upb/def.hpp - third_party/protobuf - Git at Google

 // Copyright (c) 2009-2021, Google LLC
 // All rights reserved.
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are met:
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above copyright
 //       notice, this list of conditions and the following disclaimer in the
 //       documentation and/or other materials provided with the distribution.
 //     * Neither the name of Google LLC nor the
 //       names of its contributors may be used to endorse or promote products
 //       derived from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
 // ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
 // WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
 // DISCLAIMED. IN NO EVENT SHALL Google LLC BE LIABLE FOR ANY
 // DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
 // (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 // LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
 // ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
 // SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #ifndef UPB_DEF_HPP_
 #define UPB_DEF_HPP_

 #include <cstring>
 #include <memory>
 #include <string>
 #include <vector>

 #include "upb/def.h"
 #include "upb/reflection.h"
 #include "upb/upb.hpp"

 namespace upb {

 typedef upb_msgval MessageValue;

 class EnumDefPtr;
 class MessageDefPtr;
 class OneofDefPtr;

 // A upb::FieldDefPtr describes a single field in a message.  It is most often
 // found as a part of a upb_msgdef, but can also stand alone to represent
 // an extension.
 class FieldDefPtr {
  public:
   FieldDefPtr() : ptr_(nullptr) {}
   explicit FieldDefPtr(const upb_fielddef* ptr) : ptr_(ptr) {}

   const upb_fielddef* ptr() const { return ptr_; }
   explicit operator bool() const { return ptr_ != nullptr; }

   typedef upb_fieldtype_t Type;
   typedef upb_label_t Label;
   typedef upb_descriptortype_t DescriptorType;

   const char* full_name() const { return upb_fielddef_fullname(ptr_); }

   Type type() const { return upb_fielddef_type(ptr_); }
   Label label() const { return upb_fielddef_label(ptr_); }
   const char* name() const { return upb_fielddef_name(ptr_); }
   const char* json_name() const { return upb_fielddef_jsonname(ptr_); }
   uint32_t number() const { return upb_fielddef_number(ptr_); }
   bool is_extension() const { return upb_fielddef_isextension(ptr_); }

   // For UPB_TYPE_MESSAGE fields only where is_tag_delimited() == false,
   // indicates whether this field should have lazy parsing handlers that yield
   // the unparsed string for the submessage.
   //
   // TODO(haberman): I think we want to move this into a FieldOptions container
   // when we add support for custom options (the FieldOptions struct will
   // contain both regular FieldOptions like "lazy" *and* custom options).
   bool lazy() const { return upb_fielddef_lazy(ptr_); }

   // For non-string, non-submessage fields, this indicates whether binary
   // protobufs are encoded in packed or non-packed format.
   //
   // TODO(haberman): see note above about putting options like this into a
   // FieldOptions container.
   bool packed() const { return upb_fielddef_packed(ptr_); }

   // An integer that can be used as an index into an array of fields for
   // whatever message this field belongs to.  Guaranteed to be less than
   // f->containing_type()->field_count().  May only be accessed once the def has
   // been finalized.
   uint32_t index() const { return upb_fielddef_index(ptr_); }

   // The MessageDef to which this field belongs.
   //
   // If this field has been added to a MessageDef, that message can be retrieved
   // directly (this is always the case for frozen FieldDefs).
   //
   // If the field has not yet been added to a MessageDef, you can set the name
   // of the containing type symbolically instead.  This is mostly useful for
   // extensions, where the extension is declared separately from the message.
   MessageDefPtr containing_type() const;

   // The OneofDef to which this field belongs, or NULL if this field is not part
   // of a oneof.
   OneofDefPtr containing_oneof() const;

   // The field's type according to the enum in descriptor.proto.  This is not
   // the same as UPB_TYPE_*, because it distinguishes between (for example)
   // INT32 and SINT32, whereas our "type" enum does not.  This return of
   // descriptor_type() is a function of type(), integer_format(), and
   // is_tag_delimited().
   DescriptorType descriptor_type() const {
     return upb_fielddef_descriptortype(ptr_);
   }

   // Convenient field type tests.
   bool IsSubMessage() const { return upb_fielddef_issubmsg(ptr_); }
   bool IsString() const { return upb_fielddef_isstring(ptr_); }
   bool IsSequence() const { return upb_fielddef_isseq(ptr_); }
   bool IsPrimitive() const { return upb_fielddef_isprimitive(ptr_); }
   bool IsMap() const { return upb_fielddef_ismap(ptr_); }

   // Returns the non-string default value for this fielddef, which may either
   // be something the client set explicitly or the "default default" (0 for
   // numbers, empty for strings).  The field's type indicates the type of the
   // returned value, except for enum fields that are still mutable.
   //
   // Requires that the given function matches the field's current type.
   int64_t default_int64() const { return upb_fielddef_defaultint64(ptr_); }
   int32_t default_int32() const { return upb_fielddef_defaultint32(ptr_); }
   uint64_t default_uint64() const { return upb_fielddef_defaultuint64(ptr_); }
   uint32_t default_uint32() const { return upb_fielddef_defaultuint32(ptr_); }
   bool default_bool() const { return upb_fielddef_defaultbool(ptr_); }
   float default_float() const { return upb_fielddef_defaultfloat(ptr_); }
   double default_double() const { return upb_fielddef_defaultdouble(ptr_); }

   MessageValue default_value() const { return upb_fielddef_default(ptr_); }

   // The resulting string is always NULL-terminated.  If non-NULL, the length
   // will be stored in *len.
   const char* default_string(size_t* len) const {
     return upb_fielddef_defaultstr(ptr_, len);
   }

   // Returns the enum or submessage def for this field, if any.  The field's
   // type must match (ie. you may only call enum_subdef() for fields where
   // type() == UPB_TYPE_ENUM).
   EnumDefPtr enum_subdef() const;
   MessageDefPtr message_subdef() const;

  private:
   const upb_fielddef* ptr_;
 };

 // Class that represents a oneof.
 class OneofDefPtr {
  public:
   OneofDefPtr() : ptr_(nullptr) {}
   explicit OneofDefPtr(const upb_oneofdef* ptr) : ptr_(ptr) {}

   const upb_oneofdef* ptr() const { return ptr_; }
   explicit operator bool() const { return ptr_ != nullptr; }

   // Returns the MessageDef that contains this OneofDef.
   MessageDefPtr containing_type() const;

   // Returns the name of this oneof.
   const char* name() const { return upb_oneofdef_name(ptr_); }

   // Returns the number of fields in the oneof.
   int field_count() const { return upb_oneofdef_numfields(ptr_); }
   FieldDefPtr field(int i) const { return FieldDefPtr(upb_oneofdef_field(ptr_, i)); }

   // Looks up by name.
   FieldDefPtr FindFieldByName(const char* name, size_t len) const {
     return FieldDefPtr(upb_oneofdef_ntof(ptr_, name, len));
   }
   FieldDefPtr FindFieldByName(const char* name) const {
     return FieldDefPtr(upb_oneofdef_ntofz(ptr_, name));
   }

   template <class T>
   FieldDefPtr FindFieldByName(const T& str) const {
     return FindFieldByName(str.c_str(), str.size());
   }

   // Looks up by tag number.
   FieldDefPtr FindFieldByNumber(uint32_t num) const {
     return FieldDefPtr(upb_oneofdef_itof(ptr_, num));
   }

  private:
   const upb_oneofdef* ptr_;
 };

 // Structure that describes a single .proto message type.
 class MessageDefPtr {
  public:
   MessageDefPtr() : ptr_(nullptr) {}
   explicit MessageDefPtr(const upb_msgdef* ptr) : ptr_(ptr) {}

   const upb_msgdef* ptr() const { return ptr_; }
   explicit operator bool() const { return ptr_ != nullptr; }

   const char* full_name() const { return upb_msgdef_fullname(ptr_); }
   const char* name() const { return upb_msgdef_name(ptr_); }

   // The number of fields that belong to the MessageDef.
   int field_count() const { return upb_msgdef_numfields(ptr_); }
   FieldDefPtr field(int i) const { return FieldDefPtr(upb_msgdef_field(ptr_, i)); }

   // The number of oneofs that belong to the MessageDef.
   int oneof_count() const { return upb_msgdef_numoneofs(ptr_); }
   OneofDefPtr oneof(int i) const { return OneofDefPtr(upb_msgdef_oneof(ptr_, i)); }

   upb_syntax_t syntax() const { return upb_msgdef_syntax(ptr_); }

   // These return null pointers if the field is not found.
   FieldDefPtr FindFieldByNumber(uint32_t number) const {
     return FieldDefPtr(upb_msgdef_itof(ptr_, number));
   }
   FieldDefPtr FindFieldByName(const char* name, size_t len) const {
     return FieldDefPtr(upb_msgdef_ntof(ptr_, name, len));
   }
   FieldDefPtr FindFieldByName(const char* name) const {
     return FieldDefPtr(upb_msgdef_ntofz(ptr_, name));
   }

   template <class T>
   FieldDefPtr FindFieldByName(const T& str) const {
     return FindFieldByName(str.c_str(), str.size());
   }

   OneofDefPtr FindOneofByName(const char* name, size_t len) const {
     return OneofDefPtr(upb_msgdef_ntoo(ptr_, name, len));
   }

   OneofDefPtr FindOneofByName(const char* name) const {
     return OneofDefPtr(upb_msgdef_ntooz(ptr_, name));
   }

   template <class T>
   OneofDefPtr FindOneofByName(const T& str) const {
     return FindOneofByName(str.c_str(), str.size());
   }

   // Is this message a map entry?
   bool mapentry() const { return upb_msgdef_mapentry(ptr_); }

   // Return the type of well known type message. UPB_WELLKNOWN_UNSPECIFIED for
   // non-well-known message.
   upb_wellknowntype_t wellknowntype() const {
     return upb_msgdef_wellknowntype(ptr_);
   }

   // Whether is a number wrapper.
   bool isnumberwrapper() const { return upb_msgdef_isnumberwrapper(ptr_); }

  private:
   class FieldIter {
    public:
     explicit FieldIter(const upb_msgdef *m, int i) : m_(m), i_(i) {}
     void operator++() { i_++; }

     FieldDefPtr operator*() { return FieldDefPtr(upb_msgdef_field(m_, i_)); }
     bool operator!=(const FieldIter& other) { return i_ != other.i_; }
     bool operator==(const FieldIter& other) { return i_ == other.i_; }

    private:
     const upb_msgdef *m_;
     int i_;
   };

   class FieldAccessor {
    public:
     explicit FieldAccessor(const upb_msgdef* md) : md_(md) {}
     FieldIter begin() { return FieldIter(md_, 0); }
     FieldIter end() { return FieldIter(md_, upb_msgdef_fieldcount(md_)); }

    private:
     const upb_msgdef* md_;
   };

   class OneofIter {
    public:
     explicit OneofIter(const upb_msgdef *m, int i) : m_(m), i_(i) {}
     void operator++() { i_++; }

     OneofDefPtr operator*() { return OneofDefPtr(upb_msgdef_oneof(m_, i_)); }
     bool operator!=(const OneofIter& other) { return i_ != other.i_; }
     bool operator==(const OneofIter& other) { return i_ == other.i_; }

    private:
     const upb_msgdef *m_;
     int i_;
   };

   class OneofAccessor {
    public:
     explicit OneofAccessor(const upb_msgdef* md) : md_(md) {}
     OneofIter begin() { return OneofIter(md_, 0); }
     OneofIter end() { return OneofIter(md_, upb_msgdef_oneofcount(md_)); }

    private:
     const upb_msgdef* md_;
   };

  public:
   FieldAccessor fields() const { return FieldAccessor(ptr()); }
   OneofAccessor oneofs() const { return OneofAccessor(ptr()); }

  private:
   const upb_msgdef* ptr_;
 };

 class EnumDefPtr {
  public:
   EnumDefPtr() : ptr_(nullptr) {}
   explicit EnumDefPtr(const upb_enumdef* ptr) : ptr_(ptr) {}

   const upb_enumdef* ptr() const { return ptr_; }
   explicit operator bool() const { return ptr_ != nullptr; }

   const char* full_name() const { return upb_enumdef_fullname(ptr_); }
   const char* name() const { return upb_enumdef_name(ptr_); }

   // The value that is used as the default when no field default is specified.
   // If not set explicitly, the first value that was added will be used.
   // The default value must be a member of the enum.
   // Requires that value_count() > 0.
   int32_t default_value() const { return upb_enumdef_default(ptr_); }

   // Returns the number of values currently defined in the enum.  Note that
   // multiple names can refer to the same number, so this may be greater than
   // the total number of unique numbers.
   int value_count() const { return upb_enumdef_numvals(ptr_); }

   // Lookups from name to integer, returning true if found.
   bool FindValueByName(const char* name, int32_t* num) const {
     return upb_enumdef_ntoiz(ptr_, name, num);
   }

   // Finds the name corresponding to the given number, or NULL if none was
   // found.  If more than one name corresponds to this number, returns the
   // first one that was added.
   const char* FindValueByNumber(int32_t num) const {
     return upb_enumdef_iton(ptr_, num);
   }

   // Iteration over name/value pairs.  The order is undefined.
   // Adding an enum val invalidates any iterators.
   //
   // TODO: make compatible with range-for, with elements as pairs?
   class Iterator {
    public:
     explicit Iterator(EnumDefPtr e) { upb_enum_begin(&iter_, e.ptr()); }

     int32_t number() { return upb_enum_iter_number(&iter_); }
     const char* name() { return upb_enum_iter_name(&iter_); }
     bool Done() { return upb_enum_done(&iter_); }
     void Next() { return upb_enum_next(&iter_); }

    private:
     upb_enum_iter iter_;
   };

  private:
   const upb_enumdef* ptr_;
 };

 // Class that represents a .proto file with some things defined in it.
 //
 // Many users won't care about FileDefs, but they are necessary if you want to
 // read the values of file-level options.
 class FileDefPtr {
  public:
   explicit FileDefPtr(const upb_filedef* ptr) : ptr_(ptr) {}

   const upb_filedef* ptr() const { return ptr_; }
   explicit operator bool() const { return ptr_ != nullptr; }

   // Get/set name of the file (eg. "foo/bar.proto").
   const char* name() const { return upb_filedef_name(ptr_); }

   // Package name for definitions inside the file (eg. "foo.bar").
   const char* package() const { return upb_filedef_package(ptr_); }

   // Sets the php class prefix which is prepended to all php generated classes
   // from this .proto. Default is empty.
   const char* phpprefix() const { return upb_filedef_phpprefix(ptr_); }

   // Use this option to change the namespace of php generated classes. Default
   // is empty. When this option is empty, the package name will be used for
   // determining the namespace.
   const char* phpnamespace() const { return upb_filedef_phpnamespace(ptr_); }

   // Syntax for the file.  Defaults to proto2.
   upb_syntax_t syntax() const { return upb_filedef_syntax(ptr_); }

   // Get the list of dependencies from the file.  These are returned in the
   // order that they were added to the FileDefPtr.
   int dependency_count() const { return upb_filedef_depcount(ptr_); }
   const FileDefPtr dependency(int index) const {
     return FileDefPtr(upb_filedef_dep(ptr_, index));
   }

  private:
   const upb_filedef* ptr_;
 };

 // Non-const methods in upb::SymbolTable are NOT thread-safe.
 class SymbolTable {
  public:
   SymbolTable() : ptr_(upb_symtab_new(), upb_symtab_free) {}
   explicit SymbolTable(upb_symtab* s) : ptr_(s, upb_symtab_free) {}

   const upb_symtab* ptr() const { return ptr_.get(); }
   upb_symtab* ptr() { return ptr_.get(); }

   // Finds an entry in the symbol table with this exact name.  If not found,
   // returns NULL.
   MessageDefPtr LookupMessage(const char* sym) const {
     return MessageDefPtr(upb_symtab_lookupmsg(ptr_.get(), sym));
   }

   EnumDefPtr LookupEnum(const char* sym) const {
     return EnumDefPtr(upb_symtab_lookupenum(ptr_.get(), sym));
   }

   FileDefPtr LookupFile(const char* name) const {
     return FileDefPtr(upb_symtab_lookupfile(ptr_.get(), name));
   }

   // TODO: iteration?

   // Adds the given serialized FileDescriptorProto to the pool.
   FileDefPtr AddFile(const google_protobuf_FileDescriptorProto* file_proto,
                      Status* status) {
     return FileDefPtr(
         upb_symtab_addfile(ptr_.get(), file_proto, status->ptr()));
   }

  private:
   std::unique_ptr<upb_symtab, decltype(&upb_symtab_free)> ptr_;
 };

 inline MessageDefPtr FieldDefPtr::message_subdef() const {
   return MessageDefPtr(upb_fielddef_msgsubdef(ptr_));
 }

 inline MessageDefPtr FieldDefPtr::containing_type() const {
   return MessageDefPtr(upb_fielddef_containingtype(ptr_));
 }

 inline MessageDefPtr OneofDefPtr::containing_type() const {
   return MessageDefPtr(upb_oneofdef_containingtype(ptr_));
 }

 inline OneofDefPtr FieldDefPtr::containing_oneof() const {
   return OneofDefPtr(upb_fielddef_containingoneof(ptr_));
 }

 inline EnumDefPtr FieldDefPtr::enum_subdef() const {
   return EnumDefPtr(upb_fielddef_enumsubdef(ptr_));
 }

 }  // namespace upb

 #endif  // UPB_DEF_HPP_
	// Copyright (c) 2009-2021, Google LLC
	// All rights reserved.
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are met:
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above copyright
	// notice, this list of conditions and the following disclaimer in the
	// documentation and/or other materials provided with the distribution.
	// * Neither the name of Google LLC nor the
	// names of its contributors may be used to endorse or promote products
	// derived from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
	// ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
	// WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
	// DISCLAIMED. IN NO EVENT SHALL Google LLC BE LIABLE FOR ANY
	// DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
	// (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
	// LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
	// ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
	// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#ifndef UPB_DEF_HPP_
	#define UPB_DEF_HPP_

	#include <cstring>
	#include <memory>
	#include <string>
	#include <vector>

	#include "upb/def.h"
	#include "upb/reflection.h"
	#include "upb/upb.hpp"

	namespace upb {

	typedef upb_msgval MessageValue;

	class EnumDefPtr;
	class MessageDefPtr;
	class OneofDefPtr;

	// A upb::FieldDefPtr describes a single field in a message. It is most often
	// found as a part of a upb_msgdef, but can also stand alone to represent
	// an extension.
	class FieldDefPtr {
	public:
	FieldDefPtr() : ptr_(nullptr) {}
	explicit FieldDefPtr(const upb_fielddef* ptr) : ptr_(ptr) {}

	const upb_fielddef* ptr() const { return ptr_; }
	explicit operator bool() const { return ptr_ != nullptr; }

	typedef upb_fieldtype_t Type;
	typedef upb_label_t Label;
	typedef upb_descriptortype_t DescriptorType;

	const char* full_name() const { return upb_fielddef_fullname(ptr_); }

	Type type() const { return upb_fielddef_type(ptr_); }
	Label label() const { return upb_fielddef_label(ptr_); }
	const char* name() const { return upb_fielddef_name(ptr_); }
	const char* json_name() const { return upb_fielddef_jsonname(ptr_); }
	uint32_t number() const { return upb_fielddef_number(ptr_); }
	bool is_extension() const { return upb_fielddef_isextension(ptr_); }

	// For UPB_TYPE_MESSAGE fields only where is_tag_delimited() == false,
	// indicates whether this field should have lazy parsing handlers that yield
	// the unparsed string for the submessage.
	//
	// TODO(haberman): I think we want to move this into a FieldOptions container
	// when we add support for custom options (the FieldOptions struct will
	// contain both regular FieldOptions like "lazy" and custom options).
	bool lazy() const { return upb_fielddef_lazy(ptr_); }

	// For non-string, non-submessage fields, this indicates whether binary
	// protobufs are encoded in packed or non-packed format.
	//
	// TODO(haberman): see note above about putting options like this into a
	// FieldOptions container.
	bool packed() const { return upb_fielddef_packed(ptr_); }

	// An integer that can be used as an index into an array of fields for
	// whatever message this field belongs to. Guaranteed to be less than
	// f->containing_type()->field_count(). May only be accessed once the def has
	// been finalized.
	uint32_t index() const { return upb_fielddef_index(ptr_); }

	// The MessageDef to which this field belongs.
	//
	// If this field has been added to a MessageDef, that message can be retrieved
	// directly (this is always the case for frozen FieldDefs).
	//
	// If the field has not yet been added to a MessageDef, you can set the name
	// of the containing type symbolically instead. This is mostly useful for
	// extensions, where the extension is declared separately from the message.
	MessageDefPtr containing_type() const;

	// The OneofDef to which this field belongs, or NULL if this field is not part
	// of a oneof.
	OneofDefPtr containing_oneof() const;

	// The field's type according to the enum in descriptor.proto. This is not
	// the same as UPB_TYPE_*, because it distinguishes between (for example)
	// INT32 and SINT32, whereas our "type" enum does not. This return of
	// descriptor_type() is a function of type(), integer_format(), and
	// is_tag_delimited().
	DescriptorType descriptor_type() const {
	return upb_fielddef_descriptortype(ptr_);
	}

	// Convenient field type tests.
	bool IsSubMessage() const { return upb_fielddef_issubmsg(ptr_); }
	bool IsString() const { return upb_fielddef_isstring(ptr_); }
	bool IsSequence() const { return upb_fielddef_isseq(ptr_); }
	bool IsPrimitive() const { return upb_fielddef_isprimitive(ptr_); }
	bool IsMap() const { return upb_fielddef_ismap(ptr_); }

	// Returns the non-string default value for this fielddef, which may either
	// be something the client set explicitly or the "default default" (0 for
	// numbers, empty for strings). The field's type indicates the type of the
	// returned value, except for enum fields that are still mutable.
	//
	// Requires that the given function matches the field's current type.
	int64_t default_int64() const { return upb_fielddef_defaultint64(ptr_); }
	int32_t default_int32() const { return upb_fielddef_defaultint32(ptr_); }
	uint64_t default_uint64() const { return upb_fielddef_defaultuint64(ptr_); }
	uint32_t default_uint32() const { return upb_fielddef_defaultuint32(ptr_); }
	bool default_bool() const { return upb_fielddef_defaultbool(ptr_); }
	float default_float() const { return upb_fielddef_defaultfloat(ptr_); }
	double default_double() const { return upb_fielddef_defaultdouble(ptr_); }

	MessageValue default_value() const { return upb_fielddef_default(ptr_); }

	// The resulting string is always NULL-terminated. If non-NULL, the length
	// will be stored in *len.
	const char* default_string(size_t* len) const {
	return upb_fielddef_defaultstr(ptr_, len);
	}

	// Returns the enum or submessage def for this field, if any. The field's
	// type must match (ie. you may only call enum_subdef() for fields where
	// type() == UPB_TYPE_ENUM).
	EnumDefPtr enum_subdef() const;
	MessageDefPtr message_subdef() const;

	private:
	const upb_fielddef* ptr_;
	};

	// Class that represents a oneof.
	class OneofDefPtr {
	public:
	OneofDefPtr() : ptr_(nullptr) {}
	explicit OneofDefPtr(const upb_oneofdef* ptr) : ptr_(ptr) {}

	const upb_oneofdef* ptr() const { return ptr_; }
	explicit operator bool() const { return ptr_ != nullptr; }

	// Returns the MessageDef that contains this OneofDef.
	MessageDefPtr containing_type() const;

	// Returns the name of this oneof.
	const char* name() const { return upb_oneofdef_name(ptr_); }

	// Returns the number of fields in the oneof.
	int field_count() const { return upb_oneofdef_numfields(ptr_); }
	FieldDefPtr field(int i) const { return FieldDefPtr(upb_oneofdef_field(ptr_, i)); }

	// Looks up by name.
	FieldDefPtr FindFieldByName(const char* name, size_t len) const {
	return FieldDefPtr(upb_oneofdef_ntof(ptr_, name, len));
	}
	FieldDefPtr FindFieldByName(const char* name) const {
	return FieldDefPtr(upb_oneofdef_ntofz(ptr_, name));
	}

	template <class T>
	FieldDefPtr FindFieldByName(const T& str) const {
	return FindFieldByName(str.c_str(), str.size());
	}

	// Looks up by tag number.
	FieldDefPtr FindFieldByNumber(uint32_t num) const {
	return FieldDefPtr(upb_oneofdef_itof(ptr_, num));
	}

	private:
	const upb_oneofdef* ptr_;
	};

	// Structure that describes a single .proto message type.
	class MessageDefPtr {
	public:
	MessageDefPtr() : ptr_(nullptr) {}
	explicit MessageDefPtr(const upb_msgdef* ptr) : ptr_(ptr) {}

	const upb_msgdef* ptr() const { return ptr_; }
	explicit operator bool() const { return ptr_ != nullptr; }

	const char* full_name() const { return upb_msgdef_fullname(ptr_); }
	const char* name() const { return upb_msgdef_name(ptr_); }

	// The number of fields that belong to the MessageDef.
	int field_count() const { return upb_msgdef_numfields(ptr_); }
	FieldDefPtr field(int i) const { return FieldDefPtr(upb_msgdef_field(ptr_, i)); }

	// The number of oneofs that belong to the MessageDef.
	int oneof_count() const { return upb_msgdef_numoneofs(ptr_); }
	OneofDefPtr oneof(int i) const { return OneofDefPtr(upb_msgdef_oneof(ptr_, i)); }

	upb_syntax_t syntax() const { return upb_msgdef_syntax(ptr_); }

	// These return null pointers if the field is not found.
	FieldDefPtr FindFieldByNumber(uint32_t number) const {
	return FieldDefPtr(upb_msgdef_itof(ptr_, number));
	}
	FieldDefPtr FindFieldByName(const char* name, size_t len) const {
	return FieldDefPtr(upb_msgdef_ntof(ptr_, name, len));
	}
	FieldDefPtr FindFieldByName(const char* name) const {
	return FieldDefPtr(upb_msgdef_ntofz(ptr_, name));
	}

	template <class T>
	FieldDefPtr FindFieldByName(const T& str) const {
	return FindFieldByName(str.c_str(), str.size());
	}

	OneofDefPtr FindOneofByName(const char* name, size_t len) const {
	return OneofDefPtr(upb_msgdef_ntoo(ptr_, name, len));
	}

	OneofDefPtr FindOneofByName(const char* name) const {
	return OneofDefPtr(upb_msgdef_ntooz(ptr_, name));
	}

	template <class T>
	OneofDefPtr FindOneofByName(const T& str) const {
	return FindOneofByName(str.c_str(), str.size());
	}

	// Is this message a map entry?
	bool mapentry() const { return upb_msgdef_mapentry(ptr_); }

	// Return the type of well known type message. UPB_WELLKNOWN_UNSPECIFIED for
	// non-well-known message.
	upb_wellknowntype_t wellknowntype() const {
	return upb_msgdef_wellknowntype(ptr_);
	}

	// Whether is a number wrapper.
	bool isnumberwrapper() const { return upb_msgdef_isnumberwrapper(ptr_); }

	private:
	class FieldIter {
	public:
	explicit FieldIter(const upb_msgdef *m, int i) : m_(m), i_(i) {}
	void operator++() { i_++; }

	FieldDefPtr operator*() { return FieldDefPtr(upb_msgdef_field(m_, i_)); }
	bool operator!=(const FieldIter& other) { return i_ != other.i_; }
	bool operator==(const FieldIter& other) { return i_ == other.i_; }

	private:
	const upb_msgdef *m_;
	int i_;
	};

	class FieldAccessor {
	public:
	explicit FieldAccessor(const upb_msgdef* md) : md_(md) {}
	FieldIter begin() { return FieldIter(md_, 0); }
	FieldIter end() { return FieldIter(md_, upb_msgdef_fieldcount(md_)); }

	private:
	const upb_msgdef* md_;
	};

	class OneofIter {
	public:
	explicit OneofIter(const upb_msgdef *m, int i) : m_(m), i_(i) {}
	void operator++() { i_++; }

	OneofDefPtr operator*() { return OneofDefPtr(upb_msgdef_oneof(m_, i_)); }
	bool operator!=(const OneofIter& other) { return i_ != other.i_; }
	bool operator==(const OneofIter& other) { return i_ == other.i_; }

	private:
	const upb_msgdef *m_;
	int i_;
	};

	class OneofAccessor {
	public:
	explicit OneofAccessor(const upb_msgdef* md) : md_(md) {}
	OneofIter begin() { return OneofIter(md_, 0); }
	OneofIter end() { return OneofIter(md_, upb_msgdef_oneofcount(md_)); }

	private:
	const upb_msgdef* md_;
	};

	public:
	FieldAccessor fields() const { return FieldAccessor(ptr()); }
	OneofAccessor oneofs() const { return OneofAccessor(ptr()); }

	private:
	const upb_msgdef* ptr_;
	};

	class EnumDefPtr {
	public:
	EnumDefPtr() : ptr_(nullptr) {}
	explicit EnumDefPtr(const upb_enumdef* ptr) : ptr_(ptr) {}

	const upb_enumdef* ptr() const { return ptr_; }
	explicit operator bool() const { return ptr_ != nullptr; }

	const char* full_name() const { return upb_enumdef_fullname(ptr_); }
	const char* name() const { return upb_enumdef_name(ptr_); }

	// The value that is used as the default when no field default is specified.
	// If not set explicitly, the first value that was added will be used.
	// The default value must be a member of the enum.
	// Requires that value_count() > 0.
	int32_t default_value() const { return upb_enumdef_default(ptr_); }

	// Returns the number of values currently defined in the enum. Note that
	// multiple names can refer to the same number, so this may be greater than
	// the total number of unique numbers.
	int value_count() const { return upb_enumdef_numvals(ptr_); }

	// Lookups from name to integer, returning true if found.
	bool FindValueByName(const char* name, int32_t* num) const {
	return upb_enumdef_ntoiz(ptr_, name, num);
	}

	// Finds the name corresponding to the given number, or NULL if none was
	// found. If more than one name corresponds to this number, returns the
	// first one that was added.
	const char* FindValueByNumber(int32_t num) const {
	return upb_enumdef_iton(ptr_, num);
	}

	// Iteration over name/value pairs. The order is undefined.
	// Adding an enum val invalidates any iterators.
	//
	// TODO: make compatible with range-for, with elements as pairs?
	class Iterator {
	public:
	explicit Iterator(EnumDefPtr e) { upb_enum_begin(&iter_, e.ptr()); }

	int32_t number() { return upb_enum_iter_number(&iter_); }
	const char* name() { return upb_enum_iter_name(&iter_); }
	bool Done() { return upb_enum_done(&iter_); }
	void Next() { return upb_enum_next(&iter_); }

	private:
	upb_enum_iter iter_;
	};

	private:
	const upb_enumdef* ptr_;
	};

	// Class that represents a .proto file with some things defined in it.
	//
	// Many users won't care about FileDefs, but they are necessary if you want to
	// read the values of file-level options.
	class FileDefPtr {
	public:
	explicit FileDefPtr(const upb_filedef* ptr) : ptr_(ptr) {}

	const upb_filedef* ptr() const { return ptr_; }
	explicit operator bool() const { return ptr_ != nullptr; }

	// Get/set name of the file (eg. "foo/bar.proto").
	const char* name() const { return upb_filedef_name(ptr_); }

	// Package name for definitions inside the file (eg. "foo.bar").
	const char* package() const { return upb_filedef_package(ptr_); }

	// Sets the php class prefix which is prepended to all php generated classes
	// from this .proto. Default is empty.
	const char* phpprefix() const { return upb_filedef_phpprefix(ptr_); }

	// Use this option to change the namespace of php generated classes. Default
	// is empty. When this option is empty, the package name will be used for
	// determining the namespace.
	const char* phpnamespace() const { return upb_filedef_phpnamespace(ptr_); }

	// Syntax for the file. Defaults to proto2.
	upb_syntax_t syntax() const { return upb_filedef_syntax(ptr_); }

	// Get the list of dependencies from the file. These are returned in the
	// order that they were added to the FileDefPtr.
	int dependency_count() const { return upb_filedef_depcount(ptr_); }
	const FileDefPtr dependency(int index) const {
	return FileDefPtr(upb_filedef_dep(ptr_, index));
	}

	private:
	const upb_filedef* ptr_;
	};

	// Non-const methods in upb::SymbolTable are NOT thread-safe.
	class SymbolTable {
	public:
	SymbolTable() : ptr_(upb_symtab_new(), upb_symtab_free) {}
	explicit SymbolTable(upb_symtab* s) : ptr_(s, upb_symtab_free) {}

	const upb_symtab* ptr() const { return ptr_.get(); }
	upb_symtab* ptr() { return ptr_.get(); }

	// Finds an entry in the symbol table with this exact name. If not found,
	// returns NULL.
	MessageDefPtr LookupMessage(const char* sym) const {
	return MessageDefPtr(upb_symtab_lookupmsg(ptr_.get(), sym));
	}

	EnumDefPtr LookupEnum(const char* sym) const {
	return EnumDefPtr(upb_symtab_lookupenum(ptr_.get(), sym));
	}

	FileDefPtr LookupFile(const char* name) const {
	return FileDefPtr(upb_symtab_lookupfile(ptr_.get(), name));
	}

	// TODO: iteration?

	// Adds the given serialized FileDescriptorProto to the pool.
	FileDefPtr AddFile(const google_protobuf_FileDescriptorProto* file_proto,
	Status* status) {
	return FileDefPtr(
	upb_symtab_addfile(ptr_.get(), file_proto, status->ptr()));
	}

	private:
	std::unique_ptr<upb_symtab, decltype(&upb_symtab_free)> ptr_;
	};

	inline MessageDefPtr FieldDefPtr::message_subdef() const {
	return MessageDefPtr(upb_fielddef_msgsubdef(ptr_));
	}

	inline MessageDefPtr FieldDefPtr::containing_type() const {
	return MessageDefPtr(upb_fielddef_containingtype(ptr_));
	}

	inline MessageDefPtr OneofDefPtr::containing_type() const {
	return MessageDefPtr(upb_oneofdef_containingtype(ptr_));
	}

	inline OneofDefPtr FieldDefPtr::containing_oneof() const {
	return OneofDefPtr(upb_fielddef_containingoneof(ptr_));
	}

	inline EnumDefPtr FieldDefPtr::enum_subdef() const {
	return EnumDefPtr(upb_fielddef_enumsubdef(ptr_));
	}

	} // namespace upb

	#endif // UPB_DEF_HPP_