libdwfl/cu.c - platform/external/elfutils - Gitiles

 /* Keeping track of DWARF compilation units in libdwfl.
    Copyright (C) 2005-2010 Red Hat, Inc.
    This file is part of elfutils.

    This file is free software; you can redistribute it and/or modify
    it under the terms of either

      * the GNU Lesser General Public License as published by the Free
        Software Foundation; either version 3 of the License, or (at
        your option) any later version

    or

      * the GNU General Public License as published by the Free
        Software Foundation; either version 2 of the License, or (at
        your option) any later version

    or both in parallel, as here.

    elfutils 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 copies of the GNU General Public License and
    the GNU Lesser General Public License along with this program.  If
    not, see <http://www.gnu.org/licenses/>.  */

 #include "libdwflP.h"
 #include "../libdw/libdwP.h"
 #include "../libdw/memory-access.h"
 #include <search.h>


 static inline Dwarf_Arange *
 dwar (Dwfl_Module *mod, unsigned int idx)
 {
   return &mod->dw->aranges->info[mod->aranges[idx].arange];
 }


 static Dwfl_Error
 addrarange (Dwfl_Module *mod, Dwarf_Addr addr, struct dwfl_arange **arange)
 {
   if (mod->aranges == NULL)
     {
       struct dwfl_arange *aranges = NULL;
       Dwarf_Aranges *dwaranges = NULL;
       size_t naranges;
       if (INTUSE(dwarf_getaranges) (mod->dw, &dwaranges, &naranges) != 0)
 	return DWFL_E_LIBDW;

       /* If the module has no aranges (when no code is included) we
 	 allocate nothing.  */
       if (naranges != 0)
 	{
 	  aranges = malloc (naranges * sizeof *aranges);
 	  if (unlikely (aranges == NULL))
 	    return DWFL_E_NOMEM;

 	  /* libdw has sorted its list by address, which is how we want it.
 	     But the sorted list is full of not-quite-contiguous runs pointing
 	     to the same CU.  We don't care about the little gaps inside the
 	     module, we'll consider them part of the surrounding CU anyway.
 	     Collect our own array with just one record for each run of ranges
 	     pointing to one CU.  */

 	  naranges = 0;
 	  Dwarf_Off lastcu = 0;
 	  for (size_t i = 0; i < dwaranges->naranges; ++i)
 	    if (i == 0 || dwaranges->info[i].offset != lastcu)
 	      {
 		aranges[naranges].arange = i;
 		aranges[naranges].cu = NULL;
 		++naranges;
 		lastcu = dwaranges->info[i].offset;
 	      }
 	}

       /* Store the final array, which is probably much smaller than before.  */
       mod->naranges = naranges;
       mod->aranges = (realloc (aranges, naranges * sizeof aranges[0])
 		      ?: aranges);
       mod->lazycu += naranges;
     }

   /* The address must be inside the module to begin with.  */
   addr = dwfl_deadjust_dwarf_addr (mod, addr);

   /* The ranges are sorted by address, so we can use binary search.  */
   size_t l = 0, u = mod->naranges;
   while (l < u)
     {
       size_t idx = (l + u) / 2;
       Dwarf_Addr start = dwar (mod, idx)->addr;
       if (addr < start)
 	{
 	  u = idx;
 	  continue;
 	}
       else if (addr > start)
 	{
 	  if (idx + 1 < mod->naranges)
 	    {
 	      if (addr >= dwar (mod, idx + 1)->addr)
 		{
 		  l = idx + 1;
 		  continue;
 		}
 	    }
 	  else
 	    {
 	      /* It might be in the last range.  */
 	      const Dwarf_Arange *last
 		= &mod->dw->aranges->info[mod->dw->aranges->naranges - 1];
 	      if (addr > last->addr + last->length)
 		break;
 	    }
 	}

       *arange = &mod->aranges[idx];
       return DWFL_E_NOERROR;
     }

   return DWFL_E_ADDR_OUTOFRANGE;
 }


 static void
 nofree (void *arg)
 {
   struct dwfl_cu *cu = arg;
   if (cu == (void *) -1l)
     return;

   assert (cu->mod->lazycu == 0);
 }

 /* One reason fewer to keep the lazy lookup table for CUs.  */
 static inline void
 less_lazy (Dwfl_Module *mod)
 {
   if (--mod->lazycu > 0)
     return;

   /* We know about all the CUs now, we don't need this table.  */
   tdestroy (mod->lazy_cu_root, nofree);
   mod->lazy_cu_root = NULL;
 }

 static inline Dwarf_Off
 cudie_offset (const struct dwfl_cu *cu)
 {
   /* These are real CUs, so there never is a type_sig8.  Note
      initialization of dwkey.start and offset_size in intern_cu ()
      to see why this calculates the same value for both key and
      die.cu search items.  */
   return DIE_OFFSET_FROM_CU_OFFSET (cu->die.cu->start, cu->die.cu->offset_size,
 				    0);
 }

 static int
 compare_cukey (const void *a, const void *b)
 {
   return cudie_offset (a) - cudie_offset (b);
 }

 /* Intern the CU if necessary.  */
 static Dwfl_Error
 intern_cu (Dwfl_Module *mod, Dwarf_Off cuoff, struct dwfl_cu **result)
 {
   struct Dwarf_CU dwkey;
   struct dwfl_cu key;
   key.die.cu = &dwkey;
   dwkey.offset_size = 0;
   dwkey.start = cuoff - (3 * 0 - 4 + 3);
   struct dwfl_cu **found = tsearch (&key, &mod->lazy_cu_root, &compare_cukey);
   if (unlikely (found == NULL))
     return DWFL_E_NOMEM;

   if (*found == &key || *found == NULL)
     {
       if (unlikely (cuoff + 4 >= mod->dw->sectiondata[IDX_debug_info]->d_size))
 	{
 	  /* This is the EOF marker.  Now we have interned all the CUs.
 	     One increment in MOD->lazycu counts not having hit EOF yet.  */
 	  *found = (void *) -1l;
 	  less_lazy (mod);
 	}
       else
 	{
 	  /* This is a new entry, meaning we haven't looked at this CU.  */

 	  *found = NULL;

 	  struct dwfl_cu *cu = malloc (sizeof *cu);
 	  if (unlikely (cu == NULL))
 	    return DWFL_E_NOMEM;

 	  cu->mod = mod;
 	  cu->next = NULL;
 	  cu->lines = NULL;

 	  /* XXX use non-searching lookup */
 	  Dwarf_Die *die = INTUSE(dwarf_offdie) (mod->dw, cuoff, &cu->die);
 	  if (die == NULL)
 	    {
 	      free (cu);
 	      return DWFL_E_LIBDW;
 	    }
 	  assert (die == &cu->die);

 	  struct dwfl_cu **newvec = realloc (mod->cu, ((mod->ncu + 1)
 						       * sizeof (mod->cu[0])));
 	  if (newvec == NULL)
 	    {
 	      free (cu);
 	      return DWFL_E_NOMEM;
 	    }
 	  mod->cu = newvec;

 	  mod->cu[mod->ncu++] = cu;
 	  if (cu->die.cu->start == 0)
 	    mod->first_cu = cu;

 	  *found = cu;
 	}
     }

   *result = *found;
   return DWFL_E_NOERROR;
 }


 /* Traverse all the CUs in the module.  */

 Dwfl_Error
 internal_function
 __libdwfl_nextcu (Dwfl_Module *mod, struct dwfl_cu *lastcu,
 		  struct dwfl_cu **cu)
 {
   Dwarf_Off cuoff;
   struct dwfl_cu **nextp;

   if (lastcu == NULL)
     {
       /* Start the traversal.  */
       cuoff = 0;
       nextp = &mod->first_cu;
     }
   else
     {
       /* Continue following LASTCU.  */
       cuoff = lastcu->die.cu->end;
       nextp = &lastcu->next;
     }

   if (*nextp == NULL)
     {
       size_t cuhdrsz;
       Dwarf_Off nextoff;
       int end = INTUSE(dwarf_nextcu) (mod->dw, cuoff, &nextoff, &cuhdrsz,
 				      NULL, NULL, NULL);
       if (end < 0)
 	return DWFL_E_LIBDW;
       if (end > 0)
 	{
 	  *cu = NULL;
 	  return DWFL_E_NOERROR;
 	}

       Dwfl_Error result = intern_cu (mod, cuoff + cuhdrsz, nextp);
       if (result != DWFL_E_NOERROR)
 	return result;

       if ((*nextp)->next == NULL && nextoff == (Dwarf_Off) -1l)
 	(*nextp)->next = (void *) -1l;
     }

   *cu = *nextp == (void *) -1l ? NULL : *nextp;
   return DWFL_E_NOERROR;
 }


 /* Intern the CU arange points to, if necessary.  */

 static Dwfl_Error
 arangecu (Dwfl_Module *mod, struct dwfl_arange *arange, struct dwfl_cu **cu)
 {
   if (arange->cu == NULL)
     {
       const Dwarf_Arange *dwarange = &mod->dw->aranges->info[arange->arange];
       Dwfl_Error result = intern_cu (mod, dwarange->offset, &arange->cu);
       if (result != DWFL_E_NOERROR)
 	return result;
       assert (arange->cu != NULL && arange->cu != (void *) -1l);
       less_lazy (mod);		/* Each arange with null ->cu counts once.  */
     }

   *cu = arange->cu;
   return DWFL_E_NOERROR;
 }

 Dwfl_Error
 internal_function
 __libdwfl_addrcu (Dwfl_Module *mod, Dwarf_Addr addr, struct dwfl_cu **cu)
 {
   struct dwfl_arange *arange;
   return addrarange (mod, addr, &arange) ?: arangecu (mod, arange, cu);
 }
	/* Keeping track of DWARF compilation units in libdwfl.
	Copyright (C) 2005-2010 Red Hat, Inc.
	This file is part of elfutils.

	This file is free software; you can redistribute it and/or modify
	it under the terms of either

	* the GNU Lesser General Public License as published by the Free
	Software Foundation; either version 3 of the License, or (at
	your option) any later version

	or

	* the GNU General Public License as published by the Free
	Software Foundation; either version 2 of the License, or (at
	your option) any later version

	or both in parallel, as here.

	elfutils 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 copies of the GNU General Public License and
	the GNU Lesser General Public License along with this program. If
	not, see <http://www.gnu.org/licenses/>. */

	#include "libdwflP.h"
	#include "../libdw/libdwP.h"
	#include "../libdw/memory-access.h"
	#include <search.h>


	static inline Dwarf_Arange *
	dwar (Dwfl_Module *mod, unsigned int idx)
	{
	return &mod->dw->aranges->info[mod->aranges[idx].arange];
	}


	static Dwfl_Error
	addrarange (Dwfl_Module mod, Dwarf_Addr addr, struct dwfl_arange *arange)
	{
	if (mod->aranges == NULL)
	{
	struct dwfl_arange *aranges = NULL;
	Dwarf_Aranges *dwaranges = NULL;
	size_t naranges;
	if (INTUSE(dwarf_getaranges) (mod->dw, &dwaranges, &naranges) != 0)
	return DWFL_E_LIBDW;

	/* If the module has no aranges (when no code is included) we
	allocate nothing. */
	if (naranges != 0)
	{
	aranges = malloc (naranges * sizeof *aranges);
	if (unlikely (aranges == NULL))
	return DWFL_E_NOMEM;

	/* libdw has sorted its list by address, which is how we want it.
	But the sorted list is full of not-quite-contiguous runs pointing
	to the same CU. We don't care about the little gaps inside the
	module, we'll consider them part of the surrounding CU anyway.
	Collect our own array with just one record for each run of ranges
	pointing to one CU. */

	naranges = 0;
	Dwarf_Off lastcu = 0;
	for (size_t i = 0; i < dwaranges->naranges; ++i)
	if (i == 0 \|\| dwaranges->info[i].offset != lastcu)
	{
	aranges[naranges].arange = i;
	aranges[naranges].cu = NULL;
	++naranges;
	lastcu = dwaranges->info[i].offset;
	}
	}

	/* Store the final array, which is probably much smaller than before. */
	mod->naranges = naranges;
	mod->aranges = (realloc (aranges, naranges * sizeof aranges[0])
	?: aranges);
	mod->lazycu += naranges;
	}

	/* The address must be inside the module to begin with. */
	addr = dwfl_deadjust_dwarf_addr (mod, addr);

	/* The ranges are sorted by address, so we can use binary search. */
	size_t l = 0, u = mod->naranges;
	while (l < u)
	{
	size_t idx = (l + u) / 2;
	Dwarf_Addr start = dwar (mod, idx)->addr;
	if (addr < start)
	{
	u = idx;
	continue;
	}
	else if (addr > start)
	{
	if (idx + 1 < mod->naranges)
	{
	if (addr >= dwar (mod, idx + 1)->addr)
	{
	l = idx + 1;
	continue;
	}
	}
	else
	{
	/* It might be in the last range. */
	const Dwarf_Arange *last
	= &mod->dw->aranges->info[mod->dw->aranges->naranges - 1];
	if (addr > last->addr + last->length)
	break;
	}
	}

	*arange = &mod->aranges[idx];
	return DWFL_E_NOERROR;
	}

	return DWFL_E_ADDR_OUTOFRANGE;
	}


	static void
	nofree (void *arg)
	{
	struct dwfl_cu *cu = arg;
	if (cu == (void *) -1l)
	return;

	assert (cu->mod->lazycu == 0);
	}

	/* One reason fewer to keep the lazy lookup table for CUs. */
	static inline void
	less_lazy (Dwfl_Module *mod)
	{
	if (--mod->lazycu > 0)
	return;

	/* We know about all the CUs now, we don't need this table. */
	tdestroy (mod->lazy_cu_root, nofree);
	mod->lazy_cu_root = NULL;
	}

	static inline Dwarf_Off
	cudie_offset (const struct dwfl_cu *cu)
	{
	/* These are real CUs, so there never is a type_sig8. Note
	initialization of dwkey.start and offset_size in intern_cu ()
	to see why this calculates the same value for both key and
	die.cu search items. */
	return DIE_OFFSET_FROM_CU_OFFSET (cu->die.cu->start, cu->die.cu->offset_size,
	0);
	}

	static int
	compare_cukey (const void a, const void b)
	{
	return cudie_offset (a) - cudie_offset (b);
	}

	/* Intern the CU if necessary. */
	static Dwfl_Error
	intern_cu (Dwfl_Module mod, Dwarf_Off cuoff, struct dwfl_cu *result)
	{
	struct Dwarf_CU dwkey;
	struct dwfl_cu key;
	key.die.cu = &dwkey;
	dwkey.offset_size = 0;
	dwkey.start = cuoff - (3 * 0 - 4 + 3);
	struct dwfl_cu **found = tsearch (&key, &mod->lazy_cu_root, &compare_cukey);
	if (unlikely (found == NULL))
	return DWFL_E_NOMEM;

	if (found == &key \|\| found == NULL)
	{
	if (unlikely (cuoff + 4 >= mod->dw->sectiondata[IDX_debug_info]->d_size))
	{
	/* This is the EOF marker. Now we have interned all the CUs.
	One increment in MOD->lazycu counts not having hit EOF yet. */
	found = (void ) -1l;
	less_lazy (mod);
	}
	else
	{
	/* This is a new entry, meaning we haven't looked at this CU. */

	*found = NULL;

	struct dwfl_cu cu = malloc (sizeof cu);
	if (unlikely (cu == NULL))
	return DWFL_E_NOMEM;

	cu->mod = mod;
	cu->next = NULL;
	cu->lines = NULL;

	/* XXX use non-searching lookup */
	Dwarf_Die *die = INTUSE(dwarf_offdie) (mod->dw, cuoff, &cu->die);
	if (die == NULL)
	{
	free (cu);
	return DWFL_E_LIBDW;
	}
	assert (die == &cu->die);

	struct dwfl_cu **newvec = realloc (mod->cu, ((mod->ncu + 1)
	* sizeof (mod->cu[0])));
	if (newvec == NULL)
	{
	free (cu);
	return DWFL_E_NOMEM;
	}
	mod->cu = newvec;

	mod->cu[mod->ncu++] = cu;
	if (cu->die.cu->start == 0)
	mod->first_cu = cu;

	*found = cu;
	}
	}

	result = found;
	return DWFL_E_NOERROR;
	}


	/* Traverse all the CUs in the module. */

	Dwfl_Error
	internal_function
	__libdwfl_nextcu (Dwfl_Module mod, struct dwfl_cu lastcu,
	struct dwfl_cu **cu)
	{
	Dwarf_Off cuoff;
	struct dwfl_cu **nextp;

	if (lastcu == NULL)
	{
	/* Start the traversal. */
	cuoff = 0;
	nextp = &mod->first_cu;
	}
	else
	{
	/* Continue following LASTCU. */
	cuoff = lastcu->die.cu->end;
	nextp = &lastcu->next;
	}

	if (*nextp == NULL)
	{
	size_t cuhdrsz;
	Dwarf_Off nextoff;
	int end = INTUSE(dwarf_nextcu) (mod->dw, cuoff, &nextoff, &cuhdrsz,
	NULL, NULL, NULL);
	if (end < 0)
	return DWFL_E_LIBDW;
	if (end > 0)
	{
	*cu = NULL;
	return DWFL_E_NOERROR;
	}

	Dwfl_Error result = intern_cu (mod, cuoff + cuhdrsz, nextp);
	if (result != DWFL_E_NOERROR)
	return result;

	if ((*nextp)->next == NULL && nextoff == (Dwarf_Off) -1l)
	(nextp)->next = (void ) -1l;
	}

	cu = nextp == (void ) -1l ? NULL : nextp;
	return DWFL_E_NOERROR;
	}


	/* Intern the CU arange points to, if necessary. */

	static Dwfl_Error
	arangecu (Dwfl_Module mod, struct dwfl_arange arange, struct dwfl_cu **cu)
	{
	if (arange->cu == NULL)
	{
	const Dwarf_Arange *dwarange = &mod->dw->aranges->info[arange->arange];
	Dwfl_Error result = intern_cu (mod, dwarange->offset, &arange->cu);
	if (result != DWFL_E_NOERROR)
	return result;
	assert (arange->cu != NULL && arange->cu != (void *) -1l);
	less_lazy (mod); /* Each arange with null ->cu counts once. */
	}

	*cu = arange->cu;
	return DWFL_E_NOERROR;
	}

	Dwfl_Error
	internal_function
	__libdwfl_addrcu (Dwfl_Module mod, Dwarf_Addr addr, struct dwfl_cu *cu)
	{
	struct dwfl_arange *arange;
	return addrarange (mod, addr, &arange) ?: arangecu (mod, arange, cu);
	}