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fuchsia / fuchsia / 6697568849879512cc8452e84c2db4c0da200466 / . / tools / fidl / fidlgen_llcpp / goldens / nullable.h.golden
blob: cfea005f131478af99be03c397167e2b62615aee [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>
#include <lib/zx/channel.h>
#include <lib/zx/vmo.h>
#endif // __Fuchsia__
#include <zircon/fidl.h>
#include <zx/llcpp/fidl.h>
namespace fidl_test_nullable {
namespace wire {
struct StructWithNullableVector;
struct StructWithNullableUnion;
struct StructWithNullableStruct;
struct StructWithNullableString;
struct StructWithNullableRequest;
struct StructWithNullableProtocol;
struct StructWithNullableHandle;
} // namespace wire
class SimpleProtocol;
namespace wire {
class SimpleUnion;
struct Int32Wrapper;
extern "C" const fidl_type_t fidl_test_nullable_SimpleUnionTable;
class SimpleUnion {
public:
SimpleUnion()
: ordinal_(::fidl_test_nullable::wire::SimpleUnion::Ordinal::Invalid),
envelope_{} {}
SimpleUnion(const SimpleUnion&) = default;
SimpleUnion& operator=(const SimpleUnion&) = default;
SimpleUnion(SimpleUnion&&) = default;
SimpleUnion& operator=(SimpleUnion&&) = default;
enum class Tag : fidl_xunion_tag_t {
kA = 1, // 0x1
kB = 2, // 0x2
};
bool has_invalid_tag() const {
return ordinal_ ==
::fidl_test_nullable::wire::SimpleUnion::Ordinal::Invalid;
}
bool is_a() const {
return ordinal_ == ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kA;
}
static SimpleUnion WithA(::fidl::ObjectView<int32_t> val) {
SimpleUnion result;
result.set_a(val);
return result;
}
template <typename... Args>
static SimpleUnion WithA(::fidl::AnyAllocator& allocator, Args&&... args) {
SimpleUnion result;
result.set_a(
::fidl::ObjectView<int32_t>(allocator, std::forward<Args>(args)...));
return result;
}
void set_a(::fidl::ObjectView<int32_t> elem) {
ordinal_ = ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kA;
envelope_.data =
::fidl::ObjectView<void>::FromExternal(static_cast<void*>(elem.get()));
}
template <typename... Args>
void set_a(::fidl::AnyAllocator& allocator, Args&&... args) {
ordinal_ = ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kA;
set_a(::fidl::ObjectView<int32_t>(allocator, std::forward<Args>(args)...));
}
int32_t& mutable_a() {
ZX_ASSERT(ordinal_ == ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kA);
return *static_cast<int32_t*>(envelope_.data.get());
}
const int32_t& a() const {
ZX_ASSERT(ordinal_ == ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kA);
return *static_cast<int32_t*>(envelope_.data.get());
}
bool is_b() const {
return ordinal_ == ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kB;
}
static SimpleUnion WithB(::fidl::ObjectView<float> val) {
SimpleUnion result;
result.set_b(val);
return result;
}
template <typename... Args>
static SimpleUnion WithB(::fidl::AnyAllocator& allocator, Args&&... args) {
SimpleUnion result;
result.set_b(
::fidl::ObjectView<float>(allocator, std::forward<Args>(args)...));
return result;
}
void set_b(::fidl::ObjectView<float> elem) {
ordinal_ = ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kB;
envelope_.data =
::fidl::ObjectView<void>::FromExternal(static_cast<void*>(elem.get()));
}
template <typename... Args>
void set_b(::fidl::AnyAllocator& allocator, Args&&... args) {
ordinal_ = ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kB;
set_b(::fidl::ObjectView<float>(allocator, std::forward<Args>(args)...));
}
float& mutable_b() {
ZX_ASSERT(ordinal_ == ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kB);
return *static_cast<float*>(envelope_.data.get());
}
const float& b() const {
ZX_ASSERT(ordinal_ == ::fidl_test_nullable::wire::SimpleUnion::Ordinal::kB);
return *static_cast<float*>(envelope_.data.get());
}
::fidl_test_nullable::wire::SimpleUnion::Tag which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<::fidl_test_nullable::wire::SimpleUnion::Tag>(ordinal_);
}
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_SimpleUnionTable;
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,
kA = 1, // 0x1
kB = 2, // 0x2
};
static void SizeAndOffsetAssertionHelper();
::fidl_test_nullable::wire::SimpleUnion::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::Envelope<void> envelope_;
};
extern "C" const fidl_type_t fidl_test_nullable_StructWithNullableVectorTable;
struct StructWithNullableVector {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_StructWithNullableVectorTable;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 16;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 4294967295;
static constexpr bool HasPointer = true;
::fidl::VectorView<int32_t> val = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
StructWithNullableVector* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(StructWithNullableVector)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<StructWithNullableVector>(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::internal::IovecBuffer iovecs_;
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructWithNullableVector* value)
: message_(backing_buffer_.data(), backing_buffer_.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::BoxedMessageBuffer<ZX_CHANNEL_MAX_MSG_BYTES>
backing_buffer_;
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 StructWithNullableVector>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructWithNullableVector>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct StructWithNullableVector* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructWithNullableVector*>(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_nullable_StructWithNullableUnionTable;
struct StructWithNullableUnion {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_StructWithNullableUnionTable;
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;
::fidl_test_nullable::wire::SimpleUnion val = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
StructWithNullableUnion* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(StructWithNullableUnion)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<StructWithNullableUnion>(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::internal::IovecBuffer iovecs_;
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructWithNullableUnion* value)
: message_(backing_buffer_.data(), backing_buffer_.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<32> backing_buffer_;
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 StructWithNullableUnion>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructWithNullableUnion>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct StructWithNullableUnion* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructWithNullableUnion*>(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_nullable_StructWithNullableStructTable;
struct StructWithNullableStruct {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_StructWithNullableStructTable;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 8;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 8;
static constexpr bool HasPointer = true;
::fidl::ObjectView<::fidl_test_nullable::wire::Int32Wrapper> val = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
StructWithNullableStruct* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(StructWithNullableStruct)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<StructWithNullableStruct>(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::internal::IovecBuffer iovecs_;
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructWithNullableStruct* value)
: message_(backing_buffer_.data(), backing_buffer_.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> backing_buffer_;
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 StructWithNullableStruct>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructWithNullableStruct>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct StructWithNullableStruct* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructWithNullableStruct*>(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_nullable_StructWithNullableStringTable;
struct StructWithNullableString {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_StructWithNullableStringTable;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 16;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 4294967295;
static constexpr bool HasPointer = true;
::fidl::StringView val = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
StructWithNullableString* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(StructWithNullableString)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<StructWithNullableString>(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::internal::IovecBuffer iovecs_;
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructWithNullableString* value)
: message_(backing_buffer_.data(), backing_buffer_.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::BoxedMessageBuffer<ZX_CHANNEL_MAX_MSG_BYTES>
backing_buffer_;
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 StructWithNullableString>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructWithNullableString>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct StructWithNullableString* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructWithNullableString*>(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(); }
};
};
#ifdef __Fuchsia__
extern "C" const fidl_type_t fidl_test_nullable_StructWithNullableRequestTable;
struct StructWithNullableRequest {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_StructWithNullableRequestTable;
static constexpr uint32_t MaxNumHandles = 1;
static constexpr uint32_t PrimarySize = 4;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 0;
static constexpr bool HasPointer = false;
::fidl::ServerEnd<::fidl_test_nullable::SimpleProtocol> val = {};
void _CloseHandles();
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
StructWithNullableRequest* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.handles = handles_,
.handle_capacity =
std::min(ZX_CHANNEL_MAX_MSG_HANDLES, MaxNumHandles),
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(StructWithNullableRequest)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<StructWithNullableRequest>(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(); }
const char* status_string() const { return message_.status_string(); }
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::internal::IovecBuffer iovecs_;
zx_handle_disposition_t
handles_[std::min(ZX_CHANNEL_MAX_MSG_HANDLES, MaxNumHandles)];
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructWithNullableRequest* value)
: message_(backing_buffer_.data(), backing_buffer_.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(); }
const char* status_string() const { return message_.status_string(); }
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<8> backing_buffer_;
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 StructWithNullableRequest>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructWithNullableRequest>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
~DecodedMessage() {
if (ok() && (PrimaryObject() != nullptr)) {
PrimaryObject()->_CloseHandles();
}
}
struct StructWithNullableRequest* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructWithNullableRequest*>(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(); }
};
};
#endif // __Fuchsia__
#ifdef __Fuchsia__
extern "C" const fidl_type_t fidl_test_nullable_StructWithNullableProtocolTable;
struct StructWithNullableProtocol {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_StructWithNullableProtocolTable;
static constexpr uint32_t MaxNumHandles = 1;
static constexpr uint32_t PrimarySize = 4;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 0;
static constexpr bool HasPointer = false;
::fidl::ClientEnd<::fidl_test_nullable::SimpleProtocol> val = {};
void _CloseHandles();
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
StructWithNullableProtocol* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.handles = handles_,
.handle_capacity =
std::min(ZX_CHANNEL_MAX_MSG_HANDLES, MaxNumHandles),
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(StructWithNullableProtocol)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<StructWithNullableProtocol>(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(); }
const char* status_string() const { return message_.status_string(); }
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::internal::IovecBuffer iovecs_;
zx_handle_disposition_t
handles_[std::min(ZX_CHANNEL_MAX_MSG_HANDLES, MaxNumHandles)];
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructWithNullableProtocol* value)
: message_(backing_buffer_.data(), backing_buffer_.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(); }
const char* status_string() const { return message_.status_string(); }
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<8> backing_buffer_;
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 StructWithNullableProtocol>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructWithNullableProtocol>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
~DecodedMessage() {
if (ok() && (PrimaryObject() != nullptr)) {
PrimaryObject()->_CloseHandles();
}
}
struct StructWithNullableProtocol* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructWithNullableProtocol*>(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(); }
};
};
#endif // __Fuchsia__
#ifdef __Fuchsia__
extern "C" const fidl_type_t fidl_test_nullable_StructWithNullableHandleTable;
struct StructWithNullableHandle {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_StructWithNullableHandleTable;
static constexpr uint32_t MaxNumHandles = 1;
static constexpr uint32_t PrimarySize = 4;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 0;
static constexpr bool HasPointer = false;
::zx::vmo val = {};
void _CloseHandles();
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
StructWithNullableHandle* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.handles = handles_,
.handle_capacity =
std::min(ZX_CHANNEL_MAX_MSG_HANDLES, MaxNumHandles),
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(StructWithNullableHandle)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<StructWithNullableHandle>(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(); }
const char* status_string() const { return message_.status_string(); }
bool ok() const { return message_.status() == ZX_OK; }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() { return message_; }
private:
::fidl::internal::IovecBuffer iovecs_;
zx_handle_disposition_t
handles_[std::min(ZX_CHANNEL_MAX_MSG_HANDLES, MaxNumHandles)];
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(StructWithNullableHandle* value)
: message_(backing_buffer_.data(), backing_buffer_.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(); }
const char* status_string() const { return message_.status_string(); }
bool ok() const { return message_.ok(); }
const char* error() const { return message_.error(); }
::fidl::OutgoingMessage& GetOutgoingMessage() {
return message_.GetOutgoingMessage();
}
private:
::fidl::internal::InlineMessageBuffer<8> backing_buffer_;
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 StructWithNullableHandle>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct StructWithNullableHandle>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
~DecodedMessage() {
if (ok() && (PrimaryObject() != nullptr)) {
PrimaryObject()->_CloseHandles();
}
}
struct StructWithNullableHandle* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct StructWithNullableHandle*>(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(); }
};
};
#endif // __Fuchsia__
} // namespace wire
extern "C" const fidl_type_t fidl_test_nullable_SimpleProtocolAddRequestTable;
extern "C" const fidl_type_t fidl_test_nullable_SimpleProtocolAddResponseTable;
class SimpleProtocol final {
SimpleProtocol() = delete;
public:
class Add final {
Add() = delete;
};
};
} // namespace fidl_test_nullable
#ifdef __Fuchsia__
template <>
struct ::fidl::internal::ProtocolDetails<::fidl_test_nullable::SimpleProtocol> {
};
#endif // __Fuchsia__
#ifdef __Fuchsia__
template <>
struct ::fidl::internal::WireDispatcher<::fidl_test_nullable::SimpleProtocol>
final {
WireDispatcher() = delete;
static ::fidl::DispatchResult TryDispatch(
::fidl::WireInterface<::fidl_test_nullable::SimpleProtocol>* impl,
fidl_incoming_msg_t* msg, ::fidl::Transaction* txn);
static ::fidl::DispatchResult Dispatch(
::fidl::WireInterface<::fidl_test_nullable::SimpleProtocol>* impl,
fidl_incoming_msg_t* msg, ::fidl::Transaction* txn);
};
template <>
struct ::fidl::internal::WireServerDispatcher<
::fidl_test_nullable::SimpleProtocol>
final {
WireServerDispatcher() = delete;
static ::fidl::DispatchResult TryDispatch(
::fidl::WireServer<::fidl_test_nullable::SimpleProtocol>* impl,
fidl_incoming_msg_t* msg, ::fidl::Transaction* txn);
static ::fidl::DispatchResult Dispatch(
::fidl::WireServer<::fidl_test_nullable::SimpleProtocol>* impl,
fidl_incoming_msg_t* msg, ::fidl::Transaction* txn);
};
#endif // __Fuchsia__
template <>
struct ::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add> final {
FIDL_ALIGNDECL
fidl_message_header_t _hdr;
int32_t a;
int32_t b;
explicit WireRequest(zx_txid_t _txid, int32_t a, int32_t b) : a(a), b(b) {
_InitHeader(_txid);
}
explicit WireRequest(zx_txid_t _txid) { _InitHeader(_txid); }
static constexpr const fidl_type_t* Type =
&::fidl_test_nullable::fidl_test_nullable_SimpleProtocolAddRequestTable;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 24;
static constexpr uint32_t MaxOutOfLine = 0;
static constexpr uint32_t AltPrimarySize = 24;
static constexpr uint32_t AltMaxOutOfLine = 0;
static constexpr bool HasFlexibleEnvelope = false;
static constexpr bool HasPointer = false;
static constexpr ::fidl::internal::TransactionalMessageKind MessageKind =
::fidl::internal::TransactionalMessageKind::kRequest;
using ResponseType =
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>;
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* _backing_buffer,
uint32_t _backing_buffer_size, zx_txid_t _txid,
int32_t a, int32_t b)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = _backing_buffer,
.backing_buffer_capacity = _backing_buffer_size,
}) {
if (_backing_buffer_size < sizeof(WireRequest)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
FIDL_ALIGNDECL WireRequest _request(_txid, a, b);
message_.Encode<WireRequest>(&_request);
}
UnownedEncodedMessage(uint8_t* _backing_buffer,
uint32_t _backing_buffer_size, WireRequest* request)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = _backing_buffer,
.backing_buffer_capacity = _backing_buffer_size,
}) {
if (_backing_buffer_size < sizeof(WireRequest)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<WireRequest>(request);
}
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_; }
#ifdef __Fuchsia__
template <typename ChannelLike>
void Write(ChannelLike&& client) {
message_.Write(std::forward<ChannelLike>(client));
}
#endif // __Fuchsia__
private:
::fidl::internal::IovecBuffer iovecs_;
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(zx_txid_t _txid, int32_t a, int32_t b)
: message_(backing_buffer_.data(), backing_buffer_.size(), _txid, a,
b) {}
explicit OwnedEncodedMessage(WireRequest* request)
: message_(backing_buffer_.data(), backing_buffer_.size(), request) {}
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();
}
#ifdef __Fuchsia__
template <typename ChannelLike>
void Write(ChannelLike&& client) {
message_.Write(std::forward<ChannelLike>(client));
}
#endif // __Fuchsia__
private:
::fidl::internal::InlineMessageBuffer<24> backing_buffer_;
UnownedEncodedMessage message_;
};
public:
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<WireRequest>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<WireRequest>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
WireRequest* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<WireRequest*>(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(); }
};
private:
void _InitHeader(zx_txid_t _txid);
};
template <>
struct ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add> final {
FIDL_ALIGNDECL
fidl_message_header_t _hdr;
int32_t sum;
explicit WireResponse(int32_t sum) : sum(sum) { _InitHeader(); }
WireResponse() { _InitHeader(); }
static constexpr const fidl_type_t* Type =
&::fidl_test_nullable::fidl_test_nullable_SimpleProtocolAddResponseTable;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 24;
static constexpr uint32_t MaxOutOfLine = 0;
static constexpr bool HasFlexibleEnvelope = false;
static constexpr bool HasPointer = false;
static constexpr ::fidl::internal::TransactionalMessageKind MessageKind =
::fidl::internal::TransactionalMessageKind::kResponse;
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* _backing_buffer,
uint32_t _backing_buffer_size, int32_t sum)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = _backing_buffer,
.backing_buffer_capacity = _backing_buffer_size,
}) {
FIDL_ALIGNDECL WireResponse _response{sum};
if (_backing_buffer_size < sizeof(WireResponse)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>>(
&_response);
}
UnownedEncodedMessage(uint8_t* _backing_buffer,
uint32_t _backing_buffer_size, WireResponse* response)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = _backing_buffer,
.backing_buffer_capacity = _backing_buffer_size,
}) {
if (_backing_buffer_size < sizeof(WireResponse)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>>(
response);
}
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_; }
#ifdef __Fuchsia__
template <typename ChannelLike>
void Write(ChannelLike&& client) {
message_.Write(std::forward<ChannelLike>(client));
}
#endif // __Fuchsia__
private:
::fidl::internal::IovecBuffer iovecs_;
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(int32_t sum)
: message_(backing_buffer_.data(), backing_buffer_.size(), sum) {}
explicit OwnedEncodedMessage(
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
response)
: message_(backing_buffer_.data(), backing_buffer_.size(), response) {}
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();
}
#ifdef __Fuchsia__
template <typename ChannelLike>
void Write(ChannelLike&& client) {
message_.Write(std::forward<ChannelLike>(client));
}
#endif // __Fuchsia__
private:
::fidl::internal::InlineMessageBuffer<24> backing_buffer_;
UnownedEncodedMessage message_;
};
public:
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<::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
WireResponse* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*>(
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(); }
};
private:
void _InitHeader();
};
template <>
class ::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add> final
: public ::fidl::Result {
public:
explicit WireResult(
::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol> _client,
int32_t a, int32_t b);
WireResult(
::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol> _client,
int32_t a, int32_t b, zx_time_t _deadline);
explicit WireResult(const ::fidl::Result& result) : ::fidl::Result(result) {}
WireResult(WireResult&&) = delete;
WireResult(const WireResult&) = delete;
WireResult* operator=(WireResult&&) = delete;
WireResult* operator=(const WireResult&) = delete;
~WireResult() = default;
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>* Unwrap() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*>(
bytes_.data());
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
Unwrap() const {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*>(
bytes_.data());
}
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>& value() {
return *Unwrap();
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>& value()
const {
return *Unwrap();
}
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
operator->() {
return &value();
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
operator->() const {
return &value();
}
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>& operator*() {
return value();
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>&
operator*() const {
return value();
}
private:
::fidl::internal::InlineMessageBuffer<24> bytes_;
};
template <>
class ::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add> final
: public ::fidl::Result {
public:
explicit WireUnownedResult(
::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol> _client,
uint8_t* _request_bytes, uint32_t _request_byte_capacity, int32_t a,
int32_t b, uint8_t* _response_bytes, uint32_t _response_byte_capacity);
explicit WireUnownedResult(const ::fidl::Result& result)
: ::fidl::Result(result) {}
WireUnownedResult(WireUnownedResult&&) = delete;
WireUnownedResult(const WireUnownedResult&) = delete;
WireUnownedResult* operator=(WireUnownedResult&&) = delete;
WireUnownedResult* operator=(const WireUnownedResult&) = delete;
~WireUnownedResult() = default;
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>* Unwrap() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*>(
bytes_);
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
Unwrap() const {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*>(
bytes_);
}
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>& value() {
return *Unwrap();
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>& value()
const {
return *Unwrap();
}
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
operator->() {
return &value();
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
operator->() const {
return &value();
}
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>& operator*() {
return value();
}
const ::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>&
operator*() const {
return value();
}
private:
uint8_t* bytes_;
};
// Methods to make a sync FIDL call directly on an unowned channel or a
// const reference to a |fidl::ClientEnd<::fidl_test_nullable::SimpleProtocol>|,
// avoiding setting up a client.
template <>
class ::fidl::internal::WireCaller<::fidl_test_nullable::SimpleProtocol> final {
public:
explicit WireCaller(
::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol> client_end)
: client_end_(client_end) {}
// Allocates 48 bytes of message buffer on the stack. No heap allocation
// necessary.
static ::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add> Add(
::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol>
_client_end,
int32_t a, int32_t b) {
return ::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add>(
_client_end, a, b);
}
// Allocates 48 bytes of message buffer on the stack. No heap allocation
// necessary.
::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add> Add(
int32_t a, int32_t b) && {
return ::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add>(
client_end_, a, b);
}
// Caller provides the backing storage for FIDL message via request and
// response buffers.
static ::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add>
Add(::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol>
_client_end,
::fidl::BufferSpan _request_buffer, int32_t a, int32_t b,
::fidl::BufferSpan _response_buffer) {
return ::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add>(
_client_end, _request_buffer.data, _request_buffer.capacity, a, b,
_response_buffer.data, _response_buffer.capacity);
}
// Caller provides the backing storage for FIDL message via request and
// response buffers.
::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add> Add(
::fidl::BufferSpan _request_buffer, int32_t a, int32_t b,
::fidl::BufferSpan _response_buffer) && {
return ::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add>(
client_end_, _request_buffer.data, _request_buffer.capacity, a, b,
_response_buffer.data, _response_buffer.capacity);
}
private:
::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol> client_end_;
};
#ifdef __Fuchsia__
template <>
class ::fidl::internal::WireEventHandlerInterface<
::fidl_test_nullable::SimpleProtocol> {
public:
WireEventHandlerInterface() = default;
virtual ~WireEventHandlerInterface() = default;
};
template <>
class ::fidl::WireAsyncEventHandler<::fidl_test_nullable::SimpleProtocol>
: public ::fidl::internal::WireEventHandlerInterface<
::fidl_test_nullable::SimpleProtocol> {
public:
WireAsyncEventHandler() = default;
virtual void Unbound(::fidl::UnbindInfo info) {}
};
template <>
class ::fidl::WireSyncEventHandler<::fidl_test_nullable::SimpleProtocol>
: public ::fidl::internal::WireEventHandlerInterface<
::fidl_test_nullable::SimpleProtocol> {
public:
WireSyncEventHandler() = default;
// Method called when an unknown event is found. This methods gives the status
// which, in this case, is returned by HandleOneEvent.
virtual zx_status_t Unknown() = 0;
// Handle all possible events defined in this protocol.
// Blocks to consume exactly one message from the channel, then call the
// corresponding virtual method.
::fidl::Result HandleOneEvent(
::fidl::UnownedClientEnd<::fidl_test_nullable::SimpleProtocol>
client_end);
};
#endif // __Fuchsia__
template <>
class ::fidl::WireSyncClient<::fidl_test_nullable::SimpleProtocol> final {
public:
WireSyncClient() = default;
explicit WireSyncClient(
::fidl::ClientEnd<::fidl_test_nullable::SimpleProtocol> client_end)
: client_end_(std::move(client_end)) {}
~WireSyncClient() = default;
WireSyncClient(WireSyncClient&&) = default;
WireSyncClient& operator=(WireSyncClient&&) = default;
const ::fidl::ClientEnd<::fidl_test_nullable::SimpleProtocol>& client_end()
const {
return client_end_;
}
::fidl::ClientEnd<::fidl_test_nullable::SimpleProtocol>& client_end() {
return client_end_;
}
const ::zx::channel& channel() const { return client_end_.channel(); }
::zx::channel* mutable_channel() { return &client_end_.channel(); }
// Allocates 48 bytes of message buffer on the stack. No heap allocation
// necessary.
::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add> Add(int32_t a,
int32_t b) {
return ::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add>(
this->client_end(), a, b);
}
// Caller provides the backing storage for FIDL message via request and
// response buffers.
::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add> Add(
::fidl::BufferSpan _request_buffer, int32_t a, int32_t b,
::fidl::BufferSpan _response_buffer) {
return ::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add>(
this->client_end(), _request_buffer.data, _request_buffer.capacity, a,
b, _response_buffer.data, _response_buffer.capacity);
}
private:
::fidl::ClientEnd<::fidl_test_nullable::SimpleProtocol> client_end_;
};
// Pure-virtual interface to be implemented by a server.
// This interface uses typed channels (i.e. |fidl::ClientEnd<SomeProtocol>|
// and |fidl::ServerEnd<SomeProtocol>|).
template <>
class ::fidl::WireServer<::fidl_test_nullable::SimpleProtocol>
: public ::fidl::internal::IncomingMessageDispatcher {
public:
WireServer() = default;
virtual ~WireServer() = default;
// The FIDL protocol type that is implemented by this server.
using _EnclosingProtocol = ::fidl_test_nullable::SimpleProtocol;
class AddCompleterBase : public ::fidl::CompleterBase {
public:
// In the following methods, the return value indicates internal errors
// during the reply, such as encoding or writing to the transport. Note that
// any error will automatically lead to the destruction of the binding,
// after which the |on_unbound| callback will be triggered with a detailed
// reason.
//
// See //zircon/system/ulib/fidl/include/lib/fidl/llcpp/server.h.
//
// Because the reply status is identical to the unbinding status, it can be
// safely ignored.
::fidl::Result Reply(int32_t sum);
::fidl::Result Reply(::fidl::BufferSpan _backing_buffer, int32_t sum);
protected:
using ::fidl::CompleterBase::CompleterBase;
};
using AddCompleter = ::fidl::Completer<AddCompleterBase>;
class AddRequestView {
public:
AddRequestView(
::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>* request)
: request_(request) {}
::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>* operator->()
const {
return request_;
}
private:
::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>* request_;
};
virtual void Add(AddRequestView request, AddCompleter::Sync& _completer) = 0;
private:
::fidl::DispatchResult dispatch_message(fidl_incoming_msg_t* msg,
::fidl::Transaction* txn) final;
};
// Pure-virtual interface to be implemented by a server.
// This interface uses typed channels (i.e. |fidl::ClientEnd<SomeProtocol>|
// and |fidl::ServerEnd<SomeProtocol>|).
template <>
class ::fidl::WireInterface<::fidl_test_nullable::SimpleProtocol>
: public ::fidl::internal::IncomingMessageDispatcher {
public:
WireInterface() = default;
virtual ~WireInterface() = default;
// The marker protocol type within which this |WireInterface| class is
// defined.
using _EnclosingProtocol = ::fidl_test_nullable::SimpleProtocol;
using AddCompleterBase = ::fidl::WireServer<
::fidl_test_nullable::SimpleProtocol>::AddCompleterBase;
using AddCompleter =
::fidl::WireServer<::fidl_test_nullable::SimpleProtocol>::AddCompleter;
virtual void Add(int32_t a, int32_t b, AddCompleter::Sync& _completer) = 0;
private:
::fidl::DispatchResult dispatch_message(fidl_incoming_msg_t* msg,
::fidl::Transaction* txn) final;
};
namespace fidl_test_nullable {
namespace wire {
extern "C" const fidl_type_t fidl_test_nullable_Int32WrapperTable;
struct Int32Wrapper {
static constexpr const fidl_type_t* Type =
&fidl_test_nullable_Int32WrapperTable;
static constexpr uint32_t MaxNumHandles = 0;
static constexpr uint32_t PrimarySize = 4;
[[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 0;
static constexpr bool HasPointer = false;
int32_t val = {};
class UnownedEncodedMessage final {
public:
UnownedEncodedMessage(uint8_t* backing_buffer, uint32_t backing_buffer_size,
Int32Wrapper* value)
: message_(::fidl::OutgoingMessage::ConstructorArgs{
.iovecs = iovecs_,
.iovec_capacity = ::fidl::internal::IovecBufferSize,
.backing_buffer = backing_buffer,
.backing_buffer_capacity = backing_buffer_size,
}) {
if (backing_buffer_size < sizeof(Int32Wrapper)) {
::fidl::internal::OutgoingMessageResultSetter::SetResult(
message_, ZX_ERR_BUFFER_TOO_SMALL, nullptr);
return;
}
message_.Encode<Int32Wrapper>(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::internal::IovecBuffer iovecs_;
::fidl::OutgoingMessage message_;
};
class OwnedEncodedMessage final {
public:
explicit OwnedEncodedMessage(Int32Wrapper* value)
: message_(backing_buffer_.data(), backing_buffer_.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<8> backing_buffer_;
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 Int32Wrapper>();
}
DecodedMessage(fidl_incoming_msg_t* msg)
: ::fidl::internal::IncomingMessage(msg) {
Decode<struct Int32Wrapper>();
}
DecodedMessage(const DecodedMessage&) = delete;
DecodedMessage(DecodedMessage&&) = delete;
DecodedMessage* operator=(const DecodedMessage&) = delete;
DecodedMessage* operator=(DecodedMessage&&) = delete;
struct Int32Wrapper* PrimaryObject() {
ZX_DEBUG_ASSERT(ok());
return reinterpret_cast<struct Int32Wrapper*>(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_nullable
namespace fidl {
template <>
struct IsFidlType<::fidl_test_nullable::wire::StructWithNullableVector>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::StructWithNullableVector>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_nullable::wire::StructWithNullableVector>);
static_assert(offsetof(::fidl_test_nullable::wire::StructWithNullableVector,
val) == 0);
static_assert(
sizeof(::fidl_test_nullable::wire::StructWithNullableVector) ==
::fidl_test_nullable::wire::StructWithNullableVector::PrimarySize);
template <>
struct IsFidlType<::fidl_test_nullable::wire::StructWithNullableUnion>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::StructWithNullableUnion>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_nullable::wire::StructWithNullableUnion>);
static_assert(offsetof(::fidl_test_nullable::wire::StructWithNullableUnion,
val) == 0);
static_assert(sizeof(::fidl_test_nullable::wire::StructWithNullableUnion) ==
::fidl_test_nullable::wire::StructWithNullableUnion::PrimarySize);
template <>
struct IsFidlType<::fidl_test_nullable::wire::StructWithNullableStruct>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::StructWithNullableStruct>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_nullable::wire::StructWithNullableStruct>);
static_assert(offsetof(::fidl_test_nullable::wire::StructWithNullableStruct,
val) == 0);
static_assert(
sizeof(::fidl_test_nullable::wire::StructWithNullableStruct) ==
::fidl_test_nullable::wire::StructWithNullableStruct::PrimarySize);
template <>
struct IsFidlType<::fidl_test_nullable::wire::StructWithNullableString>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::StructWithNullableString>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_nullable::wire::StructWithNullableString>);
static_assert(offsetof(::fidl_test_nullable::wire::StructWithNullableString,
val) == 0);
static_assert(
sizeof(::fidl_test_nullable::wire::StructWithNullableString) ==
::fidl_test_nullable::wire::StructWithNullableString::PrimarySize);
#ifdef __Fuchsia__
template <>
struct IsFidlType<::fidl_test_nullable::wire::StructWithNullableRequest>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::StructWithNullableRequest>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_nullable::wire::StructWithNullableRequest>);
static_assert(offsetof(::fidl_test_nullable::wire::StructWithNullableRequest,
val) == 0);
static_assert(
sizeof(::fidl_test_nullable::wire::StructWithNullableRequest) ==
::fidl_test_nullable::wire::StructWithNullableRequest::PrimarySize);
#endif // __Fuchsia__
#ifdef __Fuchsia__
template <>
struct IsFidlType<::fidl_test_nullable::wire::StructWithNullableProtocol>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::StructWithNullableProtocol>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_nullable::wire::StructWithNullableProtocol>);
static_assert(offsetof(::fidl_test_nullable::wire::StructWithNullableProtocol,
val) == 0);
static_assert(
sizeof(::fidl_test_nullable::wire::StructWithNullableProtocol) ==
::fidl_test_nullable::wire::StructWithNullableProtocol::PrimarySize);
#endif // __Fuchsia__
#ifdef __Fuchsia__
template <>
struct IsFidlType<::fidl_test_nullable::wire::StructWithNullableHandle>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::StructWithNullableHandle>
: public std::true_type {};
static_assert(std::is_standard_layout_v<
::fidl_test_nullable::wire::StructWithNullableHandle>);
static_assert(offsetof(::fidl_test_nullable::wire::StructWithNullableHandle,
val) == 0);
static_assert(
sizeof(::fidl_test_nullable::wire::StructWithNullableHandle) ==
::fidl_test_nullable::wire::StructWithNullableHandle::PrimarySize);
#endif // __Fuchsia__
template <>
struct IsFidlType<
::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>>
: public std::true_type {};
template <>
struct IsFidlMessage<
::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>>
: public std::true_type {};
static_assert(
sizeof(::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>) ==
::fidl::WireRequest<
::fidl_test_nullable::SimpleProtocol::Add>::PrimarySize);
static_assert(
offsetof(::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>,
a) == 16);
static_assert(
offsetof(::fidl::WireRequest<::fidl_test_nullable::SimpleProtocol::Add>,
b) == 20);
template <>
struct IsFidlType<
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>>
: public std::true_type {};
template <>
struct IsFidlMessage<
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>>
: public std::true_type {};
static_assert(
sizeof(::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>) ==
::fidl::WireResponse<
::fidl_test_nullable::SimpleProtocol::Add>::PrimarySize);
static_assert(
offsetof(::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>,
sum) == 16);
template <>
struct IsFidlType<::fidl_test_nullable::wire::SimpleUnion>
: public std::true_type {};
template <>
struct IsUnion<::fidl_test_nullable::wire::SimpleUnion>
: public std::true_type {};
static_assert(
std::is_standard_layout_v<::fidl_test_nullable::wire::SimpleUnion>);
template <>
struct IsFidlType<::fidl_test_nullable::wire::Int32Wrapper>
: public std::true_type {};
template <>
struct IsStruct<::fidl_test_nullable::wire::Int32Wrapper>
: public std::true_type {};
static_assert(
std::is_standard_layout_v<::fidl_test_nullable::wire::Int32Wrapper>);
static_assert(offsetof(::fidl_test_nullable::wire::Int32Wrapper, val) == 0);
static_assert(sizeof(::fidl_test_nullable::wire::Int32Wrapper) ==
::fidl_test_nullable::wire::Int32Wrapper::PrimarySize);
} // namespace fidl
#ifdef __Fuchsia__
template <>
class ::fidl::WireResponseContext<::fidl_test_nullable::SimpleProtocol::Add>
: public ::fidl::internal::ResponseContext {
public:
WireResponseContext();
virtual void OnReply(
::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
message) = 0;
private:
void OnReply(uint8_t* reply) override;
};
#endif // __Fuchsia__
#ifdef __Fuchsia__
template <>
class ::fidl::internal::WireClientImpl<::fidl_test_nullable::SimpleProtocol>
final : private ::fidl::internal::ClientBase {
public:
// Asynchronous variant of |SimpleProtocol.Add()|.
// Allocates 24 bytes of request buffer on the stack. The callback is stored
// on the heap.
::fidl::Result Add(
int32_t a, int32_t b,
::fit::callback<
void(::fidl::WireResponse<::fidl_test_nullable::SimpleProtocol::Add>*
response)>
_cb);
// Asynchronous variant of |SimpleProtocol.Add()|.
// Caller provides the backing storage for FIDL message via request buffer.
// Ownership of |_context| is given unsafely to the binding until |OnError|
// or |OnReply| are called on it.
::fidl::Result Add(
::fidl::BufferSpan _request_buffer, int32_t a, int32_t b,
::fidl::WireResponseContext<::fidl_test_nullable::SimpleProtocol::Add>*
_context);
// Synchronous variant of |SimpleProtocol.Add()|.
// Allocates 48 bytes of message buffer on the stack. No heap allocation
// necessary.
::fidl::WireResult<::fidl_test_nullable::SimpleProtocol::Add> Add_Sync(
int32_t a, int32_t b);
// Synchronous variant of |SimpleProtocol.Add()|.
// Caller provides the backing storage for FIDL message via request and
// response buffers.
::fidl::WireUnownedResult<::fidl_test_nullable::SimpleProtocol::Add> Add_Sync(
::fidl::BufferSpan _request_buffer, int32_t a, int32_t b,
::fidl::BufferSpan _response_buffer);
::fidl::WireAsyncEventHandler<::fidl_test_nullable::SimpleProtocol>*
event_handler() const {
return event_handler_.get();
}
private:
friend class ::fidl::Client<::fidl_test_nullable::SimpleProtocol>;
friend class ::fidl::internal::ControlBlock<
::fidl_test_nullable::SimpleProtocol>;
explicit WireClientImpl(
std::shared_ptr<
::fidl::WireAsyncEventHandler<::fidl_test_nullable::SimpleProtocol>>
event_handler)
: event_handler_(std::move(event_handler)) {}
std::optional<::fidl::UnbindInfo> DispatchEvent(
fidl_incoming_msg_t* msg) override;
std::shared_ptr<
::fidl::WireAsyncEventHandler<::fidl_test_nullable::SimpleProtocol>>
event_handler_;
};
#endif // __Fuchsia__
#ifdef __Fuchsia__
// |EventSender| owns a server endpoint of a channel speaking
// the SimpleProtocol protocol, and can send events in that protocol.
template <>
class ::fidl::WireEventSender<::fidl_test_nullable::SimpleProtocol> {
public:
// Constructs an event sender with an invalid channel.
WireEventSender() = default;
explicit WireEventSender(
::fidl::ServerEnd<::fidl_test_nullable::SimpleProtocol> server_end)
: server_end_(std::move(server_end)) {}
// The underlying server channel endpoint, which may be replaced at run-time.
const ::fidl::ServerEnd<::fidl_test_nullable::SimpleProtocol>& server_end()
const {
return server_end_;
}
::fidl::ServerEnd<::fidl_test_nullable::SimpleProtocol>& server_end() {
return server_end_;
}
const ::zx::channel& channel() const { return server_end_.channel(); }
::zx::channel& channel() { return server_end_.channel(); }
// Whether the underlying channel is valid.
bool is_valid() const { return server_end_.is_valid(); }
private:
::fidl::ServerEnd<::fidl_test_nullable::SimpleProtocol> server_end_;
};
template <>
class ::fidl::internal::WireWeakEventSender<
::fidl_test_nullable::SimpleProtocol> {
public:
private:
friend class ::fidl::ServerBindingRef<::fidl_test_nullable::SimpleProtocol>;
explicit WireWeakEventSender(
std::weak_ptr<::fidl::internal::AsyncServerBinding<
::fidl_test_nullable::SimpleProtocol>>
binding)
: binding_(std::move(binding)) {}
std::weak_ptr<::fidl::internal::AsyncServerBinding<
::fidl_test_nullable::SimpleProtocol>>
binding_;
};
#endif // __Fuchsia__