gcc/digraph.cc - gcc - Git at Google

 /* Template classes for directed graphs.
    Copyright (C) 2019-2021 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 "diagnostic.h"
 #include "graphviz.h"
 #include "digraph.h"
 #include "shortest-paths.h"
 #include "selftest.h"

 #if CHECKING_P

 namespace selftest {

 /* A family of digraph classes for writing selftests.  */

 struct test_node;
 struct test_edge;
 struct test_graph;
 struct test_dump_args_t {};
 struct test_cluster;

 struct test_graph_traits
 {
   typedef test_node node_t;
   typedef test_edge edge_t;
   typedef test_graph graph_t;
   typedef test_dump_args_t dump_args_t;
   typedef test_cluster cluster_t;
 };

 struct test_node : public dnode<test_graph_traits>
 {
   test_node (const char *name, int index) : m_name (name), m_index (index) {}
   void dump_dot (graphviz_out *, const dump_args_t &) const OVERRIDE
   {
   }

   const char *m_name;
   int m_index;
 };

 struct test_edge : public dedge<test_graph_traits>
 {
   test_edge (node_t *src, node_t *dest)
   : dedge<test_graph_traits> (src, dest)
   {}

   void dump_dot (graphviz_out *gv, const dump_args_t &) const OVERRIDE
   {
     gv->println ("%s %s %s%c", m_src->m_name, "->", m_dest->m_name, ';');
   }
 };

 struct test_graph : public digraph<test_graph_traits>
 {
   test_node *add_test_node (const char *name)
   {
     test_node *result = new test_node (name, m_nodes.length ());
     add_node (result);
     return result;
   }

   test_edge *add_test_edge (test_node *src, test_node *dst)
   {
     test_edge *result = new test_edge (src, dst);
     add_edge (result);
     return result;
   }
 };

 struct test_cluster : public cluster<test_graph_traits>
 {
 };

 struct test_path
 {
   auto_vec<const test_edge *> m_edges;
 };

 /* Smoketest of digraph dumping.  */

 static void
 test_dump_to_dot ()
 {
   test_graph g;
   test_node *a = g.add_test_node ("a");
   test_node *b = g.add_test_node ("b");
   g.add_test_edge (a, b);

   pretty_printer pp;
   pp.buffer->stream = NULL;
   test_dump_args_t dump_args;
   g.dump_dot_to_pp (&pp, NULL, dump_args);

   ASSERT_STR_CONTAINS (pp_formatted_text (&pp),
 		       "a -> b;\n");
 }

 /* Test shortest paths from A in this digraph,
    where edges run top-to-bottom if not otherwise labeled:

       A
      / \
     B   C-->D
     |   |
     E   |
      \ /
       F.  */

 static void
 test_shortest_paths ()
 {
   test_graph g;
   test_node *a = g.add_test_node ("a");
   test_node *b = g.add_test_node ("b");
   test_node *c = g.add_test_node ("d");
   test_node *d = g.add_test_node ("d");
   test_node *e = g.add_test_node ("e");
   test_node *f = g.add_test_node ("f");

   test_edge *ab = g.add_test_edge (a, b);
   test_edge *ac = g.add_test_edge (a, c);
   test_edge *cd = g.add_test_edge (c, d);
   test_edge *be = g.add_test_edge (b, e);
   test_edge *ef = g.add_test_edge (e, f);
   test_edge *cf = g.add_test_edge (c, f);

   /* Use "A" as the origin; all nodes should be reachable.  */
   {
     shortest_paths<test_graph_traits, test_path> sp (g, a,
 						     SPS_FROM_GIVEN_ORIGIN);

     test_path path_to_a = sp.get_shortest_path (a);
     ASSERT_EQ (path_to_a.m_edges.length (), 0); /* Trivial path.  */

     test_path path_to_b = sp.get_shortest_path (b);
     ASSERT_EQ (path_to_b.m_edges.length (), 1);
     ASSERT_EQ (path_to_b.m_edges[0], ab);

     test_path path_to_c = sp.get_shortest_path (c);
     ASSERT_EQ (path_to_c.m_edges.length (), 1);
     ASSERT_EQ (path_to_c.m_edges[0], ac);

     test_path path_to_d = sp.get_shortest_path (d);
     ASSERT_EQ (path_to_d.m_edges.length (), 2);
     ASSERT_EQ (path_to_d.m_edges[0], ac);
     ASSERT_EQ (path_to_d.m_edges[1], cd);

     test_path path_to_e = sp.get_shortest_path (e);
     ASSERT_EQ (path_to_e.m_edges.length (), 2);
     ASSERT_EQ (path_to_e.m_edges[0], ab);
     ASSERT_EQ (path_to_e.m_edges[1], be);

     test_path path_to_f = sp.get_shortest_path (f);
     ASSERT_EQ (path_to_f.m_edges.length (), 2);
     ASSERT_EQ (path_to_f.m_edges[0], ac);
     ASSERT_EQ (path_to_f.m_edges[1], cf);
   }

   /* Verify that we gracefully handle an origin from which some nodes
      aren't reachable.  */

   /* Use "B" as the origin, so only E and F are reachable.  */
   {
     shortest_paths<test_graph_traits, test_path> sp (g, b,
 						     SPS_FROM_GIVEN_ORIGIN);

     test_path path_to_a = sp.get_shortest_path (a);
     ASSERT_EQ (path_to_a.m_edges.length (), 0); /* No path.  */

     test_path path_to_b = sp.get_shortest_path (b);
     ASSERT_EQ (path_to_b.m_edges.length (), 0); /* Trivial path.  */

     test_path path_to_c = sp.get_shortest_path (c);
     ASSERT_EQ (path_to_c.m_edges.length (), 0); /* No path.  */

     test_path path_to_d = sp.get_shortest_path (d);
     ASSERT_EQ (path_to_d.m_edges.length (), 0); /* No path.  */

     test_path path_to_e = sp.get_shortest_path (e);
     ASSERT_EQ (path_to_e.m_edges.length (), 1);
     ASSERT_EQ (path_to_e.m_edges[0], be);

     test_path path_to_f = sp.get_shortest_path (f);
     ASSERT_EQ (path_to_f.m_edges.length (), 2);
     ASSERT_EQ (path_to_f.m_edges[0], be);
     ASSERT_EQ (path_to_f.m_edges[1], ef);
   }

   /* Use "C" as the origin, so only D and F are reachable.  */
   {
     shortest_paths<test_graph_traits, test_path> sp (g, c,
 						     SPS_FROM_GIVEN_ORIGIN);

     test_path path_to_a = sp.get_shortest_path (a);
     ASSERT_EQ (path_to_a.m_edges.length (), 0); /* No path.  */

     test_path path_to_b = sp.get_shortest_path (b);
     ASSERT_EQ (path_to_b.m_edges.length (), 0); /* No path.  */

     test_path path_to_c = sp.get_shortest_path (c);
     ASSERT_EQ (path_to_c.m_edges.length (), 0); /* Trivial path.  */

     test_path path_to_d = sp.get_shortest_path (d);
     ASSERT_EQ (path_to_d.m_edges.length (), 1);
     ASSERT_EQ (path_to_d.m_edges[0], cd);

     test_path path_to_e = sp.get_shortest_path (e);
     ASSERT_EQ (path_to_e.m_edges.length (), 0); /* No path.  */

     test_path path_to_f = sp.get_shortest_path (f);
     ASSERT_EQ (path_to_f.m_edges.length (), 1);
     ASSERT_EQ (path_to_f.m_edges[0], cf);
   }

   /* Test of SPS_TO_GIVEN_TARGET.  Use "F" as the target.  */
   {
     shortest_paths<test_graph_traits, test_path> sp (g, f,
 						     SPS_TO_GIVEN_TARGET);

     test_path path_to_a = sp.get_shortest_path (a);
     ASSERT_EQ (path_to_a.m_edges.length (), 2);
     ASSERT_EQ (path_to_a.m_edges[0], ac);
     ASSERT_EQ (path_to_a.m_edges[1], cf);

     test_path path_to_b = sp.get_shortest_path (b);
     ASSERT_EQ (path_to_b.m_edges.length (), 2);
     ASSERT_EQ (path_to_b.m_edges[0], be);
     ASSERT_EQ (path_to_b.m_edges[1], ef);

     test_path path_to_c = sp.get_shortest_path (c);
     ASSERT_EQ (path_to_c.m_edges.length (), 1);
     ASSERT_EQ (path_to_c.m_edges[0], cf);

     test_path path_to_d = sp.get_shortest_path (d);
     ASSERT_EQ (path_to_d.m_edges.length (), 0); /* No path.  */

     test_path path_to_e = sp.get_shortest_path (e);
     ASSERT_EQ (path_to_e.m_edges.length (), 1);
     ASSERT_EQ (path_to_e.m_edges[0], ef);

     test_path path_to_f = sp.get_shortest_path (f);
     ASSERT_EQ (path_to_f.m_edges.length (), 0);
   }
 }

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

 void
 digraph_cc_tests ()
 {
   test_dump_to_dot ();
   test_shortest_paths ();
 }

 } // namespace selftest

 #endif /* #if CHECKING_P */
	/* Template classes for directed graphs.
	Copyright (C) 2019-2021 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 "diagnostic.h"
	#include "graphviz.h"
	#include "digraph.h"
	#include "shortest-paths.h"
	#include "selftest.h"

	#if CHECKING_P

	namespace selftest {

	/* A family of digraph classes for writing selftests. */

	struct test_node;
	struct test_edge;
	struct test_graph;
	struct test_dump_args_t {};
	struct test_cluster;

	struct test_graph_traits
	{
	typedef test_node node_t;
	typedef test_edge edge_t;
	typedef test_graph graph_t;
	typedef test_dump_args_t dump_args_t;
	typedef test_cluster cluster_t;
	};

	struct test_node : public dnode<test_graph_traits>
	{
	test_node (const char *name, int index) : m_name (name), m_index (index) {}
	void dump_dot (graphviz_out *, const dump_args_t &) const OVERRIDE
	{
	}

	const char *m_name;
	int m_index;
	};

	struct test_edge : public dedge<test_graph_traits>
	{
	test_edge (node_t src, node_t dest)
	: dedge<test_graph_traits> (src, dest)
	{}

	void dump_dot (graphviz_out *gv, const dump_args_t &) const OVERRIDE
	{
	gv->println ("%s %s %s%c", m_src->m_name, "->", m_dest->m_name, ';');
	}
	};

	struct test_graph : public digraph<test_graph_traits>
	{
	test_node add_test_node (const char name)
	{
	test_node *result = new test_node (name, m_nodes.length ());
	add_node (result);
	return result;
	}

	test_edge add_test_edge (test_node src, test_node *dst)
	{
	test_edge *result = new test_edge (src, dst);
	add_edge (result);
	return result;
	}
	};

	struct test_cluster : public cluster<test_graph_traits>
	{
	};

	struct test_path
	{
	auto_vec<const test_edge *> m_edges;
	};

	/* Smoketest of digraph dumping. */

	static void
	test_dump_to_dot ()
	{
	test_graph g;
	test_node *a = g.add_test_node ("a");
	test_node *b = g.add_test_node ("b");
	g.add_test_edge (a, b);

	pretty_printer pp;
	pp.buffer->stream = NULL;
	test_dump_args_t dump_args;
	g.dump_dot_to_pp (&pp, NULL, dump_args);

	ASSERT_STR_CONTAINS (pp_formatted_text (&pp),
	"a -> b;\n");
	}

	/* Test shortest paths from A in this digraph,
	where edges run top-to-bottom if not otherwise labeled:

	A
	/ \
	B C-->D
	\| \|
	E \|
	\ /
	F. */

	static void
	test_shortest_paths ()
	{
	test_graph g;
	test_node *a = g.add_test_node ("a");
	test_node *b = g.add_test_node ("b");
	test_node *c = g.add_test_node ("d");
	test_node *d = g.add_test_node ("d");
	test_node *e = g.add_test_node ("e");
	test_node *f = g.add_test_node ("f");

	test_edge *ab = g.add_test_edge (a, b);
	test_edge *ac = g.add_test_edge (a, c);
	test_edge *cd = g.add_test_edge (c, d);
	test_edge *be = g.add_test_edge (b, e);
	test_edge *ef = g.add_test_edge (e, f);
	test_edge *cf = g.add_test_edge (c, f);

	/* Use "A" as the origin; all nodes should be reachable. */
	{
	shortest_paths<test_graph_traits, test_path> sp (g, a,
	SPS_FROM_GIVEN_ORIGIN);

	test_path path_to_a = sp.get_shortest_path (a);
	ASSERT_EQ (path_to_a.m_edges.length (), 0); /* Trivial path. */

	test_path path_to_b = sp.get_shortest_path (b);
	ASSERT_EQ (path_to_b.m_edges.length (), 1);
	ASSERT_EQ (path_to_b.m_edges[0], ab);

	test_path path_to_c = sp.get_shortest_path (c);
	ASSERT_EQ (path_to_c.m_edges.length (), 1);
	ASSERT_EQ (path_to_c.m_edges[0], ac);

	test_path path_to_d = sp.get_shortest_path (d);
	ASSERT_EQ (path_to_d.m_edges.length (), 2);
	ASSERT_EQ (path_to_d.m_edges[0], ac);
	ASSERT_EQ (path_to_d.m_edges[1], cd);

	test_path path_to_e = sp.get_shortest_path (e);
	ASSERT_EQ (path_to_e.m_edges.length (), 2);
	ASSERT_EQ (path_to_e.m_edges[0], ab);
	ASSERT_EQ (path_to_e.m_edges[1], be);

	test_path path_to_f = sp.get_shortest_path (f);
	ASSERT_EQ (path_to_f.m_edges.length (), 2);
	ASSERT_EQ (path_to_f.m_edges[0], ac);
	ASSERT_EQ (path_to_f.m_edges[1], cf);
	}

	/* Verify that we gracefully handle an origin from which some nodes
	aren't reachable. */

	/* Use "B" as the origin, so only E and F are reachable. */
	{
	shortest_paths<test_graph_traits, test_path> sp (g, b,
	SPS_FROM_GIVEN_ORIGIN);

	test_path path_to_a = sp.get_shortest_path (a);
	ASSERT_EQ (path_to_a.m_edges.length (), 0); /* No path. */

	test_path path_to_b = sp.get_shortest_path (b);
	ASSERT_EQ (path_to_b.m_edges.length (), 0); /* Trivial path. */

	test_path path_to_c = sp.get_shortest_path (c);
	ASSERT_EQ (path_to_c.m_edges.length (), 0); /* No path. */

	test_path path_to_d = sp.get_shortest_path (d);
	ASSERT_EQ (path_to_d.m_edges.length (), 0); /* No path. */

	test_path path_to_e = sp.get_shortest_path (e);
	ASSERT_EQ (path_to_e.m_edges.length (), 1);
	ASSERT_EQ (path_to_e.m_edges[0], be);

	test_path path_to_f = sp.get_shortest_path (f);
	ASSERT_EQ (path_to_f.m_edges.length (), 2);
	ASSERT_EQ (path_to_f.m_edges[0], be);
	ASSERT_EQ (path_to_f.m_edges[1], ef);
	}

	/* Use "C" as the origin, so only D and F are reachable. */
	{
	shortest_paths<test_graph_traits, test_path> sp (g, c,
	SPS_FROM_GIVEN_ORIGIN);

	test_path path_to_a = sp.get_shortest_path (a);
	ASSERT_EQ (path_to_a.m_edges.length (), 0); /* No path. */

	test_path path_to_b = sp.get_shortest_path (b);
	ASSERT_EQ (path_to_b.m_edges.length (), 0); /* No path. */

	test_path path_to_c = sp.get_shortest_path (c);
	ASSERT_EQ (path_to_c.m_edges.length (), 0); /* Trivial path. */

	test_path path_to_d = sp.get_shortest_path (d);
	ASSERT_EQ (path_to_d.m_edges.length (), 1);
	ASSERT_EQ (path_to_d.m_edges[0], cd);

	test_path path_to_e = sp.get_shortest_path (e);
	ASSERT_EQ (path_to_e.m_edges.length (), 0); /* No path. */

	test_path path_to_f = sp.get_shortest_path (f);
	ASSERT_EQ (path_to_f.m_edges.length (), 1);
	ASSERT_EQ (path_to_f.m_edges[0], cf);
	}

	/* Test of SPS_TO_GIVEN_TARGET. Use "F" as the target. */
	{
	shortest_paths<test_graph_traits, test_path> sp (g, f,
	SPS_TO_GIVEN_TARGET);

	test_path path_to_a = sp.get_shortest_path (a);
	ASSERT_EQ (path_to_a.m_edges.length (), 2);
	ASSERT_EQ (path_to_a.m_edges[0], ac);
	ASSERT_EQ (path_to_a.m_edges[1], cf);

	test_path path_to_b = sp.get_shortest_path (b);
	ASSERT_EQ (path_to_b.m_edges.length (), 2);
	ASSERT_EQ (path_to_b.m_edges[0], be);
	ASSERT_EQ (path_to_b.m_edges[1], ef);

	test_path path_to_c = sp.get_shortest_path (c);
	ASSERT_EQ (path_to_c.m_edges.length (), 1);
	ASSERT_EQ (path_to_c.m_edges[0], cf);

	test_path path_to_d = sp.get_shortest_path (d);
	ASSERT_EQ (path_to_d.m_edges.length (), 0); /* No path. */

	test_path path_to_e = sp.get_shortest_path (e);
	ASSERT_EQ (path_to_e.m_edges.length (), 1);
	ASSERT_EQ (path_to_e.m_edges[0], ef);

	test_path path_to_f = sp.get_shortest_path (f);
	ASSERT_EQ (path_to_f.m_edges.length (), 0);
	}
	}

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

	void
	digraph_cc_tests ()
	{
	test_dump_to_dot ();
	test_shortest_paths ();
	}

	} // namespace selftest

	#endif /* #if CHECKING_P */