/** @file * IPRT - C++ string class. */ /* * Copyright (C) 2007-2016 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. */ #ifndef ___iprt_cpp_ministring_h #define ___iprt_cpp_ministring_h #include #include #include #include #include /** @defgroup grp_rt_cpp_string C++ String support * @ingroup grp_rt_cpp * @{ */ /** @brief C++ string class. * * This is a C++ string class that does not depend on anything else except IPRT * memory management functions. Semantics are like in std::string, except it * can do a lot less. * * Note that RTCString does not differentiate between NULL strings * and empty strings. In other words, RTCString("") and RTCString(NULL) * behave the same. In both cases, RTCString allocates no memory, reports * a zero length and zero allocated bytes for both, and returns an empty * C string from c_str(). * * @note RTCString ASSUMES that all strings it deals with are valid UTF-8. * The caller is responsible for not breaking this assumption. */ #ifdef VBOX /** @remarks Much of the code in here used to be in com::Utf8Str so that * com::Utf8Str can now derive from RTCString and only contain code * that is COM-specific, such as com::Bstr conversions. Compared to * the old Utf8Str though, RTCString always knows the length of its * member string and the size of the buffer so it can use memcpy() * instead of strdup(). */ #endif class RT_DECL_CLASS RTCString { public: /** * Creates an empty string that has no memory allocated. */ RTCString() : m_psz(NULL), m_cch(0), m_cbAllocated(0) { } /** * Creates a copy of another RTCString. * * This allocates s.length() + 1 bytes for the new instance, unless s is empty. * * @param a_rSrc The source string. * * @throws std::bad_alloc */ RTCString(const RTCString &a_rSrc) { copyFromN(a_rSrc.m_psz, a_rSrc.m_cch); } /** * Creates a copy of a C string. * * This allocates strlen(pcsz) + 1 bytes for the new instance, unless s is empty. * * @param pcsz The source string. * * @throws std::bad_alloc */ RTCString(const char *pcsz) { copyFromN(pcsz, pcsz ? strlen(pcsz) : 0); } /** * Create a partial copy of another RTCString. * * @param a_rSrc The source string. * @param a_offSrc The byte offset into the source string. * @param a_cchSrc The max number of chars (encoded UTF-8 bytes) * to copy from the source string. */ RTCString(const RTCString &a_rSrc, size_t a_offSrc, size_t a_cchSrc = npos) { if (a_offSrc < a_rSrc.m_cch) copyFromN(&a_rSrc.m_psz[a_offSrc], RT_MIN(a_cchSrc, a_rSrc.m_cch - a_offSrc)); else { m_psz = NULL; m_cch = 0; m_cbAllocated = 0; } } /** * Create a partial copy of a C string. * * @param a_pszSrc The source string (UTF-8). * @param a_cchSrc The max number of chars (encoded UTF-8 bytes) * to copy from the source string. This must not * be '0' as the compiler could easily mistake * that for the va_list constructor. */ RTCString(const char *a_pszSrc, size_t a_cchSrc) { size_t cchMax = a_pszSrc ? RTStrNLen(a_pszSrc, a_cchSrc) : 0; copyFromN(a_pszSrc, RT_MIN(a_cchSrc, cchMax)); } /** * Create a string containing @a a_cTimes repetitions of the character @a * a_ch. * * @param a_cTimes The number of times the character is repeated. * @param a_ch The character to fill the string with. */ RTCString(size_t a_cTimes, char a_ch) : m_psz(NULL), m_cch(0), m_cbAllocated(0) { Assert((unsigned)a_ch < 0x80); if (a_cTimes) { reserve(a_cTimes + 1); memset(m_psz, a_ch, a_cTimes); m_psz[a_cTimes] = '\0'; m_cch = a_cTimes; } } /** * Create a new string given the format string and its arguments. * * @param a_pszFormat Pointer to the format string (UTF-8), * @see pg_rt_str_format. * @param a_va Argument vector containing the arguments * specified by the format string. * @sa printfV * @remarks Not part of std::string. */ RTCString(const char *a_pszFormat, va_list a_va) RT_IPRT_FORMAT_ATTR(1, 0) : m_psz(NULL), m_cch(0), m_cbAllocated(0) { printfV(a_pszFormat, a_va); } /** * Destructor. */ virtual ~RTCString() { cleanup(); } /** * String length in bytes. * * Returns the length of the member string in bytes, which is equal to strlen(c_str()). * In other words, this does not count unicode codepoints; use utf8length() for that. * The byte length is always cached so calling this is cheap and requires no * strlen() invocation. * * @returns m_cbLength. */ size_t length() const { return m_cch; } /** * String length in unicode codepoints. * * As opposed to length(), which returns the length in bytes, this counts * the number of unicode codepoints. This is *not* cached so calling this * is expensive. * * @returns Number of codepoints in the member string. */ size_t uniLength() const { return m_psz ? RTStrUniLen(m_psz) : 0; } /** * The allocated buffer size (in bytes). * * Returns the number of bytes allocated in the internal string buffer, which is * at least length() + 1 if length() > 0; for an empty string, this returns 0. * * @returns m_cbAllocated. */ size_t capacity() const { return m_cbAllocated; } /** * Make sure at that least cb of buffer space is reserved. * * Requests that the contained memory buffer have at least cb bytes allocated. * This may expand or shrink the string's storage, but will never truncate the * contained string. In other words, cb will be ignored if it's smaller than * length() + 1. * * @param cb New minimum size (in bytes) of member memory buffer. * * @throws std::bad_alloc On allocation error. The object is left unchanged. */ void reserve(size_t cb) { if ( cb != m_cbAllocated && cb > m_cch + 1 ) { int rc = RTStrRealloc(&m_psz, cb); if (RT_SUCCESS(rc)) m_cbAllocated = cb; #ifdef RT_EXCEPTIONS_ENABLED else throw std::bad_alloc(); #endif } } /** * A C like version of the reserve method, i.e. return code instead of throw. * * @returns VINF_SUCCESS or VERR_NO_STRING_MEMORY. * @param cb New minimum size (in bytes) of member memory buffer. */ int reserveNoThrow(size_t cb) { if ( cb != m_cbAllocated && cb > m_cch + 1 ) { int rc = RTStrRealloc(&m_psz, cb); if (RT_SUCCESS(rc)) m_cbAllocated = cb; else return rc; } return VINF_SUCCESS; } /** * Deallocates all memory. */ inline void setNull() { cleanup(); } RTMEMEF_NEW_AND_DELETE_OPERATORS(); /** * Assigns a copy of pcsz to "this". * * @param pcsz The source string. * * @throws std::bad_alloc On allocation failure. The object is left describing * a NULL string. * * @returns Reference to the object. */ RTCString &operator=(const char *pcsz) { if (m_psz != pcsz) { cleanup(); copyFromN(pcsz, pcsz ? strlen(pcsz) : 0); } return *this; } /** * Assigns a copy of s to "this". * * @param s The source string. * * @throws std::bad_alloc On allocation failure. The object is left describing * a NULL string. * * @returns Reference to the object. */ RTCString &operator=(const RTCString &s) { if (this != &s) { cleanup(); copyFromN(s.m_psz, s.m_cch); } return *this; } /** * Assigns the output of the string format operation (RTStrPrintf). * * @param pszFormat Pointer to the format string, * @see pg_rt_str_format. * @param ... Ellipsis containing the arguments specified by * the format string. * * @throws std::bad_alloc On allocation error. The object is left unchanged. * * @returns Reference to the object. */ RTCString &printf(const char *pszFormat, ...) RT_IPRT_FORMAT_ATTR(1, 2); /** * Assigns the output of the string format operation (RTStrPrintfV). * * @param pszFormat Pointer to the format string, * @see pg_rt_str_format. * @param va Argument vector containing the arguments * specified by the format string. * * @throws std::bad_alloc On allocation error. The object is left unchanged. * * @returns Reference to the object. */ RTCString &printfV(const char *pszFormat, va_list va) RT_IPRT_FORMAT_ATTR(1, 0); /** * Appends the string "that" to "this". * * @param that The string to append. * * @throws std::bad_alloc On allocation error. The object is left unchanged. * * @returns Reference to the object. */ RTCString &append(const RTCString &that); /** * Appends the string "that" to "this". * * @param pszThat The C string to append. * * @throws std::bad_alloc On allocation error. The object is left unchanged. * * @returns Reference to the object. */ RTCString &append(const char *pszThat); /** * Appends the given character to "this". * * @param ch The character to append. * * @throws std::bad_alloc On allocation error. The object is left unchanged. * * @returns Reference to the object. */ RTCString &append(char ch); /** * Appends the given unicode code point to "this". * * @param uc The unicode code point to append. * * @throws std::bad_alloc On allocation error. The object is left unchanged. * * @returns Reference to the object. */ RTCString &appendCodePoint(RTUNICP uc); /** * Shortcut to append(), RTCString variant. * * @param that The string to append. * * @returns Reference to the object. */ RTCString &operator+=(const RTCString &that) { return append(that); } /** * Shortcut to append(), const char* variant. * * @param pszThat The C string to append. * * @returns Reference to the object. */ RTCString &operator+=(const char *pszThat) { return append(pszThat); } /** * Shortcut to append(), char variant. * * @param ch The character to append. * * @returns Reference to the object. */ RTCString &operator+=(char ch) { return append(ch); } /** * Converts the member string to upper case. * * @returns Reference to the object. */ RTCString &toUpper() { if (length()) { /* Folding an UTF-8 string may result in a shorter encoding (see testcase), so recalculate the length afterwards. */ ::RTStrToUpper(m_psz); size_t cchNew = strlen(m_psz); Assert(cchNew <= m_cch); m_cch = cchNew; } return *this; } /** * Converts the member string to lower case. * * @returns Reference to the object. */ RTCString &toLower() { if (length()) { /* Folding an UTF-8 string may result in a shorter encoding (see testcase), so recalculate the length afterwards. */ ::RTStrToLower(m_psz); size_t cchNew = strlen(m_psz); Assert(cchNew <= m_cch); m_cch = cchNew; } return *this; } /** * Index operator. * * Returns the byte at the given index, or a null byte if the index is not * smaller than length(). This does _not_ count codepoints but simply points * into the member C string. * * @param i The index into the string buffer. * @returns char at the index or null. */ inline char operator[](size_t i) const { if (i < length()) return m_psz[i]; return '\0'; } /** * Returns the contained string as a C-style const char* pointer. * This never returns NULL; if the string is empty, this returns a * pointer to static null byte. * * @returns const pointer to C-style string. */ inline const char *c_str() const { return (m_psz) ? m_psz : ""; } /** * Returns a non-const raw pointer that allows to modify the string directly. * As opposed to c_str() and raw(), this DOES return NULL for an empty string * because we cannot return a non-const pointer to a static "" global. * * @warning * -# Be sure not to modify data beyond the allocated memory! Call * capacity() to find out how large that buffer is. * -# After any operation that modifies the length of the string, * you _must_ call RTCString::jolt(), or subsequent copy operations * may go nowhere. Better not use mutableRaw() at all. */ char *mutableRaw() { return m_psz; } /** * Clean up after using mutableRaw. * * Intended to be called after something has messed with the internal string * buffer (e.g. after using mutableRaw() or Utf8Str::asOutParam()). Resets the * internal lengths correctly. Otherwise subsequent copy operations may go * nowhere. */ void jolt() { if (m_psz) { m_cch = strlen(m_psz); m_cbAllocated = m_cch + 1; /* (Required for the Utf8Str::asOutParam case) */ } else { m_cch = 0; m_cbAllocated = 0; } } /** * Returns @c true if the member string has no length. * * This is @c true for instances created from both NULL and "" input * strings. * * This states nothing about how much memory might be allocated. * * @returns @c true if empty, @c false if not. */ bool isEmpty() const { return length() == 0; } /** * Returns @c false if the member string has no length. * * This is @c false for instances created from both NULL and "" input * strings. * * This states nothing about how much memory might be allocated. * * @returns @c false if empty, @c true if not. */ bool isNotEmpty() const { return length() != 0; } /** Case sensitivity selector. */ enum CaseSensitivity { CaseSensitive, CaseInsensitive }; /** * Compares the member string to a C-string. * * @param pcszThat The string to compare with. * @param cs Whether comparison should be case-sensitive. * @returns 0 if equal, negative if this is smaller than @a pcsz, positive * if larger. */ int compare(const char *pcszThat, CaseSensitivity cs = CaseSensitive) const { /* This klugde is for m_cch=0 and m_psz=NULL. pcsz=NULL and psz="" are treated the same way so that str.compare(str2.c_str()) works. */ if (length() == 0) return pcszThat == NULL || *pcszThat == '\0' ? 0 : -1; if (cs == CaseSensitive) return ::RTStrCmp(m_psz, pcszThat); return ::RTStrICmp(m_psz, pcszThat); } /** * Compares the member string to another RTCString. * * @param rThat The string to compare with. * @param cs Whether comparison should be case-sensitive. * @returns 0 if equal, negative if this is smaller than @a pcsz, positive * if larger. */ int compare(const RTCString &rThat, CaseSensitivity cs = CaseSensitive) const { if (cs == CaseSensitive) return ::RTStrCmp(m_psz, rThat.m_psz); return ::RTStrICmp(m_psz, rThat.m_psz); } /** * Compares the two strings. * * @returns true if equal, false if not. * @param rThat The string to compare with. */ bool equals(const RTCString &rThat) const { return rThat.length() == length() && ( length() == 0 || memcmp(rThat.m_psz, m_psz, length()) == 0); } /** * Compares the two strings. * * @returns true if equal, false if not. * @param pszThat The string to compare with. */ bool equals(const char *pszThat) const { /* This klugde is for m_cch=0 and m_psz=NULL. pcsz=NULL and psz="" are treated the same way so that str.equals(str2.c_str()) works. */ if (length() == 0) return pszThat == NULL || *pszThat == '\0'; return RTStrCmp(pszThat, m_psz) == 0; } /** * Compares the two strings ignoring differences in case. * * @returns true if equal, false if not. * @param that The string to compare with. */ bool equalsIgnoreCase(const RTCString &that) const { /* Unfolded upper and lower case characters may require different amount of encoding space, so the length optimization doesn't work. */ return RTStrICmp(that.m_psz, m_psz) == 0; } /** * Compares the two strings ignoring differences in case. * * @returns true if equal, false if not. * @param pszThat The string to compare with. */ bool equalsIgnoreCase(const char *pszThat) const { /* This klugde is for m_cch=0 and m_psz=NULL. pcsz=NULL and psz="" are treated the same way so that str.equalsIgnoreCase(str2.c_str()) works. */ if (length() == 0) return pszThat == NULL || *pszThat == '\0'; return RTStrICmp(pszThat, m_psz) == 0; } /** @name Comparison operators. * @{ */ bool operator==(const RTCString &that) const { return equals(that); } bool operator!=(const RTCString &that) const { return !equals(that); } bool operator<( const RTCString &that) const { return compare(that) < 0; } bool operator>( const RTCString &that) const { return compare(that) > 0; } bool operator==(const char *pszThat) const { return equals(pszThat); } bool operator!=(const char *pszThat) const { return !equals(pszThat); } bool operator<( const char *pszThat) const { return compare(pszThat) < 0; } bool operator>( const char *pszThat) const { return compare(pszThat) > 0; } /** @} */ /** Max string offset value. * * When returned by a method, this indicates failure. When taken as input, * typically a default, it means all the way to the string terminator. */ static const size_t npos; /** * Find the given substring. * * Looks for pcszFind in "this" starting at "pos" and returns its position * as a byte (not codepoint) offset, counting from the beginning of "this" at 0. * * @param pcszFind The substring to find. * @param pos The (byte) offset into the string buffer to start * searching. * * @returns 0 based position of pcszFind. npos if not found. */ size_t find(const char *pcszFind, size_t pos = 0) const; /** * Replaces all occurences of cFind with cReplace in the member string. * In order not to produce invalid UTF-8, the characters must be ASCII * values less than 128; this is not verified. * * @param chFind Character to replace. Must be ASCII < 128. * @param chReplace Character to replace cFind with. Must be ASCII < 128. */ void findReplace(char chFind, char chReplace); /** * Count the occurences of the specified character in the string. * * @param ch What to search for. Must be ASCII < 128. * @remarks QString::count */ size_t count(char ch) const; /** * Count the occurences of the specified sub-string in the string. * * @param psz What to search for. * @param cs Case sensitivity selector. * @remarks QString::count */ size_t count(const char *psz, CaseSensitivity cs = CaseSensitive) const; /** * Count the occurences of the specified sub-string in the string. * * @param pStr What to search for. * @param cs Case sensitivity selector. * @remarks QString::count */ size_t count(const RTCString *pStr, CaseSensitivity cs = CaseSensitive) const; /** * Returns a substring of "this" as a new Utf8Str. * * Works exactly like its equivalent in std::string. With the default * parameters "0" and "npos", this always copies the entire string. The * "pos" and "n" arguments represent bytes; it is the caller's responsibility * to ensure that the offsets do not copy invalid UTF-8 sequences. When * used in conjunction with find() and length(), this will work. * * @param pos Index of first byte offset to copy from "this", counting from 0. * @param n Number of bytes to copy, starting with the one at "pos". * The copying will stop if the null terminator is encountered before * n bytes have been copied. */ RTCString substr(size_t pos = 0, size_t n = npos) const { return RTCString(*this, pos, n); } /** * Returns a substring of "this" as a new Utf8Str. As opposed to substr(), * this variant takes codepoint offsets instead of byte offsets. * * @param pos Index of first unicode codepoint to copy from * "this", counting from 0. * @param n Number of unicode codepoints to copy, starting with * the one at "pos". The copying will stop if the null * terminator is encountered before n codepoints have * been copied. */ RTCString substrCP(size_t pos = 0, size_t n = npos) const; /** * Returns true if "this" ends with "that". * * @param that Suffix to test for. * @param cs Case sensitivity selector. * @returns true if match, false if mismatch. */ bool endsWith(const RTCString &that, CaseSensitivity cs = CaseSensitive) const; /** * Returns true if "this" begins with "that". * @param that Prefix to test for. * @param cs Case sensitivity selector. * @returns true if match, false if mismatch. */ bool startsWith(const RTCString &that, CaseSensitivity cs = CaseSensitive) const; /** * Returns true if "this" contains "that" (strstr). * * @param that Substring to look for. * @param cs Case sensitivity selector. * @returns true if match, false if mismatch. */ bool contains(const RTCString &that, CaseSensitivity cs = CaseSensitive) const; /** * Attempts to convert the member string into a 32-bit integer. * * @returns 32-bit unsigned number on success. * @returns 0 on failure. */ int32_t toInt32() const { return RTStrToInt32(m_psz); } /** * Attempts to convert the member string into an unsigned 32-bit integer. * * @returns 32-bit unsigned number on success. * @returns 0 on failure. */ uint32_t toUInt32() const { return RTStrToUInt32(m_psz); } /** * Attempts to convert the member string into an 64-bit integer. * * @returns 64-bit unsigned number on success. * @returns 0 on failure. */ int64_t toInt64() const { return RTStrToInt64(m_psz); } /** * Attempts to convert the member string into an unsigned 64-bit integer. * * @returns 64-bit unsigned number on success. * @returns 0 on failure. */ uint64_t toUInt64() const { return RTStrToUInt64(m_psz); } /** * Attempts to convert the member string into an unsigned 64-bit integer. * * @param i Where to return the value on success. * @returns IPRT error code, see RTStrToInt64. */ int toInt(uint64_t &i) const; /** * Attempts to convert the member string into an unsigned 32-bit integer. * * @param i Where to return the value on success. * @returns IPRT error code, see RTStrToInt32. */ int toInt(uint32_t &i) const; /** Splitting behavior regarding empty sections in the string. */ enum SplitMode { KeepEmptyParts, /**< Empty parts are added as empty strings to the result list. */ RemoveEmptyParts /**< Empty parts are skipped. */ }; /** * Splits a string separated by strSep into its parts. * * @param a_rstrSep The separator to search for. * @param a_enmMode How should empty parts be handled. * @returns separated strings as string list. */ RTCList split(const RTCString &a_rstrSep, SplitMode a_enmMode = RemoveEmptyParts) const; /** * Joins a list of strings together using the provided separator and * an optional prefix for each item in the list. * * @param a_rList The list to join. * @param a_rstrPrefix The prefix used for appending to each item. * @param a_rstrSep The separator used for joining. * @returns joined string. */ static RTCString joinEx(const RTCList &a_rList, const RTCString &a_rstrPrefix /* = "" */, const RTCString &a_rstrSep /* = "" */); /** * Joins a list of strings together using the provided separator. * * @param a_rList The list to join. * @param a_rstrSep The separator used for joining. * @returns joined string. */ static RTCString join(const RTCList &a_rList, const RTCString &a_rstrSep = ""); /** * Swaps two strings in a fast way. * * Exception safe. * * @param a_rThat The string to swap with. */ inline void swap(RTCString &a_rThat) throw() { char *pszTmp = m_psz; size_t cchTmp = m_cch; size_t cbAllocatedTmp = m_cbAllocated; m_psz = a_rThat.m_psz; m_cch = a_rThat.m_cch; m_cbAllocated = a_rThat.m_cbAllocated; a_rThat.m_psz = pszTmp; a_rThat.m_cch = cchTmp; a_rThat.m_cbAllocated = cbAllocatedTmp; } protected: /** * Hide operator bool() to force people to use isEmpty() explicitly. */ operator bool() const; /** * Destructor implementation, also used to clean up in operator=() before * assigning a new string. */ void cleanup() { if (m_psz) { RTStrFree(m_psz); m_psz = NULL; m_cch = 0; m_cbAllocated = 0; } } /** * Protected internal helper to copy a string. * * This ignores the previous object state, so either call this from a * constructor or call cleanup() first. copyFromN() unconditionally sets * the members to a copy of the given other strings and makes no * assumptions about previous contents. Can therefore be used both in copy * constructors, when member variables have no defined value, and in * assignments after having called cleanup(). * * @param pcszSrc The source string. * @param cchSrc The number of chars (bytes) to copy from the * source strings. RTSTR_MAX is NOT accepted. * * @throws std::bad_alloc On allocation failure. The object is left * describing a NULL string. */ void copyFromN(const char *pcszSrc, size_t cchSrc) { if (cchSrc) { m_psz = RTStrAlloc(cchSrc + 1); if (RT_LIKELY(m_psz)) { m_cch = cchSrc; m_cbAllocated = cchSrc + 1; memcpy(m_psz, pcszSrc, cchSrc); m_psz[cchSrc] = '\0'; } else { m_cch = 0; m_cbAllocated = 0; #ifdef RT_EXCEPTIONS_ENABLED throw std::bad_alloc(); #endif } } else { m_cch = 0; m_cbAllocated = 0; m_psz = NULL; } } static DECLCALLBACK(size_t) printfOutputCallback(void *pvArg, const char *pachChars, size_t cbChars); char *m_psz; /**< The string buffer. */ size_t m_cch; /**< strlen(m_psz) - i.e. no terminator included. */ size_t m_cbAllocated; /**< Size of buffer that m_psz points to; at least m_cbLength + 1. */ }; /** @} */ /** @addtogroup grp_rt_cpp_string * @{ */ /** * Concatenate two strings. * * @param a_rstr1 String one. * @param a_rstr2 String two. * @returns the concatenate string. * * @relates RTCString */ RTDECL(const RTCString) operator+(const RTCString &a_rstr1, const RTCString &a_rstr2); /** * Concatenate two strings. * * @param a_rstr1 String one. * @param a_psz2 String two. * @returns the concatenate string. * * @relates RTCString */ RTDECL(const RTCString) operator+(const RTCString &a_rstr1, const char *a_psz2); /** * Concatenate two strings. * * @param a_psz1 String one. * @param a_rstr2 String two. * @returns the concatenate string. * * @relates RTCString */ RTDECL(const RTCString) operator+(const char *a_psz1, const RTCString &a_rstr2); /** * Class with RTCString::printf as constructor for your convenience. * * Constructing a RTCString string object from a format string and a variable * number of arguments can easily be confused with the other RTCString * constructors, thus this child class. * * The usage of this class is like the following: * @code RTCStringFmt strName("program name = %s", argv[0]); @endcode */ class RTCStringFmt : public RTCString { public: /** * Constructs a new string given the format string and the list of the * arguments for the format string. * * @param a_pszFormat Pointer to the format string (UTF-8), * @see pg_rt_str_format. * @param ... Ellipsis containing the arguments specified by * the format string. */ explicit RTCStringFmt(const char *a_pszFormat, ...) RT_IPRT_FORMAT_ATTR(1, 2) { va_list va; va_start(va, a_pszFormat); printfV(a_pszFormat, va); va_end(va); } RTMEMEF_NEW_AND_DELETE_OPERATORS(); protected: RTCStringFmt() {} }; /** @} */ #endif