes(
self,
bytes: &[u8]
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_bytes_vectored<I>(
self,
len: usize,
vectors: I
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
where I: IntoIterator,
<I as IntoIterator>::Item: AsRef<[u8]> { ... }
fn encode_string(
self,
string: &str
) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn collect_string<T>(
self,
value: &T
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
where T: Display + ?Sized { ... }
fn encode_some(
self
) -> Result<Self::EncodeSome, <Self::Cx as Context>::Error> { ... }
fn encode_none(self) -> Result<Self::Ok, <Self::Cx as Context>::Error> { ... }
fn encode_pack(
self
) -> Result<Self::EncodePack, <Self::Cx as Context>::Error> { ... }
fn encode_pack_fn<F>(
self,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
where F: FnOnce(&mut Self::EncodePack) -> Result<(), <Self::Cx as Context>::Error> { ... }
fn encode_sequence(
self,
hint: &SequenceHint
) -> Result<Self::EncodeSequence, <Self::Cx as Context>::Error> { ... }
fn encode_sequence_fn<F>(
self,
hint: &SequenceHint,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
where F: FnOnce(&mut Self::EncodeSequence) -> Result<(), <Self::Cx as Context>::Error> { ... }
fn encode_map(
self,
hint: &MapHint
) -> Result<Self::EncodeMap, <Self::Cx as Context>::Error> { ... }
fn encode_map_fn<F>(
self,
hint: &MapHint,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
where F: FnOnce(&mut Self::EncodeMap) -> Result<(), <Self::Cx as Context>::Error> { ... }
fn encode_map_entries(
self,
hint: &MapHint
) -> Result<Self::EncodeMapEntries, <Self::Cx as Context>::Error> { ... }
fn encode_variant(
self
) -> Result<Self::EncodeVariant, <Self::Cx as Context>::Error> { ... }
fn encode_variant_fn<F>(
self,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
where F: FnOnce(&mut Self::EncodeVariant) -> Result<(), <Self::Cx as Context>::Error> { ... }
fn encode_unit_variant<T>(
self,
tag: &T
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
where T: Encode<<Self::Cx as Context>::Mode> + ?Sized { ... }
fn encode_sequence_variant<T>(
self,
tag: &T,
hint: &SequenceHint
) -> Result<Self::EncodeSequenceVariant, <Self::Cx as Context>::Error>
where T: Encode<<Self::Cx as Context>::Mode> + ?Sized { ... }
fn encode_map_variant<T>(
self,
tag: &T,
hint: &MapHint
) -> Result<Self::EncodeMapVariant, <Self::Cx as Context>::Error>
where T: Encode<<Self::Cx as Context>::Mode> + ?Sized { ... }
}Expand description
Trait governing how the encoder works.
Required Associated Types§
sourcetype Cx: Context<Error = Self::Error, Mode = Self::Mode> + ?Sized
type Cx: Context<Error = Self::Error, Mode = Self::Mode> + ?Sized
Context associated with the encoder.
sourcetype WithContext<'this, U: 'this + Context>: Encoder<Cx = U, Ok = Self::Ok, Error = <U as Context>::Error, Mode = <U as Context>::Mode>
type WithContext<'this, U: 'this + Context>: Encoder<Cx = U, Ok = Self::Ok, Error = <U as Context>::Error, Mode = <U as Context>::Mode>
Constructed Encoder with a different context.
sourcetype EncodePack: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>
type EncodePack: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>
A simple pack that packs a sequence of elements.
sourcetype EncodeSome: Encoder<Cx = Self::Cx, Ok = Self::Ok, Error = Self::Error, Mode = Self::Mode>
type EncodeSome: Encoder<Cx = Self::Cx, Ok = Self::Ok, Error = Self::Error, Mode = Self::Mode>
Encoder returned when encoding an optional value which is present.
sourcetype EncodeSequence: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>
type EncodeSequence: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>
The type of a sequence encoder.
sourcetype EncodeMap: MapEncoder<Cx = Self::Cx, Ok = Self::Ok>
type EncodeMap: MapEncoder<Cx = Self::Cx, Ok = Self::Ok>
The type of a map encoder.
sourcetype EncodeMapEntries: EntriesEncoder<Cx = Self::Cx, Ok = Self::Ok>
type EncodeMapEntries: EntriesEncoder<Cx = Self::Cx, Ok = Self::Ok>
Streaming encoder for map pairs.
sourcetype EncodeVariant: VariantEncoder<Cx = Self::Cx, Ok = Self::Ok>
type EncodeVariant: VariantEncoder<Cx = Self::Cx, Ok = Self::Ok>
Encoder for a struct variant.
sourcetype EncodeSequenceVariant: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>
type EncodeSequenceVariant: SequenceEncoder<Cx = Self::Cx, Ok = Self::Ok>
Specialized encoder for a tuple variant.
sourcetype EncodeMapVariant: MapEncoder<Cx = Self::Cx, Ok = Self::Ok>
type EncodeMapVariant: MapEncoder<Cx = Self::Cx, Ok = Self::Ok>
Specialized encoder for a struct variant.
Required Methods§
Provided Methods§
sourcefn with_context<U>(
self,
_: &U
) -> Result<Self::WithContext<'_, U>, <Self::Cx as Context>::Error>where
U: Context,
fn with_context<U>(
self,
_: &U
) -> Result<Self::WithContext<'_, U>, <Self::Cx as Context>::Error>where
U: Context,
Construct an encoder with a different context.
sourcefn encode_empty(self) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_empty(self) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a unit or something that is completely empty.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
struct UnitStruct;Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for UnitStruct {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_empty()
}
}sourcefn encode_bool(self, v: bool) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_bool(self, v: bool) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a boolean value.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: bool
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_bool(self.data)
}
}sourcefn encode_char(self, v: char) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_char(self, v: char) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a character.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: char
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_char(self.data)
}
}sourcefn encode_u8(self, v: u8) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_u8(self, v: u8) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 8-bit unsigned integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: u8
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_u8(self.data)
}
}sourcefn encode_u16(self, v: u16) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_u16(self, v: u16) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 16-bit unsigned integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: u16
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_u16(self.data)
}
}sourcefn encode_u32(self, v: u32) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_u32(self, v: u32) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 32-bit unsigned integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: u32
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_u32(self.data)
}
}sourcefn encode_u64(self, v: u64) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_u64(self, v: u64) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 64-bit unsigned integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: u64
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_u64(self.data)
}
}sourcefn encode_u128(self, v: u128) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_u128(self, v: u128) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 128-bit unsigned integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: u128
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_u128(self.data)
}
}sourcefn encode_i8(self, v: i8) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_i8(self, v: i8) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 8-bit signed integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: i8
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_i8(self.data)
}
}sourcefn encode_i16(self, v: i16) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_i16(self, v: i16) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 16-bit signed integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: i16
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_i16(self.data)
}
}sourcefn encode_i32(self, v: i32) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_i32(self, v: i32) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 32-bit signed integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: i32
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_i32(self.data)
}
}sourcefn encode_i64(self, v: i64) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_i64(self, v: i64) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 64-bit signed integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: i64
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_i64(self.data)
}
}sourcefn encode_i128(self, v: i128) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_i128(self, v: i128) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 128-bit signed integer.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: i128
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_i128(self.data)
}
}sourcefn encode_usize(
self,
v: usize
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_usize( self, v: usize ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a usize.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: usize
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_usize(self.data)
}
}sourcefn encode_isize(
self,
v: isize
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_isize( self, v: isize ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a isize.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: isize
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_isize(self.data)
}
}sourcefn encode_f32(self, v: f32) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_f32(self, v: f32) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 32-bit floating point value.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: f32
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_f32(self.data)
}
}sourcefn encode_f64(self, v: f64) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_f64(self, v: f64) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a 64-bit floating point value.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: f64
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_f64(self.data)
}
}sourcefn encode_array<const N: usize>(
self,
array: &[u8; N]
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_array<const N: usize>( self, array: &[u8; N] ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode fixed-length array.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: [u8; 128]
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_array(&self.data)
}
}sourcefn encode_bytes(
self,
bytes: &[u8]
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_bytes( self, bytes: &[u8] ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a sequence of bytes.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
#[musli(bytes)]
data: Vec<u8>
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_bytes(self.data.as_slice())
}
}sourcefn encode_bytes_vectored<I>(
self,
len: usize,
vectors: I
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_bytes_vectored<I>( self, len: usize, vectors: I ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode the given slices of bytes in sequence, with one following another as a single contiguous byte array.
The provided len is trusted, but providing the wrong length must never
result in any memory unsafety. It might just cause the payload to be
corrupted.
This can be useful to avoid allocations when a caller doesn’t have
access to a single byte sequence like in
VecDeque.
§Examples
Deriving an implementation:
use std::collections::VecDeque;
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: VecDeque<u8>
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let (first, second) = self.data.as_slices();
encoder.encode_bytes_vectored(self.data.len(), [first, second])
}
}sourcefn encode_string(
self,
string: &str
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_string( self, string: &str ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a string.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: String
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_string(self.data.as_str())
}
}sourcefn encode_some(self) -> Result<Self::EncodeSome, <Self::Cx as Context>::Error>
fn encode_some(self) -> Result<Self::EncodeSome, <Self::Cx as Context>::Error>
Encode an optional value that is present.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: Option<String>
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
match &self.data {
Some(data) => {
encoder.encode_some()?.encode(data)
}
None => {
encoder.encode_none()
}
}
}
}sourcefn encode_none(self) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_none(self) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode an optional value that is absent.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: Option<String>
}Implementing manually:
use musli::{Encode, Encoder};
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
match &self.data {
Some(data) => {
encoder.encode_some()?.encode(data)
}
None => {
encoder.encode_none()
}
}
}
}sourcefn encode_pack(self) -> Result<Self::EncodePack, <Self::Cx as Context>::Error>
fn encode_pack(self) -> Result<Self::EncodePack, <Self::Cx as Context>::Error>
Construct a pack that can encode more than one element at a time.
This hints to the format that it should attempt to encode all of the elements in the packed sequence as compact as possible and that subsequent unpackers will know the exact length of the element being unpacked.
§Examples
use musli::{Encode, Encoder};
use musli::en::SequenceEncoder;
struct PackedStruct {
field: u32,
data: [u8; 128],
}
impl<M> Encode<M> for PackedStruct {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let mut pack = encoder.encode_pack()?;
pack.encode_next()?.encode(self.field)?;
pack.encode_next()?.encode(self.data)?;
pack.finish_sequence()
}
}sourcefn encode_pack_fn<F>(
self,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_pack_fn<F>( self, f: F ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encodes a pack using a closure.
§Examples
use musli::{Encode, Encoder};
use musli::en::SequenceEncoder;
struct PackedStruct {
field: u32,
data: [u8; 128],
}
impl<M> Encode<M> for PackedStruct {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
encoder.encode_pack_fn(|pack| {
pack.encode_next()?.encode(self.field)?;
pack.encode_next()?.encode(&self.data)?;
Ok(())
})
}
}sourcefn encode_sequence(
self,
hint: &SequenceHint
) -> Result<Self::EncodeSequence, <Self::Cx as Context>::Error>
fn encode_sequence( self, hint: &SequenceHint ) -> Result<Self::EncodeSequence, <Self::Cx as Context>::Error>
Encode a sequence with a known length len.
A sequence encodes one element following another and must in some way encode the length of the sequence in the underlying format. It is decoded with Decoder::decode_sequence.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
#[musli(packed)]
struct MyType {
data: Vec<String>
}Implementing manually:
use musli::{Encode, Encoder};
use musli::en::SequenceEncoder;
use musli::hint::SequenceHint;
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let hint = SequenceHint::with_size(self.data.len());
let mut seq = encoder.encode_sequence(&hint)?;
for element in &self.data {
seq.push(element)?;
}
seq.finish_sequence()
}
}Encoding a tuple:
use musli::{Encode, Encoder};
use musli::en::SequenceEncoder;
use musli::hint::SequenceHint;
struct PackedTuple(u32, [u8; 128]);
impl<M> Encode<M> for PackedTuple {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
static HINT: SequenceHint = SequenceHint::with_size(2);
let mut tuple = encoder.encode_sequence(&HINT)?;
tuple.encode_next()?.encode(self.0)?;
tuple.encode_next()?.encode(&self.1)?;
tuple.finish_sequence()
}
}sourcefn encode_sequence_fn<F>(
self,
hint: &SequenceHint,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_sequence_fn<F>( self, hint: &SequenceHint, f: F ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a sequence using a closure.
§Examples
use musli::{Encode, Encoder};
use musli::en::SequenceEncoder;
use musli::hint::SequenceHint;
impl<M> Encode<M> for MyType {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let hint = SequenceHint::with_size(self.data.len());
encoder.encode_sequence_fn(&hint, |seq| {
for element in &self.data {
seq.push(element)?;
}
Ok(())
})
}
}Encoding a tuple:
use musli::{Encode, Encoder};
use musli::en::SequenceEncoder;
use musli::hint::SequenceHint;
struct PackedTuple(u32, [u8; 128]);
impl<M> Encode<M> for PackedTuple {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
static HINT: SequenceHint = SequenceHint::with_size(2);
encoder.encode_sequence_fn(&HINT, |tuple| {
tuple.encode_next()?.encode(self.0)?;
tuple.encode_next()?.encode(&self.1)?;
Ok(())
})
}
}sourcefn encode_map(
self,
hint: &MapHint
) -> Result<Self::EncodeMap, <Self::Cx as Context>::Error>
fn encode_map( self, hint: &MapHint ) -> Result<Self::EncodeMap, <Self::Cx as Context>::Error>
Encode a map with a known length len.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
struct Struct {
name: String,
age: u32,
}Implementing manually:
use musli::{Encode, Encoder};
use musli::en::MapEncoder;
use musli::hint::MapHint;
impl<M> Encode<M> for Struct {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let hint = MapHint::with_size(2);
let mut map = encoder.encode_map(&hint)?;
map.insert_entry("name", &self.name)?;
map.insert_entry("age", self.age)?;
map.finish_map()
}
}sourcefn encode_map_fn<F>(
self,
hint: &MapHint,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_map_fn<F>( self, hint: &MapHint, f: F ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a map using a closure.
§Examples
use musli::{Encode, Encoder};
use musli::en::MapEncoder;
use musli::hint::MapHint;
struct Struct {
name: String,
age: u32
}
impl<M> Encode<M> for Struct {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let hint = MapHint::with_size(2);
encoder.encode_map_fn(&hint, |map| {
map.insert_entry("name", &self.name)?;
map.insert_entry("age", self.age)?;
Ok(())
})
}
}sourcefn encode_map_entries(
self,
hint: &MapHint
) -> Result<Self::EncodeMapEntries, <Self::Cx as Context>::Error>
fn encode_map_entries( self, hint: &MapHint ) -> Result<Self::EncodeMapEntries, <Self::Cx as Context>::Error>
Encode a map through pairs with a known length len.
§Examples
use musli::{Encode, Encoder};
use musli::en::EntriesEncoder;
use musli::hint::MapHint;
struct Struct {
name: String,
age: u32,
}
impl<M> Encode<M> for Struct {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let hint = MapHint::with_size(2);
let mut m = encoder.encode_map_entries(&hint)?;
// Simplified encoding.
m.insert_entry("name", &self.name)?;
// Key and value encoding as a stream.
m.encode_entry_key()?.encode("age")?;
m.encode_entry_value()?.encode(self.age)?;
m.finish_entries()
}
}sourcefn encode_variant(
self
) -> Result<Self::EncodeVariant, <Self::Cx as Context>::Error>
fn encode_variant( self ) -> Result<Self::EncodeVariant, <Self::Cx as Context>::Error>
Encode a variant.
§Examples
use musli::Encode;
#[derive(Encode)]
enum Enum {
UnitVariant,
TupleVariant(String),
StructVariant {
data: String,
age: u32,
}
}Implementing manually:
use musli::{Encode, Encoder};
use musli::en::{VariantEncoder, SequenceEncoder, MapEncoder};
use musli::hint::{MapHint, SequenceHint};
impl<M> Encode<M> for Enum {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
let mut variant = encoder.encode_variant()?;
match self {
Enum::UnitVariant => {
variant.insert_variant("UnitVariant", ())
}
Enum::TupleVariant(data) => {
static HINT: SequenceHint = SequenceHint::with_size(1);
variant.encode_tag()?.encode_string("TupleVariant")?;
let mut tuple = variant.encode_data()?.encode_sequence(&HINT)?;
tuple.push(data)?;
tuple.finish_sequence()?;
variant.finish_variant()
}
Enum::StructVariant { data, age } => {
static HINT: MapHint = MapHint::with_size(2);
variant.encode_tag()?.encode_string("StructVariant")?;
let mut st = variant.encode_data()?.encode_map(&HINT)?;
st.insert_entry("data", data)?;
st.insert_entry("age", age)?;
st.finish_map()?;
variant.finish_variant()
}
}
}
}sourcefn encode_variant_fn<F>(
self,
f: F
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_variant_fn<F>( self, f: F ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Encode a variant using a closure.
§Examples
use musli::{Encode, Encoder};
use musli::en::{VariantEncoder, SequenceEncoder, MapEncoder};
use musli::hint::{MapHint, SequenceHint};
enum Enum {
UnitVariant,
TupleVariant(String),
StructVariant {
data: String,
age: u32,
}
}
impl<M> Encode<M> for Enum {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
match self {
Enum::UnitVariant => {
encoder.encode_variant()?.insert_variant("variant1", ())
}
Enum::TupleVariant(data) => {
static HINT: SequenceHint = SequenceHint::with_size(2);
encoder.encode_variant_fn(|variant| {
variant.encode_tag()?.encode("TupleVariant")?;
variant.encode_data()?.encode_sequence_fn(&HINT, |tuple| {
tuple.push(data)?;
Ok(())
})?;
Ok(())
})
}
Enum::StructVariant { data, age } => {
encoder.encode_variant_fn(|variant| {
static HINT: MapHint = MapHint::with_size(2);
variant.encode_tag()?.encode("variant3")?;
variant.encode_data()?.encode_map_fn(&HINT, |st| {
st.insert_entry("data", data)?;
st.insert_entry("age", age)?;
Ok(())
})?;
Ok(())
})
}
}
}
}sourcefn encode_unit_variant<T>(
self,
tag: &T
) -> Result<Self::Ok, <Self::Cx as Context>::Error>
fn encode_unit_variant<T>( self, tag: &T ) -> Result<Self::Ok, <Self::Cx as Context>::Error>
Simplified encoding for a unit variant.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
enum Enum {
UnitVariant,
}Implementing manually:
use musli::{Encode, Encoder};
use musli::en::{VariantEncoder, MapEncoder, SequenceEncoder};
impl<M> Encode<M> for Enum {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
match self {
Enum::UnitVariant => {
encoder.encode_unit_variant("variant1")
}
}
}
}sourcefn encode_sequence_variant<T>(
self,
tag: &T,
hint: &SequenceHint
) -> Result<Self::EncodeSequenceVariant, <Self::Cx as Context>::Error>
fn encode_sequence_variant<T>( self, tag: &T, hint: &SequenceHint ) -> Result<Self::EncodeSequenceVariant, <Self::Cx as Context>::Error>
Simplified encoding for a tuple variant.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
enum Enum {
TupleVariant(String),
}Implementing manually:
use musli::{Encode, Encoder};
use musli::en::SequenceEncoder;
use musli::hint::SequenceHint;
impl<M> Encode<M> for Enum {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
match self {
Enum::TupleVariant(data) => {
static HINT: SequenceHint = SequenceHint::with_size(1);
let mut variant = encoder.encode_sequence_variant("variant2", &HINT)?;
variant.push(data)?;
variant.finish_sequence()
}
}
}
}sourcefn encode_map_variant<T>(
self,
tag: &T,
hint: &MapHint
) -> Result<Self::EncodeMapVariant, <Self::Cx as Context>::Error>
fn encode_map_variant<T>( self, tag: &T, hint: &MapHint ) -> Result<Self::EncodeMapVariant, <Self::Cx as Context>::Error>
Simplified encoding for a struct variant.
§Examples
Deriving an implementation:
use musli::Encode;
#[derive(Encode)]
enum Enum {
StructVariant {
data: String,
age: u32,
}
}Implementing manually:
use musli::{Encode, Encoder};
use musli::en::MapEncoder;
use musli::hint::MapHint;
impl<M> Encode<M> for Enum {
fn encode<E>(&self, cx: &E::Cx, encoder: E) -> Result<E::Ok, E::Error>
where
E: Encoder,
{
match self {
Enum::StructVariant { data, age } => {
static HINT: MapHint = MapHint::with_size(2);
let mut variant = encoder.encode_map_variant("variant3", &HINT)?;
variant.insert_entry("data", data)?;
variant.insert_entry("age", age)?;
variant.finish_map()
}
}
}
}Object Safety§
This trait is not object safe.