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|
; REQUIRES: asserts
; RUN: opt -S -passes=dfa-jump-threading -verify-dom-info=1 -debug-only=dfa-jump-threading -disable-output %s 2>&1 | FileCheck %s
; RUN: opt -S -passes=dfa-jump-threading -verify-dom-info=1 -print-prof-data %s -o - | FileCheck %s --check-prefix=PROFILE
; This test checks that the analysis identifies all threadable paths in a
; simple CFG. A threadable path includes a list of basic blocks, the exit
; state, and the block that determines the next state.
; < path of BBs that form a cycle > [ state, determinator ]
define i32 @test1(i32 %num) !prof !0{
; CHECK: < case2, for.inc, for.body > [ 1, for.inc ]
; CHECK-NEXT: < for.inc, for.body > [ 1, for.inc ]
; CHECK-NEXT: < case1, for.inc, for.body > [ 2, for.inc ]
; CHECK-NEXT: < case2, sel.si.unfold.false, for.inc, for.body > [ 2, sel.si.unfold.false ]
entry:
br label %for.body
for.body:
%count = phi i32 [ 0, %entry ], [ %inc, %for.inc ]
%state = phi i32 [ 1, %entry ], [ %state.next, %for.inc ]
switch i32 %state, label %for.inc [
i32 1, label %case1
i32 2, label %case2
]
case1:
br label %for.inc
case2:
; PROFILE-LABEL: @test1
; PROFILE-LABEL: case2:
; PROFILE: br i1 %cmp, label %for.inc.jt1, label %sel.si.unfold.false.jt2, !prof !1 ; !1 = !{!"branch_weights", i32 3, i32 5}
%cmp = icmp eq i32 %count, 50
%sel = select i1 %cmp, i32 1, i32 2, !prof !1
br label %for.inc
for.inc:
%state.next = phi i32 [ %sel, %case2 ], [ 1, %for.body ], [ 2, %case1 ]
%inc = add nsw i32 %count, 1
%cmp.exit = icmp slt i32 %inc, %num
br i1 %cmp.exit, label %for.body, label %for.end
for.end:
ret i32 0
}
; This test checks that the analysis finds threadable paths in a more
; complicated CFG. Here the FSM is represented as a nested loop, with
; fallthrough cases.
define i32 @test2(i32 %init) {
; CHECK: < loop.1.backedge, loop.1, loop.2, loop.3 > [ 1, loop.1 ]
; CHECK-NEXT: < case4, loop.1.backedge, state.1.be2.si.unfold.false, loop.1, loop.2, loop.3 > [ 2, loop.1.backedge ]
; CHECK-NEXT: < case2, loop.1.backedge, state.1.be2.si.unfold.false, loop.1, loop.2, loop.3 > [ 4, loop.1.backedge ]
; CHECK-NEXT: < case4, loop.2.backedge, loop.2, loop.3 > [ 3, loop.2.backedge ]
; CHECK-NEXT: < case3, loop.2.backedge, loop.2, loop.3 > [ 0, loop.2.backedge ]
; CHECK-NEXT: < case2, loop.3 > [ 3, loop.3 ]
entry:
%cmp = icmp eq i32 %init, 0
%sel = select i1 %cmp, i32 0, i32 2
br label %loop.1
loop.1:
%state.1 = phi i32 [ %sel, %entry ], [ %state.1.be2, %loop.1.backedge ]
br label %loop.2
loop.2:
%state.2 = phi i32 [ %state.1, %loop.1 ], [ %state.2.be, %loop.2.backedge ]
br label %loop.3
loop.3:
%state = phi i32 [ %state.2, %loop.2 ], [ 3, %case2 ]
switch i32 %state, label %infloop.i [
i32 2, label %case2
i32 3, label %case3
i32 4, label %case4
i32 0, label %case0
i32 1, label %case1
]
case2:
br i1 %cmp, label %loop.3, label %loop.1.backedge
case3:
br i1 %cmp, label %loop.2.backedge, label %case4
case4:
br i1 %cmp, label %loop.2.backedge, label %loop.1.backedge
loop.1.backedge:
%state.1.be = phi i32 [ 2, %case4 ], [ 4, %case2 ]
%state.1.be2 = select i1 %cmp, i32 1, i32 %state.1.be
br label %loop.1
loop.2.backedge:
%state.2.be = phi i32 [ 3, %case4 ], [ 0, %case3 ]
br label %loop.2
case0:
br label %exit
case1:
br label %exit
infloop.i:
br label %infloop.i
exit:
ret i32 0
}
declare void @baz()
; Do not jump-thread those paths where the determinator basic block does not
; precede the basic block that defines the switch condition.
;
; Otherwise, it is possible that the state defined in the determinator block
; defines the state for the next iteration of the loop, rather than for the
; current one.
define i32 @wrong_bb_order() {
; CHECK-LABEL: DFA Jump threading: wrong_bb_order
; CHECK-NOT: [ 77, bb43 ]
; CHECK-NOT: [ 77, bb43 ]
bb:
%i = alloca [420 x i8], align 1
%i2 = getelementptr inbounds [420 x i8], ptr %i, i64 0, i64 390
br label %bb3
bb3: ; preds = %bb59, %bb
%i4 = phi ptr [ %i2, %bb ], [ %i60, %bb59 ]
%i5 = phi i8 [ 77, %bb ], [ %i64, %bb59 ]
%i6 = phi i32 [ 2, %bb ], [ %i63, %bb59 ]
%i7 = phi i32 [ 26, %bb ], [ %i62, %bb59 ]
%i8 = phi i32 [ 25, %bb ], [ %i61, %bb59 ]
%i9 = icmp sgt i32 %i7, 2
%i10 = select i1 %i9, i32 %i7, i32 2
%i11 = add i32 %i8, 2
%i12 = sub i32 %i11, %i10
%i13 = mul nsw i32 %i12, 3
%i14 = add nsw i32 %i13, %i6
%i15 = sext i32 %i14 to i64
%i16 = getelementptr inbounds i8, ptr %i4, i64 %i15
%i17 = load i8, ptr %i16, align 1
%i18 = icmp sgt i8 %i17, 0
br i1 %i18, label %bb21, label %bb31
bb21: ; preds = %bb3
br i1 true, label %bb59, label %bb43
bb59: ; preds = %bb49, %bb43, %bb31, %bb21
%i60 = phi ptr [ %i44, %bb49 ], [ %i44, %bb43 ], [ %i34, %bb31 ], [ %i4, %bb21 ]
%i61 = phi i32 [ %i45, %bb49 ], [ %i45, %bb43 ], [ %i33, %bb31 ], [ %i8, %bb21 ]
%i62 = phi i32 [ %i47, %bb49 ], [ %i47, %bb43 ], [ %i32, %bb31 ], [ %i7, %bb21 ]
%i63 = phi i32 [ %i48, %bb49 ], [ %i48, %bb43 ], [ 2, %bb31 ], [ %i6, %bb21 ]
%i64 = phi i8 [ %i46, %bb49 ], [ %i46, %bb43 ], [ 77, %bb31 ], [ %i5, %bb21 ]
%i65 = icmp sgt i32 %i62, 0
br i1 %i65, label %bb3, label %bb66
bb31: ; preds = %bb3
%i32 = add nsw i32 %i7, -1
%i33 = add nsw i32 %i8, -1
%i34 = getelementptr inbounds i8, ptr %i4, i64 -15
%i35 = icmp eq i8 %i5, 77
br i1 %i35, label %bb59, label %bb41
bb41: ; preds = %bb31
tail call void @baz()
br label %bb43
bb43: ; preds = %bb41, %bb21
%i44 = phi ptr [ %i34, %bb41 ], [ %i4, %bb21 ]
%i45 = phi i32 [ %i33, %bb41 ], [ %i8, %bb21 ]
%i46 = phi i8 [ 77, %bb41 ], [ %i5, %bb21 ]
%i47 = phi i32 [ %i32, %bb41 ], [ %i7, %bb21 ]
%i48 = phi i32 [ 2, %bb41 ], [ %i6, %bb21 ]
tail call void @baz()
switch i8 %i5, label %bb59 [
i8 68, label %bb49
i8 73, label %bb49
]
bb49: ; preds = %bb43, %bb43
tail call void @baz()
br label %bb59
bb66: ; preds = %bb59
ret i32 0
}
; Value %init is not predictable but it's okay since it is the value initial to the switch.
define i32 @initial.value.positive1(i32 %init) !prof !0 {
; CHECK: < loop.1.backedge, loop.1, loop.2, loop.3 > [ 1, loop.1 ]
; CHECK-NEXT: < case4, loop.1.backedge, state.1.be2.si.unfold.false, loop.1, loop.2, loop.3 > [ 2, loop.1.backedge ]
; CHECK-NEXT: < case2, loop.1.backedge, state.1.be2.si.unfold.false, loop.1, loop.2, loop.3 > [ 4, loop.1.backedge ]
; CHECK-NEXT: < case4, loop.2.backedge, loop.2, loop.3 > [ 3, loop.2.backedge ]
; CHECK-NEXT: < case3, loop.2.backedge, loop.2, loop.3 > [ 0, loop.2.backedge ]
; CHECK-NEXT: < case2, loop.3 > [ 3, loop.3 ]
entry:
%cmp = icmp eq i32 %init, 0
br label %loop.1
loop.1:
%state.1 = phi i32 [ %init, %entry ], [ %state.1.be2, %loop.1.backedge ]
br label %loop.2
loop.2:
%state.2 = phi i32 [ %state.1, %loop.1 ], [ %state.2.be, %loop.2.backedge ]
br label %loop.3
loop.3:
%state = phi i32 [ %state.2, %loop.2 ], [ 3, %case2 ]
switch i32 %state, label %infloop.i [
i32 2, label %case2
i32 3, label %case3
i32 4, label %case4
i32 0, label %case0
i32 1, label %case1
]
case2:
br i1 %cmp, label %loop.3, label %loop.1.backedge
case3:
br i1 %cmp, label %loop.2.backedge, label %case4
case4:
br i1 %cmp, label %loop.2.backedge, label %loop.1.backedge
loop.1.backedge:
%state.1.be = phi i32 [ 2, %case4 ], [ 4, %case2 ]
%state.1.be2 = select i1 %cmp, i32 1, i32 %state.1.be
br label %loop.1
loop.2.backedge:
%state.2.be = phi i32 [ 3, %case4 ], [ 0, %case3 ]
br label %loop.2
case0:
br label %exit
case1:
br label %exit
infloop.i:
br label %infloop.i
exit:
ret i32 0
}
define i8 @cyclesInPaths1(i1 %call12, i1 %cmp18) {
; CHECK-LABEL: DFA Jump threading: cyclesInPaths1
; CHECK-NOT: <{{.*}}> [{{.*}}]
entry:
br label %switchPhiDef.for.body
switchPhiDef.for.body: ; preds = %detBB2, %entry
%switchPhi.curState = phi i32 [ %curState.1, %detBB2 ], [ 0, %entry ]
br i1 %call12, label %detBB1, label %if.else
if.else: ; preds = %switchPhiDef.for.body
br label %detBB1
detBB1: ; preds = %if.else, %switchPhiDef.for.body
%newState.02 = phi i32 [ 2, %switchPhiDef.for.body ], [ 4, %if.else ]
br i1 %cmp18, label %detBB2, label %if.end20
if.end20: ; preds = %detBB1
br i1 %call12, label %if.end23, label %switchBB
switchBB: ; preds = %if.end20
switch i32 %switchPhi.curState, label %if.end23 [
i32 4, label %ret1
i32 0, label %ret2
]
ret1: ; preds = %switchBB
ret i8 1
ret2: ; preds = %switchBB
ret i8 2
if.end23: ; preds = %switchBB, %if.end20
br label %detBB2
detBB2: ; preds = %if.end23, %detBB1
%curState.1 = phi i32 [ %newState.02, %if.end23 ], [ 0, %detBB1 ]
br label %switchPhiDef.for.body
}
define void @cyclesInPaths2(i1 %tobool5.not.i) {
; CHECK-LABEL: DFA Jump threading: cyclesInPaths2
; CHECK: < sw.bb.i, bb.exit, if.end5, if.end.i > [ 1, bb.exit ]
; CHECK-NEXT: < bb.exit, if.end5, if.end.i > [ 0, bb.exit ]
entry:
br label %if.end5
if.end5: ; preds = %bb.exit, %entry
%P.sroa.8.051 = phi i16 [ %retval.sroa.6.0.i, %bb.exit ], [ 0, %entry ]
call void @foo3()
br i1 %tobool5.not.i, label %if.end.i, label %bb.exit
if.end.i: ; preds = %if.end5
switch i16 %P.sroa.8.051, label %sw.default.i [
i16 1, label %sw.bb.i
i16 0, label %bb.exit
]
sw.bb.i: ; preds = %if.end.i
call void @foo1()
br label %bb.exit
sw.default.i: ; preds = %if.end.i
unreachable
bb.exit: ; preds = %sw.bb.i, %if.end.i, %if.end5
%retval.sroa.6.0.i = phi i16 [ 1, %sw.bb.i ], [ 0, %if.end5 ], [ 0, %if.end.i ]
call void @foo2()
br label %if.end5
}
declare void @foo1()
declare void @foo2()
declare void @foo3()
!0 = !{!"function_entry_count", i32 10}
!1 = !{!"branch_weights", i32 3, i32 5}
|
