/* * Copyright (c) 2000, 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. * * 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. * */ #ifndef SHARE_VM_OOPS_METHODDATAOOP_HPP #define SHARE_VM_OOPS_METHODDATAOOP_HPP #include "interpreter/bytecodes.hpp" #include "memory/universe.hpp" #include "oops/method.hpp" #include "oops/oop.hpp" #include "runtime/orderAccess.hpp" class BytecodeStream; class KlassSizeStats; // The MethodData object collects counts and other profile information // during zeroth-tier (interpretive) and first-tier execution. // The profile is used later by compilation heuristics. Some heuristics // enable use of aggressive (or "heroic") optimizations. An aggressive // optimization often has a down-side, a corner case that it handles // poorly, but which is thought to be rare. The profile provides // evidence of this rarity for a given method or even BCI. It allows // the compiler to back out of the optimization at places where it // has historically been a poor choice. Other heuristics try to use // specific information gathered about types observed at a given site. // // All data in the profile is approximate. It is expected to be accurate // on the whole, but the system expects occasional inaccuraces, due to // counter overflow, multiprocessor races during data collection, space // limitations, missing MDO blocks, etc. Bad or missing data will degrade // optimization quality but will not affect correctness. Also, each MDO // is marked with its birth-date ("creation_mileage") which can be used // to assess the quality ("maturity") of its data. // // Short (<32-bit) counters are designed to overflow to a known "saturated" // state. Also, certain recorded per-BCI events are given one-bit counters // which overflow to a saturated state which applied to all counters at // that BCI. In other words, there is a small lattice which approximates // the ideal of an infinite-precision counter for each event at each BCI, // and the lattice quickly "bottoms out" in a state where all counters // are taken to be indefinitely large. // // The reader will find many data races in profile gathering code, starting // with invocation counter incrementation. None of these races harm correct // execution of the compiled code. // forward decl class ProfileData; // DataLayout // // Overlay for generic profiling data. class DataLayout VALUE_OBJ_CLASS_SPEC { friend class VMStructs; private: // Every data layout begins with a header. This header // contains a tag, which is used to indicate the size/layout // of the data, 4 bits of flags, which can be used in any way, // 4 bits of trap history (none/one reason/many reasons), // and a bci, which is used to tie this piece of data to a // specific bci in the bytecodes. union { intptr_t _bits; struct { u1 _tag; u1 _flags; u2 _bci; } _struct; } _header; // The data layout has an arbitrary number of cells, each sized // to accomodate a pointer or an integer. intptr_t _cells[1]; // Some types of data layouts need a length field. static bool needs_array_len(u1 tag); public: enum { counter_increment = 1 }; enum { cell_size = sizeof(intptr_t) }; // Tag values enum { no_tag, bit_data_tag, counter_data_tag, jump_data_tag, receiver_type_data_tag, virtual_call_data_tag, ret_data_tag, branch_data_tag, multi_branch_data_tag, arg_info_data_tag, call_type_data_tag, virtual_call_type_data_tag, parameters_type_data_tag, speculative_trap_data_tag }; enum { // The _struct._flags word is formatted as [trap_state:4 | flags:4]. // The trap state breaks down further as [recompile:1 | reason:3]. // This further breakdown is defined in deoptimization.cpp. // See Deoptimization::trap_state_reason for an assert that // trap_bits is big enough to hold reasons < Reason_RECORDED_LIMIT. // // The trap_state is collected only if ProfileTraps is true. trap_bits = 1+3, // 3: enough to distinguish [0..Reason_RECORDED_LIMIT]. trap_shift = BitsPerByte - trap_bits, trap_mask = right_n_bits(trap_bits), trap_mask_in_place = (trap_mask << trap_shift), flag_limit = trap_shift, flag_mask = right_n_bits(flag_limit), first_flag = 0 }; // Size computation static int header_size_in_bytes() { return cell_size; } static int header_size_in_cells() { return 1; } static int compute_size_in_bytes(int cell_count) { return header_size_in_bytes() + cell_count * cell_size; } // Initialization void initialize(u1 tag, u2 bci, int cell_count); // Accessors u1 tag() { return _header._struct._tag; } // Return a few bits of trap state. Range is [0..trap_mask]. // The state tells if traps with zero, one, or many reasons have occurred. // It also tells whether zero or many recompilations have occurred. // The associated trap histogram in the MDO itself tells whether // traps are common or not. If a BCI shows that a trap X has // occurred, and the MDO shows N occurrences of X, we make the // simplifying assumption that all N occurrences can be blamed // on that BCI. int trap_state() const { return ((_header._struct._flags >> trap_shift) & trap_mask); } void set_trap_state(int new_state) { assert(ProfileTraps, "used only under +ProfileTraps"); uint old_flags = (_header._struct._flags & flag_mask); _header._struct._flags = (new_state << trap_shift) | old_flags; } u1 flags() const { return _header._struct._flags; } u2 bci() const { return _header._struct._bci; } void set_header(intptr_t value) { _header._bits = value; } intptr_t header() { return _header._bits; } void set_cell_at(int index, intptr_t value) { _cells[index] = value; } void release_set_cell_at(int index, intptr_t value) { OrderAccess::release_store_ptr(&_cells[index], value); } intptr_t cell_at(int index) const { return _cells[index]; } void set_flag_at(int flag_number) { assert(flag_number < flag_limit, "oob"); _header._struct._flags |= (0x1 << flag_number); } bool flag_at(int flag_number) const { assert(flag_number < flag_limit, "oob"); return (_header._struct._flags & (0x1 << flag_number)) != 0; } // Low-level support for code generation. static ByteSize header_offset() { return byte_offset_of(DataLayout, _header); } static ByteSize tag_offset() { return byte_offset_of(DataLayout, _header._struct._tag); } static ByteSize flags_offset() { return byte_offset_of(DataLayout, _header._struct._flags); } static ByteSize bci_offset() { return byte_offset_of(DataLayout, _header._struct._bci); } static ByteSize cell_offset(int index) { return byte_offset_of(DataLayout, _cells) + in_ByteSize(index * cell_size); } #ifdef CC_INTERP static int cell_offset_in_bytes(int index) { return (int)offset_of(DataLayout, _cells[index]); } #endif // CC_INTERP // Return a value which, when or-ed as a byte into _flags, sets the flag. static int flag_number_to_byte_constant(int flag_number) { assert(0 <= flag_number && flag_number < flag_limit, "oob"); DataLayout temp; temp.set_header(0); temp.set_flag_at(flag_number); return temp._header._struct._flags; } // Return a value which, when or-ed as a word into _header, sets the flag. static intptr_t flag_mask_to_header_mask(int byte_constant) { DataLayout temp; temp.set_header(0); temp._header._struct._flags = byte_constant; return temp._header._bits; } ProfileData* data_in(); // GC support void clean_weak_klass_links(BoolObjectClosure* cl); // Redefinition support void clean_weak_method_links(); }; // ProfileData class hierarchy class ProfileData; class BitData; class CounterData; class ReceiverTypeData; class VirtualCallData; class VirtualCallTypeData; class RetData; class CallTypeData; class JumpData; class BranchData; class ArrayData; class MultiBranchData; class ArgInfoData; class ParametersTypeData; class SpeculativeTrapData; // ProfileData // // A ProfileData object is created to refer to a section of profiling // data in a structured way. class ProfileData : public ResourceObj { friend class TypeEntries; friend class ReturnTypeEntry; friend class TypeStackSlotEntries; private: #ifndef PRODUCT enum { tab_width_one = 16, tab_width_two = 36 }; #endif // !PRODUCT // This is a pointer to a section of profiling data. DataLayout* _data; char* print_data_on_helper(const MethodData* md) const; protected: DataLayout* data() { return _data; } const DataLayout* data() const { return _data; } enum { cell_size = DataLayout::cell_size }; public: // How many cells are in this? virtual int cell_count() const { ShouldNotReachHere(); return -1; } // Return the size of this data. int size_in_bytes() { return DataLayout::compute_size_in_bytes(cell_count()); } protected: // Low-level accessors for underlying data void set_intptr_at(int index, intptr_t value) { assert(0 <= index && index < cell_count(), "oob"); data()->set_cell_at(index, value); } void release_set_intptr_at(int index, intptr_t value) { assert(0 <= index && index < cell_count(), "oob"); data()->release_set_cell_at(index, value); } intptr_t intptr_at(int index) const { assert(0 <= index && index < cell_count(), "oob"); return data()->cell_at(index); } void set_uint_at(int index, uint value) { set_intptr_at(index, (intptr_t) value); } void release_set_uint_at(int index, uint value) { release_set_intptr_at(index, (intptr_t) value); } uint uint_at(int index) const { return (uint)intptr_at(index); } void set_int_at(int index, int value) { set_intptr_at(index, (intptr_t) value); } void release_set_int_at(int index, int value) { release_set_intptr_at(index, (intptr_t) value); } int int_at(int index) const { return (int)intptr_at(index); } int int_at_unchecked(int index) const { return (int)data()->cell_at(index); } void set_oop_at(int index, oop value) { set_intptr_at(index, cast_from_oop(value)); } oop oop_at(int index) const { return cast_to_oop(intptr_at(index)); } void set_flag_at(int flag_number) { data()->set_flag_at(flag_number); } bool flag_at(int flag_number) const { return data()->flag_at(flag_number); } // two convenient imports for use by subclasses: static ByteSize cell_offset(int index) { return DataLayout::cell_offset(index); } static int flag_number_to_byte_constant(int flag_number) { return DataLayout::flag_number_to_byte_constant(flag_number); } ProfileData(DataLayout* data) { _data = data; } #ifdef CC_INTERP // Static low level accessors for DataLayout with ProfileData's semantics. static int cell_offset_in_bytes(int index) { return DataLayout::cell_offset_in_bytes(index); } static void increment_uint_at_no_overflow(DataLayout* layout, int index, int inc = DataLayout::counter_increment) { uint count = ((uint)layout->cell_at(index)) + inc; if (count == 0) return; layout->set_cell_at(index, (intptr_t) count); } static int int_at(DataLayout* layout, int index) { return (int)layout->cell_at(index); } static int uint_at(DataLayout* layout, int index) { return (uint)layout->cell_at(index); } static oop oop_at(DataLayout* layout, int index) { return cast_to_oop(layout->cell_at(index)); } static void set_intptr_at(DataLayout* layout, int index, intptr_t value) { layout->set_cell_at(index, (intptr_t) value); } static void set_flag_at(DataLayout* layout, int flag_number) { layout->set_flag_at(flag_number); } #endif // CC_INTERP public: // Constructor for invalid ProfileData. ProfileData(); u2 bci() const { return data()->bci(); } address dp() { return (address)_data; } int trap_state() const { return data()->trap_state(); } void set_trap_state(int new_state) { data()->set_trap_state(new_state); } // Type checking virtual bool is_BitData() const { return false; } virtual bool is_CounterData() const { return false; } virtual bool is_JumpData() const { return false; } virtual bool is_ReceiverTypeData()const { return false; } virtual bool is_VirtualCallData() const { return false; } virtual bool is_RetData() const { return false; } virtual bool is_BranchData() const { return false; } virtual bool is_ArrayData() const { return false; } virtual bool is_MultiBranchData() const { return false; } virtual bool is_ArgInfoData() const { return false; } virtual bool is_CallTypeData() const { return false; } virtual bool is_VirtualCallTypeData()const { return false; } virtual bool is_ParametersTypeData() const { return false; } virtual bool is_SpeculativeTrapData()const { return false; } BitData* as_BitData() const { assert(is_BitData(), "wrong type"); return is_BitData() ? (BitData*) this : NULL; } CounterData* as_CounterData() const { assert(is_CounterData(), "wrong type"); return is_CounterData() ? (CounterData*) this : NULL; } JumpData* as_JumpData() const { assert(is_JumpData(), "wrong type"); return is_JumpData() ? (JumpData*) this : NULL; } ReceiverTypeData* as_ReceiverTypeData() const { assert(is_ReceiverTypeData(), "wrong type"); return is_ReceiverTypeData() ? (ReceiverTypeData*)this : NULL; } VirtualCallData* as_VirtualCallData() const { assert(is_VirtualCallData(), "wrong type"); return is_VirtualCallData() ? (VirtualCallData*)this : NULL; } RetData* as_RetData() const { assert(is_RetData(), "wrong type"); return is_RetData() ? (RetData*) this : NULL; } BranchData* as_BranchData() const { assert(is_BranchData(), "wrong type"); return is_BranchData() ? (BranchData*) this : NULL; } ArrayData* as_ArrayData() const { assert(is_ArrayData(), "wrong type"); return is_ArrayData() ? (ArrayData*) this : NULL; } MultiBranchData* as_MultiBranchData() const { assert(is_MultiBranchData(), "wrong type"); return is_MultiBranchData() ? (MultiBranchData*)this : NULL; } ArgInfoData* as_ArgInfoData() const { assert(is_ArgInfoData(), "wrong type"); return is_ArgInfoData() ? (ArgInfoData*)this : NULL; } CallTypeData* as_CallTypeData() const { assert(is_CallTypeData(), "wrong type"); return is_CallTypeData() ? (CallTypeData*)this : NULL; } VirtualCallTypeData* as_VirtualCallTypeData() const { assert(is_VirtualCallTypeData(), "wrong type"); return is_VirtualCallTypeData() ? (VirtualCallTypeData*)this : NULL; } ParametersTypeData* as_ParametersTypeData() const { assert(is_ParametersTypeData(), "wrong type"); return is_ParametersTypeData() ? (ParametersTypeData*)this : NULL; } SpeculativeTrapData* as_SpeculativeTrapData() const { assert(is_SpeculativeTrapData(), "wrong type"); return is_SpeculativeTrapData() ? (SpeculativeTrapData*)this : NULL; } // Subclass specific initialization virtual void post_initialize(BytecodeStream* stream, MethodData* mdo) {} // GC support virtual void clean_weak_klass_links(BoolObjectClosure* is_alive_closure) {} // Redefinition support virtual void clean_weak_method_links() {} // CI translation: ProfileData can represent both MethodDataOop data // as well as CIMethodData data. This function is provided for translating // an oop in a ProfileData to the ci equivalent. Generally speaking, // most ProfileData don't require any translation, so we provide the null // translation here, and the required translators are in the ci subclasses. virtual void translate_from(const ProfileData* data) {} virtual void print_data_on(outputStream* st, const char* extra = NULL) const { ShouldNotReachHere(); } void print_data_on(outputStream* st, const MethodData* md) const; #ifndef PRODUCT void print_shared(outputStream* st, const char* name, const char* extra) const; void tab(outputStream* st, bool first = false) const; #endif }; // BitData // // A BitData holds a flag or two in its header. class BitData : public ProfileData { protected: enum { // null_seen: // saw a null operand (cast/aastore/instanceof) null_seen_flag = DataLayout::first_flag + 0 }; enum { bit_cell_count = 0 }; // no additional data fields needed. public: BitData(DataLayout* layout) : ProfileData(layout) { } virtual bool is_BitData() const { return true; } static int static_cell_count() { return bit_cell_count; } virtual int cell_count() const { return static_cell_count(); } // Accessor // The null_seen flag bit is specially known to the interpreter. // Consulting it allows the compiler to avoid setting up null_check traps. bool null_seen() { return flag_at(null_seen_flag); } void set_null_seen() { set_flag_at(null_seen_flag); } // Code generation support static int null_seen_byte_constant() { return flag_number_to_byte_constant(null_seen_flag); } static ByteSize bit_data_size() { return cell_offset(bit_cell_count); } #ifdef CC_INTERP static int bit_data_size_in_bytes() { return cell_offset_in_bytes(bit_cell_count); } static void set_null_seen(DataLayout* layout) { set_flag_at(layout, null_seen_flag); } static DataLayout* advance(DataLayout* layout) { return (DataLayout*) (((address)layout) + (ssize_t)BitData::bit_data_size_in_bytes()); } #endif // CC_INTERP #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // CounterData // // A CounterData corresponds to a simple counter. class CounterData : public BitData { protected: enum { count_off, counter_cell_count }; public: CounterData(DataLayout* layout) : BitData(layout) {} virtual bool is_CounterData() const { return true; } static int static_cell_count() { return counter_cell_count; } virtual int cell_count() const { return static_cell_count(); } // Direct accessor uint count() const { return uint_at(count_off); } // Code generation support static ByteSize count_offset() { return cell_offset(count_off); } static ByteSize counter_data_size() { return cell_offset(counter_cell_count); } void set_count(uint count) { set_uint_at(count_off, count); } #ifdef CC_INTERP static int counter_data_size_in_bytes() { return cell_offset_in_bytes(counter_cell_count); } static void increment_count_no_overflow(DataLayout* layout) { increment_uint_at_no_overflow(layout, count_off); } // Support counter decrementation at checkcast / subtype check failed. static void decrement_count(DataLayout* layout) { increment_uint_at_no_overflow(layout, count_off, -1); } static DataLayout* advance(DataLayout* layout) { return (DataLayout*) (((address)layout) + (ssize_t)CounterData::counter_data_size_in_bytes()); } #endif // CC_INTERP #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // JumpData // // A JumpData is used to access profiling information for a direct // branch. It is a counter, used for counting the number of branches, // plus a data displacement, used for realigning the data pointer to // the corresponding target bci. class JumpData : public ProfileData { protected: enum { taken_off_set, displacement_off_set, jump_cell_count }; void set_displacement(int displacement) { set_int_at(displacement_off_set, displacement); } public: JumpData(DataLayout* layout) : ProfileData(layout) { assert(layout->tag() == DataLayout::jump_data_tag || layout->tag() == DataLayout::branch_data_tag, "wrong type"); } virtual bool is_JumpData() const { return true; } static int static_cell_count() { return jump_cell_count; } virtual int cell_count() const { return static_cell_count(); } // Direct accessor uint taken() const { return uint_at(taken_off_set); } void set_taken(uint cnt) { set_uint_at(taken_off_set, cnt); } // Saturating counter uint inc_taken() { uint cnt = taken() + 1; // Did we wrap? Will compiler screw us?? if (cnt == 0) cnt--; set_uint_at(taken_off_set, cnt); return cnt; } int displacement() const { return int_at(displacement_off_set); } // Code generation support static ByteSize taken_offset() { return cell_offset(taken_off_set); } static ByteSize displacement_offset() { return cell_offset(displacement_off_set); } #ifdef CC_INTERP static void increment_taken_count_no_overflow(DataLayout* layout) { increment_uint_at_no_overflow(layout, taken_off_set); } static DataLayout* advance_taken(DataLayout* layout) { return (DataLayout*) (((address)layout) + (ssize_t)int_at(layout, displacement_off_set)); } static uint taken_count(DataLayout* layout) { return (uint) uint_at(layout, taken_off_set); } #endif // CC_INTERP // Specific initialization. void post_initialize(BytecodeStream* stream, MethodData* mdo); #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // Entries in a ProfileData object to record types: it can either be // none (no profile), unknown (conflicting profile data) or a klass if // a single one is seen. Whether a null reference was seen is also // recorded. No counter is associated with the type and a single type // is tracked (unlike VirtualCallData). class TypeEntries { public: // A single cell is used to record information for a type: // - the cell is initialized to 0 // - when a type is discovered it is stored in the cell // - bit zero of the cell is used to record whether a null reference // was encountered or not // - bit 1 is set to record a conflict in the type information enum { null_seen = 1, type_mask = ~null_seen, type_unknown = 2, status_bits = null_seen | type_unknown, type_klass_mask = ~status_bits }; // what to initialize a cell to static intptr_t type_none() { return 0; } // null seen = bit 0 set? static bool was_null_seen(intptr_t v) { return (v & null_seen) != 0; } // conflicting type information = bit 1 set? static bool is_type_unknown(intptr_t v) { return (v & type_unknown) != 0; } // not type information yet = all bits cleared, ignoring bit 0? static bool is_type_none(intptr_t v) { return (v & type_mask) == 0; } // recorded type: cell without bit 0 and 1 static intptr_t klass_part(intptr_t v) { intptr_t r = v & type_klass_mask; return r; } // type recorded static Klass* valid_klass(intptr_t k) { if (!is_type_none(k) && !is_type_unknown(k)) { Klass* res = (Klass*)klass_part(k); assert(res != NULL, "invalid"); return res; } else { return NULL; } } static intptr_t with_status(intptr_t k, intptr_t in) { return k | (in & status_bits); } static intptr_t with_status(Klass* k, intptr_t in) { return with_status((intptr_t)k, in); } #ifndef PRODUCT static void print_klass(outputStream* st, intptr_t k); #endif // GC support static bool is_loader_alive(BoolObjectClosure* is_alive_cl, intptr_t p); protected: // ProfileData object these entries are part of ProfileData* _pd; // offset within the ProfileData object where the entries start const int _base_off; TypeEntries(int base_off) : _base_off(base_off), _pd(NULL) {} void set_intptr_at(int index, intptr_t value) { _pd->set_intptr_at(index, value); } intptr_t intptr_at(int index) const { return _pd->intptr_at(index); } public: void set_profile_data(ProfileData* pd) { _pd = pd; } }; // Type entries used for arguments passed at a call and parameters on // method entry. 2 cells per entry: one for the type encoded as in // TypeEntries and one initialized with the stack slot where the // profiled object is to be found so that the interpreter can locate // it quickly. class TypeStackSlotEntries : public TypeEntries { private: enum { stack_slot_entry, type_entry, per_arg_cell_count }; // offset of cell for stack slot for entry i within ProfileData object int stack_slot_offset(int i) const { return _base_off + stack_slot_local_offset(i); } protected: const int _number_of_entries; // offset of cell for type for entry i within ProfileData object int type_offset(int i) const { return _base_off + type_local_offset(i); } public: TypeStackSlotEntries(int base_off, int nb_entries) : TypeEntries(base_off), _number_of_entries(nb_entries) {} static int compute_cell_count(Symbol* signature, bool include_receiver, int max); void post_initialize(Symbol* signature, bool has_receiver, bool include_receiver); // offset of cell for stack slot for entry i within this block of cells for a TypeStackSlotEntries static int stack_slot_local_offset(int i) { return i * per_arg_cell_count + stack_slot_entry; } // offset of cell for type for entry i within this block of cells for a TypeStackSlotEntries static int type_local_offset(int i) { return i * per_arg_cell_count + type_entry; } // stack slot for entry i uint stack_slot(int i) const { assert(i >= 0 && i < _number_of_entries, "oob"); return _pd->uint_at(stack_slot_offset(i)); } // set stack slot for entry i void set_stack_slot(int i, uint num) { assert(i >= 0 && i < _number_of_entries, "oob"); _pd->set_uint_at(stack_slot_offset(i), num); } // type for entry i intptr_t type(int i) const { assert(i >= 0 && i < _number_of_entries, "oob"); return _pd->intptr_at(type_offset(i)); } // set type for entry i void set_type(int i, intptr_t k) { assert(i >= 0 && i < _number_of_entries, "oob"); _pd->set_intptr_at(type_offset(i), k); } static ByteSize per_arg_size() { return in_ByteSize(per_arg_cell_count * DataLayout::cell_size); } static int per_arg_count() { return per_arg_cell_count ; } // GC support void clean_weak_klass_links(BoolObjectClosure* is_alive_closure); #ifndef PRODUCT void print_data_on(outputStream* st) const; #endif }; // Type entry used for return from a call. A single cell to record the // type. class ReturnTypeEntry : public TypeEntries { private: enum { cell_count = 1 }; public: ReturnTypeEntry(int base_off) : TypeEntries(base_off) {} void post_initialize() { set_type(type_none()); } intptr_t type() const { return _pd->intptr_at(_base_off); } void set_type(intptr_t k) { _pd->set_intptr_at(_base_off, k); } static int static_cell_count() { return cell_count; } static ByteSize size() { return in_ByteSize(cell_count * DataLayout::cell_size); } ByteSize type_offset() { return DataLayout::cell_offset(_base_off); } // GC support void clean_weak_klass_links(BoolObjectClosure* is_alive_closure); #ifndef PRODUCT void print_data_on(outputStream* st) const; #endif }; // Entries to collect type information at a call: contains arguments // (TypeStackSlotEntries), a return type (ReturnTypeEntry) and a // number of cells. Because the number of cells for the return type is // smaller than the number of cells for the type of an arguments, the // number of cells is used to tell how many arguments are profiled and // whether a return value is profiled. See has_arguments() and // has_return(). class TypeEntriesAtCall { private: static int stack_slot_local_offset(int i) { return header_cell_count() + TypeStackSlotEntries::stack_slot_local_offset(i); } static int argument_type_local_offset(int i) { return header_cell_count() + TypeStackSlotEntries::type_local_offset(i);; } public: static int header_cell_count() { return 1; } static int cell_count_local_offset() { return 0; } static int compute_cell_count(BytecodeStream* stream); static void initialize(DataLayout* dl, int base, int cell_count) { int off = base + cell_count_local_offset(); dl->set_cell_at(off, cell_count - base - header_cell_count()); } static bool arguments_profiling_enabled(); static bool return_profiling_enabled(); // Code generation support static ByteSize cell_count_offset() { return in_ByteSize(cell_count_local_offset() * DataLayout::cell_size); } static ByteSize args_data_offset() { return in_ByteSize(header_cell_count() * DataLayout::cell_size); } static ByteSize stack_slot_offset(int i) { return in_ByteSize(stack_slot_local_offset(i) * DataLayout::cell_size); } static ByteSize argument_type_offset(int i) { return in_ByteSize(argument_type_local_offset(i) * DataLayout::cell_size); } static ByteSize return_only_size() { return ReturnTypeEntry::size() + in_ByteSize(header_cell_count() * DataLayout::cell_size); } }; // CallTypeData // // A CallTypeData is used to access profiling information about a non // virtual call for which we collect type information about arguments // and return value. class CallTypeData : public CounterData { private: // entries for arguments if any TypeStackSlotEntries _args; // entry for return type if any ReturnTypeEntry _ret; int cell_count_global_offset() const { return CounterData::static_cell_count() + TypeEntriesAtCall::cell_count_local_offset(); } // number of cells not counting the header int cell_count_no_header() const { return uint_at(cell_count_global_offset()); } void check_number_of_arguments(int total) { assert(number_of_arguments() == total, "should be set in DataLayout::initialize"); } public: CallTypeData(DataLayout* layout) : CounterData(layout), _args(CounterData::static_cell_count()+TypeEntriesAtCall::header_cell_count(), number_of_arguments()), _ret(cell_count() - ReturnTypeEntry::static_cell_count()) { assert(layout->tag() == DataLayout::call_type_data_tag, "wrong type"); // Some compilers (VC++) don't want this passed in member initialization list _args.set_profile_data(this); _ret.set_profile_data(this); } const TypeStackSlotEntries* args() const { assert(has_arguments(), "no profiling of arguments"); return &_args; } const ReturnTypeEntry* ret() const { assert(has_return(), "no profiling of return value"); return &_ret; } virtual bool is_CallTypeData() const { return true; } static int static_cell_count() { return -1; } static int compute_cell_count(BytecodeStream* stream) { return CounterData::static_cell_count() + TypeEntriesAtCall::compute_cell_count(stream); } static void initialize(DataLayout* dl, int cell_count) { TypeEntriesAtCall::initialize(dl, CounterData::static_cell_count(), cell_count); } virtual void post_initialize(BytecodeStream* stream, MethodData* mdo); virtual int cell_count() const { return CounterData::static_cell_count() + TypeEntriesAtCall::header_cell_count() + int_at_unchecked(cell_count_global_offset()); } int number_of_arguments() const { return cell_count_no_header() / TypeStackSlotEntries::per_arg_count(); } void set_argument_type(int i, Klass* k) { assert(has_arguments(), "no arguments!"); intptr_t current = _args.type(i); _args.set_type(i, TypeEntries::with_status(k, current)); } void set_return_type(Klass* k) { assert(has_return(), "no return!"); intptr_t current = _ret.type(); _ret.set_type(TypeEntries::with_status(k, current)); } // An entry for a return value takes less space than an entry for an // argument so if the number of cells exceeds the number of cells // needed for an argument, this object contains type information for // at least one argument. bool has_arguments() const { bool res = cell_count_no_header() >= TypeStackSlotEntries::per_arg_count(); assert (!res || TypeEntriesAtCall::arguments_profiling_enabled(), "no profiling of arguments"); return res; } // An entry for a return value takes less space than an entry for an // argument, so if the remainder of the number of cells divided by // the number of cells for an argument is not null, a return value // is profiled in this object. bool has_return() const { bool res = (cell_count_no_header() % TypeStackSlotEntries::per_arg_count()) != 0; assert (!res || TypeEntriesAtCall::return_profiling_enabled(), "no profiling of return values"); return res; } // Code generation support static ByteSize args_data_offset() { return cell_offset(CounterData::static_cell_count()) + TypeEntriesAtCall::args_data_offset(); } // GC support virtual void clean_weak_klass_links(BoolObjectClosure* is_alive_closure) { if (has_arguments()) { _args.clean_weak_klass_links(is_alive_closure); } if (has_return()) { _ret.clean_weak_klass_links(is_alive_closure); } } #ifndef PRODUCT virtual void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // ReceiverTypeData // // A ReceiverTypeData is used to access profiling information about a // dynamic type check. It consists of a counter which counts the total times // that the check is reached, and a series of (Klass*, count) pairs // which are used to store a type profile for the receiver of the check. class ReceiverTypeData : public CounterData { protected: enum { receiver0_offset = counter_cell_count, count0_offset, receiver_type_row_cell_count = (count0_offset + 1) - receiver0_offset }; public: ReceiverTypeData(DataLayout* layout) : CounterData(layout) { assert(layout->tag() == DataLayout::receiver_type_data_tag || layout->tag() == DataLayout::virtual_call_data_tag || layout->tag() == DataLayout::virtual_call_type_data_tag, "wrong type"); } virtual bool is_ReceiverTypeData() const { return true; } static int static_cell_count() { return counter_cell_count + (uint) TypeProfileWidth * receiver_type_row_cell_count; } virtual int cell_count() const { return static_cell_count(); } // Direct accessors static uint row_limit() { return TypeProfileWidth; } static int receiver_cell_index(uint row) { return receiver0_offset + row * receiver_type_row_cell_count; } static int receiver_count_cell_index(uint row) { return count0_offset + row * receiver_type_row_cell_count; } Klass* receiver(uint row) const { assert(row < row_limit(), "oob"); Klass* recv = (Klass*)intptr_at(receiver_cell_index(row)); assert(recv == NULL || recv->is_klass(), "wrong type"); return recv; } void set_receiver(uint row, Klass* k) { assert((uint)row < row_limit(), "oob"); set_intptr_at(receiver_cell_index(row), (uintptr_t)k); } uint receiver_count(uint row) const { assert(row < row_limit(), "oob"); return uint_at(receiver_count_cell_index(row)); } void set_receiver_count(uint row, uint count) { assert(row < row_limit(), "oob"); set_uint_at(receiver_count_cell_index(row), count); } void clear_row(uint row) { assert(row < row_limit(), "oob"); // Clear total count - indicator of polymorphic call site. // The site may look like as monomorphic after that but // it allow to have more accurate profiling information because // there was execution phase change since klasses were unloaded. // If the site is still polymorphic then MDO will be updated // to reflect it. But it could be the case that the site becomes // only bimorphic. Then keeping total count not 0 will be wrong. // Even if we use monomorphic (when it is not) for compilation // we will only have trap, deoptimization and recompile again // with updated MDO after executing method in Interpreter. // An additional receiver will be recorded in the cleaned row // during next call execution. // // Note: our profiling logic works with empty rows in any slot. // We do sorting a profiling info (ciCallProfile) for compilation. // set_count(0); set_receiver(row, NULL); set_receiver_count(row, 0); } // Code generation support static ByteSize receiver_offset(uint row) { return cell_offset(receiver_cell_index(row)); } static ByteSize receiver_count_offset(uint row) { return cell_offset(receiver_count_cell_index(row)); } static ByteSize receiver_type_data_size() { return cell_offset(static_cell_count()); } // GC support virtual void clean_weak_klass_links(BoolObjectClosure* is_alive_closure); #ifdef CC_INTERP static int receiver_type_data_size_in_bytes() { return cell_offset_in_bytes(static_cell_count()); } static Klass *receiver_unchecked(DataLayout* layout, uint row) { Klass* recv = (Klass*)layout->cell_at(receiver_cell_index(row)); return recv; } static void increment_receiver_count_no_overflow(DataLayout* layout, Klass *rcvr) { const int num_rows = row_limit(); // Receiver already exists? for (int row = 0; row < num_rows; row++) { if (receiver_unchecked(layout, row) == rcvr) { increment_uint_at_no_overflow(layout, receiver_count_cell_index(row)); return; } } // New receiver, find a free slot. for (int row = 0; row < num_rows; row++) { if (receiver_unchecked(layout, row) == NULL) { set_intptr_at(layout, receiver_cell_index(row), (intptr_t)rcvr); increment_uint_at_no_overflow(layout, receiver_count_cell_index(row)); return; } } // Receiver did not match any saved receiver and there is no empty row for it. // Increment total counter to indicate polymorphic case. increment_count_no_overflow(layout); } static DataLayout* advance(DataLayout* layout) { return (DataLayout*) (((address)layout) + (ssize_t)ReceiverTypeData::receiver_type_data_size_in_bytes()); } #endif // CC_INTERP #ifndef PRODUCT void print_receiver_data_on(outputStream* st) const; void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // VirtualCallData // // A VirtualCallData is used to access profiling information about a // virtual call. For now, it has nothing more than a ReceiverTypeData. class VirtualCallData : public ReceiverTypeData { public: VirtualCallData(DataLayout* layout) : ReceiverTypeData(layout) { assert(layout->tag() == DataLayout::virtual_call_data_tag || layout->tag() == DataLayout::virtual_call_type_data_tag, "wrong type"); } virtual bool is_VirtualCallData() const { return true; } static int static_cell_count() { // At this point we could add more profile state, e.g., for arguments. // But for now it's the same size as the base record type. return ReceiverTypeData::static_cell_count(); } virtual int cell_count() const { return static_cell_count(); } // Direct accessors static ByteSize virtual_call_data_size() { return cell_offset(static_cell_count()); } #ifdef CC_INTERP static int virtual_call_data_size_in_bytes() { return cell_offset_in_bytes(static_cell_count()); } static DataLayout* advance(DataLayout* layout) { return (DataLayout*) (((address)layout) + (ssize_t)VirtualCallData::virtual_call_data_size_in_bytes()); } #endif // CC_INTERP #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // VirtualCallTypeData // // A VirtualCallTypeData is used to access profiling information about // a virtual call for which we collect type information about // arguments and return value. class VirtualCallTypeData : public VirtualCallData { private: // entries for arguments if any TypeStackSlotEntries _args; // entry for return type if any ReturnTypeEntry _ret; int cell_count_global_offset() const { return VirtualCallData::static_cell_count() + TypeEntriesAtCall::cell_count_local_offset(); } // number of cells not counting the header int cell_count_no_header() const { return uint_at(cell_count_global_offset()); } void check_number_of_arguments(int total) { assert(number_of_arguments() == total, "should be set in DataLayout::initialize"); } public: VirtualCallTypeData(DataLayout* layout) : VirtualCallData(layout), _args(VirtualCallData::static_cell_count()+TypeEntriesAtCall::header_cell_count(), number_of_arguments()), _ret(cell_count() - ReturnTypeEntry::static_cell_count()) { assert(layout->tag() == DataLayout::virtual_call_type_data_tag, "wrong type"); // Some compilers (VC++) don't want this passed in member initialization list _args.set_profile_data(this); _ret.set_profile_data(this); } const TypeStackSlotEntries* args() const { assert(has_arguments(), "no profiling of arguments"); return &_args; } const ReturnTypeEntry* ret() const { assert(has_return(), "no profiling of return value"); return &_ret; } virtual bool is_VirtualCallTypeData() const { return true; } static int static_cell_count() { return -1; } static int compute_cell_count(BytecodeStream* stream) { return VirtualCallData::static_cell_count() + TypeEntriesAtCall::compute_cell_count(stream); } static void initialize(DataLayout* dl, int cell_count) { TypeEntriesAtCall::initialize(dl, VirtualCallData::static_cell_count(), cell_count); } virtual void post_initialize(BytecodeStream* stream, MethodData* mdo); virtual int cell_count() const { return VirtualCallData::static_cell_count() + TypeEntriesAtCall::header_cell_count() + int_at_unchecked(cell_count_global_offset()); } int number_of_arguments() const { return cell_count_no_header() / TypeStackSlotEntries::per_arg_count(); } void set_argument_type(int i, Klass* k) { assert(has_arguments(), "no arguments!"); intptr_t current = _args.type(i); _args.set_type(i, TypeEntries::with_status(k, current)); } void set_return_type(Klass* k) { assert(has_return(), "no return!"); intptr_t current = _ret.type(); _ret.set_type(TypeEntries::with_status(k, current)); } // An entry for a return value takes less space than an entry for an // argument, so if the remainder of the number of cells divided by // the number of cells for an argument is not null, a return value // is profiled in this object. bool has_return() const { bool res = (cell_count_no_header() % TypeStackSlotEntries::per_arg_count()) != 0; assert (!res || TypeEntriesAtCall::return_profiling_enabled(), "no profiling of return values"); return res; } // An entry for a return value takes less space than an entry for an // argument so if the number of cells exceeds the number of cells // needed for an argument, this object contains type information for // at least one argument. bool has_arguments() const { bool res = cell_count_no_header() >= TypeStackSlotEntries::per_arg_count(); assert (!res || TypeEntriesAtCall::arguments_profiling_enabled(), "no profiling of arguments"); return res; } // Code generation support static ByteSize args_data_offset() { return cell_offset(VirtualCallData::static_cell_count()) + TypeEntriesAtCall::args_data_offset(); } // GC support virtual void clean_weak_klass_links(BoolObjectClosure* is_alive_closure) { ReceiverTypeData::clean_weak_klass_links(is_alive_closure); if (has_arguments()) { _args.clean_weak_klass_links(is_alive_closure); } if (has_return()) { _ret.clean_weak_klass_links(is_alive_closure); } } #ifndef PRODUCT virtual void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // RetData // // A RetData is used to access profiling information for a ret bytecode. // It is composed of a count of the number of times that the ret has // been executed, followed by a series of triples of the form // (bci, count, di) which count the number of times that some bci was the // target of the ret and cache a corresponding data displacement. class RetData : public CounterData { protected: enum { bci0_offset = counter_cell_count, count0_offset, displacement0_offset, ret_row_cell_count = (displacement0_offset + 1) - bci0_offset }; void set_bci(uint row, int bci) { assert((uint)row < row_limit(), "oob"); set_int_at(bci0_offset + row * ret_row_cell_count, bci); } void release_set_bci(uint row, int bci) { assert((uint)row < row_limit(), "oob"); // 'release' when setting the bci acts as a valid flag for other // threads wrt bci_count and bci_displacement. release_set_int_at(bci0_offset + row * ret_row_cell_count, bci); } void set_bci_count(uint row, uint count) { assert((uint)row < row_limit(), "oob"); set_uint_at(count0_offset + row * ret_row_cell_count, count); } void set_bci_displacement(uint row, int disp) { set_int_at(displacement0_offset + row * ret_row_cell_count, disp); } public: RetData(DataLayout* layout) : CounterData(layout) { assert(layout->tag() == DataLayout::ret_data_tag, "wrong type"); } virtual bool is_RetData() const { return true; } enum { no_bci = -1 // value of bci when bci1/2 are not in use. }; static int static_cell_count() { return counter_cell_count + (uint) BciProfileWidth * ret_row_cell_count; } virtual int cell_count() const { return static_cell_count(); } static uint row_limit() { return BciProfileWidth; } static int bci_cell_index(uint row) { return bci0_offset + row * ret_row_cell_count; } static int bci_count_cell_index(uint row) { return count0_offset + row * ret_row_cell_count; } static int bci_displacement_cell_index(uint row) { return displacement0_offset + row * ret_row_cell_count; } // Direct accessors int bci(uint row) const { return int_at(bci_cell_index(row)); } uint bci_count(uint row) const { return uint_at(bci_count_cell_index(row)); } int bci_displacement(uint row) const { return int_at(bci_displacement_cell_index(row)); } // Interpreter Runtime support address fixup_ret(int return_bci, MethodData* mdo); // Code generation support static ByteSize bci_offset(uint row) { return cell_offset(bci_cell_index(row)); } static ByteSize bci_count_offset(uint row) { return cell_offset(bci_count_cell_index(row)); } static ByteSize bci_displacement_offset(uint row) { return cell_offset(bci_displacement_cell_index(row)); } #ifdef CC_INTERP static DataLayout* advance(MethodData *md, int bci); #endif // CC_INTERP // Specific initialization. void post_initialize(BytecodeStream* stream, MethodData* mdo); #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // BranchData // // A BranchData is used to access profiling data for a two-way branch. // It consists of taken and not_taken counts as well as a data displacement // for the taken case. class BranchData : public JumpData { protected: enum { not_taken_off_set = jump_cell_count, branch_cell_count }; void set_displacement(int displacement) { set_int_at(displacement_off_set, displacement); } public: BranchData(DataLayout* layout) : JumpData(layout) { assert(layout->tag() == DataLayout::branch_data_tag, "wrong type"); } virtual bool is_BranchData() const { return true; } static int static_cell_count() { return branch_cell_count; } virtual int cell_count() const { return static_cell_count(); } // Direct accessor uint not_taken() const { return uint_at(not_taken_off_set); } void set_not_taken(uint cnt) { set_uint_at(not_taken_off_set, cnt); } uint inc_not_taken() { uint cnt = not_taken() + 1; // Did we wrap? Will compiler screw us?? if (cnt == 0) cnt--; set_uint_at(not_taken_off_set, cnt); return cnt; } // Code generation support static ByteSize not_taken_offset() { return cell_offset(not_taken_off_set); } static ByteSize branch_data_size() { return cell_offset(branch_cell_count); } #ifdef CC_INTERP static int branch_data_size_in_bytes() { return cell_offset_in_bytes(branch_cell_count); } static void increment_not_taken_count_no_overflow(DataLayout* layout) { increment_uint_at_no_overflow(layout, not_taken_off_set); } static DataLayout* advance_not_taken(DataLayout* layout) { return (DataLayout*) (((address)layout) + (ssize_t)BranchData::branch_data_size_in_bytes()); } #endif // CC_INTERP // Specific initialization. void post_initialize(BytecodeStream* stream, MethodData* mdo); #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // ArrayData // // A ArrayData is a base class for accessing profiling data which does // not have a statically known size. It consists of an array length // and an array start. class ArrayData : public ProfileData { protected: friend class DataLayout; enum { array_len_off_set, array_start_off_set }; uint array_uint_at(int index) const { int aindex = index + array_start_off_set; return uint_at(aindex); } int array_int_at(int index) const { int aindex = index + array_start_off_set; return int_at(aindex); } oop array_oop_at(int index) const { int aindex = index + array_start_off_set; return oop_at(aindex); } void array_set_int_at(int index, int value) { int aindex = index + array_start_off_set; set_int_at(aindex, value); } #ifdef CC_INTERP // Static low level accessors for DataLayout with ArrayData's semantics. static void increment_array_uint_at_no_overflow(DataLayout* layout, int index) { int aindex = index + array_start_off_set; increment_uint_at_no_overflow(layout, aindex); } static int array_int_at(DataLayout* layout, int index) { int aindex = index + array_start_off_set; return int_at(layout, aindex); } #endif // CC_INTERP // Code generation support for subclasses. static ByteSize array_element_offset(int index) { return cell_offset(array_start_off_set + index); } public: ArrayData(DataLayout* layout) : ProfileData(layout) {} virtual bool is_ArrayData() const { return true; } static int static_cell_count() { return -1; } int array_len() const { return int_at_unchecked(array_len_off_set); } virtual int cell_count() const { return array_len() + 1; } // Code generation support static ByteSize array_len_offset() { return cell_offset(array_len_off_set); } static ByteSize array_start_offset() { return cell_offset(array_start_off_set); } }; // MultiBranchData // // A MultiBranchData is used to access profiling information for // a multi-way branch (*switch bytecodes). It consists of a series // of (count, displacement) pairs, which count the number of times each // case was taken and specify the data displacment for each branch target. class MultiBranchData : public ArrayData { protected: enum { default_count_off_set, default_disaplacement_off_set, case_array_start }; enum { relative_count_off_set, relative_displacement_off_set, per_case_cell_count }; void set_default_displacement(int displacement) { array_set_int_at(default_disaplacement_off_set, displacement); } void set_displacement_at(int index, int displacement) { array_set_int_at(case_array_start + index * per_case_cell_count + relative_displacement_off_set, displacement); } public: MultiBranchData(DataLayout* layout) : ArrayData(layout) { assert(layout->tag() == DataLayout::multi_branch_data_tag, "wrong type"); } virtual bool is_MultiBranchData() const { return true; } static int compute_cell_count(BytecodeStream* stream); int number_of_cases() const { int alen = array_len() - 2; // get rid of default case here. assert(alen % per_case_cell_count == 0, "must be even"); return (alen / per_case_cell_count); } uint default_count() const { return array_uint_at(default_count_off_set); } int default_displacement() const { return array_int_at(default_disaplacement_off_set); } uint count_at(int index) const { return array_uint_at(case_array_start + index * per_case_cell_count + relative_count_off_set); } int displacement_at(int index) const { return array_int_at(case_array_start + index * per_case_cell_count + relative_displacement_off_set); } // Code generation support static ByteSize default_count_offset() { return array_element_offset(default_count_off_set); } static ByteSize default_displacement_offset() { return array_element_offset(default_disaplacement_off_set); } static ByteSize case_count_offset(int index) { return case_array_offset() + (per_case_size() * index) + relative_count_offset(); } static ByteSize case_array_offset() { return array_element_offset(case_array_start); } static ByteSize per_case_size() { return in_ByteSize(per_case_cell_count) * cell_size; } static ByteSize relative_count_offset() { return in_ByteSize(relative_count_off_set) * cell_size; } static ByteSize relative_displacement_offset() { return in_ByteSize(relative_displacement_off_set) * cell_size; } #ifdef CC_INTERP static void increment_count_no_overflow(DataLayout* layout, int index) { if (index == -1) { increment_array_uint_at_no_overflow(layout, default_count_off_set); } else { increment_array_uint_at_no_overflow(layout, case_array_start + index * per_case_cell_count + relative_count_off_set); } } static DataLayout* advance(DataLayout* layout, int index) { if (index == -1) { return (DataLayout*) (((address)layout) + (ssize_t)array_int_at(layout, default_disaplacement_off_set)); } else { return (DataLayout*) (((address)layout) + (ssize_t)array_int_at(layout, case_array_start + index * per_case_cell_count + relative_displacement_off_set)); } } #endif // CC_INTERP // Specific initialization. void post_initialize(BytecodeStream* stream, MethodData* mdo); #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; class ArgInfoData : public ArrayData { public: ArgInfoData(DataLayout* layout) : ArrayData(layout) { assert(layout->tag() == DataLayout::arg_info_data_tag, "wrong type"); } virtual bool is_ArgInfoData() const { return true; } int number_of_args() const { return array_len(); } uint arg_modified(int arg) const { return array_uint_at(arg); } void set_arg_modified(int arg, uint val) { array_set_int_at(arg, val); } #ifndef PRODUCT void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // ParametersTypeData // // A ParametersTypeData is used to access profiling information about // types of parameters to a method class ParametersTypeData : public ArrayData { private: TypeStackSlotEntries _parameters; static int stack_slot_local_offset(int i) { assert_profiling_enabled(); return array_start_off_set + TypeStackSlotEntries::stack_slot_local_offset(i); } static int type_local_offset(int i) { assert_profiling_enabled(); return array_start_off_set + TypeStackSlotEntries::type_local_offset(i); } static bool profiling_enabled(); static void assert_profiling_enabled() { assert(profiling_enabled(), "method parameters profiling should be on"); } public: ParametersTypeData(DataLayout* layout) : ArrayData(layout), _parameters(1, number_of_parameters()) { assert(layout->tag() == DataLayout::parameters_type_data_tag, "wrong type"); // Some compilers (VC++) don't want this passed in member initialization list _parameters.set_profile_data(this); } static int compute_cell_count(Method* m); virtual bool is_ParametersTypeData() const { return true; } virtual void post_initialize(BytecodeStream* stream, MethodData* mdo); int number_of_parameters() const { return array_len() / TypeStackSlotEntries::per_arg_count(); } const TypeStackSlotEntries* parameters() const { return &_parameters; } uint stack_slot(int i) const { return _parameters.stack_slot(i); } void set_type(int i, Klass* k) { intptr_t current = _parameters.type(i); _parameters.set_type(i, TypeEntries::with_status((intptr_t)k, current)); } virtual void clean_weak_klass_links(BoolObjectClosure* is_alive_closure) { _parameters.clean_weak_klass_links(is_alive_closure); } #ifndef PRODUCT virtual void print_data_on(outputStream* st, const char* extra = NULL) const; #endif static ByteSize stack_slot_offset(int i) { return cell_offset(stack_slot_local_offset(i)); } static ByteSize type_offset(int i) { return cell_offset(type_local_offset(i)); } }; // SpeculativeTrapData // // A SpeculativeTrapData is used to record traps due to type // speculation. It records the root of the compilation: that type // speculation is wrong in the context of one compilation (for // method1) doesn't mean it's wrong in the context of another one (for // method2). Type speculation could have more/different data in the // context of the compilation of method2 and it's worthwhile to try an // optimization that failed for compilation of method1 in the context // of compilation of method2. // Space for SpeculativeTrapData entries is allocated from the extra // data space in the MDO. If we run out of space, the trap data for // the ProfileData at that bci is updated. class SpeculativeTrapData : public ProfileData { protected: enum { method_offset, speculative_trap_cell_count }; public: SpeculativeTrapData(DataLayout* layout) : ProfileData(layout) { assert(layout->tag() == DataLayout::speculative_trap_data_tag, "wrong type"); } virtual bool is_SpeculativeTrapData() const { return true; } static int static_cell_count() { return speculative_trap_cell_count; } virtual int cell_count() const { return static_cell_count(); } // Direct accessor Method* method() const { return (Method*)intptr_at(method_offset); } void set_method(Method* m) { set_intptr_at(method_offset, (intptr_t)m); } #ifndef PRODUCT virtual void print_data_on(outputStream* st, const char* extra = NULL) const; #endif }; // MethodData* // // A MethodData* holds information which has been collected about // a method. Its layout looks like this: // // ----------------------------- // | header | // | klass | // ----------------------------- // | method | // | size of the MethodData* | // ----------------------------- // | Data entries... | // | (variable size) | // | | // . . // . . // . . // | | // ----------------------------- // // The data entry area is a heterogeneous array of DataLayouts. Each // DataLayout in the array corresponds to a specific bytecode in the // method. The entries in the array are sorted by the corresponding // bytecode. Access to the data is via resource-allocated ProfileData, // which point to the underlying blocks of DataLayout structures. // // During interpretation, if profiling in enabled, the interpreter // maintains a method data pointer (mdp), which points at the entry // in the array corresponding to the current bci. In the course of // intepretation, when a bytecode is encountered that has profile data // associated with it, the entry pointed to by mdp is updated, then the // mdp is adjusted to point to the next appropriate DataLayout. If mdp // is NULL to begin with, the interpreter assumes that the current method // is not (yet) being profiled. // // In MethodData* parlance, "dp" is a "data pointer", the actual address // of a DataLayout element. A "di" is a "data index", the offset in bytes // from the base of the data entry array. A "displacement" is the byte offset // in certain ProfileData objects that indicate the amount the mdp must be // adjusted in the event of a change in control flow. // CC_INTERP_ONLY(class BytecodeInterpreter;) class CleanExtraDataClosure; class MethodData : public Metadata { friend class VMStructs; CC_INTERP_ONLY(friend class BytecodeInterpreter;) private: friend class ProfileData; // Back pointer to the Method* Method* _method; // Size of this oop in bytes int _size; // Cached hint for bci_to_dp and bci_to_data int _hint_di; Mutex _extra_data_lock; MethodData(methodHandle method, int size, TRAPS); public: static MethodData* allocate(ClassLoaderData* loader_data, methodHandle method, TRAPS); MethodData() : _extra_data_lock(Monitor::leaf, "MDO extra data lock") {}; // For ciMethodData bool is_methodData() const volatile { return true; } // Whole-method sticky bits and flags enum { _trap_hist_limit = 20, // decoupled from Deoptimization::Reason_LIMIT _trap_hist_mask = max_jubyte, _extra_data_count = 4 // extra DataLayout headers, for trap history }; // Public flag values private: uint _nof_decompiles; // count of all nmethod removals uint _nof_overflow_recompiles; // recompile count, excluding recomp. bits uint _nof_overflow_traps; // trap count, excluding _trap_hist union { intptr_t _align; u1 _array[_trap_hist_limit]; } _trap_hist; // Support for interprocedural escape analysis, from Thomas Kotzmann. intx _eflags; // flags on escape information intx _arg_local; // bit set of non-escaping arguments intx _arg_stack; // bit set of stack-allocatable arguments intx _arg_returned; // bit set of returned arguments int _creation_mileage; // method mileage at MDO creation // How many invocations has this MDO seen? // These counters are used to determine the exact age of MDO. // We need those because in tiered a method can be concurrently // executed at different levels. InvocationCounter _invocation_counter; // Same for backedges. InvocationCounter _backedge_counter; // Counter values at the time profiling started. int _invocation_counter_start; int _backedge_counter_start; #if INCLUDE_RTM_OPT // State of RTM code generation during compilation of the method int _rtm_state; #endif // Number of loops and blocks is computed when compiling the first // time with C1. It is used to determine if method is trivial. short _num_loops; short _num_blocks; // Does this method contain anything worth profiling? enum WouldProfile {unknown, no_profile, profile}; WouldProfile _would_profile; // Size of _data array in bytes. (Excludes header and extra_data fields.) int _data_size; // data index for the area dedicated to parameters. -1 if no // parameter profiling. int _parameters_type_data_di; // Beginning of the data entries intptr_t _data[1]; // Helper for size computation static int compute_data_size(BytecodeStream* stream); static int bytecode_cell_count(Bytecodes::Code code); static bool is_speculative_trap_bytecode(Bytecodes::Code code); enum { no_profile_data = -1, variable_cell_count = -2 }; // Helper for initialization DataLayout* data_layout_at(int data_index) const { assert(data_index % sizeof(intptr_t) == 0, "unaligned"); return (DataLayout*) (((address)_data) + data_index); } // Initialize an individual data segment. Returns the size of // the segment in bytes. int initialize_data(BytecodeStream* stream, int data_index); // Helper for data_at DataLayout* limit_data_position() const { return (DataLayout*)((address)data_base() + _data_size); } bool out_of_bounds(int data_index) const { return data_index >= data_size(); } // Give each of the data entries a chance to perform specific // data initialization. void post_initialize(BytecodeStream* stream); // hint accessors int hint_di() const { return _hint_di; } void set_hint_di(int di) { assert(!out_of_bounds(di), "hint_di out of bounds"); _hint_di = di; } ProfileData* data_before(int bci) { // avoid SEGV on this edge case if (data_size() == 0) return NULL; int hint = hint_di(); if (data_layout_at(hint)->bci() <= bci) return data_at(hint); return first_data(); } // What is the index of the first data entry? int first_di() const { return 0; } ProfileData* bci_to_extra_data_helper(int bci, Method* m, DataLayout*& dp, bool concurrent); // Find or create an extra ProfileData: ProfileData* bci_to_extra_data(int bci, Method* m, bool create_if_missing); // return the argument info cell ArgInfoData *arg_info(); enum { no_type_profile = 0, type_profile_jsr292 = 1, type_profile_all = 2 }; static bool profile_jsr292(methodHandle m, int bci); static int profile_arguments_flag(); static bool profile_all_arguments(); static bool profile_arguments_for_invoke(methodHandle m, int bci); static int profile_return_flag(); static bool profile_all_return(); static bool profile_return_for_invoke(methodHandle m, int bci); static int profile_parameters_flag(); static bool profile_parameters_jsr292_only(); static bool profile_all_parameters(); void clean_extra_data(CleanExtraDataClosure* cl); void clean_extra_data_helper(DataLayout* dp, int shift, bool reset = false); void verify_extra_data_clean(CleanExtraDataClosure* cl); public: static int header_size() { return sizeof(MethodData)/wordSize; } // Compute the size of a MethodData* before it is created. static int compute_allocation_size_in_bytes(methodHandle method); static int compute_allocation_size_in_words(methodHandle method); static int compute_extra_data_count(int data_size, int empty_bc_count, bool needs_speculative_traps); // Determine if a given bytecode can have profile information. static bool bytecode_has_profile(Bytecodes::Code code) { return bytecode_cell_count(code) != no_profile_data; } // reset into original state void init(); // My size int size_in_bytes() const { return _size; } int size() const { return align_object_size(align_size_up(_size, BytesPerWord)/BytesPerWord); } #if INCLUDE_SERVICES void collect_statistics(KlassSizeStats *sz) const; #endif int creation_mileage() const { return _creation_mileage; } void set_creation_mileage(int x) { _creation_mileage = x; } int invocation_count() { if (invocation_counter()->carry()) { return InvocationCounter::count_limit; } return invocation_counter()->count(); } int backedge_count() { if (backedge_counter()->carry()) { return InvocationCounter::count_limit; } return backedge_counter()->count(); } int invocation_count_start() { if (invocation_counter()->carry()) { return 0; } return _invocation_counter_start; } int backedge_count_start() { if (backedge_counter()->carry()) { return 0; } return _backedge_counter_start; } int invocation_count_delta() { return invocation_count() - invocation_count_start(); } int backedge_count_delta() { return backedge_count() - backedge_count_start(); } void reset_start_counters() { _invocation_counter_start = invocation_count(); _backedge_counter_start = backedge_count(); } InvocationCounter* invocation_counter() { return &_invocation_counter; } InvocationCounter* backedge_counter() { return &_backedge_counter; } #if INCLUDE_RTM_OPT int rtm_state() const { return _rtm_state; } void set_rtm_state(RTMState rstate) { _rtm_state = (int)rstate; } void atomic_set_rtm_state(RTMState rstate) { Atomic::store((int)rstate, &_rtm_state); } static int rtm_state_offset_in_bytes() { return offset_of(MethodData, _rtm_state); } #endif void set_would_profile(bool p) { _would_profile = p ? profile : no_profile; } bool would_profile() const { return _would_profile != no_profile; } int num_loops() const { return _num_loops; } void set_num_loops(int n) { _num_loops = n; } int num_blocks() const { return _num_blocks; } void set_num_blocks(int n) { _num_blocks = n; } bool is_mature() const; // consult mileage and ProfileMaturityPercentage static int mileage_of(Method* m); // Support for interprocedural escape analysis, from Thomas Kotzmann. enum EscapeFlag { estimated = 1 << 0, return_local = 1 << 1, return_allocated = 1 << 2, allocated_escapes = 1 << 3, unknown_modified = 1 << 4 }; intx eflags() { return _eflags; } intx arg_local() { return _arg_local; } intx arg_stack() { return _arg_stack; } intx arg_returned() { return _arg_returned; } uint arg_modified(int a) { ArgInfoData *aid = arg_info(); assert(aid != NULL, "arg_info must be not null"); assert(a >= 0 && a < aid->number_of_args(), "valid argument number"); return aid->arg_modified(a); } void set_eflags(intx v) { _eflags = v; } void set_arg_local(intx v) { _arg_local = v; } void set_arg_stack(intx v) { _arg_stack = v; } void set_arg_returned(intx v) { _arg_returned = v; } void set_arg_modified(int a, uint v) { ArgInfoData *aid = arg_info(); assert(aid != NULL, "arg_info must be not null"); assert(a >= 0 && a < aid->number_of_args(), "valid argument number"); aid->set_arg_modified(a, v); } void clear_escape_info() { _eflags = _arg_local = _arg_stack = _arg_returned = 0; } // Location and size of data area address data_base() const { return (address) _data; } int data_size() const { return _data_size; } // Accessors Method* method() const { return _method; } // Get the data at an arbitrary (sort of) data index. ProfileData* data_at(int data_index) const; // Walk through the data in order. ProfileData* first_data() const { return data_at(first_di()); } ProfileData* next_data(ProfileData* current) const; bool is_valid(ProfileData* current) const { return current != NULL; } // Convert a dp (data pointer) to a di (data index). int dp_to_di(address dp) const { return dp - ((address)_data); } address di_to_dp(int di) { return (address)data_layout_at(di); } // bci to di/dp conversion. address bci_to_dp(int bci); int bci_to_di(int bci) { return dp_to_di(bci_to_dp(bci)); } // Get the data at an arbitrary bci, or NULL if there is none. ProfileData* bci_to_data(int bci); // Same, but try to create an extra_data record if one is needed: ProfileData* allocate_bci_to_data(int bci, Method* m) { ProfileData* data = NULL; // If m not NULL, try to allocate a SpeculativeTrapData entry if (m == NULL) { data = bci_to_data(bci); } if (data != NULL) { return data; } data = bci_to_extra_data(bci, m, true); if (data != NULL) { return data; } // If SpeculativeTrapData allocation fails try to allocate a // regular entry data = bci_to_data(bci); if (data != NULL) { return data; } return bci_to_extra_data(bci, NULL, true); } // Add a handful of extra data records, for trap tracking. DataLayout* extra_data_base() const { return limit_data_position(); } DataLayout* extra_data_limit() const { return (DataLayout*)((address)this + size_in_bytes()); } int extra_data_size() const { return (address)extra_data_limit() - (address)extra_data_base(); } static DataLayout* next_extra(DataLayout* dp); // Return (uint)-1 for overflow. uint trap_count(int reason) const { assert((uint)reason < _trap_hist_limit, "oob"); return (int)((_trap_hist._array[reason]+1) & _trap_hist_mask) - 1; } // For loops: static uint trap_reason_limit() { return _trap_hist_limit; } static uint trap_count_limit() { return _trap_hist_mask; } uint inc_trap_count(int reason) { // Count another trap, anywhere in this method. assert(reason >= 0, "must be single trap"); if ((uint)reason < _trap_hist_limit) { uint cnt1 = 1 + _trap_hist._array[reason]; if ((cnt1 & _trap_hist_mask) != 0) { // if no counter overflow... _trap_hist._array[reason] = cnt1; return cnt1; } else { return _trap_hist_mask + (++_nof_overflow_traps); } } else { // Could not represent the count in the histogram. return (++_nof_overflow_traps); } } uint overflow_trap_count() const { return _nof_overflow_traps; } uint overflow_recompile_count() const { return _nof_overflow_recompiles; } void inc_overflow_recompile_count() { _nof_overflow_recompiles += 1; } uint decompile_count() const { return _nof_decompiles; } void inc_decompile_count() { _nof_decompiles += 1; if (decompile_count() > (uint)PerMethodRecompilationCutoff) { method()->set_not_compilable(CompLevel_full_optimization, true, "decompile_count > PerMethodRecompilationCutoff"); } } // Return pointer to area dedicated to parameters in MDO ParametersTypeData* parameters_type_data() const { return _parameters_type_data_di != -1 ? data_layout_at(_parameters_type_data_di)->data_in()->as_ParametersTypeData() : NULL; } int parameters_type_data_di() const { assert(_parameters_type_data_di != -1, "no args type data"); return _parameters_type_data_di; } // Support for code generation static ByteSize data_offset() { return byte_offset_of(MethodData, _data[0]); } static ByteSize invocation_counter_offset() { return byte_offset_of(MethodData, _invocation_counter); } static ByteSize backedge_counter_offset() { return byte_offset_of(MethodData, _backedge_counter); } static ByteSize parameters_type_data_di_offset() { return byte_offset_of(MethodData, _parameters_type_data_di); } // Deallocation support - no pointer fields to deallocate void deallocate_contents(ClassLoaderData* loader_data) {} // GC support void set_size(int object_size_in_bytes) { _size = object_size_in_bytes; } // Printing #ifndef PRODUCT void print_on (outputStream* st) const; #endif void print_value_on(outputStream* st) const; #ifndef PRODUCT // printing support for method data void print_data_on(outputStream* st) const; #endif const char* internal_name() const { return "{method data}"; } // verification void verify_on(outputStream* st); void verify_data_on(outputStream* st); static bool profile_parameters_for_method(methodHandle m); static bool profile_arguments(); static bool profile_arguments_jsr292_only(); static bool profile_return(); static bool profile_parameters(); static bool profile_return_jsr292_only(); void clean_method_data(BoolObjectClosure* is_alive); void clean_weak_method_links(); }; #endif // SHARE_VM_OOPS_METHODDATAOOP_HPP