#include #include #include #include #include #include #include #include #include #include "I2PEndian.h" #include "Reseed.h" #include "Log.h" #include "Identity.h" #include "NetDb.h" #include "util.h" namespace i2p { namespace data { static std::vector httpReseedHostList = { "http://193.150.121.66/netDb/", "http://netdb.i2p2.no/", "http://reseed.i2p-projekt.de/", "http://cowpuncher.drollette.com/netdb/", "http://i2p.mooo.com/netDb/", "http://reseed.info/", "http://uk.reseed.i2p2.no/", "http://us.reseed.i2p2.no/", "http://jp.reseed.i2p2.no/", "http://i2p-netdb.innovatio.no/", "http://ieb9oopo.mooo.com" }; //TODO: Remember to add custom port support. Not all serves on 443 static std::vector httpsReseedHostList = { "https://193.150.121.66/netDb/", "https://netdb.i2p2.no/", "https://reseed.i2p-projekt.de/", "https://cowpuncher.drollette.com/netdb/", "https://i2p.mooo.com/netDb/", "https://reseed.info/", "https://i2p-netdb.innovatio.no/", "https://ieb9oopo.mooo.com/", "https://ssl.webpack.de/ivae2he9.sg4.e-plaza.de/" // Only HTTPS and SU3 (v2) support }; //TODO: Implement v2 reseeding. Lightweight zip library is needed. //TODO: Implement SU3, utils. Reseeder::Reseeder() { } Reseeder::~Reseeder() { } bool Reseeder::reseedNow() { try { // Seems like the best place to try to intercept with SSL /*ssl_server = true; try { // SSL } catch (std::exception& e) { LogPrint("Exception in SSL: ", e.what()); }*/ std::string reseedHost = httpReseedHostList[(rand() % httpReseedHostList.size())]; LogPrint("Reseeding from ", reseedHost); std::string content = i2p::util::http::httpRequest(reseedHost); if (content == "") { LogPrint("Reseed failed"); return false; } boost::regex e("<\\s*A\\s+[^>]*href\\s*=\\s*\"([^\"]*)\"", boost::regex::normal | boost::regbase::icase); boost::sregex_token_iterator i(content.begin(), content.end(), e, 1); boost::sregex_token_iterator j; //TODO: Ugly code, try to clean up. //TODO: Try to reduce N number of variables std::string name; std::string routerInfo; std::string tmpUrl; std::string filename; std::string ignoreFileSuffix = ".su3"; boost::filesystem::path root = i2p::util::filesystem::GetDataDir(); while (i != j) { name = *i++; if (name.find(ignoreFileSuffix)!=std::string::npos) continue; LogPrint("Downloading ", name); tmpUrl = reseedHost; tmpUrl.append(name); routerInfo = i2p::util::http::httpRequest(tmpUrl); if (routerInfo.size()==0) continue; filename = root.string(); #ifndef _WIN32 filename += "/netDb/r"; #else filename += "\\netDb\\r"; #endif filename += name.at(11); // first char in id #ifndef _WIN32 filename.append("/"); #else filename.append("\\"); #endif filename.append(name.c_str()); std::ofstream outfile (filename, std::ios::binary); outfile << routerInfo; outfile.close(); } return true; } catch (std::exception& ex) { //TODO: error reporting return false; } return false; } int Reseeder::ReseedNowSU3 () { CryptoPP::AutoSeededRandomPool rnd; auto ind = rnd.GenerateWord32 (0, httpReseedHostList.size() - 1); std::string reseedHost = httpReseedHostList[ind]; return ReseedFromSU3 (reseedHost); } int Reseeder::ReseedFromSU3 (const std::string& host) { std::string url = host + "i2pseeds.su3"; LogPrint (eLogInfo, "Dowloading SU3 from ", host); std::string su3 = i2p::util::http::httpRequest (url); if (su3.length () > 0) { std::stringstream s(su3); return ProcessSU3Stream (s); } else { LogPrint (eLogWarning, "SU3 download failed"); return 0; } } int Reseeder::ProcessSU3File (const char * filename) { std::ifstream s(filename, std::ifstream::binary); if (s.is_open ()) return ProcessSU3Stream (s); else { LogPrint (eLogError, "Can't open file ", filename); return 0; } } const char SU3_MAGIC_NUMBER[]="I2Psu3"; const uint32_t ZIP_HEADER_SIGNATURE = 0x04034B50; const uint16_t ZIP_BIT_FLAG_DATA_DESCRIPTOR = 0x0008; int Reseeder::ProcessSU3Stream (std::istream& s) { char magicNumber[7]; s.read (magicNumber, 7); // magic number and zero byte 6 if (strcmp (magicNumber, SU3_MAGIC_NUMBER)) { LogPrint (eLogError, "Unexpected SU3 magic number"); return 0; } s.seekg (1, std::ios::cur); // su3 file format version SigningKeyType signatureType; s.read ((char *)&signatureType, 2); // signature type signatureType = be16toh (signatureType); uint16_t signatureLength; s.read ((char *)&signatureLength, 2); // signature length signatureLength = be16toh (signatureLength); s.seekg (1, std::ios::cur); // unused uint8_t versionLength; s.read ((char *)&versionLength, 1); // version length s.seekg (1, std::ios::cur); // unused uint8_t signerIDLength; s.read ((char *)&signerIDLength, 1); // signer ID length uint64_t contentLength; s.read ((char *)&contentLength, 8); // content length contentLength = be64toh (contentLength); s.seekg (1, std::ios::cur); // unused uint8_t fileType; s.read ((char *)&fileType, 1); // file type if (fileType != 0x00) // zip file { LogPrint (eLogError, "Can't handle file type ", (int)fileType); return 0; } s.seekg (1, std::ios::cur); // unused uint8_t contentType; s.read ((char *)&contentType, 1); // content type if (contentType != 0x03) // reseed data { LogPrint (eLogError, "Unexpected content type ", (int)contentType); return 0; } s.seekg (12, std::ios::cur); // unused s.seekg (versionLength, std::ios::cur); // skip version s.seekg (signerIDLength, std::ios::cur); // skip signer ID // handle content int numFiles = 0; size_t contentPos = s.tellg (); while (!s.eof ()) { uint32_t signature; s.read ((char *)&signature, 4); signature = le32toh (signature); if (signature == ZIP_HEADER_SIGNATURE) { // next local file s.seekg (2, std::ios::cur); // version uint16_t bitFlag; s.read ((char *)&bitFlag, 2); bitFlag = le16toh (bitFlag); uint16_t compressionMethod; s.read ((char *)&compressionMethod, 2); compressionMethod = le16toh (compressionMethod); s.seekg (8, std::ios::cur); // skip fields we don't care about uint32_t compressedSize, uncompressedSize; s.read ((char *)&compressedSize, 4); compressedSize = le32toh (compressedSize); s.read ((char *)&uncompressedSize, 4); uncompressedSize = le32toh (uncompressedSize); uint16_t fileNameLength, extraFieldLength; s.read ((char *)&fileNameLength, 2); fileNameLength = le16toh (fileNameLength); s.read ((char *)&extraFieldLength, 2); extraFieldLength = le16toh (extraFieldLength); char localFileName[255]; s.read (localFileName, fileNameLength); localFileName[fileNameLength] = 0; s.seekg (extraFieldLength, std::ios::cur); // take care about data desriptor if presented if (bitFlag & ZIP_BIT_FLAG_DATA_DESCRIPTOR) { size_t pos = s.tellg (); if (!FindZipDataDescriptor (s)) { LogPrint (eLogError, "SU3 archive data descriptor not found"); return numFiles; } s.seekg (4, std::ios::cur); // skip CRC-32 s.read ((char *)&compressedSize, 4); compressedSize = le32toh (compressedSize) + 4; // ??? we must consider signature as part of compressed data s.read ((char *)&uncompressedSize, 4); uncompressedSize = le32toh (uncompressedSize); // now we know compressed and uncompressed size s.seekg (pos, std::ios::beg); // back to compressed data } LogPrint (eLogDebug, "Proccessing file ", localFileName, " ", compressedSize, " bytes"); if (!compressedSize) { LogPrint (eLogWarning, "Unexpected size 0. Skipped"); continue; } uint8_t * compressed = new uint8_t[compressedSize]; s.read ((char *)compressed, compressedSize); if (compressionMethod) // we assume Deflate { CryptoPP::Inflator decompressor; decompressor.Put (compressed, compressedSize); decompressor.MessageEnd(); if (decompressor.MaxRetrievable () <= uncompressedSize) { uint8_t * uncompressed = new uint8_t[uncompressedSize]; decompressor.Get (uncompressed, uncompressedSize); i2p::data::netdb.AddRouterInfo (uncompressed, uncompressedSize); numFiles++; delete[] uncompressed; } else LogPrint (eLogError, "Actual uncompressed size ", decompressor.MaxRetrievable (), " exceed ", uncompressedSize, " from header"); } else // no compression { i2p::data::netdb.AddRouterInfo (compressed, compressedSize); numFiles++; } delete[] compressed; if (bitFlag & ZIP_BIT_FLAG_DATA_DESCRIPTOR) s.seekg (12, std::ios::cur); // skip data descriptor section if presented (12 = 16 - 4) } else break; // no more files size_t end = s.tellg (); if (end - contentPos >= contentLength) break; // we are beyond contentLength } return numFiles; } const uint8_t ZIP_DATA_DESCRIPTOR_SIGNATURE[] = { 0x50, 0x4B, 0x07, 0x08 }; bool Reseeder::FindZipDataDescriptor (std::istream& s) { size_t nextInd = 0; while (!s.eof ()) { uint8_t nextByte; s.read ((char *)&nextByte, 1); if (nextByte == ZIP_DATA_DESCRIPTOR_SIGNATURE[nextInd]) { nextInd++; if (nextInd >= sizeof (ZIP_DATA_DESCRIPTOR_SIGNATURE)) return true; } else nextInd = 0; } return s; } const char CERTIFICATE_HEADER[] = "-----BEGIN CERTIFICATE-----"; const char CERTIFICATE_FOOTER[] = "-----END CERTIFICATE-----"; void Reseeder::LoadCertificate (const std::string& filename) { std::ifstream s(filename, std::ifstream::binary); if (s.is_open ()) { s.seekg (0, std::ios::end); size_t len = s.tellg (); s.seekg (0, std::ios::beg); char buf[2048]; s.read (buf, len); std::string cert (buf, len); // assume file in pem format auto pos1 = cert.find (CERTIFICATE_HEADER); auto pos2 = cert.find (CERTIFICATE_FOOTER); if (pos1 == std::string::npos || pos2 == std::string::npos) { LogPrint (eLogError, "Malformed certificate file"); return; } pos1 += strlen (CERTIFICATE_HEADER); pos2 -= pos1; std::string base64 = cert.substr (pos1, pos2); CryptoPP::ByteQueue queue; CryptoPP::Base64Decoder decoder; // regular base64 rather than I2P decoder.Attach (new CryptoPP::Redirector (queue)); decoder.Put ((const uint8_t *)base64.data(), base64.length()); decoder.MessageEnd (); // extract X.509 CryptoPP::BERSequenceDecoder x509Cert (queue); CryptoPP::BERSequenceDecoder tbsCert (x509Cert); // version uint32_t ver; CryptoPP::BERGeneralDecoder context (tbsCert, CryptoPP::CONTEXT_SPECIFIC | CryptoPP::CONSTRUCTED); CryptoPP::BERDecodeUnsigned(context, ver, CryptoPP::INTEGER); // serial CryptoPP::Integer serial; serial.BERDecode(tbsCert); // signature CryptoPP::BERSequenceDecoder signature (tbsCert); signature.SkipAll(); // issuer CryptoPP::BERSequenceDecoder issuer (tbsCert); { CryptoPP::BERSetDecoder c (issuer); c.SkipAll(); CryptoPP::BERSetDecoder st (issuer); st.SkipAll(); CryptoPP::BERSetDecoder l (issuer); l.SkipAll(); CryptoPP::BERSetDecoder o (issuer); o.SkipAll(); CryptoPP::BERSetDecoder ou (issuer); ou.SkipAll(); CryptoPP::BERSetDecoder cn (issuer); { CryptoPP::BERSequenceDecoder attributes (cn); { CryptoPP::BERGeneralDecoder ident(attributes, CryptoPP::OBJECT_IDENTIFIER); ident.SkipAll (); std::string name; CryptoPP::BERDecodeTextString (attributes, name, CryptoPP::UTF8_STRING); LogPrint (eLogInfo, "Issuer name: ", name); } } } issuer.SkipAll(); // validity CryptoPP::BERSequenceDecoder validity (tbsCert); validity.SkipAll(); // subject CryptoPP::BERSequenceDecoder subject (tbsCert); subject.SkipAll(); // public key CryptoPP::BERSequenceDecoder publicKey (tbsCert); publicKey.SkipAll(); tbsCert.SkipAll(); x509Cert.SkipAll(); } else LogPrint (eLogError, "Can't open certificate file ", filename); } } }