/* A graph for exploring trees of feasible paths through the egraph. Copyright (C) 2021-2022 Free Software Foundation, Inc. Contributed by David Malcolm . 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 . */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tree.h" #include "pretty-print.h" #include "gcc-rich-location.h" #include "gimple-pretty-print.h" #include "function.h" #include "diagnostic-core.h" #include "diagnostic-event-id.h" #include "diagnostic-path.h" #include "alloc-pool.h" #include "fibonacci_heap.h" #include "shortest-paths.h" #include "sbitmap.h" #include "bitmap.h" #include "tristate.h" #include "selftest.h" #include "ordered-hash-map.h" #include "json.h" #include "analyzer/analyzer.h" #include "analyzer/analyzer-logging.h" #include "analyzer/sm.h" #include "analyzer/pending-diagnostic.h" #include "analyzer/diagnostic-manager.h" #include "analyzer/call-string.h" #include "analyzer/program-point.h" #include "analyzer/store.h" #include "analyzer/region-model.h" #include "analyzer/constraint-manager.h" #include "cfg.h" #include "basic-block.h" #include "gimple.h" #include "gimple-iterator.h" #include "cgraph.h" #include "digraph.h" #include "analyzer/supergraph.h" #include "analyzer/program-state.h" #include "analyzer/exploded-graph.h" #include "analyzer/feasible-graph.h" #if ENABLE_ANALYZER namespace ana { /* class base_feasible_node : public dnode. */ /* Print an id to PP for this node suitable for use in .dot dumps. */ void base_feasible_node::dump_dot_id (pretty_printer *pp) const { pp_printf (pp, "fnode_%i", m_index); } /* class feasible_node : public base_feasible_node. */ /* Implementation of dump_dot vfunc for feasible_node. */ void feasible_node::dump_dot (graphviz_out *gv, const dump_args_t &) const { pretty_printer *pp = gv->get_pp (); dump_dot_id (pp); pp_printf (pp, " [shape=none,margin=0,style=filled,fillcolor=%s,label=\"", m_inner_node->get_dot_fillcolor ()); pp_write_text_to_stream (pp); pp_printf (pp, "FN: %i (EN: %i); len=%i", m_index, m_inner_node->m_index, m_path_length); pp_newline (pp); format f (true); m_inner_node->get_point ().print (pp, f); pp_newline (pp); /* Show the model at this point along expansion of the feasible path, rather than the model within the enode. */ m_state.get_model ().dump_to_pp (pp, true, true); pp_newline (pp); m_inner_node->dump_processed_stmts (pp); m_inner_node->dump_saved_diagnostics (pp); pp_write_text_as_dot_label_to_stream (pp, /*for_record=*/true); pp_string (pp, "\"];\n\n"); pp_flush (pp); } /* Implementation of dump_dot vfunc for infeasible_node. In particular, show the rejected constraint. */ void infeasible_node::dump_dot (graphviz_out *gv, const dump_args_t &) const { pretty_printer *pp = gv->get_pp (); dump_dot_id (pp); pp_printf (pp, " [shape=none,margin=0,style=filled,fillcolor=%s,label=\"", m_inner_node->get_dot_fillcolor ()); pp_write_text_to_stream (pp); pp_printf (pp, "infeasible edge to EN: %i", m_inner_node->m_index); pp_newline (pp); pp_string (pp, "rejected constraint:"); pp_newline (pp); m_rc->dump_to_pp (pp); pp_write_text_as_dot_label_to_stream (pp, /*for_record=*/true); pp_string (pp, "\"];\n\n"); pp_flush (pp); } /* class base_feasible_edge : public dedge. */ /* Implementation of dump_dot vfunc for base_easible_edge. */ void base_feasible_edge::dump_dot (graphviz_out *gv, const dump_args_t &) const { pretty_printer *pp = gv->get_pp (); m_src->dump_dot_id (pp); pp_string (pp, " -> "); m_dest->dump_dot_id (pp); m_inner_edge->dump_dot_label (pp); } /* class feasible_graph : public digraph . */ /* Ctor for feasible_graph. */ feasible_graph::feasible_graph () : m_num_infeasible (0) { } /* Add a feasible_node to this graph for ENODE, STATE with the given PATH_LENGTH. */ feasible_node * feasible_graph::add_node (const exploded_node *enode, const feasibility_state &state, unsigned path_length) { /* We don't attempt get_or_create here. */ feasible_node *fnode = new feasible_node (enode, m_nodes.length (), state, path_length); digraph::add_node (fnode); return fnode; } /* Add an infeasible_node to this graph and an infeasible_edge connecting to it from SRC_FNODE, capturing a failure of RC along EEDGE. Takes ownership of RC. */ void feasible_graph::add_feasibility_problem (feasible_node *src_fnode, const exploded_edge *eedge, rejected_constraint *rc) { infeasible_node *dst_fnode = new infeasible_node (eedge->m_dest, m_nodes.length (), rc); digraph::add_node (dst_fnode); add_edge (new infeasible_edge (src_fnode, dst_fnode, eedge)); m_num_infeasible++; } /* Make an exploded_path from the origin to FNODE's exploded_node, following the edges in the feasible_graph. */ exploded_path * feasible_graph::make_epath (feasible_node *fnode) const { exploded_path *epath = new exploded_path (); /* FG is actually a tree. Built the path backwards, by walking backwards from FNODE until we reach the origin. */ while (fnode->get_inner_node ()->m_index != 0) { gcc_assert (fnode->m_preds.length () == 1); feasible_edge *pred_fedge = static_cast (fnode->m_preds[0]); epath->m_edges.safe_push (pred_fedge->get_inner_edge ()); fnode = static_cast (pred_fedge->m_src); } /* Now reverse it. */ epath->m_edges.reverse (); return epath; } /* Dump the path to DST_FNODE in textual form to PP. */ void feasible_graph::dump_feasible_path (const feasible_node &dst_fnode, pretty_printer *pp) const { const feasible_node *fnode = &dst_fnode; auto_vec fpath; /* FG is actually a tree. Built the path backwards, by walking backwards from FNODE until we reach the origin. */ while (fnode->get_inner_node ()->m_index != 0) { gcc_assert (fnode->m_preds.length () == 1); feasible_edge *pred_fedge = static_cast (fnode->m_preds[0]); fpath.safe_push (pred_fedge); fnode = static_cast (pred_fedge->m_src); } /* Now reverse it. */ fpath.reverse (); for (unsigned i = 0; i < fpath.length (); i++) { const feasible_edge *fedge = fpath[i]; const feasible_node *src_fnode = static_cast (fedge->m_src); const feasible_node *dest_fnode = static_cast (fedge->m_dest); pp_printf (pp, "fpath[%i]: FN %i (EN %i) -> FN %i (EN %i)", i, src_fnode->get_index (), src_fnode->get_inner_node ()->m_index, dest_fnode->get_index (), dest_fnode->get_inner_node ()->m_index); pp_newline (pp); pp_printf (pp, " FN %i (EN %i):", dest_fnode->get_index (), dest_fnode->get_inner_node ()->m_index); pp_newline (pp); const program_point &point = dest_fnode->get_inner_node ()->get_point (); point.print (pp, format (true)); dest_fnode->get_state ().dump_to_pp (pp, true, true); pp_newline (pp); } } /* Dump the path to DST_FNODE in textual form to FILENAME. */ void feasible_graph::dump_feasible_path (const feasible_node &dst_fnode, const char *filename) const { FILE *fp = fopen (filename, "w"); pretty_printer pp; pp_format_decoder (&pp) = default_tree_printer; pp.buffer->stream = fp; dump_feasible_path (dst_fnode, &pp); pp_flush (&pp); fclose (fp); } /* Dump stats about this graph to LOGGER. */ void feasible_graph::log_stats (logger *logger) const { logger->log ("#nodes: %i", m_nodes.length ()); logger->log ("#edges: %i", m_edges.length ()); logger->log ("#feasible nodes: %i", m_nodes.length () - m_num_infeasible); logger->log ("#feasible edges: %i", m_edges.length () - m_num_infeasible); logger->log ("#infeasible nodes/edges: %i", m_num_infeasible); } } // namespace ana #endif /* #if ENABLE_ANALYZER */