A minimalistic programming language written in C89.
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Ludovic 'Archivist' Lagouardette f9ed5f3fb8 additional cleanup: fixes the cleanup of NULL routines 2 viikkoa sitten
include Merge branch 'main' of https://git.nekoit.xyz/Archivist/ink 2 viikkoa sitten
test added parsing of string literals 4 kuukautta sitten
.gitignore Fixed a bug where routine list was not properly resized 6 kuukautta sitten
CMakeLists.txt added better error feedback and detection 2 kuukautta sitten
LICENSE Added README.md contents 6 kuukautta sitten
README.md made the allocations and printing aware of the context 2 kuukautta sitten
bench.c Reorganized the project to move headers in their own directory 5 kuukautta sitten
lib.c additional cleanup: fixes the cleanup of NULL routines 2 viikkoa sitten
main.c Added comments and fixed bugs\n\n- Added array.set\n- Added comments support\n- Fixed weird push/pop mismatches\n- Added more docs\n- Fixed examples 5 kuukautta sitten

README.md

ink

ink is a minimalistic interpreted programming language, tentatively implemented exclusively in C89. It features coroutines and can currently only manipulate integers. Part of the code may not be compliant with C89 and I will try to fix that in time.

It is fully self-contained and doesn't rely on a working standard library beyond the following:

  • malloc
  • realloc
  • free
  • putchar

These functions need to be wrapped, the wrapper allows to make them stateful to keep individual heaps per context, allowing to clean the context by cleaning up its allocations.

To make the library not use the standard library, build it with NOSTDLIB defined as a preprocessor directive.

All of these functions need to work for ink to work. It is easy to add new functions to the interpreter. I added a garbage collector to handle cleaning dynamically allocated resources.

It is possible to segregate unsafe allocations (allocations that should be hidden from the interpreter) by setting the inner_ versions of the library functions to different allocation functions.

Limits

  • Token size is limited to 127 bytes (see ink_lex)
  • Values and indices are limited to the platform size of int
  • Main function has a size limit of 256 tokens (see ink_compile)
  • Functions have a size limit of 256 tokens (see ink_parse)
  • Functions have a count limit 128 labels (see ink_parse)
  • Only non-main functions can use labels

Examples

Hello World

[ 72 101 108 108 111 32 87 111 114 108 100 10 ] 
    array.print_utf8

Clone array

# Clones an array, creating a new array
# 
# @param array The array to clone into a new array
# @return a new array that contains the same elements as the source array
# 
# array -> new_array
fn array.clone do
    array.new 2 pluck array.size 0
    # array new_array end it
    2 pluck 2 pluck == end_loop jump_if
    # array new_array end it
    loop:
        dup 5 pluck
        # array new_array end it it array
        array.index 4 pluck
        # array new_array end it v new_array
        array.push
        # array new_array end it
        1 +
   2 pluck 2 pluck > loop jump_if
   end_loop: drop drop swap drop
   # new_array
end

+% encryption

Encrypts a string with (v + add_key) % modulo_key. It modifies the array that was passed in.

# Encrypts things by doing `(v + add_key) % modulo_key`
#
# @param array An array of ints representing a string
# @param add_key Should be lower than the add key
# @param modulo_key Should ke higher than all the codepoints of the array
#
# array add_key modulo_key
fn encrypt do
    3 pluck array.size
    # array add_key modulo_key index
    loop:
        1 - dup 5 pluck
        # array add_key modulo_key index index array
        array.index
        # array add_key modulo_key index v
        4 pluck +
        # array add_key modulo_key index (v + add_key)
        3 pluck %
        # array add_key modulo_key index ((v + add_key) % modulo_key)
        2 pluck
        # array add_key modulo_key index ((v + add_key) % modulo_key) index
        6 pluck
        # array add_key modulo_key index ((v + add_key) % modulo_key) index array
        array.set
        # array add_key modulo_key index
    dup 0 != loop jump_if drop drop drop drop
end

# Prints a string as an array of ints
#
# @param array An array of ints representing a string
#
# array
fn string.dump do
    dup array.size 0
    # array end it
    91 print_utf8
    32 print_utf8
    loop:
        dup
        # array end it it
        4 pluck
        # array end it it array
        array.index print_int
        32 print_utf8
        1 +
        # array end it
    2 pluck 2 pluck > loop jump_if
    # array end it
    93 print_utf8
end
[ 72 101 108 108 111 32 87 111 114 108 100 10 ] 
    dup 
    32 128 encrypt 
    string.dump