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fuchsia / fuchsia / 099dfaa57f8e77a17e57e89b07604f2a4d648410 / . / tools / fidl / fidlgen_llcpp / goldens / protocol_layouts_wire_types.h.golden
blob: 716ca29b1ee2244c098039c3f660d8b870b810ef [file] [log] [blame]
// WARNING: This file is machine generated by fidlgen.
#pragma once
#include <lib/fidl/llcpp/array.h>
#include <lib/fidl/llcpp/envelope.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/wire_types.h>
#include <lib/stdcompat/optional.h>
#include <cinttypes>
#ifdef __Fuchsia__
#include <lib/zx/channel.h>
#endif // __Fuchsia__
#include <fidl/test.protocollayouts.imported/cpp/wire_types.h>
#include <fidl/test.protocollayouts/cpp/common_types.h>
#include <fidl/test.protocollayouts/cpp/markers.h>
namespace test_protocollayouts {
namespace wire {
struct MainProtocolTwoWayImportWithErrorTopResponse;
struct MainProtocolTwoWayAnonWithErrorTopResponse;
struct MainProtocolOnImportWithErrorRequest;
struct MainProtocolOnAnonWithErrorRequest;
struct MainProtocolTwoWayLocalWithErrorTopResponse;
struct MainProtocolOnLocalWithErrorRequest;
class MainProtocolOnAnonWithErrorResponse;
class MainProtocolTwoWayAnonWithErrorRequest;
class MainProtocolTwoWayAnonResponse;
class MainProtocolOneWayAnonRequest;
class LocalTablePayload;
class MainProtocolTwoWayImportWithErrorResult;
class MainProtocolTwoWayAnonWithErrorResponse;
class MainProtocolTwoWayAnonWithErrorResult;
class MainProtocolOnImportWithErrorResult;
class MainProtocolOnAnonWithErrorResult;
class MainProtocolTwoWayAnonRequest;
class MainProtocolOnAnonRequest;
class LocalUnionPayload;
class MainProtocolTwoWayLocalWithErrorResult;
class MainProtocolOnLocalWithErrorResult;
} // namespace wire
} // namespace test_protocollayouts
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>;
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>;
template <>
struct ::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> final {
public:
WireTableFrame() = default;
// In its intended usage, WireTableFrame will be referenced by an ObjectView.
// If the ObjectView 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.
WireTableFrame(const WireTableFrame&) = delete;
WireTableFrame& operator=(const WireTableFrame&) = delete;
private:
WireTableFrame(WireTableFrame&&) noexcept = default;
WireTableFrame& operator=(WireTableFrame&&) noexcept = default;
bool HasUnknownData() const;
::fidl::Envelope<uint16_t> a_;
friend class ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>;
};
namespace test_protocollayouts {
namespace wire {
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_OnAnonWithError_ResponseTable;
class MainProtocolOnAnonWithErrorResponse {
public:
MainProtocolOnAnonWithErrorResponse() = default;
MainProtocolOnAnonWithErrorResponse(const MainProtocolOnAnonWithErrorResponse& other) noexcept = default;
MainProtocolOnAnonWithErrorResponse& operator=(const MainProtocolOnAnonWithErrorResponse& other) noexcept = default;
MainProtocolOnAnonWithErrorResponse(MainProtocolOnAnonWithErrorResponse&& other) noexcept = default;
MainProtocolOnAnonWithErrorResponse& operator=(MainProtocolOnAnonWithErrorResponse&& other) noexcept = default;
~MainProtocolOnAnonWithErrorResponse() = default;
// Returns whether no field is set.
bool IsEmpty() const { return max_ordinal_ == 0; }
// Returns whether the table references unknown fields.
bool HasUnknownData() const;
// Return a builder that by defaults allocates of an arena.
static ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> Builder(::fidl::AnyArena& arena);
// Return a builder that relies on explicitly allocating |fidl::ObjectView|s.
static ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>> frame);
const uint16_t& a() const {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
uint16_t& a() {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
bool has_a() const {
return max_ordinal_ >= 1 && frame_ptr_->a_.has_data();
}
#if defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES) || false
public:
#else // !defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES)
private:
#endif // FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES
MainProtocolOnAnonWithErrorResponse& set_a(uint16_t elem) {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.set_data(std::move(elem));
max_ordinal_ = std::max(max_ordinal_, static_cast<uint64_t>(1));
return *this;
}
MainProtocolOnAnonWithErrorResponse& clear_a() {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.clear_data();
return *this;
}
explicit MainProtocolOnAnonWithErrorResponse(::fidl::AnyArena& allocator)
: frame_ptr_(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>(allocator)) {}
// This constructor allows a user controlled allocation (not using a Arena).
// It should only be used when performance is key.
// As soon as the frame is given to the table, it must not be used directly or for another table.
explicit MainProtocolOnAnonWithErrorResponse(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>&& frame)
: frame_ptr_(std::move(frame)) {}
void Allocate(::fidl::AnyArena& allocator) {
max_ordinal_ = 0;
frame_ptr_ = ::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>(allocator);
}
void Init(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>&& frame_ptr) {
max_ordinal_ = 0;
frame_ptr_ = std::move(frame_ptr);
}
private:
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>;
uint64_t max_ordinal_ = 0;
::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>> frame_ptr_;
};
} // namespace wire
} // namespace test_protocollayouts
template <typename BuilderImpl>
class ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, BuilderImpl> {
public:
// Build and return the table. The builder should not be used after this.
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse Build() {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse t = std::move(table_);
// Poison this builder to prevent accidental reuse.
table_.frame_ptr_ = nullptr;
return t;
}
BuilderImpl& a(uint16_t elem) {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
table_.frame_ptr_->a_.set_data(std::move(elem));
table_.max_ordinal_ = std::max(table_.max_ordinal_, static_cast<uint64_t>(1));
return *static_cast<BuilderImpl*>(this);
}
protected:
WireTableBaseBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>&& frame)
: table_(std::move(frame)) {}
private:
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse table_;
};
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>;
public:
private:
friend class ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse;
WireTableBuilder(::fidl::AnyArena& arena)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>(arena)),
arena_(arena) {}
[[maybe_unused]] std::reference_wrapper<::fidl::AnyArena> arena_;
};
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>;
private:
friend class ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse;
using Base::Base;
WireTableExternalBuilder(::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>* frame)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>>::FromExternal(frame)) {}
};
namespace test_protocollayouts {
namespace wire {
inline ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> MainProtocolOnAnonWithErrorResponse::Builder(::fidl::AnyArena& arena) {
return ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>(arena);
}
inline ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> MainProtocolOnAnonWithErrorResponse::ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>> frame) {
return ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>(std::move(frame));
}
} // namespace wire
} // namespace test_protocollayouts
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>;
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>;
template <>
struct ::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> final {
public:
WireTableFrame() = default;
// In its intended usage, WireTableFrame will be referenced by an ObjectView.
// If the ObjectView 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.
WireTableFrame(const WireTableFrame&) = delete;
WireTableFrame& operator=(const WireTableFrame&) = delete;
private:
WireTableFrame(WireTableFrame&&) noexcept = default;
WireTableFrame& operator=(WireTableFrame&&) noexcept = default;
bool HasUnknownData() const;
::fidl::Envelope<uint16_t> a_;
friend class ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>;
};
namespace test_protocollayouts {
namespace wire {
extern "C" const fidl_type_t test_protocollayouts_MainProtocolTwoWayAnonWithErrorRequestTable;
class MainProtocolTwoWayAnonWithErrorRequest {
public:
MainProtocolTwoWayAnonWithErrorRequest() = default;
MainProtocolTwoWayAnonWithErrorRequest(const MainProtocolTwoWayAnonWithErrorRequest& other) noexcept = default;
MainProtocolTwoWayAnonWithErrorRequest& operator=(const MainProtocolTwoWayAnonWithErrorRequest& other) noexcept = default;
MainProtocolTwoWayAnonWithErrorRequest(MainProtocolTwoWayAnonWithErrorRequest&& other) noexcept = default;
MainProtocolTwoWayAnonWithErrorRequest& operator=(MainProtocolTwoWayAnonWithErrorRequest&& other) noexcept = default;
~MainProtocolTwoWayAnonWithErrorRequest() = default;
// Returns whether no field is set.
bool IsEmpty() const { return max_ordinal_ == 0; }
// Returns whether the table references unknown fields.
bool HasUnknownData() const;
// Return a builder that by defaults allocates of an arena.
static ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> Builder(::fidl::AnyArena& arena);
// Return a builder that relies on explicitly allocating |fidl::ObjectView|s.
static ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>> frame);
const uint16_t& a() const {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
uint16_t& a() {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
bool has_a() const {
return max_ordinal_ >= 1 && frame_ptr_->a_.has_data();
}
#if defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES) || false
public:
#else // !defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES)
private:
#endif // FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES
MainProtocolTwoWayAnonWithErrorRequest& set_a(uint16_t elem) {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.set_data(std::move(elem));
max_ordinal_ = std::max(max_ordinal_, static_cast<uint64_t>(1));
return *this;
}
MainProtocolTwoWayAnonWithErrorRequest& clear_a() {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.clear_data();
return *this;
}
explicit MainProtocolTwoWayAnonWithErrorRequest(::fidl::AnyArena& allocator)
: frame_ptr_(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>(allocator)) {}
// This constructor allows a user controlled allocation (not using a Arena).
// It should only be used when performance is key.
// As soon as the frame is given to the table, it must not be used directly or for another table.
explicit MainProtocolTwoWayAnonWithErrorRequest(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>&& frame)
: frame_ptr_(std::move(frame)) {}
void Allocate(::fidl::AnyArena& allocator) {
max_ordinal_ = 0;
frame_ptr_ = ::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>(allocator);
}
void Init(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>&& frame_ptr) {
max_ordinal_ = 0;
frame_ptr_ = std::move(frame_ptr);
}
private:
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>;
uint64_t max_ordinal_ = 0;
::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>> frame_ptr_;
};
} // namespace wire
} // namespace test_protocollayouts
template <typename BuilderImpl>
class ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, BuilderImpl> {
public:
// Build and return the table. The builder should not be used after this.
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest Build() {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest t = std::move(table_);
// Poison this builder to prevent accidental reuse.
table_.frame_ptr_ = nullptr;
return t;
}
BuilderImpl& a(uint16_t elem) {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
table_.frame_ptr_->a_.set_data(std::move(elem));
table_.max_ordinal_ = std::max(table_.max_ordinal_, static_cast<uint64_t>(1));
return *static_cast<BuilderImpl*>(this);
}
protected:
WireTableBaseBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>&& frame)
: table_(std::move(frame)) {}
private:
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest table_;
};
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>;
public:
private:
friend class ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest;
WireTableBuilder(::fidl::AnyArena& arena)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>(arena)),
arena_(arena) {}
[[maybe_unused]] std::reference_wrapper<::fidl::AnyArena> arena_;
};
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>;
private:
friend class ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest;
using Base::Base;
WireTableExternalBuilder(::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>* frame)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>>::FromExternal(frame)) {}
};
namespace test_protocollayouts {
namespace wire {
inline ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> MainProtocolTwoWayAnonWithErrorRequest::Builder(::fidl::AnyArena& arena) {
return ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>(arena);
}
inline ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> MainProtocolTwoWayAnonWithErrorRequest::ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>> frame) {
return ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>(std::move(frame));
}
} // namespace wire
} // namespace test_protocollayouts
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>;
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>;
template <>
struct ::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> final {
public:
WireTableFrame() = default;
// In its intended usage, WireTableFrame will be referenced by an ObjectView.
// If the ObjectView 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.
WireTableFrame(const WireTableFrame&) = delete;
WireTableFrame& operator=(const WireTableFrame&) = delete;
private:
WireTableFrame(WireTableFrame&&) noexcept = default;
WireTableFrame& operator=(WireTableFrame&&) noexcept = default;
bool HasUnknownData() const;
::fidl::Envelope<uint16_t> a_;
friend class ::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>;
};
namespace test_protocollayouts {
namespace wire {
extern "C" const fidl_type_t test_protocollayouts_MainProtocolTwoWayAnonResponseTable;
class MainProtocolTwoWayAnonResponse {
public:
MainProtocolTwoWayAnonResponse() = default;
MainProtocolTwoWayAnonResponse(const MainProtocolTwoWayAnonResponse& other) noexcept = default;
MainProtocolTwoWayAnonResponse& operator=(const MainProtocolTwoWayAnonResponse& other) noexcept = default;
MainProtocolTwoWayAnonResponse(MainProtocolTwoWayAnonResponse&& other) noexcept = default;
MainProtocolTwoWayAnonResponse& operator=(MainProtocolTwoWayAnonResponse&& other) noexcept = default;
~MainProtocolTwoWayAnonResponse() = default;
// Returns whether no field is set.
bool IsEmpty() const { return max_ordinal_ == 0; }
// Returns whether the table references unknown fields.
bool HasUnknownData() const;
// Return a builder that by defaults allocates of an arena.
static ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> Builder(::fidl::AnyArena& arena);
// Return a builder that relies on explicitly allocating |fidl::ObjectView|s.
static ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>> frame);
const uint16_t& a() const {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
uint16_t& a() {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
bool has_a() const {
return max_ordinal_ >= 1 && frame_ptr_->a_.has_data();
}
#if defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES) || false
public:
#else // !defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES)
private:
#endif // FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES
MainProtocolTwoWayAnonResponse& set_a(uint16_t elem) {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.set_data(std::move(elem));
max_ordinal_ = std::max(max_ordinal_, static_cast<uint64_t>(1));
return *this;
}
MainProtocolTwoWayAnonResponse& clear_a() {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.clear_data();
return *this;
}
explicit MainProtocolTwoWayAnonResponse(::fidl::AnyArena& allocator)
: frame_ptr_(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>(allocator)) {}
// This constructor allows a user controlled allocation (not using a Arena).
// It should only be used when performance is key.
// As soon as the frame is given to the table, it must not be used directly or for another table.
explicit MainProtocolTwoWayAnonResponse(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>&& frame)
: frame_ptr_(std::move(frame)) {}
void Allocate(::fidl::AnyArena& allocator) {
max_ordinal_ = 0;
frame_ptr_ = ::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>(allocator);
}
void Init(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>&& frame_ptr) {
max_ordinal_ = 0;
frame_ptr_ = std::move(frame_ptr);
}
private:
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>;
uint64_t max_ordinal_ = 0;
::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>> frame_ptr_;
};
} // namespace wire
} // namespace test_protocollayouts
template <typename BuilderImpl>
class ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, BuilderImpl> {
public:
// Build and return the table. The builder should not be used after this.
::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse Build() {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse t = std::move(table_);
// Poison this builder to prevent accidental reuse.
table_.frame_ptr_ = nullptr;
return t;
}
BuilderImpl& a(uint16_t elem) {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
table_.frame_ptr_->a_.set_data(std::move(elem));
table_.max_ordinal_ = std::max(table_.max_ordinal_, static_cast<uint64_t>(1));
return *static_cast<BuilderImpl*>(this);
}
protected:
WireTableBaseBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>&& frame)
: table_(std::move(frame)) {}
private:
::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse table_;
};
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>;
public:
private:
friend class ::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse;
WireTableBuilder(::fidl::AnyArena& arena)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>(arena)),
arena_(arena) {}
[[maybe_unused]] std::reference_wrapper<::fidl::AnyArena> arena_;
};
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>;
private:
friend class ::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse;
using Base::Base;
WireTableExternalBuilder(::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>* frame)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>>::FromExternal(frame)) {}
};
namespace test_protocollayouts {
namespace wire {
inline ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> MainProtocolTwoWayAnonResponse::Builder(::fidl::AnyArena& arena) {
return ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>(arena);
}
inline ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> MainProtocolTwoWayAnonResponse::ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>> frame) {
return ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>(std::move(frame));
}
} // namespace wire
} // namespace test_protocollayouts
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>;
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>;
template <>
struct ::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> final {
public:
WireTableFrame() = default;
// In its intended usage, WireTableFrame will be referenced by an ObjectView.
// If the ObjectView 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.
WireTableFrame(const WireTableFrame&) = delete;
WireTableFrame& operator=(const WireTableFrame&) = delete;
private:
WireTableFrame(WireTableFrame&&) noexcept = default;
WireTableFrame& operator=(WireTableFrame&&) noexcept = default;
bool HasUnknownData() const;
::fidl::Envelope<uint16_t> a_;
friend class ::test_protocollayouts::wire::MainProtocolOneWayAnonRequest;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>;
};
namespace test_protocollayouts {
namespace wire {
extern "C" const fidl_type_t test_protocollayouts_MainProtocolOneWayAnonRequestTable;
class MainProtocolOneWayAnonRequest {
public:
MainProtocolOneWayAnonRequest() = default;
MainProtocolOneWayAnonRequest(const MainProtocolOneWayAnonRequest& other) noexcept = default;
MainProtocolOneWayAnonRequest& operator=(const MainProtocolOneWayAnonRequest& other) noexcept = default;
MainProtocolOneWayAnonRequest(MainProtocolOneWayAnonRequest&& other) noexcept = default;
MainProtocolOneWayAnonRequest& operator=(MainProtocolOneWayAnonRequest&& other) noexcept = default;
~MainProtocolOneWayAnonRequest() = default;
// Returns whether no field is set.
bool IsEmpty() const { return max_ordinal_ == 0; }
// Returns whether the table references unknown fields.
bool HasUnknownData() const;
// Return a builder that by defaults allocates of an arena.
static ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> Builder(::fidl::AnyArena& arena);
// Return a builder that relies on explicitly allocating |fidl::ObjectView|s.
static ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>> frame);
const uint16_t& a() const {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
uint16_t& a() {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
bool has_a() const {
return max_ordinal_ >= 1 && frame_ptr_->a_.has_data();
}
#if defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES) || false
public:
#else // !defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES)
private:
#endif // FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES
MainProtocolOneWayAnonRequest& set_a(uint16_t elem) {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.set_data(std::move(elem));
max_ordinal_ = std::max(max_ordinal_, static_cast<uint64_t>(1));
return *this;
}
MainProtocolOneWayAnonRequest& clear_a() {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.clear_data();
return *this;
}
explicit MainProtocolOneWayAnonRequest(::fidl::AnyArena& allocator)
: frame_ptr_(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>(allocator)) {}
// This constructor allows a user controlled allocation (not using a Arena).
// It should only be used when performance is key.
// As soon as the frame is given to the table, it must not be used directly or for another table.
explicit MainProtocolOneWayAnonRequest(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>&& frame)
: frame_ptr_(std::move(frame)) {}
void Allocate(::fidl::AnyArena& allocator) {
max_ordinal_ = 0;
frame_ptr_ = ::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>(allocator);
}
void Init(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>&& frame_ptr) {
max_ordinal_ = 0;
frame_ptr_ = std::move(frame_ptr);
}
private:
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>;
uint64_t max_ordinal_ = 0;
::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>> frame_ptr_;
};
} // namespace wire
} // namespace test_protocollayouts
template <typename BuilderImpl>
class ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, BuilderImpl> {
public:
// Build and return the table. The builder should not be used after this.
::test_protocollayouts::wire::MainProtocolOneWayAnonRequest Build() {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
::test_protocollayouts::wire::MainProtocolOneWayAnonRequest t = std::move(table_);
// Poison this builder to prevent accidental reuse.
table_.frame_ptr_ = nullptr;
return t;
}
BuilderImpl& a(uint16_t elem) {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
table_.frame_ptr_->a_.set_data(std::move(elem));
table_.max_ordinal_ = std::max(table_.max_ordinal_, static_cast<uint64_t>(1));
return *static_cast<BuilderImpl*>(this);
}
protected:
WireTableBaseBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>&& frame)
: table_(std::move(frame)) {}
private:
::test_protocollayouts::wire::MainProtocolOneWayAnonRequest table_;
};
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>;
public:
private:
friend class ::test_protocollayouts::wire::MainProtocolOneWayAnonRequest;
WireTableBuilder(::fidl::AnyArena& arena)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>(arena)),
arena_(arena) {}
[[maybe_unused]] std::reference_wrapper<::fidl::AnyArena> arena_;
};
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>;
private:
friend class ::test_protocollayouts::wire::MainProtocolOneWayAnonRequest;
using Base::Base;
WireTableExternalBuilder(::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>* frame)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>>::FromExternal(frame)) {}
};
namespace test_protocollayouts {
namespace wire {
inline ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> MainProtocolOneWayAnonRequest::Builder(::fidl::AnyArena& arena) {
return ::fidl::WireTableBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>(arena);
}
inline ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> MainProtocolOneWayAnonRequest::ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>> frame) {
return ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>(std::move(frame));
}
} // namespace wire
} // namespace test_protocollayouts
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload>;
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload>;
template <>
struct ::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload> final {
public:
WireTableFrame() = default;
// In its intended usage, WireTableFrame will be referenced by an ObjectView.
// If the ObjectView 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.
WireTableFrame(const WireTableFrame&) = delete;
WireTableFrame& operator=(const WireTableFrame&) = delete;
private:
WireTableFrame(WireTableFrame&&) noexcept = default;
WireTableFrame& operator=(WireTableFrame&&) noexcept = default;
bool HasUnknownData() const;
::fidl::Envelope<uint16_t> a_;
friend class ::test_protocollayouts::wire::LocalTablePayload;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload>>;
};
namespace test_protocollayouts {
namespace wire {
extern "C" const fidl_type_t test_protocollayouts_LocalTablePayloadTable;
class LocalTablePayload {
public:
LocalTablePayload() = default;
LocalTablePayload(const LocalTablePayload& other) noexcept = default;
LocalTablePayload& operator=(const LocalTablePayload& other) noexcept = default;
LocalTablePayload(LocalTablePayload&& other) noexcept = default;
LocalTablePayload& operator=(LocalTablePayload&& other) noexcept = default;
~LocalTablePayload() = default;
// Returns whether no field is set.
bool IsEmpty() const { return max_ordinal_ == 0; }
// Returns whether the table references unknown fields.
bool HasUnknownData() const;
// Return a builder that by defaults allocates of an arena.
static ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload> Builder(::fidl::AnyArena& arena);
// Return a builder that relies on explicitly allocating |fidl::ObjectView|s.
static ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload> ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>> frame);
const uint16_t& a() const {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
uint16_t& a() {
ZX_ASSERT(has_a());
return frame_ptr_->a_.get_data();
}
bool has_a() const {
return max_ordinal_ >= 1 && frame_ptr_->a_.has_data();
}
#if defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES) || false
public:
#else // !defined(FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES)
private:
#endif // FIDL_WIRE_ALLOW_DEPRECATED_MUTABLE_TABLES
LocalTablePayload& set_a(uint16_t elem) {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.set_data(std::move(elem));
max_ordinal_ = std::max(max_ordinal_, static_cast<uint64_t>(1));
return *this;
}
LocalTablePayload& clear_a() {
ZX_DEBUG_ASSERT(frame_ptr_ != nullptr);
frame_ptr_->a_.clear_data();
return *this;
}
explicit LocalTablePayload(::fidl::AnyArena& allocator)
: frame_ptr_(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>>(allocator)) {}
// This constructor allows a user controlled allocation (not using a Arena).
// It should only be used when performance is key.
// As soon as the frame is given to the table, it must not be used directly or for another table.
explicit LocalTablePayload(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>>&& frame)
: frame_ptr_(std::move(frame)) {}
void Allocate(::fidl::AnyArena& allocator) {
max_ordinal_ = 0;
frame_ptr_ = ::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>>(allocator);
}
void Init(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>>&& frame_ptr) {
max_ordinal_ = 0;
frame_ptr_ = std::move(frame_ptr);
}
private:
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload>>;
friend ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload>>;
uint64_t max_ordinal_ = 0;
::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>> frame_ptr_;
};
} // namespace wire
} // namespace test_protocollayouts
template <typename BuilderImpl>
class ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, BuilderImpl> {
public:
// Build and return the table. The builder should not be used after this.
::test_protocollayouts::wire::LocalTablePayload Build() {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
::test_protocollayouts::wire::LocalTablePayload t = std::move(table_);
// Poison this builder to prevent accidental reuse.
table_.frame_ptr_ = nullptr;
return t;
}
BuilderImpl& a(uint16_t elem) {
ZX_DEBUG_ASSERT(table_.frame_ptr_ != nullptr);
table_.frame_ptr_->a_.set_data(std::move(elem));
table_.max_ordinal_ = std::max(table_.max_ordinal_, static_cast<uint64_t>(1));
return *static_cast<BuilderImpl*>(this);
}
protected:
WireTableBaseBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>>&& frame)
: table_(std::move(frame)) {}
private:
::test_protocollayouts::wire::LocalTablePayload table_;
};
template <>
class ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload>>;
public:
private:
friend class ::test_protocollayouts::wire::LocalTablePayload;
WireTableBuilder(::fidl::AnyArena& arena)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>>(arena)),
arena_(arena) {}
[[maybe_unused]] std::reference_wrapper<::fidl::AnyArena> arena_;
};
template <>
class ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload> final : public ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload>> {
using Base = ::fidl::internal::WireTableBaseBuilder<::test_protocollayouts::wire::LocalTablePayload, ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload>>;
private:
friend class ::test_protocollayouts::wire::LocalTablePayload;
using Base::Base;
WireTableExternalBuilder(::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>* frame)
: Base(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>>::FromExternal(frame)) {}
};
namespace test_protocollayouts {
namespace wire {
inline ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload> LocalTablePayload::Builder(::fidl::AnyArena& arena) {
return ::fidl::WireTableBuilder<::test_protocollayouts::wire::LocalTablePayload>(arena);
}
inline ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload> LocalTablePayload::ExternalBuilder(::fidl::ObjectView<::fidl::WireTableFrame<::test_protocollayouts::wire::LocalTablePayload>> frame) {
return ::fidl::WireTableExternalBuilder<::test_protocollayouts::wire::LocalTablePayload>(std::move(frame));
}
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_TwoWayImportWithError_ResultTable;
class MainProtocolTwoWayImportWithErrorResult {
public:
MainProtocolTwoWayImportWithErrorResult() : ordinal_(::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::Invalid), envelope_{} {}
MainProtocolTwoWayImportWithErrorResult(const MainProtocolTwoWayImportWithErrorResult&) = default;
MainProtocolTwoWayImportWithErrorResult& operator=(const MainProtocolTwoWayImportWithErrorResult&) = default;
MainProtocolTwoWayImportWithErrorResult(MainProtocolTwoWayImportWithErrorResult&&) = default;
MainProtocolTwoWayImportWithErrorResult& operator=(MainProtocolTwoWayImportWithErrorResult&&) = default;
enum class Tag : fidl_xunion_tag_t {
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::Invalid; }
bool is_response() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kResponse; }
static MainProtocolTwoWayImportWithErrorResult WithResponse(::fidl::ObjectView<::test_protocollayouts_imported::wire::ImportUnionPayload> val) {
MainProtocolTwoWayImportWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kResponse;
result.envelope_.As<::test_protocollayouts_imported::wire::ImportUnionPayload>().set_data(std::move(val));
return result;
}
template <typename... Args>
static MainProtocolTwoWayImportWithErrorResult WithResponse(::fidl::AnyArena& allocator, Args&&... args) {
return WithResponse(::fidl::ObjectView<::test_protocollayouts_imported::wire::ImportUnionPayload>(allocator,
std::forward<Args>(args)...));
}
::test_protocollayouts_imported::wire::ImportUnionPayload& response() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts_imported::wire::ImportUnionPayload>().get_data();
}
const ::test_protocollayouts_imported::wire::ImportUnionPayload& response() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts_imported::wire::ImportUnionPayload>().get_data();
}
bool is_err() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kErr; }
static MainProtocolTwoWayImportWithErrorResult WithErr(uint32_t val) {
MainProtocolTwoWayImportWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kErr;
result.envelope_.As<uint32_t>().set_data(std::move(val));
return result;
}
uint32_t& err() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
const uint32_t& err() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag Which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag>(ordinal_);
}
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_TwoWayAnonWithError_ResponseTable;
class MainProtocolTwoWayAnonWithErrorResponse {
public:
MainProtocolTwoWayAnonWithErrorResponse() : ordinal_(::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Ordinal::Invalid), envelope_{} {}
MainProtocolTwoWayAnonWithErrorResponse(const MainProtocolTwoWayAnonWithErrorResponse&) = default;
MainProtocolTwoWayAnonWithErrorResponse& operator=(const MainProtocolTwoWayAnonWithErrorResponse&) = default;
MainProtocolTwoWayAnonWithErrorResponse(MainProtocolTwoWayAnonWithErrorResponse&&) = default;
MainProtocolTwoWayAnonWithErrorResponse& operator=(MainProtocolTwoWayAnonWithErrorResponse&&) = default;
enum class Tag : fidl_xunion_tag_t {
kB = 1, // 0x1
kUnknown = ::std::numeric_limits<::fidl_union_tag_t>::max(),
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Ordinal::Invalid; }
bool is_b() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Ordinal::kB; }
static MainProtocolTwoWayAnonWithErrorResponse WithB(bool val) {
MainProtocolTwoWayAnonWithErrorResponse result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Ordinal::kB;
result.envelope_.As<bool>().set_data(std::move(val));
return result;
}
bool& b() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
const bool& b() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Tag Which() const;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kB = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_TwoWayAnonWithError_ResultTable;
class MainProtocolTwoWayAnonWithErrorResult {
public:
using Response = test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse;
MainProtocolTwoWayAnonWithErrorResult() : ordinal_(::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::Invalid), envelope_{} {}
MainProtocolTwoWayAnonWithErrorResult(const MainProtocolTwoWayAnonWithErrorResult&) = default;
MainProtocolTwoWayAnonWithErrorResult& operator=(const MainProtocolTwoWayAnonWithErrorResult&) = default;
MainProtocolTwoWayAnonWithErrorResult(MainProtocolTwoWayAnonWithErrorResult&&) = default;
MainProtocolTwoWayAnonWithErrorResult& operator=(MainProtocolTwoWayAnonWithErrorResult&&) = default;
enum class Tag : fidl_xunion_tag_t {
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::Invalid; }
bool is_response() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kResponse; }
static MainProtocolTwoWayAnonWithErrorResult WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse> val) {
MainProtocolTwoWayAnonWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kResponse;
result.envelope_.As<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse>().set_data(std::move(val));
return result;
}
template <typename... Args>
static MainProtocolTwoWayAnonWithErrorResult WithResponse(::fidl::AnyArena& allocator, Args&&... args) {
return WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse>(allocator,
std::forward<Args>(args)...));
}
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse& response() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse>().get_data();
}
const ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse& response() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse>().get_data();
}
bool is_err() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kErr; }
static MainProtocolTwoWayAnonWithErrorResult WithErr(uint32_t val) {
MainProtocolTwoWayAnonWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kErr;
result.envelope_.As<uint32_t>().set_data(std::move(val));
return result;
}
uint32_t& err() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
const uint32_t& err() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag Which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag>(ordinal_);
}
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_OnImportWithError_ResultTable;
class MainProtocolOnImportWithErrorResult {
public:
MainProtocolOnImportWithErrorResult() : ordinal_(::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::Invalid), envelope_{} {}
MainProtocolOnImportWithErrorResult(const MainProtocolOnImportWithErrorResult&) = default;
MainProtocolOnImportWithErrorResult& operator=(const MainProtocolOnImportWithErrorResult&) = default;
MainProtocolOnImportWithErrorResult(MainProtocolOnImportWithErrorResult&&) = default;
MainProtocolOnImportWithErrorResult& operator=(MainProtocolOnImportWithErrorResult&&) = default;
enum class Tag : fidl_xunion_tag_t {
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::Invalid; }
bool is_response() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kResponse; }
static MainProtocolOnImportWithErrorResult WithResponse(::fidl::ObjectView<::test_protocollayouts_imported::wire::ImportTablePayload> val) {
MainProtocolOnImportWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kResponse;
result.envelope_.As<::test_protocollayouts_imported::wire::ImportTablePayload>().set_data(std::move(val));
return result;
}
template <typename... Args>
static MainProtocolOnImportWithErrorResult WithResponse(::fidl::AnyArena& allocator, Args&&... args) {
return WithResponse(::fidl::ObjectView<::test_protocollayouts_imported::wire::ImportTablePayload>(allocator,
std::forward<Args>(args)...));
}
::test_protocollayouts_imported::wire::ImportTablePayload& response() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts_imported::wire::ImportTablePayload>().get_data();
}
const ::test_protocollayouts_imported::wire::ImportTablePayload& response() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts_imported::wire::ImportTablePayload>().get_data();
}
bool is_err() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kErr; }
static MainProtocolOnImportWithErrorResult WithErr(uint32_t val) {
MainProtocolOnImportWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kErr;
result.envelope_.As<uint32_t>().set_data(std::move(val));
return result;
}
uint32_t& err() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
const uint32_t& err() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag Which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag>(ordinal_);
}
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_OnAnonWithError_ResultTable;
class MainProtocolOnAnonWithErrorResult {
public:
using Response = test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse;
MainProtocolOnAnonWithErrorResult() : ordinal_(::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::Invalid), envelope_{} {}
MainProtocolOnAnonWithErrorResult(const MainProtocolOnAnonWithErrorResult&) = default;
MainProtocolOnAnonWithErrorResult& operator=(const MainProtocolOnAnonWithErrorResult&) = default;
MainProtocolOnAnonWithErrorResult(MainProtocolOnAnonWithErrorResult&&) = default;
MainProtocolOnAnonWithErrorResult& operator=(MainProtocolOnAnonWithErrorResult&&) = default;
enum class Tag : fidl_xunion_tag_t {
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::Invalid; }
bool is_response() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kResponse; }
static MainProtocolOnAnonWithErrorResult WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> val) {
MainProtocolOnAnonWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kResponse;
result.envelope_.As<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>().set_data(std::move(val));
return result;
}
template <typename... Args>
static MainProtocolOnAnonWithErrorResult WithResponse(::fidl::AnyArena& allocator, Args&&... args) {
return WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>(allocator,
std::forward<Args>(args)...));
}
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse& response() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>().get_data();
}
const ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse& response() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>().get_data();
}
bool is_err() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kErr; }
static MainProtocolOnAnonWithErrorResult WithErr(uint32_t val) {
MainProtocolOnAnonWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kErr;
result.envelope_.As<uint32_t>().set_data(std::move(val));
return result;
}
uint32_t& err() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
const uint32_t& err() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag Which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag>(ordinal_);
}
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolTwoWayAnonRequestTable;
class MainProtocolTwoWayAnonRequest {
public:
MainProtocolTwoWayAnonRequest() : ordinal_(::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Ordinal::Invalid), envelope_{} {}
MainProtocolTwoWayAnonRequest(const MainProtocolTwoWayAnonRequest&) = default;
MainProtocolTwoWayAnonRequest& operator=(const MainProtocolTwoWayAnonRequest&) = default;
MainProtocolTwoWayAnonRequest(MainProtocolTwoWayAnonRequest&&) = default;
MainProtocolTwoWayAnonRequest& operator=(MainProtocolTwoWayAnonRequest&&) = default;
enum class Tag : fidl_xunion_tag_t {
kB = 1, // 0x1
kUnknown = ::std::numeric_limits<::fidl_union_tag_t>::max(),
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Ordinal::Invalid; }
bool is_b() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Ordinal::kB; }
static MainProtocolTwoWayAnonRequest WithB(bool val) {
MainProtocolTwoWayAnonRequest result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Ordinal::kB;
result.envelope_.As<bool>().set_data(std::move(val));
return result;
}
bool& b() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
const bool& b() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Tag Which() const;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kB = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolOnAnonRequestTable;
class MainProtocolOnAnonRequest {
public:
MainProtocolOnAnonRequest() : ordinal_(::test_protocollayouts::wire::MainProtocolOnAnonRequest::Ordinal::Invalid), envelope_{} {}
MainProtocolOnAnonRequest(const MainProtocolOnAnonRequest&) = default;
MainProtocolOnAnonRequest& operator=(const MainProtocolOnAnonRequest&) = default;
MainProtocolOnAnonRequest(MainProtocolOnAnonRequest&&) = default;
MainProtocolOnAnonRequest& operator=(MainProtocolOnAnonRequest&&) = default;
enum class Tag : fidl_xunion_tag_t {
kB = 1, // 0x1
kUnknown = ::std::numeric_limits<::fidl_union_tag_t>::max(),
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Ordinal::Invalid; }
bool is_b() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Ordinal::kB; }
static MainProtocolOnAnonRequest WithB(bool val) {
MainProtocolOnAnonRequest result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Ordinal::kB;
result.envelope_.As<bool>().set_data(std::move(val));
return result;
}
bool& b() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
const bool& b() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
::test_protocollayouts::wire::MainProtocolOnAnonRequest::Tag Which() const;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kB = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolOnAnonRequest::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_LocalUnionPayloadTable;
class LocalUnionPayload {
public:
LocalUnionPayload() : ordinal_(::test_protocollayouts::wire::LocalUnionPayload::Ordinal::Invalid), envelope_{} {}
LocalUnionPayload(const LocalUnionPayload&) = default;
LocalUnionPayload& operator=(const LocalUnionPayload&) = default;
LocalUnionPayload(LocalUnionPayload&&) = default;
LocalUnionPayload& operator=(LocalUnionPayload&&) = default;
enum class Tag : fidl_xunion_tag_t {
kB = 1, // 0x1
kUnknown = ::std::numeric_limits<::fidl_union_tag_t>::max(),
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::LocalUnionPayload::Ordinal::Invalid; }
bool is_b() const { return ordinal_ == ::test_protocollayouts::wire::LocalUnionPayload::Ordinal::kB; }
static LocalUnionPayload WithB(bool val) {
LocalUnionPayload result;
result.ordinal_ = ::test_protocollayouts::wire::LocalUnionPayload::Ordinal::kB;
result.envelope_.As<bool>().set_data(std::move(val));
return result;
}
bool& b() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::LocalUnionPayload::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
const bool& b() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::LocalUnionPayload::Ordinal::kB);
return envelope_.As<bool>().get_data();
}
::test_protocollayouts::wire::LocalUnionPayload::Tag Which() const;
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kB = 1, // 0x1
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::LocalUnionPayload::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_TwoWayLocalWithError_ResultTable;
class MainProtocolTwoWayLocalWithErrorResult {
public:
MainProtocolTwoWayLocalWithErrorResult() : ordinal_(::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::Invalid), envelope_{} {}
MainProtocolTwoWayLocalWithErrorResult(const MainProtocolTwoWayLocalWithErrorResult&) = default;
MainProtocolTwoWayLocalWithErrorResult& operator=(const MainProtocolTwoWayLocalWithErrorResult&) = default;
MainProtocolTwoWayLocalWithErrorResult(MainProtocolTwoWayLocalWithErrorResult&&) = default;
MainProtocolTwoWayLocalWithErrorResult& operator=(MainProtocolTwoWayLocalWithErrorResult&&) = default;
enum class Tag : fidl_xunion_tag_t {
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::Invalid; }
bool is_response() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kResponse; }
static MainProtocolTwoWayLocalWithErrorResult WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::LocalUnionPayload> val) {
MainProtocolTwoWayLocalWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kResponse;
result.envelope_.As<::test_protocollayouts::wire::LocalUnionPayload>().set_data(std::move(val));
return result;
}
template <typename... Args>
static MainProtocolTwoWayLocalWithErrorResult WithResponse(::fidl::AnyArena& allocator, Args&&... args) {
return WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::LocalUnionPayload>(allocator,
std::forward<Args>(args)...));
}
::test_protocollayouts::wire::LocalUnionPayload& response() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::LocalUnionPayload>().get_data();
}
const ::test_protocollayouts::wire::LocalUnionPayload& response() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::LocalUnionPayload>().get_data();
}
bool is_err() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kErr; }
static MainProtocolTwoWayLocalWithErrorResult WithErr(uint32_t val) {
MainProtocolTwoWayLocalWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kErr;
result.envelope_.As<uint32_t>().set_data(std::move(val));
return result;
}
uint32_t& err() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
const uint32_t& err() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag Which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag>(ordinal_);
}
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocol_OnLocalWithError_ResultTable;
class MainProtocolOnLocalWithErrorResult {
public:
MainProtocolOnLocalWithErrorResult() : ordinal_(::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::Invalid), envelope_{} {}
MainProtocolOnLocalWithErrorResult(const MainProtocolOnLocalWithErrorResult&) = default;
MainProtocolOnLocalWithErrorResult& operator=(const MainProtocolOnLocalWithErrorResult&) = default;
MainProtocolOnLocalWithErrorResult(MainProtocolOnLocalWithErrorResult&&) = default;
MainProtocolOnLocalWithErrorResult& operator=(MainProtocolOnLocalWithErrorResult&&) = default;
enum class Tag : fidl_xunion_tag_t {
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
bool has_invalid_tag() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::Invalid; }
bool is_response() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kResponse; }
static MainProtocolOnLocalWithErrorResult WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::LocalTablePayload> val) {
MainProtocolOnLocalWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kResponse;
result.envelope_.As<::test_protocollayouts::wire::LocalTablePayload>().set_data(std::move(val));
return result;
}
template <typename... Args>
static MainProtocolOnLocalWithErrorResult WithResponse(::fidl::AnyArena& allocator, Args&&... args) {
return WithResponse(::fidl::ObjectView<::test_protocollayouts::wire::LocalTablePayload>(allocator,
std::forward<Args>(args)...));
}
::test_protocollayouts::wire::LocalTablePayload& response() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::LocalTablePayload>().get_data();
}
const ::test_protocollayouts::wire::LocalTablePayload& response() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kResponse);
return envelope_.As<::test_protocollayouts::wire::LocalTablePayload>().get_data();
}
bool is_err() const { return ordinal_ == ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kErr; }
static MainProtocolOnLocalWithErrorResult WithErr(uint32_t val) {
MainProtocolOnLocalWithErrorResult result;
result.ordinal_ = ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kErr;
result.envelope_.As<uint32_t>().set_data(std::move(val));
return result;
}
uint32_t& err() {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
const uint32_t& err() const {
ZX_ASSERT(ordinal_ == ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal::kErr);
return envelope_.As<uint32_t>().get_data();
}
::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag Which() const {
ZX_ASSERT(!has_invalid_tag());
return static_cast<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag>(ordinal_);
}
private:
enum class Ordinal : fidl_xunion_tag_t {
Invalid = 0,
kResponse = 1, // 0x1
kErr = 2, // 0x2
};
static void SizeAndOffsetAssertionHelper();
::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Ordinal ordinal_;
FIDL_ALIGNDECL
::fidl::UntypedEnvelope envelope_;
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolTwoWayImportWithErrorTopResponseTable;
struct MainProtocolTwoWayImportWithErrorTopResponse {
using Result = test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult;
::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult result = {};
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolTwoWayAnonWithErrorTopResponseTable;
struct MainProtocolTwoWayAnonWithErrorTopResponse {
using Result = test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult;
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult result = {};
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolOnImportWithErrorRequestTable;
struct MainProtocolOnImportWithErrorRequest {
using Result = test_protocollayouts::wire::MainProtocolOnImportWithErrorResult;
::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult result = {};
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolOnAnonWithErrorRequestTable;
struct MainProtocolOnAnonWithErrorRequest {
using Result = test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult;
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult result = {};
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolTwoWayLocalWithErrorTopResponseTable;
struct MainProtocolTwoWayLocalWithErrorTopResponse {
using Result = test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult;
::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult result = {};
};
extern "C" const fidl_type_t test_protocollayouts_MainProtocolOnLocalWithErrorRequestTable;
struct MainProtocolOnLocalWithErrorRequest {
using Result = test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult;
::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult result = {};
};
} // namespace wire
} // namespace test_protocollayouts
namespace fidl {
// TODO(fxbug.dev/95833) Remove this.
template <>
struct DeprecatedCTypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse> {
static constexpr const fidl_type_t* kType = &::test_protocollayouts::wire::test_protocollayouts_MainProtocolTwoWayImportWithErrorTopResponseTable;
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 16;
static constexpr uint32_t kMaxOutOfLineV1 = 32;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse> : public std::true_type {};
template <>
struct IsStruct<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse>);
static_assert(offsetof(::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse, result) == 0);
static_assert(sizeof(::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse) == TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse>::kPrimarySize);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr auto kMembers = std::make_tuple(::fidl::internal::WireStructMemberCodingInfo<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>());
static constexpr bool kHasPadding = false;
using Base = WireStructCodingTraitsBase<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>;
static constexpr bool is_memcpy_compatible = Base::is_memcpy_compatible;
static void Encode(
internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (is_memcpy_compatible) {
memcpy(position.As<void>(), value, sizeof(::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorTopResponse));
} else {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Encode(encoder, &value->result, position + 0, recursion_depth);
}
}
static void Decode(
internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (!Base::are_members_memcpy_compatible) {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Decode(
decoder, position + 0, recursion_depth);
}
}
};
// TODO(fxbug.dev/95833) Remove this.
template <>
struct DeprecatedCTypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse> {
static constexpr const fidl_type_t* kType = &::test_protocollayouts::wire::test_protocollayouts_MainProtocolTwoWayAnonWithErrorTopResponseTable;
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 16;
static constexpr uint32_t kMaxOutOfLineV1 = 32;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse> : public std::true_type {};
template <>
struct IsStruct<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse>);
static_assert(offsetof(::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse, result) == 0);
static_assert(sizeof(::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse) == TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse>::kPrimarySize);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr auto kMembers = std::make_tuple(::fidl::internal::WireStructMemberCodingInfo<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>());
static constexpr bool kHasPadding = false;
using Base = WireStructCodingTraitsBase<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>;
static constexpr bool is_memcpy_compatible = Base::is_memcpy_compatible;
static void Encode(
internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (is_memcpy_compatible) {
memcpy(position.As<void>(), value, sizeof(::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorTopResponse));
} else {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Encode(encoder, &value->result, position + 0, recursion_depth);
}
}
static void Decode(
internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (!Base::are_members_memcpy_compatible) {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Decode(
decoder, position + 0, recursion_depth);
}
}
};
// TODO(fxbug.dev/95833) Remove this.
template <>
struct DeprecatedCTypeTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest> {
static constexpr const fidl_type_t* kType = &::test_protocollayouts::wire::test_protocollayouts_MainProtocolOnImportWithErrorRequestTable;
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 3;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 24;
static constexpr uint32_t kMaxOutOfLineV1 = 40;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest> : public std::true_type {};
template <>
struct IsStruct<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest>);
static_assert(offsetof(::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest, result) == 0);
static_assert(sizeof(::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest) == TypeTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest>::kPrimarySize);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr auto kMembers = std::make_tuple(::fidl::internal::WireStructMemberCodingInfo<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>());
static constexpr bool kHasPadding = false;
using Base = WireStructCodingTraitsBase<::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>;
static constexpr bool is_memcpy_compatible = Base::is_memcpy_compatible;
static void Encode(
internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (is_memcpy_compatible) {
memcpy(position.As<void>(), value, sizeof(::test_protocollayouts::wire::MainProtocolOnImportWithErrorRequest));
} else {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Encode(encoder, &value->result, position + 0, recursion_depth);
}
}
static void Decode(
internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (!Base::are_members_memcpy_compatible) {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Decode(
decoder, position + 0, recursion_depth);
}
}
};
// TODO(fxbug.dev/95833) Remove this.
template <>
struct DeprecatedCTypeTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest> {
static constexpr const fidl_type_t* kType = &::test_protocollayouts::wire::test_protocollayouts_MainProtocolOnAnonWithErrorRequestTable;
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 3;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 24;
static constexpr uint32_t kMaxOutOfLineV1 = 40;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest> : public std::true_type {};
template <>
struct IsStruct<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest>);
static_assert(offsetof(::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest, result) == 0);
static_assert(sizeof(::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest) == TypeTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest>::kPrimarySize);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr auto kMembers = std::make_tuple(::fidl::internal::WireStructMemberCodingInfo<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>());
static constexpr bool kHasPadding = false;
using Base = WireStructCodingTraitsBase<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>;
static constexpr bool is_memcpy_compatible = Base::is_memcpy_compatible;
static void Encode(
internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (is_memcpy_compatible) {
memcpy(position.As<void>(), value, sizeof(::test_protocollayouts::wire::MainProtocolOnAnonWithErrorRequest));
} else {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Encode(encoder, &value->result, position + 0, recursion_depth);
}
}
static void Decode(
internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (!Base::are_members_memcpy_compatible) {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Decode(
decoder, position + 0, recursion_depth);
}
}
};
// TODO(fxbug.dev/95833) Remove this.
template <>
struct DeprecatedCTypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse> {
static constexpr const fidl_type_t* kType = &::test_protocollayouts::wire::test_protocollayouts_MainProtocolTwoWayLocalWithErrorTopResponseTable;
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 16;
static constexpr uint32_t kMaxOutOfLineV1 = 32;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse> : public std::true_type {};
template <>
struct IsStruct<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse>);
static_assert(offsetof(::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse, result) == 0);
static_assert(sizeof(::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse) == TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse>::kPrimarySize);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr auto kMembers = std::make_tuple(::fidl::internal::WireStructMemberCodingInfo<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>());
static constexpr bool kHasPadding = false;
using Base = WireStructCodingTraitsBase<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>;
static constexpr bool is_memcpy_compatible = Base::is_memcpy_compatible;
static void Encode(
internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (is_memcpy_compatible) {
memcpy(position.As<void>(), value, sizeof(::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorTopResponse));
} else {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Encode(encoder, &value->result, position + 0, recursion_depth);
}
}
static void Decode(
internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (!Base::are_members_memcpy_compatible) {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Decode(
decoder, position + 0, recursion_depth);
}
}
};
// TODO(fxbug.dev/95833) Remove this.
template <>
struct DeprecatedCTypeTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest> {
static constexpr const fidl_type_t* kType = &::test_protocollayouts::wire::test_protocollayouts_MainProtocolOnLocalWithErrorRequestTable;
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 3;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 24;
static constexpr uint32_t kMaxOutOfLineV1 = 40;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest> : public std::true_type {};
template <>
struct IsStruct<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest>);
static_assert(offsetof(::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest, result) == 0);
static_assert(sizeof(::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest) == TypeTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest>::kPrimarySize);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr auto kMembers = std::make_tuple(::fidl::internal::WireStructMemberCodingInfo<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>());
static constexpr bool kHasPadding = false;
using Base = WireStructCodingTraitsBase<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>;
static constexpr bool is_memcpy_compatible = Base::is_memcpy_compatible;
static void Encode(
internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (is_memcpy_compatible) {
memcpy(position.As<void>(), value, sizeof(::test_protocollayouts::wire::MainProtocolOnLocalWithErrorRequest));
} else {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Encode(encoder, &value->result, position + 0, recursion_depth);
}
}
static void Decode(
internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
if constexpr (!Base::are_members_memcpy_compatible) {
internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::Decode(
decoder, position + 0, recursion_depth);
}
}
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 16;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 8;
static constexpr uint32_t kMaxOutOfLineV1 = 24;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> : public std::true_type {};
template <>
struct IsTable<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse>);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: ::fidl::internal::WireTableCodingTraitsBase<IsRecursive> {
using Base = ::fidl::internal::WireTableCodingTraitsBase<IsRecursive>;
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit ==
Base::PrepareForBodyEncode(encoder, value, position, &vector_position)) {
return;
}
fidl_vector_t* vec = reinterpret_cast<fidl_vector_t*>(value);
fidl_envelope_v2_t* envelopes = static_cast<fidl_envelope_v2_t*>(vec->data);
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn = nullptr;
switch (i) {
case 0:
encode_fn = ::fidl::internal::MakeEncodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
WirePosition envelope_position = vector_position + i * sizeof(fidl_envelope_v2_t);
WireEncodeEnvelope(inline_size, encode_fn, encoder, &envelopes[i], envelope_position, inner_depth);
}
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit == Base::DecodePrework(decoder, position, &vector_position)) {
return;
}
fidl_vector_t* vec = position.As<fidl_vector_t>();
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
DecodeFn<IsRecursive> decode_fn = nullptr;
switch (i) {
case 0:
decode_fn = ::fidl::internal::MakeDecodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
::fidl::internal::WireDecodeOptionalEnvelope(inline_size, decode_fn, decoder, vector_position + i * sizeof(fidl_envelope_v2_t), inner_depth);
}
}
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 16;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 8;
static constexpr uint32_t kMaxOutOfLineV1 = 24;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> : public std::true_type {};
template <>
struct IsTable<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest>);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: ::fidl::internal::WireTableCodingTraitsBase<IsRecursive> {
using Base = ::fidl::internal::WireTableCodingTraitsBase<IsRecursive>;
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorRequest* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit ==
Base::PrepareForBodyEncode(encoder, value, position, &vector_position)) {
return;
}
fidl_vector_t* vec = reinterpret_cast<fidl_vector_t*>(value);
fidl_envelope_v2_t* envelopes = static_cast<fidl_envelope_v2_t*>(vec->data);
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn = nullptr;
switch (i) {
case 0:
encode_fn = ::fidl::internal::MakeEncodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
WirePosition envelope_position = vector_position + i * sizeof(fidl_envelope_v2_t);
WireEncodeEnvelope(inline_size, encode_fn, encoder, &envelopes[i], envelope_position, inner_depth);
}
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit == Base::DecodePrework(decoder, position, &vector_position)) {
return;
}
fidl_vector_t* vec = position.As<fidl_vector_t>();
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
DecodeFn<IsRecursive> decode_fn = nullptr;
switch (i) {
case 0:
decode_fn = ::fidl::internal::MakeDecodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
::fidl::internal::WireDecodeOptionalEnvelope(inline_size, decode_fn, decoder, vector_position + i * sizeof(fidl_envelope_v2_t), inner_depth);
}
}
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 16;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 8;
static constexpr uint32_t kMaxOutOfLineV1 = 24;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> : public std::true_type {};
template <>
struct IsTable<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse>);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: ::fidl::internal::WireTableCodingTraitsBase<IsRecursive> {
using Base = ::fidl::internal::WireTableCodingTraitsBase<IsRecursive>;
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayAnonResponse* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit ==
Base::PrepareForBodyEncode(encoder, value, position, &vector_position)) {
return;
}
fidl_vector_t* vec = reinterpret_cast<fidl_vector_t*>(value);
fidl_envelope_v2_t* envelopes = static_cast<fidl_envelope_v2_t*>(vec->data);
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn = nullptr;
switch (i) {
case 0:
encode_fn = ::fidl::internal::MakeEncodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
WirePosition envelope_position = vector_position + i * sizeof(fidl_envelope_v2_t);
WireEncodeEnvelope(inline_size, encode_fn, encoder, &envelopes[i], envelope_position, inner_depth);
}
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit == Base::DecodePrework(decoder, position, &vector_position)) {
return;
}
fidl_vector_t* vec = position.As<fidl_vector_t>();
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
DecodeFn<IsRecursive> decode_fn = nullptr;
switch (i) {
case 0:
decode_fn = ::fidl::internal::MakeDecodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
::fidl::internal::WireDecodeOptionalEnvelope(inline_size, decode_fn, decoder, vector_position + i * sizeof(fidl_envelope_v2_t), inner_depth);
}
}
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 16;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 8;
static constexpr uint32_t kMaxOutOfLineV1 = 24;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> : public std::true_type {};
template <>
struct IsTable<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest>);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOneWayAnonRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: ::fidl::internal::WireTableCodingTraitsBase<IsRecursive> {
using Base = ::fidl::internal::WireTableCodingTraitsBase<IsRecursive>;
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOneWayAnonRequest* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit ==
Base::PrepareForBodyEncode(encoder, value, position, &vector_position)) {
return;
}
fidl_vector_t* vec = reinterpret_cast<fidl_vector_t*>(value);
fidl_envelope_v2_t* envelopes = static_cast<fidl_envelope_v2_t*>(vec->data);
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn = nullptr;
switch (i) {
case 0:
encode_fn = ::fidl::internal::MakeEncodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
WirePosition envelope_position = vector_position + i * sizeof(fidl_envelope_v2_t);
WireEncodeEnvelope(inline_size, encode_fn, encoder, &envelopes[i], envelope_position, inner_depth);
}
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit == Base::DecodePrework(decoder, position, &vector_position)) {
return;
}
fidl_vector_t* vec = position.As<fidl_vector_t>();
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
DecodeFn<IsRecursive> decode_fn = nullptr;
switch (i) {
case 0:
decode_fn = ::fidl::internal::MakeDecodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
::fidl::internal::WireDecodeOptionalEnvelope(inline_size, decode_fn, decoder, vector_position + i * sizeof(fidl_envelope_v2_t), inner_depth);
}
}
};
template <>
struct TypeTraits<::test_protocollayouts::wire::LocalTablePayload> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 16;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 8;
static constexpr uint32_t kMaxOutOfLineV1 = 24;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::LocalTablePayload> : public std::true_type {};
template <>
struct IsTable<::test_protocollayouts::wire::LocalTablePayload> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::LocalTablePayload>);
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalTablePayload, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: ::fidl::internal::WireTableCodingTraitsBase<IsRecursive> {
using Base = ::fidl::internal::WireTableCodingTraitsBase<IsRecursive>;
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::LocalTablePayload* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit ==
Base::PrepareForBodyEncode(encoder, value, position, &vector_position)) {
return;
}
fidl_vector_t* vec = reinterpret_cast<fidl_vector_t*>(value);
fidl_envelope_v2_t* envelopes = static_cast<fidl_envelope_v2_t*>(vec->data);
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn = nullptr;
switch (i) {
case 0:
encode_fn = ::fidl::internal::MakeEncodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
WirePosition envelope_position = vector_position + i * sizeof(fidl_envelope_v2_t);
WireEncodeEnvelope(inline_size, encode_fn, encoder, &envelopes[i], envelope_position, inner_depth);
}
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 2);
if (!inner_depth.IsValid()) {
return;
}
::fidl::internal::WirePosition vector_position;
if (Base::PreworkResult::kEarlyExit == Base::DecodePrework(decoder, position, &vector_position)) {
return;
}
fidl_vector_t* vec = position.As<fidl_vector_t>();
for (size_t i = 0; i < vec->count; i++) {
size_t inline_size = 0;
switch (i) {
case 0:
inline_size = ::fidl::internal::WireCodingTraits<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
}
DecodeFn<IsRecursive> decode_fn = nullptr;
switch (i) {
case 0:
decode_fn = ::fidl::internal::MakeDecodeFn<uint16_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
}
::fidl::internal::WireDecodeOptionalEnvelope(inline_size, decode_fn, decoder, vector_position + i * sizeof(fidl_envelope_v2_t), inner_depth);
}
}
};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 16;
static constexpr uint32_t kMaxOutOfLineV1 = 32;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kResponse
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts_imported::wire::ImportUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::inline_size;
break;
case 2: // ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kErr
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kResponse
encode_fn = ::fidl::internal::MakeEncodeFn<::test_protocollayouts_imported::wire::ImportUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>();
break;
case 2: // ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kErr
encode_fn = ::fidl::internal::MakeEncodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kResponse:
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts_imported::wire::ImportUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::inline_size;
break;
case ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kErr:
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kResponse:
decode_fn = ::fidl::internal::MakeDecodeFn<::test_protocollayouts_imported::wire::ImportUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>();
break;
case ::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult::Tag::kErr:
decode_fn = ::fidl::internal::MakeDecodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeStrictEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayImportWithErrorResult, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 1;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 0;
static constexpr uint32_t kMaxOutOfLineV1 = 8;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Tag::kB
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Tag::kB
encode_fn = ::fidl::internal::MakeEncodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Tag::kB:
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse::Tag::kB:
decode_fn = ::fidl::internal::MakeDecodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeFlexibleEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 16;
static constexpr uint32_t kMaxOutOfLineV1 = 32;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kResponse
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::inline_size;
break;
case 2: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kErr
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kResponse
encode_fn = ::fidl::internal::MakeEncodeFn<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>();
break;
case 2: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kErr
encode_fn = ::fidl::internal::MakeEncodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kResponse:
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::inline_size;
break;
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kErr:
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kResponse:
decode_fn = ::fidl::internal::MakeDecodeFn<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResponse, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>();
break;
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult::Tag::kErr:
decode_fn = ::fidl::internal::MakeDecodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeStrictEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonWithErrorResult, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 3;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 24;
static constexpr uint32_t kMaxOutOfLineV1 = 40;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kResponse
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts_imported::wire::ImportTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
case 2: // ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kErr
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kResponse
encode_fn = ::fidl::internal::MakeEncodeFn<::test_protocollayouts_imported::wire::ImportTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
case 2: // ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kErr
encode_fn = ::fidl::internal::MakeEncodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kResponse:
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts_imported::wire::ImportTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
case ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kErr:
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kResponse:
decode_fn = ::fidl::internal::MakeDecodeFn<::test_protocollayouts_imported::wire::ImportTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
case ::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult::Tag::kErr:
decode_fn = ::fidl::internal::MakeDecodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeStrictEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnImportWithErrorResult, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 3;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 24;
static constexpr uint32_t kMaxOutOfLineV1 = 40;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kResponse
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
case 2: // ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kErr
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kResponse
encode_fn = ::fidl::internal::MakeEncodeFn<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
case 2: // ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kErr
encode_fn = ::fidl::internal::MakeEncodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kResponse:
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
case ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kErr:
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kResponse:
decode_fn = ::fidl::internal::MakeDecodeFn<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResponse, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
case ::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult::Tag::kErr:
decode_fn = ::fidl::internal::MakeDecodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeStrictEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonWithErrorResult, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 1;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 0;
static constexpr uint32_t kMaxOutOfLineV1 = 8;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Tag::kB
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Tag::kB
encode_fn = ::fidl::internal::MakeEncodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Tag::kB:
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest::Tag::kB:
decode_fn = ::fidl::internal::MakeDecodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeFlexibleEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayAnonRequest, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnAnonRequest> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 1;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 0;
static constexpr uint32_t kMaxOutOfLineV1 = 8;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnAnonRequest> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolOnAnonRequest> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnAnonRequest>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonRequest, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnAnonRequest* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Tag::kB
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Tag::kB
encode_fn = ::fidl::internal::MakeEncodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolOnAnonRequest::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolOnAnonRequest::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Tag::kB:
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnAnonRequest::Tag::kB:
decode_fn = ::fidl::internal::MakeDecodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeFlexibleEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonRequest, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnAnonRequest, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::LocalUnionPayload> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 1;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 0;
static constexpr uint32_t kMaxOutOfLineV1 = 8;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::LocalUnionPayload> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::LocalUnionPayload> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::LocalUnionPayload>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalUnionPayload, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::LocalUnionPayload* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::LocalUnionPayload::Tag::kB
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::LocalUnionPayload::Tag::kB
encode_fn = ::fidl::internal::MakeEncodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::LocalUnionPayload::Tag tag = *position.As<::test_protocollayouts::wire::LocalUnionPayload::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::LocalUnionPayload::Tag::kB:
inline_size = ::fidl::internal::WireCodingTraits<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::LocalUnionPayload::Tag::kB:
decode_fn = ::fidl::internal::MakeDecodeFn<bool, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeFlexibleEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalUnionPayload, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalUnionPayload, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 2;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 16;
static constexpr uint32_t kMaxOutOfLineV1 = 32;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kResponse
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::inline_size;
break;
case 2: // ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kErr
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kResponse
encode_fn = ::fidl::internal::MakeEncodeFn<::test_protocollayouts::wire::LocalUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>();
break;
case 2: // ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kErr
encode_fn = ::fidl::internal::MakeEncodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kResponse:
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>::inline_size;
break;
case ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kErr:
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kResponse:
decode_fn = ::fidl::internal::MakeDecodeFn<::test_protocollayouts::wire::LocalUnionPayload, fidl::internal::WireCodingConstraintUnion<false>, IsRecursive>();
break;
case ::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult::Tag::kErr:
decode_fn = ::fidl::internal::MakeDecodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeStrictEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolTwoWayLocalWithErrorResult, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
template <>
struct TypeTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult> {
static constexpr uint32_t kMaxNumHandles = 0;
static constexpr uint32_t kMaxDepth = 3;
static constexpr uint32_t kPrimarySize = 16;
static constexpr uint32_t kPrimarySizeV1 = 24;
[[maybe_unused]] static constexpr uint32_t kMaxOutOfLine = 24;
static constexpr uint32_t kMaxOutOfLineV1 = 40;
static constexpr bool kHasEnvelope = true;
static constexpr bool kHasPointer = true;
};
template <>
struct IsFidlType<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult> : public std::true_type {};
template <>
struct IsUnion<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult> : public std::true_type {};
static_assert(std::is_standard_layout_v<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult>);
template <typename Constraint, bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult, Constraint, IsRecursive> {
static constexpr size_t inline_size = 16;
static constexpr bool is_memcpy_compatible = false;
static void Encode(internal::WireEncoder* encoder, ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult* value, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
fidl_xunion_v2_t* u = reinterpret_cast<fidl_xunion_v2_t*>(value);
if (unlikely(u->tag == 0)) {
if constexpr (Constraint::is_optional) {
*position.As<fidl_xunion_v2_t>() = {};
return;
}
encoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(encoder, 1);
if (!inner_depth.IsValid()) {
return;
}
*position.As<fidl_xunion_tag_t>() = u->tag;
size_t inline_size;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kResponse
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
case 2: // ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kErr
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
::fidl::internal::EncodeFn<IsRecursive> encode_fn;
switch (u->tag) {
case 1: // ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kResponse
encode_fn = ::fidl::internal::MakeEncodeFn<::test_protocollayouts::wire::LocalTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
case 2: // ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kErr
encode_fn = ::fidl::internal::MakeEncodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
encode_fn = nullptr;
break;
}
WireEncodeEnvelope(inline_size, encode_fn, encoder, &u->envelope, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
static void Decode(internal::WireDecoder* decoder, ::fidl::internal::WirePosition position, RecursionDepth<IsRecursive> recursion_depth) {
::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag tag = *position.As<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag>();
if (unlikely(static_cast<uint64_t>(tag) == 0)) {
if constexpr (!Constraint::is_optional) {
decoder->SetError(kCodingErrorInvalidUnionTag);
return;
}
static_assert(sizeof(fidl_envelope_v2_t) == sizeof(uint64_t));
if (*(position + sizeof(fidl_xunion_tag_t)).As<uint64_t>() != 0) {
decoder->SetError(kCodingErrorZeroTagButNonZeroEnvelope);
}
return;
}
RecursionDepth<IsRecursive> inner_depth = recursion_depth.Add(decoder, 1);
if (!inner_depth.IsValid()) {
return;
}
size_t inline_size;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kResponse:
inline_size = ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::LocalTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
case ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kErr:
inline_size = ::fidl::internal::WireCodingTraits<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>::inline_size;
break;
default:
inline_size = 0;
break;
}
DecodeFn<IsRecursive> decode_fn;
switch (tag) {
case ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kResponse:
decode_fn = ::fidl::internal::MakeDecodeFn<::test_protocollayouts::wire::LocalTablePayload, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
case ::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult::Tag::kErr:
decode_fn = ::fidl::internal::MakeDecodeFn<uint32_t, fidl::internal::WireCodingConstraintEmpty, IsRecursive>();
break;
default:
decode_fn = nullptr;
break;
}
::fidl::internal::WireDecodeStrictEnvelope(inline_size, decode_fn, decoder, position + sizeof(fidl_xunion_tag_t), inner_depth);
}
};
// Top-level union.
template <bool IsRecursive>
struct ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult, ::fidl::internal::WireCodingConstraintEmpty, IsRecursive>
: public ::fidl::internal::WireCodingTraits<::test_protocollayouts::wire::MainProtocolOnLocalWithErrorResult, ::fidl::internal::WireCodingConstraintUnion<false>, IsRecursive> {};
} // namespace fidl