Mercurial > jdk8-mips64-public > hotspot / file revision

 /*

  * Copyright (c) 2007, 2012, 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 "memory/allocation.inline.hpp"

 #include "opto/connode.hpp"

 #include "opto/vectornode.hpp"

 //------------------------------VectorNode--------------------------------------

 // Return the vector operator for the specified scalar operation

 // and vector length.  Also used to check if the code generator

 // supports the vector operation.

 int VectorNode::opcode(int sopc, BasicType bt) {

   switch (sopc) {

   case Op_AddI:

     switch (bt) {

     case T_BOOLEAN:

     case T_BYTE:      return Op_AddVB;

     case T_CHAR:

     case T_SHORT:     return Op_AddVS;

     case T_INT:       return Op_AddVI;

     }

     ShouldNotReachHere();

   case Op_AddL:

     assert(bt == T_LONG, "must be");

     return Op_AddVL;

   case Op_AddF:

     assert(bt == T_FLOAT, "must be");

     return Op_AddVF;

   case Op_AddD:

     assert(bt == T_DOUBLE, "must be");

     return Op_AddVD;

   case Op_SubI:

     switch (bt) {

     case T_BOOLEAN:

     case T_BYTE:   return Op_SubVB;

     case T_CHAR:

     case T_SHORT:  return Op_SubVS;

     case T_INT:    return Op_SubVI;

     }

     ShouldNotReachHere();

   case Op_SubL:

     assert(bt == T_LONG, "must be");

     return Op_SubVL;

   case Op_SubF:

     assert(bt == T_FLOAT, "must be");

     return Op_SubVF;

   case Op_SubD:

     assert(bt == T_DOUBLE, "must be");

     return Op_SubVD;

   case Op_MulI:

     switch (bt) {

     case T_BOOLEAN:

     case T_BYTE:   return 0;   // Unimplemented

     case T_CHAR:

     case T_SHORT:  return Op_MulVS;

     case T_INT:    return Matcher::match_rule_supported(Op_MulVI) ? Op_MulVI : 0; // SSE4_1

     }

     ShouldNotReachHere();

   case Op_MulF:

     assert(bt == T_FLOAT, "must be");

     return Op_MulVF;

   case Op_MulD:

     assert(bt == T_DOUBLE, "must be");

     return Op_MulVD;

   case Op_DivF:

     assert(bt == T_FLOAT, "must be");

     return Op_DivVF;

   case Op_DivD:

     assert(bt == T_DOUBLE, "must be");

     return Op_DivVD;

   case Op_LShiftI:

     switch (bt) {

     case T_BOOLEAN:

     case T_BYTE:   return Op_LShiftVB;

     case T_CHAR:

     case T_SHORT:  return Op_LShiftVS;

     case T_INT:    return Op_LShiftVI;

     }

     ShouldNotReachHere();

   case Op_LShiftL:

     assert(bt == T_LONG, "must be");

     return Op_LShiftVL;

   case Op_RShiftI:

     switch (bt) {

     case T_BOOLEAN:

     case T_BYTE:   return Op_RShiftVB;

     case T_CHAR:

     case T_SHORT:  return Op_RShiftVS;

     case T_INT:    return Op_RShiftVI;

     }

     ShouldNotReachHere();

   case Op_RShiftL:

     assert(bt == T_LONG, "must be");

     return Op_RShiftVL;

   case Op_URShiftI:

     switch (bt) {

     case T_BOOLEAN:

     case T_BYTE:   return Op_URShiftVB;

     case T_CHAR:

     case T_SHORT:  return Op_URShiftVS;

     case T_INT:    return Op_URShiftVI;

     }

     ShouldNotReachHere();

   case Op_URShiftL:

     assert(bt == T_LONG, "must be");

     return Op_URShiftVL;

   case Op_AndI:

   case Op_AndL:

     return Op_AndV;

   case Op_OrI:

   case Op_OrL:

     return Op_OrV;

   case Op_XorI:

   case Op_XorL:

     return Op_XorV;

   case Op_LoadB:

   case Op_LoadUB:

   case Op_LoadUS:

   case Op_LoadS:

   case Op_LoadI:

   case Op_LoadL:

   case Op_LoadF:

   case Op_LoadD:

     return Op_LoadVector;

   case Op_StoreB:

   case Op_StoreC:

   case Op_StoreI:

   case Op_StoreL:

   case Op_StoreF:

   case Op_StoreD:

     return Op_StoreVector;

   }

   return 0; // Unimplemented

 }

 bool VectorNode::implemented(int opc, uint vlen, BasicType bt) {

   if (is_java_primitive(bt) &&

       (vlen > 1) && is_power_of_2(vlen) &&

       Matcher::vector_size_supported(bt, vlen)) {

     int vopc = VectorNode::opcode(opc, bt);

     return vopc > 0 && Matcher::has_match_rule(vopc);

   }

   return false;

 }

 bool VectorNode::is_shift(Node* n) {

   switch (n->Opcode()) {

   case Op_LShiftI:

   case Op_LShiftL:

   case Op_RShiftI:

   case Op_RShiftL:

   case Op_URShiftI:

   case Op_URShiftL:

     return true;

   }

   return false;

 }

 // Check if input is loop invariant vector.

 bool VectorNode::is_invariant_vector(Node* n) {

   // Only Replicate vector nodes are loop invariant for now.

   switch (n->Opcode()) {

   case Op_ReplicateB:

   case Op_ReplicateS:

   case Op_ReplicateI:

   case Op_ReplicateL:

   case Op_ReplicateF:

   case Op_ReplicateD:

     return true;

   }

   return false;

 }

 // [Start, end) half-open range defining which operands are vectors

 void VectorNode::vector_operands(Node* n, uint* start, uint* end) {

   switch (n->Opcode()) {

   case Op_LoadB:   case Op_LoadUB:

   case Op_LoadS:   case Op_LoadUS:

   case Op_LoadI:   case Op_LoadL:

   case Op_LoadF:   case Op_LoadD:

   case Op_LoadP:   case Op_LoadN:

     *start = 0;

     *end   = 0; // no vector operands

     break;

   case Op_StoreB:  case Op_StoreC:

   case Op_StoreI:  case Op_StoreL:

   case Op_StoreF:  case Op_StoreD:

   case Op_StoreP:  case Op_StoreN:

     *start = MemNode::ValueIn;

     *end   = MemNode::ValueIn + 1; // 1 vector operand

     break;

   case Op_LShiftI:  case Op_LShiftL:

   case Op_RShiftI:  case Op_RShiftL:

   case Op_URShiftI: case Op_URShiftL:

     *start = 1;

     *end   = 2; // 1 vector operand

     break;

   case Op_AddI: case Op_AddL: case Op_AddF: case Op_AddD:

   case Op_SubI: case Op_SubL: case Op_SubF: case Op_SubD:

   case Op_MulI: case Op_MulL: case Op_MulF: case Op_MulD:

   case Op_DivF: case Op_DivD:

   case Op_AndI: case Op_AndL:

   case Op_OrI:  case Op_OrL:

   case Op_XorI: case Op_XorL:

     *start = 1;

     *end   = 3; // 2 vector operands

     break;

   case Op_CMoveI:  case Op_CMoveL:  case Op_CMoveF:  case Op_CMoveD:

     *start = 2;

     *end   = n->req();

     break;

   default:

     *start = 1;

     *end   = n->req(); // default is all operands

   }

 }

 // Return the vector version of a scalar operation node.

 VectorNode* VectorNode::make(Compile* C, int opc, Node* n1, Node* n2, uint vlen, BasicType bt) {

   const TypeVect* vt = TypeVect::make(bt, vlen);

   int vopc = VectorNode::opcode(opc, bt);

   // This method should not be called for unimplemented vectors.

   guarantee(vopc > 0, err_msg_res("Vector for '%s' is not implemented", NodeClassNames[opc]));

   switch (vopc) {

   case Op_AddVB: return new (C) AddVBNode(n1, n2, vt);

   case Op_AddVS: return new (C) AddVSNode(n1, n2, vt);

   case Op_AddVI: return new (C) AddVINode(n1, n2, vt);

   case Op_AddVL: return new (C) AddVLNode(n1, n2, vt);

   case Op_AddVF: return new (C) AddVFNode(n1, n2, vt);

   case Op_AddVD: return new (C) AddVDNode(n1, n2, vt);

   case Op_SubVB: return new (C) SubVBNode(n1, n2, vt);

   case Op_SubVS: return new (C) SubVSNode(n1, n2, vt);

   case Op_SubVI: return new (C) SubVINode(n1, n2, vt);

   case Op_SubVL: return new (C) SubVLNode(n1, n2, vt);

   case Op_SubVF: return new (C) SubVFNode(n1, n2, vt);

   case Op_SubVD: return new (C) SubVDNode(n1, n2, vt);

   case Op_MulVS: return new (C) MulVSNode(n1, n2, vt);

   case Op_MulVI: return new (C) MulVINode(n1, n2, vt);

   case Op_MulVF: return new (C) MulVFNode(n1, n2, vt);

   case Op_MulVD: return new (C) MulVDNode(n1, n2, vt);

   case Op_DivVF: return new (C) DivVFNode(n1, n2, vt);

   case Op_DivVD: return new (C) DivVDNode(n1, n2, vt);

   case Op_LShiftVB: return new (C) LShiftVBNode(n1, n2, vt);

   case Op_LShiftVS: return new (C) LShiftVSNode(n1, n2, vt);

   case Op_LShiftVI: return new (C) LShiftVINode(n1, n2, vt);

   case Op_LShiftVL: return new (C) LShiftVLNode(n1, n2, vt);

   case Op_RShiftVB: return new (C) RShiftVBNode(n1, n2, vt);

   case Op_RShiftVS: return new (C) RShiftVSNode(n1, n2, vt);

   case Op_RShiftVI: return new (C) RShiftVINode(n1, n2, vt);

   case Op_RShiftVL: return new (C) RShiftVLNode(n1, n2, vt);

   case Op_URShiftVB: return new (C) URShiftVBNode(n1, n2, vt);

   case Op_URShiftVS: return new (C) URShiftVSNode(n1, n2, vt);

   case Op_URShiftVI: return new (C) URShiftVINode(n1, n2, vt);

   case Op_URShiftVL: return new (C) URShiftVLNode(n1, n2, vt);

   case Op_AndV: return new (C) AndVNode(n1, n2, vt);

   case Op_OrV:  return new (C) OrVNode (n1, n2, vt);

   case Op_XorV: return new (C) XorVNode(n1, n2, vt);

   }

   fatal(err_msg_res("Missed vector creation for '%s'", NodeClassNames[vopc]));

   return NULL;

 }

 // Scalar promotion

 VectorNode* VectorNode::scalar2vector(Compile* C, Node* s, uint vlen, const Type* opd_t) {

   BasicType bt = opd_t->array_element_basic_type();

   const TypeVect* vt = opd_t->singleton() ? TypeVect::make(opd_t, vlen)

                                           : TypeVect::make(bt, vlen);

   switch (bt) {

   case T_BOOLEAN:

   case T_BYTE:

     return new (C) ReplicateBNode(s, vt);

   case T_CHAR:

   case T_SHORT:

     return new (C) ReplicateSNode(s, vt);

   case T_INT:

     return new (C) ReplicateINode(s, vt);

   case T_LONG:

     return new (C) ReplicateLNode(s, vt);

   case T_FLOAT:

     return new (C) ReplicateFNode(s, vt);

   case T_DOUBLE:

     return new (C) ReplicateDNode(s, vt);

   }

   fatal(err_msg_res("Type '%s' is not supported for vectors", type2name(bt)));

   return NULL;

 }

 VectorNode* VectorNode::shift_count(Compile* C, Node* shift, Node* cnt, uint vlen, BasicType bt) {

   assert(VectorNode::is_shift(shift) && !cnt->is_Con(), "only variable shift count");

   // Match shift count type with shift vector type.

   const TypeVect* vt = TypeVect::make(bt, vlen);

   switch (shift->Opcode()) {

   case Op_LShiftI:

   case Op_LShiftL:

     return new (C) LShiftCntVNode(cnt, vt);

   case Op_RShiftI:

   case Op_RShiftL:

   case Op_URShiftI:

   case Op_URShiftL:

     return new (C) RShiftCntVNode(cnt, vt);

   }

   fatal(err_msg_res("Missed vector creation for '%s'", NodeClassNames[shift->Opcode()]));

   return NULL;

 }

 // Return initial Pack node. Additional operands added with add_opd() calls.

 PackNode* PackNode::make(Compile* C, Node* s, uint vlen, BasicType bt) {

   const TypeVect* vt = TypeVect::make(bt, vlen);

   switch (bt) {

   case T_BOOLEAN:

   case T_BYTE:

     return new (C) PackBNode(s, vt);

   case T_CHAR:

   case T_SHORT:

     return new (C) PackSNode(s, vt);

   case T_INT:

     return new (C) PackINode(s, vt);

   case T_LONG:

     return new (C) PackLNode(s, vt);

   case T_FLOAT:

     return new (C) PackFNode(s, vt);

   case T_DOUBLE:

     return new (C) PackDNode(s, vt);

   }

   fatal(err_msg_res("Type '%s' is not supported for vectors", type2name(bt)));

   return NULL;

 }

 // Create a binary tree form for Packs. [lo, hi) (half-open) range

 PackNode* PackNode::binary_tree_pack(Compile* C, int lo, int hi) {

   int ct = hi - lo;

   assert(is_power_of_2(ct), "power of 2");

   if (ct == 2) {

     PackNode* pk = PackNode::make(C, in(lo), 2, vect_type()->element_basic_type());

     pk->add_opd(in(lo+1));

     return pk;

   } else {

     int mid = lo + ct/2;

     PackNode* n1 = binary_tree_pack(C, lo,  mid);

     PackNode* n2 = binary_tree_pack(C, mid, hi );

     BasicType bt = n1->vect_type()->element_basic_type();

     assert(bt == n2->vect_type()->element_basic_type(), "should be the same");

     switch (bt) {

     case T_BOOLEAN:

     case T_BYTE:

       return new (C) PackSNode(n1, n2, TypeVect::make(T_SHORT, 2));

     case T_CHAR:

     case T_SHORT:

       return new (C) PackINode(n1, n2, TypeVect::make(T_INT, 2));

     case T_INT:

       return new (C) PackLNode(n1, n2, TypeVect::make(T_LONG, 2));

     case T_LONG:

       return new (C) Pack2LNode(n1, n2, TypeVect::make(T_LONG, 2));

     case T_FLOAT:

       return new (C) PackDNode(n1, n2, TypeVect::make(T_DOUBLE, 2));

     case T_DOUBLE:

       return new (C) Pack2DNode(n1, n2, TypeVect::make(T_DOUBLE, 2));

     }

     fatal(err_msg_res("Type '%s' is not supported for vectors", type2name(bt)));

   }

   return NULL;

 }

 // Return the vector version of a scalar load node.

 LoadVectorNode* LoadVectorNode::make(Compile* C, int opc, Node* ctl, Node* mem,

                                      Node* adr, const TypePtr* atyp, uint vlen, BasicType bt) {

   const TypeVect* vt = TypeVect::make(bt, vlen);

   return new (C) LoadVectorNode(ctl, mem, adr, atyp, vt);

 }

 // Return the vector version of a scalar store node.

 StoreVectorNode* StoreVectorNode::make(Compile* C, int opc, Node* ctl, Node* mem,

                                        Node* adr, const TypePtr* atyp, Node* val,

                                        uint vlen) {

   return new (C) StoreVectorNode(ctl, mem, adr, atyp, val);

 }

 // Extract a scalar element of vector.

 Node* ExtractNode::make(Compile* C, Node* v, uint position, BasicType bt) {

   assert((int)position < Matcher::max_vector_size(bt), "pos in range");

   ConINode* pos = ConINode::make(C, (int)position);

   switch (bt) {

   case T_BOOLEAN:

     return new (C) ExtractUBNode(v, pos);

   case T_BYTE:

     return new (C) ExtractBNode(v, pos);

   case T_CHAR:

     return new (C) ExtractCNode(v, pos);

   case T_SHORT:

     return new (C) ExtractSNode(v, pos);

   case T_INT:

     return new (C) ExtractINode(v, pos);

   case T_LONG:

     return new (C) ExtractLNode(v, pos);

   case T_FLOAT:

     return new (C) ExtractFNode(v, pos);

   case T_DOUBLE:

     return new (C) ExtractDNode(v, pos);

   }

   fatal(err_msg_res("Type '%s' is not supported for vectors", type2name(bt)));

   return NULL;

 }