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Backport PR #8829: Qt5 fix...
Backport PR #8829: Qt5 fix Fix for issue #8757. The problem was that IPython.external.qt was moved to qtconsole.qt, but IPython.external.qt_for_kernel was still trying to import IPython.external.qt. Rather than copying the qt.py file back to external, this PR merges the logic back into qt_for_kernel.py. Deferring to qt.py was a bit silly because both qt.py and qt_for_kernel.py do basically the same thing but in slightly different ways. Moreover, the assumption of qt.py was that if the QT_API environment variable is set, it must be in an ETS environment and need to comply by the ETS import logic. This is not valid, as ipython sets the QT_API environment variable to communicate intent as to Qt version, in `IPython/lib/inputhook.py:385` ...

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embed.py
278 lines | 10.2 KiB | text/x-python | PythonLexer
# encoding: utf-8
"""
An embedded IPython shell.
"""
# Copyright (c) IPython Development Team.
# Distributed under the terms of the Modified BSD License.
from __future__ import with_statement
from __future__ import print_function
import sys
import warnings
from IPython.core import ultratb, compilerop
from IPython.core.magic import Magics, magics_class, line_magic
from IPython.core.interactiveshell import DummyMod
from IPython.core.interactiveshell import InteractiveShell
from IPython.terminal.interactiveshell import TerminalInteractiveShell
from IPython.terminal.ipapp import load_default_config
from traitlets import Bool, CBool, Unicode
from IPython.utils.io import ask_yes_no
# This is an additional magic that is exposed in embedded shells.
@magics_class
class EmbeddedMagics(Magics):
@line_magic
def kill_embedded(self, parameter_s=''):
"""%kill_embedded : deactivate for good the current embedded IPython.
This function (after asking for confirmation) sets an internal flag so
that an embedded IPython will never activate again. This is useful to
permanently disable a shell that is being called inside a loop: once
you've figured out what you needed from it, you may then kill it and
the program will then continue to run without the interactive shell
interfering again.
"""
kill = ask_yes_no("Are you sure you want to kill this embedded instance "
"(y/n)? [y/N] ",'n')
if kill:
self.shell.embedded_active = False
print ("This embedded IPython will not reactivate anymore "
"once you exit.")
class InteractiveShellEmbed(TerminalInteractiveShell):
dummy_mode = Bool(False)
exit_msg = Unicode('')
embedded = CBool(True)
embedded_active = CBool(True)
# Like the base class display_banner is not configurable, but here it
# is True by default.
display_banner = CBool(True)
exit_msg = Unicode()
def __init__(self, **kw):
if kw.get('user_global_ns', None) is not None:
warnings.warn("user_global_ns has been replaced by user_module. The\
parameter will be ignored.", DeprecationWarning)
super(InteractiveShellEmbed,self).__init__(**kw)
# don't use the ipython crash handler so that user exceptions aren't
# trapped
sys.excepthook = ultratb.FormattedTB(color_scheme=self.colors,
mode=self.xmode,
call_pdb=self.pdb)
def init_sys_modules(self):
pass
def init_magics(self):
super(InteractiveShellEmbed, self).init_magics()
self.register_magics(EmbeddedMagics)
def __call__(self, header='', local_ns=None, module=None, dummy=None,
stack_depth=1, global_ns=None, compile_flags=None):
"""Activate the interactive interpreter.
__call__(self,header='',local_ns=None,module=None,dummy=None) -> Start
the interpreter shell with the given local and global namespaces, and
optionally print a header string at startup.
The shell can be globally activated/deactivated using the
dummy_mode attribute. This allows you to turn off a shell used
for debugging globally.
However, *each* time you call the shell you can override the current
state of dummy_mode with the optional keyword parameter 'dummy'. For
example, if you set dummy mode on with IPShell.dummy_mode = True, you
can still have a specific call work by making it as IPShell(dummy=False).
"""
# If the user has turned it off, go away
if not self.embedded_active:
return
# Normal exits from interactive mode set this flag, so the shell can't
# re-enter (it checks this variable at the start of interactive mode).
self.exit_now = False
# Allow the dummy parameter to override the global __dummy_mode
if dummy or (dummy != 0 and self.dummy_mode):
return
if self.has_readline:
self.set_readline_completer()
# self.banner is auto computed
if header:
self.old_banner2 = self.banner2
self.banner2 = self.banner2 + '\n' + header + '\n'
else:
self.old_banner2 = ''
# Call the embedding code with a stack depth of 1 so it can skip over
# our call and get the original caller's namespaces.
self.mainloop(local_ns, module, stack_depth=stack_depth,
global_ns=global_ns, compile_flags=compile_flags)
self.banner2 = self.old_banner2
if self.exit_msg is not None:
print(self.exit_msg)
def mainloop(self, local_ns=None, module=None, stack_depth=0,
display_banner=None, global_ns=None, compile_flags=None):
"""Embeds IPython into a running python program.
Parameters
----------
local_ns, module
Working local namespace (a dict) and module (a module or similar
object). If given as None, they are automatically taken from the scope
where the shell was called, so that program variables become visible.
stack_depth : int
How many levels in the stack to go to looking for namespaces (when
local_ns or module is None). This allows an intermediate caller to
make sure that this function gets the namespace from the intended
level in the stack. By default (0) it will get its locals and globals
from the immediate caller.
compile_flags
A bit field identifying the __future__ features
that are enabled, as passed to the builtin :func:`compile` function.
If given as None, they are automatically taken from the scope where
the shell was called.
"""
if (global_ns is not None) and (module is None):
warnings.warn("global_ns is deprecated, use module instead.", DeprecationWarning)
module = DummyMod()
module.__dict__ = global_ns
# Get locals and globals from caller
if ((local_ns is None or module is None or compile_flags is None)
and self.default_user_namespaces):
call_frame = sys._getframe(stack_depth).f_back
if local_ns is None:
local_ns = call_frame.f_locals
if module is None:
global_ns = call_frame.f_globals
module = sys.modules[global_ns['__name__']]
if compile_flags is None:
compile_flags = (call_frame.f_code.co_flags &
compilerop.PyCF_MASK)
# Save original namespace and module so we can restore them after
# embedding; otherwise the shell doesn't shut down correctly.
orig_user_module = self.user_module
orig_user_ns = self.user_ns
orig_compile_flags = self.compile.flags
# Update namespaces and fire up interpreter
# The global one is easy, we can just throw it in
if module is not None:
self.user_module = module
# But the user/local one is tricky: ipython needs it to store internal
# data, but we also need the locals. We'll throw our hidden variables
# like _ih and get_ipython() into the local namespace, but delete them
# later.
if local_ns is not None:
reentrant_local_ns = {k: v for (k, v) in local_ns.items() if k not in self.user_ns_hidden.keys()}
self.user_ns = reentrant_local_ns
self.init_user_ns()
# Compiler flags
if compile_flags is not None:
self.compile.flags = compile_flags
# make sure the tab-completer has the correct frame information, so it
# actually completes using the frame's locals/globals
self.set_completer_frame()
with self.builtin_trap, self.display_trap:
self.interact(display_banner=display_banner)
# now, purge out the local namespace of IPython's hidden variables.
if local_ns is not None:
local_ns.update({k: v for (k, v) in self.user_ns.items() if k not in self.user_ns_hidden.keys()})
# Restore original namespace so shell can shut down when we exit.
self.user_module = orig_user_module
self.user_ns = orig_user_ns
self.compile.flags = orig_compile_flags
def embed(**kwargs):
"""Call this to embed IPython at the current point in your program.
The first invocation of this will create an :class:`InteractiveShellEmbed`
instance and then call it. Consecutive calls just call the already
created instance.
If you don't want the kernel to initialize the namespace
from the scope of the surrounding function,
and/or you want to load full IPython configuration,
you probably want `IPython.start_ipython()` instead.
Here is a simple example::
from IPython import embed
a = 10
b = 20
embed(header='First time')
c = 30
d = 40
embed()
Full customization can be done by passing a :class:`Config` in as the
config argument.
"""
config = kwargs.get('config')
header = kwargs.pop('header', u'')
compile_flags = kwargs.pop('compile_flags', None)
if config is None:
config = load_default_config()
config.InteractiveShellEmbed = config.TerminalInteractiveShell
kwargs['config'] = config
#save ps1/ps2 if defined
ps1 = None
ps2 = None
try:
ps1 = sys.ps1
ps2 = sys.ps2
except AttributeError:
pass
#save previous instance
saved_shell_instance = InteractiveShell._instance
if saved_shell_instance is not None:
cls = type(saved_shell_instance)
cls.clear_instance()
shell = InteractiveShellEmbed.instance(**kwargs)
shell(header=header, stack_depth=2, compile_flags=compile_flags)
InteractiveShellEmbed.clear_instance()
#restore previous instance
if saved_shell_instance is not None:
cls = type(saved_shell_instance)
cls.clear_instance()
for subclass in cls._walk_mro():
subclass._instance = saved_shell_instance
if ps1 is not None:
sys.ps1 = ps1
sys.ps2 = ps2