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Ruby 1.9.2p290(2011-07-09revision32553)
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00001 /********************************************************************** 00002 00003 eval.c - 00004 00005 $Author: yugui $ 00006 created at: Thu Jun 10 14:22:17 JST 1993 00007 00008 Copyright (C) 1993-2007 Yukihiro Matsumoto 00009 Copyright (C) 2000 Network Applied Communication Laboratory, Inc. 00010 Copyright (C) 2000 Information-technology Promotion Agency, Japan 00011 00012 **********************************************************************/ 00013 00014 #include "eval_intern.h" 00015 #include "iseq.h" 00016 #include "gc.h" 00017 #include "ruby/vm.h" 00018 #include "ruby/encoding.h" 00019 00020 #define numberof(array) (int)(sizeof(array) / sizeof((array)[0])) 00021 00022 VALUE proc_invoke(VALUE, VALUE, VALUE, VALUE); 00023 VALUE rb_binding_new(void); 00024 NORETURN(void rb_raise_jump(VALUE)); 00025 00026 ID rb_frame_callee(void); 00027 VALUE rb_eLocalJumpError; 00028 VALUE rb_eSysStackError; 00029 00030 #define exception_error GET_VM()->special_exceptions[ruby_error_reenter] 00031 00032 #include "eval_error.c" 00033 #include "eval_jump.c" 00034 00035 /* initialize ruby */ 00036 00037 void rb_clear_trace_func(void); 00038 void rb_thread_stop_timer_thread(void); 00039 00040 void rb_call_inits(void); 00041 void Init_heap(void); 00042 void Init_BareVM(void); 00043 00044 void 00045 ruby_init(void) 00046 { 00047 static int initialized = 0; 00048 int state; 00049 00050 if (initialized) 00051 return; 00052 initialized = 1; 00053 00054 ruby_init_stack((void *)&state); 00055 Init_BareVM(); 00056 Init_heap(); 00057 00058 PUSH_TAG(); 00059 if ((state = EXEC_TAG()) == 0) { 00060 rb_call_inits(); 00061 ruby_prog_init(); 00062 } 00063 POP_TAG(); 00064 00065 if (state) { 00066 error_print(); 00067 exit(EXIT_FAILURE); 00068 } 00069 GET_VM()->running = 1; 00070 } 00071 00072 extern void rb_clear_trace_func(void); 00073 00074 void * 00075 ruby_options(int argc, char **argv) 00076 { 00077 int state; 00078 void *volatile iseq = 0; 00079 00080 ruby_init_stack((void *)&iseq); 00081 PUSH_TAG(); 00082 if ((state = EXEC_TAG()) == 0) { 00083 SAVE_ROOT_JMPBUF(GET_THREAD(), iseq = ruby_process_options(argc, argv)); 00084 } 00085 else { 00086 rb_clear_trace_func(); 00087 state = error_handle(state); 00088 iseq = (void *)INT2FIX(state); 00089 } 00090 POP_TAG(); 00091 return iseq; 00092 } 00093 00094 static void 00095 ruby_finalize_0(void) 00096 { 00097 PUSH_TAG(); 00098 if (EXEC_TAG() == 0) { 00099 rb_trap_exit(); 00100 } 00101 POP_TAG(); 00102 rb_exec_end_proc(); 00103 rb_clear_trace_func(); 00104 } 00105 00106 static void 00107 ruby_finalize_1(void) 00108 { 00109 ruby_sig_finalize(); 00110 GET_THREAD()->errinfo = Qnil; 00111 rb_gc_call_finalizer_at_exit(); 00112 } 00113 00114 void 00115 ruby_finalize(void) 00116 { 00117 ruby_finalize_0(); 00118 ruby_finalize_1(); 00119 } 00120 00121 void rb_thread_stop_timer_thread(void); 00122 00123 int 00124 ruby_cleanup(volatile int ex) 00125 { 00126 int state; 00127 volatile VALUE errs[2]; 00128 rb_thread_t *th = GET_THREAD(); 00129 int nerr; 00130 void rb_threadptr_interrupt(rb_thread_t *th); 00131 void rb_threadptr_check_signal(rb_thread_t *mth); 00132 00133 rb_threadptr_interrupt(th); 00134 rb_threadptr_check_signal(th); 00135 PUSH_TAG(); 00136 if ((state = EXEC_TAG()) == 0) { 00137 SAVE_ROOT_JMPBUF(th, { RUBY_VM_CHECK_INTS(); }); 00138 } 00139 POP_TAG(); 00140 00141 errs[1] = th->errinfo; 00142 th->safe_level = 0; 00143 ruby_init_stack(&errs[STACK_UPPER(errs, 0, 1)]); 00144 00145 PUSH_TAG(); 00146 if ((state = EXEC_TAG()) == 0) { 00147 SAVE_ROOT_JMPBUF(th, ruby_finalize_0()); 00148 } 00149 POP_TAG(); 00150 00151 errs[0] = th->errinfo; 00152 PUSH_TAG(); 00153 if ((state = EXEC_TAG()) == 0) { 00154 SAVE_ROOT_JMPBUF(th, rb_thread_terminate_all()); 00155 } 00156 else if (ex == 0) { 00157 ex = state; 00158 } 00159 th->errinfo = errs[1]; 00160 ex = error_handle(ex); 00161 ruby_finalize_1(); 00162 POP_TAG(); 00163 rb_thread_stop_timer_thread(); 00164 00165 state = 0; 00166 for (nerr = 0; nerr < numberof(errs); ++nerr) { 00167 VALUE err = errs[nerr]; 00168 00169 if (!RTEST(err)) continue; 00170 00171 /* th->errinfo contains a NODE while break'ing */ 00172 if (TYPE(err) == T_NODE) continue; 00173 00174 if (rb_obj_is_kind_of(err, rb_eSystemExit)) { 00175 return sysexit_status(err); 00176 } 00177 else if (rb_obj_is_kind_of(err, rb_eSignal)) { 00178 VALUE sig = rb_iv_get(err, "signo"); 00179 state = NUM2INT(sig); 00180 break; 00181 } 00182 else if (ex == 0) { 00183 ex = 1; 00184 } 00185 } 00186 ruby_vm_destruct(GET_VM()); 00187 if (state) ruby_default_signal(state); 00188 00189 #if EXIT_SUCCESS != 0 || EXIT_FAILURE != 1 00190 switch (ex) { 00191 #if EXIT_SUCCESS != 0 00192 case 0: return EXIT_SUCCESS; 00193 #endif 00194 #if EXIT_FAILURE != 1 00195 case 1: return EXIT_FAILURE; 00196 #endif 00197 } 00198 #endif 00199 00200 return ex; 00201 } 00202 00203 static int 00204 ruby_exec_internal(void *n) 00205 { 00206 volatile int state; 00207 VALUE iseq = (VALUE)n; 00208 rb_thread_t *th = GET_THREAD(); 00209 00210 if (!n) return 0; 00211 00212 PUSH_TAG(); 00213 if ((state = EXEC_TAG()) == 0) { 00214 SAVE_ROOT_JMPBUF(th, { 00215 th->base_block = 0; 00216 rb_iseq_eval_main(iseq); 00217 }); 00218 } 00219 POP_TAG(); 00220 return state; 00221 } 00222 00223 void 00224 ruby_stop(int ex) 00225 { 00226 exit(ruby_cleanup(ex)); 00227 } 00228 00229 int 00230 ruby_executable_node(void *n, int *status) 00231 { 00232 VALUE v = (VALUE)n; 00233 int s; 00234 00235 switch (v) { 00236 case Qtrue: s = EXIT_SUCCESS; break; 00237 case Qfalse: s = EXIT_FAILURE; break; 00238 default: 00239 if (!FIXNUM_P(v)) return TRUE; 00240 s = FIX2INT(v); 00241 } 00242 if (status) *status = s; 00243 return FALSE; 00244 } 00245 00246 int 00247 ruby_run_node(void *n) 00248 { 00249 int status; 00250 if (!ruby_executable_node(n, &status)) { 00251 ruby_cleanup(0); 00252 return status; 00253 } 00254 return ruby_cleanup(ruby_exec_node(n)); 00255 } 00256 00257 int 00258 ruby_exec_node(void *n) 00259 { 00260 ruby_init_stack((void *)&n); 00261 return ruby_exec_internal(n); 00262 } 00263 00264 /* 00265 * call-seq: 00266 * Module.nesting -> array 00267 * 00268 * Returns the list of +Modules+ nested at the point of call. 00269 * 00270 * module M1 00271 * module M2 00272 * $a = Module.nesting 00273 * end 00274 * end 00275 * $a #=> [M1::M2, M1] 00276 * $a[0].name #=> "M1::M2" 00277 */ 00278 00279 static VALUE 00280 rb_mod_nesting(void) 00281 { 00282 VALUE ary = rb_ary_new(); 00283 const NODE *cref = rb_vm_cref(); 00284 00285 while (cref && cref->nd_next) { 00286 VALUE klass = cref->nd_clss; 00287 if (!(cref->flags & NODE_FL_CREF_PUSHED_BY_EVAL) && 00288 !NIL_P(klass)) { 00289 rb_ary_push(ary, klass); 00290 } 00291 cref = cref->nd_next; 00292 } 00293 return ary; 00294 } 00295 00296 /* 00297 * call-seq: 00298 * Module.constants -> array 00299 * 00300 * Returns an array of the names of all constants defined in the 00301 * system. This list includes the names of all modules and classes. 00302 * 00303 * p Module.constants.sort[1..5] 00304 * 00305 * <em>produces:</em> 00306 * 00307 * ["ARGV", "ArgumentError", "Array", "Bignum", "Binding"] 00308 */ 00309 00310 static VALUE 00311 rb_mod_s_constants(int argc, VALUE *argv, VALUE mod) 00312 { 00313 const NODE *cref = rb_vm_cref(); 00314 VALUE klass; 00315 VALUE cbase = 0; 00316 void *data = 0; 00317 00318 if (argc > 0) { 00319 return rb_mod_constants(argc, argv, rb_cModule); 00320 } 00321 00322 while (cref) { 00323 klass = cref->nd_clss; 00324 if (!NIL_P(klass)) { 00325 data = rb_mod_const_at(cref->nd_clss, data); 00326 if (!cbase) { 00327 cbase = klass; 00328 } 00329 } 00330 cref = cref->nd_next; 00331 } 00332 00333 if (cbase) { 00334 data = rb_mod_const_of(cbase, data); 00335 } 00336 return rb_const_list(data); 00337 } 00338 00339 void 00340 rb_frozen_class_p(VALUE klass) 00341 { 00342 const char *desc = "something(?!)"; 00343 00344 if (OBJ_FROZEN(klass)) { 00345 if (FL_TEST(klass, FL_SINGLETON)) 00346 desc = "object"; 00347 else { 00348 switch (TYPE(klass)) { 00349 case T_MODULE: 00350 case T_ICLASS: 00351 desc = "module"; 00352 break; 00353 case T_CLASS: 00354 desc = "class"; 00355 break; 00356 } 00357 } 00358 rb_error_frozen(desc); 00359 } 00360 } 00361 00362 NORETURN(static void rb_longjmp(int, volatile VALUE)); 00363 00364 static void 00365 setup_exception(rb_thread_t *th, int tag, volatile VALUE mesg) 00366 { 00367 VALUE at; 00368 VALUE e; 00369 const char *file; 00370 volatile int line = 0; 00371 00372 if (NIL_P(mesg)) 00373 mesg = th->errinfo; 00374 if (NIL_P(mesg)) { 00375 mesg = rb_exc_new(rb_eRuntimeError, 0, 0); 00376 } 00377 00378 file = rb_sourcefile(); 00379 if (file) line = rb_sourceline(); 00380 if (file && !NIL_P(mesg)) { 00381 if (mesg == sysstack_error) { 00382 at = rb_enc_sprintf(rb_usascii_encoding(), "%s:%d", file, line); 00383 at = rb_ary_new3(1, at); 00384 rb_iv_set(mesg, "bt", at); 00385 } 00386 else { 00387 at = get_backtrace(mesg); 00388 if (NIL_P(at)) { 00389 at = rb_make_backtrace(); 00390 if (OBJ_FROZEN(mesg)) { 00391 mesg = rb_obj_dup(mesg); 00392 } 00393 set_backtrace(mesg, at); 00394 } 00395 } 00396 } 00397 if (!NIL_P(mesg)) { 00398 th->errinfo = mesg; 00399 } 00400 00401 if (RTEST(ruby_debug) && !NIL_P(e = th->errinfo) && 00402 !rb_obj_is_kind_of(e, rb_eSystemExit)) { 00403 int status; 00404 00405 PUSH_TAG(); 00406 if ((status = EXEC_TAG()) == 0) { 00407 RB_GC_GUARD(e) = rb_obj_as_string(e); 00408 if (file && line) { 00409 warn_printf("Exception `%s' at %s:%d - %s\n", 00410 rb_obj_classname(th->errinfo), 00411 file, line, RSTRING_PTR(e)); 00412 } 00413 else if (file) { 00414 warn_printf("Exception `%s' at %s - %s\n", 00415 rb_obj_classname(th->errinfo), 00416 file, RSTRING_PTR(e)); 00417 } 00418 else { 00419 warn_printf("Exception `%s' - %s\n", 00420 rb_obj_classname(th->errinfo), 00421 RSTRING_PTR(e)); 00422 } 00423 } 00424 POP_TAG(); 00425 if (status == TAG_FATAL && th->errinfo == exception_error) { 00426 th->errinfo = mesg; 00427 } 00428 else if (status) { 00429 rb_threadptr_reset_raised(th); 00430 JUMP_TAG(status); 00431 } 00432 } 00433 00434 if (rb_threadptr_set_raised(th)) { 00435 th->errinfo = exception_error; 00436 rb_threadptr_reset_raised(th); 00437 JUMP_TAG(TAG_FATAL); 00438 } 00439 00440 rb_trap_restore_mask(); 00441 00442 if (tag != TAG_FATAL) { 00443 EXEC_EVENT_HOOK(th, RUBY_EVENT_RAISE, th->cfp->self, 0, 0); 00444 } 00445 } 00446 00447 static void 00448 rb_longjmp(int tag, volatile VALUE mesg) 00449 { 00450 rb_thread_t *th = GET_THREAD(); 00451 setup_exception(th, tag, mesg); 00452 rb_thread_raised_clear(th); 00453 JUMP_TAG(tag); 00454 } 00455 00456 static VALUE make_exception(int argc, VALUE *argv, int isstr); 00457 00458 void 00459 rb_exc_raise(VALUE mesg) 00460 { 00461 if (!NIL_P(mesg)) { 00462 mesg = make_exception(1, &mesg, FALSE); 00463 } 00464 rb_longjmp(TAG_RAISE, mesg); 00465 } 00466 00467 void 00468 rb_exc_fatal(VALUE mesg) 00469 { 00470 if (!NIL_P(mesg)) { 00471 mesg = make_exception(1, &mesg, FALSE); 00472 } 00473 rb_longjmp(TAG_FATAL, mesg); 00474 } 00475 00476 void 00477 rb_interrupt(void) 00478 { 00479 rb_raise(rb_eInterrupt, "%s", ""); 00480 } 00481 00482 static VALUE get_errinfo(void); 00483 00484 /* 00485 * call-seq: 00486 * raise 00487 * raise(string) 00488 * raise(exception [, string [, array]]) 00489 * fail 00490 * fail(string) 00491 * fail(exception [, string [, array]]) 00492 * 00493 * With no arguments, raises the exception in <code>$!</code> or raises 00494 * a <code>RuntimeError</code> if <code>$!</code> is +nil+. 00495 * With a single +String+ argument, raises a 00496 * +RuntimeError+ with the string as a message. Otherwise, 00497 * the first parameter should be the name of an +Exception+ 00498 * class (or an object that returns an +Exception+ object when sent 00499 * an +exception+ message). The optional second parameter sets the 00500 * message associated with the exception, and the third parameter is an 00501 * array of callback information. Exceptions are caught by the 00502 * +rescue+ clause of <code>begin...end</code> blocks. 00503 * 00504 * raise "Failed to create socket" 00505 * raise ArgumentError, "No parameters", caller 00506 */ 00507 00508 static VALUE 00509 rb_f_raise(int argc, VALUE *argv) 00510 { 00511 VALUE err; 00512 if (argc == 0) { 00513 err = get_errinfo(); 00514 if (!NIL_P(err)) { 00515 argc = 1; 00516 argv = &err; 00517 } 00518 } 00519 rb_raise_jump(rb_make_exception(argc, argv)); 00520 return Qnil; /* not reached */ 00521 } 00522 00523 static VALUE 00524 make_exception(int argc, VALUE *argv, int isstr) 00525 { 00526 VALUE mesg; 00527 ID exception; 00528 int n; 00529 00530 mesg = Qnil; 00531 switch (argc) { 00532 case 0: 00533 break; 00534 case 1: 00535 if (NIL_P(argv[0])) 00536 break; 00537 if (isstr) { 00538 mesg = rb_check_string_type(argv[0]); 00539 if (!NIL_P(mesg)) { 00540 mesg = rb_exc_new3(rb_eRuntimeError, mesg); 00541 break; 00542 } 00543 } 00544 n = 0; 00545 goto exception_call; 00546 00547 case 2: 00548 case 3: 00549 n = 1; 00550 exception_call: 00551 if (argv[0] == sysstack_error) return argv[0]; 00552 CONST_ID(exception, "exception"); 00553 mesg = rb_check_funcall(argv[0], exception, n, argv+1); 00554 if (mesg == Qundef) { 00555 rb_raise(rb_eTypeError, "exception class/object expected"); 00556 } 00557 break; 00558 default: 00559 rb_raise(rb_eArgError, "wrong number of arguments (%d for 0..3)", argc); 00560 break; 00561 } 00562 if (argc > 0) { 00563 if (!rb_obj_is_kind_of(mesg, rb_eException)) 00564 rb_raise(rb_eTypeError, "exception object expected"); 00565 if (argc > 2) 00566 set_backtrace(mesg, argv[2]); 00567 } 00568 00569 return mesg; 00570 } 00571 00572 VALUE 00573 rb_make_exception(int argc, VALUE *argv) 00574 { 00575 return make_exception(argc, argv, TRUE); 00576 } 00577 00578 void 00579 rb_raise_jump(VALUE mesg) 00580 { 00581 rb_thread_t *th = GET_THREAD(); 00582 rb_control_frame_t *cfp = th->cfp; 00583 VALUE klass = cfp->me->klass; 00584 VALUE self = cfp->self; 00585 ID mid = cfp->me->called_id; 00586 00587 th->cfp = RUBY_VM_PREVIOUS_CONTROL_FRAME(th->cfp); 00588 00589 setup_exception(th, TAG_RAISE, mesg); 00590 00591 EXEC_EVENT_HOOK(th, RUBY_EVENT_C_RETURN, self, mid, klass); 00592 rb_thread_raised_clear(th); 00593 JUMP_TAG(TAG_RAISE); 00594 } 00595 00596 void 00597 rb_jump_tag(int tag) 00598 { 00599 JUMP_TAG(tag); 00600 } 00601 00602 int 00603 rb_block_given_p(void) 00604 { 00605 rb_thread_t *th = GET_THREAD(); 00606 00607 if ((th->cfp->lfp[0] & 0x02) == 0 && 00608 GC_GUARDED_PTR_REF(th->cfp->lfp[0])) { 00609 return TRUE; 00610 } 00611 else { 00612 return FALSE; 00613 } 00614 } 00615 00616 int 00617 rb_iterator_p(void) 00618 { 00619 return rb_block_given_p(); 00620 } 00621 00622 VALUE rb_eThreadError; 00623 00624 void 00625 rb_need_block(void) 00626 { 00627 if (!rb_block_given_p()) { 00628 rb_vm_localjump_error("no block given", Qnil, 0); 00629 } 00630 } 00631 00632 VALUE 00633 rb_rescue2(VALUE (* b_proc) (ANYARGS), VALUE data1, 00634 VALUE (* r_proc) (ANYARGS), VALUE data2, ...) 00635 { 00636 int state; 00637 rb_thread_t *th = GET_THREAD(); 00638 rb_control_frame_t *cfp = th->cfp; 00639 volatile VALUE result; 00640 volatile VALUE e_info = th->errinfo; 00641 va_list args; 00642 00643 PUSH_TAG(); 00644 if ((state = EXEC_TAG()) == 0) { 00645 retry_entry: 00646 result = (*b_proc) (data1); 00647 } 00648 else { 00649 th->cfp = cfp; /* restore */ 00650 00651 if (state == TAG_RAISE) { 00652 int handle = FALSE; 00653 VALUE eclass; 00654 00655 va_init_list(args, data2); 00656 while ((eclass = va_arg(args, VALUE)) != 0) { 00657 if (rb_obj_is_kind_of(th->errinfo, eclass)) { 00658 handle = TRUE; 00659 break; 00660 } 00661 } 00662 va_end(args); 00663 00664 if (handle) { 00665 if (r_proc) { 00666 PUSH_TAG(); 00667 if ((state = EXEC_TAG()) == 0) { 00668 result = (*r_proc) (data2, th->errinfo); 00669 } 00670 POP_TAG(); 00671 if (state == TAG_RETRY) { 00672 state = 0; 00673 th->errinfo = Qnil; 00674 goto retry_entry; 00675 } 00676 } 00677 else { 00678 result = Qnil; 00679 state = 0; 00680 } 00681 if (state == 0) { 00682 th->errinfo = e_info; 00683 } 00684 } 00685 } 00686 } 00687 POP_TAG(); 00688 if (state) 00689 JUMP_TAG(state); 00690 00691 return result; 00692 } 00693 00694 VALUE 00695 rb_rescue(VALUE (* b_proc)(ANYARGS), VALUE data1, 00696 VALUE (* r_proc)(ANYARGS), VALUE data2) 00697 { 00698 return rb_rescue2(b_proc, data1, r_proc, data2, rb_eStandardError, 00699 (VALUE)0); 00700 } 00701 00702 VALUE 00703 rb_protect(VALUE (* proc) (VALUE), VALUE data, int * state) 00704 { 00705 volatile VALUE result = Qnil; 00706 int status; 00707 rb_thread_t *th = GET_THREAD(); 00708 rb_control_frame_t *cfp = th->cfp; 00709 struct rb_vm_protect_tag protect_tag; 00710 rb_jmpbuf_t org_jmpbuf; 00711 00712 protect_tag.prev = th->protect_tag; 00713 00714 PUSH_TAG(); 00715 th->protect_tag = &protect_tag; 00716 MEMCPY(&org_jmpbuf, &(th)->root_jmpbuf, rb_jmpbuf_t, 1); 00717 if ((status = EXEC_TAG()) == 0) { 00718 SAVE_ROOT_JMPBUF(th, result = (*proc) (data)); 00719 } 00720 MEMCPY(&(th)->root_jmpbuf, &org_jmpbuf, rb_jmpbuf_t, 1); 00721 th->protect_tag = protect_tag.prev; 00722 POP_TAG(); 00723 00724 if (state) { 00725 *state = status; 00726 } 00727 if (status != 0) { 00728 th->cfp = cfp; 00729 return Qnil; 00730 } 00731 00732 return result; 00733 } 00734 00735 VALUE 00736 rb_ensure(VALUE (*b_proc)(ANYARGS), VALUE data1, VALUE (*e_proc)(ANYARGS), VALUE data2) 00737 { 00738 int state; 00739 volatile VALUE result = Qnil; 00740 00741 PUSH_TAG(); 00742 if ((state = EXEC_TAG()) == 0) { 00743 result = (*b_proc) (data1); 00744 } 00745 POP_TAG(); 00746 /* TODO: fix me */ 00747 /* retval = prot_tag ? prot_tag->retval : Qnil; */ /* save retval */ 00748 (*e_proc) (data2); 00749 if (state) 00750 JUMP_TAG(state); 00751 return result; 00752 } 00753 00754 static const rb_method_entry_t * 00755 method_entry_of_iseq(rb_control_frame_t *cfp, rb_iseq_t *iseq) 00756 { 00757 rb_thread_t *th = GET_THREAD(); 00758 rb_control_frame_t *cfp_limit; 00759 00760 cfp_limit = (rb_control_frame_t *)(th->stack + th->stack_size); 00761 while (cfp_limit > cfp) { 00762 if (cfp->iseq == iseq) 00763 return cfp->me; 00764 cfp = RUBY_VM_PREVIOUS_CONTROL_FRAME(cfp); 00765 } 00766 return 0; 00767 } 00768 00769 static ID 00770 frame_func_id(rb_control_frame_t *cfp) 00771 { 00772 const rb_method_entry_t *me_local; 00773 rb_iseq_t *iseq = cfp->iseq; 00774 if (cfp->me) { 00775 return cfp->me->def->original_id; 00776 } 00777 while (iseq) { 00778 if (RUBY_VM_IFUNC_P(iseq)) { 00779 return rb_intern("<ifunc>"); 00780 } 00781 me_local = method_entry_of_iseq(cfp, iseq); 00782 if (me_local) { 00783 cfp->me = me_local; 00784 return me_local->def->original_id; 00785 } 00786 if (iseq->defined_method_id) { 00787 return iseq->defined_method_id; 00788 } 00789 if (iseq->local_iseq == iseq) { 00790 break; 00791 } 00792 iseq = iseq->parent_iseq; 00793 } 00794 return 0; 00795 } 00796 00797 ID 00798 rb_frame_this_func(void) 00799 { 00800 return frame_func_id(GET_THREAD()->cfp); 00801 } 00802 00803 ID 00804 rb_frame_callee(void) 00805 { 00806 return frame_func_id(GET_THREAD()->cfp); 00807 } 00808 00809 static ID 00810 rb_frame_caller(void) 00811 { 00812 rb_thread_t *th = GET_THREAD(); 00813 rb_control_frame_t *prev_cfp = RUBY_VM_PREVIOUS_CONTROL_FRAME(th->cfp); 00814 /* check if prev_cfp can be accessible */ 00815 if ((void *)(th->stack + th->stack_size) == (void *)(prev_cfp)) { 00816 return 0; 00817 } 00818 return frame_func_id(prev_cfp); 00819 } 00820 00821 void 00822 rb_frame_pop(void) 00823 { 00824 rb_thread_t *th = GET_THREAD(); 00825 th->cfp = RUBY_VM_PREVIOUS_CONTROL_FRAME(th->cfp); 00826 } 00827 00828 /* 00829 * call-seq: 00830 * append_features(mod) -> mod 00831 * 00832 * When this module is included in another, Ruby calls 00833 * <code>append_features</code> in this module, passing it the 00834 * receiving module in _mod_. Ruby's default implementation is 00835 * to add the constants, methods, and module variables of this module 00836 * to _mod_ if this module has not already been added to 00837 * _mod_ or one of its ancestors. See also <code>Module#include</code>. 00838 */ 00839 00840 static VALUE 00841 rb_mod_append_features(VALUE module, VALUE include) 00842 { 00843 switch (TYPE(include)) { 00844 case T_CLASS: 00845 case T_MODULE: 00846 break; 00847 default: 00848 Check_Type(include, T_CLASS); 00849 break; 00850 } 00851 rb_include_module(include, module); 00852 00853 return module; 00854 } 00855 00856 /* 00857 * call-seq: 00858 * include(module, ...) -> self 00859 * 00860 * Invokes <code>Module.append_features</code> on each parameter in reverse order. 00861 */ 00862 00863 static VALUE 00864 rb_mod_include(int argc, VALUE *argv, VALUE module) 00865 { 00866 int i; 00867 00868 for (i = 0; i < argc; i++) 00869 Check_Type(argv[i], T_MODULE); 00870 while (argc--) { 00871 rb_funcall(argv[argc], rb_intern("append_features"), 1, module); 00872 rb_funcall(argv[argc], rb_intern("included"), 1, module); 00873 } 00874 return module; 00875 } 00876 00877 void 00878 rb_obj_call_init(VALUE obj, int argc, VALUE *argv) 00879 { 00880 PASS_PASSED_BLOCK(); 00881 rb_funcall2(obj, idInitialize, argc, argv); 00882 } 00883 00884 void 00885 rb_extend_object(VALUE obj, VALUE module) 00886 { 00887 rb_include_module(rb_singleton_class(obj), module); 00888 } 00889 00890 /* 00891 * call-seq: 00892 * extend_object(obj) -> obj 00893 * 00894 * Extends the specified object by adding this module's constants and 00895 * methods (which are added as singleton methods). This is the callback 00896 * method used by <code>Object#extend</code>. 00897 * 00898 * module Picky 00899 * def Picky.extend_object(o) 00900 * if String === o 00901 * puts "Can't add Picky to a String" 00902 * else 00903 * puts "Picky added to #{o.class}" 00904 * super 00905 * end 00906 * end 00907 * end 00908 * (s = Array.new).extend Picky # Call Object.extend 00909 * (s = "quick brown fox").extend Picky 00910 * 00911 * <em>produces:</em> 00912 * 00913 * Picky added to Array 00914 * Can't add Picky to a String 00915 */ 00916 00917 static VALUE 00918 rb_mod_extend_object(VALUE mod, VALUE obj) 00919 { 00920 rb_extend_object(obj, mod); 00921 return obj; 00922 } 00923 00924 /* 00925 * call-seq: 00926 * obj.extend(module, ...) -> obj 00927 * 00928 * Adds to _obj_ the instance methods from each module given as a 00929 * parameter. 00930 * 00931 * module Mod 00932 * def hello 00933 * "Hello from Mod.\n" 00934 * end 00935 * end 00936 * 00937 * class Klass 00938 * def hello 00939 * "Hello from Klass.\n" 00940 * end 00941 * end 00942 * 00943 * k = Klass.new 00944 * k.hello #=> "Hello from Klass.\n" 00945 * k.extend(Mod) #=> #<Klass:0x401b3bc8> 00946 * k.hello #=> "Hello from Mod.\n" 00947 */ 00948 00949 static VALUE 00950 rb_obj_extend(int argc, VALUE *argv, VALUE obj) 00951 { 00952 int i; 00953 00954 if (argc == 0) { 00955 rb_raise(rb_eArgError, "wrong number of arguments (at least 1)"); 00956 } 00957 for (i = 0; i < argc; i++) 00958 Check_Type(argv[i], T_MODULE); 00959 while (argc--) { 00960 rb_funcall(argv[argc], rb_intern("extend_object"), 1, obj); 00961 rb_funcall(argv[argc], rb_intern("extended"), 1, obj); 00962 } 00963 return obj; 00964 } 00965 00966 /* 00967 * call-seq: 00968 * include(module, ...) -> self 00969 * 00970 * Invokes <code>Module.append_features</code> 00971 * on each parameter in turn. Effectively adds the methods and constants 00972 * in each module to the receiver. 00973 */ 00974 00975 static VALUE 00976 top_include(int argc, VALUE *argv, VALUE self) 00977 { 00978 rb_thread_t *th = GET_THREAD(); 00979 00980 rb_secure(4); 00981 if (th->top_wrapper) { 00982 rb_warning 00983 ("main#include in the wrapped load is effective only in wrapper module"); 00984 return rb_mod_include(argc, argv, th->top_wrapper); 00985 } 00986 return rb_mod_include(argc, argv, rb_cObject); 00987 } 00988 00989 VALUE rb_f_trace_var(); 00990 VALUE rb_f_untrace_var(); 00991 00992 static VALUE * 00993 errinfo_place(rb_thread_t *th) 00994 { 00995 rb_control_frame_t *cfp = th->cfp; 00996 rb_control_frame_t *end_cfp = RUBY_VM_END_CONTROL_FRAME(th); 00997 00998 while (RUBY_VM_VALID_CONTROL_FRAME_P(cfp, end_cfp)) { 00999 if (RUBY_VM_NORMAL_ISEQ_P(cfp->iseq)) { 01000 if (cfp->iseq->type == ISEQ_TYPE_RESCUE) { 01001 return &cfp->dfp[-2]; 01002 } 01003 else if (cfp->iseq->type == ISEQ_TYPE_ENSURE && 01004 TYPE(cfp->dfp[-2]) != T_NODE && 01005 !FIXNUM_P(cfp->dfp[-2])) { 01006 return &cfp->dfp[-2]; 01007 } 01008 } 01009 cfp = RUBY_VM_PREVIOUS_CONTROL_FRAME(cfp); 01010 } 01011 return 0; 01012 } 01013 01014 static VALUE 01015 get_thread_errinfo(rb_thread_t *th) 01016 { 01017 VALUE *ptr = errinfo_place(th); 01018 if (ptr) { 01019 return *ptr; 01020 } 01021 else { 01022 return th->errinfo; 01023 } 01024 } 01025 01026 static VALUE 01027 get_errinfo(void) 01028 { 01029 return get_thread_errinfo(GET_THREAD()); 01030 } 01031 01032 static VALUE 01033 errinfo_getter(ID id) 01034 { 01035 return get_errinfo(); 01036 } 01037 01038 #if 0 01039 static void 01040 errinfo_setter(VALUE val, ID id, VALUE *var) 01041 { 01042 if (!NIL_P(val) && !rb_obj_is_kind_of(val, rb_eException)) { 01043 rb_raise(rb_eTypeError, "assigning non-exception to $!"); 01044 } 01045 else { 01046 VALUE *ptr = errinfo_place(GET_THREAD()); 01047 if (ptr) { 01048 *ptr = val; 01049 } 01050 else { 01051 rb_raise(rb_eRuntimeError, "errinfo_setter: not in rescue clause."); 01052 } 01053 } 01054 } 01055 #endif 01056 01057 VALUE 01058 rb_errinfo(void) 01059 { 01060 rb_thread_t *th = GET_THREAD(); 01061 return th->errinfo; 01062 } 01063 01064 void 01065 rb_set_errinfo(VALUE err) 01066 { 01067 if (!NIL_P(err) && !rb_obj_is_kind_of(err, rb_eException)) { 01068 rb_raise(rb_eTypeError, "assigning non-exception to $!"); 01069 } 01070 GET_THREAD()->errinfo = err; 01071 } 01072 01073 VALUE 01074 rb_rubylevel_errinfo(void) 01075 { 01076 return get_errinfo(); 01077 } 01078 01079 static VALUE 01080 errat_getter(ID id) 01081 { 01082 VALUE err = get_errinfo(); 01083 if (!NIL_P(err)) { 01084 return get_backtrace(err); 01085 } 01086 else { 01087 return Qnil; 01088 } 01089 } 01090 01091 static void 01092 errat_setter(VALUE val, ID id, VALUE *var) 01093 { 01094 VALUE err = get_errinfo(); 01095 if (NIL_P(err)) { 01096 rb_raise(rb_eArgError, "$! not set"); 01097 } 01098 set_backtrace(err, val); 01099 } 01100 01101 /* 01102 * call-seq: 01103 * __method__ -> symbol 01104 * __callee__ -> symbol 01105 * 01106 * Returns the name of the current method as a Symbol. 01107 * If called outside of a method, it returns <code>nil</code>. 01108 * 01109 */ 01110 01111 static VALUE 01112 rb_f_method_name(void) 01113 { 01114 ID fname = rb_frame_caller(); /* need *caller* ID */ 01115 01116 if (fname) { 01117 return ID2SYM(fname); 01118 } 01119 else { 01120 return Qnil; 01121 } 01122 } 01123 01124 void 01125 Init_eval(void) 01126 { 01127 rb_define_virtual_variable("$@", errat_getter, errat_setter); 01128 rb_define_virtual_variable("$!", errinfo_getter, 0); 01129 01130 rb_define_global_function("raise", rb_f_raise, -1); 01131 rb_define_global_function("fail", rb_f_raise, -1); 01132 01133 rb_define_global_function("global_variables", rb_f_global_variables, 0); /* in variable.c */ 01134 01135 rb_define_global_function("__method__", rb_f_method_name, 0); 01136 rb_define_global_function("__callee__", rb_f_method_name, 0); 01137 01138 rb_define_private_method(rb_cModule, "append_features", rb_mod_append_features, 1); 01139 rb_define_private_method(rb_cModule, "extend_object", rb_mod_extend_object, 1); 01140 rb_define_private_method(rb_cModule, "include", rb_mod_include, -1); 01141 01142 rb_undef_method(rb_cClass, "module_function"); 01143 01144 { 01145 extern void Init_vm_eval(void); 01146 extern void Init_eval_method(void); 01147 Init_vm_eval(); 01148 Init_eval_method(); 01149 } 01150 01151 rb_define_singleton_method(rb_cModule, "nesting", rb_mod_nesting, 0); 01152 rb_define_singleton_method(rb_cModule, "constants", rb_mod_s_constants, -1); 01153 01154 rb_define_singleton_method(rb_vm_top_self(), "include", top_include, -1); 01155 01156 rb_define_method(rb_mKernel, "extend", rb_obj_extend, -1); 01157 01158 rb_define_global_function("trace_var", rb_f_trace_var, -1); /* in variable.c */ 01159 rb_define_global_function("untrace_var", rb_f_untrace_var, -1); /* in variable.c */ 01160 01161 exception_error = rb_exc_new3(rb_eFatal, 01162 rb_obj_freeze(rb_str_new2("exception reentered"))); 01163 OBJ_TAINT(exception_error); 01164 OBJ_FREEZE(exception_error); 01165 } 01166
1.7.3