transonic 0.2.0

Make your Python code fly at transonic speeds!

Documentation: https://transonic.readthedocs.io

Transonic is a pure Python package (requiring Python >= 3.6) to easily accelerate modern Python-Numpy code with different accelerators (like Cython, Pythran, Numba, Cupy, PyTorch, Uarray, etc…) opportunistically (i.e. if/when they are available).

The accelerators are not hard dependencies of Transonic: Python codes using Transonic run fine without any accelerators installed (of course without speedup)!

Warning

Transonic is still in a early stage. Remarks and suggestions are very welcome.

In particular, Transonic is now only able to use the Pythran compiler! So you are not going to be able to use for example Numba with this version of Transonic.

However, Transonic is now really usable, useful and used “in production” in FluidSim and FluidFFT (see examples for blocks, @boost and @jit).

The long-term project

Transonic targets Python end-users and library developers.

It is based on the following principles:

• We’d like to write scientific / computing applications / libraries with pythonic, readable, modern code (Python >= 3.6).

• In some cases, Python-Numpy is too slow. However, there are tools to accelerate such Python-Numpy code which lead to very good performances!

• Let’s try to write universal code which express what we want to compute and not the special hacks we want to use to make it fast. We just need nice ways to express that a function, a method or a block of code has to be accelerated (and how it has to be accelerated). We’d like to be able to do this in a pythonic way, with decorators and context managers.

• There are many tools to accelerate Python-Numpy code! Let’s avoid writting code specialized for only one of these tools.

• Let’s try to keep the code as it would be written without acceleration. For example, with Transonic, we are able to accelerate (simple) methods of classes even though most of the accelerators don’t support classes.

• Let’s accelerate/compile only what needs to be accelerated, i.e. only the bottlenecks. Python and its interpreters are good for the rest. In most cases, the benefice of writting big compiled extensions (with Cython or in other languages) is negligible.

• Adding types is sometimes necessary. In modern Python, we have nice syntaxes for type annotations! Let’s use them.

• Ahead-of-time (AOT) and just-in-time (JIT) compilation modes are both useful. We’d like to have a nice, simple and unified API for these two modes.

  • AOT is useful to be able to distribute compiled packages and in some cases, more optimizations can be applied.

  • JIT is simpler to use (no need for type annotations) and optimizations can be more hardware specific.

  Note that with Transonic, AOT compilers can be used as JIT compilers (with a cache mechanism).

  In contrast, some JIT compilers cannot be used as AOT compilers. For these tools, the AOT decorators are used in a JIT mode.

To summarize, a strategy to quickly develop a very efficient scientific application/library with Python could be:

1. Use modern Python coding, standard Numpy/Scipy for the computations and all the cool libraries you want.

2. Profile your applications on real cases, detect the bottlenecks and apply standard optimizations with Numpy.

3. Add few lines of Transonic to compile the hot spots.

What we have now

We start to have a good API to accelerate Python-Numpy code.

The only implemented Transonic backend uses Pythran and works well.

Here, we explain why Pythran is so great for Python users and why Transonic is great for Pythran users

Note

Transonic can be used in libraries and applications using MPI (as FluidSim).

Installation and configuration

pip install transonic

Transonic is sensible to environment variables:

• TRANSONIC_DIR can be set to control where the cached files are saved.

• TRANSONIC_COMPILE_AT_IMPORT can be set to enable a mode for which Transonic compiles at import time the Pythran file associated with the imported module. This behavior can also be triggered programmatically by using the function set_compile_at_import.

• TRANSONIC_NO_REPLACE can be set to disable all code replacements. This is useful to compare execution times and when measuring code coverage.

• TRANSONIC_COMPILE_JIT can be set to false to disable the compilation of jited functions. This can be useful for unittests.

A short tour of Transonic syntaxes

Decorator boost and command # transonic def

import h5py
import mpi4py

from transonic import boost

# transonic def myfunc(int, float)

@boost
def myfunc(a, b):
    return a * b

...

Most of this code looks familiar to Pythran users. The differences:

• One can use (for example) h5py and mpi4py (of course not in the Pythran functions).

• # transonic def instead of # pythran export.

• A tiny bit of Python… The decorator @boost replaces the Python function by the pythranized function if Transonic has been used to produced the associated Pythran file.

Pythran using type annotations

The previous example can be rewritten without # transonic def. It is the recommended syntaxes for ahead-of-time function acceleration:

import numpy as np
import h5py

from transonic import boost

@boost
def myfunc(a: float, d: int):
    return a * np.ones(d * [10])

...

Nice (shorter and clearer than with the Pythran command) but very limited… So one can also elegantly define many Pythran signatures using in the annotations type variables and Pythran types in strings (see these examples). Moreover, it is possible to mix type hints and # transonic def commands.

Just-In-Time compilation

With Transonic, one can use the Ahead-Of-Time compiler Pythran in a Just-In-Time mode. It is really the easiest way to speedup a function with Pythran, just by adding a decorator! And it also works in notebooks!

import numpy as np

from transonic import jit

def func0(a, b):
    return a + b

@jit
def func1(a, b):
    return np.exp(a) * b * func0(a, b)

Note that the @jit decorator takes into account type hints (see the example in the documentation).

Implementation details for just-in-time compilation: A Pythran file is produced for each “JITed” function (function decorated with @jit). The file is compiled at the first call of the function and the compiled version is used as soon as it is ready. The warmup can be quite long but the compiled version is saved and can be reused (without warmup!) by another process.

Define accelerated blocks

Transonic blocks can be used with classes and more generally in functions with lines that cannot be compiled by Pythran.

from transonic import Transonic

ts = Transonic()

class MyClass:

    ...

    def func(self, n):
        a, b = self.something_that_cannot_be_pythranized()

        if ts.is_transpiled:
            result = ts.use_block("name_block")
        else:
            # transonic block (
            #     float a, b;
            #     int n
            # )

            # transonic block (
            #     complex a, b;
            #     int n
            # )

            result = a**n + b**n

        return self.another_func_that_cannot_be_pythranized(result)

For blocks, we need a little bit more of Python.

• At import time, we have ts = Transonic(), which detects which Pythran module should be used and imports it. This is done at import time since we want to be very fast at run time.

• In the function, we define a block with three lines of Python and special Pythran annotations (# transonic block). The 3 lines of Python are used (i) at run time to choose between the two branches (is_transpiled or not) and (ii) at compile time to detect the blocks.

Note that the annotations in the command # transonic block are different (and somehow easier to write) than in the standard command # pythran export.

Blocks can now also be defined with type hints!

Warning

I’m not satisfied by the syntax for Pythran blocks so I (PA) proposed an alternative syntax in issue #29.

Python classes: @boost and @jit for methods

For simple methods only using attributes, we can write:

import numpy as np

from transonic import boost

A = "float[:]"

@boost
class MyClass:

    arr0: A
    arr1: A

    def __init__(self, n):
        self.arr0 = np.zeros(n)
        self.arr1 = np.zeros(n)

    @boost
    def compute(self, alpha: float):
        return (self.arr0 + self.arr1).mean() ** alpha

Warning

Calling another method in a Pythranized method is not yet supported!

More examples of how to use Transonic for Object Oriented Programing are given here.

Make the Pythran files

There is a command-line tool transonic which makes the associated Pythran files from Python files with annotations and transonic code. By default and if Pythran is available, the Pythran files are compiled.

There is also a function make_backend_files that can be used in a setup.py like this:

from pathlib import Path

from transonic.dist import make_backend_files

here = Path(__file__).parent.absolute()

paths = ["fluidsim/base/time_stepping/pseudo_spect.py"]
make_backend_files([here / path for path in paths])

Note that the function make_backend_files does not use compile the file produced. The compilation has to be done after the call of this function (see for example how it is done in the example package example_package_fluidpythran or in fluidsim’s setup.py).

License

Transonic is distributed under the CeCILL-B License, a BSD compatible french license.