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GenProg: Evolutionary Program Repair

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This README describes the use of GenProg v4.0, a.k.a. "repair." Previous versions exist and are described elsewhere. These instructions are very similar to those associated with previous versions of repair. Command line options should work as they did previously; older READMEs from previous releases contain detailed explanations of the relevant options.

These instructions primarily address the repair of C programs using the standard genetic algorithm. Many of these instructions translate directly to different language front-ends, however, so you should be able to figure out ASM/ELF level repair pretty trivially if you understand C-level repair. For questions about ASM repair, email Jeremy Lacomis ([email protected]) (or file an issue).

These instructions include mention of how to compile for shader repair, but the authors of this README unfortunately do not know how to run those experiments. Email Wes for pointers to who to ask ([email protected]).

Refer to the README associated with the benchmarks for information and examples regarding the use of modify/repair on particular examples.

Caveat 0: Read the entirety of this README before diving into a particular benchmark because we do not repeat instructions applying to all experiments in the benchmark-specific READMEs.

Caveat 1: GenProg operates on pre-processed code, meaning that the generated patches are sometimes non-obvious. Compare pre-processed code to original code to get a handle on what is going on.

Caveat 2: These instructions are not comprehensive, for which we apologize. repair has a huge number of command-line options and implemented behaviors. We've tried to include enough info to get you started.

  1. Basics

This code is largely written in OCaml with some C and bash scripts; it assumes various standard utilities. This code was successfully built using 4.12.0. It definitely won't compile with any version pre-4.06.0.

We have been able to build this in general linux environments, including OS X. It was once the case that you needed to ensure sh is symlinked to bash rather than dash (the default on Ubuntu); as of 2017- we're not sure this matters any more. But if you run into trouble, try that.

  1. Building

  1. OCaml

    We use opam to install and manage OCaml. This release assumes you are past 4.05.0 (we have most recently built it successfully using 4.12.0). Follow opam instructions to make and initialize a suitable ocaml installation switch.

  2. CIL

    We use CIL to parse C and manipulate ASTs. CIL is abandonware; the last version appears to be 1.7.3. It does not build after OCaml 4.05, and opam will complain if you try to install the vanilla version.

    We have forked CIL and made minor updates to (a) get it to build post 4.05, and (b) compute pointer analysis the way we want it to (addressing the strong-update problem) in repair. We recommend:

     opam install num
     opam pin cil https://github.com/squareslab/cil.git
    

    (cil depends on num)

    If you want to fork/install cil locally, you're of course welcome to do that. Your life will be easier if ocamlfind can find it.

    The included cil-cg.tar.gz tarball is a version of CIL with extensions to support the parsing of OpenGL shaders. We don't believe it will work any more, but if you get it to build, use the CIL environment variable referenced in the Makefile to point to the installation, export USE_PELLACINI=true, and re-make repair to use it.

  3. Building repair

    make, either in this directory or the genprog-code/src directory should do the trick.

    We like to go to src/ and do: ./repair --help

    To make sure it worked.

    The build process will produce several artifacts:

    • repair: the main GenProg repair program
    • nhtserver: the server for the networked hash table (optional)
    • distserver: the server for the distributed GA search (optional)
    • dll_elf_stubs.so, lib_elf_stubs.a, libelf.o: utilities for elf manipulation

    Additional build targets are:

    • doc: requires ocamldoc, generates html documentation on the API (useful if you want to understand or extend the code) in doc/
    • testsuite: runs the tests in test/. The testsuite is a work in progress and thus I make no guarantees about its functionality; this documentation will be updated as it is.
  4. Docker

    The following command should work:

     docker build -t squareslab/genprog .
    
  5. General "repair" roadmap


I will first outline the default (virtually all behaviors may be overridden) behavior of repair as run fresh on a new C program, assuming all goes well:

  1. sanity check: repair will compile the program and run it on all positive and negative test cases to check that the behavior is as expected (i.e., compiles, passes the positive test cases, fails the negative test cases).

  2. If no path files are found and no other localization strategy is specified, repair will instrument the program for coverage information and compile and run the instrumented program on the test cases to generate positive and negative paths for localization.

  3. Repair then generates an initial population and computes the fitness of all variants by running them against all positive and negative test cases.

  4. It then iterates until either the number of generations exceeds the specified/default limit or until a repair is found.

  5. If a repair is found, the source code for that variant will be printed to disk either in repair/ or repair.c (depending on whether the source code is one file or many). If minimization is specified (not by default), the repair will then be minimized, and related files will be output Minimization_Files/.

repair produces the following artifacts by default:

  • program.cache: caches the representation with localization information. If a cache is found in the directory, and repair is not told otherwise, it will load the repair from this cache. By default this skips the localization/coverage step and the sanity step.

  • repair.cache: the test cache

  • coverage.path.pos and coverage.path.neg: the path files used for localization.

  • repair.debug.N where N is the seed used for the random-number generator. All output from repair is sent both to standard out and repair.debug.N

If the caches and/or paths are found on a run on the program, they will be used. You can turn off this loading behavior with --no-rep-cache and/or --no-test-cache and/or --regen-paths (if you're using path-based localization but want to regenerate them). You can also specify alternative names for the repair cache file using --rep-cache X.

Thus, to run repair on any program, at the very least, you will need:

You might also want:

  • localization info: there are several options here; check the output of ./repair --help, in particular near --fault-scheme and --fix-scheme for options and how to use them.

I highly recommend that you stop between acquiring the program source and the compile and test scripts and make sure that you can run them manually first. Check the permissions on those scripts in particular as they must be executable.

The test directory also contains gcd-test/, an example repair scenario for the gcd program; you may find it useful as a reference.

3.1. Input program

Relevant command-line options:

  • --program X (required)
  • --rep X (optional but encouraged)
  • --prefix X (necessary for multi-file repair)

You need the source code of a program with a deterministic bug that you can expose with test cases (one or many).

  1. Preprocessing

    repair can operate on either a single C file or multiple C files, but they will need to be preprocessed. There are several possibilities for where to get such preprocessed code:

    1. If you're running a scenario in a VM as downloaded from the genprog website, the preprocessed code is included and does not need to be regenerated. The other benchmarks from previous papers include in their READMEs the mechanisms we used to generate the preprocessed source; you will almost certainly need to regenerate them as preprocessed source tends to be machine-specific.

    2. The original source code sometimes suffices (only true for the smallest of programs, such as GCD).

    3. A single source file can often be preprocessed by passing -E to gcc:

       gcc -E uniq.c > uniq.i
      

    (uniq.i is the preprocessed source version of uniq.c)

    1. If a benchmark involves modifying one file or module of a larger program (e.g., openldap), the preprocessed source can be obtained by hijacking the benchmark's original build process. Build the original benchmark source, search the compiler output for the line that compiles the file you need, copy it, cd into the appropriate directory, add --save-temps as a flag to gcc in the line, producing foo.i in that directory, where foo.i is your input source code.

    2. If a benchmark consists of more than one source file and repair is to be run on the entire (combined) program (e.g., nullhttpd), use CIL to "combine" the source code into one file (turning all the nullhttpd source code into, for example, httpd_comb.c). To do this, use cilly instead of gcc. For nullhttpd:

       cd nullhttpd-0.5.0/src
       make CC="/home/weimer/src/cil/bin/cilly --merge --keepmerged"
      

      This will generate httpd_comb.c in nullhttpd-0.5.0/httpd/bin

  2. Specifying the program

    The program is specified with --program. By default, repair will try to figure out what kind of program you're trying to repair, be it C, asm, etc, based on the argument passed to --program. You can be explicit by adding the --rep file_type argument; this switch provides a number of options even within one language family (cilpatch vs cilast, for example; patch is the default). The --rep argument is important if you are using multiple C files because repair uses the extension of the argument passed to --program to automatically guess the type of program under repair, and it might get confused if given a .txt absent further instructions.

    In the single-file case, you specify the source code with the --program command line option.

    In the multi-file case: put all preprocessed files in one directory. List all files, one per line, in a text file; do not include the top-level directory in which they are placed. Specify --prefix top-level-directory-name and --program list_of_files.txt

    For example, if you have a.i, b.i, and c.i, put them all in one directory:

     > ls preprocessed/ 
     a.i 
     b.i 
     c.i
    

    Create a text file, e.g., source.txt:

     > cat source.txt
     a.i
     b.i
     c.i
    

    To repair, include the following flags:

     --program source.txt
     --rep c
     --prefix preprocessed
    

3.2 Compilation

--compiler compiler-name
--compiler-command "compilation command"

compilation is governed by the compiler command and the specified compiler. The default compiler command is:

"__COMPILER_NAME__ -o __EXE_NAME__ __SOURCE_NAME__ __COMPILER_OPTIONS__ \ 
    2>/dev/null >/dev/null"

where each of the __KEYWORDS__ is replaced at each compilation with the associated concrete instance. __COMPILER_NAME__ is "gcc" by default. You can change either just the compiler name (--compiler) or the entire command (--compiler-command) to be whatever you want, bearing in mind that the key words in the default are the only ones currently available. Feel free to add your own by modifying the source code if you want, though we have yet to need to. Anything more complex than gcc -o foo foo.c can usually be accomplished with a shell script; examples appear in the ICSE 2012 tarballs. But, for example, if you have a compile.sh that you've written to do anything more complicated than gcc -o foo foo.c, you might say:

--compiler "./compile.sh"
--compiler-command "__COMPILER_NAME__ __SOURCE_NAME__"

Or similar.

3.3 Testing

  1. Scripts

    Relevant command-line options:

     --test-script script-name
     --test-command "test command"
    

    Testing is governed by a similar mechanism. The default test script is ./test.sh

    The default test command is:

     "__TEST_SCRIPT__ __EXE_NAME__ __TEST_NAME__ __PORT__ __SOURCE_NAME__ \
         __FITNESS_FILE__ 1>/dev/null 2>/dev/null"
    

    It may be modified as with the compiler command above, with slightly different key words. It will almost certainly need at least __TEST_NAME__. The test names are "p#" and "n#" where # is the number of the test case and p is for positive test cases and n is for negative test cases. You may also specify s, for "single test case" which should write the fitness as a (potentially list of) floating point number(s) to the fitness file. This is less common and used primarily for graphics-shader based experiments.

    Suggestion: your test scripts should likely include commands like ulimit or another utility to limit runtime and memory consumption for your program. We have a small C utility called limit that we use often use for the purpose of avoiding infinite loops, but any similar mechanism will work as well.

  2. Other concerns

     --pos-tests N
     --neg-tests N
     --fitness-in-parallel N 
     --sample X
    

    --pos-tests and --neg-tests specify the number of positive and negative tests respectively.

    If --fitness-in-parallel is > 1, more than one test case will be run in parallel.

    --sample X sets the sample size of the positive test cases. < 1.0 (the default) uses sampling.

    There are a number of other options relevant here (--samp-strat, for example); consult ./repair --help for more.

  3. Other command-line options


repair has a large number of other command-line options controlling setup, GA parameters, search type, minimization...the works. You may specify them either at the command line or using a config file (or both! They are parsed in order, so the later ones take precedence if there are repeats). I highly recommend downloading the tarballs of the experimental setup for the ICSE 2012 benchmark set and consulting the configuration files associated with each scenario to get an idea of what they are, or calling ./repair --help I have tried to make their descriptions somewhat indicative, and thus I omit additional instructions here for the sake of brevity.

I would recommend at least using --seed X for each run, which makes everything neater.

CAVEAT: as of 5/10/12, I have not yet regenerated the configuration files for those benchmarks to make use of the refactored version of the command line options. Thus, the scenario tarball config files contain a number of deprecated options. HOWEVER: repair handles a large number of deprecated options, so you can still run repair on those scenarios, just be mindful that not all of those options are currently available in those exact forms.

  1. Misc observations

Permissions are funny. Sometimes they are set so that sh test.sh executes but ./test-good.sh gives a permission denied. Check this, and then use chmod.

Use the --seed flag to specify the random seed for reproducible runs.

If a repair is found, the code output to repair.c is not the minimized repair. Minimization can be performed on the initial repair by passing --minimization in the config file.

The --continue flag bypasses modify's default behavior to quit when it finds the first fixed variant.