lib/cpp/src/protocol/TCompactProtocol.tcc - packaging/sources/thrift - Gitiles

 /*
  * Licensed to the Apache Software Foundation (ASF) under one
  * or more contributor license agreements. See the NOTICE file
  * distributed with this work for additional information
  * regarding copyright ownership. The ASF licenses this file
  * to you under the Apache License, Version 2.0 (the
  * "License"); you may not use this file except in compliance
  * with the License. You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing,
  * software distributed under the License is distributed on an
  * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
  * KIND, either express or implied. See the License for the
  * specific language governing permissions and limitations
  * under the License.
  */
 #ifndef _THRIFT_PROTOCOL_TCOMPACTPROTOCOL_TCC_
 #define _THRIFT_PROTOCOL_TCOMPACTPROTOCOL_TCC_ 1

 #include <limits>

 /*
  * TCompactProtocol::i*ToZigzag depend on the fact that the right shift
  * operator on a signed integer is an arithmetic (sign-extending) shift.
  * If this is not the case, the current implementation will not work.
  * If anyone encounters this error, we can try to figure out the best
  * way to implement an arithmetic right shift on their platform.
  */
 #if !defined(SIGNED_RIGHT_SHIFT_IS) || !defined(ARITHMETIC_RIGHT_SHIFT)
 # error "Unable to determine the behavior of a signed right shift"
 #endif
 #if SIGNED_RIGHT_SHIFT_IS != ARITHMETIC_RIGHT_SHIFT
 # error "TCompactProtocol currently only works if a signed right shift is arithmetic"
 #endif

 #ifdef __GNUC__
 #define UNLIKELY(val) (__builtin_expect((val), 0))
 #else
 #define UNLIKELY(val) (val)
 #endif

 namespace apache { namespace thrift { namespace protocol {

 namespace detail { namespace compact {

 enum Types {
   CT_STOP           = 0x00,
   CT_BOOLEAN_TRUE   = 0x01,
   CT_BOOLEAN_FALSE  = 0x02,
   CT_BYTE           = 0x03,
   CT_I16            = 0x04,
   CT_I32            = 0x05,
   CT_I64            = 0x06,
   CT_DOUBLE         = 0x07,
   CT_BINARY         = 0x08,
   CT_LIST           = 0x09,
   CT_SET            = 0x0A,
   CT_MAP            = 0x0B,
   CT_STRUCT         = 0x0C
 };

 const int8_t TTypeToCType[16] = {
   CT_STOP, // T_STOP
   0, // unused
   CT_BOOLEAN_TRUE, // T_BOOL
   CT_BYTE, // T_BYTE
   CT_DOUBLE, // T_DOUBLE
   0, // unused
   CT_I16, // T_I16
   0, // unused
   CT_I32, // T_I32
   0, // unused
   CT_I64, // T_I64
   CT_BINARY, // T_STRING
   CT_STRUCT, // T_STRUCT
   CT_MAP, // T_MAP
   CT_SET, // T_SET
   CT_LIST, // T_LIST
 };

 }} // end detail::compact namespace


 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeMessageBegin(
     const std::string& name,
     const TMessageType messageType,
     const int32_t seqid) {
   uint32_t wsize = 0;
   wsize += writeByte(PROTOCOL_ID);
   wsize += writeByte((VERSION_N & VERSION_MASK) | (((int32_t)messageType << TYPE_SHIFT_AMOUNT) & TYPE_MASK));
   wsize += writeVarint32(seqid);
   wsize += writeString(name);
   return wsize;
 }

 /**
  * Write a field header containing the field id and field type. If the
  * difference between the current field id and the last one is small (< 15),
  * then the field id will be encoded in the 4 MSB as a delta. Otherwise, the
  * field id will follow the type header as a zigzag varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeFieldBegin(const char* name,
                                                         const TType fieldType,
                                                         const int16_t fieldId) {
   if (fieldType == T_BOOL) {
     booleanField_.name = name;
     booleanField_.fieldType = fieldType;
     booleanField_.fieldId = fieldId;
   } else {
     return writeFieldBeginInternal(name, fieldType, fieldId, -1);
   }
   return 0;
 }

 /**
  * Write the STOP symbol so we know there are no more fields in this struct.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeFieldStop() {
   return writeByte(T_STOP);
 }

 /**
  * Write a struct begin. This doesn't actually put anything on the wire. We
  * use it as an opportunity to put special placeholder markers on the field
  * stack so we can get the field id deltas correct.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeStructBegin(const char* name) {
   (void) name;
   lastField_.push(lastFieldId_);
   lastFieldId_ = 0;
   return 0;
 }

 /**
  * Write a struct end. This doesn't actually put anything on the wire. We use
  * this as an opportunity to pop the last field from the current struct off
  * of the field stack.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeStructEnd() {
   lastFieldId_ = lastField_.top();
   lastField_.pop();
   return 0;
 }

 /**
  * Write a List header.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeListBegin(const TType elemType,
                                                        const uint32_t size) {
   return writeCollectionBegin(elemType, size);
 }

 /**
  * Write a set header.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeSetBegin(const TType elemType,
                                                       const uint32_t size) {
   return writeCollectionBegin(elemType, size);
 }

 /**
  * Write a map header. If the map is empty, omit the key and value type
  * headers, as we don't need any additional information to skip it.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeMapBegin(const TType keyType,
                                                       const TType valType,
                                                       const uint32_t size) {
   uint32_t wsize = 0;

   if (size == 0) {
     wsize += writeByte(0);
   } else {
     wsize += writeVarint32(size);
     wsize += writeByte(getCompactType(keyType) << 4 | getCompactType(valType));
   }
   return wsize;
 }

 /**
  * Write a boolean value. Potentially, this could be a boolean field, in
  * which case the field header info isn't written yet. If so, decide what the
  * right type header is for the value and then write the field header.
  * Otherwise, write a single byte.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeBool(const bool value) {
   uint32_t wsize = 0;

   if (booleanField_.name != NULL) {
     // we haven't written the field header yet
     wsize += writeFieldBeginInternal(booleanField_.name,
                                      booleanField_.fieldType,
                                      booleanField_.fieldId,
                                      value ? detail::compact::CT_BOOLEAN_TRUE :
                                      detail::compact::CT_BOOLEAN_FALSE);
     booleanField_.name = NULL;
   } else {
     // we're not part of a field, so just write the value
     wsize += writeByte(value ? detail::compact::CT_BOOLEAN_TRUE :
                        detail::compact::CT_BOOLEAN_FALSE);
   }
   return wsize;
 }

 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeByte(const int8_t byte) {
   trans_->write((uint8_t*)&byte, 1);
   return 1;
 }

 /**
  * Write an i16 as a zigzag varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeI16(const int16_t i16) {
   return writeVarint32(i32ToZigzag(i16));
 }

 /**
  * Write an i32 as a zigzag varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeI32(const int32_t i32) {
   return writeVarint32(i32ToZigzag(i32));
 }

 /**
  * Write an i64 as a zigzag varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeI64(const int64_t i64) {
   return writeVarint64(i64ToZigzag(i64));
 }

 /**
  * Write a double to the wire as 8 bytes.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeDouble(const double dub) {
   BOOST_STATIC_ASSERT(sizeof(double) == sizeof(uint64_t));
   BOOST_STATIC_ASSERT(std::numeric_limits<double>::is_iec559);

   uint64_t bits = bitwise_cast<uint64_t>(dub);
   bits = htolell(bits);
   trans_->write((uint8_t*)&bits, 8);
   return 8;
 }

 /**
  * Write a string to the wire with a varint size preceeding.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeString(const std::string& str) {
   return writeBinary(str);
 }

 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeBinary(const std::string& str) {
   uint32_t ssize = str.size();
   uint32_t wsize = writeVarint32(ssize) + ssize;
   trans_->write((uint8_t*)str.data(), ssize);
   return wsize;
 }

 //
 // Internal Writing methods
 //

 /**
  * The workhorse of writeFieldBegin. It has the option of doing a
  * 'type override' of the type header. This is used specifically in the
  * boolean field case.
  */
 template <class Transport_>
 int32_t TCompactProtocolT<Transport_>::writeFieldBeginInternal(
     const char* name,
     const TType fieldType,
     const int16_t fieldId,
     int8_t typeOverride) {
   (void) name;
   uint32_t wsize = 0;

   // if there's a type override, use that.
   int8_t typeToWrite = (typeOverride == -1 ? getCompactType(fieldType) : typeOverride);

   // check if we can use delta encoding for the field id
   if (fieldId > lastFieldId_ && fieldId - lastFieldId_ <= 15) {
     // write them together
     wsize += writeByte((fieldId - lastFieldId_) << 4 | typeToWrite);
   } else {
     // write them separate
     wsize += writeByte(typeToWrite);
     wsize += writeI16(fieldId);
   }

   lastFieldId_ = fieldId;
   return wsize;
 }

 /**
  * Abstract method for writing the start of lists and sets. List and sets on
  * the wire differ only by the type indicator.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeCollectionBegin(int8_t elemType,
                                                              int32_t size) {
   uint32_t wsize = 0;
   if (size <= 14) {
     wsize += writeByte(size << 4 | getCompactType(elemType));
   } else {
     wsize += writeByte(0xf0 | getCompactType(elemType));
     wsize += writeVarint32(size);
   }
   return wsize;
 }

 /**
  * Write an i32 as a varint. Results in 1-5 bytes on the wire.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeVarint32(uint32_t n) {
   uint8_t buf[5];
   uint32_t wsize = 0;

   while (true) {
     if ((n & ~0x7F) == 0) {
       buf[wsize++] = (int8_t)n;
       break;
     } else {
       buf[wsize++] = (int8_t)((n & 0x7F) | 0x80);
       n >>= 7;
     }
   }
   trans_->write(buf, wsize);
   return wsize;
 }

 /**
  * Write an i64 as a varint. Results in 1-10 bytes on the wire.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::writeVarint64(uint64_t n) {
   uint8_t buf[10];
   uint32_t wsize = 0;

   while (true) {
     if ((n & ~0x7FL) == 0) {
       buf[wsize++] = (int8_t)n;
       break;
     } else {
       buf[wsize++] = (int8_t)((n & 0x7F) | 0x80);
       n >>= 7;
     }
   }
   trans_->write(buf, wsize);
   return wsize;
 }

 /**
  * Convert l into a zigzag long. This allows negative numbers to be
  * represented compactly as a varint.
  */
 template <class Transport_>
 uint64_t TCompactProtocolT<Transport_>::i64ToZigzag(const int64_t l) {
   return (l << 1) ^ (l >> 63);
 }

 /**
  * Convert n into a zigzag int. This allows negative numbers to be
  * represented compactly as a varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::i32ToZigzag(const int32_t n) {
   return (n << 1) ^ (n >> 31);
 }

 /**
  * Given a TType value, find the appropriate detail::compact::Types value
  */
 template <class Transport_>
 int8_t TCompactProtocolT<Transport_>::getCompactType(int8_t ttype) {
   return detail::compact::TTypeToCType[ttype];
 }

 //
 // Reading Methods
 //

 /**
  * Read a message header.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readMessageBegin(
     std::string& name,
     TMessageType& messageType,
     int32_t& seqid) {
   uint32_t rsize = 0;
   int8_t protocolId;
   int8_t versionAndType;
   int8_t version;

   rsize += readByte(protocolId);
   if (protocolId != PROTOCOL_ID) {
     throw TProtocolException(TProtocolException::BAD_VERSION, "Bad protocol identifier");
   }

   rsize += readByte(versionAndType);
   version = (int8_t)(versionAndType & VERSION_MASK);
   if (version != VERSION_N) {
     throw TProtocolException(TProtocolException::BAD_VERSION, "Bad protocol version");
   }

   messageType = (TMessageType)((versionAndType >> TYPE_SHIFT_AMOUNT) & 0x03);
   rsize += readVarint32(seqid);
   rsize += readString(name);

   return rsize;
 }

 /**
  * Read a struct begin. There's nothing on the wire for this, but it is our
  * opportunity to push a new struct begin marker on the field stack.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readStructBegin(std::string& name) {
   name = "";
   lastField_.push(lastFieldId_);
   lastFieldId_ = 0;
   return 0;
 }

 /**
  * Doesn't actually consume any wire data, just removes the last field for
  * this struct from the field stack.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readStructEnd() {
   lastFieldId_ = lastField_.top();
   lastField_.pop();
   return 0;
 }

 /**
  * Read a field header off the wire.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readFieldBegin(std::string& name,
                                                        TType& fieldType,
                                                        int16_t& fieldId) {
   (void) name;
   uint32_t rsize = 0;
   int8_t byte;
   int8_t type;

   rsize += readByte(byte);
   type = (byte & 0x0f);

   // if it's a stop, then we can return immediately, as the struct is over.
   if (type == T_STOP) {
     fieldType = T_STOP;
     fieldId = 0;
     return rsize;
   }

   // mask off the 4 MSB of the type header. it could contain a field id delta.
   int16_t modifier = (int16_t)(((uint8_t)byte & 0xf0) >> 4);
   if (modifier == 0) {
     // not a delta, look ahead for the zigzag varint field id.
     rsize += readI16(fieldId);
   } else {
     fieldId = (int16_t)(lastFieldId_ + modifier);
   }
   fieldType = getTType(type);

   // if this happens to be a boolean field, the value is encoded in the type
   if (type == detail::compact::CT_BOOLEAN_TRUE ||
       type == detail::compact::CT_BOOLEAN_FALSE) {
     // save the boolean value in a special instance variable.
     boolValue_.hasBoolValue = true;
     boolValue_.boolValue =
       (type == detail::compact::CT_BOOLEAN_TRUE ? true : false);
   }

   // push the new field onto the field stack so we can keep the deltas going.
   lastFieldId_ = fieldId;
   return rsize;
 }

 /**
  * Read a map header off the wire. If the size is zero, skip reading the key
  * and value type. This means that 0-length maps will yield TMaps without the
  * "correct" types.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readMapBegin(TType& keyType,
                                                      TType& valType,
                                                      uint32_t& size) {
   uint32_t rsize = 0;
   int8_t kvType = 0;
   int32_t msize = 0;

   rsize += readVarint32(msize);
   if (msize != 0)
     rsize += readByte(kvType);

   if (msize < 0) {
     throw TProtocolException(TProtocolException::NEGATIVE_SIZE);
   } else if (container_limit_ && msize > container_limit_) {
     throw TProtocolException(TProtocolException::SIZE_LIMIT);
   }

   keyType = getTType((int8_t)((uint8_t)kvType >> 4));
   valType = getTType((int8_t)((uint8_t)kvType & 0xf));
   size = (uint32_t)msize;

   return rsize;
 }

 /**
  * Read a list header off the wire. If the list size is 0-14, the size will
  * be packed into the element type header. If it's a longer list, the 4 MSB
  * of the element type header will be 0xF, and a varint will follow with the
  * true size.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readListBegin(TType& elemType,
                                                       uint32_t& size) {
   int8_t size_and_type;
   uint32_t rsize = 0;
   int32_t lsize;

   rsize += readByte(size_and_type);

   lsize = ((uint8_t)size_and_type >> 4) & 0x0f;
   if (lsize == 15) {
     rsize += readVarint32(lsize);
   }

   if (lsize < 0) {
     throw TProtocolException(TProtocolException::NEGATIVE_SIZE);
   } else if (container_limit_ && lsize > container_limit_) {
     throw TProtocolException(TProtocolException::SIZE_LIMIT);
   }

   elemType = getTType((int8_t)(size_and_type & 0x0f));
   size = (uint32_t)lsize;

   return rsize;
 }

 /**
  * Read a set header off the wire. If the set size is 0-14, the size will
  * be packed into the element type header. If it's a longer set, the 4 MSB
  * of the element type header will be 0xF, and a varint will follow with the
  * true size.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readSetBegin(TType& elemType,
                                                      uint32_t& size) {
   return readListBegin(elemType, size);
 }

 /**
  * Read a boolean off the wire. If this is a boolean field, the value should
  * already have been read during readFieldBegin, so we'll just consume the
  * pre-stored value. Otherwise, read a byte.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readBool(bool& value) {
   if (boolValue_.hasBoolValue == true) {
     value = boolValue_.boolValue;
     boolValue_.hasBoolValue = false;
     return 0;
   } else {
     int8_t val;
     readByte(val);
     value = (val == detail::compact::CT_BOOLEAN_TRUE);
     return 1;
   }
 }

 /**
  * Read a single byte off the wire. Nothing interesting here.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readByte(int8_t& byte) {
   uint8_t b[1];
   trans_->readAll(b, 1);
   byte = *(int8_t*)b;
   return 1;
 }

 /**
  * Read an i16 from the wire as a zigzag varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readI16(int16_t& i16) {
   int32_t value;
   uint32_t rsize = readVarint32(value);
   i16 = (int16_t)zigzagToI32(value);
   return rsize;
 }

 /**
  * Read an i32 from the wire as a zigzag varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readI32(int32_t& i32) {
   int32_t value;
   uint32_t rsize = readVarint32(value);
   i32 = zigzagToI32(value);
   return rsize;
 }

 /**
  * Read an i64 from the wire as a zigzag varint.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readI64(int64_t& i64) {
   int64_t value;
   uint32_t rsize = readVarint64(value);
   i64 = zigzagToI64(value);
   return rsize;
 }

 /**
  * No magic here - just read a double off the wire.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readDouble(double& dub) {
   BOOST_STATIC_ASSERT(sizeof(double) == sizeof(uint64_t));
   BOOST_STATIC_ASSERT(std::numeric_limits<double>::is_iec559);

   uint64_t bits;
   uint8_t b[8];
   trans_->readAll(b, 8);
   bits = *(uint64_t*)b;
   bits = letohll(bits);
   dub = bitwise_cast<double>(bits);
   return 8;
 }

 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readString(std::string& str) {
   return readBinary(str);
 }

 /**
  * Read a byte[] from the wire.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readBinary(std::string& str) {
   int32_t rsize = 0;
   int32_t size;

   rsize += readVarint32(size);
   // Catch empty string case
   if (size == 0) {
     str = "";
     return rsize;
   }

   // Catch error cases
   if (size < 0) {
     throw TProtocolException(TProtocolException::NEGATIVE_SIZE);
   }
   if (string_limit_ > 0 && size > string_limit_) {
     throw TProtocolException(TProtocolException::SIZE_LIMIT);
   }

   // Use the heap here to prevent stack overflow for v. large strings
   if (size > string_buf_size_ || string_buf_ == NULL) {
     void* new_string_buf = std::realloc(string_buf_, (uint32_t)size);
     if (new_string_buf == NULL) {
       throw std::bad_alloc();
     }
     string_buf_ = (uint8_t*)new_string_buf;
     string_buf_size_ = size;
   }
   trans_->readAll(string_buf_, size);
   str.assign((char*)string_buf_, size);

   return rsize + (uint32_t)size;
 }

 /**
  * Read an i32 from the wire as a varint. The MSB of each byte is set
  * if there is another byte to follow. This can read up to 5 bytes.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readVarint32(int32_t& i32) {
   int64_t val;
   uint32_t rsize = readVarint64(val);
   i32 = (int32_t)val;
   return rsize;
 }

 /**
  * Read an i64 from the wire as a proper varint. The MSB of each byte is set
  * if there is another byte to follow. This can read up to 10 bytes.
  */
 template <class Transport_>
 uint32_t TCompactProtocolT<Transport_>::readVarint64(int64_t& i64) {
   uint32_t rsize = 0;
   uint64_t val = 0;
   int shift = 0;
   uint8_t buf[10];  // 64 bits / (7 bits/byte) = 10 bytes.
   uint32_t buf_size = sizeof(buf);
   const uint8_t* borrowed = trans_->borrow(buf, &buf_size);

   // Fast path.
   if (borrowed != NULL) {
     while (true) {
       uint8_t byte = borrowed[rsize];
       rsize++;
       val |= (uint64_t)(byte & 0x7f) << shift;
       shift += 7;
       if (!(byte & 0x80)) {
         i64 = val;
         trans_->consume(rsize);
         return rsize;
       }
       // Have to check for invalid data so we don't crash.
       if (UNLIKELY(rsize == sizeof(buf))) {
         throw TProtocolException(TProtocolException::INVALID_DATA, "Variable-length int over 10 bytes.");
       }
     }
   }

   // Slow path.
   else {
     while (true) {
       uint8_t byte;
       rsize += trans_->readAll(&byte, 1);
       val |= (uint64_t)(byte & 0x7f) << shift;
       shift += 7;
       if (!(byte & 0x80)) {
         i64 = val;
         return rsize;
       }
       // Might as well check for invalid data on the slow path too.
       if (UNLIKELY(rsize >= sizeof(buf))) {
         throw TProtocolException(TProtocolException::INVALID_DATA, "Variable-length int over 10 bytes.");
       }
     }
   }
 }

 /**
  * Convert from zigzag int to int.
  */
 template <class Transport_>
 int32_t TCompactProtocolT<Transport_>::zigzagToI32(uint32_t n) {
   return (n >> 1) ^ -(n & 1);
 }

 /**
  * Convert from zigzag long to long.
  */
 template <class Transport_>
 int64_t TCompactProtocolT<Transport_>::zigzagToI64(uint64_t n) {
   return (n >> 1) ^ -(n & 1);
 }

 template <class Transport_>
 TType TCompactProtocolT<Transport_>::getTType(int8_t type) {
   switch (type) {
     case T_STOP:
       return T_STOP;
     case detail::compact::CT_BOOLEAN_FALSE:
     case detail::compact::CT_BOOLEAN_TRUE:
       return T_BOOL;
     case detail::compact::CT_BYTE:
       return T_BYTE;
     case detail::compact::CT_I16:
       return T_I16;
     case detail::compact::CT_I32:
       return T_I32;
     case detail::compact::CT_I64:
       return T_I64;
     case detail::compact::CT_DOUBLE:
       return T_DOUBLE;
     case detail::compact::CT_BINARY:
       return T_STRING;
     case detail::compact::CT_LIST:
       return T_LIST;
     case detail::compact::CT_SET:
       return T_SET;
     case detail::compact::CT_MAP:
       return T_MAP;
     case detail::compact::CT_STRUCT:
       return T_STRUCT;
     default:
       throw TException("don't know what type: " + type);
   }
   return T_STOP;
 }

 }}} // apache::thrift::protocol

 #endif // _THRIFT_PROTOCOL_TCOMPACTPROTOCOL_TCC_
	/*
	* Licensed to the Apache Software Foundation (ASF) under one
	* or more contributor license agreements. See the NOTICE file
	* distributed with this work for additional information
	* regarding copyright ownership. The ASF licenses this file
	* to you under the Apache License, Version 2.0 (the
	* "License"); you may not use this file except in compliance
	* with the License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing,
	* software distributed under the License is distributed on an
	* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
	* KIND, either express or implied. See the License for the
	* specific language governing permissions and limitations
	* under the License.
	*/
	#ifndef _THRIFT_PROTOCOL_TCOMPACTPROTOCOL_TCC_
	#define _THRIFT_PROTOCOL_TCOMPACTPROTOCOL_TCC_ 1

	#include <limits>

	/*
	* TCompactProtocol::i*ToZigzag depend on the fact that the right shift
	* operator on a signed integer is an arithmetic (sign-extending) shift.
	* If this is not the case, the current implementation will not work.
	* If anyone encounters this error, we can try to figure out the best
	* way to implement an arithmetic right shift on their platform.
	*/
	#if !defined(SIGNED_RIGHT_SHIFT_IS) \|\| !defined(ARITHMETIC_RIGHT_SHIFT)
	# error "Unable to determine the behavior of a signed right shift"
	#endif
	#if SIGNED_RIGHT_SHIFT_IS != ARITHMETIC_RIGHT_SHIFT
	# error "TCompactProtocol currently only works if a signed right shift is arithmetic"
	#endif

	#ifdef __GNUC__
	#define UNLIKELY(val) (__builtin_expect((val), 0))
	#else
	#define UNLIKELY(val) (val)
	#endif

	namespace apache { namespace thrift { namespace protocol {

	namespace detail { namespace compact {

	enum Types {
	CT_STOP = 0x00,
	CT_BOOLEAN_TRUE = 0x01,
	CT_BOOLEAN_FALSE = 0x02,
	CT_BYTE = 0x03,
	CT_I16 = 0x04,
	CT_I32 = 0x05,
	CT_I64 = 0x06,
	CT_DOUBLE = 0x07,
	CT_BINARY = 0x08,
	CT_LIST = 0x09,
	CT_SET = 0x0A,
	CT_MAP = 0x0B,
	CT_STRUCT = 0x0C
	};

	const int8_t TTypeToCType[16] = {
	CT_STOP, // T_STOP
	0, // unused
	CT_BOOLEAN_TRUE, // T_BOOL
	CT_BYTE, // T_BYTE
	CT_DOUBLE, // T_DOUBLE
	0, // unused
	CT_I16, // T_I16
	0, // unused
	CT_I32, // T_I32
	0, // unused
	CT_I64, // T_I64
	CT_BINARY, // T_STRING
	CT_STRUCT, // T_STRUCT
	CT_MAP, // T_MAP
	CT_SET, // T_SET
	CT_LIST, // T_LIST
	};

	}} // end detail::compact namespace


	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeMessageBegin(
	const std::string& name,
	const TMessageType messageType,
	const int32_t seqid) {
	uint32_t wsize = 0;
	wsize += writeByte(PROTOCOL_ID);
	wsize += writeByte((VERSION_N & VERSION_MASK) \| (((int32_t)messageType << TYPE_SHIFT_AMOUNT) & TYPE_MASK));
	wsize += writeVarint32(seqid);
	wsize += writeString(name);
	return wsize;
	}

	/**
	* Write a field header containing the field id and field type. If the
	* difference between the current field id and the last one is small (< 15),
	* then the field id will be encoded in the 4 MSB as a delta. Otherwise, the
	* field id will follow the type header as a zigzag varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeFieldBegin(const char* name,
	const TType fieldType,
	const int16_t fieldId) {
	if (fieldType == T_BOOL) {
	booleanField_.name = name;
	booleanField_.fieldType = fieldType;
	booleanField_.fieldId = fieldId;
	} else {
	return writeFieldBeginInternal(name, fieldType, fieldId, -1);
	}
	return 0;
	}

	/**
	* Write the STOP symbol so we know there are no more fields in this struct.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeFieldStop() {
	return writeByte(T_STOP);
	}

	/**
	* Write a struct begin. This doesn't actually put anything on the wire. We
	* use it as an opportunity to put special placeholder markers on the field
	* stack so we can get the field id deltas correct.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeStructBegin(const char* name) {
	(void) name;
	lastField_.push(lastFieldId_);
	lastFieldId_ = 0;
	return 0;
	}

	/**
	* Write a struct end. This doesn't actually put anything on the wire. We use
	* this as an opportunity to pop the last field from the current struct off
	* of the field stack.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeStructEnd() {
	lastFieldId_ = lastField_.top();
	lastField_.pop();
	return 0;
	}

	/**
	* Write a List header.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeListBegin(const TType elemType,
	const uint32_t size) {
	return writeCollectionBegin(elemType, size);
	}

	/**
	* Write a set header.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeSetBegin(const TType elemType,
	const uint32_t size) {
	return writeCollectionBegin(elemType, size);
	}

	/**
	* Write a map header. If the map is empty, omit the key and value type
	* headers, as we don't need any additional information to skip it.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeMapBegin(const TType keyType,
	const TType valType,
	const uint32_t size) {
	uint32_t wsize = 0;

	if (size == 0) {
	wsize += writeByte(0);
	} else {
	wsize += writeVarint32(size);
	wsize += writeByte(getCompactType(keyType) << 4 \| getCompactType(valType));
	}
	return wsize;
	}

	/**
	* Write a boolean value. Potentially, this could be a boolean field, in
	* which case the field header info isn't written yet. If so, decide what the
	* right type header is for the value and then write the field header.
	* Otherwise, write a single byte.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeBool(const bool value) {
	uint32_t wsize = 0;

	if (booleanField_.name != NULL) {
	// we haven't written the field header yet
	wsize += writeFieldBeginInternal(booleanField_.name,
	booleanField_.fieldType,
	booleanField_.fieldId,
	value ? detail::compact::CT_BOOLEAN_TRUE :
	detail::compact::CT_BOOLEAN_FALSE);
	booleanField_.name = NULL;
	} else {
	// we're not part of a field, so just write the value
	wsize += writeByte(value ? detail::compact::CT_BOOLEAN_TRUE :
	detail::compact::CT_BOOLEAN_FALSE);
	}
	return wsize;
	}

	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeByte(const int8_t byte) {
	trans_->write((uint8_t*)&byte, 1);
	return 1;
	}

	/**
	* Write an i16 as a zigzag varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeI16(const int16_t i16) {
	return writeVarint32(i32ToZigzag(i16));
	}

	/**
	* Write an i32 as a zigzag varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeI32(const int32_t i32) {
	return writeVarint32(i32ToZigzag(i32));
	}

	/**
	* Write an i64 as a zigzag varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeI64(const int64_t i64) {
	return writeVarint64(i64ToZigzag(i64));
	}

	/**
	* Write a double to the wire as 8 bytes.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeDouble(const double dub) {
	BOOST_STATIC_ASSERT(sizeof(double) == sizeof(uint64_t));
	BOOST_STATIC_ASSERT(std::numeric_limits<double>::is_iec559);

	uint64_t bits = bitwise_cast<uint64_t>(dub);
	bits = htolell(bits);
	trans_->write((uint8_t*)&bits, 8);
	return 8;
	}

	/**
	* Write a string to the wire with a varint size preceeding.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeString(const std::string& str) {
	return writeBinary(str);
	}

	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeBinary(const std::string& str) {
	uint32_t ssize = str.size();
	uint32_t wsize = writeVarint32(ssize) + ssize;
	trans_->write((uint8_t*)str.data(), ssize);
	return wsize;
	}

	//
	// Internal Writing methods
	//

	/**
	* The workhorse of writeFieldBegin. It has the option of doing a
	* 'type override' of the type header. This is used specifically in the
	* boolean field case.
	*/
	template <class Transport_>
	int32_t TCompactProtocolT<Transport_>::writeFieldBeginInternal(
	const char* name,
	const TType fieldType,
	const int16_t fieldId,
	int8_t typeOverride) {
	(void) name;
	uint32_t wsize = 0;

	// if there's a type override, use that.
	int8_t typeToWrite = (typeOverride == -1 ? getCompactType(fieldType) : typeOverride);

	// check if we can use delta encoding for the field id
	if (fieldId > lastFieldId_ && fieldId - lastFieldId_ <= 15) {
	// write them together
	wsize += writeByte((fieldId - lastFieldId_) << 4 \| typeToWrite);
	} else {
	// write them separate
	wsize += writeByte(typeToWrite);
	wsize += writeI16(fieldId);
	}

	lastFieldId_ = fieldId;
	return wsize;
	}

	/**
	* Abstract method for writing the start of lists and sets. List and sets on
	* the wire differ only by the type indicator.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeCollectionBegin(int8_t elemType,
	int32_t size) {
	uint32_t wsize = 0;
	if (size <= 14) {
	wsize += writeByte(size << 4 \| getCompactType(elemType));
	} else {
	wsize += writeByte(0xf0 \| getCompactType(elemType));
	wsize += writeVarint32(size);
	}
	return wsize;
	}

	/**
	* Write an i32 as a varint. Results in 1-5 bytes on the wire.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeVarint32(uint32_t n) {
	uint8_t buf[5];
	uint32_t wsize = 0;

	while (true) {
	if ((n & ~0x7F) == 0) {
	buf[wsize++] = (int8_t)n;
	break;
	} else {
	buf[wsize++] = (int8_t)((n & 0x7F) \| 0x80);
	n >>= 7;
	}
	}
	trans_->write(buf, wsize);
	return wsize;
	}

	/**
	* Write an i64 as a varint. Results in 1-10 bytes on the wire.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::writeVarint64(uint64_t n) {
	uint8_t buf[10];
	uint32_t wsize = 0;

	while (true) {
	if ((n & ~0x7FL) == 0) {
	buf[wsize++] = (int8_t)n;
	break;
	} else {
	buf[wsize++] = (int8_t)((n & 0x7F) \| 0x80);
	n >>= 7;
	}
	}
	trans_->write(buf, wsize);
	return wsize;
	}

	/**
	* Convert l into a zigzag long. This allows negative numbers to be
	* represented compactly as a varint.
	*/
	template <class Transport_>
	uint64_t TCompactProtocolT<Transport_>::i64ToZigzag(const int64_t l) {
	return (l << 1) ^ (l >> 63);
	}

	/**
	* Convert n into a zigzag int. This allows negative numbers to be
	* represented compactly as a varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::i32ToZigzag(const int32_t n) {
	return (n << 1) ^ (n >> 31);
	}

	/**
	* Given a TType value, find the appropriate detail::compact::Types value
	*/
	template <class Transport_>
	int8_t TCompactProtocolT<Transport_>::getCompactType(int8_t ttype) {
	return detail::compact::TTypeToCType[ttype];
	}

	//
	// Reading Methods
	//

	/**
	* Read a message header.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readMessageBegin(
	std::string& name,
	TMessageType& messageType,
	int32_t& seqid) {
	uint32_t rsize = 0;
	int8_t protocolId;
	int8_t versionAndType;
	int8_t version;

	rsize += readByte(protocolId);
	if (protocolId != PROTOCOL_ID) {
	throw TProtocolException(TProtocolException::BAD_VERSION, "Bad protocol identifier");
	}

	rsize += readByte(versionAndType);
	version = (int8_t)(versionAndType & VERSION_MASK);
	if (version != VERSION_N) {
	throw TProtocolException(TProtocolException::BAD_VERSION, "Bad protocol version");
	}

	messageType = (TMessageType)((versionAndType >> TYPE_SHIFT_AMOUNT) & 0x03);
	rsize += readVarint32(seqid);
	rsize += readString(name);

	return rsize;
	}

	/**
	* Read a struct begin. There's nothing on the wire for this, but it is our
	* opportunity to push a new struct begin marker on the field stack.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readStructBegin(std::string& name) {
	name = "";
	lastField_.push(lastFieldId_);
	lastFieldId_ = 0;
	return 0;
	}

	/**
	* Doesn't actually consume any wire data, just removes the last field for
	* this struct from the field stack.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readStructEnd() {
	lastFieldId_ = lastField_.top();
	lastField_.pop();
	return 0;
	}

	/**
	* Read a field header off the wire.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readFieldBegin(std::string& name,
	TType& fieldType,
	int16_t& fieldId) {
	(void) name;
	uint32_t rsize = 0;
	int8_t byte;
	int8_t type;

	rsize += readByte(byte);
	type = (byte & 0x0f);

	// if it's a stop, then we can return immediately, as the struct is over.
	if (type == T_STOP) {
	fieldType = T_STOP;
	fieldId = 0;
	return rsize;
	}

	// mask off the 4 MSB of the type header. it could contain a field id delta.
	int16_t modifier = (int16_t)(((uint8_t)byte & 0xf0) >> 4);
	if (modifier == 0) {
	// not a delta, look ahead for the zigzag varint field id.
	rsize += readI16(fieldId);
	} else {
	fieldId = (int16_t)(lastFieldId_ + modifier);
	}
	fieldType = getTType(type);

	// if this happens to be a boolean field, the value is encoded in the type
	if (type == detail::compact::CT_BOOLEAN_TRUE \|\|
	type == detail::compact::CT_BOOLEAN_FALSE) {
	// save the boolean value in a special instance variable.
	boolValue_.hasBoolValue = true;
	boolValue_.boolValue =
	(type == detail::compact::CT_BOOLEAN_TRUE ? true : false);
	}

	// push the new field onto the field stack so we can keep the deltas going.
	lastFieldId_ = fieldId;
	return rsize;
	}

	/**
	* Read a map header off the wire. If the size is zero, skip reading the key
	* and value type. This means that 0-length maps will yield TMaps without the
	* "correct" types.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readMapBegin(TType& keyType,
	TType& valType,
	uint32_t& size) {
	uint32_t rsize = 0;
	int8_t kvType = 0;
	int32_t msize = 0;

	rsize += readVarint32(msize);
	if (msize != 0)
	rsize += readByte(kvType);

	if (msize < 0) {
	throw TProtocolException(TProtocolException::NEGATIVE_SIZE);
	} else if (container_limit_ && msize > container_limit_) {
	throw TProtocolException(TProtocolException::SIZE_LIMIT);
	}

	keyType = getTType((int8_t)((uint8_t)kvType >> 4));
	valType = getTType((int8_t)((uint8_t)kvType & 0xf));
	size = (uint32_t)msize;

	return rsize;
	}

	/**
	* Read a list header off the wire. If the list size is 0-14, the size will
	* be packed into the element type header. If it's a longer list, the 4 MSB
	* of the element type header will be 0xF, and a varint will follow with the
	* true size.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readListBegin(TType& elemType,
	uint32_t& size) {
	int8_t size_and_type;
	uint32_t rsize = 0;
	int32_t lsize;

	rsize += readByte(size_and_type);

	lsize = ((uint8_t)size_and_type >> 4) & 0x0f;
	if (lsize == 15) {
	rsize += readVarint32(lsize);
	}

	if (lsize < 0) {
	throw TProtocolException(TProtocolException::NEGATIVE_SIZE);
	} else if (container_limit_ && lsize > container_limit_) {
	throw TProtocolException(TProtocolException::SIZE_LIMIT);
	}

	elemType = getTType((int8_t)(size_and_type & 0x0f));
	size = (uint32_t)lsize;

	return rsize;
	}

	/**
	* Read a set header off the wire. If the set size is 0-14, the size will
	* be packed into the element type header. If it's a longer set, the 4 MSB
	* of the element type header will be 0xF, and a varint will follow with the
	* true size.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readSetBegin(TType& elemType,
	uint32_t& size) {
	return readListBegin(elemType, size);
	}

	/**
	* Read a boolean off the wire. If this is a boolean field, the value should
	* already have been read during readFieldBegin, so we'll just consume the
	* pre-stored value. Otherwise, read a byte.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readBool(bool& value) {
	if (boolValue_.hasBoolValue == true) {
	value = boolValue_.boolValue;
	boolValue_.hasBoolValue = false;
	return 0;
	} else {
	int8_t val;
	readByte(val);
	value = (val == detail::compact::CT_BOOLEAN_TRUE);
	return 1;
	}
	}

	/**
	* Read a single byte off the wire. Nothing interesting here.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readByte(int8_t& byte) {
	uint8_t b[1];
	trans_->readAll(b, 1);
	byte = (int8_t)b;
	return 1;
	}

	/**
	* Read an i16 from the wire as a zigzag varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readI16(int16_t& i16) {
	int32_t value;
	uint32_t rsize = readVarint32(value);
	i16 = (int16_t)zigzagToI32(value);
	return rsize;
	}

	/**
	* Read an i32 from the wire as a zigzag varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readI32(int32_t& i32) {
	int32_t value;
	uint32_t rsize = readVarint32(value);
	i32 = zigzagToI32(value);
	return rsize;
	}

	/**
	* Read an i64 from the wire as a zigzag varint.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readI64(int64_t& i64) {
	int64_t value;
	uint32_t rsize = readVarint64(value);
	i64 = zigzagToI64(value);
	return rsize;
	}

	/**
	* No magic here - just read a double off the wire.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readDouble(double& dub) {
	BOOST_STATIC_ASSERT(sizeof(double) == sizeof(uint64_t));
	BOOST_STATIC_ASSERT(std::numeric_limits<double>::is_iec559);

	uint64_t bits;
	uint8_t b[8];
	trans_->readAll(b, 8);
	bits = (uint64_t)b;
	bits = letohll(bits);
	dub = bitwise_cast<double>(bits);
	return 8;
	}

	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readString(std::string& str) {
	return readBinary(str);
	}

	/**
	* Read a byte[] from the wire.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readBinary(std::string& str) {
	int32_t rsize = 0;
	int32_t size;

	rsize += readVarint32(size);
	// Catch empty string case
	if (size == 0) {
	str = "";
	return rsize;
	}

	// Catch error cases
	if (size < 0) {
	throw TProtocolException(TProtocolException::NEGATIVE_SIZE);
	}
	if (string_limit_ > 0 && size > string_limit_) {
	throw TProtocolException(TProtocolException::SIZE_LIMIT);
	}

	// Use the heap here to prevent stack overflow for v. large strings
	if (size > string_buf_size_ \|\| string_buf_ == NULL) {
	void* new_string_buf = std::realloc(string_buf_, (uint32_t)size);
	if (new_string_buf == NULL) {
	throw std::bad_alloc();
	}
	string_buf_ = (uint8_t*)new_string_buf;
	string_buf_size_ = size;
	}
	trans_->readAll(string_buf_, size);
	str.assign((char*)string_buf_, size);

	return rsize + (uint32_t)size;
	}

	/**
	* Read an i32 from the wire as a varint. The MSB of each byte is set
	* if there is another byte to follow. This can read up to 5 bytes.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readVarint32(int32_t& i32) {
	int64_t val;
	uint32_t rsize = readVarint64(val);
	i32 = (int32_t)val;
	return rsize;
	}

	/**
	* Read an i64 from the wire as a proper varint. The MSB of each byte is set
	* if there is another byte to follow. This can read up to 10 bytes.
	*/
	template <class Transport_>
	uint32_t TCompactProtocolT<Transport_>::readVarint64(int64_t& i64) {
	uint32_t rsize = 0;
	uint64_t val = 0;
	int shift = 0;
	uint8_t buf[10]; // 64 bits / (7 bits/byte) = 10 bytes.
	uint32_t buf_size = sizeof(buf);
	const uint8_t* borrowed = trans_->borrow(buf, &buf_size);

	// Fast path.
	if (borrowed != NULL) {
	while (true) {
	uint8_t byte = borrowed[rsize];
	rsize++;
	val \|= (uint64_t)(byte & 0x7f) << shift;
	shift += 7;
	if (!(byte & 0x80)) {
	i64 = val;
	trans_->consume(rsize);
	return rsize;
	}
	// Have to check for invalid data so we don't crash.
	if (UNLIKELY(rsize == sizeof(buf))) {
	throw TProtocolException(TProtocolException::INVALID_DATA, "Variable-length int over 10 bytes.");
	}
	}
	}

	// Slow path.
	else {
	while (true) {
	uint8_t byte;
	rsize += trans_->readAll(&byte, 1);
	val \|= (uint64_t)(byte & 0x7f) << shift;
	shift += 7;
	if (!(byte & 0x80)) {
	i64 = val;
	return rsize;
	}
	// Might as well check for invalid data on the slow path too.
	if (UNLIKELY(rsize >= sizeof(buf))) {
	throw TProtocolException(TProtocolException::INVALID_DATA, "Variable-length int over 10 bytes.");
	}
	}
	}
	}

	/**
	* Convert from zigzag int to int.
	*/
	template <class Transport_>
	int32_t TCompactProtocolT<Transport_>::zigzagToI32(uint32_t n) {
	return (n >> 1) ^ -(n & 1);
	}

	/**
	* Convert from zigzag long to long.
	*/
	template <class Transport_>
	int64_t TCompactProtocolT<Transport_>::zigzagToI64(uint64_t n) {
	return (n >> 1) ^ -(n & 1);
	}

	template <class Transport_>
	TType TCompactProtocolT<Transport_>::getTType(int8_t type) {
	switch (type) {
	case T_STOP:
	return T_STOP;
	case detail::compact::CT_BOOLEAN_FALSE:
	case detail::compact::CT_BOOLEAN_TRUE:
	return T_BOOL;
	case detail::compact::CT_BYTE:
	return T_BYTE;
	case detail::compact::CT_I16:
	return T_I16;
	case detail::compact::CT_I32:
	return T_I32;
	case detail::compact::CT_I64:
	return T_I64;
	case detail::compact::CT_DOUBLE:
	return T_DOUBLE;
	case detail::compact::CT_BINARY:
	return T_STRING;
	case detail::compact::CT_LIST:
	return T_LIST;
	case detail::compact::CT_SET:
	return T_SET;
	case detail::compact::CT_MAP:
	return T_MAP;
	case detail::compact::CT_STRUCT:
	return T_STRUCT;
	default:
	throw TException("don't know what type: " + type);
	}
	return T_STOP;
	}

	}}} // apache::thrift::protocol

	#endif // _THRIFT_PROTOCOL_TCOMPACTPROTOCOL_TCC_