orca/ext/wasm3/platforms/cpp/README.md

99 lines
3.8 KiB
Markdown
Raw Permalink Normal View History

2023-04-12 14:21:03 +00:00
## C++ wrapper
This example shows how to embed WASM3 into a C++ application. It uses a header-only library, `wasm3_cpp.h`, provided in `wasm3_cpp` subdirectory. Like WASM3 itself, this library can be included into CMake projects using `add_subdirectory` function.
The main code of the example in `main.cpp` initializes WASM3, loads a WebAssembly module, links two external functions to the module, and executes two functions defined in WebAssembly.
The WebAssembly module source code is inside `wasm` subdirectory.
### `wasm3_cpp.h` reference
All the classes are located in `wasm3` namespace.
#### Class `environment`
`environment::environment()` — create a new WASM3 environment. Runtimes, modules are owned by an environment.
`runtime environment::new_runtime(size_t stack_size_bytes)` — create new runtime inside the environment.
`module environment::parse_module(std::istream &in)` or `module environment::parse_module(const uint8_t *data, size_t size)` — parse a WASM binary module.
#### Class `runtime`
`runtime` objects are created using `environment::new_runtime` method, see above.
`void runtime::load(module &m)` — load a parsed module into the runtime.
`function runtime::find_function(const char *name)` — find a function defined in one of the loaded modules, by name. Raises a `wasm3::error` exception if the function is not found.
#### Class `module`
`module` objects are created by `environment::parse_module`. Parsed modules can be loaded into a `runtime` object. One module can only be loaded into one runtime.
Before loading a module, you may need to link some external functions to it:
`template <Func> void module::link(const char *mod, const char *function_name, Func *function)` — link a function `function` to module named `mod` under the name `function_name`. To link to any module, use `mod="*"`.
`function` has to be either a non-member function or a static member function.
Currently, the following types of arguments can be passed to functions linked this way:
* int32_t
* int64_t
* float
* double
* const/non-const pointers
Automatic conversion of other integral types may be implemented in the future.
If the module doesn't reference an imported function named `func`, an exception is thrown. To link a function "optionally", i.e. without throwing an exception if the function is not imported, use `module::link_optional` instead.
#### Class `function`
`function` object can be obtained from a `runtime`, looking up the function by name. Function objects are used to call WebAssembly functions.
`template <typename Ret = void, typename ...Args> Ret function::call(Args...)` — calls a WebAssembly function with or without arguments and a return value.<br>
The return value of the function, if not `void`, is automatically converted to the type `Ret`.<br>
Note that you always need to specify the matching return type when using this template with a non-void function.<br>
Examples:
```cpp
// WASM signature: [] → []
func.call();
// WASM signature: [i32, i32] → []
func.call(42, 43); // implicit argument types
// WASM signature: [i32, i64] → []
func.call<void, int32_t, int64_t>(42, 43); // explicit argument types require the return type
// WASM signature: [] → [i32]
auto result = func.call<int32_t>();
// WASM signature: [i32, i32] → [i64]
auto result = func.call<int64_t>(42, 43); // implicit argument types
// WASM signature: [i32, i64] → [i64]
auto result = func.call<int64_t, int32_t, int64_t>(42, 43); // explicit argument types
```
`template <typename Ret, typename ...Args> Ret function::call_argv(Args...)` — same as above, except that this function takes arguments as C strings (`const char*`).
### Building and running
This directory is a CMake project, and can be built as follows:
```bash
mkdir build
cd build
cmake ..
cmake --build .
```
Then run the example:
```bash
./wasm3_cpp_example
```