1
0
mirror of https://git.savannah.gnu.org/git/emacs.git synced 2024-12-11 09:20:51 +00:00
emacs/etc/emacs_lldb.py
Gerd Möllmann 1038e48038 Gud LLDB completions (bug#66604)
* etc/emacs_lldb.py: Remove xcomplete.
* lisp/progmodes/gud.el: Implement lldb command completions.
* src/.lldbinit: Remove settings done in Gud.
2023-10-18 20:51:22 +02:00

316 lines
13 KiB
Python
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

# Copyright (C) 2022-2023 Free Software Foundation, Inc.
#
# This file is part of GNU Emacs.
#
# GNU Emacs is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 3, or (at your option)
# any later version.
#
# GNU Emacs is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with GNU Emacs. If not, see <https://www.gnu.org/licenses/>.
# Load this module in LLDB with
#
# (lldb) command script import emacs_lldb
#
# Available commands start with 'x' and can be seen with
#
# (lldb) help
import lldb
########################################################################
# Utilities
########################################################################
# Return the name of enumerator ENUM as a string.
def enumerator_name(enum):
enumerators = enum.GetType().GetEnumMembers()
for enum_member in enumerators:
if enum.GetValueAsUnsigned() == enum_member.GetValueAsUnsigned():
return enum_member.GetName()
return None
# A class wrapping an SBValue for a Lisp_Object, providing convenience
# functions.
class Lisp_Object:
# Map pvec_type enumerators to corresponding C types.
pvec2type = {
"PVEC_FRAME": "struct frame",
"PVEC_WINDOW": "struct window",
"PVEC_BIGNUM": "struct Lisp_Bignum",
"PVEC_MARKER": "struct Lisp_Marker",
"PVEC_OVERLAY": "struct Lisp_Overlay",
"PVEC_FINALIZER": "struct Lisp_Finalizer",
"PVEC_SYMBOL_WITH_POS": "struct Lisp_Symbol_With_Pos",
"PVEC_MISC_PTR": "",
"PVEC_USER_PTR": "struct Lisp_User_Ptr",
"PVEC_PROCESS": "struct Lisp_Process",
"PVEC_BOOL_VECTOR": "struct Lisp_Bool_Vector",
"PVEC_BUFFER": "struct buffer",
"PVEC_HASH_TABLE": "struct Lisp_Hash_Table",
"PVEC_TERMINAL": "struct terminal",
"PVEC_WINDOW_CONFIGURATION": "struct save_window_data",
"PVEC_SUBR": "struct Lisp_Subr",
"PVEC_OTHER": "void",
"PVEC_XWIDGET": "void",
"PVEC_XWIDGET_VIEW": "void",
"PVEC_THREAD": "struct thread_state",
"PVEC_MUTEX": "Lisp_Mutex",
"PVEC_CONDVAR": "Lisp_CondVar",
"PVEC_MODULE_FUNCTION": "struct Lisp_Module_Function",
"PVEC_NATIVE_COMP_UNIT": "struct Lisp_Native_Comp_Unit",
"PVEC_SQLITE": "struct Lisp_Sqlite",
"PVEC_COMPILED": "struct Lisp_Vector",
"PVEC_CHAR_TABLE": "struct Lisp_Vector",
"PVEC_SUB_CHAR_TABLE": "void",
"PVEC_RECORD": "struct Lisp_Vector",
"PVEC_FONT": "struct font",
"PVEC_NORMAL_VECTOR": "struct Lisp_Vector"
}
# Object construction/initialization.
def __init__(self, lisp_obj):
self.tagged = lisp_obj
self.unsigned = None
self.lisp_type = None
self.pvec_type = None
self.untagged = None
self.init_unsigned()
self.init_lisp_types()
self.init_values()
def init_unsigned(self):
if self.tagged.GetType().GetTypeClass() == lldb.eTypeClassStruct:
# Lisp_Object is actually a struct.
lisp_word = self.tagged.GetValueForExpressionPath(".i")
self.unsigned = lisp_word.GetValueAsUnsigned()
else:
self.unsigned = self.tagged.GetValueAsUnsigned()
# Initialize self.lisp_type to the C Lisp_Type enumerator of the
# Lisp_Object, as a string. Initialize self.pvec_type likewise to
# the pvec_type enumerator if the object is a vector-like, as a
# string.
def init_lisp_types(self):
t = self.eval(f"(enum Lisp_Type)"
f"((EMACS_INT) {self.unsigned} "
f"& (1 << GCTYPEBITS) - 1)")
self.lisp_type = enumerator_name(t)
if self.lisp_type == "Lisp_Vectorlike":
self.pvec_type = "PVEC_NORMAL_VECTOR"
vector = self.get_lisp_pointer("struct Lisp_Vector")
size = vector.GetValueForExpressionPath("->header.size")
size = size.GetValueAsUnsigned()
pseudo = self.eval(f"{size} & PSEUDOVECTOR_FLAG")
if pseudo.GetValueAsUnsigned() != 0:
typ = self.eval(
f"(enum pvec_type) (({size} "
f"& More_Lisp_Bits::PVEC_TYPE_MASK) "
f">> More_Lisp_Bits::PSEUDOVECTOR_AREA_BITS)")
self.pvec_type = enumerator_name(typ)
# Initialize self.untagged according to lisp_type and pvec_type.
def init_values(self):
if self.lisp_type == "Lisp_Symbol":
offset = self.get_lisp_pointer("char").GetValueAsUnsigned()
self.untagged = self.eval(f"(struct Lisp_Symbol *)"
f" ((char *) &lispsym + {offset})",
True)
elif self.lisp_type == "Lisp_String":
self.untagged = self.get_lisp_pointer("struct Lisp_String", True)
elif self.lisp_type == "Lisp_Vectorlike":
c_type = Lisp_Object.pvec2type[self.pvec_type]
self.untagged = self.get_lisp_pointer(c_type, True)
elif self.lisp_type == "Lisp_Cons":
self.untagged = self.get_lisp_pointer("struct Lisp_Cons", True)
elif self.lisp_type == "Lisp_Float":
self.untagged = self.get_lisp_pointer("struct Lisp_Float", True)
elif self.lisp_type in ("Lisp_Int0", "Lisp_Int1"):
self.untagged = self.eval(f"((EMACS_INT) {self.unsigned}) "
f">> (GCTYPEBITS - 1)", True)
elif self.lisp_type == "Lisp_Type_Unused0":
self.untagged = self.unsigned
else:
assert False, f"Unknown Lisp type {self.lisp_type}"
# Evaluate EXPR in the context of the current frame.
def eval(self, expr, make_var=False):
frame = self.tagged.GetFrame()
if make_var:
return frame.EvaluateExpression(expr)
options = lldb.SBExpressionOptions()
options.SetSuppressPersistentResult(True)
return frame.EvaluateExpression(expr, options)
# Return an SBValue for this object denoting a pointer of type
# TYP*.
def get_lisp_pointer(self, typ, make_var=False):
return self.eval(f"({typ}*) (((EMACS_INT) "
f"{self.unsigned}) & VALMASK)",
make_var)
# If this is a Lisp_String, return an SBValue for its string data.
# Return None otherwise.
def get_string_data(self):
if self.lisp_type == "Lisp_String":
return self.untagged.GetValueForExpressionPath("->u.s.data")
return None
# if this is a Lisp_Symbol, return an SBBalue for its name.
# Return None otherwise.
def get_symbol_name(self):
if self.lisp_type == "Lisp_Symbol":
name = self.untagged.GetValueForExpressionPath("->u.s.name")
return Lisp_Object(name).get_string_data()
return None
# Return a summary string for this object.
def summary(self):
return str(self.untagged)
########################################################################
# LLDB Commands
########################################################################
def xbacktrace(debugger, command, ctx, result, internal_dict):
"""Print Emacs Lisp backtrace"""
frame = ctx.GetFrame()
n = frame.EvaluateExpression(
"current_thread->m_specpdl_ptr - current_thread->m_specpdl")
for i in reversed(range(0, n.GetValueAsUnsigned())):
s = frame.EvaluateExpression(f"current_thread->m_specpdl[{i}]")
kind = enumerator_name(s.GetChildMemberWithName("kind"))
if kind == "SPECPDL_BACKTRACE":
function = Lisp_Object(s.GetValueForExpressionPath(".bt.function"))
if function.lisp_type == "Lisp_Symbol":
sym_name = function.get_symbol_name()
result.AppendMessage(str(sym_name))
elif function.lisp_type == "Lisp_Vectorlike":
result.AppendMessage(function.pvec_type)
else:
result.AppendMessage(function.lisp_type)
def xdebug_print(debugger, command, result, internal_dict):
"""Print Lisp_Objects using safe_debug_print()"""
debugger.HandleCommand(f"expr safe_debug_print({command})")
########################################################################
# Formatters
########################################################################
def type_summary_Lisp_Object(obj, internal_dict):
return Lisp_Object(obj).summary()
class Lisp_Object_Provider:
"""Synthetic children provider for Lisp_Objects.
Supposedly only used by 'frame variable', where -P <n> can be used
to specify a printing depth. """
def __init__(self, valobj, internal_dict):
self.valobj = valobj
self.children = {}
def update(self):
lisp_obj = Lisp_Object(self.valobj)
lisp_type = lisp_obj.lisp_type
try:
if lisp_type == "Lisp_Symbol":
child = lisp_obj.get_symbol_name()
self.children["name"] = child
elif lisp_type == "Lisp_String":
child = lisp_obj.get_string_data()
self.children["data"] = child
elif lisp_type == "Lisp_Cons":
car = lisp_obj.untagged.GetValueForExpressionPath("->u.s.car")
cdr = lisp_obj.untagged.GetValueForExpressionPath("->u.s.u.cdr")
self.children["car"] = car
self.children["cdr"] = cdr
else:
self.children["untagged"] = lisp_obj.untagged
except:
print(f"*** exception in child provider update for {lisp_type}")
pass
def num_children(self):
return len(self.children)
def get_child_index(self, name):
index = 0
for child_name, child in self.children:
if child_name == name:
return index
index = index + 1
return -1
def get_child_at_index(self, index):
key = list(self.children)[index]
return self.children[key]
########################################################################
# Initialization
########################################################################
# Define Python FUNCTION as an LLDB command.
def define_command (debugger, function):
lldb_command = function.__name__
python_function = __name__ + "." + function.__name__
interpreter = debugger.GetCommandInterpreter()
def define(overwrite):
res = lldb.SBCommandReturnObject()
interpreter.HandleCommand(f"command script add "
f"{overwrite} "
f"--function {python_function} "
f"{lldb_command}",
res)
return res.Succeeded()
if not define("--overwrite"):
define("")
# Define Python FUNCTION as an LLDB type summary provider for types
# matching REGEX. Type summaries defined here are defined in the
# category Emacs, and can be seen with 'type summary list -w Emacs',
# and deleted in a similar way.
def define_type_summary(debugger, regex, function):
python_function = __name__ + "." + function.__name__
debugger.HandleCommand(f"type summary add --expand "
f"--cascade true "
f"--category Emacs "
f"--python-function {python_function} "
+ regex)
# Define Python class CLS as a children provider for the types
# matching REFEXP. Providers are defined in the category Emacs, and
# can be seen with 'type synthetic list -w Emacs', and deleted in a
# similar way.
def define_type_synthetic(debugger, regex, cls):
python_class = __name__ + "." + cls.__name__
debugger.HandleCommand(f"type synthetic add "
f"--category Emacs "
f"--python-class {python_class} "
+ regex)
# Enable a given category of type summary providers.
def enable_type_category(debugger, category):
debugger.HandleCommand(f"type category enable {category}")
# This function is called by LLDB to initialize the module.
def __lldb_init_module(debugger, internal_dict):
define_command(debugger, xbacktrace)
define_command(debugger, xdebug_print)
define_type_summary(debugger, "Lisp_Object", type_summary_Lisp_Object)
define_type_synthetic(debugger, "Lisp_Object", Lisp_Object_Provider)
enable_type_category(debugger, "Emacs")
print('Emacs debugging support has been installed.')
# end.