/* $NetBSD: profile.c,v 1.1.1.1 2003/10/06 15:46:56 wiz Exp $ */ /* * profile.c - gawk parse tree pretty-printer with counts */ /* * Copyright (C) 1999-2003 the Free Software Foundation, Inc. * * This file is part of GAWK, the GNU implementation of the * AWK Programming Language. * * GAWK 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. * * GAWK 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 the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA */ #include "awk.h" /* where to place redirections for getline, print, printf */ enum redir_placement { BEFORE = 0, AFTER = 1 }; #undef tree_eval static void tree_eval P((NODE *tree)); static void parenthesize P((NODETYPE parent_type, NODE *tree)); static void eval_condition P((NODE *tree)); static void pp_op_assign P((NODE *tree)); static void pp_func_call P((NODE *tree)); static void pp_match_op P((NODE *tree)); static void pp_lhs P((NODE *ptr)); static void pp_print_stmt P((const char *command, NODE *tree)); static void pp_delete P((NODE *tree)); static void pp_in_array P((NODE *array, NODE *subscript)); static void pp_getline P((NODE *tree)); static void pp_builtin P((NODE *tree)); static void pp_list P((NODE *tree)); static void pp_string P((const char *str, size_t len, int delim)); static int is_scalar P((NODETYPE type)); static int prec_level P((NODETYPE type)); #ifdef PROFILING static RETSIGTYPE dump_and_exit P((int signum)) ATTRIBUTE_NORETURN; static RETSIGTYPE just_dump P((int signum)); #endif /* pretty printing related functions and variables */ static char **fparms; /* function parameter names */ static FILE *prof_fp; /* where to send the profile */ static long indent_level = 0; static int in_BEGIN_or_END = FALSE; static int in_expr = FALSE; #define SPACEOVER 0 /* init_profiling --- do needed initializations, see also main.c */ void init_profiling(int *flag ATTRIBUTE_UNUSED, const char *def_file ATTRIBUTE_UNUSED) { #ifdef PROFILING if (*flag == FALSE) { *flag = TRUE; set_prof_file(def_file); } #endif } /* set_prof_file --- set the output file for profiling */ void set_prof_file(const char *file) { assert(file != NULL); prof_fp = fopen(file, "w"); if (prof_fp == NULL) { warning(_("could not open `%s' for writing: %s"), file, strerror(errno)); warning(_("sending profile to standard error")); prof_fp = stderr; } } /* init_profiling_signals --- set up signal handling for pgawk */ void init_profiling_signals() { #ifdef PROFILING #ifdef __DJGPP__ signal(SIGINT, dump_and_exit); signal(SIGQUIT, just_dump); #else /* !__DJGPP__ */ #ifdef SIGHUP signal(SIGHUP, dump_and_exit); #endif #ifdef SIGUSR1 signal(SIGUSR1, just_dump); #endif #endif /* !__DJGPP__ */ #endif /* PROFILING */ } /* indent --- print out enough tabs */ static void indent(long count) { int i; if (count == 0) putc('\t', prof_fp); else fprintf(prof_fp, "%6ld ", count); assert(indent_level >= 0); for (i = 0; i < indent_level; i++) putc('\t', prof_fp); } /* indent_in --- increase the level, with error checking */ static void indent_in(void) { assert(indent_level >= 0); indent_level++; } /* indent_out --- decrease the level, with error checking */ static void indent_out(void) { indent_level--; assert(indent_level >= 0); } /* * pprint: * Tree is a bunch of rules to run. Returns zero if it hit an exit() * statement */ static void pprint(register NODE *volatile tree) { register NODE *volatile t = NULL; /* temporary */ int volatile traverse = TRUE; /* True => loop thru tree (Node_rule_list) */ /* avoid false source indications */ source = NULL; sourceline = 0; if (tree == NULL) return; sourceline = tree->source_line; source = tree->source_file; switch (tree->type) { case Node_rule_node: traverse = FALSE; /* False => one for-loop iteration only */ /* FALL THROUGH */ case Node_rule_list: for (t = tree; t != NULL; t = t->rnode) { if (traverse) tree = t->lnode; sourceline = tree->source_line; source = tree->source_file; if (! in_BEGIN_or_END) indent(tree->exec_count); if (tree->lnode) { eval_condition(tree->lnode); if (tree->rnode) fprintf(prof_fp, "\t"); } if (tree->rnode) { if (! in_BEGIN_or_END) { fprintf(prof_fp, "{"); if (tree->lnode != NULL && tree->lnode->exec_count) fprintf(prof_fp, " # %ld", tree->lnode->exec_count); fprintf(prof_fp, "\n"); } indent_in(); pprint(tree->rnode); indent_out(); if (! in_BEGIN_or_END) { indent(SPACEOVER); fprintf(prof_fp, "}\n"); } } if (! traverse) /* case Node_rule_node */ break; /* don't loop */ if (t->rnode && ! in_BEGIN_or_END) fprintf(prof_fp, "\n"); } break; case Node_statement_list: for (t = tree; t != NULL; t = t->rnode) { pprint(t->lnode); } break; case Node_K_if: indent(tree->exec_count); fprintf(prof_fp, "if ("); in_expr++; eval_condition(tree->lnode); in_expr--; fprintf(prof_fp, ") {"); #ifdef PROFILING if (tree->rnode->exec_count) fprintf(prof_fp, " # %ld", tree->rnode->exec_count); #endif fprintf(prof_fp, "\n"); indent_in(); pprint(tree->rnode->lnode); indent_out(); if (tree->rnode->rnode != NULL) { if (tree->exec_count - tree->rnode->exec_count > 0) indent(tree->exec_count - tree->rnode->exec_count); else indent(0); fprintf(prof_fp, "} else {\n"); indent_in(); pprint(tree->rnode->rnode); indent_out(); } indent(SPACEOVER); fprintf(prof_fp, "}\n"); break; case Node_K_switch: indent(tree->exec_count); fprintf(prof_fp, "switch ("); in_expr++; pprint(tree->lnode); in_expr--; fprintf(prof_fp, ") {\n"); pprint(tree->rnode); indent(SPACEOVER); fprintf(prof_fp, "}\n"); break; case Node_switch_body: case Node_case_list: pprint(tree->lnode); pprint(tree->rnode); break; case Node_K_case: indent(tree->exec_count); fprintf(prof_fp, "case "); in_expr++; pprint(tree->lnode); in_expr--; fprintf(prof_fp, ":\n"); indent_in(); pprint(tree->rnode); indent_out(); break; case Node_K_default: indent(tree->exec_count); fprintf(prof_fp, "default:\n"); indent_in(); pprint(tree->rnode); indent_out(); break; case Node_K_while: indent(tree->exec_count); fprintf(prof_fp, "while ("); in_expr++; eval_condition(tree->lnode); in_expr--; fprintf(prof_fp, ") {\n"); indent_in(); pprint(tree->rnode); indent_out(); indent(SPACEOVER); fprintf(prof_fp, "}\n"); break; case Node_K_do: indent(tree->exec_count); fprintf(prof_fp, "do {\n"); indent_in(); pprint(tree->rnode); indent_out(); indent(SPACEOVER); fprintf(prof_fp, "} while ("); in_expr++; eval_condition(tree->lnode); in_expr--; fprintf(prof_fp, ")\n"); break; case Node_K_for: indent(tree->exec_count); fprintf(prof_fp, "for ("); in_expr++; pprint(tree->forloop->init); fprintf(prof_fp, "; "); eval_condition(tree->forloop->cond); fprintf(prof_fp, "; "); pprint(tree->forloop->incr); fprintf(prof_fp, ") {\n"); in_expr--; indent_in(); pprint(tree->lnode); indent_out(); indent(SPACEOVER); fprintf(prof_fp, "}\n"); break; case Node_K_arrayfor: #define hakvar forloop->init #define arrvar forloop->incr indent(tree->exec_count); fprintf(prof_fp, "for ("); in_expr++; pp_lhs(tree->hakvar); in_expr--; fprintf(prof_fp, " in "); t = tree->arrvar; if (t->type == Node_param_list) fprintf(prof_fp, "%s", fparms[t->param_cnt]); else fprintf(prof_fp, "%s", t->vname); fprintf(prof_fp, ") {\n"); indent_in(); pprint(tree->lnode); indent_out(); indent(SPACEOVER); fprintf(prof_fp, "}\n"); break; #undef hakvar #undef arrvar case Node_K_break: indent(tree->exec_count); fprintf(prof_fp, "break\n"); break; case Node_K_continue: indent(tree->exec_count); fprintf(prof_fp, "continue\n"); break; case Node_K_print: case Node_K_print_rec: pp_print_stmt("print", tree); break; case Node_K_printf: pp_print_stmt("printf", tree); break; case Node_K_delete: pp_delete(tree); break; case Node_K_next: indent(tree->exec_count); fprintf(prof_fp, "next\n"); break; case Node_K_nextfile: indent(tree->exec_count); fprintf(prof_fp, "nextfile\n"); break; case Node_K_exit: indent(tree->exec_count); fprintf(prof_fp, "exit"); if (tree->lnode != NULL) { fprintf(prof_fp, " "); tree_eval(tree->lnode); } fprintf(prof_fp, "\n"); break; case Node_K_return: indent(tree->exec_count); fprintf(prof_fp, "return"); if (tree->lnode != NULL) { fprintf(prof_fp, " "); tree_eval(tree->lnode); } fprintf(prof_fp, "\n"); break; default: /* * Appears to be an expression statement. * Throw away the value. */ if (in_expr) tree_eval(tree); else { indent(tree->exec_count); tree_eval(tree); fprintf(prof_fp, "\n"); } break; } } /* tree_eval --- evaluate a subtree */ static void tree_eval(register NODE *tree) { if (tree == NULL) return; switch (tree->type) { case Node_param_list: fprintf(prof_fp, "%s", fparms[tree->param_cnt]); return; case Node_var_new: case Node_var: case Node_var_array: if (tree->vname != NULL) fprintf(prof_fp, "%s", tree->vname); else fatal(_("internal error: %s with null vname"), nodetype2str(tree->type)); return; case Node_val: if ((tree->flags & NUMBER) != 0) fprintf(prof_fp, "%g", tree->numbr); else { if ((tree->flags & INTLSTR) != 0) fprintf(prof_fp, "_"); pp_string(tree->stptr, tree->stlen, '"'); } return; case Node_and: eval_condition(tree->lnode); fprintf(prof_fp, " && "); eval_condition(tree->rnode); return; case Node_or: eval_condition(tree->lnode); fprintf(prof_fp, " || "); eval_condition(tree->rnode); return; case Node_not: parenthesize(tree->type, tree->lnode); return; /* Builtins */ case Node_builtin: pp_builtin(tree); return; case Node_in_array: in_expr++; pp_in_array(tree->lnode, tree->rnode); in_expr--; return; case Node_func_call: pp_func_call(tree); return; case Node_K_getline: pp_getline(tree); return; case Node_K_delete_loop: { char *aname; NODE *t; t = tree->lnode; if (t->type == Node_param_list) aname = fparms[t->param_cnt]; else aname = t->vname; fprintf(prof_fp, "for ("); pp_lhs(tree->rnode->lnode); fprintf(prof_fp, " in %s) { %s %s'\n", aname, _("# treated internally as `delete'"), aname); indent_in(); indent(SPACEOVER); fprintf(prof_fp, "delete %s[", aname); pp_lhs(tree->rnode->lnode); fprintf(prof_fp, "]\n"); indent_out(); indent(SPACEOVER); fprintf(prof_fp, "}"); } return; /* unary operations */ case Node_NR: fprintf(prof_fp, "NR"); return; case Node_FNR: fprintf(prof_fp, "FNR"); return; case Node_NF: fprintf(prof_fp, "NF"); return; case Node_FIELDWIDTHS: fprintf(prof_fp, "FIELDWIDTHS"); return; case Node_FS: fprintf(prof_fp, "FS"); return; case Node_RS: fprintf(prof_fp, "RS"); return; case Node_IGNORECASE: fprintf(prof_fp, "IGNORECASE"); return; case Node_OFS: fprintf(prof_fp, "OFS"); return; case Node_ORS: fprintf(prof_fp, "ORS"); return; case Node_OFMT: fprintf(prof_fp, "OFMT"); return; case Node_CONVFMT: fprintf(prof_fp, "CONVFMT"); return; case Node_BINMODE: fprintf(prof_fp, "BINMODE"); return; case Node_TEXTDOMAIN: fprintf(prof_fp, "TEXTDOMAIN"); return; case Node_field_spec: case Node_subscript: pp_lhs(tree); return; case Node_unary_minus: fprintf(prof_fp, " -"); if (is_scalar(tree->subnode->type)) tree_eval(tree->subnode); else { fprintf(prof_fp, "("); tree_eval(tree->subnode); fprintf(prof_fp, ")"); } return; case Node_cond_exp: eval_condition(tree->lnode); fprintf(prof_fp, " ? "); tree_eval(tree->rnode->lnode); fprintf(prof_fp, " : "); tree_eval(tree->rnode->rnode); return; case Node_match: case Node_nomatch: case Node_regex: case Node_dynregex: pp_match_op(tree); return; /* assignments */ case Node_assign: tree_eval(tree->lnode); fprintf(prof_fp, " = "); tree_eval(tree->rnode); return; case Node_concat: fprintf(prof_fp, "("); tree_eval(tree->lnode); fprintf(prof_fp, " "); tree_eval(tree->rnode); fprintf(prof_fp, ")"); return; /* other assignment types are easier because they are numeric */ case Node_preincrement: case Node_predecrement: case Node_postincrement: case Node_postdecrement: case Node_assign_exp: case Node_assign_times: case Node_assign_quotient: case Node_assign_mod: case Node_assign_plus: case Node_assign_minus: pp_op_assign(tree); return; default: break; /* handled below */ } /* handle binary ops */ in_expr++; parenthesize(tree->type, tree->lnode); switch (tree->type) { case Node_geq: fprintf(prof_fp, " >= "); break; case Node_leq: fprintf(prof_fp, " <= "); break; case Node_greater: fprintf(prof_fp, " > "); break; case Node_less: fprintf(prof_fp, " < "); break; case Node_notequal: fprintf(prof_fp, " != "); break; case Node_equal: fprintf(prof_fp, " == "); break; case Node_exp: fprintf(prof_fp, " ^ "); break; case Node_times: fprintf(prof_fp, " * "); break; case Node_quotient: fprintf(prof_fp, " / "); break; case Node_mod: fprintf(prof_fp, " %% "); break; case Node_plus: fprintf(prof_fp, " + "); break; case Node_minus: fprintf(prof_fp, " - "); break; default: fatal(_("illegal type (%s) in tree_eval"), nodetype2str(tree->type)); } parenthesize(tree->type, tree->rnode); in_expr--; return; } /* eval_condition --- is TREE true or false */ static void eval_condition(register NODE *tree) { if (tree == NULL) /* Null trees are the easiest kinds */ return; if (tree->type == Node_line_range) { /* /.../, /.../ */ eval_condition(tree->condpair->lnode); fprintf(prof_fp,", "); eval_condition(tree->condpair->rnode); return; } /* * Could just be J.random expression. in which case, null and 0 are * false, anything else is true */ tree_eval(tree); return; } /* pp_op_assign --- do +=, -=, etc. */ static void pp_op_assign(register NODE *tree) { const char *op = NULL; enum Order { NA = 0, PRE = 1, POST = 2 } order = NA; switch(tree->type) { case Node_preincrement: op = "++"; order = PRE; break; case Node_predecrement: op = "--"; order = PRE; break; case Node_postincrement: op = "++"; order = POST; break; case Node_postdecrement: op = "--"; order = POST; break; default: break; /* handled below */ } if (order == PRE) { fprintf(prof_fp, "%s", op); pp_lhs(tree->lnode); return; } else if (order == POST) { pp_lhs(tree->lnode); fprintf(prof_fp, "%s", op); return; } /* a binary op */ pp_lhs(tree->lnode); switch(tree->type) { case Node_assign_exp: fprintf(prof_fp, " ^= "); break; case Node_assign_times: fprintf(prof_fp, " *= "); break; case Node_assign_quotient: fprintf(prof_fp, " /= "); break; case Node_assign_mod: fprintf(prof_fp, " %%= "); break; case Node_assign_plus: fprintf(prof_fp, " += "); break; case Node_assign_minus: fprintf(prof_fp, " -= "); break; default: cant_happen(); } tree_eval(tree->rnode); } /* pp_lhs --- print the lhs */ static void pp_lhs(register NODE *ptr) { register NODE *n; switch (ptr->type) { case Node_var_array: fatal(_("attempt to use array `%s' in a scalar context"), ptr->vname); case Node_var_new: case Node_var: fprintf(prof_fp, "%s", ptr->vname); break; case Node_FIELDWIDTHS: fprintf(prof_fp, "FIELDWIDTHS"); break; case Node_RS: fprintf(prof_fp, "RS"); break; case Node_FS: fprintf(prof_fp, "FS"); break; case Node_FNR: fprintf(prof_fp, "FNR"); break; case Node_NR: fprintf(prof_fp, "NR"); break; case Node_NF: fprintf(prof_fp, "NF"); break; case Node_IGNORECASE: fprintf(prof_fp, "IGNORECASE"); break; case Node_BINMODE: fprintf(prof_fp, "BINMODE"); break; case Node_LINT: fprintf(prof_fp, "LINT"); break; case Node_OFMT: fprintf(prof_fp, "OFMT"); break; case Node_CONVFMT: fprintf(prof_fp, "CONVFMT"); break; case Node_ORS: fprintf(prof_fp, "ORS"); break; case Node_OFS: fprintf(prof_fp, "OFS"); break; case Node_TEXTDOMAIN: fprintf(prof_fp, "TEXTDOMAIN"); break; case Node_param_list: fprintf(prof_fp, "%s", fparms[ptr->param_cnt]); break; case Node_field_spec: fprintf(prof_fp, "$"); if (is_scalar(ptr->lnode->type)) tree_eval(ptr->lnode); else { fprintf(prof_fp, "("); tree_eval(ptr->lnode); fprintf(prof_fp, ")"); } break; case Node_subscript: n = ptr->lnode; if (n->type == Node_param_list) { fprintf(prof_fp, "%s[", fparms[n->param_cnt]); } else fprintf(prof_fp, "%s[", n->vname); if (ptr->rnode->type == Node_expression_list) pp_list(ptr->rnode); else tree_eval(ptr->rnode); fprintf(prof_fp, "]"); break; case Node_builtin: fatal(_("assignment is not allowed to result of builtin function")); default: cant_happen(); } } /* match_op --- do ~ and !~ */ static void pp_match_op(register NODE *tree) { register NODE *re; const char *op; const char *restr; size_t relen; NODE *text = NULL; if (tree->type == Node_dynregex) { tree_eval(tree->re_exp); return; } if (tree->type == Node_regex) { re = tree->re_exp; restr = re->stptr; relen = re->stlen; pp_string(restr, relen, '/'); return; } /* at this point, have either ~ or !~ */ text = tree->lnode; re = tree->rnode; if (tree->type == Node_nomatch) op = "!~"; else if (tree->type == Node_match) op = "~"; else op = ""; tree_eval(text); fprintf(prof_fp, " %s ", op); tree_eval(re); } /* pp_redir --- print a redirection */ static void pp_redir(register NODE *tree, enum redir_placement dir) { const char *op = "[BOGUS]"; /* should never be seen */ if (tree == NULL) return; switch (tree->type) { case Node_redirect_output: op = ">"; break; case Node_redirect_append: op = ">>"; break; case Node_redirect_pipe: op = "|"; break; case Node_redirect_pipein: op = "|"; break; case Node_redirect_input: op = "<"; break; case Node_redirect_twoway: op = "|&"; break; default: cant_happen(); } if (dir == BEFORE) { if (! is_scalar(tree->subnode->type)) { fprintf(prof_fp, "("); tree_eval(tree->subnode); fprintf(prof_fp, ")"); } else tree_eval(tree->subnode); fprintf(prof_fp, " %s ", op); } else { fprintf(prof_fp, " %s ", op); if (! is_scalar(tree->subnode->type)) { fprintf(prof_fp, "("); tree_eval(tree->subnode); fprintf(prof_fp, ")"); } else tree_eval(tree->subnode); } } /* pp_list --- dump a list of arguments, without parens */ static void pp_list(register NODE *tree) { for (; tree != NULL; tree = tree->rnode) { if (tree->type != Node_expression_list) { fprintf(stderr, "pp_list: got %s\n", nodetype2str(tree->type)); fflush(stderr); } assert(tree->type == Node_expression_list); tree_eval(tree->lnode); if (tree->rnode != NULL) fprintf(prof_fp, ", "); } } /* pp_print_stmt --- print a "print" or "printf" statement */ static void pp_print_stmt(const char *command, register NODE *tree) { NODE *redir = tree->rnode; indent(tree->exec_count); fprintf(prof_fp, "%s", command); if (redir != NULL) { if (tree->lnode != NULL) { /* parenthesize if have a redirection and a list */ fprintf(prof_fp, "("); pp_list(tree->lnode); fprintf(prof_fp, ")"); } else fprintf(prof_fp, " $0"); pp_redir(redir, AFTER); } else { fprintf(prof_fp, " "); if (tree->lnode != NULL) pp_list(tree->lnode); else fprintf(prof_fp, "$0"); } fprintf(prof_fp, "\n"); } /* pp_delete --- print a "delete" statement */ static void pp_delete(register NODE *tree) { NODE *array, *subscript; array = tree->lnode; subscript = tree->rnode; indent(array->exec_count); if (array->type == Node_param_list) fprintf(prof_fp, "delete %s", fparms[array->param_cnt]); else fprintf(prof_fp, "delete %s", array->vname); if (subscript != NULL) { fprintf(prof_fp, "["); pp_list(subscript); fprintf(prof_fp, "]"); } fprintf(prof_fp, "\n"); } /* pp_in_array --- pretty print "foo in array" test */ static void pp_in_array(NODE *array, NODE *subscript) { if (subscript->type == Node_expression_list) { fprintf(prof_fp, "("); pp_list(subscript); fprintf(prof_fp, ")"); } else pprint(subscript); if (array->type == Node_param_list) fprintf(prof_fp, " in %s", fparms[array->param_cnt]); else fprintf(prof_fp, " in %s", array->vname); } /* pp_getline --- print a getline statement */ static void pp_getline(register NODE *tree) { NODE *redir = tree->rnode; int before, after; /* * command | getline * or * command |& getline * or * getline < file */ if (redir != NULL) { before = (redir->type == Node_redirect_pipein || redir->type == Node_redirect_twoway); after = ! before; } else before = after = FALSE; if (before) pp_redir(redir, BEFORE); fprintf(prof_fp, "getline"); if (tree->lnode != NULL) { /* optional var */ fprintf(prof_fp, " "); pp_lhs(tree->lnode); } if (after) pp_redir(redir, AFTER); } /* pp_builtin --- print a builtin function */ static void pp_builtin(register NODE *tree) { const char *func = getfname(tree->builtin); fprintf(prof_fp, "%s(", func ? func : "extension_function"); if (func) pp_list(tree->subnode); fprintf(prof_fp, ")"); } /* pp_func_call --- print a function call */ static void pp_func_call(NODE *tree) { NODE *name, *arglist; name = tree->rnode; arglist = tree->lnode; fprintf(prof_fp, "%s(", name->stptr); pp_list(arglist); fprintf(prof_fp, ")"); } /* dump_prog --- dump the program */ /* * XXX: I am not sure it is right to have the strings in the dump * be translated, but I'll leave it alone for now. */ void dump_prog(NODE *begin, NODE *prog, NODE *end) { time_t now; (void) time(& now); /* \n on purpose, with \n in ctime() output */ fprintf(prof_fp, _("\t# gawk profile, created %s\n"), ctime(& now)); if (begin != NULL) { fprintf(prof_fp, _("\t# BEGIN block(s)\n\n")); fprintf(prof_fp, "\tBEGIN {\n"); in_BEGIN_or_END = TRUE; pprint(begin); in_BEGIN_or_END = FALSE; fprintf(prof_fp, "\t}\n"); if (prog != NULL || end != NULL) fprintf(prof_fp, "\n"); } if (prog != NULL) { fprintf(prof_fp, _("\t# Rule(s)\n\n")); pprint(prog); if (end != NULL) fprintf(prof_fp, "\n"); } if (end != NULL) { fprintf(prof_fp, _("\t# END block(s)\n\n")); fprintf(prof_fp, "\tEND {\n"); in_BEGIN_or_END = TRUE; pprint(end); in_BEGIN_or_END = FALSE; fprintf(prof_fp, "\t}\n"); } } /* pp_func --- pretty print a function */ void pp_func(const char *name, size_t namelen, NODE *f) { int j; char **pnames; static int first = TRUE; if (first) { first = FALSE; fprintf(prof_fp, _("\n\t# Functions, listed alphabetically\n")); } fprintf(prof_fp, "\n"); indent(f->exec_count); fprintf(prof_fp, "function %.*s(", (int) namelen, name); pnames = f->parmlist; fparms = pnames; for (j = 0; j < f->lnode->param_cnt; j++) { fprintf(prof_fp, "%s", pnames[j]); if (j < f->lnode->param_cnt - 1) fprintf(prof_fp, ", "); } fprintf(prof_fp, ")\n\t{\n"); indent_in(); pprint(f->rnode); /* body */ indent_out(); fprintf(prof_fp, "\t}\n"); } /* pp_string --- pretty print a string or regex constant */ static void pp_string(const char *str, size_t len, int delim) { pp_string_fp(prof_fp, str, len, delim, FALSE); } /* pp_string_fp --- printy print a string to the fp */ /* * This routine concentrates string pretty printing in one place, * so that it can be called from multiple places within gawk. */ void pp_string_fp(FILE *fp, const char *in_str, size_t len, int delim, int breaklines) { static char escapes[] = "\b\f\n\r\t\v\\"; static char printables[] = "bfnrtv\\"; char *cp; int i; int count; #define BREAKPOINT 70 /* arbitrary */ const unsigned char *str = (const unsigned char *) in_str; fprintf(fp, "%c", delim); for (count = 0; len > 0; len--, str++) { if (++count >= BREAKPOINT && breaklines) { fprintf(fp, "%c\n%c", delim, delim); count = 0; } if (*str == delim) { fprintf(fp, "\\%c", delim); count++; } else if (*str == BELL) { fprintf(fp, "\\a"); count++; } else if ((cp = strchr(escapes, *str)) != NULL) { i = cp - escapes; putc('\\', fp); count++; putc(printables[i], fp); if (breaklines && *str == '\n' && delim == '"') { fprintf(fp, "\"\n\""); count = 0; } /* NB: Deliberate use of lower-case versions. */ } else if (isascii(*str) && isprint(*str)) { putc(*str, fp); } else { char buf[10]; /* print 'em as they came if for whiny users */ if (whiny_users) sprintf(buf, "%c", *str & 0xff); else sprintf(buf, "\\%03o", *str & 0xff); count += strlen(buf) - 1; fprintf(fp, "%s", buf); } } fprintf(fp, "%c", delim); } /* is_scalar --- true or false if we'll get a scalar value */ static int is_scalar(NODETYPE type) { switch (type) { case Node_var_new: case Node_var: case Node_var_array: case Node_val: case Node_BINMODE: case Node_CONVFMT: case Node_FIELDWIDTHS: case Node_FNR: case Node_FS: case Node_IGNORECASE: case Node_LINT: case Node_NF: case Node_NR: case Node_OFMT: case Node_OFS: case Node_ORS: case Node_RS: case Node_TEXTDOMAIN: case Node_subscript: return TRUE; default: return FALSE; } } /* prec_level --- return the precedence of an operator, for paren tests */ static int prec_level(NODETYPE type) { switch (type) { case Node_var_new: case Node_var: case Node_var_array: case Node_param_list: case Node_subscript: case Node_func_call: case Node_K_delete_loop: case Node_val: case Node_builtin: case Node_BINMODE: case Node_CONVFMT: case Node_FIELDWIDTHS: case Node_FNR: case Node_FS: case Node_IGNORECASE: case Node_LINT: case Node_NF: case Node_NR: case Node_OFMT: case Node_OFS: case Node_ORS: case Node_RS: case Node_TEXTDOMAIN: return 15; case Node_field_spec: return 14; case Node_exp: return 13; case Node_preincrement: case Node_predecrement: case Node_postincrement: case Node_postdecrement: return 12; case Node_unary_minus: case Node_not: return 11; case Node_times: case Node_quotient: case Node_mod: return 10; case Node_plus: case Node_minus: return 9; case Node_concat: return 8; case Node_equal: case Node_notequal: case Node_greater: case Node_leq: case Node_geq: case Node_match: case Node_nomatch: return 7; case Node_K_getline: return 6; case Node_less: return 5; case Node_in_array: return 5; case Node_and: return 4; case Node_or: return 3; case Node_cond_exp: return 2; case Node_assign: case Node_assign_times: case Node_assign_quotient: case Node_assign_mod: case Node_assign_plus: case Node_assign_minus: case Node_assign_exp: return 1; default: fatal(_("unexpected type %s in prec_level"), nodetype2str(type)); return 0; /* keep the compiler happy */ } } /* parenthesize --- print a subtree in parentheses if need be */ static void parenthesize(NODETYPE parent_type, NODE *tree) { NODETYPE child_type; if (tree == NULL) return; child_type = tree->type; in_expr++; /* first the special cases, then the general ones */ if (parent_type == Node_not && child_type == Node_in_array) { fprintf(prof_fp, "! ("); pp_in_array(tree->lnode, tree->rnode); fprintf(prof_fp, ")"); /* other special cases here, as needed */ } else if (prec_level(child_type) < prec_level(parent_type)) { fprintf(prof_fp, "("); tree_eval(tree); fprintf(prof_fp, ")"); } else tree_eval(tree); in_expr--; } #ifdef PROFILING /* just_dump --- dump the profile and function stack and keep going */ static RETSIGTYPE just_dump(int signum) { extern NODE *begin_block, *expression_value, *end_block; dump_prog(begin_block, expression_value, end_block); dump_funcs(); dump_fcall_stack(prof_fp); fflush(prof_fp); signal(signum, just_dump); /* for OLD Unix systems ... */ } /* dump_and_exit --- dump the profile, the function stack, and exit */ static RETSIGTYPE dump_and_exit(int signum) { just_dump(signum); exit(1); } #endif