/* * Copyright 2016 Facebook, Inc. * * Licensed 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. */ #pragma once #include #include #include #include #include #include #include #include #include namespace folly { class IPAddress; class IPAddressV4; class IPAddressV6; class MacAddress; /** * Pair of IPAddressV6, netmask */ typedef std::pair CIDRNetworkV6; /** * Specialization for IPv6 addresses */ typedef std::array ByteArray16; /** * IPv6 variation of IPAddress. * * Added methods: createIPv4, getIPv4For6To4, is6To4, * isTeredo, isIPv4Mapped, tryCreateIPv4, type * * @see IPAddress * * Notes on scope ID parsing: * * getaddrinfo() uses if_nametoindex() to convert interface names * into a numerical index. For instance, * "fe80::202:c9ff:fec1:ee08%eth0" may return scope ID 2 on some * hosts, but other numbers on other hosts. It will fail entirely on * hosts without an eth0 interface. * * Serializing / Deserializing IPAddressB6's on different hosts * that use link-local scoping probably won't work. */ class IPAddressV6 { public: // V6 Address Type enum Type { TEREDO, T6TO4, NORMAL, }; // A constructor parameter to indicate that we should create a link-local // IPAddressV6. enum LinkLocalTag { LINK_LOCAL, }; // Thrown when a type assertion fails typedef std::runtime_error TypeError; // Binary prefix for teredo networks static const uint32_t PREFIX_TEREDO; // Binary prefix for 6to4 networks static const uint32_t PREFIX_6TO4; // Size of std::string returned by toFullyQualified. static constexpr size_t kToFullyQualifiedSize = 8 /*words*/ * 4 /*hex chars per word*/ + 7 /*separators*/; // returns true iff the input string can be parsed as an ipv6-address static bool validate(StringPiece ip); /** * Create a new IPAddress instance from the provided binary data. * @throws IPAddressFormatException if the input length is not 16 bytes. */ static IPAddressV6 fromBinary(ByteRange bytes) { IPAddressV6 addr; addr.setFromBinary(bytes); return addr; } /** * Returns the address as a Range. */ ByteRange toBinary() const { return ByteRange((const unsigned char *) &addr_.in6Addr_.s6_addr, 16); } /** * Default constructor for IPAddressV6. * * The address value will be ::0 */ IPAddressV6(); // Create an IPAddressV6 from a string // @throws IPAddressFormatException // explicit IPAddressV6(StringPiece ip); // ByteArray16 constructor explicit IPAddressV6(const ByteArray16& src); // in6_addr constructor explicit IPAddressV6(const in6_addr& src); // sockaddr_in6 constructor explicit IPAddressV6(const sockaddr_in6& src); /** * Create a link-local IPAddressV6 from the specified ethernet MAC address. */ IPAddressV6(LinkLocalTag tag, MacAddress mac); // return the mapped V4 address // @throws IPAddressFormatException if !isIPv4Mapped IPAddressV4 createIPv4() const; /** * Return a V4 address if this is a 6To4 address. * @throws TypeError if not a 6To4 address */ IPAddressV4 getIPv4For6To4() const; // Return true if a 6TO4 address bool is6To4() const { return type() == IPAddressV6::Type::T6TO4; } // Return true if a TEREDO address bool isTeredo() const { return type() == IPAddressV6::Type::TEREDO; } // return true if this is v4-to-v6-mapped bool isIPv4Mapped() const; // Return the V6 address type Type type() const; /** * @see IPAddress#bitCount * @returns 128 */ static size_t bitCount() { return 128; } /** * @see IPAddress#toJson */ std::string toJson() const; size_t hash() const; // @see IPAddress#inSubnet // @throws IPAddressFormatException if string doesn't contain a V6 address bool inSubnet(StringPiece cidrNetwork) const; // return true if address is in subnet bool inSubnet(const IPAddressV6& subnet, uint8_t cidr) const { return inSubnetWithMask(subnet, fetchMask(cidr)); } bool inSubnetWithMask(const IPAddressV6& subnet, const ByteArray16& mask) const; // @see IPAddress#isLoopback bool isLoopback() const; // @see IPAddress#isNonroutable bool isNonroutable() const { return !isRoutable(); } /** * Return true if this address is routable. */ bool isRoutable() const; // @see IPAddress#isPrivate bool isPrivate() const; /** * Return true if this is a link-local IPv6 address. * * Note that this only returns true for addresses in the fe80::/10 range. * It returns false for the loopback address (::1), even though this address * is also effectively has link-local scope. It also returns false for * link-scope and interface-scope multicast addresses. */ bool isLinkLocal() const; /** * Return true if this is a multicast address. */ bool isMulticast() const; /** * Return the flags for a multicast address. * This method may only be called on multicast addresses. */ uint8_t getMulticastFlags() const; /** * Return the scope for a multicast address. * This method may only be called on multicast addresses. */ uint8_t getMulticastScope() const; // @see IPAddress#isZero bool isZero() const { constexpr auto zero = ByteArray16{{}}; return 0 == std::memcmp(bytes(), zero.data(), zero.size()); } bool isLinkLocalBroadcast() const; // @see IPAddress#mask IPAddressV6 mask(size_t numBits) const; // return underlying in6_addr structure in6_addr toAddr() const { return addr_.in6Addr_; } uint16_t getScopeId() const { return scope_; } void setScopeId(uint16_t scope) { scope_ = scope; } sockaddr_in6 toSockAddr() const { sockaddr_in6 addr; memset(&addr, 0, sizeof(sockaddr_in6)); addr.sin6_family = AF_INET6; addr.sin6_scope_id = scope_; memcpy(&addr.sin6_addr, &addr_.in6Addr_, sizeof(in6_addr)); return addr; } ByteArray16 toByteArray() const { ByteArray16 ba{{0}}; std::memcpy(ba.data(), bytes(), 16); return ba; } // @see IPAddress#toFullyQualified std::string toFullyQualified() const; // @see IPAddress#str std::string str() const; // @see IPAddress#version size_t version() const { return 6; } /** * Return the solicited-node multicast address for this address. */ IPAddressV6 getSolicitedNodeAddress() const; /** * Return the mask associated with the given number of bits. * If for instance numBits was 24 (e.g. /24) then the V4 mask returned should * be {0xff, 0xff, 0xff, 0x00}. * @param [in] numBits bitmask to retrieve * @throws abort if numBits == 0 or numBits > bitCount() * @return mask associated with numBits */ static const ByteArray16 fetchMask(size_t numBits); // Given 2 IPAddressV6,mask pairs extract the longest common IPAddress, // mask pair static CIDRNetworkV6 longestCommonPrefix( const CIDRNetworkV6& one, const CIDRNetworkV6& two); // Number of bytes in the address representation. static constexpr size_t byteCount() { return 16; } //get nth most significant bit - 0 indexed bool getNthMSBit(size_t bitIndex) const { return detail::getNthMSBitImpl(*this, bitIndex, AF_INET6); } //get nth most significant byte - 0 indexed uint8_t getNthMSByte(size_t byteIndex) const; //get nth bit - 0 indexed bool getNthLSBit(size_t bitIndex) const { return getNthMSBit(bitCount() - bitIndex - 1); } //get nth byte - 0 indexed uint8_t getNthLSByte(size_t byteIndex) const { return getNthMSByte(byteCount() - byteIndex - 1); } const unsigned char* bytes() const { return addr_.in6Addr_.s6_addr; } protected: /** * Helper that returns true if the address is in the binary subnet specified * by addr. */ bool inBinarySubnet(const std::array addr, size_t numBits) const; private: union AddressStorage { in6_addr in6Addr_; ByteArray16 bytes_; AddressStorage() { std::memset(this, 0, sizeof(AddressStorage)); } explicit AddressStorage(const ByteArray16& bytes): bytes_(bytes) {} explicit AddressStorage(const in6_addr& addr): in6Addr_(addr) {} explicit AddressStorage(MacAddress mac); } addr_; // Link-local scope id. This should always be 0 for IPAddresses that // are *not* link-local. uint16_t scope_{0}; static const std::array masks_; /** * Set the current IPAddressV6 object to have the address specified by bytes. * @throws IPAddressFormatException if bytes.size() is not 16. */ void setFromBinary(ByteRange bytes); }; // boost::hash uses hash_value() so this allows boost::hash to work // automatically for IPAddressV6 std::size_t hash_value(const IPAddressV6& addr); std::ostream& operator<<(std::ostream& os, const IPAddressV6& addr); // Define toAppend() to allow IPAddressV6 to be used with to void toAppend(IPAddressV6 addr, std::string* result); void toAppend(IPAddressV6 addr, fbstring* result); /** * Return true if two addresses are equal. */ inline bool operator==(const IPAddressV6& addr1, const IPAddressV6& addr2) { return (std::memcmp(addr1.toAddr().s6_addr, addr2.toAddr().s6_addr, 16) == 0) && addr1.getScopeId() == addr2.getScopeId(); } // Return true if addr1 < addr2 inline bool operator<(const IPAddressV6& addr1, const IPAddressV6& addr2) { auto cmp = std::memcmp(addr1.toAddr().s6_addr, addr2.toAddr().s6_addr, 16) < 0; if (!cmp) { return addr1.getScopeId() < addr2.getScopeId(); } else { return cmp; } } // Derived operators inline bool operator!=(const IPAddressV6& a, const IPAddressV6& b) { return !(a == b); } inline bool operator>(const IPAddressV6& a, const IPAddressV6& b) { return b < a; } inline bool operator<=(const IPAddressV6& a, const IPAddressV6& b) { return !(a > b); } inline bool operator>=(const IPAddressV6& a, const IPAddressV6& b) { return !(a < b); } } // folly namespace std { template<> struct hash { size_t operator()(const folly::IPAddressV6& addr) const { return addr.hash(); } }; } // std