src/name.hpp - ndn-cxx - Gitiles

 /* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
 /*
  * Copyright (c) 2013-2017 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 Jeff Thompson <jefft0@remap.ucla.edu>
  * @author Alexander Afanasyev <http://lasr.cs.ucla.edu/afanasyev/index.html>
  * @author Zhenkai Zhu <http://irl.cs.ucla.edu/~zhenkai/>
  */

 #ifndef NDN_NAME_HPP
 #define NDN_NAME_HPP

 #include "name-component.hpp"
 #include <iterator>

 namespace ndn {

 class Name;

 /** @brief Represents an arbitrary sequence of name components
  */
 using PartialName = Name;

 /** @brief Represents an absolute name
  */
 class Name
 {
 public: // nested types
   class Error : public name::Component::Error
   {
   public:
     explicit
     Error(const std::string& what)
       : name::Component::Error(what)
     {
     }
   };

   using Component = name::Component;
   using component_container = std::vector<Component>;

   // Name appears as a container of name components
   using value_type             = Component;
   using allocator_type         = void;
   using reference              = Component&;
   using const_reference        = const Component&;
   using pointer                = Component*;
   using const_pointer          = const Component*;
   using iterator               = const Component*; // disallow modifying via iterator
   using const_iterator         = const Component*;
   using reverse_iterator       = std::reverse_iterator<iterator>;
   using const_reverse_iterator = std::reverse_iterator<const_iterator>;
   using difference_type        = component_container::difference_type;
   using size_type              = component_container::size_type;

 public: // constructors, encoding, decoding
   /** @brief Create an empty name
    *  @post empty() == true
    */
   Name();

   /** @brief Decode Name from wire encoding
    *  @throw tlv::Error wire encoding is invalid
    *
    *  This is a more efficient equivalent for
    *  @code
    *    Name name;
    *    name.wireDecode(wire);
    *  @endcode
    */
   explicit
   Name(const Block& wire);

   /** @brief Parse name from NDN URI
    *  @param uri a null-terminated URI string
    *  @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
    */
   Name(const char* uri);

   /** @brief Create name from NDN URI
    *  @param uri a URI string
    *  @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
    */
   Name(std::string uri);

   /** @brief Get URI representation of the name
    *  @return URI representation; "ndn:" scheme identifier is not included
    *  @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
    *  @note To print URI representation into a stream, it is more efficient to use ``os << name``.
    */
   std::string
   toUri() const;

   /** @brief Check if this Name instance already has wire encoding
    */
   bool
   hasWire() const
   {
     return m_wire.hasWire();
   }

   /** @brief Fast encoding or block size estimation
    */
   template<encoding::Tag TAG>
   size_t
   wireEncode(EncodingImpl<TAG>& encoder) const;

   /** @brief Perform wire encoding, or return existing wire encoding
    *  @post hasWire() == true
    */
   const Block&
   wireEncode() const;

   /** @brief Decode name from wire encoding
    *  @throw tlv::Error wire encoding is invalid
    *  @post hasWire() == true
    */
   void
   wireDecode(const Block& wire);

   /** @brief Make a deep copy of the name, reallocating the underlying memory buffer
    */
   Name
   deepCopy() const;

 public: // access
   /** @brief Check if name is empty
    */
   bool
   empty() const
   {
     return m_wire.elements().empty();
   }

   /** @brief Get number of components
    */
   size_t
   size() const
   {
     return m_wire.elements_size();
   }

   /** @brief Get the component at the given index
    *  @param i zero-based index; if negative, it starts at the end of this name
    *  @warning Indexing out of bounds triggers undefined behavior.
    */
   const Component&
   get(ssize_t i) const
   {
     if (i < 0) {
       i += size();
     }
     return reinterpret_cast<const Component&>(m_wire.elements()[i]);
   }

   /** @brief Equivalent to get(i)
    */
   const Component&
   operator[](ssize_t i) const
   {
     return get(i);
   }

   /** @brief Get the component at the given index
    *  @param i zero-based index; if negative, size()+i is used instead
    *  @throws Name::Error index is out of bounds
    */
   const Component&
   at(ssize_t i) const;

   /** @brief Extract some components as a sub-name (PartialName)
    *  @param iStartComponent zero-based index of the first component;
    *                         if negative, size()+iStartComponent is used instead
    *  @param nComponents Number of components starting at iStartComponent.
    *                     Use @p npos to get the PartialName until the end of this Name.
    *  @return a new PartialName containing the extracted components
    *
    *  If iStartComponent is positive and indexes out of bounds, returns an empty PartialName.
    *  If iStartComponent is negative and indexes out of bounds, returns components starting from the
    *  beginning of the Name. If nComponents is out of bounds, returns the components until the end
    *  of this Name.
    */
   PartialName
   getSubName(ssize_t iStartComponent, size_t nComponents = npos) const;

   /** @brief Extract a prefix of the name
    *  @param nComponents Number of components; if negative, size()+nComponents is used instead
    *  @return a new Name containing the prefix
    *                    the prefix up to name.size() - N. For example getPrefix(-1)
    *                    returns the name without the final component.
    * @return A new partial name
    */
   PartialName
   getPrefix(ssize_t nComponents) const
   {
     if (nComponents < 0)
       return getSubName(0, size() + nComponents);
     else
       return getSubName(0, nComponents);
   }

 public: // iterators
   /** @brief Begin iterator
    */
   const_iterator
   begin() const
   {
     return reinterpret_cast<const_iterator>(m_wire.elements().data());
   }

   /** @brief End iterator
    */
   const_iterator
   end() const
   {
     return reinterpret_cast<const_iterator>(m_wire.elements().data() + m_wire.elements().size());
   }

   /** @brief Reverse begin iterator
    */
   const_reverse_iterator
   rbegin() const
   {
     return const_reverse_iterator(end());
   }

   /** @brief Reverse end iterator
    */
   const_reverse_iterator
   rend() const
   {
     return const_reverse_iterator(begin());
   }

 public: // modifiers
   /** @brief Append a component
    *  @return a reference to this name, to allow chaining
    */
   Name&
   append(const Component& component)
   {
     m_wire.push_back(component);
     return *this;
   }

   /** @brief Append a component, copying from a zero-terminated byte string
    *  @param value a zero-terminated string; it will be constructed as a component as is
    *               and will not be interpreted as a URI
    *  @note This overload is necessary to ensure unambiguity of ``append("string")``, because both
    *        Component and PartialName are implicitly convertible from zero-terminated byte string.
    *        This overload ensures the string is constructed as a Component.
    */
   Name&
   append(const char* value)
   {
     return append(Component(value));
   }

   /** @brief Append a component, copying from [@p value, @p value + @p valueLength)
    *  @return a reference to this name, to allow chaining
    */
   Name&
   append(const uint8_t* value, size_t valueLength)
   {
     return append(Component(value, valueLength));
   }

   /** @brief Append a component, copying from [@p first, @p last)
    *  @tparam Iterator an InputIterator dereferencing to a one-octet value type. More efficient
    *                   implementation is available when @p Iterator additionally satisfies
    *                   RandomAccessIterator concept.
    *  @param first     begin position of the value
    *  @param last      end position of the value
    *  @return a reference to this name, to allow chaining
    */
   template<class Iterator>
   Name&
   append(Iterator first, Iterator last)
   {
     static_assert(sizeof(typename std::iterator_traits<Iterator>::value_type) == 1,
                   "iterator does not dereference to one-octet value type");
     return append(Component(first, last));
   }

   /** @brief Append a component, decoding from a Block
    *  @param value a Block; if its TLV-TYPE is not NameComponent, it is nested into a NameComponent
    *  @return a reference to this name, to allow chaining
    */
   Name&
   append(const Block& value)
   {
     if (value.type() == tlv::NameComponent) {
       m_wire.push_back(value);
     }
     else {
       m_wire.push_back(Block(tlv::NameComponent, value));
     }

     return *this;
   }

   /** @brief Append a component with a nonNegativeInteger
    *  @sa number the number
    *  @return a reference to this name, to allow chaining
    *  @sa https://named-data.net/doc/ndn-tlv/tlv.html#non-negative-integer-encoding
    */
   Name&
   appendNumber(uint64_t number)
   {
     return append(Component::fromNumber(number));
   }

   /** @brief Append a component with a marked number
    *  @param marker 1-octet marker
    *  @param number the number
    *
    *  The component is encoded as a 1-octet marker, followed by a nonNegativeInteger.
    *
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendNumberWithMarker(uint8_t marker, uint64_t number)
   {
     return append(Component::fromNumberWithMarker(marker, number));
   }

   /** @brief Append a version component
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendVersion(uint64_t version)
   {
     return append(Component::fromVersion(version));
   }

   /** @brief Append a version component based on current time
    *
    *  The version number is the current UNIX timestamp in milliseconds
    *
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendVersion();

   /** @brief Append a segment number (sequential) component
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendSegment(uint64_t segmentNo)
   {
     return append(Component::fromSegment(segmentNo));
   }

   /** @brief Append a segment byte offset component
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendSegmentOffset(uint64_t offset)
   {
     return append(Component::fromSegmentOffset(offset));
   }

   /** @brief Append a timestamp component
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendTimestamp(const time::system_clock::TimePoint& timePoint)
   {
     return append(Component::fromTimestamp(timePoint));
   }

   /** @brief Append a timestamp component based on current time
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendTimestamp();

   /** @brief Append a sequence number component
    *  @return a reference to this name, to allow chaining
    *  @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
    */
   Name&
   appendSequenceNumber(uint64_t seqNo)
   {
     return append(Component::fromSequenceNumber(seqNo));
   }

   /** @brief Append an ImplicitSha256Digest component
    *  @return a reference to this name, to allow chaining
    */
   Name&
   appendImplicitSha256Digest(const ConstBufferPtr& digest)
   {
     return append(Component::fromImplicitSha256Digest(digest));
   }

   /** @brief Append an ImplicitSha256Digest component
    *  @return a reference to this name, to allow chaining
    */
   Name&
   appendImplicitSha256Digest(const uint8_t* digest, size_t digestSize)
   {
     return append(Component::fromImplicitSha256Digest(digest, digestSize));
   }

   /** @brief Append a PartialName
    *  @param name the components to append
    *  @return a reference to this name, to allow chaining
    */
   Name&
   append(const PartialName& name);

   /** @brief Append a component
    *  @note This makes push_back an alias of append, giving Name a similar API as STL vector.
    */
   template<class T>
   void
   push_back(const T& component)
   {
     append(component);
   }

   /** @brief Remove all components
    *  @post empty() == true
    */
   void
   clear()
   {
     m_wire = Block(tlv::Name);
   }

 public: // algorithms
   /** @brief Get the successor of a name
    *
    *  The successor of a name is defined as follows:
    *
    *      N represents the set of NDN Names, and X,Y ∈ N.
    *      Operator < is defined by canonical order on N.
    *      Y is the successor of X, if (a) X < Y, and (b) ∄ Z ∈ N s.t. X < Z < Y.
    *
    *  In plain words, successor of a name is the same name, but with its last component
    *  advanced to a next possible value.
    *
    *  Examples:
    *
    *  - successor for / is /%00
    *  - successor for /%00%01/%01%02 is /%00%01/%01%03
    *  - successor for /%00%01/%01%FF is /%00%01/%02%00
    *  - successor for /%00%01/%FF%FF is /%00%01/%00%00%00
    *
    *  @return a new Name containing the successor
    */
   Name
   getSuccessor() const;

   /** @brief Check if this name is a prefix of another name
    *
    *  This name is a prefix of @p other if the N components of this name are same as the first N
    *  components of @p other.
    *
    *  @retval true this name is a prefix of @p other
    *  @retval false this name is not a prefix of @p other
    */
   bool
   isPrefixOf(const Name& other) const;

   /** @brief Check if this name equals another name
    *
    *  Two names are equal if they have the same number of components, and components at each index
    *  are equal.
    */
   bool
   equals(const Name& other) const;

   /** @brief Compare this to the other Name using NDN canonical ordering.
    *
    *  If the first components of each name are not equal, this returns a negative value if
    *  the first comes before the second using the NDN canonical ordering for name
    *  components, or a positive value if it comes after.  If they are equal, this compares
    *  the second components of each name, etc. If both names are the same up to the size
    *  of the shorter name, this returns a negative value if the first name is shorter than
    *  the second or a positive value if it is longer.  For example, if you std::sort gives:
    *  /a/b/d /a/b/cc /c /c/a /bb .
    *  This is intuitive because all names with the prefix /a are next to each other.
    *  But it may be also be counter-intuitive because /c comes before /bb according
    *  to NDN canonical ordering since it is shorter.
    *
    *  @param other The other Name to compare with.
    *
    *  @retval negative this comes before other in canonical ordering
    *  @retval zero this equals other
    *  @retval positive this comes after other in canonical ordering
    *
    *  @sa https://named-data.net/doc/ndn-tlv/name.html#canonical-order
    */
   int
   compare(const Name& other) const
   {
     return this->compare(0, npos, other);
   }

   /** @brief compares [pos1, pos1+count1) components in this Name
    *         to [pos2, pos2+count2) components in @p other
    *
    *  This is equivalent to this->getSubName(pos1, count1).compare(other.getSubName(pos2, count2));
    */
   int
   compare(size_t pos1, size_t count1,
           const Name& other, size_t pos2 = 0, size_t count2 = npos) const;

 public:
   /** @brief indicates "until the end" in getSubName and compare
    */
   static const size_t npos;

 private:
   mutable Block m_wire;
 };

 NDN_CXX_DECLARE_WIRE_ENCODE_INSTANTIATIONS(Name);

 inline bool
 operator==(const Name& lhs, const Name& rhs)
 {
   return lhs.equals(rhs);
 }

 inline bool
 operator!=(const Name& lhs, const Name& rhs)
 {
   return !lhs.equals(rhs);
 }

 inline bool
 operator<=(const Name& lhs, const Name& rhs)
 {
   return lhs.compare(rhs) <= 0;
 }

 inline bool
 operator<(const Name& lhs, const Name& rhs)
 {
   return lhs.compare(rhs) < 0;
 }

 inline bool
 operator>=(const Name& lhs, const Name& rhs)
 {
   return lhs.compare(rhs) >= 0;
 }

 inline bool
 operator>(const Name& lhs, const Name& rhs)
 {
   return lhs.compare(rhs) > 0;
 }

 /** @brief Print URI representation of a name
  *  @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
  */
 std::ostream&
 operator<<(std::ostream& os, const Name& name);

 /** @brief Parse URI from stream as Name
  *  @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
  */
 std::istream&
 operator>>(std::istream& is, Name& name);

 } // namespace ndn

 namespace std {

 template<>
 struct hash<ndn::Name>
 {
   size_t
   operator()(const ndn::Name& name) const;
 };

 } // namespace std

 #endif // NDN_NAME_HPP
	/* -- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -- */
	/*
	* Copyright (c) 2013-2017 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 Jeff Thompson <jefft0@remap.ucla.edu>
	* @author Alexander Afanasyev <http://lasr.cs.ucla.edu/afanasyev/index.html>
	* @author Zhenkai Zhu <http://irl.cs.ucla.edu/~zhenkai/>
	*/

	#ifndef NDN_NAME_HPP
	#define NDN_NAME_HPP

	#include "name-component.hpp"
	#include <iterator>

	namespace ndn {

	class Name;

	/** @brief Represents an arbitrary sequence of name components
	*/
	using PartialName = Name;

	/** @brief Represents an absolute name
	*/
	class Name
	{
	public: // nested types
	class Error : public name::Component::Error
	{
	public:
	explicit
	Error(const std::string& what)
	: name::Component::Error(what)
	{
	}
	};

	using Component = name::Component;
	using component_container = std::vector<Component>;

	// Name appears as a container of name components
	using value_type = Component;
	using allocator_type = void;
	using reference = Component&;
	using const_reference = const Component&;
	using pointer = Component*;
	using const_pointer = const Component*;
	using iterator = const Component*; // disallow modifying via iterator
	using const_iterator = const Component*;
	using reverse_iterator = std::reverse_iterator<iterator>;
	using const_reverse_iterator = std::reverse_iterator<const_iterator>;
	using difference_type = component_container::difference_type;
	using size_type = component_container::size_type;

	public: // constructors, encoding, decoding
	/** @brief Create an empty name
	* @post empty() == true
	*/
	Name();

	/** @brief Decode Name from wire encoding
	* @throw tlv::Error wire encoding is invalid
	*
	* This is a more efficient equivalent for
	* @code
	* Name name;
	* name.wireDecode(wire);
	* @endcode
	*/
	explicit
	Name(const Block& wire);

	/** @brief Parse name from NDN URI
	* @param uri a null-terminated URI string
	* @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
	*/
	Name(const char* uri);

	/** @brief Create name from NDN URI
	* @param uri a URI string
	* @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
	*/
	Name(std::string uri);

	/** @brief Get URI representation of the name
	* @return URI representation; "ndn:" scheme identifier is not included
	* @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
	* @note To print URI representation into a stream, it is more efficient to use ``os << name``.
	*/
	std::string
	toUri() const;

	/** @brief Check if this Name instance already has wire encoding
	*/
	bool
	hasWire() const
	{
	return m_wire.hasWire();
	}

	/** @brief Fast encoding or block size estimation
	*/
	template<encoding::Tag TAG>
	size_t
	wireEncode(EncodingImpl<TAG>& encoder) const;

	/** @brief Perform wire encoding, or return existing wire encoding
	* @post hasWire() == true
	*/
	const Block&
	wireEncode() const;

	/** @brief Decode name from wire encoding
	* @throw tlv::Error wire encoding is invalid
	* @post hasWire() == true
	*/
	void
	wireDecode(const Block& wire);

	/** @brief Make a deep copy of the name, reallocating the underlying memory buffer
	*/
	Name
	deepCopy() const;

	public: // access
	/** @brief Check if name is empty
	*/
	bool
	empty() const
	{
	return m_wire.elements().empty();
	}

	/** @brief Get number of components
	*/
	size_t
	size() const
	{
	return m_wire.elements_size();
	}

	/** @brief Get the component at the given index
	* @param i zero-based index; if negative, it starts at the end of this name
	* @warning Indexing out of bounds triggers undefined behavior.
	*/
	const Component&
	get(ssize_t i) const
	{
	if (i < 0) {
	i += size();
	}
	return reinterpret_cast<const Component&>(m_wire.elements()[i]);
	}

	/** @brief Equivalent to get(i)
	*/
	const Component&
	operator[](ssize_t i) const
	{
	return get(i);
	}

	/** @brief Get the component at the given index
	* @param i zero-based index; if negative, size()+i is used instead
	* @throws Name::Error index is out of bounds
	*/
	const Component&
	at(ssize_t i) const;

	/** @brief Extract some components as a sub-name (PartialName)
	* @param iStartComponent zero-based index of the first component;
	* if negative, size()+iStartComponent is used instead
	* @param nComponents Number of components starting at iStartComponent.
	* Use @p npos to get the PartialName until the end of this Name.
	* @return a new PartialName containing the extracted components
	*
	* If iStartComponent is positive and indexes out of bounds, returns an empty PartialName.
	* If iStartComponent is negative and indexes out of bounds, returns components starting from the
	* beginning of the Name. If nComponents is out of bounds, returns the components until the end
	* of this Name.
	*/
	PartialName
	getSubName(ssize_t iStartComponent, size_t nComponents = npos) const;

	/** @brief Extract a prefix of the name
	* @param nComponents Number of components; if negative, size()+nComponents is used instead
	* @return a new Name containing the prefix
	* the prefix up to name.size() - N. For example getPrefix(-1)
	* returns the name without the final component.
	* @return A new partial name
	*/
	PartialName
	getPrefix(ssize_t nComponents) const
	{
	if (nComponents < 0)
	return getSubName(0, size() + nComponents);
	else
	return getSubName(0, nComponents);
	}

	public: // iterators
	/** @brief Begin iterator
	*/
	const_iterator
	begin() const
	{
	return reinterpret_cast<const_iterator>(m_wire.elements().data());
	}

	/** @brief End iterator
	*/
	const_iterator
	end() const
	{
	return reinterpret_cast<const_iterator>(m_wire.elements().data() + m_wire.elements().size());
	}

	/** @brief Reverse begin iterator
	*/
	const_reverse_iterator
	rbegin() const
	{
	return const_reverse_iterator(end());
	}

	/** @brief Reverse end iterator
	*/
	const_reverse_iterator
	rend() const
	{
	return const_reverse_iterator(begin());
	}

	public: // modifiers
	/** @brief Append a component
	* @return a reference to this name, to allow chaining
	*/
	Name&
	append(const Component& component)
	{
	m_wire.push_back(component);
	return *this;
	}

	/** @brief Append a component, copying from a zero-terminated byte string
	* @param value a zero-terminated string; it will be constructed as a component as is
	* and will not be interpreted as a URI
	* @note This overload is necessary to ensure unambiguity of ``append("string")``, because both
	* Component and PartialName are implicitly convertible from zero-terminated byte string.
	* This overload ensures the string is constructed as a Component.
	*/
	Name&
	append(const char* value)
	{
	return append(Component(value));
	}

	/** @brief Append a component, copying from [@p value, @p value + @p valueLength)
	* @return a reference to this name, to allow chaining
	*/
	Name&
	append(const uint8_t* value, size_t valueLength)
	{
	return append(Component(value, valueLength));
	}

	/** @brief Append a component, copying from [@p first, @p last)
	* @tparam Iterator an InputIterator dereferencing to a one-octet value type. More efficient
	* implementation is available when @p Iterator additionally satisfies
	* RandomAccessIterator concept.
	* @param first begin position of the value
	* @param last end position of the value
	* @return a reference to this name, to allow chaining
	*/
	template<class Iterator>
	Name&
	append(Iterator first, Iterator last)
	{
	static_assert(sizeof(typename std::iterator_traits<Iterator>::value_type) == 1,
	"iterator does not dereference to one-octet value type");
	return append(Component(first, last));
	}

	/** @brief Append a component, decoding from a Block
	* @param value a Block; if its TLV-TYPE is not NameComponent, it is nested into a NameComponent
	* @return a reference to this name, to allow chaining
	*/
	Name&
	append(const Block& value)
	{
	if (value.type() == tlv::NameComponent) {
	m_wire.push_back(value);
	}
	else {
	m_wire.push_back(Block(tlv::NameComponent, value));
	}

	return *this;
	}

	/** @brief Append a component with a nonNegativeInteger
	* @sa number the number
	* @return a reference to this name, to allow chaining
	* @sa https://named-data.net/doc/ndn-tlv/tlv.html#non-negative-integer-encoding
	*/
	Name&
	appendNumber(uint64_t number)
	{
	return append(Component::fromNumber(number));
	}

	/** @brief Append a component with a marked number
	* @param marker 1-octet marker
	* @param number the number
	*
	* The component is encoded as a 1-octet marker, followed by a nonNegativeInteger.
	*
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendNumberWithMarker(uint8_t marker, uint64_t number)
	{
	return append(Component::fromNumberWithMarker(marker, number));
	}

	/** @brief Append a version component
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendVersion(uint64_t version)
	{
	return append(Component::fromVersion(version));
	}

	/** @brief Append a version component based on current time
	*
	* The version number is the current UNIX timestamp in milliseconds
	*
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendVersion();

	/** @brief Append a segment number (sequential) component
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendSegment(uint64_t segmentNo)
	{
	return append(Component::fromSegment(segmentNo));
	}

	/** @brief Append a segment byte offset component
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendSegmentOffset(uint64_t offset)
	{
	return append(Component::fromSegmentOffset(offset));
	}

	/** @brief Append a timestamp component
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendTimestamp(const time::system_clock::TimePoint& timePoint)
	{
	return append(Component::fromTimestamp(timePoint));
	}

	/** @brief Append a timestamp component based on current time
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendTimestamp();

	/** @brief Append a sequence number component
	* @return a reference to this name, to allow chaining
	* @sa NDN Naming Conventions https://named-data.net/doc/tech-memos/naming-conventions.pdf
	*/
	Name&
	appendSequenceNumber(uint64_t seqNo)
	{
	return append(Component::fromSequenceNumber(seqNo));
	}

	/** @brief Append an ImplicitSha256Digest component
	* @return a reference to this name, to allow chaining
	*/
	Name&
	appendImplicitSha256Digest(const ConstBufferPtr& digest)
	{
	return append(Component::fromImplicitSha256Digest(digest));
	}

	/** @brief Append an ImplicitSha256Digest component
	* @return a reference to this name, to allow chaining
	*/
	Name&
	appendImplicitSha256Digest(const uint8_t* digest, size_t digestSize)
	{
	return append(Component::fromImplicitSha256Digest(digest, digestSize));
	}

	/** @brief Append a PartialName
	* @param name the components to append
	* @return a reference to this name, to allow chaining
	*/
	Name&
	append(const PartialName& name);

	/** @brief Append a component
	* @note This makes push_back an alias of append, giving Name a similar API as STL vector.
	*/
	template<class T>
	void
	push_back(const T& component)
	{
	append(component);
	}

	/** @brief Remove all components
	* @post empty() == true
	*/
	void
	clear()
	{
	m_wire = Block(tlv::Name);
	}

	public: // algorithms
	/** @brief Get the successor of a name
	*
	* The successor of a name is defined as follows:
	*
	* N represents the set of NDN Names, and X,Y ∈ N.
	* Operator < is defined by canonical order on N.
	* Y is the successor of X, if (a) X < Y, and (b) ∄ Z ∈ N s.t. X < Z < Y.
	*
	* In plain words, successor of a name is the same name, but with its last component
	* advanced to a next possible value.
	*
	* Examples:
	*
	* - successor for / is /%00
	* - successor for /%00%01/%01%02 is /%00%01/%01%03
	* - successor for /%00%01/%01%FF is /%00%01/%02%00
	* - successor for /%00%01/%FF%FF is /%00%01/%00%00%00
	*
	* @return a new Name containing the successor
	*/
	Name
	getSuccessor() const;

	/** @brief Check if this name is a prefix of another name
	*
	* This name is a prefix of @p other if the N components of this name are same as the first N
	* components of @p other.
	*
	* @retval true this name is a prefix of @p other
	* @retval false this name is not a prefix of @p other
	*/
	bool
	isPrefixOf(const Name& other) const;

	/** @brief Check if this name equals another name
	*
	* Two names are equal if they have the same number of components, and components at each index
	* are equal.
	*/
	bool
	equals(const Name& other) const;

	/** @brief Compare this to the other Name using NDN canonical ordering.
	*
	* If the first components of each name are not equal, this returns a negative value if
	* the first comes before the second using the NDN canonical ordering for name
	* components, or a positive value if it comes after. If they are equal, this compares
	* the second components of each name, etc. If both names are the same up to the size
	* of the shorter name, this returns a negative value if the first name is shorter than
	* the second or a positive value if it is longer. For example, if you std::sort gives:
	* /a/b/d /a/b/cc /c /c/a /bb .
	* This is intuitive because all names with the prefix /a are next to each other.
	* But it may be also be counter-intuitive because /c comes before /bb according
	* to NDN canonical ordering since it is shorter.
	*
	* @param other The other Name to compare with.
	*
	* @retval negative this comes before other in canonical ordering
	* @retval zero this equals other
	* @retval positive this comes after other in canonical ordering
	*
	* @sa https://named-data.net/doc/ndn-tlv/name.html#canonical-order
	*/
	int
	compare(const Name& other) const
	{
	return this->compare(0, npos, other);
	}

	/** @brief compares [pos1, pos1+count1) components in this Name
	* to [pos2, pos2+count2) components in @p other
	*
	* This is equivalent to this->getSubName(pos1, count1).compare(other.getSubName(pos2, count2));
	*/
	int
	compare(size_t pos1, size_t count1,
	const Name& other, size_t pos2 = 0, size_t count2 = npos) const;

	public:
	/** @brief indicates "until the end" in getSubName and compare
	*/
	static const size_t npos;

	private:
	mutable Block m_wire;
	};

	NDN_CXX_DECLARE_WIRE_ENCODE_INSTANTIATIONS(Name);

	inline bool
	operator==(const Name& lhs, const Name& rhs)
	{
	return lhs.equals(rhs);
	}

	inline bool
	operator!=(const Name& lhs, const Name& rhs)
	{
	return !lhs.equals(rhs);
	}

	inline bool
	operator<=(const Name& lhs, const Name& rhs)
	{
	return lhs.compare(rhs) <= 0;
	}

	inline bool
	operator<(const Name& lhs, const Name& rhs)
	{
	return lhs.compare(rhs) < 0;
	}

	inline bool
	operator>=(const Name& lhs, const Name& rhs)
	{
	return lhs.compare(rhs) >= 0;
	}

	inline bool
	operator>(const Name& lhs, const Name& rhs)
	{
	return lhs.compare(rhs) > 0;
	}

	/** @brief Print URI representation of a name
	* @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
	*/
	std::ostream&
	operator<<(std::ostream& os, const Name& name);

	/** @brief Parse URI from stream as Name
	* @sa https://named-data.net/doc/ndn-tlv/name.html#ndn-uri-scheme
	*/
	std::istream&
	operator>>(std::istream& is, Name& name);

	} // namespace ndn

	namespace std {

	template<>
	struct hash<ndn::Name>
	{
	size_t
	operator()(const ndn::Name& name) const;
	};

	} // namespace std

	#endif // NDN_NAME_HPP