llvm-6502/lib/Target/X86/README-SSE.txt
Chris Lattner e6c1473e56 Bill implemented this.
git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@63752 91177308-0d34-0410-b5e6-96231b3b80d8
2009-02-04 19:09:07 +00:00

919 lines
26 KiB
Plaintext

//===---------------------------------------------------------------------===//
// Random ideas for the X86 backend: SSE-specific stuff.
//===---------------------------------------------------------------------===//
- Consider eliminating the unaligned SSE load intrinsics, replacing them with
unaligned LLVM load instructions.
//===---------------------------------------------------------------------===//
Expand libm rounding functions inline: Significant speedups possible.
http://gcc.gnu.org/ml/gcc-patches/2006-10/msg00909.html
//===---------------------------------------------------------------------===//
When compiled with unsafemath enabled, "main" should enable SSE DAZ mode and
other fast SSE modes.
//===---------------------------------------------------------------------===//
Think about doing i64 math in SSE regs on x86-32.
//===---------------------------------------------------------------------===//
This testcase should have no SSE instructions in it, and only one load from
a constant pool:
double %test3(bool %B) {
%C = select bool %B, double 123.412, double 523.01123123
ret double %C
}
Currently, the select is being lowered, which prevents the dag combiner from
turning 'select (load CPI1), (load CPI2)' -> 'load (select CPI1, CPI2)'
The pattern isel got this one right.
//===---------------------------------------------------------------------===//
SSE doesn't have [mem] op= reg instructions. If we have an SSE instruction
like this:
X += y
and the register allocator decides to spill X, it is cheaper to emit this as:
Y += [xslot]
store Y -> [xslot]
than as:
tmp = [xslot]
tmp += y
store tmp -> [xslot]
..and this uses one fewer register (so this should be done at load folding
time, not at spiller time). *Note* however that this can only be done
if Y is dead. Here's a testcase:
@.str_3 = external global [15 x i8]
declare void @printf(i32, ...)
define void @main() {
build_tree.exit:
br label %no_exit.i7
no_exit.i7: ; preds = %no_exit.i7, %build_tree.exit
%tmp.0.1.0.i9 = phi double [ 0.000000e+00, %build_tree.exit ],
[ %tmp.34.i18, %no_exit.i7 ]
%tmp.0.0.0.i10 = phi double [ 0.000000e+00, %build_tree.exit ],
[ %tmp.28.i16, %no_exit.i7 ]
%tmp.28.i16 = add double %tmp.0.0.0.i10, 0.000000e+00
%tmp.34.i18 = add double %tmp.0.1.0.i9, 0.000000e+00
br i1 false, label %Compute_Tree.exit23, label %no_exit.i7
Compute_Tree.exit23: ; preds = %no_exit.i7
tail call void (i32, ...)* @printf( i32 0 )
store double %tmp.34.i18, double* null
ret void
}
We currently emit:
.BBmain_1:
xorpd %XMM1, %XMM1
addsd %XMM0, %XMM1
*** movsd %XMM2, QWORD PTR [%ESP + 8]
*** addsd %XMM2, %XMM1
*** movsd QWORD PTR [%ESP + 8], %XMM2
jmp .BBmain_1 # no_exit.i7
This is a bugpoint reduced testcase, which is why the testcase doesn't make
much sense (e.g. its an infinite loop). :)
//===---------------------------------------------------------------------===//
SSE should implement 'select_cc' using 'emulated conditional moves' that use
pcmp/pand/pandn/por to do a selection instead of a conditional branch:
double %X(double %Y, double %Z, double %A, double %B) {
%C = setlt double %A, %B
%z = add double %Z, 0.0 ;; select operand is not a load
%D = select bool %C, double %Y, double %z
ret double %D
}
We currently emit:
_X:
subl $12, %esp
xorpd %xmm0, %xmm0
addsd 24(%esp), %xmm0
movsd 32(%esp), %xmm1
movsd 16(%esp), %xmm2
ucomisd 40(%esp), %xmm1
jb LBB_X_2
LBB_X_1:
movsd %xmm0, %xmm2
LBB_X_2:
movsd %xmm2, (%esp)
fldl (%esp)
addl $12, %esp
ret
//===---------------------------------------------------------------------===//
It's not clear whether we should use pxor or xorps / xorpd to clear XMM
registers. The choice may depend on subtarget information. We should do some
more experiments on different x86 machines.
//===---------------------------------------------------------------------===//
Lower memcpy / memset to a series of SSE 128 bit move instructions when it's
feasible.
//===---------------------------------------------------------------------===//
Codegen:
if (copysign(1.0, x) == copysign(1.0, y))
into:
if (x^y & mask)
when using SSE.
//===---------------------------------------------------------------------===//
Use movhps to update upper 64-bits of a v4sf value. Also movlps on lower half
of a v4sf value.
//===---------------------------------------------------------------------===//
Better codegen for vector_shuffles like this { x, 0, 0, 0 } or { x, 0, x, 0}.
Perhaps use pxor / xorp* to clear a XMM register first?
//===---------------------------------------------------------------------===//
How to decide when to use the "floating point version" of logical ops? Here are
some code fragments:
movaps LCPI5_5, %xmm2
divps %xmm1, %xmm2
mulps %xmm2, %xmm3
mulps 8656(%ecx), %xmm3
addps 8672(%ecx), %xmm3
andps LCPI5_6, %xmm2
andps LCPI5_1, %xmm3
por %xmm2, %xmm3
movdqa %xmm3, (%edi)
movaps LCPI5_5, %xmm1
divps %xmm0, %xmm1
mulps %xmm1, %xmm3
mulps 8656(%ecx), %xmm3
addps 8672(%ecx), %xmm3
andps LCPI5_6, %xmm1
andps LCPI5_1, %xmm3
orps %xmm1, %xmm3
movaps %xmm3, 112(%esp)
movaps %xmm3, (%ebx)
Due to some minor source change, the later case ended up using orps and movaps
instead of por and movdqa. Does it matter?
//===---------------------------------------------------------------------===//
X86RegisterInfo::copyRegToReg() returns X86::MOVAPSrr for VR128. Is it possible
to choose between movaps, movapd, and movdqa based on types of source and
destination?
How about andps, andpd, and pand? Do we really care about the type of the packed
elements? If not, why not always use the "ps" variants which are likely to be
shorter.
//===---------------------------------------------------------------------===//
External test Nurbs exposed some problems. Look for
__ZN15Nurbs_SSE_Cubic17TessellateSurfaceE, bb cond_next140. This is what icc
emits:
movaps (%edx), %xmm2 #59.21
movaps (%edx), %xmm5 #60.21
movaps (%edx), %xmm4 #61.21
movaps (%edx), %xmm3 #62.21
movl 40(%ecx), %ebp #69.49
shufps $0, %xmm2, %xmm5 #60.21
movl 100(%esp), %ebx #69.20
movl (%ebx), %edi #69.20
imull %ebp, %edi #69.49
addl (%eax), %edi #70.33
shufps $85, %xmm2, %xmm4 #61.21
shufps $170, %xmm2, %xmm3 #62.21
shufps $255, %xmm2, %xmm2 #63.21
lea (%ebp,%ebp,2), %ebx #69.49
negl %ebx #69.49
lea -3(%edi,%ebx), %ebx #70.33
shll $4, %ebx #68.37
addl 32(%ecx), %ebx #68.37
testb $15, %bl #91.13
jne L_B1.24 # Prob 5% #91.13
This is the llvm code after instruction scheduling:
cond_next140 (0xa910740, LLVM BB @0xa90beb0):
%reg1078 = MOV32ri -3
%reg1079 = ADD32rm %reg1078, %reg1068, 1, %NOREG, 0
%reg1037 = MOV32rm %reg1024, 1, %NOREG, 40
%reg1080 = IMUL32rr %reg1079, %reg1037
%reg1081 = MOV32rm %reg1058, 1, %NOREG, 0
%reg1038 = LEA32r %reg1081, 1, %reg1080, -3
%reg1036 = MOV32rm %reg1024, 1, %NOREG, 32
%reg1082 = SHL32ri %reg1038, 4
%reg1039 = ADD32rr %reg1036, %reg1082
%reg1083 = MOVAPSrm %reg1059, 1, %NOREG, 0
%reg1034 = SHUFPSrr %reg1083, %reg1083, 170
%reg1032 = SHUFPSrr %reg1083, %reg1083, 0
%reg1035 = SHUFPSrr %reg1083, %reg1083, 255
%reg1033 = SHUFPSrr %reg1083, %reg1083, 85
%reg1040 = MOV32rr %reg1039
%reg1084 = AND32ri8 %reg1039, 15
CMP32ri8 %reg1084, 0
JE mbb<cond_next204,0xa914d30>
Still ok. After register allocation:
cond_next140 (0xa910740, LLVM BB @0xa90beb0):
%EAX = MOV32ri -3
%EDX = MOV32rm <fi#3>, 1, %NOREG, 0
ADD32rm %EAX<def&use>, %EDX, 1, %NOREG, 0
%EDX = MOV32rm <fi#7>, 1, %NOREG, 0
%EDX = MOV32rm %EDX, 1, %NOREG, 40
IMUL32rr %EAX<def&use>, %EDX
%ESI = MOV32rm <fi#5>, 1, %NOREG, 0
%ESI = MOV32rm %ESI, 1, %NOREG, 0
MOV32mr <fi#4>, 1, %NOREG, 0, %ESI
%EAX = LEA32r %ESI, 1, %EAX, -3
%ESI = MOV32rm <fi#7>, 1, %NOREG, 0
%ESI = MOV32rm %ESI, 1, %NOREG, 32
%EDI = MOV32rr %EAX
SHL32ri %EDI<def&use>, 4
ADD32rr %EDI<def&use>, %ESI
%XMM0 = MOVAPSrm %ECX, 1, %NOREG, 0
%XMM1 = MOVAPSrr %XMM0
SHUFPSrr %XMM1<def&use>, %XMM1, 170
%XMM2 = MOVAPSrr %XMM0
SHUFPSrr %XMM2<def&use>, %XMM2, 0
%XMM3 = MOVAPSrr %XMM0
SHUFPSrr %XMM3<def&use>, %XMM3, 255
SHUFPSrr %XMM0<def&use>, %XMM0, 85
%EBX = MOV32rr %EDI
AND32ri8 %EBX<def&use>, 15
CMP32ri8 %EBX, 0
JE mbb<cond_next204,0xa914d30>
This looks really bad. The problem is shufps is a destructive opcode. Since it
appears as operand two in more than one shufps ops. It resulted in a number of
copies. Note icc also suffers from the same problem. Either the instruction
selector should select pshufd or The register allocator can made the two-address
to three-address transformation.
It also exposes some other problems. See MOV32ri -3 and the spills.
//===---------------------------------------------------------------------===//
http://gcc.gnu.org/bugzilla/show_bug.cgi?id=25500
LLVM is producing bad code.
LBB_main_4: # cond_true44
addps %xmm1, %xmm2
subps %xmm3, %xmm2
movaps (%ecx), %xmm4
movaps %xmm2, %xmm1
addps %xmm4, %xmm1
addl $16, %ecx
incl %edx
cmpl $262144, %edx
movaps %xmm3, %xmm2
movaps %xmm4, %xmm3
jne LBB_main_4 # cond_true44
There are two problems. 1) No need to two loop induction variables. We can
compare against 262144 * 16. 2) Known register coalescer issue. We should
be able eliminate one of the movaps:
addps %xmm2, %xmm1 <=== Commute!
subps %xmm3, %xmm1
movaps (%ecx), %xmm4
movaps %xmm1, %xmm1 <=== Eliminate!
addps %xmm4, %xmm1
addl $16, %ecx
incl %edx
cmpl $262144, %edx
movaps %xmm3, %xmm2
movaps %xmm4, %xmm3
jne LBB_main_4 # cond_true44
//===---------------------------------------------------------------------===//
Consider:
__m128 test(float a) {
return _mm_set_ps(0.0, 0.0, 0.0, a*a);
}
This compiles into:
movss 4(%esp), %xmm1
mulss %xmm1, %xmm1
xorps %xmm0, %xmm0
movss %xmm1, %xmm0
ret
Because mulss doesn't modify the top 3 elements, the top elements of
xmm1 are already zero'd. We could compile this to:
movss 4(%esp), %xmm0
mulss %xmm0, %xmm0
ret
//===---------------------------------------------------------------------===//
Here's a sick and twisted idea. Consider code like this:
__m128 test(__m128 a) {
float b = *(float*)&A;
...
return _mm_set_ps(0.0, 0.0, 0.0, b);
}
This might compile to this code:
movaps c(%esp), %xmm1
xorps %xmm0, %xmm0
movss %xmm1, %xmm0
ret
Now consider if the ... code caused xmm1 to get spilled. This might produce
this code:
movaps c(%esp), %xmm1
movaps %xmm1, c2(%esp)
...
xorps %xmm0, %xmm0
movaps c2(%esp), %xmm1
movss %xmm1, %xmm0
ret
However, since the reload is only used by these instructions, we could
"fold" it into the uses, producing something like this:
movaps c(%esp), %xmm1
movaps %xmm1, c2(%esp)
...
movss c2(%esp), %xmm0
ret
... saving two instructions.
The basic idea is that a reload from a spill slot, can, if only one 4-byte
chunk is used, bring in 3 zeros the the one element instead of 4 elements.
This can be used to simplify a variety of shuffle operations, where the
elements are fixed zeros.
//===---------------------------------------------------------------------===//
__m128d test1( __m128d A, __m128d B) {
return _mm_shuffle_pd(A, B, 0x3);
}
compiles to
shufpd $3, %xmm1, %xmm0
Perhaps it's better to use unpckhpd instead?
unpckhpd %xmm1, %xmm0
Don't know if unpckhpd is faster. But it is shorter.
//===---------------------------------------------------------------------===//
This code generates ugly code, probably due to costs being off or something:
define void @test(float* %P, <4 x float>* %P2 ) {
%xFloat0.688 = load float* %P
%tmp = load <4 x float>* %P2
%inFloat3.713 = insertelement <4 x float> %tmp, float 0.0, i32 3
store <4 x float> %inFloat3.713, <4 x float>* %P2
ret void
}
Generates:
_test:
movl 8(%esp), %eax
movaps (%eax), %xmm0
pxor %xmm1, %xmm1
movaps %xmm0, %xmm2
shufps $50, %xmm1, %xmm2
shufps $132, %xmm2, %xmm0
movaps %xmm0, (%eax)
ret
Would it be better to generate:
_test:
movl 8(%esp), %ecx
movaps (%ecx), %xmm0
xor %eax, %eax
pinsrw $6, %eax, %xmm0
pinsrw $7, %eax, %xmm0
movaps %xmm0, (%ecx)
ret
?
//===---------------------------------------------------------------------===//
Some useful information in the Apple Altivec / SSE Migration Guide:
http://developer.apple.com/documentation/Performance/Conceptual/
Accelerate_sse_migration/index.html
e.g. SSE select using and, andnot, or. Various SSE compare translations.
//===---------------------------------------------------------------------===//
Add hooks to commute some CMPP operations.
//===---------------------------------------------------------------------===//
Apply the same transformation that merged four float into a single 128-bit load
to loads from constant pool.
//===---------------------------------------------------------------------===//
Floating point max / min are commutable when -enable-unsafe-fp-path is
specified. We should turn int_x86_sse_max_ss and X86ISD::FMIN etc. into other
nodes which are selected to max / min instructions that are marked commutable.
//===---------------------------------------------------------------------===//
We should materialize vector constants like "all ones" and "signbit" with
code like:
cmpeqps xmm1, xmm1 ; xmm1 = all-ones
and:
cmpeqps xmm1, xmm1 ; xmm1 = all-ones
psrlq xmm1, 31 ; xmm1 = all 100000000000...
instead of using a load from the constant pool. The later is important for
ABS/NEG/copysign etc.
//===---------------------------------------------------------------------===//
These functions:
#include <xmmintrin.h>
__m128i a;
void x(unsigned short n) {
a = _mm_slli_epi32 (a, n);
}
void y(unsigned n) {
a = _mm_slli_epi32 (a, n);
}
compile to ( -O3 -static -fomit-frame-pointer):
_x:
movzwl 4(%esp), %eax
movd %eax, %xmm0
movaps _a, %xmm1
pslld %xmm0, %xmm1
movaps %xmm1, _a
ret
_y:
movd 4(%esp), %xmm0
movaps _a, %xmm1
pslld %xmm0, %xmm1
movaps %xmm1, _a
ret
"y" looks good, but "x" does silly movzwl stuff around into a GPR. It seems
like movd would be sufficient in both cases as the value is already zero
extended in the 32-bit stack slot IIRC. For signed short, it should also be
save, as a really-signed value would be undefined for pslld.
//===---------------------------------------------------------------------===//
#include <math.h>
int t1(double d) { return signbit(d); }
This currently compiles to:
subl $12, %esp
movsd 16(%esp), %xmm0
movsd %xmm0, (%esp)
movl 4(%esp), %eax
shrl $31, %eax
addl $12, %esp
ret
We should use movmskp{s|d} instead.
//===---------------------------------------------------------------------===//
CodeGen/X86/vec_align.ll tests whether we can turn 4 scalar loads into a single
(aligned) vector load. This functionality has a couple of problems.
1. The code to infer alignment from loads of globals is in the X86 backend,
not the dag combiner. This is because dagcombine2 needs to be able to see
through the X86ISD::Wrapper node, which DAGCombine can't really do.
2. The code for turning 4 x load into a single vector load is target
independent and should be moved to the dag combiner.
3. The code for turning 4 x load into a vector load can only handle a direct
load from a global or a direct load from the stack. It should be generalized
to handle any load from P, P+4, P+8, P+12, where P can be anything.
4. The alignment inference code cannot handle loads from globals in non-static
mode because it doesn't look through the extra dyld stub load. If you try
vec_align.ll without -relocation-model=static, you'll see what I mean.
//===---------------------------------------------------------------------===//
We should lower store(fneg(load p), q) into an integer load+xor+store, which
eliminates a constant pool load. For example, consider:
define i64 @ccosf(float %z.0, float %z.1) nounwind readonly {
entry:
%tmp6 = sub float -0.000000e+00, %z.1 ; <float> [#uses=1]
%tmp20 = tail call i64 @ccoshf( float %tmp6, float %z.0 ) nounwind readonly
ret i64 %tmp20
}
This currently compiles to:
LCPI1_0: # <4 x float>
.long 2147483648 # float -0
.long 2147483648 # float -0
.long 2147483648 # float -0
.long 2147483648 # float -0
_ccosf:
subl $12, %esp
movss 16(%esp), %xmm0
movss %xmm0, 4(%esp)
movss 20(%esp), %xmm0
xorps LCPI1_0, %xmm0
movss %xmm0, (%esp)
call L_ccoshf$stub
addl $12, %esp
ret
Note the load into xmm0, then xor (to negate), then store. In PIC mode,
this code computes the pic base and does two loads to do the constant pool
load, so the improvement is much bigger.
The tricky part about this xform is that the argument load/store isn't exposed
until post-legalize, and at that point, the fneg has been custom expanded into
an X86 fxor. This means that we need to handle this case in the x86 backend
instead of in target independent code.
//===---------------------------------------------------------------------===//
Non-SSE4 insert into 16 x i8 is atrociously bad.
//===---------------------------------------------------------------------===//
<2 x i64> extract is substantially worse than <2 x f64>, even if the destination
is memory.
//===---------------------------------------------------------------------===//
SSE4 extract-to-mem ops aren't being pattern matched because of the AssertZext
sitting between the truncate and the extract.
//===---------------------------------------------------------------------===//
INSERTPS can match any insert (extract, imm1), imm2 for 4 x float, and insert
any number of 0.0 simultaneously. Currently we only use it for simple
insertions.
See comments in LowerINSERT_VECTOR_ELT_SSE4.
//===---------------------------------------------------------------------===//
On a random note, SSE2 should declare insert/extract of 2 x f64 as legal, not
Custom. All combinations of insert/extract reg-reg, reg-mem, and mem-reg are
legal, it'll just take a few extra patterns written in the .td file.
Note: this is not a code quality issue; the custom lowered code happens to be
right, but we shouldn't have to custom lower anything. This is probably related
to <2 x i64> ops being so bad.
//===---------------------------------------------------------------------===//
'select' on vectors and scalars could be a whole lot better. We currently
lower them to conditional branches. On x86-64 for example, we compile this:
double test(double a, double b, double c, double d) { return a<b ? c : d; }
to:
_test:
ucomisd %xmm0, %xmm1
ja LBB1_2 # entry
LBB1_1: # entry
movapd %xmm3, %xmm2
LBB1_2: # entry
movapd %xmm2, %xmm0
ret
instead of:
_test:
cmpltsd %xmm1, %xmm0
andpd %xmm0, %xmm2
andnpd %xmm3, %xmm0
orpd %xmm2, %xmm0
ret
For unpredictable branches, the later is much more efficient. This should
just be a matter of having scalar sse map to SELECT_CC and custom expanding
or iseling it.
//===---------------------------------------------------------------------===//
LLVM currently generates stack realignment code, when it is not necessary
needed. The problem is that we need to know about stack alignment too early,
before RA runs.
At that point we don't know, whether there will be vector spill, or not.
Stack realignment logic is overly conservative here, but otherwise we can
produce unaligned loads/stores.
Fixing this will require some huge RA changes.
Testcase:
#include <emmintrin.h>
typedef short vSInt16 __attribute__ ((__vector_size__ (16)));
static const vSInt16 a = {- 22725, - 12873, - 22725, - 12873, - 22725, - 12873,
- 22725, - 12873};;
vSInt16 madd(vSInt16 b)
{
return _mm_madd_epi16(a, b);
}
Generated code (x86-32, linux):
madd:
pushl %ebp
movl %esp, %ebp
andl $-16, %esp
movaps .LCPI1_0, %xmm1
pmaddwd %xmm1, %xmm0
movl %ebp, %esp
popl %ebp
ret
//===---------------------------------------------------------------------===//
Consider:
#include <emmintrin.h>
__m128 foo2 (float x) {
return _mm_set_ps (0, 0, x, 0);
}
In x86-32 mode, we generate this spiffy code:
_foo2:
movss 4(%esp), %xmm0
pshufd $81, %xmm0, %xmm0
ret
in x86-64 mode, we generate this code, which could be better:
_foo2:
xorps %xmm1, %xmm1
movss %xmm0, %xmm1
pshufd $81, %xmm1, %xmm0
ret
In sse4 mode, we could use insertps to make both better.
Here's another testcase that could use insertps [mem]:
#include <xmmintrin.h>
extern float x2, x3;
__m128 foo1 (float x1, float x4) {
return _mm_set_ps (x2, x1, x3, x4);
}
gcc mainline compiles it to:
foo1:
insertps $0x10, x2(%rip), %xmm0
insertps $0x10, x3(%rip), %xmm1
movaps %xmm1, %xmm2
movlhps %xmm0, %xmm2
movaps %xmm2, %xmm0
ret
//===---------------------------------------------------------------------===//
We compile vector multiply-by-constant into poor code:
define <4 x i32> @f(<4 x i32> %i) nounwind {
%A = mul <4 x i32> %i, < i32 10, i32 10, i32 10, i32 10 >
ret <4 x i32> %A
}
On targets without SSE4.1, this compiles into:
LCPI1_0: ## <4 x i32>
.long 10
.long 10
.long 10
.long 10
.text
.align 4,0x90
.globl _f
_f:
pshufd $3, %xmm0, %xmm1
movd %xmm1, %eax
imull LCPI1_0+12, %eax
movd %eax, %xmm1
pshufd $1, %xmm0, %xmm2
movd %xmm2, %eax
imull LCPI1_0+4, %eax
movd %eax, %xmm2
punpckldq %xmm1, %xmm2
movd %xmm0, %eax
imull LCPI1_0, %eax
movd %eax, %xmm1
movhlps %xmm0, %xmm0
movd %xmm0, %eax
imull LCPI1_0+8, %eax
movd %eax, %xmm0
punpckldq %xmm0, %xmm1
movaps %xmm1, %xmm0
punpckldq %xmm2, %xmm0
ret
It would be better to synthesize integer vector multiplication by constants
using shifts and adds, pslld and paddd here. And even on targets with SSE4.1,
simple cases such as multiplication by powers of two would be better as
vector shifts than as multiplications.
//===---------------------------------------------------------------------===//
We compile this:
__m128i
foo2 (char x)
{
return _mm_set_epi8 (1, 0, 0, 0, 0, 0, 0, 0, 0, x, 0, 1, 0, 0, 0, 0);
}
into:
movl $1, %eax
xorps %xmm0, %xmm0
pinsrw $2, %eax, %xmm0
movzbl 4(%esp), %eax
pinsrw $3, %eax, %xmm0
movl $256, %eax
pinsrw $7, %eax, %xmm0
ret
gcc-4.2:
subl $12, %esp
movzbl 16(%esp), %eax
movdqa LC0, %xmm0
pinsrw $3, %eax, %xmm0
addl $12, %esp
ret
.const
.align 4
LC0:
.word 0
.word 0
.word 1
.word 0
.word 0
.word 0
.word 0
.word 256
With SSE4, it should be
movdqa .LC0(%rip), %xmm0
pinsrb $6, %edi, %xmm0
//===---------------------------------------------------------------------===//
We should transform a shuffle of two vectors of constants into a single vector
of constants. Also, insertelement of a constant into a vector of constants
should also result in a vector of constants. e.g. 2008-06-25-VecISelBug.ll.
We compiled it to something horrible:
.align 4
LCPI1_1: ## float
.long 1065353216 ## float 1
.const
.align 4
LCPI1_0: ## <4 x float>
.space 4
.long 1065353216 ## float 1
.space 4
.long 1065353216 ## float 1
.text
.align 4,0x90
.globl _t
_t:
xorps %xmm0, %xmm0
movhps LCPI1_0, %xmm0
movss LCPI1_1, %xmm1
movaps %xmm0, %xmm2
shufps $2, %xmm1, %xmm2
shufps $132, %xmm2, %xmm0
movaps %xmm0, 0
//===---------------------------------------------------------------------===//
rdar://5907648
This function:
float foo(unsigned char x) {
return x;
}
compiles to (x86-32):
define float @foo(i8 zeroext %x) nounwind {
%tmp12 = uitofp i8 %x to float ; <float> [#uses=1]
ret float %tmp12
}
compiles to:
_foo:
subl $4, %esp
movzbl 8(%esp), %eax
cvtsi2ss %eax, %xmm0
movss %xmm0, (%esp)
flds (%esp)
addl $4, %esp
ret
We should be able to use:
cvtsi2ss 8($esp), %xmm0
since we know the stack slot is already zext'd.
//===---------------------------------------------------------------------===//
Consider using movlps instead of movsd to implement (scalar_to_vector (loadf64))
when code size is critical. movlps is slower than movsd on core2 but it's one
byte shorter.
//===---------------------------------------------------------------------===//
We should use a dynamic programming based approach to tell when using FPStack
operations is cheaper than SSE. SciMark montecarlo contains code like this
for example:
double MonteCarlo_num_flops(int Num_samples) {
return ((double) Num_samples)* 4.0;
}
In fpstack mode, this compiles into:
LCPI1_0:
.long 1082130432 ## float 4.000000e+00
_MonteCarlo_num_flops:
subl $4, %esp
movl 8(%esp), %eax
movl %eax, (%esp)
fildl (%esp)
fmuls LCPI1_0
addl $4, %esp
ret
in SSE mode, it compiles into significantly slower code:
_MonteCarlo_num_flops:
subl $12, %esp
cvtsi2sd 16(%esp), %xmm0
mulsd LCPI1_0, %xmm0
movsd %xmm0, (%esp)
fldl (%esp)
addl $12, %esp
ret
There are also other cases in scimark where using fpstack is better, it is
cheaper to do fld1 than load from a constant pool for example, so
"load, add 1.0, store" is better done in the fp stack, etc.
//===---------------------------------------------------------------------===//