test/Transforms/InstSimplify/div.ll - llvm - Git at Google

 ; RUN: opt < %s -instsimplify -S | FileCheck %s

 ; Division-by-zero is undef. UB in any vector lane means the whole op is undef.

 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> undef
 ;
   %div = sdiv <2 x i8> <i8 1, i8 2>, <i8 0, i8 -42>
   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> undef
 ;
   %div = udiv <2 x i8> <i8 1, i8 2>, <i8 42, i8 0>
   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> undef
 ;
   %div = sdiv <2 x i8> %x, <i8 -42, i8 0>
   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> undef
 ;
   %div = udiv <2 x i8> %x, <i8 0, i8 42>
   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 @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
 }

 ; 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 !0
 ; CHECK-NEXT:    ret i32 0
 ;
   %call = call i32 @external(), !range !0
   %urem = udiv i32 %call, 3
   ret i32 %urem
 }

 !0 = !{i32 0, i32 3}
	; RUN: opt < %s -instsimplify -S \| FileCheck %s

	; Division-by-zero is undef. UB in any vector lane means the whole op is undef.

	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> undef
	;
	%div = sdiv <2 x i8> <i8 1, i8 2>, <i8 0, i8 -42>
	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> undef
	;
	%div = udiv <2 x i8> <i8 1, i8 2>, <i8 42, i8 0>
	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> undef
	;
	%div = sdiv <2 x i8> %x, <i8 -42, i8 0>
	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> undef
	;
	%div = udiv <2 x i8> %x, <i8 0, i8 42>
	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 @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
	}

	; 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 !0
	; CHECK-NEXT: ret i32 0
	;
	%call = call i32 @external(), !range !0
	%urem = udiv i32 %call, 3
	ret i32 %urem
	}

	!0 = !{i32 0, i32 3}