LLVM

3.2

Tagged version on git failed, so working from the tarballs:
Install:

cd /path/to
mkdir llvm32
cd llvm32
wget http://llvm.org/releases/3.2/llvm-3.2.src.tar.gz
wget http://llvm.org/releases/3.2/clang-3.2.src.tar.gz
tar xzf llvm-3.2.src.tar.gz
cd llvm-3.2.src/tools/
tar xzf ../../clang-3.2.src.tar.gz
cd /path/to/llvm32
mkdir llvm-build
cd llvm-build
../llvm-3.2.src/configure --enable-optimized --prefix=/path/to/llvm32/llvm-install
REQUIRES_RTTI=1 make -j3
make install

Use:

export PATH=/path/to/llvm32/llvm-install/bin:$PATH

3.3

Tagged version on git failed, so working from the tarballs:
Install:

cd /path/to
mkdir llvm33
cd llvm33
wget http://llvm.org/releases/3.3/llvm-3.3.src.tar.gz
wget http://llvm.org/releases/3.3/cfe-3.3.src.tar.gz
tar xzf llvm-3.3.src.tar.gz
cd llvm-3.3.src/tools/
tar xzf ../../cfe-3.3.src.tar.gz
mv cfe-3.3.src clang
cd /path/to/llvm33
mkdir llvm-build
cd llvm-build
../llvm-3.3.src/configure --enable-optimized --prefix=/path/to/llvm33/llvm-install
REQUIRES_RTTI=1 make -j3
make install

Use:

export PATH=/path/to/llvm33/llvm-install/bin:$PATH

3.4

Install:

cd /path/to
mkdir llvm34
cd llvm34
wget http://llvm.org/releases/3.4/llvm-3.4.src.tar.gz
wget http://llvm.org/releases/3.4/clang-3.4.src.tar.gz
tar xzf llvm-3.4.src.tar.gz
cd llvm-3.4/tools/
tar xzf ../../clang-3.4.src.tar.gz
mv clang-3.4 clang
cd /path/to/llvm34
mkdir llvm-build
cd llvm-build
../llvm-3.4/configure --enable-optimized --prefix=/path/to/llvm34/llvm-install
REQUIRES_RTTI=1 make -j3
make install

Use:

export PATH=/path/to/llvm34/llvm-install/bin:$PATH

LLVM basics

src2ir

clang -Os -S -emit-llvm foo.c -o foo.ll

src2bc

clang -Os -c -emit-llvm foo.c -o foo.bc

ir2bc

clang -Os -c -emit-llvm foo.ll -o foo.bc

bc2ir

llvm-dis -f foo.bc

bc2bin

llc foo.bc

bc analysis

opt -stats  -instcount  foo.bc

llvm-bcanalyzer [-dump] foo.bc

See also bc.py for another bc parser written in Python

with Python

llvmpy

Install with LLVM 3.2:

export PATH=/path/to/llvm32/llvm-install/bin:$PATH
virtualenv llvmpy_llvm32.env
. llvmpy_llvm32.env/bin/activate
git clone git@github.com:llvmpy/llvmpy.git llvmpy.git
cd llvmpy.git
git checkout 0.12.5
LLVM_CONFIG_PATH=/path/to/llvm32/llvm-install/bin/llvm-config python setup.py install
cd ..
python -c "import llvm; llvm.test()"
deactivate

Usage with LLVM 3.2:

export PATH=/path/to/llvm32/llvm-install/bin:$PATH
. llvmpy_llvm32.env/bin/activate
# Do your stuff... python -c "import llvm; llvm.test()"
deactivate

Install with LLVM 3.3:
idem, just replace llvm32 by llvm33

Install with LLVM 3.4
v0.12.5 doesn't support LLVM 3.4 apparently, compil fails

llvm_cbuilder

set of Python-contexts you can use to write C-like constructs in Python which generates llvmpy code directly.
Similar to llpython it allows you to build llvm IR without using the llvmpy interface directly.

llpython

• on Github

The primary goal of the llpython package is to provide a Python dialect/subset that maps directly to LLVM code.
LLPython differs from its originating LLVM translator, Numba, in the following aspects:

• LLPython code is not intended to work in Python if not translated and wrapped.
• The LLPython translator only uses LLVM types.
• LLPython is explicitly typed, and does not support type inference. LLPython does not support implicit casts, all casts must be explicit.
• LLPython supports code that directly calls the C API, the Python C API, and the llvm.core.Builder methods.

We developed LLPython with the initial goal of simplifying writing LLVM code.

Tests as at the moment there is very little user doc:

import llvm.core as lc
from llpython import bytetype

ll_ipow = lc.Type.function(bytetype.li32, (bytetype.li32, bytetype.li32))

def ipow (val, exp):
    ret_val = 1
    temp = val
    w = exp
    while w > 0:
        if (w & 1) != 0:
            ret_val *= temp
            # TODO: Overflow check on ret_val
        w >>= 1
        if w == 0: break
        temp *= temp
        # TODO: Overflow check on temp
    return ret_val

ll_pymod = lc.Type.function(bytetype.li32, (bytetype.li32, bytetype.li32))

def pymod (arg1, arg2):
    ret_val = arg1 % arg2
    if ret_val < 0:
        if arg2 > 0:
            ret_val += arg2
    elif arg2 < 0:
        ret_val += arg2
    return ret_val

lm = lc.Module.new('test_module')
from llpython import byte_translator
byte_translator.translate_function(ipow, ll_ipow, lm)
byte_translator.translate_function(pymod, ll_pymod, lm)
print(lm)

# Ok let's JIT & run the LLVM IR code:
from llvm.ee import ExecutionEngine, GenericValue
ee = ExecutionEngine.new(lm)

arg1 = GenericValue.int(bytetype.li32, 235)
arg2 = GenericValue.int(bytetype.li32, 17)
retval = ee.run_function(lm.get_function_named('pymod'), [arg1, arg2])
print "pymod(235, 17) =", retval.as_int()

# Tried ipow() but it loops infinitely
#arg1 = GenericValue.int(bytetype.li32, 2)
#arg2 = GenericValue.int(bytetype.li32, 8)
#retval = ee.run_function(lm.get_function_named('ipow'), [arg1, arg2])
#print "returned", retval.as_int()

Numba

Numba is a NumPy aware dynamic compiler for Python. It creates LLVM bit-code from Python syntax and then creates a wrapper around that bitcode to call from Python.

• 0.13 doc
• on Github
• Numba Python bytecode to LLVM translator (video)

pycc allows users to compile Numba functions into a shared library. The user writes the functions, exports them and the compiler will import the module, collect the exported functions and compile them to a shared library. Below is an example:

from numba import *
def mult(a, b):
    return a * b
export('mult f8(f8, f8)'))(mult)
export(['multf f4(f4, f4)', 'multi i4(i4, i4)'])(mult)
export('multc c16(c16, c16)'))(mult)

LLVMlite

llvmlite is the lightweight Python binding developed for Numba

Pyston

by Dropbox

• https://tech.dropbox.com/2014/04/introducing-pyston-an-upcoming-jit-based-python-implementation/

Not mature yet

old attempts

• llvm-py
• RPython
• Unladen Swallow
• py2llvm