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llvm-mirror/test/CodeGen/PowerPC/sub-of-not.ll
David Green f56c09c87f [MachineScheduler] Update available queue on the first mop of a new cycle
If a resource can be held for multiple cycles in the schedule model
then an instruction can be placed into the available queue, another
instruction can be scheduled, but the first will not be taken back out if
the two instructions hazard. To fix this make sure that we update the
available queue even on the first MOp of a cycle, pushing available
instructions back into the pending queue if they now conflict.

This happens with some downstream schedules we have around MVE
instruction scheduling where we use ResourceCycles=[2] to show the
instruction executing over two beats. Apparently the test changes here
are OK too.

Differential Revision: https://reviews.llvm.org/D76909
2020-06-09 19:13:53 +01:00

436 lines
14 KiB
LLVM

; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
; RUN: llc < %s -mtriple=ppc32-unknown-unknown | FileCheck %s --check-prefixes=ALL,PPC32
; RUN: llc < %s -mtriple=powerpc64-unknown-unknown | FileCheck %s --check-prefixes=ALL,PPC64,PPC64BE
; RUN: llc < %s -mtriple=powerpc64le-unknown-unknown | FileCheck %s --check-prefixes=ALL,PPC64,PPC64LE
; These two forms are equivalent:
; sub %y, (xor %x, -1)
; add (add %x, 1), %y
; Some targets may prefer one to the other.
define i8 @scalar_i8(i8 %x, i8 %y) nounwind {
; ALL-LABEL: scalar_i8:
; ALL: # %bb.0:
; ALL-NEXT: add 3, 4, 3
; ALL-NEXT: addi 3, 3, 1
; ALL-NEXT: blr
%t0 = xor i8 %x, -1
%t1 = sub i8 %y, %t0
ret i8 %t1
}
define i16 @scalar_i16(i16 %x, i16 %y) nounwind {
; ALL-LABEL: scalar_i16:
; ALL: # %bb.0:
; ALL-NEXT: add 3, 4, 3
; ALL-NEXT: addi 3, 3, 1
; ALL-NEXT: blr
%t0 = xor i16 %x, -1
%t1 = sub i16 %y, %t0
ret i16 %t1
}
define i32 @scalar_i32(i32 %x, i32 %y) nounwind {
; ALL-LABEL: scalar_i32:
; ALL: # %bb.0:
; ALL-NEXT: add 3, 4, 3
; ALL-NEXT: addi 3, 3, 1
; ALL-NEXT: blr
%t0 = xor i32 %x, -1
%t1 = sub i32 %y, %t0
ret i32 %t1
}
define i64 @scalar_i64(i64 %x, i64 %y) nounwind {
; PPC32-LABEL: scalar_i64:
; PPC32: # %bb.0:
; PPC32-NEXT: addc 4, 6, 4
; PPC32-NEXT: adde 3, 5, 3
; PPC32-NEXT: addic 4, 4, 1
; PPC32-NEXT: addze 3, 3
; PPC32-NEXT: blr
;
; PPC64-LABEL: scalar_i64:
; PPC64: # %bb.0:
; PPC64-NEXT: add 3, 4, 3
; PPC64-NEXT: addi 3, 3, 1
; PPC64-NEXT: blr
%t0 = xor i64 %x, -1
%t1 = sub i64 %y, %t0
ret i64 %t1
}
define <16 x i8> @vector_i128_i8(<16 x i8> %x, <16 x i8> %y) nounwind {
; PPC32-LABEL: vector_i128_i8:
; PPC32: # %bb.0:
; PPC32-NEXT: stwu 1, -64(1)
; PPC32-NEXT: stw 21, 20(1) # 4-byte Folded Spill
; PPC32-NEXT: lbz 21, 123(1)
; PPC32-NEXT: stw 22, 24(1) # 4-byte Folded Spill
; PPC32-NEXT: stw 23, 28(1) # 4-byte Folded Spill
; PPC32-NEXT: add 7, 21, 7
; PPC32-NEXT: lbz 23, 115(1)
; PPC32-NEXT: lbz 22, 119(1)
; PPC32-NEXT: lbz 21, 135(1)
; PPC32-NEXT: add 5, 23, 5
; PPC32-NEXT: lbz 23, 127(1)
; PPC32-NEXT: add 6, 22, 6
; PPC32-NEXT: lbz 22, 131(1)
; PPC32-NEXT: add 10, 21, 10
; PPC32-NEXT: stw 26, 40(1) # 4-byte Folded Spill
; PPC32-NEXT: add 8, 23, 8
; PPC32-NEXT: lbz 26, 83(1)
; PPC32-NEXT: add 9, 22, 9
; PPC32-NEXT: lbz 21, 147(1)
; PPC32-NEXT: stw 24, 32(1) # 4-byte Folded Spill
; PPC32-NEXT: stw 25, 36(1) # 4-byte Folded Spill
; PPC32-NEXT: add 26, 21, 26
; PPC32-NEXT: lbz 25, 79(1)
; PPC32-NEXT: lbz 24, 75(1)
; PPC32-NEXT: lbz 23, 139(1)
; PPC32-NEXT: lbz 22, 143(1)
; PPC32-NEXT: stw 29, 52(1) # 4-byte Folded Spill
; PPC32-NEXT: add 24, 23, 24
; PPC32-NEXT: lbz 29, 95(1)
; PPC32-NEXT: add 25, 22, 25
; PPC32-NEXT: lbz 21, 159(1)
; PPC32-NEXT: stw 27, 44(1) # 4-byte Folded Spill
; PPC32-NEXT: stw 28, 48(1) # 4-byte Folded Spill
; PPC32-NEXT: add 29, 21, 29
; PPC32-NEXT: lbz 28, 91(1)
; PPC32-NEXT: lbz 27, 87(1)
; PPC32-NEXT: lbz 23, 151(1)
; PPC32-NEXT: lbz 22, 155(1)
; PPC32-NEXT: lbz 4, 111(1)
; PPC32-NEXT: add 27, 23, 27
; PPC32-NEXT: lbz 21, 175(1)
; PPC32-NEXT: add 28, 22, 28
; PPC32-NEXT: lbz 11, 107(1)
; PPC32-NEXT: lbz 12, 171(1)
; PPC32-NEXT: add 4, 21, 4
; PPC32-NEXT: stw 30, 56(1) # 4-byte Folded Spill
; PPC32-NEXT: addi 4, 4, 1
; PPC32-NEXT: lbz 0, 103(1)
; PPC32-NEXT: add 11, 12, 11
; PPC32-NEXT: lbz 30, 99(1)
; PPC32-NEXT: lbz 23, 163(1)
; PPC32-NEXT: lbz 22, 167(1)
; PPC32-NEXT: add 30, 23, 30
; PPC32-NEXT: stb 4, 15(3)
; PPC32-NEXT: add 23, 22, 0
; PPC32-NEXT: addi 4, 11, 1
; PPC32-NEXT: stb 4, 14(3)
; PPC32-NEXT: addi 4, 23, 1
; PPC32-NEXT: stb 4, 13(3)
; PPC32-NEXT: addi 4, 30, 1
; PPC32-NEXT: stb 4, 12(3)
; PPC32-NEXT: addi 4, 29, 1
; PPC32-NEXT: stb 4, 11(3)
; PPC32-NEXT: addi 4, 28, 1
; PPC32-NEXT: stb 4, 10(3)
; PPC32-NEXT: addi 4, 27, 1
; PPC32-NEXT: stb 4, 9(3)
; PPC32-NEXT: addi 4, 26, 1
; PPC32-NEXT: stb 4, 8(3)
; PPC32-NEXT: addi 4, 25, 1
; PPC32-NEXT: stb 4, 7(3)
; PPC32-NEXT: addi 4, 24, 1
; PPC32-NEXT: stb 4, 6(3)
; PPC32-NEXT: addi 4, 10, 1
; PPC32-NEXT: stb 4, 5(3)
; PPC32-NEXT: addi 4, 9, 1
; PPC32-NEXT: stb 4, 4(3)
; PPC32-NEXT: addi 4, 8, 1
; PPC32-NEXT: stb 4, 3(3)
; PPC32-NEXT: addi 4, 7, 1
; PPC32-NEXT: stb 4, 2(3)
; PPC32-NEXT: addi 4, 6, 1
; PPC32-NEXT: stb 4, 1(3)
; PPC32-NEXT: addi 4, 5, 1
; PPC32-NEXT: stb 4, 0(3)
; PPC32-NEXT: lwz 30, 56(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 29, 52(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 28, 48(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 27, 44(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 26, 40(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 25, 36(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 24, 32(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 23, 28(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 22, 24(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 21, 20(1) # 4-byte Folded Reload
; PPC32-NEXT: addi 1, 1, 64
; PPC32-NEXT: blr
;
; PPC64BE-LABEL: vector_i128_i8:
; PPC64BE: # %bb.0:
; PPC64BE-NEXT: std 21, -88(1) # 8-byte Folded Spill
; PPC64BE-NEXT: lbz 21, 207(1)
; PPC64BE-NEXT: std 22, -80(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 23, -72(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 25, -56(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 24, -64(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 28, -32(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 27, -40(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 26, -48(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 30, -16(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 29, -24(1) # 8-byte Folded Spill
; PPC64BE-NEXT: lbz 22, 199(1)
; PPC64BE-NEXT: lbz 23, 191(1)
; PPC64BE-NEXT: add 6, 21, 6
; PPC64BE-NEXT: lbz 21, 231(1)
; PPC64BE-NEXT: add 5, 22, 5
; PPC64BE-NEXT: lbz 22, 223(1)
; PPC64BE-NEXT: add 4, 23, 4
; PPC64BE-NEXT: lbz 23, 215(1)
; PPC64BE-NEXT: add 9, 21, 9
; PPC64BE-NEXT: lbz 25, 127(1)
; PPC64BE-NEXT: add 8, 22, 8
; PPC64BE-NEXT: lbz 21, 255(1)
; PPC64BE-NEXT: add 7, 23, 7
; PPC64BE-NEXT: lbz 24, 119(1)
; PPC64BE-NEXT: addi 9, 9, 1
; PPC64BE-NEXT: lbz 22, 247(1)
; PPC64BE-NEXT: add 25, 21, 25
; PPC64BE-NEXT: lbz 23, 239(1)
; PPC64BE-NEXT: addi 8, 8, 1
; PPC64BE-NEXT: lbz 28, 151(1)
; PPC64BE-NEXT: add 24, 22, 24
; PPC64BE-NEXT: lbz 21, 279(1)
; PPC64BE-NEXT: add 10, 23, 10
; PPC64BE-NEXT: lbz 27, 143(1)
; PPC64BE-NEXT: addi 10, 10, 1
; PPC64BE-NEXT: lbz 22, 271(1)
; PPC64BE-NEXT: add 28, 21, 28
; PPC64BE-NEXT: lbz 26, 135(1)
; PPC64BE-NEXT: addi 7, 7, 1
; PPC64BE-NEXT: lbz 23, 263(1)
; PPC64BE-NEXT: add 27, 22, 27
; PPC64BE-NEXT: lbz 11, 183(1)
; PPC64BE-NEXT: addi 6, 6, 1
; PPC64BE-NEXT: lbz 21, 311(1)
; PPC64BE-NEXT: add 26, 23, 26
; PPC64BE-NEXT: lbz 12, 175(1)
; PPC64BE-NEXT: addi 5, 5, 1
; PPC64BE-NEXT: lbz 0, 303(1)
; PPC64BE-NEXT: add 11, 21, 11
; PPC64BE-NEXT: lbz 30, 167(1)
; PPC64BE-NEXT: addi 11, 11, 1
; PPC64BE-NEXT: lbz 22, 295(1)
; PPC64BE-NEXT: add 12, 0, 12
; PPC64BE-NEXT: lbz 29, 159(1)
; PPC64BE-NEXT: addi 4, 4, 1
; PPC64BE-NEXT: lbz 23, 287(1)
; PPC64BE-NEXT: add 30, 22, 30
; PPC64BE-NEXT: stb 11, 15(3)
; PPC64BE-NEXT: addi 11, 12, 1
; PPC64BE-NEXT: add 29, 23, 29
; PPC64BE-NEXT: stb 11, 14(3)
; PPC64BE-NEXT: addi 11, 30, 1
; PPC64BE-NEXT: stb 11, 13(3)
; PPC64BE-NEXT: addi 11, 29, 1
; PPC64BE-NEXT: stb 11, 12(3)
; PPC64BE-NEXT: addi 11, 28, 1
; PPC64BE-NEXT: stb 11, 11(3)
; PPC64BE-NEXT: addi 11, 27, 1
; PPC64BE-NEXT: stb 11, 10(3)
; PPC64BE-NEXT: addi 11, 26, 1
; PPC64BE-NEXT: stb 11, 9(3)
; PPC64BE-NEXT: addi 11, 25, 1
; PPC64BE-NEXT: stb 11, 8(3)
; PPC64BE-NEXT: addi 11, 24, 1
; PPC64BE-NEXT: stb 11, 7(3)
; PPC64BE-NEXT: stb 10, 6(3)
; PPC64BE-NEXT: stb 9, 5(3)
; PPC64BE-NEXT: stb 8, 4(3)
; PPC64BE-NEXT: stb 7, 3(3)
; PPC64BE-NEXT: stb 6, 2(3)
; PPC64BE-NEXT: stb 5, 1(3)
; PPC64BE-NEXT: stb 4, 0(3)
; PPC64BE-NEXT: ld 30, -16(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 29, -24(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 28, -32(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 27, -40(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 26, -48(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 25, -56(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 24, -64(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 23, -72(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 22, -80(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 21, -88(1) # 8-byte Folded Reload
; PPC64BE-NEXT: blr
;
; PPC64LE-LABEL: vector_i128_i8:
; PPC64LE: # %bb.0:
; PPC64LE-NEXT: xxlnor 34, 34, 34
; PPC64LE-NEXT: vsububm 2, 3, 2
; PPC64LE-NEXT: blr
%t0 = xor <16 x i8> %x, <i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1, i8 -1>
%t1 = sub <16 x i8> %y, %t0
ret <16 x i8> %t1
}
define <8 x i16> @vector_i128_i16(<8 x i16> %x, <8 x i16> %y) nounwind {
; PPC32-LABEL: vector_i128_i16:
; PPC32: # %bb.0:
; PPC32-NEXT: stwu 1, -32(1)
; PPC32-NEXT: stw 26, 8(1) # 4-byte Folded Spill
; PPC32-NEXT: stw 27, 12(1) # 4-byte Folded Spill
; PPC32-NEXT: stw 28, 16(1) # 4-byte Folded Spill
; PPC32-NEXT: stw 29, 20(1) # 4-byte Folded Spill
; PPC32-NEXT: stw 30, 24(1) # 4-byte Folded Spill
; PPC32-NEXT: lhz 11, 70(1)
; PPC32-NEXT: lhz 12, 66(1)
; PPC32-NEXT: lhz 0, 62(1)
; PPC32-NEXT: add 10, 11, 10
; PPC32-NEXT: lhz 30, 58(1)
; PPC32-NEXT: add 9, 12, 9
; PPC32-NEXT: lhz 29, 50(1)
; PPC32-NEXT: add 8, 0, 8
; PPC32-NEXT: lhz 28, 42(1)
; PPC32-NEXT: add 7, 30, 7
; PPC32-NEXT: lhz 27, 46(1)
; PPC32-NEXT: add 5, 29, 5
; PPC32-NEXT: lhz 26, 54(1)
; PPC32-NEXT: add 3, 28, 3
; PPC32-NEXT: add 4, 27, 4
; PPC32-NEXT: addi 3, 3, 1
; PPC32-NEXT: add 6, 26, 6
; PPC32-NEXT: addi 4, 4, 1
; PPC32-NEXT: addi 5, 5, 1
; PPC32-NEXT: addi 6, 6, 1
; PPC32-NEXT: addi 7, 7, 1
; PPC32-NEXT: addi 8, 8, 1
; PPC32-NEXT: addi 9, 9, 1
; PPC32-NEXT: addi 10, 10, 1
; PPC32-NEXT: lwz 30, 24(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 29, 20(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 28, 16(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 27, 12(1) # 4-byte Folded Reload
; PPC32-NEXT: lwz 26, 8(1) # 4-byte Folded Reload
; PPC32-NEXT: addi 1, 1, 32
; PPC32-NEXT: blr
;
; PPC64BE-LABEL: vector_i128_i16:
; PPC64BE: # %bb.0:
; PPC64BE-NEXT: std 25, -56(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 26, -48(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 27, -40(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 28, -32(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 29, -24(1) # 8-byte Folded Spill
; PPC64BE-NEXT: std 30, -16(1) # 8-byte Folded Spill
; PPC64BE-NEXT: lhz 11, 118(1)
; PPC64BE-NEXT: lhz 12, 182(1)
; PPC64BE-NEXT: lhz 0, 174(1)
; PPC64BE-NEXT: lhz 30, 166(1)
; PPC64BE-NEXT: add 11, 12, 11
; PPC64BE-NEXT: lhz 29, 158(1)
; PPC64BE-NEXT: add 10, 0, 10
; PPC64BE-NEXT: lhz 28, 142(1)
; PPC64BE-NEXT: add 9, 30, 9
; PPC64BE-NEXT: lhz 27, 126(1)
; PPC64BE-NEXT: add 8, 29, 8
; PPC64BE-NEXT: lhz 26, 134(1)
; PPC64BE-NEXT: add 6, 28, 6
; PPC64BE-NEXT: lhz 25, 150(1)
; PPC64BE-NEXT: add 4, 27, 4
; PPC64BE-NEXT: add 5, 26, 5
; PPC64BE-NEXT: addi 11, 11, 1
; PPC64BE-NEXT: add 7, 25, 7
; PPC64BE-NEXT: addi 10, 10, 1
; PPC64BE-NEXT: addi 9, 9, 1
; PPC64BE-NEXT: addi 8, 8, 1
; PPC64BE-NEXT: addi 7, 7, 1
; PPC64BE-NEXT: addi 6, 6, 1
; PPC64BE-NEXT: addi 5, 5, 1
; PPC64BE-NEXT: addi 4, 4, 1
; PPC64BE-NEXT: sth 11, 14(3)
; PPC64BE-NEXT: sth 10, 12(3)
; PPC64BE-NEXT: sth 9, 10(3)
; PPC64BE-NEXT: sth 8, 8(3)
; PPC64BE-NEXT: sth 7, 6(3)
; PPC64BE-NEXT: sth 6, 4(3)
; PPC64BE-NEXT: sth 5, 2(3)
; PPC64BE-NEXT: sth 4, 0(3)
; PPC64BE-NEXT: ld 30, -16(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 29, -24(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 28, -32(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 27, -40(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 26, -48(1) # 8-byte Folded Reload
; PPC64BE-NEXT: ld 25, -56(1) # 8-byte Folded Reload
; PPC64BE-NEXT: blr
;
; PPC64LE-LABEL: vector_i128_i16:
; PPC64LE: # %bb.0:
; PPC64LE-NEXT: xxlnor 34, 34, 34
; PPC64LE-NEXT: vsubuhm 2, 3, 2
; PPC64LE-NEXT: blr
%t0 = xor <8 x i16> %x, <i16 -1, i16 -1, i16 -1, i16 -1, i16 -1, i16 -1, i16 -1, i16 -1>
%t1 = sub <8 x i16> %y, %t0
ret <8 x i16> %t1
}
define <4 x i32> @vector_i128_i32(<4 x i32> %x, <4 x i32> %y) nounwind {
; PPC32-LABEL: vector_i128_i32:
; PPC32: # %bb.0:
; PPC32-NEXT: add 3, 7, 3
; PPC32-NEXT: add 4, 8, 4
; PPC32-NEXT: add 5, 9, 5
; PPC32-NEXT: add 6, 10, 6
; PPC32-NEXT: addi 3, 3, 1
; PPC32-NEXT: addi 4, 4, 1
; PPC32-NEXT: addi 5, 5, 1
; PPC32-NEXT: addi 6, 6, 1
; PPC32-NEXT: blr
;
; PPC64BE-LABEL: vector_i128_i32:
; PPC64BE: # %bb.0:
; PPC64BE-NEXT: add 6, 10, 6
; PPC64BE-NEXT: add 5, 9, 5
; PPC64BE-NEXT: add 4, 8, 4
; PPC64BE-NEXT: add 3, 7, 3
; PPC64BE-NEXT: addi 6, 6, 1
; PPC64BE-NEXT: addi 5, 5, 1
; PPC64BE-NEXT: addi 4, 4, 1
; PPC64BE-NEXT: addi 3, 3, 1
; PPC64BE-NEXT: blr
;
; PPC64LE-LABEL: vector_i128_i32:
; PPC64LE: # %bb.0:
; PPC64LE-NEXT: xxlnor 34, 34, 34
; PPC64LE-NEXT: vsubuwm 2, 3, 2
; PPC64LE-NEXT: blr
%t0 = xor <4 x i32> %x, <i32 -1, i32 -1, i32 -1, i32 -1>
%t1 = sub <4 x i32> %y, %t0
ret <4 x i32> %t1
}
define <2 x i64> @vector_i128_i64(<2 x i64> %x, <2 x i64> %y) nounwind {
; PPC32-LABEL: vector_i128_i64:
; PPC32: # %bb.0:
; PPC32-NEXT: not 4, 4
; PPC32-NEXT: not 3, 3
; PPC32-NEXT: subc 4, 8, 4
; PPC32-NEXT: not 6, 6
; PPC32-NEXT: subfe 3, 3, 7
; PPC32-NEXT: not 5, 5
; PPC32-NEXT: subc 6, 10, 6
; PPC32-NEXT: subfe 5, 5, 9
; PPC32-NEXT: blr
;
; PPC64BE-LABEL: vector_i128_i64:
; PPC64BE: # %bb.0:
; PPC64BE-NEXT: add 3, 5, 3
; PPC64BE-NEXT: add 4, 6, 4
; PPC64BE-NEXT: addi 3, 3, 1
; PPC64BE-NEXT: addi 4, 4, 1
; PPC64BE-NEXT: blr
;
; PPC64LE-LABEL: vector_i128_i64:
; PPC64LE: # %bb.0:
; PPC64LE-NEXT: xxlnor 34, 34, 34
; PPC64LE-NEXT: vsubudm 2, 3, 2
; PPC64LE-NEXT: blr
%t0 = xor <2 x i64> %x, <i64 -1, i64 -1>
%t1 = sub <2 x i64> %y, %t0
ret <2 x i64> %t1
}