Dg is a library which implements dependence graphs for programs. It contains a set of generic templates that can be specialized to user's needs. Dg can be used for different analyses, optimizations or program slicing (we currently use it for the last one in our tool called Symbiotic: https://github.com/staticafi/symbiotic). As a part of dg, you can find pointer analyses, reaching definitions analysis and a static slicer for LLVM.
Whole project is under developement and lacks documentation for now, so in the case of need, contact us by an e-mail (below).
We have implemented a dependence graph for LLVM and a static slicer for LLVM.
LLVM DependenceGraph needs LLVM 3.4 or higher. Clone the repository to your machine:
git clone https://github.com/mchalupa/dg
cd dg
Once you have the project cloned, you need to configure it. Fully manual configuration would look like this:
cmake -DLLVM_SRC_PATH=/path/to/src -DLLVM_BUILD_PATH=/path/to/build -DLLVM_DIR=path/to/llvm/share/llvm/cmake .
LLVM_DIR is an environment variable used by LLVM to find cmake config files (it points to the build or install directory), LLVM_SRC_DIR is a variable that tells cmake where to look for llvm's sources and it is used to override include paths. The same holds for LLVM_BUILD_PATH that is used to override library paths. Usually, you don't need to specify all these variables. When LLVM is installed on your system in standard paths, the configuration should look just like:
cmake .
If there is any collision (i.e. there are more versions of LLVM installed), you may need to define the LLVM_DIR variable to point to the directory where are the config files of the desired version ($PREFIX/share/llvm/cmake or $PREFIX/lib/cmake/llvm/ for newer versions). If you have LLVM compiled from sources, but not installed anywhere, you may need to use LLVM_SRC_PATH and LLVM_BUILD_PATH variables too. For the last case, suppose you have LLVM built in /home/user/llvm-build from sources in /home/user/llvm-src. Then the following configuration should work:
cmake -DLLVM_SRC_PATH=/home/user/llvm-src -DLLVM_BUILD_PATH=/home/user/llvm-build -DLLVM_DIR=/home/user/llvm-build/share/llvm/cmake .
After configuring the project, usual make takes place:
make -j4
You can run tests with make check
or make test
. To change the pointer analysis used while testing,
you can export DG_TESTS_PTA
variable before running tests and set it to one of fi
, fs
or old
.
The ompiled llvm-slicer
can be found in the tools
subdirectory. First, you need to compile your
program into LLVM IR (make sure you are using the correct version of LLVM binaries if you have more of them):
clang -c -emit-llvm source.c -o bitecode.bc
If the program is split into more source files (exactly one of them must contain main),
you must compile all of them separately (as above) and then link the bitcodes together using llvm-link
:
llvm-link bitecode1.bc bitecode2.bc ... -o bitecode.bc
Now you're ready to slice the program:
./llvm-slicer -c slicing_criterion bitecode.bc
The slicing_criterion
is a call-site of some function or ret
to slice
with respect to the return value of the main function. You can provide a comma-separated list of
slicing criterions, e.g.: -c crit1,crit2,crit3
To export the dependence graph to .dot file, use -dump-dg
switch with llvm-slicer
or a stand-alone tool
llvm-dg-dump
:
./llvm-dg-dump bitecode.bc > file.dot
You can highligh nodes from the dependence graph that will be in the slice using -mark
switch:
./llvm-dg-dump -mark slicing_criterion bitecode.bc > file.dot
When using -dump-dg
with llvm-slicer
, the nodes should be already highlighted.
Also a .dot file with the sliced dependence graph is generated (similar behviour
can be achieved with llvm-dg-dump
using the -slice
switch).
In the tools/
directory, there are few scripts for convenient manipulation
with sliced bitecode. First is a sliced-diff.sh
. This script takes file and shows
differences after slicing. It uses meld
or kompare
or just diff
program
to display the results (the first that is available on the system, in this order)
./llvm-slicer -c crit code.bc
./slicer-diff.sh code.bc
Another script is a wrapper around the llvm-dg-dump
. It uses xdot
or evince
or okular
(or xdg-open
).
It takes exactly the same arguments as the llvm-dg-dump
:
./llvmdg-show -mark crit code.bc
If the dependence graph is too big to be displayed using .dot files, you can debug the slice right from
the LLVM. Just pass -annotate
option to the llvm-slicer
and it will store readable annotated LLVM in file-debug.ll
(where file.bc
is the name of file being sliced). There are more options (try llvm-slicer -help
for all of them),
but the most interesting is probably the -annotate slicer
:
./llvm-slicer -c crit -annotate slicer code.bc
The content of code-debug.ll will look like this:
; <label>:25 ; preds = %20
; x call void @llvm.dbg.value(metadata !{i32* %i}, i64 0, metadata !151), !dbg !164
%26 = load i32* %i, align 4, !dbg !164
%27 = add nsw i32 %26, 1, !dbg !164
; x call void @llvm.dbg.value(metadata !{i32 %27}, i64 0, metadata !151), !dbg !164
store i32 %27, i32* %i, align 4, !dbg !164
; x call void @llvm.dbg.value(metadata !{i32* %j}, i64 0, metadata !153), !dbg !161
; x %28 = load i32* %j, align 4, !dbg !161
; x %29 = add nsw i32 %28, 1, !dbg !161
; x call void @llvm.dbg.value(metadata !{i32 %29}, i64 0, metadata !153), !dbg !161
; x br label %20, !dbg !165
.critedge: ; preds = %20
; x call void @llvm.dbg.value(metadata !{i32* %j}, i64 0, metadata !153), !dbg !166
; x %30 = load i32* %j, align 4, !dbg !166
; x %31 = icmp sgt i32 %30, 99, !dbg !166
; x br i1 %31, label %19, label %32, !dbg !166
Other interesting debugging options are ptr
, rd
, dd
, cd
, postdom
to annotate points-to information,
reaching definitions, data dependences, control dependences or post-dominator information.
You can provide comma-separated list of more options (-annotate cd,slice,dd
)
We can try slice for example this program (with respect to the assertion):
#include <assert.h>
#include <stdio.h>
long int fact(int x)
{
long int r = x;
while (--x >=2)
r *= x;
return r;
}
int main(void)
{
int a, b, c = 7;
while (scanf("%d", &a) > 0) {
assert(a > 0);
printf("fact: %lu\n", fact(a));
}
return 0;
}
Let's say the program is stored in a file fact.c
. We translate it into LLVM bitcode and then slice:
$ cd tools
$ clang -c -emit-llvm fact.c -o fact.bc
$ ./llvm-slicer -c __assert_fail fact.bc
The output is in fact.sliced, we can look at the result using llvm-dis
or sliced-diff.sh
script:
; Function Attrs: nounwind uwtable
define i32 @main() #0 {
%a = alloca i32, align 4
br label %1
; <label>:1 ; preds = %4, %0
%2 = call i32 (i8*, ...) @__isoc99_scanf(i8* getelementptr inbounds ([3 x i8], [3 x i8]* @.str, i32 0, i32 0), i32* %a)
%3 = icmp sgt i32 %2, 0
br i1 %3, label %4, label %safe_return
; <label>:4 ; preds = %1
%5 = load i32, i32* %a, align 4
%6 = icmp sgt i32 %5, 0
br i1 %6, label %1, label %7
; <label>:7 ; preds = %4
call void @__assert_fail(i8* getelementptr inbounds ([6 x i8], [6 x i8]* @.str1, i32 0, i32 0), ... [truncated])
unreachable
safe_return: ; preds = %1
ret i32 0
}
To get this output conveniently, you can use:
./sliced-diff.sh fact.bc
The tools subdirectory contains a set of useful programs for debugging
and playing with the llvm bitcode. Except for the llvm-slicer
you can find there:
llvm-dg-dump
- Dump the dependence graph for given program to graphviz format (to stdout)llvmdg-show
- wrapper for llvm-dg-dump that displays the graph as pdfllvm-ps-dump
- dump pointer subgraph and results of the points-to analysis to stdoutps-show
- wrapper for llvm-ps-dump that prints the PS in grapviz to pdfllvm-rd-dump
- display reaching definitions in llvm-bitcoderd-show
- wrapper for llvm-rd-dumpllvm-to-source
- find lines from the source code that are in given filellvm-to-source.py
- wrapper around llvm-to-source that gives an HTML output
All these programs take as an input llvm bitcode, for example:
./ps-show code.bc
will show the pointer state subgraph for code.bc and the results of points-to analysis.
Some useful switches for all programs are -pta fs
and -pta fi
that switch between flow-sensitive
and flow-insensitive points-to analysis within all these programs that use points-to analysis.
You can find more information about dg in http://is.muni.cz/th/396236/fi_m/thesis.pdf or you can write e-mails to: [email protected] [email protected]