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24 
25 #ifndef SHARE_VM_RUNTIME_VFRAMEARRAY_HPP
26 #define SHARE_VM_RUNTIME_VFRAMEARRAY_HPP
27 
28 #include "memory/allocation.hpp"
29 #include "oops/arrayOop.hpp"
30 #include "runtime/deoptimization.hpp"
31 #include "runtime/frame.hpp"
32 #include "runtime/monitorChunk.hpp"
33 #include "utilities/growableArray.hpp"
34 
35 // A vframeArray is an array used for momentarily storing off stack Java method activations
36 // during deoptimization. Essentially it is an array of vframes where each vframe
37 // data is stored off stack. This structure will never exist across a safepoint so
38 // there is no need to gc any oops that are stored in the structure.
39 
40 
41 class LocalsClosure;
42 class ExpressionStackClosure;
43 class MonitorStackClosure;
44 class MonitorArrayElement;
45 class StackValueCollection;
46 
47 // A vframeArrayElement is an element of a vframeArray. Each element
48 // represent an interpreter frame which will eventually be created.
49 
50 class vframeArrayElement {
51   friend class VMStructs;
52 
53   private:
54 
55     frame _frame;                                                // the interpreter frame we will unpack into
56     int  _bci;                                                   // raw bci for this vframe
57     bool _reexecute;                                             // whether we should reexecute this bytecode
58     Method*    _method;                                          // the method for this vframe
59     MonitorChunk* _monitors;                                     // active monitors for this vframe
60     StackValueCollection* _locals;
61     StackValueCollection* _expressions;
62 #ifdef ASSERT
63     bool _removed_monitors;
64 #endif
65 
66   public:
67 
iframe(void)68   frame* iframe(void)                { return &_frame; }
69 
70   int bci(void) const;
71 
raw_bci(void) const72   int raw_bci(void) const            { return _bci; }
should_reexecute(void) const73   bool should_reexecute(void) const  { return _reexecute; }
74 
method(void) const75   Method* method(void) const       { return _method; }
76 
monitors(void) const77   MonitorChunk* monitors(void) const { return _monitors; }
78 
79   void free_monitors(JavaThread* jt);
80 
locals(void) const81   StackValueCollection* locals(void) const             { return _locals; }
82 
expressions(void) const83   StackValueCollection* expressions(void) const        { return _expressions; }
84 
85   void fill_in(compiledVFrame* vf, bool realloc_failures);
86 
87   // Formerly part of deoptimizedVFrame
88 
89 
90   // Returns the on stack word size for this frame
91   // callee_parameters is the number of callee locals residing inside this frame
92   int on_stack_size(int callee_parameters,
93                     int callee_locals,
94                     bool is_top_frame,
95                     int popframe_extra_stack_expression_els) const;
96 
97   // Unpacks the element to skeletal interpreter frame
98   void unpack_on_stack(int caller_actual_parameters,
99                        int callee_parameters,
100                        int callee_locals,
101                        frame* caller,
102                        bool is_top_frame,
103                        bool is_bottom_frame,
104                        int exec_mode);
105 
106 #ifdef ASSERT
set_removed_monitors()107   void set_removed_monitors() {
108     _removed_monitors = true;
109   }
110 #endif
111 
112 #ifndef PRODUCT
113   void print(outputStream* st);
114 #endif /* PRODUCT */
115 };
116 
117 // this can be a ResourceObj if we don't save the last one...
118 // but it does make debugging easier even if we can't look
119 // at the data in each vframeElement
120 
121 class vframeArray: public CHeapObj<mtCompiler> {
122   friend class VMStructs;
123 
124  private:
125 
126 
127   // Here is what a vframeArray looks like in memory
128 
129   /*
130       fixed part
131         description of the original frame
132         _frames - number of vframes in this array
133         adapter info
134         callee register save area
135       variable part
136         vframeArrayElement   [ 0 ]
137         ...
138         vframeArrayElement   [_frames - 1]
139 
140   */
141 
142   JavaThread*                  _owner_thread;
143   vframeArray*                 _next;
144   frame                        _original;          // the original frame of the deoptee
145   frame                        _caller;            // caller of root frame in vframeArray
146   frame                        _sender;
147 
148   Deoptimization::UnrollBlock* _unroll_block;
149   int                          _frame_size;
150 
151   int                          _frames; // number of javavframes in the array (does not count any adapter)
152 
153   intptr_t                     _callee_registers[RegisterMap::reg_count];
154   unsigned char                _valid[RegisterMap::reg_count];
155 
156   vframeArrayElement           _elements[1];   // First variable section.
157 
158   void fill_in_element(int index, compiledVFrame* vf);
159 
is_location_valid(int i) const160   bool is_location_valid(int i) const        { return _valid[i] != 0; }
set_location_valid(int i,bool valid)161   void set_location_valid(int i, bool valid) { _valid[i] = valid; }
162 
163  public:
164 
165 
166   // Tells whether index is within bounds.
is_within_bounds(int index) const167   bool is_within_bounds(int index) const        { return 0 <= index && index < frames(); }
168 
169   // Accessories for instance variable
frames() const170   int frames() const                            { return _frames;   }
171 
172   static vframeArray* allocate(JavaThread* thread, int frame_size, GrowableArray<compiledVFrame*>* chunk,
173                                RegisterMap* reg_map, frame sender, frame caller, frame self,
174                                bool realloc_failures);
175 
176 
element(int index)177   vframeArrayElement* element(int index)        { assert(is_within_bounds(index), "Bad index"); return &_elements[index]; }
178 
179   // Allocates a new vframe in the array and fills the array with vframe information in chunk
180   void fill_in(JavaThread* thread, int frame_size, GrowableArray<compiledVFrame*>* chunk, const RegisterMap *reg_map, bool realloc_failures);
181 
182   // Returns the owner of this vframeArray
owner_thread() const183   JavaThread* owner_thread() const           { return _owner_thread; }
184 
185   // Accessors for next
next() const186   vframeArray* next() const                  { return _next; }
set_next(vframeArray * value)187   void set_next(vframeArray* value)          { _next = value; }
188 
189   // Accessors for sp
sp() const190   intptr_t* sp() const                       { return _original.sp(); }
191 
192   intptr_t* unextended_sp() const;
193 
original_pc() const194   address original_pc() const                { return _original.pc(); }
195 
original() const196   frame original() const                     { return _original; }
197 
caller() const198   frame caller() const                       { return _caller; }
199 
sender() const200   frame sender() const                       { return _sender; }
201 
202   // Accessors for unroll block
unroll_block() const203   Deoptimization::UnrollBlock* unroll_block() const         { return _unroll_block; }
set_unroll_block(Deoptimization::UnrollBlock * block)204   void set_unroll_block(Deoptimization::UnrollBlock* block) { _unroll_block = block; }
205 
206   // Returns the size of the frame that got deoptimized
frame_size() const207   int frame_size() const { return _frame_size; }
208 
209   // Unpack the array on the stack passed in stack interval
210   void unpack_to_stack(frame &unpack_frame, int exec_mode, int caller_actual_parameters);
211 
212   // Deallocates monitor chunks allocated during deoptimization.
213   // This should be called when the array is not used anymore.
214   void deallocate_monitor_chunks();
215 
216 
217 
218   // Accessor for register map
219   address register_location(int i) const;
220 
221   void print_on_2(outputStream* st) PRODUCT_RETURN;
222   void print_value_on(outputStream* st) const PRODUCT_RETURN;
223 
224 #ifndef PRODUCT
225   // Comparing
226   bool structural_compare(JavaThread* thread, GrowableArray<compiledVFrame*>* chunk);
227 #endif
228 
229 };
230 
231 #endif // SHARE_VM_RUNTIME_VFRAMEARRAY_HPP
232