gcc/analyzer/program-point.cc - gcc - Git at Google

 /* Classes for representing locations within the program.
    Copyright (C) 2019-2020 Free Software Foundation, Inc.
    Contributed by David Malcolm <dmalcolm@redhat.com>.

 This file is part of GCC.

 GCC 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.

 GCC 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 GCC; see the file COPYING3.  If not see
 <http://www.gnu.org/licenses/>.  */

 #include "config.h"
 #include "system.h"
 #include "coretypes.h"
 #include "tree.h"
 #include "gimple-pretty-print.h"
 #include "gcc-rich-location.h"
 #include "analyzer/call-string.h"
 #include "ordered-hash-map.h"
 #include "options.h"
 #include "cgraph.h"
 #include "function.h"
 #include "cfg.h"
 #include "basic-block.h"
 #include "gimple.h"
 #include "gimple-iterator.h"
 #include "digraph.h"
 #include "analyzer/analyzer.h"
 #include "analyzer/analyzer-logging.h"
 #include "analyzer/supergraph.h"
 #include "analyzer/program-point.h"
 #include "sbitmap.h"
 #include "bitmap.h"
 #include "tristate.h"
 #include "selftest.h"
 #include "analyzer/region-model.h"
 #include "analyzer/sm.h"
 #include "analyzer/program-state.h"
 #include "alloc-pool.h"
 #include "fibonacci_heap.h"
 #include "diagnostic-event-id.h"
 #include "analyzer/pending-diagnostic.h"
 #include "analyzer/diagnostic-manager.h"
 #include "shortest-paths.h"
 #include "analyzer/exploded-graph.h"
 #include "analyzer/analysis-plan.h"

 #if ENABLE_ANALYZER

 namespace ana {

 /* Get a string for PK.  */

 const char *
 point_kind_to_string (enum point_kind pk)
 {
   switch (pk)
     {
     default:
       gcc_unreachable ();
     case PK_ORIGIN:
       return "PK_ORIGIN";
     case PK_BEFORE_SUPERNODE:
       return "PK_BEFORE_SUPERNODE";
     case PK_BEFORE_STMT:
       return "PK_BEFORE_STMT";
     case PK_AFTER_SUPERNODE:
       return "PK_AFTER_SUPERNODE";
     case PK_EMPTY:
       return "PK_EMPTY";
     case PK_DELETED:
       return "PK_DELETED";
     }
 }

 /* class function_point.  */

 /* Print this function_point to PP.  */

 void
 function_point::print (pretty_printer *pp, const format &f) const
 {
   switch (get_kind ())
     {
     default:
       gcc_unreachable ();

     case PK_ORIGIN:
       pp_printf (pp, "origin");
       break;

     case PK_BEFORE_SUPERNODE:
       {
 	if (m_from_edge)
 	  pp_printf (pp, "before SN: %i (from SN: %i)",
 		     m_supernode->m_index, m_from_edge->m_src->m_index);
 	else
 	  pp_printf (pp, "before SN: %i (NULL from-edge)",
 		     m_supernode->m_index);
 	f.spacer (pp);
 	for (gphi_iterator gpi
 	       = const_cast<supernode *>(get_supernode ())->start_phis ();
 	     !gsi_end_p (gpi); gsi_next (&gpi))
 	  {
 	    const gphi *phi = gpi.phi ();
 	    pp_gimple_stmt_1 (pp, phi, 0, (dump_flags_t)0);
 	  }
       }
       break;

     case PK_BEFORE_STMT:
       pp_printf (pp, "before (SN: %i stmt: %i): ", m_supernode->m_index,
 		 m_stmt_idx);
       f.spacer (pp);
       pp_gimple_stmt_1 (pp, get_stmt (), 0, (dump_flags_t)0);
       if (f.m_newlines)
 	{
 	  pp_newline (pp);
 	  print_source_line (pp);
 	}
       break;

     case PK_AFTER_SUPERNODE:
       pp_printf (pp, "after SN: %i", m_supernode->m_index);
       break;
     }
 }

 /* Generate a hash value for this function_point.  */

 hashval_t
 function_point::hash () const
 {
   inchash::hash hstate;
   if (m_supernode)
     hstate.add_int (m_supernode->m_index);
   hstate.add_ptr (m_from_edge);
   hstate.add_int (m_stmt_idx);
   hstate.add_int (m_kind);
   return hstate.end ();
 }

 /* Get the gimple stmt for this function_point, if any.  */

 const gimple *
 function_point::get_stmt () const
 {
   if (m_kind == PK_BEFORE_STMT)
     return m_supernode->m_stmts[m_stmt_idx];
   else if (m_kind == PK_AFTER_SUPERNODE)
     return m_supernode->get_last_stmt ();
   else
     return NULL;
 }

 /* Get a location for this function_point, if any.  */

 location_t
 function_point::get_location () const
 {
   const gimple *stmt = get_stmt ();
   if (stmt)
     return stmt->location;

   return UNKNOWN_LOCATION;
 }

 /* A subclass of diagnostic_context for use by
    program_point::print_source_line.  */

 class debug_diagnostic_context : public diagnostic_context
 {
 public:
   debug_diagnostic_context ()
   {
     diagnostic_initialize (this, 0);
     show_line_numbers_p = true;
     show_caret = true;
   }
   ~debug_diagnostic_context ()
   {
     diagnostic_finish (this);
   }
 };

 /* Print the source line (if any) for this function_point to PP.  */

 void
 function_point::print_source_line (pretty_printer *pp) const
 {
   const gimple *stmt = get_stmt ();
   if (!stmt)
     return;
   // TODO: monospace font
   debug_diagnostic_context tmp_dc;
   gcc_rich_location richloc (stmt->location);
   diagnostic_show_locus (&tmp_dc, &richloc, DK_ERROR);
   pp_string (pp, pp_formatted_text (tmp_dc.printer));
 }

 /* class program_point.  */

 /* Print this program_point to PP.  */

 void
 program_point::print (pretty_printer *pp, const format &f) const
 {
   pp_string (pp, "callstring: ");
   m_call_string.print (pp);
   f.spacer (pp);

   m_function_point.print (pp, f);
 }

 /* Dump this point to stderr.  */

 DEBUG_FUNCTION void
 program_point::dump () const
 {
   pretty_printer pp;
   pp_show_color (&pp) = pp_show_color (global_dc->printer);
   pp.buffer->stream = stderr;
   print (&pp, format (true));
   pp_flush (&pp);
 }

 /* Generate a hash value for this program_point.  */

 hashval_t
 program_point::hash () const
 {
   inchash::hash hstate;
   hstate.merge_hash (m_function_point.hash ());
   hstate.merge_hash (m_call_string.hash ());
   return hstate.end ();
 }

 /* Get the function * at DEPTH within the call stack.  */

 function *
 program_point::get_function_at_depth (unsigned depth) const
 {
   gcc_assert (depth <= m_call_string.length ());
   if (depth == m_call_string.length ())
     return m_function_point.get_function ();
   else
     return m_call_string[depth]->get_caller_function ();
 }

 /* Assert that this object is sane.  */

 void
 program_point::validate () const
 {
   /* Skip this in a release build.  */
 #if !CHECKING_P
   return;
 #endif

   m_call_string.validate ();
   /* The "callee" of the final entry in the callstring should be the
      function of the m_function_point.  */
   if (m_call_string.length () > 0)
     gcc_assert (m_call_string[m_call_string.length () - 1]->get_callee_function ()
 		== get_function ());
 }

 /* Check to see if SUCC is a valid edge to take (ensuring that we have
    interprocedurally valid paths in the exploded graph, and enforcing
    recursion limits).

    Update the call string if SUCC is a call or a return.

    Return true if SUCC can be taken, or false otherwise.

    This is the "point" half of exploded_node::on_edge.  */

 bool
 program_point::on_edge (exploded_graph &eg,
 			const superedge *succ)
 {
   logger * const logger = eg.get_logger ();
   LOG_FUNC (logger);
   switch (succ->m_kind)
     {
     case SUPEREDGE_CFG_EDGE:
       {
 	const cfg_superedge *cfg_sedge = as_a <const cfg_superedge *> (succ);

 	/* Reject abnormal edges; we special-case setjmp/longjmp.  */
 	if (cfg_sedge->get_flags () & EDGE_ABNORMAL)
 	  return false;
       }
       break;

     case SUPEREDGE_CALL:
       {
 	const call_superedge *call_sedge = as_a <const call_superedge *> (succ);

 	if (eg.get_analysis_plan ().use_summary_p (call_sedge->m_cedge))
 	  {
 	    if (logger)
 	      logger->log ("rejecting call edge: using summary instead");
 	    return false;
 	  }

 	/* Add the callsite to the call string.  */
 	m_call_string.push_call (eg.get_supergraph (), call_sedge);

 	/* Impose a maximum recursion depth and don't analyze paths
 	   that exceed it further.
 	   This is something of a blunt workaround, but it only
 	   applies to recursion (and mutual recursion), not to
 	   general call stacks.  */
 	if (m_call_string.calc_recursion_depth ()
 	    > param_analyzer_max_recursion_depth)
 	  {
 	    if (logger)
 	      logger->log ("rejecting call edge: recursion limit exceeded");
 	    // TODO: issue a sorry for this?
 	    return false;
 	  }
       }
       break;

     case SUPEREDGE_RETURN:
       {
 	/* Require that we return to the call site in the call string.  */
 	if (m_call_string.empty_p ())
 	  {
 	    if (logger)
 	      logger->log ("rejecting return edge: empty call string");
 	    return false;
 	  }
 	const return_superedge *top_of_stack = m_call_string.pop ();
 	if (top_of_stack != succ)
 	  {
 	    if (logger)
 	      logger->log ("rejecting return edge: return to wrong callsite");
 	    return false;
 	  }
       }
       break;

     case SUPEREDGE_INTRAPROCEDURAL_CALL:
       {
 	const callgraph_superedge *cg_sedge
 	  = as_a <const callgraph_superedge *> (succ);
 	/* Consider turning this edge into a use of an
 	   interprocedural summary.  */
 	if (eg.get_analysis_plan ().use_summary_p (cg_sedge->m_cedge))
 	  {
 	    if (logger)
 	      logger->log ("using function summary for %qE in %qE",
 			   cg_sedge->get_callee_decl (),
 			   cg_sedge->get_caller_decl ());
 	    return true;
 	  }
 	else
 	  {
 	    /* Otherwise, we ignore these edges  */
 	    if (logger)
 	      logger->log ("rejecting interprocedural edge");
 	    return false;
 	  }
       }
     }

   return true;
 }

 /* Comparator for program points within the same supernode,
    for implementing worklist::key_t comparison operators.
    Return negative if POINT_A is before POINT_B
    Return positive if POINT_A is after POINT_B
    Return 0 if they are equal.  */

 int
 function_point::cmp_within_supernode_1 (const function_point &point_a,
 					const function_point &point_b)
 {
   gcc_assert (point_a.get_supernode () == point_b.get_supernode ());

   switch (point_a.m_kind)
     {
     default:
       gcc_unreachable ();
     case PK_BEFORE_SUPERNODE:
       switch (point_b.m_kind)
 	{
 	default:
 	  gcc_unreachable ();
 	case PK_BEFORE_SUPERNODE:
 	  {
 	    int a_src_idx = -1;
 	    int b_src_idx = -1;
 	    if (point_a.m_from_edge)
 	      a_src_idx = point_a.m_from_edge->m_src->m_index;
 	    if (point_b.m_from_edge)
 	      b_src_idx = point_b.m_from_edge->m_src->m_index;
 	    return a_src_idx - b_src_idx;
 	  }
 	  break;

 	case PK_BEFORE_STMT:
 	case PK_AFTER_SUPERNODE:
 	  return -1;
 	}
       break;
     case PK_BEFORE_STMT:
       switch (point_b.m_kind)
 	{
 	default:
 	  gcc_unreachable ();
 	case PK_BEFORE_SUPERNODE:
 	  return 1;

 	case PK_BEFORE_STMT:
 	  return point_a.m_stmt_idx - point_b.m_stmt_idx;

 	case PK_AFTER_SUPERNODE:
 	  return -1;
 	}
       break;
     case PK_AFTER_SUPERNODE:
       switch (point_b.m_kind)
 	{
 	default:
 	  gcc_unreachable ();
 	case PK_BEFORE_SUPERNODE:
 	case PK_BEFORE_STMT:
 	  return 1;

 	case PK_AFTER_SUPERNODE:
 	  return 0;
 	}
       break;
     }
 }

 /* Comparator for program points within the same supernode,
    for implementing worklist::key_t comparison operators.
    Return negative if POINT_A is before POINT_B
    Return positive if POINT_A is after POINT_B
    Return 0 if they are equal.  */

 int
 function_point::cmp_within_supernode (const function_point &point_a,
 				      const function_point &point_b)
 {
   int result = cmp_within_supernode_1 (point_a, point_b);

   /* Check that the ordering is symmetric  */
 #if CHECKING_P
   int reversed = cmp_within_supernode_1 (point_b, point_a);
   gcc_assert (reversed == -result);
 #endif

   return result;
 }

 #if CHECKING_P

 namespace selftest {

 /* Verify that function_point::operator== works as expected.  */

 static void
 test_function_point_equality ()
 {
   const supernode *snode = NULL;

   function_point a = function_point (snode, NULL, 0,
 				     PK_BEFORE_SUPERNODE);
   function_point b = function_point::before_supernode (snode, NULL);
   ASSERT_EQ (a, b);
 }

 /* Verify that function_point::cmp_within_supernode works as expected.  */

 static void
 test_function_point_ordering ()
 {
   const supernode *snode = NULL;
   const call_string call_string;

   /* Populate an array with various points within the same
      snode, in order.  */
   auto_vec<function_point> points;
   points.safe_push (function_point::before_supernode (snode, NULL));
   points.safe_push (function_point::before_stmt (snode, 0));
   points.safe_push (function_point::before_stmt (snode, 1));
   points.safe_push (function_point::after_supernode (snode));

   /* Check all pairs.  */
   unsigned i;
   function_point *point_a;
   FOR_EACH_VEC_ELT (points, i, point_a)
     {
       unsigned j;
       function_point *point_b;
       FOR_EACH_VEC_ELT (points, j, point_b)
 	{
 	  int cmp = function_point::cmp_within_supernode (*point_a, *point_b);
 	  if (i == j)
 	    ASSERT_EQ (cmp, 0);
 	  if (i < j)
 	    ASSERT_TRUE (cmp < 0);
 	  if (i > j)
 	    ASSERT_TRUE (cmp > 0);
 	}
     }
 }

 /* Verify that program_point::operator== works as expected.  */

 static void
 test_program_point_equality ()
 {
   const supernode *snode = NULL;

   const call_string cs;

   program_point a = program_point::before_supernode (snode, NULL,
 						     cs);

   program_point b = program_point::before_supernode (snode, NULL,
 						     cs);

   ASSERT_EQ (a, b);
   // TODO: verify with non-empty callstrings, with different edges
 }

 /* Run all of the selftests within this file.  */

 void
 analyzer_program_point_cc_tests ()
 {
   test_function_point_equality ();
   test_function_point_ordering ();
   test_program_point_equality ();
 }

 } // namespace selftest

 #endif /* CHECKING_P */

 } // namespace ana

 #endif /* #if ENABLE_ANALYZER */
	/* Classes for representing locations within the program.
	Copyright (C) 2019-2020 Free Software Foundation, Inc.
	Contributed by David Malcolm <dmalcolm@redhat.com>.

	This file is part of GCC.

	GCC 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.

	GCC 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 GCC; see the file COPYING3. If not see
	<http://www.gnu.org/licenses/>. */

	#include "config.h"
	#include "system.h"
	#include "coretypes.h"
	#include "tree.h"
	#include "gimple-pretty-print.h"
	#include "gcc-rich-location.h"
	#include "analyzer/call-string.h"
	#include "ordered-hash-map.h"
	#include "options.h"
	#include "cgraph.h"
	#include "function.h"
	#include "cfg.h"
	#include "basic-block.h"
	#include "gimple.h"
	#include "gimple-iterator.h"
	#include "digraph.h"
	#include "analyzer/analyzer.h"
	#include "analyzer/analyzer-logging.h"
	#include "analyzer/supergraph.h"
	#include "analyzer/program-point.h"
	#include "sbitmap.h"
	#include "bitmap.h"
	#include "tristate.h"
	#include "selftest.h"
	#include "analyzer/region-model.h"
	#include "analyzer/sm.h"
	#include "analyzer/program-state.h"
	#include "alloc-pool.h"
	#include "fibonacci_heap.h"
	#include "diagnostic-event-id.h"
	#include "analyzer/pending-diagnostic.h"
	#include "analyzer/diagnostic-manager.h"
	#include "shortest-paths.h"
	#include "analyzer/exploded-graph.h"
	#include "analyzer/analysis-plan.h"

	#if ENABLE_ANALYZER

	namespace ana {

	/* Get a string for PK. */

	const char *
	point_kind_to_string (enum point_kind pk)
	{
	switch (pk)
	{
	default:
	gcc_unreachable ();
	case PK_ORIGIN:
	return "PK_ORIGIN";
	case PK_BEFORE_SUPERNODE:
	return "PK_BEFORE_SUPERNODE";
	case PK_BEFORE_STMT:
	return "PK_BEFORE_STMT";
	case PK_AFTER_SUPERNODE:
	return "PK_AFTER_SUPERNODE";
	case PK_EMPTY:
	return "PK_EMPTY";
	case PK_DELETED:
	return "PK_DELETED";
	}
	}

	/* class function_point. */

	/* Print this function_point to PP. */

	void
	function_point::print (pretty_printer *pp, const format &f) const
	{
	switch (get_kind ())
	{
	default:
	gcc_unreachable ();

	case PK_ORIGIN:
	pp_printf (pp, "origin");
	break;

	case PK_BEFORE_SUPERNODE:
	{
	if (m_from_edge)
	pp_printf (pp, "before SN: %i (from SN: %i)",
	m_supernode->m_index, m_from_edge->m_src->m_index);
	else
	pp_printf (pp, "before SN: %i (NULL from-edge)",
	m_supernode->m_index);
	f.spacer (pp);
	for (gphi_iterator gpi
	= const_cast<supernode *>(get_supernode ())->start_phis ();
	!gsi_end_p (gpi); gsi_next (&gpi))
	{
	const gphi *phi = gpi.phi ();
	pp_gimple_stmt_1 (pp, phi, 0, (dump_flags_t)0);
	}
	}
	break;

	case PK_BEFORE_STMT:
	pp_printf (pp, "before (SN: %i stmt: %i): ", m_supernode->m_index,
	m_stmt_idx);
	f.spacer (pp);
	pp_gimple_stmt_1 (pp, get_stmt (), 0, (dump_flags_t)0);
	if (f.m_newlines)
	{
	pp_newline (pp);
	print_source_line (pp);
	}
	break;

	case PK_AFTER_SUPERNODE:
	pp_printf (pp, "after SN: %i", m_supernode->m_index);
	break;
	}
	}

	/* Generate a hash value for this function_point. */

	hashval_t
	function_point::hash () const
	{
	inchash::hash hstate;
	if (m_supernode)
	hstate.add_int (m_supernode->m_index);
	hstate.add_ptr (m_from_edge);
	hstate.add_int (m_stmt_idx);
	hstate.add_int (m_kind);
	return hstate.end ();
	}

	/* Get the gimple stmt for this function_point, if any. */

	const gimple *
	function_point::get_stmt () const
	{
	if (m_kind == PK_BEFORE_STMT)
	return m_supernode->m_stmts[m_stmt_idx];
	else if (m_kind == PK_AFTER_SUPERNODE)
	return m_supernode->get_last_stmt ();
	else
	return NULL;
	}

	/* Get a location for this function_point, if any. */

	location_t
	function_point::get_location () const
	{
	const gimple *stmt = get_stmt ();
	if (stmt)
	return stmt->location;

	return UNKNOWN_LOCATION;
	}

	/* A subclass of diagnostic_context for use by
	program_point::print_source_line. */

	class debug_diagnostic_context : public diagnostic_context
	{
	public:
	debug_diagnostic_context ()
	{
	diagnostic_initialize (this, 0);
	show_line_numbers_p = true;
	show_caret = true;
	}
	~debug_diagnostic_context ()
	{
	diagnostic_finish (this);
	}
	};

	/* Print the source line (if any) for this function_point to PP. */

	void
	function_point::print_source_line (pretty_printer *pp) const
	{
	const gimple *stmt = get_stmt ();
	if (!stmt)
	return;
	// TODO: monospace font
	debug_diagnostic_context tmp_dc;
	gcc_rich_location richloc (stmt->location);
	diagnostic_show_locus (&tmp_dc, &richloc, DK_ERROR);
	pp_string (pp, pp_formatted_text (tmp_dc.printer));
	}

	/* class program_point. */

	/* Print this program_point to PP. */

	void
	program_point::print (pretty_printer *pp, const format &f) const
	{
	pp_string (pp, "callstring: ");
	m_call_string.print (pp);
	f.spacer (pp);

	m_function_point.print (pp, f);
	}

	/* Dump this point to stderr. */

	DEBUG_FUNCTION void
	program_point::dump () const
	{
	pretty_printer pp;
	pp_show_color (&pp) = pp_show_color (global_dc->printer);
	pp.buffer->stream = stderr;
	print (&pp, format (true));
	pp_flush (&pp);
	}

	/* Generate a hash value for this program_point. */

	hashval_t
	program_point::hash () const
	{
	inchash::hash hstate;
	hstate.merge_hash (m_function_point.hash ());
	hstate.merge_hash (m_call_string.hash ());
	return hstate.end ();
	}

	/* Get the function * at DEPTH within the call stack. */

	function *
	program_point::get_function_at_depth (unsigned depth) const
	{
	gcc_assert (depth <= m_call_string.length ());
	if (depth == m_call_string.length ())
	return m_function_point.get_function ();
	else
	return m_call_string[depth]->get_caller_function ();
	}

	/* Assert that this object is sane. */

	void
	program_point::validate () const
	{
	/* Skip this in a release build. */
	#if !CHECKING_P
	return;
	#endif

	m_call_string.validate ();
	/* The "callee" of the final entry in the callstring should be the
	function of the m_function_point. */
	if (m_call_string.length () > 0)
	gcc_assert (m_call_string[m_call_string.length () - 1]->get_callee_function ()
	== get_function ());
	}

	/* Check to see if SUCC is a valid edge to take (ensuring that we have
	interprocedurally valid paths in the exploded graph, and enforcing
	recursion limits).

	Update the call string if SUCC is a call or a return.

	Return true if SUCC can be taken, or false otherwise.

	This is the "point" half of exploded_node::on_edge. */

	bool
	program_point::on_edge (exploded_graph &eg,
	const superedge *succ)
	{
	logger * const logger = eg.get_logger ();
	LOG_FUNC (logger);
	switch (succ->m_kind)
	{
	case SUPEREDGE_CFG_EDGE:
	{
	const cfg_superedge cfg_sedge = as_a <const cfg_superedge > (succ);

	/* Reject abnormal edges; we special-case setjmp/longjmp. */
	if (cfg_sedge->get_flags () & EDGE_ABNORMAL)
	return false;
	}
	break;

	case SUPEREDGE_CALL:
	{
	const call_superedge call_sedge = as_a <const call_superedge > (succ);

	if (eg.get_analysis_plan ().use_summary_p (call_sedge->m_cedge))
	{
	if (logger)
	logger->log ("rejecting call edge: using summary instead");
	return false;
	}

	/* Add the callsite to the call string. */
	m_call_string.push_call (eg.get_supergraph (), call_sedge);

	/* Impose a maximum recursion depth and don't analyze paths
	that exceed it further.
	This is something of a blunt workaround, but it only
	applies to recursion (and mutual recursion), not to
	general call stacks. */
	if (m_call_string.calc_recursion_depth ()
	> param_analyzer_max_recursion_depth)
	{
	if (logger)
	logger->log ("rejecting call edge: recursion limit exceeded");
	// TODO: issue a sorry for this?
	return false;
	}
	}
	break;

	case SUPEREDGE_RETURN:
	{
	/* Require that we return to the call site in the call string. */
	if (m_call_string.empty_p ())
	{
	if (logger)
	logger->log ("rejecting return edge: empty call string");
	return false;
	}
	const return_superedge *top_of_stack = m_call_string.pop ();
	if (top_of_stack != succ)
	{
	if (logger)
	logger->log ("rejecting return edge: return to wrong callsite");
	return false;
	}
	}
	break;

	case SUPEREDGE_INTRAPROCEDURAL_CALL:
	{
	const callgraph_superedge *cg_sedge
	= as_a <const callgraph_superedge *> (succ);
	/* Consider turning this edge into a use of an
	interprocedural summary. */
	if (eg.get_analysis_plan ().use_summary_p (cg_sedge->m_cedge))
	{
	if (logger)
	logger->log ("using function summary for %qE in %qE",
	cg_sedge->get_callee_decl (),
	cg_sedge->get_caller_decl ());
	return true;
	}
	else
	{
	/* Otherwise, we ignore these edges */
	if (logger)
	logger->log ("rejecting interprocedural edge");
	return false;
	}
	}
	}

	return true;
	}

	/* Comparator for program points within the same supernode,
	for implementing worklist::key_t comparison operators.
	Return negative if POINT_A is before POINT_B
	Return positive if POINT_A is after POINT_B
	Return 0 if they are equal. */

	int
	function_point::cmp_within_supernode_1 (const function_point &point_a,
	const function_point &point_b)
	{
	gcc_assert (point_a.get_supernode () == point_b.get_supernode ());

	switch (point_a.m_kind)
	{
	default:
	gcc_unreachable ();
	case PK_BEFORE_SUPERNODE:
	switch (point_b.m_kind)
	{
	default:
	gcc_unreachable ();
	case PK_BEFORE_SUPERNODE:
	{
	int a_src_idx = -1;
	int b_src_idx = -1;
	if (point_a.m_from_edge)
	a_src_idx = point_a.m_from_edge->m_src->m_index;
	if (point_b.m_from_edge)
	b_src_idx = point_b.m_from_edge->m_src->m_index;
	return a_src_idx - b_src_idx;
	}
	break;

	case PK_BEFORE_STMT:
	case PK_AFTER_SUPERNODE:
	return -1;
	}
	break;
	case PK_BEFORE_STMT:
	switch (point_b.m_kind)
	{
	default:
	gcc_unreachable ();
	case PK_BEFORE_SUPERNODE:
	return 1;

	case PK_BEFORE_STMT:
	return point_a.m_stmt_idx - point_b.m_stmt_idx;

	case PK_AFTER_SUPERNODE:
	return -1;
	}
	break;
	case PK_AFTER_SUPERNODE:
	switch (point_b.m_kind)
	{
	default:
	gcc_unreachable ();
	case PK_BEFORE_SUPERNODE:
	case PK_BEFORE_STMT:
	return 1;

	case PK_AFTER_SUPERNODE:
	return 0;
	}
	break;
	}
	}

	/* Comparator for program points within the same supernode,
	for implementing worklist::key_t comparison operators.
	Return negative if POINT_A is before POINT_B
	Return positive if POINT_A is after POINT_B
	Return 0 if they are equal. */

	int
	function_point::cmp_within_supernode (const function_point &point_a,
	const function_point &point_b)
	{
	int result = cmp_within_supernode_1 (point_a, point_b);

	/* Check that the ordering is symmetric */
	#if CHECKING_P
	int reversed = cmp_within_supernode_1 (point_b, point_a);
	gcc_assert (reversed == -result);
	#endif

	return result;
	}

	#if CHECKING_P

	namespace selftest {

	/* Verify that function_point::operator== works as expected. */

	static void
	test_function_point_equality ()
	{
	const supernode *snode = NULL;

	function_point a = function_point (snode, NULL, 0,
	PK_BEFORE_SUPERNODE);
	function_point b = function_point::before_supernode (snode, NULL);
	ASSERT_EQ (a, b);
	}

	/* Verify that function_point::cmp_within_supernode works as expected. */

	static void
	test_function_point_ordering ()
	{
	const supernode *snode = NULL;
	const call_string call_string;

	/* Populate an array with various points within the same
	snode, in order. */
	auto_vec<function_point> points;
	points.safe_push (function_point::before_supernode (snode, NULL));
	points.safe_push (function_point::before_stmt (snode, 0));
	points.safe_push (function_point::before_stmt (snode, 1));
	points.safe_push (function_point::after_supernode (snode));

	/* Check all pairs. */
	unsigned i;
	function_point *point_a;
	FOR_EACH_VEC_ELT (points, i, point_a)
	{
	unsigned j;
	function_point *point_b;
	FOR_EACH_VEC_ELT (points, j, point_b)
	{
	int cmp = function_point::cmp_within_supernode (point_a, point_b);
	if (i == j)
	ASSERT_EQ (cmp, 0);
	if (i < j)
	ASSERT_TRUE (cmp < 0);
	if (i > j)
	ASSERT_TRUE (cmp > 0);
	}
	}
	}

	/* Verify that program_point::operator== works as expected. */

	static void
	test_program_point_equality ()
	{
	const supernode *snode = NULL;

	const call_string cs;

	program_point a = program_point::before_supernode (snode, NULL,
	cs);

	program_point b = program_point::before_supernode (snode, NULL,
	cs);

	ASSERT_EQ (a, b);
	// TODO: verify with non-empty callstrings, with different edges
	}

	/* Run all of the selftests within this file. */

	void
	analyzer_program_point_cc_tests ()
	{
	test_function_point_equality ();
	test_function_point_ordering ();
	test_program_point_equality ();
	}

	} // namespace selftest

	#endif /* CHECKING_P */

	} // namespace ana

	#endif /* #if ENABLE_ANALYZER */