lyx_mirror/src/support/lstrings.cpp
Peter Kümmel 8e91dbd4f0 remove debug code, we know the translation failed
git-svn-id: svn://svn.lyx.org/lyx/lyx-devel/trunk@38323 a592a061-630c-0410-9148-cb99ea01b6c8
2011-04-09 22:13:58 +00:00

1418 lines
31 KiB
C++

/**
* \file lstrings.cpp
* This file is part of LyX, the document processor.
* Licence details can be found in the file COPYING.
*
* \author Lars Gullik Bjønnes
* \author Jean-Marc Lasgouttes
* \author Dekel Tsur
*
* Full author contact details are available in file CREDITS.
*/
#include <config.h>
#include "support/lstrings.h"
#include "support/convert.h"
#include "support/gettext.h"
#include "support/qstring_helpers.h"
#include "support/textutils.h"
#include <boost/tokenizer.hpp>
#include "support/lassert.h"
#include <QString>
#include <QVector>
#include <cstdio>
#include <algorithm>
using namespace std;
namespace lyx {
// Using this allows us to have docstring default arguments in headers
// without #include "support/docstring" there.
docstring const & empty_docstring()
{
static docstring s;
return s;
}
// Using this allows us to have string default arguments in headers
// without #include <string>
string const & empty_string()
{
static string s;
return s;
}
namespace {
/**
* Convert a QChar into a UCS4 character.
* This is a hack (it does only make sense for the common part of the UCS4
* and UTF16 encodings) and should not be used.
* This does only exist because of performance reasons (a real conversion
* using iconv is too slow on windows).
*/
inline char_type qchar_to_ucs4(QChar const & qchar)
{
LASSERT(is_utf16(static_cast<char_type>(qchar.unicode())), /**/);
return static_cast<char_type>(qchar.unicode());
}
/**
* Convert a UCS4 character into a QChar.
* This is a hack (it does only make sense for the common part of the UCS4
* and UTF16 encodings) and should not be used.
* This does only exist because of performance reasons (a real conversion
* using iconv is too slow on windows).
*/
inline QChar const ucs4_to_qchar(char_type const ucs4)
{
LASSERT(is_utf16(ucs4), /**/);
return QChar(static_cast<unsigned short>(ucs4));
}
/// Maximum valid UCS4 code point
char_type const ucs4_max = 0x10ffff;
} // anon namespace
bool isLetterChar(char_type c)
{
if (!is_utf16(c)) {
if (c > ucs4_max)
// outside the UCS4 range
return false;
// assume that all non-utf16 characters are letters
return true;
}
return ucs4_to_qchar(c).isLetter();
}
bool isLower(char_type c)
{
if (!is_utf16(c))
return false;
return ucs4_to_qchar(c).isLower();
}
bool isAlphaASCII(char_type c)
{
return ('a' <= c && c <= 'z') || ('A' <= c && c <= 'Z');
}
bool isPrintable(char_type c)
{
if (!is_utf16(c)) {
if (c > ucs4_max)
// outside the UCS4 range
return false;
// assume that all non-utf16 characters are printable
return true;
}
return ucs4_to_qchar(c).isPrint();
}
bool isPrintableNonspace(char_type c)
{
if (!is_utf16(c)) {
if (c > ucs4_max)
// outside the UCS4 range
return false;
// assume that all non-utf16 characters are printable and
// no space
return true;
}
QChar const qc = ucs4_to_qchar(c);
return qc.isPrint() && !qc.isSpace();
}
bool isSpace(char_type c)
{
if (!is_utf16(c)) {
// assume that no non-utf16 character is a space
// c outside the UCS4 range is catched as well
return false;
}
QChar const qc = ucs4_to_qchar(c);
return qc.isSpace();
}
bool isNumber(char_type c)
{
if (!is_utf16(c))
// assume that no non-utf16 character is a numeral
// c outside the UCS4 range is catched as well
return false;
return ucs4_to_qchar(c).isNumber();
}
bool isDigitASCII(char_type c)
{
return '0' <= c && c <= '9';
}
bool isAlnumASCII(char_type c)
{
return isAlphaASCII(c) || isDigitASCII(c);
}
namespace support {
int compare_no_case(docstring const & s, docstring const & s2)
{
docstring::const_iterator p = s.begin();
docstring::const_iterator p2 = s2.begin();
while (p != s.end() && p2 != s2.end()) {
char_type const lc1 = lowercase(*p);
char_type const lc2 = lowercase(*p2);
if (lc1 != lc2)
return (lc1 < lc2) ? -1 : 1;
++p;
++p2;
}
if (s.size() == s2.size())
return 0;
if (s.size() < s2.size())
return -1;
return 1;
}
namespace {
template<typename Char>
Char ascii_tolower(Char c) {
if (c >= 'A' && c <= 'Z')
return c - 'A' + 'a';
return c;
}
}
int compare_ascii_no_case(string const & s, string const & s2)
{
string::const_iterator p = s.begin();
string::const_iterator p2 = s2.begin();
while (p != s.end() && p2 != s2.end()) {
int const lc1 = ascii_tolower(*p);
int const lc2 = ascii_tolower(*p2);
if (lc1 != lc2)
return (lc1 < lc2) ? -1 : 1;
++p;
++p2;
}
if (s.size() == s2.size())
return 0;
if (s.size() < s2.size())
return -1;
return 1;
}
int compare_ascii_no_case(docstring const & s, docstring const & s2)
{
docstring::const_iterator p = s.begin();
docstring::const_iterator p2 = s2.begin();
while (p != s.end() && p2 != s2.end()) {
char_type const lc1 = ascii_tolower(*p);
char_type const lc2 = ascii_tolower(*p2);
if (lc1 != lc2)
return (lc1 < lc2) ? -1 : 1;
++p;
++p2;
}
if (s.size() == s2.size())
return 0;
if (s.size() < s2.size())
return -1;
return 1;
}
bool isStrInt(string const & str)
{
if (str.empty())
return false;
// Remove leading and trailing white space chars.
string const tmpstr = trim(str);
if (tmpstr.empty())
return false;
string::const_iterator cit = tmpstr.begin();
if ((*cit) == '-')
++cit;
string::const_iterator end = tmpstr.end();
for (; cit != end; ++cit)
if (!isDigitASCII(*cit))
return false;
return true;
}
bool isStrUnsignedInt(string const & str)
{
if (str.empty())
return false;
// Remove leading and trailing white space chars.
string const tmpstr = trim(str);
if (tmpstr.empty())
return false;
string::const_iterator cit = tmpstr.begin();
string::const_iterator end = tmpstr.end();
for (; cit != end; ++cit)
if (!isDigitASCII(*cit))
return false;
return true;
}
bool isStrDbl(string const & str)
{
if (str.empty())
return false;
// Remove leading and trailing white space chars.
string const tmpstr = trim(str);
if (tmpstr.empty())
return false;
// if (tmpstr.count('.') > 1) return false;
string::const_iterator cit = tmpstr.begin();
bool found_dot = false;
if (*cit == '-')
++cit;
string::const_iterator end = tmpstr.end();
for (; cit != end; ++cit) {
if (!isDigitASCII(*cit) && *cit != '.')
return false;
if ('.' == (*cit)) {
if (found_dot)
return false;
found_dot = true;
}
}
return true;
}
bool hasDigitASCII(docstring const & str)
{
docstring::const_iterator cit = str.begin();
docstring::const_iterator const end = str.end();
for (; cit != end; ++cit)
if (isDigitASCII(*cit))
return true;
return false;
}
bool isHexChar(char_type c)
{
return c == '0' ||
c == '1' ||
c == '2' ||
c == '3' ||
c == '4' ||
c == '5' ||
c == '6' ||
c == '7' ||
c == '8' ||
c == '9' ||
c == 'a' || c == 'A' ||
c == 'b' || c == 'B' ||
c == 'c' || c == 'C' ||
c == 'd' || c == 'D' ||
c == 'e' || c == 'E' ||
c == 'f' || c == 'F';
}
bool isHex(docstring const & str)
{
int index = 0;
if (str.length() > 2 && str[0] == '0' &&
(str[1] == 'x' || str[1] == 'X'))
index = 2;
int const len = str.length();
for (; index < len; ++index) {
if (!isHexChar(str[index]))
return false;
}
return true;
}
int hexToInt(docstring const & str)
{
string s = to_ascii(str);
int h;
sscanf(s.c_str(), "%x", &h);
return h;
}
bool isAscii(docstring const & str)
{
int const len = str.length();
for (int i = 0; i < len; ++i)
if (str[i] >= 0x80)
return false;
return true;
}
bool isAscii(string const & str)
{
int const len = str.length();
for (int i = 0; i < len; ++i)
if (static_cast<unsigned char>(str[i]) >= 0x80)
return false;
return true;
}
char lowercase(char c)
{
LASSERT(static_cast<unsigned char>(c) < 0x80, /**/);
return char(tolower(c));
}
char uppercase(char c)
{
LASSERT(static_cast<unsigned char>(c) < 0x80, /**/);
return char(toupper(c));
}
char_type lowercase(char_type c)
{
if (!is_utf16(c))
// We don't know how to lowercase a non-utf16 char
return c;
return qchar_to_ucs4(ucs4_to_qchar(c).toLower());
}
char_type uppercase(char_type c)
{
if (!is_utf16(c))
// We don't know how to uppercase a non-utf16 char
return c;
return qchar_to_ucs4(ucs4_to_qchar(c).toUpper());
}
bool isLowerCase(char_type ch) {
return lowercase(ch) == ch;
}
bool isUpperCase(char_type ch) {
return uppercase(ch) == ch;
}
namespace {
// since we cannot use tolower and toupper directly in the
// calls to transform yet, we use these helper clases. (Lgb)
struct local_lowercase {
char_type operator()(char_type c) const {
return lowercase(c);
}
};
struct local_uppercase {
char_type operator()(char_type c) const {
return uppercase(c);
}
};
template<typename Char> struct local_ascii_lowercase {
Char operator()(Char c) const { return ascii_tolower(c); }
};
} // end of anon namespace
docstring const lowercase(docstring const & a)
{
docstring tmp(a);
transform(tmp.begin(), tmp.end(), tmp.begin(), local_lowercase());
return tmp;
}
docstring const uppercase(docstring const & a)
{
docstring tmp(a);
transform(tmp.begin(), tmp.end(), tmp.begin(), local_uppercase());
return tmp;
}
string const ascii_lowercase(string const & a)
{
string tmp(a);
transform(tmp.begin(), tmp.end(), tmp.begin(),
local_ascii_lowercase<char>());
return tmp;
}
docstring const ascii_lowercase(docstring const & a)
{
docstring tmp(a);
transform(tmp.begin(), tmp.end(), tmp.begin(),
local_ascii_lowercase<char_type>());
return tmp;
}
char_type superscript(char_type c)
{
switch (c) {
case '2': return 0x00b2;
case '3': return 0x00b3;
case '1': return 0x00b9;
case '0': return 0x2070;
case 'i': return 0x2071;
case '4': return 0x2074;
case '5': return 0x2075;
case '6': return 0x2076;
case '7': return 0x2077;
case '8': return 0x2078;
case '9': return 0x2079;
case '+': return 0x207a;
case '-': return 0x207b;
case '=': return 0x207c;
case '(': return 0x207d;
case ')': return 0x207e;
case 'n': return 0x207f;
case 'h': return 0x02b0;
case 0x0266: return 0x02b1; // LATIN SMALL LETTER H WITH HOOK
case 'j': return 0x02b2;
case 'r': return 0x02b3;
case 0x0279: return 0x02b4; // LATIN SMALL LETTER TURNED R
case 0x027b: return 0x02b5; // LATIN SMALL LETTER TURNED R WITH HOOK
case 0x0281: return 0x02b6; // LATIN SMALL LETTER CAPITAL INVERTED R
case 'w': return 0x02b7;
case 'y': return 0x02b8;
// case 0x0294: return 0x02c0; // LATIN LETTER GLOTTAL STOP)
// case 0x0295: return 0x02c1; // LATIN LETTER PHARYNGEAL VOICED FRICATIVE
// (= LATIN LETTER REVERSED GLOTTAL STOP)
case 'l': return 0x02e1;
case 's': return 0x02e2;
case 'x': return 0x02e3;
// case 0x0295: return 0x02e4; // LATIN SMALL LETTER REVERSED GLOTTAL STOP
case 'A': return 0x1d2c;
case 0x00c6: return 0x1d2d; // LATIN CAPITAL LETTER AE
case 'B': return 0x1d2e;
case 'D': return 0x1d30;
case 'E': return 0x1d31;
case 'G': return 0x1d33;
case 'H': return 0x1d34;
case 'I': return 0x1d35;
case 'J': return 0x1d36;
case 'K': return 0x1d37;
case 'L': return 0x1d38;
case 'M': return 0x1d39;
case 'N': return 0x1d3a;
case 'O': return 0x1d3c;
case 'P': return 0x1d3e;
case 'R': return 0x1d3f;
case 'T': return 0x1d40;
case 'U': return 0x1d41;
case 'W': return 0x1d42;
case 'a': return 0x1d43;
case 0x0250: return 0x1d44; // LATIN SMALL LETTER TURNED A
case 0x0251: return 0x1d45; // LATIN SMALL LETTER ALPHA
case 'b': return 0x1d47;
case 'd': return 0x1d48;
case 'e': return 0x1d49;
case 0x0259: return 0x1d4a; // LATIN SMALL LETTER SCHWA
case 0x025b: return 0x1d4b; // LATIN SMALL LETTER OPEN E
case 0x1d08: return 0x1d4c; // LATIN SMALL LETTER TURNED OPEN E
case 'g': return 0x1d4d;
case 0x1d09: return 0x1d4e; // LATIN SMALL LETTER TURNED I
case 'k': return 0x1d4f;
case 'm': return 0x1d50;
case 0x014b: return 0x1d51; // LATIN SMALL LETTER ENG
case 'o': return 0x1d52;
case 0x0254: return 0x1d53; // LATIN SMALL LETTER OPEN O
case 0x1d16: return 0x1d54; // LATIN SMALL LETTER TOP HALF O
case 0x1d17: return 0x1d55; // LATIN SMALL LETTER BOTTOM HALF O
case 'p': return 0x1d56;
case 't': return 0x1d57;
case 'u': return 0x1d58;
case 0x1d1d: return 0x1d59; // LATIN SMALL LETTER SIDEWAYS U
case 0x1d1f: return 0x1d5a; // LATIN SMALL LETTER SIDEWAYS TURNED M
case 'v': return 0x1d5b;
case 0x03b2: return 0x1d5d; // GREEK SMALL LETTER BETA
case 0x03b3: return 0x1d5e; // GREEK SMALL LETTER GAMMA
case 0x03b4: return 0x1d5f; // GREEK SMALL LETTER DELTA
case 0x03c6: return 0x1d60; // GREEK SMALL LETTER PHI
case 0x03c7: return 0x1d61; // GREEK SMALL LETTER CHI
}
return c;
}
char_type subscript(char_type c)
{
switch (c) {
case 'i': return 0x1d62;
case 'r': return 0x1d63;
case 'u': return 0x1d64;
case 'v': return 0x1d65;
case 0x03b2: return 0x1d66; // GREEK SMALL LETTER BETA
case 0x03b3: return 0x1d67; // GREEK SMALL LETTER GAMMA
case 0x03c1: return 0x1d68; // GREEK SMALL LETTER RHO
case 0x03c6: return 0x1d69; // GREEK SMALL LETTER PHI
case 0x03c7: return 0x1d6a; // GREEK SMALL LETTER CHI
case '0': return 0x2080;
case '1': return 0x2081;
case '2': return 0x2082;
case '3': return 0x2083;
case '4': return 0x2084;
case '5': return 0x2085;
case '6': return 0x2086;
case '7': return 0x2087;
case '8': return 0x2088;
case '9': return 0x2089;
case '+': return 0x208a;
case '-': return 0x208b;
case '=': return 0x208c;
case '(': return 0x208d;
case ')': return 0x208e;
case 'a': return 0x2090;
case 'e': return 0x2091;
case 'o': return 0x2092;
case 'x': return 0x2093;
case 0x0259: return 0x2093; // LATIN SMALL LETTER SCHWA
}
return c;
}
bool prefixIs(docstring const & a, char_type c)
{
if (a.empty())
return false;
return a[0] == c;
}
bool prefixIs(string const & a, string const & pre)
{
size_t const prelen = pre.length();
size_t const alen = a.length();
return prelen <= alen && !a.empty() && a.compare(0, prelen, pre) == 0;
}
bool prefixIs(docstring const & a, docstring const & pre)
{
size_t const prelen = pre.length();
size_t const alen = a.length();
return prelen <= alen && !a.empty() && a.compare(0, prelen, pre) == 0;
}
bool suffixIs(string const & a, char c)
{
if (a.empty())
return false;
return a[a.length() - 1] == c;
}
bool suffixIs(docstring const & a, char_type c)
{
if (a.empty())
return false;
return a[a.length() - 1] == c;
}
bool suffixIs(string const & a, string const & suf)
{
size_t const suflen = suf.length();
size_t const alen = a.length();
return suflen <= alen && a.compare(alen - suflen, suflen, suf) == 0;
}
bool suffixIs(docstring const & a, docstring const & suf)
{
size_t const suflen = suf.length();
size_t const alen = a.length();
return suflen <= alen && a.compare(alen - suflen, suflen, suf) == 0;
}
bool containsOnly(string const & s, string const & cset)
{
return s.find_first_not_of(cset) == string::npos;
}
// ale970405+lasgoutt-970425
// rewritten to use new string (Lgb)
string const token(string const & a, char delim, int n)
{
if (a.empty())
return string();
size_t k = 0;
size_t i = 0;
// Find delimiter or end of string
for (; n--;) {
if ((i = a.find(delim, i)) == string::npos)
break;
else
++i; // step delim
}
// i is now the n'th delim (or string::npos)
if (i == string::npos)
return string();
k = a.find(delim, i);
// k is now the n'th + 1 delim (or string::npos)
return a.substr(i, k - i);
}
docstring const token(docstring const & a, char_type delim, int n)
{
if (a.empty())
return docstring();
size_t k = 0;
size_t i = 0;
// Find delimiter or end of string
for (; n--;) {
if ((i = a.find(delim, i)) == docstring::npos)
break;
else
++i; // step delim
}
// i is now the n'th delim (or string::npos)
if (i == docstring::npos)
return docstring();
k = a.find(delim, i);
// k is now the n'th + 1 delim (or string::npos)
return a.substr(i, k - i);
}
// this could probably be faster and/or cleaner, but it seems to work (JMarc)
// rewritten to use new string (Lgb)
int tokenPos(string const & a, char delim, string const & tok)
{
int i = 0;
string str = a;
string tmptok;
while (!str.empty()) {
str = split(str, tmptok, delim);
if (tok == tmptok)
return i;
++i;
}
return -1;
}
// this could probably be faster and/or cleaner, but it seems to work (JMarc)
// rewritten to use new string (Lgb)
int tokenPos(docstring const & a, char_type delim, docstring const & tok)
{
int i = 0;
docstring str = a;
docstring tmptok;
while (!str.empty()) {
str = split(str, tmptok, delim);
if (tok == tmptok)
return i;
++i;
}
return -1;
}
namespace {
/// Substitute all \a oldchar with \a newchar
template<typename Ch> inline
basic_string<Ch> const subst_char(basic_string<Ch> const & a,
Ch oldchar, Ch newchar)
{
typedef basic_string<Ch> String;
String tmp(a);
typename String::iterator lit = tmp.begin();
typename String::iterator end = tmp.end();
for (; lit != end; ++lit)
if ((*lit) == oldchar)
(*lit) = newchar;
return tmp;
}
/// Substitute all \a oldchar with \a newchar
docstring const subst_char(docstring const & a,
docstring::value_type oldchar, docstring::value_type newchar)
{
docstring tmp(a);
docstring::iterator lit = tmp.begin();
docstring::iterator end = tmp.end();
for (; lit != end; ++lit)
if ((*lit) == oldchar)
(*lit) = newchar;
return tmp;
}
/// substitutes all instances of \a oldstr with \a newstr
template<typename String> inline
String const subst_string(String const & a,
String const & oldstr, String const & newstr)
{
LASSERT(!oldstr.empty(), /**/);
String lstr = a;
size_t i = 0;
size_t const olen = oldstr.length();
while ((i = lstr.find(oldstr, i)) != string::npos) {
lstr.replace(i, olen, newstr);
i += newstr.length(); // We need to be sure that we dont
// use the same i over and over again.
}
return lstr;
}
docstring const subst_string(docstring const & a,
docstring const & oldstr, docstring const & newstr)
{
LASSERT(!oldstr.empty(), /**/);
docstring lstr = a;
size_t i = 0;
size_t const olen = oldstr.length();
while ((i = lstr.find(oldstr, i)) != string::npos) {
lstr.replace(i, olen, newstr);
i += newstr.length(); // We need to be sure that we dont
// use the same i over and over again.
}
return lstr;
}
}
string const subst(string const & a, char oldchar, char newchar)
{
return subst_char(a, oldchar, newchar);
}
docstring const subst(docstring const & a,
char_type oldchar, char_type newchar)
{
return subst_char(a, oldchar, newchar);
}
string const subst(string const & a,
string const & oldstr, string const & newstr)
{
return subst_string(a, oldstr, newstr);
}
docstring const subst(docstring const & a,
docstring const & oldstr, docstring const & newstr)
{
return subst_string(a, oldstr, newstr);
}
/// Count all occurences of char \a chr inside \a str
int count_char(docstring const & str, docstring::value_type chr)
{
int count = 0;
docstring::const_iterator lit = str.begin();
docstring::const_iterator end = str.end();
for (; lit != end; ++lit)
if ((*lit) == chr)
count++;
return count;
}
docstring const trim(docstring const & a, char const * p)
{
LASSERT(p, /**/);
if (a.empty() || !*p)
return a;
docstring s = from_ascii(p);
size_t r = a.find_last_not_of(s);
size_t l = a.find_first_not_of(s);
// Is this the minimal test? (lgb)
if (r == docstring::npos && l == docstring::npos)
return docstring();
return a.substr(l, r - l + 1);
}
string const trim(string const & a, char const * p)
{
LASSERT(p, /**/);
if (a.empty() || !*p)
return a;
size_t r = a.find_last_not_of(p);
size_t l = a.find_first_not_of(p);
// Is this the minimal test? (lgb)
if (r == string::npos && l == string::npos)
return string();
return a.substr(l, r - l + 1);
}
string const rtrim(string const & a, char const * p)
{
LASSERT(p, /**/);
if (a.empty() || !*p)
return a;
size_t r = a.find_last_not_of(p);
// Is this test really needed? (Lgb)
if (r == string::npos)
return string();
return a.substr(0, r + 1);
}
docstring const rtrim(docstring const & a, char const * p)
{
LASSERT(p, /**/);
if (a.empty() || !*p)
return a;
size_t r = a.find_last_not_of(from_ascii(p));
// Is this test really needed? (Lgb)
if (r == docstring::npos)
return docstring();
return a.substr(0, r + 1);
}
string const ltrim(string const & a, char const * p)
{
LASSERT(p, /**/);
if (a.empty() || !*p)
return a;
size_t l = a.find_first_not_of(p);
if (l == string::npos)
return string();
return a.substr(l, string::npos);
}
docstring const ltrim(docstring const & a, char const * p)
{
LASSERT(p, /**/);
if (a.empty() || !*p)
return a;
size_t l = a.find_first_not_of(from_ascii(p));
if (l == docstring::npos)
return docstring();
return a.substr(l, docstring::npos);
}
namespace {
template<typename String, typename Char> inline
String const doSplit(String const & a, String & piece, Char delim)
{
String tmp;
size_t i = a.find(delim);
if (i == a.length() - 1) {
piece = a.substr(0, i);
} else if (i != String::npos) {
piece = a.substr(0, i);
tmp = a.substr(i + 1);
} else if (i == 0) {
piece.erase();
tmp = a.substr(i + 1);
} else {
piece = a;
}
return tmp;
}
template<typename Char> inline
docstring const doSplit(docstring const & a, docstring & piece, Char delim)
{
docstring tmp;
size_t i = a.find(delim);
if (i == a.length() - 1) {
piece = a.substr(0, i);
} else if (i != docstring::npos) {
piece = a.substr(0, i);
tmp = a.substr(i + 1);
} else if (i == 0) {
piece.erase();
tmp = a.substr(i + 1);
} else {
piece = a;
}
return tmp;
}
} // anon
string const split(string const & a, string & piece, char delim)
{
return doSplit(a, piece, delim);
}
docstring const split(docstring const & a, docstring & piece, char_type delim)
{
return doSplit(a, piece, delim);
}
string const split(string const & a, char delim)
{
string tmp;
size_t i = a.find(delim);
if (i != string::npos) // found delim
tmp = a.substr(i + 1);
return tmp;
}
// ale970521
string const rsplit(string const & a, string & piece, char delim)
{
string tmp;
size_t i = a.rfind(delim);
if (i != string::npos) { // delimiter was found
piece = a.substr(0, i);
tmp = a.substr(i + 1);
} else { // delimiter was not found
piece.erase();
}
return tmp;
}
docstring const rsplit(docstring const & a, char_type delim)
{
docstring tmp;
size_t i = a.rfind(delim);
if (i != string::npos)
tmp = a.substr(i + 1);
return tmp;
}
docstring const escape(docstring const & lab)
{
char_type hexdigit[16] = { '0', '1', '2', '3', '4', '5', '6', '7',
'8', '9', 'A', 'B', 'C', 'D', 'E', 'F' };
docstring enc;
for (size_t i = 0; i < lab.length(); ++i) {
char_type c = lab[i];
if (c >= 128 || c == '=' || c == '%') {
// Although char_type is a 32 bit type we know that
// UCS4 occupies only 21 bits, so we don't need to
// encode bigger values. Test for 2^24 because we
// can encode that with the 6 hex digits that are
// needed for 21 bits anyway.
LASSERT(c < (1 << 24), /**/);
enc += '=';
enc += hexdigit[(c>>20) & 15];
enc += hexdigit[(c>>16) & 15];
enc += hexdigit[(c>>12) & 15];
enc += hexdigit[(c>> 8) & 15];
enc += hexdigit[(c>> 4) & 15];
enc += hexdigit[ c & 15];
} else {
enc += c;
}
}
return enc;
}
namespace {
// this doesn't check whether str is empty, so do that first.
vector<docstring> wrapToVec(docstring const & str, int ind,
size_t const width)
{
docstring s = trim(str);
if (s.empty())
return vector<docstring>();
docstring indent;
if (ind < 0) {
indent.insert(0, -ind, ' ');
ind = 0;
} else if (ind > 0)
s.insert(0, ind, ' ');
vector<docstring> retval;
while (s.size() > width) {
// find the last space within the first 'width' chars
size_t const i = s.find_last_of(' ', width - 1);
if (i == docstring::npos || i <= size_t(ind)) {
// no space found
s = s.substr(0, width - 3) + "...";
break;
}
retval.push_back(s.substr(0, i));
s = indent + s.substr(i);
ind = indent.size();
}
if (!s.empty())
retval.push_back(s);
return retval;
}
}
docstring wrap(docstring const & str, int const ind, size_t const width)
{
docstring s = trim(str);
if (s.empty())
return docstring();
vector<docstring> const svec = wrapToVec(str, ind, width);
return getStringFromVector(svec, from_ascii("\n"));
}
docstring wrapParas(docstring const & str, int const indent,
size_t const width, size_t const maxlines)
{
docstring const dots = from_ascii("...");
if (str.empty())
return docstring();
vector<docstring> const pars = getVectorFromString(str, from_ascii("\n"), true);
vector<docstring> retval;
vector<docstring>::const_iterator it = pars.begin();
vector<docstring>::const_iterator const en = pars.end();
for (; it != en; ++it) {
vector<docstring> tmp = wrapToVec(*it, indent, width);
size_t const nlines = tmp.size();
if (nlines == 0)
continue;
size_t const curlines = retval.size();
if (maxlines > 0 && curlines + nlines > maxlines) {
tmp.resize(maxlines - curlines);
docstring last = tmp.back();
size_t const lsize = last.size();
if (lsize > width - 3) {
size_t const i = last.find_last_of(' ', width - 3);
if (i == docstring::npos || i <= size_t(indent))
// no space found
last = last.substr(0, lsize - 3) + dots;
else
last = last.substr(0, i) + dots;
} else
last += dots;
tmp.pop_back();
tmp.push_back(last);
}
retval.insert(retval.end(), tmp.begin(), tmp.end());
if (maxlines > 0 && retval.size() >= maxlines)
break;
}
return getStringFromVector(retval, from_ascii("\n"));
}
namespace {
template<typename String> vector<String> const
getVectorFromStringT(String const & str, String const & delim, bool keepempty)
{
// Lars would like this code to go, but for now his replacement (below)
// doesn't fullfil the same function. I have, therefore, reactivated the
// old code for now. Angus 11 Nov 2002.
#if 1
vector<String> vec;
if (str.empty())
return vec;
String keys = rtrim(str);
while (true) {
size_t const idx = keys.find(delim);
if (idx == String::npos) {
vec.push_back(ltrim(keys));
break;
}
String const key = trim(keys.substr(0, idx));
if (!key.empty() || keepempty)
vec.push_back(key);
size_t const start = idx + delim.size();
keys = keys.substr(start);
}
return vec;
#else
typedef boost::char_separator<typename String::value_type> Separator;
typedef boost::tokenizer<Separator, typename String::const_iterator, String> Tokenizer;
Separator sep(delim.c_str());
Tokenizer tokens(str, sep);
return vector<String>(tokens.begin(), tokens.end());
#endif
}
template<typename String> const String
getStringFromVector(vector<String> const & vec, String const & delim)
{
String str;
typename vector<String>::const_iterator it = vec.begin();
typename vector<String>::const_iterator en = vec.end();
for (; it != en; ++it) {
String item = trim(*it);
if (item.empty())
continue;
if (!str.empty())
str += delim;
str += item;
}
return str;
}
} // namespace anon
vector<string> const getVectorFromString(string const & str,
string const & delim,
bool keepempty)
{
return getVectorFromStringT<string>(str, delim, keepempty);
}
vector<docstring> const getVectorFromString(docstring const & str,
docstring const & delim,
bool keepempty)
{
return getVectorFromStringT<docstring>(str, delim, keepempty);
}
string const getStringFromVector(vector<string> const & vec,
string const & delim)
{
return getStringFromVector<string>(vec, delim);
}
docstring const getStringFromVector(vector<docstring> const & vec,
docstring const & delim)
{
return getStringFromVector<docstring>(vec, delim);
}
int findToken(char const * const str[], string const & search_token)
{
int i = 0;
while (str[i][0] && str[i] != search_token)
++i;
if (!str[i][0])
i = -1;
return i;
}
string const languageTestString()
{
return N_("[[Replace with the code of your language]]");
}
template<>
docstring bformat(docstring const & fmt, int arg1)
{
LASSERT(contains(fmt, from_ascii("%1$d")), /**/);
docstring const str = subst(fmt, from_ascii("%1$d"), convert<docstring>(arg1));
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, long arg1)
{
LASSERT(contains(fmt, from_ascii("%1$d")), /**/);
docstring const str = subst(fmt, from_ascii("%1$d"), convert<docstring>(arg1));
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, unsigned int arg1)
{
LASSERT(contains(fmt, from_ascii("%1$d")), /**/);
docstring const str = subst(fmt, from_ascii("%1$d"), convert<docstring>(arg1));
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, docstring arg1)
{
LASSERT(contains(fmt, from_ascii("%1$s")), /**/);
docstring const str = subst(fmt, from_ascii("%1$s"), arg1);
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, char * arg1)
{
LASSERT(contains(fmt, from_ascii("%1$s")), /**/);
docstring const str = subst(fmt, from_ascii("%1$s"), from_ascii(arg1));
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, docstring arg1, docstring arg2)
{
LASSERT(contains(fmt, from_ascii("%1$s")), /**/);
LASSERT(contains(fmt, from_ascii("%2$s")), /**/);
docstring str = subst(fmt, from_ascii("%1$s"), arg1);
str = subst(str, from_ascii("%2$s"), arg2);
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, docstring arg1, int arg2)
{
LASSERT(contains(fmt, from_ascii("%1$s")), /**/);
LASSERT(contains(fmt, from_ascii("%2$d")), /**/);
docstring str = subst(fmt, from_ascii("%1$s"), arg1);
str = subst(str, from_ascii("%2$d"), convert<docstring>(arg2));
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, char const * arg1, docstring arg2)
{
LASSERT(contains(fmt, from_ascii("%1$s")), /**/);
LASSERT(contains(fmt, from_ascii("%2$s")), /**/);
docstring str = subst(fmt, from_ascii("%1$s"), from_ascii(arg1));
str = subst(fmt, from_ascii("%2$s"), arg2);
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, int arg1, int arg2)
{
LASSERT(contains(fmt, from_ascii("%1$d")), /**/);
LASSERT(contains(fmt, from_ascii("%2$d")), /**/);
docstring str = subst(fmt, from_ascii("%1$d"), convert<docstring>(arg1));
str = subst(str, from_ascii("%2$d"), convert<docstring>(arg2));
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt, docstring arg1, docstring arg2, docstring arg3)
{
LASSERT(contains(fmt, from_ascii("%1$s")), /**/);
LASSERT(contains(fmt, from_ascii("%2$s")), /**/);
LASSERT(contains(fmt, from_ascii("%3$s")), /**/);
docstring str = subst(fmt, from_ascii("%1$s"), arg1);
str = subst(str, from_ascii("%2$s"), arg2);
str = subst(str, from_ascii("%3$s"), arg3);
return subst(str, from_ascii("%%"), from_ascii("%"));
}
template<>
docstring bformat(docstring const & fmt,
docstring arg1, docstring arg2, docstring arg3, docstring arg4)
{
LASSERT(contains(fmt, from_ascii("%1$s")), /**/);
LASSERT(contains(fmt, from_ascii("%2$s")), /**/);
LASSERT(contains(fmt, from_ascii("%3$s")), /**/);
LASSERT(contains(fmt, from_ascii("%4$s")), /**/);
docstring str = subst(fmt, from_ascii("%1$s"), arg1);
str = subst(str, from_ascii("%2$s"), arg2);
str = subst(str, from_ascii("%3$s"), arg3);
str = subst(str, from_ascii("%4$s"), arg4);
return subst(str, from_ascii("%%"), from_ascii("%"));
}
} // namespace support
} // namespace lyx