| ; RUN: llc -mtriple=i686-linux < %s | FileCheck %s |
| |
| declare void @error(i32 %i, i32 %a, i32 %b) |
| |
| define i32 @test_ifchains(i32 %i, i32* %a, i32 %b) { |
| ; Test a chain of ifs, where the block guarded by the if is error handling code |
| ; that is not expected to run. |
| ; CHECK: test_ifchains: |
| ; CHECK: %entry |
| ; CHECK-NOT: .align |
| ; CHECK: %else1 |
| ; CHECK-NOT: .align |
| ; CHECK: %else2 |
| ; CHECK-NOT: .align |
| ; CHECK: %else3 |
| ; CHECK-NOT: .align |
| ; CHECK: %else4 |
| ; CHECK-NOT: .align |
| ; CHECK: %exit |
| ; CHECK: %then1 |
| ; CHECK: %then2 |
| ; CHECK: %then3 |
| ; CHECK: %then4 |
| ; CHECK: %then5 |
| |
| entry: |
| %gep1 = getelementptr i32* %a, i32 1 |
| %val1 = load i32* %gep1 |
| %cond1 = icmp ugt i32 %val1, 1 |
| br i1 %cond1, label %then1, label %else1, !prof !0 |
| |
| then1: |
| call void @error(i32 %i, i32 1, i32 %b) |
| br label %else1 |
| |
| else1: |
| %gep2 = getelementptr i32* %a, i32 2 |
| %val2 = load i32* %gep2 |
| %cond2 = icmp ugt i32 %val2, 2 |
| br i1 %cond2, label %then2, label %else2, !prof !0 |
| |
| then2: |
| call void @error(i32 %i, i32 1, i32 %b) |
| br label %else2 |
| |
| else2: |
| %gep3 = getelementptr i32* %a, i32 3 |
| %val3 = load i32* %gep3 |
| %cond3 = icmp ugt i32 %val3, 3 |
| br i1 %cond3, label %then3, label %else3, !prof !0 |
| |
| then3: |
| call void @error(i32 %i, i32 1, i32 %b) |
| br label %else3 |
| |
| else3: |
| %gep4 = getelementptr i32* %a, i32 4 |
| %val4 = load i32* %gep4 |
| %cond4 = icmp ugt i32 %val4, 4 |
| br i1 %cond4, label %then4, label %else4, !prof !0 |
| |
| then4: |
| call void @error(i32 %i, i32 1, i32 %b) |
| br label %else4 |
| |
| else4: |
| %gep5 = getelementptr i32* %a, i32 3 |
| %val5 = load i32* %gep5 |
| %cond5 = icmp ugt i32 %val5, 3 |
| br i1 %cond5, label %then5, label %exit, !prof !0 |
| |
| then5: |
| call void @error(i32 %i, i32 1, i32 %b) |
| br label %exit |
| |
| exit: |
| ret i32 %b |
| } |
| |
| define i32 @test_loop_cold_blocks(i32 %i, i32* %a) { |
| ; Check that we sink cold loop blocks after the hot loop body. |
| ; CHECK: test_loop_cold_blocks: |
| ; CHECK: %entry |
| ; CHECK-NOT: .align |
| ; CHECK: %unlikely1 |
| ; CHECK-NOT: .align |
| ; CHECK: %unlikely2 |
| ; CHECK: .align |
| ; CHECK: %body1 |
| ; CHECK: %body2 |
| ; CHECK: %body3 |
| ; CHECK: %exit |
| |
| entry: |
| br label %body1 |
| |
| body1: |
| %iv = phi i32 [ 0, %entry ], [ %next, %body3 ] |
| %base = phi i32 [ 0, %entry ], [ %sum, %body3 ] |
| %unlikelycond1 = icmp slt i32 %base, 42 |
| br i1 %unlikelycond1, label %unlikely1, label %body2, !prof !0 |
| |
| unlikely1: |
| call void @error(i32 %i, i32 1, i32 %base) |
| br label %body2 |
| |
| body2: |
| %unlikelycond2 = icmp sgt i32 %base, 21 |
| br i1 %unlikelycond2, label %unlikely2, label %body3, !prof !0 |
| |
| unlikely2: |
| call void @error(i32 %i, i32 2, i32 %base) |
| br label %body3 |
| |
| body3: |
| %arrayidx = getelementptr inbounds i32* %a, i32 %iv |
| %0 = load i32* %arrayidx |
| %sum = add nsw i32 %0, %base |
| %next = add i32 %iv, 1 |
| %exitcond = icmp eq i32 %next, %i |
| br i1 %exitcond, label %exit, label %body1 |
| |
| exit: |
| ret i32 %sum |
| } |
| |
| !0 = metadata !{metadata !"branch_weights", i32 4, i32 64} |
| |
| define i32 @test_loop_early_exits(i32 %i, i32* %a) { |
| ; Check that we sink early exit blocks out of loop bodies. |
| ; CHECK: test_loop_early_exits: |
| ; CHECK: %entry |
| ; CHECK: %body1 |
| ; CHECK: %body2 |
| ; CHECK: %body3 |
| ; CHECK: %body4 |
| ; CHECK: %exit |
| ; CHECK: %bail1 |
| ; CHECK: %bail2 |
| ; CHECK: %bail3 |
| |
| entry: |
| br label %body1 |
| |
| body1: |
| %iv = phi i32 [ 0, %entry ], [ %next, %body4 ] |
| %base = phi i32 [ 0, %entry ], [ %sum, %body4 ] |
| %bailcond1 = icmp eq i32 %base, 42 |
| br i1 %bailcond1, label %bail1, label %body2 |
| |
| bail1: |
| ret i32 -1 |
| |
| body2: |
| %bailcond2 = icmp eq i32 %base, 43 |
| br i1 %bailcond2, label %bail2, label %body3 |
| |
| bail2: |
| ret i32 -2 |
| |
| body3: |
| %bailcond3 = icmp eq i32 %base, 44 |
| br i1 %bailcond3, label %bail3, label %body4 |
| |
| bail3: |
| ret i32 -3 |
| |
| body4: |
| %arrayidx = getelementptr inbounds i32* %a, i32 %iv |
| %0 = load i32* %arrayidx |
| %sum = add nsw i32 %0, %base |
| %next = add i32 %iv, 1 |
| %exitcond = icmp eq i32 %next, %i |
| br i1 %exitcond, label %exit, label %body1 |
| |
| exit: |
| ret i32 %sum |
| } |
| |
| define i32 @test_loop_rotate(i32 %i, i32* %a) { |
| ; Check that we rotate conditional exits from the loop to the bottom of the |
| ; loop, eliminating unconditional branches to the top. |
| ; CHECK: test_loop_rotate: |
| ; CHECK: %entry |
| ; CHECK: %body1 |
| ; CHECK: %body0 |
| ; CHECK: %exit |
| |
| entry: |
| br label %body0 |
| |
| body0: |
| %iv = phi i32 [ 0, %entry ], [ %next, %body1 ] |
| %base = phi i32 [ 0, %entry ], [ %sum, %body1 ] |
| %next = add i32 %iv, 1 |
| %exitcond = icmp eq i32 %next, %i |
| br i1 %exitcond, label %exit, label %body1 |
| |
| body1: |
| %arrayidx = getelementptr inbounds i32* %a, i32 %iv |
| %0 = load i32* %arrayidx |
| %sum = add nsw i32 %0, %base |
| %bailcond1 = icmp eq i32 %sum, 42 |
| br label %body0 |
| |
| exit: |
| ret i32 %base |
| } |
| |
| define i32 @test_no_loop_rotate(i32 %i, i32* %a) { |
| ; Check that we don't try to rotate a loop which is already laid out with |
| ; fallthrough opportunities into the top and out of the bottom. |
| ; CHECK: test_no_loop_rotate: |
| ; CHECK: %entry |
| ; CHECK: %body0 |
| ; CHECK: %body1 |
| ; CHECK: %exit |
| |
| entry: |
| br label %body0 |
| |
| body0: |
| %iv = phi i32 [ 0, %entry ], [ %next, %body1 ] |
| %base = phi i32 [ 0, %entry ], [ %sum, %body1 ] |
| %arrayidx = getelementptr inbounds i32* %a, i32 %iv |
| %0 = load i32* %arrayidx |
| %sum = add nsw i32 %0, %base |
| %bailcond1 = icmp eq i32 %sum, 42 |
| br i1 %bailcond1, label %exit, label %body1 |
| |
| body1: |
| %next = add i32 %iv, 1 |
| %exitcond = icmp eq i32 %next, %i |
| br i1 %exitcond, label %exit, label %body0 |
| |
| exit: |
| ret i32 %base |
| } |
| |
| define void @test_loop_rotate_reversed_blocks() { |
| ; This test case (greatly reduced from an Olden bencmark) ensures that the loop |
| ; rotate implementation doesn't assume that loops are laid out in a particular |
| ; order. The first loop will get split into two basic blocks, with the loop |
| ; header coming after the loop latch. |
| ; |
| ; CHECK: test_loop_rotate_reversed_blocks |
| ; CHECK: %entry |
| ; Look for a jump into the middle of the loop, and no branches mid-way. |
| ; CHECK: jmp |
| ; CHECK: %loop1 |
| ; CHECK-NOT: j{{\w*}} .LBB{{.*}} |
| ; CHECK: %loop1 |
| ; CHECK: je |
| |
| entry: |
| %cond1 = load volatile i1* undef |
| br i1 %cond1, label %loop2.preheader, label %loop1 |
| |
| loop1: |
| call i32 @f() |
| %cond2 = load volatile i1* undef |
| br i1 %cond2, label %loop2.preheader, label %loop1 |
| |
| loop2.preheader: |
| call i32 @f() |
| %cond3 = load volatile i1* undef |
| br i1 %cond3, label %exit, label %loop2 |
| |
| loop2: |
| call i32 @f() |
| %cond4 = load volatile i1* undef |
| br i1 %cond4, label %exit, label %loop2 |
| |
| exit: |
| ret void |
| } |
| |
| define i32 @test_loop_align(i32 %i, i32* %a) { |
| ; Check that we provide basic loop body alignment with the block placement |
| ; pass. |
| ; CHECK: test_loop_align: |
| ; CHECK: %entry |
| ; CHECK: .align [[ALIGN:[0-9]+]], |
| ; CHECK-NEXT: %body |
| ; CHECK: %exit |
| |
| entry: |
| br label %body |
| |
| body: |
| %iv = phi i32 [ 0, %entry ], [ %next, %body ] |
| %base = phi i32 [ 0, %entry ], [ %sum, %body ] |
| %arrayidx = getelementptr inbounds i32* %a, i32 %iv |
| %0 = load i32* %arrayidx |
| %sum = add nsw i32 %0, %base |
| %next = add i32 %iv, 1 |
| %exitcond = icmp eq i32 %next, %i |
| br i1 %exitcond, label %exit, label %body |
| |
| exit: |
| ret i32 %sum |
| } |
| |
| define i32 @test_nested_loop_align(i32 %i, i32* %a, i32* %b) { |
| ; Check that we provide nested loop body alignment. |
| ; CHECK: test_nested_loop_align: |
| ; CHECK: %entry |
| ; CHECK: .align [[ALIGN]], |
| ; CHECK-NEXT: %loop.body.1 |
| ; CHECK: .align [[ALIGN]], |
| ; CHECK-NEXT: %inner.loop.body |
| ; CHECK-NOT: .align |
| ; CHECK: %exit |
| |
| entry: |
| br label %loop.body.1 |
| |
| loop.body.1: |
| %iv = phi i32 [ 0, %entry ], [ %next, %loop.body.2 ] |
| %arrayidx = getelementptr inbounds i32* %a, i32 %iv |
| %bidx = load i32* %arrayidx |
| br label %inner.loop.body |
| |
| inner.loop.body: |
| %inner.iv = phi i32 [ 0, %loop.body.1 ], [ %inner.next, %inner.loop.body ] |
| %base = phi i32 [ 0, %loop.body.1 ], [ %sum, %inner.loop.body ] |
| %scaled_idx = mul i32 %bidx, %iv |
| %inner.arrayidx = getelementptr inbounds i32* %b, i32 %scaled_idx |
| %0 = load i32* %inner.arrayidx |
| %sum = add nsw i32 %0, %base |
| %inner.next = add i32 %iv, 1 |
| %inner.exitcond = icmp eq i32 %inner.next, %i |
| br i1 %inner.exitcond, label %loop.body.2, label %inner.loop.body |
| |
| loop.body.2: |
| %next = add i32 %iv, 1 |
| %exitcond = icmp eq i32 %next, %i |
| br i1 %exitcond, label %exit, label %loop.body.1 |
| |
| exit: |
| ret i32 %sum |
| } |
| |
| define void @unnatural_cfg1() { |
| ; Test that we can handle a loop with an inner unnatural loop at the end of |
| ; a function. This is a gross CFG reduced out of the single source GCC. |
| ; CHECK: unnatural_cfg1 |
| ; CHECK: %entry |
| ; CHECK: %loop.body1 |
| ; CHECK: %loop.body2 |
| ; CHECK: %loop.body3 |
| |
| entry: |
| br label %loop.header |
| |
| loop.header: |
| br label %loop.body1 |
| |
| loop.body1: |
| br i1 undef, label %loop.body3, label %loop.body2 |
| |
| loop.body2: |
| %ptr = load i32** undef, align 4 |
| br label %loop.body3 |
| |
| loop.body3: |
| %myptr = phi i32* [ %ptr2, %loop.body5 ], [ %ptr, %loop.body2 ], [ undef, %loop.body1 ] |
| %bcmyptr = bitcast i32* %myptr to i32* |
| %val = load i32* %bcmyptr, align 4 |
| %comp = icmp eq i32 %val, 48 |
| br i1 %comp, label %loop.body4, label %loop.body5 |
| |
| loop.body4: |
| br i1 undef, label %loop.header, label %loop.body5 |
| |
| loop.body5: |
| %ptr2 = load i32** undef, align 4 |
| br label %loop.body3 |
| } |
| |
| define void @unnatural_cfg2() { |
| ; Test that we can handle a loop with a nested natural loop *and* an unnatural |
| ; loop. This was reduced from a crash on block placement when run over |
| ; single-source GCC. |
| ; CHECK: unnatural_cfg2 |
| ; CHECK: %entry |
| ; CHECK: %loop.body1 |
| ; CHECK: %loop.body2 |
| ; CHECK: %loop.body3 |
| ; CHECK: %loop.inner1.begin |
| ; The end block is folded with %loop.body3... |
| ; CHECK-NOT: %loop.inner1.end |
| ; CHECK: %loop.body4 |
| ; CHECK: %loop.inner2.begin |
| ; The loop.inner2.end block is folded |
| ; CHECK: %loop.header |
| ; CHECK: %bail |
| |
| entry: |
| br label %loop.header |
| |
| loop.header: |
| %comp0 = icmp eq i32* undef, null |
| br i1 %comp0, label %bail, label %loop.body1 |
| |
| loop.body1: |
| %val0 = load i32** undef, align 4 |
| br i1 undef, label %loop.body2, label %loop.inner1.begin |
| |
| loop.body2: |
| br i1 undef, label %loop.body4, label %loop.body3 |
| |
| loop.body3: |
| %ptr1 = getelementptr inbounds i32* %val0, i32 0 |
| %castptr1 = bitcast i32* %ptr1 to i32** |
| %val1 = load i32** %castptr1, align 4 |
| br label %loop.inner1.begin |
| |
| loop.inner1.begin: |
| %valphi = phi i32* [ %val2, %loop.inner1.end ], [ %val1, %loop.body3 ], [ %val0, %loop.body1 ] |
| %castval = bitcast i32* %valphi to i32* |
| %comp1 = icmp eq i32 undef, 48 |
| br i1 %comp1, label %loop.inner1.end, label %loop.body4 |
| |
| loop.inner1.end: |
| %ptr2 = getelementptr inbounds i32* %valphi, i32 0 |
| %castptr2 = bitcast i32* %ptr2 to i32** |
| %val2 = load i32** %castptr2, align 4 |
| br label %loop.inner1.begin |
| |
| loop.body4.dead: |
| br label %loop.body4 |
| |
| loop.body4: |
| %comp2 = icmp ult i32 undef, 3 |
| br i1 %comp2, label %loop.inner2.begin, label %loop.end |
| |
| loop.inner2.begin: |
| br i1 false, label %loop.end, label %loop.inner2.end |
| |
| loop.inner2.end: |
| %comp3 = icmp eq i32 undef, 1769472 |
| br i1 %comp3, label %loop.end, label %loop.inner2.begin |
| |
| loop.end: |
| br label %loop.header |
| |
| bail: |
| unreachable |
| } |
| |
| define i32 @problematic_switch() { |
| ; This function's CFG caused overlow in the machine branch probability |
| ; calculation, triggering asserts. Make sure we don't crash on it. |
| ; CHECK: problematic_switch |
| |
| entry: |
| switch i32 undef, label %exit [ |
| i32 879, label %bogus |
| i32 877, label %step |
| i32 876, label %step |
| i32 875, label %step |
| i32 874, label %step |
| i32 873, label %step |
| i32 872, label %step |
| i32 868, label %step |
| i32 867, label %step |
| i32 866, label %step |
| i32 861, label %step |
| i32 860, label %step |
| i32 856, label %step |
| i32 855, label %step |
| i32 854, label %step |
| i32 831, label %step |
| i32 830, label %step |
| i32 829, label %step |
| i32 828, label %step |
| i32 815, label %step |
| i32 814, label %step |
| i32 811, label %step |
| i32 806, label %step |
| i32 805, label %step |
| i32 804, label %step |
| i32 803, label %step |
| i32 802, label %step |
| i32 801, label %step |
| i32 800, label %step |
| i32 799, label %step |
| i32 798, label %step |
| i32 797, label %step |
| i32 796, label %step |
| i32 795, label %step |
| ] |
| bogus: |
| unreachable |
| step: |
| br label %exit |
| exit: |
| %merge = phi i32 [ 3, %step ], [ 6, %entry ] |
| ret i32 %merge |
| } |
| |
| define void @fpcmp_unanalyzable_branch(i1 %cond) { |
| ; This function's CFG contains an unanalyzable branch that is likely to be |
| ; split due to having a different high-probability predecessor. |
| ; CHECK: fpcmp_unanalyzable_branch |
| ; CHECK: %entry |
| ; CHECK: %exit |
| ; CHECK-NOT: %if.then |
| ; CHECK-NOT: %if.end |
| ; CHECK-NOT: jne |
| ; CHECK-NOT: jnp |
| ; CHECK: jne |
| ; CHECK-NEXT: jnp |
| ; CHECK-NEXT: %if.then |
| |
| entry: |
| ; Note that this branch must be strongly biased toward |
| ; 'entry.if.then_crit_edge' to ensure that we would try to form a chain for |
| ; 'entry' -> 'entry.if.then_crit_edge' -> 'if.then'. It is the last edge in that |
| ; chain which would violate the unanalyzable branch in 'exit', but we won't even |
| ; try this trick unless 'if.then' is believed to almost always be reached from |
| ; 'entry.if.then_crit_edge'. |
| br i1 %cond, label %entry.if.then_crit_edge, label %lor.lhs.false, !prof !1 |
| |
| entry.if.then_crit_edge: |
| %.pre14 = load i8* undef, align 1, !tbaa !0 |
| br label %if.then |
| |
| lor.lhs.false: |
| br i1 undef, label %if.end, label %exit |
| |
| exit: |
| %cmp.i = fcmp une double 0.000000e+00, undef |
| br i1 %cmp.i, label %if.then, label %if.end |
| |
| if.then: |
| %0 = phi i8 [ %.pre14, %entry.if.then_crit_edge ], [ undef, %exit ] |
| %1 = and i8 %0, 1 |
| store i8 %1, i8* undef, align 4, !tbaa !0 |
| br label %if.end |
| |
| if.end: |
| ret void |
| } |
| |
| !1 = metadata !{metadata !"branch_weights", i32 1000, i32 1} |
| |
| declare i32 @f() |
| declare i32 @g() |
| declare i32 @h(i32 %x) |
| |
| define i32 @test_global_cfg_break_profitability() { |
| ; Check that our metrics for the profitability of a CFG break are global rather |
| ; than local. A successor may be very hot, but if the current block isn't, it |
| ; doesn't matter. Within this test the 'then' block is slightly warmer than the |
| ; 'else' block, but not nearly enough to merit merging it with the exit block |
| ; even though the probability of 'then' branching to the 'exit' block is very |
| ; high. |
| ; CHECK: test_global_cfg_break_profitability |
| ; CHECK: calll {{_?}}f |
| ; CHECK: calll {{_?}}g |
| ; CHECK: calll {{_?}}h |
| ; CHECK: ret |
| |
| entry: |
| br i1 undef, label %then, label %else, !prof !2 |
| |
| then: |
| %then.result = call i32 @f() |
| br label %exit |
| |
| else: |
| %else.result = call i32 @g() |
| br label %exit |
| |
| exit: |
| %result = phi i32 [ %then.result, %then ], [ %else.result, %else ] |
| %result2 = call i32 @h(i32 %result) |
| ret i32 %result |
| } |
| |
| !2 = metadata !{metadata !"branch_weights", i32 3, i32 1} |
| |
| declare i32 @__gxx_personality_v0(...) |
| |
| define void @test_eh_lpad_successor() { |
| ; Some times the landing pad ends up as the first successor of an invoke block. |
| ; When this happens, a strange result used to fall out of updateTerminators: we |
| ; didn't correctly locate the fallthrough successor, assuming blindly that the |
| ; first one was the fallthrough successor. As a result, we would add an |
| ; erroneous jump to the landing pad thinking *that* was the default successor. |
| ; CHECK: test_eh_lpad_successor |
| ; CHECK: %entry |
| ; CHECK-NOT: jmp |
| ; CHECK: %loop |
| |
| entry: |
| invoke i32 @f() to label %preheader unwind label %lpad |
| |
| preheader: |
| br label %loop |
| |
| lpad: |
| %lpad.val = landingpad { i8*, i32 } personality i8* bitcast (i32 (...)* @__gxx_personality_v0 to i8*) |
| cleanup |
| resume { i8*, i32 } %lpad.val |
| |
| loop: |
| br label %loop |
| } |
| |
| declare void @fake_throw() noreturn |
| |
| define void @test_eh_throw() { |
| ; For blocks containing a 'throw' (or similar functionality), we have |
| ; a no-return invoke. In this case, only EH successors will exist, and |
| ; fallthrough simply won't occur. Make sure we don't crash trying to update |
| ; terminators for such constructs. |
| ; |
| ; CHECK: test_eh_throw |
| ; CHECK: %entry |
| ; CHECK: %cleanup |
| |
| entry: |
| invoke void @fake_throw() to label %continue unwind label %cleanup |
| |
| continue: |
| unreachable |
| |
| cleanup: |
| %0 = landingpad { i8*, i32 } personality i8* bitcast (i32 (...)* @__gxx_personality_v0 to i8*) |
| cleanup |
| unreachable |
| } |
| |
| define void @test_unnatural_cfg_backwards_inner_loop() { |
| ; Test that when we encounter an unnatural CFG structure after having formed |
| ; a chain for an inner loop which happened to be laid out backwards we don't |
| ; attempt to merge onto the wrong end of the inner loop just because we find it |
| ; first. This was reduced from a crasher in GCC's single source. |
| ; |
| ; CHECK: test_unnatural_cfg_backwards_inner_loop |
| ; CHECK: %entry |
| ; CHECK: [[BODY:# BB#[0-9]+]]: |
| ; CHECK: %loop2b |
| ; CHECK: %loop1 |
| ; CHECK: %loop2a |
| |
| entry: |
| br i1 undef, label %loop2a, label %body |
| |
| body: |
| br label %loop2a |
| |
| loop1: |
| %next.load = load i32** undef |
| br i1 %comp.a, label %loop2a, label %loop2b |
| |
| loop2a: |
| %var = phi i32* [ null, %entry ], [ null, %body ], [ %next.phi, %loop1 ] |
| %next.var = phi i32* [ null, %entry ], [ undef, %body ], [ %next.load, %loop1 ] |
| %comp.a = icmp eq i32* %var, null |
| br label %loop3 |
| |
| loop2b: |
| %gep = getelementptr inbounds i32* %var.phi, i32 0 |
| %next.ptr = bitcast i32* %gep to i32** |
| store i32* %next.phi, i32** %next.ptr |
| br label %loop3 |
| |
| loop3: |
| %var.phi = phi i32* [ %next.phi, %loop2b ], [ %var, %loop2a ] |
| %next.phi = phi i32* [ %next.load, %loop2b ], [ %next.var, %loop2a ] |
| br label %loop1 |
| } |
| |
| define void @unanalyzable_branch_to_loop_header() { |
| ; Ensure that we can handle unanalyzable branches into loop headers. We |
| ; pre-form chains for unanalyzable branches, and will find the tail end of that |
| ; at the start of the loop. This function uses floating point comparison |
| ; fallthrough because that happens to always produce unanalyzable branches on |
| ; x86. |
| ; |
| ; CHECK: unanalyzable_branch_to_loop_header |
| ; CHECK: %entry |
| ; CHECK: %loop |
| ; CHECK: %exit |
| |
| entry: |
| %cmp = fcmp une double 0.000000e+00, undef |
| br i1 %cmp, label %loop, label %exit |
| |
| loop: |
| %cond = icmp eq i8 undef, 42 |
| br i1 %cond, label %exit, label %loop |
| |
| exit: |
| ret void |
| } |
| |
| define void @unanalyzable_branch_to_best_succ(i1 %cond) { |
| ; Ensure that we can handle unanalyzable branches where the destination block |
| ; gets selected as the optimal sucessor to merge. |
| ; |
| ; CHECK: unanalyzable_branch_to_best_succ |
| ; CHECK: %entry |
| ; CHECK: %foo |
| ; CHECK: %bar |
| ; CHECK: %exit |
| |
| entry: |
| ; Bias this branch toward bar to ensure we form that chain. |
| br i1 %cond, label %bar, label %foo, !prof !1 |
| |
| foo: |
| %cmp = fcmp une double 0.000000e+00, undef |
| br i1 %cmp, label %bar, label %exit |
| |
| bar: |
| call i32 @f() |
| br label %exit |
| |
| exit: |
| ret void |
| } |
| |
| define void @unanalyzable_branch_to_free_block(float %x) { |
| ; Ensure that we can handle unanalyzable branches where the destination block |
| ; gets selected as the best free block in the CFG. |
| ; |
| ; CHECK: unanalyzable_branch_to_free_block |
| ; CHECK: %entry |
| ; CHECK: %a |
| ; CHECK: %b |
| ; CHECK: %c |
| ; CHECK: %exit |
| |
| entry: |
| br i1 undef, label %a, label %b |
| |
| a: |
| call i32 @f() |
| br label %c |
| |
| b: |
| %cmp = fcmp une float %x, undef |
| br i1 %cmp, label %c, label %exit |
| |
| c: |
| call i32 @g() |
| br label %exit |
| |
| exit: |
| ret void |
| } |
| |
| define void @many_unanalyzable_branches() { |
| ; Ensure that we don't crash as we're building up many unanalyzable branches, |
| ; blocks, and loops. |
| ; |
| ; CHECK: many_unanalyzable_branches |
| ; CHECK: %entry |
| ; CHECK: %exit |
| |
| entry: |
| br label %0 |
| |
| %val0 = load volatile float* undef |
| %cmp0 = fcmp une float %val0, undef |
| br i1 %cmp0, label %1, label %0 |
| %val1 = load volatile float* undef |
| %cmp1 = fcmp une float %val1, undef |
| br i1 %cmp1, label %2, label %1 |
| %val2 = load volatile float* undef |
| %cmp2 = fcmp une float %val2, undef |
| br i1 %cmp2, label %3, label %2 |
| %val3 = load volatile float* undef |
| %cmp3 = fcmp une float %val3, undef |
| br i1 %cmp3, label %4, label %3 |
| %val4 = load volatile float* undef |
| %cmp4 = fcmp une float %val4, undef |
| br i1 %cmp4, label %5, label %4 |
| %val5 = load volatile float* undef |
| %cmp5 = fcmp une float %val5, undef |
| br i1 %cmp5, label %6, label %5 |
| %val6 = load volatile float* undef |
| %cmp6 = fcmp une float %val6, undef |
| br i1 %cmp6, label %7, label %6 |
| %val7 = load volatile float* undef |
| %cmp7 = fcmp une float %val7, undef |
| br i1 %cmp7, label %8, label %7 |
| %val8 = load volatile float* undef |
| %cmp8 = fcmp une float %val8, undef |
| br i1 %cmp8, label %9, label %8 |
| %val9 = load volatile float* undef |
| %cmp9 = fcmp une float %val9, undef |
| br i1 %cmp9, label %10, label %9 |
| %val10 = load volatile float* undef |
| %cmp10 = fcmp une float %val10, undef |
| br i1 %cmp10, label %11, label %10 |
| %val11 = load volatile float* undef |
| %cmp11 = fcmp une float %val11, undef |
| br i1 %cmp11, label %12, label %11 |
| %val12 = load volatile float* undef |
| %cmp12 = fcmp une float %val12, undef |
| br i1 %cmp12, label %13, label %12 |
| %val13 = load volatile float* undef |
| %cmp13 = fcmp une float %val13, undef |
| br i1 %cmp13, label %14, label %13 |
| %val14 = load volatile float* undef |
| %cmp14 = fcmp une float %val14, undef |
| br i1 %cmp14, label %15, label %14 |
| %val15 = load volatile float* undef |
| %cmp15 = fcmp une float %val15, undef |
| br i1 %cmp15, label %16, label %15 |
| %val16 = load volatile float* undef |
| %cmp16 = fcmp une float %val16, undef |
| br i1 %cmp16, label %17, label %16 |
| %val17 = load volatile float* undef |
| %cmp17 = fcmp une float %val17, undef |
| br i1 %cmp17, label %18, label %17 |
| %val18 = load volatile float* undef |
| %cmp18 = fcmp une float %val18, undef |
| br i1 %cmp18, label %19, label %18 |
| %val19 = load volatile float* undef |
| %cmp19 = fcmp une float %val19, undef |
| br i1 %cmp19, label %20, label %19 |
| %val20 = load volatile float* undef |
| %cmp20 = fcmp une float %val20, undef |
| br i1 %cmp20, label %21, label %20 |
| %val21 = load volatile float* undef |
| %cmp21 = fcmp une float %val21, undef |
| br i1 %cmp21, label %22, label %21 |
| %val22 = load volatile float* undef |
| %cmp22 = fcmp une float %val22, undef |
| br i1 %cmp22, label %23, label %22 |
| %val23 = load volatile float* undef |
| %cmp23 = fcmp une float %val23, undef |
| br i1 %cmp23, label %24, label %23 |
| %val24 = load volatile float* undef |
| %cmp24 = fcmp une float %val24, undef |
| br i1 %cmp24, label %25, label %24 |
| %val25 = load volatile float* undef |
| %cmp25 = fcmp une float %val25, undef |
| br i1 %cmp25, label %26, label %25 |
| %val26 = load volatile float* undef |
| %cmp26 = fcmp une float %val26, undef |
| br i1 %cmp26, label %27, label %26 |
| %val27 = load volatile float* undef |
| %cmp27 = fcmp une float %val27, undef |
| br i1 %cmp27, label %28, label %27 |
| %val28 = load volatile float* undef |
| %cmp28 = fcmp une float %val28, undef |
| br i1 %cmp28, label %29, label %28 |
| %val29 = load volatile float* undef |
| %cmp29 = fcmp une float %val29, undef |
| br i1 %cmp29, label %30, label %29 |
| %val30 = load volatile float* undef |
| %cmp30 = fcmp une float %val30, undef |
| br i1 %cmp30, label %31, label %30 |
| %val31 = load volatile float* undef |
| %cmp31 = fcmp une float %val31, undef |
| br i1 %cmp31, label %32, label %31 |
| %val32 = load volatile float* undef |
| %cmp32 = fcmp une float %val32, undef |
| br i1 %cmp32, label %33, label %32 |
| %val33 = load volatile float* undef |
| %cmp33 = fcmp une float %val33, undef |
| br i1 %cmp33, label %34, label %33 |
| %val34 = load volatile float* undef |
| %cmp34 = fcmp une float %val34, undef |
| br i1 %cmp34, label %35, label %34 |
| %val35 = load volatile float* undef |
| %cmp35 = fcmp une float %val35, undef |
| br i1 %cmp35, label %36, label %35 |
| %val36 = load volatile float* undef |
| %cmp36 = fcmp une float %val36, undef |
| br i1 %cmp36, label %37, label %36 |
| %val37 = load volatile float* undef |
| %cmp37 = fcmp une float %val37, undef |
| br i1 %cmp37, label %38, label %37 |
| %val38 = load volatile float* undef |
| %cmp38 = fcmp une float %val38, undef |
| br i1 %cmp38, label %39, label %38 |
| %val39 = load volatile float* undef |
| %cmp39 = fcmp une float %val39, undef |
| br i1 %cmp39, label %40, label %39 |
| %val40 = load volatile float* undef |
| %cmp40 = fcmp une float %val40, undef |
| br i1 %cmp40, label %41, label %40 |
| %val41 = load volatile float* undef |
| %cmp41 = fcmp une float %val41, undef |
| br i1 %cmp41, label %42, label %41 |
| %val42 = load volatile float* undef |
| %cmp42 = fcmp une float %val42, undef |
| br i1 %cmp42, label %43, label %42 |
| %val43 = load volatile float* undef |
| %cmp43 = fcmp une float %val43, undef |
| br i1 %cmp43, label %44, label %43 |
| %val44 = load volatile float* undef |
| %cmp44 = fcmp une float %val44, undef |
| br i1 %cmp44, label %45, label %44 |
| %val45 = load volatile float* undef |
| %cmp45 = fcmp une float %val45, undef |
| br i1 %cmp45, label %46, label %45 |
| %val46 = load volatile float* undef |
| %cmp46 = fcmp une float %val46, undef |
| br i1 %cmp46, label %47, label %46 |
| %val47 = load volatile float* undef |
| %cmp47 = fcmp une float %val47, undef |
| br i1 %cmp47, label %48, label %47 |
| %val48 = load volatile float* undef |
| %cmp48 = fcmp une float %val48, undef |
| br i1 %cmp48, label %49, label %48 |
| %val49 = load volatile float* undef |
| %cmp49 = fcmp une float %val49, undef |
| br i1 %cmp49, label %50, label %49 |
| %val50 = load volatile float* undef |
| %cmp50 = fcmp une float %val50, undef |
| br i1 %cmp50, label %51, label %50 |
| %val51 = load volatile float* undef |
| %cmp51 = fcmp une float %val51, undef |
| br i1 %cmp51, label %52, label %51 |
| %val52 = load volatile float* undef |
| %cmp52 = fcmp une float %val52, undef |
| br i1 %cmp52, label %53, label %52 |
| %val53 = load volatile float* undef |
| %cmp53 = fcmp une float %val53, undef |
| br i1 %cmp53, label %54, label %53 |
| %val54 = load volatile float* undef |
| %cmp54 = fcmp une float %val54, undef |
| br i1 %cmp54, label %55, label %54 |
| %val55 = load volatile float* undef |
| %cmp55 = fcmp une float %val55, undef |
| br i1 %cmp55, label %56, label %55 |
| %val56 = load volatile float* undef |
| %cmp56 = fcmp une float %val56, undef |
| br i1 %cmp56, label %57, label %56 |
| %val57 = load volatile float* undef |
| %cmp57 = fcmp une float %val57, undef |
| br i1 %cmp57, label %58, label %57 |
| %val58 = load volatile float* undef |
| %cmp58 = fcmp une float %val58, undef |
| br i1 %cmp58, label %59, label %58 |
| %val59 = load volatile float* undef |
| %cmp59 = fcmp une float %val59, undef |
| br i1 %cmp59, label %60, label %59 |
| %val60 = load volatile float* undef |
| %cmp60 = fcmp une float %val60, undef |
| br i1 %cmp60, label %61, label %60 |
| %val61 = load volatile float* undef |
| %cmp61 = fcmp une float %val61, undef |
| br i1 %cmp61, label %62, label %61 |
| %val62 = load volatile float* undef |
| %cmp62 = fcmp une float %val62, undef |
| br i1 %cmp62, label %63, label %62 |
| %val63 = load volatile float* undef |
| %cmp63 = fcmp une float %val63, undef |
| br i1 %cmp63, label %64, label %63 |
| %val64 = load volatile float* undef |
| %cmp64 = fcmp une float %val64, undef |
| br i1 %cmp64, label %65, label %64 |
| |
| br label %exit |
| exit: |
| ret void |
| } |
| |
| define void @benchmark_heapsort(i32 %n, double* nocapture %ra) { |
| ; This test case comes from the heapsort benchmark, and exemplifies several |
| ; important aspects to block placement in the presence of loops: |
| ; 1) Loop rotation needs to *ensure* that the desired exiting edge can be |
| ; a fallthrough. |
| ; 2) The exiting edge from the loop which is rotated to be laid out at the |
| ; bottom of the loop needs to be exiting into the nearest enclosing loop (to |
| ; which there is an exit). Otherwise, we force that enclosing loop into |
| ; strange layouts that are siginificantly less efficient, often times maing |
| ; it discontiguous. |
| ; |
| ; CHECK: @benchmark_heapsort |
| ; CHECK: %entry |
| ; First rotated loop top. |
| ; CHECK: .align |
| ; CHECK: %while.end |
| ; CHECK: %for.cond |
| ; CHECK: %if.then |
| ; CHECK: %if.else |
| ; CHECK: %if.end10 |
| ; Second rotated loop top |
| ; CHECK: .align |
| ; CHECK: %if.then24 |
| ; CHECK: %while.cond.outer |
| ; Third rotated loop top |
| ; CHECK: .align |
| ; CHECK: %while.cond |
| ; CHECK: %while.body |
| ; CHECK: %land.lhs.true |
| ; CHECK: %if.then19 |
| ; CHECK: %if.then19 |
| ; CHECK: %if.then8 |
| ; CHECK: ret |
| |
| entry: |
| %shr = ashr i32 %n, 1 |
| %add = add nsw i32 %shr, 1 |
| %arrayidx3 = getelementptr inbounds double* %ra, i64 1 |
| br label %for.cond |
| |
| for.cond: |
| %ir.0 = phi i32 [ %n, %entry ], [ %ir.1, %while.end ] |
| %l.0 = phi i32 [ %add, %entry ], [ %l.1, %while.end ] |
| %cmp = icmp sgt i32 %l.0, 1 |
| br i1 %cmp, label %if.then, label %if.else |
| |
| if.then: |
| %dec = add nsw i32 %l.0, -1 |
| %idxprom = sext i32 %dec to i64 |
| %arrayidx = getelementptr inbounds double* %ra, i64 %idxprom |
| %0 = load double* %arrayidx, align 8 |
| br label %if.end10 |
| |
| if.else: |
| %idxprom1 = sext i32 %ir.0 to i64 |
| %arrayidx2 = getelementptr inbounds double* %ra, i64 %idxprom1 |
| %1 = load double* %arrayidx2, align 8 |
| %2 = load double* %arrayidx3, align 8 |
| store double %2, double* %arrayidx2, align 8 |
| %dec6 = add nsw i32 %ir.0, -1 |
| %cmp7 = icmp eq i32 %dec6, 1 |
| br i1 %cmp7, label %if.then8, label %if.end10 |
| |
| if.then8: |
| store double %1, double* %arrayidx3, align 8 |
| ret void |
| |
| if.end10: |
| %ir.1 = phi i32 [ %ir.0, %if.then ], [ %dec6, %if.else ] |
| %l.1 = phi i32 [ %dec, %if.then ], [ %l.0, %if.else ] |
| %rra.0 = phi double [ %0, %if.then ], [ %1, %if.else ] |
| %add31 = add nsw i32 %ir.1, 1 |
| br label %while.cond.outer |
| |
| while.cond.outer: |
| %j.0.ph.in = phi i32 [ %l.1, %if.end10 ], [ %j.1, %if.then24 ] |
| %j.0.ph = shl i32 %j.0.ph.in, 1 |
| br label %while.cond |
| |
| while.cond: |
| %j.0 = phi i32 [ %add31, %if.end20 ], [ %j.0.ph, %while.cond.outer ] |
| %cmp11 = icmp sgt i32 %j.0, %ir.1 |
| br i1 %cmp11, label %while.end, label %while.body |
| |
| while.body: |
| %cmp12 = icmp slt i32 %j.0, %ir.1 |
| br i1 %cmp12, label %land.lhs.true, label %if.end20 |
| |
| land.lhs.true: |
| %idxprom13 = sext i32 %j.0 to i64 |
| %arrayidx14 = getelementptr inbounds double* %ra, i64 %idxprom13 |
| %3 = load double* %arrayidx14, align 8 |
| %add15 = add nsw i32 %j.0, 1 |
| %idxprom16 = sext i32 %add15 to i64 |
| %arrayidx17 = getelementptr inbounds double* %ra, i64 %idxprom16 |
| %4 = load double* %arrayidx17, align 8 |
| %cmp18 = fcmp olt double %3, %4 |
| br i1 %cmp18, label %if.then19, label %if.end20 |
| |
| if.then19: |
| br label %if.end20 |
| |
| if.end20: |
| %j.1 = phi i32 [ %add15, %if.then19 ], [ %j.0, %land.lhs.true ], [ %j.0, %while.body ] |
| %idxprom21 = sext i32 %j.1 to i64 |
| %arrayidx22 = getelementptr inbounds double* %ra, i64 %idxprom21 |
| %5 = load double* %arrayidx22, align 8 |
| %cmp23 = fcmp olt double %rra.0, %5 |
| br i1 %cmp23, label %if.then24, label %while.cond |
| |
| if.then24: |
| %idxprom27 = sext i32 %j.0.ph.in to i64 |
| %arrayidx28 = getelementptr inbounds double* %ra, i64 %idxprom27 |
| store double %5, double* %arrayidx28, align 8 |
| br label %while.cond.outer |
| |
| while.end: |
| %idxprom33 = sext i32 %j.0.ph.in to i64 |
| %arrayidx34 = getelementptr inbounds double* %ra, i64 %idxprom33 |
| store double %rra.0, double* %arrayidx34, align 8 |
| br label %for.cond |
| } |