/* flow.c Flow graph analysis Copyright (C) 2012 Bill Currie Author: Bill Currie Date: 2012/10/30 This program 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 2 of the License, or (at your option) any later version. This program 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 this program; if not, write to: Free Software Foundation, Inc. 59 Temple Place - Suite 330 Boston, MA 02111-1307, USA */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #ifdef HAVE_STRING_H # include #endif #ifdef HAVE_STRINGS_H # include #endif #include #include "QF/alloc.h" #include "QF/dstring.h" #include "QF/set.h" #include "QF/va.h" #include "dags.h" #include "def.h" #include "diagnostic.h" #include "dot.h" #include "flow.h" #include "function.h" #include "options.h" #include "qfcc.h" #include "statements.h" #include "symtab.h" #include "type.h" static flowvar_t *free_vars; static flowloop_t *free_loops; static flownode_t *free_nodes; static flowgraph_t *free_graphs; static struct { const char *name; operand_t op; } flow_params[] = { {".return", {0, op_def}}, {".param_0", {0, op_def}}, {".param_1", {0, op_def}}, {".param_2", {0, op_def}}, {".param_3", {0, op_def}}, {".param_4", {0, op_def}}, {".param_5", {0, op_def}}, {".param_6", {0, op_def}}, {".param_7", {0, op_def}}, }; static const int num_flow_params = sizeof(flow_params)/sizeof(flow_params[0]); static flowvar_t * new_flowvar (void) { flowvar_t *var; ALLOC (256, flowvar_t, vars, var); var->use = set_new (); var->define = set_new (); return var; } static flowloop_t * new_loop (void) { flowloop_t *loop; ALLOC (256, flowloop_t, loops, loop); loop->nodes = set_new (); return loop; } static void delete_loop (flowloop_t *loop) { set_delete (loop->nodes); FREE (loops, loop); } static flownode_t * new_node (void) { flownode_t *node; ALLOC (256, flownode_t, nodes, node); return node; } static void delete_node (flownode_t *node) { if (node->predecessors) set_delete (node->predecessors); if (node->successors) set_delete (node->successors); if (node->edges) set_delete (node->edges); if (node->dom) set_delete (node->dom); FREE (nodes, node); } static flowgraph_t * new_graph (void) { flowgraph_t *graph; ALLOC (256, flowgraph_t, graphs, graph); return graph; } static void __attribute__((unused)) delete_graph (flowgraph_t *graph) { int i; if (graph->nodes) { for (i = 0; i < graph->num_nodes; i++) delete_node (graph->nodes[i]); free (graph->nodes); } if (graph->edges) free (graph->edges); if (graph->dfst) set_delete (graph->dfst); if (graph->dfo) free (graph->dfo); FREE (graphs, graph); } static def_t * flowvar_get_def (flowvar_t *var) { operand_t *op = var->op; switch (op->op_type) { case op_def: return op->o.def; case op_value: case op_label: return 0; case op_temp: return op->o.tempop.def; } internal_error (0, "oops, blue pill"); return 0; } static int flowvar_is_global (flowvar_t *var) { def_t *def; if (var->op->op_type != op_def) return 0; def = var->op->o.def; if (def->local) return 0; return 1; } static int flowvar_is_param (flowvar_t *var) { def_t *def; if (var->op->op_type != op_def) return 0; def = var->op->o.def; if (!def->local) return 0; if (!def->param) return 0; return 1; } static int flowvar_is_initialized (flowvar_t *var) { def_t *def; if (var->op->op_type != op_def) return 0; def = var->op->o.def; return def->initialized; } flowvar_t * flow_get_var (operand_t *op) { if (!op) return 0; if (op->op_type == op_temp) { if (!op->o.tempop.flowvar) op->o.tempop.flowvar = new_flowvar (); return op->o.tempop.flowvar; } if (op->op_type == op_def) { if (!op->o.def->flowvar) op->o.def->flowvar = new_flowvar (); return op->o.def->flowvar; } return 0; } static int count_operand (operand_t *op) { flowvar_t *var; if (!op) return 0; if (op->op_type == op_label) return 0; var = flow_get_var (op); // flowvars are initialized with number == 0, and any global flowvar // used by a function will always have a number >= 0 after flow analysis, // and local flowvars will always be 0 before flow analysis, so use -1 // to indicate the variable has been counted. // // Also, since this is the beginning of flow analysis for this function, // ensure the define/use sets for global vars are empty. However, as // checking if a var is global is too much trouble, just clear them all. if (var && var->number != -1) { set_empty (var->use); set_empty (var->define); var->number = -1; return 1; } return 0; } static void add_operand (function_t *func, operand_t *op) { flowvar_t *var; if (!op) return; if (op->op_type == op_label) return; var = flow_get_var (op); // If the flowvar number is still -1, then the flowvar has not yet been // added to the list of variables referenced by the function. if (var && var->number == -1) { var->number = func->num_vars++; var->op = op; func->vars[var->number] = var; } } static symbol_t * param_symbol (const char *name) { symbol_t *sym; sym = make_symbol (name, &type_param, pr.symtab->space, sc_extern); if (!sym->table) symtab_addsymbol (pr.symtab, sym); return sym; } static void flow_build_statements (function_t *func) { sblock_t *sblock; statement_t *s; int num_statements = 0; for (sblock = func->sblock; sblock; sblock = sblock->next) { for (s = sblock->statements; s; s = s->next) s->number = num_statements++; } if (!num_statements) return; func->statements = malloc (num_statements * sizeof (statement_t *)); func->num_statements = num_statements; for (sblock = func->sblock; sblock; sblock = sblock->next) { for (s = sblock->statements; s; s = s->next) func->statements[s->number] = s; } } static void flow_build_vars (function_t *func) { statement_t *s; int num_vars = 0; int i; set_t *stuse; set_t *stdef; set_iter_t *var_i; flowvar_t *var; // first, count .return and .param_[0-7] as they are always needed for (i = 0; i < num_flow_params; i++) { flow_params[i].op.o.def = param_symbol (flow_params[i].name)->s.def; num_vars += count_operand (&flow_params[i].op); } // then run through the statements in the function looking for accessed // variables for (i = 0; i < func->num_statements; i++) { s = func->statements[i]; num_vars += count_operand (s->opa); num_vars += count_operand (s->opb); num_vars += count_operand (s->opc); } if (!num_vars) return; func->vars = malloc (num_vars * sizeof (daglabel_t *)); stuse = set_new (); stdef = set_new (); func->num_vars = 0; // incremented by add_operand // first, add .return and .param_[0-7] as they are always needed for (i = 0; i < num_flow_params; i++) add_operand (func, &flow_params[i].op); // then run through the statements in the function adding accessed // variables for (i = 0; i < func->num_statements; i++) { s = func->statements[i]; add_operand (func, s->opa); add_operand (func, s->opb); add_operand (func, s->opc); flow_analyze_statement (s, stuse, stdef, 0, 0); for (var_i = set_first (stdef); var_i; var_i = set_next (var_i)) { var = func->vars[var_i->value]; set_add (var->define, i); } for (var_i = set_first (stuse); var_i; var_i = set_next (var_i)) { var = func->vars[var_i->value]; set_add (var->use, i); } } func->global_vars = set_new (); // mark all global vars (except .return and .param_N) for (i = num_flow_params; i < func->num_vars; i++) { if (flowvar_is_global (func->vars[i])) set_add (func->global_vars, i); } set_delete (stuse); set_delete (stdef); } static void flow_kill_aliases (set_t *kill, flowvar_t *var) { operand_t *op; def_t *st_def; def_t *def; set_union (kill, var->define); op = var->op; if (op->op_type == op_temp) { if (op->o.tempop.alias) { op = op->o.tempop.alias; var = op->o.tempop.flowvar; if (var) set_union (kill, var->define); } for (op = op->o.tempop.alias_ops; op; op = op->next) { var = op->o.tempop.flowvar; if (var) set_union (kill, var->define); } } else if (op->op_type == op_def) { st_def = def = op->o.def; if (def->alias) { def = def->alias; var = def->flowvar; if (var) set_union (kill, var->define); } for (def = def->alias_defs; def; def = def->next) { if (!def_overlap (def, st_def)) continue; var = def->flowvar; if (var) set_union (kill, var->define); } } } static void flow_reaching_defs (flowgraph_t *graph) { int i; int changed; flownode_t *node; statement_t *st; set_t *stdef = set_new (); set_t *stgen = set_new (); set_t *stkill = set_new (); set_t *oldout = set_new (); set_t *gen, *kill, *in, *out; set_iter_t *var_i; set_iter_t *pred_i; flowvar_t *var; // First, calculate gen and kill for each block, and initialize in and out for (i = 0; i < graph->num_nodes; i++) { node = graph->nodes[i]; gen = set_new (); kill = set_new (); for (st = node->sblock->statements; st; st = st->next) { flow_analyze_statement (st, 0, stdef, 0, 0); set_empty (stgen); set_empty (stkill); for (var_i = set_first (stdef); var_i; var_i = set_next (var_i)) { var = graph->func->vars[var_i->value]; flow_kill_aliases (stkill, var); set_remove (stkill, st->number); set_add (stgen, st->number); } set_difference (gen, stkill); set_union (gen, stgen); set_difference (kill, stgen); set_union (kill, stkill); } node->reaching_defs.gen = gen; node->reaching_defs.kill = kill; node->reaching_defs.in = set_new (); node->reaching_defs.out = set_new (); } while (changed) { changed = 0; // flow down the graph for (i = 0; i < graph->num_nodes; i++) { node = graph->nodes[graph->dfo[i]]; in = node->reaching_defs.in; out = node->reaching_defs.out; gen = node->reaching_defs.gen; kill = node->reaching_defs.kill; for (pred_i = set_first (node->predecessors); pred_i; pred_i = set_next (pred_i)) { flownode_t *pred = graph->nodes[pred_i->value]; set_union (in, pred->reaching_defs.out); } set_assign (oldout, out); set_assign (out, in); set_difference (out, kill); set_union (out, gen); if (!set_is_equivalent (out, oldout)) changed = 1; } } set_delete (oldout); set_delete (stdef); set_delete (stgen); set_delete (stkill); } static void live_set_use (set_t *stuse, set_t *use, set_t *def) { // the variable is used before it is defined set_difference (stuse, def); set_union (use, stuse); } static void live_set_def (set_t *stdef, set_t *use, set_t *def) { // the variable is defined before it is used set_difference (stdef, use); set_union (def, stdef); } static void flow_live_vars (flowgraph_t *graph) { int i, j; flownode_t *node; set_t *use; set_t *def; set_t *stuse = set_new (); set_t *stdef = set_new (); set_t *tmp = set_new (); set_iter_t *succ; statement_t *st; int changed = 1; // first, calculate use and def for each block, and initialize the in and // out sets. for (i = 0; i < graph->num_nodes; i++) { node = graph->nodes[i]; use = set_new (); def = set_new (); for (st = node->sblock->statements; st; st = st->next) { flow_analyze_statement (st, stuse, stdef, 0, 0); if (st->type == st_func && !strncmp (st->opcode, "func->global_vars); live_set_use (global_vars, use, def); set_delete (global_vars); } live_set_use (stuse, use, def); live_set_def (stdef, use, def); } node->live_vars.use = use; node->live_vars.def = def; node->live_vars.in = set_new (); node->live_vars.out = set_new (); } while (changed) { changed = 0; // flow UP the graph because live variable analysis uses information // from a node's successors rather than its predecessors. for (j = graph->num_nodes - 1; j >= 0; j--) { node = graph->nodes[graph->dfo[j]]; set_empty (tmp); for (succ = set_first (node->successors); succ; succ = set_next (succ)) set_union (tmp, graph->nodes[succ->value]->live_vars.in); if (!set_is_equivalent (node->live_vars.out, tmp)) { changed = 1; set_assign (node->live_vars.out, tmp); } set_assign (node->live_vars.in, node->live_vars.out); set_difference (node->live_vars.in, node->live_vars.def); set_union (node->live_vars.in, node->live_vars.use); } } set_delete (stuse); set_delete (stdef); set_delete (tmp); } static void flow_uninitialized (flowgraph_t *graph) { set_t *stuse; set_t *stdef; set_t *tmp; set_t *uninit; set_t *use; set_t *def; set_t *predecessors; set_iter_t *pred_iter; set_iter_t *var_iter; flownode_t *node, *pred; function_t *func = graph->func; statement_t *st; int i; if (!graph->num_nodes) return; stuse = set_new (); stdef = set_new (); tmp = set_new (); uninit = set_new (); predecessors = set_new (); // in for the inital node contains parameters and global vars tmp = set_new (); for (i = 0; i < func->num_vars; i++) { flowvar_t *var = func->vars[i]; if (flowvar_is_global (var) || flowvar_is_param (var) || flowvar_is_initialized (var)) set_add (tmp, i); } // first, calculate use and def for each block, and initialize the in and // out sets. for (i = 0; i < graph->num_nodes; i++) { node = graph->nodes[i]; use = set_new (); def = set_new (); for (st = node->sblock->statements; st; st = st->next) { flow_analyze_statement (st, stuse, stdef, 0, 0); live_set_use (stuse, use, def); // init use uses same rules as live set_union (def, stdef); // for init, always def a set var } node->init_vars.use = use; node->init_vars.def = def; node->init_vars.in = set_new (); node->init_vars.out = set_new (); } // flow DOWN the graph in dept-first order node = graph->nodes[0]; set_assign (node->init_vars.in, tmp); set_assign (node->init_vars.out, tmp); set_union (node->init_vars.out, node->init_vars.def); set_assign (tmp, node->init_vars.use); set_difference (tmp, node->init_vars.in); set_union (uninit, tmp); for (i = 1; i < graph->num_nodes; i++) { node = graph->nodes[graph->dfo[i]]; set_assign (predecessors, node->predecessors); // not interested in back edges for (pred_iter = set_first (predecessors); pred_iter; pred_iter = set_next (pred_iter)) { pred = graph->nodes[pred_iter->value]; if (pred->dfn >= node->dfn) set_remove (predecessors, pred->id); } set_empty (tmp); pred_iter = set_first (predecessors); if (pred_iter) { pred = graph->nodes[pred_iter->value]; set_assign (tmp, pred->init_vars.out); pred_iter = set_next (pred_iter); } for ( ; pred_iter; pred_iter = set_next (pred_iter)) { pred = graph->nodes[pred_iter->value]; set_intersection (tmp, pred->init_vars.out); } set_assign (node->init_vars.in, tmp); set_assign (node->init_vars.out, tmp); set_union (node->init_vars.out, node->init_vars.def); set_assign (tmp, node->init_vars.use); set_difference (tmp, node->init_vars.in); set_union (uninit, tmp); } for (var_iter = set_first (uninit); var_iter; var_iter = set_next (var_iter)) { expr_t dummy; flowvar_t *var = func->vars[var_iter->value]; def_t *def; if (var->op->op_type == op_temp) { bug (0, "uninitialized temporary: %s", operand_string (var->op)); } else { def = flowvar_get_def (var); dummy.line = def->line; dummy.file = def->file; if (type_size (def->type) != 1) { bug (&dummy, "too hard basket"); } else { warning (&dummy, "%s may be used uninitialized", def->name); } } } set_delete (stuse); set_delete (stdef); set_delete (tmp); set_delete (uninit); set_delete (predecessors); } static void flow_build_dags (flowgraph_t *graph) { int i; flownode_t *node; for (i = 0; i < graph->num_nodes; i++) { node = graph->nodes[i]; node->dag = dag_create (node); } if (options.block_dot.dags) dump_dot ("dags", graph, dump_dot_flow_dags); } static sblock_t * flow_generate (flowgraph_t *graph) { int i; sblock_t *code = 0; sblock_t **tail = &code; for (i = 0; i < graph->num_nodes; i++) { ex_label_t *label; sblock_t *block; flownode_t *node = graph->nodes[i]; *tail = block = new_sblock (); tail = &(*tail)->next; // first, transfer any labels on the old node to the new while ((label = node->sblock->labels)) { node->sblock->labels = label->next; label->next = block->labels; block->labels = label; label->dest = block; } // generate new statements from the dag; dag_generate (node->dag, block); } if (options.block_dot.post) dump_dot ("post", code, dump_dot_sblock); return code; } static void flow_add_op_var (set_t *set, operand_t *op) { flowvar_t *var; if (!set) return; if (!(var = flow_get_var (op))) return; set_add (set, var->number); } void flow_analyze_statement (statement_t *s, set_t *use, set_t *def, set_t *kill, operand_t *operands[4]) { int i, start, calln = -1; if (use) set_empty (use); if (def) set_empty (def); if (kill) set_empty (kill); if (operands) { for (i = 0; i < 4; i++) operands[i] = 0; } switch (s->type) { case st_none: internal_error (s->expr, "not a statement"); case st_expr: flow_add_op_var (def, s->opc); flow_add_op_var (use, s->opa); if (s->opb) flow_add_op_var (use, s->opb); if (operands) { operands[0] = s->opc; operands[1] = s->opa; operands[2] = s->opb; } break; case st_assign: flow_add_op_var (def, s->opb); flow_add_op_var (use, s->opa); if (operands) { operands[0] = s->opb; operands[1] = s->opa; } break; case st_ptrassign: case st_move: flow_add_op_var (use, s->opa); flow_add_op_var (use, s->opb); if (!strcmp (s->opcode, "")) { flow_add_op_var (def, s->opc); } else { if (s->opc) flow_add_op_var (use, s->opc); } if (kill) { //FIXME set of everything } if (operands) { operands[1] = s->opa; operands[2] = s->opb; operands[3] = s->opc; } break; case st_state: flow_add_op_var (use, s->opa); flow_add_op_var (use, s->opb); if (s->opc) flow_add_op_var (use, s->opc); //FIXME entity members if (operands) { operands[1] = s->opa; operands[2] = s->opb; operands[3] = s->opc; } break; case st_func: if (strcmp (s->opcode, "") == 0 || strcmp (s->opcode, "") == 0) { flow_add_op_var (use, s->opa); } else if (strcmp (s->opcode, "") == 0) { if (use) set_add (use, 0); //FIXME assumes .return location } if (strncmp (s->opcode, "opcode[5] - '0'; flow_add_op_var (use, s->opa); } else if (strncmp (s->opcode, "opcode[6] - '0'; flow_add_op_var (use, s->opa); flow_add_op_var (use, s->opb); if (s->opc) flow_add_op_var (use, s->opc); } if (calln >= 0) { if (use) { for (i = start; i < calln; i++) set_add (use, i + 1);//FIXME assumes .param_N locations } if (kill) set_add (kill, 0); //FIXME assumes .return location } if (operands) { operands[1] = s->opa; operands[2] = s->opb; operands[3] = s->opc; } break; case st_flow: if (strcmp (s->opcode, "") != 0) { flow_add_op_var (use, s->opa); if (strcmp (s->opcode, "") == 0) flow_add_op_var (use, s->opb); } if (operands) { operands[1] = s->opa; operands[2] = s->opb; } break; } } static void flow_find_predecessors (flowgraph_t *graph) { int i; flownode_t *node; set_iter_t *succ; for (i = 0; i < graph->num_nodes + 2; i++) { node = graph->nodes[i]; for (succ = set_first (node->successors); succ; succ = set_next (succ)) { set_add (graph->nodes[succ->value]->predecessors, i); } } for (i = 1; i < graph->num_nodes; i++) { node = graph->nodes[i]; if (set_is_empty (node->predecessors)) internal_error (0, "non-initial node with no predecessors"); } } static void flow_find_dominators (flowgraph_t *graph) { set_t *work; flownode_t *node; int i; set_iter_t *pred; int changed; if (!graph->num_nodes) return; // First, create a base set for the initial state of the non-initial nodes work = set_new (); for (i = 0; i < graph->num_nodes; i++) set_add (work, i); set_add (graph->nodes[0]->dom, 0); // initialize dom for the non-initial nodes for (i = 1; i < graph->num_nodes; i++) { set_assign (graph->nodes[i]->dom, work); } do { changed = 0; for (i = 1; i < graph->num_nodes; i++) { node = graph->nodes[i]; pred = set_first (node->predecessors); set_empty (work); for (pred = set_first (node->predecessors); pred; pred = set_next (pred)) set_intersection (work, graph->nodes[pred->value]->dom); set_add (work, i); if (!set_is_equivalent (work, node->dom)) changed = 1; set_assign (node->dom, work); } } while (changed); set_delete (work); } static void insert_loop_node (flowloop_t *loop, unsigned n, set_t *stack) { if (!set_is_member (loop->nodes, n)) { set_add (loop->nodes, n); set_add (stack, n); } } static flowloop_t * make_loop (flowgraph_t *graph, unsigned n, unsigned d) { flowloop_t *loop = new_loop (); flownode_t *node; set_t *stack = set_new (); set_iter_t *pred; loop->head = d; set_add (loop->nodes, d); insert_loop_node (loop, n, stack); while (!set_is_empty (stack)) { set_iter_t *ss = set_first (stack); unsigned m = ss->value; set_del_iter (ss); set_remove (stack, m); node = graph->nodes[m]; for (pred = set_first (node->predecessors); pred; pred = set_next (pred)) insert_loop_node (loop, pred->value, stack); } set_delete (stack); return loop; } static void flow_find_loops (flowgraph_t *graph) { flownode_t *node; set_iter_t *succ; flowloop_t *loop, *l; flowloop_t *loop_list = 0; int i; for (i = 0; i < graph->num_nodes; i++) { node = graph->nodes[i]; for (succ = set_first (node->successors); succ; succ = set_next (succ)) { if (set_is_member (node->dom, succ->value)) { loop = make_loop (graph, node->id, succ->value); for (l = loop_list; l; l = l->next) { if (l->head == loop->head && !set_is_subset (l->nodes, loop->nodes) && !set_is_subset (loop->nodes, l->nodes)) { set_union (l->nodes, loop->nodes); delete_loop (loop); loop = 0; break; } } if (loop) { loop->next = loop_list; loop_list = loop; } } } } graph->loops = loop_list; } static void df_search (flowgraph_t *graph, set_t *visited, int *i, int n) { flownode_t *node; set_iter_t *edge; int succ; set_add (visited, n); node = graph->nodes[n]; for (edge = set_first (node->edges); edge; edge = set_next (edge)) { succ = graph->edges[edge->value].head; if (!set_is_member (visited, succ)) { set_add (graph->dfst, edge->value); df_search (graph, visited, i, succ); } } node->dfn = --*i; graph->dfo[node->dfn] = n; } static void flow_build_dfst (flowgraph_t *graph) { set_t *visited = set_new (); int i; // mark the dummy nodes as visited to keep them out of the dfst set_add (visited, graph->num_nodes); set_add (visited, graph->num_nodes + 1); graph->dfo = malloc (graph->num_nodes * sizeof (unsigned)); graph->dfst = set_new (); i = graph->num_nodes; df_search (graph, visited, &i, 0); set_delete (visited); } static flownode_t * flow_make_node (sblock_t *sblock, int id, function_t *func) { flownode_t *node; node = new_node (); node->predecessors = set_new (); node->successors = set_new (); node->edges = set_new (); node->dom = set_new (); node->global_vars = func->global_vars; node->id = id; node->sblock = sblock; return node; } static flowgraph_t * flow_build_graph (function_t *func) { sblock_t *sblock = func->sblock; flowgraph_t *graph; flownode_t *node; sblock_t *sb; sblock_t **target_list, **target; statement_t *st; set_iter_t *succ; int i, j; graph = new_graph (); graph->func = func; for (sb = sblock; sb; sb = sb->next) sb->number = graph->num_nodes++; // + 2 for the uninitialized dummy head block and the live dummy end block graph->nodes = malloc ((graph->num_nodes + 2) * sizeof (flownode_t *)); for (sb = sblock; sb; sb = sb->next) graph->nodes[sb->number] = flow_make_node (sb, sb->number, func); // Create the dummy node for detecting uninitialized variables node = flow_make_node (0, graph->num_nodes, func); graph->nodes[graph->num_nodes] = node; // Create the dummy node for making global vars live at function exit node = flow_make_node (0, graph->num_nodes + 1, func); graph->nodes[graph->num_nodes + 1] = node; // "convert" the basic blocks connections to flow-graph connections for (i = 0; i < graph->num_nodes; i++) { node = graph->nodes[i]; sb = node->sblock; st = 0; if (sb->statements) st = (statement_t *) sb->tail; //NOTE: if st is null (the sblock has no statements), statement_is_* //will return false //FIXME jump/jumpb if (statement_is_goto (st)) { // sb's next is never followed. set_add (node->successors, statement_get_target (st)->number); } else if (statement_is_jumpb (st)) { target_list = statement_get_targetlist (st); for (target = target_list; *target; target++) set_add (node->successors, (*target)->number); free (target_list); } else if (statement_is_cond (st)) { // branch: either sb's next or the conditional statment's // target will be followed. set_add (node->successors, sb->next->number); set_add (node->successors, statement_get_target (st)->number); } else if (statement_is_return (st)) { // exit from function (dead end) // however, make the exit dummy block the node's successor set_add (node->successors, graph->num_nodes + 1); } else { // there is no flow-control statement in sb, so sb's next // must be followed if (sb->next) { set_add (node->successors, sb->next->number); } else { bug (0, "code drops off the end of the function"); // this shouldn't happen // however, make the exit dummy block the node's successor set_add (node->successors, graph->num_nodes + 1); } } graph->num_edges += set_size (node->successors); } // set the successor for the entry dummy node to the real entry node node = graph->nodes[graph->num_nodes]; set_add (node->successors, 0); graph->num_edges += set_size (node->successors); graph->edges = malloc (graph->num_edges * sizeof (flowedge_t *)); for (j = 0, i = 0; i < graph->num_nodes + 2; i++) { node = graph->nodes[i]; for (succ = set_first (node->successors); succ; succ = set_next (succ), j++) { set_add (node->edges, j); graph->edges[j].tail = i; graph->edges[j].head = succ->value; } } flow_build_dfst (graph); flow_find_predecessors (graph); flow_find_dominators (graph); flow_find_loops (graph); return graph; } void flow_data_flow (function_t *func) { flowgraph_t *graph; flow_build_statements (func); flow_build_vars (func); graph = flow_build_graph (func); if (options.block_dot.flow) dump_dot ("flow", graph, dump_dot_flow); func->graph = graph; flow_reaching_defs (graph); if (options.block_dot.reaching) dump_dot ("reaching", graph, dump_dot_flow_reaching); flow_live_vars (graph); flow_uninitialized (graph); flow_build_dags (graph); func->sblock = flow_generate (graph); }