"""
The Python Debugger Pdb
=======================
To use the debugger in its simplest form:
>>> import pdb
>>> pdb.run('<a statement>')
The debugger's prompt is '(Pdb) '. This will stop in the first
function call in <a statement>.
Alternatively, if a statement terminated with an unhandled exception,
you can use pdb's post-mortem facility to inspect the contents of the
traceback:
>>> <a statement>
<exception traceback>
>>> import pdb
>>> pdb.pm()
The commands recognized by the debugger are listed in the next
section. Most can be abbreviated as indicated; e.g., h(elp) means
that 'help' can be typed as 'h' or 'help' (but not as 'he' or 'hel',
nor as 'H' or 'Help' or 'HELP'). Optional arguments are enclosed in
square brackets. Alternatives in the command syntax are separated
by a vertical bar (|).
A blank line repeats the previous command literally, except for
'list', where it lists the next 11 lines.
Commands that the debugger doesn't recognize are assumed to be Python
statements and are executed in the context of the program being
debugged. Python statements can also be prefixed with an exclamation
point ('!'). This is a powerful way to inspect the program being
debugged; it is even possible to change variables or call functions.
When an exception occurs in such a statement, the exception name is
printed but the debugger's state is not changed.
The debugger supports aliases, which can save typing. And aliases can
have parameters (see the alias help entry) which allows one a certain
level of adaptability to the context under examination.
Multiple commands may be entered on a single line, separated by the
pair ';;'. No intelligence is applied to separating the commands; the
input is split at the first ';;', even if it is in the middle of a
quoted string.
If a file ".pdbrc" exists in your home directory or in the current
directory, it is read in and executed as if it had been typed at the
debugger prompt. This is particularly useful for aliases. If both
files exist, the one in the home directory is read first and aliases
defined there can be overridden by the local file. This behavior can be
disabled by passing the "readrc=False" argument to the Pdb constructor.
Aside from aliases, the debugger is not directly programmable; but it
is implemented as a class from which you can derive your own debugger
class, which you can make as fancy as you like.
Debugger commands
=================
"""
# NOTE: the actual command documentation is collected from docstrings of the
# commands and is appended to __doc__ after the class has been defined.
import os
import io
import re
import sys
import cmd
import bdb
import dis
import code
import glob
import token
import types
import codeop
import pprint
import signal
import inspect
import textwrap
import tokenize
import itertools
import traceback
import linecache
import _colorize
from contextlib import contextmanager
from rlcompleter import Completer
from types import CodeType
class Restart(Exception):
"""Causes a debugger to be restarted for the debugged python program."""
pass
__all__ = ["run", "pm", "Pdb", "runeval", "runctx", "runcall", "set_trace",
"post_mortem", "help"]
def find_first_executable_line(code):
""" Try to find the first executable line of the code object.
Equivalently, find the line number of the instruction that's
after RESUME
Return code.co_firstlineno if no executable line is found.
"""
prev = None
for instr in dis.get_instructions(code):
if prev is not None and prev.opname == 'RESUME':
if instr.positions.lineno is not None:
return instr.positions.lineno
return code.co_firstlineno
prev = instr
return code.co_firstlineno
def find_function(funcname, filename):
cre = re.compile(r'def\s+%s(\s*\[.+\])?\s*[(]' % re.escape(funcname))
try:
fp = tokenize.open(filename)
except OSError:
lines = linecache.getlines(filename)
if not lines:
return None
fp = io.StringIO(''.join(lines))
funcdef = ""
funcstart = 0
# consumer of this info expects the first line to be 1
with fp:
for lineno, line in enumerate(fp, start=1):
if cre.match(line):
funcstart, funcdef = lineno, line
elif funcdef:
funcdef += line
if funcdef:
try:
code = compile(funcdef, filename, 'exec')
except SyntaxError:
continue
# We should always be able to find the code object here
funccode = next(c for c in code.co_consts if
isinstance(c, CodeType) and c.co_name == funcname)
lineno_offset = find_first_executable_line(funccode)
return funcname, filename, funcstart + lineno_offset - 1
return None
def lasti2lineno(code, lasti):
linestarts = list(dis.findlinestarts(code))
linestarts.reverse()
for i, lineno in linestarts:
if lasti >= i:
return lineno
return 0
class _rstr(str):
"""String that doesn't quote its repr."""
def __repr__(self):
return self
class _ExecutableTarget:
filename: str
code: CodeType | str
namespace: dict
class _ScriptTarget(_ExecutableTarget):
def __init__(self, target):
self._target = os.path.realpath(target)
if not os.path.exists(self._target):
print(f'Error: {target} does not exist')
sys.exit(1)
if os.path.isdir(self._target):
print(f'Error: {target} is a directory')
sys.exit(1)
# If safe_path(-P) is not set, sys.path[0] is the directory
# of pdb, and we should replace it with the directory of the script
if not sys.flags.safe_path:
sys.path[0] = os.path.dirname(self._target)
def __repr__(self):
return self._target
@property
def filename(self):
return self._target
@property
def code(self):
# Open the file each time because the file may be modified
with io.open_code(self._target) as fp:
return f"exec(compile({fp.read()!r}, {self._target!r}, 'exec'))"
@property
def namespace(self):
return dict(
__name__='__main__',
__file__=self._target,
__builtins__=__builtins__,
__spec__=None,
)
class _ModuleTarget(_ExecutableTarget):
def __init__(self, target):
self._target = target
import runpy
try:
_, self._spec, self._code = runpy._get_module_details(self._target)
except ImportError as e:
print(f"ImportError: {e}")
sys.exit(1)
except Exception:
traceback.print_exc()
sys.exit(1)
def __repr__(self):
return self._target
@property
def filename(self):
return self._code.co_filename
@property
def code(self):
return self._code
@property
def namespace(self):
return dict(
__name__='__main__',
__file__=os.path.normcase(os.path.abspath(self.filename)),
__package__=self._spec.parent,
__loader__=self._spec.loader,
__spec__=self._spec,
__builtins__=__builtins__,
)
class _ZipTarget(_ExecutableTarget):
def __init__(self, target):
import runpy
self._target = os.path.realpath(target)
sys.path.insert(0, self._target)
try:
_, self._spec, self._code = runpy._get_main_module_details()
except ImportError as e:
print(f"ImportError: {e}")
sys.exit(1)
except Exception:
traceback.print_exc()
sys.exit(1)
def __repr__(self):
return self._target
@property
def filename(self):
return self._code.co_filename
@property
def code(self):
return self._code
@property
def namespace(self):
return dict(
__name__='__main__',
__file__=os.path.normcase(os.path.abspath(self.filename)),
__package__=self._spec.parent,
__loader__=self._spec.loader,
__spec__=self._spec,
__builtins__=__builtins__,
)
class _PdbInteractiveConsole(code.InteractiveConsole):
def __init__(self, ns, message):
self._message = message
super().__init__(locals=ns, local_exit=True)
def write(self, data):
self._message(data, end='')
# Interaction prompt line will separate file and call info from code
# text using value of line_prefix string. A newline and arrow may
# be to your liking. You can set it once pdb is imported using the
# command "pdb.line_prefix = '\n% '".
# line_prefix = ': ' # Use this to get the old situation back
line_prefix = '\n-> ' # Probably a better default
class Pdb(bdb.Bdb, cmd.Cmd):
_previous_sigint_handler = None
# Limit the maximum depth of chained exceptions, we should be handling cycles,
# but in case there are recursions, we stop at 999.
MAX_CHAINED_EXCEPTION_DEPTH = 999
_file_mtime_table = {}
_last_pdb_instance = None
def __init__(self, completekey='tab', stdin=None, stdout=None, skip=None,
nosigint=False, readrc=True, mode=None):
bdb.Bdb.__init__(self, skip=skip)
cmd.Cmd.__init__(self, completekey, stdin, stdout)
sys.audit("pdb.Pdb")
if stdout:
self.use_rawinput = 0
self.prompt = '(Pdb) '
self.aliases = {}
self.displaying = {}
self.mainpyfile = ''
self._wait_for_mainpyfile = False
self.tb_lineno = {}
self.mode = mode
# Try to load readline if it exists
try:
import readline
# remove some common file name delimiters
readline.set_completer_delims(' \t\n`@#%^&*()=+[{]}\\|;:\'",<>?')
except ImportError:
pass
self.allow_kbdint = False
self.nosigint = nosigint
# Consider these characters as part of the command so when the users type
# c.a or c['a'], it won't be recognized as a c(ontinue) command
self.identchars = cmd.Cmd.identchars + '=.[](),"\'+-*/%@&|<>~^'
# Read ~/.pdbrc and ./.pdbrc
self.rcLines = []
if readrc:
try:
with open(os.path.expanduser('~/.pdbrc'), encoding='utf-8') as rcFile:
self.rcLines.extend(rcFile)
except OSError:
pass
try:
with open(".pdbrc", encoding='utf-8') as rcFile:
self.rcLines.extend(rcFile)
except OSError:
pass
self.commands = {} # associates a command list to breakpoint numbers
self.commands_defining = False # True while in the process of defining
# a command list
self.commands_bnum = None # The breakpoint number for which we are
# defining a list
self._chained_exceptions = tuple()
self._chained_exception_index = 0
def set_trace(self, frame=None, *, commands=None):
Pdb._last_pdb_instance = self
if frame is None:
frame = sys._getframe().f_back
if commands is not None:
self.rcLines.extend(commands)
super().set_trace(frame)
def sigint_handler(self, signum, frame):
if self.allow_kbdint:
raise KeyboardInterrupt
self.message("\nProgram interrupted. (Use 'cont' to resume).")
self.set_step()
self.set_trace(frame)
def reset(self):
bdb.Bdb.reset(self)
self.forget()
def forget(self):
self.lineno = None
self.stack = []
self.curindex = 0
if hasattr(self, 'curframe') and self.curframe:
self.curframe.f_globals.pop('__pdb_convenience_variables', None)
self.curframe = None
self.tb_lineno.clear()
def setup(self, f, tb):
self.forget()
self.stack, self.curindex = self.get_stack(f, tb)
while tb:
# when setting up post-mortem debugging with a traceback, save all
# the original line numbers to be displayed along the current line
# numbers (which can be different, e.g. due to finally clauses)
lineno = lasti2lineno(tb.tb_frame.f_code, tb.tb_lasti)
self.tb_lineno[tb.tb_frame] = lineno
tb = tb.tb_next
self.curframe = self.stack[self.curindex][0]
self.set_convenience_variable(self.curframe, '_frame', self.curframe)
self._save_initial_file_mtime(self.curframe)
if self._chained_exceptions:
self.set_convenience_variable(
self.curframe,
'_exception',
self._chained_exceptions[self._chained_exception_index],
)
if self.rcLines:
self.cmdqueue = [
line for line in self.rcLines
if line.strip() and not line.strip().startswith("#")
]
self.rcLines = []
# Override Bdb methods
def user_call(self, frame, argument_list):
"""This method is called when there is the remote possibility
that we ever need to stop in this function."""
if self._wait_for_mainpyfile:
return
if self.stop_here(frame):
self.message('--Call--')
self.interaction(frame, None)
def user_line(self, frame):
"""This function is called when we stop or break at this line."""
if self._wait_for_mainpyfile:
if (self.mainpyfile != self.canonic(frame.f_code.co_filename)):
return
self._wait_for_mainpyfile = False
if self.trace_opcodes:
# GH-127321
# We want to avoid stopping at an opcode that does not have
# an associated line number because pdb does not like it
if frame.f_lineno is None:
self.set_stepinstr()
return
self.bp_commands(frame)
self.interaction(frame, None)
user_opcode = user_line
def bp_commands(self, frame):
"""Call every command that was set for the current active breakpoint
(if there is one).
Returns True if the normal interaction function must be called,
False otherwise."""
# self.currentbp is set in bdb in Bdb.break_here if a breakpoint was hit
if getattr(self, "currentbp", False) and \
self.currentbp in self.commands:
currentbp = self.currentbp
self.currentbp = 0
for line in self.commands[currentbp]:
self.cmdqueue.append(line)
self.cmdqueue.append(f'_pdbcmd_restore_lastcmd {self.lastcmd}')
def user_return(self, frame, return_value):
"""This function is called when a return trap is set here."""
if self._wait_for_mainpyfile:
return
frame.f_locals['__return__'] = return_value
self.set_convenience_variable(frame, '_retval', return_value)
self.message('--Return--')
self.interaction(frame, None)
def user_exception(self, frame, exc_info):
"""This function is called if an exception occurs,
but only if we are to stop at or just below this level."""
if self._wait_for_mainpyfile:
return
exc_type, exc_value, exc_traceback = exc_info
frame.f_locals['__exception__'] = exc_type, exc_value
self.set_convenience_variable(frame, '_exception', exc_value)
# An 'Internal StopIteration' exception is an exception debug event
# issued by the interpreter when handling a subgenerator run with
# 'yield from' or a generator controlled by a for loop. No exception has
# actually occurred in this case. The debugger uses this debug event to
# stop when the debuggee is returning from such generators.
prefix = 'Internal ' if (not exc_traceback
and exc_type is StopIteration) else ''
self.message('%s%s' % (prefix, self._format_exc(exc_value)))
self.interaction(frame, exc_traceback)
# General interaction function
def _cmdloop(self):
while True:
try:
# keyboard interrupts allow for an easy way to cancel
# the current command, so allow them during interactive input
self.allow_kbdint = True
self.cmdloop()
self.allow_kbdint = False
break
except KeyboardInterrupt:
self.message('--KeyboardInterrupt--')
def _save_initial_file_mtime(self, frame):
"""save the mtime of the all the files in the frame stack in the file mtime table
if they haven't been saved yet."""
while frame:
filename = frame.f_code.co_filename
if filename not in self._file_mtime_table:
try:
self._file_mtime_table[filename] = os.path.getmtime(filename)
except Exception:
pass
frame = frame.f_back
def _validate_file_mtime(self):
"""Check if the source file of the current frame has been modified.
If so, give a warning and reset the modify time to current."""
try:
filename = self.curframe.f_code.co_filename
mtime = os.path.getmtime(filename)
except Exception:
return
if (filename in self._file_mtime_table and
mtime != self._file_mtime_table[filename]):
self.message(f"*** WARNING: file '{filename}' was edited, "
"running stale code until the program is rerun")
self._file_mtime_table[filename] = mtime
# Called before loop, handles display expressions
# Set up convenience variable containers
def _show_display(self):
displaying = self.displaying.get(self.curframe)
if displaying:
for expr, oldvalue in displaying.items():
newvalue = self._getval_except(expr)
# check for identity first; this prevents custom __eq__ to
# be called at every loop, and also prevents instances whose
# fields are changed to be displayed
if newvalue is not oldvalue and newvalue != oldvalue:
displaying[expr] = newvalue
self.message('display %s: %s [old: %s]' %
(expr, self._safe_repr(newvalue, expr),
self._safe_repr(oldvalue, expr)))
def _get_tb_and_exceptions(self, tb_or_exc):
"""
Given a tracecack or an exception, return a tuple of chained exceptions
and current traceback to inspect.
This will deal with selecting the right ``__cause__`` or ``__context__``
as well as handling cycles, and return a flattened list of exceptions we
can jump to with do_exceptions.
"""
_exceptions = []
if isinstance(tb_or_exc, BaseException):
traceback, current = tb_or_exc.__traceback__, tb_or_exc
while current is not None:
if current in _exceptions:
break
_exceptions.append(current)
if current.__cause__ is not None:
current = current.__cause__
elif (
current.__context__ is not None and not current.__suppress_context__
):
current = current.__context__
if len(_exceptions) >= self.MAX_CHAINED_EXCEPTION_DEPTH:
self.message(
f"More than {self.MAX_CHAINED_EXCEPTION_DEPTH}"
" chained exceptions found, not all exceptions"
"will be browsable with `exceptions`."
)
break
else:
traceback = tb_or_exc
return tuple(reversed(_exceptions)), traceback
@contextmanager
def _hold_exceptions(self, exceptions):
"""
Context manager to ensure proper cleaning of exceptions references
When given a chained exception instead of a traceback,
pdb may hold references to many objects which may leak memory.
We use this context manager to make sure everything is properly cleaned
"""
try:
self._chained_exceptions = exceptions
self._chained_exception_index = len(exceptions) - 1
yield
finally:
# we can't put those in forget as otherwise they would
# be cleared on exception change
self._chained_exceptions = tuple()
self._chained_exception_index = 0
def interaction(self, frame, tb_or_exc):
# Restore the previous signal handler at the Pdb prompt.
if Pdb._previous_sigint_handler:
try:
signal.signal(signal.SIGINT, Pdb._previous_sigint_handler)
except ValueError: # ValueError: signal only works in main thread
pass
else:
Pdb._previous_sigint_handler = None
_chained_exceptions, tb = self._get_tb_and_exceptions(tb_or_exc)
if isinstance(tb_or_exc, BaseException):
assert tb is not None, "main exception must have a traceback"
with self._hold_exceptions(_chained_exceptions):
self.setup(frame, tb)
# We should print the stack entry if and only if the user input
# is expected, and we should print it right before the user input.
# We achieve this by appending _pdbcmd_print_frame_status to the
# command queue. If cmdqueue is not exhausted, the user input is
# not expected and we will not print the stack entry.
self.cmdqueue.append('_pdbcmd_print_frame_status')
self._cmdloop()
# If _pdbcmd_print_frame_status is not used, pop it out
if self.cmdqueue and self.cmdqueue[-1] == '_pdbcmd_print_frame_status':
self.cmdqueue.pop()
self.forget()
def displayhook(self, obj):
"""Custom displayhook for the exec in default(), which prevents
assignment of the _ variable in the builtins.
"""
# reproduce the behavior of the standard displayhook, not printing None
if obj is not None:
self.message(repr(obj))
@contextmanager
def _disable_command_completion(self):
completenames = self.completenames
try:
self.completenames = self.completedefault
yield
finally:
self.completenames = completenames
return
def _exec_in_closure(self, source, globals, locals):
""" Run source code in closure so code object created within source
can find variables in locals correctly
returns True if the source is executed, False otherwise
"""
# Determine if the source should be executed in closure. Only when the
# source compiled to multiple code objects, we should use this feature.
# Otherwise, we can just raise an exception and normal exec will be used.
code = compile(source, "<string>", "exec")
if not any(isinstance(const, CodeType) for const in code.co_consts):
return False
# locals could be a proxy which does not support pop
# copy it first to avoid modifying the original locals
locals_copy = dict(locals)
locals_copy["__pdb_eval__"] = {
"result": None,
"write_back": {}
}
# If the source is an expression, we need to print its value
try:
compile(source, "<string>", "eval")
except SyntaxError:
pass
else:
source = "__pdb_eval__['result'] = " + source
# Add write-back to update the locals
source = ("try:\n" +
textwrap.indent(source, " ") + "\n" +
"finally:\n" +
" __pdb_eval__['write_back'] = locals()")
# Build a closure source code with freevars from locals like:
# def __pdb_outer():
# var = None
# def __pdb_scope(): # This is the code object we want to execute
# nonlocal var
# <source>
# return __pdb_scope.__code__
source_with_closure = ("def __pdb_outer():\n" +
"\n".join(f" {var} = None" for var in locals_copy) + "\n" +
" def __pdb_scope():\n" +
"\n".join(f" nonlocal {var}" for var in locals_copy) + "\n" +
textwrap.indent(source, " ") + "\n" +
" return __pdb_scope.__code__"
)
# Get the code object of __pdb_scope()
# The exec fills locals_copy with the __pdb_outer() function and we can call
# that to get the code object of __pdb_scope()
ns = {}
try:
exec(source_with_closure, {}, ns)
except Exception:
return False
code = ns["__pdb_outer"]()
cells = tuple(types.CellType(locals_copy.get(var)) for var in code.co_freevars)
try:
exec(code, globals, locals_copy, closure=cells)
except Exception:
return False
# get the data we need from the statement
pdb_eval = locals_copy["__pdb_eval__"]
# __pdb_eval__ should not be updated back to locals
pdb_eval["write_back"].pop("__pdb_eval__")
# Write all local variables back to locals
locals.update(pdb_eval["write_back"])
eval_result = pdb_eval["result"]
if eval_result is not None:
print(repr(eval_result))
return True
def default(self, line):
if line[:1] == '!': line = line[1:].strip()
locals = self.curframe.f_locals
globals = self.curframe.f_globals
try:
buffer = line
if (code := codeop.compile_command(line + '\n', '<stdin>', 'single')) is None:
# Multi-line mode
with self._disable_command_completion():
buffer = line
continue_prompt = "... "
while (code := codeop.compile_command(buffer, '<stdin>', 'single')) is None:
if self.use_rawinput:
try:
line = input(continue_prompt)
except (EOFError, KeyboardInterrupt):
self.lastcmd = ""
print('\n')
return
else:
self.stdout.write(continue_prompt)
self.stdout.flush()
line = self.stdin.readline()
if not len(line):
self.lastcmd = ""
self.stdout.write('\n')
self.stdout.flush()
return
else:
line = line.rstrip('\r\n')
buffer += '\n' + line
self.lastcmd = buffer
save_stdout = sys.stdout
save_stdin = sys.stdin
save_displayhook = sys.displayhook
try:
sys.stdin = self.stdin
sys.stdout = self.stdout
sys.displayhook = self.displayhook
if not self._exec_in_closure(buffer, globals, locals):
exec(code, globals, locals)
finally:
sys.stdout = save_stdout
sys.stdin = save_stdin
sys.displayhook = save_displayhook
except:
self._error_exc()
def _replace_convenience_variables(self, line):
"""Replace the convenience variables in 'line' with their values.
e.g. $foo is replaced by __pdb_convenience_variables["foo"].
Note: such pattern in string literals will be skipped"""
if "$" not in line:
return line
dollar_start = dollar_end = (-1, -1)
replace_variables = []
try:
for t in tokenize.generate_tokens(io.StringIO(line).readline):
token_type, token_string, start, end, _ = t
if token_type == token.OP and token_string == '$':
dollar_start, dollar_end = start, end
elif start == dollar_end and token_type == token.NAME:
# line is a one-line command so we only care about column
replace_variables.append((dollar_start[1], end[1], token_string))
except tokenize.TokenError:
return line
if not replace_variables:
return line
last_end = 0
line_pieces = []
for start, end, name in replace_variables:
line_pieces.append(line[last_end:start] + f'__pdb_convenience_variables["{name}"]')
last_end = end
line_pieces.append(line[last_end:])
return ''.join(line_pieces)
def precmd(self, line):
"""Handle alias expansion and ';;' separator."""
if not line.strip():
return line
args = line.split()
while args[0] in self.aliases:
line = self.aliases[args[0]]
for idx in range(1, 10):
if f'%{idx}' in line:
if idx >= len(args):
self.error(f"Not enough arguments for alias '{args[0]}'")
# This is a no-op
return "!"
line = line.replace(f'%{idx}', args[idx])
elif '%*' not in line:
if idx < len(args):
self.error(f"Too many arguments for alias '{args[0]}'")
# This is a no-op
return "!"
break
line = line.replace("%*", ' '.join(args[1:]))
args = line.split()
# split into ';;' separated commands
# unless it's an alias command
if args[0] != 'alias':
marker = line.find(';;')
if marker >= 0:
# queue up everything after marker
next = line[marker+2:].lstrip()
self.cmdqueue.insert(0, next)
line = line[:marker].rstrip()
# Replace all the convenience variables
line = self._replace_convenience_variables(line)
return line
def onecmd(self, line):
"""Interpret the argument as though it had been typed in response
to the prompt.
Checks whether this line is typed at the normal prompt or in
a breakpoint command list definition.
"""
if not self.commands_defining:
if line.startswith('_pdbcmd'):
command, arg, line = self.parseline(line)
if hasattr(self, command):
return getattr(self, command)(arg)
return cmd.Cmd.onecmd(self, line)
else:
return self.handle_command_def(line)
def handle_command_def(self, line):
"""Handles one command line during command list definition."""
cmd, arg, line = self.parseline(line)
if not cmd:
return False
if cmd == 'end':
return True # end of cmd list
elif cmd == 'EOF':
print('')
return True # end of cmd list
cmdlist = self.commands[self.commands_bnum]
if cmd == 'silent':
cmdlist.append('_pdbcmd_silence_frame_status')
return False # continue to handle other cmd def in the cmd list
if arg:
cmdlist.append(cmd+' '+arg)
else:
cmdlist.append(cmd)
# Determine if we must stop
try:
func = getattr(self, 'do_' + cmd)
except AttributeError:
func = self.default
# one of the resuming commands
if func.__name__ in self.commands_resuming:
return True
return False
# interface abstraction functions
def message(self, msg, end='\n'):
print(msg, end=end, file=self.stdout)
def error(self, msg):
print('***', msg, file=self.stdout)
# convenience variables
def set_convenience_variable(self, frame, name, value):
if '__pdb_convenience_variables' not in frame.f_globals:
frame.f_globals['__pdb_convenience_variables'] = {}
frame.f_globals['__pdb_convenience_variables'][name] = value
# Generic completion functions. Individual complete_foo methods can be
# assigned below to one of these functions.
def completenames(self, text, line, begidx, endidx):
# Overwrite completenames() of cmd so for the command completion,
# if no current command matches, check for expressions as well
commands = super().completenames(text, line, begidx, endidx)
for alias in self.aliases:
if alias.startswith(text):
commands.append(alias)
if commands:
return commands
else:
expressions = self._complete_expression(text, line, begidx, endidx)
if expressions:
return expressions
return self.completedefault(text, line, begidx, endidx)
def _complete_location(self, text, line, begidx, endidx):
# Complete a file/module/function location for break/tbreak/clear.
if line.strip().endswith((':', ',')):
# Here comes a line number or a condition which we can't complete.
return []
# First, try to find matching functions (i.e. expressions).
try:
ret = self._complete_expression(text, line, begidx, endidx)
except Exception:
ret = []
# Then, try to complete file names as well.
globs = glob.glob(glob.escape(text) + '*')
for fn in globs:
if os.path.isdir(fn):
ret.append(fn + '/')
elif os.path.isfile(fn) and fn.lower().endswith(('.py', '.pyw')):
ret.append(fn + ':')
return ret
def _complete_bpnumber(self, text, line, begidx, endidx):
# Complete a breakpoint number. (This would be more helpful if we could
# display additional info along with the completions, such as file/line
# of the breakpoint.)
return [str(i) for i, bp in enumerate(bdb.Breakpoint.bpbynumber)
if bp is not None and str(i).startswith(text)]
def _complete_expression(self, text, line, begidx, endidx):
# Complete an arbitrary expression.
if not self.curframe:
return []
# Collect globals and locals. It is usually not really sensible to also
# complete builtins, and they clutter the namespace quite heavily, so we
# leave them out.
ns = {**self.curframe.f_globals, **self.curframe.f_locals}
if text.startswith("$"):
# Complete convenience variables
conv_vars = self.curframe.f_globals.get('__pdb_convenience_variables', {})
return [f"${name}" for name in conv_vars if name.startswith(text[1:])]
if '.' in text:
# Walk an attribute chain up to the last part, similar to what
# rlcompleter does. This will bail if any of the parts are not
# simple attribute access, which is what we want.
dotted = text.split('.')
try:
obj = ns[dotted[0]]
for part in dotted[1:-1]:
obj = getattr(obj, part)
except (KeyError, AttributeError):
return []
prefix = '.'.join(dotted[:-1]) + '.'
return [prefix + n for n in dir(obj) if n.startswith(dotted[-1])]
else:
# Complete a simple name.
return [n for n in ns.keys() if n.startswith(text)]
def completedefault(self, text, line, begidx, endidx):
if text.startswith("$"):
# Complete convenience variables
conv_vars = self.curframe.f_globals.get('__pdb_convenience_variables', {})
return [f"${name}" for name in conv_vars if name.startswith(text[1:])]
# Use rlcompleter to do the completion
state = 0
matches = []
completer = Completer(self.curframe.f_globals | self.curframe.f_locals)
while (match := completer.complete(text, state)) is not None:
matches.append(match)
state += 1
return matches
# Pdb meta commands, only intended to be used internally by pdb
def _pdbcmd_print_frame_status(self, arg):
self.print_stack_trace(0)
self._validate_file_mtime()
self._show_display()
def _pdbcmd_silence_frame_status(self, arg):
if self.cmdqueue and self.cmdqueue[-1] == '_pdbcmd_print_frame_status':
self.cmdqueue.pop()
def _pdbcmd_restore_lastcmd(self, arg):
self.lastcmd = arg
# Command definitions, called by cmdloop()
# The argument is the remaining string on the command line
# Return true to exit from the command loop
def do_commands(self, arg):
"""(Pdb) commands [bpnumber]
(com) ...
(com) end
(Pdb)
Specify a list of commands for breakpoint number bpnumber.
The commands themselves are entered on the following lines.
Type a line containing just 'end' to terminate the commands.
The commands are executed when the breakpoint is hit.
To remove all commands from a breakpoint, type commands and
follow it immediately with end; that is, give no commands.
With no bpnumber argument, commands refers to the last
breakpoint set.
You can use breakpoint commands to start your program up
again. Simply use the continue command, or step, or any other
command that resumes execution.
Specifying any command resuming execution (currently continue,
step, next, return, jump, quit and their abbreviations)
terminates the command list (as if that command was
immediately followed by end). This is because any time you
resume execution (even with a simple next or step), you may
encounter another breakpoint -- which could have its own
command list, leading to ambiguities about which list to
execute.
If you use the 'silent' command in the command list, the usual
message about stopping at a breakpoint is not printed. This
may be desirable for breakpoints that are to print a specific
message and then continue. If none of the other commands
print anything, you will see no sign that the breakpoint was
reached.
"""
if not arg:
bnum = len(bdb.Breakpoint.bpbynumber) - 1
else:
try:
bnum = int(arg)
except:
self._print_invalid_arg(arg)
return
try:
self.get_bpbynumber(bnum)
except ValueError as err:
self.error('cannot set commands: %s' % err)
return
self.commands_bnum = bnum
# Save old definitions for the case of a keyboard interrupt.
if bnum in self.commands:
old_commands = self.commands[bnum]
else:
old_commands = None
self.commands[bnum] = []
prompt_back = self.prompt
self.prompt = '(com) '
self.commands_defining = True
try:
self.cmdloop()
except KeyboardInterrupt:
# Restore old definitions.
if old_commands:
self.commands[bnum] = old_commands
else:
del self.commands[bnum]
self.error('command definition aborted, old commands restored')
finally:
self.commands_defining = False
self.prompt = prompt_back
complete_commands = _complete_bpnumber
def do_break(self, arg, temporary=False):
"""b(reak) [ ([filename:]lineno | function) [, condition] ]
Without argument, list all breaks.
With a line number argument, set a break at this line in the
current file. With a function name, set a break at the first
executable line of that function. If a second argument is
present, it is a string specifying an expression which must
evaluate to true before the breakpoint is honored.
The line number may be prefixed with a filename and a colon,
to specify a breakpoint in another file (probably one that
hasn't been loaded yet). The file is searched for on
sys.path; the .py suffix may be omitted.
"""
if not arg:
if self.breaks: # There's at least one
self.message("Num Type Disp Enb Where")
for bp in bdb.Breakpoint.bpbynumber:
if bp:
self.message(bp.bpformat())
return
# parse arguments; comma has lowest precedence
# and cannot occur in filename
filename = None
lineno = None
cond = None
comma = arg.find(',')
if comma > 0:
# parse stuff after comma: "condition"
cond = arg[comma+1:].lstrip()
if err := self._compile_error_message(cond):
self.error('Invalid condition %s: %r' % (cond, err))
return
arg = arg[:comma].rstrip()
# parse stuff before comma: [filename:]lineno | function
colon = arg.rfind(':')
funcname = None
if colon >= 0:
filename = arg[:colon].rstrip()
f = self.lookupmodule(filename)
if not f:
self.error('%r not found from sys.path' % filename)
return
else:
filename = f
arg = arg[colon+1:].lstrip()
try:
lineno = int(arg)
except ValueError:
self.error('Bad lineno: %s' % arg)
return
else:
# no colon; can be lineno or function
try:
lineno = int(arg)
except ValueError:
try:
func = eval(arg,
self.curframe.f_globals,
self.curframe.f_locals)
except:
func = arg
try:
if hasattr(func, '__func__'):
func = func.__func__
code = func.__code__
#use co_name to identify the bkpt (function names
#could be aliased, but co_name is invariant)
funcname = code.co_name
lineno = find_first_executable_line(code)
filename = code.co_filename
except:
# last thing to try
(ok, filename, ln) = self.lineinfo(arg)
if not ok:
self.error('The specified object %r is not a function '
'or was not found along sys.path.' % arg)
return
funcname = ok # ok contains a function name
lineno = int(ln)
if not filename:
filename = self.defaultFile()
# Check for reasonable breakpoint
line = self.checkline(filename, lineno)
if line:
# now set the break point
err = self.set_break(filename, line, temporary, cond, funcname)
if err:
self.error(err)
else:
bp = self.get_breaks(filename, line)[-1]
self.message("Breakpoint %d at %s:%d" %
(bp.number, bp.file, bp.line))
# To be overridden in derived debuggers
def defaultFile(self):
"""Produce a reasonable default."""
filename = self.curframe.f_code.co_filename
if filename == '<string>' and self.mainpyfile:
filename = self.mainpyfile
return filename
do_b = do_break
complete_break = _complete_location
complete_b = _complete_location
def do_tbreak(self, arg):
"""tbreak [ ([filename:]lineno | function) [, condition] ]
Same arguments as break, but sets a temporary breakpoint: it
is automatically deleted when first hit.
"""
self.do_break(arg, True)
complete_tbreak = _complete_location
def lineinfo(self, identifier):
failed = (None, None, None)
# Input is identifier, may be in single quotes
idstring = identifier.split("'")
if len(idstring) == 1:
# not in single quotes
id = idstring[0].strip()
elif len(idstring) == 3:
# quoted
id = idstring[1].strip()
else:
return failed
if id == '': return failed
parts = id.split('.')
# Protection for derived debuggers
if parts[0] == 'self':
del parts[0]
if len(parts) == 0:
return failed
# Best first guess at file to look at
fname = self.defaultFile()
if len(parts) == 1:
item = parts[0]
else:
# More than one part.
# First is module, second is method/class
f = self.lookupmodule(parts[0])
if f:
fname = f
item = parts[1]
answer = find_function(item, self.canonic(fname))
return answer or failed
def checkline(self, filename, lineno):
"""Check whether specified line seems to be executable.
Return `lineno` if it is, 0 if not (e.g. a docstring, comment, blank
line or EOF). Warning: testing is not comprehensive.
"""
# this method should be callable before starting debugging, so default
# to "no globals" if there is no current frame
frame = getattr(self, 'curframe', None)
globs = frame.f_globals if frame else None
line = linecache.getline(filename, lineno, globs)
if not line:
self.message('End of file')
return 0
line = line.strip()
# Don't allow setting breakpoint at a blank line
if (not line or (line[0] == '#') or
(line[:3] == '"""') or line[:3] == "'''"):
self.error('Blank or comment')
return 0
return lineno
def do_enable(self, arg):
"""enable bpnumber [bpnumber ...]
Enables the breakpoints given as a space separated list of
breakpoint numbers.
"""
args = arg.split()
for i in args:
try:
bp = self.get_bpbynumber(i)
except ValueError as err:
self.error(err)
else:
bp.enable()
self.message('Enabled %s' % bp)
complete_enable = _complete_bpnumber
def do_disable(self, arg):
"""disable bpnumber [bpnumber ...]
Disables the breakpoints given as a space separated list of
breakpoint numbers. Disabling a breakpoint means it cannot
cause the program to stop execution, but unlike clearing a
breakpoint, it remains in the list of breakpoints and can be
(re-)enabled.
"""
args = arg.split()
for i in args:
try:
bp = self.get_bpbynumber(i)
except ValueError as err:
self.error(err)
else:
bp.disable()
self.message('Disabled %s' % bp)
complete_disable = _complete_bpnumber
def do_condition(self, arg):
"""condition bpnumber [condition]
Set a new condition for the breakpoint, an expression which
must evaluate to true before the breakpoint is honored. If
condition is absent, any existing condition is removed; i.e.,
the breakpoint is made unconditional.
"""
args = arg.split(' ', 1)
try:
cond = args[1]
if err := self._compile_error_message(cond):
self.error('Invalid condition %s: %r' % (cond, err))
return
except IndexError:
cond = None
try:
bp = self.get_bpbynumber(args[0].strip())
except IndexError:
self.error('Breakpoint number expected')
except ValueError as err:
self.error(err)
else:
bp.cond = cond
if not cond:
self.message('Breakpoint %d is now unconditional.' % bp.number)
else:
self.message('New condition set for breakpoint %d.' % bp.number)
complete_condition = _complete_bpnumber
def do_ignore(self, arg):
"""ignore bpnumber [count]
Set the ignore count for the given breakpoint number. If
count is omitted, the ignore count is set to 0. A breakpoint
becomes active when the ignore count is zero. When non-zero,
the count is decremented each time the breakpoint is reached
and the breakpoint is not disabled and any associated
condition evaluates to true.
"""
args = arg.split()
if not args:
self.error('Breakpoint number expected')
return
if len(args) == 1:
count = 0
elif len(args) == 2:
try:
count = int(args[1])
except ValueError:
self._print_invalid_arg(arg)
return
else:
self._print_invalid_arg(arg)
return
try:
bp = self.get_bpbynumber(args[0].strip())
except ValueError as err:
self.error(err)
else:
bp.ignore = count
if count > 0:
if count > 1:
countstr = '%d crossings' % count
else:
countstr = '1 crossing'
self.message('Will ignore next %s of breakpoint %d.' %
(countstr, bp.number))
else:
self.message('Will stop next time breakpoint %d is reached.'
% bp.number)
complete_ignore = _complete_bpnumber
def do_clear(self, arg):
"""cl(ear) [filename:lineno | bpnumber ...]
With a space separated list of breakpoint numbers, clear
those breakpoints. Without argument, clear all breaks (but
first ask confirmation). With a filename:lineno argument,
clear all breaks at that line in that file.
"""
if not arg:
try:
reply = input('Clear all breaks? ')
except EOFError:
reply = 'no'
reply = reply.strip().lower()
if reply in ('y', 'yes'):
bplist = [bp for bp in bdb.Breakpoint.bpbynumber if bp]
self.clear_all_breaks()
for bp in bplist:
self.message('Deleted %s' % bp)
return
if ':' in arg:
# Make sure it works for "clear C:\foo\bar.py:12"
i = arg.rfind(':')
filename = arg[:i]
arg = arg[i+1:]
try:
lineno = int(arg)
except ValueError:
err = "Invalid line number (%s)" % arg
else:
bplist = self.get_breaks(filename, lineno)[:]
err = self.clear_break(filename, lineno)
if err:
self.error(err)
else:
for bp in bplist:
self.message('Deleted %s' % bp)
return
numberlist = arg.split()
for i in numberlist:
try:
bp = self.get_bpbynumber(i)
except ValueError as err:
self.error(err)
else:
self.clear_bpbynumber(i)
self.message('Deleted %s' % bp)
do_cl = do_clear # 'c' is already an abbreviation for 'continue'
complete_clear = _complete_location
complete_cl = _complete_location
def do_where(self, arg):
"""w(here) [count]
Print a stack trace. If count is not specified, print the full stack.
If count is 0, print the current frame entry. If count is positive,
print count entries from the most recent frame. If count is negative,
print -count entries from the least recent frame.
An arrow indicates the "current frame", which determines the
context of most commands. 'bt' is an alias for this command.
"""
if not arg:
count = None
else:
try:
count = int(arg)
except ValueError:
self.error('Invalid count (%s)' % arg)
return
self.print_stack_trace(count)
do_w = do_where
do_bt = do_where
def _select_frame(self, number):
assert 0 <= number < len(self.stack)
self.curindex = number
self.curframe = self.stack[self.curindex][0]
self.set_convenience_variable(self.curframe, '_frame', self.curframe)
self.print_stack_entry(self.stack[self.curindex])
self.lineno = None
def do_exceptions(self, arg):
"""exceptions [number]
List or change current exception in an exception chain.
Without arguments, list all the current exception in the exception
chain. Exceptions will be numbered, with the current exception indicated
with an arrow.
If given an integer as argument, switch to the exception at that index.
"""
if not self._chained_exceptions:
self.message(
"Did not find chained exceptions. To move between"
" exceptions, pdb/post_mortem must be given an exception"
" object rather than a traceback."
)
return
if not arg:
for ix, exc in enumerate(self._chained_exceptions):
prompt = ">" if ix == self._chained_exception_index else " "
rep = repr(exc)
if len(rep) > 80:
rep = rep[:77] + "..."
indicator = (
" -"
if self._chained_exceptions[ix].__traceback__ is None
else f"{ix:>3}"
)
self.message(f"{prompt} {indicator} {rep}")
else:
try:
number = int(arg)
except ValueError:
self.error("Argument must be an integer")
return
if 0 <= number < len(self._chained_exceptions):
if self._chained_exceptions[number].__traceback__ is None:
self.error("This exception does not have a traceback, cannot jump to it")
return
self._chained_exception_index = number
self.setup(None, self._chained_exceptions[number].__traceback__)
self.print_stack_entry(self.stack[self.curindex])
else:
self.error("No exception with that number")
def do_up(self, arg):
"""u(p) [count]
Move the current frame count (default one) levels up in the
stack trace (to an older frame).
"""
if self.curindex == 0:
self.error('Oldest frame')
return
try:
count = int(arg or 1)
except ValueError:
self.error('Invalid frame count (%s)' % arg)
return
if count < 0:
newframe = 0
else:
newframe = max(0, self.curindex - count)
self._select_frame(newframe)
do_u = do_up
def do_down(self, arg):
"""d(own) [count]
Move the current frame count (default one) levels down in the
stack trace (to a newer frame).
"""
if self.curindex + 1 == len(self.stack):
self.error('Newest frame')
return
try:
count = int(arg or 1)
except ValueError:
self.error('Invalid frame count (%s)' % arg)
return
if count < 0:
newframe = len(self.stack) - 1
else:
newframe = min(len(self.stack) - 1, self.curindex + count)
self._select_frame(newframe)
do_d = do_down
def do_until(self, arg):
"""unt(il) [lineno]
Without argument, continue execution until the line with a
number greater than the current one is reached. With a line
number, continue execution until a line with a number greater
or equal to that is reached. In both cases, also stop when
the current frame returns.
"""
if arg:
try:
lineno = int(arg)
except ValueError:
self.error('Error in argument: %r' % arg)
return
if lineno <= self.curframe.f_lineno:
self.error('"until" line number is smaller than current '
'line number')
return
else:
lineno = None
self.set_until(self.curframe, lineno)
return 1
do_unt = do_until
def do_step(self, arg):
"""s(tep)
Execute the current line, stop at the first possible occasion
(either in a function that is called or in the current
function).
"""
if arg:
self._print_invalid_arg(arg)
return
self.set_step()
return 1
do_s = do_step
def do_next(self, arg):
"""n(ext)
Continue execution until the next line in the current function
is reached or it returns.
"""
if arg:
self._print_invalid_arg(arg)
return
self.set_next(self.curframe)
return 1
do_n = do_next
def do_run(self, arg):
"""run [args...]
Restart the debugged python program. If a string is supplied
it is split with "shlex", and the result is used as the new
sys.argv. History, breakpoints, actions and debugger options
are preserved. "restart" is an alias for "run".
"""
if self.mode == 'inline':
self.error('run/restart command is disabled when pdb is running in inline mode.\n'
'Use the command line interface to enable restarting your program\n'
'e.g. "python -m pdb myscript.py"')
return
if arg:
import shlex
argv0 = sys.argv[0:1]
try:
sys.argv = shlex.split(arg)
except ValueError as e:
self.error('Cannot run %s: %s' % (arg, e))
return
sys.argv[:0] = argv0
# this is caught in the main debugger loop
raise Restart
do_restart = do_run
def do_return(self, arg):
"""r(eturn)
Continue execution until the current function returns.
"""
if arg:
self._print_invalid_arg(arg)
return
self.set_return(self.curframe)
return 1
do_r = do_return
def do_continue(self, arg):
"""c(ont(inue))
Continue execution, only stop when a breakpoint is encountered.
"""
if arg:
self._print_invalid_arg(arg)
return
if not self.nosigint:
try:
Pdb._previous_sigint_handler = \
signal.signal(signal.SIGINT, self.sigint_handler)
except ValueError:
# ValueError happens when do_continue() is invoked from
# a non-main thread in which case we just continue without
# SIGINT set. Would printing a message here (once) make
# sense?
pass
self.set_continue()
return 1
do_c = do_cont = do_continue
def do_jump(self, arg):
"""j(ump) lineno
Set the next line that will be executed. Only available in
the bottom-most frame. This lets you jump back and execute
code again, or jump forward to skip code that you don't want
to run.
It should be noted that not all jumps are allowed -- for
instance it is not possible to jump into the middle of a
for loop or out of a finally clause.
"""
if self.curindex + 1 != len(self.stack):
self.error('You can only jump within the bottom frame')
return
try:
arg = int(arg)
except ValueError:
self.error("The 'jump' command requires a line number")
else:
try:
# Do the jump, fix up our copy of the stack, and display the
# new position
self.curframe.f_lineno = arg
self.stack[self.curindex] = self.stack[self.curindex][0], arg
self.print_stack_entry(self.stack[self.curindex])
except ValueError as e:
self.error('Jump failed: %s' % e)
do_j = do_jump
def do_debug(self, arg):
"""debug code
Enter a recursive debugger that steps through the code
argument (which is an arbitrary expression or statement to be
executed in the current environment).
"""
sys.settrace(None)
globals = self.curframe.f_globals
locals = self.curframe.f_locals
p = Pdb(self.completekey, self.stdin, self.stdout)
p.prompt = "(%s) " % self.prompt.strip()
self.message("ENTERING RECURSIVE DEBUGGER")
try:
sys.call_tracing(p.run, (arg, globals, locals))
except Exception:
self._error_exc()
self.message("LEAVING RECURSIVE DEBUGGER")
sys.settrace(self.trace_dispatch)
self.lastcmd = p.lastcmd
complete_debug = _complete_expression
def do_quit(self, arg):
"""q(uit) | exit
Quit from the debugger. The program being executed is aborted.
"""
self._user_requested_quit = True
self.set_quit()
return 1
do_q = do_quit
do_exit = do_quit
def do_EOF(self, arg):
"""EOF
Handles the receipt of EOF as a command.
"""
self.message('')
self._user_requested_quit = True
self.set_quit()
return 1
def do_args(self, arg):
"""a(rgs)
Print the argument list of the current function.
"""
if arg:
self._print_invalid_arg(arg)
return
co = self.curframe.f_code
dict = self.curframe.f_locals
n = co.co_argcount + co.co_kwonlyargcount
if co.co_flags & inspect.CO_VARARGS: n = n+1
if co.co_flags & inspect.CO_VARKEYWORDS: n = n+1
for i in range(n):
name = co.co_varnames[i]
if name in dict:
self.message('%s = %s' % (name, self._safe_repr(dict[name], name)))
else:
self.message('%s = *** undefined ***' % (name,))
do_a = do_args
def do_retval(self, arg):
"""retval
Print the return value for the last return of a function.
"""
if arg:
self._print_invalid_arg(arg)
return
if '__return__' in self.curframe.f_locals:
self.message(self._safe_repr(self.curframe.f_locals['__return__'], "retval"))
else:
self.error('Not yet returned!')
do_rv = do_retval
def _getval(self, arg):
try:
return eval(arg, self.curframe.f_globals, self.curframe.f_locals)
except:
self._error_exc()
raise
def _getval_except(self, arg, frame=None):
try:
if frame is None:
return eval(arg, self.curframe.f_globals, self.curframe.f_locals)
else:
return eval(arg, frame.f_globals, frame.f_locals)
except BaseException as exc:
return _rstr('** raised %s **' % self._format_exc(exc))
def _error_exc(self):
exc = sys.exception()
self.error(self._format_exc(exc))
def _msg_val_func(self, arg, func):
try:
val = self._getval(arg)
except:
return # _getval() has displayed the error
try:
self.message(func(val))
except:
self._error_exc()
def _safe_repr(self, obj, expr):
try:
return repr(obj)
except Exception as e:
return _rstr(f"*** repr({expr}) failed: {self._format_exc(e)} ***")
def do_p(self, arg):
"""p expression
Print the value of the expression.
"""
self._msg_val_func(arg, repr)
def do_pp(self, arg):
"""pp expression
Pretty-print the value of the expression.
"""
self._msg_val_func(arg, pprint.pformat)
complete_print = _complete_expression
complete_p = _complete_expression
complete_pp = _complete_expression
def do_list(self, arg):
"""l(ist) [first[, last] | .]
List source code for the current file. Without arguments,
list 11 lines around the current line or continue the previous
listing. With . as argument, list 11 lines around the current
line. With one argument, list 11 lines starting at that line.
With two arguments, list the given range; if the second
argument is less than the first, it is a count.
The current line in the current frame is indicated by "->".
If an exception is being debugged, the line where the
exception was originally raised or propagated is indicated by
">>", if it differs from the current line.
"""
self.lastcmd = 'list'
last = None
if arg and arg != '.':
try:
if ',' in arg:
first, last = arg.split(',')
first = int(first.strip())
last = int(last.strip())
if last < first:
# assume it's a count
last = first + last
else:
first = int(arg.strip())
first = max(1, first - 5)
except ValueError:
self.error('Error in argument: %r' % arg)
return
elif self.lineno is None or arg == '.':
first = max(1, self.curframe.f_lineno - 5)
else:
first = self.lineno + 1
if last is None:
last = first + 10
filename = self.curframe.f_code.co_filename
# gh-93696: stdlib frozen modules provide a useful __file__
# this workaround can be removed with the closure of gh-89815
if filename.startswith("<frozen"):
tmp = self.curframe.f_globals.get("__file__")
if isinstance(tmp, str):
filename = tmp
breaklist = self.get_file_breaks(filename)
try:
lines = linecache.getlines(filename, self.curframe.f_globals)
self._print_lines(lines[first-1:last], first, breaklist,
self.curframe)
self.lineno = min(last, len(lines))
if len(lines) < last:
self.message('[EOF]')
except KeyboardInterrupt:
pass
self._validate_file_mtime()
do_l = do_list
def do_longlist(self, arg):
"""ll | longlist
List the whole source code for the current function or frame.
"""
if arg:
self._print_invalid_arg(arg)
return
filename = self.curframe.f_code.co_filename
breaklist = self.get_file_breaks(filename)
try:
lines, lineno = self._getsourcelines(self.curframe)
except OSError as err:
self.error(err)
return
self._print_lines(lines, lineno, breaklist, self.curframe)
self._validate_file_mtime()
do_ll = do_longlist
def do_source(self, arg):
"""source expression
Try to get source code for the given object and display it.
"""
try:
obj = self._getval(arg)
except:
return
try:
lines, lineno = self._getsourcelines(obj)
except (OSError, TypeError) as err:
self.error(err)
return
self._print_lines(lines, lineno)
complete_source = _complete_expression
def _print_lines(self, lines, start, breaks=(), frame=None):
"""Print a range of lines."""
if frame:
current_lineno = frame.f_lineno
exc_lineno = self.tb_lineno.get(frame, -1)
else:
current_lineno = exc_lineno = -1
for lineno, line in enumerate(lines, start):
s = str(lineno).rjust(3)
if len(s) < 4:
s += ' '
if lineno in breaks:
s += 'B'
else:
s += ' '
if lineno == current_lineno:
s += '->'
elif lineno == exc_lineno:
s += '>>'
self.message(s + '\t' + line.rstrip())
def do_whatis(self, arg):
"""whatis expression
Print the type of the argument.
"""
try:
value = self._getval(arg)
except:
# _getval() already printed the error
return
code = None
# Is it an instance method?
try:
code = value.__func__.__code__
except Exception:
pass
if code:
self.message('Method %s' % code.co_name)
return
# Is it a function?
try:
code = value.__code__
except Exception:
pass
if code:
self.message('Function %s' % code.co_name)
return
# Is it a class?
if value.__class__ is type:
self.message('Class %s.%s' % (value.__module__, value.__qualname__))
return
# None of the above...
self.message(type(value))
complete_whatis = _complete_expression
def do_display(self, arg):
"""display [expression]
Display the value of the expression if it changed, each time execution
stops in the current frame.
Without expression, list all display expressions for the current frame.
"""
if not arg:
if self.displaying:
self.message('Currently displaying:')
for key, val in self.displaying.get(self.curframe, {}).items():
self.message('%s: %s' % (key, self._safe_repr(val, key)))
else:
self.message('No expression is being displayed')
else:
if err := self._compile_error_message(arg):
self.error('Unable to display %s: %r' % (arg, err))
else:
val = self._getval_except(arg)
self.displaying.setdefault(self.curframe, {})[arg] = val
self.message('display %s: %s' % (arg, self._safe_repr(val, arg)))
complete_display = _complete_expression
def do_undisplay(self, arg):
"""undisplay [expression]
Do not display the expression any more in the current frame.
Without expression, clear all display expressions for the current frame.
"""
if arg:
try:
del self.displaying.get(self.curframe, {})[arg]
except KeyError:
self.error('not displaying %s' % arg)
else:
self.displaying.pop(self.curframe, None)
def complete_undisplay(self, text, line, begidx, endidx):
return [e for e in self.displaying.get(self.curframe, {})
if e.startswith(text)]
def do_interact(self, arg):
"""interact
Start an interactive interpreter whose global namespace
contains all the (global and local) names found in the current scope.
"""
ns = {**self.curframe.f_globals, **self.curframe.f_locals}
console = _PdbInteractiveConsole(ns, message=self.message)
console.interact(banner="*pdb interact start*",
exitmsg="*exit from pdb interact command*")
def do_alias(self, arg):
"""alias [name [command]]
Create an alias called 'name' that executes 'command'. The
command must *not* be enclosed in quotes. Replaceable
parameters can be indicated by %1, %2, and so on, while %* is
replaced by all the parameters. If no command is given, the
current alias for name is shown. If no name is given, all
aliases are listed.
Aliases may be nested and can contain anything that can be
legally typed at the pdb prompt. Note! You *can* override
internal pdb commands with aliases! Those internal commands
are then hidden until the alias is removed. Aliasing is
recursively applied to the first word of the command line; all
other words in the line are left alone.
As an example, here are two useful aliases (especially when
placed in the .pdbrc file):
# Print instance variables (usage "pi classInst")
alias pi for k in %1.__dict__.keys(): print("%1.",k,"=",%1.__dict__[k])
# Print instance variables in self
alias ps pi self
"""
args = arg.split()
if len(args) == 0:
keys = sorted(self.aliases.keys())
for alias in keys:
self.message("%s = %s" % (alias, self.aliases[alias]))
return
if len(args) == 1:
if args[0] in self.aliases:
self.message("%s = %s" % (args[0], self.aliases[args[0]]))
else:
self.error(f"Unknown alias '{args[0]}'")
else:
# Do a validation check to make sure no replaceable parameters
# are skipped if %* is not used.
alias = ' '.join(args[1:])
if '%*' not in alias:
consecutive = True
for idx in range(1, 10):
if f'%{idx}' not in alias:
consecutive = False
if f'%{idx}' in alias and not consecutive:
self.error("Replaceable parameters must be consecutive")
return
self.aliases[args[0]] = alias
def do_unalias(self, arg):
"""unalias name
Delete the specified alias.
"""
args = arg.split()
if len(args) == 0:
self._print_invalid_arg(arg)
return
if args[0] in self.aliases:
del self.aliases[args[0]]
def complete_unalias(self, text, line, begidx, endidx):
return [a for a in self.aliases if a.startswith(text)]
# List of all the commands making the program resume execution.
commands_resuming = ['do_continue', 'do_step', 'do_next', 'do_return',
'do_until', 'do_quit', 'do_jump']
# Print a traceback starting at the top stack frame.
# The most recently entered frame is printed last;
# this is different from dbx and gdb, but consistent with
# the Python interpreter's stack trace.
# It is also consistent with the up/down commands (which are
# compatible with dbx and gdb: up moves towards 'main()'
# and down moves towards the most recent stack frame).
# * if count is None, prints the full stack
# * if count = 0, prints the current frame entry
# * if count < 0, prints -count least recent frame entries
# * if count > 0, prints count most recent frame entries
def print_stack_trace(self, count=None):
if count is None:
stack_to_print = self.stack
elif count == 0:
stack_to_print = [self.stack[self.curindex]]
elif count < 0:
stack_to_print = self.stack[:-count]
else:
stack_to_print = self.stack[-count:]
try:
for frame_lineno in stack_to_print:
self.print_stack_entry(frame_lineno)
except KeyboardInterrupt:
pass
def print_stack_entry(self, frame_lineno, prompt_prefix=line_prefix):
frame, lineno = frame_lineno
if frame is self.curframe:
prefix = '> '
else:
prefix = ' '
self.message(prefix +
self.format_stack_entry(frame_lineno, prompt_prefix))
# Provide help
def do_help(self, arg):
"""h(elp)
Without argument, print the list of available commands.
With a command name as argument, print help about that command.
"help pdb" shows the full pdb documentation.
"help exec" gives help on the ! command.
"""
if not arg:
return cmd.Cmd.do_help(self, arg)
try:
try:
topic = getattr(self, 'help_' + arg)
return topic()
except AttributeError:
command = getattr(self, 'do_' + arg)
except AttributeError:
self.error('No help for %r' % arg)
else:
if sys.flags.optimize >= 2:
self.error('No help for %r; please do not run Python with -OO '
'if you need command help' % arg)
return
if command.__doc__ is None:
self.error('No help for %r; __doc__ string missing' % arg)
return
self.message(self._help_message_from_doc(command.__doc__))
do_h = do_help
def help_exec(self):
"""(!) statement
Execute the (one-line) statement in the context of the current
stack frame. The exclamation point can be omitted unless the
first word of the statement resembles a debugger command, e.g.:
(Pdb) ! n=42
(Pdb)
To assign to a global variable you must always prefix the command with
a 'global' command, e.g.:
(Pdb) global list_options; list_options = ['-l']
(Pdb)
"""
self.message((self.help_exec.__doc__ or '').strip())
def help_pdb(self):
help()
# other helper functions
def lookupmodule(self, filename):
"""Helper function for break/clear parsing -- may be overridden.
lookupmodule() translates (possibly incomplete) file or module name
into an absolute file name.
filename could be in format of:
* an absolute path like '/path/to/file.py'
* a relative path like 'file.py' or 'dir/file.py'
* a module name like 'module' or 'package.module'
files and modules will be searched in sys.path.
"""
if not filename.endswith('.py'):
# A module is passed in so convert it to equivalent file
filename = filename.replace('.', os.sep) + '.py'
if os.path.isabs(filename):
if os.path.exists(filename):
return filename
return None
for dirname in sys.path:
while os.path.islink(dirname):
dirname = os.readlink(dirname)
fullname = os.path.join(dirname, filename)
if os.path.exists(fullname):
return fullname
return None
def _run(self, target: _ExecutableTarget):
# When bdb sets tracing, a number of call and line events happen
# BEFORE debugger even reaches user's code (and the exact sequence of
# events depends on python version). Take special measures to
# avoid stopping before reaching the main script (see user_line and
# user_call for details).
self._wait_for_mainpyfile = True
self._user_requested_quit = False
self.mainpyfile = self.canonic(target.filename)
# The target has to run in __main__ namespace (or imports from
# __main__ will break). Clear __main__ and replace with
# the target namespace.
import __main__
__main__.__dict__.clear()
__main__.__dict__.update(target.namespace)
# Clear the mtime table for program reruns, assume all the files
# are up to date.
self._file_mtime_table.clear()
self.run(target.code)
def _format_exc(self, exc: BaseException):
return traceback.format_exception_only(exc)[-1].strip()
def _compile_error_message(self, expr):
"""Return the error message as string if compiling `expr` fails."""
try:
compile(expr, "<stdin>", "eval")
except SyntaxError as exc:
return _rstr(self._format_exc(exc))
return ""
def _getsourcelines(self, obj):
# GH-103319
# inspect.getsourcelines() returns lineno = 0 for
# module-level frame which breaks our code print line number
# This method should be replaced by inspect.getsourcelines(obj)
# once this bug is fixed in inspect
lines, lineno = inspect.getsourcelines(obj)
lineno = max(1, lineno)
return lines, lineno
def _help_message_from_doc(self, doc, usage_only=False):
lines = [line.strip() for line in doc.rstrip().splitlines()]
if not lines:
return "No help message found."
if "" in lines:
usage_end = lines.index("")
else:
usage_end = 1
formatted = []
indent = " " * len(self.prompt)
for i, line in enumerate(lines):
if i == 0:
prefix = "Usage: "
elif i < usage_end:
prefix = " "
else:
if usage_only:
break
prefix = ""
formatted.append(indent + prefix + line)
return "\n".join(formatted)
def _print_invalid_arg(self, arg):
"""Return the usage string for a function."""
self.error(f"Invalid argument: {arg}")
# Yes it's a bit hacky. Get the caller name, get the method based on
# that name, and get the docstring from that method.
# This should NOT fail if the caller is a method of this class.
doc = inspect.getdoc(getattr(self, sys._getframe(1).f_code.co_name))
if doc is not None:
self.message(self._help_message_from_doc(doc, usage_only=True))
# Collect all command help into docstring, if not run with -OO
if __doc__ is not None:
# unfortunately we can't guess this order from the class definition
_help_order = [
'help', 'where', 'down', 'up', 'break', 'tbreak', 'clear', 'disable',
'enable', 'ignore', 'condition', 'commands', 'step', 'next', 'until',
'jump', 'return', 'retval', 'run', 'continue', 'list', 'longlist',
'args', 'p', 'pp', 'whatis', 'source', 'display', 'undisplay',
'interact', 'alias', 'unalias', 'debug', 'quit',
]
for _command in _help_order:
__doc__ += getattr(Pdb, 'do_' + _command).__doc__.strip() + '\n\n'
__doc__ += Pdb.help_exec.__doc__
del _help_order, _command
# Simplified interface
def run(statement, globals=None, locals=None):
"""Execute the *statement* (given as a string or a code object)
under debugger control.
The debugger prompt appears before any code is executed; you can set
breakpoints and type continue, or you can step through the statement
using step or next.
The optional *globals* and *locals* arguments specify the
environment in which the code is executed; by default the
dictionary of the module __main__ is used (see the explanation of
the built-in exec() or eval() functions.).
"""
Pdb().run(statement, globals, locals)
def runeval(expression, globals=None, locals=None):
"""Evaluate the *expression* (given as a string or a code object)
under debugger control.
When runeval() returns, it returns the value of the expression.
Otherwise this function is similar to run().
"""
return Pdb().runeval(expression, globals, locals)
def runctx(statement, globals, locals):
# B/W compatibility
run(statement, globals, locals)
def runcall(*args, **kwds):
"""Call the function (a function or method object, not a string)
with the given arguments.
When runcall() returns, it returns whatever the function call
returned. The debugger prompt appears as soon as the function is
entered.
"""
return Pdb().runcall(*args, **kwds)
def set_trace(*, header=None, commands=None):
"""Enter the debugger at the calling stack frame.
This is useful to hard-code a breakpoint at a given point in a
program, even if the code is not otherwise being debugged (e.g. when
an assertion fails). If given, *header* is printed to the console
just before debugging begins. *commands* is an optional list of
pdb commands to run when the debugger starts.
"""
if Pdb._last_pdb_instance is not None:
pdb = Pdb._last_pdb_instance
else:
pdb = Pdb(mode='inline')
if header is not None:
pdb.message(header)
pdb.set_trace(sys._getframe().f_back, commands=commands)
# Post-Mortem interface
def post_mortem(t=None):
"""Enter post-mortem debugging of the given *traceback*, or *exception*
object.
If no traceback is given, it uses the one of the exception that is
currently being handled (an exception must be being handled if the
default is to be used).
If `t` is an exception object, the `exceptions` command makes it possible to
list and inspect its chained exceptions (if any).
"""
return _post_mortem(t, Pdb())
def _post_mortem(t, pdb_instance):
"""
Private version of post_mortem, which allow to pass a pdb instance
for testing purposes.
"""
# handling the default
if t is None:
exc = sys.exception()
if exc is not None:
t = exc.__traceback__
if t is None or (isinstance(t, BaseException) and t.__traceback__ is None):
raise ValueError("A valid traceback must be passed if no "
"exception is being handled")
pdb_instance.reset()
pdb_instance.interaction(None, t)
def pm():
"""Enter post-mortem debugging of the traceback found in sys.last_exc."""
post_mortem(sys.last_exc)
# Main program for testing
TESTCMD = 'import x; x.main()'
def test():
run(TESTCMD)
# print help
def help():
import pydoc
pydoc.pager(__doc__)
_usage = """\
Debug the Python program given by pyfile. Alternatively,
an executable module or package to debug can be specified using
the -m switch.
Initial commands are read from .pdbrc files in your home directory
and in the current directory, if they exist. Commands supplied with
-c are executed after commands from .pdbrc files.
To let the script run until an exception occurs, use "-c continue".
To let the script run up to a given line X in the debugged file, use
"-c 'until X'"."""
def main():
import argparse
parser = argparse.ArgumentParser(usage="%(prog)s [-h] [-c command] (-m module | pyfile) [args ...]",
description=_usage,
formatter_class=argparse.RawDescriptionHelpFormatter,
allow_abbrev=False)
# We need to maunally get the script from args, because the first positional
# arguments could be either the script we need to debug, or the argument
# to the -m module
parser.add_argument('-c', '--command', action='append', default=[], metavar='command', dest='commands',
help='pdb commands to execute as if given in a .pdbrc file')
parser.add_argument('-m', metavar='module', dest='module')
if len(sys.argv) == 1:
# If no arguments were given (python -m pdb), print the whole help message.
# Without this check, argparse would only complain about missing required arguments.
parser.print_help()
sys.exit(2)
opts, args = parser.parse_known_args()
if opts.module:
# If a module is being debugged, we consider the arguments after "-m module" to
# be potential arguments to the module itself. We need to parse the arguments
# before "-m" to check if there is any invalid argument.
# e.g. "python -m pdb -m foo --spam" means passing "--spam" to "foo"
# "python -m pdb --spam -m foo" means passing "--spam" to "pdb" and is invalid
idx = sys.argv.index('-m')
args_to_pdb = sys.argv[1:idx]
# This will raise an error if there are invalid arguments
parser.parse_args(args_to_pdb)
else:
# If a script is being debugged, then pdb expects the script name as the first argument.
# Anything before the script is considered an argument to pdb itself, which would
# be invalid because it's not parsed by argparse.
invalid_args = list(itertools.takewhile(lambda a: a.startswith('-'), args))
if invalid_args:
parser.error(f"unrecognized arguments: {' '.join(invalid_args)}")
sys.exit(2)
if opts.module:
file = opts.module
target = _ModuleTarget(file)
else:
if not args:
parser.error("no module or script to run")
file = args.pop(0)
if file.endswith('.pyz'):
target = _ZipTarget(file)
else:
target = _ScriptTarget(file)
sys.argv[:] = [file] + args # Hide "pdb.py" and pdb options from argument list
# Note on saving/restoring sys.argv: it's a good idea when sys.argv was
# modified by the script being debugged. It's a bad idea when it was
# changed by the user from the command line. There is a "restart" command
# which allows explicit specification of command line arguments.
pdb = Pdb(mode='cli')
pdb.rcLines.extend(opts.commands)
while True:
try:
pdb._run(target)
except Restart:
print("Restarting", target, "with arguments:")
print("\t" + " ".join(sys.argv[1:]))
except SystemExit as e:
# In most cases SystemExit does not warrant a post-mortem session.
print("The program exited via sys.exit(). Exit status:", end=' ')
print(e)
except BaseException as e:
traceback.print_exception(e, colorize=_colorize.can_colorize())
print("Uncaught exception. Entering post mortem debugging")
print("Running 'cont' or 'step' will restart the program")
try:
pdb.interaction(None, e)
except Restart:
print("Restarting", target, "with arguments:")
print("\t" + " ".join(sys.argv[1:]))
continue
if pdb._user_requested_quit:
break
print("The program finished and will be restarted")
# When invoked as main program, invoke the debugger on a script
if __name__ == '__main__':
import pdb
pdb.main()