Getting Started with the LLVM System
By:
Guochun Shi,
Chris Lattner,
John Criswell,
Misha Brukman, and
Vikram Adve.
Welcome to LLVM! In order to get started, you first need to know some
basic information.
First, LLVM comes in two pieces. The first piece is the LLVM suite. This
contains all of the tools, libraries, and header files needed to use the low
level virtual machine. It contains an assembler, disassembler, bytecode
analyzer, and bytecode optimizer. It also contains a test suite that can be
used to test the LLVM tools and the GCC front end.
The second piece is the GCC front end. This component provides a version of
GCC that compiles C and C++ code into LLVM bytecode. Currently, the GCC front
end is a modified version of GCC 3.4 (we track the GCC 3.4 development). Once
compiled into LLVM bytecode, a program can be manipulated with the LLVM tools
from the LLVM suite.
Here's the short story for getting up and running quickly with LLVM:
- Install the GCC front end:
- cd where-you-want-the-C-front-end-to-live
- gunzip --stdout cfrontend.platform.tar.gz | tar -xvf -
- Sparc Only:
cd cfrontend/sparc
./fixheaders
- Get the Source Code
- With the distributed files:
- cd where-you-want-llvm-to-live
- gunzip --stdout llvm.tar.gz | tar -xvf -
- cd llvm
- With anonymous CVS access:
- cd where-you-want-llvm-to-live
- cvs -d
:pserver:anon@llvm-cvs.cs.uiuc.edu:/var/cvs/llvm login
- Hit the return key when prompted for the password.
- cvs -z3 -d :pserver:anon@llvm-cvs.cs.uiuc.edu:/var/cvs/llvm
co llvm
- cd llvm
- Configure the LLVM Build Environment
- Change directory to where you want to store the LLVM object
files and run configure to configure the Makefiles and
header files for the default platform. Useful options include:
- Build the LLVM Suite:
- Set your LLVM_LIB_SEARCH_PATH environment variable.
- gmake -k |& tee gnumake.out
# this is csh or tcsh syntax
Consult the Getting Started with LLVM section for
detailed information on configuring and compiling LLVM. See Setting Up Your Environment for tips that simplify
working with the GCC front end and LLVM tools. Go to Program
Layout to learn about the layout of the source code tree.
Before you begin to use the LLVM system, review the requirements given below.
This may save you some trouble by knowing ahead of time what hardware and
software you will need.
LLVM is known to work on the following platforms:
- Linux on x86 (Pentium and above)
- Approximately 760 MB of Free Disk Space
- Source code: 30 MB
- Object code: 670 MB
- GCC front end: 60 MB
- Solaris on SparcV9 (Ultrasparc)
- Approximately 1.24 GB of Free Disk Space
- Source code: 30 MB
- Object code: 1000 MB
- GCC front end: 210 MB
The LLVM suite may compile on other platforms, but it is not
guaranteed to do so. If compilation is successful, the LLVM utilities should be
able to assemble, disassemble, analyze, and optimize LLVM bytecode. Code
generation should work as well, although the generated native code may not work
on your platform.
The GCC front end is not very portable at the moment. If you want to get it
to work on another platform, you can download a copy of the source and try to
compile it on your platform.
Compiling LLVM requires that you have several software packages
installed:
There are some additional tools that you may want to have when working with
LLVM:
- GNU Autoconf
- GNU M4
If you want to make changes to the configure scripts, you will need GNU
autoconf (2.57 or higher), and consequently, GNU M4 (version 1.4 or
higher).
- QMTest
- Python
These are needed to use the LLVM test suite.
The remainder of this guide is meant to get you up and running with
LLVM and to give you some basic information about the LLVM environment.
A complete guide to installation is provided in the
next section.
The later sections of this guide describe the general layout of the the LLVM source tree, a simple example using the LLVM tool chain, and links to find more information about LLVM or to get
help via e-mail.
Throughout this manual, the following names are used to denote paths
specific to the local system and working environment. These are not
environment variables you need to set but just strings used in the rest
of this document below. In any of the examples below, simply replace
each of these names with the appropriate pathname on your local system.
All these paths are absolute:
- SRC_ROOT
-
This is the top level directory of the LLVM source tree.
- OBJ_ROOT
-
This is the top level directory of the LLVM object tree (i.e. the
tree where object files and compiled programs will be placed. It
can be the same as SRC_ROOT).
- LLVMGCCDIR
-
This is the where the LLVM GCC Front End is installed.
For the pre-built GCC front end binaries, the LLVMGCCDIR is
cfrontend/platform/llvm-gcc.
In order to compile and use LLVM, you will need to set some environment
variables. There are also some shell aliases which you may find useful.
You can set these on the command line, or better yet, set them in your
.cshrc or .profile.
- LLVM_LIB_SEARCH_PATH=LLVMGCCDIR/bytecode-libs
-
This environment variable helps the LLVM GCC front end find bytecode
libraries that it will need for compilation.
- alias llvmgcc LLVMGCCDIR/bin/gcc
- alias llvmg++ LLVMGCCDIR/bin/g++
-
This alias allows you to use the LLVM C and C++ front ends without putting
them in your PATH or typing in their complete pathnames.
If you have the LLVM distribution, you will need to unpack it before you
can begin to compile it. LLVM is distributed as a set of three files. Each
file is a TAR archive that is compressed with the gzip program.
The three files are as follows:
- llvm.tar.gz
- This is the source code to the LLVM suite.
- cfrontend.sparc.tar.gz
- This is the binary release of the GCC front end for Solaris/Sparc.
- cfrontend.x86.tar.gz
- This is the binary release of the GCC front end for Linux/x86.
If you have access to our CVS repository, you can get a fresh copy of
the entire source code. All you need to do is check it out from CVS as
follows:
- cd where-you-want-llvm-to-live
- cvs -d :pserver:anon@llvm-cvs.cs.uiuc.edu:/var/cvs/llvm login
- Hit the return key when prompted for the password.
- cvs -z3 -d :pserver:anon@llvm-cvs.cs.uiuc.edu:/var/cvs/llvm co
llvm
This will create an 'llvm' directory in the current
directory and fully populate it with the LLVM source code, Makefiles,
test directories, and local copies of documentation files.
Note that the GCC front end is not included in the CVS repository. You
should have downloaded the binary distribution for your platform.
Before configuring and compiling the LLVM suite, you need to extract the LLVM
GCC front end from the binary distribution. It is used for building the
bytecode libraries later used by the GCC front end for linking programs, and its
location must be specified when the LLVM suite is configured.
To install the GCC front end, do the following:
- cd where-you-want-the-front-end-to-live
- gunzip --stdout cfrontend.platform.tar.gz | tar -xvf
-
If you are on a Sparc/Solaris machine, you will need to fix the header
files:
cd cfrontend/sparc
./fixheaders
The binary versions of the GCC front end may not suit all of your needs. For
example, the binary distribution may include an old version of a system header
file, not "fix" a header file that needs to be fixed for GCC, or it may be
linked with libraries not available on your system.
In cases like these, you may want to try building the GCC front end from source. This is
not for the faint of heart, so be forewarned.
Once checked out from the CVS repository, the LLVM suite source code must be
configured via the configure script. This script sets variables in
llvm/Makefile.config and llvm/include/Config/config.h. It
also populates OBJ_ROOT with the Makefiles needed to build LLVM.
The following environment variables are used by the configure
script to configure the build system:
Variable |
Purpose |
CC |
Tells configure which C compiler to use. By default,
configure will look for the first GCC C compiler in
PATH. Use this variable to override
configure's default behavior. |
CXX |
Tells configure which C++ compiler to use. By default,
configure will look for the first GCC C++ compiler in
PATH. Use this variable to override
configure's default behavior. |
The following options can be used to set or enable LLVM specific options:
- --with-llvmgccdir=LLVMGCCDIR
-
Path to the location where the LLVM C front end binaries and
associated libraries will be installed.
- --enable-optimized
-
Enables optimized compilation by default (debugging symbols are removed
and GCC optimization flags are enabled). The default is to use an
unoptimized build (also known as a debug build).
- --enable-jit
-
Compile the Just In Time (JIT) functionality. This is not available
on all platforms. The default is dependent on platform, so it is best
to explicitly enable it if you want it.
- --enable-spec2000
- --enable-spec2000=<directory>
-
Enable the use of SPEC2000 when testing LLVM. This is disabled by default
(unless configure finds SPEC2000 installed). By specifying
directory, you can tell configure where to find the SPEC2000
benchmarks. If directory is left unspecified, configure
uses the default value
/home/vadve/shared/benchmarks/speccpu2000/benchspec.
To configure LLVM, follow these steps:
- Change directory into the object root directory:
cd OBJ_ROOT
- Run the configure script located in the LLVM source tree:
SRC_ROOT/configure
In addition to running configure, you must set the
LLVM_LIB_SEARCH_PATH environment variable in your startup scripts.
This environment variable is used to locate "system" libraries like
"-lc" and "-lm" when linking. This variable should be set to
the absolute path for the bytecode-libs subdirectory of the GCC front end
install, or LLVMGCCDIR/bytecode-libs. For example, one might set
LLVM_LIB_SEARCH_PATH to
/home/vadve/lattner/local/x86/llvm-gcc/bytecode-libs for the X86
version of the GCC front end on our research machines.
Once you have configured LLVM, you can build it. There are three types of
builds:
- Debug Builds
-
These builds are the default when one types gmake (unless the
--enable-optimized option was used during configuration). The
build system will compile the tools and libraries with debugging
information.
- Release (Optimized) Builds
-
These builds are enabled with the --enable-optimized option to
configure or by specifying ENABLE_OPTIMIZED=1 on the
gmake command line. For these builds, the build system will
compile the tools and libraries with GCC optimizations enabled and strip
debugging information from the libraries and executables it generates.
- Profile Builds
-
These builds are for use with profiling. They compile profiling
information into the code for use with programs like gprof.
Profile builds must be started by specifying ENABLE_PROFILING=1
on the gmake command line.
Once you have LLVM configured, you can build it by entering the
OBJ_ROOT directory and issuing the following command:
gmake
If you have multiple processors in your machine, you may wish to use some of
the parallel build options provided by GNU Make. For example, you could use the
command:
gmake -j2
There are several special targets which are useful when working with the LLVM
source code:
- gmake clean
-
Removes all files generated by the build. This includes object files,
generated C/C++ files, libraries, and executables.
- gmake distclean
-
Removes everything that gmake clean does, but also removes
files generated by configure. It attempts to return the
source tree to the original state in which it was shipped.
- gmake install
-
Installs LLVM files into the proper location. For the most part,
this does nothing, but it does install bytecode libraries into the
GCC front end's bytecode library directory. If you need to update
your bytecode libraries, this is the target to use once you've built
them.
It is also possible to override default values from configure by
declaring variables on the command line. The following are some examples:
- gmake ENABLE_OPTIMIZED=1
-
Perform a Release (Optimized) build.
- gmake ENABLE_PROFILING=1
-
Perform a Profiling build.
- gmake VERBOSE=1
-
Print what gmake is doing on standard output.
Every directory in the LLVM object tree includes a Makefile to build
it and any subdirectories that it contains. Entering any directory inside the
LLVM object tree and typing gmake should rebuild anything in or below
that directory that is out of date.
The LLVM build system is capable of sharing a single LLVM source tree among
several LLVM builds. Hence, it is possible to build LLVM for several different
platforms or configurations using the same source tree.
This is accomplished in the typical autoconf manner:
The LLVM build will place files underneath OBJ_ROOT in directories
named after the build type:
- Debug Builds
-
- Tools
- OBJ_ROOT/tools/Debug
- Libraries
- OBJ_ROOT/lib/Debug
- Release Builds
-
- Tools
- OBJ_ROOT/tools/Release
- Libraries
- OBJ_ROOT/lib/Release
- Profile Builds
-
- Tools
- OBJ_ROOT/tools/Profile
- Libraries
- OBJ_ROOT/lib/Profile
One useful source of information about the LLVM source base is the LLVM doxygen documentation, available at http://llvm.cs.uiuc.edu/doxygen/.
The following is a brief introduction to code layout:
Every directory checked out of CVS will contain a CVS directory; for
the most part these can just be ignored.
This directory contains public header files exported from the LLVM
library. The three main subdirectories of this directory are:
- llvm/include/llvm - This directory contains all of the LLVM
specific header files. This directory also has subdirectories for
different portions of LLVM: Analysis, CodeGen,
Target, Transforms, etc...
- llvm/include/Support - This directory contains generic
support libraries that are independent of LLVM, but are used by LLVM.
For example, some C++ STL utilities and a Command Line option processing
library store their header files here.
- llvm/include/Config - This directory contains header files
configured by the configure script. They wrap "standard" UNIX
and C header files. Source code can include these header files which
automatically take care of the conditional #includes that the
configure script generates.
This directory contains most of the source files of the LLVM system. In LLVM,
almost all code exists in libraries, making it very easy to share code among the
different tools.
- llvm/lib/VMCore/
- This directory holds the core LLVM
source files that implement core classes like Instruction and BasicBlock.
- llvm/lib/AsmParser/
- This directory holds the source code
for the LLVM assembly language parser library.
- llvm/lib/ByteCode/
- This directory holds code for reading
and write LLVM bytecode.
- llvm/lib/CWriter/
- This directory implements the LLVM to C
converter.
- llvm/lib/Analysis/
- This directory contains a variety of
different program analyses, such as Dominator Information, Call Graphs,
Induction Variables, Interval Identification, Natural Loop Identification,
etc...
- llvm/lib/Transforms/
- This directory contains the source
code for the LLVM to LLVM program transformations, such as Aggressive Dead
Code Elimination, Sparse Conditional Constant Propagation, Inlining, Loop
Invariant Code Motion, Dead Global Elimination, and many others...
- llvm/lib/Target/
- This directory contains files that
describe various target architectures for code generation. For example,
the llvm/lib/Target/Sparc directory holds the Sparc machine
description.
- llvm/lib/CodeGen/
- This directory contains the major parts
of the code generator: Instruction Selector, Instruction Scheduling, and
Register Allocation.
- llvm/lib/Support/
- This directory contains the source code
that corresponds to the header files located in
llvm/include/Support/.
This directory contains libraries which are compiled into LLVM bytecode and
used when linking programs with the GCC front end. Most of these libraries are
skeleton versions of real libraries; for example, libc is a stripped down
version of glibc.
Unlike the rest of the LLVM suite, this directory needs the LLVM GCC front
end to compile.
This directory contains regression tests and source code that is used to test
the LLVM infrastructure.
The tools directory contains the executables built out of the
libraries above, which form the main part of the user interface. You can
always get help for a tool by typing tool_name --help. The
following is a brief introduction to the most important tools.
-
- analyze
- analyze is used to run a specific
analysis on an input LLVM bytecode file and print out the results. It is
primarily useful for debugging analyses, or familiarizing yourself with
what an analysis does.
- bugpoint
- bugpoint is used to debug
optimization passes or code generation backends by narrowing down the
given test case to the minimum number of passes and/or instructions that
still cause a problem, whether it is a crash or miscompilation. See HowToSubmitABug.html for more information
on using bugpoint.
- llvm-ar
- The archiver produces an archive containing
the given LLVM bytecode files, optionally with an index for faster
lookup.
- llvm-as
- The assembler transforms the human readable
LLVM assembly to LLVM bytecode.
- llvm-dis
- The disassembler transforms the LLVM
bytecode to human readable LLVM assembly. Additionally, it can convert
LLVM bytecode to C, which is enabled with the -c option.
- llvm-link
- llvm-link, not surprisingly,
links multiple LLVM modules into a single program.
- lli
- lli is the LLVM interpreter, which
can directly execute LLVM bytecode (although very slowly...). In addition
to a simple interpreter, lli also has a tracing mode (entered by
specifying -trace on the command line). Finally, for
architectures that support it (currently only x86 and Sparc), by default,
lli will function as a Just-In-Time compiler (if the
functionality was compiled in), and will execute the code much
faster than the interpreter.
- llc
- llc is the LLVM backend compiler,
which translates LLVM bytecode to a SPARC or x86 assembly file.
- llvmgcc
- llvmgcc is a GCC-based C frontend
that has been retargeted to emit LLVM code as the machine code output. It
works just like any other GCC compiler, taking the typical -c, -S, -E,
-o options that are typically used. The source code for the
llvmgcc tool is currently not included in the LLVM CVS tree
because it is quite large and not very interesting.
- gccas
- This tool is invoked by the
llvmgcc frontend as the "assembler" part of the compiler. This
tool actually assembles LLVM assembly to LLVM bytecode,
performs a variety of optimizations, and outputs LLVM bytecode. Thus
when you invoke llvmgcc -c x.c -o x.o, you are causing
gccas to be run, which writes the x.o file (which is
an LLVM bytecode file that can be disassembled or manipulated just like
any other bytecode file). The command line interface to gccas
is designed to be as close as possible to the system
`as' utility so that the gcc frontend itself did not have to be
modified to interface to a "weird" assembler.
- gccld
- gccld links together several LLVM
bytecode files into one bytecode file and does some optimization. It is
the linker invoked by the GCC frontend when multiple .o files need to be
linked together. Like gccas, the command line interface of
gccld is designed to match the system linker, to aid
interfacing with the GCC frontend.
- opt
- opt reads LLVM bytecode, applies a
series of LLVM to LLVM transformations (which are specified on the command
line), and then outputs the resultant bytecode. The 'opt --help'
command is a good way to get a list of the program transformations
available in LLVM.
This directory contains utilities for working with LLVM source code, and some
of the utilities are actually required as part of the build process because they
are code generators for parts of LLVM infrastructure.
Burg/- Burg is an instruction selector
generator -- it builds trees on which it then performs pattern-matching to
select instructions according to the patterns the user has specified. Burg
is currently used in the Sparc V9 backend.
- codegen-diff
- codegen-diff is a script
that finds differences between code that LLC generates and code that LLI
generates. This is a useful tool if you are debugging one of them,
assuming that the other generates correct output. For the full user
manual, run `perldoc codegen-diff'.
- cvsupdate
- cvsupdate is a script that will
update your CVS tree, but produce a much cleaner and more organized output
than simply running `cvs -z3 up -dP' will. For example, it will group
together all the new and updated files and modified files in separate
sections, so you can see at a glance what has changed. If you are at the
top of your LLVM CVS tree, running utils/cvsupdate is the
preferred way of updating the tree.
- emacs/
- The emacs directory contains
syntax-highlighting files which will work with Emacs and XEmacs editors,
providing syntax highlighting support for LLVM assembly files and TableGen
description files. For information on how to use the syntax files, consult
the README file in that directory.
- getsrcs.sh
- The getsrcs.sh script finds
and outputs all non-generated source files, which is useful if one wishes
to do a lot of development across directories and does not want to
individually find each file. One way to use it is to run, for example:
xemacs `utils/getsources.sh` from the top of your LLVM source
tree.
- makellvm
- The makellvm script compiles all
files in the current directory and then compiles and links the tool that
is the first argument. For example, assuming you are in the directory
llvm/lib/Target/Sparc, if makellvm is in your path,
simply running makellvm llc will make a build of the current
directory, switch to directory llvm/tools/llc and build it,
causing a re-linking of LLC.
- NightlyTest.pl and
NightlyTestTemplate.html
- These files are used in a
cron script to generate nightly status reports of the functionality of
tools, and the results can be seen by following the appropriate link on
the LLVM homepage.
- TableGen/
- The TableGen directory contains
the tool used to generate register descriptions, instruction set
descriptions, and even assemblers from common TableGen description
files.
- vim/
- The vim directory contains
syntax-highlighting files which will work with the VIM editor, providing
syntax highlighting support for LLVM assembly files and TableGen
description files. For information on how to use the syntax files, consult
the README file in that directory.
- First, create a simple C file, name it 'hello.c':
#include <stdio.h>
int main() {
printf("hello world\n");
return 0;
}
Next, compile the C file into a LLVM bytecode file:
% llvmgcc hello.c -o hello
This will create two result files: hello and
hello.bc. The hello.bc is the LLVM bytecode that
corresponds the the compiled program and the library facilities that it
required. hello is a simple shell script that runs the bytecode
file with lli, making the result directly executable.
Run the program. To make sure the program ran, execute one of the
following commands:
% ./hello
or
% lli hello.bc
Use the llvm-dis utility to take a look at the LLVM assembly
code:
% llvm-dis < hello.bc | less
Compile the program to native Sparc assembly using the code
generator (assuming you are currently on a Sparc system):
% llc hello.bc -o hello.s
Assemble the native sparc assemble file into a program:
% /opt/SUNWspro/bin/cc -xarch=v9 hello.s -o hello.sparc
Execute the native sparc program:
% ./hello.sparc
If you are having problems building or using LLVM, or if you have any other
general questions about LLVM, please consult the Frequently
Asked Questions page.
This document is just an introduction to how to use LLVM to do
some simple things... there are many more interesting and complicated things
that you can do that aren't documented here (but we'll gladly accept a patch
if you want to write something up!). For more information about LLVM, check
out:
Chris Lattner
The LLVM Compiler Infrastructure
Last modified: $Date$
|