llvm dev - Apr 2017 - [NewGVN] Plan for GVNPRE?

Hello,

In some of our internal benchmarks, I observe that LLVM performs worse than GCC
because LLVM fails to perform PRE when GCC can. I hope this problem goes away
when NewGVN equipped with PRE, and wonder if anyone has an idea about the status
of PRE on top of NewGVN. Thanks!

Best,
Taewook
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Hi Taewook,
I have prototypes, and they work well enough that i was convinced it's not
a big deal to implement.
If you are interested in working on it, let me know.
Otherwise, i'll get to it.
I'm just knocking down the rest of the generated code perf differences i
can find that matter between gvn and newgvn.
we are fairly close (IMHO) at this point.

Though i wrote GCC's current GVN-PRE, i am unlikely to take exactly the
same approach for LLVM (iterative dataflow)
I am also still testing out various non-"lifetime optimal" approaches.

I am busy making the current GVN a complete one, which will eliminate:
1. the need for full redundancy elimination
2. issues that pop up where we discover we could phi values together (this
is really a case of #1).

That will leave *literally* partial redundancies as the only thing that
needs to be eliminated, simplifying our task.


The only source of incompleteness in NewGVN is the inability to consider
phi of ops and op of phis the same thing (and the related phi + op and op +
phi)
Here is an example (pull from a real program where it makes a significant
perf difference)
:
 ; <label>:9:                                      ; preds = %7, %4
   %10 = phi i64 [ %0, %4 ], [ %11, %7 ]
   %11 = add nsw i64 %10, -1
   %12 = load i64, i64* getelementptr inbounds ([100 x i64], [100 x i64]*
@a, i64 0, i64 0), align 16, !tbaa !2
   %13 = load i64, i64* getelementptr inbounds ([100 x i64], [100 x i64]*
@b, i64 0, i64 0), align 16, !tbaa !2
   %14 = mul nsw i64 %13, %12
   %15 = icmp eq i64 %14, 0
   br i1 %15, label %7, label %16

; <label>: 17
   %18 = phi i64 [ %26, %17 ], [ %13, %16 ]
   %19 = phi i64 [ %24, %17 ], [ %12, %16 ]
   %20 = phi i64 [ %22, %17 ], [ 0, %16 ]
   %21 = mul nsw i64 %18, %19
   store i64 2, i64* %2, align 8, !tbaa !2
   %22 = add nuw nsw i64 %20, 1
   %23 = getelementptr inbounds [100 x i64], [100 x i64]* @a, i64 0, i64 %22
   %24 = load i64, i64* %23, align 8, !tbaa !2
   %25 = getelementptr inbounds [100 x i64], [100 x i64]* @b, i64 0, i64 %22
   %26 = load i64, i64* %25, align 8, !tbaa !2
   %27 = mul nsw i64 %26, %24
   %28 = icmp eq i64 %22, %27
   br i1 %28, label %6, label %17

The multiply at 18, 19 is completely redundant.
It is a phi of the computations in 9 and 17.

Once done (almost!), newgvn will actually detect that a simple phi inserted
in 17 would have the same  value as %21.
The work is https://bugs.llvm.org//show_bug.cgi?id=31868

Wwhen we see op of phis, we use fake instructions to treat it like we saw
ops in the predecessor blocks, and see whether the fake phi we build ends
up with real instructions as for the operands. if it does, we insert it.
Note this computation is similar to the one SSAPRE does to determine
whether anything is redundant.

Once you do this, i believe all initial partial redundancies (IE not second
order effects) in the program will be of a form of a fake phi with one real
leader, one fake., recursively [1]
Then, again, you perform a similar sparse dataflow that SSAPRE does to
figure out which will, if inserted, make other computations redundant.

IE c = a + b
     if (foo)
           b = 50
     d = a + b

this will end up as d = op  + phi

WE will convert to phi of ops form, phi(a + 50,  a +b)
One real (a+b), one fake (a+50).
full availability will show up as real,real:
int x, c, y;
x = 3;
if (c)
x = 2;
y = x + 1;
return y;

phi(2 + 1, 3 + 1)

etc

The only practical difference will be the computation of what we want to
insert (in FRE, we would insert only fully-available phis, in PRE, we
insert instructions to make the not-fully-available ones real)




On Tue, Apr 4, 2017 at 3:04 PM, Taewook Oh via llvm-dev <
llvm-dev at lists.llvm.org> wrote:
> Hello,
>
>
>
> In some of our internal benchmarks, I observe that LLVM performs worse
> than GCC because LLVM fails to perform PRE when GCC can. I hope this
> problem goes away when NewGVN equipped with PRE, and wonder if anyone has
> an idea about the status of PRE on top of NewGVN. Thanks!
>
>
>
> Best,
>
> Taewook
>
> _______________________________________________
> LLVM Developers mailing list
> llvm-dev at lists.llvm.org
> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev
>
>
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Hi Daniel,

Thank you for your detailed reply, and thank you for working on GVNPRE. I’d more
than happy to test/evaluate it with our benchmark once it is ready. Please let
me know if you need any help.

Thanks,
Taewook

From: Daniel Berlin <dberlin at dberlin.org>
Date: Tuesday, April 4, 2017 at 6:13 PM
To: Taewook Oh <twoh at fb.com>
Cc: "llvm-dev at lists.llvm.org" <llvm-dev at lists.llvm.org>
Subject: Re: [llvm-dev] [NewGVN] Plan for GVNPRE?

Hi Taewook,
I have prototypes, and they work well enough that i was convinced it's not a
big deal to implement.
If you are interested in working on it, let me know.
Otherwise, i'll get to it.
I'm just knocking down the rest of the generated code perf differences i can
find that matter between gvn and newgvn.
we are fairly close (IMHO) at this point.

Though i wrote GCC's current GVN-PRE, i am unlikely to take exactly the same
approach for LLVM (iterative dataflow)
I am also still testing out various non-"lifetime optimal" approaches.

I am busy making the current GVN a complete one, which will eliminate:
1. the need for full redundancy elimination
2. issues that pop up where we discover we could phi values together (this is
really a case of #1).

That will leave *literally* partial redundancies as the only thing that needs to
be eliminated, simplifying our task.


The only source of incompleteness in NewGVN is the inability to consider phi of
ops and op of phis the same thing (and the related phi + op and op + phi)
Here is an example (pull from a real program where it makes a significant perf
difference)
:
 ; <label>:9:                                      ; preds = %7, %4
   %10 = phi i64 [ %0, %4 ], [ %11, %7 ]
   %11 = add nsw i64 %10, -1
   %12 = load i64, i64* getelementptr inbounds ([100 x i64], [100 x i64]* @a,
i64 0, i64 0), align 16, !tbaa !2
   %13 = load i64, i64* getelementptr inbounds ([100 x i64], [100 x i64]* @b,
i64 0, i64 0), align 16, !tbaa !2
   %14 = mul nsw i64 %13, %12
   %15 = icmp eq i64 %14, 0
   br i1 %15, label %7, label %16

; <label>: 17
   %18 = phi i64 [ %26, %17 ], [ %13, %16 ]
   %19 = phi i64 [ %24, %17 ], [ %12, %16 ]
   %20 = phi i64 [ %22, %17 ], [ 0, %16 ]
   %21 = mul nsw i64 %18, %19
   store i64 2, i64* %2, align 8, !tbaa !2
   %22 = add nuw nsw i64 %20, 1
   %23 = getelementptr inbounds [100 x i64], [100 x i64]* @a, i64 0, i64 %22
   %24 = load i64, i64* %23, align 8, !tbaa !2
   %25 = getelementptr inbounds [100 x i64], [100 x i64]* @b, i64 0, i64 %22
   %26 = load i64, i64* %25, align 8, !tbaa !2
   %27 = mul nsw i64 %26, %24
   %28 = icmp eq i64 %22, %27
   br i1 %28, label %6, label %17

The multiply at 18, 19 is completely redundant.
It is a phi of the computations in 9 and 17.

Once done (almost!), newgvn will actually detect that a simple phi inserted in
17 would have the same  value as %21.
The work is
https://bugs.llvm.org//show_bug.cgi?id=31868<https://urldefense.proofpoint.com/v2/url?u=https-3A__bugs.llvm.org__show-5Fbug.cgi-3Fid-3D31868&d=DwMFaQ&c=5VD0RTtNlTh3ycd41b3MUw&r=kOsLCgQzH7N8ptZ7diJD9g&m=Sv5T08BLc94DspNTrXv67YwHnXVNmVllN9p8B7fZgTs&s=bOw6bI0rowF-LG3wUx222kr4j4lEwZCz1sGk-DR39Ts&e=>

Wwhen we see op of phis, we use fake instructions to treat it like we saw ops in
the predecessor blocks, and see whether the fake phi we build ends up with real
instructions as for the operands. if it does, we insert it.
Note this computation is similar to the one SSAPRE does to determine whether
anything is redundant.

Once you do this, i believe all initial partial redundancies (IE not second
order effects) in the program will be of a form of a fake phi with one real
leader, one fake., recursively [1]
Then, again, you perform a similar sparse dataflow that SSAPRE does to figure
out which will, if inserted, make other computations redundant.

IE c = a + b
     if (foo)
           b = 50
     d = a + b

this will end up as d = op  + phi

WE will convert to phi of ops form, phi(a + 50,  a +b)
One real (a+b), one fake (a+50).
full availability will show up as real,real:
int x, c, y;
x = 3;
if (c)
x = 2;
y = x + 1;
return y;

phi(2 + 1, 3 + 1)

etc

The only practical difference will be the computation of what we want to insert
(in FRE, we would insert only fully-available phis, in PRE, we insert
instructions to make the not-fully-available ones real)




On Tue, Apr 4, 2017 at 3:04 PM, Taewook Oh via llvm-dev <llvm-dev at
lists.llvm.org<mailto:llvm-dev at lists.llvm.org>> wrote:
Hello,

In some of our internal benchmarks, I observe that LLVM performs worse than GCC
because LLVM fails to perform PRE when GCC can. I hope this problem goes away
when NewGVN equipped with PRE, and wonder if anyone has an idea about the status
of PRE on top of NewGVN. Thanks!

Best,
Taewook

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llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org>
http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev<https://urldefense.proofpoint.com/v2/url?u=http-3A__lists.llvm.org_cgi-2Dbin_mailman_listinfo_llvm-2Ddev&d=DwMFaQ&c=5VD0RTtNlTh3ycd41b3MUw&r=kOsLCgQzH7N8ptZ7diJD9g&m=Sv5T08BLc94DspNTrXv67YwHnXVNmVllN9p8B7fZgTs&s=Vsgb6wKgVyG2pYh24S1iO6teXM5YmLuMw8Gh_-rPbvI&e=>

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