blob: beb72fd0250c22c3702ea9ce240dce0d284dd837 [file] [log] [blame]
// WARNING: This file is machine generated by fidlgen.
#include <inheritance_with_recursive_decl.test.json.llcpp.h>
#include <memory>
namespace llcpp {
namespace fidl {
namespace test {
namespace json {
namespace {
[[maybe_unused]] constexpr uint64_t kParent_First_Ordinal =
0x66a95ddc00000000lu;
[[maybe_unused]] constexpr uint64_t kParent_First_GenOrdinal =
0x239f8fdea8de880clu;
extern "C" const fidl_type_t v1_fidl_test_json_ParentFirstRequestTable;
extern "C" const fidl_type_t v1_fidl_test_json_ParentFirstResponseTable;
} // namespace
Parent::ResultOf::First_Impl::First_Impl(::zx::unowned_channel _client_end,
::zx::channel request) {
constexpr uint32_t _kWriteAllocSize = ::fidl::internal::ClampedMessageSize<
FirstRequest, ::fidl::MessageDirection::kSending>();
::fidl::internal::AlignedBuffer<_kWriteAllocSize> _write_bytes_inlined;
auto& _write_bytes_array = _write_bytes_inlined;
uint8_t* _write_bytes = _write_bytes_array.view().data();
memset(_write_bytes, 0, FirstRequest::PrimarySize);
auto& _request = *reinterpret_cast<FirstRequest*>(_write_bytes);
_request.request = std::move(request);
::fidl::BytePart _request_bytes(_write_bytes, _kWriteAllocSize,
sizeof(FirstRequest));
::fidl::DecodedMessage<FirstRequest> _decoded_request(
std::move(_request_bytes));
Super::operator=(Parent::InPlace::First(std::move(_client_end),
std::move(_decoded_request)));
}
Parent::ResultOf::First Parent::SyncClient::First(::zx::channel request) {
return ResultOf::First(::zx::unowned_channel(this->channel_),
std::move(request));
}
Parent::ResultOf::First Parent::Call::First(::zx::unowned_channel _client_end,
::zx::channel request) {
return ResultOf::First(std::move(_client_end), std::move(request));
}
Parent::UnownedResultOf::First_Impl::First_Impl(
::zx::unowned_channel _client_end, ::fidl::BytePart _request_buffer,
::zx::channel request) {
if (_request_buffer.capacity() < FirstRequest::PrimarySize) {
Super::status_ = ZX_ERR_BUFFER_TOO_SMALL;
Super::error_ = ::fidl::internal::kErrorRequestBufferTooSmall;
return;
}
memset(_request_buffer.data(), 0, FirstRequest::PrimarySize);
auto& _request = *reinterpret_cast<FirstRequest*>(_request_buffer.data());
_request.request = std::move(request);
_request_buffer.set_actual(sizeof(FirstRequest));
::fidl::DecodedMessage<FirstRequest> _decoded_request(
std::move(_request_buffer));
Super::operator=(Parent::InPlace::First(std::move(_client_end),
std::move(_decoded_request)));
}
Parent::UnownedResultOf::First Parent::SyncClient::First(
::fidl::BytePart _request_buffer, ::zx::channel request) {
return UnownedResultOf::First(::zx::unowned_channel(this->channel_),
std::move(_request_buffer), std::move(request));
}
Parent::UnownedResultOf::First Parent::Call::First(
::zx::unowned_channel _client_end, ::fidl::BytePart _request_buffer,
::zx::channel request) {
return UnownedResultOf::First(std::move(_client_end),
std::move(_request_buffer), std::move(request));
}
::fidl::internal::StatusAndError Parent::InPlace::First(
::zx::unowned_channel _client_end,
::fidl::DecodedMessage<FirstRequest> params) {
Parent::SetTransactionHeaderFor::FirstRequest(params);
auto _encode_request_result = ::fidl::Encode(std::move(params));
if (_encode_request_result.status != ZX_OK) {
return ::fidl::internal::StatusAndError::FromFailure(
std::move(_encode_request_result));
}
zx_status_t _write_status = ::fidl::Write(
std::move(_client_end), std::move(_encode_request_result.message));
if (_write_status != ZX_OK) {
return ::fidl::internal::StatusAndError(
_write_status, ::fidl::internal::kErrorWriteFailed);
} else {
return ::fidl::internal::StatusAndError(ZX_OK, nullptr);
}
}
bool Parent::TryDispatch(Interface* impl, fidl_msg_t* msg,
::fidl::Transaction* txn) {
if (msg->num_bytes < sizeof(fidl_message_header_t)) {
zx_handle_close_many(msg->handles, msg->num_handles);
txn->Close(ZX_ERR_INVALID_ARGS);
return true;
}
fidl_message_header_t* hdr =
reinterpret_cast<fidl_message_header_t*>(msg->bytes);
zx_status_t status = fidl_validate_txn_header(hdr);
if (status != ZX_OK) {
txn->Close(status);
return true;
}
switch (hdr->ordinal) {
case kParent_First_Ordinal:
case kParent_First_GenOrdinal: {
auto result = ::fidl::DecodeAs<FirstRequest>(msg);
if (result.status != ZX_OK) {
txn->Close(ZX_ERR_INVALID_ARGS);
return true;
}
auto message = result.message.message();
impl->First(std::move(message->request),
Interface::FirstCompleter::Sync(txn));
return true;
}
default: {
return false;
}
}
}
bool Parent::Dispatch(Interface* impl, fidl_msg_t* msg,
::fidl::Transaction* txn) {
bool found = TryDispatch(impl, msg, txn);
if (!found) {
zx_handle_close_many(msg->handles, msg->num_handles);
txn->Close(ZX_ERR_NOT_SUPPORTED);
}
return found;
}
void Parent::SetTransactionHeaderFor::FirstRequest(
const ::fidl::DecodedMessage<Parent::FirstRequest>& _msg) {
fidl_init_txn_header(&_msg.message()->_hdr, 0, kParent_First_GenOrdinal);
_msg.message()->_hdr.flags[0] |= FIDL_TXN_HEADER_UNION_FROM_XUNION_FLAG;
}
namespace {
[[maybe_unused]] constexpr uint64_t kChild_First_Ordinal = 0x66a95ddc00000000lu;
[[maybe_unused]] constexpr uint64_t kChild_First_GenOrdinal =
0x239f8fdea8de880clu;
extern "C" const fidl_type_t v1_fidl_test_json_ChildFirstRequestTable;
extern "C" const fidl_type_t v1_fidl_test_json_ChildFirstResponseTable;
[[maybe_unused]] constexpr uint64_t kChild_Second_Ordinal = 0x1240cb600000000lu;
[[maybe_unused]] constexpr uint64_t kChild_Second_GenOrdinal =
0x24799ea8916d88aflu;
extern "C" const fidl_type_t v1_fidl_test_json_ChildSecondRequestTable;
extern "C" const fidl_type_t v1_fidl_test_json_ChildSecondResponseTable;
} // namespace
Child::ResultOf::First_Impl::First_Impl(::zx::unowned_channel _client_end,
::zx::channel request) {
constexpr uint32_t _kWriteAllocSize = ::fidl::internal::ClampedMessageSize<
FirstRequest, ::fidl::MessageDirection::kSending>();
::fidl::internal::AlignedBuffer<_kWriteAllocSize> _write_bytes_inlined;
auto& _write_bytes_array = _write_bytes_inlined;
uint8_t* _write_bytes = _write_bytes_array.view().data();
memset(_write_bytes, 0, FirstRequest::PrimarySize);
auto& _request = *reinterpret_cast<FirstRequest*>(_write_bytes);
_request.request = std::move(request);
::fidl::BytePart _request_bytes(_write_bytes, _kWriteAllocSize,
sizeof(FirstRequest));
::fidl::DecodedMessage<FirstRequest> _decoded_request(
std::move(_request_bytes));
Super::operator=(Child::InPlace::First(std::move(_client_end),
std::move(_decoded_request)));
}
Child::ResultOf::First Child::SyncClient::First(::zx::channel request) {
return ResultOf::First(::zx::unowned_channel(this->channel_),
std::move(request));
}
Child::ResultOf::First Child::Call::First(::zx::unowned_channel _client_end,
::zx::channel request) {
return ResultOf::First(std::move(_client_end), std::move(request));
}
Child::UnownedResultOf::First_Impl::First_Impl(
::zx::unowned_channel _client_end, ::fidl::BytePart _request_buffer,
::zx::channel request) {
if (_request_buffer.capacity() < FirstRequest::PrimarySize) {
Super::status_ = ZX_ERR_BUFFER_TOO_SMALL;
Super::error_ = ::fidl::internal::kErrorRequestBufferTooSmall;
return;
}
memset(_request_buffer.data(), 0, FirstRequest::PrimarySize);
auto& _request = *reinterpret_cast<FirstRequest*>(_request_buffer.data());
_request.request = std::move(request);
_request_buffer.set_actual(sizeof(FirstRequest));
::fidl::DecodedMessage<FirstRequest> _decoded_request(
std::move(_request_buffer));
Super::operator=(Child::InPlace::First(std::move(_client_end),
std::move(_decoded_request)));
}
Child::UnownedResultOf::First Child::SyncClient::First(
::fidl::BytePart _request_buffer, ::zx::channel request) {
return UnownedResultOf::First(::zx::unowned_channel(this->channel_),
std::move(_request_buffer), std::move(request));
}
Child::UnownedResultOf::First Child::Call::First(
::zx::unowned_channel _client_end, ::fidl::BytePart _request_buffer,
::zx::channel request) {
return UnownedResultOf::First(std::move(_client_end),
std::move(_request_buffer), std::move(request));
}
::fidl::internal::StatusAndError Child::InPlace::First(
::zx::unowned_channel _client_end,
::fidl::DecodedMessage<FirstRequest> params) {
Child::SetTransactionHeaderFor::FirstRequest(params);
auto _encode_request_result = ::fidl::Encode(std::move(params));
if (_encode_request_result.status != ZX_OK) {
return ::fidl::internal::StatusAndError::FromFailure(
std::move(_encode_request_result));
}
zx_status_t _write_status = ::fidl::Write(
std::move(_client_end), std::move(_encode_request_result.message));
if (_write_status != ZX_OK) {
return ::fidl::internal::StatusAndError(
_write_status, ::fidl::internal::kErrorWriteFailed);
} else {
return ::fidl::internal::StatusAndError(ZX_OK, nullptr);
}
}
Child::ResultOf::Second_Impl::Second_Impl(::zx::unowned_channel _client_end,
::zx::channel request) {
constexpr uint32_t _kWriteAllocSize = ::fidl::internal::ClampedMessageSize<
SecondRequest, ::fidl::MessageDirection::kSending>();
::fidl::internal::AlignedBuffer<_kWriteAllocSize> _write_bytes_inlined;
auto& _write_bytes_array = _write_bytes_inlined;
uint8_t* _write_bytes = _write_bytes_array.view().data();
memset(_write_bytes, 0, SecondRequest::PrimarySize);
auto& _request = *reinterpret_cast<SecondRequest*>(_write_bytes);
_request.request = std::move(request);
::fidl::BytePart _request_bytes(_write_bytes, _kWriteAllocSize,
sizeof(SecondRequest));
::fidl::DecodedMessage<SecondRequest> _decoded_request(
std::move(_request_bytes));
Super::operator=(Child::InPlace::Second(std::move(_client_end),
std::move(_decoded_request)));
}
Child::ResultOf::Second Child::SyncClient::Second(::zx::channel request) {
return ResultOf::Second(::zx::unowned_channel(this->channel_),
std::move(request));
}
Child::ResultOf::Second Child::Call::Second(::zx::unowned_channel _client_end,
::zx::channel request) {
return ResultOf::Second(std::move(_client_end), std::move(request));
}
Child::UnownedResultOf::Second_Impl::Second_Impl(
::zx::unowned_channel _client_end, ::fidl::BytePart _request_buffer,
::zx::channel request) {
if (_request_buffer.capacity() < SecondRequest::PrimarySize) {
Super::status_ = ZX_ERR_BUFFER_TOO_SMALL;
Super::error_ = ::fidl::internal::kErrorRequestBufferTooSmall;
return;
}
memset(_request_buffer.data(), 0, SecondRequest::PrimarySize);
auto& _request = *reinterpret_cast<SecondRequest*>(_request_buffer.data());
_request.request = std::move(request);
_request_buffer.set_actual(sizeof(SecondRequest));
::fidl::DecodedMessage<SecondRequest> _decoded_request(
std::move(_request_buffer));
Super::operator=(Child::InPlace::Second(std::move(_client_end),
std::move(_decoded_request)));
}
Child::UnownedResultOf::Second Child::SyncClient::Second(
::fidl::BytePart _request_buffer, ::zx::channel request) {
return UnownedResultOf::Second(::zx::unowned_channel(this->channel_),
std::move(_request_buffer),
std::move(request));
}
Child::UnownedResultOf::Second Child::Call::Second(
::zx::unowned_channel _client_end, ::fidl::BytePart _request_buffer,
::zx::channel request) {
return UnownedResultOf::Second(
std::move(_client_end), std::move(_request_buffer), std::move(request));
}
::fidl::internal::StatusAndError Child::InPlace::Second(
::zx::unowned_channel _client_end,
::fidl::DecodedMessage<SecondRequest> params) {
Child::SetTransactionHeaderFor::SecondRequest(params);
auto _encode_request_result = ::fidl::Encode(std::move(params));
if (_encode_request_result.status != ZX_OK) {
return ::fidl::internal::StatusAndError::FromFailure(
std::move(_encode_request_result));
}
zx_status_t _write_status = ::fidl::Write(
std::move(_client_end), std::move(_encode_request_result.message));
if (_write_status != ZX_OK) {
return ::fidl::internal::StatusAndError(
_write_status, ::fidl::internal::kErrorWriteFailed);
} else {
return ::fidl::internal::StatusAndError(ZX_OK, nullptr);
}
}
bool Child::TryDispatch(Interface* impl, fidl_msg_t* msg,
::fidl::Transaction* txn) {
if (msg->num_bytes < sizeof(fidl_message_header_t)) {
zx_handle_close_many(msg->handles, msg->num_handles);
txn->Close(ZX_ERR_INVALID_ARGS);
return true;
}
fidl_message_header_t* hdr =
reinterpret_cast<fidl_message_header_t*>(msg->bytes);
zx_status_t status = fidl_validate_txn_header(hdr);
if (status != ZX_OK) {
txn->Close(status);
return true;
}
switch (hdr->ordinal) {
case kChild_First_Ordinal:
case kChild_First_GenOrdinal: {
auto result = ::fidl::DecodeAs<FirstRequest>(msg);
if (result.status != ZX_OK) {
txn->Close(ZX_ERR_INVALID_ARGS);
return true;
}
auto message = result.message.message();
impl->First(std::move(message->request),
Interface::FirstCompleter::Sync(txn));
return true;
}
case kChild_Second_Ordinal:
case kChild_Second_GenOrdinal: {
auto result = ::fidl::DecodeAs<SecondRequest>(msg);
if (result.status != ZX_OK) {
txn->Close(ZX_ERR_INVALID_ARGS);
return true;
}
auto message = result.message.message();
impl->Second(std::move(message->request),
Interface::SecondCompleter::Sync(txn));
return true;
}
default: {
return false;
}
}
}
bool Child::Dispatch(Interface* impl, fidl_msg_t* msg,
::fidl::Transaction* txn) {
bool found = TryDispatch(impl, msg, txn);
if (!found) {
zx_handle_close_many(msg->handles, msg->num_handles);
txn->Close(ZX_ERR_NOT_SUPPORTED);
}
return found;
}
void Child::SetTransactionHeaderFor::FirstRequest(
const ::fidl::DecodedMessage<Child::FirstRequest>& _msg) {
fidl_init_txn_header(&_msg.message()->_hdr, 0, kChild_First_GenOrdinal);
_msg.message()->_hdr.flags[0] |= FIDL_TXN_HEADER_UNION_FROM_XUNION_FLAG;
}
void Child::SetTransactionHeaderFor::SecondRequest(
const ::fidl::DecodedMessage<Child::SecondRequest>& _msg) {
fidl_init_txn_header(&_msg.message()->_hdr, 0, kChild_Second_GenOrdinal);
_msg.message()->_hdr.flags[0] |= FIDL_TXN_HEADER_UNION_FROM_XUNION_FLAG;
}
} // namespace json
} // namespace test
} // namespace fidl
} // namespace llcpp