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denoland-deno/ext/ffi/call.rs
Divy Srivastava a2db70a8d0
refactor(ext/ffi): split into multiple parts (#16950)
- [x] `dlfcn.rs` - `dlopen()`-related code.
- [x] `turbocall.rs` - Call trampoline JIT compiler. 
- [x] `repr.rs` - Pointer representation. Home of the UnsafePointerView
ops.
- [x] `symbol.rs` - Function symbol related code.
- [x] `callback.rs` - Home of `Deno.UnsafeCallback` ops.
- [x] `ir.rs` - Intermediate representation for values. Home of the
`NativeValue` type.
- [x] `call.rs` - Generic call ops. Home to everything related to
calling FFI symbols.
- [x] `static.rs` - static symbol support

I find easier to work with this setup, I eventually want to expand
TurboCall to unroll type conversion loop in generic calls, generate code
for individual symbols (lazy function pointers), etc.
2022-12-12 14:14:20 +00:00

335 lines
9.8 KiB
Rust

// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license.
use crate::callback::PtrSymbol;
use crate::check_unstable2;
use crate::dlfcn::DynamicLibraryResource;
use crate::ir::*;
use crate::symbol::NativeType;
use crate::symbol::Symbol;
use crate::FfiPermissions;
use crate::ForeignFunction;
use deno_core::anyhow::anyhow;
use deno_core::error::type_error;
use deno_core::error::AnyError;
use deno_core::op;
use deno_core::serde_json::Value;
use deno_core::serde_v8;
use deno_core::v8;
use deno_core::ResourceId;
use libffi::middle::Arg;
use std::cell::RefCell;
use std::ffi::c_void;
use std::future::Future;
use std::rc::Rc;
// A one-off synchronous FFI call.
pub(crate) fn ffi_call_sync<'scope>(
scope: &mut v8::HandleScope<'scope>,
args: v8::FunctionCallbackArguments,
symbol: &Symbol,
) -> Result<NativeValue, AnyError>
where
'scope: 'scope,
{
let Symbol {
parameter_types,
result_type,
cif,
ptr: fun_ptr,
..
} = symbol;
let mut ffi_args: Vec<NativeValue> =
Vec::with_capacity(parameter_types.len());
for (index, native_type) in parameter_types.iter().enumerate() {
let value = args.get(index as i32);
match native_type {
NativeType::Bool => {
ffi_args.push(ffi_parse_bool_arg(value)?);
}
NativeType::U8 => {
ffi_args.push(ffi_parse_u8_arg(value)?);
}
NativeType::I8 => {
ffi_args.push(ffi_parse_i8_arg(value)?);
}
NativeType::U16 => {
ffi_args.push(ffi_parse_u16_arg(value)?);
}
NativeType::I16 => {
ffi_args.push(ffi_parse_i16_arg(value)?);
}
NativeType::U32 => {
ffi_args.push(ffi_parse_u32_arg(value)?);
}
NativeType::I32 => {
ffi_args.push(ffi_parse_i32_arg(value)?);
}
NativeType::U64 => {
ffi_args.push(ffi_parse_u64_arg(scope, value)?);
}
NativeType::I64 => {
ffi_args.push(ffi_parse_i64_arg(scope, value)?);
}
NativeType::USize => {
ffi_args.push(ffi_parse_usize_arg(scope, value)?);
}
NativeType::ISize => {
ffi_args.push(ffi_parse_isize_arg(scope, value)?);
}
NativeType::F32 => {
ffi_args.push(ffi_parse_f32_arg(value)?);
}
NativeType::F64 => {
ffi_args.push(ffi_parse_f64_arg(value)?);
}
NativeType::Buffer => {
ffi_args.push(ffi_parse_buffer_arg(scope, value)?);
}
NativeType::Pointer => {
ffi_args.push(ffi_parse_pointer_arg(scope, value)?);
}
NativeType::Function => {
ffi_args.push(ffi_parse_function_arg(scope, value)?);
}
NativeType::Void => {
unreachable!();
}
}
}
let call_args: Vec<Arg> = ffi_args.iter().map(Arg::new).collect();
// SAFETY: types in the `Cif` match the actual calling convention and
// types of symbol.
unsafe {
Ok(match result_type {
NativeType::Void => NativeValue {
void_value: cif.call::<()>(*fun_ptr, &call_args),
},
NativeType::Bool => NativeValue {
bool_value: cif.call::<bool>(*fun_ptr, &call_args),
},
NativeType::U8 => NativeValue {
u8_value: cif.call::<u8>(*fun_ptr, &call_args),
},
NativeType::I8 => NativeValue {
i8_value: cif.call::<i8>(*fun_ptr, &call_args),
},
NativeType::U16 => NativeValue {
u16_value: cif.call::<u16>(*fun_ptr, &call_args),
},
NativeType::I16 => NativeValue {
i16_value: cif.call::<i16>(*fun_ptr, &call_args),
},
NativeType::U32 => NativeValue {
u32_value: cif.call::<u32>(*fun_ptr, &call_args),
},
NativeType::I32 => NativeValue {
i32_value: cif.call::<i32>(*fun_ptr, &call_args),
},
NativeType::U64 => NativeValue {
u64_value: cif.call::<u64>(*fun_ptr, &call_args),
},
NativeType::I64 => NativeValue {
i64_value: cif.call::<i64>(*fun_ptr, &call_args),
},
NativeType::USize => NativeValue {
usize_value: cif.call::<usize>(*fun_ptr, &call_args),
},
NativeType::ISize => NativeValue {
isize_value: cif.call::<isize>(*fun_ptr, &call_args),
},
NativeType::F32 => NativeValue {
f32_value: cif.call::<f32>(*fun_ptr, &call_args),
},
NativeType::F64 => NativeValue {
f64_value: cif.call::<f64>(*fun_ptr, &call_args),
},
NativeType::Pointer | NativeType::Function | NativeType::Buffer => {
NativeValue {
pointer: cif.call::<*mut c_void>(*fun_ptr, &call_args),
}
}
})
}
}
fn ffi_call(
call_args: Vec<NativeValue>,
cif: &libffi::middle::Cif,
fun_ptr: libffi::middle::CodePtr,
parameter_types: &[NativeType],
result_type: NativeType,
) -> Result<NativeValue, AnyError> {
let call_args: Vec<Arg> = call_args
.iter()
.enumerate()
.map(|(index, ffi_arg)| {
// SAFETY: the union field is initialized
unsafe { ffi_arg.as_arg(*parameter_types.get(index).unwrap()) }
})
.collect();
// SAFETY: types in the `Cif` match the actual calling convention and
// types of symbol.
unsafe {
Ok(match result_type {
NativeType::Void => NativeValue {
void_value: cif.call::<()>(fun_ptr, &call_args),
},
NativeType::Bool => NativeValue {
bool_value: cif.call::<bool>(fun_ptr, &call_args),
},
NativeType::U8 => NativeValue {
u8_value: cif.call::<u8>(fun_ptr, &call_args),
},
NativeType::I8 => NativeValue {
i8_value: cif.call::<i8>(fun_ptr, &call_args),
},
NativeType::U16 => NativeValue {
u16_value: cif.call::<u16>(fun_ptr, &call_args),
},
NativeType::I16 => NativeValue {
i16_value: cif.call::<i16>(fun_ptr, &call_args),
},
NativeType::U32 => NativeValue {
u32_value: cif.call::<u32>(fun_ptr, &call_args),
},
NativeType::I32 => NativeValue {
i32_value: cif.call::<i32>(fun_ptr, &call_args),
},
NativeType::U64 => NativeValue {
u64_value: cif.call::<u64>(fun_ptr, &call_args),
},
NativeType::I64 => NativeValue {
i64_value: cif.call::<i64>(fun_ptr, &call_args),
},
NativeType::USize => NativeValue {
usize_value: cif.call::<usize>(fun_ptr, &call_args),
},
NativeType::ISize => NativeValue {
isize_value: cif.call::<isize>(fun_ptr, &call_args),
},
NativeType::F32 => NativeValue {
f32_value: cif.call::<f32>(fun_ptr, &call_args),
},
NativeType::F64 => NativeValue {
f64_value: cif.call::<f64>(fun_ptr, &call_args),
},
NativeType::Pointer | NativeType::Function | NativeType::Buffer => {
NativeValue {
pointer: cif.call::<*mut c_void>(fun_ptr, &call_args),
}
}
})
}
}
#[op(v8)]
pub fn op_ffi_call_ptr_nonblocking<'scope, FP>(
scope: &mut v8::HandleScope<'scope>,
state: Rc<RefCell<deno_core::OpState>>,
pointer: usize,
def: ForeignFunction,
parameters: serde_v8::Value<'scope>,
) -> Result<impl Future<Output = Result<Value, AnyError>>, AnyError>
where
FP: FfiPermissions + 'static,
{
check_unstable2(&state, "Deno.UnsafeFnPointer#call");
{
let mut state = state.borrow_mut();
let permissions = state.borrow_mut::<FP>();
permissions.check(None)?;
};
let symbol = PtrSymbol::new(pointer, &def);
let call_args = ffi_parse_args(scope, parameters, &def.parameters)?;
let join_handle = tokio::task::spawn_blocking(move || {
let PtrSymbol { cif, ptr } = symbol.clone();
ffi_call(call_args, &cif, ptr, &def.parameters, def.result)
});
Ok(async move {
let result = join_handle
.await
.map_err(|err| anyhow!("Nonblocking FFI call failed: {}", err))??;
// SAFETY: Same return type declared to libffi; trust user to have it right beyond that.
Ok(unsafe { result.to_value(def.result) })
})
}
/// A non-blocking FFI call.
#[op(v8)]
pub fn op_ffi_call_nonblocking<'scope>(
scope: &mut v8::HandleScope<'scope>,
state: Rc<RefCell<deno_core::OpState>>,
rid: ResourceId,
symbol: String,
parameters: serde_v8::Value<'scope>,
) -> Result<impl Future<Output = Result<Value, AnyError>> + 'static, AnyError> {
let symbol = {
let state = state.borrow();
let resource = state.resource_table.get::<DynamicLibraryResource>(rid)?;
let symbols = &resource.symbols;
*symbols
.get(&symbol)
.ok_or_else(|| type_error("Invalid FFI symbol name"))?
.clone()
};
let call_args = ffi_parse_args(scope, parameters, &symbol.parameter_types)?;
let result_type = symbol.result_type;
let join_handle = tokio::task::spawn_blocking(move || {
let Symbol {
cif,
ptr,
parameter_types,
result_type,
..
} = symbol.clone();
ffi_call(call_args, &cif, ptr, &parameter_types, result_type)
});
Ok(async move {
let result = join_handle
.await
.map_err(|err| anyhow!("Nonblocking FFI call failed: {}", err))??;
// SAFETY: Same return type declared to libffi; trust user to have it right beyond that.
Ok(unsafe { result.to_value(result_type) })
})
}
#[op(v8)]
pub fn op_ffi_call_ptr<FP, 'scope>(
scope: &mut v8::HandleScope<'scope>,
state: Rc<RefCell<deno_core::OpState>>,
pointer: usize,
def: ForeignFunction,
parameters: serde_v8::Value<'scope>,
) -> Result<serde_v8::Value<'scope>, AnyError>
where
FP: FfiPermissions + 'static,
{
check_unstable2(&state, "Deno.UnsafeFnPointer#call");
{
let mut state = state.borrow_mut();
let permissions = state.borrow_mut::<FP>();
permissions.check(None)?;
};
let symbol = PtrSymbol::new(pointer, &def);
let call_args = ffi_parse_args(scope, parameters, &def.parameters)?;
let result = ffi_call(
call_args,
&symbol.cif,
symbol.ptr,
&def.parameters,
def.result,
)?;
// SAFETY: Same return type declared to libffi; trust user to have it right beyond that.
let result = unsafe { result.to_v8(scope, def.result) };
Ok(result)
}