author | pliden |
Mon, 14 May 2018 15:42:59 +0200 | |
changeset 50102 | 454fa295105c |
parent 47216 | 71c04702a3d5 |
child 53244 | 9807daeb47c4 |
permissions | -rw-r--r-- |
1 | 1 |
/* |
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* Copyright (c) 2005, 2016, Oracle and/or its affiliates. All rights reserved. |
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. |
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* |
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* This code is free software; you can redistribute it and/or modify it |
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* under the terms of the GNU General Public License version 2 only, as |
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* published by the Free Software Foundation. |
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* |
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* This code is distributed in the hope that it will be useful, but WITHOUT |
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or |
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License |
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* version 2 for more details (a copy is included in the LICENSE file that |
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* accompanied this code). |
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* |
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* You should have received a copy of the GNU General Public License version |
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* 2 along with this work; if not, write to the Free Software Foundation, |
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* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. |
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* |
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* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
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* or visit www.oracle.com if you need additional information or have any |
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* questions. |
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* |
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*/ |
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#ifndef SHARE_VM_C1_C1_LINEARSCAN_HPP |
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#define SHARE_VM_C1_C1_LINEARSCAN_HPP |
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#include "c1/c1_FpuStackSim.hpp" |
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#include "c1/c1_FrameMap.hpp" |
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#include "c1/c1_IR.hpp" |
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#include "c1/c1_Instruction.hpp" |
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#include "c1/c1_LIR.hpp" |
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#include "c1/c1_LIRGenerator.hpp" |
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#include "utilities/align.hpp" |
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#include "utilities/macros.hpp" |
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class DebugInfoCache; |
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class FpuStackAllocator; |
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class IRScopeDebugInfo; |
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class Interval; |
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class IntervalWalker; |
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class LIRGenerator; |
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class LinearScan; |
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class MoveResolver; |
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class Range; |
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typedef GrowableArray<Interval*> IntervalArray; |
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typedef GrowableArray<Interval*> IntervalList; |
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typedef GrowableArray<IntervalList*> IntervalsList; |
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typedef GrowableArray<ScopeValue*> ScopeValueArray; |
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typedef GrowableArray<LIR_OpList*> LIR_OpListStack; |
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enum IntervalUseKind { |
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// priority of use kinds must be ascending |
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noUse = 0, |
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loopEndMarker = 1, |
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shouldHaveRegister = 2, |
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mustHaveRegister = 3, |
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firstValidKind = 1, |
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lastValidKind = 3 |
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}; |
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enum IntervalKind { |
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fixedKind = 0, // interval pre-colored by LIR_Generator |
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anyKind = 1, // no register/memory allocated by LIR_Generator |
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nofKinds, |
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firstKind = fixedKind |
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}; |
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// during linear scan an interval is in one of four states in |
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enum IntervalState { |
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unhandledState = 0, // unhandled state (not processed yet) |
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activeState = 1, // life and is in a physical register |
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inactiveState = 2, // in a life time hole and is in a physical register |
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handledState = 3, // spilled or not life again |
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invalidState = -1 |
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}; |
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enum IntervalSpillState { |
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noDefinitionFound, // starting state of calculation: no definition found yet |
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oneDefinitionFound, // one definition has already been found. |
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// Note: two consecutive definitions are treated as one (e.g. consecutive move and add because of two-operand LIR form) |
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// the position of this definition is stored in _definition_pos |
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oneMoveInserted, // one spill move has already been inserted. |
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storeAtDefinition, // the interval should be stored immediately after its definition because otherwise |
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// there would be multiple redundant stores |
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startInMemory, // the interval starts in memory (e.g. method parameter), so a store is never necessary |
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noOptimization // the interval has more then one definition (e.g. resulting from phi moves), so stores to memory are not optimized |
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}; |
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#define for_each_interval_kind(kind) \ |
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for (IntervalKind kind = firstKind; kind < nofKinds; kind = (IntervalKind)(kind + 1)) |
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#define for_each_visitor_mode(mode) \ |
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for (LIR_OpVisitState::OprMode mode = LIR_OpVisitState::firstMode; mode < LIR_OpVisitState::numModes; mode = (LIR_OpVisitState::OprMode)(mode + 1)) |
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class LinearScan : public CompilationResourceObj { |
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// declare classes used by LinearScan as friends because they |
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// need a wide variety of functions declared here |
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// |
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// Only the small interface to the rest of the compiler is public |
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friend class Interval; |
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friend class IntervalWalker; |
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friend class LinearScanWalker; |
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friend class FpuStackAllocator; |
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friend class MoveResolver; |
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friend class LinearScanStatistic; |
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friend class LinearScanTimers; |
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friend class RegisterVerifier; |
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public: |
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enum { |
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any_reg = -1, |
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nof_cpu_regs = pd_nof_cpu_regs_linearscan, |
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nof_fpu_regs = pd_nof_fpu_regs_linearscan, |
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nof_xmm_regs = pd_nof_xmm_regs_linearscan, |
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nof_regs = nof_cpu_regs + nof_fpu_regs + nof_xmm_regs |
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}; |
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private: |
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Compilation* _compilation; |
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IR* _ir; |
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LIRGenerator* _gen; |
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FrameMap* _frame_map; |
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BlockList _cached_blocks; // cached list with all blocks in linear-scan order (only correct if original list keeps unchanged) |
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int _num_virtual_regs; // number of virtual registers (without new registers introduced because of splitting intervals) |
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bool _has_fpu_registers; // true if this method uses any floating point registers (and so fpu stack allocation is necessary) |
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int _num_calls; // total number of calls in this method |
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int _max_spills; // number of stack slots used for intervals allocated to memory |
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int _unused_spill_slot; // unused spill slot for a single-word value because of alignment of a double-word value |
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IntervalList _intervals; // mapping from register number to interval |
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IntervalList* _new_intervals_from_allocation; // list with all intervals created during allocation when an existing interval is split |
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IntervalArray* _sorted_intervals; // intervals sorted by Interval::from() |
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bool _needs_full_resort; // set to true if an Interval::from() is changed and _sorted_intervals must be resorted |
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LIR_OpArray _lir_ops; // mapping from LIR_Op id to LIR_Op node |
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BlockBeginArray _block_of_op; // mapping from LIR_Op id to the BlockBegin containing this instruction |
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ResourceBitMap _has_info; // bit set for each LIR_Op id that has a CodeEmitInfo |
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ResourceBitMap _has_call; // bit set for each LIR_Op id that destroys all caller save registers |
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BitMap2D _interval_in_loop; // bit set for each virtual register that is contained in each loop |
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// cached debug info to prevent multiple creation of same object |
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// TODO: cached scope values for registers could be static |
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ScopeValueArray _scope_value_cache; |
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static ConstantOopWriteValue* _oop_null_scope_value; |
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static ConstantIntValue* _int_m1_scope_value; |
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static ConstantIntValue* _int_0_scope_value; |
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static ConstantIntValue* _int_1_scope_value; |
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static ConstantIntValue* _int_2_scope_value; |
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// accessors |
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IR* ir() const { return _ir; } |
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Compilation* compilation() const { return _compilation; } |
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LIRGenerator* gen() const { return _gen; } |
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FrameMap* frame_map() const { return _frame_map; } |
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// unified bailout support |
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void bailout(const char* msg) const { compilation()->bailout(msg); } |
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bool bailed_out() const { return compilation()->bailed_out(); } |
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// access to block list (sorted in linear scan order) |
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int block_count() const { assert(_cached_blocks.length() == ir()->linear_scan_order()->length(), "invalid cached block list"); return _cached_blocks.length(); } |
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BlockBegin* block_at(int idx) const { assert(_cached_blocks.at(idx) == ir()->linear_scan_order()->at(idx), "invalid cached block list"); return _cached_blocks.at(idx); } |
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int num_virtual_regs() const { return _num_virtual_regs; } |
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// size of live_in and live_out sets of BasicBlocks (BitMap needs rounded size for iteration) |
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int live_set_size() const { return align_up(_num_virtual_regs, BitsPerWord); } |
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bool has_fpu_registers() const { return _has_fpu_registers; } |
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int num_loops() const { return ir()->num_loops(); } |
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bool is_interval_in_loop(int interval, int loop) const { return _interval_in_loop.at(interval, loop); } |
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// handling of fpu stack allocation (platform dependent, needed for debug information generation) |
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#ifdef X86 |
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FpuStackAllocator* _fpu_stack_allocator; |
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bool use_fpu_stack_allocation() const { return UseSSE < 2 && has_fpu_registers(); } |
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#else |
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bool use_fpu_stack_allocation() const { return false; } |
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#endif |
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// access to interval list |
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int interval_count() const { return _intervals.length(); } |
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Interval* interval_at(int reg_num) const { return _intervals.at(reg_num); } |
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IntervalList* new_intervals_from_allocation() const { return _new_intervals_from_allocation; } |
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// access to LIR_Ops and Blocks indexed by op_id |
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int max_lir_op_id() const { assert(_lir_ops.length() > 0, "no operations"); return (_lir_ops.length() - 1) << 1; } |
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LIR_Op* lir_op_with_id(int op_id) const { assert(op_id >= 0 && op_id <= max_lir_op_id() && op_id % 2 == 0, "op_id out of range or not even"); return _lir_ops.at(op_id >> 1); } |
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BlockBegin* block_of_op_with_id(int op_id) const { assert(_block_of_op.length() > 0 && op_id >= 0 && op_id <= max_lir_op_id() + 1, "op_id out of range"); return _block_of_op.at(op_id >> 1); } |
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bool is_block_begin(int op_id) { return op_id == 0 || block_of_op_with_id(op_id) != block_of_op_with_id(op_id - 1); } |
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bool covers_block_begin(int op_id_1, int op_id_2) { return block_of_op_with_id(op_id_1) != block_of_op_with_id(op_id_2); } |
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bool has_call(int op_id) { assert(op_id % 2 == 0, "must be even"); return _has_call.at(op_id >> 1); } |
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bool has_info(int op_id) { assert(op_id % 2 == 0, "must be even"); return _has_info.at(op_id >> 1); } |
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// functions for converting LIR-Operands to register numbers |
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static bool is_valid_reg_num(int reg_num) { return reg_num >= 0; } |
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static int reg_num(LIR_Opr opr); |
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static int reg_numHi(LIR_Opr opr); |
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// functions for classification of intervals |
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static bool is_precolored_interval(const Interval* i); |
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static bool is_virtual_interval(const Interval* i); |
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static bool is_precolored_cpu_interval(const Interval* i); |
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static bool is_virtual_cpu_interval(const Interval* i); |
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static bool is_precolored_fpu_interval(const Interval* i); |
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static bool is_virtual_fpu_interval(const Interval* i); |
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static bool is_in_fpu_register(const Interval* i); |
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static bool is_oop_interval(const Interval* i); |
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// General helper functions |
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int allocate_spill_slot(bool double_word); |
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void assign_spill_slot(Interval* it); |
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void propagate_spill_slots(); |
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Interval* create_interval(int reg_num); |
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void append_interval(Interval* it); |
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void copy_register_flags(Interval* from, Interval* to); |
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// platform dependent functions |
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static bool is_processed_reg_num(int reg_num); |
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static int num_physical_regs(BasicType type); |
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static bool requires_adjacent_regs(BasicType type); |
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static bool is_caller_save(int assigned_reg); |
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// spill move optimization: eliminate moves from register to stack if |
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// stack slot is known to be correct |
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void change_spill_definition_pos(Interval* interval, int def_pos); |
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void change_spill_state(Interval* interval, int spill_pos); |
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static bool must_store_at_definition(const Interval* i); |
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void eliminate_spill_moves(); |
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// Phase 1: number all instructions in all blocks |
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void number_instructions(); |
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// Phase 2: compute local live sets separately for each block |
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// (sets live_gen and live_kill for each block) |
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// |
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// helper methods used by compute_local_live_sets() |
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void set_live_gen_kill(Value value, LIR_Op* op, BitMap& live_gen, BitMap& live_kill); |
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void compute_local_live_sets(); |
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// Phase 3: perform a backward dataflow analysis to compute global live sets |
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// (sets live_in and live_out for each block) |
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void compute_global_live_sets(); |
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// Phase 4: build intervals |
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// (fills the list _intervals) |
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// |
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// helper methods used by build_intervals() |
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void add_use (Value value, int from, int to, IntervalUseKind use_kind); |
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void add_def (LIR_Opr opr, int def_pos, IntervalUseKind use_kind); |
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void add_use (LIR_Opr opr, int from, int to, IntervalUseKind use_kind); |
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void add_temp(LIR_Opr opr, int temp_pos, IntervalUseKind use_kind); |
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void add_def (int reg_num, int def_pos, IntervalUseKind use_kind, BasicType type); |
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void add_use (int reg_num, int from, int to, IntervalUseKind use_kind, BasicType type); |
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void add_temp(int reg_num, int temp_pos, IntervalUseKind use_kind, BasicType type); |
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// Add platform dependent kills for particular LIR ops. Can be used |
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// to add platform dependent behaviour for some operations. |
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void pd_add_temps(LIR_Op* op); |
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IntervalUseKind use_kind_of_output_operand(LIR_Op* op, LIR_Opr opr); |
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IntervalUseKind use_kind_of_input_operand(LIR_Op* op, LIR_Opr opr); |
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void handle_method_arguments(LIR_Op* op); |
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void handle_doubleword_moves(LIR_Op* op); |
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void add_register_hints(LIR_Op* op); |
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void build_intervals(); |
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// Phase 5: actual register allocation |
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// (Uses LinearScanWalker) |
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// |
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// helper functions for building a sorted list of intervals |
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NOT_PRODUCT(bool is_sorted(IntervalArray* intervals);) |
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static int interval_cmp(Interval** a, Interval** b); |
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void add_to_list(Interval** first, Interval** prev, Interval* interval); |
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void create_unhandled_lists(Interval** list1, Interval** list2, bool (is_list1)(const Interval* i), bool (is_list2)(const Interval* i)); |
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void sort_intervals_before_allocation(); |
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void sort_intervals_after_allocation(); |
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void allocate_registers(); |
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// Phase 6: resolve data flow |
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// (insert moves at edges between blocks if intervals have been split) |
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// |
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// helper functions for resolve_data_flow() |
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Interval* split_child_at_op_id(Interval* interval, int op_id, LIR_OpVisitState::OprMode mode); |
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Interval* interval_at_block_begin(BlockBegin* block, int reg_num); |
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Interval* interval_at_block_end(BlockBegin* block, int reg_num); |
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Interval* interval_at_op_id(int reg_num, int op_id); |
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void resolve_collect_mappings(BlockBegin* from_block, BlockBegin* to_block, MoveResolver &move_resolver); |
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void resolve_find_insert_pos(BlockBegin* from_block, BlockBegin* to_block, MoveResolver &move_resolver); |
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void resolve_data_flow(); |
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void resolve_exception_entry(BlockBegin* block, int reg_num, MoveResolver &move_resolver); |
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void resolve_exception_entry(BlockBegin* block, MoveResolver &move_resolver); |
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void resolve_exception_edge(XHandler* handler, int throwing_op_id, int reg_num, Phi* phi, MoveResolver &move_resolver); |
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void resolve_exception_edge(XHandler* handler, int throwing_op_id, MoveResolver &move_resolver); |
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void resolve_exception_handlers(); |
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// Phase 7: assign register numbers back to LIR |
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// (includes computation of debug information and oop maps) |
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// |
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// helper functions for assign_reg_num() |
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VMReg vm_reg_for_interval(Interval* interval); |
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VMReg vm_reg_for_operand(LIR_Opr opr); |
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static LIR_Opr operand_for_interval(Interval* interval); |
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static LIR_Opr calc_operand_for_interval(const Interval* interval); |
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LIR_Opr canonical_spill_opr(Interval* interval); |
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LIR_Opr color_lir_opr(LIR_Opr opr, int id, LIR_OpVisitState::OprMode); |
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// methods used for oop map computation |
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IntervalWalker* init_compute_oop_maps(); |
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OopMap* compute_oop_map(IntervalWalker* iw, LIR_Op* op, CodeEmitInfo* info, bool is_call_site); |
|
338 |
void compute_oop_map(IntervalWalker* iw, const LIR_OpVisitState &visitor, LIR_Op* op); |
|
339 |
||
340 |
// methods used for debug information computation |
|
341 |
void init_compute_debug_info(); |
|
342 |
||
343 |
MonitorValue* location_for_monitor_index(int monitor_index); |
|
344 |
LocationValue* location_for_name(int name, Location::Type loc_type); |
|
10517
f92c9ff3a15f
7051798: SA-JDI: NPE in Frame.addressOfStackSlot(Frame.java:244)
never
parents:
8921
diff
changeset
|
345 |
void set_oop(OopMap* map, VMReg name) { |
f92c9ff3a15f
7051798: SA-JDI: NPE in Frame.addressOfStackSlot(Frame.java:244)
never
parents:
8921
diff
changeset
|
346 |
if (map->legal_vm_reg_name(name)) { |
f92c9ff3a15f
7051798: SA-JDI: NPE in Frame.addressOfStackSlot(Frame.java:244)
never
parents:
8921
diff
changeset
|
347 |
map->set_oop(name); |
f92c9ff3a15f
7051798: SA-JDI: NPE in Frame.addressOfStackSlot(Frame.java:244)
never
parents:
8921
diff
changeset
|
348 |
} else { |
f92c9ff3a15f
7051798: SA-JDI: NPE in Frame.addressOfStackSlot(Frame.java:244)
never
parents:
8921
diff
changeset
|
349 |
bailout("illegal oopMap register name"); |
f92c9ff3a15f
7051798: SA-JDI: NPE in Frame.addressOfStackSlot(Frame.java:244)
never
parents:
8921
diff
changeset
|
350 |
} |
f92c9ff3a15f
7051798: SA-JDI: NPE in Frame.addressOfStackSlot(Frame.java:244)
never
parents:
8921
diff
changeset
|
351 |
} |
1 | 352 |
|
353 |
int append_scope_value_for_constant(LIR_Opr opr, GrowableArray<ScopeValue*>* scope_values); |
|
354 |
int append_scope_value_for_operand(LIR_Opr opr, GrowableArray<ScopeValue*>* scope_values); |
|
355 |
int append_scope_value(int op_id, Value value, GrowableArray<ScopeValue*>* scope_values); |
|
356 |
||
6745 | 357 |
IRScopeDebugInfo* compute_debug_info_for_scope(int op_id, IRScope* cur_scope, ValueStack* cur_state, ValueStack* innermost_state); |
1 | 358 |
void compute_debug_info(CodeEmitInfo* info, int op_id); |
359 |
||
360 |
void assign_reg_num(LIR_OpList* instructions, IntervalWalker* iw); |
|
361 |
void assign_reg_num(); |
|
362 |
||
363 |
||
364 |
// Phase 8: fpu stack allocation |
|
365 |
// (Used only on x86 when fpu operands are present) |
|
366 |
void allocate_fpu_stack(); |
|
367 |
||
368 |
||
369 |
// helper functions for printing state |
|
370 |
#ifndef PRODUCT |
|
371 |
static void print_bitmap(BitMap& bitmap); |
|
372 |
void print_intervals(const char* label); |
|
373 |
void print_lir(int level, const char* label, bool hir_valid = true); |
|
374 |
#endif |
|
375 |
||
376 |
#ifdef ASSERT |
|
377 |
// verification functions for allocation |
|
378 |
// (check that all intervals have a correct register and that no registers are overwritten) |
|
379 |
void verify(); |
|
380 |
void verify_intervals(); |
|
381 |
void verify_no_oops_in_fixed_intervals(); |
|
382 |
void verify_constants(); |
|
383 |
void verify_registers(); |
|
384 |
#endif |
|
385 |
||
386 |
public: |
|
387 |
// creation |
|
388 |
LinearScan(IR* ir, LIRGenerator* gen, FrameMap* frame_map); |
|
389 |
||
390 |
// main entry function: perform linear scan register allocation |
|
391 |
void do_linear_scan(); |
|
392 |
||
393 |
// accessors used by Compilation |
|
394 |
int max_spills() const { return _max_spills; } |
|
395 |
int num_calls() const { assert(_num_calls >= 0, "not set"); return _num_calls; } |
|
396 |
||
397 |
// entry functions for printing |
|
398 |
#ifndef PRODUCT |
|
399 |
static void print_statistics(); |
|
400 |
static void print_timers(double total); |
|
401 |
#endif |
|
402 |
}; |
|
403 |
||
404 |
||
405 |
// Helper class for ordering moves that are inserted at the same position in the LIR |
|
406 |
// When moves between registers are inserted, it is important that the moves are |
|
407 |
// ordered such that no register is overwritten. So moves from register to stack |
|
408 |
// are processed prior to moves from stack to register. When moves have circular |
|
409 |
// dependencies, a temporary stack slot is used to break the circle. |
|
410 |
// The same logic is used in the LinearScanWalker and in LinearScan during resolve_data_flow |
|
411 |
// and therefore factored out in a separate class |
|
412 |
class MoveResolver: public StackObj { |
|
413 |
private: |
|
414 |
LinearScan* _allocator; |
|
415 |
||
416 |
LIR_List* _insert_list; |
|
417 |
int _insert_idx; |
|
418 |
LIR_InsertionBuffer _insertion_buffer; // buffer where moves are inserted |
|
419 |
||
420 |
IntervalList _mapping_from; |
|
421 |
LIR_OprList _mapping_from_opr; |
|
422 |
IntervalList _mapping_to; |
|
423 |
bool _multiple_reads_allowed; |
|
424 |
int _register_blocked[LinearScan::nof_regs]; |
|
425 |
||
426 |
int register_blocked(int reg) { assert(reg >= 0 && reg < LinearScan::nof_regs, "out of bounds"); return _register_blocked[reg]; } |
|
427 |
void set_register_blocked(int reg, int direction) { assert(reg >= 0 && reg < LinearScan::nof_regs, "out of bounds"); assert(direction == 1 || direction == -1, "out of bounds"); _register_blocked[reg] += direction; } |
|
428 |
||
429 |
void block_registers(Interval* it); |
|
430 |
void unblock_registers(Interval* it); |
|
431 |
bool save_to_process_move(Interval* from, Interval* to); |
|
432 |
||
433 |
void create_insertion_buffer(LIR_List* list); |
|
434 |
void append_insertion_buffer(); |
|
435 |
void insert_move(Interval* from_interval, Interval* to_interval); |
|
436 |
void insert_move(LIR_Opr from_opr, Interval* to_interval); |
|
437 |
||
438 |
DEBUG_ONLY(void verify_before_resolve();) |
|
439 |
void resolve_mappings(); |
|
440 |
public: |
|
441 |
MoveResolver(LinearScan* allocator); |
|
442 |
||
443 |
DEBUG_ONLY(void check_empty();) |
|
444 |
void set_multiple_reads_allowed() { _multiple_reads_allowed = true; } |
|
445 |
void set_insert_position(LIR_List* insert_list, int insert_idx); |
|
446 |
void move_insert_position(LIR_List* insert_list, int insert_idx); |
|
447 |
void add_mapping(Interval* from, Interval* to); |
|
448 |
void add_mapping(LIR_Opr from, Interval* to); |
|
449 |
void resolve_and_append_moves(); |
|
450 |
||
451 |
LinearScan* allocator() { return _allocator; } |
|
452 |
bool has_mappings() { return _mapping_from.length() > 0; } |
|
453 |
}; |
|
454 |
||
455 |
||
456 |
class Range : public CompilationResourceObj { |
|
457 |
friend class Interval; |
|
458 |
||
459 |
private: |
|
460 |
static Range* _end; // sentinel (from == to == max_jint) |
|
461 |
||
462 |
int _from; // from (inclusive) |
|
463 |
int _to; // to (exclusive) |
|
464 |
Range* _next; // linear list of Ranges |
|
465 |
||
466 |
// used only by class Interval, so hide them |
|
467 |
bool intersects(Range* r) const { return intersects_at(r) != -1; } |
|
468 |
int intersects_at(Range* r) const; |
|
469 |
||
470 |
public: |
|
471 |
Range(int from, int to, Range* next); |
|
472 |
||
5707 | 473 |
static void initialize(Arena* arena); |
1 | 474 |
static Range* end() { return _end; } |
475 |
||
476 |
int from() const { return _from; } |
|
477 |
int to() const { return _to; } |
|
478 |
Range* next() const { return _next; } |
|
479 |
void set_from(int from) { _from = from; } |
|
480 |
void set_to(int to) { _to = to; } |
|
481 |
void set_next(Range* next) { _next = next; } |
|
482 |
||
483 |
// for testing |
|
484 |
void print(outputStream* out = tty) const PRODUCT_RETURN; |
|
485 |
}; |
|
486 |
||
487 |
||
488 |
// Interval is an ordered list of disjoint ranges. |
|
489 |
||
490 |
// For pre-colored double word LIR_Oprs, one interval is created for |
|
491 |
// the low word register and one is created for the hi word register. |
|
492 |
// On Intel for FPU double registers only one interval is created. At |
|
493 |
// all times assigned_reg contains the reg. number of the physical |
|
494 |
// register. |
|
495 |
||
496 |
// For LIR_Opr in virtual registers a single interval can represent |
|
497 |
// single and double word values. When a physical register is |
|
498 |
// assigned to the interval, assigned_reg contains the |
|
499 |
// phys. reg. number and for double word values assigned_regHi the |
|
500 |
// phys. reg. number of the hi word if there is any. For spilled |
|
501 |
// intervals assigned_reg contains the stack index. assigned_regHi is |
|
502 |
// always -1. |
|
503 |
||
504 |
class Interval : public CompilationResourceObj { |
|
505 |
private: |
|
506 |
static Interval* _end; // sentinel (interval with only range Range::end()) |
|
507 |
||
508 |
int _reg_num; |
|
509 |
BasicType _type; // valid only for virtual registers |
|
510 |
Range* _first; // sorted list of Ranges |
|
511 |
intStack _use_pos_and_kinds; // sorted list of use-positions and their according use-kinds |
|
512 |
||
513 |
Range* _current; // interval iteration: the current Range |
|
514 |
Interval* _next; // interval iteration: sorted list of Intervals (ends with sentinel) |
|
515 |
IntervalState _state; // interval iteration: to which set belongs this interval |
|
516 |
||
517 |
||
518 |
int _assigned_reg; |
|
519 |
int _assigned_regHi; |
|
520 |
||
521 |
int _cached_to; // cached value: to of last range (-1: not cached) |
|
522 |
LIR_Opr _cached_opr; |
|
523 |
VMReg _cached_vm_reg; |
|
524 |
||
525 |
Interval* _split_parent; // the original interval where this interval is derived from |
|
526 |
IntervalList _split_children; // list of all intervals that are split off from this interval (only available for split parents) |
|
527 |
Interval* _current_split_child; // the current split child that has been active or inactive last (always stored in split parents) |
|
528 |
||
529 |
int _canonical_spill_slot; // the stack slot where all split parts of this interval are spilled to (always stored in split parents) |
|
530 |
bool _insert_move_when_activated; // true if move is inserted between _current_split_child and this interval when interval gets active the first time |
|
531 |
IntervalSpillState _spill_state; // for spill move optimization |
|
532 |
int _spill_definition_pos; // position where the interval is defined (if defined only once) |
|
533 |
Interval* _register_hint; // this interval should be in the same register as the hint interval |
|
534 |
||
535 |
int calc_to(); |
|
536 |
Interval* new_split_child(); |
|
537 |
public: |
|
538 |
Interval(int reg_num); |
|
539 |
||
5707 | 540 |
static void initialize(Arena* arena); |
1 | 541 |
static Interval* end() { return _end; } |
542 |
||
543 |
// accessors |
|
544 |
int reg_num() const { return _reg_num; } |
|
545 |
void set_reg_num(int r) { assert(_reg_num == -1, "cannot change reg_num"); _reg_num = r; } |
|
546 |
BasicType type() const { assert(_reg_num == -1 || _reg_num >= LIR_OprDesc::vreg_base, "cannot access type for fixed interval"); return _type; } |
|
547 |
void set_type(BasicType type) { assert(_reg_num < LIR_OprDesc::vreg_base || _type == T_ILLEGAL || _type == type, "overwriting existing type"); _type = type; } |
|
548 |
||
549 |
Range* first() const { return _first; } |
|
550 |
int from() const { return _first->from(); } |
|
551 |
int to() { if (_cached_to == -1) _cached_to = calc_to(); assert(_cached_to == calc_to(), "invalid cached value"); return _cached_to; } |
|
552 |
int num_use_positions() const { return _use_pos_and_kinds.length() / 2; } |
|
553 |
||
554 |
Interval* next() const { return _next; } |
|
555 |
Interval** next_addr() { return &_next; } |
|
556 |
void set_next(Interval* next) { _next = next; } |
|
557 |
||
558 |
int assigned_reg() const { return _assigned_reg; } |
|
559 |
int assigned_regHi() const { return _assigned_regHi; } |
|
560 |
void assign_reg(int reg) { _assigned_reg = reg; _assigned_regHi = LinearScan::any_reg; } |
|
561 |
void assign_reg(int reg,int regHi) { _assigned_reg = reg; _assigned_regHi = regHi; } |
|
562 |
||
563 |
Interval* register_hint(bool search_split_child = true) const; // calculation needed |
|
564 |
void set_register_hint(Interval* i) { _register_hint = i; } |
|
565 |
||
566 |
int state() const { return _state; } |
|
567 |
void set_state(IntervalState s) { _state = s; } |
|
568 |
||
569 |
// access to split parent and split children |
|
570 |
bool is_split_parent() const { return _split_parent == this; } |
|
571 |
bool is_split_child() const { return _split_parent != this; } |
|
572 |
Interval* split_parent() const { assert(_split_parent->is_split_parent(), "must be"); return _split_parent; } |
|
573 |
Interval* split_child_at_op_id(int op_id, LIR_OpVisitState::OprMode mode); |
|
574 |
Interval* split_child_before_op_id(int op_id); |
|
575 |
bool split_child_covers(int op_id, LIR_OpVisitState::OprMode mode); |
|
576 |
DEBUG_ONLY(void check_split_children();) |
|
577 |
||
578 |
// information stored in split parent, but available for all children |
|
579 |
int canonical_spill_slot() const { return split_parent()->_canonical_spill_slot; } |
|
580 |
void set_canonical_spill_slot(int slot) { assert(split_parent()->_canonical_spill_slot == -1, "overwriting existing value"); split_parent()->_canonical_spill_slot = slot; } |
|
581 |
Interval* current_split_child() const { return split_parent()->_current_split_child; } |
|
582 |
void make_current_split_child() { split_parent()->_current_split_child = this; } |
|
583 |
||
584 |
bool insert_move_when_activated() const { return _insert_move_when_activated; } |
|
585 |
void set_insert_move_when_activated(bool b) { _insert_move_when_activated = b; } |
|
586 |
||
587 |
// for spill optimization |
|
588 |
IntervalSpillState spill_state() const { return split_parent()->_spill_state; } |
|
589 |
int spill_definition_pos() const { return split_parent()->_spill_definition_pos; } |
|
590 |
void set_spill_state(IntervalSpillState state) { assert(state >= spill_state(), "state cannot decrease"); split_parent()->_spill_state = state; } |
|
591 |
void set_spill_definition_pos(int pos) { assert(spill_definition_pos() == -1, "cannot set the position twice"); split_parent()->_spill_definition_pos = pos; } |
|
592 |
// returns true if this interval has a shadow copy on the stack that is always correct |
|
593 |
bool always_in_memory() const { return split_parent()->_spill_state == storeAtDefinition || split_parent()->_spill_state == startInMemory; } |
|
594 |
||
595 |
// caching of values that take time to compute and are used multiple times |
|
596 |
LIR_Opr cached_opr() const { return _cached_opr; } |
|
597 |
VMReg cached_vm_reg() const { return _cached_vm_reg; } |
|
598 |
void set_cached_opr(LIR_Opr opr) { _cached_opr = opr; } |
|
599 |
void set_cached_vm_reg(VMReg reg) { _cached_vm_reg = reg; } |
|
600 |
||
601 |
// access to use positions |
|
602 |
int first_usage(IntervalUseKind min_use_kind) const; // id of the first operation requiring this interval in a register |
|
603 |
int next_usage(IntervalUseKind min_use_kind, int from) const; // id of next usage seen from the given position |
|
604 |
int next_usage_exact(IntervalUseKind exact_use_kind, int from) const; |
|
605 |
int previous_usage(IntervalUseKind min_use_kind, int from) const; |
|
606 |
||
607 |
// manipulating intervals |
|
608 |
void add_use_pos(int pos, IntervalUseKind use_kind); |
|
609 |
void add_range(int from, int to); |
|
610 |
Interval* split(int split_pos); |
|
611 |
Interval* split_from_start(int split_pos); |
|
38031
e0b822facc03
8149374: Replace C1-specific collection classes with universal collection classes
fzhinkin
parents:
36302
diff
changeset
|
612 |
void remove_first_use_pos() { _use_pos_and_kinds.trunc_to(_use_pos_and_kinds.length() - 2); } |
1 | 613 |
|
614 |
// test intersection |
|
615 |
bool covers(int op_id, LIR_OpVisitState::OprMode mode) const; |
|
616 |
bool has_hole_between(int from, int to); |
|
617 |
bool intersects(Interval* i) const { return _first->intersects(i->_first); } |
|
618 |
int intersects_at(Interval* i) const { return _first->intersects_at(i->_first); } |
|
619 |
||
620 |
// range iteration |
|
621 |
void rewind_range() { _current = _first; } |
|
622 |
void next_range() { assert(this != _end, "not allowed on sentinel"); _current = _current->next(); } |
|
623 |
int current_from() const { return _current->from(); } |
|
624 |
int current_to() const { return _current->to(); } |
|
625 |
bool current_at_end() const { return _current == Range::end(); } |
|
626 |
bool current_intersects(Interval* it) { return _current->intersects(it->_current); }; |
|
627 |
int current_intersects_at(Interval* it) { return _current->intersects_at(it->_current); }; |
|
628 |
||
629 |
// printing |
|
630 |
void print(outputStream* out = tty) const PRODUCT_RETURN; |
|
631 |
}; |
|
632 |
||
633 |
||
634 |
class IntervalWalker : public CompilationResourceObj { |
|
635 |
protected: |
|
636 |
Compilation* _compilation; |
|
637 |
LinearScan* _allocator; |
|
638 |
||
639 |
Interval* _unhandled_first[nofKinds]; // sorted list of intervals, not life before the current position |
|
640 |
Interval* _active_first [nofKinds]; // sorted list of intervals, life at the current position |
|
641 |
Interval* _inactive_first [nofKinds]; // sorted list of intervals, intervals in a life time hole at the current position |
|
642 |
||
643 |
Interval* _current; // the current interval coming from unhandled list |
|
644 |
int _current_position; // the current position (intercept point through the intervals) |
|
645 |
IntervalKind _current_kind; // and whether it is fixed_kind or any_kind. |
|
646 |
||
647 |
||
648 |
Compilation* compilation() const { return _compilation; } |
|
649 |
LinearScan* allocator() const { return _allocator; } |
|
650 |
||
651 |
// unified bailout support |
|
652 |
void bailout(const char* msg) const { compilation()->bailout(msg); } |
|
653 |
bool bailed_out() const { return compilation()->bailed_out(); } |
|
654 |
||
655 |
void check_bounds(IntervalKind kind) { assert(kind >= fixedKind && kind <= anyKind, "invalid interval_kind"); } |
|
656 |
||
657 |
Interval** unhandled_first_addr(IntervalKind kind) { check_bounds(kind); return &_unhandled_first[kind]; } |
|
658 |
Interval** active_first_addr(IntervalKind kind) { check_bounds(kind); return &_active_first[kind]; } |
|
659 |
Interval** inactive_first_addr(IntervalKind kind) { check_bounds(kind); return &_inactive_first[kind]; } |
|
660 |
||
661 |
void append_unsorted(Interval** first, Interval* interval); |
|
662 |
void append_sorted(Interval** first, Interval* interval); |
|
663 |
void append_to_unhandled(Interval** list, Interval* interval); |
|
664 |
||
665 |
bool remove_from_list(Interval** list, Interval* i); |
|
666 |
void remove_from_list(Interval* i); |
|
667 |
||
668 |
void next_interval(); |
|
669 |
Interval* current() const { return _current; } |
|
670 |
IntervalKind current_kind() const { return _current_kind; } |
|
671 |
||
672 |
void walk_to(IntervalState state, int from); |
|
673 |
||
674 |
// activate_current() is called when an unhandled interval becomes active (in current(), current_kind()). |
|
675 |
// Return false if current() should not be moved the the active interval list. |
|
676 |
// It is safe to append current to any interval list but the unhandled list. |
|
677 |
virtual bool activate_current() { return true; } |
|
678 |
||
679 |
// interval_moved() is called whenever an interval moves from one interval list to another. |
|
680 |
// In the implementation of this method it is prohibited to move the interval to any list. |
|
681 |
virtual void interval_moved(Interval* interval, IntervalKind kind, IntervalState from, IntervalState to); |
|
682 |
||
683 |
public: |
|
684 |
IntervalWalker(LinearScan* allocator, Interval* unhandled_fixed_first, Interval* unhandled_any_first); |
|
685 |
||
686 |
Interval* unhandled_first(IntervalKind kind) { check_bounds(kind); return _unhandled_first[kind]; } |
|
687 |
Interval* active_first(IntervalKind kind) { check_bounds(kind); return _active_first[kind]; } |
|
688 |
Interval* inactive_first(IntervalKind kind) { check_bounds(kind); return _inactive_first[kind]; } |
|
689 |
||
690 |
// active contains the intervals that are live after the lir_op |
|
691 |
void walk_to(int lir_op_id); |
|
692 |
// active contains the intervals that are live before the lir_op |
|
693 |
void walk_before(int lir_op_id) { walk_to(lir_op_id-1); } |
|
694 |
// walk through all intervals |
|
695 |
void walk() { walk_to(max_jint); } |
|
696 |
||
697 |
int current_position() { return _current_position; } |
|
698 |
}; |
|
699 |
||
700 |
||
701 |
// The actual linear scan register allocator |
|
702 |
class LinearScanWalker : public IntervalWalker { |
|
703 |
enum { |
|
704 |
any_reg = LinearScan::any_reg |
|
705 |
}; |
|
706 |
||
707 |
private: |
|
708 |
int _first_reg; // the reg. number of the first phys. register |
|
709 |
int _last_reg; // the reg. nmber of the last phys. register |
|
710 |
int _num_phys_regs; // required by current interval |
|
711 |
bool _adjacent_regs; // have lo/hi words of phys. regs be adjacent |
|
712 |
||
713 |
int _use_pos[LinearScan::nof_regs]; |
|
714 |
int _block_pos[LinearScan::nof_regs]; |
|
715 |
IntervalList* _spill_intervals[LinearScan::nof_regs]; |
|
716 |
||
717 |
MoveResolver _move_resolver; // for ordering spill moves |
|
718 |
||
719 |
// accessors mapped to same functions in class LinearScan |
|
720 |
int block_count() const { return allocator()->block_count(); } |
|
721 |
BlockBegin* block_at(int idx) const { return allocator()->block_at(idx); } |
|
722 |
BlockBegin* block_of_op_with_id(int op_id) const { return allocator()->block_of_op_with_id(op_id); } |
|
723 |
||
724 |
void init_use_lists(bool only_process_use_pos); |
|
725 |
void exclude_from_use(int reg); |
|
726 |
void exclude_from_use(Interval* i); |
|
727 |
void set_use_pos(int reg, Interval* i, int use_pos, bool only_process_use_pos); |
|
728 |
void set_use_pos(Interval* i, int use_pos, bool only_process_use_pos); |
|
729 |
void set_block_pos(int reg, Interval* i, int block_pos); |
|
730 |
void set_block_pos(Interval* i, int block_pos); |
|
731 |
||
732 |
void free_exclude_active_fixed(); |
|
733 |
void free_exclude_active_any(); |
|
734 |
void free_collect_inactive_fixed(Interval* cur); |
|
735 |
void free_collect_inactive_any(Interval* cur); |
|
736 |
void free_collect_unhandled(IntervalKind kind, Interval* cur); |
|
737 |
void spill_exclude_active_fixed(); |
|
738 |
void spill_block_unhandled_fixed(Interval* cur); |
|
739 |
void spill_block_inactive_fixed(Interval* cur); |
|
740 |
void spill_collect_active_any(); |
|
741 |
void spill_collect_inactive_any(Interval* cur); |
|
742 |
||
743 |
void insert_move(int op_id, Interval* src_it, Interval* dst_it); |
|
744 |
int find_optimal_split_pos(BlockBegin* min_block, BlockBegin* max_block, int max_split_pos); |
|
745 |
int find_optimal_split_pos(Interval* it, int min_split_pos, int max_split_pos, bool do_loop_optimization); |
|
746 |
void split_before_usage(Interval* it, int min_split_pos, int max_split_pos); |
|
747 |
void split_for_spilling(Interval* it); |
|
748 |
void split_stack_interval(Interval* it); |
|
749 |
void split_when_partial_register_available(Interval* it, int register_available_until); |
|
750 |
void split_and_spill_interval(Interval* it); |
|
751 |
||
752 |
int find_free_reg(int reg_needed_until, int interval_to, int hint_reg, int ignore_reg, bool* need_split); |
|
753 |
int find_free_double_reg(int reg_needed_until, int interval_to, int hint_reg, bool* need_split); |
|
754 |
bool alloc_free_reg(Interval* cur); |
|
755 |
||
756 |
int find_locked_reg(int reg_needed_until, int interval_to, int hint_reg, int ignore_reg, bool* need_split); |
|
757 |
int find_locked_double_reg(int reg_needed_until, int interval_to, int hint_reg, bool* need_split); |
|
758 |
void split_and_spill_intersecting_intervals(int reg, int regHi); |
|
759 |
void alloc_locked_reg(Interval* cur); |
|
760 |
||
761 |
bool no_allocation_possible(Interval* cur); |
|
762 |
void update_phys_reg_range(bool requires_cpu_register); |
|
763 |
void init_vars_for_alloc(Interval* cur); |
|
764 |
bool pd_init_regs_for_alloc(Interval* cur); |
|
765 |
||
766 |
void combine_spilled_intervals(Interval* cur); |
|
767 |
bool is_move(LIR_Op* op, Interval* from, Interval* to); |
|
768 |
||
769 |
bool activate_current(); |
|
770 |
||
771 |
public: |
|
772 |
LinearScanWalker(LinearScan* allocator, Interval* unhandled_fixed_first, Interval* unhandled_any_first); |
|
773 |
||
774 |
// must be called when all intervals are allocated |
|
775 |
void finish_allocation() { _move_resolver.resolve_and_append_moves(); } |
|
776 |
}; |
|
777 |
||
778 |
||
779 |
||
780 |
/* |
|
781 |
When a block has more than one predecessor, and all predecessors end with |
|
782 |
the same sequence of move-instructions, than this moves can be placed once |
|
783 |
at the beginning of the block instead of multiple times in the predecessors. |
|
784 |
||
785 |
Similarly, when a block has more than one successor, then equal sequences of |
|
786 |
moves at the beginning of the successors can be placed once at the end of |
|
787 |
the block. But because the moves must be inserted before all branch |
|
788 |
instructions, this works only when there is exactly one conditional branch |
|
789 |
at the end of the block (because the moves must be inserted before all |
|
790 |
branches, but after all compares). |
|
791 |
||
792 |
This optimization affects all kind of moves (reg->reg, reg->stack and |
|
793 |
stack->reg). Because this optimization works best when a block contains only |
|
794 |
few moves, it has a huge impact on the number of blocks that are totally |
|
795 |
empty. |
|
796 |
*/ |
|
797 |
class EdgeMoveOptimizer : public StackObj { |
|
798 |
private: |
|
799 |
// the class maintains a list with all lir-instruction-list of the |
|
800 |
// successors (predecessors) and the current index into the lir-lists |
|
801 |
LIR_OpListStack _edge_instructions; |
|
802 |
intStack _edge_instructions_idx; |
|
803 |
||
804 |
void init_instructions(); |
|
805 |
void append_instructions(LIR_OpList* instructions, int instructions_idx); |
|
806 |
LIR_Op* instruction_at(int edge); |
|
807 |
void remove_cur_instruction(int edge, bool decrement_index); |
|
808 |
||
809 |
bool operations_different(LIR_Op* op1, LIR_Op* op2); |
|
810 |
||
811 |
void optimize_moves_at_block_end(BlockBegin* cur); |
|
812 |
void optimize_moves_at_block_begin(BlockBegin* cur); |
|
813 |
||
814 |
EdgeMoveOptimizer(); |
|
815 |
||
816 |
public: |
|
817 |
static void optimize(BlockList* code); |
|
818 |
}; |
|
819 |
||
820 |
||
821 |
||
822 |
class ControlFlowOptimizer : public StackObj { |
|
823 |
private: |
|
824 |
BlockList _original_preds; |
|
825 |
||
826 |
enum { |
|
827 |
ShortLoopSize = 5 |
|
828 |
}; |
|
829 |
void reorder_short_loop(BlockList* code, BlockBegin* header_block, int header_idx); |
|
830 |
void reorder_short_loops(BlockList* code); |
|
831 |
||
832 |
bool can_delete_block(BlockBegin* cur); |
|
833 |
void substitute_branch_target(BlockBegin* cur, BlockBegin* target_from, BlockBegin* target_to); |
|
834 |
void delete_empty_blocks(BlockList* code); |
|
835 |
||
836 |
void delete_unnecessary_jumps(BlockList* code); |
|
837 |
void delete_jumps_to_return(BlockList* code); |
|
838 |
||
839 |
DEBUG_ONLY(void verify(BlockList* code);) |
|
840 |
||
841 |
ControlFlowOptimizer(); |
|
842 |
public: |
|
843 |
static void optimize(BlockList* code); |
|
844 |
}; |
|
845 |
||
846 |
||
847 |
#ifndef PRODUCT |
|
848 |
||
849 |
// Helper class for collecting statistics of LinearScan |
|
850 |
class LinearScanStatistic : public StackObj { |
|
851 |
public: |
|
852 |
enum Counter { |
|
853 |
// general counters |
|
854 |
counter_method, |
|
855 |
counter_fpu_method, |
|
856 |
counter_loop_method, |
|
857 |
counter_exception_method, |
|
858 |
counter_loop, |
|
859 |
counter_block, |
|
860 |
counter_loop_block, |
|
861 |
counter_exception_block, |
|
862 |
counter_interval, |
|
863 |
counter_fixed_interval, |
|
864 |
counter_range, |
|
865 |
counter_fixed_range, |
|
866 |
counter_use_pos, |
|
867 |
counter_fixed_use_pos, |
|
868 |
counter_spill_slots, |
|
869 |
blank_line_1, |
|
870 |
||
871 |
// counter for classes of lir instructions |
|
872 |
counter_instruction, |
|
873 |
counter_label, |
|
874 |
counter_entry, |
|
875 |
counter_return, |
|
876 |
counter_call, |
|
877 |
counter_move, |
|
878 |
counter_cmp, |
|
879 |
counter_cond_branch, |
|
880 |
counter_uncond_branch, |
|
881 |
counter_stub_branch, |
|
882 |
counter_alu, |
|
883 |
counter_alloc, |
|
884 |
counter_sync, |
|
885 |
counter_throw, |
|
886 |
counter_unwind, |
|
887 |
counter_typecheck, |
|
888 |
counter_fpu_stack, |
|
889 |
counter_misc_inst, |
|
890 |
counter_other_inst, |
|
891 |
blank_line_2, |
|
892 |
||
893 |
// counter for different types of moves |
|
894 |
counter_move_total, |
|
895 |
counter_move_reg_reg, |
|
896 |
counter_move_reg_stack, |
|
897 |
counter_move_stack_reg, |
|
898 |
counter_move_stack_stack, |
|
899 |
counter_move_reg_mem, |
|
900 |
counter_move_mem_reg, |
|
901 |
counter_move_const_any, |
|
902 |
||
903 |
number_of_counters, |
|
904 |
invalid_counter = -1 |
|
905 |
}; |
|
906 |
||
907 |
private: |
|
908 |
int _counters_sum[number_of_counters]; |
|
909 |
int _counters_max[number_of_counters]; |
|
910 |
||
911 |
void inc_counter(Counter idx, int value = 1) { _counters_sum[idx] += value; } |
|
912 |
||
913 |
const char* counter_name(int counter_idx); |
|
914 |
Counter base_counter(int counter_idx); |
|
915 |
||
916 |
void sum_up(LinearScanStatistic &method_statistic); |
|
917 |
void collect(LinearScan* allocator); |
|
918 |
||
919 |
public: |
|
920 |
LinearScanStatistic(); |
|
921 |
void print(const char* title); |
|
922 |
static void compute(LinearScan* allocator, LinearScanStatistic &global_statistic); |
|
923 |
}; |
|
924 |
||
925 |
||
926 |
// Helper class for collecting compilation time of LinearScan |
|
927 |
class LinearScanTimers : public StackObj { |
|
928 |
public: |
|
929 |
enum Timer { |
|
930 |
timer_do_nothing, |
|
931 |
timer_number_instructions, |
|
932 |
timer_compute_local_live_sets, |
|
933 |
timer_compute_global_live_sets, |
|
934 |
timer_build_intervals, |
|
935 |
timer_sort_intervals_before, |
|
936 |
timer_allocate_registers, |
|
937 |
timer_resolve_data_flow, |
|
938 |
timer_sort_intervals_after, |
|
939 |
timer_eliminate_spill_moves, |
|
940 |
timer_assign_reg_num, |
|
941 |
timer_allocate_fpu_stack, |
|
942 |
timer_optimize_lir, |
|
943 |
||
944 |
number_of_timers |
|
945 |
}; |
|
946 |
||
947 |
private: |
|
948 |
elapsedTimer _timers[number_of_timers]; |
|
949 |
const char* timer_name(int idx); |
|
950 |
||
951 |
public: |
|
952 |
LinearScanTimers(); |
|
953 |
||
954 |
void begin_method(); // called for each method when register allocation starts |
|
955 |
void end_method(LinearScan* allocator); // called for each method when register allocation completed |
|
956 |
void print(double total_time); // called before termination of VM to print global summary |
|
957 |
||
958 |
elapsedTimer* timer(int idx) { return &(_timers[idx]); } |
|
959 |
}; |
|
960 |
||
961 |
||
962 |
#endif // ifndef PRODUCT |
|
963 |
||
964 |
// Pick up platform-dependent implementation details |
|
40010 | 965 |
#include CPU_HEADER(c1_LinearScan) |
7397 | 966 |
|
967 |
#endif // SHARE_VM_C1_C1_LINEARSCAN_HPP |