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fuchsia / fuchsia / c46e161d2d61e35b4d90ed962fa02839309831bb / . / tools / fidl / fidlgen_llcpp / goldens / union_sandwich.h.golden
blob: fd4d6975dfebbcd5b5f31f721d987cf47f3b84a9 [file] [log] [blame]
// WARNING: This file is machine generated by fidlgen.
#pragma once
#include <lib/fidl/internal.h>
#include <lib/fidl/llcpp/array.h>
#include <lib/fidl/llcpp/coding.h>
#include <lib/fidl/llcpp/envelope.h>
#include <lib/fidl/llcpp/errors.h>
#include <lib/fidl/llcpp/message.h>
#include <lib/fidl/llcpp/message_storage.h>
#include <lib/fidl/llcpp/object_view.h>
#include <lib/fidl/llcpp/string_view.h>
#include <lib/fidl/llcpp/traits.h>
#include <lib/fidl/llcpp/vector_view.h>
#include <lib/fit/function.h>
#include <lib/stdcompat/optional.h>
#include <algorithm>
#include <cstddef>
#include <variant>
#ifdef __Fuchsia__
#include <lib/fidl/llcpp/client.h>
#include <lib/fidl/llcpp/client_end.h>
#include <lib/fidl/llcpp/connect_service.h>
#include <lib/fidl/llcpp/result.h>
#include <lib/fidl/llcpp/server.h>
#include <lib/fidl/llcpp/server_end.h>
#include <lib/fidl/llcpp/service_handler_interface.h>
#include <lib/fidl/llcpp/sync_call.h>
#include <lib/fidl/llcpp/transaction.h>
#include <lib/fidl/llcpp/wire_messaging.h>
#include <lib/fidl/txn_header.h>
#endif // __Fuchsia__
#include <zircon/fidl.h>
namespace fidl_test_unionsandwich {
namespace wire {
class UnionSize8Alignment4;
struct SandwichUnionSize8Alignment4;
class UnionSize36Alignment4;
struct SandwichUnionSize36Alignment4;
class UnionSize12Alignment4;
struct SandwichUnionSize12Alignment4;
struct StructSize16Alignment8;
class UnionSize24Alignment8;
struct SandwichUnionSize24Alignment8;
extern "C" const fidl_type_t fidl_test_unionsandwich_UnionSize8Alignment4Table;
class UnionSize8Alignment4 {
public:
UnionSize8Alignment4()
: ordinal_(::fidl_test_unionsandwich::wire::UnionSize8Alignment4::
Ordinal::Invalid),
envelope_{} {}
UnionSize8Alignment4(const UnionSize8Alignment4&) = default;
UnionSize8Alignment4& operator=(const UnionSize8Alignment4&) = default;
UnionSize8Alignment4(UnionSize8Alignment4&&) = default;
UnionSize8Alignment4& operator=(UnionSize8Alignment4&&) = default;
enum class Tag : fidl_xunion_tag_t {
kVariant = 1, // 0x1
};
bool has_invalid_tag() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize8Alignment4::
Ordinal::Invalid;
}
bool is_variant() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize8Alignment4::
Ordinal::kVariant;
}
static UnionSize8Alignment4 WithVariant(::fidl::ObjectView<uint32_t> val) {
UnionSize8Alignment4 result;
result.set_variant(val);
return result;
}
template <typename... Args>
static UnionSize8Alignment4 WithVariant(::fidl::AnyAllocator& allocator,
Args&&... args) {
UnionSize8Alignment4 result;
result.set_variant(
::fidl::ObjectView<uint32_t>(allocator, std::forward<Args>(args)...));
return result;
}
void set_variant(::fidl::ObjectView<uint32_t> elem) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize8Alignment4::Ordinal::
kVariant;
envelope_.data =
::fidl::ObjectView<void>::FromExternal(static_cast<void*>(elem.get()));
}
template <typename... Args>
void set_variant(::fidl::AnyAllocator& allocator, Args&&... args) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize8Alignment4::Ordinal::
kVariant;
set_variant(
::fidl::ObjectView<uint32_t>(allocator, std::forward<Args>(args)...));
}
uint32_t& mutable_variant() {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize8Alignment4::Ordinal::kVariant);
return *static_cast<uint32_t*>(envelope_.data.get());
}
const uint32_t& variant() const {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize8Alignment4::Ordinal::kVariant);
return *static_cast<uint32_t*>(envelope_.data.get());
}
::fidl_test_unionsandwich::wire::UnionSize8Alignment4::Tag which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<
::fidl_test_unionsandwich::wire::UnionSize8Alignment4::Tag>(ordinal_);
}
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_UnionSize8Alignment4Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 24;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 8;
static constexpr bool HasPointer = true;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kVariant = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::fidl_test_unionsandwich::wire::UnionSize8Alignment4::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::Envelope<void> envelope_;
};
extern "C" const fidl_type_t fidl_test_unionsandwich_UnionSize36Alignment4Table;
class UnionSize36Alignment4 {
public:
UnionSize36Alignment4()
: ordinal_(::fidl_test_unionsandwich::wire::UnionSize36Alignment4::
Ordinal::Invalid),
envelope_{} {}
UnionSize36Alignment4(const UnionSize36Alignment4&) = default;
UnionSize36Alignment4& operator=(const UnionSize36Alignment4&) = default;
UnionSize36Alignment4(UnionSize36Alignment4&&) = default;
UnionSize36Alignment4& operator=(UnionSize36Alignment4&&) = default;
enum class Tag : fidl_xunion_tag_t {
kVariant = 1, // 0x1
};
bool has_invalid_tag() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize36Alignment4::
Ordinal::Invalid;
}
bool is_variant() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize36Alignment4::
Ordinal::kVariant;
}
static UnionSize36Alignment4 WithVariant(
::fidl::ObjectView<::fidl::Array<uint8_t, 32>> val) {
UnionSize36Alignment4 result;
result.set_variant(val);
return result;
}
template <typename... Args>
static UnionSize36Alignment4 WithVariant(::fidl::AnyAllocator& allocator,
Args&&... args) {
UnionSize36Alignment4 result;
result.set_variant(::fidl::ObjectView<::fidl::Array<uint8_t, 32>>(
allocator, std::forward<Args>(args)...));
return result;
}
void set_variant(::fidl::ObjectView<::fidl::Array<uint8_t, 32>> elem) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize36Alignment4::Ordinal::
kVariant;
envelope_.data =
::fidl::ObjectView<void>::FromExternal(static_cast<void*>(elem.get()));
}
template <typename... Args>
void set_variant(::fidl::AnyAllocator& allocator, Args&&... args) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize36Alignment4::Ordinal::
kVariant;
set_variant(::fidl::ObjectView<::fidl::Array<uint8_t, 32>>(
allocator, std::forward<Args>(args)...));
}
::fidl::Array<uint8_t, 32>& mutable_variant() {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize36Alignment4::Ordinal::kVariant);
return *static_cast<::fidl::Array<uint8_t, 32>*>(envelope_.data.get());
}
const ::fidl::Array<uint8_t, 32>& variant() const {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize36Alignment4::Ordinal::kVariant);
return *static_cast<::fidl::Array<uint8_t, 32>*>(envelope_.data.get());
}
::fidl_test_unionsandwich::wire::UnionSize36Alignment4::Tag which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<
::fidl_test_unionsandwich::wire::UnionSize36Alignment4::Tag>(ordinal_);
}
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_UnionSize36Alignment4Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 24;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 32;
static constexpr bool HasPointer = true;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kVariant = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::fidl_test_unionsandwich::wire::UnionSize36Alignment4::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::Envelope<void> envelope_;
};
extern "C" const fidl_type_t fidl_test_unionsandwich_UnionSize12Alignment4Table;
class UnionSize12Alignment4 {
public:
UnionSize12Alignment4()
: ordinal_(::fidl_test_unionsandwich::wire::UnionSize12Alignment4::
Ordinal::Invalid),
envelope_{} {}
UnionSize12Alignment4(const UnionSize12Alignment4&) = default;
UnionSize12Alignment4& operator=(const UnionSize12Alignment4&) = default;
UnionSize12Alignment4(UnionSize12Alignment4&&) = default;
UnionSize12Alignment4& operator=(UnionSize12Alignment4&&) = default;
enum class Tag : fidl_xunion_tag_t {
kVariant = 1, // 0x1
};
bool has_invalid_tag() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize12Alignment4::
Ordinal::Invalid;
}
bool is_variant() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize12Alignment4::
Ordinal::kVariant;
}
static UnionSize12Alignment4 WithVariant(
::fidl::ObjectView<::fidl::Array<uint8_t, 6>> val) {
UnionSize12Alignment4 result;
result.set_variant(val);
return result;
}
template <typename... Args>
static UnionSize12Alignment4 WithVariant(::fidl::AnyAllocator& allocator,
Args&&... args) {
UnionSize12Alignment4 result;
result.set_variant(::fidl::ObjectView<::fidl::Array<uint8_t, 6>>(
allocator, std::forward<Args>(args)...));
return result;
}
void set_variant(::fidl::ObjectView<::fidl::Array<uint8_t, 6>> elem) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize12Alignment4::Ordinal::
kVariant;
envelope_.data =
::fidl::ObjectView<void>::FromExternal(static_cast<void*>(elem.get()));
}
template <typename... Args>
void set_variant(::fidl::AnyAllocator& allocator, Args&&... args) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize12Alignment4::Ordinal::
kVariant;
set_variant(::fidl::ObjectView<::fidl::Array<uint8_t, 6>>(
allocator, std::forward<Args>(args)...));
}
::fidl::Array<uint8_t, 6>& mutable_variant() {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize12Alignment4::Ordinal::kVariant);
return *static_cast<::fidl::Array<uint8_t, 6>*>(envelope_.data.get());
}
const ::fidl::Array<uint8_t, 6>& variant() const {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize12Alignment4::Ordinal::kVariant);
return *static_cast<::fidl::Array<uint8_t, 6>*>(envelope_.data.get());
}
::fidl_test_unionsandwich::wire::UnionSize12Alignment4::Tag which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<
::fidl_test_unionsandwich::wire::UnionSize12Alignment4::Tag>(ordinal_);
}
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_UnionSize12Alignment4Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 24;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 8;
static constexpr bool HasPointer = true;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kVariant = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::fidl_test_unionsandwich::wire::UnionSize12Alignment4::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::Envelope<void> envelope_;
};
extern "C" const fidl_type_t fidl_test_unionsandwich_UnionSize24Alignment8Table;
class UnionSize24Alignment8 {
public:
UnionSize24Alignment8()
: ordinal_(::fidl_test_unionsandwich::wire::UnionSize24Alignment8::
Ordinal::Invalid),
envelope_{} {}
UnionSize24Alignment8(const UnionSize24Alignment8&) = default;
UnionSize24Alignment8& operator=(const UnionSize24Alignment8&) = default;
UnionSize24Alignment8(UnionSize24Alignment8&&) = default;
UnionSize24Alignment8& operator=(UnionSize24Alignment8&&) = default;
enum class Tag : fidl_xunion_tag_t {
kVariant = 1, // 0x1
};
bool has_invalid_tag() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize24Alignment8::
Ordinal::Invalid;
}
bool is_variant() const {
return ordinal_ == ::fidl_test_unionsandwich::wire::UnionSize24Alignment8::
Ordinal::kVariant;
}
static UnionSize24Alignment8 WithVariant(
::fidl::ObjectView<
::fidl_test_unionsandwich::wire::StructSize16Alignment8>
val) {
UnionSize24Alignment8 result;
result.set_variant(val);
return result;
}
template <typename... Args>
static UnionSize24Alignment8 WithVariant(::fidl::AnyAllocator& allocator,
Args&&... args) {
UnionSize24Alignment8 result;
result.set_variant(::fidl::ObjectView<
::fidl_test_unionsandwich::wire::StructSize16Alignment8>(
allocator, std::forward<Args>(args)...));
return result;
}
void set_variant(::fidl::ObjectView<
::fidl_test_unionsandwich::wire::StructSize16Alignment8>
elem) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize24Alignment8::Ordinal::
kVariant;
envelope_.data =
::fidl::ObjectView<void>::FromExternal(static_cast<void*>(elem.get()));
}
template <typename... Args>
void set_variant(::fidl::AnyAllocator& allocator, Args&&... args) {
ordinal_ = ::fidl_test_unionsandwich::wire::UnionSize24Alignment8::Ordinal::
kVariant;
set_variant(::fidl::ObjectView<
::fidl_test_unionsandwich::wire::StructSize16Alignment8>(
allocator, std::forward<Args>(args)...));
}
::fidl_test_unionsandwich::wire::StructSize16Alignment8& mutable_variant() {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize24Alignment8::Ordinal::kVariant);
return *static_cast<
::fidl_test_unionsandwich::wire::StructSize16Alignment8*>(
envelope_.data.get());
}
const ::fidl_test_unionsandwich::wire::StructSize16Alignment8& variant()
const {
ZX_ASSERT(ordinal_ == ::fidl_test_unionsandwich::wire::
UnionSize24Alignment8::Ordinal::kVariant);
return *static_cast<
::fidl_test_unionsandwich::wire::StructSize16Alignment8*>(
envelope_.data.get());
}
::fidl_test_unionsandwich::wire::UnionSize24Alignment8::Tag which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<
::fidl_test_unionsandwich::wire::UnionSize24Alignment8::Tag>(ordinal_);
}
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_UnionSize24Alignment8Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 24;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 16;
static constexpr bool HasPointer = true;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kVariant = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::fidl_test_unionsandwich::wire::UnionSize24Alignment8::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::Envelope<void> envelope_;
};
extern "C" const fidl_type_t
fidl_test_unionsandwich_SandwichUnionSize8Alignment4Table;
struct SandwichUnionSize8Alignment4 {
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_SandwichUnionSize8Alignment4Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 40;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 8;
static constexpr bool HasPointer = true;
uint32_t before = {};
::fidl_test_unionsandwich::wire::UnionSize8Alignment4 union_ = {};
uint32_t after = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* bytes, uint32_t byte_size,
SandwichUnionSize8Alignment4* value)
: message_(bytes, byte_size, sizeof(SandwichUnionSize8Alignment4),
nullptr, 0, 0) {
message_.Encode<SandwichUnionSize8Alignment4>(value);
}
UnownedEncodedMessage(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage(UnownedEncodedMessage&&) = delete;
UnownedEncodedMessage* operator=(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage* operator=(UnownedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(SandwichUnionSize8Alignment4* value)
: message_(bytes_.data(), bytes_.size(), value) {}
OwnedEncodedMessage(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage(OwnedEncodedMessage&&) = delete;
OwnedEncodedMessage* operator=(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage* operator=(OwnedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<48> bytes_;
UnownedEncodedMessage message_;
};
class DecodedMessage final : public ::fidl::internal::IncomingMessage {
public:
DecodedMessage(uint8_t* bytes, uint32_t byte_actual,
zx_handle_info_t* handles = nullptr,
uint32_t handle_actual = 0)
: ::fidl::internal::IncomingMessage(bytes, byte_actual, handles,
handle_actual) {
Decode<struct SandwichUnionSize8Alignment4>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct SandwichUnionSize8Alignment4>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct SandwichUnionSize8Alignment4* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct SandwichUnionSize8Alignment4*>(bytes());
}
// Release the ownership of the decoded message. That means that the handles
// won't be closed When the object is destroyed. After calling this method,
// the DecodedMessage object should not be used anymore.
void ReleasePrimaryObject() { ResetBytes(); }
};
};
extern "C" const fidl_type_t
fidl_test_unionsandwich_SandwichUnionSize36Alignment4Table;
struct SandwichUnionSize36Alignment4 {
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_SandwichUnionSize36Alignment4Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 40;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 32;
static constexpr bool HasPointer = true;
uint32_t before = {};
::fidl_test_unionsandwich::wire::UnionSize36Alignment4 union_ = {};
uint32_t after = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* bytes, uint32_t byte_size,
SandwichUnionSize36Alignment4* value)
: message_(bytes, byte_size, sizeof(SandwichUnionSize36Alignment4),
nullptr, 0, 0) {
message_.Encode<SandwichUnionSize36Alignment4>(value);
}
UnownedEncodedMessage(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage(UnownedEncodedMessage&&) = delete;
UnownedEncodedMessage* operator=(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage* operator=(UnownedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(SandwichUnionSize36Alignment4* value)
: message_(bytes_.data(), bytes_.size(), value) {}
OwnedEncodedMessage(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage(OwnedEncodedMessage&&) = delete;
OwnedEncodedMessage* operator=(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage* operator=(OwnedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<72> bytes_;
UnownedEncodedMessage message_;
};
class DecodedMessage final : public ::fidl::internal::IncomingMessage {
public:
DecodedMessage(uint8_t* bytes, uint32_t byte_actual,
zx_handle_info_t* handles = nullptr,
uint32_t handle_actual = 0)
: ::fidl::internal::IncomingMessage(bytes, byte_actual, handles,
handle_actual) {
Decode<struct SandwichUnionSize36Alignment4>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct SandwichUnionSize36Alignment4>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct SandwichUnionSize36Alignment4* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct SandwichUnionSize36Alignment4*>(bytes());
}
// Release the ownership of the decoded message. That means that the handles
// won't be closed When the object is destroyed. After calling this method,
// the DecodedMessage object should not be used anymore.
void ReleasePrimaryObject() { ResetBytes(); }
};
};
extern "C" const fidl_type_t
fidl_test_unionsandwich_SandwichUnionSize12Alignment4Table;
struct SandwichUnionSize12Alignment4 {
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_SandwichUnionSize12Alignment4Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 40;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 8;
static constexpr bool HasPointer = true;
uint32_t before = {};
::fidl_test_unionsandwich::wire::UnionSize12Alignment4 union_ = {};
int32_t after = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* bytes, uint32_t byte_size,
SandwichUnionSize12Alignment4* value)
: message_(bytes, byte_size, sizeof(SandwichUnionSize12Alignment4),
nullptr, 0, 0) {
message_.Encode<SandwichUnionSize12Alignment4>(value);
}
UnownedEncodedMessage(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage(UnownedEncodedMessage&&) = delete;
UnownedEncodedMessage* operator=(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage* operator=(UnownedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(SandwichUnionSize12Alignment4* value)
: message_(bytes_.data(), bytes_.size(), value) {}
OwnedEncodedMessage(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage(OwnedEncodedMessage&&) = delete;
OwnedEncodedMessage* operator=(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage* operator=(OwnedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<48> bytes_;
UnownedEncodedMessage message_;
};
class DecodedMessage final : public ::fidl::internal::IncomingMessage {
public:
DecodedMessage(uint8_t* bytes, uint32_t byte_actual,
zx_handle_info_t* handles = nullptr,
uint32_t handle_actual = 0)
: ::fidl::internal::IncomingMessage(bytes, byte_actual, handles,
handle_actual) {
Decode<struct SandwichUnionSize12Alignment4>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct SandwichUnionSize12Alignment4>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct SandwichUnionSize12Alignment4* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct SandwichUnionSize12Alignment4*>(bytes());
}
// Release the ownership of the decoded message. That means that the handles
// won't be closed When the object is destroyed. After calling this method,
// the DecodedMessage object should not be used anymore.
void ReleasePrimaryObject() { ResetBytes(); }
};
};
extern "C" const fidl_type_t
fidl_test_unionsandwich_StructSize16Alignment8Table;
struct StructSize16Alignment8 {
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_StructSize16Alignment8Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 16;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 0;
static constexpr bool HasPointer = false;
uint64_t f1 = {};
uint64_t f2 = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* bytes, uint32_t byte_size,
StructSize16Alignment8* value)
: message_(bytes, byte_size, sizeof(StructSize16Alignment8), nullptr, 0,
0) {
message_.Encode<StructSize16Alignment8>(value);
}
UnownedEncodedMessage(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage(UnownedEncodedMessage&&) = delete;
UnownedEncodedMessage* operator=(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage* operator=(UnownedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructSize16Alignment8* value)
: message_(bytes_.data(), bytes_.size(), value) {}
OwnedEncodedMessage(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage(OwnedEncodedMessage&&) = delete;
OwnedEncodedMessage* operator=(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage* operator=(OwnedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<16> bytes_;
UnownedEncodedMessage message_;
};
class DecodedMessage final : public ::fidl::internal::IncomingMessage {
public:
DecodedMessage(uint8_t* bytes, uint32_t byte_actual,
zx_handle_info_t* handles = nullptr,
uint32_t handle_actual = 0)
: ::fidl::internal::IncomingMessage(bytes, byte_actual, handles,
handle_actual) {
Decode<struct StructSize16Alignment8>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructSize16Alignment8>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct StructSize16Alignment8* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructSize16Alignment8*>(bytes());
}
// Release the ownership of the decoded message. That means that the handles
// won't be closed When the object is destroyed. After calling this method,
// the DecodedMessage object should not be used anymore.
void ReleasePrimaryObject() { ResetBytes(); }
};
};
extern "C" const fidl_type_t
fidl_test_unionsandwich_SandwichUnionSize24Alignment8Table;
struct SandwichUnionSize24Alignment8 {
static constexpr const fidl_type_t* Type =
&fidl_test_unionsandwich_SandwichUnionSize24Alignment8Table;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 40;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 16;
static constexpr bool HasPointer = true;
uint32_t before = {};
::fidl_test_unionsandwich::wire::UnionSize24Alignment8 union_ = {};
uint32_t after = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* bytes, uint32_t byte_size,
SandwichUnionSize24Alignment8* value)
: message_(bytes, byte_size, sizeof(SandwichUnionSize24Alignment8),
nullptr, 0, 0) {
message_.Encode<SandwichUnionSize24Alignment8>(value);
}
UnownedEncodedMessage(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage(UnownedEncodedMessage&&) = delete;
UnownedEncodedMessage* operator=(const UnownedEncodedMessage&) = delete;
UnownedEncodedMessage* operator=(UnownedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(SandwichUnionSize24Alignment8* value)
: message_(bytes_.data(), bytes_.size(), value) {}
OwnedEncodedMessage(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage(OwnedEncodedMessage&&) = delete;
OwnedEncodedMessage* operator=(const OwnedEncodedMessage&) = delete;
OwnedEncodedMessage* operator=(OwnedEncodedMessage&&) = delete;
zx_status_t status() const { return message_.status(); }
#ifdef __Fuchsia__
const char* status_string() const { return message_.status_string(); }
#endif // __Fuchsia__
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<56> bytes_;
UnownedEncodedMessage message_;
};
class DecodedMessage final : public ::fidl::internal::IncomingMessage {
public:
DecodedMessage(uint8_t* bytes, uint32_t byte_actual,
zx_handle_info_t* handles = nullptr,
uint32_t handle_actual = 0)
: ::fidl::internal::IncomingMessage(bytes, byte_actual, handles,
handle_actual) {
Decode<struct SandwichUnionSize24Alignment8>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct SandwichUnionSize24Alignment8>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct SandwichUnionSize24Alignment8* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct SandwichUnionSize24Alignment8*>(bytes());
}
// Release the ownership of the decoded message. That means that the handles
// won't be closed When the object is destroyed. After calling this method,
// the DecodedMessage object should not be used anymore.
void ReleasePrimaryObject() { ResetBytes(); }
};
};
} // namespace wire
} // namespace fidl_test_unionsandwich
namespace fidl {
template <>
struct IsFidlType<::fidl_test_unionsandwich::wire::UnionSize8Alignment4>
: public std::true_type {};
template <>
struct IsUnion<::fidl_test_unionsandwich::wire::UnionSize8Alignment4>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::UnionSize8Alignment4>);
template <>
struct IsFidlType<::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4>);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4,
before) == 0);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4,
union_) == 8);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4,
after) == 32);
static_assert(
sizeof(::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4) ==
::fidl_test_unionsandwich::wire::SandwichUnionSize8Alignment4::PrimarySize);
template <>
struct IsFidlType<::fidl_test_unionsandwich::wire::UnionSize36Alignment4>
: public std::true_type {};
template <>
struct IsUnion<::fidl_test_unionsandwich::wire::UnionSize36Alignment4>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::UnionSize36Alignment4>);
template <>
struct IsFidlType<
::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4>);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4,
before) == 0);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4,
union_) == 8);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4,
after) == 32);
static_assert(
sizeof(::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4) ==
::fidl_test_unionsandwich::wire::SandwichUnionSize36Alignment4::
PrimarySize);
template <>
struct IsFidlType<::fidl_test_unionsandwich::wire::UnionSize12Alignment4>
: public std::true_type {};
template <>
struct IsUnion<::fidl_test_unionsandwich::wire::UnionSize12Alignment4>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::UnionSize12Alignment4>);
template <>
struct IsFidlType<
::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4>);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4,
before) == 0);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4,
union_) == 8);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4,
after) == 32);
static_assert(
sizeof(::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4) ==
::fidl_test_unionsandwich::wire::SandwichUnionSize12Alignment4::
PrimarySize);
template <>
struct IsFidlType<::fidl_test_unionsandwich::wire::StructSize16Alignment8>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_unionsandwich::wire::StructSize16Alignment8>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::StructSize16Alignment8>);
static_assert(offsetof(::fidl_test_unionsandwich::wire::StructSize16Alignment8,
f1) == 0);
static_assert(offsetof(::fidl_test_unionsandwich::wire::StructSize16Alignment8,
f2) == 8);
static_assert(
sizeof(::fidl_test_unionsandwich::wire::StructSize16Alignment8) ==
::fidl_test_unionsandwich::wire::StructSize16Alignment8::PrimarySize);
template <>
struct IsFidlType<::fidl_test_unionsandwich::wire::UnionSize24Alignment8>
: public std::true_type {};
template <>
struct IsUnion<::fidl_test_unionsandwich::wire::UnionSize24Alignment8>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::UnionSize24Alignment8>);
template <>
struct IsFidlType<
::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8>);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8,
before) == 0);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8,
union_) == 8);
static_assert(
offsetof(::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8,
after) == 32);
static_assert(
sizeof(::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8) ==
::fidl_test_unionsandwich::wire::SandwichUnionSize24Alignment8::
PrimarySize);
} // namespace fidl