Exemplo n.º 1
0
// Rewrite a SIMD indirection as GT_IND(GT_LEA(obj.op1)), or as a simple
// lclVar if possible.
//
// Arguments:
//    use      - A use reference for a block node
//    keepBlk  - True if this should remain a block node if it is not a lclVar
//
// Return Value:
//    None.
//
// TODO-1stClassStructs: These should be eliminated earlier, once we can handle
// lclVars in all the places that used to have GT_OBJ.
//
void Rationalizer::RewriteSIMDOperand(LIR::Use& use, bool keepBlk)
{
#ifdef FEATURE_SIMD
    // No lowering is needed for non-SIMD nodes, so early out if featureSIMD is not enabled.
    if (!comp->featureSIMD)
    {
        return;
    }

    GenTree* tree = use.Def();
    if (!tree->OperIsIndir())
    {
        return;
    }
    var_types simdType = tree->TypeGet();

    if (!varTypeIsSIMD(simdType))
    {
        return;
    }

    // If we have GT_IND(GT_LCL_VAR_ADDR) and the GT_LCL_VAR_ADDR is TYP_BYREF/TYP_I_IMPL,
    // and the var is a SIMD type, replace the expression by GT_LCL_VAR.
    GenTree* addr = tree->AsIndir()->Addr();
    if (addr->OperIsLocalAddr() && comp->isAddrOfSIMDType(addr))
    {
        BlockRange().Remove(tree);

        addr->SetOper(loadForm(addr->OperGet()));
        addr->gtType = simdType;
        use.ReplaceWith(comp, addr);
    }
    else if ((addr->OperGet() == GT_ADDR) && (addr->gtGetOp1()->OperGet() == GT_SIMD))
    {
        // if we have GT_IND(GT_ADDR(GT_SIMD)), remove the GT_IND(GT_ADDR()), leaving just the GT_SIMD.
        BlockRange().Remove(tree);
        BlockRange().Remove(addr);

        use.ReplaceWith(comp, addr->gtGetOp1());
    }
    else if (!keepBlk)
    {
        tree->SetOper(GT_IND);
        tree->gtType = simdType;
    }
#endif // FEATURE_SIMD
}
Exemplo n.º 2
0
// Rewrite GT_OBJ of SIMD Vector as GT_IND(GT_LEA(obj.op1)) of a SIMD type.
//
// Arguments:
//    ppTree      - A pointer-to-a-pointer for the GT_OBJ
//    fgWalkData  - A pointer to tree walk data providing the context
//
// Return Value:
//    None.
//
// TODO-Cleanup: Once SIMD types are plumbed through the frontend, this will no longer
// be required.
//
void Rationalizer::RewriteObj(LIR::Use& use)
{
#ifdef FEATURE_SIMD
    GenTreeObj* obj = use.Def()->AsObj();

// For UNIX struct passing, we can have Obj nodes for arguments.
// For other cases, we should never see a non-SIMD type here.
#ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
    if (!varTypeIsSIMD(obj))
    {
        return;
    }
#endif // FEATURE_UNIX_AMD64_STRUCT_PASSING

    // Should come here only if featureSIMD is enabled
    noway_assert(comp->featureSIMD);

    // We should only call this with a SIMD type.
    noway_assert(varTypeIsSIMD(obj));
    var_types simdType = obj->TypeGet();

    // If the operand of obj is a GT_ADDR(GT_LCL_VAR) and LclVar is known to be a SIMD type,
    // replace obj by GT_LCL_VAR.
    GenTree* srcAddr = obj->gtGetOp1();
    if (srcAddr->OperIsLocalAddr() && comp->isAddrOfSIMDType(srcAddr))
    {
        BlockRange().Remove(obj);

        srcAddr->SetOper(loadForm(srcAddr->OperGet()));
        srcAddr->gtType = simdType;
        use.ReplaceWith(comp, srcAddr);
    }
    else
    {
        obj->SetOper(GT_IND);
        obj->gtType = simdType;
    }
#else
    // we should never reach without feature SIMD
    assert(!"Unexpected obj during rationalization\n");
    unreached();
#endif
}
Exemplo n.º 3
0
// Rewrite a SIMD indirection as GT_IND(GT_LEA(obj.op1)), or as a simple
// lclVar if possible.
//
// Arguments:
//    use      - A use reference for a block node
//    keepBlk  - True if this should remain a block node if it is not a lclVar
//
// Return Value:
//    None.
//
// TODO-1stClassStructs: These should be eliminated earlier, once we can handle
// lclVars in all the places that used to have GT_OBJ.
//
void Rationalizer::RewriteSIMDOperand(LIR::Use& use, bool keepBlk)
{
#ifdef FEATURE_SIMD
    // No lowering is needed for non-SIMD nodes, so early out if featureSIMD is not enabled.
    if (!comp->featureSIMD)
    {
        return;
    }

    GenTree* tree = use.Def();
    if (!tree->OperIsIndir())
    {
        return;
    }
    var_types simdType = tree->TypeGet();

    if (!varTypeIsSIMD(simdType))
    {
        return;
    }

    // If the operand of is a GT_ADDR(GT_LCL_VAR) and LclVar is known to be of simdType,
    // replace obj by GT_LCL_VAR.
    GenTree* addr = tree->AsIndir()->Addr();
    if (addr->OperIsLocalAddr() && comp->isAddrOfSIMDType(addr))
    {
        BlockRange().Remove(tree);

        addr->SetOper(loadForm(addr->OperGet()));
        addr->gtType = simdType;
        use.ReplaceWith(comp, addr);
    }
    else if (!keepBlk)
    {
        tree->SetOper(GT_IND);
        tree->gtType = simdType;
    }
#endif // FEATURE_SIMD
}
Exemplo n.º 4
0
//------------------------------------------------------------------------
// LowerBlockStore: Set block store type
//
// Arguments:
//    blkNode       - The block store node of interest
//
// Return Value:
//    None.
//
void Lowering::LowerBlockStore(GenTreeBlk* blkNode)
{
    GenTree*  dstAddr  = blkNode->Addr();
    unsigned  size     = blkNode->gtBlkSize;
    GenTree*  source   = blkNode->Data();
    Compiler* compiler = comp;

    // Sources are dest address and initVal or source.
    GenTree* srcAddrOrFill = nullptr;
    bool     isInitBlk     = blkNode->OperIsInitBlkOp();

    if (!isInitBlk)
    {
        // CopyObj or CopyBlk
        if ((blkNode->OperGet() == GT_STORE_OBJ) && ((blkNode->AsObj()->gtGcPtrCount == 0) || blkNode->gtBlkOpGcUnsafe))
        {
            blkNode->SetOper(GT_STORE_BLK);
        }
        if (source->gtOper == GT_IND)
        {
            srcAddrOrFill = blkNode->Data()->gtGetOp1();
        }
    }

    if (isInitBlk)
    {
        GenTree* initVal = source;
        if (initVal->OperIsInitVal())
        {
            initVal->SetContained();
            initVal = initVal->gtGetOp1();
        }
        srcAddrOrFill = initVal;

#ifdef _TARGET_ARM64_
        if ((size != 0) && (size <= INITBLK_UNROLL_LIMIT) && initVal->IsCnsIntOrI())
        {
            // TODO-ARM-CQ: Currently we generate a helper call for every
            // initblk we encounter.  Later on we should implement loop unrolling
            // code sequences to improve CQ.
            // For reference see the code in LowerXArch.cpp.
            NYI_ARM("initblk loop unrolling is currently not implemented.");

            // The fill value of an initblk is interpreted to hold a
            // value of (unsigned int8) however a constant of any size
            // may practically reside on the evaluation stack. So extract
            // the lower byte out of the initVal constant and replicate
            // it to a larger constant whose size is sufficient to support
            // the largest width store of the desired inline expansion.

            ssize_t fill = initVal->gtIntCon.gtIconVal & 0xFF;
            if (fill == 0)
            {
                MakeSrcContained(blkNode, source);
            }
            else if (size < REGSIZE_BYTES)
            {
                initVal->gtIntCon.gtIconVal = 0x01010101 * fill;
            }
            else
            {
                initVal->gtIntCon.gtIconVal = 0x0101010101010101LL * fill;
                initVal->gtType             = TYP_LONG;
            }
            blkNode->gtBlkOpKind = GenTreeBlk::BlkOpKindUnroll;
        }
        else
#endif // _TARGET_ARM64_
        {
            blkNode->gtBlkOpKind = GenTreeBlk::BlkOpKindHelper;
        }
    }
    else
    {
        // CopyObj or CopyBlk
        // Sources are src and dest and size if not constant.

        if (blkNode->OperGet() == GT_STORE_OBJ)
        {
            // CopyObj
            GenTreeObj* objNode = blkNode->AsObj();

            unsigned slots = objNode->gtSlots;

#ifdef DEBUG
            // CpObj must always have at least one GC-Pointer as a member.
            assert(objNode->gtGcPtrCount > 0);

            assert(dstAddr->gtType == TYP_BYREF || dstAddr->gtType == TYP_I_IMPL);

            CORINFO_CLASS_HANDLE clsHnd    = objNode->gtClass;
            size_t               classSize = compiler->info.compCompHnd->getClassSize(clsHnd);
            size_t               blkSize   = roundUp(classSize, TARGET_POINTER_SIZE);

            // Currently, the EE always round up a class data structure so
            // we are not handling the case where we have a non multiple of pointer sized
            // struct. This behavior may change in the future so in order to keeps things correct
            // let's assert it just to be safe. Going forward we should simply
            // handle this case.
            assert(classSize == blkSize);
            assert((blkSize / TARGET_POINTER_SIZE) == slots);
            assert(objNode->HasGCPtr());
#endif

            blkNode->gtBlkOpKind = GenTreeBlk::BlkOpKindUnroll;
        }
        else // CopyBlk
        {
            // In case of a CpBlk with a constant size and less than CPBLK_UNROLL_LIMIT size
            // we should unroll the loop to improve CQ.
            // For reference see the code in lowerxarch.cpp.

            if ((size != 0) && (size <= CPBLK_UNROLL_LIMIT))
            {
                blkNode->gtBlkOpKind = GenTreeBlk::BlkOpKindUnroll;
            }
            else
            {
                // In case we have a constant integer this means we went beyond
                // CPBLK_UNROLL_LIMIT bytes of size, still we should never have the case of
                // any GC-Pointers in the src struct.
                blkNode->gtBlkOpKind = GenTreeBlk::BlkOpKindHelper;
            }
        }
        // CopyObj or CopyBlk
        if (source->gtOper == GT_IND)
        {
            MakeSrcContained(blkNode, source);
            GenTree* addr = source->AsIndir()->Addr();
            if (!addr->OperIsLocalAddr())
            {
                addr->ClearContained();
            }
        }
        else if (!source->IsMultiRegCall() && !source->OperIsSIMD())
        {
            assert(source->IsLocal());
            MakeSrcContained(blkNode, source);
        }
    }
}
Exemplo n.º 5
0
// Transform CopyBlk involving SIMD vectors into stlclvar or stind of a SIMD type.
// Transformation is done if either src or dst are known to be SIMD vectors.
//
// Arguments:
//    ppTree      - A pointer-to-a-pointer for the GT_COPYBLK
//    fgWalkData  - A pointer to tree walk data providing the context
//
// Return Value:
//    None.
//
// If either the source or the dst are known to be SIMD (a lclVar or SIMD intrinsic),
// get the simdType (TYP_DOUBLE or a SIMD type for SSE2) from the size of the SIMD node.
//
// For the source:
// - If it is a SIMD intrinsic or a lvSIMDType lclVar, change the node type to simdType.
// - Otherwise, add a GT_IND of simdType.
// For the dst:
// - If it is a lclVar of a SIMD type, chanage the node type to simdType.
// - Otherwise, change it to a GT_STORE_IND of simdType
//
// TODO-Cleanup: Once SIMD types are plumbed through the frontend, this will no longer
// be required.
//
void Rationalizer::RewriteCopyBlk(LIR::Use& use)
{
#ifdef FEATURE_SIMD
    // No need to transofrm non-SIMD nodes, if featureSIMD is not enabled.
    if (!comp->featureSIMD)
    {
        return;
    }

    // See if this is a SIMD copyBlk
    GenTreeCpBlk* cpBlk   = use.Def()->AsCpBlk();
    GenTreePtr    dstAddr = cpBlk->Dest();
    GenTree*      srcAddr = cpBlk->Source();

    const bool srcIsSIMDAddr = comp->isAddrOfSIMDType(srcAddr);
    const bool dstIsSIMDAddr = comp->isAddrOfSIMDType(dstAddr);

    // Do not transform if neither src or dst is known to be a SIMD type.
    // If src tree type is something we cannot reason but if dst is known to be of a SIMD type
    // we will treat src tree as a SIMD type and vice versa.
    if (!srcIsSIMDAddr && !dstIsSIMDAddr)
    {
        return;
    }

    // At this point it is known to be a copyblk of SIMD vectors and we can
    // start transforming the original tree. Prior to this point do not perform
    // any modifications to the original tree.
    JITDUMP("\nRewriting SIMD CopyBlk\n");
    DISPTREERANGE(BlockRange(), cpBlk);

    // There are currently only three sizes supported: 8 bytes, 12 bytes, 16 bytes or the vector register length.
    GenTreeIntConCommon* sizeNode = cpBlk->Size()->AsIntConCommon();
    var_types            simdType = comp->getSIMDTypeForSize((unsigned int)sizeNode->IconValue());

    // Remove 'size' from execution order
    BlockRange().Remove(sizeNode);

    // Is destination a lclVar which is not an arg?
    // If yes then we can turn it to a stlcl.var, otherwise turn into stind.
    GenTree*   simdDst = nullptr;
    genTreeOps oper    = GT_NONE;
    if (dstIsSIMDAddr && dstAddr->OperIsLocalAddr())
    {
        simdDst         = dstAddr;
        simdDst->gtType = simdType;
        oper            = GT_STORE_LCL_VAR;

        // For structs that are padded (e.g. Vector3f, Vector3i), the morpher will have marked them
        // as GTF_VAR_USEASG.  Unmark them.
        simdDst->gtFlags &= ~(GTF_VAR_USEASG);
    }
    else
    {
        // Address of a non-local var
        simdDst = dstAddr;
        oper    = GT_STOREIND;
    }

    GenTree* simdSrc = nullptr;
    if ((srcAddr->OperGet() == GT_ADDR) && varTypeIsSIMD(srcAddr->gtGetOp1()))
    {
        // Get rid of parent node of GT_ADDR(..) if its child happens to be of a SIMD type.
        BlockRange().Remove(srcAddr);
        simdSrc = srcAddr->gtGetOp1();
    }
    else if (srcIsSIMDAddr && srcAddr->OperIsLocalAddr())
    {
        // If the source has been rewritten into a local addr node, rewrite it back into a
        // local var node.
        simdSrc = srcAddr;
        simdSrc->SetOper(loadForm(srcAddr->OperGet()));
    }
    else
    {
        // Since destination is known to be a SIMD type, src must be a SIMD type too
        // though we cannot figure it out easily enough. Transform src into
        // GT_IND(src) of simdType.
        GenTree* indir = comp->gtNewOperNode(GT_IND, simdType, srcAddr);
        BlockRange().InsertAfter(srcAddr, indir);

        cpBlk->gtGetOp1()->gtOp.gtOp2 = indir;
        simdSrc                       = indir;
    }
    simdSrc->gtType = simdType;

    // Change cpblk to either a st.lclvar or st.ind.
    // At this point we are manipulating cpblk node with the knowledge of
    // its internals (i.e. op1 is the size node, and the src & dst are in a GT_LIST on op2).
    // This logic might need to be changed if we ever restructure cpblk node.

    assert(simdDst != nullptr);
    assert(simdSrc != nullptr);

    GenTree* newNode = nullptr;
    if (oper == GT_STORE_LCL_VAR)
    {
        newNode = simdDst;
        newNode->SetOper(oper);

        GenTreeLclVar* store = newNode->AsLclVar();
        store->gtOp1         = simdSrc;
        store->gtType        = simdType;
        store->gtFlags |= ((simdSrc->gtFlags & GTF_ALL_EFFECT) | GTF_ASG);

        BlockRange().Remove(simdDst);
        BlockRange().InsertAfter(simdSrc, store);
    }
    else
    {
        assert(oper == GT_STOREIND);

        newNode = cpBlk->gtGetOp1();
        newNode->SetOper(oper);

        GenTreeStoreInd* storeInd = newNode->AsStoreInd();
        storeInd->gtType          = simdType;
        storeInd->gtFlags |= ((simdSrc->gtFlags & GTF_ALL_EFFECT) | GTF_ASG);
        storeInd->gtOp1 = simdDst;
        storeInd->gtOp2 = simdSrc;

        BlockRange().InsertBefore(cpBlk, storeInd);
    }

    use.ReplaceWith(comp, newNode);
    BlockRange().Remove(cpBlk);

    JITDUMP("After rewriting SIMD CopyBlk:\n");
    DISPTREERANGE(BlockRange(), use.Def());
    JITDUMP("\n");
#endif // FEATURE_SIMD
}
Exemplo n.º 6
0
// Rewrite InitBlk involving SIMD vector into stlcl.var of a SIMD type.
//
// Arguments:
//    ppTree      - A pointer-to-a-pointer for the GT_INITBLK
//    fgWalkData  - A pointer to tree walk data providing the context
//
// Return Value:
//    None.
//
// TODO-Cleanup: Once SIMD types are plumbed through the frontend, this will no longer
// be required.
//
void Rationalizer::RewriteInitBlk(LIR::Use& use)
{
#ifdef FEATURE_SIMD
    // No lowering is needed for non-SIMD nodes, so early out if featureSIMD is not enabled.
    if (!comp->featureSIMD)
    {
        return;
    }

    // See if this is a SIMD initBlk that needs to be changed to a simple st.lclVar.
    GenTreeInitBlk* initBlk = use.Def()->AsInitBlk();

    // Is the dstAddr is addr of a SIMD type lclVar?
    GenTree* dstAddr = initBlk->Dest();
    if (!comp->isAddrOfSIMDType(dstAddr) || !dstAddr->OperIsLocalAddr())
    {
        return;
    }

    unsigned lclNum = dstAddr->AsLclVarCommon()->gtLclNum;
    if (!comp->lvaTable[lclNum].lvSIMDType)
    {
        return;
    }

    var_types            baseType      = comp->lvaTable[lclNum].lvBaseType;
    CORINFO_CLASS_HANDLE typeHnd       = comp->lvaTable[lclNum].lvVerTypeInfo.GetClassHandle();
    unsigned             simdLocalSize = comp->getSIMDTypeSizeInBytes(typeHnd);

    JITDUMP("Rewriting SIMD InitBlk\n");
    DISPTREERANGE(BlockRange(), initBlk);

    assert((dstAddr->gtFlags & GTF_VAR_USEASG) == 0);

    // There are currently only three sizes supported: 8 bytes, 16 bytes or the vector register length.
    GenTreeIntConCommon* sizeNode = initBlk->Size()->AsIntConCommon();
    unsigned int         size     = (unsigned int)roundUp(sizeNode->IconValue(), TARGET_POINTER_SIZE);
    var_types            simdType = comp->getSIMDTypeForSize(size);
    assert(roundUp(simdLocalSize, TARGET_POINTER_SIZE) == size);

    GenTree*     initVal  = initBlk->InitVal();
    GenTreeSIMD* simdNode = new (comp, GT_SIMD)
        GenTreeSIMD(simdType, initVal, SIMDIntrinsicInit, baseType, (unsigned)sizeNode->IconValue());

    dstAddr->SetOper(GT_STORE_LCL_VAR);
    GenTreeLclVar* store = dstAddr->AsLclVar();
    store->gtType        = simdType;
    store->gtOp.gtOp1    = simdNode;
    store->gtFlags |= ((simdNode->gtFlags & GTF_ALL_EFFECT) | GTF_ASG);
    BlockRange().Remove(store);

    // Insert the new nodes into the block
    BlockRange().InsertAfter(initVal, simdNode, store);
    use.ReplaceWith(comp, store);

    // Remove the old size and GT_INITBLK nodes.
    BlockRange().Remove(sizeNode);
    BlockRange().Remove(initBlk);

    JITDUMP("After rewriting SIMD InitBlk:\n");
    DISPTREERANGE(BlockRange(), use.Def());
    JITDUMP("\n");
#endif // FEATURE_SIMD
}