8215555: TieredCompilation C2 threads can excessively block handshakes
Reviewed-by: kvn, neliasso, rehn
/*
* Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
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* 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.
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#ifndef SHARE_VM_OPTO_PARSE_HPP
#define SHARE_VM_OPTO_PARSE_HPP
#include "ci/ciMethodData.hpp"
#include "ci/ciTypeFlow.hpp"
#include "compiler/methodLiveness.hpp"
#include "libadt/vectset.hpp"
#include "oops/generateOopMap.hpp"
#include "opto/graphKit.hpp"
#include "opto/subnode.hpp"
class BytecodeParseHistogram;
class InlineTree;
class Parse;
class SwitchRange;
//------------------------------InlineTree-------------------------------------
class InlineTree : public ResourceObj {
friend class VMStructs;
Compile* C; // cache
JVMState* _caller_jvms; // state of caller
ciMethod* _method; // method being called by the caller_jvms
InlineTree* _caller_tree;
uint _count_inline_bcs; // Accumulated count of inlined bytecodes
// Call-site count / interpreter invocation count, scaled recursively.
// Always between 0.0 and 1.0. Represents the percentage of the method's
// total execution time used at this call site.
const float _site_invoke_ratio;
const int _max_inline_level; // the maximum inline level for this sub-tree (may be adjusted)
float compute_callee_frequency( int caller_bci ) const;
GrowableArray<InlineTree*> _subtrees;
void print_impl(outputStream* stj, int indent) const PRODUCT_RETURN;
const char* _msg;
protected:
InlineTree(Compile* C,
const InlineTree* caller_tree,
ciMethod* callee_method,
JVMState* caller_jvms,
int caller_bci,
float site_invoke_ratio,
int max_inline_level);
InlineTree *build_inline_tree_for_callee(ciMethod* callee_method,
JVMState* caller_jvms,
int caller_bci);
bool try_to_inline(ciMethod* callee_method,
ciMethod* caller_method,
int caller_bci,
JVMState* jvms,
ciCallProfile& profile,
WarmCallInfo* wci_result,
bool& should_delay);
bool should_inline(ciMethod* callee_method,
ciMethod* caller_method,
int caller_bci,
ciCallProfile& profile,
WarmCallInfo* wci_result);
bool should_not_inline(ciMethod* callee_method,
ciMethod* caller_method,
JVMState* jvms,
WarmCallInfo* wci_result);
void print_inlining(ciMethod* callee_method, int caller_bci,
ciMethod* caller_method, bool success) const;
InlineTree* caller_tree() const { return _caller_tree; }
InlineTree* callee_at(int bci, ciMethod* m) const;
int inline_level() const { return stack_depth(); }
int stack_depth() const { return _caller_jvms ? _caller_jvms->depth() : 0; }
const char* msg() const { return _msg; }
void set_msg(const char* msg) { _msg = msg; }
public:
static const char* check_can_parse(ciMethod* callee);
static InlineTree* build_inline_tree_root();
static InlineTree* find_subtree_from_root(InlineTree* root, JVMState* jvms, ciMethod* callee);
// For temporary (stack-allocated, stateless) ilts:
InlineTree(Compile* c, ciMethod* callee_method, JVMState* caller_jvms, float site_invoke_ratio, int max_inline_level);
// See if it is OK to inline.
// The receiver is the inline tree for the caller.
//
// The result is a temperature indication. If it is hot or cold,
// inlining is immediate or undesirable. Otherwise, the info block
// returned is newly allocated and may be enqueued.
//
// If the method is inlinable, a new inline subtree is created on the fly,
// and may be accessed by find_subtree_from_root.
// The call_method is the dest_method for a special or static invocation.
// The call_method is an optimized virtual method candidate otherwise.
WarmCallInfo* ok_to_inline(ciMethod *call_method, JVMState* caller_jvms, ciCallProfile& profile, WarmCallInfo* wci, bool& should_delay);
// Information about inlined method
JVMState* caller_jvms() const { return _caller_jvms; }
ciMethod *method() const { return _method; }
int caller_bci() const { return _caller_jvms ? _caller_jvms->bci() : InvocationEntryBci; }
uint count_inline_bcs() const { return _count_inline_bcs; }
float site_invoke_ratio() const { return _site_invoke_ratio; };
#ifndef PRODUCT
private:
uint _count_inlines; // Count of inlined methods
public:
// Debug information collected during parse
uint count_inlines() const { return _count_inlines; };
#endif
GrowableArray<InlineTree*> subtrees() { return _subtrees; }
void print_value_on(outputStream* st) const PRODUCT_RETURN;
bool _forced_inline; // Inlining was forced by CompilerOracle, ciReplay or annotation
bool forced_inline() const { return _forced_inline; }
// Count number of nodes in this subtree
int count() const;
// Dump inlining replay data to the stream.
void dump_replay_data(outputStream* out);
};
//-----------------------------------------------------------------------------
//------------------------------Parse------------------------------------------
// Parse bytecodes, build a Graph
class Parse : public GraphKit {
public:
// Per-block information needed by the parser:
class Block {
private:
ciTypeFlow::Block* _flow;
int _pred_count; // how many predecessors in CFG?
int _preds_parsed; // how many of these have been parsed?
uint _count; // how many times executed? Currently only set by _goto's
bool _is_parsed; // has this block been parsed yet?
bool _is_handler; // is this block an exception handler?
bool _has_merged_backedge; // does this block have merged backedge?
SafePointNode* _start_map; // all values flowing into this block
MethodLivenessResult _live_locals; // lazily initialized liveness bitmap
bool _has_predicates; // Were predicates added before parsing of the loop head?
int _num_successors; // Includes only normal control flow.
int _all_successors; // Include exception paths also.
Block** _successors;
public:
// Set up the block data structure itself.
Block(Parse* outer, int rpo);
// Set up the block's relations to other blocks.
void init_graph(Parse* outer);
ciTypeFlow::Block* flow() const { return _flow; }
int pred_count() const { return _pred_count; }
int preds_parsed() const { return _preds_parsed; }
bool is_parsed() const { return _is_parsed; }
bool is_handler() const { return _is_handler; }
void set_count( uint x ) { _count = x; }
uint count() const { return _count; }
SafePointNode* start_map() const { assert(is_merged(),""); return _start_map; }
void set_start_map(SafePointNode* m) { assert(!is_merged(), ""); _start_map = m; }
// True after any predecessor flows control into this block
bool is_merged() const { return _start_map != NULL; }
#ifdef ASSERT
// True after backedge predecessor flows control into this block
bool has_merged_backedge() const { return _has_merged_backedge; }
void mark_merged_backedge(Block* pred) {
assert(is_SEL_head(), "should be loop head");
if (pred != NULL && is_SEL_backedge(pred)) {
assert(is_parsed(), "block should be parsed before merging backedges");
_has_merged_backedge = true;
}
}
#endif
// True when all non-exception predecessors have been parsed.
bool is_ready() const { return preds_parsed() == pred_count(); }
bool has_predicates() const { return _has_predicates; }
void set_has_predicates() { _has_predicates = true; }
int num_successors() const { return _num_successors; }
int all_successors() const { return _all_successors; }
Block* successor_at(int i) const {
assert((uint)i < (uint)all_successors(), "");
return _successors[i];
}
Block* successor_for_bci(int bci);
int start() const { return flow()->start(); }
int limit() const { return flow()->limit(); }
int rpo() const { return flow()->rpo(); }
int start_sp() const { return flow()->stack_size(); }
bool is_loop_head() const { return flow()->is_loop_head(); }
bool is_SEL_head() const { return flow()->is_single_entry_loop_head(); }
bool is_SEL_backedge(Block* pred) const{ return is_SEL_head() && pred->rpo() >= rpo(); }
bool is_invariant_local(uint i) const {
const JVMState* jvms = start_map()->jvms();
if (!jvms->is_loc(i) || flow()->outer()->has_irreducible_entry()) return false;
return flow()->is_invariant_local(i - jvms->locoff());
}
bool can_elide_SEL_phi(uint i) const { assert(is_SEL_head(),""); return is_invariant_local(i); }
const Type* peek(int off=0) const { return stack_type_at(start_sp() - (off+1)); }
const Type* stack_type_at(int i) const;
const Type* local_type_at(int i) const;
static const Type* get_type(ciType* t) { return Type::get_typeflow_type(t); }
bool has_trap_at(int bci) const { return flow()->has_trap() && flow()->trap_bci() == bci; }
// Call this just before parsing a block.
void mark_parsed() {
assert(!_is_parsed, "must parse each block exactly once");
_is_parsed = true;
}
// Return the phi/region input index for the "current" pred,
// and bump the pred number. For historical reasons these index
// numbers are handed out in descending order. The last index is
// always PhiNode::Input (i.e., 1). The value returned is known
// as a "path number" because it distinguishes by which path we are
// entering the block.
int next_path_num() {
assert(preds_parsed() < pred_count(), "too many preds?");
return pred_count() - _preds_parsed++;
}
// Add a previously unaccounted predecessor to this block.
// This operates by increasing the size of the block's region
// and all its phi nodes (if any). The value returned is a
// path number ("pnum").
int add_new_path();
// Initialize me by recording the parser's map. My own map must be NULL.
void record_state(Parse* outer);
};
#ifndef PRODUCT
// BytecodeParseHistogram collects number of bytecodes parsed, nodes constructed, and transformations.
class BytecodeParseHistogram : public ResourceObj {
private:
enum BPHType {
BPH_transforms,
BPH_values
};
static bool _initialized;
static uint _bytecodes_parsed [Bytecodes::number_of_codes];
static uint _nodes_constructed[Bytecodes::number_of_codes];
static uint _nodes_transformed[Bytecodes::number_of_codes];
static uint _new_values [Bytecodes::number_of_codes];
Bytecodes::Code _initial_bytecode;
int _initial_node_count;
int _initial_transforms;
int _initial_values;
Parse *_parser;
Compile *_compiler;
// Initialization
static void reset();
// Return info being collected, select with global flag 'BytecodeParseInfo'
int current_count(BPHType info_selector);
public:
BytecodeParseHistogram(Parse *p, Compile *c);
static bool initialized();
// Record info when starting to parse one bytecode
void set_initial_state( Bytecodes::Code bc );
// Record results of parsing one bytecode
void record_change();
// Profile printing
static void print(float cutoff = 0.01F); // cutoff in percent
};
public:
// Record work done during parsing
BytecodeParseHistogram* _parse_histogram;
void set_parse_histogram(BytecodeParseHistogram *bph) { _parse_histogram = bph; }
BytecodeParseHistogram* parse_histogram() { return _parse_histogram; }
#endif
private:
friend class Block;
// Variables which characterize this compilation as a whole:
JVMState* _caller; // JVMS which carries incoming args & state.
float _expected_uses; // expected number of calls to this code
float _prof_factor; // discount applied to my profile counts
int _depth; // Inline tree depth, for debug printouts
const TypeFunc*_tf; // My kind of function type
int _entry_bci; // the osr bci or InvocationEntryBci
ciTypeFlow* _flow; // Results of previous flow pass.
Block* _blocks; // Array of basic-block structs.
int _block_count; // Number of elements in _blocks.
GraphKit _exits; // Record all normal returns and throws here.
bool _wrote_final; // Did we write a final field?
bool _wrote_volatile; // Did we write a volatile field?
bool _wrote_stable; // Did we write a @Stable field?
bool _wrote_fields; // Did we write any field?
bool _count_invocations; // update and test invocation counter
bool _method_data_update; // update method data oop
Node* _alloc_with_final; // An allocation node with final field
// Variables which track Java semantics during bytecode parsing:
Block* _block; // block currently getting parsed
ciBytecodeStream _iter; // stream of this method's bytecodes
const FastLockNode* _synch_lock; // FastLockNode for synchronized method
#ifndef PRODUCT
int _max_switch_depth; // Debugging SwitchRanges.
int _est_switch_depth; // Debugging SwitchRanges.
#endif
bool _first_return; // true if return is the first to be parsed
bool _replaced_nodes_for_exceptions; // needs processing of replaced nodes in exception paths?
uint _new_idx; // any node with _idx above were new during this parsing. Used to trim the replaced nodes list.
public:
// Constructor
Parse(JVMState* caller, ciMethod* parse_method, float expected_uses);
virtual Parse* is_Parse() const { return (Parse*)this; }
// Accessors.
JVMState* caller() const { return _caller; }
float expected_uses() const { return _expected_uses; }
float prof_factor() const { return _prof_factor; }
int depth() const { return _depth; }
const TypeFunc* tf() const { return _tf; }
// entry_bci() -- see osr_bci, etc.
ciTypeFlow* flow() const { return _flow; }
// blocks() -- see rpo_at, start_block, etc.
int block_count() const { return _block_count; }
GraphKit& exits() { return _exits; }
bool wrote_final() const { return _wrote_final; }
void set_wrote_final(bool z) { _wrote_final = z; }
bool wrote_volatile() const { return _wrote_volatile; }
void set_wrote_volatile(bool z) { _wrote_volatile = z; }
bool wrote_stable() const { return _wrote_stable; }
void set_wrote_stable(bool z) { _wrote_stable = z; }
bool wrote_fields() const { return _wrote_fields; }
void set_wrote_fields(bool z) { _wrote_fields = z; }
bool count_invocations() const { return _count_invocations; }
bool method_data_update() const { return _method_data_update; }
Node* alloc_with_final() const { return _alloc_with_final; }
void set_alloc_with_final(Node* n) {
assert((_alloc_with_final == NULL) || (_alloc_with_final == n), "different init objects?");
_alloc_with_final = n;
}
Block* block() const { return _block; }
ciBytecodeStream& iter() { return _iter; }
Bytecodes::Code bc() const { return _iter.cur_bc(); }
void set_block(Block* b) { _block = b; }
// Derived accessors:
bool is_normal_parse() const { return _entry_bci == InvocationEntryBci; }
bool is_osr_parse() const { return _entry_bci != InvocationEntryBci; }
int osr_bci() const { assert(is_osr_parse(),""); return _entry_bci; }
void set_parse_bci(int bci);
// Must this parse be aborted?
bool failing() { return C->failing(); }
Block* rpo_at(int rpo) {
assert(0 <= rpo && rpo < _block_count, "oob");
return &_blocks[rpo];
}
Block* start_block() {
return rpo_at(flow()->start_block()->rpo());
}
// Can return NULL if the flow pass did not complete a block.
Block* successor_for_bci(int bci) {
return block()->successor_for_bci(bci);
}
private:
// Create a JVMS & map for the initial state of this method.
SafePointNode* create_entry_map();
// OSR helpers
Node *fetch_interpreter_state(int index, BasicType bt, Node *local_addrs, Node *local_addrs_base);
Node* check_interpreter_type(Node* l, const Type* type, SafePointNode* &bad_type_exit);
void load_interpreter_state(Node* osr_buf);
// Functions for managing basic blocks:
void init_blocks();
void load_state_from(Block* b);
void store_state_to(Block* b) { b->record_state(this); }
// Parse all the basic blocks.
void do_all_blocks();
// Parse the current basic block
void do_one_block();
// Raise an error if we get a bad ciTypeFlow CFG.
void handle_missing_successor(int bci);
// first actions (before BCI 0)
void do_method_entry();
// implementation of monitorenter/monitorexit
void do_monitor_enter();
void do_monitor_exit();
// Eagerly create phie throughout the state, to cope with back edges.
void ensure_phis_everywhere();
// Merge the current mapping into the basic block starting at bci
void merge( int target_bci);
// Same as plain merge, except that it allocates a new path number.
void merge_new_path( int target_bci);
// Merge the current mapping into an exception handler.
void merge_exception(int target_bci);
// Helper: Merge the current mapping into the given basic block
void merge_common(Block* target, int pnum);
// Helper functions for merging individual cells.
PhiNode *ensure_phi( int idx, bool nocreate = false);
PhiNode *ensure_memory_phi(int idx, bool nocreate = false);
// Helper to merge the current memory state into the given basic block
void merge_memory_edges(MergeMemNode* n, int pnum, bool nophi);
// Parse this bytecode, and alter the Parsers JVM->Node mapping
void do_one_bytecode();
// helper function to generate array store check
void array_store_check();
// Helper function to generate array load
void array_load(BasicType etype);
// Helper function to generate array store
void array_store(BasicType etype);
// Helper function to compute array addressing
Node* array_addressing(BasicType type, int vals, const Type* *result2=NULL);
void rtm_deopt();
// Pass current map to exits
void return_current(Node* value);
// Register finalizers on return from Object.<init>
void call_register_finalizer();
// Insert a compiler safepoint into the graph
void add_safepoint();
// Insert a compiler safepoint into the graph, if there is a back-branch.
void maybe_add_safepoint(int target_bci) {
if (UseLoopSafepoints && target_bci <= bci()) {
add_safepoint();
}
}
// Note: Intrinsic generation routines may be found in library_call.cpp.
// Helper function to setup Ideal Call nodes
void do_call();
// Helper function to uncommon-trap or bailout for non-compilable call-sites
bool can_not_compile_call_site(ciMethod *dest_method, ciInstanceKlass *klass);
// Helper function to setup for type-profile based inlining
bool prepare_type_profile_inline(ciInstanceKlass* prof_klass, ciMethod* prof_method);
// Helper functions for type checking bytecodes:
void do_checkcast();
void do_instanceof();
// Helper functions for shifting & arithmetic
void modf();
void modd();
void l2f();
void do_irem();
// implementation of _get* and _put* bytecodes
void do_getstatic() { do_field_access(true, false); }
void do_getfield () { do_field_access(true, true); }
void do_putstatic() { do_field_access(false, false); }
void do_putfield () { do_field_access(false, true); }
// common code for making initial checks and forming addresses
void do_field_access(bool is_get, bool is_field);
bool static_field_ok_in_clinit(ciField *field, ciMethod *method);
// common code for actually performing the load or store
void do_get_xxx(Node* obj, ciField* field, bool is_field);
void do_put_xxx(Node* obj, ciField* field, bool is_field);
// implementation of object creation bytecodes
void emit_guard_for_new(ciInstanceKlass* klass);
void do_new();
void do_newarray(BasicType elemtype);
void do_anewarray();
void do_multianewarray();
Node* expand_multianewarray(ciArrayKlass* array_klass, Node* *lengths, int ndimensions, int nargs);
// implementation of jsr/ret
void do_jsr();
void do_ret();
float dynamic_branch_prediction(float &cnt, BoolTest::mask btest, Node* test);
float branch_prediction(float &cnt, BoolTest::mask btest, int target_bci, Node* test);
bool seems_never_taken(float prob) const;
bool path_is_suitable_for_uncommon_trap(float prob) const;
bool seems_stable_comparison() const;
void do_ifnull(BoolTest::mask btest, Node* c);
void do_if(BoolTest::mask btest, Node* c);
int repush_if_args();
void adjust_map_after_if(BoolTest::mask btest, Node* c, float prob,
Block* path, Block* other_path);
void sharpen_type_after_if(BoolTest::mask btest,
Node* con, const Type* tcon,
Node* val, const Type* tval);
void maybe_add_predicate_after_if(Block* path);
IfNode* jump_if_fork_int(Node* a, Node* b, BoolTest::mask mask, float prob, float cnt);
Node* jump_if_join(Node* iffalse, Node* iftrue);
void jump_if_true_fork(IfNode *ifNode, int dest_bci_if_true, int prof_table_index, bool unc);
void jump_if_false_fork(IfNode *ifNode, int dest_bci_if_false, int prof_table_index, bool unc);
void jump_if_always_fork(int dest_bci_if_true, int prof_table_index, bool unc);
friend class SwitchRange;
void do_tableswitch();
void do_lookupswitch();
void jump_switch_ranges(Node* a, SwitchRange* lo, SwitchRange* hi, int depth = 0);
bool create_jump_tables(Node* a, SwitchRange* lo, SwitchRange* hi);
void linear_search_switch_ranges(Node* key_val, SwitchRange*& lo, SwitchRange*& hi);
void decrement_age();
// helper functions for methodData style profiling
void test_counter_against_threshold(Node* cnt, int limit);
void increment_and_test_invocation_counter(int limit);
void test_for_osr_md_counter_at(ciMethodData* md, ciProfileData* data, ByteSize offset, int limit);
Node* method_data_addressing(ciMethodData* md, ciProfileData* data, ByteSize offset, Node* idx = NULL, uint stride = 0);
void increment_md_counter_at(ciMethodData* md, ciProfileData* data, ByteSize offset, Node* idx = NULL, uint stride = 0);
void set_md_flag_at(ciMethodData* md, ciProfileData* data, int flag_constant);
void profile_method_entry();
void profile_taken_branch(int target_bci, bool force_update = false);
void profile_not_taken_branch(bool force_update = false);
void profile_call(Node* receiver);
void profile_generic_call();
void profile_receiver_type(Node* receiver);
void profile_ret(int target_bci);
void profile_null_checkcast();
void profile_switch_case(int table_index);
// helper function for call statistics
void count_compiled_calls(bool at_method_entry, bool is_inline) PRODUCT_RETURN;
Node_Notes* make_node_notes(Node_Notes* caller_nn);
// Helper functions for handling normal and abnormal exits.
void build_exits();
// Fix up all exceptional control flow exiting a single bytecode.
void do_exceptions();
// Fix up all exiting control flow at the end of the parse.
void do_exits();
// Add Catch/CatchProjs
// The call is either a Java call or the VM's rethrow stub
void catch_call_exceptions(ciExceptionHandlerStream&);
// Handle all exceptions thrown by the inlined method.
// Also handles exceptions for individual bytecodes.
void catch_inline_exceptions(SafePointNode* ex_map);
// Merge the given map into correct exceptional exit state.
// Assumes that there is no applicable local handler.
void throw_to_exit(SafePointNode* ex_map);
// Use speculative type to optimize CmpP node
Node* optimize_cmp_with_klass(Node* c);
public:
#ifndef PRODUCT
// Handle PrintOpto, etc.
void show_parse_info();
void dump_map_adr_mem() const;
static void print_statistics(); // Print some performance counters
void dump();
void dump_bci(int bci);
#endif
};
#endif // SHARE_VM_OPTO_PARSE_HPP