/* $Id: getopt.cpp 83982 2020-04-26 23:36:21Z vboxsync $ */ /** @file * IPRT - Command Line Parsing */ /* * Copyright (C) 2007-2020 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 #include /* must come before getopt.h */ #include #include "internal/iprt.h" #include #include #include #include #include #include /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ #ifdef IN_RT_STATIC /* We don't need full unicode case insensitive if we ASSUME basic latin only. */ # define RTStrICmp RTStrICmpAscii # define RTStrNICmp RTStrNICmpAscii #endif /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** * Standard options that gets included unless RTGETOPTINIT_FLAGS_NO_STD_OPTS is * set. */ static RTGETOPTDEF const g_aStdOptions[] = { { "--help", 'h', RTGETOPT_REQ_NOTHING }, { "-help", 'h', RTGETOPT_REQ_NOTHING }, { "--version", 'V', RTGETOPT_REQ_NOTHING }, { "-version", 'V', RTGETOPT_REQ_NOTHING }, }; /** The index of --help in g_aStdOptions. Used for some trickery. */ #define RTGETOPT_STD_OPTIONS_HELP_IDX 0 RTDECL(int) RTGetOptInit(PRTGETOPTSTATE pState, int argc, char **argv, PCRTGETOPTDEF paOptions, size_t cOptions, int iFirst, uint32_t fFlags) { AssertReturn(!(fFlags & ~(RTGETOPTINIT_FLAGS_OPTS_FIRST | RTGETOPTINIT_FLAGS_NO_STD_OPTS)), VERR_INVALID_PARAMETER); pState->argv = argv; pState->argc = argc; pState->paOptions = paOptions; pState->cOptions = cOptions; pState->iNext = iFirst; pState->pszNextShort = NULL; pState->pDef = NULL; pState->uIndex = UINT32_MAX; pState->fFlags = fFlags; pState->cNonOptions = 0; #ifdef RT_STRICT /* validate the options. */ for (size_t i = 0; i < cOptions; i++) { Assert(!(paOptions[i].fFlags & ~RTGETOPT_VALID_MASK)); Assert(paOptions[i].iShort > 0); Assert(paOptions[i].iShort != VINF_GETOPT_NOT_OPTION); Assert(paOptions[i].iShort != '-'); if (paOptions[i].fFlags & RTGETOPT_FLAG_ICASE) { const char *psz = paOptions[i].pszLong; unsigned char ch; while ((ch = *psz++) != '\0') Assert(ch <= 0x7f); /* ASSUMPTION that we can use RTStrICmpAscii and RTStrNICmpAscii. */ } } #endif return VINF_SUCCESS; } RT_EXPORT_SYMBOL(RTGetOptInit); #ifndef IPRT_GETOPT_WITHOUT_NETWORK_ADDRESSES /** * Converts an stringified IPv4 address into the RTNETADDRIPV4 representation. * * @returns VINF_SUCCESS on success, VERR_GETOPT_INVALID_ARGUMENT_FORMAT on * failure. * * @param pszValue The value to convert. * @param pAddr Where to store the result. */ static int rtgetoptConvertIPv4Addr(const char *pszValue, PRTNETADDRIPV4 pAddr) { if (RT_FAILURE(RTNetStrToIPv4Addr(pszValue, pAddr))) return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; return VINF_SUCCESS; } /** * Converts an stringified Ethernet MAC address into the RTMAC representation. * * @returns VINF_SUCCESS on success, VERR_GETOPT_INVALID_ARGUMENT_FORMAT on * failure. * * @param pszValue The value to convert. * @param pAddr Where to store the result. */ static int rtgetoptConvertMacAddr(const char *pszValue, PRTMAC pAddr) { int rc = RTNetStrToMacAddr(pszValue, pAddr); if (RT_FAILURE(rc)) return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; return VINF_SUCCESS; } #endif /* IPRT_GETOPT_WITHOUT_NETWORK_ADDRESSES */ /** * Searches for a long option. * * @returns Pointer to a matching option. * @param pszOption The alleged long option. * @param paOptions Option array. * @param cOptions Number of items in the array. * @param fFlags Init flags. */ static PCRTGETOPTDEF rtGetOptSearchLong(const char *pszOption, PCRTGETOPTDEF paOptions, size_t cOptions, uint32_t fFlags) { PCRTGETOPTDEF pOpt = paOptions; while (cOptions-- > 0) { if (pOpt->pszLong) { if ((pOpt->fFlags & RTGETOPT_REQ_MASK) != RTGETOPT_REQ_NOTHING) { /* * A value is required with the argument. We're trying to be * understanding here and will permit any of the following: * --long12:value, --long12=value, --long12 value, * --long:value, --long=value, --long value, * * If the option is index, then all trailing chars must be * digits. For error reporting reasons we also match where * there is no index. */ size_t cchLong = strlen(pOpt->pszLong); if ( !strncmp(pszOption, pOpt->pszLong, cchLong) || ( pOpt->fFlags & RTGETOPT_FLAG_ICASE && !RTStrNICmp(pszOption, pOpt->pszLong, cchLong))) { if (pOpt->fFlags & RTGETOPT_FLAG_INDEX) while (RT_C_IS_DIGIT(pszOption[cchLong])) cchLong++; if ( pszOption[cchLong] == '\0' || pszOption[cchLong] == ':' || pszOption[cchLong] == '=') return pOpt; } } else if (pOpt->fFlags & RTGETOPT_FLAG_INDEX) { /* * The option takes an index but no value. * As above, we also match where there is no index. */ size_t cchLong = strlen(pOpt->pszLong); if ( !strncmp(pszOption, pOpt->pszLong, cchLong) || ( pOpt->fFlags & RTGETOPT_FLAG_ICASE && !RTStrNICmp(pszOption, pOpt->pszLong, cchLong))) { while (RT_C_IS_DIGIT(pszOption[cchLong])) cchLong++; if (pszOption[cchLong] == '\0') return pOpt; } } else if ( !strcmp(pszOption, pOpt->pszLong) || ( pOpt->fFlags & RTGETOPT_FLAG_ICASE && !RTStrICmp(pszOption, pOpt->pszLong))) return pOpt; } pOpt++; } if (!(fFlags & RTGETOPTINIT_FLAGS_NO_STD_OPTS)) for (uint32_t i = 0; i < RT_ELEMENTS(g_aStdOptions); i++) if ( !strcmp(pszOption, g_aStdOptions[i].pszLong) || ( g_aStdOptions[i].fFlags & RTGETOPT_FLAG_ICASE && !RTStrICmp(pszOption, g_aStdOptions[i].pszLong))) return &g_aStdOptions[i]; return NULL; } /** * Searches for a matching short option. * * @returns Pointer to a matching option. * @param chOption The option char. * @param paOptions Option array. * @param cOptions Number of items in the array. * @param fFlags Init flags. */ static PCRTGETOPTDEF rtGetOptSearchShort(int chOption, PCRTGETOPTDEF paOptions, size_t cOptions, uint32_t fFlags) { PCRTGETOPTDEF pOpt = paOptions; while (cOptions-- > 0) { if (pOpt->iShort == chOption) return pOpt; pOpt++; } if (!(fFlags & RTGETOPTINIT_FLAGS_NO_STD_OPTS)) { for (uint32_t i = 0; i < RT_ELEMENTS(g_aStdOptions); i++) if (g_aStdOptions[i].iShort == chOption) return &g_aStdOptions[i]; if (chOption == '?') return &g_aStdOptions[RTGETOPT_STD_OPTIONS_HELP_IDX]; } return NULL; } /** * Value string -> Value union. * * @returns IPRT status code. * @param fFlags The value flags. * @param pszValue The value string. * @param pValueUnion Where to return the processed value. */ static int rtGetOptProcessValue(uint32_t fFlags, const char *pszValue, PRTGETOPTUNION pValueUnion) { /* * Transform into a option value as requested. * If decimal conversion fails, we'll check for "0x" and * try a 16 based conversion. We will not interpret any of the * generic ints as octals. */ uint32_t const fSwitchValue = fFlags & ( RTGETOPT_REQ_MASK | RTGETOPT_FLAG_HEX | RTGETOPT_FLAG_DEC | RTGETOPT_FLAG_OCT); switch (fSwitchValue) { case RTGETOPT_REQ_STRING: pValueUnion->psz = pszValue; break; case RTGETOPT_REQ_BOOL: if ( !RTStrICmp(pszValue, "true") || !RTStrICmp(pszValue, "t") || !RTStrICmp(pszValue, "yes") || !RTStrICmp(pszValue, "y") || !RTStrICmp(pszValue, "enabled") || !RTStrICmp(pszValue, "enable") || !RTStrICmp(pszValue, "en") || !RTStrICmp(pszValue, "e") || !RTStrICmp(pszValue, "on") || !RTStrCmp(pszValue, "1") ) pValueUnion->f = true; else if ( !RTStrICmp(pszValue, "false") || !RTStrICmp(pszValue, "f") || !RTStrICmp(pszValue, "no") || !RTStrICmp(pszValue, "n") || !RTStrICmp(pszValue, "disabled") || !RTStrICmp(pszValue, "disable") || !RTStrICmp(pszValue, "dis") || !RTStrICmp(pszValue, "d") || !RTStrICmp(pszValue, "off") || !RTStrCmp(pszValue, "0") ) pValueUnion->f = false; else { pValueUnion->psz = pszValue; return VERR_GETOPT_UNKNOWN_OPTION; } break; case RTGETOPT_REQ_BOOL_ONOFF: if (!RTStrICmp(pszValue, "on")) pValueUnion->f = true; else if (!RTStrICmp(pszValue, "off")) pValueUnion->f = false; else { pValueUnion->psz = pszValue; return VERR_GETOPT_UNKNOWN_OPTION; } break; #define MY_INT_CASE(req, type, memb, convfn) \ case req: \ { \ type Value; \ if ( convfn(pszValue, 10, &Value) != VINF_SUCCESS \ && ( pszValue[0] != '0' \ || (pszValue[1] != 'x' && pszValue[1] != 'X') \ || !RT_C_IS_XDIGIT(pszValue[2]) \ || convfn(pszValue, 16, &Value) != VINF_SUCCESS ) ) \ return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; \ pValueUnion->memb = Value; \ break; \ } #define MY_BASE_INT_CASE(req, type, memb, convfn, base) \ case req: \ { \ type Value; \ if (convfn(pszValue, base, &Value) != VINF_SUCCESS) \ return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; \ pValueUnion->memb = Value; \ break; \ } MY_INT_CASE(RTGETOPT_REQ_INT8, int8_t, i8, RTStrToInt8Full) MY_INT_CASE(RTGETOPT_REQ_INT16, int16_t, i16, RTStrToInt16Full) MY_INT_CASE(RTGETOPT_REQ_INT32, int32_t, i32, RTStrToInt32Full) MY_INT_CASE(RTGETOPT_REQ_INT64, int64_t, i64, RTStrToInt64Full) MY_INT_CASE(RTGETOPT_REQ_UINT8, uint8_t, u8, RTStrToUInt8Full) MY_INT_CASE(RTGETOPT_REQ_UINT16, uint16_t, u16, RTStrToUInt16Full) MY_INT_CASE(RTGETOPT_REQ_UINT32, uint32_t, u32, RTStrToUInt32Full) MY_INT_CASE(RTGETOPT_REQ_UINT64, uint64_t, u64, RTStrToUInt64Full) MY_BASE_INT_CASE(RTGETOPT_REQ_INT8 | RTGETOPT_FLAG_HEX, int8_t, i8, RTStrToInt8Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_INT16 | RTGETOPT_FLAG_HEX, int16_t, i16, RTStrToInt16Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_INT32 | RTGETOPT_FLAG_HEX, int32_t, i32, RTStrToInt32Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_INT64 | RTGETOPT_FLAG_HEX, int64_t, i64, RTStrToInt64Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT8 | RTGETOPT_FLAG_HEX, uint8_t, u8, RTStrToUInt8Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT16 | RTGETOPT_FLAG_HEX, uint16_t, u16, RTStrToUInt16Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT32 | RTGETOPT_FLAG_HEX, uint32_t, u32, RTStrToUInt32Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT64 | RTGETOPT_FLAG_HEX, uint64_t, u64, RTStrToUInt64Full, 16) MY_BASE_INT_CASE(RTGETOPT_REQ_INT8 | RTGETOPT_FLAG_DEC, int8_t, i8, RTStrToInt8Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_INT16 | RTGETOPT_FLAG_DEC, int16_t, i16, RTStrToInt16Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_INT32 | RTGETOPT_FLAG_DEC, int32_t, i32, RTStrToInt32Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_INT64 | RTGETOPT_FLAG_DEC, int64_t, i64, RTStrToInt64Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT8 | RTGETOPT_FLAG_DEC, uint8_t, u8, RTStrToUInt8Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT16 | RTGETOPT_FLAG_DEC, uint16_t, u16, RTStrToUInt16Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT32 | RTGETOPT_FLAG_DEC, uint32_t, u32, RTStrToUInt32Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT64 | RTGETOPT_FLAG_DEC, uint64_t, u64, RTStrToUInt64Full, 10) MY_BASE_INT_CASE(RTGETOPT_REQ_INT8 | RTGETOPT_FLAG_OCT, int8_t, i8, RTStrToInt8Full, 8) MY_BASE_INT_CASE(RTGETOPT_REQ_INT16 | RTGETOPT_FLAG_OCT, int16_t, i16, RTStrToInt16Full, 8) MY_BASE_INT_CASE(RTGETOPT_REQ_INT32 | RTGETOPT_FLAG_OCT, int32_t, i32, RTStrToInt32Full, 8) MY_BASE_INT_CASE(RTGETOPT_REQ_INT64 | RTGETOPT_FLAG_OCT, int64_t, i64, RTStrToInt64Full, 8) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT8 | RTGETOPT_FLAG_OCT, uint8_t, u8, RTStrToUInt8Full, 8) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT16 | RTGETOPT_FLAG_OCT, uint16_t, u16, RTStrToUInt16Full, 8) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT32 | RTGETOPT_FLAG_OCT, uint32_t, u32, RTStrToUInt32Full, 8) MY_BASE_INT_CASE(RTGETOPT_REQ_UINT64 | RTGETOPT_FLAG_OCT, uint64_t, u64, RTStrToUInt64Full, 8) #undef MY_INT_CASE #undef MY_BASE_INT_CASE #ifndef IPRT_GETOPT_WITHOUT_NETWORK_ADDRESSES case RTGETOPT_REQ_IPV4ADDR: { RTNETADDRIPV4 Addr; if (rtgetoptConvertIPv4Addr(pszValue, &Addr) != VINF_SUCCESS) return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; pValueUnion->IPv4Addr = Addr; break; } case RTGETOPT_REQ_IPV4CIDR: { RTNETADDRIPV4 network; RTNETADDRIPV4 netmask; if (RT_FAILURE(RTCidrStrToIPv4(pszValue, &network, &netmask))) return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; pValueUnion->CidrIPv4.IPv4Network.u = network.u; pValueUnion->CidrIPv4.IPv4Netmask.u = netmask.u; break; } case RTGETOPT_REQ_MACADDR: { RTMAC Addr; if (rtgetoptConvertMacAddr(pszValue, &Addr) != VINF_SUCCESS) return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; pValueUnion->MacAddr = Addr; break; } #endif /* IPRT_GETOPT_WITHOUT_NETWORK_ADDRESSES */ case RTGETOPT_REQ_UUID: { RTUUID Uuid; if (RTUuidFromStr(&Uuid, pszValue) != VINF_SUCCESS) return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; pValueUnion->Uuid = Uuid; break; } #define MY_INT_PAIR_CASE(a_fReqValue, a_fReqValueOptional, a_Type, a_MemberPrefix, a_fnConv, a_ConvBase, a_DefaultValue) \ case a_fReqValue: \ case a_fReqValueOptional: \ { \ /* First value: */ \ a_Type Value1; \ char *pszNext = NULL; \ unsigned uBase = pszValue[0] == '0' \ && (pszValue[1] == 'x' || pszValue[1] == 'X') \ && RT_C_IS_XDIGIT(pszValue[2]) \ ? 16 : a_ConvBase; \ int rc = a_fnConv(pszValue, &pszNext, uBase, &Value1); \ if (rc == VINF_SUCCESS || rc == VWRN_TRAILING_CHARS || rc == VWRN_TRAILING_SPACES) \ { \ /* The second value, could be optional: */ \ a_Type Value2 = a_DefaultValue; \ pszValue = pszNext;\ if (pszValue) \ { \ while (RT_C_IS_BLANK(*pszValue)) \ pszValue++; \ if (*pszValue == ':' || *pszValue == '/' || *pszValue == '|') \ do pszValue++; \ while (RT_C_IS_BLANK(*pszValue)); \ if (pszValue != pszNext) \ { \ uBase = pszValue[0] == '0' \ && (pszValue[1] == 'x' || pszValue[1] == 'X') \ && RT_C_IS_XDIGIT(pszValue[2]) \ ? 16 : a_ConvBase; \ rc = a_fnConv(pszValue, &pszNext, uBase, &Value2); \ if (rc == VINF_SUCCESS) \ { /* likely */ } \ else \ AssertMsgFailedReturn(("z rc=%Rrc: '%s' '%s' uBase=%d\n", rc, pszValue, pszNext, uBase), \ VERR_GETOPT_INVALID_ARGUMENT_FORMAT); \ } \ else if (fSwitchValue != (a_fReqValueOptional)) \ AssertMsgFailedReturn(("x\n"), VERR_GETOPT_INVALID_ARGUMENT_FORMAT); \ } \ else if (fSwitchValue != (a_fReqValueOptional)) \ AssertMsgFailedReturn(("y\n"), VERR_GETOPT_INVALID_ARGUMENT_FORMAT); \ pValueUnion->a_MemberPrefix##Second = Value2; \ pValueUnion->a_MemberPrefix##First = Value1; \ break; \ } \ return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; \ } MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT32_PAIR, RTGETOPT_REQ_UINT32_OPTIONAL_PAIR, uint32_t, PairU32.u, RTStrToUInt32Ex, 10, UINT32_MAX) MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT32_PAIR | RTGETOPT_FLAG_DEC, RTGETOPT_REQ_UINT32_OPTIONAL_PAIR | RTGETOPT_FLAG_DEC, uint32_t, PairU32.u, RTStrToUInt32Ex, 10, UINT32_MAX) MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT32_PAIR | RTGETOPT_FLAG_HEX, RTGETOPT_REQ_UINT32_OPTIONAL_PAIR | RTGETOPT_FLAG_HEX, uint32_t, PairU32.u, RTStrToUInt32Ex, 16, UINT32_MAX) MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT32_PAIR | RTGETOPT_FLAG_OCT, RTGETOPT_REQ_UINT32_OPTIONAL_PAIR | RTGETOPT_FLAG_OCT, uint32_t, PairU32.u, RTStrToUInt32Ex, 8, UINT32_MAX) MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT64_PAIR, RTGETOPT_REQ_UINT64_OPTIONAL_PAIR, uint64_t, PairU64.u, RTStrToUInt64Ex, 10, UINT64_MAX) MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT64_PAIR | RTGETOPT_FLAG_DEC, RTGETOPT_REQ_UINT64_OPTIONAL_PAIR | RTGETOPT_FLAG_DEC, uint64_t, PairU64.u, RTStrToUInt64Ex, 10, UINT64_MAX) MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT64_PAIR | RTGETOPT_FLAG_HEX, RTGETOPT_REQ_UINT64_OPTIONAL_PAIR | RTGETOPT_FLAG_HEX, uint64_t, PairU64.u, RTStrToUInt64Ex, 16, UINT64_MAX) MY_INT_PAIR_CASE(RTGETOPT_REQ_UINT64_PAIR | RTGETOPT_FLAG_OCT, RTGETOPT_REQ_UINT64_OPTIONAL_PAIR | RTGETOPT_FLAG_OCT, uint64_t, PairU64.u, RTStrToUInt64Ex, 8, UINT64_MAX) default: AssertMsgFailed(("f=%#x\n", fFlags)); return VERR_INTERNAL_ERROR; } return VINF_SUCCESS; } /** * Moves one argv option entries. * * @param papszTo Destination. * @param papszFrom Source. */ static void rtGetOptMoveArgvEntries(char **papszTo, char **papszFrom) { if (papszTo != papszFrom) { Assert((uintptr_t)papszTo < (uintptr_t)papszFrom); char * const pszMoved = papszFrom[0]; memmove(&papszTo[1], &papszTo[0], (uintptr_t)papszFrom - (uintptr_t)papszTo); papszTo[0] = pszMoved; } } RTDECL(int) RTGetOpt(PRTGETOPTSTATE pState, PRTGETOPTUNION pValueUnion) { /* * Reset the variables kept in state. */ pState->pDef = NULL; pState->uIndex = UINT32_MAX; /* * Make sure the union is completely cleared out, whatever happens below. */ pValueUnion->u64 = 0; pValueUnion->pDef = NULL; /* * The next option. */ bool fShort; int iThis; const char *pszArgThis; PCRTGETOPTDEF pOpt; if (pState->pszNextShort) { /* * We've got short options left over from the previous call. */ pOpt = rtGetOptSearchShort(*pState->pszNextShort, pState->paOptions, pState->cOptions, pState->fFlags); if (!pOpt) { pValueUnion->psz = pState->pszNextShort; return VERR_GETOPT_UNKNOWN_OPTION; } pState->pszNextShort++; pszArgThis = pState->pszNextShort - 2; iThis = pState->iNext; fShort = true; } else { /* * Pop off the next argument. Sorting options and dealing with the * dash-dash makes this a little extra complicated. */ for (;;) { if (pState->iNext >= pState->argc) return 0; if (pState->cNonOptions) { if (pState->cNonOptions == INT32_MAX) { pValueUnion->psz = pState->argv[pState->iNext++]; return VINF_GETOPT_NOT_OPTION; } if (pState->iNext + pState->cNonOptions >= pState->argc) { pState->cNonOptions = INT32_MAX; continue; } } iThis = pState->iNext++; pszArgThis = pState->argv[iThis + pState->cNonOptions]; /* * Do a long option search first and then a short option one. * This way we can make sure single dash long options doesn't * get mixed up with short ones. */ pOpt = rtGetOptSearchLong(pszArgThis, pState->paOptions, pState->cOptions, pState->fFlags); if ( !pOpt && pszArgThis[0] == '-' && pszArgThis[1] != '-' && pszArgThis[1] != '\0') { pOpt = rtGetOptSearchShort(pszArgThis[1], pState->paOptions, pState->cOptions, pState->fFlags); fShort = pOpt != NULL; } else fShort = false; /* Look for dash-dash. */ if (!pOpt && !strcmp(pszArgThis, "--")) { rtGetOptMoveArgvEntries(&pState->argv[iThis], &pState->argv[iThis + pState->cNonOptions]); pState->cNonOptions = INT32_MAX; continue; } /* Options first hacks. */ if (pState->fFlags & RTGETOPTINIT_FLAGS_OPTS_FIRST) { if (pOpt) rtGetOptMoveArgvEntries(&pState->argv[iThis], &pState->argv[iThis + pState->cNonOptions]); else if (*pszArgThis == '-') { pValueUnion->psz = pszArgThis; return VERR_GETOPT_UNKNOWN_OPTION; } else { /* not an option, add it to the non-options and try again. */ pState->iNext--; pState->cNonOptions++; /* Switch to returning non-options if we've reached the end. */ if (pState->iNext + pState->cNonOptions >= pState->argc) pState->cNonOptions = INT32_MAX; continue; } } /* done */ break; } } if (pOpt) { pValueUnion->pDef = pOpt; /* in case of no value or error. */ if ((pOpt->fFlags & RTGETOPT_REQ_MASK) != RTGETOPT_REQ_NOTHING) { /* * Find the argument value. * * A value is required with the argument. We're trying to be * understanding here and will permit any of the following: * -svalue, -s value, -s:value and -s=value * (Ditto for long options.) */ const char *pszValue; if (fShort) { if (pszArgThis[2] == '\0') { if (iThis + 1 >= pState->argc) return VERR_GETOPT_REQUIRED_ARGUMENT_MISSING; pszValue = pState->argv[iThis + pState->cNonOptions + 1]; rtGetOptMoveArgvEntries(&pState->argv[iThis + 1], &pState->argv[iThis + pState->cNonOptions + 1]); pState->iNext++; } else /* same argument. */ pszValue = &pszArgThis[2 + (pszArgThis[2] == ':' || pszArgThis[2] == '=')]; if (pState->pszNextShort) { pState->pszNextShort = NULL; pState->iNext++; } } else { size_t cchLong = strlen(pOpt->pszLong); if (pOpt->fFlags & RTGETOPT_FLAG_INDEX) { if (pszArgThis[cchLong] == '\0') return VERR_GETOPT_INDEX_MISSING; uint32_t uIndex; char *pszRet = NULL; int rc = RTStrToUInt32Ex(&pszArgThis[cchLong], &pszRet, 10, &uIndex); if (rc == VWRN_TRAILING_CHARS) { if ( pszRet[0] != ':' && pszRet[0] != '=') return VERR_GETOPT_INVALID_ARGUMENT_FORMAT; pState->uIndex = uIndex; pszValue = pszRet + 1; } else if (rc == VINF_SUCCESS) { if (iThis + 1 + pState->cNonOptions >= pState->argc) return VERR_GETOPT_REQUIRED_ARGUMENT_MISSING; pState->uIndex = uIndex; pszValue = pState->argv[iThis + pState->cNonOptions + 1]; rtGetOptMoveArgvEntries(&pState->argv[iThis + 1], &pState->argv[iThis + pState->cNonOptions + 1]); pState->iNext++; } else AssertMsgFailedReturn(("%s\n", pszArgThis), VERR_GETOPT_INVALID_ARGUMENT_FORMAT); /* search bug */ } else { if (pszArgThis[cchLong] == '\0') { if (iThis + 1 + pState->cNonOptions >= pState->argc) return VERR_GETOPT_REQUIRED_ARGUMENT_MISSING; pszValue = pState->argv[iThis + pState->cNonOptions + 1]; rtGetOptMoveArgvEntries(&pState->argv[iThis + 1], &pState->argv[iThis + pState->cNonOptions + 1]); pState->iNext++; } else /* same argument. */ pszValue = &pszArgThis[cchLong + 1]; } } /* * Set up the ValueUnion. */ int rc = rtGetOptProcessValue(pOpt->fFlags, pszValue, pValueUnion); if (RT_FAILURE(rc)) return rc; } else if (fShort) { /* * Deal with "compressed" short option lists, correcting the next * state variables for the start and end cases. */ if (pszArgThis[2]) { if (!pState->pszNextShort) { /* start */ pState->pszNextShort = &pszArgThis[2]; pState->iNext--; } } else if (pState->pszNextShort) { /* end */ pState->pszNextShort = NULL; pState->iNext++; } } else if (pOpt->fFlags & RTGETOPT_FLAG_INDEX) { size_t cchLong = strlen(pOpt->pszLong); if (pszArgThis[cchLong] == '\0') return VERR_GETOPT_INDEX_MISSING; uint32_t uIndex; if (RTStrToUInt32Full(&pszArgThis[cchLong], 10, &uIndex) == VINF_SUCCESS) pState->uIndex = uIndex; else AssertMsgFailedReturn(("%s\n", pszArgThis), VERR_GETOPT_INVALID_ARGUMENT_FORMAT); /* search bug */ } pState->pDef = pOpt; return pOpt->iShort; } /* * Not a known option argument. If it starts with a switch char (-) we'll * fail with unknown option, and if it doesn't we'll return it as a non-option. */ if (*pszArgThis == '-') { pValueUnion->psz = pszArgThis; return VERR_GETOPT_UNKNOWN_OPTION; } pValueUnion->psz = pszArgThis; return VINF_GETOPT_NOT_OPTION; } RT_EXPORT_SYMBOL(RTGetOpt); RTDECL(int) RTGetOptFetchValue(PRTGETOPTSTATE pState, PRTGETOPTUNION pValueUnion, uint32_t fFlags) { /* * Validate input. */ PCRTGETOPTDEF pOpt = pState->pDef; AssertReturn(!(fFlags & ~RTGETOPT_VALID_MASK), VERR_INVALID_PARAMETER); AssertReturn((fFlags & RTGETOPT_REQ_MASK) != RTGETOPT_REQ_NOTHING, VERR_INVALID_PARAMETER); /* * Make sure the union is completely cleared out, whatever happens below. */ pValueUnion->u64 = 0; pValueUnion->pDef = NULL; /* * Pop off the next argument and convert it into a value union. */ if (pState->iNext >= pState->argc) return VERR_GETOPT_REQUIRED_ARGUMENT_MISSING; int iThis = pState->iNext++; const char *pszValue = pState->argv[iThis + (pState->cNonOptions != INT32_MAX ? pState->cNonOptions : 0)]; pValueUnion->pDef = pOpt; /* in case of no value or error. */ if (pState->cNonOptions && pState->cNonOptions != INT32_MAX) rtGetOptMoveArgvEntries(&pState->argv[iThis], &pState->argv[iThis + pState->cNonOptions]); return rtGetOptProcessValue(fFlags, pszValue, pValueUnion); } RT_EXPORT_SYMBOL(RTGetOptFetchValue); RTDECL(char **) RTGetOptNonOptionArrayPtr(PRTGETOPTSTATE pState) { AssertReturn(pState->fFlags & RTGETOPTINIT_FLAGS_OPTS_FIRST, NULL); return &pState->argv[pState->iNext - 1]; } RT_EXPORT_SYMBOL(RTGetOptNonOptionArrayPtr); RTDECL(RTEXITCODE) RTGetOptPrintError(int ch, PCRTGETOPTUNION pValueUnion) { if (ch == VINF_GETOPT_NOT_OPTION) RTMsgError("Invalid parameter: %s", pValueUnion->psz); else if (ch > 0) { if (RT_C_IS_GRAPH(ch)) RTMsgError("Unhandled option: -%c", ch); else RTMsgError("Unhandled option: %i (%#x)", ch, ch); } else if (ch == VERR_GETOPT_UNKNOWN_OPTION) RTMsgError("Unknown option: '%s'", pValueUnion->psz); else if (pValueUnion->pDef && ch == VERR_GETOPT_INVALID_ARGUMENT_FORMAT) /** @todo r=klaus not really ideal, as the value isn't available */ RTMsgError("The value given '%s' has an invalid format.", pValueUnion->pDef->pszLong); else if (pValueUnion->pDef) RTMsgError("%s: %Rrs\n", pValueUnion->pDef->pszLong, ch); else RTMsgError("%Rrs\n", ch); return RTEXITCODE_SYNTAX; } RT_EXPORT_SYMBOL(RTGetOptPrintError); RTDECL(ssize_t) RTGetOptFormatError(char *pszBuf, size_t cbBuf, int ch, PCRTGETOPTUNION pValueUnion) { ssize_t cchRet; if (ch == VINF_GETOPT_NOT_OPTION) cchRet = RTStrPrintf2(pszBuf, cbBuf, "Invalid parameter: %s", pValueUnion->psz); else if (ch > 0) { if (RT_C_IS_GRAPH(ch)) cchRet = RTStrPrintf2(pszBuf, cbBuf, "Unhandled option: -%c", ch); else cchRet = RTStrPrintf2(pszBuf, cbBuf, "Unhandled option: %i (%#x)", ch, ch); } else if (ch == VERR_GETOPT_UNKNOWN_OPTION) cchRet = RTStrPrintf2(pszBuf, cbBuf, "Unknown option: '%s'", pValueUnion->psz); else if (pValueUnion->pDef && ch == VERR_GETOPT_INVALID_ARGUMENT_FORMAT) /** @todo r=klaus not really ideal, as the value isn't available */ cchRet = RTStrPrintf2(pszBuf, cbBuf, "The value given '%s' has an invalid format.", pValueUnion->pDef->pszLong); else if (pValueUnion->pDef) cchRet = RTStrPrintf2(pszBuf, cbBuf, "%s: %Rrs\n", pValueUnion->pDef->pszLong, ch); else cchRet = RTStrPrintf2(pszBuf, cbBuf, "%Rrs\n", ch); return cchRet; } RT_EXPORT_SYMBOL(RTGetOptFormatError);