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A Concurrent WLLVM in Go
TL; DR: A drop-in replacement for wllvm, that builds the bitcode in parallel, and is faster. A comparison between the two tools can be gleaned from building the Linux kernel.
Quick Start Comparison Table
| wllvm command/env variable | gllvm command/env variable |
|---|---|
| wllvm | gclang |
| wllvm++ | gclang++ |
| extract-bc | get-bc |
| wllvm-sanity-checker | gsanity-check |
| LLVM_COMPILER_PATH | LLVM_COMPILER_PATH |
| LLVM_CC_NAME ... | LLVM_CC_NAME ... |
| WLLVM_CONFIGURE_ONLY | WLLVM_CONFIGURE_ONLY |
| WLLVM_OUTPUT_LEVEL | WLLVM_OUTPUT_LEVEL |
| WLLVM_OUTPUT_FILE | WLLVM_OUTPUT_FILE |
| LLVM_COMPILER | not supported (clang only) |
| LLVM_GCC_PREFIX | not supported (clang only) |
| LLVM_DRAGONEGG_PLUGIN | not supported (clang only) |
This project, gllvm, provides tools for building whole-program (or
whole-library) LLVM bitcode files from an unmodified C or C++
source package. It currently runs on *nix platforms such as Linux,
FreeBSD, and Mac OS X. It is a Go port of wllvm.
gllvm provides compiler wrappers that work in two
phases. The wrappers first invoke the compiler as normal. Then, for
each object file, they call a bitcode compiler to produce LLVM
bitcode. The wrappers then store the location of the generated bitcode
file in a dedicated section of the object file. When object files are
linked together, the contents of the dedicated sections are
concatenated (so we don't lose the locations of any of the constituent
bitcode files). After the build completes, one can use a gllvm
utility to read the contents of the dedicated section and link all of
the bitcode into a single whole-program bitcode file. This utility
works for both executable and native libraries.
For more details see wllvm.
Prerequisites
To install gllvm you need the go language tool.
To use gllvm you need clang/clang++ and the llvm tools llvm-link and llvm-ar.
gllvm is agnostic to the actual llvm version. gllvm also relies on standard build
tools such as objcopy and ld.
Installation
To install, simply do
go get github.com/SRI-CSL/gllvm/cmd/...
This should install four binaries: gclang, gclang++, get-bc, and gsanity-check
in the $GOPATH/bin directory.
Usage
gclang and
gclang++ are the wrappers used to compile C and C++. get-bc is used for
extracting the bitcode from a build product (either an object file, executable, library
or archive). gsanity-check can be used for detecting configuration errors.
Here is a simple example. Assuming that clang is in your PATH, you can build
bitcode for pkg-config as follows:
tar xf pkg-config-0.26.tar.gz
cd pkg-config-0.26
CC=gclang ./configure
make
This should produce the executable pkg-config. To extract the bitcode:
get-bc pkg-config
which will produce the bitcode module pkg-config.bc.
If clang and the llvm tools are not in your PATH, you will need to set some
environment variables.
-
LLVM_COMPILER_PATHcan be set to the absolute path of the directory that contains the compiler and the other LLVM tools to be used. -
LLVM_CC_NAMEcan be set if your clang compiler is not calledclangbut something likeclang-3.7. SimilarlyLLVM_CXX_NAMEcan be used to describe what the C++ compiler is called. We also pay attention to the environment variablesLLVM_LINK_NAMEandLLVM_AR_NAMEin an analogous way.
Another useful environment variable is WLLVM_CONFIGURE_ONLY. Its use is explained in the
README of wllvm.
gllvm does not support the dragonegg plugin. All other features of wllvm, such as logging, and the bitcode store,
are supported in exactly the same fashion.
Under the hoods
Both wllvm and gllvm toolsets do much the same thing, but the way
they do it is slightly different. The gllvm toolset's code base is
written in golang, and is largely derived from the wllvm's python
codebase.
Both generate object files and bitcode files using the
compiler. wllvm can use gcc and dragonegg, gllvm can only use
clang. The gllvm toolset does these two tasks in parallel, while
wllvm does them sequentially. This together with the slowness of
python's fork exec-ing, and it's interpreted nature accounts for the
large efficiency gap between the two toolsets.
Both inject the path of the bitcode version of the .o file into a
dedicated segment of the .o file itself. This segment is the same
across toolsets, so extracting the bitcode can be done by the
appropriate tool in either toolset. On *nix both toolsets use
objcopy to add the segment, while on OS X they use ld.
When the object files are linked into the resulting library or
executable, the bitcode path segments are appended, so the resulting
binary contains the paths of all the bitcode files that constitute the
binary. To extract the sections the gllvm toolset uses the golang
packages "debug/elf" and "debug/macho", while the wllvm toolset
uses objdump on *nix, and otool on OS X.
Both tools then use llvm-link or llvm-ar to combine the bitcode
files into the desired form.
License
gllvm is released under a BSD license. See the file LICENSE for details.
This material is based upon work supported by the National Science Foundation under Grant ACI-1440800. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation.