/********************************************************************** eval.c - $Author$ $Date$ created at: Thu Jun 10 14:22:17 JST 1993 Copyright (C) 1993-2003 Yukihiro Matsumoto Copyright (C) 2000 Network Applied Communication Laboratory, Inc. Copyright (C) 2000 Information-technology Promotion Agency, Japan **********************************************************************/ #include "ruby.h" #include "node.h" #include "env.h" #include "util.h" #include "rubysig.h" #include #include #include "st.h" #include "dln.h" #ifdef __APPLE__ #include #endif /* Make alloca work the best possible way. */ #ifdef __GNUC__ # ifndef atarist # ifndef alloca # define alloca __builtin_alloca # endif # endif /* atarist */ #else # ifdef HAVE_ALLOCA_H # include # else # ifdef _AIX #pragma alloca # else # ifndef alloca /* predefined by HP cc +Olibcalls */ void *alloca (); # endif # endif /* AIX */ # endif /* HAVE_ALLOCA_H */ #endif /* __GNUC__ */ #ifdef HAVE_STDARG_PROTOTYPES #include #define va_init_list(a,b) va_start(a,b) #else #include #define va_init_list(a,b) va_start(a) #endif #ifndef HAVE_STRING_H char *strrchr _((const char*,const char)); #endif #ifdef HAVE_UNISTD_H #include #endif #ifdef __BEOS__ #include #endif #ifdef __MACOS__ #include "macruby_private.h" #endif #ifndef setjmp #ifdef HAVE__SETJMP #define setjmp(env) _setjmp(env) #define longjmp(env,val) _longjmp(env,val) #endif #endif #include #include #include #if defined(__VMS) #pragma nostandard #endif #ifdef HAVE_SYS_SELECT_H #include #endif #include VALUE rb_cProc; static VALUE rb_cBinding; static VALUE proc_invoke _((VALUE,VALUE,VALUE,VALUE)); static VALUE rb_f_binding _((VALUE)); static void rb_f_END _((void)); static VALUE rb_f_block_given_p _((void)); static VALUE block_pass _((VALUE,NODE*)); static VALUE rb_cMethod; static VALUE method_call _((int, VALUE*, VALUE)); static VALUE rb_cUnboundMethod; static VALUE umethod_bind _((VALUE, VALUE)); static VALUE rb_mod_define_method _((int, VALUE*, VALUE)); static int scope_vmode; #define SCOPE_PUBLIC 0 #define SCOPE_PRIVATE 1 #define SCOPE_PROTECTED 2 #define SCOPE_MODFUNC 5 #define SCOPE_MASK 7 #define SCOPE_SET(f) (scope_vmode=(f)) #define SCOPE_TEST(f) (scope_vmode&(f)) NODE* ruby_current_node; int ruby_safe_level = 0; /* safe-level: 0 - strings from streams/environment/ARGV are tainted (default) 1 - no dangerous operation by tainted value 2 - process/file operations prohibited 3 - all genetated objects are tainted 4 - no global (non-tainted) variable modification/no direct output */ static VALUE safe_getter _((void)); static void safe_setter _((VALUE val)); void rb_secure(level) int level; { if (level <= ruby_safe_level) { if (ruby_frame->last_func) { rb_raise(rb_eSecurityError, "Insecure operation `%s' at level %d", rb_id2name(ruby_frame->last_func), ruby_safe_level); } else { rb_raise(rb_eSecurityError, "Insecure operation at level %d", ruby_safe_level); } } } void rb_secure_update(obj) VALUE obj; { if (!OBJ_TAINTED(obj)) rb_secure(4); } void rb_check_safe_obj(x) VALUE x; { if (ruby_safe_level > 0 && OBJ_TAINTED(x)){ if (ruby_frame->last_func) { rb_raise(rb_eSecurityError, "Insecure operation - %s", rb_id2name(ruby_frame->last_func)); } else { rb_raise(rb_eSecurityError, "Insecure operation: -r"); } } rb_secure(4); } void rb_check_safe_str(x) VALUE x; { rb_check_safe_obj(x); if (TYPE(x)!= T_STRING) { rb_raise(rb_eTypeError, "wrong argument type %s (expected String)", rb_obj_classname(x)); } } NORETURN(static void print_undef _((VALUE, ID))); static void print_undef(klass, id) VALUE klass; ID id; { rb_name_error(id, "undefined method `%s' for %s `%s'", rb_id2name(id), (TYPE(klass) == T_MODULE) ? "module" : "class", rb_class2name(klass)); } static ID removed, singleton_removed, undefined, singleton_undefined; #define CACHE_SIZE 0x800 #define CACHE_MASK 0x7ff #define EXPR1(c,m) ((((c)>>3)^(m))&CACHE_MASK) struct cache_entry { /* method hash table. */ ID mid; /* method's id */ ID mid0; /* method's original id */ VALUE klass; /* receiver's class */ VALUE origin; /* where method defined */ NODE *method; int noex; }; static struct cache_entry cache[CACHE_SIZE]; static int ruby_running = 0; void rb_clear_cache() { struct cache_entry *ent, *end; if (!ruby_running) return; ent = cache; end = ent + CACHE_SIZE; while (ent < end) { ent->mid = 0; ent++; } } static void rb_clear_cache_for_undef(klass, id) VALUE klass; ID id; { struct cache_entry *ent, *end; if (!ruby_running) return; ent = cache; end = ent + CACHE_SIZE; while (ent < end) { if (ent->origin == klass && ent->mid == id) { ent->mid = 0; } ent++; } } static void rb_clear_cache_by_id(id) ID id; { struct cache_entry *ent, *end; if (!ruby_running) return; ent = cache; end = ent + CACHE_SIZE; while (ent < end) { if (ent->mid == id) { ent->mid = 0; } ent++; } } void rb_clear_cache_by_class(klass) VALUE klass; { struct cache_entry *ent, *end; if (!ruby_running) return; ent = cache; end = ent + CACHE_SIZE; while (ent < end) { if (ent->klass == klass || ent->origin == klass) { ent->mid = 0; } ent++; } } static ID init, eqq, each, aref, aset, match, missing; static ID added, singleton_added; static ID __id__, __send__; void rb_add_method(klass, mid, node, noex) VALUE klass; ID mid; NODE *node; int noex; { NODE *body; if (NIL_P(klass)) klass = rb_cObject; if (ruby_safe_level >= 4 && (klass == rb_cObject || !OBJ_TAINTED(klass))) { rb_raise(rb_eSecurityError, "Insecure: can't define method"); } if (!FL_TEST(klass, FL_SINGLETON) && node && nd_type(node) != NODE_ZSUPER && (mid == rb_intern("initialize" )|| mid == rb_intern("initialize_copy"))) { noex = NOEX_PRIVATE | noex; } else if (FL_TEST(klass, FL_SINGLETON) && node && nd_type(node) == NODE_CFUNC && mid == rb_intern("allocate")) { rb_warn("defining %s.allocate is deprecated; use rb_define_alloc_func()", rb_class2name(rb_iv_get(klass, "__attached__"))); mid = ID_ALLOCATOR; } if (OBJ_FROZEN(klass)) rb_error_frozen("class/module"); rb_clear_cache_by_id(mid); body = NEW_METHOD(node, noex); st_insert(RCLASS(klass)->m_tbl, mid, (st_data_t)body); if (node && mid != ID_ALLOCATOR && ruby_running) { if (FL_TEST(klass, FL_SINGLETON)) { rb_funcall(rb_iv_get(klass, "__attached__"), singleton_added, 1, ID2SYM(mid)); } else { rb_funcall(klass, added, 1, ID2SYM(mid)); } } } void rb_define_alloc_func(klass, func) VALUE klass; VALUE (*func) _((VALUE)); { Check_Type(klass, T_CLASS); rb_add_method(CLASS_OF(klass), ID_ALLOCATOR, NEW_CFUNC(func, 0), NOEX_PRIVATE); } void rb_undef_alloc_func(klass) VALUE klass; { Check_Type(klass, T_CLASS); rb_add_method(CLASS_OF(klass), ID_ALLOCATOR, 0, NOEX_UNDEF); } static NODE* search_method(klass, id, origin) VALUE klass, *origin; ID id; { NODE *body; if (!klass) return 0; while (!st_lookup(RCLASS(klass)->m_tbl, id, (st_data_t *)&body)) { klass = RCLASS(klass)->super; if (!klass) return 0; } if (origin) *origin = klass; return body; } static NODE* rb_get_method_body(klassp, idp, noexp) VALUE *klassp; ID *idp; int *noexp; { ID id = *idp; VALUE klass = *klassp; VALUE origin; NODE * volatile body; struct cache_entry *ent; if ((body = search_method(klass, id, &origin)) == 0 || !body->nd_body) { /* store empty info in cache */ ent = cache + EXPR1(klass, id); ent->klass = klass; ent->origin = klass; ent->mid = ent->mid0 = id; ent->noex = 0; ent->method = 0; return 0; } if (ruby_running) { /* store in cache */ if (BUILTIN_TYPE(origin) == T_ICLASS) origin = RBASIC(origin)->klass; ent = cache + EXPR1(klass, id); ent->klass = klass; ent->noex = body->nd_noex; if (noexp) *noexp = body->nd_noex; body = body->nd_body; if (nd_type(body) == NODE_FBODY) { ent->mid = id; *klassp = body->nd_orig; ent->origin = body->nd_orig; *idp = ent->mid0 = body->nd_mid; body = ent->method = body->nd_head; } else { *klassp = origin; ent->origin = origin; ent->mid = ent->mid0 = id; ent->method = body; } } else { if (noexp) *noexp = body->nd_noex; body = body->nd_body; if (nd_type(body) == NODE_FBODY) { *klassp = body->nd_orig; *idp = body->nd_mid; body = body->nd_head; } else { *klassp = origin; } } return body; } static void remove_method(klass, mid) VALUE klass; ID mid; { NODE *body; if (klass == rb_cObject) { rb_secure(4); } if (ruby_safe_level >= 4 && !OBJ_TAINTED(klass)) { rb_raise(rb_eSecurityError, "Insecure: can't remove method"); } if (OBJ_FROZEN(klass)) rb_error_frozen("class/module"); if (mid == __id__ || mid == __send__ || mid == init) { rb_warn("removing `%s' may cause serious problem", rb_id2name(mid)); } if (!st_delete(RCLASS(klass)->m_tbl, &mid, (st_data_t *)&body) || !body->nd_body) { rb_name_error(mid, "method `%s' not defined in %s", rb_id2name(mid), rb_class2name(klass)); } rb_clear_cache_for_undef(klass, mid); if (FL_TEST(klass, FL_SINGLETON)) { rb_funcall(rb_iv_get(klass, "__attached__"), singleton_removed, 1, ID2SYM(mid)); } else { rb_funcall(klass, removed, 1, ID2SYM(mid)); } } void rb_remove_method(klass, name) VALUE klass; const char *name; { remove_method(klass, rb_intern(name)); } static VALUE rb_mod_remove_method(argc, argv, mod) int argc; VALUE *argv; VALUE mod; { int i; for (i=0; ind_body) { print_undef(klass, name); } if (body->nd_noex != noex) { if (klass == origin) { body->nd_noex = noex; } else { rb_add_method(klass, name, NEW_ZSUPER(), noex); } } } int rb_method_boundp(klass, id, ex) VALUE klass; ID id; int ex; { struct cache_entry *ent; int noex; /* is it in the method cache? */ ent = cache + EXPR1(klass, id); if (ent->mid == id && ent->klass == klass) { if (ex && (ent->noex & NOEX_PRIVATE)) return Qfalse; if (!ent->method) return Qfalse; return Qtrue; } if (rb_get_method_body(&klass, &id, &noex)) { if (ex && (noex & NOEX_PRIVATE)) return Qfalse; return Qtrue; } return Qfalse; } void rb_attr(klass, id, read, write, ex) VALUE klass; ID id; int read, write, ex; { const char *name; char *buf; ID attriv; int noex; if (!ex) noex = NOEX_PUBLIC; else { if (SCOPE_TEST(SCOPE_PRIVATE)) { noex = NOEX_PRIVATE; rb_warning((scope_vmode == SCOPE_MODFUNC) ? "attribute accessor as module_function" : "private attribute?"); } else if (SCOPE_TEST(SCOPE_PROTECTED)) { noex = NOEX_PROTECTED; } else { noex = NOEX_PUBLIC; } } name = rb_id2name(id); if (!name) { rb_raise(rb_eArgError, "argument needs to be symbol or string"); } buf = ALLOCA_N(char,strlen(name)+2); sprintf(buf, "@%s", name); attriv = rb_intern(buf); if (read) { rb_add_method(klass, id, NEW_IVAR(attriv), noex); } if (write) { sprintf(buf, "%s=", name); id = rb_intern(buf); rb_add_method(klass, id, NEW_ATTRSET(attriv), noex); } } extern int ruby_in_compile; VALUE ruby_errinfo = Qnil; extern NODE *ruby_eval_tree_begin; extern NODE *ruby_eval_tree; extern int ruby_nerrs; static VALUE rb_eLocalJumpError; static VALUE rb_eSysStackError; extern VALUE ruby_top_self; struct FRAME *ruby_frame; struct SCOPE *ruby_scope; static struct FRAME *top_frame; static struct SCOPE *top_scope; #define PUSH_FRAME() do { \ struct FRAME _frame; \ _frame.prev = ruby_frame; \ _frame.tmp = 0; \ _frame.node = ruby_current_node; \ _frame.iter = ruby_iter->iter; \ _frame.argc = 0; \ _frame.argv = 0; \ _frame.flags = FRAME_ALLOCA; \ ruby_frame = &_frame #define POP_FRAME() \ ruby_current_node = _frame.node; \ ruby_frame = _frame.prev; \ } while (0) struct BLOCK { NODE *var; NODE *body; VALUE self; struct FRAME frame; struct SCOPE *scope; VALUE klass; NODE *cref; int iter; int vmode; int flags; struct RVarmap *dyna_vars; VALUE orig_thread; VALUE wrapper; VALUE block_obj; struct BLOCK *outer; struct BLOCK *prev; }; #define BLOCK_D_SCOPE 1 #define BLOCK_LAMBDA 2 static struct BLOCK *ruby_block; #define PUSH_BLOCK(v,b) do { \ struct BLOCK _block; \ _block.var = v; \ _block.body = b; \ _block.self = self; \ _block.frame = *ruby_frame; \ _block.klass = ruby_class; \ _block.cref = ruby_cref; \ _block.frame.node = ruby_current_node;\ _block.scope = ruby_scope; \ _block.prev = ruby_block; \ _block.outer = ruby_block; \ _block.iter = ruby_iter->iter; \ _block.vmode = scope_vmode; \ _block.flags = BLOCK_D_SCOPE; \ _block.dyna_vars = ruby_dyna_vars; \ _block.wrapper = ruby_wrapper; \ _block.block_obj = 0; \ ruby_block = &_block #define POP_BLOCK() \ ruby_block = _block.prev; \ } while (0) struct RVarmap *ruby_dyna_vars; #define PUSH_VARS() do { \ struct RVarmap * volatile _old; \ _old = ruby_dyna_vars; \ ruby_dyna_vars = 0 #define POP_VARS() \ if (_old && (ruby_scope->flags & SCOPE_DONT_RECYCLE)) {\ if (RBASIC(_old)->flags) /* unless it's already recycled */ \ FL_SET(_old, DVAR_DONT_RECYCLE); \ }\ ruby_dyna_vars = _old; \ } while (0) #define DVAR_DONT_RECYCLE FL_USER2 static struct RVarmap* new_dvar(id, value, prev) ID id; VALUE value; struct RVarmap *prev; { NEWOBJ(vars, struct RVarmap); OBJSETUP(vars, 0, T_VARMAP); vars->id = id; vars->val = value; vars->next = prev; return vars; } VALUE rb_dvar_defined(id) ID id; { struct RVarmap *vars = ruby_dyna_vars; while (vars) { if (vars->id == id) return Qtrue; vars = vars->next; } return Qfalse; } VALUE rb_dvar_curr(id) ID id; { struct RVarmap *vars = ruby_dyna_vars; while (vars) { if (vars->id == 0) break; if (vars->id == id) return Qtrue; vars = vars->next; } return Qfalse; } VALUE rb_dvar_ref(id) ID id; { struct RVarmap *vars = ruby_dyna_vars; while (vars) { if (vars->id == id) { return vars->val; } vars = vars->next; } return Qnil; } void rb_dvar_push(id, value) ID id; VALUE value; { ruby_dyna_vars = new_dvar(id, value, ruby_dyna_vars); } static void dvar_asgn_internal(id, value, curr) ID id; VALUE value; int curr; { int n = 0; struct RVarmap *vars = ruby_dyna_vars; while (vars) { if (curr && vars->id == 0) { /* first null is a dvar header */ n++; if (n == 2) break; } if (vars->id == id) { vars->val = value; return; } vars = vars->next; } if (!ruby_dyna_vars) { ruby_dyna_vars = new_dvar(id, value, 0); } else { vars = new_dvar(id, value, ruby_dyna_vars->next); ruby_dyna_vars->next = vars; } } static inline void dvar_asgn(id, value) ID id; VALUE value; { dvar_asgn_internal(id, value, 0); } static inline void dvar_asgn_curr(id, value) ID id; VALUE value; { dvar_asgn_internal(id, value, 1); } VALUE * rb_svar(cnt) int cnt; { struct RVarmap *vars = ruby_dyna_vars; ID id; if (!ruby_scope->local_tbl) return NULL; if (cnt >= ruby_scope->local_tbl[0]) return NULL; id = ruby_scope->local_tbl[cnt+1]; while (vars) { if (vars->id == id) return &vars->val; vars = vars->next; } if (ruby_scope->local_vars == 0) return NULL; return &ruby_scope->local_vars[cnt]; } struct iter { int iter; struct iter *prev; }; static struct iter *ruby_iter; #define ITER_NOT 0 #define ITER_PRE 1 #define ITER_CUR 2 #define PUSH_ITER(i) do { \ struct iter _iter; \ _iter.prev = ruby_iter; \ _iter.iter = (i); \ ruby_iter = &_iter #define POP_ITER() \ ruby_iter = _iter.prev; \ } while (0) struct tag { jmp_buf buf; struct FRAME *frame; struct iter *iter; VALUE tag; VALUE retval; struct SCOPE *scope; VALUE dst; struct tag *prev; }; static struct tag *prot_tag; #define PUSH_TAG(ptag) do { \ struct tag _tag; \ _tag.retval = Qnil; \ _tag.frame = ruby_frame; \ _tag.iter = ruby_iter; \ _tag.prev = prot_tag; \ _tag.scope = ruby_scope; \ _tag.tag = ptag; \ _tag.dst = 0; \ prot_tag = &_tag #define PROT_NONE Qfalse /* 0 */ #define PROT_THREAD Qtrue /* 2 */ #define PROT_FUNC INT2FIX(0) /* 1 */ #define PROT_ITER INT2FIX(1) /* 3 */ #define PROT_CALL INT2FIX(2) /* 5 */ #define PROT_PCALL INT2FIX(3) /* 7 */ #define EXEC_TAG() (FLUSH_REGISTER_WINDOWS, setjmp(prot_tag->buf)) #define JUMP_TAG(st) do { \ ruby_frame = prot_tag->frame; \ ruby_iter = prot_tag->iter; \ longjmp(prot_tag->buf,(st)); \ } while (0) #define POP_TAG() \ prot_tag = _tag.prev; \ } while (0) #define TAG_DST() (_tag.dst == (VALUE)_tag.scope) #define TAG_RETURN 0x1 #define TAG_BREAK 0x2 #define TAG_NEXT 0x3 #define TAG_RETRY 0x4 #define TAG_REDO 0x5 #define TAG_RAISE 0x6 #define TAG_THROW 0x7 #define TAG_FATAL 0x8 #define TAG_MASK 0xf VALUE ruby_class; static VALUE ruby_wrapper; /* security wrapper */ #define PUSH_CLASS(c) do { \ VALUE _class = ruby_class; \ ruby_class = (c) #define POP_CLASS() ruby_class = _class; \ } while (0) static NODE *ruby_cref = 0; static NODE *top_cref; #define PUSH_CREF(c) ruby_cref = NEW_NODE(NODE_CREF,(c),0,ruby_cref) #define POP_CREF() ruby_cref = ruby_cref->nd_next #define PUSH_SCOPE() do { \ volatile int _vmode = scope_vmode; \ struct SCOPE * volatile _old; \ NEWOBJ(_scope, struct SCOPE); \ OBJSETUP(_scope, 0, T_SCOPE); \ _scope->local_tbl = 0; \ _scope->local_vars = 0; \ _scope->flags = 0; \ _old = ruby_scope; \ ruby_scope = _scope; \ scope_vmode = SCOPE_PUBLIC typedef struct thread * rb_thread_t; static rb_thread_t curr_thread = 0; static rb_thread_t main_thread; static void scope_dup _((struct SCOPE *)); #define POP_SCOPE() \ if (ruby_scope->flags & SCOPE_DONT_RECYCLE) {\ if (_old) scope_dup(_old); \ } \ if (!(ruby_scope->flags & SCOPE_MALLOC)) {\ ruby_scope->local_vars = 0; \ ruby_scope->local_tbl = 0; \ if (!(ruby_scope->flags & SCOPE_DONT_RECYCLE) && \ ruby_scope != top_scope) { \ rb_gc_force_recycle((VALUE)ruby_scope);\ } \ } \ ruby_scope->flags |= SCOPE_NOSTACK; \ ruby_scope = _old; \ scope_vmode = _vmode; \ } while (0) static VALUE rb_eval _((VALUE,NODE*)); static VALUE eval _((VALUE,VALUE,VALUE,char*,int)); static NODE *compile _((VALUE, char*, int)); static VALUE rb_yield_0 _((VALUE, VALUE, VALUE, int, int)); #define YIELD_PROC_CALL 1 #define YIELD_PUBLIC_DEF 2 #define YIELD_FUNC_AVALUE 1 #define YIELD_FUNC_SVALUE 2 static VALUE rb_call _((VALUE,VALUE,ID,int,const VALUE*,int)); static VALUE module_setup _((VALUE,NODE*)); static VALUE massign _((VALUE,NODE*,VALUE,int)); static void assign _((VALUE,NODE*,VALUE,int)); static VALUE trace_func = 0; static int tracing = 0; static void call_trace_func _((char*,NODE*,VALUE,ID,VALUE)); #if 0 #define SET_CURRENT_SOURCE() (ruby_sourcefile = ruby_current_node->nd_file, \ ruby_sourceline = nd_line(ruby_current_node)) #else #define SET_CURRENT_SOURCE() ((void)0) #endif void ruby_set_current_source() { if (ruby_current_node) { ruby_sourcefile = ruby_current_node->nd_file; ruby_sourceline = nd_line(ruby_current_node); } } static void #ifdef HAVE_STDARG_PROTOTYPES warn_printf(const char *fmt, ...) #else warn_printf(fmt, va_alist) const char *fmt; va_dcl #endif { char buf[BUFSIZ]; va_list args; va_init_list(args, fmt); vsnprintf(buf, BUFSIZ, fmt, args); va_end(args); rb_write_error(buf); } #define warn_print(x) rb_write_error(x) #define warn_print2(x,l) rb_write_error2(x,l) static void error_pos() { ruby_set_current_source(); if (ruby_sourcefile) { if (ruby_frame->last_func) { warn_printf("%s:%d:in `%s'", ruby_sourcefile, ruby_sourceline, rb_id2name(ruby_frame->last_func)); } else if (ruby_sourceline == 0) { warn_printf("%s", ruby_sourcefile); } else { warn_printf("%s:%d", ruby_sourcefile, ruby_sourceline); } } } static VALUE get_backtrace(info) VALUE info; { if (NIL_P(info)) return Qnil; return rb_funcall(info, rb_intern("backtrace"), 0); } static void set_backtrace(info, bt) VALUE info, bt; { rb_funcall(info, rb_intern("set_backtrace"), 1, bt); } static void error_print() { VALUE errat = Qnil; /* OK */ volatile VALUE eclass, e; char *einfo; long elen; if (NIL_P(ruby_errinfo)) return; PUSH_TAG(PROT_NONE); if (EXEC_TAG() == 0) { errat = get_backtrace(ruby_errinfo); } else { errat = Qnil; } if (EXEC_TAG()) goto error; if (NIL_P(errat)){ ruby_set_current_source(); if (ruby_sourcefile) warn_printf("%s:%d", ruby_sourcefile, ruby_sourceline); else warn_printf("%d", ruby_sourceline); } else if (RARRAY(errat)->len == 0) { error_pos(); } else { VALUE mesg = RARRAY(errat)->ptr[0]; if (NIL_P(mesg)) error_pos(); else { warn_print2(RSTRING(mesg)->ptr, RSTRING(mesg)->len); } } eclass = CLASS_OF(ruby_errinfo); if (EXEC_TAG() == 0) { e = rb_obj_as_string(ruby_errinfo); einfo = RSTRING(e)->ptr; elen = RSTRING(e)->len; } else { einfo = ""; elen = 0; } if (EXEC_TAG()) goto error; if (eclass == rb_eRuntimeError && elen == 0) { warn_print(": unhandled exception\n"); } else { VALUE epath; epath = rb_class_path(eclass); if (elen == 0) { warn_print(": "); warn_print2(RSTRING(epath)->ptr, RSTRING(epath)->len); } else { char *tail = 0; long len = elen; if (RSTRING(epath)->ptr[0] == '#') epath = 0; if (tail = memchr(einfo, '\n', elen)) { len = tail - einfo; tail++; /* skip newline */ } warn_print(": "); warn_print2(einfo, len); if (epath) { warn_print(" ("); warn_print2(RSTRING(epath)->ptr, RSTRING(epath)->len); warn_print(")\n"); } if (tail) { warn_print2(tail, elen-len-1); } } } if (!NIL_P(errat)) { long i; struct RArray *ep = RARRAY(errat); #define TRACE_MAX (TRACE_HEAD+TRACE_TAIL+5) #define TRACE_HEAD 8 #define TRACE_TAIL 5 ep = RARRAY(errat); for (i=1; ilen; i++) { if (TYPE(ep->ptr[i]) == T_STRING) { warn_printf("\tfrom %s\n", RSTRING(ep->ptr[i])->ptr); } if (i == TRACE_HEAD && ep->len > TRACE_MAX) { warn_printf("\t ... %ld levels...\n", ep->len - TRACE_HEAD - TRACE_TAIL); i = ep->len - TRACE_TAIL; } } } error: POP_TAG(); } #if defined(__APPLE__) #define environ (*_NSGetEnviron()) #elif !defined(_WIN32) && !defined(__MACOS__) || defined(_WIN32_WCE) extern char **environ; #endif char **rb_origenviron; void rb_call_inits _((void)); void Init_stack _((void*)); void Init_heap _((void)); void Init_ext _((void)); void ruby_init() { static int initialized = 0; static struct FRAME frame; static struct iter iter; int state; if (initialized) return; initialized = 1; ruby_frame = top_frame = &frame; ruby_iter = &iter; #ifdef __MACOS__ rb_origenviron = 0; #else rb_origenviron = environ; #endif Init_stack((void*)&state); Init_heap(); PUSH_SCOPE(); ruby_scope->local_vars = 0; ruby_scope->local_tbl = 0; top_scope = ruby_scope; /* default visibility is private at toplevel */ SCOPE_SET(SCOPE_PRIVATE); PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { rb_call_inits(); ruby_class = rb_cObject; ruby_frame->self = ruby_top_self; top_cref = rb_node_newnode(NODE_CREF,rb_cObject,0,0); ruby_cref = top_cref; rb_define_global_const("TOPLEVEL_BINDING", rb_f_binding(ruby_top_self)); #ifdef __MACOS__ _macruby_init(); #endif ruby_prog_init(); ALLOW_INTS; } POP_TAG(); if (state) { error_print(); exit(1); } POP_SCOPE(); ruby_scope = top_scope; ruby_running = 1; } static VALUE eval_node(self, node) VALUE self; NODE *node; { NODE *beg_tree = ruby_eval_tree_begin; ruby_eval_tree_begin = 0; if (beg_tree) { rb_eval(self, beg_tree); } if (!node) return Qnil; return rb_eval(self, node); } int ruby_in_eval; static void rb_thread_cleanup _((void)); static void rb_thread_wait_other_threads _((void)); static int thread_set_raised(); static int thread_reset_raised(); static VALUE exception_error; static VALUE sysstack_error; static int error_handle(ex) int ex; { if (thread_set_raised()) return 1; switch (ex & TAG_MASK) { case 0: ex = 0; break; case TAG_RETURN: error_pos(); warn_print(": unexpected return\n"); ex = 1; break; case TAG_NEXT: error_pos(); warn_print(": unexpected next\n"); ex = 1; break; case TAG_BREAK: error_pos(); warn_print(": unexpected break\n"); ex = 1; break; case TAG_REDO: error_pos(); warn_print(": unexpected redo\n"); ex = 1; break; case TAG_RETRY: error_pos(); warn_print(": retry outside of rescue clause\n"); ex = 1; break; case TAG_THROW: if (prot_tag && prot_tag->frame && prot_tag->frame->node) { NODE *tag = prot_tag->frame->node; warn_printf("%s:%d: uncaught throw\n", tag->nd_file, nd_line(tag)); } else { error_pos(); warn_printf(": unexpected throw\n"); } ex = 1; break; case TAG_RAISE: case TAG_FATAL: if (rb_obj_is_kind_of(ruby_errinfo, rb_eSystemExit)) { VALUE st = rb_iv_get(ruby_errinfo, "status"); ex = NUM2INT(st); } else { error_print(); ex = 1; } break; default: rb_bug("Unknown longjmp status %d", ex); break; } thread_reset_raised(); return ex; } void ruby_options(argc, argv) int argc; char **argv; { int state; Init_stack((void*)&state); PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { ruby_process_options(argc, argv); } if (state) { trace_func = 0; tracing = 0; exit(error_handle(state)); } POP_TAG(); } void rb_exec_end_proc _((void)); static void ruby_finalize_0(exp) int *exp; { ruby_errinfo = 0; PUSH_TAG(PROT_NONE); if (EXEC_TAG() == 0) { rb_trap_exit(); } POP_TAG(); rb_exec_end_proc(); rb_gc_call_finalizer_at_exit(); if (exp && ruby_errinfo && rb_obj_is_kind_of(ruby_errinfo, rb_eSystemExit)) { VALUE st = rb_iv_get(ruby_errinfo, "status"); *exp = NUM2INT(st); } trace_func = 0; tracing = 0; } void ruby_finalize() { ruby_finalize_0(0); } int ruby_cleanup(ex) int ex; { int state; ruby_safe_level = 0; PUSH_TAG(PROT_NONE); PUSH_ITER(ITER_NOT); if ((state = EXEC_TAG()) == 0) { rb_thread_cleanup(); rb_thread_wait_other_threads(); } else if (ex == 0) { ex = state; } POP_ITER(); ex = error_handle(ex); POP_TAG(); ruby_finalize_0(&ex); return ex; } int ruby_exec() { int state; volatile NODE *tmp; Init_stack((void*)&tmp); PUSH_TAG(PROT_NONE); PUSH_ITER(ITER_NOT); /* default visibility is private at toplevel */ SCOPE_SET(SCOPE_PRIVATE); if ((state = EXEC_TAG()) == 0) { eval_node(ruby_top_self, ruby_eval_tree); } POP_ITER(); POP_TAG(); return state; } void ruby_stop(ex) int ex; { exit(ruby_cleanup(ex)); } void ruby_run() { int state; static int ex; if (ruby_nerrs > 0) exit(ruby_nerrs); state = ruby_exec(); if (state && !ex) ex = state; ruby_stop(ex); } static void compile_error(at) const char *at; { VALUE str; ruby_nerrs = 0; str = rb_str_buf_new2("compile error"); if (at) { rb_str_buf_cat2(str, " in "); rb_str_buf_cat2(str, at); } rb_str_buf_cat(str, "\n", 1); if (!NIL_P(ruby_errinfo)) { rb_str_append(str, rb_obj_as_string(ruby_errinfo)); } rb_exc_raise(rb_exc_new3(rb_eSyntaxError, str)); } VALUE rb_eval_string(str) const char *str; { VALUE v; NODE *oldsrc = ruby_current_node; ruby_current_node = 0; ruby_sourcefile = rb_source_filename("(eval)"); v = eval(ruby_top_self, rb_str_new2(str), Qnil, 0, 0); ruby_current_node = oldsrc; return v; } VALUE rb_eval_string_protect(str, state) const char *str; int *state; { VALUE result = Qnil; /* OK */ int status; PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { result = rb_eval_string(str); } POP_TAG(); if (state) { *state = status; } if (status != 0) { return Qnil; } return result; } VALUE rb_eval_string_wrap(str, state) const char *str; int *state; { int status; VALUE self = ruby_top_self; VALUE wrapper = ruby_wrapper; VALUE val; PUSH_CLASS(ruby_wrapper = rb_module_new()); ruby_top_self = rb_obj_clone(ruby_top_self); rb_extend_object(ruby_top_self, ruby_wrapper); PUSH_FRAME(); ruby_frame->last_func = 0; ruby_frame->orig_func = 0; ruby_frame->last_class = 0; ruby_frame->self = self; PUSH_CREF(ruby_wrapper); PUSH_SCOPE(); val = rb_eval_string_protect(str, &status); ruby_top_self = self; POP_SCOPE(); POP_FRAME(); POP_CLASS(); ruby_wrapper = wrapper; if (state) { *state = status; } else if (status) { JUMP_TAG(status); } return val; } static void localjump_error(mesg, value, reason) const char *mesg; VALUE value; int reason; { VALUE exc = rb_exc_new2(rb_eLocalJumpError, mesg); VALUE id; rb_iv_set(exc, "@exit_value", value); switch (reason) { case TAG_BREAK: id = rb_intern("break"); break; case TAG_REDO: id = rb_intern("redo"); break; case TAG_RETRY: id = rb_intern("retry"); break; case TAG_NEXT: id = rb_intern("next"); break; case TAG_RETURN: id = rb_intern("return"); break; default: id = rb_intern("noreason"); break; } rb_iv_set(exc, "@reason", ID2SYM(id)); rb_exc_raise(exc); } static VALUE localjump_xvalue(exc) VALUE exc; { return rb_iv_get(exc, "@exit_value"); } static VALUE localjump_reason(exc) VALUE exc; { return rb_iv_get(exc, "@reason"); } NORETURN(static void jump_tag_but_local_jump _((int))); static void jump_tag_but_local_jump(state) int state; { VALUE val; if (prot_tag) val = prot_tag->retval; else val = Qnil; switch (state) { case 0: break; case TAG_RETURN: localjump_error("unexpected return", val, state); break; case TAG_BREAK: localjump_error("unexpected break", val, state); break; case TAG_NEXT: localjump_error("unexpected next", val, state); break; case TAG_REDO: localjump_error("unexpected redo", Qnil, state); break; case TAG_RETRY: localjump_error("retry outside of rescue clause", Qnil, state); break; default: break; } JUMP_TAG(state); } VALUE rb_eval_cmd(cmd, arg, tcheck) VALUE cmd, arg; int tcheck; { int state; VALUE val = Qnil; /* OK */ struct SCOPE *saved_scope; volatile int safe = ruby_safe_level; if (TYPE(cmd) != T_STRING) { PUSH_ITER(ITER_NOT); val = rb_funcall2(cmd, rb_intern("call"), RARRAY(arg)->len, RARRAY(arg)->ptr); POP_ITER(); return val; } saved_scope = ruby_scope; ruby_scope = top_scope; PUSH_FRAME(); ruby_frame->last_func = 0; ruby_frame->orig_func = 0; ruby_frame->last_class = 0; ruby_frame->self = ruby_top_self; PUSH_CREF(ruby_wrapper ? ruby_wrapper : rb_cObject); if (tcheck && OBJ_TAINTED(cmd)) { ruby_safe_level = 4; } PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { val = eval(ruby_top_self, cmd, Qnil, 0, 0); } if (ruby_scope->flags & SCOPE_DONT_RECYCLE) scope_dup(saved_scope); ruby_scope = saved_scope; ruby_safe_level = safe; POP_TAG(); POP_FRAME(); jump_tag_but_local_jump(state); return val; } static VALUE superclass(self, node) VALUE self; NODE *node; { VALUE val = Qnil; /* OK */ int state; PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { val = rb_eval(self, node); } POP_TAG(); if (state) { switch (nd_type(node)) { case NODE_COLON2: rb_raise(rb_eTypeError, "undefined superclass `%s'", rb_id2name(node->nd_mid)); case NODE_CONST: rb_raise(rb_eTypeError, "undefined superclass `%s'", rb_id2name(node->nd_vid)); default: break; } JUMP_TAG(state); } if (TYPE(val) != T_CLASS) { rb_raise(rb_eTypeError, "superclass must be a Class (%s given)", rb_obj_classname(val)); } if (FL_TEST(val, FL_SINGLETON)) { rb_raise(rb_eTypeError, "can't make subclass of virtual class"); } return val; } #define ruby_cbase (ruby_cref->nd_clss) static VALUE ev_const_defined(cref, id, self) NODE *cref; ID id; VALUE self; { NODE *cbase = cref; VALUE result; while (cbase && cbase->nd_next) { struct RClass *klass = RCLASS(cbase->nd_clss); if (NIL_P(klass)) return rb_const_defined(CLASS_OF(self), id); if (klass->iv_tbl && st_lookup(klass->iv_tbl, id, &result)) { if (result == Qundef && NIL_P(rb_autoload_p((VALUE)klass, id))) { return Qfalse; } return Qtrue; } cbase = cbase->nd_next; } return rb_const_defined(cref->nd_clss, id); } static VALUE ev_const_get(cref, id, self) NODE *cref; ID id; VALUE self; { NODE *cbase = cref; VALUE result; while (cbase && cbase->nd_next) { VALUE klass = cbase->nd_clss; if (NIL_P(klass)) return rb_const_get(CLASS_OF(self), id); while (RCLASS(klass)->iv_tbl && st_lookup(RCLASS(klass)->iv_tbl, id, &result)) { if (result == Qundef) { rb_autoload_load(klass, id); continue; } return result; } cbase = cbase->nd_next; } return rb_const_get(cref->nd_clss, id); } static VALUE cvar_cbase() { NODE *cref = ruby_cref; while (cref && cref->nd_next && FL_TEST(cref->nd_clss, FL_SINGLETON)) { cref = cref->nd_next; if (!cref->nd_next) { rb_warn("class variable access from toplevel singleton method"); } } return cref->nd_clss; } static VALUE rb_mod_nesting() { NODE *cbase = ruby_cref; VALUE ary = rb_ary_new(); while (cbase && cbase->nd_next) { if (!NIL_P(cbase->nd_clss)) rb_ary_push(ary, cbase->nd_clss); cbase = cbase->nd_next; } if (ruby_wrapper && RARRAY(ary)->len == 0) { rb_ary_push(ary, ruby_wrapper); } return ary; } static VALUE rb_mod_s_constants() { NODE *cbase = ruby_cref; void *data = 0; while (cbase) { if (!NIL_P(cbase->nd_clss)) { data = rb_mod_const_at(cbase->nd_clss, data); } cbase = cbase->nd_next; } if (!NIL_P(ruby_cbase)) { data = rb_mod_const_of(ruby_cbase, data); } return rb_const_list(data); } void rb_frozen_class_p(klass) VALUE klass; { char *desc = "something(?!)"; if (OBJ_FROZEN(klass)) { if (FL_TEST(klass, FL_SINGLETON)) desc = "object"; else { switch (TYPE(klass)) { case T_MODULE: case T_ICLASS: desc = "module"; break; case T_CLASS: desc = "class"; break; } } rb_error_frozen(desc); } } void rb_undef(klass, id) VALUE klass; ID id; { VALUE origin; NODE *body; if (ruby_cbase == rb_cObject && klass == rb_cObject) { rb_secure(4); } if (ruby_safe_level >= 4 && !OBJ_TAINTED(klass)) { rb_raise(rb_eSecurityError, "Insecure: can't undef `%s'", rb_id2name(id)); } rb_frozen_class_p(klass); if (id == __id__ || id == __send__ || id == init) { rb_warn("undefining `%s' may cause serious problem", rb_id2name(id)); } body = search_method(klass, id, &origin); if (!body || !body->nd_body) { char *s0 = " class"; VALUE c = klass; if (FL_TEST(c, FL_SINGLETON)) { VALUE obj = rb_iv_get(klass, "__attached__"); switch (TYPE(obj)) { case T_MODULE: case T_CLASS: c = obj; s0 = ""; } } else if (TYPE(c) == T_MODULE) { s0 = " module"; } rb_name_error(id, "undefined method `%s' for%s `%s'", rb_id2name(id),s0,rb_class2name(c)); } rb_add_method(klass, id, 0, NOEX_PUBLIC); if (FL_TEST(klass, FL_SINGLETON)) { rb_funcall(rb_iv_get(klass, "__attached__"), singleton_undefined, 1, ID2SYM(id)); } else { rb_funcall(klass, undefined, 1, ID2SYM(id)); } } static VALUE rb_mod_undef_method(argc, argv, mod) int argc; VALUE *argv; VALUE mod; { int i; for (i=0; ind_body) { if (TYPE(klass) == T_MODULE) { orig = search_method(rb_cObject, def, &origin); } } if (!orig || !orig->nd_body) { print_undef(klass, def); } if (FL_TEST(klass, FL_SINGLETON)) { singleton = rb_iv_get(klass, "__attached__"); } body = orig->nd_body; orig->nd_cnt++; if (nd_type(body) == NODE_FBODY) { /* was alias */ def = body->nd_mid; origin = body->nd_orig; body = body->nd_head; } rb_clear_cache_by_id(name); st_insert(RCLASS(klass)->m_tbl, name, (st_data_t)NEW_METHOD(NEW_FBODY(body, def, origin), orig->nd_noex)); if (singleton) { rb_funcall(singleton, singleton_added, 1, ID2SYM(name)); } else { rb_funcall(klass, added, 1, ID2SYM(name)); } } static VALUE rb_mod_alias_method(mod, newname, oldname) VALUE mod, newname, oldname; { rb_alias(mod, rb_to_id(newname), rb_to_id(oldname)); return mod; } static NODE* copy_node_scope(node, rval) NODE *node; NODE *rval; { NODE *copy = NEW_NODE(NODE_SCOPE,0,rval,node->nd_next); if (node->nd_tbl) { copy->nd_tbl = ALLOC_N(ID, node->nd_tbl[0]+1); MEMCPY(copy->nd_tbl, node->nd_tbl, ID, node->nd_tbl[0]+1); } else { copy->nd_tbl = 0; } return copy; } #ifdef C_ALLOCA # define TMP_PROTECT NODE * volatile tmp__protect_tmp=0 # define TMP_ALLOC(n) \ (tmp__protect_tmp = rb_node_newnode(NODE_ALLOCA, \ ALLOC_N(VALUE,n),tmp__protect_tmp,n), \ (void*)tmp__protect_tmp->nd_head) #else # define TMP_PROTECT typedef int foobazzz # define TMP_ALLOC(n) ALLOCA_N(VALUE,n) #endif #define SETUP_ARGS0(anode,alen) do {\ NODE *n = anode;\ if (!n) {\ argc = 0;\ argv = 0;\ }\ else if (nd_type(n) == NODE_ARRAY) {\ argc=alen;\ if (argc > 0) {\ int i;\ n = anode;\ argv = TMP_ALLOC(argc);\ for (i=0;ind_head);\ n=n->nd_next;\ }\ }\ else {\ argc = 0;\ argv = 0;\ }\ }\ else {\ VALUE args = rb_eval(self,n);\ if (TYPE(args) != T_ARRAY)\ args = rb_ary_to_ary(args);\ argc = RARRAY(args)->len;\ argv = ALLOCA_N(VALUE, argc);\ MEMCPY(argv, RARRAY(args)->ptr, VALUE, argc);\ }\ } while (0) #define SETUP_ARGS(anode) SETUP_ARGS0(anode, anode->nd_alen) #define BEGIN_CALLARGS do {\ struct BLOCK *tmp_block = ruby_block;\ int tmp_iter = ruby_iter->iter;\ if (tmp_iter == ITER_PRE) {\ ruby_block = ruby_block->outer;\ tmp_iter = ITER_NOT;\ }\ PUSH_ITER(tmp_iter) #define END_CALLARGS \ ruby_block = tmp_block;\ POP_ITER();\ } while (0) #define MATCH_DATA *rb_svar(node->nd_cnt) static char* is_defined _((VALUE, NODE*, char*)); static char* arg_defined(self, node, buf, type) VALUE self; NODE *node; char *buf; char *type; { int argc; int i; if (!node) return type; /* no args */ if (nd_type(node) == NODE_ARRAY) { argc=node->nd_alen; if (argc > 0) { for (i=0;ind_head, buf)) return 0; node = node->nd_next; } } } else if (!is_defined(self, node, buf)) { return 0; } return type; } static char* is_defined(self, node, buf) VALUE self; NODE *node; /* OK */ char *buf; { VALUE val; /* OK */ int state; again: if (!node) return "expression"; switch (nd_type(node)) { case NODE_SUPER: case NODE_ZSUPER: if (ruby_frame->orig_func == 0) return 0; else if (ruby_frame->last_class == 0) return 0; else if (rb_method_boundp(RCLASS(ruby_frame->last_class)->super, ruby_frame->orig_func, 0)) { if (nd_type(node) == NODE_SUPER) { return arg_defined(self, node->nd_args, buf, "super"); } return "super"; } break; case NODE_VCALL: case NODE_FCALL: val = self; goto check_bound; case NODE_ATTRASGN: val = self; if (node->nd_recv == (NODE *)1) goto check_bound; case NODE_CALL: PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { val = rb_eval(self, node->nd_recv); } POP_TAG(); if (state) { ruby_errinfo = Qnil; return 0; } check_bound: { int call = nd_type(node)==NODE_CALL; val = CLASS_OF(val); if (call) { int noex; ID id = node->nd_mid; if (!rb_get_method_body(&val, &id, &noex)) break; if ((noex & NOEX_PRIVATE)) break; if ((noex & NOEX_PROTECTED) && !rb_obj_is_kind_of(self, rb_class_real(val))) break; } else if (!rb_method_boundp(val, node->nd_mid, call)) break; return arg_defined(self, node->nd_args, buf, nd_type(node) == NODE_ATTRASGN ? "assignment" : "method"); } break; case NODE_MATCH2: case NODE_MATCH3: return "method"; case NODE_YIELD: if (rb_block_given_p()) { return "yield"; } break; case NODE_SELF: return "self"; case NODE_NIL: return "nil"; case NODE_TRUE: return "true"; case NODE_FALSE: return "false"; case NODE_ATTRSET: case NODE_OP_ASGN1: case NODE_OP_ASGN2: case NODE_MASGN: case NODE_LASGN: case NODE_DASGN: case NODE_DASGN_CURR: case NODE_GASGN: case NODE_CDECL: case NODE_CVDECL: case NODE_CVASGN: return "assignment"; case NODE_LVAR: return "local-variable"; case NODE_DVAR: return "local-variable(in-block)"; case NODE_GVAR: if (rb_gvar_defined(node->nd_entry)) { return "global-variable"; } break; case NODE_IVAR: if (rb_ivar_defined(self, node->nd_vid)) { return "instance-variable"; } break; case NODE_CONST: if (ev_const_defined(ruby_cref, node->nd_vid, self)) { return "constant"; } break; case NODE_CVAR: if (rb_cvar_defined(cvar_cbase(), node->nd_vid)) { return "class variable"; } break; case NODE_COLON2: PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { val = rb_eval(self, node->nd_head); } POP_TAG(); if (state) { ruby_errinfo = Qnil; return 0; } else { switch (TYPE(val)) { case T_CLASS: case T_MODULE: if (rb_const_defined_from(val, node->nd_mid)) return "constant"; break; default: if (rb_method_boundp(CLASS_OF(val), node->nd_mid, 1)) { return "method"; } } } break; case NODE_COLON3: if (rb_const_defined_from(rb_cObject, node->nd_mid)) { return "constant"; } break; case NODE_NTH_REF: if (RTEST(rb_reg_nth_defined(node->nd_nth, MATCH_DATA))) { sprintf(buf, "$%d", (int)node->nd_nth); return buf; } break; case NODE_BACK_REF: if (RTEST(rb_reg_nth_defined(0, MATCH_DATA))) { sprintf(buf, "$%c", (char)node->nd_nth); return buf; } break; case NODE_NEWLINE: node = node->nd_next; goto again; default: PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { rb_eval(self, node); } POP_TAG(); if (!state) { return "expression"; } ruby_errinfo = Qnil; break; } return 0; } static int handle_rescue _((VALUE,NODE*)); static void blk_free(); static VALUE rb_obj_is_proc(proc) VALUE proc; { if (TYPE(proc) == T_DATA && RDATA(proc)->dfree == (RUBY_DATA_FUNC)blk_free) { return Qtrue; } return Qfalse; } static VALUE set_trace_func(obj, trace) VALUE obj, trace; { if (NIL_P(trace)) { trace_func = 0; return Qnil; } if (!rb_obj_is_proc(trace)) { rb_raise(rb_eTypeError, "trace_func needs to be Proc"); } return trace_func = trace; } static void call_trace_func(event, node, self, id, klass) char *event; NODE *node; VALUE self; ID id; VALUE klass; /* OK */ { int state, raised; struct FRAME *prev; NODE *node_save; VALUE srcfile; if (!trace_func) return; if (tracing) return; if (ruby_in_compile) return; if (id == ID_ALLOCATOR) return; if (!(node_save = ruby_current_node)) { node_save = NEW_NEWLINE(0); } tracing = 1; prev = ruby_frame; PUSH_FRAME(); *ruby_frame = *prev; ruby_frame->prev = prev; ruby_frame->iter = 0; /* blocks not available anyway */ if (node) { ruby_current_node = node; ruby_frame->node = node; ruby_sourcefile = node->nd_file; ruby_sourceline = nd_line(node); } if (klass) { if (TYPE(klass) == T_ICLASS) { klass = RBASIC(klass)->klass; } else if (FL_TEST(klass, FL_SINGLETON)) { klass = self; } } PUSH_TAG(PROT_NONE); raised = thread_reset_raised(); if ((state = EXEC_TAG()) == 0) { srcfile = rb_str_new2(ruby_sourcefile?ruby_sourcefile:"(ruby)"); proc_invoke(trace_func, rb_ary_new3(6, rb_str_new2(event), srcfile, INT2FIX(ruby_sourceline), id?ID2SYM(id):Qnil, self?rb_f_binding(self):Qnil, klass), Qundef, 0); } if (raised) thread_set_raised(); POP_TAG(); POP_FRAME(); tracing = 0; ruby_current_node = node_save; SET_CURRENT_SOURCE(); if (state) JUMP_TAG(state); } static VALUE avalue_to_svalue(v) VALUE v; { VALUE tmp, top; tmp = rb_check_array_type(v); if (NIL_P(tmp)) { return v; } if (RARRAY(tmp)->len == 0) { return Qundef; } if (RARRAY(tmp)->len == 1) { top = rb_check_array_type(RARRAY(tmp)->ptr[0]); if (NIL_P(top)) { return RARRAY(tmp)->ptr[0]; } if (RARRAY(top)->len > 1) { return v; } return top; } return tmp; } static VALUE svalue_to_avalue(v) VALUE v; { VALUE tmp, top; if (v == Qundef) return rb_ary_new2(0); tmp = rb_check_array_type(v); if (NIL_P(tmp)) { return rb_ary_new3(1, v); } if (RARRAY(tmp)->len == 1) { top = rb_check_array_type(RARRAY(tmp)->ptr[0]); if (!NIL_P(top) && RARRAY(top)->len > 1) { return v; } return rb_ary_new3(1, v); } return tmp; } static VALUE svalue_to_mrhs(v, lhs) VALUE v; NODE *lhs; { VALUE tmp; if (v == Qundef) return rb_ary_new2(0); tmp = rb_check_array_type(v); if (NIL_P(tmp)) { return rb_ary_new3(1, v); } /* no lhs means splat lhs only */ if (!lhs) { return rb_ary_new3(1, v); } return tmp; } static VALUE avalue_splat(v) VALUE v; { if (RARRAY(v)->len == 0) { return Qundef; } if (RARRAY(v)->len == 1) { return RARRAY(v)->ptr[0]; } return v; } #if 1 VALUE rb_Array(val) VALUE val; { VALUE tmp = rb_check_array_type(val); if (NIL_P(tmp)) { /* hack to avoid invoke Object#to_a */ VALUE origin; ID id = rb_intern("to_a"); if (search_method(CLASS_OF(val), id, &origin) && RCLASS(origin)->m_tbl != RCLASS(rb_mKernel)->m_tbl) { /* exclude Kernel#to_a */ val = rb_funcall(val, id, 0); if (TYPE(val) != T_ARRAY) { rb_raise(rb_eTypeError, "`to_a' did not return Array"); } return val; } else { return rb_ary_new3(1, val); } } return tmp; } #endif static VALUE splat_value(v) VALUE v; { if (NIL_P(v)) return rb_ary_new3(1, Qnil); return rb_Array(v); } static VALUE class_prefix(self, cpath) VALUE self; NODE *cpath; { if (!cpath) { rb_bug("class path missing"); } if (cpath->nd_head) { VALUE c = rb_eval(self, cpath->nd_head); switch (TYPE(c)) { case T_CLASS: case T_MODULE: break; default: rb_raise(rb_eTypeError, "%s is not a class/module", RSTRING(rb_obj_as_string(c))->ptr); } return c; } else if (nd_type(cpath) == NODE_COLON2) { return ruby_cbase; } else if (ruby_wrapper) { return ruby_wrapper; } else { return rb_cObject; } } #define return_value(v) do {\ if ((prot_tag->retval = (v)) == Qundef) {\ prot_tag->retval = Qnil;\ }\ } while (0) NORETURN(static void localjump_destination _((int, struct SCOPE*, VALUE))); static VALUE rb_eval(self, n) VALUE self; NODE *n; { NODE * volatile contnode = 0; NODE * volatile node = n; int state; volatile VALUE result = Qnil; #define RETURN(v) do { \ result = (v); \ goto finish; \ } while (0) again: if (!node) RETURN(Qnil); ruby_current_node = node; switch (nd_type(node)) { case NODE_BLOCK: if (contnode) { result = rb_eval(self, node); break; } contnode = node->nd_next; node = node->nd_head; goto again; case NODE_POSTEXE: rb_f_END(); nd_set_type(node, NODE_NIL); /* exec just once */ result = Qnil; break; /* begin .. end without clauses */ case NODE_BEGIN: node = node->nd_body; goto again; /* nodes for speed-up(default match) */ case NODE_MATCH: result = rb_reg_match2(node->nd_lit); break; /* nodes for speed-up(literal match) */ case NODE_MATCH2: result = rb_reg_match(rb_eval(self,node->nd_recv), rb_eval(self,node->nd_value)); break; /* nodes for speed-up(literal match) */ case NODE_MATCH3: { VALUE r = rb_eval(self,node->nd_recv); VALUE l = rb_eval(self,node->nd_value); if (TYPE(l) == T_STRING) { result = rb_reg_match(r, l); } else { result = rb_funcall(l, match, 1, r); } } break; /* node for speed-up(top-level loop for -n/-p) */ case NODE_OPT_N: PUSH_TAG(PROT_ITER); switch (state = EXEC_TAG()) { case 0: opt_n_next: while (!NIL_P(rb_gets())) { opt_n_redo: rb_eval(self, node->nd_body); } break; case TAG_REDO: state = 0; goto opt_n_redo; case TAG_NEXT: state = 0; goto opt_n_next; case TAG_BREAK: state = 0; default: break; } POP_TAG(); if (state) JUMP_TAG(state); RETURN(Qnil); case NODE_SELF: RETURN(self); case NODE_NIL: RETURN(Qnil); case NODE_TRUE: RETURN(Qtrue); case NODE_FALSE: RETURN(Qfalse); case NODE_IF: if (trace_func) { call_trace_func("line", node, self, ruby_frame->last_func, ruby_frame->last_class); } if (RTEST(rb_eval(self, node->nd_cond))) { node = node->nd_body; } else { node = node->nd_else; } goto again; case NODE_WHEN: while (node) { NODE *tag; if (nd_type(node) != NODE_WHEN) goto again; tag = node->nd_head; while (tag) { if (trace_func) { call_trace_func("line", tag, self, ruby_frame->last_func, ruby_frame->last_class); } if (nd_type(tag->nd_head) == NODE_WHEN) { VALUE v = rb_eval(self, tag->nd_head->nd_head); long i; if (TYPE(v) != T_ARRAY) v = rb_ary_to_ary(v); for (i=0; ilen; i++) { if (RTEST(RARRAY(v)->ptr[i])) { node = node->nd_body; goto again; } } tag = tag->nd_next; continue; } if (RTEST(rb_eval(self, tag->nd_head))) { node = node->nd_body; goto again; } tag = tag->nd_next; } node = node->nd_next; } RETURN(Qnil); case NODE_CASE: { VALUE val; val = rb_eval(self, node->nd_head); node = node->nd_body; while (node) { NODE *tag; if (nd_type(node) != NODE_WHEN) { goto again; } tag = node->nd_head; while (tag) { if (trace_func) { call_trace_func("line", tag, self, ruby_frame->last_func, ruby_frame->last_class); } if (nd_type(tag->nd_head) == NODE_WHEN) { VALUE v = rb_eval(self, tag->nd_head->nd_head); long i; if (TYPE(v) != T_ARRAY) v = rb_ary_to_ary(v); for (i=0; ilen; i++) { if (RTEST(rb_funcall2(RARRAY(v)->ptr[i], eqq, 1, &val))){ node = node->nd_body; goto again; } } tag = tag->nd_next; continue; } if (RTEST(rb_funcall2(rb_eval(self, tag->nd_head), eqq, 1, &val))) { node = node->nd_body; goto again; } tag = tag->nd_next; } node = node->nd_next; } } RETURN(Qnil); case NODE_WHILE: PUSH_TAG(PROT_ITER); result = Qnil; switch (state = EXEC_TAG()) { case 0: if (node->nd_state && !RTEST(rb_eval(self, node->nd_cond))) goto while_out; do { while_redo: rb_eval(self, node->nd_body); while_next: ; } while (RTEST(rb_eval(self, node->nd_cond))); break; case TAG_REDO: state = 0; goto while_redo; case TAG_NEXT: state = 0; goto while_next; case TAG_BREAK: if (TAG_DST()) { state = 0; result = prot_tag->retval; } /* fall through */ default: break; } while_out: POP_TAG(); if (state) JUMP_TAG(state); RETURN(result); case NODE_UNTIL: PUSH_TAG(PROT_ITER); result = Qnil; switch (state = EXEC_TAG()) { case 0: if (node->nd_state && RTEST(rb_eval(self, node->nd_cond))) goto until_out; do { until_redo: rb_eval(self, node->nd_body); until_next: ; } while (!RTEST(rb_eval(self, node->nd_cond))); break; case TAG_REDO: state = 0; goto until_redo; case TAG_NEXT: state = 0; goto until_next; case TAG_BREAK: if (TAG_DST()) { state = 0; result = prot_tag->retval; } /* fall through */ default: break; } until_out: POP_TAG(); if (state) JUMP_TAG(state); RETURN(result); case NODE_BLOCK_PASS: result = block_pass(self, node); break; case NODE_ITER: case NODE_FOR: { PUSH_TAG(PROT_ITER); PUSH_BLOCK(node->nd_var, node->nd_body); state = EXEC_TAG(); if (state == 0) { iter_retry: PUSH_ITER(ITER_PRE); if (nd_type(node) == NODE_ITER) { result = rb_eval(self, node->nd_iter); } else { VALUE recv; _block.flags &= ~BLOCK_D_SCOPE; BEGIN_CALLARGS; recv = rb_eval(self, node->nd_iter); END_CALLARGS; ruby_current_node = node; SET_CURRENT_SOURCE(); result = rb_call(CLASS_OF(recv),recv,each,0,0,0); } POP_ITER(); } else if (state == TAG_BREAK && TAG_DST()) { result = prot_tag->retval; state = 0; } else if (state == TAG_RETRY) { state = 0; goto iter_retry; } POP_BLOCK(); POP_TAG(); switch (state) { case 0: break; default: JUMP_TAG(state); } } break; case NODE_BREAK: localjump_destination(TAG_BREAK, ruby_scope, rb_eval(self, node->nd_stts)); break; case NODE_NEXT: CHECK_INTS; return_value(rb_eval(self, node->nd_stts)); JUMP_TAG(TAG_NEXT); break; case NODE_REDO: CHECK_INTS; JUMP_TAG(TAG_REDO); break; case NODE_RETRY: CHECK_INTS; JUMP_TAG(TAG_RETRY); break; case NODE_SPLAT: result = splat_value(rb_eval(self, node->nd_head)); break; case NODE_SVALUE: result = avalue_splat(rb_eval(self, node->nd_head)); if (result == Qundef) result = Qnil; break; case NODE_YIELD: if (node->nd_head) { result = rb_eval(self, node->nd_head); } else { result = Qundef; /* no arg */ } SET_CURRENT_SOURCE(); result = rb_yield_0(result, 0, 0, 0, node->nd_state); break; case NODE_RESCUE: { volatile VALUE e_info = ruby_errinfo; volatile int rescuing = 0; PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { result = rb_eval(self, node->nd_head); } else if (rescuing) { if (rescuing < 0) { /* in rescue argument, just reraise */ } else if (state == TAG_RETRY) { rescuing = state = 0; e_info = ruby_errinfo = Qnil; result = rb_eval(self, node->nd_head); } else if (state != TAG_RAISE) { ruby_errinfo = e_info; } } else if (state == TAG_RAISE) { NODE *resq = node->nd_resq; rescuing = -1; while (resq) { ruby_current_node = resq; if (handle_rescue(self, resq)) { state = 0; rescuing = 1; result = rb_eval(self, resq->nd_body); ruby_errinfo = e_info; break; } resq = resq->nd_head; /* next rescue */ } } POP_TAG(); if (state) JUMP_TAG(state); /* no exception raised */ if (node = node->nd_else) { /* else clause given */ goto again; } } break; case NODE_ENSURE: PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { result = rb_eval(self, node->nd_head); } POP_TAG(); if (node->nd_ensr) { VALUE retval = prot_tag->retval; /* save retval */ VALUE errinfo = ruby_errinfo; rb_eval(self, node->nd_ensr); return_value(retval); ruby_errinfo = errinfo; } if (state) JUMP_TAG(state); break; case NODE_AND: result = rb_eval(self, node->nd_1st); if (!RTEST(result)) break; node = node->nd_2nd; goto again; case NODE_OR: result = rb_eval(self, node->nd_1st); if (RTEST(result)) break; node = node->nd_2nd; goto again; case NODE_NOT: if (RTEST(rb_eval(self, node->nd_body))) result = Qfalse; else result = Qtrue; break; case NODE_DOT2: case NODE_DOT3: result = rb_range_new(rb_eval(self, node->nd_beg), rb_eval(self, node->nd_end), nd_type(node) == NODE_DOT3); if (node->nd_state) break; if (nd_type(node->nd_beg) == NODE_LIT && FIXNUM_P(node->nd_beg->nd_lit) && nd_type(node->nd_end) == NODE_LIT && FIXNUM_P(node->nd_end->nd_lit)) { nd_set_type(node, NODE_LIT); node->nd_lit = result; } else { node->nd_state = 1; } break; case NODE_FLIP2: /* like AWK */ { VALUE *flip = rb_svar(node->nd_cnt); if (!flip) rb_bug("unexpected local variable"); if (!RTEST(*flip)) { if (RTEST(rb_eval(self, node->nd_beg))) { *flip = RTEST(rb_eval(self, node->nd_end))?Qfalse:Qtrue; result = Qtrue; } else { result = Qfalse; } } else { if (RTEST(rb_eval(self, node->nd_end))) { *flip = Qfalse; } result = Qtrue; } } break; case NODE_FLIP3: /* like SED */ { VALUE *flip = rb_svar(node->nd_cnt); if (!flip) rb_bug("unexpected local variable"); if (!RTEST(*flip)) { result = RTEST(rb_eval(self, node->nd_beg)) ? Qtrue : Qfalse; *flip = result; } else { if (RTEST(rb_eval(self, node->nd_end))) { *flip = Qfalse; } result = Qtrue; } } break; case NODE_RETURN: localjump_destination(TAG_RETURN, ruby_scope, rb_eval(self, node->nd_stts)); break; case NODE_ARGSCAT: result = rb_ary_concat(rb_eval(self, node->nd_head), splat_value(rb_eval(self, node->nd_body))); break; case NODE_ARGSPUSH: result = rb_ary_push(rb_ary_dup(rb_eval(self, node->nd_head)), rb_eval(self, node->nd_body)); break; case NODE_ATTRASGN: { VALUE recv; int argc; VALUE *argv; /* used in SETUP_ARGS */ int scope; TMP_PROTECT; BEGIN_CALLARGS; if (node->nd_recv == (NODE *)1) { recv = self; scope = 1; } else { recv = rb_eval(self, node->nd_recv); scope = 0; } SETUP_ARGS(node->nd_args); END_CALLARGS; SET_CURRENT_SOURCE(); rb_call(CLASS_OF(recv),recv,node->nd_mid,argc,argv,scope); result = argv[argc-1]; } break; case NODE_CALL: { VALUE recv; int argc; VALUE *argv; /* used in SETUP_ARGS */ TMP_PROTECT; BEGIN_CALLARGS; recv = rb_eval(self, node->nd_recv); SETUP_ARGS(node->nd_args); END_CALLARGS; SET_CURRENT_SOURCE(); result = rb_call(CLASS_OF(recv),recv,node->nd_mid,argc,argv,0); } break; case NODE_FCALL: { int argc; VALUE *argv; /* used in SETUP_ARGS */ TMP_PROTECT; BEGIN_CALLARGS; SETUP_ARGS(node->nd_args); END_CALLARGS; SET_CURRENT_SOURCE(); result = rb_call(CLASS_OF(self),self,node->nd_mid,argc,argv,1); } break; case NODE_VCALL: SET_CURRENT_SOURCE(); result = rb_call(CLASS_OF(self),self,node->nd_mid,0,0,2); break; case NODE_SUPER: case NODE_ZSUPER: { int argc; VALUE *argv; /* used in SETUP_ARGS */ TMP_PROTECT; if (ruby_frame->last_class == 0) { if (ruby_frame->orig_func) { rb_name_error(ruby_frame->last_func, "superclass method `%s' disabled", rb_id2name(ruby_frame->orig_func)); } else { rb_raise(rb_eNoMethodError, "super called outside of method"); } } if (nd_type(node) == NODE_ZSUPER) { argc = ruby_frame->argc; argv = ruby_frame->argv; } else { BEGIN_CALLARGS; SETUP_ARGS(node->nd_args); END_CALLARGS; } SET_CURRENT_SOURCE(); result = rb_call_super(argc, argv); } break; case NODE_SCOPE: { struct FRAME frame; NODE *saved_cref = 0; int jump_chain = Qfalse; frame = *ruby_frame; frame.tmp = ruby_frame; ruby_frame = &frame; PUSH_SCOPE(); PUSH_TAG(PROT_PCALL); if (node->nd_rval) { saved_cref = ruby_cref; ruby_cref = (NODE*)node->nd_rval; } if (node->nd_tbl) { VALUE *vars = ALLOCA_N(VALUE, node->nd_tbl[0]+1); *vars++ = (VALUE)node; ruby_scope->local_vars = vars; rb_mem_clear(ruby_scope->local_vars, node->nd_tbl[0]); ruby_scope->local_tbl = node->nd_tbl; } else { ruby_scope->local_vars = 0; ruby_scope->local_tbl = 0; } if ((state = EXEC_TAG()) == 0) { result = rb_eval(self, node->nd_next); } else if (TAG_DST()) { result = prot_tag->retval; jump_chain = Qtrue; } POP_TAG(); POP_SCOPE(); ruby_frame = frame.tmp; if (saved_cref) ruby_cref = saved_cref; switch (state) { case 0: break; case TAG_RETURN: case TAG_BREAK: localjump_destination(state, ruby_scope, result); default: JUMP_TAG(state); } } break; case NODE_OP_ASGN1: { int argc; VALUE *argv; /* used in SETUP_ARGS */ VALUE recv, val; NODE *rval; TMP_PROTECT; recv = rb_eval(self, node->nd_recv); rval = node->nd_args->nd_head; SETUP_ARGS0(node->nd_args->nd_next, node->nd_args->nd_alen - 1); val = rb_funcall2(recv, aref, argc-1, argv); switch (node->nd_mid) { case 0: /* OR */ if (RTEST(val)) RETURN(val); val = rb_eval(self, rval); break; case 1: /* AND */ if (!RTEST(val)) RETURN(val); val = rb_eval(self, rval); break; default: val = rb_funcall(val, node->nd_mid, 1, rb_eval(self, rval)); } argv[argc-1] = val; rb_funcall2(recv, aset, argc, argv); result = val; } break; case NODE_OP_ASGN2: { ID id = node->nd_next->nd_vid; VALUE recv, val; recv = rb_eval(self, node->nd_recv); val = rb_funcall(recv, id, 0); switch (node->nd_next->nd_mid) { case 0: /* OR */ if (RTEST(val)) RETURN(val); val = rb_eval(self, node->nd_value); break; case 1: /* AND */ if (!RTEST(val)) RETURN(val); val = rb_eval(self, node->nd_value); break; default: val = rb_funcall(val, node->nd_next->nd_mid, 1, rb_eval(self, node->nd_value)); } rb_funcall2(recv, node->nd_next->nd_aid, 1, &val); result = val; } break; case NODE_OP_ASGN_AND: result = rb_eval(self, node->nd_head); if (!RTEST(result)) break; node = node->nd_value; goto again; case NODE_OP_ASGN_OR: if ((node->nd_aid && !is_defined(self, node->nd_head, 0)) || !RTEST(result = rb_eval(self, node->nd_head))) { node = node->nd_value; goto again; } break; case NODE_MASGN: result = massign(self, node, rb_eval(self, node->nd_value), 0); break; case NODE_LASGN: if (ruby_scope->local_vars == 0) rb_bug("unexpected local variable assignment"); result = rb_eval(self, node->nd_value); ruby_scope->local_vars[node->nd_cnt] = result; break; case NODE_DASGN: result = rb_eval(self, node->nd_value); dvar_asgn(node->nd_vid, result); break; case NODE_DASGN_CURR: result = rb_eval(self, node->nd_value); dvar_asgn_curr(node->nd_vid, result); break; case NODE_GASGN: result = rb_eval(self, node->nd_value); rb_gvar_set(node->nd_entry, result); break; case NODE_IASGN: result = rb_eval(self, node->nd_value); rb_ivar_set(self, node->nd_vid, result); break; case NODE_CDECL: result = rb_eval(self, node->nd_value); if (node->nd_vid == 0) { rb_const_set(class_prefix(self, node->nd_else), node->nd_else->nd_mid, result); } else { if (NIL_P(ruby_cbase)) { rb_raise(rb_eTypeError, "no class/module to define constant"); } rb_const_set(ruby_cbase, node->nd_vid, result); } break; case NODE_CVDECL: if (NIL_P(ruby_cbase)) { rb_raise(rb_eTypeError, "no class/module to define class variable"); } result = rb_eval(self, node->nd_value); rb_cvar_set(cvar_cbase(), node->nd_vid, result, Qtrue); break; case NODE_CVASGN: result = rb_eval(self, node->nd_value); rb_cvar_set(cvar_cbase(), node->nd_vid, result, Qfalse); break; case NODE_LVAR: if (ruby_scope->local_vars == 0) { rb_bug("unexpected local variable"); } result = ruby_scope->local_vars[node->nd_cnt]; break; case NODE_DVAR: result = rb_dvar_ref(node->nd_vid); break; case NODE_GVAR: result = rb_gvar_get(node->nd_entry); break; case NODE_IVAR: result = rb_ivar_get(self, node->nd_vid); break; case NODE_CONST: result = ev_const_get(ruby_cref, node->nd_vid, self); break; case NODE_CVAR: result = rb_cvar_get(cvar_cbase(), node->nd_vid); break; case NODE_BLOCK_ARG: if (ruby_scope->local_vars == 0) rb_bug("unexpected block argument"); if (rb_block_given_p()) { result = rb_block_proc(); ruby_scope->local_vars[node->nd_cnt] = result; } else { result = Qnil; } break; case NODE_COLON2: { VALUE klass; klass = rb_eval(self, node->nd_head); if (rb_is_const_id(node->nd_mid)) { switch (TYPE(klass)) { case T_CLASS: case T_MODULE: result = rb_const_get_from(klass, node->nd_mid); break; default: rb_raise(rb_eTypeError, "%s is not a class/module", RSTRING(rb_obj_as_string(klass))->ptr); break; } } else { result = rb_funcall(klass, node->nd_mid, 0, 0); } } break; case NODE_COLON3: result = rb_const_get_from(rb_cObject, node->nd_mid); break; case NODE_NTH_REF: result = rb_reg_nth_match(node->nd_nth, MATCH_DATA); break; case NODE_BACK_REF: switch (node->nd_nth) { case '&': result = rb_reg_last_match(MATCH_DATA); break; case '`': result = rb_reg_match_pre(MATCH_DATA); break; case '\'': result = rb_reg_match_post(MATCH_DATA); break; case '+': result = rb_reg_match_last(MATCH_DATA); break; default: rb_bug("unexpected back-ref"); } break; case NODE_HASH: { NODE *list; VALUE hash = rb_hash_new(); VALUE key, val; list = node->nd_head; while (list) { key = rb_eval(self, list->nd_head); list = list->nd_next; if (list == 0) rb_bug("odd number list for Hash"); val = rb_eval(self, list->nd_head); list = list->nd_next; rb_hash_aset(hash, key, val); } result = hash; } break; case NODE_ZARRAY: /* zero length list */ result = rb_ary_new(); break; case NODE_ARRAY: { VALUE ary; long i; i = node->nd_alen; ary = rb_ary_new2(i); for (i=0;node;node=node->nd_next) { RARRAY(ary)->ptr[i++] = rb_eval(self, node->nd_head); RARRAY(ary)->len = i; } result = ary; } break; case NODE_STR: result = rb_str_new3(node->nd_lit); break; case NODE_EVSTR: result = rb_obj_as_string(rb_eval(self, node->nd_body)); break; case NODE_DSTR: case NODE_DXSTR: case NODE_DREGX: case NODE_DREGX_ONCE: case NODE_DSYM: { VALUE str, str2; NODE *list = node->nd_next; str = rb_str_new3(node->nd_lit); while (list) { if (list->nd_head) { switch (nd_type(list->nd_head)) { case NODE_STR: str2 = list->nd_head->nd_lit; break; default: str2 = rb_eval(self, list->nd_head); break; } rb_str_append(str, str2); OBJ_INFECT(str, str2); } list = list->nd_next; } switch (nd_type(node)) { case NODE_DREGX: result = rb_reg_new(RSTRING(str)->ptr, RSTRING(str)->len, node->nd_cflag); break; case NODE_DREGX_ONCE: /* regexp expand once */ result = rb_reg_new(RSTRING(str)->ptr, RSTRING(str)->len, node->nd_cflag); nd_set_type(node, NODE_LIT); node->nd_lit = result; break; case NODE_DXSTR: result = rb_funcall(self, '`', 1, str); break; case NODE_DSYM: result = rb_str_intern(str); break; default: result = str; break; } } break; case NODE_XSTR: result = rb_funcall(self, '`', 1, node->nd_lit); break; case NODE_LIT: result = node->nd_lit; break; case NODE_ATTRSET: if (ruby_frame->argc != 1) rb_raise(rb_eArgError, "wrong number of arguments(%d for 1)", ruby_frame->argc); result = rb_ivar_set(self, node->nd_vid, ruby_frame->argv[0]); break; case NODE_DEFN: if (node->nd_defn) { NODE *body, *defn; VALUE origin; int noex; if (NIL_P(ruby_class)) { rb_raise(rb_eTypeError, "no class/module to add method"); } if (ruby_class == rb_cObject && node->nd_mid == init) { rb_warn("redefining Object#initialize may cause infinite loop"); } if (node->nd_mid == __id__ || node->nd_mid == __send__) { rb_warn("redefining `%s' may cause serious problem", rb_id2name(node->nd_mid)); } rb_frozen_class_p(ruby_class); body = search_method(ruby_class, node->nd_mid, &origin); if (body){ if (RTEST(ruby_verbose) && ruby_class == origin && body->nd_cnt == 0 && body->nd_body) { rb_warning("method redefined; discarding old %s", rb_id2name(node->nd_mid)); } } if (SCOPE_TEST(SCOPE_PRIVATE) || node->nd_mid == init) { noex = NOEX_PRIVATE; } else if (SCOPE_TEST(SCOPE_PROTECTED)) { noex = NOEX_PROTECTED; } else { noex = NOEX_PUBLIC; } if (body && origin == ruby_class && body->nd_body == 0) { noex |= NOEX_NOSUPER; } defn = copy_node_scope(node->nd_defn, ruby_cref); rb_add_method(ruby_class, node->nd_mid, defn, noex); if (scope_vmode == SCOPE_MODFUNC) { rb_add_method(rb_singleton_class(ruby_class), node->nd_mid, defn, NOEX_PUBLIC); } result = Qnil; } break; case NODE_DEFS: if (node->nd_defn) { VALUE recv = rb_eval(self, node->nd_recv); VALUE klass; NODE *body = 0, *defn; if (ruby_safe_level >= 4 && !OBJ_TAINTED(recv)) { rb_raise(rb_eSecurityError, "Insecure: can't define singleton method"); } if (FIXNUM_P(recv) || SYMBOL_P(recv)) { rb_raise(rb_eTypeError, "can't define singleton method \"%s\" for %s", rb_id2name(node->nd_mid), rb_obj_classname(recv)); } if (OBJ_FROZEN(recv)) rb_error_frozen("object"); klass = rb_singleton_class(recv); if (st_lookup(RCLASS(klass)->m_tbl, node->nd_mid, (st_data_t *)&body)) { if (ruby_safe_level >= 4) { rb_raise(rb_eSecurityError, "redefining method prohibited"); } if (RTEST(ruby_verbose)) { rb_warning("redefine %s", rb_id2name(node->nd_mid)); } } defn = copy_node_scope(node->nd_defn, ruby_cref); defn->nd_rval = (VALUE)ruby_cref; rb_add_method(klass, node->nd_mid, defn, NOEX_PUBLIC|(body?body->nd_noex&NOEX_UNDEF:0)); result = Qnil; } break; case NODE_UNDEF: if (NIL_P(ruby_class)) { rb_raise(rb_eTypeError, "no class to undef method"); } rb_undef(ruby_class, node->nd_mid); result = Qnil; break; case NODE_ALIAS: if (NIL_P(ruby_class)) { rb_raise(rb_eTypeError, "no class to make alias"); } rb_alias(ruby_class, node->nd_new, node->nd_old); result = Qnil; break; case NODE_VALIAS: rb_alias_variable(node->nd_new, node->nd_old); result = Qnil; break; case NODE_CLASS: { VALUE super, klass, tmp, cbase; ID cname; if (NIL_P(ruby_cbase)) { rb_raise(rb_eTypeError, "no outer class/module"); } if (node->nd_super) { super = superclass(self, node->nd_super); } else { super = 0; } cbase = class_prefix(self, node->nd_cpath); cname = node->nd_cpath->nd_mid; if (rb_const_defined_at(cbase, cname)) { klass = rb_const_get_at(cbase, cname); if (TYPE(klass) != T_CLASS) { rb_raise(rb_eTypeError, "%s is not a class", rb_id2name(cname)); } if (super) { tmp = rb_class_real(RCLASS(klass)->super); if (tmp != super) { goto override_class; } super = 0; } if (ruby_safe_level >= 4) { rb_raise(rb_eSecurityError, "extending class prohibited"); } } else { override_class: if (!super) super = rb_cObject; klass = rb_define_class_id(cname, super); rb_set_class_path(klass, cbase, rb_id2name(cname)); rb_const_set(cbase, cname, klass); } if (ruby_wrapper) { rb_extend_object(klass, ruby_wrapper); rb_include_module(klass, ruby_wrapper); } if (super) rb_class_inherited(super, klass); result = module_setup(klass, node); } break; case NODE_MODULE: { VALUE module, cbase; ID cname; if (NIL_P(ruby_cbase)) { rb_raise(rb_eTypeError, "no outer class/module"); } cbase = class_prefix(self, node->nd_cpath); cname = node->nd_cpath->nd_mid; if (rb_const_defined_at(cbase, cname)) { module = rb_const_get_at(cbase, cname); if (TYPE(module) != T_MODULE) { rb_raise(rb_eTypeError, "%s is not a module", rb_id2name(cname)); } if (ruby_safe_level >= 4) { rb_raise(rb_eSecurityError, "extending module prohibited"); } } else { module = rb_define_module_id(cname); rb_set_class_path(module, cbase, rb_id2name(cname)); rb_const_set(cbase, cname, module); } if (ruby_wrapper) { rb_extend_object(module, ruby_wrapper); rb_include_module(module, ruby_wrapper); } result = module_setup(module, node); } break; case NODE_SCLASS: { VALUE klass; result = rb_eval(self, node->nd_recv); if (FIXNUM_P(result) || SYMBOL_P(result)) { rb_raise(rb_eTypeError, "no virtual class for %s", rb_obj_classname(result)); } if (ruby_safe_level >= 4 && !OBJ_TAINTED(result)) rb_raise(rb_eSecurityError, "Insecure: can't extend object"); klass = rb_singleton_class(result); if (ruby_wrapper) { rb_extend_object(klass, ruby_wrapper); rb_include_module(klass, ruby_wrapper); } result = module_setup(klass, node); } break; case NODE_DEFINED: { char buf[20]; char *desc = is_defined(self, node->nd_head, buf); if (desc) result = rb_str_new2(desc); else result = Qnil; } break; case NODE_NEWLINE: if (trace_func) { call_trace_func("line", node, self, ruby_frame->last_func, ruby_frame->last_class); } node = node->nd_next; goto again; default: rb_bug("unknown node type %d", nd_type(node)); } finish: CHECK_INTS; if (contnode) { node = contnode; contnode = 0; goto again; } return result; } static VALUE module_setup(module, n) VALUE module; NODE *n; { NODE * volatile node = n->nd_body; int state; struct FRAME frame; VALUE result = Qnil; /* OK */ TMP_PROTECT; frame = *ruby_frame; frame.tmp = ruby_frame; ruby_frame = &frame; PUSH_CLASS(module); PUSH_SCOPE(); PUSH_VARS(); if (node->nd_tbl) { VALUE *vars = TMP_ALLOC(node->nd_tbl[0]+1); *vars++ = (VALUE)node; ruby_scope->local_vars = vars; rb_mem_clear(ruby_scope->local_vars, node->nd_tbl[0]); ruby_scope->local_tbl = node->nd_tbl; } else { ruby_scope->local_vars = 0; ruby_scope->local_tbl = 0; } PUSH_CREF(module); PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { if (trace_func) { call_trace_func("class", n, ruby_cbase, ruby_frame->last_func, ruby_frame->last_class); } result = rb_eval(ruby_cbase, node->nd_next); } POP_TAG(); POP_CREF(); POP_VARS(); POP_SCOPE(); POP_CLASS(); ruby_frame = frame.tmp; if (trace_func) { call_trace_func("end", n, 0, ruby_frame->last_func, ruby_frame->last_class); } if (state) JUMP_TAG(state); return result; } int rb_respond_to(obj, id) VALUE obj; ID id; { if (rb_method_boundp(CLASS_OF(obj), id, 0)) { return Qtrue; } return Qfalse; } static VALUE rb_obj_respond_to(argc, argv, obj) int argc; VALUE *argv; VALUE obj; { VALUE mid, priv; ID id; rb_scan_args(argc, argv, "11", &mid, &priv); id = rb_to_id(mid); if (rb_method_boundp(CLASS_OF(obj), id, !RTEST(priv))) { return Qtrue; } return Qfalse; } static VALUE rb_mod_method_defined(mod, mid) VALUE mod, mid; { return rb_method_boundp(mod, rb_to_id(mid), 1); } #define VISI_CHECK(x,f) (((x)&NOEX_MASK) == (f)) static VALUE rb_mod_public_method_defined(mod, mid) VALUE mod, mid; { ID id = rb_to_id(mid); int noex; if (rb_get_method_body(&mod, &id, &noex)) { if (VISI_CHECK(noex, NOEX_PUBLIC)) return Qtrue; } return Qfalse; } static VALUE rb_mod_private_method_defined(mod, mid) VALUE mod, mid; { ID id = rb_to_id(mid); int noex; if (rb_get_method_body(&mod, &id, &noex)) { if (VISI_CHECK(noex, NOEX_PRIVATE)) return Qtrue; } return Qfalse; } static VALUE rb_mod_protected_method_defined(mod, mid) VALUE mod, mid; { ID id = rb_to_id(mid); int noex; if (rb_get_method_body(&mod, &id, &noex)) { if (VISI_CHECK(noex, NOEX_PROTECTED)) return Qtrue; } return Qfalse; } NORETURN(static VALUE terminate_process _((int, const char *, long))); static VALUE terminate_process(status, mesg, mlen) int status; const char *mesg; long mlen; { VALUE args[2]; args[0] = INT2NUM(status); args[1] = rb_str_new(mesg, mlen); rb_exc_raise(rb_class_new_instance(2, args, rb_eSystemExit)); } void rb_exit(status) int status; { if (prot_tag) { terminate_process(status, "exit", 4); } ruby_finalize(); exit(status); } VALUE rb_f_exit(argc, argv) int argc; VALUE *argv; { VALUE status; int istatus; rb_secure(4); if (rb_scan_args(argc, argv, "01", &status) == 1) { istatus = NUM2INT(status); } else { istatus = 0; } rb_exit(istatus); return Qnil; /* not reached */ } VALUE rb_f_abort(argc, argv) int argc; VALUE *argv; { rb_secure(4); if (argc == 0) { if (!NIL_P(ruby_errinfo)) { error_print(); } rb_exit(1); } else { VALUE mesg; rb_scan_args(argc, argv, "1", &mesg); StringValue(argv[0]); rb_io_puts(argc, argv, rb_stderr); terminate_process(1, RSTRING(argv[0])->ptr, RSTRING(argv[0])->len); } return Qnil; /* not reached */ } void rb_iter_break() { localjump_destination(TAG_BREAK, ruby_scope, Qnil); } NORETURN(static void rb_longjmp _((int, VALUE))); static VALUE make_backtrace _((void)); static void rb_longjmp(tag, mesg) int tag; VALUE mesg; { VALUE at; if (thread_set_raised()) { ruby_errinfo = exception_error; JUMP_TAG(TAG_FATAL); } if (NIL_P(mesg)) mesg = ruby_errinfo; if (NIL_P(mesg)) { mesg = rb_exc_new(rb_eRuntimeError, 0, 0); } ruby_set_current_source(); if (ruby_sourcefile && !NIL_P(mesg)) { at = get_backtrace(mesg); if (NIL_P(at)) { at = make_backtrace(); set_backtrace(mesg, at); } } if (!NIL_P(mesg)) { ruby_errinfo = mesg; } if (RTEST(ruby_debug) && !NIL_P(ruby_errinfo) && !rb_obj_is_kind_of(ruby_errinfo, rb_eSystemExit)) { VALUE e = ruby_errinfo; int status; PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { StringValue(e); warn_printf("Exception `%s' at %s:%d - %s\n", rb_obj_classname(ruby_errinfo), ruby_sourcefile, ruby_sourceline, RSTRING(e)->ptr); } POP_TAG(); if (status) { thread_reset_raised(); JUMP_TAG(status); } } rb_trap_restore_mask(); if (trace_func && tag != TAG_FATAL) { call_trace_func("raise", ruby_current_node, ruby_frame->self, ruby_frame->last_func, ruby_frame->last_class); } if (!prot_tag) { error_print(); } thread_reset_raised(); JUMP_TAG(tag); } void rb_exc_raise(mesg) VALUE mesg; { rb_longjmp(TAG_RAISE, mesg); } void rb_exc_fatal(mesg) VALUE mesg; { rb_longjmp(TAG_FATAL, mesg); } void rb_interrupt() { rb_raise(rb_eInterrupt, ""); } static VALUE rb_f_raise(argc, argv) int argc; VALUE *argv; { VALUE mesg; ID exception; int n; mesg = Qnil; switch (argc) { case 0: mesg = Qnil; break; case 1: if (NIL_P(argv[0])) break; if (TYPE(argv[0]) == T_STRING) { mesg = rb_exc_new3(rb_eRuntimeError, argv[0]); break; } n = 0; goto exception_call; case 2: case 3: n = 1; exception_call: exception = rb_intern("exception"); if (!rb_respond_to(argv[0], exception)) { rb_raise(rb_eTypeError, "exception class/object expected"); } mesg = rb_funcall(argv[0], exception, n, argv[1]); break; default: rb_raise(rb_eArgError, "wrong number of arguments"); break; } if (argc > 0) { if (!rb_obj_is_kind_of(mesg, rb_eException)) rb_raise(rb_eTypeError, "exception object expected"); set_backtrace(mesg, (argc>2)?argv[2]:Qnil); } if (ruby_frame != top_frame) { PUSH_FRAME(); /* fake frame */ *ruby_frame = *_frame.prev->prev; rb_longjmp(TAG_RAISE, mesg); POP_FRAME(); } rb_longjmp(TAG_RAISE, mesg); return Qnil; /* not reached */ } void rb_jump_tag(tag) int tag; { JUMP_TAG(tag); } int rb_block_given_p() { if (ruby_frame->iter == ITER_CUR && ruby_block) return Qtrue; return Qfalse; } int rb_iterator_p() { return rb_block_given_p(); } static VALUE rb_f_block_given_p() { if (ruby_frame->prev && ruby_frame->prev->iter == ITER_CUR && ruby_block) return Qtrue; return Qfalse; } static VALUE rb_eThreadError; static void localjump_destination(state, scope, retval) int state; struct SCOPE *scope; VALUE retval; { struct tag *tt = prot_tag; VALUE tag = (state == TAG_BREAK) ? PROT_ITER : PROT_FUNC; if (retval == Qundef) retval = Qnil; while (tt) { if (tt->tag == PROT_PCALL || (tt->tag == PROT_THREAD && state == TAG_BREAK) || (tt->tag == PROT_CALL || tt->tag == tag) && tt->scope == scope) { tt->dst = (VALUE)scope; tt->retval = retval; JUMP_TAG(state); } if (tt->tag == PROT_FUNC && tt->scope == scope) break; if (tt->tag == PROT_THREAD) { rb_raise(rb_eThreadError, "return jump can't across threads"); } tt = tt->prev; } jump_tag_but_local_jump(state); } static VALUE rb_yield_0(val, self, klass, flags, avalue) VALUE val, self, klass; /* OK */ int flags, avalue; { NODE *node; volatile VALUE result = Qnil; volatile VALUE old_cref; volatile VALUE old_wrapper; struct BLOCK * volatile block; struct SCOPE * volatile old_scope; int old_vmode; struct FRAME frame; NODE *cnode = ruby_current_node; int state; static unsigned serial = 1; if (!rb_block_given_p()) { localjump_error("no block given", Qnil, 0); } PUSH_VARS(); block = ruby_block; frame = block->frame; frame.prev = ruby_frame; ruby_frame = &(frame); old_cref = (VALUE)ruby_cref; ruby_cref = block->cref; old_wrapper = ruby_wrapper; ruby_wrapper = block->wrapper; old_scope = ruby_scope; ruby_scope = block->scope; old_vmode = scope_vmode; scope_vmode = (flags & YIELD_PUBLIC_DEF) ? SCOPE_PUBLIC : block->vmode; ruby_block = block->prev; if (block->flags & BLOCK_D_SCOPE) { /* put place holder for dynamic (in-block) local variables */ ruby_dyna_vars = new_dvar(0, 0, block->dyna_vars); } else { /* FOR does not introduce new scope */ ruby_dyna_vars = block->dyna_vars; } PUSH_CLASS(klass ? klass : block->klass); if (!klass) { self = block->self; } node = block->body; if (block->var) { PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { if (block->var == (NODE*)1) { /* no parameter || */ if ((flags & YIELD_PROC_CALL) && RARRAY(val)->len != 0) { rb_raise(rb_eArgError, "wrong number of arguments (%ld for 0)", RARRAY(val)->len); } } else if (block->var == (NODE*)2) { if (TYPE(val) == T_ARRAY && RARRAY(val)->len != 0) { rb_raise(rb_eArgError, "wrong number of arguments (%ld for 0)", RARRAY(val)->len); } } else if (nd_type(block->var) == NODE_MASGN) { if (!avalue) { val = svalue_to_mrhs(val, block->var->nd_head); } massign(self, block->var, val, flags&YIELD_PROC_CALL); } else { int len = 0; if (avalue) { len = RARRAY(val)->len; if (len == 0) { goto zero_arg; } if (len == 1) { val = RARRAY(val)->ptr[0]; } else { goto multi_values; } } else if (val == Qundef) { zero_arg: val = Qnil; multi_values: { NODE *curr = ruby_current_node; ruby_current_node = block->var; rb_warn("multiple values for a block parameter (%d for 1)\n\tfrom %s:%d", len, curr->nd_file, nd_line(curr)); ruby_current_node = curr; } } assign(self, block->var, val, flags&YIELD_PROC_CALL); } } POP_TAG(); if (state) goto pop_state; } PUSH_ITER(block->iter); PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { redo: if (!node) { result = Qnil; } else if (nd_type(node) == NODE_CFUNC || nd_type(node) == NODE_IFUNC) { if (node->nd_state == YIELD_FUNC_AVALUE) { if (!avalue) { val = svalue_to_avalue(val); } } else { if (avalue) { val = avalue_to_svalue(val); } if (val == Qundef && node->nd_state != YIELD_FUNC_SVALUE) val = Qnil; } result = (*node->nd_cfnc)(val, node->nd_tval, self); } else { result = rb_eval(self, node); } } else { switch (state) { case TAG_REDO: state = 0; CHECK_INTS; goto redo; case TAG_NEXT: state = 0; result = prot_tag->retval; break; default: break; } } POP_TAG(); POP_ITER(); pop_state: POP_CLASS(); if (ruby_dyna_vars && (block->flags & BLOCK_D_SCOPE) && !FL_TEST(ruby_dyna_vars, DVAR_DONT_RECYCLE)) { struct RVarmap *vars = ruby_dyna_vars; if (ruby_dyna_vars->id == 0) { vars = ruby_dyna_vars->next; rb_gc_force_recycle((VALUE)ruby_dyna_vars); while (vars && vars->id != 0 && vars != block->dyna_vars) { struct RVarmap *tmp = vars->next; rb_gc_force_recycle((VALUE)vars); vars = tmp; } } } POP_VARS(); ruby_block = block; ruby_frame = ruby_frame->prev; ruby_cref = (NODE*)old_cref; ruby_wrapper = old_wrapper; if (ruby_scope->flags & SCOPE_DONT_RECYCLE) scope_dup(old_scope); ruby_scope = old_scope; scope_vmode = old_vmode; ruby_current_node = cnode; if (state) JUMP_TAG(state); return result; } VALUE rb_yield(val) VALUE val; { return rb_yield_0(val, 0, 0, Qfalse, Qfalse); } VALUE #ifdef HAVE_STDARG_PROTOTYPES rb_yield_values(int n, ...) #else rb_yield_values(n, va_alist) int n; va_dcl #endif { va_list args; VALUE ary; if (n == 0) { return rb_yield_0(Qundef, 0, 0, Qfalse, Qfalse); } ary = rb_ary_new2(n); va_init_list(args, n); while (n--) { rb_ary_push(ary, va_arg(args, VALUE)); } va_end(args); return rb_yield_0(ary, 0, 0, Qfalse, Qtrue); } VALUE rb_yield_splat(values) VALUE values; { int avalue = Qfalse; if (TYPE(values) == T_ARRAY) { if (RARRAY(values)->len == 0) { values = Qundef; } else { avalue = Qtrue; } } return rb_yield_0(values, 0, 0, Qfalse, avalue); } static VALUE rb_f_loop() { for (;;) { rb_yield_0(Qundef, 0, 0, Qfalse, Qfalse); CHECK_INTS; } return Qnil; /* dummy */ } static VALUE massign(self, node, val, pcall) VALUE self; NODE *node; VALUE val; int pcall; { NODE *list; long i = 0, len; len = RARRAY(val)->len; list = node->nd_head; for (; list && ind_head, RARRAY(val)->ptr[i], pcall); list = list->nd_next; } if (pcall && list) goto arg_error; if (node->nd_args) { if (node->nd_args == (NODE*)-1) { /* no check for mere `*' */ } else if (!list && ind_args, rb_ary_new4(len-i, RARRAY(val)->ptr+i), pcall); } else { assign(self, node->nd_args, rb_ary_new2(0), pcall); } } else if (pcall && i < len) { goto arg_error; } while (list) { i++; assign(self, list->nd_head, Qnil, pcall); list = list->nd_next; } return val; arg_error: while (list) { i++; list = list->nd_next; } rb_raise(rb_eArgError, "wrong number of arguments (%ld for %ld)", len, i); } static void assign(self, lhs, val, pcall) VALUE self; NODE *lhs; VALUE val; int pcall; { ruby_current_node = lhs; if (val == Qundef) { rb_warning("assigning void value"); val = Qnil; } switch (nd_type(lhs)) { case NODE_GASGN: rb_gvar_set(lhs->nd_entry, val); break; case NODE_IASGN: rb_ivar_set(self, lhs->nd_vid, val); break; case NODE_LASGN: if (ruby_scope->local_vars == 0) rb_bug("unexpected local variable assignment"); ruby_scope->local_vars[lhs->nd_cnt] = val; break; case NODE_DASGN: dvar_asgn(lhs->nd_vid, val); break; case NODE_DASGN_CURR: dvar_asgn_curr(lhs->nd_vid, val); break; case NODE_CDECL: if (lhs->nd_vid == 0) { rb_const_set(class_prefix(self, lhs->nd_else), lhs->nd_else->nd_mid, val); } else { rb_const_set(ruby_cbase, lhs->nd_vid, val); } break; case NODE_CVDECL: if (RTEST(ruby_verbose) && FL_TEST(ruby_cbase, FL_SINGLETON)) { rb_warn("declaring singleton class variable"); } rb_cvar_set(cvar_cbase(), lhs->nd_vid, val, Qtrue); break; case NODE_CVASGN: rb_cvar_set(cvar_cbase(), lhs->nd_vid, val, Qfalse); break; case NODE_MASGN: massign(self, lhs, svalue_to_mrhs(val, lhs->nd_head), pcall); break; case NODE_CALL: case NODE_ATTRASGN: { VALUE recv; int scope; if (lhs->nd_recv == (NODE *)1) { recv = self; scope = 1; } else { recv = rb_eval(self, lhs->nd_recv); scope = 0; } if (!lhs->nd_args) { /* attr set */ ruby_current_node = lhs; SET_CURRENT_SOURCE(); rb_call(CLASS_OF(recv), recv, lhs->nd_mid, 1, &val, scope); } else { /* array set */ VALUE args; args = rb_eval(self, lhs->nd_args); rb_ary_push(args, val); ruby_current_node = lhs; SET_CURRENT_SOURCE(); rb_call(CLASS_OF(recv), recv, lhs->nd_mid, RARRAY(args)->len, RARRAY(args)->ptr, scope); } } break; default: rb_bug("bug in variable assignment"); break; } } VALUE rb_iterate(it_proc, data1, bl_proc, data2) VALUE (*it_proc) _((VALUE)), (*bl_proc)(ANYARGS); VALUE data1, data2; { int state; volatile VALUE retval = Qnil; NODE *node = NEW_IFUNC(bl_proc, data2); VALUE self = ruby_top_self; PUSH_ITER(ITER_PRE); PUSH_BLOCK(0, node); PUSH_TAG(PROT_ITER); state = EXEC_TAG(); if (state == 0) { iter_retry: retval = (*it_proc)(data1); } else if (state == TAG_BREAK && TAG_DST()) { retval = prot_tag->retval; state = 0; } else if (state == TAG_RETRY) { state = 0; goto iter_retry; } POP_TAG(); POP_BLOCK(); POP_ITER(); switch (state) { case 0: break; default: JUMP_TAG(state); } return retval; } static int handle_rescue(self, node) VALUE self; NODE *node; { int argc; VALUE *argv; /* used in SETUP_ARGS */ TMP_PROTECT; if (!node->nd_args) { return rb_obj_is_kind_of(ruby_errinfo, rb_eStandardError); } BEGIN_CALLARGS; SETUP_ARGS(node->nd_args); END_CALLARGS; while (argc--) { if (!rb_obj_is_kind_of(argv[0], rb_cModule)) { rb_raise(rb_eTypeError, "class or module required for rescue clause"); } if (RTEST(rb_funcall(*argv, eqq, 1, ruby_errinfo))) return 1; argv++; } return 0; } VALUE #ifdef HAVE_STDARG_PROTOTYPES rb_rescue2(VALUE (*b_proc)(ANYARGS), VALUE data1, VALUE (*r_proc)(ANYARGS), VALUE data2, ...) #else rb_rescue2(b_proc, data1, r_proc, data2, va_alist) VALUE (*b_proc)(ANYARGS), (*r_proc)(ANYARGS); VALUE data1, data2; va_dcl #endif { int state; volatile VALUE result; volatile VALUE e_info = ruby_errinfo; va_list args; PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { retry_entry: result = (*b_proc)(data1); } else if (state == TAG_RAISE) { int handle = Qfalse; VALUE eclass; va_init_list(args, data2); while (eclass = va_arg(args, VALUE)) { if (rb_obj_is_kind_of(ruby_errinfo, eclass)) { handle = Qtrue; break; } } va_end(args); if (handle) { if (r_proc) { PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { result = (*r_proc)(data2, ruby_errinfo); } POP_TAG(); if (state == TAG_RETRY) { state = 0; ruby_errinfo = Qnil; goto retry_entry; } } else { result = Qnil; state = 0; } if (state == 0) { ruby_errinfo = e_info; } } } POP_TAG(); if (state) JUMP_TAG(state); return result; } VALUE rb_rescue(b_proc, data1, r_proc, data2) VALUE (*b_proc)(), (*r_proc)(); VALUE data1, data2; { return rb_rescue2(b_proc, data1, r_proc, data2, rb_eStandardError, (VALUE)0); } VALUE rb_protect(proc, data, state) VALUE (*proc) _((VALUE)); VALUE data; int *state; { VALUE result = Qnil; /* OK */ int status; PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { result = (*proc)(data); } POP_TAG(); if (state) { *state = status; } if (status != 0) { return Qnil; } return result; } VALUE rb_ensure(b_proc, data1, e_proc, data2) VALUE (*b_proc)(); VALUE data1; VALUE (*e_proc)(); VALUE data2; { int state; volatile VALUE result = Qnil; VALUE retval; PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { result = (*b_proc)(data1); } POP_TAG(); retval = prot_tag ? prot_tag->retval : Qnil; /* save retval */ (*e_proc)(data2); if (prot_tag) return_value(retval); if (state) JUMP_TAG(state); return result; } VALUE rb_with_disable_interrupt(proc, data) VALUE (*proc)(); VALUE data; { VALUE result = Qnil; /* OK */ int status; DEFER_INTS; PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { result = (*proc)(data); } POP_TAG(); ALLOW_INTS; if (status) JUMP_TAG(status); return result; } static inline void stack_check() { static int overflowing = 0; if (!overflowing && ruby_stack_check()) { int state; overflowing = 1; PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { rb_exc_raise(sysstack_error); } POP_TAG(); overflowing = 0; JUMP_TAG(state); } } static int last_call_status; #define CSTAT_PRIV 1 #define CSTAT_PROT 2 #define CSTAT_VCALL 4 #define CSTAT_SUPER 8 static VALUE rb_method_missing(argc, argv, obj) int argc; VALUE *argv; VALUE obj; { ID id; VALUE exc = rb_eNoMethodError; volatile VALUE d = 0; char *format = 0; char *desc = ""; NODE *cnode = ruby_current_node; if (argc == 0 || !SYMBOL_P(argv[0])) { rb_raise(rb_eArgError, "no id given"); } stack_check(); id = SYM2ID(argv[0]); switch (TYPE(obj)) { case T_NIL: desc = "nil"; break; case T_TRUE: desc = "true"; break; case T_FALSE: desc = "false"; break; default: if (rb_respond_to(obj, rb_intern("inspect"))) d = rb_inspect(obj); else d = rb_any_to_s(obj); break; } if (d) { if (RSTRING(d)->len > 65) { d = rb_any_to_s(obj); } desc = RSTRING(d)->ptr; } if (last_call_status & CSTAT_PRIV) { format = "private method `%s' called for %s%s%s"; } else if (last_call_status & CSTAT_PROT) { format = "protected method `%s' called for %s%s%s"; } else if (last_call_status & CSTAT_VCALL) { format = "undefined local variable or method `%s' for %s%s%s"; exc = rb_eNameError; } else if (last_call_status & CSTAT_SUPER) { format = "super: no superclass method `%s'"; } if (!format) { format = "undefined method `%s' for %s%s%s"; } ruby_current_node = cnode; { char buf[BUFSIZ]; int noclass = (!desc || desc[0]=='#'); int n = 0; VALUE args[3]; snprintf(buf, BUFSIZ, format, rb_id2name(id), desc, noclass ? "" : ":", noclass ? "" : rb_obj_classname(obj)); args[n++] = rb_str_new2(buf); args[n++] = argv[0]; if (exc == rb_eNoMethodError) { args[n++] = rb_ary_new4(argc-1, argv+1); } exc = rb_class_new_instance(n, args, exc); ruby_frame = ruby_frame->prev; /* pop frame for "method_missing" */ rb_exc_raise(exc); } return Qnil; /* not reached */ } static VALUE method_missing(obj, id, argc, argv, call_status) VALUE obj; ID id; int argc; const VALUE *argv; int call_status; { VALUE *nargv; last_call_status = call_status; if (id == missing) { PUSH_FRAME(); rb_method_missing(argc, argv, obj); POP_FRAME(); } else if (id == ID_ALLOCATOR) { rb_raise(rb_eNoMethodError, "allocator undefined for %s", rb_class2name(obj)); } nargv = ALLOCA_N(VALUE, argc+1); nargv[0] = ID2SYM(id); MEMCPY(nargv+1, argv, VALUE, argc); return rb_funcall2(obj, missing, argc+1, nargv); } static inline VALUE call_cfunc(func, recv, len, argc, argv) VALUE (*func)(); VALUE recv; int len, argc; VALUE *argv; { if (len >= 0 && argc != len) { rb_raise(rb_eArgError, "wrong number of arguments(%d for %d)", argc, len); } switch (len) { case -2: return (*func)(recv, rb_ary_new4(argc, argv)); break; case -1: return (*func)(argc, argv, recv); break; case 0: return (*func)(recv); break; case 1: return (*func)(recv, argv[0]); break; case 2: return (*func)(recv, argv[0], argv[1]); break; case 3: return (*func)(recv, argv[0], argv[1], argv[2]); break; case 4: return (*func)(recv, argv[0], argv[1], argv[2], argv[3]); break; case 5: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4]); break; case 6: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5]); break; case 7: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6]); break; case 8: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7]); break; case 9: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7], argv[8]); break; case 10: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7], argv[8], argv[9]); break; case 11: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7], argv[8], argv[9], argv[10]); break; case 12: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7], argv[8], argv[9], argv[10], argv[11]); break; case 13: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7], argv[8], argv[9], argv[10], argv[11], argv[12]); break; case 14: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7], argv[8], argv[9], argv[10], argv[11], argv[12], argv[13]); break; case 15: return (*func)(recv, argv[0], argv[1], argv[2], argv[3], argv[4], argv[5], argv[6], argv[7], argv[8], argv[9], argv[10], argv[11], argv[12], argv[13], argv[14]); break; default: rb_raise(rb_eArgError, "too many arguments(%d)", len); break; } return Qnil; /* not reached */ } static VALUE rb_call0(klass, recv, id, oid, argc, argv, body, nosuper) VALUE klass, recv; ID id; ID oid; int argc; /* OK */ VALUE *argv; /* OK */ NODE *body; /* OK */ int nosuper; { NODE *b2; /* OK */ volatile VALUE result = Qnil; int itr; static int tick; TMP_PROTECT; switch (ruby_iter->iter) { case ITER_PRE: itr = ITER_CUR; break; case ITER_CUR: default: itr = ITER_NOT; break; } if ((++tick & 0xff) == 0) { CHECK_INTS; /* better than nothing */ stack_check(); } PUSH_ITER(itr); PUSH_FRAME(); ruby_frame->last_func = id; ruby_frame->orig_func = oid; ruby_frame->last_class = nosuper?0:klass; ruby_frame->self = recv; ruby_frame->argc = argc; ruby_frame->argv = argv; switch (nd_type(body)) { case NODE_CFUNC: { int len = body->nd_argc; if (len < -2) { rb_bug("bad argc(%d) specified for `%s(%s)'", len, rb_class2name(klass), rb_id2name(id)); } if (trace_func) { int state; call_trace_func("c-call", ruby_current_node, recv, id, klass); PUSH_TAG(PROT_FUNC); if ((state = EXEC_TAG()) == 0) { result = call_cfunc(body->nd_cfnc, recv, len, argc, argv); } POP_TAG(); ruby_current_node = ruby_frame->node; call_trace_func("c-return", ruby_current_node, recv, id, klass); if (state) JUMP_TAG(state); } else { result = call_cfunc(body->nd_cfnc, recv, len, argc, argv); } } break; /* for attr get/set */ case NODE_IVAR: if (argc != 0) { rb_raise(rb_eArgError, "wrong number of arguments(%d for 0)", argc); } result = rb_attr_get(recv, body->nd_vid); break; case NODE_ATTRSET: /* for re-scoped/renamed method */ case NODE_ZSUPER: result = rb_eval(recv, body); break; case NODE_DMETHOD: result = method_call(argc, argv, umethod_bind(body->nd_cval, recv)); break; case NODE_BMETHOD: result = proc_invoke(body->nd_cval, rb_ary_new4(argc, argv), recv, klass); break; case NODE_SCOPE: { int state; VALUE *local_vars; /* OK */ NODE *saved_cref = 0; PUSH_SCOPE(); if (body->nd_rval) { saved_cref = ruby_cref; ruby_cref = (NODE*)body->nd_rval; } PUSH_CLASS(ruby_cbase); if (body->nd_tbl) { local_vars = TMP_ALLOC(body->nd_tbl[0]+1); *local_vars++ = (VALUE)body; rb_mem_clear(local_vars, body->nd_tbl[0]); ruby_scope->local_tbl = body->nd_tbl; ruby_scope->local_vars = local_vars; } else { local_vars = ruby_scope->local_vars = 0; ruby_scope->local_tbl = 0; } b2 = body = body->nd_next; PUSH_VARS(); PUSH_TAG(PROT_FUNC); if ((state = EXEC_TAG()) == 0) { NODE *node = 0; int i; if (nd_type(body) == NODE_ARGS) { node = body; body = 0; } else if (nd_type(body) == NODE_BLOCK) { node = body->nd_head; body = body->nd_next; } if (node) { if (nd_type(node) != NODE_ARGS) { rb_bug("no argument-node"); } i = node->nd_cnt; if (i > argc) { rb_raise(rb_eArgError, "wrong number of arguments(%d for %d)", argc, i); } if (node->nd_rest == -1) { int opt = i; NODE *optnode = node->nd_opt; while (optnode) { opt++; optnode = optnode->nd_next; } if (opt < argc) { rb_raise(rb_eArgError, "wrong number of arguments(%d for %d)", argc, opt); } ruby_frame->argc = opt; ruby_frame->argv = local_vars+2; } if (local_vars) { if (i > 0) { /* +2 for $_ and $~ */ MEMCPY(local_vars+2, argv, VALUE, i); } argv += i; argc -= i; if (node->nd_opt) { NODE *opt = node->nd_opt; while (opt && argc) { assign(recv, opt->nd_head, *argv, 1); argv++; argc--; opt = opt->nd_next; } if (opt) { rb_eval(recv, opt); } } local_vars = ruby_scope->local_vars; if (node->nd_rest >= 0) { VALUE v; if (argc > 0) v = rb_ary_new4(argc,argv); else v = rb_ary_new2(0); ruby_scope->local_vars[node->nd_rest] = v; } } } if (trace_func) { call_trace_func("call", b2, recv, id, klass); } result = rb_eval(recv, body); } else if (state == TAG_RETURN && TAG_DST()) { result = prot_tag->retval; state = 0; } POP_TAG(); POP_VARS(); POP_CLASS(); POP_SCOPE(); ruby_cref = saved_cref; if (trace_func) { call_trace_func("return", ruby_frame->prev->node, recv, id, klass); } switch (state) { case 0: break; case TAG_BREAK: case TAG_RETURN: JUMP_TAG(state); break; case TAG_RETRY: if (rb_block_given_p()) JUMP_TAG(state); /* fall through */ default: jump_tag_but_local_jump(state); break; } } break; default: rb_bug("unknown node type %d", nd_type(body)); break; } POP_FRAME(); POP_ITER(); return result; } static VALUE rb_call(klass, recv, mid, argc, argv, scope) VALUE klass, recv; ID mid; int argc; /* OK */ const VALUE *argv; /* OK */ int scope; { NODE *body; /* OK */ int noex; ID id = mid; struct cache_entry *ent; if (!klass) { rb_raise(rb_eNotImpError, "method `%s' called on terminated object (0x%lx)", rb_id2name(mid), recv); } /* is it in the method cache? */ ent = cache + EXPR1(klass, mid); if (ent->mid == mid && ent->klass == klass) { if (!ent->method) return method_missing(recv, mid, argc, argv, scope==2?CSTAT_VCALL:0); klass = ent->origin; id = ent->mid0; noex = ent->noex; body = ent->method; } else if ((body = rb_get_method_body(&klass, &id, &noex)) == 0) { if (scope == 3) { return method_missing(recv, mid, argc, argv, CSTAT_SUPER); } return method_missing(recv, mid, argc, argv, scope==2?CSTAT_VCALL:0); } if (mid != missing) { /* receiver specified form for private method */ if ((noex & NOEX_PRIVATE) && scope == 0) return method_missing(recv, mid, argc, argv, CSTAT_PRIV); /* self must be kind of a specified form for protected method */ if ((noex & NOEX_PROTECTED)) { VALUE defined_class = klass; if (TYPE(defined_class) == T_ICLASS) { defined_class = RBASIC(defined_class)->klass; } if (!rb_obj_is_kind_of(ruby_frame->self, rb_class_real(defined_class))) return method_missing(recv, mid, argc, argv, CSTAT_PROT); } } return rb_call0(klass, recv, mid, id, argc, argv, body, noex & NOEX_NOSUPER); } VALUE rb_apply(recv, mid, args) VALUE recv; ID mid; VALUE args; { int argc; VALUE *argv; argc = RARRAY(args)->len; /* Assigns LONG, but argc is INT */ argv = ALLOCA_N(VALUE, argc); MEMCPY(argv, RARRAY(args)->ptr, VALUE, argc); return rb_call(CLASS_OF(recv), recv, mid, argc, argv, 1); } static VALUE rb_f_send(argc, argv, recv) int argc; VALUE *argv; VALUE recv; { VALUE vid; if (argc == 0) rb_raise(rb_eArgError, "no method name given"); vid = *argv++; argc--; PUSH_ITER(rb_block_given_p()?ITER_PRE:ITER_NOT); vid = rb_call(CLASS_OF(recv), recv, rb_to_id(vid), argc, argv, 1); POP_ITER(); return vid; } VALUE #ifdef HAVE_STDARG_PROTOTYPES rb_funcall(VALUE recv, ID mid, int n, ...) #else rb_funcall(recv, mid, n, va_alist) VALUE recv; ID mid; int n; va_dcl #endif { va_list ar; VALUE *argv; if (n > 0) { long i; argv = ALLOCA_N(VALUE, n); va_init_list(ar, n); for (i=0;ilast_class == 0) { rb_name_error(ruby_frame->last_func, "calling `super' from `%s' is prohibited", rb_id2name(ruby_frame->last_func)); } self = ruby_frame->self; klass = ruby_frame->last_class; if (BUILTIN_TYPE(klass) == T_MODULE) { k = CLASS_OF(self); while (!(BUILTIN_TYPE(k) == T_ICLASS && RBASIC(k)->klass == klass)) { k = RCLASS(k)->super; if (!k) { rb_raise(rb_eTypeError, "%s is not included in %s", rb_class2name(klass), rb_class2name(CLASS_OF(self))); } } if (RCLASS(k)->super == 0) { rb_name_error(ruby_frame->last_func, "super: no superclass method `%s'", rb_id2name(ruby_frame->last_func)); } klass = k; } PUSH_ITER(ruby_iter->iter ? ITER_PRE : ITER_NOT); result = rb_call(RCLASS(klass)->super, self, ruby_frame->orig_func, argc, argv, 3); POP_ITER(); return result; } static VALUE backtrace(lev) int lev; { struct FRAME *frame = ruby_frame; char buf[BUFSIZ]; VALUE ary; NODE *n; ary = rb_ary_new(); if (frame->last_func == ID_ALLOCATOR) { frame = frame->prev; } if (lev < 0) { ruby_set_current_source(); if (frame->last_func) { snprintf(buf, BUFSIZ, "%s:%d:in `%s'", ruby_sourcefile, ruby_sourceline, rb_id2name(frame->last_func)); } else if (ruby_sourceline == 0) { snprintf(buf, BUFSIZ, "%s", ruby_sourcefile); } else { snprintf(buf, BUFSIZ, "%s:%d", ruby_sourcefile, ruby_sourceline); } rb_ary_push(ary, rb_str_new2(buf)); } else { while (lev-- > 0) { frame = frame->prev; if (!frame) { ary = Qnil; break; } } } while (frame && (n = frame->node)) { if (frame->prev && frame->prev->last_func) { snprintf(buf, BUFSIZ, "%s:%d:in `%s'", n->nd_file, nd_line(n), rb_id2name(frame->prev->last_func)); } else { snprintf(buf, BUFSIZ, "%s:%d", n->nd_file, nd_line(n)); } rb_ary_push(ary, rb_str_new2(buf)); frame = frame->prev; } return ary; } static VALUE rb_f_caller(argc, argv) int argc; VALUE *argv; { VALUE level; int lev; rb_scan_args(argc, argv, "01", &level); if (NIL_P(level)) lev = 1; else lev = NUM2INT(level); if (lev < 0) rb_raise(rb_eArgError, "negative level(%d)", lev); return backtrace(lev); } void rb_backtrace() { long i; VALUE ary; ary = backtrace(-1); for (i=0; ilen; i++) { printf("\tfrom %s\n", RSTRING(RARRAY(ary)->ptr[i])->ptr); } } static VALUE make_backtrace() { return backtrace(-1); } ID rb_frame_last_func() { return ruby_frame->last_func; } static NODE* compile(src, file, line) VALUE src; char *file; int line; { NODE *node; int critical; ruby_nerrs = 0; StringValue(src); critical = rb_thread_critical; rb_thread_critical = Qtrue; node = rb_compile_string(file, src, line); rb_thread_critical = critical; if (ruby_nerrs == 0) return node; return 0; } static VALUE eval(self, src, scope, file, line) VALUE self, src, scope; char *file; int line; { struct BLOCK *data = NULL; volatile VALUE result = Qnil; struct SCOPE * volatile old_scope; struct BLOCK * volatile old_block; struct RVarmap * volatile old_dyna_vars; VALUE volatile old_cref; int volatile old_vmode; volatile VALUE old_wrapper; struct FRAME frame; NODE *nodesave = ruby_current_node; volatile int iter = ruby_frame->iter; int state; if (!NIL_P(scope)) { if (!rb_obj_is_proc(scope)) { rb_raise(rb_eTypeError, "wrong argument type %s (expected Proc/Binding)", rb_obj_classname(scope)); } Data_Get_Struct(scope, struct BLOCK, data); /* PUSH BLOCK from data */ frame = data->frame; frame.tmp = ruby_frame; /* gc protection */ ruby_frame = &(frame); old_scope = ruby_scope; ruby_scope = data->scope; old_block = ruby_block; ruby_block = data->prev; old_dyna_vars = ruby_dyna_vars; ruby_dyna_vars = data->dyna_vars; old_vmode = scope_vmode; scope_vmode = data->vmode; old_cref = (VALUE)ruby_cref; ruby_cref = data->cref; old_wrapper = ruby_wrapper; ruby_wrapper = data->wrapper; if ((file == 0 || (line == 1 && strcmp(file, "(eval)") == 0)) && data->body) { file = data->body->nd_file; if (!file) file = "__builtin__"; line = nd_line(data->body); } self = data->self; ruby_frame->iter = data->iter; } else { if (ruby_frame->prev) { ruby_frame->iter = ruby_frame->prev->iter; } } if (file == 0) { ruby_set_current_source(); file = ruby_sourcefile; line = ruby_sourceline; } PUSH_CLASS(ruby_cbase); ruby_in_eval++; if (TYPE(ruby_class) == T_ICLASS) { ruby_class = RBASIC(ruby_class)->klass; } PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { NODE *node; result = ruby_errinfo; ruby_errinfo = Qnil; node = compile(src, file, line); if (ruby_nerrs > 0) { compile_error(0); } if (!NIL_P(result)) ruby_errinfo = result; result = eval_node(self, node); } POP_TAG(); POP_CLASS(); ruby_in_eval--; if (!NIL_P(scope)) { int dont_recycle = ruby_scope->flags & SCOPE_DONT_RECYCLE; ruby_wrapper = old_wrapper; ruby_cref = (NODE*)old_cref; ruby_frame = frame.tmp; ruby_scope = old_scope; ruby_block = old_block; ruby_dyna_vars = old_dyna_vars; data->vmode = scope_vmode; /* write back visibility mode */ scope_vmode = old_vmode; if (dont_recycle) { struct tag *tag; struct RVarmap *vars; scope_dup(ruby_scope); for (tag=prot_tag; tag; tag=tag->prev) { scope_dup(tag->scope); } for (vars = ruby_dyna_vars; vars; vars = vars->next) { FL_SET(vars, DVAR_DONT_RECYCLE); } } } else { ruby_frame->iter = iter; } ruby_current_node = nodesave; ruby_set_current_source(); if (state) { if (state == TAG_RAISE) { VALUE err, errat, mesg; mesg = rb_obj_as_string(ruby_errinfo); if (strcmp(file, "(eval)") == 0) { if (ruby_sourceline > 1) { errat = get_backtrace(ruby_errinfo); err = rb_str_dup(RARRAY(errat)->ptr[0]); rb_str_cat2(err, ": "); rb_str_append(err, mesg); } else { err = mesg; } rb_exc_raise(rb_funcall(ruby_errinfo, rb_intern("exception"), 1, err)); } rb_exc_raise(ruby_errinfo); } JUMP_TAG(state); } return result; } static VALUE rb_f_eval(argc, argv, self) int argc; VALUE *argv; VALUE self; { VALUE src, scope, vfile, vline; char *file = "(eval)"; int line = 1; rb_scan_args(argc, argv, "13", &src, &scope, &vfile, &vline); if (ruby_safe_level >= 4) { StringValue(src); if (!NIL_P(scope) && !OBJ_TAINTED(scope)) { rb_raise(rb_eSecurityError, "Insecure: can't modify trusted binding"); } } else { SafeStringValue(src); } if (argc >= 3) { file = StringValuePtr(vfile); } if (argc >= 4) { line = NUM2INT(vline); } if (NIL_P(scope) && ruby_frame->prev) { struct FRAME *prev; VALUE val; prev = ruby_frame; PUSH_FRAME(); *ruby_frame = *prev->prev; ruby_frame->prev = prev; val = eval(self, src, scope, file, line); POP_FRAME(); return val; } return eval(self, src, scope, file, line); } /* function to call func under the specified class/module context */ static VALUE exec_under(func, under, cbase, args) VALUE (*func)(); VALUE under, cbase; void *args; { VALUE val = Qnil; /* OK */ int state; int mode; PUSH_CLASS(under); PUSH_FRAME(); ruby_frame->self = _frame.prev->self; ruby_frame->last_func = _frame.prev->last_func; ruby_frame->last_class = _frame.prev->last_class; ruby_frame->argc = _frame.prev->argc; ruby_frame->argv = _frame.prev->argv; if (cbase) { PUSH_CREF(cbase); } mode = scope_vmode; SCOPE_SET(SCOPE_PUBLIC); PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { val = (*func)(args); } POP_TAG(); if (cbase) POP_CREF(); SCOPE_SET(mode); POP_FRAME(); POP_CLASS(); if (state) JUMP_TAG(state); return val; } static VALUE eval_under_i(args) VALUE *args; { return eval(args[0], args[1], Qnil, (char*)args[2], (int)args[3]); } /* string eval under the class/module context */ static VALUE eval_under(under, self, src, file, line) VALUE under, self, src; const char *file; int line; { VALUE args[4]; if (ruby_safe_level >= 4) { StringValue(src); } else { SafeStringValue(src); } args[0] = self; args[1] = src; args[2] = (VALUE)file; args[3] = (VALUE)line; return exec_under(eval_under_i, under, under, args); } static VALUE yield_under_i(self) VALUE self; { return rb_yield_0(self, self, ruby_class, YIELD_PUBLIC_DEF, Qfalse); } /* block eval under the class/module context */ static VALUE yield_under(under, self) VALUE under, self; { return exec_under(yield_under_i, under, 0, self); } static VALUE specific_eval(argc, argv, klass, self) int argc; VALUE *argv; VALUE klass, self; { if (rb_block_given_p()) { if (argc > 0) { rb_raise(rb_eArgError, "wrong number of arguments (%d for 0)", argc); } return yield_under(klass, self); } else { char *file = "(eval)"; int line = 1; if (argc == 0) { rb_raise(rb_eArgError, "block not supplied"); } else { if (ruby_safe_level >= 4) { StringValue(argv[0]); } else { SafeStringValue(argv[0]); } if (argc > 3) { rb_raise(rb_eArgError, "wrong number of arguments: %s(src) or %s{..}", rb_id2name(ruby_frame->last_func), rb_id2name(ruby_frame->last_func)); } if (argc > 1) { file = StringValuePtr(argv[1]); } if (argc > 2) line = NUM2INT(argv[2]); } return eval_under(klass, self, argv[0], file, line); } } VALUE rb_obj_instance_eval(argc, argv, self) int argc; VALUE *argv; VALUE self; { VALUE klass; if (rb_special_const_p(self)) { klass = Qnil; } else { klass = rb_singleton_class(self); } return specific_eval(argc, argv, klass, self); } VALUE rb_mod_module_eval(argc, argv, mod) int argc; VALUE *argv; VALUE mod; { return specific_eval(argc, argv, mod, mod); } VALUE rb_load_path; void rb_load(fname, wrap) VALUE fname; int wrap; { VALUE tmp; int state; volatile ID last_func; volatile VALUE wrapper = 0; volatile VALUE self = ruby_top_self; NODE *volatile last_node; NODE *saved_cref = ruby_cref; TMP_PROTECT; if (wrap && ruby_safe_level >= 4) { StringValue(fname); } else { SafeStringValue(fname); } tmp = rb_find_file(fname); if (!tmp) { rb_raise(rb_eLoadError, "No such file to load -- %s", RSTRING(fname)->ptr); } fname = tmp; ruby_errinfo = Qnil; /* ensure */ PUSH_VARS(); PUSH_CLASS(ruby_wrapper); ruby_cref = top_cref; if (!wrap) { rb_secure(4); /* should alter global state */ ruby_class = rb_cObject; ruby_wrapper = 0; } else { /* load in anonymous module as toplevel */ ruby_class = ruby_wrapper = rb_module_new(); self = rb_obj_clone(ruby_top_self); rb_extend_object(self, ruby_wrapper); PUSH_CREF(ruby_wrapper); } PUSH_ITER(ITER_NOT); PUSH_FRAME(); ruby_frame->last_func = 0; ruby_frame->last_class = 0; ruby_frame->self = self; PUSH_SCOPE(); /* default visibility is private at loading toplevel */ SCOPE_SET(SCOPE_PRIVATE); PUSH_TAG(PROT_NONE); state = EXEC_TAG(); last_func = ruby_frame->last_func; last_node = ruby_current_node; if (!ruby_current_node && ruby_sourcefile) { last_node = NEW_NEWLINE(0); } ruby_current_node = 0; if (state == 0) { NODE *node; volatile int critical; DEFER_INTS; ruby_in_eval++; critical = rb_thread_critical; rb_thread_critical = Qtrue; rb_load_file(RSTRING(fname)->ptr); ruby_in_eval--; node = ruby_eval_tree; rb_thread_critical = critical; if (ruby_nerrs == 0) { eval_node(self, node); } } ALLOW_INTS; ruby_frame->last_func = last_func; ruby_current_node = last_node; ruby_sourcefile = 0; ruby_set_current_source(); if (ruby_scope->flags == SCOPE_ALLOCA && ruby_class == rb_cObject) { if (ruby_scope->local_tbl) /* toplevel was empty */ free(ruby_scope->local_tbl); } POP_TAG(); ruby_cref = saved_cref; POP_SCOPE(); POP_FRAME(); POP_ITER(); POP_CLASS(); POP_VARS(); ruby_wrapper = wrapper; if (ruby_nerrs > 0) { ruby_nerrs = 0; rb_exc_raise(ruby_errinfo); } if (state) jump_tag_but_local_jump(state); if (!NIL_P(ruby_errinfo)) /* exception during load */ rb_exc_raise(ruby_errinfo); } void rb_load_protect(fname, wrap, state) VALUE fname; int wrap; int *state; { int status; PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { rb_load(fname, wrap); } POP_TAG(); if (state) *state = status; } static VALUE rb_f_load(argc, argv) int argc; VALUE *argv; { VALUE fname, wrap; rb_scan_args(argc, argv, "11", &fname, &wrap); rb_load(fname, RTEST(wrap)); return Qtrue; } VALUE ruby_dln_librefs; static VALUE rb_features; static st_table *loading_tbl; static int rb_feature_p(feature, wait) const char *feature; int wait; { VALUE v; char *f; long i, len = strlen(feature); for (i = 0; i < RARRAY(rb_features)->len; ++i) { v = RARRAY(rb_features)->ptr[i]; f = StringValuePtr(v); if (strcmp(f, feature) == 0) { goto load_wait; } if (strncmp(f, feature, len) == 0) { if (strcmp(f+len, ".so") == 0) { return Qtrue; } if (strcmp(f+len, ".rb") == 0) { if (wait) goto load_wait; return Qtrue; } } } return Qfalse; load_wait: if (loading_tbl) { char *ext = strrchr(f, '.'); if (ext && strcmp(ext, ".rb") == 0) { rb_thread_t th; while (st_lookup(loading_tbl, (st_data_t)f, (st_data_t *)&th)) { if (th == curr_thread) { return Qtrue; } CHECK_INTS; rb_thread_schedule(); } } } return Qtrue; } static const char *const loadable_ext[] = { ".rb", DLEXT, #ifdef DLEXT2 DLEXT2, #endif 0 }; int rb_provided(feature) const char *feature; { VALUE f = rb_str_new2(feature); if (strrchr(feature, '.') == 0) { if (rb_find_file_ext(&f, loadable_ext) == 0) { return rb_feature_p(feature, Qfalse); } } return rb_feature_p(RSTRING(f)->ptr, Qfalse); } static void rb_provide_feature(feature) VALUE feature; { rb_ary_push(rb_features, feature); } void rb_provide(feature) const char *feature; { rb_provide_feature(rb_str_new2(feature)); } NORETURN(static void load_failed _((VALUE))); static VALUE load_dyna _((VALUE, VALUE)); static VALUE load_rb _((VALUE, VALUE)); VALUE rb_f_require(obj, fname) VALUE obj, fname; { VALUE feature, tmp; char *ext; /* OK */ if (OBJ_TAINTED(fname)) { rb_check_safe_obj(fname); } StringValue(fname); ext = strrchr(RSTRING(fname)->ptr, '.'); if (ext && strchr(ext, '/')) ext = 0; if (ext) { if (strcmp(".rb", ext) == 0) { feature = rb_str_dup(fname); tmp = rb_find_file(fname); if (tmp) { return load_rb(feature, tmp); } load_failed(fname); } else if (strcmp(".so", ext) == 0 || strcmp(".o", ext) == 0) { tmp = rb_str_new(RSTRING(fname)->ptr, ext-RSTRING(fname)->ptr); #ifdef DLEXT2 if (rb_find_file_ext(&tmp, loadable_ext+1)) { return load_dyna(tmp, rb_find_file(tmp)); } #else feature = tmp; rb_str_cat2(tmp, DLEXT); tmp = rb_find_file(tmp); if (tmp) { return load_dyna(feature, tmp); } #endif } else if (strcmp(DLEXT, ext) == 0) { tmp = rb_find_file(fname); if (tmp) { return load_dyna(fname, tmp); } } #ifdef DLEXT2 else if (strcmp(DLEXT2, ext) == 0) { tmp = rb_find_file(fname); if (tmp) { return load_dyna(fname, tmp); } } #endif } tmp = fname; switch (rb_find_file_ext(&tmp, loadable_ext)) { case 0: break; case 1: return load_rb(tmp, tmp); default: return load_dyna(tmp, rb_find_file(tmp)); } if (!rb_feature_p(RSTRING(fname)->ptr, Qfalse)) load_failed(fname); return Qfalse; } static void load_failed(fname) VALUE fname; { rb_raise(rb_eLoadError, "No such file to load -- %s", RSTRING(fname)->ptr); } static VALUE load_dyna(feature, fname) VALUE feature, fname; { int state; volatile int safe = ruby_safe_level; if (rb_feature_p(RSTRING(feature)->ptr, Qfalse)) return Qfalse; rb_provide_feature(feature); { volatile int old_vmode = scope_vmode; NODE *const volatile old_node = ruby_current_node; const volatile ID old_func = ruby_frame->last_func; ruby_safe_level = 0; ruby_current_node = 0; ruby_sourcefile = rb_source_filename(RSTRING(fname)->ptr); ruby_sourceline = 0; ruby_frame->last_func = 0; PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { void *handle; SCOPE_SET(SCOPE_PUBLIC); handle = dln_load(RSTRING(fname)->ptr); rb_ary_push(ruby_dln_librefs, LONG2NUM((long)handle)); } POP_TAG(); ruby_current_node = old_node; ruby_set_current_source(); ruby_frame->last_func = old_func; SCOPE_SET(old_vmode); } ruby_safe_level = safe; if (state) JUMP_TAG(state); ruby_errinfo = Qnil; return Qtrue; } static VALUE load_rb(feature, fname) VALUE feature, fname; { int state; char *ftptr; volatile int safe = ruby_safe_level; if (rb_feature_p(RSTRING(feature)->ptr, Qtrue)) return Qfalse; ruby_safe_level = 0; rb_provide_feature(feature); /* loading ruby library should be serialized. */ if (!loading_tbl) { loading_tbl = st_init_strtable(); } /* partial state */ ftptr = ruby_strdup(RSTRING(feature)->ptr); st_insert(loading_tbl, (st_data_t)ftptr, (st_data_t)curr_thread); PUSH_TAG(PROT_NONE); if ((state = EXEC_TAG()) == 0) { rb_load(fname, 0); } POP_TAG(); st_delete(loading_tbl, (st_data_t *)&ftptr, 0); /* loading done */ free(ftptr); ruby_safe_level = safe; if (state) JUMP_TAG(state); return Qtrue; } VALUE rb_require(fname) const char *fname; { return rb_f_require(Qnil, rb_str_new2(fname)); } static void secure_visibility(self) VALUE self; { if (ruby_safe_level >= 4 && !OBJ_TAINTED(self)) { rb_raise(rb_eSecurityError, "Insecure: can't change method visibility"); } } static void set_method_visibility(self, argc, argv, ex) VALUE self; int argc; VALUE *argv; ID ex; { int i; secure_visibility(self); for (i=0; ind_body == 0) { rb_bug("undefined method `%s'; can't happen", rb_id2name(id)); } if (nd_type(body->nd_body) != NODE_ZSUPER) { break; /* normal case: need not to follow 'super' link */ } m = RCLASS(m)->super; } rb_add_method(rb_singleton_class(module), id, body->nd_body, NOEX_PUBLIC); } return module; } static VALUE rb_mod_append_features(module, include) VALUE module, include; { switch (TYPE(include)) { case T_CLASS: case T_MODULE: break; default: Check_Type(include, T_CLASS); break; } rb_include_module(include, module); return module; } static VALUE rb_mod_include(argc, argv, module) int argc; VALUE *argv; VALUE module; { while (argc--) { VALUE m = argv[argc]; Check_Type(m, T_MODULE); rb_funcall(m, rb_intern("append_features"), 1, module); rb_funcall(m, rb_intern("included"), 1, module); } return module; } void rb_obj_call_init(obj, argc, argv) VALUE obj; int argc; VALUE *argv; { PUSH_ITER(rb_block_given_p()?ITER_PRE:ITER_NOT); rb_funcall2(obj, init, argc, argv); POP_ITER(); } void rb_extend_object(obj, module) VALUE obj, module; { rb_include_module(rb_singleton_class(obj), module); } static VALUE rb_mod_extend_object(mod, obj) VALUE mod, obj; { rb_extend_object(obj, mod); return obj; } static VALUE rb_obj_extend(argc, argv, obj) int argc; VALUE *argv; VALUE obj; { int i; if (argc == 0) { rb_raise(rb_eArgError, "wrong number of arguments(0 for 1)"); } for (i=0; ilocal_tbl; if (tbl) { n = *tbl++; for (i=2; iid && rb_is_local_id(vars->id)) { /* skip $_, $~ and flip states */ rb_ary_push(ary, rb_str_new2(rb_id2name(vars->id))); } vars = vars->next; } return ary; } static VALUE rb_f_catch _((VALUE,VALUE)); NORETURN(static VALUE rb_f_throw _((int,VALUE*))); struct end_proc_data { void (*func)(); VALUE data; struct end_proc_data *next; }; static struct end_proc_data *end_procs, *ephemeral_end_procs; void rb_set_end_proc(func, data) void (*func) _((VALUE)); VALUE data; { struct end_proc_data *link = ALLOC(struct end_proc_data); struct end_proc_data **list; if (ruby_wrapper) list = &ephemeral_end_procs; else list = &end_procs; link->next = *list; link->func = func; link->data = data; *list = link; } void rb_mark_end_proc() { struct end_proc_data *link; link = end_procs; while (link) { rb_gc_mark(link->data); link = link->next; } link = ephemeral_end_procs; while (link) { rb_gc_mark(link->data); link = link->next; } } static void call_end_proc _((VALUE data)); static void call_end_proc(data) VALUE data; { PUSH_ITER(ITER_NOT); PUSH_FRAME(); ruby_frame->self = ruby_frame->prev->self; ruby_frame->last_func = 0; ruby_frame->last_class = 0; proc_invoke(data, rb_ary_new2(0), Qundef, 0); POP_FRAME(); POP_ITER(); } static void rb_f_END() { PUSH_FRAME(); ruby_frame->argc = 0; rb_set_end_proc(call_end_proc, rb_block_proc()); POP_FRAME(); } static VALUE rb_f_at_exit() { VALUE proc; if (!rb_block_given_p()) { rb_raise(rb_eArgError, "called without a block"); } proc = rb_block_proc(); rb_set_end_proc(call_end_proc, proc); return proc; } void rb_exec_end_proc() { struct end_proc_data *link, *save; int status; save = link = end_procs; while (link) { PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { (*link->func)(link->data); } POP_TAG(); if (status) { error_handle(status); } link = link->next; } link = end_procs; while (link != save) { PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { (*link->func)(link->data); } POP_TAG(); if (status) { error_handle(status); } link = link->next; } while (ephemeral_end_procs) { link = ephemeral_end_procs; ephemeral_end_procs = link->next; PUSH_TAG(PROT_NONE); if ((status = EXEC_TAG()) == 0) { (*link->func)(link->data); } POP_TAG(); if (status) { error_handle(status); } free(link); } } void Init_eval() { init = rb_intern("initialize"); eqq = rb_intern("==="); each = rb_intern("each"); aref = rb_intern("[]"); aset = rb_intern("[]="); match = rb_intern("=~"); missing = rb_intern("method_missing"); added = rb_intern("method_added"); singleton_added = rb_intern("singleton_method_added"); removed = rb_intern("method_removed"); singleton_removed = rb_intern("singleton_method_removed"); undefined = rb_intern("method_undefined"); singleton_undefined = rb_intern("singleton_method_undefined"); __id__ = rb_intern("__id__"); __send__ = rb_intern("__send__"); rb_global_variable((VALUE*)&top_scope); rb_global_variable((VALUE*)&ruby_eval_tree_begin); rb_global_variable((VALUE*)&ruby_eval_tree); rb_global_variable((VALUE*)&ruby_dyna_vars); rb_define_virtual_variable("$@", errat_getter, errat_setter); rb_define_hooked_variable("$!", &ruby_errinfo, 0, errinfo_setter); rb_define_global_function("eval", rb_f_eval, -1); rb_define_global_function("iterator?", rb_f_block_given_p, 0); rb_define_global_function("block_given?", rb_f_block_given_p, 0); rb_define_global_function("method_missing", rb_method_missing, -1); rb_define_global_function("loop", rb_f_loop, 0); rb_define_method(rb_mKernel, "respond_to?", rb_obj_respond_to, -1); rb_define_global_function("raise", rb_f_raise, -1); rb_define_global_function("fail", rb_f_raise, -1); rb_define_global_function("caller", rb_f_caller, -1); rb_define_global_function("exit", rb_f_exit, -1); rb_define_global_function("abort", rb_f_abort, -1); rb_define_global_function("at_exit", rb_f_at_exit, 0); rb_define_global_function("catch", rb_f_catch, 1); rb_define_global_function("throw", rb_f_throw, -1); rb_define_global_function("global_variables", rb_f_global_variables, 0); rb_define_global_function("local_variables", rb_f_local_variables, 0); rb_define_method(rb_mKernel, "send", rb_f_send, -1); rb_define_method(rb_mKernel, "__send__", rb_f_send, -1); rb_define_method(rb_mKernel, "instance_eval", rb_obj_instance_eval, -1); rb_define_private_method(rb_cModule, "append_features", rb_mod_append_features, 1); rb_define_private_method(rb_cModule, "extend_object", rb_mod_extend_object, 1); rb_define_private_method(rb_cModule, "include", rb_mod_include, -1); rb_define_private_method(rb_cModule, "public", rb_mod_public, -1); rb_define_private_method(rb_cModule, "protected", rb_mod_protected, -1); rb_define_private_method(rb_cModule, "private", rb_mod_private, -1); rb_define_private_method(rb_cModule, "module_function", rb_mod_modfunc, -1); rb_define_method(rb_cModule, "method_defined?", rb_mod_method_defined, 1); rb_define_method(rb_cModule, "public_method_defined?", rb_mod_public_method_defined, 1); rb_define_method(rb_cModule, "private_method_defined?", rb_mod_private_method_defined, 1); rb_define_method(rb_cModule, "protected_method_defined?", rb_mod_protected_method_defined, 1); rb_define_method(rb_cModule, "public_class_method", rb_mod_public_method, -1); rb_define_method(rb_cModule, "private_class_method", rb_mod_private_method, -1); rb_define_method(rb_cModule, "module_eval", rb_mod_module_eval, -1); rb_define_method(rb_cModule, "class_eval", rb_mod_module_eval, -1); rb_undef_method(rb_cClass, "module_function"); rb_define_private_method(rb_cModule, "remove_method", rb_mod_remove_method, -1); rb_define_private_method(rb_cModule, "undef_method", rb_mod_undef_method, -1); rb_define_private_method(rb_cModule, "alias_method", rb_mod_alias_method, 2); rb_define_private_method(rb_cModule, "define_method", rb_mod_define_method, -1); rb_define_singleton_method(rb_cModule, "nesting", rb_mod_nesting, 0); rb_define_singleton_method(rb_cModule, "constants", rb_mod_s_constants, 0); rb_define_singleton_method(ruby_top_self, "include", top_include, -1); rb_define_singleton_method(ruby_top_self, "public", top_public, -1); rb_define_singleton_method(ruby_top_self, "private", top_private, -1); rb_define_method(rb_mKernel, "extend", rb_obj_extend, -1); rb_define_global_function("trace_var", rb_f_trace_var, -1); rb_define_global_function("untrace_var", rb_f_untrace_var, -1); rb_define_global_function("set_trace_func", set_trace_func, 1); rb_global_variable(&trace_func); rb_define_virtual_variable("$SAFE", safe_getter, safe_setter); } static VALUE rb_mod_autoload(mod, sym, file) VALUE mod; VALUE sym; VALUE file; { ID id = rb_to_id(sym); Check_SafeStr(file); rb_autoload(mod, id, RSTRING(file)->ptr); return Qnil; } static VALUE rb_mod_autoload_p(mod, sym) VALUE mod, sym; { return rb_autoload_p(mod, rb_to_id(sym)); } static VALUE rb_f_autoload(obj, sym, file) VALUE obj; VALUE sym; VALUE file; { return rb_mod_autoload(ruby_cbase, sym, file); } static VALUE rb_f_autoload_p(obj, sym) VALUE obj; VALUE sym; { /* use ruby_cbase as same as rb_f_autoload. */ return rb_mod_autoload_p(ruby_cbase, sym); } void Init_load() { rb_load_path = rb_ary_new(); rb_define_readonly_variable("$:", &rb_load_path); rb_define_readonly_variable("$-I", &rb_load_path); rb_define_readonly_variable("$LOAD_PATH", &rb_load_path); rb_features = rb_ary_new(); rb_define_readonly_variable("$\"", &rb_features); rb_define_global_function("load", rb_f_load, -1); rb_define_global_function("require", rb_f_require, 1); rb_define_method(rb_cModule, "autoload", rb_mod_autoload, 2); rb_define_method(rb_cModule, "autoload?", rb_mod_autoload_p, 1); rb_define_global_function("autoload", rb_f_autoload, 2); rb_define_global_function("autoload?", rb_f_autoload_p, 1); rb_global_variable(&ruby_wrapper); ruby_dln_librefs = rb_ary_new(); rb_global_variable(&ruby_dln_librefs); } static void scope_dup(scope) struct SCOPE *scope; { ID *tbl; VALUE *vars; scope->flags |= SCOPE_DONT_RECYCLE; if (scope->flags & SCOPE_MALLOC) return; if (scope->local_tbl) { tbl = scope->local_tbl; vars = ALLOC_N(VALUE, tbl[0]+1); *vars++ = scope->local_vars[-1]; MEMCPY(vars, scope->local_vars, VALUE, tbl[0]); scope->local_vars = vars; scope->flags |= SCOPE_MALLOC; } } static void blk_mark(data) struct BLOCK *data; { while (data) { rb_gc_mark_frame(&data->frame); rb_gc_mark((VALUE)data->scope); rb_gc_mark((VALUE)data->var); rb_gc_mark((VALUE)data->body); rb_gc_mark((VALUE)data->self); rb_gc_mark((VALUE)data->dyna_vars); rb_gc_mark((VALUE)data->cref); rb_gc_mark(data->wrapper); rb_gc_mark(data->block_obj); data = data->prev; } } static void blk_free(data) struct BLOCK *data; { struct FRAME *frame; void *tmp; frame = data->frame.prev; while (frame) { if (frame->argc > 0 && (frame->flags & FRAME_MALLOC)) free(frame->argv); tmp = frame; frame = frame->prev; free(tmp); } while (data) { if (data->frame.argc > 0) free(data->frame.argv); tmp = data; data = data->prev; free(tmp); } } static void blk_copy_prev(block) struct BLOCK *block; { struct BLOCK *tmp; struct RVarmap* vars; while (block->prev) { tmp = ALLOC_N(struct BLOCK, 1); MEMCPY(tmp, block->prev, struct BLOCK, 1); if (tmp->frame.argc > 0) { tmp->frame.argv = ALLOC_N(VALUE, tmp->frame.argc); MEMCPY(tmp->frame.argv, block->prev->frame.argv, VALUE, tmp->frame.argc); tmp->frame.flags |= FRAME_MALLOC; } scope_dup(tmp->scope); for (vars = tmp->dyna_vars; vars; vars = vars->next) { if (FL_TEST(vars, DVAR_DONT_RECYCLE)) break; FL_SET(vars, DVAR_DONT_RECYCLE); } block->prev = tmp; block = tmp; } } static void frame_dup(frame) struct FRAME *frame; { VALUE *argv; struct FRAME *tmp; for (;;) { if (frame->argc > 0) { argv = ALLOC_N(VALUE, frame->argc); MEMCPY(argv, frame->argv, VALUE, frame->argc); frame->argv = argv; frame->flags |= FRAME_MALLOC; } frame->tmp = 0; /* should not preserve tmp */ if (!frame->prev) break; tmp = ALLOC(struct FRAME); *tmp = *frame->prev; frame->prev = tmp; frame = tmp; } } static VALUE proc_clone(self) VALUE self; { struct BLOCK *orig, *data; VALUE bind; Data_Get_Struct(self, struct BLOCK, orig); bind = Data_Make_Struct(rb_obj_class(self),struct BLOCK,blk_mark,blk_free,data); CLONESETUP(bind, self); MEMCPY(data, orig, struct BLOCK, 1); frame_dup(&data->frame); if (data->iter) { blk_copy_prev(data); } else { data->prev = 0; } return bind; } static VALUE rb_f_binding(self) VALUE self; { struct BLOCK *data, *p; struct RVarmap *vars; VALUE bind; PUSH_BLOCK(0,0); bind = Data_Make_Struct(rb_cBinding,struct BLOCK,blk_mark,blk_free,data); *data = *ruby_block; data->orig_thread = rb_thread_current(); data->wrapper = ruby_wrapper; data->iter = rb_f_block_given_p(); frame_dup(&data->frame); if (ruby_frame->prev) { data->frame.last_func = ruby_frame->prev->last_func; data->frame.last_class = ruby_frame->prev->last_class; } if (data->iter) { blk_copy_prev(data); } else { data->prev = 0; } for (p = data; p; p = p->prev) { for (vars = p->dyna_vars; vars; vars = vars->next) { if (FL_TEST(vars, DVAR_DONT_RECYCLE)) break; FL_SET(vars, DVAR_DONT_RECYCLE); } } scope_dup(data->scope); POP_BLOCK(); return bind; } #define PROC_T3 FL_USER1 #define PROC_T4 FL_USER2 #define PROC_TMAX (FL_USER1|FL_USER2) #define PROC_TMASK (FL_USER1|FL_USER2) static void proc_save_safe_level(data) VALUE data; { if (OBJ_TAINTED(data)) { switch (ruby_safe_level) { case 3: FL_SET(data, PROC_T3); break; case 4: FL_SET(data, PROC_T4); break; default: if (ruby_safe_level > 4) { FL_SET(data, PROC_TMAX); } break; } } } static int proc_get_safe_level(data) VALUE data; { if (OBJ_TAINTED(data)) { switch (RBASIC(data)->flags & PROC_TMASK) { case PROC_T3: return 3; case PROC_T4: return 4; case PROC_TMAX: return 5; } return 3; } return 0; } static void proc_set_safe_level(data) VALUE data; { if (OBJ_TAINTED(data)) { ruby_safe_level = proc_get_safe_level(data); } } static VALUE proc_alloc(klass, proc) VALUE klass; int proc; { volatile VALUE block; struct BLOCK *data, *p; struct RVarmap *vars; if (!rb_block_given_p() && !rb_f_block_given_p()) { rb_raise(rb_eArgError, "tried to create Proc object without a block"); } if (proc && !rb_block_given_p()) { rb_warn("tried to create Proc object without a block"); } if (!proc && ruby_block->block_obj) { return ruby_block->block_obj; } block = Data_Make_Struct(klass, struct BLOCK, blk_mark, blk_free, data); *data = *ruby_block; data->orig_thread = rb_thread_current(); data->wrapper = ruby_wrapper; data->iter = data->prev?Qtrue:Qfalse; frame_dup(&data->frame); if (data->iter) { blk_copy_prev(data); } else { data->prev = 0; } for (p = data; p; p = p->prev) { for (vars = p->dyna_vars; vars; vars = vars->next) { if (FL_TEST(vars, DVAR_DONT_RECYCLE)) break; FL_SET(vars, DVAR_DONT_RECYCLE); } } scope_dup(data->scope); proc_save_safe_level(block); if (proc) { data->flags |= BLOCK_LAMBDA; } else { ruby_block->block_obj = block; } return block; } static VALUE proc_s_new(argc, argv, klass) int argc; VALUE *argv; VALUE klass; { VALUE block = proc_alloc(klass, Qfalse); rb_obj_call_init(block, argc, argv); return block; } VALUE rb_block_proc() { return proc_alloc(rb_cProc, Qfalse); } VALUE rb_f_lambda() { rb_warn("rb_f_lambda() is deprecated; use rb_block_proc() instead"); return proc_alloc(rb_cProc, Qtrue); } static VALUE proc_lambda() { return proc_alloc(rb_cProc, Qtrue); } static int block_orphan(data) struct BLOCK *data; { if (data->scope->flags & SCOPE_NOSTACK) { return 1; } if (data->orig_thread != rb_thread_current()) { return 1; } return 0; } static VALUE proc_invoke(proc, args, self, klass) VALUE proc, args; /* OK */ VALUE self, klass; { struct BLOCK * volatile old_block; struct BLOCK _block; struct BLOCK *data; volatile VALUE result = Qundef; int state; volatile int orphan; volatile int safe = ruby_safe_level; volatile VALUE old_wrapper = ruby_wrapper; struct RVarmap * volatile old_dvars = ruby_dyna_vars; volatile int pcall; if (rb_block_given_p() && ruby_frame->last_func) { rb_warning("block for %s#%s is useless", rb_obj_classname(proc), rb_id2name(ruby_frame->last_func)); } Data_Get_Struct(proc, struct BLOCK, data); orphan = block_orphan(data); pcall = data->flags & BLOCK_LAMBDA ? YIELD_PROC_CALL : 0; ruby_wrapper = data->wrapper; ruby_dyna_vars = data->dyna_vars; /* PUSH BLOCK from data */ old_block = ruby_block; _block = *data; if (self != Qundef) _block.frame.self = self; if (klass) _block.frame.last_class = klass; ruby_block = &_block; PUSH_ITER(ITER_CUR); ruby_frame->iter = ITER_CUR; PUSH_TAG((pcall || orphan) ? PROT_PCALL : PROT_CALL); state = EXEC_TAG(); if (state == 0) { proc_set_safe_level(proc); result = rb_yield_0(args, self, self!=Qundef?CLASS_OF(self):0, pcall, Qtrue); } else if (pcall || orphan || TAG_DST()) { result = prot_tag->retval; } POP_TAG(); POP_ITER(); ruby_block = old_block; ruby_wrapper = old_wrapper; ruby_dyna_vars = old_dvars; ruby_safe_level = safe; switch (state) { case 0: break; case TAG_RETRY: if (pcall || orphan) { localjump_error("retry from proc-closure", Qnil, state); } /* fall through */ case TAG_BREAK: case TAG_RETURN: if (pcall) break; if (orphan) { /* orphan block */ char mesg[32]; snprintf(mesg, sizeof mesg, "%s from proc-closure", state == TAG_BREAK ? "break" : "return"); localjump_error(mesg, result, state); } if (result != Qundef) { localjump_destination(state, ruby_scope, result); } default: JUMP_TAG(state); } return result; } static VALUE proc_call(proc, args) VALUE proc, args; /* OK */ { return proc_invoke(proc, args, Qundef, 0); } static VALUE bmcall _((VALUE, VALUE)); static VALUE method_arity _((VALUE)); static VALUE proc_arity(proc) VALUE proc; { struct BLOCK *data; NODE *list; int n; Data_Get_Struct(proc, struct BLOCK, data); if (data->var == 0) { if (data->body && nd_type(data->body) == NODE_IFUNC && data->body->nd_cfnc == bmcall) { return method_arity(data->body->nd_tval); } return INT2FIX(-1); } if (data->var == (NODE*)1) return INT2FIX(0); if (data->var == (NODE*)2) return INT2FIX(0); switch (nd_type(data->var)) { default: return INT2FIX(1); case NODE_MASGN: list = data->var->nd_head; n = 0; while (list) { n++; list = list->nd_next; } if (data->var->nd_args) return INT2FIX(-n-1); return INT2FIX(n); } } static VALUE proc_eq(self, other) VALUE self, other; { struct BLOCK *data, *data2; if (self == other) return Qtrue; if (TYPE(other) != T_DATA) return Qfalse; if (RDATA(other)->dmark != (RUBY_DATA_FUNC)blk_mark) return Qfalse; if (CLASS_OF(self) != CLASS_OF(other)) return Qfalse; Data_Get_Struct(self, struct BLOCK, data); Data_Get_Struct(other, struct BLOCK, data2); if (data->body == data2->body) return Qtrue; return Qfalse; } static VALUE proc_to_s(self, other) VALUE self, other; { struct BLOCK *data; NODE *node; char *cname = rb_obj_classname(self); const int w = (SIZEOF_LONG * CHAR_BIT) / 4; long len = strlen(cname)+6+w; /* 6:tags 16:addr */ VALUE str; Data_Get_Struct(self, struct BLOCK, data); if ((node = data->frame.node) || (node = data->body)) { len += strlen(node->nd_file) + 2 + (SIZEOF_LONG*CHAR_BIT-NODE_LSHIFT)/3; str = rb_str_new(0, len); sprintf(RSTRING(str)->ptr, "#<%s:0x%.*lx@%s:%d>", cname, w, (VALUE)data->body, node->nd_file, nd_line(node)); } else { str = rb_str_new(0, len); sprintf(RSTRING(str)->ptr, "#<%s:0x%.*lx>", cname, w, (VALUE)data->body); } RSTRING(str)->len = strlen(RSTRING(str)->ptr); if (OBJ_TAINTED(self)) OBJ_TAINT(str); return str; } static VALUE proc_to_self(self) VALUE self; { return self; } static VALUE proc_binding(proc) VALUE proc; { struct BLOCK *orig, *data; VALUE bind; Data_Get_Struct(proc, struct BLOCK, orig); bind = Data_Make_Struct(rb_cBinding,struct BLOCK,blk_mark,blk_free,data); MEMCPY(data, orig, struct BLOCK, 1); frame_dup(&data->frame); if (data->iter) { blk_copy_prev(data); } else { data->prev = 0; } return bind; } static VALUE block_pass(self, node) VALUE self; NODE *node; { VALUE proc = rb_eval(self, node->nd_body); /* OK */ VALUE b; struct BLOCK * volatile old_block; struct BLOCK _block; struct BLOCK *data; volatile VALUE result = Qnil; int state; volatile int orphan; volatile int safe = ruby_safe_level; if (NIL_P(proc)) { PUSH_ITER(ITER_NOT); result = rb_eval(self, node->nd_iter); POP_ITER(); return result; } if (!rb_obj_is_proc(proc)) { b = rb_check_convert_type(proc, T_DATA, "Proc", "to_proc"); if (!rb_obj_is_proc(b)) { rb_raise(rb_eTypeError, "wrong argument type %s (expected Proc)", rb_obj_classname(proc)); } proc = b; } if (ruby_safe_level >= 1 && OBJ_TAINTED(proc)) { if (ruby_safe_level > proc_get_safe_level(proc)) { rb_raise(rb_eSecurityError, "Insecure: tainted block value"); } } if (ruby_block && ruby_block->block_obj == proc) { PUSH_ITER(ITER_PRE); result = rb_eval(self, node->nd_iter); POP_ITER(); return result; } Data_Get_Struct(proc, struct BLOCK, data); orphan = block_orphan(data); /* PUSH BLOCK from data */ old_block = ruby_block; _block = *data; _block.outer = ruby_block; ruby_block = &_block; PUSH_ITER(ITER_PRE); if (ruby_frame->iter == ITER_NOT) ruby_frame->iter = ITER_PRE; PUSH_TAG(PROT_ITER); state = EXEC_TAG(); if (state == 0) { retry: proc_set_safe_level(proc); if (safe > ruby_safe_level) ruby_safe_level = safe; result = rb_eval(self, node->nd_iter); } else if (state == TAG_BREAK && TAG_DST()) { result = prot_tag->retval; state = 0; } else if (state == TAG_RETRY) { state = 0; goto retry; } POP_TAG(); POP_ITER(); ruby_block = old_block; ruby_safe_level = safe; switch (state) {/* escape from orphan block */ case 0: break; case TAG_RETURN: if (orphan) { localjump_error("return from proc-closure", prot_tag->retval, state); } default: JUMP_TAG(state); } return result; } struct METHOD { VALUE klass, rklass; VALUE recv; ID id, oid; NODE *body; }; static void bm_mark(data) struct METHOD *data; { rb_gc_mark(data->rklass); rb_gc_mark(data->klass); rb_gc_mark(data->recv); rb_gc_mark((VALUE)data->body); } static VALUE mnew(klass, obj, id, mklass) VALUE klass, obj, mklass; ID id; { VALUE method; NODE *body; int noex; struct METHOD *data; VALUE rklass = klass; ID oid = id; again: if ((body = rb_get_method_body(&klass, &id, &noex)) == 0) { print_undef(rklass, oid); } if (nd_type(body) == NODE_ZSUPER) { klass = RCLASS(klass)->super; goto again; } while (rklass != klass && (FL_TEST(rklass, FL_SINGLETON) || TYPE(rklass) == T_ICLASS)) { rklass = RCLASS(rklass)->super; } if (TYPE(klass) == T_ICLASS) klass = RBASIC(klass)->klass; method = Data_Make_Struct(mklass, struct METHOD, bm_mark, free, data); data->klass = klass; data->recv = obj; data->id = id; data->body = body; data->rklass = rklass; data->oid = oid; OBJ_INFECT(method, klass); return method; } static VALUE method_eq(method, other) VALUE method, other; { struct METHOD *m1, *m2; if (TYPE(other) != T_DATA || RDATA(other)->dmark != (RUBY_DATA_FUNC)bm_mark) return Qfalse; if (CLASS_OF(method) != CLASS_OF(other)) return Qfalse; Data_Get_Struct(method, struct METHOD, m1); Data_Get_Struct(other, struct METHOD, m2); if (m1->klass != m2->klass || m1->rklass != m2->rklass || m1->recv != m2->recv || m1->body != m2->body) return Qfalse; return Qtrue; } static VALUE method_unbind(obj) VALUE obj; { VALUE method; struct METHOD *orig, *data; Data_Get_Struct(obj, struct METHOD, orig); method = Data_Make_Struct(rb_cUnboundMethod, struct METHOD, bm_mark, free, data); data->klass = orig->klass; data->recv = Qundef; data->id = orig->id; data->body = orig->body; data->rklass = orig->rklass; data->oid = orig->oid; OBJ_INFECT(method, obj); return method; } static VALUE rb_obj_method(obj, vid) VALUE obj; VALUE vid; { return mnew(CLASS_OF(obj), obj, rb_to_id(vid), rb_cMethod); } static VALUE rb_mod_method(mod, vid) VALUE mod; VALUE vid; { return mnew(mod, Qundef, rb_to_id(vid), rb_cUnboundMethod); } static VALUE method_clone(self) VALUE self; { VALUE clone; struct METHOD *orig, *data; Data_Get_Struct(self, struct METHOD, orig); clone = Data_Make_Struct(CLASS_OF(self),struct METHOD, bm_mark, free, data); CLONESETUP(clone, self); *data = *orig; return clone; } static VALUE method_call(argc, argv, method) int argc; VALUE *argv; VALUE method; { VALUE result = Qnil; /* OK */ struct METHOD *data; int state; volatile int safe = ruby_safe_level; Data_Get_Struct(method, struct METHOD, data); if (data->recv == Qundef) { rb_raise(rb_eTypeError, "you cannot call unbound method; bind first"); } PUSH_ITER(rb_block_given_p()?ITER_PRE:ITER_NOT); PUSH_TAG(PROT_NONE); if (OBJ_TAINTED(method) && ruby_safe_level < 4) { ruby_safe_level = 4; } if ((state = EXEC_TAG()) == 0) { result = rb_call0(data->klass,data->recv,data->id,data->oid,argc,argv,data->body,0); } POP_TAG(); POP_ITER(); ruby_safe_level = safe; if (state) JUMP_TAG(state); return result; } static VALUE umethod_bind(method, recv) VALUE method, recv; { struct METHOD *data, *bound; Data_Get_Struct(method, struct METHOD, data); if (data->rklass != CLASS_OF(recv)) { if (FL_TEST(data->rklass, FL_SINGLETON)) { rb_raise(rb_eTypeError, "singleton method called for a different object"); } if (FL_TEST(CLASS_OF(recv), FL_SINGLETON) && st_lookup(RCLASS(CLASS_OF(recv))->m_tbl, data->oid, 0)) { rb_raise(rb_eTypeError, "method `%s' overridden", rb_id2name(data->oid)); } if(!rb_obj_is_kind_of(recv, data->rklass)) { rb_raise(rb_eTypeError, "bind argument must be an instance of %s", rb_class2name(data->rklass)); } } method = Data_Make_Struct(rb_cMethod,struct METHOD,bm_mark,free,bound); *bound = *data; bound->recv = recv; bound->rklass = CLASS_OF(recv); return method; } static VALUE method_arity(method) VALUE method; { struct METHOD *data; NODE *body; int n; Data_Get_Struct(method, struct METHOD, data); body = data->body; switch (nd_type(body)) { case NODE_CFUNC: if (body->nd_argc < 0) return INT2FIX(-1); return INT2FIX(body->nd_argc); case NODE_ZSUPER: return INT2FIX(-1); case NODE_ATTRSET: return INT2FIX(1); case NODE_IVAR: return INT2FIX(0); case NODE_BMETHOD: case NODE_DMETHOD: return proc_arity(method); default: body = body->nd_next; /* skip NODE_SCOPE */ if (nd_type(body) == NODE_BLOCK) body = body->nd_head; if (!body) return INT2FIX(0); n = body->nd_cnt; if (body->nd_opt || body->nd_rest != -1) n = -n-1; return INT2FIX(n); } } static VALUE method_inspect(method) VALUE method; { struct METHOD *data; VALUE str; const char *s; char *sharp = "#"; Data_Get_Struct(method, struct METHOD, data); str = rb_str_buf_new2("#<"); s = rb_obj_classname(method); rb_str_buf_cat2(str, s); rb_str_buf_cat2(str, ": "); if (FL_TEST(data->klass, FL_SINGLETON)) { VALUE v = rb_iv_get(data->klass, "__attached__"); if (data->recv == Qundef) { rb_str_buf_append(str, rb_inspect(data->klass)); } else if (data->recv == v) { rb_str_buf_append(str, rb_inspect(v)); sharp = "."; } else { rb_str_buf_append(str, rb_inspect(data->recv)); rb_str_buf_cat2(str, "("); rb_str_buf_append(str, rb_inspect(v)); rb_str_buf_cat2(str, ")"); sharp = "."; } } else { rb_str_buf_cat2(str, rb_class2name(data->rklass)); if (data->rklass != data->klass) { rb_str_buf_cat2(str, "("); rb_str_buf_cat2(str, rb_class2name(data->klass)); rb_str_buf_cat2(str, ")"); } } rb_str_buf_cat2(str, sharp); rb_str_buf_cat2(str, rb_id2name(data->oid)); rb_str_buf_cat2(str, ">"); return str; } static VALUE mproc(method) VALUE method; { VALUE proc; /* emulate ruby's method call */ PUSH_ITER(ITER_CUR); PUSH_FRAME(); proc = rb_block_proc(); POP_FRAME(); POP_ITER(); return proc; } static VALUE bmcall(args, method) VALUE args, method; { volatile VALUE a; a = svalue_to_avalue(args); return method_call(RARRAY(a)->len, RARRAY(a)->ptr, method); } VALUE rb_proc_new(func, val) VALUE (*func)(ANYARGS); /* VALUE yieldarg[, VALUE procarg] */ VALUE val; { struct BLOCK *data; VALUE proc = rb_iterate((VALUE(*)_((VALUE)))mproc, 0, func, val); Data_Get_Struct(proc, struct BLOCK, data); data->body->nd_state = YIELD_FUNC_AVALUE; return proc; } static VALUE method_proc(method) VALUE method; { VALUE proc; struct METHOD *mdata; struct BLOCK *bdata; proc = rb_iterate((VALUE(*)_((VALUE)))mproc, 0, bmcall, method); Data_Get_Struct(method, struct METHOD, mdata); Data_Get_Struct(proc, struct BLOCK, bdata); bdata->body->nd_file = mdata->body->nd_file; nd_set_line(bdata->body, nd_line(mdata->body)); bdata->body->nd_state = YIELD_FUNC_SVALUE; return proc; } static VALUE rb_obj_is_method(m) VALUE m; { if (TYPE(m) == T_DATA && RDATA(m)->dmark == (RUBY_DATA_FUNC)bm_mark) { return Qtrue; } return Qfalse; } static VALUE rb_mod_define_method(argc, argv, mod) int argc; VALUE *argv; VALUE mod; { ID id; VALUE body; NODE *node; int noex; if (argc == 1) { id = rb_to_id(argv[0]); body = proc_lambda(); } else if (argc == 2) { id = rb_to_id(argv[0]); body = argv[1]; if (!rb_obj_is_method(body) && !rb_obj_is_proc(body)) { rb_raise(rb_eTypeError, "wrong argument type %s (expected Proc/Method)", rb_obj_classname(body)); } } else { rb_raise(rb_eArgError, "wrong number of arguments(%d for 1)", argc); } if (RDATA(body)->dmark == (RUBY_DATA_FUNC)bm_mark) { node = NEW_DMETHOD(method_unbind(body)); } else if (RDATA(body)->dmark == (RUBY_DATA_FUNC)blk_mark) { struct BLOCK *block; body = proc_clone(body); Data_Get_Struct(body, struct BLOCK, block); block->frame.last_func = id; block->frame.orig_func = id; block->frame.last_class = mod; node = NEW_BMETHOD(body); } else { /* type error */ rb_raise(rb_eTypeError, "wrong argument type (expected Proc/Method)"); } if (SCOPE_TEST(SCOPE_PRIVATE)) { noex = NOEX_PRIVATE; } else if (SCOPE_TEST(SCOPE_PROTECTED)) { noex = NOEX_PROTECTED; } else { noex = NOEX_PUBLIC; } rb_add_method(mod, id, node, noex); return body; } void Init_Proc() { rb_eLocalJumpError = rb_define_class("LocalJumpError", rb_eStandardError); rb_define_method(rb_eLocalJumpError, "exit_value", localjump_xvalue, 0); rb_define_method(rb_eLocalJumpError, "reason", localjump_reason, 0); exception_error = rb_exc_new2(rb_eFatal, "exception reentered"); rb_global_variable(&exception_error); rb_eSysStackError = rb_define_class("SystemStackError", rb_eStandardError); sysstack_error = rb_exc_new2(rb_eSysStackError, "stack level too deep"); rb_global_variable(&sysstack_error); rb_cProc = rb_define_class("Proc", rb_cObject); rb_undef_alloc_func(rb_cProc); rb_define_singleton_method(rb_cProc, "new", proc_s_new, -1); rb_define_method(rb_cProc, "clone", proc_clone, 0); rb_define_method(rb_cProc, "call", proc_call, -2); rb_define_method(rb_cProc, "arity", proc_arity, 0); rb_define_method(rb_cProc, "[]", proc_call, -2); rb_define_method(rb_cProc, "==", proc_eq, 1); rb_define_method(rb_cProc, "to_s", proc_to_s, 0); rb_define_method(rb_cProc, "to_proc", proc_to_self, 0); rb_define_method(rb_cProc, "binding", proc_binding, 0); rb_define_global_function("proc", proc_lambda, 0); rb_define_global_function("lambda", proc_lambda, 0); rb_cBinding = rb_define_class("Binding", rb_cObject); rb_undef_alloc_func(rb_cBinding); rb_undef_method(CLASS_OF(rb_cBinding), "new"); rb_define_method(rb_cBinding, "clone", proc_clone, 0); rb_define_global_function("binding", rb_f_binding, 0); rb_cMethod = rb_define_class("Method", rb_cObject); rb_undef_alloc_func(rb_cMethod); rb_undef_method(CLASS_OF(rb_cMethod), "new"); rb_define_method(rb_cMethod, "==", method_eq, 1); rb_define_method(rb_cMethod, "clone", method_clone, 0); rb_define_method(rb_cMethod, "call", method_call, -1); rb_define_method(rb_cMethod, "[]", method_call, -1); rb_define_method(rb_cMethod, "arity", method_arity, 0); rb_define_method(rb_cMethod, "inspect", method_inspect, 0); rb_define_method(rb_cMethod, "to_s", method_inspect, 0); rb_define_method(rb_cMethod, "to_proc", method_proc, 0); rb_define_method(rb_cMethod, "unbind", method_unbind, 0); rb_define_method(rb_mKernel, "method", rb_obj_method, 1); rb_cUnboundMethod = rb_define_class("UnboundMethod", rb_cObject); rb_undef_alloc_func(rb_cUnboundMethod); rb_undef_method(CLASS_OF(rb_cUnboundMethod), "new"); rb_define_method(rb_cUnboundMethod, "==", method_eq, 1); rb_define_method(rb_cUnboundMethod, "clone", method_clone, 0); rb_define_method(rb_cUnboundMethod, "arity", method_arity, 0); rb_define_method(rb_cUnboundMethod, "inspect", method_inspect, 0); rb_define_method(rb_cUnboundMethod, "to_s", method_inspect, 0); rb_define_method(rb_cUnboundMethod, "bind", umethod_bind, 1); rb_define_method(rb_cModule, "instance_method", rb_mod_method, 1); } #ifdef __ia64__ #include #pragma weak __libc_ia64_register_backing_store_base extern unsigned long __libc_ia64_register_backing_store_base; #endif /* Windows SEH refers data on the stack. */ #undef SAVE_WIN32_EXCEPTION_LIST #if defined _WIN32 || defined __CYGWIN__ #if defined __CYGWIN__ typedef unsigned long DWORD; #endif static inline DWORD win32_get_exception_list() { DWORD p; # if defined _MSC_VER # ifdef _M_IX86 # define SAVE_WIN32_EXCEPTION_LIST # if _MSC_VER >= 1310 /* warning: unsafe assignment to fs:0 ... this is ok */ # pragma warning(disable: 4733) # endif __asm mov eax, fs:[0]; __asm mov p, eax; # endif # elif defined __GNUC__ # ifdef __i386__ # define SAVE_WIN32_EXCEPTION_LIST __asm__("movl %%fs:0,%0" : "=r"(p)); # endif # elif defined __BORLANDC__ # define SAVE_WIN32_EXCEPTION_LIST __emit__(0x64, 0xA1, 0, 0, 0, 0); /* mov eax, fs:[0] */ p = _EAX; # endif return p; } static inline void win32_set_exception_list(p) DWORD p; { # if defined _MSC_VER # ifdef _M_IX86 __asm mov eax, p; __asm mov fs:[0], eax; # endif # elif defined __GNUC__ # ifdef __i386__ __asm__("movl %0,%%fs:0" :: "r"(p)); # endif # elif defined __BORLANDC__ _EAX = p; __emit__(0x64, 0xA3, 0, 0, 0, 0); /* mov fs:[0], eax */ # endif } #if !defined SAVE_WIN32_EXCEPTION_LIST && !defined _WIN32_WCE # error unsupported platform #endif #endif int rb_thread_pending = 0; VALUE rb_cThread; extern VALUE rb_last_status; enum thread_status { THREAD_TO_KILL, THREAD_RUNNABLE, THREAD_STOPPED, THREAD_KILLED, }; #define WAIT_FD (1<<0) #define WAIT_SELECT (1<<1) #define WAIT_TIME (1<<2) #define WAIT_JOIN (1<<3) #define WAIT_PID (1<<4) /* +infty, for this purpose */ #define DELAY_INFTY 1E30 #if !defined HAVE_PAUSE # if defined _WIN32 && !defined __CYGWIN__ # define pause() Sleep(INFINITE) # else # define pause() sleep(0x7fffffff) # endif #endif /* typedef struct thread * rb_thread_t; */ struct thread { struct thread *next, *prev; #ifdef __ia64__ ucontext_t context; int context_status; #else jmp_buf context; #endif #ifdef SAVE_WIN32_EXCEPTION_LIST DWORD win32_exception_list; #endif VALUE result; long stk_len; long stk_max; VALUE *stk_ptr; VALUE *stk_pos; #ifdef __ia64__ VALUE *bstr_ptr; long bstr_len; #endif struct FRAME *frame; struct SCOPE *scope; struct RVarmap *dyna_vars; struct BLOCK *block; struct iter *iter; struct tag *tag; VALUE klass; VALUE wrapper; NODE *cref; int flags; /* misc. states (vmode/rb_trap_immediate/raised) */ NODE *node; int tracing; VALUE errinfo; VALUE last_status; VALUE last_line; VALUE last_match; int safe; enum thread_status status; int wait_for; int fd; fd_set readfds; fd_set writefds; fd_set exceptfds; int select_value; double delay; rb_thread_t join; int abort; int priority; VALUE thgroup; st_table *locals; VALUE thread; }; #define THREAD_RAISED 0x200 /* temporary flag */ #define THREAD_TERMINATING 0x400 /* persistent flag */ #define THREAD_FLAGS_MASK 0x400 /* mask for persistent flags */ #define FOREACH_THREAD_FROM(f,x) x = f; do { x = x->next; #define END_FOREACH_FROM(f,x) } while (x != f) #define FOREACH_THREAD(x) FOREACH_THREAD_FROM(curr_thread,x) #define END_FOREACH(x) END_FOREACH_FROM(curr_thread,x) struct thread_status_t { NODE *node; int tracing; VALUE errinfo; VALUE last_status; VALUE last_line; VALUE last_match; int safe; enum thread_status status; int wait_for; int fd; fd_set readfds; fd_set writefds; fd_set exceptfds; int select_value; double delay; rb_thread_t join; }; #define THREAD_COPY_STATUS(src, dst) (void)( \ (dst)->node = (src)->node, \ \ (dst)->tracing = (src)->tracing, \ (dst)->errinfo = (src)->errinfo, \ (dst)->last_status = (src)->last_status, \ (dst)->last_line = (src)->last_line, \ (dst)->last_match = (src)->last_match, \ \ (dst)->safe = (src)->safe, \ \ (dst)->status = (src)->status, \ (dst)->wait_for = (src)->wait_for, \ (dst)->fd = (src)->fd, \ (dst)->readfds = (src)->readfds, \ (dst)->writefds = (src)->writefds, \ (dst)->exceptfds = (src)->exceptfds, \ (dst)->select_value = (src)->select_value, \ (dst)->delay = (src)->delay, \ (dst)->join = (src)->join, \ 0) static int thread_set_raised() { if (curr_thread->flags & THREAD_RAISED) return 1; curr_thread->flags |= THREAD_RAISED; return 0; } static int thread_reset_raised() { if (!(curr_thread->flags & THREAD_RAISED)) return 0; curr_thread->flags &= ~THREAD_RAISED; return 1; } static void rb_thread_ready _((rb_thread_t)); static VALUE rb_trap_eval(cmd, sig) VALUE cmd; int sig; { int state; VALUE val = Qnil; /* OK */ volatile struct thread_status_t save; THREAD_COPY_STATUS(curr_thread, &save); rb_thread_ready(curr_thread); PUSH_TAG(PROT_NONE); PUSH_ITER(ITER_NOT); if ((state = EXEC_TAG()) == 0) { val = rb_eval_cmd(cmd, rb_ary_new3(1, INT2FIX(sig)), 0); } POP_ITER(); POP_TAG(); THREAD_COPY_STATUS(&save, curr_thread); if (state) { rb_trap_immediate = 0; JUMP_TAG(state); } if (curr_thread->status == THREAD_STOPPED) { rb_thread_schedule(); } errno = EINTR; return val; } static const char * thread_status_name(status) enum thread_status status; { switch (status) { case THREAD_RUNNABLE: return "run"; case THREAD_STOPPED: return "sleep"; case THREAD_TO_KILL: return "aborting"; case THREAD_KILLED: return "dead"; default: return "unknown"; } } /* $SAFE accessor */ void rb_set_safe_level(level) int level; { if (level > ruby_safe_level) { ruby_safe_level = level; curr_thread->safe = level; } } static VALUE safe_getter() { return INT2NUM(ruby_safe_level); } static void safe_setter(val) VALUE val; { int level = NUM2INT(val); if (level < ruby_safe_level) { rb_raise(rb_eSecurityError, "tried to downgrade safe level from %d to %d", ruby_safe_level, level); } ruby_safe_level = level; curr_thread->safe = level; } /* Return the current time as a floating-point number */ static double timeofday() { struct timeval tv; gettimeofday(&tv, NULL); return (double)tv.tv_sec + (double)tv.tv_usec * 1e-6; } #define STACK(addr) (th->stk_pos<(VALUE*)(addr) && (VALUE*)(addr)stk_pos+th->stk_len) #define ADJ(addr) (void*)(STACK(addr)?(((VALUE*)(addr)-th->stk_pos)+th->stk_ptr):(VALUE*)(addr)) #ifdef C_ALLOCA # define MARK_FRAME_ADJ(f) rb_gc_mark_frame(f) #else # define MARK_FRAME_ADJ(f) mark_frame_adj(f, th) static void mark_frame_adj(frame, th) struct FRAME *frame; rb_thread_t th; { if (frame->flags & FRAME_MALLOC) { rb_gc_mark_locations(frame->argv, frame->argv+frame->argc); } else { VALUE *start = ADJ(frame->argv); rb_gc_mark_locations(start, start+frame->argc); } rb_gc_mark((VALUE)frame->node); } #endif static void thread_mark(th) rb_thread_t th; { struct FRAME *frame; struct BLOCK *block; rb_gc_mark(th->result); rb_gc_mark(th->thread); if (th->join) rb_gc_mark(th->join->thread); rb_gc_mark(th->klass); rb_gc_mark(th->wrapper); rb_gc_mark((VALUE)th->cref); rb_gc_mark((VALUE)th->scope); rb_gc_mark((VALUE)th->dyna_vars); rb_gc_mark(th->errinfo); rb_gc_mark(th->last_line); rb_gc_mark(th->last_match); rb_mark_tbl(th->locals); /* mark data in copied stack */ if (th == curr_thread) return; if (th->status == THREAD_KILLED) return; if (th->stk_len == 0) return; /* stack not active, no need to mark. */ if (th->stk_ptr) { rb_gc_mark_locations(th->stk_ptr, th->stk_ptr+th->stk_len); #if defined(THINK_C) || defined(__human68k__) rb_gc_mark_locations(th->stk_ptr+2, th->stk_ptr+th->stk_len+2); #endif #ifdef __ia64__ if (th->bstr_ptr) { rb_gc_mark_locations(th->bstr_ptr, th->bstr_ptr+th->bstr_len); } #endif } frame = th->frame; while (frame && frame != top_frame) { frame = ADJ(frame); MARK_FRAME_ADJ(frame); if (frame->tmp) { struct FRAME *tmp = frame->tmp; while (tmp && tmp != top_frame) { tmp = ADJ(tmp); MARK_FRAME_ADJ(tmp); tmp = tmp->prev; } } frame = frame->prev; } block = th->block; while (block) { block = ADJ(block); MARK_FRAME_ADJ(&block->frame); block = block->prev; } } void rb_gc_mark_threads() { rb_thread_t th; /* static global mark */ rb_gc_mark((VALUE)ruby_cref); if (!curr_thread) return; FOREACH_THREAD(th) { rb_gc_mark(th->thread); } END_FOREACH(th); } static void thread_free(th) rb_thread_t th; { if (th->stk_ptr) free(th->stk_ptr); th->stk_ptr = 0; #ifdef __ia64__ if (th->bstr_ptr) free(th->bstr_ptr); th->bstr_ptr = 0; #endif if (th->locals) st_free_table(th->locals); if (th->status != THREAD_KILLED) { if (th->prev) th->prev->next = th->next; if (th->next) th->next->prev = th->prev; } if (th != main_thread) free(th); } static rb_thread_t rb_thread_check(data) VALUE data; { if (TYPE(data) != T_DATA || RDATA(data)->dmark != (RUBY_DATA_FUNC)thread_mark) { rb_raise(rb_eTypeError, "wrong argument type %s (expected Thread)", rb_obj_classname(data)); } return (rb_thread_t)RDATA(data)->data; } static VALUE rb_thread_raise _((int, VALUE*, rb_thread_t)); static int th_raise_argc; static VALUE th_raise_argv[2]; static NODE *th_raise_node; static VALUE th_cmd; static int th_sig; static char *th_signm; #define RESTORE_NORMAL 1 #define RESTORE_FATAL 2 #define RESTORE_INTERRUPT 3 #define RESTORE_TRAP 4 #define RESTORE_RAISE 5 #define RESTORE_SIGNAL 6 #define RESTORE_EXIT 7 extern VALUE *rb_gc_stack_start; static void rb_thread_save_context(th) rb_thread_t th; { VALUE *pos; int len; static VALUE tval; len = ruby_stack_length(&pos); th->stk_len = 0; th->stk_pos = pos; if (len > th->stk_max) { REALLOC_N(th->stk_ptr, VALUE, len); th->stk_max = len; } th->stk_len = len; FLUSH_REGISTER_WINDOWS; MEMCPY(th->stk_ptr, th->stk_pos, VALUE, th->stk_len); #ifdef __ia64__ { ucontext_t ctx; VALUE *top, *bot; getcontext(&ctx); bot = (VALUE*)__libc_ia64_register_backing_store_base; #if defined(__FreeBSD__) top = (VALUE*)ctx.uc_mcontext.mc_special.bspstore; #else top = (VALUE*)ctx.uc_mcontext.sc_ar_bsp; #endif th->bstr_len = top - bot; REALLOC_N(th->bstr_ptr, VALUE, th->bstr_len); MEMCPY(th->bstr_ptr, (VALUE*)__libc_ia64_register_backing_store_base, VALUE, th->bstr_len); } #endif #ifdef SAVE_WIN32_EXCEPTION_LIST th->win32_exception_list = win32_get_exception_list(); #endif th->frame = ruby_frame; th->scope = ruby_scope; th->klass = ruby_class; th->wrapper = ruby_wrapper; th->cref = ruby_cref; th->dyna_vars = ruby_dyna_vars; th->block = ruby_block; th->flags &= THREAD_FLAGS_MASK; th->flags |= (rb_trap_immediate<<8) | scope_vmode; th->iter = ruby_iter; th->tag = prot_tag; th->tracing = tracing; th->errinfo = ruby_errinfo; th->last_status = rb_last_status; tval = rb_lastline_get(); rb_lastline_set(th->last_line); th->last_line = tval; tval = rb_backref_get(); rb_backref_set(th->last_match); th->last_match = tval; th->safe = ruby_safe_level; th->node = ruby_current_node; } static int rb_thread_switch(n) int n; { rb_trap_immediate = (curr_thread->flags&0x100)?1:0; switch (n) { case 0: return 0; case RESTORE_FATAL: JUMP_TAG(TAG_FATAL); break; case RESTORE_INTERRUPT: rb_interrupt(); break; case RESTORE_TRAP: rb_trap_eval(th_cmd, th_sig); break; case RESTORE_RAISE: ruby_frame->last_func = 0; ruby_current_node = th_raise_node; rb_f_raise(th_raise_argc, th_raise_argv); break; case RESTORE_SIGNAL: rb_raise(rb_eSignal, "SIG%s", th_signm); break; case RESTORE_EXIT: ruby_errinfo = th_raise_argv[0]; ruby_current_node = th_raise_node; error_print(); terminate_process(1, 0, 0); break; case RESTORE_NORMAL: default: break; } return 1; } #ifdef __ia64__ # define THREAD_SAVE_CONTEXT(th) \ (rb_thread_save_context(th),\ th->context_status = 0,\ rb_thread_switch((FLUSH_REGISTER_WINDOWS, getcontext(&th->context),(th)->context_status))) #else # define THREAD_SAVE_CONTEXT(th) \ (rb_thread_save_context(th),\ rb_thread_switch((FLUSH_REGISTER_WINDOWS, setjmp((th)->context)))) #endif NORETURN(static void rb_thread_restore_context _((rb_thread_t,int))); static void stack_extend(th, exit) rb_thread_t th; int exit; { VALUE space[1024]; memset(space, 0, 1); /* prevent array from optimization */ rb_thread_restore_context(th, exit); } static void rb_thread_restore_context(th, exit) rb_thread_t th; int exit; { VALUE v; static rb_thread_t tmp; static int ex; static VALUE tval; if (!th->stk_ptr) rb_bug("unsaved context"); #if STACK_GROW_DIRECTION < 0 if (&v > th->stk_pos) stack_extend(th, exit); #elif STACK_GROW_DIRECTION > 0 if (&v < th->stk_pos + th->stk_len) stack_extend(th, exit); #else if (&v < rb_gc_stack_start) { /* Stack grows downward */ if (&v > th->stk_pos) stack_extend(th, exit); } else { /* Stack grows upward */ if (&v < th->stk_pos + th->stk_len) stack_extend(th, exit); } #endif rb_trap_immediate = 0; /* inhibit interrupts from here */ ruby_frame = th->frame; ruby_scope = th->scope; ruby_class = th->klass; ruby_wrapper = th->wrapper; ruby_cref = th->cref; ruby_dyna_vars = th->dyna_vars; ruby_block = th->block; scope_vmode = th->flags&SCOPE_MASK; ruby_iter = th->iter; prot_tag = th->tag; tracing = th->tracing; ruby_errinfo = th->errinfo; rb_last_status = th->last_status; ruby_safe_level = th->safe; ruby_current_node = th->node; #ifdef SAVE_WIN32_EXCEPTION_LIST win32_set_exception_list(th->win32_exception_list); #endif tmp = th; ex = exit; FLUSH_REGISTER_WINDOWS; MEMCPY(tmp->stk_pos, tmp->stk_ptr, VALUE, tmp->stk_len); #ifdef __ia64__ MEMCPY((VALUE*)__libc_ia64_register_backing_store_base, tmp->bstr_ptr, VALUE, tmp->bstr_len); #endif tval = rb_lastline_get(); rb_lastline_set(tmp->last_line); tmp->last_line = tval; tval = rb_backref_get(); rb_backref_set(tmp->last_match); tmp->last_match = tval; #ifdef __ia64__ tmp->context_status = ex; setcontext(&tmp->context); #else longjmp(tmp->context, ex); #endif } static void rb_thread_ready(th) rb_thread_t th; { th->wait_for = 0; if (th->status != THREAD_TO_KILL) { th->status = THREAD_RUNNABLE; } } static void rb_thread_die(th) rb_thread_t th; { th->thgroup = 0; th->status = THREAD_KILLED; if (th->stk_ptr) free(th->stk_ptr); th->stk_ptr = 0; } static void rb_thread_remove(th) rb_thread_t th; { if (th->status == THREAD_KILLED) return; rb_thread_ready(th); rb_thread_die(th); th->prev->next = th->next; th->next->prev = th->prev; } static int rb_thread_dead(th) rb_thread_t th; { return th->status == THREAD_KILLED; } void rb_thread_fd_close(fd) int fd; { rb_thread_t th; FOREACH_THREAD(th) { if (((th->wait_for & WAIT_FD) && fd == th->fd) || ((th->wait_for & WAIT_SELECT) && (fd < th->fd) && (FD_ISSET(fd, &th->readfds) || FD_ISSET(fd, &th->writefds) || FD_ISSET(fd, &th->exceptfds)))) { VALUE exc = rb_exc_new2(rb_eIOError, "stream closed"); rb_thread_raise(1, &exc, th); } } END_FOREACH(th); } NORETURN(static void rb_thread_main_jump _((VALUE, int))); static void rb_thread_main_jump(err, tag) VALUE err; int tag; { curr_thread = main_thread; th_raise_argc = 1; th_raise_argv[0] = err; th_raise_node = ruby_current_node; rb_thread_restore_context(main_thread, tag); } NORETURN(static void rb_thread_deadlock _((void))); static void rb_thread_deadlock() { char msg[21+SIZEOF_LONG*2]; VALUE e; sprintf(msg, "Thread(0x%lx): deadlock", curr_thread->thread); e = rb_exc_new2(rb_eFatal, msg); if (curr_thread == main_thread) { rb_exc_raise(e); } rb_thread_main_jump(e, RESTORE_RAISE); } static void copy_fds(dst, src, max) fd_set *dst, *src; int max; { int n = 0; int i; for (i=0; i<=max; i++) { if (FD_ISSET(i, src)) { n = i; FD_SET(i, dst); } } } static int match_fds(dst, src, max) fd_set *dst, *src; int max; { int i; for (i=0; i<=max; i++) { if (FD_ISSET(i, src) && FD_ISSET(i, dst)) { return Qtrue; } } return Qfalse; } static int intersect_fds(src, dst, max) fd_set *src, *dst; int max; { int i, n = 0; for (i=0; i<=max; i++) { if (FD_ISSET(i, dst)) { if (FD_ISSET(i, src)) { /* Wake up only one thread per fd. */ FD_CLR(i, src); n++; } else { FD_CLR(i, dst); } } } return n; } static int find_bad_fds(dst, src, max) fd_set *dst, *src; int max; { int i, test = Qfalse; for (i=0; i<=max; i++) { if (FD_ISSET(i, src) && !FD_ISSET(i, dst)) { FD_CLR(i, src); test = Qtrue; } } return test; } void rb_thread_schedule() { rb_thread_t next; /* OK */ rb_thread_t th; rb_thread_t curr; int found = 0; fd_set readfds; fd_set writefds; fd_set exceptfds; struct timeval delay_tv, *delay_ptr; double delay, now; /* OK */ int n, max; int need_select = 0; int select_timeout = 0; rb_thread_pending = 0; if (curr_thread == curr_thread->next && curr_thread->status == THREAD_RUNNABLE) return; next = 0; curr = curr_thread; /* starting thread */ while (curr->status == THREAD_KILLED) { curr = curr->prev; } again: max = -1; FD_ZERO(&readfds); FD_ZERO(&writefds); FD_ZERO(&exceptfds); delay = DELAY_INFTY; now = -1.0; FOREACH_THREAD_FROM(curr, th) { if (!found && th->status <= THREAD_RUNNABLE) { found = 1; } if (th->status != THREAD_STOPPED) continue; if (th->wait_for & WAIT_JOIN) { if (rb_thread_dead(th->join)) { th->status = THREAD_RUNNABLE; found = 1; } } if (th->wait_for & WAIT_FD) { FD_SET(th->fd, &readfds); if (max < th->fd) max = th->fd; need_select = 1; } if (th->wait_for & WAIT_SELECT) { copy_fds(&readfds, &th->readfds, th->fd); copy_fds(&writefds, &th->writefds, th->fd); copy_fds(&exceptfds, &th->exceptfds, th->fd); if (max < th->fd) max = th->fd; need_select = 1; if (th->wait_for & WAIT_TIME) { select_timeout = 1; } th->select_value = 0; } if (th->wait_for & WAIT_TIME) { double th_delay; if (now < 0.0) now = timeofday(); th_delay = th->delay - now; if (th_delay <= 0.0) { th->status = THREAD_RUNNABLE; found = 1; } else if (th_delay < delay) { delay = th_delay; need_select = 1; } else if (th->delay == DELAY_INFTY) { need_select = 1; } } } END_FOREACH_FROM(curr, th); /* Do the select if needed */ if (need_select) { /* Convert delay to a timeval */ /* If a thread is runnable, just poll */ if (found) { delay_tv.tv_sec = 0; delay_tv.tv_usec = 0; delay_ptr = &delay_tv; } else if (delay == DELAY_INFTY) { delay_ptr = 0; } else { delay_tv.tv_sec = delay; delay_tv.tv_usec = (delay - (double)delay_tv.tv_sec)*1e6; delay_ptr = &delay_tv; } n = select(max+1, &readfds, &writefds, &exceptfds, delay_ptr); if (n < 0) { int e = errno; if (rb_trap_pending) rb_trap_exec(); if (e == EINTR) goto again; #ifdef ERESTART if (e == ERESTART) goto again; #endif FOREACH_THREAD_FROM(curr, th) { if (th->wait_for & WAIT_SELECT) { int v = 0; v |= find_bad_fds(&readfds, &th->readfds, th->fd); v |= find_bad_fds(&writefds, &th->writefds, th->fd); v |= find_bad_fds(&exceptfds, &th->exceptfds, th->fd); if (v) { th->select_value = n; n = max; } } } END_FOREACH_FROM(curr, th); } if (select_timeout && n == 0) { if (now < 0.0) now = timeofday(); FOREACH_THREAD_FROM(curr, th) { if (((th->wait_for&(WAIT_SELECT|WAIT_TIME)) == (WAIT_SELECT|WAIT_TIME)) && th->delay <= now) { th->status = THREAD_RUNNABLE; th->wait_for = 0; th->select_value = 0; found = 1; intersect_fds(&readfds, &th->readfds, max); intersect_fds(&writefds, &th->writefds, max); intersect_fds(&exceptfds, &th->exceptfds, max); } } END_FOREACH_FROM(curr, th); } if (n > 0) { now = -1.0; /* Some descriptors are ready. Make the corresponding threads runnable. */ FOREACH_THREAD_FROM(curr, th) { if ((th->wait_for&WAIT_FD) && FD_ISSET(th->fd, &readfds)) { /* Wake up only one thread per fd. */ FD_CLR(th->fd, &readfds); th->status = THREAD_RUNNABLE; th->fd = 0; th->wait_for = 0; found = 1; } if ((th->wait_for&WAIT_SELECT) && (match_fds(&readfds, &th->readfds, max) || match_fds(&writefds, &th->writefds, max) || match_fds(&exceptfds, &th->exceptfds, max))) { /* Wake up only one thread per fd. */ th->status = THREAD_RUNNABLE; th->wait_for = 0; n = intersect_fds(&readfds, &th->readfds, max) + intersect_fds(&writefds, &th->writefds, max) + intersect_fds(&exceptfds, &th->exceptfds, max); th->select_value = n; found = 1; } } END_FOREACH_FROM(curr, th); } /* The delays for some of the threads should have expired. Go through the loop once more, to check the delays. */ if (!found && delay != DELAY_INFTY) goto again; } FOREACH_THREAD_FROM(curr, th) { if (th->status == THREAD_TO_KILL) { next = th; break; } if (th->status == THREAD_RUNNABLE && th->stk_ptr) { if (!next || next->priority < th->priority) next = th; } } END_FOREACH_FROM(curr, th); if (!next) { /* raise fatal error to main thread */ curr_thread->node = ruby_current_node; if (curr->next == curr) { TRAP_BEG; pause(); TRAP_END; } FOREACH_THREAD_FROM(curr, th) { warn_printf("deadlock 0x%lx: %s:", th->thread, thread_status_name(th->status)); if (th->wait_for & WAIT_FD) warn_printf("F(%d)", th->fd); if (th->wait_for & WAIT_SELECT) warn_printf("S"); if (th->wait_for & WAIT_TIME) warn_printf("T(%f)", th->delay); if (th->wait_for & WAIT_JOIN) warn_printf("J(0x%lx)", th->join ? th->join->thread : 0); if (th->wait_for & WAIT_PID) warn_printf("P"); if (!th->wait_for) warn_printf("-"); warn_printf(" %s - %s:%d\n", th==main_thread ? "(main)" : "", th->node->nd_file, nd_line(th->node)); } END_FOREACH_FROM(curr, th); next = main_thread; rb_thread_ready(next); next->status = THREAD_TO_KILL; if (!rb_thread_dead(curr_thread)) { rb_thread_save_context(curr_thread); } rb_thread_deadlock(); } next->wait_for = 0; if (next->status == THREAD_RUNNABLE && next == curr_thread) { return; } /* context switch */ if (curr == curr_thread) { if (THREAD_SAVE_CONTEXT(curr)) { return; } } curr_thread = next; if (next->status == THREAD_TO_KILL) { if (!(next->flags & THREAD_TERMINATING)) { next->flags |= THREAD_TERMINATING; /* terminate; execute ensure-clause if any */ rb_thread_restore_context(next, RESTORE_FATAL); } } rb_thread_restore_context(next, RESTORE_NORMAL); } void rb_thread_wait_fd(fd) int fd; { if (rb_thread_critical) return; if (ruby_in_compile) return; if (curr_thread == curr_thread->next) return; if (curr_thread->status == THREAD_TO_KILL) return; curr_thread->status = THREAD_STOPPED; curr_thread->fd = fd; curr_thread->wait_for = WAIT_FD; rb_thread_schedule(); } int rb_thread_fd_writable(fd) int fd; { if (rb_thread_critical) return Qtrue; if (curr_thread == curr_thread->next) return Qtrue; if (curr_thread->status == THREAD_TO_KILL) return Qtrue; curr_thread->status = THREAD_STOPPED; FD_ZERO(&curr_thread->readfds); FD_ZERO(&curr_thread->writefds); FD_SET(fd, &curr_thread->writefds); FD_ZERO(&curr_thread->exceptfds); curr_thread->fd = fd+1; curr_thread->wait_for = WAIT_SELECT; rb_thread_schedule(); return Qfalse; } void rb_thread_wait_for(time) struct timeval time; { double date; if (rb_thread_critical || curr_thread == curr_thread->next || curr_thread->status == THREAD_TO_KILL) { int n; #ifndef linux double d, limit; limit = timeofday()+(double)time.tv_sec+(double)time.tv_usec*1e-6; #endif for (;;) { TRAP_BEG; n = select(0, 0, 0, 0, &time); TRAP_END; if (n == 0) return; if (n < 0) { switch (errno) { case EINTR: #ifdef ERESTART case ERESTART: #endif return; default: rb_sys_fail("sleep"); } } #ifndef linux d = limit - timeofday(); time.tv_sec = (int)d; time.tv_usec = (int)((d - (int)d)*1e6); if (time.tv_usec < 0) { time.tv_usec += (long)1e6; time.tv_sec -= 1; } if (time.tv_sec < 0) return; #endif } } date = timeofday() + (double)time.tv_sec + (double)time.tv_usec*1e-6; curr_thread->status = THREAD_STOPPED; curr_thread->delay = date; curr_thread->wait_for = WAIT_TIME; rb_thread_schedule(); } void rb_thread_sleep_forever _((void)); int rb_thread_alone() { return curr_thread == curr_thread->next; } int rb_thread_select(max, read, write, except, timeout) int max; fd_set *read, *write, *except; struct timeval *timeout; { double limit; int n; if (!read && !write && !except) { if (!timeout) { rb_thread_sleep_forever(); return 0; } rb_thread_wait_for(*timeout); return 0; } if (timeout) { limit = timeofday()+ (double)timeout->tv_sec+(double)timeout->tv_usec*1e-6; } if (rb_thread_critical || curr_thread == curr_thread->next || curr_thread->status == THREAD_TO_KILL) { #ifndef linux struct timeval tv, *tvp = timeout; if (timeout) { tv = *timeout; tvp = &tv; } #else struct timeval *const tvp = timeout; #endif for (;;) { TRAP_BEG; n = select(max, read, write, except, tvp); TRAP_END; if (n < 0) { switch (errno) { case EINTR: #ifdef ERESTART case ERESTART: #endif #ifndef linux if (timeout) { double d = limit - timeofday(); tv.tv_sec = (unsigned int)d; tv.tv_usec = (long)((d-(double)tv.tv_sec)*1e6); if (tv.tv_sec < 0) tv.tv_sec = 0; if (tv.tv_usec < 0) tv.tv_usec = 0; } #endif continue; default: break; } } return n; } } curr_thread->status = THREAD_STOPPED; if (read) curr_thread->readfds = *read; else FD_ZERO(&curr_thread->readfds); if (write) curr_thread->writefds = *write; else FD_ZERO(&curr_thread->writefds); if (except) curr_thread->exceptfds = *except; else FD_ZERO(&curr_thread->exceptfds); curr_thread->fd = max; curr_thread->wait_for = WAIT_SELECT; if (timeout) { curr_thread->delay = timeofday() + (double)timeout->tv_sec + (double)timeout->tv_usec*1e-6; curr_thread->wait_for |= WAIT_TIME; } rb_thread_schedule(); if (read) *read = curr_thread->readfds; if (write) *write = curr_thread->writefds; if (except) *except = curr_thread->exceptfds; return curr_thread->select_value; } static int rb_thread_join _((rb_thread_t, double)); static int rb_thread_join(th, limit) rb_thread_t th; double limit; { enum thread_status last_status = THREAD_RUNNABLE; if (rb_thread_critical) rb_thread_deadlock(); if (!rb_thread_dead(th)) { if (th == curr_thread) rb_raise(rb_eThreadError, "thread 0x%lx tried to join itself", th->thread); if ((th->wait_for & WAIT_JOIN) && th->join == curr_thread) rb_raise(rb_eThreadError, "Thread#join: deadlock 0x%lx - mutual join(0x%lx)", curr_thread->thread, th->thread); if (curr_thread->status == THREAD_TO_KILL) last_status = THREAD_TO_KILL; if (limit == 0) return Qfalse; curr_thread->status = THREAD_STOPPED; curr_thread->join = th; curr_thread->wait_for = WAIT_JOIN; curr_thread->delay = timeofday() + limit; if (limit < DELAY_INFTY) curr_thread->wait_for |= WAIT_TIME; rb_thread_schedule(); curr_thread->status = last_status; if (!rb_thread_dead(th)) return Qfalse; } if (!NIL_P(th->errinfo) && (th->flags & THREAD_RAISED)) { VALUE oldbt = get_backtrace(th->errinfo); VALUE errat = make_backtrace(); if (TYPE(oldbt) == T_ARRAY && RARRAY(oldbt)->len > 0) { rb_ary_unshift(errat, rb_ary_entry(oldbt, 0)); } set_backtrace(th->errinfo, errat); rb_exc_raise(th->errinfo); } return Qtrue; } static VALUE rb_thread_join_m(argc, argv, thread) int argc; VALUE *argv; VALUE thread; { VALUE limit; double delay = DELAY_INFTY; rb_thread_t th = rb_thread_check(thread); rb_scan_args(argc, argv, "01", &limit); if (!NIL_P(limit)) delay = rb_num2dbl(limit); if (!rb_thread_join(th, delay)) return Qnil; return thread; } VALUE rb_thread_current() { return curr_thread->thread; } VALUE rb_thread_main() { return main_thread->thread; } VALUE rb_thread_list() { rb_thread_t th; VALUE ary = rb_ary_new(); FOREACH_THREAD(th) { switch (th->status) { case THREAD_RUNNABLE: case THREAD_STOPPED: case THREAD_TO_KILL: rb_ary_push(ary, th->thread); default: break; } } END_FOREACH(th); return ary; } VALUE rb_thread_wakeup(thread) VALUE thread; { rb_thread_t th = rb_thread_check(thread); if (th->status == THREAD_KILLED) rb_raise(rb_eThreadError, "killed thread"); rb_thread_ready(th); return thread; } VALUE rb_thread_run(thread) VALUE thread; { rb_thread_wakeup(thread); if (!rb_thread_critical) rb_thread_schedule(); return thread; } VALUE rb_thread_kill(thread) VALUE thread; { rb_thread_t th = rb_thread_check(thread); if (th != curr_thread && th->safe < 4) { rb_secure(4); } if (th->status == THREAD_TO_KILL || th->status == THREAD_KILLED) return thread; if (th == th->next || th == main_thread) rb_exit(0); rb_thread_ready(th); th->status = THREAD_TO_KILL; if (!rb_thread_critical) rb_thread_schedule(); return thread; } static VALUE rb_thread_s_kill(obj, th) VALUE obj, th; { return rb_thread_kill(th); } static VALUE rb_thread_exit() { return rb_thread_kill(curr_thread->thread); } static VALUE rb_thread_pass() { rb_thread_schedule(); return Qnil; } VALUE rb_thread_stop() { enum thread_status last_status = THREAD_RUNNABLE; rb_thread_critical = 0; if (curr_thread == curr_thread->next) { rb_raise(rb_eThreadError, "stopping only thread\n\tnote: use sleep to stop forever"); } if (curr_thread->status == THREAD_TO_KILL) last_status = THREAD_TO_KILL; curr_thread->status = THREAD_STOPPED; rb_thread_schedule(); curr_thread->status = last_status; return Qnil; } struct timeval rb_time_timeval(); void rb_thread_polling() { if (curr_thread != curr_thread->next) { curr_thread->status = THREAD_STOPPED; curr_thread->delay = timeofday() + (double)0.06; curr_thread->wait_for = WAIT_TIME; rb_thread_schedule(); } } void rb_thread_sleep(sec) int sec; { if (curr_thread == curr_thread->next) { TRAP_BEG; sleep(sec); TRAP_END; return; } rb_thread_wait_for(rb_time_timeval(INT2FIX(sec))); } void rb_thread_sleep_forever() { if (curr_thread == curr_thread->next || curr_thread->status == THREAD_TO_KILL) { TRAP_BEG; pause(); TRAP_END; return; } curr_thread->delay = DELAY_INFTY; curr_thread->wait_for = WAIT_TIME; curr_thread->status = THREAD_STOPPED; rb_thread_schedule(); } static VALUE rb_thread_priority(thread) VALUE thread; { return INT2NUM(rb_thread_check(thread)->priority); } static VALUE rb_thread_priority_set(thread, prio) VALUE thread, prio; { rb_thread_t th; rb_secure(4); th = rb_thread_check(thread); th->priority = NUM2INT(prio); rb_thread_schedule(); return prio; } static VALUE rb_thread_safe_level(thread) VALUE thread; { rb_thread_t th; th = rb_thread_check(thread); if (th == curr_thread) { return INT2NUM(ruby_safe_level); } return INT2NUM(th->safe); } static int ruby_thread_abort; static VALUE thgroup_default; static VALUE rb_thread_s_abort_exc() { return ruby_thread_abort?Qtrue:Qfalse; } static VALUE rb_thread_s_abort_exc_set(self, val) VALUE self, val; { rb_secure(4); ruby_thread_abort = RTEST(val); return val; } static VALUE rb_thread_abort_exc(thread) VALUE thread; { return rb_thread_check(thread)->abort?Qtrue:Qfalse; } static VALUE rb_thread_abort_exc_set(thread, val) VALUE thread, val; { rb_secure(4); rb_thread_check(thread)->abort = RTEST(val); return val; } VALUE rb_thread_group(thread) VALUE thread; { VALUE group = rb_thread_check(thread)->thgroup; if (!group) { group = Qnil; } return group; } #ifdef __ia64__ # define IA64_INIT(x) x #else # define IA64_INIT(x) #endif #define THREAD_ALLOC(th) do {\ th = ALLOC(struct thread);\ \ th->next = 0;\ th->prev = 0;\ \ th->status = THREAD_RUNNABLE;\ th->result = 0;\ th->flags = 0;\ \ th->stk_ptr = 0;\ th->stk_len = 0;\ th->stk_max = 0;\ th->wait_for = 0;\ IA64_INIT(th->bstr_ptr = 0);\ IA64_INIT(th->bstr_len = 0);\ FD_ZERO(&th->readfds);\ FD_ZERO(&th->writefds);\ FD_ZERO(&th->exceptfds);\ th->delay = 0.0;\ th->join = 0;\ \ th->frame = 0;\ th->scope = 0;\ th->klass = 0;\ th->wrapper = 0;\ th->cref = ruby_cref;\ th->dyna_vars = ruby_dyna_vars;\ th->block = 0;\ th->iter = 0;\ th->tag = 0;\ th->tracing = 0;\ th->errinfo = Qnil;\ th->last_status = 0;\ th->last_line = 0;\ th->last_match = Qnil;\ th->abort = 0;\ th->priority = 0;\ th->thgroup = thgroup_default;\ th->locals = 0;\ } while (0) static rb_thread_t rb_thread_alloc(klass) VALUE klass; { rb_thread_t th; struct RVarmap *vars; THREAD_ALLOC(th); th->thread = Data_Wrap_Struct(klass, thread_mark, thread_free, th); for (vars = th->dyna_vars; vars; vars = vars->next) { if (FL_TEST(vars, DVAR_DONT_RECYCLE)) break; FL_SET(vars, DVAR_DONT_RECYCLE); } return th; } #if defined(HAVE_SETITIMER) static void catch_timer(sig) int sig; { #if !defined(POSIX_SIGNAL) && !defined(BSD_SIGNAL) signal(sig, catch_timer); #endif if (!rb_thread_critical) { if (rb_trap_immediate) { rb_thread_schedule(); } else rb_thread_pending = 1; } } #else int rb_thread_tick = THREAD_TICK; #endif #if defined(HAVE_SETITIMER) static int thread_init = 0; void rb_thread_start_timer() { struct itimerval tval; if (!thread_init) return; tval.it_interval.tv_sec = 0; tval.it_interval.tv_usec = 10000; tval.it_value = tval.it_interval; setitimer(ITIMER_VIRTUAL, &tval, NULL); } void rb_thread_stop_timer() { struct itimerval tval; if (!thread_init) return; tval.it_interval.tv_sec = 0; tval.it_interval.tv_usec = 0; tval.it_value = tval.it_interval; setitimer(ITIMER_VIRTUAL, &tval, NULL); } #endif static VALUE rb_thread_start_0(fn, arg, th_arg) VALUE (*fn)(); void *arg; rb_thread_t th_arg; { volatile rb_thread_t th = th_arg; volatile VALUE thread = th->thread; volatile struct BLOCK* saved_block = 0; enum thread_status status; int state; if (OBJ_FROZEN(curr_thread->thgroup)) { rb_raise(rb_eThreadError, "can't start a new thread (frozen ThreadGroup)"); } #if defined(HAVE_SETITIMER) if (!thread_init) { #ifdef POSIX_SIGNAL posix_signal(SIGVTALRM, catch_timer); #else signal(SIGVTALRM, catch_timer); #endif thread_init = 1; rb_thread_start_timer(); } #endif if (THREAD_SAVE_CONTEXT(curr_thread)) { return thread; } if (ruby_block) { /* should nail down higher blocks */ struct BLOCK dummy; dummy.prev = ruby_block; blk_copy_prev(&dummy); saved_block = ruby_block = dummy.prev; } scope_dup(ruby_scope); if (!th->next) { /* merge in thread list */ th->prev = curr_thread; curr_thread->next->prev = th; th->next = curr_thread->next; curr_thread->next = th; th->priority = curr_thread->priority; th->thgroup = curr_thread->thgroup; } PUSH_TAG(PROT_THREAD); if ((state = EXEC_TAG()) == 0) { if (THREAD_SAVE_CONTEXT(th) == 0) { curr_thread = th; th->result = (*fn)(arg, th); } } POP_TAG(); status = th->status; if (th == main_thread) ruby_stop(state); rb_thread_remove(th); while (saved_block) { volatile struct BLOCK *tmp = saved_block; if (tmp->frame.argc > 0) free(tmp->frame.argv); saved_block = tmp->prev; free((void*)tmp); } if (state && status != THREAD_TO_KILL && !NIL_P(ruby_errinfo)) { th->flags |= THREAD_RAISED; if (state == TAG_FATAL) { /* fatal error within this thread, need to stop whole script */ main_thread->errinfo = ruby_errinfo; rb_thread_cleanup(); } else if (rb_obj_is_kind_of(ruby_errinfo, rb_eSystemExit)) { if (th->safe >= 4) { char buf[32]; sprintf(buf, "Insecure exit at level %d", th->safe); th->errinfo = rb_exc_new2(rb_eSecurityError, buf); } else { /* delegate exception to main_thread */ rb_thread_main_jump(ruby_errinfo, RESTORE_RAISE); } } else if (th->safe < 4 && (ruby_thread_abort || th->abort || RTEST(ruby_debug))) { /* exit on main_thread */ rb_thread_main_jump(ruby_errinfo, RESTORE_EXIT); } else { th->errinfo = ruby_errinfo; } } rb_thread_schedule(); ruby_stop(0); /* last thread termination */ return 0; /* not reached */ } VALUE rb_thread_create(fn, arg) VALUE (*fn)(); void *arg; { Init_stack((VALUE*)&arg); return rb_thread_start_0(fn, arg, rb_thread_alloc(rb_cThread)); } static VALUE rb_thread_yield(arg, th) VALUE arg; rb_thread_t th; { const ID *tbl; scope_dup(ruby_block->scope); tbl = ruby_scope->local_tbl; if (tbl) { int n = *tbl++; for (tbl += 2, n -= 2; n > 0; --n) { /* skip first 2 ($_ and $~) */ ID id = *tbl++; if (id != 0 && !rb_is_local_id(id)) /* push flip states */ rb_dvar_push(id, Qfalse); } } rb_dvar_push('_', Qnil); rb_dvar_push('~', Qnil); ruby_block->dyna_vars = ruby_dyna_vars; return rb_yield_0(arg, 0, 0, Qtrue, Qtrue); } static VALUE rb_thread_s_new(argc, argv, klass) int argc; VALUE *argv; VALUE klass; { rb_thread_t th = rb_thread_alloc(klass); volatile VALUE *pos; pos = th->stk_pos; rb_obj_call_init(th->thread, argc, argv); if (th->stk_pos == 0) { rb_raise(rb_eThreadError, "uninitialized thread - check `%s#initialize'", rb_class2name(klass)); } return th->thread; } static VALUE rb_thread_initialize(thread, args) VALUE thread, args; { if (!rb_block_given_p()) { rb_raise(rb_eThreadError, "must be called with a block"); } return rb_thread_start_0(rb_thread_yield, args, rb_thread_check(thread)); } static VALUE rb_thread_start(klass, args) VALUE klass, args; { if (!rb_block_given_p()) { rb_raise(rb_eThreadError, "must be called with a block"); } return rb_thread_start_0(rb_thread_yield, args, rb_thread_alloc(klass)); } static VALUE rb_thread_value(thread) VALUE thread; { rb_thread_t th = rb_thread_check(thread); while (!rb_thread_join(th, DELAY_INFTY)); return th->result; } static VALUE rb_thread_status(thread) VALUE thread; { rb_thread_t th = rb_thread_check(thread); if (rb_thread_dead(th)) { if (!NIL_P(th->errinfo) && (th->flags & THREAD_RAISED)) return Qnil; return Qfalse; } return rb_str_new2(thread_status_name(th->status)); } static VALUE rb_thread_alive_p(thread) VALUE thread; { rb_thread_t th = rb_thread_check(thread); if (rb_thread_dead(th)) return Qfalse; return Qtrue; } static VALUE rb_thread_stop_p(thread) VALUE thread; { rb_thread_t th = rb_thread_check(thread); if (rb_thread_dead(th)) return Qtrue; if (th->status == THREAD_STOPPED) return Qtrue; return Qfalse; } static void rb_thread_wait_other_threads() { rb_thread_t th; int found; /* wait other threads to terminate */ while (curr_thread != curr_thread->next) { found = 0; FOREACH_THREAD(th) { if (th != curr_thread && th->status != THREAD_STOPPED) { found = 1; break; } } END_FOREACH(th); if (!found) return; rb_thread_schedule(); } } static void rb_thread_cleanup() { rb_thread_t curr, th; curr = curr_thread; while (curr->status == THREAD_KILLED) { curr = curr->prev; } FOREACH_THREAD_FROM(curr, th) { if (th->status != THREAD_KILLED) { rb_thread_ready(th); th->thgroup = 0; th->priority = 0; if (th != main_thread) { th->status = THREAD_TO_KILL; RDATA(th->thread)->dfree = NULL; } } } END_FOREACH_FROM(curr, th); } int rb_thread_critical; static VALUE rb_thread_critical_get() { return rb_thread_critical?Qtrue:Qfalse; } static VALUE rb_thread_critical_set(obj, val) VALUE obj, val; { rb_thread_critical = RTEST(val); return val; } void rb_thread_interrupt() { rb_thread_critical = 0; rb_thread_ready(main_thread); if (curr_thread == main_thread) { rb_interrupt(); } if (!rb_thread_dead(curr_thread)) { if (THREAD_SAVE_CONTEXT(curr_thread)) { return; } } curr_thread = main_thread; rb_thread_restore_context(curr_thread, RESTORE_INTERRUPT); } void rb_thread_signal_raise(sig) char *sig; { if (sig == 0) return; /* should not happen */ rb_thread_critical = 0; if (curr_thread == main_thread) { rb_thread_ready(curr_thread); rb_raise(rb_eSignal, "SIG%s", sig); } rb_thread_ready(main_thread); if (!rb_thread_dead(curr_thread)) { if (THREAD_SAVE_CONTEXT(curr_thread)) { return; } } th_signm = sig; curr_thread = main_thread; rb_thread_restore_context(curr_thread, RESTORE_SIGNAL); } void rb_thread_trap_eval(cmd, sig) VALUE cmd; int sig; { #if 0 rb_thread_critical = 0; if (!rb_thread_dead(curr_thread)) { rb_thread_ready(curr_thread); rb_trap_eval(cmd, sig); return; } rb_thread_ready(main_thread); if (THREAD_SAVE_CONTEXT(curr_thread)) { return; } th_cmd = cmd; th_sig = sig; curr_thread = main_thread; rb_thread_restore_context(curr_thread, RESTORE_TRAP); #else rb_thread_critical = 0; if (!rb_thread_dead(curr_thread)) { if (THREAD_SAVE_CONTEXT(curr_thread)) { return; } } th_cmd = cmd; th_sig = sig; curr_thread = main_thread; rb_thread_restore_context(curr_thread, RESTORE_TRAP); #endif } static VALUE rb_thread_raise(argc, argv, th) int argc; VALUE *argv; volatile rb_thread_t th; { if (rb_thread_dead(th)) return Qnil; if (curr_thread == th) { rb_f_raise(argc, argv); } if (!rb_thread_dead(curr_thread)) { if (THREAD_SAVE_CONTEXT(curr_thread)) { return th->thread; } } rb_scan_args(argc, argv, "11", &th_raise_argv[0], &th_raise_argv[1]); rb_thread_ready(th); curr_thread = th; th_raise_argc = argc; th_raise_node = ruby_current_node; rb_thread_restore_context(curr_thread, RESTORE_RAISE); return Qnil; /* not reached */ } static VALUE rb_thread_raise_m(argc, argv, thread) int argc; VALUE *argv; VALUE thread; { rb_thread_t th = rb_thread_check(thread); if (ruby_safe_level > th->safe) { rb_secure(4); } rb_thread_raise(argc, argv, th); return Qnil; /* not reached */ } VALUE rb_thread_local_aref(thread, id) VALUE thread; ID id; { rb_thread_t th; VALUE val; th = rb_thread_check(thread); if (ruby_safe_level >= 4 && th != curr_thread) { rb_raise(rb_eSecurityError, "Insecure: thread locals"); } if (!th->locals) return Qnil; if (st_lookup(th->locals, id, &val)) { return val; } return Qnil; } static VALUE rb_thread_aref(thread, id) VALUE thread, id; { return rb_thread_local_aref(thread, rb_to_id(id)); } VALUE rb_thread_local_aset(thread, id, val) VALUE thread; ID id; VALUE val; { rb_thread_t th = rb_thread_check(thread); if (ruby_safe_level >= 4 && th != curr_thread) { rb_raise(rb_eSecurityError, "Insecure: can't modify thread locals"); } if (OBJ_FROZEN(thread)) rb_error_frozen("thread locals"); if (!th->locals) { th->locals = st_init_numtable(); } if (NIL_P(val)) { st_delete(th->locals, (st_data_t*)&id, 0); return Qnil; } st_insert(th->locals, id, val); return val; } static VALUE rb_thread_aset(thread, id, val) VALUE thread, id, val; { return rb_thread_local_aset(thread, rb_to_id(id), val); } static VALUE rb_thread_key_p(thread, id) VALUE thread, id; { rb_thread_t th = rb_thread_check(thread); if (!th->locals) return Qfalse; if (st_lookup(th->locals, rb_to_id(id), 0)) return Qtrue; return Qfalse; } static int thread_keys_i(key, value, ary) ID key; VALUE value, ary; { rb_ary_push(ary, ID2SYM(key)); return ST_CONTINUE; } static VALUE rb_thread_keys(thread) VALUE thread; { rb_thread_t th = rb_thread_check(thread); VALUE ary = rb_ary_new(); if (th->locals) { st_foreach(th->locals, thread_keys_i, ary); } return ary; } static VALUE rb_thread_inspect(thread) VALUE thread; { char *cname = rb_obj_classname(thread); rb_thread_t th = rb_thread_check(thread); const char *status = thread_status_name(th->status); VALUE str; str = rb_str_new(0, strlen(cname)+7+16+9+1); /* 7:tags 16:addr 9:status 1:nul */ sprintf(RSTRING(str)->ptr, "#<%s:0x%lx %s>", cname, thread, status); RSTRING(str)->len = strlen(RSTRING(str)->ptr); OBJ_INFECT(str, thread); return str; } void rb_thread_atfork() { rb_thread_t th; if (rb_thread_alone()) return; FOREACH_THREAD(th) { if (th != curr_thread) { rb_warn("fork terminates thread at %s:%d", th->node->nd_file, nd_line(th->node)); rb_thread_die(th); } } END_FOREACH(th); main_thread = curr_thread; curr_thread->next = curr_thread; curr_thread->prev = curr_thread; } static VALUE rb_cCont; static VALUE rb_callcc(self) VALUE self; { volatile VALUE cont; volatile rb_thread_t th; struct tag *tag; struct RVarmap *vars; THREAD_ALLOC(th); cont = Data_Wrap_Struct(rb_cCont, thread_mark, thread_free, th); scope_dup(ruby_scope); for (tag=prot_tag; tag; tag=tag->prev) { scope_dup(tag->scope); } th->thread = curr_thread->thread; for (vars = th->dyna_vars; vars; vars = vars->next) { if (FL_TEST(vars, DVAR_DONT_RECYCLE)) break; FL_SET(vars, DVAR_DONT_RECYCLE); } if (THREAD_SAVE_CONTEXT(th)) { return th->result; } else { return rb_yield(cont); } } static VALUE rb_cont_call(argc, argv, cont) int argc; VALUE *argv; VALUE cont; { rb_thread_t th = rb_thread_check(cont); if (th->thread != curr_thread->thread) { rb_raise(rb_eRuntimeError, "continuation called across threads"); } switch (argc) { case 0: th->result = Qnil; break; case 1: th->result = argv[0]; break; default: th->result = rb_ary_new4(argc, argv); break; } rb_thread_restore_context(th, RESTORE_NORMAL); return Qnil; } struct thgroup { int enclosed; VALUE group; }; static VALUE thgroup_s_alloc _((VALUE)); static VALUE thgroup_s_alloc(klass) VALUE klass; { VALUE group; struct thgroup *data; group = Data_Make_Struct(klass, struct thgroup, 0, free, data); data->enclosed = 0; data->group = group; return group; } static VALUE thgroup_list(group) VALUE group; { struct thgroup *data; rb_thread_t th; VALUE ary; Data_Get_Struct(group, struct thgroup, data); ary = rb_ary_new(); FOREACH_THREAD(th) { if (th->thgroup == data->group) { rb_ary_push(ary, th->thread); } } END_FOREACH(th); return ary; } VALUE thgroup_enclose(group) VALUE group; { struct thgroup *data; Data_Get_Struct(group, struct thgroup, data); data->enclosed = 1; return group; } static VALUE thgroup_enclosed_p(group) VALUE group; { struct thgroup *data; Data_Get_Struct(group, struct thgroup, data); if (data->enclosed) return Qtrue; return Qfalse; } static VALUE thgroup_add(group, thread) VALUE group, thread; { rb_thread_t th; struct thgroup *data; rb_secure(4); th = rb_thread_check(thread); if (OBJ_FROZEN(group)) { rb_raise(rb_eThreadError, "can't move to the frozen thread group"); } Data_Get_Struct(group, struct thgroup, data); if (data->enclosed) { rb_raise(rb_eThreadError, "can't move to the enclosed thread group"); } if (!th->thgroup) { return Qnil; } if (OBJ_FROZEN(th->thgroup)) { rb_raise(rb_eThreadError, "can't move from the frozen thread group"); } Data_Get_Struct(th->thgroup, struct thgroup, data); if (data->enclosed) { rb_raise(rb_eThreadError, "can't move from the enclosed thread group"); } th->thgroup = group; return group; } void Init_Thread() { VALUE cThGroup; rb_eThreadError = rb_define_class("ThreadError", rb_eStandardError); rb_cThread = rb_define_class("Thread", rb_cObject); rb_undef_alloc_func(rb_cThread); rb_define_singleton_method(rb_cThread, "new", rb_thread_s_new, -1); rb_define_method(rb_cThread, "initialize", rb_thread_initialize, -2); rb_define_singleton_method(rb_cThread, "start", rb_thread_start, -2); rb_define_singleton_method(rb_cThread, "fork", rb_thread_start, -2); rb_define_singleton_method(rb_cThread, "stop", rb_thread_stop, 0); rb_define_singleton_method(rb_cThread, "kill", rb_thread_s_kill, 1); rb_define_singleton_method(rb_cThread, "exit", rb_thread_exit, 0); rb_define_singleton_method(rb_cThread, "pass", rb_thread_pass, 0); rb_define_singleton_method(rb_cThread, "current", rb_thread_current, 0); rb_define_singleton_method(rb_cThread, "main", rb_thread_main, 0); rb_define_singleton_method(rb_cThread, "list", rb_thread_list, 0); rb_define_singleton_method(rb_cThread, "critical", rb_thread_critical_get, 0); rb_define_singleton_method(rb_cThread, "critical=", rb_thread_critical_set, 1); rb_define_singleton_method(rb_cThread, "abort_on_exception", rb_thread_s_abort_exc, 0); rb_define_singleton_method(rb_cThread, "abort_on_exception=", rb_thread_s_abort_exc_set, 1); rb_define_method(rb_cThread, "run", rb_thread_run, 0); rb_define_method(rb_cThread, "wakeup", rb_thread_wakeup, 0); rb_define_method(rb_cThread, "kill", rb_thread_kill, 0); rb_define_method(rb_cThread, "terminate", rb_thread_kill, 0); rb_define_method(rb_cThread, "exit", rb_thread_kill, 0); rb_define_method(rb_cThread, "value", rb_thread_value, 0); rb_define_method(rb_cThread, "status", rb_thread_status, 0); rb_define_method(rb_cThread, "join", rb_thread_join_m, -1); rb_define_method(rb_cThread, "alive?", rb_thread_alive_p, 0); rb_define_method(rb_cThread, "stop?", rb_thread_stop_p, 0); rb_define_method(rb_cThread, "raise", rb_thread_raise_m, -1); rb_define_method(rb_cThread, "abort_on_exception", rb_thread_abort_exc, 0); rb_define_method(rb_cThread, "abort_on_exception=", rb_thread_abort_exc_set, 1); rb_define_method(rb_cThread, "priority", rb_thread_priority, 0); rb_define_method(rb_cThread, "priority=", rb_thread_priority_set, 1); rb_define_method(rb_cThread, "safe_level", rb_thread_safe_level, 0); rb_define_method(rb_cThread, "group", rb_thread_group, 0); rb_define_method(rb_cThread, "[]", rb_thread_aref, 1); rb_define_method(rb_cThread, "[]=", rb_thread_aset, 2); rb_define_method(rb_cThread, "key?", rb_thread_key_p, 1); rb_define_method(rb_cThread, "keys", rb_thread_keys, 0); rb_define_method(rb_cThread, "inspect", rb_thread_inspect, 0); rb_cCont = rb_define_class("Continuation", rb_cObject); rb_undef_alloc_func(rb_cCont); rb_undef_method(CLASS_OF(rb_cCont), "new"); rb_define_method(rb_cCont, "call", rb_cont_call, -1); rb_define_method(rb_cCont, "[]", rb_cont_call, -1); rb_define_global_function("callcc", rb_callcc, 0); cThGroup = rb_define_class("ThreadGroup", rb_cObject); rb_define_alloc_func(cThGroup, thgroup_s_alloc); rb_define_method(cThGroup, "list", thgroup_list, 0); rb_define_method(cThGroup, "enclose", thgroup_enclose, 0); rb_define_method(cThGroup, "enclosed?", thgroup_enclosed_p, 0); rb_define_method(cThGroup, "add", thgroup_add, 1); thgroup_default = rb_obj_alloc(cThGroup); rb_define_const(cThGroup, "Default", thgroup_default); rb_global_variable(&thgroup_default); /* allocate main thread */ main_thread = rb_thread_alloc(rb_cThread); curr_thread = main_thread->prev = main_thread->next = main_thread; } static VALUE rb_f_catch(dmy, tag) VALUE dmy, tag; { int state; VALUE val = Qnil; /* OK */ tag = ID2SYM(rb_to_id(tag)); PUSH_TAG(tag); if ((state = EXEC_TAG()) == 0) { val = rb_yield_0(tag, 0, 0, Qfalse, Qfalse); } else if (state == TAG_THROW && tag == prot_tag->dst) { val = prot_tag->retval; state = 0; } POP_TAG(); if (state) JUMP_TAG(state); return val; } static VALUE catch_i(tag) VALUE tag; { return rb_funcall(Qnil, rb_intern("catch"), 1, tag); } VALUE rb_catch(tag, func, data) const char *tag; VALUE (*func)(); VALUE data; { return rb_iterate((VALUE(*)_((VALUE)))catch_i, ID2SYM(rb_intern(tag)), func, data); } static VALUE rb_f_throw(argc, argv) int argc; VALUE *argv; { VALUE tag, value; struct tag *tt = prot_tag; rb_scan_args(argc, argv, "11", &tag, &value); tag = ID2SYM(rb_to_id(tag)); while (tt) { if (tt->tag == tag) { tt->dst = tag; tt->retval = value; break; } if (tt->tag == PROT_THREAD) { rb_raise(rb_eThreadError, "uncaught throw `%s' in thread 0x%lx", rb_id2name(SYM2ID(tag)), curr_thread); } tt = tt->prev; } if (!tt) { rb_name_error(SYM2ID(tag), "uncaught throw `%s'", rb_id2name(SYM2ID(tag))); } rb_trap_restore_mask(); JUMP_TAG(TAG_THROW); #ifndef __GNUC__ return Qnil; /* not reached */ #endif } void rb_throw(tag, val) const char *tag; VALUE val; { VALUE argv[2]; argv[0] = ID2SYM(rb_intern(tag)); argv[1] = val; rb_f_throw(2, argv); }