3 releases
0.1.4 | Dec 7, 2023 |
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0.1.1 | Oct 22, 2023 |
0.1.0 | Oct 22, 2023 |
#1745 in Procedural macros
29 downloads per month
4KB
ferment
Syntax-tree morphing tool for FFI (work in progress)
Allows to generate an FFI-compliant equivalent for rust types (structures, enums, types, functions).
The project is a rust-workspace consisting several crates:
ferment-interfaces
: A traits that provide conversion methods from/to FFI-compatible types and some helper functions and structuresferment-macro
: a procedural macro that just catch target code as syn-based item.ferment-example
: provides basic example.ferment-example-nested
: provides example with dependent fermented crate.ferment
: a tool for morphing FFI-compatible syntax trees that uses the power of thesyn
crate.
A procedural macro consists of 2 macros:
export
- for structures / enums / functions / typesregister
- for custom-defined conversions
Usage
Crate is not published yet, so use it for example locally
ferment-interfaces = { path = "../../ferment/ferment-interfaces" }
ferment-macro = { path = "../../ferment/ferment-macro" }
ferment = { path = "../../ferment/ferment" }
Using the tool implies using cbindgen
with a configuration like this:
extern crate cbindgen;
fn main() {
extern crate cbindgen;
extern crate ferment;
use std::process::Command;
fn main() {
match ferment::Builder::new()
.with_mod_name("fermented")
.with_crates(vec![])
.generate() {
Ok(()) => match Command::new("cbindgen")
.args(&["--config", "cbindgen.toml", "-o", "target/example.h"])
.status() {
Ok(status) => println!("Bindings generated into target/example.h with status: {}", status),
Err(err) => panic!("Can't generate bindings: {}", err)
}
Err(err) => panic!("Can't create FFI expansion: {}", err)
}
}
}
Examples
For traits marked for export like this:
#[ferment_macro::export]
pub trait IHaveChainSettings {
fn name(&self) -> String;
}
You can also use macro with comma-separated trait names
#[ferment_macro::export(IHaveChainSettings)]
pub enum ChainType {
MainNet,
TestNet,
DevNet(DevnetType)
}
This will expose bindings for trait methods for particular types
For the structure labeled with ferment::export
#[derive(Clone)]
#[ferment_macro::export]
pub struct LLMQSnapshot {
pub member_list: Vec<u8>,
pub skip_list: Vec<i32>,
pub skip_list_mode: LLMQSnapshotSkipMode,
pub option_vec: Option<Vec<u8>>,
}
the following code with FFI-compatible fields and corresponding from/to conversions will be generated:
#[doc = "FFI-representation of the "crate::model::snapshot::LLMQSnapshot""]
#[repr(C)]
#[derive(Clone)]
#[allow(non_camel_case_types)]
pub struct LLMQSnapshot {
pub member_list: *mut crate::fermented::generics::Vec_u8,
pub skip_list: *mut crate::fermented::generics::Vec_i32,
pub skip_list_mode: *mut crate::fermented::types::model::snapshot::LLMQSnapshotSkipMode,
pub option_vec: *mut crate::fermented::generics::Vec_u8,
}
impl ferment_interfaces::FFIConversion<crate::model::snapshot::LLMQSnapshot> for LLMQSnapshot {
unsafe fn ffi_from_const(ffi: *const LLMQSnapshot) -> crate::model::snapshot::LLMQSnapshot {
let ffi_ref = &*ffi;
crate::model::snapshot::LLMQSnapshot {
member_list: ferment_interfaces::FFIConversion::ffi_from(ffi_ref.member_list),
skip_list: ferment_interfaces::FFIConversion::ffi_from(ffi_ref.skip_list),
skip_list_mode: ferment_interfaces::FFIConversion::ffi_from(ffi_ref.skip_list_mode),
option_vec: ferment_interfaces::FFIConversion::ffi_from_opt(ffi_ref.option_vec),
}
}
unsafe fn ffi_to_const(obj: crate::model::snapshot::LLMQSnapshot) -> *const LLMQSnapshot {
ferment_interfaces::boxed(LLMQSnapshot {
member_list: ferment_interfaces::FFIConversion::ffi_to(obj.member_list),
skip_list: ferment_interfaces::FFIConversion::ffi_to(obj.skip_list),
skip_list_mode: ferment_interfaces::FFIConversion::ffi_to(obj.skip_list_mode),
option_vec: match obj.option_vec {
Some(vec) => ferment_interfaces::FFIConversion::ffi_to(vec),
None => std::ptr::null_mut(),
},
})
}
unsafe fn destroy(ffi: *mut LLMQSnapshot) {
ferment_interfaces::unbox_any(ffi);
}
}
impl Drop for LLMQSnapshot {
fn drop(&mut self) {
unsafe {
let ffi_ref = self;
ferment_interfaces::unbox_any(ffi_ref.member_list);
ferment_interfaces::unbox_any(ffi_ref.skip_list);
<crate::fermented::types::model::snapshot::LLMQSnapshotSkipMode as ferment_interfaces::FFIConversion<crate::model::snapshot::LLMQSnapshotSkipMode>>::
destroy(ffi_ref.skip_list_mode);
if !ffi_ref.option_vec.is_null() {
ferment_interfaces::unbox_any(ffi_ref.option_vec);
};
}
}
}
#[doc = "# Safety"]
#[allow(non_snake_case)]
#[no_mangle]
pub unsafe extern "C" fn LLMQSnapshot_ctor(
member_list: *mut crate::fermented::generics::Vec_u8,
skip_list: *mut crate::fermented::generics::Vec_i32,
skip_list_mode: *mut crate::fermented::types::model::snapshot::LLMQSnapshotSkipMode,
option_vec: *mut crate::fermented::generics::Vec_u8)
-> *mut LLMQSnapshot {
ferment_interfaces::boxed(LLMQSnapshot {
member_list,
skip_list,
skip_list_mode,
option_vec,
})
}
#[doc = "# Safety"]
#[allow(non_snake_case)]
#[no_mangle]
pub unsafe extern "C" fn LLMQSnapshot_destroy(ffi: *mut LLMQSnapshot) {
ferment_interfaces::unbox_any(ffi);
}
For the function labeled with export
#[ferment_macro::export]
pub fn address_with_script_pubkey(script: Vec<u8>) -> Option<String> {
Some(format_args!("{0:?}", script).to_string())
}
the following code will be generated:
#[doc = "FFI-representation of the "address_with_script_pubkey""]
#[doc = "# Safety"]
#[no_mangle]
pub unsafe extern "C" fn ffi_address_with_script_pubkey(script: *mut crate::fermented::generics::Vec_u8) -> *mut std::os::raw::c_char {
let conversion = ferment_interfaces::FFIConversion::ffi_from(script);
let obj = crate::example::address::address_with_script_pubkey(conversion);
ferment_interfaces::FFIConversion::ffi_to_opt(obj)
}
For type aliases labeled with export
#[ferment::export]
pub type HashID = [u8; 32];
the following code will be generated in crate::fermented::types::*
with similar conversions and bindings:
#[repr(C)]
#[derive(Clone, Debug)]
pub struct HashID(*mut [u8; 32]);
For traits labeled with export
#[ferment_macro::export]
pub trait IHaveChainSettings {
// ..
}
There will be vtable and trait obj generated
#[repr(C)]
#[derive(Clone)]
#[allow(non_camel_case_types)]
pub struct IHaveChainSettings_VTable {
// ..
}
#[repr(C)]
#[derive(Clone)]
#[allow(non_camel_case_types)]
pub struct IHaveChainSettings_TraitObject {
pub object: *const (),
pub vtable: *const IHaveChainSettings_VTable,
}
and bindings for their implementors like this:
#[doc = "# Safety"]
#[allow(non_snake_case)]
#[no_mangle]
pub extern "C" fn ChainType_as_IHaveChainSettings_TraitObject(
obj: *const crate::chain::common::chain_type::ChainType)
-> IHaveChainSettings_TraitObject {
IHaveChainSettings_TraitObject {
object: obj as *const (),
vtable: &ChainType_IHaveChainSettings_VTable,
}
}
#[doc = "# Safety"]
#[allow(non_snake_case)]
#[no_mangle]
pub unsafe extern "C" fn ChainType_as_IHaveChainSettings_TraitObject_destroy(obj: IHaveChainSettings_TraitObject) {
ferment_interfaces::unbox_any(obj.object as *mut crate::chain::common::chain_type::ChainType);
}
using this code cbindgen will be able to generate binding
struct IHaveChainSettings_TraitObject ChainType_as_IHaveChainSettings_TraitObject(const struct ChainType *obj);
void ChainType_as_IHaveChainSettings_TraitObject_destroy(struct IHaveChainSettings_TraitObject obj);
Current limitations:
- We should mark all structures that involved into export with the macro definition
- There is some difficulty with handling type aliases. Therefore, if possible, they should be avoided. Because, in order to guarantee that it can be processed, one has to wrap it in an unnamed struct. Which is, for most cases, less efficient than using the type it uses directly. That is,
pub type KeyID = u32
becomespub struct KeyID_FFI(u32)
There will be a support at some point.
Generic mangling rules
Conversion follows some mangling rules and gives the name for ffi structure. Examples for translated names:
Vec<u8>
->Vec_u8
Vec<u32>
->Vec_u32
Vec<Vec<u32>>
->Vec_Vec_u32
BTreeMap<HashID, Vec<u32>>
->std_collections_Map_keys_crate_HashID_values_Vec_u32
BTreeMap<HashID, Vec<u32>>
->std_collections_Map_keys_u32_values_Vec_u32
BTreeMap<HashID, BTreeMap<HashID, Vec<u32>>>
->std_collections_Map_keys_crate_HashID_values_std_collections_Map_keys_crate_HashID_values_Vec_u32
- etc
Then macro implements the necessary conversions for these structures. Example for BTreeMap<HashID, Vec<HashID>>
:
#[repr(C)]
#[derive(Clone)]
#[allow(non_camel_case_types)]
pub struct std_collections_Map_keys_crate_nested_HashID_values_Vec_crate_nested_HashID {
pub count: usize,
pub keys: *mut *mut crate::fermented::types::nested::HashID,
pub values: *mut *mut crate::fermented::generics::Vec_crate_nested_HashID,
}
impl ferment_interfaces::FFIConversion<std::collections::BTreeMap<crate::nested::HashID, Vec<crate::nested::HashID>>>
for std_collections_Map_keys_crate_nested_HashID_values_Vec_crate_nested_HashID {
unsafe fn ffi_from_const(
ffi: *const std_collections_Map_keys_crate_nested_HashID_values_Vec_crate_nested_HashID)
-> std::collections::BTreeMap<crate::nested::HashID, Vec<crate::nested::HashID>> {
let ffi_ref = &*ffi;
ferment_interfaces::from_complex_map(ffi_ref.count, ffi_ref.keys, ffi_ref.values)
}
unsafe fn ffi_to_const(
obj: std::collections::BTreeMap<crate::nested::HashID, Vec<crate::nested::HashID>>)
-> *const std_collections_Map_keys_crate_nested_HashID_values_Vec_crate_nested_HashID {
ferment_interfaces::boxed(Self {
count: obj.len(),
keys: ferment_interfaces::to_complex_vec(obj.keys().cloned()),
values: ferment_interfaces::to_complex_vec(obj.values().cloned()),
})
}
unsafe fn destroy(ffi: *mut std_collections_Map_keys_crate_nested_HashID_values_Vec_crate_nested_HashID) {
ferment_interfaces::unbox_any(ffi);
}
}
impl Drop for std_collections_Map_keys_crate_nested_HashID_values_Vec_crate_nested_HashID {
fn drop(&mut self) {
unsafe {
ferment_interfaces::unbox_any_vec_ptr(self.keys, self.count);
ferment_interfaces::unbox_any_vec_ptr(self.values, self.count);
}
}
}
The final generated code is placed in the file specified in the configuration like this:
pub mod types {
// package relationships are inherited
// so type like crate::some_module::SomeStruct will be expanded like this:
pub mod some_module {
pub struct SomeStruct {
// ...
}
}
}
pub mod generics {
// We expand generic types separately here to avoid duplication
#[allow(non_camel_case_types)]
pub struct std_collections_Map_keys_crate_nested_HashID_values_Vec_crate_nested_HashID {
// ..
}
}
Manual conversion support
- We can use
[ferment_macro::register(SomeFFIIncompatibleStructOrWhatever)]
- It allows us to manually create custom conversions for types.
- It's especially important for non-fermentable code like types from rust std lib or from any other 3-rd party-crates.
- Example
Dependencies
~1.5MB
~37K SLoC