def export_keying_materials(connection, out_len, label, context=None):
out = bytearray(length)
out_ptr = _ffi.cast("unsigned char*", _ffi.from_buffer(out))
label_ptr = _ffi.cast("const char*", _ffi.from_buffer(label))
label_len = len(label)
if context is not None:
context_ptr = _ffi.cast("const unsigned char*",
_ffi.from_buffer(context))
context_len = len(context)
use_context = 1
else:
context_ptr = _ffi.cast("const unsigned char*", _ffi.NULL)
context_len = 0
use_context = 0
ret = _lib.SSL_export_keying_materials(connection.ssl, out_ptr, out_len,
label_ptr, label_len, context_ptr,
context_len, use_context)
if ret != 1:
raise IOError("SSL_export_keying_materials")
return out
def _reportLeaks(self, leaks, result):
def format_leak(p):
stacks = memdbg.heap[p]
# Eventually look at multiple stacks for the realloc() case. For
# now just look at the original allocation location.
(size, python_stack, c_stack) = stacks[0]
stack = traceback.format_list(python_stack)[:-1]
# c_stack looks something like this (interesting parts indicated
# with inserted arrows not part of the data):
#
# /home/exarkun/Projects/pyOpenSSL/branches/use-opentls/__pycache__/_cffi__x89095113xb9185b9b.so(+0x12cf) [0x7fe2e20582cf]
# /home/exarkun/Projects/cpython/2.7/python(PyCFunction_Call+0x8b) [0x56265a]
# /home/exarkun/Projects/cpython/2.7/python() [0x4d5f52]
# /home/exarkun/Projects/cpython/2.7/python(PyEval_EvalFrameEx+0x753b) [0x4d0e1e]
# /home/exarkun/Projects/cpython/2.7/python() [0x4d6419]
# /home/exarkun/Projects/cpython/2.7/python() [0x4d6129]
# /home/exarkun/Projects/cpython/2.7/python(PyEval_EvalFrameEx+0x753b) [0x4d0e1e]
# /home/exarkun/Projects/cpython/2.7/python(PyEval_EvalCodeEx+0x1043) [0x4d3726]
# /home/exarkun/Projects/cpython/2.7/python() [0x55fd51]
# /home/exarkun/Projects/cpython/2.7/python(PyObject_Call+0x7e) [0x420ee6]
# /home/exarkun/Projects/cpython/2.7/python(PyEval_CallObjectWithKeywords+0x158) [0x4d56ec]
# /home/exarkun/.local/lib/python2.7/site-packages/cffi-0.5-py2.7-linux-x86_64.egg/_cffi_backend.so(+0xe96e) [0x7fe2e38be96e]
# /usr/lib/x86_64-linux-gnu/libffi.so.6(ffi_closure_unix64_inner+0x1b9) [0x7fe2e36ad819]
# /usr/lib/x86_64-linux-gnu/libffi.so.6(ffi_closure_unix64+0x46) [0x7fe2e36adb7c]
# /lib/x86_64-linux-gnu/libcrypto.so.1.0.0(CRYPTO_malloc+0x64) [0x7fe2e1cef784] <------ end interesting
# /lib/x86_64-linux-gnu/libcrypto.so.1.0.0(lh_insert+0x16b) [0x7fe2e1d6a24b] .
# /lib/x86_64-linux-gnu/libcrypto.so.1.0.0(+0x61c18) [0x7fe2e1cf0c18] .
# /lib/x86_64-linux-gnu/libcrypto.so.1.0.0(+0x625ec) [0x7fe2e1cf15ec] .
# /lib/x86_64-linux-gnu/libcrypto.so.1.0.0(DSA_new_method+0xe6) [0x7fe2e1d524d6] .
# /lib/x86_64-linux-gnu/libcrypto.so.1.0.0(DSA_generate_parameters+0x3a) [0x7fe2e1d5364a] <------ begin interesting
# /home/exarkun/Projects/opentls/trunk/tls/c/__pycache__/_cffi__x305d4698xb539baaa.so(+0x1f397) [0x7fe2df84d397]
# /home/exarkun/Projects/cpython/2.7/python(PyCFunction_Call+0x8b) [0x56265a]
# /home/exarkun/Projects/cpython/2.7/python() [0x4d5f52]
# /home/exarkun/Projects/cpython/2.7/python(PyEval_EvalFrameEx+0x753b) [0x4d0e1e]
# /home/exarkun/Projects/cpython/2.7/python() [0x4d6419]
# ...
#
# Notice the stack is upside down compared to a Python traceback.
# Identify the start and end of interesting bits and stuff it into the stack we report.
saved = list(c_stack)
# Figure the first interesting frame will be after a the cffi-compiled module
while c_stack and '/__pycache__/_cffi__' not in c_stack[-1]:
c_stack.pop()
# Figure the last interesting frame will always be CRYPTO_malloc,
# since that's where we hooked in to things.
while c_stack and 'CRYPTO_malloc' not in c_stack[
0] and 'CRYPTO_realloc' not in c_stack[0]:
c_stack.pop(0)
if c_stack:
c_stack.reverse()
else:
c_stack = saved[::-1]
stack.extend([frame + "\n" for frame in c_stack])
stack.insert(0, "Leaked (%s) at:\n")
return "".join(stack)
if leaks:
unique_leaks = {}
for p in leaks:
size = memdbg.heap[p][-1][0]
new_leak = format_leak(p)
if new_leak not in unique_leaks:
unique_leaks[new_leak] = [(size, p)]
else:
unique_leaks[new_leak].append((size, p))
memdbg.free(p)
for (stack, allocs) in unique_leaks.iteritems():
allocs_accum = []
for (size, pointer) in allocs:
addr = int(ffi.cast('uintptr_t', pointer))
allocs_accum.append("%d@0x%x" % (size, addr))
allocs_report = ", ".join(sorted(allocs_accum))
result.addError(
self, (None, Exception(stack % (allocs_report, )), None))
def _reportLeaks(self, leaks, result):
def format_leak(p):
"""
c_stack looks something like this (interesting parts indicated
with inserted arrows not part of the data):
cpython/2.7/python(PyCFunction_Call+0x8b) [0x56265a]
cpython/2.7/python() [0x4d5f52]
cpython/2.7/python(PyEval_EvalFrameEx+0x753b) [0x4d0e1e]
cpython/2.7/python() [0x4d6419]
cpython/2.7/python() [0x4d6129]
cpython/2.7/python(PyEval_EvalFrameEx+0x753b) [0x4d0e1e]
cpython/2.7/python(PyEval_EvalCodeEx+0x1043) [0x4d3726]
cpython/2.7/python() [0x55fd51]
cpython/2.7/python(PyObject_Call+0x7e) [0x420ee6]
cpython/2.7/python(PyEval_CallObjectWithKeywords+0x158) [0x4d56ec]
_cffi_backend.so(+0xe96e) [0x7fe2e38be96e]
libffi.so.6(ffi_closure_unix64_inner+0x1b9) [0x7fe2e36ad819]
libffi.so.6(ffi_closure_unix64+0x46) [0x7fe2e36adb7c]
|----- end interesting
v
libcrypto.so.1.0.0(CRYPTO_malloc+0x64) [0x7fe2e1cef784]
libcrypto.so.1.0.0(lh_insert+0x16b) [0x7fe2e1d6a24b]
libcrypto.so.1.0.0(+0x61c18) [0x7fe2e1cf0c18]
libcrypto.so.1.0.0(+0x625ec) [0x7fe2e1cf15ec]
libcrypto.so.1.0.0(DSA_new_method+0xe6) [0x7fe2e1d524d6]
libcrypto.so.1.0.0(DSA_generate_parameters+0x3a) [0x7fe2e1d5364a]
^
|----- begin interesting
_cffi__x305d4698xb539baaa.so(+0x1f397) [0x7fe2df84d397]
cpython/2.7/python(PyCFunction_Call+0x8b) [0x56265a]
cpython/2.7/python() [0x4d5f52]
cpython/2.7/python(PyEval_EvalFrameEx+0x753b) [0x4d0e1e]
cpython/2.7/python() [0x4d6419]
...
Notice the stack is upside down compared to a Python traceback.
Identify the start and end of interesting bits and stuff it into
the stack we report.
"""
stacks = memdbg.heap[p]
# Eventually look at multiple stacks for the realloc() case. For
# now just look at the original allocation location.
(size, python_stack, c_stack) = stacks[0]
stack = traceback.format_list(python_stack)[:-1]
saved = list(c_stack)
# Figure the first interesting frame will be after a the
# cffi-compiled module
while c_stack and '/__pycache__/_cffi__' not in c_stack[-1]:
c_stack.pop()
# Figure the last interesting frame will always be CRYPTO_malloc,
# since that's where we hooked in to things.
while (
c_stack and 'CRYPTO_malloc' not in c_stack[0] and
'CRYPTO_realloc' not in c_stack[0]
):
c_stack.pop(0)
if c_stack:
c_stack.reverse()
else:
c_stack = saved[::-1]
stack.extend([frame + "\n" for frame in c_stack])
stack.insert(0, "Leaked (%s) at:\n")
return "".join(stack)
if leaks:
unique_leaks = {}
for p in leaks:
size = memdbg.heap[p][-1][0]
new_leak = format_leak(p)
if new_leak not in unique_leaks:
unique_leaks[new_leak] = [(size, p)]
else:
unique_leaks[new_leak].append((size, p))
memdbg.free(p)
for (stack, allocs) in unique_leaks.iteritems():
allocs_accum = []
for (size, pointer) in allocs:
addr = int(ffi.cast('uintptr_t', pointer))
allocs_accum.append("%d@0x%x" % (size, addr))
allocs_report = ", ".join(sorted(allocs_accum))
result.addError(
self,
(None, Exception(stack % (allocs_report,)), None))