garnet/go/src/fidl/compiler/backend/goldens/doc_comments.test.json.llcpp.h.golden

// 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/buffer_allocator.h>
#include <lib/fidl/llcpp/buffer_then_heap_allocator.h>
#include <lib/fidl/llcpp/coding.h>
#include <lib/fidl/llcpp/envelope.h>
#include <lib/fidl/llcpp/errors.h>
#include <lib/fidl/llcpp/linearized_and_encoded.h>
#include <lib/fidl/llcpp/memory.h>
#include <lib/fidl/llcpp/string_view.h>
#include <lib/fidl/llcpp/tracking_ptr.h>
#include <lib/fidl/llcpp/traits.h>
#include <lib/fidl/llcpp/vector_view.h>
#include <lib/fit/function.h>

#include <variant>
#ifdef __Fuchsia__
#include <lib/fidl/llcpp/client.h>
#include <lib/fidl/llcpp/connect_service.h>
#include <lib/fidl/llcpp/message.h>
#include <lib/fidl/llcpp/result.h>
#include <lib/fidl/llcpp/server.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/txn_header.h>
#include <lib/zx/channel.h>
#endif  // __Fuchsia__
#include <zircon/fidl.h>

namespace llcpp {

namespace test {
namespace name {

class Union;
class Table;
struct Struct;
class Interface;
class Service;
enum class MyEnum : uint32_t {
  FOO = 1u,
  BAR = 2u,
};

class MyBits final {
 public:
  constexpr MyBits() : value_(0u) {}
  explicit constexpr MyBits(uint32_t value) : value_(value) {}
  const static MyBits MY_FIRST_BIT;
  const static MyBits MY_OTHER_BIT;
  const static MyBits mask;

  explicit constexpr inline operator uint32_t() const { return value_; }
  explicit constexpr inline operator bool() const {
    return static_cast<bool>(value_);
  }
  constexpr inline bool operator==(const MyBits& other) const {
    return value_ == other.value_;
  }
  constexpr inline bool operator!=(const MyBits& other) const {
    return value_ != other.value_;
  }
  constexpr inline MyBits operator~() const;
  constexpr inline MyBits operator|(const MyBits& other) const;
  constexpr inline MyBits operator&(const MyBits& other) const;
  constexpr inline MyBits operator^(const MyBits& other) const;
  constexpr inline void operator|=(const MyBits& other);
  constexpr inline void operator&=(const MyBits& other);
  constexpr inline void operator^=(const MyBits& other);

 private:
  uint32_t value_;
};
constexpr const ::llcpp::test::name::MyBits MyBits::MY_FIRST_BIT =
    ::llcpp::test::name::MyBits(1u);
constexpr const ::llcpp::test::name::MyBits MyBits::MY_OTHER_BIT =
    ::llcpp::test::name::MyBits(2u);
constexpr const ::llcpp::test::name::MyBits MyBits::mask =
    ::llcpp::test::name::MyBits(3u);

constexpr inline ::llcpp::test::name::MyBits MyBits::operator~() const {
  return ::llcpp::test::name::MyBits(
      static_cast<uint32_t>(~this->value_ & mask.value_));
}

constexpr inline ::llcpp::test::name::MyBits MyBits::operator|(
    const ::llcpp::test::name::MyBits& other) const {
  return ::llcpp::test::name::MyBits(
      static_cast<uint32_t>(this->value_ | other.value_));
}

constexpr inline ::llcpp::test::name::MyBits MyBits::operator&(
    const ::llcpp::test::name::MyBits& other) const {
  return ::llcpp::test::name::MyBits(
      static_cast<uint32_t>(this->value_ & other.value_));
}

constexpr inline ::llcpp::test::name::MyBits MyBits::operator^(
    const ::llcpp::test::name::MyBits& other) const {
  return ::llcpp::test::name::MyBits(
      static_cast<uint32_t>(this->value_ ^ other.value_));
}

constexpr inline void MyBits::operator|=(
    const ::llcpp::test::name::MyBits& other) {
  this->value_ |= other.value_;
}

constexpr inline void MyBits::operator&=(
    const ::llcpp::test::name::MyBits& other) {
  this->value_ &= other.value_;
}

constexpr inline void MyBits::operator^=(
    const ::llcpp::test::name::MyBits& other) {
  this->value_ ^= other.value_;
}

extern "C" const fidl_type_t test_name_UnionTable;

// union comment #1
//
// union comment #3
class Union {
 public:
  Union() : ordinal_(Ordinal::Invalid), envelope_{} {}

  Union(Union&&) = default;
  Union& operator=(Union&&) = default;

  ~Union() { reset_ptr(nullptr); }

  enum class Tag : fidl_xunion_tag_t {
    kField = 1,  // 0x1
  };

  bool has_invalid_tag() const { return ordinal_ == Ordinal::Invalid; }

  bool is_Field() const { return ordinal_ == Ordinal::kField; }

  static Union WithField(::fidl::tracking_ptr<int32_t>&& val) {
    Union result;
    result.set_Field(std::move(val));
    return result;
  }

  // union member comment #1
  //
  // union member comment #3
  void set_Field(::fidl::tracking_ptr<int32_t>&& elem) {
    ordinal_ = Ordinal::kField;
    reset_ptr(static_cast<::fidl::tracking_ptr<void>>(std::move(elem)));
  }

  // union member comment #1
  //
  // union member comment #3
  int32_t& mutable_Field() {
    ZX_ASSERT(ordinal_ == Ordinal::kField);
    return *static_cast<int32_t*>(envelope_.data.get());
  }
  const int32_t& Field() const {
    ZX_ASSERT(ordinal_ == Ordinal::kField);
    return *static_cast<int32_t*>(envelope_.data.get());
  }
  Tag which() const {
    ZX_ASSERT(!has_invalid_tag());
    return static_cast<Tag>(ordinal_);
  }

  static constexpr const fidl_type_t* Type = &test_name_UnionTable;
  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;
  static constexpr bool IsResource = false;

 private:
  enum class Ordinal : fidl_xunion_tag_t {
    Invalid = 0,
    kField = 1,  // 0x1
  };

  void reset_ptr(::fidl::tracking_ptr<void>&& new_ptr) {
    // To clear the existing value, std::move it and let it go out of scope.
    switch (static_cast<fidl_xunion_tag_t>(ordinal_)) {
      case 1: {
        ::fidl::tracking_ptr<int32_t> to_destroy =
            static_cast<::fidl::tracking_ptr<int32_t>>(
                std::move(envelope_.data));
        break;
      }
    }

    envelope_.data = std::move(new_ptr);
  }

  static void SizeAndOffsetAssertionHelper();
  Ordinal ordinal_;
  FIDL_ALIGNDECL
  ::fidl::Envelope<void> envelope_;
};

extern "C" const fidl_type_t test_name_TableTable;

// table comment #1
//
// table comment #3
class Table final {
 public:
  // Returns whether no field is set.
  bool IsEmpty() const { return max_ordinal_ == 0; }

  // table field comment #1
  //
  // table field comment #3
  const int32_t& Field() const {
    ZX_ASSERT(has_Field());
    return *frame_ptr_->Field_.data;
  }
  int32_t& Field() {
    ZX_ASSERT(has_Field());
    return *frame_ptr_->Field_.data;
  }
  bool has_Field() const {
    return max_ordinal_ >= 1 && frame_ptr_->Field_.data != nullptr;
  }

  Table() = default;
  ~Table() = default;
  Table(Table&& other) noexcept = default;
  Table& operator=(Table&& other) noexcept = default;

  static constexpr const fidl_type_t* Type = &test_name_TableTable;
  static constexpr uint32_t MaxNumHandles = 0;
  static constexpr uint32_t PrimarySize = 16;
  [[maybe_unused]] static constexpr uint32_t MaxOutOfLine = 24;
  static constexpr bool HasPointer = true;
  static constexpr bool IsResource = false;

  class Builder;
  class UnownedBuilder;

  class Frame final {
   public:
    Frame() = default;
    // In its intended usage, Frame will be referenced by a tracking_ptr. If the
    // tracking_ptr is assigned before a move or copy, then it will reference
    // the old invalid object. Because this is unsafe, copies are disallowed and
    // moves are only allowed by friend classes that operate safely.
    Frame(const Frame&) = delete;
    Frame& operator=(const Frame&) = delete;

   private:
    Frame(Frame&&) noexcept = default;
    Frame& operator=(Frame&&) noexcept = default;
    ::fidl::Envelope<int32_t> Field_;

    friend class Table;
    friend class Table::Builder;
    friend class Table::UnownedBuilder;
  };

 private:
  Table(uint64_t max_ordinal, ::fidl::tracking_ptr<Frame>&& frame_ptr)
      : max_ordinal_(max_ordinal), frame_ptr_(std::move(frame_ptr)) {}
  uint64_t max_ordinal_ = 0;
  ::fidl::tracking_ptr<Frame> frame_ptr_;
};

// Table::Builder builds Table.
// Usage:
// Table val = Table::Builder(std::make_unique<Table::Frame>())
// .set_Field(ptr)
// .build();
class Table::Builder final {
 public:
  ~Builder() = default;
  Builder() = delete;
  Builder(::fidl::tracking_ptr<Table::Frame>&& frame_ptr)
      : max_ordinal_(0), frame_ptr_(std::move(frame_ptr)) {}

  Builder(Builder&& other) noexcept = default;
  Builder& operator=(Builder&& other) noexcept = default;

  Builder(const Builder& other) = delete;
  Builder& operator=(const Builder& other) = delete;

  // Returns whether no field is set.
  bool IsEmpty() const { return max_ordinal_ == 0; }

  // table field comment #1
  //
  // table field comment #3
  Builder&& set_Field(::fidl::tracking_ptr<int32_t> elem) {
    frame_ptr_->Field_.data = std::move(elem);
    if (max_ordinal_ < 1) {
      // Note: the table size is not currently reduced if nullptr is set.
      // This is possible to reconsider in the future.
      max_ordinal_ = 1;
    }
    return std::move(*this);
  }
  const int32_t& Field() const {
    ZX_ASSERT(has_Field());
    return *frame_ptr_->Field_.data;
  }
  int32_t& Field() {
    ZX_ASSERT(has_Field());
    return *frame_ptr_->Field_.data;
  }
  bool has_Field() const {
    return max_ordinal_ >= 1 && frame_ptr_->Field_.data != nullptr;
  }

  Table build() { return Table(max_ordinal_, std::move(frame_ptr_)); }

 private:
  uint64_t max_ordinal_ = 0;
  ::fidl::tracking_ptr<Table::Frame> frame_ptr_;
};

// UnownedBuilder acts like Builder but directly owns its Frame, simplifying
// working with unowned data.
class Table::UnownedBuilder final {
 public:
  ~UnownedBuilder() = default;
  UnownedBuilder() noexcept = default;
  UnownedBuilder(UnownedBuilder&& other) noexcept = default;
  UnownedBuilder& operator=(UnownedBuilder&& other) noexcept = default;

  // Returns whether no field is set.
  bool IsEmpty() const { return max_ordinal_ == 0; }

  // table field comment #1
  //
  // table field comment #3
  UnownedBuilder&& set_Field(::fidl::tracking_ptr<int32_t> elem) {
    ZX_ASSERT(elem);
    frame_.Field_.data = std::move(elem);
    if (max_ordinal_ < 1) {
      max_ordinal_ = 1;
    }
    return std::move(*this);
  }
  const int32_t& Field() const {
    ZX_ASSERT(has_Field());
    return *frame_.Field_.data;
  }
  int32_t& Field() {
    ZX_ASSERT(has_Field());
    return *frame_.Field_.data;
  }
  bool has_Field() const {
    return max_ordinal_ >= 1 && frame_.Field_.data != nullptr;
  }

  Table build() { return Table(max_ordinal_, ::fidl::unowned_ptr(&frame_)); }

 private:
  uint64_t max_ordinal_ = 0;
  Table::Frame frame_;
};

extern "C" const fidl_type_t test_name_StructTable;

// struct comment #1
//
// struct comment #3
struct Struct {
  static constexpr const fidl_type_t* Type = &test_name_StructTable;
  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;
  static constexpr bool IsResource = false;

  // struct member comment #1
  //
  // struct member comment #3
  int32_t Field = {};
};

extern "C" const fidl_type_t test_name_InterfaceMethodRequestTable;
extern "C" const fidl_type_t test_name_InterfaceMethodResponseTable;
extern "C" const fidl_type_t test_name_InterfaceOnEventRequestTable;
extern "C" const fidl_type_t test_name_InterfaceOnEventEventTable;
// interface comment #1
//
// interface comment #3
class Interface final {
  Interface() = delete;

 public:
  struct MethodRequest final {
    FIDL_ALIGNDECL
    fidl_message_header_t _hdr;
    explicit MethodRequest(zx_txid_t _txid) { _InitHeader(_txid); }

    static constexpr const fidl_type_t* Type =
        &::fidl::_llcpp_coding_AnyZeroArgMessageTable;
    static constexpr uint32_t MaxNumHandles = 0;
    static constexpr uint32_t PrimarySize = 16;
    static constexpr uint32_t MaxOutOfLine = 0;
    static constexpr uint32_t AltPrimarySize = 16;
    static constexpr uint32_t AltMaxOutOfLine = 0;
    static constexpr bool HasFlexibleEnvelope = false;
    static constexpr bool HasPointer = false;
    static constexpr bool IsResource = false;
    static constexpr ::fidl::internal::TransactionalMessageKind MessageKind =
        ::fidl::internal::TransactionalMessageKind::kRequest;

   private:
    void _InitHeader(zx_txid_t _txid);
  };

  struct OnEventResponse final {
    FIDL_ALIGNDECL
    fidl_message_header_t _hdr;
    OnEventResponse() { _InitHeader(); }

    static constexpr const fidl_type_t* Type =
        &::fidl::_llcpp_coding_AnyZeroArgMessageTable;
    static constexpr uint32_t MaxNumHandles = 0;
    static constexpr uint32_t PrimarySize = 16;
    static constexpr uint32_t MaxOutOfLine = 0;
    static constexpr bool HasFlexibleEnvelope = false;
    static constexpr bool HasPointer = false;
    static constexpr bool IsResource = false;
    static constexpr ::fidl::internal::TransactionalMessageKind MessageKind =
        ::fidl::internal::TransactionalMessageKind::kResponse;

   private:
    void _InitHeader();
  };

  struct EventHandlers {
    // event comment #1
    //
    // event comment #3
    fit::function<zx_status_t()> on_event;

    // Fallback handler when an unknown ordinal is received.
    // Caller may put custom error handling logic here.
    fit::function<zx_status_t()> unknown;
  };

  // Collection of return types of FIDL calls in this protocol.
  class ResultOf final {
    ResultOf() = delete;

   public:
    class Method final : public ::fidl::Result {
     public:
      explicit Method(zx_handle_t _client);
      explicit Method(const ::fidl::Result& result) : ::fidl::Result(result) {}
      Method(Method&&) = delete;
      Method(const Method&) = delete;
      Method* operator=(Method&&) = delete;
      Method* operator=(const Method&) = delete;
      ~Method() = default;

     private:
    };
  };

  // Collection of return types of FIDL calls in this protocol,
  // when the caller-allocate flavor or in-place call is used.
  class UnownedResultOf final {
    UnownedResultOf() = delete;

   public:
    class Method final : public ::fidl::Result {
     public:
      explicit Method(zx_handle_t _client);
      explicit Method(const ::fidl::Result& result) : ::fidl::Result(result) {}
      Method(Method&&) = delete;
      Method(const Method&) = delete;
      Method* operator=(Method&&) = delete;
      Method* operator=(const Method&) = delete;
      ~Method() = default;
    };
  };

  class MethodUnownedRequest final {
   public:
    MethodUnownedRequest(uint8_t* _bytes, uint32_t _byte_size, zx_txid_t _txid)
        : message_(_bytes, _byte_size, sizeof(MethodRequest), nullptr, 0, 0) {
      // Destructors can't be called because it will lead to handle double close
      // (here and in fidl::Encode).
      FIDL_ALIGNDECL uint8_t _request_buffer[sizeof(MethodRequest)];
      auto& _request = *new (_request_buffer) MethodRequest(_txid);
      message_.LinearizeAndEncode(MethodRequest::Type, &_request);
    }

    zx_status_t status() const { return message_.status(); }
    bool ok() const { return message_.status() == ZX_OK; }
    const char* error() const { return message_.error(); }
    bool linearized() const { return message_.linearized(); }
    bool encoded() const { return message_.encoded(); }

    ::fidl::internal::FidlMessage& GetFidlMessage() { return message_; }

    void Write(zx_handle_t client) { message_.Write(client); }

   private:
    MethodRequest& Message() {
      return *reinterpret_cast<MethodRequest*>(message_.bytes().data());
    }
    ::fidl::internal::FidlMessage message_;
  };

  class MethodOwnedRequest final {
   public:
    explicit MethodOwnedRequest(zx_txid_t _txid)
        : message_(bytes_, sizeof(bytes_), _txid) {}

    zx_status_t status() const { return message_.status(); }
    bool ok() const { return message_.ok(); }
    const char* error() const { return message_.error(); }
    bool linearized() const { return message_.linearized(); }
    bool encoded() const { return message_.encoded(); }

    ::fidl::internal::FidlMessage& GetFidlMessage() {
      return message_.GetFidlMessage();
    }

    void Write(zx_handle_t client) { message_.Write(client); }

   private:
    FIDL_ALIGNDECL
    uint8_t bytes_[MethodRequest::PrimarySize + MethodRequest::MaxOutOfLine];
    MethodUnownedRequest message_;
  };

  class OnEventUnownedResponse final {
   public:
    OnEventUnownedResponse(uint8_t* _bytes, uint32_t _byte_size)
        : message_(_bytes, _byte_size, sizeof(OnEventResponse), nullptr, 0, 0) {
      // Destructors can't be called because it will lead to handle double close
      // (here and in fidl::Encode).
      FIDL_ALIGNDECL uint8_t _response_buffer[sizeof(OnEventResponse)];
      auto& _response = *new (_response_buffer) OnEventResponse();
      message_.LinearizeAndEncode(OnEventResponse::Type, &_response);
    }

    zx_status_t status() const { return message_.status(); }
    bool ok() const { return message_.status() == ZX_OK; }
    const char* error() const { return message_.error(); }
    bool linearized() const { return message_.linearized(); }
    bool encoded() const { return message_.encoded(); }

    ::fidl::internal::FidlMessage& GetFidlMessage() { return message_; }

    void Write(zx_handle_t client) { message_.Write(client); }

   private:
    OnEventResponse& Message() {
      return *reinterpret_cast<OnEventResponse*>(message_.bytes().data());
    }
    ::fidl::internal::FidlMessage message_;
  };

  class OnEventOwnedResponse final {
   public:
    explicit OnEventOwnedResponse() : message_(bytes_, sizeof(bytes_)) {}

    zx_status_t status() const { return message_.status(); }
    bool ok() const { return message_.ok(); }
    const char* error() const { return message_.error(); }
    bool linearized() const { return message_.linearized(); }
    bool encoded() const { return message_.encoded(); }

    ::fidl::internal::FidlMessage& GetFidlMessage() {
      return message_.GetFidlMessage();
    }

    void Write(zx_handle_t client) { message_.Write(client); }

   private:
    FIDL_ALIGNDECL
    uint8_t
        bytes_[OnEventResponse::PrimarySize + OnEventResponse::MaxOutOfLine];
    OnEventUnownedResponse message_;
  };

  // Methods to make a sync FIDL call directly on an unowned channel, avoiding
  // setting up a client.
  class Call final {
    Call() = delete;

   public:
    // method comment #1
    //
    // method comment #3
    // Allocates 16 bytes of message buffer on the stack. No heap allocation
    // necessary.
    static ResultOf::Method Method(::zx::unowned_channel _client_end) {
      return ResultOf::Method(_client_end->get());
    }

    // Handle all possible events defined in this protocol.
    // Blocks to consume exactly one message from the channel, then call the
    // corresponding handler defined in |EventHandlers|. The return status of
    // the handler function is folded with any transport-level errors and
    // returned.
    static ::fidl::Result HandleEvents(::zx::unowned_channel client_end,
                                       EventHandlers& handlers);
  };

  class SyncClient final {
   public:
    SyncClient() = default;
    explicit SyncClient(::zx::channel channel) : channel_(std::move(channel)) {}
    ~SyncClient() = default;
    SyncClient(SyncClient&&) = default;
    SyncClient& operator=(SyncClient&&) = default;

    const ::zx::channel& channel() const { return channel_; }

    ::zx::channel* mutable_channel() { return &channel_; }

    // method comment #1
    //
    // method comment #3
    // Allocates 16 bytes of message buffer on the stack. No heap allocation
    // necessary.
    ResultOf::Method Method() {
      return ResultOf::Method(this->channel().get());
    }

    // Handle all possible events defined in this protocol.
    // Blocks to consume exactly one message from the channel, then call the
    // corresponding handler defined in |EventHandlers|. The return status of
    // the handler function is folded with any transport-level errors and
    // returned.
    ::fidl::Result HandleEvents(EventHandlers& handlers) {
      return Call::HandleEvents(::zx::unowned_channel(channel_), handlers);
    }

   private:
    ::zx::channel channel_;
  };

  struct AsyncEventHandlers;
  class ClientImpl;

  // Pure-virtual interface to be implemented by a server.
  class Interface {
   public:
    Interface() = default;
    virtual ~Interface() = default;
    using _Outer = Interface;
    using _Base = ::fidl::CompleterBase;

    using MethodCompleter = ::fidl::Completer<>;

    virtual void Method(MethodCompleter::Sync _completer) = 0;
  };

  // Attempts to dispatch the incoming message to a handler function in the
  // server implementation. If there is no matching handler, it returns false,
  // leaving the message and transaction intact. In all other cases, it consumes
  // the message and returns true. It is possible to chain multiple TryDispatch
  // functions in this manner.
  static bool TryDispatch(Interface* impl, fidl_msg_t* msg,
                          ::fidl::Transaction* txn);

  // Dispatches the incoming message to one of the handlers functions in the
  // protocol. If there is no matching handler, it closes all the handles in
  // |msg| and closes the channel with a |ZX_ERR_NOT_SUPPORTED| epitaph, before
  // returning false. The message should then be discarded.
  static bool Dispatch(Interface* impl, fidl_msg_t* msg,
                       ::fidl::Transaction* txn);

  // Same as |Dispatch|, but takes a |void*| instead of |Interface*|.
  // Only used with |fidl::BindServer| to reduce template expansion.
  // Do not call this method manually. Use |Dispatch| instead.
  static bool TypeErasedDispatch(void* impl, fidl_msg_t* msg,
                                 ::fidl::Transaction* txn) {
    return Dispatch(static_cast<Interface*>(impl), msg, txn);
  }

  // event comment #1
  //
  // event comment #3
  static zx_status_t SendOnEventEvent(::zx::unowned_channel _channel);

  class EventSender;
};

// service comment #1
//
// service comment #3
class Service final {
  Service() = default;

 public:
  static constexpr char Name[] = "test.name.Service";

  // Client protocol for connecting to member protocols of a service instance.
  class ServiceClient final {
    ServiceClient() = delete;

   public:
    ServiceClient(::zx::channel dir,
                  ::fidl::internal::ConnectMemberFunc connect_func)
        : dir_(std::move(dir)), connect_func_(connect_func) {}

    // Connects to the member protocol "interface". Returns a
    // |fidl::ClientChannel| on success, which can be used with
    // |fidl::BindSyncClient| to create a synchronous client.
    //
    // # Errors
    //
    // On failure, returns a fit::error with zx_status_t != ZX_OK.
    // Failures can occur if channel creation failed, or if there was an issue
    // making a |fuchsia.io.Directory::Open| call.
    //
    // Since the call to |Open| is asynchronous, an error sent by the remote end
    // will not result in a failure of this method. Any errors sent by the
    // remote will appear on the |ClientChannel| returned from this method.
    ::fidl::result<::fidl::ClientChannel<Interface>> connect_interface() {
      ::zx::channel local, remote;
      zx_status_t result = ::zx::channel::create(0, &local, &remote);
      if (result != ZX_OK) {
        return ::fit::error(result);
      }
      result =
          connect_func_(::zx::unowned_channel(dir_),
                        ::fidl::StringView("interface"), std::move(remote));
      if (result != ZX_OK) {
        return ::fit::error(result);
      }
      return ::fit::ok(::fidl::ClientChannel<Interface>(std::move(local)));
    }

   private:
    ::zx::channel dir_;
    ::fidl::internal::ConnectMemberFunc connect_func_;
  };

  // Facilitates member protocol registration for servers.
  class Handler final {
   public:
    // Constructs a FIDL Service-typed handler. Does not take ownership of
    // |service_handler|.
    explicit Handler(::llcpp::fidl::ServiceHandlerInterface* service_handler)
        : service_handler_(service_handler) {}

    // Adds member "interface" to the service instance. |handler| will be
    // invoked on connection attempts.
    //
    // # Errors
    //
    // Returns ZX_ERR_ALREADY_EXISTS if the member was already added.
    zx_status_t add_interface(
        ::llcpp::fidl::ServiceHandlerInterface::MemberHandler handler) {
      return service_handler_->AddMember("interface", std::move(handler));
    }

   private:
    ::llcpp::fidl::ServiceHandlerInterface* service_handler_;  // Not owned.
  };
};

// const comment #1
//
// const comment #3
constexpr int32_t C = 4u;

}  // namespace name
}  // namespace test
}  // namespace llcpp

namespace fidl {

template <>
struct IsFidlType<::llcpp::test::name::Union> : public std::true_type {};
template <>
struct IsUnion<::llcpp::test::name::Union> : public std::true_type {};
static_assert(std::is_standard_layout_v<::llcpp::test::name::Union>);

template <>
struct IsFidlType<::llcpp::test::name::Table> : public std::true_type {};
template <>
struct IsTable<::llcpp::test::name::Table> : public std::true_type {};
template <>
struct IsTableBuilder<::llcpp::test::name::Table::Builder>
    : public std::true_type {};
static_assert(std::is_standard_layout_v<::llcpp::test::name::Table>);

template <>
struct IsFidlType<::llcpp::test::name::Struct> : public std::true_type {};
template <>
struct IsStruct<::llcpp::test::name::Struct> : public std::true_type {};
static_assert(std::is_standard_layout_v<::llcpp::test::name::Struct>);
static_assert(offsetof(::llcpp::test::name::Struct, Field) == 0);
static_assert(sizeof(::llcpp::test::name::Struct) ==
              ::llcpp::test::name::Struct::PrimarySize);

template <>
struct IsFidlType<::llcpp::test::name::Interface::MethodRequest>
    : public std::true_type {};
template <>
struct IsFidlMessage<::llcpp::test::name::Interface::MethodRequest>
    : public std::true_type {};
static_assert(sizeof(::llcpp::test::name::Interface::MethodRequest) ==
              ::llcpp::test::name::Interface::MethodRequest::PrimarySize);

template <>
struct IsFidlType<::llcpp::test::name::Interface::OnEventResponse>
    : public std::true_type {};
template <>
struct IsFidlMessage<::llcpp::test::name::Interface::OnEventResponse>
    : public std::true_type {};
static_assert(sizeof(::llcpp::test::name::Interface::OnEventResponse) ==
              ::llcpp::test::name::Interface::OnEventResponse::PrimarySize);

template <>
struct IsFidlType<::llcpp::test::name::MyEnum> : public std::true_type {};

template <>
struct IsFidlType<::llcpp::test::name::MyBits> : public std::true_type {};
static_assert(std::is_standard_layout_v<::llcpp::test::name::MyBits>);
static_assert(sizeof(::llcpp::test::name::MyBits) == sizeof(uint32_t));

}  // namespace fidl

namespace llcpp {

namespace test {
namespace name {

struct Interface::AsyncEventHandlers {
  // event comment #1
  //
  // event comment #3
  ::fit::function<void()> on_event;
};

class Interface::ClientImpl final : private ::fidl::internal::ClientBase {
 public:
  // method comment #1
  //
  // method comment #3
  // Allocates 16 bytes of message buffer on the stack. No heap allocation
  // necessary.
  ::fidl::Result Method();

 private:
  friend class ::fidl::Client<Interface>;

  ClientImpl(::zx::channel client_end, async_dispatcher_t* dispatcher,
             ::fidl::internal::TypeErasedOnUnboundFn on_unbound,
             AsyncEventHandlers handlers)
      : ::fidl::internal::ClientBase(std::move(client_end), dispatcher,
                                     std::move(on_unbound)),
        handlers_(std::move(handlers)) {}

  std::optional<::fidl::UnbindInfo> DispatchEvent(fidl_msg_t* msg) override;

  AsyncEventHandlers handlers_;
};

class Interface::EventSender {
 public:
  zx_status_t OnEvent() const {
    if (auto _binding = binding_.lock()) {
      return SendOnEventEvent(_binding->channel());
    }
    return ZX_ERR_CANCELED;
  }

 private:
  friend class ::fidl::ServerBindingRef<Interface>;

  explicit EventSender(std::weak_ptr<::fidl::internal::AsyncBinding> binding)
      : binding_(std::move(binding)) {}

  std::weak_ptr<::fidl::internal::AsyncBinding> binding_;
};

}  // namespace name
}  // namespace test
}  // namespace llcpp