// Protocol Buffers - Google's data interchange format // Copyright 2008 Google Inc. All rights reserved. // https://developers.google.com/protocol-buffers/ // // 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 Inc. 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 THE COPYRIGHT // OWNER OR CONTRIBUTORS 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. // Author: kenton@google.com (Kenton Varda) // Based on original Protocol Buffers design by // Sanjay Ghemawat, Jeff Dean, and others. // // RepeatedField and RepeatedPtrField are used by generated protocol message // classes to manipulate repeated fields. These classes are very similar to // STL's vector, but include a number of optimizations found to be useful // specifically in the case of Protocol Buffers. RepeatedPtrField is // particularly different from STL vector as it manages ownership of the // pointers that it contains. // // Typically, clients should not need to access RepeatedField objects directly, // but should instead use the accessor functions generated automatically by the // protocol compiler. #ifndef GOOGLE_PROTOBUF_REPEATED_FIELD_H__ #define GOOGLE_PROTOBUF_REPEATED_FIELD_H__ #ifdef _MSC_VER // This is required for min/max on VS2013 only. #include #endif #include #include #include #include #include #include namespace google { namespace upb { namespace google_opensource { class GMR_Handlers; } // namespace google_opensource } // namespace upb namespace protobuf { class Message; namespace internal { static const int kMinRepeatedFieldAllocationSize = 4; // A utility function for logging that doesn't need any template types. void LogIndexOutOfBounds(int index, int size); template inline int CalculateReserve(Iter begin, Iter end, std::forward_iterator_tag) { return std::distance(begin, end); } template inline int CalculateReserve(Iter /*begin*/, Iter /*end*/, std::input_iterator_tag) { return -1; } template inline int CalculateReserve(Iter begin, Iter end) { typedef typename std::iterator_traits::iterator_category Category; return CalculateReserve(begin, end, Category()); } } // namespace internal // RepeatedField is used to represent repeated fields of a primitive type (in // other words, everything except strings and nested Messages). Most users will // not ever use a RepeatedField directly; they will use the get-by-index, // set-by-index, and add accessors that are generated for all repeated fields. template class RepeatedField { public: RepeatedField(); RepeatedField(const RepeatedField& other); template RepeatedField(Iter begin, const Iter& end); ~RepeatedField(); RepeatedField& operator=(const RepeatedField& other); bool empty() const; int size() const; const Element& Get(int index) const; Element* Mutable(int index); void Set(int index, const Element& value); void Add(const Element& value); Element* Add(); // Remove the last element in the array. void RemoveLast(); // Extract elements with indices in "[start .. start+num-1]". // Copy them into "elements[0 .. num-1]" if "elements" is not NULL. // Caution: implementation also moves elements with indices [start+num ..]. // Calling this routine inside a loop can cause quadratic behavior. void ExtractSubrange(int start, int num, Element* elements); void Clear(); void MergeFrom(const RepeatedField& other); void CopyFrom(const RepeatedField& other); // Reserve space to expand the field to at least the given size. If the // array is grown, it will always be at least doubled in size. void Reserve(int new_size); // Resize the RepeatedField to a new, smaller size. This is O(1). void Truncate(int new_size); void AddAlreadyReserved(const Element& value); Element* AddAlreadyReserved(); int Capacity() const; // Like STL resize. Uses value to fill appended elements. // Like Truncate() if new_size <= size(), otherwise this is // O(new_size - size()). void Resize(int new_size, const Element& value); // Gets the underlying array. This pointer is possibly invalidated by // any add or remove operation. Element* mutable_data(); const Element* data() const; // Swap entire contents with "other". void Swap(RepeatedField* other); // Swap two elements. void SwapElements(int index1, int index2); // STL-like iterator support typedef Element* iterator; typedef const Element* const_iterator; typedef Element value_type; typedef value_type& reference; typedef const value_type& const_reference; typedef value_type* pointer; typedef const value_type* const_pointer; typedef int size_type; typedef ptrdiff_t difference_type; iterator begin(); const_iterator begin() const; iterator end(); const_iterator end() const; // Reverse iterator support typedef std::reverse_iterator const_reverse_iterator; typedef std::reverse_iterator reverse_iterator; reverse_iterator rbegin() { return reverse_iterator(end()); } const_reverse_iterator rbegin() const { return const_reverse_iterator(end()); } reverse_iterator rend() { return reverse_iterator(begin()); } const_reverse_iterator rend() const { return const_reverse_iterator(begin()); } // Returns the number of bytes used by the repeated field, excluding // sizeof(*this) int SpaceUsedExcludingSelf() const; private: static const int kInitialSize = 0; Element* elements_; int current_size_; int total_size_; // Move the contents of |from| into |to|, possibly clobbering |from| in the // process. For primitive types this is just a memcpy(), but it could be // specialized for non-primitive types to, say, swap each element instead. void MoveArray(Element to[], Element from[], int size); // Copy the elements of |from| into |to|. void CopyArray(Element to[], const Element from[], int size); }; namespace internal { template class RepeatedPtrIterator; template class RepeatedPtrOverPtrsIterator; } // namespace internal namespace internal { // This is a helper template to copy an array of elements effeciently when they // have a trivial copy constructor, and correctly otherwise. This really // shouldn't be necessary, but our compiler doesn't optimize std::copy very // effectively. template ::value> struct ElementCopier { void operator()(Element to[], const Element from[], int array_size); }; } // namespace internal namespace internal { // This is the common base class for RepeatedPtrFields. It deals only in void* // pointers. Users should not use this interface directly. // // The methods of this interface correspond to the methods of RepeatedPtrField, // but may have a template argument called TypeHandler. Its signature is: // class TypeHandler { // public: // typedef MyType Type; // static Type* New(); // static void Delete(Type*); // static void Clear(Type*); // static void Merge(const Type& from, Type* to); // // // Only needs to be implemented if SpaceUsedExcludingSelf() is called. // static int SpaceUsed(const Type&); // }; class LIBPROTOBUF_EXPORT RepeatedPtrFieldBase { protected: // The reflection implementation needs to call protected methods directly, // reinterpreting pointers as being to Message instead of a specific Message // subclass. friend class GeneratedMessageReflection; // ExtensionSet stores repeated message extensions as // RepeatedPtrField, but non-lite ExtensionSets need to // implement SpaceUsed(), and thus need to call SpaceUsedExcludingSelf() // reinterpreting MessageLite as Message. ExtensionSet also needs to make // use of AddFromCleared(), which is not part of the public interface. friend class ExtensionSet; // To parse directly into a proto2 generated class, the upb class GMR_Handlers // needs to be able to modify a RepeatedPtrFieldBase directly. friend class LIBPROTOBUF_EXPORT upb::google_opensource::GMR_Handlers; RepeatedPtrFieldBase(); // Must be called from destructor. template void Destroy(); bool empty() const; int size() const; template const typename TypeHandler::Type& Get(int index) const; template typename TypeHandler::Type* Mutable(int index); template typename TypeHandler::Type* Add(); template void RemoveLast(); template void Clear(); template void MergeFrom(const RepeatedPtrFieldBase& other); template void CopyFrom(const RepeatedPtrFieldBase& other); void CloseGap(int start, int num) { // Close up a gap of "num" elements starting at offset "start". for (int i = start + num; i < allocated_size_; ++i) elements_[i - num] = elements_[i]; current_size_ -= num; allocated_size_ -= num; } void Reserve(int new_size); int Capacity() const; // Used for constructing iterators. void* const* raw_data() const; void** raw_mutable_data() const; template typename TypeHandler::Type** mutable_data(); template const typename TypeHandler::Type* const* data() const; void Swap(RepeatedPtrFieldBase* other); void SwapElements(int index1, int index2); template int SpaceUsedExcludingSelf() const; // Advanced memory management -------------------------------------- // Like Add(), but if there are no cleared objects to use, returns NULL. template typename TypeHandler::Type* AddFromCleared(); template void AddAllocated(typename TypeHandler::Type* value); template typename TypeHandler::Type* ReleaseLast(); int ClearedCount() const; template void AddCleared(typename TypeHandler::Type* value); template typename TypeHandler::Type* ReleaseCleared(); private: static const int kInitialSize = 0; void** elements_; int current_size_; int allocated_size_; int total_size_; template static inline typename TypeHandler::Type* cast(void* element) { return reinterpret_cast(element); } template static inline const typename TypeHandler::Type* cast(const void* element) { return reinterpret_cast(element); } GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(RepeatedPtrFieldBase); }; template class GenericTypeHandler { public: typedef GenericType Type; static GenericType* New() { return new GenericType; } static void Delete(GenericType* value) { delete value; } static void Clear(GenericType* value) { value->Clear(); } static void Merge(const GenericType& from, GenericType* to) { to->MergeFrom(from); } static int SpaceUsed(const GenericType& value) { return value.SpaceUsed(); } static const Type& default_instance() { return Type::default_instance(); } }; template <> inline void GenericTypeHandler::Merge( const MessageLite& from, MessageLite* to) { to->CheckTypeAndMergeFrom(from); } template <> inline const MessageLite& GenericTypeHandler::default_instance() { // Yes, the behavior of the code is undefined, but this function is only // called when we're already deep into the world of undefined, because the // caller called Get(index) out of bounds. MessageLite* null = NULL; return *null; } template <> inline const Message& GenericTypeHandler::default_instance() { // Yes, the behavior of the code is undefined, but this function is only // called when we're already deep into the world of undefined, because the // caller called Get(index) out of bounds. Message* null = NULL; return *null; } // HACK: If a class is declared as DLL-exported in MSVC, it insists on // generating copies of all its methods -- even inline ones -- to include // in the DLL. But SpaceUsed() calls StringSpaceUsedExcludingSelf() which // isn't in the lite library, therefore the lite library cannot link if // StringTypeHandler is exported. So, we factor out StringTypeHandlerBase, // export that, then make StringTypeHandler be a subclass which is NOT // exported. // TODO(kenton): There has to be a better way. class LIBPROTOBUF_EXPORT StringTypeHandlerBase { public: typedef string Type; static string* New(); static void Delete(string* value); static void Clear(string* value) { value->clear(); } static void Merge(const string& from, string* to) { *to = from; } static const Type& default_instance() { return ::google::protobuf::internal::GetEmptyString(); } }; class StringTypeHandler : public StringTypeHandlerBase { public: static int SpaceUsed(const string& value) { return sizeof(value) + StringSpaceUsedExcludingSelf(value); } }; } // namespace internal // RepeatedPtrField is like RepeatedField, but used for repeated strings or // Messages. template class RepeatedPtrField : public internal::RepeatedPtrFieldBase { public: RepeatedPtrField(); RepeatedPtrField(const RepeatedPtrField& other); template RepeatedPtrField(Iter begin, const Iter& end); ~RepeatedPtrField(); RepeatedPtrField& operator=(const RepeatedPtrField& other); bool empty() const; int size() const; const Element& Get(int index) const; Element* Mutable(int index); Element* Add(); // Remove the last element in the array. // Ownership of the element is retained by the array. void RemoveLast(); // Delete elements with indices in the range [start .. start+num-1]. // Caution: implementation moves all elements with indices [start+num .. ]. // Calling this routine inside a loop can cause quadratic behavior. void DeleteSubrange(int start, int num); void Clear(); void MergeFrom(const RepeatedPtrField& other); void CopyFrom(const RepeatedPtrField& other); // Reserve space to expand the field to at least the given size. This only // resizes the pointer array; it doesn't allocate any objects. If the // array is grown, it will always be at least doubled in size. void Reserve(int new_size); int Capacity() const; // Gets the underlying array. This pointer is possibly invalidated by // any add or remove operation. Element** mutable_data(); const Element* const* data() const; // Swap entire contents with "other". void Swap(RepeatedPtrField* other); // Swap two elements. void SwapElements(int index1, int index2); // STL-like iterator support typedef internal::RepeatedPtrIterator iterator; typedef internal::RepeatedPtrIterator const_iterator; typedef Element value_type; typedef value_type& reference; typedef const value_type& const_reference; typedef value_type* pointer; typedef const value_type* const_pointer; typedef int size_type; typedef ptrdiff_t difference_type; iterator begin(); const_iterator begin() const; iterator end(); const_iterator end() const; // Reverse iterator support typedef std::reverse_iterator const_reverse_iterator; typedef std::reverse_iterator reverse_iterator; reverse_iterator rbegin() { return reverse_iterator(end()); } const_reverse_iterator rbegin() const { return const_reverse_iterator(end()); } reverse_iterator rend() { return reverse_iterator(begin()); } const_reverse_iterator rend() const { return const_reverse_iterator(begin()); } // Custom STL-like iterator that iterates over and returns the underlying // pointers to Element rather than Element itself. typedef internal::RepeatedPtrOverPtrsIterator pointer_iterator; typedef internal::RepeatedPtrOverPtrsIterator const_pointer_iterator; pointer_iterator pointer_begin(); const_pointer_iterator pointer_begin() const; pointer_iterator pointer_end(); const_pointer_iterator pointer_end() const; // Returns (an estimate of) the number of bytes used by the repeated field, // excluding sizeof(*this). int SpaceUsedExcludingSelf() const; // Advanced memory management -------------------------------------- // When hardcore memory management becomes necessary -- as it sometimes // does here at Google -- the following methods may be useful. // Add an already-allocated object, passing ownership to the // RepeatedPtrField. void AddAllocated(Element* value); // Remove the last element and return it, passing ownership to the caller. // Requires: size() > 0 Element* ReleaseLast(); // Extract elements with indices in the range "[start .. start+num-1]". // The caller assumes ownership of the extracted elements and is responsible // for deleting them when they are no longer needed. // If "elements" is non-NULL, then pointers to the extracted elements // are stored in "elements[0 .. num-1]" for the convenience of the caller. // If "elements" is NULL, then the caller must use some other mechanism // to perform any further operations (like deletion) on these elements. // Caution: implementation also moves elements with indices [start+num ..]. // Calling this routine inside a loop can cause quadratic behavior. void ExtractSubrange(int start, int num, Element** elements); // When elements are removed by calls to RemoveLast() or Clear(), they // are not actually freed. Instead, they are cleared and kept so that // they can be reused later. This can save lots of CPU time when // repeatedly reusing a protocol message for similar purposes. // // Hardcore programs may choose to manipulate these cleared objects // to better optimize memory management using the following routines. // Get the number of cleared objects that are currently being kept // around for reuse. int ClearedCount() const; // Add an element to the pool of cleared objects, passing ownership to // the RepeatedPtrField. The element must be cleared prior to calling // this method. void AddCleared(Element* value); // Remove a single element from the cleared pool and return it, passing // ownership to the caller. The element is guaranteed to be cleared. // Requires: ClearedCount() > 0 Element* ReleaseCleared(); protected: // Note: RepeatedPtrField SHOULD NOT be subclassed by users. We only // subclass it in one place as a hack for compatibility with proto1. The // subclass needs to know about TypeHandler in order to call protected // methods on RepeatedPtrFieldBase. class TypeHandler; }; // implementation ==================================================== template inline RepeatedField::RepeatedField() : elements_(NULL), current_size_(0), total_size_(kInitialSize) { } template inline RepeatedField::RepeatedField(const RepeatedField& other) : elements_(NULL), current_size_(0), total_size_(kInitialSize) { CopyFrom(other); } template template inline RepeatedField::RepeatedField(Iter begin, const Iter& end) : elements_(NULL), current_size_(0), total_size_(kInitialSize) { int reserve = internal::CalculateReserve(begin, end); if (reserve != -1) { Reserve(reserve); for (; begin != end; ++begin) { AddAlreadyReserved(*begin); } } else { for (; begin != end; ++begin) { Add(*begin); } } } template RepeatedField::~RepeatedField() { delete [] elements_; } template inline RepeatedField& RepeatedField::operator=(const RepeatedField& other) { if (this != &other) CopyFrom(other); return *this; } template inline bool RepeatedField::empty() const { return current_size_ == 0; } template inline int RepeatedField::size() const { return current_size_; } template inline int RepeatedField::Capacity() const { return total_size_; } template inline void RepeatedField::AddAlreadyReserved(const Element& value) { GOOGLE_DCHECK_LT(size(), Capacity()); elements_[current_size_++] = value; } template inline Element* RepeatedField::AddAlreadyReserved() { GOOGLE_DCHECK_LT(size(), Capacity()); return &elements_[current_size_++]; } template inline void RepeatedField::Resize(int new_size, const Element& value) { GOOGLE_DCHECK_GE(new_size, 0); if (new_size > size()) { Reserve(new_size); std::fill(&elements_[current_size_], &elements_[new_size], value); } current_size_ = new_size; } template inline const Element& RepeatedField::Get(int index) const { GOOGLE_DCHECK_GE(index, 0); GOOGLE_DCHECK_LT(index, size()); return elements_[index]; } template inline Element* RepeatedField::Mutable(int index) { GOOGLE_DCHECK_GE(index, 0); GOOGLE_DCHECK_LT(index, size()); return elements_ + index; } template inline void RepeatedField::Set(int index, const Element& value) { GOOGLE_DCHECK_GE(index, 0); GOOGLE_DCHECK_LT(index, size()); elements_[index] = value; } template inline void RepeatedField::Add(const Element& value) { if (current_size_ == total_size_) Reserve(total_size_ + 1); elements_[current_size_++] = value; } template inline Element* RepeatedField::Add() { if (current_size_ == total_size_) Reserve(total_size_ + 1); return &elements_[current_size_++]; } template inline void RepeatedField::RemoveLast() { GOOGLE_DCHECK_GT(current_size_, 0); --current_size_; } template void RepeatedField::ExtractSubrange( int start, int num, Element* elements) { GOOGLE_DCHECK_GE(start, 0); GOOGLE_DCHECK_GE(num, 0); GOOGLE_DCHECK_LE(start + num, this->size()); // Save the values of the removed elements if requested. if (elements != NULL) { for (int i = 0; i < num; ++i) elements[i] = this->Get(i + start); } // Slide remaining elements down to fill the gap. if (num > 0) { for (int i = start + num; i < this->size(); ++i) this->Set(i - num, this->Get(i)); this->Truncate(this->size() - num); } } template inline void RepeatedField::Clear() { current_size_ = 0; } template inline void RepeatedField::MergeFrom(const RepeatedField& other) { GOOGLE_CHECK_NE(&other, this); if (other.current_size_ != 0) { Reserve(current_size_ + other.current_size_); CopyArray(elements_ + current_size_, other.elements_, other.current_size_); current_size_ += other.current_size_; } } template inline void RepeatedField::CopyFrom(const RepeatedField& other) { if (&other == this) return; Clear(); MergeFrom(other); } template inline Element* RepeatedField::mutable_data() { return elements_; } template inline const Element* RepeatedField::data() const { return elements_; } template void RepeatedField::Swap(RepeatedField* other) { if (this == other) return; Element* swap_elements = elements_; int swap_current_size = current_size_; int swap_total_size = total_size_; elements_ = other->elements_; current_size_ = other->current_size_; total_size_ = other->total_size_; other->elements_ = swap_elements; other->current_size_ = swap_current_size; other->total_size_ = swap_total_size; } template void RepeatedField::SwapElements(int index1, int index2) { using std::swap; // enable ADL with fallback swap(elements_[index1], elements_[index2]); } template inline typename RepeatedField::iterator RepeatedField::begin() { return elements_; } template inline typename RepeatedField::const_iterator RepeatedField::begin() const { return elements_; } template inline typename RepeatedField::iterator RepeatedField::end() { return elements_ + current_size_; } template inline typename RepeatedField::const_iterator RepeatedField::end() const { return elements_ + current_size_; } template inline int RepeatedField::SpaceUsedExcludingSelf() const { return (elements_ != NULL) ? total_size_ * sizeof(elements_[0]) : 0; } // Avoid inlining of Reserve(): new, copy, and delete[] lead to a significant // amount of code bloat. template void RepeatedField::Reserve(int new_size) { if (total_size_ >= new_size) return; Element* old_elements = elements_; total_size_ = max(google::protobuf::internal::kMinRepeatedFieldAllocationSize, max(total_size_ * 2, new_size)); elements_ = new Element[total_size_]; if (old_elements != NULL) { MoveArray(elements_, old_elements, current_size_); delete [] old_elements; } } template inline void RepeatedField::Truncate(int new_size) { GOOGLE_DCHECK_LE(new_size, current_size_); current_size_ = new_size; } template inline void RepeatedField::MoveArray( Element to[], Element from[], int array_size) { CopyArray(to, from, array_size); } template inline void RepeatedField::CopyArray( Element to[], const Element from[], int array_size) { internal::ElementCopier()(to, from, array_size); } namespace internal { template void ElementCopier::operator()( Element to[], const Element from[], int array_size) { std::copy(from, from + array_size, to); } template struct ElementCopier { void operator()(Element to[], const Element from[], int array_size) { memcpy(to, from, array_size * sizeof(Element)); } }; } // namespace internal // ------------------------------------------------------------------- namespace internal { inline RepeatedPtrFieldBase::RepeatedPtrFieldBase() : elements_(NULL), current_size_(0), allocated_size_(0), total_size_(kInitialSize) { } template void RepeatedPtrFieldBase::Destroy() { for (int i = 0; i < allocated_size_; i++) { TypeHandler::Delete(cast(elements_[i])); } delete [] elements_; } inline bool RepeatedPtrFieldBase::empty() const { return current_size_ == 0; } inline int RepeatedPtrFieldBase::size() const { return current_size_; } template inline const typename TypeHandler::Type& RepeatedPtrFieldBase::Get(int index) const { GOOGLE_DCHECK_GE(index, 0); GOOGLE_DCHECK_LT(index, size()); return *cast(elements_[index]); } template inline typename TypeHandler::Type* RepeatedPtrFieldBase::Mutable(int index) { GOOGLE_DCHECK_GE(index, 0); GOOGLE_DCHECK_LT(index, size()); return cast(elements_[index]); } template inline typename TypeHandler::Type* RepeatedPtrFieldBase::Add() { if (current_size_ < allocated_size_) { return cast(elements_[current_size_++]); } if (allocated_size_ == total_size_) Reserve(total_size_ + 1); typename TypeHandler::Type* result = TypeHandler::New(); ++allocated_size_; elements_[current_size_++] = result; return result; } template inline void RepeatedPtrFieldBase::RemoveLast() { GOOGLE_DCHECK_GT(current_size_, 0); TypeHandler::Clear(cast(elements_[--current_size_])); } template void RepeatedPtrFieldBase::Clear() { for (int i = 0; i < current_size_; i++) { TypeHandler::Clear(cast(elements_[i])); } current_size_ = 0; } template inline void RepeatedPtrFieldBase::MergeFrom(const RepeatedPtrFieldBase& other) { GOOGLE_CHECK_NE(&other, this); Reserve(current_size_ + other.current_size_); for (int i = 0; i < other.current_size_; i++) { TypeHandler::Merge(other.template Get(i), Add()); } } template inline void RepeatedPtrFieldBase::CopyFrom(const RepeatedPtrFieldBase& other) { if (&other == this) return; RepeatedPtrFieldBase::Clear(); RepeatedPtrFieldBase::MergeFrom(other); } inline int RepeatedPtrFieldBase::Capacity() const { return total_size_; } inline void* const* RepeatedPtrFieldBase::raw_data() const { return elements_; } inline void** RepeatedPtrFieldBase::raw_mutable_data() const { return elements_; } template inline typename TypeHandler::Type** RepeatedPtrFieldBase::mutable_data() { // TODO(kenton): Breaks C++ aliasing rules. We should probably remove this // method entirely. return reinterpret_cast(elements_); } template inline const typename TypeHandler::Type* const* RepeatedPtrFieldBase::data() const { // TODO(kenton): Breaks C++ aliasing rules. We should probably remove this // method entirely. return reinterpret_cast(elements_); } inline void RepeatedPtrFieldBase::SwapElements(int index1, int index2) { using std::swap; // enable ADL with fallback swap(elements_[index1], elements_[index2]); } template inline int RepeatedPtrFieldBase::SpaceUsedExcludingSelf() const { int allocated_bytes = (elements_ != NULL) ? total_size_ * sizeof(elements_[0]) : 0; for (int i = 0; i < allocated_size_; ++i) { allocated_bytes += TypeHandler::SpaceUsed(*cast(elements_[i])); } return allocated_bytes; } template inline typename TypeHandler::Type* RepeatedPtrFieldBase::AddFromCleared() { if (current_size_ < allocated_size_) { return cast(elements_[current_size_++]); } else { return NULL; } } template void RepeatedPtrFieldBase::AddAllocated( typename TypeHandler::Type* value) { // Make room for the new pointer. if (current_size_ == total_size_) { // The array is completely full with no cleared objects, so grow it. Reserve(total_size_ + 1); ++allocated_size_; } else if (allocated_size_ == total_size_) { // There is no more space in the pointer array because it contains some // cleared objects awaiting reuse. We don't want to grow the array in this // case because otherwise a loop calling AddAllocated() followed by Clear() // would leak memory. TypeHandler::Delete(cast(elements_[current_size_])); } else if (current_size_ < allocated_size_) { // We have some cleared objects. We don't care about their order, so we // can just move the first one to the end to make space. elements_[allocated_size_] = elements_[current_size_]; ++allocated_size_; } else { // There are no cleared objects. ++allocated_size_; } elements_[current_size_++] = value; } template inline typename TypeHandler::Type* RepeatedPtrFieldBase::ReleaseLast() { GOOGLE_DCHECK_GT(current_size_, 0); typename TypeHandler::Type* result = cast(elements_[--current_size_]); --allocated_size_; if (current_size_ < allocated_size_) { // There are cleared elements on the end; replace the removed element // with the last allocated element. elements_[current_size_] = elements_[allocated_size_]; } return result; } inline int RepeatedPtrFieldBase::ClearedCount() const { return allocated_size_ - current_size_; } template inline void RepeatedPtrFieldBase::AddCleared( typename TypeHandler::Type* value) { if (allocated_size_ == total_size_) Reserve(total_size_ + 1); elements_[allocated_size_++] = value; } template inline typename TypeHandler::Type* RepeatedPtrFieldBase::ReleaseCleared() { GOOGLE_DCHECK_GT(allocated_size_, current_size_); return cast(elements_[--allocated_size_]); } } // namespace internal // ------------------------------------------------------------------- template class RepeatedPtrField::TypeHandler : public internal::GenericTypeHandler { }; template <> class RepeatedPtrField::TypeHandler : public internal::StringTypeHandler { }; template inline RepeatedPtrField::RepeatedPtrField() {} template inline RepeatedPtrField::RepeatedPtrField( const RepeatedPtrField& other) : RepeatedPtrFieldBase() { CopyFrom(other); } template template inline RepeatedPtrField::RepeatedPtrField( Iter begin, const Iter& end) { int reserve = internal::CalculateReserve(begin, end); if (reserve != -1) { Reserve(reserve); } for (; begin != end; ++begin) { *Add() = *begin; } } template RepeatedPtrField::~RepeatedPtrField() { Destroy(); } template inline RepeatedPtrField& RepeatedPtrField::operator=( const RepeatedPtrField& other) { if (this != &other) CopyFrom(other); return *this; } template inline bool RepeatedPtrField::empty() const { return RepeatedPtrFieldBase::empty(); } template inline int RepeatedPtrField::size() const { return RepeatedPtrFieldBase::size(); } template inline const Element& RepeatedPtrField::Get(int index) const { return RepeatedPtrFieldBase::Get(index); } template inline Element* RepeatedPtrField::Mutable(int index) { return RepeatedPtrFieldBase::Mutable(index); } template inline Element* RepeatedPtrField::Add() { return RepeatedPtrFieldBase::Add(); } template inline void RepeatedPtrField::RemoveLast() { RepeatedPtrFieldBase::RemoveLast(); } template inline void RepeatedPtrField::DeleteSubrange(int start, int num) { GOOGLE_DCHECK_GE(start, 0); GOOGLE_DCHECK_GE(num, 0); GOOGLE_DCHECK_LE(start + num, size()); for (int i = 0; i < num; ++i) delete RepeatedPtrFieldBase::Mutable(start + i); ExtractSubrange(start, num, NULL); } template inline void RepeatedPtrField::ExtractSubrange( int start, int num, Element** elements) { GOOGLE_DCHECK_GE(start, 0); GOOGLE_DCHECK_GE(num, 0); GOOGLE_DCHECK_LE(start + num, size()); if (num > 0) { // Save the values of the removed elements if requested. if (elements != NULL) { for (int i = 0; i < num; ++i) elements[i] = RepeatedPtrFieldBase::Mutable(i + start); } CloseGap(start, num); } } template inline void RepeatedPtrField::Clear() { RepeatedPtrFieldBase::Clear(); } template inline void RepeatedPtrField::MergeFrom( const RepeatedPtrField& other) { RepeatedPtrFieldBase::MergeFrom(other); } template inline void RepeatedPtrField::CopyFrom( const RepeatedPtrField& other) { RepeatedPtrFieldBase::CopyFrom(other); } template inline Element** RepeatedPtrField::mutable_data() { return RepeatedPtrFieldBase::mutable_data(); } template inline const Element* const* RepeatedPtrField::data() const { return RepeatedPtrFieldBase::data(); } template void RepeatedPtrField::Swap(RepeatedPtrField* other) { RepeatedPtrFieldBase::Swap(other); } template void RepeatedPtrField::SwapElements(int index1, int index2) { RepeatedPtrFieldBase::SwapElements(index1, index2); } template inline int RepeatedPtrField::SpaceUsedExcludingSelf() const { return RepeatedPtrFieldBase::SpaceUsedExcludingSelf(); } template inline void RepeatedPtrField::AddAllocated(Element* value) { RepeatedPtrFieldBase::AddAllocated(value); } template inline Element* RepeatedPtrField::ReleaseLast() { return RepeatedPtrFieldBase::ReleaseLast(); } template inline int RepeatedPtrField::ClearedCount() const { return RepeatedPtrFieldBase::ClearedCount(); } template inline void RepeatedPtrField::AddCleared(Element* value) { return RepeatedPtrFieldBase::AddCleared(value); } template inline Element* RepeatedPtrField::ReleaseCleared() { return RepeatedPtrFieldBase::ReleaseCleared(); } template inline void RepeatedPtrField::Reserve(int new_size) { return RepeatedPtrFieldBase::Reserve(new_size); } template inline int RepeatedPtrField::Capacity() const { return RepeatedPtrFieldBase::Capacity(); } // ------------------------------------------------------------------- namespace internal { // STL-like iterator implementation for RepeatedPtrField. You should not // refer to this class directly; use RepeatedPtrField::iterator instead. // // The iterator for RepeatedPtrField, RepeatedPtrIterator, is // very similar to iterator_ptr in util/gtl/iterator_adaptors.h, // but adds random-access operators and is modified to wrap a void** base // iterator (since RepeatedPtrField stores its array as a void* array and // casting void** to T** would violate C++ aliasing rules). // // This code based on net/proto/proto-array-internal.h by Jeffrey Yasskin // (jyasskin@google.com). template class RepeatedPtrIterator : public std::iterator< std::random_access_iterator_tag, Element> { public: typedef RepeatedPtrIterator iterator; typedef std::iterator< std::random_access_iterator_tag, Element> superclass; // Shadow the value_type in std::iterator<> because const_iterator::value_type // needs to be T, not const T. typedef typename remove_const::type value_type; // Let the compiler know that these are type names, so we don't have to // write "typename" in front of them everywhere. typedef typename superclass::reference reference; typedef typename superclass::pointer pointer; typedef typename superclass::difference_type difference_type; RepeatedPtrIterator() : it_(NULL) {} explicit RepeatedPtrIterator(void* const* it) : it_(it) {} // Allow "upcasting" from RepeatedPtrIterator to // RepeatedPtrIterator. template RepeatedPtrIterator(const RepeatedPtrIterator& other) : it_(other.it_) { // Force a compiler error if the other type is not convertible to ours. if (false) { implicit_cast(0); } } // dereferenceable reference operator*() const { return *reinterpret_cast(*it_); } pointer operator->() const { return &(operator*()); } // {inc,dec}rementable iterator& operator++() { ++it_; return *this; } iterator operator++(int) { return iterator(it_++); } iterator& operator--() { --it_; return *this; } iterator operator--(int) { return iterator(it_--); } // equality_comparable bool operator==(const iterator& x) const { return it_ == x.it_; } bool operator!=(const iterator& x) const { return it_ != x.it_; } // less_than_comparable bool operator<(const iterator& x) const { return it_ < x.it_; } bool operator<=(const iterator& x) const { return it_ <= x.it_; } bool operator>(const iterator& x) const { return it_ > x.it_; } bool operator>=(const iterator& x) const { return it_ >= x.it_; } // addable, subtractable iterator& operator+=(difference_type d) { it_ += d; return *this; } friend iterator operator+(iterator it, difference_type d) { it += d; return it; } friend iterator operator+(difference_type d, iterator it) { it += d; return it; } iterator& operator-=(difference_type d) { it_ -= d; return *this; } friend iterator operator-(iterator it, difference_type d) { it -= d; return it; } // indexable reference operator[](difference_type d) const { return *(*this + d); } // random access iterator difference_type operator-(const iterator& x) const { return it_ - x.it_; } private: template friend class RepeatedPtrIterator; // The internal iterator. void* const* it_; }; // Provide an iterator that operates on pointers to the underlying objects // rather than the objects themselves as RepeatedPtrIterator does. // Consider using this when working with stl algorithms that change // the array. // The VoidPtr template parameter holds the type-agnostic pointer value // referenced by the iterator. It should either be "void *" for a mutable // iterator, or "const void *" for a constant iterator. template class RepeatedPtrOverPtrsIterator : public std::iterator { public: typedef RepeatedPtrOverPtrsIterator iterator; typedef std::iterator< std::random_access_iterator_tag, Element*> superclass; // Shadow the value_type in std::iterator<> because const_iterator::value_type // needs to be T, not const T. typedef typename remove_const::type value_type; // Let the compiler know that these are type names, so we don't have to // write "typename" in front of them everywhere. typedef typename superclass::reference reference; typedef typename superclass::pointer pointer; typedef typename superclass::difference_type difference_type; RepeatedPtrOverPtrsIterator() : it_(NULL) {} explicit RepeatedPtrOverPtrsIterator(VoidPtr* it) : it_(it) {} // dereferenceable reference operator*() const { return *reinterpret_cast(it_); } pointer operator->() const { return &(operator*()); } // {inc,dec}rementable iterator& operator++() { ++it_; return *this; } iterator operator++(int) { return iterator(it_++); } iterator& operator--() { --it_; return *this; } iterator operator--(int) { return iterator(it_--); } // equality_comparable bool operator==(const iterator& x) const { return it_ == x.it_; } bool operator!=(const iterator& x) const { return it_ != x.it_; } // less_than_comparable bool operator<(const iterator& x) const { return it_ < x.it_; } bool operator<=(const iterator& x) const { return it_ <= x.it_; } bool operator>(const iterator& x) const { return it_ > x.it_; } bool operator>=(const iterator& x) const { return it_ >= x.it_; } // addable, subtractable iterator& operator+=(difference_type d) { it_ += d; return *this; } friend iterator operator+(iterator it, difference_type d) { it += d; return it; } friend iterator operator+(difference_type d, iterator it) { it += d; return it; } iterator& operator-=(difference_type d) { it_ -= d; return *this; } friend iterator operator-(iterator it, difference_type d) { it -= d; return it; } // indexable reference operator[](difference_type d) const { return *(*this + d); } // random access iterator difference_type operator-(const iterator& x) const { return it_ - x.it_; } private: template friend class RepeatedPtrIterator; // The internal iterator. VoidPtr* it_; }; } // namespace internal template inline typename RepeatedPtrField::iterator RepeatedPtrField::begin() { return iterator(raw_data()); } template inline typename RepeatedPtrField::const_iterator RepeatedPtrField::begin() const { return iterator(raw_data()); } template inline typename RepeatedPtrField::iterator RepeatedPtrField::end() { return iterator(raw_data() + size()); } template inline typename RepeatedPtrField::const_iterator RepeatedPtrField::end() const { return iterator(raw_data() + size()); } template inline typename RepeatedPtrField::pointer_iterator RepeatedPtrField::pointer_begin() { return pointer_iterator(raw_mutable_data()); } template inline typename RepeatedPtrField::const_pointer_iterator RepeatedPtrField::pointer_begin() const { return const_pointer_iterator(const_cast(raw_mutable_data())); } template inline typename RepeatedPtrField::pointer_iterator RepeatedPtrField::pointer_end() { return pointer_iterator(raw_mutable_data() + size()); } template inline typename RepeatedPtrField::const_pointer_iterator RepeatedPtrField::pointer_end() const { return const_pointer_iterator( const_cast(raw_mutable_data() + size())); } // Iterators and helper functions that follow the spirit of the STL // std::back_insert_iterator and std::back_inserter but are tailor-made // for RepeatedField and RepatedPtrField. Typical usage would be: // // std::copy(some_sequence.begin(), some_sequence.end(), // google::protobuf::RepeatedFieldBackInserter(proto.mutable_sequence())); // // Ported by johannes from util/gtl/proto-array-iterators.h namespace internal { // A back inserter for RepeatedField objects. template class RepeatedFieldBackInsertIterator : public std::iterator { public: explicit RepeatedFieldBackInsertIterator( RepeatedField* const mutable_field) : field_(mutable_field) { } RepeatedFieldBackInsertIterator& operator=(const T& value) { field_->Add(value); return *this; } RepeatedFieldBackInsertIterator& operator*() { return *this; } RepeatedFieldBackInsertIterator& operator++() { return *this; } RepeatedFieldBackInsertIterator& operator++(int /* unused */) { return *this; } private: RepeatedField* field_; }; // A back inserter for RepeatedPtrField objects. template class RepeatedPtrFieldBackInsertIterator : public std::iterator { public: RepeatedPtrFieldBackInsertIterator( RepeatedPtrField* const mutable_field) : field_(mutable_field) { } RepeatedPtrFieldBackInsertIterator& operator=(const T& value) { *field_->Add() = value; return *this; } RepeatedPtrFieldBackInsertIterator& operator=( const T* const ptr_to_value) { *field_->Add() = *ptr_to_value; return *this; } RepeatedPtrFieldBackInsertIterator& operator*() { return *this; } RepeatedPtrFieldBackInsertIterator& operator++() { return *this; } RepeatedPtrFieldBackInsertIterator& operator++(int /* unused */) { return *this; } private: RepeatedPtrField* field_; }; // A back inserter for RepeatedPtrFields that inserts by transfering ownership // of a pointer. template class AllocatedRepeatedPtrFieldBackInsertIterator : public std::iterator { public: explicit AllocatedRepeatedPtrFieldBackInsertIterator( RepeatedPtrField* const mutable_field) : field_(mutable_field) { } AllocatedRepeatedPtrFieldBackInsertIterator& operator=( T* const ptr_to_value) { field_->AddAllocated(ptr_to_value); return *this; } AllocatedRepeatedPtrFieldBackInsertIterator& operator*() { return *this; } AllocatedRepeatedPtrFieldBackInsertIterator& operator++() { return *this; } AllocatedRepeatedPtrFieldBackInsertIterator& operator++( int /* unused */) { return *this; } private: RepeatedPtrField* field_; }; } // namespace internal // Provides a back insert iterator for RepeatedField instances, // similar to std::back_inserter(). template internal::RepeatedFieldBackInsertIterator RepeatedFieldBackInserter(RepeatedField* const mutable_field) { return internal::RepeatedFieldBackInsertIterator(mutable_field); } // Provides a back insert iterator for RepeatedPtrField instances, // similar to std::back_inserter(). template internal::RepeatedPtrFieldBackInsertIterator RepeatedPtrFieldBackInserter(RepeatedPtrField* const mutable_field) { return internal::RepeatedPtrFieldBackInsertIterator(mutable_field); } // Special back insert iterator for RepeatedPtrField instances, just in // case someone wants to write generic template code that can access both // RepeatedFields and RepeatedPtrFields using a common name. template internal::RepeatedPtrFieldBackInsertIterator RepeatedFieldBackInserter(RepeatedPtrField* const mutable_field) { return internal::RepeatedPtrFieldBackInsertIterator(mutable_field); } // Provides a back insert iterator for RepeatedPtrField instances // similar to std::back_inserter() which transfers the ownership while // copying elements. template internal::AllocatedRepeatedPtrFieldBackInsertIterator AllocatedRepeatedPtrFieldBackInserter( RepeatedPtrField* const mutable_field) { return internal::AllocatedRepeatedPtrFieldBackInsertIterator( mutable_field); } } // namespace protobuf } // namespace google #endif // GOOGLE_PROTOBUF_REPEATED_FIELD_H__