From 3cd01b932e1c85394272ae64fae67ebeda92fb00 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sat, 13 Apr 2024 23:11:59 +0200 Subject: Adding upstream version 1.8.3. Signed-off-by: Daniel Baumann --- iputils.hh | 1723 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1723 insertions(+) create mode 100644 iputils.hh (limited to 'iputils.hh') diff --git a/iputils.hh b/iputils.hh new file mode 100644 index 0000000..dafc24a --- /dev/null +++ b/iputils.hh @@ -0,0 +1,1723 @@ +/* + * This file is part of PowerDNS or dnsdist. + * Copyright -- PowerDNS.COM B.V. and its contributors + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of version 2 of the GNU General Public License as + * published by the Free Software Foundation. + * + * In addition, for the avoidance of any doubt, permission is granted to + * link this program with OpenSSL and to (re)distribute the binaries + * produced as the result of such linking. + * + * This program 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 General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. + */ +#pragma once +#include +#include +#include +#include +#include +#include +#include +#include +#include "pdnsexception.hh" +#include "misc.hh" +#include +#include + +#include "namespaces.hh" + +#ifdef __APPLE__ +#include + +#define htobe16(x) OSSwapHostToBigInt16(x) +#define htole16(x) OSSwapHostToLittleInt16(x) +#define be16toh(x) OSSwapBigToHostInt16(x) +#define le16toh(x) OSSwapLittleToHostInt16(x) + +#define htobe32(x) OSSwapHostToBigInt32(x) +#define htole32(x) OSSwapHostToLittleInt32(x) +#define be32toh(x) OSSwapBigToHostInt32(x) +#define le32toh(x) OSSwapLittleToHostInt32(x) + +#define htobe64(x) OSSwapHostToBigInt64(x) +#define htole64(x) OSSwapHostToLittleInt64(x) +#define be64toh(x) OSSwapBigToHostInt64(x) +#define le64toh(x) OSSwapLittleToHostInt64(x) +#endif + +#ifdef __sun + +#define htobe16(x) BE_16(x) +#define htole16(x) LE_16(x) +#define be16toh(x) BE_IN16(&(x)) +#define le16toh(x) LE_IN16(&(x)) + +#define htobe32(x) BE_32(x) +#define htole32(x) LE_32(x) +#define be32toh(x) BE_IN32(&(x)) +#define le32toh(x) LE_IN32(&(x)) + +#define htobe64(x) BE_64(x) +#define htole64(x) LE_64(x) +#define be64toh(x) BE_IN64(&(x)) +#define le64toh(x) LE_IN64(&(x)) + +#endif + +#ifdef __FreeBSD__ +#include +#endif + +#if defined(__NetBSD__) && defined(IP_PKTINFO) && !defined(IP_SENDSRCADDR) +// The IP_PKTINFO option in NetBSD was incompatible with Linux until a +// change that also introduced IP_SENDSRCADDR for FreeBSD compatibility. +#undef IP_PKTINFO +#endif + +union ComboAddress { + struct sockaddr_in sin4; + struct sockaddr_in6 sin6; + + bool operator==(const ComboAddress& rhs) const + { + if(std::tie(sin4.sin_family, sin4.sin_port) != std::tie(rhs.sin4.sin_family, rhs.sin4.sin_port)) + return false; + if(sin4.sin_family == AF_INET) + return sin4.sin_addr.s_addr == rhs.sin4.sin_addr.s_addr; + else + return memcmp(&sin6.sin6_addr.s6_addr, &rhs.sin6.sin6_addr.s6_addr, sizeof(sin6.sin6_addr.s6_addr))==0; + } + + bool operator!=(const ComboAddress& rhs) const + { + return(!operator==(rhs)); + } + + bool operator<(const ComboAddress& rhs) const + { + if(sin4.sin_family == 0) { + return false; + } + if(std::tie(sin4.sin_family, sin4.sin_port) < std::tie(rhs.sin4.sin_family, rhs.sin4.sin_port)) + return true; + if(std::tie(sin4.sin_family, sin4.sin_port) > std::tie(rhs.sin4.sin_family, rhs.sin4.sin_port)) + return false; + + if(sin4.sin_family == AF_INET) + return sin4.sin_addr.s_addr < rhs.sin4.sin_addr.s_addr; + else + return memcmp(&sin6.sin6_addr.s6_addr, &rhs.sin6.sin6_addr.s6_addr, sizeof(sin6.sin6_addr.s6_addr)) < 0; + } + + bool operator>(const ComboAddress& rhs) const + { + return rhs.operator<(*this); + } + + struct addressOnlyHash + { + uint32_t operator()(const ComboAddress& ca) const + { + const unsigned char* start = nullptr; + uint32_t len = 0; + if (ca.sin4.sin_family == AF_INET) { + start = reinterpret_cast(&ca.sin4.sin_addr.s_addr); + len = 4; + } + else { + start = reinterpret_cast(&ca.sin6.sin6_addr.s6_addr); + len = 16; + } + return burtle(start, len, 0); + } + }; + + struct addressOnlyLessThan + { + bool operator()(const ComboAddress& a, const ComboAddress& b) const + { + if(a.sin4.sin_family < b.sin4.sin_family) + return true; + if(a.sin4.sin_family > b.sin4.sin_family) + return false; + if(a.sin4.sin_family == AF_INET) + return a.sin4.sin_addr.s_addr < b.sin4.sin_addr.s_addr; + else + return memcmp(&a.sin6.sin6_addr.s6_addr, &b.sin6.sin6_addr.s6_addr, sizeof(a.sin6.sin6_addr.s6_addr)) < 0; + } + }; + + struct addressOnlyEqual + { + bool operator()(const ComboAddress& a, const ComboAddress& b) const + { + if(a.sin4.sin_family != b.sin4.sin_family) + return false; + if(a.sin4.sin_family == AF_INET) + return a.sin4.sin_addr.s_addr == b.sin4.sin_addr.s_addr; + else + return !memcmp(&a.sin6.sin6_addr.s6_addr, &b.sin6.sin6_addr.s6_addr, sizeof(a.sin6.sin6_addr.s6_addr)); + } + }; + + + socklen_t getSocklen() const + { + if(sin4.sin_family == AF_INET) + return sizeof(sin4); + else + return sizeof(sin6); + } + + ComboAddress() + { + sin4.sin_family=AF_INET; + sin4.sin_addr.s_addr=0; + sin4.sin_port=0; + sin6.sin6_scope_id = 0; + sin6.sin6_flowinfo = 0; + } + + ComboAddress(const struct sockaddr *sa, socklen_t salen) { + setSockaddr(sa, salen); + }; + + ComboAddress(const struct sockaddr_in6 *sa) { + setSockaddr((const struct sockaddr*)sa, sizeof(struct sockaddr_in6)); + }; + + ComboAddress(const struct sockaddr_in *sa) { + setSockaddr((const struct sockaddr*)sa, sizeof(struct sockaddr_in)); + }; + + void setSockaddr(const struct sockaddr *sa, socklen_t salen) { + if (salen > sizeof(struct sockaddr_in6)) throw PDNSException("ComboAddress can't handle other than sockaddr_in or sockaddr_in6"); + memcpy(this, sa, salen); + } + + // 'port' sets a default value in case 'str' does not set a port + explicit ComboAddress(const string& str, uint16_t port=0) + { + memset(&sin6, 0, sizeof(sin6)); + sin4.sin_family = AF_INET; + sin4.sin_port = 0; + if(makeIPv4sockaddr(str, &sin4)) { + sin6.sin6_family = AF_INET6; + if(makeIPv6sockaddr(str, &sin6) < 0) + throw PDNSException("Unable to convert presentation address '"+ str +"'"); + + } + if(!sin4.sin_port) // 'str' overrides port! + sin4.sin_port=htons(port); + } + + bool isIPv6() const + { + return sin4.sin_family == AF_INET6; + } + bool isIPv4() const + { + return sin4.sin_family == AF_INET; + } + + bool isMappedIPv4() const + { + if(sin4.sin_family!=AF_INET6) + return false; + + int n=0; + const unsigned char* ptr = reinterpret_cast(&sin6.sin6_addr.s6_addr); + for(n=0; n < 10; ++n) + if(ptr[n]) + return false; + + for(; n < 12; ++n) + if(ptr[n]!=0xff) + return false; + + return true; + } + + ComboAddress mapToIPv4() const + { + if(!isMappedIPv4()) + throw PDNSException("ComboAddress can't map non-mapped IPv6 address back to IPv4"); + ComboAddress ret; + ret.sin4.sin_family=AF_INET; + ret.sin4.sin_port=sin4.sin_port; + + const unsigned char* ptr = reinterpret_cast(&sin6.sin6_addr.s6_addr); + ptr+=(sizeof(sin6.sin6_addr.s6_addr) - sizeof(ret.sin4.sin_addr.s_addr)); + memcpy(&ret.sin4.sin_addr.s_addr, ptr, sizeof(ret.sin4.sin_addr.s_addr)); + return ret; + } + + string toString() const + { + char host[1024]; + int retval = 0; + if(sin4.sin_family && !(retval = getnameinfo(reinterpret_cast(this), getSocklen(), host, sizeof(host),0, 0, NI_NUMERICHOST))) + return string(host); + else + return "invalid "+string(gai_strerror(retval)); + } + + //! Ignores any interface specifiers possibly available in the sockaddr data. + string toStringNoInterface() const + { + char host[1024]; + if(sin4.sin_family == AF_INET && (nullptr != inet_ntop(sin4.sin_family, &sin4.sin_addr, host, sizeof(host)))) + return string(host); + else if(sin4.sin_family == AF_INET6 && (nullptr != inet_ntop(sin4.sin_family, &sin6.sin6_addr, host, sizeof(host)))) + return string(host); + else + return "invalid "+stringerror(); + } + + [[nodiscard]] string toStringReversed() const + { + if (isIPv4()) { + const auto ip = ntohl(sin4.sin_addr.s_addr); + auto a = (ip >> 0) & 0xFF; + auto b = (ip >> 8) & 0xFF; + auto c = (ip >> 16) & 0xFF; + auto d = (ip >> 24) & 0xFF; + return std::to_string(a) + "." + std::to_string(b) + "." + std::to_string(c) + "." + std::to_string(d); + } + else { + const auto* addr = &sin6.sin6_addr; + std::stringstream res{}; + res << std::hex; + for (int i = 15; i >= 0; i--) { + auto byte = addr->s6_addr[i]; + res << ((byte >> 0) & 0xF) << "."; + res << ((byte >> 4) & 0xF); + if (i != 0) { + res << "."; + } + } + return res.str(); + } + } + + string toStringWithPort() const + { + if(sin4.sin_family==AF_INET) + return toString() + ":" + std::to_string(ntohs(sin4.sin_port)); + else + return "["+toString() + "]:" + std::to_string(ntohs(sin4.sin_port)); + } + + string toStringWithPortExcept(int port) const + { + if(ntohs(sin4.sin_port) == port) + return toString(); + if(sin4.sin_family==AF_INET) + return toString() + ":" + std::to_string(ntohs(sin4.sin_port)); + else + return "["+toString() + "]:" + std::to_string(ntohs(sin4.sin_port)); + } + + string toLogString() const + { + return toStringWithPortExcept(53); + } + + string toByteString() const + { + if (isIPv4()) { + return string(reinterpret_cast(&sin4.sin_addr.s_addr), sizeof(sin4.sin_addr.s_addr)); + } + return string(reinterpret_cast(&sin6.sin6_addr.s6_addr), sizeof(sin6.sin6_addr.s6_addr)); + } + + void truncate(unsigned int bits) noexcept; + + uint16_t getPort() const + { + return ntohs(sin4.sin_port); + } + + void setPort(uint16_t port) + { + sin4.sin_port = htons(port); + } + + void reset() + { + memset(&sin4, 0, sizeof(sin4)); + memset(&sin6, 0, sizeof(sin6)); + } + + //! Get the total number of address bits (either 32 or 128 depending on IP version) + uint8_t getBits() const + { + if (isIPv4()) + return 32; + if (isIPv6()) + return 128; + return 0; + } + /** Get the value of the bit at the provided bit index. When the index >= 0, + the index is relative to the LSB starting at index zero. When the index < 0, + the index is relative to the MSB starting at index -1 and counting down. + */ + bool getBit(int index) const + { + if(isIPv4()) { + if (index >= 32) + return false; + if (index < 0) { + if (index < -32) + return false; + index = 32 + index; + } + + uint32_t ls_addr = ntohl(sin4.sin_addr.s_addr); + + return ((ls_addr & (1U<= 128) + return false; + if (index < 0) { + if (index < -128) + return false; + index = 128 + index; + } + + const uint8_t* ls_addr = reinterpret_cast(sin6.sin6_addr.s6_addr); + uint8_t byte_idx = index / 8; + uint8_t bit_idx = index % 8; + + return ((ls_addr[15-byte_idx] & (1U << bit_idx)) != 0x00); + } + return false; + } + + /*! Returns a comma-separated string of IP addresses + * + * \param c An stl container with ComboAddresses + * \param withPort Also print the port (default true) + * \param portExcept Print the port, except when this is the port (default 53) + */ + template < template < class ... > class Container, class ... Args > + static string caContainerToString(const Container& c, const bool withPort = true, const uint16_t portExcept = 53) { + vector strs; + for (const auto& ca : c) { + if (withPort) { + strs.push_back(ca.toStringWithPortExcept(portExcept)); + continue; + } + strs.push_back(ca.toString()); + } + return boost::join(strs, ","); + }; +}; + +/** This exception is thrown by the Netmask class and by extension by the NetmaskGroup class */ +class NetmaskException: public PDNSException +{ +public: + NetmaskException(const string &a) : PDNSException(a) {} +}; + +inline ComboAddress makeComboAddress(const string& str) +{ + ComboAddress address; + address.sin4.sin_family=AF_INET; + if(inet_pton(AF_INET, str.c_str(), &address.sin4.sin_addr) <= 0) { + address.sin4.sin_family=AF_INET6; + if(makeIPv6sockaddr(str, &address.sin6) < 0) + throw NetmaskException("Unable to convert '"+str+"' to a netmask"); + } + return address; +} + +inline ComboAddress makeComboAddressFromRaw(uint8_t version, const char* raw, size_t len) +{ + ComboAddress address; + + if (version == 4) { + address.sin4.sin_family = AF_INET; + if (len != sizeof(address.sin4.sin_addr)) throw NetmaskException("invalid raw address length"); + memcpy(&address.sin4.sin_addr, raw, sizeof(address.sin4.sin_addr)); + } + else if (version == 6) { + address.sin6.sin6_family = AF_INET6; + if (len != sizeof(address.sin6.sin6_addr)) throw NetmaskException("invalid raw address length"); + memcpy(&address.sin6.sin6_addr, raw, sizeof(address.sin6.sin6_addr)); + } + else throw NetmaskException("invalid address family"); + + return address; +} + +inline ComboAddress makeComboAddressFromRaw(uint8_t version, const string &str) +{ + return makeComboAddressFromRaw(version, str.c_str(), str.size()); +} + +/** This class represents a netmask and can be queried to see if a certain + IP address is matched by this mask */ +class Netmask +{ +public: + Netmask() + { + d_network.sin4.sin_family = 0; // disable this doing anything useful + d_network.sin4.sin_port = 0; // this guarantees d_network compares identical + d_mask = 0; + d_bits = 0; + } + + Netmask(const ComboAddress& network, uint8_t bits=0xff): d_network(network) + { + d_network.sin4.sin_port = 0; + setBits(network.isIPv4() ? std::min(bits, static_cast(32)) : std::min(bits, static_cast(128))); + } + + Netmask(const sockaddr_in* network, uint8_t bits = 0xff): d_network(network) + { + d_network.sin4.sin_port = 0; + setBits(std::min(bits, static_cast(32))); + } + Netmask(const sockaddr_in6* network, uint8_t bits = 0xff): d_network(network) + { + d_network.sin4.sin_port = 0; + setBits(std::min(bits, static_cast(128))); + } + void setBits(uint8_t value) + { + d_bits = value; + + if (d_bits < 32) { + d_mask = ~(0xFFFFFFFF >> d_bits); + } + else { + // note that d_mask is unused for IPv6 + d_mask = 0xFFFFFFFF; + } + + if (isIPv4()) { + d_network.sin4.sin_addr.s_addr = htonl(ntohl(d_network.sin4.sin_addr.s_addr) & d_mask); + } + else if (isIPv6()) { + uint8_t bytes = d_bits/8; + uint8_t *us = (uint8_t*) &d_network.sin6.sin6_addr.s6_addr; + uint8_t bits = d_bits % 8; + uint8_t mask = (uint8_t) ~(0xFF>>bits); + + if (bytes < sizeof(d_network.sin6.sin6_addr.s6_addr)) { + us[bytes] &= mask; + } + + for(size_t idx = bytes + 1; idx < sizeof(d_network.sin6.sin6_addr.s6_addr); ++idx) { + us[idx] = 0; + } + } + } + + //! Constructor supplies the mask, which cannot be changed + Netmask(const string &mask) + { + pair split = splitField(mask,'/'); + d_network = makeComboAddress(split.first); + + if (!split.second.empty()) { + setBits(pdns::checked_stoi(split.second)); + } + else if (d_network.sin4.sin_family == AF_INET) { + setBits(32); + } + else { + setBits(128); + } + } + + bool match(const ComboAddress& ip) const + { + return match(&ip); + } + + //! If this IP address in socket address matches + bool match(const ComboAddress *ip) const + { + if(d_network.sin4.sin_family != ip->sin4.sin_family) { + return false; + } + if(d_network.sin4.sin_family == AF_INET) { + return match4(htonl((unsigned int)ip->sin4.sin_addr.s_addr)); + } + if(d_network.sin6.sin6_family == AF_INET6) { + uint8_t bytes=d_bits/8, n; + const uint8_t *us=(const uint8_t*) &d_network.sin6.sin6_addr.s6_addr; + const uint8_t *them=(const uint8_t*) &ip->sin6.sin6_addr.s6_addr; + + for(n=0; n < bytes; ++n) { + if(us[n]!=them[n]) { + return false; + } + } + // still here, now match remaining bits + uint8_t bits= d_bits % 8; + uint8_t mask= (uint8_t) ~(0xFF>>bits); + + return((us[n]) == (them[n] & mask)); + } + return false; + } + + //! If this ASCII IP address matches + bool match(const string &ip) const + { + ComboAddress address=makeComboAddress(ip); + return match(&address); + } + + //! If this IP address in native format matches + bool match4(uint32_t ip) const + { + return (ip & d_mask) == (ntohl(d_network.sin4.sin_addr.s_addr)); + } + + string toString() const + { + return d_network.toStringNoInterface()+"/"+std::to_string((unsigned int)d_bits); + } + + string toStringNoMask() const + { + return d_network.toStringNoInterface(); + } + + const ComboAddress& getNetwork() const + { + return d_network; + } + + const ComboAddress& getMaskedNetwork() const + { + return getNetwork(); + } + + uint8_t getBits() const + { + return d_bits; + } + + bool isIPv6() const + { + return d_network.sin6.sin6_family == AF_INET6; + } + + bool isIPv4() const + { + return d_network.sin4.sin_family == AF_INET; + } + + bool operator<(const Netmask& rhs) const + { + if (empty() && !rhs.empty()) + return false; + + if (!empty() && rhs.empty()) + return true; + + if (d_bits > rhs.d_bits) + return true; + if (d_bits < rhs.d_bits) + return false; + + return d_network < rhs.d_network; + } + + bool operator>(const Netmask& rhs) const + { + return rhs.operator<(*this); + } + + bool operator==(const Netmask& rhs) const + { + return std::tie(d_network, d_bits) == std::tie(rhs.d_network, rhs.d_bits); + } + + bool empty() const + { + return d_network.sin4.sin_family==0; + } + + //! Get normalized version of the netmask. This means that all address bits below the network bits are zero. + Netmask getNormalized() const { + return Netmask(getMaskedNetwork(), d_bits); + } + //! Get Netmask for super network of this one (i.e. with fewer network bits) + Netmask getSuper(uint8_t bits) const { + return Netmask(d_network, std::min(d_bits, bits)); + } + + //! Get the total number of address bits for this netmask (either 32 or 128 depending on IP version) + uint8_t getFullBits() const + { + return d_network.getBits(); + } + + /** Get the value of the bit at the provided bit index. When the index >= 0, + the index is relative to the LSB starting at index zero. When the index < 0, + the index is relative to the MSB starting at index -1 and counting down. + When the index points outside the network bits, it always yields zero. + */ + bool getBit(int bit) const + { + if (bit < -d_bits) + return false; + if (bit >= 0) { + if(isIPv4()) { + if (bit >= 32 || bit < (32 - d_bits)) + return false; + } + if(isIPv6()) { + if (bit >= 128 || bit < (128 - d_bits)) + return false; + } + } + return d_network.getBit(bit); + } + + struct Hash { + size_t operator()(const Netmask& nm) const + { + return burtle(&nm.d_bits, 1, ComboAddress::addressOnlyHash()(nm.d_network)); + } + }; + +private: + ComboAddress d_network; + uint32_t d_mask; + uint8_t d_bits; +}; + +namespace std { + template<> + struct hash { + auto operator()(const Netmask& nm) const { + return Netmask::Hash{}(nm); + } + }; +} + +/** Binary tree map implementation with pair. + * + * This is an binary tree implementation for storing attributes for IPv4 and IPv6 prefixes. + * The most simple use case is simple NetmaskTree used by NetmaskGroup, which only + * wants to know if given IP address is matched in the prefixes stored. + * + * This element is useful for anything that needs to *STORE* prefixes, and *MATCH* IP addresses + * to a *LIST* of *PREFIXES*. Not the other way round. + * + * You can store IPv4 and IPv6 addresses to same tree, separate payload storage is kept per AFI. + * Network prefixes (Netmasks) are always recorded in normalized fashion, meaning that only + * the network bits are set. This is what is returned in the insert() and lookup() return + * values. + * + * Use swap if you need to move the tree to another NetmaskTree instance, it is WAY faster + * than using copy ctor or assignment operator, since it moves the nodes and tree root to + * new home instead of actually recreating the tree. + * + * Please see NetmaskGroup for example of simple use case. Other usecases can be found + * from GeoIPBackend and Sortlist, and from dnsdist. + */ +template +class NetmaskTree { +public: + class Iterator; + + typedef K key_type; + typedef T value_type; + typedef std::pair node_type; + typedef size_t size_type; + typedef class Iterator iterator; + +private: + /** Single node in tree, internal use only. + */ + class TreeNode : boost::noncopyable { + public: + explicit TreeNode() noexcept : + parent(nullptr), node(), assigned(false), d_bits(0) { + } + explicit TreeNode(const key_type& key) : + parent(nullptr), node({key.getNormalized(), value_type()}), + assigned(false), d_bits(key.getFullBits()) { + } + + //(key); + left->parent = this; + return left.get(); + } + + //(key); + right->parent = this; + return right.get(); + } + + //& parent_ref = + (parent->left.get() == this ? parent->left : parent->right); + if (parent_ref.get() != this) { + throw std::logic_error( + "NetmaskTree::TreeNode::split(): parent node reference is invalid"); + } + + // create new tree node for the new key + TreeNode* new_node = new TreeNode(key); + new_node->d_bits = bits; + + // attach the new node under our former parent + unique_ptr new_child(new_node); + std::swap(parent_ref, new_child); // hereafter new_child points to "this" + new_node->parent = parent; + + // attach "this" node below the new node + // (left or right depending on bit) + new_child->parent = new_node; + if (new_child->node.first.getBit(-1-bits)) { + std::swap(new_node->right, new_child); + } else { + std::swap(new_node->left, new_child); + } + + return new_node; + } + + //& parent_ref = + (parent->left.get() == this ? parent->left : parent->right); + if (parent_ref.get() != this) { + throw std::logic_error( + "NetmaskTree::TreeNode::fork(): parent node reference is invalid"); + } + + // create new tree node for the branch point + TreeNode* branch_node = new TreeNode(node.first.getSuper(bits)); + branch_node->d_bits = bits; + + // the current node will now be a child of the new branch node + // (hereafter new_child1 points to "this") + unique_ptr new_child1 = std::move(parent_ref); + // attach the branch node under our former parent + parent_ref = std::unique_ptr(branch_node); + branch_node->parent = parent; + + // create second new leaf node for the new key + unique_ptr new_child2 = make_unique(key); + TreeNode* new_node = new_child2.get(); + + // attach the new child nodes below the branch node + // (left or right depending on bit) + new_child1->parent = branch_node; + new_child2->parent = branch_node; + if (new_child1->node.first.getBit(-1-bits)) { + branch_node->right = std::move(new_child1); + branch_node->left = std::move(new_child2); + } else { + branch_node->right = std::move(new_child2); + branch_node->left = std::move(new_child1); + } + // now we have attached the new unique pointers to the tree: + // - branch_node is below its parent + // - new_child1 (ourselves) is below branch_node + // - new_child2, the new leaf node, is below branch_node as well + + return new_node; + } + + //left) + tnode = tnode->left.get(); + return tnode; + } + + //right) { + // descend right + tnode = tnode->right.get(); + // descend left as deep as possible and return next node + return tnode->traverse_l(); + } + + // ascend to parent + while (tnode->parent != nullptr) { + TreeNode *prev_child = tnode; + tnode = tnode->parent; + + // return this node, but only when we come from the left child branch + if (tnode->left && tnode->left.get() == prev_child) + return tnode; + } + return nullptr; + } + + //assigned) + tnode = tnode->traverse_lnr(); + return tnode; + } + + unique_ptr left; + unique_ptr right; + TreeNode* parent; + + node_type node; + bool assigned; //left || node->right || node->assigned)) { + // get parent node ptr + TreeNode* pparent = node->parent; + // delete this node + if (pparent) { + if (pparent->left.get() == node) + pparent->left.reset(); + else + pparent->right.reset(); + // now recurse up to the parent + cleanup_tree(pparent); + } + } + } + + void copyTree(const NetmaskTree& rhs) + { + try { + TreeNode *node = rhs.d_root.get(); + if (node != nullptr) + node = node->traverse_l(); + while (node != nullptr) { + if (node->assigned) + insert(node->node.first).second = node->node.second; + node = node->traverse_lnr(); + } + } + catch (const NetmaskException&) { + abort(); + } + catch (const std::logic_error&) { + abort(); + } + } + +public: + class Iterator { + public: + typedef node_type value_type; + typedef node_type& reference; + typedef node_type* pointer; + typedef std::forward_iterator_tag iterator_category; + typedef size_type difference_type; + + private: + friend class NetmaskTree; + + const NetmaskTree* d_tree; + TreeNode* d_node; + + Iterator(const NetmaskTree* tree, TreeNode* node): d_tree(tree), d_node(node) { + } + + public: + Iterator(): d_tree(nullptr), d_node(nullptr) {} + + Iterator& operator++() // prefix + { + if (d_node == nullptr) { + throw std::logic_error( + "NetmaskTree::Iterator::operator++: iterator is invalid"); + } + d_node = d_node->traverse_lnr_assigned(); + return *this; + } + Iterator operator++(int) // postfix + { + Iterator tmp(*this); + operator++(); + return tmp; + } + + reference operator*() + { + if (d_node == nullptr) { + throw std::logic_error( + "NetmaskTree::Iterator::operator*: iterator is invalid"); + } + return d_node->node; + } + + pointer operator->() + { + if (d_node == nullptr) { + throw std::logic_error( + "NetmaskTree::Iterator::operator->: iterator is invalid"); + } + return &d_node->node; + } + + bool operator==(const Iterator& rhs) + { + return (d_tree == rhs.d_tree && d_node == rhs.d_node); + } + bool operator!=(const Iterator& rhs) + { + return !(*this == rhs); + } + }; + +public: + NetmaskTree() noexcept: d_root(new TreeNode()), d_left(nullptr), d_size(0) { + } + + NetmaskTree(const NetmaskTree& rhs): d_root(new TreeNode()), d_left(nullptr), d_size(0) { + copyTree(rhs); + } + + NetmaskTree& operator=(const NetmaskTree& rhs) { + clear(); + copyTree(rhs); + return *this; + } + + const iterator begin() const { + return Iterator(this, d_left); + } + const iterator end() const { + return Iterator(this, nullptr); + } + iterator begin() { + return Iterator(this, d_left); + } + iterator end() { + return Iterator(this, nullptr); + } + + node_type& insert(const string &mask) { + return insert(key_type(mask)); + } + + //left.get(); + if (node == nullptr) { + node = new TreeNode(key); + node->assigned = true; + node->parent = d_root.get(); + + d_root->left = unique_ptr(node); + d_size++; + d_left = node; + return node->node; + } + } else if (key.isIPv6()) { + node = d_root->right.get(); + if (node == nullptr) { + node = new TreeNode(key); + node->assigned = true; + node->parent = d_root.get(); + + d_root->right = unique_ptr(node); + d_size++; + if (!d_root->left) + d_left = node; + return node->node; + } + if (d_root->left) + is_left = false; + } else + throw NetmaskException("invalid address family"); + + // we turn left on 0 and right on 1 + int bits = 0; + for(; bits < key.getBits(); bits++) { + bool vall = key.getBit(-1-bits); + + if (bits >= node->d_bits) { + // the end of the current node is reached; continue with the next + if (vall) { + if (node->left || node->assigned) + is_left = false; + if (!node->right) { + // the right branch doesn't exist yet; attach our key here + node = node->make_right(key); + break; + } + node = node->right.get(); + } else { + if (!node->left) { + // the left branch doesn't exist yet; attach our key here + node = node->make_left(key); + break; + } + node = node->left.get(); + } + continue; + } + if (bits >= node->node.first.getBits()) { + // the matching branch ends here, yet the key netmask has more bits; add a + // child node below the existing branch leaf. + if (vall) { + if (node->assigned) + is_left = false; + node = node->make_right(key); + } else { + node = node->make_left(key); + } + break; + } + bool valr = node->node.first.getBit(-1-bits); + if (vall != valr) { + if (vall) + is_left = false; + // the branch matches just upto this point, yet continues in a different + // direction; fork the branch. + node = node->fork(key, bits); + break; + } + } + + if (node->node.first.getBits() > key.getBits()) { + // key is a super-network of the matching node; split the branch and + // insert a node for the key above the matching node. + node = node->split(key, key.getBits()); + } + + if (node->left) + is_left = false; + + node_type& value = node->node; + + if (!node->assigned) { + // only increment size if not assigned before + d_size++; + // update the pointer to the left-most tree node + if (is_left) + d_left = node; + node->assigned = true; + } else { + // tree node exists for this value + if (is_left && d_left != node) { + throw std::logic_error( + "NetmaskTree::insert(): lost track of left-most node in tree"); + } + } + + return value; + } + + //first == key; + } + + // addr_bits) { + max_bits = addr_bits; + } + + return lookupImpl(key_type(value, max_bits), max_bits); + } + + //left.get(); + else if (key.isIPv6()) + node = d_root->right.get(); + else + throw NetmaskException("invalid address family"); + // no tree, no value + if (node == nullptr) return; + + int bits = 0; + for(; node && bits < key.getBits(); bits++) { + bool vall = key.getBit(-1-bits); + if (bits >= node->d_bits) { + // the end of the current node is reached; continue with the next + if (vall) { + node = node->right.get(); + } else { + node = node->left.get(); + } + continue; + } + if (bits >= node->node.first.getBits()) { + // the matching branch ends here + if (key.getBits() != node->node.first.getBits()) + node = nullptr; + break; + } + bool valr = node->node.first.getBit(-1-bits); + if (vall != valr) { + // the branch matches just upto this point, yet continues in a different + // direction + node = nullptr; + break; + } + } + if (node) { + if (d_size == 0) { + throw std::logic_error( + "NetmaskTree::erase(): size of tree is zero before erase"); + } + d_size--; + node->assigned = false; + node->node.second = value_type(); + + if (node == d_left) + d_left = d_left->traverse_lnr_assigned(); + + cleanup_tree(node); + } + } + + void erase(const string& key) { + erase(key_type(key)); + } + + //left.get(); + else if (value.isIPv6()) + node = d_root->right.get(); + else + throw NetmaskException("invalid address family"); + if (node == nullptr) return nullptr; + + node_type *ret = nullptr; + + int bits = 0; + for(; bits < max_bits; bits++) { + bool vall = value.getBit(-1-bits); + if (bits >= node->d_bits) { + // the end of the current node is reached; continue with the next + // (we keep track of last assigned node) + if (node->assigned && bits == node->node.first.getBits()) + ret = &node->node; + if (vall) { + if (!node->right) + break; + node = node->right.get(); + } else { + if (!node->left) + break; + node = node->left.get(); + } + continue; + } + if (bits >= node->node.first.getBits()) { + // the matching branch ends here + break; + } + bool valr = node->node.first.getBit(-1-bits); + if (vall != valr) { + // the branch matches just upto this point, yet continues in a different + // direction + break; + } + } + // needed if we did not find one in loop + if (node->assigned && bits == node->node.first.getBits()) + ret = &node->node; + + // this can be nullptr. + return ret; + } + + unique_ptr d_root; //second; + return false; + } + + bool match(const ComboAddress& ip) const + { + return match(&ip); + } + + bool lookup(const ComboAddress* ip, Netmask* nmp) const + { + const auto &ret = tree.lookup(*ip); + if (ret) { + if (nmp != nullptr) + *nmp = ret->first; + + return ret->second; + } + return false; + } + + bool lookup(const ComboAddress& ip, Netmask* nmp) const + { + return lookup(&ip, nmp); + } + + //! Add this string to the list of possible matches + void addMask(const string &ip, bool positive=true) + { + if(!ip.empty() && ip[0] == '!') { + addMask(Netmask(ip.substr(1)), false); + } else { + addMask(Netmask(ip), positive); + } + } + + //! Add this Netmask to the list of possible matches + void addMask(const Netmask& nm, bool positive=true) + { + tree.insert(nm).second=positive; + } + + void addMasks(const NetmaskGroup& group, boost::optional positive) + { + for (const auto& entry : group.tree) { + addMask(entry.first, positive ? *positive : entry.second); + } + } + + //! Delete this Netmask from the list of possible matches + void deleteMask(const Netmask& nm) + { + tree.erase(nm); + } + + void deleteMasks(const NetmaskGroup& group) + { + for (const auto& entry : group.tree) { + deleteMask(entry.first); + } + } + + void deleteMask(const std::string& ip) + { + if (!ip.empty()) + deleteMask(Netmask(ip)); + } + + void clear() + { + tree.clear(); + } + + bool empty() const + { + return tree.empty(); + } + + size_t size() const + { + return tree.size(); + } + + string toString() const + { + ostringstream str; + for(auto iter = tree.begin(); iter != tree.end(); ++iter) { + if(iter != tree.begin()) + str <<", "; + if(!(iter->second)) + str<<"!"; + str<first.toString(); + } + return str.str(); + } + + void toStringVector(vector* vec) const + { + for(auto iter = tree.begin(); iter != tree.end(); ++iter) { + vec->push_back((iter->second ? "" : "!") + iter->first.toString()); + } + } + + void toMasks(const string &ips) + { + vector parts; + stringtok(parts, ips, ", \t"); + + for (vector::const_iterator iter = parts.begin(); iter != parts.end(); ++iter) + addMask(*iter); + } + +private: + NetmaskTree tree; +}; + +struct SComboAddress +{ + SComboAddress(const ComboAddress& orig) : ca(orig) {} + ComboAddress ca; + bool operator<(const SComboAddress& rhs) const + { + return ComboAddress::addressOnlyLessThan()(ca, rhs.ca); + } + operator const ComboAddress&() + { + return ca; + } +}; + +class NetworkError : public runtime_error +{ +public: + NetworkError(const string& why="Network Error") : runtime_error(why.c_str()) + {} + NetworkError(const char *why="Network Error") : runtime_error(why) + {} +}; + +class AddressAndPortRange +{ +public: + AddressAndPortRange(): d_addrMask(0), d_portMask(0) + { + d_addr.sin4.sin_family = 0; // disable this doing anything useful + d_addr.sin4.sin_port = 0; // this guarantees d_network compares identical + } + + AddressAndPortRange(ComboAddress ca, uint8_t addrMask, uint8_t portMask = 0): d_addr(std::move(ca)), d_addrMask(addrMask), d_portMask(portMask) + { + if (!d_addr.isIPv4()) { + d_portMask = 0; + } + + uint16_t port = d_addr.getPort(); + if (d_portMask < 16) { + uint16_t mask = ~(0xFFFF >> d_portMask); + port = port & mask; + } + + if (d_addrMask < d_addr.getBits()) { + if (d_portMask > 0) { + throw std::runtime_error("Trying to create a AddressAndPortRange with a reduced address mask (" + std::to_string(d_addrMask) + ") and a port range (" + std::to_string(d_portMask) + ")"); + } + d_addr = Netmask(d_addr, d_addrMask).getMaskedNetwork(); + } + d_addr.setPort(port); + } + + uint8_t getFullBits() const + { + return d_addr.getBits() + 16; + } + + uint8_t getBits() const + { + if (d_addrMask < d_addr.getBits()) { + return d_addrMask; + } + + return d_addr.getBits() + d_portMask; + } + + /** Get the value of the bit at the provided bit index. When the index >= 0, + the index is relative to the LSB starting at index zero. When the index < 0, + the index is relative to the MSB starting at index -1 and counting down. + */ + bool getBit(int index) const + { + if (index >= getFullBits()) { + return false; + } + if (index < 0) { + index = getFullBits() + index; + } + + if (index < 16) { + /* we are into the port bits */ + uint16_t port = d_addr.getPort(); + return ((port & (1U< rhs.d_addrMask) { + return true; + } + + if (d_addrMask < rhs.d_addrMask) { + return false; + } + + if (d_addr < rhs.d_addr) { + return true; + } + + if (d_addr > rhs.d_addr) { + return false; + } + + if (d_portMask > rhs.d_portMask) { + return true; + } + + if (d_portMask < rhs.d_portMask) { + return false; + } + + return d_addr.getPort() < rhs.d_addr.getPort(); + } + + bool operator>(const AddressAndPortRange& rhs) const + { + return rhs.operator<(*this); + } + + struct hash + { + uint32_t operator()(const AddressAndPortRange& apr) const + { + ComboAddress::addressOnlyHash hashOp; + uint16_t port = apr.d_addr.getPort(); + /* it's fine to hash the whole address and port because the non-relevant parts have + been masked to 0 */ + return burtle(reinterpret_cast(&port), sizeof(port), hashOp(apr.d_addr)); + } + }; + +private: + ComboAddress d_addr; + uint8_t d_addrMask; + /* only used for v4 addresses */ + uint8_t d_portMask; +}; + +int SSocket(int family, int type, int flags); +int SConnect(int sockfd, const ComboAddress& remote); +/* tries to connect to remote for a maximum of timeout seconds. + sockfd should be set to non-blocking beforehand. + returns 0 on success (the socket is writable), throw a + runtime_error otherwise */ +int SConnectWithTimeout(int sockfd, const ComboAddress& remote, const struct timeval& timeout); +int SBind(int sockfd, const ComboAddress& local); +int SAccept(int sockfd, ComboAddress& remote); +int SListen(int sockfd, int limit); +int SSetsockopt(int sockfd, int level, int opname, int value); +void setSocketIgnorePMTU(int sockfd, int family); +bool setReusePort(int sockfd); + +#if defined(IP_PKTINFO) + #define GEN_IP_PKTINFO IP_PKTINFO +#elif defined(IP_RECVDSTADDR) + #define GEN_IP_PKTINFO IP_RECVDSTADDR +#endif + +bool IsAnyAddress(const ComboAddress& addr); +bool HarvestDestinationAddress(const struct msghdr* msgh, ComboAddress* destination); +bool HarvestTimestamp(struct msghdr* msgh, struct timeval* tv); +void fillMSGHdr(struct msghdr* msgh, struct iovec* iov, cmsgbuf_aligned* cbuf, size_t cbufsize, char* data, size_t datalen, ComboAddress* addr); +int sendOnNBSocket(int fd, const struct msghdr *msgh); +size_t sendMsgWithOptions(int fd, const char* buffer, size_t len, const ComboAddress* dest, const ComboAddress* local, unsigned int localItf, int flags); + +/* requires a non-blocking, connected TCP socket */ +bool isTCPSocketUsable(int sock); + +extern template class NetmaskTree; +ComboAddress parseIPAndPort(const std::string& input, uint16_t port); + +std::set getListOfNetworkInterfaces(); +std::vector getListOfAddressesOfNetworkInterface(const std::string& itf); +std::vector getListOfRangesOfNetworkInterface(const std::string& itf); + +/* These functions throw if the value was already set to a higher value, + or on error */ +void setSocketBuffer(int fd, int optname, uint32_t size); +void setSocketReceiveBuffer(int fd, uint32_t size); +void setSocketSendBuffer(int fd, uint32_t size); -- cgit v1.2.3