// Debugging mode support code -*- C++ -*-
// Copyright (C) 2003-2019 Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library. This library is free
// software; you can redistribute it and/or modify it under the
// terms of the GNU General Public License as published by the
// Free Software Foundation; either version 3, or (at your option)
// any later version.
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.
// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
// .
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include // for std::isspace
#include // for std::min
#include // for __cxa_demangle
// libstdc++/85768
#if 0 // defined _GLIBCXX_HAVE_EXECINFO_H
# include // for backtrace
#endif
#include "mutex_pool.h"
using namespace std;
namespace
{
/** Returns different instances of __mutex depending on the passed address
* in order to limit contention without breaking current library binary
* compatibility. */
__gnu_cxx::__mutex&
get_safe_base_mutex(void* address)
{
// Use arbitrarily __gnu_debug::vector as the container giving
// alignment of debug containers.
const auto alignbits = __builtin_ctz(alignof(__gnu_debug::vector));
const unsigned char index
= (reinterpret_cast(address) >> alignbits)
& __gnu_internal::mask;
return __gnu_internal::get_mutex(index);
}
#pragma GCC diagnostic push
// Suppress -Wabi=2 warnings due to PR c++/51322 mangling change
#pragma GCC diagnostic warning "-Wabi=6"
void
swap_its(__gnu_debug::_Safe_sequence_base& __lhs,
__gnu_debug::_Safe_iterator_base*& __lhs_its,
__gnu_debug::_Safe_sequence_base& __rhs,
__gnu_debug::_Safe_iterator_base*& __rhs_its)
{
swap(__lhs_its, __rhs_its);
__gnu_debug::_Safe_iterator_base* __iter;
for (__iter = __rhs_its; __iter; __iter = __iter->_M_next)
__iter->_M_sequence = &__rhs;
for (__iter = __lhs_its; __iter; __iter = __iter->_M_next)
__iter->_M_sequence = &__lhs;
}
void
swap_seq_single(__gnu_debug::_Safe_sequence_base& __lhs,
__gnu_debug::_Safe_sequence_base& __rhs)
{
swap(__lhs._M_version, __rhs._M_version);
swap_its(__lhs, __lhs._M_iterators,
__rhs, __rhs._M_iterators);
swap_its(__lhs, __lhs._M_const_iterators,
__rhs, __rhs._M_const_iterators);
}
#pragma GCC diagnostic pop
template
void
lock_and_run(__gnu_cxx::__mutex& lhs_mutex, __gnu_cxx::__mutex& rhs_mutex,
_Action action)
{
// We need to lock both sequences to run action.
if (&lhs_mutex == &rhs_mutex)
{
__gnu_cxx::__scoped_lock sentry(lhs_mutex);
action();
}
else
{
__gnu_cxx::__scoped_lock sentry1(&lhs_mutex < &rhs_mutex
? lhs_mutex : rhs_mutex);
__gnu_cxx::__scoped_lock sentry2(&lhs_mutex < &rhs_mutex
? rhs_mutex : lhs_mutex);
action();
}
}
void
swap_seq(__gnu_cxx::__mutex& lhs_mutex,
__gnu_debug::_Safe_sequence_base& lhs,
__gnu_cxx::__mutex& rhs_mutex,
__gnu_debug::_Safe_sequence_base& rhs)
{
lock_and_run(lhs_mutex, rhs_mutex,
[&lhs, &rhs]() { swap_seq_single(lhs, rhs); });
}
void
swap_ucont_single(__gnu_debug::_Safe_unordered_container_base& __lhs,
__gnu_debug::_Safe_unordered_container_base& __rhs)
{
swap_seq_single(__lhs, __rhs);
swap_its(__lhs, __lhs._M_local_iterators,
__rhs, __rhs._M_local_iterators);
swap_its(__lhs, __lhs._M_const_local_iterators,
__rhs, __rhs._M_const_local_iterators);
}
void
swap_ucont(__gnu_cxx::__mutex& lhs_mutex,
__gnu_debug::_Safe_unordered_container_base& lhs,
__gnu_cxx::__mutex& rhs_mutex,
__gnu_debug::_Safe_unordered_container_base& rhs)
{
lock_and_run(lhs_mutex, rhs_mutex,
[&lhs, &rhs]() { swap_ucont_single(lhs, rhs); });
}
void
detach_all(__gnu_debug::_Safe_iterator_base* __iter)
{
for (; __iter;)
{
__gnu_debug::_Safe_iterator_base* __old = __iter;
__iter = __iter->_M_next;
__old->_M_reset();
}
}
} // anonymous namespace
namespace __gnu_debug
{
const char* const _S_debug_messages[] =
{
// General Checks
"function requires a valid iterator range [%1.name;, %2.name;)",
"attempt to insert into container with a singular iterator",
"attempt to insert into container with an iterator"
" from a different container",
"attempt to erase from container with a %2.state; iterator",
"attempt to erase from container with an iterator"
" from a different container",
"attempt to subscript container with out-of-bounds index %2;,"
" but container only holds %3; elements",
"attempt to access an element in an empty container",
"elements in iterator range [%1.name;, %2.name;)"
" are not partitioned by the value %3;",
"elements in iterator range [%1.name;, %2.name;)"
" are not partitioned by the predicate %3; and value %4;",
"elements in iterator range [%1.name;, %2.name;) are not sorted",
"elements in iterator range [%1.name;, %2.name;)"
" are not sorted according to the predicate %3;",
"elements in iterator range [%1.name;, %2.name;) do not form a heap",
"elements in iterator range [%1.name;, %2.name;)"
" do not form a heap with respect to the predicate %3;",
// std::bitset checks
"attempt to write through a singular bitset reference",
"attempt to read from a singular bitset reference",
"attempt to flip a singular bitset reference",
// std::list checks
"attempt to splice a list into itself",
"attempt to splice lists with unequal allocators",
"attempt to splice elements referenced by a %1.state; iterator",
"attempt to splice an iterator from a different container",
"splice destination %1.name;"
" occurs within source range [%2.name;, %3.name;)",
// iterator checks
"attempt to initialize an iterator that will immediately become singular",
"attempt to copy-construct an iterator from a singular iterator",
"attempt to construct a constant iterator"
" from a singular mutable iterator",
"attempt to copy from a singular iterator",
"attempt to dereference a %1.state; iterator",
"attempt to increment a %1.state; iterator",
"attempt to decrement a %1.state; iterator",
"attempt to subscript a %1.state; iterator %2; step from"
" its current position, which falls outside its dereferenceable range",
"attempt to advance a %1.state; iterator %2; steps,"
" which falls outside its valid range",
"attempt to retreat a %1.state; iterator %2; steps,"
" which falls outside its valid range",
"attempt to compare a %1.state; iterator to a %2.state; iterator",
"attempt to compare iterators from different sequences",
"attempt to order a %1.state; iterator to a %2.state; iterator",
"attempt to order iterators from different sequences",
"attempt to compute the difference between a %1.state;"
" iterator to a %2.state; iterator",
"attempt to compute the different between two iterators"
" from different sequences",
// istream_iterator
"attempt to dereference an end-of-stream istream_iterator",
"attempt to increment an end-of-stream istream_iterator",
// ostream_iterator
"attempt to output via an ostream_iterator with no associated stream",
// istreambuf_iterator
"attempt to dereference an end-of-stream istreambuf_iterator"
" (this is a GNU extension)",
"attempt to increment an end-of-stream istreambuf_iterator",
// std::forward_list
"attempt to insert into container after an end iterator",
"attempt to erase from container after a %2.state; iterator not followed"
" by a dereferenceable one",
"function requires a valid iterator range (%2.name;, %3.name;)"
", \"%2.name;\" shall be before and not equal to \"%3.name;\"",
// std::unordered_container::local_iterator
"attempt to compare local iterators from different unordered container"
" buckets",
"function requires a non-empty iterator range [%1.name;, %2.name;)",
"attempt to self move assign",
"attempt to access container with out-of-bounds bucket index %2;,"
" container only holds %3; buckets",
"load factor shall be positive",
"allocators must be equal",
"attempt to insert with an iterator range [%1.name;, %2.name;) from this"
" container",
"comparison doesn't meet irreflexive requirements, assert(!(a < a))"
};
void
_Safe_sequence_base::
_M_detach_all()
{
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
detach_all(_M_iterators);
_M_iterators = 0;
detach_all(_M_const_iterators);
_M_const_iterators = 0;
}
void
_Safe_sequence_base::
_M_detach_singular()
{
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
for (_Safe_iterator_base* __iter = _M_iterators; __iter;)
{
_Safe_iterator_base* __old = __iter;
__iter = __iter->_M_next;
if (__old->_M_singular())
__old->_M_detach_single();
}
for (_Safe_iterator_base* __iter2 = _M_const_iterators; __iter2;)
{
_Safe_iterator_base* __old = __iter2;
__iter2 = __iter2->_M_next;
if (__old->_M_singular())
__old->_M_detach_single();
}
}
void
_Safe_sequence_base::
_M_revalidate_singular()
{
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
for (_Safe_iterator_base* __iter = _M_iterators; __iter;
__iter = __iter->_M_next)
__iter->_M_version = _M_version;
for (_Safe_iterator_base* __iter2 = _M_const_iterators; __iter2;
__iter2 = __iter2->_M_next)
__iter2->_M_version = _M_version;
}
void
_Safe_sequence_base::
_M_swap(_Safe_sequence_base& __x) noexcept
{ swap_seq(_M_get_mutex(), *this, __x._M_get_mutex(), __x); }
__gnu_cxx::__mutex&
_Safe_sequence_base::
_M_get_mutex() throw ()
{ return get_safe_base_mutex(this); }
void
_Safe_sequence_base::
_M_attach(_Safe_iterator_base* __it, bool __constant)
{
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
_M_attach_single(__it, __constant);
}
void
_Safe_sequence_base::
_M_attach_single(_Safe_iterator_base* __it, bool __constant) throw ()
{
_Safe_iterator_base*& __its =
__constant ? _M_const_iterators : _M_iterators;
__it->_M_next = __its;
if (__it->_M_next)
__it->_M_next->_M_prior = __it;
__its = __it;
}
void
_Safe_sequence_base::
_M_detach(_Safe_iterator_base* __it)
{
// Remove __it from this sequence's list
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
_M_detach_single(__it);
}
void
_Safe_sequence_base::
_M_detach_single(_Safe_iterator_base* __it) throw ()
{
// Remove __it from this sequence's list
__it->_M_unlink();
if (_M_const_iterators == __it)
_M_const_iterators = __it->_M_next;
if (_M_iterators == __it)
_M_iterators = __it->_M_next;
}
void
_Safe_iterator_base::
_M_attach(_Safe_sequence_base* __seq, bool __constant)
{
_M_detach();
// Attach to the new sequence (if there is one)
if (__seq)
{
_M_sequence = __seq;
_M_version = _M_sequence->_M_version;
_M_sequence->_M_attach(this, __constant);
}
}
void
_Safe_iterator_base::
_M_attach_single(_Safe_sequence_base* __seq, bool __constant) throw ()
{
_M_detach_single();
// Attach to the new sequence (if there is one)
if (__seq)
{
_M_sequence = __seq;
_M_version = _M_sequence->_M_version;
_M_sequence->_M_attach_single(this, __constant);
}
}
void
_Safe_iterator_base::
_M_detach()
{
// This function can run concurrently with the sequence destructor,
// so there is a TOCTTOU race here: the sequence could be destroyed
// after we check that _M_sequence is not null. Use the pointer value
// to acquire the mutex (rather than via _M_sequence->_M_get_mutex()).
// If the sequence destructor runs between loading the pointer and
// locking the mutex, it will detach this iterator and set _M_sequence
// to null, and then _M_detach_single() will do nothing.
if (auto seq = __atomic_load_n(&_M_sequence, __ATOMIC_ACQUIRE))
{
__gnu_cxx::__scoped_lock sentry(get_safe_base_mutex(seq));
_M_detach_single();
}
}
void
_Safe_iterator_base::
_M_detach_single() throw ()
{
if (_M_sequence)
{
_M_sequence->_M_detach_single(this);
_M_reset();
}
}
void
_Safe_iterator_base::
_M_reset() throw ()
{
__atomic_store_n(&_M_sequence, (_Safe_sequence_base*)0, __ATOMIC_RELEASE);
_M_version = 0;
_M_prior = 0;
_M_next = 0;
}
bool
_Safe_iterator_base::
_M_singular() const throw ()
{ return !_M_sequence || _M_version != _M_sequence->_M_version; }
bool
_Safe_iterator_base::
_M_can_compare(const _Safe_iterator_base& __x) const throw ()
{
return (!_M_singular()
&& !__x._M_singular() && _M_sequence == __x._M_sequence);
}
__gnu_cxx::__mutex&
_Safe_iterator_base::
_M_get_mutex() throw ()
{ return _M_sequence->_M_get_mutex(); }
_Safe_unordered_container_base*
_Safe_local_iterator_base::
_M_get_container() const noexcept
{ return static_cast<_Safe_unordered_container_base*>(_M_sequence); }
void
_Safe_local_iterator_base::
_M_attach(_Safe_sequence_base* __cont, bool __constant)
{
_M_detach();
// Attach to the new container (if there is one)
if (__cont)
{
_M_sequence = __cont;
_M_version = _M_sequence->_M_version;
_M_get_container()->_M_attach_local(this, __constant);
}
}
void
_Safe_local_iterator_base::
_M_attach_single(_Safe_sequence_base* __cont, bool __constant) throw ()
{
_M_detach_single();
// Attach to the new container (if there is one)
if (__cont)
{
_M_sequence = __cont;
_M_version = _M_sequence->_M_version;
_M_get_container()->_M_attach_local_single(this, __constant);
}
}
void
_Safe_local_iterator_base::
_M_detach()
{
if (auto seq = __atomic_load_n(&_M_sequence, __ATOMIC_ACQUIRE))
{
__gnu_cxx::__scoped_lock sentry(get_safe_base_mutex(seq));
_M_detach_single();
}
}
void
_Safe_local_iterator_base::
_M_detach_single() throw ()
{
if (_M_sequence)
{
_M_get_container()->_M_detach_local_single(this);
_M_reset();
}
}
void
_Safe_unordered_container_base::
_M_detach_all()
{
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
detach_all(_M_iterators);
_M_iterators = 0;
detach_all(_M_const_iterators);
_M_const_iterators = 0;
detach_all(_M_local_iterators);
_M_local_iterators = 0;
detach_all(_M_const_local_iterators);
_M_const_local_iterators = 0;
}
void
_Safe_unordered_container_base::
_M_swap(_Safe_unordered_container_base& __x) noexcept
{ swap_ucont(_M_get_mutex(), *this, __x._M_get_mutex(), __x); }
void
_Safe_unordered_container_base::
_M_attach_local(_Safe_iterator_base* __it, bool __constant)
{
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
_M_attach_local_single(__it, __constant);
}
void
_Safe_unordered_container_base::
_M_attach_local_single(_Safe_iterator_base* __it, bool __constant) throw ()
{
_Safe_iterator_base*& __its =
__constant ? _M_const_local_iterators : _M_local_iterators;
__it->_M_next = __its;
if (__it->_M_next)
__it->_M_next->_M_prior = __it;
__its = __it;
}
void
_Safe_unordered_container_base::
_M_detach_local(_Safe_iterator_base* __it)
{
// Remove __it from this container's list
__gnu_cxx::__scoped_lock sentry(_M_get_mutex());
_M_detach_local_single(__it);
}
void
_Safe_unordered_container_base::
_M_detach_local_single(_Safe_iterator_base* __it) throw ()
{
// Remove __it from this container's list
__it->_M_unlink();
if (_M_const_local_iterators == __it)
_M_const_local_iterators = __it->_M_next;
if (_M_local_iterators == __it)
_M_local_iterators = __it->_M_next;
}
}
namespace
{
using _Error_formatter = __gnu_debug::_Error_formatter;
using _Parameter = __gnu_debug::_Error_formatter::_Parameter;
void
get_max_length(std::size_t& max_length)
{
const char* nptr = std::getenv("GLIBCXX_DEBUG_MESSAGE_LENGTH");
if (nptr)
{
char* endptr;
const unsigned long ret = std::strtoul(nptr, &endptr, 0);
if (*nptr != '\0' && *endptr == '\0')
max_length = ret;
}
}
struct PrintContext
{
PrintContext()
: _M_max_length(78), _M_column(1), _M_first_line(true), _M_wordwrap(false)
{ get_max_length(_M_max_length); }
std::size_t _M_max_length;
enum { _M_indent = 4 } ;
std::size_t _M_column;
bool _M_first_line;
bool _M_wordwrap;
};
template
void
print_literal(PrintContext& ctx, const char(&word)[Length])
{ print_word(ctx, word, Length - 1); }
void
print_word(PrintContext& ctx, const char* word,
std::ptrdiff_t count = -1)
{
size_t length = count >= 0 ? count : __builtin_strlen(word);
if (length == 0)
return;
// Consider first '\n' at begining cause it impacts column.
if (word[0] == '\n')
{
fprintf(stderr, "\n");
ctx._M_column = 1;
++word;
--length;
if (length == 0)
return;
}
size_t visual_length
= isspace(word[length - 1]) ? length - 1 : length;
if (visual_length == 0
|| !ctx._M_wordwrap
|| (ctx._M_column + visual_length < ctx._M_max_length)
|| (visual_length >= ctx._M_max_length && ctx._M_column == 1))
{
// If this isn't the first line, indent
if (ctx._M_column == 1 && !ctx._M_first_line)
{
char spacing[ctx._M_indent + 1];
for (int i = 0; i < ctx._M_indent; ++i)
spacing[i] = ' ';
spacing[ctx._M_indent] = '\0';
fprintf(stderr, "%s", spacing);
ctx._M_column += ctx._M_indent;
}
int written = fprintf(stderr, "%s", word);
if (word[length - 1] == '\n')
{
ctx._M_first_line = false;
ctx._M_column = 1;
}
else
ctx._M_column += written;
}
else
{
print_literal(ctx, "\n");
print_word(ctx, word, count);
}
}
template
void
print_type(PrintContext& ctx,
const type_info* info,
const char(&unknown_name)[Length])
{
if (!info)
print_literal(ctx, unknown_name);
else
{
int status;
char* demangled_name =
__cxxabiv1::__cxa_demangle(info->name(), NULL, NULL, &status);
print_word(ctx, status == 0 ? demangled_name : info->name());
free(demangled_name);
}
}
bool
print_field(PrintContext& ctx,
const char* name, const _Parameter::_Type& type)
{
if (__builtin_strcmp(name, "name") == 0)
{
assert(type._M_name);
print_word(ctx, type._M_name);
}
else if (__builtin_strcmp(name, "type") == 0)
print_type(ctx, type._M_type, "");
else
return false;
return true;
}
bool
print_field(PrintContext& ctx,
const char* name, const _Parameter::_Instance& inst)
{
const _Parameter::_Type& type = inst;
if (print_field(ctx, name, type))
{ }
else if (__builtin_strcmp(name, "address") == 0)
{
char buf[64];
int ret = __builtin_sprintf(buf, "%p", inst._M_address);
print_word(ctx, buf, ret);
}
else
return false;
return true;
}
void
print_field(PrintContext& ctx, const _Parameter& param, const char* name)
{
assert(param._M_kind != _Parameter::__unused_param);
const int bufsize = 64;
char buf[bufsize];
const auto& variant = param._M_variant;
switch (param._M_kind)
{
case _Parameter::__iterator:
{
const auto& iterator = variant._M_iterator;
if (print_field(ctx, name, iterator))
{ }
else if (__builtin_strcmp(name, "constness") == 0)
{
static const char*
constness_names[_Error_formatter::__last_constness] =
{
"",
"constant",
"mutable"
};
print_word(ctx, constness_names[iterator._M_constness]);
}
else if (__builtin_strcmp(name, "state") == 0)
{
static const char*
state_names[_Error_formatter::__last_state] =
{
"",
"singular",
"dereferenceable (start-of-sequence)",
"dereferenceable",
"past-the-end",
"before-begin",
"dereferenceable (start-of-reverse-sequence)",
"dereferenceable (reverse)",
"past-the-reverse-end"
};
print_word(ctx, state_names[iterator._M_state]);
}
else if (__builtin_strcmp(name, "sequence") == 0)
{
assert(iterator._M_sequence);
int written = __builtin_sprintf(buf, "%p", iterator._M_sequence);
print_word(ctx, buf, written);
}
else if (__builtin_strcmp(name, "seq_type") == 0)
print_type(ctx, iterator._M_seq_type, "");
else
assert(false);
}
break;
case _Parameter::__sequence:
if (!print_field(ctx, name, variant._M_sequence))
assert(false);
break;
case _Parameter::__integer:
if (__builtin_strcmp(name, "name") == 0)
{
assert(variant._M_integer._M_name);
print_word(ctx, variant._M_integer._M_name);
}
else
assert(false);
break;
case _Parameter::__string:
if (__builtin_strcmp(name, "name") == 0)
{
assert(variant._M_string._M_name);
print_word(ctx, variant._M_string._M_name);
}
else
assert(false);
break;
case _Parameter::__instance:
if (!print_field(ctx, name, variant._M_instance))
assert(false);
break;
case _Parameter::__iterator_value_type:
if (!print_field(ctx, name, variant._M_iterator_value_type))
assert(false);
break;
default:
assert(false);
break;
}
}
void
print_description(PrintContext& ctx, const _Parameter::_Type& type)
{
if (type._M_name)
{
print_literal(ctx, "\"");
print_word(ctx, type._M_name);
print_literal(ctx, "\"");
}
print_literal(ctx, " {\n");
if (type._M_type)
{
print_literal(ctx, " type = ");
print_type(ctx, type._M_type, "");
print_literal(ctx, ";\n");
}
}
void
print_description(PrintContext& ctx, const _Parameter::_Instance& inst)
{
const int bufsize = 64;
char buf[bufsize];
if (inst._M_name)
{
print_literal(ctx, "\"");
print_word(ctx, inst._M_name);
print_literal(ctx, "\" ");
}
int written
= __builtin_sprintf(buf, "@ 0x%p {\n", inst._M_address);
print_word(ctx, buf, written);
if (inst._M_type)
{
print_literal(ctx, " type = ");
print_type(ctx, inst._M_type, "");
}
}
void
print_description(PrintContext& ctx, const _Parameter& param)
{
const int bufsize = 128;
char buf[bufsize];
const auto& variant = param._M_variant;
switch (param._M_kind)
{
case _Parameter::__iterator:
{
const auto& ite = variant._M_iterator;
print_literal(ctx, "iterator ");
print_description(ctx, ite);
if (ite._M_type)
{
if (ite._M_constness != _Error_formatter::__unknown_constness)
{
print_literal(ctx, " (");
print_field(ctx, param, "constness");
print_literal(ctx, " iterator)");
}
print_literal(ctx, ";\n");
}
if (ite._M_state != _Error_formatter::__unknown_state)
{
print_literal(ctx, " state = ");
print_field(ctx, param, "state");
print_literal(ctx, ";\n");
}
if (ite._M_sequence)
{
print_literal(ctx, " references sequence ");
if (ite._M_seq_type)
{
print_literal(ctx, "with type '");
print_field(ctx, param, "seq_type");
print_literal(ctx, "' ");
}
int written
= __builtin_sprintf(buf, "@ 0x%p\n", ite._M_sequence);
print_word(ctx, buf, written);
}
print_literal(ctx, "}\n");
}
break;
case _Parameter::__sequence:
print_literal(ctx, "sequence ");
print_description(ctx, variant._M_sequence);
if (variant._M_sequence._M_type)
print_literal(ctx, ";\n");
print_literal(ctx, "}\n");
break;
case _Parameter::__instance:
print_literal(ctx, "instance ");
print_description(ctx, variant._M_instance);
if (variant._M_instance._M_type)
print_literal(ctx, ";\n");
print_literal(ctx, "}\n");
break;
case _Parameter::__iterator_value_type:
print_literal(ctx, "iterator::value_type ");
print_description(ctx, variant._M_iterator_value_type);
print_literal(ctx, "}\n");
break;
default:
break;
}
}
void
print_string(PrintContext& ctx, const char* string,
const _Parameter* parameters, std::size_t num_parameters)
{
const char* start = string;
const int bufsize = 128;
char buf[bufsize];
int bufindex = 0;
while (*start)
{
if (isspace(*start))
{
buf[bufindex++] = *start++;
buf[bufindex] = '\0';
print_word(ctx, buf, bufindex);
bufindex = 0;
continue;
}
if (!num_parameters || *start != '%')
{
// Normal char or no parameter to look for.
buf[bufindex++] = *start++;
continue;
}
if (*++start == '%')
{
// Escaped '%'
buf[bufindex++] = *start++;
continue;
}
// We are on a parameter property reference, we need to flush buffer
// first.
if (bufindex != 0)
{
buf[bufindex] = '\0';
print_word(ctx, buf, bufindex);
bufindex = 0;
}
// Get the parameter number
assert(*start >= '1' && *start <= '9');
size_t param_index = *start - '0' - 1;
assert(param_index < num_parameters);
const auto& param = parameters[param_index];
// '.' separates the parameter number from the field
// name, if there is one.
++start;
if (*start != '.')
{
assert(*start == ';');
++start;
if (param._M_kind == _Parameter::__integer)
{
int written
= __builtin_sprintf(buf, "%ld",
param._M_variant._M_integer._M_value);
print_word(ctx, buf, written);
}
else if (param._M_kind == _Parameter::__string)
print_string(ctx, param._M_variant._M_string._M_value,
parameters, num_parameters);
continue;
}
// Extract the field name we want
const int max_field_len = 16;
char field[max_field_len];
int field_idx = 0;
++start;
while (*start != ';')
{
assert(*start);
assert(field_idx < max_field_len - 1);
field[field_idx++] = *start++;
}
++start;
field[field_idx] = '\0';
print_field(ctx, param, field);
}
// Might need to flush.
if (bufindex)
{
buf[bufindex] = '\0';
print_word(ctx, buf, bufindex);
}
}
}
namespace __gnu_debug
{
_Error_formatter&
_Error_formatter::_M_message(_Debug_msg_id __id) const throw ()
{
return const_cast<_Error_formatter*>(this)
->_M_message(_S_debug_messages[__id]);
}
void
_Error_formatter::_M_error() const
{
// Emit file & line number information
bool go_to_next_line = false;
PrintContext ctx;
if (_M_file)
{
print_word(ctx, _M_file);
print_literal(ctx, ":");
go_to_next_line = true;
}
if (_M_line > 0)
{
char buf[64];
int written = __builtin_sprintf(buf, "%u:", _M_line);
print_word(ctx, buf, written);
go_to_next_line = true;
}
if (go_to_next_line)
print_literal(ctx, "\n");
if (ctx._M_max_length)
ctx._M_wordwrap = true;
if (_M_function)
{
print_literal(ctx, "In function:\n");
print_string(ctx, _M_function, nullptr, 0);
print_literal(ctx, "\n");
ctx._M_first_line = true;
print_literal(ctx, "\n");
}
// libstdc++/85768
#if 0 //defined _GLIBCXX_HAVE_EXECINFO_H
{
void* stack[32];
int nb = backtrace(stack, 32);
// Note that we skip current method symbol.
if (nb > 1)
{
print_literal(ctx, "Backtrace:\n");
auto symbols = backtrace_symbols(stack, nb);
for (int i = 1; i < nb; ++i)
{
print_word(ctx, symbols[i]);
print_literal(ctx, "\n");
}
free(symbols);
ctx._M_first_line = true;
print_literal(ctx, "\n");
}
}
#endif
print_literal(ctx, "Error: ");
// Print the error message
assert(_M_text);
print_string(ctx, _M_text, _M_parameters, _M_num_parameters);
print_literal(ctx, ".\n");
// Emit descriptions of the objects involved in the operation
ctx._M_first_line = true;
ctx._M_wordwrap = false;
bool has_header = false;
for (unsigned int i = 0; i < _M_num_parameters; ++i)
{
switch (_M_parameters[i]._M_kind)
{
case _Parameter::__iterator:
case _Parameter::__sequence:
case _Parameter::__instance:
case _Parameter::__iterator_value_type:
if (!has_header)
{
print_literal(ctx, "\nObjects involved in the operation:\n");
has_header = true;
}
print_description(ctx, _M_parameters[i]);
break;
default:
break;
}
}
abort();
}
#if !_GLIBCXX_INLINE_VERSION
// Deprecated methods kept for backward compatibility.
void
_Error_formatter::_Parameter::_M_print_field(
const _Error_formatter*, const char*) const
{ }
void
_Error_formatter::_Parameter::_M_print_description(const _Error_formatter*) const
{ }
template
void
_Error_formatter::_M_format_word(char*, int, const char*, _Tp)
const throw ()
{ }
void
_Error_formatter::_M_print_word(const char*) const
{ }
void
_Error_formatter::_M_print_string(const char*) const
{ }
void
_Error_formatter::_M_get_max_length() const throw ()
{ }
// Instantiations.
template
void
_Error_formatter::_M_format_word(char*, int, const char*,
const void*) const;
template
void
_Error_formatter::_M_format_word(char*, int, const char*, long) const;
template
void
_Error_formatter::_M_format_word(char*, int, const char*,
std::size_t) const;
template
void
_Error_formatter::_M_format_word(char*, int, const char*,
const char*) const;
#endif
} // namespace __gnu_debug