示例#1
0
void wrenMarkObj(WrenVM* vm, Obj* obj)
{
#if WREN_DEBUG_TRACE_MEMORY
  static int indent = 0;
  indent++;
  for (int i = 0; i < indent; i++) printf("  ");
  printf("mark ");
  wrenPrintValue(OBJ_VAL(obj));
  printf(" @ %p\n", obj);
#endif

  // Traverse the object's fields.
  switch (obj->type)
  {
    case OBJ_CLASS:    markClass(   vm, (ObjClass*)   obj); break;
    case OBJ_CLOSURE:  markClosure( vm, (ObjClosure*) obj); break;
    case OBJ_FIBER:    markFiber(   vm, (ObjFiber*)   obj); break;
    case OBJ_FN:       markFn(      vm, (ObjFn*)      obj); break;
    case OBJ_INSTANCE: markInstance(vm, (ObjInstance*)obj); break;
    case OBJ_LIST:     markList(    vm, (ObjList*)    obj); break;
    case OBJ_RANGE:    setMarkedFlag(obj); break;
    case OBJ_STRING:   markString(  vm, (ObjString*)  obj); break;
    case OBJ_UPVALUE:  markUpvalue( vm, (Upvalue*)    obj); break;
  }

#if WREN_DEBUG_TRACE_MEMORY
  indent--;
#endif
}
示例#2
0
文件: wren_value.c 项目: Drooids/wren
ObjClass* wrenNewClass(WrenVM* vm, ObjClass* superclass, int numFields,
                       ObjString* name)
{
  // Create the metaclass.
  Value metaclassName = wrenStringFormat(vm, "@ metaclass", OBJ_VAL(name));
  wrenPushRoot(vm, AS_OBJ(metaclassName));

  ObjClass* metaclass = wrenNewSingleClass(vm, 0, AS_STRING(metaclassName));
  metaclass->obj.classObj = vm->classClass;

  wrenPopRoot(vm);

  // Make sure the metaclass isn't collected when we allocate the class.
  wrenPushRoot(vm, (Obj*)metaclass);

  // Metaclasses always inherit Class and do not parallel the non-metaclass
  // hierarchy.
  wrenBindSuperclass(vm, metaclass, vm->classClass);

  ObjClass* classObj = wrenNewSingleClass(vm, numFields, name);

  // Make sure the class isn't collected while the inherited methods are being
  // bound.
  wrenPushRoot(vm, (Obj*)classObj);

  classObj->obj.classObj = metaclass;
  wrenBindSuperclass(vm, classObj, superclass);

  wrenPopRoot(vm);
  wrenPopRoot(vm);

  return classObj;
}
示例#3
0
文件: wren_core.c 项目: 1100110/wren
// Validates that the given argument in [args] is a function. Returns true if
// it is. If not, reports an error and returns false.
static bool validateFn(WrenVM* vm, Value* args, int index, const char* argName)
{
  if (IS_FN(args[index]) || IS_CLOSURE(args[index])) return true;

  args[0] = OBJ_VAL(wrenStringConcat(vm, argName, " must be a function."));
  return false;
}
示例#4
0
文件: wren_core.c 项目: 1100110/wren
// Validates that the given argument in [args] is a Num. Returns true if it is.
// If not, reports an error and returns false.
static bool validateNum(WrenVM* vm, Value* args, int index, const char* argName)
{
  if (IS_NUM(args[index])) return true;

  args[0] = OBJ_VAL(wrenStringConcat(vm, argName, " must be a number."));
  return false;
}
示例#5
0
文件: wren_vm.c 项目: zeckalpha/wren
static void defineMethod(WrenVM* vm, const char* className,
                         const char* methodName, int numParams,
                         WrenForeignMethodFn methodFn, bool isStatic)
{
  ASSERT(className != NULL, "Must provide class name.");

  int length = (int)strlen(methodName);
  ASSERT(methodName != NULL, "Must provide method name.");
  ASSERT(strlen(methodName) < MAX_METHOD_NAME, "Method name too long.");

  ASSERT(numParams >= 0, "numParams cannot be negative.");
  ASSERT(numParams <= MAX_PARAMETERS, "Too many parameters.");

  ASSERT(methodFn != NULL, "Must provide method function.");

  // Find or create the class to bind the method to.
  int classSymbol = wrenSymbolTableFind(&vm->globalNames,
                               className, strlen(className));
  ObjClass* classObj;

  if (classSymbol != -1)
  {
    // TODO: Handle name is not class.
    classObj = AS_CLASS(vm->globals.data[classSymbol]);
  }
  else
  {
    // The class doesn't already exist, so create it.
    size_t length = strlen(className);
    ObjString* nameString = AS_STRING(wrenNewString(vm, className, length));

    WREN_PIN(vm, nameString);

    // TODO: Allow passing in name for superclass?
    classObj = wrenNewClass(vm, vm->objectClass, 0, nameString);
    wrenDefineGlobal(vm, className, length, OBJ_VAL(classObj));

    WREN_UNPIN(vm);
  }

  // Create a name for the method, including its arity.
  char name[MAX_METHOD_SIGNATURE];
  strncpy(name, methodName, length);
  for (int i = 0; i < numParams; i++)
  {
    name[length++] = ' ';
  }
  name[length] = '\0';

  // Bind the method.
  int methodSymbol = wrenSymbolTableEnsure(vm, &vm->methodNames, name, length);

  Method method;
  method.type = METHOD_FOREIGN;
  method.fn.foreign = methodFn;

  if (isStatic) classObj = classObj->obj.classObj;

  wrenBindMethod(vm, classObj, methodSymbol, method);
}
示例#6
0
文件: wren_core.c 项目: 1100110/wren
// Validates that [value] is an integer. Returns true if it is. If not, reports
// an error and returns false.
static bool validateIntValue(WrenVM* vm, Value* args, double value,
                             const char* argName)
{
  if (trunc(value) == value) return true;

  args[0] = OBJ_VAL(wrenStringConcat(vm, argName, " must be an integer."));
  return false;
}
示例#7
0
void metaCompile(WrenVM* vm)
{
  // Evaluate the code in the module where the calling function was defined.
  // That's one stack frame back from the top since the top-most frame is the
  // helper eval() method in Meta itself.
  Value callingFn = OBJ_VAL(vm->fiber->frames[vm->fiber->numFrames - 2].fn);
  ObjModule* module = IS_FN(callingFn)
      ? AS_FN(callingFn)->module
      : AS_CLOSURE(callingFn)->fn->module;

  // Compile it.
  ObjFn* fn = wrenCompile(vm, module, wrenGetArgumentString(vm, 1), false);
  if (fn == NULL) return;

  // Return the result. We can't use the public API for this since we have a
  // bare ObjFn.
  *vm->foreignCallSlot = OBJ_VAL(fn);
  vm->foreignCallSlot = NULL;
}
示例#8
0
Value wrenNewRange(WrenVM* vm, double from, double to, bool isInclusive)
{
  ObjRange* range = allocate(vm, sizeof(ObjRange) + 16);
  initObj(vm, &range->obj, OBJ_RANGE, vm->rangeClass);
  range->from = from;
  range->to = to;
  range->isInclusive = isInclusive;

  return OBJ_VAL(range);
}
示例#9
0
Value wrenNewUninitializedString(WrenVM* vm, size_t length)
{
  // Allocate before the string object in case this triggers a GC which would
  // free the string object.
  char* heapText = allocate(vm, length + 1);

  ObjString* string = allocate(vm, sizeof(ObjString));
  initObj(vm, &string->obj, OBJ_STRING, vm->stringClass);
  string->value = heapText;

  return OBJ_VAL(string);
}
示例#10
0
文件: wren_core.c 项目: 1100110/wren
static ObjClass* defineClass(WrenVM* vm, const char* name)
{
  size_t length = strlen(name);
  ObjString* nameString = AS_STRING(wrenNewString(vm, name, length));
  WREN_PIN(vm, nameString);

  ObjClass* classObj = wrenNewClass(vm, vm->objectClass, 0, nameString);
  wrenDefineGlobal(vm, name, length, OBJ_VAL(classObj));

  WREN_UNPIN(vm);
  return classObj;
}
示例#11
0
文件: wren_core.c 项目: iskolbin/wren
// Creates either the Object or Class class in the core module with [name].
static ObjClass* defineClass(WrenVM* vm, ObjModule* module, const char* name)
{
  ObjString* nameString = AS_STRING(wrenStringFormat(vm, "$", name));
  wrenPushRoot(vm, (Obj*)nameString);

  ObjClass* classObj = wrenNewSingleClass(vm, 0, nameString);

  wrenDefineVariable(vm, module, name, nameString->length, OBJ_VAL(classObj));

  wrenPopRoot(vm);
  return classObj;
}
示例#12
0
Value wrenNewInstance(WrenVM* vm, ObjClass* classObj)
{
  ObjInstance* instance = allocate(vm,
      sizeof(ObjInstance) + classObj->numFields * sizeof(Value));
  initObj(vm, &instance->obj, OBJ_INSTANCE, classObj);

  // Initialize fields to null.
  for (int i = 0; i < classObj->numFields; i++)
  {
    instance->fields[i] = NULL_VAL;
  }

  return OBJ_VAL(instance);
}
示例#13
0
文件: wren_value.c 项目: 1100110/wren
void wrenFreeObj(WrenVM* vm, Obj* obj)
{
#if WREN_DEBUG_TRACE_MEMORY
  printf("free ");
  wrenPrintValue(OBJ_VAL(obj));
  printf(" @ %p\n", obj);
#endif

  switch (obj->type)
  {
    case OBJ_CLASS:
      wrenMethodBufferClear(vm, &((ObjClass*)obj)->methods);
      break;

    case OBJ_FIBER:
    {
      ObjFiber* fiber = ((ObjFiber*)obj);
      if (fiber->error != NULL) wrenReallocate(vm, fiber->error, 0, 0);
      break;
    }

    case OBJ_FN:
    {
      ObjFn* fn = (ObjFn*)obj;
      wrenReallocate(vm, fn->constants, 0, 0);
      wrenReallocate(vm, fn->bytecode, 0, 0);
      wrenReallocate(vm, fn->debug->name, 0, 0);
      wrenReallocate(vm, fn->debug->sourceLines, 0, 0);
      wrenReallocate(vm, fn->debug, 0, 0);
      break;
    }

    case OBJ_LIST:
      wrenReallocate(vm, ((ObjList*)obj)->elements, 0, 0);
      break;

    case OBJ_STRING:
      wrenReallocate(vm, ((ObjString*)obj)->value, 0, 0);
      break;

    case OBJ_CLOSURE:
    case OBJ_INSTANCE:
    case OBJ_RANGE:
    case OBJ_UPVALUE:
      break;
  }

  wrenReallocate(vm, obj, 0, 0);
}
示例#14
0
文件: wren_core.c 项目: 1100110/wren
// Validates that [value] is an integer within `[0, count)`. Also allows
// negative indices which map backwards from the end. Returns the valid positive
// index value. If invalid, reports an error and returns -1.
static int validateIndexValue(WrenVM* vm, Value* args, int count, double value,
                              const char* argName)
{
  if (!validateIntValue(vm, args, value, argName)) return -1;

  int index = (int)value;

  // Negative indices count from the end.
  if (index < 0) index = count + index;

  // Check bounds.
  if (index >= 0 && index < count) return index;

  args[0] = OBJ_VAL(wrenStringConcat(vm, argName, " out of bounds."));
  return -1;
}
示例#15
0
Value wrenNewString(WrenVM* vm, const char* text, size_t length)
{
  // Allow NULL if the string is empty since byte buffers don't allocate any
  // characters for a zero-length string.
  ASSERT(length == 0 || text != NULL, "Unexpected NULL string.");

  // TODO: Don't allocate a heap string at all for zero-length strings.
  ObjString* string = AS_STRING(wrenNewUninitializedString(vm, length));

  // Copy the string (if given one).
  if (length > 0) strncpy(string->value, text, length);

  string->value[length] = '\0';

  return OBJ_VAL(string);
}
示例#16
0
文件: wren_value.c 项目: 1100110/wren
Value wrenNewString(WrenVM* vm, const char* text, size_t length)
{
  // Allocate before the string object in case this triggers a GC which would
  // free the string object.
  char* heapText = allocate(vm, length + 1);

  ObjString* string = allocate(vm, sizeof(ObjString));
  initObj(vm, &string->obj, OBJ_STRING);
  string->value = heapText;

  // Copy the string (if given one).
  if (text != NULL)
  {
    strncpy(heapText, text, length);
    heapText[length] = '\0';
  }

  return OBJ_VAL(string);
}
示例#17
0
文件: wren_vm.c 项目: zeckalpha/wren
// Puts [fiber] into a runtime failed state because of [error].
//
// Returns the fiber that should receive the error or `NULL` if no fiber
// caught it.
static ObjFiber* runtimeError(WrenVM* vm, ObjFiber* fiber, ObjString* error)
{
  ASSERT(fiber->error == NULL, "Can only fail once.");

  // Store the error in the fiber so it can be accessed later.
  fiber->error = error;

  // If the caller ran this fiber using "try", give it the error.
  if (fiber->callerIsTrying)
  {
    ObjFiber* caller = fiber->caller;

    // Make the caller's try method return the error message.
    *(caller->stackTop - 1) = OBJ_VAL(fiber->error);
    return caller;
  }

  // If we got here, nothing caught the error, so show the stack trace.
  wrenDebugPrintStackTrace(vm, fiber);
  return NULL;
}
示例#18
0
文件: wren_core.c 项目: iskolbin/wren
void wrenInitializeCore(WrenVM* vm)
{
  ObjModule* coreModule = wrenNewModule(vm, NULL);
  wrenPushRoot(vm, (Obj*)coreModule);
  
  // The core module's key is null in the module map.
  wrenMapSet(vm, vm->modules, NULL_VAL, OBJ_VAL(coreModule));
  wrenPopRoot(vm); // coreModule.

  // Define the root Object class. This has to be done a little specially
  // because it has no superclass.
  vm->objectClass = defineClass(vm, coreModule, "Object");
  PRIMITIVE(vm->objectClass, "!", object_not);
  PRIMITIVE(vm->objectClass, "==(_)", object_eqeq);
  PRIMITIVE(vm->objectClass, "!=(_)", object_bangeq);
  PRIMITIVE(vm->objectClass, "is(_)", object_is);
  PRIMITIVE(vm->objectClass, "toString", object_toString);
  PRIMITIVE(vm->objectClass, "type", object_type);

  // Now we can define Class, which is a subclass of Object.
  vm->classClass = defineClass(vm, coreModule, "Class");
  wrenBindSuperclass(vm, vm->classClass, vm->objectClass);
  PRIMITIVE(vm->classClass, "name", class_name);
  PRIMITIVE(vm->classClass, "supertype", class_supertype);
  PRIMITIVE(vm->classClass, "toString", class_toString);

  // Finally, we can define Object's metaclass which is a subclass of Class.
  ObjClass* objectMetaclass = defineClass(vm, coreModule, "Object metaclass");

  // Wire up the metaclass relationships now that all three classes are built.
  vm->objectClass->obj.classObj = objectMetaclass;
  objectMetaclass->obj.classObj = vm->classClass;
  vm->classClass->obj.classObj = vm->classClass;

  // Do this after wiring up the metaclasses so objectMetaclass doesn't get
  // collected.
  wrenBindSuperclass(vm, objectMetaclass, vm->classClass);

  PRIMITIVE(objectMetaclass, "same(_,_)", object_same);

  // The core class diagram ends up looking like this, where single lines point
  // to a class's superclass, and double lines point to its metaclass:
  //
  //        .------------------------------------. .====.
  //        |                  .---------------. | #    #
  //        v                  |               v | v    #
  //   .---------.   .-------------------.   .-------.  #
  //   | Object  |==>| Object metaclass  |==>| Class |=="
  //   '---------'   '-------------------'   '-------'
  //        ^                                 ^ ^ ^ ^
  //        |                  .--------------' # | #
  //        |                  |                # | #
  //   .---------.   .-------------------.      # | # -.
  //   |  Base   |==>|  Base metaclass   |======" | #  |
  //   '---------'   '-------------------'        | #  |
  //        ^                                     | #  |
  //        |                  .------------------' #  | Example classes
  //        |                  |                    #  |
  //   .---------.   .-------------------.          #  |
  //   | Derived |==>| Derived metaclass |=========="  |
  //   '---------'   '-------------------'            -'

  // The rest of the classes can now be defined normally.
  wrenInterpretInModule(vm, NULL, coreModuleSource);

  vm->boolClass = AS_CLASS(wrenFindVariable(vm, coreModule, "Bool"));
  PRIMITIVE(vm->boolClass, "toString", bool_toString);
  PRIMITIVE(vm->boolClass, "!", bool_not);

  vm->fiberClass = AS_CLASS(wrenFindVariable(vm, coreModule, "Fiber"));
  PRIMITIVE(vm->fiberClass->obj.classObj, "new(_)", fiber_new);
  PRIMITIVE(vm->fiberClass->obj.classObj, "abort(_)", fiber_abort);
  PRIMITIVE(vm->fiberClass->obj.classObj, "current", fiber_current);
  PRIMITIVE(vm->fiberClass->obj.classObj, "suspend()", fiber_suspend);
  PRIMITIVE(vm->fiberClass->obj.classObj, "yield()", fiber_yield);
  PRIMITIVE(vm->fiberClass->obj.classObj, "yield(_)", fiber_yield1);
  PRIMITIVE(vm->fiberClass, "call()", fiber_call);
  PRIMITIVE(vm->fiberClass, "call(_)", fiber_call1);
  PRIMITIVE(vm->fiberClass, "error", fiber_error);
  PRIMITIVE(vm->fiberClass, "isDone", fiber_isDone);
  PRIMITIVE(vm->fiberClass, "transfer()", fiber_transfer);
  PRIMITIVE(vm->fiberClass, "transfer(_)", fiber_transfer1);
  PRIMITIVE(vm->fiberClass, "transferError(_)", fiber_transferError);
  PRIMITIVE(vm->fiberClass, "try()", fiber_try);

  vm->fnClass = AS_CLASS(wrenFindVariable(vm, coreModule, "Fn"));
  PRIMITIVE(vm->fnClass->obj.classObj, "new(_)", fn_new);

  PRIMITIVE(vm->fnClass, "arity", fn_arity);
  fnCall(vm, "call()");
  fnCall(vm, "call(_)");
  fnCall(vm, "call(_,_)");
  fnCall(vm, "call(_,_,_)");
  fnCall(vm, "call(_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_,_,_,_,_,_,_)");
  fnCall(vm, "call(_,_,_,_,_,_,_,_,_,_,_,_,_,_,_,_)");
  PRIMITIVE(vm->fnClass, "toString", fn_toString);

  vm->nullClass = AS_CLASS(wrenFindVariable(vm, coreModule, "Null"));
  PRIMITIVE(vm->nullClass, "!", null_not);
  PRIMITIVE(vm->nullClass, "toString", null_toString);

  vm->numClass = AS_CLASS(wrenFindVariable(vm, coreModule, "Num"));
  PRIMITIVE(vm->numClass->obj.classObj, "fromString(_)", num_fromString);
  PRIMITIVE(vm->numClass->obj.classObj, "pi", num_pi);
  PRIMITIVE(vm->numClass, "-(_)", num_minus);
  PRIMITIVE(vm->numClass, "+(_)", num_plus);
  PRIMITIVE(vm->numClass, "*(_)", num_multiply);
  PRIMITIVE(vm->numClass, "/(_)", num_divide);
  PRIMITIVE(vm->numClass, "<(_)", num_lt);
  PRIMITIVE(vm->numClass, ">(_)", num_gt);
  PRIMITIVE(vm->numClass, "<=(_)", num_lte);
  PRIMITIVE(vm->numClass, ">=(_)", num_gte);
  PRIMITIVE(vm->numClass, "&(_)", num_bitwiseAnd);
  PRIMITIVE(vm->numClass, "|(_)", num_bitwiseOr);
  PRIMITIVE(vm->numClass, "^(_)", num_bitwiseXor);
  PRIMITIVE(vm->numClass, "<<(_)", num_bitwiseLeftShift);
  PRIMITIVE(vm->numClass, ">>(_)", num_bitwiseRightShift);
  PRIMITIVE(vm->numClass, "abs", num_abs);
  PRIMITIVE(vm->numClass, "acos", num_acos);
  PRIMITIVE(vm->numClass, "asin", num_asin);
  PRIMITIVE(vm->numClass, "atan", num_atan);
  PRIMITIVE(vm->numClass, "ceil", num_ceil);
  PRIMITIVE(vm->numClass, "cos", num_cos);
  PRIMITIVE(vm->numClass, "floor", num_floor);
  PRIMITIVE(vm->numClass, "-", num_negate);
  PRIMITIVE(vm->numClass, "sin", num_sin);
  PRIMITIVE(vm->numClass, "sqrt", num_sqrt);
  PRIMITIVE(vm->numClass, "tan", num_tan);
  PRIMITIVE(vm->numClass, "%(_)", num_mod);
  PRIMITIVE(vm->numClass, "~", num_bitwiseNot);
  PRIMITIVE(vm->numClass, "..(_)", num_dotDot);
  PRIMITIVE(vm->numClass, "...(_)", num_dotDotDot);
  PRIMITIVE(vm->numClass, "atan(_)", num_atan2);
  PRIMITIVE(vm->numClass, "fraction", num_fraction);
  PRIMITIVE(vm->numClass, "isInfinity", num_isInfinity);
  PRIMITIVE(vm->numClass, "isInteger", num_isInteger);
  PRIMITIVE(vm->numClass, "isNan", num_isNan);
  PRIMITIVE(vm->numClass, "sign", num_sign);
  PRIMITIVE(vm->numClass, "toString", num_toString);
  PRIMITIVE(vm->numClass, "truncate", num_truncate);

  // These are defined just so that 0 and -0 are equal, which is specified by
  // IEEE 754 even though they have different bit representations.
  PRIMITIVE(vm->numClass, "==(_)", num_eqeq);
  PRIMITIVE(vm->numClass, "!=(_)", num_bangeq);

  vm->stringClass = AS_CLASS(wrenFindVariable(vm, coreModule, "String"));
  PRIMITIVE(vm->stringClass->obj.classObj, "fromCodePoint(_)", string_fromCodePoint);
  PRIMITIVE(vm->stringClass, "+(_)", string_plus);
  PRIMITIVE(vm->stringClass, "[_]", string_subscript);
  PRIMITIVE(vm->stringClass, "byteAt_(_)", string_byteAt);
  PRIMITIVE(vm->stringClass, "byteCount_", string_byteCount);
  PRIMITIVE(vm->stringClass, "codePointAt_(_)", string_codePointAt);
  PRIMITIVE(vm->stringClass, "contains(_)", string_contains);
  PRIMITIVE(vm->stringClass, "endsWith(_)", string_endsWith);
  PRIMITIVE(vm->stringClass, "indexOf(_)", string_indexOf);
  PRIMITIVE(vm->stringClass, "iterate(_)", string_iterate);
  PRIMITIVE(vm->stringClass, "iterateByte_(_)", string_iterateByte);
  PRIMITIVE(vm->stringClass, "iteratorValue(_)", string_iteratorValue);
  PRIMITIVE(vm->stringClass, "startsWith(_)", string_startsWith);
  PRIMITIVE(vm->stringClass, "toString", string_toString);

  vm->listClass = AS_CLASS(wrenFindVariable(vm, coreModule, "List"));
  PRIMITIVE(vm->listClass->obj.classObj, "new()", list_new);
  PRIMITIVE(vm->listClass, "[_]", list_subscript);
  PRIMITIVE(vm->listClass, "[_]=(_)", list_subscriptSetter);
  PRIMITIVE(vm->listClass, "add(_)", list_add);
  PRIMITIVE(vm->listClass, "addCore_(_)", list_addCore);
  PRIMITIVE(vm->listClass, "clear()", list_clear);
  PRIMITIVE(vm->listClass, "count", list_count);
  PRIMITIVE(vm->listClass, "insert(_,_)", list_insert);
  PRIMITIVE(vm->listClass, "iterate(_)", list_iterate);
  PRIMITIVE(vm->listClass, "iteratorValue(_)", list_iteratorValue);
  PRIMITIVE(vm->listClass, "removeAt(_)", list_removeAt);

  vm->mapClass = AS_CLASS(wrenFindVariable(vm, coreModule, "Map"));
  PRIMITIVE(vm->mapClass->obj.classObj, "new()", map_new);
  PRIMITIVE(vm->mapClass, "[_]", map_subscript);
  PRIMITIVE(vm->mapClass, "[_]=(_)", map_subscriptSetter);
  PRIMITIVE(vm->mapClass, "addCore_(_,_)", map_addCore);
  PRIMITIVE(vm->mapClass, "clear()", map_clear);
  PRIMITIVE(vm->mapClass, "containsKey(_)", map_containsKey);
  PRIMITIVE(vm->mapClass, "count", map_count);
  PRIMITIVE(vm->mapClass, "remove(_)", map_remove);
  PRIMITIVE(vm->mapClass, "iterate_(_)", map_iterate);
  PRIMITIVE(vm->mapClass, "keyIteratorValue_(_)", map_keyIteratorValue);
  PRIMITIVE(vm->mapClass, "valueIteratorValue_(_)", map_valueIteratorValue);

  vm->rangeClass = AS_CLASS(wrenFindVariable(vm, coreModule, "Range"));
  PRIMITIVE(vm->rangeClass, "from", range_from);
  PRIMITIVE(vm->rangeClass, "to", range_to);
  PRIMITIVE(vm->rangeClass, "min", range_min);
  PRIMITIVE(vm->rangeClass, "max", range_max);
  PRIMITIVE(vm->rangeClass, "isInclusive", range_isInclusive);
  PRIMITIVE(vm->rangeClass, "iterate(_)", range_iterate);
  PRIMITIVE(vm->rangeClass, "iteratorValue(_)", range_iteratorValue);
  PRIMITIVE(vm->rangeClass, "toString", range_toString);

  ObjClass* systemClass = AS_CLASS(wrenFindVariable(vm, coreModule, "System"));
  PRIMITIVE(systemClass->obj.classObj, "clock", system_clock);
  PRIMITIVE(systemClass->obj.classObj, "gc()", system_gc);
  // TODO: Do we want to give these magic names that can't be called from
  // regular code?
  PRIMITIVE(systemClass->obj.classObj, "getModuleVariable(_,_)", system_getModuleVariable);
  PRIMITIVE(systemClass->obj.classObj, "importModule(_)", system_importModule);
  PRIMITIVE(systemClass->obj.classObj, "writeString_(_)", system_writeString);

  // While bootstrapping the core types and running the core module, a number
  // of string objects have been created, many of which were instantiated
  // before stringClass was stored in the VM. Some of them *must* be created
  // first -- the ObjClass for string itself has a reference to the ObjString
  // for its name.
  //
  // These all currently have a NULL classObj pointer, so go back and assign
  // them now that the string class is known.
  for (Obj* obj = vm->first; obj != NULL; obj = obj->next)
  {
    if (obj->type == OBJ_STRING) obj->classObj = vm->stringClass;
  }
}
示例#19
0
文件: wren_vm.c 项目: zeckalpha/wren
// The main bytecode interpreter loop. This is where the magic happens. It is
// also, as you can imagine, highly performance critical. Returns `true` if the
// fiber completed without error.
static bool runInterpreter(WrenVM* vm)
{
  // Hoist these into local variables. They are accessed frequently in the loop
  // but assigned less frequently. Keeping them in locals and updating them when
  // a call frame has been pushed or popped gives a large speed boost.
  register ObjFiber* fiber = vm->fiber;
  register CallFrame* frame;
  register Value* stackStart;
  register uint8_t* ip;
  register ObjFn* fn;

  // These macros are designed to only be invoked within this function.
  #define PUSH(value)  (*fiber->stackTop++ = value)
  #define POP()        (*(--fiber->stackTop))
  #define DROP()       (fiber->stackTop--)
  #define PEEK()       (*(fiber->stackTop - 1))
  #define PEEK2()      (*(fiber->stackTop - 2))
  #define READ_BYTE()  (*ip++)
  #define READ_SHORT() (ip += 2, (ip[-2] << 8) | ip[-1])

  // Use this before a CallFrame is pushed to store the local variables back
  // into the current one.
  #define STORE_FRAME() frame->ip = ip

  // Use this after a CallFrame has been pushed or popped to refresh the local
  // variables.
  #define LOAD_FRAME()                                 \
      frame = &fiber->frames[fiber->numFrames - 1];    \
      stackStart = frame->stackStart;                  \
      ip = frame->ip;                                  \
      if (frame->fn->type == OBJ_FN)                   \
      {                                                \
        fn = (ObjFn*)frame->fn;                        \
      }                                                \
      else                                             \
      {                                                \
        fn = ((ObjClosure*)frame->fn)->fn;             \
      }

  // Terminates the current fiber with error string [error]. If another calling
  // fiber is willing to catch the error, transfers control to it, otherwise
  // exits the interpreter.
  #define RUNTIME_ERROR(error)                         \
      do {                                             \
        STORE_FRAME();                                 \
        fiber = runtimeError(vm, fiber, error);        \
        if (fiber == NULL) return false;               \
        LOAD_FRAME();                                  \
        DISPATCH();                                    \
      }                                                \
      while (false)

  #if WREN_COMPUTED_GOTO

  // Note that the order of instructions here must exacly match the Code enum
  // in wren_vm.h or horrendously bad things happen.
  static void* dispatchTable[] = {
    &&code_CONSTANT,
    &&code_NULL,
    &&code_FALSE,
    &&code_TRUE,
    &&code_LOAD_LOCAL_0,
    &&code_LOAD_LOCAL_1,
    &&code_LOAD_LOCAL_2,
    &&code_LOAD_LOCAL_3,
    &&code_LOAD_LOCAL_4,
    &&code_LOAD_LOCAL_5,
    &&code_LOAD_LOCAL_6,
    &&code_LOAD_LOCAL_7,
    &&code_LOAD_LOCAL_8,
    &&code_LOAD_LOCAL,
    &&code_STORE_LOCAL,
    &&code_LOAD_UPVALUE,
    &&code_STORE_UPVALUE,
    &&code_LOAD_GLOBAL,
    &&code_STORE_GLOBAL,
    &&code_LOAD_FIELD_THIS,
    &&code_STORE_FIELD_THIS,
    &&code_LOAD_FIELD,
    &&code_STORE_FIELD,
    &&code_POP,
    &&code_CALL_0,
    &&code_CALL_1,
    &&code_CALL_2,
    &&code_CALL_3,
    &&code_CALL_4,
    &&code_CALL_5,
    &&code_CALL_6,
    &&code_CALL_7,
    &&code_CALL_8,
    &&code_CALL_9,
    &&code_CALL_10,
    &&code_CALL_11,
    &&code_CALL_12,
    &&code_CALL_13,
    &&code_CALL_14,
    &&code_CALL_15,
    &&code_CALL_16,
    &&code_SUPER_0,
    &&code_SUPER_1,
    &&code_SUPER_2,
    &&code_SUPER_3,
    &&code_SUPER_4,
    &&code_SUPER_5,
    &&code_SUPER_6,
    &&code_SUPER_7,
    &&code_SUPER_8,
    &&code_SUPER_9,
    &&code_SUPER_10,
    &&code_SUPER_11,
    &&code_SUPER_12,
    &&code_SUPER_13,
    &&code_SUPER_14,
    &&code_SUPER_15,
    &&code_SUPER_16,
    &&code_JUMP,
    &&code_LOOP,
    &&code_JUMP_IF,
    &&code_AND,
    &&code_OR,
    &&code_IS,
    &&code_CLOSE_UPVALUE,
    &&code_RETURN,
    &&code_LIST,
    &&code_CLOSURE,
    &&code_CLASS,
    &&code_METHOD_INSTANCE,
    &&code_METHOD_STATIC,
    &&code_END
  };

  #define INTERPRET_LOOP    DISPATCH();
  #define CASE_CODE(name)   code_##name

  #if WREN_DEBUG_TRACE_INSTRUCTIONS
    // Prints the stack and instruction before each instruction is executed.
    #define DISPATCH() \
        { \
          wrenDebugPrintStack(fiber); \
          wrenDebugPrintInstruction(vm, fn, (int)(ip - fn->bytecode)); \
          instruction = *ip++; \
          goto *dispatchTable[instruction]; \
        }
  #else

    #define DISPATCH()      goto *dispatchTable[instruction = READ_BYTE()];

  #endif

  #else

  #define INTERPRET_LOOP    for (;;) switch (instruction = READ_BYTE())
  #define CASE_CODE(name)   case CODE_##name
  #define DISPATCH()        break

  #endif

  LOAD_FRAME();

  Code instruction;
  INTERPRET_LOOP
  {
    CASE_CODE(LOAD_LOCAL_0):
    CASE_CODE(LOAD_LOCAL_1):
    CASE_CODE(LOAD_LOCAL_2):
    CASE_CODE(LOAD_LOCAL_3):
    CASE_CODE(LOAD_LOCAL_4):
    CASE_CODE(LOAD_LOCAL_5):
    CASE_CODE(LOAD_LOCAL_6):
    CASE_CODE(LOAD_LOCAL_7):
    CASE_CODE(LOAD_LOCAL_8):
      PUSH(stackStart[instruction - CODE_LOAD_LOCAL_0]);
      DISPATCH();

    CASE_CODE(LOAD_LOCAL):
      PUSH(stackStart[READ_BYTE()]);
      DISPATCH();

    CASE_CODE(LOAD_FIELD_THIS):
    {
      int field = READ_BYTE();
      Value receiver = stackStart[0];
      ASSERT(IS_INSTANCE(receiver), "Receiver should be instance.");
      ObjInstance* instance = AS_INSTANCE(receiver);
      ASSERT(field < instance->obj.classObj->numFields, "Out of bounds field.");
      PUSH(instance->fields[field]);
      DISPATCH();
    }

    CASE_CODE(POP):   DROP(); DISPATCH();
    CASE_CODE(NULL):  PUSH(NULL_VAL); DISPATCH();
    CASE_CODE(FALSE): PUSH(FALSE_VAL); DISPATCH();
    CASE_CODE(TRUE):  PUSH(TRUE_VAL); DISPATCH();

    CASE_CODE(CALL_0):
    CASE_CODE(CALL_1):
    CASE_CODE(CALL_2):
    CASE_CODE(CALL_3):
    CASE_CODE(CALL_4):
    CASE_CODE(CALL_5):
    CASE_CODE(CALL_6):
    CASE_CODE(CALL_7):
    CASE_CODE(CALL_8):
    CASE_CODE(CALL_9):
    CASE_CODE(CALL_10):
    CASE_CODE(CALL_11):
    CASE_CODE(CALL_12):
    CASE_CODE(CALL_13):
    CASE_CODE(CALL_14):
    CASE_CODE(CALL_15):
    CASE_CODE(CALL_16):
    {
      // Add one for the implicit receiver argument.
      int numArgs = instruction - CODE_CALL_0 + 1;
      int symbol = READ_SHORT();

      Value receiver = *(fiber->stackTop - numArgs);
      ObjClass* classObj = wrenGetClassInline(vm, receiver);

      // If the class's method table doesn't include the symbol, bail.
      if (symbol >= classObj->methods.count)
      {
        RUNTIME_ERROR(methodNotFound(vm, classObj, symbol));
      }

      Method* method = &classObj->methods.data[symbol];
      switch (method->type)
      {
        case METHOD_PRIMITIVE:
        {
          Value* args = fiber->stackTop - numArgs;

          // After calling this, the result will be in the first arg slot.
          switch (method->fn.primitive(vm, fiber, args))
          {
            case PRIM_VALUE:
              // The result is now in the first arg slot. Discard the other
              // stack slots.
              fiber->stackTop -= numArgs - 1;
              break;

            case PRIM_ERROR:
              RUNTIME_ERROR(AS_STRING(args[0]));

            case PRIM_CALL:
              STORE_FRAME();
              callFunction(fiber, AS_OBJ(args[0]), numArgs);
              LOAD_FRAME();
              break;

            case PRIM_RUN_FIBER:
              STORE_FRAME();
              fiber = AS_FIBER(args[0]);
              LOAD_FRAME();
              break;
          }
          break;
        }

        case METHOD_FOREIGN:
          callForeign(vm, fiber, method->fn.foreign, numArgs);
          break;

        case METHOD_BLOCK:
          STORE_FRAME();
          callFunction(fiber, method->fn.obj, numArgs);
          LOAD_FRAME();
          break;

        case METHOD_NONE:
          RUNTIME_ERROR(methodNotFound(vm, classObj, symbol));
          break;
      }
      DISPATCH();
    }

    CASE_CODE(STORE_LOCAL):
      stackStart[READ_BYTE()] = PEEK();
      DISPATCH();

    CASE_CODE(CONSTANT):
      PUSH(fn->constants[READ_SHORT()]);
      DISPATCH();

    CASE_CODE(SUPER_0):
    CASE_CODE(SUPER_1):
    CASE_CODE(SUPER_2):
    CASE_CODE(SUPER_3):
    CASE_CODE(SUPER_4):
    CASE_CODE(SUPER_5):
    CASE_CODE(SUPER_6):
    CASE_CODE(SUPER_7):
    CASE_CODE(SUPER_8):
    CASE_CODE(SUPER_9):
    CASE_CODE(SUPER_10):
    CASE_CODE(SUPER_11):
    CASE_CODE(SUPER_12):
    CASE_CODE(SUPER_13):
    CASE_CODE(SUPER_14):
    CASE_CODE(SUPER_15):
    CASE_CODE(SUPER_16):
    {
      // TODO: Almost completely copied from CALL. Unify somehow.

      // Add one for the implicit receiver argument.
      int numArgs = instruction - CODE_SUPER_0 + 1;
      int symbol = READ_SHORT();

      Value receiver = *(fiber->stackTop - numArgs);
      ObjClass* classObj = wrenGetClassInline(vm, receiver);

      // Ignore methods defined on the receiver's immediate class.
      classObj = classObj->superclass;

      // If the class's method table doesn't include the symbol, bail.
      if (symbol >= classObj->methods.count)
      {
        RUNTIME_ERROR(methodNotFound(vm, classObj, symbol));
      }

      Method* method = &classObj->methods.data[symbol];
      switch (method->type)
      {
        case METHOD_PRIMITIVE:
        {
          Value* args = fiber->stackTop - numArgs;

          // After calling this, the result will be in the first arg slot.
          switch (method->fn.primitive(vm, fiber, args))
          {
            case PRIM_VALUE:
              // The result is now in the first arg slot. Discard the other
              // stack slots.
              fiber->stackTop -= numArgs - 1;
              break;

            case PRIM_ERROR:
              RUNTIME_ERROR(AS_STRING(args[0]));

            case PRIM_CALL:
              STORE_FRAME();
              callFunction(fiber, AS_OBJ(args[0]), numArgs);
              LOAD_FRAME();
              break;

            case PRIM_RUN_FIBER:
              STORE_FRAME();
              fiber = AS_FIBER(args[0]);
              LOAD_FRAME();
              break;
          }
          break;
        }

        case METHOD_FOREIGN:
          callForeign(vm, fiber, method->fn.foreign, numArgs);
          break;

        case METHOD_BLOCK:
          STORE_FRAME();
          callFunction(fiber, method->fn.obj, numArgs);
          LOAD_FRAME();
          break;

        case METHOD_NONE:
          RUNTIME_ERROR(methodNotFound(vm, classObj, symbol));
          break;
      }
      DISPATCH();
    }

    CASE_CODE(LOAD_UPVALUE):
    {
      Upvalue** upvalues = ((ObjClosure*)frame->fn)->upvalues;
      PUSH(*upvalues[READ_BYTE()]->value);
      DISPATCH();
    }

    CASE_CODE(STORE_UPVALUE):
    {
      Upvalue** upvalues = ((ObjClosure*)frame->fn)->upvalues;
      *upvalues[READ_BYTE()]->value = PEEK();
      DISPATCH();
    }

    CASE_CODE(LOAD_GLOBAL):
      PUSH(vm->globals.data[READ_SHORT()]);
      DISPATCH();

    CASE_CODE(STORE_GLOBAL):
      vm->globals.data[READ_SHORT()] = PEEK();
      DISPATCH();

    CASE_CODE(STORE_FIELD_THIS):
    {
      int field = READ_BYTE();
      Value receiver = stackStart[0];
      ASSERT(IS_INSTANCE(receiver), "Receiver should be instance.");
      ObjInstance* instance = AS_INSTANCE(receiver);
      ASSERT(field < instance->obj.classObj->numFields, "Out of bounds field.");
      instance->fields[field] = PEEK();
      DISPATCH();
    }

    CASE_CODE(LOAD_FIELD):
    {
      int field = READ_BYTE();
      Value receiver = POP();
      ASSERT(IS_INSTANCE(receiver), "Receiver should be instance.");
      ObjInstance* instance = AS_INSTANCE(receiver);
      ASSERT(field < instance->obj.classObj->numFields, "Out of bounds field.");
      PUSH(instance->fields[field]);
      DISPATCH();
    }

    CASE_CODE(STORE_FIELD):
    {
      int field = READ_BYTE();
      Value receiver = POP();
      ASSERT(IS_INSTANCE(receiver), "Receiver should be instance.");
      ObjInstance* instance = AS_INSTANCE(receiver);
      ASSERT(field < instance->obj.classObj->numFields, "Out of bounds field.");
      instance->fields[field] = PEEK();
      DISPATCH();
    }

    CASE_CODE(JUMP):
    {
      int offset = READ_SHORT();
      ip += offset;
      DISPATCH();
    }

    CASE_CODE(LOOP):
    {
      // Jump back to the top of the loop.
      int offset = READ_SHORT();
      ip -= offset;
      DISPATCH();
    }

    CASE_CODE(JUMP_IF):
    {
      int offset = READ_SHORT();
      Value condition = POP();

      if (IS_FALSE(condition) || IS_NULL(condition)) ip += offset;
      DISPATCH();
    }

    CASE_CODE(AND):
    {
      int offset = READ_SHORT();
      Value condition = PEEK();

      if (IS_FALSE(condition) || IS_NULL(condition))
      {
        // Short-circuit the right hand side.
        ip += offset;
      }
      else
      {
        // Discard the condition and evaluate the right hand side.
        DROP();
      }
      DISPATCH();
    }

    CASE_CODE(OR):
    {
      int offset = READ_SHORT();
      Value condition = PEEK();

      if (IS_FALSE(condition) || IS_NULL(condition))
      {
        // Discard the condition and evaluate the right hand side.
        DROP();
      }
      else
      {
        // Short-circuit the right hand side.
        ip += offset;
      }
      DISPATCH();
    }

    CASE_CODE(IS):
    {
      Value expected = POP();
      if (!IS_CLASS(expected))
      {
        const char* message = "Right operand must be a class.";
        RUNTIME_ERROR(AS_STRING(wrenNewString(vm, message, strlen(message))));
      }

      ObjClass* actual = wrenGetClass(vm, POP());
      bool isInstance = false;

      // Walk the superclass chain looking for the class.
      while (actual != NULL)
      {
        if (actual == AS_CLASS(expected))
        {
          isInstance = true;
          break;
        }
        actual = actual->superclass;
      }
      PUSH(BOOL_VAL(isInstance));
      DISPATCH();
    }

    CASE_CODE(CLOSE_UPVALUE):
      closeUpvalue(fiber);
      DROP();
      DISPATCH();

    CASE_CODE(RETURN):
    {
      Value result = POP();
      fiber->numFrames--;

      // Close any upvalues still in scope.
      Value* firstValue = stackStart;
      while (fiber->openUpvalues != NULL &&
             fiber->openUpvalues->value >= firstValue)
      {
        closeUpvalue(fiber);
      }

      // If the fiber is complete, end it.
      if (fiber->numFrames == 0)
      {
        // If this is the main fiber, we're done.
        if (fiber->caller == NULL) return true;

        // We have a calling fiber to resume.
        fiber = fiber->caller;

        // Store the result in the resuming fiber.
        *(fiber->stackTop - 1) = result;
      }
      else
      {
        // Store the result of the block in the first slot, which is where the
        // caller expects it.
        stackStart[0] = result;

        // Discard the stack slots for the call frame (leaving one slot for the
        // result).
        fiber->stackTop = frame->stackStart + 1;
      }

      LOAD_FRAME();
      DISPATCH();
    }

    CASE_CODE(LIST):
    {
      int numElements = READ_BYTE();
      ObjList* list = wrenNewList(vm, numElements);
      // TODO: Do a straight memcopy.
      for (int i = 0; i < numElements; i++)
      {
        list->elements[i] = *(fiber->stackTop - numElements + i);
      }

      // Discard the elements.
      fiber->stackTop -= numElements;

      PUSH(OBJ_VAL(list));
      DISPATCH();
    }

    CASE_CODE(CLOSURE):
    {
      ObjFn* prototype = AS_FN(fn->constants[READ_SHORT()]);

      ASSERT(prototype->numUpvalues > 0,
             "Should not create closure for functions that don't need it.");

      // Create the closure and push it on the stack before creating upvalues
      // so that it doesn't get collected.
      ObjClosure* closure = wrenNewClosure(vm, prototype);
      PUSH(OBJ_VAL(closure));

      // Capture upvalues.
      for (int i = 0; i < prototype->numUpvalues; i++)
      {
        bool isLocal = READ_BYTE();
        int index = READ_BYTE();
        if (isLocal)
        {
          // Make an new upvalue to close over the parent's local variable.
          closure->upvalues[i] = captureUpvalue(vm, fiber,
                                                frame->stackStart + index);
        }
        else
        {
          // Use the same upvalue as the current call frame.
          closure->upvalues[i] = ((ObjClosure*)frame->fn)->upvalues[index];
        }
      }

      DISPATCH();
    }

    CASE_CODE(CLASS):
    {
      ObjString* name = AS_STRING(PEEK2());

      ObjClass* superclass;
      if (IS_NULL(PEEK()))
      {
        // Implicit Object superclass.
        superclass = vm->objectClass;
      }
      else
      {
        // TODO: Handle the superclass not being a class object!
        superclass = AS_CLASS(PEEK());
      }

      int numFields = READ_BYTE();

      ObjClass* classObj = wrenNewClass(vm, superclass, numFields, name);

      // Don't pop the superclass and name off the stack until the subclass is
      // done being created, to make sure it doesn't get collected.
      DROP();
      DROP();

      // Now that we know the total number of fields, make sure we don't
      // overflow.
      if (superclass->numFields + numFields > MAX_FIELDS)
      {
        char message[70 + MAX_VARIABLE_NAME];
        snprintf(message, 70 + MAX_VARIABLE_NAME,
            "Class '%s' may not have more than %d fields, including inherited "
            "ones.", name->value, MAX_FIELDS);

        RUNTIME_ERROR(AS_STRING(wrenNewString(vm, message, strlen(message))));
      }

      PUSH(OBJ_VAL(classObj));
      DISPATCH();
    }

    CASE_CODE(METHOD_INSTANCE):
    CASE_CODE(METHOD_STATIC):
    {
      int type = instruction;
      int symbol = READ_SHORT();
      ObjClass* classObj = AS_CLASS(PEEK());
      Value method = PEEK2();
      bindMethod(vm, type, symbol, classObj, method);
      DROP();
      DROP();
      DISPATCH();
    }

    CASE_CODE(END):
      // A CODE_END should always be preceded by a CODE_RETURN. If we get here,
      // the compiler generated wrong code.
      UNREACHABLE();
  }

  // We should only exit this function from an explicit return from CODE_RETURN
  // or a runtime error.
  UNREACHABLE();
  return false;
}

WrenInterpretResult wrenInterpret(WrenVM* vm, const char* sourcePath,
                                  const char* source)
{
  // TODO: Check for freed VM.
  ObjFn* fn = wrenCompile(vm, sourcePath, source);
  if (fn == NULL) return WREN_RESULT_COMPILE_ERROR;

  WREN_PIN(vm, fn);
  vm->fiber = wrenNewFiber(vm, (Obj*)fn);
  WREN_UNPIN(vm);

  if (runInterpreter(vm))
  {
    return WREN_RESULT_SUCCESS;
  }
  else
  {
    return WREN_RESULT_RUNTIME_ERROR;
  }
}
示例#20
0
文件: compiler.c 项目: lerno/coil
static void string()
{
	emit_constant(OBJ_VAL(copy_string(parser.previous.start + 1, parser.previous.length - 2)));
}