| #!/usr/bin/python |
| ''' |
| From gdb 7 onwards, gdb's build can be configured --with-python, allowing gdb |
| to be extended with Python code e.g. for library-specific data visualizations, |
| such as for the C++ STL types. Documentation on this API can be seen at: |
| http://sourceware.org/gdb/current/onlinedocs/gdb/Python-API.html |
| |
| |
| This python module deals with the case when the process being debugged (the |
| "inferior process" in gdb parlance) is itself python, or more specifically, |
| linked against libpython. In this situation, almost every item of data is a |
| (PyObject*), and having the debugger merely print their addresses is not very |
| enlightening. |
| |
| This module embeds knowledge about the implementation details of libpython so |
| that we can emit useful visualizations e.g. a string, a list, a dict, a frame |
| giving file/line information and the state of local variables |
| |
| In particular, given a gdb.Value corresponding to a PyObject* in the inferior |
| process, we can generate a "proxy value" within the gdb process. For example, |
| given a PyObject* in the inferior process that is in fact a PyListObject* |
| holding three PyObject* that turn out to be PyBytesObject* instances, we can |
| generate a proxy value within the gdb process that is a list of bytes |
| instances: |
| [b"foo", b"bar", b"baz"] |
| |
| Doing so can be expensive for complicated graphs of objects, and could take |
| some time, so we also have a "write_repr" method that writes a representation |
| of the data to a file-like object. This allows us to stop the traversal by |
| having the file-like object raise an exception if it gets too much data. |
| |
| With both "proxyval" and "write_repr" we keep track of the set of all addresses |
| visited so far in the traversal, to avoid infinite recursion due to cycles in |
| the graph of object references. |
| |
| We try to defer gdb.lookup_type() invocations for python types until as late as |
| possible: for a dynamically linked python binary, when the process starts in |
| the debugger, the libpython.so hasn't been dynamically loaded yet, so none of |
| the type names are known to the debugger |
| |
| The module also extends gdb with some python-specific commands. |
| ''' |
| from __future__ import with_statement |
| import gdb |
| import locale |
| import sys |
| |
| # Look up the gdb.Type for some standard types: |
| _type_char_ptr = gdb.lookup_type('char').pointer() # char* |
| _type_unsigned_char_ptr = gdb.lookup_type('unsigned char').pointer() # unsigned char* |
| _type_void_ptr = gdb.lookup_type('void').pointer() # void* |
| _type_unsigned_short_ptr = gdb.lookup_type('unsigned short').pointer() |
| _type_unsigned_int_ptr = gdb.lookup_type('unsigned int').pointer() |
| |
| # value computed later, see PyUnicodeObjectPtr.proxy() |
| _is_pep393 = None |
| |
| SIZEOF_VOID_P = _type_void_ptr.sizeof |
| |
| |
| Py_TPFLAGS_HEAPTYPE = (1L << 9) |
| |
| Py_TPFLAGS_LONG_SUBCLASS = (1L << 24) |
| Py_TPFLAGS_LIST_SUBCLASS = (1L << 25) |
| Py_TPFLAGS_TUPLE_SUBCLASS = (1L << 26) |
| Py_TPFLAGS_BYTES_SUBCLASS = (1L << 27) |
| Py_TPFLAGS_UNICODE_SUBCLASS = (1L << 28) |
| Py_TPFLAGS_DICT_SUBCLASS = (1L << 29) |
| Py_TPFLAGS_BASE_EXC_SUBCLASS = (1L << 30) |
| Py_TPFLAGS_TYPE_SUBCLASS = (1L << 31) |
| |
| |
| MAX_OUTPUT_LEN=1024 |
| |
| hexdigits = "0123456789abcdef" |
| |
| ENCODING = locale.getpreferredencoding() |
| |
| class NullPyObjectPtr(RuntimeError): |
| pass |
| |
| |
| def safety_limit(val): |
| # Given a integer value from the process being debugged, limit it to some |
| # safety threshold so that arbitrary breakage within said process doesn't |
| # break the gdb process too much (e.g. sizes of iterations, sizes of lists) |
| return min(val, 1000) |
| |
| |
| def safe_range(val): |
| # As per range, but don't trust the value too much: cap it to a safety |
| # threshold in case the data was corrupted |
| return xrange(safety_limit(val)) |
| |
| def write_unicode(file, text): |
| # Write a byte or unicode string to file. Unicode strings are encoded to |
| # ENCODING encoding with 'backslashreplace' error handler to avoid |
| # UnicodeEncodeError. |
| if isinstance(text, unicode): |
| text = text.encode(ENCODING, 'backslashreplace') |
| file.write(text) |
| |
| def os_fsencode(filename): |
| if not isinstance(filename, unicode): |
| return filename |
| encoding = sys.getfilesystemencoding() |
| if encoding == 'mbcs': |
| # mbcs doesn't support surrogateescape |
| return filename.encode(encoding) |
| encoded = [] |
| for char in filename: |
| # surrogateescape error handler |
| if 0xDC80 <= ord(char) <= 0xDCFF: |
| byte = chr(ord(char) - 0xDC00) |
| else: |
| byte = char.encode(encoding) |
| encoded.append(byte) |
| return ''.join(encoded) |
| |
| class StringTruncated(RuntimeError): |
| pass |
| |
| class TruncatedStringIO(object): |
| '''Similar to cStringIO, but can truncate the output by raising a |
| StringTruncated exception''' |
| def __init__(self, maxlen=None): |
| self._val = '' |
| self.maxlen = maxlen |
| |
| def write(self, data): |
| if self.maxlen: |
| if len(data) + len(self._val) > self.maxlen: |
| # Truncation: |
| self._val += data[0:self.maxlen - len(self._val)] |
| raise StringTruncated() |
| |
| self._val += data |
| |
| def getvalue(self): |
| return self._val |
| |
| class PyObjectPtr(object): |
| """ |
| Class wrapping a gdb.Value that's a either a (PyObject*) within the |
| inferior process, or some subclass pointer e.g. (PyBytesObject*) |
| |
| There will be a subclass for every refined PyObject type that we care |
| about. |
| |
| Note that at every stage the underlying pointer could be NULL, point |
| to corrupt data, etc; this is the debugger, after all. |
| """ |
| _typename = 'PyObject' |
| |
| def __init__(self, gdbval, cast_to=None): |
| if cast_to: |
| self._gdbval = gdbval.cast(cast_to) |
| else: |
| self._gdbval = gdbval |
| |
| def field(self, name): |
| ''' |
| Get the gdb.Value for the given field within the PyObject, coping with |
| some python 2 versus python 3 differences. |
| |
| Various libpython types are defined using the "PyObject_HEAD" and |
| "PyObject_VAR_HEAD" macros. |
| |
| In Python 2, this these are defined so that "ob_type" and (for a var |
| object) "ob_size" are fields of the type in question. |
| |
| In Python 3, this is defined as an embedded PyVarObject type thus: |
| PyVarObject ob_base; |
| so that the "ob_size" field is located insize the "ob_base" field, and |
| the "ob_type" is most easily accessed by casting back to a (PyObject*). |
| ''' |
| if self.is_null(): |
| raise NullPyObjectPtr(self) |
| |
| if name == 'ob_type': |
| pyo_ptr = self._gdbval.cast(PyObjectPtr.get_gdb_type()) |
| return pyo_ptr.dereference()[name] |
| |
| if name == 'ob_size': |
| pyo_ptr = self._gdbval.cast(PyVarObjectPtr.get_gdb_type()) |
| return pyo_ptr.dereference()[name] |
| |
| # General case: look it up inside the object: |
| return self._gdbval.dereference()[name] |
| |
| def pyop_field(self, name): |
| ''' |
| Get a PyObjectPtr for the given PyObject* field within this PyObject, |
| coping with some python 2 versus python 3 differences. |
| ''' |
| return PyObjectPtr.from_pyobject_ptr(self.field(name)) |
| |
| def write_field_repr(self, name, out, visited): |
| ''' |
| Extract the PyObject* field named "name", and write its representation |
| to file-like object "out" |
| ''' |
| field_obj = self.pyop_field(name) |
| field_obj.write_repr(out, visited) |
| |
| def get_truncated_repr(self, maxlen): |
| ''' |
| Get a repr-like string for the data, but truncate it at "maxlen" bytes |
| (ending the object graph traversal as soon as you do) |
| ''' |
| out = TruncatedStringIO(maxlen) |
| try: |
| self.write_repr(out, set()) |
| except StringTruncated: |
| # Truncation occurred: |
| return out.getvalue() + '...(truncated)' |
| |
| # No truncation occurred: |
| return out.getvalue() |
| |
| def type(self): |
| return PyTypeObjectPtr(self.field('ob_type')) |
| |
| def is_null(self): |
| return 0 == long(self._gdbval) |
| |
| def is_optimized_out(self): |
| ''' |
| Is the value of the underlying PyObject* visible to the debugger? |
| |
| This can vary with the precise version of the compiler used to build |
| Python, and the precise version of gdb. |
| |
| See e.g. https://bugzilla.redhat.com/show_bug.cgi?id=556975 with |
| PyEval_EvalFrameEx's "f" |
| ''' |
| return self._gdbval.is_optimized_out |
| |
| def safe_tp_name(self): |
| try: |
| return self.type().field('tp_name').string() |
| except NullPyObjectPtr: |
| # NULL tp_name? |
| return 'unknown' |
| except RuntimeError: |
| # Can't even read the object at all? |
| return 'unknown' |
| |
| def proxyval(self, visited): |
| ''' |
| Scrape a value from the inferior process, and try to represent it |
| within the gdb process, whilst (hopefully) avoiding crashes when |
| the remote data is corrupt. |
| |
| Derived classes will override this. |
| |
| For example, a PyIntObject* with ob_ival 42 in the inferior process |
| should result in an int(42) in this process. |
| |
| visited: a set of all gdb.Value pyobject pointers already visited |
| whilst generating this value (to guard against infinite recursion when |
| visiting object graphs with loops). Analogous to Py_ReprEnter and |
| Py_ReprLeave |
| ''' |
| |
| class FakeRepr(object): |
| """ |
| Class representing a non-descript PyObject* value in the inferior |
| process for when we don't have a custom scraper, intended to have |
| a sane repr(). |
| """ |
| |
| def __init__(self, tp_name, address): |
| self.tp_name = tp_name |
| self.address = address |
| |
| def __repr__(self): |
| # For the NULL pointer, we have no way of knowing a type, so |
| # special-case it as per |
| # http://bugs.python.org/issue8032#msg100882 |
| if self.address == 0: |
| return '0x0' |
| return '<%s at remote 0x%x>' % (self.tp_name, self.address) |
| |
| return FakeRepr(self.safe_tp_name(), |
| long(self._gdbval)) |
| |
| def write_repr(self, out, visited): |
| ''' |
| Write a string representation of the value scraped from the inferior |
| process to "out", a file-like object. |
| ''' |
| # Default implementation: generate a proxy value and write its repr |
| # However, this could involve a lot of work for complicated objects, |
| # so for derived classes we specialize this |
| return out.write(repr(self.proxyval(visited))) |
| |
| @classmethod |
| def subclass_from_type(cls, t): |
| ''' |
| Given a PyTypeObjectPtr instance wrapping a gdb.Value that's a |
| (PyTypeObject*), determine the corresponding subclass of PyObjectPtr |
| to use |
| |
| Ideally, we would look up the symbols for the global types, but that |
| isn't working yet: |
| (gdb) python print gdb.lookup_symbol('PyList_Type')[0].value |
| Traceback (most recent call last): |
| File "<string>", line 1, in <module> |
| NotImplementedError: Symbol type not yet supported in Python scripts. |
| Error while executing Python code. |
| |
| For now, we use tp_flags, after doing some string comparisons on the |
| tp_name for some special-cases that don't seem to be visible through |
| flags |
| ''' |
| try: |
| tp_name = t.field('tp_name').string() |
| tp_flags = int(t.field('tp_flags')) |
| except RuntimeError: |
| # Handle any kind of error e.g. NULL ptrs by simply using the base |
| # class |
| return cls |
| |
| #print 'tp_flags = 0x%08x' % tp_flags |
| #print 'tp_name = %r' % tp_name |
| |
| name_map = {'bool': PyBoolObjectPtr, |
| 'classobj': PyClassObjectPtr, |
| 'NoneType': PyNoneStructPtr, |
| 'frame': PyFrameObjectPtr, |
| 'set' : PySetObjectPtr, |
| 'frozenset' : PySetObjectPtr, |
| 'builtin_function_or_method' : PyCFunctionObjectPtr, |
| } |
| if tp_name in name_map: |
| return name_map[tp_name] |
| |
| if tp_flags & Py_TPFLAGS_HEAPTYPE: |
| return HeapTypeObjectPtr |
| |
| if tp_flags & Py_TPFLAGS_LONG_SUBCLASS: |
| return PyLongObjectPtr |
| if tp_flags & Py_TPFLAGS_LIST_SUBCLASS: |
| return PyListObjectPtr |
| if tp_flags & Py_TPFLAGS_TUPLE_SUBCLASS: |
| return PyTupleObjectPtr |
| if tp_flags & Py_TPFLAGS_BYTES_SUBCLASS: |
| return PyBytesObjectPtr |
| if tp_flags & Py_TPFLAGS_UNICODE_SUBCLASS: |
| return PyUnicodeObjectPtr |
| if tp_flags & Py_TPFLAGS_DICT_SUBCLASS: |
| return PyDictObjectPtr |
| if tp_flags & Py_TPFLAGS_BASE_EXC_SUBCLASS: |
| return PyBaseExceptionObjectPtr |
| #if tp_flags & Py_TPFLAGS_TYPE_SUBCLASS: |
| # return PyTypeObjectPtr |
| |
| # Use the base class: |
| return cls |
| |
| @classmethod |
| def from_pyobject_ptr(cls, gdbval): |
| ''' |
| Try to locate the appropriate derived class dynamically, and cast |
| the pointer accordingly. |
| ''' |
| try: |
| p = PyObjectPtr(gdbval) |
| cls = cls.subclass_from_type(p.type()) |
| return cls(gdbval, cast_to=cls.get_gdb_type()) |
| except RuntimeError: |
| # Handle any kind of error e.g. NULL ptrs by simply using the base |
| # class |
| pass |
| return cls(gdbval) |
| |
| @classmethod |
| def get_gdb_type(cls): |
| return gdb.lookup_type(cls._typename).pointer() |
| |
| def as_address(self): |
| return long(self._gdbval) |
| |
| class PyVarObjectPtr(PyObjectPtr): |
| _typename = 'PyVarObject' |
| |
| class ProxyAlreadyVisited(object): |
| ''' |
| Placeholder proxy to use when protecting against infinite recursion due to |
| loops in the object graph. |
| |
| Analogous to the values emitted by the users of Py_ReprEnter and Py_ReprLeave |
| ''' |
| def __init__(self, rep): |
| self._rep = rep |
| |
| def __repr__(self): |
| return self._rep |
| |
| |
| def _write_instance_repr(out, visited, name, pyop_attrdict, address): |
| '''Shared code for use by all classes: |
| write a representation to file-like object "out"''' |
| out.write('<') |
| out.write(name) |
| |
| # Write dictionary of instance attributes: |
| if isinstance(pyop_attrdict, PyDictObjectPtr): |
| out.write('(') |
| first = True |
| for pyop_arg, pyop_val in pyop_attrdict.iteritems(): |
| if not first: |
| out.write(', ') |
| first = False |
| out.write(pyop_arg.proxyval(visited)) |
| out.write('=') |
| pyop_val.write_repr(out, visited) |
| out.write(')') |
| out.write(' at remote 0x%x>' % address) |
| |
| |
| class InstanceProxy(object): |
| |
| def __init__(self, cl_name, attrdict, address): |
| self.cl_name = cl_name |
| self.attrdict = attrdict |
| self.address = address |
| |
| def __repr__(self): |
| if isinstance(self.attrdict, dict): |
| kwargs = ', '.join(["%s=%r" % (arg, val) |
| for arg, val in self.attrdict.iteritems()]) |
| return '<%s(%s) at remote 0x%x>' % (self.cl_name, |
| kwargs, self.address) |
| else: |
| return '<%s at remote 0x%x>' % (self.cl_name, |
| self.address) |
| |
| def _PyObject_VAR_SIZE(typeobj, nitems): |
| if _PyObject_VAR_SIZE._type_size_t is None: |
| _PyObject_VAR_SIZE._type_size_t = gdb.lookup_type('size_t') |
| |
| return ( ( typeobj.field('tp_basicsize') + |
| nitems * typeobj.field('tp_itemsize') + |
| (SIZEOF_VOID_P - 1) |
| ) & ~(SIZEOF_VOID_P - 1) |
| ).cast(_PyObject_VAR_SIZE._type_size_t) |
| _PyObject_VAR_SIZE._type_size_t = None |
| |
| class HeapTypeObjectPtr(PyObjectPtr): |
| _typename = 'PyObject' |
| |
| def get_attr_dict(self): |
| ''' |
| Get the PyDictObject ptr representing the attribute dictionary |
| (or None if there's a problem) |
| ''' |
| try: |
| typeobj = self.type() |
| dictoffset = int_from_int(typeobj.field('tp_dictoffset')) |
| if dictoffset != 0: |
| if dictoffset < 0: |
| type_PyVarObject_ptr = gdb.lookup_type('PyVarObject').pointer() |
| tsize = int_from_int(self._gdbval.cast(type_PyVarObject_ptr)['ob_size']) |
| if tsize < 0: |
| tsize = -tsize |
| size = _PyObject_VAR_SIZE(typeobj, tsize) |
| dictoffset += size |
| assert dictoffset > 0 |
| assert dictoffset % SIZEOF_VOID_P == 0 |
| |
| dictptr = self._gdbval.cast(_type_char_ptr) + dictoffset |
| PyObjectPtrPtr = PyObjectPtr.get_gdb_type().pointer() |
| dictptr = dictptr.cast(PyObjectPtrPtr) |
| return PyObjectPtr.from_pyobject_ptr(dictptr.dereference()) |
| except RuntimeError: |
| # Corrupt data somewhere; fail safe |
| pass |
| |
| # Not found, or some kind of error: |
| return None |
| |
| def proxyval(self, visited): |
| ''' |
| Support for classes. |
| |
| Currently we just locate the dictionary using a transliteration to |
| python of _PyObject_GetDictPtr, ignoring descriptors |
| ''' |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| return ProxyAlreadyVisited('<...>') |
| visited.add(self.as_address()) |
| |
| pyop_attr_dict = self.get_attr_dict() |
| if pyop_attr_dict: |
| attr_dict = pyop_attr_dict.proxyval(visited) |
| else: |
| attr_dict = {} |
| tp_name = self.safe_tp_name() |
| |
| # Class: |
| return InstanceProxy(tp_name, attr_dict, long(self._gdbval)) |
| |
| def write_repr(self, out, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| out.write('<...>') |
| return |
| visited.add(self.as_address()) |
| |
| pyop_attrdict = self.get_attr_dict() |
| _write_instance_repr(out, visited, |
| self.safe_tp_name(), pyop_attrdict, self.as_address()) |
| |
| class ProxyException(Exception): |
| def __init__(self, tp_name, args): |
| self.tp_name = tp_name |
| self.args = args |
| |
| def __repr__(self): |
| return '%s%r' % (self.tp_name, self.args) |
| |
| class PyBaseExceptionObjectPtr(PyObjectPtr): |
| """ |
| Class wrapping a gdb.Value that's a PyBaseExceptionObject* i.e. an exception |
| within the process being debugged. |
| """ |
| _typename = 'PyBaseExceptionObject' |
| |
| def proxyval(self, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| return ProxyAlreadyVisited('(...)') |
| visited.add(self.as_address()) |
| arg_proxy = self.pyop_field('args').proxyval(visited) |
| return ProxyException(self.safe_tp_name(), |
| arg_proxy) |
| |
| def write_repr(self, out, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| out.write('(...)') |
| return |
| visited.add(self.as_address()) |
| |
| out.write(self.safe_tp_name()) |
| self.write_field_repr('args', out, visited) |
| |
| class PyClassObjectPtr(PyObjectPtr): |
| """ |
| Class wrapping a gdb.Value that's a PyClassObject* i.e. a <classobj> |
| instance within the process being debugged. |
| """ |
| _typename = 'PyClassObject' |
| |
| |
| class BuiltInFunctionProxy(object): |
| def __init__(self, ml_name): |
| self.ml_name = ml_name |
| |
| def __repr__(self): |
| return "<built-in function %s>" % self.ml_name |
| |
| class BuiltInMethodProxy(object): |
| def __init__(self, ml_name, pyop_m_self): |
| self.ml_name = ml_name |
| self.pyop_m_self = pyop_m_self |
| |
| def __repr__(self): |
| return ('<built-in method %s of %s object at remote 0x%x>' |
| % (self.ml_name, |
| self.pyop_m_self.safe_tp_name(), |
| self.pyop_m_self.as_address()) |
| ) |
| |
| class PyCFunctionObjectPtr(PyObjectPtr): |
| """ |
| Class wrapping a gdb.Value that's a PyCFunctionObject* |
| (see Include/methodobject.h and Objects/methodobject.c) |
| """ |
| _typename = 'PyCFunctionObject' |
| |
| def proxyval(self, visited): |
| m_ml = self.field('m_ml') # m_ml is a (PyMethodDef*) |
| ml_name = m_ml['ml_name'].string() |
| |
| pyop_m_self = self.pyop_field('m_self') |
| if pyop_m_self.is_null(): |
| return BuiltInFunctionProxy(ml_name) |
| else: |
| return BuiltInMethodProxy(ml_name, pyop_m_self) |
| |
| |
| class PyCodeObjectPtr(PyObjectPtr): |
| """ |
| Class wrapping a gdb.Value that's a PyCodeObject* i.e. a <code> instance |
| within the process being debugged. |
| """ |
| _typename = 'PyCodeObject' |
| |
| def addr2line(self, addrq): |
| ''' |
| Get the line number for a given bytecode offset |
| |
| Analogous to PyCode_Addr2Line; translated from pseudocode in |
| Objects/lnotab_notes.txt |
| ''' |
| co_lnotab = self.pyop_field('co_lnotab').proxyval(set()) |
| |
| # Initialize lineno to co_firstlineno as per PyCode_Addr2Line |
| # not 0, as lnotab_notes.txt has it: |
| lineno = int_from_int(self.field('co_firstlineno')) |
| |
| addr = 0 |
| for addr_incr, line_incr in zip(co_lnotab[::2], co_lnotab[1::2]): |
| addr += ord(addr_incr) |
| if addr > addrq: |
| return lineno |
| lineno += ord(line_incr) |
| return lineno |
| |
| |
| class PyDictObjectPtr(PyObjectPtr): |
| """ |
| Class wrapping a gdb.Value that's a PyDictObject* i.e. a dict instance |
| within the process being debugged. |
| """ |
| _typename = 'PyDictObject' |
| |
| def iteritems(self): |
| ''' |
| Yields a sequence of (PyObjectPtr key, PyObjectPtr value) pairs, |
| analagous to dict.iteritems() |
| ''' |
| keys = self.field('ma_keys') |
| values = self.field('ma_values') |
| for i in safe_range(keys['dk_size']): |
| ep = keys['dk_entries'].address + i |
| if long(values): |
| pyop_value = PyObjectPtr.from_pyobject_ptr(values[i]) |
| else: |
| pyop_value = PyObjectPtr.from_pyobject_ptr(ep['me_value']) |
| if not pyop_value.is_null(): |
| pyop_key = PyObjectPtr.from_pyobject_ptr(ep['me_key']) |
| yield (pyop_key, pyop_value) |
| |
| def proxyval(self, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| return ProxyAlreadyVisited('{...}') |
| visited.add(self.as_address()) |
| |
| result = {} |
| for pyop_key, pyop_value in self.iteritems(): |
| proxy_key = pyop_key.proxyval(visited) |
| proxy_value = pyop_value.proxyval(visited) |
| result[proxy_key] = proxy_value |
| return result |
| |
| def write_repr(self, out, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| out.write('{...}') |
| return |
| visited.add(self.as_address()) |
| |
| out.write('{') |
| first = True |
| for pyop_key, pyop_value in self.iteritems(): |
| if not first: |
| out.write(', ') |
| first = False |
| pyop_key.write_repr(out, visited) |
| out.write(': ') |
| pyop_value.write_repr(out, visited) |
| out.write('}') |
| |
| class PyListObjectPtr(PyObjectPtr): |
| _typename = 'PyListObject' |
| |
| def __getitem__(self, i): |
| # Get the gdb.Value for the (PyObject*) with the given index: |
| field_ob_item = self.field('ob_item') |
| return field_ob_item[i] |
| |
| def proxyval(self, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| return ProxyAlreadyVisited('[...]') |
| visited.add(self.as_address()) |
| |
| result = [PyObjectPtr.from_pyobject_ptr(self[i]).proxyval(visited) |
| for i in safe_range(int_from_int(self.field('ob_size')))] |
| return result |
| |
| def write_repr(self, out, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| out.write('[...]') |
| return |
| visited.add(self.as_address()) |
| |
| out.write('[') |
| for i in safe_range(int_from_int(self.field('ob_size'))): |
| if i > 0: |
| out.write(', ') |
| element = PyObjectPtr.from_pyobject_ptr(self[i]) |
| element.write_repr(out, visited) |
| out.write(']') |
| |
| class PyLongObjectPtr(PyObjectPtr): |
| _typename = 'PyLongObject' |
| |
| def proxyval(self, visited): |
| ''' |
| Python's Include/longobjrep.h has this declaration: |
| struct _longobject { |
| PyObject_VAR_HEAD |
| digit ob_digit[1]; |
| }; |
| |
| with this description: |
| The absolute value of a number is equal to |
| SUM(for i=0 through abs(ob_size)-1) ob_digit[i] * 2**(SHIFT*i) |
| Negative numbers are represented with ob_size < 0; |
| zero is represented by ob_size == 0. |
| |
| where SHIFT can be either: |
| #define PyLong_SHIFT 30 |
| #define PyLong_SHIFT 15 |
| ''' |
| ob_size = long(self.field('ob_size')) |
| if ob_size == 0: |
| return 0L |
| |
| ob_digit = self.field('ob_digit') |
| |
| if gdb.lookup_type('digit').sizeof == 2: |
| SHIFT = 15L |
| else: |
| SHIFT = 30L |
| |
| digits = [long(ob_digit[i]) * 2**(SHIFT*i) |
| for i in safe_range(abs(ob_size))] |
| result = sum(digits) |
| if ob_size < 0: |
| result = -result |
| return result |
| |
| def write_repr(self, out, visited): |
| # Write this out as a Python 3 int literal, i.e. without the "L" suffix |
| proxy = self.proxyval(visited) |
| out.write("%s" % proxy) |
| |
| |
| class PyBoolObjectPtr(PyLongObjectPtr): |
| """ |
| Class wrapping a gdb.Value that's a PyBoolObject* i.e. one of the two |
| <bool> instances (Py_True/Py_False) within the process being debugged. |
| """ |
| def proxyval(self, visited): |
| if PyLongObjectPtr.proxyval(self, visited): |
| return True |
| else: |
| return False |
| |
| class PyNoneStructPtr(PyObjectPtr): |
| """ |
| Class wrapping a gdb.Value that's a PyObject* pointing to the |
| singleton (we hope) _Py_NoneStruct with ob_type PyNone_Type |
| """ |
| _typename = 'PyObject' |
| |
| def proxyval(self, visited): |
| return None |
| |
| |
| class PyFrameObjectPtr(PyObjectPtr): |
| _typename = 'PyFrameObject' |
| |
| def __init__(self, gdbval, cast_to=None): |
| PyObjectPtr.__init__(self, gdbval, cast_to) |
| |
| if not self.is_optimized_out(): |
| self.co = PyCodeObjectPtr.from_pyobject_ptr(self.field('f_code')) |
| self.co_name = self.co.pyop_field('co_name') |
| self.co_filename = self.co.pyop_field('co_filename') |
| |
| self.f_lineno = int_from_int(self.field('f_lineno')) |
| self.f_lasti = int_from_int(self.field('f_lasti')) |
| self.co_nlocals = int_from_int(self.co.field('co_nlocals')) |
| self.co_varnames = PyTupleObjectPtr.from_pyobject_ptr(self.co.field('co_varnames')) |
| |
| def iter_locals(self): |
| ''' |
| Yield a sequence of (name,value) pairs of PyObjectPtr instances, for |
| the local variables of this frame |
| ''' |
| if self.is_optimized_out(): |
| return |
| |
| f_localsplus = self.field('f_localsplus') |
| for i in safe_range(self.co_nlocals): |
| pyop_value = PyObjectPtr.from_pyobject_ptr(f_localsplus[i]) |
| if not pyop_value.is_null(): |
| pyop_name = PyObjectPtr.from_pyobject_ptr(self.co_varnames[i]) |
| yield (pyop_name, pyop_value) |
| |
| def iter_globals(self): |
| ''' |
| Yield a sequence of (name,value) pairs of PyObjectPtr instances, for |
| the global variables of this frame |
| ''' |
| if self.is_optimized_out(): |
| return () |
| |
| pyop_globals = self.pyop_field('f_globals') |
| return pyop_globals.iteritems() |
| |
| def iter_builtins(self): |
| ''' |
| Yield a sequence of (name,value) pairs of PyObjectPtr instances, for |
| the builtin variables |
| ''' |
| if self.is_optimized_out(): |
| return () |
| |
| pyop_builtins = self.pyop_field('f_builtins') |
| return pyop_builtins.iteritems() |
| |
| def get_var_by_name(self, name): |
| ''' |
| Look for the named local variable, returning a (PyObjectPtr, scope) pair |
| where scope is a string 'local', 'global', 'builtin' |
| |
| If not found, return (None, None) |
| ''' |
| for pyop_name, pyop_value in self.iter_locals(): |
| if name == pyop_name.proxyval(set()): |
| return pyop_value, 'local' |
| for pyop_name, pyop_value in self.iter_globals(): |
| if name == pyop_name.proxyval(set()): |
| return pyop_value, 'global' |
| for pyop_name, pyop_value in self.iter_builtins(): |
| if name == pyop_name.proxyval(set()): |
| return pyop_value, 'builtin' |
| return None, None |
| |
| def filename(self): |
| '''Get the path of the current Python source file, as a string''' |
| if self.is_optimized_out(): |
| return '(frame information optimized out)' |
| return self.co_filename.proxyval(set()) |
| |
| def current_line_num(self): |
| '''Get current line number as an integer (1-based) |
| |
| Translated from PyFrame_GetLineNumber and PyCode_Addr2Line |
| |
| See Objects/lnotab_notes.txt |
| ''' |
| if self.is_optimized_out(): |
| return None |
| f_trace = self.field('f_trace') |
| if long(f_trace) != 0: |
| # we have a non-NULL f_trace: |
| return self.f_lineno |
| else: |
| #try: |
| return self.co.addr2line(self.f_lasti) |
| #except ValueError: |
| # return self.f_lineno |
| |
| def current_line(self): |
| '''Get the text of the current source line as a string, with a trailing |
| newline character''' |
| if self.is_optimized_out(): |
| return '(frame information optimized out)' |
| filename = self.filename() |
| try: |
| f = open(os_fsencode(filename), 'r') |
| except IOError: |
| return None |
| with f: |
| all_lines = f.readlines() |
| # Convert from 1-based current_line_num to 0-based list offset: |
| return all_lines[self.current_line_num()-1] |
| |
| def write_repr(self, out, visited): |
| if self.is_optimized_out(): |
| out.write('(frame information optimized out)') |
| return |
| out.write('Frame 0x%x, for file %s, line %i, in %s (' |
| % (self.as_address(), |
| self.co_filename.proxyval(visited), |
| self.current_line_num(), |
| self.co_name.proxyval(visited))) |
| first = True |
| for pyop_name, pyop_value in self.iter_locals(): |
| if not first: |
| out.write(', ') |
| first = False |
| |
| out.write(pyop_name.proxyval(visited)) |
| out.write('=') |
| pyop_value.write_repr(out, visited) |
| |
| out.write(')') |
| |
| def print_traceback(self): |
| if self.is_optimized_out(): |
| sys.stdout.write(' (frame information optimized out)\n') |
| return |
| visited = set() |
| sys.stdout.write(' File "%s", line %i, in %s\n' |
| % (self.co_filename.proxyval(visited), |
| self.current_line_num(), |
| self.co_name.proxyval(visited))) |
| |
| class PySetObjectPtr(PyObjectPtr): |
| _typename = 'PySetObject' |
| |
| def proxyval(self, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| return ProxyAlreadyVisited('%s(...)' % self.safe_tp_name()) |
| visited.add(self.as_address()) |
| |
| members = [] |
| table = self.field('table') |
| for i in safe_range(self.field('mask')+1): |
| setentry = table[i] |
| key = setentry['key'] |
| if key != 0: |
| key_proxy = PyObjectPtr.from_pyobject_ptr(key).proxyval(visited) |
| if key_proxy != '<dummy key>': |
| members.append(key_proxy) |
| if self.safe_tp_name() == 'frozenset': |
| return frozenset(members) |
| else: |
| return set(members) |
| |
| def write_repr(self, out, visited): |
| # Emulate Python 3's set_repr |
| tp_name = self.safe_tp_name() |
| |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| out.write('(...)') |
| return |
| visited.add(self.as_address()) |
| |
| # Python 3's set_repr special-cases the empty set: |
| if not self.field('used'): |
| out.write(tp_name) |
| out.write('()') |
| return |
| |
| # Python 3 uses {} for set literals: |
| if tp_name != 'set': |
| out.write(tp_name) |
| out.write('(') |
| |
| out.write('{') |
| first = True |
| table = self.field('table') |
| for i in safe_range(self.field('mask')+1): |
| setentry = table[i] |
| key = setentry['key'] |
| if key != 0: |
| pyop_key = PyObjectPtr.from_pyobject_ptr(key) |
| key_proxy = pyop_key.proxyval(visited) # FIXME! |
| if key_proxy != '<dummy key>': |
| if not first: |
| out.write(', ') |
| first = False |
| pyop_key.write_repr(out, visited) |
| out.write('}') |
| |
| if tp_name != 'set': |
| out.write(')') |
| |
| |
| class PyBytesObjectPtr(PyObjectPtr): |
| _typename = 'PyBytesObject' |
| |
| def __str__(self): |
| field_ob_size = self.field('ob_size') |
| field_ob_sval = self.field('ob_sval') |
| char_ptr = field_ob_sval.address.cast(_type_unsigned_char_ptr) |
| return ''.join([chr(char_ptr[i]) for i in safe_range(field_ob_size)]) |
| |
| def proxyval(self, visited): |
| return str(self) |
| |
| def write_repr(self, out, visited): |
| # Write this out as a Python 3 bytes literal, i.e. with a "b" prefix |
| |
| # Get a PyStringObject* within the Python 2 gdb process: |
| proxy = self.proxyval(visited) |
| |
| # Transliteration of Python 3's Objects/bytesobject.c:PyBytes_Repr |
| # to Python 2 code: |
| quote = "'" |
| if "'" in proxy and not '"' in proxy: |
| quote = '"' |
| out.write('b') |
| out.write(quote) |
| for byte in proxy: |
| if byte == quote or byte == '\\': |
| out.write('\\') |
| out.write(byte) |
| elif byte == '\t': |
| out.write('\\t') |
| elif byte == '\n': |
| out.write('\\n') |
| elif byte == '\r': |
| out.write('\\r') |
| elif byte < ' ' or ord(byte) >= 0x7f: |
| out.write('\\x') |
| out.write(hexdigits[(ord(byte) & 0xf0) >> 4]) |
| out.write(hexdigits[ord(byte) & 0xf]) |
| else: |
| out.write(byte) |
| out.write(quote) |
| |
| class PyTupleObjectPtr(PyObjectPtr): |
| _typename = 'PyTupleObject' |
| |
| def __getitem__(self, i): |
| # Get the gdb.Value for the (PyObject*) with the given index: |
| field_ob_item = self.field('ob_item') |
| return field_ob_item[i] |
| |
| def proxyval(self, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| return ProxyAlreadyVisited('(...)') |
| visited.add(self.as_address()) |
| |
| result = tuple([PyObjectPtr.from_pyobject_ptr(self[i]).proxyval(visited) |
| for i in safe_range(int_from_int(self.field('ob_size')))]) |
| return result |
| |
| def write_repr(self, out, visited): |
| # Guard against infinite loops: |
| if self.as_address() in visited: |
| out.write('(...)') |
| return |
| visited.add(self.as_address()) |
| |
| out.write('(') |
| for i in safe_range(int_from_int(self.field('ob_size'))): |
| if i > 0: |
| out.write(', ') |
| element = PyObjectPtr.from_pyobject_ptr(self[i]) |
| element.write_repr(out, visited) |
| if self.field('ob_size') == 1: |
| out.write(',)') |
| else: |
| out.write(')') |
| |
| class PyTypeObjectPtr(PyObjectPtr): |
| _typename = 'PyTypeObject' |
| |
| |
| def _unichr_is_printable(char): |
| # Logic adapted from Python 3's Tools/unicode/makeunicodedata.py |
| if char == u" ": |
| return True |
| import unicodedata |
| return unicodedata.category(char) not in ("C", "Z") |
| |
| if sys.maxunicode >= 0x10000: |
| _unichr = unichr |
| else: |
| # Needed for proper surrogate support if sizeof(Py_UNICODE) is 2 in gdb |
| def _unichr(x): |
| if x < 0x10000: |
| return unichr(x) |
| x -= 0x10000 |
| ch1 = 0xD800 | (x >> 10) |
| ch2 = 0xDC00 | (x & 0x3FF) |
| return unichr(ch1) + unichr(ch2) |
| |
| |
| class PyUnicodeObjectPtr(PyObjectPtr): |
| _typename = 'PyUnicodeObject' |
| |
| def char_width(self): |
| _type_Py_UNICODE = gdb.lookup_type('Py_UNICODE') |
| return _type_Py_UNICODE.sizeof |
| |
| def proxyval(self, visited): |
| global _is_pep393 |
| if _is_pep393 is None: |
| fields = gdb.lookup_type('PyUnicodeObject').target().fields() |
| _is_pep393 = 'data' in [f.name for f in fields] |
| if _is_pep393: |
| # Python 3.3 and newer |
| may_have_surrogates = False |
| compact = self.field('_base') |
| ascii = compact['_base'] |
| state = ascii['state'] |
| is_compact_ascii = (int(state['ascii']) and int(state['compact'])) |
| if not int(state['ready']): |
| # string is not ready |
| field_length = long(compact['wstr_length']) |
| may_have_surrogates = True |
| field_str = ascii['wstr'] |
| else: |
| field_length = long(ascii['length']) |
| if is_compact_ascii: |
| field_str = ascii.address + 1 |
| elif int(state['compact']): |
| field_str = compact.address + 1 |
| else: |
| field_str = self.field('data')['any'] |
| repr_kind = int(state['kind']) |
| if repr_kind == 1: |
| field_str = field_str.cast(_type_unsigned_char_ptr) |
| elif repr_kind == 2: |
| field_str = field_str.cast(_type_unsigned_short_ptr) |
| elif repr_kind == 4: |
| field_str = field_str.cast(_type_unsigned_int_ptr) |
| else: |
| # Python 3.2 and earlier |
| field_length = long(self.field('length')) |
| field_str = self.field('str') |
| may_have_surrogates = self.char_width() == 2 |
| |
| # Gather a list of ints from the Py_UNICODE array; these are either |
| # UCS-1, UCS-2 or UCS-4 code points: |
| if not may_have_surrogates: |
| Py_UNICODEs = [int(field_str[i]) for i in safe_range(field_length)] |
| else: |
| # A more elaborate routine if sizeof(Py_UNICODE) is 2 in the |
| # inferior process: we must join surrogate pairs. |
| Py_UNICODEs = [] |
| i = 0 |
| limit = safety_limit(field_length) |
| while i < limit: |
| ucs = int(field_str[i]) |
| i += 1 |
| if ucs < 0xD800 or ucs >= 0xDC00 or i == field_length: |
| Py_UNICODEs.append(ucs) |
| continue |
| # This could be a surrogate pair. |
| ucs2 = int(field_str[i]) |
| if ucs2 < 0xDC00 or ucs2 > 0xDFFF: |
| continue |
| code = (ucs & 0x03FF) << 10 |
| code |= ucs2 & 0x03FF |
| code += 0x00010000 |
| Py_UNICODEs.append(code) |
| i += 1 |
| |
| # Convert the int code points to unicode characters, and generate a |
| # local unicode instance. |
| # This splits surrogate pairs if sizeof(Py_UNICODE) is 2 here (in gdb). |
| result = u''.join([ |
| (_unichr(ucs) if ucs <= 0x10ffff else '\ufffd') |
| for ucs in Py_UNICODEs]) |
| return result |
| |
| def write_repr(self, out, visited): |
| # Write this out as a Python 3 str literal, i.e. without a "u" prefix |
| |
| # Get a PyUnicodeObject* within the Python 2 gdb process: |
| proxy = self.proxyval(visited) |
| |
| # Transliteration of Python 3's Object/unicodeobject.c:unicode_repr |
| # to Python 2: |
| if "'" in proxy and '"' not in proxy: |
| quote = '"' |
| else: |
| quote = "'" |
| out.write(quote) |
| |
| i = 0 |
| while i < len(proxy): |
| ch = proxy[i] |
| i += 1 |
| |
| # Escape quotes and backslashes |
| if ch == quote or ch == '\\': |
| out.write('\\') |
| out.write(ch) |
| |
| # Map special whitespace to '\t', \n', '\r' |
| elif ch == '\t': |
| out.write('\\t') |
| elif ch == '\n': |
| out.write('\\n') |
| elif ch == '\r': |
| out.write('\\r') |
| |
| # Map non-printable US ASCII to '\xhh' */ |
| elif ch < ' ' or ch == 0x7F: |
| out.write('\\x') |
| out.write(hexdigits[(ord(ch) >> 4) & 0x000F]) |
| out.write(hexdigits[ord(ch) & 0x000F]) |
| |
| # Copy ASCII characters as-is |
| elif ord(ch) < 0x7F: |
| out.write(ch) |
| |
| # Non-ASCII characters |
| else: |
| ucs = ch |
| ch2 = None |
| if sys.maxunicode < 0x10000: |
| # If sizeof(Py_UNICODE) is 2 here (in gdb), join |
| # surrogate pairs before calling _unichr_is_printable. |
| if (i < len(proxy) |
| and 0xD800 <= ord(ch) < 0xDC00 \ |
| and 0xDC00 <= ord(proxy[i]) <= 0xDFFF): |
| ch2 = proxy[i] |
| ucs = ch + ch2 |
| i += 1 |
| |
| # Unfortuately, Python 2's unicode type doesn't seem |
| # to expose the "isprintable" method |
| printable = _unichr_is_printable(ucs) |
| if printable: |
| try: |
| ucs.encode(ENCODING) |
| except UnicodeEncodeError: |
| printable = False |
| |
| # Map Unicode whitespace and control characters |
| # (categories Z* and C* except ASCII space) |
| if not printable: |
| if ch2 is not None: |
| # Match Python 3's representation of non-printable |
| # wide characters. |
| code = (ord(ch) & 0x03FF) << 10 |
| code |= ord(ch2) & 0x03FF |
| code += 0x00010000 |
| else: |
| code = ord(ucs) |
| |
| # Map 8-bit characters to '\\xhh' |
| if code <= 0xff: |
| out.write('\\x') |
| out.write(hexdigits[(code >> 4) & 0x000F]) |
| out.write(hexdigits[code & 0x000F]) |
| # Map 21-bit characters to '\U00xxxxxx' |
| elif code >= 0x10000: |
| out.write('\\U') |
| out.write(hexdigits[(code >> 28) & 0x0000000F]) |
| out.write(hexdigits[(code >> 24) & 0x0000000F]) |
| out.write(hexdigits[(code >> 20) & 0x0000000F]) |
| out.write(hexdigits[(code >> 16) & 0x0000000F]) |
| out.write(hexdigits[(code >> 12) & 0x0000000F]) |
| out.write(hexdigits[(code >> 8) & 0x0000000F]) |
| out.write(hexdigits[(code >> 4) & 0x0000000F]) |
| out.write(hexdigits[code & 0x0000000F]) |
| # Map 16-bit characters to '\uxxxx' |
| else: |
| out.write('\\u') |
| out.write(hexdigits[(code >> 12) & 0x000F]) |
| out.write(hexdigits[(code >> 8) & 0x000F]) |
| out.write(hexdigits[(code >> 4) & 0x000F]) |
| out.write(hexdigits[code & 0x000F]) |
| else: |
| # Copy characters as-is |
| out.write(ch) |
| if ch2 is not None: |
| out.write(ch2) |
| |
| out.write(quote) |
| |
| |
| |
| |
| def int_from_int(gdbval): |
| return int(str(gdbval)) |
| |
| |
| def stringify(val): |
| # TODO: repr() puts everything on one line; pformat can be nicer, but |
| # can lead to v.long results; this function isolates the choice |
| if True: |
| return repr(val) |
| else: |
| from pprint import pformat |
| return pformat(val) |
| |
| |
| class PyObjectPtrPrinter: |
| "Prints a (PyObject*)" |
| |
| def __init__ (self, gdbval): |
| self.gdbval = gdbval |
| |
| def to_string (self): |
| pyop = PyObjectPtr.from_pyobject_ptr(self.gdbval) |
| if True: |
| return pyop.get_truncated_repr(MAX_OUTPUT_LEN) |
| else: |
| # Generate full proxy value then stringify it. |
| # Doing so could be expensive |
| proxyval = pyop.proxyval(set()) |
| return stringify(proxyval) |
| |
| def pretty_printer_lookup(gdbval): |
| type = gdbval.type.unqualified() |
| if type.code == gdb.TYPE_CODE_PTR: |
| type = type.target().unqualified() |
| t = str(type) |
| if t in ("PyObject", "PyFrameObject", "PyUnicodeObject"): |
| return PyObjectPtrPrinter(gdbval) |
| |
| """ |
| During development, I've been manually invoking the code in this way: |
| (gdb) python |
| |
| import sys |
| sys.path.append('/home/david/coding/python-gdb') |
| import libpython |
| end |
| |
| then reloading it after each edit like this: |
| (gdb) python reload(libpython) |
| |
| The following code should ensure that the prettyprinter is registered |
| if the code is autoloaded by gdb when visiting libpython.so, provided |
| that this python file is installed to the same path as the library (or its |
| .debug file) plus a "-gdb.py" suffix, e.g: |
| /usr/lib/libpython2.6.so.1.0-gdb.py |
| /usr/lib/debug/usr/lib/libpython2.6.so.1.0.debug-gdb.py |
| """ |
| def register (obj): |
| if obj is None: |
| obj = gdb |
| |
| # Wire up the pretty-printer |
| obj.pretty_printers.append(pretty_printer_lookup) |
| |
| register (gdb.current_objfile ()) |
| |
| |
| |
| # Unfortunately, the exact API exposed by the gdb module varies somewhat |
| # from build to build |
| # See http://bugs.python.org/issue8279?#msg102276 |
| |
| class Frame(object): |
| ''' |
| Wrapper for gdb.Frame, adding various methods |
| ''' |
| def __init__(self, gdbframe): |
| self._gdbframe = gdbframe |
| |
| def older(self): |
| older = self._gdbframe.older() |
| if older: |
| return Frame(older) |
| else: |
| return None |
| |
| def newer(self): |
| newer = self._gdbframe.newer() |
| if newer: |
| return Frame(newer) |
| else: |
| return None |
| |
| def select(self): |
| '''If supported, select this frame and return True; return False if unsupported |
| |
| Not all builds have a gdb.Frame.select method; seems to be present on Fedora 12 |
| onwards, but absent on Ubuntu buildbot''' |
| if not hasattr(self._gdbframe, 'select'): |
| print ('Unable to select frame: ' |
| 'this build of gdb does not expose a gdb.Frame.select method') |
| return False |
| self._gdbframe.select() |
| return True |
| |
| def get_index(self): |
| '''Calculate index of frame, starting at 0 for the newest frame within |
| this thread''' |
| index = 0 |
| # Go down until you reach the newest frame: |
| iter_frame = self |
| while iter_frame.newer(): |
| index += 1 |
| iter_frame = iter_frame.newer() |
| return index |
| |
| # We divide frames into: |
| # - "python frames": |
| # - "bytecode frames" i.e. PyEval_EvalFrameEx |
| # - "other python frames": things that are of interest from a python |
| # POV, but aren't bytecode (e.g. GC, GIL) |
| # - everything else |
| |
| def is_python_frame(self): |
| '''Is this a PyEval_EvalFrameEx frame, or some other important |
| frame? (see is_other_python_frame for what "important" means in this |
| context)''' |
| if self.is_evalframeex(): |
| return True |
| if self.is_other_python_frame(): |
| return True |
| return False |
| |
| def is_evalframeex(self): |
| '''Is this a PyEval_EvalFrameEx frame?''' |
| if self._gdbframe.name() == 'PyEval_EvalFrameEx': |
| ''' |
| I believe we also need to filter on the inline |
| struct frame_id.inline_depth, only regarding frames with |
| an inline depth of 0 as actually being this function |
| |
| So we reject those with type gdb.INLINE_FRAME |
| ''' |
| if self._gdbframe.type() == gdb.NORMAL_FRAME: |
| # We have a PyEval_EvalFrameEx frame: |
| return True |
| |
| return False |
| |
| def is_other_python_frame(self): |
| '''Is this frame worth displaying in python backtraces? |
| Examples: |
| - waiting on the GIL |
| - garbage-collecting |
| - within a CFunction |
| If it is, return a descriptive string |
| For other frames, return False |
| ''' |
| if self.is_waiting_for_gil(): |
| return 'Waiting for the GIL' |
| elif self.is_gc_collect(): |
| return 'Garbage-collecting' |
| else: |
| # Detect invocations of PyCFunction instances: |
| older = self.older() |
| if older and older._gdbframe.name() == 'PyCFunction_Call': |
| # Within that frame: |
| # "func" is the local containing the PyObject* of the |
| # PyCFunctionObject instance |
| # "f" is the same value, but cast to (PyCFunctionObject*) |
| # "self" is the (PyObject*) of the 'self' |
| try: |
| # Use the prettyprinter for the func: |
| func = older._gdbframe.read_var('func') |
| return str(func) |
| except RuntimeError: |
| return 'PyCFunction invocation (unable to read "func")' |
| |
| # This frame isn't worth reporting: |
| return False |
| |
| def is_waiting_for_gil(self): |
| '''Is this frame waiting on the GIL?''' |
| # This assumes the _POSIX_THREADS version of Python/ceval_gil.h: |
| name = self._gdbframe.name() |
| if name: |
| return name.startswith('pthread_cond_timedwait') |
| |
| def is_gc_collect(self): |
| '''Is this frame "collect" within the garbage-collector?''' |
| return self._gdbframe.name() == 'collect' |
| |
| def get_pyop(self): |
| try: |
| f = self._gdbframe.read_var('f') |
| frame = PyFrameObjectPtr.from_pyobject_ptr(f) |
| if not frame.is_optimized_out(): |
| return frame |
| # gdb is unable to get the "f" argument of PyEval_EvalFrameEx() |
| # because it was "optimized out". Try to get "f" from the frame |
| # of the caller, PyEval_EvalCodeEx(). |
| orig_frame = frame |
| caller = self._gdbframe.older() |
| if caller: |
| f = caller.read_var('f') |
| frame = PyFrameObjectPtr.from_pyobject_ptr(f) |
| if not frame.is_optimized_out(): |
| return frame |
| return orig_frame |
| except ValueError: |
| return None |
| |
| @classmethod |
| def get_selected_frame(cls): |
| _gdbframe = gdb.selected_frame() |
| if _gdbframe: |
| return Frame(_gdbframe) |
| return None |
| |
| @classmethod |
| def get_selected_python_frame(cls): |
| '''Try to obtain the Frame for the python-related code in the selected |
| frame, or None''' |
| frame = cls.get_selected_frame() |
| |
| while frame: |
| if frame.is_python_frame(): |
| return frame |
| frame = frame.older() |
| |
| # Not found: |
| return None |
| |
| @classmethod |
| def get_selected_bytecode_frame(cls): |
| '''Try to obtain the Frame for the python bytecode interpreter in the |
| selected GDB frame, or None''' |
| frame = cls.get_selected_frame() |
| |
| while frame: |
| if frame.is_evalframeex(): |
| return frame |
| frame = frame.older() |
| |
| # Not found: |
| return None |
| |
| def print_summary(self): |
| if self.is_evalframeex(): |
| pyop = self.get_pyop() |
| if pyop: |
| line = pyop.get_truncated_repr(MAX_OUTPUT_LEN) |
| write_unicode(sys.stdout, '#%i %s\n' % (self.get_index(), line)) |
| if not pyop.is_optimized_out(): |
| line = pyop.current_line() |
| if line is not None: |
| sys.stdout.write(' %s\n' % line.strip()) |
| else: |
| sys.stdout.write('#%i (unable to read python frame information)\n' % self.get_index()) |
| else: |
| info = self.is_other_python_frame() |
| if info: |
| sys.stdout.write('#%i %s\n' % (self.get_index(), info)) |
| else: |
| sys.stdout.write('#%i\n' % self.get_index()) |
| |
| def print_traceback(self): |
| if self.is_evalframeex(): |
| pyop = self.get_pyop() |
| if pyop: |
| pyop.print_traceback() |
| if not pyop.is_optimized_out(): |
| line = pyop.current_line() |
| if line is not None: |
| sys.stdout.write(' %s\n' % line.strip()) |
| else: |
| sys.stdout.write(' (unable to read python frame information)\n') |
| else: |
| info = self.is_other_python_frame() |
| if info: |
| sys.stdout.write(' %s\n' % info) |
| else: |
| sys.stdout.write(' (not a python frame)\n') |
| |
| class PyList(gdb.Command): |
| '''List the current Python source code, if any |
| |
| Use |
| py-list START |
| to list at a different line number within the python source. |
| |
| Use |
| py-list START, END |
| to list a specific range of lines within the python source. |
| ''' |
| |
| def __init__(self): |
| gdb.Command.__init__ (self, |
| "py-list", |
| gdb.COMMAND_FILES, |
| gdb.COMPLETE_NONE) |
| |
| |
| def invoke(self, args, from_tty): |
| import re |
| |
| start = None |
| end = None |
| |
| m = re.match(r'\s*(\d+)\s*', args) |
| if m: |
| start = int(m.group(0)) |
| end = start + 10 |
| |
| m = re.match(r'\s*(\d+)\s*,\s*(\d+)\s*', args) |
| if m: |
| start, end = map(int, m.groups()) |
| |
| # py-list requires an actual PyEval_EvalFrameEx frame: |
| frame = Frame.get_selected_bytecode_frame() |
| if not frame: |
| print 'Unable to locate gdb frame for python bytecode interpreter' |
| return |
| |
| pyop = frame.get_pyop() |
| if not pyop or pyop.is_optimized_out(): |
| print 'Unable to read information on python frame' |
| return |
| |
| filename = pyop.filename() |
| lineno = pyop.current_line_num() |
| |
| if start is None: |
| start = lineno - 5 |
| end = lineno + 5 |
| |
| if start<1: |
| start = 1 |
| |
| try: |
| f = open(os_fsencode(filename), 'r') |
| except IOError as err: |
| sys.stdout.write('Unable to open %s: %s\n' |
| % (filename, err)) |
| return |
| with f: |
| all_lines = f.readlines() |
| # start and end are 1-based, all_lines is 0-based; |
| # so [start-1:end] as a python slice gives us [start, end] as a |
| # closed interval |
| for i, line in enumerate(all_lines[start-1:end]): |
| linestr = str(i+start) |
| # Highlight current line: |
| if i + start == lineno: |
| linestr = '>' + linestr |
| sys.stdout.write('%4s %s' % (linestr, line)) |
| |
| |
| # ...and register the command: |
| PyList() |
| |
| def move_in_stack(move_up): |
| '''Move up or down the stack (for the py-up/py-down command)''' |
| frame = Frame.get_selected_python_frame() |
| while frame: |
| if move_up: |
| iter_frame = frame.older() |
| else: |
| iter_frame = frame.newer() |
| |
| if not iter_frame: |
| break |
| |
| if iter_frame.is_python_frame(): |
| # Result: |
| if iter_frame.select(): |
| iter_frame.print_summary() |
| return |
| |
| frame = iter_frame |
| |
| if move_up: |
| print 'Unable to find an older python frame' |
| else: |
| print 'Unable to find a newer python frame' |
| |
| class PyUp(gdb.Command): |
| 'Select and print the python stack frame that called this one (if any)' |
| def __init__(self): |
| gdb.Command.__init__ (self, |
| "py-up", |
| gdb.COMMAND_STACK, |
| gdb.COMPLETE_NONE) |
| |
| |
| def invoke(self, args, from_tty): |
| move_in_stack(move_up=True) |
| |
| class PyDown(gdb.Command): |
| 'Select and print the python stack frame called by this one (if any)' |
| def __init__(self): |
| gdb.Command.__init__ (self, |
| "py-down", |
| gdb.COMMAND_STACK, |
| gdb.COMPLETE_NONE) |
| |
| |
| def invoke(self, args, from_tty): |
| move_in_stack(move_up=False) |
| |
| # Not all builds of gdb have gdb.Frame.select |
| if hasattr(gdb.Frame, 'select'): |
| PyUp() |
| PyDown() |
| |
| class PyBacktraceFull(gdb.Command): |
| 'Display the current python frame and all the frames within its call stack (if any)' |
| def __init__(self): |
| gdb.Command.__init__ (self, |
| "py-bt-full", |
| gdb.COMMAND_STACK, |
| gdb.COMPLETE_NONE) |
| |
| |
| def invoke(self, args, from_tty): |
| frame = Frame.get_selected_python_frame() |
| while frame: |
| if frame.is_python_frame(): |
| frame.print_summary() |
| frame = frame.older() |
| |
| PyBacktraceFull() |
| |
| class PyBacktrace(gdb.Command): |
| 'Display the current python frame and all the frames within its call stack (if any)' |
| def __init__(self): |
| gdb.Command.__init__ (self, |
| "py-bt", |
| gdb.COMMAND_STACK, |
| gdb.COMPLETE_NONE) |
| |
| |
| def invoke(self, args, from_tty): |
| sys.stdout.write('Traceback (most recent call first):\n') |
| frame = Frame.get_selected_python_frame() |
| while frame: |
| if frame.is_python_frame(): |
| frame.print_traceback() |
| frame = frame.older() |
| |
| PyBacktrace() |
| |
| class PyPrint(gdb.Command): |
| 'Look up the given python variable name, and print it' |
| def __init__(self): |
| gdb.Command.__init__ (self, |
| "py-print", |
| gdb.COMMAND_DATA, |
| gdb.COMPLETE_NONE) |
| |
| |
| def invoke(self, args, from_tty): |
| name = str(args) |
| |
| frame = Frame.get_selected_python_frame() |
| if not frame: |
| print 'Unable to locate python frame' |
| return |
| |
| pyop_frame = frame.get_pyop() |
| if not pyop_frame: |
| print 'Unable to read information on python frame' |
| return |
| |
| pyop_var, scope = pyop_frame.get_var_by_name(name) |
| |
| if pyop_var: |
| print ('%s %r = %s' |
| % (scope, |
| name, |
| pyop_var.get_truncated_repr(MAX_OUTPUT_LEN))) |
| else: |
| print '%r not found' % name |
| |
| PyPrint() |
| |
| class PyLocals(gdb.Command): |
| 'Look up the given python variable name, and print it' |
| def __init__(self): |
| gdb.Command.__init__ (self, |
| "py-locals", |
| gdb.COMMAND_DATA, |
| gdb.COMPLETE_NONE) |
| |
| |
| def invoke(self, args, from_tty): |
| name = str(args) |
| |
| frame = Frame.get_selected_python_frame() |
| if not frame: |
| print 'Unable to locate python frame' |
| return |
| |
| pyop_frame = frame.get_pyop() |
| if not pyop_frame: |
| print 'Unable to read information on python frame' |
| return |
| |
| for pyop_name, pyop_value in pyop_frame.iter_locals(): |
| print ('%s = %s' |
| % (pyop_name.proxyval(set()), |
| pyop_value.get_truncated_repr(MAX_OUTPUT_LEN))) |
| |
| PyLocals() |