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view src/share/vm/utilities/globalDefinitions.hpp @ 2035:0fa27f37d4d4
6977804: G1: remove the zero-filling thread
Summary: This changeset removes the zero-filling thread from G1 and collapses the two free region lists we had before (the "free" and "unclean" lists) into one. The new free list uses the new heap region sets / lists abstractions that we'll ultimately use it to keep track of all regions in the heap. A heap region set was also introduced for the humongous regions. Finally, this change increases the concurrency between the thread that completes freeing regions (after a cleanup pause) and the rest of the system (before we'd have to wait for said thread to complete before allocating a new region). The changest also includes a lot of refactoring and code simplification.
Reviewed-by: jcoomes, johnc
| author | tonyp |
|---|---|
| date | Wed, 19 Jan 2011 19:30:42 -0500 |
| parents | f95d63e2154a |
| children |
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/* * Copyright (c) 1997, 2011, 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_UTILITIES_GLOBALDEFINITIONS_HPP #define SHARE_VM_UTILITIES_GLOBALDEFINITIONS_HPP #ifdef TARGET_COMPILER_gcc # include "utilities/globalDefinitions_gcc.hpp" #endif #ifdef TARGET_COMPILER_visCPP # include "utilities/globalDefinitions_visCPP.hpp" #endif #ifdef TARGET_COMPILER_sparcWorks # include "utilities/globalDefinitions_sparcWorks.hpp" #endif #include "utilities/macros.hpp" // This file holds all globally used constants & types, class (forward) // declarations and a few frequently used utility functions. //---------------------------------------------------------------------------------------------------- // Constants const int LogBytesPerShort = 1; const int LogBytesPerInt = 2; #ifdef _LP64 const int LogBytesPerWord = 3; #else const int LogBytesPerWord = 2; #endif const int LogBytesPerLong = 3; const int BytesPerShort = 1 << LogBytesPerShort; const int BytesPerInt = 1 << LogBytesPerInt; const int BytesPerWord = 1 << LogBytesPerWord; const int BytesPerLong = 1 << LogBytesPerLong; const int LogBitsPerByte = 3; const int LogBitsPerShort = LogBitsPerByte + LogBytesPerShort; const int LogBitsPerInt = LogBitsPerByte + LogBytesPerInt; const int LogBitsPerWord = LogBitsPerByte + LogBytesPerWord; const int LogBitsPerLong = LogBitsPerByte + LogBytesPerLong; const int BitsPerByte = 1 << LogBitsPerByte; const int BitsPerShort = 1 << LogBitsPerShort; const int BitsPerInt = 1 << LogBitsPerInt; const int BitsPerWord = 1 << LogBitsPerWord; const int BitsPerLong = 1 << LogBitsPerLong; const int WordAlignmentMask = (1 << LogBytesPerWord) - 1; const int LongAlignmentMask = (1 << LogBytesPerLong) - 1; const int WordsPerLong = 2; // Number of stack entries for longs const int oopSize = sizeof(char*); // Full-width oop extern int heapOopSize; // Oop within a java object const int wordSize = sizeof(char*); const int longSize = sizeof(jlong); const int jintSize = sizeof(jint); const int size_tSize = sizeof(size_t); const int BytesPerOop = BytesPerWord; // Full-width oop extern int LogBytesPerHeapOop; // Oop within a java object extern int LogBitsPerHeapOop; extern int BytesPerHeapOop; extern int BitsPerHeapOop; // Oop encoding heap max extern uint64_t OopEncodingHeapMax; const int BitsPerJavaInteger = 32; const int BitsPerJavaLong = 64; const int BitsPerSize_t = size_tSize * BitsPerByte; // Size of a char[] needed to represent a jint as a string in decimal. const int jintAsStringSize = 12; // In fact this should be // log2_intptr(sizeof(class JavaThread)) - log2_intptr(64); // see os::set_memory_serialize_page() #ifdef _LP64 const int SerializePageShiftCount = 4; #else const int SerializePageShiftCount = 3; #endif // An opaque struct of heap-word width, so that HeapWord* can be a generic // pointer into the heap. We require that object sizes be measured in // units of heap words, so that that // HeapWord* hw; // hw += oop(hw)->foo(); // works, where foo is a method (like size or scavenge) that returns the // object size. class HeapWord { friend class VMStructs; private: char* i; #ifndef PRODUCT public: char* value() { return i; } #endif }; // HeapWordSize must be 2^LogHeapWordSize. const int HeapWordSize = sizeof(HeapWord); #ifdef _LP64 const int LogHeapWordSize = 3; #else const int LogHeapWordSize = 2; #endif const int HeapWordsPerLong = BytesPerLong / HeapWordSize; const int LogHeapWordsPerLong = LogBytesPerLong - LogHeapWordSize; // The larger HeapWordSize for 64bit requires larger heaps // for the same application running in 64bit. See bug 4967770. // The minimum alignment to a heap word size is done. Other // parts of the memory system may required additional alignment // and are responsible for those alignments. #ifdef _LP64 #define ScaleForWordSize(x) align_size_down_((x) * 13 / 10, HeapWordSize) #else #define ScaleForWordSize(x) (x) #endif // The minimum number of native machine words necessary to contain "byte_size" // bytes. inline size_t heap_word_size(size_t byte_size) { return (byte_size + (HeapWordSize-1)) >> LogHeapWordSize; } const size_t K = 1024; const size_t M = K*K; const size_t G = M*K; const size_t HWperKB = K / sizeof(HeapWord); const size_t LOG_K = 10; const size_t LOG_M = 2 * LOG_K; const size_t LOG_G = 2 * LOG_M; const jint min_jint = (jint)1 << (sizeof(jint)*BitsPerByte-1); // 0x80000000 == smallest jint const jint max_jint = (juint)min_jint - 1; // 0x7FFFFFFF == largest jint // Constants for converting from a base unit to milli-base units. For // example from seconds to milliseconds and microseconds const int MILLIUNITS = 1000; // milli units per base unit const int MICROUNITS = 1000000; // micro units per base unit const int NANOUNITS = 1000000000; // nano units per base unit inline const char* proper_unit_for_byte_size(size_t s) { if (s >= 10*M) { return "M"; } else if (s >= 10*K) { return "K"; } else { return "B"; } } inline size_t byte_size_in_proper_unit(size_t s) { if (s >= 10*M) { return s/M; } else if (s >= 10*K) { return s/K; } else { return s; } } //---------------------------------------------------------------------------------------------------- // VM type definitions // intx and uintx are the 'extended' int and 'extended' unsigned int types; // they are 32bit wide on a 32-bit platform, and 64bit wide on a 64bit platform. typedef intptr_t intx; typedef uintptr_t uintx; const intx min_intx = (intx)1 << (sizeof(intx)*BitsPerByte-1); const intx max_intx = (uintx)min_intx - 1; const uintx max_uintx = (uintx)-1; // Table of values: // sizeof intx 4 8 // min_intx 0x80000000 0x8000000000000000 // max_intx 0x7FFFFFFF 0x7FFFFFFFFFFFFFFF // max_uintx 0xFFFFFFFF 0xFFFFFFFFFFFFFFFF typedef unsigned int uint; NEEDS_CLEANUP //---------------------------------------------------------------------------------------------------- // Java type definitions // All kinds of 'plain' byte addresses typedef signed char s_char; typedef unsigned char u_char; typedef u_char* address; typedef uintptr_t address_word; // unsigned integer which will hold a pointer // except for some implementations of a C++ // linkage pointer to function. Should never // need one of those to be placed in this // type anyway. // Utility functions to "portably" (?) bit twiddle pointers // Where portable means keep ANSI C++ compilers quiet inline address set_address_bits(address x, int m) { return address(intptr_t(x) | m); } inline address clear_address_bits(address x, int m) { return address(intptr_t(x) & ~m); } // Utility functions to "portably" make cast to/from function pointers. inline address_word mask_address_bits(address x, int m) { return address_word(x) & m; } inline address_word castable_address(address x) { return address_word(x) ; } inline address_word castable_address(void* x) { return address_word(x) ; } // Pointer subtraction. // The idea here is to avoid ptrdiff_t, which is signed and so doesn't have // the range we might need to find differences from one end of the heap // to the other. // A typical use might be: // if (pointer_delta(end(), top()) >= size) { // // enough room for an object of size // ... // and then additions like // ... top() + size ... // are safe because we know that top() is at least size below end(). inline size_t pointer_delta(const void* left, const void* right, size_t element_size) { return (((uintptr_t) left) - ((uintptr_t) right)) / element_size; } // A version specialized for HeapWord*'s. inline size_t pointer_delta(const HeapWord* left, const HeapWord* right) { return pointer_delta(left, right, sizeof(HeapWord)); } // // ANSI C++ does not allow casting from one pointer type to a function pointer // directly without at best a warning. This macro accomplishes it silently // In every case that is present at this point the value be cast is a pointer // to a C linkage function. In somecase the type used for the cast reflects // that linkage and a picky compiler would not complain. In other cases because // there is no convenient place to place a typedef with extern C linkage (i.e // a platform dependent header file) it doesn't. At this point no compiler seems // picky enough to catch these instances (which are few). It is possible that // using templates could fix these for all cases. This use of templates is likely // so far from the middle of the road that it is likely to be problematic in // many C++ compilers. // #define CAST_TO_FN_PTR(func_type, value) ((func_type)(castable_address(value))) #define CAST_FROM_FN_PTR(new_type, func_ptr) ((new_type)((address_word)(func_ptr))) // Unsigned byte types for os and stream.hpp // Unsigned one, two, four and eigth byte quantities used for describing // the .class file format. See JVM book chapter 4. typedef jubyte u1; typedef jushort u2; typedef juint u4; typedef julong u8; const jubyte max_jubyte = (jubyte)-1; // 0xFF largest jubyte const jushort max_jushort = (jushort)-1; // 0xFFFF largest jushort const juint max_juint = (juint)-1; // 0xFFFFFFFF largest juint const julong max_julong = (julong)-1; // 0xFF....FF largest julong //---------------------------------------------------------------------------------------------------- // JVM spec restrictions const int max_method_code_size = 64*K - 1; // JVM spec, 2nd ed. section 4.8.1 (p.134) //---------------------------------------------------------------------------------------------------- // HotSwap - for JVMTI aka Class File Replacement and PopFrame // // Determines whether on-the-fly class replacement and frame popping are enabled. #define HOTSWAP //---------------------------------------------------------------------------------------------------- // Object alignment, in units of HeapWords. // // Minimum is max(BytesPerLong, BytesPerDouble, BytesPerOop) / HeapWordSize, so jlong, jdouble and // reference fields can be naturally aligned. extern int MinObjAlignment; extern int MinObjAlignmentInBytes; extern int MinObjAlignmentInBytesMask; extern int LogMinObjAlignment; extern int LogMinObjAlignmentInBytes; // Machine dependent stuff #ifdef TARGET_ARCH_x86 # include "globalDefinitions_x86.hpp" #endif #ifdef TARGET_ARCH_sparc # include "globalDefinitions_sparc.hpp" #endif #ifdef TARGET_ARCH_zero # include "globalDefinitions_zero.hpp" #endif // The byte alignment to be used by Arena::Amalloc. See bugid 4169348. // Note: this value must be a power of 2 #define ARENA_AMALLOC_ALIGNMENT (2*BytesPerWord) // Signed variants of alignment helpers. There are two versions of each, a macro // for use in places like enum definitions that require compile-time constant // expressions and a function for all other places so as to get type checking. #define align_size_up_(size, alignment) (((size) + ((alignment) - 1)) & ~((alignment) - 1)) inline intptr_t align_size_up(intptr_t size, intptr_t alignment) { return align_size_up_(size, alignment); } #define align_size_down_(size, alignment) ((size) & ~((alignment) - 1)) inline intptr_t align_size_down(intptr_t size, intptr_t alignment) { return align_size_down_(size, alignment); } // Align objects by rounding up their size, in HeapWord units. #define align_object_size_(size) align_size_up_(size, MinObjAlignment) inline intptr_t align_object_size(intptr_t size) { return align_size_up(size, MinObjAlignment); } inline bool is_object_aligned(intptr_t addr) { return addr == align_object_size(addr); } // Pad out certain offsets to jlong alignment, in HeapWord units. inline intptr_t align_object_offset(intptr_t offset) { return align_size_up(offset, HeapWordsPerLong); } // The expected size in bytes of a cache line, used to pad data structures. #define DEFAULT_CACHE_LINE_SIZE 64 // Bytes needed to pad type to avoid cache-line sharing; alignment should be the // expected cache line size (a power of two). The first addend avoids sharing // when the start address is not a multiple of alignment; the second maintains // alignment of starting addresses that happen to be a multiple. #define PADDING_SIZE(type, alignment) \ ((alignment) + align_size_up_(sizeof(type), alignment)) // Templates to create a subclass padded to avoid cache line sharing. These are // effective only when applied to derived-most (leaf) classes. // When no args are passed to the base ctor. template <class T, size_t alignment = DEFAULT_CACHE_LINE_SIZE> class Padded: public T { private: char _pad_buf_[PADDING_SIZE(T, alignment)]; }; // When either 0 or 1 args may be passed to the base ctor. template <class T, typename Arg1T, size_t alignment = DEFAULT_CACHE_LINE_SIZE> class Padded01: public T { public: Padded01(): T() { } Padded01(Arg1T arg1): T(arg1) { } private: char _pad_buf_[PADDING_SIZE(T, alignment)]; }; //---------------------------------------------------------------------------------------------------- // Utility macros for compilers // used to silence compiler warnings #define Unused_Variable(var) var //---------------------------------------------------------------------------------------------------- // Miscellaneous // 6302670 Eliminate Hotspot __fabsf dependency // All fabs() callers should call this function instead, which will implicitly // convert the operand to double, avoiding a dependency on __fabsf which // doesn't exist in early versions of Solaris 8. inline double fabsd(double value) { return fabs(value); } inline jint low (jlong value) { return jint(value); } inline jint high(jlong value) { return jint(value >> 32); } // the fancy casts are a hopefully portable way // to do unsigned 32 to 64 bit type conversion inline void set_low (jlong* value, jint low ) { *value &= (jlong)0xffffffff << 32; *value |= (jlong)(julong)(juint)low; } inline void set_high(jlong* value, jint high) { *value &= (jlong)(julong)(juint)0xffffffff; *value |= (jlong)high << 32; } inline jlong jlong_from(jint h, jint l) { jlong result = 0; // initialization to avoid warning set_high(&result, h); set_low(&result, l); return result; } union jlong_accessor { jint words[2]; jlong long_value; }; void basic_types_init(); // cannot define here; uses assert // NOTE: replicated in SA in vm/agent/sun/jvm/hotspot/runtime/BasicType.java enum BasicType { T_BOOLEAN = 4, T_CHAR = 5, T_FLOAT = 6, T_DOUBLE = 7, T_BYTE = 8, T_SHORT = 9, T_INT = 10, T_LONG = 11, T_OBJECT = 12, T_ARRAY = 13, T_VOID = 14, T_ADDRESS = 15, T_NARROWOOP= 16, T_CONFLICT = 17, // for stack value type with conflicting contents T_ILLEGAL = 99 }; inline bool is_java_primitive(BasicType t) { return T_BOOLEAN <= t && t <= T_LONG; } inline bool is_subword_type(BasicType t) { // these guys are processed exactly like T_INT in calling sequences: return (t == T_BOOLEAN || t == T_CHAR || t == T_BYTE || t == T_SHORT); } inline bool is_signed_subword_type(BasicType t) { return (t == T_BYTE || t == T_SHORT); } // Convert a char from a classfile signature to a BasicType inline BasicType char2type(char c) { switch( c ) { case 'B': return T_BYTE; case 'C': return T_CHAR; case 'D': return T_DOUBLE; case 'F': return T_FLOAT; case 'I': return T_INT; case 'J': return T_LONG; case 'S': return T_SHORT; case 'Z': return T_BOOLEAN; case 'V': return T_VOID; case 'L': return T_OBJECT; case '[': return T_ARRAY; } return T_ILLEGAL; } extern char type2char_tab[T_CONFLICT+1]; // Map a BasicType to a jchar inline char type2char(BasicType t) { return (uint)t < T_CONFLICT+1 ? type2char_tab[t] : 0; } extern int type2size[T_CONFLICT+1]; // Map BasicType to result stack elements extern const char* type2name_tab[T_CONFLICT+1]; // Map a BasicType to a jchar inline const char* type2name(BasicType t) { return (uint)t < T_CONFLICT+1 ? type2name_tab[t] : NULL; } extern BasicType name2type(const char* name); // Auxilary math routines // least common multiple extern size_t lcm(size_t a, size_t b); // NOTE: replicated in SA in vm/agent/sun/jvm/hotspot/runtime/BasicType.java enum BasicTypeSize { T_BOOLEAN_size = 1, T_CHAR_size = 1, T_FLOAT_size = 1, T_DOUBLE_size = 2, T_BYTE_size = 1, T_SHORT_size = 1, T_INT_size = 1, T_LONG_size = 2, T_OBJECT_size = 1, T_ARRAY_size = 1, T_NARROWOOP_size = 1, T_VOID_size = 0 }; // maps a BasicType to its instance field storage type: // all sub-word integral types are widened to T_INT extern BasicType type2field[T_CONFLICT+1]; extern BasicType type2wfield[T_CONFLICT+1]; // size in bytes enum ArrayElementSize { T_BOOLEAN_aelem_bytes = 1, T_CHAR_aelem_bytes = 2, T_FLOAT_aelem_bytes = 4, T_DOUBLE_aelem_bytes = 8, T_BYTE_aelem_bytes = 1, T_SHORT_aelem_bytes = 2, T_INT_aelem_bytes = 4, T_LONG_aelem_bytes = 8, #ifdef _LP64 T_OBJECT_aelem_bytes = 8, T_ARRAY_aelem_bytes = 8, #else T_OBJECT_aelem_bytes = 4, T_ARRAY_aelem_bytes = 4, #endif T_NARROWOOP_aelem_bytes = 4, T_VOID_aelem_bytes = 0 }; extern int _type2aelembytes[T_CONFLICT+1]; // maps a BasicType to nof bytes used by its array element #ifdef ASSERT extern int type2aelembytes(BasicType t, bool allow_address = false); // asserts #else inline int type2aelembytes(BasicType t, bool allow_address = false) { return _type2aelembytes[t]; } #endif // JavaValue serves as a container for arbitrary Java values. class JavaValue { public: typedef union JavaCallValue { jfloat f; jdouble d; jint i; jlong l; jobject h; } JavaCallValue; private: BasicType _type; JavaCallValue _value; public: JavaValue(BasicType t = T_ILLEGAL) { _type = t; } JavaValue(jfloat value) { _type = T_FLOAT; _value.f = value; } JavaValue(jdouble value) { _type = T_DOUBLE; _value.d = value; } jfloat get_jfloat() const { return _value.f; } jdouble get_jdouble() const { return _value.d; } jint get_jint() const { return _value.i; } jlong get_jlong() const { return _value.l; } jobject get_jobject() const { return _value.h; } JavaCallValue* get_value_addr() { return &_value; } BasicType get_type() const { return _type; } void set_jfloat(jfloat f) { _value.f = f;} void set_jdouble(jdouble d) { _value.d = d;} void set_jint(jint i) { _value.i = i;} void set_jlong(jlong l) { _value.l = l;} void set_jobject(jobject h) { _value.h = h;} void set_type(BasicType t) { _type = t; } jboolean get_jboolean() const { return (jboolean) (_value.i);} jbyte get_jbyte() const { return (jbyte) (_value.i);} jchar get_jchar() const { return (jchar) (_value.i);} jshort get_jshort() const { return (jshort) (_value.i);} }; #define STACK_BIAS 0 // V9 Sparc CPU's running in 64 Bit mode use a stack bias of 7ff // in order to extend the reach of the stack pointer. #if defined(SPARC) && defined(_LP64) #undef STACK_BIAS #define STACK_BIAS 0x7ff #endif // TosState describes the top-of-stack state before and after the execution of // a bytecode or method. The top-of-stack value may be cached in one or more CPU // registers. The TosState corresponds to the 'machine represention' of this cached // value. There's 4 states corresponding to the JAVA types int, long, float & double // as well as a 5th state in case the top-of-stack value is actually on the top // of stack (in memory) and thus not cached. The atos state corresponds to the itos // state when it comes to machine representation but is used separately for (oop) // type specific operations (e.g. verification code). enum TosState { // describes the tos cache contents btos = 0, // byte, bool tos cached ctos = 1, // char tos cached stos = 2, // short tos cached itos = 3, // int tos cached ltos = 4, // long tos cached ftos = 5, // float tos cached dtos = 6, // double tos cached atos = 7, // object cached vtos = 8, // tos not cached number_of_states, ilgl // illegal state: should not occur }; inline TosState as_TosState(BasicType type) { switch (type) { case T_BYTE : return btos; case T_BOOLEAN: return btos; // FIXME: Add ztos case T_CHAR : return ctos; case T_SHORT : return stos; case T_INT : return itos; case T_LONG : return ltos; case T_FLOAT : return ftos; case T_DOUBLE : return dtos; case T_VOID : return vtos; case T_ARRAY : // fall through case T_OBJECT : return atos; } return ilgl; } inline BasicType as_BasicType(TosState state) { switch (state) { //case ztos: return T_BOOLEAN;//FIXME case btos : return T_BYTE; case ctos : return T_CHAR; case stos : return T_SHORT; case itos : return T_INT; case ltos : return T_LONG; case ftos : return T_FLOAT; case dtos : return T_DOUBLE; case atos : return T_OBJECT; case vtos : return T_VOID; } return T_ILLEGAL; } // Helper function to convert BasicType info into TosState // Note: Cannot define here as it uses global constant at the time being. TosState as_TosState(BasicType type); // ReferenceType is used to distinguish between java/lang/ref/Reference subclasses enum ReferenceType { REF_NONE, // Regular class REF_OTHER, // Subclass of java/lang/ref/Reference, but not subclass of one of the classes below REF_SOFT, // Subclass of java/lang/ref/SoftReference REF_WEAK, // Subclass of java/lang/ref/WeakReference REF_FINAL, // Subclass of java/lang/ref/FinalReference REF_PHANTOM // Subclass of java/lang/ref/PhantomReference }; // JavaThreadState keeps track of which part of the code a thread is executing in. This // information is needed by the safepoint code. // // There are 4 essential states: // // _thread_new : Just started, but not executed init. code yet (most likely still in OS init code) // _thread_in_native : In native code. This is a safepoint region, since all oops will be in jobject handles // _thread_in_vm : Executing in the vm // _thread_in_Java : Executing either interpreted or compiled Java code (or could be in a stub) // // Each state has an associated xxxx_trans state, which is an intermediate state used when a thread is in // a transition from one state to another. These extra states makes it possible for the safepoint code to // handle certain thread_states without having to suspend the thread - making the safepoint code faster. // // Given a state, the xxx_trans state can always be found by adding 1. // enum JavaThreadState { _thread_uninitialized = 0, // should never happen (missing initialization) _thread_new = 2, // just starting up, i.e., in process of being initialized _thread_new_trans = 3, // corresponding transition state (not used, included for completness) _thread_in_native = 4, // running in native code _thread_in_native_trans = 5, // corresponding transition state _thread_in_vm = 6, // running in VM _thread_in_vm_trans = 7, // corresponding transition state _thread_in_Java = 8, // running in Java or in stub code _thread_in_Java_trans = 9, // corresponding transition state (not used, included for completness) _thread_blocked = 10, // blocked in vm _thread_blocked_trans = 11, // corresponding transition state _thread_max_state = 12 // maximum thread state+1 - used for statistics allocation }; // Handy constants for deciding which compiler mode to use. enum MethodCompilation { InvocationEntryBci = -1, // i.e., not a on-stack replacement compilation InvalidOSREntryBci = -2 }; // Enumeration to distinguish tiers of compilation enum CompLevel { CompLevel_any = -1, CompLevel_all = -1, CompLevel_none = 0, // Interpreter CompLevel_simple = 1, // C1 CompLevel_limited_profile = 2, // C1, invocation & backedge counters CompLevel_full_profile = 3, // C1, invocation & backedge counters + mdo CompLevel_full_optimization = 4, // C2 #if defined(COMPILER2) CompLevel_highest_tier = CompLevel_full_optimization, // pure C2 and tiered #elif defined(COMPILER1) CompLevel_highest_tier = CompLevel_simple, // pure C1 #else CompLevel_highest_tier = CompLevel_none, #endif #if defined(TIERED) CompLevel_initial_compile = CompLevel_full_profile // tiered #elif defined(COMPILER1) CompLevel_initial_compile = CompLevel_simple // pure C1 #elif defined(COMPILER2) CompLevel_initial_compile = CompLevel_full_optimization // pure C2 #else CompLevel_initial_compile = CompLevel_none #endif }; inline bool is_c1_compile(int comp_level) { return comp_level > CompLevel_none && comp_level < CompLevel_full_optimization; } inline bool is_c2_compile(int comp_level) { return comp_level == CompLevel_full_optimization; } inline bool is_highest_tier_compile(int comp_level) { return comp_level == CompLevel_highest_tier; } //---------------------------------------------------------------------------------------------------- // 'Forward' declarations of frequently used classes // (in order to reduce interface dependencies & reduce // number of unnecessary compilations after changes) class symbolTable; class ClassFileStream; class Event; class Thread; class VMThread; class JavaThread; class Threads; class VM_Operation; class VMOperationQueue; class CodeBlob; class nmethod; class OSRAdapter; class I2CAdapter; class C2IAdapter; class CompiledIC; class relocInfo; class ScopeDesc; class PcDesc; class Recompiler; class Recompilee; class RecompilationPolicy; class RFrame; class CompiledRFrame; class InterpretedRFrame; class frame; class vframe; class javaVFrame; class interpretedVFrame; class compiledVFrame; class deoptimizedVFrame; class externalVFrame; class entryVFrame; class RegisterMap; class Mutex; class Monitor; class BasicLock; class BasicObjectLock; class PeriodicTask; class JavaCallWrapper; class oopDesc; class NativeCall; class zone; class StubQueue; class outputStream; class ResourceArea; class DebugInformationRecorder; class ScopeValue; class CompressedStream; class DebugInfoReadStream; class DebugInfoWriteStream; class LocationValue; class ConstantValue; class IllegalValue; class PrivilegedElement; class MonitorArray; class MonitorInfo; class OffsetClosure; class OopMapCache; class InterpreterOopMap; class OopMapCacheEntry; class OSThread; typedef int (*OSThreadStartFunc)(void*); class Space; class JavaValue; class methodHandle; class JavaCallArguments; // Basic support for errors (general debug facilities not defined at this point fo the include phase) extern void basic_fatal(const char* msg); //---------------------------------------------------------------------------------------------------- // Special constants for debugging const jint badInt = -3; // generic "bad int" value const long badAddressVal = -2; // generic "bad address" value const long badOopVal = -1; // generic "bad oop" value const intptr_t badHeapOopVal = (intptr_t) CONST64(0x2BAD4B0BBAADBABE); // value used to zap heap after GC const int badHandleValue = 0xBC; // value used to zap vm handle area const int badResourceValue = 0xAB; // value used to zap resource area const int freeBlockPad = 0xBA; // value used to pad freed blocks. const int uninitBlockPad = 0xF1; // value used to zap newly malloc'd blocks. const intptr_t badJNIHandleVal = (intptr_t) CONST64(0xFEFEFEFEFEFEFEFE); // value used to zap jni handle area const juint badHeapWordVal = 0xBAADBABE; // value used to zap heap after GC const int badCodeHeapNewVal= 0xCC; // value used to zap Code heap at allocation const int badCodeHeapFreeVal = 0xDD; // value used to zap Code heap at deallocation // (These must be implemented as #defines because C++ compilers are // not obligated to inline non-integral constants!) #define badAddress ((address)::badAddressVal) #define badOop ((oop)::badOopVal) #define badHeapWord (::badHeapWordVal) #define badJNIHandle ((oop)::badJNIHandleVal) // Default TaskQueue size is 16K (32-bit) or 128K (64-bit) #define TASKQUEUE_SIZE (NOT_LP64(1<<14) LP64_ONLY(1<<17)) //---------------------------------------------------------------------------------------------------- // Utility functions for bitfield manipulations const intptr_t AllBits = ~0; // all bits set in a word const intptr_t NoBits = 0; // no bits set in a word const jlong NoLongBits = 0; // no bits set in a long const intptr_t OneBit = 1; // only right_most bit set in a word // get a word with the n.th or the right-most or left-most n bits set // (note: #define used only so that they can be used in enum constant definitions) #define nth_bit(n) (n >= BitsPerWord ? 0 : OneBit << (n)) #define right_n_bits(n) (nth_bit(n) - 1) #define left_n_bits(n) (right_n_bits(n) << (n >= BitsPerWord ? 0 : (BitsPerWord - n))) // bit-operations using a mask m inline void set_bits (intptr_t& x, intptr_t m) { x |= m; } inline void clear_bits (intptr_t& x, intptr_t m) { x &= ~m; } inline intptr_t mask_bits (intptr_t x, intptr_t m) { return x & m; } inline jlong mask_long_bits (jlong x, jlong m) { return x & m; } inline bool mask_bits_are_true (intptr_t flags, intptr_t mask) { return (flags & mask) == mask; } // bit-operations using the n.th bit inline void set_nth_bit(intptr_t& x, int n) { set_bits (x, nth_bit(n)); } inline void clear_nth_bit(intptr_t& x, int n) { clear_bits(x, nth_bit(n)); } inline bool is_set_nth_bit(intptr_t x, int n) { return mask_bits (x, nth_bit(n)) != NoBits; } // returns the bitfield of x starting at start_bit_no with length field_length (no sign-extension!) inline intptr_t bitfield(intptr_t x, int start_bit_no, int field_length) { return mask_bits(x >> start_bit_no, right_n_bits(field_length)); } //---------------------------------------------------------------------------------------------------- // Utility functions for integers // Avoid use of global min/max macros which may cause unwanted double // evaluation of arguments. #ifdef max #undef max #endif #ifdef min #undef min #endif #define max(a,b) Do_not_use_max_use_MAX2_instead #define min(a,b) Do_not_use_min_use_MIN2_instead // It is necessary to use templates here. Having normal overloaded // functions does not work because it is necessary to provide both 32- // and 64-bit overloaded functions, which does not work, and having // explicitly-typed versions of these routines (i.e., MAX2I, MAX2L) // will be even more error-prone than macros. template<class T> inline T MAX2(T a, T b) { return (a > b) ? a : b; } template<class T> inline T MIN2(T a, T b) { return (a < b) ? a : b; } template<class T> inline T MAX3(T a, T b, T c) { return MAX2(MAX2(a, b), c); } template<class T> inline T MIN3(T a, T b, T c) { return MIN2(MIN2(a, b), c); } template<class T> inline T MAX4(T a, T b, T c, T d) { return MAX2(MAX3(a, b, c), d); } template<class T> inline T MIN4(T a, T b, T c, T d) { return MIN2(MIN3(a, b, c), d); } template<class T> inline T ABS(T x) { return (x > 0) ? x : -x; } // true if x is a power of 2, false otherwise inline bool is_power_of_2(intptr_t x) { return ((x != NoBits) && (mask_bits(x, x - 1) == NoBits)); } // long version of is_power_of_2 inline bool is_power_of_2_long(jlong x) { return ((x != NoLongBits) && (mask_long_bits(x, x - 1) == NoLongBits)); } //* largest i such that 2^i <= x // A negative value of 'x' will return '31' inline int log2_intptr(intptr_t x) { int i = -1; uintptr_t p = 1; while (p != 0 && p <= (uintptr_t)x) { // p = 2^(i+1) && p <= x (i.e., 2^(i+1) <= x) i++; p *= 2; } // p = 2^(i+1) && x < p (i.e., 2^i <= x < 2^(i+1)) // (if p = 0 then overflow occurred and i = 31) return i; } //* largest i such that 2^i <= x // A negative value of 'x' will return '63' inline int log2_long(jlong x) { int i = -1; julong p = 1; while (p != 0 && p <= (julong)x) { // p = 2^(i+1) && p <= x (i.e., 2^(i+1) <= x) i++; p *= 2; } // p = 2^(i+1) && x < p (i.e., 2^i <= x < 2^(i+1)) // (if p = 0 then overflow occurred and i = 63) return i; } //* the argument must be exactly a power of 2 inline int exact_log2(intptr_t x) { #ifdef ASSERT if (!is_power_of_2(x)) basic_fatal("x must be a power of 2"); #endif return log2_intptr(x); } //* the argument must be exactly a power of 2 inline int exact_log2_long(jlong x) { #ifdef ASSERT if (!is_power_of_2_long(x)) basic_fatal("x must be a power of 2"); #endif return log2_long(x); } // returns integer round-up to the nearest multiple of s (s must be a power of two) inline intptr_t round_to(intptr_t x, uintx s) { #ifdef ASSERT if (!is_power_of_2(s)) basic_fatal("s must be a power of 2"); #endif const uintx m = s - 1; return mask_bits(x + m, ~m); } // returns integer round-down to the nearest multiple of s (s must be a power of two) inline intptr_t round_down(intptr_t x, uintx s) { #ifdef ASSERT if (!is_power_of_2(s)) basic_fatal("s must be a power of 2"); #endif const uintx m = s - 1; return mask_bits(x, ~m); } inline bool is_odd (intx x) { return x & 1; } inline bool is_even(intx x) { return !is_odd(x); } // "to" should be greater than "from." inline intx byte_size(void* from, void* to) { return (address)to - (address)from; } //---------------------------------------------------------------------------------------------------- // Avoid non-portable casts with these routines (DEPRECATED) // NOTE: USE Bytes class INSTEAD WHERE POSSIBLE // Bytes is optimized machine-specifically and may be much faster then the portable routines below. // Given sequence of four bytes, build into a 32-bit word // following the conventions used in class files. // On the 386, this could be realized with a simple address cast. // // This routine takes eight bytes: inline u8 build_u8_from( u1 c1, u1 c2, u1 c3, u1 c4, u1 c5, u1 c6, u1 c7, u1 c8 ) { return (( u8(c1) << 56 ) & ( u8(0xff) << 56 )) | (( u8(c2) << 48 ) & ( u8(0xff) << 48 )) | (( u8(c3) << 40 ) & ( u8(0xff) << 40 )) | (( u8(c4) << 32 ) & ( u8(0xff) << 32 )) | (( u8(c5) << 24 ) & ( u8(0xff) << 24 )) | (( u8(c6) << 16 ) & ( u8(0xff) << 16 )) | (( u8(c7) << 8 ) & ( u8(0xff) << 8 )) | (( u8(c8) << 0 ) & ( u8(0xff) << 0 )); } // This routine takes four bytes: inline u4 build_u4_from( u1 c1, u1 c2, u1 c3, u1 c4 ) { return (( u4(c1) << 24 ) & 0xff000000) | (( u4(c2) << 16 ) & 0x00ff0000) | (( u4(c3) << 8 ) & 0x0000ff00) | (( u4(c4) << 0 ) & 0x000000ff); } // And this one works if the four bytes are contiguous in memory: inline u4 build_u4_from( u1* p ) { return build_u4_from( p[0], p[1], p[2], p[3] ); } // Ditto for two-byte ints: inline u2 build_u2_from( u1 c1, u1 c2 ) { return u2((( u2(c1) << 8 ) & 0xff00) | (( u2(c2) << 0 ) & 0x00ff)); } // And this one works if the two bytes are contiguous in memory: inline u2 build_u2_from( u1* p ) { return build_u2_from( p[0], p[1] ); } // Ditto for floats: inline jfloat build_float_from( u1 c1, u1 c2, u1 c3, u1 c4 ) { u4 u = build_u4_from( c1, c2, c3, c4 ); return *(jfloat*)&u; } inline jfloat build_float_from( u1* p ) { u4 u = build_u4_from( p ); return *(jfloat*)&u; } // now (64-bit) longs inline jlong build_long_from( u1 c1, u1 c2, u1 c3, u1 c4, u1 c5, u1 c6, u1 c7, u1 c8 ) { return (( jlong(c1) << 56 ) & ( jlong(0xff) << 56 )) | (( jlong(c2) << 48 ) & ( jlong(0xff) << 48 )) | (( jlong(c3) << 40 ) & ( jlong(0xff) << 40 )) | (( jlong(c4) << 32 ) & ( jlong(0xff) << 32 )) | (( jlong(c5) << 24 ) & ( jlong(0xff) << 24 )) | (( jlong(c6) << 16 ) & ( jlong(0xff) << 16 )) | (( jlong(c7) << 8 ) & ( jlong(0xff) << 8 )) | (( jlong(c8) << 0 ) & ( jlong(0xff) << 0 )); } inline jlong build_long_from( u1* p ) { return build_long_from( p[0], p[1], p[2], p[3], p[4], p[5], p[6], p[7] ); } // Doubles, too! inline jdouble build_double_from( u1 c1, u1 c2, u1 c3, u1 c4, u1 c5, u1 c6, u1 c7, u1 c8 ) { jlong u = build_long_from( c1, c2, c3, c4, c5, c6, c7, c8 ); return *(jdouble*)&u; } inline jdouble build_double_from( u1* p ) { jlong u = build_long_from( p ); return *(jdouble*)&u; } // Portable routines to go the other way: inline void explode_short_to( u2 x, u1& c1, u1& c2 ) { c1 = u1(x >> 8); c2 = u1(x); } inline void explode_short_to( u2 x, u1* p ) { explode_short_to( x, p[0], p[1]); } inline void explode_int_to( u4 x, u1& c1, u1& c2, u1& c3, u1& c4 ) { c1 = u1(x >> 24); c2 = u1(x >> 16); c3 = u1(x >> 8); c4 = u1(x); } inline void explode_int_to( u4 x, u1* p ) { explode_int_to( x, p[0], p[1], p[2], p[3]); } // Pack and extract shorts to/from ints: inline int extract_low_short_from_int(jint x) { return x & 0xffff; } inline int extract_high_short_from_int(jint x) { return (x >> 16) & 0xffff; } inline int build_int_from_shorts( jushort low, jushort high ) { return ((int)((unsigned int)high << 16) | (unsigned int)low); } // Printf-style formatters for fixed- and variable-width types as pointers and // integers. // // Each compiler-specific definitions file (e.g., globalDefinitions_gcc.hpp) // must define the macro FORMAT64_MODIFIER, which is the modifier for '%x' or // '%d' formats to indicate a 64-bit quantity; commonly "l" (in LP64) or "ll" // (in ILP32). #define BOOL_TO_STR(__b) (__b) ? "true" : "false" // Format 32-bit quantities. #define INT32_FORMAT "%d" #define UINT32_FORMAT "%u" #define INT32_FORMAT_W(width) "%" #width "d" #define UINT32_FORMAT_W(width) "%" #width "u" #define PTR32_FORMAT "0x%08x" // Format 64-bit quantities. #define INT64_FORMAT "%" FORMAT64_MODIFIER "d" #define UINT64_FORMAT "%" FORMAT64_MODIFIER "u" #define PTR64_FORMAT "0x%016" FORMAT64_MODIFIER "x" #define INT64_FORMAT_W(width) "%" #width FORMAT64_MODIFIER "d" #define UINT64_FORMAT_W(width) "%" #width FORMAT64_MODIFIER "u" // Format macros that allow the field width to be specified. The width must be // a string literal (e.g., "8") or a macro that evaluates to one. #ifdef _LP64 #define UINTX_FORMAT_W(width) UINT64_FORMAT_W(width) #define SSIZE_FORMAT_W(width) INT64_FORMAT_W(width) #define SIZE_FORMAT_W(width) UINT64_FORMAT_W(width) #else #define UINTX_FORMAT_W(width) UINT32_FORMAT_W(width) #define SSIZE_FORMAT_W(width) INT32_FORMAT_W(width) #define SIZE_FORMAT_W(width) UINT32_FORMAT_W(width) #endif // _LP64 // Format pointers and size_t (or size_t-like integer types) which change size // between 32- and 64-bit. The pointer format theoretically should be "%p", // however, it has different output on different platforms. On Windows, the data // will be padded with zeros automatically. On Solaris, we can use "%016p" & // "%08p" on 64 bit & 32 bit platforms to make the data padded with extra zeros. // On Linux, "%016p" or "%08p" is not be allowed, at least on the latest GCC // 4.3.2. So we have to use "%016x" or "%08x" to simulate the printing format. // GCC 4.3.2, however requires the data to be converted to "intptr_t" when // using "%x". #ifdef _LP64 #define PTR_FORMAT PTR64_FORMAT #define UINTX_FORMAT UINT64_FORMAT #define INTX_FORMAT INT64_FORMAT #define SIZE_FORMAT UINT64_FORMAT #define SSIZE_FORMAT INT64_FORMAT #else // !_LP64 #define PTR_FORMAT PTR32_FORMAT #define UINTX_FORMAT UINT32_FORMAT #define INTX_FORMAT INT32_FORMAT #define SIZE_FORMAT UINT32_FORMAT #define SSIZE_FORMAT INT32_FORMAT #endif // _LP64 #define INTPTR_FORMAT PTR_FORMAT // Enable zap-a-lot if in debug version. # ifdef ASSERT # ifdef COMPILER2 # define ENABLE_ZAP_DEAD_LOCALS #endif /* COMPILER2 */ # endif /* ASSERT */ #define ARRAY_SIZE(array) (sizeof(array)/sizeof((array)[0])) #endif // SHARE_VM_UTILITIES_GLOBALDEFINITIONS_HPP