/* $Id: strformatrt.cpp 5999 2007-12-07 15:05:06Z vboxsync $ */ /** @file * innotek Portable Runtime - IPRT String Formatter Extensions. */ /* * Copyright (C) 2006-2007 innotek GmbH * * 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. */ /** @page pg_rt_str_format_rt The IPRT String Format Extensions * * The string formatter supports most of the non-float format types and flags. * See RTStrFormatV() for the full tail there. In addition we've added a number * of iprt specific format types for the iprt typedefs and other useful stuff. * Note that several of these are similar to \%p and doesn't care much if you try * add formating flags/width/precision. * * * Group 1, the basic runtime typedefs (excluding those which obviously are pointer). * - \%RTbool - Takes a bool value and prints 'true', 'false', or '!%d!'. * - \%RTfile - Takes a #RTFILE value. * - \%RTfmode - Takes a #RTFMODE value. * - \%RTfoff - Takes a #RTFOFF value. * - \%RTfp16 - Takes a #RTFAR16 value. * - \%RTfp32 - Takes a #RTFAR32 value. * - \%RTfp64 - Takes a #RTFAR64 value. * - \%RTgid - Takes a #RTGID value. * - \%RTino - Takes a #RTINODE value. * - \%RTint - Takes a #RTINT value. * - \%RTiop - Takes a #RTIOPORT value. * - \%RTldrm - Takes a #RTLDRMOD value. * - \%RTnthrd - Takes a #RTNATIVETHREAD value. * - \%RTproc - Takes a #RTPROCESS value. * - \%RTptr - Takes a #RTINTPTR or #RTUINTPTR value (but not void *). * - \%RTreg - Takes a #RTUINTREG value. * - \%RTsel - Takes a #RTSEL value. * - \%RTsem - Takes a #RTSEMEVENT, #RTSEMEVENTMULTI, #RTSEMMUTEX, #RTSEMFASTMUTEX, or #RTSEMRW value. * - \%RTsock - Takes a #RTSOCKET value. * - \%RTthrd - Takes a #RTTHREAD value. * - \%RTuid - Takes a #RTUID value. * - \%RTuint - Takes a #RTUINT value. * - \%RTunicp - Takes a #RTUNICP value. * - \%RTutf16 - Takes a #RTUTF16 value. * - \%RTuuid - Takes a #PCRTUUID and will print the UUID as a string. * - \%RTxuint - Takes a #RTUINT or #RTINT value, formatting it as hex. * - \%RGi - Takes a #RTGCINT value. * - \%RGp - Takes a #RTGCPHYS value. * - \%RGr - Takes a #RTGCUINTREG value. * - \%RGu - Takes a #RTGCUINT value. * - \%RGv - Takes a #RTGCPTR, #RTGCINTPTR or #RTGCUINTPTR value. * - \%RGx - Takes a #RTGCUINT or #RTGCINT value, formatting it as hex. * - \%RHi - Takes a #RTHCINT value. * - \%RHp - Takes a #RTHCPHYS value. * - \%RHr - Takes a #RTHCUINTREG value. * - \%RHu - Takes a #RTHCUINT value. * - \%RHv - Takes a #RTHCPTR, #RTHCINTPTR or #RTHCUINTPTR value. * - \%RHx - Takes a #RTHCUINT or #RTHCINT value, formatting it as hex. * - \%RCi - Takes a #RTCCINT value. * - \%RCp - Takes a #RTCCPHYS value. * - \%RCr - Takes a #RTCCUINTREG value. * - \%RCu - Takes a #RTUINT value. * - \%RCv - Takes a #uintptr_t, #intptr_t, void * value. * - \%RCx - Takes a #RTUINT or #RTINT value, formatting it as hex. * * * Group 2, the generic integer types which are prefered over relying on what * bit-count a 'long', 'short', or 'long long' has on a platform. This are * highly prefered for the [u]intXX_t kind of types. * - \%RI[8|16|32|64] - Signed integer value of the specifed bit count. * - \%RU[8|16|32|64] - Unsigned integer value of the specifed bit count. * - \%RX[8|16|32|64] - Hexadecimal integer value of the specifed bit count. * * * Group 3, hex dumpers and other complex stuff which requires more than simple formatting. * - \%Rhxd - Takes a pointer to the memory which is to be dumped in typical * hex format. Use the width to specify the length, and the precision to * set the number of bytes per line. Default width and precision is 16. * - \%Rhxs - Takes a pointer to the memory to be displayed as a hex string, * i.e. a series of space separated bytes formatted as two digit hex value. * Use the width to specify the length. Default length is 16 bytes. * - \%Rrc - Takes an integer iprt status code as argument. Will insert the * status code define corresponding to the iprt status code. * - \%Rrs - Takes an integer iprt status code as argument. Will insert the * short description of the specified status code. * - \%Rrf - Takes an integer iprt status code as argument. Will insert the * full description of the specified status code. * - \%Rra - Takes an integer iprt status code as argument. Will insert the * status code define + full description. * - \%Rt - Current thread (RTThreadSelf()), no arguments. * * - \%Rwc - Takes a long Windows error code as argument. Will insert the status * code define corresponding to the Windows error code. * - \%Rwf - Takes a long Windows error code as argument. Will insert the * full description of the specified status code. * - \%Rwa - Takes a long Windows error code as argument. Will insert the * error code define + full description. * * On other platforms, \%Rw? simply prints the argument in a form of 0xXXXXXXXX. * * @todo (r=dmik) Add a cross-platform \%Rcomr? that will fall back to \%Rw? on * Win32 platforms and will interpret XPCOM result codes on all other. * * * Group 4, structure dumpers. * * - \%RDtimespec - Takes a PCRTTIMESPEC. * * */ /******************************************************************************* * Header Files * *******************************************************************************/ #define LOG_GROUP RTLOGGROUP_STRING #include #include #include #include #include #ifdef IN_RING3 # include # include #endif #include #include "internal/string.h" /** * Callback to format iprt formatting extentions. * See @ref pg_rt_str_format_rt for a reference on the format types. * * @returns The number of bytes formatted. * @param pfnOutput Pointer to output function. * @param pvArgOutput Argument for the output function. * @param ppszFormat Pointer to the format string pointer. Advance this till the char * after the format specifier. * @param pArgs Pointer to the argument list. Use this to fetch the arguments. * @param cchWidth Format Width. -1 if not specified. * @param cchPrecision Format Precision. -1 if not specified. * @param fFlags Flags (RTSTR_NTFS_*). * @param chArgSize The argument size specifier, 'l' or 'L'. */ size_t rtstrFormatRt(PFNRTSTROUTPUT pfnOutput, void *pvArgOutput, const char **ppszFormat, va_list *pArgs, int cchWidth, int cchPrecision, unsigned fFlags, char chArgSize) { const char *pszFormatOrg = *ppszFormat; char ch = *(*ppszFormat)++; if (ch == 'R') { ch = *(*ppszFormat)++; switch (ch) { /* * Groups 1 and 2. */ case 'T': case 'G': case 'H': case 'C': case 'I': case 'X': case 'U': { /* * Interpret the type. */ typedef enum { RTSF_INT, RTSF_INTW, RTSF_FP16, RTSF_FP32, RTSF_FP64, RTSF_UUID, RTSF_BOOL } RTSF; static const struct { uint8_t cch; /**< the length of the string. */ char sz[10]; /**< the part following 'R'. */ uint8_t cb; /**< the size of the type. */ uint8_t u8Base; /**< the size of the type. */ RTSF enmFormat; /**< The way to format it. */ uint16_t fFlags; /**< additional RTSTR_F_* flags. */ } /** Sorted array of types, looked up using binary search! */ s_aTypes[] = { #define STRMEM(str) sizeof(str) - 1, str { STRMEM("Ci"), sizeof(RTINT), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Cp"), sizeof(RTGCPHYS), 16, RTSF_INTW, 0 }, { STRMEM("Cr"), sizeof(RTCCUINTREG), 16, RTSF_INTW, 0 }, { STRMEM("Cu"), sizeof(RTUINT), 10, RTSF_INT, 0 }, { STRMEM("Cv"), sizeof(void *), 16, RTSF_INTW, 0 }, { STRMEM("Cx"), sizeof(RTUINT), 16, RTSF_INT, 0 }, { STRMEM("Gi"), sizeof(RTGCINT), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Gp"), sizeof(RTGCPHYS), 16, RTSF_INTW, 0 }, { STRMEM("Gr"), sizeof(RTGCUINTREG), 16, RTSF_INTW, 0 }, { STRMEM("Gu"), sizeof(RTGCUINT), 10, RTSF_INT, 0 }, { STRMEM("Gv"), sizeof(RTGCPTR), 16, RTSF_INTW, 0 }, { STRMEM("Gx"), sizeof(RTGCUINT), 16, RTSF_INT, 0 }, { STRMEM("Hi"), sizeof(RTHCINT), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Hp"), sizeof(RTHCPHYS), 16, RTSF_INTW, 0 }, { STRMEM("Hr"), sizeof(RTGCUINTREG), 16, RTSF_INTW, 0 }, { STRMEM("Hu"), sizeof(RTHCUINT), 10, RTSF_INT, 0 }, { STRMEM("Hv"), sizeof(RTHCPTR), 16, RTSF_INTW, 0 }, { STRMEM("Hx"), sizeof(RTHCUINT), 16, RTSF_INT, 0 }, { STRMEM("I16"), sizeof(int16_t), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("I32"), sizeof(int32_t), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("I64"), sizeof(int64_t), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("I8"), sizeof(int8_t), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Tbool"), sizeof(bool), 10, RTSF_BOOL, 0 }, { STRMEM("Tfile"), sizeof(RTFILE), 10, RTSF_INT, 0 }, { STRMEM("Tfmode"), sizeof(RTFMODE), 16, RTSF_INTW, 0 }, { STRMEM("Tfoff"), sizeof(RTFOFF), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Tfp16"), sizeof(RTFAR16), 16, RTSF_FP16, RTSTR_F_ZEROPAD }, { STRMEM("Tfp32"), sizeof(RTFAR32), 16, RTSF_FP32, RTSTR_F_ZEROPAD }, { STRMEM("Tfp64"), sizeof(RTFAR64), 16, RTSF_FP64, RTSTR_F_ZEROPAD }, { STRMEM("Tgid"), sizeof(RTGID), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Tino"), sizeof(RTINODE), 16, RTSF_INTW, 0 }, { STRMEM("Tint"), sizeof(RTINT), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Tiop"), sizeof(RTIOPORT), 16, RTSF_INTW, 0 }, { STRMEM("Tldrm"), sizeof(RTLDRMOD), 16, RTSF_INTW, 0 }, { STRMEM("Tnthrd"), sizeof(RTNATIVETHREAD), 16, RTSF_INTW, 0 }, { STRMEM("Tproc"), sizeof(RTPROCESS), 16, RTSF_INTW, 0 }, { STRMEM("Tptr"), sizeof(RTUINTPTR), 16, RTSF_INTW, 0 }, { STRMEM("Treg"), sizeof(RTUINTREG), 16, RTSF_INTW, 0 }, { STRMEM("Tsel"), sizeof(RTSEL), 16, RTSF_INTW, 0 }, { STRMEM("Tsem"), sizeof(RTSEMEVENT), 16, RTSF_INTW, 0 }, { STRMEM("Tsock"), sizeof(RTSOCKET), 10, RTSF_INT, 0 }, { STRMEM("Tthrd"), sizeof(RTTHREAD), 16, RTSF_INTW, 0 }, { STRMEM("Tuid"), sizeof(RTUID), 10, RTSF_INT, RTSTR_F_VALSIGNED }, { STRMEM("Tuint"), sizeof(RTUINT), 10, RTSF_INT, 0 }, { STRMEM("Tunicp"), sizeof(RTUNICP), 16, RTSF_INTW, RTSTR_F_ZEROPAD }, { STRMEM("Tutf16"), sizeof(RTUTF16), 16, RTSF_INTW, RTSTR_F_ZEROPAD }, { STRMEM("Tuuid"), sizeof(PCRTUUID), 16, RTSF_UUID, 0 }, { STRMEM("Txint"), sizeof(RTUINT), 16, RTSF_INT, 0 }, { STRMEM("U16"), sizeof(uint16_t), 10, RTSF_INT, 0 }, { STRMEM("U32"), sizeof(uint32_t), 10, RTSF_INT, 0 }, { STRMEM("U64"), sizeof(uint64_t), 10, RTSF_INT, 0 }, { STRMEM("U8"), sizeof(uint8_t), 10, RTSF_INT, 0 }, { STRMEM("X16"), sizeof(uint16_t), 16, RTSF_INT, 0 }, { STRMEM("X32"), sizeof(uint32_t), 16, RTSF_INT, 0 }, { STRMEM("X64"), sizeof(uint64_t), 16, RTSF_INT, 0 }, { STRMEM("X8"), sizeof(uint8_t), 16, RTSF_INT, 0 }, #undef STRMEM }; const char *pszType = *ppszFormat - 1; int iStart = 0; int iEnd = ELEMENTS(s_aTypes) - 1; int i = ELEMENTS(s_aTypes) / 2; union { uint8_t u8; uint16_t u16; uint32_t u32; uint64_t u64; int8_t i8; int16_t i16; int32_t i32; int64_t i64; RTFAR16 fp16; RTFAR32 fp32; RTFAR64 fp64; bool fBool; PCRTUUID pUuid; } u; char szBuf[80]; unsigned cch; AssertMsg(!chArgSize, ("Not argument size '%c' for RT types! '%.10s'\n", chArgSize, pszFormatOrg)); /* * Lookup the type - binary search. */ for (;;) { int iDiff = strncmp(pszType, s_aTypes[i].sz, s_aTypes[i].cch); if (!iDiff) break; if (iEnd == iStart) { AssertMsgFailed(("Invalid format type '%.10s'!\n", pszFormatOrg)); return 0; } if (iDiff < 0) iEnd = i - 1; else iStart = i + 1; if (iEnd < iStart) { AssertMsgFailed(("Invalid format type '%.10s'!\n", pszFormatOrg)); return 0; } i = iStart + (iEnd - iStart) / 2; } /* * Advance the format string and merge flags. */ *ppszFormat += s_aTypes[i].cch - 1; fFlags |= s_aTypes[i].fFlags; /* * Fetch the argument. * It's important that a signed value gets sign-extended up to 64-bit. */ u.u64 = 0; if (fFlags & RTSTR_F_VALSIGNED) { switch (s_aTypes[i].cb) { case sizeof(int8_t): u.i64 = va_arg(*pArgs, /*int8_t*/int); fFlags |= RTSTR_F_8BIT; break; case sizeof(int16_t): u.i64 = va_arg(*pArgs, /*int16_t*/int); fFlags |= RTSTR_F_16BIT; break; case sizeof(int32_t): u.i64 = va_arg(*pArgs, int32_t); fFlags |= RTSTR_F_32BIT; break; case sizeof(int64_t): u.i64 = va_arg(*pArgs, int64_t); fFlags |= RTSTR_F_64BIT; break; default: AssertMsgFailed(("Invalid format error, size %d'!\n", s_aTypes[i].cb)); break; } } else { switch (s_aTypes[i].cb) { case sizeof(uint8_t): u.u8 = va_arg(*pArgs, /*uint8_t*/unsigned); fFlags |= RTSTR_F_8BIT; break; case sizeof(uint16_t): u.u16 = va_arg(*pArgs, /*uint16_t*/unsigned); fFlags |= RTSTR_F_16BIT; break; case sizeof(uint32_t): u.u32 = va_arg(*pArgs, uint32_t); fFlags |= RTSTR_F_32BIT; break; case sizeof(uint64_t): u.u64 = va_arg(*pArgs, uint64_t); fFlags |= RTSTR_F_64BIT; break; case sizeof(RTFAR32): u.fp32 = va_arg(*pArgs, RTFAR32); break; case sizeof(RTFAR64): u.fp64 = va_arg(*pArgs, RTFAR64); break; default: AssertMsgFailed(("Invalid format error, size %d'!\n", s_aTypes[i].cb)); break; } } /* * Format the output. */ switch (s_aTypes[i].enmFormat) { case RTSF_INT: { cch = RTStrFormatNumber(szBuf, u.u64, s_aTypes[i].u8Base, cchWidth, cchPrecision, fFlags); break; } /* hex which defaults to max width. */ case RTSF_INTW: { Assert(s_aTypes[i].u8Base == 16); if (cchWidth < 0) { cchWidth = s_aTypes[i].cb * 2 + (fFlags & RTSTR_F_SPECIAL ? 2 : 0); fFlags |= RTSTR_F_ZEROPAD; } cch = RTStrFormatNumber(szBuf, u.u64, s_aTypes[i].u8Base, cchWidth, cchPrecision, fFlags); break; } case RTSF_FP16: { fFlags &= ~(RTSTR_F_VALSIGNED | RTSTR_F_BIT_MASK | RTSTR_F_WIDTH | RTSTR_F_PRECISION); cch = RTStrFormatNumber(&szBuf[0], u.fp16.sel, 16, 4, -1, fFlags | RTSTR_F_16BIT); Assert(cch == 4); szBuf[4] = ':'; cch = RTStrFormatNumber(&szBuf[5], u.fp16.off, 16, 4, -1, fFlags | RTSTR_F_16BIT); Assert(cch == 4); cch = 4 + 1 + 4; break; } case RTSF_FP32: { fFlags &= ~(RTSTR_F_VALSIGNED | RTSTR_F_BIT_MASK | RTSTR_F_WIDTH | RTSTR_F_PRECISION); cch = RTStrFormatNumber(&szBuf[0], u.fp32.sel, 16, 4, -1, fFlags | RTSTR_F_16BIT); Assert(cch == 4); szBuf[4] = ':'; cch = RTStrFormatNumber(&szBuf[5], u.fp32.off, 16, 8, -1, fFlags | RTSTR_F_32BIT); Assert(cch == 8); cch = 4 + 1 + 8; break; } case RTSF_FP64: { fFlags &= ~(RTSTR_F_VALSIGNED | RTSTR_F_BIT_MASK | RTSTR_F_WIDTH | RTSTR_F_PRECISION); cch = RTStrFormatNumber(&szBuf[0], u.fp64.sel, 16, 4, -1, fFlags | RTSTR_F_16BIT); Assert(cch == 4); szBuf[4] = ':'; cch = RTStrFormatNumber(&szBuf[5], u.fp64.off, 16, 16, -1, fFlags | RTSTR_F_64BIT); Assert(cch == 16); cch = 4 + 1 + 16; break; } case RTSF_UUID: { static const char szNull[] = ""; if (VALID_PTR(u.pUuid)) { /* cannot call RTUuidToStr because of GC/R0. */ return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "%08x-%04x-%04x-%02x%02x-%02x%02x%02x%02x%02x%02x", u.pUuid->Gen.u32TimeLow, u.pUuid->Gen.u16TimeMid, u.pUuid->Gen.u16TimeHiAndVersion, u.pUuid->Gen.u16ClockSeq & 0xff, u.pUuid->Gen.u16ClockSeq >> 8, u.pUuid->Gen.au8Node[0], u.pUuid->Gen.au8Node[1], u.pUuid->Gen.au8Node[2], u.pUuid->Gen.au8Node[3], u.pUuid->Gen.au8Node[4], u.pUuid->Gen.au8Node[5]); } return pfnOutput(pvArgOutput, szNull, sizeof(szNull) - 1); } case RTSF_BOOL: { static const char szTrue[] = "true "; static const char szFalse[] = "false"; if (u.u64 == 1) return pfnOutput(pvArgOutput, szTrue, sizeof(szTrue) - 1); if (u.u64 == 0) return pfnOutput(pvArgOutput, szFalse, sizeof(szFalse) - 1); /* invalid boolean value */ return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "!%lld!", u.u64); } default: AssertMsgFailed(("Internal error %d\n", s_aTypes[i].enmFormat)); return 0; } /* * Finally, output the formatted string and return. */ return pfnOutput(pvArgOutput, szBuf, cch); } /* Group 3 */ /* * hex dumping. */ case 'h': { char ch = *(*ppszFormat)++; switch (ch) { /* * Hex stuff. */ case 'x': { uint8_t *pu8 = va_arg(*pArgs, uint8_t *); if (cchWidth <= 0) cchWidth = 16; if (pu8) { ch = *(*ppszFormat)++; switch (ch) { /* * Regular hex dump. */ case 'd': { size_t cch = 0; int off = 0; if (cchPrecision <= 0) cchPrecision = 16; while (off < cchWidth) { int i; cch += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "%s%0*x %04x:", off ? "\n" : "", sizeof(pu8) * 2, (uintptr_t)pu8, off); for (i = 0; i < cchPrecision && off + i < cchWidth ; i++) cch += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, off + i < cchWidth ? !(i & 7) && i ? "-%02x" : " %02x" : " ", pu8[i]); while (i++ < cchPrecision) cch += pfnOutput(pvArgOutput, " ", 3); cch += pfnOutput(pvArgOutput, " ", 1); for (i = 0; i < cchPrecision && off + i < cchWidth; i++) { uint8_t u8 = pu8[i]; cch += pfnOutput(pvArgOutput, u8 < 127 && u8 >= 32 ? (const char *)&u8 : ".", 1); } /* next */ pu8 += cchPrecision; off += cchPrecision; } return cch; } /* * Hex string. */ case 's': { if (cchWidth-- > 0) { size_t cch = RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "%02x", *pu8++); for (; cchWidth > 0; cchWidth--, pu8++) cch += RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, " %02x", *pu8); return cch; } break; } default: AssertMsgFailed(("Invalid status code format type '%.10s'!\n", ch, pszFormatOrg)); break; } } else return pfnOutput(pvArgOutput, "", sizeof("") - 1); break; } default: AssertMsgFailed(("Invalid status code format type '%.10s'!\n", ch, pszFormatOrg)); return 0; } break; } /* * iprt status code: %Vrc, %Vrs, %Vrf, %Vra. */ case 'r': { int rc = va_arg(*pArgs, int); char ch = *(*ppszFormat)++; #ifdef IN_RING3 /* we don't want this anywhere else yet. */ PCRTSTATUSMSG pMsg = RTErrGet(rc); switch (ch) { case 'c': return pfnOutput(pvArgOutput, pMsg->pszDefine, strlen(pMsg->pszDefine)); case 's': return pfnOutput(pvArgOutput, pMsg->pszMsgShort, strlen(pMsg->pszMsgShort)); case 'f': return pfnOutput(pvArgOutput, pMsg->pszMsgFull, strlen(pMsg->pszMsgFull)); case 'a': return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "%s (%d) - %s", pMsg->pszDefine, rc, pMsg->pszMsgFull); default: AssertMsgFailed(("Invalid status code format type '%.10s'!\n", pszFormatOrg)); return 0; } #else /* !IN_RING3 */ switch (ch) { case 'c': case 's': case 'f': case 'a': return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "%d", rc); default: AssertMsgFailed(("Invalid status code format type '%.10s'!\n", pszFormatOrg)); return 0; } #endif /* !IN_RING3 */ break; } #if defined(IN_RING3) /* * Windows status code: %Rwc, %Rwf, %Rwa */ case 'w': { long rc = va_arg(*pArgs, long); char ch = *(*ppszFormat)++; #if defined(RT_OS_WINDOWS) PCRTWINERRMSG pMsg = RTErrWinGet(rc); #endif switch (ch) { #if defined(RT_OS_WINDOWS) case 'c': return pfnOutput(pvArgOutput, pMsg->pszDefine, strlen(pMsg->pszDefine)); case 'f': return pfnOutput(pvArgOutput, pMsg->pszMsgFull,strlen(pMsg->pszMsgFull)); case 'a': return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "%s (0x%08X) - %s", pMsg->pszDefine, rc, pMsg->pszMsgFull); #else case 'c': case 'f': case 'a': return RTStrFormat(pfnOutput, pvArgOutput, NULL, 0, "0x%08X", rc); #endif default: AssertMsgFailed(("Invalid status code format type '%.10s'!\n", pszFormatOrg)); return 0; } break; } #endif /* IN_RING3 */ /* * Group 4, structure dumpers. */ case 'D': { /* * Interpret the type. */ typedef enum { RTST_TIMESPEC } RTST; /** Set if it's a pointer */ #define RTST_FLAGS_POINTER RT_BIT(0) static const struct { uint8_t cch; /**< the length of the string. */ char sz[16-2]; /**< the part following 'R'. */ uint8_t cb; /**< the size of the argument. */ uint8_t fFlags; /**< RTST_FLAGS_* */ RTST enmType; /**< The structure type. */ } /** Sorted array of types, looked up using binary search! */ s_aTypes[] = { #define STRMEM(str) sizeof(str) - 1, str { STRMEM("Dtimespec"), sizeof(PCRTTIMESPEC), RTST_FLAGS_POINTER, RTST_TIMESPEC}, #undef STRMEM }; const char *pszType = *ppszFormat - 1; int iStart = 0; int iEnd = ELEMENTS(s_aTypes) - 1; int i = ELEMENTS(s_aTypes) / 2; union { const void *pv; uint64_t u64; PCRTTIMESPEC pTimeSpec; } u; AssertMsg(!chArgSize, ("Not argument size '%c' for RT types! '%.10s'\n", chArgSize, pszFormatOrg)); /* * Lookup the type - binary search. */ for (;;) { int iDiff = strncmp(pszType, s_aTypes[i].sz, s_aTypes[i].cch); if (!iDiff) break; if (iEnd == iStart) { AssertMsgFailed(("Invalid format type '%.10s'!\n", pszFormatOrg)); return 0; } if (iDiff < 0) iEnd = i - 1; else iStart = i + 1; if (iEnd < iStart) { AssertMsgFailed(("Invalid format type '%.10s'!\n", pszFormatOrg)); return 0; } i = iStart + (iEnd - iStart) / 2; } *ppszFormat += s_aTypes[i].cch - 1; /* * Fetch the argument. */ u.u64 = 0; switch (s_aTypes[i].cb) { case sizeof(const void *): u.pv = va_arg(*pArgs, const void *); break; default: AssertMsgFailed(("Invalid format error, size %d'!\n", s_aTypes[i].cb)); break; } /* * If it's a pointer, we'll check if it's valid before going on. */ if ((s_aTypes[i].fFlags & RTST_FLAGS_POINTER) && !VALID_PTR(u.pv)) return pfnOutput(pvArgOutput, "", sizeof("") - 1); /* * Format the output. */ switch (s_aTypes[i].enmType) { case RTST_TIMESPEC: return RTStrFormat(pfnOutput, pvArgOutput, NULL, NULL, "%lld ns", RTTimeSpecGetNano(u.pTimeSpec)); default: AssertMsgFailed(("Invalid/unhandled enmType=%d\n", s_aTypes[i].enmType)); break; } break; } /* * Invalid/Unknown. Bitch about it. */ default: AssertMsgFailed(("Invalid VBox format type '%.10s'!\n", pszFormatOrg)); break; } } else AssertMsgFailed(("Invalid VBox format type '%.10s'!\n", pszFormatOrg)); NOREF(pszFormatOrg); return 0; }