from __future__ import print_function

import signal as cpy_signal
import sys
import os
import errno

from pypy.interpreter.error import (
    OperationError, exception_from_saved_errno, oefmt, wrap_oserror)
from pypy.interpreter.executioncontext import (AsyncAction, AbstractActionFlag,
    PeriodicAsyncAction)
from pypy.interpreter.gateway import unwrap_spec

from rpython.rlib import jit, rgc, rposix, rposix_stat, rthread
from rpython.rlib.objectmodel import we_are_translated
from rpython.rlib.rarithmetic import intmask, widen
from rpython.rlib.rsignal import *
from rpython.rtyper.lltypesystem import lltype, rffi


WIN32 = sys.platform == 'win32'


class SignalActionFlag(AbstractActionFlag):
    # This class uses the C-level pypysig_counter variable as the tick
    # counter.  The C-level signal handler will reset it to -1 whenever
    # a signal is received.  This causes CheckSignalAction.perform() to
    # be called.

    def get_ticker(self):
        p = pypysig_getaddr_occurred()
        return p.c_value

    def reset_ticker(self, value):
        p = pypysig_getaddr_occurred()
        p.c_value = value

    def rearm_ticker(self):
        p = pypysig_getaddr_occurred()
        p.c_value = -1

    def decrement_ticker(self, by):
        p = pypysig_getaddr_occurred()
        value = p.c_value
        if self.has_bytecode_counter:    # this 'if' is constant-folded
            if jit.isconstant(by) and by == 0:
                pass     # normally constant-folded too
            else:
                value -= by
                p.c_value = value
        return value


class CheckSignalAction(PeriodicAsyncAction):
    """An action that is automatically invoked when a signal is received."""

    # Note that this is a PeriodicAsyncAction: it means more precisely
    # that it is called whenever the C-level ticker becomes < 0.
    # Without threads, it is only ever set to -1 when we receive a
    # signal.  With threads, it also decrements steadily (but slowly).

    def __init__(self, space):
        "NOT_RPYTHON"
        AsyncAction.__init__(self, space)
        self.pending_signal = -1
        self.fire_in_another_thread = False

        @rgc.no_collect
        def _after_thread_switch():
            # if threadlocals is the fake ThreadLocals from miscutils, we
            # cannot ever end up here, it's only called after a thread switch
            ec = self.space.threadlocals.get_ec()
            if ec is not None and ec.w_async_exception_type:
                self.space.actionflag.rearm_ticker() # ensure perform is called
                return
            if self.fire_in_another_thread:
                if self.space.threadlocals.signals_enabled():
                    self.fire_in_another_thread = False
                    self.space.actionflag.rearm_ticker()
                    # this occurs when we just switched to the main thread
                    # and there is a signal pending: we force the ticker to
                    # -1, which should ensure perform() is called quickly.
        self._after_thread_switch = _after_thread_switch
        # ^^^ so that 'self._after_thread_switch' can be annotated as a
        # constant

    def startup(self, space):
        # this is translated
        if space.config.objspace.usemodules.thread:
            from rpython.rlib import rgil
            rgil.invoke_after_thread_switch(self._after_thread_switch)

    def perform(self, executioncontext, frame):
        w_exc = executioncontext.w_async_exception_type
        if w_exc is not None:
            executioncontext.w_async_exception_type = None
            raise oefmt(w_exc, "asynchronous exception triggered from another thread")
        self._poll_for_signals()

    @jit.dont_look_inside
    def _poll_for_signals(self):
        # Poll for the next signal, if any
        n = self.pending_signal
        p = pypysig_getaddr_occurred_fullstruct()
        if p.c_debugger_pending_call:
            path = rffi.charp2str(p.c_debugger_script_path)
            p.c_debugger_pending_call = 0
            run_debugger(self.space, path)
            return
        if n < 0:
            n = pypysig_poll()
        while n >= 0:
            if self.space.threadlocals.signals_enabled():
                # If we are in the main thread, report the signal now,
                # and poll more
                self.pending_signal = -1
                report_signal(self.space, n)
                n = self.pending_signal
                if n < 0:
                    n = pypysig_poll()
            else:
                # Otherwise, arrange for perform() to be called again
                # after we switch to the main thread.
                self.pending_signal = n
                self.fire_in_another_thread = True
                break

    def set_interrupt(self, signum=cpy_signal.SIGINT):
        "Simulates the effect of a signal arriving, defaults to SIGINT"
        if not (1 <= signum < NSIG):
            return
        if not we_are_translated():
            self.pending_signal = signum
            # ^^^ may override another signal, but it's just for testing
            self.fire_in_another_thread = True
        else:
            pypysig_pushback(signum)

# ____________________________________________________________


class Handlers:
    def __init__(self, space):
        self.handlers_w = {}
        for signum in range(1, NSIG):
            if WIN32 and signum not in signal_values:
                self.handlers_w[signum] = space.w_None
            else:
                self.handlers_w[signum] = space.newint(SIG_DFL)

def _get_handlers(space):
    return space.fromcache(Handlers).handlers_w


def report_signal(space, n):
    handlers_w = _get_handlers(space)
    try:
        w_handler = handlers_w[n]
    except KeyError:
        return    # no handler, ignore signal
    if not space.is_true(space.callable(w_handler)):
        return    # w_handler is SIG_IGN or SIG_DFL?
    # re-install signal handler, for OSes that clear it
    pypysig_reinstall(n)
    # invoke the app-level handler
    ec = space.getexecutioncontext()
    w_frame = ec.gettopframe_nohidden()
    space.call_function(w_handler, space.newint(n), w_frame)

def run_debugger(space, path):
    from pypy.interpreter.streamutil import wrap_streamerror
    from pypy.interpreter.eval import Code
    from rpython.rlib import streamio
    w_pypymod = space.getbuiltinmodule('__pypy__')
    if space.is_true(space.getattr(w_pypymod, space.newtext('_pypy_disable_remote_debugger'))):
        return
    try:
        w_file = space.call_method(space.newbytes(path), 'decode', space.newtext('utf-8'))
        space.audit('remote_exec', [w_file])
        msg = "Executing remote debugger script "
        w_msg = space.add(space.newtext(msg), w_file)
        w_msg = space.add(w_msg, space.newtext('\n'))
        space.call_method(space.getattr(space.sys, space.newtext('stdout')), 'write', w_msg)
        try:
            stream = streamio.open_file_as_stream(path, 'r')
            source = stream.readall()
        except streamio.StreamErrors as e:
            raise wrap_streamerror(space, e)
        ec = space.getexecutioncontext()
        pycode = ec.compiler.compile(source, path, 'exec', 0)
        w_globals = space.newdict()
        pycode.exec_code(space, w_globals, w_globals)
    except OperationError as e:
        e.write_unraisable(space, "in remote debugger invocation")


@unwrap_spec(signum=int)
def getsignal(space, signum):
    """
    getsignal(sig) -> action

    Return the current action for the given signal.  The return value can be:
    SIG_IGN -- if the signal is being ignored
    SIG_DFL -- if the default action for the signal is in effect
    None -- if an unknown handler is in effect
    anything else -- the callable Python object used as a handler
    """
    check_signum_in_range(space, signum)
    handlers_w = _get_handlers(space)
    return handlers_w[signum]


def default_int_handler(space, args_w):
    """
    default_int_handler(...)

    The default handler for SIGINT installed by Python.
    It raises KeyboardInterrupt.
    """
    # issue #2780: accept and ignore any non-keyword arguments
    raise OperationError(space.w_KeyboardInterrupt, space.w_None)


@jit.dont_look_inside
@unwrap_spec(timeout=int)
def alarm(space, timeout):
    """alarm(seconds)

    Arrange for SIGALRM to arrive after the given number of seconds.
    """
    return space.newint(c_alarm(timeout))


@jit.dont_look_inside
def pause(space):
    """pause()

    Wait until a signal arrives.
    """
    c_pause()
    return space.w_None


def check_signum_in_range(space, signum):
    if 1 <= signum < NSIG:
        return
    raise oefmt(space.w_ValueError, "signal number out of range")


@jit.dont_look_inside
@unwrap_spec(signum=int)
def signal(space, signum, w_handler):
    """
    signal(sig, action) -> action

    Set the action for the given signal.  The action can be SIG_DFL,
    SIG_IGN, or a callable Python object.  The previous action is
    returned.  See getsignal() for possible return values.

    *** IMPORTANT NOTICE ***
    A signal handler function is called with two arguments:
    the first is the signal number, the second is the interrupted stack frame.
    """
    if WIN32 and signum not in signal_values:
        raise oefmt(space.w_ValueError, "invalid signal value")
    if not space.threadlocals.signals_enabled():
        raise oefmt(space.w_ValueError,
                    "signal only works in main thread or with "
                    "__pypy__.thread.enable_signals()")
    check_signum_in_range(space, signum)

    if space.eq_w(w_handler, space.newint(SIG_DFL)):
        pypysig_default(signum)
    elif space.eq_w(w_handler, space.newint(SIG_IGN)):
        pypysig_ignore(signum)
    else:
        if not space.is_true(space.callable(w_handler)):
            raise oefmt(space.w_TypeError,
                        "'handler' must be a callable or SIG_DFL or SIG_IGN")
        pypysig_setflag(signum)

    handlers_w = _get_handlers(space)
    old_handler = handlers_w[signum]
    handlers_w[signum] = w_handler
    return old_handler


@jit.dont_look_inside
@unwrap_spec(fd="c_int", warn_on_full_buffer=bool)
def set_wakeup_fd(space, fd, __kwonly__, warn_on_full_buffer=True):
    """Sets the fd to be written to (with the signal number) when a signal
    comes in.  Returns the old fd.  A library can use this to
    wakeup select or poll.  The previous fd is returned.

    The fd must be non-blocking.
    """
    if not space.threadlocals.signals_enabled():
        raise oefmt(space.w_ValueError,
                    "set_wakeup_fd only works in main thread or with "
                    "__pypy__.thread.enable_signals()")

    send_flags = 0
    if fd != -1:
        if WIN32:
            from rpython.rlib._rsocket_rffi import SOL_SOCKET, SO_TYPE
            from rpython.rlib.rsocket import getsockopt_int, SocketError
            # it could be a socket fd or a file fd
            try:
                type = getsockopt_int(fd, SOL_SOCKET, SO_TYPE)
                is_socket = True
            except SocketError as e:
                is_socket = False
            if is_socket:
                send_flags |= PYPYSIG_USE_SEND
            else:
                try:
                    os.fstat(fd)
                except OSError as e:
                    if e.errno == errno.EBADF:
                        raise oefmt(space.w_ValueError, "invalid fd")
        else:
            try:
                os.fstat(fd)
                flags = rposix.get_status_flags(fd)
            except OSError as e:
                if e.errno == errno.EBADF:
                    raise oefmt(space.w_ValueError, "invalid fd")
                raise wrap_oserror(space, e, eintr_retry=False)
            if flags & rposix.O_NONBLOCK == 0:
                raise oefmt(space.w_ValueError,
                            "the fd %d must be in non-blocking mode", fd)

    if not warn_on_full_buffer:
        send_flags |= PYPYSIG_NO_WARN_FULL
    old_fd = pypysig_set_wakeup_fd(fd, send_flags)
    return space.newint(intmask(old_fd))

@jit.dont_look_inside
@unwrap_spec(signum=int, flag=int)
def siginterrupt(space, signum, flag):
    """siginterrupt(sig, flag) -> None

    change system call restart behaviour: if flag is False, system calls
    will be restarted when interrupted by signal sig, else system calls
    will be interrupted.
    """
    check_signum_in_range(space, signum)
    if rffi.cast(lltype.Signed, c_siginterrupt(signum, flag)) < 0:
        raise exception_from_saved_errno(space, space.w_OSError)


#__________________________________________________________

def timeval_from_double(d, timeval):
    c_tv_sec = int(d)
    c_tv_usec = int((d - int(d)) * 1000000)
    # Don't disable the timer if the computation above rounds down to zero.
    if d > 0.0 and c_tv_sec == 0 and c_tv_usec == 0:
        c_tv_usec = 1
    rffi.setintfield(timeval, 'c_tv_sec', c_tv_sec)
    rffi.setintfield(timeval, 'c_tv_usec', c_tv_usec)


def double_from_timeval(tv):
    return rffi.getintfield(tv, 'c_tv_sec') + (
        rffi.getintfield(tv, 'c_tv_usec') / 1000000.0)


def itimer_retval(space, val):
    w_value = space.newfloat(double_from_timeval(val.c_it_value))
    w_interval = space.newfloat(double_from_timeval(val.c_it_interval))
    return space.newtuple2(w_value, w_interval)


class Cache:
    def __init__(self, space):
        self.w_itimererror = space.new_exception_class("signal.ItimerError",
                                                       space.w_IOError)


def get_itimer_error(space):
    return space.fromcache(Cache).w_itimererror


@jit.dont_look_inside
@unwrap_spec(which=int, first=float, interval=float)
def setitimer(space, which, first, interval=0):
    """setitimer(which, seconds[, interval])
    Sets given itimer (one of ITIMER_REAL, ITIMER_VIRTUAL

    or ITIMER_PROF) to fire after value seconds and after
    that every interval seconds.
    The itimer can be cleared by setting seconds to zero.

    Returns old values as a tuple: (delay, interval).
    """
    with lltype.scoped_alloc(itimervalP.TO, 1) as new:

        timeval_from_double(first, new[0].c_it_value)
        timeval_from_double(interval, new[0].c_it_interval)

        with lltype.scoped_alloc(itimervalP.TO, 1) as old:

            ret = c_setitimer(which, new, old)
            if ret != 0:
                raise exception_from_saved_errno(space, get_itimer_error(space))

            return itimer_retval(space, old[0])


@jit.dont_look_inside
@unwrap_spec(which=int)
def getitimer(space, which):
    """getitimer(which)

    Returns current value of given itimer.
    """
    with lltype.scoped_alloc(itimervalP.TO, 1) as old:

        c_getitimer(which, old)

        return itimer_retval(space, old[0])


@unwrap_spec(tid=int, signum=int)
def pthread_kill(space, tid, signum):
    "Send a signal to a thread."
    ret = rthread.c_pthread_kill(tid, signum)
    if widen(ret) < 0:
        raise exception_from_saved_errno(space, space.w_OSError)
    # the signal may have been send to the current thread
    space.getexecutioncontext().checksignals()


class SignalMask(object):
    def __init__(self, space, w_signals):
        self.space = space
        self.w_signals = w_signals

    def __enter__(self):
        space = self.space
        self.mask = lltype.malloc(c_sigset_t.TO, flavor='raw')
        c_sigemptyset(self.mask)
        for w_signum in space.unpackiterable(self.w_signals):
            signum = space.int_w(w_signum)
            check_signum_in_range(space, signum)
            # bpo-33329: ignore c_sigaddset() return value as it can fail
            # for some reserved signals, but we want the `range(1, NSIG)`
            # idiom to allow selecting all valid signals.
            c_sigaddset(self.mask, signum)
        return self.mask

    def __exit__(self, *args):
        lltype.free(self.mask, flavor='raw')

def _sigset_to_signals(space, mask):
    signals_w = []
    for sig in range(1, NSIG):
        if c_sigismember(mask, sig) != 1:
            continue
        # Handle the case where it is a member by adding the signal to
        # the result list.  Ignore the other cases because they mean
        # the signal isn't a member of the mask or the signal was
        # invalid, and an invalid signal must have been our fault in
        # constructing the loop boundaries.
        signals_w.append(space.newint(sig))
    return space.call_function(space.w_set, space.newtuple(signals_w))

def sigwait(space, w_signals):
    """Suspend execution of the calling thread until the delivery of one of the
    signals specified in the signal set signals. """
    with SignalMask(space, w_signals) as sigset:
        with lltype.scoped_alloc(rffi.INT_realP.TO, 1) as signum_ptr:
            ret = widen(c_sigwait(sigset, signum_ptr))
            if ret != 0:
                raise exception_from_saved_errno(space, space.w_OSError)
            signum = signum_ptr[0]
    return space.newint(signum)

def sigpending(space):
    """Examine pending signals.

    Returns a set of signal numbers that are pending for delivery to
    the calling thread.
    """
    with lltype.scoped_alloc(c_sigset_t.TO) as mask:
        ret = c_sigpending(mask)
        if ret != 0:
            raise exception_from_saved_errno(space, space.w_OSError)
        return _sigset_to_signals(space, mask)

@unwrap_spec(how=int)
def pthread_sigmask(space, how, w_signals):
    'Fetch and/or change the signal mask of the calling thread.'
    with SignalMask(space, w_signals) as sigset:
        with lltype.scoped_alloc(c_sigset_t.TO) as previous:
            ret = c_pthread_sigmask(how, sigset, previous)
            if ret != 0:
                raise exception_from_saved_errno(space, space.w_OSError)
            # if signals was unblocked, signal handlers have been called
            space.getexecutioncontext().checksignals()
            return _sigset_to_signals(space, previous)

def valid_signals(space):
    '''Return a set of valid signal numbers on this platform.

    The signal numbers returned by this function can be safely passed to
    functions like `pthread_sigmask`.'''
    if WIN32:
        # follow cpython
        signals_w = [space.newint(SIGABRT), space.newint(SIGBREAK),
                     space.newint(SIGFPE), space.newint(SIGILL),
                     space.newint(SIGINT), space.newint(SIGSEGV),
                     space.newint(SIGTERM),
                    ]
        return space.call_function(space.w_set, space.newtuple(signals_w))
    else:     
        mask = lltype.malloc(c_sigset_t.TO, flavor='raw')
        try:
            ret = c_sigemptyset(mask)
            if ret != 0:
                raise exception_from_saved_errno(space, space.w_OSError)
            ret = c_sigfillset(mask)
            if ret != 0:
                raise exception_from_saved_errno(space, space.w_OSError)
            return _sigset_to_signals(space, mask)
        finally:
            lltype.free(mask, flavor='raw')

@unwrap_spec(signalnum=int)
def raise_signal(space, signalnum):
    'Send a signal to the executing process.'
    with rposix.SuppressIPH():
        err = c_raise(signalnum)
    if err != 0:
        raise exception_from_saved_errno(space, space.w_OSError)

@unwrap_spec(signalnum=int)
def strsignal(space, signalnum):
    '''Return the system description of the given signal.
    The return values can be such as "Interrupt", "Segmentation fault", etc.
    Returns None if the signal is not recognized.'''
    from rpython.rlib import rsignal
    if signalnum < 1 or signalnum > NSIG:
        raise oefmt(space.w_ValueError, 'signal number out of range')
    res = rsignal.strsignal(signalnum)
    if res is None:
        return space.w_None
    return space.newtext(res)