|
|
||
|---|---|---|
| build | ||
| cli | ||
| docs | ||
| src | ||
| tests | ||
| .gitignore | ||
| AUTHORS | ||
| LICENSE | ||
| README.md | ||
Pocketlang is a small (~3000 semicollons) and fast functional language written in C. It's syntactically similar to Ruby and it can be learned within 15 minutes. Including the compiler, bytecode VM and runtime, it's a standalone executable with zero external dependecies just as it's self descriptive name. The pocketlang VM can be embedded in another hosting program very easily.
The language is written using Wren Language and their wonderful book Crafting Interpreters as a reference.
What pocketlang looks like
# Python like import statement.
from lang import clock as now
# A recursive fibonacci function.
def fib(n)
if n < 2 then return n end
return fib(n-1) + fib(n-2)
end
# Prints all fibonacci from 0 to 10 exclusive.
for i in 0..10
print(fib(i))
end
Try It Now
You can try pocketlang on your browser. It's a WebAssembly build of the VM compiled using emscripten. Note that in the webassembly version of the language, some features (input, file handling, relative import, etc.) have disabled, has limited memory allocations, and the stdout calls might be slower.
Documentation
The pocketlang documentation is hosted at https://thakeenathees.github.io/pocketlang/ which
is built from the docs branch generated by a little python script at docs/generate.py.
Note that the documentations are WIP and might not be up to date.
Performance
Pocketlang supports tail call optimization. When a function returns a call, the callee can re-use the caller's stack frame, this will optimize memory from O(n) to O(1) and for tail recursive it'll completely prevent stackoverflows and yet it's faster then tco disabled.
All the below benchmarks are ran on, Windows10 (64bit), ASUS N552VX, Intel Core i7-6700HQ 2.6GHz with 12GB SODIMM Ram. And the language versions are: pocketlang (pre-alpha), wren v0.3.0, python v3.7.4, ruby v2.7.2.
The source files used to run benchmarks could be found at test/benchmarks/
directory. They were ran using a small python script in the test directory.
Building From Source
See build documentation
for using an optional build script (Makefile, batch script for MSVC, SCons found in the build/ directory).
It can be build from source easily without any depencency, or additional
requirenments except for a c99 compatible compiler. It can be compiled with the
following command.
GCC
gcc -o pocket cli/*.c src/*.c -Isrc/include -lm -Wno-int-to-pointer-cast
MSVC
cl /Fepocket cli/*.c src/*.c /Isrc/include && rm *.obj
For other compiler/IDE
- Create an empty project file / makefile.
- Add all C files in the src directory.
- Add all C files in the cli directory (not recursively).
- Add
src/includeto include path. - Compile.
If you weren't able to compile it, please report by opening an issue.
References
-
Bob Nystrom.(2021) craftinginterpreters [online] Available at www.craftinginterpreters.com/ (Accessed January 2021)
-
Mark W. Bailey, Nathan C. Weston (June 2001) Technical report. Performance Benefits of Tail Recursion Removal in Procedural Languages [online] Available at http://cs.hamilton.edu/~mbailey/pubs/techreps/TR-2001-2.pdf
-
Leonard sch<63>tz.(2020) Dynamic Typing and NaN Boxing [online] Available at https://leonardschuetz.ch/blog/nan-boxing/ (Accessed December 2020)
-
Bob Nystrom.(2011) Pratt Parsers: Expression Parsing Made Easy [online] Avaliable at http://journal.stuffwithstuff.com/2011/03/19/pratt-parsers-expression-parsing-made-easy/ (Accessed December 2020)
-
Carol E. (Wolf of Pace University), P. Oser. The Shunting Yard Algorithm [online] Available at http://mathcenter.oxford.emory.edu/site/cs171/shuntingYardAlgorithm/ (Accessed September 2020)