; Check that differences are reported in the BB processing order
; following the control flow, independent on whether the diff was depending
; on an assumption or not.
;
; Replace %newvar1 with %newvar2 in the phi node. This can only
; be detected to be different once BB2 has been processed, so leads to a assumption
; and is detected to diff later on.
; Also, replace the 1000 by 2000 in BB1, which is detected directly.
;
; RUN: rm -f %t.ll
; RUN: cat %s | sed -e 's/ %newvar1, %BB2 / %newvar2, %BB2 /' | sed -e 's/1000/2000/' > %t.ll
; RUN: not llvm-diff %s %t.ll 2>&1 | FileCheck %s
; CHECK: in function func:
; CHECK-NEXT: in block %BB0:
; CHECK-NEXT: > %var = phi i32 [ 0, %ENTRY ], [ %newvar2, %BB2 ]
; CHECK-NEXT: < %var = phi i32 [ 0, %ENTRY ], [ %newvar1, %BB2 ]
; CHECK-NEXT: in block %BB1:
; CHECK-NEXT: > %diffvar = add i32 %var, 2000
; CHECK-NEXT: < %diffvar = add i32 %var, 1000
define i32 @func() {
ENTRY:
br label %BB0
BB0:
; When diffing this phi node, we need to detect whether
; %newvar1 is equivalent, which is not known until BB2 has been processed.
%var = phi i32 [ 0, %ENTRY ], [ %newvar1, %BB2 ]
%cnd = icmp eq i32 %var, 0
br i1 %cnd, label %BB1, label %END
BB1:
%diffvar = add i32 %var, 1000
br label %BB1
BB2:
%newvar1 = add i32 %var, 1
%newvar2 = add i32 %var, 2
br label %BB0
END:
; Equivalence of the ret depends on equivalence of %var.
; Even if %var differs, we do not report a diff here, because
; this is an indirect diff caused by another diff.
ret i32 %var
}