mirror of
https://github.com/RPCS3/llvm-mirror.git
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a4e410aa9c
llvm-svn: 35049
474 lines
15 KiB
Plaintext
474 lines
15 KiB
Plaintext
//===---------------------------------------------------------------------===//
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// Random ideas for the ARM backend.
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//===---------------------------------------------------------------------===//
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Reimplement 'select' in terms of 'SEL'.
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* We would really like to support UXTAB16, but we need to prove that the
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add doesn't need to overflow between the two 16-bit chunks.
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* implement predication support
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* Implement pre/post increment support. (e.g. PR935)
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* Coalesce stack slots!
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* Implement smarter constant generation for binops with large immediates.
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* Consider materializing FP constants like 0.0f and 1.0f using integer
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immediate instructions then copy to FPU. Slower than load into FPU?
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//===---------------------------------------------------------------------===//
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The constant island pass is in good shape. Some cleanups might be desirable,
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but there is unlikely to be much improvement in the generated code.
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1. There may be some advantage to trying to be smarter about the initial
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placement, rather than putting everything at the end.
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2. The handling of 2-byte padding for Thumb is overly conservative. There
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would be a small gain to keeping accurate track of the padding (which would
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require aligning functions containing constant pools to 4-byte boundaries).
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3. There might be some compile-time efficiency to be had by representing
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consecutive islands as a single block rather than multiple blocks.
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4. Use a priority queue to sort constant pool users in inverse order of
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position so we always process the one closed to the end of functions
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first. This may simply CreateNewWater.
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//===---------------------------------------------------------------------===//
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We need to start generating predicated instructions. The .td files have a way
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to express this now (see the PPC conditional return instruction), but the
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branch folding pass (or a new if-cvt pass) should start producing these, at
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least in the trivial case.
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Among the obvious wins, doing so can eliminate the need to custom expand
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copysign (i.e. we won't need to custom expand it to get the conditional
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negate).
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This allows us to eliminate one instruction from:
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define i32 @_Z6slow4bii(i32 %x, i32 %y) {
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%tmp = icmp sgt i32 %x, %y
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%retval = select i1 %tmp, i32 %x, i32 %y
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ret i32 %retval
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}
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__Z6slow4bii:
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cmp r0, r1
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movgt r1, r0
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mov r0, r1
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bx lr
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//===---------------------------------------------------------------------===//
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Implement long long "X-3" with instructions that fold the immediate in. These
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were disabled due to badness with the ARM carry flag on subtracts.
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//===---------------------------------------------------------------------===//
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We currently compile abs:
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int foo(int p) { return p < 0 ? -p : p; }
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into:
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_foo:
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rsb r1, r0, #0
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cmn r0, #1
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movgt r1, r0
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mov r0, r1
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bx lr
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This is very, uh, literal. This could be a 3 operation sequence:
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t = (p sra 31);
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res = (p xor t)-t
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Which would be better. This occurs in png decode.
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//===---------------------------------------------------------------------===//
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More load / store optimizations:
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1) Look past instructions without side-effects (not load, store, branch, etc.)
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when forming the list of loads / stores to optimize.
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2) Smarter register allocation?
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We are probably missing some opportunities to use ldm / stm. Consider:
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ldr r5, [r0]
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ldr r4, [r0, #4]
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This cannot be merged into a ldm. Perhaps we will need to do the transformation
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before register allocation. Then teach the register allocator to allocate a
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chunk of consecutive registers.
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3) Better representation for block transfer? This is from Olden/power:
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fldd d0, [r4]
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fstd d0, [r4, #+32]
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fldd d0, [r4, #+8]
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fstd d0, [r4, #+40]
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fldd d0, [r4, #+16]
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fstd d0, [r4, #+48]
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fldd d0, [r4, #+24]
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fstd d0, [r4, #+56]
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If we can spare the registers, it would be better to use fldm and fstm here.
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Need major register allocator enhancement though.
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4) Can we recognize the relative position of constantpool entries? i.e. Treat
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ldr r0, LCPI17_3
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ldr r1, LCPI17_4
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ldr r2, LCPI17_5
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as
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ldr r0, LCPI17
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ldr r1, LCPI17+4
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ldr r2, LCPI17+8
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Then the ldr's can be combined into a single ldm. See Olden/power.
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Note for ARM v4 gcc uses ldmia to load a pair of 32-bit values to represent a
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double 64-bit FP constant:
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adr r0, L6
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ldmia r0, {r0-r1}
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.align 2
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L6:
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.long -858993459
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.long 1074318540
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5) Can we make use of ldrd and strd? Instead of generating ldm / stm, use
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ldrd/strd instead if there are only two destination registers that form an
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odd/even pair. However, we probably would pay a penalty if the address is not
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aligned on 8-byte boundary. This requires more information on load / store
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nodes (and MI's?) then we currently carry.
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6) struct copies appear to be done field by field
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instead of by words, at least sometimes:
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struct foo { int x; short s; char c1; char c2; };
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void cpy(struct foo*a, struct foo*b) { *a = *b; }
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llvm code (-O2)
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ldrb r3, [r1, #+6]
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ldr r2, [r1]
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ldrb r12, [r1, #+7]
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ldrh r1, [r1, #+4]
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str r2, [r0]
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strh r1, [r0, #+4]
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strb r3, [r0, #+6]
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strb r12, [r0, #+7]
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gcc code (-O2)
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ldmia r1, {r1-r2}
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stmia r0, {r1-r2}
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In this benchmark poor handling of aggregate copies has shown up as
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having a large effect on size, and possibly speed as well (we don't have
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a good way to measure on ARM).
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//===---------------------------------------------------------------------===//
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* Consider this silly example:
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double bar(double x) {
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double r = foo(3.1);
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return x+r;
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}
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_bar:
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sub sp, sp, #16
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str r4, [sp, #+12]
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str r5, [sp, #+8]
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str lr, [sp, #+4]
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mov r4, r0
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mov r5, r1
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ldr r0, LCPI2_0
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bl _foo
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fmsr f0, r0
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fcvtsd d0, f0
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fmdrr d1, r4, r5
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faddd d0, d0, d1
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fmrrd r0, r1, d0
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ldr lr, [sp, #+4]
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ldr r5, [sp, #+8]
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ldr r4, [sp, #+12]
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add sp, sp, #16
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bx lr
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Ignore the prologue and epilogue stuff for a second. Note
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mov r4, r0
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mov r5, r1
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the copys to callee-save registers and the fact they are only being used by the
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fmdrr instruction. It would have been better had the fmdrr been scheduled
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before the call and place the result in a callee-save DPR register. The two
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mov ops would not have been necessary.
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//===---------------------------------------------------------------------===//
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Calling convention related stuff:
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* gcc's parameter passing implementation is terrible and we suffer as a result:
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e.g.
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struct s {
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double d1;
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int s1;
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};
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void foo(struct s S) {
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printf("%g, %d\n", S.d1, S.s1);
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}
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'S' is passed via registers r0, r1, r2. But gcc stores them to the stack, and
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then reload them to r1, r2, and r3 before issuing the call (r0 contains the
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address of the format string):
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stmfd sp!, {r7, lr}
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add r7, sp, #0
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sub sp, sp, #12
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stmia sp, {r0, r1, r2}
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ldmia sp, {r1-r2}
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ldr r0, L5
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ldr r3, [sp, #8]
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L2:
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add r0, pc, r0
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bl L_printf$stub
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Instead of a stmia, ldmia, and a ldr, wouldn't it be better to do three moves?
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* Return an aggregate type is even worse:
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e.g.
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struct s foo(void) {
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struct s S = {1.1, 2};
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return S;
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}
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mov ip, r0
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ldr r0, L5
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sub sp, sp, #12
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L2:
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add r0, pc, r0
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@ lr needed for prologue
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ldmia r0, {r0, r1, r2}
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stmia sp, {r0, r1, r2}
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stmia ip, {r0, r1, r2}
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mov r0, ip
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add sp, sp, #12
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bx lr
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r0 (and later ip) is the hidden parameter from caller to store the value in. The
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first ldmia loads the constants into r0, r1, r2. The last stmia stores r0, r1,
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r2 into the address passed in. However, there is one additional stmia that
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stores r0, r1, and r2 to some stack location. The store is dead.
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The llvm-gcc generated code looks like this:
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csretcc void %foo(%struct.s* %agg.result) {
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entry:
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%S = alloca %struct.s, align 4 ; <%struct.s*> [#uses=1]
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%memtmp = alloca %struct.s ; <%struct.s*> [#uses=1]
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cast %struct.s* %S to sbyte* ; <sbyte*>:0 [#uses=2]
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call void %llvm.memcpy.i32( sbyte* %0, sbyte* cast ({ double, int }* %C.0.904 to sbyte*), uint 12, uint 4 )
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cast %struct.s* %agg.result to sbyte* ; <sbyte*>:1 [#uses=2]
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call void %llvm.memcpy.i32( sbyte* %1, sbyte* %0, uint 12, uint 0 )
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cast %struct.s* %memtmp to sbyte* ; <sbyte*>:2 [#uses=1]
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call void %llvm.memcpy.i32( sbyte* %2, sbyte* %1, uint 12, uint 0 )
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ret void
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}
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llc ends up issuing two memcpy's (the first memcpy becomes 3 loads from
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constantpool). Perhaps we should 1) fix llvm-gcc so the memcpy is translated
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into a number of load and stores, or 2) custom lower memcpy (of small size) to
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be ldmia / stmia. I think option 2 is better but the current register
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allocator cannot allocate a chunk of registers at a time.
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A feasible temporary solution is to use specific physical registers at the
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lowering time for small (<= 4 words?) transfer size.
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* ARM CSRet calling convention requires the hidden argument to be returned by
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the callee.
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//===---------------------------------------------------------------------===//
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We can definitely do a better job on BB placements to eliminate some branches.
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It's very common to see llvm generated assembly code that looks like this:
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LBB3:
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...
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LBB4:
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...
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beq LBB3
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b LBB2
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If BB4 is the only predecessor of BB3, then we can emit BB3 after BB4. We can
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then eliminate beq and and turn the unconditional branch to LBB2 to a bne.
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See McCat/18-imp/ComputeBoundingBoxes for an example.
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//===---------------------------------------------------------------------===//
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Register scavenging is now implemented. The example in the previous version
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of this document produces optimal code at -O2.
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//===---------------------------------------------------------------------===//
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Pre-/post- indexed load / stores:
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1) We should not make the pre/post- indexed load/store transform if the base ptr
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is guaranteed to be live beyond the load/store. This can happen if the base
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ptr is live out of the block we are performing the optimization. e.g.
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mov r1, r2
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ldr r3, [r1], #4
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...
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vs.
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ldr r3, [r2]
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add r1, r2, #4
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...
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In most cases, this is just a wasted optimization. However, sometimes it can
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negatively impact the performance because two-address code is more restrictive
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when it comes to scheduling.
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Unfortunately, liveout information is currently unavailable during DAG combine
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time.
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2) Consider spliting a indexed load / store into a pair of add/sub + load/store
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to solve #1 (in TwoAddressInstructionPass.cpp).
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3) Enhance LSR to generate more opportunities for indexed ops.
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4) Once we added support for multiple result patterns, write indexed loads
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patterns instead of C++ instruction selection code.
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5) Use FLDM / FSTM to emulate indexed FP load / store.
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//===---------------------------------------------------------------------===//
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We should add i64 support to take advantage of the 64-bit load / stores.
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We can add a pseudo i64 register class containing pseudo registers that are
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register pairs. All other ops (e.g. add, sub) would be expanded as usual.
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We need to add pseudo instructions (i.e. gethi / getlo) to extract i32 registers
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from the i64 register. These are single moves which can be eliminated if the
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destination register is a sub-register of the source. We should implement proper
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subreg support in the register allocator to coalesce these away.
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There are other minor issues such as multiple instructions for a spill / restore
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/ move.
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//===---------------------------------------------------------------------===//
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Implement support for some more tricky ways to materialize immediates. For
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example, to get 0xffff8000, we can use:
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mov r9, #&3f8000
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sub r9, r9, #&400000
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//===---------------------------------------------------------------------===//
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We sometimes generate multiple add / sub instructions to update sp in prologue
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and epilogue if the inc / dec value is too large to fit in a single immediate
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operand. In some cases, perhaps it might be better to load the value from a
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constantpool instead.
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//===---------------------------------------------------------------------===//
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GCC generates significantly better code for this function.
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int foo(int StackPtr, unsigned char *Line, unsigned char *Stack, int LineLen) {
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int i = 0;
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if (StackPtr != 0) {
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while (StackPtr != 0 && i < (((LineLen) < (32768))? (LineLen) : (32768)))
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Line[i++] = Stack[--StackPtr];
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if (LineLen > 32768)
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{
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while (StackPtr != 0 && i < LineLen)
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{
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i++;
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--StackPtr;
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}
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}
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}
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return StackPtr;
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}
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//===---------------------------------------------------------------------===//
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This should compile to the mlas instruction:
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int mlas(int x, int y, int z) { return ((x * y + z) < 0) ? 7 : 13; }
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//===---------------------------------------------------------------------===//
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At some point, we should triage these to see if they still apply to us:
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=19598
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=18560
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=27016
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=11831
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=11826
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=11825
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=11824
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=11823
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=11820
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=10982
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=10242
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=9831
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=9760
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=9759
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=9703
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=9702
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http://gcc.gnu.org/bugzilla/show_bug.cgi?id=9663
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http://www.inf.u-szeged.hu/gcc-arm/
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http://citeseer.ist.psu.edu/debus04linktime.html
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//===---------------------------------------------------------------------===//
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gcc generates smaller code for this function at -O2 or -Os:
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void foo(signed char* p) {
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if (*p == 3)
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bar();
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else if (*p == 4)
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baz();
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else if (*p == 5)
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quux();
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}
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llvm decides it's a good idea to turn the repeated if...else into a
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binary tree, as if it were a switch; the resulting code requires -1
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compare-and-branches when *p<=2 or *p==5, the same number if *p==4
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or *p>6, and +1 if *p==3. So it should be a speed win
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(on balance). However, the revised code is larger, with 4 conditional
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branches instead of 3.
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More seriously, there is a byte->word extend before
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each comparison, where there should be only one, and the condition codes
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are not remembered when the same two values are compared twice.
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//===---------------------------------------------------------------------===//
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More register scavenging work:
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1. Use the register scavenger to track frame index materialized into registers
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(those that do not fit in addressing modes) to allow reuse in the same BB.
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2. Finish scavenging for Thumb.
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3. We know some spills and restores are unnecessary. The issue is once live
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intervals are merged, they are not never split. So every def is spilled
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and every use requires a restore if the register allocator decides the
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resulting live interval is not assigned a physical register. It may be
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possible (with the help of the scavenger) to turn some spill / restore
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pairs into register copies.
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//===---------------------------------------------------------------------===//
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Teach LSR about ARM addressing modes.
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