/* * Copyright (c) Facebook, Inc. and its affiliates. * * 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. */ #include #include #include #include #include #include #include #include using std::ostream; using std::string; using std::vector; namespace folly { // free functions size_t hash_value(const IPAddress& addr) { return addr.hash(); } ostream& operator<<(ostream& os, const IPAddress& addr) { os << addr.str(); return os; } void toAppend(IPAddress addr, string* result) { result->append(addr.str()); } void toAppend(IPAddress addr, fbstring* result) { result->append(addr.str()); } bool IPAddress::validate(StringPiece ip) noexcept { return IPAddressV4::validate(ip) || IPAddressV6::validate(ip); } // public static IPAddressV4 IPAddress::createIPv4(const IPAddress& addr) { if (addr.isV4()) { return addr.asV4(); } else { return addr.asV6().createIPv4(); } } // public static IPAddressV6 IPAddress::createIPv6(const IPAddress& addr) { if (addr.isV6()) { return addr.asV6(); } else { return addr.asV4().createIPv6(); } } namespace { vector splitIpSlashCidr(StringPiece ipSlashCidr) { vector vec; split("/", ipSlashCidr, vec); return vec; } } // namespace // public static CIDRNetwork IPAddress::createNetwork( StringPiece ipSlashCidr, int defaultCidr, /* = -1 */ bool applyMask /* = true */) { auto const ret = IPAddress::tryCreateNetwork(ipSlashCidr, defaultCidr, applyMask); if (ret.hasValue()) { return ret.value(); } if (ret.error() == CIDRNetworkError::INVALID_DEFAULT_CIDR) { throw std::range_error("defaultCidr must be <= UINT8_MAX"); } if (ret.error() == CIDRNetworkError::INVALID_IP_SLASH_CIDR) { throw IPAddressFormatException(sformat( "Invalid ipSlashCidr specified. Expected IP/CIDR format, got '{}'", ipSlashCidr)); } // Handler the remaining error cases. We re-parse the ip/mask pair // to make error messages more meaningful auto const vec = splitIpSlashCidr(ipSlashCidr); switch (ret.error()) { case CIDRNetworkError::INVALID_IP: CHECK_GE(vec.size(), 1); throw IPAddressFormatException( sformat("Invalid IP address {}", vec.at(0))); case CIDRNetworkError::INVALID_CIDR: CHECK_GE(vec.size(), 2); throw IPAddressFormatException( sformat("Mask value '{}' not a valid mask", vec.at(1))); case CIDRNetworkError::CIDR_MISMATCH: { auto const subnet = IPAddress::tryFromString(vec.at(0)).value(); auto cidr = static_cast( (defaultCidr > -1) ? defaultCidr : (subnet.isV4() ? 32 : 128)); throw IPAddressFormatException(sformat( "CIDR value '{}' is > network bit count '{}'", vec.size() == 2 ? vec.at(1) : to(cidr), subnet.bitCount())); } case CIDRNetworkError::INVALID_DEFAULT_CIDR: case CIDRNetworkError::INVALID_IP_SLASH_CIDR: default: // unreachable break; } CHECK(0); return CIDRNetwork{}; } // public static Expected IPAddress::tryCreateNetwork( StringPiece ipSlashCidr, int defaultCidr, bool applyMask) { if (defaultCidr > std::numeric_limits::max()) { return makeUnexpected(CIDRNetworkError::INVALID_DEFAULT_CIDR); } auto const vec = splitIpSlashCidr(ipSlashCidr); auto const elemCount = vec.size(); if (elemCount == 0 || // weird invalid string elemCount > 2) { // invalid string (IP/CIDR/extras) return makeUnexpected(CIDRNetworkError::INVALID_IP_SLASH_CIDR); } auto const subnet = IPAddress::tryFromString(vec.at(0)); if (subnet.hasError()) { return makeUnexpected(CIDRNetworkError::INVALID_IP); } auto cidr = static_cast( (defaultCidr > -1) ? defaultCidr : (subnet.value().isV4() ? 32 : 128)); if (elemCount == 2) { auto const maybeCidr = tryTo(vec.at(1)); if (maybeCidr.hasError()) { return makeUnexpected(CIDRNetworkError::INVALID_CIDR); } cidr = maybeCidr.value(); } if (cidr > subnet.value().bitCount()) { return makeUnexpected(CIDRNetworkError::CIDR_MISMATCH); } return std::make_pair( applyMask ? subnet.value().mask(cidr) : subnet.value(), cidr); } // public static std::string IPAddress::networkToString(const CIDRNetwork& network) { return sformat("{}/{}", network.first.str(), network.second); } // public static IPAddress IPAddress::fromBinary(ByteRange bytes) { if (bytes.size() == 4) { return IPAddress(IPAddressV4::fromBinary(bytes)); } else if (bytes.size() == 16) { return IPAddress(IPAddressV6::fromBinary(bytes)); } else { string hexval = detail::Bytes::toHex(bytes.data(), bytes.size()); throw IPAddressFormatException( sformat("Invalid address with hex value '{}'", hexval)); } } Expected IPAddress::tryFromBinary( ByteRange bytes) noexcept { // Check IPv6 first since it's our main protocol. if (bytes.size() == 16) { return IPAddressV6::tryFromBinary(bytes); } else if (bytes.size() == 4) { return IPAddressV4::tryFromBinary(bytes); } else { return makeUnexpected(IPAddressFormatError::UNSUPPORTED_ADDR_FAMILY); } } // public static IPAddress IPAddress::fromLong(uint32_t src) { return IPAddress(IPAddressV4::fromLong(src)); } IPAddress IPAddress::fromLongHBO(uint32_t src) { return IPAddress(IPAddressV4::fromLongHBO(src)); } // default constructor IPAddress::IPAddress() : addr_(), family_(AF_UNSPEC) {} // public string constructor IPAddress::IPAddress(StringPiece str) : addr_(), family_(AF_UNSPEC) { auto maybeIp = tryFromString(str); if (maybeIp.hasError()) { throw IPAddressFormatException( to("Invalid IP address '", str, "'")); } *this = maybeIp.value(); } Expected IPAddress::tryFromString( StringPiece str) noexcept { // need to check for V4 address second, since IPv4-mapped IPv6 addresses may // contain a period if (str.find(':') != string::npos) { return IPAddressV6::tryFromString(str); } else if (str.find('.') != string::npos) { return IPAddressV4::tryFromString(str); } else { return makeUnexpected(IPAddressFormatError::UNSUPPORTED_ADDR_FAMILY); } } // public sockaddr constructor IPAddress::IPAddress(const sockaddr* addr) : addr_(), family_(AF_UNSPEC) { if (addr == nullptr) { throw IPAddressFormatException("sockaddr == nullptr"); } family_ = addr->sa_family; switch (addr->sa_family) { case AF_INET: { auto v4addr = reinterpret_cast(addr); addr_.ipV4Addr = IPAddressV4(v4addr->sin_addr); break; } case AF_INET6: { auto v6addr = reinterpret_cast(addr); addr_.ipV6Addr = IPAddressV6(*v6addr); break; } default: throw InvalidAddressFamilyException(addr->sa_family); } } // public ipv4 constructor IPAddress::IPAddress(const IPAddressV4 ipV4Addr) noexcept : addr_(ipV4Addr), family_(AF_INET) {} // public ipv4 constructor IPAddress::IPAddress(const in_addr ipV4Addr) noexcept : addr_(IPAddressV4(ipV4Addr)), family_(AF_INET) {} // public ipv6 constructor IPAddress::IPAddress(const IPAddressV6& ipV6Addr) noexcept : addr_(ipV6Addr), family_(AF_INET6) {} // public ipv6 constructor IPAddress::IPAddress(const in6_addr& ipV6Addr) noexcept : addr_(IPAddressV6(ipV6Addr)), family_(AF_INET6) {} // Assign from V4 address IPAddress& IPAddress::operator=(const IPAddressV4& ipv4_addr) noexcept { addr_ = IPAddressV46(ipv4_addr); family_ = AF_INET; return *this; } // Assign from V6 address IPAddress& IPAddress::operator=(const IPAddressV6& ipv6_addr) noexcept { addr_ = IPAddressV46(ipv6_addr); family_ = AF_INET6; return *this; } // public bool IPAddress::inSubnet(StringPiece cidrNetwork) const { auto subnetInfo = IPAddress::createNetwork(cidrNetwork); return inSubnet(subnetInfo.first, subnetInfo.second); } // public bool IPAddress::inSubnet(const IPAddress& subnet, uint8_t cidr) const { if (bitCount() == subnet.bitCount()) { if (isV4()) { return asV4().inSubnet(subnet.asV4(), cidr); } else { return asV6().inSubnet(subnet.asV6(), cidr); } } // an IPv4 address can never belong in a IPv6 subnet unless the IPv6 is a 6to4 // address and vice-versa if (isV6()) { const IPAddressV6& v6addr = asV6(); const IPAddressV4& v4subnet = subnet.asV4(); if (v6addr.is6To4()) { return v6addr.getIPv4For6To4().inSubnet(v4subnet, cidr); } } else if (subnet.isV6()) { const IPAddressV6& v6subnet = subnet.asV6(); const IPAddressV4& v4addr = asV4(); if (v6subnet.is6To4()) { return v4addr.inSubnet(v6subnet.getIPv4For6To4(), cidr); } } return false; } // public bool IPAddress::inSubnetWithMask(const IPAddress& subnet, ByteRange mask) const { auto mkByteArray4 = [&]() -> ByteArray4 { ByteArray4 ba{{0}}; std::memcpy(ba.data(), mask.begin(), std::min(mask.size(), 4)); return ba; }; if (bitCount() == subnet.bitCount()) { if (isV4()) { return asV4().inSubnetWithMask(subnet.asV4(), mkByteArray4()); } else { ByteArray16 ba{{0}}; std::memcpy(ba.data(), mask.begin(), std::min(mask.size(), 16)); return asV6().inSubnetWithMask(subnet.asV6(), ba); } } // an IPv4 address can never belong in a IPv6 subnet unless the IPv6 is a 6to4 // address and vice-versa if (isV6()) { const IPAddressV6& v6addr = asV6(); const IPAddressV4& v4subnet = subnet.asV4(); if (v6addr.is6To4()) { return v6addr.getIPv4For6To4().inSubnetWithMask(v4subnet, mkByteArray4()); } } else if (subnet.isV6()) { const IPAddressV6& v6subnet = subnet.asV6(); const IPAddressV4& v4addr = asV4(); if (v6subnet.is6To4()) { return v4addr.inSubnetWithMask(v6subnet.getIPv4For6To4(), mkByteArray4()); } } return false; } uint8_t IPAddress::getNthMSByte(size_t byteIndex) const { const auto highestIndex = byteCount() - 1; if (byteIndex > highestIndex) { throw std::invalid_argument(sformat( "Byte index must be <= {} for addresses of type: {}", highestIndex, detail::familyNameStr(family()))); } if (isV4()) { return asV4().bytes()[byteIndex]; } return asV6().bytes()[byteIndex]; } // public bool operator==(const IPAddress& addr1, const IPAddress& addr2) { if (addr1.empty() || addr2.empty()) { return addr1.empty() == addr2.empty(); } if (addr1.family() == addr2.family()) { if (addr1.isV6()) { return (addr1.asV6() == addr2.asV6()); } else if (addr1.isV4()) { return (addr1.asV4() == addr2.asV4()); } else { CHECK_EQ(addr1.family(), AF_UNSPEC); // Two default initialized AF_UNSPEC addresses should be considered equal. // AF_UNSPEC is the only other value for which an IPAddress can be // created, in the default constructor case. return true; } } // addr1 is v4 mapped v6 address, addr2 is v4 if (addr1.isIPv4Mapped() && addr2.isV4()) { if (IPAddress::createIPv4(addr1) == addr2.asV4()) { return true; } } // addr2 is v4 mapped v6 address, addr1 is v4 if (addr2.isIPv4Mapped() && addr1.isV4()) { if (IPAddress::createIPv4(addr2) == addr1.asV4()) { return true; } } // we only compare IPv4 and IPv6 addresses return false; } bool operator<(const IPAddress& addr1, const IPAddress& addr2) { if (addr1.empty() || addr2.empty()) { return addr1.empty() < addr2.empty(); } if (addr1.family() == addr2.family()) { if (addr1.isV6()) { return (addr1.asV6() < addr2.asV6()); } else if (addr1.isV4()) { return (addr1.asV4() < addr2.asV4()); } else { CHECK_EQ(addr1.family(), AF_UNSPEC); // Two default initialized AF_UNSPEC addresses can not be less than each // other. AF_UNSPEC is the only other value for which an IPAddress can be // created, in the default constructor case. return false; } } if (addr1.isV6()) { // means addr2 is v4, convert it to a mapped v6 address and compare return addr1.asV6() < addr2.asV4().createIPv6(); } if (addr2.isV6()) { // means addr2 is v6, convert addr1 to v4 mapped and compare return addr1.asV4().createIPv6() < addr2.asV6(); } return false; } CIDRNetwork IPAddress::longestCommonPrefix( const CIDRNetwork& one, const CIDRNetwork& two) { if (one.first.family() != two.first.family()) { throw std::invalid_argument(sformat( "Can't compute longest common prefix between addresses of different" "families. Passed: {} and {}", detail::familyNameStr(one.first.family()), detail::familyNameStr(two.first.family()))); } if (one.first.isV4()) { auto prefix = IPAddressV4::longestCommonPrefix( {one.first.asV4(), one.second}, {two.first.asV4(), two.second}); return {IPAddress(prefix.first), prefix.second}; } else if (one.first.isV6()) { auto prefix = IPAddressV6::longestCommonPrefix( {one.first.asV6(), one.second}, {two.first.asV6(), two.second}); return {IPAddress(prefix.first), prefix.second}; } else { throw std::invalid_argument("Unknown address family"); } } // clang-format off [[noreturn]] void IPAddress::asV4Throw() const { auto fam = detail::familyNameStr(family()); throw InvalidAddressFamilyException( sformat("Can't convert address with family {} to AF_INET address", fam)); } [[noreturn]] void IPAddress::asV6Throw() const { auto fam = detail::familyNameStr(family()); throw InvalidAddressFamilyException( sformat("Can't convert address with family {} to AF_INET6 address", fam)); } // clang-format on } // namespace folly