Write C Code With out Studying C: The Magic of PythoC

an attention-grabbing library the opposite day that I hadn’t heard of earlier than. 

PythoC is a Area-Particular Language (DSL) compiler that enables builders to write down C applications utilizing normal Python syntax. It takes a statically-typed subset of Python code and compiles it immediately all the way down to native machine code through LLVM IR (Low Stage Digital Machine Intermediate Illustration).

LLVM IR is a platform-independent code format used internally by the LLVM compiler framework. Compilers translate supply code into LLVM IR first, after which LLVM turns that IR into optimised machine code for particular CPUs (x86, ARM, and so on.).

A core design philosophy of PythoC is: C-equivalent runtime + Python-powered compile-time, and it has the next nearly distinctive promoting factors.

1. Creates Standalone Native Executables

In contrast to instruments corresponding to Cython, that are primarily used to create C-extensions to hurry up present Python scripts, PythoC can generate utterly unbiased, standalone C-style executables. As soon as compiled, the ensuing binary doesn’t require the Python interpreter or a rubbish collector to run.

2. Has Low-Stage Management with Python Syntax

PythoC mirrors C’s capabilities however wraps them in Python’s cleaner syntax. To realize this, it makes use of machine-native sort hints as an alternative of Python’s normal dynamic sorts.

• Primitives: i32, i8, f64, and so on.
• Reminiscence constructions: Pointers (ptr[T]), arrays (array[T, N]), and structs (created by adorning normal Python courses).
• Guide Reminiscence Administration: As a result of it doesn’t use a rubbish collector by default, reminiscence administration is express, identical to in C. Nevertheless, it affords fashionable, elective security checks, corresponding to linear sorts (which be certain that each allocation is explicitly deallocated to forestall leaks) and refinement sorts (to implement compile-time validation checks).

Python as a Metaprogramming Engine

One in all PythoC’s strongest options is its dealing with of the compilation step. As a result of the compile-time atmosphere is simply Python, you should utilize normal Python logic to generate, manipulate, and specialise your PythoC code earlier than it will get compiled all the way down to LLVM. This offers you extremely versatile compile-time code-generation capabilities (just like C++ templates however pushed by pure Python).

It sounds promising, however does the fact stay as much as the hype? Okay, let’s see this library in motion. Putting in it’s straightforward, like most Python libraries its only a pip set up like this:

pip set up pythoc

Nevertheless it’s in all probability higher to arrange a correct growth atmosphere the place you’ll be able to silo your completely different initiatives. In my instance, I’m utilizing the UV utility, however use whichever methodology you might be most comfy with. Kind within the following instructions into your command line terminal.

C:Usersthomaprojects> cd initiatives
C:Usersthomaprojects> uv init pythoc_test
C:Usersthomaprojects> cd pythoc_test
C:Usersthomaprojectspythoc_test> uv venv --python 3.12
C:Usersthomaprojectspythoc_test> .venvScriptsactivate
(pythoc_test) C:Usersthomaprojectspythoc_test> uv pip set up pythoc

A Easy Instance

To make use of PythoC, you outline capabilities utilizing particular machine sorts and mark them with PythoC’s compile decorator. There are two predominant methods to run your PythoC code. You possibly can name the compiled library immediately from Python like this,

from pythoc import compile, i32

@compile
def add(x: i32, y: i32) -> i32:
    return x + y

# Can compile to native code
@compile
def predominant() -> i32:
    return add(10, 20)

# Name the compiled dynamic library from Python immediately
outcome = predominant()
print(outcome)

Then run it like this.

(pythoc_test) C:Usersthomaprojectspythoc_test>python test1.py

30

Or you’ll be able to create a standalone executable you could run independently from Python. To try this, use code like this.

from pythoc import compile, i32

@compile
def add(x: i32, y: i32) -> i32:
    print(x + y)
    return x + y

# Can compile to native code
@compile
def predominant() -> i32:
    return add(10, 20)

if __name__ == "__main__":
    from pythoc import compile_to_executable
    compile_to_executable()

We run it the identical approach. 

(pythoc_test) C:Usersthomaprojectspythoc_test>python test4.py

Efficiently compiled to executable: buildtest4.exe
Linked 1 object file(s)

This time, we don’t see any output. As an alternative, PythoC creates a construct listing beneath your present listing, then creates an executable file there you could run.

(pythoc_test) C:Usersthomaprojectspythoc_test>dir buildtest4*
 Quantity in drive C is Home windows
 Quantity Serial Quantity is EEB4-E9CA

 Listing of C:Usersthomaprojectspythoc_testbuild

26/02/2026  14:32               297 test4.deps
26/02/2026  14:32           168,448 test4.exe
26/02/2026  14:32               633 test4.ll
26/02/2026  14:32               412 test4.o
26/02/2026  14:32                 0 test4.o.lock
26/02/2026  14:32         1,105,920 test4.pdb

We are able to run the test4.exe file simply as we’d another executable.

(pythoc_test) C:Usersthomaprojectspythoc_test>buildtest4.exe

(pythoc_test) C:Usersthomaprojectspythoc_test>

However wait a second. In our Python code, we explicitly requested to print the addition outcome, however we don’t see any output. What’s occurring?

The reply is that the built-in Python print() perform depends on the Python interpreter working within the background to determine show objects. As a result of PythoC strips all of that away to construct a tiny, blazing-fast native executable, the print assertion will get stripped out.

To print to the display in a local binary, it’s important to use the usual C library perform: printf.

How one can use printf in PythoC

In C (and subsequently in PythoC), printing variables requires format specifiers. You write a string with a placeholder (like %d for a decimal integer), after which cross the variable you wish to insert into that placeholder.

Right here is the way you replace our code to import the C printf perform and use it accurately:

from pythoc import compile, i32, ptr, i8, extern

# 1. Inform PythoC to hyperlink to the usual C printf perform
@extern
def printf(fmt: ptr[i8], *args) -> i32:
    cross

@compile
def add(x: i32, y: i32) -> i32:
  
    printf("Including 10 and 20 = %dn", x+y)
    return x + y

@compile
def predominant() -> i32:
    outcome = add(10, 20)
    
    # 2. Use printf with a C-style format string. 
    # %d is the placeholder for our integer (outcome).
    # n provides a brand new line on the finish.
   
    
    return 0

if __name__ == "__main__":
    from pythoc import compile_to_executable
    compile_to_executable()

Now, if we re-run the above code and run the ensuing executable, our output turns into what we anticipated.

(pythoc_test) C:Usersthomaprojectspythoc_test>python test5.py
Efficiently compiled to executable: buildtest5.exe
Linked 1 object file(s)

(pythoc_test) C:Usersthomaprojectspythoc_test>buildtest5.exe
Including 10 and 20 = 30

Is it actually definitely worth the trouble, although?

All of the issues we’ve talked about will solely be price it if we see actual pace enhancements in our code. So, for our last instance, let’s see how briskly our compiled applications will be in comparison with the equal in Python, and that ought to reply our query definitively.

First, the common Python code. We’ll use a recursive Fibonacci calculation to simulate a long-running course of. Let’s calculate the fortieth Fibonacci quantity.

import time

def fib(n):
    # This calculates the sequence recursively
    if n <= 1:
        return n
    return fib(n - 1) + fib(n - 2)

if __name__ == "__main__":
    print("Beginning Customary Python pace take a look at...")
    
    start_time = time.time()
    
    # fib(38) often takes round 10 seconds in Python, 
    # relying in your laptop's CPU.
    outcome = fib(40) 
    
    end_time = time.time()
    
    print(f"Consequence: {outcome}")
    print(f"Time taken: {end_time - start_time:.4f} seconds")

I bought this outcome when working the above code.

(pythoc_test) C:Usersthomaprojectspythoc_test>python test6.py
Beginning Customary Python pace take a look at...
Consequence: 102334155
Time taken: 15.1611 seconds

Now for the PythoC-based code. Once more, as with the print assertion in our earlier instance, we are able to’t simply use the common import timing directive from Python for our timings. As an alternative, we’ve got to borrow the usual timing perform immediately from the C programming language: clock(). We outline this in the identical approach because the printf assertion we used earlier.

Right here is the up to date PythoC script with the C timer in-built.

from pythoc import compile, i32, ptr, i8, extern

# 1. Import C's printf
@extern
def printf(fmt: ptr[i8], *args) -> i32:
    cross

# 2. Import C's clock perform
@extern
def clock() -> i32:
    cross

@compile
def fib(n: i32) -> i32:
    if n <= 1:
        return n
    return fib(n - 1) + fib(n - 2)

@compile
def predominant() -> i32:
    printf("Beginning PythoC pace take a look at...n")
    
    # Get the beginning time (this counts in "ticks")
    start_time = clock()
    
    # Run the heavy calculation
    outcome = fib(40)
    
    # Get the top time
    end_time = clock()
    
    # Calculate the distinction. 
    # Word: On Home windows, 1 clock tick = 1 millisecond.
    elapsed_ms = end_time - start_time
    
    printf("Consequence: %dn", outcome)
    printf("Time taken: %d millisecondsn", elapsed_ms)
    
    return 0

if __name__ == "__main__":
    from pythoc import compile_to_executable
    compile_to_executable()

My output this time was,

(pythoc_test) C:Usersthomaprojectspythoc_test>python test7.py
Efficiently compiled to executable: buildtest7.exe
Linked 1 object file(s)

(pythoc_test) C:Usersthomaprojectspythoc_test>buildtest7.exe
Beginning PythoC pace take a look at...
Consequence: 102334155
Time taken: 308 milliseconds

And on this small instance, though the code is barely extra advanced, we see the true benefit of utilizing compiled languages like C. Our executable was a whopping 40x quicker than the equal Python code. Not too shabby.

Who’s PythoC for?

I see three predominant kinds of customers for PythoC.

1/ As we noticed in our Fibonacci pace take a look at, normal Python will be sluggish when doing heavy mathematical lifting. PythoC may very well be helpful for any Python developer constructing physics simulations, advanced algorithms, or customized data-processing pipelines who has hit a efficiency wall.

2/ Programmers who work intently with laptop {hardware} (like constructing sport engines, writing drivers, or programming small IoT gadgets) often write in C as a result of they should handle laptop reminiscence manually.

PythoC might attraction to those builders as a result of it affords the identical handbook reminiscence management (utilizing pointers and native sorts), nevertheless it lets them use Python as a “metaprogramming” engine to write down cleaner, extra versatile code earlier than it will get compiled all the way down to the {hardware} degree.

3/ When you write a useful Python script and wish to share it with a coworker, that coworker often wants to put in Python, arrange a digital atmosphere, and obtain your dependencies. It may be a trouble, significantly if the goal person shouldn’t be very IT-literate. With PythoC, although, after you have your compiled C executable, anybody can run it simply by double-clicking on the file.

And who it’s not for

The flip facet of the above is that PythoC might be not one of the best software for an internet developer, as efficiency bottlenecks there are often community or database speeds, not CPU calculation speeds.

Likewise, in case you are already a person of optimised libraries corresponding to NumPy, you received’t see many advantages both.

Abstract

This text launched to you the comparatively new and unknown PythoC library. With it, you should utilize Python to create super-fast stand-alone C executable code.

I gave a number of examples of utilizing Python and the PythoC library to provide C executable applications, together with one which confirmed an unbelievable speedup when working the executable produced by the PythoC library in comparison with an ordinary Python program. 

One subject you’ll run into is that Python imports aren’t supported in PythoC applications, however I additionally confirmed work round this by changing them with equal C built-ins.

Lastly, I mentioned who I believed had been the sorts of Python programmers who may see a profit in utilizing PythonC of their workloads, and people who wouldn’t. 

I hope this has whetted your urge for food for seeing what sorts of use instances you’ll be able to leverage PythoC for. You possibly can be taught far more about this convenient library by trying out the GitHub repo on the following hyperlink.

https://github.com/1flei/PythoC