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klp-ccp - Preliminary documentation

Introduction

klp-ccp aims at automating source based Linux kernel live patch creation. It's main purpose is to create a minimal, self-contained source code file containing all functions marked as "patched" from the original input sources.

klp-ccp has no notion of "diffs" yet, so users would run klp-ccp either on patched kernel sources or (preferred) on the unpatched sources and apply the diff in question manually afterwards. Implementing support for working directly with diffs is a planned feature though.

Warning: There are known issues, see the section at the end of this file.

The main motivation for making the sources public at this point is to allow attendees of the Live Patching MC at the upcoming Linux Plumbers Conference 2019 to get an idea of klp-ccp's current capabilities and its intended usage.

Building

If on a desktop machine with about 8GB of RAM, close your browser and don't use -j. You have been warned.

A C++ compiler with C++11 support is needed. A reasonably recent GCC or clang will do. If you pulled from git, GNU bison 3.0 (tested: 3.0.4) will be required for the autogeneration of the parser code. Anything before that won't work, because there had been some incompatible changes.

To build klp-ccp, run the common

./configure
make
make check # optional

# make install not needed

sequence.

Overview on the general approach

klp-ccp proceeds in several steps to create the live patch from the input kernel source file:

  1. The input source gets preprocessed. In the course of doing so, all information needed for restoring macro invocations and header inclusions in the final step gets recorded.
  2. The output from the preprocessor is parsed to create an internal representation of the AST.
  3. The AST is evaluted w.r.t types and constant expressions.
  4. Starting from the set of functions marked as patched, a closure is built. In the course of doing so, externalization decisions from the user policy (c.f. below) are taken into account.
  5. Patched, externalized and rewritten function's symbols are modified as determined by the user policy. Same for externalized objects.
  6. Header files eligible for inclusion from the live patch (c.f. below) are checked for conflicting declarations and/or definitions and marked as non-eligible if any are found.
  7. Type dependencies from the live patch closure get resolved recursively. Eligible header files providing any needed declaration or definition get selected for inclusion from the resulting live patch.
  8. An internal representation of the resulting live patch source code is prepared and passed to the macro depreprocessor.
  9. The macro depreprocessor determines the set of retainable macro invocations as well as the set of #defines and #undefs to get emitted into the resulting live patch's source code.
  10. The depreprocessor writes the output file.

Invocation

Usage: klp-ccp OPTIONS -- ORIGINAL COMPILER COMMAND LINE

where ORIGINAL COMPILER COMMAND LINE denotes the full compiler invocation as used when building the input source file in question for the live patching target, but with the leading compiler program name stripped. Currently, klp-ccp uses this only for extracting preprocessor options, but in the future it might warn on options affecting code generation like -fpack-struct and the like.

Options:

  • --compiler=ARCH-COMPILER-VERSION: specification of the compiler which had been used for the live patch target's compilation. Affects mostly the predefined macros, but also type evaluation (sizeof etc.). Currently, only "x86_64" is supported for ARCH and "gcc" for COMPILER. Example: --compiler=x86_64-gcc-4.8.5.
  • --outfile=FILE: the file to write the result to.
  • --patched-functions=LIST: comma separated list of functions to consider as "patched".
  • --python-policy=POLICY-IMPL-CLASS: the controlling user policy, c.f. below.

User policy

Even though many decisions need to be made in the course of live patch creation, like about which headers includes may be retained in the result, what and how to externalize, how to rename symbols and so on, klp-ccp does not implement any of such policy in itself by design. Instead, it is expected that the user implements a controlling policy to be queried by klp-ccp in Python, by implementing the abstract base class ("ABC") ccp.LpCreationPolicyAbc and specifes its (fully qualified) name on the klp-ccp command line by means of the --python-policy=POLICY-IMPL-CLASS option. The environment variable $KLP_CCP_PYTHONPOLICY_PATH can be set to extend the search path for such policies, in analogy to the well-known $PYTHONPATH.

For an example of an ccp.LpCreationPolicyAbc refer to the toy policies used for running the testcases, implemented in testsuite/lib/ccp-toy-policy/, or to a real one located in examples/policies/suse/.

Known issues and limitations

  • klp-ccp is largely untested
  • klp-cpp hasn't support for directly operating on diffs yet.
  • You'll notice that a lot of CONFIG_ defines get emitted into the resulting live patch source. That's because klp-ccp would currently pull in headers only if some declaration is needed from them -- something which is clearly not the case with include/generated/autoconf.h. This behaviour might change in the future for headers containing nothing but preprocessor directives and/or pre-includes.
  • Support for GCC's vector_size attribute is missing.
  • A large number of machine specific predefined macros like __PCLMUL__, __MMX__, etc. aren't provided by klp-ccp yet.
  • ...?