6668573: CMS: reference processing crash if ParallelCMSThreads > ParallelGCThreads
Summary: Use _max_num_q = max(discovery_degree, processing_degree), and let balance_queues() redistribute from discovery_degree to processing_degree of queues. This should also allow a more dynamic and flexible parallelism policy in the future.
Reviewed-by: jmasa, johnc
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#ifndef SHARE_VM_MEMORY_HEAP_HPP
#define SHARE_VM_MEMORY_HEAP_HPP
#include "memory/allocation.hpp"
#include "runtime/virtualspace.hpp"
// Blocks
class HeapBlock VALUE_OBJ_CLASS_SPEC {
friend class VMStructs;
public:
struct Header {
size_t _length; // the length in segments
bool _used; // Used bit
};
protected:
union {
Header _header;
int64_t _padding[ (sizeof(Header) + sizeof(int64_t)-1) / sizeof(int64_t) ];
// pad to 0 mod 8
};
public:
// Initialization
void initialize(size_t length) { _header._length = length; set_used(); }
// Accessors
void* allocated_space() const { return (void*)(this + 1); }
size_t length() const { return _header._length; }
// Used/free
void set_used() { _header._used = true; }
void set_free() { _header._used = false; }
bool free() { return !_header._used; }
};
class FreeBlock: public HeapBlock {
friend class VMStructs;
protected:
FreeBlock* _link;
public:
// Initialization
void initialize(size_t length) { HeapBlock::initialize(length); _link= NULL; }
// Merging
void set_length(size_t l) { _header._length = l; }
// Accessors
FreeBlock* link() const { return _link; }
void set_link(FreeBlock* link) { _link = link; }
};
class CodeHeap : public CHeapObj {
friend class VMStructs;
private:
VirtualSpace _memory; // the memory holding the blocks
VirtualSpace _segmap; // the memory holding the segment map
size_t _number_of_committed_segments;
size_t _number_of_reserved_segments;
size_t _segment_size;
int _log2_segment_size;
size_t _next_segment;
FreeBlock* _freelist;
size_t _free_segments; // No. of segments in freelist
// Helper functions
size_t number_of_segments(size_t size) const { return (size + _segment_size - 1) >> _log2_segment_size; }
size_t size(size_t number_of_segments) const { return number_of_segments << _log2_segment_size; }
size_t segment_for(void* p) const { return ((char*)p - _memory.low()) >> _log2_segment_size; }
HeapBlock* block_at(size_t i) const { return (HeapBlock*)(_memory.low() + (i << _log2_segment_size)); }
void mark_segmap_as_free(size_t beg, size_t end);
void mark_segmap_as_used(size_t beg, size_t end);
// Freelist management helpers
FreeBlock* following_block(FreeBlock *b);
void insert_after(FreeBlock* a, FreeBlock* b);
void merge_right (FreeBlock* a);
// Toplevel freelist management
void add_to_freelist(HeapBlock *b);
FreeBlock* search_freelist(size_t length);
// Iteration helpers
void* next_free(HeapBlock* b) const;
HeapBlock* first_block() const;
HeapBlock* next_block(HeapBlock* b) const;
HeapBlock* block_start(void* p) const;
// to perform additional actions on creation of executable code
void on_code_mapping(char* base, size_t size);
public:
CodeHeap();
// Heap extents
bool reserve(size_t reserved_size, size_t committed_size, size_t segment_size);
void release(); // releases all allocated memory
bool expand_by(size_t size); // expands commited memory by size
void shrink_by(size_t size); // shrinks commited memory by size
void clear(); // clears all heap contents
// Memory allocation
void* allocate (size_t size); // allocates a block of size or returns NULL
void deallocate(void* p); // deallocates a block
// Attributes
void* begin() const { return _memory.low (); }
void* end() const { return _memory.high(); }
bool contains(void* p) const { return begin() <= p && p < end(); }
void* find_start(void* p) const; // returns the block containing p or NULL
size_t alignment_unit() const; // alignment of any block
size_t alignment_offset() const; // offset of first byte of any block, within the enclosing alignment unit
static size_t header_size(); // returns the header size for each heap block
// Returns reserved area high and low addresses
char *low_boundary() const { return _memory.low_boundary (); }
char *high() const { return _memory.high(); }
char *high_boundary() const { return _memory.high_boundary(); }
// Iteration
// returns the first block or NULL
void* first() const { return next_free(first_block()); }
// returns the next block given a block p or NULL
void* next(void* p) const { return next_free(next_block(block_start(p))); }
// Statistics
size_t capacity() const;
size_t max_capacity() const;
size_t allocated_capacity() const;
size_t unallocated_capacity() const { return max_capacity() - allocated_capacity(); }
size_t largest_free_block() const;
// Debugging
void verify();
void print() PRODUCT_RETURN;
};
#endif // SHARE_VM_MEMORY_HEAP_HPP