rust/src/abi.rs

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use std::iter;
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use rustc::hir;
use rustc_target::spec::abi::Abi;
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use crate::prelude::*;
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#[derive(Debug)]
enum PassMode {
NoPass,
ByVal(Type),
ByRef,
}
impl PassMode {
fn get_param_ty(self, fx: &FunctionCx<impl Backend>) -> Type {
match self {
PassMode::NoPass => unimplemented!("pass mode nopass"),
PassMode::ByVal(cton_type) => cton_type,
PassMode::ByRef => fx.module.pointer_type(),
}
}
}
fn get_pass_mode<'a, 'tcx: 'a>(
tcx: TyCtxt<'a, 'tcx, 'tcx>,
abi: Abi,
ty: Ty<'tcx>,
is_return: bool,
) -> PassMode {
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assert!(
!tcx.layout_of(ParamEnv::reveal_all().and(ty))
.unwrap()
.is_unsized()
);
if ty.sty == tcx.mk_nil().sty {
if is_return {
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//if false {
PassMode::NoPass
} else {
PassMode::ByRef
}
} else if let Some(ret_ty) = crate::common::cton_type_from_ty(tcx, ty) {
PassMode::ByVal(ret_ty)
} else {
if abi == Abi::C {
unimplemented!("Non scalars are not yet supported for \"C\" abi");
}
PassMode::ByRef
}
}
pub fn cton_sig_from_fn_ty<'a, 'tcx: 'a>(
tcx: TyCtxt<'a, 'tcx, 'tcx>,
fn_ty: Ty<'tcx>,
) -> Signature {
let sig = ty_fn_sig(tcx, fn_ty);
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assert!(!sig.variadic, "Variadic function are not yet supported");
let (call_conv, inputs, output): (CallConv, Vec<Ty>, Ty) = match sig.abi {
Abi::Rust => (CallConv::Fast, sig.inputs().to_vec(), sig.output()),
Abi::C => (CallConv::SystemV, sig.inputs().to_vec(), sig.output()),
Abi::RustCall => {
assert_eq!(sig.inputs().len(), 2);
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let extra_args = match sig.inputs().last().unwrap().sty {
ty::Tuple(ref tupled_arguments) => tupled_arguments,
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_ => bug!("argument to function with \"rust-call\" ABI is not a tuple"),
};
let mut inputs: Vec<Ty> = vec![sig.inputs()[0]];
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inputs.extend(extra_args.into_iter());
(CallConv::Fast, inputs, sig.output())
}
Abi::System => bug!("system abi should be selected elsewhere"),
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Abi::RustIntrinsic => (CallConv::SystemV, sig.inputs().to_vec(), sig.output()),
_ => unimplemented!("unsupported abi {:?}", sig.abi),
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};
let inputs = inputs
.into_iter()
.filter_map(|ty| match get_pass_mode(tcx, sig.abi, ty, false) {
PassMode::ByVal(cton_ty) => Some(cton_ty),
PassMode::NoPass => unimplemented!("pass mode nopass"),
PassMode::ByRef => Some(pointer_ty(tcx)),
});
let (params, returns) = match get_pass_mode(tcx, sig.abi, output, true) {
PassMode::NoPass => (inputs.map(AbiParam::new).collect(), vec![]),
PassMode::ByVal(ret_ty) => (
inputs.map(AbiParam::new).collect(),
vec![AbiParam::new(ret_ty)],
),
PassMode::ByRef => {
(
Some(pointer_ty(tcx)).into_iter() // First param is place to put return val
.chain(inputs)
.map(AbiParam::new)
.collect(),
vec![],
)
}
};
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Signature {
params,
returns,
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call_conv,
}
}
fn ty_fn_sig<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, ty: Ty<'tcx>) -> ty::FnSig<'tcx> {
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let sig = match ty.sty {
ty::FnDef(..) |
// Shims currently have type TyFnPtr. Not sure this should remain.
ty::FnPtr(_) => ty.fn_sig(tcx),
ty::Closure(def_id, substs) => {
let sig = substs.closure_sig(def_id, tcx);
let env_ty = tcx.closure_env_ty(def_id, substs).unwrap();
sig.map_bound(|sig| tcx.mk_fn_sig(
iter::once(*env_ty.skip_binder()).chain(sig.inputs().iter().cloned()),
sig.output(),
sig.variadic,
sig.unsafety,
sig.abi
))
}
ty::Generator(def_id, substs, _) => {
let sig = substs.poly_sig(def_id, tcx);
let env_region = ty::ReLateBound(ty::INNERMOST, ty::BrEnv);
let env_ty = tcx.mk_mut_ref(tcx.mk_region(env_region), ty);
sig.map_bound(|sig| {
let state_did = tcx.lang_items().gen_state().unwrap();
let state_adt_ref = tcx.adt_def(state_did);
let state_substs = tcx.intern_substs(&[
sig.yield_ty.into(),
sig.return_ty.into(),
]);
let ret_ty = tcx.mk_adt(state_adt_ref, state_substs);
tcx.mk_fn_sig(iter::once(env_ty),
ret_ty,
false,
hir::Unsafety::Normal,
Abi::Rust
)
})
}
_ => bug!("unexpected type {:?} to ty_fn_sig", ty)
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};
tcx.normalize_erasing_late_bound_regions(ParamEnv::reveal_all(), &sig)
}
pub fn get_function_name_and_sig<'a, 'tcx>(
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tcx: TyCtxt<'a, 'tcx, 'tcx>,
inst: Instance<'tcx>,
) -> (String, Signature) {
assert!(!inst.substs.needs_infer() && !inst.substs.has_param_types());
let fn_ty = inst.ty(tcx);
let sig = cton_sig_from_fn_ty(tcx, fn_ty);
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(tcx.symbol_name(inst).as_str().to_string(), sig)
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}
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impl<'a, 'tcx: 'a, B: Backend + 'a> FunctionCx<'a, 'tcx, B> {
/// Instance must be monomorphized
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pub fn get_function_ref(&mut self, inst: Instance<'tcx>) -> FuncRef {
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let (name, sig) = get_function_name_and_sig(self.tcx, inst);
let func_id = self
.module
.declare_function(&name, Linkage::Import, &sig)
.unwrap();
self.module
.declare_func_in_func(func_id, &mut self.bcx.func)
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}
fn lib_call(
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&mut self,
name: &str,
input_tys: Vec<types::Type>,
output_ty: Option<types::Type>,
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args: &[Value],
) -> Option<Value> {
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let sig = Signature {
params: input_tys.iter().cloned().map(AbiParam::new).collect(),
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returns: output_ty.map(|output_ty| vec![AbiParam::new(output_ty)]).unwrap_or(Vec::new()),
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call_conv: CallConv::SystemV,
};
let func_id = self
.module
.declare_function(&name, Linkage::Import, &sig)
.unwrap();
let func_ref = self
.module
.declare_func_in_func(func_id, &mut self.bcx.func);
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let call_inst = self.bcx.ins().call(func_ref, args);
if output_ty.is_none() {
return None;
}
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let results = self.bcx.inst_results(call_inst);
assert_eq!(results.len(), 1);
Some(results[0])
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}
pub fn easy_call(
&mut self,
name: &str,
args: &[CValue<'tcx>],
return_ty: Ty<'tcx>,
) -> CValue<'tcx> {
let (input_tys, args): (Vec<_>, Vec<_>) = args
.into_iter()
.map(|arg| {
(
self.cton_type(arg.layout().ty).unwrap(),
arg.load_value(self),
)
}).unzip();
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let return_layout = self.layout_of(return_ty);
let return_ty = if let ty::Tuple(tup) = return_ty.sty {
if !tup.is_empty() {
bug!("easy_call( (...) -> <non empty tuple> ) is not allowed");
}
None
} else {
Some(self.cton_type(return_ty).unwrap())
};
if let Some(val) = self.lib_call(name, input_tys, return_ty, &args) {
CValue::ByVal(val, return_layout)
} else {
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CValue::ByRef(
self.bcx.ins().iconst(self.module.pointer_type(), 0),
return_layout,
)
}
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}
fn self_sig(&self) -> FnSig<'tcx> {
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ty_fn_sig(self.tcx, self.instance.ty(self.tcx))
}
fn return_type(&self) -> Ty<'tcx> {
self.self_sig().output()
}
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}
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pub fn codegen_fn_prelude<'a, 'tcx: 'a>(
fx: &mut FunctionCx<'a, 'tcx, impl Backend>,
start_ebb: Ebb,
) {
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let ssa_analyzed = crate::analyze::analyze(fx);
match fx.self_sig().abi {
Abi::Rust | Abi::RustCall => {}
_ => unimplemented!("declared function with non \"rust\" or \"rust-call\" abi"),
}
let ret_layout = fx.layout_of(fx.return_type());
let output_pass_mode = get_pass_mode(fx.tcx, fx.self_sig().abi, fx.return_type(), true);
let ret_param = match output_pass_mode {
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PassMode::NoPass => None,
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PassMode::ByVal(_) => None,
PassMode::ByRef => Some(fx.bcx.append_ebb_param(start_ebb, fx.module.pointer_type())),
};
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enum ArgKind {
Normal(Value),
Spread(Vec<Value>),
}
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let func_params = fx
.mir
.args_iter()
.map(|local| {
let arg_ty = fx.monomorphize(&fx.mir.local_decls[local].ty);
// Adapted from https://github.com/rust-lang/rust/blob/145155dc96757002c7b2e9de8489416e2fdbbd57/src/librustc_codegen_llvm/mir/mod.rs#L442-L482
if Some(local) == fx.mir.spread_arg {
// This argument (e.g. the last argument in the "rust-call" ABI)
// is a tuple that was spread at the ABI level and now we have
// to reconstruct it into a tuple local variable, from multiple
// individual function arguments.
let tupled_arg_tys = match arg_ty.sty {
ty::Tuple(ref tys) => tys,
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_ => bug!("spread argument isn't a tuple?! but {:?}", arg_ty),
};
let mut ebb_params = Vec::new();
for arg_ty in tupled_arg_tys.iter() {
let cton_type =
get_pass_mode(fx.tcx, fx.self_sig().abi, arg_ty, false).get_param_ty(fx);
ebb_params.push(fx.bcx.append_ebb_param(start_ebb, cton_type));
}
(local, ArgKind::Spread(ebb_params), arg_ty)
} else {
let cton_type =
get_pass_mode(fx.tcx, fx.self_sig().abi, arg_ty, false).get_param_ty(fx);
(
local,
ArgKind::Normal(fx.bcx.append_ebb_param(start_ebb, cton_type)),
arg_ty,
)
}
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}).collect::<Vec<(Local, ArgKind, Ty)>>();
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fx.bcx.switch_to_block(start_ebb);
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fx.top_nop = Some(fx.bcx.ins().nop());
fx.add_global_comment(format!("ssa {:?}", ssa_analyzed));
match output_pass_mode {
PassMode::NoPass => {
let null = fx.bcx.ins().iconst(fx.module.pointer_type(), 0);
//unimplemented!("pass mode nopass");
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fx.local_map.insert(
RETURN_PLACE,
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CPlace::Addr(null, None, fx.layout_of(fx.return_type())),
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);
}
PassMode::ByVal(ret_ty) => {
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fx.bcx.declare_var(mir_var(RETURN_PLACE), ret_ty);
fx.local_map
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.insert(RETURN_PLACE, CPlace::Var(RETURN_PLACE, ret_layout));
}
PassMode::ByRef => {
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fx.local_map.insert(
RETURN_PLACE,
CPlace::Addr(ret_param.unwrap(), None, ret_layout),
);
}
}
for (local, arg_kind, ty) in func_params {
let layout = fx.layout_of(ty);
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if let ArgKind::Normal(ebb_param) = arg_kind {
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if !ssa_analyzed
.get(&local)
.unwrap()
.contains(crate::analyze::Flags::NOT_SSA)
{
fx.bcx
.declare_var(mir_var(local), fx.cton_type(ty).unwrap());
match get_pass_mode(fx.tcx, fx.self_sig().abi, ty, false) {
PassMode::NoPass => unimplemented!("pass mode nopass"),
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PassMode::ByVal(_) => fx.bcx.def_var(mir_var(local), ebb_param),
PassMode::ByRef => {
let val = CValue::ByRef(ebb_param, fx.layout_of(ty)).load_value(fx);
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fx.bcx.def_var(mir_var(local), val);
}
}
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fx.local_map.insert(local, CPlace::Var(local, layout));
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continue;
}
}
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let stack_slot = fx.bcx.create_stack_slot(StackSlotData {
kind: StackSlotKind::ExplicitSlot,
size: layout.size.bytes() as u32,
offset: None,
});
let place = CPlace::from_stack_slot(fx, stack_slot, ty);
match arg_kind {
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ArgKind::Normal(ebb_param) => match get_pass_mode(fx.tcx, fx.self_sig().abi, ty, false)
{
PassMode::NoPass => unimplemented!("pass mode nopass"),
PassMode::ByVal(_) => {
place.write_cvalue(fx, CValue::ByVal(ebb_param, place.layout()))
}
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PassMode::ByRef => place.write_cvalue(fx, CValue::ByRef(ebb_param, place.layout())),
},
ArgKind::Spread(ebb_params) => {
for (i, ebb_param) in ebb_params.into_iter().enumerate() {
let sub_place = place.place_field(fx, mir::Field::new(i));
match get_pass_mode(fx.tcx, fx.self_sig().abi, sub_place.layout().ty, false) {
PassMode::NoPass => unimplemented!("pass mode nopass"),
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PassMode::ByVal(_) => {
sub_place.write_cvalue(fx, CValue::ByVal(ebb_param, sub_place.layout()))
}
PassMode::ByRef => {
sub_place.write_cvalue(fx, CValue::ByRef(ebb_param, sub_place.layout()))
}
}
}
}
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}
fx.local_map.insert(local, place);
}
for local in fx.mir.vars_and_temps_iter() {
let ty = fx.mir.local_decls[local].ty;
let layout = fx.layout_of(ty);
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let place = if ssa_analyzed
.get(&local)
.unwrap()
.contains(crate::analyze::Flags::NOT_SSA)
{
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let stack_slot = fx.bcx.create_stack_slot(StackSlotData {
kind: StackSlotKind::ExplicitSlot,
size: layout.size.bytes() as u32,
offset: None,
});
CPlace::from_stack_slot(fx, stack_slot, ty)
} else {
fx.bcx
.declare_var(mir_var(local), fx.cton_type(ty).unwrap());
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CPlace::Var(local, layout)
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};
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fx.local_map.insert(local, place);
}
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fx.bcx
.ins()
.jump(*fx.ebb_map.get(&START_BLOCK).unwrap(), &[]);
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}
pub fn codegen_call<'a, 'tcx: 'a>(
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fx: &mut FunctionCx<'a, 'tcx, impl Backend>,
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func: &Operand<'tcx>,
args: &[Operand<'tcx>],
destination: &Option<(Place<'tcx>, BasicBlock)>,
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) {
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let fn_ty = fx.monomorphize(&func.ty(&fx.mir.local_decls, fx.tcx));
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let sig = ty_fn_sig(fx.tcx, fn_ty);
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// Unpack arguments tuple for closures
let args = if sig.abi == Abi::RustCall {
assert_eq!(args.len(), 2, "rust-call abi requires two arguments");
let self_arg = trans_operand(fx, &args[0]);
let pack_arg = trans_operand(fx, &args[1]);
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let mut args = Vec::new();
args.push(self_arg);
match pack_arg.layout().ty.sty {
ty::Tuple(ref tupled_arguments) => {
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for (i, _) in tupled_arguments.iter().enumerate() {
args.push(pack_arg.value_field(fx, mir::Field::new(i)));
}
}
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_ => bug!("argument to function with \"rust-call\" ABI is not a tuple"),
}
args
} else {
args.into_iter()
.map(|arg| trans_operand(fx, arg))
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.collect::<Vec<_>>()
};
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let destination = destination
.as_ref()
.map(|(place, bb)| (trans_place(fx, place), *bb));
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if codegen_intrinsic_call(fx, fn_ty, sig, &args, destination) {
return;
}
let ret_layout = fx.layout_of(sig.output());
let output_pass_mode = get_pass_mode(fx.tcx, sig.abi, sig.output(), true);
let return_ptr = match output_pass_mode {
PassMode::NoPass => None,
PassMode::ByRef => match destination {
Some((place, _)) => Some(place.expect_addr()),
None => Some(fx.bcx.ins().iconst(fx.module.pointer_type(), 0)),
},
PassMode::ByVal(_) => None,
};
let call_args: Vec<Value> = return_ptr
.into_iter()
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.chain(args.into_iter().map(|arg| {
match get_pass_mode(fx.tcx, sig.abi, arg.layout().ty, false) {
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PassMode::NoPass => unimplemented!("pass mode nopass"),
PassMode::ByVal(_) => arg.load_value(fx),
PassMode::ByRef => arg.force_stack(fx),
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}
})).collect::<Vec<_>>();
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let call_inst = match fn_ty.sty {
ty::FnDef(def_id, substs) => {
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let func_ref = fx.get_function_ref(
Instance::resolve(fx.tcx, ParamEnv::reveal_all(), def_id, substs).unwrap(),
);
fx.bcx.ins().call(func_ref, &call_args)
}
_ => {
let func = trans_operand(fx, func);
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let func = func.load_value(fx);
let sig = fx.bcx.import_signature(cton_sig_from_fn_ty(fx.tcx, fn_ty));
fx.bcx.ins().call_indirect(sig, func, &call_args)
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}
};
match output_pass_mode {
PassMode::NoPass => {}
PassMode::ByVal(_) => {
if let Some((ret_place, _)) = destination {
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let results = fx.bcx.inst_results(call_inst);
ret_place.write_cvalue(fx, CValue::ByVal(results[0], ret_layout));
}
}
PassMode::ByRef => {}
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}
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if let Some((_, dest)) = destination {
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let ret_ebb = fx.get_ebb(dest);
fx.bcx.ins().jump(ret_ebb, &[]);
} else {
fx.bcx.ins().trap(TrapCode::User(!0));
}
}
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pub fn codegen_return(fx: &mut FunctionCx<impl Backend>) {
match get_pass_mode(fx.tcx, fx.self_sig().abi, fx.return_type(), true) {
PassMode::NoPass | PassMode::ByRef => {
fx.bcx.ins().return_(&[]);
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}
PassMode::ByVal(_) => {
let place = fx.get_local_place(RETURN_PLACE);
let ret_val = place.to_cvalue(fx).load_value(fx);
fx.bcx.ins().return_(&[ret_val]);
}
}
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}
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fn codegen_intrinsic_call<'a, 'tcx: 'a>(
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fx: &mut FunctionCx<'a, 'tcx, impl Backend>,
fn_ty: Ty<'tcx>,
sig: FnSig<'tcx>,
args: &[CValue<'tcx>],
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destination: Option<(CPlace<'tcx>, BasicBlock)>,
) -> bool {
if let ty::FnDef(def_id, substs) = fn_ty.sty {
if sig.abi == Abi::RustIntrinsic {
let intrinsic = fx.tcx.item_name(def_id).as_str();
let intrinsic = &intrinsic[..];
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let ret = match destination {
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Some((place, _)) => place,
None => {
// Insert non returning intrinsics here
match intrinsic {
"abort" => {
fx.bcx.ins().trap(TrapCode::User(!0 - 1));
}
"unreachable" => {
fx.bcx.ins().trap(TrapCode::User(!0 - 1));
}
_ => unimplemented!("unsupported instrinsic {}", intrinsic),
}
return true;
}
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};
let nil_ty = fx.tcx.mk_nil();
let u64_layout = fx.layout_of(fx.tcx.types.u64);
let usize_layout = fx.layout_of(fx.tcx.types.usize);
match intrinsic {
"assume" => {
assert_eq!(args.len(), 1);
}
"arith_offset" => {
assert_eq!(args.len(), 2);
let base = args[0].load_value(fx);
let offset = args[1].load_value(fx);
let res = fx.bcx.ins().iadd(base, offset);
let res = CValue::ByVal(res, ret.layout());
ret.write_cvalue(fx, res);
}
"likely" | "unlikely" => {
assert_eq!(args.len(), 1);
ret.write_cvalue(fx, args[0]);
}
"copy" | "copy_nonoverlapping" => {
let elem_ty = substs.type_at(0);
let elem_size: u64 = fx.layout_of(elem_ty).size.bytes();
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let elem_size = fx
.bcx
.ins()
.iconst(fx.module.pointer_type(), elem_size as i64);
assert_eq!(args.len(), 3);
let src = args[0];
let dst = args[1];
let count = args[2].load_value(fx);
let byte_amount = fx.bcx.ins().imul(count, elem_size);
fx.easy_call(
"memmove",
&[dst, src, CValue::ByVal(byte_amount, usize_layout)],
nil_ty,
);
}
"discriminant_value" => {
assert_eq!(args.len(), 1);
let discr = crate::base::trans_get_discriminant(fx, args[0], ret.layout());
ret.write_cvalue(fx, discr);
}
"size_of" => {
assert_eq!(args.len(), 0);
let size_of = fx.layout_of(substs.type_at(0)).size.bytes();
let size_of = CValue::const_val(fx, usize_layout.ty, size_of as i64);
ret.write_cvalue(fx, size_of);
}
"type_id" => {
assert_eq!(args.len(), 0);
let type_id = fx.tcx.type_id_hash(substs.type_at(0));
let type_id = CValue::const_val(fx, u64_layout.ty, type_id as i64);
ret.write_cvalue(fx, type_id);
}
"min_align_of" => {
assert_eq!(args.len(), 0);
let min_align = fx.layout_of(substs.type_at(0)).align.abi();
let min_align = CValue::const_val(fx, usize_layout.ty, min_align as i64);
ret.write_cvalue(fx, min_align);
}
_ if intrinsic.starts_with("unchecked_") => {
assert_eq!(args.len(), 2);
let bin_op = match intrinsic {
"unchecked_div" => BinOp::Div,
"unchecked_rem" => BinOp::Rem,
"unchecked_shl" => BinOp::Shl,
"unchecked_shr" => BinOp::Shr,
_ => unimplemented!("intrinsic {}", intrinsic),
};
let res = match ret.layout().ty.sty {
ty::Uint(_) => crate::base::trans_int_binop(
fx,
bin_op,
args[0],
args[1],
ret.layout().ty,
false,
),
ty::Int(_) => crate::base::trans_int_binop(
fx,
bin_op,
args[0],
args[1],
ret.layout().ty,
true,
),
_ => panic!(),
};
ret.write_cvalue(fx, res);
}
_ if intrinsic.ends_with("_with_overflow") => {
assert_eq!(args.len(), 2);
assert_eq!(args[0].layout().ty, args[1].layout().ty);
let bin_op = match intrinsic {
"add_with_overflow" => BinOp::Add,
"sub_with_overflow" => BinOp::Sub,
"mul_with_overflow" => BinOp::Mul,
_ => unimplemented!("intrinsic {}", intrinsic),
};
let res = match args[0].layout().ty.sty {
ty::Uint(_) => crate::base::trans_checked_int_binop(
fx,
bin_op,
args[0],
args[1],
ret.layout().ty,
false,
),
ty::Int(_) => crate::base::trans_checked_int_binop(
fx,
bin_op,
args[0],
args[1],
ret.layout().ty,
true,
),
_ => panic!(),
};
ret.write_cvalue(fx, res);
}
_ if intrinsic.starts_with("overflowing_") => {
assert_eq!(args.len(), 2);
assert_eq!(args[0].layout().ty, args[1].layout().ty);
let bin_op = match intrinsic {
"overflowing_add" => BinOp::Add,
"overflowing_sub" => BinOp::Sub,
"overflowing_mul" => BinOp::Mul,
_ => unimplemented!("intrinsic {}", intrinsic),
};
let res = match args[0].layout().ty.sty {
ty::Uint(_) => crate::base::trans_int_binop(
fx,
bin_op,
args[0],
args[1],
ret.layout().ty,
false,
),
ty::Int(_) => crate::base::trans_int_binop(
fx,
bin_op,
args[0],
args[1],
ret.layout().ty,
true,
),
_ => panic!(),
};
ret.write_cvalue(fx, res);
}
"offset" => {
assert_eq!(args.len(), 2);
let base = args[0].load_value(fx);
let offset = args[1].load_value(fx);
let res = fx.bcx.ins().iadd(base, offset);
ret.write_cvalue(fx, CValue::ByVal(res, args[0].layout()));
}
"transmute" => {
assert_eq!(args.len(), 1);
let src_ty = substs.type_at(0);
let dst_ty = substs.type_at(1);
assert_eq!(args[0].layout().ty, src_ty);
let addr = args[0].force_stack(fx);
let dst_layout = fx.layout_of(dst_ty);
ret.write_cvalue(fx, CValue::ByRef(addr, dst_layout))
}
"uninit" => {
assert_eq!(args.len(), 0);
let ty = substs.type_at(0);
let layout = fx.layout_of(ty);
let stack_slot = fx.bcx.create_stack_slot(StackSlotData {
kind: StackSlotKind::ExplicitSlot,
size: layout.size.bytes() as u32,
offset: None,
});
let uninit_place = CPlace::from_stack_slot(fx, stack_slot, ty);
let uninit_val = uninit_place.to_cvalue(fx);
ret.write_cvalue(fx, uninit_val);
}
"ctlz" | "ctlz_nonzero" => {
assert_eq!(args.len(), 1);
let arg = args[0].load_value(fx);
let res = CValue::ByVal(fx.bcx.ins().clz(arg), args[0].layout());
ret.write_cvalue(fx, res);
}
"cttz" | "cttz_nonzero" => {
assert_eq!(args.len(), 1);
let arg = args[0].load_value(fx);
let res = CValue::ByVal(fx.bcx.ins().clz(arg), args[0].layout());
ret.write_cvalue(fx, res);
}
"ctpop" => {
assert_eq!(args.len(), 1);
let arg = args[0].load_value(fx);
let res = CValue::ByVal(fx.bcx.ins().popcnt(arg), args[0].layout());
ret.write_cvalue(fx, res);
}
_ => unimpl!("unsupported intrinsic {}", intrinsic),
}
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if let Some((_, dest)) = destination {
let ret_ebb = fx.get_ebb(dest);
fx.bcx.ins().jump(ret_ebb, &[]);
} else {
fx.bcx.ins().trap(TrapCode::User(!0));
}
return true;
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}
}
false
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}