/** @file * IPRT - Mini C++ string class. */ /* * Copyright (C) 2007-2009 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 ___VBox_ministring_h #define ___VBox_ministring_h #include #include #include namespace iprt { /** * @brief Mini C++ string class. * * "MiniString" is a small 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 MiniString does not differentiate between NULL strings and * empty strings. In other words, MiniString("") and MiniString(NULL) * behave the same. In both cases, MiniString allocates no memory, reports * a zero length and zero allocated bytes for both, and returns an empty * C string from c_str(). */ #ifdef VBOX /** @remarks Much of the code in here used to be in com::Utf8Str so that * com::Utf8Str can now derive from MiniString and only contain code * that is COM-specific, such as com::Bstr conversions. Compared to * the old Utf8Str though, MiniString 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 MiniString { public: /** * Creates an empty string that has no memory allocated. */ MiniString() : m_psz(NULL), m_cbLength(0), m_cbAllocated(0) { } /** * Creates a copy of another MiniString. * * This allocates s.length() + 1 bytes for the new instance, unless s is empty. * * @param s The source string. * * @throws std::bad_alloc */ MiniString(const MiniString &s) { copyFrom(s); } /** * 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 */ MiniString(const char *pcsz) { copyFrom(pcsz); } /** * Destructor. */ virtual ~MiniString() { cleanup(); } /** * String length in bytes. * * Returns the length of the member string, which is equal to strlen(c_str()). * In other words, this does not count unicode codepoints but returns the number * of bytes. This is always cached so calling this is cheap and requires no * strlen() invocation. * * @returns m_cbLength. */ size_t length() const { return m_cbLength; } /** * 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_cbLength + 1 ) { int vrc = RTStrRealloc(&m_psz, cb); if (RT_SUCCESS(vrc)) m_cbAllocated = cb; #ifdef RT_EXCEPTIONS_ENABLED else throw std::bad_alloc(); #endif } } /** * Deallocates all memory. */ inline void setNull() { cleanup(); } /** * 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. */ MiniString &operator=(const char *pcsz) { if (m_psz != pcsz) { cleanup(); copyFrom(pcsz); } 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. */ MiniString &operator=(const MiniString &s) { if (this != &s) { cleanup(); copyFrom(s); } return *this; } /** * 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. */ MiniString &append(const MiniString &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. */ MiniString &append(const char *pszThat); /** * Appends the given character to "this". * * @param c The character to append. * * @throws std::bad_alloc On allocation error. The object is left unchanged. * * @returns Reference to the object. */ MiniString &append(char c); /** * Shortcut to append(), MiniString variant. * * @param that The string to append. * * @returns Reference to the object. */ MiniString &operator+=(const MiniString &that) { return append(that); } /** * Shortcut to append(), const char* variant. * * @param pszThat The C string to append. * * @returns Reference to the object. */ MiniString &operator+=(const char *pszThat) { return append(pszThat); } /** * Shortcut to append(), char variant. * * @param pszThat The character to append. * * @returns Reference to the object. */ MiniString &operator+=(char c) { return append(c); } /** * 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 MiniString::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_cbLength = strlen(m_psz); m_cbAllocated = m_cbLength + 1; /* (Required for the Utf8Str::asOutParam case) */ } else { m_cbLength = 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 pcsz. * @param pcsz * @param cs Whether comparison should be case-sensitive. * @return */ int compare(const char *pcsz, CaseSensitivity cs = CaseSensitive) const { if (m_psz == pcsz) return 0; if (m_psz == NULL) return -1; if (pcsz == NULL) return 1; if (cs == CaseSensitive) return ::RTStrCmp(m_psz, pcsz); else return ::RTStrICmp(m_psz, pcsz); } int compare(const MiniString &that, CaseSensitivity cs = CaseSensitive) const { return compare(that.m_psz, cs); } /** @name Comparison operators. * @{ */ bool operator==(const MiniString &that) const { return !compare(that); } bool operator!=(const MiniString &that) const { return !!compare(that); } bool operator<( const MiniString &that) const { return compare(that) < 0; } bool operator>( const MiniString &that) const { return compare(that) > 0; } bool operator==(const char *that) const { return !compare(that); } bool operator!=(const char *that) const { return !!compare(that); } bool operator<( const char *that) const { return compare(that) < 0; } bool operator>( const char *that) const { return compare(that) > 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, * 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; /** * Returns a substring of "this" as a new Utf8Str. * * Works exactly like its equivalent in std::string except that this interprets * pos and n as unicode codepoints instead of bytes. With the default * parameters "0" and "npos", this always copies the entire string. * * @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. * * @remarks This works on code points, not bytes! */ iprt::MiniString substr(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 iprt::MiniString &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 iprt::MiniString &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 iprt::MiniString &that, CaseSensitivity cs = CaseSensitive) const; /** * 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; 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_cbLength = 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. * * copyFrom() 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(). * * This variant copies from another MiniString and is fast since * the length of the source string is known. * * @param s The source string. * * @throws std::bad_alloc On allocation failure. The object is left describing * a NULL string. */ void copyFrom(const MiniString &s) { if ((m_cbLength = s.m_cbLength)) { m_cbAllocated = m_cbLength + 1; m_psz = (char *)RTStrAlloc(m_cbAllocated); if (RT_LIKELY(m_psz)) memcpy(m_psz, s.m_psz, m_cbAllocated); // include 0 terminator else { m_cbLength = 0; m_cbAllocated = 0; #ifdef RT_EXCEPTIONS_ENABLED throw std::bad_alloc(); #endif } } else { m_cbAllocated = 0; m_psz = NULL; } } /** * Protected internal helper to copy a string. This ignores the previous object * state, so either call this from a constructor or call cleanup() first. * * See copyFrom() above. * * This variant copies from a C string and needs to call strlen() * on it. It's therefore slower than the one above. * * @param pcsz The source string. * * @throws std::bad_alloc On allocation failure. The object is left describing * a NULL string. */ void copyFrom(const char *pcsz) { if (pcsz && *pcsz) { m_cbLength = strlen(pcsz); m_cbAllocated = m_cbLength + 1; m_psz = (char *)RTStrAlloc(m_cbAllocated); if (RT_LIKELY(m_psz)) memcpy(m_psz, pcsz, m_cbAllocated); // include 0 terminator else { m_cbLength = 0; m_cbAllocated = 0; #ifdef RT_EXCEPTIONS_ENABLED throw std::bad_alloc(); #endif } } else { m_cbLength = 0; m_cbAllocated = 0; m_psz = NULL; } } char *m_psz; /**< The string buffer. */ size_t m_cbLength; /**< 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. */ }; } // namespace iprt #endif