tests/localization/22.locale.moneypunct.mt.cpp - stdcxx - Git at Google

 /************************************************************************
  *
  * 22.locale.moneypunct.mt.cpp
  *
  * test exercising the thread safety of the moneypunct facet
  *
  * $Id$
  *
  ***************************************************************************
  *
  * Licensed to the Apache Software  Foundation (ASF) under one or more
  * contributor  license agreements.  See  the NOTICE  file distributed
  * with  this  work  for  additional information  regarding  copyright
  * ownership.   The ASF  licenses this  file to  you under  the Apache
  * License, Version  2.0 (the  "License"); you may  not use  this file
  * except in  compliance with the License.   You may obtain  a copy of
  * the License at
  *
  * http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the  License is distributed on an  "AS IS" BASIS,
  * WITHOUT  WARRANTIES OR CONDITIONS  OF ANY  KIND, either  express or
  * implied.   See  the License  for  the  specific language  governing
  * permissions and limitations under the License.
  *
  **************************************************************************/

 #include <ios>        // for ios
 #include <locale>     // for locale, moneypunct

 #include <clocale>    // for lconv, localeconv()
 #include <cstdlib>    // for mbstowcs()
 #include <cstring>    // for size_t, strcpy()

 #include <rw_locale.h>
 #include <rw_thread.h>
 #include <driver.h>
 #include <valcmp.h>


 // maximum number of threads allowed by the command line interface
 #define MAX_THREADS   32


 #ifdef _RWSTD_REENTRANT
 int rw_opt_nthreads = 4;
 #else   // if !defined (_RWSTD_REENTRANT)
 // in non-threaded builds use just one thread
 int rw_opt_nthreads = 1;
 #endif   // _RWSTD_REENTRANT

 // the number of times each thread should iterate (unless specified
 // otherwise on the command line)
 int rw_opt_nloops = 200000;

 /**************************************************************************/

 // number of locales to test
 static std::size_t
 nlocales;

 /**************************************************************************/

 struct MoneypunctData
 {
     // the name of the locale the data goes with
     const char* locale_name_;

     char decimal_point_;
     char thousands_sep_;
     char grouping_ [32];
     char curr_symbol_ [32];
     char positive_sign_ [32];
     char negative_sign_ [32];
     int  frac_digits_;
     char pos_format_ [32];
     char neg_format_ [32];

     char int_curr_symbol_ [32];

     int  int_frac_digits_;
     char int_pos_format_ [32];
     char int_neg_format_ [32];

 #ifndef _RWSTD_NO_WCHAR_T

     wchar_t wdecimal_point_;
     wchar_t wthousands_sep_;
     wchar_t wcurr_symbol_ [32];
     wchar_t wpositive_sign_ [32];
     wchar_t wnegative_sign_ [32];

     wchar_t wint_curr_symbol_ [32];

 #endif   // _RWSTD_NO_WCHAR_T

 } punct_data [MAX_THREADS];


 extern "C" {

 bool test_char;    // exercise num_put<char>
 bool test_wchar;   // exercise num_put<wchar_t>


 static void*
 thread_func (void*)
 {
     for (int i = 0; i != rw_opt_nloops; ++i) {

         const std::size_t inx = std::size_t (i) % nlocales;

         const MoneypunctData* const data = punct_data + inx;

         // construct a named locale
         const std::locale loc (data->locale_name_);

         if (test_char) {
             // exercise the narrow char, local specialization of the facet

             typedef std::moneypunct<char, false> Punct;

             const Punct &mp = std::use_facet<Punct>(loc);

             const char           dp  = mp.decimal_point ();
             const char           ts  = mp.thousands_sep ();
             const std::string    grp = mp.grouping ();
             const std::string    cur = mp.curr_symbol ();
             const std::string    pos = mp.positive_sign ();
             const std::string    neg = mp.negative_sign ();
             const int            fd  = mp.frac_digits ();
             const Punct::pattern pfm = mp.pos_format ();
             const Punct::pattern nfm = mp.neg_format ();

             RW_ASSERT (dp == data->decimal_point_);
             RW_ASSERT (ts == data->thousands_sep_);
             RW_ASSERT (fd == data->frac_digits_);
             RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
             RW_ASSERT (!rw_strncmp (cur.c_str (), data->curr_symbol_));
             RW_ASSERT (!rw_strncmp (pos.c_str (), data->positive_sign_));
             RW_ASSERT (!rw_strncmp (neg.c_str (), data->negative_sign_));

             RW_ASSERT (!std::memcmp (&pfm, data->pos_format_, 4));
             RW_ASSERT (!std::memcmp (&nfm, data->neg_format_, 4));
         }

         if (test_char) {
             // exercise the narrow char, international specialization

             typedef std::moneypunct<char, true> Punct;

             const Punct &mp = std::use_facet<Punct>(loc);

             const char           dp  = mp.decimal_point ();
             const char           ts  = mp.thousands_sep ();
             const std::string    grp = mp.grouping ();
             const std::string    cur = mp.curr_symbol ();
             const std::string    pos = mp.positive_sign ();
             const std::string    neg = mp.negative_sign ();
             const int            fd  = mp.frac_digits ();
             const Punct::pattern pfm = mp.pos_format ();
             const Punct::pattern nfm = mp.neg_format ();

             RW_ASSERT (dp == data->decimal_point_);
             RW_ASSERT (ts == data->thousands_sep_);
             RW_ASSERT (fd == data->frac_digits_);
             RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
             RW_ASSERT (!rw_strncmp (cur.c_str (), data->int_curr_symbol_));
             RW_ASSERT (!rw_strncmp (pos.c_str (), data->positive_sign_));
             RW_ASSERT (!rw_strncmp (neg.c_str (), data->negative_sign_));

             RW_ASSERT (!std::memcmp (&pfm, data->int_pos_format_, 4));
             RW_ASSERT (!std::memcmp (&nfm, data->int_neg_format_, 4));
         }

         // both specializations may be tested at the same time

 #ifndef _RWSTD_NO_WCHAR_T

         if (test_wchar) {
             // exercise the wide char, local specialization of the facet

             typedef std::moneypunct<wchar_t, false> Punct;

             const Punct &mp = std::use_facet<Punct>(loc);

             const char           dp  = mp.decimal_point ();
             const char           ts  = mp.thousands_sep ();
             const std::string    grp = mp.grouping ();
             const std::wstring   cur = mp.curr_symbol ();
             const std::wstring   pos = mp.positive_sign ();
             const std::wstring   neg = mp.negative_sign ();
             const int            fd  = mp.frac_digits ();
             const Punct::pattern pfm = mp.pos_format ();
             const Punct::pattern nfm = mp.neg_format ();

             RW_ASSERT (dp == data->wdecimal_point_);
             RW_ASSERT (ts == data->wthousands_sep_);
             RW_ASSERT (fd == data->frac_digits_);
             RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
             RW_ASSERT (!rw_strncmp (cur.c_str (), data->wcurr_symbol_));
             RW_ASSERT (!rw_strncmp (pos.c_str (), data->wpositive_sign_));
             RW_ASSERT (!rw_strncmp (neg.c_str (), data->wnegative_sign_));

             RW_ASSERT (!std::memcmp (&pfm, data->pos_format_, 4));
             RW_ASSERT (!std::memcmp (&nfm, data->neg_format_, 4));
         }

         if (test_wchar) {
             // exercise the wide char, international specialization

             typedef std::moneypunct<wchar_t, true> Punct;

             const Punct &mp = std::use_facet<Punct>(loc);

             const char           dp  = mp.decimal_point ();
             const char           ts  = mp.thousands_sep ();
             const std::string    grp = mp.grouping ();
             const std::wstring   cur = mp.curr_symbol ();
             const std::wstring   pos = mp.positive_sign ();
             const std::wstring   neg = mp.negative_sign ();
             const int            fd  = mp.frac_digits ();
             const Punct::pattern pfm = mp.pos_format ();
             const Punct::pattern nfm = mp.neg_format ();

             RW_ASSERT (dp == data->wdecimal_point_);
             RW_ASSERT (ts == data->wthousands_sep_);
             RW_ASSERT (fd == data->frac_digits_);
             RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
             RW_ASSERT (!rw_strncmp (cur.c_str (), data->wint_curr_symbol_));
             RW_ASSERT (!rw_strncmp (pos.c_str (), data->wpositive_sign_));
             RW_ASSERT (!rw_strncmp (neg.c_str (), data->wnegative_sign_));

             RW_ASSERT (!std::memcmp (&pfm, data->int_pos_format_, 4));
             RW_ASSERT (!std::memcmp (&nfm, data->int_neg_format_, 4));
         }

 #endif   // _RWSTD_NO_WCHAR_T

     }

     return 0;
 }

 }   // extern "C"

 /**************************************************************************/

 static void
 get_format (MoneypunctData *pdata, const std::lconv *pconv)
 {
     // code copied from src/punct.cpp

     enum {
         // for syntactic convenience
         none   = std::money_base::none,
         space  = std::money_base::space,
         symbol = std::money_base::symbol,
         sign   = std::money_base::sign,
         value  = std::money_base::value
     };

     static const std::money_base::pattern pat[] = {

         // cs_precedes [0..1]:
         //
         // An integer set to 1 if the currency_symbol precedes the value
         // for a monetary value, and set to 0 if the symbol succeeds
         // the value.

         // sep_by_space [0..2]:
         //
         // 0  No space separates the currency_symbol from the value for
         //    a monetary value.
         // 1  If the currency symbol and sign string are adjacent, a space
         //    separates them from the value; otherwise, a space separates
         //    the currency symbol from the value.
         // 2  If the currency symbol and sign string are adjacent, a space
         //    separates them; otherwise, a space separates the sign string
         //    from the value.

         // sign_posn [0..4]:
         //
         // An integer set to a value indicating the positioning of the
         // positive_sign for a monetary value. The following integer
         // values shall be recognized:
         //
         // 0  Parentheses enclose the value and the currency_symbol.
         // 1  The sign string precedes the value and the currency_symbol.
         // 2  The sign string succeeds the value and the currency_symbol.
         // 3  The sign string immediately precedes the currency_symbol.
         // 4  The sign string immediately succeeds the currency_symbol.

         // +-------- cs_precedes
         // |+----- sep_by_space
         // ||+-- sign_posn
         // |||
         // VVV  ....        -     1      $       .           // pattern
         /* 000: -1$. */ { { sign, value, symbol, none } },   // "\3\4\2\0"
         /* 001: -1$. */ { { sign, value, symbol, none } },   // "\3\4\2\0"
         /* 002: 1$-. */ { { value, symbol, sign, none } },   // "\4\2\3\0"
         /* 003: 1-$. */ { { value, sign, symbol, none } },   // "\4\3\2\0"
         /* 004: 1$-. */ { { value, symbol, sign, none } },   // "\4\2\3\0"

         /* 010: -1 $ */ { { sign, value, space, symbol } },  // "\3\4\1\2"
         /* 011: -1 $ */ { { sign, value, space, symbol } },  // "\3\4\1\2"
         /* 012: 1 $- */ { { value, space, symbol, sign } },  // "\4\1\2\3"
         /* 013: 1 -$ */ { { value, space, sign, symbol } },  // "\4\3\3\2"
         /* 014: 1 $- */ { { value, space, symbol, sign } },  // "\4\1\2\3"

         /* 020: - 1$ */ { { sign, space, value, symbol } },  // "\3\1\4\2"
         /* 021: - 1$ */ { { sign, space, value, symbol } },  // "\3\1\4\2"
         /* 022: 1$ - */ { { value, symbol, space, sign } },  // "\4\2\1\3"
         /* 023: 1- $ */ { { value, sign, space, symbol } },  // "\4\3\1\2"
         /* 024: 1$ - */ { { value, symbol, space, sign } },  // "\4\2\1\3"

         /* 100: -$1. */ { { sign, symbol, value, none } },   // "\3\2\4\0"
         /* 101: -$1. */ { { sign, symbol, value, none } },   // "\3\2\4\0"
         /* 102: $1-. */ { { symbol, value, sign, none } },   // "\2\4\3\0"
         /* 103: -$1. */ { { sign, symbol, value, none } },   // "\3\2\4\0"
         /* 104: $-1. */ { { symbol, sign, value, none } },   // "\2\3\4\0"

         /* 110: -$ 1 */ { { sign, symbol, space, value } },  // "\3\2\1\4"
         /* 111: -$ 1 */ { { sign, symbol, space, value } },  // "\3\2\1\4"
         /* 112: $ 1- */ { { symbol, space, value, sign } },  // "\2\1\4\3"
         /* 113: -$ 1 */ { { sign, symbol, space, value } },  // "\3\2\1\4"
         /* 114: $- 1 */ { { symbol, sign, space, value } },  // "\2\3\1\4"

         /* 120: - $1 */ { { sign, space, symbol, value } },  // "\3\1\2\4"
         /* 121: - $1 */ { { sign, space, symbol, value } },  // "\3\1\2\4"
         /* 122: $1 - */ { { symbol, value, space, sign } },  // "\2\4\1\3"
         /* 123: - $1 */ { { sign, space, symbol, value } },  // "\3\1\2\4"
         /* 124: $ -1 */ { { symbol, space, sign, value } }   // "\2\1\3\4"
     };

     std::size_t inx;

     inx =   std::size_t (pconv->p_cs_precedes) * (3U * 5U)
           + std::size_t (pconv->p_sep_by_space) * 5U
           + std::size_t (pconv->p_sign_posn);

     if (inx < sizeof pat / sizeof *pat)
         std::memcpy (pdata->pos_format_, pat + inx, sizeof *pat);
     else
         std::memset (pdata->pos_format_, none, sizeof *pat);

     inx =   std::size_t (pconv->n_cs_precedes) * (3U * 5U)
           + std::size_t (pconv->n_sep_by_space) * 5U
           + std::size_t (pconv->n_sign_posn);

     if (inx < sizeof pat / sizeof *pat)
         std::memcpy (pdata->neg_format_, pat + inx, sizeof *pat);
     else
         std::memset (pdata->neg_format_, none, sizeof *pat);


 #ifndef _RWSTD_NO_LCONV_INT_FMAT

     inx =   std::size_t (pconv->int_p_cs_precedes) * (3U * 5U)
           + std::size_t (pconv->int_p_sep_by_space) * 5U
           + std::size_t (pconv->int_p_sign_posn);

     if (inx < sizeof pat / sizeof *pat)
         std::memcpy (pdata->int_pos_format_, pat + inx, sizeof *pat);
     else
         std::memset (pdata->int_pos_format_, none, sizeof *pat);

     inx =   std::size_t (pconv->int_n_cs_precedes) * (3U * 5U)
           + std::size_t (pconv->int_n_sep_by_space) * 5U
           + std::size_t (pconv->int_n_sign_posn);

     if (inx < sizeof pat / sizeof *pat)
         memcpy (pdata->int_neg_format_, pat + inx, sizeof *pat);
     else
         memset (pdata->int_neg_format_, none, sizeof *pat);

     std::strcpy (pdata->int_curr_symbol_, pconv->int_curr_symbol);

     pdata->int_frac_digits_ = pconv->int_frac_digits;

 #else   // if defined (_RWSTD_NO_LCONV_INT_FMAT)

     std::strcpy (pdata->int_curr_symbol_, pconv->curr_symbol);

     pdata->int_frac_digits_ = pconv->frac_digits;

 #endif   // _RWSTD_NO_LCONV_INT_FMAT

 }


 static int
 run_test (int, char**)
 {
     // get a NUL-separated list of names of installed locales
     char* const locale_list = rw_locales ();

     // array of locale names to use for testing
     const char* locales [sizeof punct_data / sizeof *punct_data];

     const std::size_t maxinx = sizeof locales / sizeof *locales;

     // iterate over locales, initializing a global punct_data array
     for (char *name = locale_list; *name; name += std::strlen (name) + 1) {

         const std::size_t inx = nlocales;

         // set LC_NUMERIC and LC_CTYPE to be able to use mbstowcs()
         if (std::setlocale (LC_ALL, name)) {

             const std::lconv* const pconv = std::localeconv ();
             MoneypunctData* const pdata = punct_data + inx;

             locales [inx] = pdata->locale_name_ = name;

             // assign just the first character of the (potentially)
             // multibyte decimal_point and thousands_sep (C++ locale
             // can't deal with more)
             pdata->decimal_point_ = *pconv->mon_decimal_point;
             pdata->thousands_sep_ = *pconv->mon_thousands_sep;

             pdata->frac_digits_   = pconv->frac_digits;

             // simply copy the narrow grouping, currency symbols,
             // and signs
             std::strcpy (pdata->grouping_,      pconv->mon_grouping);
             std::strcpy (pdata->curr_symbol_,   pconv->currency_symbol);
             std::strcpy (pdata->negative_sign_, pconv->negative_sign);
             std::strcpy (pdata->positive_sign_, pconv->positive_sign);
             std::strcpy (pdata->grouping_,      pconv->mon_grouping);

             get_format (pdata, pconv);

 #ifndef _RWSTD_WCHAR_T

             wchar_t tmp [2];

             // convert multibyte decimal point and thousands separator
             // to wide characters (assumes they are single character
             // each -- C++ locale can't handle more)
             std::mbstowcs (tmp, pconv->mon_decimal_point, 2);
             pdata->wdecimal_point_ = tmp [0];

             std::mbstowcs (tmp, pconv->mon_thousands_sep, 2);
             pdata->wthousands_sep_ = tmp [0];

             const std::size_t n =
                 sizeof pdata->wcurr_symbol_ / sizeof (wchar_t);

             std::mbstowcs (pdata->wcurr_symbol_,   pdata->curr_symbol_,   n);
             std::mbstowcs (pdata->wnegative_sign_, pdata->negative_sign_, n);
             std::mbstowcs (pdata->wpositive_sign_, pdata->positive_sign_, n);

             std::mbstowcs (pdata->wint_curr_symbol_,
                            pdata->int_curr_symbol_,
                            n);

 #endif   // _RWSTD_WCHAR_T

             ++nlocales;
         }

         if (nlocales == maxinx)
             break;
     }

     // reset the global locale
     std::setlocale (LC_ALL, "C");

     rw_info (0, 0, 0,
              "testing std::moneypunct<charT> with %d thread%{?}s%{;}, "
              "%zu iteration%{?}s%{;} each, in locales { %{ .*A@} }",
              rw_opt_nthreads, 1 != rw_opt_nthreads,
              rw_opt_nloops, 1 != rw_opt_nloops,
              int (nlocales), "%#s", locales);

     rw_info (0, 0, 0, "exercising std::moneypunct<char>");

     test_char  = true;
     test_wchar = false;

     // create and start a pool of threads and wait for them to finish
     int result =
         rw_thread_pool (0, std::size_t (rw_opt_nthreads), 0, thread_func, 0);

     rw_error (result == 0, 0, __LINE__,
               "rw_thread_pool(0, %d, 0, %{#f}, 0) failed",
               rw_opt_nthreads, thread_func);

 #ifndef _RWSTD_NO_WCHAR_T

     rw_info (0, 0, 0, "exercising std::moneypunct<wchar_t>");

     test_char  = false;
     test_wchar = true;

     // start a pool of threads to exercise the thread safety
     // of the wchar_t specialization
     result =
         rw_thread_pool (0, std::size_t (rw_opt_nthreads), 0, thread_func, 0);

     rw_error (result == 0, 0, __LINE__,
               "rw_thread_pool(0, %d, 0, %{#f}, 0) failed",
               rw_opt_nthreads, thread_func);

     // exercise both the char and the wchar_t specializations
     // at the same time

     rw_info (0, 0, 0,
              "exercising both std::moneypunct<char> "
              "and std::moneypunct<wchar_t>");

     test_char  = true;
     test_wchar = true;

     // start a pool of threads to exercise wstring thread safety
     result =
         rw_thread_pool (0, std::size_t (rw_opt_nthreads), 0, thread_func, 0);

     rw_error (result == 0, 0, __LINE__,
               "rw_thread_pool(0, %d, 0, %{#f}, 0) failed",
               rw_opt_nthreads, thread_func);

 #endif   // _RWSTD_NO_WCHAR_T

     return result;
 }

 /**************************************************************************/

 int main (int argc, char *argv[])
 {
     return rw_test (argc, argv, __FILE__,
                     "lib.locale.moneypunct",
                     "thread safety", run_test,
                     "|-nloops#0 "       // must be non-negative
                     "|-nthreads#0-*",   // must be in [0, MAX_THREADS]
                     &rw_opt_nloops,
                     int (MAX_THREADS),
                     &rw_opt_nthreads);
 }
	/************************************************************************
	*
	* 22.locale.moneypunct.mt.cpp
	*
	* test exercising the thread safety of the moneypunct facet
	*
	* $Id$
	*
	***************************************************************************
	*
	* Licensed to the Apache Software Foundation (ASF) under one or more
	* contributor license agreements. See the NOTICE file distributed
	* with this work for additional information regarding copyright
	* ownership. The ASF licenses this file to you under the Apache
	* License, Version 2.0 (the "License"); you may not use this file
	* except in compliance with the License. You may obtain a copy of
	* the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
	* implied. See the License for the specific language governing
	* permissions and limitations under the License.
	*
	**************************************************************************/

	#include <ios> // for ios
	#include <locale> // for locale, moneypunct

	#include <clocale> // for lconv, localeconv()
	#include <cstdlib> // for mbstowcs()
	#include <cstring> // for size_t, strcpy()

	#include <rw_locale.h>
	#include <rw_thread.h>
	#include <driver.h>
	#include <valcmp.h>


	// maximum number of threads allowed by the command line interface
	#define MAX_THREADS 32


	#ifdef _RWSTD_REENTRANT
	int rw_opt_nthreads = 4;
	#else // if !defined (_RWSTD_REENTRANT)
	// in non-threaded builds use just one thread
	int rw_opt_nthreads = 1;
	#endif // _RWSTD_REENTRANT

	// the number of times each thread should iterate (unless specified
	// otherwise on the command line)
	int rw_opt_nloops = 200000;

	/**************************************************************************/

	// number of locales to test
	static std::size_t
	nlocales;

	/**************************************************************************/

	struct MoneypunctData
	{
	// the name of the locale the data goes with
	const char* locale_name_;

	char decimal_point_;
	char thousands_sep_;
	char grouping_ [32];
	char curr_symbol_ [32];
	char positive_sign_ [32];
	char negative_sign_ [32];
	int frac_digits_;
	char pos_format_ [32];
	char neg_format_ [32];

	char int_curr_symbol_ [32];

	int int_frac_digits_;
	char int_pos_format_ [32];
	char int_neg_format_ [32];

	#ifndef _RWSTD_NO_WCHAR_T

	wchar_t wdecimal_point_;
	wchar_t wthousands_sep_;
	wchar_t wcurr_symbol_ [32];
	wchar_t wpositive_sign_ [32];
	wchar_t wnegative_sign_ [32];

	wchar_t wint_curr_symbol_ [32];

	#endif // _RWSTD_NO_WCHAR_T

	} punct_data [MAX_THREADS];


	extern "C" {

	bool test_char; // exercise num_put<char>
	bool test_wchar; // exercise num_put<wchar_t>


	static void*
	thread_func (void*)
	{
	for (int i = 0; i != rw_opt_nloops; ++i) {

	const std::size_t inx = std::size_t (i) % nlocales;

	const MoneypunctData* const data = punct_data + inx;

	// construct a named locale
	const std::locale loc (data->locale_name_);

	if (test_char) {
	// exercise the narrow char, local specialization of the facet

	typedef std::moneypunct<char, false> Punct;

	const Punct &mp = std::use_facet<Punct>(loc);

	const char dp = mp.decimal_point ();
	const char ts = mp.thousands_sep ();
	const std::string grp = mp.grouping ();
	const std::string cur = mp.curr_symbol ();
	const std::string pos = mp.positive_sign ();
	const std::string neg = mp.negative_sign ();
	const int fd = mp.frac_digits ();
	const Punct::pattern pfm = mp.pos_format ();
	const Punct::pattern nfm = mp.neg_format ();

	RW_ASSERT (dp == data->decimal_point_);
	RW_ASSERT (ts == data->thousands_sep_);
	RW_ASSERT (fd == data->frac_digits_);
	RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
	RW_ASSERT (!rw_strncmp (cur.c_str (), data->curr_symbol_));
	RW_ASSERT (!rw_strncmp (pos.c_str (), data->positive_sign_));
	RW_ASSERT (!rw_strncmp (neg.c_str (), data->negative_sign_));

	RW_ASSERT (!std::memcmp (&pfm, data->pos_format_, 4));
	RW_ASSERT (!std::memcmp (&nfm, data->neg_format_, 4));
	}

	if (test_char) {
	// exercise the narrow char, international specialization

	typedef std::moneypunct<char, true> Punct;

	const Punct &mp = std::use_facet<Punct>(loc);

	const char dp = mp.decimal_point ();
	const char ts = mp.thousands_sep ();
	const std::string grp = mp.grouping ();
	const std::string cur = mp.curr_symbol ();
	const std::string pos = mp.positive_sign ();
	const std::string neg = mp.negative_sign ();
	const int fd = mp.frac_digits ();
	const Punct::pattern pfm = mp.pos_format ();
	const Punct::pattern nfm = mp.neg_format ();

	RW_ASSERT (dp == data->decimal_point_);
	RW_ASSERT (ts == data->thousands_sep_);
	RW_ASSERT (fd == data->frac_digits_);
	RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
	RW_ASSERT (!rw_strncmp (cur.c_str (), data->int_curr_symbol_));
	RW_ASSERT (!rw_strncmp (pos.c_str (), data->positive_sign_));
	RW_ASSERT (!rw_strncmp (neg.c_str (), data->negative_sign_));

	RW_ASSERT (!std::memcmp (&pfm, data->int_pos_format_, 4));
	RW_ASSERT (!std::memcmp (&nfm, data->int_neg_format_, 4));
	}

	// both specializations may be tested at the same time

	#ifndef _RWSTD_NO_WCHAR_T

	if (test_wchar) {
	// exercise the wide char, local specialization of the facet

	typedef std::moneypunct<wchar_t, false> Punct;

	const Punct &mp = std::use_facet<Punct>(loc);

	const char dp = mp.decimal_point ();
	const char ts = mp.thousands_sep ();
	const std::string grp = mp.grouping ();
	const std::wstring cur = mp.curr_symbol ();
	const std::wstring pos = mp.positive_sign ();
	const std::wstring neg = mp.negative_sign ();
	const int fd = mp.frac_digits ();
	const Punct::pattern pfm = mp.pos_format ();
	const Punct::pattern nfm = mp.neg_format ();

	RW_ASSERT (dp == data->wdecimal_point_);
	RW_ASSERT (ts == data->wthousands_sep_);
	RW_ASSERT (fd == data->frac_digits_);
	RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
	RW_ASSERT (!rw_strncmp (cur.c_str (), data->wcurr_symbol_));
	RW_ASSERT (!rw_strncmp (pos.c_str (), data->wpositive_sign_));
	RW_ASSERT (!rw_strncmp (neg.c_str (), data->wnegative_sign_));

	RW_ASSERT (!std::memcmp (&pfm, data->pos_format_, 4));
	RW_ASSERT (!std::memcmp (&nfm, data->neg_format_, 4));
	}

	if (test_wchar) {
	// exercise the wide char, international specialization

	typedef std::moneypunct<wchar_t, true> Punct;

	const Punct &mp = std::use_facet<Punct>(loc);

	const char dp = mp.decimal_point ();
	const char ts = mp.thousands_sep ();
	const std::string grp = mp.grouping ();
	const std::wstring cur = mp.curr_symbol ();
	const std::wstring pos = mp.positive_sign ();
	const std::wstring neg = mp.negative_sign ();
	const int fd = mp.frac_digits ();
	const Punct::pattern pfm = mp.pos_format ();
	const Punct::pattern nfm = mp.neg_format ();

	RW_ASSERT (dp == data->wdecimal_point_);
	RW_ASSERT (ts == data->wthousands_sep_);
	RW_ASSERT (fd == data->frac_digits_);
	RW_ASSERT (!rw_strncmp (grp.c_str (), data->grouping_));
	RW_ASSERT (!rw_strncmp (cur.c_str (), data->wint_curr_symbol_));
	RW_ASSERT (!rw_strncmp (pos.c_str (), data->wpositive_sign_));
	RW_ASSERT (!rw_strncmp (neg.c_str (), data->wnegative_sign_));

	RW_ASSERT (!std::memcmp (&pfm, data->int_pos_format_, 4));
	RW_ASSERT (!std::memcmp (&nfm, data->int_neg_format_, 4));
	}

	#endif // _RWSTD_NO_WCHAR_T

	}

	return 0;
	}

	} // extern "C"

	/**************************************************************************/

	static void
	get_format (MoneypunctData pdata, const std::lconv pconv)
	{
	// code copied from src/punct.cpp

	enum {
	// for syntactic convenience
	none = std::money_base::none,
	space = std::money_base::space,
	symbol = std::money_base::symbol,
	sign = std::money_base::sign,
	value = std::money_base::value
	};

	static const std::money_base::pattern pat[] = {

	// cs_precedes [0..1]:
	//
	// An integer set to 1 if the currency_symbol precedes the value
	// for a monetary value, and set to 0 if the symbol succeeds
	// the value.

	// sep_by_space [0..2]:
	//
	// 0 No space separates the currency_symbol from the value for
	// a monetary value.
	// 1 If the currency symbol and sign string are adjacent, a space
	// separates them from the value; otherwise, a space separates
	// the currency symbol from the value.
	// 2 If the currency symbol and sign string are adjacent, a space
	// separates them; otherwise, a space separates the sign string
	// from the value.

	// sign_posn [0..4]:
	//
	// An integer set to a value indicating the positioning of the
	// positive_sign for a monetary value. The following integer
	// values shall be recognized:
	//
	// 0 Parentheses enclose the value and the currency_symbol.
	// 1 The sign string precedes the value and the currency_symbol.
	// 2 The sign string succeeds the value and the currency_symbol.
	// 3 The sign string immediately precedes the currency_symbol.
	// 4 The sign string immediately succeeds the currency_symbol.

	// +-------- cs_precedes
	// \|+----- sep_by_space
	// \|\|+-- sign_posn
	// \|\|\|
	// VVV .... - 1 $ . // pattern
	/* 000: -1$. */ { { sign, value, symbol, none } }, // "\3\4\2\0"
	/* 001: -1$. */ { { sign, value, symbol, none } }, // "\3\4\2\0"
	/* 002: 1$-. */ { { value, symbol, sign, none } }, // "\4\2\3\0"
	/* 003: 1-$. */ { { value, sign, symbol, none } }, // "\4\3\2\0"
	/* 004: 1$-. */ { { value, symbol, sign, none } }, // "\4\2\3\0"

	/* 010: -1 $ */ { { sign, value, space, symbol } }, // "\3\4\1\2"
	/* 011: -1 $ */ { { sign, value, space, symbol } }, // "\3\4\1\2"
	/* 012: 1 $- */ { { value, space, symbol, sign } }, // "\4\1\2\3"
	/* 013: 1 -$ */ { { value, space, sign, symbol } }, // "\4\3\3\2"
	/* 014: 1 $- */ { { value, space, symbol, sign } }, // "\4\1\2\3"

	/* 020: - 1$ */ { { sign, space, value, symbol } }, // "\3\1\4\2"
	/* 021: - 1$ */ { { sign, space, value, symbol } }, // "\3\1\4\2"
	/* 022: 1$ - */ { { value, symbol, space, sign } }, // "\4\2\1\3"
	/* 023: 1- $ */ { { value, sign, space, symbol } }, // "\4\3\1\2"
	/* 024: 1$ - */ { { value, symbol, space, sign } }, // "\4\2\1\3"

	/* 100: -$1. */ { { sign, symbol, value, none } }, // "\3\2\4\0"
	/* 101: -$1. */ { { sign, symbol, value, none } }, // "\3\2\4\0"
	/* 102: $1-. */ { { symbol, value, sign, none } }, // "\2\4\3\0"
	/* 103: -$1. */ { { sign, symbol, value, none } }, // "\3\2\4\0"
	/* 104: $-1. */ { { symbol, sign, value, none } }, // "\2\3\4\0"

	/* 110: -$ 1 */ { { sign, symbol, space, value } }, // "\3\2\1\4"
	/* 111: -$ 1 */ { { sign, symbol, space, value } }, // "\3\2\1\4"
	/* 112: $ 1- */ { { symbol, space, value, sign } }, // "\2\1\4\3"
	/* 113: -$ 1 */ { { sign, symbol, space, value } }, // "\3\2\1\4"
	/* 114: $- 1 */ { { symbol, sign, space, value } }, // "\2\3\1\4"

	/* 120: - $1 */ { { sign, space, symbol, value } }, // "\3\1\2\4"
	/* 121: - $1 */ { { sign, space, symbol, value } }, // "\3\1\2\4"
	/* 122: $1 - */ { { symbol, value, space, sign } }, // "\2\4\1\3"
	/* 123: - $1 */ { { sign, space, symbol, value } }, // "\3\1\2\4"
	/* 124: $ -1 */ { { symbol, space, sign, value } } // "\2\1\3\4"
	};

	std::size_t inx;

	inx = std::size_t (pconv->p_cs_precedes) * (3U * 5U)
	+ std::size_t (pconv->p_sep_by_space) * 5U
	+ std::size_t (pconv->p_sign_posn);

	if (inx < sizeof pat / sizeof *pat)
	std::memcpy (pdata->pos_format_, pat + inx, sizeof *pat);
	else
	std::memset (pdata->pos_format_, none, sizeof *pat);

	inx = std::size_t (pconv->n_cs_precedes) * (3U * 5U)
	+ std::size_t (pconv->n_sep_by_space) * 5U
	+ std::size_t (pconv->n_sign_posn);

	if (inx < sizeof pat / sizeof *pat)
	std::memcpy (pdata->neg_format_, pat + inx, sizeof *pat);
	else
	std::memset (pdata->neg_format_, none, sizeof *pat);


	#ifndef _RWSTD_NO_LCONV_INT_FMAT

	inx = std::size_t (pconv->int_p_cs_precedes) * (3U * 5U)
	+ std::size_t (pconv->int_p_sep_by_space) * 5U
	+ std::size_t (pconv->int_p_sign_posn);

	if (inx < sizeof pat / sizeof *pat)
	std::memcpy (pdata->int_pos_format_, pat + inx, sizeof *pat);
	else
	std::memset (pdata->int_pos_format_, none, sizeof *pat);

	inx = std::size_t (pconv->int_n_cs_precedes) * (3U * 5U)
	+ std::size_t (pconv->int_n_sep_by_space) * 5U
	+ std::size_t (pconv->int_n_sign_posn);

	if (inx < sizeof pat / sizeof *pat)
	memcpy (pdata->int_neg_format_, pat + inx, sizeof *pat);
	else
	memset (pdata->int_neg_format_, none, sizeof *pat);

	std::strcpy (pdata->int_curr_symbol_, pconv->int_curr_symbol);

	pdata->int_frac_digits_ = pconv->int_frac_digits;

	#else // if defined (_RWSTD_NO_LCONV_INT_FMAT)

	std::strcpy (pdata->int_curr_symbol_, pconv->curr_symbol);

	pdata->int_frac_digits_ = pconv->frac_digits;

	#endif // _RWSTD_NO_LCONV_INT_FMAT

	}


	static int
	run_test (int, char**)
	{
	// get a NUL-separated list of names of installed locales
	char* const locale_list = rw_locales ();

	// array of locale names to use for testing
	const char* locales [sizeof punct_data / sizeof *punct_data];

	const std::size_t maxinx = sizeof locales / sizeof *locales;

	// iterate over locales, initializing a global punct_data array
	for (char name = locale_list; name; name += std::strlen (name) + 1) {

	const std::size_t inx = nlocales;

	// set LC_NUMERIC and LC_CTYPE to be able to use mbstowcs()
	if (std::setlocale (LC_ALL, name)) {

	const std::lconv* const pconv = std::localeconv ();
	MoneypunctData* const pdata = punct_data + inx;

	locales [inx] = pdata->locale_name_ = name;

	// assign just the first character of the (potentially)
	// multibyte decimal_point and thousands_sep (C++ locale
	// can't deal with more)
	pdata->decimal_point_ = *pconv->mon_decimal_point;
	pdata->thousands_sep_ = *pconv->mon_thousands_sep;

	pdata->frac_digits_ = pconv->frac_digits;

	// simply copy the narrow grouping, currency symbols,
	// and signs
	std::strcpy (pdata->grouping_, pconv->mon_grouping);
	std::strcpy (pdata->curr_symbol_, pconv->currency_symbol);
	std::strcpy (pdata->negative_sign_, pconv->negative_sign);
	std::strcpy (pdata->positive_sign_, pconv->positive_sign);
	std::strcpy (pdata->grouping_, pconv->mon_grouping);

	get_format (pdata, pconv);

	#ifndef _RWSTD_WCHAR_T

	wchar_t tmp [2];

	// convert multibyte decimal point and thousands separator
	// to wide characters (assumes they are single character
	// each -- C++ locale can't handle more)
	std::mbstowcs (tmp, pconv->mon_decimal_point, 2);
	pdata->wdecimal_point_ = tmp [0];

	std::mbstowcs (tmp, pconv->mon_thousands_sep, 2);
	pdata->wthousands_sep_ = tmp [0];

	const std::size_t n =
	sizeof pdata->wcurr_symbol_ / sizeof (wchar_t);

	std::mbstowcs (pdata->wcurr_symbol_, pdata->curr_symbol_, n);
	std::mbstowcs (pdata->wnegative_sign_, pdata->negative_sign_, n);
	std::mbstowcs (pdata->wpositive_sign_, pdata->positive_sign_, n);

	std::mbstowcs (pdata->wint_curr_symbol_,
	pdata->int_curr_symbol_,
	n);

	#endif // _RWSTD_WCHAR_T

	++nlocales;
	}

	if (nlocales == maxinx)
	break;
	}

	// reset the global locale
	std::setlocale (LC_ALL, "C");

	rw_info (0, 0, 0,
	"testing std::moneypunct<charT> with %d thread%{?}s%{;}, "
	"%zu iteration%{?}s%{;} each, in locales { %{ .*A@} }",
	rw_opt_nthreads, 1 != rw_opt_nthreads,
	rw_opt_nloops, 1 != rw_opt_nloops,
	int (nlocales), "%#s", locales);

	rw_info (0, 0, 0, "exercising std::moneypunct<char>");

	test_char = true;
	test_wchar = false;

	// create and start a pool of threads and wait for them to finish
	int result =
	rw_thread_pool (0, std::size_t (rw_opt_nthreads), 0, thread_func, 0);

	rw_error (result == 0, 0, __LINE__,
	"rw_thread_pool(0, %d, 0, %{#f}, 0) failed",
	rw_opt_nthreads, thread_func);

	#ifndef _RWSTD_NO_WCHAR_T

	rw_info (0, 0, 0, "exercising std::moneypunct<wchar_t>");

	test_char = false;
	test_wchar = true;

	// start a pool of threads to exercise the thread safety
	// of the wchar_t specialization
	result =
	rw_thread_pool (0, std::size_t (rw_opt_nthreads), 0, thread_func, 0);

	rw_error (result == 0, 0, __LINE__,
	"rw_thread_pool(0, %d, 0, %{#f}, 0) failed",
	rw_opt_nthreads, thread_func);

	// exercise both the char and the wchar_t specializations
	// at the same time

	rw_info (0, 0, 0,
	"exercising both std::moneypunct<char> "
	"and std::moneypunct<wchar_t>");

	test_char = true;
	test_wchar = true;

	// start a pool of threads to exercise wstring thread safety
	result =
	rw_thread_pool (0, std::size_t (rw_opt_nthreads), 0, thread_func, 0);

	rw_error (result == 0, 0, __LINE__,
	"rw_thread_pool(0, %d, 0, %{#f}, 0) failed",
	rw_opt_nthreads, thread_func);

	#endif // _RWSTD_NO_WCHAR_T

	return result;
	}

	/**************************************************************************/

	int main (int argc, char *argv[])
	{
	return rw_test (argc, argv, __FILE__,
	"lib.locale.moneypunct",
	"thread safety", run_test,
	"\|-nloops#0 " // must be non-negative
	"\|-nthreads#0-*", // must be in [0, MAX_THREADS]
	&rw_opt_nloops,
	int (MAX_THREADS),
	&rw_opt_nthreads);
	}