llvm/test/CodeGen/AArch64/bitfield-insert.ll - third_party/github.com/llvm/llvm-project - Git at Google

 ; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
 ; RUN: llc -mtriple=aarch64-none-linux-gnu < %s | FileCheck %s

 ; First, a simple example from Clang. The registers could plausibly be
 ; different, but probably won't be.

 %struct.foo = type { i8, [2 x i8], i8 }

 define [1 x i64] @from_clang([1 x i64] %f.coerce, i32 %n) nounwind readnone {
 ; CHECK-LABEL: from_clang:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    mov w8, #135
 ; CHECK-NEXT:    and w8, w0, w8
 ; CHECK-NEXT:    bfi w8, w1, #3, #4
 ; CHECK-NEXT:    and x9, x0, #0xffffff00
 ; CHECK-NEXT:    orr x0, x8, x9
 ; CHECK-NEXT:    ret
 entry:
   %f.coerce.fca.0.extract = extractvalue [1 x i64] %f.coerce, 0
   %tmp.sroa.0.0.extract.trunc = trunc i64 %f.coerce.fca.0.extract to i32
   %bf.value = shl i32 %n, 3
   %0 = and i32 %bf.value, 120
   %f.sroa.0.0.insert.ext.masked = and i32 %tmp.sroa.0.0.extract.trunc, 135
   %1 = or i32 %f.sroa.0.0.insert.ext.masked, %0
   %f.sroa.0.0.extract.trunc = zext i32 %1 to i64
   %tmp1.sroa.1.1.insert.insert = and i64 %f.coerce.fca.0.extract, 4294967040
   %tmp1.sroa.0.0.insert.insert = or i64 %f.sroa.0.0.extract.trunc, %tmp1.sroa.1.1.insert.insert
   %.fca.0.insert = insertvalue [1 x i64] undef, i64 %tmp1.sroa.0.0.insert.insert, 0
   ret [1 x i64] %.fca.0.insert
 }

 define void @test_whole32(i32* %existing, i32* %new) {
 ; CHECK-LABEL: test_whole32:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    ldr w9, [x1]
 ; CHECK-NEXT:    bfi w8, w9, #26, #5
 ; CHECK-NEXT:    str w8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i32, i32* %existing
   %oldval_keep = and i32 %oldval, 2214592511 ; =0x83ffffff

   %newval = load volatile i32, i32* %new
   %newval_shifted = shl i32 %newval, 26
   %newval_masked = and i32 %newval_shifted, 2080374784 ; = 0x7c000000

   %combined = or i32 %oldval_keep, %newval_masked
   store volatile i32 %combined, i32* %existing

   ret void
 }

 define void @test_whole64(i64* %existing, i64* %new) {
 ; CHECK-LABEL: test_whole64:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr x8, [x0]
 ; CHECK-NEXT:    ldr x9, [x1]
 ; CHECK-NEXT:    bfi x8, x9, #26, #14
 ; CHECK-NEXT:    str x8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i64, i64* %existing
   %oldval_keep = and i64 %oldval, 18446742974265032703 ; = 0xffffff0003ffffffL

   %newval = load volatile i64, i64* %new
   %newval_shifted = shl i64 %newval, 26
   %newval_masked = and i64 %newval_shifted, 1099444518912 ; = 0xfffc000000

   %combined = or i64 %oldval_keep, %newval_masked
   store volatile i64 %combined, i64* %existing

   ret void
 }

 define void @test_whole32_from64(i64* %existing, i64* %new) {
 ; CHECK-LABEL: test_whole32_from64:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr x8, [x0]
 ; CHECK-NEXT:    ldr x9, [x1]
 ; CHECK-NEXT:    and x8, x8, #0xffff0000
 ; CHECK-NEXT:    bfxil x8, x9, #0, #16
 ; CHECK-NEXT:    str x8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i64, i64* %existing
   %oldval_keep = and i64 %oldval, 4294901760 ; = 0xffff0000

   %newval = load volatile i64, i64* %new
   %newval_masked = and i64 %newval, 65535 ; = 0xffff

   %combined = or i64 %oldval_keep, %newval_masked
   store volatile i64 %combined, i64* %existing

   ret void
 }

 define void @test_32bit_masked(i32 *%existing, i32 *%new) {
 ; CHECK-LABEL: test_32bit_masked:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    ldr w9, [x1]
 ; CHECK-NEXT:    mov w10, #135
 ; CHECK-NEXT:    and w8, w8, w10
 ; CHECK-NEXT:    bfi w8, w9, #3, #4
 ; CHECK-NEXT:    str w8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i32, i32* %existing
   %oldval_keep = and i32 %oldval, 135 ; = 0x87

   %newval = load volatile i32, i32* %new
   %newval_shifted = shl i32 %newval, 3
   %newval_masked = and i32 %newval_shifted, 120 ; = 0x78

   %combined = or i32 %oldval_keep, %newval_masked
   store volatile i32 %combined, i32* %existing

   ret void
 }

 define void @test_64bit_masked(i64 *%existing, i64 *%new) {
 ; CHECK-LABEL: test_64bit_masked:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr x8, [x0]
 ; CHECK-NEXT:    ldr x9, [x1]
 ; CHECK-NEXT:    and x8, x8, #0xff00000000
 ; CHECK-NEXT:    bfi x8, x9, #40, #8
 ; CHECK-NEXT:    str x8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i64, i64* %existing
   %oldval_keep = and i64 %oldval, 1095216660480 ; = 0xff_0000_0000

   %newval = load volatile i64, i64* %new
   %newval_shifted = shl i64 %newval, 40
   %newval_masked = and i64 %newval_shifted, 280375465082880 ; = 0xff00_0000_0000

   %combined = or i64 %newval_masked, %oldval_keep
   store volatile i64 %combined, i64* %existing

   ret void
 }

 ; Mask is too complicated for literal ANDwwi, make sure other avenues are tried.
 define void @test_32bit_complexmask(i32 *%existing, i32 *%new) {
 ; CHECK-LABEL: test_32bit_complexmask:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    ldr w9, [x1]
 ; CHECK-NEXT:    mov w10, #647
 ; CHECK-NEXT:    and w8, w8, w10
 ; CHECK-NEXT:    bfi w8, w9, #3, #4
 ; CHECK-NEXT:    str w8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i32, i32* %existing
   %oldval_keep = and i32 %oldval, 647 ; = 0x287

   %newval = load volatile i32, i32* %new
   %newval_shifted = shl i32 %newval, 3
   %newval_masked = and i32 %newval_shifted, 120 ; = 0x278

   %combined = or i32 %oldval_keep, %newval_masked
   store volatile i32 %combined, i32* %existing

   ret void
 }

 ; Neither mask is a contiguous set of 1s. BFI can't be used
 define void @test_32bit_badmask(i32 *%existing, i32 *%new) {
 ; CHECK-LABEL: test_32bit_badmask:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    ldr w9, [x1]
 ; CHECK-NEXT:    mov w10, #135
 ; CHECK-NEXT:    mov w11, #632
 ; CHECK-NEXT:    and w8, w8, w10
 ; CHECK-NEXT:    and w9, w11, w9, lsl #3
 ; CHECK-NEXT:    orr w8, w8, w9
 ; CHECK-NEXT:    str w8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i32, i32* %existing
   %oldval_keep = and i32 %oldval, 135 ; = 0x87

   %newval = load volatile i32, i32* %new
   %newval_shifted = shl i32 %newval, 3
   %newval_masked = and i32 %newval_shifted, 632 ; = 0x278

   %combined = or i32 %oldval_keep, %newval_masked
   store volatile i32 %combined, i32* %existing

   ret void
 }

 ; Ditto
 define void @test_64bit_badmask(i64 *%existing, i64 *%new) {
 ; CHECK-LABEL: test_64bit_badmask:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr x8, [x0]
 ; CHECK-NEXT:    ldr x9, [x1]
 ; CHECK-NEXT:    mov w10, #135
 ; CHECK-NEXT:    and x8, x8, x10
 ; CHECK-NEXT:    lsl w9, w9, #3
 ; CHECK-NEXT:    mov w10, #664
 ; CHECK-NEXT:    and x9, x9, x10
 ; CHECK-NEXT:    orr x8, x8, x9
 ; CHECK-NEXT:    str x8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i64, i64* %existing
   %oldval_keep = and i64 %oldval, 135 ; = 0x87

   %newval = load volatile i64, i64* %new
   %newval_shifted = shl i64 %newval, 3
   %newval_masked = and i64 %newval_shifted, 664 ; = 0x278

   %combined = or i64 %oldval_keep, %newval_masked
   store volatile i64 %combined, i64* %existing

   ret void
 }

 ; Bitfield insert where there's a left-over shr needed at the beginning
 ; (e.g. result of str.bf1 = str.bf2)
 define void @test_32bit_with_shr(i32* %existing, i32* %new) {
 ; CHECK-LABEL: test_32bit_with_shr:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    ldr w9, [x1]
 ; CHECK-NEXT:    lsr w9, w9, #14
 ; CHECK-NEXT:    bfi w8, w9, #26, #5
 ; CHECK-NEXT:    str w8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i32, i32* %existing
   %oldval_keep = and i32 %oldval, 2214592511 ; =0x83ffffff

   %newval = load i32, i32* %new
   %newval_shifted = shl i32 %newval, 12
   %newval_masked = and i32 %newval_shifted, 2080374784 ; = 0x7c000000

   %combined = or i32 %oldval_keep, %newval_masked
   store volatile i32 %combined, i32* %existing

   ret void
 }

 ; Bitfield insert where the second or operand is a better match to be folded into the BFM
 define void @test_32bit_opnd1_better(i32* %existing, i32* %new) {
 ; CHECK-LABEL: test_32bit_opnd1_better:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    ldr w9, [x1]
 ; CHECK-NEXT:    and w8, w8, #0xffff
 ; CHECK-NEXT:    bfi w8, w9, #16, #8
 ; CHECK-NEXT:    str w8, [x0]
 ; CHECK-NEXT:    ret
   %oldval = load volatile i32, i32* %existing
   %oldval_keep = and i32 %oldval, 65535 ; 0x0000ffff

   %newval = load i32, i32* %new
   %newval_shifted = shl i32 %newval, 16
   %newval_masked = and i32 %newval_shifted, 16711680 ; 0x00ff0000

   %combined = or i32 %oldval_keep, %newval_masked
   store volatile i32 %combined, i32* %existing

   ret void
 }

 ; Tests when all the bits from one operand are not useful
 define i32 @test_nouseful_bits(i8 %a, i32 %b) {
 ; CHECK-LABEL: test_nouseful_bits:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    and w8, w0, #0xff
 ; CHECK-NEXT:    lsl w8, w8, #8
 ; CHECK-NEXT:    mov w9, w8
 ; CHECK-NEXT:    bfxil w9, w0, #0, #8
 ; CHECK-NEXT:    bfi w8, w9, #16, #16
 ; CHECK-NEXT:    mov w0, w8
 ; CHECK-NEXT:    ret
   %conv = zext i8 %a to i32     ;   0  0  0  A
   %shl = shl i32 %b, 8          ;   B2 B1 B0 0
   %or = or i32 %conv, %shl      ;   B2 B1 B0 A
   %shl.1 = shl i32 %or, 8       ;   B1 B0 A 0
   %or.1 = or i32 %conv, %shl.1  ;   B1 B0 A A
   %shl.2 = shl i32 %or.1, 8     ;   B0 A A 0
   %or.2 = or i32 %conv, %shl.2  ;   B0 A A A
   %shl.3 = shl i32 %or.2, 8     ;   A A A 0
   %or.3 = or i32 %conv, %shl.3  ;   A A A A
   %shl.4 = shl i32 %or.3, 8     ;   A A A 0
   ret i32 %shl.4
 }

 define void @test_nouseful_strb(i32* %ptr32, i8* %ptr8, i32 %x)  {
 ; CHECK-LABEL: test_nouseful_strb:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    bfxil w8, w2, #16, #3
 ; CHECK-NEXT:    strb w8, [x1]
 ; CHECK-NEXT:    ret
 entry:
   %0 = load i32, i32* %ptr32, align 8
   %and = and i32 %0, -8
   %shr = lshr i32 %x, 16
   %and1 = and i32 %shr, 7
   %or = or i32 %and, %and1
   %trunc = trunc i32 %or to i8
   store i8 %trunc, i8* %ptr8
   ret void
 }

 define void @test_nouseful_strh(i32* %ptr32, i16* %ptr16, i32 %x)  {
 ; CHECK-LABEL: test_nouseful_strh:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    bfxil w8, w2, #16, #4
 ; CHECK-NEXT:    strh w8, [x1]
 ; CHECK-NEXT:    ret
 entry:
   %0 = load i32, i32* %ptr32, align 8
   %and = and i32 %0, -16
   %shr = lshr i32 %x, 16
   %and1 = and i32 %shr, 15
   %or = or i32 %and, %and1
   %trunc = trunc i32 %or to i16
   store i16 %trunc, i16* %ptr16
   ret void
 }

 define void @test_nouseful_sturb(i32* %ptr32, i8* %ptr8, i32 %x)  {
 ; CHECK-LABEL: test_nouseful_sturb:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    bfxil w8, w2, #16, #3
 ; CHECK-NEXT:    sturb w8, [x1, #-1]
 ; CHECK-NEXT:    ret
 entry:
   %0 = load i32, i32* %ptr32, align 8
   %and = and i32 %0, -8
   %shr = lshr i32 %x, 16
   %and1 = and i32 %shr, 7
   %or = or i32 %and, %and1
   %trunc = trunc i32 %or to i8
   %gep = getelementptr i8, i8* %ptr8, i64 -1
   store i8 %trunc, i8* %gep
   ret void
 }

 define void @test_nouseful_sturh(i32* %ptr32, i16* %ptr16, i32 %x)  {
 ; CHECK-LABEL: test_nouseful_sturh:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    ldr w8, [x0]
 ; CHECK-NEXT:    bfxil w8, w2, #16, #4
 ; CHECK-NEXT:    sturh w8, [x1, #-2]
 ; CHECK-NEXT:    ret
 entry:
   %0 = load i32, i32* %ptr32, align 8
   %and = and i32 %0, -16
   %shr = lshr i32 %x, 16
   %and1 = and i32 %shr, 15
   %or = or i32 %and, %and1
   %trunc = trunc i32 %or to i16
   %gep = getelementptr i16, i16* %ptr16, i64 -1
   store i16 %trunc, i16* %gep
   ret void
 }

 ; The next set of tests generate a BFXIL from 'or (and X, Mask0Imm),
 ; (and Y, Mask1Imm)' iff Mask0Imm and ~Mask1Imm are equivalent and one of the
 ; MaskImms is a shifted mask (e.g., 0x000ffff0).

 define i32 @test_or_and_and1(i32 %a, i32 %b) {
 ; CHECK-LABEL: test_or_and_and1:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    lsr w8, w1, #4
 ; CHECK-NEXT:    bfi w0, w8, #4, #12
 ; CHECK-NEXT:    ret
 entry:
   %and = and i32 %a, -65521 ; 0xffff000f
   %and1 = and i32 %b, 65520 ; 0x0000fff0
   %or = or i32 %and1, %and
   ret i32 %or
 }

 define i32 @test_or_and_and2(i32 %a, i32 %b) {
 ; CHECK-LABEL: test_or_and_and2:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    lsr w8, w0, #4
 ; CHECK-NEXT:    bfi w1, w8, #4, #12
 ; CHECK-NEXT:    mov w0, w1
 ; CHECK-NEXT:    ret
 entry:
   %and = and i32 %a, 65520   ; 0x0000fff0
   %and1 = and i32 %b, -65521 ; 0xffff000f
   %or = or i32 %and1, %and
   ret i32 %or
 }

 define i64 @test_or_and_and3(i64 %a, i64 %b) {
 ; CHECK-LABEL: test_or_and_and3:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    lsr x8, x1, #16
 ; CHECK-NEXT:    bfi x0, x8, #16, #32
 ; CHECK-NEXT:    ret
 entry:
   %and = and i64 %a, -281474976645121 ; 0xffff00000000ffff
   %and1 = and i64 %b, 281474976645120 ; 0x0000ffffffff0000
   %or = or i64 %and1, %and
   ret i64 %or
 }

 ; Don't convert 'and' with multiple uses.
 define i32 @test_or_and_and4(i32 %a, i32 %b, i32* %ptr) {
 ; CHECK-LABEL: test_or_and_and4:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    and w8, w0, #0xffff000f
 ; CHECK-NEXT:    and w9, w1, #0xfff0
 ; CHECK-NEXT:    orr w0, w9, w8
 ; CHECK-NEXT:    str w8, [x2]
 ; CHECK-NEXT:    ret
 entry:
   %and = and i32 %a, -65521
   store i32 %and, i32* %ptr, align 4
   %and2 = and i32 %b, 65520
   %or = or i32 %and2, %and
   ret i32 %or
 }

 ; Don't convert 'and' with multiple uses.
 define i32 @test_or_and_and5(i32 %a, i32 %b, i32* %ptr) {
 ; CHECK-LABEL: test_or_and_and5:
 ; CHECK:       // %bb.0: // %entry
 ; CHECK-NEXT:    and w8, w1, #0xfff0
 ; CHECK-NEXT:    and w9, w0, #0xffff000f
 ; CHECK-NEXT:    orr w0, w8, w9
 ; CHECK-NEXT:    str w8, [x2]
 ; CHECK-NEXT:    ret
 entry:
   %and = and i32 %b, 65520
   store i32 %and, i32* %ptr, align 4
   %and1 = and i32 %a, -65521
   %or = or i32 %and, %and1
   ret i32 %or
 }

 define i32 @test1(i32 %a) {
 ; CHECK-LABEL: test1:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    mov w8, #5
 ; CHECK-NEXT:    bfxil w0, w8, #0, #4
 ; CHECK-NEXT:    ret
   %1 = and i32 %a, -16 ; 0xfffffff0
   %2 = or i32 %1, 5    ; 0x00000005
   ret i32 %2
 }

 define i32 @test2(i32 %a) {
 ; CHECK-LABEL: test2:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    mov w8, #10
 ; CHECK-NEXT:    bfi w0, w8, #22, #4
 ; CHECK-NEXT:    ret
   %1 = and i32 %a, -62914561 ; 0xfc3fffff
   %2 = or i32 %1, 41943040   ; 0x06400000
   ret i32 %2
 }

 define i64 @test3(i64 %a) {
 ; CHECK-LABEL: test3:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    mov x8, #5
 ; CHECK-NEXT:    bfxil x0, x8, #0, #3
 ; CHECK-NEXT:    ret
   %1 = and i64 %a, -8 ; 0xfffffffffffffff8
   %2 = or i64 %1, 5   ; 0x0000000000000005
   ret i64 %2
 }

 define i64 @test4(i64 %a) {
 ; CHECK-LABEL: test4:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    mov x8, #9
 ; CHECK-NEXT:    bfi x0, x8, #1, #7
 ; CHECK-NEXT:    ret
   %1 = and i64 %a, -255 ; 0xffffffffffffff01
   %2 = or i64 %1,  18   ; 0x0000000000000012
   ret i64 %2
 }

 ; Don't generate BFI/BFXIL if the immediate can be encoded in the ORR.
 define i32 @test5(i32 %a) {
 ; CHECK-LABEL: test5:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    and w8, w0, #0xfffffff0
 ; CHECK-NEXT:    orr w0, w8, #0x6
 ; CHECK-NEXT:    ret
   %1 = and i32 %a, 4294967280 ; 0xfffffff0
   %2 = or i32 %1, 6           ; 0x00000006
   ret i32 %2
 }

 ; BFXIL will use the same constant as the ORR, so we don't care how the constant
 ; is materialized (it's an equal cost either way).
 define i32 @test6(i32 %a) {
 ; CHECK-LABEL: test6:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    mov w8, #23250
 ; CHECK-NEXT:    movk w8, #11, lsl #16
 ; CHECK-NEXT:    bfxil w0, w8, #0, #20
 ; CHECK-NEXT:    ret
   %1 = and i32 %a, 4293918720 ; 0xfff00000
   %2 = or i32 %1, 744146      ; 0x000b5ad2
   ret i32 %2
 }

 ; BFIs that require the same number of instruction to materialize the constant
 ; as the original ORR are okay.
 define i32 @test7(i32 %a) {
 ; CHECK-LABEL: test7:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    mov w8, #44393
 ; CHECK-NEXT:    movk w8, #5, lsl #16
 ; CHECK-NEXT:    bfi w0, w8, #1, #19
 ; CHECK-NEXT:    ret
   %1 = and i32 %a, 4293918721 ; 0xfff00001
   %2 = or i32 %1, 744146      ; 0x000b5ad2
   ret i32 %2
 }

 ; BFIs that require more instructions to materialize the constant as compared
 ; to the original ORR are not okay.  In this case we would be replacing the
 ; 'and' with a 'movk', which would decrease ILP while using the same number of
 ; instructions.
 define i64 @test8(i64 %a) {
 ; CHECK-LABEL: test8:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    mov x9, #2035482624
 ; CHECK-NEXT:    and x8, x0, #0xff000000000000ff
 ; CHECK-NEXT:    movk x9, #36694, lsl #32
 ; CHECK-NEXT:    orr x0, x8, x9
 ; CHECK-NEXT:    ret
   %1 = and i64 %a, -72057594037927681 ; 0xff000000000000ff
   %2 = or i64 %1, 157601565442048     ; 0x00008f5679530000
   ret i64 %2
 }

 ; This test exposed an issue with an overly aggressive assert.  The bit of code
 ; that is expected to catch this case is unable to deal with the trunc, which
 ; results in a failing check due to a mismatch between the BFI opcode and
 ; the expected value type of the OR.
 define i32 @test9(i64 %b, i32 %e) {
 ; CHECK-LABEL: test9:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    lsr x0, x0, #12
 ; CHECK-NEXT:    lsr w8, w1, #23
 ; CHECK-NEXT:    bfi w0, w8, #23, #9
 ; CHECK-NEXT:    // kill: def $w0 killed $w0 killed $x0
 ; CHECK-NEXT:    ret
   %c = lshr i64 %b, 12
   %d = trunc i64 %c to i32
   %f = and i32 %d, 8388607
   %g = and i32 %e, -8388608
   %h = or i32 %g, %f
   ret i32 %h
 }

 define <2 x i32> @test_complex_type(<2 x i32>* %addr, i64 %in, i64* %bf ) {
 ; CHECK-LABEL: test_complex_type:
 ; CHECK:       // %bb.0:
 ; CHECK-NEXT:    ldr d0, [x0], #8
 ; CHECK-NEXT:    orr x8, x0, x1, lsl #32
 ; CHECK-NEXT:    str x8, [x2]
 ; CHECK-NEXT:    ret
   %vec = load <2 x i32>, <2 x i32>* %addr

   %vec.next = getelementptr <2 x i32>, <2 x i32>* %addr, i32 1
   %lo = ptrtoint <2 x i32>* %vec.next to i64

   %hi = shl i64 %in, 32
   %both = or i64 %lo, %hi
   store i64 %both, i64* %bf

   ret <2 x i32> %vec
 }
	; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
	; RUN: llc -mtriple=aarch64-none-linux-gnu < %s \| FileCheck %s

	; First, a simple example from Clang. The registers could plausibly be
	; different, but probably won't be.

	%struct.foo = type { i8, [2 x i8], i8 }

	define [1 x i64] @from_clang([1 x i64] %f.coerce, i32 %n) nounwind readnone {
	; CHECK-LABEL: from_clang:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: mov w8, #135
	; CHECK-NEXT: and w8, w0, w8
	; CHECK-NEXT: bfi w8, w1, #3, #4
	; CHECK-NEXT: and x9, x0, #0xffffff00
	; CHECK-NEXT: orr x0, x8, x9
	; CHECK-NEXT: ret
	entry:
	%f.coerce.fca.0.extract = extractvalue [1 x i64] %f.coerce, 0
	%tmp.sroa.0.0.extract.trunc = trunc i64 %f.coerce.fca.0.extract to i32
	%bf.value = shl i32 %n, 3
	%0 = and i32 %bf.value, 120
	%f.sroa.0.0.insert.ext.masked = and i32 %tmp.sroa.0.0.extract.trunc, 135
	%1 = or i32 %f.sroa.0.0.insert.ext.masked, %0
	%f.sroa.0.0.extract.trunc = zext i32 %1 to i64
	%tmp1.sroa.1.1.insert.insert = and i64 %f.coerce.fca.0.extract, 4294967040
	%tmp1.sroa.0.0.insert.insert = or i64 %f.sroa.0.0.extract.trunc, %tmp1.sroa.1.1.insert.insert
	%.fca.0.insert = insertvalue [1 x i64] undef, i64 %tmp1.sroa.0.0.insert.insert, 0
	ret [1 x i64] %.fca.0.insert
	}

	define void @test_whole32(i32* %existing, i32* %new) {
	; CHECK-LABEL: test_whole32:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: ldr w9, [x1]
	; CHECK-NEXT: bfi w8, w9, #26, #5
	; CHECK-NEXT: str w8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i32, i32* %existing
	%oldval_keep = and i32 %oldval, 2214592511 ; =0x83ffffff

	%newval = load volatile i32, i32* %new
	%newval_shifted = shl i32 %newval, 26
	%newval_masked = and i32 %newval_shifted, 2080374784 ; = 0x7c000000

	%combined = or i32 %oldval_keep, %newval_masked
	store volatile i32 %combined, i32* %existing

	ret void
	}

	define void @test_whole64(i64* %existing, i64* %new) {
	; CHECK-LABEL: test_whole64:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr x8, [x0]
	; CHECK-NEXT: ldr x9, [x1]
	; CHECK-NEXT: bfi x8, x9, #26, #14
	; CHECK-NEXT: str x8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i64, i64* %existing
	%oldval_keep = and i64 %oldval, 18446742974265032703 ; = 0xffffff0003ffffffL

	%newval = load volatile i64, i64* %new
	%newval_shifted = shl i64 %newval, 26
	%newval_masked = and i64 %newval_shifted, 1099444518912 ; = 0xfffc000000

	%combined = or i64 %oldval_keep, %newval_masked
	store volatile i64 %combined, i64* %existing

	ret void
	}

	define void @test_whole32_from64(i64* %existing, i64* %new) {
	; CHECK-LABEL: test_whole32_from64:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr x8, [x0]
	; CHECK-NEXT: ldr x9, [x1]
	; CHECK-NEXT: and x8, x8, #0xffff0000
	; CHECK-NEXT: bfxil x8, x9, #0, #16
	; CHECK-NEXT: str x8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i64, i64* %existing
	%oldval_keep = and i64 %oldval, 4294901760 ; = 0xffff0000

	%newval = load volatile i64, i64* %new
	%newval_masked = and i64 %newval, 65535 ; = 0xffff

	%combined = or i64 %oldval_keep, %newval_masked
	store volatile i64 %combined, i64* %existing

	ret void
	}

	define void @test_32bit_masked(i32 %existing, i32 %new) {
	; CHECK-LABEL: test_32bit_masked:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: ldr w9, [x1]
	; CHECK-NEXT: mov w10, #135
	; CHECK-NEXT: and w8, w8, w10
	; CHECK-NEXT: bfi w8, w9, #3, #4
	; CHECK-NEXT: str w8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i32, i32* %existing
	%oldval_keep = and i32 %oldval, 135 ; = 0x87

	%newval = load volatile i32, i32* %new
	%newval_shifted = shl i32 %newval, 3
	%newval_masked = and i32 %newval_shifted, 120 ; = 0x78

	%combined = or i32 %oldval_keep, %newval_masked
	store volatile i32 %combined, i32* %existing

	ret void
	}

	define void @test_64bit_masked(i64 %existing, i64 %new) {
	; CHECK-LABEL: test_64bit_masked:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr x8, [x0]
	; CHECK-NEXT: ldr x9, [x1]
	; CHECK-NEXT: and x8, x8, #0xff00000000
	; CHECK-NEXT: bfi x8, x9, #40, #8
	; CHECK-NEXT: str x8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i64, i64* %existing
	%oldval_keep = and i64 %oldval, 1095216660480 ; = 0xff_0000_0000

	%newval = load volatile i64, i64* %new
	%newval_shifted = shl i64 %newval, 40
	%newval_masked = and i64 %newval_shifted, 280375465082880 ; = 0xff00_0000_0000

	%combined = or i64 %newval_masked, %oldval_keep
	store volatile i64 %combined, i64* %existing

	ret void
	}

	; Mask is too complicated for literal ANDwwi, make sure other avenues are tried.
	define void @test_32bit_complexmask(i32 %existing, i32 %new) {
	; CHECK-LABEL: test_32bit_complexmask:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: ldr w9, [x1]
	; CHECK-NEXT: mov w10, #647
	; CHECK-NEXT: and w8, w8, w10
	; CHECK-NEXT: bfi w8, w9, #3, #4
	; CHECK-NEXT: str w8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i32, i32* %existing
	%oldval_keep = and i32 %oldval, 647 ; = 0x287

	%newval = load volatile i32, i32* %new
	%newval_shifted = shl i32 %newval, 3
	%newval_masked = and i32 %newval_shifted, 120 ; = 0x278

	%combined = or i32 %oldval_keep, %newval_masked
	store volatile i32 %combined, i32* %existing

	ret void
	}

	; Neither mask is a contiguous set of 1s. BFI can't be used
	define void @test_32bit_badmask(i32 %existing, i32 %new) {
	; CHECK-LABEL: test_32bit_badmask:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: ldr w9, [x1]
	; CHECK-NEXT: mov w10, #135
	; CHECK-NEXT: mov w11, #632
	; CHECK-NEXT: and w8, w8, w10
	; CHECK-NEXT: and w9, w11, w9, lsl #3
	; CHECK-NEXT: orr w8, w8, w9
	; CHECK-NEXT: str w8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i32, i32* %existing
	%oldval_keep = and i32 %oldval, 135 ; = 0x87

	%newval = load volatile i32, i32* %new
	%newval_shifted = shl i32 %newval, 3
	%newval_masked = and i32 %newval_shifted, 632 ; = 0x278

	%combined = or i32 %oldval_keep, %newval_masked
	store volatile i32 %combined, i32* %existing

	ret void
	}

	; Ditto
	define void @test_64bit_badmask(i64 %existing, i64 %new) {
	; CHECK-LABEL: test_64bit_badmask:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr x8, [x0]
	; CHECK-NEXT: ldr x9, [x1]
	; CHECK-NEXT: mov w10, #135
	; CHECK-NEXT: and x8, x8, x10
	; CHECK-NEXT: lsl w9, w9, #3
	; CHECK-NEXT: mov w10, #664
	; CHECK-NEXT: and x9, x9, x10
	; CHECK-NEXT: orr x8, x8, x9
	; CHECK-NEXT: str x8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i64, i64* %existing
	%oldval_keep = and i64 %oldval, 135 ; = 0x87

	%newval = load volatile i64, i64* %new
	%newval_shifted = shl i64 %newval, 3
	%newval_masked = and i64 %newval_shifted, 664 ; = 0x278

	%combined = or i64 %oldval_keep, %newval_masked
	store volatile i64 %combined, i64* %existing

	ret void
	}

	; Bitfield insert where there's a left-over shr needed at the beginning
	; (e.g. result of str.bf1 = str.bf2)
	define void @test_32bit_with_shr(i32* %existing, i32* %new) {
	; CHECK-LABEL: test_32bit_with_shr:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: ldr w9, [x1]
	; CHECK-NEXT: lsr w9, w9, #14
	; CHECK-NEXT: bfi w8, w9, #26, #5
	; CHECK-NEXT: str w8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i32, i32* %existing
	%oldval_keep = and i32 %oldval, 2214592511 ; =0x83ffffff

	%newval = load i32, i32* %new
	%newval_shifted = shl i32 %newval, 12
	%newval_masked = and i32 %newval_shifted, 2080374784 ; = 0x7c000000

	%combined = or i32 %oldval_keep, %newval_masked
	store volatile i32 %combined, i32* %existing

	ret void
	}

	; Bitfield insert where the second or operand is a better match to be folded into the BFM
	define void @test_32bit_opnd1_better(i32* %existing, i32* %new) {
	; CHECK-LABEL: test_32bit_opnd1_better:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: ldr w9, [x1]
	; CHECK-NEXT: and w8, w8, #0xffff
	; CHECK-NEXT: bfi w8, w9, #16, #8
	; CHECK-NEXT: str w8, [x0]
	; CHECK-NEXT: ret
	%oldval = load volatile i32, i32* %existing
	%oldval_keep = and i32 %oldval, 65535 ; 0x0000ffff

	%newval = load i32, i32* %new
	%newval_shifted = shl i32 %newval, 16
	%newval_masked = and i32 %newval_shifted, 16711680 ; 0x00ff0000

	%combined = or i32 %oldval_keep, %newval_masked
	store volatile i32 %combined, i32* %existing

	ret void
	}

	; Tests when all the bits from one operand are not useful
	define i32 @test_nouseful_bits(i8 %a, i32 %b) {
	; CHECK-LABEL: test_nouseful_bits:
	; CHECK: // %bb.0:
	; CHECK-NEXT: and w8, w0, #0xff
	; CHECK-NEXT: lsl w8, w8, #8
	; CHECK-NEXT: mov w9, w8
	; CHECK-NEXT: bfxil w9, w0, #0, #8
	; CHECK-NEXT: bfi w8, w9, #16, #16
	; CHECK-NEXT: mov w0, w8
	; CHECK-NEXT: ret
	%conv = zext i8 %a to i32 ; 0 0 0 A
	%shl = shl i32 %b, 8 ; B2 B1 B0 0
	%or = or i32 %conv, %shl ; B2 B1 B0 A
	%shl.1 = shl i32 %or, 8 ; B1 B0 A 0
	%or.1 = or i32 %conv, %shl.1 ; B1 B0 A A
	%shl.2 = shl i32 %or.1, 8 ; B0 A A 0
	%or.2 = or i32 %conv, %shl.2 ; B0 A A A
	%shl.3 = shl i32 %or.2, 8 ; A A A 0
	%or.3 = or i32 %conv, %shl.3 ; A A A A
	%shl.4 = shl i32 %or.3, 8 ; A A A 0
	ret i32 %shl.4
	}

	define void @test_nouseful_strb(i32* %ptr32, i8* %ptr8, i32 %x) {
	; CHECK-LABEL: test_nouseful_strb:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: bfxil w8, w2, #16, #3
	; CHECK-NEXT: strb w8, [x1]
	; CHECK-NEXT: ret
	entry:
	%0 = load i32, i32* %ptr32, align 8
	%and = and i32 %0, -8
	%shr = lshr i32 %x, 16
	%and1 = and i32 %shr, 7
	%or = or i32 %and, %and1
	%trunc = trunc i32 %or to i8
	store i8 %trunc, i8* %ptr8
	ret void
	}

	define void @test_nouseful_strh(i32* %ptr32, i16* %ptr16, i32 %x) {
	; CHECK-LABEL: test_nouseful_strh:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: bfxil w8, w2, #16, #4
	; CHECK-NEXT: strh w8, [x1]
	; CHECK-NEXT: ret
	entry:
	%0 = load i32, i32* %ptr32, align 8
	%and = and i32 %0, -16
	%shr = lshr i32 %x, 16
	%and1 = and i32 %shr, 15
	%or = or i32 %and, %and1
	%trunc = trunc i32 %or to i16
	store i16 %trunc, i16* %ptr16
	ret void
	}

	define void @test_nouseful_sturb(i32* %ptr32, i8* %ptr8, i32 %x) {
	; CHECK-LABEL: test_nouseful_sturb:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: bfxil w8, w2, #16, #3
	; CHECK-NEXT: sturb w8, [x1, #-1]
	; CHECK-NEXT: ret
	entry:
	%0 = load i32, i32* %ptr32, align 8
	%and = and i32 %0, -8
	%shr = lshr i32 %x, 16
	%and1 = and i32 %shr, 7
	%or = or i32 %and, %and1
	%trunc = trunc i32 %or to i8
	%gep = getelementptr i8, i8* %ptr8, i64 -1
	store i8 %trunc, i8* %gep
	ret void
	}

	define void @test_nouseful_sturh(i32* %ptr32, i16* %ptr16, i32 %x) {
	; CHECK-LABEL: test_nouseful_sturh:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: ldr w8, [x0]
	; CHECK-NEXT: bfxil w8, w2, #16, #4
	; CHECK-NEXT: sturh w8, [x1, #-2]
	; CHECK-NEXT: ret
	entry:
	%0 = load i32, i32* %ptr32, align 8
	%and = and i32 %0, -16
	%shr = lshr i32 %x, 16
	%and1 = and i32 %shr, 15
	%or = or i32 %and, %and1
	%trunc = trunc i32 %or to i16
	%gep = getelementptr i16, i16* %ptr16, i64 -1
	store i16 %trunc, i16* %gep
	ret void
	}

	; The next set of tests generate a BFXIL from 'or (and X, Mask0Imm),
	; (and Y, Mask1Imm)' iff Mask0Imm and ~Mask1Imm are equivalent and one of the
	; MaskImms is a shifted mask (e.g., 0x000ffff0).

	define i32 @test_or_and_and1(i32 %a, i32 %b) {
	; CHECK-LABEL: test_or_and_and1:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: lsr w8, w1, #4
	; CHECK-NEXT: bfi w0, w8, #4, #12
	; CHECK-NEXT: ret
	entry:
	%and = and i32 %a, -65521 ; 0xffff000f
	%and1 = and i32 %b, 65520 ; 0x0000fff0
	%or = or i32 %and1, %and
	ret i32 %or
	}

	define i32 @test_or_and_and2(i32 %a, i32 %b) {
	; CHECK-LABEL: test_or_and_and2:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: lsr w8, w0, #4
	; CHECK-NEXT: bfi w1, w8, #4, #12
	; CHECK-NEXT: mov w0, w1
	; CHECK-NEXT: ret
	entry:
	%and = and i32 %a, 65520 ; 0x0000fff0
	%and1 = and i32 %b, -65521 ; 0xffff000f
	%or = or i32 %and1, %and
	ret i32 %or
	}

	define i64 @test_or_and_and3(i64 %a, i64 %b) {
	; CHECK-LABEL: test_or_and_and3:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: lsr x8, x1, #16
	; CHECK-NEXT: bfi x0, x8, #16, #32
	; CHECK-NEXT: ret
	entry:
	%and = and i64 %a, -281474976645121 ; 0xffff00000000ffff
	%and1 = and i64 %b, 281474976645120 ; 0x0000ffffffff0000
	%or = or i64 %and1, %and
	ret i64 %or
	}

	; Don't convert 'and' with multiple uses.
	define i32 @test_or_and_and4(i32 %a, i32 %b, i32* %ptr) {
	; CHECK-LABEL: test_or_and_and4:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: and w8, w0, #0xffff000f
	; CHECK-NEXT: and w9, w1, #0xfff0
	; CHECK-NEXT: orr w0, w9, w8
	; CHECK-NEXT: str w8, [x2]
	; CHECK-NEXT: ret
	entry:
	%and = and i32 %a, -65521
	store i32 %and, i32* %ptr, align 4
	%and2 = and i32 %b, 65520
	%or = or i32 %and2, %and
	ret i32 %or
	}

	; Don't convert 'and' with multiple uses.
	define i32 @test_or_and_and5(i32 %a, i32 %b, i32* %ptr) {
	; CHECK-LABEL: test_or_and_and5:
	; CHECK: // %bb.0: // %entry
	; CHECK-NEXT: and w8, w1, #0xfff0
	; CHECK-NEXT: and w9, w0, #0xffff000f
	; CHECK-NEXT: orr w0, w8, w9
	; CHECK-NEXT: str w8, [x2]
	; CHECK-NEXT: ret
	entry:
	%and = and i32 %b, 65520
	store i32 %and, i32* %ptr, align 4
	%and1 = and i32 %a, -65521
	%or = or i32 %and, %and1
	ret i32 %or
	}

	define i32 @test1(i32 %a) {
	; CHECK-LABEL: test1:
	; CHECK: // %bb.0:
	; CHECK-NEXT: mov w8, #5
	; CHECK-NEXT: bfxil w0, w8, #0, #4
	; CHECK-NEXT: ret
	%1 = and i32 %a, -16 ; 0xfffffff0
	%2 = or i32 %1, 5 ; 0x00000005
	ret i32 %2
	}

	define i32 @test2(i32 %a) {
	; CHECK-LABEL: test2:
	; CHECK: // %bb.0:
	; CHECK-NEXT: mov w8, #10
	; CHECK-NEXT: bfi w0, w8, #22, #4
	; CHECK-NEXT: ret
	%1 = and i32 %a, -62914561 ; 0xfc3fffff
	%2 = or i32 %1, 41943040 ; 0x06400000
	ret i32 %2
	}

	define i64 @test3(i64 %a) {
	; CHECK-LABEL: test3:
	; CHECK: // %bb.0:
	; CHECK-NEXT: mov x8, #5
	; CHECK-NEXT: bfxil x0, x8, #0, #3
	; CHECK-NEXT: ret
	%1 = and i64 %a, -8 ; 0xfffffffffffffff8
	%2 = or i64 %1, 5 ; 0x0000000000000005
	ret i64 %2
	}

	define i64 @test4(i64 %a) {
	; CHECK-LABEL: test4:
	; CHECK: // %bb.0:
	; CHECK-NEXT: mov x8, #9
	; CHECK-NEXT: bfi x0, x8, #1, #7
	; CHECK-NEXT: ret
	%1 = and i64 %a, -255 ; 0xffffffffffffff01
	%2 = or i64 %1, 18 ; 0x0000000000000012
	ret i64 %2
	}

	; Don't generate BFI/BFXIL if the immediate can be encoded in the ORR.
	define i32 @test5(i32 %a) {
	; CHECK-LABEL: test5:
	; CHECK: // %bb.0:
	; CHECK-NEXT: and w8, w0, #0xfffffff0
	; CHECK-NEXT: orr w0, w8, #0x6
	; CHECK-NEXT: ret
	%1 = and i32 %a, 4294967280 ; 0xfffffff0
	%2 = or i32 %1, 6 ; 0x00000006
	ret i32 %2
	}

	; BFXIL will use the same constant as the ORR, so we don't care how the constant
	; is materialized (it's an equal cost either way).
	define i32 @test6(i32 %a) {
	; CHECK-LABEL: test6:
	; CHECK: // %bb.0:
	; CHECK-NEXT: mov w8, #23250
	; CHECK-NEXT: movk w8, #11, lsl #16
	; CHECK-NEXT: bfxil w0, w8, #0, #20
	; CHECK-NEXT: ret
	%1 = and i32 %a, 4293918720 ; 0xfff00000
	%2 = or i32 %1, 744146 ; 0x000b5ad2
	ret i32 %2
	}

	; BFIs that require the same number of instruction to materialize the constant
	; as the original ORR are okay.
	define i32 @test7(i32 %a) {
	; CHECK-LABEL: test7:
	; CHECK: // %bb.0:
	; CHECK-NEXT: mov w8, #44393
	; CHECK-NEXT: movk w8, #5, lsl #16
	; CHECK-NEXT: bfi w0, w8, #1, #19
	; CHECK-NEXT: ret
	%1 = and i32 %a, 4293918721 ; 0xfff00001
	%2 = or i32 %1, 744146 ; 0x000b5ad2
	ret i32 %2
	}

	; BFIs that require more instructions to materialize the constant as compared
	; to the original ORR are not okay. In this case we would be replacing the
	; 'and' with a 'movk', which would decrease ILP while using the same number of
	; instructions.
	define i64 @test8(i64 %a) {
	; CHECK-LABEL: test8:
	; CHECK: // %bb.0:
	; CHECK-NEXT: mov x9, #2035482624
	; CHECK-NEXT: and x8, x0, #0xff000000000000ff
	; CHECK-NEXT: movk x9, #36694, lsl #32
	; CHECK-NEXT: orr x0, x8, x9
	; CHECK-NEXT: ret
	%1 = and i64 %a, -72057594037927681 ; 0xff000000000000ff
	%2 = or i64 %1, 157601565442048 ; 0x00008f5679530000
	ret i64 %2
	}

	; This test exposed an issue with an overly aggressive assert. The bit of code
	; that is expected to catch this case is unable to deal with the trunc, which
	; results in a failing check due to a mismatch between the BFI opcode and
	; the expected value type of the OR.
	define i32 @test9(i64 %b, i32 %e) {
	; CHECK-LABEL: test9:
	; CHECK: // %bb.0:
	; CHECK-NEXT: lsr x0, x0, #12
	; CHECK-NEXT: lsr w8, w1, #23
	; CHECK-NEXT: bfi w0, w8, #23, #9
	; CHECK-NEXT: // kill: def $w0 killed $w0 killed $x0
	; CHECK-NEXT: ret
	%c = lshr i64 %b, 12
	%d = trunc i64 %c to i32
	%f = and i32 %d, 8388607
	%g = and i32 %e, -8388608
	%h = or i32 %g, %f
	ret i32 %h
	}

	define <2 x i32> @test_complex_type(<2 x i32>* %addr, i64 %in, i64* %bf ) {
	; CHECK-LABEL: test_complex_type:
	; CHECK: // %bb.0:
	; CHECK-NEXT: ldr d0, [x0], #8
	; CHECK-NEXT: orr x8, x0, x1, lsl #32
	; CHECK-NEXT: str x8, [x2]
	; CHECK-NEXT: ret
	%vec = load <2 x i32>, <2 x i32>* %addr

	%vec.next = getelementptr <2 x i32>, <2 x i32>* %addr, i32 1
	%lo = ptrtoint <2 x i32>* %vec.next to i64

	%hi = shl i64 %in, 32
	%both = or i64 %lo, %hi
	store i64 %both, i64* %bf

	ret <2 x i32> %vec
	}