; Test insertions of 32-bit constants into one half of an i64. ; ; RUN: llc < %s -mtriple=s390x-linux-gnu | FileCheck %s ; Prefer LHI over IILF for signed 16-bit constants. define i64 @f1(i64 %a) { ; CHECK-LABEL: f1: ; CHECK-NOT: ni ; CHECK: lhi %r2, 1 ; CHECK: br %r14 %and = and i64 %a, 18446744069414584320 %or = or i64 %and, 1 ret i64 %or } ; Check the high end of the LHI range. define i64 @f2(i64 %a) { ; CHECK-LABEL: f2: ; CHECK-NOT: ni ; CHECK: lhi %r2, 32767 ; CHECK: br %r14 %and = and i64 %a, 18446744069414584320 %or = or i64 %and, 32767 ret i64 %or } ; Check the next value up, which should use IILF instead. define i64 @f3(i64 %a) { ; CHECK-LABEL: f3: ; CHECK-NOT: ni ; CHECK: iilf %r2, 32768 ; CHECK: br %r14 %and = and i64 %a, 18446744069414584320 %or = or i64 %and, 32768 ret i64 %or } ; Check a value in which the lower 16 bits are clear. define i64 @f4(i64 %a) { ; CHECK-LABEL: f4: ; CHECK-NOT: ni ; CHECK: iilf %r2, 65536 ; CHECK: br %r14 %and = and i64 %a, 18446744069414584320 %or = or i64 %and, 65536 ret i64 %or } ; Check the highest useful IILF value (-0x8001). define i64 @f5(i64 %a) { ; CHECK-LABEL: f5: ; CHECK-NOT: ni ; CHECK: iilf %r2, 4294934527 ; CHECK: br %r14 %and = and i64 %a, 18446744069414584320 %or = or i64 %and, 4294934527 ret i64 %or } ; Check the next value up, which should use LHI instead. define i64 @f6(i64 %a) { ; CHECK-LABEL: f6: ; CHECK-NOT: ni ; CHECK: lhi %r2, -32768 ; CHECK: br %r14 %and = and i64 %a, 18446744069414584320 %or = or i64 %and, 4294934528 ret i64 %or } ; Check the highest useful LHI value. (We use OILF for -1 instead, although ; LHI might be better there too.) define i64 @f7(i64 %a) { ; CHECK-LABEL: f7: ; CHECK-NOT: ni ; CHECK: lhi %r2, -2 ; CHECK: br %r14 %and = and i64 %a, 18446744069414584320 %or = or i64 %and, 4294967294 ret i64 %or } ; Check that SRLG is still used if some of the high bits are known to be 0 ; (and so might be removed from the mask). define i64 @f8(i64 %a) { ; CHECK-LABEL: f8: ; CHECK: srlg %r2, %r2, 1 ; CHECK-NEXT: iilf %r2, 32768 ; CHECK: br %r14 %shifted = lshr i64 %a, 1 %and = and i64 %shifted, 18446744069414584320 %or = or i64 %and, 32768 ret i64 %or } ; Repeat f8 with addition, which is known to be equivalent to OR in this case. define i64 @f9(i64 %a) { ; CHECK-LABEL: f9: ; CHECK: srlg %r2, %r2, 1 ; CHECK-NEXT: iilf %r2, 32768 ; CHECK: br %r14 %shifted = lshr i64 %a, 1 %and = and i64 %shifted, 18446744069414584320 %or = add i64 %and, 32768 ret i64 %or } ; Repeat f8 with already-zero bits removed from the mask. define i64 @f10(i64 %a) { ; CHECK-LABEL: f10: ; CHECK: srlg %r2, %r2, 1 ; CHECK-NEXT: iilf %r2, 32768 ; CHECK: br %r14 %shifted = lshr i64 %a, 1 %and = and i64 %shifted, 9223372032559808512 %or = or i64 %and, 32768 ret i64 %or } ; Repeat f10 with addition, which is known to be equivalent to OR in this case. define i64 @f11(i64 %a) { ; CHECK-LABEL: f11: ; CHECK: srlg %r2, %r2, 1 ; CHECK-NEXT: iilf %r2, 32768 ; CHECK: br %r14 %shifted = lshr i64 %a, 1 %and = and i64 %shifted, 9223372032559808512 %or = add i64 %and, 32768 ret i64 %or } ; Check the lowest useful IIHF value. define i64 @f12(i64 %a) { ; CHECK-LABEL: f12: ; CHECK-NOT: ni ; CHECK: iihf %r2, 1 ; CHECK: br %r14 %and = and i64 %a, 4294967295 %or = or i64 %and, 4294967296 ret i64 %or } ; Check a value in which the lower 16 bits are clear. define i64 @f13(i64 %a) { ; CHECK-LABEL: f13: ; CHECK-NOT: ni ; CHECK: iihf %r2, 2147483648 ; CHECK: br %r14 %and = and i64 %a, 4294967295 %or = or i64 %and, 9223372036854775808 ret i64 %or } ; Check the highest useful IIHF value (0xfffffffe). define i64 @f14(i64 %a) { ; CHECK-LABEL: f14: ; CHECK-NOT: ni ; CHECK: iihf %r2, 4294967294 ; CHECK: br %r14 %and = and i64 %a, 4294967295 %or = or i64 %and, 18446744065119617024 ret i64 %or } ; Check a case in which some of the low 32 bits are known to be clear, ; and so could be removed from the AND mask. define i64 @f15(i64 %a) { ; CHECK-LABEL: f15: ; CHECK: sllg %r2, %r2, 1 ; CHECK-NEXT: iihf %r2, 1 ; CHECK: br %r14 %shifted = shl i64 %a, 1 %and = and i64 %shifted, 4294967295 %or = or i64 %and, 4294967296 ret i64 %or } ; Repeat f15 with the zero bits explicitly removed from the mask. define i64 @f16(i64 %a) { ; CHECK-LABEL: f16: ; CHECK: sllg %r2, %r2, 1 ; CHECK-NEXT: iihf %r2, 1 ; CHECK: br %r14 %shifted = shl i64 %a, 1 %and = and i64 %shifted, 4294967294 %or = or i64 %and, 4294967296 ret i64 %or } ; Check concatenation of two i32s. define i64 @f17(i32 %a) { ; CHECK-LABEL: f17: ; CHECK: msr %r2, %r2 ; CHECK-NEXT: iihf %r2, 1 ; CHECK: br %r14 %mul = mul i32 %a, %a %ext = zext i32 %mul to i64 %or = or i64 %ext, 4294967296 ret i64 %or } ; Repeat f17 with the operands reversed. define i64 @f18(i32 %a) { ; CHECK-LABEL: f18: ; CHECK: msr %r2, %r2 ; CHECK-NEXT: iihf %r2, 1 ; CHECK: br %r14 %mul = mul i32 %a, %a %ext = zext i32 %mul to i64 %or = or i64 4294967296, %ext ret i64 %or } ; The truncation here isn't free; we need an explicit zero extension. define i64 @f19(i32 %a) { ; CHECK-LABEL: f19: ; CHECK: llcr %r2, %r2 ; CHECK: iihf %r2, 1 ; CHECK: br %r14 %trunc = trunc i32 %a to i8 %ext = zext i8 %trunc to i64 %or = or i64 %ext, 4294967296 ret i64 %or }