Mercurial > hg > openjdk > jdk9 > hotspot
view src/share/vm/opto/subnode.cpp @ 12815:f490955a6745
8173770: Image conversion improvements
Reviewed-by: kvn, vlivanov, dlong, rhalade, mschoene, iignatyev
| author | thartmann |
|---|---|
| date | Thu, 23 Mar 2017 15:14:18 +0100 |
| parents | b3bb54a37da0 |
| children |
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/* * Copyright (c) 1997, 2015, 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 "compiler/compileLog.hpp" #include "memory/allocation.inline.hpp" #include "opto/addnode.hpp" #include "opto/callnode.hpp" #include "opto/cfgnode.hpp" #include "opto/loopnode.hpp" #include "opto/matcher.hpp" #include "opto/movenode.hpp" #include "opto/mulnode.hpp" #include "opto/opcodes.hpp" #include "opto/phaseX.hpp" #include "opto/subnode.hpp" #include "runtime/sharedRuntime.hpp" // Portions of code courtesy of Clifford Click // Optimization - Graph Style #include "math.h" //============================================================================= //------------------------------Identity--------------------------------------- // If right input is a constant 0, return the left input. Node* SubNode::Identity(PhaseGVN* phase) { assert(in(1) != this, "Must already have called Value"); assert(in(2) != this, "Must already have called Value"); // Remove double negation const Type *zero = add_id(); if( phase->type( in(1) )->higher_equal( zero ) && in(2)->Opcode() == Opcode() && phase->type( in(2)->in(1) )->higher_equal( zero ) ) { return in(2)->in(2); } // Convert "(X+Y) - Y" into X and "(X+Y) - X" into Y if( in(1)->Opcode() == Op_AddI ) { if( phase->eqv(in(1)->in(2),in(2)) ) return in(1)->in(1); if (phase->eqv(in(1)->in(1),in(2))) return in(1)->in(2); // Also catch: "(X + Opaque2(Y)) - Y". In this case, 'Y' is a loop-varying // trip counter and X is likely to be loop-invariant (that's how O2 Nodes // are originally used, although the optimizer sometimes jiggers things). // This folding through an O2 removes a loop-exit use of a loop-varying // value and generally lowers register pressure in and around the loop. if( in(1)->in(2)->Opcode() == Op_Opaque2 && phase->eqv(in(1)->in(2)->in(1),in(2)) ) return in(1)->in(1); } return ( phase->type( in(2) )->higher_equal( zero ) ) ? in(1) : this; } //------------------------------Value------------------------------------------ // A subtract node differences it's two inputs. const Type* SubNode::Value_common(PhaseTransform *phase) const { const Node* in1 = in(1); const Node* in2 = in(2); // Either input is TOP ==> the result is TOP const Type* t1 = (in1 == this) ? Type::TOP : phase->type(in1); if( t1 == Type::TOP ) return Type::TOP; const Type* t2 = (in2 == this) ? Type::TOP : phase->type(in2); if( t2 == Type::TOP ) return Type::TOP; // Not correct for SubFnode and AddFNode (must check for infinity) // Equal? Subtract is zero if (in1->eqv_uncast(in2)) return add_id(); // Either input is BOTTOM ==> the result is the local BOTTOM if( t1 == Type::BOTTOM || t2 == Type::BOTTOM ) return bottom_type(); return NULL; } const Type* SubNode::Value(PhaseGVN* phase) const { const Type* t = Value_common(phase); if (t != NULL) { return t; } const Type* t1 = phase->type(in(1)); const Type* t2 = phase->type(in(2)); return sub(t1,t2); // Local flavor of type subtraction } //============================================================================= //------------------------------Helper function-------------------------------- static bool ok_to_convert(Node* inc, Node* iv) { // Do not collapse (x+c0)-y if "+" is a loop increment, because the // "-" is loop invariant and collapsing extends the live-range of "x" // to overlap with the "+", forcing another register to be used in // the loop. // This test will be clearer with '&&' (apply DeMorgan's rule) // but I like the early cutouts that happen here. const PhiNode *phi; if( ( !inc->in(1)->is_Phi() || !(phi=inc->in(1)->as_Phi()) || phi->is_copy() || !phi->region()->is_CountedLoop() || inc != phi->region()->as_CountedLoop()->incr() ) && // Do not collapse (x+c0)-iv if "iv" is a loop induction variable, // because "x" maybe invariant. ( !iv->is_loop_iv() ) ) { return true; } else { return false; } } //------------------------------Ideal------------------------------------------ Node *SubINode::Ideal(PhaseGVN *phase, bool can_reshape){ Node *in1 = in(1); Node *in2 = in(2); uint op1 = in1->Opcode(); uint op2 = in2->Opcode(); #ifdef ASSERT // Check for dead loop if( phase->eqv( in1, this ) || phase->eqv( in2, this ) || ( op1 == Op_AddI || op1 == Op_SubI ) && ( phase->eqv( in1->in(1), this ) || phase->eqv( in1->in(2), this ) || phase->eqv( in1->in(1), in1 ) || phase->eqv( in1->in(2), in1 ) ) ) assert(false, "dead loop in SubINode::Ideal"); #endif const Type *t2 = phase->type( in2 ); if( t2 == Type::TOP ) return NULL; // Convert "x-c0" into "x+ -c0". if( t2->base() == Type::Int ){ // Might be bottom or top... const TypeInt *i = t2->is_int(); if( i->is_con() ) return new AddINode(in1, phase->intcon(-i->get_con())); } // Convert "(x+c0) - y" into (x-y) + c0" // Do not collapse (x+c0)-y if "+" is a loop increment or // if "y" is a loop induction variable. if( op1 == Op_AddI && ok_to_convert(in1, in2) ) { const Type *tadd = phase->type( in1->in(2) ); if( tadd->singleton() && tadd != Type::TOP ) { Node *sub2 = phase->transform( new SubINode( in1->in(1), in2 )); return new AddINode( sub2, in1->in(2) ); } } // Convert "x - (y+c0)" into "(x-y) - c0" // Need the same check as in above optimization but reversed. if (op2 == Op_AddI && ok_to_convert(in2, in1)) { Node* in21 = in2->in(1); Node* in22 = in2->in(2); const TypeInt* tcon = phase->type(in22)->isa_int(); if (tcon != NULL && tcon->is_con()) { Node* sub2 = phase->transform( new SubINode(in1, in21) ); Node* neg_c0 = phase->intcon(- tcon->get_con()); return new AddINode(sub2, neg_c0); } } const Type *t1 = phase->type( in1 ); if( t1 == Type::TOP ) return NULL; #ifdef ASSERT // Check for dead loop if( ( op2 == Op_AddI || op2 == Op_SubI ) && ( phase->eqv( in2->in(1), this ) || phase->eqv( in2->in(2), this ) || phase->eqv( in2->in(1), in2 ) || phase->eqv( in2->in(2), in2 ) ) ) assert(false, "dead loop in SubINode::Ideal"); #endif // Convert "x - (x+y)" into "-y" if( op2 == Op_AddI && phase->eqv( in1, in2->in(1) ) ) return new SubINode( phase->intcon(0),in2->in(2)); // Convert "(x-y) - x" into "-y" if( op1 == Op_SubI && phase->eqv( in1->in(1), in2 ) ) return new SubINode( phase->intcon(0),in1->in(2)); // Convert "x - (y+x)" into "-y" if( op2 == Op_AddI && phase->eqv( in1, in2->in(2) ) ) return new SubINode( phase->intcon(0),in2->in(1)); // Convert "0 - (x-y)" into "y-x" if( t1 == TypeInt::ZERO && op2 == Op_SubI ) return new SubINode( in2->in(2), in2->in(1) ); // Convert "0 - (x+con)" into "-con-x" jint con; if( t1 == TypeInt::ZERO && op2 == Op_AddI && (con = in2->in(2)->find_int_con(0)) != 0 ) return new SubINode( phase->intcon(-con), in2->in(1) ); // Convert "(X+A) - (X+B)" into "A - B" if( op1 == Op_AddI && op2 == Op_AddI && in1->in(1) == in2->in(1) ) return new SubINode( in1->in(2), in2->in(2) ); // Convert "(A+X) - (B+X)" into "A - B" if( op1 == Op_AddI && op2 == Op_AddI && in1->in(2) == in2->in(2) ) return new SubINode( in1->in(1), in2->in(1) ); // Convert "(A+X) - (X+B)" into "A - B" if( op1 == Op_AddI && op2 == Op_AddI && in1->in(2) == in2->in(1) ) return new SubINode( in1->in(1), in2->in(2) ); // Convert "(X+A) - (B+X)" into "A - B" if( op1 == Op_AddI && op2 == Op_AddI && in1->in(1) == in2->in(2) ) return new SubINode( in1->in(2), in2->in(1) ); // Convert "A-(B-C)" into (A+C)-B", since add is commutative and generally // nicer to optimize than subtract. if( op2 == Op_SubI && in2->outcnt() == 1) { Node *add1 = phase->transform( new AddINode( in1, in2->in(2) ) ); return new SubINode( add1, in2->in(1) ); } return NULL; } //------------------------------sub-------------------------------------------- // A subtract node differences it's two inputs. const Type *SubINode::sub( const Type *t1, const Type *t2 ) const { const TypeInt *r0 = t1->is_int(); // Handy access const TypeInt *r1 = t2->is_int(); int32_t lo = java_subtract(r0->_lo, r1->_hi); int32_t hi = java_subtract(r0->_hi, r1->_lo); // We next check for 32-bit overflow. // If that happens, we just assume all integers are possible. if( (((r0->_lo ^ r1->_hi) >= 0) || // lo ends have same signs OR ((r0->_lo ^ lo) >= 0)) && // lo results have same signs AND (((r0->_hi ^ r1->_lo) >= 0) || // hi ends have same signs OR ((r0->_hi ^ hi) >= 0)) ) // hi results have same signs return TypeInt::make(lo,hi,MAX2(r0->_widen,r1->_widen)); else // Overflow; assume all integers return TypeInt::INT; } //============================================================================= //------------------------------Ideal------------------------------------------ Node *SubLNode::Ideal(PhaseGVN *phase, bool can_reshape) { Node *in1 = in(1); Node *in2 = in(2); uint op1 = in1->Opcode(); uint op2 = in2->Opcode(); #ifdef ASSERT // Check for dead loop if( phase->eqv( in1, this ) || phase->eqv( in2, this ) || ( op1 == Op_AddL || op1 == Op_SubL ) && ( phase->eqv( in1->in(1), this ) || phase->eqv( in1->in(2), this ) || phase->eqv( in1->in(1), in1 ) || phase->eqv( in1->in(2), in1 ) ) ) assert(false, "dead loop in SubLNode::Ideal"); #endif if( phase->type( in2 ) == Type::TOP ) return NULL; const TypeLong *i = phase->type( in2 )->isa_long(); // Convert "x-c0" into "x+ -c0". if( i && // Might be bottom or top... i->is_con() ) return new AddLNode(in1, phase->longcon(-i->get_con())); // Convert "(x+c0) - y" into (x-y) + c0" // Do not collapse (x+c0)-y if "+" is a loop increment or // if "y" is a loop induction variable. if( op1 == Op_AddL && ok_to_convert(in1, in2) ) { Node *in11 = in1->in(1); const Type *tadd = phase->type( in1->in(2) ); if( tadd->singleton() && tadd != Type::TOP ) { Node *sub2 = phase->transform( new SubLNode( in11, in2 )); return new AddLNode( sub2, in1->in(2) ); } } // Convert "x - (y+c0)" into "(x-y) - c0" // Need the same check as in above optimization but reversed. if (op2 == Op_AddL && ok_to_convert(in2, in1)) { Node* in21 = in2->in(1); Node* in22 = in2->in(2); const TypeLong* tcon = phase->type(in22)->isa_long(); if (tcon != NULL && tcon->is_con()) { Node* sub2 = phase->transform( new SubLNode(in1, in21) ); Node* neg_c0 = phase->longcon(- tcon->get_con()); return new AddLNode(sub2, neg_c0); } } const Type *t1 = phase->type( in1 ); if( t1 == Type::TOP ) return NULL; #ifdef ASSERT // Check for dead loop if( ( op2 == Op_AddL || op2 == Op_SubL ) && ( phase->eqv( in2->in(1), this ) || phase->eqv( in2->in(2), this ) || phase->eqv( in2->in(1), in2 ) || phase->eqv( in2->in(2), in2 ) ) ) assert(false, "dead loop in SubLNode::Ideal"); #endif // Convert "x - (x+y)" into "-y" if( op2 == Op_AddL && phase->eqv( in1, in2->in(1) ) ) return new SubLNode( phase->makecon(TypeLong::ZERO), in2->in(2)); // Convert "x - (y+x)" into "-y" if( op2 == Op_AddL && phase->eqv( in1, in2->in(2) ) ) return new SubLNode( phase->makecon(TypeLong::ZERO),in2->in(1)); // Convert "0 - (x-y)" into "y-x" if( phase->type( in1 ) == TypeLong::ZERO && op2 == Op_SubL ) return new SubLNode( in2->in(2), in2->in(1) ); // Convert "(X+A) - (X+B)" into "A - B" if( op1 == Op_AddL && op2 == Op_AddL && in1->in(1) == in2->in(1) ) return new SubLNode( in1->in(2), in2->in(2) ); // Convert "(A+X) - (B+X)" into "A - B" if( op1 == Op_AddL && op2 == Op_AddL && in1->in(2) == in2->in(2) ) return new SubLNode( in1->in(1), in2->in(1) ); // Convert "A-(B-C)" into (A+C)-B" if( op2 == Op_SubL && in2->outcnt() == 1) { Node *add1 = phase->transform( new AddLNode( in1, in2->in(2) ) ); return new SubLNode( add1, in2->in(1) ); } return NULL; } //------------------------------sub-------------------------------------------- // A subtract node differences it's two inputs. const Type *SubLNode::sub( const Type *t1, const Type *t2 ) const { const TypeLong *r0 = t1->is_long(); // Handy access const TypeLong *r1 = t2->is_long(); jlong lo = java_subtract(r0->_lo, r1->_hi); jlong hi = java_subtract(r0->_hi, r1->_lo); // We next check for 32-bit overflow. // If that happens, we just assume all integers are possible. if( (((r0->_lo ^ r1->_hi) >= 0) || // lo ends have same signs OR ((r0->_lo ^ lo) >= 0)) && // lo results have same signs AND (((r0->_hi ^ r1->_lo) >= 0) || // hi ends have same signs OR ((r0->_hi ^ hi) >= 0)) ) // hi results have same signs return TypeLong::make(lo,hi,MAX2(r0->_widen,r1->_widen)); else // Overflow; assume all integers return TypeLong::LONG; } //============================================================================= //------------------------------Value------------------------------------------ // A subtract node differences its two inputs. const Type* SubFPNode::Value(PhaseGVN* phase) const { const Node* in1 = in(1); const Node* in2 = in(2); // Either input is TOP ==> the result is TOP const Type* t1 = (in1 == this) ? Type::TOP : phase->type(in1); if( t1 == Type::TOP ) return Type::TOP; const Type* t2 = (in2 == this) ? Type::TOP : phase->type(in2); if( t2 == Type::TOP ) return Type::TOP; // if both operands are infinity of same sign, the result is NaN; do // not replace with zero if( (t1->is_finite() && t2->is_finite()) ) { if( phase->eqv(in1, in2) ) return add_id(); } // Either input is BOTTOM ==> the result is the local BOTTOM const Type *bot = bottom_type(); if( (t1 == bot) || (t2 == bot) || (t1 == Type::BOTTOM) || (t2 == Type::BOTTOM) ) return bot; return sub(t1,t2); // Local flavor of type subtraction } //============================================================================= //------------------------------Ideal------------------------------------------ Node *SubFNode::Ideal(PhaseGVN *phase, bool can_reshape) { const Type *t2 = phase->type( in(2) ); // Convert "x-c0" into "x+ -c0". if( t2->base() == Type::FloatCon ) { // Might be bottom or top... // return new (phase->C, 3) AddFNode(in(1), phase->makecon( TypeF::make(-t2->getf()) ) ); } // Not associative because of boundary conditions (infinity) if( IdealizedNumerics && !phase->C->method()->is_strict() ) { // Convert "x - (x+y)" into "-y" if( in(2)->is_Add() && phase->eqv(in(1),in(2)->in(1) ) ) return new SubFNode( phase->makecon(TypeF::ZERO),in(2)->in(2)); } // Cannot replace 0.0-X with -X because a 'fsub' bytecode computes // 0.0-0.0 as +0.0, while a 'fneg' bytecode computes -0.0. //if( phase->type(in(1)) == TypeF::ZERO ) //return new (phase->C, 2) NegFNode(in(2)); return NULL; } //------------------------------sub-------------------------------------------- // A subtract node differences its two inputs. const Type *SubFNode::sub( const Type *t1, const Type *t2 ) const { // no folding if one of operands is infinity or NaN, do not do constant folding if( g_isfinite(t1->getf()) && g_isfinite(t2->getf()) ) { return TypeF::make( t1->getf() - t2->getf() ); } else if( g_isnan(t1->getf()) ) { return t1; } else if( g_isnan(t2->getf()) ) { return t2; } else { return Type::FLOAT; } } //============================================================================= //------------------------------Ideal------------------------------------------ Node *SubDNode::Ideal(PhaseGVN *phase, bool can_reshape){ const Type *t2 = phase->type( in(2) ); // Convert "x-c0" into "x+ -c0". if( t2->base() == Type::DoubleCon ) { // Might be bottom or top... // return new (phase->C, 3) AddDNode(in(1), phase->makecon( TypeD::make(-t2->getd()) ) ); } // Not associative because of boundary conditions (infinity) if( IdealizedNumerics && !phase->C->method()->is_strict() ) { // Convert "x - (x+y)" into "-y" if( in(2)->is_Add() && phase->eqv(in(1),in(2)->in(1) ) ) return new SubDNode( phase->makecon(TypeD::ZERO),in(2)->in(2)); } // Cannot replace 0.0-X with -X because a 'dsub' bytecode computes // 0.0-0.0 as +0.0, while a 'dneg' bytecode computes -0.0. //if( phase->type(in(1)) == TypeD::ZERO ) //return new (phase->C, 2) NegDNode(in(2)); return NULL; } //------------------------------sub-------------------------------------------- // A subtract node differences its two inputs. const Type *SubDNode::sub( const Type *t1, const Type *t2 ) const { // no folding if one of operands is infinity or NaN, do not do constant folding if( g_isfinite(t1->getd()) && g_isfinite(t2->getd()) ) { return TypeD::make( t1->getd() - t2->getd() ); } else if( g_isnan(t1->getd()) ) { return t1; } else if( g_isnan(t2->getd()) ) { return t2; } else { return Type::DOUBLE; } } //============================================================================= //------------------------------Idealize--------------------------------------- // Unlike SubNodes, compare must still flatten return value to the // range -1, 0, 1. // And optimizations like those for (X + Y) - X fail if overflow happens. Node* CmpNode::Identity(PhaseGVN* phase) { return this; } #ifndef PRODUCT //----------------------------related------------------------------------------ // Related nodes of comparison nodes include all data inputs (until hitting a // control boundary) as well as all outputs until and including control nodes // as well as their projections. In compact mode, data inputs till depth 1 and // all outputs till depth 1 are considered. void CmpNode::related(GrowableArray<Node*> *in_rel, GrowableArray<Node*> *out_rel, bool compact) const { if (compact) { this->collect_nodes(in_rel, 1, false, true); this->collect_nodes(out_rel, -1, false, false); } else { this->collect_nodes_in_all_data(in_rel, false); this->collect_nodes_out_all_ctrl_boundary(out_rel); // Now, find all control nodes in out_rel, and include their projections // and projection targets (if any) in the result. GrowableArray<Node*> proj(Compile::current()->unique()); for (GrowableArrayIterator<Node*> it = out_rel->begin(); it != out_rel->end(); ++it) { Node* n = *it; if (n->is_CFG() && !n->is_Proj()) { // Assume projections and projection targets are found at levels 1 and 2. n->collect_nodes(&proj, -2, false, false); for (GrowableArrayIterator<Node*> p = proj.begin(); p != proj.end(); ++p) { out_rel->append_if_missing(*p); } proj.clear(); } } } } #endif //============================================================================= //------------------------------cmp-------------------------------------------- // Simplify a CmpI (compare 2 integers) node, based on local information. // If both inputs are constants, compare them. const Type *CmpINode::sub( const Type *t1, const Type *t2 ) const { const TypeInt *r0 = t1->is_int(); // Handy access const TypeInt *r1 = t2->is_int(); if( r0->_hi < r1->_lo ) // Range is always low? return TypeInt::CC_LT; else if( r0->_lo > r1->_hi ) // Range is always high? return TypeInt::CC_GT; else if( r0->is_con() && r1->is_con() ) { // comparing constants? assert(r0->get_con() == r1->get_con(), "must be equal"); return TypeInt::CC_EQ; // Equal results. } else if( r0->_hi == r1->_lo ) // Range is never high? return TypeInt::CC_LE; else if( r0->_lo == r1->_hi ) // Range is never low? return TypeInt::CC_GE; return TypeInt::CC; // else use worst case results } // Simplify a CmpU (compare 2 integers) node, based on local information. // If both inputs are constants, compare them. const Type *CmpUNode::sub( const Type *t1, const Type *t2 ) const { assert(!t1->isa_ptr(), "obsolete usage of CmpU"); // comparing two unsigned ints const TypeInt *r0 = t1->is_int(); // Handy access const TypeInt *r1 = t2->is_int(); // Current installed version // Compare ranges for non-overlap juint lo0 = r0->_lo; juint hi0 = r0->_hi; juint lo1 = r1->_lo; juint hi1 = r1->_hi; // If either one has both negative and positive values, // it therefore contains both 0 and -1, and since [0..-1] is the // full unsigned range, the type must act as an unsigned bottom. bool bot0 = ((jint)(lo0 ^ hi0) < 0); bool bot1 = ((jint)(lo1 ^ hi1) < 0); if (bot0 || bot1) { // All unsigned values are LE -1 and GE 0. if (lo0 == 0 && hi0 == 0) { return TypeInt::CC_LE; // 0 <= bot } else if ((jint)lo0 == -1 && (jint)hi0 == -1) { return TypeInt::CC_GE; // -1 >= bot } else if (lo1 == 0 && hi1 == 0) { return TypeInt::CC_GE; // bot >= 0 } else if ((jint)lo1 == -1 && (jint)hi1 == -1) { return TypeInt::CC_LE; // bot <= -1 } } else { // We can use ranges of the form [lo..hi] if signs are the same. assert(lo0 <= hi0 && lo1 <= hi1, "unsigned ranges are valid"); // results are reversed, '-' > '+' for unsigned compare if (hi0 < lo1) { return TypeInt::CC_LT; // smaller } else if (lo0 > hi1) { return TypeInt::CC_GT; // greater } else if (hi0 == lo1 && lo0 == hi1) { return TypeInt::CC_EQ; // Equal results } else if (lo0 >= hi1) { return TypeInt::CC_GE; } else if (hi0 <= lo1) { // Check for special case in Hashtable::get. (See below.) if ((jint)lo0 >= 0 && (jint)lo1 >= 0 && is_index_range_check()) return TypeInt::CC_LT; return TypeInt::CC_LE; } } // Check for special case in Hashtable::get - the hash index is // mod'ed to the table size so the following range check is useless. // Check for: (X Mod Y) CmpU Y, where the mod result and Y both have // to be positive. // (This is a gross hack, since the sub method never // looks at the structure of the node in any other case.) if ((jint)lo0 >= 0 && (jint)lo1 >= 0 && is_index_range_check()) return TypeInt::CC_LT; return TypeInt::CC; // else use worst case results } const Type* CmpUNode::Value(PhaseGVN* phase) const { const Type* t = SubNode::Value_common(phase); if (t != NULL) { return t; } const Node* in1 = in(1); const Node* in2 = in(2); const Type* t1 = phase->type(in1); const Type* t2 = phase->type(in2); assert(t1->isa_int(), "CmpU has only Int type inputs"); if (t2 == TypeInt::INT) { // Compare to bottom? return bottom_type(); } uint in1_op = in1->Opcode(); if (in1_op == Op_AddI || in1_op == Op_SubI) { // The problem rise when result of AddI(SubI) may overflow // signed integer value. Let say the input type is // [256, maxint] then +128 will create 2 ranges due to // overflow: [minint, minint+127] and [384, maxint]. // But C2 type system keep only 1 type range and as result // it use general [minint, maxint] for this case which we // can't optimize. // // Make 2 separate type ranges based on types of AddI(SubI) inputs // and compare results of their compare. If results are the same // CmpU node can be optimized. const Node* in11 = in1->in(1); const Node* in12 = in1->in(2); const Type* t11 = (in11 == in1) ? Type::TOP : phase->type(in11); const Type* t12 = (in12 == in1) ? Type::TOP : phase->type(in12); // Skip cases when input types are top or bottom. if ((t11 != Type::TOP) && (t11 != TypeInt::INT) && (t12 != Type::TOP) && (t12 != TypeInt::INT)) { const TypeInt *r0 = t11->is_int(); const TypeInt *r1 = t12->is_int(); jlong lo_r0 = r0->_lo; jlong hi_r0 = r0->_hi; jlong lo_r1 = r1->_lo; jlong hi_r1 = r1->_hi; if (in1_op == Op_SubI) { jlong tmp = hi_r1; hi_r1 = -lo_r1; lo_r1 = -tmp; // Note, for substructing [minint,x] type range // long arithmetic provides correct overflow answer. // The confusion come from the fact that in 32-bit // -minint == minint but in 64-bit -minint == maxint+1. } jlong lo_long = lo_r0 + lo_r1; jlong hi_long = hi_r0 + hi_r1; int lo_tr1 = min_jint; int hi_tr1 = (int)hi_long; int lo_tr2 = (int)lo_long; int hi_tr2 = max_jint; bool underflow = lo_long != (jlong)lo_tr2; bool overflow = hi_long != (jlong)hi_tr1; // Use sub(t1, t2) when there is no overflow (one type range) // or when both overflow and underflow (too complex). if ((underflow != overflow) && (hi_tr1 < lo_tr2)) { // Overflow only on one boundary, compare 2 separate type ranges. int w = MAX2(r0->_widen, r1->_widen); // _widen does not matter here const TypeInt* tr1 = TypeInt::make(lo_tr1, hi_tr1, w); const TypeInt* tr2 = TypeInt::make(lo_tr2, hi_tr2, w); const Type* cmp1 = sub(tr1, t2); const Type* cmp2 = sub(tr2, t2); if (cmp1 == cmp2) { return cmp1; // Hit! } } } } return sub(t1, t2); // Local flavor of type subtraction } bool CmpUNode::is_index_range_check() const { // Check for the "(X ModI Y) CmpU Y" shape return (in(1)->Opcode() == Op_ModI && in(1)->in(2)->eqv_uncast(in(2))); } //------------------------------Idealize--------------------------------------- Node *CmpINode::Ideal( PhaseGVN *phase, bool can_reshape ) { if (phase->type(in(2))->higher_equal(TypeInt::ZERO)) { switch (in(1)->Opcode()) { case Op_CmpL3: // Collapse a CmpL3/CmpI into a CmpL return new CmpLNode(in(1)->in(1),in(1)->in(2)); case Op_CmpF3: // Collapse a CmpF3/CmpI into a CmpF return new CmpFNode(in(1)->in(1),in(1)->in(2)); case Op_CmpD3: // Collapse a CmpD3/CmpI into a CmpD return new CmpDNode(in(1)->in(1),in(1)->in(2)); //case Op_SubI: // If (x - y) cannot overflow, then ((x - y) <?> 0) // can be turned into (x <?> y). // This is handled (with more general cases) by Ideal_sub_algebra. } } return NULL; // No change } //============================================================================= // Simplify a CmpL (compare 2 longs ) node, based on local information. // If both inputs are constants, compare them. const Type *CmpLNode::sub( const Type *t1, const Type *t2 ) const { const TypeLong *r0 = t1->is_long(); // Handy access const TypeLong *r1 = t2->is_long(); if( r0->_hi < r1->_lo ) // Range is always low? return TypeInt::CC_LT; else if( r0->_lo > r1->_hi ) // Range is always high? return TypeInt::CC_GT; else if( r0->is_con() && r1->is_con() ) { // comparing constants? assert(r0->get_con() == r1->get_con(), "must be equal"); return TypeInt::CC_EQ; // Equal results. } else if( r0->_hi == r1->_lo ) // Range is never high? return TypeInt::CC_LE; else if( r0->_lo == r1->_hi ) // Range is never low? return TypeInt::CC_GE; return TypeInt::CC; // else use worst case results } // Simplify a CmpUL (compare 2 unsigned longs) node, based on local information. // If both inputs are constants, compare them. const Type* CmpULNode::sub(const Type* t1, const Type* t2) const { assert(!t1->isa_ptr(), "obsolete usage of CmpUL"); // comparing two unsigned longs const TypeLong* r0 = t1->is_long(); // Handy access const TypeLong* r1 = t2->is_long(); // Current installed version // Compare ranges for non-overlap julong lo0 = r0->_lo; julong hi0 = r0->_hi; julong lo1 = r1->_lo; julong hi1 = r1->_hi; // If either one has both negative and positive values, // it therefore contains both 0 and -1, and since [0..-1] is the // full unsigned range, the type must act as an unsigned bottom. bool bot0 = ((jlong)(lo0 ^ hi0) < 0); bool bot1 = ((jlong)(lo1 ^ hi1) < 0); if (bot0 || bot1) { // All unsigned values are LE -1 and GE 0. if (lo0 == 0 && hi0 == 0) { return TypeInt::CC_LE; // 0 <= bot } else if ((jlong)lo0 == -1 && (jlong)hi0 == -1) { return TypeInt::CC_GE; // -1 >= bot } else if (lo1 == 0 && hi1 == 0) { return TypeInt::CC_GE; // bot >= 0 } else if ((jlong)lo1 == -1 && (jlong)hi1 == -1) { return TypeInt::CC_LE; // bot <= -1 } } else { // We can use ranges of the form [lo..hi] if signs are the same. assert(lo0 <= hi0 && lo1 <= hi1, "unsigned ranges are valid"); // results are reversed, '-' > '+' for unsigned compare if (hi0 < lo1) { return TypeInt::CC_LT; // smaller } else if (lo0 > hi1) { return TypeInt::CC_GT; // greater } else if (hi0 == lo1 && lo0 == hi1) { return TypeInt::CC_EQ; // Equal results } else if (lo0 >= hi1) { return TypeInt::CC_GE; } else if (hi0 <= lo1) { return TypeInt::CC_LE; } } return TypeInt::CC; // else use worst case results } //============================================================================= //------------------------------sub-------------------------------------------- // Simplify an CmpP (compare 2 pointers) node, based on local information. // If both inputs are constants, compare them. const Type *CmpPNode::sub( const Type *t1, const Type *t2 ) const { const TypePtr *r0 = t1->is_ptr(); // Handy access const TypePtr *r1 = t2->is_ptr(); // Undefined inputs makes for an undefined result if( TypePtr::above_centerline(r0->_ptr) || TypePtr::above_centerline(r1->_ptr) ) return Type::TOP; if (r0 == r1 && r0->singleton()) { // Equal pointer constants (klasses, nulls, etc.) return TypeInt::CC_EQ; } // See if it is 2 unrelated classes. const TypeOopPtr* p0 = r0->isa_oopptr(); const TypeOopPtr* p1 = r1->isa_oopptr(); if (p0 && p1) { Node* in1 = in(1)->uncast(); Node* in2 = in(2)->uncast(); AllocateNode* alloc1 = AllocateNode::Ideal_allocation(in1, NULL); AllocateNode* alloc2 = AllocateNode::Ideal_allocation(in2, NULL); if (MemNode::detect_ptr_independence(in1, alloc1, in2, alloc2, NULL)) { return TypeInt::CC_GT; // different pointers } ciKlass* klass0 = p0->klass(); bool xklass0 = p0->klass_is_exact(); ciKlass* klass1 = p1->klass(); bool xklass1 = p1->klass_is_exact(); int kps = (p0->isa_klassptr()?1:0) + (p1->isa_klassptr()?1:0); if (klass0 && klass1 && kps != 1 && // both or neither are klass pointers klass0->is_loaded() && !klass0->is_interface() && // do not trust interfaces klass1->is_loaded() && !klass1->is_interface() && (!klass0->is_obj_array_klass() || !klass0->as_obj_array_klass()->base_element_klass()->is_interface()) && (!klass1->is_obj_array_klass() || !klass1->as_obj_array_klass()->base_element_klass()->is_interface())) { bool unrelated_classes = false; // See if neither subclasses the other, or if the class on top // is precise. In either of these cases, the compare is known // to fail if at least one of the pointers is provably not null. if (klass0->equals(klass1)) { // if types are unequal but klasses are equal // Do nothing; we know nothing for imprecise types } else if (klass0->is_subtype_of(klass1)) { // If klass1's type is PRECISE, then classes are unrelated. unrelated_classes = xklass1; } else if (klass1->is_subtype_of(klass0)) { // If klass0's type is PRECISE, then classes are unrelated. unrelated_classes = xklass0; } else { // Neither subtypes the other unrelated_classes = true; } if (unrelated_classes) { // The oops classes are known to be unrelated. If the joined PTRs of // two oops is not Null and not Bottom, then we are sure that one // of the two oops is non-null, and the comparison will always fail. TypePtr::PTR jp = r0->join_ptr(r1->_ptr); if (jp != TypePtr::Null && jp != TypePtr::BotPTR) { return TypeInt::CC_GT; } } } } // Known constants can be compared exactly // Null can be distinguished from any NotNull pointers // Unknown inputs makes an unknown result if( r0->singleton() ) { intptr_t bits0 = r0->get_con(); if( r1->singleton() ) return bits0 == r1->get_con() ? TypeInt::CC_EQ : TypeInt::CC_GT; return ( r1->_ptr == TypePtr::NotNull && bits0==0 ) ? TypeInt::CC_GT : TypeInt::CC; } else if( r1->singleton() ) { intptr_t bits1 = r1->get_con(); return ( r0->_ptr == TypePtr::NotNull && bits1==0 ) ? TypeInt::CC_GT : TypeInt::CC; } else return TypeInt::CC; } static inline Node* isa_java_mirror_load(PhaseGVN* phase, Node* n) { // Return the klass node for // LoadP(AddP(foo:Klass, #java_mirror)) // or NULL if not matching. if (n->Opcode() != Op_LoadP) return NULL; const TypeInstPtr* tp = phase->type(n)->isa_instptr(); if (!tp || tp->klass() != phase->C->env()->Class_klass()) return NULL; Node* adr = n->in(MemNode::Address); intptr_t off = 0; Node* k = AddPNode::Ideal_base_and_offset(adr, phase, off); if (k == NULL) return NULL; const TypeKlassPtr* tkp = phase->type(k)->isa_klassptr(); if (!tkp || off != in_bytes(Klass::java_mirror_offset())) return NULL; // We've found the klass node of a Java mirror load. return k; } static inline Node* isa_const_java_mirror(PhaseGVN* phase, Node* n) { // for ConP(Foo.class) return ConP(Foo.klass) // otherwise return NULL if (!n->is_Con()) return NULL; const TypeInstPtr* tp = phase->type(n)->isa_instptr(); if (!tp) return NULL; ciType* mirror_type = tp->java_mirror_type(); // TypeInstPtr::java_mirror_type() returns non-NULL for compile- // time Class constants only. if (!mirror_type) return NULL; // x.getClass() == int.class can never be true (for all primitive types) // Return a ConP(NULL) node for this case. if (mirror_type->is_classless()) { return phase->makecon(TypePtr::NULL_PTR); } // return the ConP(Foo.klass) assert(mirror_type->is_klass(), "mirror_type should represent a Klass*"); return phase->makecon(TypeKlassPtr::make(mirror_type->as_klass())); } //------------------------------Ideal------------------------------------------ // Normalize comparisons between Java mirror loads to compare the klass instead. // // Also check for the case of comparing an unknown klass loaded from the primary // super-type array vs a known klass with no subtypes. This amounts to // checking to see an unknown klass subtypes a known klass with no subtypes; // this only happens on an exact match. We can shorten this test by 1 load. Node *CmpPNode::Ideal( PhaseGVN *phase, bool can_reshape ) { // Normalize comparisons between Java mirrors into comparisons of the low- // level klass, where a dependent load could be shortened. // // The new pattern has a nice effect of matching the same pattern used in the // fast path of instanceof/checkcast/Class.isInstance(), which allows // redundant exact type check be optimized away by GVN. // For example, in // if (x.getClass() == Foo.class) { // Foo foo = (Foo) x; // // ... use a ... // } // a CmpPNode could be shared between if_acmpne and checkcast { Node* k1 = isa_java_mirror_load(phase, in(1)); Node* k2 = isa_java_mirror_load(phase, in(2)); Node* conk2 = isa_const_java_mirror(phase, in(2)); if (k1 && (k2 || conk2)) { Node* lhs = k1; Node* rhs = (k2 != NULL) ? k2 : conk2; this->set_req(1, lhs); this->set_req(2, rhs); return this; } } // Constant pointer on right? const TypeKlassPtr* t2 = phase->type(in(2))->isa_klassptr(); if (t2 == NULL || !t2->klass_is_exact()) return NULL; // Get the constant klass we are comparing to. ciKlass* superklass = t2->klass(); // Now check for LoadKlass on left. Node* ldk1 = in(1); if (ldk1->is_DecodeNKlass()) { ldk1 = ldk1->in(1); if (ldk1->Opcode() != Op_LoadNKlass ) return NULL; } else if (ldk1->Opcode() != Op_LoadKlass ) return NULL; // Take apart the address of the LoadKlass: Node* adr1 = ldk1->in(MemNode::Address); intptr_t con2 = 0; Node* ldk2 = AddPNode::Ideal_base_and_offset(adr1, phase, con2); if (ldk2 == NULL) return NULL; if (con2 == oopDesc::klass_offset_in_bytes()) { // We are inspecting an object's concrete class. // Short-circuit the check if the query is abstract. if (superklass->is_interface() || superklass->is_abstract()) { // Make it come out always false: this->set_req(2, phase->makecon(TypePtr::NULL_PTR)); return this; } } // Check for a LoadKlass from primary supertype array. // Any nested loadklass from loadklass+con must be from the p.s. array. if (ldk2->is_DecodeNKlass()) { // Keep ldk2 as DecodeN since it could be used in CmpP below. if (ldk2->in(1)->Opcode() != Op_LoadNKlass ) return NULL; } else if (ldk2->Opcode() != Op_LoadKlass) return NULL; // Verify that we understand the situation if (con2 != (intptr_t) superklass->super_check_offset()) return NULL; // Might be element-klass loading from array klass // If 'superklass' has no subklasses and is not an interface, then we are // assured that the only input which will pass the type check is // 'superklass' itself. // // We could be more liberal here, and allow the optimization on interfaces // which have a single implementor. This would require us to increase the // expressiveness of the add_dependency() mechanism. // %%% Do this after we fix TypeOopPtr: Deps are expressive enough now. // Object arrays must have their base element have no subtypes while (superklass->is_obj_array_klass()) { ciType* elem = superklass->as_obj_array_klass()->element_type(); superklass = elem->as_klass(); } if (superklass->is_instance_klass()) { ciInstanceKlass* ik = superklass->as_instance_klass(); if (ik->has_subklass() || ik->is_interface()) return NULL; // Add a dependency if there is a chance that a subclass will be added later. if (!ik->is_final()) { phase->C->dependencies()->assert_leaf_type(ik); } } // Bypass the dependent load, and compare directly this->set_req(1,ldk2); return this; } //============================================================================= //------------------------------sub-------------------------------------------- // Simplify an CmpN (compare 2 pointers) node, based on local information. // If both inputs are constants, compare them. const Type *CmpNNode::sub( const Type *t1, const Type *t2 ) const { const TypePtr *r0 = t1->make_ptr(); // Handy access const TypePtr *r1 = t2->make_ptr(); // Undefined inputs makes for an undefined result if ((r0 == NULL) || (r1 == NULL) || TypePtr::above_centerline(r0->_ptr) || TypePtr::above_centerline(r1->_ptr)) { return Type::TOP; } if (r0 == r1 && r0->singleton()) { // Equal pointer constants (klasses, nulls, etc.) return TypeInt::CC_EQ; } // See if it is 2 unrelated classes. const TypeOopPtr* p0 = r0->isa_oopptr(); const TypeOopPtr* p1 = r1->isa_oopptr(); if (p0 && p1) { ciKlass* klass0 = p0->klass(); bool xklass0 = p0->klass_is_exact(); ciKlass* klass1 = p1->klass(); bool xklass1 = p1->klass_is_exact(); int kps = (p0->isa_klassptr()?1:0) + (p1->isa_klassptr()?1:0); if (klass0 && klass1 && kps != 1 && // both or neither are klass pointers !klass0->is_interface() && // do not trust interfaces !klass1->is_interface()) { bool unrelated_classes = false; // See if neither subclasses the other, or if the class on top // is precise. In either of these cases, the compare is known // to fail if at least one of the pointers is provably not null. if (klass0->equals(klass1)) { // if types are unequal but klasses are equal // Do nothing; we know nothing for imprecise types } else if (klass0->is_subtype_of(klass1)) { // If klass1's type is PRECISE, then classes are unrelated. unrelated_classes = xklass1; } else if (klass1->is_subtype_of(klass0)) { // If klass0's type is PRECISE, then classes are unrelated. unrelated_classes = xklass0; } else { // Neither subtypes the other unrelated_classes = true; } if (unrelated_classes) { // The oops classes are known to be unrelated. If the joined PTRs of // two oops is not Null and not Bottom, then we are sure that one // of the two oops is non-null, and the comparison will always fail. TypePtr::PTR jp = r0->join_ptr(r1->_ptr); if (jp != TypePtr::Null && jp != TypePtr::BotPTR) { return TypeInt::CC_GT; } } } } // Known constants can be compared exactly // Null can be distinguished from any NotNull pointers // Unknown inputs makes an unknown result if( r0->singleton() ) { intptr_t bits0 = r0->get_con(); if( r1->singleton() ) return bits0 == r1->get_con() ? TypeInt::CC_EQ : TypeInt::CC_GT; return ( r1->_ptr == TypePtr::NotNull && bits0==0 ) ? TypeInt::CC_GT : TypeInt::CC; } else if( r1->singleton() ) { intptr_t bits1 = r1->get_con(); return ( r0->_ptr == TypePtr::NotNull && bits1==0 ) ? TypeInt::CC_GT : TypeInt::CC; } else return TypeInt::CC; } //------------------------------Ideal------------------------------------------ Node *CmpNNode::Ideal( PhaseGVN *phase, bool can_reshape ) { return NULL; } //============================================================================= //------------------------------Value------------------------------------------ // Simplify an CmpF (compare 2 floats ) node, based on local information. // If both inputs are constants, compare them. const Type* CmpFNode::Value(PhaseGVN* phase) const { const Node* in1 = in(1); const Node* in2 = in(2); // Either input is TOP ==> the result is TOP const Type* t1 = (in1 == this) ? Type::TOP : phase->type(in1); if( t1 == Type::TOP ) return Type::TOP; const Type* t2 = (in2 == this) ? Type::TOP : phase->type(in2); if( t2 == Type::TOP ) return Type::TOP; // Not constants? Don't know squat - even if they are the same // value! If they are NaN's they compare to LT instead of EQ. const TypeF *tf1 = t1->isa_float_constant(); const TypeF *tf2 = t2->isa_float_constant(); if( !tf1 || !tf2 ) return TypeInt::CC; // This implements the Java bytecode fcmpl, so unordered returns -1. if( tf1->is_nan() || tf2->is_nan() ) return TypeInt::CC_LT; if( tf1->_f < tf2->_f ) return TypeInt::CC_LT; if( tf1->_f > tf2->_f ) return TypeInt::CC_GT; assert( tf1->_f == tf2->_f, "do not understand FP behavior" ); return TypeInt::CC_EQ; } //============================================================================= //------------------------------Value------------------------------------------ // Simplify an CmpD (compare 2 doubles ) node, based on local information. // If both inputs are constants, compare them. const Type* CmpDNode::Value(PhaseGVN* phase) const { const Node* in1 = in(1); const Node* in2 = in(2); // Either input is TOP ==> the result is TOP const Type* t1 = (in1 == this) ? Type::TOP : phase->type(in1); if( t1 == Type::TOP ) return Type::TOP; const Type* t2 = (in2 == this) ? Type::TOP : phase->type(in2); if( t2 == Type::TOP ) return Type::TOP; // Not constants? Don't know squat - even if they are the same // value! If they are NaN's they compare to LT instead of EQ. const TypeD *td1 = t1->isa_double_constant(); const TypeD *td2 = t2->isa_double_constant(); if( !td1 || !td2 ) return TypeInt::CC; // This implements the Java bytecode dcmpl, so unordered returns -1. if( td1->is_nan() || td2->is_nan() ) return TypeInt::CC_LT; if( td1->_d < td2->_d ) return TypeInt::CC_LT; if( td1->_d > td2->_d ) return TypeInt::CC_GT; assert( td1->_d == td2->_d, "do not understand FP behavior" ); return TypeInt::CC_EQ; } //------------------------------Ideal------------------------------------------ Node *CmpDNode::Ideal(PhaseGVN *phase, bool can_reshape){ // Check if we can change this to a CmpF and remove a ConvD2F operation. // Change (CMPD (F2D (float)) (ConD value)) // To (CMPF (float) (ConF value)) // Valid when 'value' does not lose precision as a float. // Benefits: eliminates conversion, does not require 24-bit mode // NaNs prevent commuting operands. This transform works regardless of the // order of ConD and ConvF2D inputs by preserving the original order. int idx_f2d = 1; // ConvF2D on left side? if( in(idx_f2d)->Opcode() != Op_ConvF2D ) idx_f2d = 2; // No, swap to check for reversed args int idx_con = 3-idx_f2d; // Check for the constant on other input if( ConvertCmpD2CmpF && in(idx_f2d)->Opcode() == Op_ConvF2D && in(idx_con)->Opcode() == Op_ConD ) { const TypeD *t2 = in(idx_con)->bottom_type()->is_double_constant(); double t2_value_as_double = t2->_d; float t2_value_as_float = (float)t2_value_as_double; if( t2_value_as_double == (double)t2_value_as_float ) { // Test value can be represented as a float // Eliminate the conversion to double and create new comparison Node *new_in1 = in(idx_f2d)->in(1); Node *new_in2 = phase->makecon( TypeF::make(t2_value_as_float) ); if( idx_f2d != 1 ) { // Must flip args to match original order Node *tmp = new_in1; new_in1 = new_in2; new_in2 = tmp; } CmpFNode *new_cmp = (Opcode() == Op_CmpD3) ? new CmpF3Node( new_in1, new_in2 ) : new CmpFNode ( new_in1, new_in2 ) ; return new_cmp; // Changed to CmpFNode } // Testing value required the precision of a double } return NULL; // No change } //============================================================================= //------------------------------cc2logical------------------------------------- // Convert a condition code type to a logical type const Type *BoolTest::cc2logical( const Type *CC ) const { if( CC == Type::TOP ) return Type::TOP; if( CC->base() != Type::Int ) return TypeInt::BOOL; // Bottom or worse const TypeInt *ti = CC->is_int(); if( ti->is_con() ) { // Only 1 kind of condition codes set? // Match low order 2 bits int tmp = ((ti->get_con()&3) == (_test&3)) ? 1 : 0; if( _test & 4 ) tmp = 1-tmp; // Optionally complement result return TypeInt::make(tmp); // Boolean result } if( CC == TypeInt::CC_GE ) { if( _test == ge ) return TypeInt::ONE; if( _test == lt ) return TypeInt::ZERO; } if( CC == TypeInt::CC_LE ) { if( _test == le ) return TypeInt::ONE; if( _test == gt ) return TypeInt::ZERO; } return TypeInt::BOOL; } //------------------------------dump_spec------------------------------------- // Print special per-node info void BoolTest::dump_on(outputStream *st) const { const char *msg[] = {"eq","gt","of","lt","ne","le","nof","ge"}; st->print("%s", msg[_test]); } //============================================================================= uint BoolNode::hash() const { return (Node::hash() << 3)|(_test._test+1); } uint BoolNode::size_of() const { return sizeof(BoolNode); } //------------------------------operator==------------------------------------- uint BoolNode::cmp( const Node &n ) const { const BoolNode *b = (const BoolNode *)&n; // Cast up return (_test._test == b->_test._test); } //-------------------------------make_predicate-------------------------------- Node* BoolNode::make_predicate(Node* test_value, PhaseGVN* phase) { if (test_value->is_Con()) return test_value; if (test_value->is_Bool()) return test_value; if (test_value->is_CMove() && test_value->in(CMoveNode::Condition)->is_Bool()) { BoolNode* bol = test_value->in(CMoveNode::Condition)->as_Bool(); const Type* ftype = phase->type(test_value->in(CMoveNode::IfFalse)); const Type* ttype = phase->type(test_value->in(CMoveNode::IfTrue)); if (ftype == TypeInt::ZERO && !TypeInt::ZERO->higher_equal(ttype)) { return bol; } else if (ttype == TypeInt::ZERO && !TypeInt::ZERO->higher_equal(ftype)) { return phase->transform( bol->negate(phase) ); } // Else fall through. The CMove gets in the way of the test. // It should be the case that make_predicate(bol->as_int_value()) == bol. } Node* cmp = new CmpINode(test_value, phase->intcon(0)); cmp = phase->transform(cmp); Node* bol = new BoolNode(cmp, BoolTest::ne); return phase->transform(bol); } //--------------------------------as_int_value--------------------------------- Node* BoolNode::as_int_value(PhaseGVN* phase) { // Inverse to make_predicate. The CMove probably boils down to a Conv2B. Node* cmov = CMoveNode::make(NULL, this, phase->intcon(0), phase->intcon(1), TypeInt::BOOL); return phase->transform(cmov); } //----------------------------------negate------------------------------------- BoolNode* BoolNode::negate(PhaseGVN* phase) { return new BoolNode(in(1), _test.negate()); } // Change "bool eq/ne (cmp (add/sub A B) C)" into false/true if add/sub // overflows and we can prove that C is not in the two resulting ranges. // This optimization is similar to the one performed by CmpUNode::Value(). Node* BoolNode::fold_cmpI(PhaseGVN* phase, SubNode* cmp, Node* cmp1, int cmp_op, int cmp1_op, const TypeInt* cmp2_type) { // Only optimize eq/ne integer comparison of add/sub if((_test._test == BoolTest::eq || _test._test == BoolTest::ne) && (cmp_op == Op_CmpI) && (cmp1_op == Op_AddI || cmp1_op == Op_SubI)) { // Skip cases were inputs of add/sub are not integers or of bottom type const TypeInt* r0 = phase->type(cmp1->in(1))->isa_int(); const TypeInt* r1 = phase->type(cmp1->in(2))->isa_int(); if ((r0 != NULL) && (r0 != TypeInt::INT) && (r1 != NULL) && (r1 != TypeInt::INT) && (cmp2_type != TypeInt::INT)) { // Compute exact (long) type range of add/sub result jlong lo_long = r0->_lo; jlong hi_long = r0->_hi; if (cmp1_op == Op_AddI) { lo_long += r1->_lo; hi_long += r1->_hi; } else { lo_long -= r1->_hi; hi_long -= r1->_lo; } // Check for over-/underflow by casting to integer int lo_int = (int)lo_long; int hi_int = (int)hi_long; bool underflow = lo_long != (jlong)lo_int; bool overflow = hi_long != (jlong)hi_int; if ((underflow != overflow) && (hi_int < lo_int)) { // Overflow on one boundary, compute resulting type ranges: // tr1 [MIN_INT, hi_int] and tr2 [lo_int, MAX_INT] int w = MAX2(r0->_widen, r1->_widen); // _widen does not matter here const TypeInt* tr1 = TypeInt::make(min_jint, hi_int, w); const TypeInt* tr2 = TypeInt::make(lo_int, max_jint, w); // Compare second input of cmp to both type ranges const Type* sub_tr1 = cmp->sub(tr1, cmp2_type); const Type* sub_tr2 = cmp->sub(tr2, cmp2_type); if (sub_tr1 == TypeInt::CC_LT && sub_tr2 == TypeInt::CC_GT) { // The result of the add/sub will never equal cmp2. Replace BoolNode // by false (0) if it tests for equality and by true (1) otherwise. return ConINode::make((_test._test == BoolTest::eq) ? 0 : 1); } } } } return NULL; } //------------------------------Ideal------------------------------------------ Node *BoolNode::Ideal(PhaseGVN *phase, bool can_reshape) { // Change "bool tst (cmp con x)" into "bool ~tst (cmp x con)". // This moves the constant to the right. Helps value-numbering. Node *cmp = in(1); if( !cmp->is_Sub() ) return NULL; int cop = cmp->Opcode(); if( cop == Op_FastLock || cop == Op_FastUnlock) return NULL; Node *cmp1 = cmp->in(1); Node *cmp2 = cmp->in(2); if( !cmp1 ) return NULL; if (_test._test == BoolTest::overflow || _test._test == BoolTest::no_overflow) { return NULL; } // Constant on left? Node *con = cmp1; uint op2 = cmp2->Opcode(); // Move constants to the right of compare's to canonicalize. // Do not muck with Opaque1 nodes, as this indicates a loop // guard that cannot change shape. if( con->is_Con() && !cmp2->is_Con() && op2 != Op_Opaque1 && // Because of NaN's, CmpD and CmpF are not commutative cop != Op_CmpD && cop != Op_CmpF && // Protect against swapping inputs to a compare when it is used by a // counted loop exit, which requires maintaining the loop-limit as in(2) !is_counted_loop_exit_test() ) { // Ok, commute the constant to the right of the cmp node. // Clone the Node, getting a new Node of the same class cmp = cmp->clone(); // Swap inputs to the clone cmp->swap_edges(1, 2); cmp = phase->transform( cmp ); return new BoolNode( cmp, _test.commute() ); } // Change "bool eq/ne (cmp (xor X 1) 0)" into "bool ne/eq (cmp X 0)". // The XOR-1 is an idiom used to flip the sense of a bool. We flip the // test instead. int cmp1_op = cmp1->Opcode(); const TypeInt* cmp2_type = phase->type(cmp2)->isa_int(); if (cmp2_type == NULL) return NULL; Node* j_xor = cmp1; if( cmp2_type == TypeInt::ZERO && cmp1_op == Op_XorI && j_xor->in(1) != j_xor && // An xor of itself is dead phase->type( j_xor->in(1) ) == TypeInt::BOOL && phase->type( j_xor->in(2) ) == TypeInt::ONE && (_test._test == BoolTest::eq || _test._test == BoolTest::ne) ) { Node *ncmp = phase->transform(new CmpINode(j_xor->in(1),cmp2)); return new BoolNode( ncmp, _test.negate() ); } // Change ((x & m) u<= m) or ((m & x) u<= m) to always true // Same with ((x & m) u< m+1) and ((m & x) u< m+1) if (cop == Op_CmpU && cmp1->Opcode() == Op_AndI) { Node* bound = NULL; if (_test._test == BoolTest::le) { bound = cmp2; } else if (_test._test == BoolTest::lt && cmp2->Opcode() == Op_AddI && cmp2->in(2)->find_int_con(0) == 1) { bound = cmp2->in(1); } if (cmp1->in(2) == bound || cmp1->in(1) == bound) { return ConINode::make(1); } } // Change ((x & (m - 1)) u< m) into (m > 0) // This is the off-by-one variant of the above if (cop == Op_CmpU && _test._test == BoolTest::lt && cmp1->Opcode() == Op_AndI) { Node* l = cmp1->in(1); Node* r = cmp1->in(2); for (int repeat = 0; repeat < 2; repeat++) { bool match = r->Opcode() == Op_AddI && r->in(2)->find_int_con(0) == -1 && r->in(1) == cmp2; if (match) { // arraylength known to be non-negative, so a (arraylength != 0) is sufficient, // but to be compatible with the array range check pattern, use (arraylength u> 0) Node* ncmp = cmp2->Opcode() == Op_LoadRange ? phase->transform(new CmpUNode(cmp2, phase->intcon(0))) : phase->transform(new CmpINode(cmp2, phase->intcon(0))); return new BoolNode(ncmp, BoolTest::gt); } else { // commute and try again l = cmp1->in(2); r = cmp1->in(1); } } } // Change (arraylength <= 0) or (arraylength == 0) // into (arraylength u<= 0) // Also change (arraylength != 0) into (arraylength u> 0) // The latter version matches the code pattern generated for // array range checks, which will more likely be optimized later. if (cop == Op_CmpI && cmp1->Opcode() == Op_LoadRange && cmp2->find_int_con(-1) == 0) { if (_test._test == BoolTest::le || _test._test == BoolTest::eq) { Node* ncmp = phase->transform(new CmpUNode(cmp1, cmp2)); return new BoolNode(ncmp, BoolTest::le); } else if (_test._test == BoolTest::ne) { Node* ncmp = phase->transform(new CmpUNode(cmp1, cmp2)); return new BoolNode(ncmp, BoolTest::gt); } } // Change "bool eq/ne (cmp (Conv2B X) 0)" into "bool eq/ne (cmp X 0)". // This is a standard idiom for branching on a boolean value. Node *c2b = cmp1; if( cmp2_type == TypeInt::ZERO && cmp1_op == Op_Conv2B && (_test._test == BoolTest::eq || _test._test == BoolTest::ne) ) { Node *ncmp = phase->transform(phase->type(c2b->in(1))->isa_int() ? (Node*)new CmpINode(c2b->in(1),cmp2) : (Node*)new CmpPNode(c2b->in(1),phase->makecon(TypePtr::NULL_PTR)) ); return new BoolNode( ncmp, _test._test ); } // Comparing a SubI against a zero is equal to comparing the SubI // arguments directly. This only works for eq and ne comparisons // due to possible integer overflow. if ((_test._test == BoolTest::eq || _test._test == BoolTest::ne) && (cop == Op_CmpI) && (cmp1->Opcode() == Op_SubI) && ( cmp2_type == TypeInt::ZERO ) ) { Node *ncmp = phase->transform( new CmpINode(cmp1->in(1),cmp1->in(2))); return new BoolNode( ncmp, _test._test ); } // Change (-A vs 0) into (A vs 0) by commuting the test. Disallow in the // most general case because negating 0x80000000 does nothing. Needed for // the CmpF3/SubI/CmpI idiom. if( cop == Op_CmpI && cmp1->Opcode() == Op_SubI && cmp2_type == TypeInt::ZERO && phase->type( cmp1->in(1) ) == TypeInt::ZERO && phase->type( cmp1->in(2) )->higher_equal(TypeInt::SYMINT) ) { Node *ncmp = phase->transform( new CmpINode(cmp1->in(2),cmp2)); return new BoolNode( ncmp, _test.commute() ); } // Try to optimize signed integer comparison return fold_cmpI(phase, cmp->as_Sub(), cmp1, cop, cmp1_op, cmp2_type); // The transformation below is not valid for either signed or unsigned // comparisons due to wraparound concerns at MAX_VALUE and MIN_VALUE. // This transformation can be resurrected when we are able to // make inferences about the range of values being subtracted from // (or added to) relative to the wraparound point. // // // Remove +/-1's if possible. // // "X <= Y-1" becomes "X < Y" // // "X+1 <= Y" becomes "X < Y" // // "X < Y+1" becomes "X <= Y" // // "X-1 < Y" becomes "X <= Y" // // Do not this to compares off of the counted-loop-end. These guys are // // checking the trip counter and they want to use the post-incremented // // counter. If they use the PRE-incremented counter, then the counter has // // to be incremented in a private block on a loop backedge. // if( du && du->cnt(this) && du->out(this)[0]->Opcode() == Op_CountedLoopEnd ) // return NULL; // #ifndef PRODUCT // // Do not do this in a wash GVN pass during verification. // // Gets triggered by too many simple optimizations to be bothered with // // re-trying it again and again. // if( !phase->allow_progress() ) return NULL; // #endif // // Not valid for unsigned compare because of corner cases in involving zero. // // For example, replacing "X-1 <u Y" with "X <=u Y" fails to throw an // // exception in case X is 0 (because 0-1 turns into 4billion unsigned but // // "0 <=u Y" is always true). // if( cmp->Opcode() == Op_CmpU ) return NULL; // int cmp2_op = cmp2->Opcode(); // if( _test._test == BoolTest::le ) { // if( cmp1_op == Op_AddI && // phase->type( cmp1->in(2) ) == TypeInt::ONE ) // return clone_cmp( cmp, cmp1->in(1), cmp2, phase, BoolTest::lt ); // else if( cmp2_op == Op_AddI && // phase->type( cmp2->in(2) ) == TypeInt::MINUS_1 ) // return clone_cmp( cmp, cmp1, cmp2->in(1), phase, BoolTest::lt ); // } else if( _test._test == BoolTest::lt ) { // if( cmp1_op == Op_AddI && // phase->type( cmp1->in(2) ) == TypeInt::MINUS_1 ) // return clone_cmp( cmp, cmp1->in(1), cmp2, phase, BoolTest::le ); // else if( cmp2_op == Op_AddI && // phase->type( cmp2->in(2) ) == TypeInt::ONE ) // return clone_cmp( cmp, cmp1, cmp2->in(1), phase, BoolTest::le ); // } } //------------------------------Value------------------------------------------ // Simplify a Bool (convert condition codes to boolean (1 or 0)) node, // based on local information. If the input is constant, do it. const Type* BoolNode::Value(PhaseGVN* phase) const { return _test.cc2logical( phase->type( in(1) ) ); } #ifndef PRODUCT //------------------------------dump_spec-------------------------------------- // Dump special per-node info void BoolNode::dump_spec(outputStream *st) const { st->print("["); _test.dump_on(st); st->print("]"); } //-------------------------------related--------------------------------------- // A BoolNode's related nodes are all of its data inputs, and all of its // outputs until control nodes are hit, which are included. In compact // representation, inputs till level 3 and immediate outputs are included. void BoolNode::related(GrowableArray<Node*> *in_rel, GrowableArray<Node*> *out_rel, bool compact) const { if (compact) { this->collect_nodes(in_rel, 3, false, true); this->collect_nodes(out_rel, -1, false, false); } else { this->collect_nodes_in_all_data(in_rel, false); this->collect_nodes_out_all_ctrl_boundary(out_rel); } } #endif //----------------------is_counted_loop_exit_test------------------------------ // Returns true if node is used by a counted loop node. bool BoolNode::is_counted_loop_exit_test() { for( DUIterator_Fast imax, i = fast_outs(imax); i < imax; i++ ) { Node* use = fast_out(i); if (use->is_CountedLoopEnd()) { return true; } } return false; } //============================================================================= //------------------------------Value------------------------------------------ // Compute sqrt const Type* SqrtDNode::Value(PhaseGVN* phase) const { const Type *t1 = phase->type( in(1) ); if( t1 == Type::TOP ) return Type::TOP; if( t1->base() != Type::DoubleCon ) return Type::DOUBLE; double d = t1->getd(); if( d < 0.0 ) return Type::DOUBLE; return TypeD::make( sqrt( d ) ); }