3 use rustc::ty::subst::SubstsRef;
5 macro_rules! intrinsic_pat {
14 macro_rules! intrinsic_arg {
15 (c $fx:expr, $arg:ident) => {
18 (v $fx:expr, $arg:ident) => {
23 macro_rules! intrinsic_substs {
24 ($substs:expr, $index:expr,) => {};
25 ($substs:expr, $index:expr, $first:ident $(,$rest:ident)*) => {
26 let $first = $substs.type_at($index);
27 intrinsic_substs!($substs, $index+1, $($rest),*);
31 macro_rules! intrinsic_match {
32 ($fx:expr, $intrinsic:expr, $substs:expr, $args:expr, $(
33 $($name:tt)|+ $(if $cond:expr)?, $(<$($subst:ident),*>)? ($($a:ident $arg:ident),*) $content:block;
37 $(intrinsic_pat!($name))|* $(if $cond)? => {
38 #[allow(unused_parens, non_snake_case)]
41 intrinsic_substs!($substs, 0, $($subst),*);
43 if let [$($arg),*] = *$args {
45 $(intrinsic_arg!($a $fx, $arg)),*
47 #[warn(unused_parens, non_snake_case)]
52 bug!("wrong number of args for intrinsic {:?}", $intrinsic);
57 _ => unimpl!("unsupported intrinsic {}", $intrinsic),
62 macro_rules! atomic_binop_return_old {
63 ($fx:expr, $op:ident<$T:ident>($ptr:ident, $src:ident) -> $ret:ident) => {
64 let clif_ty = $fx.clif_type($T).unwrap();
65 let old = $fx.bcx.ins().load(clif_ty, MemFlags::new(), $ptr, 0);
66 let new = $fx.bcx.ins().$op(old, $src);
67 $fx.bcx.ins().store(MemFlags::new(), new, $ptr, 0);
68 $ret.write_cvalue($fx, CValue::by_val(old, $fx.layout_of($T)));
72 macro_rules! atomic_minmax {
73 ($fx:expr, $cc:expr, <$T:ident> ($ptr:ident, $src:ident) -> $ret:ident) => {
75 let clif_ty = $fx.clif_type($T).unwrap();
76 let old = $fx.bcx.ins().load(clif_ty, MemFlags::new(), $ptr, 0);
79 let is_eq = $fx.bcx.ins().icmp(IntCC::SignedGreaterThan, old, $src);
80 let new = crate::common::codegen_select(&mut $fx.bcx, is_eq, old, $src);
83 $fx.bcx.ins().store(MemFlags::new(), new, $ptr, 0);
85 let ret_val = CValue::by_val(old, $ret.layout());
86 $ret.write_cvalue($fx, ret_val);
90 pub fn codegen_intrinsic_call<'a, 'tcx: 'a>(
91 fx: &mut FunctionCx<'a, 'tcx, impl Backend>,
93 substs: SubstsRef<'tcx>,
94 args: Vec<CValue<'tcx>>,
95 destination: Option<(CPlace<'tcx>, BasicBlock)>,
97 let intrinsic = fx.tcx.item_name(def_id).as_str();
98 let intrinsic = &intrinsic[..];
100 let ret = match destination {
101 Some((place, _)) => place,
103 // Insert non returning intrinsics here
106 trap_panic(fx, "Called intrinisc::abort.");
109 trap_unreachable(fx, "[corruption] Called intrinsic::unreachable.");
111 _ => unimplemented!("unsupported instrinsic {}", intrinsic),
117 let u64_layout = fx.layout_of(fx.tcx.types.u64);
118 let usize_layout = fx.layout_of(fx.tcx.types.usize);
121 fx, intrinsic, substs, args,
124 likely | unlikely, (c a) {
125 ret.write_cvalue(fx, a);
128 fx.bcx.ins().debugtrap();
130 copy | copy_nonoverlapping, <elem_ty> (v src, v dst, v count) {
131 let elem_size: u64 = fx.layout_of(elem_ty).size.bytes();
135 .iconst(fx.pointer_type, elem_size as i64);
136 assert_eq!(args.len(), 3);
137 let byte_amount = fx.bcx.ins().imul(count, elem_size);
139 if intrinsic.ends_with("_nonoverlapping") {
140 fx.bcx.call_memcpy(fx.module.target_config(), dst, src, byte_amount);
142 fx.bcx.call_memmove(fx.module.target_config(), dst, src, byte_amount);
145 discriminant_value, (c val) {
146 let pointee_layout = fx.layout_of(val.layout().ty.builtin_deref(true).unwrap().ty);
147 let place = CPlace::for_addr(val.load_scalar(fx), pointee_layout);
148 let discr = crate::base::trans_get_discriminant(fx, place, ret.layout());
149 ret.write_cvalue(fx, discr);
152 let size_of = fx.layout_of(T).size.bytes();
153 let size_of = CValue::const_val(fx, usize_layout.ty, size_of as i64);
154 ret.write_cvalue(fx, size_of);
156 size_of_val, <T> (c ptr) {
157 let layout = fx.layout_of(T);
158 let size = if layout.is_unsized() {
159 let (_ptr, info) = ptr.load_scalar_pair(fx);
160 let (size, _align) = crate::unsize::size_and_align_of_dst(fx, layout.ty, info);
166 .iconst(fx.pointer_type, layout.size.bytes() as i64)
168 ret.write_cvalue(fx, CValue::by_val(size, usize_layout));
170 min_align_of, <T> () {
171 let min_align = fx.layout_of(T).align.abi.bytes();
172 let min_align = CValue::const_val(fx, usize_layout.ty, min_align as i64);
173 ret.write_cvalue(fx, min_align);
175 min_align_of_val, <T> (c ptr) {
176 let layout = fx.layout_of(T);
177 let align = if layout.is_unsized() {
178 let (_ptr, info) = ptr.load_scalar_pair(fx);
179 let (_size, align) = crate::unsize::size_and_align_of_dst(fx, layout.ty, info);
185 .iconst(fx.pointer_type, layout.align.abi.bytes() as i64)
187 ret.write_cvalue(fx, CValue::by_val(align, usize_layout));
190 let type_id = fx.tcx.type_id_hash(T);
191 let type_id = CValue::const_val(fx, u64_layout.ty, type_id as i64);
192 ret.write_cvalue(fx, type_id);
194 _ if intrinsic.starts_with("unchecked_") || intrinsic == "exact_div", (c x, c y) {
195 // FIXME trap on overflow
196 let bin_op = match intrinsic {
197 "unchecked_div" | "exact_div" => BinOp::Div,
198 "unchecked_rem" => BinOp::Rem,
199 "unchecked_shl" => BinOp::Shl,
200 "unchecked_shr" => BinOp::Shr,
201 _ => unimplemented!("intrinsic {}", intrinsic),
203 let res = match ret.layout().ty.sty {
204 ty::Uint(_) => crate::base::trans_int_binop(
212 ty::Int(_) => crate::base::trans_int_binop(
222 ret.write_cvalue(fx, res);
224 _ if intrinsic.ends_with("_with_overflow"), <T> (c x, c y) {
225 assert_eq!(x.layout().ty, y.layout().ty);
226 let bin_op = match intrinsic {
227 "add_with_overflow" => BinOp::Add,
228 "sub_with_overflow" => BinOp::Sub,
229 "mul_with_overflow" => BinOp::Mul,
230 _ => unimplemented!("intrinsic {}", intrinsic),
232 let res = match T.sty {
233 ty::Uint(_) => crate::base::trans_checked_int_binop(
241 ty::Int(_) => crate::base::trans_checked_int_binop(
251 ret.write_cvalue(fx, res);
253 _ if intrinsic.starts_with("overflowing_"), <T> (c x, c y) {
254 assert_eq!(x.layout().ty, y.layout().ty);
255 let bin_op = match intrinsic {
256 "overflowing_add" => BinOp::Add,
257 "overflowing_sub" => BinOp::Sub,
258 "overflowing_mul" => BinOp::Mul,
259 _ => unimplemented!("intrinsic {}", intrinsic),
261 let res = match T.sty {
262 ty::Uint(_) => crate::base::trans_int_binop(
270 ty::Int(_) => crate::base::trans_int_binop(
280 ret.write_cvalue(fx, res);
282 _ if intrinsic.starts_with("saturating_"), <T> (c x, c y) {
283 // FIXME implement saturating behavior
284 assert_eq!(x.layout().ty, y.layout().ty);
285 let bin_op = match intrinsic {
286 "saturating_add" => BinOp::Add,
287 "saturating_sub" => BinOp::Sub,
288 "saturating_mul" => BinOp::Mul,
289 _ => unimplemented!("intrinsic {}", intrinsic),
291 let res = match T.sty {
292 ty::Uint(_) => crate::base::trans_int_binop(
300 ty::Int(_) => crate::base::trans_int_binop(
310 ret.write_cvalue(fx, res);
312 rotate_left, <T>(v x, v y) {
313 let layout = fx.layout_of(T);
314 let res = fx.bcx.ins().rotl(x, y);
315 ret.write_cvalue(fx, CValue::by_val(res, layout));
317 rotate_right, <T>(v x, v y) {
318 let layout = fx.layout_of(T);
319 let res = fx.bcx.ins().rotr(x, y);
320 ret.write_cvalue(fx, CValue::by_val(res, layout));
323 // The only difference between offset and arith_offset is regarding UB. Because Cranelift
324 // doesn't have UB both are codegen'ed the same way
325 offset | arith_offset, (c base, v offset) {
326 let pointee_ty = base.layout().ty.builtin_deref(true).unwrap().ty;
327 let pointee_size = fx.layout_of(pointee_ty).size.bytes();
328 let ptr_diff = fx.bcx.ins().imul_imm(offset, pointee_size as i64);
329 let base_val = base.load_scalar(fx);
330 let res = fx.bcx.ins().iadd(base_val, ptr_diff);
331 ret.write_cvalue(fx, CValue::by_val(res, args[0].layout()));
334 transmute, <src_ty, dst_ty> (c from) {
335 assert_eq!(from.layout().ty, src_ty);
336 let addr = from.force_stack(fx);
337 let dst_layout = fx.layout_of(dst_ty);
338 ret.write_cvalue(fx, CValue::by_ref(addr, dst_layout))
341 if ret.layout().abi == Abi::Uninhabited {
342 crate::trap::trap_panic(fx, "[panic] Called intrinsic::init for uninhabited type.");
347 CPlace::NoPlace(_layout) => {}
348 CPlace::Var(var, layout) => {
349 let clif_ty = fx.clif_type(layout.ty).unwrap();
350 let val = match clif_ty {
351 types::I8 | types::I16 | types::I32 | types::I64 => fx.bcx.ins().iconst(clif_ty, 0),
353 let zero = fx.bcx.ins().iconst(types::I32, 0);
354 fx.bcx.ins().bitcast(types::F32, zero)
357 let zero = fx.bcx.ins().iconst(types::I64, 0);
358 fx.bcx.ins().bitcast(types::F64, zero)
360 _ => panic!("clif_type returned {}", clif_ty),
362 fx.bcx.def_var(mir_var(var), val);
365 let addr = ret.to_addr(fx);
366 let layout = ret.layout();
367 fx.bcx.emit_small_memset(fx.module.target_config(), addr, 0, layout.size.bytes(), 1);
371 write_bytes, (c dst, v val, v count) {
372 let pointee_ty = dst.layout().ty.builtin_deref(true).unwrap().ty;
373 let pointee_size = fx.layout_of(pointee_ty).size.bytes();
374 let count = fx.bcx.ins().imul_imm(count, pointee_size as i64);
375 let dst_ptr = dst.load_scalar(fx);
376 fx.bcx.call_memset(fx.module.target_config(), dst_ptr, val, count);
379 if ret.layout().abi == Abi::Uninhabited {
380 crate::trap::trap_panic(fx, "[panic] Called intrinsic::uninit for uninhabited type.");
384 let uninit_place = CPlace::new_stack_slot(fx, T);
385 let uninit_val = uninit_place.to_cvalue(fx);
386 ret.write_cvalue(fx, uninit_val);
388 ctlz | ctlz_nonzero, <T> (v arg) {
389 let res = CValue::by_val(fx.bcx.ins().clz(arg), fx.layout_of(T));
390 ret.write_cvalue(fx, res);
392 cttz | cttz_nonzero, <T> (v arg) {
393 let res = CValue::by_val(fx.bcx.ins().ctz(arg), fx.layout_of(T));
394 ret.write_cvalue(fx, res);
397 let res = CValue::by_val(fx.bcx.ins().popcnt(arg), fx.layout_of(T));
398 ret.write_cvalue(fx, res);
400 bitreverse, <T> (v arg) {
401 let res = CValue::by_val(fx.bcx.ins().bitrev(arg), fx.layout_of(T));
402 ret.write_cvalue(fx, res);
405 let needs_drop = if T.needs_drop(fx.tcx, ParamEnv::reveal_all()) {
410 let needs_drop = CValue::const_val(fx, fx.tcx.types.bool, needs_drop);
411 ret.write_cvalue(fx, needs_drop);
413 panic_if_uninhabited, <T> () {
414 if fx.layout_of(T).abi.is_uninhabited() {
415 crate::trap::trap_panic(fx, "[panic] Called intrinsic::panic_if_uninhabited for uninhabited type.");
420 _ if intrinsic.starts_with("atomic_fence"), () {};
421 _ if intrinsic.starts_with("atomic_singlethreadfence"), () {};
422 _ if intrinsic.starts_with("atomic_load"), (c ptr) {
424 fx.layout_of(ptr.layout().ty.builtin_deref(true).unwrap().ty);
425 let val = CValue::by_ref(ptr.load_scalar(fx), inner_layout);
426 ret.write_cvalue(fx, val);
428 _ if intrinsic.starts_with("atomic_store"), (v ptr, c val) {
429 let dest = CPlace::for_addr(ptr, val.layout());
430 dest.write_cvalue(fx, val);
432 _ if intrinsic.starts_with("atomic_xchg"), <T> (v ptr, c src) {
434 let clif_ty = fx.clif_type(T).unwrap();
435 let old = fx.bcx.ins().load(clif_ty, MemFlags::new(), ptr, 0);
436 ret.write_cvalue(fx, CValue::by_val(old, fx.layout_of(T)));
439 let dest = CPlace::for_addr(ptr, src.layout());
440 dest.write_cvalue(fx, src);
442 _ if intrinsic.starts_with("atomic_cxchg"), <T> (v ptr, v test_old, v new) { // both atomic_cxchg_* and atomic_cxchgweak_*
444 let clif_ty = fx.clif_type(T).unwrap();
445 let old = fx.bcx.ins().load(clif_ty, MemFlags::new(), ptr, 0);
448 let is_eq = fx.bcx.ins().icmp(IntCC::Equal, old, test_old);
449 let new = crate::common::codegen_select(&mut fx.bcx, is_eq, new, old); // Keep old if not equal to test_old
452 fx.bcx.ins().store(MemFlags::new(), new, ptr, 0);
454 let ret_val = CValue::by_val_pair(old, fx.bcx.ins().bint(types::I8, is_eq), ret.layout());
455 ret.write_cvalue(fx, ret_val);
458 _ if intrinsic.starts_with("atomic_xadd"), <T> (v ptr, v amount) {
459 atomic_binop_return_old! (fx, iadd<T>(ptr, amount) -> ret);
461 _ if intrinsic.starts_with("atomic_xsub"), <T> (v ptr, v amount) {
462 atomic_binop_return_old! (fx, isub<T>(ptr, amount) -> ret);
464 _ if intrinsic.starts_with("atomic_and"), <T> (v ptr, v src) {
465 atomic_binop_return_old! (fx, band<T>(ptr, src) -> ret);
467 _ if intrinsic.starts_with("atomic_nand"), <T> (v ptr, v src) {
468 atomic_binop_return_old! (fx, band_not<T>(ptr, src) -> ret);
470 _ if intrinsic.starts_with("atomic_or"), <T> (v ptr, v src) {
471 atomic_binop_return_old! (fx, bor<T>(ptr, src) -> ret);
473 _ if intrinsic.starts_with("atomic_xor"), <T> (v ptr, v src) {
474 atomic_binop_return_old! (fx, bxor<T>(ptr, src) -> ret);
477 _ if intrinsic.starts_with("atomic_max"), <T> (v ptr, v src) {
478 atomic_minmax!(fx, IntCC::SignedGreaterThan, <T> (ptr, src) -> ret);
480 _ if intrinsic.starts_with("atomic_umax"), <T> (v ptr, v src) {
481 atomic_minmax!(fx, IntCC::UnsignedGreaterThan, <T> (ptr, src) -> ret);
483 _ if intrinsic.starts_with("atomic_min"), <T> (v ptr, v src) {
484 atomic_minmax!(fx, IntCC::SignedLessThan, <T> (ptr, src) -> ret);
486 _ if intrinsic.starts_with("atomic_umin"), <T> (v ptr, v src) {
487 atomic_minmax!(fx, IntCC::UnsignedLessThan, <T> (ptr, src) -> ret);
491 if let Some((_, dest)) = destination {
492 let ret_ebb = fx.get_ebb(dest);
493 fx.bcx.ins().jump(ret_ebb, &[]);
495 trap_unreachable(fx, "[corruption] Diverging intrinsic returned.");