jdk8-mips64-public/hotspot: src/share/vm/opto/postaloc.cpp@83f08886981c (annotated)

src/share/vm/opto/postaloc.cpp@83f08886981c (annotated)

src/share/vm/opto/postaloc.cpp

Fri, 11 Mar 2011 07:50:51 -0800

author: kvn
date: Fri, 11 Mar 2011 07:50:51 -0800
changeset 2636: 83f08886981c
parent 2350: 2f644f85485d
child 3133: 8f47d8870d9a
permissions: -rw-r--r--

7026631: field _klass is incorrectly set for dual type of TypeAryPtr::OOPS
Summary: add missing check this->dual() != TypeAryPtr::OOPS into TypeAryPtr::klass().
Reviewed-by: never

 /*
  * Copyright (c) 1998, 2010, 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/chaitin.hpp"
 #include "opto/machnode.hpp"
 // see if this register kind does not requires two registers
 static bool is_single_register(uint x) {
 #ifdef _LP64
   return (x != Op_RegD && x != Op_RegL && x != Op_RegP);
 #else
   return (x != Op_RegD && x != Op_RegL);
 #endif
 }
 //---------------------------may_be_copy_of_callee-----------------------------
 // Check to see if we can possibly be a copy of a callee-save value.
 bool PhaseChaitin::may_be_copy_of_callee( Node *def ) const {
   // Short circuit if there are no callee save registers
   if (_matcher.number_of_saved_registers() == 0) return false;
   // Expect only a spill-down and reload on exit for callee-save spills.
   // Chains of copies cannot be deep.
   // 5008997 - This is wishful thinking. Register allocator seems to
   // be splitting live ranges for callee save registers to such
   // an extent that in large methods the chains can be very long
   // (50+). The conservative answer is to return true if we don't
   // know as this prevents optimizations from occurring.
   const int limit = 60;
   int i;
   for( i=0; i < limit; i++ ) {
     if( def->is_Proj() && def->in(0)->is_Start() &&
         _matcher.is_save_on_entry(lrgs(n2lidx(def)).reg()) )
       return true;              // Direct use of callee-save proj
     if( def->is_Copy() )        // Copies carry value through
       def = def->in(def->is_Copy());
     else if( def->is_Phi() )    // Phis can merge it from any direction
       def = def->in(1);
     else
       break;
     guarantee(def != NULL, "must not resurrect dead copy");
   }
   // If we reached the end and didn't find a callee save proj
   // then this may be a callee save proj so we return true
   // as the conservative answer. If we didn't reach then end
   // we must have discovered that it was not a callee save
   // else we would have returned.
   return i == limit;
 }
 //------------------------------yank_if_dead-----------------------------------
 // Removed an edge from 'old'.  Yank if dead.  Return adjustment counts to
 // iterators in the current block.
 int PhaseChaitin::yank_if_dead( Node *old, Block *current_block, Node_List *value, Node_List *regnd ) {
   int blk_adjust=0;
   while (old->outcnt() == 0 && old != C->top()) {
     Block *oldb = _cfg._bbs[old->_idx];
     oldb->find_remove(old);
     // Count 1 if deleting an instruction from the current block
     if( oldb == current_block ) blk_adjust++;
     _cfg._bbs.map(old->_idx,NULL);
     OptoReg::Name old_reg = lrgs(n2lidx(old)).reg();
     if( regnd && (*regnd)[old_reg]==old ) { // Instruction is currently available?
       value->map(old_reg,NULL);  // Yank from value/regnd maps
       regnd->map(old_reg,NULL);  // This register's value is now unknown
     }
     assert(old->req() <= 2, "can't handle more inputs");
     Node *tmp = old->req() > 1 ? old->in(1) : NULL;
     old->disconnect_inputs(NULL);
     if( !tmp ) break;
     old = tmp;
   }
   return blk_adjust;
 }
 //------------------------------use_prior_register-----------------------------
 // Use the prior value instead of the current value, in an effort to make
 // the current value go dead.  Return block iterator adjustment, in case
 // we yank some instructions from this block.
 int PhaseChaitin::use_prior_register( Node *n, uint idx, Node *def, Block *current_block, Node_List &value, Node_List &regnd ) {
   // No effect?
   if( def == n->in(idx) ) return 0;
   // Def is currently dead and can be removed?  Do not resurrect
   if( def->outcnt() == 0 ) return 0;
   // Not every pair of physical registers are assignment compatible,
   // e.g. on sparc floating point registers are not assignable to integer
   // registers.
   const LRG &def_lrg = lrgs(n2lidx(def));
   OptoReg::Name def_reg = def_lrg.reg();
   const RegMask &use_mask = n->in_RegMask(idx);
   bool can_use = ( RegMask::can_represent(def_reg) ? (use_mask.Member(def_reg) != 0)
                                                    : (use_mask.is_AllStack() != 0));
   // Check for a copy to or from a misaligned pair.
   can_use = can_use && !use_mask.is_misaligned_Pair() && !def_lrg.mask().is_misaligned_Pair();
   if (!can_use)
     return 0;
   // Capture the old def in case it goes dead...
   Node *old = n->in(idx);
   // Save-on-call copies can only be elided if the entire copy chain can go
   // away, lest we get the same callee-save value alive in 2 locations at
   // once.  We check for the obvious trivial case here.  Although it can
   // sometimes be elided with cooperation outside our scope, here we will just
   // miss the opportunity.  :-(
   if( may_be_copy_of_callee(def) ) {
     if( old->outcnt() > 1 ) return 0; // We're the not last user
     int idx = old->is_Copy();
     assert( idx, "chain of copies being removed" );
     Node *old2 = old->in(idx);  // Chain of copies
     if( old2->outcnt() > 1 ) return 0; // old is not the last user
     int idx2 = old2->is_Copy();
     if( !idx2 ) return 0;       // Not a chain of 2 copies
     if( def != old2->in(idx2) ) return 0; // Chain of exactly 2 copies
   }
   // Use the new def
   n->set_req(idx,def);
   _post_alloc++;
   // Is old def now dead?  We successfully yanked a copy?
   return yank_if_dead(old,current_block,&value,&regnd);
 }
 //------------------------------skip_copies------------------------------------
 // Skip through any number of copies (that don't mod oop-i-ness)
 Node *PhaseChaitin::skip_copies( Node *c ) {
   int idx = c->is_Copy();
   uint is_oop = lrgs(n2lidx(c))._is_oop;
   while (idx != 0) {
     guarantee(c->in(idx) != NULL, "must not resurrect dead copy");
     if (lrgs(n2lidx(c->in(idx)))._is_oop != is_oop)
       break;  // casting copy, not the same value
     c = c->in(idx);
     idx = c->is_Copy();
   }
   return c;
 }
 //------------------------------elide_copy-------------------------------------
 // Remove (bypass) copies along Node n, edge k.
 int PhaseChaitin::elide_copy( Node *n, int k, Block *current_block, Node_List &value, Node_List &regnd, bool can_change_regs ) {
   int blk_adjust = 0;
   uint nk_idx = n2lidx(n->in(k));
   OptoReg::Name nk_reg = lrgs(nk_idx ).reg();
   // Remove obvious same-register copies
   Node *x = n->in(k);
   int idx;
   while( (idx=x->is_Copy()) != 0 ) {
     Node *copy = x->in(idx);
     guarantee(copy != NULL, "must not resurrect dead copy");
     if( lrgs(n2lidx(copy)).reg() != nk_reg ) break;
     blk_adjust += use_prior_register(n,k,copy,current_block,value,regnd);
     if( n->in(k) != copy ) break; // Failed for some cutout?
     x = copy;                   // Progress, try again
   }
   // Phis and 2-address instructions cannot change registers so easily - their
   // outputs must match their input.
   if( !can_change_regs )
     return blk_adjust;          // Only check stupid copies!
   // Loop backedges won't have a value-mapping yet
   if( &value == NULL ) return blk_adjust;
   // Skip through all copies to the _value_ being used.  Do not change from
   // int to pointer.  This attempts to jump through a chain of copies, where
   // intermediate copies might be illegal, i.e., value is stored down to stack
   // then reloaded BUT survives in a register the whole way.
   Node *val = skip_copies(n->in(k));
   if (val == x && nk_idx != 0 &&
       regnd[nk_reg] != NULL && regnd[nk_reg] != x &&
       n2lidx(x) == n2lidx(regnd[nk_reg])) {
     // When rematerialzing nodes and stretching lifetimes, the
     // allocator will reuse the original def for multidef LRG instead
     // of the current reaching def because it can't know it's safe to
     // do so.  After allocation completes if they are in the same LRG
     // then it should use the current reaching def instead.
     n->set_req(k, regnd[nk_reg]);
     blk_adjust += yank_if_dead(val, current_block, &value, &regnd);
     val = skip_copies(n->in(k));
   }
   if( val == x ) return blk_adjust; // No progress?
   bool single = is_single_register(val->ideal_reg());
   uint val_idx = n2lidx(val);
   OptoReg::Name val_reg = lrgs(val_idx).reg();
   // See if it happens to already be in the correct register!
   // (either Phi's direct register, or the common case of the name
   // never-clobbered original-def register)
   if( value[val_reg] == val &&
       // Doubles check both halves
       ( single || value[val_reg-1] == val ) ) {
     blk_adjust += use_prior_register(n,k,regnd[val_reg],current_block,value,regnd);
     if( n->in(k) == regnd[val_reg] ) // Success!  Quit trying
       return blk_adjust;
   }
   // See if we can skip the copy by changing registers.  Don't change from
   // using a register to using the stack unless we know we can remove a
   // copy-load.  Otherwise we might end up making a pile of Intel cisc-spill
   // ops reading from memory instead of just loading once and using the
   // register.
   // Also handle duplicate copies here.
   const Type *t = val->is_Con() ? val->bottom_type() : NULL;
   // Scan all registers to see if this value is around already
   for( uint reg = 0; reg < (uint)_max_reg; reg++ ) {
     if (reg == (uint)nk_reg) {
       // Found ourselves so check if there is only one user of this
       // copy and keep on searching for a better copy if so.
       bool ignore_self = true;
       x = n->in(k);
       DUIterator_Fast imax, i = x->fast_outs(imax);
       Node* first = x->fast_out(i); i++;
       while (i < imax && ignore_self) {
         Node* use = x->fast_out(i); i++;
         if (use != first) ignore_self = false;
       }
       if (ignore_self) continue;
     }
     Node *vv = value[reg];
     if( !single ) {             // Doubles check for aligned-adjacent pair
       if( (reg&1)==0 ) continue;  // Wrong half of a pair
       if( vv != value[reg-1] ) continue; // Not a complete pair
     }
     if( vv == val ||            // Got a direct hit?
         (t && vv && vv->bottom_type() == t && vv->is_Mach() &&
          vv->as_Mach()->rule() == val->as_Mach()->rule()) ) { // Or same constant?
       assert( !n->is_Phi(), "cannot change registers at a Phi so easily" );
       if( OptoReg::is_stack(nk_reg) || // CISC-loading from stack OR
           OptoReg::is_reg(reg) || // turning into a register use OR
           regnd[reg]->outcnt()==1 ) { // last use of a spill-load turns into a CISC use
         blk_adjust += use_prior_register(n,k,regnd[reg],current_block,value,regnd);
         if( n->in(k) == regnd[reg] ) // Success!  Quit trying
           return blk_adjust;
       } // End of if not degrading to a stack
     } // End of if found value in another register
   } // End of scan all machine registers
   return blk_adjust;
 }
 //
 // Check if nreg already contains the constant value val.  Normal copy
 // elimination doesn't doesn't work on constants because multiple
 // nodes can represent the same constant so the type and rule of the
 // MachNode must be checked to ensure equivalence.
 //
 bool PhaseChaitin::eliminate_copy_of_constant(Node* val, Node* n,
                                               Block *current_block,
                                               Node_List& value, Node_List& regnd,
                                               OptoReg::Name nreg, OptoReg::Name nreg2) {
   if (value[nreg] != val && val->is_Con() &&
       value[nreg] != NULL && value[nreg]->is_Con() &&
       (nreg2 == OptoReg::Bad || value[nreg] == value[nreg2]) &&
       value[nreg]->bottom_type() == val->bottom_type() &&
       value[nreg]->as_Mach()->rule() == val->as_Mach()->rule()) {
     // This code assumes that two MachNodes representing constants
     // which have the same rule and the same bottom type will produce
     // identical effects into a register.  This seems like it must be
     // objectively true unless there are hidden inputs to the nodes
     // but if that were to change this code would need to updated.
     // Since they are equivalent the second one if redundant and can
     // be removed.
     //
     // n will be replaced with the old value but n might have
     // kills projections associated with it so remove them now so that
     // yank_if_dead will be able to eliminate the copy once the uses
     // have been transferred to the old[value].
     for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) {
       Node* use = n->fast_out(i);
       if (use->is_Proj() && use->outcnt() == 0) {
         // Kill projections have no users and one input
         use->set_req(0, C->top());
         yank_if_dead(use, current_block, &value, &regnd);
         --i; --imax;
       }
     }
     _post_alloc++;
     return true;
   }
   return false;
 }
 //------------------------------post_allocate_copy_removal---------------------
 // Post-Allocation peephole copy removal.  We do this in 1 pass over the
 // basic blocks.  We maintain a mapping of registers to Nodes (an  array of
 // Nodes indexed by machine register or stack slot number).  NULL means that a
 // register is not mapped to any Node.  We can (want to have!) have several
 // registers map to the same Node.  We walk forward over the instructions
 // updating the mapping as we go.  At merge points we force a NULL if we have
 // to merge 2 different Nodes into the same register.  Phi functions will give
 // us a new Node if there is a proper value merging.  Since the blocks are
 // arranged in some RPO, we will visit all parent blocks before visiting any
 // successor blocks (except at loops).
 //
 // If we find a Copy we look to see if the Copy's source register is a stack
 // slot and that value has already been loaded into some machine register; if
 // so we use machine register directly.  This turns a Load into a reg-reg
 // Move.  We also look for reloads of identical constants.
 //
 // When we see a use from a reg-reg Copy, we will attempt to use the copy's
 // source directly and make the copy go dead.
 void PhaseChaitin::post_allocate_copy_removal() {
   NOT_PRODUCT( Compile::TracePhase t3("postAllocCopyRemoval", &_t_postAllocCopyRemoval, TimeCompiler); )
   ResourceMark rm;
   // Need a mapping from basic block Node_Lists.  We need a Node_List to
   // map from register number to value-producing Node.
   Node_List **blk2value = NEW_RESOURCE_ARRAY( Node_List *, _cfg._num_blocks+1);
   memset( blk2value, 0, sizeof(Node_List*)*(_cfg._num_blocks+1) );
   // Need a mapping from basic block Node_Lists.  We need a Node_List to
   // map from register number to register-defining Node.
   Node_List **blk2regnd = NEW_RESOURCE_ARRAY( Node_List *, _cfg._num_blocks+1);
   memset( blk2regnd, 0, sizeof(Node_List*)*(_cfg._num_blocks+1) );
   // We keep unused Node_Lists on a free_list to avoid wasting
   // memory.
   GrowableArray<Node_List*> free_list = GrowableArray<Node_List*>(16);
   // For all blocks
   for( uint i = 0; i < _cfg._num_blocks; i++ ) {
     uint j;
     Block *b = _cfg._blocks[i];
     // Count of Phis in block
     uint phi_dex;
     for( phi_dex = 1; phi_dex < b->_nodes.size(); phi_dex++ ) {
       Node *phi = b->_nodes[phi_dex];
       if( !phi->is_Phi() )
         break;
     }
     // If any predecessor has not been visited, we do not know the state
     // of registers at the start.  Check for this, while updating copies
     // along Phi input edges
     bool missing_some_inputs = false;
     Block *freed = NULL;
     for( j = 1; j < b->num_preds(); j++ ) {
       Block *pb = _cfg._bbs[b->pred(j)->_idx];
       // Remove copies along phi edges
       for( uint k=1; k<phi_dex; k++ )
         elide_copy( b->_nodes[k], j, b, *blk2value[pb->_pre_order], *blk2regnd[pb->_pre_order], false );
       if( blk2value[pb->_pre_order] ) { // Have a mapping on this edge?
         // See if this predecessor's mappings have been used by everybody
         // who wants them.  If so, free 'em.
         uint k;
         for( k=0; k<pb->_num_succs; k++ ) {
           Block *pbsucc = pb->_succs[k];
           if( !blk2value[pbsucc->_pre_order] && pbsucc != b )
             break;              // Found a future user
         }
         if( k >= pb->_num_succs ) { // No more uses, free!
           freed = pb;           // Record last block freed
           free_list.push(blk2value[pb->_pre_order]);
           free_list.push(blk2regnd[pb->_pre_order]);
         }
       } else {                  // This block has unvisited (loopback) inputs
         missing_some_inputs = true;
       }
     }
     // Extract Node_List mappings.  If 'freed' is non-zero, we just popped
     // 'freed's blocks off the list
     Node_List &regnd = *(free_list.is_empty() ? new Node_List() : free_list.pop());
     Node_List &value = *(free_list.is_empty() ? new Node_List() : free_list.pop());
     assert( !freed || blk2value[freed->_pre_order] == &value, "" );
     value.map(_max_reg,NULL);
     regnd.map(_max_reg,NULL);
     // Set mappings as OUR mappings
     blk2value[b->_pre_order] = &value;
     blk2regnd[b->_pre_order] = &regnd;
     // Initialize value & regnd for this block
     if( missing_some_inputs ) {
       // Some predecessor has not yet been visited; zap map to empty
       for( uint k = 0; k < (uint)_max_reg; k++ ) {
         value.map(k,NULL);
         regnd.map(k,NULL);
       }
     } else {
       if( !freed ) {            // Didn't get a freebie prior block
         // Must clone some data
         freed = _cfg._bbs[b->pred(1)->_idx];
         Node_List &f_value = *blk2value[freed->_pre_order];
         Node_List &f_regnd = *blk2regnd[freed->_pre_order];
         for( uint k = 0; k < (uint)_max_reg; k++ ) {
           value.map(k,f_value[k]);
           regnd.map(k,f_regnd[k]);
         }
       }
       // Merge all inputs together, setting to NULL any conflicts.
       for( j = 1; j < b->num_preds(); j++ ) {
         Block *pb = _cfg._bbs[b->pred(j)->_idx];
         if( pb == freed ) continue; // Did self already via freelist
         Node_List &p_regnd = *blk2regnd[pb->_pre_order];
         for( uint k = 0; k < (uint)_max_reg; k++ ) {
           if( regnd[k] != p_regnd[k] ) { // Conflict on reaching defs?
             value.map(k,NULL); // Then no value handy
             regnd.map(k,NULL);
           }
         }
       }
     }
     // For all Phi's
     for( j = 1; j < phi_dex; j++ ) {
       uint k;
       Node *phi = b->_nodes[j];
       uint pidx = n2lidx(phi);
       OptoReg::Name preg = lrgs(n2lidx(phi)).reg();
       // Remove copies remaining on edges.  Check for junk phi.
       Node *u = NULL;
       for( k=1; k<phi->req(); k++ ) {
         Node *x = phi->in(k);
         if( phi != x && u != x ) // Found a different input
           u = u ? NodeSentinel : x; // Capture unique input, or NodeSentinel for 2nd input
       }
       if( u != NodeSentinel ) {    // Junk Phi.  Remove
         b->_nodes.remove(j--); phi_dex--;
         _cfg._bbs.map(phi->_idx,NULL);
         phi->replace_by(u);
         phi->disconnect_inputs(NULL);
         continue;
       }
       // Note that if value[pidx] exists, then we merged no new values here
       // and the phi is useless.  This can happen even with the above phi
       // removal for complex flows.  I cannot keep the better known value here
       // because locally the phi appears to define a new merged value.  If I
       // keep the better value then a copy of the phi, being unable to use the
       // global flow analysis, can't "peek through" the phi to the original
       // reaching value and so will act like it's defining a new value.  This
       // can lead to situations where some uses are from the old and some from
       // the new values.  Not illegal by itself but throws the over-strong
       // assert in scheduling.
       if( pidx ) {
         value.map(preg,phi);
         regnd.map(preg,phi);
         OptoReg::Name preg_lo = OptoReg::add(preg,-1);
         if( !is_single_register(phi->ideal_reg()) ) {
           value.map(preg_lo,phi);
           regnd.map(preg_lo,phi);
         }
       }
     }
     // For all remaining instructions
     for( j = phi_dex; j < b->_nodes.size(); j++ ) {
       Node *n = b->_nodes[j];
       if( n->outcnt() == 0 &&   // Dead?
           n != C->top() &&      // (ignore TOP, it has no du info)
           !n->is_Proj() ) {     // fat-proj kills
         j -= yank_if_dead(n,b,&value,&regnd);
         continue;
       }
       // Improve reaching-def info.  Occasionally post-alloc's liveness gives
       // up (at loop backedges, because we aren't doing a full flow pass).
       // The presence of a live use essentially asserts that the use's def is
       // alive and well at the use (or else the allocator fubar'd).  Take
       // advantage of this info to set a reaching def for the use-reg.
       uint k;
       for( k = 1; k < n->req(); k++ ) {
         Node *def = n->in(k);   // n->in(k) is a USE; def is the DEF for this USE
         guarantee(def != NULL, "no disconnected nodes at this point");
         uint useidx = n2lidx(def); // useidx is the live range index for this USE
         if( useidx ) {
           OptoReg::Name ureg = lrgs(useidx).reg();
           if( !value[ureg] ) {
             int idx;            // Skip occasional useless copy
             while( (idx=def->is_Copy()) != 0 &&
                    def->in(idx) != NULL &&  // NULL should not happen
                    ureg == lrgs(n2lidx(def->in(idx))).reg() )
               def = def->in(idx);
             Node *valdef = skip_copies(def); // tighten up val through non-useless copies
             value.map(ureg,valdef); // record improved reaching-def info
             regnd.map(ureg,   def);
             // Record other half of doubles
             OptoReg::Name ureg_lo = OptoReg::add(ureg,-1);
             if( !is_single_register(def->ideal_reg()) &&
                 ( !RegMask::can_represent(ureg_lo) ||
                   lrgs(useidx).mask().Member(ureg_lo) ) && // Nearly always adjacent
                 !value[ureg_lo] ) {
               value.map(ureg_lo,valdef); // record improved reaching-def info
               regnd.map(ureg_lo,   def);
             }
           }
         }
       }
       const uint two_adr = n->is_Mach() ? n->as_Mach()->two_adr() : 0;
       // Remove copies along input edges
       for( k = 1; k < n->req(); k++ )
         j -= elide_copy( n, k, b, value, regnd, two_adr!=k );
       // Unallocated Nodes define no registers
       uint lidx = n2lidx(n);
       if( !lidx ) continue;
       // Update the register defined by this instruction
       OptoReg::Name nreg = lrgs(lidx).reg();
       // Skip through all copies to the _value_ being defined.
       // Do not change from int to pointer
       Node *val = skip_copies(n);
       // Clear out a dead definition before starting so that the
       // elimination code doesn't have to guard against it.  The
       // definition could in fact be a kill projection with a count of
       // 0 which is safe but since those are uninteresting for copy
       // elimination just delete them as well.
       if (regnd[nreg] != NULL && regnd[nreg]->outcnt() == 0) {
         regnd.map(nreg, NULL);
         value.map(nreg, NULL);
       }
       uint n_ideal_reg = n->ideal_reg();
       if( is_single_register(n_ideal_reg) ) {
         // If Node 'n' does not change the value mapped by the register,
         // then 'n' is a useless copy.  Do not update the register->node
         // mapping so 'n' will go dead.
         if( value[nreg] != val ) {
           if (eliminate_copy_of_constant(val, n, b, value, regnd, nreg, OptoReg::Bad)) {
             j -= replace_and_yank_if_dead(n, nreg, b, value, regnd);
           } else {
             // Update the mapping: record new Node defined by the register
             regnd.map(nreg,n);
             // Update mapping for defined *value*, which is the defined
             // Node after skipping all copies.
             value.map(nreg,val);
           }
         } else if( !may_be_copy_of_callee(n) ) {
           assert( n->is_Copy(), "" );
           j -= replace_and_yank_if_dead(n, nreg, b, value, regnd);
         }
       } else {
         // If the value occupies a register pair, record same info
         // in both registers.
         OptoReg::Name nreg_lo = OptoReg::add(nreg,-1);
         if( RegMask::can_represent(nreg_lo) &&     // Either a spill slot, or
             !lrgs(lidx).mask().Member(nreg_lo) ) { // Nearly always adjacent
           // Sparc occasionally has non-adjacent pairs.
           // Find the actual other value
           RegMask tmp = lrgs(lidx).mask();
           tmp.Remove(nreg);
           nreg_lo = tmp.find_first_elem();
         }
         if( value[nreg] != val || value[nreg_lo] != val ) {
           if (eliminate_copy_of_constant(val, n, b, value, regnd, nreg, nreg_lo)) {
             j -= replace_and_yank_if_dead(n, nreg, b, value, regnd);
           } else {
             regnd.map(nreg   , n );
             regnd.map(nreg_lo, n );
             value.map(nreg   ,val);
             value.map(nreg_lo,val);
           }
         } else if( !may_be_copy_of_callee(n) ) {
           assert( n->is_Copy(), "" );
           j -= replace_and_yank_if_dead(n, nreg, b, value, regnd);
         }
       }
       // Fat projections kill many registers
       if( n_ideal_reg == MachProjNode::fat_proj ) {
         RegMask rm = n->out_RegMask();
         // wow, what an expensive iterator...
         nreg = rm.find_first_elem();
         while( OptoReg::is_valid(nreg)) {
           rm.Remove(nreg);
           value.map(nreg,n);
           regnd.map(nreg,n);
           nreg = rm.find_first_elem();
         }
       }
     } // End of for all instructions in the block
   } // End for all blocks
 }

Mercurial > jdk8-mips64-public > hotspot / annotate

src/share/vm/opto/postaloc.cpp@83f08886981c (annotated)

src/share/vm/opto/postaloc.cpp