gdb/dwarf2/cooked-index.c - binutils-gdb - Git at Google

 /* DIE indexing

    Copyright (C) 2022-2023 Free Software Foundation, Inc.

    This file is part of GDB.

    This program 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 of the License, or
    (at your option) any later version.

    This program 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.

    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.  */

 #include "defs.h"
 #include "dwarf2/cooked-index.h"
 #include "dwarf2/read.h"
 #include "dwarf2/stringify.h"
 #include "cp-support.h"
 #include "c-lang.h"
 #include "ada-lang.h"
 #include "split-name.h"
 #include <algorithm>
 #include "safe-ctype.h"
 #include "gdbsupport/selftest.h"

 /* See cooked-index.h.  */

 std::string
 to_string (cooked_index_flag flags)
 {
   static constexpr cooked_index_flag::string_mapping mapping[] = {
     MAP_ENUM_FLAG (IS_MAIN),
     MAP_ENUM_FLAG (IS_STATIC),
     MAP_ENUM_FLAG (IS_ENUM_CLASS),
     MAP_ENUM_FLAG (IS_LINKAGE),
     MAP_ENUM_FLAG (IS_TYPE_DECLARATION),
   };

   return flags.to_string (mapping);
 }

 /* See cooked-index.h.  */

 int
 cooked_index_entry::compare (const char *stra, const char *strb,
 			     comparison_mode mode)
 {
   auto munge = [] (char c) -> unsigned char
     {
       /* We want to sort '<' before any other printable character.
 	 So, rewrite '<' to something just before ' '.  */
       if (c == '<')
 	return '\x1f';
       return TOLOWER ((unsigned char) c);
     };

   while (*stra != '\0'
 	 && *strb != '\0'
 	 && (munge (*stra) == munge (*strb)))
     {
       ++stra;
       ++strb;
     }

   unsigned char c1 = munge (*stra);
   unsigned char c2 = munge (*strb);

   if (c1 == c2)
     return 0;

   /* When completing, if STRB ends earlier than STRA, consider them as
      equal.  When comparing, if STRB ends earlier and STRA ends with
      '<', consider them as equal.  */
   if (mode == COMPLETE || (mode == MATCH && c1 == munge ('<')))
     {
       if (c2 == '\0')
 	return 0;
     }

   return c1 < c2 ? -1 : 1;
 }

 #if GDB_SELF_TEST

 namespace {

 void
 test_compare ()
 {
   /* Convenience aliases.  */
   const auto mode_compare = cooked_index_entry::MATCH;
   const auto mode_sort = cooked_index_entry::SORT;
   const auto mode_complete = cooked_index_entry::COMPLETE;

   SELF_CHECK (cooked_index_entry::compare ("abcd", "abcd",
 					   mode_compare) == 0);
   SELF_CHECK (cooked_index_entry::compare ("abcd", "abcd",
 					   mode_complete) == 0);

   SELF_CHECK (cooked_index_entry::compare ("abcd", "ABCDE",
 					   mode_compare) < 0);
   SELF_CHECK (cooked_index_entry::compare ("ABCDE", "abcd",
 					   mode_compare) > 0);
   SELF_CHECK (cooked_index_entry::compare ("abcd", "ABCDE",
 					   mode_complete) < 0);
   SELF_CHECK (cooked_index_entry::compare ("ABCDE", "abcd",
 					   mode_complete) == 0);

   SELF_CHECK (cooked_index_entry::compare ("name", "name<>",
 					   mode_compare) < 0);
   SELF_CHECK (cooked_index_entry::compare ("name<>", "name",
 					   mode_compare) == 0);
   SELF_CHECK (cooked_index_entry::compare ("name", "name<>",
 					   mode_complete) < 0);
   SELF_CHECK (cooked_index_entry::compare ("name<>", "name",
 					   mode_complete) == 0);

   SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<arg>",
 					   mode_compare) == 0);
   SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<ag>",
 					   mode_compare) > 0);
   SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<arg>",
 					   mode_complete) == 0);
   SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<ag>",
 					   mode_complete) > 0);

   SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>",
 					   "name<arg<more>>",
 					   mode_compare) == 0);

   SELF_CHECK (cooked_index_entry::compare ("name", "name<arg<more>>",
 					   mode_compare) < 0);
   SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>", "name",
 					   mode_compare) == 0);
   SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>", "name<arg<",
 					   mode_compare) > 0);
   SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>", "name<arg<",
 					   mode_complete) == 0);

   SELF_CHECK (cooked_index_entry::compare ("", "abcd", mode_compare) < 0);
   SELF_CHECK (cooked_index_entry::compare ("", "abcd", mode_complete) < 0);
   SELF_CHECK (cooked_index_entry::compare ("abcd", "", mode_compare) > 0);
   SELF_CHECK (cooked_index_entry::compare ("abcd", "", mode_complete) == 0);

   SELF_CHECK (cooked_index_entry::compare ("func", "func<type>",
 					   mode_sort) < 0);
   SELF_CHECK (cooked_index_entry::compare ("func<type>", "func1",
 					   mode_sort) < 0);
 }

 } /* anonymous namespace */

 #endif /* GDB_SELF_TEST */

 /* See cooked-index.h.  */

 const char *
 cooked_index_entry::full_name (struct obstack *storage) const
 {
   if ((flags & IS_LINKAGE) != 0 || parent_entry == nullptr)
     return canonical;

   const char *sep = nullptr;
   switch (per_cu->lang ())
     {
     case language_cplus:
     case language_rust:
       sep = "::";
       break;

     case language_go:
     case language_d:
     case language_ada:
       sep = ".";
       break;

     default:
       return canonical;
     }

   parent_entry->write_scope (storage, sep);
   obstack_grow0 (storage, canonical, strlen (canonical));
   return (const char *) obstack_finish (storage);
 }

 /* See cooked-index.h.  */

 void
 cooked_index_entry::write_scope (struct obstack *storage,
 				 const char *sep) const
 {
   if (parent_entry != nullptr)
     parent_entry->write_scope (storage, sep);
   obstack_grow (storage, canonical, strlen (canonical));
   obstack_grow (storage, sep, strlen (sep));
 }

 /* See cooked-index.h.  */

 const cooked_index_entry *
 cooked_index_shard::add (sect_offset die_offset, enum dwarf_tag tag,
 			 cooked_index_flag flags, const char *name,
 			 const cooked_index_entry *parent_entry,
 			 dwarf2_per_cu_data *per_cu)
 {
   cooked_index_entry *result = create (die_offset, tag, flags, name,
 				       parent_entry, per_cu);
   m_entries.push_back (result);

   /* An explicitly-tagged main program should always override the
      implicit "main" discovery.  */
   if ((flags & IS_MAIN) != 0)
     m_main = result;
   else if (per_cu->lang () != language_ada
 	   && m_main == nullptr
 	   && strcmp (name, "main") == 0)
     m_main = result;

   return result;
 }

 /* See cooked-index.h.  */

 void
 cooked_index_shard::finalize ()
 {
   m_future = gdb::thread_pool::g_thread_pool->post_task ([this] ()
     {
       do_finalize ();
     });
 }

 /* See cooked-index.h.  */

 gdb::unique_xmalloc_ptr<char>
 cooked_index_shard::handle_gnat_encoded_entry (cooked_index_entry *entry,
 					       htab_t gnat_entries)
 {
   std::string canonical = ada_decode (entry->name, false, false);
   if (canonical.empty ())
     return {};
   std::vector<gdb::string_view> names = split_name (canonical.c_str (),
 						    split_style::DOT);
   gdb::string_view tail = names.back ();
   names.pop_back ();

   const cooked_index_entry *parent = nullptr;
   for (const auto &name : names)
     {
       uint32_t hashval = dwarf5_djb_hash (name);
       void **slot = htab_find_slot_with_hash (gnat_entries, &name,
 					      hashval, INSERT);
       /* CUs are processed in order, so we only need to check the most
 	 recent entry.  */
       cooked_index_entry *last = (cooked_index_entry *) *slot;
       if (last == nullptr || last->per_cu != entry->per_cu)
 	{
 	  gdb::unique_xmalloc_ptr<char> new_name
 	    = make_unique_xstrndup (name.data (), name.length ());
 	  last = create (entry->die_offset, DW_TAG_namespace,
 			 0, new_name.get (), parent,
 			 entry->per_cu);
 	  last->canonical = last->name;
 	  m_names.push_back (std::move (new_name));
 	  *slot = last;
 	}

       parent = last;
     }

   entry->parent_entry = parent;
   return make_unique_xstrndup (tail.data (), tail.length ());
 }

 /* See cooked-index.h.  */

 void
 cooked_index_shard::do_finalize ()
 {
   auto hash_name_ptr = [] (const void *p)
     {
       const cooked_index_entry *entry = (const cooked_index_entry *) p;
       return htab_hash_pointer (entry->name);
     };

   auto eq_name_ptr = [] (const void *a, const void *b) -> int
     {
       const cooked_index_entry *ea = (const cooked_index_entry *) a;
       const cooked_index_entry *eb = (const cooked_index_entry *) b;
       return ea->name == eb->name;
     };

   /* We can use pointer equality here because names come from
      .debug_str, which will normally be unique-ified by the linker.
      Also, duplicates are relatively harmless -- they just mean a bit
      of extra memory is used.  */
   htab_up seen_names (htab_create_alloc (10, hash_name_ptr, eq_name_ptr,
 					 nullptr, xcalloc, xfree));

   auto hash_entry = [] (const void *e)
     {
       const cooked_index_entry *entry = (const cooked_index_entry *) e;
       return dwarf5_djb_hash (entry->canonical);
     };

   auto eq_entry = [] (const void *a, const void *b) -> int
     {
       const cooked_index_entry *ae = (const cooked_index_entry *) a;
       const gdb::string_view *sv = (const gdb::string_view *) b;
       return (strlen (ae->canonical) == sv->length ()
 	      && strncasecmp (ae->canonical, sv->data (), sv->length ()) == 0);
     };

   htab_up gnat_entries (htab_create_alloc (10, hash_entry, eq_entry,
 					   nullptr, xcalloc, xfree));

   for (cooked_index_entry *entry : m_entries)
     {
       gdb_assert (entry->canonical == nullptr);
       if ((entry->flags & IS_LINKAGE) != 0)
 	entry->canonical = entry->name;
       else if (entry->per_cu->lang () == language_ada)
 	{
 	  gdb::unique_xmalloc_ptr<char> canon_name
 	    = handle_gnat_encoded_entry (entry, gnat_entries.get ());
 	  if (canon_name == nullptr)
 	    entry->canonical = entry->name;
 	  else
 	    {
 	      entry->canonical = canon_name.get ();
 	      m_names.push_back (std::move (canon_name));
 	    }
 	}
       else if (entry->per_cu->lang () == language_cplus
 	       || entry->per_cu->lang () == language_c)
 	{
 	  void **slot = htab_find_slot (seen_names.get (), entry,
 					INSERT);
 	  if (*slot == nullptr)
 	    {
 	      gdb::unique_xmalloc_ptr<char> canon_name
 		= (entry->per_cu->lang () == language_cplus
 		   ? cp_canonicalize_string (entry->name)
 		   : c_canonicalize_name (entry->name));
 	      if (canon_name == nullptr)
 		entry->canonical = entry->name;
 	      else
 		{
 		  entry->canonical = canon_name.get ();
 		  m_names.push_back (std::move (canon_name));
 		}
 	    }
 	  else
 	    {
 	      const cooked_index_entry *other
 		= (const cooked_index_entry *) *slot;
 	      entry->canonical = other->canonical;
 	    }
 	}
       else
 	entry->canonical = entry->name;
     }

   m_names.shrink_to_fit ();
   m_entries.shrink_to_fit ();
   std::sort (m_entries.begin (), m_entries.end (),
 	     [] (const cooked_index_entry *a, const cooked_index_entry *b)
 	     {
 	       return *a < *b;
 	     });
 }

 /* See cooked-index.h.  */

 cooked_index_shard::range
 cooked_index_shard::find (const std::string &name, bool completing) const
 {
   wait ();

   cooked_index_entry::comparison_mode mode = (completing
 					      ? cooked_index_entry::COMPLETE
 					      : cooked_index_entry::MATCH);

   auto lower = std::lower_bound (m_entries.cbegin (), m_entries.cend (), name,
 				 [=] (const cooked_index_entry *entry,
 				      const std::string &n)
   {
     return cooked_index_entry::compare (entry->canonical, n.c_str (), mode) < 0;
   });

   auto upper = std::upper_bound (m_entries.cbegin (), m_entries.cend (), name,
 				 [=] (const std::string &n,
 				      const cooked_index_entry *entry)
   {
     return cooked_index_entry::compare (entry->canonical, n.c_str (), mode) > 0;
   });

   return range (lower, upper);
 }

 cooked_index_vector::cooked_index_vector (vec_type &&vec)
   : m_vector (std::move (vec))
 {
   for (auto &idx : m_vector)
     idx->finalize ();
 }

 /* See cooked-index.h.  */

 dwarf2_per_cu_data *
 cooked_index_vector::lookup (CORE_ADDR addr)
 {
   for (const auto &index : m_vector)
     {
       dwarf2_per_cu_data *result = index->lookup (addr);
       if (result != nullptr)
 	return result;
     }
   return nullptr;
 }

 /* See cooked-index.h.  */

 std::vector<const addrmap *>
 cooked_index_vector::get_addrmaps () const
 {
   std::vector<const addrmap *> result;
   for (const auto &index : m_vector)
     result.push_back (index->m_addrmap);
   return result;
 }

 /* See cooked-index.h.  */

 cooked_index_vector::range
 cooked_index_vector::find (const std::string &name, bool completing) const
 {
   std::vector<cooked_index_shard::range> result_range;
   result_range.reserve (m_vector.size ());
   for (auto &entry : m_vector)
     result_range.push_back (entry->find (name, completing));
   return range (std::move (result_range));
 }

 /* See cooked-index.h.  */

 const cooked_index_entry *
 cooked_index_vector::get_main () const
 {
   const cooked_index_entry *result = nullptr;

   for (const auto &index : m_vector)
     {
       const cooked_index_entry *entry = index->get_main ();
       if (result == nullptr
 	  || ((result->flags & IS_MAIN) == 0
 	      && entry != nullptr
 	      && (entry->flags & IS_MAIN) != 0))
 	result = entry;
     }

   return result;
 }

 /* See cooked-index.h.  */

 void
 cooked_index_vector::dump (gdbarch *arch) const
 {
   /* Ensure the index is done building.  */
   this->wait ();

   gdb_printf ("  entries:\n");
   gdb_printf ("\n");

   size_t i = 0;
   for (const cooked_index_entry *entry : this->all_entries ())
     {
       QUIT;

       gdb_printf ("    [%zu] ((cooked_index_entry *) %p)\n", i++, entry);
       gdb_printf ("    name:       %s\n", entry->name);
       gdb_printf ("    canonical:  %s\n", entry->canonical);
       gdb_printf ("    DWARF tag:  %s\n", dwarf_tag_name (entry->tag));
       gdb_printf ("    flags:      %s\n", to_string (entry->flags).c_str ());
       gdb_printf ("    DIE offset: 0x%" PRIx64 "\n",
 		  to_underlying (entry->die_offset));

       if (entry->parent_entry != nullptr)
 	gdb_printf ("    parent:     ((cooked_index_entry *) %p) [%s]\n",
 		    entry->parent_entry, entry->parent_entry->name);
       else
 	gdb_printf ("    parent:     ((cooked_index_entry *) 0)\n");

       gdb_printf ("\n");
     }

   const cooked_index_entry *main_entry = this->get_main ();
   if (main_entry != nullptr)
     gdb_printf ("  main: ((cooked_index_entry *) %p) [%s]\n", main_entry,
 		  main_entry->name);
   else
     gdb_printf ("  main: ((cooked_index_entry *) 0)\n");

   gdb_printf ("\n");
   gdb_printf ("  address maps:\n");
   gdb_printf ("\n");

   std::vector<const addrmap *> addrmaps = this->get_addrmaps ();
   for (i = 0; i < addrmaps.size (); ++i)
     {
       const addrmap &addrmap = *addrmaps[i];

       gdb_printf ("    [%zu] ((addrmap *) %p)\n", i, &addrmap);
       gdb_printf ("\n");

       addrmap.foreach ([arch] (CORE_ADDR start_addr, const void *obj)
 	{
 	  QUIT;

 	  const char *start_addr_str = paddress (arch, start_addr);

 	  if (obj != nullptr)
 	    {
 	      const dwarf2_per_cu_data *per_cu
 		= static_cast<const dwarf2_per_cu_data *> (obj);
 	      gdb_printf ("      [%s] ((dwarf2_per_cu_data *) %p)\n",
 			  start_addr_str, per_cu);
 	    }
 	  else
 	    gdb_printf ("      [%s] ((dwarf2_per_cu_data *) 0)\n",
 			start_addr_str);

 	  return 0;
 	});

       gdb_printf ("\n");
     }
 }

 void _initialize_cooked_index ();
 void
 _initialize_cooked_index ()
 {
 #if GDB_SELF_TEST
   selftests::register_test ("cooked_index_entry::compare", test_compare);
 #endif
 }
	/* DIE indexing

	Copyright (C) 2022-2023 Free Software Foundation, Inc.

	This file is part of GDB.

	This program 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 of the License, or
	(at your option) any later version.

	This program 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.

	You should have received a copy of the GNU General Public License
	along with this program. If not, see <http://www.gnu.org/licenses/>. */

	#include "defs.h"
	#include "dwarf2/cooked-index.h"
	#include "dwarf2/read.h"
	#include "dwarf2/stringify.h"
	#include "cp-support.h"
	#include "c-lang.h"
	#include "ada-lang.h"
	#include "split-name.h"
	#include <algorithm>
	#include "safe-ctype.h"
	#include "gdbsupport/selftest.h"

	/* See cooked-index.h. */

	std::string
	to_string (cooked_index_flag flags)
	{
	static constexpr cooked_index_flag::string_mapping mapping[] = {
	MAP_ENUM_FLAG (IS_MAIN),
	MAP_ENUM_FLAG (IS_STATIC),
	MAP_ENUM_FLAG (IS_ENUM_CLASS),
	MAP_ENUM_FLAG (IS_LINKAGE),
	MAP_ENUM_FLAG (IS_TYPE_DECLARATION),
	};

	return flags.to_string (mapping);
	}

	/* See cooked-index.h. */

	int
	cooked_index_entry::compare (const char stra, const char strb,
	comparison_mode mode)
	{
	auto munge = [] (char c) -> unsigned char
	{
	/* We want to sort '<' before any other printable character.
	So, rewrite '<' to something just before ' '. */
	if (c == '<')
	return '\x1f';
	return TOLOWER ((unsigned char) c);
	};

	while (*stra != '\0'
	&& *strb != '\0'
	&& (munge (stra) == munge (strb)))
	{
	++stra;
	++strb;
	}

	unsigned char c1 = munge (*stra);
	unsigned char c2 = munge (*strb);

	if (c1 == c2)
	return 0;

	/* When completing, if STRB ends earlier than STRA, consider them as
	equal. When comparing, if STRB ends earlier and STRA ends with
	'<', consider them as equal. */
	if (mode == COMPLETE \|\| (mode == MATCH && c1 == munge ('<')))
	{
	if (c2 == '\0')
	return 0;
	}

	return c1 < c2 ? -1 : 1;
	}

	#if GDB_SELF_TEST

	namespace {

	void
	test_compare ()
	{
	/* Convenience aliases. */
	const auto mode_compare = cooked_index_entry::MATCH;
	const auto mode_sort = cooked_index_entry::SORT;
	const auto mode_complete = cooked_index_entry::COMPLETE;

	SELF_CHECK (cooked_index_entry::compare ("abcd", "abcd",
	mode_compare) == 0);
	SELF_CHECK (cooked_index_entry::compare ("abcd", "abcd",
	mode_complete) == 0);

	SELF_CHECK (cooked_index_entry::compare ("abcd", "ABCDE",
	mode_compare) < 0);
	SELF_CHECK (cooked_index_entry::compare ("ABCDE", "abcd",
	mode_compare) > 0);
	SELF_CHECK (cooked_index_entry::compare ("abcd", "ABCDE",
	mode_complete) < 0);
	SELF_CHECK (cooked_index_entry::compare ("ABCDE", "abcd",
	mode_complete) == 0);

	SELF_CHECK (cooked_index_entry::compare ("name", "name<>",
	mode_compare) < 0);
	SELF_CHECK (cooked_index_entry::compare ("name<>", "name",
	mode_compare) == 0);
	SELF_CHECK (cooked_index_entry::compare ("name", "name<>",
	mode_complete) < 0);
	SELF_CHECK (cooked_index_entry::compare ("name<>", "name",
	mode_complete) == 0);

	SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<arg>",
	mode_compare) == 0);
	SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<ag>",
	mode_compare) > 0);
	SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<arg>",
	mode_complete) == 0);
	SELF_CHECK (cooked_index_entry::compare ("name<arg>", "name<ag>",
	mode_complete) > 0);

	SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>",
	"name<arg<more>>",
	mode_compare) == 0);

	SELF_CHECK (cooked_index_entry::compare ("name", "name<arg<more>>",
	mode_compare) < 0);
	SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>", "name",
	mode_compare) == 0);
	SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>", "name<arg<",
	mode_compare) > 0);
	SELF_CHECK (cooked_index_entry::compare ("name<arg<more>>", "name<arg<",
	mode_complete) == 0);

	SELF_CHECK (cooked_index_entry::compare ("", "abcd", mode_compare) < 0);
	SELF_CHECK (cooked_index_entry::compare ("", "abcd", mode_complete) < 0);
	SELF_CHECK (cooked_index_entry::compare ("abcd", "", mode_compare) > 0);
	SELF_CHECK (cooked_index_entry::compare ("abcd", "", mode_complete) == 0);

	SELF_CHECK (cooked_index_entry::compare ("func", "func<type>",
	mode_sort) < 0);
	SELF_CHECK (cooked_index_entry::compare ("func<type>", "func1",
	mode_sort) < 0);
	}

	} /* anonymous namespace */

	#endif /* GDB_SELF_TEST */

	/* See cooked-index.h. */

	const char *
	cooked_index_entry::full_name (struct obstack *storage) const
	{
	if ((flags & IS_LINKAGE) != 0 \|\| parent_entry == nullptr)
	return canonical;

	const char *sep = nullptr;
	switch (per_cu->lang ())
	{
	case language_cplus:
	case language_rust:
	sep = "::";
	break;

	case language_go:
	case language_d:
	case language_ada:
	sep = ".";
	break;

	default:
	return canonical;
	}

	parent_entry->write_scope (storage, sep);
	obstack_grow0 (storage, canonical, strlen (canonical));
	return (const char *) obstack_finish (storage);
	}

	/* See cooked-index.h. */

	void
	cooked_index_entry::write_scope (struct obstack *storage,
	const char *sep) const
	{
	if (parent_entry != nullptr)
	parent_entry->write_scope (storage, sep);
	obstack_grow (storage, canonical, strlen (canonical));
	obstack_grow (storage, sep, strlen (sep));
	}

	/* See cooked-index.h. */

	const cooked_index_entry *
	cooked_index_shard::add (sect_offset die_offset, enum dwarf_tag tag,
	cooked_index_flag flags, const char *name,
	const cooked_index_entry *parent_entry,
	dwarf2_per_cu_data *per_cu)
	{
	cooked_index_entry *result = create (die_offset, tag, flags, name,
	parent_entry, per_cu);
	m_entries.push_back (result);

	/* An explicitly-tagged main program should always override the
	implicit "main" discovery. */
	if ((flags & IS_MAIN) != 0)
	m_main = result;
	else if (per_cu->lang () != language_ada
	&& m_main == nullptr
	&& strcmp (name, "main") == 0)
	m_main = result;

	return result;
	}

	/* See cooked-index.h. */

	void
	cooked_index_shard::finalize ()
	{
	m_future = gdb::thread_pool::g_thread_pool->post_task ([this] ()
	{
	do_finalize ();
	});
	}

	/* See cooked-index.h. */

	gdb::unique_xmalloc_ptr<char>
	cooked_index_shard::handle_gnat_encoded_entry (cooked_index_entry *entry,
	htab_t gnat_entries)
	{
	std::string canonical = ada_decode (entry->name, false, false);
	if (canonical.empty ())
	return {};
	std::vector<gdb::string_view> names = split_name (canonical.c_str (),
	split_style::DOT);
	gdb::string_view tail = names.back ();
	names.pop_back ();

	const cooked_index_entry *parent = nullptr;
	for (const auto &name : names)
	{
	uint32_t hashval = dwarf5_djb_hash (name);
	void **slot = htab_find_slot_with_hash (gnat_entries, &name,
	hashval, INSERT);
	/* CUs are processed in order, so we only need to check the most
	recent entry. */
	cooked_index_entry last = (cooked_index_entry ) *slot;
	if (last == nullptr \|\| last->per_cu != entry->per_cu)
	{
	gdb::unique_xmalloc_ptr<char> new_name
	= make_unique_xstrndup (name.data (), name.length ());
	last = create (entry->die_offset, DW_TAG_namespace,
	0, new_name.get (), parent,
	entry->per_cu);
	last->canonical = last->name;
	m_names.push_back (std::move (new_name));
	*slot = last;
	}

	parent = last;
	}

	entry->parent_entry = parent;
	return make_unique_xstrndup (tail.data (), tail.length ());
	}

	/* See cooked-index.h. */

	void
	cooked_index_shard::do_finalize ()
	{
	auto hash_name_ptr = [] (const void *p)
	{
	const cooked_index_entry entry = (const cooked_index_entry ) p;
	return htab_hash_pointer (entry->name);
	};

	auto eq_name_ptr = [] (const void a, const void b) -> int
	{
	const cooked_index_entry ea = (const cooked_index_entry ) a;
	const cooked_index_entry eb = (const cooked_index_entry ) b;
	return ea->name == eb->name;
	};

	/* We can use pointer equality here because names come from
	.debug_str, which will normally be unique-ified by the linker.
	Also, duplicates are relatively harmless -- they just mean a bit
	of extra memory is used. */
	htab_up seen_names (htab_create_alloc (10, hash_name_ptr, eq_name_ptr,
	nullptr, xcalloc, xfree));

	auto hash_entry = [] (const void *e)
	{
	const cooked_index_entry entry = (const cooked_index_entry ) e;
	return dwarf5_djb_hash (entry->canonical);
	};

	auto eq_entry = [] (const void a, const void b) -> int
	{
	const cooked_index_entry ae = (const cooked_index_entry ) a;
	const gdb::string_view sv = (const gdb::string_view ) b;
	return (strlen (ae->canonical) == sv->length ()
	&& strncasecmp (ae->canonical, sv->data (), sv->length ()) == 0);
	};

	htab_up gnat_entries (htab_create_alloc (10, hash_entry, eq_entry,
	nullptr, xcalloc, xfree));

	for (cooked_index_entry *entry : m_entries)
	{
	gdb_assert (entry->canonical == nullptr);
	if ((entry->flags & IS_LINKAGE) != 0)
	entry->canonical = entry->name;
	else if (entry->per_cu->lang () == language_ada)
	{
	gdb::unique_xmalloc_ptr<char> canon_name
	= handle_gnat_encoded_entry (entry, gnat_entries.get ());
	if (canon_name == nullptr)
	entry->canonical = entry->name;
	else
	{
	entry->canonical = canon_name.get ();
	m_names.push_back (std::move (canon_name));
	}
	}
	else if (entry->per_cu->lang () == language_cplus
	\|\| entry->per_cu->lang () == language_c)
	{
	void **slot = htab_find_slot (seen_names.get (), entry,
	INSERT);
	if (*slot == nullptr)
	{
	gdb::unique_xmalloc_ptr<char> canon_name
	= (entry->per_cu->lang () == language_cplus
	? cp_canonicalize_string (entry->name)
	: c_canonicalize_name (entry->name));
	if (canon_name == nullptr)
	entry->canonical = entry->name;
	else
	{
	entry->canonical = canon_name.get ();
	m_names.push_back (std::move (canon_name));
	}
	}
	else
	{
	const cooked_index_entry *other
	= (const cooked_index_entry ) slot;
	entry->canonical = other->canonical;
	}
	}
	else
	entry->canonical = entry->name;
	}

	m_names.shrink_to_fit ();
	m_entries.shrink_to_fit ();
	std::sort (m_entries.begin (), m_entries.end (),
	[] (const cooked_index_entry a, const cooked_index_entry b)
	{
	return a < b;
	});
	}

	/* See cooked-index.h. */

	cooked_index_shard::range
	cooked_index_shard::find (const std::string &name, bool completing) const
	{
	wait ();

	cooked_index_entry::comparison_mode mode = (completing
	? cooked_index_entry::COMPLETE
	: cooked_index_entry::MATCH);

	auto lower = std::lower_bound (m_entries.cbegin (), m_entries.cend (), name,
	[=] (const cooked_index_entry *entry,
	const std::string &n)
	{
	return cooked_index_entry::compare (entry->canonical, n.c_str (), mode) < 0;
	});

	auto upper = std::upper_bound (m_entries.cbegin (), m_entries.cend (), name,
	[=] (const std::string &n,
	const cooked_index_entry *entry)
	{
	return cooked_index_entry::compare (entry->canonical, n.c_str (), mode) > 0;
	});

	return range (lower, upper);
	}

	cooked_index_vector::cooked_index_vector (vec_type &&vec)
	: m_vector (std::move (vec))
	{
	for (auto &idx : m_vector)
	idx->finalize ();
	}

	/* See cooked-index.h. */

	dwarf2_per_cu_data *
	cooked_index_vector::lookup (CORE_ADDR addr)
	{
	for (const auto &index : m_vector)
	{
	dwarf2_per_cu_data *result = index->lookup (addr);
	if (result != nullptr)
	return result;
	}
	return nullptr;
	}

	/* See cooked-index.h. */

	std::vector<const addrmap *>
	cooked_index_vector::get_addrmaps () const
	{
	std::vector<const addrmap *> result;
	for (const auto &index : m_vector)
	result.push_back (index->m_addrmap);
	return result;
	}

	/* See cooked-index.h. */

	cooked_index_vector::range
	cooked_index_vector::find (const std::string &name, bool completing) const
	{
	std::vector<cooked_index_shard::range> result_range;
	result_range.reserve (m_vector.size ());
	for (auto &entry : m_vector)
	result_range.push_back (entry->find (name, completing));
	return range (std::move (result_range));
	}

	/* See cooked-index.h. */

	const cooked_index_entry *
	cooked_index_vector::get_main () const
	{
	const cooked_index_entry *result = nullptr;

	for (const auto &index : m_vector)
	{
	const cooked_index_entry *entry = index->get_main ();
	if (result == nullptr
	\|\| ((result->flags & IS_MAIN) == 0
	&& entry != nullptr
	&& (entry->flags & IS_MAIN) != 0))
	result = entry;
	}

	return result;
	}

	/* See cooked-index.h. */

	void
	cooked_index_vector::dump (gdbarch *arch) const
	{
	/* Ensure the index is done building. */
	this->wait ();

	gdb_printf (" entries:\n");
	gdb_printf ("\n");

	size_t i = 0;
	for (const cooked_index_entry *entry : this->all_entries ())
	{
	QUIT;

	gdb_printf (" [%zu] ((cooked_index_entry *) %p)\n", i++, entry);
	gdb_printf (" name: %s\n", entry->name);
	gdb_printf (" canonical: %s\n", entry->canonical);
	gdb_printf (" DWARF tag: %s\n", dwarf_tag_name (entry->tag));
	gdb_printf (" flags: %s\n", to_string (entry->flags).c_str ());
	gdb_printf (" DIE offset: 0x%" PRIx64 "\n",
	to_underlying (entry->die_offset));

	if (entry->parent_entry != nullptr)
	gdb_printf (" parent: ((cooked_index_entry *) %p) [%s]\n",
	entry->parent_entry, entry->parent_entry->name);
	else
	gdb_printf (" parent: ((cooked_index_entry *) 0)\n");

	gdb_printf ("\n");
	}

	const cooked_index_entry *main_entry = this->get_main ();
	if (main_entry != nullptr)
	gdb_printf (" main: ((cooked_index_entry *) %p) [%s]\n", main_entry,
	main_entry->name);
	else
	gdb_printf (" main: ((cooked_index_entry *) 0)\n");

	gdb_printf ("\n");
	gdb_printf (" address maps:\n");
	gdb_printf ("\n");

	std::vector<const addrmap *> addrmaps = this->get_addrmaps ();
	for (i = 0; i < addrmaps.size (); ++i)
	{
	const addrmap &addrmap = *addrmaps[i];

	gdb_printf (" [%zu] ((addrmap *) %p)\n", i, &addrmap);
	gdb_printf ("\n");

	addrmap.foreach ([arch] (CORE_ADDR start_addr, const void *obj)
	{
	QUIT;

	const char *start_addr_str = paddress (arch, start_addr);

	if (obj != nullptr)
	{
	const dwarf2_per_cu_data *per_cu
	= static_cast<const dwarf2_per_cu_data *> (obj);
	gdb_printf (" [%s] ((dwarf2_per_cu_data *) %p)\n",
	start_addr_str, per_cu);
	}
	else
	gdb_printf (" [%s] ((dwarf2_per_cu_data *) 0)\n",
	start_addr_str);

	return 0;
	});

	gdb_printf ("\n");
	}
	}

	void _initialize_cooked_index ();
	void
	_initialize_cooked_index ()
	{
	#if GDB_SELF_TEST
	selftests::register_test ("cooked_index_entry::compare", test_compare);
	#endif
	}