> -----Original Message----- > From: Richard Biener <[email protected]> > Sent: Tuesday, October 31, 2023 9:48 PM > To: Di Zhao OS <[email protected]> > Cc: [email protected] > Subject: Re: [PATCH v4] [tree-optimization/110279] Consider FMA in > get_reassociation_width > > On Sun, Oct 8, 2023 at 6:40 PM Di Zhao OS <[email protected]> > wrote: > > > > Attached is a new version of the patch. > > > > > -----Original Message----- > > > From: Richard Biener <[email protected]> > > > Sent: Friday, October 6, 2023 5:33 PM > > > To: Di Zhao OS <[email protected]> > > > Cc: [email protected] > > > Subject: Re: [PATCH v4] [tree-optimization/110279] Consider FMA in > > > get_reassociation_width > > > > > > On Thu, Sep 14, 2023 at 2:43 PM Di Zhao OS > > > <[email protected]> wrote: > > > > > > > > This is a new version of the patch on "nested FMA". > > > > Sorry for updating this after so long, I've been studying and > > > > writing micro cases to sort out the cause of the regression. > > > > > > Sorry for taking so long to reply. > > > > > > > First, following previous discussion: > > > > (https://gcc.gnu.org/pipermail/gcc-patches/2023-September/629080.html) > > > > > > > > 1. From testing more altered cases, I don't think the > > > > problem is that reassociation works locally. In that: > > > > > > > > 1) On the example with multiplications: > > > > > > > > tmp1 = a + c * c + d * d + x * y; > > > > tmp2 = x * tmp1; > > > > result += (a + c + d + tmp2); > > > > > > > > Given "result" rewritten by width=2, the performance is > > > > worse if we rewrite "tmp1" with width=2. In contrast, if we > > > > remove the multiplications from the example (and make "tmp1" > > > > not singe used), and still rewrite "result" by width=2, then > > > > rewriting "tmp1" with width=2 is better. (Make sense because > > > > the tree's depth at "result" is still smaller if we rewrite > > > > "tmp1".) > > > > > > > > 2) I tried to modify the assembly code of the example without > > > > FMA, so the width of "result" is 4. On Ampere1 there's no > > > > obvious improvement. So although this is an interesting > > > > problem, it doesn't seem like the cause of the regression. > > > > > > OK, I see. > > > > > > > 2. From assembly code of the case with FMA, one problem is > > > > that, rewriting "tmp1" to parallel didn't decrease the > > > > minimum CPU cycles (taking MULT_EXPRs into account), but > > > > increased code size, so the overhead is increased. > > > > > > > > a) When "tmp1" is not re-written to parallel: > > > > fmadd d31, d2, d2, d30 > > > > fmadd d31, d3, d3, d31 > > > > fmadd d31, d4, d5, d31 //"tmp1" > > > > fmadd d31, d31, d4, d3 > > > > > > > > b) When "tmp1" is re-written to parallel: > > > > fmul d31, d4, d5 > > > > fmadd d27, d2, d2, d30 > > > > fmadd d31, d3, d3, d31 > > > > fadd d31, d31, d27 //"tmp1" > > > > fmadd d31, d31, d4, d3 > > > > > > > > For version a), there are 3 dependent FMAs to calculate "tmp1". > > > > For version b), there are also 3 dependent instructions in the > > > > longer path: the 1st, 3rd and 4th. > > > > > > Yes, it doesn't really change anything. The patch has > > > > > > + /* If there's code like "acc = a * b + c * d + acc" in a tight loop, > some > > > + uarchs can execute results like: > > > + > > > + _1 = a * b; > > > + _2 = .FMA (c, d, _1); > > > + acc_1 = acc_0 + _2; > > > + > > > + in parallel, while turning it into > > > + > > > + _1 = .FMA(a, b, acc_0); > > > + acc_1 = .FMA(c, d, _1); > > > + > > > + hinders that, because then the first FMA depends on the result > > > of preceding > > > + iteration. */ > > > > > > I can't see what can be run in parallel for the first case. The .FMA > > > depends on the multiplication a * b. Iff the uarch somehow decomposes > > > .FMA into multiply + add then the c * d multiply could run in parallel > > > with the a * b multiply which _might_ be able to hide some of the > > > latency of the full .FMA. Like on x86 Zen FMA has a latency of 4 > > > cycles but a multiply only 3. But I never got confirmation from any > > > of the CPU designers that .FMAs are issued when the multiply > > > operands are ready and the add operand can be forwarded. > > > > > > I also wonder why the multiplications of the two-FMA sequence > > > then cannot be executed at the same time? So I have some doubt > > > of the theory above. > > > > The parallel execution for the code snippet above was the other > > issue (previously discussed here: > > https://gcc.gnu.org/pipermail/gcc-patches/2023-August/628960.html). > > Sorry it's a bit confusing to include that here, but these 2 fixes > > needs to be combined to avoid new regressions. Since considering > > FMA in get_reassociation_width produces more results of width=1, > > so there would be more loop depending FMA chains. > > > > > Iff this really is the reason for the sequence to execute with lower > > > overall latency and we want to attack this on GIMPLE then I think > > > we need a target hook telling us this fact (I also wonder if such > > > behavior can be modeled in the scheduler pipeline description at all?) > > > > > > > So it seems to me the current get_reassociation_width algorithm > > > > isn't optimal in the presence of FMA. So I modified the patch to > > > > improve get_reassociation_width, rather than check for code > > > > patterns. (Although there could be some other complicated > > > > factors so the regression is more obvious when there's "nested > > > > FMA". But with this patch that should be avoided or reduced.) > > > > > > > > With this patch 508.namd_r 1-copy run has 7% improvement on > > > > Ampere1, on Intel Xeon there's about 3%. While I'm still > > > > collecting data on other CPUs, I'd like to know how do you > > > > think of this. > > > > > > > > About changes in the patch: > > > > > > > > 1. When the op list forms a complete FMA chain, try to search > > > > for a smaller width considering the benefit of using FMA. With > > > > a smaller width, the increment of code size is smaller when > > > > breaking the chain. > > > > > > But this is all highly target specific (code size even more so). > > > > > > How I understand your approach to fixing the issue leads me to > > > the suggestion to prioritize parallel rewriting, thus alter > rank_ops_for_fma, > > > taking the reassoc width into account (the computed width should be > > > unchanged from rank_ops_for_fma) instead of "fixing up" the parallel > > > rewriting of FMAs (well, they are not yet formed of course). > > > get_reassociation_width has 'get_required_cycles', the above theory > > > could be verified with a very simple toy pipeline model. We'd have > > > to ask the target for the reassoc width for MULT_EXPRs as well (or maybe > > > even FMA_EXPRs). > > > > > > Taking the width of FMAs into account when computing the reassoc width > > > might be another way to attack this. > > > > Previously I tried to solve this generally, on the assumption that > > FMA (smaller code size) is preferred. Now I agree it's difficult > > since: 1) As you mentioned, the latency of FMA, FMUL and FADD can > > be different. 2) From my test result on different machines we > > have, it seems simply adding the cycles together is not a good way > > to estimate the latency of consecutive FMA. > > > > I think an easier way to fix this is to add a parameter to suggest > > the length of complete FMA chain to keep. (It can be set by target > > specific tuning then.) And we can break longer FMA chains for > > better parallelism. Attached is the new implementation. With > > max-fma-chain-len=8, there's about 7% improvement in spec2017 > > 508.namd_r on ampere1, and the overall improvement on fprate is > > about 1%. > > > > Since there's code in rank_ops_for_fma to identify MULT_EXPRs from > > others, I left it before get_reassociation_width so the number of > > MULT_EXPRs can be used. > > Sorry again for the delay in replying. > > + /* Check if keeping complete FMA chains is preferred. */ > + if (width > 1 && mult_num >= 2 && param_max_fma_chain_len) > + { > + /* num_fma_chain + (num_fma_chain - 1) >= num_plus . */ > + int num_others = ops_num - mult_num; > + int num_fma_chain = CEIL (num_others + 1, 2); > + > + if (num_fma_chain < width > + && CEIL (mult_num, num_fma_chain) <= param_max_fma_chain_len) > + width = num_fma_chain; > + } > > so here 'mult_num' serves as a heuristical value how many > FMAs we could build. If that were close to ops_num - 1 then > we'd have a chain of FMAs. Not sure how you get at > num_others / 2 here. Maybe we need to elaborate on what an > FMA chain is? I thought it is FMA (FMA (FMA (..., b, c), d, e), f, g) > where each (b,c) pair is really just one operand in the ops array, > one of the 'mult's. Thus a FMA chain is _not_ > FMA (a, b, c) + FMA (d, e, f) + FMA (...) + ..., right?
The "FMA chain" here refers to consecutive FMAs, each taking
The previous one's result as the third operator, i.e.
... FMA(e, f, FMA(c, d, FMA (a, b, r)))... . So original op
list looks like "r + a * b + c * d + e * f + ...". These FMAs
will end up using the same accumulate register.
When num_others=2 or 3, there can be 2 complete chains, e.g.
FMA (d, e, FMA (a, b, c)) + FMA (f, g, h)
or
FMA (d, e, FMA (a, b, c)) + FMA (f, g, h) + i .
And so on, that's where the "CEIL (num_others + 1, 2)" comes from.
>
> Forming an FMA chain effectively reduces the reassociation width
> of the participating multiplies. If we were not to form FMAs all
> the multiplies could execute in parallel.
>
> So what does the above do, in terms of adjusting the reassociation
> width for the _adds_, and what's the ripple-down effect on later
> FMA forming?
>
The above code calculates the number of such FMA chains in the op
list. And if the length of each chain doesn't exceed
param_max_fma_chain_len, then width is set to the number of chains,
so we won't break them (because rewrite_expr_tree_parallel handles
this well).
> The change still feels like whack-a-mole playing rather than understanding
> the fundamental issue on the targets.
I think the complexity is in how the instructions are piped.
Some Arm CPUs such as Neoverse V2 supports "late-forwarding":
"FP multiply-accumulate pipelines support late-forwarding of
accumulate operands from similar μOPs, allowing a typical
sequence of multiply-accumulate μOPs to issue one every N
cycles". ("N" is smaller than the latency of a single FMA
instruction.) So keeping such FMA chains can utilize such
feature and uses less FP units. I guess the case is similar on
some late X86 CPUs.
If we try to compute the minimum circles of each option, I think
at least we'll need to know whether the target has similar
feature, and the latency of each uop. While using an
experiential length of beneficial FMA chain could be a shortcut.
(Maybe allowing different lengths for different data widths is
better.)
>
> + /* If there's loop dependent FMA result, return width=2 to avoid it. This
> is
> + better than skipping these FMA candidates in widening_mul. */
>
> better than skipping, but you don't touch it there? I suppose width == 2
> will bypass the skipping, right? This heuristic only comes in when the above
> change made width == 1, since otherwise we have an earlier
>
> if (width == 1)
> return width;
>
> which als guarantees width == 2 was allowed by the hook/param, right?
Yes, that's right.
>
> + if (width == 1 && mult_num
> + && maybe_le (tree_to_poly_int64 (TYPE_SIZE (TREE_TYPE (lhs))),
> + param_avoid_fma_max_bits))
> + {
> + /* Look for cross backedge dependency:
> + 1. LHS is a phi argument in the same basic block it is defined.
> + 2. And the result of the phi node is used in OPS. */
> + basic_block bb = gimple_bb (SSA_NAME_DEF_STMT (lhs));
> + gimple_stmt_iterator gsi;
> + for (gsi = gsi_start_phis (bb); !gsi_end_p (gsi); gsi_next (&gsi))
> + {
> + gphi *phi = dyn_cast<gphi *> (gsi_stmt (gsi));
> + for (unsigned i = 0; i < gimple_phi_num_args (phi); ++i)
> + {
> + tree op = PHI_ARG_DEF (phi, i);
> + if (!(op == lhs && gimple_phi_arg_edge (phi, i)->src == bb))
> + continue;
>
> I think it's easier to iterate over the immediate uses of LHS like
>
> FOR_EACH_IMM_USE_FAST (use_p, iter, lhs)
> if (gphi *phi = dyn_cast <gphi *> (USE_STMT (use_p)))
> {
> if (gimple_phi_arg_edge (phi, phi_arg_index_from_use
> (use_p))->src != bb)
> continue;
> ...
> }
>
> otherwise I think _this_ part of the patch looks reasonable.
>
> As you say heuristically they might go together but I think we should split
> the
> patch - the cross-loop part can probably stand independently. Can you adjust
> and re-post?
Attached is the separated part for cross-loop FMA. Thank you for the correction.
>
> As for the first part I still don't understand very well and am still hoping
> we
> can get away without yet another knob to tune.
>
> Richard.
>
> > >
> > > > 2. To avoid regressions, included the other patch
> > > > (https://gcc.gnu.org/pipermail/gcc-patches/2023-September/629203.html)
> > > > on this tracker again. This is because more FMA will be kept
> > > > with 1., so we need to rule out the loop dependent
> > > > FMA chains when param_avoid_fma_max_bits is set.
> > >
> > > Sorry again for taking so long to reply.
> > >
> > > I'll note we have an odd case on x86 Zen2(?) as well which we don't really
> > > understand from a CPU behavior perspective.
> > >
> > > Thanks,
> > > Richard.
> > >
> > > > Thanks,
> > > > Di Zhao
> > > >
> > > > ----
> > > >
> > > > PR tree-optimization/110279
> > > >
> > > > gcc/ChangeLog:
> > > >
> > > > * tree-ssa-reassoc.cc (rank_ops_for_better_parallelism_p):
> > > > New function to check whether ranking the ops results in
> > > > better parallelism.
> > > > (get_reassociation_width): Add new parameters. Search for
> > > > smaller width considering the benefit of FMA.
> > > > (rank_ops_for_fma): Change return value to be number of
> > > > MULT_EXPRs.
> > > > (reassociate_bb): For 3 ops, refine the condition to call
> > > > swap_ops_for_binary_stmt.
> > > >
> > > > gcc/testsuite/ChangeLog:
> > > >
> > > > * gcc.dg/pr110279.c: New test.
> >
> > Thanks,
> > Di Zhao
> >
> > ----
> >
> > PR tree-optimization/110279
> >
> > gcc/ChangeLog:
> >
> > * doc/invoke.texi: Description of param_max_fma_chain_len.
> > * params.opt: New parameter param_max_fma_chain_len.
> > * tree-ssa-reassoc.cc (get_reassociation_width):
> > Support param_max_fma_chain_len; check for loop dependent
> > FMAs.
> > (rank_ops_for_fma): Return the number of MULT_EXPRs.
> > (reassociate_bb): For 3 ops, refine the condition to call
> > swap_ops_for_binary_stmt.
> >
> > gcc/testsuite/ChangeLog:
> >
> > * gcc.dg/pr110279-1.c: New test.
> > * gcc.dg/pr110279-2.c: New test.
> > * gcc.dg/pr110279-3.c: New test.
---
PR tree-optimization/110279
gcc/ChangeLog:
* tree-ssa-reassoc.cc (get_reassociation_width): check
for loop dependent FMAs.
(reassociate_bb): For 3 ops, refine the condition to call
swap_ops_for_binary_stmt.
gcc/testsuite/ChangeLog:
* gcc.dg/pr110279-1.c: New test.
0001-swap-ops-in-reassoc-to-reduce-cross-backedge-FMA.patch
Description: 0001-swap-ops-in-reassoc-to-reduce-cross-backedge-FMA.patch
