src/third_party/llvm-project/llvm/test/CodeGen/WebAssembly/atomic-mem-consistency.ll - cobalt - Git at Google

 ; RUN: not llc < %s -asm-verbose=false -disable-wasm-fallthrough-return-opt
 ; RUN: llc < %s -asm-verbose=false -disable-wasm-fallthrough-return-opt -disable-wasm-explicit-locals -mattr=+atomics,+sign-ext | FileCheck %s

 ; Currently all wasm atomic memory access instructions are sequentially
 ; consistent, so even if LLVM IR specifies weaker orderings than that, we
 ; should upgrade them to sequential ordering and treat them in the same way.

 target datalayout = "e-m:e-p:32:32-i64:64-n32:64-S128"
 target triple = "wasm32-unknown-unknown"

 ;===----------------------------------------------------------------------------
 ; Atomic loads
 ;===----------------------------------------------------------------------------

 ; The 'release' and 'acq_rel' orderings are not valid on load instructions.

 ; CHECK-LABEL: load_i32_unordered:
 ; CHECK: i32.atomic.load $push0=, 0($0){{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @load_i32_unordered(i32 *%p) {
   %v = load atomic i32, i32* %p unordered, align 4
   ret i32 %v
 }

 ; CHECK-LABEL: load_i32_monotonic:
 ; CHECK: i32.atomic.load $push0=, 0($0){{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @load_i32_monotonic(i32 *%p) {
   %v = load atomic i32, i32* %p monotonic, align 4
   ret i32 %v
 }

 ; CHECK-LABEL: load_i32_acquire:
 ; CHECK: i32.atomic.load $push0=, 0($0){{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @load_i32_acquire(i32 *%p) {
   %v = load atomic i32, i32* %p acquire, align 4
   ret i32 %v
 }

 ; CHECK-LABEL: load_i32_seq_cst:
 ; CHECK: i32.atomic.load $push0=, 0($0){{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @load_i32_seq_cst(i32 *%p) {
   %v = load atomic i32, i32* %p seq_cst, align 4
   ret i32 %v
 }

 ;===----------------------------------------------------------------------------
 ; Atomic stores
 ;===----------------------------------------------------------------------------

 ; The 'acquire' and 'acq_rel' orderings aren’t valid on store instructions.

 ; CHECK-LABEL: store_i32_unordered:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
 ; CHECK-NEXT: return{{$}}
 define void @store_i32_unordered(i32 *%p, i32 %v) {
   store atomic i32 %v, i32* %p unordered, align 4
   ret void
 }

 ; CHECK-LABEL: store_i32_monotonic:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
 ; CHECK-NEXT: return{{$}}
 define void @store_i32_monotonic(i32 *%p, i32 %v) {
   store atomic i32 %v, i32* %p monotonic, align 4
   ret void
 }

 ; CHECK-LABEL: store_i32_release:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
 ; CHECK-NEXT: return{{$}}
 define void @store_i32_release(i32 *%p, i32 %v) {
   store atomic i32 %v, i32* %p release, align 4
   ret void
 }

 ; CHECK-LABEL: store_i32_seq_cst:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
 ; CHECK-NEXT: return{{$}}
 define void @store_i32_seq_cst(i32 *%p, i32 %v) {
   store atomic i32 %v, i32* %p seq_cst, align 4
   ret void
 }

 ;===----------------------------------------------------------------------------
 ; Atomic read-modify-writes
 ;===----------------------------------------------------------------------------

 ; Out of several binary RMW instructions, here we test 'add' as an example.
 ; The 'unordered' ordering is not valid on atomicrmw instructions.

 ; CHECK-LABEL: add_i32_monotonic:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @add_i32_monotonic(i32* %p, i32 %v) {
   %old = atomicrmw add i32* %p, i32 %v monotonic
   ret i32 %old
 }

 ; CHECK-LABEL: add_i32_acquire:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @add_i32_acquire(i32* %p, i32 %v) {
   %old = atomicrmw add i32* %p, i32 %v acquire
   ret i32 %old
 }

 ; CHECK-LABEL: add_i32_release:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @add_i32_release(i32* %p, i32 %v) {
   %old = atomicrmw add i32* %p, i32 %v release
   ret i32 %old
 }

 ; CHECK-LABEL: add_i32_acq_rel:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @add_i32_acq_rel(i32* %p, i32 %v) {
   %old = atomicrmw add i32* %p, i32 %v acq_rel
   ret i32 %old
 }

 ; CHECK-LABEL: add_i32_seq_cst:
 ; CHECK-NEXT: .param i32, i32{{$}}
 ; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
 ; CHECK-NEXT: return $pop0{{$}}
 define i32 @add_i32_seq_cst(i32* %p, i32 %v) {
   %old = atomicrmw add i32* %p, i32 %v seq_cst
   ret i32 %old
 }
	; RUN: not llc < %s -asm-verbose=false -disable-wasm-fallthrough-return-opt
	; RUN: llc < %s -asm-verbose=false -disable-wasm-fallthrough-return-opt -disable-wasm-explicit-locals -mattr=+atomics,+sign-ext \| FileCheck %s

	; Currently all wasm atomic memory access instructions are sequentially
	; consistent, so even if LLVM IR specifies weaker orderings than that, we
	; should upgrade them to sequential ordering and treat them in the same way.

	target datalayout = "e-m:e-p:32:32-i64:64-n32:64-S128"
	target triple = "wasm32-unknown-unknown"

	;===----------------------------------------------------------------------------
	; Atomic loads
	;===----------------------------------------------------------------------------

	; The 'release' and 'acq_rel' orderings are not valid on load instructions.

	; CHECK-LABEL: load_i32_unordered:
	; CHECK: i32.atomic.load $push0=, 0($0){{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @load_i32_unordered(i32 *%p) {
	%v = load atomic i32, i32* %p unordered, align 4
	ret i32 %v
	}

	; CHECK-LABEL: load_i32_monotonic:
	; CHECK: i32.atomic.load $push0=, 0($0){{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @load_i32_monotonic(i32 *%p) {
	%v = load atomic i32, i32* %p monotonic, align 4
	ret i32 %v
	}

	; CHECK-LABEL: load_i32_acquire:
	; CHECK: i32.atomic.load $push0=, 0($0){{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @load_i32_acquire(i32 *%p) {
	%v = load atomic i32, i32* %p acquire, align 4
	ret i32 %v
	}

	; CHECK-LABEL: load_i32_seq_cst:
	; CHECK: i32.atomic.load $push0=, 0($0){{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @load_i32_seq_cst(i32 *%p) {
	%v = load atomic i32, i32* %p seq_cst, align 4
	ret i32 %v
	}

	;===----------------------------------------------------------------------------
	; Atomic stores
	;===----------------------------------------------------------------------------

	; The 'acquire' and 'acq_rel' orderings aren’t valid on store instructions.

	; CHECK-LABEL: store_i32_unordered:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
	; CHECK-NEXT: return{{$}}
	define void @store_i32_unordered(i32 *%p, i32 %v) {
	store atomic i32 %v, i32* %p unordered, align 4
	ret void
	}

	; CHECK-LABEL: store_i32_monotonic:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
	; CHECK-NEXT: return{{$}}
	define void @store_i32_monotonic(i32 *%p, i32 %v) {
	store atomic i32 %v, i32* %p monotonic, align 4
	ret void
	}

	; CHECK-LABEL: store_i32_release:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
	; CHECK-NEXT: return{{$}}
	define void @store_i32_release(i32 *%p, i32 %v) {
	store atomic i32 %v, i32* %p release, align 4
	ret void
	}

	; CHECK-LABEL: store_i32_seq_cst:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK-NEXT: i32.atomic.store 0($0), $1{{$}}
	; CHECK-NEXT: return{{$}}
	define void @store_i32_seq_cst(i32 *%p, i32 %v) {
	store atomic i32 %v, i32* %p seq_cst, align 4
	ret void
	}

	;===----------------------------------------------------------------------------
	; Atomic read-modify-writes
	;===----------------------------------------------------------------------------

	; Out of several binary RMW instructions, here we test 'add' as an example.
	; The 'unordered' ordering is not valid on atomicrmw instructions.

	; CHECK-LABEL: add_i32_monotonic:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @add_i32_monotonic(i32* %p, i32 %v) {
	%old = atomicrmw add i32* %p, i32 %v monotonic
	ret i32 %old
	}

	; CHECK-LABEL: add_i32_acquire:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @add_i32_acquire(i32* %p, i32 %v) {
	%old = atomicrmw add i32* %p, i32 %v acquire
	ret i32 %old
	}

	; CHECK-LABEL: add_i32_release:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @add_i32_release(i32* %p, i32 %v) {
	%old = atomicrmw add i32* %p, i32 %v release
	ret i32 %old
	}

	; CHECK-LABEL: add_i32_acq_rel:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @add_i32_acq_rel(i32* %p, i32 %v) {
	%old = atomicrmw add i32* %p, i32 %v acq_rel
	ret i32 %old
	}

	; CHECK-LABEL: add_i32_seq_cst:
	; CHECK-NEXT: .param i32, i32{{$}}
	; CHECK: i32.atomic.rmw.add $push0=, 0($0), $1{{$}}
	; CHECK-NEXT: return $pop0{{$}}
	define i32 @add_i32_seq_cst(i32* %p, i32 %v) {
	%old = atomicrmw add i32* %p, i32 %v seq_cst
	ret i32 %old
	}