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wrong for volatile loads and stores. In fact this is almost all of them! There are three types of problems: (1) it is wrong to change the width of a volatile memory access. These may be used to do memory mapped i/o, in which case a load can have an effect even if the result is not used. Consider loading an i32 but only using the lower 8 bits. It is wrong to change this into a load of an i8, because you are no longer tickling the other three bytes. It is also unwise to make a load/store wider. For example, changing an i16 load into an i32 load is wrong no matter how aligned things are, since the fact of loading an additional 2 bytes can have i/o side-effects. (2) it is wrong to change the number of volatile load/stores: they may be counted by the hardware. (3) it is wrong to change a volatile load/store that requires one memory access into one that requires several. For example on x86-32, you can store a double in one processor operation, but to store an i64 requires two (two i32 stores). In a multi-threaded program you may want to bitcast an i64 to a double and store as a double because that will occur atomically, and be indivisible to other threads. So it would be wrong to convert the store-of-double into a store of an i64, because this will become two i32 stores - no longer atomic. My policy here is to say that the number of processor operations for an illegal operation is undefined. So it is alright to change a store of an i64 (requires at least two stores; but could be validly lowered to memcpy for example) into a store of double (one processor op). In short, if the new store is legal and has the same size then I say that the transform is ok. It would also be possible to say that transforms are always ok if before they were illegal, whether after they are illegal or not, but that's more awkward to do and I doubt it buys us anything much. However this exposed an interesting thing - on x86-32 a store of i64 is considered legal! That is because operations are marked legal by default, regardless of whether the type is legal or not. In some ways this is clever: before type legalization this means that operations on illegal types are considered legal; after type legalization there are no illegal types so now operations are only legal if they really are. But I consider this to be too cunning for mere mortals. Better to do things explicitly by testing AfterLegalize. So I have changed things so that operations with illegal types are considered illegal - indeed they can never map to a machine operation. However this means that the DAG combiner is more conservative because before it was "accidentally" performing transforms where the type was illegal because the operation was nonetheless marked legal. So in a few such places I added a check on AfterLegalize, which I suppose was actually just forgotten before. This causes the DAG combiner to do slightly more than it used to, which resulted in the X86 backend blowing up because it got a slightly surprising node it wasn't expecting, so I tweaked it. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@52254 91177308-0d34-0410-b5e6-96231b3b80d8
//===---------------------------------------------------------------------===//
Common register allocation / spilling problem:
mul lr, r4, lr
str lr, [sp, #+52]
ldr lr, [r1, #+32]
sxth r3, r3
ldr r4, [sp, #+52]
mla r4, r3, lr, r4
can be:
mul lr, r4, lr
mov r4, lr
str lr, [sp, #+52]
ldr lr, [r1, #+32]
sxth r3, r3
mla r4, r3, lr, r4
and then "merge" mul and mov:
mul r4, r4, lr
str lr, [sp, #+52]
ldr lr, [r1, #+32]
sxth r3, r3
mla r4, r3, lr, r4
It also increase the likelyhood the store may become dead.
//===---------------------------------------------------------------------===//
I think we should have a "hasSideEffects" flag (which is automatically set for
stuff that "isLoad" "isCall" etc), and the remat pass should eventually be able
to remat any instruction that has no side effects, if it can handle it and if
profitable.
For now, I'd suggest having the remat stuff work like this:
1. I need to spill/reload this thing.
2. Check to see if it has side effects.
3. Check to see if it is simple enough: e.g. it only has one register
destination and no register input.
4. If so, clone the instruction, do the xform, etc.
Advantages of this are:
1. the .td file describes the behavior of the instructions, not the way the
algorithm should work.
2. as remat gets smarter in the future, we shouldn't have to be changing the .td
files.
3. it is easier to explain what the flag means in the .td file, because you
don't have to pull in the explanation of how the current remat algo works.
Some potential added complexities:
1. Some instructions have to be glued to it's predecessor or successor. All of
the PC relative instructions and condition code setting instruction. We could
mark them as hasSideEffects, but that's not quite right. PC relative loads
from constantpools can be remat'ed, for example. But it requires more than
just cloning the instruction. Some instructions can be remat'ed but it
expands to more than one instruction. But allocator will have to make a
decision.
4. As stated in 3, not as simple as cloning in some cases. The target will have
to decide how to remat it. For example, an ARM 2-piece constant generation
instruction is remat'ed as a load from constantpool.
//===---------------------------------------------------------------------===//
bb27 ...
...
%reg1037 = ADDri %reg1039, 1
%reg1038 = ADDrs %reg1032, %reg1039, %NOREG, 10
Successors according to CFG: 0x8b03bf0 (#5)
bb76 (0x8b03bf0, LLVM BB @0x8b032d0, ID#5):
Predecessors according to CFG: 0x8b0c5f0 (#3) 0x8b0a7c0 (#4)
%reg1039 = PHI %reg1070, mbb<bb76.outer,0x8b0c5f0>, %reg1037, mbb<bb27,0x8b0a7c0>
Note ADDri is not a two-address instruction. However, its result %reg1037 is an
operand of the PHI node in bb76 and its operand %reg1039 is the result of the
PHI node. We should treat it as a two-address code and make sure the ADDri is
scheduled after any node that reads %reg1039.
//===---------------------------------------------------------------------===//
Use local info (i.e. register scavenger) to assign it a free register to allow
reuse:
ldr r3, [sp, #+4]
add r3, r3, #3
ldr r2, [sp, #+8]
add r2, r2, #2
ldr r1, [sp, #+4] <==
add r1, r1, #1
ldr r0, [sp, #+4]
add r0, r0, #2
//===---------------------------------------------------------------------===//
LLVM aggressively lift CSE out of loop. Sometimes this can be negative side-
effects:
R1 = X + 4
R2 = X + 7
R3 = X + 15
loop:
load [i + R1]
...
load [i + R2]
...
load [i + R3]
Suppose there is high register pressure, R1, R2, R3, can be spilled. We need
to implement proper re-materialization to handle this:
R1 = X + 4
R2 = X + 7
R3 = X + 15
loop:
R1 = X + 4 @ re-materialized
load [i + R1]
...
R2 = X + 7 @ re-materialized
load [i + R2]
...
R3 = X + 15 @ re-materialized
load [i + R3]
Furthermore, with re-association, we can enable sharing:
R1 = X + 4
R2 = X + 7
R3 = X + 15
loop:
T = i + X
load [T + 4]
...
load [T + 7]
...
load [T + 15]
//===---------------------------------------------------------------------===//
It's not always a good idea to choose rematerialization over spilling. If all
the load / store instructions would be folded then spilling is cheaper because
it won't require new live intervals / registers. See 2003-05-31-LongShifts for
an example.
//===---------------------------------------------------------------------===//
With a copying garbage collector, derived pointers must not be retained across
collector safe points; the collector could move the objects and invalidate the
derived pointer. This is bad enough in the first place, but safe points can
crop up unpredictably. Consider:
%array = load { i32, [0 x %obj] }** %array_addr
%nth_el = getelementptr { i32, [0 x %obj] }* %array, i32 0, i32 %n
%old = load %obj** %nth_el
%z = div i64 %x, %y
store %obj* %new, %obj** %nth_el
If the i64 division is lowered to a libcall, then a safe point will (must)
appear for the call site. If a collection occurs, %array and %nth_el no longer
point into the correct object.
The fix for this is to copy address calculations so that dependent pointers
are never live across safe point boundaries. But the loads cannot be copied
like this if there was an intervening store, so may be hard to get right.
Only a concurrent mutator can trigger a collection at the libcall safe point.
So single-threaded programs do not have this requirement, even with a copying
collector. Still, LLVM optimizations would probably undo a front-end's careful
work.
//===---------------------------------------------------------------------===//
The ocaml frametable structure supports liveness information. It would be good
to support it.
//===---------------------------------------------------------------------===//
The FIXME in ComputeCommonTailLength in BranchFolding.cpp needs to be
revisited. The check is there to work around a misuse of directives in inline
assembly.
//===---------------------------------------------------------------------===//
It would be good to detect collector/target compatibility instead of silently
doing the wrong thing.
//===---------------------------------------------------------------------===//
It would be really nice to be able to write patterns in .td files for copies,
which would eliminate a bunch of explicit predicates on them (e.g. no side
effects). Once this is in place, it would be even better to have tblgen
synthesize the various copy insertion/inspection methods in TargetInstrInfo.
//===---------------------------------------------------------------------===//
Stack coloring improvments:
1. Do proper LiveStackAnalysis on all stack objects including those which are
not spill slots.
2. Reorder objects to fill in gaps between objects.
e.g. 4, 1, <gap>, 4, 1, 1, 1, <gap>, 4 => 4, 1, 1, 1, 1, 4, 4