test/Transforms/LoopPredication/widened.ll - llvm - Git at Google

 ; RUN: opt -S -loop-predication -loop-predication-enable-iv-truncation=true < %s 2>&1 | FileCheck %s
 declare void @llvm.experimental.guard(i1, ...)

 declare i32 @length(i8*)

 declare i16 @short_length(i8*)
 ; Consider range check of type i16 and i32, while IV is of type i64
 ; We can loop predicate this because the IV range is within i16 and within i32.
 define i64 @iv_wider_type_rc_two_narrow_types(i32 %offA, i16 %offB, i8* %arrA, i8* %arrB) {
 ; CHECK-LABEL: iv_wider_type_rc_two_narrow_types
 entry:
 ; CHECK-LABEL: entry:
 ; CHECK: [[idxB:[^ ]+]] = sub i16 %lengthB, %offB
 ; CHECK-NEXT: [[limit_checkB:[^ ]+]] = icmp ule i16 16, [[idxB]]
 ; CHECK-NEXT: [[first_iteration_checkB:[^ ]+]] = icmp ult i16 %offB, %lengthB
 ; CHECK-NEXT: [[WideChkB:[^ ]+]] = and i1 [[first_iteration_checkB]], [[limit_checkB]]
 ; CHECK-NEXT: [[idxA:[^ ]+]] = sub i32 %lengthA, %offA
 ; CHECK-NEXT: [[limit_checkA:[^ ]+]] = icmp ule i32 16, [[idxA]]
 ; CHECK-NEXT: [[first_iteration_checkA:[^ ]+]] = icmp ult i32 %offA, %lengthA
 ; CHECK-NEXT: [[WideChkA:[^ ]+]] = and i1 [[first_iteration_checkA]], [[limit_checkA]]
   %lengthA = call i32 @length(i8* %arrA)
   %lengthB = call i16 @short_length(i8* %arrB)
    br label %loop

 loop:
 ; CHECK-LABEL: loop:
 ; CHECK: [[invariant_check:[^ ]+]] = and i1 [[WideChkB]], [[WideChkA]]
 ; CHECK-NEXT: call void (i1, ...) @llvm.experimental.guard(i1 [[invariant_check]], i32 9)
   %iv = phi i64 [0, %entry ], [ %iv.next, %loop ]
   %iv.trunc.32 = trunc i64 %iv to i32
   %iv.trunc.16 = trunc i64 %iv to i16
   %indexA = add i32 %iv.trunc.32, %offA
   %indexB = add i16 %iv.trunc.16, %offB
   %rcA = icmp ult i32 %indexA, %lengthA
   %rcB = icmp ult i16 %indexB, %lengthB
   %wide.chk = and i1 %rcA, %rcB
   call void (i1, ...) @llvm.experimental.guard(i1 %wide.chk, i32 9) [ "deopt"() ]
   %indexA.ext = zext i32 %indexA to i64
   %addrA = getelementptr inbounds i8, i8* %arrA, i64 %indexA.ext
   %eltA = load i8, i8* %addrA
   %indexB.ext = zext i16 %indexB to i64
   %addrB = getelementptr inbounds i8, i8* %arrB, i64 %indexB.ext
   store i8 %eltA, i8* %addrB
   %iv.next = add nuw nsw i64 %iv, 1
   %latch.check = icmp ult i64 %iv.next, 16
   br i1 %latch.check, label %loop, label %exit

 exit:
  ret i64 %iv
 }


 ; Consider an IV of type long and an array access into int array.
 ; IV is of type i64 while the range check operands are of type i32 and i64.
 define i64 @iv_rc_different_types(i32 %offA, i32 %offB, i8* %arrA, i8* %arrB, i64 %max)
 {
 ; CHECK-LABEL: iv_rc_different_types
 entry:
 ; CHECK-LABEL: entry:
 ; CHECK: [[lenB:[^ ]+]] = add i32 %lengthB, -1
 ; CHECK-NEXT: [[idxB:[^ ]+]] = sub i32 [[lenB]], %offB
 ; CHECK-NEXT: [[limit_checkB:[^ ]+]] = icmp ule i32 15, [[idxB]]
 ; CHECK-NEXT: [[first_iteration_checkB:[^ ]+]] = icmp ult i32 %offB, %lengthB
 ; CHECK-NEXT: [[WideChkB:[^ ]+]] = and i1 [[first_iteration_checkB]], [[limit_checkB]]
 ; CHECK-NEXT: [[maxMinusOne:[^ ]+]] = add i64 %max, -1
 ; CHECK-NEXT: [[limit_checkMax:[^ ]+]] = icmp ule i64 15, [[maxMinusOne]]
 ; CHECK-NEXT: [[first_iteration_checkMax:[^ ]+]] = icmp ult  i64 0, %max
 ; CHECK-NEXT: [[WideChkMax:[^ ]+]] = and i1 [[first_iteration_checkMax]], [[limit_checkMax]]
 ; CHECK-NEXT: [[lenA:[^ ]+]] = add i32 %lengthA, -1
 ; CHECK-NEXT: [[idxA:[^ ]+]] = sub i32 [[lenA]], %offA
 ; CHECK-NEXT: [[limit_checkA:[^ ]+]] = icmp ule i32 15, [[idxA]]
 ; CHECK-NEXT: [[first_iteration_checkA:[^ ]+]] = icmp ult i32 %offA, %lengthA
 ; CHECK-NEXT: [[WideChkA:[^ ]+]] = and i1 [[first_iteration_checkA]], [[limit_checkA]]
   %lengthA = call i32 @length(i8* %arrA)
   %lengthB = call i32 @length(i8* %arrB)
   br label %loop

 loop:
 ; CHECK-LABEL: loop:
 ; CHECK: [[BandMax:[^ ]+]] = and i1 [[WideChkB]], [[WideChkMax]]
 ; CHECK: [[ABandMax:[^ ]+]] = and i1 [[BandMax]], [[WideChkA]]
 ; CHECK: call void (i1, ...) @llvm.experimental.guard(i1 [[ABandMax]], i32 9)
   %iv = phi i64 [0, %entry ], [ %iv.next, %loop ]
   %iv.trunc = trunc i64 %iv to i32
   %indexA = add i32 %iv.trunc, %offA
   %indexB = add i32 %iv.trunc, %offB
   %rcA = icmp ult i32 %indexA, %lengthA
   %rcIV = icmp ult i64 %iv, %max
   %wide.chk = and i1 %rcA, %rcIV
   %rcB = icmp ult i32 %indexB, %lengthB
   %wide.chk.final = and i1 %wide.chk, %rcB
   call void (i1, ...) @llvm.experimental.guard(i1 %wide.chk.final, i32 9) [ "deopt"() ]
   %indexA.ext = zext i32 %indexA to i64
   %addrA = getelementptr inbounds i8, i8* %arrA, i64 %indexA.ext
   %eltA = load i8, i8* %addrA
   %indexB.ext = zext i32 %indexB to i64
   %addrB = getelementptr inbounds i8, i8* %arrB, i64 %indexB.ext
   %eltB = load i8, i8* %addrB
   %result = xor i8 %eltA, %eltB
   store i8 %result, i8* %addrA
   %iv.next = add nuw nsw i64 %iv, 1
   %latch.check = icmp ult i64 %iv, 15
   br i1 %latch.check, label %loop, label %exit

 exit:
   ret i64 %iv
 }

 ; cannot narrow the IV to the range type, because we lose information.
 ; for (i64 i= 5; i>= 2; i++)
 ; this loop wraps around after reaching 2^64.
 define i64 @iv_rc_different_type(i32 %offA, i8* %arrA) {
 ; CHECK-LABEL: iv_rc_different_type
 entry:
   %lengthA = call i32 @length(i8* %arrA)
   br label %loop

 loop:
 ; CHECK-LABEL: loop:
 ; CHECK: %rcA = icmp ult i32 %indexA, %lengthA
 ; CHECK-NEXT: call void (i1, ...) @llvm.experimental.guard(i1 %rcA, i32 9)
   %iv = phi i64 [ 5, %entry ], [ %iv.next, %loop ]
   %iv.trunc.32 = trunc i64 %iv to i32
   %indexA = add i32 %iv.trunc.32, %offA
   %rcA = icmp ult i32 %indexA, %lengthA
   call void (i1, ...) @llvm.experimental.guard(i1 %rcA, i32 9) [ "deopt"() ]
   %indexA.ext = zext i32 %indexA to i64
   %addrA = getelementptr inbounds i8, i8* %arrA, i64 %indexA.ext
   %eltA = load i8, i8* %addrA
   %res = add i8 %eltA, 2
   store i8 %eltA, i8* %addrA
   %iv.next = add i64 %iv, 1
   %latch.check = icmp sge i64 %iv.next, 2
   br i1 %latch.check, label %loop, label %exit

 exit:
  ret i64 %iv
 }
	; RUN: opt -S -loop-predication -loop-predication-enable-iv-truncation=true < %s 2>&1 \| FileCheck %s
	declare void @llvm.experimental.guard(i1, ...)

	declare i32 @length(i8*)

	declare i16 @short_length(i8*)
	; Consider range check of type i16 and i32, while IV is of type i64
	; We can loop predicate this because the IV range is within i16 and within i32.
	define i64 @iv_wider_type_rc_two_narrow_types(i32 %offA, i16 %offB, i8* %arrA, i8* %arrB) {
	; CHECK-LABEL: iv_wider_type_rc_two_narrow_types
	entry:
	; CHECK-LABEL: entry:
	; CHECK: [[idxB:[^ ]+]] = sub i16 %lengthB, %offB
	; CHECK-NEXT: [[limit_checkB:[^ ]+]] = icmp ule i16 16, [[idxB]]
	; CHECK-NEXT: [[first_iteration_checkB:[^ ]+]] = icmp ult i16 %offB, %lengthB
	; CHECK-NEXT: [[WideChkB:[^ ]+]] = and i1 [[first_iteration_checkB]], [[limit_checkB]]
	; CHECK-NEXT: [[idxA:[^ ]+]] = sub i32 %lengthA, %offA
	; CHECK-NEXT: [[limit_checkA:[^ ]+]] = icmp ule i32 16, [[idxA]]
	; CHECK-NEXT: [[first_iteration_checkA:[^ ]+]] = icmp ult i32 %offA, %lengthA
	; CHECK-NEXT: [[WideChkA:[^ ]+]] = and i1 [[first_iteration_checkA]], [[limit_checkA]]
	%lengthA = call i32 @length(i8* %arrA)
	%lengthB = call i16 @short_length(i8* %arrB)
	br label %loop

	loop:
	; CHECK-LABEL: loop:
	; CHECK: [[invariant_check:[^ ]+]] = and i1 [[WideChkB]], [[WideChkA]]
	; CHECK-NEXT: call void (i1, ...) @llvm.experimental.guard(i1 [[invariant_check]], i32 9)
	%iv = phi i64 [0, %entry ], [ %iv.next, %loop ]
	%iv.trunc.32 = trunc i64 %iv to i32
	%iv.trunc.16 = trunc i64 %iv to i16
	%indexA = add i32 %iv.trunc.32, %offA
	%indexB = add i16 %iv.trunc.16, %offB
	%rcA = icmp ult i32 %indexA, %lengthA
	%rcB = icmp ult i16 %indexB, %lengthB
	%wide.chk = and i1 %rcA, %rcB
	call void (i1, ...) @llvm.experimental.guard(i1 %wide.chk, i32 9) [ "deopt"() ]
	%indexA.ext = zext i32 %indexA to i64
	%addrA = getelementptr inbounds i8, i8* %arrA, i64 %indexA.ext
	%eltA = load i8, i8* %addrA
	%indexB.ext = zext i16 %indexB to i64
	%addrB = getelementptr inbounds i8, i8* %arrB, i64 %indexB.ext
	store i8 %eltA, i8* %addrB
	%iv.next = add nuw nsw i64 %iv, 1
	%latch.check = icmp ult i64 %iv.next, 16
	br i1 %latch.check, label %loop, label %exit

	exit:
	ret i64 %iv
	}


	; Consider an IV of type long and an array access into int array.
	; IV is of type i64 while the range check operands are of type i32 and i64.
	define i64 @iv_rc_different_types(i32 %offA, i32 %offB, i8* %arrA, i8* %arrB, i64 %max)
	{
	; CHECK-LABEL: iv_rc_different_types
	entry:
	; CHECK-LABEL: entry:
	; CHECK: [[lenB:[^ ]+]] = add i32 %lengthB, -1
	; CHECK-NEXT: [[idxB:[^ ]+]] = sub i32 [[lenB]], %offB
	; CHECK-NEXT: [[limit_checkB:[^ ]+]] = icmp ule i32 15, [[idxB]]
	; CHECK-NEXT: [[first_iteration_checkB:[^ ]+]] = icmp ult i32 %offB, %lengthB
	; CHECK-NEXT: [[WideChkB:[^ ]+]] = and i1 [[first_iteration_checkB]], [[limit_checkB]]
	; CHECK-NEXT: [[maxMinusOne:[^ ]+]] = add i64 %max, -1
	; CHECK-NEXT: [[limit_checkMax:[^ ]+]] = icmp ule i64 15, [[maxMinusOne]]
	; CHECK-NEXT: [[first_iteration_checkMax:[^ ]+]] = icmp ult i64 0, %max
	; CHECK-NEXT: [[WideChkMax:[^ ]+]] = and i1 [[first_iteration_checkMax]], [[limit_checkMax]]
	; CHECK-NEXT: [[lenA:[^ ]+]] = add i32 %lengthA, -1
	; CHECK-NEXT: [[idxA:[^ ]+]] = sub i32 [[lenA]], %offA
	; CHECK-NEXT: [[limit_checkA:[^ ]+]] = icmp ule i32 15, [[idxA]]
	; CHECK-NEXT: [[first_iteration_checkA:[^ ]+]] = icmp ult i32 %offA, %lengthA
	; CHECK-NEXT: [[WideChkA:[^ ]+]] = and i1 [[first_iteration_checkA]], [[limit_checkA]]
	%lengthA = call i32 @length(i8* %arrA)
	%lengthB = call i32 @length(i8* %arrB)
	br label %loop

	loop:
	; CHECK-LABEL: loop:
	; CHECK: [[BandMax:[^ ]+]] = and i1 [[WideChkB]], [[WideChkMax]]
	; CHECK: [[ABandMax:[^ ]+]] = and i1 [[BandMax]], [[WideChkA]]
	; CHECK: call void (i1, ...) @llvm.experimental.guard(i1 [[ABandMax]], i32 9)
	%iv = phi i64 [0, %entry ], [ %iv.next, %loop ]
	%iv.trunc = trunc i64 %iv to i32
	%indexA = add i32 %iv.trunc, %offA
	%indexB = add i32 %iv.trunc, %offB
	%rcA = icmp ult i32 %indexA, %lengthA
	%rcIV = icmp ult i64 %iv, %max
	%wide.chk = and i1 %rcA, %rcIV
	%rcB = icmp ult i32 %indexB, %lengthB
	%wide.chk.final = and i1 %wide.chk, %rcB
	call void (i1, ...) @llvm.experimental.guard(i1 %wide.chk.final, i32 9) [ "deopt"() ]
	%indexA.ext = zext i32 %indexA to i64
	%addrA = getelementptr inbounds i8, i8* %arrA, i64 %indexA.ext
	%eltA = load i8, i8* %addrA
	%indexB.ext = zext i32 %indexB to i64
	%addrB = getelementptr inbounds i8, i8* %arrB, i64 %indexB.ext
	%eltB = load i8, i8* %addrB
	%result = xor i8 %eltA, %eltB
	store i8 %result, i8* %addrA
	%iv.next = add nuw nsw i64 %iv, 1
	%latch.check = icmp ult i64 %iv, 15
	br i1 %latch.check, label %loop, label %exit

	exit:
	ret i64 %iv
	}

	; cannot narrow the IV to the range type, because we lose information.
	; for (i64 i= 5; i>= 2; i++)
	; this loop wraps around after reaching 2^64.
	define i64 @iv_rc_different_type(i32 %offA, i8* %arrA) {
	; CHECK-LABEL: iv_rc_different_type
	entry:
	%lengthA = call i32 @length(i8* %arrA)
	br label %loop

	loop:
	; CHECK-LABEL: loop:
	; CHECK: %rcA = icmp ult i32 %indexA, %lengthA
	; CHECK-NEXT: call void (i1, ...) @llvm.experimental.guard(i1 %rcA, i32 9)
	%iv = phi i64 [ 5, %entry ], [ %iv.next, %loop ]
	%iv.trunc.32 = trunc i64 %iv to i32
	%indexA = add i32 %iv.trunc.32, %offA
	%rcA = icmp ult i32 %indexA, %lengthA
	call void (i1, ...) @llvm.experimental.guard(i1 %rcA, i32 9) [ "deopt"() ]
	%indexA.ext = zext i32 %indexA to i64
	%addrA = getelementptr inbounds i8, i8* %arrA, i64 %indexA.ext
	%eltA = load i8, i8* %addrA
	%res = add i8 %eltA, 2
	store i8 %eltA, i8* %addrA
	%iv.next = add i64 %iv, 1
	%latch.check = icmp sge i64 %iv.next, 2
	br i1 %latch.check, label %loop, label %exit

	exit:
	ret i64 %iv
	}