src/encoding/block.cpp - ndn-cxx - Gitiles

 /* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
 /**
  * Copyright (c) 2013-2016 Regents of the University of California.
  *
  * This file is part of ndn-cxx library (NDN C++ library with eXperimental eXtensions).
  *
  * ndn-cxx library is free software: you can redistribute it and/or modify it under the
  * terms of the GNU Lesser General Public License as published by the Free Software
  * Foundation, either version 3 of the License, or (at your option) any later version.
  *
  * ndn-cxx library is distributed in the hope that it will be useful, but WITHOUT ANY
  * WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A
  * PARTICULAR PURPOSE.  See the GNU Lesser General Public License for more details.
  *
  * You should have received copies of the GNU General Public License and GNU Lesser
  * General Public License along with ndn-cxx, e.g., in COPYING.md file.  If not, see
  * <http://www.gnu.org/licenses/>.
  *
  * See AUTHORS.md for complete list of ndn-cxx authors and contributors.
  *
  * @author Alexander Afanasyev <http://lasr.cs.ucla.edu/afanasyev/index.html>
  */

 #include "block.hpp"
 #include "block-helpers.hpp"

 #include "tlv.hpp"
 #include "encoding-buffer.hpp"
 #include "buffer-stream.hpp"

 #include <boost/lexical_cast.hpp>
 #include <boost/asio/buffer.hpp>

 namespace ndn {

 #if NDN_CXX_HAVE_IS_NOTHROW_MOVE_CONSTRUCTIBLE
 static_assert(std::is_nothrow_move_constructible<Block>::value,
               "Block must be MoveConstructible with noexcept");
 #endif // NDN_CXX_HAVE_IS_NOTHROW_MOVE_CONSTRUCTIBLE

 #if NDN_CXX_HAVE_IS_NOTHROW_MOVE_ASSIGNABLE
 static_assert(std::is_nothrow_move_assignable<Block>::value,
               "Block must be MoveAssignable with noexcept");
 #endif // NDN_CXX_HAVE_IS_NOTHROW_MOVE_ASSIGNABLE

 const size_t MAX_SIZE_OF_BLOCK_FROM_STREAM = MAX_NDN_PACKET_SIZE;

 Block::Block()
   : m_type(std::numeric_limits<uint32_t>::max())
 {
 }

 Block::Block(const EncodingBuffer& buffer)
   : m_buffer(const_cast<EncodingBuffer&>(buffer).getBuffer())
   , m_begin(buffer.begin())
   , m_end(buffer.end())
   , m_size(m_end - m_begin)
 {
   m_value_begin = m_begin;
   m_value_end   = m_end;

   m_type = tlv::readType(m_value_begin, m_value_end);
   uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
   if (length != static_cast<uint64_t>(m_value_end - m_value_begin))
     {
       BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
     }
 }

 Block::Block(const ConstBufferPtr& wire,
              uint32_t type,
              const Buffer::const_iterator& begin, const Buffer::const_iterator& end,
              const Buffer::const_iterator& valueBegin, const Buffer::const_iterator& valueEnd)
   : m_buffer(wire)
   , m_type(type)
   , m_begin(begin)
   , m_end(end)
   , m_size(m_end - m_begin)
   , m_value_begin(valueBegin)
   , m_value_end(valueEnd)
 {
 }

 Block::Block(const ConstBufferPtr& buffer)
   : m_buffer(buffer)
   , m_begin(m_buffer->begin())
   , m_end(m_buffer->end())
   , m_size(m_end - m_begin)
 {
   m_value_begin = m_begin;
   m_value_end   = m_end;

   m_type = tlv::readType(m_value_begin, m_value_end);

   uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
   if (length != static_cast<uint64_t>(m_value_end - m_value_begin))
     {
       BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
     }
 }

 Block::Block(const ConstBufferPtr& buffer,
              const Buffer::const_iterator& begin, const Buffer::const_iterator& end,
              bool verifyLength/* = true*/)
   : m_buffer(buffer)
   , m_begin(begin)
   , m_end(end)
   , m_size(m_end - m_begin)
 {
   m_value_begin = m_begin;
   m_value_end   = m_end;

   m_type = tlv::readType(m_value_begin, m_value_end);
   uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
   if (verifyLength) {
     if (length != static_cast<uint64_t>(std::distance(m_value_begin, m_value_end))) {
       BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
     }
   }
 }

 Block::Block(const Block& block,
              const Buffer::const_iterator& begin, const Buffer::const_iterator& end,
              bool verifyLength/* = true*/)
   : m_buffer(block.m_buffer)
   , m_begin(begin)
   , m_end(end)
   , m_size(m_end - m_begin)
 {
   if (!(m_buffer->begin() <= begin && begin <= m_buffer->end()) ||
       !(m_buffer->begin() <= end   && end   <= m_buffer->end())) {
     BOOST_THROW_EXCEPTION(Error("begin/end iterators do not point to the underlying buffer of the block"));
   }

   m_value_begin = m_begin;
   m_value_end   = m_end;

   m_type = tlv::readType(m_value_begin, m_value_end);
   uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
   if (verifyLength) {
     if (length != static_cast<uint64_t>(std::distance(m_value_begin, m_value_end))) {
       BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
     }
   }
 }

 Block::Block(const uint8_t* buffer, size_t maxlength)
 {
   const uint8_t*  tmp_begin = buffer;
   const uint8_t*  tmp_end   = buffer + maxlength;

   m_type = tlv::readType(tmp_begin, tmp_end);
   uint64_t length = tlv::readVarNumber(tmp_begin, tmp_end);

   if (length > static_cast<uint64_t>(tmp_end - tmp_begin))
     {
       BOOST_THROW_EXCEPTION(tlv::Error("Not enough data in the buffer to fully parse TLV"));
     }

   m_buffer = make_shared<Buffer>(buffer, (tmp_begin - buffer) + length);

   m_begin = m_buffer->begin();
   m_end = m_buffer->end();
   m_size = m_end - m_begin;

   m_value_begin = m_buffer->begin() + (tmp_begin - buffer);
   m_value_end   = m_buffer->end();
 }

 Block::Block(const void* bufferX, size_t maxlength)
 {
   const uint8_t* buffer = reinterpret_cast<const uint8_t*>(bufferX);

   const uint8_t* tmp_begin = buffer;
   const uint8_t* tmp_end   = buffer + maxlength;

   m_type = tlv::readType(tmp_begin, tmp_end);
   uint64_t length = tlv::readVarNumber(tmp_begin, tmp_end);

   if (length > static_cast<uint64_t>(tmp_end - tmp_begin))
     {
       BOOST_THROW_EXCEPTION(tlv::Error("Not enough data in the buffer to fully parse TLV"));
     }

   m_buffer = make_shared<Buffer>(buffer, (tmp_begin - buffer) + length);

   m_begin = m_buffer->begin();
   m_end = m_buffer->end();
   m_size = m_end - m_begin;

   m_value_begin = m_buffer->begin() + (tmp_begin - buffer);
   m_value_end   = m_buffer->end();
 }

 Block::Block(uint32_t type)
   : m_type(type)
 {
 }

 Block::Block(uint32_t type, const ConstBufferPtr& value)
   : m_buffer(value)
   , m_type(type)
   , m_begin(m_buffer->end())
   , m_end(m_buffer->end())
   , m_value_begin(m_buffer->begin())
   , m_value_end(m_buffer->end())
 {
   m_size = tlv::sizeOfVarNumber(m_type) + tlv::sizeOfVarNumber(value_size()) + value_size();
 }

 Block::Block(uint32_t type, const Block& value)
   : m_buffer(value.m_buffer)
   , m_type(type)
   , m_begin(m_buffer->end())
   , m_end(m_buffer->end())
   , m_value_begin(value.begin())
   , m_value_end(value.end())
 {
   m_size = tlv::sizeOfVarNumber(m_type) + tlv::sizeOfVarNumber(value_size()) + value_size();
 }

 Block
 Block::fromStream(std::istream& is)
 {
   std::istream_iterator<uint8_t> begin(is >> std::noskipws);
   std::istream_iterator<uint8_t> end;

   uint32_t type = tlv::readType(begin, end);
   uint64_t length = tlv::readVarNumber(begin, end);

   if (length == 0) {
     return makeEmptyBlock(type);
   }

   if (length > MAX_SIZE_OF_BLOCK_FROM_STREAM)
     BOOST_THROW_EXCEPTION(tlv::Error("Length of block from stream is too large"));

   // We may still have some problem here, if some exception happens,
   // we may completely lose all the bytes extracted from the stream.

   char buf[MAX_SIZE_OF_BLOCK_FROM_STREAM];
   buf[0] = *begin;
   is.read(buf + 1, length - 1);

   if (length != static_cast<uint64_t>(is.gcount()) + 1) {
     BOOST_THROW_EXCEPTION(tlv::Error("Not enough data in the buffer to fully parse TLV"));
   }

   return makeBinaryBlock(type, buf, length);
 }

 std::tuple<bool, Block>
 Block::fromBuffer(ConstBufferPtr buffer, size_t offset)
 {
   Buffer::const_iterator tempBegin = buffer->begin() + offset;

   uint32_t type;
   bool isOk = tlv::readType(tempBegin, buffer->end(), type);
   if (!isOk)
     return std::make_tuple(false, Block());

   uint64_t length;
   isOk = tlv::readVarNumber(tempBegin, buffer->end(), length);
   if (!isOk)
     return std::make_tuple(false, Block());

   if (length > static_cast<uint64_t>(buffer->end() - tempBegin))
     return std::make_tuple(false, Block());

   return std::make_tuple(true, Block(buffer, type,
                                      buffer->begin() + offset, tempBegin + length,
                                      tempBegin, tempBegin + length));
 }

 std::tuple<bool, Block>
 Block::fromBuffer(const uint8_t* buffer, size_t maxSize)
 {
   const uint8_t* tempBegin = buffer;
   const uint8_t* tempEnd = buffer + maxSize;

   uint32_t type = 0;
   bool isOk = tlv::readType(tempBegin, tempEnd, type);
   if (!isOk)
     return std::make_tuple(false, Block());

   uint64_t length;
   isOk = tlv::readVarNumber(tempBegin, tempEnd, length);
   if (!isOk)
     return std::make_tuple(false, Block());

   if (length > static_cast<uint64_t>(tempEnd - tempBegin))
     return std::make_tuple(false, Block());

   BufferPtr sharedBuffer = make_shared<Buffer>(buffer, tempBegin + length);
   return std::make_tuple(true,
          Block(sharedBuffer, type,
                sharedBuffer->begin(), sharedBuffer->end(),
                sharedBuffer->begin() + (tempBegin - buffer), sharedBuffer->end()));
 }

 void
 Block::reset()
 {
   m_buffer.reset(); // reset of the shared_ptr
   m_subBlocks.clear(); // remove all parsed subelements

   m_type = std::numeric_limits<uint32_t>::max();
   m_begin = m_end = m_value_begin = m_value_end = Buffer::const_iterator();
 }

 void
 Block::resetWire()
 {
   m_buffer.reset(); // reset of the shared_ptr
   // keep subblocks

   // keep type
   m_begin = m_end = m_value_begin = m_value_end = Buffer::const_iterator();
 }

 void
 Block::parse() const
 {
   if (!m_subBlocks.empty() || value_size() == 0)
     return;

   Buffer::const_iterator begin = value_begin();
   Buffer::const_iterator end = value_end();

   while (begin != end)
     {
       Buffer::const_iterator element_begin = begin;

       uint32_t type = tlv::readType(begin, end);
       uint64_t length = tlv::readVarNumber(begin, end);

       if (length > static_cast<uint64_t>(end - begin))
         {
           m_subBlocks.clear();
           BOOST_THROW_EXCEPTION(tlv::Error("TLV length exceeds buffer length"));
         }
       Buffer::const_iterator element_end = begin + length;

       m_subBlocks.push_back(Block(m_buffer,
                                   type,
                                   element_begin, element_end,
                                   begin, element_end));

       begin = element_end;
       // don't do recursive parsing, just the top level
     }
 }

 void
 Block::encode()
 {
   if (hasWire())
     return;

   OBufferStream os;
   tlv::writeVarNumber(os, type());

   if (hasValue())
     {
       tlv::writeVarNumber(os, value_size());
       os.write(reinterpret_cast<const char*>(value()), value_size());
     }
   else if (m_subBlocks.size() == 0)
     {
       tlv::writeVarNumber(os, 0);
     }
   else
     {
       size_t valueSize = 0;
       for (element_const_iterator i = m_subBlocks.begin(); i != m_subBlocks.end(); ++i) {
         valueSize += i->size();
       }

       tlv::writeVarNumber(os, valueSize);

       for (element_const_iterator i = m_subBlocks.begin(); i != m_subBlocks.end(); ++i) {
         if (i->hasWire())
           os.write(reinterpret_cast<const char*>(i->wire()), i->size());
         else if (i->hasValue()) {
           tlv::writeVarNumber(os, i->type());
           tlv::writeVarNumber(os, i->value_size());
           os.write(reinterpret_cast<const char*>(i->value()), i->value_size());
         }
         else
           BOOST_THROW_EXCEPTION(Error("Underlying value buffer is empty"));
       }
     }

   // now assign correct block

   m_buffer = os.buf();
   m_begin = m_buffer->begin();
   m_end   = m_buffer->end();
   m_size  = m_end - m_begin;

   m_value_begin = m_buffer->begin();
   m_value_end   = m_buffer->end();

   tlv::readType(m_value_begin, m_value_end);
   tlv::readVarNumber(m_value_begin, m_value_end);
 }

 const Block&
 Block::get(uint32_t type) const
 {
   element_const_iterator it = this->find(type);
   if (it != m_subBlocks.end())
     return *it;

   BOOST_THROW_EXCEPTION(Error("(Block::get) Requested a non-existed type [" +
                               boost::lexical_cast<std::string>(type) + "] from Block"));
 }

 Block::element_const_iterator
 Block::find(uint32_t type) const
 {
   return std::find_if(m_subBlocks.begin(), m_subBlocks.end(),
                       [type] (const Block& subBlock) { return subBlock.type() == type; });
 }

 void
 Block::remove(uint32_t type)
 {
   resetWire();

   auto it = std::remove_if(m_subBlocks.begin(), m_subBlocks.end(),
                            [type] (const Block& subBlock) { return subBlock.type() == type; });
   m_subBlocks.resize(it - m_subBlocks.begin());
 }

 Block
 Block::blockFromValue() const
 {
   if (value_size() == 0)
     BOOST_THROW_EXCEPTION(Error("Underlying value buffer is empty"));

   Buffer::const_iterator begin = value_begin(),
                          end = value_end();

   Buffer::const_iterator element_begin = begin;

   uint32_t type = tlv::readType(begin, end);
   uint64_t length = tlv::readVarNumber(begin, end);

   if (length != static_cast<uint64_t>(end - begin))
     BOOST_THROW_EXCEPTION(tlv::Error("TLV length mismatches buffer length"));

   return Block(m_buffer,
                type,
                element_begin, end,
                begin, end);
 }

 Block::operator boost::asio::const_buffer() const
 {
   return boost::asio::const_buffer(wire(), size());
 }

 bool
 Block::empty() const
 {
   return m_type == std::numeric_limits<uint32_t>::max();
 }

 bool
 Block::hasWire() const
 {
   return m_buffer && (m_begin != m_end);
 }

 Buffer::const_iterator
 Block::begin() const
 {
   if (!hasWire())
     BOOST_THROW_EXCEPTION(Error("Underlying wire buffer is empty"));

   return m_begin;
 }

 Buffer::const_iterator
 Block::end() const
 {
   if (!hasWire())
     BOOST_THROW_EXCEPTION(Error("Underlying wire buffer is empty"));

   return m_end;
 }

 const uint8_t*
 Block::wire() const
 {
   if (!hasWire())
     BOOST_THROW_EXCEPTION(Error("(Block::wire) Underlying wire buffer is empty"));

   return &*m_begin;
 }

 size_t
 Block::size() const
 {
   if (hasWire() || hasValue()) {
     return m_size;
   }
   else
     BOOST_THROW_EXCEPTION(Error("Block size cannot be determined (undefined block size)"));
 }

 bool
 Block::hasValue() const
 {
   return static_cast<bool>(m_buffer);
 }

 const uint8_t*
 Block::value() const
 {
   if (!hasValue())
     return 0;

   return &*m_value_begin;
 }

 size_t
 Block::value_size() const
 {
   if (!hasValue())
     return 0;

   return m_value_end - m_value_begin;
 }

 Block::element_iterator
 Block::erase(Block::element_const_iterator position)
 {
   resetWire();

 #ifdef NDN_CXX_HAVE_VECTOR_INSERT_ERASE_CONST_ITERATOR
   return m_subBlocks.erase(position);
 #else
   element_iterator it = m_subBlocks.begin();
   std::advance(it, std::distance(m_subBlocks.cbegin(), position));
   return m_subBlocks.erase(it);
 #endif
 }

 Block::element_iterator
 Block::erase(Block::element_const_iterator first, Block::element_const_iterator last)
 {
   resetWire();

 #ifdef NDN_CXX_HAVE_VECTOR_INSERT_ERASE_CONST_ITERATOR
   return m_subBlocks.erase(first, last);
 #else
   element_iterator itStart = m_subBlocks.begin();
   element_iterator itEnd = m_subBlocks.begin();
   std::advance(itStart, std::distance(m_subBlocks.cbegin(), first));
   std::advance(itEnd, std::distance(m_subBlocks.cbegin(), last));
   return m_subBlocks.erase(itStart, itEnd);
 #endif
 }

 void
 Block::push_back(const Block& element)
 {
   resetWire();
   m_subBlocks.push_back(element);
 }

 Block::element_iterator
 Block::insert(Block::element_const_iterator pos, const Block& element)
 {
   resetWire();

 #ifdef NDN_CXX_HAVE_VECTOR_INSERT_ERASE_CONST_ITERATOR
   return m_subBlocks.insert(pos, element);
 #else
   element_iterator it = m_subBlocks.begin();
   std::advance(it, std::distance(m_subBlocks.cbegin(), pos));
   return m_subBlocks.insert(it, element);
 #endif
 }

 Block::element_const_iterator
 Block::elements_begin() const
 {
   return m_subBlocks.begin();
 }

 Block::element_const_iterator
 Block::elements_end() const
 {
   return m_subBlocks.end();
 }

 size_t
 Block::elements_size() const
 {
   return m_subBlocks.size();
 }

 bool
 Block::operator!=(const Block& other) const
 {
   return !this->operator==(other);
 }

 bool
 Block::operator==(const Block& other) const
 {
   return this->size() == other.size() &&
          std::equal(this->begin(), this->end(), other.begin());
 }

 } // namespace ndn
	/* -- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -- */
	/**
	* Copyright (c) 2013-2016 Regents of the University of California.
	*
	* This file is part of ndn-cxx library (NDN C++ library with eXperimental eXtensions).
	*
	* ndn-cxx library is free software: you can redistribute it and/or modify it under the
	* terms of the GNU Lesser General Public License as published by the Free Software
	* Foundation, either version 3 of the License, or (at your option) any later version.
	*
	* ndn-cxx library is distributed in the hope that it will be useful, but WITHOUT ANY
	* WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A
	* PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details.
	*
	* You should have received copies of the GNU General Public License and GNU Lesser
	* General Public License along with ndn-cxx, e.g., in COPYING.md file. If not, see
	* <http://www.gnu.org/licenses/>.
	*
	* See AUTHORS.md for complete list of ndn-cxx authors and contributors.
	*
	* @author Alexander Afanasyev <http://lasr.cs.ucla.edu/afanasyev/index.html>
	*/

	#include "block.hpp"
	#include "block-helpers.hpp"

	#include "tlv.hpp"
	#include "encoding-buffer.hpp"
	#include "buffer-stream.hpp"

	#include <boost/lexical_cast.hpp>
	#include <boost/asio/buffer.hpp>

	namespace ndn {

	#if NDN_CXX_HAVE_IS_NOTHROW_MOVE_CONSTRUCTIBLE
	static_assert(std::is_nothrow_move_constructible<Block>::value,
	"Block must be MoveConstructible with noexcept");
	#endif // NDN_CXX_HAVE_IS_NOTHROW_MOVE_CONSTRUCTIBLE

	#if NDN_CXX_HAVE_IS_NOTHROW_MOVE_ASSIGNABLE
	static_assert(std::is_nothrow_move_assignable<Block>::value,
	"Block must be MoveAssignable with noexcept");
	#endif // NDN_CXX_HAVE_IS_NOTHROW_MOVE_ASSIGNABLE

	const size_t MAX_SIZE_OF_BLOCK_FROM_STREAM = MAX_NDN_PACKET_SIZE;

	Block::Block()
	: m_type(std::numeric_limits<uint32_t>::max())
	{
	}

	Block::Block(const EncodingBuffer& buffer)
	: m_buffer(const_cast<EncodingBuffer&>(buffer).getBuffer())
	, m_begin(buffer.begin())
	, m_end(buffer.end())
	, m_size(m_end - m_begin)
	{
	m_value_begin = m_begin;
	m_value_end = m_end;

	m_type = tlv::readType(m_value_begin, m_value_end);
	uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
	if (length != static_cast<uint64_t>(m_value_end - m_value_begin))
	{
	BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
	}
	}

	Block::Block(const ConstBufferPtr& wire,
	uint32_t type,
	const Buffer::const_iterator& begin, const Buffer::const_iterator& end,
	const Buffer::const_iterator& valueBegin, const Buffer::const_iterator& valueEnd)
	: m_buffer(wire)
	, m_type(type)
	, m_begin(begin)
	, m_end(end)
	, m_size(m_end - m_begin)
	, m_value_begin(valueBegin)
	, m_value_end(valueEnd)
	{
	}

	Block::Block(const ConstBufferPtr& buffer)
	: m_buffer(buffer)
	, m_begin(m_buffer->begin())
	, m_end(m_buffer->end())
	, m_size(m_end - m_begin)
	{
	m_value_begin = m_begin;
	m_value_end = m_end;

	m_type = tlv::readType(m_value_begin, m_value_end);

	uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
	if (length != static_cast<uint64_t>(m_value_end - m_value_begin))
	{
	BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
	}
	}

	Block::Block(const ConstBufferPtr& buffer,
	const Buffer::const_iterator& begin, const Buffer::const_iterator& end,
	bool verifyLength/* = true*/)
	: m_buffer(buffer)
	, m_begin(begin)
	, m_end(end)
	, m_size(m_end - m_begin)
	{
	m_value_begin = m_begin;
	m_value_end = m_end;

	m_type = tlv::readType(m_value_begin, m_value_end);
	uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
	if (verifyLength) {
	if (length != static_cast<uint64_t>(std::distance(m_value_begin, m_value_end))) {
	BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
	}
	}
	}

	Block::Block(const Block& block,
	const Buffer::const_iterator& begin, const Buffer::const_iterator& end,
	bool verifyLength/* = true*/)
	: m_buffer(block.m_buffer)
	, m_begin(begin)
	, m_end(end)
	, m_size(m_end - m_begin)
	{
	if (!(m_buffer->begin() <= begin && begin <= m_buffer->end()) \|\|
	!(m_buffer->begin() <= end && end <= m_buffer->end())) {
	BOOST_THROW_EXCEPTION(Error("begin/end iterators do not point to the underlying buffer of the block"));
	}

	m_value_begin = m_begin;
	m_value_end = m_end;

	m_type = tlv::readType(m_value_begin, m_value_end);
	uint64_t length = tlv::readVarNumber(m_value_begin, m_value_end);
	if (verifyLength) {
	if (length != static_cast<uint64_t>(std::distance(m_value_begin, m_value_end))) {
	BOOST_THROW_EXCEPTION(tlv::Error("TLV length doesn't match buffer length"));
	}
	}
	}

	Block::Block(const uint8_t* buffer, size_t maxlength)
	{
	const uint8_t* tmp_begin = buffer;
	const uint8_t* tmp_end = buffer + maxlength;

	m_type = tlv::readType(tmp_begin, tmp_end);
	uint64_t length = tlv::readVarNumber(tmp_begin, tmp_end);

	if (length > static_cast<uint64_t>(tmp_end - tmp_begin))
	{
	BOOST_THROW_EXCEPTION(tlv::Error("Not enough data in the buffer to fully parse TLV"));
	}

	m_buffer = make_shared<Buffer>(buffer, (tmp_begin - buffer) + length);

	m_begin = m_buffer->begin();
	m_end = m_buffer->end();
	m_size = m_end - m_begin;

	m_value_begin = m_buffer->begin() + (tmp_begin - buffer);
	m_value_end = m_buffer->end();
	}

	Block::Block(const void* bufferX, size_t maxlength)
	{
	const uint8_t* buffer = reinterpret_cast<const uint8_t*>(bufferX);

	const uint8_t* tmp_begin = buffer;
	const uint8_t* tmp_end = buffer + maxlength;

	m_type = tlv::readType(tmp_begin, tmp_end);
	uint64_t length = tlv::readVarNumber(tmp_begin, tmp_end);

	if (length > static_cast<uint64_t>(tmp_end - tmp_begin))
	{
	BOOST_THROW_EXCEPTION(tlv::Error("Not enough data in the buffer to fully parse TLV"));
	}

	m_buffer = make_shared<Buffer>(buffer, (tmp_begin - buffer) + length);

	m_begin = m_buffer->begin();
	m_end = m_buffer->end();
	m_size = m_end - m_begin;

	m_value_begin = m_buffer->begin() + (tmp_begin - buffer);
	m_value_end = m_buffer->end();
	}

	Block::Block(uint32_t type)
	: m_type(type)
	{
	}

	Block::Block(uint32_t type, const ConstBufferPtr& value)
	: m_buffer(value)
	, m_type(type)
	, m_begin(m_buffer->end())
	, m_end(m_buffer->end())
	, m_value_begin(m_buffer->begin())
	, m_value_end(m_buffer->end())
	{
	m_size = tlv::sizeOfVarNumber(m_type) + tlv::sizeOfVarNumber(value_size()) + value_size();
	}

	Block::Block(uint32_t type, const Block& value)
	: m_buffer(value.m_buffer)
	, m_type(type)
	, m_begin(m_buffer->end())
	, m_end(m_buffer->end())
	, m_value_begin(value.begin())
	, m_value_end(value.end())
	{
	m_size = tlv::sizeOfVarNumber(m_type) + tlv::sizeOfVarNumber(value_size()) + value_size();
	}

	Block
	Block::fromStream(std::istream& is)
	{
	std::istream_iterator<uint8_t> begin(is >> std::noskipws);
	std::istream_iterator<uint8_t> end;

	uint32_t type = tlv::readType(begin, end);
	uint64_t length = tlv::readVarNumber(begin, end);

	if (length == 0) {
	return makeEmptyBlock(type);
	}

	if (length > MAX_SIZE_OF_BLOCK_FROM_STREAM)
	BOOST_THROW_EXCEPTION(tlv::Error("Length of block from stream is too large"));

	// We may still have some problem here, if some exception happens,
	// we may completely lose all the bytes extracted from the stream.

	char buf[MAX_SIZE_OF_BLOCK_FROM_STREAM];
	buf[0] = *begin;
	is.read(buf + 1, length - 1);

	if (length != static_cast<uint64_t>(is.gcount()) + 1) {
	BOOST_THROW_EXCEPTION(tlv::Error("Not enough data in the buffer to fully parse TLV"));
	}

	return makeBinaryBlock(type, buf, length);
	}

	std::tuple<bool, Block>
	Block::fromBuffer(ConstBufferPtr buffer, size_t offset)
	{
	Buffer::const_iterator tempBegin = buffer->begin() + offset;

	uint32_t type;
	bool isOk = tlv::readType(tempBegin, buffer->end(), type);
	if (!isOk)
	return std::make_tuple(false, Block());

	uint64_t length;
	isOk = tlv::readVarNumber(tempBegin, buffer->end(), length);
	if (!isOk)
	return std::make_tuple(false, Block());

	if (length > static_cast<uint64_t>(buffer->end() - tempBegin))
	return std::make_tuple(false, Block());

	return std::make_tuple(true, Block(buffer, type,
	buffer->begin() + offset, tempBegin + length,
	tempBegin, tempBegin + length));
	}

	std::tuple<bool, Block>
	Block::fromBuffer(const uint8_t* buffer, size_t maxSize)
	{
	const uint8_t* tempBegin = buffer;
	const uint8_t* tempEnd = buffer + maxSize;

	uint32_t type = 0;
	bool isOk = tlv::readType(tempBegin, tempEnd, type);
	if (!isOk)
	return std::make_tuple(false, Block());

	uint64_t length;
	isOk = tlv::readVarNumber(tempBegin, tempEnd, length);
	if (!isOk)
	return std::make_tuple(false, Block());

	if (length > static_cast<uint64_t>(tempEnd - tempBegin))
	return std::make_tuple(false, Block());

	BufferPtr sharedBuffer = make_shared<Buffer>(buffer, tempBegin + length);
	return std::make_tuple(true,
	Block(sharedBuffer, type,
	sharedBuffer->begin(), sharedBuffer->end(),
	sharedBuffer->begin() + (tempBegin - buffer), sharedBuffer->end()));
	}

	void
	Block::reset()
	{
	m_buffer.reset(); // reset of the shared_ptr
	m_subBlocks.clear(); // remove all parsed subelements

	m_type = std::numeric_limits<uint32_t>::max();
	m_begin = m_end = m_value_begin = m_value_end = Buffer::const_iterator();
	}

	void
	Block::resetWire()
	{
	m_buffer.reset(); // reset of the shared_ptr
	// keep subblocks

	// keep type
	m_begin = m_end = m_value_begin = m_value_end = Buffer::const_iterator();
	}

	void
	Block::parse() const
	{
	if (!m_subBlocks.empty() \|\| value_size() == 0)
	return;

	Buffer::const_iterator begin = value_begin();
	Buffer::const_iterator end = value_end();

	while (begin != end)
	{
	Buffer::const_iterator element_begin = begin;

	uint32_t type = tlv::readType(begin, end);
	uint64_t length = tlv::readVarNumber(begin, end);

	if (length > static_cast<uint64_t>(end - begin))
	{
	m_subBlocks.clear();
	BOOST_THROW_EXCEPTION(tlv::Error("TLV length exceeds buffer length"));
	}
	Buffer::const_iterator element_end = begin + length;

	m_subBlocks.push_back(Block(m_buffer,
	type,
	element_begin, element_end,
	begin, element_end));

	begin = element_end;
	// don't do recursive parsing, just the top level
	}
	}

	void
	Block::encode()
	{
	if (hasWire())
	return;

	OBufferStream os;
	tlv::writeVarNumber(os, type());

	if (hasValue())
	{
	tlv::writeVarNumber(os, value_size());
	os.write(reinterpret_cast<const char*>(value()), value_size());
	}
	else if (m_subBlocks.size() == 0)
	{
	tlv::writeVarNumber(os, 0);
	}
	else
	{
	size_t valueSize = 0;
	for (element_const_iterator i = m_subBlocks.begin(); i != m_subBlocks.end(); ++i) {
	valueSize += i->size();
	}

	tlv::writeVarNumber(os, valueSize);

	for (element_const_iterator i = m_subBlocks.begin(); i != m_subBlocks.end(); ++i) {
	if (i->hasWire())
	os.write(reinterpret_cast<const char*>(i->wire()), i->size());
	else if (i->hasValue()) {
	tlv::writeVarNumber(os, i->type());
	tlv::writeVarNumber(os, i->value_size());
	os.write(reinterpret_cast<const char*>(i->value()), i->value_size());
	}
	else
	BOOST_THROW_EXCEPTION(Error("Underlying value buffer is empty"));
	}
	}

	// now assign correct block

	m_buffer = os.buf();
	m_begin = m_buffer->begin();
	m_end = m_buffer->end();
	m_size = m_end - m_begin;

	m_value_begin = m_buffer->begin();
	m_value_end = m_buffer->end();

	tlv::readType(m_value_begin, m_value_end);
	tlv::readVarNumber(m_value_begin, m_value_end);
	}

	const Block&
	Block::get(uint32_t type) const
	{
	element_const_iterator it = this->find(type);
	if (it != m_subBlocks.end())
	return *it;

	BOOST_THROW_EXCEPTION(Error("(Block::get) Requested a non-existed type [" +
	boost::lexical_cast<std::string>(type) + "] from Block"));
	}

	Block::element_const_iterator
	Block::find(uint32_t type) const
	{
	return std::find_if(m_subBlocks.begin(), m_subBlocks.end(),
	[type] (const Block& subBlock) { return subBlock.type() == type; });
	}

	void
	Block::remove(uint32_t type)
	{
	resetWire();

	auto it = std::remove_if(m_subBlocks.begin(), m_subBlocks.end(),
	[type] (const Block& subBlock) { return subBlock.type() == type; });
	m_subBlocks.resize(it - m_subBlocks.begin());
	}

	Block
	Block::blockFromValue() const
	{
	if (value_size() == 0)
	BOOST_THROW_EXCEPTION(Error("Underlying value buffer is empty"));

	Buffer::const_iterator begin = value_begin(),
	end = value_end();

	Buffer::const_iterator element_begin = begin;

	uint32_t type = tlv::readType(begin, end);
	uint64_t length = tlv::readVarNumber(begin, end);

	if (length != static_cast<uint64_t>(end - begin))
	BOOST_THROW_EXCEPTION(tlv::Error("TLV length mismatches buffer length"));

	return Block(m_buffer,
	type,
	element_begin, end,
	begin, end);
	}

	Block::operator boost::asio::const_buffer() const
	{
	return boost::asio::const_buffer(wire(), size());
	}

	bool
	Block::empty() const
	{
	return m_type == std::numeric_limits<uint32_t>::max();
	}

	bool
	Block::hasWire() const
	{
	return m_buffer && (m_begin != m_end);
	}

	Buffer::const_iterator
	Block::begin() const
	{
	if (!hasWire())
	BOOST_THROW_EXCEPTION(Error("Underlying wire buffer is empty"));

	return m_begin;
	}

	Buffer::const_iterator
	Block::end() const
	{
	if (!hasWire())
	BOOST_THROW_EXCEPTION(Error("Underlying wire buffer is empty"));

	return m_end;
	}

	const uint8_t*
	Block::wire() const
	{
	if (!hasWire())
	BOOST_THROW_EXCEPTION(Error("(Block::wire) Underlying wire buffer is empty"));

	return &*m_begin;
	}

	size_t
	Block::size() const
	{
	if (hasWire() \|\| hasValue()) {
	return m_size;
	}
	else
	BOOST_THROW_EXCEPTION(Error("Block size cannot be determined (undefined block size)"));
	}

	bool
	Block::hasValue() const
	{
	return static_cast<bool>(m_buffer);
	}

	const uint8_t*
	Block::value() const
	{
	if (!hasValue())
	return 0;

	return &*m_value_begin;
	}

	size_t
	Block::value_size() const
	{
	if (!hasValue())
	return 0;

	return m_value_end - m_value_begin;
	}

	Block::element_iterator
	Block::erase(Block::element_const_iterator position)
	{
	resetWire();

	#ifdef NDN_CXX_HAVE_VECTOR_INSERT_ERASE_CONST_ITERATOR
	return m_subBlocks.erase(position);
	#else
	element_iterator it = m_subBlocks.begin();
	std::advance(it, std::distance(m_subBlocks.cbegin(), position));
	return m_subBlocks.erase(it);
	#endif
	}

	Block::element_iterator
	Block::erase(Block::element_const_iterator first, Block::element_const_iterator last)
	{
	resetWire();

	#ifdef NDN_CXX_HAVE_VECTOR_INSERT_ERASE_CONST_ITERATOR
	return m_subBlocks.erase(first, last);
	#else
	element_iterator itStart = m_subBlocks.begin();
	element_iterator itEnd = m_subBlocks.begin();
	std::advance(itStart, std::distance(m_subBlocks.cbegin(), first));
	std::advance(itEnd, std::distance(m_subBlocks.cbegin(), last));
	return m_subBlocks.erase(itStart, itEnd);
	#endif
	}

	void
	Block::push_back(const Block& element)
	{
	resetWire();
	m_subBlocks.push_back(element);
	}

	Block::element_iterator
	Block::insert(Block::element_const_iterator pos, const Block& element)
	{
	resetWire();

	#ifdef NDN_CXX_HAVE_VECTOR_INSERT_ERASE_CONST_ITERATOR
	return m_subBlocks.insert(pos, element);
	#else
	element_iterator it = m_subBlocks.begin();
	std::advance(it, std::distance(m_subBlocks.cbegin(), pos));
	return m_subBlocks.insert(it, element);
	#endif
	}

	Block::element_const_iterator
	Block::elements_begin() const
	{
	return m_subBlocks.begin();
	}

	Block::element_const_iterator
	Block::elements_end() const
	{
	return m_subBlocks.end();
	}

	size_t
	Block::elements_size() const
	{
	return m_subBlocks.size();
	}

	bool
	Block::operator!=(const Block& other) const
	{
	return !this->operator==(other);
	}

	bool
	Block::operator==(const Block& other) const
	{
	return this->size() == other.size() &&
	std::equal(this->begin(), this->end(), other.begin());
	}

	} // namespace ndn