/* * ZeroTier One - Network Virtualization Everywhere * Copyright (C) 2011-2019 ZeroTier, Inc. https://www.zerotier.com/ * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * 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, see . * * -- * * You can be released from the requirements of the license by purchasing * a commercial license. Buying such a license is mandatory as soon as you * develop commercial closed-source software that incorporates or links * directly against ZeroTier software without disclosing the source code * of your own application. */ #include #include #include #include #include #ifndef _WIN32 #include #endif #include #include #include #include #include #include #include #include "../include/ZeroTierOne.h" #include "../version.h" #include "EmbeddedNetworkController.hpp" #include "LFDB.hpp" #include "FileDB.hpp" #ifdef ZT_CONTROLLER_USE_LIBPQ #include "PostgreSQL.hpp" #endif #include "../node/Node.hpp" #include "../node/CertificateOfMembership.hpp" #include "../node/NetworkConfig.hpp" #include "../node/Dictionary.hpp" #include "../node/MAC.hpp" using json = nlohmann::json; // API version reported via JSON control plane #define ZT_NETCONF_CONTROLLER_API_VERSION 4 // Min duration between requests for an address/nwid combo to prevent floods #define ZT_NETCONF_MIN_REQUEST_PERIOD 1000 // Global maximum size of arrays in JSON objects #define ZT_CONTROLLER_MAX_ARRAY_SIZE 16384 namespace ZeroTier { namespace { static json _renderRule(ZT_VirtualNetworkRule &rule) { char tmp[128]; json r = json::object(); const ZT_VirtualNetworkRuleType rt = (ZT_VirtualNetworkRuleType)(rule.t & 0x3f); switch(rt) { case ZT_NETWORK_RULE_ACTION_DROP: r["type"] = "ACTION_DROP"; break; case ZT_NETWORK_RULE_ACTION_ACCEPT: r["type"] = "ACTION_ACCEPT"; break; case ZT_NETWORK_RULE_ACTION_TEE: r["type"] = "ACTION_TEE"; r["address"] = Address(rule.v.fwd.address).toString(tmp); r["flags"] = (unsigned int)rule.v.fwd.flags; r["length"] = (unsigned int)rule.v.fwd.length; break; case ZT_NETWORK_RULE_ACTION_WATCH: r["type"] = "ACTION_WATCH"; r["address"] = Address(rule.v.fwd.address).toString(tmp); r["flags"] = (unsigned int)rule.v.fwd.flags; r["length"] = (unsigned int)rule.v.fwd.length; break; case ZT_NETWORK_RULE_ACTION_REDIRECT: r["type"] = "ACTION_REDIRECT"; r["address"] = Address(rule.v.fwd.address).toString(tmp); r["flags"] = (unsigned int)rule.v.fwd.flags; break; case ZT_NETWORK_RULE_ACTION_BREAK: r["type"] = "ACTION_BREAK"; break; default: break; } if (r.size() == 0) { switch(rt) { case ZT_NETWORK_RULE_MATCH_SOURCE_ZEROTIER_ADDRESS: r["type"] = "MATCH_SOURCE_ZEROTIER_ADDRESS"; r["zt"] = Address(rule.v.zt).toString(tmp); break; case ZT_NETWORK_RULE_MATCH_DEST_ZEROTIER_ADDRESS: r["type"] = "MATCH_DEST_ZEROTIER_ADDRESS"; r["zt"] = Address(rule.v.zt).toString(tmp); break; case ZT_NETWORK_RULE_MATCH_VLAN_ID: r["type"] = "MATCH_VLAN_ID"; r["vlanId"] = (unsigned int)rule.v.vlanId; break; case ZT_NETWORK_RULE_MATCH_VLAN_PCP: r["type"] = "MATCH_VLAN_PCP"; r["vlanPcp"] = (unsigned int)rule.v.vlanPcp; break; case ZT_NETWORK_RULE_MATCH_VLAN_DEI: r["type"] = "MATCH_VLAN_DEI"; r["vlanDei"] = (unsigned int)rule.v.vlanDei; break; case ZT_NETWORK_RULE_MATCH_MAC_SOURCE: r["type"] = "MATCH_MAC_SOURCE"; OSUtils::ztsnprintf(tmp,sizeof(tmp),"%.2x:%.2x:%.2x:%.2x:%.2x:%.2x",(unsigned int)rule.v.mac[0],(unsigned int)rule.v.mac[1],(unsigned int)rule.v.mac[2],(unsigned int)rule.v.mac[3],(unsigned int)rule.v.mac[4],(unsigned int)rule.v.mac[5]); r["mac"] = tmp; break; case ZT_NETWORK_RULE_MATCH_MAC_DEST: r["type"] = "MATCH_MAC_DEST"; OSUtils::ztsnprintf(tmp,sizeof(tmp),"%.2x:%.2x:%.2x:%.2x:%.2x:%.2x",(unsigned int)rule.v.mac[0],(unsigned int)rule.v.mac[1],(unsigned int)rule.v.mac[2],(unsigned int)rule.v.mac[3],(unsigned int)rule.v.mac[4],(unsigned int)rule.v.mac[5]); r["mac"] = tmp; break; case ZT_NETWORK_RULE_MATCH_IPV4_SOURCE: r["type"] = "MATCH_IPV4_SOURCE"; r["ip"] = InetAddress(&(rule.v.ipv4.ip),4,(unsigned int)rule.v.ipv4.mask).toString(tmp); break; case ZT_NETWORK_RULE_MATCH_IPV4_DEST: r["type"] = "MATCH_IPV4_DEST"; r["ip"] = InetAddress(&(rule.v.ipv4.ip),4,(unsigned int)rule.v.ipv4.mask).toString(tmp); break; case ZT_NETWORK_RULE_MATCH_IPV6_SOURCE: r["type"] = "MATCH_IPV6_SOURCE"; r["ip"] = InetAddress(rule.v.ipv6.ip,16,(unsigned int)rule.v.ipv6.mask).toString(tmp); break; case ZT_NETWORK_RULE_MATCH_IPV6_DEST: r["type"] = "MATCH_IPV6_DEST"; r["ip"] = InetAddress(rule.v.ipv6.ip,16,(unsigned int)rule.v.ipv6.mask).toString(tmp); break; case ZT_NETWORK_RULE_MATCH_IP_TOS: r["type"] = "MATCH_IP_TOS"; r["mask"] = (unsigned int)rule.v.ipTos.mask; r["start"] = (unsigned int)rule.v.ipTos.value[0]; r["end"] = (unsigned int)rule.v.ipTos.value[1]; break; case ZT_NETWORK_RULE_MATCH_IP_PROTOCOL: r["type"] = "MATCH_IP_PROTOCOL"; r["ipProtocol"] = (unsigned int)rule.v.ipProtocol; break; case ZT_NETWORK_RULE_MATCH_ETHERTYPE: r["type"] = "MATCH_ETHERTYPE"; r["etherType"] = (unsigned int)rule.v.etherType; break; case ZT_NETWORK_RULE_MATCH_ICMP: r["type"] = "MATCH_ICMP"; r["icmpType"] = (unsigned int)rule.v.icmp.type; if ((rule.v.icmp.flags & 0x01) != 0) r["icmpCode"] = (unsigned int)rule.v.icmp.code; else r["icmpCode"] = json(); break; case ZT_NETWORK_RULE_MATCH_IP_SOURCE_PORT_RANGE: r["type"] = "MATCH_IP_SOURCE_PORT_RANGE"; r["start"] = (unsigned int)rule.v.port[0]; r["end"] = (unsigned int)rule.v.port[1]; break; case ZT_NETWORK_RULE_MATCH_IP_DEST_PORT_RANGE: r["type"] = "MATCH_IP_DEST_PORT_RANGE"; r["start"] = (unsigned int)rule.v.port[0]; r["end"] = (unsigned int)rule.v.port[1]; break; case ZT_NETWORK_RULE_MATCH_CHARACTERISTICS: r["type"] = "MATCH_CHARACTERISTICS"; OSUtils::ztsnprintf(tmp,sizeof(tmp),"%.16llx",rule.v.characteristics); r["mask"] = tmp; break; case ZT_NETWORK_RULE_MATCH_FRAME_SIZE_RANGE: r["type"] = "MATCH_FRAME_SIZE_RANGE"; r["start"] = (unsigned int)rule.v.frameSize[0]; r["end"] = (unsigned int)rule.v.frameSize[1]; break; case ZT_NETWORK_RULE_MATCH_RANDOM: r["type"] = "MATCH_RANDOM"; r["probability"] = (unsigned long)rule.v.randomProbability; break; case ZT_NETWORK_RULE_MATCH_TAGS_DIFFERENCE: r["type"] = "MATCH_TAGS_DIFFERENCE"; r["id"] = rule.v.tag.id; r["value"] = rule.v.tag.value; break; case ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_AND: r["type"] = "MATCH_TAGS_BITWISE_AND"; r["id"] = rule.v.tag.id; r["value"] = rule.v.tag.value; break; case ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_OR: r["type"] = "MATCH_TAGS_BITWISE_OR"; r["id"] = rule.v.tag.id; r["value"] = rule.v.tag.value; break; case ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_XOR: r["type"] = "MATCH_TAGS_BITWISE_XOR"; r["id"] = rule.v.tag.id; r["value"] = rule.v.tag.value; break; case ZT_NETWORK_RULE_MATCH_TAGS_EQUAL: r["type"] = "MATCH_TAGS_EQUAL"; r["id"] = rule.v.tag.id; r["value"] = rule.v.tag.value; break; case ZT_NETWORK_RULE_MATCH_TAG_SENDER: r["type"] = "MATCH_TAG_SENDER"; r["id"] = rule.v.tag.id; r["value"] = rule.v.tag.value; break; case ZT_NETWORK_RULE_MATCH_TAG_RECEIVER: r["type"] = "MATCH_TAG_RECEIVER"; r["id"] = rule.v.tag.id; r["value"] = rule.v.tag.value; break; case ZT_NETWORK_RULE_MATCH_INTEGER_RANGE: r["type"] = "INTEGER_RANGE"; OSUtils::ztsnprintf(tmp,sizeof(tmp),"%.16llx",rule.v.intRange.start); r["start"] = tmp; OSUtils::ztsnprintf(tmp,sizeof(tmp),"%.16llx",rule.v.intRange.start + (uint64_t)rule.v.intRange.end); r["end"] = tmp; r["idx"] = rule.v.intRange.idx; r["little"] = ((rule.v.intRange.format & 0x80) != 0); r["bits"] = (rule.v.intRange.format & 63) + 1; break; default: break; } if (r.size() > 0) { r["not"] = ((rule.t & 0x80) != 0); r["or"] = ((rule.t & 0x40) != 0); } } return r; } static bool _parseRule(json &r,ZT_VirtualNetworkRule &rule) { if (!r.is_object()) return false; const std::string t(OSUtils::jsonString(r["type"],"")); memset(&rule,0,sizeof(ZT_VirtualNetworkRule)); if (OSUtils::jsonBool(r["not"],false)) rule.t = 0x80; else rule.t = 0x00; if (OSUtils::jsonBool(r["or"],false)) rule.t |= 0x40; bool tag = false; if (t == "ACTION_DROP") { rule.t |= ZT_NETWORK_RULE_ACTION_DROP; return true; } else if (t == "ACTION_ACCEPT") { rule.t |= ZT_NETWORK_RULE_ACTION_ACCEPT; return true; } else if (t == "ACTION_TEE") { rule.t |= ZT_NETWORK_RULE_ACTION_TEE; rule.v.fwd.address = Utils::hexStrToU64(OSUtils::jsonString(r["address"],"0").c_str()) & 0xffffffffffULL; rule.v.fwd.flags = (uint32_t)(OSUtils::jsonInt(r["flags"],0ULL) & 0xffffffffULL); rule.v.fwd.length = (uint16_t)(OSUtils::jsonInt(r["length"],0ULL) & 0xffffULL); return true; } else if (t == "ACTION_WATCH") { rule.t |= ZT_NETWORK_RULE_ACTION_WATCH; rule.v.fwd.address = Utils::hexStrToU64(OSUtils::jsonString(r["address"],"0").c_str()) & 0xffffffffffULL; rule.v.fwd.flags = (uint32_t)(OSUtils::jsonInt(r["flags"],0ULL) & 0xffffffffULL); rule.v.fwd.length = (uint16_t)(OSUtils::jsonInt(r["length"],0ULL) & 0xffffULL); return true; } else if (t == "ACTION_REDIRECT") { rule.t |= ZT_NETWORK_RULE_ACTION_REDIRECT; rule.v.fwd.address = Utils::hexStrToU64(OSUtils::jsonString(r["address"],"0").c_str()) & 0xffffffffffULL; rule.v.fwd.flags = (uint32_t)(OSUtils::jsonInt(r["flags"],0ULL) & 0xffffffffULL); return true; } else if (t == "ACTION_BREAK") { rule.t |= ZT_NETWORK_RULE_ACTION_BREAK; return true; } else if (t == "MATCH_SOURCE_ZEROTIER_ADDRESS") { rule.t |= ZT_NETWORK_RULE_MATCH_SOURCE_ZEROTIER_ADDRESS; rule.v.zt = Utils::hexStrToU64(OSUtils::jsonString(r["zt"],"0").c_str()) & 0xffffffffffULL; return true; } else if (t == "MATCH_DEST_ZEROTIER_ADDRESS") { rule.t |= ZT_NETWORK_RULE_MATCH_DEST_ZEROTIER_ADDRESS; rule.v.zt = Utils::hexStrToU64(OSUtils::jsonString(r["zt"],"0").c_str()) & 0xffffffffffULL; return true; } else if (t == "MATCH_VLAN_ID") { rule.t |= ZT_NETWORK_RULE_MATCH_VLAN_ID; rule.v.vlanId = (uint16_t)(OSUtils::jsonInt(r["vlanId"],0ULL) & 0xffffULL); return true; } else if (t == "MATCH_VLAN_PCP") { rule.t |= ZT_NETWORK_RULE_MATCH_VLAN_PCP; rule.v.vlanPcp = (uint8_t)(OSUtils::jsonInt(r["vlanPcp"],0ULL) & 0xffULL); return true; } else if (t == "MATCH_VLAN_DEI") { rule.t |= ZT_NETWORK_RULE_MATCH_VLAN_DEI; rule.v.vlanDei = (uint8_t)(OSUtils::jsonInt(r["vlanDei"],0ULL) & 0xffULL); return true; } else if (t == "MATCH_MAC_SOURCE") { rule.t |= ZT_NETWORK_RULE_MATCH_MAC_SOURCE; const std::string mac(OSUtils::jsonString(r["mac"],"0")); Utils::unhex(mac.c_str(),(unsigned int)mac.length(),rule.v.mac,6); return true; } else if (t == "MATCH_MAC_DEST") { rule.t |= ZT_NETWORK_RULE_MATCH_MAC_DEST; const std::string mac(OSUtils::jsonString(r["mac"],"0")); Utils::unhex(mac.c_str(),(unsigned int)mac.length(),rule.v.mac,6); return true; } else if (t == "MATCH_IPV4_SOURCE") { rule.t |= ZT_NETWORK_RULE_MATCH_IPV4_SOURCE; InetAddress ip(OSUtils::jsonString(r["ip"],"0.0.0.0").c_str()); rule.v.ipv4.ip = reinterpret_cast(&ip)->sin_addr.s_addr; rule.v.ipv4.mask = Utils::ntoh(reinterpret_cast(&ip)->sin_port) & 0xff; if (rule.v.ipv4.mask > 32) rule.v.ipv4.mask = 32; return true; } else if (t == "MATCH_IPV4_DEST") { rule.t |= ZT_NETWORK_RULE_MATCH_IPV4_DEST; InetAddress ip(OSUtils::jsonString(r["ip"],"0.0.0.0").c_str()); rule.v.ipv4.ip = reinterpret_cast(&ip)->sin_addr.s_addr; rule.v.ipv4.mask = Utils::ntoh(reinterpret_cast(&ip)->sin_port) & 0xff; if (rule.v.ipv4.mask > 32) rule.v.ipv4.mask = 32; return true; } else if (t == "MATCH_IPV6_SOURCE") { rule.t |= ZT_NETWORK_RULE_MATCH_IPV6_SOURCE; InetAddress ip(OSUtils::jsonString(r["ip"],"::0").c_str()); memcpy(rule.v.ipv6.ip,reinterpret_cast(&ip)->sin6_addr.s6_addr,16); rule.v.ipv6.mask = Utils::ntoh(reinterpret_cast(&ip)->sin6_port) & 0xff; if (rule.v.ipv6.mask > 128) rule.v.ipv6.mask = 128; return true; } else if (t == "MATCH_IPV6_DEST") { rule.t |= ZT_NETWORK_RULE_MATCH_IPV6_DEST; InetAddress ip(OSUtils::jsonString(r["ip"],"::0").c_str()); memcpy(rule.v.ipv6.ip,reinterpret_cast(&ip)->sin6_addr.s6_addr,16); rule.v.ipv6.mask = Utils::ntoh(reinterpret_cast(&ip)->sin6_port) & 0xff; if (rule.v.ipv6.mask > 128) rule.v.ipv6.mask = 128; return true; } else if (t == "MATCH_IP_TOS") { rule.t |= ZT_NETWORK_RULE_MATCH_IP_TOS; rule.v.ipTos.mask = (uint8_t)(OSUtils::jsonInt(r["mask"],0ULL) & 0xffULL); rule.v.ipTos.value[0] = (uint8_t)(OSUtils::jsonInt(r["start"],0ULL) & 0xffULL); rule.v.ipTos.value[1] = (uint8_t)(OSUtils::jsonInt(r["end"],0ULL) & 0xffULL); return true; } else if (t == "MATCH_IP_PROTOCOL") { rule.t |= ZT_NETWORK_RULE_MATCH_IP_PROTOCOL; rule.v.ipProtocol = (uint8_t)(OSUtils::jsonInt(r["ipProtocol"],0ULL) & 0xffULL); return true; } else if (t == "MATCH_ETHERTYPE") { rule.t |= ZT_NETWORK_RULE_MATCH_ETHERTYPE; rule.v.etherType = (uint16_t)(OSUtils::jsonInt(r["etherType"],0ULL) & 0xffffULL); return true; } else if (t == "MATCH_ICMP") { rule.t |= ZT_NETWORK_RULE_MATCH_ICMP; rule.v.icmp.type = (uint8_t)(OSUtils::jsonInt(r["icmpType"],0ULL) & 0xffULL); json &code = r["icmpCode"]; if (code.is_null()) { rule.v.icmp.code = 0; rule.v.icmp.flags = 0x00; } else { rule.v.icmp.code = (uint8_t)(OSUtils::jsonInt(code,0ULL) & 0xffULL); rule.v.icmp.flags = 0x01; } return true; } else if (t == "MATCH_IP_SOURCE_PORT_RANGE") { rule.t |= ZT_NETWORK_RULE_MATCH_IP_SOURCE_PORT_RANGE; rule.v.port[0] = (uint16_t)(OSUtils::jsonInt(r["start"],0ULL) & 0xffffULL); rule.v.port[1] = (uint16_t)(OSUtils::jsonInt(r["end"],(uint64_t)rule.v.port[0]) & 0xffffULL); return true; } else if (t == "MATCH_IP_DEST_PORT_RANGE") { rule.t |= ZT_NETWORK_RULE_MATCH_IP_DEST_PORT_RANGE; rule.v.port[0] = (uint16_t)(OSUtils::jsonInt(r["start"],0ULL) & 0xffffULL); rule.v.port[1] = (uint16_t)(OSUtils::jsonInt(r["end"],(uint64_t)rule.v.port[0]) & 0xffffULL); return true; } else if (t == "MATCH_CHARACTERISTICS") { rule.t |= ZT_NETWORK_RULE_MATCH_CHARACTERISTICS; if (r.count("mask")) { json &v = r["mask"]; if (v.is_number()) { rule.v.characteristics = v; } else { std::string tmp = v; rule.v.characteristics = Utils::hexStrToU64(tmp.c_str()); } } return true; } else if (t == "MATCH_FRAME_SIZE_RANGE") { rule.t |= ZT_NETWORK_RULE_MATCH_FRAME_SIZE_RANGE; rule.v.frameSize[0] = (uint16_t)(OSUtils::jsonInt(r["start"],0ULL) & 0xffffULL); rule.v.frameSize[1] = (uint16_t)(OSUtils::jsonInt(r["end"],(uint64_t)rule.v.frameSize[0]) & 0xffffULL); return true; } else if (t == "MATCH_RANDOM") { rule.t |= ZT_NETWORK_RULE_MATCH_RANDOM; rule.v.randomProbability = (uint32_t)(OSUtils::jsonInt(r["probability"],0ULL) & 0xffffffffULL); return true; } else if (t == "MATCH_TAGS_DIFFERENCE") { rule.t |= ZT_NETWORK_RULE_MATCH_TAGS_DIFFERENCE; tag = true; } else if (t == "MATCH_TAGS_BITWISE_AND") { rule.t |= ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_AND; tag = true; } else if (t == "MATCH_TAGS_BITWISE_OR") { rule.t |= ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_OR; tag = true; } else if (t == "MATCH_TAGS_BITWISE_XOR") { rule.t |= ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_XOR; tag = true; } else if (t == "MATCH_TAGS_EQUAL") { rule.t |= ZT_NETWORK_RULE_MATCH_TAGS_EQUAL; tag = true; } else if (t == "MATCH_TAG_SENDER") { rule.t |= ZT_NETWORK_RULE_MATCH_TAG_SENDER; tag = true; } else if (t == "MATCH_TAG_RECEIVER") { rule.t |= ZT_NETWORK_RULE_MATCH_TAG_RECEIVER; tag = true; } else if (t == "INTEGER_RANGE") { json &s = r["start"]; if (s.is_string()) { std::string tmp = s; rule.v.intRange.start = Utils::hexStrToU64(tmp.c_str()); } else { rule.v.intRange.start = OSUtils::jsonInt(s,0ULL); } json &e = r["end"]; if (e.is_string()) { std::string tmp = e; rule.v.intRange.end = (uint32_t)(Utils::hexStrToU64(tmp.c_str()) - rule.v.intRange.start); } else { rule.v.intRange.end = (uint32_t)(OSUtils::jsonInt(e,0ULL) - rule.v.intRange.start); } rule.v.intRange.idx = (uint16_t)OSUtils::jsonInt(r["idx"],0ULL); rule.v.intRange.format = (OSUtils::jsonBool(r["little"],false)) ? 0x80 : 0x00; rule.v.intRange.format |= (uint8_t)((OSUtils::jsonInt(r["bits"],1ULL) - 1) & 63); } if (tag) { rule.v.tag.id = (uint32_t)(OSUtils::jsonInt(r["id"],0ULL) & 0xffffffffULL); rule.v.tag.value = (uint32_t)(OSUtils::jsonInt(r["value"],0ULL) & 0xffffffffULL); return true; } return false; } } // anonymous namespace EmbeddedNetworkController::EmbeddedNetworkController(Node *node,const char *dbPath, int listenPort, MQConfig *mqc) : _startTime(OSUtils::now()), _listenPort(listenPort), _node(node), _path(dbPath), _sender((NetworkController::Sender *)0), _mqc(mqc) { } EmbeddedNetworkController::~EmbeddedNetworkController() { std::lock_guard l(_threads_l); _queue.stop(); for(auto t=_threads.begin();t!=_threads.end();++t) t->join(); } void EmbeddedNetworkController::init(const Identity &signingId,Sender *sender) { char tmp[64]; _signingId = signingId; _sender = sender; _signingIdAddressString = signingId.address().toString(tmp); #ifdef ZT_CONTROLLER_USE_LIBPQ if ((_path.length() > 9)&&(_path.substr(0,9) == "postgres:")) { _db.reset(new PostgreSQL(this,_signingId,_path.substr(9).c_str(), _listenPort, _mqc)); } else { #endif std::string lfJSON; OSUtils::readFile((_path + ZT_PATH_SEPARATOR_S ".." ZT_PATH_SEPARATOR_S "local.conf").c_str(),lfJSON); if (lfJSON.length() > 0) { nlohmann::json lfConfig(OSUtils::jsonParse(lfJSON)); nlohmann::json &settings = lfConfig["settings"]; if (settings.is_object()) { nlohmann::json &controllerDb = settings["controllerDb"]; if (controllerDb.is_object()) { std::string type = controllerDb["type"]; if (type == "lf") { std::string lfOwner = controllerDb["owner"]; std::string lfHost = controllerDb["host"]; int lfPort = controllerDb["port"]; bool storeOnlineState = controllerDb["storeOnlineState"]; if ((lfOwner.length())&&(lfHost.length())&&(lfPort > 0)&&(lfPort < 65536)) { std::size_t pubHdrLoc = lfOwner.find("Public: "); if ((pubHdrLoc > 0)&&((pubHdrLoc + 8) < lfOwner.length())) { std::string lfOwnerPublic = lfOwner.substr(pubHdrLoc + 8); std::size_t pubHdrEnd = lfOwnerPublic.find_first_of("\n\r\t "); if (pubHdrEnd != std::string::npos) { lfOwnerPublic = lfOwnerPublic.substr(0,pubHdrEnd); _db.reset(new LFDB(this,_signingId,_path.c_str(),lfOwner.c_str(),lfOwnerPublic.c_str(),lfHost.c_str(),lfPort,storeOnlineState)); } } } } } } } if (!_db) _db.reset(new FileDB(this,_signingId,_path.c_str())); #ifdef ZT_CONTROLLER_USE_LIBPQ } #endif _db->waitForReady(); } void EmbeddedNetworkController::request( uint64_t nwid, const InetAddress &fromAddr, uint64_t requestPacketId, const Identity &identity, const Dictionary &metaData) { if (((!_signingId)||(!_signingId.hasPrivate()))||(_signingId.address().toInt() != (nwid >> 24))||(!_sender)) return; _startThreads(); _RQEntry *qe = new _RQEntry; qe->nwid = nwid; qe->requestPacketId = requestPacketId; qe->fromAddr = fromAddr; qe->identity = identity; qe->metaData = metaData; qe->type = _RQEntry::RQENTRY_TYPE_REQUEST; _queue.post(qe); } unsigned int EmbeddedNetworkController::handleControlPlaneHttpGET( const std::vector &path, const std::map &urlArgs, const std::map &headers, const std::string &body, std::string &responseBody, std::string &responseContentType) { if (!_db) return 500; if ((path.size() > 0)&&(path[0] == "network")) { if ((path.size() >= 2)&&(path[1].length() == 16)) { const uint64_t nwid = Utils::hexStrToU64(path[1].c_str()); json network; if (!_db->get(nwid,network)) return 404; if (path.size() >= 3) { if (path[2] == "member") { if (path.size() >= 4) { // Get member const uint64_t address = Utils::hexStrToU64(path[3].c_str()); json member; if (!_db->get(nwid,network,address,member)) return 404; responseBody = OSUtils::jsonDump(member); responseContentType = "application/json"; } else { // List members and their revisions responseBody = "{"; std::vector members; if (_db->get(nwid,network,members)) { responseBody.reserve((members.size() + 2) * 32); std::string mid; for(auto member=members.begin();member!=members.end();++member) { mid = (*member)["id"]; char tmp[128]; OSUtils::ztsnprintf(tmp,sizeof(tmp),"%s\"%s\":%llu",(responseBody.length() > 1) ? "," : "",mid.c_str(),(unsigned long long)OSUtils::jsonInt((*member)["revision"],0)); responseBody.append(tmp); } } responseBody.push_back('}'); responseContentType = "application/json"; } return 200; } // else 404 } else { // Get network responseBody = OSUtils::jsonDump(network); responseContentType = "application/json"; return 200; } } else if (path.size() == 1) { // List networks std::vector networkIds; _db->networks(networkIds); char tmp[64]; responseBody = "["; responseBody.reserve((networkIds.size() + 1) * 24); for(std::vector::const_iterator i(networkIds.begin());i!=networkIds.end();++i) { if (responseBody.length() > 1) responseBody.push_back(','); OSUtils::ztsnprintf(tmp,sizeof(tmp),"\"%.16llx\"",(unsigned long long)*i); responseBody.append(tmp); } responseBody.push_back(']'); responseContentType = "application/json"; return 200; } // else 404 } else { // Controller status char tmp[4096]; const bool dbOk = _db->isReady(); OSUtils::ztsnprintf(tmp,sizeof(tmp),"{\n\t\"controller\": true,\n\t\"apiVersion\": %d,\n\t\"clock\": %llu,\n\t\"databaseReady\": %s\n}\n",ZT_NETCONF_CONTROLLER_API_VERSION,(unsigned long long)OSUtils::now(),dbOk ? "true" : "false"); responseBody = tmp; responseContentType = "application/json"; return dbOk ? 200 : 503; } return 404; } unsigned int EmbeddedNetworkController::handleControlPlaneHttpPOST( const std::vector &path, const std::map &urlArgs, const std::map &headers, const std::string &body, std::string &responseBody, std::string &responseContentType) { if (!_db) return 500; if (path.empty()) return 404; json b; try { b = OSUtils::jsonParse(body); if (!b.is_object()) { responseBody = "{ \"message\": \"body is not a JSON object\" }"; responseContentType = "application/json"; return 400; } } catch ( ... ) { responseBody = "{ \"message\": \"body JSON is invalid\" }"; responseContentType = "application/json"; return 400; } const int64_t now = OSUtils::now(); if (path[0] == "network") { if ((path.size() >= 2)&&(path[1].length() == 16)) { uint64_t nwid = Utils::hexStrToU64(path[1].c_str()); char nwids[24]; OSUtils::ztsnprintf(nwids,sizeof(nwids),"%.16llx",(unsigned long long)nwid); if (path.size() >= 3) { if ((path.size() == 4)&&(path[2] == "member")&&(path[3].length() == 10)) { uint64_t address = Utils::hexStrToU64(path[3].c_str()); char addrs[24]; OSUtils::ztsnprintf(addrs,sizeof(addrs),"%.10llx",(unsigned long long)address); json member,network; _db->get(nwid,network,address,member); json origMember(member); // for detecting changes DB::initMember(member); try { if (b.count("activeBridge")) member["activeBridge"] = OSUtils::jsonBool(b["activeBridge"],false); if (b.count("noAutoAssignIps")) member["noAutoAssignIps"] = OSUtils::jsonBool(b["noAutoAssignIps"],false); if (b.count("remoteTraceTarget")) { const std::string rtt(OSUtils::jsonString(b["remoteTraceTarget"],"")); if (rtt.length() == 10) { member["remoteTraceTarget"] = rtt; } else { member["remoteTraceTarget"] = json(); } } if (b.count("remoteTraceLevel")) member["remoteTraceLevel"] = OSUtils::jsonInt(b["remoteTraceLevel"],0ULL); if (b.count("authorized")) { const bool newAuth = OSUtils::jsonBool(b["authorized"],false); if (newAuth != OSUtils::jsonBool(member["authorized"],false)) { member["authorized"] = newAuth; member[((newAuth) ? "lastAuthorizedTime" : "lastDeauthorizedTime")] = now; if (newAuth) { member["lastAuthorizedCredentialType"] = "api"; member["lastAuthorizedCredential"] = json(); } } } if (b.count("ipAssignments")) { json &ipa = b["ipAssignments"]; if (ipa.is_array()) { json mipa(json::array()); for(unsigned long i=0;i= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } } member["ipAssignments"] = mipa; } } if (b.count("tags")) { json &tags = b["tags"]; if (tags.is_array()) { std::map mtags; for(unsigned long i=0;i::iterator t(mtags.begin());t!=mtags.end();++t) { json ta = json::array(); ta.push_back(t->first); ta.push_back(t->second); mtagsa.push_back(ta); if (mtagsa.size() >= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } member["tags"] = mtagsa; } } if (b.count("capabilities")) { json &capabilities = b["capabilities"]; if (capabilities.is_array()) { json mcaps = json::array(); for(unsigned long i=0;i= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } std::sort(mcaps.begin(),mcaps.end()); mcaps.erase(std::unique(mcaps.begin(),mcaps.end()),mcaps.end()); member["capabilities"] = mcaps; } } } catch ( ... ) { responseBody = "{ \"message\": \"exception while processing parameters in JSON body\" }"; responseContentType = "application/json"; return 400; } member["id"] = addrs; member["address"] = addrs; // legacy member["nwid"] = nwids; DB::cleanMember(member); _db->save(&origMember,member); responseBody = OSUtils::jsonDump(member); responseContentType = "application/json"; return 200; } // else 404 } else { // POST to network ID // Magic ID ending with ______ picks a random unused network ID if (path[1].substr(10) == "______") { nwid = 0; uint64_t nwidPrefix = (Utils::hexStrToU64(path[1].substr(0,10).c_str()) << 24) & 0xffffffffff000000ULL; uint64_t nwidPostfix = 0; for(unsigned long k=0;k<100000;++k) { // sanity limit on trials Utils::getSecureRandom(&nwidPostfix,sizeof(nwidPostfix)); uint64_t tryNwid = nwidPrefix | (nwidPostfix & 0xffffffULL); if ((tryNwid & 0xffffffULL) == 0ULL) tryNwid |= 1ULL; if (!_db->hasNetwork(tryNwid)) { nwid = tryNwid; break; } } if (!nwid) return 503; } OSUtils::ztsnprintf(nwids,sizeof(nwids),"%.16llx",(unsigned long long)nwid); json network; _db->get(nwid,network); json origNetwork(network); // for detecting changes DB::initNetwork(network); try { if (b.count("name")) network["name"] = OSUtils::jsonString(b["name"],""); if (b.count("private")) network["private"] = OSUtils::jsonBool(b["private"],true); if (b.count("enableBroadcast")) network["enableBroadcast"] = OSUtils::jsonBool(b["enableBroadcast"],false); if (b.count("multicastLimit")) network["multicastLimit"] = OSUtils::jsonInt(b["multicastLimit"],32ULL); if (b.count("mtu")) network["mtu"] = std::max(std::min((unsigned int)OSUtils::jsonInt(b["mtu"],ZT_DEFAULT_MTU),(unsigned int)ZT_MAX_MTU),(unsigned int)ZT_MIN_MTU); if (b.count("remoteTraceTarget")) { const std::string rtt(OSUtils::jsonString(b["remoteTraceTarget"],"")); if (rtt.length() == 10) { network["remoteTraceTarget"] = rtt; } else { network["remoteTraceTarget"] = json(); } } if (b.count("remoteTraceLevel")) network["remoteTraceLevel"] = OSUtils::jsonInt(b["remoteTraceLevel"],0ULL); if (b.count("v4AssignMode")) { json nv4m; json &v4m = b["v4AssignMode"]; if (v4m.is_string()) { // backward compatibility nv4m["zt"] = (OSUtils::jsonString(v4m,"") == "zt"); } else if (v4m.is_object()) { nv4m["zt"] = OSUtils::jsonBool(v4m["zt"],false); } else nv4m["zt"] = false; network["v4AssignMode"] = nv4m; } if (b.count("v6AssignMode")) { json nv6m; json &v6m = b["v6AssignMode"]; if (!nv6m.is_object()) nv6m = json::object(); if (v6m.is_string()) { // backward compatibility std::vector v6ms(OSUtils::split(OSUtils::jsonString(v6m,"").c_str(),",","","")); std::sort(v6ms.begin(),v6ms.end()); v6ms.erase(std::unique(v6ms.begin(),v6ms.end()),v6ms.end()); nv6m["rfc4193"] = false; nv6m["zt"] = false; nv6m["6plane"] = false; for(std::vector::iterator i(v6ms.begin());i!=v6ms.end();++i) { if (*i == "rfc4193") nv6m["rfc4193"] = true; else if (*i == "zt") nv6m["zt"] = true; else if (*i == "6plane") nv6m["6plane"] = true; } } else if (v6m.is_object()) { if (v6m.count("rfc4193")) nv6m["rfc4193"] = OSUtils::jsonBool(v6m["rfc4193"],false); if (v6m.count("zt")) nv6m["zt"] = OSUtils::jsonBool(v6m["zt"],false); if (v6m.count("6plane")) nv6m["6plane"] = OSUtils::jsonBool(v6m["6plane"],false); } else { nv6m["rfc4193"] = false; nv6m["zt"] = false; nv6m["6plane"] = false; } network["v6AssignMode"] = nv6m; } if (b.count("routes")) { json &rts = b["routes"]; if (rts.is_array()) { json nrts = json::array(); for(unsigned long i=0;i().c_str()); InetAddress v; if (via.is_string()) v.fromString(via.get().c_str()); if ( ((t.ss_family == AF_INET)||(t.ss_family == AF_INET6)) && (t.netmaskBitsValid()) ) { json tmp; char tmp2[64]; tmp["target"] = t.toString(tmp2); if (v.ss_family == t.ss_family) tmp["via"] = v.toIpString(tmp2); else tmp["via"] = json(); nrts.push_back(tmp); if (nrts.size() >= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } } } } network["routes"] = nrts; } } if (b.count("ipAssignmentPools")) { json &ipp = b["ipAssignmentPools"]; if (ipp.is_array()) { json nipp = json::array(); for(unsigned long i=0;i= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } } } network["ipAssignmentPools"] = nipp; } } if (b.count("rules")) { json &rules = b["rules"]; if (rules.is_array()) { json nrules = json::array(); for(unsigned long i=0;i= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } } } network["rules"] = nrules; } } if (b.count("authTokens")) { json &authTokens = b["authTokens"]; if (authTokens.is_object()) { json nat; for(json::iterator t(authTokens.begin());t!=authTokens.end();++t) { if ((t.value().is_number())&&(t.value() >= 0)) nat[t.key()] = t.value(); } network["authTokens"] = nat; } else { network["authTokens"] = {{}}; } } if (b.count("capabilities")) { json &capabilities = b["capabilities"]; if (capabilities.is_array()) { std::map< uint64_t,json > ncaps; for(unsigned long i=0;i= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } } } } ncap["rules"] = nrules; ncaps[capId] = ncap; } } json ncapsa = json::array(); for(std::map< uint64_t,json >::iterator c(ncaps.begin());c!=ncaps.end();++c) { ncapsa.push_back(c->second); if (ncapsa.size() >= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } network["capabilities"] = ncapsa; } } if (b.count("tags")) { json &tags = b["tags"]; if (tags.is_array()) { std::map< uint64_t,json > ntags; for(unsigned long i=0;i::iterator t(ntags.begin());t!=ntags.end();++t) { ntagsa.push_back(t->second); if (ntagsa.size() >= ZT_CONTROLLER_MAX_ARRAY_SIZE) break; } network["tags"] = ntagsa; } } } catch ( ... ) { responseBody = "{ \"message\": \"exception occurred while parsing body variables\" }"; responseContentType = "application/json"; return 400; } network["id"] = nwids; network["nwid"] = nwids; // legacy DB::cleanNetwork(network); _db->save(&origNetwork,network); responseBody = OSUtils::jsonDump(network); responseContentType = "application/json"; return 200; } // else 404 } // else 404 } return 404; } unsigned int EmbeddedNetworkController::handleControlPlaneHttpDELETE( const std::vector &path, const std::map &urlArgs, const std::map &headers, const std::string &body, std::string &responseBody, std::string &responseContentType) { if (!_db) return 500; if (path.empty()) return 404; if (path[0] == "network") { if ((path.size() >= 2)&&(path[1].length() == 16)) { const uint64_t nwid = Utils::hexStrToU64(path[1].c_str()); if (path.size() >= 3) { if ((path.size() == 4)&&(path[2] == "member")&&(path[3].length() == 10)) { const uint64_t address = Utils::hexStrToU64(path[3].c_str()); json network,member; _db->get(nwid,network,address,member); _db->eraseMember(nwid, address); { std::lock_guard l(_memberStatus_l); _memberStatus.erase(_MemberStatusKey(nwid,address)); } if (!member.size()) return 404; responseBody = OSUtils::jsonDump(member); responseContentType = "application/json"; return 200; } } else { json network; _db->get(nwid,network); _db->eraseNetwork(nwid); { std::lock_guard l(_memberStatus_l); for(auto i=_memberStatus.begin();i!=_memberStatus.end();) { if (i->first.networkId == nwid) _memberStatus.erase(i++); else ++i; } } if (!network.size()) return 404; responseBody = OSUtils::jsonDump(network); responseContentType = "application/json"; return 200; } } // else 404 } // else 404 return 404; } void EmbeddedNetworkController::handleRemoteTrace(const ZT_RemoteTrace &rt) { static volatile unsigned long idCounter = 0; char id[128],tmp[128]; std::string k,v; if (!_db) return; try { // Convert Dictionary into JSON object json d; char *saveptr = (char *)0; for(char *l=Utils::stok(rt.data,"\n",&saveptr);(l);l=Utils::stok((char *)0,"\n",&saveptr)) { char *eq = strchr(l,'='); if (eq > l) { k.assign(l,(unsigned long)(eq - l)); v.clear(); ++eq; while (*eq) { if (*eq == '\\') { ++eq; if (*eq) { switch(*eq) { case 'r': v.push_back('\r'); break; case 'n': v.push_back('\n'); break; case '0': v.push_back((char)0); break; case 'e': v.push_back('='); break; default: v.push_back(*eq); break; } ++eq; } } else { v.push_back(*(eq++)); } } if ((k.length() > 0)&&(v.length() > 0)) d[k] = v; } } const int64_t now = OSUtils::now(); OSUtils::ztsnprintf(id,sizeof(id),"%.10llx-%.16llx-%.10llx-%.4x",_signingId.address().toInt(),now,rt.origin,(unsigned int)(idCounter++ & 0xffff)); d["id"] = id; d["objtype"] = "trace"; d["ts"] = now; d["nodeId"] = Utils::hex10(rt.origin,tmp); _db->save((nlohmann::json *)0,d); } catch ( ... ) { // drop invalid trace messages if an error occurs } } void EmbeddedNetworkController::onNetworkUpdate(const uint64_t networkId) { // Send an update to all members of the network that are online const int64_t now = OSUtils::now(); std::lock_guard l(_memberStatus_l); for(auto i=_memberStatus.begin();i!=_memberStatus.end();++i) { if ((i->first.networkId == networkId)&&(i->second.online(now))&&(i->second.lastRequestMetaData)) request(networkId,InetAddress(),0,i->second.identity,i->second.lastRequestMetaData); } } void EmbeddedNetworkController::onNetworkMemberUpdate(const uint64_t networkId,const uint64_t memberId) { // Push update to member if online try { std::lock_guard l(_memberStatus_l); _MemberStatus &ms = _memberStatus[_MemberStatusKey(networkId,memberId)]; if ((ms.online(OSUtils::now()))&&(ms.lastRequestMetaData)) request(networkId,InetAddress(),0,ms.identity,ms.lastRequestMetaData); } catch ( ... ) {} } void EmbeddedNetworkController::onNetworkMemberDeauthorize(const uint64_t networkId,const uint64_t memberId) { const int64_t now = OSUtils::now(); Revocation rev((uint32_t)_node->prng(),networkId,0,now,ZT_REVOCATION_FLAG_FAST_PROPAGATE,Address(memberId),Revocation::CREDENTIAL_TYPE_COM); rev.sign(_signingId); { std::lock_guard l(_memberStatus_l); for(auto i=_memberStatus.begin();i!=_memberStatus.end();++i) { if ((i->first.networkId == networkId)&&(i->second.online(now))) _node->ncSendRevocation(Address(i->first.nodeId),rev); } } } void EmbeddedNetworkController::_request( uint64_t nwid, const InetAddress &fromAddr, uint64_t requestPacketId, const Identity &identity, const Dictionary &metaData) { char nwids[24]; DB::NetworkSummaryInfo ns; json network,member,origMember; if (!_db) return; if (((!_signingId)||(!_signingId.hasPrivate()))||(_signingId.address().toInt() != (nwid >> 24))||(!_sender)) return; const int64_t now = OSUtils::now(); if (requestPacketId) { std::lock_guard l(_memberStatus_l); _MemberStatus &ms = _memberStatus[_MemberStatusKey(nwid,identity.address().toInt())]; if ((now - ms.lastRequestTime) <= ZT_NETCONF_MIN_REQUEST_PERIOD) return; ms.lastRequestTime = now; } _db->nodeIsOnline(nwid,identity.address().toInt(),fromAddr); Utils::hex(nwid,nwids); _db->get(nwid,network,identity.address().toInt(),member,ns); if ((!network.is_object())||(network.size() == 0)) { _sender->ncSendError(nwid,requestPacketId,identity.address(),NetworkController::NC_ERROR_OBJECT_NOT_FOUND); return; } origMember = member; const bool newMember = ((!member.is_object())||(member.size() == 0)); DB::initMember(member); { const std::string haveIdStr(OSUtils::jsonString(member["identity"],"")); if (haveIdStr.length() > 0) { // If we already know this member's identity perform a full compare. This prevents // a "collision" from being able to auth onto our network in place of an already // known member. try { if (Identity(haveIdStr.c_str()) != identity) { _sender->ncSendError(nwid,requestPacketId,identity.address(),NetworkController::NC_ERROR_ACCESS_DENIED); return; } } catch ( ... ) { _sender->ncSendError(nwid,requestPacketId,identity.address(),NetworkController::NC_ERROR_ACCESS_DENIED); return; } } else { // If we do not yet know this member's identity, learn it. char idtmp[1024]; member["identity"] = identity.toString(false,idtmp); } } // These are always the same, but make sure they are set { char tmpid[128]; const std::string addrs(identity.address().toString(tmpid)); member["id"] = addrs; member["address"] = addrs; member["nwid"] = nwids; } // Determine whether and how member is authorized bool authorized = false; bool autoAuthorized = false; json autoAuthCredentialType,autoAuthCredential; if (OSUtils::jsonBool(member["authorized"],false)) { authorized = true; } else if (!OSUtils::jsonBool(network["private"],true)) { authorized = true; autoAuthorized = true; autoAuthCredentialType = "public"; } else { char presentedAuth[512]; if (metaData.get(ZT_NETWORKCONFIG_REQUEST_METADATA_KEY_AUTH,presentedAuth,sizeof(presentedAuth)) > 0) { presentedAuth[511] = (char)0; // sanity check if ((strlen(presentedAuth) > 6)&&(!strncmp(presentedAuth,"token:",6))) { const char *const presentedToken = presentedAuth + 6; json authTokens(network["authTokens"]); json &tokenExpires = authTokens[presentedToken]; if (tokenExpires.is_number()) { if ((tokenExpires == 0)||(tokenExpires > now)) { authorized = true; autoAuthorized = true; autoAuthCredentialType = "token"; autoAuthCredential = presentedToken; } } } } } // If we auto-authorized, update member record if ((autoAuthorized)&&(authorized)) { member["authorized"] = true; member["lastAuthorizedTime"] = now; member["lastAuthorizedCredentialType"] = autoAuthCredentialType; member["lastAuthorizedCredential"] = autoAuthCredential; } if (authorized) { // Update version info and meta-data if authorized and if this is a genuine request if (requestPacketId) { const uint64_t vMajor = metaData.getUI(ZT_NETWORKCONFIG_REQUEST_METADATA_KEY_NODE_MAJOR_VERSION,0); const uint64_t vMinor = metaData.getUI(ZT_NETWORKCONFIG_REQUEST_METADATA_KEY_NODE_MINOR_VERSION,0); const uint64_t vRev = metaData.getUI(ZT_NETWORKCONFIG_REQUEST_METADATA_KEY_NODE_REVISION,0); const uint64_t vProto = metaData.getUI(ZT_NETWORKCONFIG_REQUEST_METADATA_KEY_PROTOCOL_VERSION,0); member["vMajor"] = vMajor; member["vMinor"] = vMinor; member["vRev"] = vRev; member["vProto"] = vProto; { std::lock_guard l(_memberStatus_l); _MemberStatus &ms = _memberStatus[_MemberStatusKey(nwid,identity.address().toInt())]; ms.vMajor = (int)vMajor; ms.vMinor = (int)vMinor; ms.vRev = (int)vRev; ms.vProto = (int)vProto; ms.lastRequestMetaData = metaData; ms.identity = identity; } } } else { // If they are not authorized, STOP! DB::cleanMember(member); _db->save(&origMember,member); _sender->ncSendError(nwid,requestPacketId,identity.address(),NetworkController::NC_ERROR_ACCESS_DENIED); return; } // ------------------------------------------------------------------------- // If we made it this far, they are authorized. // ------------------------------------------------------------------------- int64_t credentialtmd = ZT_NETWORKCONFIG_DEFAULT_CREDENTIAL_TIME_MAX_MAX_DELTA; if (now > ns.mostRecentDeauthTime) { // If we recently de-authorized a member, shrink credential TTL/max delta to // be below the threshold required to exclude it. Cap this to a min/max to // prevent jitter or absurdly large values. const uint64_t deauthWindow = now - ns.mostRecentDeauthTime; if (deauthWindow < ZT_NETWORKCONFIG_DEFAULT_CREDENTIAL_TIME_MIN_MAX_DELTA) { credentialtmd = ZT_NETWORKCONFIG_DEFAULT_CREDENTIAL_TIME_MIN_MAX_DELTA; } else if (deauthWindow < (ZT_NETWORKCONFIG_DEFAULT_CREDENTIAL_TIME_MAX_MAX_DELTA + 5000ULL)) { credentialtmd = deauthWindow - 5000ULL; } } std::unique_ptr nc(new NetworkConfig()); nc->networkId = nwid; nc->type = OSUtils::jsonBool(network["private"],true) ? ZT_NETWORK_TYPE_PRIVATE : ZT_NETWORK_TYPE_PUBLIC; nc->timestamp = now; nc->credentialTimeMaxDelta = credentialtmd; nc->revision = OSUtils::jsonInt(network["revision"],0ULL); nc->issuedTo = identity.address(); if (OSUtils::jsonBool(network["enableBroadcast"],true)) nc->flags |= ZT_NETWORKCONFIG_FLAG_ENABLE_BROADCAST; Utils::scopy(nc->name,sizeof(nc->name),OSUtils::jsonString(network["name"],"").c_str()); nc->mtu = std::max(std::min((unsigned int)OSUtils::jsonInt(network["mtu"],ZT_DEFAULT_MTU),(unsigned int)ZT_MAX_MTU),(unsigned int)ZT_MIN_MTU); nc->multicastLimit = (unsigned int)OSUtils::jsonInt(network["multicastLimit"],32ULL); std::string rtt(OSUtils::jsonString(member["remoteTraceTarget"],"")); if (rtt.length() == 10) { nc->remoteTraceTarget = Address(Utils::hexStrToU64(rtt.c_str())); nc->remoteTraceLevel = (Trace::Level)OSUtils::jsonInt(member["remoteTraceLevel"],0ULL); } else { rtt = OSUtils::jsonString(network["remoteTraceTarget"],""); if (rtt.length() == 10) { nc->remoteTraceTarget = Address(Utils::hexStrToU64(rtt.c_str())); } else { nc->remoteTraceTarget.zero(); } nc->remoteTraceLevel = (Trace::Level)OSUtils::jsonInt(network["remoteTraceLevel"],0ULL); } for(std::vector
::const_iterator ab(ns.activeBridges.begin());ab!=ns.activeBridges.end();++ab) nc->addSpecialist(*ab,ZT_NETWORKCONFIG_SPECIALIST_TYPE_ACTIVE_BRIDGE); json &v4AssignMode = network["v4AssignMode"]; json &v6AssignMode = network["v6AssignMode"]; json &ipAssignmentPools = network["ipAssignmentPools"]; json &routes = network["routes"]; json &rules = network["rules"]; json &capabilities = network["capabilities"]; json &tags = network["tags"]; json &memberCapabilities = member["capabilities"]; json &memberTags = member["tags"]; if (metaData.getUI(ZT_NETWORKCONFIG_REQUEST_METADATA_KEY_RULES_ENGINE_REV,0) <= 0) { // Old versions with no rules engine support get an allow everything rule. // Since rules are enforced bidirectionally, newer versions *will* still // enforce rules on the inbound side. nc->ruleCount = 1; nc->rules[0].t = ZT_NETWORK_RULE_ACTION_ACCEPT; } else { if (rules.is_array()) { for(unsigned long i=0;iruleCount >= ZT_MAX_NETWORK_RULES) break; if (_parseRule(rules[i],nc->rules[nc->ruleCount])) ++nc->ruleCount; } } std::map< uint64_t,json * > capsById; if (!memberCapabilities.is_array()) memberCapabilities = json::array(); if (capabilities.is_array()) { for(unsigned long i=0;i::const_iterator ctmp = capsById.find(capId); if (ctmp != capsById.end()) { json *cap = ctmp->second; if ((cap)&&(cap->is_object())&&(cap->size() > 0)) { ZT_VirtualNetworkRule capr[ZT_MAX_CAPABILITY_RULES]; unsigned int caprc = 0; json &caprj = (*cap)["rules"]; if ((caprj.is_array())&&(caprj.size() > 0)) { for(unsigned long j=0;j= ZT_MAX_CAPABILITY_RULES) break; if (_parseRule(caprj[j],capr[caprc])) ++caprc; } } nc->capabilities[nc->capabilityCount] = Capability((uint32_t)capId,nwid,now,1,capr,caprc); if (nc->capabilities[nc->capabilityCount].sign(_signingId,identity.address())) ++nc->capabilityCount; if (nc->capabilityCount >= ZT_MAX_NETWORK_CAPABILITIES) break; } } } std::map< uint32_t,uint32_t > memberTagsById; if (memberTags.is_array()) { for(unsigned long i=0;i::const_iterator t(memberTagsById.begin());t!=memberTagsById.end();++t) { if (nc->tagCount >= ZT_MAX_NETWORK_TAGS) break; nc->tags[nc->tagCount] = Tag(nwid,now,identity.address(),t->first,t->second); if (nc->tags[nc->tagCount].sign(_signingId)) ++nc->tagCount; } } if (routes.is_array()) { for(unsigned long i=0;irouteCount >= ZT_MAX_NETWORK_ROUTES) break; json &route = routes[i]; json &target = route["target"]; json &via = route["via"]; if (target.is_string()) { const InetAddress t(target.get().c_str()); InetAddress v; if (via.is_string()) v.fromString(via.get().c_str()); if ((t.ss_family == AF_INET)||(t.ss_family == AF_INET6)) { ZT_VirtualNetworkRoute *r = &(nc->routes[nc->routeCount]); *(reinterpret_cast(&(r->target))) = t; if (v.ss_family == t.ss_family) *(reinterpret_cast(&(r->via))) = v; ++nc->routeCount; } } } } const bool noAutoAssignIps = OSUtils::jsonBool(member["noAutoAssignIps"],false); if ((v6AssignMode.is_object())&&(!noAutoAssignIps)) { if ((OSUtils::jsonBool(v6AssignMode["rfc4193"],false))&&(nc->staticIpCount < ZT_MAX_ZT_ASSIGNED_ADDRESSES)) { nc->staticIps[nc->staticIpCount++] = InetAddress::makeIpv6rfc4193(nwid,identity.address().toInt()); nc->flags |= ZT_NETWORKCONFIG_FLAG_ENABLE_IPV6_NDP_EMULATION; } if ((OSUtils::jsonBool(v6AssignMode["6plane"],false))&&(nc->staticIpCount < ZT_MAX_ZT_ASSIGNED_ADDRESSES)) { nc->staticIps[nc->staticIpCount++] = InetAddress::makeIpv66plane(nwid,identity.address().toInt()); nc->flags |= ZT_NETWORKCONFIG_FLAG_ENABLE_IPV6_NDP_EMULATION; } } bool haveManagedIpv4AutoAssignment = false; bool haveManagedIpv6AutoAssignment = false; // "special" NDP-emulated address types do not count json ipAssignments = member["ipAssignments"]; // we want to make a copy if (ipAssignments.is_array()) { for(unsigned long i=0;irouteCount;++rk) { if (reinterpret_cast(&(nc->routes[rk].target))->containsAddress(ip)) { const int nb = (int)(reinterpret_cast(&(nc->routes[rk].target))->netmaskBits()); if (nb > routedNetmaskBits) routedNetmaskBits = nb; } } if (routedNetmaskBits >= 0) { if (nc->staticIpCount < ZT_MAX_ZT_ASSIGNED_ADDRESSES) { ip.setPort(routedNetmaskBits); nc->staticIps[nc->staticIpCount++] = ip; } if (ip.ss_family == AF_INET) haveManagedIpv4AutoAssignment = true; else if (ip.ss_family == AF_INET6) haveManagedIpv6AutoAssignment = true; } } } } else { ipAssignments = json::array(); } if ( (ipAssignmentPools.is_array()) && ((v6AssignMode.is_object())&&(OSUtils::jsonBool(v6AssignMode["zt"],false))) && (!haveManagedIpv6AutoAssignment) && (!noAutoAssignIps) ) { for(unsigned long p=0;((p s[1])&&((e[1] - s[1]) >= 0xffffffffffULL)) { // First see if we can just cram a ZeroTier ID into the higher 64 bits. If so do that. xx[0] = Utils::hton(x[0]); xx[1] = Utils::hton(x[1] + identity.address().toInt()); } else { // Otherwise pick random addresses -- this technically doesn't explore the whole range if the lower 64 bit range is >= 1 but that won't matter since that would be huge anyway Utils::getSecureRandom((void *)xx,16); if ((e[0] > s[0])) xx[0] %= (e[0] - s[0]); else xx[0] = 0; if ((e[1] > s[1])) xx[1] %= (e[1] - s[1]); else xx[1] = 0; xx[0] = Utils::hton(x[0] + xx[0]); xx[1] = Utils::hton(x[1] + xx[1]); } InetAddress ip6((const void *)xx,16,0); // Check if this IP is within a local-to-Ethernet routed network int routedNetmaskBits = 0; for(unsigned int rk=0;rkrouteCount;++rk) { if ( (!nc->routes[rk].via.ss_family) && (nc->routes[rk].target.ss_family == AF_INET6) && (reinterpret_cast(&(nc->routes[rk].target))->containsAddress(ip6)) ) routedNetmaskBits = reinterpret_cast(&(nc->routes[rk].target))->netmaskBits(); } // If it's routed, then try to claim and assign it and if successful end loop if ( (routedNetmaskBits > 0) && (!std::binary_search(ns.allocatedIps.begin(),ns.allocatedIps.end(),ip6)) ) { char tmpip[64]; const std::string ipStr(ip6.toIpString(tmpip)); if (std::find(ipAssignments.begin(),ipAssignments.end(),ipStr) == ipAssignments.end()) { ipAssignments.push_back(ipStr); member["ipAssignments"] = ipAssignments; ip6.setPort((unsigned int)routedNetmaskBits); if (nc->staticIpCount < ZT_MAX_ZT_ASSIGNED_ADDRESSES) nc->staticIps[nc->staticIpCount++] = ip6; haveManagedIpv6AutoAssignment = true; break; } } } } } } } if ( (ipAssignmentPools.is_array()) && ((v4AssignMode.is_object())&&(OSUtils::jsonBool(v4AssignMode["zt"],false))) && (!haveManagedIpv4AutoAssignment) && (!noAutoAssignIps) ) { for(unsigned long p=0;((p(&ipRangeStartIA)->sin_addr.s_addr)); uint32_t ipRangeEnd = Utils::ntoh((uint32_t)(reinterpret_cast(&ipRangeEndIA)->sin_addr.s_addr)); if ((ipRangeEnd < ipRangeStart)||(ipRangeStart == 0)) continue; uint32_t ipRangeLen = ipRangeEnd - ipRangeStart; // Start with the LSB of the member's address uint32_t ipTrialCounter = (uint32_t)(identity.address().toInt() & 0xffffffff); for(uint32_t k=ipRangeStart,trialCount=0;((k<=ipRangeEnd)&&(trialCount < 1000));++k,++trialCount) { uint32_t ip = (ipRangeLen > 0) ? (ipRangeStart + (ipTrialCounter % ipRangeLen)) : ipRangeStart; ++ipTrialCounter; if ((ip & 0x000000ff) == 0x000000ff) { continue; // don't allow addresses that end in .255 } // Check if this IP is within a local-to-Ethernet routed network int routedNetmaskBits = -1; for(unsigned int rk=0;rkrouteCount;++rk) { if (nc->routes[rk].target.ss_family == AF_INET) { uint32_t targetIp = Utils::ntoh((uint32_t)(reinterpret_cast(&(nc->routes[rk].target))->sin_addr.s_addr)); int targetBits = Utils::ntoh((uint16_t)(reinterpret_cast(&(nc->routes[rk].target))->sin_port)); if ((ip & (0xffffffff << (32 - targetBits))) == targetIp) { routedNetmaskBits = targetBits; break; } } } // If it's routed, then try to claim and assign it and if successful end loop const InetAddress ip4(Utils::hton(ip),0); if ( (routedNetmaskBits > 0) && (!std::binary_search(ns.allocatedIps.begin(),ns.allocatedIps.end(),ip4)) ) { char tmpip[64]; const std::string ipStr(ip4.toIpString(tmpip)); if (std::find(ipAssignments.begin(),ipAssignments.end(),ipStr) == ipAssignments.end()) { ipAssignments.push_back(ipStr); member["ipAssignments"] = ipAssignments; if (nc->staticIpCount < ZT_MAX_ZT_ASSIGNED_ADDRESSES) { struct sockaddr_in *const v4ip = reinterpret_cast(&(nc->staticIps[nc->staticIpCount++])); v4ip->sin_family = AF_INET; v4ip->sin_port = Utils::hton((uint16_t)routedNetmaskBits); v4ip->sin_addr.s_addr = Utils::hton(ip); } haveManagedIpv4AutoAssignment = true; break; } } } } } } } // Issue a certificate of ownership for all static IPs if (nc->staticIpCount) { nc->certificatesOfOwnership[0] = CertificateOfOwnership(nwid,now,identity.address(),1); for(unsigned int i=0;istaticIpCount;++i) nc->certificatesOfOwnership[0].addThing(nc->staticIps[i]); nc->certificatesOfOwnership[0].sign(_signingId); nc->certificateOfOwnershipCount = 1; } CertificateOfMembership com(now,credentialtmd,nwid,identity.address()); if (com.sign(_signingId)) { nc->com = com; } else { _sender->ncSendError(nwid,requestPacketId,identity.address(),NetworkController::NC_ERROR_INTERNAL_SERVER_ERROR); return; } DB::cleanMember(member); _db->save(&origMember,member); _sender->ncSendConfig(nwid,requestPacketId,identity.address(),*(nc.get()),metaData.getUI(ZT_NETWORKCONFIG_REQUEST_METADATA_KEY_VERSION,0) < 6); } void EmbeddedNetworkController::_startThreads() { std::lock_guard l(_threads_l); if (!_threads.empty()) return; const long hwc = std::max((long)std::thread::hardware_concurrency(),(long)1); for(long t=0;tnwid,qe->fromAddr,qe->requestPacketId,qe->identity,qe->metaData); delete qe; } } catch (std::exception &e) { fprintf(stderr,"ERROR: exception in controller request handling thread: %s" ZT_EOL_S,e.what()); } catch ( ... ) { fprintf(stderr,"ERROR: exception in controller request handling thread: unknown exception" ZT_EOL_S); } } }); } } } // namespace ZeroTier