/* Classes for purging state at function_points. Copyright (C) 2019-2020 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 "timevar.h" #include "tree-ssa-alias.h" #include "function.h" #include "basic-block.h" #include "gimple.h" #include "stringpool.h" #include "tree-vrp.h" #include "gimple-ssa.h" #include "tree-ssanames.h" #include "tree-phinodes.h" #include "options.h" #include "ssa-iterators.h" #include "diagnostic-core.h" #include "gimple-pretty-print.h" #include "function.h" #include "analyzer/analyzer.h" #include "analyzer/call-string.h" #include "digraph.h" #include "ordered-hash-map.h" #include "cfg.h" #include "gimple-iterator.h" #include "cgraph.h" #include "analyzer/supergraph.h" #include "analyzer/program-point.h" #include "analyzer/analyzer-logging.h" #include "analyzer/state-purge.h" #if ENABLE_ANALYZER /* state_purge_map's ctor. Walk all SSA names in all functions, building a state_purge_per_ssa_name instance for each. */ state_purge_map::state_purge_map (const supergraph &sg, logger *logger) : log_user (logger), m_sg (sg) { LOG_FUNC (logger); auto_timevar tv (TV_ANALYZER_STATE_PURGE); cgraph_node *node; FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (node) { function *fun = node->get_fun (); if (logger) log ("function: %s", function_name (fun)); tree name; unsigned int i;; FOR_EACH_SSA_NAME (i, name, fun) { /* For now, don't bother tracking the .MEM SSA names. */ if (tree var = SSA_NAME_VAR (name)) if (TREE_CODE (var) == VAR_DECL) if (VAR_DECL_IS_VIRTUAL_OPERAND (var)) continue; m_map.put (name, new state_purge_per_ssa_name (*this, name, fun)); } } } /* state_purge_map's dtor. */ state_purge_map::~state_purge_map () { for (iterator iter = m_map.begin (); iter != m_map.end (); ++iter) delete (*iter).second; } /* state_purge_per_ssa_name's ctor. Locate all uses of VAR within FUN. Walk backwards from each use, marking program points, until we reach the def stmt, populating m_points_needing_var. We have to track program points rather than just stmts since there could be empty basic blocks on the way. */ state_purge_per_ssa_name::state_purge_per_ssa_name (const state_purge_map &map, tree name, function *fun) : m_points_needing_name (), m_name (name), m_fun (fun) { LOG_FUNC (map.get_logger ()); if (map.get_logger ()) { map.log ("SSA name: %qE within %qD", name, fun->decl); /* Show def stmt. */ const gimple *def_stmt = SSA_NAME_DEF_STMT (name); pretty_printer pp; pp_gimple_stmt_1 (&pp, def_stmt, 0, (dump_flags_t)0); map.log ("def stmt: %s", pp_formatted_text (&pp)); } auto_vec worklist; /* Add all immediate uses of name to the worklist. Compare with debug_immediate_uses. */ imm_use_iterator iter; use_operand_p use_p; FOR_EACH_IMM_USE_FAST (use_p, iter, name) { if (USE_STMT (use_p)) { const gimple *use_stmt = USE_STMT (use_p); if (map.get_logger ()) { pretty_printer pp; pp_gimple_stmt_1 (&pp, use_stmt, 0, (dump_flags_t)0); map.log ("used by stmt: %s", pp_formatted_text (&pp)); } const supernode *snode = map.get_sg ().get_supernode_for_stmt (use_stmt); /* If it's a use within a phi node, then we care about which in-edge we came from. */ if (use_stmt->code == GIMPLE_PHI) { for (gphi_iterator gpi = const_cast (snode)->start_phis (); !gsi_end_p (gpi); gsi_next (&gpi)) { gphi *phi = gpi.phi (); if (phi == use_stmt) { /* Find arguments (and thus in-edges) which use NAME. */ for (unsigned arg_idx = 0; arg_idx < gimple_phi_num_args (phi); ++arg_idx) { if (name == gimple_phi_arg (phi, arg_idx)->def) { edge in_edge = gimple_phi_arg_edge (phi, arg_idx); const superedge *in_sedge = map.get_sg ().get_edge_for_cfg_edge (in_edge); function_point point = function_point::before_supernode (snode, in_sedge); add_to_worklist (point, &worklist, map.get_logger ()); m_points_needing_name.add (point); } } } } } else { function_point point = before_use_stmt (map, use_stmt); add_to_worklist (point, &worklist, map.get_logger ()); m_points_needing_name.add (point); /* We also need to add uses for conditionals and switches, where the stmt "happens" at the after_supernode, for filtering the out-edges. */ if (use_stmt == snode->get_last_stmt ()) { if (map.get_logger ()) map.log ("last stmt in BB"); function_point point = function_point::after_supernode (snode); add_to_worklist (point, &worklist, map.get_logger ()); m_points_needing_name.add (point); } else if (map.get_logger ()) map.log ("not last stmt in BB"); } } } /* Process worklist by walking backwards until we reach the def stmt. */ { log_scope s (map.get_logger (), "processing worklist"); while (worklist.length () > 0) { function_point point = worklist.pop (); process_point (point, &worklist, map); } } if (map.get_logger ()) { map.log ("%qE in %qD is needed to process:", name, fun->decl); for (point_set_t::iterator iter = m_points_needing_name.begin (); iter != m_points_needing_name.end (); ++iter) { map.start_log_line (); map.get_logger ()->log_partial (" point: "); (*iter).print (map.get_logger ()->get_printer (), format (false)); map.end_log_line (); } } } /* Return true if the SSA name is needed at POINT. */ bool state_purge_per_ssa_name::needed_at_point_p (const function_point &point) const { return const_cast (m_points_needing_name).contains (point); } /* Get the function_point representing immediately before USE_STMT. Subroutine of ctor. */ function_point state_purge_per_ssa_name::before_use_stmt (const state_purge_map &map, const gimple *use_stmt) { gcc_assert (use_stmt->code != GIMPLE_PHI); const supernode *supernode = map.get_sg ().get_supernode_for_stmt (use_stmt); unsigned int stmt_idx = supernode->get_stmt_index (use_stmt); return function_point::before_stmt (supernode, stmt_idx); } /* Add POINT to *WORKLIST if the point has not already been seen. Subroutine of ctor. */ void state_purge_per_ssa_name::add_to_worklist (const function_point &point, auto_vec *worklist, logger *logger) { LOG_FUNC (logger); if (logger) { logger->start_log_line (); logger->log_partial ("point: '"); point.print (logger->get_printer (), format (false)); logger->log_partial ("' for worklist for %qE", m_name); logger->end_log_line (); } gcc_assert (point.get_function () == m_fun); if (point.get_from_edge ()) gcc_assert (point.get_from_edge ()->get_kind () == SUPEREDGE_CFG_EDGE); if (m_points_needing_name.contains (point)) { if (logger) logger->log ("already seen for %qE", m_name); } else { if (logger) logger->log ("not seen; adding to worklist for %qE", m_name); m_points_needing_name.add (point); worklist->safe_push (point); } } /* Process POINT, popped from WORKLIST. Iterate over predecessors of POINT, adding to WORKLIST. */ void state_purge_per_ssa_name::process_point (const function_point &point, auto_vec *worklist, const state_purge_map &map) { logger *logger = map.get_logger (); LOG_FUNC (logger); if (logger) { logger->start_log_line (); logger->log_partial ("considering point: '"); point.print (logger->get_printer (), format (false)); logger->log_partial ("' for %qE", m_name); logger->end_log_line (); } gimple *def_stmt = SSA_NAME_DEF_STMT (m_name); const supernode *snode = point.get_supernode (); switch (point.get_kind ()) { default: gcc_unreachable (); case PK_ORIGIN: break; case PK_BEFORE_SUPERNODE: { for (gphi_iterator gpi = const_cast (snode)->start_phis (); !gsi_end_p (gpi); gsi_next (&gpi)) { gphi *phi = gpi.phi (); if (phi == def_stmt) { if (logger) logger->log ("def stmt within phis; terminating"); return; } } /* Add given pred to worklist. */ if (point.get_from_edge ()) { gcc_assert (point.get_from_edge ()->m_src); add_to_worklist (function_point::after_supernode (point.get_from_edge ()->m_src), worklist, logger); } else { /* Add any intraprocedually edge for a call. */ if (snode->m_returning_call) { cgraph_edge *cedge = supergraph_call_edge (snode->m_fun, snode->m_returning_call); gcc_assert (cedge); superedge *sedge = map.get_sg ().get_intraprocedural_edge_for_call (cedge); gcc_assert (sedge); add_to_worklist (function_point::after_supernode (sedge->m_src), worklist, logger); } } } break; case PK_BEFORE_STMT: { if (def_stmt == point.get_stmt ()) { if (logger) logger->log ("def stmt; terminating"); return; } if (point.get_stmt_idx () > 0) add_to_worklist (function_point::before_stmt (snode, point.get_stmt_idx () - 1), worklist, logger); else { /* Add before_supernode to worklist. This captures the in-edge, so we have to do it once per in-edge. */ unsigned i; superedge *pred; FOR_EACH_VEC_ELT (snode->m_preds, i, pred) add_to_worklist (function_point::before_supernode (snode, pred), worklist, logger); } } break; case PK_AFTER_SUPERNODE: { if (snode->m_stmts.length ()) add_to_worklist (function_point::before_stmt (snode, snode->m_stmts.length () - 1), worklist, logger); else { /* Add before_supernode to worklist. This captures the in-edge, so we have to do it once per in-edge. */ unsigned i; superedge *pred; FOR_EACH_VEC_ELT (snode->m_preds, i, pred) add_to_worklist (function_point::before_supernode (snode, pred), worklist, logger); /* If it's the initial BB, add it, to ensure that we have "before supernode" for the initial ENTRY block, and don't erroneously purge SSA names for initial values of parameters. */ if (snode->entry_p ()) { add_to_worklist (function_point::before_supernode (snode, NULL), worklist, logger); } } } break; } } /* class state_purge_annotator : public dot_annotator. */ /* Implementation of dot_annotator::add_node_annotations vfunc for state_purge_annotator. Add an additional record showing which names are purged on entry to the supernode N. */ bool state_purge_annotator::add_node_annotations (graphviz_out *gv, const supernode &n, bool within_table) const { if (m_map == NULL) return false; if (within_table) return false; pretty_printer *pp = gv->get_pp (); pp_printf (pp, "annotation_for_node_%i", n.m_index); pp_printf (pp, " [shape=none,margin=0,style=filled,fillcolor=%s,label=\"", "lightblue"); pp_write_text_to_stream (pp); // FIXME: passing in a NULL in-edge means we get no hits function_point before_supernode (function_point::before_supernode (&n, NULL)); for (state_purge_map::iterator iter = m_map->begin (); iter != m_map->end (); ++iter) { tree name = (*iter).first; state_purge_per_ssa_name *per_name_data = (*iter).second; if (per_name_data->get_function () == n.m_fun) { if (per_name_data->needed_at_point_p (before_supernode)) pp_printf (pp, "%qE needed here", name); else pp_printf (pp, "%qE not needed here", name); } pp_newline (pp); } pp_string (pp, "\"];\n\n"); pp_flush (pp); return false; } /* Print V to GV as a comma-separated list in braces within a , titling it with TITLE. Subroutine of state_purge_annotator::add_stmt_annotations. */ static void print_vec_of_names (graphviz_out *gv, const char *title, const auto_vec &v) { pretty_printer *pp = gv->get_pp (); tree name; unsigned i; gv->begin_trtd (); pp_printf (pp, "%s: {", title); FOR_EACH_VEC_ELT (v, i, name) { if (i > 0) pp_string (pp, ", "); pp_printf (pp, "%qE", name); } pp_printf (pp, "}"); pp_write_text_as_html_like_dot_to_stream (pp); gv->end_tdtr (); pp_newline (pp); } /* Implementation of dot_annotator::add_stmt_annotations for state_purge_annotator. Add text showing which names are purged at STMT. */ void state_purge_annotator::add_stmt_annotations (graphviz_out *gv, const gimple *stmt, bool within_row) const { if (within_row) return; if (m_map == NULL) return; if (stmt->code == GIMPLE_PHI) return; pretty_printer *pp = gv->get_pp (); pp_newline (pp); const supernode *supernode = m_map->get_sg ().get_supernode_for_stmt (stmt); unsigned int stmt_idx = supernode->get_stmt_index (stmt); function_point before_stmt (function_point::before_stmt (supernode, stmt_idx)); auto_vec needed; auto_vec not_needed; for (state_purge_map::iterator iter = m_map->begin (); iter != m_map->end (); ++iter) { tree name = (*iter).first; state_purge_per_ssa_name *per_name_data = (*iter).second; if (per_name_data->get_function () == supernode->m_fun) { if (per_name_data->needed_at_point_p (before_stmt)) needed.safe_push (name); else not_needed.safe_push (name); } } print_vec_of_names (gv, "needed here", needed); print_vec_of_names (gv, "not needed here", not_needed); } #endif /* #if ENABLE_ANALYZER */