1; Test 64-bit inequality comparisons in which the second operand is a constant. 2; 3; RUN: llc < %s -mtriple=s390x-linux-gnu | FileCheck %s 4 5; Check comparisons with 0. 6define double @f1(double %a, double %b, i64 %i1) { 7; CHECK-LABEL: f1: 8; CHECK: cgijlh %r2, 0 9; CHECK: ldr %f0, %f2 10; CHECK: br %r14 11 %cond = icmp ne i64 %i1, 0 12 %tmp = select i1 %cond, double %a, double %b 13 %res = fadd double %tmp, 1.0 14 ret double %res 15} 16 17; Check the high end of the CGIJ range. 18define double @f2(double %a, double %b, i64 %i1) { 19; CHECK-LABEL: f2: 20; CHECK: cgijlh %r2, 127 21; CHECK: ldr %f0, %f2 22; CHECK: br %r14 23 %cond = icmp ne i64 %i1, 127 24 %tmp = select i1 %cond, double %a, double %b 25 %res = fadd double %tmp, 1.0 26 ret double %res 27} 28 29; Check the next value up, which must use CGHI instead. 30define double @f3(double %a, double %b, i64 %i1) { 31; CHECK-LABEL: f3: 32; CHECK: cghi %r2, 128 33; CHECK-NEXT: jlh 34; CHECK: ldr %f0, %f2 35; CHECK: br %r14 36 %cond = icmp ne i64 %i1, 128 37 %tmp = select i1 %cond, double %a, double %b 38 %res = fadd double %tmp, 1.0 39 ret double %res 40} 41 42; Check the high end of the CGHI range. 43define double @f4(double %a, double %b, i64 %i1) { 44; CHECK-LABEL: f4: 45; CHECK: cghi %r2, 32767 46; CHECK-NEXT: jlh 47; CHECK: ldr %f0, %f2 48; CHECK: br %r14 49 %cond = icmp ne i64 %i1, 32767 50 %tmp = select i1 %cond, double %a, double %b 51 %res = fadd double %tmp, 1.0 52 ret double %res 53} 54 55; Check the next value up, which must use CGFI. 56define double @f5(double %a, double %b, i64 %i1) { 57; CHECK-LABEL: f5: 58; CHECK: cgfi %r2, 32768 59; CHECK-NEXT: jlh 60; CHECK: ldr %f0, %f2 61; CHECK: br %r14 62 %cond = icmp ne i64 %i1, 32768 63 %tmp = select i1 %cond, double %a, double %b 64 %res = fadd double %tmp, 1.0 65 ret double %res 66} 67 68; Check the high end of the CGFI range. 69define double @f6(double %a, double %b, i64 %i1) { 70; CHECK-LABEL: f6: 71; CHECK: cgfi %r2, 2147483647 72; CHECK-NEXT: jlh 73; CHECK: ldr %f0, %f2 74; CHECK: br %r14 75 %cond = icmp ne i64 %i1, 2147483647 76 %tmp = select i1 %cond, double %a, double %b 77 %res = fadd double %tmp, 1.0 78 ret double %res 79} 80 81; Check the next value up, which should use CLGFI instead. 82define double @f7(double %a, double %b, i64 %i1) { 83; CHECK-LABEL: f7: 84; CHECK: clgfi %r2, 2147483648 85; CHECK-NEXT: jlh 86; CHECK: ldr %f0, %f2 87; CHECK: br %r14 88 %cond = icmp ne i64 %i1, 2147483648 89 %tmp = select i1 %cond, double %a, double %b 90 %res = fadd double %tmp, 1.0 91 ret double %res 92} 93 94; Check the high end of the CLGFI range. 95define double @f8(double %a, double %b, i64 %i1) { 96; CHECK-LABEL: f8: 97; CHECK: clgfi %r2, 4294967295 98; CHECK-NEXT: jlh 99; CHECK: ldr %f0, %f2 100; CHECK: br %r14 101 %cond = icmp ne i64 %i1, 4294967295 102 %tmp = select i1 %cond, double %a, double %b 103 %res = fadd double %tmp, 1.0 104 ret double %res 105} 106 107; Check the next value up, which must use a register comparison. 108define double @f9(double %a, double %b, i64 %i1) { 109; CHECK-LABEL: f9: 110; CHECK: cgrjlh %r2, 111; CHECK: ldr %f0, %f2 112; CHECK: br %r14 113 %cond = icmp ne i64 %i1, 4294967296 114 %tmp = select i1 %cond, double %a, double %b 115 %res = fadd double %tmp, 1.0 116 ret double %res 117} 118 119; Check the high end of the negative CGIJ range. 120define double @f10(double %a, double %b, i64 %i1) { 121; CHECK-LABEL: f10: 122; CHECK: cgijlh %r2, -1 123; CHECK: ldr %f0, %f2 124; CHECK: br %r14 125 %cond = icmp ne i64 %i1, -1 126 %tmp = select i1 %cond, double %a, double %b 127 %res = fadd double %tmp, 1.0 128 ret double %res 129} 130 131; Check the low end of the CGIJ range. 132define double @f11(double %a, double %b, i64 %i1) { 133; CHECK-LABEL: f11: 134; CHECK: cgijlh %r2, -128 135; CHECK: ldr %f0, %f2 136; CHECK: br %r14 137 %cond = icmp ne i64 %i1, -128 138 %tmp = select i1 %cond, double %a, double %b 139 %res = fadd double %tmp, 1.0 140 ret double %res 141} 142 143; Check the next value down, which must use CGHI instead. 144define double @f12(double %a, double %b, i64 %i1) { 145; CHECK-LABEL: f12: 146; CHECK: cghi %r2, -129 147; CHECK-NEXT: jlh 148; CHECK: ldr %f0, %f2 149; CHECK: br %r14 150 %cond = icmp ne i64 %i1, -129 151 %tmp = select i1 %cond, double %a, double %b 152 %res = fadd double %tmp, 1.0 153 ret double %res 154} 155 156; Check the low end of the CGHI range. 157define double @f13(double %a, double %b, i64 %i1) { 158; CHECK-LABEL: f13: 159; CHECK: cghi %r2, -32768 160; CHECK-NEXT: jlh 161; CHECK: ldr %f0, %f2 162; CHECK: br %r14 163 %cond = icmp ne i64 %i1, -32768 164 %tmp = select i1 %cond, double %a, double %b 165 %res = fadd double %tmp, 1.0 166 ret double %res 167} 168 169; Check the next value down, which must use CGFI instead. 170define double @f14(double %a, double %b, i64 %i1) { 171; CHECK-LABEL: f14: 172; CHECK: cgfi %r2, -32769 173; CHECK-NEXT: jlh 174; CHECK: ldr %f0, %f2 175; CHECK: br %r14 176 %cond = icmp ne i64 %i1, -32769 177 %tmp = select i1 %cond, double %a, double %b 178 %res = fadd double %tmp, 1.0 179 ret double %res 180} 181 182; Check the low end of the CGFI range. 183define double @f15(double %a, double %b, i64 %i1) { 184; CHECK-LABEL: f15: 185; CHECK: cgfi %r2, -2147483648 186; CHECK-NEXT: jlh 187; CHECK: ldr %f0, %f2 188; CHECK: br %r14 189 %cond = icmp ne i64 %i1, -2147483648 190 %tmp = select i1 %cond, double %a, double %b 191 %res = fadd double %tmp, 1.0 192 ret double %res 193} 194 195; Check the next value down, which must use register comparison. 196define double @f16(double %a, double %b, i64 %i1) { 197; CHECK-LABEL: f16: 198; CHECK: cgrjlh 199; CHECK: ldr %f0, %f2 200; CHECK: br %r14 201 %cond = icmp ne i64 %i1, -2147483649 202 %tmp = select i1 %cond, double %a, double %b 203 %res = fadd double %tmp, 1.0 204 ret double %res 205} 206