llvm/test/Analysis/ScalarEvolution/widenable-condition.ll - llvm-project - Git at Google

 ; NOTE: Assertions have been autogenerated by utils/update_analyze_test_checks.py
 ; RUN: opt -analyze -enable-new-pm=0 -scalar-evolution < %s | FileCheck %s
 ; RUN: opt -disable-output "-passes=print<scalar-evolution>" < %s 2>&1 | FileCheck %s

 ; The semanics of this example are a bit subtle.  The loop is required
 ; execute some number of times up to 1999.  The compiler is free to reduce
 ; the number of said iterations to zero (or any value in between) if desired,
 ; but if it does so, the return value and the last value stored to G must
 ; agree.  For SCEV, this translates as widenable conditions preventing exact
 ; exit counts from being computed, but not restricting max exit counts.
 ; It's tempting to say that SCEV should return a precise exit count here, but
 ; would result in miscompiles if transformations such as RLEV ran before
 ; widening of the WC.
 define i32 @wc_max() {
 ; CHECK-LABEL: 'wc_max'
 ; CHECK-NEXT:  Classifying expressions for: @wc_max
 ; CHECK-NEXT:    %iv = phi i32 [ 0, %entry ], [ %iv.next, %loop ]
 ; CHECK-NEXT:    --> {0,+,1}<%loop> U: [0,2000) S: [0,2000) Exits: <<Unknown>> LoopDispositions: { %loop: Computable }
 ; CHECK-NEXT:    %iv.next = add i32 %iv, 1
 ; CHECK-NEXT:    --> {1,+,1}<%loop> U: [1,2001) S: [1,2001) Exits: <<Unknown>> LoopDispositions: { %loop: Computable }
 ; CHECK-NEXT:    %widenable_cond3 = call i1 @llvm.experimental.widenable.condition()
 ; CHECK-NEXT:    --> %widenable_cond3 U: full-set S: full-set Exits: <<Unknown>> LoopDispositions: { %loop: Variant }
 ; CHECK-NEXT:    %exiplicit_guard_cond4 = and i1 %cond_1, %widenable_cond3
 ; CHECK-NEXT:    --> %exiplicit_guard_cond4 U: full-set S: full-set Exits: <<Unknown>> LoopDispositions: { %loop: Variant }
 ; CHECK-NEXT:  Determining loop execution counts for: @wc_max
 ; CHECK-NEXT:  Loop %loop: Unpredictable backedge-taken count.
 ; CHECK-NEXT:  Loop %loop: max backedge-taken count is 1999
 ; CHECK-NEXT:  Loop %loop: Unpredictable predicated backedge-taken count.
 ;
 entry:
   br label %loop
 loop:
   %iv = phi i32 [0, %entry], [%iv.next, %loop]
   %iv.next = add i32 %iv, 1
   store i32 %iv, i32 *@G
   %cond_1 = icmp slt i32 %iv.next, 2000
   %widenable_cond3 = call i1 @llvm.experimental.widenable.condition()
   %exiplicit_guard_cond4 = and i1 %cond_1, %widenable_cond3
   br i1 %exiplicit_guard_cond4, label %loop, label %exit

 exit:
   ret i32 %iv
 }

 @G = external global i32
 declare i1 @llvm.experimental.widenable.condition()
	; NOTE: Assertions have been autogenerated by utils/update_analyze_test_checks.py
	; RUN: opt -analyze -enable-new-pm=0 -scalar-evolution < %s \| FileCheck %s
	; RUN: opt -disable-output "-passes=print<scalar-evolution>" < %s 2>&1 \| FileCheck %s

	; The semanics of this example are a bit subtle. The loop is required
	; execute some number of times up to 1999. The compiler is free to reduce
	; the number of said iterations to zero (or any value in between) if desired,
	; but if it does so, the return value and the last value stored to G must
	; agree. For SCEV, this translates as widenable conditions preventing exact
	; exit counts from being computed, but not restricting max exit counts.
	; It's tempting to say that SCEV should return a precise exit count here, but
	; would result in miscompiles if transformations such as RLEV ran before
	; widening of the WC.
	define i32 @wc_max() {
	; CHECK-LABEL: 'wc_max'
	; CHECK-NEXT: Classifying expressions for: @wc_max
	; CHECK-NEXT: %iv = phi i32 [ 0, %entry ], [ %iv.next, %loop ]
	; CHECK-NEXT: --> {0,+,1}<%loop> U: [0,2000) S: [0,2000) Exits: <<Unknown>> LoopDispositions: { %loop: Computable }
	; CHECK-NEXT: %iv.next = add i32 %iv, 1
	; CHECK-NEXT: --> {1,+,1}<%loop> U: [1,2001) S: [1,2001) Exits: <<Unknown>> LoopDispositions: { %loop: Computable }
	; CHECK-NEXT: %widenable_cond3 = call i1 @llvm.experimental.widenable.condition()
	; CHECK-NEXT: --> %widenable_cond3 U: full-set S: full-set Exits: <<Unknown>> LoopDispositions: { %loop: Variant }
	; CHECK-NEXT: %exiplicit_guard_cond4 = and i1 %cond_1, %widenable_cond3
	; CHECK-NEXT: --> %exiplicit_guard_cond4 U: full-set S: full-set Exits: <<Unknown>> LoopDispositions: { %loop: Variant }
	; CHECK-NEXT: Determining loop execution counts for: @wc_max
	; CHECK-NEXT: Loop %loop: Unpredictable backedge-taken count.
	; CHECK-NEXT: Loop %loop: max backedge-taken count is 1999
	; CHECK-NEXT: Loop %loop: Unpredictable predicated backedge-taken count.
	;
	entry:
	br label %loop
	loop:
	%iv = phi i32 [0, %entry], [%iv.next, %loop]
	%iv.next = add i32 %iv, 1
	store i32 %iv, i32 *@G
	%cond_1 = icmp slt i32 %iv.next, 2000
	%widenable_cond3 = call i1 @llvm.experimental.widenable.condition()
	%exiplicit_guard_cond4 = and i1 %cond_1, %widenable_cond3
	br i1 %exiplicit_guard_cond4, label %loop, label %exit

	exit:
	ret i32 %iv
	}

	@G = external global i32
	declare i1 @llvm.experimental.widenable.condition()