1 /*
   2  * Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
   3  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
   4  *
   5  * This code is free software; you can redistribute it and/or modify it
   6  * under the terms of the GNU General Public License version 2 only, as
   7  * published by the Free Software Foundation.
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   9  * This code is distributed in the hope that it will be useful, but WITHOUT
  10  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  11  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  12  * version 2 for more details (a copy is included in the LICENSE file that
  13  * accompanied this code).
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  17  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  18  *
  19  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  20  * or visit www.oracle.com if you need additional information or have any
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  24 
  25 #ifndef SHARE_VM_CODE_RELOCINFO_HPP
  26 #define SHARE_VM_CODE_RELOCINFO_HPP
  27 
  28 #include "memory/allocation.hpp"
  29 #include "utilities/top.hpp"
  30 
  31 class NativeMovConstReg;
  32 
  33 // Types in this file:
  34 //    relocInfo
  35 //      One element of an array of halfwords encoding compressed relocations.
  36 //      Also, the source of relocation types (relocInfo::oop_type, ...).
  37 //    Relocation
  38 //      A flyweight object representing a single relocation.
  39 //      It is fully unpacked from the compressed relocation array.
  40 //    metadata_Relocation, ... (subclasses of Relocation)
  41 //      The location of some type-specific operations (metadata_addr, ...).
  42 //      Also, the source of relocation specs (metadata_Relocation::spec, ...).
  43 //    oop_Relocation, ... (subclasses of Relocation)
  44 //      oops in the code stream (strings, class loaders)
  45 //      Also, the source of relocation specs (oop_Relocation::spec, ...).
  46 //    RelocationHolder
  47 //      A ValueObj type which acts as a union holding a Relocation object.
  48 //      Represents a relocation spec passed into a CodeBuffer during assembly.
  49 //    RelocIterator
  50 //      A StackObj which iterates over the relocations associated with
  51 //      a range of code addresses.  Can be used to operate a copy of code.
  52 //    BoundRelocation
  53 //      An _internal_ type shared by packers and unpackers of relocations.
  54 //      It pastes together a RelocationHolder with some pointers into
  55 //      code and relocInfo streams.
  56 
  57 
  58 // Notes on relocType:
  59 //
  60 // These hold enough information to read or write a value embedded in
  61 // the instructions of an CodeBlob.  They're used to update:
  62 //
  63 //   1) embedded oops     (isOop()          == true)
  64 //   2) inline caches     (isIC()           == true)
  65 //   3) runtime calls     (isRuntimeCall()  == true)
  66 //   4) internal word ref (isInternalWord() == true)
  67 //   5) external word ref (isExternalWord() == true)
  68 //
  69 // when objects move (GC) or if code moves (compacting the code heap).
  70 // They are also used to patch the code (if a call site must change)
  71 //
  72 // A relocInfo is represented in 16 bits:
  73 //   4 bits indicating the relocation type
  74 //  12 bits indicating the offset from the previous relocInfo address
  75 //
  76 // The offsets accumulate along the relocInfo stream to encode the
  77 // address within the CodeBlob, which is named RelocIterator::addr().
  78 // The address of a particular relocInfo always points to the first
  79 // byte of the relevant instruction (and not to any of its subfields
  80 // or embedded immediate constants).
  81 //
  82 // The offset value is scaled appropriately for the target machine.
  83 // (See relocInfo_<arch>.hpp for the offset scaling.)
  84 //
  85 // On some machines, there may also be a "format" field which may provide
  86 // additional information about the format of the instruction stream
  87 // at the corresponding code address.  The format value is usually zero.
  88 // Any machine (such as Intel) whose instructions can sometimes contain
  89 // more than one relocatable constant needs format codes to distinguish
  90 // which operand goes with a given relocation.
  91 //
  92 // If the target machine needs N format bits, the offset has 12-N bits,
  93 // the format is encoded between the offset and the type, and the
  94 // relocInfo_<arch>.hpp file has manifest constants for the format codes.
  95 //
  96 // If the type is "data_prefix_tag" then the offset bits are further encoded,
  97 // and in fact represent not a code-stream offset but some inline data.
  98 // The data takes the form of a counted sequence of halfwords, which
  99 // precedes the actual relocation record.  (Clients never see it directly.)
 100 // The interpetation of this extra data depends on the relocation type.
 101 //
 102 // On machines that have 32-bit immediate fields, there is usually
 103 // little need for relocation "prefix" data, because the instruction stream
 104 // is a perfectly reasonable place to store the value.  On machines in
 105 // which 32-bit values must be "split" across instructions, the relocation
 106 // data is the "true" specification of the value, which is then applied
 107 // to some field of the instruction (22 or 13 bits, on SPARC).
 108 //
 109 // Whenever the location of the CodeBlob changes, any PC-relative
 110 // relocations, and any internal_word_type relocations, must be reapplied.
 111 // After the GC runs, oop_type relocations must be reapplied.
 112 //
 113 //
 114 // Here are meanings of the types:
 115 //
 116 // relocInfo::none -- a filler record
 117 //   Value:  none
 118 //   Instruction: The corresponding code address is ignored
 119 //   Data:  Any data prefix and format code are ignored
 120 //   (This means that any relocInfo can be disabled by setting
 121 //   its type to none.  See relocInfo::remove.)
 122 //
 123 // relocInfo::oop_type, relocInfo::metadata_type -- a reference to an oop or meta data
 124 //   Value:  an oop, or else the address (handle) of an oop
 125 //   Instruction types: memory (load), set (load address)
 126 //   Data:  []       an oop stored in 4 bytes of instruction
 127 //          [n]      n is the index of an oop in the CodeBlob's oop pool
 128 //          [[N]n l] and l is a byte offset to be applied to the oop
 129 //          [Nn Ll]  both index and offset may be 32 bits if necessary
 130 //   Here is a special hack, used only by the old compiler:
 131 //          [[N]n 00] the value is the __address__ of the nth oop in the pool
 132 //   (Note that the offset allows optimal references to class variables.)
 133 //
 134 // relocInfo::internal_word_type -- an address within the same CodeBlob
 135 // relocInfo::section_word_type -- same, but can refer to another section
 136 //   Value:  an address in the CodeBlob's code or constants section
 137 //   Instruction types: memory (load), set (load address)
 138 //   Data:  []     stored in 4 bytes of instruction
 139 //          [[L]l] a relative offset (see [About Offsets] below)
 140 //   In the case of section_word_type, the offset is relative to a section
 141 //   base address, and the section number (e.g., SECT_INSTS) is encoded
 142 //   into the low two bits of the offset L.
 143 //
 144 // relocInfo::external_word_type -- a fixed address in the runtime system
 145 //   Value:  an address
 146 //   Instruction types: memory (load), set (load address)
 147 //   Data:  []   stored in 4 bytes of instruction
 148 //          [n]  the index of a "well-known" stub (usual case on RISC)
 149 //          [Ll] a 32-bit address
 150 //
 151 // relocInfo::runtime_call_type -- a fixed subroutine in the runtime system
 152 //   Value:  an address
 153 //   Instruction types: PC-relative call (or a PC-relative branch)
 154 //   Data:  []   stored in 4 bytes of instruction
 155 //
 156 // relocInfo::static_call_type -- a static call
 157 //   Value:  an CodeBlob, a stub, or a fixup routine
 158 //   Instruction types: a call
 159 //   Data:  []
 160 //   The identity of the callee is extracted from debugging information.
 161 //   //%note reloc_3
 162 //
 163 // relocInfo::virtual_call_type -- a virtual call site (which includes an inline
 164 //                                 cache)
 165 //   Value:  an CodeBlob, a stub, the interpreter, or a fixup routine
 166 //   Instruction types: a call, plus some associated set-oop instructions
 167 //   Data:  []       the associated set-oops are adjacent to the call
 168 //          [n]      n is a relative offset to the first set-oop
 169 //          [[N]n l] and l is a limit within which the set-oops occur
 170 //          [Nn Ll]  both n and l may be 32 bits if necessary
 171 //   The identity of the callee is extracted from debugging information.
 172 //
 173 // relocInfo::opt_virtual_call_type -- a virtual call site that is statically bound
 174 //
 175 //    Same info as a static_call_type. We use a special type, so the handling of
 176 //    virtuals and statics are separated.
 177 //
 178 //
 179 //   The offset n points to the first set-oop.  (See [About Offsets] below.)
 180 //   In turn, the set-oop instruction specifies or contains an oop cell devoted
 181 //   exclusively to the IC call, which can be patched along with the call.
 182 //
 183 //   The locations of any other set-oops are found by searching the relocation
 184 //   information starting at the first set-oop, and continuing until all
 185 //   relocations up through l have been inspected.  The value l is another
 186 //   relative offset.  (Both n and l are relative to the call's first byte.)
 187 //
 188 //   The limit l of the search is exclusive.  However, if it points within
 189 //   the call (e.g., offset zero), it is adjusted to point after the call and
 190 //   any associated machine-specific delay slot.
 191 //
 192 //   Since the offsets could be as wide as 32-bits, these conventions
 193 //   put no restrictions whatever upon code reorganization.
 194 //
 195 //   The compiler is responsible for ensuring that transition from a clean
 196 //   state to a monomorphic compiled state is MP-safe.  This implies that
 197 //   the system must respond well to intermediate states where a random
 198 //   subset of the set-oops has been correctly from the clean state
 199 //   upon entry to the VEP of the compiled method.  In the case of a
 200 //   machine (Intel) with a single set-oop instruction, the 32-bit
 201 //   immediate field must not straddle a unit of memory coherence.
 202 //   //%note reloc_3
 203 //
 204 // relocInfo::static_stub_type -- an extra stub for each static_call_type
 205 //   Value:  none
 206 //   Instruction types: a virtual call:  { set_oop; jump; }
 207 //   Data:  [[N]n]  the offset of the associated static_call reloc
 208 //   This stub becomes the target of a static call which must be upgraded
 209 //   to a virtual call (because the callee is interpreted).
 210 //   See [About Offsets] below.
 211 //   //%note reloc_2
 212 //
 213 // For example:
 214 //
 215 //   INSTRUCTIONS                        RELOC: TYPE    PREFIX DATA
 216 //   ------------                               ----    -----------
 217 // sethi      %hi(myObject),  R               oop_type [n(myObject)]
 218 // ld      [R+%lo(myObject)+fldOffset], R2    oop_type [n(myObject) fldOffset]
 219 // add R2, 1, R2
 220 // st  R2, [R+%lo(myObject)+fldOffset]        oop_type [n(myObject) fldOffset]
 221 //%note reloc_1
 222 //
 223 // This uses 4 instruction words, 8 relocation halfwords,
 224 // and an entry (which is sharable) in the CodeBlob's oop pool,
 225 // for a total of 36 bytes.
 226 //
 227 // Note that the compiler is responsible for ensuring the "fldOffset" when
 228 // added to "%lo(myObject)" does not overflow the immediate fields of the
 229 // memory instructions.
 230 //
 231 //
 232 // [About Offsets] Relative offsets are supplied to this module as
 233 // positive byte offsets, but they may be internally stored scaled
 234 // and/or negated, depending on what is most compact for the target
 235 // system.  Since the object pointed to by the offset typically
 236 // precedes the relocation address, it is profitable to store
 237 // these negative offsets as positive numbers, but this decision
 238 // is internal to the relocation information abstractions.
 239 //
 240 
 241 class Relocation;
 242 class CodeBuffer;
 243 class CodeSection;
 244 class RelocIterator;
 245 
 246 class relocInfo VALUE_OBJ_CLASS_SPEC {
 247   friend class RelocIterator;
 248  public:
 249   enum relocType {
 250     none                    =  0, // Used when no relocation should be generated
 251     oop_type                =  1, // embedded oop
 252     virtual_call_type       =  2, // a standard inline cache call for a virtual send
 253     opt_virtual_call_type   =  3, // a virtual call that has been statically bound (i.e., no IC cache)
 254     static_call_type        =  4, // a static send
 255     static_stub_type        =  5, // stub-entry for static send  (takes care of interpreter case)
 256     runtime_call_type       =  6, // call to fixed external routine
 257     external_word_type      =  7, // reference to fixed external address
 258     internal_word_type      =  8, // reference within the current code blob
 259     section_word_type       =  9, // internal, but a cross-section reference
 260     poll_type               = 10, // polling instruction for safepoints
 261     poll_return_type        = 11, // polling instruction for safepoints at return
 262     metadata_type           = 12, // metadata that used to be oops
 263     trampoline_stub_type    = 13, // stub-entry for trampoline
 264     yet_unused_type_1       = 14, // Still unused
 265     data_prefix_tag         = 15, // tag for a prefix (carries data arguments)
 266     type_mask               = 15  // A mask which selects only the above values
 267   };
 268 
 269  protected:
 270   unsigned short _value;
 271 
 272   enum RawBitsToken { RAW_BITS };
 273   relocInfo(relocType type, RawBitsToken ignore, int bits)
 274     : _value((type << nontype_width) + bits) { }
 275 
 276   relocInfo(relocType type, RawBitsToken ignore, int off, int f)
 277     : _value((type << nontype_width) + (off / (unsigned)offset_unit) + (f << offset_width)) { }
 278 
 279  public:
 280   // constructor
 281   relocInfo(relocType type, int offset, int format = 0)
 282 #ifndef ASSERT
 283   {
 284     (*this) = relocInfo(type, RAW_BITS, offset, format);
 285   }
 286 #else
 287   // Put a bunch of assertions out-of-line.
 288   ;
 289 #endif
 290 
 291   #define APPLY_TO_RELOCATIONS(visitor) \
 292     visitor(oop) \
 293     visitor(metadata) \
 294     visitor(virtual_call) \
 295     visitor(opt_virtual_call) \
 296     visitor(static_call) \
 297     visitor(static_stub) \
 298     visitor(runtime_call) \
 299     visitor(external_word) \
 300     visitor(internal_word) \
 301     visitor(poll) \
 302     visitor(poll_return) \
 303     visitor(section_word) \
 304     visitor(trampoline_stub) \
 305 
 306 
 307  public:
 308   enum {
 309     value_width             = sizeof(unsigned short) * BitsPerByte,
 310     type_width              = 4,   // == log2(type_mask+1)
 311     nontype_width           = value_width - type_width,
 312     datalen_width           = nontype_width-1,
 313     datalen_tag             = 1 << datalen_width,  // or-ed into _value
 314     datalen_limit           = 1 << datalen_width,
 315     datalen_mask            = (1 << datalen_width)-1
 316   };
 317 
 318   // accessors
 319  public:
 320   relocType  type()       const { return (relocType)((unsigned)_value >> nontype_width); }
 321   int  format()           const { return format_mask==0? 0: format_mask &
 322                                          ((unsigned)_value >> offset_width); }
 323   int  addr_offset()      const { assert(!is_prefix(), "must have offset");
 324                                   return (_value & offset_mask)*offset_unit; }
 325 
 326  protected:
 327   const short* data()     const { assert(is_datalen(), "must have data");
 328                                   return (const short*)(this + 1); }
 329   int          datalen()  const { assert(is_datalen(), "must have data");
 330                                   return (_value & datalen_mask); }
 331   int         immediate() const { assert(is_immediate(), "must have immed");
 332                                   return (_value & datalen_mask); }
 333  public:
 334   static int addr_unit()        { return offset_unit; }
 335   static int offset_limit()     { return (1 << offset_width) * offset_unit; }
 336 
 337   void set_type(relocType type);
 338   void set_format(int format);
 339 
 340   void remove() { set_type(none); }
 341 
 342  protected:
 343   bool is_none()                const { return type() == none; }
 344   bool is_prefix()              const { return type() == data_prefix_tag; }
 345   bool is_datalen()             const { assert(is_prefix(), "must be prefix");
 346                                         return (_value & datalen_tag) != 0; }
 347   bool is_immediate()           const { assert(is_prefix(), "must be prefix");
 348                                         return (_value & datalen_tag) == 0; }
 349 
 350  public:
 351   // Occasionally records of type relocInfo::none will appear in the stream.
 352   // We do not bother to filter these out, but clients should ignore them.
 353   // These records serve as "filler" in three ways:
 354   //  - to skip large spans of unrelocated code (this is rare)
 355   //  - to pad out the relocInfo array to the required oop alignment
 356   //  - to disable old relocation information which is no longer applicable
 357 
 358   inline friend relocInfo filler_relocInfo();
 359 
 360   // Every non-prefix relocation may be preceded by at most one prefix,
 361   // which supplies 1 or more halfwords of associated data.  Conventionally,
 362   // an int is represented by 0, 1, or 2 halfwords, depending on how
 363   // many bits are required to represent the value.  (In addition,
 364   // if the sole halfword is a 10-bit unsigned number, it is made
 365   // "immediate" in the prefix header word itself.  This optimization
 366   // is invisible outside this module.)
 367 
 368   inline friend relocInfo prefix_relocInfo(int datalen);
 369 
 370  protected:
 371   // an immediate relocInfo optimizes a prefix with one 10-bit unsigned value
 372   static relocInfo immediate_relocInfo(int data0) {
 373     assert(fits_into_immediate(data0), "data0 in limits");
 374     return relocInfo(relocInfo::data_prefix_tag, RAW_BITS, data0);
 375   }
 376   static bool fits_into_immediate(int data0) {
 377     return (data0 >= 0 && data0 < datalen_limit);
 378   }
 379 
 380  public:
 381   // Support routines for compilers.
 382 
 383   // This routine takes an infant relocInfo (unprefixed) and
 384   // edits in its prefix, if any.  It also updates dest.locs_end.
 385   void initialize(CodeSection* dest, Relocation* reloc);
 386 
 387   // This routine updates a prefix and returns the limit pointer.
 388   // It tries to compress the prefix from 32 to 16 bits, and if
 389   // successful returns a reduced "prefix_limit" pointer.
 390   relocInfo* finish_prefix(short* prefix_limit);
 391 
 392   // bit-packers for the data array:
 393 
 394   // As it happens, the bytes within the shorts are ordered natively,
 395   // but the shorts within the word are ordered big-endian.
 396   // This is an arbitrary choice, made this way mainly to ease debugging.
 397   static int data0_from_int(jint x)         { return x >> value_width; }
 398   static int data1_from_int(jint x)         { return (short)x; }
 399   static jint jint_from_data(short* data) {
 400     return (data[0] << value_width) + (unsigned short)data[1];
 401   }
 402 
 403   static jint short_data_at(int n, short* data, int datalen) {
 404     return datalen > n ? data[n] : 0;
 405   }
 406 
 407   static jint jint_data_at(int n, short* data, int datalen) {
 408     return datalen > n+1 ? jint_from_data(&data[n]) : short_data_at(n, data, datalen);
 409   }
 410 
 411   // Update methods for relocation information
 412   // (since code is dynamically patched, we also need to dynamically update the relocation info)
 413   // Both methods takes old_type, so it is able to performe sanity checks on the information removed.
 414   static void change_reloc_info_for_address(RelocIterator *itr, address pc, relocType old_type, relocType new_type);
 415   static void remove_reloc_info_for_address(RelocIterator *itr, address pc, relocType old_type);
 416 
 417   // Machine dependent stuff
 418 #ifdef TARGET_ARCH_x86
 419 # include "relocInfo_x86.hpp"
 420 #endif



 421 #ifdef TARGET_ARCH_sparc
 422 # include "relocInfo_sparc.hpp"
 423 #endif
 424 #ifdef TARGET_ARCH_zero
 425 # include "relocInfo_zero.hpp"
 426 #endif
 427 #ifdef TARGET_ARCH_arm
 428 # include "relocInfo_arm.hpp"
 429 #endif
 430 #ifdef TARGET_ARCH_ppc
 431 # include "relocInfo_ppc.hpp"
 432 #endif
 433 
 434 
 435  protected:
 436   // Derived constant, based on format_width which is PD:
 437   enum {
 438     offset_width       = nontype_width - format_width,
 439     offset_mask        = (1<<offset_width) - 1,
 440     format_mask        = (1<<format_width) - 1
 441   };
 442  public:
 443   enum {
 444     // Conservatively large estimate of maximum length (in shorts)
 445     // of any relocation record.
 446     // Extended format is length prefix, data words, and tag/offset suffix.
 447     length_limit       = 1 + 1 + (3*BytesPerWord/BytesPerShort) + 1,
 448     have_format        = format_width > 0
 449   };
 450 };
 451 
 452 #define FORWARD_DECLARE_EACH_CLASS(name)              \
 453 class name##_Relocation;
 454 APPLY_TO_RELOCATIONS(FORWARD_DECLARE_EACH_CLASS)
 455 #undef FORWARD_DECLARE_EACH_CLASS
 456 
 457 
 458 
 459 inline relocInfo filler_relocInfo() {
 460   return relocInfo(relocInfo::none, relocInfo::offset_limit() - relocInfo::offset_unit);
 461 }
 462 
 463 inline relocInfo prefix_relocInfo(int datalen = 0) {
 464   assert(relocInfo::fits_into_immediate(datalen), "datalen in limits");
 465   return relocInfo(relocInfo::data_prefix_tag, relocInfo::RAW_BITS, relocInfo::datalen_tag | datalen);
 466 }
 467 
 468 
 469 // Holder for flyweight relocation objects.
 470 // Although the flyweight subclasses are of varying sizes,
 471 // the holder is "one size fits all".
 472 class RelocationHolder VALUE_OBJ_CLASS_SPEC {
 473   friend class Relocation;
 474   friend class CodeSection;
 475 
 476  private:
 477   // this preallocated memory must accommodate all subclasses of Relocation
 478   // (this number is assertion-checked in Relocation::operator new)
 479   enum { _relocbuf_size = 5 };
 480   void* _relocbuf[ _relocbuf_size ];
 481 
 482  public:
 483   Relocation* reloc() const { return (Relocation*) &_relocbuf[0]; }
 484   inline relocInfo::relocType type() const;
 485 
 486   // Add a constant offset to a relocation.  Helper for class Address.
 487   RelocationHolder plus(int offset) const;
 488 
 489   inline RelocationHolder();                // initializes type to none
 490 
 491   inline RelocationHolder(Relocation* r);   // make a copy
 492 
 493   static const RelocationHolder none;
 494 };
 495 
 496 // A RelocIterator iterates through the relocation information of a CodeBlob.
 497 // It is a variable BoundRelocation which is able to take on successive
 498 // values as it is advanced through a code stream.
 499 // Usage:
 500 //   RelocIterator iter(nm);
 501 //   while (iter.next()) {
 502 //     iter.reloc()->some_operation();
 503 //   }
 504 // or:
 505 //   RelocIterator iter(nm);
 506 //   while (iter.next()) {
 507 //     switch (iter.type()) {
 508 //      case relocInfo::oop_type          :
 509 //      case relocInfo::ic_type           :
 510 //      case relocInfo::prim_type         :
 511 //      case relocInfo::uncommon_type     :
 512 //      case relocInfo::runtime_call_type :
 513 //      case relocInfo::internal_word_type:
 514 //      case relocInfo::external_word_type:
 515 //      ...
 516 //     }
 517 //   }
 518 
 519 class RelocIterator : public StackObj {
 520   enum { SECT_LIMIT = 3 };  // must be equal to CodeBuffer::SECT_LIMIT, checked in ctor
 521   friend class Relocation;
 522   friend class relocInfo;       // for change_reloc_info_for_address only
 523   typedef relocInfo::relocType relocType;
 524 
 525  private:
 526   address    _limit;   // stop producing relocations after this _addr
 527   relocInfo* _current; // the current relocation information
 528   relocInfo* _end;     // end marker; we're done iterating when _current == _end
 529   nmethod*   _code;    // compiled method containing _addr
 530   address    _addr;    // instruction to which the relocation applies
 531   short      _databuf; // spare buffer for compressed data
 532   short*     _data;    // pointer to the relocation's data
 533   short      _datalen; // number of halfwords in _data
 534   char       _format;  // position within the instruction
 535 
 536   // Base addresses needed to compute targets of section_word_type relocs.
 537   address    _section_start[SECT_LIMIT];
 538   address    _section_end  [SECT_LIMIT];
 539 
 540   void set_has_current(bool b) {
 541     _datalen = !b ? -1 : 0;
 542     debug_only(_data = NULL);
 543   }
 544   void set_current(relocInfo& ri) {
 545     _current = &ri;
 546     set_has_current(true);
 547   }
 548 
 549   RelocationHolder _rh; // where the current relocation is allocated
 550 
 551   relocInfo* current() const { assert(has_current(), "must have current");
 552                                return _current; }
 553 
 554   void set_limits(address begin, address limit);
 555 
 556   void advance_over_prefix();    // helper method
 557 
 558   void initialize_misc();
 559 
 560   void initialize(nmethod* nm, address begin, address limit);
 561 
 562   RelocIterator() { initialize_misc(); }
 563 
 564  public:
 565   // constructor
 566   RelocIterator(nmethod* nm,     address begin = NULL, address limit = NULL);
 567   RelocIterator(CodeSection* cb, address begin = NULL, address limit = NULL);
 568 
 569   // get next reloc info, return !eos
 570   bool next() {
 571     _current++;
 572     assert(_current <= _end, "must not overrun relocInfo");
 573     if (_current == _end) {
 574       set_has_current(false);
 575       return false;
 576     }
 577     set_has_current(true);
 578 
 579     if (_current->is_prefix()) {
 580       advance_over_prefix();
 581       assert(!current()->is_prefix(), "only one prefix at a time");
 582     }
 583 
 584     _addr += _current->addr_offset();
 585 
 586     if (_limit != NULL && _addr >= _limit) {
 587       set_has_current(false);
 588       return false;
 589     }
 590 
 591     if (relocInfo::have_format)  _format = current()->format();
 592     return true;
 593   }
 594 
 595   // accessors
 596   address      limit()        const { return _limit; }
 597   void     set_limit(address x);
 598   relocType    type()         const { return current()->type(); }
 599   int          format()       const { return (relocInfo::have_format) ? current()->format() : 0; }
 600   address      addr()         const { return _addr; }
 601   nmethod*     code()         const { return _code; }
 602   short*       data()         const { return _data; }
 603   int          datalen()      const { return _datalen; }
 604   bool     has_current()      const { return _datalen >= 0; }
 605 
 606   void       set_addr(address addr) { _addr = addr; }
 607   bool   addr_in_const()      const;
 608 
 609   address section_start(int n) const {
 610     assert(_section_start[n], "must be initialized");
 611     return _section_start[n];
 612   }
 613   address section_end(int n) const {
 614     assert(_section_end[n], "must be initialized");
 615     return _section_end[n];
 616   }
 617 
 618   // The address points to the affected displacement part of the instruction.
 619   // For RISC, this is just the whole instruction.
 620   // For Intel, this is an unaligned 32-bit word.
 621 
 622   // type-specific relocation accessors:  oop_Relocation* oop_reloc(), etc.
 623   #define EACH_TYPE(name)                               \
 624   inline name##_Relocation* name##_reloc();
 625   APPLY_TO_RELOCATIONS(EACH_TYPE)
 626   #undef EACH_TYPE
 627   // generic relocation accessor; switches on type to call the above
 628   Relocation* reloc();
 629 
 630   // CodeBlob's have relocation indexes for faster random access:
 631   static int locs_and_index_size(int code_size, int locs_size);
 632   // Store an index into [dest_start+dest_count..dest_end).
 633   // At dest_start[0..dest_count] is the actual relocation information.
 634   // Everything else up to dest_end is free space for the index.
 635   static void create_index(relocInfo* dest_begin, int dest_count, relocInfo* dest_end);
 636 
 637 #ifndef PRODUCT
 638  public:
 639   void print();
 640   void print_current();
 641 #endif
 642 };
 643 
 644 
 645 // A Relocation is a flyweight object allocated within a RelocationHolder.
 646 // It represents the relocation data of relocation record.
 647 // So, the RelocIterator unpacks relocInfos into Relocations.
 648 
 649 class Relocation VALUE_OBJ_CLASS_SPEC {
 650   friend class RelocationHolder;
 651   friend class RelocIterator;
 652 
 653  private:
 654   static void guarantee_size();
 655 
 656   // When a relocation has been created by a RelocIterator,
 657   // this field is non-null.  It allows the relocation to know
 658   // its context, such as the address to which it applies.
 659   RelocIterator* _binding;
 660 
 661  protected:
 662   RelocIterator* binding() const {
 663     assert(_binding != NULL, "must be bound");
 664     return _binding;
 665   }
 666   void set_binding(RelocIterator* b) {
 667     assert(_binding == NULL, "must be unbound");
 668     _binding = b;
 669     assert(_binding != NULL, "must now be bound");
 670   }
 671 
 672   Relocation() {
 673     _binding = NULL;
 674   }
 675 
 676   static RelocationHolder newHolder() {
 677     return RelocationHolder();
 678   }
 679 
 680  public:
 681   void* operator new(size_t size, const RelocationHolder& holder) throw() {
 682     if (size > sizeof(holder._relocbuf)) guarantee_size();
 683     assert((void* const *)holder.reloc() == &holder._relocbuf[0], "ptrs must agree");
 684     return holder.reloc();
 685   }
 686 
 687   // make a generic relocation for a given type (if possible)
 688   static RelocationHolder spec_simple(relocInfo::relocType rtype);
 689 
 690   // here is the type-specific hook which writes relocation data:
 691   virtual void pack_data_to(CodeSection* dest) { }
 692 
 693   // here is the type-specific hook which reads (unpacks) relocation data:
 694   virtual void unpack_data() {
 695     assert(datalen()==0 || type()==relocInfo::none, "no data here");
 696   }
 697 
 698   static bool is_reloc_index(intptr_t index) {
 699     return 0 < index && index < os::vm_page_size();
 700   }
 701 
 702  protected:
 703   // Helper functions for pack_data_to() and unpack_data().
 704 
 705   // Most of the compression logic is confined here.
 706   // (The "immediate data" mechanism of relocInfo works independently
 707   // of this stuff, and acts to further compress most 1-word data prefixes.)
 708 
 709   // A variable-width int is encoded as a short if it will fit in 16 bits.
 710   // The decoder looks at datalen to decide whether to unpack short or jint.
 711   // Most relocation records are quite simple, containing at most two ints.
 712 
 713   static bool is_short(jint x) { return x == (short)x; }
 714   static short* add_short(short* p, int x)  { *p++ = x; return p; }
 715   static short* add_jint (short* p, jint x) {
 716     *p++ = relocInfo::data0_from_int(x); *p++ = relocInfo::data1_from_int(x);
 717     return p;
 718   }
 719   static short* add_var_int(short* p, jint x) {   // add a variable-width int
 720     if (is_short(x))  p = add_short(p, x);
 721     else              p = add_jint (p, x);
 722     return p;
 723   }
 724 
 725   static short* pack_1_int_to(short* p, jint x0) {
 726     // Format is one of:  [] [x] [Xx]
 727     if (x0 != 0)  p = add_var_int(p, x0);
 728     return p;
 729   }
 730   int unpack_1_int() {
 731     assert(datalen() <= 2, "too much data");
 732     return relocInfo::jint_data_at(0, data(), datalen());
 733   }
 734 
 735   // With two ints, the short form is used only if both ints are short.
 736   short* pack_2_ints_to(short* p, jint x0, jint x1) {
 737     // Format is one of:  [] [x y?] [Xx Y?y]
 738     if (x0 == 0 && x1 == 0) {
 739       // no halfwords needed to store zeroes
 740     } else if (is_short(x0) && is_short(x1)) {
 741       // 1-2 halfwords needed to store shorts
 742       p = add_short(p, x0); if (x1!=0) p = add_short(p, x1);
 743     } else {
 744       // 3-4 halfwords needed to store jints
 745       p = add_jint(p, x0);             p = add_var_int(p, x1);
 746     }
 747     return p;
 748   }
 749   void unpack_2_ints(jint& x0, jint& x1) {
 750     int    dlen = datalen();
 751     short* dp  = data();
 752     if (dlen <= 2) {
 753       x0 = relocInfo::short_data_at(0, dp, dlen);
 754       x1 = relocInfo::short_data_at(1, dp, dlen);
 755     } else {
 756       assert(dlen <= 4, "too much data");
 757       x0 = relocInfo::jint_data_at(0, dp, dlen);
 758       x1 = relocInfo::jint_data_at(2, dp, dlen);
 759     }
 760   }
 761 
 762  protected:
 763   // platform-dependent utilities for decoding and patching instructions
 764   void       pd_set_data_value       (address x, intptr_t off, bool verify_only = false); // a set or mem-ref
 765   void       pd_verify_data_value    (address x, intptr_t off) { pd_set_data_value(x, off, true); }
 766   address    pd_call_destination     (address orig_addr = NULL);
 767   void       pd_set_call_destination (address x);
 768 
 769   // this extracts the address of an address in the code stream instead of the reloc data
 770   address* pd_address_in_code       ();
 771 
 772   // this extracts an address from the code stream instead of the reloc data
 773   address  pd_get_address_from_code ();
 774 
 775   // these convert from byte offsets, to scaled offsets, to addresses
 776   static jint scaled_offset(address x, address base) {
 777     int byte_offset = x - base;
 778     int offset = -byte_offset / relocInfo::addr_unit();
 779     assert(address_from_scaled_offset(offset, base) == x, "just checkin'");
 780     return offset;
 781   }
 782   static jint scaled_offset_null_special(address x, address base) {
 783     // Some relocations treat offset=0 as meaning NULL.
 784     // Handle this extra convention carefully.
 785     if (x == NULL)  return 0;
 786     assert(x != base, "offset must not be zero");
 787     return scaled_offset(x, base);
 788   }
 789   static address address_from_scaled_offset(jint offset, address base) {
 790     int byte_offset = -( offset * relocInfo::addr_unit() );
 791     return base + byte_offset;
 792   }
 793 
 794   // these convert between indexes and addresses in the runtime system
 795   static int32_t runtime_address_to_index(address runtime_address);
 796   static address index_to_runtime_address(int32_t index);
 797 
 798   // helpers for mapping between old and new addresses after a move or resize
 799   address old_addr_for(address newa, const CodeBuffer* src, CodeBuffer* dest);
 800   address new_addr_for(address olda, const CodeBuffer* src, CodeBuffer* dest);
 801   void normalize_address(address& addr, const CodeSection* dest, bool allow_other_sections = false);
 802 
 803  public:
 804   // accessors which only make sense for a bound Relocation
 805   address  addr()         const { return binding()->addr(); }
 806   nmethod* code()         const { return binding()->code(); }
 807   bool     addr_in_const() const { return binding()->addr_in_const(); }
 808  protected:
 809   short*   data()         const { return binding()->data(); }
 810   int      datalen()      const { return binding()->datalen(); }
 811   int      format()       const { return binding()->format(); }
 812 
 813  public:
 814   virtual relocInfo::relocType type()            { return relocInfo::none; }
 815 
 816   // is it a call instruction?
 817   virtual bool is_call()                         { return false; }
 818 
 819   // is it a data movement instruction?
 820   virtual bool is_data()                         { return false; }
 821 
 822   // some relocations can compute their own values
 823   virtual address  value();
 824 
 825   // all relocations are able to reassert their values
 826   virtual void set_value(address x);
 827 
 828   virtual void clear_inline_cache()              { }
 829 
 830   // This method assumes that all virtual/static (inline) caches are cleared (since for static_call_type and
 831   // ic_call_type is not always posisition dependent (depending on the state of the cache)). However, this is
 832   // probably a reasonable assumption, since empty caches simplifies code reloacation.
 833   virtual void fix_relocation_after_move(const CodeBuffer* src, CodeBuffer* dest) { }
 834 
 835   void print();
 836 };
 837 
 838 
 839 // certain inlines must be deferred until class Relocation is defined:
 840 
 841 inline RelocationHolder::RelocationHolder() {
 842   // initialize the vtbl, just to keep things type-safe
 843   new(*this) Relocation();
 844 }
 845 
 846 
 847 inline RelocationHolder::RelocationHolder(Relocation* r) {
 848   // wordwise copy from r (ok if it copies garbage after r)
 849   for (int i = 0; i < _relocbuf_size; i++) {
 850     _relocbuf[i] = ((void**)r)[i];
 851   }
 852 }
 853 
 854 
 855 relocInfo::relocType RelocationHolder::type() const {
 856   return reloc()->type();
 857 }
 858 
 859 // A DataRelocation always points at a memory or load-constant instruction..
 860 // It is absolute on most machines, and the constant is split on RISCs.
 861 // The specific subtypes are oop, external_word, and internal_word.
 862 // By convention, the "value" does not include a separately reckoned "offset".
 863 class DataRelocation : public Relocation {
 864  public:
 865   bool          is_data()                      { return true; }
 866 
 867   // both target and offset must be computed somehow from relocation data
 868   virtual int    offset()                      { return 0; }
 869   address         value()                      = 0;
 870   void        set_value(address x)             { set_value(x, offset()); }
 871   void        set_value(address x, intptr_t o) {
 872     if (addr_in_const())
 873       *(address*)addr() = x;
 874     else
 875       pd_set_data_value(x, o);
 876   }
 877   void        verify_value(address x) {
 878     if (addr_in_const())
 879       assert(*(address*)addr() == x, "must agree");
 880     else
 881       pd_verify_data_value(x, offset());
 882   }
 883 
 884   // The "o" (displacement) argument is relevant only to split relocations
 885   // on RISC machines.  In some CPUs (SPARC), the set-hi and set-lo ins'ns
 886   // can encode more than 32 bits between them.  This allows compilers to
 887   // share set-hi instructions between addresses that differ by a small
 888   // offset (e.g., different static variables in the same class).
 889   // On such machines, the "x" argument to set_value on all set-lo
 890   // instructions must be the same as the "x" argument for the
 891   // corresponding set-hi instructions.  The "o" arguments for the
 892   // set-hi instructions are ignored, and must not affect the high-half
 893   // immediate constant.  The "o" arguments for the set-lo instructions are
 894   // added into the low-half immediate constant, and must not overflow it.
 895 };
 896 
 897 // A CallRelocation always points at a call instruction.
 898 // It is PC-relative on most machines.
 899 class CallRelocation : public Relocation {
 900  public:
 901   bool is_call() { return true; }
 902 
 903   address  destination()                    { return pd_call_destination(); }
 904   void     set_destination(address x); // pd_set_call_destination
 905 
 906   void     fix_relocation_after_move(const CodeBuffer* src, CodeBuffer* dest);
 907   address  value()                          { return destination();  }
 908   void     set_value(address x)             { set_destination(x); }
 909 };
 910 
 911 class oop_Relocation : public DataRelocation {
 912   relocInfo::relocType type() { return relocInfo::oop_type; }
 913 
 914  public:
 915   // encode in one of these formats:  [] [n] [n l] [Nn l] [Nn Ll]
 916   // an oop in the CodeBlob's oop pool
 917   static RelocationHolder spec(int oop_index, int offset = 0) {
 918     assert(oop_index > 0, "must be a pool-resident oop");
 919     RelocationHolder rh = newHolder();
 920     new(rh) oop_Relocation(oop_index, offset);
 921     return rh;
 922   }
 923   // an oop in the instruction stream
 924   static RelocationHolder spec_for_immediate() {
 925     const int oop_index = 0;
 926     const int offset    = 0;    // if you want an offset, use the oop pool
 927     RelocationHolder rh = newHolder();
 928     new(rh) oop_Relocation(oop_index, offset);
 929     return rh;
 930   }
 931 
 932  private:
 933   jint _oop_index;                  // if > 0, index into CodeBlob::oop_at
 934   jint _offset;                     // byte offset to apply to the oop itself
 935 
 936   oop_Relocation(int oop_index, int offset) {
 937     _oop_index = oop_index; _offset = offset;
 938   }
 939 
 940   friend class RelocIterator;
 941   oop_Relocation() { }
 942 
 943  public:
 944   int oop_index() { return _oop_index; }
 945   int offset()    { return _offset; }
 946 
 947   // data is packed in "2_ints" format:  [i o] or [Ii Oo]
 948   void pack_data_to(CodeSection* dest);
 949   void unpack_data();
 950 
 951   void fix_oop_relocation();        // reasserts oop value
 952 
 953   void verify_oop_relocation();
 954 
 955   address value()  { return (address) *oop_addr(); }
 956 
 957   bool oop_is_immediate()  { return oop_index() == 0; }
 958 
 959   oop* oop_addr();                  // addr or &pool[jint_data]
 960   oop  oop_value();                 // *oop_addr
 961   // Note:  oop_value transparently converts Universe::non_oop_word to NULL.
 962 };
 963 
 964 
 965 // copy of oop_Relocation for now but may delete stuff in both/either
 966 class metadata_Relocation : public DataRelocation {
 967   relocInfo::relocType type() { return relocInfo::metadata_type; }
 968 
 969  public:
 970   // encode in one of these formats:  [] [n] [n l] [Nn l] [Nn Ll]
 971   // an metadata in the CodeBlob's metadata pool
 972   static RelocationHolder spec(int metadata_index, int offset = 0) {
 973     assert(metadata_index > 0, "must be a pool-resident metadata");
 974     RelocationHolder rh = newHolder();
 975     new(rh) metadata_Relocation(metadata_index, offset);
 976     return rh;
 977   }
 978   // an metadata in the instruction stream
 979   static RelocationHolder spec_for_immediate() {
 980     const int metadata_index = 0;
 981     const int offset    = 0;    // if you want an offset, use the metadata pool
 982     RelocationHolder rh = newHolder();
 983     new(rh) metadata_Relocation(metadata_index, offset);
 984     return rh;
 985   }
 986 
 987  private:
 988   jint _metadata_index;            // if > 0, index into nmethod::metadata_at
 989   jint _offset;                     // byte offset to apply to the metadata itself
 990 
 991   metadata_Relocation(int metadata_index, int offset) {
 992     _metadata_index = metadata_index; _offset = offset;
 993   }
 994 
 995   friend class RelocIterator;
 996   metadata_Relocation() { }
 997 
 998   // Fixes a Metadata pointer in the code. Most platforms embeds the
 999   // Metadata pointer in the code at compile time so this is empty
1000   // for them.
1001   void pd_fix_value(address x);
1002 
1003  public:
1004   int metadata_index() { return _metadata_index; }
1005   int offset()    { return _offset; }
1006 
1007   // data is packed in "2_ints" format:  [i o] or [Ii Oo]
1008   void pack_data_to(CodeSection* dest);
1009   void unpack_data();
1010 
1011   void fix_metadata_relocation();        // reasserts metadata value
1012 
1013   void verify_metadata_relocation();
1014 
1015   address value()  { return (address) *metadata_addr(); }
1016 
1017   bool metadata_is_immediate()  { return metadata_index() == 0; }
1018 
1019   Metadata**   metadata_addr();                  // addr or &pool[jint_data]
1020   Metadata*    metadata_value();                 // *metadata_addr
1021   // Note:  metadata_value transparently converts Universe::non_metadata_word to NULL.
1022 };
1023 
1024 
1025 class virtual_call_Relocation : public CallRelocation {
1026   relocInfo::relocType type() { return relocInfo::virtual_call_type; }
1027 
1028  public:
1029   // "cached_value" points to the first associated set-oop.
1030   // The oop_limit helps find the last associated set-oop.
1031   // (See comments at the top of this file.)
1032   static RelocationHolder spec(address cached_value) {
1033     RelocationHolder rh = newHolder();
1034     new(rh) virtual_call_Relocation(cached_value);
1035     return rh;
1036   }
1037 
1038   virtual_call_Relocation(address cached_value) {
1039     _cached_value = cached_value;
1040     assert(cached_value != NULL, "first oop address must be specified");
1041   }
1042 
1043  private:
1044   address _cached_value;               // location of set-value instruction
1045 
1046   friend class RelocIterator;
1047   virtual_call_Relocation() { }
1048 
1049 
1050  public:
1051   address cached_value();
1052 
1053   // data is packed as scaled offsets in "2_ints" format:  [f l] or [Ff Ll]
1054   // oop_limit is set to 0 if the limit falls somewhere within the call.
1055   // When unpacking, a zero oop_limit is taken to refer to the end of the call.
1056   // (This has the effect of bringing in the call's delay slot on SPARC.)
1057   void pack_data_to(CodeSection* dest);
1058   void unpack_data();
1059 
1060   void clear_inline_cache();
1061 };
1062 
1063 
1064 class opt_virtual_call_Relocation : public CallRelocation {
1065   relocInfo::relocType type() { return relocInfo::opt_virtual_call_type; }
1066 
1067  public:
1068   static RelocationHolder spec() {
1069     RelocationHolder rh = newHolder();
1070     new(rh) opt_virtual_call_Relocation();
1071     return rh;
1072   }
1073 
1074  private:
1075   friend class RelocIterator;
1076   opt_virtual_call_Relocation() { }
1077 
1078  public:
1079   void clear_inline_cache();
1080 
1081   // find the matching static_stub
1082   address static_stub();
1083 };
1084 
1085 
1086 class static_call_Relocation : public CallRelocation {
1087   relocInfo::relocType type() { return relocInfo::static_call_type; }
1088 
1089  public:
1090   static RelocationHolder spec() {
1091     RelocationHolder rh = newHolder();
1092     new(rh) static_call_Relocation();
1093     return rh;
1094   }
1095 
1096  private:
1097   friend class RelocIterator;
1098   static_call_Relocation() { }
1099 
1100  public:
1101   void clear_inline_cache();
1102 
1103   // find the matching static_stub
1104   address static_stub();
1105 };
1106 
1107 class static_stub_Relocation : public Relocation {
1108   relocInfo::relocType type() { return relocInfo::static_stub_type; }
1109 
1110  public:
1111   static RelocationHolder spec(address static_call) {
1112     RelocationHolder rh = newHolder();
1113     new(rh) static_stub_Relocation(static_call);
1114     return rh;
1115   }
1116 
1117  private:
1118   address _static_call;             // location of corresponding static_call
1119 
1120   static_stub_Relocation(address static_call) {
1121     _static_call = static_call;
1122   }
1123 
1124   friend class RelocIterator;
1125   static_stub_Relocation() { }
1126 
1127  public:
1128   void clear_inline_cache();
1129 
1130   address static_call() { return _static_call; }
1131 
1132   // data is packed as a scaled offset in "1_int" format:  [c] or [Cc]
1133   void pack_data_to(CodeSection* dest);
1134   void unpack_data();
1135 };
1136 
1137 class runtime_call_Relocation : public CallRelocation {
1138   relocInfo::relocType type() { return relocInfo::runtime_call_type; }
1139 
1140  public:
1141   static RelocationHolder spec() {
1142     RelocationHolder rh = newHolder();
1143     new(rh) runtime_call_Relocation();
1144     return rh;
1145   }
1146 
1147  private:
1148   friend class RelocIterator;
1149   runtime_call_Relocation() { }
1150 
1151  public:
1152 };
1153 
1154 // Trampoline Relocations.
1155 // A trampoline allows to encode a small branch in the code, even if there
1156 // is the chance that this branch can not reach all possible code locations.
1157 // If the relocation finds that a branch is too far for the instruction
1158 // in the code, it can patch it to jump to the trampoline where is
1159 // sufficient space for a far branch. Needed on PPC.
1160 class trampoline_stub_Relocation : public Relocation {
1161   relocInfo::relocType type() { return relocInfo::trampoline_stub_type; }
1162 
1163  public:
1164   static RelocationHolder spec(address static_call) {
1165     RelocationHolder rh = newHolder();
1166     return (new (rh) trampoline_stub_Relocation(static_call));
1167   }
1168 
1169  private:
1170   address _owner;    // Address of the NativeCall that owns the trampoline.
1171 
1172   trampoline_stub_Relocation(address owner) {
1173     _owner = owner;
1174   }
1175 
1176   friend class RelocIterator;
1177   trampoline_stub_Relocation() { }
1178 
1179  public:
1180 
1181   // Return the address of the NativeCall that owns the trampoline.
1182   address owner() { return _owner; }
1183 
1184   void pack_data_to(CodeSection * dest);
1185   void unpack_data();
1186 
1187   // Find the trampoline stub for a call.
1188   static address get_trampoline_for(address call, nmethod* code);
1189 };
1190 
1191 class external_word_Relocation : public DataRelocation {
1192   relocInfo::relocType type() { return relocInfo::external_word_type; }
1193 
1194  public:
1195   static RelocationHolder spec(address target) {
1196     assert(target != NULL, "must not be null");
1197     RelocationHolder rh = newHolder();
1198     new(rh) external_word_Relocation(target);
1199     return rh;
1200   }
1201 
1202   // Use this one where all 32/64 bits of the target live in the code stream.
1203   // The target must be an intptr_t, and must be absolute (not relative).
1204   static RelocationHolder spec_for_immediate() {
1205     RelocationHolder rh = newHolder();
1206     new(rh) external_word_Relocation(NULL);
1207     return rh;
1208   }
1209 
1210   // Some address looking values aren't safe to treat as relocations
1211   // and should just be treated as constants.
1212   static bool can_be_relocated(address target) {
1213     return target != NULL && !is_reloc_index((intptr_t)target);
1214   }
1215 
1216  private:
1217   address _target;                  // address in runtime
1218 
1219   external_word_Relocation(address target) {
1220     _target = target;
1221   }
1222 
1223   friend class RelocIterator;
1224   external_word_Relocation() { }
1225 
1226  public:
1227   // data is packed as a well-known address in "1_int" format:  [a] or [Aa]
1228   // The function runtime_address_to_index is used to turn full addresses
1229   // to short indexes, if they are pre-registered by the stub mechanism.
1230   // If the "a" value is 0 (i.e., _target is NULL), the address is stored
1231   // in the code stream.  See external_word_Relocation::target().
1232   void pack_data_to(CodeSection* dest);
1233   void unpack_data();
1234 
1235   void fix_relocation_after_move(const CodeBuffer* src, CodeBuffer* dest);
1236   address  target();        // if _target==NULL, fetch addr from code stream
1237   address  value()          { return target(); }
1238 };
1239 
1240 class internal_word_Relocation : public DataRelocation {
1241   relocInfo::relocType type() { return relocInfo::internal_word_type; }
1242 
1243  public:
1244   static RelocationHolder spec(address target) {
1245     assert(target != NULL, "must not be null");
1246     RelocationHolder rh = newHolder();
1247     new(rh) internal_word_Relocation(target);
1248     return rh;
1249   }
1250 
1251   // use this one where all the bits of the target can fit in the code stream:
1252   static RelocationHolder spec_for_immediate() {
1253     RelocationHolder rh = newHolder();
1254     new(rh) internal_word_Relocation(NULL);
1255     return rh;
1256   }
1257 
1258   internal_word_Relocation(address target) {
1259     _target  = target;
1260     _section = -1;  // self-relative
1261   }
1262 
1263  protected:
1264   address _target;                  // address in CodeBlob
1265   int     _section;                 // section providing base address, if any
1266 
1267   friend class RelocIterator;
1268   internal_word_Relocation() { }
1269 
1270   // bit-width of LSB field in packed offset, if section >= 0
1271   enum { section_width = 2 }; // must equal CodeBuffer::sect_bits
1272 
1273  public:
1274   // data is packed as a scaled offset in "1_int" format:  [o] or [Oo]
1275   // If the "o" value is 0 (i.e., _target is NULL), the offset is stored
1276   // in the code stream.  See internal_word_Relocation::target().
1277   // If _section is not -1, it is appended to the low bits of the offset.
1278   void pack_data_to(CodeSection* dest);
1279   void unpack_data();
1280 
1281   void fix_relocation_after_move(const CodeBuffer* src, CodeBuffer* dest);
1282   address  target();        // if _target==NULL, fetch addr from code stream
1283   int      section()        { return _section;   }
1284   address  value()          { return target();   }
1285 };
1286 
1287 class section_word_Relocation : public internal_word_Relocation {
1288   relocInfo::relocType type() { return relocInfo::section_word_type; }
1289 
1290  public:
1291   static RelocationHolder spec(address target, int section) {
1292     RelocationHolder rh = newHolder();
1293     new(rh) section_word_Relocation(target, section);
1294     return rh;
1295   }
1296 
1297   section_word_Relocation(address target, int section) {
1298     assert(target != NULL, "must not be null");
1299     assert(section >= 0, "must be a valid section");
1300     _target  = target;
1301     _section = section;
1302   }
1303 
1304   //void pack_data_to -- inherited
1305   void unpack_data();
1306 
1307  private:
1308   friend class RelocIterator;
1309   section_word_Relocation() { }
1310 };
1311 
1312 
1313 class poll_Relocation : public Relocation {
1314   bool          is_data()                      { return true; }
1315   relocInfo::relocType type() { return relocInfo::poll_type; }
1316   void     fix_relocation_after_move(const CodeBuffer* src, CodeBuffer* dest);
1317 };
1318 
1319 class poll_return_Relocation : public Relocation {
1320   bool          is_data()                      { return true; }
1321   relocInfo::relocType type() { return relocInfo::poll_return_type; }
1322   void     fix_relocation_after_move(const CodeBuffer* src, CodeBuffer* dest);
1323 };
1324 
1325 // We know all the xxx_Relocation classes, so now we can define these:
1326 #define EACH_CASE(name)                                         \
1327 inline name##_Relocation* RelocIterator::name##_reloc() {       \
1328   assert(type() == relocInfo::name##_type, "type must agree");  \
1329   /* The purpose of the placed "new" is to re-use the same */   \
1330   /* stack storage for each new iteration. */                   \
1331   name##_Relocation* r = new(_rh) name##_Relocation();          \
1332   r->set_binding(this);                                         \
1333   r->name##_Relocation::unpack_data();                          \
1334   return r;                                                     \
1335 }
1336 APPLY_TO_RELOCATIONS(EACH_CASE);
1337 #undef EACH_CASE
1338 
1339 inline RelocIterator::RelocIterator(nmethod* nm, address begin, address limit) {
1340   initialize(nm, begin, limit);
1341 }
1342 
1343 #endif // SHARE_VM_CODE_RELOCINFO_HPP
--- EOF ---