Exemplo n.º 1
0
// sanity checks that apply to all kinds of IR
void Rationalizer::SanityCheck()
{
    // TODO: assert(!IsLIR());
    BasicBlock* block;
    foreach_block(comp, block)
    {
        for (GenTree* statement = block->bbTreeList; statement != nullptr; statement = statement->gtNext)
        {
            ValidateStatement(statement, block);

            for (GenTree* tree = statement->gtStmt.gtStmtList; tree; tree = tree->gtNext)
            {
                // QMARK nodes should have been removed before this phase.
                assert(tree->OperGet() != GT_QMARK);

                if (tree->OperGet() == GT_ASG)
                {
                    if (tree->gtGetOp1()->OperGet() == GT_LCL_VAR)
                    {
                        assert(tree->gtGetOp1()->gtFlags & GTF_VAR_DEF);
                    }
                    else if (tree->gtGetOp2()->OperGet() == GT_LCL_VAR)
                    {
                        assert(!(tree->gtGetOp2()->gtFlags & GTF_VAR_DEF));
                    }
                }
            }
        }
    }
}
Exemplo n.º 2
0
//------------------------------------------------------------------------
// DecomposeMul: Decompose GT_MUL. The only GT_MULs that make it to decompose are
// those with the GTF_MUL_64RSLT flag set. These muls result in a mul instruction that
// returns its result in two registers like GT_CALLs do. Additionally, these muls are
// guaranteed to be in the form long = (long)int * (long)int. Therefore, to decompose
// these nodes, we convert them into GT_MUL_LONGs, undo the cast from int to long by
// stripping out the lo ops, and force them into the form var = mul, as we do for
// GT_CALLs. In codegen, we then produce a mul instruction that produces the result
// in edx:eax, and store those registers on the stack in genStoreLongLclVar.
//
// All other GT_MULs have been converted to helper calls in morph.cpp
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeMul(LIR::Use& use)
{
    assert(use.IsInitialized());

    GenTree*   tree = use.Def();
    genTreeOps oper = tree->OperGet();

    assert(oper == GT_MUL);
    assert((tree->gtFlags & GTF_MUL_64RSLT) != 0);

    GenTree* op1 = tree->gtGetOp1();
    GenTree* op2 = tree->gtGetOp2();

    GenTree* loOp1 = op1->gtGetOp1();
    GenTree* hiOp1 = op1->gtGetOp2();
    GenTree* loOp2 = op2->gtGetOp1();
    GenTree* hiOp2 = op2->gtGetOp2();

    Range().Remove(hiOp1);
    Range().Remove(hiOp2);
    Range().Remove(op1);
    Range().Remove(op2);

    // Get rid of the hi ops. We don't need them.
    tree->gtOp.gtOp1 = loOp1;
    tree->gtOp.gtOp2 = loOp2;
    tree->gtOper = GT_MUL_LONG;

    return StoreNodeToVar(use);
}
Exemplo n.º 3
0
//------------------------------------------------------------------------
// DecomposeNeg: Decompose GT_NEG.
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeNeg(LIR::Use& use)
{
    assert(use.IsInitialized());
    assert(use.Def()->OperGet() == GT_NEG);

    GenTree* tree   = use.Def();
    GenTree* gtLong = tree->gtGetOp1();
    noway_assert(gtLong->OperGet() == GT_LONG);

    LIR::Use op1(Range(), &gtLong->gtOp.gtOp1, gtLong);
    op1.ReplaceWithLclVar(m_compiler, m_blockWeight);

    LIR::Use op2(Range(), &gtLong->gtOp.gtOp2, gtLong);
    op2.ReplaceWithLclVar(m_compiler, m_blockWeight);

    // Neither GT_NEG nor the introduced temporaries have side effects.
    tree->gtFlags &= ~GTF_ALL_EFFECT;
    GenTree* loOp1 = gtLong->gtGetOp1();
    GenTree* hiOp1 = gtLong->gtGetOp2();

    Range().Remove(gtLong);

    GenTree* loResult    = tree;
    loResult->gtType     = TYP_INT;
    loResult->gtOp.gtOp1 = loOp1;

    GenTree* zero     = m_compiler->gtNewZeroConNode(TYP_INT);
    GenTree* hiAdjust = m_compiler->gtNewOperNode(GT_ADD_HI, TYP_INT, hiOp1, zero);
    GenTree* hiResult = m_compiler->gtNewOperNode(GT_NEG, TYP_INT, hiAdjust);
    hiResult->gtFlags = tree->gtFlags;

    Range().InsertAfter(loResult, zero, hiAdjust, hiResult);

    return FinalizeDecomposition(use, loResult, hiResult);
}
Exemplo n.º 4
0
//------------------------------------------------------------------------
// DecomposeArith: Decompose GT_ADD, GT_SUB, GT_OR, GT_XOR, GT_AND.
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeArith(LIR::Use& use)
{
    assert(use.IsInitialized());

    GenTree*   tree = use.Def();
    genTreeOps oper = tree->OperGet();

    assert((oper == GT_ADD) || (oper == GT_SUB) || (oper == GT_OR) || (oper == GT_XOR) || (oper == GT_AND));

    GenTree* op1 = tree->gtGetOp1();
    GenTree* op2 = tree->gtGetOp2();

    // Both operands must have already been decomposed into GT_LONG operators.
    noway_assert((op1->OperGet() == GT_LONG) && (op2->OperGet() == GT_LONG));

    // Capture the lo and hi halves of op1 and op2.
    GenTree* loOp1 = op1->gtGetOp1();
    GenTree* hiOp1 = op1->gtGetOp2();
    GenTree* loOp2 = op2->gtGetOp1();
    GenTree* hiOp2 = op2->gtGetOp2();

    // Now, remove op1 and op2 from the node list.
    Range().Remove(op1);
    Range().Remove(op2);

    // We will reuse "tree" for the loResult, which will now be of TYP_INT, and its operands
    // will be the lo halves of op1 from above.
    GenTree* loResult = tree;
    loResult->SetOper(GetLoOper(oper));
    loResult->gtType     = TYP_INT;
    loResult->gtOp.gtOp1 = loOp1;
    loResult->gtOp.gtOp2 = loOp2;

    GenTree* hiResult = new (m_compiler, oper) GenTreeOp(GetHiOper(oper), TYP_INT, hiOp1, hiOp2);
    Range().InsertAfter(loResult, hiResult);

    if ((oper == GT_ADD) || (oper == GT_SUB))
    {
        if (loResult->gtOverflow())
        {
            hiResult->gtFlags |= GTF_OVERFLOW;
            loResult->gtFlags &= ~GTF_OVERFLOW;
        }
        if (loResult->gtFlags & GTF_UNSIGNED)
        {
            hiResult->gtFlags |= GTF_UNSIGNED;
        }
    }

    return FinalizeDecomposition(use, loResult, hiResult);
}
Exemplo n.º 5
0
//------------------------------------------------------------------------
// DecomposeNot: Decompose GT_NOT.
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeNot(LIR::Use& use)
{
    assert(use.IsInitialized());
    assert(use.Def()->OperGet() == GT_NOT);

    GenTree* tree   = use.Def();
    GenTree* gtLong = tree->gtGetOp1();
    noway_assert(gtLong->OperGet() == GT_LONG);
    GenTree* loOp1 = gtLong->gtGetOp1();
    GenTree* hiOp1 = gtLong->gtGetOp2();

    Range().Remove(gtLong);

    GenTree* loResult    = tree;
    loResult->gtType     = TYP_INT;
    loResult->gtOp.gtOp1 = loOp1;

    GenTree* hiResult = new (m_compiler, GT_NOT) GenTreeOp(GT_NOT, TYP_INT, hiOp1, nullptr);
    Range().InsertAfter(loResult, hiResult);

    return FinalizeDecomposition(use, loResult, hiResult);
}
Exemplo n.º 6
0
//------------------------------------------------------------------------
// DecomposeStoreLclVar: Decompose GT_STORE_LCL_VAR.
//
// Arguments:
//    ppTree - the tree to decompose
//    data - tree walk context
//
// Return Value:
//    None.
//
void DecomposeLongs::DecomposeStoreLclVar(GenTree** ppTree, Compiler::fgWalkData* data)
{
    assert(ppTree != nullptr);
    assert(*ppTree != nullptr);
    assert(data != nullptr);
    assert((*ppTree)->OperGet() == GT_STORE_LCL_VAR);
    assert(m_compiler->compCurStmt != nullptr);

    GenTreeStmt* curStmt = m_compiler->compCurStmt->AsStmt();

    GenTree* tree = *ppTree;
    GenTree* nextTree = tree->gtNext;
    GenTree* rhs = tree->gtGetOp1();
    if ((rhs->OperGet() == GT_PHI) || (rhs->OperGet() == GT_CALL))
    {
        // GT_CALLs are not decomposed, so will not be converted to GT_LONG
        // GT_STORE_LCL_VAR = GT_CALL are handled in genMultiRegCallStoreToLocal
        return;
    }

    noway_assert(rhs->OperGet() == GT_LONG);
    unsigned varNum = tree->AsLclVarCommon()->gtLclNum;
    LclVarDsc* varDsc = m_compiler->lvaTable + varNum;
    m_compiler->lvaDecRefCnts(tree);

    GenTree* loRhs = rhs->gtGetOp1();
    GenTree* hiRhs = rhs->gtGetOp2();
    GenTree* hiStore = m_compiler->gtNewLclLNode(varNum, TYP_INT);

    if (varDsc->lvPromoted)
    {
        assert(varDsc->lvFieldCnt == 2);

        unsigned loVarNum = varDsc->lvFieldLclStart;
        unsigned hiVarNum = loVarNum + 1;
        tree->AsLclVarCommon()->SetLclNum(loVarNum);
        hiStore->SetOper(GT_STORE_LCL_VAR);
        hiStore->AsLclVarCommon()->SetLclNum(hiVarNum);
    }
    else
    {
        noway_assert(varDsc->lvLRACandidate == false);

        tree->SetOper(GT_STORE_LCL_FLD);
        tree->AsLclFld()->gtLclOffs = 0;
        tree->AsLclFld()->gtFieldSeq = FieldSeqStore::NotAField();

        hiStore->SetOper(GT_STORE_LCL_FLD);
        hiStore->AsLclFld()->gtLclOffs = 4;
        hiStore->AsLclFld()->gtFieldSeq = FieldSeqStore::NotAField();
    }

    tree->gtOp.gtOp1 = loRhs;
    tree->gtType = TYP_INT;

    loRhs->gtNext = tree;
    tree->gtPrev = loRhs;

    hiStore->gtOp.gtOp1 = hiRhs;
    hiStore->CopyCosts(tree);
    hiStore->gtFlags |= GTF_VAR_DEF;

    m_compiler->lvaIncRefCnts(tree);
    m_compiler->lvaIncRefCnts(hiStore);

    tree->gtNext = hiRhs;
    hiRhs->gtPrev = tree;
    hiRhs->gtNext = hiStore;
    hiStore->gtPrev = hiRhs;
    hiStore->gtNext = nextTree;
    if (nextTree != nullptr)
    {
        nextTree->gtPrev = hiStore;
    }
    nextTree = hiRhs;

    bool isEmbeddedStmt = !curStmt->gtStmtIsTopLevel();
    if (!isEmbeddedStmt)
    {
        tree->gtNext = nullptr;
        hiRhs->gtPrev = nullptr;
    }

    InsertNodeAsStmt(hiStore);
}
Exemplo n.º 7
0
//------------------------------------------------------------------------
// DecomposeArith: Decompose GT_ADD, GT_SUB, GT_OR, GT_XOR, GT_AND.
//
// Arguments:
//    ppTree - the tree to decompose
//    data - tree walk context
//
// Return Value:
//    None.
//
void DecomposeLongs::DecomposeArith(GenTree** ppTree, Compiler::fgWalkData* data)
{
    assert(ppTree != nullptr);
    assert(*ppTree != nullptr);
    assert(data != nullptr);
    assert(m_compiler->compCurStmt != nullptr);

    GenTreeStmt* curStmt = m_compiler->compCurStmt->AsStmt();
    GenTree* tree = *ppTree;
    genTreeOps oper = tree->OperGet();

    assert((oper == GT_ADD) ||
           (oper == GT_SUB) ||
           (oper == GT_OR)  ||
           (oper == GT_XOR) ||
           (oper == GT_AND));

    NYI_IF((tree->gtFlags & GTF_REVERSE_OPS) != 0, "Binary operator with GTF_REVERSE_OPS");

    GenTree* op1 = tree->gtGetOp1();
    GenTree* op2 = tree->gtGetOp2();

    // Both operands must have already been decomposed into GT_LONG operators.
    noway_assert((op1->OperGet() == GT_LONG) && (op2->OperGet() == GT_LONG));

    // Capture the lo and hi halves of op1 and op2.
    GenTree* loOp1 = op1->gtGetOp1();
    GenTree* hiOp1 = op1->gtGetOp2();
    GenTree* loOp2 = op2->gtGetOp1();
    GenTree* hiOp2 = op2->gtGetOp2();

    // We don't have support to decompose a TYP_LONG node that already has a child that has
    // been decomposed into parts, where the high part depends on the value generated by the
    // low part (via the flags register). For example, if we have:
    //    +(gt_long(+(lo3, lo4), +Hi(hi3, hi4)), gt_long(lo2, hi2))
    // We would decompose it here to:
    //    gt_long(+(+(lo3, lo4), lo2), +Hi(+Hi(hi3, hi4), hi2))
    // But this would generate incorrect code, because the "+Hi(hi3, hi4)" code generation
    // needs to immediately follow the "+(lo3, lo4)" part. Also, if this node is one that
    // requires a unique high operator, and the child nodes are not simple locals (e.g.,
    // they are decomposed nodes), then we also can't decompose the node, as we aren't
    // guaranteed the high and low parts will be executed immediately after each other.
    
    NYI_IF(hiOp1->OperIsHigh() ||
           hiOp2->OperIsHigh() ||
           (GenTree::OperIsHigh(GetHiOper(oper)) &&
            (!loOp1->OperIsLeaf() ||
             !hiOp1->OperIsLeaf() ||
             !loOp1->OperIsLeaf() ||
             !hiOp2->OperIsLeaf())),
            "Can't decompose expression tree TYP_LONG node");

    // Now, remove op1 and op2 from the node list.
    m_compiler->fgSnipNode(curStmt, op1);
    m_compiler->fgSnipNode(curStmt, op2);

    // We will reuse "tree" for the loResult, which will now be of TYP_INT, and its operands
    // will be the lo halves of op1 from above.
    GenTree* loResult = tree;
    loResult->SetOper(GetLoOper(loResult->OperGet()));
    loResult->gtType = TYP_INT;
    loResult->gtOp.gtOp1 = loOp1;
    loResult->gtOp.gtOp2 = loOp2;

    // The various halves will be correctly threaded internally. We simply need to
    // relink them into the proper order, i.e. loOp1 is followed by loOp2, and then
    // the loResult node.
    // (This rethreading, and that below, are where we need to address the reverse ops case).
    // The current order is (after snipping op1 and op2):
    // ... loOp1-> ... hiOp1->loOp2First ... loOp2->hiOp2First ... hiOp2
    // The order we want is:
    // ... loOp1->loOp2First ... loOp2->loResult
    // ... hiOp1->hiOp2First ... hiOp2->hiResult
    // i.e. we swap hiOp1 and loOp2, and create (for now) separate loResult and hiResult trees
    GenTree* loOp2First = hiOp1->gtNext;
    GenTree* hiOp2First = loOp2->gtNext;

    // First, we will NYI if both hiOp1 and loOp2 have side effects.
    NYI_IF(((loOp2->gtFlags & GTF_ALL_EFFECT) != 0) && ((hiOp1->gtFlags & GTF_ALL_EFFECT) != 0),
           "Binary long operator with non-reorderable sub expressions");

    // Now, we reorder the loOps and the loResult.
    loOp1->gtNext      = loOp2First;
    loOp2First->gtPrev = loOp1;
    loOp2->gtNext      = loResult;
    loResult->gtPrev   = loOp2;

    // Next, reorder the hiOps and the hiResult.
    GenTree* hiResult = new (m_compiler, oper) GenTreeOp(GetHiOper(oper), TYP_INT, hiOp1, hiOp2);
    hiOp1->gtNext      = hiOp2First;
    hiOp2First->gtPrev = hiOp1;
    hiOp2->gtNext      = hiResult;
    hiResult->gtPrev   = hiOp2;

    if ((oper == GT_ADD) || (oper == GT_SUB))
    {
        if (loResult->gtOverflow())
        {
            hiResult->gtFlags |= GTF_OVERFLOW;
            loResult->gtFlags &= ~GTF_OVERFLOW;
        }
        if (loResult->gtFlags & GTF_UNSIGNED)
        {
            hiResult->gtFlags |= GTF_UNSIGNED;
        }
    }

    FinalizeDecomposition(ppTree, data, loResult, hiResult);
}
Exemplo n.º 8
0
Compiler::fgWalkResult Rationalizer::RewriteNode(GenTree** useEdge, ArrayStack<GenTree*>& parentStack)
{
    assert(useEdge != nullptr);

    GenTree* node = *useEdge;
    assert(node != nullptr);

#ifdef DEBUG
    const bool isLateArg = (node->gtFlags & GTF_LATE_ARG) != 0;
#endif

    // First, remove any preceeding list nodes, which are not otherwise visited by the tree walk.
    //
    // NOTE: GT_FIELD_LIST head nodes, and GT_LIST nodes used by phi nodes will in fact be visited.
    for (GenTree* prev = node->gtPrev; prev != nullptr && prev->OperIsAnyList() && !(prev->OperIsFieldListHead());
         prev          = node->gtPrev)
    {
        BlockRange().Remove(prev);
    }

    // In addition, remove the current node if it is a GT_LIST node that is not an aggregate.
    if (node->OperIsAnyList())
    {
        GenTreeArgList* list = node->AsArgList();
        if (!list->OperIsFieldListHead())
        {
            BlockRange().Remove(list);
        }
        return Compiler::WALK_CONTINUE;
    }

    LIR::Use use;
    if (parentStack.Height() < 2)
    {
        use = LIR::Use::GetDummyUse(BlockRange(), *useEdge);
    }
    else
    {
        use = LIR::Use(BlockRange(), useEdge, parentStack.Index(1));
    }

    assert(node == use.Def());
    switch (node->OperGet())
    {
        case GT_ASG:
            RewriteAssignment(use);
            break;

        case GT_BOX:
            // GT_BOX at this level just passes through so get rid of it
            use.ReplaceWith(comp, node->gtGetOp1());
            BlockRange().Remove(node);
            break;

        case GT_ADDR:
            RewriteAddress(use);
            break;

        case GT_IND:
            // Clear the `GTF_IND_ASG_LHS` flag, which overlaps with `GTF_IND_REQ_ADDR_IN_REG`.
            node->gtFlags &= ~GTF_IND_ASG_LHS;

            if (varTypeIsSIMD(node))
            {
                RewriteSIMDOperand(use, false);
            }
            else
            {
                // Due to promotion of structs containing fields of type struct with a
                // single scalar type field, we could potentially see IR nodes of the
                // form GT_IND(GT_ADD(lclvarAddr, 0)) where 0 is an offset representing
                // a field-seq. These get folded here.
                //
                // TODO: This code can be removed once JIT implements recursive struct
                // promotion instead of lying about the type of struct field as the type
                // of its single scalar field.
                GenTree* addr = node->AsIndir()->Addr();
                if (addr->OperGet() == GT_ADD && addr->gtGetOp1()->OperGet() == GT_LCL_VAR_ADDR &&
                    addr->gtGetOp2()->IsIntegralConst(0))
                {
                    GenTreeLclVarCommon* lclVarNode = addr->gtGetOp1()->AsLclVarCommon();
                    unsigned             lclNum     = lclVarNode->GetLclNum();
                    LclVarDsc*           varDsc     = comp->lvaTable + lclNum;
                    if (node->TypeGet() == varDsc->TypeGet())
                    {
                        JITDUMP("Rewriting GT_IND(GT_ADD(LCL_VAR_ADDR,0)) to LCL_VAR\n");
                        lclVarNode->SetOper(GT_LCL_VAR);
                        lclVarNode->gtType = node->TypeGet();
                        use.ReplaceWith(comp, lclVarNode);
                        BlockRange().Remove(addr);
                        BlockRange().Remove(addr->gtGetOp2());
                        BlockRange().Remove(node);
                    }
                }
            }
            break;

        case GT_NOP:
            // fgMorph sometimes inserts NOP nodes between defs and uses
            // supposedly 'to prevent constant folding'. In this case, remove the
            // NOP.
            if (node->gtGetOp1() != nullptr)
            {
                use.ReplaceWith(comp, node->gtGetOp1());
                BlockRange().Remove(node);
            }
            break;

        case GT_COMMA:
        {
            GenTree* op1 = node->gtGetOp1();
            if ((op1->gtFlags & GTF_ALL_EFFECT) == 0)
            {
                // The LHS has no side effects. Remove it.
                bool               isClosed    = false;
                unsigned           sideEffects = 0;
                LIR::ReadOnlyRange lhsRange    = BlockRange().GetTreeRange(op1, &isClosed, &sideEffects);

                // None of the transforms performed herein violate tree order, so these
                // should always be true.
                assert(isClosed);
                assert((sideEffects & GTF_ALL_EFFECT) == 0);

                BlockRange().Delete(comp, m_block, std::move(lhsRange));
            }

            GenTree* replacement = node->gtGetOp2();
            if (!use.IsDummyUse())
            {
                use.ReplaceWith(comp, replacement);
            }
            else
            {
                // This is a top-level comma. If the RHS has no side effects we can remove
                // it as well.
                if ((replacement->gtFlags & GTF_ALL_EFFECT) == 0)
                {
                    bool               isClosed    = false;
                    unsigned           sideEffects = 0;
                    LIR::ReadOnlyRange rhsRange    = BlockRange().GetTreeRange(replacement, &isClosed, &sideEffects);

                    // None of the transforms performed herein violate tree order, so these
                    // should always be true.
                    assert(isClosed);
                    assert((sideEffects & GTF_ALL_EFFECT) == 0);

                    BlockRange().Delete(comp, m_block, std::move(rhsRange));
                }
            }

            BlockRange().Remove(node);
        }
        break;

        case GT_ARGPLACE:
            // Remove argplace and list nodes from the execution order.
            //
            // TODO: remove phi args and phi nodes as well?
            BlockRange().Remove(node);
            break;

#if defined(_TARGET_XARCH_) || defined(_TARGET_ARM_)
        case GT_CLS_VAR:
        {
            // Class vars that are the target of an assignment will get rewritten into
            // GT_STOREIND(GT_CLS_VAR_ADDR, val) by RewriteAssignment. This check is
            // not strictly necessary--the GT_IND(GT_CLS_VAR_ADDR) pattern that would
            // otherwise be generated would also be picked up by RewriteAssignment--but
            // skipping the rewrite here saves an allocation and a bit of extra work.
            const bool isLHSOfAssignment = (use.User()->OperGet() == GT_ASG) && (use.User()->gtGetOp1() == node);
            if (!isLHSOfAssignment)
            {
                GenTree* ind = comp->gtNewOperNode(GT_IND, node->TypeGet(), node);

                node->SetOper(GT_CLS_VAR_ADDR);
                node->gtType = TYP_BYREF;

                BlockRange().InsertAfter(node, ind);
                use.ReplaceWith(comp, ind);

                // TODO: JIT dump
            }
        }
        break;
#endif // _TARGET_XARCH_

        case GT_INTRINSIC:
            // Non-target intrinsics should have already been rewritten back into user calls.
            assert(Compiler::IsTargetIntrinsic(node->gtIntrinsic.gtIntrinsicId));
            break;

#ifdef FEATURE_SIMD
        case GT_BLK:
        case GT_OBJ:
        {
            // TODO-1stClassStructs: These should have been transformed to GT_INDs, but in order
            // to preserve existing behavior, we will keep this as a block node if this is the
            // lhs of a block assignment, and either:
            // - It is a "generic" TYP_STRUCT assignment, OR
            // - It is an initblk, OR
            // - Neither the lhs or rhs are known to be of SIMD type.

            GenTree* parent  = use.User();
            bool     keepBlk = false;
            if ((parent->OperGet() == GT_ASG) && (node == parent->gtGetOp1()))
            {
                if ((node->TypeGet() == TYP_STRUCT) || parent->OperIsInitBlkOp())
                {
                    keepBlk = true;
                }
                else if (!comp->isAddrOfSIMDType(node->AsBlk()->Addr()))
                {
                    GenTree* dataSrc = parent->gtGetOp2();
                    if (!dataSrc->IsLocal() && (dataSrc->OperGet() != GT_SIMD))
                    {
                        noway_assert(dataSrc->OperIsIndir());
                        keepBlk = !comp->isAddrOfSIMDType(dataSrc->AsIndir()->Addr());
                    }
                }
            }
            RewriteSIMDOperand(use, keepBlk);
        }
        break;

        case GT_LCL_FLD:
        case GT_STORE_LCL_FLD:
            // TODO-1stClassStructs: Eliminate this.
            FixupIfSIMDLocal(node->AsLclVarCommon());
            break;

        case GT_SIMD:
        {
            noway_assert(comp->featureSIMD);
            GenTreeSIMD* simdNode = node->AsSIMD();
            unsigned     simdSize = simdNode->gtSIMDSize;
            var_types    simdType = comp->getSIMDTypeForSize(simdSize);

            // TODO-1stClassStructs: This should be handled more generally for enregistered or promoted
            // structs that are passed or returned in a different register type than their enregistered
            // type(s).
            if (simdNode->gtType == TYP_I_IMPL && simdNode->gtSIMDSize == TARGET_POINTER_SIZE)
            {
                // This happens when it is consumed by a GT_RET_EXPR.
                // It can only be a Vector2f or Vector2i.
                assert(genTypeSize(simdNode->gtSIMDBaseType) == 4);
                simdNode->gtType = TYP_SIMD8;
            }
            // Certain SIMD trees require rationalizing.
            if (simdNode->gtSIMD.gtSIMDIntrinsicID == SIMDIntrinsicInitArray)
            {
                // Rewrite this as an explicit load.
                JITDUMP("Rewriting GT_SIMD array init as an explicit load:\n");
                unsigned int baseTypeSize = genTypeSize(simdNode->gtSIMDBaseType);
                GenTree*     address = new (comp, GT_LEA) GenTreeAddrMode(TYP_BYREF, simdNode->gtOp1, simdNode->gtOp2,
                                                                      baseTypeSize, offsetof(CORINFO_Array, u1Elems));
                GenTree* ind = comp->gtNewOperNode(GT_IND, simdType, address);

                BlockRange().InsertBefore(simdNode, address, ind);
                use.ReplaceWith(comp, ind);
                BlockRange().Remove(simdNode);

                DISPTREERANGE(BlockRange(), use.Def());
                JITDUMP("\n");
            }
            else
            {
                // This code depends on the fact that NONE of the SIMD intrinsics take vector operands
                // of a different width.  If that assumption changes, we will EITHER have to make these type
                // transformations during importation, and plumb the types all the way through the JIT,
                // OR add a lot of special handling here.
                GenTree* op1 = simdNode->gtGetOp1();
                if (op1 != nullptr && op1->gtType == TYP_STRUCT)
                {
                    op1->gtType = simdType;
                }

                GenTree* op2 = simdNode->gtGetOp2IfPresent();
                if (op2 != nullptr && op2->gtType == TYP_STRUCT)
                {
                    op2->gtType = simdType;
                }
            }
        }
        break;
#endif // FEATURE_SIMD

        default:
            // JCC nodes should not be present in HIR.
            assert(node->OperGet() != GT_JCC);
            break;
    }

    // Do some extra processing on top-level nodes to remove unused local reads.
    if (node->OperIsLocalRead())
    {
        if (use.IsDummyUse())
        {
            comp->lvaDecRefCnts(node);
            BlockRange().Remove(node);
        }
        else
        {
            // Local reads are side-effect-free; clear any flags leftover from frontend transformations.
            node->gtFlags &= ~GTF_ALL_EFFECT;
        }
    }

    assert(isLateArg == ((use.Def()->gtFlags & GTF_LATE_ARG) != 0));

    return Compiler::WALK_CONTINUE;
}
Exemplo n.º 9
0
//------------------------------------------------------------------------
// DecomposeShift: Decompose GT_LSH, GT_RSH, GT_RSZ. For shift nodes, we need to use
// the shift helper functions, so we here convert the shift into a helper call by
// pulling its arguments out of linear order and making them the args to a call, then
// replacing the original node with the new call.
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeShift(LIR::Use& use)
{
    assert(use.IsInitialized());

    GenTree* tree   = use.Def();
    GenTree* gtLong = tree->gtGetOp1();
    genTreeOps oper = tree->OperGet();

    assert((oper == GT_LSH) || (oper == GT_RSH) || (oper == GT_RSZ));

    LIR::Use loOp1Use(Range(), &gtLong->gtOp.gtOp1, gtLong);
    loOp1Use.ReplaceWithLclVar(m_compiler, m_blockWeight);

    LIR::Use hiOp1Use(Range(), &gtLong->gtOp.gtOp2, gtLong);
    hiOp1Use.ReplaceWithLclVar(m_compiler, m_blockWeight);

    LIR::Use shiftWidthUse(Range(), &tree->gtOp.gtOp2, tree);
    shiftWidthUse.ReplaceWithLclVar(m_compiler, m_blockWeight);

    GenTree* loOp1 = gtLong->gtGetOp1();
    GenTree* hiOp1 = gtLong->gtGetOp2();

    GenTree* shiftWidthOp = tree->gtGetOp2();

    Range().Remove(gtLong);
    Range().Remove(loOp1);
    Range().Remove(hiOp1);

    Range().Remove(shiftWidthOp);

    // TODO-X86-CQ: If the shift operand is a GT_CNS_INT, we should pipe the instructions through to codegen
    // and generate the shift instructions ourselves there, rather than replacing it with a helper call.

    unsigned helper;

    switch (oper)
    {
    case GT_LSH:
        helper = CORINFO_HELP_LLSH;
        break;
    case GT_RSH:
        helper = CORINFO_HELP_LRSH;
        break;
    case GT_RSZ:
        helper = CORINFO_HELP_LRSZ;
        break;
    default:
        unreached();
    }

    GenTreeArgList* argList = m_compiler->gtNewArgList(loOp1, hiOp1, shiftWidthOp);

    GenTree* call = m_compiler->gtNewHelperCallNode(helper, TYP_LONG, 0, argList);

    GenTreeCall*    callNode    = call->AsCall();
    ReturnTypeDesc* retTypeDesc = callNode->GetReturnTypeDesc();
    retTypeDesc->InitializeLongReturnType(m_compiler);

    call = m_compiler->fgMorphArgs(callNode);
    Range().InsertAfter(tree, LIR::SeqTree(m_compiler, call));

    Range().Remove(tree);
    use.ReplaceWith(m_compiler, call);
    return call;
}
Exemplo n.º 10
0
//------------------------------------------------------------------------
// DecomposeCast: Decompose GT_CAST.
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeCast(LIR::Use& use)
{
    assert(use.IsInitialized());
    assert(use.Def()->OperGet() == GT_CAST);

    GenTree* cast     = use.Def()->AsCast();
    GenTree* loResult = nullptr;
    GenTree* hiResult = nullptr;

    var_types srcType = cast->CastFromType();
    var_types dstType = cast->CastToType();

    if ((cast->gtFlags & GTF_UNSIGNED) != 0)
    {
        srcType = genUnsignedType(srcType);
    }

    if (varTypeIsLong(srcType))
    {
        if (cast->gtOverflow() && (varTypeIsUnsigned(srcType) != varTypeIsUnsigned(dstType)))
        {
            GenTree* srcOp = cast->gtGetOp1();
            noway_assert(srcOp->OperGet() == GT_LONG);
            GenTree* loSrcOp = srcOp->gtGetOp1();
            GenTree* hiSrcOp = srcOp->gtGetOp2();

            //
            // When casting between long types an overflow check is needed only if the types
            // have different signedness. In both cases (long->ulong and ulong->long) we only
            // need to check if the high part is negative or not. Use the existing cast node
            // to perform a int->uint cast of the high part to take advantage of the overflow
            // check provided by codegen.
            //

            loResult = loSrcOp;

            hiResult                       = cast;
            hiResult->gtType               = TYP_INT;
            hiResult->AsCast()->gtCastType = TYP_UINT;
            hiResult->gtFlags &= ~GTF_UNSIGNED;
            hiResult->gtOp.gtOp1 = hiSrcOp;

            Range().Remove(cast);
            Range().Remove(srcOp);
            Range().InsertAfter(hiSrcOp, hiResult);
        }
        else
        {
            NYI("Unimplemented long->long no-op cast decomposition");
        }
    }
    else if (varTypeIsIntegralOrI(srcType))
    {
        if (cast->gtOverflow() && !varTypeIsUnsigned(srcType) && varTypeIsUnsigned(dstType))
        {
            //
            // An overflow check is needed only when casting from a signed type to ulong.
            // Change the cast type to uint to take advantage of the overflow check provided
            // by codegen and then zero extend the resulting uint to ulong.
            //

            loResult                       = cast;
            loResult->AsCast()->gtCastType = TYP_UINT;
            loResult->gtType               = TYP_INT;

            hiResult = m_compiler->gtNewZeroConNode(TYP_INT);

            Range().InsertAfter(loResult, hiResult);
        }
        else
        {
            if (varTypeIsUnsigned(srcType))
            {
                loResult = cast->gtGetOp1();
                hiResult = m_compiler->gtNewZeroConNode(TYP_INT);

                Range().Remove(cast);
                Range().InsertAfter(loResult, hiResult);
            }
            else
            {
                LIR::Use src(Range(), &(cast->gtOp.gtOp1), cast);
                unsigned lclNum = src.ReplaceWithLclVar(m_compiler, m_blockWeight);

                loResult = src.Def();

                GenTree* loCopy  = m_compiler->gtNewLclvNode(lclNum, TYP_INT);
                GenTree* shiftBy = m_compiler->gtNewIconNode(31, TYP_INT);
                hiResult         = m_compiler->gtNewOperNode(GT_RSH, TYP_INT, loCopy, shiftBy);

                Range().Remove(cast);
                Range().InsertAfter(loResult, loCopy, shiftBy, hiResult);
                m_compiler->lvaIncRefCnts(loCopy);
            }
        }
    }
    else
    {
        NYI("Unimplemented cast decomposition");
    }

    return FinalizeDecomposition(use, loResult, hiResult);
}
Exemplo n.º 11
0
//------------------------------------------------------------------------
// DecomposeStoreLclVar: Decompose GT_STORE_LCL_VAR.
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeStoreLclVar(LIR::Use& use)
{
    assert(use.IsInitialized());
    assert(use.Def()->OperGet() == GT_STORE_LCL_VAR);

    GenTree* tree = use.Def();
    GenTree* rhs  = tree->gtGetOp1();
    if ((rhs->OperGet() == GT_PHI) || (rhs->OperGet() == GT_CALL) ||
            ((rhs->OperGet() == GT_MUL_LONG) && (rhs->gtFlags & GTF_MUL_64RSLT) != 0))
    {
        // GT_CALLs are not decomposed, so will not be converted to GT_LONG
        // GT_STORE_LCL_VAR = GT_CALL are handled in genMultiRegCallStoreToLocal
        // GT_MULs are not decomposed, so will not be converted to GT_LONG
        return tree->gtNext;
    }

    noway_assert(rhs->OperGet() == GT_LONG);
    unsigned   varNum = tree->AsLclVarCommon()->gtLclNum;
    LclVarDsc* varDsc = m_compiler->lvaTable + varNum;
    m_compiler->lvaDecRefCnts(tree);

    GenTree* loRhs   = rhs->gtGetOp1();
    GenTree* hiRhs   = rhs->gtGetOp2();
    GenTree* hiStore = m_compiler->gtNewLclLNode(varNum, TYP_INT);

    if (varDsc->lvPromoted)
    {
        assert(varDsc->lvFieldCnt == 2);

        unsigned loVarNum = varDsc->lvFieldLclStart;
        unsigned hiVarNum = loVarNum + 1;
        tree->AsLclVarCommon()->SetLclNum(loVarNum);
        hiStore->SetOper(GT_STORE_LCL_VAR);
        hiStore->AsLclVarCommon()->SetLclNum(hiVarNum);
    }
    else
    {
        noway_assert(varDsc->lvLRACandidate == false);

        tree->SetOper(GT_STORE_LCL_FLD);
        tree->AsLclFld()->gtLclOffs  = 0;
        tree->AsLclFld()->gtFieldSeq = FieldSeqStore::NotAField();

        hiStore->SetOper(GT_STORE_LCL_FLD);
        hiStore->AsLclFld()->gtLclOffs  = 4;
        hiStore->AsLclFld()->gtFieldSeq = FieldSeqStore::NotAField();
    }

    // 'tree' is going to steal the loRhs node for itself, so we need to remove the
    // GT_LONG node from the threading.
    Range().Remove(rhs);

    tree->gtOp.gtOp1 = loRhs;
    tree->gtType     = TYP_INT;

    hiStore->gtOp.gtOp1 = hiRhs;
    hiStore->gtFlags |= GTF_VAR_DEF;

    m_compiler->lvaIncRefCnts(tree);
    m_compiler->lvaIncRefCnts(hiStore);

    Range().InsertAfter(tree, hiStore);

    return hiStore->gtNext;
}
Exemplo n.º 12
0
Compiler::fgWalkResult Rationalizer::RewriteNode(GenTree** useEdge, ArrayStack<GenTree*>& parentStack)
{
    assert(useEdge != nullptr);

    GenTree* node = *useEdge;
    assert(node != nullptr);

#ifdef DEBUG
    const bool isLateArg = (node->gtFlags & GTF_LATE_ARG) != 0;
#endif

    // First, remove any preceeding GT_LIST nodes, which are not otherwise visited by the tree walk.
    //
    // NOTE: GT_LIST nodes that are used by block ops and phi nodes will in fact be visited.
    for (GenTree* prev = node->gtPrev; prev != nullptr && prev->OperGet() == GT_LIST; prev = node->gtPrev)
    {
        BlockRange().Remove(prev);
    }

    // In addition, remove the current node if it is a GT_LIST node.
    if ((*useEdge)->OperGet() == GT_LIST)
    {
        BlockRange().Remove(*useEdge);
        return Compiler::WALK_CONTINUE;
    }

    LIR::Use use;
    if (parentStack.Height() < 2)
    {
        use = LIR::Use::GetDummyUse(BlockRange(), *useEdge);
    }
    else
    {
        use = LIR::Use(BlockRange(), useEdge, parentStack.Index(1));
    }

    assert(node == use.Def());
    switch (node->OperGet())
    {
        case GT_ASG:
            RewriteAssignment(use);
            break;

        case GT_BOX:
            // GT_BOX at this level just passes through so get rid of it
            use.ReplaceWith(comp, node->gtGetOp1());
            BlockRange().Remove(node);
            break;

        case GT_ADDR:
            RewriteAddress(use);
            break;

        case GT_NOP:
            // fgMorph sometimes inserts NOP nodes between defs and uses
            // supposedly 'to prevent constant folding'. In this case, remove the
            // NOP.
            if (node->gtGetOp1() != nullptr)
            {
                use.ReplaceWith(comp, node->gtGetOp1());
                BlockRange().Remove(node);
            }
            break;

        case GT_COMMA:
        {
            GenTree* op1 = node->gtGetOp1();
            if ((op1->gtFlags & GTF_ALL_EFFECT) == 0)
            {
                // The LHS has no side effects. Remove it.
                bool               isClosed    = false;
                unsigned           sideEffects = 0;
                LIR::ReadOnlyRange lhsRange    = BlockRange().GetTreeRange(op1, &isClosed, &sideEffects);

                // None of the transforms performed herein violate tree order, so these
                // should always be true.
                assert(isClosed);
                assert((sideEffects & GTF_ALL_EFFECT) == 0);

                BlockRange().Delete(comp, m_block, std::move(lhsRange));
            }

            GenTree* replacement = node->gtGetOp2();
            if (!use.IsDummyUse())
            {
                use.ReplaceWith(comp, replacement);
            }
            else
            {
                // This is a top-level comma. If the RHS has no side effects we can remove
                // it as well.
                if ((replacement->gtFlags & GTF_ALL_EFFECT) == 0)
                {
                    bool               isClosed    = false;
                    unsigned           sideEffects = 0;
                    LIR::ReadOnlyRange rhsRange    = BlockRange().GetTreeRange(replacement, &isClosed, &sideEffects);

                    // None of the transforms performed herein violate tree order, so these
                    // should always be true.
                    assert(isClosed);
                    assert((sideEffects & GTF_ALL_EFFECT) == 0);

                    BlockRange().Delete(comp, m_block, std::move(rhsRange));
                }
            }

            BlockRange().Remove(node);
        }
        break;

        case GT_ARGPLACE:
            // Remove argplace and list nodes from the execution order.
            //
            // TODO: remove phi args and phi nodes as well?
            BlockRange().Remove(node);
            break;

#ifdef _TARGET_XARCH_
        case GT_CLS_VAR:
        {
            // Class vars that are the target of an assignment will get rewritten into
            // GT_STOREIND(GT_CLS_VAR_ADDR, val) by RewriteAssignment. This check is
            // not strictly necessary--the GT_IND(GT_CLS_VAR_ADDR) pattern that would
            // otherwise be generated would also be picked up by RewriteAssignment--but
            // skipping the rewrite here saves an allocation and a bit of extra work.
            const bool isLHSOfAssignment = (use.User()->OperGet() == GT_ASG) && (use.User()->gtGetOp1() == node);
            if (!isLHSOfAssignment)
            {
                GenTree* ind = comp->gtNewOperNode(GT_IND, node->TypeGet(), node);

                node->SetOper(GT_CLS_VAR_ADDR);
                node->gtType = TYP_BYREF;

                BlockRange().InsertAfter(node, ind);
                use.ReplaceWith(comp, ind);

                // TODO: JIT dump
            }
        }
        break;
#endif // _TARGET_XARCH_

        case GT_INTRINSIC:
            // Non-target intrinsics should have already been rewritten back into user calls.
            assert(Compiler::IsTargetIntrinsic(node->gtIntrinsic.gtIntrinsicId));
            break;

#ifdef FEATURE_SIMD
        case GT_INITBLK:
            RewriteInitBlk(use);
            break;

        case GT_COPYBLK:
            RewriteCopyBlk(use);
            break;

        case GT_OBJ:
            RewriteObj(use);
            break;

        case GT_LCL_FLD:
        case GT_STORE_LCL_FLD:
            // TODO-1stClassStructs: Eliminate this.
            FixupIfSIMDLocal(node->AsLclVarCommon());
            break;

        case GT_STOREIND:
        case GT_IND:
            if (node->gtType == TYP_STRUCT)
            {
                GenTree* addr = node->AsIndir()->Addr();
                assert(addr->TypeGet() == TYP_BYREF);

                if (addr->OperIsLocal())
                {
                    LclVarDsc* varDsc = &(comp->lvaTable[addr->AsLclVarCommon()->gtLclNum]);
                    assert(varDsc->lvSIMDType);
                    unsigned simdSize = (unsigned int)roundUp(varDsc->lvExactSize, TARGET_POINTER_SIZE);
                    node->gtType      = comp->getSIMDTypeForSize(simdSize);
                }
#if DEBUG
                else
                {
                    // If the address is not a local var, assert that the user of this IND is an ADDR node.
                    assert((use.User()->OperGet() == GT_ADDR) || use.User()->OperIsLocalAddr());
                }
#endif
            }
            break;

        case GT_SIMD:
        {
            noway_assert(comp->featureSIMD);
            GenTreeSIMD* simdNode = node->AsSIMD();
            unsigned     simdSize = simdNode->gtSIMDSize;
            var_types    simdType = comp->getSIMDTypeForSize(simdSize);

            // TODO-1stClassStructs: This should be handled more generally for enregistered or promoted
            // structs that are passed or returned in a different register type than their enregistered
            // type(s).
            if (simdNode->gtType == TYP_I_IMPL && simdNode->gtSIMDSize == TARGET_POINTER_SIZE)
            {
                // This happens when it is consumed by a GT_RET_EXPR.
                // It can only be a Vector2f or Vector2i.
                assert(genTypeSize(simdNode->gtSIMDBaseType) == 4);
                simdNode->gtType = TYP_SIMD8;
            }
            else if (simdNode->gtType == TYP_STRUCT || varTypeIsSIMD(simdNode))
            {
                node->gtType = simdType;
            }

            // Certain SIMD trees require rationalizing.
            if (simdNode->gtSIMD.gtSIMDIntrinsicID == SIMDIntrinsicInitArray)
            {
                // Rewrite this as an explicit load.
                JITDUMP("Rewriting GT_SIMD array init as an explicit load:\n");
                unsigned int baseTypeSize = genTypeSize(simdNode->gtSIMDBaseType);
                GenTree*     address = new (comp, GT_LEA) GenTreeAddrMode(TYP_BYREF, simdNode->gtOp1, simdNode->gtOp2,
                                                                      baseTypeSize, offsetof(CORINFO_Array, u1Elems));
                GenTree* ind = comp->gtNewOperNode(GT_IND, simdType, address);

                BlockRange().InsertBefore(simdNode, address, ind);
                use.ReplaceWith(comp, ind);
                BlockRange().Remove(simdNode);

                DISPTREERANGE(BlockRange(), use.Def());
                JITDUMP("\n");
            }
            else
            {
                // This code depends on the fact that NONE of the SIMD intrinsics take vector operands
                // of a different width.  If that assumption changes, we will EITHER have to make these type
                // transformations during importation, and plumb the types all the way through the JIT,
                // OR add a lot of special handling here.
                GenTree* op1 = simdNode->gtGetOp1();
                if (op1 != nullptr && op1->gtType == TYP_STRUCT)
                {
                    op1->gtType = simdType;
                }

                GenTree* op2 = simdNode->gtGetOp2();
                if (op2 != nullptr && op2->gtType == TYP_STRUCT)
                {
                    op2->gtType = simdType;
                }
            }
        }
        break;
#endif // FEATURE_SIMD

        default:
            break;
    }

    // Do some extra processing on top-level nodes to remove unused local reads.
    if (use.IsDummyUse() && node->OperIsLocalRead())
    {
        assert((node->gtFlags & GTF_ALL_EFFECT) == 0);

        comp->lvaDecRefCnts(node);
        BlockRange().Remove(node);
    }

    assert(isLateArg == ((node->gtFlags & GTF_LATE_ARG) != 0));

    return Compiler::WALK_CONTINUE;
}
Exemplo n.º 13
0
//------------------------------------------------------------------------
// MorphAllocObjNodes: Morph each GT_ALLOCOBJ node either into an
//                     allocation helper call or stack allocation.
//
// Notes:
//    Runs only over the blocks having bbFlags BBF_HAS_NEWOBJ set.
void ObjectAllocator::MorphAllocObjNodes()
{
    BasicBlock* block;

    foreach_block(comp, block)
    {
        const bool basicBlockHasNewObj = (block->bbFlags & BBF_HAS_NEWOBJ) == BBF_HAS_NEWOBJ;
#ifndef DEBUG
        if (!basicBlockHasNewObj)
        {
            continue;
        }
#endif // DEBUG

        for (GenTreeStmt* stmt = block->firstStmt(); stmt; stmt = stmt->gtNextStmt)
        {
            GenTree* stmtExpr = stmt->gtStmtExpr;
            GenTree* op2      = nullptr;

            bool canonicalAllocObjFound = false;

            if (stmtExpr->OperGet() == GT_ASG && stmtExpr->TypeGet() == TYP_REF)
            {
                op2 = stmtExpr->gtGetOp2();

                if (op2->OperGet() == GT_ALLOCOBJ)
                {
                    canonicalAllocObjFound = true;
                }
            }

            if (canonicalAllocObjFound)
            {
                assert(basicBlockHasNewObj);
                //------------------------------------------------------------------------
                // We expect the following expression tree at this point
                //  *  GT_STMT   void  (top level)
                // 	|  /--*  GT_ALLOCOBJ   ref
                // 	\--*  GT_ASG    ref
                // 	   \--*  GT_LCL_VAR    ref
                //------------------------------------------------------------------------

                GenTree* op1 = stmtExpr->gtGetOp1();

                assert(op1->OperGet() == GT_LCL_VAR);
                assert(op1->TypeGet() == TYP_REF);
                assert(op2 != nullptr);
                assert(op2->OperGet() == GT_ALLOCOBJ);

                GenTreeAllocObj* asAllocObj = op2->AsAllocObj();
                unsigned int     lclNum     = op1->AsLclVar()->GetLclNum();

                if (IsObjectStackAllocationEnabled() && CanAllocateLclVarOnStack(lclNum))
                {
                    op2 = MorphAllocObjNodeIntoStackAlloc(asAllocObj, block, stmt);
                }
                else
                {
                    op2 = MorphAllocObjNodeIntoHelperCall(asAllocObj);
                }

                // Propagate flags of op2 to its parent.
                stmtExpr->gtOp.gtOp2 = op2;
                stmtExpr->gtFlags |= op2->gtFlags & GTF_ALL_EFFECT;
            }
#ifdef DEBUG
            else
            {
                // We assume that GT_ALLOCOBJ nodes are always present in the
                // canonical form.
                comp->fgWalkTreePre(&stmt->gtStmtExpr, AssertWhenAllocObjFoundVisitor);
            }
#endif // DEBUG
        }
    }
}
Exemplo n.º 14
0
//------------------------------------------------------------------------
// BuildSIMD: Set the NodeInfo for a GT_SIMD tree.
//
// Arguments:
//    tree       - The GT_SIMD node of interest
//
// Return Value:
//    The number of sources consumed by this node.
//
int LinearScan::BuildSIMD(GenTreeSIMD* simdTree)
{
    int srcCount = 0;
    // Only SIMDIntrinsicInit can be contained
    if (simdTree->isContained())
    {
        assert(simdTree->gtSIMDIntrinsicID == SIMDIntrinsicInit);
    }
    int dstCount = simdTree->IsValue() ? 1 : 0;
    assert(dstCount == 1);

    bool buildUses = true;

    GenTree* op1 = simdTree->gtGetOp1();
    GenTree* op2 = simdTree->gtGetOp2();

    switch (simdTree->gtSIMDIntrinsicID)
    {
        case SIMDIntrinsicInit:
        case SIMDIntrinsicCast:
        case SIMDIntrinsicSqrt:
        case SIMDIntrinsicAbs:
        case SIMDIntrinsicConvertToSingle:
        case SIMDIntrinsicConvertToInt32:
        case SIMDIntrinsicConvertToDouble:
        case SIMDIntrinsicConvertToInt64:
        case SIMDIntrinsicWidenLo:
        case SIMDIntrinsicWidenHi:
            // No special handling required.
            break;

        case SIMDIntrinsicGetItem:
        {
            op1 = simdTree->gtGetOp1();
            op2 = simdTree->gtGetOp2();

            // We have an object and an index, either of which may be contained.
            bool setOp2DelayFree = false;
            if (!op2->IsCnsIntOrI() && (!op1->isContained() || op1->OperIsLocal()))
            {
                // If the index is not a constant and the object is not contained or is a local
                // we will need a general purpose register to calculate the address
                // internal register must not clobber input index
                // TODO-Cleanup: An internal register will never clobber a source; this code actually
                // ensures that the index (op2) doesn't interfere with the target.
                buildInternalIntRegisterDefForNode(simdTree);
                setOp2DelayFree = true;
            }
            srcCount += BuildOperandUses(op1);
            if (!op2->isContained())
            {
                RefPosition* op2Use = BuildUse(op2);
                if (setOp2DelayFree)
                {
                    setDelayFree(op2Use);
                }
                srcCount++;
            }

            if (!op2->IsCnsIntOrI() && (!op1->isContained()))
            {
                // If vector is not already in memory (contained) and the index is not a constant,
                // we will use the SIMD temp location to store the vector.
                compiler->getSIMDInitTempVarNum();
            }
            buildUses = false;
        }
        break;

        case SIMDIntrinsicAdd:
        case SIMDIntrinsicSub:
        case SIMDIntrinsicMul:
        case SIMDIntrinsicDiv:
        case SIMDIntrinsicBitwiseAnd:
        case SIMDIntrinsicBitwiseAndNot:
        case SIMDIntrinsicBitwiseOr:
        case SIMDIntrinsicBitwiseXor:
        case SIMDIntrinsicMin:
        case SIMDIntrinsicMax:
        case SIMDIntrinsicEqual:
        case SIMDIntrinsicLessThan:
        case SIMDIntrinsicGreaterThan:
        case SIMDIntrinsicLessThanOrEqual:
        case SIMDIntrinsicGreaterThanOrEqual:
            // No special handling required.
            break;

        case SIMDIntrinsicSetX:
        case SIMDIntrinsicSetY:
        case SIMDIntrinsicSetZ:
        case SIMDIntrinsicSetW:
        case SIMDIntrinsicNarrow:
        {
            // Op1 will write to dst before Op2 is free
            BuildUse(op1);
            RefPosition* op2Use = BuildUse(op2);
            setDelayFree(op2Use);
            srcCount  = 2;
            buildUses = false;
            break;
        }

        case SIMDIntrinsicInitN:
        {
            var_types baseType = simdTree->gtSIMDBaseType;
            srcCount           = (short)(simdTree->gtSIMDSize / genTypeSize(baseType));
            if (varTypeIsFloating(simdTree->gtSIMDBaseType))
            {
                // Need an internal register to stitch together all the values into a single vector in a SIMD reg.
                buildInternalFloatRegisterDefForNode(simdTree);
            }

            int initCount = 0;
            for (GenTree* list = op1; list != nullptr; list = list->gtGetOp2())
            {
                assert(list->OperGet() == GT_LIST);
                GenTree* listItem = list->gtGetOp1();
                assert(listItem->TypeGet() == baseType);
                assert(!listItem->isContained());
                BuildUse(listItem);
                initCount++;
            }
            assert(initCount == srcCount);
            buildUses = false;

            break;
        }

        case SIMDIntrinsicInitArray:
            // We have an array and an index, which may be contained.
            break;

        case SIMDIntrinsicOpEquality:
        case SIMDIntrinsicOpInEquality:
            buildInternalFloatRegisterDefForNode(simdTree);
            break;

        case SIMDIntrinsicDotProduct:
            buildInternalFloatRegisterDefForNode(simdTree);
            break;

        case SIMDIntrinsicSelect:
            // TODO-ARM64-CQ Allow lowering to see SIMDIntrinsicSelect so we can generate BSL VC, VA, VB
            // bsl target register must be VC.  Reserve a temp in case we need to shuffle things.
            // This will require a different approach, as GenTreeSIMD has only two operands.
            assert(!"SIMDIntrinsicSelect not yet supported");
            buildInternalFloatRegisterDefForNode(simdTree);
            break;

        case SIMDIntrinsicInitArrayX:
        case SIMDIntrinsicInitFixed:
        case SIMDIntrinsicCopyToArray:
        case SIMDIntrinsicCopyToArrayX:
        case SIMDIntrinsicNone:
        case SIMDIntrinsicGetCount:
        case SIMDIntrinsicGetOne:
        case SIMDIntrinsicGetZero:
        case SIMDIntrinsicGetAllOnes:
        case SIMDIntrinsicGetX:
        case SIMDIntrinsicGetY:
        case SIMDIntrinsicGetZ:
        case SIMDIntrinsicGetW:
        case SIMDIntrinsicInstEquals:
        case SIMDIntrinsicHWAccel:
        case SIMDIntrinsicWiden:
        case SIMDIntrinsicInvalid:
            assert(!"These intrinsics should not be seen during register allocation");
            __fallthrough;

        default:
            noway_assert(!"Unimplemented SIMD node type.");
            unreached();
    }
    if (buildUses)
    {
        assert(!op1->OperIs(GT_LIST));
        assert(srcCount == 0);
        srcCount = BuildOperandUses(op1);
        if ((op2 != nullptr) && !op2->isContained())
        {
            srcCount += BuildOperandUses(op2);
        }
    }
    assert(internalCount <= MaxInternalCount);
    buildInternalRegisterUses();
    if (dstCount == 1)
    {
        BuildDef(simdTree);
    }
    else
    {
        assert(dstCount == 0);
    }
    return srcCount;
}
Exemplo n.º 15
0
//------------------------------------------------------------------------
// DecomposeArith: Decompose GT_ADD, GT_SUB, GT_OR, GT_XOR, GT_AND.
//
// Arguments:
//    use - the LIR::Use object for the def that needs to be decomposed.
//
// Return Value:
//    The next node to process.
//
GenTree* DecomposeLongs::DecomposeArith(LIR::Use& use)
{
    assert(use.IsInitialized());

    GenTree*   tree = use.Def();
    genTreeOps oper = tree->OperGet();

    assert((oper == GT_ADD) || (oper == GT_SUB) || (oper == GT_OR) || (oper == GT_XOR) || (oper == GT_AND));

    GenTree* op1 = tree->gtGetOp1();
    GenTree* op2 = tree->gtGetOp2();

    // Both operands must have already been decomposed into GT_LONG operators.
    noway_assert((op1->OperGet() == GT_LONG) && (op2->OperGet() == GT_LONG));

    // Capture the lo and hi halves of op1 and op2.
    GenTree* loOp1 = op1->gtGetOp1();
    GenTree* hiOp1 = op1->gtGetOp2();
    GenTree* loOp2 = op2->gtGetOp1();
    GenTree* hiOp2 = op2->gtGetOp2();

    // We don't have support to decompose a TYP_LONG node that already has a child that has
    // been decomposed into parts, where the high part depends on the value generated by the
    // low part (via the flags register). For example, if we have:
    //    +(gt_long(+(lo3, lo4), +Hi(hi3, hi4)), gt_long(lo2, hi2))
    // We would decompose it here to:
    //    gt_long(+(+(lo3, lo4), lo2), +Hi(+Hi(hi3, hi4), hi2))
    // But this would generate incorrect code, because the "+Hi(hi3, hi4)" code generation
    // needs to immediately follow the "+(lo3, lo4)" part. Also, if this node is one that
    // requires a unique high operator, and the child nodes are not simple locals (e.g.,
    // they are decomposed nodes), then we also can't decompose the node, as we aren't
    // guaranteed the high and low parts will be executed immediately after each other.

    NYI_IF(hiOp1->OperIsHigh() || hiOp2->OperIsHigh() ||
               (GenTree::OperIsHigh(GetHiOper(oper)) &&
                (!loOp1->OperIsLeaf() || !hiOp1->OperIsLeaf() || !loOp1->OperIsLeaf() || !hiOp2->OperIsLeaf())),
           "Can't decompose expression tree TYP_LONG node");

    // Now, remove op1 and op2 from the node list.
    BlockRange().Remove(op1);
    BlockRange().Remove(op2);

    // We will reuse "tree" for the loResult, which will now be of TYP_INT, and its operands
    // will be the lo halves of op1 from above.
    GenTree* loResult = tree;
    loResult->SetOper(GetLoOper(loResult->OperGet()));
    loResult->gtType     = TYP_INT;
    loResult->gtOp.gtOp1 = loOp1;
    loResult->gtOp.gtOp2 = loOp2;

    GenTree* hiResult = new (m_compiler, oper) GenTreeOp(GetHiOper(oper), TYP_INT, hiOp1, hiOp2);
    hiResult->CopyCosts(loResult);
    BlockRange().InsertAfter(loResult, hiResult);

    if ((oper == GT_ADD) || (oper == GT_SUB))
    {
        if (loResult->gtOverflow())
        {
            hiResult->gtFlags |= GTF_OVERFLOW;
            loResult->gtFlags &= ~GTF_OVERFLOW;
        }
        if (loResult->gtFlags & GTF_UNSIGNED)
        {
            hiResult->gtFlags |= GTF_UNSIGNED;
        }
    }

    return FinalizeDecomposition(use, loResult, hiResult);
}