// WebAssemblyInstrAtomics.td-WebAssembly Atomic codegen support-*- tablegen -*- // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// /// /// \file /// WebAssembly Atomic operand code-gen constructs. /// //===----------------------------------------------------------------------===// let UseNamedOperandTable = 1 in multiclass ATOMIC_I pattern_r, string asmstr_r, string asmstr_s, bits<32> atomic_op, bit is64 = false> { defm "" : I, Requires<[HasAtomics]>; } multiclass ATOMIC_NRI pattern, string asmstr = "", bits<32> atomic_op = -1> { defm "" : NRI, Requires<[HasAtomics]>; } //===----------------------------------------------------------------------===// // Atomic wait / notify //===----------------------------------------------------------------------===// let hasSideEffects = 1 in { defm MEMORY_ATOMIC_NOTIFY_A32 : ATOMIC_I<(outs I32:$dst), (ins P2Align:$p2align, offset32_op:$off, I32:$addr, I32:$count), (outs), (ins P2Align:$p2align, offset32_op:$off), [], "memory.atomic.notify \t$dst, ${off}(${addr})${p2align}, $count", "memory.atomic.notify \t${off}${p2align}", 0x00, false>; defm MEMORY_ATOMIC_NOTIFY_A64 : ATOMIC_I<(outs I32:$dst), (ins P2Align:$p2align, offset64_op:$off, I64:$addr, I32:$count), (outs), (ins P2Align:$p2align, offset64_op:$off), [], "memory.atomic.notify \t$dst, ${off}(${addr})${p2align}, $count", "memory.atomic.notify \t${off}${p2align}", 0x00, true>; let mayLoad = 1 in { defm MEMORY_ATOMIC_WAIT32_A32 : ATOMIC_I<(outs I32:$dst), (ins P2Align:$p2align, offset32_op:$off, I32:$addr, I32:$exp, I64:$timeout), (outs), (ins P2Align:$p2align, offset32_op:$off), [], "memory.atomic.wait32 \t$dst, ${off}(${addr})${p2align}, $exp, $timeout", "memory.atomic.wait32 \t${off}${p2align}", 0x01, false>; defm MEMORY_ATOMIC_WAIT32_A64 : ATOMIC_I<(outs I32:$dst), (ins P2Align:$p2align, offset64_op:$off, I64:$addr, I32:$exp, I64:$timeout), (outs), (ins P2Align:$p2align, offset64_op:$off), [], "memory.atomic.wait32 \t$dst, ${off}(${addr})${p2align}, $exp, $timeout", "memory.atomic.wait32 \t${off}${p2align}", 0x01, true>; defm MEMORY_ATOMIC_WAIT64_A32 : ATOMIC_I<(outs I32:$dst), (ins P2Align:$p2align, offset32_op:$off, I32:$addr, I64:$exp, I64:$timeout), (outs), (ins P2Align:$p2align, offset32_op:$off), [], "memory.atomic.wait64 \t$dst, ${off}(${addr})${p2align}, $exp, $timeout", "memory.atomic.wait64 \t${off}${p2align}", 0x02, false>; defm MEMORY_ATOMIC_WAIT64_A64 : ATOMIC_I<(outs I32:$dst), (ins P2Align:$p2align, offset64_op:$off, I64:$addr, I64:$exp, I64:$timeout), (outs), (ins P2Align:$p2align, offset64_op:$off), [], "memory.atomic.wait64 \t$dst, ${off}(${addr})${p2align}, $exp, $timeout", "memory.atomic.wait64 \t${off}${p2align}", 0x02, true>; } // mayLoad = 1 } // hasSideEffects = 1 def NotifyPat_A32 : Pat<(i32 (int_wasm_memory_atomic_notify (AddrOps32 offset32_op:$offset, I32:$addr), I32:$count)), (MEMORY_ATOMIC_NOTIFY_A32 0, $offset, $addr, $count)>, Requires<[HasAddr32, HasAtomics]>; def NotifyPat_A64 : Pat<(i32 (int_wasm_memory_atomic_notify (AddrOps64 offset64_op:$offset, I64:$addr), I32:$count)), (MEMORY_ATOMIC_NOTIFY_A64 0, $offset, $addr, $count)>, Requires<[HasAddr64, HasAtomics]>; multiclass WaitPat { def WaitPat_A32 : Pat<(i32 (kind (AddrOps32 offset32_op:$offset, I32:$addr), ty:$exp, I64:$timeout)), (!cast(inst#_A32) 0, $offset, $addr, $exp, $timeout)>, Requires<[HasAddr32, HasAtomics]>; def WaitPat_A64 : Pat<(i32 (kind (AddrOps64 offset64_op:$offset, I64:$addr), ty:$exp, I64:$timeout)), (!cast(inst#_A64) 0, $offset, $addr, $exp, $timeout)>, Requires<[HasAddr64, HasAtomics]>; } defm : WaitPat; defm : WaitPat; //===----------------------------------------------------------------------===// // Atomic fences //===----------------------------------------------------------------------===// // A compiler fence instruction that prevents reordering of instructions. let Defs = [ARGUMENTS] in { let isPseudo = 1, hasSideEffects = 1 in defm COMPILER_FENCE : ATOMIC_NRI<(outs), (ins), [], "compiler_fence">; let hasSideEffects = 1 in defm ATOMIC_FENCE : ATOMIC_NRI<(outs), (ins i8imm:$flags), [], "atomic.fence", 0x03>; } // Defs = [ARGUMENTS] //===----------------------------------------------------------------------===// // Atomic loads //===----------------------------------------------------------------------===// multiclass AtomicLoad { defm "" : WebAssemblyLoad; } defm ATOMIC_LOAD_I32 : AtomicLoad; defm ATOMIC_LOAD_I64 : AtomicLoad; // Select loads defm : LoadPat; defm : LoadPat; // Extending loads. Note that there are only zero-extending atomic loads, no // sign-extending loads. defm ATOMIC_LOAD8_U_I32 : AtomicLoad; defm ATOMIC_LOAD16_U_I32 : AtomicLoad; defm ATOMIC_LOAD8_U_I64 : AtomicLoad; defm ATOMIC_LOAD16_U_I64 : AtomicLoad; defm ATOMIC_LOAD32_U_I64 : AtomicLoad; // Fragments for extending loads. These are different from regular loads because // the SDNodes are derived from AtomicSDNode rather than LoadSDNode and // therefore don't have the extension type field. So instead of matching that, // we match the patterns that the type legalizer expands them to. // Unlike regular loads, extension to i64 is handled differently than i32. // i64 (zext (i8 (atomic_load_8))) gets legalized to // i64 (and (i64 (anyext (i32 (atomic_load_8)))), 255) // Extension to i32 is elided by SelectionDAG as our atomic loads are // zero-extending. def zext_aload_8_64 : PatFrag<(ops node:$addr), (i64 (zext (i32 (atomic_load_8 node:$addr))))>; def zext_aload_16_64 : PatFrag<(ops node:$addr), (i64 (zext (i32 (atomic_load_16 node:$addr))))>; def zext_aload_32_64 : PatFrag<(ops node:$addr), (i64 (zext (i32 (atomic_load_32 node:$addr))))>; // We don't have single sext atomic load instructions. So for sext loads, we // match bare subword loads (for 32-bit results) and anyext loads (for 64-bit // results) and select a zext load; the next instruction will be sext_inreg // which is selected by itself. def sext_aload_8_64 : PatFrag<(ops node:$addr), (anyext (i32 (atomic_load_8 node:$addr)))>; def sext_aload_16_64 : PatFrag<(ops node:$addr), (anyext (i32 (atomic_load_16 node:$addr)))>; // Select zero-extending loads defm : LoadPat; defm : LoadPat; defm : LoadPat; // Select sign-extending loads defm : LoadPat; defm : LoadPat; defm : LoadPat; defm : LoadPat; // 32->64 sext load gets selected as i32.atomic.load, i64.extend_i32_s //===----------------------------------------------------------------------===// // Atomic stores //===----------------------------------------------------------------------===// multiclass AtomicStore { defm "" : WebAssemblyStore; } defm ATOMIC_STORE_I32 : AtomicStore; defm ATOMIC_STORE_I64 : AtomicStore; // We used to need an 'atomic' version of store patterns because store and atomic_store // nodes have different operand orders. // // TODO: This is no longer true and atomic_store and store patterns // can be unified. multiclass AStorePat { def : Pat<(kind ty:$val, (AddrOps32 offset32_op:$offset, I32:$addr)), (!cast(inst#_A32) 0, $offset, $addr, $val)>, Requires<[HasAddr32, HasAtomics]>; def : Pat<(kind ty:$val, (AddrOps64 offset64_op:$offset, I64:$addr)), (!cast(inst#_A64) 0, $offset, $addr, $val)>, Requires<[HasAddr64, HasAtomics]>; } defm : AStorePat; defm : AStorePat; // Truncating stores. defm ATOMIC_STORE8_I32 : AtomicStore; defm ATOMIC_STORE16_I32 : AtomicStore; defm ATOMIC_STORE8_I64 : AtomicStore; defm ATOMIC_STORE16_I64 : AtomicStore; defm ATOMIC_STORE32_I64 : AtomicStore; // Fragments for truncating stores. // We don't have single truncating atomic store instructions. For 32-bit // instructions, we just need to match bare atomic stores. On the other hand, // truncating stores from i64 values are once truncated to i32 first. class trunc_astore_64 : PatFrag<(ops node:$val, node:$addr), (kind (i32 (trunc (i64 node:$val))), node:$addr)>; def trunc_astore_8_64 : trunc_astore_64; def trunc_astore_16_64 : trunc_astore_64; def trunc_astore_32_64 : trunc_astore_64; // Truncating stores with no constant offset defm : AStorePat; defm : AStorePat; defm : AStorePat; defm : AStorePat; defm : AStorePat; //===----------------------------------------------------------------------===// // Atomic binary read-modify-writes //===----------------------------------------------------------------------===// multiclass WebAssemblyBinRMW { defm "_A32" : ATOMIC_I<(outs rc:$dst), (ins P2Align:$p2align, offset32_op:$off, I32:$addr, rc:$val), (outs), (ins P2Align:$p2align, offset32_op:$off), [], !strconcat(name, "\t$dst, ${off}(${addr})${p2align}, $val"), !strconcat(name, "\t${off}${p2align}"), atomic_op, false>; defm "_A64" : ATOMIC_I<(outs rc:$dst), (ins P2Align:$p2align, offset64_op:$off, I64:$addr, rc:$val), (outs), (ins P2Align:$p2align, offset64_op:$off), [], !strconcat(name, "\t$dst, ${off}(${addr})${p2align}, $val"), !strconcat(name, "\t${off}${p2align}"), atomic_op, true>; } defm ATOMIC_RMW_ADD_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW_ADD_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_ADD_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_ADD_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_ADD_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_ADD_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW32_U_ADD_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW_SUB_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW_SUB_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_SUB_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_SUB_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_SUB_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_SUB_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW32_U_SUB_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW_AND_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW_AND_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_AND_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_AND_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_AND_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_AND_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW32_U_AND_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW_OR_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW_OR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_OR_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_OR_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_OR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_OR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW32_U_OR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW_XOR_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW_XOR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_XOR_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_XOR_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_XOR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_XOR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW32_U_XOR_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW_XCHG_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW_XCHG_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_XCHG_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_XCHG_I32 : WebAssemblyBinRMW; defm ATOMIC_RMW8_U_XCHG_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW16_U_XCHG_I64 : WebAssemblyBinRMW; defm ATOMIC_RMW32_U_XCHG_I64 : WebAssemblyBinRMW; multiclass BinRMWPat { def : Pat<(ty (kind (AddrOps32 offset32_op:$offset, I32:$addr), ty:$val)), (!cast(inst#_A32) 0, $offset, $addr, $val)>, Requires<[HasAddr32, HasAtomics]>; def : Pat<(ty (kind (AddrOps64 offset64_op:$offset, I64:$addr), ty:$val)), (!cast(inst#_A64) 0, $offset, $addr, $val)>, Requires<[HasAddr64, HasAtomics]>; } // Patterns for various addressing modes. multiclass BinRMWPattern { defm : BinRMWPat; defm : BinRMWPat; } defm : BinRMWPattern; defm : BinRMWPattern; defm : BinRMWPattern; defm : BinRMWPattern; defm : BinRMWPattern; defm : BinRMWPattern; // Truncating & zero-extending binary RMW patterns. // These are combined patterns of truncating store patterns and zero-extending // load patterns above. class zext_bin_rmw_8_32 : PatFrag<(ops node:$addr, node:$val), (i32 (kind node:$addr, node:$val))>; class zext_bin_rmw_16_32 : zext_bin_rmw_8_32; class zext_bin_rmw_8_64 : PatFrag<(ops node:$addr, node:$val), (zext (i32 (kind node:$addr, (i32 (trunc (i64 node:$val))))))>; class zext_bin_rmw_16_64 : zext_bin_rmw_8_64; class zext_bin_rmw_32_64 : zext_bin_rmw_8_64; // Truncating & sign-extending binary RMW patterns. // These are combined patterns of truncating store patterns and sign-extending // load patterns above. We match subword RMWs (for 32-bit) and anyext RMWs (for // 64-bit) and select a zext RMW; the next instruction will be sext_inreg which // is selected by itself. class sext_bin_rmw_8_32 : PatFrag<(ops node:$addr, node:$val), (kind node:$addr, node:$val)>; class sext_bin_rmw_16_32 : sext_bin_rmw_8_32; class sext_bin_rmw_8_64 : PatFrag<(ops node:$addr, node:$val), (anyext (i32 (kind node:$addr, (i32 (trunc (i64 node:$val))))))>; class sext_bin_rmw_16_64 : sext_bin_rmw_8_64; // 32->64 sext RMW gets selected as i32.atomic.rmw.***, i64.extend_i32_s // Patterns for various addressing modes for truncating-extending binary RMWs. multiclass BinRMWTruncExtPattern< PatFrag rmw_8, PatFrag rmw_16, PatFrag rmw_32, string inst8_32, string inst16_32, string inst8_64, string inst16_64, string inst32_64> { // Truncating-extending binary RMWs defm : BinRMWPat, inst8_32>; defm : BinRMWPat, inst16_32>; defm : BinRMWPat, inst8_64>; defm : BinRMWPat, inst16_64>; defm : BinRMWPat, inst32_64>; defm : BinRMWPat, inst8_32>; defm : BinRMWPat, inst16_32>; defm : BinRMWPat, inst8_64>; defm : BinRMWPat, inst16_64>; } defm : BinRMWTruncExtPattern< atomic_load_add_i8, atomic_load_add_i16, atomic_load_add_i32, "ATOMIC_RMW8_U_ADD_I32", "ATOMIC_RMW16_U_ADD_I32", "ATOMIC_RMW8_U_ADD_I64", "ATOMIC_RMW16_U_ADD_I64", "ATOMIC_RMW32_U_ADD_I64">; defm : BinRMWTruncExtPattern< atomic_load_sub_i8, atomic_load_sub_i16, atomic_load_sub_i32, "ATOMIC_RMW8_U_SUB_I32", "ATOMIC_RMW16_U_SUB_I32", "ATOMIC_RMW8_U_SUB_I64", "ATOMIC_RMW16_U_SUB_I64", "ATOMIC_RMW32_U_SUB_I64">; defm : BinRMWTruncExtPattern< atomic_load_and_i8, atomic_load_and_i16, atomic_load_and_i32, "ATOMIC_RMW8_U_AND_I32", "ATOMIC_RMW16_U_AND_I32", "ATOMIC_RMW8_U_AND_I64", "ATOMIC_RMW16_U_AND_I64", "ATOMIC_RMW32_U_AND_I64">; defm : BinRMWTruncExtPattern< atomic_load_or_i8, atomic_load_or_i16, atomic_load_or_i32, "ATOMIC_RMW8_U_OR_I32", "ATOMIC_RMW16_U_OR_I32", "ATOMIC_RMW8_U_OR_I64", "ATOMIC_RMW16_U_OR_I64", "ATOMIC_RMW32_U_OR_I64">; defm : BinRMWTruncExtPattern< atomic_load_xor_i8, atomic_load_xor_i16, atomic_load_xor_i32, "ATOMIC_RMW8_U_XOR_I32", "ATOMIC_RMW16_U_XOR_I32", "ATOMIC_RMW8_U_XOR_I64", "ATOMIC_RMW16_U_XOR_I64", "ATOMIC_RMW32_U_XOR_I64">; defm : BinRMWTruncExtPattern< atomic_swap_i8, atomic_swap_i16, atomic_swap_i32, "ATOMIC_RMW8_U_XCHG_I32", "ATOMIC_RMW16_U_XCHG_I32", "ATOMIC_RMW8_U_XCHG_I64", "ATOMIC_RMW16_U_XCHG_I64", "ATOMIC_RMW32_U_XCHG_I64">; //===----------------------------------------------------------------------===// // Atomic ternary read-modify-writes //===----------------------------------------------------------------------===// // TODO LLVM IR's cmpxchg instruction returns a pair of {loaded value, success // flag}. When we use the success flag or both values, we can't make use of i64 // truncate/extend versions of instructions for now, which is suboptimal. // Consider adding a pass after instruction selection that optimizes this case // if it is frequent. multiclass WebAssemblyTerRMW { defm "_A32" : ATOMIC_I<(outs rc:$dst), (ins P2Align:$p2align, offset32_op:$off, I32:$addr, rc:$exp, rc:$new_), (outs), (ins P2Align:$p2align, offset32_op:$off), [], !strconcat(name, "\t$dst, ${off}(${addr})${p2align}, $exp, $new_"), !strconcat(name, "\t${off}${p2align}"), atomic_op, false>; defm "_A64" : ATOMIC_I<(outs rc:$dst), (ins P2Align:$p2align, offset64_op:$off, I64:$addr, rc:$exp, rc:$new_), (outs), (ins P2Align:$p2align, offset64_op:$off), [], !strconcat(name, "\t$dst, ${off}(${addr})${p2align}, $exp, $new_"), !strconcat(name, "\t${off}${p2align}"), atomic_op, true>; } defm ATOMIC_RMW_CMPXCHG_I32 : WebAssemblyTerRMW; defm ATOMIC_RMW_CMPXCHG_I64 : WebAssemblyTerRMW; defm ATOMIC_RMW8_U_CMPXCHG_I32 : WebAssemblyTerRMW; defm ATOMIC_RMW16_U_CMPXCHG_I32 : WebAssemblyTerRMW; defm ATOMIC_RMW8_U_CMPXCHG_I64 : WebAssemblyTerRMW; defm ATOMIC_RMW16_U_CMPXCHG_I64 : WebAssemblyTerRMW; defm ATOMIC_RMW32_U_CMPXCHG_I64 : WebAssemblyTerRMW; multiclass TerRMWPat { def : Pat<(ty (kind (AddrOps32 offset32_op:$offset, I32:$addr), ty:$exp, ty:$new)), (!cast(inst#_A32) 0, $offset, $addr, $exp, $new)>, Requires<[HasAddr32, HasAtomics]>; def : Pat<(ty (kind (AddrOps64 offset64_op:$offset, I64:$addr), ty:$exp, ty:$new)), (!cast(inst#_A64) 0, $offset, $addr, $exp, $new)>, Requires<[HasAddr64, HasAtomics]>; } defm : TerRMWPat; defm : TerRMWPat; // Truncating & zero-extending ternary RMW patterns. // DAG legalization & optimization before instruction selection may introduce // additional nodes such as anyext or assertzext depending on operand types. class zext_ter_rmw_8_32 : PatFrag<(ops node:$addr, node:$exp, node:$new), (i32 (kind node:$addr, node:$exp, node:$new))>; class zext_ter_rmw_16_32 : zext_ter_rmw_8_32; class zext_ter_rmw_8_64 : PatFrag<(ops node:$addr, node:$exp, node:$new), (zext (i32 (assertzext (i32 (kind node:$addr, (i32 (trunc (i64 node:$exp))), (i32 (trunc (i64 node:$new))))))))>; class zext_ter_rmw_16_64 : zext_ter_rmw_8_64; class zext_ter_rmw_32_64 : PatFrag<(ops node:$addr, node:$exp, node:$new), (zext (i32 (kind node:$addr, (i32 (trunc (i64 node:$exp))), (i32 (trunc (i64 node:$new))))))>; // Truncating & sign-extending ternary RMW patterns. // We match subword RMWs (for 32-bit) and anyext RMWs (for 64-bit) and select a // zext RMW; the next instruction will be sext_inreg which is selected by // itself. class sext_ter_rmw_8_32 : PatFrag<(ops node:$addr, node:$exp, node:$new), (kind node:$addr, node:$exp, node:$new)>; class sext_ter_rmw_16_32 : sext_ter_rmw_8_32; class sext_ter_rmw_8_64 : PatFrag<(ops node:$addr, node:$exp, node:$new), (anyext (i32 (assertzext (i32 (kind node:$addr, (i32 (trunc (i64 node:$exp))), (i32 (trunc (i64 node:$new))))))))>; class sext_ter_rmw_16_64 : sext_ter_rmw_8_64; // 32->64 sext RMW gets selected as i32.atomic.rmw.***, i64.extend_i32_s defm : TerRMWPat, "ATOMIC_RMW8_U_CMPXCHG_I32">; defm : TerRMWPat, "ATOMIC_RMW16_U_CMPXCHG_I32">; defm : TerRMWPat, "ATOMIC_RMW8_U_CMPXCHG_I64">; defm : TerRMWPat, "ATOMIC_RMW16_U_CMPXCHG_I64">; defm : TerRMWPat, "ATOMIC_RMW32_U_CMPXCHG_I64">; defm : TerRMWPat, "ATOMIC_RMW8_U_CMPXCHG_I32">; defm : TerRMWPat, "ATOMIC_RMW16_U_CMPXCHG_I32">; defm : TerRMWPat, "ATOMIC_RMW8_U_CMPXCHG_I64">; defm : TerRMWPat, "ATOMIC_RMW16_U_CMPXCHG_I64">;