本文整理汇总了Python中quex.engine.state_machine.core.StateMachine.mount_to_acceptance_states方法的典型用法代码示例。如果您正苦于以下问题:Python StateMachine.mount_to_acceptance_states方法的具体用法?Python StateMachine.mount_to_acceptance_states怎么用?Python StateMachine.mount_to_acceptance_states使用的例子?那么恭喜您, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类quex.engine.state_machine.core.StateMachine
的用法示例。
在下文中一共展示了StateMachine.mount_to_acceptance_states方法的1个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的Python代码示例。
示例1: do
# 需要导入模块: from quex.engine.state_machine.core import StateMachine [as 别名]
# 或者: from quex.engine.state_machine.core.StateMachine import mount_to_acceptance_states [as 别名]
def do(StateMachineList, CommonTerminalStateF=True, CloneF=True):
"""Connect state machines paralell.
CommonTerminalStateF tells whether the state machines shall trigger
to a common terminal. This may help nfa-to-dfa
or hopcroft minimization for ISOLATED patterns.
A state machine that consists of the COMBINATION
of patterns MUST set this flag to 'False'.
CloneF Controls if state machine list is cloned or not.
If the single state machines are no longer required after
construction, the CloneF can be set to False.
If Cloning is disabled the state machines themselves
will be altered--which brings some advantage in speed.
"""
assert type(StateMachineList) == list
assert len(StateMachineList) != 0
for x in StateMachineList:
assert isinstance(x, StateMachine), x.__class__.__name__
# filter out empty state machines from the consideration
state_machine_list = [ sm for sm in StateMachineList if not (sm.is_empty() or special.is_none(sm))]
empty_state_machine_list = [ sm for sm in StateMachineList if (sm.is_empty() or special.is_none(sm))]
if len(state_machine_list) < 2:
if len(state_machine_list) < 1: result = StateMachine()
elif CloneF: result = state_machine_list[0].clone()
else: result = state_machine_list[0]
return __consider_empty_state_machines(result, empty_state_machine_list)
# (*) need to clone the state machines, i.e. provide their internal
# states with new ids, but the 'behavior' remains. This allows
# state machines to appear twice, or being used in 'larger'
# conglomerates.
if CloneF: clone_list = map(lambda sm: sm.clone(), state_machine_list)
else: clone_list = state_machine_list
# (*) collect all transitions from both state machines into a single one
# (clone to ensure unique identifiers of states)
new_init_state = State.new_merged_core_state((clone.get_init_state() for clone in clone_list),
ClearF=True)
result = StateMachine(InitState=new_init_state)
for clone in clone_list:
result.states.update(clone.states)
# (*) add additional **init** and **end** state
# NOTE: when the result state machine was created, it already contains a
# new initial state index. thus at this point only the new terminal
# state has to be created.
# NOTE: it is essential that the acceptance flag stays False, at this
# point in time, so that the mounting operations only happen on
# the old acceptance states. Later the acceptance state is raised
# to 'accepted' (see below)
new_terminal_state_index = -1L
if CommonTerminalStateF:
new_terminal_state_index = index.get()
result.states[new_terminal_state_index] = \
State.new_merged_core_state(result.get_acceptance_state_list(), \
ClearF=True)
# (*) Connect from the new initial state to the initial states of the
# clones via epsilon transition.
# Connect from each success state of the clones to the new end state
# via epsilon transition.
for clone in clone_list:
result.mount_to_initial_state(clone.init_state_index)
if CommonTerminalStateF:
result.mount_to_acceptance_states(new_terminal_state_index,
CancelStartAcceptanceStateF=False)
return __consider_empty_state_machines(result, empty_state_machine_list)