/**
* @file llstring.h
* @brief String utility functions and std::string class.
*
* $LicenseInfo:firstyear=2001&license=viewergpl$
*
* Copyright (c) 2001-2008, Linden Research, Inc.
*
* Second Life Viewer Source Code
* The source code in this file ("Source Code") is provided by Linden Lab
* to you under the terms of the GNU General Public License, version 2.0
* ("GPL"), unless you have obtained a separate licensing agreement
* ("Other License"), formally executed by you and Linden Lab. Terms of
* the GPL can be found in doc/GPL-license.txt in this distribution, or
* online at http://secondlifegrid.net/programs/open_source/licensing/gplv2
*
* There are special exceptions to the terms and conditions of the GPL as
* it is applied to this Source Code. View the full text of the exception
* in the file doc/FLOSS-exception.txt in this software distribution, or
* online at http://secondlifegrid.net/programs/open_source/licensing/flossexception
*
* By copying, modifying or distributing this software, you acknowledge
* that you have read and understood your obligations described above,
* and agree to abide by those obligations.
*
* ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO
* WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY,
* COMPLETENESS OR PERFORMANCE.
* $/LicenseInfo$
*/
#ifndef LL_LLSTRING_H
#define LL_LLSTRING_H
#if LL_LINUX || LL_SOLARIS
#include <wctype.h>
#include <wchar.h>
#endif
const char LL_UNKNOWN_CHAR = '?';
#if LL_DARWIN || LL_LINUX || LL_SOLARIS
// Template specialization of char_traits for U16s. Only necessary on Mac and Linux (exists on Windows already)
namespace std
{
template<>
struct char_traits<U16>
{
typedef U16 char_type;
typedef int int_type;
typedef streampos pos_type;
typedef streamoff off_type;
typedef mbstate_t state_type;
static void
assign(char_type& __c1, const char_type& __c2)
{ __c1 = __c2; }
static bool
eq(const char_type& __c1, const char_type& __c2)
{ return __c1 == __c2; }
static bool
lt(const char_type& __c1, const char_type& __c2)
{ return __c1 < __c2; }
static int
compare(const char_type* __s1, const char_type* __s2, size_t __n)
{ return memcmp(__s1, __s2, __n * sizeof(char_type)); }
static size_t
length(const char_type* __s)
{
const char_type *cur_char = __s;
while (*cur_char != 0)
{
++cur_char;
}
return cur_char - __s;
}
static const char_type*
find(const char_type* __s, size_t __n, const char_type& __a)
{ return static_cast<const char_type*>(memchr(__s, __a, __n * sizeof(char_type))); }
static char_type*
move(char_type* __s1, const char_type* __s2, size_t __n)
{ return static_cast<char_type*>(memmove(__s1, __s2, __n * sizeof(char_type))); }
static char_type*
copy(char_type* __s1, const char_type* __s2, size_t __n)
{ return static_cast<char_type*>(memcpy(__s1, __s2, __n * sizeof(char_type))); } /* Flawfinder: ignore */
static char_type*
assign(char_type* __s, size_t __n, char_type __a)
{
// This isn't right.
//return static_cast<char_type*>(memset(__s, __a, __n * sizeof(char_type)));
// I don't think there's a standard 'memset' for 16-bit values.
// Do this the old-fashioned way.
size_t __i;
for(__i = 0; __i < __n; __i++)
{
__s[__i] = __a;
}
return __s;
}
static char_type
to_char_type(const int_type& __c)
{ return static_cast<char_type>(__c); }
static int_type
to_int_type(const char_type& __c)
{ return static_cast<int_type>(__c); }
static bool
eq_int_type(const int_type& __c1, const int_type& __c2)
{ return __c1 == __c2; }
static int_type
eof() { return static_cast<int_type>(EOF); }
static int_type
not_eof(const int_type& __c)
{ return (__c == eof()) ? 0 : __c; }
};
};
#endif
class LLStringOps
{
public:
static char toUpper(char elem) { return toupper(elem); }
static llwchar toUpper(llwchar elem) { return towupper(elem); }
static char toLower(char elem) { return tolower(elem); }
static llwchar toLower(llwchar elem) { return towlower(elem); }
static BOOL isSpace(char elem) { return isspace(elem) != 0; }
static BOOL isSpace(llwchar elem) { return iswspace(elem) != 0; }
static BOOL isUpper(char elem) { return isupper(elem) != 0; }
static BOOL isUpper(llwchar elem) { return iswupper(elem) != 0; }
static BOOL isLower(char elem) { return islower(elem) != 0; }
static BOOL isLower(llwchar elem) { return iswlower(elem) != 0; }
static S32 collate(const char* a, const char* b) { return strcoll(a, b); }
static S32 collate(const llwchar* a, const llwchar* b);
static BOOL isDigit(char a) { return isdigit(a) != 0; }
static BOOL isDigit(llwchar a) { return iswdigit(a) != 0; }
};
/**
* @brief Return a string constructed from in without crashing if the
* pointer is NULL.
*/
std::string ll_safe_string(const char* in);
std::string ll_safe_string(const char* in, S32 maxlen);
// Allowing assignments from non-strings into format_map_t is apparently
// *really* error-prone, so subclass std::string with just basic c'tors.
class LLFormatMapString
{
public:
LLFormatMapString() {};
LLFormatMapString(const char* s) : mString(ll_safe_string(s)) {};
LLFormatMapString(const std::string& s) : mString(s) {};
operator std::string() const { return mString; }
bool operator<(const LLFormatMapString& rhs) const { return mString < rhs.mString; }
std::size_t length() const { return mString.length(); }
private:
std::string mString;
};
template <class T>
class LLStringUtilBase
{
public:
typedef typename std::basic_string<T>::size_type size_type;
public:
/////////////////////////////////////////////////////////////////////////////////////////
// Static Utility functions that operate on std::strings
static std::basic_string<T> null;
typedef std::map<LLFormatMapString, LLFormatMapString> format_map_t;
static S32 format(std::basic_string<T>& s, const format_map_t& fmt_map);
static BOOL isValidIndex(const std::basic_string<T>& string, size_type i)
{
return !string.empty() && (0 <= i) && (i <= string.size());
}
static void trimHead(std::basic_string<T>& string);
static void trimTail(std::basic_string<T>& string);
static void trim(std::basic_string<T>& string) { trimHead(string); trimTail(string); }
static void truncate(std::basic_string<T>& string, size_type count);
static void toUpper(std::basic_string<T>& string);
static void toLower(std::basic_string<T>& string);
// True if this is the head of s.
static BOOL isHead( const std::basic_string<T>& string, const T* s );
static void addCRLF(std::basic_string<T>& string);
static void removeCRLF(std::basic_string<T>& string);
static void replaceTabsWithSpaces( std::basic_string<T>& string, size_type spaces_per_tab );
static void replaceNonstandardASCII( std::basic_string<T>& string, T replacement );
static void replaceChar( std::basic_string<T>& string, T target, T replacement );
static BOOL containsNonprintable(const std::basic_string<T>& string);
static void stripNonprintable(std::basic_string<T>& string);
/**
* @brief Unsafe way to make ascii characters. You should probably
* only call this when interacting with the host operating system.
* The 1 byte std::string does not work correctly.
* The 2 and 4 byte std::string probably work, so LLWStringUtil::_makeASCII
* should work.
*/
static void _makeASCII(std::basic_string<T>& string);
// Conversion to other data types
static BOOL convertToBOOL(const std::basic_string<T>& string, BOOL& value);
static BOOL convertToU8(const std::basic_string<T>& string, U8& value);
static BOOL convertToS8(const std::basic_string<T>& string, S8& value);
static BOOL convertToS16(const std::basic_string<T>& string, S16& value);
static BOOL convertToU16(const std::basic_string<T>& string, U16& value);
static BOOL convertToU32(const std::basic_string<T>& string, U32& value);
static BOOL convertToS32(const std::basic_string<T>& string, S32& value);
static BOOL convertToF32(const std::basic_string<T>& string, F32& value);
static BOOL convertToF64(const std::basic_string<T>& string, F64& value);
/////////////////////////////////////////////////////////////////////////////////////////
// Utility functions for working with char*'s and strings
// Like strcmp but also handles empty strings. Uses
// current locale.
static S32 compareStrings(const T* lhs, const T* rhs);
static S32 compareStrings(const std::basic_string<T>& lhs, const std::basic_string<T>& rhs);
// case insensitive version of above. Uses current locale on
// Win32, and falls back to a non-locale aware comparison on
// Linux.
static S32 compareInsensitive(const T* lhs, const T* rhs);
static S32 compareInsensitive(const std::basic_string<T>& lhs, const std::basic_string<T>& rhs);
// Case sensitive comparison with good handling of numbers. Does not use current locale.
// a.k.a. strdictcmp()
static S32 compareDict(const std::basic_string<T>& a, const std::basic_string<T>& b);
// Case *in*sensitive comparison with good handling of numbers. Does not use current locale.
// a.k.a. strdictcmp()
static S32 compareDictInsensitive(const std::basic_string<T>& a, const std::basic_string<T>& b);
// Puts compareDict() in a form appropriate for LL container classes to use for sorting.
static BOOL precedesDict( const std::basic_string<T>& a, const std::basic_string<T>& b );
// A replacement for strncpy.
// If the dst buffer is dst_size bytes long or more, ensures that dst is null terminated and holds
// up to dst_size-1 characters of src.
static void copy(T* dst, const T* src, size_type dst_size);
// Copies src into dst at a given offset.
static void copyInto(std::basic_string<T>& dst, const std::basic_string<T>& src, size_type offset);
#ifdef _DEBUG
static void testHarness();
#endif
};
template<class T> std::basic_string<T> LLStringUtilBase<T>::null;
typedef LLStringUtilBase<char> LLStringUtil;
typedef LLStringUtilBase<llwchar> LLWStringUtil;
typedef std::basic_string<llwchar> LLWString;
//@ Use this where we want to disallow input in the form of "foo"
// This is used to catch places where english text is embedded in the code
// instead of in a translatable XUI file.
class LLStringExplicit : public std::string
{
public:
explicit LLStringExplicit(const char* s) : std::string(s) {}
LLStringExplicit(const std::string& s) : std::string(s) {}
LLStringExplicit(const std::string& s, size_type pos, size_type n = std::string::npos) : std::string(s, pos, n) {}
};
struct LLDictionaryLess
{
public:
bool operator()(const std::string& a, const std::string& b)
{
return (LLStringUtil::precedesDict(a, b) ? true : false);
}
};
/**
* Simple support functions
*/
/**
* @brief chop off the trailing characters in a string.
*
* This function works on bytes rather than glyphs, so this will
* incorrectly truncate non-single byte strings.
* Use utf8str_truncate() for utf8 strings
* @return a copy of in string minus the trailing count characters.
*/
inline std::string chop_tail_copy(
const std::string& in,
std::string::size_type count)
{
return std::string(in, 0, in.length() - count);
}
/**
* @brief This translates a nybble stored as a hex value from 0-f back
* to a nybble in the low order bits of the return byte.
*/
U8 hex_as_nybble(char hex);
/**
* @brief read the contents of a file into a string.
*
* Since this function has no concept of character encoding, most
* anything you do with this method ill-advised. Please avoid.
* @param str [out] The string which will have.
* @param filename The full name of the file to read.
* @return Returns true on success. If false, str is unmodified.
*/
bool _read_file_into_string(std::string& str, const std::string& filename);
/**
* Unicode support
*/
// Make the incoming string a utf8 string. Replaces any unknown glyph
// with the UNKOWN_CHARACTER. Once any unknown glph is found, the rest
// of the data may not be recovered.
std::string rawstr_to_utf8(const std::string& raw);
//
// We should never use UTF16 except when communicating with Win32!
//
typedef std::basic_string<U16> llutf16string;
LLWString utf16str_to_wstring(const llutf16string &utf16str, S32 len);
LLWString utf16str_to_wstring(const llutf16string &utf16str);
llutf16string wstring_to_utf16str(const LLWString &utf32str, S32 len);
llutf16string wstring_to_utf16str(const LLWString &utf32str);
llutf16string utf8str_to_utf16str ( const std::string& utf8str, S32 len);
llutf16string utf8str_to_utf16str ( const std::string& utf8str );
LLWString utf8str_to_wstring(const std::string &utf8str, S32 len);
LLWString utf8str_to_wstring(const std::string &utf8str);
// Same function, better name. JC
inline LLWString utf8string_to_wstring(const std::string& utf8_string) { return utf8str_to_wstring(utf8_string); }
//
S32 wchar_to_utf8chars(llwchar inchar, char* outchars);
std::string wstring_to_utf8str(const LLWString &utf32str, S32 len);
std::string wstring_to_utf8str(const LLWString &utf32str);
std::string utf16str_to_utf8str(const llutf16string &utf16str, S32 len);
std::string utf16str_to_utf8str(const llutf16string &utf16str);
// Length of this UTF32 string in bytes when transformed to UTF8
S32 wstring_utf8_length(const LLWString& wstr);
// Length in bytes of this wide char in a UTF8 string
S32 wchar_utf8_length(const llwchar wc);
std::string utf8str_tolower(const std::string& utf8str);
// Length in llwchar (UTF-32) of the first len units (16 bits) of the given UTF-16 string.
S32 utf16str_wstring_length(const llutf16string &utf16str, S32 len);
// Length in utf16string (UTF-16) of wlen wchars beginning at woffset.
S32 wstring_utf16_length(const LLWString & wstr, S32 woffset, S32 wlen);
// Length in wstring (i.e., llwchar count) of a part of a wstring specified by utf16 length (i.e., utf16 units.)
S32 wstring_wstring_length_from_utf16_length(const LLWString & wstr, S32 woffset, S32 utf16_length, BOOL *unaligned = NULL);
/**
* @brief Properly truncate a utf8 string to a maximum byte count.
*
* The returned string may be less than max_len if the truncation
* happens in the middle of a glyph. If max_len is longer than the
* string passed in, the return value == utf8str.
* @param utf8str A valid utf8 string to truncate.
* @param max_len The maximum number of bytes in the return value.
* @return Returns a valid utf8 string with byte count <= max_len.
*/
std::string utf8str_truncate(const std::string& utf8str, const S32 max_len);
std::string utf8str_trim(const std::string& utf8str);
S32 utf8str_compare_insensitive(
const std::string& lhs,
const std::string& rhs);
/**
* @brief Replace all occurences of target_char with replace_char
*
* @param utf8str A utf8 string to process.
* @param target_char The wchar to be replaced
* @param replace_char The wchar which is written on replace
*/
std::string utf8str_substChar(
const std::string& utf8str,
const llwchar target_char,
const llwchar replace_char);
std::string utf8str_makeASCII(const std::string& utf8str);
// Hack - used for evil notecards.
std::string mbcsstring_makeASCII(const std::string& str);
std::string utf8str_removeCRLF(const std::string& utf8str);
#if LL_WINDOWS
/* @name Windows string helpers
*/
//@{
/**
* @brief Implementation the expected snprintf interface.
*
* If the size of the passed in buffer is not large enough to hold the string,
* two bad things happen:
* 1. resulting formatted string is NOT null terminated
* 2. Depending on the platform, the return value could be a) the required
* size of the buffer to copy the entire formatted string or b) -1.
* On Windows with VS.Net 2003, it returns -1 e.g.
*
* safe_snprintf always adds a NULL terminator so that the caller does not
* need to check for return value or need to add the NULL terminator.
* It does not, however change the return value - to let the caller know
* that the passed in buffer size was not large enough to hold the
* formatted string.
*
*/
int safe_snprintf(char* str, size_t size, const char* format, ...);
/**
* @brief Convert a wide string to std::string
*
* This replaces the unsafe W2A macro from ATL.
*/
std::string ll_convert_wide_to_string(const wchar_t* in);
//@}
#endif // LL_WINDOWS
/**
* Many of the 'strip' and 'replace' methods of LLStringUtilBase need
* specialization to work with the signed char type.
* Sadly, it is not possible (AFAIK) to specialize a single method of
* a template class.
* That stuff should go here.
*/
namespace LLStringFn
{
/**
* @brief Replace all non-printable characters with replacement in
* string.
*
* @param [in,out] string the to modify. out value is the string
* with zero non-printable characters.
* @param The replacement character. use LL_UNKNOWN_CHAR if unsure.
*/
void replace_nonprintable(
std::basic_string<char>& string,
char replacement);
/**
* @brief Replace all non-printable characters with replacement in
* a wide string.
*
* @param [in,out] string the to modify. out value is the string
* with zero non-printable characters.
* @param The replacement character. use LL_UNKNOWN_CHAR if unsure.
*/
void replace_nonprintable(
std::basic_string<llwchar>& string,
llwchar replacement);
/**
* @brief Replace all non-printable characters and pipe characters
* with replacement in a string.
*
* @param [in,out] the string to modify. out value is the string
* with zero non-printable characters and zero pipe characters.
* @param The replacement character. use LL_UNKNOWN_CHAR if unsure.
*/
void replace_nonprintable_and_pipe(std::basic_string<char>& str,
char replacement);
/**
* @brief Replace all non-printable characters and pipe characters
* with replacement in a wide string.
*
* @param [in,out] the string to modify. out value is the string
* with zero non-printable characters and zero pipe characters.
* @param The replacement wide character. use LL_UNKNOWN_CHAR if unsure.
*/
void replace_nonprintable_and_pipe(std::basic_string<llwchar>& str,
llwchar replacement);
/**
* @brief Remove all characters that are not allowed in XML 1.0.
* Returns a copy of the string with those characters removed.
* Works with US ASCII and UTF-8 encoded strings. JC
*/
std::string strip_invalid_xml(const std::string& input);
}
////////////////////////////////////////////////////////////
// LLStringBase::format()
//
// This function takes a string 's' and a map 'fmt_map' of strings-to-strings.
// All occurances of strings in 's' from the left-hand side of 'fmt_map' are
// then replaced with the corresponding right-hand side of 'fmt_map', non-
// recursively. The function returns the number of substitutions made.
// static
template<class T>
S32 LLStringUtilBase<T>::format(std::basic_string<T>& s, const format_map_t& fmt_map)
{
typedef typename std::basic_string<T>::size_type string_size_type_t;
string_size_type_t scanstart = 0;
S32 res = 0;
// Look for the first match of any keyword, replace that keyword,
// repeat from the end of the replacement string. This avoids
// accidentally performing substitution on a substituted string.
while (1)
{
string_size_type_t first_match_pos = scanstart;
string_size_type_t first_match_str_length = 0;
std::basic_string<T> first_match_str_replacement;
for (format_map_t::const_iterator iter = fmt_map.begin();
iter != fmt_map.end();
++iter)
{
string_size_type_t n = s.find(iter->first, scanstart);
if (n != std::basic_string<T>::npos &&
(n < first_match_pos ||
0 == first_match_str_length))
{
first_match_pos = n;
first_match_str_length = iter->first.length();
first_match_str_replacement = iter->second;
}
}
if (0 == first_match_str_length)
{
// no more keys found to substitute from this point
// in the string forward.
break;
}
else
{
s.erase(first_match_pos, first_match_str_length);
s.insert(first_match_pos, first_match_str_replacement);
scanstart = first_match_pos +
first_match_str_replacement.length();
++res;
}
}
return res;
}
// static
template<class T>
S32 LLStringUtilBase<T>::compareStrings(const T* lhs, const T* rhs)
{
S32 result;
if( lhs == rhs )
{
result = 0;
}
else
if ( !lhs || !lhs[0] )
{
result = ((!rhs || !rhs[0]) ? 0 : 1);
}
else
if ( !rhs || !rhs[0])
{
result = -1;
}
else
{
result = LLStringOps::collate(lhs, rhs);
}
return result;
}
//static
template<class T>
S32 LLStringUtilBase<T>::compareStrings(const std::basic_string<T>& lhs, const std::basic_string<T>& rhs)
{
return LLStringOps::collate(lhs.c_str(), rhs.c_str());
}
// static
template<class T>
S32 LLStringUtilBase<T>::compareInsensitive(const T* lhs, const T* rhs )
{
S32 result;
if( lhs == rhs )
{
result = 0;
}
else
if ( !lhs || !lhs[0] )
{
result = ((!rhs || !rhs[0]) ? 0 : 1);
}
else
if ( !rhs || !rhs[0] )
{
result = -1;
}
else
{
std::basic_string<T> lhs_string(lhs);
std::basic_string<T> rhs_string(rhs);
LLStringUtilBase<T>::toUpper(lhs_string);
LLStringUtilBase<T>::toUpper(rhs_string);
result = LLStringOps::collate(lhs_string.c_str(), rhs_string.c_str());
}
return result;
}
//static
template<class T>
S32 LLStringUtilBase<T>::compareInsensitive(const std::basic_string<T>& lhs, const std::basic_string<T>& rhs)
{
std::basic_string<T> lhs_string(lhs);
std::basic_string<T> rhs_string(rhs);
LLStringUtilBase<T>::toUpper(lhs_string);
LLStringUtilBase<T>::toUpper(rhs_string);
return LLStringOps::collate(lhs_string.c_str(), rhs_string.c_str());
}
// Case sensitive comparison with good handling of numbers. Does not use current locale.
// a.k.a. strdictcmp()
//static
template<class T>
S32 LLStringUtilBase<T>::compareDict(const std::basic_string<T>& astr, const std::basic_string<T>& bstr)
{
const T* a = astr.c_str();
const T* b = bstr.c_str();
T ca, cb;
S32 ai, bi, cnt = 0;
S32 bias = 0;
ca = *(a++);
cb = *(b++);
while( ca && cb ){
if( bias==0 ){
if( LLStringOps::isUpper(ca) ){ ca = LLStringOps::toLower(ca); bias--; }
if( LLStringOps::isUpper(cb) ){ cb = LLStringOps::toLower(cb); bias++; }
}else{
if( LLStringOps::isUpper(ca) ){ ca = LLStringOps::toLower(ca); }
if( LLStringOps::isUpper(cb) ){ cb = LLStringOps::toLower(cb); }
}
if( LLStringOps::isDigit(ca) ){
if( cnt-->0 ){
if( cb!=ca ) break;
}else{
if( !LLStringOps::isDigit(cb) ) break;
for(ai=0; LLStringOps::isDigit(a[ai]); ai++);
for(bi=0; LLStringOps::isDigit(b[bi]); bi++);
if( ai<bi ){ ca=0; break; }
if( bi<ai ){ cb=0; break; }
if( ca!=cb ) break;
cnt = ai;
}
}else if( ca!=cb ){ break;
}
ca = *(a++);
cb = *(b++);
}
if( ca==cb ) ca += bias;
return ca-cb;
}
// static
template<class T>
S32 LLStringUtilBase<T>::compareDictInsensitive(const std::basic_string<T>& astr, const std::basic_string<T>& bstr)
{
const T* a = astr.c_str();
const T* b = bstr.c_str();
T ca, cb;
S32 ai, bi, cnt = 0;
ca = *(a++);
cb = *(b++);
while( ca && cb ){
if( LLStringOps::isUpper(ca) ){ ca = LLStringOps::toLower(ca); }
if( LLStringOps::isUpper(cb) ){ cb = LLStringOps::toLower(cb); }
if( LLStringOps::isDigit(ca) ){
if( cnt-->0 ){
if( cb!=ca ) break;
}else{
if( !LLStringOps::isDigit(cb) ) break;
for(ai=0; LLStringOps::isDigit(a[ai]); ai++);
for(bi=0; LLStringOps::isDigit(b[bi]); bi++);
if( ai<bi ){ ca=0; break; }
if( bi<ai ){ cb=0; break; }
if( ca!=cb ) break;
cnt = ai;
}
}else if( ca!=cb ){ break;
}
ca = *(a++);
cb = *(b++);
}
return ca-cb;
}
// Puts compareDict() in a form appropriate for LL container classes to use for sorting.
// static
template<class T>
BOOL LLStringUtilBase<T>::precedesDict( const std::basic_string<T>& a, const std::basic_string<T>& b )
{
if( a.size() && b.size() )
{
return (LLStringUtilBase<T>::compareDict(a.c_str(), b.c_str()) < 0);
}
else
{
return (!b.empty());
}
}
//static
template<class T>
void LLStringUtilBase<T>::toUpper(std::basic_string<T>& string)
{
if( !string.empty() )
{
std::transform(
string.begin(),
string.end(),
string.begin(),
(T(*)(T)) &LLStringOps::toUpper);
}
}
//static
template<class T>
void LLStringUtilBase<T>::toLower(std::basic_string<T>& string)
{
if( !string.empty() )
{
std::transform(
string.begin(),
string.end(),
string.begin(),
(T(*)(T)) &LLStringOps::toLower);
}
}
//static
template<class T>
void LLStringUtilBase<T>::trimHead(std::basic_string<T>& string)
{
if( !string.empty() )
{
size_type i = 0;
while( i < string.length() && LLStringOps::isSpace( string[i] ) )
{
i++;
}
string.erase(0, i);
}
}
//static
template<class T>
void LLStringUtilBase<T>::trimTail(std::basic_string<T>& string)
{
if( string.size() )
{
size_type len = string.length();
size_type i = len;
while( i > 0 && LLStringOps::isSpace( string[i-1] ) )
{
i--;
}
string.erase( i, len - i );
}
}
// Replace line feeds with carriage return-line feed pairs.
//static
template<class T>
void LLStringUtilBase<T>::addCRLF(std::basic_string<T>& string)
{
const T LF = 10;
const T CR = 13;
// Count the number of line feeds
size_type count = 0;
size_type len = string.size();
size_type i;
for( i = 0; i < len; i++ )
{
if( string[i] == LF )
{
count++;
}
}
// Insert a carriage return before each line feed
if( count )
{
size_type size = len + count;
T *t = new T[size];
size_type j = 0;
for( i = 0; i < len; ++i )
{
if( string[i] == LF )
{
t[j] = CR;
++j;
}
t[j] = string[i];
++j;
}
string.assign(t, size);
}
}
// Remove all carriage returns
//static
template<class T>
void LLStringUtilBase<T>::removeCRLF(std::basic_string<T>& string)
{
const T CR = 13;
size_type cr_count = 0;
size_type len = string.size();
size_type i;
for( i = 0; i < len - cr_count; i++ )
{
if( string[i+cr_count] == CR )
{
cr_count++;
}
string[i] = string[i+cr_count];
}
string.erase(i, cr_count);
}
//static
template<class T>
void LLStringUtilBase<T>::replaceChar( std::basic_string<T>& string, T target, T replacement )
{
size_type found_pos = 0;
for (found_pos = string.find(target, found_pos);
found_pos != std::basic_string<T>::npos;
found_pos = string.find(target, found_pos))
{
string[found_pos] = replacement;
}
}
//static
template<class T>
void LLStringUtilBase<T>::replaceNonstandardASCII( std::basic_string<T>& string, T replacement )
{
const char LF = 10;
const S8 MIN = 32;
// const S8 MAX = 127;
size_type len = string.size();
for( size_type i = 0; i < len; i++ )
{
// No need to test MAX < mText[i] because we treat mText[i] as a signed char,
// which has a max value of 127.
if( ( S8(string[i]) < MIN ) && (string[i] != LF) )
{
string[i] = replacement;
}
}
}
//static
template<class T>
void LLStringUtilBase<T>::replaceTabsWithSpaces( std::basic_string<T>& str, size_type spaces_per_tab )
{
const T TAB = '\t';
const T SPACE = ' ';
std::basic_string<T> out_str;
// Replace tabs with spaces
for (size_type i = 0; i < str.length(); i++)
{
if (str[i] == TAB)
{
for (size_type j = 0; j < spaces_per_tab; j++)
out_str += SPACE;
}
else
{
out_str += str[i];
}
}
str = out_str;
}
//static
template<class T>
BOOL LLStringUtilBase<T>::containsNonprintable(const std::basic_string<T>& string)
{
const char MIN = 32;
BOOL rv = FALSE;
for (size_type i = 0; i < string.size(); i++)
{
if(string[i] < MIN)
{
rv = TRUE;
break;
}
}
return rv;
}
//static
template<class T>
void LLStringUtilBase<T>::stripNonprintable(std::basic_string<T>& string)
{
const char MIN = 32;
size_type j = 0;
if (string.empty())
{
return;
}
char* c_string = new char[string.size() + 1];
if(c_string == NULL)
{
return;
}
strcpy(c_string, string.c_str()); /*Flawfinder: ignore*/
char* write_head = &c_string[0];
for (size_type i = 0; i < string.size(); i++)
{
char* read_head = &string[i];
write_head = &c_string[j];
if(!(*read_head < MIN))
{
*write_head = *read_head;
++j;
}
}
c_string[j]= '\0';
string = c_string;
delete []c_string;
}
template<class T>
void LLStringUtilBase<T>::_makeASCII(std::basic_string<T>& string)
{
// Replace non-ASCII chars with LL_UNKNOWN_CHAR
for (size_type i = 0; i < string.length(); i++)
{
if (string[i] > 0x7f)
{
string[i] = LL_UNKNOWN_CHAR;
}
}
}
// static
template<class T>
void LLStringUtilBase<T>::copy( T* dst, const T* src, size_type dst_size )
{
if( dst_size > 0 )
{
size_type min_len = 0;
if( src )
{
min_len = llmin( dst_size - 1, strlen( src ) ); /* Flawfinder: ignore */
memcpy(dst, src, min_len * sizeof(T)); /* Flawfinder: ignore */
}
dst[min_len] = '\0';
}
}
// static
template<class T>
void LLStringUtilBase<T>::copyInto(std::basic_string<T>& dst, const std::basic_string<T>& src, size_type offset)
{
if ( offset == dst.length() )
{
// special case - append to end of string and avoid expensive
// (when strings are large) string manipulations
dst += src;
}
else
{
std::basic_string<T> tail = dst.substr(offset);
dst = dst.substr(0, offset);
dst += src;
dst += tail;
};
}
// True if this is the head of s.
//static
template<class T>
BOOL LLStringUtilBase<T>::isHead( const std::basic_string<T>& string, const T* s )
{
if( string.empty() )
{
// Early exit
return FALSE;
}
else
{
return (strncmp( s, string.c_str(), string.size() ) == 0);
}
}
template<class T>
BOOL LLStringUtilBase<T>::convertToBOOL(const std::basic_string<T>& string, BOOL& value)
{
if( string.empty() )
{
return FALSE;
}
std::basic_string<T> temp( string );
trim(temp);
if(
(temp == "1") ||
(temp == "T") ||
(temp == "t") ||
(temp == "TRUE") ||
(temp == "true") ||
(temp == "True") )
{
value = TRUE;
return TRUE;
}
else
if(
(temp == "0") ||
(temp == "F") ||
(temp == "f") ||
(temp == "FALSE") ||
(temp == "false") ||
(temp == "False") )
{
value = FALSE;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToU8(const std::basic_string<T>& string, U8& value)
{
S32 value32 = 0;
BOOL success = convertToS32(string, value32);
if( success && (U8_MIN <= value32) && (value32 <= U8_MAX) )
{
value = (U8) value32;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToS8(const std::basic_string<T>& string, S8& value)
{
S32 value32 = 0;
BOOL success = convertToS32(string, value32);
if( success && (S8_MIN <= value32) && (value32 <= S8_MAX) )
{
value = (S8) value32;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToS16(const std::basic_string<T>& string, S16& value)
{
S32 value32 = 0;
BOOL success = convertToS32(string, value32);
if( success && (S16_MIN <= value32) && (value32 <= S16_MAX) )
{
value = (S16) value32;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToU16(const std::basic_string<T>& string, U16& value)
{
S32 value32 = 0;
BOOL success = convertToS32(string, value32);
if( success && (U16_MIN <= value32) && (value32 <= U16_MAX) )
{
value = (U16) value32;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToU32(const std::basic_string<T>& string, U32& value)
{
if( string.empty() )
{
return FALSE;
}
std::basic_string<T> temp( string );
trim(temp);
U32 v;
std::basic_istringstream<T> i_stream((std::basic_string<T>)temp);
if(i_stream >> v)
{
//TODO: figure out overflow reporting here
//if( ULONG_MAX == v )
//{
// // Underflow or overflow
// return FALSE;
//}
value = v;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToS32(const std::basic_string<T>& string, S32& value)
{
if( string.empty() )
{
return FALSE;
}
std::basic_string<T> temp( string );
trim(temp);
S32 v;
std::basic_istringstream<T> i_stream((std::basic_string<T>)temp);
if(i_stream >> v)
{
//TODO: figure out overflow and underflow reporting here
//if((LONG_MAX == v) || (LONG_MIN == v))
//{
// // Underflow or overflow
// return FALSE;
//}
value = v;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToF32(const std::basic_string<T>& string, F32& value)
{
F64 value64 = 0.0;
BOOL success = convertToF64(string, value64);
if( success && (-F32_MAX <= value64) && (value64 <= F32_MAX) )
{
value = (F32) value64;
return TRUE;
}
return FALSE;
}
template<class T>
BOOL LLStringUtilBase<T>::convertToF64(const std::basic_string<T>& string, F64& value)
{
if( string.empty() )
{
return FALSE;
}
std::basic_string<T> temp( string );
trim(temp);
F64 v;
std::basic_istringstream<T> i_stream((std::basic_string<T>)temp);
if(i_stream >> v)
{
//TODO: figure out overflow and underflow reporting here
//if( ((-HUGE_VAL == v) || (HUGE_VAL == v))) )
//{
// // Underflow or overflow
// return FALSE;
//}
value = v;
return TRUE;
}
return FALSE;
}
template<class T>
void LLStringUtilBase<T>::truncate(std::basic_string<T>& string, size_type count)
{
size_type cur_size = string.size();
string.resize(count < cur_size ? count : cur_size);
}
#endif // LL_STRING_H