Foreign Function Interfaces (FFI)
To reduce the sizes of smartcontracts, we provide a dynamic library in the execution environment. We shall detail how to link against that library and use the functions at a later date, but for now, let's explore how to include functions and trait implementations into that library.
Why FFI
A function is a rather abstract entity, and while most languages agree on what a function should do, the way in which said functions are represented is very different. Moreover, in some languages (like Rust), the consequences of calling a function, and the things that it is allowed to do are different. Because one can use any language to create a WASM smartcontract, we need to level the playing field. This is where the concept of foreign function interface (FFI) comes in.
The main standard used today is the C application binary interface. It's simple, it's guaranteed to be available even in languages which can't compile to WASM, and it's stable. In principle, you could do everything manually, but Iroha provides you with a crate iroha_ffi
which contains all you need to generate FFI-compliant functions out of your existing Rust
API.
You can, of course, do this your way. The iroha_ffi
crate merely generates the code that you would need to generate anyway. Writing the necessary boilerplate requires quite a bit of diligence and discipline. Every function call over the FFI boundary is unsafe
with a potential to cause undefined behaviour. The method by which we managed to solve it, revolves around using robust repr(C)
types.
INFO
The only exception are pointers. The null check and the validity cannot be enforced globally, so raw pointers (as always) are only used in exceptional cases. Given that we provide wrappers around almost every instance of an object in the Iroha data model, you shouldn't have to use raw pointers at all.
Example
Here is an example of generating a binding:
#[derive(FfiType)]
struct DaysSinceEquinox(u32);
#[ffi_export]
impl DaysSinceEquinox {
pub fn update_value(&mut self, a: &u8) {
self.0 = *a as u32;
}
}
The example above will generate the following binding with DaysSinceEquinox
represented as an opaque pointer:
pub extern fn DaysSinceEquinox__update_value(handle: *mut DaysSinceEquinox, a: *const u8) -> FfiReturn {
// function implementation
}
FFI Binding Generation
The iroha_ffi
crate is used to generate functions that are callable via FFI. Given Rust
structs and methods, they generate the unsafe
code that you would need in order to cross the linking boundary.
A Rust type is converted into a robust repr(C)
type that can cross the FFI boundary with FfiType::into_ffi
. This goes the other way around as well: FFI ReprC
type is converted into a Rust
type via FfiType::try_from_ffi
.
WARNING
Note that the opposite conversion is fallible and can cause undefined behaviour. While we can make the best effort to avoid the most obvious mistakes, you must ensure the program's correctness on your end.
The diagram below uses the creation of a new domain as an example to show the conversion process (more on the name mangling semantics in a separate section).
The main traits that enable binding generation are ReprC
, FfiType
and FfiConvert
Trait | Description |
---|---|
ReprC | This trait represents a robust type that conforms to C ABI. The type can be safely shared across FFI boundaries. |
FfiType | This trait defines a corresponding ReprC type for a given Rust type. The defined ReprC type is used in place of the Rust type in the API of the generated FFI function. |
FfiConvert | This trait defines two methods into_ffi and try_from_ffi that are used to perform the conversion of the Rust type to or from ReprC type. |
Note that there is no ownership transfer over FFI except for opaque pointer types. All other types that carry ownership, such as Vec<T>
, are cloned.
Name Mangling
Note the use of double underscores in generated names of FFI objects:
For the
inherent_fn
method defined on theStructName
struct, the FFI name would beStructName__inherent_fn
.For the
MethodName
method from theTraitName
trait in theStructName
struct, the FFI name would beStructName__TraitName__MethodName
.To set the
field_name
field in theStructName
struct, the FFI function name would beStructName__set_field_name
.To get the
field_name
field in theStructName
struct, the FFI function name would beStructName__field_name
.To get the mutable
field_name
field in theStructName
struct, the FFI function name would beStrucuName__field_name_mut
.For the freestanding
module_name::fn_name
, the FFI name would bemodule_name::__fn_name
.For the traits that are not generic and allow sharing their implementation in the FFI (see
Clone
below), the FFI name would bemodule_name::__clone
.rustimpl Clone for Type1 { fn clone(&self) -> Self; } impl Clone for Type2 { fn clone(&self) -> Self; }