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use syntax::abi::{OsWin32, OsMacos, OsiOS};
use lib::llvm::*;
use super::cabi::*;
use super::common::*;
use super::machine::*;
use middle::trans::type_::Type;
pub fn compute_abi_info(ccx: &CrateContext,
atys: &[Type],
rty: Type,
ret_def: bool) -> FnType {
let mut arg_tys = Vec::new();
let ret_ty;
if !ret_def {
ret_ty = ArgType::direct(Type::void(ccx), None, None, None);
} else if rty.kind() == Struct {enum Strategy { RetValue(Type), RetPointer }
let strategy = match ccx.sess().targ_cfg.os {
OsWin32 | OsMacos | OsiOS => {
match llsize_of_alloc(ccx, rty) {
1 => RetValue(Type::i8(ccx)),
2 => RetValue(Type::i16(ccx)),
4 => RetValue(Type::i32(ccx)),
8 => RetValue(Type::i64(ccx)),
_ => RetPointer
}
}
_ => {
RetPointer
}
};
match strategy {
RetValue(t) => {
ret_ty = ArgType::direct(rty, Some(t), None, None);
}
RetPointer => {
ret_ty = ArgType::indirect(rty, Some(StructRetAttribute));
}
}
} else {
let attr = if rty == Type::bool(ccx) { Some(ZExtAttribute) } else { None };
ret_ty = ArgType::direct(rty, None, None, attr);
}
for &t in atys.iter() {
let ty = match t.kind() {
Struct => {
let size = llsize_of_alloc(ccx, t);
if size == 0 {
ArgType::ignore(t)
} else {
ArgType::indirect(t, Some(ByValAttribute))
}
}
_ => {
let attr = if t == Type::bool(ccx) { Some(ZExtAttribute) } else { None };
ArgType::direct(t, None, None, attr)
}
};
arg_tys.push(ty);
}
return FnType {
arg_tys: arg_tys,
ret_ty: ret_ty,
};
}