In gdb terminology “unwinding” is the process of finding the previous frame (that is, caller's) from the current one. An unwinder has three methods. The first one checks if it can handle given frame (“sniff” it). For the frames it can sniff an unwinder provides two additional methods: it can return frame's ID, and it can fetch registers from the previous frame. A running gdb mantains a list of the unwinders and calls each unwinder's sniffer in turn until it finds the one that recognizes the current frame. There is an API to register an unwinder.
The unwinders that come with gdb handle standard frames. However, mixed language applications (for example, an application running Java Virtual Machine) sometimes use frame layouts that cannot be handled by the gdb unwinders. You can write Python code that can handle such custom frames.
You implement a frame unwinder in Python as a class with which has two
attributes, name and enabled, with obvious meanings, and
a single method __call__, which examines a given frame and
returns an object (an instance of gdb.UnwindInfo class)
describing it. If an unwinder does not recognize a frame, it should
return None. The code in gdb that enables writing
unwinders in Python uses this object to return frame's ID and previous
frame registers when gdb core asks for them.
An unwinder should do as little work as possible. Some otherwise innocuous operations can cause problems (even crashes, as this code is not not well-hardened yet). For example, making an inferior call from an unwinder is unadvisable, as an inferior call will reset gdb's stack unwinding process, potentially causing re-entrant unwinding.
An object passed to an unwinder (a gdb.PendingFrame instance)
provides a method to read frame's registers:
This method returns the contents of the register reg in the frame as a
gdb.Valueobject. reg can be either a register number or a register name; the values are platform-specific. They are usually found in the corresponding platform-tdep.h file in the gdb source tree. If reg does not name a register for the current architecture, this method will throw an exception.Note that this method will always return a
gdb.Valuefor a valid register name. This does not mean that the value will be valid. For example, you may request a register that an earlier unwinder could not unwind—the value will be unavailable. Instead, thegdb.Valuereturned from this method will be lazy; that is, its underlying bits will not be fetched until it is first used. So, attempting to use such a value will cause an exception at the point of use.The type of the returned
gdb.Valuedepends on the register and the architecture. It is common for registers to have a scalar type, likelong long; but many other types are possible, such as pointer, pointer-to-function, floating point or vector types.
It also provides a factory method to create a gdb.UnwindInfo
instance to be returned to gdb:
Returns a new
gdb.UnwindInfoinstance identified by given frame_id. The argument is used to build gdb's frame ID using one of functions provided by gdb. frame_id's attributes determine which function will be used, as follows:
sp, pc- The frame is identified by the given stack address and PC. The stack address must be chosen so that it is constant throughout the lifetime of the frame, so a typical choice is the value of the stack pointer at the start of the function—in the DWARF standard, this would be the “Call Frame Address”.
This is the most common case by far. The other cases are documented for completeness but are only useful in specialized situations.
sp, pc, special- The frame is identified by the stack address, the PC, and a “special” address. The special address is used on architectures that can have frames that do not change the stack, but which are still distinct, for example the IA-64, which has a second stack for registers. Both sp and special must be constant throughout the lifetime of the frame.
sp- The frame is identified by the stack address only. Any other stack frame with a matching sp will be considered to match this frame. Inside gdb, this is called a “wild frame”. You will never need this.
Each attribute value should be an instance of
gdb.Value.
Use PendingFrame.create_unwind_info method described above to
create a gdb.UnwindInfo instance. Use the following method to
specify caller registers that have been saved in this frame:
reg identifies the register. It can be a number or a name, just as for the
PendingFrame.read_registermethod above. value is a register value (agdb.Valueobject).
gdb comes with the module containing the base Unwinder
class. Derive your unwinder class from it and structure the code as
follows:
from gdb.unwinders import Unwinder
class FrameId(object):
def __init__(self, sp, pc):
self.sp = sp
self.pc = pc
class MyUnwinder(Unwinder):
def __init__(....):
supe(MyUnwinder, self).__init___(<expects unwinder name argument>)
def __call__(pending_frame):
if not <we recognize frame>:
return None
# Create UnwindInfo. Usually the frame is identified by the stack
# pointer and the program counter.
sp = pending_frame.read_register(<SP number>)
pc = pending_frame.read_register(<PC number>)
unwind_info = pending_frame.create_unwind_info(FrameId(sp, pc))
# Find the values of the registers in the caller's frame and
# save them in the result:
unwind_info.add_saved_register(<register>, <value>)
....
# Return the result:
return unwind_info
An object file, a program space, and the gdb proper can have unwinders registered with it.
The gdb.unwinders module provides the function to register a
unwinder:
locus is specifies an object file or a program space to which unwinder is added. Passing
Noneorgdbadds unwinder to the gdb's global unwinder list. The newly added unwinder will be called before any other unwinder from the same locus. Two unwinders in the same locus cannot have the same name. An attempt to add a unwinder with already existing name raises an exception unless replace isTrue, in which case the old unwinder is deleted.
gdb first calls the unwinders from all the object files in no particular order, then the unwinders from the current program space, and finally the unwinders from gdb.