/* $Id: netaddrstr.cpp $ */ /** @file * IPRT - Network Address String Handling. * * @remarks Don't add new functionality to this file, it goes into netaddrstr2.cpp * or some other suitable file (legal reasons + code not up to oracle * quality standards and requires rewrite from scratch). */ /* * Contributed by Oliver Loch. * * Copyright (C) 2012-2020 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #include "internal/iprt.h" #include #include #include #include #include "internal/string.h" /** @page pg_rtnetipv6_addr IPv6 Address Format * * IPv6 Addresses, their representation in text and other problems. * * The following is based on: * * - http://tools.ietf.org/html/rfc4291 * - http://tools.ietf.org/html/rfc5952 * - http://tools.ietf.org/html/rfc6052 * * * Before you start using those functions, you should have an idea of * what you're dealing with, before you come and blame the functions... * * First of all, the address itself: * * An address is written like this: (READ THIS FINE MANUAL!) * * - 2001:db8:abc:def::1 * * The characters between two colons are called a "hextet". * Each hextet consists of four characters and each IPv6 address * consists of a maximum of eight hextets. So a full blown address * would look like this: * * - 1111:2222:3333:4444:5555:6666:7777:8888 * * The allowed characters are "0123456789abcdef". They have to be * lower case. Upper case is not allowed. * * *** Gaps and adress shortening * * If an address contains hextets that contain only "0"s, they * can be shortened, like this: * * - 1111:2222:0000:0000:0000:0000:7777:8888 -> 1111:2222::7777:8888 * * The double colon represents the hextets that have been shortened "::". * The "::" will be called "gap" from now on. * * When shortening an address, there are some special rules that need to be applied: * * - Shorten always the longest group of hextets. * * Let's say, you have this address: 2001:db8:0:0:0:1:0:0 then it has to be * shortened to "2001:db8::1:0:0". Shortening to "2001:db8:0:0:0:1::" would * return an error. * * - Two or more gaps the same size. * * Let's say you have this address: 2001:db8:0:0:1:0:0:1. As you can see, there * are two gaps, both the size of two hextets. If you shorten the last two hextets, * you end up in pain, as the RFC forbids this, so the correct address is: * "2001:db8::1:0:0:1" * * It's important to note that an address can only be shortened ONE TIME! * This is invalid: "2001:db8::1::1" * * *** The scope. * * Each address has a so called "scope" it is added to the end of the address, * separated by a percent sign "%". If there is no scope at the end, it defaults * to "0". * * So "2001:db8::1" is the same as "2001:db8::1%0". * * As in IPv6 all network interfaces can/should have the same address, the scope * gives you the ability to choose on which interface the system should listen. * * AFAIK, the scope can be used with unicast as well as link local addresses, but * it is mandatory with link local addresses (starting with fe80::). * * On Linux the default scope is the interface's name. On Windows it's just the index * of the interface. Run "route print -6" in the shell, to see the interface's index * on Winodows. * * All functions can deal with the scope, and DO NOT warn if you put garbage there. * * *** Port added to the IPv6 address * * There is only one way to add a port to an IPv6 address is to embed it in brackets: * * [2001:db8::1]:12345 * * This gives you the address "2001:db8::1" and the port "12345". * * What also works, but is not recommended by rfc is to separate the port * by a dot: * * 2001:db8::1.12345 * * It even works with embedded IPv4 addresses. * * *** Special addresses and how they are written * * The following are notations to represent "special addresses". * * "::" IN6ADDR_ANY * ":::123" IN6ADDR_ANY with port "123" * "[::]:123" IN6ADDR_ANY with port "123" * "[:::123]" -> NO. Not allowed and makes no sense * "::1" -> address of the loopback device (127.0.0.1 in v4) * * On systems with dual sockets, one can use so called embedded IPv4 addresses: * * "::ffff:192.168.1.1" results in the IPv6 address "::ffff:c0a8:0101" as two octets * of the IPv4 address will be converted to one hextet in the IPv6 address. * * The prefix of such addresses MUST BE "::ffff:", 10 bytes as zero and two bytes as 255. * * The so called IPv4-compatible IPv6 addresses are deprecated and no longer in use. * * *** Valid addresses and string * * If you use any of the IPv6 address functions, keep in mind, that those addresses * are all returning "valid" even if the underlying system (e.g. VNC) doesn't like * such strings. * * [2001:db8::1] * [2001:db8::1]:12345 * * and so on. So to make sure you only pass the underlying software a pure IPv6 address * without any garbage, you should use the "outAddress" parameters to get a RFC compliant * address returned. * * So after reading the above, you'll start using the functions and see a bool called * "followRfc" which is true by default. This is what this bool does: * * The following addresses all represent the exact same address: * * 1 - 2001:db8::1 * 2 - 2001:db8:0::1 * 3 - 2001:0db8:0000:0000:0000:0000:0000:0001 * 4 - 2001:DB8::1 * 5 - [2001:db8::1] * 6 - [2001:db8:0::1] * * According to RFC 5952, number two, three, four and six are invalid. * * #2 - because there is a single hextet that hasn't been shortened * * #3 - because there has nothing been shortened (hextets 3 to 7) and * there are leading zeros in at least one hextet ("0db8") * * #4 - all characters in an IPv6 address have to be lower case * * #6 - same as two but included in brackets * * If you follow RFC, the above addresses are not converted and an * error is returned. If you turn RFC off, you will get the expected * representation of the address. * * It's a nice way to convert "weird" addresses to rfc compliant addresses * */ /** * Parses any string and tests if it is an IPv6 Address * * This function should NOT be used directly. If you do, note * that no security checks are done at the moment. This can change. * * @returns iprt sstatus code, yeah, right... This function most certainly DOES * NOT RETURN ANY IPRT STATUS CODES. It's also a unreadable mess. * @param pszAddress The strin that holds the IPv6 address * @param addressLength The length of pszAddress * @param pszAddressOut Returns a plain, full blown IPv6 address * as a char array * @param addressOutSize The size of pszAddressOut (length) * @param pPortOut 32 bit unsigned integer, holding the port * If pszAddress doesn't contain a port, it's 0 * @param pszScopeOut Returns the scope of the address, if none it's 0 * @param scopeOutSize sizeof(pszScopeOut) * @param pBrackets returns true if the address was enclosed in brackets * @param pEmbeddedV4 returns true if the address is an embedded IPv4 address * @param followRfc if set to true, the function follows RFC (default) */ static int rtStrParseAddrStr6(const char *pszAddress, size_t addressLength, char *pszAddressOut, size_t addressOutSize, uint32_t *pPortOut, char *pszIfIdOut, size_t ifIdOutSize, bool *pBrackets, bool *pEmbeddedV4, bool followRfc) { /************************\ * Pointer Hell Ahead * \************************/ const char szIpV6AddressChars[] = "ABCDEF01234567890abcdef.:[]%"; // order IMPORTANT const char szIpV4AddressChars[] = "01234567890.:[]"; // order IMPORTANT const char szLinkLocalPrefix[] = "FfEe8800"; // const char *pszIpV6AddressChars = NULL, *pszIpV4AddressChars = NULL, *pszLinkLocalPrefix = NULL; char *pszSourceAddress = NULL, *pszSourceAddressStart = NULL; char *pszResultAddress = NULL, *pszResultAddressStart = NULL; char *pszResultAddress4 = NULL, *pszResultAddress4Start = NULL; char *pszResultPort = NULL, *pszResultPortStart = NULL; char *pszInternalAddress = NULL, *pszInternalAddressStart = NULL; char *pszInternalPort = NULL, *pszInternalPortStart = NULL; char *pStart = NULL, *pNow = NULL, *pNext = NULL, *pNowChar = NULL, *pIfId = NULL, *pIfIdEnd = NULL; char *pNowDigit = NULL, *pFrom = NULL, *pTo = NULL, *pLast = NULL; char *pGap = NULL, *pMisc = NULL, *pDotStart = NULL, *pFieldStart = NULL, *pFieldEnd = NULL; char *pFieldStartLongest = NULL, *pBracketOpen = NULL, *pBracketClose = NULL; char *pszRc = NULL; bool isLinkLocal = false; char szDummy[4]; uint8_t *pByte = NULL; uint32_t byteOut = 0; uint16_t returnValue = 0; uint32_t colons = 0; uint32_t colonsOverAll = 0; uint32_t fieldLength = 0; uint32_t dots = 0; size_t gapSize = 0; uint32_t intPortOut = 0; pszIpV4AddressChars = &szIpV4AddressChars[0]; pszIpV6AddressChars = &szIpV6AddressChars[6]; pszLinkLocalPrefix = &szLinkLocalPrefix[6]; if (!followRfc) pszIpV6AddressChars = &szIpV6AddressChars[0]; if (addressLength<2) returnValue = 711; pszResultAddressStart = (char *)RTMemTmpAlloc(34); pszInternalAddressStart = (char *)RTMemTmpAlloc(34); pszInternalPortStart = (char * )RTMemTmpAlloc(10); if (! (pszResultAddressStart && pszInternalAddressStart && pszInternalPortStart)) { if (pszResultAddressStart) RTMemTmpFree(pszResultAddressStart); if (pszInternalAddressStart) RTMemTmpFree(pszInternalAddressStart); if (pszInternalPortStart) RTMemTmpFree(pszInternalPortStart); return -701; } memset(szDummy, '\0', 4); pszResultAddress = pszResultAddressStart; memset(pszResultAddressStart, '\0', 34); pszInternalAddress = pszInternalAddressStart; memset(pszInternalAddressStart, '\0' , 34); pszInternalPort = pszInternalPortStart; memset(pszInternalPortStart, '\0', 10); pszSourceAddress = pszSourceAddressStart = (char *)pszAddress; pFrom = pTo = pStart = pLast = pszSourceAddressStart; while (*pszSourceAddress != '\0' && !returnValue) { pNow = NULL; pNext = NULL; pNowChar = NULL; pNowDigit = NULL; pNow = pszSourceAddress; pNext = pszSourceAddress + 1; if (!pFrom) pFrom = pTo = pNow; pNowChar = (char *)memchr(pszIpV6AddressChars, *pNow, strlen(pszIpV6AddressChars)); pNowDigit = (char *)memchr(pszIpV6AddressChars, *pNow, strlen(pszIpV6AddressChars) - 5); if (pszResultPort) { if (pLast && (pszResultPort == pszSourceAddressStart)) { if (*pLast == '\0') returnValue = 721; pszResultPortStart = (char *)RTMemTmpAlloc(10); if (!pszResultPortStart) returnValue = 702; memset(pszResultPortStart, '\0', 10); pszResultPort = pszResultPortStart; pszSourceAddress = pLast; pMisc = pLast; pLast = NULL; continue; } pNowDigit = NULL; pNowDigit = (char *)memchr(pszIpV4AddressChars, *pNow, strlen(pszIpV4AddressChars) - 4); if (strlen(pszResultPortStart) == 5) returnValue = 11; if (*pNow == '0' && pszResultPort == pszResultPortStart && *pNext != '\0' && (pNow - pMisc) < 5 ) { pszSourceAddress++; continue; } if (pNowDigit) { *pszResultPort = *pNowDigit; pszResultPort++; pszSourceAddress++; continue; } else returnValue = 12; } if (pszResultAddress4) { if (pszResultAddress4 == pszSourceAddressStart && pLast) { dots = 0; pszResultAddress4 = NULL; pszResultAddress4Start = NULL; pszResultAddress4Start = (char *)RTMemTmpAlloc(20); if (!pszResultAddress4Start) { returnValue = 401; break; } memset(pszResultAddress4Start, '\0', 20); pszResultAddress4 = pszResultAddress4Start; pszSourceAddress = pLast; pFrom = pLast; pTo = pLast; pLast = NULL; continue; } pTo = pNow; pNowDigit = NULL; pNowDigit = (char *)memchr(pszIpV4AddressChars, *pNow, strlen(pszIpV4AddressChars) - 4); if (!pNowDigit && *pNow != '.' && *pNow != ']' && *pNow != ':' && *pNow != '%') returnValue = 412; if ((pNow - pFrom) > 3) { returnValue = 402; break; } if (pNowDigit && *pNext != '\0') { pszSourceAddress++; continue; } if (!pNowDigit && !pBracketOpen && (*pNext == '.' || *pNext == ']' || *pNext == ':')) returnValue = 411; memset(pszResultAddress4, '0', 3); pMisc = pszResultAddress4 + 2; pszResultAddress4 = pszResultAddress4 + 3; if (*pNow != '.' && !pNowDigit && strlen(pszResultAddress4Start) < 9) returnValue = 403; if ((pTo - pFrom) > 0) pTo--; dots++; while (pTo >= pFrom) { *pMisc = *pTo; pMisc--; pTo--; } if (dots == 4 && *pNow == '.') { if (!pBracketOpen) { pszResultPort = pszSourceAddressStart; pLast = pNext; } else { returnValue = 409; } } dots = 0; pFrom = pNext; pTo = pNext; if (strlen(pszResultAddress4Start) > 11) pszResultAddress4 = NULL; if ((*pNow == ':' || *pNow == '.') && strlen(pszResultAddress4Start) == 12) { pLast = pNext; pszResultPort = pszSourceAddressStart; } if (*pNow == '%') { pIfId = pNow; pLast = pNow; continue; } pszSourceAddress = pNext; if (*pNow != ']') continue; pFrom = pNow; pTo = pNow; } if (pIfId && (!pIfIdEnd)) { if (*pIfId == '%' && pIfId == pLast && *pNext != '\0') { pFrom = pNext; pIfId = pNext; pLast = NULL; pszSourceAddress++; continue; } if (*pNow == '%' && pIfId <= pNow) { returnValue = 442; break; } if (*pNow != ']' && *pNext != '\0') { pTo = pNow; pszSourceAddress++; continue; } if (*pNow == ']') { pIfIdEnd = pNow - 1; pFrom = pNow; pTo = pNow; continue; } else { pIfIdEnd = pNow; pFrom = NULL; pTo = NULL; pszSourceAddress++; continue; } } if (!pNowChar) { returnValue = 254; if (followRfc) { pMisc = (char *)memchr(&szIpV6AddressChars[0], *pNow, strlen(&szIpV6AddressChars[0])); if (pMisc) returnValue = 253; } } if (strlen(pszResultAddressStart) > 32 && !pszResultAddress4Start) returnValue = 255; if (pNowDigit && *pNext != '\0' && colons == 0) { pTo = pNow; pszSourceAddress++; continue; } if (*pNow == ':' && *pNext != '\0') { colonsOverAll++; colons++; pszSourceAddress++; continue; } if (*pNow == ':' ) { colons++; colonsOverAll++; } if (*pNow == '.') { pMisc = pNow; while (*pMisc != '\0' && *pMisc != ']') { if (*pMisc == '.') dots++; pMisc++; } } if (*pNow == ']') { if (pBracketClose) returnValue = 77; if (!pBracketOpen) returnValue = 22; if (*pNext == ':' || *pNext == '.') { pszResultPort = pszSourceAddressStart; pLast = pNext + 1; } if (pFrom == pNow) pFrom = NULL; pBracketClose = pNow; } if (*pNow == '[') { if (pBracketOpen) returnValue = 23; if (pStart != pNow) returnValue = 24; pBracketOpen = pNow; pStart++; pFrom++; pszSourceAddress++; continue; } if (*pNow == '%') { if (pIfId) returnValue = 441; pLast = pNext; pIfId = pNext; } if (colons > 0) { if (colons == 1) { if (pStart + 1 == pNow ) returnValue = 31; if (*pNext == '\0' && !pNowDigit) returnValue = 32; pLast = pNow; } if (colons == 2) { if (pGap) returnValue = 33; pGap = pszResultAddress + 4; if (pStart + 1 == pNow || pStart + 2 == pNow) { pGap = pszResultAddressStart; pFrom = pNow; } if (*pNext == '\0' && !pNowDigit) pszSourceAddress++; if (*pNext != ':' && *pNext != '.') pLast = pNow; } if (colons == 3) { pFrom = pLast; pLast = pNow; if (*pNext == '\0' && !pNowDigit) returnValue = 34; if (pBracketOpen) returnValue = 35; if (pGap && followRfc) returnValue = 36; if (!pGap) pGap = pszResultAddress + 4; if (pStart + 3 == pNow) { pszResultPort = pszSourceAddressStart; pGap = pszResultAddress; pFrom = NULL; } if (pNowDigit) { pszResultPort = pszSourceAddressStart; } } } if (*pNext == '\0' && colons == 0 && !pIfIdEnd) { pFrom = pLast; if (pNowDigit) pTo = pNow; pLast = NULL; } if (dots > 0) { if (dots == 1) { pszResultPort = pszSourceAddressStart; pLast = pNext; } if (dots == 4 && pBracketOpen) returnValue = 601; if (dots == 3 || dots == 4) { pszResultAddress4 = pszSourceAddressStart; pLast = pFrom; pFrom = NULL; } if (dots > 4) returnValue = 603; dots = 0; } if (pFrom && pTo) { if (pTo - pFrom > 3) { returnValue = 51; break; } if (followRfc) { if ((pTo - pFrom > 0) && *pFrom == '0') returnValue = 101; if ((pTo - pFrom) == 0 && *pFrom == '0' && colons == 2) returnValue = 102; if ((pTo - pFrom) == 0 && *pFrom == '0' && pszResultAddress == pGap) returnValue = 103; if ((pTo - pFrom) == 0 && *pFrom == '0') { if (!pFieldStart) { pFieldStart = pszResultAddress; pFieldEnd = pszResultAddress + 4; } else { pFieldEnd = pFieldEnd + 4; } } else { if ((size_t)(pFieldEnd - pFieldStart) > fieldLength) { fieldLength = pFieldEnd - pFieldStart; pFieldStartLongest = pFieldStart; } pFieldStart = NULL; pFieldEnd = NULL; } } if (!(pGap == pszResultAddressStart && (size_t)(pNow - pStart) == colons)) { memset(pszResultAddress, '0', 4); pMisc = pszResultAddress + 3; pszResultAddress = pszResultAddress + 4; if (pFrom == pStart && (pTo - pFrom) == 3) { isLinkLocal = true; while (pTo >= pFrom) { *pMisc = *pTo; if (*pTo != *pszLinkLocalPrefix && *pTo != *(pszLinkLocalPrefix + 1)) isLinkLocal = false; pTo--; pMisc--; pszLinkLocalPrefix = pszLinkLocalPrefix - 2; } } else { while (pTo >= pFrom) { *pMisc = *pTo; pMisc--; pTo--; } } } pFrom = pNow; pTo = pNow; } if (*pNext == '\0' && colons == 0) pszSourceAddress++; if (*pNext == '\0' && !pBracketClose && !pszResultPort) pTo = pNext; colons = 0; } // end of loop if (!returnValue && colonsOverAll < 2) returnValue = 252; if (!returnValue && (pBracketOpen && !pBracketClose)) returnValue = 25; if (!returnValue && pGap) { gapSize = 32 - strlen(pszResultAddressStart); if (followRfc) { if (gapSize < 5) returnValue = 104; if (fieldLength > gapSize) returnValue = 105; if (fieldLength == gapSize && pFieldStartLongest < pGap) returnValue = 106; } pszResultAddress = pszResultAddressStart; pszInternalAddress = pszInternalAddressStart; if (!returnValue && pszResultAddress4Start) { if (strlen(pszResultAddressStart) > 4) returnValue = 405; pszResultAddress = pszResultAddressStart; if (pGap != pszResultAddressStart) returnValue = 407; memset(pszInternalAddressStart, '0', 20); pszInternalAddress = pszInternalAddressStart + 20; for (int i = 0; i < 4; i++) { if (*pszResultAddress != 'f' && *pszResultAddress != 'F') { returnValue = 406; break; } *pszInternalAddress = *pszResultAddress; pszResultAddress++; pszInternalAddress++; } pszResultAddress4 = pszResultAddress4Start; for (int i = 0; i<4; i++) { memcpy(szDummy, pszResultAddress4, 3); int rc = RTStrToUInt32Ex((const char *)&szDummy[0], NULL, 16, &byteOut); if (rc == 0 && byteOut < 256) { RTStrPrintf(szDummy, 3, "%02x", byteOut); memcpy(pszInternalAddress, szDummy, 2); pszInternalAddress = pszInternalAddress + 2; pszResultAddress4 = pszResultAddress4 + 3; memset(szDummy, '\0', 4); } else { returnValue = 499; } } } else { while (!returnValue && pszResultAddress != pGap) { *pszInternalAddress = *pszResultAddress; pszResultAddress++; pszInternalAddress++; } memset(pszInternalAddress, '0', gapSize); pszInternalAddress = pszInternalAddress + gapSize; while (!returnValue && *pszResultAddress != '\0') { *pszInternalAddress = *pszResultAddress; pszResultAddress++; pszInternalAddress++; } } } else { if (!returnValue) { if (strlen(pszResultAddressStart) != 32) returnValue = 111; if (followRfc) { if (fieldLength > 4) returnValue = 112; } memcpy(pszInternalAddressStart, pszResultAddressStart, strlen(pszResultAddressStart)); } } if (pszResultPortStart) { if (strlen(pszResultPortStart) > 0 && strlen(pszResultPortStart) < 6) { memcpy(pszInternalPortStart, pszResultPortStart, strlen(pszResultPortStart)); intPortOut = 0; int rc = RTStrToUInt32Ex(pszInternalPortStart, NULL, 10, &intPortOut); if (rc == 0) { if (!(intPortOut > 0 && intPortOut < 65536)) intPortOut = 0; } else { returnValue = 888; } } else { returnValue = 889; } } /* full blown address 32 bytes, no colons -> pszInternalAddressStart port as string -> pszResultPortStart port as binary integer -> intPortOut interface id in pIfId and pIfIdEnd Now fill the out parameters. */ if (!returnValue && pszAddressOut) { if (strlen(pszInternalAddressStart) < addressOutSize) { pszRc = NULL; pszRc = (char *)memset(pszAddressOut, '\0', addressOutSize); if (!pszRc) returnValue = 910; pszRc = NULL; pszRc = (char *)memcpy(pszAddressOut, pszInternalAddressStart, strlen(pszInternalAddressStart)); if (!pszRc) returnValue = 911; } else { returnValue = 912; } } if (!returnValue && pPortOut) { *pPortOut = intPortOut; } if (!returnValue && pszIfIdOut) { if (pIfIdEnd && pIfId) { if ((size_t)(pIfIdEnd - pIfId) + 1 < ifIdOutSize) { pszRc = NULL; pszRc = (char *)memset(pszIfIdOut, '\0', ifIdOutSize); if (!pszRc) returnValue = 913; pszRc = NULL; pszRc = (char *)memcpy(pszIfIdOut, pIfId, (pIfIdEnd - pIfId) + 1); if (!pszRc) returnValue = 914; } else { returnValue = 915; } } else { pszRc = NULL; pszRc = (char *)memset(pszIfIdOut, '\0', ifIdOutSize); if (!pszRc) returnValue = 916; } // temporary hack if (isLinkLocal && (strlen(pszIfIdOut) < 1)) { memset(pszIfIdOut, '\0', ifIdOutSize); *pszIfIdOut = '%'; pszIfIdOut++; *pszIfIdOut = '0'; pszIfIdOut++; } } if (pBracketOpen && pBracketClose && pBrackets) *pBrackets = true; if (pEmbeddedV4 && pszResultAddress4Start) *pEmbeddedV4 = true; if (pszResultAddressStart) RTMemTmpFree(pszResultAddressStart); if (pszResultPortStart) RTMemTmpFree(pszResultPortStart); if (pszResultAddress4Start) RTMemTmpFree(pszResultAddress4Start); if (pszInternalAddressStart) RTMemTmpFree(pszInternalAddressStart); if (pszInternalPortStart) RTMemTmpFree(pszInternalPortStart); return (uint32_t)(returnValue - (returnValue * 2)); // make it negative... } /** * Takes a string and returns a RFC compliant string of the address * This function SHOULD NOT be used directly. It expects a 33 byte * char array with a full blown IPv6 address without separators. * * @returns iprt status code. * @param psz The string to convert * @param pszAddrOut The char[] that will hold the result * @param addOutSize The size of the char[] from above. * @param pszPortOut char[] for the text representation of the port * @param portOutSize sizeof(pszPortOut); */ DECLHIDDEN(int) rtStrToIpAddr6Str(const char *psz, char *pszAddrOut, size_t addrOutSize, char *pszPortOut, size_t portOutSize, bool followRfc) { char *pStart = NULL; char *pGapStart = NULL; char *pGapEnd = NULL; char *pGapTStart = NULL; char *pGapTEnd = NULL; char *pCurrent = NULL; char *pOut = NULL; if (!psz || !pszAddrOut) return VERR_NOT_SUPPORTED; if (addrOutSize < 40) return VERR_NOT_SUPPORTED; pStart = (char *)psz; pCurrent = (char *)psz; pGapStart = (char *)psz; pGapEnd = (char *)psz; while (*pCurrent != '\0') { if (*pCurrent != '0') pGapTStart = NULL; if ((pCurrent - pStart) % 4 == 0) // ok, start of a hextet { if (*pCurrent == '0' && !pGapTStart) pGapTStart = pCurrent; } if ((pCurrent - pStart) % 4 == 3) { if (*pCurrent == '0' && pGapTStart) pGapTEnd = pCurrent; if (pGapTStart && pGapTEnd) { pGapTEnd = pCurrent; if ((pGapTEnd - pGapTStart) > (pGapEnd - pGapStart)) { pGapEnd = pGapTEnd; pGapStart = pGapTStart; } } } pCurrent++; } pCurrent = (char *)psz; pStart = (char *)psz; pOut = (char *)pszAddrOut; while (*pCurrent != '\0') { if (*pCurrent != '0') pGapTStart = NULL; if (!pGapTStart) { *pOut = *pCurrent; pOut++; } if ((pCurrent - pStart) % 4 == 3) { if (pGapTStart && *pCurrent == '0') { *pOut = *pCurrent; pOut++; } if (*(pCurrent + 1) != '\0') { *pOut = ':'; pOut++; } pGapTStart = pCurrent + 1; } if ((pCurrent + 1) == pGapStart && (pGapEnd - pGapStart) > 3) { *pOut = ':'; pOut++; pCurrent = pGapEnd; } pCurrent++; } return VINF_SUCCESS; } /** * Tests if the given string is a valid IPv6 address. * * @returns 0 if valid, some random number if not. THIS IS NOT AN IPRT STATUS! * @param psz The string to test * @param pszResultAddress plain address, optional read "valid addresses * and strings" above. * @param resultAddressSize size of pszResultAddress * @param addressOnly return only the plain address (no scope) * Ignored, and will always return the if id */ static int rtNetIpv6CheckAddrStr(const char *psz, char *pszResultAddress, size_t resultAddressSize, bool addressOnly, bool followRfc) { int rc; int rc2; int returnValue = VERR_NOT_SUPPORTED; /* gcc want's this initialized, I understand its confusion. */ char *p = NULL, *pl = NULL; size_t memAllocMaxSize = RT_MAX(strlen(psz), resultAddressSize) + 40; char *pszAddressOutLocal = (char *)RTMemTmpAlloc(memAllocMaxSize); char *pszIfIdOutLocal = (char *)RTMemTmpAlloc(memAllocMaxSize); char *pszAddressRfcOutLocal = (char *)RTMemTmpAlloc(memAllocMaxSize); if (!pszAddressOutLocal || !pszIfIdOutLocal || !pszAddressRfcOutLocal) return VERR_NO_TMP_MEMORY; memset(pszAddressOutLocal, '\0', memAllocMaxSize); memset(pszIfIdOutLocal, '\0', memAllocMaxSize); memset(pszAddressRfcOutLocal, '\0', memAllocMaxSize); rc = rtStrParseAddrStr6(psz, strlen(psz), pszAddressOutLocal, memAllocMaxSize, NULL, pszIfIdOutLocal, memAllocMaxSize, NULL, NULL, followRfc); if (rc == 0) returnValue = VINF_SUCCESS; if (rc == 0 && pszResultAddress) { // convert the 32 characters to a valid, shortened ipv6 address rc2 = rtStrToIpAddr6Str((const char *)pszAddressOutLocal, pszAddressRfcOutLocal, memAllocMaxSize, NULL, 0, followRfc); if (rc2 != 0) returnValue = 951; // this is a temporary solution if (!returnValue && strlen(pszIfIdOutLocal) > 0) // the if identifier is copied over _ALWAYS_ && !addressOnly) { p = pszAddressRfcOutLocal + strlen(pszAddressRfcOutLocal); *p = '%'; p++; pl = (char *)memcpy(p, pszIfIdOutLocal, strlen(pszIfIdOutLocal)); if (!pl) returnValue = VERR_NOT_SUPPORTED; } pl = NULL; pl = (char *)memcpy(pszResultAddress, pszAddressRfcOutLocal, strlen(pszAddressRfcOutLocal)); if (!pl) returnValue = VERR_NOT_SUPPORTED; } if (rc != 0) returnValue = VERR_NOT_SUPPORTED; if (pszAddressOutLocal) RTMemTmpFree(pszAddressOutLocal); if (pszAddressRfcOutLocal) RTMemTmpFree(pszAddressRfcOutLocal); if (pszIfIdOutLocal) RTMemTmpFree(pszIfIdOutLocal); return returnValue; }