1. The hard, universal and "write once, run everywhere" approach:
Your programming language enforces the user to somehow provide declarations of C functions to be used (as well as their implementation, most probably as a dynamically linkable/loadable library). Your programming language parser/compiler/interpreter interprets the function signature, and possibly uses a foreign function interface library, such as libFFI, to make calls that obey the ABI and C calling convention of the platform. This way one can call any C function from within your language without writing bindings.
This method is used in a few programming languages, for example PyObjC is a library that makes it possible for Python programmers to directly call Objective-C APIs from Python.
2. The easy, not-even-close-to-universal and "write as many times as you want to use it" way:
You require the user of your programming language to write the C extension functions with a signature specified beforehands, i. e. all programming language extensions should look like
GenericValueType *extension_function(int argc, GenericValueType **argv);
and then whoever wants to connect some other code to your programming language has to write bindings using a function and the dedicated API of your programming language. For example, if you wanted to use the strlen()
function from the C standard library, you would write this (pseudoo-)code:
GenericValueType *my_ext_strlen(int argc, GenericValueType **argv)
{
GenericValueType *arg1 = argv[0];
const char *input = ValueToCString(arg1);
size_t len = strlen(input);
return NewValueFromInteger(len);
}
This is easier to implement for the creator of the language, but as I mentioned it before, it's not universal - every function has to be bound/ported to be compatible. This is the approach that most scripting languages take, for example Python, PHP and Lua require bindings to external libraries to be written in this way.