#![warn(clippy::all)]
#![allow(unused_parens, unused_mut, unused_imports, nonstandard_style)]
use {
bitflags::bitflags,
fidl::{
client::QueryResponseFut,
endpoints::{ControlHandle as _, Responder as _},
},
fuchsia_zircon_status as zx_status,
futures::future::{self, MaybeDone, TryFutureExt},
};
#[cfg(target_os = "fuchsia")]
use fuchsia_zircon as zx;
pub const BIND_RULES_INSTRUCTIONS_MAX: u32 = 256;
pub const DEVICE_PATH_MAX: u32 = 1024;
pub const PROPERTIES_MAX: u32 = 256;
pub const STR_LENGTH_MAX: u32 = 255;
pub const STR_PROPERTIES_MAX: u32 = 256;
bitflags! {
#[derive(Clone, Copy, Debug, Default, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DeviceFlags: u32 {
const IMMORTAL = 1;
const MUST_ISOLATE = 2;
const BOUND = 8;
const DEAD = 16;
const ALLOW_MULTI_COMPOSITE = 32;
const PROXY = 64;
const INVISIBLE = 128;
const SKIP_AUTOBIND = 256;
}
}
impl DeviceFlags {
#[deprecated = "Strict bits should not use `has_unknown_bits`"]
#[inline(always)]
pub fn has_unknown_bits(&self) -> bool {
false
}
#[deprecated = "Strict bits should not use `get_unknown_bits`"]
#[inline(always)]
pub fn get_unknown_bits(&self) -> u32 {
0
}
}
#[derive(Clone, Copy, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
#[repr(C)]
pub struct BindInstruction {
pub op: u32,
pub arg: u32,
pub debug: u32,
}
impl fidl::Persistable for BindInstruction {}
#[derive(Clone, Copy, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
#[repr(C)]
pub struct DeviceProperty {
pub id: u16,
pub reserved: u16,
pub value: u32,
}
impl fidl::Persistable for DeviceProperty {}
#[derive(Clone, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
pub struct DevicePropertyList {
pub props: Vec<DeviceProperty>,
pub str_props: Vec<DeviceStrProperty>,
}
impl fidl::Persistable for DevicePropertyList {}
#[derive(Clone, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
pub struct DeviceStrProperty {
pub key: String,
pub value: PropertyValue,
}
impl fidl::Persistable for DeviceStrProperty {}
#[derive(Clone, Debug, Default, PartialEq)]
pub struct CompositeFragmentInfo {
pub name: Option<String>,
pub bind_rules: Option<Vec<BindInstruction>>,
#[doc(hidden)]
pub __source_breaking: fidl::marker::SourceBreaking,
}
impl fidl::Persistable for CompositeFragmentInfo {}
#[derive(Clone, Debug, Default, PartialEq)]
pub struct CompositeInfo {
pub name: Option<String>,
pub fragments: Option<Vec<CompositeFragmentInfo>>,
pub properties: Option<Vec<fidl_fuchsia_driver_framework::NodeProperty>>,
pub matched_driver: Option<fidl_fuchsia_driver_framework::DriverInfo>,
pub primary_fragment_index: Option<u32>,
#[doc(hidden)]
pub __source_breaking: fidl::marker::SourceBreaking,
}
impl fidl::Persistable for CompositeInfo {}
#[derive(Clone, Debug, Default, PartialEq)]
pub struct CompositeParent {
pub composite: Option<CompositeInfo>,
pub index: Option<u32>,
#[doc(hidden)]
pub __source_breaking: fidl::marker::SourceBreaking,
}
impl fidl::Persistable for CompositeParent {}
#[derive(Clone, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
pub enum PropertyValue {
IntValue(u32),
StrValue(String),
BoolValue(bool),
EnumValue(String),
}
impl PropertyValue {
#[inline]
pub fn ordinal(&self) -> u64 {
match *self {
Self::IntValue(_) => 1,
Self::StrValue(_) => 2,
Self::BoolValue(_) => 3,
Self::EnumValue(_) => 4,
}
}
#[deprecated = "Strict unions should not use `is_unknown`"]
#[inline]
pub fn is_unknown(&self) -> bool {
false
}
}
impl fidl::Persistable for PropertyValue {}
mod internal {
use super::*;
unsafe impl fidl::encoding::TypeMarker for DeviceFlags {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
4
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
4
}
}
impl fidl::encoding::ValueTypeMarker for DeviceFlags {
type Borrowed<'a> = Self;
#[inline(always)]
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
*value
}
}
unsafe impl fidl::encoding::Encode<Self> for DeviceFlags {
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<Self>(offset);
if self.bits() & Self::all().bits() != self.bits() {
return Err(fidl::Error::InvalidBitsValue);
}
encoder.write_num(self.bits(), offset);
Ok(())
}
}
impl fidl::encoding::Decode<Self> for DeviceFlags {
#[inline(always)]
fn new_empty() -> Self {
Self::empty()
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
let prim = decoder.read_num::<u32>(offset);
*self = Self::from_bits(prim).ok_or(fidl::Error::InvalidBitsValue)?;
Ok(())
}
}
unsafe impl fidl::encoding::TypeMarker for BindInstruction {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
4
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
12
}
#[inline(always)]
fn encode_is_copy() -> bool {
true
}
#[inline(always)]
fn decode_is_copy() -> bool {
true
}
}
impl fidl::encoding::ValueTypeMarker for BindInstruction {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<BindInstruction> for &BindInstruction {
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<BindInstruction>(offset);
unsafe {
let buf_ptr = encoder.buf.as_mut_ptr().add(offset);
(buf_ptr as *mut BindInstruction)
.write_unaligned((self as *const BindInstruction).read());
}
Ok(())
}
}
unsafe impl<
T0: fidl::encoding::Encode<u32>,
T1: fidl::encoding::Encode<u32>,
T2: fidl::encoding::Encode<u32>,
> fidl::encoding::Encode<BindInstruction> for (T0, T1, T2)
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<BindInstruction>(offset);
self.0.encode(encoder, offset + 0, depth)?;
self.1.encode(encoder, offset + 4, depth)?;
self.2.encode(encoder, offset + 8, depth)?;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for BindInstruction {
#[inline(always)]
fn new_empty() -> Self {
Self {
op: fidl::new_empty!(u32),
arg: fidl::new_empty!(u32),
debug: fidl::new_empty!(u32),
}
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
let buf_ptr = unsafe { decoder.buf.as_ptr().add(offset) };
unsafe {
std::ptr::copy_nonoverlapping(buf_ptr, self as *mut Self as *mut u8, 12);
}
Ok(())
}
}
unsafe impl fidl::encoding::TypeMarker for DeviceProperty {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
4
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn encode_is_copy() -> bool {
true
}
#[inline(always)]
fn decode_is_copy() -> bool {
true
}
}
impl fidl::encoding::ValueTypeMarker for DeviceProperty {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<DeviceProperty> for &DeviceProperty {
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<DeviceProperty>(offset);
unsafe {
let buf_ptr = encoder.buf.as_mut_ptr().add(offset);
(buf_ptr as *mut DeviceProperty)
.write_unaligned((self as *const DeviceProperty).read());
}
Ok(())
}
}
unsafe impl<
T0: fidl::encoding::Encode<u16>,
T1: fidl::encoding::Encode<u16>,
T2: fidl::encoding::Encode<u32>,
> fidl::encoding::Encode<DeviceProperty> for (T0, T1, T2)
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<DeviceProperty>(offset);
self.0.encode(encoder, offset + 0, depth)?;
self.1.encode(encoder, offset + 2, depth)?;
self.2.encode(encoder, offset + 4, depth)?;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for DeviceProperty {
#[inline(always)]
fn new_empty() -> Self {
Self {
id: fidl::new_empty!(u16),
reserved: fidl::new_empty!(u16),
value: fidl::new_empty!(u32),
}
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
let buf_ptr = unsafe { decoder.buf.as_ptr().add(offset) };
unsafe {
std::ptr::copy_nonoverlapping(buf_ptr, self as *mut Self as *mut u8, 8);
}
Ok(())
}
}
unsafe impl fidl::encoding::TypeMarker for DevicePropertyList {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
32
}
}
impl fidl::encoding::ValueTypeMarker for DevicePropertyList {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<DevicePropertyList> for &DevicePropertyList {
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<DevicePropertyList>(offset);
fidl::encoding::Encode::<DevicePropertyList>::encode(
(
<fidl::encoding::Vector<DeviceProperty, 256> as fidl::encoding::ValueTypeMarker>::borrow(&self.props),
<fidl::encoding::Vector<DeviceStrProperty, 256> as fidl::encoding::ValueTypeMarker>::borrow(&self.str_props),
),
encoder, offset, _depth
)
}
}
unsafe impl<
T0: fidl::encoding::Encode<fidl::encoding::Vector<DeviceProperty, 256>>,
T1: fidl::encoding::Encode<fidl::encoding::Vector<DeviceStrProperty, 256>>,
> fidl::encoding::Encode<DevicePropertyList> for (T0, T1)
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<DevicePropertyList>(offset);
self.0.encode(encoder, offset + 0, depth)?;
self.1.encode(encoder, offset + 16, depth)?;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for DevicePropertyList {
#[inline(always)]
fn new_empty() -> Self {
Self {
props: fidl::new_empty!(fidl::encoding::Vector<DeviceProperty, 256>),
str_props: fidl::new_empty!(fidl::encoding::Vector<DeviceStrProperty, 256>),
}
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
fidl::decode!(fidl::encoding::Vector<DeviceProperty, 256>, &mut self.props, decoder, offset + 0, _depth)?;
fidl::decode!(fidl::encoding::Vector<DeviceStrProperty, 256>, &mut self.str_props, decoder, offset + 16, _depth)?;
Ok(())
}
}
unsafe impl fidl::encoding::TypeMarker for DeviceStrProperty {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
32
}
}
impl fidl::encoding::ValueTypeMarker for DeviceStrProperty {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<DeviceStrProperty> for &DeviceStrProperty {
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<DeviceStrProperty>(offset);
fidl::encoding::Encode::<DeviceStrProperty>::encode(
(
<fidl::encoding::BoundedString<255> as fidl::encoding::ValueTypeMarker>::borrow(
&self.key,
),
<PropertyValue as fidl::encoding::ValueTypeMarker>::borrow(&self.value),
),
encoder,
offset,
_depth,
)
}
}
unsafe impl<
T0: fidl::encoding::Encode<fidl::encoding::BoundedString<255>>,
T1: fidl::encoding::Encode<PropertyValue>,
> fidl::encoding::Encode<DeviceStrProperty> for (T0, T1)
{
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<DeviceStrProperty>(offset);
self.0.encode(encoder, offset + 0, depth)?;
self.1.encode(encoder, offset + 16, depth)?;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for DeviceStrProperty {
#[inline(always)]
fn new_empty() -> Self {
Self {
key: fidl::new_empty!(fidl::encoding::BoundedString<255>),
value: fidl::new_empty!(PropertyValue),
}
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
fidl::decode!(
fidl::encoding::BoundedString<255>,
&mut self.key,
decoder,
offset + 0,
_depth
)?;
fidl::decode!(PropertyValue, &mut self.value, decoder, offset + 16, _depth)?;
Ok(())
}
}
impl CompositeFragmentInfo {
#[inline(always)]
fn max_ordinal_present(&self) -> u64 {
if let Some(_) = self.bind_rules {
return 2;
}
if let Some(_) = self.name {
return 1;
}
0
}
}
unsafe impl fidl::encoding::TypeMarker for CompositeFragmentInfo {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
16
}
}
impl fidl::encoding::ValueTypeMarker for CompositeFragmentInfo {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<CompositeFragmentInfo> for &CompositeFragmentInfo {
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
mut depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<CompositeFragmentInfo>(offset);
let max_ordinal: u64 = self.max_ordinal_present();
encoder.write_num(max_ordinal, offset);
encoder.write_num(fidl::encoding::ALLOC_PRESENT_U64, offset + 8);
if max_ordinal == 0 {
return Ok(());
}
depth.increment()?;
let envelope_size = 8;
let bytes_len = max_ordinal as usize * envelope_size;
#[allow(unused_variables)]
let offset = encoder.out_of_line_offset(bytes_len);
let mut _prev_end_offset: usize = 0;
if 1 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (1 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<fidl::encoding::UnboundedString>(
self.name.as_ref().map(
<fidl::encoding::UnboundedString as fidl::encoding::ValueTypeMarker>::borrow,
),
encoder,
offset + cur_offset,
depth,
)?;
_prev_end_offset = cur_offset + envelope_size;
if 2 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (2 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<fidl::encoding::Vector<BindInstruction, 256>>(
self.bind_rules.as_ref().map(<fidl::encoding::Vector<BindInstruction, 256> as fidl::encoding::ValueTypeMarker>::borrow),
encoder, offset + cur_offset, depth
)?;
_prev_end_offset = cur_offset + envelope_size;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for CompositeFragmentInfo {
#[inline(always)]
fn new_empty() -> Self {
Self::default()
}
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
mut depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
let len = match fidl::encoding::decode_vector_header(decoder, offset)? {
None => return Err(fidl::Error::NotNullable),
Some(len) => len,
};
if len == 0 {
return Ok(());
};
depth.increment()?;
let envelope_size = 8;
let bytes_len = len * envelope_size;
let offset = decoder.out_of_line_offset(bytes_len)?;
let mut _next_ordinal_to_read = 0;
let mut next_offset = offset;
let end_offset = offset + bytes_len;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 1 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size =
<fidl::encoding::UnboundedString as fidl::encoding::TypeMarker>::inline_size(
decoder.context,
);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref = self
.name
.get_or_insert_with(|| fidl::new_empty!(fidl::encoding::UnboundedString));
fidl::decode!(
fidl::encoding::UnboundedString,
val_ref,
decoder,
inner_offset,
inner_depth
)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 2 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size = <fidl::encoding::Vector<BindInstruction, 256> as fidl::encoding::TypeMarker>::inline_size(decoder.context);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref = self.bind_rules.get_or_insert_with(
|| fidl::new_empty!(fidl::encoding::Vector<BindInstruction, 256>),
);
fidl::decode!(fidl::encoding::Vector<BindInstruction, 256>, val_ref, decoder, inner_offset, inner_depth)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
while next_offset < end_offset {
_next_ordinal_to_read += 1;
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
next_offset += envelope_size;
}
Ok(())
}
}
impl CompositeInfo {
#[inline(always)]
fn max_ordinal_present(&self) -> u64 {
if let Some(_) = self.primary_fragment_index {
return 5;
}
if let Some(_) = self.matched_driver {
return 4;
}
if let Some(_) = self.properties {
return 3;
}
if let Some(_) = self.fragments {
return 2;
}
if let Some(_) = self.name {
return 1;
}
0
}
}
unsafe impl fidl::encoding::TypeMarker for CompositeInfo {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
16
}
}
impl fidl::encoding::ValueTypeMarker for CompositeInfo {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<CompositeInfo> for &CompositeInfo {
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
mut depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<CompositeInfo>(offset);
let max_ordinal: u64 = self.max_ordinal_present();
encoder.write_num(max_ordinal, offset);
encoder.write_num(fidl::encoding::ALLOC_PRESENT_U64, offset + 8);
if max_ordinal == 0 {
return Ok(());
}
depth.increment()?;
let envelope_size = 8;
let bytes_len = max_ordinal as usize * envelope_size;
#[allow(unused_variables)]
let offset = encoder.out_of_line_offset(bytes_len);
let mut _prev_end_offset: usize = 0;
if 1 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (1 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<fidl::encoding::UnboundedString>(
self.name.as_ref().map(
<fidl::encoding::UnboundedString as fidl::encoding::ValueTypeMarker>::borrow,
),
encoder,
offset + cur_offset,
depth,
)?;
_prev_end_offset = cur_offset + envelope_size;
if 2 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (2 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<fidl::encoding::UnboundedVector<CompositeFragmentInfo>>(
self.fragments.as_ref().map(<fidl::encoding::UnboundedVector<CompositeFragmentInfo> as fidl::encoding::ValueTypeMarker>::borrow),
encoder, offset + cur_offset, depth
)?;
_prev_end_offset = cur_offset + envelope_size;
if 3 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (3 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<fidl::encoding::Vector<fidl_fuchsia_driver_framework::NodeProperty, 64>>(
self.properties.as_ref().map(<fidl::encoding::Vector<fidl_fuchsia_driver_framework::NodeProperty, 64> as fidl::encoding::ValueTypeMarker>::borrow),
encoder, offset + cur_offset, depth
)?;
_prev_end_offset = cur_offset + envelope_size;
if 4 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (4 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<fidl_fuchsia_driver_framework::DriverInfo>(
self.matched_driver.as_ref().map(<fidl_fuchsia_driver_framework::DriverInfo as fidl::encoding::ValueTypeMarker>::borrow),
encoder, offset + cur_offset, depth
)?;
_prev_end_offset = cur_offset + envelope_size;
if 5 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (5 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<u32>(
self.primary_fragment_index
.as_ref()
.map(<u32 as fidl::encoding::ValueTypeMarker>::borrow),
encoder,
offset + cur_offset,
depth,
)?;
_prev_end_offset = cur_offset + envelope_size;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for CompositeInfo {
#[inline(always)]
fn new_empty() -> Self {
Self::default()
}
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
mut depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
let len = match fidl::encoding::decode_vector_header(decoder, offset)? {
None => return Err(fidl::Error::NotNullable),
Some(len) => len,
};
if len == 0 {
return Ok(());
};
depth.increment()?;
let envelope_size = 8;
let bytes_len = len * envelope_size;
let offset = decoder.out_of_line_offset(bytes_len)?;
let mut _next_ordinal_to_read = 0;
let mut next_offset = offset;
let end_offset = offset + bytes_len;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 1 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size =
<fidl::encoding::UnboundedString as fidl::encoding::TypeMarker>::inline_size(
decoder.context,
);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref = self
.name
.get_or_insert_with(|| fidl::new_empty!(fidl::encoding::UnboundedString));
fidl::decode!(
fidl::encoding::UnboundedString,
val_ref,
decoder,
inner_offset,
inner_depth
)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 2 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size = <fidl::encoding::UnboundedVector<CompositeFragmentInfo> as fidl::encoding::TypeMarker>::inline_size(decoder.context);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref = self.fragments.get_or_insert_with(|| {
fidl::new_empty!(fidl::encoding::UnboundedVector<CompositeFragmentInfo>)
});
fidl::decode!(
fidl::encoding::UnboundedVector<CompositeFragmentInfo>,
val_ref,
decoder,
inner_offset,
inner_depth
)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 3 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size = <fidl::encoding::Vector<
fidl_fuchsia_driver_framework::NodeProperty,
64,
> as fidl::encoding::TypeMarker>::inline_size(
decoder.context
);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref =
self.properties.get_or_insert_with(|| fidl::new_empty!(fidl::encoding::Vector<fidl_fuchsia_driver_framework::NodeProperty, 64>));
fidl::decode!(fidl::encoding::Vector<fidl_fuchsia_driver_framework::NodeProperty, 64>, val_ref, decoder, inner_offset, inner_depth)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 4 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size = <fidl_fuchsia_driver_framework::DriverInfo as fidl::encoding::TypeMarker>::inline_size(decoder.context);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref = self.matched_driver.get_or_insert_with(|| {
fidl::new_empty!(fidl_fuchsia_driver_framework::DriverInfo)
});
fidl::decode!(
fidl_fuchsia_driver_framework::DriverInfo,
val_ref,
decoder,
inner_offset,
inner_depth
)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 5 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size =
<u32 as fidl::encoding::TypeMarker>::inline_size(decoder.context);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref =
self.primary_fragment_index.get_or_insert_with(|| fidl::new_empty!(u32));
fidl::decode!(u32, val_ref, decoder, inner_offset, inner_depth)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
while next_offset < end_offset {
_next_ordinal_to_read += 1;
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
next_offset += envelope_size;
}
Ok(())
}
}
impl CompositeParent {
#[inline(always)]
fn max_ordinal_present(&self) -> u64 {
if let Some(_) = self.index {
return 2;
}
if let Some(_) = self.composite {
return 1;
}
0
}
}
unsafe impl fidl::encoding::TypeMarker for CompositeParent {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
16
}
}
impl fidl::encoding::ValueTypeMarker for CompositeParent {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<CompositeParent> for &CompositeParent {
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
mut depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<CompositeParent>(offset);
let max_ordinal: u64 = self.max_ordinal_present();
encoder.write_num(max_ordinal, offset);
encoder.write_num(fidl::encoding::ALLOC_PRESENT_U64, offset + 8);
if max_ordinal == 0 {
return Ok(());
}
depth.increment()?;
let envelope_size = 8;
let bytes_len = max_ordinal as usize * envelope_size;
#[allow(unused_variables)]
let offset = encoder.out_of_line_offset(bytes_len);
let mut _prev_end_offset: usize = 0;
if 1 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (1 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<CompositeInfo>(
self.composite
.as_ref()
.map(<CompositeInfo as fidl::encoding::ValueTypeMarker>::borrow),
encoder,
offset + cur_offset,
depth,
)?;
_prev_end_offset = cur_offset + envelope_size;
if 2 > max_ordinal {
return Ok(());
}
let cur_offset: usize = (2 - 1) * envelope_size;
encoder.padding(offset + _prev_end_offset, cur_offset - _prev_end_offset);
fidl::encoding::encode_in_envelope_optional::<u32>(
self.index.as_ref().map(<u32 as fidl::encoding::ValueTypeMarker>::borrow),
encoder,
offset + cur_offset,
depth,
)?;
_prev_end_offset = cur_offset + envelope_size;
Ok(())
}
}
impl fidl::encoding::Decode<Self> for CompositeParent {
#[inline(always)]
fn new_empty() -> Self {
Self::default()
}
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
mut depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
let len = match fidl::encoding::decode_vector_header(decoder, offset)? {
None => return Err(fidl::Error::NotNullable),
Some(len) => len,
};
if len == 0 {
return Ok(());
};
depth.increment()?;
let envelope_size = 8;
let bytes_len = len * envelope_size;
let offset = decoder.out_of_line_offset(bytes_len)?;
let mut _next_ordinal_to_read = 0;
let mut next_offset = offset;
let end_offset = offset + bytes_len;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 1 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size =
<CompositeInfo as fidl::encoding::TypeMarker>::inline_size(decoder.context);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref = self.composite.get_or_insert_with(|| fidl::new_empty!(CompositeInfo));
fidl::decode!(CompositeInfo, val_ref, decoder, inner_offset, inner_depth)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
_next_ordinal_to_read += 1;
if next_offset >= end_offset {
return Ok(());
}
while _next_ordinal_to_read < 2 {
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
_next_ordinal_to_read += 1;
next_offset += envelope_size;
}
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
if let Some((inlined, num_bytes, num_handles)) =
fidl::encoding::decode_envelope_header(decoder, next_offset)?
{
let member_inline_size =
<u32 as fidl::encoding::TypeMarker>::inline_size(decoder.context);
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let inner_offset;
let mut inner_depth = depth.clone();
if inlined {
decoder.check_inline_envelope_padding(next_offset, member_inline_size)?;
inner_offset = next_offset;
} else {
inner_offset = decoder.out_of_line_offset(member_inline_size)?;
inner_depth.increment()?;
}
let val_ref = self.index.get_or_insert_with(|| fidl::new_empty!(u32));
fidl::decode!(u32, val_ref, decoder, inner_offset, inner_depth)?;
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize)
{
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
}
next_offset += envelope_size;
while next_offset < end_offset {
_next_ordinal_to_read += 1;
fidl::encoding::decode_unknown_envelope(decoder, next_offset, depth)?;
next_offset += envelope_size;
}
Ok(())
}
}
unsafe impl fidl::encoding::TypeMarker for PropertyValue {
type Owned = Self;
#[inline(always)]
fn inline_align(_context: fidl::encoding::Context) -> usize {
8
}
#[inline(always)]
fn inline_size(_context: fidl::encoding::Context) -> usize {
16
}
}
impl fidl::encoding::ValueTypeMarker for PropertyValue {
type Borrowed<'a> = &'a Self;
fn borrow<'a>(
value: &'a <Self as fidl::encoding::TypeMarker>::Owned,
) -> Self::Borrowed<'a> {
value
}
}
unsafe impl fidl::encoding::Encode<PropertyValue> for &PropertyValue {
#[inline]
unsafe fn encode(
self,
encoder: &mut fidl::encoding::Encoder<'_>,
offset: usize,
_depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
encoder.debug_check_bounds::<PropertyValue>(offset);
encoder.write_num::<u64>(self.ordinal(), offset);
match self {
PropertyValue::IntValue(ref val) => fidl::encoding::encode_in_envelope::<u32>(
<u32 as fidl::encoding::ValueTypeMarker>::borrow(val),
encoder,
offset + 8,
_depth,
),
PropertyValue::StrValue(ref val) => fidl::encoding::encode_in_envelope::<
fidl::encoding::BoundedString<255>,
>(
<fidl::encoding::BoundedString<255> as fidl::encoding::ValueTypeMarker>::borrow(
val,
),
encoder,
offset + 8,
_depth,
),
PropertyValue::BoolValue(ref val) => fidl::encoding::encode_in_envelope::<bool>(
<bool as fidl::encoding::ValueTypeMarker>::borrow(val),
encoder,
offset + 8,
_depth,
),
PropertyValue::EnumValue(ref val) => fidl::encoding::encode_in_envelope::<
fidl::encoding::BoundedString<255>,
>(
<fidl::encoding::BoundedString<255> as fidl::encoding::ValueTypeMarker>::borrow(
val,
),
encoder,
offset + 8,
_depth,
),
}
}
}
impl fidl::encoding::Decode<Self> for PropertyValue {
#[inline(always)]
fn new_empty() -> Self {
Self::IntValue(fidl::new_empty!(u32))
}
#[inline]
unsafe fn decode(
&mut self,
decoder: &mut fidl::encoding::Decoder<'_>,
offset: usize,
mut depth: fidl::encoding::Depth,
) -> fidl::Result<()> {
decoder.debug_check_bounds::<Self>(offset);
#[allow(unused_variables)]
let next_out_of_line = decoder.next_out_of_line();
let handles_before = decoder.remaining_handles();
let (ordinal, inlined, num_bytes, num_handles) =
fidl::encoding::decode_union_inline_portion(decoder, offset)?;
let member_inline_size = match ordinal {
1 => <u32 as fidl::encoding::TypeMarker>::inline_size(decoder.context),
2 => {
<fidl::encoding::BoundedString<255> as fidl::encoding::TypeMarker>::inline_size(
decoder.context,
)
}
3 => <bool as fidl::encoding::TypeMarker>::inline_size(decoder.context),
4 => {
<fidl::encoding::BoundedString<255> as fidl::encoding::TypeMarker>::inline_size(
decoder.context,
)
}
_ => return Err(fidl::Error::UnknownUnionTag),
};
if inlined != (member_inline_size <= 4) {
return Err(fidl::Error::InvalidInlineBitInEnvelope);
}
let _inner_offset;
if inlined {
decoder.check_inline_envelope_padding(offset + 8, member_inline_size)?;
_inner_offset = offset + 8;
} else {
depth.increment()?;
_inner_offset = decoder.out_of_line_offset(member_inline_size)?;
}
match ordinal {
1 => {
#[allow(irrefutable_let_patterns)]
if let PropertyValue::IntValue(_) = self {
} else {
*self = PropertyValue::IntValue(fidl::new_empty!(u32));
}
#[allow(irrefutable_let_patterns)]
if let PropertyValue::IntValue(ref mut val) = self {
fidl::decode!(u32, val, decoder, _inner_offset, depth)?;
} else {
unreachable!()
}
}
2 => {
#[allow(irrefutable_let_patterns)]
if let PropertyValue::StrValue(_) = self {
} else {
*self = PropertyValue::StrValue(fidl::new_empty!(
fidl::encoding::BoundedString<255>
));
}
#[allow(irrefutable_let_patterns)]
if let PropertyValue::StrValue(ref mut val) = self {
fidl::decode!(
fidl::encoding::BoundedString<255>,
val,
decoder,
_inner_offset,
depth
)?;
} else {
unreachable!()
}
}
3 => {
#[allow(irrefutable_let_patterns)]
if let PropertyValue::BoolValue(_) = self {
} else {
*self = PropertyValue::BoolValue(fidl::new_empty!(bool));
}
#[allow(irrefutable_let_patterns)]
if let PropertyValue::BoolValue(ref mut val) = self {
fidl::decode!(bool, val, decoder, _inner_offset, depth)?;
} else {
unreachable!()
}
}
4 => {
#[allow(irrefutable_let_patterns)]
if let PropertyValue::EnumValue(_) = self {
} else {
*self = PropertyValue::EnumValue(fidl::new_empty!(
fidl::encoding::BoundedString<255>
));
}
#[allow(irrefutable_let_patterns)]
if let PropertyValue::EnumValue(ref mut val) = self {
fidl::decode!(
fidl::encoding::BoundedString<255>,
val,
decoder,
_inner_offset,
depth
)?;
} else {
unreachable!()
}
}
ordinal => panic!("unexpected ordinal {:?}", ordinal),
}
if !inlined && decoder.next_out_of_line() != next_out_of_line + (num_bytes as usize) {
return Err(fidl::Error::InvalidNumBytesInEnvelope);
}
if handles_before != decoder.remaining_handles() + (num_handles as usize) {
return Err(fidl::Error::InvalidNumHandlesInEnvelope);
}
Ok(())
}
}
}