; NOTE: Assertions have been autogenerated by utils/update_test_checks.py ; RUN: opt < %s -passes=instsimplify -S | FileCheck %s define i32 @zero_dividend(i32 %A) { ; CHECK-LABEL: @zero_dividend( ; CHECK-NEXT: ret i32 0 ; %B = sdiv i32 0, %A ret i32 %B } define <2 x i32> @zero_dividend_vector(<2 x i32> %A) { ; CHECK-LABEL: @zero_dividend_vector( ; CHECK-NEXT: ret <2 x i32> zeroinitializer ; %B = udiv <2 x i32> zeroinitializer, %A ret <2 x i32> %B } define <2 x i32> @zero_dividend_vector_undef_elt(<2 x i32> %A) { ; CHECK-LABEL: @zero_dividend_vector_undef_elt( ; CHECK-NEXT: ret <2 x i32> zeroinitializer ; %B = sdiv <2 x i32> , %A ret <2 x i32> %B } ; Division-by-zero is poison. UB in any vector lane means the whole op is poison. define <2 x i8> @sdiv_zero_elt_vec_constfold(<2 x i8> %x) { ; CHECK-LABEL: @sdiv_zero_elt_vec_constfold( ; CHECK-NEXT: ret <2 x i8> poison ; %div = sdiv <2 x i8> , ret <2 x i8> %div } define <2 x i8> @udiv_zero_elt_vec_constfold(<2 x i8> %x) { ; CHECK-LABEL: @udiv_zero_elt_vec_constfold( ; CHECK-NEXT: ret <2 x i8> poison ; %div = udiv <2 x i8> , ret <2 x i8> %div } define <2 x i8> @sdiv_zero_elt_vec(<2 x i8> %x) { ; CHECK-LABEL: @sdiv_zero_elt_vec( ; CHECK-NEXT: ret <2 x i8> poison ; %div = sdiv <2 x i8> %x, ret <2 x i8> %div } define <2 x i8> @udiv_zero_elt_vec(<2 x i8> %x) { ; CHECK-LABEL: @udiv_zero_elt_vec( ; CHECK-NEXT: ret <2 x i8> poison ; %div = udiv <2 x i8> %x, ret <2 x i8> %div } define <2 x i8> @sdiv_undef_elt_vec(<2 x i8> %x) { ; CHECK-LABEL: @sdiv_undef_elt_vec( ; CHECK-NEXT: ret <2 x i8> poison ; %div = sdiv <2 x i8> %x, ret <2 x i8> %div } define <2 x i8> @udiv_undef_elt_vec(<2 x i8> %x) { ; CHECK-LABEL: @udiv_undef_elt_vec( ; CHECK-NEXT: ret <2 x i8> poison ; %div = udiv <2 x i8> %x, ret <2 x i8> %div } ; Division-by-zero is undef. UB in any vector lane means the whole op is undef. ; Thus, we can simplify this: if any element of 'y' is 0, we can do anything. ; Therefore, assume that all elements of 'y' must be 1. define <2 x i1> @sdiv_bool_vec(<2 x i1> %x, <2 x i1> %y) { ; CHECK-LABEL: @sdiv_bool_vec( ; CHECK-NEXT: ret <2 x i1> [[X:%.*]] ; %div = sdiv <2 x i1> %x, %y ret <2 x i1> %div } define <2 x i1> @udiv_bool_vec(<2 x i1> %x, <2 x i1> %y) { ; CHECK-LABEL: @udiv_bool_vec( ; CHECK-NEXT: ret <2 x i1> [[X:%.*]] ; %div = udiv <2 x i1> %x, %y ret <2 x i1> %div } define i32 @zext_bool_udiv_divisor(i1 %x, i32 %y) { ; CHECK-LABEL: @zext_bool_udiv_divisor( ; CHECK-NEXT: ret i32 [[Y:%.*]] ; %ext = zext i1 %x to i32 %r = udiv i32 %y, %ext ret i32 %r } define <2 x i32> @zext_bool_sdiv_divisor_vec(<2 x i1> %x, <2 x i32> %y) { ; CHECK-LABEL: @zext_bool_sdiv_divisor_vec( ; CHECK-NEXT: ret <2 x i32> [[Y:%.*]] ; %ext = zext <2 x i1> %x to <2 x i32> %r = sdiv <2 x i32> %y, %ext ret <2 x i32> %r } define i32 @udiv_dividend_known_smaller_than_constant_divisor(i32 %x) { ; CHECK-LABEL: @udiv_dividend_known_smaller_than_constant_divisor( ; CHECK-NEXT: ret i32 0 ; %and = and i32 %x, 250 %div = udiv i32 %and, 251 ret i32 %div } define i32 @not_udiv_dividend_known_smaller_than_constant_divisor(i32 %x) { ; CHECK-LABEL: @not_udiv_dividend_known_smaller_than_constant_divisor( ; CHECK-NEXT: [[AND:%.*]] = and i32 [[X:%.*]], 251 ; CHECK-NEXT: [[DIV:%.*]] = udiv i32 [[AND]], 251 ; CHECK-NEXT: ret i32 [[DIV]] ; %and = and i32 %x, 251 %div = udiv i32 %and, 251 ret i32 %div } define i32 @udiv_constant_dividend_known_smaller_than_divisor(i32 %x) { ; CHECK-LABEL: @udiv_constant_dividend_known_smaller_than_divisor( ; CHECK-NEXT: ret i32 0 ; %or = or i32 %x, 251 %div = udiv i32 250, %or ret i32 %div } define i32 @not_udiv_constant_dividend_known_smaller_than_divisor(i32 %x) { ; CHECK-LABEL: @not_udiv_constant_dividend_known_smaller_than_divisor( ; CHECK-NEXT: [[OR:%.*]] = or i32 [[X:%.*]], 251 ; CHECK-NEXT: [[DIV:%.*]] = udiv i32 251, [[OR]] ; CHECK-NEXT: ret i32 [[DIV]] ; %or = or i32 %x, 251 %div = udiv i32 251, %or ret i32 %div } define i8 @udiv_dividend_known_smaller_than_constant_divisor2(i1 %b) { ; CHECK-LABEL: @udiv_dividend_known_smaller_than_constant_divisor2( ; CHECK-NEXT: ret i8 0 ; %t0 = zext i1 %b to i8 %xor = xor i8 %t0, 12 %r = udiv i8 %xor, 14 ret i8 %r } ; negative test - dividend can equal 13 define i8 @not_udiv_dividend_known_smaller_than_constant_divisor2(i1 %b) { ; CHECK-LABEL: @not_udiv_dividend_known_smaller_than_constant_divisor2( ; CHECK-NEXT: [[T0:%.*]] = zext i1 [[B:%.*]] to i8 ; CHECK-NEXT: [[XOR:%.*]] = xor i8 [[T0]], 12 ; CHECK-NEXT: [[R:%.*]] = udiv i8 [[XOR]], 13 ; CHECK-NEXT: ret i8 [[R]] ; %t0 = zext i1 %b to i8 %xor = xor i8 %t0, 12 %r = udiv i8 %xor, 13 ret i8 %r } ; This would require computing known bits on both x and y. Is it worth doing? define i32 @udiv_dividend_known_smaller_than_divisor(i32 %x, i32 %y) { ; CHECK-LABEL: @udiv_dividend_known_smaller_than_divisor( ; CHECK-NEXT: [[AND:%.*]] = and i32 [[X:%.*]], 250 ; CHECK-NEXT: [[OR:%.*]] = or i32 [[Y:%.*]], 251 ; CHECK-NEXT: [[DIV:%.*]] = udiv i32 [[AND]], [[OR]] ; CHECK-NEXT: ret i32 [[DIV]] ; %and = and i32 %x, 250 %or = or i32 %y, 251 %div = udiv i32 %and, %or ret i32 %div } define i32 @not_udiv_dividend_known_smaller_than_divisor(i32 %x, i32 %y) { ; CHECK-LABEL: @not_udiv_dividend_known_smaller_than_divisor( ; CHECK-NEXT: [[AND:%.*]] = and i32 [[X:%.*]], 251 ; CHECK-NEXT: [[OR:%.*]] = or i32 [[Y:%.*]], 251 ; CHECK-NEXT: [[DIV:%.*]] = udiv i32 [[AND]], [[OR]] ; CHECK-NEXT: ret i32 [[DIV]] ; %and = and i32 %x, 251 %or = or i32 %y, 251 %div = udiv i32 %and, %or ret i32 %div } declare i32 @external() define i32 @div1() { ; CHECK-LABEL: @div1( ; CHECK-NEXT: [[CALL:%.*]] = call i32 @external(), !range [[RNG0:![0-9]+]] ; CHECK-NEXT: ret i32 0 ; %call = call i32 @external(), !range !0 %urem = udiv i32 %call, 3 ret i32 %urem } define i8 @sdiv_minusone_divisor() { ; CHECK-LABEL: @sdiv_minusone_divisor( ; CHECK-NEXT: ret i8 poison ; %v = sdiv i8 -128, -1 ret i8 %v } @g = external global i64 @g2 = external global i64 define i64 @const_sdiv_one() { ; CHECK-LABEL: @const_sdiv_one( ; CHECK-NEXT: ret i64 ptrtoint (ptr @g to i64) ; %div = sdiv i64 ptrtoint (ptr @g to i64), 1 ret i64 %div } define i64 @const_srem_one() { ; CHECK-LABEL: @const_srem_one( ; CHECK-NEXT: ret i64 0 ; %rem = srem i64 ptrtoint (ptr @g to i64), 1 ret i64 %rem } define i64 @const_udiv_one() { ; CHECK-LABEL: @const_udiv_one( ; CHECK-NEXT: ret i64 ptrtoint (ptr @g to i64) ; %div = udiv i64 ptrtoint (ptr @g to i64), 1 ret i64 %div } define i64 @const_urem_one() { ; CHECK-LABEL: @const_urem_one( ; CHECK-NEXT: ret i64 0 ; %rem = urem i64 ptrtoint (ptr @g to i64), 1 ret i64 %rem } define i64 @const_sdiv_zero() { ; CHECK-LABEL: @const_sdiv_zero( ; CHECK-NEXT: ret i64 0 ; %div = sdiv i64 0, ptrtoint (ptr @g to i64) ret i64 %div } define i64 @const_srem_zero() { ; CHECK-LABEL: @const_srem_zero( ; CHECK-NEXT: ret i64 0 ; %rem = srem i64 0, ptrtoint (ptr @g to i64) ret i64 %rem } define i64 @const_udiv_zero() { ; CHECK-LABEL: @const_udiv_zero( ; CHECK-NEXT: ret i64 0 ; %div = udiv i64 0, ptrtoint (ptr @g to i64) ret i64 %div } define i64 @const_urem_zero() { ; CHECK-LABEL: @const_urem_zero( ; CHECK-NEXT: ret i64 0 ; %rem = urem i64 0, ptrtoint (ptr @g to i64) ret i64 %rem } define i64 @const_sdiv_zero_negone() { ; CHECK-LABEL: @const_sdiv_zero_negone( ; CHECK-NEXT: ret i64 0 ; %div = sdiv i64 0, -1 ret i64 %div } define i1 @const_sdiv_i1() { ; CHECK-LABEL: @const_sdiv_i1( ; CHECK-NEXT: ret i1 ptrtoint (ptr @g to i1) ; %div = sdiv i1 ptrtoint (ptr @g to i1), ptrtoint (ptr @g2 to i1) ret i1 %div } define i1 @const_srem_1() { ; CHECK-LABEL: @const_srem_1( ; CHECK-NEXT: ret i1 false ; %rem = srem i1 ptrtoint (ptr @g to i1), ptrtoint (ptr @g2 to i1) ret i1 %rem } define i1 @const_udiv_i1() { ; CHECK-LABEL: @const_udiv_i1( ; CHECK-NEXT: ret i1 ptrtoint (ptr @g to i1) ; %div = udiv i1 ptrtoint (ptr @g to i1), ptrtoint (ptr @g2 to i1) ret i1 %div } define i1 @const_urem_1() { ; CHECK-LABEL: @const_urem_1( ; CHECK-NEXT: ret i1 false ; %rem = urem i1 ptrtoint (ptr @g to i1), ptrtoint (ptr @g2 to i1) ret i1 %rem } ; Can't divide evenly, so create poison. define i8 @sdiv_exact_trailing_zeros(i8 %x) { ; CHECK-LABEL: @sdiv_exact_trailing_zeros( ; CHECK-NEXT: ret i8 poison ; %o = or i8 %x, 1 ; odd number %r = sdiv exact i8 %o, -42 ; can't divide exactly ret i8 %r } ; Negative test - could divide evenly. define i8 @sdiv_exact_trailing_zeros_eq(i8 %x) { ; CHECK-LABEL: @sdiv_exact_trailing_zeros_eq( ; CHECK-NEXT: [[O:%.*]] = or i8 [[X:%.*]], 2 ; CHECK-NEXT: [[R:%.*]] = sdiv exact i8 [[O]], -42 ; CHECK-NEXT: ret i8 [[R]] ; %o = or i8 %x, 2 %r = sdiv exact i8 %o, -42 ret i8 %r } ; Negative test - must be exact div. define i8 @sdiv_trailing_zeros(i8 %x) { ; CHECK-LABEL: @sdiv_trailing_zeros( ; CHECK-NEXT: [[O:%.*]] = or i8 [[X:%.*]], 1 ; CHECK-NEXT: [[R:%.*]] = sdiv i8 [[O]], -12 ; CHECK-NEXT: ret i8 [[R]] ; %o = or i8 %x, 1 %r = sdiv i8 %o, -12 ret i8 %r } ; TODO: Match non-splat vector constants. define <2 x i8> @sdiv_exact_trailing_zeros_nonuniform_vector(<2 x i8> %x) { ; CHECK-LABEL: @sdiv_exact_trailing_zeros_nonuniform_vector( ; CHECK-NEXT: [[O:%.*]] = or <2 x i8> [[X:%.*]], ; CHECK-NEXT: [[R:%.*]] = sdiv exact <2 x i8> [[O]], ; CHECK-NEXT: ret <2 x i8> [[R]] ; %o = or <2 x i8> %x, %r = sdiv exact <2 x i8> %o, ret <2 x i8> %r } ; Can't divide evenly, so create poison. define <2 x i8> @udiv_exact_trailing_zeros(<2 x i8> %x) { ; CHECK-LABEL: @udiv_exact_trailing_zeros( ; CHECK-NEXT: ret <2 x i8> poison ; %o = or <2 x i8> %x, %r = udiv exact <2 x i8> %o, ; can't divide exactly ret <2 x i8> %r } ; Negative test - could divide evenly. define <2 x i8> @udiv_exact_trailing_zeros_eq(<2 x i8> %x) { ; CHECK-LABEL: @udiv_exact_trailing_zeros_eq( ; CHECK-NEXT: [[O:%.*]] = or <2 x i8> [[X:%.*]], ; CHECK-NEXT: [[R:%.*]] = udiv exact <2 x i8> [[O]], ; CHECK-NEXT: ret <2 x i8> [[R]] ; %o = or <2 x i8> %x, %r = udiv exact <2 x i8> %o, ret <2 x i8> %r } ; Negative test - must be exact div. define i8 @udiv_trailing_zeros(i8 %x) { ; CHECK-LABEL: @udiv_trailing_zeros( ; CHECK-NEXT: [[O:%.*]] = or i8 [[X:%.*]], 1 ; CHECK-NEXT: [[R:%.*]] = udiv i8 [[O]], 12 ; CHECK-NEXT: ret i8 [[R]] ; %o = or i8 %x, 1 %r = udiv i8 %o, 12 ret i8 %r } ; Negative test - only the first element is poison define <2 x i8> @udiv_exact_trailing_zeros_nonuniform_vector(<2 x i8> %x) { ; CHECK-LABEL: @udiv_exact_trailing_zeros_nonuniform_vector( ; CHECK-NEXT: [[O:%.*]] = or <2 x i8> [[X:%.*]], ; CHECK-NEXT: [[R:%.*]] = udiv exact <2 x i8> [[O]], ; CHECK-NEXT: ret <2 x i8> [[R]] ; %o = or <2 x i8> %x, %r = udiv exact <2 x i8> %o, ret <2 x i8> %r } !0 = !{i32 0, i32 3} define i32 @sdiv_one_srem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @sdiv_one_srem_divisor( ; CHECK-NEXT: ret i32 [[A:%.*]] ; %srem = srem i32 1, %b %sdiv = sdiv i32 %a, %srem ret i32 %sdiv } define i32 @sdiv_one_urem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @sdiv_one_urem_divisor( ; CHECK-NEXT: ret i32 [[A:%.*]] ; %urem = urem i32 1, %b %sdiv = sdiv i32 %a, %urem ret i32 %sdiv } define i32 @udiv_one_srem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @udiv_one_srem_divisor( ; CHECK-NEXT: ret i32 [[A:%.*]] ; %srem = srem i32 1, %b %udiv = udiv i32 %a, %srem ret i32 %udiv } define i32 @udiv_one_urem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @udiv_one_urem_divisor( ; CHECK-NEXT: ret i32 [[A:%.*]] ; %urem = urem i32 1, %b %udiv = udiv i32 %a, %urem ret i32 %udiv } define i32 @srem_one_srem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @srem_one_srem_divisor( ; CHECK-NEXT: ret i32 0 ; %srem = srem i32 1, %b %srem1 = srem i32 %a, %srem ret i32 %srem1 } define i32 @urem_one_srem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @urem_one_srem_divisor( ; CHECK-NEXT: ret i32 0 ; %srem = srem i32 1, %b %urem = urem i32 %a, %srem ret i32 %urem } define i32 @srem_one_urem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @srem_one_urem_divisor( ; CHECK-NEXT: ret i32 0 ; %urem = urem i32 1, %b %srem = srem i32 %a, %urem ret i32 %srem } define i32 @urem_one_urem_divisor(i32 %a, i32 %b) { ; CHECK-LABEL: @urem_one_urem_divisor( ; CHECK-NEXT: ret i32 0 ; %urem = urem i32 1, %b %urem1 = urem i32 %a, %urem ret i32 %urem1 } define <2 x i8> @sdiv_one_vec_srem_divisor(<2 x i8> %a, <2 x i8> %b) { ; CHECK-LABEL: @sdiv_one_vec_srem_divisor( ; CHECK-NEXT: ret <2 x i8> [[A:%.*]] ; %srem = srem <2 x i8> , %b %sdiv = sdiv <2 x i8> %a, %srem ret <2 x i8> %sdiv } define i32 @sdiv_and_one_divisor(i32 %x, i32 %y) { ; CHECK-LABEL: @sdiv_and_one_divisor( ; CHECK-NEXT: ret i32 [[Y:%.*]] ; %and = and i32 %x, 1 %res = sdiv i32 %y, %and ret i32 %res } define <2 x i8> @sdiv_and_one_vec_divisor(<2 x i8> %x, <2 x i8> %y) { ; CHECK-LABEL: @sdiv_and_one_vec_divisor( ; CHECK-NEXT: ret <2 x i8> [[Y:%.*]] ; %and = and <2 x i8> %x, %res = sdiv <2 x i8> %y, %and ret <2 x i8> %res } define i32 @sdiv_neg_or_divisor(i32 %x, i32 %y) { ; CHECK-LABEL: @sdiv_neg_or_divisor( ; CHECK-NEXT: ret i32 [[Y:%.*]] ; %or = or i32 %x, -2 %neg = xor i32 %or, -1 %res = sdiv i32 %y, %neg ret i32 %res } define i32 @sdiv_neg_or_multi_one_bit_divisor(i32 %x, i32 %y) { ; CHECK-LABEL: @sdiv_neg_or_multi_one_bit_divisor( ; CHECK-NEXT: [[OR:%.*]] = or i32 [[X:%.*]], -3 ; CHECK-NEXT: [[NEG:%.*]] = xor i32 [[OR]], -1 ; CHECK-NEXT: [[RES:%.*]] = sdiv i32 [[Y:%.*]], [[NEG]] ; CHECK-NEXT: ret i32 [[RES]] ; %or = or i32 %x, -3 %neg = xor i32 %or, -1 %res = sdiv i32 %y, %neg ret i32 %res } define <2 x i8> @sdiv_vec_multi_one_bit_divisor(<2 x i8> %x, <2 x i8> %y) { ; CHECK-LABEL: @sdiv_vec_multi_one_bit_divisor( ; CHECK-NEXT: [[AND:%.*]] = and <2 x i8> [[X:%.*]], ; CHECK-NEXT: [[RES:%.*]] = sdiv <2 x i8> [[Y:%.*]], [[AND]] ; CHECK-NEXT: ret <2 x i8> [[RES]] ; %and = and <2 x i8> %x, %res = sdiv <2 x i8> %y, %and ret <2 x i8> %res } define i8 @udiv_exact_mul_nsw(i8 %x) { ; CHECK-LABEL: @udiv_exact_mul_nsw( ; CHECK-NEXT: ret i8 [[X:%.*]] ; %a = mul nsw i8 %x, 24 %b = udiv exact i8 %a, 24 ret i8 %b } define i8 @sdiv_exact_mul_nuw(i8 %x) { ; CHECK-LABEL: @sdiv_exact_mul_nuw( ; CHECK-NEXT: ret i8 [[X:%.*]] ; %a = mul nuw i8 %x, 24 %b = sdiv exact i8 %a, 24 ret i8 %b } ; Negative tests define i8 @udiv_exact_mul_nsw_mismatch(i8 %x) { ; CHECK-LABEL: @udiv_exact_mul_nsw_mismatch( ; CHECK-NEXT: [[A:%.*]] = mul nsw i8 [[X:%.*]], 24 ; CHECK-NEXT: [[B:%.*]] = udiv exact i8 [[A]], 12 ; CHECK-NEXT: ret i8 [[B]] ; %a = mul nsw i8 %x, 24 %b = udiv exact i8 %a, 12 ret i8 %b } define i8 @udiv_exact_mul_nsw_power_of_2(i8 %x) { ; CHECK-LABEL: @udiv_exact_mul_nsw_power_of_2( ; CHECK-NEXT: [[A:%.*]] = mul nsw i8 [[X:%.*]], 8 ; CHECK-NEXT: [[B:%.*]] = udiv exact i8 [[A]], 8 ; CHECK-NEXT: ret i8 [[B]] ; %a = mul nsw i8 %x, 8 %b = udiv exact i8 %a, 8 ret i8 %b } define i8 @sdiv_exact_mul_nuw_power_of_2(i8 %x) { ; CHECK-LABEL: @sdiv_exact_mul_nuw_power_of_2( ; CHECK-NEXT: [[A:%.*]] = mul nuw i8 [[X:%.*]], 8 ; CHECK-NEXT: [[B:%.*]] = sdiv exact i8 [[A]], 8 ; CHECK-NEXT: ret i8 [[B]] ; %a = mul nuw i8 %x, 8 %b = sdiv exact i8 %a, 8 ret i8 %b } define i8 @udiv_exact_mul(i8 %x) { ; CHECK-LABEL: @udiv_exact_mul( ; CHECK-NEXT: [[A:%.*]] = mul i8 [[X:%.*]], 24 ; CHECK-NEXT: [[B:%.*]] = udiv exact i8 [[A]], 24 ; CHECK-NEXT: ret i8 [[B]] ; %a = mul i8 %x, 24 %b = udiv exact i8 %a, 24 ret i8 %b } define i8 @sdiv_exact_mul(i8 %x) { ; CHECK-LABEL: @sdiv_exact_mul( ; CHECK-NEXT: [[A:%.*]] = mul i8 [[X:%.*]], 24 ; CHECK-NEXT: [[B:%.*]] = sdiv exact i8 [[A]], 24 ; CHECK-NEXT: ret i8 [[B]] ; %a = mul i8 %x, 24 %b = sdiv exact i8 %a, 24 ret i8 %b } define i8 @udiv_mul_nsw(i8 %x) { ; CHECK-LABEL: @udiv_mul_nsw( ; CHECK-NEXT: [[A:%.*]] = mul nsw i8 [[X:%.*]], 24 ; CHECK-NEXT: [[B:%.*]] = udiv i8 [[A]], 24 ; CHECK-NEXT: ret i8 [[B]] ; %a = mul nsw i8 %x, 24 %b = udiv i8 %a, 24 ret i8 %b } define i8 @sdiv_mul_nuw(i8 %x) { ; CHECK-LABEL: @sdiv_mul_nuw( ; CHECK-NEXT: [[A:%.*]] = mul nuw i8 [[X:%.*]], 24 ; CHECK-NEXT: [[B:%.*]] = sdiv i8 [[A]], 24 ; CHECK-NEXT: ret i8 [[B]] ; %a = mul nuw i8 %x, 24 %b = sdiv i8 %a, 24 ret i8 %b }