test/Transforms/InstCombine/and.ll - llvm - Git at Google

 ; NOTE: Assertions have been autogenerated by utils/update_test_checks.py
 ; RUN: opt < %s -instcombine -S | FileCheck %s

 ; There should be no 'and' instructions left in any test.

 define i32 @test1(i32 %A) {
 ; CHECK-LABEL: @test1(
 ; CHECK-NEXT:    ret i32 0
 ;
   %B = and i32 %A, 0
   ret i32 %B
 }

 define i32 @test2(i32 %A) {
 ; CHECK-LABEL: @test2(
 ; CHECK-NEXT:    ret i32 %A
 ;
   %B = and i32 %A, -1
   ret i32 %B
 }

 define i1 @test3(i1 %A) {
 ; CHECK-LABEL: @test3(
 ; CHECK-NEXT:    ret i1 false
 ;
   %B = and i1 %A, false
   ret i1 %B
 }

 define i1 @test4(i1 %A) {
 ; CHECK-LABEL: @test4(
 ; CHECK-NEXT:    ret i1 %A
 ;
   %B = and i1 %A, true
   ret i1 %B
 }

 define i32 @test5(i32 %A) {
 ; CHECK-LABEL: @test5(
 ; CHECK-NEXT:    ret i32 %A
 ;
   %B = and i32 %A, %A
   ret i32 %B
 }

 define i1 @test6(i1 %A) {
 ; CHECK-LABEL: @test6(
 ; CHECK-NEXT:    ret i1 %A
 ;
   %B = and i1 %A, %A
   ret i1 %B
 }

 ; A & ~A == 0
 define i32 @test7(i32 %A) {
 ; CHECK-LABEL: @test7(
 ; CHECK-NEXT:    ret i32 0
 ;
   %NotA = xor i32 %A, -1
   %B = and i32 %A, %NotA
   ret i32 %B
 }

 ; AND associates
 define i8 @test8(i8 %A) {
 ; CHECK-LABEL: @test8(
 ; CHECK-NEXT:    ret i8 0
 ;
   %B = and i8 %A, 3
   %C = and i8 %B, 4
   ret i8 %C
 }

 ; Test of sign bit, convert to setle %A, 0
 define i1 @test9(i32 %A) {
 ; CHECK-LABEL: @test9(
 ; CHECK-NEXT:    [[C:%.*]] = icmp slt i32 %A, 0
 ; CHECK-NEXT:    ret i1 [[C]]
 ;
   %B = and i32 %A, -2147483648
   %C = icmp ne i32 %B, 0
   ret i1 %C
 }

 ; Test of sign bit, convert to setle %A, 0
 define i1 @test9a(i32 %A) {
 ; CHECK-LABEL: @test9a(
 ; CHECK-NEXT:    [[C:%.*]] = icmp slt i32 %A, 0
 ; CHECK-NEXT:    ret i1 [[C]]
 ;
   %B = and i32 %A, -2147483648
   %C = icmp ne i32 %B, 0
   ret i1 %C
 }

 define i32 @test10(i32 %A) {
 ; CHECK-LABEL: @test10(
 ; CHECK-NEXT:    ret i32 1
 ;
   %B = and i32 %A, 12
   %C = xor i32 %B, 15
   ; (X ^ C1) & C2 --> (X & C2) ^ (C1&C2)
   %D = and i32 %C, 1
   ret i32 %D
 }

 define i32 @test11(i32 %A, i32* %P) {
 ; CHECK-LABEL: @test11(
 ; CHECK-NEXT:    [[B:%.*]] = or i32 %A, 3
 ; CHECK-NEXT:    [[C:%.*]] = xor i32 [[B]], 12
 ; CHECK-NEXT:    store i32 [[C]], i32* %P, align 4
 ; CHECK-NEXT:    ret i32 3
 ;
   %B = or i32 %A, 3
   %C = xor i32 %B, 12
   ; additional use of C
   store i32 %C, i32* %P
   ; %C = and uint %B, 3 --> 3
   %D = and i32 %C, 3
   ret i32 %D
 }

 define i1 @test12(i32 %A, i32 %B) {
 ; CHECK-LABEL: @test12(
 ; CHECK-NEXT:    [[TMP1:%.*]] = icmp ult i32 %A, %B
 ; CHECK-NEXT:    ret i1 [[TMP1]]
 ;
   %C1 = icmp ult i32 %A, %B
   %C2 = icmp ule i32 %A, %B
   ; (A < B) & (A <= B) === (A < B)
   %D = and i1 %C1, %C2
   ret i1 %D
 }

 define i1 @test13(i32 %A, i32 %B) {
 ; CHECK-LABEL: @test13(
 ; CHECK-NEXT:    ret i1 false
 ;
   %C1 = icmp ult i32 %A, %B
   %C2 = icmp ugt i32 %A, %B
   ; (A < B) & (A > B) === false
   %D = and i1 %C1, %C2
   ret i1 %D
 }

 define i1 @test14(i8 %A) {
 ; CHECK-LABEL: @test14(
 ; CHECK-NEXT:    [[C:%.*]] = icmp slt i8 %A, 0
 ; CHECK-NEXT:    ret i1 [[C]]
 ;
   %B = and i8 %A, -128
   %C = icmp ne i8 %B, 0
   ret i1 %C
 }

 define i8 @test15(i8 %A) {
 ; CHECK-LABEL: @test15(
 ; CHECK-NEXT:    ret i8 0
 ;
   %B = lshr i8 %A, 7
   ; Always equals zero
   %C = and i8 %B, 2
   ret i8 %C
 }

 define i8 @test16(i8 %A) {
 ; CHECK-LABEL: @test16(
 ; CHECK-NEXT:    ret i8 0
 ;
   %B = shl i8 %A, 2
   %C = and i8 %B, 3
   ret i8 %C
 }

 define i1 @test18(i32 %A) {
 ; CHECK-LABEL: @test18(
 ; CHECK-NEXT:    [[C:%.*]] = icmp ugt i32 %A, 127
 ; CHECK-NEXT:    ret i1 [[C]]
 ;
   %B = and i32 %A, -128
   ;; C >= 128
   %C = icmp ne i32 %B, 0
   ret i1 %C
 }

 define <2 x i1> @test18_vec(<2 x i32> %A) {
 ; CHECK-LABEL: @test18_vec(
 ; CHECK-NEXT:    [[C:%.*]] = icmp ugt <2 x i32> %A, <i32 127, i32 127>
 ; CHECK-NEXT:    ret <2 x i1> [[C]]
 ;
   %B = and <2 x i32> %A, <i32 -128, i32 -128>
   %C = icmp ne <2 x i32> %B, zeroinitializer
   ret <2 x i1> %C
 }

 define i1 @test18a(i8 %A) {
 ; CHECK-LABEL: @test18a(
 ; CHECK-NEXT:    [[C:%.*]] = icmp ult i8 %A, 2
 ; CHECK-NEXT:    ret i1 [[C]]
 ;
   %B = and i8 %A, -2
   %C = icmp eq i8 %B, 0
   ret i1 %C
 }

 define <2 x i1> @test18a_vec(<2 x i8> %A) {
 ; CHECK-LABEL: @test18a_vec(
 ; CHECK-NEXT:    [[C:%.*]] = icmp ult <2 x i8> %A, <i8 2, i8 2>
 ; CHECK-NEXT:    ret <2 x i1> [[C]]
 ;
   %B = and <2 x i8> %A, <i8 -2, i8 -2>
   %C = icmp eq <2 x i8> %B, zeroinitializer
   ret <2 x i1> %C
 }

 define i32 @test19(i32 %A) {
 ; CHECK-LABEL: @test19(
 ; CHECK-NEXT:    [[B:%.*]] = shl i32 %A, 3
 ; CHECK-NEXT:    ret i32 [[B]]
 ;
   %B = shl i32 %A, 3
   ;; Clearing a zero bit
   %C = and i32 %B, -2
   ret i32 %C
 }

 define i8 @test20(i8 %A) {
 ; CHECK-LABEL: @test20(
 ; CHECK-NEXT:    [[C:%.*]] = lshr i8 %A, 7
 ; CHECK-NEXT:    ret i8 [[C]]
 ;
   %C = lshr i8 %A, 7
   ;; Unneeded
   %D = and i8 %C, 1
   ret i8 %D
 }

 define i1 @test23(i32 %A) {
 ; CHECK-LABEL: @test23(
 ; CHECK-NEXT:    [[TMP1:%.*]] = icmp eq i32 %A, 2
 ; CHECK-NEXT:    ret i1 [[TMP1]]
 ;
   %B = icmp sgt i32 %A, 1
   %C = icmp sle i32 %A, 2
   %D = and i1 %B, %C
   ret i1 %D
 }

 ; FIXME: Vectors should fold too.
 define <2 x i1> @test23vec(<2 x i32> %A) {
 ; CHECK-LABEL: @test23vec(
 ; CHECK-NEXT:    [[B:%.*]] = icmp sgt <2 x i32> %A, <i32 1, i32 1>
 ; CHECK-NEXT:    [[C:%.*]] = icmp slt <2 x i32> %A, <i32 3, i32 3>
 ; CHECK-NEXT:    [[D:%.*]] = and <2 x i1> [[B]], [[C]]
 ; CHECK-NEXT:    ret <2 x i1> [[D]]
 ;
   %B = icmp sgt <2 x i32> %A, <i32 1, i32 1>
   %C = icmp sle <2 x i32> %A, <i32 2, i32 2>
   %D = and <2 x i1> %B, %C
   ret <2 x i1> %D
 }

 define i1 @test24(i32 %A) {
 ; CHECK-LABEL: @test24(
 ; CHECK-NEXT:    [[TMP1:%.*]] = icmp sgt i32 %A, 2
 ; CHECK-NEXT:    ret i1 [[TMP1]]
 ;
   %B = icmp sgt i32 %A, 1
   %C = icmp ne i32 %A, 2
   ;; A > 2
   %D = and i1 %B, %C
   ret i1 %D
 }

 define i1 @test25(i32 %A) {
 ; CHECK-LABEL: @test25(
 ; CHECK-NEXT:    [[A_OFF:%.*]] = add i32 %A, -50
 ; CHECK-NEXT:    [[TMP1:%.*]] = icmp ult i32 [[A_OFF]], 50
 ; CHECK-NEXT:    ret i1 [[TMP1]]
 ;
   %B = icmp sge i32 %A, 50
   %C = icmp slt i32 %A, 100
   %D = and i1 %B, %C
   ret i1 %D
 }

 ; FIXME: Vectors should fold too.
 define <2 x i1> @test25vec(<2 x i32> %A) {
 ; CHECK-LABEL: @test25vec(
 ; CHECK-NEXT:    [[B:%.*]] = icmp sgt <2 x i32> %A, <i32 49, i32 49>
 ; CHECK-NEXT:    [[C:%.*]] = icmp slt <2 x i32> %A, <i32 100, i32 100>
 ; CHECK-NEXT:    [[D:%.*]] = and <2 x i1> [[B]], [[C]]
 ; CHECK-NEXT:    ret <2 x i1> [[D]]
 ;
   %B = icmp sge <2 x i32> %A, <i32 50, i32 50>
   %C = icmp slt <2 x i32> %A, <i32 100, i32 100>
   %D = and <2 x i1> %B, %C
   ret <2 x i1> %D
 }

 define i8 @test27(i8 %A) {
 ; CHECK-LABEL: @test27(
 ; CHECK-NEXT:    ret i8 0
 ;
   %B = and i8 %A, 4
   %C = sub i8 %B, 16
   ;; 0xF0
   %D = and i8 %C, -16
   %E = add i8 %D, 16
   ret i8 %E
 }

 ;; This is just a zero-extending shr.
 define i32 @test28(i32 %X) {
 ; CHECK-LABEL: @test28(
 ; CHECK-NEXT:    [[Y1:%.*]] = lshr i32 %X, 24
 ; CHECK-NEXT:    ret i32 [[Y1]]
 ;
   ;; Sign extend
   %Y = ashr i32 %X, 24
   ;; Mask out sign bits
   %Z = and i32 %Y, 255
   ret i32 %Z
 }

 define i32 @test29(i8 %X) {
 ; CHECK-LABEL: @test29(
 ; CHECK-NEXT:    [[Y:%.*]] = zext i8 %X to i32
 ; CHECK-NEXT:    ret i32 [[Y]]
 ;
   %Y = zext i8 %X to i32
   ;; Zero extend makes this unneeded.
   %Z = and i32 %Y, 255
   ret i32 %Z
 }

 define i32 @test30(i1 %X) {
 ; CHECK-LABEL: @test30(
 ; CHECK-NEXT:    [[Y:%.*]] = zext i1 %X to i32
 ; CHECK-NEXT:    ret i32 [[Y]]
 ;
   %Y = zext i1 %X to i32
   %Z = and i32 %Y, 1
   ret i32 %Z
 }

 define i32 @test31(i1 %X) {
 ; CHECK-LABEL: @test31(
 ; CHECK-NEXT:    [[Y:%.*]] = zext i1 %X to i32
 ; CHECK-NEXT:    [[Z:%.*]] = shl nuw nsw i32 [[Y]], 4
 ; CHECK-NEXT:    ret i32 [[Z]]
 ;
   %Y = zext i1 %X to i32
   %Z = shl i32 %Y, 4
   %A = and i32 %Z, 16
   ret i32 %A
 }

 ; Demanded bit analysis allows us to eliminate the add.

 define <2 x i32> @and_demanded_bits_splat_vec(<2 x i32> %x) {
 ; CHECK-LABEL: @and_demanded_bits_splat_vec(
 ; CHECK-NEXT:    [[Z:%.*]] = and <2 x i32> %x, <i32 7, i32 7>
 ; CHECK-NEXT:    ret <2 x i32> [[Z]]
 ;
   %y = add <2 x i32> %x, <i32 8, i32 8>
   %z = and <2 x i32> %y, <i32 7, i32 7>
   ret <2 x i32> %z
 }

 ; zext (x >> 8) has all zeros in the high 24-bits:  0x000000xx
 ; (y | 255) has all ones in the low 8-bits: 0xyyyyyyff
 ; 'and' of those is all known bits - it's just 'z'.

 define i32 @and_zext_demanded(i16 %x, i32 %y) {
 ; CHECK-LABEL: @and_zext_demanded(
 ; CHECK-NEXT:    [[S:%.*]] = lshr i16 %x, 8
 ; CHECK-NEXT:    [[Z:%.*]] = zext i16 [[S]] to i32
 ; CHECK-NEXT:    ret i32 [[Z]]
 ;
   %s = lshr i16 %x, 8
   %z = zext i16 %s to i32
   %o = or i32 %y, 255
   %a = and i32 %o, %z
   ret i32 %a
 }

 define i32 @test32(i32 %In) {
 ; CHECK-LABEL: @test32(
 ; CHECK-NEXT:    ret i32 0
 ;
   %Y = and i32 %In, 16
   %Z = lshr i32 %Y, 2
   %A = and i32 %Z, 1
   ret i32 %A
 }

 ;; Code corresponding to one-bit bitfield ^1.
 define i32 @test33(i32 %b) {
 ; CHECK-LABEL: @test33(
 ; CHECK-NEXT:    [[TMP_13:%.*]] = xor i32 %b, 1
 ; CHECK-NEXT:    ret i32 [[TMP_13]]
 ;
   %tmp.4.mask = and i32 %b, 1
   %tmp.10 = xor i32 %tmp.4.mask, 1
   %tmp.12 = and i32 %b, -2
   %tmp.13 = or i32 %tmp.12, %tmp.10
   ret i32 %tmp.13
 }

 define i32 @test33b(i32 %b) {
 ; CHECK-LABEL: @test33b(
 ; CHECK-NEXT:    [[TMP_13:%.*]] = xor i32 [[B:%.*]], 1
 ; CHECK-NEXT:    ret i32 [[TMP_13]]
 ;
   %tmp.4.mask = and i32 %b, 1
   %tmp.10 = xor i32 %tmp.4.mask, 1
   %tmp.12 = and i32 %b, -2
   %tmp.13 = or i32 %tmp.10, %tmp.12
   ret i32 %tmp.13
 }

 define <2 x i32> @test33vec(<2 x i32> %b) {
 ; CHECK-LABEL: @test33vec(
 ; CHECK-NEXT:    [[TMP_13:%.*]] = xor <2 x i32> [[B:%.*]], <i32 1, i32 1>
 ; CHECK-NEXT:    ret <2 x i32> [[TMP_13]]
 ;
   %tmp.4.mask = and <2 x i32> %b, <i32 1, i32 1>
   %tmp.10 = xor <2 x i32> %tmp.4.mask, <i32 1, i32 1>
   %tmp.12 = and <2 x i32> %b, <i32 -2, i32 -2>
   %tmp.13 = or <2 x i32> %tmp.12, %tmp.10
   ret <2 x i32> %tmp.13
 }

 define <2 x i32> @test33vecb(<2 x i32> %b) {
 ; CHECK-LABEL: @test33vecb(
 ; CHECK-NEXT:    [[TMP_13:%.*]] = xor <2 x i32> [[B:%.*]], <i32 1, i32 1>
 ; CHECK-NEXT:    ret <2 x i32> [[TMP_13]]
 ;
   %tmp.4.mask = and <2 x i32> %b, <i32 1, i32 1>
   %tmp.10 = xor <2 x i32> %tmp.4.mask, <i32 1, i32 1>
   %tmp.12 = and <2 x i32> %b, <i32 -2, i32 -2>
   %tmp.13 = or <2 x i32> %tmp.10, %tmp.12
   ret <2 x i32> %tmp.13
 }

 define i32 @test34(i32 %A, i32 %B) {
 ; CHECK-LABEL: @test34(
 ; CHECK-NEXT:    ret i32 %B
 ;
   %tmp.2 = or i32 %B, %A
   %tmp.4 = and i32 %tmp.2, %B
   ret i32 %tmp.4
 }

 ; FIXME: This test should only need -instsimplify (ValueTracking / computeKnownBits), not -instcombine.

 define <2 x i32> @PR24942(<2 x i32> %x) {
 ; CHECK-LABEL: @PR24942(
 ; CHECK-NEXT:    ret <2 x i32> zeroinitializer
 ;
   %lshr = lshr <2 x i32> %x, <i32 31, i32 31>
   %and = and <2 x i32> %lshr, <i32 2, i32 2>
   ret <2 x i32> %and
 }

 define i64 @test35(i32 %X) {
 ; CHECK-LABEL: @test35(
 ; CHECK-NEXT:  %[[sub:.*]] = sub i32 0, %X
 ; CHECK-NEXT:  %[[and:.*]] = and i32 %[[sub]], 240
 ; CHECK-NEXT:  %[[cst:.*]] = zext i32 %[[and]] to i64
 ; CHECK-NEXT:  ret i64 %[[cst]]
   %zext = zext i32 %X to i64
   %zsub = sub i64 0, %zext
   %res = and i64 %zsub, 240
   ret i64 %res
 }

 define i64 @test36(i32 %X) {
 ; CHECK-LABEL: @test36(
 ; CHECK-NEXT:  %[[sub:.*]] = add i32 %X, 7
 ; CHECK-NEXT:  %[[and:.*]] = and i32 %[[sub]], 240
 ; CHECK-NEXT:  %[[cst:.*]] = zext i32 %[[and]] to i64
 ; CHECK-NEXT:  ret i64 %[[cst]]
   %zext = zext i32 %X to i64
   %zsub = add i64 %zext, 7
   %res = and i64 %zsub, 240
   ret i64 %res
 }

 define i64 @test37(i32 %X) {
 ; CHECK-LABEL: @test37(
 ; CHECK-NEXT:  %[[sub:.*]] = mul i32 %X, 7
 ; CHECK-NEXT:  %[[and:.*]] = and i32 %[[sub]], 240
 ; CHECK-NEXT:  %[[cst:.*]] = zext i32 %[[and]] to i64
 ; CHECK-NEXT:  ret i64 %[[cst]]
   %zext = zext i32 %X to i64
   %zsub = mul i64 %zext, 7
   %res = and i64 %zsub, 240
   ret i64 %res
 }

 define i64 @test38(i32 %X) {
 ; CHECK-LABEL: @test38(
 ; CHECK-NEXT:  %[[and:.*]] = and i32 %X, 240
 ; CHECK-NEXT:  %[[cst:.*]] = zext i32 %[[and]] to i64
 ; CHECK-NEXT:  ret i64 %[[cst]]
   %zext = zext i32 %X to i64
   %zsub = xor i64 %zext, 7
   %res = and i64 %zsub, 240
   ret i64 %res
 }

 define i64 @test39(i32 %X) {
 ; CHECK-LABEL: @test39(
 ; CHECK-NEXT:  %[[and:.*]] = and i32 %X, 240
 ; CHECK-NEXT:  %[[cst:.*]] = zext i32 %[[and]] to i64
 ; CHECK-NEXT:  ret i64 %[[cst]]
   %zext = zext i32 %X to i64
   %zsub = or i64 %zext, 7
   %res = and i64 %zsub, 240
   ret i64 %res
 }

 define i32 @test40(i1 %C) {
 ; CHECK-LABEL: @test40(
 ; CHECK-NEXT:    [[A:%.*]] = select i1 [[C:%.*]], i32 104, i32 10
 ; CHECK-NEXT:    ret i32 [[A]]
 ;
   %A = select i1 %C, i32 1000, i32 10
   %V = and i32 %A, 123
   ret i32 %V
 }

 define <2 x i32> @test40vec(i1 %C) {
 ; CHECK-LABEL: @test40vec(
 ; CHECK-NEXT:    [[A:%.*]] = select i1 [[C:%.*]], <2 x i32> <i32 104, i32 104>, <2 x i32> <i32 10, i32 10>
 ; CHECK-NEXT:    ret <2 x i32> [[A]]
 ;
   %A = select i1 %C, <2 x i32> <i32 1000, i32 1000>, <2 x i32> <i32 10, i32 10>
   %V = and <2 x i32> %A, <i32 123, i32 123>
   ret <2 x i32> %V
 }

 define <2 x i32> @test40vec2(i1 %C) {
 ; CHECK-LABEL: @test40vec2(
 ; CHECK-NEXT:    [[V:%.*]] = select i1 [[C:%.*]], <2 x i32> <i32 104, i32 324>, <2 x i32> <i32 10, i32 12>
 ; CHECK-NEXT:    ret <2 x i32> [[V]]
 ;
   %A = select i1 %C, <2 x i32> <i32 1000, i32 2500>, <2 x i32> <i32 10, i32 30>
   %V = and <2 x i32> %A, <i32 123, i32 333>
   ret <2 x i32> %V
 }

 define i32 @test41(i1 %which) {
 ; CHECK-LABEL: @test41(
 ; CHECK-NEXT:  entry:
 ; CHECK-NEXT:    br i1 [[WHICH:%.*]], label [[FINAL:%.*]], label [[DELAY:%.*]]
 ; CHECK:       delay:
 ; CHECK-NEXT:    br label [[FINAL]]
 ; CHECK:       final:
 ; CHECK-NEXT:    [[A:%.*]] = phi i32 [ 104, [[ENTRY:%.*]] ], [ 10, [[DELAY]] ]
 ; CHECK-NEXT:    ret i32 [[A]]
 ;
 entry:
   br i1 %which, label %final, label %delay

 delay:
   br label %final

 final:
   %A = phi i32 [ 1000, %entry ], [ 10, %delay ]
   %value = and i32 %A, 123
   ret i32 %value
 }

 define <2 x i32> @test41vec(i1 %which) {
 ; CHECK-LABEL: @test41vec(
 ; CHECK-NEXT:  entry:
 ; CHECK-NEXT:    br i1 [[WHICH:%.*]], label [[FINAL:%.*]], label [[DELAY:%.*]]
 ; CHECK:       delay:
 ; CHECK-NEXT:    br label [[FINAL]]
 ; CHECK:       final:
 ; CHECK-NEXT:    [[A:%.*]] = phi <2 x i32> [ <i32 104, i32 104>, [[ENTRY:%.*]] ], [ <i32 10, i32 10>, [[DELAY]] ]
 ; CHECK-NEXT:    ret <2 x i32> [[A]]
 ;
 entry:
   br i1 %which, label %final, label %delay

 delay:
   br label %final

 final:
   %A = phi <2 x i32> [ <i32 1000, i32 1000>, %entry ], [ <i32 10, i32 10>, %delay ]
   %value = and <2 x i32> %A, <i32 123, i32 123>
   ret <2 x i32> %value
 }

 define <2 x i32> @test41vec2(i1 %which) {
 ; CHECK-LABEL: @test41vec2(
 ; CHECK-NEXT:  entry:
 ; CHECK-NEXT:    br i1 [[WHICH:%.*]], label [[FINAL:%.*]], label [[DELAY:%.*]]
 ; CHECK:       delay:
 ; CHECK-NEXT:    br label [[FINAL]]
 ; CHECK:       final:
 ; CHECK-NEXT:    [[A:%.*]] = phi <2 x i32> [ <i32 104, i32 324>, [[ENTRY:%.*]] ], [ <i32 10, i32 12>, [[DELAY]] ]
 ; CHECK-NEXT:    ret <2 x i32> [[A]]
 ;
 entry:
   br i1 %which, label %final, label %delay

 delay:
   br label %final

 final:
   %A = phi <2 x i32> [ <i32 1000, i32 2500>, %entry ], [ <i32 10, i32 30>, %delay ]
   %value = and <2 x i32> %A, <i32 123, i32 333>
   ret <2 x i32> %value
 }

 define i32 @test42(i32 %a, i32 %c, i32 %d) {
 ; CHECK-LABEL: @test42(
 ; CHECK-NEXT:    [[FORCE:%.*]] = mul i32 [[C:%.*]], [[D:%.*]]
 ; CHECK-NEXT:    [[AND:%.*]] = and i32 [[FORCE]], [[A:%.*]]
 ; CHECK-NEXT:    ret i32 [[AND]]
 ;
   %force = mul i32 %c, %d ; forces the complexity sorting
   %or = or i32 %a, %force
   %nota = xor i32 %a, -1
   %xor = xor i32 %nota, %force
   %and = and i32 %xor, %or
   ret i32 %and
 }

 define i32 @test43(i32 %a, i32 %c, i32 %d) {
 ; CHECK-LABEL: @test43(
 ; CHECK-NEXT:    [[FORCE:%.*]] = mul i32 [[C:%.*]], [[D:%.*]]
 ; CHECK-NEXT:    [[AND:%.*]] = and i32 [[FORCE]], [[A:%.*]]
 ; CHECK-NEXT:    ret i32 [[AND]]
 ;
   %force = mul i32 %c, %d ; forces the complexity sorting
   %or = or i32 %a, %force
   %nota = xor i32 %a, -1
   %xor = xor i32 %nota, %force
   %and = and i32 %or, %xor
   ret i32 %and
 }

 ; (~y | x) & y -> x & y
 define i32 @test44(i32 %x, i32 %y) nounwind {
 ; CHECK-LABEL: @test44(
 ; CHECK-NEXT:    [[A:%.*]] = and i32 [[X:%.*]], [[Y:%.*]]
 ; CHECK-NEXT:    ret i32 [[A]]
 ;
   %n = xor i32 %y, -1
   %o = or i32 %n, %x
   %a = and i32 %o, %y
   ret i32 %a
 }

 ; (x | ~y) & y -> x & y
 define i32 @test45(i32 %x, i32 %y) nounwind {
 ; CHECK-LABEL: @test45(
 ; CHECK-NEXT:    [[A:%.*]] = and i32 [[X:%.*]], [[Y:%.*]]
 ; CHECK-NEXT:    ret i32 [[A]]
 ;
   %n = xor i32 %y, -1
   %o = or i32 %x, %n
   %a = and i32 %o, %y
   ret i32 %a
 }

 ; y & (~y | x) -> y | x
 define i32 @test46(i32 %x, i32 %y) nounwind {
 ; CHECK-LABEL: @test46(
 ; CHECK-NEXT:    [[A:%.*]] = and i32 [[X:%.*]], [[Y:%.*]]
 ; CHECK-NEXT:    ret i32 [[A]]
 ;
   %n = xor i32 %y, -1
   %o = or i32 %n, %x
   %a = and i32 %y, %o
   ret i32 %a
 }

 ; y & (x | ~y) -> y | x
 define i32 @test47(i32 %x, i32 %y) nounwind {
 ; CHECK-LABEL: @test47(
 ; CHECK-NEXT:    [[A:%.*]] = and i32 [[X:%.*]], [[Y:%.*]]
 ; CHECK-NEXT:    ret i32 [[A]]
 ;
   %n = xor i32 %y, -1
   %o = or i32 %x, %n
   %a = and i32 %y, %o
   ret i32 %a
 }

 ; In the next 4 tests, vary the types and predicates for extra coverage.
 ; (X & (Y | ~X)) -> (X & Y), where 'not' is an inverted cmp

 define i1 @and_orn_cmp_1(i32 %a, i32 %b, i32 %c) {
 ; CHECK-LABEL: @and_orn_cmp_1(
 ; CHECK-NEXT:    [[X:%.*]] = icmp sgt i32 [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt i32 [[C:%.*]], 42
 ; CHECK-NEXT:    [[AND:%.*]] = and i1 [[X]], [[Y]]
 ; CHECK-NEXT:    ret i1 [[AND]]
 ;
   %x = icmp sgt i32 %a, %b
   %x_inv = icmp sle i32 %a, %b
   %y = icmp ugt i32 %c, 42      ; thwart complexity-based ordering
   %or = or i1 %y, %x_inv
   %and = and i1 %x, %or
   ret i1 %and
 }

 ; Commute the 'and':
 ; ((Y | ~X) & X) -> (X & Y), where 'not' is an inverted cmp

 define <2 x i1> @and_orn_cmp_2(<2 x i32> %a, <2 x i32> %b, <2 x i32> %c) {
 ; CHECK-LABEL: @and_orn_cmp_2(
 ; CHECK-NEXT:    [[X:%.*]] = icmp sge <2 x i32> [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt <2 x i32> [[C:%.*]], <i32 42, i32 47>
 ; CHECK-NEXT:    [[AND:%.*]] = and <2 x i1> [[Y]], [[X]]
 ; CHECK-NEXT:    ret <2 x i1> [[AND]]
 ;
   %x = icmp sge <2 x i32> %a, %b
   %x_inv = icmp slt <2 x i32> %a, %b
   %y = icmp ugt <2 x i32> %c, <i32 42, i32 47>      ; thwart complexity-based ordering
   %or = or <2 x i1> %y, %x_inv
   %and = and <2 x i1> %or, %x
   ret <2 x i1> %and
 }

 ; Commute the 'or':
 ; (X & (~X | Y)) -> (X & Y), where 'not' is an inverted cmp

 define i1 @and_orn_cmp_3(i72 %a, i72 %b, i72 %c) {
 ; CHECK-LABEL: @and_orn_cmp_3(
 ; CHECK-NEXT:    [[X:%.*]] = icmp ugt i72 [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt i72 [[C:%.*]], 42
 ; CHECK-NEXT:    [[AND:%.*]] = and i1 [[X]], [[Y]]
 ; CHECK-NEXT:    ret i1 [[AND]]
 ;
   %x = icmp ugt i72 %a, %b
   %x_inv = icmp ule i72 %a, %b
   %y = icmp ugt i72 %c, 42      ; thwart complexity-based ordering
   %or = or i1 %x_inv, %y
   %and = and i1 %x, %or
   ret i1 %and
 }

 ; Commute the 'and':
 ; ((~X | Y) & X) -> (X & Y), where 'not' is an inverted cmp

 define <3 x i1> @or_andn_cmp_4(<3 x i32> %a, <3 x i32> %b, <3 x i32> %c) {
 ; CHECK-LABEL: @or_andn_cmp_4(
 ; CHECK-NEXT:    [[X:%.*]] = icmp eq <3 x i32> [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt <3 x i32> [[C:%.*]], <i32 42, i32 43, i32 -1>
 ; CHECK-NEXT:    [[AND:%.*]] = and <3 x i1> [[Y]], [[X]]
 ; CHECK-NEXT:    ret <3 x i1> [[AND]]
 ;
   %x = icmp eq <3 x i32> %a, %b
   %x_inv = icmp ne <3 x i32> %a, %b
   %y = icmp ugt <3 x i32> %c, <i32 42, i32 43, i32 -1>      ; thwart complexity-based ordering
   %or = or <3 x i1> %x_inv, %y
   %and = and <3 x i1> %or, %x
   ret <3 x i1> %and
 }

 ; In the next 4 tests, vary the types and predicates for extra coverage.
 ; (~X & (Y | X)) -> (~X & Y), where 'not' is an inverted cmp

 define i1 @andn_or_cmp_1(i37 %a, i37 %b, i37 %c) {
 ; CHECK-LABEL: @andn_or_cmp_1(
 ; CHECK-NEXT:    [[X_INV:%.*]] = icmp sle i37 [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt i37 [[C:%.*]], 42
 ; CHECK-NEXT:    [[AND:%.*]] = and i1 [[X_INV]], [[Y]]
 ; CHECK-NEXT:    ret i1 [[AND]]
 ;
   %x = icmp sgt i37 %a, %b
   %x_inv = icmp sle i37 %a, %b
   %y = icmp ugt i37 %c, 42      ; thwart complexity-based ordering
   %or = or i1 %y, %x
   %and = and i1 %x_inv, %or
   ret i1 %and
 }

 ; Commute the 'and':
 ; ((Y | X) & ~X) -> (~X & Y), where 'not' is an inverted cmp

 define i1 @andn_or_cmp_2(i16 %a, i16 %b, i16 %c) {
 ; CHECK-LABEL: @andn_or_cmp_2(
 ; CHECK-NEXT:    [[X_INV:%.*]] = icmp slt i16 [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt i16 [[C:%.*]], 42
 ; CHECK-NEXT:    [[AND:%.*]] = and i1 [[Y]], [[X_INV]]
 ; CHECK-NEXT:    ret i1 [[AND]]
 ;
   %x = icmp sge i16 %a, %b
   %x_inv = icmp slt i16 %a, %b
   %y = icmp ugt i16 %c, 42      ; thwart complexity-based ordering
   %or = or i1 %y, %x
   %and = and i1 %or, %x_inv
   ret i1 %and
 }

 ; Commute the 'or':
 ; (~X & (X | Y)) -> (~X & Y), where 'not' is an inverted cmp

 define <4 x i1> @andn_or_cmp_3(<4 x i32> %a, <4 x i32> %b, <4 x i32> %c) {
 ; CHECK-LABEL: @andn_or_cmp_3(
 ; CHECK-NEXT:    [[X_INV:%.*]] = icmp ule <4 x i32> [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt <4 x i32> [[C:%.*]], <i32 42, i32 0, i32 1, i32 -1>
 ; CHECK-NEXT:    [[AND:%.*]] = and <4 x i1> [[X_INV]], [[Y]]
 ; CHECK-NEXT:    ret <4 x i1> [[AND]]
 ;
   %x = icmp ugt <4 x i32> %a, %b
   %x_inv = icmp ule <4 x i32> %a, %b
   %y = icmp ugt <4 x i32> %c, <i32 42, i32 0, i32 1, i32 -1>      ; thwart complexity-based ordering
   %or = or <4 x i1> %x, %y
   %and = and <4 x i1> %x_inv, %or
   ret <4 x i1> %and
 }

 ; Commute the 'and':
 ; ((X | Y) & ~X) -> (~X & Y), where 'not' is an inverted cmp

 define i1 @andn_or_cmp_4(i32 %a, i32 %b, i32 %c) {
 ; CHECK-LABEL: @andn_or_cmp_4(
 ; CHECK-NEXT:    [[X_INV:%.*]] = icmp ne i32 [[A:%.*]], [[B:%.*]]
 ; CHECK-NEXT:    [[Y:%.*]] = icmp ugt i32 [[C:%.*]], 42
 ; CHECK-NEXT:    [[AND:%.*]] = and i1 [[Y]], [[X_INV]]
 ; CHECK-NEXT:    ret i1 [[AND]]
 ;
   %x = icmp eq i32 %a, %b
   %x_inv = icmp ne i32 %a, %b
   %y = icmp ugt i32 %c, 42      ; thwart complexity-based ordering
   %or = or i1 %x, %y
   %and = and i1 %or, %x_inv
   ret i1 %and
 }
	; NOTE: Assertions have been autogenerated by utils/update_test_checks.py
	; RUN: opt < %s -instcombine -S \| FileCheck %s

	; There should be no 'and' instructions left in any test.

	define i32 @test1(i32 %A) {
	; CHECK-LABEL: @test1(
	; CHECK-NEXT: ret i32 0
	;
	%B = and i32 %A, 0
	ret i32 %B
	}

	define i32 @test2(i32 %A) {
	; CHECK-LABEL: @test2(
	; CHECK-NEXT: ret i32 %A
	;
	%B = and i32 %A, -1
	ret i32 %B
	}

	define i1 @test3(i1 %A) {
	; CHECK-LABEL: @test3(
	; CHECK-NEXT: ret i1 false
	;
	%B = and i1 %A, false
	ret i1 %B
	}

	define i1 @test4(i1 %A) {
	; CHECK-LABEL: @test4(
	; CHECK-NEXT: ret i1 %A
	;
	%B = and i1 %A, true
	ret i1 %B
	}

	define i32 @test5(i32 %A) {
	; CHECK-LABEL: @test5(
	; CHECK-NEXT: ret i32 %A
	;
	%B = and i32 %A, %A
	ret i32 %B
	}

	define i1 @test6(i1 %A) {
	; CHECK-LABEL: @test6(
	; CHECK-NEXT: ret i1 %A
	;
	%B = and i1 %A, %A
	ret i1 %B
	}

	; A & ~A == 0
	define i32 @test7(i32 %A) {
	; CHECK-LABEL: @test7(
	; CHECK-NEXT: ret i32 0
	;
	%NotA = xor i32 %A, -1
	%B = and i32 %A, %NotA
	ret i32 %B
	}

	; AND associates
	define i8 @test8(i8 %A) {
	; CHECK-LABEL: @test8(
	; CHECK-NEXT: ret i8 0
	;
	%B = and i8 %A, 3
	%C = and i8 %B, 4
	ret i8 %C
	}

	; Test of sign bit, convert to setle %A, 0
	define i1 @test9(i32 %A) {
	; CHECK-LABEL: @test9(
	; CHECK-NEXT: [[C:%.*]] = icmp slt i32 %A, 0
	; CHECK-NEXT: ret i1 [[C]]
	;
	%B = and i32 %A, -2147483648
	%C = icmp ne i32 %B, 0
	ret i1 %C
	}

	; Test of sign bit, convert to setle %A, 0
	define i1 @test9a(i32 %A) {
	; CHECK-LABEL: @test9a(
	; CHECK-NEXT: [[C:%.*]] = icmp slt i32 %A, 0
	; CHECK-NEXT: ret i1 [[C]]
	;
	%B = and i32 %A, -2147483648
	%C = icmp ne i32 %B, 0
	ret i1 %C
	}

	define i32 @test10(i32 %A) {
	; CHECK-LABEL: @test10(
	; CHECK-NEXT: ret i32 1
	;
	%B = and i32 %A, 12
	%C = xor i32 %B, 15
	; (X ^ C1) & C2 --> (X & C2) ^ (C1&C2)
	%D = and i32 %C, 1
	ret i32 %D
	}

	define i32 @test11(i32 %A, i32* %P) {
	; CHECK-LABEL: @test11(
	; CHECK-NEXT: [[B:%.*]] = or i32 %A, 3
	; CHECK-NEXT: [[C:%.*]] = xor i32 [[B]], 12
	; CHECK-NEXT: store i32 [[C]], i32* %P, align 4
	; CHECK-NEXT: ret i32 3
	;
	%B = or i32 %A, 3
	%C = xor i32 %B, 12
	; additional use of C
	store i32 %C, i32* %P
	; %C = and uint %B, 3 --> 3
	%D = and i32 %C, 3
	ret i32 %D
	}

	define i1 @test12(i32 %A, i32 %B) {
	; CHECK-LABEL: @test12(
	; CHECK-NEXT: [[TMP1:%.*]] = icmp ult i32 %A, %B
	; CHECK-NEXT: ret i1 [[TMP1]]
	;
	%C1 = icmp ult i32 %A, %B
	%C2 = icmp ule i32 %A, %B
	; (A < B) & (A <= B) === (A < B)
	%D = and i1 %C1, %C2
	ret i1 %D
	}

	define i1 @test13(i32 %A, i32 %B) {
	; CHECK-LABEL: @test13(
	; CHECK-NEXT: ret i1 false
	;
	%C1 = icmp ult i32 %A, %B
	%C2 = icmp ugt i32 %A, %B
	; (A < B) & (A > B) === false
	%D = and i1 %C1, %C2
	ret i1 %D
	}

	define i1 @test14(i8 %A) {
	; CHECK-LABEL: @test14(
	; CHECK-NEXT: [[C:%.*]] = icmp slt i8 %A, 0
	; CHECK-NEXT: ret i1 [[C]]
	;
	%B = and i8 %A, -128
	%C = icmp ne i8 %B, 0
	ret i1 %C
	}

	define i8 @test15(i8 %A) {
	; CHECK-LABEL: @test15(
	; CHECK-NEXT: ret i8 0
	;
	%B = lshr i8 %A, 7
	; Always equals zero
	%C = and i8 %B, 2
	ret i8 %C
	}

	define i8 @test16(i8 %A) {
	; CHECK-LABEL: @test16(
	; CHECK-NEXT: ret i8 0
	;
	%B = shl i8 %A, 2
	%C = and i8 %B, 3
	ret i8 %C
	}

	define i1 @test18(i32 %A) {
	; CHECK-LABEL: @test18(
	; CHECK-NEXT: [[C:%.*]] = icmp ugt i32 %A, 127
	; CHECK-NEXT: ret i1 [[C]]
	;
	%B = and i32 %A, -128
	;; C >= 128
	%C = icmp ne i32 %B, 0
	ret i1 %C
	}

	define <2 x i1> @test18_vec(<2 x i32> %A) {
	; CHECK-LABEL: @test18_vec(
	; CHECK-NEXT: [[C:%.*]] = icmp ugt <2 x i32> %A, <i32 127, i32 127>
	; CHECK-NEXT: ret <2 x i1> [[C]]
	;
	%B = and <2 x i32> %A, <i32 -128, i32 -128>
	%C = icmp ne <2 x i32> %B, zeroinitializer
	ret <2 x i1> %C
	}

	define i1 @test18a(i8 %A) {
	; CHECK-LABEL: @test18a(
	; CHECK-NEXT: [[C:%.*]] = icmp ult i8 %A, 2
	; CHECK-NEXT: ret i1 [[C]]
	;
	%B = and i8 %A, -2
	%C = icmp eq i8 %B, 0
	ret i1 %C
	}

	define <2 x i1> @test18a_vec(<2 x i8> %A) {
	; CHECK-LABEL: @test18a_vec(
	; CHECK-NEXT: [[C:%.*]] = icmp ult <2 x i8> %A, <i8 2, i8 2>
	; CHECK-NEXT: ret <2 x i1> [[C]]
	;
	%B = and <2 x i8> %A, <i8 -2, i8 -2>
	%C = icmp eq <2 x i8> %B, zeroinitializer
	ret <2 x i1> %C
	}

	define i32 @test19(i32 %A) {
	; CHECK-LABEL: @test19(
	; CHECK-NEXT: [[B:%.*]] = shl i32 %A, 3
	; CHECK-NEXT: ret i32 [[B]]
	;
	%B = shl i32 %A, 3
	;; Clearing a zero bit
	%C = and i32 %B, -2
	ret i32 %C
	}

	define i8 @test20(i8 %A) {
	; CHECK-LABEL: @test20(
	; CHECK-NEXT: [[C:%.*]] = lshr i8 %A, 7
	; CHECK-NEXT: ret i8 [[C]]
	;
	%C = lshr i8 %A, 7
	;; Unneeded
	%D = and i8 %C, 1
	ret i8 %D
	}

	define i1 @test23(i32 %A) {
	; CHECK-LABEL: @test23(
	; CHECK-NEXT: [[TMP1:%.*]] = icmp eq i32 %A, 2
	; CHECK-NEXT: ret i1 [[TMP1]]
	;
	%B = icmp sgt i32 %A, 1
	%C = icmp sle i32 %A, 2
	%D = and i1 %B, %C
	ret i1 %D
	}

	; FIXME: Vectors should fold too.
	define <2 x i1> @test23vec(<2 x i32> %A) {
	; CHECK-LABEL: @test23vec(
	; CHECK-NEXT: [[B:%.*]] = icmp sgt <2 x i32> %A, <i32 1, i32 1>
	; CHECK-NEXT: [[C:%.*]] = icmp slt <2 x i32> %A, <i32 3, i32 3>
	; CHECK-NEXT: [[D:%.*]] = and <2 x i1> [[B]], [[C]]
	; CHECK-NEXT: ret <2 x i1> [[D]]
	;
	%B = icmp sgt <2 x i32> %A, <i32 1, i32 1>
	%C = icmp sle <2 x i32> %A, <i32 2, i32 2>
	%D = and <2 x i1> %B, %C
	ret <2 x i1> %D
	}

	define i1 @test24(i32 %A) {
	; CHECK-LABEL: @test24(
	; CHECK-NEXT: [[TMP1:%.*]] = icmp sgt i32 %A, 2
	; CHECK-NEXT: ret i1 [[TMP1]]
	;
	%B = icmp sgt i32 %A, 1
	%C = icmp ne i32 %A, 2
	;; A > 2
	%D = and i1 %B, %C
	ret i1 %D
	}

	define i1 @test25(i32 %A) {
	; CHECK-LABEL: @test25(
	; CHECK-NEXT: [[A_OFF:%.*]] = add i32 %A, -50
	; CHECK-NEXT: [[TMP1:%.*]] = icmp ult i32 [[A_OFF]], 50
	; CHECK-NEXT: ret i1 [[TMP1]]
	;
	%B = icmp sge i32 %A, 50
	%C = icmp slt i32 %A, 100
	%D = and i1 %B, %C
	ret i1 %D
	}

	; FIXME: Vectors should fold too.
	define <2 x i1> @test25vec(<2 x i32> %A) {
	; CHECK-LABEL: @test25vec(
	; CHECK-NEXT: [[B:%.*]] = icmp sgt <2 x i32> %A, <i32 49, i32 49>
	; CHECK-NEXT: [[C:%.*]] = icmp slt <2 x i32> %A, <i32 100, i32 100>
	; CHECK-NEXT: [[D:%.*]] = and <2 x i1> [[B]], [[C]]
	; CHECK-NEXT: ret <2 x i1> [[D]]
	;
	%B = icmp sge <2 x i32> %A, <i32 50, i32 50>
	%C = icmp slt <2 x i32> %A, <i32 100, i32 100>
	%D = and <2 x i1> %B, %C
	ret <2 x i1> %D
	}

	define i8 @test27(i8 %A) {
	; CHECK-LABEL: @test27(
	; CHECK-NEXT: ret i8 0
	;
	%B = and i8 %A, 4
	%C = sub i8 %B, 16
	;; 0xF0
	%D = and i8 %C, -16
	%E = add i8 %D, 16
	ret i8 %E
	}

	;; This is just a zero-extending shr.
	define i32 @test28(i32 %X) {
	; CHECK-LABEL: @test28(
	; CHECK-NEXT: [[Y1:%.*]] = lshr i32 %X, 24
	; CHECK-NEXT: ret i32 [[Y1]]
	;
	;; Sign extend
	%Y = ashr i32 %X, 24
	;; Mask out sign bits
	%Z = and i32 %Y, 255
	ret i32 %Z
	}

	define i32 @test29(i8 %X) {
	; CHECK-LABEL: @test29(
	; CHECK-NEXT: [[Y:%.*]] = zext i8 %X to i32
	; CHECK-NEXT: ret i32 [[Y]]
	;
	%Y = zext i8 %X to i32
	;; Zero extend makes this unneeded.
	%Z = and i32 %Y, 255
	ret i32 %Z
	}

	define i32 @test30(i1 %X) {
	; CHECK-LABEL: @test30(
	; CHECK-NEXT: [[Y:%.*]] = zext i1 %X to i32
	; CHECK-NEXT: ret i32 [[Y]]
	;
	%Y = zext i1 %X to i32
	%Z = and i32 %Y, 1
	ret i32 %Z
	}

	define i32 @test31(i1 %X) {
	; CHECK-LABEL: @test31(
	; CHECK-NEXT: [[Y:%.*]] = zext i1 %X to i32
	; CHECK-NEXT: [[Z:%.*]] = shl nuw nsw i32 [[Y]], 4
	; CHECK-NEXT: ret i32 [[Z]]
	;
	%Y = zext i1 %X to i32
	%Z = shl i32 %Y, 4
	%A = and i32 %Z, 16
	ret i32 %A
	}

	; Demanded bit analysis allows us to eliminate the add.

	define <2 x i32> @and_demanded_bits_splat_vec(<2 x i32> %x) {
	; CHECK-LABEL: @and_demanded_bits_splat_vec(
	; CHECK-NEXT: [[Z:%.*]] = and <2 x i32> %x, <i32 7, i32 7>
	; CHECK-NEXT: ret <2 x i32> [[Z]]
	;
	%y = add <2 x i32> %x, <i32 8, i32 8>
	%z = and <2 x i32> %y, <i32 7, i32 7>
	ret <2 x i32> %z
	}

	; zext (x >> 8) has all zeros in the high 24-bits: 0x000000xx
	; (y \| 255) has all ones in the low 8-bits: 0xyyyyyyff
	; 'and' of those is all known bits - it's just 'z'.

	define i32 @and_zext_demanded(i16 %x, i32 %y) {
	; CHECK-LABEL: @and_zext_demanded(
	; CHECK-NEXT: [[S:%.*]] = lshr i16 %x, 8
	; CHECK-NEXT: [[Z:%.*]] = zext i16 [[S]] to i32
	; CHECK-NEXT: ret i32 [[Z]]
	;
	%s = lshr i16 %x, 8
	%z = zext i16 %s to i32
	%o = or i32 %y, 255
	%a = and i32 %o, %z
	ret i32 %a
	}

	define i32 @test32(i32 %In) {
	; CHECK-LABEL: @test32(
	; CHECK-NEXT: ret i32 0
	;
	%Y = and i32 %In, 16
	%Z = lshr i32 %Y, 2
	%A = and i32 %Z, 1
	ret i32 %A
	}

	;; Code corresponding to one-bit bitfield ^1.
	define i32 @test33(i32 %b) {
	; CHECK-LABEL: @test33(
	; CHECK-NEXT: [[TMP_13:%.*]] = xor i32 %b, 1
	; CHECK-NEXT: ret i32 [[TMP_13]]
	;
	%tmp.4.mask = and i32 %b, 1
	%tmp.10 = xor i32 %tmp.4.mask, 1
	%tmp.12 = and i32 %b, -2
	%tmp.13 = or i32 %tmp.12, %tmp.10
	ret i32 %tmp.13
	}

	define i32 @test33b(i32 %b) {
	; CHECK-LABEL: @test33b(
	; CHECK-NEXT: [[TMP_13:%.]] = xor i32 [[B:%.]], 1
	; CHECK-NEXT: ret i32 [[TMP_13]]
	;
	%tmp.4.mask = and i32 %b, 1
	%tmp.10 = xor i32 %tmp.4.mask, 1
	%tmp.12 = and i32 %b, -2
	%tmp.13 = or i32 %tmp.10, %tmp.12
	ret i32 %tmp.13
	}

	define <2 x i32> @test33vec(<2 x i32> %b) {
	; CHECK-LABEL: @test33vec(
	; CHECK-NEXT: [[TMP_13:%.]] = xor <2 x i32> [[B:%.]], <i32 1, i32 1>
	; CHECK-NEXT: ret <2 x i32> [[TMP_13]]
	;
	%tmp.4.mask = and <2 x i32> %b, <i32 1, i32 1>
	%tmp.10 = xor <2 x i32> %tmp.4.mask, <i32 1, i32 1>
	%tmp.12 = and <2 x i32> %b, <i32 -2, i32 -2>
	%tmp.13 = or <2 x i32> %tmp.12, %tmp.10
	ret <2 x i32> %tmp.13
	}

	define <2 x i32> @test33vecb(<2 x i32> %b) {
	; CHECK-LABEL: @test33vecb(
	; CHECK-NEXT: [[TMP_13:%.]] = xor <2 x i32> [[B:%.]], <i32 1, i32 1>
	; CHECK-NEXT: ret <2 x i32> [[TMP_13]]
	;
	%tmp.4.mask = and <2 x i32> %b, <i32 1, i32 1>
	%tmp.10 = xor <2 x i32> %tmp.4.mask, <i32 1, i32 1>
	%tmp.12 = and <2 x i32> %b, <i32 -2, i32 -2>
	%tmp.13 = or <2 x i32> %tmp.10, %tmp.12
	ret <2 x i32> %tmp.13
	}

	define i32 @test34(i32 %A, i32 %B) {
	; CHECK-LABEL: @test34(
	; CHECK-NEXT: ret i32 %B
	;
	%tmp.2 = or i32 %B, %A
	%tmp.4 = and i32 %tmp.2, %B
	ret i32 %tmp.4
	}

	; FIXME: This test should only need -instsimplify (ValueTracking / computeKnownBits), not -instcombine.

	define <2 x i32> @PR24942(<2 x i32> %x) {
	; CHECK-LABEL: @PR24942(
	; CHECK-NEXT: ret <2 x i32> zeroinitializer
	;
	%lshr = lshr <2 x i32> %x, <i32 31, i32 31>
	%and = and <2 x i32> %lshr, <i32 2, i32 2>
	ret <2 x i32> %and
	}

	define i64 @test35(i32 %X) {
	; CHECK-LABEL: @test35(
	; CHECK-NEXT: %[[sub:.*]] = sub i32 0, %X
	; CHECK-NEXT: %[[and:.*]] = and i32 %[[sub]], 240
	; CHECK-NEXT: %[[cst:.*]] = zext i32 %[[and]] to i64
	; CHECK-NEXT: ret i64 %[[cst]]
	%zext = zext i32 %X to i64
	%zsub = sub i64 0, %zext
	%res = and i64 %zsub, 240
	ret i64 %res
	}

	define i64 @test36(i32 %X) {
	; CHECK-LABEL: @test36(
	; CHECK-NEXT: %[[sub:.*]] = add i32 %X, 7
	; CHECK-NEXT: %[[and:.*]] = and i32 %[[sub]], 240
	; CHECK-NEXT: %[[cst:.*]] = zext i32 %[[and]] to i64
	; CHECK-NEXT: ret i64 %[[cst]]
	%zext = zext i32 %X to i64
	%zsub = add i64 %zext, 7
	%res = and i64 %zsub, 240
	ret i64 %res
	}

	define i64 @test37(i32 %X) {
	; CHECK-LABEL: @test37(
	; CHECK-NEXT: %[[sub:.*]] = mul i32 %X, 7
	; CHECK-NEXT: %[[and:.*]] = and i32 %[[sub]], 240
	; CHECK-NEXT: %[[cst:.*]] = zext i32 %[[and]] to i64
	; CHECK-NEXT: ret i64 %[[cst]]
	%zext = zext i32 %X to i64
	%zsub = mul i64 %zext, 7
	%res = and i64 %zsub, 240
	ret i64 %res
	}

	define i64 @test38(i32 %X) {
	; CHECK-LABEL: @test38(
	; CHECK-NEXT: %[[and:.*]] = and i32 %X, 240
	; CHECK-NEXT: %[[cst:.*]] = zext i32 %[[and]] to i64
	; CHECK-NEXT: ret i64 %[[cst]]
	%zext = zext i32 %X to i64
	%zsub = xor i64 %zext, 7
	%res = and i64 %zsub, 240
	ret i64 %res
	}

	define i64 @test39(i32 %X) {
	; CHECK-LABEL: @test39(
	; CHECK-NEXT: %[[and:.*]] = and i32 %X, 240
	; CHECK-NEXT: %[[cst:.*]] = zext i32 %[[and]] to i64
	; CHECK-NEXT: ret i64 %[[cst]]
	%zext = zext i32 %X to i64
	%zsub = or i64 %zext, 7
	%res = and i64 %zsub, 240
	ret i64 %res
	}

	define i32 @test40(i1 %C) {
	; CHECK-LABEL: @test40(
	; CHECK-NEXT: [[A:%.]] = select i1 [[C:%.]], i32 104, i32 10
	; CHECK-NEXT: ret i32 [[A]]
	;
	%A = select i1 %C, i32 1000, i32 10
	%V = and i32 %A, 123
	ret i32 %V
	}

	define <2 x i32> @test40vec(i1 %C) {
	; CHECK-LABEL: @test40vec(
	; CHECK-NEXT: [[A:%.]] = select i1 [[C:%.]], <2 x i32> <i32 104, i32 104>, <2 x i32> <i32 10, i32 10>
	; CHECK-NEXT: ret <2 x i32> [[A]]
	;
	%A = select i1 %C, <2 x i32> <i32 1000, i32 1000>, <2 x i32> <i32 10, i32 10>
	%V = and <2 x i32> %A, <i32 123, i32 123>
	ret <2 x i32> %V
	}

	define <2 x i32> @test40vec2(i1 %C) {
	; CHECK-LABEL: @test40vec2(
	; CHECK-NEXT: [[V:%.]] = select i1 [[C:%.]], <2 x i32> <i32 104, i32 324>, <2 x i32> <i32 10, i32 12>
	; CHECK-NEXT: ret <2 x i32> [[V]]
	;
	%A = select i1 %C, <2 x i32> <i32 1000, i32 2500>, <2 x i32> <i32 10, i32 30>
	%V = and <2 x i32> %A, <i32 123, i32 333>
	ret <2 x i32> %V
	}

	define i32 @test41(i1 %which) {
	; CHECK-LABEL: @test41(
	; CHECK-NEXT: entry:
	; CHECK-NEXT: br i1 [[WHICH:%.]], label [[FINAL:%.]], label [[DELAY:%.*]]
	; CHECK: delay:
	; CHECK-NEXT: br label [[FINAL]]
	; CHECK: final:
	; CHECK-NEXT: [[A:%.]] = phi i32 [ 104, [[ENTRY:%.]] ], [ 10, [[DELAY]] ]
	; CHECK-NEXT: ret i32 [[A]]
	;
	entry:
	br i1 %which, label %final, label %delay

	delay:
	br label %final

	final:
	%A = phi i32 [ 1000, %entry ], [ 10, %delay ]
	%value = and i32 %A, 123
	ret i32 %value
	}

	define <2 x i32> @test41vec(i1 %which) {
	; CHECK-LABEL: @test41vec(
	; CHECK-NEXT: entry:
	; CHECK-NEXT: br i1 [[WHICH:%.]], label [[FINAL:%.]], label [[DELAY:%.*]]
	; CHECK: delay:
	; CHECK-NEXT: br label [[FINAL]]
	; CHECK: final:
	; CHECK-NEXT: [[A:%.]] = phi <2 x i32> [ <i32 104, i32 104>, [[ENTRY:%.]] ], [ <i32 10, i32 10>, [[DELAY]] ]
	; CHECK-NEXT: ret <2 x i32> [[A]]
	;
	entry:
	br i1 %which, label %final, label %delay

	delay:
	br label %final

	final:
	%A = phi <2 x i32> [ <i32 1000, i32 1000>, %entry ], [ <i32 10, i32 10>, %delay ]
	%value = and <2 x i32> %A, <i32 123, i32 123>
	ret <2 x i32> %value
	}

	define <2 x i32> @test41vec2(i1 %which) {
	; CHECK-LABEL: @test41vec2(
	; CHECK-NEXT: entry:
	; CHECK-NEXT: br i1 [[WHICH:%.]], label [[FINAL:%.]], label [[DELAY:%.*]]
	; CHECK: delay:
	; CHECK-NEXT: br label [[FINAL]]
	; CHECK: final:
	; CHECK-NEXT: [[A:%.]] = phi <2 x i32> [ <i32 104, i32 324>, [[ENTRY:%.]] ], [ <i32 10, i32 12>, [[DELAY]] ]
	; CHECK-NEXT: ret <2 x i32> [[A]]
	;
	entry:
	br i1 %which, label %final, label %delay

	delay:
	br label %final

	final:
	%A = phi <2 x i32> [ <i32 1000, i32 2500>, %entry ], [ <i32 10, i32 30>, %delay ]
	%value = and <2 x i32> %A, <i32 123, i32 333>
	ret <2 x i32> %value
	}

	define i32 @test42(i32 %a, i32 %c, i32 %d) {
	; CHECK-LABEL: @test42(
	; CHECK-NEXT: [[FORCE:%.]] = mul i32 [[C:%.]], [[D:%.*]]
	; CHECK-NEXT: [[AND:%.]] = and i32 [[FORCE]], [[A:%.]]
	; CHECK-NEXT: ret i32 [[AND]]
	;
	%force = mul i32 %c, %d ; forces the complexity sorting
	%or = or i32 %a, %force
	%nota = xor i32 %a, -1
	%xor = xor i32 %nota, %force
	%and = and i32 %xor, %or
	ret i32 %and
	}

	define i32 @test43(i32 %a, i32 %c, i32 %d) {
	; CHECK-LABEL: @test43(
	; CHECK-NEXT: [[FORCE:%.]] = mul i32 [[C:%.]], [[D:%.*]]
	; CHECK-NEXT: [[AND:%.]] = and i32 [[FORCE]], [[A:%.]]
	; CHECK-NEXT: ret i32 [[AND]]
	;
	%force = mul i32 %c, %d ; forces the complexity sorting
	%or = or i32 %a, %force
	%nota = xor i32 %a, -1
	%xor = xor i32 %nota, %force
	%and = and i32 %or, %xor
	ret i32 %and
	}

	; (~y \| x) & y -> x & y
	define i32 @test44(i32 %x, i32 %y) nounwind {
	; CHECK-LABEL: @test44(
	; CHECK-NEXT: [[A:%.]] = and i32 [[X:%.]], [[Y:%.*]]
	; CHECK-NEXT: ret i32 [[A]]
	;
	%n = xor i32 %y, -1
	%o = or i32 %n, %x
	%a = and i32 %o, %y
	ret i32 %a
	}

	; (x \| ~y) & y -> x & y
	define i32 @test45(i32 %x, i32 %y) nounwind {
	; CHECK-LABEL: @test45(
	; CHECK-NEXT: [[A:%.]] = and i32 [[X:%.]], [[Y:%.*]]
	; CHECK-NEXT: ret i32 [[A]]
	;
	%n = xor i32 %y, -1
	%o = or i32 %x, %n
	%a = and i32 %o, %y
	ret i32 %a
	}

	; y & (~y \| x) -> y \| x
	define i32 @test46(i32 %x, i32 %y) nounwind {
	; CHECK-LABEL: @test46(
	; CHECK-NEXT: [[A:%.]] = and i32 [[X:%.]], [[Y:%.*]]
	; CHECK-NEXT: ret i32 [[A]]
	;
	%n = xor i32 %y, -1
	%o = or i32 %n, %x
	%a = and i32 %y, %o
	ret i32 %a
	}

	; y & (x \| ~y) -> y \| x
	define i32 @test47(i32 %x, i32 %y) nounwind {
	; CHECK-LABEL: @test47(
	; CHECK-NEXT: [[A:%.]] = and i32 [[X:%.]], [[Y:%.*]]
	; CHECK-NEXT: ret i32 [[A]]
	;
	%n = xor i32 %y, -1
	%o = or i32 %x, %n
	%a = and i32 %y, %o
	ret i32 %a
	}

	; In the next 4 tests, vary the types and predicates for extra coverage.
	; (X & (Y \| ~X)) -> (X & Y), where 'not' is an inverted cmp

	define i1 @and_orn_cmp_1(i32 %a, i32 %b, i32 %c) {
	; CHECK-LABEL: @and_orn_cmp_1(
	; CHECK-NEXT: [[X:%.]] = icmp sgt i32 [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt i32 [[C:%.]], 42
	; CHECK-NEXT: [[AND:%.*]] = and i1 [[X]], [[Y]]
	; CHECK-NEXT: ret i1 [[AND]]
	;
	%x = icmp sgt i32 %a, %b
	%x_inv = icmp sle i32 %a, %b
	%y = icmp ugt i32 %c, 42 ; thwart complexity-based ordering
	%or = or i1 %y, %x_inv
	%and = and i1 %x, %or
	ret i1 %and
	}

	; Commute the 'and':
	; ((Y \| ~X) & X) -> (X & Y), where 'not' is an inverted cmp

	define <2 x i1> @and_orn_cmp_2(<2 x i32> %a, <2 x i32> %b, <2 x i32> %c) {
	; CHECK-LABEL: @and_orn_cmp_2(
	; CHECK-NEXT: [[X:%.]] = icmp sge <2 x i32> [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt <2 x i32> [[C:%.]], <i32 42, i32 47>
	; CHECK-NEXT: [[AND:%.*]] = and <2 x i1> [[Y]], [[X]]
	; CHECK-NEXT: ret <2 x i1> [[AND]]
	;
	%x = icmp sge <2 x i32> %a, %b
	%x_inv = icmp slt <2 x i32> %a, %b
	%y = icmp ugt <2 x i32> %c, <i32 42, i32 47> ; thwart complexity-based ordering
	%or = or <2 x i1> %y, %x_inv
	%and = and <2 x i1> %or, %x
	ret <2 x i1> %and
	}

	; Commute the 'or':
	; (X & (~X \| Y)) -> (X & Y), where 'not' is an inverted cmp

	define i1 @and_orn_cmp_3(i72 %a, i72 %b, i72 %c) {
	; CHECK-LABEL: @and_orn_cmp_3(
	; CHECK-NEXT: [[X:%.]] = icmp ugt i72 [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt i72 [[C:%.]], 42
	; CHECK-NEXT: [[AND:%.*]] = and i1 [[X]], [[Y]]
	; CHECK-NEXT: ret i1 [[AND]]
	;
	%x = icmp ugt i72 %a, %b
	%x_inv = icmp ule i72 %a, %b
	%y = icmp ugt i72 %c, 42 ; thwart complexity-based ordering
	%or = or i1 %x_inv, %y
	%and = and i1 %x, %or
	ret i1 %and
	}

	; Commute the 'and':
	; ((~X \| Y) & X) -> (X & Y), where 'not' is an inverted cmp

	define <3 x i1> @or_andn_cmp_4(<3 x i32> %a, <3 x i32> %b, <3 x i32> %c) {
	; CHECK-LABEL: @or_andn_cmp_4(
	; CHECK-NEXT: [[X:%.]] = icmp eq <3 x i32> [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt <3 x i32> [[C:%.]], <i32 42, i32 43, i32 -1>
	; CHECK-NEXT: [[AND:%.*]] = and <3 x i1> [[Y]], [[X]]
	; CHECK-NEXT: ret <3 x i1> [[AND]]
	;
	%x = icmp eq <3 x i32> %a, %b
	%x_inv = icmp ne <3 x i32> %a, %b
	%y = icmp ugt <3 x i32> %c, <i32 42, i32 43, i32 -1> ; thwart complexity-based ordering
	%or = or <3 x i1> %x_inv, %y
	%and = and <3 x i1> %or, %x
	ret <3 x i1> %and
	}

	; In the next 4 tests, vary the types and predicates for extra coverage.
	; (~X & (Y \| X)) -> (~X & Y), where 'not' is an inverted cmp

	define i1 @andn_or_cmp_1(i37 %a, i37 %b, i37 %c) {
	; CHECK-LABEL: @andn_or_cmp_1(
	; CHECK-NEXT: [[X_INV:%.]] = icmp sle i37 [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt i37 [[C:%.]], 42
	; CHECK-NEXT: [[AND:%.*]] = and i1 [[X_INV]], [[Y]]
	; CHECK-NEXT: ret i1 [[AND]]
	;
	%x = icmp sgt i37 %a, %b
	%x_inv = icmp sle i37 %a, %b
	%y = icmp ugt i37 %c, 42 ; thwart complexity-based ordering
	%or = or i1 %y, %x
	%and = and i1 %x_inv, %or
	ret i1 %and
	}

	; Commute the 'and':
	; ((Y \| X) & ~X) -> (~X & Y), where 'not' is an inverted cmp

	define i1 @andn_or_cmp_2(i16 %a, i16 %b, i16 %c) {
	; CHECK-LABEL: @andn_or_cmp_2(
	; CHECK-NEXT: [[X_INV:%.]] = icmp slt i16 [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt i16 [[C:%.]], 42
	; CHECK-NEXT: [[AND:%.*]] = and i1 [[Y]], [[X_INV]]
	; CHECK-NEXT: ret i1 [[AND]]
	;
	%x = icmp sge i16 %a, %b
	%x_inv = icmp slt i16 %a, %b
	%y = icmp ugt i16 %c, 42 ; thwart complexity-based ordering
	%or = or i1 %y, %x
	%and = and i1 %or, %x_inv
	ret i1 %and
	}

	; Commute the 'or':
	; (~X & (X \| Y)) -> (~X & Y), where 'not' is an inverted cmp

	define <4 x i1> @andn_or_cmp_3(<4 x i32> %a, <4 x i32> %b, <4 x i32> %c) {
	; CHECK-LABEL: @andn_or_cmp_3(
	; CHECK-NEXT: [[X_INV:%.]] = icmp ule <4 x i32> [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt <4 x i32> [[C:%.]], <i32 42, i32 0, i32 1, i32 -1>
	; CHECK-NEXT: [[AND:%.*]] = and <4 x i1> [[X_INV]], [[Y]]
	; CHECK-NEXT: ret <4 x i1> [[AND]]
	;
	%x = icmp ugt <4 x i32> %a, %b
	%x_inv = icmp ule <4 x i32> %a, %b
	%y = icmp ugt <4 x i32> %c, <i32 42, i32 0, i32 1, i32 -1> ; thwart complexity-based ordering
	%or = or <4 x i1> %x, %y
	%and = and <4 x i1> %x_inv, %or
	ret <4 x i1> %and
	}

	; Commute the 'and':
	; ((X \| Y) & ~X) -> (~X & Y), where 'not' is an inverted cmp

	define i1 @andn_or_cmp_4(i32 %a, i32 %b, i32 %c) {
	; CHECK-LABEL: @andn_or_cmp_4(
	; CHECK-NEXT: [[X_INV:%.]] = icmp ne i32 [[A:%.]], [[B:%.*]]
	; CHECK-NEXT: [[Y:%.]] = icmp ugt i32 [[C:%.]], 42
	; CHECK-NEXT: [[AND:%.*]] = and i1 [[Y]], [[X_INV]]
	; CHECK-NEXT: ret i1 [[AND]]
	;
	%x = icmp eq i32 %a, %b
	%x_inv = icmp ne i32 %a, %b
	%y = icmp ugt i32 %c, 42 ; thwart complexity-based ordering
	%or = or i1 %x, %y
	%and = and i1 %or, %x_inv
	ret i1 %and
	}