Google Git
Sign in
llvm / llvm-project / c01c62c76c60a5a5da0496e41faae907944c92dd / . / llvm / test / Transforms / LICM / sinking.ll
blob: 63d97afe150ba90c3535736abc59a049facdead9 [file] [log] [blame]
; NOTE: Assertions have been autogenerated by utils/update_test_checks.py
; RUN: opt < %s -basic-aa -licm -S -verify-memoryssa | FileCheck %s
declare i32 @strlen(i8*) readonly nounwind willreturn
declare void @foo()
; Sink readonly function.
define i32 @test1(i8* %P) {
; CHECK-LABEL: @test1(
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: br i1 false, label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[A_LE:%.*]] = call i32 @strlen(i8* [[P:%.*]]) #[[ATTR3:[0-9]+]]
; CHECK-NEXT: ret i32 [[A_LE]]
;
br label %Loop
Loop: ; preds = %Loop, %0
%A = call i32 @strlen( i8* %P ) readonly
br i1 false, label %Loop, label %Out
Out: ; preds = %Loop
ret i32 %A
}
declare double @sin(double) readnone nounwind willreturn
; Sink readnone function out of loop with unknown memory behavior.
define double @test2(double %X) {
; CHECK-LABEL: @test2(
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: call void @foo()
; CHECK-NEXT: br i1 true, label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[A_LE:%.*]] = call double @sin(double [[X:%.*]]) #[[ATTR4:[0-9]+]]
; CHECK-NEXT: ret double [[A_LE]]
;
br label %Loop
Loop: ; preds = %Loop, %0
call void @foo( )
%A = call double @sin( double %X ) readnone
br i1 true, label %Loop, label %Out
Out: ; preds = %Loop
ret double %A
}
; FIXME: Should be able to sink this case
define i32 @test2b(i32 %X) {
; CHECK-LABEL: @test2b(
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: call void @foo()
; CHECK-NEXT: br i1 true, label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[A_LE:%.*]] = sdiv i32 10, [[X:%.*]]
; CHECK-NEXT: ret i32 [[A_LE]]
;
br label %Loop
Loop: ; preds = %Loop, %0
call void @foo( )
%A = sdiv i32 10, %X
br i1 true, label %Loop, label %Out
Out: ; preds = %Loop
ret i32 %A
}
define double @test2c(double* %P) {
; CHECK-LABEL: @test2c(
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: call void @foo()
; CHECK-NEXT: br i1 true, label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[A_LE:%.*]] = load double, double* [[P:%.*]], align 8, !invariant.load !0
; CHECK-NEXT: ret double [[A_LE]]
;
br label %Loop
Loop: ; preds = %Loop, %0
call void @foo( )
%A = load double, double* %P, !invariant.load !{}
br i1 true, label %Loop, label %Out
Out: ; preds = %Loop
ret double %A
}
; This testcase checks to make sure the sinker does not cause problems with
; critical edges.
define void @test3() {
; CHECK-LABEL: @test3(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br i1 false, label [[LOOP_PREHEADER:%.*]], label [[EXIT:%.*]]
; CHECK: Loop.preheader:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: br i1 false, label [[LOOP]], label [[EXIT_LOOPEXIT:%.*]]
; CHECK: Exit.loopexit:
; CHECK-NEXT: [[X_LE:%.*]] = add i32 0, 1
; CHECK-NEXT: br label [[EXIT]]
; CHECK: Exit:
; CHECK-NEXT: [[Y:%.*]] = phi i32 [ 0, [[ENTRY:%.*]] ], [ [[X_LE]], [[EXIT_LOOPEXIT]] ]
; CHECK-NEXT: ret void
;
Entry:
br i1 false, label %Loop, label %Exit
Loop:
%X = add i32 0, 1
br i1 false, label %Loop, label %Exit
Exit:
%Y = phi i32 [ 0, %Entry ], [ %X, %Loop ]
ret void
}
; If the result of an instruction is only used outside of the loop, sink
; the instruction to the exit blocks instead of executing it on every
; iteration of the loop.
;
define i32 @test4(i32 %N) {
; CHECK-LABEL: @test4(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[N_ADDR_0_PN:%.*]] = phi i32 [ [[DEC:%.*]], [[LOOP]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[DEC]] = add i32 [[N_ADDR_0_PN]], -1
; CHECK-NEXT: [[TMP_1:%.*]] = icmp ne i32 [[N_ADDR_0_PN]], 1
; CHECK-NEXT: br i1 [[TMP_1]], label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[LOOP]] ]
; CHECK-NEXT: [[TMP_6_LE:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA]]
; CHECK-NEXT: [[TMP_7_LE:%.*]] = sub i32 [[TMP_6_LE]], [[N]]
; CHECK-NEXT: ret i32 [[TMP_7_LE]]
;
Entry:
br label %Loop
Loop: ; preds = %Loop, %Entry
%N_addr.0.pn = phi i32 [ %dec, %Loop ], [ %N, %Entry ]
%tmp.6 = mul i32 %N, %N_addr.0.pn ; <i32> [#uses=1]
%tmp.7 = sub i32 %tmp.6, %N ; <i32> [#uses=1]
%dec = add i32 %N_addr.0.pn, -1 ; <i32> [#uses=1]
%tmp.1 = icmp ne i32 %N_addr.0.pn, 1 ; <i1> [#uses=1]
br i1 %tmp.1, label %Loop, label %Out
Out: ; preds = %Loop
ret i32 %tmp.7
}
; To reduce register pressure, if a load is hoistable out of the loop, and the
; result of the load is only used outside of the loop, sink the load instead of
; hoisting it!
;
@X = global i32 5 ; <i32*> [#uses=1]
define i32 @test5(i32 %N) {
; CHECK-LABEL: @test5(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[N_ADDR_0_PN:%.*]] = phi i32 [ [[DEC:%.*]], [[LOOP]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[DEC]] = add i32 [[N_ADDR_0_PN]], -1
; CHECK-NEXT: [[TMP_1:%.*]] = icmp ne i32 [[N_ADDR_0_PN]], 1
; CHECK-NEXT: br i1 [[TMP_1]], label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[TMP_6_LE:%.*]] = load i32, i32* @X, align 4
; CHECK-NEXT: ret i32 [[TMP_6_LE]]
;
Entry:
br label %Loop
Loop: ; preds = %Loop, %Entry
%N_addr.0.pn = phi i32 [ %dec, %Loop ], [ %N, %Entry ]
%tmp.6 = load i32, i32* @X ; <i32> [#uses=1]
%dec = add i32 %N_addr.0.pn, -1 ; <i32> [#uses=1]
%tmp.1 = icmp ne i32 %N_addr.0.pn, 1 ; <i1> [#uses=1]
br i1 %tmp.1, label %Loop, label %Out
Out: ; preds = %Loop
ret i32 %tmp.6
}
; The loop sinker was running from the bottom of the loop to the top, causing
; it to miss opportunities to sink instructions that depended on sinking other
; instructions from the loop. Instead they got hoisted, which is better than
; leaving them in the loop, but increases register pressure pointlessly.
%Ty = type { i32, i32 }
@X2 = external global %Ty
define i32 @test6() {
; CHECK-LABEL: @test6(
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: br i1 false, label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[DEAD_LE:%.*]] = getelementptr [[TY:%.*]], %Ty* @X2, i64 0, i32 0
; CHECK-NEXT: [[SUNK2_LE:%.*]] = load i32, i32* [[DEAD_LE]], align 4
; CHECK-NEXT: ret i32 [[SUNK2_LE]]
;
br label %Loop
Loop:
%dead = getelementptr %Ty, %Ty* @X2, i64 0, i32 0
%sunk2 = load i32, i32* %dead
br i1 false, label %Loop, label %Out
Out: ; preds = %Loop
ret i32 %sunk2
}
; This testcase ensures that we can sink instructions from loops with
; multiple exits.
;
define i32 @test7(i32 %N, i1 %C) {
; CHECK-LABEL: @test7(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[N_ADDR_0_PN:%.*]] = phi i32 [ [[DEC:%.*]], [[CONTLOOP:%.*]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[DEC]] = add i32 [[N_ADDR_0_PN]], -1
; CHECK-NEXT: br i1 [[C:%.*]], label [[CONTLOOP]], label [[OUT1:%.*]]
; CHECK: ContLoop:
; CHECK-NEXT: [[TMP_1:%.*]] = icmp ne i32 [[N_ADDR_0_PN]], 1
; CHECK-NEXT: br i1 [[TMP_1]], label [[LOOP]], label [[OUT2:%.*]]
; CHECK: Out1:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[LOOP]] ]
; CHECK-NEXT: [[TMP_6_LE:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA]]
; CHECK-NEXT: [[TMP_7_LE2:%.*]] = sub i32 [[TMP_6_LE]], [[N]]
; CHECK-NEXT: ret i32 [[TMP_7_LE2]]
; CHECK: Out2:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA5:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[CONTLOOP]] ]
; CHECK-NEXT: [[TMP_6_LE4:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA5]]
; CHECK-NEXT: [[TMP_7_LE:%.*]] = sub i32 [[TMP_6_LE4]], [[N]]
; CHECK-NEXT: ret i32 [[TMP_7_LE]]
;
Entry:
br label %Loop
Loop: ; preds = %ContLoop, %Entry
%N_addr.0.pn = phi i32 [ %dec, %ContLoop ], [ %N, %Entry ]
%tmp.6 = mul i32 %N, %N_addr.0.pn
%tmp.7 = sub i32 %tmp.6, %N ; <i32> [#uses=2]
%dec = add i32 %N_addr.0.pn, -1 ; <i32> [#uses=1]
br i1 %C, label %ContLoop, label %Out1
ContLoop:
%tmp.1 = icmp ne i32 %N_addr.0.pn, 1
br i1 %tmp.1, label %Loop, label %Out2
Out1: ; preds = %Loop
ret i32 %tmp.7
Out2: ; preds = %ContLoop
ret i32 %tmp.7
}
; This testcase checks to make sure we can sink values which are only live on
; some exits out of the loop, and that we can do so without breaking dominator
; info.
define i32 @test8(i1 %C1, i1 %C2, i32* %P, i32* %Q) {
; CHECK-LABEL: @test8(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: br i1 [[C1:%.*]], label [[CONT:%.*]], label [[EXIT1:%.*]]
; CHECK: Cont:
; CHECK-NEXT: [[X:%.*]] = load i32, i32* [[P:%.*]], align 4
; CHECK-NEXT: store i32 [[X]], i32* [[Q:%.*]], align 4
; CHECK-NEXT: br i1 [[C2:%.*]], label [[LOOP]], label [[EXIT2:%.*]]
; CHECK: exit1:
; CHECK-NEXT: ret i32 0
; CHECK: exit2:
; CHECK-NEXT: [[X_LCSSA:%.*]] = phi i32 [ [[X]], [[CONT]] ]
; CHECK-NEXT: [[V_LE:%.*]] = add i32 [[X_LCSSA]], 1
; CHECK-NEXT: ret i32 [[V_LE]]
;
Entry:
br label %Loop
Loop: ; preds = %Cont, %Entry
br i1 %C1, label %Cont, label %exit1
Cont: ; preds = %Loop
%X = load i32, i32* %P ; <i32> [#uses=2]
store i32 %X, i32* %Q
%V = add i32 %X, 1 ; <i32> [#uses=1]
br i1 %C2, label %Loop, label %exit2
exit1: ; preds = %Loop
ret i32 0
exit2: ; preds = %Cont
ret i32 %V
}
define void @test9() {
; CHECK-LABEL: @test9(
; CHECK-NEXT: loopentry.2.i:
; CHECK-NEXT: br i1 false, label [[NO_EXIT_1_I_PREHEADER:%.*]], label [[LOOPENTRY_3_I_PREHEADER:%.*]]
; CHECK: no_exit.1.i.preheader:
; CHECK-NEXT: br label [[NO_EXIT_1_I:%.*]]
; CHECK: no_exit.1.i:
; CHECK-NEXT: br i1 false, label [[RETURN_I:%.*]], label [[ENDIF_8_I:%.*]]
; CHECK: endif.8.i:
; CHECK-NEXT: br i1 false, label [[NO_EXIT_1_I]], label [[LOOPENTRY_3_I_PREHEADER_LOOPEXIT:%.*]]
; CHECK: loopentry.3.i.preheader.loopexit:
; CHECK-NEXT: [[INC_1_I_LE:%.*]] = add i32 0, 1
; CHECK-NEXT: br label [[LOOPENTRY_3_I_PREHEADER]]
; CHECK: loopentry.3.i.preheader:
; CHECK-NEXT: [[ARG_NUM_0_I_PH13000:%.*]] = phi i32 [ 0, [[LOOPENTRY_2_I:%.*]] ], [ [[INC_1_I_LE]], [[LOOPENTRY_3_I_PREHEADER_LOOPEXIT]] ]
; CHECK-NEXT: ret void
; CHECK: return.i:
; CHECK-NEXT: ret void
;
loopentry.2.i:
br i1 false, label %no_exit.1.i.preheader, label %loopentry.3.i.preheader
no_exit.1.i.preheader: ; preds = %loopentry.2.i
br label %no_exit.1.i
no_exit.1.i: ; preds = %endif.8.i, %no_exit.1.i.preheader
br i1 false, label %return.i, label %endif.8.i
endif.8.i: ; preds = %no_exit.1.i
%inc.1.i = add i32 0, 1 ; <i32> [#uses=1]
br i1 false, label %no_exit.1.i, label %loopentry.3.i.preheader.loopexit
loopentry.3.i.preheader.loopexit: ; preds = %endif.8.i
br label %loopentry.3.i.preheader
loopentry.3.i.preheader: ; preds = %loopentry.3.i.preheader.loopexit, %loopentry.2.i
%arg_num.0.i.ph13000 = phi i32 [ 0, %loopentry.2.i ], [ %inc.1.i, %loopentry.3.i.preheader.loopexit ] ; <i32> [#uses=0]
ret void
return.i: ; preds = %no_exit.1.i
ret void
}
; Potentially trapping instructions may be sunk as long as they are guaranteed
; to be executed.
define i32 @test10(i32 %N) {
; CHECK-LABEL: @test10(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[N_ADDR_0_PN:%.*]] = phi i32 [ [[DEC:%.*]], [[LOOP]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[DEC]] = add i32 [[N_ADDR_0_PN]], -1
; CHECK-NEXT: [[TMP_1:%.*]] = icmp ne i32 [[N_ADDR_0_PN]], 0
; CHECK-NEXT: br i1 [[TMP_1]], label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[LOOP]] ]
; CHECK-NEXT: [[TMP_6_LE:%.*]] = sdiv i32 [[N]], [[N_ADDR_0_PN_LCSSA]]
; CHECK-NEXT: ret i32 [[TMP_6_LE]]
;
Entry:
br label %Loop
Loop: ; preds = %Loop, %Entry
%N_addr.0.pn = phi i32 [ %dec, %Loop ], [ %N, %Entry ] ; <i32> [#uses=3]
%tmp.6 = sdiv i32 %N, %N_addr.0.pn ; <i32> [#uses=1]
%dec = add i32 %N_addr.0.pn, -1 ; <i32> [#uses=1]
%tmp.1 = icmp ne i32 %N_addr.0.pn, 0 ; <i1> [#uses=1]
br i1 %tmp.1, label %Loop, label %Out
Out: ; preds = %Loop
ret i32 %tmp.6
}
; Should delete, not sink, dead instructions.
define void @test11() {
; CHECK-LABEL: @test11(
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: br i1 false, label [[LOOP]], label [[OUT:%.*]]
; CHECK: Out:
; CHECK-NEXT: ret void
;
br label %Loop
Loop:
%dead1 = getelementptr %Ty, %Ty* @X2, i64 0, i32 0
%dead2 = getelementptr %Ty, %Ty* @X2, i64 0, i32 1
br i1 false, label %Loop, label %Out
Out:
ret void
}
@c = common global [1 x i32] zeroinitializer, align 4
; Test a *many* way nested loop with multiple exit blocks both of which exit
; multiple loop nests. This exercises LCSSA corner cases.
define i32 @PR18753(i1* %a, i1* %b, i1* %c, i1* %d) {
; CHECK-LABEL: @PR18753(
; CHECK-NEXT: entry:
; CHECK-NEXT: br label [[L1_HEADER:%.*]]
; CHECK: l1.header:
; CHECK-NEXT: [[IV:%.*]] = phi i64 [ [[IV_NEXT:%.*]], [[L1_LATCH:%.*]] ], [ 0, [[ENTRY:%.*]] ]
; CHECK-NEXT: [[ARRAYIDX_I:%.*]] = getelementptr inbounds [1 x i32], [1 x i32]* @c, i64 0, i64 [[IV]]
; CHECK-NEXT: br label [[L2_HEADER:%.*]]
; CHECK: l2.header:
; CHECK-NEXT: [[X0:%.*]] = load i1, i1* [[C:%.*]], align 4
; CHECK-NEXT: br i1 [[X0]], label [[L1_LATCH]], label [[L3_PREHEADER:%.*]]
; CHECK: l3.preheader:
; CHECK-NEXT: br label [[L3_HEADER:%.*]]
; CHECK: l3.header:
; CHECK-NEXT: [[X1:%.*]] = load i1, i1* [[D:%.*]], align 4
; CHECK-NEXT: br i1 [[X1]], label [[L2_LATCH:%.*]], label [[L4_PREHEADER:%.*]]
; CHECK: l4.preheader:
; CHECK-NEXT: br label [[L4_HEADER:%.*]]
; CHECK: l4.header:
; CHECK-NEXT: [[X2:%.*]] = load i1, i1* [[A:%.*]], align 1
; CHECK-NEXT: br i1 [[X2]], label [[L3_LATCH:%.*]], label [[L4_BODY:%.*]]
; CHECK: l4.body:
; CHECK-NEXT: call void @f(i32* [[ARRAYIDX_I]])
; CHECK-NEXT: [[X3:%.*]] = load i1, i1* [[B:%.*]], align 1
; CHECK-NEXT: br i1 [[X3]], label [[L4_LATCH:%.*]], label [[EXIT:%.*]]
; CHECK: l4.latch:
; CHECK-NEXT: call void @g()
; CHECK-NEXT: [[X4:%.*]] = load i1, i1* [[B]], align 4
; CHECK-NEXT: br i1 [[X4]], label [[L4_HEADER]], label [[EXIT]]
; CHECK: l3.latch:
; CHECK-NEXT: br label [[L3_HEADER]]
; CHECK: l2.latch:
; CHECK-NEXT: br label [[L2_HEADER]]
; CHECK: l1.latch:
; CHECK-NEXT: [[IV_NEXT]] = add nsw i64 [[IV]], 1
; CHECK-NEXT: br label [[L1_HEADER]]
; CHECK: exit:
; CHECK-NEXT: [[IV_LCSSA:%.*]] = phi i64 [ [[IV]], [[L4_LATCH]] ], [ [[IV]], [[L4_BODY]] ]
; CHECK-NEXT: [[L_LE:%.*]] = trunc i64 [[IV_LCSSA]] to i32
; CHECK-NEXT: ret i32 [[L_LE]]
;
entry:
br label %l1.header
l1.header:
%iv = phi i64 [ %iv.next, %l1.latch ], [ 0, %entry ]
%arrayidx.i = getelementptr inbounds [1 x i32], [1 x i32]* @c, i64 0, i64 %iv
br label %l2.header
l2.header:
%x0 = load i1, i1* %c, align 4
br i1 %x0, label %l1.latch, label %l3.preheader
l3.preheader:
br label %l3.header
l3.header:
%x1 = load i1, i1* %d, align 4
br i1 %x1, label %l2.latch, label %l4.preheader
l4.preheader:
br label %l4.header
l4.header:
%x2 = load i1, i1* %a
br i1 %x2, label %l3.latch, label %l4.body
l4.body:
call void @f(i32* %arrayidx.i)
%x3 = load i1, i1* %b
%l = trunc i64 %iv to i32
br i1 %x3, label %l4.latch, label %exit
l4.latch:
call void @g()
%x4 = load i1, i1* %b, align 4
br i1 %x4, label %l4.header, label %exit
l3.latch:
br label %l3.header
l2.latch:
br label %l2.header
l1.latch:
%iv.next = add nsw i64 %iv, 1
br label %l1.header
exit:
%lcssa = phi i32 [ %l, %l4.latch ], [ %l, %l4.body ]
ret i32 %lcssa
}
; @test12 moved to sink-promote.ll, as it tests sinking and promotion.
; Test that we don't crash when trying to sink stores and there's no preheader
; available (which is used for creating loads that may be used by the SSA
; updater)
define void @test13() {
; CHECK-LABEL: @test13(
; CHECK-NEXT: br label [[LAB59:%.*]]
; CHECK: lab19:
; CHECK-NEXT: br i1 false, label [[LAB20:%.*]], label [[LAB38_LOOPEXIT:%.*]]
; CHECK: lab20:
; CHECK-NEXT: br label [[LAB60:%.*]]
; CHECK: lab21:
; CHECK-NEXT: br i1 undef, label [[LAB22:%.*]], label [[LAB38:%.*]]
; CHECK: lab22:
; CHECK-NEXT: br label [[LAB38]]
; CHECK: lab38.loopexit:
; CHECK-NEXT: br label [[LAB38]]
; CHECK: lab38:
; CHECK-NEXT: ret void
; CHECK: lab59:
; CHECK-NEXT: indirectbr i8* undef, [label [[LAB60]], label %lab38]
; CHECK: lab60:
; CHECK-NEXT: store i32 2145244101, i32* undef, align 4
; CHECK-NEXT: indirectbr i8* undef, [label [[LAB21:%.*]], label %lab19]
;
br label %lab59
lab19:
br i1 undef, label %lab20, label %lab38
lab20:
br label %lab60
lab21:
br i1 undef, label %lab22, label %lab38
lab22:
br label %lab38
lab38:
ret void
lab59:
indirectbr i8* undef, [label %lab60, label %lab38]
lab60:
store i32 2145244101, i32* undef, align 4
indirectbr i8* undef, [label %lab21, label %lab19]
}
; Check if LICM can sink a sinkable instruction the exit blocks through
; a non-trivially replacable PHI node.
define i32 @test14(i32 %N, i32 %N2, i1 %C) {
; CHECK-LABEL: @test14(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[N_ADDR_0_PN:%.*]] = phi i32 [ [[DEC:%.*]], [[CONTLOOP:%.*]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[DEC]] = add i32 [[N_ADDR_0_PN]], -1
; CHECK-NEXT: br i1 [[C:%.*]], label [[CONTLOOP]], label [[OUT12_SPLIT_LOOP_EXIT1:%.*]]
; CHECK: ContLoop:
; CHECK-NEXT: [[TMP_1:%.*]] = icmp ne i32 [[N_ADDR_0_PN]], 1
; CHECK-NEXT: br i1 [[TMP_1]], label [[LOOP]], label [[OUT12_SPLIT_LOOP_EXIT:%.*]]
; CHECK: Out12.split.loop.exit:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA4:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[CONTLOOP]] ]
; CHECK-NEXT: [[SINK_MUL_LE3:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA4]]
; CHECK-NEXT: br label [[OUT12:%.*]]
; CHECK: Out12.split.loop.exit1:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[LOOP]] ]
; CHECK-NEXT: [[SINK_MUL_LE:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA]]
; CHECK-NEXT: [[SINK_SUB_LE:%.*]] = sub i32 [[SINK_MUL_LE]], [[N]]
; CHECK-NEXT: br label [[OUT12]]
; CHECK: Out12:
; CHECK-NEXT: [[TMP:%.*]] = phi i32 [ [[SINK_MUL_LE3]], [[OUT12_SPLIT_LOOP_EXIT]] ], [ [[SINK_SUB_LE]], [[OUT12_SPLIT_LOOP_EXIT1]] ]
; CHECK-NEXT: ret i32 [[TMP]]
;
Entry:
br label %Loop
Loop:
%N_addr.0.pn = phi i32 [ %dec, %ContLoop ], [ %N, %Entry ]
%sink.mul = mul i32 %N, %N_addr.0.pn
%sink.sub = sub i32 %sink.mul, %N
%dec = add i32 %N_addr.0.pn, -1
br i1 %C, label %ContLoop, label %Out12
ContLoop:
%tmp.1 = icmp ne i32 %N_addr.0.pn, 1
br i1 %tmp.1, label %Loop, label %Out12
Out12:
%tmp = phi i32 [%sink.mul, %ContLoop], [%sink.sub, %Loop]
ret i32 %tmp
}
; In this test, splitting predecessors is not really required because the
; operations of sinkable instructions (sub and mul) are same. In this case, we
; can sink the same sinkable operations and modify the PHI to pass the operands
; to the shared operations. As of now, we split predecessors of non-trivially
; replicalbe PHIs by default in LICM because all incoming edges of a
; non-trivially replacable PHI in LCSSA is critical.
define i32 @test15(i32 %N, i32 %N2, i1 %C) {
; CHECK-LABEL: @test15(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[N_ADDR_0_PN:%.*]] = phi i32 [ [[DEC:%.*]], [[CONTLOOP:%.*]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[DEC]] = add i32 [[N_ADDR_0_PN]], -1
; CHECK-NEXT: br i1 [[C:%.*]], label [[CONTLOOP]], label [[OUT12_SPLIT_LOOP_EXIT1:%.*]]
; CHECK: ContLoop:
; CHECK-NEXT: [[TMP_1:%.*]] = icmp ne i32 [[N_ADDR_0_PN]], 1
; CHECK-NEXT: br i1 [[TMP_1]], label [[LOOP]], label [[OUT12_SPLIT_LOOP_EXIT:%.*]]
; CHECK: Out12.split.loop.exit:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA5:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[CONTLOOP]] ]
; CHECK-NEXT: [[SINK_MUL_LE4:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA5]]
; CHECK-NEXT: [[SINK_SUB2_LE:%.*]] = sub i32 [[SINK_MUL_LE4]], [[N2:%.*]]
; CHECK-NEXT: br label [[OUT12:%.*]]
; CHECK: Out12.split.loop.exit1:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[LOOP]] ]
; CHECK-NEXT: [[SINK_MUL_LE:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA]]
; CHECK-NEXT: [[SINK_SUB_LE:%.*]] = sub i32 [[SINK_MUL_LE]], [[N]]
; CHECK-NEXT: br label [[OUT12]]
; CHECK: Out12:
; CHECK-NEXT: [[TMP:%.*]] = phi i32 [ [[SINK_SUB2_LE]], [[OUT12_SPLIT_LOOP_EXIT]] ], [ [[SINK_SUB_LE]], [[OUT12_SPLIT_LOOP_EXIT1]] ]
; CHECK-NEXT: ret i32 [[TMP]]
;
Entry:
br label %Loop
Loop:
%N_addr.0.pn = phi i32 [ %dec, %ContLoop ], [ %N, %Entry ]
%sink.mul = mul i32 %N, %N_addr.0.pn
%sink.sub = sub i32 %sink.mul, %N
%sink.sub2 = sub i32 %sink.mul, %N2
%dec = add i32 %N_addr.0.pn, -1
br i1 %C, label %ContLoop, label %Out12
ContLoop:
%tmp.1 = icmp ne i32 %N_addr.0.pn, 1
br i1 %tmp.1, label %Loop, label %Out12
Out12:
%tmp = phi i32 [%sink.sub2, %ContLoop], [%sink.sub, %Loop]
ret i32 %tmp
}
; Sink through a non-trivially replacable PHI node which use the same sinkable
; instruction multiple times.
define i32 @test16(i1 %c, i8** %P, i32* %P2, i64 %V) {
; CHECK-LABEL: @test16(
; CHECK-NEXT: entry:
; CHECK-NEXT: br label [[LOOP_PH:%.*]]
; CHECK: loop.ph:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[IV:%.*]] = phi i64 [ 0, [[LOOP_PH]] ], [ [[NEXT:%.*]], [[CONTLOOP:%.*]] ]
; CHECK-NEXT: [[L2:%.*]] = call i32 @getv()
; CHECK-NEXT: switch i32 [[L2]], label [[CONTLOOP]] [
; CHECK-NEXT: i32 32, label [[OUT_SPLIT_LOOP_EXIT1:%.*]]
; CHECK-NEXT: i32 46, label [[OUT_SPLIT_LOOP_EXIT1]]
; CHECK-NEXT: i32 95, label [[OUT_SPLIT_LOOP_EXIT1]]
; CHECK-NEXT: ]
; CHECK: ContLoop:
; CHECK-NEXT: [[NEXT]] = add nuw i64 [[IV]], 1
; CHECK-NEXT: [[C1:%.*]] = call i1 @getc()
; CHECK-NEXT: br i1 [[C1]], label [[LOOP]], label [[OUT_SPLIT_LOOP_EXIT:%.*]]
; CHECK: Out.split.loop.exit:
; CHECK-NEXT: [[IDX_PH:%.*]] = phi i32 [ [[L2]], [[CONTLOOP]] ]
; CHECK-NEXT: br label [[OUT:%.*]]
; CHECK: Out.split.loop.exit1:
; CHECK-NEXT: [[IV_LCSSA:%.*]] = phi i64 [ [[IV]], [[LOOP]] ], [ [[IV]], [[LOOP]] ], [ [[IV]], [[LOOP]] ]
; CHECK-NEXT: [[L2_LCSSA:%.*]] = phi i32 [ [[L2]], [[LOOP]] ], [ [[L2]], [[LOOP]] ], [ [[L2]], [[LOOP]] ]
; CHECK-NEXT: [[T_LE:%.*]] = trunc i64 [[IV_LCSSA]] to i32
; CHECK-NEXT: [[SINKABLE_LE:%.*]] = mul i32 [[L2_LCSSA]], [[T_LE]]
; CHECK-NEXT: br label [[OUT]]
; CHECK: Out:
; CHECK-NEXT: [[IDX:%.*]] = phi i32 [ [[IDX_PH]], [[OUT_SPLIT_LOOP_EXIT]] ], [ [[SINKABLE_LE]], [[OUT_SPLIT_LOOP_EXIT1]] ]
; CHECK-NEXT: ret i32 [[IDX]]
;
entry:
br label %loop.ph
loop.ph:
br label %Loop
Loop:
%iv = phi i64 [ 0, %loop.ph ], [ %next, %ContLoop ]
%l2 = call i32 @getv()
%t = trunc i64 %iv to i32
%sinkable = mul i32 %l2, %t
switch i32 %l2, label %ContLoop [
i32 32, label %Out
i32 46, label %Out
i32 95, label %Out
]
ContLoop:
%next = add nuw i64 %iv, 1
%c1 = call i1 @getc()
br i1 %c1, label %Loop, label %Out
Out:
%idx = phi i32 [ %l2, %ContLoop ], [ %sinkable, %Loop ], [ %sinkable, %Loop ], [ %sinkable, %Loop ]
ret i32 %idx
}
; Sink a sinkable instruction through multiple non-trivially replacable PHIs in
; differect exit blocks.
define i32 @test17(i32 %N, i32 %N2) {
; CHECK-LABEL: @test17(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[N_ADDR_0_PN:%.*]] = phi i32 [ [[DEC:%.*]], [[CONTLOOP3:%.*]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[C0:%.*]] = call i1 @getc()
; CHECK-NEXT: br i1 [[C0]], label [[CONTLOOP1:%.*]], label [[OUTA_SPLIT_LOOP_EXIT3:%.*]]
; CHECK: ContLoop1:
; CHECK-NEXT: [[C1:%.*]] = call i1 @getc()
; CHECK-NEXT: br i1 [[C1]], label [[CONTLOOP2:%.*]], label [[OUTA_SPLIT_LOOP_EXIT:%.*]]
; CHECK: ContLoop2:
; CHECK-NEXT: [[C2:%.*]] = call i1 @getc()
; CHECK-NEXT: br i1 [[C2]], label [[CONTLOOP3]], label [[OUTB_SPLIT_LOOP_EXIT1:%.*]]
; CHECK: ContLoop3:
; CHECK-NEXT: [[C3:%.*]] = call i1 @getc()
; CHECK-NEXT: [[DEC]] = add i32 [[N_ADDR_0_PN]], -1
; CHECK-NEXT: br i1 [[C3]], label [[LOOP]], label [[OUTB_SPLIT_LOOP_EXIT:%.*]]
; CHECK: OutA.split.loop.exit:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[CONTLOOP1]] ]
; CHECK-NEXT: [[SINK_MUL_LE:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA]]
; CHECK-NEXT: br label [[OUTA:%.*]]
; CHECK: OutA.split.loop.exit3:
; CHECK-NEXT: [[TMP1_PH4:%.*]] = phi i32 [ [[N2:%.*]], [[LOOP]] ]
; CHECK-NEXT: br label [[OUTA]]
; CHECK: OutA:
; CHECK-NEXT: [[TMP1:%.*]] = phi i32 [ [[SINK_MUL_LE]], [[OUTA_SPLIT_LOOP_EXIT]] ], [ [[TMP1_PH4]], [[OUTA_SPLIT_LOOP_EXIT3]] ]
; CHECK-NEXT: br label [[OUT12:%.*]]
; CHECK: OutB.split.loop.exit:
; CHECK-NEXT: [[TMP2_PH:%.*]] = phi i32 [ [[DEC]], [[CONTLOOP3]] ]
; CHECK-NEXT: br label [[OUTB:%.*]]
; CHECK: OutB.split.loop.exit1:
; CHECK-NEXT: [[N_ADDR_0_PN_LCSSA6:%.*]] = phi i32 [ [[N_ADDR_0_PN]], [[CONTLOOP2]] ]
; CHECK-NEXT: [[SINK_MUL_LE5:%.*]] = mul i32 [[N]], [[N_ADDR_0_PN_LCSSA6]]
; CHECK-NEXT: br label [[OUTB]]
; CHECK: OutB:
; CHECK-NEXT: [[TMP2:%.*]] = phi i32 [ [[TMP2_PH]], [[OUTB_SPLIT_LOOP_EXIT]] ], [ [[SINK_MUL_LE5]], [[OUTB_SPLIT_LOOP_EXIT1]] ]
; CHECK-NEXT: br label [[OUT12]]
; CHECK: Out12:
; CHECK-NEXT: [[TMP:%.*]] = phi i32 [ [[TMP1]], [[OUTA]] ], [ [[TMP2]], [[OUTB]] ]
; CHECK-NEXT: ret i32 [[TMP]]
;
Entry:
br label %Loop
Loop:
%N_addr.0.pn = phi i32 [ %dec, %ContLoop3 ], [ %N, %Entry ]
%sink.mul = mul i32 %N, %N_addr.0.pn
%c0 = call i1 @getc()
br i1 %c0 , label %ContLoop1, label %OutA
ContLoop1:
%c1 = call i1 @getc()
br i1 %c1, label %ContLoop2, label %OutA
ContLoop2:
%c2 = call i1 @getc()
br i1 %c2, label %ContLoop3, label %OutB
ContLoop3:
%c3 = call i1 @getc()
%dec = add i32 %N_addr.0.pn, -1
br i1 %c3, label %Loop, label %OutB
OutA:
%tmp1 = phi i32 [%sink.mul, %ContLoop1], [%N2, %Loop]
br label %Out12
OutB:
%tmp2 = phi i32 [%sink.mul, %ContLoop2], [%dec, %ContLoop3]
br label %Out12
Out12:
%tmp = phi i32 [%tmp1, %OutA], [%tmp2, %OutB]
ret i32 %tmp
}
; Sink a sinkable instruction through both trivially and non-trivially replacable PHIs.
define i32 @test18(i32 %N, i32 %N2) {
; CHECK-LABEL: @test18(
; CHECK-NEXT: Entry:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: [[IV:%.*]] = phi i32 [ [[DEC:%.*]], [[CONTLOOP:%.*]] ], [ [[N:%.*]], [[ENTRY:%.*]] ]
; CHECK-NEXT: [[C0:%.*]] = call i1 @getc()
; CHECK-NEXT: br i1 [[C0]], label [[CONTLOOP]], label [[OUT12_SPLIT_LOOP_EXIT1:%.*]]
; CHECK: ContLoop:
; CHECK-NEXT: [[DEC]] = add i32 [[IV]], -1
; CHECK-NEXT: [[C1:%.*]] = call i1 @getc()
; CHECK-NEXT: br i1 [[C1]], label [[LOOP]], label [[OUT12_SPLIT_LOOP_EXIT:%.*]]
; CHECK: Out12.split.loop.exit:
; CHECK-NEXT: [[IV_LCSSA:%.*]] = phi i32 [ [[IV]], [[CONTLOOP]] ]
; CHECK-NEXT: [[TMP2_PH:%.*]] = phi i32 [ [[DEC]], [[CONTLOOP]] ]
; CHECK-NEXT: [[SINK_MUL_LE:%.*]] = mul i32 [[N]], [[IV_LCSSA]]
; CHECK-NEXT: [[SINK_SUB_LE4:%.*]] = sub i32 [[SINK_MUL_LE]], [[N2:%.*]]
; CHECK-NEXT: br label [[OUT12:%.*]]
; CHECK: Out12.split.loop.exit1:
; CHECK-NEXT: [[IV_LCSSA7:%.*]] = phi i32 [ [[IV]], [[LOOP]] ]
; CHECK-NEXT: [[SINK_MUL_LE6:%.*]] = mul i32 [[N]], [[IV_LCSSA7]]
; CHECK-NEXT: [[SINK_SUB_LE:%.*]] = sub i32 [[SINK_MUL_LE6]], [[N2]]
; CHECK-NEXT: br label [[OUT12]]
; CHECK: Out12:
; CHECK-NEXT: [[TMP1:%.*]] = phi i32 [ [[SINK_SUB_LE4]], [[OUT12_SPLIT_LOOP_EXIT]] ], [ [[SINK_SUB_LE]], [[OUT12_SPLIT_LOOP_EXIT1]] ]
; CHECK-NEXT: [[TMP2:%.*]] = phi i32 [ [[TMP2_PH]], [[OUT12_SPLIT_LOOP_EXIT]] ], [ [[SINK_SUB_LE]], [[OUT12_SPLIT_LOOP_EXIT1]] ]
; CHECK-NEXT: [[ADD:%.*]] = add i32 [[TMP1]], [[TMP2]]
; CHECK-NEXT: ret i32 [[ADD]]
;
Entry:
br label %Loop
Loop:
%iv = phi i32 [ %dec, %ContLoop ], [ %N, %Entry ]
%sink.mul = mul i32 %N, %iv
%sink.sub = sub i32 %sink.mul, %N2
%c0 = call i1 @getc()
br i1 %c0, label %ContLoop, label %Out12
ContLoop:
%dec = add i32 %iv, -1
%c1 = call i1 @getc()
br i1 %c1, label %Loop, label %Out12
Out12:
%tmp1 = phi i32 [%sink.sub, %ContLoop], [%sink.sub, %Loop]
%tmp2 = phi i32 [%dec, %ContLoop], [%sink.sub, %Loop]
%add = add i32 %tmp1, %tmp2
ret i32 %add
}
; Do not sink an instruction through a non-trivially replacable PHI, to avoid
; assert while splitting predecessors, if the terminator of predecessor is an
; indirectbr.
define i32 @test19(i1 %cond, i1 %cond2, i8* %address, i32 %v1) nounwind {
; CHECK-LABEL: @test19(
; CHECK-NEXT: entry:
; CHECK-NEXT: [[INDIRECT_GOTO_DEST:%.*]] = select i1 [[COND:%.*]], i8* blockaddress(@test19, [[EXIT:%.*]]), i8* [[ADDRESS:%.*]]
; CHECK-NEXT: [[INDIRECT_GOTO_DEST2:%.*]] = select i1 [[COND2:%.*]], i8* blockaddress(@test19, [[EXIT]]), i8* [[ADDRESS]]
; CHECK-NEXT: br label [[L0:%.*]]
; CHECK: L0:
; CHECK-NEXT: [[V2:%.*]] = call i32 @getv()
; CHECK-NEXT: [[SINKABLE:%.*]] = mul i32 [[V1:%.*]], [[V2]]
; CHECK-NEXT: [[SINKABLE2:%.*]] = add i32 [[V1]], [[V2]]
; CHECK-NEXT: indirectbr i8* [[INDIRECT_GOTO_DEST]], [label [[L1:%.*]], label %exit]
; CHECK: L1:
; CHECK-NEXT: indirectbr i8* [[INDIRECT_GOTO_DEST2]], [label [[L0]], label %exit]
; CHECK: exit:
; CHECK-NEXT: [[R:%.*]] = phi i32 [ [[SINKABLE]], [[L0]] ], [ [[SINKABLE2]], [[L1]] ]
; CHECK-NEXT: ret i32 [[R]]
;
entry:
br label %L0
L0:
%indirect.goto.dest = select i1 %cond, i8* blockaddress(@test19, %exit), i8* %address
%v2 = call i32 @getv()
%sinkable = mul i32 %v1, %v2
%sinkable2 = add i32 %v1, %v2
indirectbr i8* %indirect.goto.dest, [label %L1, label %exit]
L1:
%indirect.goto.dest2 = select i1 %cond2, i8* blockaddress(@test19, %exit), i8* %address
indirectbr i8* %indirect.goto.dest2, [label %L0, label %exit]
exit:
%r = phi i32 [%sinkable, %L0], [%sinkable2, %L1]
ret i32 %r
}
; Do not sink through a non-trivially replacable PHI if splitting predecessors
; not allowed in SplitBlockPredecessors().
define void @test20(i32* %s, i1 %b, i32 %v1, i32 %v2) personality i32 (...)* @__CxxFrameHandler3 {
; CHECK-LABEL: @test20(
; CHECK-NEXT: entry:
; CHECK-NEXT: br label [[WHILE_COND:%.*]]
; CHECK: while.cond:
; CHECK-NEXT: [[V:%.*]] = call i32 @getv()
; CHECK-NEXT: [[SINKABLE:%.*]] = mul i32 [[V]], [[V2:%.*]]
; CHECK-NEXT: [[SINKABLE2:%.*]] = add i32 [[V]], [[V2]]
; CHECK-NEXT: br i1 [[B:%.*]], label [[TRY_CONT:%.*]], label [[WHILE_BODY:%.*]]
; CHECK: while.body:
; CHECK-NEXT: invoke void @may_throw()
; CHECK-NEXT: to label [[WHILE_BODY2:%.*]] unwind label [[CATCH_DISPATCH:%.*]]
; CHECK: while.body2:
; CHECK-NEXT: invoke void @may_throw2()
; CHECK-NEXT: to label [[WHILE_COND]] unwind label [[CATCH_DISPATCH]]
; CHECK: catch.dispatch:
; CHECK-NEXT: [[DOTLCSSA1:%.*]] = phi i32 [ [[SINKABLE]], [[WHILE_BODY]] ], [ [[SINKABLE2]], [[WHILE_BODY2]] ]
; CHECK-NEXT: [[CP:%.*]] = cleanuppad within none []
; CHECK-NEXT: store i32 [[DOTLCSSA1]], i32* [[S:%.*]], align 4
; CHECK-NEXT: cleanupret from [[CP]] unwind to caller
; CHECK: try.cont:
; CHECK-NEXT: ret void
;
entry:
br label %while.cond
while.cond:
%v = call i32 @getv()
%sinkable = mul i32 %v, %v2
%sinkable2 = add i32 %v, %v2
br i1 %b, label %try.cont, label %while.body
while.body:
invoke void @may_throw()
to label %while.body2 unwind label %catch.dispatch
while.body2:
invoke void @may_throw2()
to label %while.cond unwind label %catch.dispatch
catch.dispatch:
%.lcssa1 = phi i32 [ %sinkable, %while.body ], [ %sinkable2, %while.body2 ]
%cp = cleanuppad within none []
store i32 %.lcssa1, i32* %s
cleanupret from %cp unwind to caller
try.cont:
ret void
}
; The sinkable call should be sunk into an exit block split. After splitting
; the exit block, BlockColor for new blocks should be added properly so
; that we should be able to access valid ColorVector.
define i32 @test21_pr36184(i8* %P) personality i32 (...)* @__CxxFrameHandler3 {
; CHECK-LABEL: @test21_pr36184(
; CHECK-NEXT: entry:
; CHECK-NEXT: br label [[LOOP_PH:%.*]]
; CHECK: loop.ph:
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: Loop:
; CHECK-NEXT: br i1 false, label [[CONTLOOP:%.*]], label [[OUT_SPLIT_LOOP_EXIT1:%.*]]
; CHECK: ContLoop:
; CHECK-NEXT: br i1 false, label [[LOOP]], label [[OUT_SPLIT_LOOP_EXIT:%.*]]
; CHECK: Out.split.loop.exit:
; CHECK-NEXT: [[IDX_PH:%.*]] = phi i32 [ 0, [[CONTLOOP]] ]
; CHECK-NEXT: br label [[OUT:%.*]]
; CHECK: Out.split.loop.exit1:
; CHECK-NEXT: [[SINKABLECALL_LE:%.*]] = call i32 @strlen(i8* [[P:%.*]]) #[[ATTR3]]
; CHECK-NEXT: br label [[OUT]]
; CHECK: Out:
; CHECK-NEXT: [[IDX:%.*]] = phi i32 [ [[IDX_PH]], [[OUT_SPLIT_LOOP_EXIT]] ], [ [[SINKABLECALL_LE]], [[OUT_SPLIT_LOOP_EXIT1]] ]
; CHECK-NEXT: ret i32 [[IDX]]
;
entry:
br label %loop.ph
loop.ph:
br label %Loop
Loop:
%sinkableCall = call i32 @strlen( i8* %P ) readonly
br i1 undef, label %ContLoop, label %Out
ContLoop:
br i1 undef, label %Loop, label %Out
Out:
%idx = phi i32 [ %sinkableCall, %Loop ], [0, %ContLoop ]
ret i32 %idx
}
; We do not support splitting a landingpad block if BlockColors is not empty.
define void @test22(i1 %b, i32 %v1, i32 %v2) personality i32 (...)* @__CxxFrameHandler3 {
; CHECK-LABEL: @test22(
; CHECK-NEXT: entry:
; CHECK-NEXT: br label [[WHILE_COND:%.*]]
; CHECK: while.cond:
; CHECK-NEXT: br i1 [[B:%.*]], label [[TRY_CONT:%.*]], label [[WHILE_BODY:%.*]]
; CHECK: while.body:
; CHECK-NEXT: invoke void @may_throw()
; CHECK-NEXT: to label [[WHILE_BODY2:%.*]] unwind label [[LPADBB:%.*]]
; CHECK: while.body2:
; CHECK-NEXT: [[V:%.*]] = call i32 @getv()
; CHECK-NEXT: [[MUL:%.*]] = mul i32 [[V]], [[V2:%.*]]
; CHECK-NEXT: invoke void @may_throw2()
; CHECK-NEXT: to label [[WHILE_COND]] unwind label [[LPADBB]]
; CHECK: lpadBB:
; CHECK-NEXT: [[DOTLCSSA1:%.*]] = phi i32 [ 0, [[WHILE_BODY]] ], [ [[MUL]], [[WHILE_BODY2]] ]
; CHECK-NEXT: [[TMP0:%.*]] = landingpad { i8*, i32 }
; CHECK-NEXT: catch i8* null
; CHECK-NEXT: br label [[LPADBBSUCC1:%.*]]
; CHECK: lpadBBSucc1:
; CHECK-NEXT: ret void
; CHECK: try.cont:
; CHECK-NEXT: ret void
;
entry:
br label %while.cond
while.cond:
br i1 %b, label %try.cont, label %while.body
while.body:
invoke void @may_throw()
to label %while.body2 unwind label %lpadBB
while.body2:
%v = call i32 @getv()
%mul = mul i32 %v, %v2
invoke void @may_throw2()
to label %while.cond unwind label %lpadBB
lpadBB:
%.lcssa1 = phi i32 [ 0, %while.body ], [ %mul, %while.body2 ]
landingpad { i8*, i32 }
catch i8* null
br label %lpadBBSucc1
lpadBBSucc1:
ret void
try.cont:
ret void
}
define i32 @not_willreturn(i8* %p) {
; CHECK-LABEL: @not_willreturn(
; CHECK-NEXT: [[X:%.*]] = call i32 @getv() #[[ATTR5:[0-9]+]]
; CHECK-NEXT: br label [[LOOP:%.*]]
; CHECK: loop:
; CHECK-NEXT: store volatile i8 0, i8* [[P:%.*]], align 1
; CHECK-NEXT: br i1 true, label [[LOOP]], label [[OUT:%.*]]
; CHECK: out:
; CHECK-NEXT: [[X_LCSSA:%.*]] = phi i32 [ [[X]], [[LOOP]] ]
; CHECK-NEXT: ret i32 [[X_LCSSA]]
;
br label %loop
loop:
%x = call i32 @getv() nounwind readnone
store volatile i8 0, i8* %p
br i1 true, label %loop, label %out
out:
ret i32 %x
}
declare void @may_throw()
declare void @may_throw2()
declare i32 @__CxxFrameHandler3(...)
declare i32 @getv()
declare i1 @getc()
declare void @f(i32*)
declare void @g()