| // 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) |
| // atenasio@google.com (Chris Atenasio) (ZigZag transform) |
| // wink@google.com (Wink Saville) (refactored from wire_format.h) |
| // Based on original Protocol Buffers design by |
| // Sanjay Ghemawat, Jeff Dean, and others. |
| // |
| // This header is logically internal, but is made public because it is used |
| // from protocol-compiler-generated code, which may reside in other components. |
| |
| #ifndef GOOGLE_PROTOBUF_WIRE_FORMAT_LITE_H__ |
| #define GOOGLE_PROTOBUF_WIRE_FORMAT_LITE_H__ |
| |
| #include <string> |
| #include <google/protobuf/stubs/common.h> |
| #include <google/protobuf/message_lite.h> |
| #include <google/protobuf/io/coded_stream.h> // for CodedOutputStream::Varint32Size |
| |
| namespace google { |
| |
| namespace protobuf { |
| template <typename T> class RepeatedField; // repeated_field.h |
| } |
| |
| namespace protobuf { |
| namespace internal { |
| |
| class StringPieceField; |
| |
| // This class is for internal use by the protocol buffer library and by |
| // protocol-complier-generated message classes. It must not be called |
| // directly by clients. |
| // |
| // This class contains helpers for implementing the binary protocol buffer |
| // wire format without the need for reflection. Use WireFormat when using |
| // reflection. |
| // |
| // This class is really a namespace that contains only static methods. |
| class LIBPROTOBUF_EXPORT WireFormatLite { |
| public: |
| |
| // ----------------------------------------------------------------- |
| // Helper constants and functions related to the format. These are |
| // mostly meant for internal and generated code to use. |
| |
| // The wire format is composed of a sequence of tag/value pairs, each |
| // of which contains the value of one field (or one element of a repeated |
| // field). Each tag is encoded as a varint. The lower bits of the tag |
| // identify its wire type, which specifies the format of the data to follow. |
| // The rest of the bits contain the field number. Each type of field (as |
| // declared by FieldDescriptor::Type, in descriptor.h) maps to one of |
| // these wire types. Immediately following each tag is the field's value, |
| // encoded in the format specified by the wire type. Because the tag |
| // identifies the encoding of this data, it is possible to skip |
| // unrecognized fields for forwards compatibility. |
| |
| enum WireType { |
| WIRETYPE_VARINT = 0, |
| WIRETYPE_FIXED64 = 1, |
| WIRETYPE_LENGTH_DELIMITED = 2, |
| WIRETYPE_START_GROUP = 3, |
| WIRETYPE_END_GROUP = 4, |
| WIRETYPE_FIXED32 = 5, |
| }; |
| |
| // Lite alternative to FieldDescriptor::Type. Must be kept in sync. |
| enum FieldType { |
| TYPE_DOUBLE = 1, |
| TYPE_FLOAT = 2, |
| TYPE_INT64 = 3, |
| TYPE_UINT64 = 4, |
| TYPE_INT32 = 5, |
| TYPE_FIXED64 = 6, |
| TYPE_FIXED32 = 7, |
| TYPE_BOOL = 8, |
| TYPE_STRING = 9, |
| TYPE_GROUP = 10, |
| TYPE_MESSAGE = 11, |
| TYPE_BYTES = 12, |
| TYPE_UINT32 = 13, |
| TYPE_ENUM = 14, |
| TYPE_SFIXED32 = 15, |
| TYPE_SFIXED64 = 16, |
| TYPE_SINT32 = 17, |
| TYPE_SINT64 = 18, |
| MAX_FIELD_TYPE = 18, |
| }; |
| |
| // Lite alternative to FieldDescriptor::CppType. Must be kept in sync. |
| enum CppType { |
| CPPTYPE_INT32 = 1, |
| CPPTYPE_INT64 = 2, |
| CPPTYPE_UINT32 = 3, |
| CPPTYPE_UINT64 = 4, |
| CPPTYPE_DOUBLE = 5, |
| CPPTYPE_FLOAT = 6, |
| CPPTYPE_BOOL = 7, |
| CPPTYPE_ENUM = 8, |
| CPPTYPE_STRING = 9, |
| CPPTYPE_MESSAGE = 10, |
| MAX_CPPTYPE = 10, |
| }; |
| |
| // Helper method to get the CppType for a particular Type. |
| static CppType FieldTypeToCppType(FieldType type); |
| |
| // Given a FieldSescriptor::Type return its WireType |
| static inline WireFormatLite::WireType WireTypeForFieldType( |
| WireFormatLite::FieldType type) { |
| return kWireTypeForFieldType[type]; |
| } |
| |
| // Number of bits in a tag which identify the wire type. |
| static const int kTagTypeBits = 3; |
| // Mask for those bits. |
| static const uint32 kTagTypeMask = (1 << kTagTypeBits) - 1; |
| |
| // Helper functions for encoding and decoding tags. (Inlined below and in |
| // _inl.h) |
| // |
| // This is different from MakeTag(field->number(), field->type()) in the case |
| // of packed repeated fields. |
| static uint32 MakeTag(int field_number, WireType type); |
| static WireType GetTagWireType(uint32 tag); |
| static int GetTagFieldNumber(uint32 tag); |
| |
| // Compute the byte size of a tag. For groups, this includes both the start |
| // and end tags. |
| static inline int TagSize(int field_number, WireFormatLite::FieldType type); |
| |
| // Skips a field value with the given tag. The input should start |
| // positioned immediately after the tag. Skipped values are simply discarded, |
| // not recorded anywhere. See WireFormat::SkipField() for a version that |
| // records to an UnknownFieldSet. |
| static bool SkipField(io::CodedInputStream* input, uint32 tag); |
| |
| // Skips a field value with the given tag. The input should start |
| // positioned immediately after the tag. Skipped values are recorded to a |
| // CodedOutputStream. |
| static bool SkipField(io::CodedInputStream* input, uint32 tag, |
| io::CodedOutputStream* output); |
| |
| // Reads and ignores a message from the input. Skipped values are simply |
| // discarded, not recorded anywhere. See WireFormat::SkipMessage() for a |
| // version that records to an UnknownFieldSet. |
| static bool SkipMessage(io::CodedInputStream* input); |
| |
| // Reads and ignores a message from the input. Skipped values are recorded |
| // to a CodedOutputStream. |
| static bool SkipMessage(io::CodedInputStream* input, |
| io::CodedOutputStream* output); |
| |
| // This macro does the same thing as WireFormatLite::MakeTag(), but the |
| // result is usable as a compile-time constant, which makes it usable |
| // as a switch case or a template input. WireFormatLite::MakeTag() is more |
| // type-safe, though, so prefer it if possible. |
| #define GOOGLE_PROTOBUF_WIRE_FORMAT_MAKE_TAG(FIELD_NUMBER, TYPE) \ |
| static_cast<uint32>( \ |
| ((FIELD_NUMBER) << ::google::protobuf::internal::WireFormatLite::kTagTypeBits) \ |
| | (TYPE)) |
| |
| // These are the tags for the old MessageSet format, which was defined as: |
| // message MessageSet { |
| // repeated group Item = 1 { |
| // required int32 type_id = 2; |
| // required string message = 3; |
| // } |
| // } |
| static const int kMessageSetItemNumber = 1; |
| static const int kMessageSetTypeIdNumber = 2; |
| static const int kMessageSetMessageNumber = 3; |
| static const int kMessageSetItemStartTag = |
| GOOGLE_PROTOBUF_WIRE_FORMAT_MAKE_TAG(kMessageSetItemNumber, |
| WireFormatLite::WIRETYPE_START_GROUP); |
| static const int kMessageSetItemEndTag = |
| GOOGLE_PROTOBUF_WIRE_FORMAT_MAKE_TAG(kMessageSetItemNumber, |
| WireFormatLite::WIRETYPE_END_GROUP); |
| static const int kMessageSetTypeIdTag = |
| GOOGLE_PROTOBUF_WIRE_FORMAT_MAKE_TAG(kMessageSetTypeIdNumber, |
| WireFormatLite::WIRETYPE_VARINT); |
| static const int kMessageSetMessageTag = |
| GOOGLE_PROTOBUF_WIRE_FORMAT_MAKE_TAG(kMessageSetMessageNumber, |
| WireFormatLite::WIRETYPE_LENGTH_DELIMITED); |
| |
| // Byte size of all tags of a MessageSet::Item combined. |
| static const int kMessageSetItemTagsSize; |
| |
| // Helper functions for converting between floats/doubles and IEEE-754 |
| // uint32s/uint64s so that they can be written. (Assumes your platform |
| // uses IEEE-754 floats.) |
| static uint32 EncodeFloat(float value); |
| static float DecodeFloat(uint32 value); |
| static uint64 EncodeDouble(double value); |
| static double DecodeDouble(uint64 value); |
| |
| // Helper functions for mapping signed integers to unsigned integers in |
| // such a way that numbers with small magnitudes will encode to smaller |
| // varints. If you simply static_cast a negative number to an unsigned |
| // number and varint-encode it, it will always take 10 bytes, defeating |
| // the purpose of varint. So, for the "sint32" and "sint64" field types, |
| // we ZigZag-encode the values. |
| static uint32 ZigZagEncode32(int32 n); |
| static int32 ZigZagDecode32(uint32 n); |
| static uint64 ZigZagEncode64(int64 n); |
| static int64 ZigZagDecode64(uint64 n); |
| |
| // ================================================================= |
| // Methods for reading/writing individual field. The implementations |
| // of these methods are defined in wire_format_lite_inl.h; you must #include |
| // that file to use these. |
| |
| // Avoid ugly line wrapping |
| #define input io::CodedInputStream* input_arg |
| #define output io::CodedOutputStream* output_arg |
| #define field_number int field_number_arg |
| #define INL GOOGLE_ATTRIBUTE_ALWAYS_INLINE |
| |
| // Read fields, not including tags. The assumption is that you already |
| // read the tag to determine what field to read. |
| |
| // For primitive fields, we just use a templatized routine parameterized by |
| // the represented type and the FieldType. These are specialized with the |
| // appropriate definition for each declared type. |
| template <typename CType, enum FieldType DeclaredType> INL |
| static bool ReadPrimitive(input, CType* value); |
| |
| // Reads repeated primitive values, with optimizations for repeats. |
| // tag_size and tag should both be compile-time constants provided by the |
| // protocol compiler. |
| template <typename CType, enum FieldType DeclaredType> INL |
| static bool ReadRepeatedPrimitive(int tag_size, |
| uint32 tag, |
| input, |
| RepeatedField<CType>* value); |
| |
| // Identical to ReadRepeatedPrimitive, except will not inline the |
| // implementation. |
| template <typename CType, enum FieldType DeclaredType> |
| static bool ReadRepeatedPrimitiveNoInline(int tag_size, |
| uint32 tag, |
| input, |
| RepeatedField<CType>* value); |
| |
| // Reads a primitive value directly from the provided buffer. It returns a |
| // pointer past the segment of data that was read. |
| // |
| // This is only implemented for the types with fixed wire size, e.g. |
| // float, double, and the (s)fixed* types. |
| template <typename CType, enum FieldType DeclaredType> INL |
| static const uint8* ReadPrimitiveFromArray(const uint8* buffer, CType* value); |
| |
| // Reads a primitive packed field. |
| // |
| // This is only implemented for packable types. |
| template <typename CType, enum FieldType DeclaredType> INL |
| static bool ReadPackedPrimitive(input, RepeatedField<CType>* value); |
| |
| // Identical to ReadPackedPrimitive, except will not inline the |
| // implementation. |
| template <typename CType, enum FieldType DeclaredType> |
| static bool ReadPackedPrimitiveNoInline(input, RepeatedField<CType>* value); |
| |
| // Read a packed enum field. If the is_valid function is not NULL, values for |
| // which is_valid(value) returns false are silently dropped. |
| static bool ReadPackedEnumNoInline(input, |
| bool (*is_valid)(int), |
| RepeatedField<int>* values); |
| |
| // Read a packed enum field. If the is_valid function is not NULL, values for |
| // which is_valid(value) returns false are appended to unknown_fields_stream. |
| static bool ReadPackedEnumPreserveUnknowns( |
| input, |
| field_number, |
| bool (*is_valid)(int), |
| io::CodedOutputStream* unknown_fields_stream, |
| RepeatedField<int>* values); |
| |
| // Read a string. ReadString(..., string* value) requires an existing string. |
| static inline bool ReadString(input, string* value); |
| // ReadString(..., string** p) is internal-only, and should only be called |
| // from generated code. It starts by setting *p to "new string" |
| // if *p == &GetEmptyStringAlreadyInited(). It then invokes |
| // ReadString(input, *p). This is useful for reducing code size. |
| static inline bool ReadString(input, string** p); |
| // Analogous to ReadString(). |
| static bool ReadBytes(input, string* value); |
| static bool ReadBytes(input, string** p); |
| |
| |
| enum Operation { |
| PARSE = 0, |
| SERIALIZE = 1, |
| }; |
| |
| // Returns true if the data is valid UTF-8. |
| static bool VerifyUtf8String(const char* data, int size, |
| Operation op, |
| const char* field_name); |
| |
| static inline bool ReadGroup (field_number, input, MessageLite* value); |
| static inline bool ReadMessage(input, MessageLite* value); |
| |
| // Like above, but de-virtualize the call to MergePartialFromCodedStream(). |
| // The pointer must point at an instance of MessageType, *not* a subclass (or |
| // the subclass must not override MergePartialFromCodedStream()). |
| template<typename MessageType> |
| static inline bool ReadGroupNoVirtual(field_number, input, |
| MessageType* value); |
| template<typename MessageType> |
| static inline bool ReadMessageNoVirtual(input, MessageType* value); |
| |
| // The same, but do not modify input's recursion depth. This is useful |
| // when reading a bunch of groups or messages in a loop, because then the |
| // recursion depth can be incremented before the loop and decremented after. |
| template<typename MessageType> |
| static inline bool ReadGroupNoVirtualNoRecursionDepth(field_number, input, |
| MessageType* value); |
| |
| template<typename MessageType> |
| static inline bool ReadMessageNoVirtualNoRecursionDepth(input, |
| MessageType* value); |
| |
| // Write a tag. The Write*() functions typically include the tag, so |
| // normally there's no need to call this unless using the Write*NoTag() |
| // variants. |
| INL static void WriteTag(field_number, WireType type, output); |
| |
| // Write fields, without tags. |
| INL static void WriteInt32NoTag (int32 value, output); |
| INL static void WriteInt64NoTag (int64 value, output); |
| INL static void WriteUInt32NoTag (uint32 value, output); |
| INL static void WriteUInt64NoTag (uint64 value, output); |
| INL static void WriteSInt32NoTag (int32 value, output); |
| INL static void WriteSInt64NoTag (int64 value, output); |
| INL static void WriteFixed32NoTag (uint32 value, output); |
| INL static void WriteFixed64NoTag (uint64 value, output); |
| INL static void WriteSFixed32NoTag(int32 value, output); |
| INL static void WriteSFixed64NoTag(int64 value, output); |
| INL static void WriteFloatNoTag (float value, output); |
| INL static void WriteDoubleNoTag (double value, output); |
| INL static void WriteBoolNoTag (bool value, output); |
| INL static void WriteEnumNoTag (int value, output); |
| |
| // Write fields, including tags. |
| static void WriteInt32 (field_number, int32 value, output); |
| static void WriteInt64 (field_number, int64 value, output); |
| static void WriteUInt32 (field_number, uint32 value, output); |
| static void WriteUInt64 (field_number, uint64 value, output); |
| static void WriteSInt32 (field_number, int32 value, output); |
| static void WriteSInt64 (field_number, int64 value, output); |
| static void WriteFixed32 (field_number, uint32 value, output); |
| static void WriteFixed64 (field_number, uint64 value, output); |
| static void WriteSFixed32(field_number, int32 value, output); |
| static void WriteSFixed64(field_number, int64 value, output); |
| static void WriteFloat (field_number, float value, output); |
| static void WriteDouble (field_number, double value, output); |
| static void WriteBool (field_number, bool value, output); |
| static void WriteEnum (field_number, int value, output); |
| |
| static void WriteString(field_number, const string& value, output); |
| static void WriteBytes (field_number, const string& value, output); |
| static void WriteStringMaybeAliased( |
| field_number, const string& value, output); |
| static void WriteBytesMaybeAliased( |
| field_number, const string& value, output); |
| |
| static void WriteGroup( |
| field_number, const MessageLite& value, output); |
| static void WriteMessage( |
| field_number, const MessageLite& value, output); |
| // Like above, but these will check if the output stream has enough |
| // space to write directly to a flat array. |
| static void WriteGroupMaybeToArray( |
| field_number, const MessageLite& value, output); |
| static void WriteMessageMaybeToArray( |
| field_number, const MessageLite& value, output); |
| |
| // Like above, but de-virtualize the call to SerializeWithCachedSizes(). The |
| // pointer must point at an instance of MessageType, *not* a subclass (or |
| // the subclass must not override SerializeWithCachedSizes()). |
| template<typename MessageType> |
| static inline void WriteGroupNoVirtual( |
| field_number, const MessageType& value, output); |
| template<typename MessageType> |
| static inline void WriteMessageNoVirtual( |
| field_number, const MessageType& value, output); |
| |
| #undef output |
| #define output uint8* target |
| |
| // Like above, but use only *ToArray methods of CodedOutputStream. |
| INL static uint8* WriteTagToArray(field_number, WireType type, output); |
| |
| // Write fields, without tags. |
| INL static uint8* WriteInt32NoTagToArray (int32 value, output); |
| INL static uint8* WriteInt64NoTagToArray (int64 value, output); |
| INL static uint8* WriteUInt32NoTagToArray (uint32 value, output); |
| INL static uint8* WriteUInt64NoTagToArray (uint64 value, output); |
| INL static uint8* WriteSInt32NoTagToArray (int32 value, output); |
| INL static uint8* WriteSInt64NoTagToArray (int64 value, output); |
| INL static uint8* WriteFixed32NoTagToArray (uint32 value, output); |
| INL static uint8* WriteFixed64NoTagToArray (uint64 value, output); |
| INL static uint8* WriteSFixed32NoTagToArray(int32 value, output); |
| INL static uint8* WriteSFixed64NoTagToArray(int64 value, output); |
| INL static uint8* WriteFloatNoTagToArray (float value, output); |
| INL static uint8* WriteDoubleNoTagToArray (double value, output); |
| INL static uint8* WriteBoolNoTagToArray (bool value, output); |
| INL static uint8* WriteEnumNoTagToArray (int value, output); |
| |
| // Write fields, including tags. |
| INL static uint8* WriteInt32ToArray(field_number, int32 value, output); |
| INL static uint8* WriteInt64ToArray(field_number, int64 value, output); |
| INL static uint8* WriteUInt32ToArray(field_number, uint32 value, output); |
| INL static uint8* WriteUInt64ToArray(field_number, uint64 value, output); |
| INL static uint8* WriteSInt32ToArray(field_number, int32 value, output); |
| INL static uint8* WriteSInt64ToArray(field_number, int64 value, output); |
| INL static uint8* WriteFixed32ToArray(field_number, uint32 value, output); |
| INL static uint8* WriteFixed64ToArray(field_number, uint64 value, output); |
| INL static uint8* WriteSFixed32ToArray(field_number, int32 value, output); |
| INL static uint8* WriteSFixed64ToArray(field_number, int64 value, output); |
| INL static uint8* WriteFloatToArray(field_number, float value, output); |
| INL static uint8* WriteDoubleToArray(field_number, double value, output); |
| INL static uint8* WriteBoolToArray(field_number, bool value, output); |
| INL static uint8* WriteEnumToArray(field_number, int value, output); |
| |
| INL static uint8* WriteStringToArray( |
| field_number, const string& value, output); |
| INL static uint8* WriteBytesToArray( |
| field_number, const string& value, output); |
| |
| INL static uint8* WriteGroupToArray( |
| field_number, const MessageLite& value, output); |
| INL static uint8* WriteMessageToArray( |
| field_number, const MessageLite& value, output); |
| |
| // Like above, but de-virtualize the call to SerializeWithCachedSizes(). The |
| // pointer must point at an instance of MessageType, *not* a subclass (or |
| // the subclass must not override SerializeWithCachedSizes()). |
| template<typename MessageType> |
| INL static uint8* WriteGroupNoVirtualToArray( |
| field_number, const MessageType& value, output); |
| template<typename MessageType> |
| INL static uint8* WriteMessageNoVirtualToArray( |
| field_number, const MessageType& value, output); |
| |
| #undef output |
| #undef input |
| #undef INL |
| |
| #undef field_number |
| |
| // Compute the byte size of a field. The XxSize() functions do NOT include |
| // the tag, so you must also call TagSize(). (This is because, for repeated |
| // fields, you should only call TagSize() once and multiply it by the element |
| // count, but you may have to call XxSize() for each individual element.) |
| static inline int Int32Size ( int32 value); |
| static inline int Int64Size ( int64 value); |
| static inline int UInt32Size (uint32 value); |
| static inline int UInt64Size (uint64 value); |
| static inline int SInt32Size ( int32 value); |
| static inline int SInt64Size ( int64 value); |
| static inline int EnumSize ( int value); |
| |
| // These types always have the same size. |
| static const int kFixed32Size = 4; |
| static const int kFixed64Size = 8; |
| static const int kSFixed32Size = 4; |
| static const int kSFixed64Size = 8; |
| static const int kFloatSize = 4; |
| static const int kDoubleSize = 8; |
| static const int kBoolSize = 1; |
| |
| static inline int StringSize(const string& value); |
| static inline int BytesSize (const string& value); |
| |
| static inline int GroupSize (const MessageLite& value); |
| static inline int MessageSize(const MessageLite& value); |
| |
| // Like above, but de-virtualize the call to ByteSize(). The |
| // pointer must point at an instance of MessageType, *not* a subclass (or |
| // the subclass must not override ByteSize()). |
| template<typename MessageType> |
| static inline int GroupSizeNoVirtual (const MessageType& value); |
| template<typename MessageType> |
| static inline int MessageSizeNoVirtual(const MessageType& value); |
| |
| // Given the length of data, calculate the byte size of the data on the |
| // wire if we encode the data as a length delimited field. |
| static inline int LengthDelimitedSize(int length); |
| |
| private: |
| // A helper method for the repeated primitive reader. This method has |
| // optimizations for primitive types that have fixed size on the wire, and |
| // can be read using potentially faster paths. |
| template <typename CType, enum FieldType DeclaredType> GOOGLE_ATTRIBUTE_ALWAYS_INLINE |
| static bool ReadRepeatedFixedSizePrimitive( |
| int tag_size, |
| uint32 tag, |
| google::protobuf::io::CodedInputStream* input, |
| RepeatedField<CType>* value); |
| |
| // Like ReadRepeatedFixedSizePrimitive but for packed primitive fields. |
| template <typename CType, enum FieldType DeclaredType> GOOGLE_ATTRIBUTE_ALWAYS_INLINE |
| static bool ReadPackedFixedSizePrimitive(google::protobuf::io::CodedInputStream* input, |
| RepeatedField<CType>* value); |
| |
| static const CppType kFieldTypeToCppTypeMap[]; |
| static const WireFormatLite::WireType kWireTypeForFieldType[]; |
| |
| GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(WireFormatLite); |
| }; |
| |
| // A class which deals with unknown values. The default implementation just |
| // discards them. WireFormat defines a subclass which writes to an |
| // UnknownFieldSet. This class is used by ExtensionSet::ParseField(), since |
| // ExtensionSet is part of the lite library but UnknownFieldSet is not. |
| class LIBPROTOBUF_EXPORT FieldSkipper { |
| public: |
| FieldSkipper() {} |
| virtual ~FieldSkipper() {} |
| |
| // Skip a field whose tag has already been consumed. |
| virtual bool SkipField(io::CodedInputStream* input, uint32 tag); |
| |
| // Skip an entire message or group, up to an end-group tag (which is consumed) |
| // or end-of-stream. |
| virtual bool SkipMessage(io::CodedInputStream* input); |
| |
| // Deal with an already-parsed unrecognized enum value. The default |
| // implementation does nothing, but the UnknownFieldSet-based implementation |
| // saves it as an unknown varint. |
| virtual void SkipUnknownEnum(int field_number, int value); |
| }; |
| |
| // Subclass of FieldSkipper which saves skipped fields to a CodedOutputStream. |
| |
| class LIBPROTOBUF_EXPORT CodedOutputStreamFieldSkipper : public FieldSkipper { |
| public: |
| explicit CodedOutputStreamFieldSkipper(io::CodedOutputStream* unknown_fields) |
| : unknown_fields_(unknown_fields) {} |
| virtual ~CodedOutputStreamFieldSkipper() {} |
| |
| // implements FieldSkipper ----------------------------------------- |
| virtual bool SkipField(io::CodedInputStream* input, uint32 tag); |
| virtual bool SkipMessage(io::CodedInputStream* input); |
| virtual void SkipUnknownEnum(int field_number, int value); |
| |
| protected: |
| io::CodedOutputStream* unknown_fields_; |
| }; |
| |
| |
| // inline methods ==================================================== |
| |
| inline WireFormatLite::CppType |
| WireFormatLite::FieldTypeToCppType(FieldType type) { |
| return kFieldTypeToCppTypeMap[type]; |
| } |
| |
| inline uint32 WireFormatLite::MakeTag(int field_number, WireType type) { |
| return GOOGLE_PROTOBUF_WIRE_FORMAT_MAKE_TAG(field_number, type); |
| } |
| |
| inline WireFormatLite::WireType WireFormatLite::GetTagWireType(uint32 tag) { |
| return static_cast<WireType>(tag & kTagTypeMask); |
| } |
| |
| inline int WireFormatLite::GetTagFieldNumber(uint32 tag) { |
| return static_cast<int>(tag >> kTagTypeBits); |
| } |
| |
| inline int WireFormatLite::TagSize(int field_number, |
| WireFormatLite::FieldType type) { |
| int result = io::CodedOutputStream::VarintSize32( |
| field_number << kTagTypeBits); |
| if (type == TYPE_GROUP) { |
| // Groups have both a start and an end tag. |
| return result * 2; |
| } else { |
| return result; |
| } |
| } |
| |
| inline uint32 WireFormatLite::EncodeFloat(float value) { |
| union {float f; uint32 i;}; |
| f = value; |
| return i; |
| } |
| |
| inline float WireFormatLite::DecodeFloat(uint32 value) { |
| union {float f; uint32 i;}; |
| i = value; |
| return f; |
| } |
| |
| inline uint64 WireFormatLite::EncodeDouble(double value) { |
| union {double f; uint64 i;}; |
| f = value; |
| return i; |
| } |
| |
| inline double WireFormatLite::DecodeDouble(uint64 value) { |
| union {double f; uint64 i;}; |
| i = value; |
| return f; |
| } |
| |
| // ZigZag Transform: Encodes signed integers so that they can be |
| // effectively used with varint encoding. |
| // |
| // varint operates on unsigned integers, encoding smaller numbers into |
| // fewer bytes. If you try to use it on a signed integer, it will treat |
| // this number as a very large unsigned integer, which means that even |
| // small signed numbers like -1 will take the maximum number of bytes |
| // (10) to encode. ZigZagEncode() maps signed integers to unsigned |
| // in such a way that those with a small absolute value will have smaller |
| // encoded values, making them appropriate for encoding using varint. |
| // |
| // int32 -> uint32 |
| // ------------------------- |
| // 0 -> 0 |
| // -1 -> 1 |
| // 1 -> 2 |
| // -2 -> 3 |
| // ... -> ... |
| // 2147483647 -> 4294967294 |
| // -2147483648 -> 4294967295 |
| // |
| // >> encode >> |
| // << decode << |
| |
| inline uint32 WireFormatLite::ZigZagEncode32(int32 n) { |
| // Note: the right-shift must be arithmetic |
| return (static_cast<uint32>(n) << 1) ^ (n >> 31); |
| } |
| |
| inline int32 WireFormatLite::ZigZagDecode32(uint32 n) { |
| return (n >> 1) ^ -static_cast<int32>(n & 1); |
| } |
| |
| inline uint64 WireFormatLite::ZigZagEncode64(int64 n) { |
| // Note: the right-shift must be arithmetic |
| return (static_cast<uint64>(n) << 1) ^ (n >> 63); |
| } |
| |
| inline int64 WireFormatLite::ZigZagDecode64(uint64 n) { |
| return (n >> 1) ^ -static_cast<int64>(n & 1); |
| } |
| |
| // String is for UTF-8 text only, but, even so, ReadString() can simply |
| // call ReadBytes(). |
| |
| inline bool WireFormatLite::ReadString(io::CodedInputStream* input, |
| string* value) { |
| return ReadBytes(input, value); |
| } |
| |
| inline bool WireFormatLite::ReadString(io::CodedInputStream* input, |
| string** p) { |
| return ReadBytes(input, p); |
| } |
| |
| } // namespace internal |
| } // namespace protobuf |
| |
| } // namespace google |
| #endif // GOOGLE_PROTOBUF_WIRE_FORMAT_LITE_H__ |