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 /*

  * Copyright (c) 1999, 2013, Oracle and/or its affiliates. All rights reserved.

  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.

  *

  * This code is free software; you can redistribute it and/or modify it

  * under the terms of the GNU General Public License version 2 only, as

  * published by the Free Software Foundation.

  *

  * This code is distributed in the hope that it will be useful, but WITHOUT

  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or

  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License

  * version 2 for more details (a copy is included in the LICENSE file that

  * accompanied this code).

  *

  * You should have received a copy of the GNU General Public License version

  * 2 along with this work; if not, write to the Free Software Foundation,

  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.

  *

  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA

  * or visit www.oracle.com if you need additional information or have any

  * questions.

  *

  */

 #include "precompiled.hpp"

 #include "c1/c1_Canonicalizer.hpp"

 #include "c1/c1_InstructionPrinter.hpp"

 #include "c1/c1_ValueStack.hpp"

 #include "ci/ciArray.hpp"

 #include "runtime/sharedRuntime.hpp"

 class PrintValueVisitor: public ValueVisitor {

   void visit(Value* vp) {

     (*vp)->print_line();

   }

 };

 void Canonicalizer::set_canonical(Value x) {

   assert(x != NULL, "value must exist");

   // Note: we can not currently substitute root nodes which show up in

   // the instruction stream (because the instruction list is embedded

   // in the instructions).

   if (canonical() != x) {

 #ifndef PRODUCT

     if (!x->has_printable_bci()) {

       x->set_printable_bci(bci());

     }

 #endif

     if (PrintCanonicalization) {

       PrintValueVisitor do_print_value;

       canonical()->input_values_do(&do_print_value);

       canonical()->print_line();

       tty->print_cr("canonicalized to:");

       x->input_values_do(&do_print_value);

       x->print_line();

       tty->cr();

     }

     assert(_canonical->type()->tag() == x->type()->tag(), "types must match");

     _canonical = x;

   }

 }

 void Canonicalizer::move_const_to_right(Op2* x) {

   if (x->x()->type()->is_constant() && x->is_commutative()) x->swap_operands();

 }

 void Canonicalizer::do_Op2(Op2* x) {

   if (x->x() == x->y()) {

     switch (x->op()) {

     case Bytecodes::_isub: set_constant(0); return;

     case Bytecodes::_lsub: set_constant(jlong_cast(0)); return;

     case Bytecodes::_iand: // fall through

     case Bytecodes::_land: // fall through

     case Bytecodes::_ior:  // fall through

     case Bytecodes::_lor : set_canonical(x->x()); return;

     case Bytecodes::_ixor: set_constant(0); return;

     case Bytecodes::_lxor: set_constant(jlong_cast(0)); return;

     }

   }

   if (x->x()->type()->is_constant() && x->y()->type()->is_constant()) {

     // do constant folding for selected operations

     switch (x->type()->tag()) {

       case intTag:

         { jint a = x->x()->type()->as_IntConstant()->value();

           jint b = x->y()->type()->as_IntConstant()->value();

           switch (x->op()) {

             case Bytecodes::_iadd: set_constant(a + b); return;

             case Bytecodes::_isub: set_constant(a - b); return;

             case Bytecodes::_imul: set_constant(a * b); return;

             case Bytecodes::_idiv:

               if (b != 0) {

                 if (a == min_jint && b == -1) {

                   set_constant(min_jint);

                 } else {

                   set_constant(a / b);

                 }

                 return;

               }

               break;

             case Bytecodes::_irem:

               if (b != 0) {

                 if (a == min_jint && b == -1) {

                   set_constant(0);

                 } else {

                   set_constant(a % b);

                 }

                 return;

               }

               break;

             case Bytecodes::_iand: set_constant(a & b); return;

             case Bytecodes::_ior : set_constant(a | b); return;

             case Bytecodes::_ixor: set_constant(a ^ b); return;

           }

         }

         break;

       case longTag:

         { jlong a = x->x()->type()->as_LongConstant()->value();

           jlong b = x->y()->type()->as_LongConstant()->value();

           switch (x->op()) {

             case Bytecodes::_ladd: set_constant(a + b); return;

             case Bytecodes::_lsub: set_constant(a - b); return;

             case Bytecodes::_lmul: set_constant(a * b); return;

             case Bytecodes::_ldiv:

               if (b != 0) {

                 set_constant(SharedRuntime::ldiv(b, a));

                 return;

               }

               break;

             case Bytecodes::_lrem:

               if (b != 0) {

                 set_constant(SharedRuntime::lrem(b, a));

                 return;

               }

               break;

             case Bytecodes::_land: set_constant(a & b); return;

             case Bytecodes::_lor : set_constant(a | b); return;

             case Bytecodes::_lxor: set_constant(a ^ b); return;

           }

         }

         break;

       // other cases not implemented (must be extremely careful with floats & doubles!)

     }

   }

   // make sure constant is on the right side, if any

   move_const_to_right(x);

   if (x->y()->type()->is_constant()) {

     // do constant folding for selected operations

     switch (x->type()->tag()) {

       case intTag:

         if (x->y()->type()->as_IntConstant()->value() == 0) {

           switch (x->op()) {

             case Bytecodes::_iadd: set_canonical(x->x()); return;

             case Bytecodes::_isub: set_canonical(x->x()); return;

             case Bytecodes::_imul: set_constant(0); return;

               // Note: for div and rem, make sure that C semantics

               //       corresponds to Java semantics!

             case Bytecodes::_iand: set_constant(0); return;

             case Bytecodes::_ior : set_canonical(x->x()); return;

           }

         }

         break;

       case longTag:

         if (x->y()->type()->as_LongConstant()->value() == (jlong)0) {

           switch (x->op()) {

             case Bytecodes::_ladd: set_canonical(x->x()); return;

             case Bytecodes::_lsub: set_canonical(x->x()); return;

             case Bytecodes::_lmul: set_constant((jlong)0); return;

               // Note: for div and rem, make sure that C semantics

               //       corresponds to Java semantics!

             case Bytecodes::_land: set_constant((jlong)0); return;

             case Bytecodes::_lor : set_canonical(x->x()); return;

           }

         }

         break;

     }

   }

 }

 void Canonicalizer::do_Phi            (Phi*             x) {}

 void Canonicalizer::do_Constant       (Constant*        x) {}

 void Canonicalizer::do_Local          (Local*           x) {}

 void Canonicalizer::do_LoadField      (LoadField*       x) {}

 // checks if v is in the block that is currently processed by

 // GraphBuilder. This is the only block that has not BlockEnd yet.

 static bool in_current_block(Value v) {

   int max_distance = 4;

   while (max_distance > 0 && v != NULL && v->as_BlockEnd() == NULL) {

     v = v->next();

     max_distance--;

   }

   return v == NULL;

 }

 void Canonicalizer::do_StoreField     (StoreField*      x) {

   // If a value is going to be stored into a field or array some of

   // the conversions emitted by javac are unneeded because the fields

   // are packed to their natural size.

   Convert* conv = x->value()->as_Convert();

   if (conv) {

     Value value = NULL;

     BasicType type = x->field()->type()->basic_type();

     switch (conv->op()) {

     case Bytecodes::_i2b: if (type == T_BYTE)  value = conv->value(); break;

     case Bytecodes::_i2s: if (type == T_SHORT || type == T_BYTE) value = conv->value(); break;

     case Bytecodes::_i2c: if (type == T_CHAR  || type == T_BYTE)  value = conv->value(); break;

     }

     // limit this optimization to current block

     if (value != NULL && in_current_block(conv)) {

       set_canonical(new StoreField(x->obj(), x->offset(), x->field(), value, x->is_static(),

                                    x->state_before(), x->needs_patching()));

       return;

     }

   }

 }

 void Canonicalizer::do_ArrayLength    (ArrayLength*     x) {

   NewArray* array = x->array()->as_NewArray();

   if (array != NULL && array->length() != NULL) {

     Constant* length = array->length()->as_Constant();

     if (length != NULL) {

       // do not use the Constant itself, but create a new Constant

       // with same value Otherwise a Constant is live over multiple

       // blocks without being registered in a state array.

       assert(length->type()->as_IntConstant() != NULL, "array length must be integer");

       set_constant(length->type()->as_IntConstant()->value());

     }

   } else {

     LoadField* lf = x->array()->as_LoadField();

     if (lf != NULL) {

       ciField* field = lf->field();

       if (field->is_constant() && field->is_static()) {

         // final static field

         ciObject* c = field->constant_value().as_object();

         if (c->is_array()) {

           ciArray* array = (ciArray*) c;

           set_constant(array->length());

         }

       }

     }

   }

 }

 void Canonicalizer::do_LoadIndexed    (LoadIndexed*     x) {}

 void Canonicalizer::do_StoreIndexed   (StoreIndexed*    x) {

   // If a value is going to be stored into a field or array some of

   // the conversions emitted by javac are unneeded because the fields

   // are packed to their natural size.

   Convert* conv = x->value()->as_Convert();

   if (conv) {

     Value value = NULL;

     BasicType type = x->elt_type();

     switch (conv->op()) {

     case Bytecodes::_i2b: if (type == T_BYTE)  value = conv->value(); break;

     case Bytecodes::_i2s: if (type == T_SHORT || type == T_BYTE) value = conv->value(); break;

     case Bytecodes::_i2c: if (type == T_CHAR  || type == T_BYTE) value = conv->value(); break;

     }

     // limit this optimization to current block

     if (value != NULL && in_current_block(conv)) {

       set_canonical(new StoreIndexed(x->array(), x->index(), x->length(),

                                      x->elt_type(), value, x->state_before()));

       return;

     }

   }

 }

 void Canonicalizer::do_NegateOp(NegateOp* x) {

   ValueType* t = x->x()->type();

   if (t->is_constant()) {

     switch (t->tag()) {

       case intTag   : set_constant(-t->as_IntConstant   ()->value()); return;

       case longTag  : set_constant(-t->as_LongConstant  ()->value()); return;

       case floatTag : set_constant(-t->as_FloatConstant ()->value()); return;

       case doubleTag: set_constant(-t->as_DoubleConstant()->value()); return;

       default       : ShouldNotReachHere();

     }

   }

 }

 void Canonicalizer::do_ArithmeticOp   (ArithmeticOp*    x) { do_Op2(x); }

 void Canonicalizer::do_ShiftOp        (ShiftOp*         x) {

   ValueType* t = x->x()->type();

   ValueType* t2 = x->y()->type();

   if (t->is_constant()) {

     switch (t->tag()) {

     case intTag   : if (t->as_IntConstant()->value() == 0)         { set_constant(0); return; } break;

     case longTag  : if (t->as_LongConstant()->value() == (jlong)0) { set_constant(jlong_cast(0)); return; } break;

     default       : ShouldNotReachHere();

     }

     if (t2->is_constant()) {

       if (t->tag() == intTag) {

         int value = t->as_IntConstant()->value();

         int shift = t2->as_IntConstant()->value() & 31;

         jint mask = ~(~0 << (32 - shift));

         if (shift == 0) mask = ~0;

         switch (x->op()) {

           case Bytecodes::_ishl:  set_constant(value << shift); return;

           case Bytecodes::_ishr:  set_constant(value >> shift); return;

           case Bytecodes::_iushr: set_constant((value >> shift) & mask); return;

         }

       } else if (t->tag() == longTag) {

         jlong value = t->as_LongConstant()->value();

         int shift = t2->as_IntConstant()->value() & 63;

         jlong mask = ~(~jlong_cast(0) << (64 - shift));

         if (shift == 0) mask = ~jlong_cast(0);

         switch (x->op()) {

           case Bytecodes::_lshl:  set_constant(value << shift); return;

           case Bytecodes::_lshr:  set_constant(value >> shift); return;

           case Bytecodes::_lushr: set_constant((value >> shift) & mask); return;

         }

       }

     }

   }

   if (t2->is_constant()) {

     switch (t2->tag()) {

       case intTag   : if (t2->as_IntConstant()->value() == 0)  set_canonical(x->x()); return;

       case longTag  : if (t2->as_LongConstant()->value() == (jlong)0)  set_canonical(x->x()); return;

       default       : ShouldNotReachHere();

     }

   }

 }

 void Canonicalizer::do_LogicOp        (LogicOp*         x) { do_Op2(x); }

 void Canonicalizer::do_CompareOp      (CompareOp*       x) {

   if (x->x() == x->y()) {

     switch (x->x()->type()->tag()) {

       case longTag: set_constant(0); break;

       case floatTag: {

         FloatConstant* fc = x->x()->type()->as_FloatConstant();

         if (fc) {

           if (g_isnan(fc->value())) {

             set_constant(x->op() == Bytecodes::_fcmpl ? -1 : 1);

           } else {

             set_constant(0);

           }

         }

         break;

       }

       case doubleTag: {

         DoubleConstant* dc = x->x()->type()->as_DoubleConstant();

         if (dc) {

           if (g_isnan(dc->value())) {

             set_constant(x->op() == Bytecodes::_dcmpl ? -1 : 1);

           } else {

             set_constant(0);

           }

         }

         break;

       }

     }

   } else if (x->x()->type()->is_constant() && x->y()->type()->is_constant()) {

     switch (x->x()->type()->tag()) {

       case longTag: {

         jlong vx = x->x()->type()->as_LongConstant()->value();

         jlong vy = x->y()->type()->as_LongConstant()->value();

         if (vx == vy)

           set_constant(0);

         else if (vx < vy)

           set_constant(-1);

         else

           set_constant(1);

         break;

       }

       case floatTag: {

         float vx = x->x()->type()->as_FloatConstant()->value();

         float vy = x->y()->type()->as_FloatConstant()->value();

         if (g_isnan(vx) || g_isnan(vy))

           set_constant(x->op() == Bytecodes::_fcmpl ? -1 : 1);

         else if (vx == vy)

           set_constant(0);

         else if (vx < vy)

           set_constant(-1);

         else

           set_constant(1);

         break;

       }

       case doubleTag: {

         double vx = x->x()->type()->as_DoubleConstant()->value();

         double vy = x->y()->type()->as_DoubleConstant()->value();

         if (g_isnan(vx) || g_isnan(vy))

           set_constant(x->op() == Bytecodes::_dcmpl ? -1 : 1);

         else if (vx == vy)

           set_constant(0);

         else if (vx < vy)

           set_constant(-1);

         else

           set_constant(1);

         break;

       }

     }

   }

 }

 void Canonicalizer::do_IfInstanceOf(IfInstanceOf*    x) {}

 void Canonicalizer::do_IfOp(IfOp* x) {

   // Caution: do not use do_Op2(x) here for now since

   //          we map the condition to the op for now!

   move_const_to_right(x);

 }

 void Canonicalizer::do_Intrinsic      (Intrinsic*       x) {

   switch (x->id()) {

   case vmIntrinsics::_floatToRawIntBits   : {

     FloatConstant* c = x->argument_at(0)->type()->as_FloatConstant();

     if (c != NULL) {

       JavaValue v;

       v.set_jfloat(c->value());

       set_constant(v.get_jint());

     }

     break;

   }

   case vmIntrinsics::_intBitsToFloat      : {

     IntConstant* c = x->argument_at(0)->type()->as_IntConstant();

     if (c != NULL) {

       JavaValue v;

       v.set_jint(c->value());

       set_constant(v.get_jfloat());

     }

     break;

   }

   case vmIntrinsics::_doubleToRawLongBits : {

     DoubleConstant* c = x->argument_at(0)->type()->as_DoubleConstant();

     if (c != NULL) {

       JavaValue v;

       v.set_jdouble(c->value());

       set_constant(v.get_jlong());

     }

     break;

   }

   case vmIntrinsics::_longBitsToDouble    : {

     LongConstant* c = x->argument_at(0)->type()->as_LongConstant();

     if (c != NULL) {

       JavaValue v;

       v.set_jlong(c->value());

       set_constant(v.get_jdouble());

     }

     break;

   }

   case vmIntrinsics::_isInstance          : {

     assert(x->number_of_arguments() == 2, "wrong type");

     InstanceConstant* c = x->argument_at(0)->type()->as_InstanceConstant();

     if (c != NULL && !c->value()->is_null_object()) {

       // ciInstance::java_mirror_type() returns non-NULL only for Java mirrors

       ciType* t = c->value()->as_instance()->java_mirror_type();

       if (t->is_klass()) {

         // substitute cls.isInstance(obj) of a constant Class into

         // an InstantOf instruction

         InstanceOf* i = new InstanceOf(t->as_klass(), x->argument_at(1), x->state_before());

         set_canonical(i);

         // and try to canonicalize even further

         do_InstanceOf(i);

       } else {

         assert(t->is_primitive_type(), "should be a primitive type");

         // cls.isInstance(obj) always returns false for primitive classes

         set_constant(0);

       }

     }

     break;

   }

   }

 }

 void Canonicalizer::do_Convert        (Convert*         x) {

   if (x->value()->type()->is_constant()) {

     switch (x->op()) {

     case Bytecodes::_i2b:  set_constant((int)((x->value()->type()->as_IntConstant()->value() << 24) >> 24)); break;

     case Bytecodes::_i2s:  set_constant((int)((x->value()->type()->as_IntConstant()->value() << 16) >> 16)); break;

     case Bytecodes::_i2c:  set_constant((int)(x->value()->type()->as_IntConstant()->value() & ((1<<16)-1))); break;

     case Bytecodes::_i2l:  set_constant((jlong)(x->value()->type()->as_IntConstant()->value()));             break;

     case Bytecodes::_i2f:  set_constant((float)(x->value()->type()->as_IntConstant()->value()));             break;

     case Bytecodes::_i2d:  set_constant((double)(x->value()->type()->as_IntConstant()->value()));            break;

     case Bytecodes::_l2i:  set_constant((int)(x->value()->type()->as_LongConstant()->value()));              break;

     case Bytecodes::_l2f:  set_constant(SharedRuntime::l2f(x->value()->type()->as_LongConstant()->value())); break;

     case Bytecodes::_l2d:  set_constant(SharedRuntime::l2d(x->value()->type()->as_LongConstant()->value())); break;

     case Bytecodes::_f2d:  set_constant((double)(x->value()->type()->as_FloatConstant()->value()));          break;

     case Bytecodes::_f2i:  set_constant(SharedRuntime::f2i(x->value()->type()->as_FloatConstant()->value())); break;

     case Bytecodes::_f2l:  set_constant(SharedRuntime::f2l(x->value()->type()->as_FloatConstant()->value())); break;

     case Bytecodes::_d2f:  set_constant((float)(x->value()->type()->as_DoubleConstant()->value()));          break;

     case Bytecodes::_d2i:  set_constant(SharedRuntime::d2i(x->value()->type()->as_DoubleConstant()->value())); break;

     case Bytecodes::_d2l:  set_constant(SharedRuntime::d2l(x->value()->type()->as_DoubleConstant()->value())); break;

     default:

       ShouldNotReachHere();

     }

   }

   Value value = x->value();

   BasicType type = T_ILLEGAL;

   LoadField* lf = value->as_LoadField();

   if (lf) {

     type = lf->field_type();

   } else {

     LoadIndexed* li = value->as_LoadIndexed();

     if (li) {

       type = li->elt_type();

     } else {

       Convert* conv = value->as_Convert();

       if (conv) {

         switch (conv->op()) {

           case Bytecodes::_i2b: type = T_BYTE;  break;

           case Bytecodes::_i2s: type = T_SHORT; break;

           case Bytecodes::_i2c: type = T_CHAR;  break;

         }

       }

     }

   }

   if (type != T_ILLEGAL) {

     switch (x->op()) {

       case Bytecodes::_i2b: if (type == T_BYTE)                    set_canonical(x->value()); break;

       case Bytecodes::_i2s: if (type == T_SHORT || type == T_BYTE) set_canonical(x->value()); break;

       case Bytecodes::_i2c: if (type == T_CHAR)                    set_canonical(x->value()); break;

     }

   } else {

     Op2* op2 = x->value()->as_Op2();

     if (op2 && op2->op() == Bytecodes::_iand && op2->y()->type()->is_constant()) {

       jint safebits = 0;

       jint mask = op2->y()->type()->as_IntConstant()->value();

       switch (x->op()) {

         case Bytecodes::_i2b: safebits = 0x7f;   break;

         case Bytecodes::_i2s: safebits = 0x7fff; break;

         case Bytecodes::_i2c: safebits = 0xffff; break;

       }

       // When casting a masked integer to a smaller signed type, if

       // the mask doesn't include the sign bit the cast isn't needed.

       if (safebits && (mask & ~safebits) == 0) {

         set_canonical(x->value());

       }

     }

   }

 }

 void Canonicalizer::do_NullCheck      (NullCheck*       x) {

   if (x->obj()->as_NewArray() != NULL || x->obj()->as_NewInstance() != NULL) {

     set_canonical(x->obj());

   } else {

     Constant* con = x->obj()->as_Constant();

     if (con) {

       ObjectType* c = con->type()->as_ObjectType();

       if (c && c->is_loaded()) {

         ObjectConstant* oc = c->as_ObjectConstant();

         if (!oc || !oc->value()->is_null_object()) {

           set_canonical(con);

         }

       }

     }

   }

 }

 void Canonicalizer::do_TypeCast       (TypeCast*        x) {}

 void Canonicalizer::do_Invoke         (Invoke*          x) {}

 void Canonicalizer::do_NewInstance    (NewInstance*     x) {}

 void Canonicalizer::do_NewTypeArray   (NewTypeArray*    x) {}

 void Canonicalizer::do_NewObjectArray (NewObjectArray*  x) {}

 void Canonicalizer::do_NewMultiArray  (NewMultiArray*   x) {}

 void Canonicalizer::do_CheckCast      (CheckCast*       x) {

   if (x->klass()->is_loaded()) {

     Value obj = x->obj();

     ciType* klass = obj->exact_type();

     if (klass == NULL) klass = obj->declared_type();

     if (klass != NULL && klass->is_loaded() && klass->is_subtype_of(x->klass())) {

       set_canonical(obj);

       return;

     }

     // checkcast of null returns null

     if (obj->as_Constant() && obj->type()->as_ObjectType()->constant_value()->is_null_object()) {

       set_canonical(obj);

     }

   }

 }

 void Canonicalizer::do_InstanceOf     (InstanceOf*      x) {

   if (x->klass()->is_loaded()) {

     Value obj = x->obj();

     ciType* exact = obj->exact_type();

     if (exact != NULL && exact->is_loaded() && (obj->as_NewInstance() || obj->as_NewArray())) {

       set_constant(exact->is_subtype_of(x->klass()) ? 1 : 0);

       return;

     }

     // instanceof null returns false

     if (obj->as_Constant() && obj->type()->as_ObjectType()->constant_value()->is_null_object()) {

       set_constant(0);

     }

   }

 }

 void Canonicalizer::do_MonitorEnter   (MonitorEnter*    x) {}

 void Canonicalizer::do_MonitorExit    (MonitorExit*     x) {}

 void Canonicalizer::do_BlockBegin     (BlockBegin*      x) {}

 void Canonicalizer::do_Goto           (Goto*            x) {}

 static bool is_true(jlong x, If::Condition cond, jlong y) {

   switch (cond) {

     case If::eql: return x == y;

     case If::neq: return x != y;

     case If::lss: return x <  y;

     case If::leq: return x <= y;

     case If::gtr: return x >  y;

     case If::geq: return x >= y;

   }

   ShouldNotReachHere();

   return false;

 }

 static bool is_safepoint(BlockEnd* x, BlockBegin* sux) {

   // An Instruction with multiple successors, x, is replaced by a Goto

   // to a single successor, sux. Is a safepoint check needed = was the

   // instruction being replaced a safepoint and the single remaining

   // successor a back branch?

   return x->is_safepoint() && (sux->bci() < x->state_before()->bci());

 }

 void Canonicalizer::do_If(If* x) {

   // move const to right

   if (x->x()->type()->is_constant()) x->swap_operands();

   // simplify

   const Value l = x->x(); ValueType* lt = l->type();

   const Value r = x->y(); ValueType* rt = r->type();

   if (l == r && !lt->is_float_kind()) {

     // pattern: If (a cond a) => simplify to Goto

     BlockBegin* sux;

     switch (x->cond()) {

     case If::eql: sux = x->sux_for(true);  break;

     case If::neq: sux = x->sux_for(false); break;

     case If::lss: sux = x->sux_for(false); break;

     case If::leq: sux = x->sux_for(true);  break;

     case If::gtr: sux = x->sux_for(false); break;

     case If::geq: sux = x->sux_for(true);  break;

     }

     // If is a safepoint then the debug information should come from the state_before of the If.

     set_canonical(new Goto(sux, x->state_before(), is_safepoint(x, sux)));

     return;

   }

   if (lt->is_constant() && rt->is_constant()) {

     if (x->x()->as_Constant() != NULL) {

       // pattern: If (lc cond rc) => simplify to: Goto

       BlockBegin* sux = x->x()->as_Constant()->compare(x->cond(), x->y(),

                                                        x->sux_for(true),

                                                        x->sux_for(false));

       if (sux != NULL) {

         // If is a safepoint then the debug information should come from the state_before of the If.

         set_canonical(new Goto(sux, x->state_before(), is_safepoint(x, sux)));

       }

     }

   } else if (rt->as_IntConstant() != NULL) {

     // pattern: If (l cond rc) => investigate further

     const jint rc = rt->as_IntConstant()->value();

     if (l->as_CompareOp() != NULL) {

       // pattern: If ((a cmp b) cond rc) => simplify to: If (x cond y) or: Goto

       CompareOp* cmp = l->as_CompareOp();

       bool unordered_is_less = cmp->op() == Bytecodes::_fcmpl || cmp->op() == Bytecodes::_dcmpl;

       BlockBegin* lss_sux = x->sux_for(is_true(-1, x->cond(), rc)); // successor for a < b

       BlockBegin* eql_sux = x->sux_for(is_true( 0, x->cond(), rc)); // successor for a = b

       BlockBegin* gtr_sux = x->sux_for(is_true(+1, x->cond(), rc)); // successor for a > b

       BlockBegin* nan_sux = unordered_is_less ? lss_sux : gtr_sux ; // successor for unordered

       // Note: At this point all successors (lss_sux, eql_sux, gtr_sux, nan_sux) are

       //       equal to x->tsux() or x->fsux(). Furthermore, nan_sux equals either

       //       lss_sux or gtr_sux.

       if (lss_sux == eql_sux && eql_sux == gtr_sux) {

         // all successors identical => simplify to: Goto

         set_canonical(new Goto(lss_sux, x->state_before(), x->is_safepoint()));

       } else {

         // two successors differ and two successors are the same => simplify to: If (x cmp y)

         // determine new condition & successors

         If::Condition cond;

         BlockBegin* tsux = NULL;

         BlockBegin* fsux = NULL;

              if (lss_sux == eql_sux) { cond = If::leq; tsux = lss_sux; fsux = gtr_sux; }

         else if (lss_sux == gtr_sux) { cond = If::neq; tsux = lss_sux; fsux = eql_sux; }

         else if (eql_sux == gtr_sux) { cond = If::geq; tsux = eql_sux; fsux = lss_sux; }

         else                         { ShouldNotReachHere();                           }

         If* canon = new If(cmp->x(), cond, nan_sux == tsux, cmp->y(), tsux, fsux, cmp->state_before(), x->is_safepoint());

         if (cmp->x() == cmp->y()) {

           do_If(canon);

         } else {

           if (compilation()->profile_branches()) {

             // TODO: If profiling, leave floating point comparisons unoptimized.

             // We currently do not support profiling of the unordered case.

             switch(cmp->op()) {

               case Bytecodes::_fcmpl: case Bytecodes::_fcmpg:

               case Bytecodes::_dcmpl: case Bytecodes::_dcmpg:

                 set_canonical(x);

                 return;

             }

           }

           set_bci(cmp->state_before()->bci());

           set_canonical(canon);

         }

       }

     } else if (l->as_InstanceOf() != NULL) {

       // NOTE: Code permanently disabled for now since it leaves the old InstanceOf

       //       instruction in the graph (it is pinned). Need to fix this at some point.

       //       It should also be left in the graph when generating a profiled method version or Goto

       //       has to know that it was an InstanceOf.

       return;

       // pattern: If ((obj instanceof klass) cond rc) => simplify to: IfInstanceOf or: Goto

       InstanceOf* inst = l->as_InstanceOf();

       BlockBegin* is_inst_sux = x->sux_for(is_true(1, x->cond(), rc)); // successor for instanceof == 1

       BlockBegin* no_inst_sux = x->sux_for(is_true(0, x->cond(), rc)); // successor for instanceof == 0

       if (is_inst_sux == no_inst_sux && inst->is_loaded()) {

         // both successors identical and klass is loaded => simplify to: Goto

         set_canonical(new Goto(is_inst_sux, x->state_before(), x->is_safepoint()));

       } else {

         // successors differ => simplify to: IfInstanceOf

         set_canonical(new IfInstanceOf(inst->klass(), inst->obj(), true, inst->state_before()->bci(), is_inst_sux, no_inst_sux));

       }

     }

   } else if (rt == objectNull && (l->as_NewInstance() || l->as_NewArray())) {

     if (x->cond() == Instruction::eql) {

       BlockBegin* sux = x->fsux();

       set_canonical(new Goto(sux, x->state_before(), is_safepoint(x, sux)));

     } else {

       assert(x->cond() == Instruction::neq, "only other valid case");

       BlockBegin* sux = x->tsux();

       set_canonical(new Goto(sux, x->state_before(), is_safepoint(x, sux)));

     }

   }

 }

 void Canonicalizer::do_TableSwitch(TableSwitch* x) {

   if (x->tag()->type()->is_constant()) {

     int v = x->tag()->type()->as_IntConstant()->value();

     BlockBegin* sux = x->default_sux();

     if (v >= x->lo_key() && v <= x->hi_key()) {

       sux = x->sux_at(v - x->lo_key());

     }

     set_canonical(new Goto(sux, x->state_before(), is_safepoint(x, sux)));

   } else if (x->number_of_sux() == 1) {

     // NOTE: Code permanently disabled for now since the switch statement's

     //       tag expression may produce side-effects in which case it must

     //       be executed.

     return;

     // simplify to Goto

     set_canonical(new Goto(x->default_sux(), x->state_before(), x->is_safepoint()));

   } else if (x->number_of_sux() == 2) {

     // NOTE: Code permanently disabled for now since it produces two new nodes

     //       (Constant & If) and the Canonicalizer cannot return them correctly

     //       yet. For now we copied the corresponding code directly into the

     //       GraphBuilder (i.e., we should never reach here).

     return;

     // simplify to If

     assert(x->lo_key() == x->hi_key(), "keys must be the same");

     Constant* key = new Constant(new IntConstant(x->lo_key()));

     set_canonical(new If(x->tag(), If::eql, true, key, x->sux_at(0), x->default_sux(), x->state_before(), x->is_safepoint()));

   }

 }

 void Canonicalizer::do_LookupSwitch(LookupSwitch* x) {

   if (x->tag()->type()->is_constant()) {

     int v = x->tag()->type()->as_IntConstant()->value();

     BlockBegin* sux = x->default_sux();

     for (int i = 0; i < x->length(); i++) {

       if (v == x->key_at(i)) {

         sux = x->sux_at(i);

       }

     }

     set_canonical(new Goto(sux, x->state_before(), is_safepoint(x, sux)));

   } else if (x->number_of_sux() == 1) {

     // NOTE: Code permanently disabled for now since the switch statement's

     //       tag expression may produce side-effects in which case it must

     //       be executed.

     return;

     // simplify to Goto

     set_canonical(new Goto(x->default_sux(), x->state_before(), x->is_safepoint()));

   } else if (x->number_of_sux() == 2) {

     // NOTE: Code permanently disabled for now since it produces two new nodes

     //       (Constant & If) and the Canonicalizer cannot return them correctly

     //       yet. For now we copied the corresponding code directly into the

     //       GraphBuilder (i.e., we should never reach here).

     return;

     // simplify to If

     assert(x->length() == 1, "length must be the same");

     Constant* key = new Constant(new IntConstant(x->key_at(0)));

     set_canonical(new If(x->tag(), If::eql, true, key, x->sux_at(0), x->default_sux(), x->state_before(), x->is_safepoint()));

   }

 }

 void Canonicalizer::do_Return         (Return*          x) {}

 void Canonicalizer::do_Throw          (Throw*           x) {}

 void Canonicalizer::do_Base           (Base*            x) {}

 void Canonicalizer::do_OsrEntry       (OsrEntry*        x) {}

 void Canonicalizer::do_ExceptionObject(ExceptionObject* x) {}

 static bool match_index_and_scale(Instruction*  instr,

                                   Instruction** index,

                                   int*          log2_scale) {

   // Skip conversion ops. This works only on 32bit because of the implicit l2i that the

   // unsafe performs.

 #ifndef _LP64

   Convert* convert = instr->as_Convert();

   if (convert != NULL && convert->op() == Bytecodes::_i2l) {

     assert(convert->value()->type() == intType, "invalid input type");

     instr = convert->value();

   }

 #endif

   ShiftOp* shift = instr->as_ShiftOp();

   if (shift != NULL) {

     if (shift->op() == Bytecodes::_lshl) {

       assert(shift->x()->type() == longType, "invalid input type");

     } else {

 #ifndef _LP64

       if (shift->op() == Bytecodes::_ishl) {

         assert(shift->x()->type() == intType, "invalid input type");

       } else {

         return false;

       }

 #else

       return false;

 #endif

     }

     // Constant shift value?

     Constant* con = shift->y()->as_Constant();

     if (con == NULL) return false;

     // Well-known type and value?

     IntConstant* val = con->type()->as_IntConstant();

     assert(val != NULL, "Should be an int constant");

     *index = shift->x();

     int tmp_scale = val->value();

     if (tmp_scale >= 0 && tmp_scale < 4) {

       *log2_scale = tmp_scale;

       return true;

     } else {

       return false;

     }

   }

   ArithmeticOp* arith = instr->as_ArithmeticOp();

   if (arith != NULL) {

     // See if either arg is a known constant

     Constant* con = arith->x()->as_Constant();

     if (con != NULL) {

       *index = arith->y();

     } else {

       con = arith->y()->as_Constant();

       if (con == NULL) return false;

       *index = arith->x();

     }

     long const_value;

     // Check for integer multiply

     if (arith->op() == Bytecodes::_lmul) {

       assert((*index)->type() == longType, "invalid input type");

       LongConstant* val = con->type()->as_LongConstant();

       assert(val != NULL, "expecting a long constant");

       const_value = val->value();

     } else {

 #ifndef _LP64

       if (arith->op() == Bytecodes::_imul) {

         assert((*index)->type() == intType, "invalid input type");

         IntConstant* val = con->type()->as_IntConstant();

         assert(val != NULL, "expecting an int constant");

         const_value = val->value();

       } else {

         return false;

       }

 #else

       return false;

 #endif

     }

     switch (const_value) {

     case 1: *log2_scale = 0; return true;

     case 2: *log2_scale = 1; return true;

     case 4: *log2_scale = 2; return true;

     case 8: *log2_scale = 3; return true;

     default:            return false;

     }

   }

   // Unknown instruction sequence; don't touch it

   return false;

 }

 static bool match(UnsafeRawOp* x,

                   Instruction** base,

                   Instruction** index,

                   int*          log2_scale) {

   ArithmeticOp* root = x->base()->as_ArithmeticOp();

   if (root == NULL) return false;

   // Limit ourselves to addition for now

   if (root->op() != Bytecodes::_ladd) return false;

   bool match_found = false;

   // Try to find shift or scale op

   if (match_index_and_scale(root->y(), index, log2_scale)) {

     *base = root->x();

     match_found = true;

   } else if (match_index_and_scale(root->x(), index, log2_scale)) {

     *base = root->y();

     match_found = true;

   } else if (NOT_LP64(root->y()->as_Convert() != NULL) LP64_ONLY(false)) {

     // Skipping i2l works only on 32bit because of the implicit l2i that the unsafe performs.

     // 64bit needs a real sign-extending conversion.

     Convert* convert = root->y()->as_Convert();

     if (convert->op() == Bytecodes::_i2l) {

       assert(convert->value()->type() == intType, "should be an int");

       // pick base and index, setting scale at 1

       *base  = root->x();

       *index = convert->value();

       *log2_scale = 0;

       match_found = true;

     }

   }

   // The default solution

   if (!match_found) {

     *base = root->x();

     *index = root->y();

     *log2_scale = 0;

   }

   // If the value is pinned then it will be always be computed so

   // there's no profit to reshaping the expression.

   return !root->is_pinned();

 }

 void Canonicalizer::do_UnsafeRawOp(UnsafeRawOp* x) {

   Instruction* base = NULL;

   Instruction* index = NULL;

   int          log2_scale;

   if (match(x, &base, &index, &log2_scale)) {

     x->set_base(base);

     x->set_index(index);

     x->set_log2_scale(log2_scale);

     if (PrintUnsafeOptimization) {

       tty->print_cr("Canonicalizer: UnsafeRawOp id %d: base = id %d, index = id %d, log2_scale = %d",

                     x->id(), x->base()->id(), x->index()->id(), x->log2_scale());

     }

   }

 }

 void Canonicalizer::do_RoundFP(RoundFP* x) {}

 void Canonicalizer::do_UnsafeGetRaw(UnsafeGetRaw* x) { if (OptimizeUnsafes) do_UnsafeRawOp(x); }

 void Canonicalizer::do_UnsafePutRaw(UnsafePutRaw* x) { if (OptimizeUnsafes) do_UnsafeRawOp(x); }

 void Canonicalizer::do_UnsafeGetObject(UnsafeGetObject* x) {}

 void Canonicalizer::do_UnsafePutObject(UnsafePutObject* x) {}

 void Canonicalizer::do_UnsafeGetAndSetObject(UnsafeGetAndSetObject* x) {}

 void Canonicalizer::do_UnsafePrefetchRead (UnsafePrefetchRead*  x) {}

 void Canonicalizer::do_UnsafePrefetchWrite(UnsafePrefetchWrite* x) {}

 void Canonicalizer::do_ProfileCall(ProfileCall* x) {}

 void Canonicalizer::do_ProfileReturnType(ProfileReturnType* x) {}

 void Canonicalizer::do_ProfileInvoke(ProfileInvoke* x) {}

 void Canonicalizer::do_RuntimeCall(RuntimeCall* x) {}

 void Canonicalizer::do_RangeCheckPredicate(RangeCheckPredicate* x) {}

 #ifdef ASSERT

 void Canonicalizer::do_Assert(Assert* x) {}

 #endif

 void Canonicalizer::do_MemBar(MemBar* x) {}