source: Sophya/trunk/Poubelle/DPC:FitsIOServer/Blitz/blitz/array/eval.cc@ 3201

/*
 * $Id: eval.cc,v 1.1.1.1 1999-11-26 16:37:06 ansari Exp $
 *
 * $Log: not supported by cvs2svn $
// Revision 1.1.1.1  1999/04/09  17:59:03  ansari
// Creation module DPC/Blitz (blitz 0.4) Reza 09/04/99
//
 * Revision 1.2  1998/03/14 00:04:47  tveldhui
 * 0.2-alpha-05
 *
 * Revision 1.1  1998/02/25 20:04:01  tveldhui
 * Initial revision
 *
 */

#ifndef BZ_ARRAYEVAL_CC
#define BZ_ARRAYEVAL_CC

#ifndef BZ_ARRAY_H
 #error <blitz/array/eval.cc> must be included via <blitz/array.h>
#endif

BZ_NAMESPACE(blitz)

/*
 * Assign an expression to an array.  For performance reasons, there are
 * several traversal mechanisms:
 *
 * - Index traversal scans through the destination array in storage order.
 *   The expression is evaluated using a TinyVector<int,N> operand.  This
 *   version is used only when there are index placeholders in the expression
 *   (see <blitz/indexexpr.h>)
 * - Stack traversal also scans through the destination array in storage
 *   order.  However, push/pop stack iterators are used.
 * - Fast traversal follows a Hilbert (or other) space-filling curve to
 *   improve cache reuse for stencilling operations.  Currently, the
 *   space filling curves must be generated by calling 
 *   generateFastTraversalOrder(TinyVector<int,N_dimensions>).
 * - 2D tiled traversal follows a tiled traversal, to improve cache reuse
 *   for 2D stencils.  Space filling curves have too much overhead to use
 *   in two-dimensions.
 *
 * _bz_tryFastTraversal is a helper class.  Fast traversals are only
 * attempted if the expression looks like a stencil -- it's at least
 * three-dimensional, has at least six array operands, and there are
 * no index placeholders in the expression.  These are all things which
 * can be checked at compile time, so the if()/else() syntax has been
 * replaced with this class template.
 */

// Fast traversals require <set> from the ISO/ANSI C++ standard library
#ifdef BZ_HAVE_STD

template<_bz_bool canTryFastTraversal>
struct _bz_tryFastTraversal {
    template<class T_numtype, int N_rank, class T_expr, class T_update>
    static _bz_bool tryFast(Array<T_numtype,N_rank>& array, 
        _bz_ArrayExpr<T_expr> expr, T_update)
    {
        return _bz_false;
    }
};

template<>
struct _bz_tryFastTraversal<_bz_true> {
    template<class T_numtype, int N_rank, class T_expr, class T_update>
    static _bz_bool tryFast(Array<T_numtype,N_rank>& array, 
        _bz_ArrayExpr<T_expr> expr, T_update)
    {
        // See if there's an appropriate space filling curve available.
        // Currently fast traversals use an N-1 dimensional curve.  The
        // Nth dimension column corresponding to each point on the curve
        // is traversed in the normal fashion.
        TraversalOrderCollection<N_rank-1> traversals;
        TinyVector<int, N_rank - 1> traversalGridSize;

        for (int i=0; i < N_rank - 1; ++i)
            traversalGridSize[i] = array.length(array.ordering(i+1));

#ifdef BZ_DEBUG_TRAVERSE
cout << "traversalGridSize = " << traversalGridSize << endl;
cout.flush();
#endif

        const TraversalOrder<N_rank-1>* order =
            traversals.find(traversalGridSize);

        if (order)
        {
#ifdef BZ_DEBUG_TRAVERSE
    cerr << "Array<" << BZ_DEBUG_TEMPLATE_AS_STRING_LITERAL(T_numtype)
         << ", " << N_rank << ">: Using stack traversal" << endl;
#endif
            // A curve was available -- use fast traversal.
            array.evaluateWithFastTraversal(*order, expr, T_update());
            return _bz_true;
        }

        return _bz_false;
    }
};

#endif // BZ_HAVE_STD

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>& 
Array<T_numtype, N_rank>::evaluate(_bz_ArrayExpr<T_expr> expr, T_update)
{
    // Check that all arrays have the same shape
#ifdef BZ_DEBUG
    if (!expr.shapeCheck(shape()))
    {
      if (assertFailMode == _bz_false)
      {
        cerr << "[Blitz++] Shape check failed: Module " << __FILE__
             << " line " << __LINE__ << endl
             << "          Expression: ";
        prettyPrintFormat format(_bz_true);   // Use terse formatting
        string str;
        expr.prettyPrint(str, format);
        cerr << str << endl ;
      }

#if 0
// Shape dumping is broken by change to using string for prettyPrint
             << "          Shapes: " << shape() << " = ";
        prettyPrintFormat format2;
        format2.setDumpArrayShapesMode();
        expr.prettyPrint(cerr, format2);
        cerr << endl;
#endif
        BZ_PRE_FAIL;
    }
#endif

    BZPRECHECK(expr.shapeCheck(shape()),
        "Shape check failed." << endl << "Expression:");

    BZPRECHECK((T_expr::rank == N_rank) || (T_expr::numArrayOperands == 0), 
        "Assigned rank " << T_expr::rank << " expression to rank " 
        << N_rank << " array.");

#ifdef BZ_DEBUG_TRAVERSE
cout << "T_expr::numIndexPlaceholders = " << T_expr::numIndexPlaceholders
     << endl; cout.flush();
#endif

    // Tau profiling code.  Provide Tau with a pretty-printed version of
    // the expression.
    // NEEDS_WORK-- use a static initializer somehow.

#ifdef BZ_TAU_PROFILING
    static string exprDescription;
    if (!exprDescription.length())   // faked static initializer
    {
        exprDescription = "A";
        prettyPrintFormat format(_bz_true);   // Terse mode on
        format.nextArrayOperandSymbol();
        T_update::prettyPrint(exprDescription);
        expr.prettyPrint(exprDescription, format);
    }
    TAU_PROFILE(" ", exprDescription, TAU_BLITZ);
#endif

    // Determine which evaluation mechanism to use 
    if (T_expr::numIndexPlaceholders > 0)
    {
        // The expression involves index placeholders, so have to
        // use index traversal rather than stack traversal.

        if (N_rank == 1)
            return evaluateWithIndexTraversal1(expr, T_update());
        else
            return evaluateWithIndexTraversalN(expr, T_update());
    }
    else {

        // If this expression looks like an array stencil, then attempt to
        // use a fast traversal order.
        // Fast traversals require <set> from the ISO/ANSI C++ standard
        // library.

#ifdef BZ_HAVE_STD

        enum { isStencil = (N_rank >= 3) && (T_expr::numArrayOperands > 6)
            && (T_expr::numIndexPlaceholders == 0) };

        if (_bz_tryFastTraversal<isStencil>::tryFast(*this, expr, T_update()))
            return *this;

#endif

#ifdef BZ_ARRAY_2D_STENCIL_TILING
        // Does this look like a 2-dimensional stencil on a largeish
        // array?

        if ((N_rank == 2) && (T_expr::numArrayOperands >= 5))
        {
            // Use a heuristic to determine whether a tiled traversal
            // is desirable.  First, estimate how much L1 cache is needed 
            // to achieve a high hit rate using the stack traversal.
            // Try to err on the side of using tiled traversal even when
            // it isn't strictly needed.

            // Assumptions:
            //    Stencil width 3
            //    3 arrays involved in stencil
            //    Uniform data type in arrays (all T_numtype)
            
            int cacheNeeded = 3 * 3 * sizeof(T_numtype) * length(ordering(0));
            if (cacheNeeded > BZ_L1_CACHE_ESTIMATED_SIZE)
                return evaluateWithTiled2DTraversal(expr, T_update());
        }

#endif

        // If fast traversal isn't available or appropriate, then just
        // do a stack traversal.
        if (N_rank == 1)
            return evaluateWithStackTraversal1(expr, T_update());
        else
            return evaluateWithStackTraversalN(expr, T_update());
    }
}

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>&
Array<T_numtype, N_rank>::evaluateWithStackTraversal1(_bz_ArrayExpr<T_expr> 
    expr, T_update)
{
#ifdef BZ_DEBUG_TRAVERSE
    BZ_DEBUG_MESSAGE("Array<" << BZ_DEBUG_TEMPLATE_AS_STRING_LITERAL(T_numtype)
         << ", " << N_rank << ">: Using stack traversal");
#endif
    ArrayIterator<T_numtype, N_rank> iter(*this);
    iter.loadStride(firstRank);
    expr.loadStride(firstRank);

    _bz_bool useUnitStride = iter.isUnitStride(firstRank)
          && expr.isUnitStride(firstRank);

#ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
    int commonStride = expr.suggestStride(firstRank);
    if (iter.suggestStride(firstRank) > commonStride)
        commonStride = iter.suggestStride(firstRank);
    bool useCommonStride = iter.isStride(firstRank,commonStride)
        && expr.isStride(firstRank,commonStride);

 #ifdef BZ_DEBUG_TRAVERSE
    BZ_DEBUG_MESSAGE("BZ_ARRAY_EXPR_USE_COMMON_STRIDE:" << endl
        << "    commonStride = " << commonStride << " useCommonStride = "
        << useCommonStride);
 #endif
#else
    int commonStride = 1;
    bool useCommonStride = _bz_false;
#endif

    const T_numtype * last = iter.data() + length(firstRank) 
        * stride(firstRank);

    if (useUnitStride || useCommonStride)
    {
#ifdef BZ_USE_FAST_READ_ARRAY_EXPR

#ifdef BZ_DEBUG_TRAVERSE
    BZ_DEBUG_MESSAGE("BZ_USE_FAST_READ_ARRAY_EXPR with commonStride");
#endif
        int ubound = length(firstRank) * commonStride;
        T_numtype* _bz_restrict data = const_cast<T_numtype*>(iter.data());

        if (commonStride == 1)
        {
 #ifndef BZ_ARRAY_STACK_TRAVERSAL_UNROLL
            for (int i=0; i < ubound; ++i)
                T_update::update(data[i], expr.fastRead(i));
 #else
            int n1 = ubound & 3;
            int i = 0;
            for (; i < n1; ++i)
                T_update::update(data[i], expr.fastRead(i));
           
            for (; i < ubound; i += 4)
            {
#ifndef BZ_ARRAY_STACK_TRAVERSAL_CSE_AND_ANTIALIAS
                T_update::update(data[i], expr.fastRead(i));
                T_update::update(data[i+1], expr.fastRead(i+1));
                T_update::update(data[i+2], expr.fastRead(i+2));
                T_update::update(data[i+3], expr.fastRead(i+3));
#else
                int t1 = i+1;
                int t2 = i+2;
                int t3 = i+3;

                _bz_typename T_expr::T_numtype tmp1, tmp2, tmp3, tmp4;

                tmp1 = expr.fastRead(i);
                tmp2 = expr.fastRead(BZ_NO_PROPAGATE(t1));
                tmp3 = expr.fastRead(BZ_NO_PROPAGATE(t2));
                tmp4 = expr.fastRead(BZ_NO_PROPAGATE(t3));

                T_update::update(data[i], BZ_NO_PROPAGATE(tmp1));
                T_update::update(data[BZ_NO_PROPAGATE(t1)], tmp2);
                T_update::update(data[BZ_NO_PROPAGATE(t2)], tmp3);
                T_update::update(data[BZ_NO_PROPAGATE(t3)], tmp4);
#endif
            }
 #endif // BZ_ARRAY_STACK_TRAVERSAL_UNROLL

        }
 #ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
        else {

  #ifndef BZ_ARRAY_STACK_TRAVERSAL_UNROLL
            for (int i=0; i < ubound; i += commonStride)
                T_update::update(data[i], expr.fastRead(i));
  #else
            int n1 = (length(firstRank) & 3) * commonStride;

            int i = 0;
            for (; i < n1; i += commonStride)
                T_update::update(data[i], expr.fastRead(i));

            int strideInc = 4 * commonStride;
            for (; i < ubound; i += strideInc)
            {
                T_update::update(data[i], expr.fastRead(i));
                int i2 = i + commonStride;
                T_update::update(data[i2], expr.fastRead(i2));
                int i3 = i + 2 * commonStride;
                T_update::update(data[i3], expr.fastRead(i3));
                int i4 = i + 3 * commonStride;
                T_update::update(data[i4], expr.fastRead(i4));
            }
  #endif  // BZ_ARRAY_STACK_TRAVERSAL_UNROLL
        }
 #endif  // BZ_ARRAY_EXPR_USE_COMMON_STRIDE

#else   // ! BZ_USE_FAST_READ_ARRAY_EXPR

#ifdef BZ_DEBUG_TRAVERSE
    BZ_DEBUG_MESSAGE("Common stride, no fast read");
#endif
        while (iter.data() != last)
        {
            T_update::update(*const_cast<T_numtype*>(iter.data()), *expr);
            iter.advance(commonStride);
            expr.advance(commonStride);
        }
#endif
    }
    else {
        while (iter.data() != last)
        {
            T_update::update(*const_cast<T_numtype*>(iter.data()), *expr);
            iter.advance();
            expr.advance();
        }
    }

    return *this;
}

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>&
Array<T_numtype, N_rank>::evaluateWithStackTraversalN(_bz_ArrayExpr<T_expr>
    expr, T_update)
{
    /*
     * A stack traversal replaces the usual nested loops:
     *
     * for (int i=A.lbound(firstDim); i <= A.ubound(firstDim); ++i)
     *   for (int j=A.lbound(secondDim); j <= A.ubound(secondDim); ++j)
     *     for (int k=A.lbound(thirdDim); k <= A.ubound(thirdDim); ++k)
     *       A(i,j,k) = 0;
     *
     * with a stack data structure.  The stack allows this single
     * routine to replace any number of nested loops.
     *
     * For each dimension (loop), these quantities are needed:
     * - a pointer to the first element encountered in the loop
     * - the stride associated with the dimension/loop
     * - a pointer to the last element encountered in the loop
     *
     * The basic idea is that entering each loop is a "push" onto the
     * stack, and exiting each loop is a "pop".  In practice, this
     * routine treats accesses the stack in a random-access way,
     * which confuses the picture a bit.  But conceptually, that's
     * what is going on.
     */

    /*
     * ordering(0) gives the dimension associated with the smallest
     * stride (usually; the exceptions have to do with subarrays and
     * are uninteresting).  We call this dimension maxRank; it will
     * become the innermost "loop".
     *
     * Ordering the loops from ordering(N_rank-1) down to
     * ordering(0) ensures that the largest stride is associated
     * with the outermost loop, and the smallest stride with the
     * innermost.  This is critical for good performance on
     * cached machines.
     */
    const int maxRank = ordering(0);
    const int secondLastRank = ordering(1);

    // Create an iterator for the array receiving the result
    ArrayIterator<T_numtype, N_rank> iter(*this);

    // Set the initial stack configuration by pushing the pointer
    // to the first element of the array onto the stack N times.

    int i;
    for (i=1; i < N_rank; ++i)
    {
        iter.push(i);
        expr.push(i);
    }

    // Load the strides associated with the innermost loop.
    iter.loadStride(maxRank);
    expr.loadStride(maxRank);

    /* 
     * Is the stride in the innermost loop equal to 1?  If so,
     * we might take advantage of this and generate more
     * efficient code.
     */
    _bz_bool useUnitStride = iter.isUnitStride(maxRank)
                          && expr.isUnitStride(maxRank);

    /*
     * Do all array operands share a common stride in the innermost
     * loop?  If so, we can generate more efficient code (but only
     * if this optimization has been enabled).
     */
#ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
    int commonStride = expr.suggestStride(maxRank);
    if (iter.suggestStride(maxRank) > commonStride)
        commonStride = iter.suggestStride(maxRank);
    bool useCommonStride = iter.isStride(maxRank,commonStride)
        && expr.isStride(maxRank,commonStride);

#ifdef BZ_DEBUG_TRAVERSE
    BZ_DEBUG_MESSAGE("BZ_ARRAY_EXPR_USE_COMMON_STRIDE" << endl
        << "commonStride = " << commonStride << " useCommonStride = "
        << useCommonStride);
#endif

#else
    int commonStride = 1;
    bool useCommonStride = _bz_false;
#endif

    /*
     * The "last" array contains a pointer to the last element
     * encountered in each "loop".
     */
    const T_numtype* _bz_restrict last[N_rank];

    // Set up the initial state of the "last" array
    for (i=1; i < N_rank; ++i)
        last[i] = iter.data() + length(ordering(i)) * stride(ordering(i));

    int lastLength = length(maxRank);
    int firstNoncollapsedLoop = 1;

#ifdef BZ_COLLAPSE_LOOPS

    /*
     * This bit of code handles collapsing loops.  When possible,
     * the N nested loops are converted into a single loop (basically,
     * the N-dimensional array is treated as a long vector).
     * This is important for cases where the length of the innermost
     * loop is very small, for example a 100x100x3 array.
     * If this code can't collapse all the loops into a single loop,
     * it will collapse as many loops as possible starting from the
     * innermost and working out.
     */

    // Collapse loops when possible
    for (i=1; i < N_rank; ++i)
    {
        // Figure out which pair of loops we are considering combining.
        int outerLoopRank = ordering(i);
        int innerLoopRank = ordering(i-1);

        /*
         * The canCollapse() routines look at the strides and extents
         * of the loops, and determine if they can be combined into
         * one loop.
         */

        if (canCollapse(outerLoopRank,innerLoopRank) 
          && expr.canCollapse(outerLoopRank,innerLoopRank))
        {
            lastLength *= length(outerLoopRank);
            firstNoncollapsedLoop = i+1;
        }
    }
#endif // BZ_COLLAPSE_LOOPS

    /*
     * Now we actually perform the loops.  This while loop contains
     * two parts: first, the innermost loop is performed.  Then we
     * exit the loop, and pop our way down the stack until we find
     * a loop that isn't completed.  We then restart the inner loops
     * and push them onto the stack.
     */

    while (true) {

        /*
         * This bit of code handles the innermost loop.  It would look
         * a lot simpler if it weren't for unit stride and common stride
         * optimizations; these clutter up the code with multiple versions.
         */

        if ((useUnitStride) || (useCommonStride))
        {
            T_numtype * _bz_restrict end = const_cast<T_numtype*>(iter.data()) 
                + lastLength;

#ifdef BZ_USE_FAST_READ_ARRAY_EXPR

            /*
             * The check for BZ_USE_FAST_READ_ARRAY_EXPR can probably
             * be taken out.  This was put in place while the unit stride/
             * common stride optimizations were being implemented and
             * tested.
             */

            // Calculate the end of the innermost loop
            int ubound = lastLength * commonStride;

            /*
             * This is a real kludge.  I didn't want to have to write
             * a const and non-const version of ArrayIterator, so I use a
             * const iterator and cast away const.  This could
             * probably be avoided with some trick, but the whole routine
             * is ugly, so why bother.
             */

            T_numtype* _bz_restrict data = const_cast<T_numtype*>(iter.data());

            /*
             * BZ_NEEDS_WORK-- need to implement optional unrolling.
             */
            if (commonStride == 1)
            {
                for (int i=0; i < ubound; ++i)
                    T_update::update(data[i], expr.fastRead(i));
            }
#ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
            else {
                for (int i=0; i < ubound; i += commonStride)
                    T_update::update(data[i], expr.fastRead(i));
            }
#endif
            /*
             * Tidy up for the fact that we haven't actually been
             * incrementing the iterators in the innermost loop, by
             * faking it afterward.
             */
            iter.advance(lastLength * commonStride);
            expr.advance(lastLength * commonStride);
#else        
            // !BZ_USE_FAST_READ_ARRAY_EXPR
            // This bit of code not really needed; should remove at some
            // point, along with the test for BZ_USE_FAST_READ_ARRAY_EXPR 

            while (iter.data() != end) 
            {
                T_update::update(*const_cast<T_numtype*>(iter.data()), *expr);
                iter.advance(commonStride);
                expr.advance(commonStride);
            }
#endif
        }
        else {
            /*
             * We don't have a unit stride or common stride in the innermost
             * loop.  This is going to hurt performance.  Luckily 95% of
             * the time, we hit the cases above.
             */
            T_numtype * _bz_restrict end = const_cast<T_numtype*>(iter.data())
                + lastLength * stride(maxRank);

            while (iter.data() != end)
            {
                T_update::update(*const_cast<T_numtype*>(iter.data()), *expr);
                iter.advance();
                expr.advance();
            }
        }


        /*
         * We just finished the innermost loop.  Now we pop our way down
         * the stack, until we hit a loop that hasn't completed yet.
         */ 
        int j = firstNoncollapsedLoop;
        for (; j < N_rank; ++j)
        {
            // Get the next loop
            int r = ordering(j);

            // Pop-- this restores the data pointers to the first element
            // encountered in the loop.
            iter.pop(j);
            expr.pop(j);

            // Load the stride associated with this loop, and increment
            // once.
            iter.loadStride(r);
            expr.loadStride(r);
            iter.advance();
            expr.advance();

            // If we aren't at the end of this loop, then stop popping.
            if (iter.data() != last[j])
                break;
        }

        // Are we completely done?
        if (j == N_rank)
            break;

        // No, so push all the inner loops back onto the stack.
        for (; j >= firstNoncollapsedLoop; --j)
        {
            int r2 = ordering(j-1);
            iter.push(j);
            expr.push(j);
            last[j-1] = iter.data() + length(r2) * stride(r2);
        }

        // Load the stride for the innermost loop again.
        iter.loadStride(maxRank);
        expr.loadStride(maxRank);
    }

    return *this;
}

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>&
Array<T_numtype, N_rank>::evaluateWithIndexTraversal1(_bz_ArrayExpr<T_expr> 
    expr, T_update)
{
    TinyVector<int,N_rank> index;

    if (stride(firstRank) == 1)
    {
        T_numtype * _bz_restrict iter = data_;
        int last = ubound(firstRank);

        for (index[0] = lbound(firstRank); index[0] <= last;
            ++index[0])
        {
            iter[index[0]] = expr(index);
        }
    }
    else {
        ArrayIterator<T_numtype, N_rank> iter(*this);
        iter.loadStride(0);
        int last = ubound(firstRank);

        for (index[0] = lbound(firstRank); index[0] <= last;
            ++index[0])
        {
            T_update::update(*const_cast<T_numtype*>(iter.data()), 
                expr(index));
            iter.advance();
        }
    }

    return *this;
}

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>&
Array<T_numtype, N_rank>::evaluateWithIndexTraversalN(_bz_ArrayExpr<T_expr> 
    expr, T_update)
{
    // Do a stack-type traversal for the destination array and use
    // index traversal for the source expression
   
    const int maxRank = ordering(0);
    const int secondLastRank = ordering(1);

#ifdef BZ_DEBUG_TRAVERSE
cout << "Index traversal: N_rank = " << N_rank << endl;
cout << "maxRank = " << maxRank << " secondLastRank = " << secondLastRank
     << endl;
cout.flush();
#endif

    ArrayIterator<T_numtype, N_rank> iter(*this);
    for (int i=1; i < N_rank; ++i)
        iter.push(ordering(i));

    iter.loadStride(maxRank);

    TinyVector<int,N_rank> index, last;

    index = storage_.base();
    last = storage_.base() + length_;

    int lastLength = length(maxRank);

    while (true) {

        for (index[maxRank] = base(maxRank); 
             index[maxRank] < last[maxRank]; 
             ++index[maxRank])
        {
#ifdef BZ_DEBUG_TRAVERSE
#if 0
    cout << "(" << index[0] << "," << index[1] << ") " << endl;
    cout.flush();
#endif
#endif

            T_update::update(*const_cast<T_numtype*>(iter.data()), expr(index));
            iter.advance();
        }

        int j = 1;
        for (; j < N_rank; ++j)
        {
            iter.pop(ordering(j));
            iter.loadStride(ordering(j));
            iter.advance();

            index[ordering(j-1)] = base(ordering(j-1));
            ++index[ordering(j)];
            if (index[ordering(j)] != last[ordering(j)])
                break;
        }

        if (j == N_rank)
            break;

        for (; j > 0; --j)
        {
            iter.push(ordering(j));
        }
        iter.loadStride(maxRank);
    }

    return *this; 
}

// Fast traversals require <set> from the ISO/ANSI C++ standard library

#ifdef BZ_HAVE_STD

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>&
Array<T_numtype, N_rank>::evaluateWithFastTraversal(
    const TraversalOrder<N_rank - 1>& order, _bz_ArrayExpr<T_expr> expr,
    T_update)
{
    const int maxRank = ordering(0);
    const int secondLastRank = ordering(1);

#ifdef BZ_DEBUG_TRAVERSE
cerr << "maxRank = " << maxRank << " secondLastRank = " << secondLastRank
     << endl;
#endif

    ArrayIterator<T_numtype, N_rank> iter(*this);
    iter.push(0);
    expr.push(0);

    _bz_bool useUnitStride = iter.isUnitStride(maxRank) 
                          && expr.isUnitStride(maxRank);

#ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
    int commonStride = expr.suggestStride(maxRank);
    if (iter.suggestStride(maxRank) > commonStride)
        commonStride = iter.suggestStride(maxRank);
    bool useCommonStride = iter.isStride(maxRank,commonStride)
        && expr.isStride(maxRank,commonStride);
#else
    int commonStride = 1;
    bool useCommonStride = _bz_false;
#endif

    int lastLength = length(maxRank);

    for (int i=0; i < order.length(); ++i)
    {
        iter.pop(0);
        expr.pop(0);

#ifdef BZ_DEBUG_TRAVERSE
    cerr << "Traversing: " << order[i] << endl;
#endif
        // Position the iterator at the start of the next column       
        for (int j=1; j < N_rank; ++j)
        {
            iter.loadStride(ordering(j));
            expr.loadStride(ordering(j));

            int offset = order[i][j-1];
            iter.advance(offset);
            expr.advance(offset);
        }

        iter.loadStride(maxRank);
        expr.loadStride(maxRank);

        // Evaluate the expression along the column

        if ((useUnitStride) || (useCommonStride))
        {
            T_numtype* _bz_restrict last = const_cast<T_numtype*>(iter.data()) 
                + lastLength * commonStride;

#ifdef BZ_USE_FAST_READ_ARRAY_EXPR
            int ubound = lastLength * commonStride;
            T_numtype* _bz_restrict data = const_cast<T_numtype*>(iter.data());

            if (commonStride == 1)
            {            
 #ifndef BZ_ARRAY_FAST_TRAVERSAL_UNROLL
                for (int i=0; i < ubound; ++i)
                    T_update::update(data[i], expr.fastRead(i));
 #else
                int n1 = ubound & 3;
                int i=0;
                for (; i < n1; ++i)
                    T_update::update(data[i], expr.fastRead(i));

                for (; i < ubound; i += 4)
                {
                    T_update::update(data[i], expr.fastRead(i));
                    T_update::update(data[i+1], expr.fastRead(i+1));
                    T_update::update(data[i+2], expr.fastRead(i+2));
                    T_update::update(data[i+3], expr.fastRead(i+3));
                }
 #endif  // BZ_ARRAY_FAST_TRAVERSAL_UNROLL
            }
 #ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
            else {
                for (int i=0; i < ubound; i += commonStride)
                    T_update::update(data[i], expr.fastRead(i));
            }
 #endif // BZ_ARRAY_EXPR_USE_COMMON_STRIDE

            iter.advance(lastLength * commonStride);
            expr.advance(lastLength * commonStride);
#else   // ! BZ_USE_FAST_READ_ARRAY_EXPR
            while (iter.data() != last)
            {
                T_update::update(*const_cast<T_numtype*>(iter.data()), *expr);
                iter.advance(commonStride);
                expr.advance(commonStride);
            }
#endif  // BZ_USE_FAST_READ_ARRAY_EXPR

        }
        else {
            // No common stride

            T_numtype* _bz_restrict last = const_cast<T_numtype*>(iter.data()) 
                + lastLength * stride(maxRank);

            while (iter.data() != last)
            {
                T_update::update(*const_cast<T_numtype*>(iter.data()), *expr);
                iter.advance();
                expr.advance();
            }
        }
    }

    return *this;
}
#endif // BZ_HAVE_STD

#ifdef BZ_ARRAY_2D_NEW_STENCIL_TILING

#ifdef BZ_ARRAY_2D_STENCIL_TILING

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>& 
Array<T_numtype, N_rank>::evaluateWithTiled2DTraversal(_bz_ArrayExpr<T_expr> 
    expr, T_update)
{
    const int minorRank = ordering(0);
    const int majorRank = ordering(1);

    ArrayIterator<T_numtype, N_rank> iter(*this);
    iter.push(0);
    expr.push(0);

#ifdef BZ_2D_STENCIL_DEBUG
    int count = 0;
#endif

    _bz_bool useUnitStride = iter.isUnitStride(minorRank)
                          && expr.isUnitStride(minorRank);

#ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
    int commonStride = expr.suggestStride(minorRank);
    if (iter.suggestStride(minorRank) > commonStride)
        commonStride = iter.suggestStride(minorRank);
    bool useCommonStride = iter.isStride(minorRank,commonStride)
        && expr.isStride(minorRank,commonStride);
#else
    int commonStride = 1;
    bool useCommonStride = _bz_false;
#endif

    // Determine if a common major stride exists
    int commonMajorStride = expr.suggestStride(majorRank);
    if (iter.suggestStride(majorRank) > commonMajorStride)
        commonMajorStride = iter.suggestStride(majorRank);
    bool haveCommonMajorStride = iter.isStride(majorRank,commonMajorStride)
        && expr.isStride(majorRank,commonMajorStride);


    int maxi = length(majorRank);
    int maxj = length(minorRank);

    const int tileHeight = 16, tileWidth = 3;

    int bi, bj;
    for (bi=0; bi < maxi; bi += tileHeight)
    {
        int ni = bi + tileHeight;
        if (ni > maxi)
            ni = maxi;

        // Move back to the beginning of the array
        iter.pop(0);
        expr.pop(0);

        // Move to the start of this tile row
        iter.loadStride(majorRank);
        iter.advance(bi);
        expr.loadStride(majorRank);
        expr.advance(bi);

        // Save this position
        iter.push(1);
        expr.push(1);

        for (bj=0; bj < maxj; bj += tileWidth)
        {
            // Move to the beginning of the tile row
            iter.pop(1);
            expr.pop(1);

            // Move to the top of the current tile (bi,bj)
            iter.loadStride(minorRank);
            iter.advance(bj);
            expr.loadStride(minorRank);
            expr.advance(bj);

            if (bj + tileWidth <= maxj)
            {
                // Strip mining

                if ((useUnitStride) && (haveCommonMajorStride))
                {
                    int offset = 0;
                    T_numtype* _bz_restrict data = const_cast<T_numtype*>
                        (iter.data());

                    for (int i=bi; i < ni; ++i)
                    {
                        _bz_typename T_expr::T_numtype tmp1, tmp2, tmp3;

                        // Common subexpression elimination -- compilers
                        // won't necessarily do this on their own.
                        int t1 = offset+1;
                        int t2 = offset+2;

                        tmp1 = expr.fastRead(offset);
                        tmp2 = expr.fastRead(t1);
                        tmp3 = expr.fastRead(t2);

                        T_update::update(data[0], tmp1);
                        T_update::update(data[1], tmp2);
                        T_update::update(data[2], tmp3);

                        offset += commonMajorStride;
                        data += commonMajorStride;

#ifdef BZ_2D_STENCIL_DEBUG
    count += 3;
#endif
                    }
                }
                else {

                    for (int i=bi; i < ni; ++i)
                    {
                        iter.loadStride(minorRank);
                        expr.loadStride(minorRank);

                        // Loop through current row elements
                        T_update::update(*const_cast<T_numtype*>(iter.data()),
                            *expr);
                        iter.advance();
                        expr.advance();

                        T_update::update(*const_cast<T_numtype*>(iter.data()),
                            *expr);
                        iter.advance();
                        expr.advance();

                        T_update::update(*const_cast<T_numtype*>(iter.data()),
                            *expr);
                        iter.advance(-2);
                        expr.advance(-2);

                        iter.loadStride(majorRank);
                        expr.loadStride(majorRank);
                        iter.advance();
                        expr.advance();

#ifdef BZ_2D_STENCIL_DEBUG
    count += 3;
#endif

                    }
                }
            }
            else {

                // This code handles partial tiles at the bottom of the
                // array.

                for (int j=bj; j < maxj; ++j)
                {
                    iter.loadStride(majorRank);
                    expr.loadStride(majorRank);

                    for (int i=bi; i < ni; ++i)
                    {
                        T_update::update(*const_cast<T_numtype*>(iter.data()),
                            *expr);
                        iter.advance();
                        expr.advance();
#ifdef BZ_2D_STENCIL_DEBUG
    ++count;
#endif

                    }

                    // Move back to the top of this column
                    iter.advance(bi-ni);
                    expr.advance(bi-ni);

                    // Move over to the next column
                    iter.loadStride(minorRank);
                    expr.loadStride(minorRank);

                    iter.advance();
                    expr.advance();
                }
            }
        }
    }

#ifdef BZ_2D_STENCIL_DEBUG
    cout << "BZ_2D_STENCIL_DEBUG: count = " << count << endl;
#endif

    return *this;
}

#endif // BZ_ARRAY_2D_STENCIL_TILING
#endif // BZ_ARRAY_2D_NEW_STENCIL_TILING



#ifndef BZ_ARRAY_2D_NEW_STENCIL_TILING

#ifdef BZ_ARRAY_2D_STENCIL_TILING

template<class T_numtype, int N_rank> template<class T_expr, class T_update>
inline Array<T_numtype, N_rank>& 
Array<T_numtype, N_rank>::evaluateWithTiled2DTraversal(_bz_ArrayExpr<T_expr> 
    expr, T_update)
{
    const int minorRank = ordering(0);
    const int majorRank = ordering(1);

    const int blockSize = 16;
    
    ArrayIterator<T_numtype, N_rank> iter(*this);
    iter.push(0);
    expr.push(0);

    _bz_bool useUnitStride = iter.isUnitStride(minorRank)
                          && expr.isUnitStride(minorRank);

#ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
    int commonStride = expr.suggestStride(minorRank);
    if (iter.suggestStride(minorRank) > commonStride)
        commonStride = iter.suggestStride(minorRank);
    bool useCommonStride = iter.isStride(minorRank,commonStride)
        && expr.isStride(minorRank,commonStride);
#else
    int commonStride = 1;
    bool useCommonStride = _bz_false;
#endif

    int maxi = length(majorRank);
    int maxj = length(minorRank);

    int bi, bj;
    for (bi=0; bi < maxi; bi += blockSize)
    {
        int ni = bi + blockSize;
        if (ni > maxi)
            ni = maxi;

        for (bj=0; bj < maxj; bj += blockSize)
        {
            int nj = bj + blockSize;
            if (nj > maxj)
                nj = maxj;

            // Move to the beginning of the array
            iter.pop(0);
            expr.pop(0);

            // Move to the beginning of the tile (bi,bj)
            iter.loadStride(majorRank);
            iter.advance(bi);
            iter.loadStride(minorRank);
            iter.advance(bj);

            expr.loadStride(majorRank);
            expr.advance(bi);
            expr.loadStride(minorRank);
            expr.advance(bj);

            // Loop through tile rows
            for (int i=bi; i < ni; ++i)
            {
                // Save the beginning of this tile row
                iter.push(1);
                expr.push(1);

                // Load the minor stride
                iter.loadStride(minorRank);
                expr.loadStride(minorRank);

                if (useUnitStride)
                {
                    T_numtype* _bz_restrict data = const_cast<T_numtype*>
                        (iter.data());

                    int ubound = (nj-bj);
                    for (int j=0; j < ubound; ++j)
                        T_update::update(data[j], expr.fastRead(j));
                }
#ifdef BZ_ARRAY_EXPR_USE_COMMON_STRIDE
                else if (useCommonStride)
                {
                    int ubound = (nj-bj) * commonStride;
                    T_numtype* _bz_restrict data = const_cast<T_numtype*>
                        (iter.data());

                    for (int j=0; j < ubound; j += commonStride)
                        T_update::update(data[j], expr.fastRead(j));
                }
#endif
                else {
                    for (int j=bj; j < nj; ++j)
                    {
                        // Loop through current row elements
                        T_update::update(*const_cast<T_numtype*>(iter.data()), 
                            *expr);
                        iter.advance();
                        expr.advance();
                    }
                }

                // Move back to the beginning of the tile row, then
                // move to the next row
                iter.pop(1);
                iter.loadStride(majorRank);
                iter.advance(1);

                expr.pop(1);
                expr.loadStride(majorRank);
                expr.advance(1);
            }
        }
    }

    return *this;
}
#endif // BZ_ARRAY_2D_STENCIL_TILING
#endif // BZ_ARRAY_2D_NEW_STENCIL_TILING

BZ_NAMESPACE_END

#endif // BZ_ARRAYEVAL_CC