Moved documentation out to pdb.doc file.

Moved class Cmd out to module cmd.py.
Rewrote implementation of stack trace to incorporate traceback objects.
This commit is contained in:
Guido van Rossum 1992-01-16 13:50:21 +00:00
parent 7c36ad7f44
commit 6fe08b0fe4
1 changed files with 88 additions and 273 deletions

View File

@ -1,232 +1,19 @@
# pdb.py -- finally, a Python debugger! See below for instructions. # pdb.py -- finally, a Python debugger!
# See file pdb.doc for instructions.
# To do: # To do:
# - Keep a list of exceptions trapped (default only KeyboardInterrupt?) # - It should be possible to intercept KeyboardInterrupt
# - It should be possible to intercept KeyboardInterrupt completely # - Handle return events differently -- always printing the r.v. can be bad!
# - Handle return events differently (how?) # - Merge with tb, to get a single debugger for active and post-mortem usage
# - When stopping on an exception, show traceback stack # - Solve bugs in termination (e.g., 'continue' after the program
# - Merge with tb (for post-mortem usage) # is done proceeds to debug the debugger; 'quit' sometimes complains
# - Show stack traces upside-down (like dbx/gdb) ??? # about the PdbQuit exception...)
# (actually, the current way is more natural given the directions
# taken by the up/down commands)
# 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>.
# The commands recognized by the debugger are listed below.
# 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.
# A blank line repeats the previous command literally.
# (Except for 'list', where it lists the next 11 lines.)
# Commands that the debugger does not recognized 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.
# When an exception occurs in such a statement, the exception name
# is printed but the debugger's state is not changed.
# The debugger is not directly programmable; but it is implemented
# as a class from which you can derive your own debugger class,
# so you can make as fancy as you like.
# The debugger's commands are:
# h(elp)
# Without argument, print the list of available commands.
# With a command name as argument, print help about that command
# (this is currently not implemented).
# w(here)
# Print a stack trace, with the most recent frame at the bottom.
# An arrow indicates the "current frame", which determines the
# context of most commands.
# d(own)
# Move the current frame one level down in the stack trace
# (to an older frame).
# u(p)
# Move the current frame one level up in the stack trace
# (to a newer frame).
# b(reak) [lineno]
# With a line number argument, set a break there in the current file.
# Without argument, list all breaks.
# cl(ear) [lineno]
# With a line number argument, clear that break in the current file.
# Without argument, clear all breaks (but first ask confirmation).
# s(tep)
# Execute the current line, stop at the first possible occasion
# (either in a function that is called or in the current function).
# n(ext)
# Continue execution until the next line in the current function
# is reached or it returns.
# r(eturn)
# Continue execution until the current function returns.
# c(ont(inue))
# Continue execution, only stop when a breakpoint is encountered.
# 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 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.
# a(rgs)
# Print the argument list of the current function.
# p expression
# Print the value of the expression.
# (!) 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.
# 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)
# q(uit)
# Quit from the debugger.
# The program being executed is aborted.
# Here's how it works.
# Some changes were made to the interpreter:
# - if sys.trace is defined (by the user), it should be a function
# - sys.trace is called the global trace function
# - there can also a local trace function (see later)
# Trace functions have three arguments: (frame, event, arg)
# - frame is the current stack frame
# - event is a string: 'call', 'line', 'return' or 'exception'
# - arg is dependent on the event type
# A trace function should return a new trace function or None.
# Class methods are accepted (and most useful!) as trace methods.
# The events have the following meaning:
#
# 'call': A function is called (or some other code block entered).
# The global trace function is called;
# arg is the argument list to the function;
# the return value specifies the local trace function.
#
# 'line': The interpreter is about to execute a new line of code
# (sometimes multiple line events on one line exist).
# The local trace function is called; arg in None;
# the return value specifies the new local trace function.
#
# 'return': A function (or other code block) is about to return.
# The local trace function is called;
# arg is the value that will be returned.
# The trace function's return value is ignored.
#
# 'exception': An exception has occurred.
# The local trace function is called if there is one,
# else the global trace function is called;
# arg is a triple (exception, value, traceback);
# the return value specifies the new local trace function
#
# Note that as an exception is propagated down the chain of callers,
# an 'exception' event is generated at each level.
# A stack frame object has the following read-only attributes:
# f_code: the code object being executed
# f_lineno: the current line number (-1 for 'call' events)
# f_back: the stack frame of the caller, or None
# f_locals: dictionary containing local name bindings
# f_globals: dictionary containing global name bindings
# A code object has the following read-only attributes:
# co_code: the code string
# co_names: the list of names used by the code
# co_consts: the list of (literal) constants used by the code
# co_filename: the filename from which the code was compiled
import string import string
import sys import sys
import linecache import linecache
from cmd import Cmd
# A generic class to build command interpreters
PROMPT = '(Cmd) '
IDENTCHARS = string.letters + string.digits + '_'
class Cmd:
def init(self):
self.prompt = PROMPT
self.identchars = IDENTCHARS
self.lastcmd = ''
return self
def cmdloop(self):
stop = None
while not stop:
try:
line = raw_input(self.prompt)
except EOFError:
line = 'EOF'
stop = self.onecmd(line)
return stop
def onecmd(self, line):
line = string.strip(line)
if not line:
line = self.lastcmd
print line
else:
self.lastcmd = line
i, n = 0, len(line)
while i < n and line[i] in self.identchars: i = i+1
cmd, arg = line[:i], string.strip(line[i:])
if cmd == '':
return self.default(line)
else:
try:
func = eval('self.do_' + cmd)
except AttributeError:
return self.default(line)
return func(arg)
def default(self, line):
print '*** Unknown syntax:', line
def do_help(self, arg):
if arg:
# XXX check arg syntax
try:
func = eval('self.help_' + arg)
except:
print '*** No help on', `arg`
return
func()
else:
import getattr
names = getattr.dir(self)
cmds = []
for name in names:
if name[:3] == 'do_':
cmds.append(name[3:])
print cmds
# A specialization of Cmd for use by the debugger # A specialization of Cmd for use by the debugger
@ -242,18 +29,32 @@ class Pdb(Cmd):
return self return self
def reset(self): def reset(self):
self.quitting = 0
self.breaks = {} self.breaks = {}
self.botframe = None self.botframe = None
self.stopframe = None self.stopframe = None
self.forget() self.forget()
def forget(self): def forget(self):
self.setup(None) self.setup(None, None)
def setup(self, frame): def setup(self, f, t):
self.curframe = self.topframe = frame
self.stack = []
self.lineno = None self.lineno = None
self.stack = []
if t and t.tb_frame is f:
t = t.tb_next
while f and f is not self.botframe:
self.stack.append((f, f.f_lineno))
f = f.f_back
self.stack.reverse()
self.curindex = max(0, len(self.stack) - 1)
while t:
self.stack.append((t.tb_frame, t.tb_lineno))
t = t.tb_next
if 0 <= self.curindex < len(self.stack):
self.curframe = self.stack[self.curindex][0]
else:
self.curframe = None
def run(self, cmd): def run(self, cmd):
import __main__ import __main__
@ -267,12 +68,21 @@ class Pdb(Cmd):
exec(cmd + '\n', globals, locals) exec(cmd + '\n', globals, locals)
except PdbQuit: except PdbQuit:
pass pass
finally: except:
print '***', sys.exc_type + ':', `sys.exc_value`
print '*** Post Mortem Debugging:'
sys.trace = None sys.trace = None
del sys.trace del sys.trace
try:
self.ask_user(None, sys.exc_traceback)
except PdbQuit:
pass
finally:
self.reset() self.reset()
def dispatch(self, frame, event, arg): def dispatch(self, frame, event, arg):
if self.quitting:
return None
if event == 'line': if event == 'line':
return self.dispatch_line(frame) return self.dispatch_line(frame)
if event == 'call': if event == 'call':
@ -286,7 +96,7 @@ class Pdb(Cmd):
def dispatch_line(self, frame): def dispatch_line(self, frame):
if self.stop_here(frame) or self.break_here(frame): if self.stop_here(frame) or self.break_here(frame):
self.ask_user(frame) self.ask_user(frame, None)
return self.dispatch return self.dispatch
def dispatch_call(self, frame, arg): def dispatch_call(self, frame, arg):
@ -304,10 +114,9 @@ class Pdb(Cmd):
return return
def dispatch_exception(self, frame, arg): def dispatch_exception(self, frame, arg):
if arg[0] is PdbQuit: return None
if self.stop_here(frame): if self.stop_here(frame):
print '!!! exception', arg[0] + ':', `arg[1]` print '!!! exception', arg[0] + ':', `arg[1]`
self.ask_user(frame) self.ask_user(frame, arg[2])
return self.dispatch return self.dispatch
def stop_here(self, frame): def stop_here(self, frame):
@ -315,8 +124,8 @@ class Pdb(Cmd):
return 1 return 1
if frame is self.stopframe: if frame is self.stopframe:
return 1 return 1
while frame is not self.stopframe: while frame is not None and frame is not self.stopframe:
if frame is None: if frame is self.botframe:
return 1 return 1
frame = frame.f_back frame = frame.f_back
return 0 return 0
@ -332,10 +141,10 @@ class Pdb(Cmd):
def break_anywhere(self, frame): def break_anywhere(self, frame):
return self.breaks.has_key(frame.f_code.co_filename) return self.breaks.has_key(frame.f_code.co_filename)
def ask_user(self, frame): def ask_user(self, frame, traceback):
self.setup(frame) self.setup(frame, traceback)
self.printwhere(self.curframe) self.printframelineno(self.stack[self.curindex])
dummy = self.cmdloop() self.cmdloop()
self.forget() self.forget()
def default(self, line): def default(self, line):
@ -402,26 +211,25 @@ class Pdb(Cmd):
do_cl = do_clear # 'c' is already an abbreviation for 'continue' do_cl = do_clear # 'c' is already an abbreviation for 'continue'
def do_where(self, arg): def do_where(self, arg):
self.printtb() self.printstacktrace()
do_w = do_where do_w = do_where
def do_up(self, arg): def do_up(self, arg):
if self.curframe == self.botframe or \ if self.curindex == 0:
not self.curframe.f_back: print '*** Top' print '*** Oldest frame'
else: else:
self.stack.append(self.curframe) self.curindex = self.curindex - 1
self.curframe = self.curframe.f_back self.curframe = self.stack[self.curindex][0]
self.lineno = None self.printframelineno(self.stack[self.curindex])
self.printwhere(self.curframe)
do_u = do_up do_u = do_up
def do_down(self, arg): def do_down(self, arg):
if not self.stack: print '*** Bottom' if self.curindex + 1 == len(self.stack):
print '*** Newest frame'
else: else:
self.curframe = self.stack[-1] self.curindex = self.curindex + 1
self.lineno = None self.curframe = self.stack[self.curindex][0]
del self.stack[-1] self.printframelineno(self.stack[self.curindex])
self.printwhere(self.curframe)
do_d = do_down do_d = do_down
def do_step(self, arg): def do_step(self, arg):
@ -445,7 +253,8 @@ class Pdb(Cmd):
do_c = do_cont = do_continue do_c = do_cont = do_continue
def do_quit(self, arg): def do_quit(self, arg):
self.stopframe = self.botframe self.quitting = 1
sys.trace = None; del sys.trace
raise PdbQuit raise PdbQuit
do_q = do_quit do_q = do_quit
@ -516,36 +325,39 @@ class Pdb(Cmd):
return return
print `value` print `value`
# Print a traceback starting at a given stack frame # Print a traceback starting at the top stack frame.
# Note that it is printed upside-down with respect # Note that the most recently entered frame is printed last;
# to the orientation suggested by the up/down commands. # this is different from dbx and gdb, but consistent with
# This is consistent with gdb. # the Python interpreter's stack trace.
def printtb(self): # It is also consistent with the up/down commands (which are
list = [] # compatible with dbx and gdb: up moves towards 'main()'
frame = self.topframe # and down moves towards the most recent stack frame).
while frame:
list.append(frame)
if frame is self.botframe: break
frame = frame.f_back
list.reverse()
for frame in list:
self.printwhere(frame)
def printwhere(self, frame): def printstacktrace(self):
for x in self.stack:
self.printframelineno(x)
def printframelineno(self, (frame, lineno)):
if frame is self.curframe: print '->', if frame is self.curframe: print '->',
code = frame.f_code code = frame.f_code
filename = code.co_filename filename = code.co_filename
lineno = frame.f_lineno
print filename + '(' + `lineno` + ')', print filename + '(' + `lineno` + ')',
line = linecache.getline(filename, lineno) line = linecache.getline(filename, lineno)
if line: print string.strip(line), print string.strip(line),
print print
def run(statement):
Pdb().init().run(statement)
def runctx(statement, globals, locals):
Pdb().init().runctx(statement, globals, locals)
# --------------------- testing --------------------- # --------------------- testing ---------------------
# The Ackermann function -- a highly recursive beast # The Ackermann function -- a highly recursive beast
cheat = 0 cheat = 2
cache = {} cache = {}
def ack(x, y): def ack(x, y):
key = `(long(x), long(y))` key = `(long(x), long(y))`
@ -572,15 +384,21 @@ def foo(n):
print 'foo', n print 'foo', n
x = bar(n*2) x = bar(n*2)
print 'bar returned', x print 'bar returned', x
return y = ack(4, 3)
return y
def bar(a): def bar(a):
print 'bar', a print 'bar', a
return a*10 return a*10
def melt(n):
print 1.0/n
melt(n-1)
def test(): def test():
linecache.checkcache() linecache.checkcache()
Pdb().init().run('foo(12)\n') runctx('from pdb import foo; foo(12)', {}, {})
runctx('from pdb import melt; melt(5)', {}, {})
# --------------------- main --------------------- # --------------------- main ---------------------
@ -600,7 +418,4 @@ def main():
sys.path.insert(0, head) sys.path.insert(0, head)
run('import ' + tail[:-3]) run('import ' + tail[:-3])
else: else:
run('') run(raw_input('Python statement to debug: '))
def run(statement):
Pdb().init().run(statement)