from .operations import * from .base import get_member, get_member_dot, PyJsFunction, Scope class OP_CODE(object): _params = [] # def eval(self, ctx): # raise def __repr__(self): return self.__class__.__name__ + str( tuple([getattr(self, e) for e in self._params])) # --------------------- UNARY ---------------------- class UNARY_OP(OP_CODE): _params = ['operator'] def __init__(self, operator): self.operator = operator def eval(self, ctx): val = ctx.stack.pop() ctx.stack.append(UNARY_OPERATIONS[self.operator](val)) # special unary operations class TYPEOF(OP_CODE): _params = ['identifier'] def __init__(self, identifier): self.identifier = identifier def eval(self, ctx): # typeof something_undefined does not throw reference error val = ctx.get(self.identifier, False) # <= this makes it slightly different! ctx.stack.append(typeof_uop(val)) class POSTFIX(OP_CODE): _params = ['cb', 'ca', 'identifier'] def __init__(self, post, incr, identifier): self.identifier = identifier self.cb = 1 if incr else -1 self.ca = -self.cb if post else 0 def eval(self, ctx): target = to_number(ctx.get(self.identifier)) + self.cb ctx.put(self.identifier, target) ctx.stack.append(target + self.ca) class POSTFIX_MEMBER(OP_CODE): _params = ['cb', 'ca'] def __init__(self, post, incr): self.cb = 1 if incr else -1 self.ca = -self.cb if post else 0 def eval(self, ctx): name = ctx.stack.pop() left = ctx.stack.pop() target = to_number(get_member(left, name, ctx.space)) + self.cb if type(left) not in PRIMITIVES: left.put_member(name, target) ctx.stack.append(target + self.ca) class POSTFIX_MEMBER_DOT(OP_CODE): _params = ['cb', 'ca', 'prop'] def __init__(self, post, incr, prop): self.cb = 1 if incr else -1 self.ca = -self.cb if post else 0 self.prop = prop def eval(self, ctx): left = ctx.stack.pop() target = to_number(get_member_dot(left, self.prop, ctx.space)) + self.cb if type(left) not in PRIMITIVES: left.put(self.prop, target) ctx.stack.append(target + self.ca) class DELETE(OP_CODE): _params = ['name'] def __init__(self, name): self.name = name def eval(self, ctx): ctx.stack.append(ctx.delete(self.name)) class DELETE_MEMBER(OP_CODE): def eval(self, ctx): prop = to_string(ctx.stack.pop()) obj = to_object(ctx.stack.pop(), ctx) ctx.stack.append(obj.delete(prop, False)) # --------------------- BITWISE ---------------------- class BINARY_OP(OP_CODE): _params = ['operator'] def __init__(self, operator): self.operator = operator def eval(self, ctx): right = ctx.stack.pop() left = ctx.stack.pop() ctx.stack.append(BINARY_OPERATIONS[self.operator](left, right)) # &&, || and conditional are implemented in bytecode # --------------------- JUMPS ---------------------- # simple label that will be removed from code after compilation. labels ID will be translated # to source code position. class LABEL(OP_CODE): _params = ['num'] def __init__(self, num): self.num = num # I implemented interpreter in the way that when an integer is returned by eval operation the execution will jump # to the location of the label (it is loc = label_locations[label]) class BASE_JUMP(OP_CODE): _params = ['label'] def __init__(self, label): self.label = label class JUMP(BASE_JUMP): def eval(self, ctx): return self.label class JUMP_IF_TRUE(BASE_JUMP): def eval(self, ctx): val = ctx.stack.pop() if to_boolean(val): return self.label class JUMP_IF_EQ(BASE_JUMP): # this one is used in switch statement - compares last 2 values using === operator and jumps popping both if true else pops last. def eval(self, ctx): cmp = ctx.stack.pop() if strict_equality_op(ctx.stack[-1], cmp): ctx.stack.pop() return self.label class JUMP_IF_TRUE_WITHOUT_POP(BASE_JUMP): def eval(self, ctx): val = ctx.stack[-1] if to_boolean(val): return self.label class JUMP_IF_FALSE(BASE_JUMP): def eval(self, ctx): val = ctx.stack.pop() if not to_boolean(val): return self.label class JUMP_IF_FALSE_WITHOUT_POP(BASE_JUMP): def eval(self, ctx): val = ctx.stack[-1] if not to_boolean(val): return self.label class POP(OP_CODE): def eval(self, ctx): # todo remove this check later assert len(ctx.stack), 'Popped from empty stack!' del ctx.stack[-1] # class REDUCE(OP_CODE): # def eval(self, ctx): # assert len(ctx.stack)==2 # ctx.stack[0] = ctx.stack[1] # del ctx.stack[1] # --------------- LOADING -------------- class LOAD_NONE(OP_CODE): # be careful with this :) _params = [] def eval(self, ctx): ctx.stack.append(None) class LOAD_N_TUPLE( OP_CODE ): # loads the tuple composed of n last elements on stack. elements are popped. _params = ['n'] def __init__(self, n): self.n = n def eval(self, ctx): tup = tuple(ctx.stack[-self.n:]) del ctx.stack[-self.n:] ctx.stack.append(tup) class LOAD_UNDEFINED(OP_CODE): def eval(self, ctx): ctx.stack.append(undefined) class LOAD_NULL(OP_CODE): def eval(self, ctx): ctx.stack.append(null) class LOAD_BOOLEAN(OP_CODE): _params = ['val'] def __init__(self, val): assert val in (0, 1) self.val = bool(val) def eval(self, ctx): ctx.stack.append(self.val) class LOAD_STRING(OP_CODE): _params = ['val'] def __init__(self, val): assert isinstance(val, basestring) self.val = unicode(val) def eval(self, ctx): ctx.stack.append(self.val) class LOAD_NUMBER(OP_CODE): _params = ['val'] def __init__(self, val): assert isinstance(val, (float, int, long)) self.val = float(val) def eval(self, ctx): ctx.stack.append(self.val) class LOAD_REGEXP(OP_CODE): _params = ['body', 'flags'] def __init__(self, body, flags): self.body = body self.flags = flags def eval(self, ctx): # we have to generate a new regexp - they are mutable ctx.stack.append(ctx.space.NewRegExp(self.body, self.flags)) class LOAD_FUNCTION(OP_CODE): _params = ['start', 'params', 'name', 'is_declaration', 'definitions'] def __init__(self, start, params, name, is_declaration, definitions): assert type(start) == int self.start = start # its an ID of label pointing to the beginning of the function bytecode self.params = params self.name = name self.is_declaration = bool(is_declaration) self.definitions = tuple(set(definitions + params)) def eval(self, ctx): ctx.stack.append( ctx.space.NewFunction(self.start, ctx, self.params, self.name, self.is_declaration, self.definitions)) class LOAD_OBJECT(OP_CODE): _params = [ 'props' ] # props are py string pairs (prop_name, kind): kind can be either i, g or s. (init, get, set) def __init__(self, props): self.num = len(props) self.props = props def eval(self, ctx): obj = ctx.space.NewObject() if self.num: obj._init(self.props, ctx.stack[-self.num:]) del ctx.stack[-self.num:] ctx.stack.append(obj) class LOAD_ARRAY(OP_CODE): _params = ['num'] def __init__(self, num): self.num = num def eval(self, ctx): arr = ctx.space.NewArray(self.num) if self.num: arr._init(ctx.stack[-self.num:]) del ctx.stack[-self.num:] ctx.stack.append(arr) class LOAD_THIS(OP_CODE): def eval(self, ctx): ctx.stack.append(ctx.THIS_BINDING) class LOAD(OP_CODE): # todo check! _params = ['identifier'] def __init__(self, identifier): self.identifier = identifier # 11.1.2 def eval(self, ctx): ctx.stack.append(ctx.get(self.identifier, throw=True)) class LOAD_MEMBER(OP_CODE): def eval(self, ctx): prop = ctx.stack.pop() obj = ctx.stack.pop() ctx.stack.append(get_member(obj, prop, ctx.space)) class LOAD_MEMBER_DOT(OP_CODE): _params = ['prop'] def __init__(self, prop): self.prop = prop def eval(self, ctx): obj = ctx.stack.pop() ctx.stack.append(get_member_dot(obj, self.prop, ctx.space)) # --------------- STORING -------------- class STORE(OP_CODE): _params = ['identifier'] def __init__(self, identifier): self.identifier = identifier def eval(self, ctx): value = ctx.stack[-1] # don't pop ctx.put(self.identifier, value) class STORE_MEMBER(OP_CODE): def eval(self, ctx): value = ctx.stack.pop() name = ctx.stack.pop() left = ctx.stack.pop() typ = type(left) if typ in PRIMITIVES: prop = to_string(name) if typ == NULL_TYPE: raise MakeError('TypeError', "Cannot set property '%s' of null" % prop) elif typ == UNDEFINED_TYPE: raise MakeError('TypeError', "Cannot set property '%s' of undefined" % prop) # just ignore... else: left.put_member(name, value) ctx.stack.append(value) class STORE_MEMBER_DOT(OP_CODE): _params = ['prop'] def __init__(self, prop): self.prop = prop def eval(self, ctx): value = ctx.stack.pop() left = ctx.stack.pop() typ = type(left) if typ in PRIMITIVES: if typ == NULL_TYPE: raise MakeError('TypeError', "Cannot set property '%s' of null" % self.prop) elif typ == UNDEFINED_TYPE: raise MakeError( 'TypeError', "Cannot set property '%s' of undefined" % self.prop) # just ignore... else: left.put(self.prop, value) ctx.stack.append(value) class STORE_OP(OP_CODE): _params = ['identifier', 'op'] def __init__(self, identifier, op): self.identifier = identifier self.op = op def eval(self, ctx): value = ctx.stack.pop() new_value = BINARY_OPERATIONS[self.op](ctx.get(self.identifier), value) ctx.put(self.identifier, new_value) ctx.stack.append(new_value) class STORE_MEMBER_OP(OP_CODE): _params = ['op'] def __init__(self, op): self.op = op def eval(self, ctx): value = ctx.stack.pop() name = ctx.stack.pop() left = ctx.stack.pop() typ = type(left) if typ in PRIMITIVES: if typ is NULL_TYPE: raise MakeError( 'TypeError', "Cannot set property '%s' of null" % to_string(name)) elif typ is UNDEFINED_TYPE: raise MakeError( 'TypeError', "Cannot set property '%s' of undefined" % to_string(name)) ctx.stack.append(BINARY_OPERATIONS[self.op](get_member( left, name, ctx.space), value)) return else: ctx.stack.append(BINARY_OPERATIONS[self.op](get_member( left, name, ctx.space), value)) left.put_member(name, ctx.stack[-1]) class STORE_MEMBER_DOT_OP(OP_CODE): _params = ['prop', 'op'] def __init__(self, prop, op): self.prop = prop self.op = op def eval(self, ctx): value = ctx.stack.pop() left = ctx.stack.pop() typ = type(left) if typ in PRIMITIVES: if typ == NULL_TYPE: raise MakeError('TypeError', "Cannot set property '%s' of null" % self.prop) elif typ == UNDEFINED_TYPE: raise MakeError( 'TypeError', "Cannot set property '%s' of undefined" % self.prop) ctx.stack.append(BINARY_OPERATIONS[self.op](get_member_dot( left, self.prop, ctx.space), value)) return else: ctx.stack.append(BINARY_OPERATIONS[self.op](get_member_dot( left, self.prop, ctx.space), value)) left.put(self.prop, ctx.stack[-1]) # --------------- CALLS -------------- def bytecode_call(ctx, func, this, args): if type(func) is not PyJsFunction: raise MakeError('TypeError', "%s is not a function" % Type(func)) if func.is_native: # call to built-in function or method ctx.stack.append(func.call(this, args)) return None # therefore not native. we have to return (new_context, function_label) to instruct interpreter to call return func._generate_my_context(this, args), func.code class CALL(OP_CODE): def eval(self, ctx): args = ctx.stack.pop() func = ctx.stack.pop() return bytecode_call(ctx, func, ctx.space.GlobalObj, args) class CALL_METHOD(OP_CODE): def eval(self, ctx): args = ctx.stack.pop() prop = ctx.stack.pop() base = ctx.stack.pop() func = get_member(base, prop, ctx.space) return bytecode_call(ctx, func, base, args) class CALL_METHOD_DOT(OP_CODE): _params = ['prop'] def __init__(self, prop): self.prop = prop def eval(self, ctx): args = ctx.stack.pop() base = ctx.stack.pop() func = get_member_dot(base, self.prop, ctx.space) return bytecode_call(ctx, func, base, args) class CALL_NO_ARGS(OP_CODE): def eval(self, ctx): func = ctx.stack.pop() return bytecode_call(ctx, func, ctx.space.GlobalObj, ()) class CALL_METHOD_NO_ARGS(OP_CODE): def eval(self, ctx): prop = ctx.stack.pop() base = ctx.stack.pop() func = get_member(base, prop, ctx.space) return bytecode_call(ctx, func, base, ()) class CALL_METHOD_DOT_NO_ARGS(OP_CODE): _params = ['prop'] def __init__(self, prop): self.prop = prop def eval(self, ctx): base = ctx.stack.pop() func = get_member_dot(base, self.prop, ctx.space) return bytecode_call(ctx, func, base, ()) class NOP(OP_CODE): def eval(self, ctx): pass class RETURN(OP_CODE): def eval( self, ctx ): # remember to load the return value on stack before using RETURN op. return (None, None) class NEW(OP_CODE): def eval(self, ctx): args = ctx.stack.pop() constructor = ctx.stack.pop() if type(constructor) in PRIMITIVES or not hasattr( constructor, 'create'): raise MakeError('TypeError', '%s is not a constructor' % Type(constructor)) ctx.stack.append(constructor.create(args, space=ctx.space)) class NEW_NO_ARGS(OP_CODE): def eval(self, ctx): constructor = ctx.stack.pop() if type(constructor) in PRIMITIVES or not hasattr( constructor, 'create'): raise MakeError('TypeError', '%s is not a constructor' % Type(constructor)) ctx.stack.append(constructor.create((), space=ctx.space)) # --------------- EXCEPTIONS -------------- class THROW(OP_CODE): def eval(self, ctx): raise MakeError(None, None, ctx.stack.pop()) class TRY_CATCH_FINALLY(OP_CODE): _params = [ 'try_label', 'catch_label', 'catch_variable', 'finally_label', 'finally_present', 'end_label' ] def __init__(self, try_label, catch_label, catch_variable, finally_label, finally_present, end_label): self.try_label = try_label self.catch_label = catch_label self.catch_variable = catch_variable self.finally_label = finally_label self.finally_present = finally_present self.end_label = end_label def eval(self, ctx): # 4 different exectution results # 0=normal, 1=return, 2=jump_outside, 3=errors # execute_fragment_under_context returns: # (return_value, typ, jump_loc/error) ctx.stack.pop() # execute try statement try_status = ctx.space.exe.execute_fragment_under_context( ctx, self.try_label, self.catch_label) errors = try_status[1] == 3 # catch if errors and self.catch_variable is not None: # generate catch block context... catch_context = Scope({ self.catch_variable: try_status[2].get_thrown_value(ctx.space) }, ctx.space, ctx) catch_context.THIS_BINDING = ctx.THIS_BINDING catch_status = ctx.space.exe.execute_fragment_under_context( catch_context, self.catch_label, self.finally_label) else: catch_status = None # finally if self.finally_present: finally_status = ctx.space.exe.execute_fragment_under_context( ctx, self.finally_label, self.end_label) else: finally_status = None # now return controls other_status = catch_status or try_status if finally_status is None or (finally_status[1] == 0 and other_status[1] != 0): winning_status = other_status else: winning_status = finally_status val, typ, spec = winning_status if typ == 0: # normal ctx.stack.append(val) return elif typ == 1: # return ctx.stack.append(spec) return None, None # send return signal elif typ == 2: # jump outside ctx.stack.append(val) return spec elif typ == 3: # throw is made with empty stack as usual raise spec else: raise RuntimeError('Invalid return code') # ------------ WITH + ITERATORS ---------- class WITH(OP_CODE): _params = ['beg_label', 'end_label'] def __init__(self, beg_label, end_label): self.beg_label = beg_label self.end_label = end_label def eval(self, ctx): obj = to_object(ctx.stack.pop(), ctx.space) with_context = Scope( obj, ctx.space, ctx) # todo actually use the obj to modify the ctx with_context.THIS_BINDING = ctx.THIS_BINDING status = ctx.space.exe.execute_fragment_under_context( with_context, self.beg_label, self.end_label) val, typ, spec = status if typ != 3: # exception ctx.stack.pop() if typ == 0: # normal ctx.stack.append(val) return elif typ == 1: # return ctx.stack.append(spec) return None, None # send return signal elif typ == 2: # jump outside ctx.stack.append(val) return spec elif typ == 3: # exception # throw is made with empty stack as usual raise spec else: raise RuntimeError('Invalid return code') class FOR_IN(OP_CODE): _params = ['name', 'body_start_label', 'continue_label', 'break_label'] def __init__(self, name, body_start_label, continue_label, break_label): self.name = name self.body_start_label = body_start_label self.continue_label = continue_label self.break_label = break_label def eval(self, ctx): iterable = ctx.stack.pop() if is_null(iterable) or is_undefined(iterable): ctx.stack.pop() ctx.stack.append(undefined) return self.break_label obj = to_object(iterable, ctx.space) for e in sorted(obj.own): if not obj.own[e]['enumerable']: continue ctx.put( self.name, e ) # JS would have been so much nicer if this was ctx.space.put(self.name, obj.get(e)) # evaluate the body status = ctx.space.exe.execute_fragment_under_context( ctx, self.body_start_label, self.break_label) val, typ, spec = status if typ != 3: # exception ctx.stack.pop() if typ == 0: # normal ctx.stack.append(val) continue elif typ == 1: # return ctx.stack.append(spec) return None, None # send return signal elif typ == 2: # jump outside # now have to figure out whether this is a continue or something else... ctx.stack.append(val) if spec == self.continue_label: # just a continue, perform next iteration as normal continue return spec # break or smth, go there and finish the iteration elif typ == 3: # exception # throw is made with empty stack as usual raise spec else: raise RuntimeError('Invalid return code') return self.break_label # all opcodes... OP_CODES = {} g = '' for g in globals(): try: if not issubclass(globals()[g], OP_CODE) or g is 'OP_CODE': continue except: continue OP_CODES[g] = globals()[g]