Mercurial > hg > CbC > CbC_gcc
view gcc/analyzer/supergraph.cc @ 145:1830386684a0
gcc-9.2.0
| author | anatofuz |
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| date | Thu, 13 Feb 2020 11:34:05 +0900 |
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| children |
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/* "Supergraph" classes that combine CFGs and callgraph into one digraph. 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 "tm.h" #include "toplev.h" #include "hash-table.h" #include "vec.h" #include "ggc.h" #include "basic-block.h" #include "function.h" #include "gimple-fold.h" #include "tree-eh.h" #include "gimple-expr.h" #include "is-a.h" #include "timevar.h" #include "gimple.h" #include "gimple-iterator.h" #include "gimple-pretty-print.h" #include "tree-pretty-print.h" #include "graphviz.h" #include "cgraph.h" #include "tree-dfa.h" #include "cfganal.h" #include "function.h" #include "analyzer/analyzer.h" #include "ordered-hash-map.h" #include "options.h" #include "cgraph.h" #include "cfg.h" #include "digraph.h" #include "analyzer/supergraph.h" #include "analyzer/analyzer-logging.h" #if ENABLE_ANALYZER namespace ana { /* Get the function of the ultimate alias target being called at EDGE, if any. */ static function * get_ultimate_function_for_cgraph_edge (cgraph_edge *edge) { cgraph_node *ultimate_node = edge->callee->ultimate_alias_target (); if (!ultimate_node) return NULL; return ultimate_node->get_fun (); } /* Get the cgraph_edge, but only if there's an underlying function body. */ cgraph_edge * supergraph_call_edge (function *fun, gimple *stmt) { gcall *call = dyn_cast<gcall *> (stmt); if (!call) return NULL; cgraph_edge *edge = cgraph_node::get (fun->decl)->get_edge (stmt); if (!edge) return NULL; if (!edge->callee) return NULL; /* e.g. for a function pointer. */ if (!get_ultimate_function_for_cgraph_edge (edge)) return NULL; return edge; } /* supergraph's ctor. Walk the callgraph, building supernodes for each CFG basic block, splitting the basic blocks at callsites. Join together the supernodes with interprocedural and intraprocedural superedges as appropriate. */ supergraph::supergraph (logger *logger) { auto_timevar tv (TV_ANALYZER_SUPERGRAPH); LOG_FUNC (logger); /* First pass: make supernodes. */ { /* Sort the cgraph_nodes? */ cgraph_node *node; FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (node) { function *fun = node->get_fun (); /* Ensure that EDGE_DFS_BACK is correct for every CFG edge in the supergraph (by doing it per-function). */ auto_cfun sentinel (fun); mark_dfs_back_edges (); const int start_idx = m_nodes.length (); basic_block bb; FOR_ALL_BB_FN (bb, fun) { /* The initial supernode for the BB gets the phi nodes (if any). */ supernode *node_for_stmts = add_node (fun, bb, NULL, phi_nodes (bb)); m_bb_to_initial_node.put (bb, node_for_stmts); for (gphi_iterator gpi = gsi_start_phis (bb); !gsi_end_p (gpi); gsi_next (&gpi)) { gimple *stmt = gsi_stmt (gpi); m_stmt_to_node_t.put (stmt, node_for_stmts); } /* Append statements from BB to the current supernode, splitting them into a new supernode at each call site; such call statements appear in both supernodes (representing call and return). */ gimple_stmt_iterator gsi; for (gsi = gsi_start_bb (bb); !gsi_end_p (gsi); gsi_next (&gsi)) { gimple *stmt = gsi_stmt (gsi); node_for_stmts->m_stmts.safe_push (stmt); m_stmt_to_node_t.put (stmt, node_for_stmts); if (cgraph_edge *edge = supergraph_call_edge (fun, stmt)) { m_cgraph_edge_to_caller_prev_node.put(edge, node_for_stmts); node_for_stmts = add_node (fun, bb, as_a <gcall *> (stmt), NULL); m_cgraph_edge_to_caller_next_node.put (edge, node_for_stmts); } } m_bb_to_final_node.put (bb, node_for_stmts); } const unsigned num_snodes = m_nodes.length () - start_idx; m_function_to_num_snodes.put (fun, num_snodes); if (logger) { const int end_idx = m_nodes.length () - 1; logger->log ("SN: %i...%i: function %qD", start_idx, end_idx, fun->decl); } } } /* Second pass: make superedges. */ { /* Make superedges for CFG edges. */ for (bb_to_node_t::iterator iter = m_bb_to_final_node.begin (); iter != m_bb_to_final_node.end (); ++iter) { basic_block bb = (*iter).first; supernode *src_supernode = (*iter).second; ::edge cfg_edge; int idx; if (bb->succs) FOR_EACH_VEC_ELT (*bb->succs, idx, cfg_edge) { basic_block dest_cfg_block = cfg_edge->dest; supernode *dest_supernode = *m_bb_to_initial_node.get (dest_cfg_block); cfg_superedge *cfg_sedge = add_cfg_edge (src_supernode, dest_supernode, cfg_edge, idx); m_cfg_edge_to_cfg_superedge.put (cfg_edge, cfg_sedge); } } /* Make interprocedural superedges for calls. */ { for (cgraph_edge_to_node_t::iterator iter = m_cgraph_edge_to_caller_prev_node.begin (); iter != m_cgraph_edge_to_caller_prev_node.end (); ++iter) { cgraph_edge *edge = (*iter).first; supernode *caller_prev_supernode = (*iter).second; function* callee_fn = get_ultimate_function_for_cgraph_edge (edge); if (!callee_fn || !callee_fn->cfg) continue; basic_block callee_cfg_block = ENTRY_BLOCK_PTR_FOR_FN (callee_fn); supernode *callee_supernode = *m_bb_to_initial_node.get (callee_cfg_block); call_superedge *sedge = add_call_superedge (caller_prev_supernode, callee_supernode, edge); m_cgraph_edge_to_call_superedge.put (edge, sedge); } } /* Make interprocedural superedges for returns. */ { for (cgraph_edge_to_node_t::iterator iter = m_cgraph_edge_to_caller_next_node.begin (); iter != m_cgraph_edge_to_caller_next_node.end (); ++iter) { cgraph_edge *edge = (*iter).first; supernode *caller_next_supernode = (*iter).second; function* callee_fn = get_ultimate_function_for_cgraph_edge (edge); if (!callee_fn || !callee_fn->cfg) continue; basic_block callee_cfg_block = EXIT_BLOCK_PTR_FOR_FN (callee_fn); supernode *callee_supernode = *m_bb_to_initial_node.get (callee_cfg_block); return_superedge *sedge = add_return_superedge (callee_supernode, caller_next_supernode, edge); m_cgraph_edge_to_return_superedge.put (edge, sedge); } } /* Make intraprocedural superedges linking the two halves of a call. */ { for (cgraph_edge_to_node_t::iterator iter = m_cgraph_edge_to_caller_prev_node.begin (); iter != m_cgraph_edge_to_caller_prev_node.end (); ++iter) { cgraph_edge *edge = (*iter).first; supernode *caller_prev_supernode = (*iter).second; supernode *caller_next_supernode = *m_cgraph_edge_to_caller_next_node.get (edge); superedge *sedge = new callgraph_superedge (caller_prev_supernode, caller_next_supernode, SUPEREDGE_INTRAPROCEDURAL_CALL, edge); add_edge (sedge); m_cgraph_edge_to_intraproc_superedge.put (edge, sedge); } } } } /* Dump this graph in .dot format to PP, using DUMP_ARGS. Cluster the supernodes by function, then by BB from original CFG. */ void supergraph::dump_dot_to_pp (pretty_printer *pp, const dump_args_t &dump_args) const { graphviz_out gv (pp); pp_string (pp, "digraph \""); pp_write_text_to_stream (pp); pp_string (pp, "supergraph"); pp_write_text_as_dot_label_to_stream (pp, /*for_record=*/false); pp_string (pp, "\" {\n"); gv.indent (); gv.println ("overlap=false;"); gv.println ("compound=true;"); /* TODO: maybe (optionally) sub-subdivide by TU, for LTO; see also: https://gcc-python-plugin.readthedocs.io/en/latest/_images/sample-supergraph.png */ /* Break out the supernodes into clusters by function. */ { cgraph_node *node; FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (node) { function *fun = node->get_fun (); const char *funcname = function_name (fun); gv.println ("subgraph \"cluster_%s\" {", funcname); gv.indent (); pp_printf (pp, ("style=\"dashed\";" " color=\"black\";" " label=\"%s\";\n"), funcname); /* Break out the nodes into clusters by BB from original CFG. */ { basic_block bb; FOR_ALL_BB_FN (bb, fun) { if (dump_args.m_flags & SUPERGRAPH_DOT_SHOW_BBS) { gv.println ("subgraph \"cluster_%s_bb_%i\" {", funcname, bb->index); gv.indent (); pp_printf (pp, ("style=\"dashed\";" " color=\"black\";" " label=\"bb: %i\";\n"), bb->index); } // TODO: maybe keep an index per-function/per-bb to speed this up??? int i; supernode *n; FOR_EACH_VEC_ELT (m_nodes, i, n) if (n->m_fun == fun && n->m_bb == bb) n->dump_dot (&gv, dump_args); if (dump_args.m_flags & SUPERGRAPH_DOT_SHOW_BBS) { /* Terminate per-bb "subgraph" */ gv.outdent (); gv.println ("}"); } } } /* Add an invisible edge from ENTRY to EXIT, to improve the graph layout. */ pp_string (pp, "\t"); get_node_for_function_entry (fun)->dump_dot_id (pp); pp_string (pp, ":s -> "); get_node_for_function_exit (fun)->dump_dot_id (pp); pp_string (pp, ":n [style=\"invis\",constraint=true];\n"); /* Terminate per-function "subgraph" */ gv.outdent (); gv.println ("}"); } } /* Superedges. */ int i; superedge *e; FOR_EACH_VEC_ELT (m_edges, i, e) e->dump_dot (&gv, dump_args); /* Terminate "digraph" */ gv.outdent (); gv.println ("}"); } /* Dump this graph in .dot format to FP, using DUMP_ARGS. */ void supergraph::dump_dot_to_file (FILE *fp, const dump_args_t &dump_args) const { pretty_printer *pp = global_dc->printer->clone (); pp_show_color (pp) = 0; /* %qE in logs for SSA_NAMEs should show the ssa names, rather than trying to prettify things by showing the underlying var. */ pp_format_decoder (pp) = default_tree_printer; pp->buffer->stream = fp; dump_dot_to_pp (pp, dump_args); pp_flush (pp); delete pp; } /* Dump this graph in .dot format to PATH, using DUMP_ARGS. */ void supergraph::dump_dot (const char *path, const dump_args_t &dump_args) const { FILE *fp = fopen (path, "w"); dump_dot_to_file (fp, dump_args); fclose (fp); } /* Create a supernode for BB within FUN and add it to this supergraph. If RETURNING_CALL is non-NULL, the supernode represents the resumption of the basic block after returning from that call. If PHI_NODES is non-NULL, this is the initial supernode for the basic block, and is responsible for any handling of the phi nodes. */ supernode * supergraph::add_node (function *fun, basic_block bb, gcall *returning_call, gimple_seq phi_nodes) { supernode *n = new supernode (fun, bb, returning_call, phi_nodes, m_nodes.length ()); m_nodes.safe_push (n); return n; } /* Create a new cfg_superedge from SRC to DEST for the underlying CFG edge E, adding it to this supergraph. If the edge is for a switch statement, create a switch_cfg_superedge subclass using IDX (the index of E within the out-edges from SRC's underlying basic block). */ cfg_superedge * supergraph::add_cfg_edge (supernode *src, supernode *dest, ::edge e, int idx) { /* Special-case switch edges. */ gimple *stmt = src->get_last_stmt (); cfg_superedge *new_edge; if (stmt && stmt->code == GIMPLE_SWITCH) new_edge = new switch_cfg_superedge (src, dest, e, idx); else new_edge = new cfg_superedge (src, dest, e); add_edge (new_edge); return new_edge; } /* Create and add a call_superedge representing an interprocedural call from SRC to DEST, using CEDGE. */ call_superedge * supergraph::add_call_superedge (supernode *src, supernode *dest, cgraph_edge *cedge) { call_superedge *new_edge = new call_superedge (src, dest, cedge); add_edge (new_edge); return new_edge; } /* Create and add a return_superedge representing returning from an interprocedural call, returning from SRC to DEST, using CEDGE. */ return_superedge * supergraph::add_return_superedge (supernode *src, supernode *dest, cgraph_edge *cedge) { return_superedge *new_edge = new return_superedge (src, dest, cedge); add_edge (new_edge); return new_edge; } /* Implementation of dnode::dump_dot vfunc for supernodes. Write a cluster for the node, and within it a .dot node showing the phi nodes and stmts. Call into any node annotator from ARGS to potentially add other records to the cluster. */ void supernode::dump_dot (graphviz_out *gv, const dump_args_t &args) const { gv->println ("subgraph cluster_node_%i {", m_index); gv->indent (); gv->println("style=\"solid\";"); gv->println("color=\"black\";"); gv->println("fillcolor=\"lightgrey\";"); gv->println("label=\"sn: %i (bb: %i)\";", m_index, m_bb->index); pretty_printer *pp = gv->get_pp (); if (args.m_node_annotator) args.m_node_annotator->add_node_annotations (gv, *this); gv->write_indent (); dump_dot_id (pp); pp_printf (pp, " [shape=none,margin=0,style=filled,fillcolor=%s,label=<", "lightgrey"); pp_string (pp, "<TABLE BORDER=\"0\">"); pp_write_text_to_stream (pp); bool had_row = false; if (m_returning_call) { gv->begin_tr (); pp_string (pp, "returning call: "); gv->end_tr (); gv->begin_tr (); pp_gimple_stmt_1 (pp, m_returning_call, 0, (dump_flags_t)0); pp_write_text_as_html_like_dot_to_stream (pp); gv->end_tr (); if (args.m_node_annotator) args.m_node_annotator->add_stmt_annotations (gv, m_returning_call); pp_newline (pp); had_row = true; } if (entry_p ()) { pp_string (pp, "<TR><TD>ENTRY</TD></TR>"); pp_newline (pp); had_row = true; } if (return_p ()) { pp_string (pp, "<TR><TD>EXIT</TD></TR>"); pp_newline (pp); had_row = true; } /* Phi nodes. */ for (gphi_iterator gpi = const_cast<supernode *> (this)->start_phis (); !gsi_end_p (gpi); gsi_next (&gpi)) { const gimple *stmt = gsi_stmt (gpi); gv->begin_tr (); pp_gimple_stmt_1 (pp, stmt, 0, (dump_flags_t)0); pp_write_text_as_html_like_dot_to_stream (pp); gv->end_tr (); if (args.m_node_annotator) args.m_node_annotator->add_stmt_annotations (gv, stmt); pp_newline (pp); had_row = true; } /* Statements. */ int i; gimple *stmt; FOR_EACH_VEC_ELT (m_stmts, i, stmt) { gv->begin_tr (); pp_gimple_stmt_1 (pp, stmt, 0, (dump_flags_t)0); pp_write_text_as_html_like_dot_to_stream (pp); gv->end_tr (); if (args.m_node_annotator) args.m_node_annotator->add_stmt_annotations (gv, stmt); pp_newline (pp); had_row = true; } /* Graphviz requires a TABLE element to have at least one TR (and each TR to have at least one TD). */ if (!had_row) { pp_string (pp, "<TR><TD>(empty)</TD></TR>"); pp_newline (pp); } pp_string (pp, "</TABLE>>];\n\n"); pp_flush (pp); /* Terminate "subgraph" */ gv->outdent (); gv->println ("}"); } /* Write an ID for this node to PP, for use in .dot output. */ void supernode::dump_dot_id (pretty_printer *pp) const { pp_printf (pp, "node_%i", m_index); } /* Get a location_t for the start of this supernode. */ location_t supernode::get_start_location () const { if (m_returning_call && get_pure_location (m_returning_call->location) != UNKNOWN_LOCATION) return m_returning_call->location; int i; gimple *stmt; FOR_EACH_VEC_ELT (m_stmts, i, stmt) if (get_pure_location (stmt->location) != UNKNOWN_LOCATION) return stmt->location; if (entry_p ()) { // TWEAK: show the decl instead; this leads to more readable output: return DECL_SOURCE_LOCATION (m_fun->decl); return m_fun->function_start_locus; } if (return_p ()) return m_fun->function_end_locus; return UNKNOWN_LOCATION; } /* Get a location_t for the end of this supernode. */ location_t supernode::get_end_location () const { int i; gimple *stmt; FOR_EACH_VEC_ELT_REVERSE (m_stmts, i, stmt) if (get_pure_location (stmt->location) != UNKNOWN_LOCATION) return stmt->location; if (m_returning_call && get_pure_location (m_returning_call->location) != UNKNOWN_LOCATION) return m_returning_call->location; if (entry_p ()) return m_fun->function_start_locus; if (return_p ()) return m_fun->function_end_locus; return UNKNOWN_LOCATION; } /* Given STMT within this supernode, return its index within m_stmts. */ unsigned int supernode::get_stmt_index (const gimple *stmt) const { unsigned i; gimple *iter_stmt; FOR_EACH_VEC_ELT (m_stmts, i, iter_stmt) if (iter_stmt == stmt) return i; gcc_unreachable (); } /* Implementation of dedge::dump_dot for superedges. Write a .dot edge to GV representing this superedge. */ void superedge::dump_dot (graphviz_out *gv, const dump_args_t &) const { const char *style = "\"solid,bold\""; const char *color = "black"; int weight = 10; const char *constraint = "true"; switch (m_kind) { default: gcc_unreachable (); case SUPEREDGE_CFG_EDGE: break; case SUPEREDGE_CALL: color = "red"; break; case SUPEREDGE_RETURN: color = "green"; break; case SUPEREDGE_INTRAPROCEDURAL_CALL: style = "\"dotted\""; break; } /* Adapted from graph.c:draw_cfg_node_succ_edges. */ if (::edge cfg_edge = get_any_cfg_edge ()) { if (cfg_edge->flags & EDGE_FAKE) { style = "dotted"; color = "green"; weight = 0; } else if (cfg_edge->flags & EDGE_DFS_BACK) { style = "\"dotted,bold\""; color = "blue"; weight = 10; } else if (cfg_edge->flags & EDGE_FALLTHRU) { color = "blue"; weight = 100; } if (cfg_edge->flags & EDGE_ABNORMAL) color = "red"; } gv->write_indent (); pretty_printer *pp = gv->get_pp (); m_src->dump_dot_id (pp); pp_string (pp, " -> "); m_dest->dump_dot_id (pp); pp_printf (pp, (" [style=%s, color=%s, weight=%d, constraint=%s," " ltail=\"cluster_node_%i\", lhead=\"cluster_node_%i\"" " headlabel=\""), style, color, weight, constraint, m_src->m_index, m_dest->m_index); dump_label_to_pp (pp, false); pp_printf (pp, "\"];\n"); } /* If this is an intraprocedural superedge, return the associated CFG edge. Otherwise, return NULL. */ ::edge superedge::get_any_cfg_edge () const { if (const cfg_superedge *sub = dyn_cast_cfg_superedge ()) return sub->get_cfg_edge (); return NULL; } /* If this is an interprocedural superedge, return the associated cgraph_edge *. Otherwise, return NULL. */ cgraph_edge * superedge::get_any_callgraph_edge () const { if (const callgraph_superedge *sub = dyn_cast_callgraph_superedge ()) return sub->m_cedge; return NULL; } /* Build a description of this superedge (e.g. "true" for the true edge of a conditional, or "case 42:" for a switch case). The caller is responsible for freeing the result. If USER_FACING is false, the result also contains any underlying CFG edge flags. e.g. " (flags FALLTHRU | DFS_BACK)". */ char * superedge::get_description (bool user_facing) const { pretty_printer pp; dump_label_to_pp (&pp, user_facing); return xstrdup (pp_formatted_text (&pp)); } /* Implementation of superedge::dump_label_to_pp for non-switch CFG superedges. For true/false edges, print "true" or "false" to PP. If USER_FACING is false, also print flags on the underlying CFG edge to PP. */ void cfg_superedge::dump_label_to_pp (pretty_printer *pp, bool user_facing) const { if (true_value_p ()) pp_printf (pp, "true"); else if (false_value_p ()) pp_printf (pp, "false"); if (user_facing) return; /* Express edge flags as a string with " | " separator. e.g. " (flags FALLTHRU | DFS_BACK)". */ if (get_flags ()) { pp_string (pp, " (flags "); bool seen_flag = false; #define DEF_EDGE_FLAG(NAME,IDX) \ do { \ if (get_flags () & EDGE_##NAME) \ { \ if (seen_flag) \ pp_string (pp, " | "); \ pp_printf (pp, "%s", (#NAME)); \ seen_flag = true; \ } \ } while (0); #include "cfg-flags.def" #undef DEF_EDGE_FLAG pp_string (pp, ")"); } /* Otherwise, no label. */ } /* Get the phi argument for PHI for this CFG edge. */ tree cfg_superedge::get_phi_arg (const gphi *phi) const { size_t index = m_cfg_edge->dest_idx; return gimple_phi_arg_def (phi, index); } /* Implementation of superedge::dump_label_to_pp for CFG superedges for "switch" statements. Print "case VAL:", "case LOWER ... UPPER:", or "default:" to PP. */ void switch_cfg_superedge::dump_label_to_pp (pretty_printer *pp, bool user_facing ATTRIBUTE_UNUSED) const { tree case_label = get_case_label (); gcc_assert (TREE_CODE (case_label) == CASE_LABEL_EXPR); tree lower_bound = CASE_LOW (case_label); tree upper_bound = CASE_HIGH (case_label); if (lower_bound) { pp_printf (pp, "case "); dump_generic_node (pp, lower_bound, 0, (dump_flags_t)0, false); if (upper_bound) { pp_printf (pp, " ... "); dump_generic_node (pp, upper_bound, 0, (dump_flags_t)0, false); } pp_printf (pp, ":"); } else pp_printf (pp, "default:"); } /* Get the case label for this "switch" superedge. */ tree switch_cfg_superedge::get_case_label () const { return gimple_switch_label (get_switch_stmt (), m_idx); } /* Implementation of superedge::dump_label_to_pp for interprocedural superedges. */ void callgraph_superedge::dump_label_to_pp (pretty_printer *pp, bool user_facing ATTRIBUTE_UNUSED) const { switch (m_kind) { default: case SUPEREDGE_CFG_EDGE: gcc_unreachable (); case SUPEREDGE_CALL: pp_printf (pp, "call"); break; case SUPEREDGE_RETURN: pp_printf (pp, "return"); break; case SUPEREDGE_INTRAPROCEDURAL_CALL: pp_printf (pp, "intraproc link"); break; } } /* Get the function that was called at this interprocedural call/return edge. */ function * callgraph_superedge::get_callee_function () const { return get_ultimate_function_for_cgraph_edge (m_cedge); } /* Get the calling function at this interprocedural call/return edge. */ function * callgraph_superedge::get_caller_function () const { return m_cedge->caller->get_fun (); } /* Get the fndecl that was called at this interprocedural call/return edge. */ tree callgraph_superedge::get_callee_decl () const { return get_callee_function ()->decl; } /* Get the calling fndecl at this interprocedural call/return edge. */ tree callgraph_superedge::get_caller_decl () const { return get_caller_function ()->decl; } /* Given PARM_TO_FIND, a PARM_DECL, identify its index (writing it to *OUT if OUT is non-NULL), and return the corresponding argument at the callsite. */ tree callgraph_superedge::get_arg_for_parm (tree parm_to_find, callsite_expr *out) const { gcc_assert (TREE_CODE (parm_to_find) == PARM_DECL); tree callee = get_callee_decl (); const gcall *call_stmt = get_call_stmt (); unsigned i = 0; for (tree iter_parm = DECL_ARGUMENTS (callee); iter_parm; iter_parm = DECL_CHAIN (iter_parm), ++i) { if (i >= gimple_call_num_args (call_stmt)) return NULL_TREE; if (iter_parm == parm_to_find) { if (out) *out = callsite_expr::from_zero_based_param (i); return gimple_call_arg (call_stmt, i); } } /* Not found. */ return NULL_TREE; } /* Look for a use of ARG_TO_FIND as an argument at this callsite. If found, return the default SSA def of the corresponding parm within the callee, and if OUT is non-NULL, write the index to *OUT. Only the first match is handled. */ tree callgraph_superedge::get_parm_for_arg (tree arg_to_find, callsite_expr *out) const { tree callee = get_callee_decl (); const gcall *call_stmt = get_call_stmt (); unsigned i = 0; for (tree iter_parm = DECL_ARGUMENTS (callee); iter_parm; iter_parm = DECL_CHAIN (iter_parm), ++i) { if (i >= gimple_call_num_args (call_stmt)) return NULL_TREE; tree param = gimple_call_arg (call_stmt, i); if (arg_to_find == param) { if (out) *out = callsite_expr::from_zero_based_param (i); return ssa_default_def (get_callee_function (), iter_parm); } } /* Not found. */ return NULL_TREE; } /* Map caller_expr back to an expr within the callee, or return NULL_TREE. If non-NULL is returned, populate OUT. */ tree callgraph_superedge::map_expr_from_caller_to_callee (tree caller_expr, callsite_expr *out) const { /* Is it an argument (actual param)? If so, convert to parameter (formal param). */ tree parm = get_parm_for_arg (caller_expr, out); if (parm) return parm; /* Otherwise try return value. */ if (caller_expr == gimple_call_lhs (get_call_stmt ())) { if (out) *out = callsite_expr::from_return_value (); return DECL_RESULT (get_callee_decl ()); } return NULL_TREE; } /* Map callee_expr back to an expr within the caller, or return NULL_TREE. If non-NULL is returned, populate OUT. */ tree callgraph_superedge::map_expr_from_callee_to_caller (tree callee_expr, callsite_expr *out) const { if (callee_expr == NULL_TREE) return NULL_TREE; /* If it's a parameter (formal param), get the argument (actual param). */ if (TREE_CODE (callee_expr) == PARM_DECL) return get_arg_for_parm (callee_expr, out); /* Similar for the default SSA name of the PARM_DECL. */ if (TREE_CODE (callee_expr) == SSA_NAME && SSA_NAME_IS_DEFAULT_DEF (callee_expr) && TREE_CODE (SSA_NAME_VAR (callee_expr)) == PARM_DECL) return get_arg_for_parm (SSA_NAME_VAR (callee_expr), out); /* Otherwise try return value. */ if (callee_expr == DECL_RESULT (get_callee_decl ())) { if (out) *out = callsite_expr::from_return_value (); return gimple_call_lhs (get_call_stmt ()); } return NULL_TREE; } } // namespace ana #endif /* #if ENABLE_ANALYZER */