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// Generated by the protocol buffer compiler. DO NOT EDIT!
// source: mediapipe/calculators/tensor/image_to_tensor_calculator.proto
#ifndef GOOGLE_PROTOBUF_INCLUDED_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto
#define GOOGLE_PROTOBUF_INCLUDED_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto
#include <limits>
#include <string>
#include <google/protobuf/port_def.inc>
#if PROTOBUF_VERSION < 3019000
#error This file was generated by a newer version of protoc which is
#error incompatible with your Protocol Buffer headers. Please update
#error your headers.
#endif
#if 3019001 < PROTOBUF_MIN_PROTOC_VERSION
#error This file was generated by an older version of protoc which is
#error incompatible with your Protocol Buffer headers. Please
#error regenerate this file with a newer version of protoc.
#endif
#include <google/protobuf/port_undef.inc>
#include <google/protobuf/io/coded_stream.h>
#include <google/protobuf/arena.h>
#include <google/protobuf/arenastring.h>
#include <google/protobuf/generated_message_table_driven.h>
#include <google/protobuf/generated_message_util.h>
#include <google/protobuf/metadata_lite.h>
#include <google/protobuf/generated_message_reflection.h>
#include <google/protobuf/message.h>
#include <google/protobuf/repeated_field.h> // IWYU pragma: export
#include <google/protobuf/extension_set.h> // IWYU pragma: export
#include <google/protobuf/generated_enum_reflection.h>
#include <google/protobuf/unknown_field_set.h>
#include "mediapipe/framework/calculator.pb.h"
#include "mediapipe/gpu/gpu_origin.pb.h"
// @@protoc_insertion_point(includes)
#include <google/protobuf/port_def.inc>
#define PROTOBUF_INTERNAL_EXPORT_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto
PROTOBUF_NAMESPACE_OPEN
namespace internal {
class AnyMetadata;
} // namespace internal
PROTOBUF_NAMESPACE_CLOSE
// Internal implementation detail -- do not use these members.
struct TableStruct_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto {
static const ::PROTOBUF_NAMESPACE_ID::internal::ParseTableField entries[]
PROTOBUF_SECTION_VARIABLE(protodesc_cold);
static const ::PROTOBUF_NAMESPACE_ID::internal::AuxiliaryParseTableField aux[]
PROTOBUF_SECTION_VARIABLE(protodesc_cold);
static const ::PROTOBUF_NAMESPACE_ID::internal::ParseTable schema[4]
PROTOBUF_SECTION_VARIABLE(protodesc_cold);
static const ::PROTOBUF_NAMESPACE_ID::internal::FieldMetadata field_metadata[];
static const ::PROTOBUF_NAMESPACE_ID::internal::SerializationTable serialization_table[];
static const uint32_t offsets[];
};
extern const ::PROTOBUF_NAMESPACE_ID::internal::DescriptorTable descriptor_table_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto;
namespace mediapipe {
class ImageToTensorCalculatorOptions;
struct ImageToTensorCalculatorOptionsDefaultTypeInternal;
extern ImageToTensorCalculatorOptionsDefaultTypeInternal _ImageToTensorCalculatorOptions_default_instance_;
class ImageToTensorCalculatorOptions_FloatRange;
struct ImageToTensorCalculatorOptions_FloatRangeDefaultTypeInternal;
extern ImageToTensorCalculatorOptions_FloatRangeDefaultTypeInternal _ImageToTensorCalculatorOptions_FloatRange_default_instance_;
class ImageToTensorCalculatorOptions_IntRange;
struct ImageToTensorCalculatorOptions_IntRangeDefaultTypeInternal;
extern ImageToTensorCalculatorOptions_IntRangeDefaultTypeInternal _ImageToTensorCalculatorOptions_IntRange_default_instance_;
class ImageToTensorCalculatorOptions_UIntRange;
struct ImageToTensorCalculatorOptions_UIntRangeDefaultTypeInternal;
extern ImageToTensorCalculatorOptions_UIntRangeDefaultTypeInternal _ImageToTensorCalculatorOptions_UIntRange_default_instance_;
} // namespace mediapipe
PROTOBUF_NAMESPACE_OPEN
template<> ::mediapipe::ImageToTensorCalculatorOptions* Arena::CreateMaybeMessage<::mediapipe::ImageToTensorCalculatorOptions>(Arena*);
template<> ::mediapipe::ImageToTensorCalculatorOptions_FloatRange* Arena::CreateMaybeMessage<::mediapipe::ImageToTensorCalculatorOptions_FloatRange>(Arena*);
template<> ::mediapipe::ImageToTensorCalculatorOptions_IntRange* Arena::CreateMaybeMessage<::mediapipe::ImageToTensorCalculatorOptions_IntRange>(Arena*);
template<> ::mediapipe::ImageToTensorCalculatorOptions_UIntRange* Arena::CreateMaybeMessage<::mediapipe::ImageToTensorCalculatorOptions_UIntRange>(Arena*);
PROTOBUF_NAMESPACE_CLOSE
namespace mediapipe {
enum ImageToTensorCalculatorOptions_BorderMode : int {
ImageToTensorCalculatorOptions_BorderMode_BORDER_UNSPECIFIED = 0,
ImageToTensorCalculatorOptions_BorderMode_BORDER_ZERO = 1,
ImageToTensorCalculatorOptions_BorderMode_BORDER_REPLICATE = 2
};
bool ImageToTensorCalculatorOptions_BorderMode_IsValid(int value);
constexpr ImageToTensorCalculatorOptions_BorderMode ImageToTensorCalculatorOptions_BorderMode_BorderMode_MIN = ImageToTensorCalculatorOptions_BorderMode_BORDER_UNSPECIFIED;
constexpr ImageToTensorCalculatorOptions_BorderMode ImageToTensorCalculatorOptions_BorderMode_BorderMode_MAX = ImageToTensorCalculatorOptions_BorderMode_BORDER_REPLICATE;
constexpr int ImageToTensorCalculatorOptions_BorderMode_BorderMode_ARRAYSIZE = ImageToTensorCalculatorOptions_BorderMode_BorderMode_MAX + 1;
const ::PROTOBUF_NAMESPACE_ID::EnumDescriptor* ImageToTensorCalculatorOptions_BorderMode_descriptor();
template<typename T>
inline const std::string& ImageToTensorCalculatorOptions_BorderMode_Name(T enum_t_value) {
static_assert(::std::is_same<T, ImageToTensorCalculatorOptions_BorderMode>::value ||
::std::is_integral<T>::value,
"Incorrect type passed to function ImageToTensorCalculatorOptions_BorderMode_Name.");
return ::PROTOBUF_NAMESPACE_ID::internal::NameOfEnum(
ImageToTensorCalculatorOptions_BorderMode_descriptor(), enum_t_value);
}
inline bool ImageToTensorCalculatorOptions_BorderMode_Parse(
::PROTOBUF_NAMESPACE_ID::ConstStringParam name, ImageToTensorCalculatorOptions_BorderMode* value) {
return ::PROTOBUF_NAMESPACE_ID::internal::ParseNamedEnum<ImageToTensorCalculatorOptions_BorderMode>(
ImageToTensorCalculatorOptions_BorderMode_descriptor(), name, value);
}
// ===================================================================
class ImageToTensorCalculatorOptions_FloatRange final :
public ::PROTOBUF_NAMESPACE_ID::Message /* @@protoc_insertion_point(class_definition:mediapipe.ImageToTensorCalculatorOptions.FloatRange) */ {
public:
inline ImageToTensorCalculatorOptions_FloatRange() : ImageToTensorCalculatorOptions_FloatRange(nullptr) {}
~ImageToTensorCalculatorOptions_FloatRange() override;
explicit constexpr ImageToTensorCalculatorOptions_FloatRange(::PROTOBUF_NAMESPACE_ID::internal::ConstantInitialized);
ImageToTensorCalculatorOptions_FloatRange(const ImageToTensorCalculatorOptions_FloatRange& from);
ImageToTensorCalculatorOptions_FloatRange(ImageToTensorCalculatorOptions_FloatRange&& from) noexcept
: ImageToTensorCalculatorOptions_FloatRange() {
*this = ::std::move(from);
}
inline ImageToTensorCalculatorOptions_FloatRange& operator=(const ImageToTensorCalculatorOptions_FloatRange& from) {
CopyFrom(from);
return *this;
}
inline ImageToTensorCalculatorOptions_FloatRange& operator=(ImageToTensorCalculatorOptions_FloatRange&& from) noexcept {
if (this == &from) return *this;
if (GetOwningArena() == from.GetOwningArena()
#ifdef PROTOBUF_FORCE_COPY_IN_MOVE
&& GetOwningArena() != nullptr
#endif // !PROTOBUF_FORCE_COPY_IN_MOVE
) {
InternalSwap(&from);
} else {
CopyFrom(from);
}
return *this;
}
inline const ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet& unknown_fields() const {
return _internal_metadata_.unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>(::PROTOBUF_NAMESPACE_ID::UnknownFieldSet::default_instance);
}
inline ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet* mutable_unknown_fields() {
return _internal_metadata_.mutable_unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* descriptor() {
return GetDescriptor();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* GetDescriptor() {
return default_instance().GetMetadata().descriptor;
}
static const ::PROTOBUF_NAMESPACE_ID::Reflection* GetReflection() {
return default_instance().GetMetadata().reflection;
}
static const ImageToTensorCalculatorOptions_FloatRange& default_instance() {
return *internal_default_instance();
}
static inline const ImageToTensorCalculatorOptions_FloatRange* internal_default_instance() {
return reinterpret_cast<const ImageToTensorCalculatorOptions_FloatRange*>(
&_ImageToTensorCalculatorOptions_FloatRange_default_instance_);
}
static constexpr int kIndexInFileMessages =
0;
friend void swap(ImageToTensorCalculatorOptions_FloatRange& a, ImageToTensorCalculatorOptions_FloatRange& b) {
a.Swap(&b);
}
inline void Swap(ImageToTensorCalculatorOptions_FloatRange* other) {
if (other == this) return;
#ifdef PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() != nullptr &&
GetOwningArena() == other->GetOwningArena()) {
#else // PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() == other->GetOwningArena()) {
#endif // !PROTOBUF_FORCE_COPY_IN_SWAP
InternalSwap(other);
} else {
::PROTOBUF_NAMESPACE_ID::internal::GenericSwap(this, other);
}
}
void UnsafeArenaSwap(ImageToTensorCalculatorOptions_FloatRange* other) {
if (other == this) return;
GOOGLE_DCHECK(GetOwningArena() == other->GetOwningArena());
InternalSwap(other);
}
// implements Message ----------------------------------------------
ImageToTensorCalculatorOptions_FloatRange* New(::PROTOBUF_NAMESPACE_ID::Arena* arena = nullptr) const final {
return CreateMaybeMessage<ImageToTensorCalculatorOptions_FloatRange>(arena);
}
using ::PROTOBUF_NAMESPACE_ID::Message::CopyFrom;
void CopyFrom(const ImageToTensorCalculatorOptions_FloatRange& from);
using ::PROTOBUF_NAMESPACE_ID::Message::MergeFrom;
void MergeFrom(const ImageToTensorCalculatorOptions_FloatRange& from);
private:
static void MergeImpl(::PROTOBUF_NAMESPACE_ID::Message* to, const ::PROTOBUF_NAMESPACE_ID::Message& from);
public:
PROTOBUF_ATTRIBUTE_REINITIALIZES void Clear() final;
bool IsInitialized() const final;
size_t ByteSizeLong() const final;
const char* _InternalParse(const char* ptr, ::PROTOBUF_NAMESPACE_ID::internal::ParseContext* ctx) final;
uint8_t* _InternalSerialize(
uint8_t* target, ::PROTOBUF_NAMESPACE_ID::io::EpsCopyOutputStream* stream) const final;
int GetCachedSize() const final { return _cached_size_.Get(); }
private:
void SharedCtor();
void SharedDtor();
void SetCachedSize(int size) const final;
void InternalSwap(ImageToTensorCalculatorOptions_FloatRange* other);
private:
friend class ::PROTOBUF_NAMESPACE_ID::internal::AnyMetadata;
static ::PROTOBUF_NAMESPACE_ID::StringPiece FullMessageName() {
return "mediapipe.ImageToTensorCalculatorOptions.FloatRange";
}
protected:
explicit ImageToTensorCalculatorOptions_FloatRange(::PROTOBUF_NAMESPACE_ID::Arena* arena,
bool is_message_owned = false);
private:
static void ArenaDtor(void* object);
inline void RegisterArenaDtor(::PROTOBUF_NAMESPACE_ID::Arena* arena);
public:
static const ClassData _class_data_;
const ::PROTOBUF_NAMESPACE_ID::Message::ClassData*GetClassData() const final;
::PROTOBUF_NAMESPACE_ID::Metadata GetMetadata() const final;
// nested types ----------------------------------------------------
// accessors -------------------------------------------------------
enum : int {
kMinFieldNumber = 1,
kMaxFieldNumber = 2,
};
// optional float min = 1;
bool has_min() const;
private:
bool _internal_has_min() const;
public:
void clear_min();
float min() const;
void set_min(float value);
private:
float _internal_min() const;
void _internal_set_min(float value);
public:
// optional float max = 2;
bool has_max() const;
private:
bool _internal_has_max() const;
public:
void clear_max();
float max() const;
void set_max(float value);
private:
float _internal_max() const;
void _internal_set_max(float value);
public:
// @@protoc_insertion_point(class_scope:mediapipe.ImageToTensorCalculatorOptions.FloatRange)
private:
class _Internal;
template <typename T> friend class ::PROTOBUF_NAMESPACE_ID::Arena::InternalHelper;
typedef void InternalArenaConstructable_;
typedef void DestructorSkippable_;
::PROTOBUF_NAMESPACE_ID::internal::HasBits<1> _has_bits_;
mutable ::PROTOBUF_NAMESPACE_ID::internal::CachedSize _cached_size_;
float min_;
float max_;
friend struct ::TableStruct_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto;
};
// -------------------------------------------------------------------
class ImageToTensorCalculatorOptions_IntRange final :
public ::PROTOBUF_NAMESPACE_ID::Message /* @@protoc_insertion_point(class_definition:mediapipe.ImageToTensorCalculatorOptions.IntRange) */ {
public:
inline ImageToTensorCalculatorOptions_IntRange() : ImageToTensorCalculatorOptions_IntRange(nullptr) {}
~ImageToTensorCalculatorOptions_IntRange() override;
explicit constexpr ImageToTensorCalculatorOptions_IntRange(::PROTOBUF_NAMESPACE_ID::internal::ConstantInitialized);
ImageToTensorCalculatorOptions_IntRange(const ImageToTensorCalculatorOptions_IntRange& from);
ImageToTensorCalculatorOptions_IntRange(ImageToTensorCalculatorOptions_IntRange&& from) noexcept
: ImageToTensorCalculatorOptions_IntRange() {
*this = ::std::move(from);
}
inline ImageToTensorCalculatorOptions_IntRange& operator=(const ImageToTensorCalculatorOptions_IntRange& from) {
CopyFrom(from);
return *this;
}
inline ImageToTensorCalculatorOptions_IntRange& operator=(ImageToTensorCalculatorOptions_IntRange&& from) noexcept {
if (this == &from) return *this;
if (GetOwningArena() == from.GetOwningArena()
#ifdef PROTOBUF_FORCE_COPY_IN_MOVE
&& GetOwningArena() != nullptr
#endif // !PROTOBUF_FORCE_COPY_IN_MOVE
) {
InternalSwap(&from);
} else {
CopyFrom(from);
}
return *this;
}
inline const ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet& unknown_fields() const {
return _internal_metadata_.unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>(::PROTOBUF_NAMESPACE_ID::UnknownFieldSet::default_instance);
}
inline ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet* mutable_unknown_fields() {
return _internal_metadata_.mutable_unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* descriptor() {
return GetDescriptor();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* GetDescriptor() {
return default_instance().GetMetadata().descriptor;
}
static const ::PROTOBUF_NAMESPACE_ID::Reflection* GetReflection() {
return default_instance().GetMetadata().reflection;
}
static const ImageToTensorCalculatorOptions_IntRange& default_instance() {
return *internal_default_instance();
}
static inline const ImageToTensorCalculatorOptions_IntRange* internal_default_instance() {
return reinterpret_cast<const ImageToTensorCalculatorOptions_IntRange*>(
&_ImageToTensorCalculatorOptions_IntRange_default_instance_);
}
static constexpr int kIndexInFileMessages =
1;
friend void swap(ImageToTensorCalculatorOptions_IntRange& a, ImageToTensorCalculatorOptions_IntRange& b) {
a.Swap(&b);
}
inline void Swap(ImageToTensorCalculatorOptions_IntRange* other) {
if (other == this) return;
#ifdef PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() != nullptr &&
GetOwningArena() == other->GetOwningArena()) {
#else // PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() == other->GetOwningArena()) {
#endif // !PROTOBUF_FORCE_COPY_IN_SWAP
InternalSwap(other);
} else {
::PROTOBUF_NAMESPACE_ID::internal::GenericSwap(this, other);
}
}
void UnsafeArenaSwap(ImageToTensorCalculatorOptions_IntRange* other) {
if (other == this) return;
GOOGLE_DCHECK(GetOwningArena() == other->GetOwningArena());
InternalSwap(other);
}
// implements Message ----------------------------------------------
ImageToTensorCalculatorOptions_IntRange* New(::PROTOBUF_NAMESPACE_ID::Arena* arena = nullptr) const final {
return CreateMaybeMessage<ImageToTensorCalculatorOptions_IntRange>(arena);
}
using ::PROTOBUF_NAMESPACE_ID::Message::CopyFrom;
void CopyFrom(const ImageToTensorCalculatorOptions_IntRange& from);
using ::PROTOBUF_NAMESPACE_ID::Message::MergeFrom;
void MergeFrom(const ImageToTensorCalculatorOptions_IntRange& from);
private:
static void MergeImpl(::PROTOBUF_NAMESPACE_ID::Message* to, const ::PROTOBUF_NAMESPACE_ID::Message& from);
public:
PROTOBUF_ATTRIBUTE_REINITIALIZES void Clear() final;
bool IsInitialized() const final;
size_t ByteSizeLong() const final;
const char* _InternalParse(const char* ptr, ::PROTOBUF_NAMESPACE_ID::internal::ParseContext* ctx) final;
uint8_t* _InternalSerialize(
uint8_t* target, ::PROTOBUF_NAMESPACE_ID::io::EpsCopyOutputStream* stream) const final;
int GetCachedSize() const final { return _cached_size_.Get(); }
private:
void SharedCtor();
void SharedDtor();
void SetCachedSize(int size) const final;
void InternalSwap(ImageToTensorCalculatorOptions_IntRange* other);
private:
friend class ::PROTOBUF_NAMESPACE_ID::internal::AnyMetadata;
static ::PROTOBUF_NAMESPACE_ID::StringPiece FullMessageName() {
return "mediapipe.ImageToTensorCalculatorOptions.IntRange";
}
protected:
explicit ImageToTensorCalculatorOptions_IntRange(::PROTOBUF_NAMESPACE_ID::Arena* arena,
bool is_message_owned = false);
private:
static void ArenaDtor(void* object);
inline void RegisterArenaDtor(::PROTOBUF_NAMESPACE_ID::Arena* arena);
public:
static const ClassData _class_data_;
const ::PROTOBUF_NAMESPACE_ID::Message::ClassData*GetClassData() const final;
::PROTOBUF_NAMESPACE_ID::Metadata GetMetadata() const final;
// nested types ----------------------------------------------------
// accessors -------------------------------------------------------
enum : int {
kMinFieldNumber = 1,
kMaxFieldNumber = 2,
};
// optional int64 min = 1;
bool has_min() const;
private:
bool _internal_has_min() const;
public:
void clear_min();
int64_t min() const;
void set_min(int64_t value);
private:
int64_t _internal_min() const;
void _internal_set_min(int64_t value);
public:
// optional int64 max = 2;
bool has_max() const;
private:
bool _internal_has_max() const;
public:
void clear_max();
int64_t max() const;
void set_max(int64_t value);
private:
int64_t _internal_max() const;
void _internal_set_max(int64_t value);
public:
// @@protoc_insertion_point(class_scope:mediapipe.ImageToTensorCalculatorOptions.IntRange)
private:
class _Internal;
template <typename T> friend class ::PROTOBUF_NAMESPACE_ID::Arena::InternalHelper;
typedef void InternalArenaConstructable_;
typedef void DestructorSkippable_;
::PROTOBUF_NAMESPACE_ID::internal::HasBits<1> _has_bits_;
mutable ::PROTOBUF_NAMESPACE_ID::internal::CachedSize _cached_size_;
int64_t min_;
int64_t max_;
friend struct ::TableStruct_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto;
};
// -------------------------------------------------------------------
class ImageToTensorCalculatorOptions_UIntRange final :
public ::PROTOBUF_NAMESPACE_ID::Message /* @@protoc_insertion_point(class_definition:mediapipe.ImageToTensorCalculatorOptions.UIntRange) */ {
public:
inline ImageToTensorCalculatorOptions_UIntRange() : ImageToTensorCalculatorOptions_UIntRange(nullptr) {}
~ImageToTensorCalculatorOptions_UIntRange() override;
explicit constexpr ImageToTensorCalculatorOptions_UIntRange(::PROTOBUF_NAMESPACE_ID::internal::ConstantInitialized);
ImageToTensorCalculatorOptions_UIntRange(const ImageToTensorCalculatorOptions_UIntRange& from);
ImageToTensorCalculatorOptions_UIntRange(ImageToTensorCalculatorOptions_UIntRange&& from) noexcept
: ImageToTensorCalculatorOptions_UIntRange() {
*this = ::std::move(from);
}
inline ImageToTensorCalculatorOptions_UIntRange& operator=(const ImageToTensorCalculatorOptions_UIntRange& from) {
CopyFrom(from);
return *this;
}
inline ImageToTensorCalculatorOptions_UIntRange& operator=(ImageToTensorCalculatorOptions_UIntRange&& from) noexcept {
if (this == &from) return *this;
if (GetOwningArena() == from.GetOwningArena()
#ifdef PROTOBUF_FORCE_COPY_IN_MOVE
&& GetOwningArena() != nullptr
#endif // !PROTOBUF_FORCE_COPY_IN_MOVE
) {
InternalSwap(&from);
} else {
CopyFrom(from);
}
return *this;
}
inline const ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet& unknown_fields() const {
return _internal_metadata_.unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>(::PROTOBUF_NAMESPACE_ID::UnknownFieldSet::default_instance);
}
inline ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet* mutable_unknown_fields() {
return _internal_metadata_.mutable_unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* descriptor() {
return GetDescriptor();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* GetDescriptor() {
return default_instance().GetMetadata().descriptor;
}
static const ::PROTOBUF_NAMESPACE_ID::Reflection* GetReflection() {
return default_instance().GetMetadata().reflection;
}
static const ImageToTensorCalculatorOptions_UIntRange& default_instance() {
return *internal_default_instance();
}
static inline const ImageToTensorCalculatorOptions_UIntRange* internal_default_instance() {
return reinterpret_cast<const ImageToTensorCalculatorOptions_UIntRange*>(
&_ImageToTensorCalculatorOptions_UIntRange_default_instance_);
}
static constexpr int kIndexInFileMessages =
2;
friend void swap(ImageToTensorCalculatorOptions_UIntRange& a, ImageToTensorCalculatorOptions_UIntRange& b) {
a.Swap(&b);
}
inline void Swap(ImageToTensorCalculatorOptions_UIntRange* other) {
if (other == this) return;
#ifdef PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() != nullptr &&
GetOwningArena() == other->GetOwningArena()) {
#else // PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() == other->GetOwningArena()) {
#endif // !PROTOBUF_FORCE_COPY_IN_SWAP
InternalSwap(other);
} else {
::PROTOBUF_NAMESPACE_ID::internal::GenericSwap(this, other);
}
}
void UnsafeArenaSwap(ImageToTensorCalculatorOptions_UIntRange* other) {
if (other == this) return;
GOOGLE_DCHECK(GetOwningArena() == other->GetOwningArena());
InternalSwap(other);
}
// implements Message ----------------------------------------------
ImageToTensorCalculatorOptions_UIntRange* New(::PROTOBUF_NAMESPACE_ID::Arena* arena = nullptr) const final {
return CreateMaybeMessage<ImageToTensorCalculatorOptions_UIntRange>(arena);
}
using ::PROTOBUF_NAMESPACE_ID::Message::CopyFrom;
void CopyFrom(const ImageToTensorCalculatorOptions_UIntRange& from);
using ::PROTOBUF_NAMESPACE_ID::Message::MergeFrom;
void MergeFrom(const ImageToTensorCalculatorOptions_UIntRange& from);
private:
static void MergeImpl(::PROTOBUF_NAMESPACE_ID::Message* to, const ::PROTOBUF_NAMESPACE_ID::Message& from);
public:
PROTOBUF_ATTRIBUTE_REINITIALIZES void Clear() final;
bool IsInitialized() const final;
size_t ByteSizeLong() const final;
const char* _InternalParse(const char* ptr, ::PROTOBUF_NAMESPACE_ID::internal::ParseContext* ctx) final;
uint8_t* _InternalSerialize(
uint8_t* target, ::PROTOBUF_NAMESPACE_ID::io::EpsCopyOutputStream* stream) const final;
int GetCachedSize() const final { return _cached_size_.Get(); }
private:
void SharedCtor();
void SharedDtor();
void SetCachedSize(int size) const final;
void InternalSwap(ImageToTensorCalculatorOptions_UIntRange* other);
private:
friend class ::PROTOBUF_NAMESPACE_ID::internal::AnyMetadata;
static ::PROTOBUF_NAMESPACE_ID::StringPiece FullMessageName() {
return "mediapipe.ImageToTensorCalculatorOptions.UIntRange";
}
protected:
explicit ImageToTensorCalculatorOptions_UIntRange(::PROTOBUF_NAMESPACE_ID::Arena* arena,
bool is_message_owned = false);
private:
static void ArenaDtor(void* object);
inline void RegisterArenaDtor(::PROTOBUF_NAMESPACE_ID::Arena* arena);
public:
static const ClassData _class_data_;
const ::PROTOBUF_NAMESPACE_ID::Message::ClassData*GetClassData() const final;
::PROTOBUF_NAMESPACE_ID::Metadata GetMetadata() const final;
// nested types ----------------------------------------------------
// accessors -------------------------------------------------------
enum : int {
kMinFieldNumber = 1,
kMaxFieldNumber = 2,
};
// optional uint64 min = 1;
bool has_min() const;
private:
bool _internal_has_min() const;
public:
void clear_min();
uint64_t min() const;
void set_min(uint64_t value);
private:
uint64_t _internal_min() const;
void _internal_set_min(uint64_t value);
public:
// optional uint64 max = 2;
bool has_max() const;
private:
bool _internal_has_max() const;
public:
void clear_max();
uint64_t max() const;
void set_max(uint64_t value);
private:
uint64_t _internal_max() const;
void _internal_set_max(uint64_t value);
public:
// @@protoc_insertion_point(class_scope:mediapipe.ImageToTensorCalculatorOptions.UIntRange)
private:
class _Internal;
template <typename T> friend class ::PROTOBUF_NAMESPACE_ID::Arena::InternalHelper;
typedef void InternalArenaConstructable_;
typedef void DestructorSkippable_;
::PROTOBUF_NAMESPACE_ID::internal::HasBits<1> _has_bits_;
mutable ::PROTOBUF_NAMESPACE_ID::internal::CachedSize _cached_size_;
uint64_t min_;
uint64_t max_;
friend struct ::TableStruct_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto;
};
// -------------------------------------------------------------------
class ImageToTensorCalculatorOptions final :
public ::PROTOBUF_NAMESPACE_ID::Message /* @@protoc_insertion_point(class_definition:mediapipe.ImageToTensorCalculatorOptions) */ {
public:
inline ImageToTensorCalculatorOptions() : ImageToTensorCalculatorOptions(nullptr) {}
~ImageToTensorCalculatorOptions() override;
explicit constexpr ImageToTensorCalculatorOptions(::PROTOBUF_NAMESPACE_ID::internal::ConstantInitialized);
ImageToTensorCalculatorOptions(const ImageToTensorCalculatorOptions& from);
ImageToTensorCalculatorOptions(ImageToTensorCalculatorOptions&& from) noexcept
: ImageToTensorCalculatorOptions() {
*this = ::std::move(from);
}
inline ImageToTensorCalculatorOptions& operator=(const ImageToTensorCalculatorOptions& from) {
CopyFrom(from);
return *this;
}
inline ImageToTensorCalculatorOptions& operator=(ImageToTensorCalculatorOptions&& from) noexcept {
if (this == &from) return *this;
if (GetOwningArena() == from.GetOwningArena()
#ifdef PROTOBUF_FORCE_COPY_IN_MOVE
&& GetOwningArena() != nullptr
#endif // !PROTOBUF_FORCE_COPY_IN_MOVE
) {
InternalSwap(&from);
} else {
CopyFrom(from);
}
return *this;
}
inline const ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet& unknown_fields() const {
return _internal_metadata_.unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>(::PROTOBUF_NAMESPACE_ID::UnknownFieldSet::default_instance);
}
inline ::PROTOBUF_NAMESPACE_ID::UnknownFieldSet* mutable_unknown_fields() {
return _internal_metadata_.mutable_unknown_fields<::PROTOBUF_NAMESPACE_ID::UnknownFieldSet>();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* descriptor() {
return GetDescriptor();
}
static const ::PROTOBUF_NAMESPACE_ID::Descriptor* GetDescriptor() {
return default_instance().GetMetadata().descriptor;
}
static const ::PROTOBUF_NAMESPACE_ID::Reflection* GetReflection() {
return default_instance().GetMetadata().reflection;
}
static const ImageToTensorCalculatorOptions& default_instance() {
return *internal_default_instance();
}
enum RangeCase {
kOutputTensorFloatRange = 4,
kOutputTensorIntRange = 7,
kOutputTensorUintRange = 8,
RANGE_NOT_SET = 0,
};
static inline const ImageToTensorCalculatorOptions* internal_default_instance() {
return reinterpret_cast<const ImageToTensorCalculatorOptions*>(
&_ImageToTensorCalculatorOptions_default_instance_);
}
static constexpr int kIndexInFileMessages =
3;
friend void swap(ImageToTensorCalculatorOptions& a, ImageToTensorCalculatorOptions& b) {
a.Swap(&b);
}
inline void Swap(ImageToTensorCalculatorOptions* other) {
if (other == this) return;
#ifdef PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() != nullptr &&
GetOwningArena() == other->GetOwningArena()) {
#else // PROTOBUF_FORCE_COPY_IN_SWAP
if (GetOwningArena() == other->GetOwningArena()) {
#endif // !PROTOBUF_FORCE_COPY_IN_SWAP
InternalSwap(other);
} else {
::PROTOBUF_NAMESPACE_ID::internal::GenericSwap(this, other);
}
}
void UnsafeArenaSwap(ImageToTensorCalculatorOptions* other) {
if (other == this) return;
GOOGLE_DCHECK(GetOwningArena() == other->GetOwningArena());
InternalSwap(other);
}
// implements Message ----------------------------------------------
ImageToTensorCalculatorOptions* New(::PROTOBUF_NAMESPACE_ID::Arena* arena = nullptr) const final {
return CreateMaybeMessage<ImageToTensorCalculatorOptions>(arena);
}
using ::PROTOBUF_NAMESPACE_ID::Message::CopyFrom;
void CopyFrom(const ImageToTensorCalculatorOptions& from);
using ::PROTOBUF_NAMESPACE_ID::Message::MergeFrom;
void MergeFrom(const ImageToTensorCalculatorOptions& from);
private:
static void MergeImpl(::PROTOBUF_NAMESPACE_ID::Message* to, const ::PROTOBUF_NAMESPACE_ID::Message& from);
public:
PROTOBUF_ATTRIBUTE_REINITIALIZES void Clear() final;
bool IsInitialized() const final;
size_t ByteSizeLong() const final;
const char* _InternalParse(const char* ptr, ::PROTOBUF_NAMESPACE_ID::internal::ParseContext* ctx) final;
uint8_t* _InternalSerialize(
uint8_t* target, ::PROTOBUF_NAMESPACE_ID::io::EpsCopyOutputStream* stream) const final;
int GetCachedSize() const final { return _cached_size_.Get(); }
private:
void SharedCtor();
void SharedDtor();
void SetCachedSize(int size) const final;
void InternalSwap(ImageToTensorCalculatorOptions* other);
private:
friend class ::PROTOBUF_NAMESPACE_ID::internal::AnyMetadata;
static ::PROTOBUF_NAMESPACE_ID::StringPiece FullMessageName() {
return "mediapipe.ImageToTensorCalculatorOptions";
}
protected:
explicit ImageToTensorCalculatorOptions(::PROTOBUF_NAMESPACE_ID::Arena* arena,
bool is_message_owned = false);
private:
static void ArenaDtor(void* object);
inline void RegisterArenaDtor(::PROTOBUF_NAMESPACE_ID::Arena* arena);
public:
static const ClassData _class_data_;
const ::PROTOBUF_NAMESPACE_ID::Message::ClassData*GetClassData() const final;
::PROTOBUF_NAMESPACE_ID::Metadata GetMetadata() const final;
// nested types ----------------------------------------------------
typedef ImageToTensorCalculatorOptions_FloatRange FloatRange;
typedef ImageToTensorCalculatorOptions_IntRange IntRange;
typedef ImageToTensorCalculatorOptions_UIntRange UIntRange;
typedef ImageToTensorCalculatorOptions_BorderMode BorderMode;
static constexpr BorderMode BORDER_UNSPECIFIED =
ImageToTensorCalculatorOptions_BorderMode_BORDER_UNSPECIFIED;
static constexpr BorderMode BORDER_ZERO =
ImageToTensorCalculatorOptions_BorderMode_BORDER_ZERO;
static constexpr BorderMode BORDER_REPLICATE =
ImageToTensorCalculatorOptions_BorderMode_BORDER_REPLICATE;
static inline bool BorderMode_IsValid(int value) {
return ImageToTensorCalculatorOptions_BorderMode_IsValid(value);
}
static constexpr BorderMode BorderMode_MIN =
ImageToTensorCalculatorOptions_BorderMode_BorderMode_MIN;
static constexpr BorderMode BorderMode_MAX =
ImageToTensorCalculatorOptions_BorderMode_BorderMode_MAX;
static constexpr int BorderMode_ARRAYSIZE =
ImageToTensorCalculatorOptions_BorderMode_BorderMode_ARRAYSIZE;
static inline const ::PROTOBUF_NAMESPACE_ID::EnumDescriptor*
BorderMode_descriptor() {
return ImageToTensorCalculatorOptions_BorderMode_descriptor();
}
template<typename T>
static inline const std::string& BorderMode_Name(T enum_t_value) {
static_assert(::std::is_same<T, BorderMode>::value ||
::std::is_integral<T>::value,
"Incorrect type passed to function BorderMode_Name.");
return ImageToTensorCalculatorOptions_BorderMode_Name(enum_t_value);
}
static inline bool BorderMode_Parse(::PROTOBUF_NAMESPACE_ID::ConstStringParam name,
BorderMode* value) {
return ImageToTensorCalculatorOptions_BorderMode_Parse(name, value);
}
// accessors -------------------------------------------------------
enum : int {
kOutputTensorWidthFieldNumber = 1,
kOutputTensorHeightFieldNumber = 2,
kKeepAspectRatioFieldNumber = 3,
kGpuOriginFieldNumber = 5,
kBorderModeFieldNumber = 6,
kOutputTensorFloatRangeFieldNumber = 4,
kOutputTensorIntRangeFieldNumber = 7,
kOutputTensorUintRangeFieldNumber = 8,
};
// optional int32 output_tensor_width = 1;
bool has_output_tensor_width() const;
private:
bool _internal_has_output_tensor_width() const;
public:
void clear_output_tensor_width();
int32_t output_tensor_width() const;
void set_output_tensor_width(int32_t value);
private:
int32_t _internal_output_tensor_width() const;
void _internal_set_output_tensor_width(int32_t value);
public:
// optional int32 output_tensor_height = 2;
bool has_output_tensor_height() const;
private:
bool _internal_has_output_tensor_height() const;
public:
void clear_output_tensor_height();
int32_t output_tensor_height() const;
void set_output_tensor_height(int32_t value);
private:
int32_t _internal_output_tensor_height() const;
void _internal_set_output_tensor_height(int32_t value);
public:
// optional bool keep_aspect_ratio = 3;
bool has_keep_aspect_ratio() const;
private:
bool _internal_has_keep_aspect_ratio() const;
public:
void clear_keep_aspect_ratio();
bool keep_aspect_ratio() const;
void set_keep_aspect_ratio(bool value);
private:
bool _internal_keep_aspect_ratio() const;
void _internal_set_keep_aspect_ratio(bool value);
public:
// optional .mediapipe.GpuOrigin.Mode gpu_origin = 5;
bool has_gpu_origin() const;
private:
bool _internal_has_gpu_origin() const;
public:
void clear_gpu_origin();
::mediapipe::GpuOrigin_Mode gpu_origin() const;
void set_gpu_origin(::mediapipe::GpuOrigin_Mode value);
private:
::mediapipe::GpuOrigin_Mode _internal_gpu_origin() const;
void _internal_set_gpu_origin(::mediapipe::GpuOrigin_Mode value);
public:
// optional .mediapipe.ImageToTensorCalculatorOptions.BorderMode border_mode = 6;
bool has_border_mode() const;
private:
bool _internal_has_border_mode() const;
public:
void clear_border_mode();
::mediapipe::ImageToTensorCalculatorOptions_BorderMode border_mode() const;
void set_border_mode(::mediapipe::ImageToTensorCalculatorOptions_BorderMode value);
private:
::mediapipe::ImageToTensorCalculatorOptions_BorderMode _internal_border_mode() const;
void _internal_set_border_mode(::mediapipe::ImageToTensorCalculatorOptions_BorderMode value);
public:
// .mediapipe.ImageToTensorCalculatorOptions.FloatRange output_tensor_float_range = 4;
bool has_output_tensor_float_range() const;
private:
bool _internal_has_output_tensor_float_range() const;
public:
void clear_output_tensor_float_range();
const ::mediapipe::ImageToTensorCalculatorOptions_FloatRange& output_tensor_float_range() const;
PROTOBUF_NODISCARD ::mediapipe::ImageToTensorCalculatorOptions_FloatRange* release_output_tensor_float_range();
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* mutable_output_tensor_float_range();
void set_allocated_output_tensor_float_range(::mediapipe::ImageToTensorCalculatorOptions_FloatRange* output_tensor_float_range);
private:
const ::mediapipe::ImageToTensorCalculatorOptions_FloatRange& _internal_output_tensor_float_range() const;
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* _internal_mutable_output_tensor_float_range();
public:
void unsafe_arena_set_allocated_output_tensor_float_range(
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* output_tensor_float_range);
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* unsafe_arena_release_output_tensor_float_range();
// .mediapipe.ImageToTensorCalculatorOptions.IntRange output_tensor_int_range = 7;
bool has_output_tensor_int_range() const;
private:
bool _internal_has_output_tensor_int_range() const;
public:
void clear_output_tensor_int_range();
const ::mediapipe::ImageToTensorCalculatorOptions_IntRange& output_tensor_int_range() const;
PROTOBUF_NODISCARD ::mediapipe::ImageToTensorCalculatorOptions_IntRange* release_output_tensor_int_range();
::mediapipe::ImageToTensorCalculatorOptions_IntRange* mutable_output_tensor_int_range();
void set_allocated_output_tensor_int_range(::mediapipe::ImageToTensorCalculatorOptions_IntRange* output_tensor_int_range);
private:
const ::mediapipe::ImageToTensorCalculatorOptions_IntRange& _internal_output_tensor_int_range() const;
::mediapipe::ImageToTensorCalculatorOptions_IntRange* _internal_mutable_output_tensor_int_range();
public:
void unsafe_arena_set_allocated_output_tensor_int_range(
::mediapipe::ImageToTensorCalculatorOptions_IntRange* output_tensor_int_range);
::mediapipe::ImageToTensorCalculatorOptions_IntRange* unsafe_arena_release_output_tensor_int_range();
// .mediapipe.ImageToTensorCalculatorOptions.UIntRange output_tensor_uint_range = 8;
bool has_output_tensor_uint_range() const;
private:
bool _internal_has_output_tensor_uint_range() const;
public:
void clear_output_tensor_uint_range();
const ::mediapipe::ImageToTensorCalculatorOptions_UIntRange& output_tensor_uint_range() const;
PROTOBUF_NODISCARD ::mediapipe::ImageToTensorCalculatorOptions_UIntRange* release_output_tensor_uint_range();
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* mutable_output_tensor_uint_range();
void set_allocated_output_tensor_uint_range(::mediapipe::ImageToTensorCalculatorOptions_UIntRange* output_tensor_uint_range);
private:
const ::mediapipe::ImageToTensorCalculatorOptions_UIntRange& _internal_output_tensor_uint_range() const;
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* _internal_mutable_output_tensor_uint_range();
public:
void unsafe_arena_set_allocated_output_tensor_uint_range(
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* output_tensor_uint_range);
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* unsafe_arena_release_output_tensor_uint_range();
void clear_range();
RangeCase range_case() const;
static const int kExtFieldNumber = 334361939;
static ::PROTOBUF_NAMESPACE_ID::internal::ExtensionIdentifier< ::mediapipe::CalculatorOptions,
::PROTOBUF_NAMESPACE_ID::internal::MessageTypeTraits< ::mediapipe::ImageToTensorCalculatorOptions >, 11, false >
ext;
// @@protoc_insertion_point(class_scope:mediapipe.ImageToTensorCalculatorOptions)
private:
class _Internal;
void set_has_output_tensor_float_range();
void set_has_output_tensor_int_range();
void set_has_output_tensor_uint_range();
inline bool has_range() const;
inline void clear_has_range();
template <typename T> friend class ::PROTOBUF_NAMESPACE_ID::Arena::InternalHelper;
typedef void InternalArenaConstructable_;
typedef void DestructorSkippable_;
::PROTOBUF_NAMESPACE_ID::internal::HasBits<1> _has_bits_;
mutable ::PROTOBUF_NAMESPACE_ID::internal::CachedSize _cached_size_;
int32_t output_tensor_width_;
int32_t output_tensor_height_;
bool keep_aspect_ratio_;
int gpu_origin_;
int border_mode_;
union RangeUnion {
constexpr RangeUnion() : _constinit_{} {}
::PROTOBUF_NAMESPACE_ID::internal::ConstantInitialized _constinit_;
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* output_tensor_float_range_;
::mediapipe::ImageToTensorCalculatorOptions_IntRange* output_tensor_int_range_;
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* output_tensor_uint_range_;
} range_;
uint32_t _oneof_case_[1];
friend struct ::TableStruct_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto;
};
// ===================================================================
// ===================================================================
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wstrict-aliasing"
#endif // __GNUC__
// ImageToTensorCalculatorOptions_FloatRange
// optional float min = 1;
inline bool ImageToTensorCalculatorOptions_FloatRange::_internal_has_min() const {
bool value = (_has_bits_[0] & 0x00000001u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions_FloatRange::has_min() const {
return _internal_has_min();
}
inline void ImageToTensorCalculatorOptions_FloatRange::clear_min() {
min_ = 0;
_has_bits_[0] &= ~0x00000001u;
}
inline float ImageToTensorCalculatorOptions_FloatRange::_internal_min() const {
return min_;
}
inline float ImageToTensorCalculatorOptions_FloatRange::min() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.FloatRange.min)
return _internal_min();
}
inline void ImageToTensorCalculatorOptions_FloatRange::_internal_set_min(float value) {
_has_bits_[0] |= 0x00000001u;
min_ = value;
}
inline void ImageToTensorCalculatorOptions_FloatRange::set_min(float value) {
_internal_set_min(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.FloatRange.min)
}
// optional float max = 2;
inline bool ImageToTensorCalculatorOptions_FloatRange::_internal_has_max() const {
bool value = (_has_bits_[0] & 0x00000002u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions_FloatRange::has_max() const {
return _internal_has_max();
}
inline void ImageToTensorCalculatorOptions_FloatRange::clear_max() {
max_ = 0;
_has_bits_[0] &= ~0x00000002u;
}
inline float ImageToTensorCalculatorOptions_FloatRange::_internal_max() const {
return max_;
}
inline float ImageToTensorCalculatorOptions_FloatRange::max() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.FloatRange.max)
return _internal_max();
}
inline void ImageToTensorCalculatorOptions_FloatRange::_internal_set_max(float value) {
_has_bits_[0] |= 0x00000002u;
max_ = value;
}
inline void ImageToTensorCalculatorOptions_FloatRange::set_max(float value) {
_internal_set_max(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.FloatRange.max)
}
// -------------------------------------------------------------------
// ImageToTensorCalculatorOptions_IntRange
// optional int64 min = 1;
inline bool ImageToTensorCalculatorOptions_IntRange::_internal_has_min() const {
bool value = (_has_bits_[0] & 0x00000001u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions_IntRange::has_min() const {
return _internal_has_min();
}
inline void ImageToTensorCalculatorOptions_IntRange::clear_min() {
min_ = int64_t{0};
_has_bits_[0] &= ~0x00000001u;
}
inline int64_t ImageToTensorCalculatorOptions_IntRange::_internal_min() const {
return min_;
}
inline int64_t ImageToTensorCalculatorOptions_IntRange::min() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.IntRange.min)
return _internal_min();
}
inline void ImageToTensorCalculatorOptions_IntRange::_internal_set_min(int64_t value) {
_has_bits_[0] |= 0x00000001u;
min_ = value;
}
inline void ImageToTensorCalculatorOptions_IntRange::set_min(int64_t value) {
_internal_set_min(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.IntRange.min)
}
// optional int64 max = 2;
inline bool ImageToTensorCalculatorOptions_IntRange::_internal_has_max() const {
bool value = (_has_bits_[0] & 0x00000002u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions_IntRange::has_max() const {
return _internal_has_max();
}
inline void ImageToTensorCalculatorOptions_IntRange::clear_max() {
max_ = int64_t{0};
_has_bits_[0] &= ~0x00000002u;
}
inline int64_t ImageToTensorCalculatorOptions_IntRange::_internal_max() const {
return max_;
}
inline int64_t ImageToTensorCalculatorOptions_IntRange::max() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.IntRange.max)
return _internal_max();
}
inline void ImageToTensorCalculatorOptions_IntRange::_internal_set_max(int64_t value) {
_has_bits_[0] |= 0x00000002u;
max_ = value;
}
inline void ImageToTensorCalculatorOptions_IntRange::set_max(int64_t value) {
_internal_set_max(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.IntRange.max)
}
// -------------------------------------------------------------------
// ImageToTensorCalculatorOptions_UIntRange
// optional uint64 min = 1;
inline bool ImageToTensorCalculatorOptions_UIntRange::_internal_has_min() const {
bool value = (_has_bits_[0] & 0x00000001u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions_UIntRange::has_min() const {
return _internal_has_min();
}
inline void ImageToTensorCalculatorOptions_UIntRange::clear_min() {
min_ = uint64_t{0u};
_has_bits_[0] &= ~0x00000001u;
}
inline uint64_t ImageToTensorCalculatorOptions_UIntRange::_internal_min() const {
return min_;
}
inline uint64_t ImageToTensorCalculatorOptions_UIntRange::min() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.UIntRange.min)
return _internal_min();
}
inline void ImageToTensorCalculatorOptions_UIntRange::_internal_set_min(uint64_t value) {
_has_bits_[0] |= 0x00000001u;
min_ = value;
}
inline void ImageToTensorCalculatorOptions_UIntRange::set_min(uint64_t value) {
_internal_set_min(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.UIntRange.min)
}
// optional uint64 max = 2;
inline bool ImageToTensorCalculatorOptions_UIntRange::_internal_has_max() const {
bool value = (_has_bits_[0] & 0x00000002u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions_UIntRange::has_max() const {
return _internal_has_max();
}
inline void ImageToTensorCalculatorOptions_UIntRange::clear_max() {
max_ = uint64_t{0u};
_has_bits_[0] &= ~0x00000002u;
}
inline uint64_t ImageToTensorCalculatorOptions_UIntRange::_internal_max() const {
return max_;
}
inline uint64_t ImageToTensorCalculatorOptions_UIntRange::max() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.UIntRange.max)
return _internal_max();
}
inline void ImageToTensorCalculatorOptions_UIntRange::_internal_set_max(uint64_t value) {
_has_bits_[0] |= 0x00000002u;
max_ = value;
}
inline void ImageToTensorCalculatorOptions_UIntRange::set_max(uint64_t value) {
_internal_set_max(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.UIntRange.max)
}
// -------------------------------------------------------------------
// ImageToTensorCalculatorOptions
// optional int32 output_tensor_width = 1;
inline bool ImageToTensorCalculatorOptions::_internal_has_output_tensor_width() const {
bool value = (_has_bits_[0] & 0x00000001u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions::has_output_tensor_width() const {
return _internal_has_output_tensor_width();
}
inline void ImageToTensorCalculatorOptions::clear_output_tensor_width() {
output_tensor_width_ = 0;
_has_bits_[0] &= ~0x00000001u;
}
inline int32_t ImageToTensorCalculatorOptions::_internal_output_tensor_width() const {
return output_tensor_width_;
}
inline int32_t ImageToTensorCalculatorOptions::output_tensor_width() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.output_tensor_width)
return _internal_output_tensor_width();
}
inline void ImageToTensorCalculatorOptions::_internal_set_output_tensor_width(int32_t value) {
_has_bits_[0] |= 0x00000001u;
output_tensor_width_ = value;
}
inline void ImageToTensorCalculatorOptions::set_output_tensor_width(int32_t value) {
_internal_set_output_tensor_width(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.output_tensor_width)
}
// optional int32 output_tensor_height = 2;
inline bool ImageToTensorCalculatorOptions::_internal_has_output_tensor_height() const {
bool value = (_has_bits_[0] & 0x00000002u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions::has_output_tensor_height() const {
return _internal_has_output_tensor_height();
}
inline void ImageToTensorCalculatorOptions::clear_output_tensor_height() {
output_tensor_height_ = 0;
_has_bits_[0] &= ~0x00000002u;
}
inline int32_t ImageToTensorCalculatorOptions::_internal_output_tensor_height() const {
return output_tensor_height_;
}
inline int32_t ImageToTensorCalculatorOptions::output_tensor_height() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.output_tensor_height)
return _internal_output_tensor_height();
}
inline void ImageToTensorCalculatorOptions::_internal_set_output_tensor_height(int32_t value) {
_has_bits_[0] |= 0x00000002u;
output_tensor_height_ = value;
}
inline void ImageToTensorCalculatorOptions::set_output_tensor_height(int32_t value) {
_internal_set_output_tensor_height(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.output_tensor_height)
}
// optional bool keep_aspect_ratio = 3;
inline bool ImageToTensorCalculatorOptions::_internal_has_keep_aspect_ratio() const {
bool value = (_has_bits_[0] & 0x00000004u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions::has_keep_aspect_ratio() const {
return _internal_has_keep_aspect_ratio();
}
inline void ImageToTensorCalculatorOptions::clear_keep_aspect_ratio() {
keep_aspect_ratio_ = false;
_has_bits_[0] &= ~0x00000004u;
}
inline bool ImageToTensorCalculatorOptions::_internal_keep_aspect_ratio() const {
return keep_aspect_ratio_;
}
inline bool ImageToTensorCalculatorOptions::keep_aspect_ratio() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.keep_aspect_ratio)
return _internal_keep_aspect_ratio();
}
inline void ImageToTensorCalculatorOptions::_internal_set_keep_aspect_ratio(bool value) {
_has_bits_[0] |= 0x00000004u;
keep_aspect_ratio_ = value;
}
inline void ImageToTensorCalculatorOptions::set_keep_aspect_ratio(bool value) {
_internal_set_keep_aspect_ratio(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.keep_aspect_ratio)
}
// .mediapipe.ImageToTensorCalculatorOptions.FloatRange output_tensor_float_range = 4;
inline bool ImageToTensorCalculatorOptions::_internal_has_output_tensor_float_range() const {
return range_case() == kOutputTensorFloatRange;
}
inline bool ImageToTensorCalculatorOptions::has_output_tensor_float_range() const {
return _internal_has_output_tensor_float_range();
}
inline void ImageToTensorCalculatorOptions::set_has_output_tensor_float_range() {
_oneof_case_[0] = kOutputTensorFloatRange;
}
inline void ImageToTensorCalculatorOptions::clear_output_tensor_float_range() {
if (_internal_has_output_tensor_float_range()) {
if (GetArenaForAllocation() == nullptr) {
delete range_.output_tensor_float_range_;
}
clear_has_range();
}
}
inline ::mediapipe::ImageToTensorCalculatorOptions_FloatRange* ImageToTensorCalculatorOptions::release_output_tensor_float_range() {
// @@protoc_insertion_point(field_release:mediapipe.ImageToTensorCalculatorOptions.output_tensor_float_range)
if (_internal_has_output_tensor_float_range()) {
clear_has_range();
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* temp = range_.output_tensor_float_range_;
if (GetArenaForAllocation() != nullptr) {
temp = ::PROTOBUF_NAMESPACE_ID::internal::DuplicateIfNonNull(temp);
}
range_.output_tensor_float_range_ = nullptr;
return temp;
} else {
return nullptr;
}
}
inline const ::mediapipe::ImageToTensorCalculatorOptions_FloatRange& ImageToTensorCalculatorOptions::_internal_output_tensor_float_range() const {
return _internal_has_output_tensor_float_range()
? *range_.output_tensor_float_range_
: reinterpret_cast< ::mediapipe::ImageToTensorCalculatorOptions_FloatRange&>(::mediapipe::_ImageToTensorCalculatorOptions_FloatRange_default_instance_);
}
inline const ::mediapipe::ImageToTensorCalculatorOptions_FloatRange& ImageToTensorCalculatorOptions::output_tensor_float_range() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.output_tensor_float_range)
return _internal_output_tensor_float_range();
}
inline ::mediapipe::ImageToTensorCalculatorOptions_FloatRange* ImageToTensorCalculatorOptions::unsafe_arena_release_output_tensor_float_range() {
// @@protoc_insertion_point(field_unsafe_arena_release:mediapipe.ImageToTensorCalculatorOptions.output_tensor_float_range)
if (_internal_has_output_tensor_float_range()) {
clear_has_range();
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* temp = range_.output_tensor_float_range_;
range_.output_tensor_float_range_ = nullptr;
return temp;
} else {
return nullptr;
}
}
inline void ImageToTensorCalculatorOptions::unsafe_arena_set_allocated_output_tensor_float_range(::mediapipe::ImageToTensorCalculatorOptions_FloatRange* output_tensor_float_range) {
clear_range();
if (output_tensor_float_range) {
set_has_output_tensor_float_range();
range_.output_tensor_float_range_ = output_tensor_float_range;
}
// @@protoc_insertion_point(field_unsafe_arena_set_allocated:mediapipe.ImageToTensorCalculatorOptions.output_tensor_float_range)
}
inline ::mediapipe::ImageToTensorCalculatorOptions_FloatRange* ImageToTensorCalculatorOptions::_internal_mutable_output_tensor_float_range() {
if (!_internal_has_output_tensor_float_range()) {
clear_range();
set_has_output_tensor_float_range();
range_.output_tensor_float_range_ = CreateMaybeMessage< ::mediapipe::ImageToTensorCalculatorOptions_FloatRange >(GetArenaForAllocation());
}
return range_.output_tensor_float_range_;
}
inline ::mediapipe::ImageToTensorCalculatorOptions_FloatRange* ImageToTensorCalculatorOptions::mutable_output_tensor_float_range() {
::mediapipe::ImageToTensorCalculatorOptions_FloatRange* _msg = _internal_mutable_output_tensor_float_range();
// @@protoc_insertion_point(field_mutable:mediapipe.ImageToTensorCalculatorOptions.output_tensor_float_range)
return _msg;
}
// .mediapipe.ImageToTensorCalculatorOptions.IntRange output_tensor_int_range = 7;
inline bool ImageToTensorCalculatorOptions::_internal_has_output_tensor_int_range() const {
return range_case() == kOutputTensorIntRange;
}
inline bool ImageToTensorCalculatorOptions::has_output_tensor_int_range() const {
return _internal_has_output_tensor_int_range();
}
inline void ImageToTensorCalculatorOptions::set_has_output_tensor_int_range() {
_oneof_case_[0] = kOutputTensorIntRange;
}
inline void ImageToTensorCalculatorOptions::clear_output_tensor_int_range() {
if (_internal_has_output_tensor_int_range()) {
if (GetArenaForAllocation() == nullptr) {
delete range_.output_tensor_int_range_;
}
clear_has_range();
}
}
inline ::mediapipe::ImageToTensorCalculatorOptions_IntRange* ImageToTensorCalculatorOptions::release_output_tensor_int_range() {
// @@protoc_insertion_point(field_release:mediapipe.ImageToTensorCalculatorOptions.output_tensor_int_range)
if (_internal_has_output_tensor_int_range()) {
clear_has_range();
::mediapipe::ImageToTensorCalculatorOptions_IntRange* temp = range_.output_tensor_int_range_;
if (GetArenaForAllocation() != nullptr) {
temp = ::PROTOBUF_NAMESPACE_ID::internal::DuplicateIfNonNull(temp);
}
range_.output_tensor_int_range_ = nullptr;
return temp;
} else {
return nullptr;
}
}
inline const ::mediapipe::ImageToTensorCalculatorOptions_IntRange& ImageToTensorCalculatorOptions::_internal_output_tensor_int_range() const {
return _internal_has_output_tensor_int_range()
? *range_.output_tensor_int_range_
: reinterpret_cast< ::mediapipe::ImageToTensorCalculatorOptions_IntRange&>(::mediapipe::_ImageToTensorCalculatorOptions_IntRange_default_instance_);
}
inline const ::mediapipe::ImageToTensorCalculatorOptions_IntRange& ImageToTensorCalculatorOptions::output_tensor_int_range() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.output_tensor_int_range)
return _internal_output_tensor_int_range();
}
inline ::mediapipe::ImageToTensorCalculatorOptions_IntRange* ImageToTensorCalculatorOptions::unsafe_arena_release_output_tensor_int_range() {
// @@protoc_insertion_point(field_unsafe_arena_release:mediapipe.ImageToTensorCalculatorOptions.output_tensor_int_range)
if (_internal_has_output_tensor_int_range()) {
clear_has_range();
::mediapipe::ImageToTensorCalculatorOptions_IntRange* temp = range_.output_tensor_int_range_;
range_.output_tensor_int_range_ = nullptr;
return temp;
} else {
return nullptr;
}
}
inline void ImageToTensorCalculatorOptions::unsafe_arena_set_allocated_output_tensor_int_range(::mediapipe::ImageToTensorCalculatorOptions_IntRange* output_tensor_int_range) {
clear_range();
if (output_tensor_int_range) {
set_has_output_tensor_int_range();
range_.output_tensor_int_range_ = output_tensor_int_range;
}
// @@protoc_insertion_point(field_unsafe_arena_set_allocated:mediapipe.ImageToTensorCalculatorOptions.output_tensor_int_range)
}
inline ::mediapipe::ImageToTensorCalculatorOptions_IntRange* ImageToTensorCalculatorOptions::_internal_mutable_output_tensor_int_range() {
if (!_internal_has_output_tensor_int_range()) {
clear_range();
set_has_output_tensor_int_range();
range_.output_tensor_int_range_ = CreateMaybeMessage< ::mediapipe::ImageToTensorCalculatorOptions_IntRange >(GetArenaForAllocation());
}
return range_.output_tensor_int_range_;
}
inline ::mediapipe::ImageToTensorCalculatorOptions_IntRange* ImageToTensorCalculatorOptions::mutable_output_tensor_int_range() {
::mediapipe::ImageToTensorCalculatorOptions_IntRange* _msg = _internal_mutable_output_tensor_int_range();
// @@protoc_insertion_point(field_mutable:mediapipe.ImageToTensorCalculatorOptions.output_tensor_int_range)
return _msg;
}
// .mediapipe.ImageToTensorCalculatorOptions.UIntRange output_tensor_uint_range = 8;
inline bool ImageToTensorCalculatorOptions::_internal_has_output_tensor_uint_range() const {
return range_case() == kOutputTensorUintRange;
}
inline bool ImageToTensorCalculatorOptions::has_output_tensor_uint_range() const {
return _internal_has_output_tensor_uint_range();
}
inline void ImageToTensorCalculatorOptions::set_has_output_tensor_uint_range() {
_oneof_case_[0] = kOutputTensorUintRange;
}
inline void ImageToTensorCalculatorOptions::clear_output_tensor_uint_range() {
if (_internal_has_output_tensor_uint_range()) {
if (GetArenaForAllocation() == nullptr) {
delete range_.output_tensor_uint_range_;
}
clear_has_range();
}
}
inline ::mediapipe::ImageToTensorCalculatorOptions_UIntRange* ImageToTensorCalculatorOptions::release_output_tensor_uint_range() {
// @@protoc_insertion_point(field_release:mediapipe.ImageToTensorCalculatorOptions.output_tensor_uint_range)
if (_internal_has_output_tensor_uint_range()) {
clear_has_range();
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* temp = range_.output_tensor_uint_range_;
if (GetArenaForAllocation() != nullptr) {
temp = ::PROTOBUF_NAMESPACE_ID::internal::DuplicateIfNonNull(temp);
}
range_.output_tensor_uint_range_ = nullptr;
return temp;
} else {
return nullptr;
}
}
inline const ::mediapipe::ImageToTensorCalculatorOptions_UIntRange& ImageToTensorCalculatorOptions::_internal_output_tensor_uint_range() const {
return _internal_has_output_tensor_uint_range()
? *range_.output_tensor_uint_range_
: reinterpret_cast< ::mediapipe::ImageToTensorCalculatorOptions_UIntRange&>(::mediapipe::_ImageToTensorCalculatorOptions_UIntRange_default_instance_);
}
inline const ::mediapipe::ImageToTensorCalculatorOptions_UIntRange& ImageToTensorCalculatorOptions::output_tensor_uint_range() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.output_tensor_uint_range)
return _internal_output_tensor_uint_range();
}
inline ::mediapipe::ImageToTensorCalculatorOptions_UIntRange* ImageToTensorCalculatorOptions::unsafe_arena_release_output_tensor_uint_range() {
// @@protoc_insertion_point(field_unsafe_arena_release:mediapipe.ImageToTensorCalculatorOptions.output_tensor_uint_range)
if (_internal_has_output_tensor_uint_range()) {
clear_has_range();
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* temp = range_.output_tensor_uint_range_;
range_.output_tensor_uint_range_ = nullptr;
return temp;
} else {
return nullptr;
}
}
inline void ImageToTensorCalculatorOptions::unsafe_arena_set_allocated_output_tensor_uint_range(::mediapipe::ImageToTensorCalculatorOptions_UIntRange* output_tensor_uint_range) {
clear_range();
if (output_tensor_uint_range) {
set_has_output_tensor_uint_range();
range_.output_tensor_uint_range_ = output_tensor_uint_range;
}
// @@protoc_insertion_point(field_unsafe_arena_set_allocated:mediapipe.ImageToTensorCalculatorOptions.output_tensor_uint_range)
}
inline ::mediapipe::ImageToTensorCalculatorOptions_UIntRange* ImageToTensorCalculatorOptions::_internal_mutable_output_tensor_uint_range() {
if (!_internal_has_output_tensor_uint_range()) {
clear_range();
set_has_output_tensor_uint_range();
range_.output_tensor_uint_range_ = CreateMaybeMessage< ::mediapipe::ImageToTensorCalculatorOptions_UIntRange >(GetArenaForAllocation());
}
return range_.output_tensor_uint_range_;
}
inline ::mediapipe::ImageToTensorCalculatorOptions_UIntRange* ImageToTensorCalculatorOptions::mutable_output_tensor_uint_range() {
::mediapipe::ImageToTensorCalculatorOptions_UIntRange* _msg = _internal_mutable_output_tensor_uint_range();
// @@protoc_insertion_point(field_mutable:mediapipe.ImageToTensorCalculatorOptions.output_tensor_uint_range)
return _msg;
}
// optional .mediapipe.GpuOrigin.Mode gpu_origin = 5;
inline bool ImageToTensorCalculatorOptions::_internal_has_gpu_origin() const {
bool value = (_has_bits_[0] & 0x00000008u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions::has_gpu_origin() const {
return _internal_has_gpu_origin();
}
inline void ImageToTensorCalculatorOptions::clear_gpu_origin() {
gpu_origin_ = 0;
_has_bits_[0] &= ~0x00000008u;
}
inline ::mediapipe::GpuOrigin_Mode ImageToTensorCalculatorOptions::_internal_gpu_origin() const {
return static_cast< ::mediapipe::GpuOrigin_Mode >(gpu_origin_);
}
inline ::mediapipe::GpuOrigin_Mode ImageToTensorCalculatorOptions::gpu_origin() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.gpu_origin)
return _internal_gpu_origin();
}
inline void ImageToTensorCalculatorOptions::_internal_set_gpu_origin(::mediapipe::GpuOrigin_Mode value) {
assert(::mediapipe::GpuOrigin_Mode_IsValid(value));
_has_bits_[0] |= 0x00000008u;
gpu_origin_ = value;
}
inline void ImageToTensorCalculatorOptions::set_gpu_origin(::mediapipe::GpuOrigin_Mode value) {
_internal_set_gpu_origin(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.gpu_origin)
}
// optional .mediapipe.ImageToTensorCalculatorOptions.BorderMode border_mode = 6;
inline bool ImageToTensorCalculatorOptions::_internal_has_border_mode() const {
bool value = (_has_bits_[0] & 0x00000010u) != 0;
return value;
}
inline bool ImageToTensorCalculatorOptions::has_border_mode() const {
return _internal_has_border_mode();
}
inline void ImageToTensorCalculatorOptions::clear_border_mode() {
border_mode_ = 0;
_has_bits_[0] &= ~0x00000010u;
}
inline ::mediapipe::ImageToTensorCalculatorOptions_BorderMode ImageToTensorCalculatorOptions::_internal_border_mode() const {
return static_cast< ::mediapipe::ImageToTensorCalculatorOptions_BorderMode >(border_mode_);
}
inline ::mediapipe::ImageToTensorCalculatorOptions_BorderMode ImageToTensorCalculatorOptions::border_mode() const {
// @@protoc_insertion_point(field_get:mediapipe.ImageToTensorCalculatorOptions.border_mode)
return _internal_border_mode();
}
inline void ImageToTensorCalculatorOptions::_internal_set_border_mode(::mediapipe::ImageToTensorCalculatorOptions_BorderMode value) {
assert(::mediapipe::ImageToTensorCalculatorOptions_BorderMode_IsValid(value));
_has_bits_[0] |= 0x00000010u;
border_mode_ = value;
}
inline void ImageToTensorCalculatorOptions::set_border_mode(::mediapipe::ImageToTensorCalculatorOptions_BorderMode value) {
_internal_set_border_mode(value);
// @@protoc_insertion_point(field_set:mediapipe.ImageToTensorCalculatorOptions.border_mode)
}
inline bool ImageToTensorCalculatorOptions::has_range() const {
return range_case() != RANGE_NOT_SET;
}
inline void ImageToTensorCalculatorOptions::clear_has_range() {
_oneof_case_[0] = RANGE_NOT_SET;
}
inline ImageToTensorCalculatorOptions::RangeCase ImageToTensorCalculatorOptions::range_case() const {
return ImageToTensorCalculatorOptions::RangeCase(_oneof_case_[0]);
}
#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif // __GNUC__
// -------------------------------------------------------------------
// -------------------------------------------------------------------
// -------------------------------------------------------------------
// @@protoc_insertion_point(namespace_scope)
} // namespace mediapipe
PROTOBUF_NAMESPACE_OPEN
template <> struct is_proto_enum< ::mediapipe::ImageToTensorCalculatorOptions_BorderMode> : ::std::true_type {};
template <>
inline const EnumDescriptor* GetEnumDescriptor< ::mediapipe::ImageToTensorCalculatorOptions_BorderMode>() {
return ::mediapipe::ImageToTensorCalculatorOptions_BorderMode_descriptor();
}
PROTOBUF_NAMESPACE_CLOSE
// @@protoc_insertion_point(global_scope)
#include <google/protobuf/port_undef.inc>
#endif // GOOGLE_PROTOBUF_INCLUDED_GOOGLE_PROTOBUF_INCLUDED_mediapipe_2fcalculators_2ftensor_2fimage_5fto_5ftensor_5fcalculator_2eproto