1 /*
   2  * Copyright (c) 1997, 2016, 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.
   8  *
   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).
  14  *
  15  * You should have received a copy of the GNU General Public License version
  16  * 2 along with this work; if not, write to the Free Software Foundation,
  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
  21  * questions.
  22  *
  23  */
  24 
  25 #ifndef SHARE_VM_ASM_CODEBUFFER_HPP
  26 #define SHARE_VM_ASM_CODEBUFFER_HPP
  27 
  28 #include "code/oopRecorder.hpp"
  29 #include "code/relocInfo.hpp"
  30 #include "utilities/align.hpp"
  31 #include "utilities/debug.hpp"
  32 #include "utilities/macros.hpp"
  33 
  34 class CodeStrings;
  35 class PhaseCFG;
  36 class Compile;
  37 class BufferBlob;
  38 class CodeBuffer;
  39 class Label;
  40 
  41 class CodeOffsets: public StackObj {
  42 public:
  43   enum Entries { Entry,
  44                  Verified_Entry,
  45                  Frame_Complete, // Offset in the code where the frame setup is (for forte stackwalks) is complete
  46                  OSR_Entry,
  47                  Exceptions,     // Offset where exception handler lives
  48                  Deopt,          // Offset where deopt handler lives
  49                  DeoptMH,        // Offset where MethodHandle deopt handler lives
  50                  UnwindHandler,  // Offset to default unwind handler
  51                  max_Entries };
  52 
  53   // special value to note codeBlobs where profile (forte) stack walking is
  54   // always dangerous and suspect.
  55 
  56   enum { frame_never_safe = -1 };
  57 
  58 private:
  59   int _values[max_Entries];
  60 
  61 public:
  62   CodeOffsets() {
  63     _values[Entry         ] = 0;
  64     _values[Verified_Entry] = 0;
  65     _values[Frame_Complete] = frame_never_safe;
  66     _values[OSR_Entry     ] = 0;
  67     _values[Exceptions    ] = -1;
  68     _values[Deopt         ] = -1;
  69     _values[DeoptMH       ] = -1;
  70     _values[UnwindHandler ] = -1;
  71   }
  72 
  73   int value(Entries e) { return _values[e]; }
  74   void set_value(Entries e, int val) { _values[e] = val; }
  75 };
  76 
  77 // This class represents a stream of code and associated relocations.
  78 // There are a few in each CodeBuffer.
  79 // They are filled concurrently, and concatenated at the end.
  80 class CodeSection VALUE_OBJ_CLASS_SPEC {
  81   friend class CodeBuffer;
  82  public:
  83   typedef int csize_t;  // code size type; would be size_t except for history
  84 
  85  private:
  86   address     _start;           // first byte of contents (instructions)
  87   address     _mark;            // user mark, usually an instruction beginning
  88   address     _end;             // current end address
  89   address     _limit;           // last possible (allocated) end address
  90   relocInfo*  _locs_start;      // first byte of relocation information
  91   relocInfo*  _locs_end;        // first byte after relocation information
  92   relocInfo*  _locs_limit;      // first byte after relocation information buf
  93   address     _locs_point;      // last relocated position (grows upward)
  94   bool        _locs_own;        // did I allocate the locs myself?
  95   bool        _frozen;          // no more expansion of this section
  96   bool        _scratch_emit;    // Buffer is used for scratch emit, don't relocate.
  97   char        _index;           // my section number (SECT_INST, etc.)
  98   CodeBuffer* _outer;           // enclosing CodeBuffer
  99 
 100   // (Note:  _locs_point used to be called _last_reloc_offset.)
 101 
 102   CodeSection() {
 103     _start         = NULL;
 104     _mark          = NULL;
 105     _end           = NULL;
 106     _limit         = NULL;
 107     _locs_start    = NULL;
 108     _locs_end      = NULL;
 109     _locs_limit    = NULL;
 110     _locs_point    = NULL;
 111     _locs_own      = false;
 112     _frozen        = false;
 113     _scratch_emit  = false;
 114     debug_only(_index = (char)-1);
 115     debug_only(_outer = (CodeBuffer*)badAddress);
 116   }
 117 
 118   void initialize_outer(CodeBuffer* outer, int index) {
 119     _outer = outer;
 120     _index = index;
 121   }
 122 
 123   void initialize(address start, csize_t size = 0) {
 124     assert(_start == NULL, "only one init step, please");
 125     _start         = start;
 126     _mark          = NULL;
 127     _end           = start;
 128 
 129     _limit         = start + size;
 130     _locs_point    = start;
 131   }
 132 
 133   void initialize_locs(int locs_capacity);
 134   void expand_locs(int new_capacity);
 135   void initialize_locs_from(const CodeSection* source_cs);
 136 
 137   // helper for CodeBuffer::expand()
 138   void take_over_code_from(CodeSection* cs) {
 139     _start      = cs->_start;
 140     _mark       = cs->_mark;
 141     _end        = cs->_end;
 142     _limit      = cs->_limit;
 143     _locs_point = cs->_locs_point;
 144   }
 145 
 146  public:
 147   address     start() const         { return _start; }
 148   address     mark() const          { return _mark; }
 149   address     end() const           { return _end; }
 150   address     limit() const         { return _limit; }
 151   csize_t     size() const          { return (csize_t)(_end - _start); }
 152   csize_t     mark_off() const      { assert(_mark != NULL, "not an offset");
 153                                       return (csize_t)(_mark - _start); }
 154   csize_t     capacity() const      { return (csize_t)(_limit - _start); }
 155   csize_t     remaining() const     { return (csize_t)(_limit - _end); }
 156 
 157   relocInfo*  locs_start() const    { return _locs_start; }
 158   relocInfo*  locs_end() const      { return _locs_end; }
 159   int         locs_count() const    { return (int)(_locs_end - _locs_start); }
 160   relocInfo*  locs_limit() const    { return _locs_limit; }
 161   address     locs_point() const    { return _locs_point; }
 162   csize_t     locs_point_off() const{ return (csize_t)(_locs_point - _start); }
 163   csize_t     locs_capacity() const { return (csize_t)(_locs_limit - _locs_start); }
 164   csize_t     locs_remaining()const { return (csize_t)(_locs_limit - _locs_end); }
 165 
 166   int         index() const         { return _index; }
 167   bool        is_allocated() const  { return _start != NULL; }
 168   bool        is_empty() const      { return _start == _end; }
 169   bool        is_frozen() const     { return _frozen; }
 170   bool        has_locs() const      { return _locs_end != NULL; }
 171 
 172   // Mark scratch buffer.
 173   void        set_scratch_emit()    { _scratch_emit = true; }
 174   bool        scratch_emit()        { return _scratch_emit; }
 175 
 176   CodeBuffer* outer() const         { return _outer; }
 177 
 178   // is a given address in this section?  (2nd version is end-inclusive)
 179   bool contains(address pc) const   { return pc >= _start && pc <  _end; }
 180   bool contains2(address pc) const  { return pc >= _start && pc <= _end; }
 181   bool allocates(address pc) const  { return pc >= _start && pc <  _limit; }
 182   bool allocates2(address pc) const { return pc >= _start && pc <= _limit; }
 183 
 184   void    set_end(address pc)       { assert(allocates2(pc), "not in CodeBuffer memory: " INTPTR_FORMAT " <= " INTPTR_FORMAT " <= " INTPTR_FORMAT, p2i(_start), p2i(pc), p2i(_limit)); _end = pc; }
 185   void    set_mark(address pc)      { assert(contains2(pc), "not in codeBuffer");
 186                                       _mark = pc; }
 187   void    set_mark_off(int offset)  { assert(contains2(offset+_start),"not in codeBuffer");
 188                                       _mark = offset + _start; }
 189   void    set_mark()                { _mark = _end; }
 190   void    clear_mark()              { _mark = NULL; }
 191 
 192   void    set_locs_end(relocInfo* p) {
 193     assert(p <= locs_limit(), "locs data fits in allocated buffer");
 194     _locs_end = p;
 195   }
 196   void    set_locs_point(address pc) {
 197     assert(pc >= locs_point(), "relocation addr may not decrease");
 198     assert(allocates2(pc),     "relocation addr must be in this section");
 199     _locs_point = pc;
 200   }
 201 
 202   // Code emission
 203   void emit_int8 ( int8_t  x)  { *((int8_t*)  end()) = x; set_end(end() + sizeof(int8_t)); }
 204   void emit_int16( int16_t x)  { *((int16_t*) end()) = x; set_end(end() + sizeof(int16_t)); }
 205   void emit_int32( int32_t x)  { *((int32_t*) end()) = x; set_end(end() + sizeof(int32_t)); }
 206   void emit_int64( int64_t x)  { *((int64_t*) end()) = x; set_end(end() + sizeof(int64_t)); }
 207 
 208   void emit_float( jfloat  x)  { *((jfloat*)  end()) = x; set_end(end() + sizeof(jfloat)); }
 209   void emit_double(jdouble x)  { *((jdouble*) end()) = x; set_end(end() + sizeof(jdouble)); }
 210   void emit_address(address x) { *((address*) end()) = x; set_end(end() + sizeof(address)); }
 211 
 212   // Share a scratch buffer for relocinfo.  (Hacky; saves a resource allocation.)
 213   void initialize_shared_locs(relocInfo* buf, int length);
 214 
 215   // Manage labels and their addresses.
 216   address target(Label& L, address branch_pc);
 217 
 218   // Emit a relocation.
 219   void relocate(address at, RelocationHolder const& rspec, int format = 0);
 220   void relocate(address at,    relocInfo::relocType rtype, int format = 0, jint method_index = 0);
 221 
 222   // alignment requirement for starting offset
 223   // Requirements are that the instruction area and the
 224   // stubs area must start on CodeEntryAlignment, and
 225   // the ctable on sizeof(jdouble)
 226   int alignment() const             { return MAX2((int)sizeof(jdouble), (int)CodeEntryAlignment); }
 227 
 228   // Slop between sections, used only when allocating temporary BufferBlob buffers.
 229   static csize_t end_slop()         { return MAX2((int)sizeof(jdouble), (int)CodeEntryAlignment); }
 230 
 231   csize_t align_at_start(csize_t off) const { return (csize_t) align_up(off, alignment()); }
 232 
 233   // Mark a section frozen.  Assign its remaining space to
 234   // the following section.  It will never expand after this point.
 235   inline void freeze();         //  { _outer->freeze_section(this); }
 236 
 237   // Ensure there's enough space left in the current section.
 238   // Return true if there was an expansion.
 239   bool maybe_expand_to_ensure_remaining(csize_t amount);
 240 
 241 #ifndef PRODUCT
 242   void decode();
 243   void dump();
 244   void print(const char* name);
 245 #endif //PRODUCT
 246 };
 247 
 248 class CodeString;
 249 class CodeStrings VALUE_OBJ_CLASS_SPEC {
 250 private:
 251 #ifndef PRODUCT
 252   CodeString* _strings;
 253 #ifdef ASSERT
 254   // Becomes true after copy-out, forbids further use.
 255   bool _defunct; // Zero bit pattern is "valid", see memset call in decode_env::decode_env
 256 #endif
 257   static const char* _prefix; // defaults to " ;; "
 258 #endif
 259 
 260   CodeString* find(intptr_t offset) const;
 261   CodeString* find_last(intptr_t offset) const;
 262 
 263   void set_null_and_invalidate() {
 264 #ifndef PRODUCT
 265     _strings = NULL;
 266 #ifdef ASSERT
 267     _defunct = true;
 268 #endif
 269 #endif
 270   }
 271 
 272 public:
 273   CodeStrings() {
 274 #ifndef PRODUCT
 275     _strings = NULL;
 276 #ifdef ASSERT
 277     _defunct = false;
 278 #endif
 279 #endif
 280   }
 281 
 282   bool is_null() {
 283 #ifdef ASSERT
 284     return _strings == NULL;
 285 #else
 286     return true;
 287 #endif
 288   }
 289 
 290   const char* add_string(const char * string) PRODUCT_RETURN_(return NULL;);
 291 
 292   void add_comment(intptr_t offset, const char * comment) PRODUCT_RETURN;
 293   void print_block_comment(outputStream* stream, intptr_t offset) const PRODUCT_RETURN;
 294   // MOVE strings from other to this; invalidate other.
 295   void assign(CodeStrings& other)  PRODUCT_RETURN;
 296   // COPY strings from other to this; leave other valid.
 297   void copy(CodeStrings& other)  PRODUCT_RETURN;
 298   // FREE strings; invalidate this.
 299   void free() PRODUCT_RETURN;
 300   // Guarantee that _strings are used at most once; assign and free invalidate a buffer.
 301   inline void check_valid() const {
 302 #ifdef ASSERT
 303     assert(!_defunct, "Use of invalid CodeStrings");
 304 #endif
 305   }
 306 
 307   static void set_prefix(const char *prefix) {
 308 #ifndef PRODUCT
 309     _prefix = prefix;
 310 #endif
 311   }
 312 };
 313 
 314 // A CodeBuffer describes a memory space into which assembly
 315 // code is generated.  This memory space usually occupies the
 316 // interior of a single BufferBlob, but in some cases it may be
 317 // an arbitrary span of memory, even outside the code cache.
 318 //
 319 // A code buffer comes in two variants:
 320 //
 321 // (1) A CodeBuffer referring to an already allocated piece of memory:
 322 //     This is used to direct 'static' code generation (e.g. for interpreter
 323 //     or stubroutine generation, etc.).  This code comes with NO relocation
 324 //     information.
 325 //
 326 // (2) A CodeBuffer referring to a piece of memory allocated when the
 327 //     CodeBuffer is allocated.  This is used for nmethod generation.
 328 //
 329 // The memory can be divided up into several parts called sections.
 330 // Each section independently accumulates code (or data) an relocations.
 331 // Sections can grow (at the expense of a reallocation of the BufferBlob
 332 // and recopying of all active sections).  When the buffered code is finally
 333 // written to an nmethod (or other CodeBlob), the contents (code, data,
 334 // and relocations) of the sections are padded to an alignment and concatenated.
 335 // Instructions and data in one section can contain relocatable references to
 336 // addresses in a sibling section.
 337 
 338 class CodeBuffer: public StackObj {
 339   friend class CodeSection;
 340 
 341  private:
 342   // CodeBuffers must be allocated on the stack except for a single
 343   // special case during expansion which is handled internally.  This
 344   // is done to guarantee proper cleanup of resources.
 345   void* operator new(size_t size) throw() { return ResourceObj::operator new(size); }
 346   void  operator delete(void* p)          { ShouldNotCallThis(); }
 347 
 348  public:
 349   typedef int csize_t;  // code size type; would be size_t except for history
 350   enum {
 351     // Here is the list of all possible sections.  The order reflects
 352     // the final layout.
 353     SECT_FIRST = 0,
 354     SECT_CONSTS = SECT_FIRST, // Non-instruction data:  Floats, jump tables, etc.
 355     SECT_INSTS,               // Executable instructions.
 356     SECT_STUBS,               // Outbound trampolines for supporting call sites.
 357     SECT_LIMIT, SECT_NONE = -1
 358   };
 359 
 360  private:
 361   enum {
 362     sect_bits = 2,      // assert (SECT_LIMIT <= (1<<sect_bits))
 363     sect_mask = (1<<sect_bits)-1
 364   };
 365 
 366   const char*  _name;
 367 
 368   CodeSection  _consts;             // constants, jump tables
 369   CodeSection  _insts;              // instructions (the main section)
 370   CodeSection  _stubs;              // stubs (call site support), deopt, exception handling
 371 
 372   CodeBuffer*  _before_expand;  // dead buffer, from before the last expansion
 373 
 374   BufferBlob*  _blob;           // optional buffer in CodeCache for generated code
 375   address      _total_start;    // first address of combined memory buffer
 376   csize_t      _total_size;     // size in bytes of combined memory buffer
 377 
 378   OopRecorder* _oop_recorder;
 379   CodeStrings  _code_strings;
 380   OopRecorder  _default_oop_recorder;  // override with initialize_oop_recorder
 381   Arena*       _overflow_arena;
 382 
 383   address      _last_membar;     // used to merge consecutive memory barriers
 384 
 385   address      _decode_begin;   // start address for decode
 386   address      decode_begin();
 387 
 388   void initialize_misc(const char * name) {
 389     // all pointers other than code_start/end and those inside the sections
 390     assert(name != NULL, "must have a name");
 391     _name            = name;
 392     _before_expand   = NULL;
 393     _blob            = NULL;
 394     _oop_recorder    = NULL;
 395     _decode_begin    = NULL;
 396     _overflow_arena  = NULL;
 397     _code_strings    = CodeStrings();
 398     _last_membar     = NULL;
 399   }
 400 
 401   void initialize(address code_start, csize_t code_size) {
 402     _consts.initialize_outer(this,  SECT_CONSTS);
 403     _insts.initialize_outer(this,   SECT_INSTS);
 404     _stubs.initialize_outer(this,   SECT_STUBS);
 405     _total_start = code_start;
 406     _total_size  = code_size;
 407     // Initialize the main section:
 408     _insts.initialize(code_start, code_size);
 409     assert(!_stubs.is_allocated(),  "no garbage here");
 410     assert(!_consts.is_allocated(), "no garbage here");
 411     _oop_recorder = &_default_oop_recorder;
 412   }
 413 
 414   void initialize_section_size(CodeSection* cs, csize_t size);
 415 
 416   void freeze_section(CodeSection* cs);
 417 
 418   // helper for CodeBuffer::expand()
 419   void take_over_code_from(CodeBuffer* cs);
 420 
 421   // ensure sections are disjoint, ordered, and contained in the blob
 422   void verify_section_allocation();
 423 
 424   // copies combined relocations to the blob, returns bytes copied
 425   // (if target is null, it is a dry run only, just for sizing)
 426   csize_t copy_relocations_to(CodeBlob* blob) const;
 427 
 428   // copies combined code to the blob (assumes relocs are already in there)
 429   void copy_code_to(CodeBlob* blob);
 430 
 431   // moves code sections to new buffer (assumes relocs are already in there)
 432   void relocate_code_to(CodeBuffer* cb) const;
 433 
 434   // set up a model of the final layout of my contents
 435   void compute_final_layout(CodeBuffer* dest) const;
 436 
 437   // Expand the given section so at least 'amount' is remaining.
 438   // Creates a new, larger BufferBlob, and rewrites the code & relocs.
 439   void expand(CodeSection* which_cs, csize_t amount);
 440 
 441   // Helper for expand.
 442   csize_t figure_expanded_capacities(CodeSection* which_cs, csize_t amount, csize_t* new_capacity);
 443 
 444  public:
 445   // (1) code buffer referring to pre-allocated instruction memory
 446   CodeBuffer(address code_start, csize_t code_size) {
 447     assert(code_start != NULL, "sanity");
 448     initialize_misc("static buffer");
 449     initialize(code_start, code_size);
 450     verify_section_allocation();
 451   }
 452 
 453   // (2) CodeBuffer referring to pre-allocated CodeBlob.
 454   CodeBuffer(CodeBlob* blob);
 455 
 456   // (3) code buffer allocating codeBlob memory for code & relocation
 457   // info but with lazy initialization.  The name must be something
 458   // informative.
 459   CodeBuffer(const char* name) {
 460     initialize_misc(name);
 461   }
 462 
 463   // (4) code buffer allocating codeBlob memory for code & relocation
 464   // info.  The name must be something informative and code_size must
 465   // include both code and stubs sizes.
 466   CodeBuffer(const char* name, csize_t code_size, csize_t locs_size) {
 467     initialize_misc(name);
 468     initialize(code_size, locs_size);
 469   }
 470 
 471   ~CodeBuffer();
 472 
 473   // Initialize a CodeBuffer constructed using constructor 3.  Using
 474   // constructor 4 is equivalent to calling constructor 3 and then
 475   // calling this method.  It's been factored out for convenience of
 476   // construction.
 477   void initialize(csize_t code_size, csize_t locs_size);
 478 
 479   CodeSection* consts() { return &_consts; }
 480   CodeSection* insts() { return &_insts; }
 481   CodeSection* stubs() { return &_stubs; }
 482 
 483   const CodeSection* insts() const { return &_insts; }
 484 
 485   // present sections in order; return NULL at end; consts is #0, etc.
 486   CodeSection* code_section(int n) {
 487     // This makes the slightly questionable but portable assumption
 488     // that the various members (_consts, _insts, _stubs, etc.) are
 489     // adjacent in the layout of CodeBuffer.
 490     CodeSection* cs = &_consts + n;
 491     assert(cs->index() == n || !cs->is_allocated(), "sanity");
 492     return cs;
 493   }
 494   const CodeSection* code_section(int n) const {  // yucky const stuff
 495     return ((CodeBuffer*)this)->code_section(n);
 496   }
 497   static const char* code_section_name(int n);
 498   int section_index_of(address addr) const;
 499   bool contains(address addr) const {
 500     // handy for debugging
 501     return section_index_of(addr) > SECT_NONE;
 502   }
 503 
 504   // A stable mapping between 'locators' (small ints) and addresses.
 505   static int locator_pos(int locator)   { return locator >> sect_bits; }
 506   static int locator_sect(int locator)  { return locator &  sect_mask; }
 507   static int locator(int pos, int sect) { return (pos << sect_bits) | sect; }
 508   int        locator(address addr) const;
 509   address    locator_address(int locator) const;
 510 
 511   // Heuristic for pre-packing the taken/not-taken bit of a predicted branch.
 512   bool is_backward_branch(Label& L);
 513 
 514   // Properties
 515   const char* name() const                  { return _name; }
 516   void set_name(const char* name)           { _name = name; }
 517   CodeBuffer* before_expand() const         { return _before_expand; }
 518   BufferBlob* blob() const                  { return _blob; }
 519   void    set_blob(BufferBlob* blob);
 520   void   free_blob();                       // Free the blob, if we own one.
 521 
 522   // Properties relative to the insts section:
 523   address       insts_begin() const      { return _insts.start();      }
 524   address       insts_end() const        { return _insts.end();        }
 525   void      set_insts_end(address end)   {        _insts.set_end(end); }
 526   address       insts_limit() const      { return _insts.limit();      }
 527   address       insts_mark() const       { return _insts.mark();       }
 528   void      set_insts_mark()             {        _insts.set_mark();   }
 529   void    clear_insts_mark()             {        _insts.clear_mark(); }
 530 
 531   // is there anything in the buffer other than the current section?
 532   bool    is_pure() const                { return insts_size() == total_content_size(); }
 533 
 534   // size in bytes of output so far in the insts sections
 535   csize_t insts_size() const             { return _insts.size(); }
 536 
 537   // same as insts_size(), except that it asserts there is no non-code here
 538   csize_t pure_insts_size() const        { assert(is_pure(), "no non-code");
 539                                            return insts_size(); }
 540   // capacity in bytes of the insts sections
 541   csize_t insts_capacity() const         { return _insts.capacity(); }
 542 
 543   // number of bytes remaining in the insts section
 544   csize_t insts_remaining() const        { return _insts.remaining(); }
 545 
 546   // is a given address in the insts section?  (2nd version is end-inclusive)
 547   bool insts_contains(address pc) const  { return _insts.contains(pc); }
 548   bool insts_contains2(address pc) const { return _insts.contains2(pc); }
 549 
 550   // Record any extra oops required to keep embedded metadata alive
 551   void finalize_oop_references(const methodHandle& method);
 552 
 553   // Allocated size in all sections, when aligned and concatenated
 554   // (this is the eventual state of the content in its final
 555   // CodeBlob).
 556   csize_t total_content_size() const;
 557 
 558   // Combined offset (relative to start of first section) of given
 559   // section, as eventually found in the final CodeBlob.
 560   csize_t total_offset_of(const CodeSection* cs) const;
 561 
 562   // allocated size of all relocation data, including index, rounded up
 563   csize_t total_relocation_size() const;
 564 
 565   csize_t copy_relocations_to(address buf, csize_t buf_limit, bool only_inst) const;
 566 
 567   // allocated size of any and all recorded oops
 568   csize_t total_oop_size() const {
 569     OopRecorder* recorder = oop_recorder();
 570     return (recorder == NULL)? 0: recorder->oop_size();
 571   }
 572 
 573   // allocated size of any and all recorded metadata
 574   csize_t total_metadata_size() const {
 575     OopRecorder* recorder = oop_recorder();
 576     return (recorder == NULL)? 0: recorder->metadata_size();
 577   }
 578 
 579   // Configuration functions, called immediately after the CB is constructed.
 580   // The section sizes are subtracted from the original insts section.
 581   // Note:  Call them in reverse section order, because each steals from insts.
 582   void initialize_consts_size(csize_t size)            { initialize_section_size(&_consts,  size); }
 583   void initialize_stubs_size(csize_t size)             { initialize_section_size(&_stubs,   size); }
 584   // Override default oop recorder.
 585   void initialize_oop_recorder(OopRecorder* r);
 586 
 587   OopRecorder* oop_recorder() const   { return _oop_recorder; }
 588   CodeStrings& strings()              { return _code_strings; }
 589 
 590   address last_membar() const { return _last_membar; }
 591   void set_last_membar(address a) { _last_membar = a; }
 592   void clear_last_membar() { set_last_membar(NULL); }
 593 
 594   void free_strings() {
 595     if (!_code_strings.is_null()) {
 596       _code_strings.free(); // sets _strings Null as a side-effect.
 597     }
 598   }
 599 
 600   // Code generation
 601   void relocate(address at, RelocationHolder const& rspec, int format = 0) {
 602     _insts.relocate(at, rspec, format);
 603   }
 604   void relocate(address at,    relocInfo::relocType rtype, int format = 0) {
 605     _insts.relocate(at, rtype, format);
 606   }
 607 
 608   // Management of overflow storage for binding of Labels.
 609   GrowableArray<int>* create_patch_overflow();
 610 
 611   // NMethod generation
 612   void copy_code_and_locs_to(CodeBlob* blob) {
 613     assert(blob != NULL, "sane");
 614     copy_relocations_to(blob);
 615     copy_code_to(blob);
 616   }
 617   void copy_values_to(nmethod* nm) {
 618     if (!oop_recorder()->is_unused()) {
 619       oop_recorder()->copy_values_to(nm);
 620     }
 621   }
 622 
 623   // Transform an address from the code in this code buffer to a specified code buffer
 624   address transform_address(const CodeBuffer &cb, address addr) const;
 625 
 626   void block_comment(intptr_t offset, const char * comment) PRODUCT_RETURN;
 627   const char* code_string(const char* str) PRODUCT_RETURN_(return NULL;);
 628 
 629   // Log a little info about section usage in the CodeBuffer
 630   void log_section_sizes(const char* name);
 631 
 632 #ifndef PRODUCT
 633  public:
 634   // Printing / Decoding
 635   // decodes from decode_begin() to code_end() and sets decode_begin to end
 636   void    decode();
 637   void    decode_all();         // decodes all the code
 638   void    skip_decode();        // sets decode_begin to code_end();
 639   void    print();
 640 #endif
 641 
 642 
 643   // The following header contains architecture-specific implementations
 644 #include CPU_HEADER(codeBuffer)
 645 
 646 };
 647 
 648 
 649 inline void CodeSection::freeze() {
 650   _outer->freeze_section(this);
 651 }
 652 
 653 inline bool CodeSection::maybe_expand_to_ensure_remaining(csize_t amount) {
 654   if (remaining() < amount) { _outer->expand(this, amount); return true; }
 655   return false;
 656 }
 657 
 658 #endif // SHARE_VM_ASM_CODEBUFFER_HPP