; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py ; RUN: llc < %s -mtriple=aarch64-- | FileCheck %s declare i8 @llvm.fshl.i8(i8, i8, i8) declare i16 @llvm.fshl.i16(i16, i16, i16) declare i32 @llvm.fshl.i32(i32, i32, i32) declare i64 @llvm.fshl.i64(i64, i64, i64) declare <4 x i32> @llvm.fshl.v4i32(<4 x i32>, <4 x i32>, <4 x i32>) declare i8 @llvm.fshr.i8(i8, i8, i8) declare i16 @llvm.fshr.i16(i16, i16, i16) declare i32 @llvm.fshr.i32(i32, i32, i32) declare i64 @llvm.fshr.i64(i64, i64, i64) declare <4 x i32> @llvm.fshr.v4i32(<4 x i32>, <4 x i32>, <4 x i32>) ; General case - all operands can be variables. define i32 @fshl_i32(i32 %x, i32 %y, i32 %z) { ; CHECK-LABEL: fshl_i32: ; CHECK: // %bb.0: ; CHECK-NEXT: and w9, w2, #0x1f ; CHECK-NEXT: neg w9, w9 ; CHECK-NEXT: lsl w8, w0, w2 ; CHECK-NEXT: lsr w9, w1, w9 ; CHECK-NEXT: orr w8, w8, w9 ; CHECK-NEXT: tst w2, #0x1f ; CHECK-NEXT: csel w0, w0, w8, eq ; CHECK-NEXT: ret %f = call i32 @llvm.fshl.i32(i32 %x, i32 %y, i32 %z) ret i32 %f } ; Verify that weird types are minimally supported. declare i37 @llvm.fshl.i37(i37, i37, i37) define i37 @fshl_i37(i37 %x, i37 %y, i37 %z) { ; CHECK-LABEL: fshl_i37: ; CHECK: // %bb.0: ; CHECK-NEXT: mov x10, #31883 ; CHECK-NEXT: movk x10, #3542, lsl #16 ; CHECK-NEXT: movk x10, #51366, lsl #32 ; CHECK-NEXT: and x9, x2, #0x1fffffffff ; CHECK-NEXT: movk x10, #56679, lsl #48 ; CHECK-NEXT: umulh x10, x9, x10 ; CHECK-NEXT: mov w11, #37 ; CHECK-NEXT: lsr x10, x10, #5 ; CHECK-NEXT: msub x9, x10, x11, x9 ; CHECK-NEXT: and x8, x1, #0x1fffffffff ; CHECK-NEXT: sub x11, x11, x9 ; CHECK-NEXT: lsl x10, x0, x9 ; CHECK-NEXT: lsr x8, x8, x11 ; CHECK-NEXT: orr x8, x10, x8 ; CHECK-NEXT: cmp x9, #0 // =0 ; CHECK-NEXT: csel x0, x0, x8, eq ; CHECK-NEXT: ret %f = call i37 @llvm.fshl.i37(i37 %x, i37 %y, i37 %z) ret i37 %f } ; extract(concat(0b1110000, 0b1111111) << 2) = 0b1000011 declare i7 @llvm.fshl.i7(i7, i7, i7) define i7 @fshl_i7_const_fold() { ; CHECK-LABEL: fshl_i7_const_fold: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #67 ; CHECK-NEXT: ret %f = call i7 @llvm.fshl.i7(i7 112, i7 127, i7 2) ret i7 %f } define i8 @fshl_i8_const_fold_overshift_1() { ; CHECK-LABEL: fshl_i8_const_fold_overshift_1: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #128 ; CHECK-NEXT: ret %f = call i8 @llvm.fshl.i8(i8 255, i8 0, i8 15) ret i8 %f } define i8 @fshl_i8_const_fold_overshift_2() { ; CHECK-LABEL: fshl_i8_const_fold_overshift_2: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #120 ; CHECK-NEXT: ret %f = call i8 @llvm.fshl.i8(i8 15, i8 15, i8 11) ret i8 %f } define i8 @fshl_i8_const_fold_overshift_3() { ; CHECK-LABEL: fshl_i8_const_fold_overshift_3: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, wzr ; CHECK-NEXT: ret %f = call i8 @llvm.fshl.i8(i8 0, i8 225, i8 8) ret i8 %f } ; With constant shift amount, this is 'extr'. define i32 @fshl_i32_const_shift(i32 %x, i32 %y) { ; CHECK-LABEL: fshl_i32_const_shift: ; CHECK: // %bb.0: ; CHECK-NEXT: extr w0, w0, w1, #23 ; CHECK-NEXT: ret %f = call i32 @llvm.fshl.i32(i32 %x, i32 %y, i32 9) ret i32 %f } ; Check modulo math on shift amount. define i32 @fshl_i32_const_overshift(i32 %x, i32 %y) { ; CHECK-LABEL: fshl_i32_const_overshift: ; CHECK: // %bb.0: ; CHECK-NEXT: extr w0, w0, w1, #23 ; CHECK-NEXT: ret %f = call i32 @llvm.fshl.i32(i32 %x, i32 %y, i32 41) ret i32 %f } ; 64-bit should also work. define i64 @fshl_i64_const_overshift(i64 %x, i64 %y) { ; CHECK-LABEL: fshl_i64_const_overshift: ; CHECK: // %bb.0: ; CHECK-NEXT: extr x0, x0, x1, #23 ; CHECK-NEXT: ret %f = call i64 @llvm.fshl.i64(i64 %x, i64 %y, i64 105) ret i64 %f } ; This should work without any node-specific logic. define i8 @fshl_i8_const_fold() { ; CHECK-LABEL: fshl_i8_const_fold: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #128 ; CHECK-NEXT: ret %f = call i8 @llvm.fshl.i8(i8 255, i8 0, i8 7) ret i8 %f } ; Repeat everything for funnel shift right. ; General case - all operands can be variables. define i32 @fshr_i32(i32 %x, i32 %y, i32 %z) { ; CHECK-LABEL: fshr_i32: ; CHECK: // %bb.0: ; CHECK-NEXT: and w9, w2, #0x1f ; CHECK-NEXT: neg w9, w9 ; CHECK-NEXT: lsr w8, w1, w2 ; CHECK-NEXT: lsl w9, w0, w9 ; CHECK-NEXT: orr w8, w9, w8 ; CHECK-NEXT: tst w2, #0x1f ; CHECK-NEXT: csel w0, w1, w8, eq ; CHECK-NEXT: ret %f = call i32 @llvm.fshr.i32(i32 %x, i32 %y, i32 %z) ret i32 %f } ; Verify that weird types are minimally supported. declare i37 @llvm.fshr.i37(i37, i37, i37) define i37 @fshr_i37(i37 %x, i37 %y, i37 %z) { ; CHECK-LABEL: fshr_i37: ; CHECK: // %bb.0: ; CHECK-NEXT: mov x10, #31883 ; CHECK-NEXT: movk x10, #3542, lsl #16 ; CHECK-NEXT: movk x10, #51366, lsl #32 ; CHECK-NEXT: and x9, x2, #0x1fffffffff ; CHECK-NEXT: movk x10, #56679, lsl #48 ; CHECK-NEXT: umulh x10, x9, x10 ; CHECK-NEXT: mov w11, #37 ; CHECK-NEXT: lsr x10, x10, #5 ; CHECK-NEXT: msub x9, x10, x11, x9 ; CHECK-NEXT: and x8, x1, #0x1fffffffff ; CHECK-NEXT: sub x10, x11, x9 ; CHECK-NEXT: lsr x8, x8, x9 ; CHECK-NEXT: lsl x10, x0, x10 ; CHECK-NEXT: orr x8, x10, x8 ; CHECK-NEXT: cmp x9, #0 // =0 ; CHECK-NEXT: csel x0, x1, x8, eq ; CHECK-NEXT: ret %f = call i37 @llvm.fshr.i37(i37 %x, i37 %y, i37 %z) ret i37 %f } ; extract(concat(0b1110000, 0b1111111) >> 2) = 0b0011111 declare i7 @llvm.fshr.i7(i7, i7, i7) define i7 @fshr_i7_const_fold() { ; CHECK-LABEL: fshr_i7_const_fold: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #31 ; CHECK-NEXT: ret %f = call i7 @llvm.fshr.i7(i7 112, i7 127, i7 2) ret i7 %f } define i8 @fshr_i8_const_fold_overshift_1() { ; CHECK-LABEL: fshr_i8_const_fold_overshift_1: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #254 ; CHECK-NEXT: ret %f = call i8 @llvm.fshr.i8(i8 255, i8 0, i8 15) ret i8 %f } define i8 @fshr_i8_const_fold_overshift_2() { ; CHECK-LABEL: fshr_i8_const_fold_overshift_2: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #225 ; CHECK-NEXT: ret %f = call i8 @llvm.fshr.i8(i8 15, i8 15, i8 11) ret i8 %f } define i8 @fshr_i8_const_fold_overshift_3() { ; CHECK-LABEL: fshr_i8_const_fold_overshift_3: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #255 ; CHECK-NEXT: ret %f = call i8 @llvm.fshr.i8(i8 0, i8 255, i8 8) ret i8 %f } ; With constant shift amount, this is 'extr'. define i32 @fshr_i32_const_shift(i32 %x, i32 %y) { ; CHECK-LABEL: fshr_i32_const_shift: ; CHECK: // %bb.0: ; CHECK-NEXT: extr w0, w0, w1, #9 ; CHECK-NEXT: ret %f = call i32 @llvm.fshr.i32(i32 %x, i32 %y, i32 9) ret i32 %f } ; Check modulo math on shift amount. 41-32=9. define i32 @fshr_i32_const_overshift(i32 %x, i32 %y) { ; CHECK-LABEL: fshr_i32_const_overshift: ; CHECK: // %bb.0: ; CHECK-NEXT: extr w0, w0, w1, #9 ; CHECK-NEXT: ret %f = call i32 @llvm.fshr.i32(i32 %x, i32 %y, i32 41) ret i32 %f } ; 64-bit should also work. 105-64 = 41. define i64 @fshr_i64_const_overshift(i64 %x, i64 %y) { ; CHECK-LABEL: fshr_i64_const_overshift: ; CHECK: // %bb.0: ; CHECK-NEXT: extr x0, x0, x1, #41 ; CHECK-NEXT: ret %f = call i64 @llvm.fshr.i64(i64 %x, i64 %y, i64 105) ret i64 %f } ; This should work without any node-specific logic. define i8 @fshr_i8_const_fold() { ; CHECK-LABEL: fshr_i8_const_fold: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, #254 ; CHECK-NEXT: ret %f = call i8 @llvm.fshr.i8(i8 255, i8 0, i8 7) ret i8 %f } define i32 @fshl_i32_shift_by_bitwidth(i32 %x, i32 %y) { ; CHECK-LABEL: fshl_i32_shift_by_bitwidth: ; CHECK: // %bb.0: ; CHECK-NEXT: ret %f = call i32 @llvm.fshl.i32(i32 %x, i32 %y, i32 32) ret i32 %f } define i32 @fshr_i32_shift_by_bitwidth(i32 %x, i32 %y) { ; CHECK-LABEL: fshr_i32_shift_by_bitwidth: ; CHECK: // %bb.0: ; CHECK-NEXT: mov w0, w1 ; CHECK-NEXT: ret %f = call i32 @llvm.fshr.i32(i32 %x, i32 %y, i32 32) ret i32 %f } define <4 x i32> @fshl_v4i32_shift_by_bitwidth(<4 x i32> %x, <4 x i32> %y) { ; CHECK-LABEL: fshl_v4i32_shift_by_bitwidth: ; CHECK: // %bb.0: ; CHECK-NEXT: ret %f = call <4 x i32> @llvm.fshl.v4i32(<4 x i32> %x, <4 x i32> %y, <4 x i32> ) ret <4 x i32> %f } define <4 x i32> @fshr_v4i32_shift_by_bitwidth(<4 x i32> %x, <4 x i32> %y) { ; CHECK-LABEL: fshr_v4i32_shift_by_bitwidth: ; CHECK: // %bb.0: ; CHECK-NEXT: mov v0.16b, v1.16b ; CHECK-NEXT: ret %f = call <4 x i32> @llvm.fshr.v4i32(<4 x i32> %x, <4 x i32> %y, <4 x i32> ) ret <4 x i32> %f }