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Commit 1cb7f91f by Benjamin Kosnik Committed by Benjamin Kosnik
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bitset_members.cc: New test. 


2002-04-09  Benjamin Kosnik  <bkoz@redhat.com>

	libstdc++/6124
	* testsuite/23_containers/bitset_members.cc: New test.
	* include/std/std_bitset.h (_Bit_count::_S_bit_count): Move..
	(_S_bit_count): Here.
	(_First_one::_S_first_one): Move...
	(_S_first_one): Here.
	Format.
	* src/bitset.cc: Adjust.
	* config/linker-map.gnu: Export.

From-SVN: r52066
parent e70ed0d9
Showing with 762 additions and 649 deletions
libstdc++-v3/ChangeLog
2002-04-09 Benjamin Kosnik <bkoz@redhat.com>
libstdc++/6124
* testsuite/23_containers/bitset_members.cc: New test.
* include/std/std_bitset.h (_Bit_count::_S_bit_count): Move..
(_S_bit_count): Here.
(_First_one::_S_first_one): Move...
(_S_first_one): Here.
Format.
* src/bitset.cc: Adjust.
* config/linker-map.gnu: Export.
2002-04-08 Benjamin Kosnik <bkoz@redhat.com> 2002-04-08 Benjamin Kosnik <bkoz@redhat.com>
libstdc++/5180 libstdc++/5180
......
libstdc++-v3/config/linker-map.gnu
...@@ -34,7 +34,9 @@ GLIBCPP_3.1 { ...@@ -34,7 +34,9 @@ GLIBCPP_3.1 {
std::__basic_file*; std::__basic_file*;
std::__num_base*; std::__num_base*;
std::__timepunct*; std::__timepunct*;
std::__numeric_limits_base* std::__numeric_limits_base*;
std::_S_bit_count;
std::_S_first_one
}; };
# Names not in an 'extern' block are mangled names. # Names not in an 'extern' block are mangled names.
......
libstdc++-v3/include/std/std_bitset.h
...@@ -60,7 +60,6 @@ ...@@ -60,7 +60,6 @@
// individual bits. This allows us to specialize _Base_bitset for the // individual bits. This allows us to specialize _Base_bitset for the
// important special case where the bitset is only a single word. // important special case where the bitset is only a single word.
#include <cstddef> // for size_t #include <cstddef> // for size_t
#include <cstring> // for memset #include <cstring> // for memset
#include <string> #include <string>
...@@ -75,739 +74,840 @@ ...@@ -75,739 +74,840 @@
namespace std namespace std
{ {
extern unsigned char _S_bit_count[256];
extern unsigned char _S_first_one[256];
// Base class: general case.
template<size_t _Nw>
struct _Base_bitset
{
typedef unsigned long _WordT;
// 0 is the least significant word.
_WordT _M_w[_Nw];
_Base_bitset() { _M_do_reset(); }
_Base_bitset(unsigned long __val)
{
_M_do_reset();
_M_w[0] = __val;
}
// structure to aid in counting bits static size_t
template<bool __dummy> _S_whichword(size_t __pos )
struct _Bit_count { { return __pos / _GLIBCPP_BITSET_BITS_PER_WORD; }
static unsigned char _S_bit_count[256];
};
// Mapping from 8 bit unsigned integers to the index of the first one static size_t
// bit: _S_whichbyte(size_t __pos )
template<bool __dummy> { return (__pos % _GLIBCPP_BITSET_BITS_PER_WORD) / CHAR_BIT; }
struct _First_one {
static unsigned char _S_first_one[256];
};
// static size_t
// Base class: general case. _S_whichbit(size_t __pos )
// { return __pos % _GLIBCPP_BITSET_BITS_PER_WORD; }
template<size_t _Nw> static _WordT
struct _Base_bitset { _S_maskbit(size_t __pos )
typedef unsigned long _WordT; { return (static_cast<_WordT>(1)) << _S_whichbit(__pos); }
_WordT _M_w[_Nw]; // 0 is the least significant word. _WordT&
_M_getword(size_t __pos)
{ return _M_w[_S_whichword(__pos)]; }
_Base_bitset( void ) { _M_do_reset(); } _WordT
_Base_bitset(unsigned long __val) { _M_getword(size_t __pos) const
_M_do_reset(); { return _M_w[_S_whichword(__pos)]; }
_M_w[0] = __val;
}
static size_t _S_whichword( size_t __pos ) _WordT&
{ return __pos / _GLIBCPP_BITSET_BITS_PER_WORD; } _M_hiword() { return _M_w[_Nw - 1]; }
static size_t _S_whichbyte( size_t __pos )
{ return (__pos % _GLIBCPP_BITSET_BITS_PER_WORD) / CHAR_BIT; }
static size_t _S_whichbit( size_t __pos )
{ return __pos % _GLIBCPP_BITSET_BITS_PER_WORD; }
static _WordT _S_maskbit( size_t __pos )
{ return (static_cast<_WordT>(1)) << _S_whichbit(__pos); }
_WordT& _M_getword(size_t __pos) { return _M_w[_S_whichword(__pos)]; } _WordT
_WordT _M_getword(size_t __pos) const { return _M_w[_S_whichword(__pos)]; } _M_hiword() const { return _M_w[_Nw - 1]; }
_WordT& _M_hiword() { return _M_w[_Nw - 1]; } void
_WordT _M_hiword() const { return _M_w[_Nw - 1]; } _M_do_and(const _Base_bitset<_Nw>& __x)
{
for (size_t __i = 0; __i < _Nw; __i++)
_M_w[__i] &= __x._M_w[__i];
}
void _M_do_and(const _Base_bitset<_Nw>& __x) { void
for ( size_t __i = 0; __i < _Nw; __i++ ) { _M_do_or(const _Base_bitset<_Nw>& __x)
_M_w[__i] &= __x._M_w[__i]; {
} for (size_t __i = 0; __i < _Nw; __i++)
} _M_w[__i] |= __x._M_w[__i];
}
void _M_do_or(const _Base_bitset<_Nw>& __x) { void
for ( size_t __i = 0; __i < _Nw; __i++ ) { _M_do_xor(const _Base_bitset<_Nw>& __x)
_M_w[__i] |= __x._M_w[__i]; {
} for (size_t __i = 0; __i < _Nw; __i++)
} _M_w[__i] ^= __x._M_w[__i];
}
void _M_do_xor(const _Base_bitset<_Nw>& __x) { void
for ( size_t __i = 0; __i < _Nw; __i++ ) { _M_do_left_shift(size_t __shift);
_M_w[__i] ^= __x._M_w[__i];
} void
} _M_do_right_shift(size_t __shift);
void
_M_do_flip()
{
for (size_t __i = 0; __i < _Nw; __i++)
_M_w[__i] = ~_M_w[__i];
}
void _M_do_left_shift(size_t __shift); void
void _M_do_right_shift(size_t __shift); _M_do_set()
{
for (size_t __i = 0; __i < _Nw; __i++)
_M_w[__i] = ~static_cast<_WordT>(0);
}
void _M_do_flip() { void
for ( size_t __i = 0; __i < _Nw; __i++ ) { _M_do_reset() { memset(_M_w, 0, _Nw * sizeof(_WordT)); }
_M_w[__i] = ~_M_w[__i];
} bool
} _M_is_equal(const _Base_bitset<_Nw>& __x) const
{
for (size_t __i = 0; __i < _Nw; ++__i)
{
if (_M_w[__i] != __x._M_w[__i])
return false;
}
return true;
}
void _M_do_set() { bool
for ( size_t __i = 0; __i < _Nw; __i++ ) { _M_is_any() const
_M_w[__i] = ~static_cast<_WordT>(0); {
} for (size_t __i = 0; __i < _Nw; __i++)
} {
if (_M_w[__i] != static_cast<_WordT>(0))
return true;
}
return false;
}
void _M_do_reset() { memset(_M_w, 0, _Nw * sizeof(_WordT)); } size_t
_M_do_count() const
{
size_t __result = 0;
const unsigned char* __byte_ptr = (const unsigned char*)_M_w;
const unsigned char* __end_ptr = (const unsigned char*)(_M_w + _Nw);
while ( __byte_ptr < __end_ptr )
{
__result += _S_bit_count[*__byte_ptr];
__byte_ptr++;
}
return __result;
}
bool _M_is_equal(const _Base_bitset<_Nw>& __x) const { unsigned long
for (size_t __i = 0; __i < _Nw; ++__i) { _M_do_to_ulong() const;
if (_M_w[__i] != __x._M_w[__i])
return false; // find first "on" bit
size_t
_M_do_find_first(size_t __not_found) const;
// find the next "on" bit that follows "prev"
size_t
_M_do_find_next(size_t __prev, size_t __not_found) const;
};
// Definitions of non-inline functions from _Base_bitset.
template<size_t _Nw>
void
_Base_bitset<_Nw>::_M_do_left_shift(size_t __shift)
{
if (__shift != 0)
{
const size_t __wshift = __shift / _GLIBCPP_BITSET_BITS_PER_WORD;
const size_t __offset = __shift % _GLIBCPP_BITSET_BITS_PER_WORD;
if (__offset == 0)
for (size_t __n = _Nw - 1; __n >= __wshift; --__n)
_M_w[__n] = _M_w[__n - __wshift];
else
{
const size_t __sub_offset = _GLIBCPP_BITSET_BITS_PER_WORD - __offset;
for (size_t __n = _Nw - 1; __n > __wshift; --__n)
_M_w[__n] = (_M_w[__n - __wshift] << __offset) |
(_M_w[__n - __wshift - 1] >> __sub_offset);
_M_w[__wshift] = _M_w[0] << __offset;
}
fill(_M_w + 0, _M_w + __wshift, static_cast<_WordT>(0));
}
} }
return true;
} template<size_t _Nw>
void
bool _M_is_any() const { _Base_bitset<_Nw>::_M_do_right_shift(size_t __shift)
for ( size_t __i = 0; __i < _Nw; __i++ ) { {
if ( _M_w[__i] != static_cast<_WordT>(0) ) if (__shift != 0)
return true; {
const size_t __wshift = __shift / _GLIBCPP_BITSET_BITS_PER_WORD;
const size_t __offset = __shift % _GLIBCPP_BITSET_BITS_PER_WORD;
const size_t __limit = _Nw - __wshift - 1;
if (__offset == 0)
for (size_t __n = 0; __n <= __limit; ++__n)
_M_w[__n] = _M_w[__n + __wshift];
else
{
const size_t __sub_offset = _GLIBCPP_BITSET_BITS_PER_WORD - __offset;
for (size_t __n = 0; __n < __limit; ++__n)
_M_w[__n] = (_M_w[__n + __wshift] >> __offset) |
(_M_w[__n + __wshift + 1] << __sub_offset);
_M_w[__limit] = _M_w[_Nw-1] >> __offset;
}
fill(_M_w + __limit + 1, _M_w + _Nw, static_cast<_WordT>(0));
}
} }
return false;
}
size_t _M_do_count() const { template<size_t _Nw>
size_t __result = 0; unsigned long
const unsigned char* __byte_ptr = (const unsigned char*)_M_w; _Base_bitset<_Nw>::_M_do_to_ulong() const
const unsigned char* __end_ptr = (const unsigned char*)(_M_w+_Nw); {
for (size_t __i = 1; __i < _Nw; ++__i)
while ( __byte_ptr < __end_ptr ) { if (_M_w[__i])
__result += _Bit_count<true>::_S_bit_count[*__byte_ptr]; __throw_overflow_error("bitset");
__byte_ptr++; return _M_w[0];
} }
return __result;
}
unsigned long _M_do_to_ulong() const;
// find first "on" bit
size_t _M_do_find_first(size_t __not_found) const;
// find the next "on" bit that follows "prev"
size_t _M_do_find_next(size_t __prev, size_t __not_found) const;
};
// template<size_t _Nw>
// Definitions of non-inline functions from _Base_bitset. size_t
// _Base_bitset<_Nw>::_M_do_find_first(size_t __not_found) const
{
template<size_t _Nw> for (size_t __i = 0; __i < _Nw; __i++ )
void _Base_bitset<_Nw>::_M_do_left_shift(size_t __shift) {
{ _WordT __thisword = _M_w[__i];
if (__shift != 0) { if ( __thisword != static_cast<_WordT>(0) )
const size_t __wshift = __shift / _GLIBCPP_BITSET_BITS_PER_WORD; {
const size_t __offset = __shift % _GLIBCPP_BITSET_BITS_PER_WORD; // find byte within word
for (size_t __j = 0; __j < sizeof(_WordT); __j++ )
if (__offset == 0) {
for (size_t __n = _Nw - 1; __n >= __wshift; --__n) unsigned char __this_byte
_M_w[__n] = _M_w[__n - __wshift]; = static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if (__this_byte)
else { return __i*_GLIBCPP_BITSET_BITS_PER_WORD + __j*CHAR_BIT +
const size_t __sub_offset = _GLIBCPP_BITSET_BITS_PER_WORD - __offset; _S_first_one[__this_byte];
for (size_t __n = _Nw - 1; __n > __wshift; --__n)
_M_w[__n] = (_M_w[__n - __wshift] << __offset) | __thisword >>= CHAR_BIT;
(_M_w[__n - __wshift - 1] >> __sub_offset); }
_M_w[__wshift] = _M_w[0] << __offset; }
}
// not found, so return an indication of failure.
return __not_found;
} }
fill(_M_w + 0, _M_w + __wshift, static_cast<_WordT>(0)); template<size_t _Nw>
} size_t
} _Base_bitset<_Nw>::_M_do_find_next(size_t __prev, size_t __not_found) const
{
// make bound inclusive
++__prev;
// check out of bounds
if ( __prev >= _Nw * _GLIBCPP_BITSET_BITS_PER_WORD )
return __not_found;
// search first word
size_t __i = _S_whichword(__prev);
_WordT __thisword = _M_w[__i];
// mask off bits below bound
__thisword &= (~static_cast<_WordT>(0)) << _S_whichbit(__prev);
if ( __thisword != static_cast<_WordT>(0) )
{
// find byte within word
// get first byte into place
__thisword >>= _S_whichbyte(__prev) * CHAR_BIT;
for (size_t __j = _S_whichbyte(__prev); __j < sizeof(_WordT); __j++)
{
unsigned char __this_byte
= static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if ( __this_byte )
return __i*_GLIBCPP_BITSET_BITS_PER_WORD + __j*CHAR_BIT +
_S_first_one[__this_byte];
__thisword >>= CHAR_BIT;
}
}
// check subsequent words
__i++;
for ( ; __i < _Nw; __i++ )
{
__thisword = _M_w[__i];
if ( __thisword != static_cast<_WordT>(0) )
{
// find byte within word
for (size_t __j = 0; __j < sizeof(_WordT); __j++ )
{
unsigned char __this_byte
= static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if ( __this_byte )
return __i*_GLIBCPP_BITSET_BITS_PER_WORD + __j*CHAR_BIT +
_S_first_one[__this_byte];
__thisword >>= CHAR_BIT;
}
}
}
// not found, so return an indication of failure.
return __not_found;
} // end _M_do_find_next
template<size_t _Nw> // Base class: specialization for a single word.
void _Base_bitset<_Nw>::_M_do_right_shift(size_t __shift) template<>
{ struct _Base_bitset<1>
if (__shift != 0) { {
const size_t __wshift = __shift / _GLIBCPP_BITSET_BITS_PER_WORD; typedef unsigned long _WordT;
const size_t __offset = __shift % _GLIBCPP_BITSET_BITS_PER_WORD; _WordT _M_w;
const size_t __limit = _Nw - __wshift - 1;
if (__offset == 0)
for (size_t __n = 0; __n <= __limit; ++__n)
_M_w[__n] = _M_w[__n + __wshift];
else {
const size_t __sub_offset = _GLIBCPP_BITSET_BITS_PER_WORD - __offset;
for (size_t __n = 0; __n < __limit; ++__n)
_M_w[__n] = (_M_w[__n + __wshift] >> __offset) |
(_M_w[__n + __wshift + 1] << __sub_offset);
_M_w[__limit] = _M_w[_Nw-1] >> __offset;
}
fill(_M_w + __limit + 1, _M_w + _Nw, static_cast<_WordT>(0)); _Base_bitset( void ) : _M_w(0) {}
} _Base_bitset(unsigned long __val) : _M_w(__val) {}
}
template<size_t _Nw> static size_t
unsigned long _Base_bitset<_Nw>::_M_do_to_ulong() const _S_whichword(size_t __pos )
{ { return __pos / _GLIBCPP_BITSET_BITS_PER_WORD; }
for (size_t __i = 1; __i < _Nw; ++__i)
if (_M_w[__i])
__throw_overflow_error("bitset");
return _M_w[0];
}
template<size_t _Nw> static size_t
size_t _Base_bitset<_Nw>::_M_do_find_first(size_t __not_found) const _S_whichbyte(size_t __pos )
{ { return (__pos % _GLIBCPP_BITSET_BITS_PER_WORD) / CHAR_BIT; }
for ( size_t __i = 0; __i < _Nw; __i++ ) {
_WordT __thisword = _M_w[__i];
if ( __thisword != static_cast<_WordT>(0) ) {
// find byte within word
for ( size_t __j = 0; __j < sizeof(_WordT); __j++ ) {
unsigned char __this_byte
= static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if ( __this_byte )
return __i*_GLIBCPP_BITSET_BITS_PER_WORD + __j*CHAR_BIT +
_First_one<true>::_S_first_one[__this_byte];
__thisword >>= CHAR_BIT;
}
}
}
// not found, so return an indication of failure.
return __not_found;
}
template<size_t _Nw>
size_t
_Base_bitset<_Nw>::_M_do_find_next(size_t __prev, size_t __not_found) const
{
// make bound inclusive
++__prev;
// check out of bounds
if ( __prev >= _Nw * _GLIBCPP_BITSET_BITS_PER_WORD )
return __not_found;
// search first word
size_t __i = _S_whichword(__prev);
_WordT __thisword = _M_w[__i];
// mask off bits below bound
__thisword &= (~static_cast<_WordT>(0)) << _S_whichbit(__prev);
if ( __thisword != static_cast<_WordT>(0) ) {
// find byte within word
// get first byte into place
__thisword >>= _S_whichbyte(__prev) * CHAR_BIT;
for ( size_t __j = _S_whichbyte(__prev); __j < sizeof(_WordT); __j++ ) {
unsigned char __this_byte
= static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if ( __this_byte )
return __i*_GLIBCPP_BITSET_BITS_PER_WORD + __j*CHAR_BIT +
_First_one<true>::_S_first_one[__this_byte];
__thisword >>= CHAR_BIT;
}
}
// check subsequent words
__i++;
for ( ; __i < _Nw; __i++ ) {
__thisword = _M_w[__i];
if ( __thisword != static_cast<_WordT>(0) ) {
// find byte within word
for ( size_t __j = 0; __j < sizeof(_WordT); __j++ ) {
unsigned char __this_byte
= static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if ( __this_byte )
return __i*_GLIBCPP_BITSET_BITS_PER_WORD + __j*CHAR_BIT +
_First_one<true>::_S_first_one[__this_byte];
__thisword >>= CHAR_BIT;
}
}
}
// not found, so return an indication of failure. static size_t
return __not_found; _S_whichbit(size_t __pos )
} // end _M_do_find_next { return __pos % _GLIBCPP_BITSET_BITS_PER_WORD; }
static _WordT
_S_maskbit(size_t __pos )
{ return (static_cast<_WordT>(1)) << _S_whichbit(__pos); }
// ------------------------------------------------------------ _WordT&
_M_getword(size_t) { return _M_w; }
// _WordT
// Base class: specialization for a single word. _M_getword(size_t) const { return _M_w; }
//
template<> struct _Base_bitset<1> { _WordT&
typedef unsigned long _WordT; _M_hiword() { return _M_w; }
_WordT _M_w;
_Base_bitset( void ) : _M_w(0) {}
_Base_bitset(unsigned long __val) : _M_w(__val) {}
static size_t _S_whichword( size_t __pos )
{ return __pos / _GLIBCPP_BITSET_BITS_PER_WORD; }
static size_t _S_whichbyte( size_t __pos )
{ return (__pos % _GLIBCPP_BITSET_BITS_PER_WORD) / CHAR_BIT; }
static size_t _S_whichbit( size_t __pos )
{ return __pos % _GLIBCPP_BITSET_BITS_PER_WORD; }
static _WordT _S_maskbit( size_t __pos )
{ return (static_cast<_WordT>(1)) << _S_whichbit(__pos); }
_WordT& _M_getword(size_t) { return _M_w; }
_WordT _M_getword(size_t) const { return _M_w; }
_WordT& _M_hiword() { return _M_w; }
_WordT _M_hiword() const { return _M_w; }
void _M_do_and(const _Base_bitset<1>& __x) { _M_w &= __x._M_w; }
void _M_do_or(const _Base_bitset<1>& __x) { _M_w |= __x._M_w; }
void _M_do_xor(const _Base_bitset<1>& __x) { _M_w ^= __x._M_w; }
void _M_do_left_shift(size_t __shift) { _M_w <<= __shift; }
void _M_do_right_shift(size_t __shift) { _M_w >>= __shift; }
void _M_do_flip() { _M_w = ~_M_w; }
void _M_do_set() { _M_w = ~static_cast<_WordT>(0); }
void _M_do_reset() { _M_w = 0; }
bool _M_is_equal(const _Base_bitset<1>& __x) const
{ return _M_w == __x._M_w; }
bool _M_is_any() const
{ return _M_w != 0; }
size_t _M_do_count() const {
size_t __result = 0;
const unsigned char* __byte_ptr = (const unsigned char*)&_M_w;
const unsigned char* __end_ptr
= ((const unsigned char*)&_M_w)+sizeof(_M_w);
while ( __byte_ptr < __end_ptr ) {
__result += _Bit_count<true>::_S_bit_count[*__byte_ptr];
__byte_ptr++;
}
return __result;
}
unsigned long _M_do_to_ulong() const { return _M_w; } _WordT
_M_hiword() const { return _M_w; }
size_t _M_do_find_first(size_t __not_found) const; void
_M_do_and(const _Base_bitset<1>& __x) { _M_w &= __x._M_w; }
// find the next "on" bit that follows "prev" void
size_t _M_do_find_next(size_t __prev, size_t __not_found) const; _M_do_or(const _Base_bitset<1>& __x) { _M_w |= __x._M_w; }
}; void
_M_do_xor(const _Base_bitset<1>& __x) { _M_w ^= __x._M_w; }
void
_M_do_left_shift(size_t __shift) { _M_w <<= __shift; }
// ------------------------------------------------------------ void
// Helper class to zero out the unused high-order bits in the highest word. _M_do_right_shift(size_t __shift) { _M_w >>= __shift; }
template <size_t _Extrabits> struct _Sanitize { void
static void _M_do_sanitize(unsigned long& __val) _M_do_flip() { _M_w = ~_M_w; }
{ __val &= ~((~static_cast<unsigned long>(0)) << _Extrabits); }
};
template<> struct _Sanitize<0> { void
static void _M_do_sanitize(unsigned long) {} _M_do_set() { _M_w = ~static_cast<_WordT>(0); }
};
void
_M_do_reset() { _M_w = 0; }
bool
_M_is_equal(const _Base_bitset<1>& __x) const
{ return _M_w == __x._M_w; }
// ------------------------------------------------------------ bool
// Class bitset. _M_is_any() const { return _M_w != 0; }
// _Nb may be any nonzero number of type size_t.
template<size_t _Nb> size_t
class bitset : private _Base_bitset<__BITSET_WORDS(_Nb)> _M_do_count() const
{ {
private: size_t __result = 0;
typedef _Base_bitset<__BITSET_WORDS(_Nb)> _Base; const unsigned char* __byte_ptr = (const unsigned char*)&_M_w;
typedef unsigned long _WordT; const unsigned char* __end_ptr
= ((const unsigned char*)&_M_w)+sizeof(_M_w);
while ( __byte_ptr < __end_ptr )
{
__result += _S_bit_count[*__byte_ptr];
__byte_ptr++;
}
return __result;
}
private: unsigned long
void _M_do_sanitize() { _M_do_to_ulong() const { return _M_w; }
_Sanitize<_Nb%_GLIBCPP_BITSET_BITS_PER_WORD>::_M_do_sanitize(this->_M_hiword());
} size_t
_M_do_find_first(size_t __not_found) const;
// find the next "on" bit that follows "prev"
size_t
_M_do_find_next(size_t __prev, size_t __not_found) const;
};
// Helper class to zero out the unused high-order bits in the highest word.
template<size_t _Extrabits>
struct _Sanitize
{
static void _S_do_sanitize(unsigned long& __val)
{ __val &= ~((~static_cast<unsigned long>(0)) << _Extrabits); }
};
template<>
struct _Sanitize<0>
{ static void _S_do_sanitize(unsigned long) { } };
// Class bitset.
// _Nb may be any nonzero number of type size_t.
template<size_t _Nb>
class bitset : private _Base_bitset<__BITSET_WORDS(_Nb)>
{
private:
typedef _Base_bitset<__BITSET_WORDS(_Nb)> _Base;
typedef unsigned long _WordT;
void
_M_do_sanitize()
{
_Sanitize<_Nb%_GLIBCPP_BITSET_BITS_PER_WORD>::_S_do_sanitize(this->_M_hiword());
}
public: public:
// bit reference:
class reference;
friend class reference;
class reference
{
friend class bitset;
_WordT *_M_wp;
size_t _M_bpos;
// left undefined
reference();
public:
reference( bitset& __b, size_t __pos )
{
_M_wp = &__b._M_getword(__pos);
_M_bpos = _Base::_S_whichbit(__pos);
}
// bit reference: ~reference() { }
class reference;
friend class reference; // for b[i] = __x;
reference&
operator=(bool __x)
{
if ( __x )
*_M_wp |= _Base::_S_maskbit(_M_bpos);
else
*_M_wp &= ~_Base::_S_maskbit(_M_bpos);
return *this;
}
// for b[i] = b[__j];
reference&
operator=(const reference& __j)
{
if ( (*(__j._M_wp) & _Base::_S_maskbit(__j._M_bpos)) )
*_M_wp |= _Base::_S_maskbit(_M_bpos);
else
*_M_wp &= ~_Base::_S_maskbit(_M_bpos);
return *this;
}
class reference { // flips the bit
friend class bitset; bool
operator~() const
{ return (*(_M_wp) & _Base::_S_maskbit(_M_bpos)) == 0; }
_WordT *_M_wp; // for __x = b[i];
size_t _M_bpos; operator bool() const
{ return (*(_M_wp) & _Base::_S_maskbit(_M_bpos)) != 0; }
// left undefined // for b[i].flip();
reference(); reference&
flip()
{
*_M_wp ^= _Base::_S_maskbit(_M_bpos);
return *this;
}
};
// 23.3.5.1 constructors:
bitset() { }
public: bitset(unsigned long __val) : _Base_bitset<__BITSET_WORDS(_Nb)>(__val)
reference( bitset& __b, size_t __pos ) { { _M_do_sanitize(); }
_M_wp = &__b._M_getword(__pos);
_M_bpos = _Base::_S_whichbit(__pos);
}
~reference() {} template<class _CharT, class _Traits, class _Alloc>
explicit bitset(const basic_string<_CharT, _Traits, _Alloc>& __s,
size_t __pos = 0) : _Base()
{
if (__pos > __s.size())
__throw_out_of_range("bitset");
_M_copy_from_string(__s, __pos,
basic_string<_CharT, _Traits, _Alloc>::npos);
}
// for b[i] = __x; template<class _CharT, class _Traits, class _Alloc>
reference& operator=(bool __x) { bitset(const basic_string<_CharT, _Traits, _Alloc>& __s,
if ( __x ) size_t __pos, size_t __n) : _Base()
*_M_wp |= _Base::_S_maskbit(_M_bpos); {
else if (__pos > __s.size())
*_M_wp &= ~_Base::_S_maskbit(_M_bpos); __throw_out_of_range("bitset");
_M_copy_from_string(__s, __pos, __n);
}
// 23.3.5.2 bitset operations:
bitset<_Nb>&
operator&=(const bitset<_Nb>& __rhs)
{
this->_M_do_and(__rhs);
return *this; return *this;
} }
// for b[i] = b[__j]; bitset<_Nb>&
reference& operator=(const reference& __j) { operator|=(const bitset<_Nb>& __rhs)
if ( (*(__j._M_wp) & _Base::_S_maskbit(__j._M_bpos)) ) {
*_M_wp |= _Base::_S_maskbit(_M_bpos); this->_M_do_or(__rhs);
else
*_M_wp &= ~_Base::_S_maskbit(_M_bpos);
return *this; return *this;
} }
// flips the bit bitset<_Nb>&
bool operator~() const operator^=(const bitset<_Nb>& __rhs)
{ return (*(_M_wp) & _Base::_S_maskbit(_M_bpos)) == 0; } {
this->_M_do_xor(__rhs);
// for __x = b[i]; return *this;
operator bool() const }
{ return (*(_M_wp) & _Base::_S_maskbit(_M_bpos)) != 0; }
// for b[i].flip(); bitset<_Nb>&
reference& flip() { operator<<=(size_t __pos)
*_M_wp ^= _Base::_S_maskbit(_M_bpos); {
this->_M_do_left_shift(__pos);
this->_M_do_sanitize();
return *this; return *this;
} }
};
// 23.3.5.1 constructors: bitset<_Nb>&
bitset() {} operator>>=(size_t __pos)
bitset(unsigned long __val) : _Base_bitset<__BITSET_WORDS(_Nb)>(__val) {
{ _M_do_sanitize(); } this->_M_do_right_shift(__pos);
this->_M_do_sanitize();
return *this;
}
template<class _CharT, class _Traits, class _Alloc> // Extension:
explicit bitset(const basic_string<_CharT, _Traits, _Alloc>& __s, // Versions of single-bit set, reset, flip, test with no range checking.
size_t __pos = 0) bitset<_Nb>&
: _Base() _Unchecked_set(size_t __pos)
{ {
if (__pos > __s.size())
__throw_out_of_range("bitset");
_M_copy_from_string(__s, __pos,
basic_string<_CharT, _Traits, _Alloc>::npos);
}
template<class _CharT, class _Traits, class _Alloc>
bitset(const basic_string<_CharT, _Traits, _Alloc>& __s,
size_t __pos,
size_t __n)
: _Base()
{
if (__pos > __s.size())
__throw_out_of_range("bitset");
_M_copy_from_string(__s, __pos, __n);
}
// 23.3.5.2 bitset operations:
bitset<_Nb>& operator&=(const bitset<_Nb>& __rhs) {
this->_M_do_and(__rhs);
return *this;
}
bitset<_Nb>& operator|=(const bitset<_Nb>& __rhs) {
this->_M_do_or(__rhs);
return *this;
}
bitset<_Nb>& operator^=(const bitset<_Nb>& __rhs) {
this->_M_do_xor(__rhs);
return *this;
}
bitset<_Nb>& operator<<=(size_t __pos) {
this->_M_do_left_shift(__pos);
this->_M_do_sanitize();
return *this;
}
bitset<_Nb>& operator>>=(size_t __pos) {
this->_M_do_right_shift(__pos);
this->_M_do_sanitize();
return *this;
}
//
// Extension:
// Versions of single-bit set, reset, flip, test with no range checking.
//
bitset<_Nb>& _Unchecked_set(size_t __pos) {
this->_M_getword(__pos) |= _Base::_S_maskbit(__pos);
return *this;
}
bitset<_Nb>& _Unchecked_set(size_t __pos, int __val) {
if (__val)
this->_M_getword(__pos) |= _Base::_S_maskbit(__pos); this->_M_getword(__pos) |= _Base::_S_maskbit(__pos);
else return *this;
this->_M_getword(__pos) &= ~_Base::_S_maskbit(__pos); }
return *this;
}
bitset<_Nb>& _Unchecked_reset(size_t __pos) {
this->_M_getword(__pos) &= ~_Base::_S_maskbit(__pos);
return *this;
}
bitset<_Nb>& _Unchecked_flip(size_t __pos) {
this->_M_getword(__pos) ^= _Base::_S_maskbit(__pos);
return *this;
}
bool _Unchecked_test(size_t __pos) const { bitset<_Nb>&
return (this->_M_getword(__pos) & _Base::_S_maskbit(__pos)) _Unchecked_set(size_t __pos, int __val)
!= static_cast<_WordT>(0); {
} if (__val)
this->_M_getword(__pos) |= _Base::_S_maskbit(__pos);
else
this->_M_getword(__pos) &= ~_Base::_S_maskbit(__pos);
return *this;
}
// Set, reset, and flip. bitset<_Nb>&
_Unchecked_reset(size_t __pos)
{
this->_M_getword(__pos) &= ~_Base::_S_maskbit(__pos);
return *this;
}
bitset<_Nb>& set() { bitset<_Nb>&
this->_M_do_set(); _Unchecked_flip(size_t __pos)
this->_M_do_sanitize(); {
return *this; this->_M_getword(__pos) ^= _Base::_S_maskbit(__pos);
} return *this;
}
bitset<_Nb>& set(size_t __pos, bool __val = true) { bool
if (__pos >= _Nb) _Unchecked_test(size_t __pos) const
__throw_out_of_range("bitset"); {
return (this->_M_getword(__pos) & _Base::_S_maskbit(__pos))
!= static_cast<_WordT>(0);
}
return _Unchecked_set(__pos, __val); // Set, reset, and flip.
} bitset<_Nb>&
set()
{
this->_M_do_set();
this->_M_do_sanitize();
return *this;
}
bitset<_Nb>& reset() { bitset<_Nb>&
this->_M_do_reset(); set(size_t __pos, bool __val = true)
return *this; {
} if (__pos >= _Nb)
__throw_out_of_range("bitset");
return _Unchecked_set(__pos, __val);
}
bitset<_Nb>& reset(size_t __pos) { bitset<_Nb>&
if (__pos >= _Nb) reset()
__throw_out_of_range("bitset"); {
this->_M_do_reset();
return *this;
}
return _Unchecked_reset(__pos); bitset<_Nb>&
} reset(size_t __pos)
{
if (__pos >= _Nb)
__throw_out_of_range("bitset");
return _Unchecked_reset(__pos);
}
bitset<_Nb>& flip() { bitset<_Nb>&
this->_M_do_flip(); flip()
this->_M_do_sanitize(); {
return *this; this->_M_do_flip();
} this->_M_do_sanitize();
return *this;
}
bitset<_Nb>& flip(size_t __pos) { bitset<_Nb>&
if (__pos >= _Nb) flip(size_t __pos)
__throw_out_of_range("bitset"); {
if (__pos >= _Nb)
__throw_out_of_range("bitset");
return _Unchecked_flip(__pos);
}
return _Unchecked_flip(__pos); bitset<_Nb>
} operator~() const { return bitset<_Nb>(*this).flip(); }
// element access:
//for b[i];
// _GLIBCPP_RESOLVE_LIB_DEFECTS Note that this implementation already
// resolves DR 11 (items 1 and 2), but does not do the range-checking
// required by that DR's resolution. -pme
reference
operator[](size_t __pos) { return reference(*this,__pos); }
bool
operator[](size_t __pos) const { return _Unchecked_test(__pos); }
unsigned long
to_ulong() const { return this->_M_do_to_ulong(); }
template<class _CharT, class _Traits, class _Alloc>
basic_string<_CharT, _Traits, _Alloc>
to_string() const
{
basic_string<_CharT, _Traits, _Alloc> __result;
_M_copy_to_string(__result);
return __result;
}
bitset<_Nb> operator~() const { // Helper functions for string operations.
return bitset<_Nb>(*this).flip(); template<class _CharT, class _Traits, class _Alloc>
} void
_M_copy_from_string(const basic_string<_CharT,_Traits,_Alloc>& __s,
size_t, size_t);
// element access: template<class _CharT, class _Traits, class _Alloc>
//for b[i]; void
// _GLIBCPP_RESOLVE_LIB_DEFECTS Note that this implementation already _M_copy_to_string(basic_string<_CharT,_Traits,_Alloc>&) const;
// resolves DR 11 (items 1 and 2), but does not do the range-checking
// required by that DR's resolution. -pme
reference operator[](size_t __pos) { return reference(*this,__pos); }
bool operator[](size_t __pos) const { return _Unchecked_test(__pos); }
unsigned long to_ulong() const { return this->_M_do_to_ulong(); } size_t
count() const { return this->_M_do_count(); }
template <class _CharT, class _Traits, class _Alloc> size_t
basic_string<_CharT, _Traits, _Alloc> to_string() const { size() const { return _Nb; }
basic_string<_CharT, _Traits, _Alloc> __result;
_M_copy_to_string(__result);
return __result;
}
// Helper functions for string operations. bool
template<class _CharT, class _Traits, class _Alloc> operator==(const bitset<_Nb>& __rhs) const
void _M_copy_from_string(const basic_string<_CharT,_Traits,_Alloc>& __s, { return this->_M_is_equal(__rhs); }
size_t,
size_t);
template<class _CharT, class _Traits, class _Alloc> bool
void _M_copy_to_string(basic_string<_CharT,_Traits,_Alloc>&) const; operator!=(const bitset<_Nb>& __rhs) const
{ return !this->_M_is_equal(__rhs); }
size_t count() const { return this->_M_do_count(); } bool
test(size_t __pos) const
{
if (__pos >= _Nb)
__throw_out_of_range("bitset");
return _Unchecked_test(__pos);
}
size_t size() const { return _Nb; } bool
any() const { return this->_M_is_any(); }
bool operator==(const bitset<_Nb>& __rhs) const { bool
return this->_M_is_equal(__rhs); none() const { return !this->_M_is_any(); }
}
bool operator!=(const bitset<_Nb>& __rhs) const {
return !this->_M_is_equal(__rhs);
}
bool test(size_t __pos) const { bitset<_Nb>
if (__pos >= _Nb) operator<<(size_t __pos) const
__throw_out_of_range("bitset");
return _Unchecked_test(__pos);
}
bool any() const { return this->_M_is_any(); }
bool none() const { return !this->_M_is_any(); }
bitset<_Nb> operator<<(size_t __pos) const
{ return bitset<_Nb>(*this) <<= __pos; } { return bitset<_Nb>(*this) <<= __pos; }
bitset<_Nb> operator>>(size_t __pos) const
bitset<_Nb>
operator>>(size_t __pos) const
{ return bitset<_Nb>(*this) >>= __pos; } { return bitset<_Nb>(*this) >>= __pos; }
// // EXTENSIONS: bit-find operations. These operations are
// EXTENSIONS: bit-find operations. These operations are // experimental, and are subject to change or removal in future
// experimental, and are subject to change or removal in future // versions.
// versions.
//
// find the index of the first "on" bit // find the index of the first "on" bit
size_t _Find_first() const size_t
_Find_first() const
{ return this->_M_do_find_first(_Nb); } { return this->_M_do_find_first(_Nb); }
// find the index of the next "on" bit after prev // find the index of the next "on" bit after prev
size_t _Find_next( size_t __prev ) const size_t
_Find_next(size_t __prev ) const
{ return this->_M_do_find_next(__prev, _Nb); } { return this->_M_do_find_next(__prev, _Nb); }
};
}; // Definitions of non-inline member functions.
template<size_t _Nb>
// template<class _CharT, class _Traits, class _Alloc>
// Definitions of non-inline member functions. void
// bitset<_Nb>::_M_copy_from_string(const basic_string<_CharT,_Traits,_Alloc>& __s, size_t __pos, size_t __n)
{
template <size_t _Nb> reset();
template<class _CharT, class _Traits, class _Alloc> const size_t __nbits = min(_Nb, min(__n, __s.size() - __pos));
void bitset<_Nb> for (size_t __i = 0; __i < __nbits; ++__i)
::_M_copy_from_string(const basic_string<_CharT,_Traits,_Alloc>& __s, {
size_t __pos, switch(__s[__pos + __nbits - __i - 1])
size_t __n) {
{ case '0':
reset(); break;
const size_t __nbits = min(_Nb, min(__n, __s.size() - __pos)); case '1':
for (size_t __i = 0; __i < __nbits; ++__i) { set(__i);
switch(__s[__pos + __nbits - __i - 1]) { break;
case '0': default:
break; __throw_invalid_argument("bitset");
case '1': }
set(__i); }
break;
default:
__throw_invalid_argument("bitset");
} }
}
}
template <size_t _Nb>
template <class _CharT, class _Traits, class _Alloc>
void bitset<_Nb>
::_M_copy_to_string(basic_string<_CharT, _Traits, _Alloc>& __s) const
{
__s.assign(_Nb, '0');
for (size_t __i = 0; __i < _Nb; ++__i)
if (_Unchecked_test(__i))
__s[_Nb - 1 - __i] = '1';
}
// ------------------------------------------------------------ template<size_t _Nb>
template<class _CharT, class _Traits, class _Alloc>
// void
// 23.3.5.3 bitset operations: bitset<_Nb>::_M_copy_to_string(basic_string<_CharT, _Traits, _Alloc>& __s) const
// {
__s.assign(_Nb, '0');
for (size_t __i = 0; __i < _Nb; ++__i)
if (_Unchecked_test(__i))
__s[_Nb - 1 - __i] = '1';
}
template <size_t _Nb> // 23.3.5.3 bitset operations:
inline bitset<_Nb> operator&(const bitset<_Nb>& __x, const bitset<_Nb>& __y) { template<size_t _Nb>
bitset<_Nb> __result(__x); inline bitset<_Nb>
__result &= __y; operator&(const bitset<_Nb>& __x, const bitset<_Nb>& __y)
return __result; {
} bitset<_Nb> __result(__x);
__result &= __y;
return __result;
template <size_t _Nb>
inline bitset<_Nb> operator|(const bitset<_Nb>& __x, const bitset<_Nb>& __y) {
bitset<_Nb> __result(__x);
__result |= __y;
return __result;
}
template <size_t _Nb>
inline bitset<_Nb> operator^(const bitset<_Nb>& __x, const bitset<_Nb>& __y) {
bitset<_Nb> __result(__x);
__result ^= __y;
return __result;
}
template <class _CharT, class _Traits, size_t _Nb>
basic_istream<_CharT, _Traits>&
operator>>(basic_istream<_CharT, _Traits>& __is, bitset<_Nb>& __x)
{
typedef typename _Traits::char_type char_type;
basic_string<_CharT, _Traits> __tmp;
__tmp.reserve(_Nb);
// Skip whitespace
typename basic_istream<_CharT, _Traits>::sentry __sentry(__is);
if (__sentry) {
basic_streambuf<_CharT, _Traits>* __buf = __is.rdbuf();
for (size_t __i = 0; __i < _Nb; ++__i) {
static typename _Traits::int_type __eof = _Traits::eof();
typename _Traits::int_type __c1 = __buf->sbumpc();
if (_Traits::eq_int_type(__c1, __eof)) {
__is.setstate(ios_base::eofbit);
break;
}
else {
char_type __c2 = _Traits::to_char_type(__c1);
char_type __c = __is.narrow(__c2, '*');
if (__c == '0' || __c == '1')
__tmp.push_back(__c);
else if (_Traits::eq_int_type(__buf->sputbackc(__c2), __eof)) {
__is.setstate(ios_base::failbit);
break;
}
}
} }
if (__tmp.empty()) template<size_t _Nb>
__is.setstate(ios_base::failbit); inline bitset<_Nb>
else operator|(const bitset<_Nb>& __x, const bitset<_Nb>& __y)
__x._M_copy_from_string(__tmp, static_cast<size_t>(0), _Nb); {
} bitset<_Nb> __result(__x);
__result |= __y;
return __result;
}
return __is; template <size_t _Nb>
} inline bitset<_Nb>
operator^(const bitset<_Nb>& __x, const bitset<_Nb>& __y)
{
bitset<_Nb> __result(__x);
__result ^= __y;
return __result;
}
template <class _CharT, class _Traits, size_t _Nb> template<class _CharT, class _Traits, size_t _Nb>
basic_ostream<_CharT, _Traits>& basic_istream<_CharT, _Traits>&
operator<<(basic_ostream<_CharT, _Traits>& __os, const bitset<_Nb>& __x) operator>>(basic_istream<_CharT, _Traits>& __is, bitset<_Nb>& __x)
{ {
basic_string<_CharT, _Traits> __tmp; typedef typename _Traits::char_type char_type;
__x._M_copy_to_string(__tmp); basic_string<_CharT, _Traits> __tmp;
return __os << __tmp; __tmp.reserve(_Nb);
}
// Skip whitespace
typename basic_istream<_CharT, _Traits>::sentry __sentry(__is);
if (__sentry)
{
basic_streambuf<_CharT, _Traits>* __buf = __is.rdbuf();
for (size_t __i = 0; __i < _Nb; ++__i)
{
static typename _Traits::int_type __eof = _Traits::eof();
typename _Traits::int_type __c1 = __buf->sbumpc();
if (_Traits::eq_int_type(__c1, __eof))
{
__is.setstate(ios_base::eofbit);
break;
}
else
{
char_type __c2 = _Traits::to_char_type(__c1);
char_type __c = __is.narrow(__c2, '*');
if (__c == '0' || __c == '1')
__tmp.push_back(__c);
else if (_Traits::eq_int_type(__buf->sputbackc(__c2),
__eof))
{
__is.setstate(ios_base::failbit);
break;
}
}
}
if (__tmp.empty())
__is.setstate(ios_base::failbit);
else
__x._M_copy_from_string(__tmp, static_cast<size_t>(0), _Nb);
}
return __is;
}
template <class _CharT, class _Traits, size_t _Nb>
basic_ostream<_CharT, _Traits>&
operator<<(basic_ostream<_CharT, _Traits>& __os, const bitset<_Nb>& __x)
{
basic_string<_CharT, _Traits> __tmp;
__x._M_copy_to_string(__tmp);
return __os << __tmp;
}
} // namespace std } // namespace std
#undef __BITSET_WORDS #undef __BITSET_WORDS
#endif /* __GLIBCPP_BITSET */ #endif
// Local Variables:
// mode:C++
// End:
libstdc++-v3/src/bitset.cc
// Bitset definitions -*- C++ -*- // Bitset definitions -*- C++ -*-
// Copyright (C) 2001 Free Software Foundation // Copyright (C) 2001, 2002 Free Software Foundation
// //
// This file is part of GNU CC. // This file is part of GNU CC.
// //
...@@ -59,7 +59,7 @@ std::_Base_bitset<1>::_M_do_find_first(std::size_t __not_found) const ...@@ -59,7 +59,7 @@ std::_Base_bitset<1>::_M_do_find_first(std::size_t __not_found) const
unsigned char __this_byte unsigned char __this_byte
= static_cast<unsigned char>(__thisword & (~(unsigned char)0)); = static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if ( __this_byte ) if ( __this_byte )
return __j*CHAR_BIT + _First_one<true>::_S_first_one[__this_byte]; return __j * CHAR_BIT + _S_first_one[__this_byte];
__thisword >>= CHAR_BIT; __thisword >>= CHAR_BIT;
} }
...@@ -93,7 +93,7 @@ std::_Base_bitset<1>::_M_do_find_next(std::size_t __prev, ...@@ -93,7 +93,7 @@ std::_Base_bitset<1>::_M_do_find_next(std::size_t __prev,
unsigned char __this_byte unsigned char __this_byte
= static_cast<unsigned char>(__thisword & (~(unsigned char)0)); = static_cast<unsigned char>(__thisword & (~(unsigned char)0));
if ( __this_byte ) if ( __this_byte )
return __j*CHAR_BIT + _First_one<true>::_S_first_one[__this_byte]; return __j * CHAR_BIT + _S_first_one[__this_byte];
__thisword >>= CHAR_BIT; __thisword >>= CHAR_BIT;
} }
...@@ -103,11 +103,10 @@ std::_Base_bitset<1>::_M_do_find_next(std::size_t __prev, ...@@ -103,11 +103,10 @@ std::_Base_bitset<1>::_M_do_find_next(std::size_t __prev,
return __not_found; return __not_found;
} // end _M_do_find_next } // end _M_do_find_next
// ------------------------------------------------------------
// Lookup tables for find and count operations.
template<bool __dummy> // Lookup tables for find and count operations.
unsigned char std::_Bit_count<__dummy>::_S_bit_count[] = { unsigned char std::_S_bit_count[256] =
{
0, /* 0 */ 1, /* 1 */ 1, /* 2 */ 2, /* 3 */ 1, /* 4 */ 0, /* 0 */ 1, /* 1 */ 1, /* 2 */ 2, /* 3 */ 1, /* 4 */
2, /* 5 */ 2, /* 6 */ 3, /* 7 */ 1, /* 8 */ 2, /* 9 */ 2, /* 5 */ 2, /* 6 */ 3, /* 7 */ 1, /* 8 */ 2, /* 9 */
2, /* 10 */ 3, /* 11 */ 2, /* 12 */ 3, /* 13 */ 3, /* 14 */ 2, /* 10 */ 3, /* 11 */ 2, /* 12 */ 3, /* 13 */ 3, /* 14 */
...@@ -160,10 +159,10 @@ unsigned char std::_Bit_count<__dummy>::_S_bit_count[] = { ...@@ -160,10 +159,10 @@ unsigned char std::_Bit_count<__dummy>::_S_bit_count[] = {
6, /* 245 */ 6, /* 246 */ 7, /* 247 */ 5, /* 248 */ 6, /* 249 */ 6, /* 245 */ 6, /* 246 */ 7, /* 247 */ 5, /* 248 */ 6, /* 249 */
6, /* 250 */ 7, /* 251 */ 6, /* 252 */ 7, /* 253 */ 7, /* 254 */ 6, /* 250 */ 7, /* 251 */ 6, /* 252 */ 7, /* 253 */ 7, /* 254 */
8 /* 255 */ 8 /* 255 */
}; // end _Bit_count }; // end _S_bit_count
template<bool __dummy> unsigned char std::_S_first_one[256] =
unsigned char std::_First_one<__dummy>::_S_first_one[] = { {
0, /* 0 */ 0, /* 1 */ 1, /* 2 */ 0, /* 3 */ 2, /* 4 */ 0, /* 0 */ 0, /* 1 */ 1, /* 2 */ 0, /* 3 */ 2, /* 4 */
0, /* 5 */ 1, /* 6 */ 0, /* 7 */ 3, /* 8 */ 0, /* 9 */ 0, /* 5 */ 1, /* 6 */ 0, /* 7 */ 3, /* 8 */ 0, /* 9 */
1, /* 10 */ 0, /* 11 */ 2, /* 12 */ 0, /* 13 */ 1, /* 14 */ 1, /* 10 */ 0, /* 11 */ 2, /* 12 */ 0, /* 13 */ 1, /* 14 */
...@@ -216,12 +215,5 @@ unsigned char std::_First_one<__dummy>::_S_first_one[] = { ...@@ -216,12 +215,5 @@ unsigned char std::_First_one<__dummy>::_S_first_one[] = {
0, /* 245 */ 1, /* 246 */ 0, /* 247 */ 3, /* 248 */ 0, /* 249 */ 0, /* 245 */ 1, /* 246 */ 0, /* 247 */ 3, /* 248 */ 0, /* 249 */
1, /* 250 */ 0, /* 251 */ 2, /* 252 */ 0, /* 253 */ 1, /* 254 */ 1, /* 250 */ 0, /* 251 */ 2, /* 252 */ 0, /* 253 */ 1, /* 254 */
0, /* 255 */ 0, /* 255 */
}; // end _First_one }; // end _S_first_one
// Explicitly instantiate them.
template unsigned char std::_Bit_count<false>::_S_bit_count[];
template unsigned char std::_Bit_count<true>::_S_bit_count[];
template unsigned char std::_First_one<false>::_S_first_one[];
template unsigned char std::_First_one<true>::_S_first_one[];
libstdc++-v3/testsuite/23_containers/bitset_members.cc
...@@ -45,9 +45,16 @@ test01(void) ...@@ -45,9 +45,16 @@ test01(void)
VERIFY( test ); VERIFY( test );
} }
// libstdc++/6124
void test02()
{
std::bitset<1> bs;
bs.count();
}
int main() int main()
{ {
test01(); test01();
test02();
return 0; return 0;
} }
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