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mbed I/F binding for mruby
Dependents: mruby_mbed_web mirb_mbed
mbed-mruby
How to use
Class
src/vm.c
- Committer:
- mzta
- Date:
- 2015-04-13
- Revision:
- 1:8ccd1d494a4b
- Parent:
- 0:158c61bb030f
File content as of revision 1:8ccd1d494a4b:
/*
** vm.c - virtual machine for mruby
**
** See Copyright Notice in mruby.h
*/
#include <stddef.h>
#include <stdarg.h>
#include <math.h>
#include "mruby.h"
#include "mruby/array.h"
#include "mruby/class.h"
#include "mruby/hash.h"
#include "mruby/irep.h"
#include "mruby/numeric.h"
#include "mruby/proc.h"
#include "mruby/range.h"
#include "mruby/string.h"
#include "mruby/variable.h"
#include "mruby/error.h"
#include "mruby/opcode.h"
#include "value_array.h"
#include "mrb_throw.h"
#ifndef ENABLE_STDIO
#if defined(__cplusplus)
extern "C" {
#endif
void abort(void);
#if defined(__cplusplus)
} /* extern "C" { */
#endif
#endif
#define STACK_INIT_SIZE 128
#define CALLINFO_INIT_SIZE 32
/* Define amount of linear stack growth. */
#ifndef MRB_STACK_GROWTH
#define MRB_STACK_GROWTH 128
#endif
/* Maximum stack depth. Should be set lower on memory constrained systems.
The value below allows about 60000 recursive calls in the simplest case. */
#ifndef MRB_STACK_MAX
#define MRB_STACK_MAX (0x40000 - MRB_STACK_GROWTH)
#endif
#ifdef VM_DEBUG
# define DEBUG(x) (x)
#else
# define DEBUG(x)
#endif
#define ARENA_RESTORE(mrb,ai) (mrb)->arena_idx = (ai)
static inline void
stack_clear(mrb_value *from, size_t count)
{
#ifndef MRB_NAN_BOXING
const mrb_value mrb_value_zero = { { 0 } };
while (count-- > 0) {
*from++ = mrb_value_zero;
}
#else
while (count-- > 0) {
SET_NIL_VALUE(*from);
from++;
}
#endif
}
static inline void
stack_copy(mrb_value *dst, const mrb_value *src, size_t size)
{
while (size-- > 0) {
*dst++ = *src++;
}
}
static void
stack_init(mrb_state *mrb)
{
struct mrb_context *c = mrb->c;
/* mrb_assert(mrb->stack == NULL); */
c->stbase = (mrb_value *)mrb_calloc(mrb, STACK_INIT_SIZE, sizeof(mrb_value));
c->stend = c->stbase + STACK_INIT_SIZE;
c->stack = c->stbase;
/* mrb_assert(ci == NULL); */
c->cibase = (mrb_callinfo *)mrb_calloc(mrb, CALLINFO_INIT_SIZE, sizeof(mrb_callinfo));
c->ciend = c->cibase + CALLINFO_INIT_SIZE;
c->ci = c->cibase;
c->ci->target_class = mrb->object_class;
c->ci->stackent = c->stack;
}
static inline void
envadjust(mrb_state *mrb, mrb_value *oldbase, mrb_value *newbase)
{
mrb_callinfo *ci = mrb->c->cibase;
if (newbase == oldbase) return;
while (ci <= mrb->c->ci) {
struct REnv *e = ci->env;
if (e && MRB_ENV_STACK_SHARED_P(e)) {
ptrdiff_t off = e->stack - oldbase;
e->stack = newbase + off;
}
ci->stackent = newbase + (ci->stackent - oldbase);
ci++;
}
}
static inline void
init_new_stack_space(mrb_state *mrb, int room, int keep)
{
if (room > keep) {
/* do not leave uninitialized malloc region */
stack_clear(&(mrb->c->stack[keep]), room - keep);
}
}
/** def rec ; $deep =+ 1 ; if $deep > 1000 ; return 0 ; end ; rec ; end */
static void
stack_extend_alloc(mrb_state *mrb, int room, int keep)
{
mrb_value *oldbase = mrb->c->stbase;
int size = mrb->c->stend - mrb->c->stbase;
int off = mrb->c->stack - mrb->c->stbase;
#ifdef MRB_STACK_EXTEND_DOUBLING
if (room <= size)
size *= 2;
else
size += room;
#else
/* Use linear stack growth.
It is slightly slower than doubling the stack space,
but it saves memory on small devices. */
if (room <= MRB_STACK_GROWTH)
size += MRB_STACK_GROWTH;
else
size += room;
#endif
mrb->c->stbase = (mrb_value *)mrb_realloc(mrb, mrb->c->stbase, sizeof(mrb_value) * size);
mrb->c->stack = mrb->c->stbase + off;
mrb->c->stend = mrb->c->stbase + size;
envadjust(mrb, oldbase, mrb->c->stbase);
/* Raise an exception if the new stack size will be too large,
to prevent infinite recursion. However, do this only after resizing the stack, so mrb_raise has stack space to work with. */
if (size > MRB_STACK_MAX) {
init_new_stack_space(mrb, room, keep);
mrb_raise(mrb, E_SYSSTACK_ERROR, "stack level too deep. (limit=" MRB_STRINGIZE(MRB_STACK_MAX) ")");
}
}
static inline void
stack_extend(mrb_state *mrb, int room, int keep)
{
if (mrb->c->stack + room >= mrb->c->stend) {
stack_extend_alloc(mrb, room, keep);
}
init_new_stack_space(mrb, room, keep);
}
static inline struct REnv*
uvenv(mrb_state *mrb, int up)
{
struct REnv *e = mrb->c->ci->proc->env;
while (up--) {
if (!e) return NULL;
e = (struct REnv*)e->c;
}
return e;
}
static inline mrb_bool
is_strict(mrb_state *mrb, struct REnv *e)
{
int cioff = e->cioff;
if (MRB_ENV_STACK_SHARED_P(e) && mrb->c->cibase[cioff].proc &&
MRB_PROC_STRICT_P(mrb->c->cibase[cioff].proc)) {
return TRUE;
}
return FALSE;
}
static inline struct REnv*
top_env(mrb_state *mrb, struct RProc *proc)
{
struct REnv *e = proc->env;
if (is_strict(mrb, e)) return e;
while (e->c) {
e = (struct REnv*)e->c;
if (is_strict(mrb, e)) return e;
}
return e;
}
#define CI_ACC_SKIP -1
#define CI_ACC_DIRECT -2
static mrb_callinfo*
cipush(mrb_state *mrb)
{
struct mrb_context *c = mrb->c;
mrb_callinfo *ci = c->ci;
int eidx = ci->eidx;
int ridx = ci->ridx;
if (ci + 1 == c->ciend) {
size_t size = ci - c->cibase;
c->cibase = (mrb_callinfo *)mrb_realloc(mrb, c->cibase, sizeof(mrb_callinfo)*size*2);
c->ci = c->cibase + size;
c->ciend = c->cibase + size * 2;
}
ci = ++c->ci;
ci->eidx = eidx;
ci->ridx = ridx;
ci->env = 0;
ci->pc = 0;
ci->err = 0;
ci->proc = 0;
return ci;
}
static void
cipop(mrb_state *mrb)
{
struct mrb_context *c = mrb->c;
if (c->ci->env) {
struct REnv *e = c->ci->env;
size_t len = (size_t)MRB_ENV_STACK_LEN(e);
mrb_value *p = (mrb_value *)mrb_malloc(mrb, sizeof(mrb_value)*len);
MRB_ENV_UNSHARE_STACK(e);
if (len > 0) {
stack_copy(p, e->stack, len);
}
e->stack = p;
mrb_write_barrier(mrb, (struct RBasic *)e);
}
c->ci--;
}
static void
ecall(mrb_state *mrb, int i)
{
struct RProc *p;
mrb_callinfo *ci;
mrb_value *self = mrb->c->stack;
struct RObject *exc;
p = mrb->c->ensure[i];
if (!p) return;
if (mrb->c->ci->eidx > i)
mrb->c->ci->eidx = i;
ci = cipush(mrb);
ci->stackent = mrb->c->stack;
ci->mid = ci[-1].mid;
ci->acc = CI_ACC_SKIP;
ci->argc = 0;
ci->proc = p;
ci->nregs = p->body.irep->nregs;
ci->target_class = p->target_class;
mrb->c->stack = mrb->c->stack + ci[-1].nregs;
exc = mrb->exc; mrb->exc = 0;
mrb_run(mrb, p, *self);
mrb->c->ensure[i] = NULL;
if (!mrb->exc) mrb->exc = exc;
}
#ifndef MRB_FUNCALL_ARGC_MAX
#define MRB_FUNCALL_ARGC_MAX 16
#endif
MRB_API mrb_value
mrb_funcall(mrb_state *mrb, mrb_value self, const char *name, mrb_int argc, ...)
{
mrb_value argv[MRB_FUNCALL_ARGC_MAX];
va_list ap;
mrb_int i;
mrb_sym mid = mrb_intern_cstr(mrb, name);
if (argc > MRB_FUNCALL_ARGC_MAX) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "Too long arguments. (limit=" MRB_STRINGIZE(MRB_FUNCALL_ARGC_MAX) ")");
}
va_start(ap, argc);
for (i = 0; i < argc; i++) {
argv[i] = va_arg(ap, mrb_value);
}
va_end(ap);
return mrb_funcall_argv(mrb, self, mid, argc, argv);
}
MRB_API mrb_value
mrb_funcall_with_block(mrb_state *mrb, mrb_value self, mrb_sym mid, mrb_int argc, const mrb_value *argv, mrb_value blk)
{
mrb_value val;
if (!mrb->jmp) {
struct mrb_jmpbuf c_jmp;
mrb_callinfo *old_ci = mrb->c->ci;
MRB_TRY(&c_jmp) {
mrb->jmp = &c_jmp;
/* recursive call */
val = mrb_funcall_with_block(mrb, self, mid, argc, argv, blk);
mrb->jmp = 0;
}
MRB_CATCH(&c_jmp) { /* error */
while (old_ci != mrb->c->ci) {
mrb->c->stack = mrb->c->ci->stackent;
cipop(mrb);
}
mrb->jmp = 0;
val = mrb_obj_value(mrb->exc);
}
MRB_END_EXC(&c_jmp);
}
else {
struct RProc *p;
struct RClass *c;
mrb_sym undef = 0;
mrb_callinfo *ci;
int n;
if (!mrb->c->stack) {
stack_init(mrb);
}
n = mrb->c->ci->nregs;
if (argc < 0) {
mrb_raisef(mrb, E_ARGUMENT_ERROR, "negative argc for funcall (%S)", mrb_fixnum_value(argc));
}
c = mrb_class(mrb, self);
p = mrb_method_search_vm(mrb, &c, mid);
if (!p) {
undef = mid;
mid = mrb_intern_lit(mrb, "method_missing");
p = mrb_method_search_vm(mrb, &c, mid);
n++; argc++;
}
ci = cipush(mrb);
ci->mid = mid;
ci->proc = p;
ci->stackent = mrb->c->stack;
ci->argc = argc;
ci->target_class = c;
mrb->c->stack = mrb->c->stack + n;
if (MRB_PROC_CFUNC_P(p)) {
ci->nregs = argc + 2;
stack_extend(mrb, ci->nregs, 0);
}
else {
ci->nregs = p->body.irep->nregs + n;
stack_extend(mrb, ci->nregs, argc+2);
}
mrb->c->stack[0] = self;
if (undef) {
mrb->c->stack[1] = mrb_symbol_value(undef);
if (argc > 1) {
stack_copy(mrb->c->stack+2, argv, argc-1);
}
}
else if (argc > 0) {
stack_copy(mrb->c->stack+1, argv, argc);
}
mrb->c->stack[argc+1] = blk;
if (MRB_PROC_CFUNC_P(p)) {
int ai = mrb_gc_arena_save(mrb);
ci->acc = CI_ACC_DIRECT;
val = p->body.func(mrb, self);
mrb->c->stack = mrb->c->ci->stackent;
cipop(mrb);
mrb_gc_arena_restore(mrb, ai);
}
else {
ci->acc = CI_ACC_SKIP;
val = mrb_run(mrb, p, self);
}
}
mrb_gc_protect(mrb, val);
return val;
}
MRB_API mrb_value
mrb_funcall_argv(mrb_state *mrb, mrb_value self, mrb_sym mid, mrb_int argc, const mrb_value *argv)
{
return mrb_funcall_with_block(mrb, self, mid, argc, argv, mrb_nil_value());
}
/* 15.3.1.3.4 */
/* 15.3.1.3.44 */
/*
* call-seq:
* obj.send(symbol [, args...]) -> obj
* obj.__send__(symbol [, args...]) -> obj
*
* Invokes the method identified by _symbol_, passing it any
* arguments specified. You can use <code>__send__</code> if the name
* +send+ clashes with an existing method in _obj_.
*
* class Klass
* def hello(*args)
* "Hello " + args.join(' ')
* end
* end
* k = Klass.new
* k.send :hello, "gentle", "readers" #=> "Hello gentle readers"
*/
MRB_API mrb_value
mrb_f_send(mrb_state *mrb, mrb_value self)
{
mrb_sym name;
mrb_value block, *argv, *regs;
mrb_int argc, i, len;
struct RProc *p;
struct RClass *c;
mrb_callinfo *ci;
mrb_get_args(mrb, "n*&", &name, &argv, &argc, &block);
c = mrb_class(mrb, self);
p = mrb_method_search_vm(mrb, &c, name);
if (!p) { /* call method_mising */
return mrb_funcall_with_block(mrb, self, name, argc, argv, block);
}
ci = mrb->c->ci;
ci->mid = name;
ci->target_class = c;
ci->proc = p;
regs = mrb->c->stack+1;
/* remove first symbol from arguments */
if (ci->argc >= 0) {
for (i=0,len=ci->argc; i<len; i++) {
regs[i] = regs[i+1];
}
ci->argc--;
}
else { /* variable length arguments */
mrb_ary_shift(mrb, regs[0]);
}
if (MRB_PROC_CFUNC_P(p)) {
return p->body.func(mrb, self);
}
ci->nregs = p->body.irep->nregs;
ci = cipush(mrb);
ci->nregs = 0;
ci->target_class = 0;
ci->pc = p->body.irep->iseq;
ci->stackent = mrb->c->stack;
ci->acc = 0;
return self;
}
static mrb_value
eval_under(mrb_state *mrb, mrb_value self, mrb_value blk, struct RClass *c)
{
struct RProc *p;
mrb_callinfo *ci;
if (mrb_nil_p(blk)) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "no block given");
}
ci = mrb->c->ci;
if (ci->acc == CI_ACC_DIRECT) {
return mrb_yield_with_class(mrb, blk, 0, 0, self, c);
}
ci->target_class = c;
p = mrb_proc_ptr(blk);
ci->proc = p;
if (MRB_PROC_CFUNC_P(p)) {
return p->body.func(mrb, self);
}
ci->nregs = p->body.irep->nregs;
ci = cipush(mrb);
ci->nregs = 0;
ci->target_class = 0;
ci->pc = p->body.irep->iseq;
ci->stackent = mrb->c->stack;
ci->acc = 0;
return self;
}
/* 15.2.2.4.35 */
/*
* call-seq:
* mod.class_eval {| | block } -> obj
* mod.module_eval {| | block } -> obj
*
* Evaluates block in the context of _mod_. This can
* be used to add methods to a class. <code>module_eval</code> returns
* the result of evaluating its argument.
*/
mrb_value
mrb_mod_module_eval(mrb_state *mrb, mrb_value mod)
{
mrb_value a, b;
if (mrb_get_args(mrb, "|S&", &a, &b) == 1) {
mrb_raise(mrb, E_NOTIMP_ERROR, "module_eval/class_eval with string not implemented");
}
return eval_under(mrb, mod, b, mrb_class_ptr(mod));
}
/* 15.3.1.3.18 */
/*
* call-seq:
* obj.instance_eval {| | block } -> obj
*
* Evaluates the given block,within the context of the receiver (_obj_).
* In order to set the context, the variable +self+ is set to _obj_ while
* the code is executing, giving the code access to _obj_'s
* instance variables. In the version of <code>instance_eval</code>
* that takes a +String+, the optional second and third
* parameters supply a filename and starting line number that are used
* when reporting compilation errors.
*
* class KlassWithSecret
* def initialize
* @secret = 99
* end
* end
* k = KlassWithSecret.new
* k.instance_eval { @secret } #=> 99
*/
mrb_value
mrb_obj_instance_eval(mrb_state *mrb, mrb_value self)
{
mrb_value a, b;
mrb_value cv;
struct RClass *c;
if (mrb_get_args(mrb, "|S&", &a, &b) == 1) {
mrb_raise(mrb, E_NOTIMP_ERROR, "instance_eval with string not implemented");
}
switch (mrb_type(self)) {
case MRB_TT_SYMBOL:
case MRB_TT_FIXNUM:
case MRB_TT_FLOAT:
c = 0;
break;
default:
cv = mrb_singleton_class(mrb, self);
c = mrb_class_ptr(cv);
break;
}
return eval_under(mrb, self, b, c);
}
MRB_API mrb_value
mrb_yield_with_class(mrb_state *mrb, mrb_value b, mrb_int argc, const mrb_value *argv, mrb_value self, struct RClass *c)
{
struct RProc *p;
mrb_sym mid = mrb->c->ci->mid;
mrb_callinfo *ci;
int n = mrb->c->ci->nregs;
mrb_value val;
if (mrb_nil_p(b)) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "no block given");
}
p = mrb_proc_ptr(b);
ci = cipush(mrb);
ci->mid = mid;
ci->proc = p;
ci->stackent = mrb->c->stack;
ci->argc = argc;
ci->target_class = c;
ci->acc = CI_ACC_SKIP;
mrb->c->stack = mrb->c->stack + n;
if (MRB_PROC_CFUNC_P(p)) {
ci->nregs = argc + 2;
stack_extend(mrb, ci->nregs, 0);
}
else {
ci->nregs = p->body.irep->nregs;
stack_extend(mrb, ci->nregs, argc+2);
}
mrb->c->stack[0] = self;
if (argc > 0) {
stack_copy(mrb->c->stack+1, argv, argc);
}
mrb->c->stack[argc+1] = mrb_nil_value();
if (MRB_PROC_CFUNC_P(p)) {
val = p->body.func(mrb, self);
mrb->c->stack = mrb->c->ci->stackent;
cipop(mrb);
}
else {
val = mrb_run(mrb, p, self);
}
return val;
}
MRB_API mrb_value
mrb_yield_argv(mrb_state *mrb, mrb_value b, mrb_int argc, const mrb_value *argv)
{
struct RProc *p = mrb_proc_ptr(b);
return mrb_yield_with_class(mrb, b, argc, argv, p->env->stack[0], p->target_class);
}
MRB_API mrb_value
mrb_yield(mrb_state *mrb, mrb_value b, mrb_value arg)
{
struct RProc *p = mrb_proc_ptr(b);
return mrb_yield_with_class(mrb, b, 1, &arg, p->env->stack[0], p->target_class);
}
typedef enum {
LOCALJUMP_ERROR_RETURN = 0,
LOCALJUMP_ERROR_BREAK = 1,
LOCALJUMP_ERROR_YIELD = 2
} localjump_error_kind;
static void
localjump_error(mrb_state *mrb, localjump_error_kind kind)
{
char kind_str[3][7] = { "return", "break", "yield" };
char kind_str_len[] = { 6, 5, 5 };
static const char lead[] = "unexpected ";
mrb_value msg;
mrb_value exc;
msg = mrb_str_buf_new(mrb, sizeof(lead) + 7);
mrb_str_cat(mrb, msg, lead, sizeof(lead) - 1);
mrb_str_cat(mrb, msg, kind_str[kind], kind_str_len[kind]);
exc = mrb_exc_new_str(mrb, E_LOCALJUMP_ERROR, msg);
mrb->exc = mrb_obj_ptr(exc);
}
static void
argnum_error(mrb_state *mrb, mrb_int num)
{
mrb_value exc;
mrb_value str;
if (mrb->c->ci->mid) {
str = mrb_format(mrb, "'%S': wrong number of arguments (%S for %S)",
mrb_sym2str(mrb, mrb->c->ci->mid),
mrb_fixnum_value(mrb->c->ci->argc), mrb_fixnum_value(num));
}
else {
str = mrb_format(mrb, "wrong number of arguments (%S for %S)",
mrb_fixnum_value(mrb->c->ci->argc), mrb_fixnum_value(num));
}
exc = mrb_exc_new_str(mrb, E_ARGUMENT_ERROR, str);
mrb->exc = mrb_obj_ptr(exc);
}
#define ERR_PC_SET(mrb, pc) mrb->c->ci->err = pc;
#define ERR_PC_CLR(mrb) mrb->c->ci->err = 0;
#ifdef ENABLE_DEBUG
#define CODE_FETCH_HOOK(mrb, irep, pc, regs) if ((mrb)->code_fetch_hook) (mrb)->code_fetch_hook((mrb), (irep), (pc), (regs));
#else
#define CODE_FETCH_HOOK(mrb, irep, pc, regs)
#endif
#if defined __GNUC__ || defined __clang__ || defined __INTEL_COMPILER
#define DIRECT_THREADED
#endif
#ifndef DIRECT_THREADED
#define INIT_DISPATCH for (;;) { i = *pc; CODE_FETCH_HOOK(mrb, irep, pc, regs); switch (GET_OPCODE(i)) {
#define CASE(op) case op:
#define NEXT pc++; break
#define JUMP break
#define END_DISPATCH }}
#else
#define INIT_DISPATCH JUMP; return mrb_nil_value();
#define CASE(op) L_ ## op:
#define NEXT i=*++pc; CODE_FETCH_HOOK(mrb, irep, pc, regs); goto *optable[GET_OPCODE(i)]
#define JUMP i=*pc; CODE_FETCH_HOOK(mrb, irep, pc, regs); goto *optable[GET_OPCODE(i)]
#define END_DISPATCH
#endif
mrb_value mrb_gv_val_get(mrb_state *mrb, mrb_sym sym);
void mrb_gv_val_set(mrb_state *mrb, mrb_sym sym, mrb_value val);
#define CALL_MAXARGS 127
MRB_API mrb_value
mrb_context_run(mrb_state *mrb, struct RProc *proc, mrb_value self, unsigned int stack_keep)
{
/* mrb_assert(mrb_proc_cfunc_p(proc)) */
mrb_irep *irep = proc->body.irep;
mrb_code *pc = irep->iseq;
mrb_value *pool = irep->pool;
mrb_sym *syms = irep->syms;
mrb_value *regs = NULL;
mrb_code i;
int ai = mrb_gc_arena_save(mrb);
struct mrb_jmpbuf *prev_jmp = mrb->jmp;
struct mrb_jmpbuf c_jmp;
#ifdef DIRECT_THREADED
static void *optable[] = {
&&L_OP_NOP, &&L_OP_MOVE,
&&L_OP_LOADL, &&L_OP_LOADI, &&L_OP_LOADSYM, &&L_OP_LOADNIL,
&&L_OP_LOADSELF, &&L_OP_LOADT, &&L_OP_LOADF,
&&L_OP_GETGLOBAL, &&L_OP_SETGLOBAL, &&L_OP_GETSPECIAL, &&L_OP_SETSPECIAL,
&&L_OP_GETIV, &&L_OP_SETIV, &&L_OP_GETCV, &&L_OP_SETCV,
&&L_OP_GETCONST, &&L_OP_SETCONST, &&L_OP_GETMCNST, &&L_OP_SETMCNST,
&&L_OP_GETUPVAR, &&L_OP_SETUPVAR,
&&L_OP_JMP, &&L_OP_JMPIF, &&L_OP_JMPNOT,
&&L_OP_ONERR, &&L_OP_RESCUE, &&L_OP_POPERR, &&L_OP_RAISE, &&L_OP_EPUSH, &&L_OP_EPOP,
&&L_OP_SEND, &&L_OP_SENDB, &&L_OP_FSEND,
&&L_OP_CALL, &&L_OP_SUPER, &&L_OP_ARGARY, &&L_OP_ENTER,
&&L_OP_KARG, &&L_OP_KDICT, &&L_OP_RETURN, &&L_OP_TAILCALL, &&L_OP_BLKPUSH,
&&L_OP_ADD, &&L_OP_ADDI, &&L_OP_SUB, &&L_OP_SUBI, &&L_OP_MUL, &&L_OP_DIV,
&&L_OP_EQ, &&L_OP_LT, &&L_OP_LE, &&L_OP_GT, &&L_OP_GE,
&&L_OP_ARRAY, &&L_OP_ARYCAT, &&L_OP_ARYPUSH, &&L_OP_AREF, &&L_OP_ASET, &&L_OP_APOST,
&&L_OP_STRING, &&L_OP_STRCAT, &&L_OP_HASH,
&&L_OP_LAMBDA, &&L_OP_RANGE, &&L_OP_OCLASS,
&&L_OP_CLASS, &&L_OP_MODULE, &&L_OP_EXEC,
&&L_OP_METHOD, &&L_OP_SCLASS, &&L_OP_TCLASS,
&&L_OP_DEBUG, &&L_OP_STOP, &&L_OP_ERR,
};
#endif
mrb_bool exc_catched = FALSE;
RETRY_TRY_BLOCK:
MRB_TRY(&c_jmp) {
if (exc_catched) {
exc_catched = FALSE;
goto L_RAISE;
}
mrb->jmp = &c_jmp;
if (!mrb->c->stack) {
stack_init(mrb);
}
stack_extend(mrb, irep->nregs, stack_keep);
mrb->c->ci->proc = proc;
mrb->c->ci->nregs = irep->nregs;
regs = mrb->c->stack;
regs[0] = self;
INIT_DISPATCH {
CASE(OP_NOP) {
/* do nothing */
NEXT;
}
CASE(OP_MOVE) {
/* A B R(A) := R(B) */
regs[GETARG_A(i)] = regs[GETARG_B(i)];
NEXT;
}
CASE(OP_LOADL) {
/* A Bx R(A) := Pool(Bx) */
regs[GETARG_A(i)] = pool[GETARG_Bx(i)];
NEXT;
}
CASE(OP_LOADI) {
/* A sBx R(A) := sBx */
SET_INT_VALUE(regs[GETARG_A(i)], GETARG_sBx(i));
NEXT;
}
CASE(OP_LOADSYM) {
/* A Bx R(A) := Syms(Bx) */
SET_SYM_VALUE(regs[GETARG_A(i)], syms[GETARG_Bx(i)]);
NEXT;
}
CASE(OP_LOADSELF) {
/* A R(A) := self */
regs[GETARG_A(i)] = regs[0];
NEXT;
}
CASE(OP_LOADT) {
/* A R(A) := true */
SET_TRUE_VALUE(regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_LOADF) {
/* A R(A) := false */
SET_FALSE_VALUE(regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_GETGLOBAL) {
/* A Bx R(A) := getglobal(Syms(Bx)) */
regs[GETARG_A(i)] = mrb_gv_get(mrb, syms[GETARG_Bx(i)]);
NEXT;
}
CASE(OP_SETGLOBAL) {
/* setglobal(Syms(Bx), R(A)) */
mrb_gv_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_GETSPECIAL) {
/* A Bx R(A) := Special[Bx] */
regs[GETARG_A(i)] = mrb_vm_special_get(mrb, GETARG_Bx(i));
NEXT;
}
CASE(OP_SETSPECIAL) {
/* A Bx Special[Bx] := R(A) */
mrb_vm_special_set(mrb, GETARG_Bx(i), regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_GETIV) {
/* A Bx R(A) := ivget(Bx) */
regs[GETARG_A(i)] = mrb_vm_iv_get(mrb, syms[GETARG_Bx(i)]);
NEXT;
}
CASE(OP_SETIV) {
/* ivset(Syms(Bx),R(A)) */
mrb_vm_iv_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_GETCV) {
/* A Bx R(A) := cvget(Syms(Bx)) */
ERR_PC_SET(mrb, pc);
regs[GETARG_A(i)] = mrb_vm_cv_get(mrb, syms[GETARG_Bx(i)]);
ERR_PC_CLR(mrb);
NEXT;
}
CASE(OP_SETCV) {
/* cvset(Syms(Bx),R(A)) */
mrb_vm_cv_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_GETCONST) {
/* A Bx R(A) := constget(Syms(Bx)) */
mrb_value val;
ERR_PC_SET(mrb, pc);
val = mrb_vm_const_get(mrb, syms[GETARG_Bx(i)]);
ERR_PC_CLR(mrb);
regs = mrb->c->stack;
regs[GETARG_A(i)] = val;
NEXT;
}
CASE(OP_SETCONST) {
/* A Bx constset(Syms(Bx),R(A)) */
mrb_vm_const_set(mrb, syms[GETARG_Bx(i)], regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_GETMCNST) {
/* A Bx R(A) := R(A)::Syms(Bx) */
mrb_value val;
int a = GETARG_A(i);
ERR_PC_SET(mrb, pc);
val = mrb_const_get(mrb, regs[a], syms[GETARG_Bx(i)]);
ERR_PC_CLR(mrb);
regs = mrb->c->stack;
regs[a] = val;
NEXT;
}
CASE(OP_SETMCNST) {
/* A Bx R(A+1)::Syms(Bx) := R(A) */
int a = GETARG_A(i);
mrb_const_set(mrb, regs[a+1], syms[GETARG_Bx(i)], regs[a]);
NEXT;
}
CASE(OP_GETUPVAR) {
/* A B C R(A) := uvget(B,C) */
mrb_value *regs_a = regs + GETARG_A(i);
int up = GETARG_C(i);
struct REnv *e = uvenv(mrb, up);
if (!e) {
*regs_a = mrb_nil_value();
}
else {
int idx = GETARG_B(i);
*regs_a = e->stack[idx];
}
NEXT;
}
CASE(OP_SETUPVAR) {
/* A B C uvset(B,C,R(A)) */
int up = GETARG_C(i);
struct REnv *e = uvenv(mrb, up);
if (e) {
mrb_value *regs_a = regs + GETARG_A(i);
int idx = GETARG_B(i);
e->stack[idx] = *regs_a;
mrb_write_barrier(mrb, (struct RBasic*)e);
}
NEXT;
}
CASE(OP_JMP) {
/* sBx pc+=sBx */
pc += GETARG_sBx(i);
JUMP;
}
CASE(OP_JMPIF) {
/* A sBx if R(A) pc+=sBx */
if (mrb_test(regs[GETARG_A(i)])) {
pc += GETARG_sBx(i);
JUMP;
}
NEXT;
}
CASE(OP_JMPNOT) {
/* A sBx if !R(A) pc+=sBx */
if (!mrb_test(regs[GETARG_A(i)])) {
pc += GETARG_sBx(i);
JUMP;
}
NEXT;
}
CASE(OP_ONERR) {
/* sBx pc+=sBx on exception */
if (mrb->c->rsize <= mrb->c->ci->ridx) {
if (mrb->c->rsize == 0) mrb->c->rsize = 16;
else mrb->c->rsize *= 2;
mrb->c->rescue = (mrb_code **)mrb_realloc(mrb, mrb->c->rescue, sizeof(mrb_code*) * mrb->c->rsize);
}
mrb->c->rescue[mrb->c->ci->ridx++] = pc + GETARG_sBx(i);
NEXT;
}
CASE(OP_RESCUE) {
/* A R(A) := exc; clear(exc) */
SET_OBJ_VALUE(regs[GETARG_A(i)], mrb->exc);
mrb->exc = 0;
NEXT;
}
CASE(OP_POPERR) {
/* A A.times{rescue_pop()} */
int a = GETARG_A(i);
while (a--) {
mrb->c->ci->ridx--;
}
NEXT;
}
CASE(OP_RAISE) {
/* A raise(R(A)) */
mrb->exc = mrb_obj_ptr(regs[GETARG_A(i)]);
goto L_RAISE;
}
CASE(OP_EPUSH) {
/* Bx ensure_push(SEQ[Bx]) */
struct RProc *p;
p = mrb_closure_new(mrb, irep->reps[GETARG_Bx(i)]);
/* push ensure_stack */
if (mrb->c->esize <= mrb->c->ci->eidx) {
if (mrb->c->esize == 0) mrb->c->esize = 16;
else mrb->c->esize *= 2;
mrb->c->ensure = (struct RProc **)mrb_realloc(mrb, mrb->c->ensure, sizeof(struct RProc*) * mrb->c->esize);
}
mrb->c->ensure[mrb->c->ci->eidx++] = p;
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_EPOP) {
/* A A.times{ensure_pop().call} */
int a = GETARG_A(i);
mrb_callinfo *ci = mrb->c->ci;
int n, eidx = ci->eidx;
for (n=0; n<a && eidx > ci[-1].eidx; n++) {
ecall(mrb, --eidx);
ARENA_RESTORE(mrb, ai);
}
NEXT;
}
CASE(OP_LOADNIL) {
/* A R(A) := nil */
int a = GETARG_A(i);
SET_NIL_VALUE(regs[a]);
NEXT;
}
CASE(OP_SENDB) {
/* A B C R(A) := call(R(A),Syms(B),R(A+1),...,R(A+C),&R(A+C+1))*/
/* fall through */
};
L_SEND:
CASE(OP_SEND) {
/* A B C R(A) := call(R(A),Syms(B),R(A+1),...,R(A+C)) */
int a = GETARG_A(i);
int n = GETARG_C(i);
struct RProc *m;
struct RClass *c;
mrb_callinfo *ci;
mrb_value recv, result;
mrb_sym mid = syms[GETARG_B(i)];
recv = regs[a];
if (GET_OPCODE(i) != OP_SENDB) {
if (n == CALL_MAXARGS) {
SET_NIL_VALUE(regs[a+2]);
}
else {
SET_NIL_VALUE(regs[a+n+1]);
}
}
c = mrb_class(mrb, recv);
m = mrb_method_search_vm(mrb, &c, mid);
if (!m) {
mrb_value sym = mrb_symbol_value(mid);
mid = mrb_intern_lit(mrb, "method_missing");
m = mrb_method_search_vm(mrb, &c, mid);
if (n == CALL_MAXARGS) {
mrb_ary_unshift(mrb, regs[a+1], sym);
}
else {
value_move(regs+a+2, regs+a+1, ++n);
regs[a+1] = sym;
}
}
/* push callinfo */
ci = cipush(mrb);
ci->mid = mid;
ci->proc = m;
ci->stackent = mrb->c->stack;
if (c->tt == MRB_TT_ICLASS) {
ci->target_class = c->c;
}
else {
ci->target_class = c;
}
ci->pc = pc + 1;
ci->acc = a;
/* prepare stack */
mrb->c->stack += a;
if (MRB_PROC_CFUNC_P(m)) {
if (n == CALL_MAXARGS) {
ci->argc = -1;
ci->nregs = 3;
}
else {
ci->argc = n;
ci->nregs = n + 2;
}
result = m->body.func(mrb, recv);
mrb->c->stack[0] = result;
mrb_gc_arena_restore(mrb, ai);
if (mrb->exc) goto L_RAISE;
/* pop stackpos */
ci = mrb->c->ci;
if (!ci->target_class) { /* return from context modifying method (resume/yield) */
if (!MRB_PROC_CFUNC_P(ci[-1].proc)) {
proc = ci[-1].proc;
irep = proc->body.irep;
pool = irep->pool;
syms = irep->syms;
}
}
regs = mrb->c->stack = ci->stackent;
pc = ci->pc;
cipop(mrb);
JUMP;
}
else {
/* setup environment for calling method */
proc = mrb->c->ci->proc = m;
irep = m->body.irep;
pool = irep->pool;
syms = irep->syms;
ci->nregs = irep->nregs;
if (n == CALL_MAXARGS) {
ci->argc = -1;
stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3);
}
else {
ci->argc = n;
stack_extend(mrb, irep->nregs, n+2);
}
regs = mrb->c->stack;
pc = irep->iseq;
JUMP;
}
}
CASE(OP_FSEND) {
/* A B C R(A) := fcall(R(A),Syms(B),R(A+1),... ,R(A+C-1)) */
NEXT;
}
CASE(OP_CALL) {
/* A R(A) := self.call(frame.argc, frame.argv) */
mrb_callinfo *ci;
mrb_value recv = mrb->c->stack[0];
struct RProc *m = mrb_proc_ptr(recv);
/* replace callinfo */
ci = mrb->c->ci;
ci->target_class = m->target_class;
ci->proc = m;
if (m->env) {
if (m->env->mid) {
ci->mid = m->env->mid;
}
if (!m->env->stack) {
m->env->stack = mrb->c->stack;
}
}
/* prepare stack */
if (MRB_PROC_CFUNC_P(m)) {
recv = m->body.func(mrb, recv);
mrb_gc_arena_restore(mrb, ai);
if (mrb->exc) goto L_RAISE;
/* pop stackpos */
ci = mrb->c->ci;
regs = mrb->c->stack = ci->stackent;
regs[ci->acc] = recv;
pc = ci->pc;
cipop(mrb);
irep = mrb->c->ci->proc->body.irep;
pool = irep->pool;
syms = irep->syms;
JUMP;
}
else {
/* setup environment for calling method */
proc = m;
irep = m->body.irep;
if (!irep) {
mrb->c->stack[0] = mrb_nil_value();
goto L_RETURN;
}
pool = irep->pool;
syms = irep->syms;
ci->nregs = irep->nregs;
if (ci->argc < 0) {
stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3);
}
else {
stack_extend(mrb, irep->nregs, ci->argc+2);
}
regs = mrb->c->stack;
regs[0] = m->env->stack[0];
pc = irep->iseq;
JUMP;
}
}
CASE(OP_SUPER) {
/* A C R(A) := super(R(A+1),... ,R(A+C+1)) */
mrb_value recv;
mrb_callinfo *ci = mrb->c->ci;
struct RProc *m;
struct RClass *c;
mrb_sym mid = ci->mid;
int a = GETARG_A(i);
int n = GETARG_C(i);
recv = regs[0];
c = mrb->c->ci->target_class->super;
m = mrb_method_search_vm(mrb, &c, mid);
if (!m) {
mid = mrb_intern_lit(mrb, "method_missing");
m = mrb_method_search_vm(mrb, &c, mid);
if (n == CALL_MAXARGS) {
mrb_ary_unshift(mrb, regs[a+1], mrb_symbol_value(ci->mid));
}
else {
value_move(regs+a+2, regs+a+1, ++n);
SET_SYM_VALUE(regs[a+1], ci->mid);
}
}
/* push callinfo */
ci = cipush(mrb);
ci->mid = mid;
ci->proc = m;
ci->stackent = mrb->c->stack;
if (n == CALL_MAXARGS) {
ci->argc = -1;
}
else {
ci->argc = n;
}
ci->target_class = c;
ci->pc = pc + 1;
/* prepare stack */
mrb->c->stack += a;
mrb->c->stack[0] = recv;
if (MRB_PROC_CFUNC_P(m)) {
ci->nregs = 0;
mrb->c->stack[0] = m->body.func(mrb, recv);
mrb_gc_arena_restore(mrb, ai);
if (mrb->exc) goto L_RAISE;
/* pop stackpos */
regs = mrb->c->stack = mrb->c->ci->stackent;
cipop(mrb);
NEXT;
}
else {
/* fill callinfo */
ci->acc = a;
/* setup environment for calling method */
ci->proc = m;
irep = m->body.irep;
pool = irep->pool;
syms = irep->syms;
ci->nregs = irep->nregs;
if (n == CALL_MAXARGS) {
stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3);
}
else {
stack_extend(mrb, irep->nregs, ci->argc+2);
}
regs = mrb->c->stack;
pc = irep->iseq;
JUMP;
}
}
CASE(OP_ARGARY) {
/* A Bx R(A) := argument array (16=6:1:5:4) */
int a = GETARG_A(i);
int bx = GETARG_Bx(i);
int m1 = (bx>>10)&0x3f;
int r = (bx>>9)&0x1;
int m2 = (bx>>4)&0x1f;
int lv = (bx>>0)&0xf;
mrb_value *stack;
if (lv == 0) stack = regs + 1;
else {
struct REnv *e = uvenv(mrb, lv-1);
if (!e) {
mrb_value exc;
exc = mrb_exc_new_str_lit(mrb, E_NOMETHOD_ERROR, "super called outside of method");
mrb->exc = mrb_obj_ptr(exc);
goto L_RAISE;
}
stack = e->stack + 1;
}
if (r == 0) {
regs[a] = mrb_ary_new_from_values(mrb, m1+m2, stack);
}
else {
mrb_value *pp = NULL;
struct RArray *rest;
int len = 0;
if (mrb_array_p(stack[m1])) {
struct RArray *ary = mrb_ary_ptr(stack[m1]);
pp = ary->ptr;
len = ary->len;
}
regs[a] = mrb_ary_new_capa(mrb, m1+len+m2);
rest = mrb_ary_ptr(regs[a]);
if (m1 > 0) {
stack_copy(rest->ptr, stack, m1);
}
if (len > 0) {
stack_copy(rest->ptr+m1, pp, len);
}
if (m2 > 0) {
stack_copy(rest->ptr+m1+len, stack+m1+1, m2);
}
rest->len = m1+len+m2;
}
regs[a+1] = stack[m1+r+m2];
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_ENTER) {
/* Ax arg setup according to flags (23=5:5:1:5:5:1:1) */
/* number of optional arguments times OP_JMP should follow */
mrb_aspec ax = GETARG_Ax(i);
int m1 = MRB_ASPEC_REQ(ax);
int o = MRB_ASPEC_OPT(ax);
int r = MRB_ASPEC_REST(ax);
int m2 = MRB_ASPEC_POST(ax);
/* unused
int k = MRB_ASPEC_KEY(ax);
int kd = MRB_ASPEC_KDICT(ax);
int b = MRB_ASPEC_BLOCK(ax);
*/
int argc = mrb->c->ci->argc;
mrb_value *argv = regs+1;
mrb_value *argv0 = argv;
int len = m1 + o + r + m2;
mrb_value *blk = &argv[argc < 0 ? 1 : argc];
if (!mrb_nil_p(*blk) && mrb_type(*blk) != MRB_TT_PROC) {
*blk = mrb_convert_type(mrb, *blk, MRB_TT_PROC, "Proc", "to_proc");
}
if (argc < 0) {
struct RArray *ary = mrb_ary_ptr(regs[1]);
argv = ary->ptr;
argc = ary->len;
mrb_gc_protect(mrb, regs[1]);
}
if (mrb->c->ci->proc && MRB_PROC_STRICT_P(mrb->c->ci->proc)) {
if (argc >= 0) {
if (argc < m1 + m2 || (r == 0 && argc > len)) {
argnum_error(mrb, m1+m2);
goto L_RAISE;
}
}
}
else if (len > 1 && argc == 1 && mrb_array_p(argv[0])) {
mrb_gc_protect(mrb, argv[0]);
argc = mrb_ary_ptr(argv[0])->len;
argv = mrb_ary_ptr(argv[0])->ptr;
}
mrb->c->ci->argc = len;
if (argc < len) {
int mlen = m2;
if (argc < m1+m2) {
if (m1 < argc)
mlen = argc - m1;
else
mlen = 0;
}
regs[len+1] = *blk; /* move block */
SET_NIL_VALUE(regs[argc+1]);
if (argv0 != argv) {
value_move(®s[1], argv, argc-mlen); /* m1 + o */
}
if (mlen) {
value_move(®s[len-m2+1], &argv[argc-mlen], mlen);
}
if (r) {
regs[m1+o+1] = mrb_ary_new_capa(mrb, 0);
}
if (o == 0 || argc < m1+m2) pc++;
else
pc += argc - m1 - m2 + 1;
}
else {
int rnum = 0;
if (argv0 != argv) {
regs[len+1] = *blk; /* move block */
value_move(®s[1], argv, m1+o);
}
if (r) {
rnum = argc-m1-o-m2;
regs[m1+o+1] = mrb_ary_new_from_values(mrb, rnum, argv+m1+o);
}
if (m2) {
if (argc-m2 > m1) {
value_move(®s[m1+o+r+1], &argv[m1+o+rnum], m2);
}
}
if (argv0 == argv) {
regs[len+1] = *blk; /* move block */
}
pc += o + 1;
}
JUMP;
}
CASE(OP_KARG) {
/* A B C R(A) := kdict[Syms(B)]; if C kdict.rm(Syms(B)) */
/* if C == 2; raise unless kdict.empty? */
/* OP_JMP should follow to skip init code */
NEXT;
}
CASE(OP_KDICT) {
/* A C R(A) := kdict */
NEXT;
}
L_RETURN:
i = MKOP_AB(OP_RETURN, GETARG_A(i), OP_R_NORMAL);
/* fall through */
CASE(OP_RETURN) {
/* A B return R(A) (B=normal,in-block return/break) */
if (mrb->exc) {
mrb_callinfo *ci;
int eidx;
L_RAISE:
ci = mrb->c->ci;
mrb_obj_iv_ifnone(mrb, mrb->exc, mrb_intern_lit(mrb, "lastpc"), mrb_cptr_value(mrb, pc));
mrb_obj_iv_ifnone(mrb, mrb->exc, mrb_intern_lit(mrb, "ciidx"), mrb_fixnum_value(ci - mrb->c->cibase));
eidx = ci->eidx;
if (ci == mrb->c->cibase) {
if (ci->ridx == 0) goto L_STOP;
goto L_RESCUE;
}
while (eidx > ci[-1].eidx) {
ecall(mrb, --eidx);
}
while (ci[0].ridx == ci[-1].ridx) {
cipop(mrb);
ci = mrb->c->ci;
mrb->c->stack = ci[1].stackent;
if (ci[1].acc == CI_ACC_SKIP && prev_jmp) {
mrb->jmp = prev_jmp;
MRB_THROW(prev_jmp);
}
if (ci > mrb->c->cibase) {
while (eidx > ci[-1].eidx) {
ecall(mrb, --eidx);
}
}
else if (ci == mrb->c->cibase) {
if (ci->ridx == 0) {
if (mrb->c == mrb->root_c) {
regs = mrb->c->stack = mrb->c->stbase;
goto L_STOP;
}
else {
struct mrb_context *c = mrb->c;
mrb->c = c->prev;
c->prev = NULL;
goto L_RAISE;
}
}
break;
}
}
L_RESCUE:
if (ci->ridx == 0) goto L_STOP;
proc = ci->proc;
irep = proc->body.irep;
pool = irep->pool;
syms = irep->syms;
regs = mrb->c->stack = ci[1].stackent;
pc = mrb->c->rescue[--ci->ridx];
}
else {
mrb_callinfo *ci = mrb->c->ci;
int acc, eidx = mrb->c->ci->eidx;
mrb_value v = regs[GETARG_A(i)];
switch (GETARG_B(i)) {
case OP_R_RETURN:
/* Fall through to OP_R_NORMAL otherwise */
if (proc->env && !MRB_PROC_STRICT_P(proc)) {
struct REnv *e = top_env(mrb, proc);
if (!MRB_ENV_STACK_SHARED_P(e)) {
localjump_error(mrb, LOCALJUMP_ERROR_RETURN);
goto L_RAISE;
}
ci = mrb->c->cibase + e->cioff;
if (ci == mrb->c->cibase) {
localjump_error(mrb, LOCALJUMP_ERROR_RETURN);
goto L_RAISE;
}
mrb->c->ci = ci;
break;
}
case OP_R_NORMAL:
if (ci == mrb->c->cibase) {
if (!mrb->c->prev) { /* toplevel return */
localjump_error(mrb, LOCALJUMP_ERROR_RETURN);
goto L_RAISE;
}
if (mrb->c->prev->ci == mrb->c->prev->cibase) {
mrb_value exc = mrb_exc_new_str_lit(mrb, E_FIBER_ERROR, "double resume");
mrb->exc = mrb_obj_ptr(exc);
goto L_RAISE;
}
/* automatic yield at the end */
mrb->c->status = MRB_FIBER_TERMINATED;
mrb->c = mrb->c->prev;
mrb->c->status = MRB_FIBER_RUNNING;
}
ci = mrb->c->ci;
break;
case OP_R_BREAK:
if (!proc->env || !MRB_ENV_STACK_SHARED_P(proc->env)) {
localjump_error(mrb, LOCALJUMP_ERROR_BREAK);
goto L_RAISE;
}
/* break from fiber block */
if (mrb->c->ci == mrb->c->cibase && mrb->c->ci->pc) {
struct mrb_context *c = mrb->c;
mrb->c = c->prev;
c->prev = NULL;
}
ci = mrb->c->ci;
mrb->c->ci = mrb->c->cibase + proc->env->cioff + 1;
while (ci > mrb->c->ci) {
if (ci[-1].acc == CI_ACC_SKIP) {
mrb->c->ci = ci;
break;
}
ci--;
}
break;
default:
/* cannot happen */
break;
}
while (eidx > mrb->c->ci[-1].eidx) {
ecall(mrb, --eidx);
}
cipop(mrb);
acc = ci->acc;
pc = ci->pc;
regs = mrb->c->stack = ci->stackent;
if (acc == CI_ACC_SKIP) {
mrb->jmp = prev_jmp;
return v;
}
DEBUG(printf("from :%s\n", mrb_sym2name(mrb, ci->mid)));
proc = mrb->c->ci->proc;
irep = proc->body.irep;
pool = irep->pool;
syms = irep->syms;
regs[acc] = v;
}
JUMP;
}
CASE(OP_TAILCALL) {
/* A B C return call(R(A),Syms(B),R(A+1),... ,R(A+C+1)) */
int a = GETARG_A(i);
int n = GETARG_C(i);
struct RProc *m;
struct RClass *c;
mrb_callinfo *ci;
mrb_value recv;
mrb_sym mid = syms[GETARG_B(i)];
recv = regs[a];
c = mrb_class(mrb, recv);
m = mrb_method_search_vm(mrb, &c, mid);
if (!m) {
mrb_value sym = mrb_symbol_value(mid);
mid = mrb_intern_lit(mrb, "method_missing");
m = mrb_method_search_vm(mrb, &c, mid);
if (n == CALL_MAXARGS) {
mrb_ary_unshift(mrb, regs[a+1], sym);
}
else {
value_move(regs+a+2, regs+a+1, ++n);
regs[a+1] = sym;
}
}
/* replace callinfo */
ci = mrb->c->ci;
ci->mid = mid;
ci->target_class = c;
if (n == CALL_MAXARGS) {
ci->argc = -1;
}
else {
ci->argc = n;
}
/* move stack */
value_move(mrb->c->stack, ®s[a], ci->argc+1);
if (MRB_PROC_CFUNC_P(m)) {
mrb->c->stack[0] = m->body.func(mrb, recv);
mrb_gc_arena_restore(mrb, ai);
goto L_RETURN;
}
else {
/* setup environment for calling method */
irep = m->body.irep;
pool = irep->pool;
syms = irep->syms;
if (ci->argc < 0) {
stack_extend(mrb, (irep->nregs < 3) ? 3 : irep->nregs, 3);
}
else {
stack_extend(mrb, irep->nregs, ci->argc+2);
}
regs = mrb->c->stack;
pc = irep->iseq;
}
JUMP;
}
CASE(OP_BLKPUSH) {
/* A Bx R(A) := block (16=6:1:5:4) */
int a = GETARG_A(i);
int bx = GETARG_Bx(i);
int m1 = (bx>>10)&0x3f;
int r = (bx>>9)&0x1;
int m2 = (bx>>4)&0x1f;
int lv = (bx>>0)&0xf;
mrb_value *stack;
if (lv == 0) stack = regs + 1;
else {
struct REnv *e = uvenv(mrb, lv-1);
if (!e) {
localjump_error(mrb, LOCALJUMP_ERROR_YIELD);
goto L_RAISE;
}
stack = e->stack + 1;
}
regs[a] = stack[m1+r+m2];
NEXT;
}
#define TYPES2(a,b) ((((uint16_t)(a))<<8)|(((uint16_t)(b))&0xff))
#define OP_MATH_BODY(op,v1,v2) do {\
v1(regs[a]) = v1(regs[a]) op v2(regs[a+1]);\
} while(0)
CASE(OP_ADD) {
/* A B C R(A) := R(A)+R(A+1) (Syms[B]=:+,C=1)*/
int a = GETARG_A(i);
/* need to check if op is overridden */
switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) {
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM):
{
mrb_int x, y, z;
mrb_value *regs_a = regs + a;
x = mrb_fixnum(regs_a[0]);
y = mrb_fixnum(regs_a[1]);
if (mrb_int_add_overflow(x, y, &z)) {
SET_FLOAT_VALUE(mrb, regs_a[0], (mrb_float)x + (mrb_float)y);
break;
}
SET_INT_VALUE(regs[a], z);
}
break;
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT):
{
mrb_int x = mrb_fixnum(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], (mrb_float)x + y);
}
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_int y = mrb_fixnum(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x + y);
}
#else
OP_MATH_BODY(+,mrb_float,mrb_fixnum);
#endif
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x + y);
}
#else
OP_MATH_BODY(+,mrb_float,mrb_float);
#endif
break;
case TYPES2(MRB_TT_STRING,MRB_TT_STRING):
regs[a] = mrb_str_plus(mrb, regs[a], regs[a+1]);
break;
default:
goto L_SEND;
}
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_SUB) {
/* A B C R(A) := R(A)-R(A+1) (Syms[B]=:-,C=1)*/
int a = GETARG_A(i);
/* need to check if op is overridden */
switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) {
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM):
{
mrb_int x, y, z;
x = mrb_fixnum(regs[a]);
y = mrb_fixnum(regs[a+1]);
if (mrb_int_sub_overflow(x, y, &z)) {
SET_FLOAT_VALUE(mrb, regs[a], (mrb_float)x - (mrb_float)y);
break;
}
SET_INT_VALUE(regs[a], z);
}
break;
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT):
{
mrb_int x = mrb_fixnum(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], (mrb_float)x - y);
}
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_int y = mrb_fixnum(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x - y);
}
#else
OP_MATH_BODY(-,mrb_float,mrb_fixnum);
#endif
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x - y);
}
#else
OP_MATH_BODY(-,mrb_float,mrb_float);
#endif
break;
default:
goto L_SEND;
}
NEXT;
}
CASE(OP_MUL) {
/* A B C R(A) := R(A)*R(A+1) (Syms[B]=:*,C=1)*/
int a = GETARG_A(i);
/* need to check if op is overridden */
switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) {
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM):
{
mrb_value z;
z = mrb_fixnum_mul(mrb, regs[a], regs[a+1]);
switch (mrb_type(z)) {
case MRB_TT_FIXNUM:
{
SET_INT_VALUE(regs[a], mrb_fixnum(z));
}
break;
case MRB_TT_FLOAT:
{
SET_FLOAT_VALUE(mrb, regs[a], mrb_float(z));
}
break;
default:
/* cannot happen */
break;
}
}
break;
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT):
{
mrb_int x = mrb_fixnum(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], (mrb_float)x * y);
}
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_int y = mrb_fixnum(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x * y);
}
#else
OP_MATH_BODY(*,mrb_float,mrb_fixnum);
#endif
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x * y);
}
#else
OP_MATH_BODY(*,mrb_float,mrb_float);
#endif
break;
default:
goto L_SEND;
}
NEXT;
}
CASE(OP_DIV) {
/* A B C R(A) := R(A)/R(A+1) (Syms[B]=:/,C=1)*/
int a = GETARG_A(i);
/* need to check if op is overridden */
switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) {
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM):
{
mrb_int x = mrb_fixnum(regs[a]);
mrb_int y = mrb_fixnum(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], (mrb_float)x / (mrb_float)y);
}
break;
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT):
{
mrb_int x = mrb_fixnum(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], (mrb_float)x / y);
}
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_int y = mrb_fixnum(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x / y);
}
#else
OP_MATH_BODY(/,mrb_float,mrb_fixnum);
#endif
break;
case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT):
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
mrb_float y = mrb_float(regs[a+1]);
SET_FLOAT_VALUE(mrb, regs[a], x / y);
}
#else
OP_MATH_BODY(/,mrb_float,mrb_float);
#endif
break;
default:
goto L_SEND;
}
#ifdef MRB_NAN_BOXING
if (isnan(mrb_float(regs[a]))) {
regs[a] = mrb_float_value(mrb, mrb_float(regs[a]));
}
#endif
NEXT;
}
CASE(OP_ADDI) {
/* A B C R(A) := R(A)+C (Syms[B]=:+)*/
int a = GETARG_A(i);
/* need to check if + is overridden */
switch (mrb_type(regs[a])) {
case MRB_TT_FIXNUM:
{
mrb_int x = mrb_fixnum(regs[a]);
mrb_int y = GETARG_C(i);
mrb_int z;
if (mrb_int_add_overflow(x, y, &z)) {
SET_FLOAT_VALUE(mrb, regs[a], (mrb_float)x + (mrb_float)y);
break;
}
mrb_fixnum(regs[a]) = z;
}
break;
case MRB_TT_FLOAT:
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
SET_FLOAT_VALUE(mrb, regs[a], x + GETARG_C(i));
}
#else
mrb_float(regs[a]) += GETARG_C(i);
#endif
break;
default:
SET_INT_VALUE(regs[a+1], GETARG_C(i));
i = MKOP_ABC(OP_SEND, a, GETARG_B(i), 1);
goto L_SEND;
}
NEXT;
}
CASE(OP_SUBI) {
/* A B C R(A) := R(A)-C (Syms[B]=:-)*/
int a = GETARG_A(i);
mrb_value *regs_a = regs + a;
/* need to check if + is overridden */
switch (mrb_type(regs_a[0])) {
case MRB_TT_FIXNUM:
{
mrb_int x = mrb_fixnum(regs_a[0]);
mrb_int y = GETARG_C(i);
mrb_int z;
if (mrb_int_sub_overflow(x, y, &z)) {
SET_FLOAT_VALUE(mrb, regs_a[0], (mrb_float)x - (mrb_float)y);
}
else {
mrb_fixnum(regs_a[0]) = z;
}
}
break;
case MRB_TT_FLOAT:
#ifdef MRB_WORD_BOXING
{
mrb_float x = mrb_float(regs[a]);
SET_FLOAT_VALUE(mrb, regs[a], x - GETARG_C(i));
}
#else
mrb_float(regs_a[0]) -= GETARG_C(i);
#endif
break;
default:
SET_INT_VALUE(regs_a[1], GETARG_C(i));
i = MKOP_ABC(OP_SEND, a, GETARG_B(i), 1);
goto L_SEND;
}
NEXT;
}
#define OP_CMP_BODY(op,v1,v2) (v1(regs[a]) op v2(regs[a+1]))
#define OP_CMP(op) do {\
int result;\
/* need to check if - is overridden */\
switch (TYPES2(mrb_type(regs[a]),mrb_type(regs[a+1]))) {\
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FIXNUM):\
result = OP_CMP_BODY(op,mrb_fixnum,mrb_fixnum);\
break;\
case TYPES2(MRB_TT_FIXNUM,MRB_TT_FLOAT):\
result = OP_CMP_BODY(op,mrb_fixnum,mrb_float);\
break;\
case TYPES2(MRB_TT_FLOAT,MRB_TT_FIXNUM):\
result = OP_CMP_BODY(op,mrb_float,mrb_fixnum);\
break;\
case TYPES2(MRB_TT_FLOAT,MRB_TT_FLOAT):\
result = OP_CMP_BODY(op,mrb_float,mrb_float);\
break;\
default:\
goto L_SEND;\
}\
if (result) {\
SET_TRUE_VALUE(regs[a]);\
}\
else {\
SET_FALSE_VALUE(regs[a]);\
}\
} while(0)
CASE(OP_EQ) {
/* A B C R(A) := R(A)==R(A+1) (Syms[B]=:==,C=1)*/
int a = GETARG_A(i);
if (mrb_obj_eq(mrb, regs[a], regs[a+1])) {
SET_TRUE_VALUE(regs[a]);
}
else {
OP_CMP(==);
}
NEXT;
}
CASE(OP_LT) {
/* A B C R(A) := R(A)<R(A+1) (Syms[B]=:<,C=1)*/
int a = GETARG_A(i);
OP_CMP(<);
NEXT;
}
CASE(OP_LE) {
/* A B C R(A) := R(A)<=R(A+1) (Syms[B]=:<=,C=1)*/
int a = GETARG_A(i);
OP_CMP(<=);
NEXT;
}
CASE(OP_GT) {
/* A B C R(A) := R(A)>R(A+1) (Syms[B]=:>,C=1)*/
int a = GETARG_A(i);
OP_CMP(>);
NEXT;
}
CASE(OP_GE) {
/* A B C R(A) := R(A)>=R(A+1) (Syms[B]=:>=,C=1)*/
int a = GETARG_A(i);
OP_CMP(>=);
NEXT;
}
CASE(OP_ARRAY) {
/* A B C R(A) := ary_new(R(B),R(B+1)..R(B+C)) */
regs[GETARG_A(i)] = mrb_ary_new_from_values(mrb, GETARG_C(i), ®s[GETARG_B(i)]);
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_ARYCAT) {
/* A B mrb_ary_concat(R(A),R(B)) */
mrb_ary_concat(mrb, regs[GETARG_A(i)],
mrb_ary_splat(mrb, regs[GETARG_B(i)]));
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_ARYPUSH) {
/* A B R(A).push(R(B)) */
mrb_ary_push(mrb, regs[GETARG_A(i)], regs[GETARG_B(i)]);
NEXT;
}
CASE(OP_AREF) {
/* A B C R(A) := R(B)[C] */
int a = GETARG_A(i);
int c = GETARG_C(i);
mrb_value v = regs[GETARG_B(i)];
if (!mrb_array_p(v)) {
if (c == 0) {
regs[GETARG_A(i)] = v;
}
else {
SET_NIL_VALUE(regs[a]);
}
}
else {
regs[GETARG_A(i)] = mrb_ary_ref(mrb, v, c);
}
NEXT;
}
CASE(OP_ASET) {
/* A B C R(B)[C] := R(A) */
mrb_ary_set(mrb, regs[GETARG_B(i)], GETARG_C(i), regs[GETARG_A(i)]);
NEXT;
}
CASE(OP_APOST) {
/* A B C *R(A),R(A+1)..R(A+C) := R(A) */
int a = GETARG_A(i);
mrb_value v = regs[a];
int pre = GETARG_B(i);
int post = GETARG_C(i);
if (!mrb_array_p(v)) {
regs[a++] = mrb_ary_new_capa(mrb, 0);
while (post--) {
SET_NIL_VALUE(regs[a]);
a++;
}
}
else {
struct RArray *ary = mrb_ary_ptr(v);
int len = ary->len;
int idx;
if (len > pre + post) {
regs[a++] = mrb_ary_new_from_values(mrb, len - pre - post, ary->ptr+pre);
while (post--) {
regs[a++] = ary->ptr[len-post-1];
}
}
else {
regs[a++] = mrb_ary_new_capa(mrb, 0);
for (idx=0; idx+pre<len; idx++) {
regs[a+idx] = ary->ptr[pre+idx];
}
while (idx < post) {
SET_NIL_VALUE(regs[a+idx]);
idx++;
}
}
}
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_STRING) {
/* A Bx R(A) := str_new(Lit(Bx)) */
regs[GETARG_A(i)] = mrb_str_dup(mrb, pool[GETARG_Bx(i)]);
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_STRCAT) {
/* A B R(A).concat(R(B)) */
mrb_str_concat(mrb, regs[GETARG_A(i)], regs[GETARG_B(i)]);
NEXT;
}
CASE(OP_HASH) {
/* A B C R(A) := hash_new(R(B),R(B+1)..R(B+C)) */
int b = GETARG_B(i);
int c = GETARG_C(i);
int lim = b+c*2;
mrb_value hash = mrb_hash_new_capa(mrb, c);
while (b < lim) {
mrb_hash_set(mrb, hash, regs[b], regs[b+1]);
b+=2;
}
regs[GETARG_A(i)] = hash;
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_LAMBDA) {
/* A b c R(A) := lambda(SEQ[b],c) (b:c = 14:2) */
struct RProc *p;
int c = GETARG_c(i);
if (c & OP_L_CAPTURE) {
p = mrb_closure_new(mrb, irep->reps[GETARG_b(i)]);
}
else {
p = mrb_proc_new(mrb, irep->reps[GETARG_b(i)]);
if (c & OP_L_METHOD) {
if (p->target_class->tt == MRB_TT_SCLASS) {
mrb_value klass;
klass = mrb_obj_iv_get(mrb,
(struct RObject *)p->target_class,
mrb_intern_lit(mrb, "__attached__"));
p->target_class = mrb_class_ptr(klass);
}
}
}
if (c & OP_L_STRICT) p->flags |= MRB_PROC_STRICT;
regs[GETARG_A(i)] = mrb_obj_value(p);
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_OCLASS) {
/* A R(A) := ::Object */
regs[GETARG_A(i)] = mrb_obj_value(mrb->object_class);
NEXT;
}
CASE(OP_CLASS) {
/* A B R(A) := newclass(R(A),Syms(B),R(A+1)) */
struct RClass *c = 0;
int a = GETARG_A(i);
mrb_value base, super;
mrb_sym id = syms[GETARG_B(i)];
base = regs[a];
super = regs[a+1];
if (mrb_nil_p(base)) {
base = mrb_obj_value(mrb->c->ci->target_class);
}
c = mrb_vm_define_class(mrb, base, super, id);
regs[a] = mrb_obj_value(c);
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_MODULE) {
/* A B R(A) := newmodule(R(A),Syms(B)) */
struct RClass *c = 0;
int a = GETARG_A(i);
mrb_value base;
mrb_sym id = syms[GETARG_B(i)];
base = regs[a];
if (mrb_nil_p(base)) {
base = mrb_obj_value(mrb->c->ci->target_class);
}
c = mrb_vm_define_module(mrb, base, id);
regs[a] = mrb_obj_value(c);
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_EXEC) {
/* A Bx R(A) := blockexec(R(A),SEQ[Bx]) */
int a = GETARG_A(i);
mrb_callinfo *ci;
mrb_value recv = regs[a];
struct RProc *p;
/* prepare stack */
ci = cipush(mrb);
ci->pc = pc + 1;
ci->acc = a;
ci->mid = 0;
ci->stackent = mrb->c->stack;
ci->argc = 0;
ci->target_class = mrb_class_ptr(recv);
/* prepare stack */
mrb->c->stack += a;
p = mrb_proc_new(mrb, irep->reps[GETARG_Bx(i)]);
p->target_class = ci->target_class;
ci->proc = p;
if (MRB_PROC_CFUNC_P(p)) {
ci->nregs = 0;
mrb->c->stack[0] = p->body.func(mrb, recv);
mrb_gc_arena_restore(mrb, ai);
if (mrb->exc) goto L_RAISE;
/* pop stackpos */
regs = mrb->c->stack = mrb->c->ci->stackent;
cipop(mrb);
NEXT;
}
else {
irep = p->body.irep;
pool = irep->pool;
syms = irep->syms;
stack_extend(mrb, irep->nregs, 1);
ci->nregs = irep->nregs;
regs = mrb->c->stack;
pc = irep->iseq;
JUMP;
}
}
CASE(OP_METHOD) {
/* A B R(A).newmethod(Syms(B),R(A+1)) */
int a = GETARG_A(i);
struct RClass *c = mrb_class_ptr(regs[a]);
mrb_define_method_vm(mrb, c, syms[GETARG_B(i)], regs[a+1]);
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_SCLASS) {
/* A B R(A) := R(B).singleton_class */
regs[GETARG_A(i)] = mrb_singleton_class(mrb, regs[GETARG_B(i)]);
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_TCLASS) {
/* A R(A) := target_class */
if (!mrb->c->ci->target_class) {
mrb_value exc = mrb_exc_new_str_lit(mrb, E_TYPE_ERROR, "no target class or module");
mrb->exc = mrb_obj_ptr(exc);
goto L_RAISE;
}
regs[GETARG_A(i)] = mrb_obj_value(mrb->c->ci->target_class);
NEXT;
}
CASE(OP_RANGE) {
/* A B C R(A) := range_new(R(B),R(B+1),C) */
int b = GETARG_B(i);
regs[GETARG_A(i)] = mrb_range_new(mrb, regs[b], regs[b+1], GETARG_C(i));
ARENA_RESTORE(mrb, ai);
NEXT;
}
CASE(OP_DEBUG) {
/* A B C debug print R(A),R(B),R(C) */
#ifdef ENABLE_DEBUG
mrb->debug_op_hook(mrb, irep, pc, regs);
#else
#ifdef ENABLE_STDIO
printf("OP_DEBUG %d %d %d\n", GETARG_A(i), GETARG_B(i), GETARG_C(i));
#else
abort();
#endif
#endif
NEXT;
}
CASE(OP_STOP) {
/* stop VM */
L_STOP:
{
int eidx_stop = mrb->c->ci == mrb->c->cibase ? 0 : mrb->c->ci[-1].eidx;
int eidx = mrb->c->ci->eidx;
while (eidx > eidx_stop) {
ecall(mrb, --eidx);
}
}
ERR_PC_CLR(mrb);
mrb->jmp = prev_jmp;
if (mrb->exc) {
return mrb_obj_value(mrb->exc);
}
return regs[irep->nlocals];
}
CASE(OP_ERR) {
/* Bx raise RuntimeError with message Lit(Bx) */
mrb_value msg = mrb_str_dup(mrb, pool[GETARG_Bx(i)]);
mrb_value exc;
if (GETARG_A(i) == 0) {
exc = mrb_exc_new_str(mrb, E_RUNTIME_ERROR, msg);
}
else {
exc = mrb_exc_new_str(mrb, E_LOCALJUMP_ERROR, msg);
}
mrb->exc = mrb_obj_ptr(exc);
goto L_RAISE;
}
}
END_DISPATCH;
}
MRB_CATCH(&c_jmp) {
exc_catched = TRUE;
goto RETRY_TRY_BLOCK;
}
MRB_END_EXC(&c_jmp);
}
MRB_API mrb_value
mrb_run(mrb_state *mrb, struct RProc *proc, mrb_value self)
{
return mrb_context_run(mrb, proc, self, mrb->c->ci->argc + 2); /* argc + 2 (receiver and block) */
}
MRB_API mrb_value
mrb_toplevel_run_keep(mrb_state *mrb, struct RProc *proc, unsigned int stack_keep)
{
mrb_callinfo *ci;
mrb_value v;
if (!mrb->c->cibase || mrb->c->ci == mrb->c->cibase) {
return mrb_context_run(mrb, proc, mrb_top_self(mrb), stack_keep);
}
ci = cipush(mrb);
ci->nregs = 1; /* protect the receiver */
ci->acc = CI_ACC_SKIP;
ci->target_class = mrb->object_class;
v = mrb_context_run(mrb, proc, mrb_top_self(mrb), stack_keep);
cipop(mrb);
return v;
}
MRB_API mrb_value
mrb_toplevel_run(mrb_state *mrb, struct RProc *proc)
{
return mrb_toplevel_run_keep(mrb, proc, 0);
}