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// file : libbutl/regex.txx -*- C++ -*-
// license : MIT; see accompanying LICENSE file
LIBBUTL_MODEXPORT namespace butl //@@ MOD Clang needs this for some reason.
{
template <typename C>
std::basic_string<C>
regex_replace_match_results (
const std::match_results<typename std::basic_string<C>::const_iterator>& m,
const C* fmt, std::size_t n)
{
using namespace std;
using string_type = basic_string<C>;
using str_it = typename string_type::const_iterator;
string_type r;
// Note that we are using char type literals with the assumption that
// being ASCII characters they will be properly "widened" to the
// corresponding literals of the C template parameter type.
//
auto digit = [] (C c) -> int
{
return c >= '0' && c <= '9' ? c - '0' : -1;
};
enum class case_conv {none, upper, lower, upper_once, lower_once}
mode (case_conv::none);
locale cl; // Copy of the global C++ locale.
auto conv_chr = [&mode, &cl] (C c) -> C
{
switch (mode)
{
case case_conv::upper_once: mode = case_conv::none; // Fall through.
case case_conv::upper: c = toupper (c, cl); break;
case case_conv::lower_once: mode = case_conv::none; // Fall through.
case case_conv::lower: c = tolower (c, cl); break;
case case_conv::none: break;
}
return c;
};
auto append_chr = [&r, &conv_chr] (C c) {r.push_back (conv_chr (c));};
auto append_str = [&r, &mode, &conv_chr] (str_it b, str_it e)
{
// Optimize for the common case.
//
if (mode == case_conv::none)
r.append (b, e);
else
{
for (str_it i (b); i != e; ++i)
r.push_back (conv_chr (*i));
}
};
for (size_t i (0); i < n; ++i)
{
C c (fmt[i]);
switch (c)
{
case '$':
{
// Check if this is a $-based escape sequence. Interpret it
// accordingly if that's the case, treat '$' as a regular character
// otherwise.
//
c = fmt[++i]; // '\0' if last.
switch (c)
{
case '$': append_chr (c); break;
case '&': append_str (m[0].first, m[0].second); break;
case '`':
{
append_str (m.prefix ().first, m.prefix ().second);
break;
}
case '\'':
{
append_str (m.suffix ().first, m.suffix ().second);
break;
}
default:
{
// Check if this is a sub-expression 1-based index ($n or $nn).
// Append the matching substring if that's the case. Treat '$'
// as a regular character otherwise. Index greater than the
// sub-expression count is silently ignored.
//
int si (digit (c));
if (si >= 0)
{
int d;
if ((d = digit (fmt[i + 1])) >= 0) // '\0' if last.
{
si = si * 10 + d;
++i;
}
}
if (si > 0)
{
// m[0] refers to the matched substring. Note that we ignore
// unmatched sub-expression references.
//
if (static_cast<size_t> (si) < m.size () && m[si].matched)
append_str (m[si].first, m[si].second);
}
else
{
// Not a $-based escape sequence so treat '$' as a regular
// character.
//
--i;
append_chr ('$');
}
break;
}
}
break;
}
case '\\':
{
c = fmt[++i]; // '\0' if last.
switch (c)
{
case '\\': append_chr (c); break;
case 'n': append_chr ('\n'); break;
case 'u': mode = case_conv::upper_once; break;
case 'l': mode = case_conv::lower_once; break;
case 'U': mode = case_conv::upper; break;
case 'L': mode = case_conv::lower; break;
case 'E': mode = case_conv::none; break;
default:
{
// Check if this is a sub-expression 1-based index. Append the
// matching substring if that's the case, Skip '\\' otherwise.
// Index greater than the sub-expression count is silently
// ignored.
//
int si (digit (c));
if (si > 0)
{
// m[0] refers to the matched substring. Note that we ignore
// unmatched sub-expression references.
//
if (static_cast<size_t> (si) < m.size () && m[si].matched)
append_str (m[si].first, m[si].second);
}
else
--i;
break;
}
}
break;
}
default:
{
// Append a regular character.
//
append_chr (c);
break;
}
}
}
return r;
}
template <typename C>
std::pair<std::basic_string<C>, bool>
regex_replace_match (const std::basic_string<C>& s,
const std::basic_regex<C>& re,
const std::basic_string<C>& fmt)
{
using namespace std;
using string_type = basic_string<C>;
using str_it = typename string_type::const_iterator;
match_results<str_it> m;
bool match (regex_match (s, m, re));
return make_pair (match ? regex_replace_match_results (m, fmt) : string (),
match);
}
template <typename C, typename F>
bool
regex_replace_search (const std::basic_string<C>& s,
const std::basic_regex<C>& re,
const std::basic_string<C>& fmt,
F&& append,
std::regex_constants::match_flag_type flags)
{
using namespace std;
using string_type = basic_string<C>;
using str_it = typename string_type::const_iterator;
using regex_it = regex_iterator<str_it>;
bool first_only ((flags & regex_constants::format_first_only) != 0);
bool no_copy ((flags & regex_constants::format_no_copy) != 0);
// Beginning of the last unmatched substring.
//
str_it ub (s.begin ());
regex_it b (s.begin (), s.end (), re, flags);
regex_it e;
bool match (b != e);
// For libc++, the end-of-sequence regex iterator can never be reached
// for some regular expressions (LLVM bug #33681). We will check if the
// matching sequence start is the same as the one for the previous match
// and bail out if that's the case.
//
#if defined(_LIBCPP_VERSION) && _LIBCPP_VERSION <= 4000
str_it pm;
#endif
for (regex_it i (b); i != e; ++i)
{
const match_results<str_it>& m (*i);
#if defined(_LIBCPP_VERSION) && _LIBCPP_VERSION <= 4000
if (i != b && m[0].first == pm)
break;
pm = m[0].first;
#endif
// Copy the preceeding unmatched substring, save the beginning of the
// one that follows.
//
if (!no_copy)
{
append (ub, m.prefix ().second);
ub = m.suffix ().first;
}
if (first_only && i != b)
{
// Append matched substring.
//
if (!no_copy)
append (m[0].first, m[0].second);
}
else
{
// The standard implementation calls m.format() here. We perform our
// own formatting.
//
string_type r (regex_replace_match_results (m, fmt));
append (r.begin (), r.end ());
}
}
// Append the rightmost non-matched substring.
//
if (!no_copy)
append (ub, s.end ());
return match;
}
template <typename C>
std::pair<std::basic_regex<C>, std::basic_string<C>>
regex_replace_parse (const C* s, size_t n,
std::regex_constants::syntax_option_type f)
{
using namespace std;
using string_type = basic_string<C>;
size_t e;
pair<string_type, string_type> r (regex_replace_parse (s, n, e));
if (e != n)
throw invalid_argument ("junk after trailing delimiter");
return make_pair (basic_regex<C> (r.first, f), move (r.second));
}
template <typename C>
std::pair<std::basic_string<C>, std::basic_string<C>>
regex_replace_parse (const C* s, size_t n, size_t& e)
{
using namespace std;
using string_type = basic_string<C>;
if (n == 0)
throw invalid_argument ("no leading delimiter");
const C* b (s); // Save the beginning of the string.
char delim (s[0]);
// Position to the regex first character and find the regex-terminating
// delimiter.
//
--n;
++s;
const C* p (string_type::traits_type::find (s, n, delim));
if (p == nullptr)
throw invalid_argument ("no delimiter after regex");
// Empty regex matches nothing, so not of much use.
//
if (p == s)
throw invalid_argument ("empty regex");
// Save the regex.
//
string_type re (s, p - s);
// Position to the format first character and find the trailing delimiter.
//
n -= p - s + 1;
s = p + 1;
p = string_type::traits_type::find (s, n, delim);
if (p == nullptr)
throw invalid_argument ("no delimiter after replacement");
e = p - b + 1;
return make_pair (move (re), string_type (s, p - s));
}
}
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