bazarr/libs/js2py/internals/code.py

from opcodes import *
from space import *
from base import *


class Code:
    '''Can generate, store and run sequence of ops representing js code'''

    def __init__(self, is_strict=False):
        self.tape = []
        self.compiled = False
        self.label_locs = None
        self.is_strict = is_strict

        self.contexts = []
        self.current_ctx = None
        self.return_locs = []
        self._label_count = 0
        self.label_locs = None

        # useful references
        self.GLOBAL_THIS = None
        self.space = None

    def get_new_label(self):
        self._label_count += 1
        return self._label_count

    def emit(self, op_code, *args):
        ''' Adds op_code with specified args to tape '''
        self.tape.append(OP_CODES[op_code](*args))

    def compile(self, start_loc=0):
        ''' Records locations of labels and compiles the code '''
        self.label_locs = {} if self.label_locs is None else self.label_locs
        loc = start_loc
        while loc < len(self.tape):
            if type(self.tape[loc]) == LABEL:
                self.label_locs[self.tape[loc].num] = loc
                del self.tape[loc]
                continue
            loc += 1
        self.compiled = True

    def _call(self, func, this, args):
        ''' Calls a bytecode function func
            NOTE:  use !ONLY! when calling functions from native methods! '''
        assert not func.is_native
        # fake call - the the runner to return to the end of the file
        old_contexts = self.contexts
        old_return_locs = self.return_locs
        old_curr_ctx = self.current_ctx

        self.contexts = [FakeCtx()]
        self.return_locs = [len(self.tape)]  # target line after return

        # prepare my ctx
        my_ctx = func._generate_my_context(this, args)
        self.current_ctx = my_ctx

        # execute dunction
        ret = self.run(my_ctx, starting_loc=self.label_locs[func.code])

        # bring back old execution
        self.current_ctx = old_curr_ctx
        self.contexts = old_contexts
        self.return_locs = old_return_locs

        return ret

    def execute_fragment_under_context(self, ctx, start_label, end_label):
        ''' just like run but returns if moved outside of the specified fragment
            # 4 different exectution results
            # 0=normal, 1=return, 2=jump_outside, 3=errors
            # execute_fragment_under_context returns:
            # (return_value, typ, return_value/jump_loc/py_error)
            # ctx.stack must be len 1 and its always empty after the call.
        '''
        old_curr_ctx = self.current_ctx
        try:
            self.current_ctx = ctx
            return self._execute_fragment_under_context(
                ctx, start_label, end_label)
        except JsException as err:
            # undo the things that were put on the stack (if any)
            # don't worry, I know the recovery is possible through try statement and for this reason try statement
            # has its own context and stack so it will not delete the contents of the outer stack
            del ctx.stack[:]
            return undefined, 3, err
        finally:
            self.current_ctx = old_curr_ctx

    def _execute_fragment_under_context(self, ctx, start_label, end_label):
        start, end = self.label_locs[start_label], self.label_locs[end_label]
        initial_len = len(ctx.stack)
        loc = start
        entry_level = len(self.contexts)
        # for e in self.tape[start:end]:
        #     print e

        while loc < len(self.tape):
            #print loc, self.tape[loc]
            if len(self.contexts) == entry_level and loc >= end:
                assert loc == end
                assert len(ctx.stack) == (
                    1 + initial_len), 'Stack change must be equal to +1!'
                return ctx.stack.pop(), 0, None  # means normal return

            # execute instruction
            status = self.tape[loc].eval(ctx)

            # check status for special actions
            if status is not None:
                if type(status) == int:  # jump to label
                    loc = self.label_locs[status]
                    if len(self.contexts) == entry_level:
                        # check if jumped outside of the fragment and break if so
                        if not start <= loc < end:
                            assert len(ctx.stack) == (
                                1 + initial_len
                            ), 'Stack change must be equal to +1!'
                            return ctx.stack.pop(), 2, status  # jump outside
                    continue

                elif len(status) == 2:  # a call or a return!
                    # call: (new_ctx, func_loc_label_num)
                    if status[0] is not None:
                        # append old state to the stack
                        self.contexts.append(ctx)
                        self.return_locs.append(loc + 1)
                        # set new state
                        loc = self.label_locs[status[1]]
                        ctx = status[0]
                        self.current_ctx = ctx
                        continue

                    # return: (None, None)
                    else:
                        if len(self.contexts) == entry_level:
                            assert len(ctx.stack) == 1 + initial_len
                            return undefined, 1, ctx.stack.pop(
                            )  # return signal
                        return_value = ctx.stack.pop()
                        ctx = self.contexts.pop()
                        self.current_ctx = ctx
                        ctx.stack.append(return_value)

                        loc = self.return_locs.pop()
                        continue
            # next instruction
            loc += 1
        assert False, 'Remember to add NOP at the end!'

    def run(self, ctx, starting_loc=0):
        loc = starting_loc
        self.current_ctx = ctx
        while loc < len(self.tape):
            # execute instruction
            #print loc, self.tape[loc]
            status = self.tape[loc].eval(ctx)

            # check status for special actions
            if status is not None:
                if type(status) == int:  # jump to label
                    loc = self.label_locs[status]
                    continue

                elif len(status) == 2:  # a call or a return!
                    # call: (new_ctx, func_loc_label_num)
                    if status[0] is not None:
                        # append old state to the stack
                        self.contexts.append(ctx)
                        self.return_locs.append(loc + 1)
                        # set new state
                        loc = self.label_locs[status[1]]
                        ctx = status[0]
                        self.current_ctx = ctx
                        continue

                    # return: (None, None)
                    else:
                        return_value = ctx.stack.pop()
                        ctx = self.contexts.pop()
                        self.current_ctx = ctx
                        ctx.stack.append(return_value)

                        loc = self.return_locs.pop()
                        continue
            # next instruction
            loc += 1
        assert len(ctx.stack) == 1, ctx.stack
        return ctx.stack.pop()


class FakeCtx(object):
    def __init__(self):
        self.stack = []
core: update to subliminal_patch:head; replace cfscrape; add dependencies 6 years ago			`from opcodes import *`
			`from space import *`
			`from base import *`


			`class Code:`
			`'''Can generate, store and run sequence of ops representing js code'''`

			`def __init__(self, is_strict=False):`
			`self.tape = []`
			`self.compiled = False`
			`self.label_locs = None`
			`self.is_strict = is_strict`

			`self.contexts = []`
			`self.current_ctx = None`
			`self.return_locs = []`
			`self._label_count = 0`
			`self.label_locs = None`

			`# useful references`
			`self.GLOBAL_THIS = None`
			`self.space = None`

			`def get_new_label(self):`
			`self._label_count += 1`
			`return self._label_count`

			`def emit(self, op_code, *args):`
			`''' Adds op_code with specified args to tape '''`
			`self.tape.append(OP_CODES[op_code](*args))`

			`def compile(self, start_loc=0):`
			`''' Records locations of labels and compiles the code '''`
			`self.label_locs = {} if self.label_locs is None else self.label_locs`
			`loc = start_loc`
			`while loc < len(self.tape):`
			`if type(self.tape[loc]) == LABEL:`
			`self.label_locs[self.tape[loc].num] = loc`
			`del self.tape[loc]`
			`continue`
			`loc += 1`
			`self.compiled = True`

			`def _call(self, func, this, args):`
			`''' Calls a bytecode function func`
			`NOTE: use !ONLY! when calling functions from native methods! '''`
			`assert not func.is_native`
			`# fake call - the the runner to return to the end of the file`
			`old_contexts = self.contexts`
			`old_return_locs = self.return_locs`
			`old_curr_ctx = self.current_ctx`

			`self.contexts = [FakeCtx()]`
			`self.return_locs = [len(self.tape)] # target line after return`

			`# prepare my ctx`
			`my_ctx = func._generate_my_context(this, args)`
			`self.current_ctx = my_ctx`

			`# execute dunction`
			`ret = self.run(my_ctx, starting_loc=self.label_locs[func.code])`

			`# bring back old execution`
			`self.current_ctx = old_curr_ctx`
			`self.contexts = old_contexts`
			`self.return_locs = old_return_locs`

			`return ret`

			`def execute_fragment_under_context(self, ctx, start_label, end_label):`
			`''' just like run but returns if moved outside of the specified fragment`
			`# 4 different exectution results`
			`# 0=normal, 1=return, 2=jump_outside, 3=errors`
			`# execute_fragment_under_context returns:`
			`# (return_value, typ, return_value/jump_loc/py_error)`
			`# ctx.stack must be len 1 and its always empty after the call.`
			`'''`
			`old_curr_ctx = self.current_ctx`
			`try:`
			`self.current_ctx = ctx`
			`return self._execute_fragment_under_context(`
			`ctx, start_label, end_label)`
			`except JsException as err:`
			`# undo the things that were put on the stack (if any)`
			`# don't worry, I know the recovery is possible through try statement and for this reason try statement`
			`# has its own context and stack so it will not delete the contents of the outer stack`
			`del ctx.stack[:]`
			`return undefined, 3, err`
			`finally:`
			`self.current_ctx = old_curr_ctx`

			`def _execute_fragment_under_context(self, ctx, start_label, end_label):`
			`start, end = self.label_locs[start_label], self.label_locs[end_label]`
			`initial_len = len(ctx.stack)`
			`loc = start`
			`entry_level = len(self.contexts)`
			`# for e in self.tape[start:end]:`
			`# print e`

			`while loc < len(self.tape):`
			`#print loc, self.tape[loc]`
			`if len(self.contexts) == entry_level and loc >= end:`
			`assert loc == end`
			`assert len(ctx.stack) == (`
			`1 + initial_len), 'Stack change must be equal to +1!'`
			`return ctx.stack.pop(), 0, None # means normal return`

			`# execute instruction`
			`status = self.tape[loc].eval(ctx)`

			`# check status for special actions`
			`if status is not None:`
			`if type(status) == int: # jump to label`
			`loc = self.label_locs[status]`
			`if len(self.contexts) == entry_level:`
			`# check if jumped outside of the fragment and break if so`
			`if not start <= loc < end:`
			`assert len(ctx.stack) == (`
			`1 + initial_len`
			`), 'Stack change must be equal to +1!'`
			`return ctx.stack.pop(), 2, status # jump outside`
			`continue`

			`elif len(status) == 2: # a call or a return!`
			`# call: (new_ctx, func_loc_label_num)`
			`if status[0] is not None:`
			`# append old state to the stack`
			`self.contexts.append(ctx)`
			`self.return_locs.append(loc + 1)`
			`# set new state`
			`loc = self.label_locs[status[1]]`
			`ctx = status[0]`
			`self.current_ctx = ctx`
			`continue`

			`# return: (None, None)`
			`else:`
			`if len(self.contexts) == entry_level:`
			`assert len(ctx.stack) == 1 + initial_len`
			`return undefined, 1, ctx.stack.pop(`
			`) # return signal`
			`return_value = ctx.stack.pop()`
			`ctx = self.contexts.pop()`
			`self.current_ctx = ctx`
			`ctx.stack.append(return_value)`

			`loc = self.return_locs.pop()`
			`continue`
			`# next instruction`
			`loc += 1`
			`assert False, 'Remember to add NOP at the end!'`

			`def run(self, ctx, starting_loc=0):`
			`loc = starting_loc`
			`self.current_ctx = ctx`
			`while loc < len(self.tape):`
			`# execute instruction`
			`#print loc, self.tape[loc]`
			`status = self.tape[loc].eval(ctx)`

			`# check status for special actions`
			`if status is not None:`
			`if type(status) == int: # jump to label`
			`loc = self.label_locs[status]`
			`continue`

			`elif len(status) == 2: # a call or a return!`
			`# call: (new_ctx, func_loc_label_num)`
			`if status[0] is not None:`
			`# append old state to the stack`
			`self.contexts.append(ctx)`
			`self.return_locs.append(loc + 1)`
			`# set new state`
			`loc = self.label_locs[status[1]]`
			`ctx = status[0]`
			`self.current_ctx = ctx`
			`continue`

			`# return: (None, None)`
			`else:`
			`return_value = ctx.stack.pop()`
			`ctx = self.contexts.pop()`
			`self.current_ctx = ctx`
			`ctx.stack.append(return_value)`

			`loc = self.return_locs.pop()`
			`continue`
			`# next instruction`
			`loc += 1`
			`assert len(ctx.stack) == 1, ctx.stack`
			`return ctx.stack.pop()`


			`class FakeCtx(object):`
			`def __init__(self):`
			`self.stack = []`