// // Copyright Aliaksei Levin (levlam@telegram.org), Arseny Smirnov (arseny30@gmail.com) 2014-2018 // // Distributed under the Boost Software License, Version 1.0. (See accompanying // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) // #include "td/utils/port/IPAddress.h" #include "td/utils/format.h" #include "td/utils/logging.h" #include "td/utils/misc.h" #include "td/utils/port/SocketFd.h" #include "td/utils/port/thread_local.h" #include "td/utils/ScopeGuard.h" #include "td/utils/Slice.h" #include "td/utils/utf8.h" #if TD_WINDOWS #include "td/utils/port/wstring_convert.h" #else #include #include #include #endif #include #include namespace td { static bool is_ascii_host_char(char c) { return static_cast(c) <= 127; } static bool is_ascii_host(Slice host) { for (auto c : host) { if (!is_ascii_host_char(c)) { return false; } } return true; } #if !TD_WINDOWS static void punycode(string &result, Slice part) { vector codes; codes.reserve(utf8_length(part)); uint32 processed = 0; auto begin = part.ubegin(); auto end = part.uend(); while (begin != end) { uint32 code; begin = next_utf8_unsafe(begin, &code, "punycode"); if (code <= 127u) { result += to_lower(static_cast(code)); processed++; } codes.push_back(code); } if (processed > 0) { result += '-'; } uint32 n = 127; uint32 delta = 0; int bias = -72; bool is_first = true; while (processed < codes.size()) { // choose lowest not processed code uint32 next_n = 0x110000; for (auto code : codes) { if (code > n && code < next_n) { next_n = code; } } delta += (next_n - n - 1) * (processed + 1); for (auto code : codes) { if (code < next_n) { delta++; } if (code == next_n) { // found next symbol, encode delta int left = static_cast(delta); while (true) { bias += 36; auto t = clamp(bias, 1, 26); if (left < t) { result += static_cast(left + 'a'); break; } left -= t; auto digit = t + left % (36 - t); result += static_cast(digit < 26 ? digit + 'a' : digit - 26 + '0'); left /= 36 - t; } processed++; // update bias if (is_first) { delta /= 700; is_first = false; } else { delta /= 2; } delta += delta / processed; bias = 0; while (delta > 35 * 13) { delta /= 35; bias -= 36; } bias -= static_cast(36 * delta / (delta + 38)); delta = 0; } } delta++; n = next_n; } } #endif Result idn_to_ascii(CSlice host) { if (is_ascii_host(host)) { return to_lower(host); } if (!check_utf8(host)) { return Status::Error("Host name must be encoded in UTF-8"); } const int MAX_DNS_NAME_LENGTH = 255; if (host.size() >= MAX_DNS_NAME_LENGTH * 4) { // upper bound, 4 characters per symbol return Status::Error("Host name is too long"); } #if TD_WINDOWS TRY_RESULT(whost, to_wstring(host)); wchar_t punycode[MAX_DNS_NAME_LENGTH + 1]; int result_length = IdnToAscii(IDN_ALLOW_UNASSIGNED, whost.c_str(), narrow_cast(whost.size()), punycode, MAX_DNS_NAME_LENGTH); if (result_length == 0) { return Status::Error("Host can't be converted to ASCII"); } TRY_RESULT(idn_host, from_wstring(punycode, result_length)); return idn_host; #else auto parts = full_split(Slice(host), '.'); bool is_first = true; string result; for (auto part : parts) { if (!is_first) { result += '.'; } if (is_ascii_host(part)) { result.append(part.data(), part.size()); } else { // TODO nameprep should be applied first, but punycode is better than nothing. // It is better to use libidn/ICU here if available result += "xn--"; punycode(result, part); } is_first = false; } return result; #endif } IPAddress::IPAddress() : is_valid_(false) { } bool IPAddress::is_valid() const { return is_valid_; } bool IPAddress::is_reserved() const { CHECK(is_valid()); if (is_ipv6()) { // TODO proper check for reserved IPv6 addresses return true; } uint32 ip = get_ipv4(); struct IpBlock { CSlice ip; int mask; IpBlock(CSlice ip, int mask) : ip(ip), mask(mask) { } }; static const IpBlock blocks[] = {{"0.0.0.0", 8}, {"10.0.0.0", 8}, {"100.64.0.0", 10}, {"127.0.0.0", 8}, {"169.254.0.0", 16}, {"172.16.0.0", 12}, {"192.0.0.0", 24}, {"192.0.2.0", 24}, {"192.88.99.0", 24}, {"192.168.0.0", 16}, {"198.18.0.0", 15}, {"198.51.100.0", 24}, {"203.0.113.0", 24}, {"224.0.0.0", 3}}; for (auto &block : blocks) { IPAddress block_ip_address; block_ip_address.init_ipv4_port(block.ip, 80).ensure(); uint32 range = block_ip_address.get_ipv4(); CHECK(block.mask != 0); uint32 mask = std::numeric_limits::max() >> (32 - block.mask) << (32 - block.mask); if ((ip & mask) == (range & mask)) { return true; } } return false; } const sockaddr *IPAddress::get_sockaddr() const { CHECK(is_valid()); return &sockaddr_; } size_t IPAddress::get_sockaddr_len() const { CHECK(is_valid()); switch (sockaddr_.sa_family) { case AF_INET6: return sizeof(ipv6_addr_); case AF_INET: return sizeof(ipv4_addr_); default: LOG(FATAL) << "Unknown address family"; return 0; } } int IPAddress::get_address_family() const { return get_sockaddr()->sa_family; } bool IPAddress::is_ipv4() const { return is_valid() && get_address_family() == AF_INET; } bool IPAddress::is_ipv6() const { return is_valid() && get_address_family() == AF_INET6; } uint32 IPAddress::get_ipv4() const { CHECK(is_valid()); CHECK(is_ipv4()); return htonl(ipv4_addr_.sin_addr.s_addr); } Slice IPAddress::get_ipv6() const { static_assert(sizeof(ipv6_addr_.sin6_addr) == 16, "ipv6 size == 16"); CHECK(is_valid()); CHECK(!is_ipv4()); return Slice(ipv6_addr_.sin6_addr.s6_addr, 16); } IPAddress IPAddress::get_any_addr() const { IPAddress res; switch (get_address_family()) { case AF_INET6: res.init_ipv6_any(); break; case AF_INET: res.init_ipv4_any(); break; default: LOG(FATAL) << "Unknown address family"; } return res; } void IPAddress::init_ipv4_any() { is_valid_ = true; ipv4_addr_.sin_family = AF_INET; ipv4_addr_.sin_addr.s_addr = INADDR_ANY; ipv4_addr_.sin_port = 0; } void IPAddress::init_ipv6_any() { is_valid_ = true; ipv6_addr_.sin6_family = AF_INET6; ipv6_addr_.sin6_addr = in6addr_any; ipv6_addr_.sin6_port = 0; } Status IPAddress::init_ipv6_port(CSlice ipv6, int port) { is_valid_ = false; if (port <= 0 || port >= (1 << 16)) { return Status::Error(PSLICE() << "Invalid [port=" << port << "]"); } std::memset(&ipv6_addr_, 0, sizeof(ipv6_addr_)); ipv6_addr_.sin6_family = AF_INET6; ipv6_addr_.sin6_port = htons(static_cast(port)); int err = inet_pton(AF_INET6, ipv6.c_str(), &ipv6_addr_.sin6_addr); if (err == 0) { return Status::Error(PSLICE() << "Failed inet_pton(AF_INET6, " << ipv6 << ")"); } else if (err == -1) { return OS_SOCKET_ERROR(PSLICE() << "Failed inet_pton(AF_INET6, " << ipv6 << ")"); } is_valid_ = true; return Status::OK(); } Status IPAddress::init_ipv6_as_ipv4_port(CSlice ipv4, int port) { return init_ipv6_port(string("::FFFF:").append(ipv4.begin(), ipv4.size()), port); } Status IPAddress::init_ipv4_port(CSlice ipv4, int port) { is_valid_ = false; if (port <= 0 || port >= (1 << 16)) { return Status::Error(PSLICE() << "Invalid [port=" << port << "]"); } std::memset(&ipv4_addr_, 0, sizeof(ipv4_addr_)); ipv4_addr_.sin_family = AF_INET; ipv4_addr_.sin_port = htons(static_cast(port)); int err = inet_pton(AF_INET, ipv4.c_str(), &ipv4_addr_.sin_addr); if (err == 0) { return Status::Error(PSLICE() << "Failed inet_pton(AF_INET, " << ipv4 << ")"); } else if (err == -1) { return OS_SOCKET_ERROR(PSLICE() << "Failed inet_pton(AF_INET, " << ipv4 << ")"); } is_valid_ = true; return Status::OK(); } Status IPAddress::init_host_port(CSlice host, int port, bool prefer_ipv6) { auto str_port = to_string(port); return init_host_port(host, str_port, prefer_ipv6); } Status IPAddress::init_host_port(CSlice host, CSlice port, bool prefer_ipv6) { if (host.empty()) { return Status::Error("Host is empty"); } #if TD_WINDOWS if (host == "..localmachine") { return Status::Error("Host is invalid"); } #endif TRY_RESULT(ascii_host, idn_to_ascii(host)); host = ascii_host; addrinfo hints; addrinfo *info = nullptr; std::memset(&hints, 0, sizeof(hints)); hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_STREAM; hints.ai_protocol = IPPROTO_TCP; LOG(INFO) << "Try to init IP address of " << host << " with port " << port; auto err = getaddrinfo(host.c_str(), port.c_str(), &hints, &info); if (err != 0) { #if TD_WINDOWS return OS_SOCKET_ERROR("Failed to resolve host"); #else return Status::Error(PSLICE() << "Failed to resolve host: " << gai_strerror(err)); #endif } SCOPE_EXIT { freeaddrinfo(info); }; addrinfo *best_info = nullptr; for (auto *ptr = info; ptr != nullptr; ptr = ptr->ai_next) { if (ptr->ai_family == AF_INET && (!prefer_ipv6 || best_info == nullptr)) { // just use first IPv4 address if there is no IPv6 and it isn't preferred best_info = ptr; if (!prefer_ipv6) { break; } } if (ptr->ai_family == AF_INET6 && (prefer_ipv6 || best_info == nullptr)) { // or first IPv6 address if there is no IPv4 and it isn't preferred best_info = ptr; if (prefer_ipv6) { break; } } } if (best_info == nullptr) { return Status::Error("Failed to find IPv4/IPv6 address"); } return init_sockaddr(best_info->ai_addr, narrow_cast(best_info->ai_addrlen)); } Status IPAddress::init_host_port(CSlice host_port) { auto pos = host_port.rfind(':'); if (pos == static_cast(-1)) { return Status::Error("Can't split string into host and port"); } return init_host_port(host_port.substr(0, pos).str(), host_port.substr(pos + 1).str()); } Status IPAddress::init_sockaddr(sockaddr *addr) { if (addr->sa_family == AF_INET6) { return init_sockaddr(addr, sizeof(ipv6_addr_)); } else if (addr->sa_family == AF_INET) { return init_sockaddr(addr, sizeof(ipv4_addr_)); } else { return init_sockaddr(addr, 0); } } Status IPAddress::init_sockaddr(sockaddr *addr, socklen_t len) { if (addr->sa_family == AF_INET6) { CHECK(len == sizeof(ipv6_addr_)); std::memcpy(&ipv6_addr_, reinterpret_cast(addr), sizeof(ipv6_addr_)); } else if (addr->sa_family == AF_INET) { CHECK(len == sizeof(ipv4_addr_)); std::memcpy(&ipv4_addr_, reinterpret_cast(addr), sizeof(ipv4_addr_)); } else { return Status::Error(PSLICE() << "Unknown " << tag("sa_family", addr->sa_family)); } is_valid_ = true; LOG(INFO) << "Have address " << get_ip_str() << " with port " << get_port(); return Status::OK(); } Status IPAddress::init_socket_address(const SocketFd &socket_fd) { is_valid_ = false; auto socket = socket_fd.get_native_fd().socket(); socklen_t len = storage_size(); int ret = getsockname(socket, &sockaddr_, &len); if (ret != 0) { return OS_SOCKET_ERROR("Failed to get socket address"); } is_valid_ = true; return Status::OK(); } Status IPAddress::init_peer_address(const SocketFd &socket_fd) { is_valid_ = false; auto socket = socket_fd.get_native_fd().socket(); socklen_t len = storage_size(); int ret = getpeername(socket, &sockaddr_, &len); if (ret != 0) { return OS_SOCKET_ERROR("Failed to get peer socket address"); } is_valid_ = true; return Status::OK(); } static CSlice get_ip_str(int family, const void *addr) { const int buf_size = INET6_ADDRSTRLEN; static TD_THREAD_LOCAL char *buf; init_thread_local(buf, buf_size); const char *res = inet_ntop(family, #if TD_WINDOWS const_cast(addr), #else addr, #endif buf, buf_size); if (res == nullptr) { return CSlice(); } else { return CSlice(res); } } CSlice IPAddress::ipv4_to_str(uint32 ipv4) { ipv4 = ntohl(ipv4); return ::td::get_ip_str(AF_INET, &ipv4); } Slice IPAddress::get_ip_str() const { if (!is_valid()) { return Slice("0.0.0.0"); } switch (get_address_family()) { case AF_INET6: return ::td::get_ip_str(AF_INET6, &ipv6_addr_.sin6_addr); case AF_INET: return ::td::get_ip_str(AF_INET, &ipv4_addr_.sin_addr); default: UNREACHABLE(); return Slice(); } } int IPAddress::get_port() const { if (!is_valid()) { return 0; } switch (get_address_family()) { case AF_INET6: return ntohs(ipv6_addr_.sin6_port); case AF_INET: return ntohs(ipv4_addr_.sin_port); default: UNREACHABLE(); return 0; } } void IPAddress::set_port(int port) { CHECK(is_valid()); switch (get_address_family()) { case AF_INET6: ipv6_addr_.sin6_port = htons(static_cast(port)); break; case AF_INET: ipv4_addr_.sin_port = htons(static_cast(port)); break; default: UNREACHABLE(); } } bool operator==(const IPAddress &a, const IPAddress &b) { if (!a.is_valid() || !b.is_valid()) { return !a.is_valid() && !b.is_valid(); } if (a.get_address_family() != b.get_address_family()) { return false; } if (a.get_address_family() == AF_INET) { return a.ipv4_addr_.sin_port == b.ipv4_addr_.sin_port && std::memcmp(&a.ipv4_addr_.sin_addr, &b.ipv4_addr_.sin_addr, sizeof(a.ipv4_addr_.sin_addr)) == 0; } else if (a.get_address_family() == AF_INET6) { return a.ipv6_addr_.sin6_port == b.ipv6_addr_.sin6_port && std::memcmp(&a.ipv6_addr_.sin6_addr, &b.ipv6_addr_.sin6_addr, sizeof(a.ipv6_addr_.sin6_addr)) == 0; } LOG(FATAL) << "Unknown address family"; return false; } bool operator<(const IPAddress &a, const IPAddress &b) { if (!a.is_valid() || !b.is_valid()) { return !a.is_valid() && b.is_valid(); } if (a.get_address_family() != b.get_address_family()) { return a.get_address_family() < b.get_address_family(); } if (a.get_address_family() == AF_INET) { if (a.ipv4_addr_.sin_port != b.ipv4_addr_.sin_port) { return a.ipv4_addr_.sin_port < b.ipv4_addr_.sin_port; } return std::memcmp(&a.ipv4_addr_.sin_addr, &b.ipv4_addr_.sin_addr, sizeof(a.ipv4_addr_.sin_addr)) < 0; } else if (a.get_address_family() == AF_INET6) { if (a.ipv6_addr_.sin6_port != b.ipv6_addr_.sin6_port) { return a.ipv6_addr_.sin6_port < b.ipv6_addr_.sin6_port; } return std::memcmp(&a.ipv6_addr_.sin6_addr, &b.ipv6_addr_.sin6_addr, sizeof(a.ipv6_addr_.sin6_addr)) < 0; } LOG(FATAL) << "Unknown address family"; return false; } StringBuilder &operator<<(StringBuilder &builder, const IPAddress &address) { if (!address.is_valid()) { return builder << "[invalid]"; } if (address.get_address_family() == AF_INET) { return builder << "[" << address.get_ip_str() << ":" << address.get_port() << "]"; } else { CHECK(address.get_address_family() == AF_INET6); return builder << "[[" << address.get_ip_str() << "]:" << address.get_port() << "]"; } } } // namespace td