Mercurial > hg > truffle
annotate src/share/vm/gc_implementation/concurrentMarkSweep/binaryTreeDictionary.cpp @ 975:83c29a26f67c
6879572: SA fails _is_marked_dependent not found
Reviewed-by: kamg, dcubed
author | acorn |
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date | Wed, 16 Sep 2009 15:42:46 -0400 |
parents | 850fdf70db2b |
children | e018e6884bd8 |
rev | line source |
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0 | 1 /* |
196 | 2 * Copyright 2001-2008 Sun Microsystems, Inc. All Rights Reserved. |
0 | 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 Sun Microsystems, Inc., 4150 Network Circle, Santa Clara, | |
20 * CA 95054 USA or visit www.sun.com if you need additional information or | |
21 * have any questions. | |
22 * | |
23 */ | |
24 | |
25 # include "incls/_precompiled.incl" | |
26 # include "incls/_binaryTreeDictionary.cpp.incl" | |
27 | |
28 //////////////////////////////////////////////////////////////////////////////// | |
29 // A binary tree based search structure for free blocks. | |
30 // This is currently used in the Concurrent Mark&Sweep implementation. | |
31 //////////////////////////////////////////////////////////////////////////////// | |
32 | |
33 TreeChunk* TreeChunk::as_TreeChunk(FreeChunk* fc) { | |
34 // Do some assertion checking here. | |
35 return (TreeChunk*) fc; | |
36 } | |
37 | |
38 void TreeChunk::verifyTreeChunkList() const { | |
39 TreeChunk* nextTC = (TreeChunk*)next(); | |
40 if (prev() != NULL) { // interior list node shouldn'r have tree fields | |
41 guarantee(embedded_list()->parent() == NULL && embedded_list()->left() == NULL && | |
42 embedded_list()->right() == NULL, "should be clear"); | |
43 } | |
44 if (nextTC != NULL) { | |
45 guarantee(as_TreeChunk(nextTC->prev()) == this, "broken chain"); | |
46 guarantee(nextTC->size() == size(), "wrong size"); | |
47 nextTC->verifyTreeChunkList(); | |
48 } | |
49 } | |
50 | |
51 | |
52 TreeList* TreeList::as_TreeList(TreeChunk* tc) { | |
53 // This first free chunk in the list will be the tree list. | |
54 assert(tc->size() >= sizeof(TreeChunk), "Chunk is too small for a TreeChunk"); | |
55 TreeList* tl = tc->embedded_list(); | |
56 tc->set_list(tl); | |
57 #ifdef ASSERT | |
58 tl->set_protecting_lock(NULL); | |
59 #endif | |
60 tl->set_hint(0); | |
61 tl->set_size(tc->size()); | |
62 tl->link_head(tc); | |
63 tl->link_tail(tc); | |
64 tl->set_count(1); | |
65 tl->init_statistics(); | |
66 tl->setParent(NULL); | |
67 tl->setLeft(NULL); | |
68 tl->setRight(NULL); | |
69 return tl; | |
70 } | |
71 TreeList* TreeList::as_TreeList(HeapWord* addr, size_t size) { | |
72 TreeChunk* tc = (TreeChunk*) addr; | |
73 assert(size >= sizeof(TreeChunk), "Chunk is too small for a TreeChunk"); | |
263
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74 // The space in the heap will have been mangled initially but |
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75 // is not remangled when a free chunk is returned to the free list |
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76 // (since it is used to maintain the chunk on the free list). |
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77 assert((ZapUnusedHeapArea && |
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78 SpaceMangler::is_mangled((HeapWord*) tc->size_addr()) && |
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79 SpaceMangler::is_mangled((HeapWord*) tc->prev_addr()) && |
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80 SpaceMangler::is_mangled((HeapWord*) tc->next_addr())) || |
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81 (tc->size() == 0 && tc->prev() == NULL && tc->next() == NULL), |
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82 "Space should be clear or mangled"); |
0 | 83 tc->setSize(size); |
84 tc->linkPrev(NULL); | |
85 tc->linkNext(NULL); | |
86 TreeList* tl = TreeList::as_TreeList(tc); | |
87 return tl; | |
88 } | |
89 | |
90 TreeList* TreeList::removeChunkReplaceIfNeeded(TreeChunk* tc) { | |
91 | |
92 TreeList* retTL = this; | |
93 FreeChunk* list = head(); | |
94 assert(!list || list != list->next(), "Chunk on list twice"); | |
95 assert(tc != NULL, "Chunk being removed is NULL"); | |
96 assert(parent() == NULL || this == parent()->left() || | |
97 this == parent()->right(), "list is inconsistent"); | |
98 assert(tc->isFree(), "Header is not marked correctly"); | |
99 assert(head() == NULL || head()->prev() == NULL, "list invariant"); | |
100 assert(tail() == NULL || tail()->next() == NULL, "list invariant"); | |
101 | |
102 FreeChunk* prevFC = tc->prev(); | |
103 TreeChunk* nextTC = TreeChunk::as_TreeChunk(tc->next()); | |
104 assert(list != NULL, "should have at least the target chunk"); | |
105 | |
106 // Is this the first item on the list? | |
107 if (tc == list) { | |
108 // The "getChunk..." functions for a TreeList will not return the | |
109 // first chunk in the list unless it is the last chunk in the list | |
110 // because the first chunk is also acting as the tree node. | |
111 // When coalescing happens, however, the first chunk in the a tree | |
112 // list can be the start of a free range. Free ranges are removed | |
113 // from the free lists so that they are not available to be | |
114 // allocated when the sweeper yields (giving up the free list lock) | |
115 // to allow mutator activity. If this chunk is the first in the | |
116 // list and is not the last in the list, do the work to copy the | |
117 // TreeList from the first chunk to the next chunk and update all | |
118 // the TreeList pointers in the chunks in the list. | |
119 if (nextTC == NULL) { | |
120 assert(prevFC == NULL, "Not last chunk in the list") | |
121 set_tail(NULL); | |
122 set_head(NULL); | |
123 } else { | |
124 // copy embedded list. | |
125 nextTC->set_embedded_list(tc->embedded_list()); | |
126 retTL = nextTC->embedded_list(); | |
127 // Fix the pointer to the list in each chunk in the list. | |
128 // This can be slow for a long list. Consider having | |
129 // an option that does not allow the first chunk on the | |
130 // list to be coalesced. | |
131 for (TreeChunk* curTC = nextTC; curTC != NULL; | |
132 curTC = TreeChunk::as_TreeChunk(curTC->next())) { | |
133 curTC->set_list(retTL); | |
134 } | |
135 // Fix the parent to point to the new TreeList. | |
136 if (retTL->parent() != NULL) { | |
137 if (this == retTL->parent()->left()) { | |
138 retTL->parent()->setLeft(retTL); | |
139 } else { | |
140 assert(this == retTL->parent()->right(), "Parent is incorrect"); | |
141 retTL->parent()->setRight(retTL); | |
142 } | |
143 } | |
144 // Fix the children's parent pointers to point to the | |
145 // new list. | |
146 assert(right() == retTL->right(), "Should have been copied"); | |
147 if (retTL->right() != NULL) { | |
148 retTL->right()->setParent(retTL); | |
149 } | |
150 assert(left() == retTL->left(), "Should have been copied"); | |
151 if (retTL->left() != NULL) { | |
152 retTL->left()->setParent(retTL); | |
153 } | |
154 retTL->link_head(nextTC); | |
155 assert(nextTC->isFree(), "Should be a free chunk"); | |
156 } | |
157 } else { | |
158 if (nextTC == NULL) { | |
159 // Removing chunk at tail of list | |
160 link_tail(prevFC); | |
161 } | |
162 // Chunk is interior to the list | |
163 prevFC->linkAfter(nextTC); | |
164 } | |
165 | |
166 // Below this point the embeded TreeList being used for the | |
167 // tree node may have changed. Don't use "this" | |
168 // TreeList*. | |
169 // chunk should still be a free chunk (bit set in _prev) | |
170 assert(!retTL->head() || retTL->size() == retTL->head()->size(), | |
171 "Wrong sized chunk in list"); | |
172 debug_only( | |
173 tc->linkPrev(NULL); | |
174 tc->linkNext(NULL); | |
175 tc->set_list(NULL); | |
176 bool prev_found = false; | |
177 bool next_found = false; | |
178 for (FreeChunk* curFC = retTL->head(); | |
179 curFC != NULL; curFC = curFC->next()) { | |
180 assert(curFC != tc, "Chunk is still in list"); | |
181 if (curFC == prevFC) { | |
182 prev_found = true; | |
183 } | |
184 if (curFC == nextTC) { | |
185 next_found = true; | |
186 } | |
187 } | |
188 assert(prevFC == NULL || prev_found, "Chunk was lost from list"); | |
189 assert(nextTC == NULL || next_found, "Chunk was lost from list"); | |
190 assert(retTL->parent() == NULL || | |
191 retTL == retTL->parent()->left() || | |
192 retTL == retTL->parent()->right(), | |
193 "list is inconsistent"); | |
194 ) | |
195 retTL->decrement_count(); | |
196 | |
197 assert(tc->isFree(), "Should still be a free chunk"); | |
198 assert(retTL->head() == NULL || retTL->head()->prev() == NULL, | |
199 "list invariant"); | |
200 assert(retTL->tail() == NULL || retTL->tail()->next() == NULL, | |
201 "list invariant"); | |
202 return retTL; | |
203 } | |
204 void TreeList::returnChunkAtTail(TreeChunk* chunk) { | |
205 assert(chunk != NULL, "returning NULL chunk"); | |
206 assert(chunk->list() == this, "list should be set for chunk"); | |
207 assert(tail() != NULL, "The tree list is embedded in the first chunk"); | |
208 // which means that the list can never be empty. | |
209 assert(!verifyChunkInFreeLists(chunk), "Double entry"); | |
210 assert(head() == NULL || head()->prev() == NULL, "list invariant"); | |
211 assert(tail() == NULL || tail()->next() == NULL, "list invariant"); | |
212 | |
213 FreeChunk* fc = tail(); | |
214 fc->linkAfter(chunk); | |
215 link_tail(chunk); | |
216 | |
217 assert(!tail() || size() == tail()->size(), "Wrong sized chunk in list"); | |
218 increment_count(); | |
219 debug_only(increment_returnedBytes_by(chunk->size()*sizeof(HeapWord));) | |
220 assert(head() == NULL || head()->prev() == NULL, "list invariant"); | |
221 assert(tail() == NULL || tail()->next() == NULL, "list invariant"); | |
222 } | |
223 | |
224 // Add this chunk at the head of the list. "At the head of the list" | |
225 // is defined to be after the chunk pointer to by head(). This is | |
226 // because the TreeList is embedded in the first TreeChunk in the | |
227 // list. See the definition of TreeChunk. | |
228 void TreeList::returnChunkAtHead(TreeChunk* chunk) { | |
229 assert(chunk->list() == this, "list should be set for chunk"); | |
230 assert(head() != NULL, "The tree list is embedded in the first chunk"); | |
231 assert(chunk != NULL, "returning NULL chunk"); | |
232 assert(!verifyChunkInFreeLists(chunk), "Double entry"); | |
233 assert(head() == NULL || head()->prev() == NULL, "list invariant"); | |
234 assert(tail() == NULL || tail()->next() == NULL, "list invariant"); | |
235 | |
236 FreeChunk* fc = head()->next(); | |
237 if (fc != NULL) { | |
238 chunk->linkAfter(fc); | |
239 } else { | |
240 assert(tail() == NULL, "List is inconsistent"); | |
241 link_tail(chunk); | |
242 } | |
243 head()->linkAfter(chunk); | |
244 assert(!head() || size() == head()->size(), "Wrong sized chunk in list"); | |
245 increment_count(); | |
246 debug_only(increment_returnedBytes_by(chunk->size()*sizeof(HeapWord));) | |
247 assert(head() == NULL || head()->prev() == NULL, "list invariant"); | |
248 assert(tail() == NULL || tail()->next() == NULL, "list invariant"); | |
249 } | |
250 | |
251 TreeChunk* TreeList::head_as_TreeChunk() { | |
252 assert(head() == NULL || TreeChunk::as_TreeChunk(head())->list() == this, | |
253 "Wrong type of chunk?"); | |
254 return TreeChunk::as_TreeChunk(head()); | |
255 } | |
256 | |
257 TreeChunk* TreeList::first_available() { | |
258 guarantee(head() != NULL, "The head of the list cannot be NULL"); | |
259 FreeChunk* fc = head()->next(); | |
260 TreeChunk* retTC; | |
261 if (fc == NULL) { | |
262 retTC = head_as_TreeChunk(); | |
263 } else { | |
264 retTC = TreeChunk::as_TreeChunk(fc); | |
265 } | |
266 assert(retTC->list() == this, "Wrong type of chunk."); | |
267 return retTC; | |
268 } | |
269 | |
270 BinaryTreeDictionary::BinaryTreeDictionary(MemRegion mr, bool splay): | |
271 _splay(splay) | |
272 { | |
273 assert(mr.byte_size() > MIN_TREE_CHUNK_SIZE, "minimum chunk size"); | |
274 | |
275 reset(mr); | |
276 assert(root()->left() == NULL, "reset check failed"); | |
277 assert(root()->right() == NULL, "reset check failed"); | |
278 assert(root()->head()->next() == NULL, "reset check failed"); | |
279 assert(root()->head()->prev() == NULL, "reset check failed"); | |
280 assert(totalSize() == root()->size(), "reset check failed"); | |
281 assert(totalFreeBlocks() == 1, "reset check failed"); | |
282 } | |
283 | |
284 void BinaryTreeDictionary::inc_totalSize(size_t inc) { | |
285 _totalSize = _totalSize + inc; | |
286 } | |
287 | |
288 void BinaryTreeDictionary::dec_totalSize(size_t dec) { | |
289 _totalSize = _totalSize - dec; | |
290 } | |
291 | |
292 void BinaryTreeDictionary::reset(MemRegion mr) { | |
293 assert(mr.byte_size() > MIN_TREE_CHUNK_SIZE, "minimum chunk size"); | |
294 set_root(TreeList::as_TreeList(mr.start(), mr.word_size())); | |
295 set_totalSize(mr.word_size()); | |
296 set_totalFreeBlocks(1); | |
297 } | |
298 | |
299 void BinaryTreeDictionary::reset(HeapWord* addr, size_t byte_size) { | |
300 MemRegion mr(addr, heap_word_size(byte_size)); | |
301 reset(mr); | |
302 } | |
303 | |
304 void BinaryTreeDictionary::reset() { | |
305 set_root(NULL); | |
306 set_totalSize(0); | |
307 set_totalFreeBlocks(0); | |
308 } | |
309 | |
310 // Get a free block of size at least size from tree, or NULL. | |
311 // If a splay step is requested, the removal algorithm (only) incorporates | |
312 // a splay step as follows: | |
313 // . the search proceeds down the tree looking for a possible | |
314 // match. At the (closest) matching location, an appropriate splay step is applied | |
315 // (zig, zig-zig or zig-zag). A chunk of the appropriate size is then returned | |
316 // if available, and if it's the last chunk, the node is deleted. A deteleted | |
317 // node is replaced in place by its tree successor. | |
318 TreeChunk* | |
319 BinaryTreeDictionary::getChunkFromTree(size_t size, Dither dither, bool splay) | |
320 { | |
321 TreeList *curTL, *prevTL; | |
322 TreeChunk* retTC = NULL; | |
323 assert(size >= MIN_TREE_CHUNK_SIZE, "minimum chunk size"); | |
324 if (FLSVerifyDictionary) { | |
325 verifyTree(); | |
326 } | |
327 // starting at the root, work downwards trying to find match. | |
328 // Remember the last node of size too great or too small. | |
329 for (prevTL = curTL = root(); curTL != NULL;) { | |
330 if (curTL->size() == size) { // exact match | |
331 break; | |
332 } | |
333 prevTL = curTL; | |
334 if (curTL->size() < size) { // proceed to right sub-tree | |
335 curTL = curTL->right(); | |
336 } else { // proceed to left sub-tree | |
337 assert(curTL->size() > size, "size inconsistency"); | |
338 curTL = curTL->left(); | |
339 } | |
340 } | |
341 if (curTL == NULL) { // couldn't find exact match | |
342 // try and find the next larger size by walking back up the search path | |
343 for (curTL = prevTL; curTL != NULL;) { | |
344 if (curTL->size() >= size) break; | |
345 else curTL = curTL->parent(); | |
346 } | |
347 assert(curTL == NULL || curTL->count() > 0, | |
348 "An empty list should not be in the tree"); | |
349 } | |
350 if (curTL != NULL) { | |
351 assert(curTL->size() >= size, "size inconsistency"); | |
352 if (UseCMSAdaptiveFreeLists) { | |
353 | |
354 // A candidate chunk has been found. If it is already under | |
355 // populated, get a chunk associated with the hint for this | |
356 // chunk. | |
357 if (curTL->surplus() <= 0) { | |
358 /* Use the hint to find a size with a surplus, and reset the hint. */ | |
359 TreeList* hintTL = curTL; | |
360 while (hintTL->hint() != 0) { | |
361 assert(hintTL->hint() == 0 || hintTL->hint() > hintTL->size(), | |
362 "hint points in the wrong direction"); | |
363 hintTL = findList(hintTL->hint()); | |
364 assert(curTL != hintTL, "Infinite loop"); | |
365 if (hintTL == NULL || | |
366 hintTL == curTL /* Should not happen but protect against it */ ) { | |
367 // No useful hint. Set the hint to NULL and go on. | |
368 curTL->set_hint(0); | |
369 break; | |
370 } | |
371 assert(hintTL->size() > size, "hint is inconsistent"); | |
372 if (hintTL->surplus() > 0) { | |
373 // The hint led to a list that has a surplus. Use it. | |
374 // Set the hint for the candidate to an overpopulated | |
375 // size. | |
376 curTL->set_hint(hintTL->size()); | |
377 // Change the candidate. | |
378 curTL = hintTL; | |
379 break; | |
380 } | |
381 // The evm code reset the hint of the candidate as | |
382 // at an interrim point. Why? Seems like this leaves | |
383 // the hint pointing to a list that didn't work. | |
384 // curTL->set_hint(hintTL->size()); | |
385 } | |
386 } | |
387 } | |
388 // don't waste time splaying if chunk's singleton | |
389 if (splay && curTL->head()->next() != NULL) { | |
390 semiSplayStep(curTL); | |
391 } | |
392 retTC = curTL->first_available(); | |
393 assert((retTC != NULL) && (curTL->count() > 0), | |
394 "A list in the binary tree should not be NULL"); | |
395 assert(retTC->size() >= size, | |
396 "A chunk of the wrong size was found"); | |
397 removeChunkFromTree(retTC); | |
398 assert(retTC->isFree(), "Header is not marked correctly"); | |
399 } | |
400 | |
401 if (FLSVerifyDictionary) { | |
402 verify(); | |
403 } | |
404 return retTC; | |
405 } | |
406 | |
407 TreeList* BinaryTreeDictionary::findList(size_t size) const { | |
408 TreeList* curTL; | |
409 for (curTL = root(); curTL != NULL;) { | |
410 if (curTL->size() == size) { // exact match | |
411 break; | |
412 } | |
413 | |
414 if (curTL->size() < size) { // proceed to right sub-tree | |
415 curTL = curTL->right(); | |
416 } else { // proceed to left sub-tree | |
417 assert(curTL->size() > size, "size inconsistency"); | |
418 curTL = curTL->left(); | |
419 } | |
420 } | |
421 return curTL; | |
422 } | |
423 | |
424 | |
425 bool BinaryTreeDictionary::verifyChunkInFreeLists(FreeChunk* tc) const { | |
426 size_t size = tc->size(); | |
427 TreeList* tl = findList(size); | |
428 if (tl == NULL) { | |
429 return false; | |
430 } else { | |
431 return tl->verifyChunkInFreeLists(tc); | |
432 } | |
433 } | |
434 | |
435 FreeChunk* BinaryTreeDictionary::findLargestDict() const { | |
436 TreeList *curTL = root(); | |
437 if (curTL != NULL) { | |
438 while(curTL->right() != NULL) curTL = curTL->right(); | |
439 return curTL->first_available(); | |
440 } else { | |
441 return NULL; | |
442 } | |
443 } | |
444 | |
445 // Remove the current chunk from the tree. If it is not the last | |
446 // chunk in a list on a tree node, just unlink it. | |
447 // If it is the last chunk in the list (the next link is NULL), | |
448 // remove the node and repair the tree. | |
449 TreeChunk* | |
450 BinaryTreeDictionary::removeChunkFromTree(TreeChunk* tc) { | |
451 assert(tc != NULL, "Should not call with a NULL chunk"); | |
452 assert(tc->isFree(), "Header is not marked correctly"); | |
453 | |
454 TreeList *newTL, *parentTL; | |
455 TreeChunk* retTC; | |
456 TreeList* tl = tc->list(); | |
457 debug_only( | |
458 bool removing_only_chunk = false; | |
459 if (tl == _root) { | |
460 if ((_root->left() == NULL) && (_root->right() == NULL)) { | |
461 if (_root->count() == 1) { | |
462 assert(_root->head() == tc, "Should only be this one chunk"); | |
463 removing_only_chunk = true; | |
464 } | |
465 } | |
466 } | |
467 ) | |
468 assert(tl != NULL, "List should be set"); | |
469 assert(tl->parent() == NULL || tl == tl->parent()->left() || | |
470 tl == tl->parent()->right(), "list is inconsistent"); | |
471 | |
472 bool complicatedSplice = false; | |
473 | |
474 retTC = tc; | |
475 // Removing this chunk can have the side effect of changing the node | |
476 // (TreeList*) in the tree. If the node is the root, update it. | |
477 TreeList* replacementTL = tl->removeChunkReplaceIfNeeded(tc); | |
478 assert(tc->isFree(), "Chunk should still be free"); | |
479 assert(replacementTL->parent() == NULL || | |
480 replacementTL == replacementTL->parent()->left() || | |
481 replacementTL == replacementTL->parent()->right(), | |
482 "list is inconsistent"); | |
483 if (tl == root()) { | |
484 assert(replacementTL->parent() == NULL, "Incorrectly replacing root"); | |
485 set_root(replacementTL); | |
486 } | |
487 debug_only( | |
488 if (tl != replacementTL) { | |
489 assert(replacementTL->head() != NULL, | |
490 "If the tree list was replaced, it should not be a NULL list"); | |
491 TreeList* rhl = replacementTL->head_as_TreeChunk()->list(); | |
492 TreeList* rtl = TreeChunk::as_TreeChunk(replacementTL->tail())->list(); | |
493 assert(rhl == replacementTL, "Broken head"); | |
494 assert(rtl == replacementTL, "Broken tail"); | |
495 assert(replacementTL->size() == tc->size(), "Broken size"); | |
496 } | |
497 ) | |
498 | |
499 // Does the tree need to be repaired? | |
500 if (replacementTL->count() == 0) { | |
501 assert(replacementTL->head() == NULL && | |
502 replacementTL->tail() == NULL, "list count is incorrect"); | |
503 // Find the replacement node for the (soon to be empty) node being removed. | |
504 // if we have a single (or no) child, splice child in our stead | |
505 if (replacementTL->left() == NULL) { | |
506 // left is NULL so pick right. right may also be NULL. | |
507 newTL = replacementTL->right(); | |
508 debug_only(replacementTL->clearRight();) | |
509 } else if (replacementTL->right() == NULL) { | |
510 // right is NULL | |
511 newTL = replacementTL->left(); | |
512 debug_only(replacementTL->clearLeft();) | |
513 } else { // we have both children, so, by patriarchal convention, | |
514 // my replacement is least node in right sub-tree | |
515 complicatedSplice = true; | |
516 newTL = removeTreeMinimum(replacementTL->right()); | |
517 assert(newTL != NULL && newTL->left() == NULL && | |
518 newTL->right() == NULL, "sub-tree minimum exists"); | |
519 } | |
520 // newTL is the replacement for the (soon to be empty) node. | |
521 // newTL may be NULL. | |
522 // should verify; we just cleanly excised our replacement | |
523 if (FLSVerifyDictionary) { | |
524 verifyTree(); | |
525 } | |
526 // first make newTL my parent's child | |
527 if ((parentTL = replacementTL->parent()) == NULL) { | |
528 // newTL should be root | |
529 assert(tl == root(), "Incorrectly replacing root"); | |
530 set_root(newTL); | |
531 if (newTL != NULL) { | |
532 newTL->clearParent(); | |
533 } | |
534 } else if (parentTL->right() == replacementTL) { | |
535 // replacementTL is a right child | |
536 parentTL->setRight(newTL); | |
537 } else { // replacementTL is a left child | |
538 assert(parentTL->left() == replacementTL, "should be left child"); | |
539 parentTL->setLeft(newTL); | |
540 } | |
541 debug_only(replacementTL->clearParent();) | |
542 if (complicatedSplice) { // we need newTL to get replacementTL's | |
543 // two children | |
544 assert(newTL != NULL && | |
545 newTL->left() == NULL && newTL->right() == NULL, | |
546 "newTL should not have encumbrances from the past"); | |
547 // we'd like to assert as below: | |
548 // assert(replacementTL->left() != NULL && replacementTL->right() != NULL, | |
549 // "else !complicatedSplice"); | |
550 // ... however, the above assertion is too strong because we aren't | |
551 // guaranteed that replacementTL->right() is still NULL. | |
552 // Recall that we removed | |
553 // the right sub-tree minimum from replacementTL. | |
554 // That may well have been its right | |
555 // child! So we'll just assert half of the above: | |
556 assert(replacementTL->left() != NULL, "else !complicatedSplice"); | |
557 newTL->setLeft(replacementTL->left()); | |
558 newTL->setRight(replacementTL->right()); | |
559 debug_only( | |
560 replacementTL->clearRight(); | |
561 replacementTL->clearLeft(); | |
562 ) | |
563 } | |
564 assert(replacementTL->right() == NULL && | |
565 replacementTL->left() == NULL && | |
566 replacementTL->parent() == NULL, | |
567 "delete without encumbrances"); | |
568 } | |
569 | |
570 assert(totalSize() >= retTC->size(), "Incorrect total size"); | |
571 dec_totalSize(retTC->size()); // size book-keeping | |
572 assert(totalFreeBlocks() > 0, "Incorrect total count"); | |
573 set_totalFreeBlocks(totalFreeBlocks() - 1); | |
574 | |
575 assert(retTC != NULL, "null chunk?"); | |
576 assert(retTC->prev() == NULL && retTC->next() == NULL, | |
577 "should return without encumbrances"); | |
578 if (FLSVerifyDictionary) { | |
579 verifyTree(); | |
580 } | |
581 assert(!removing_only_chunk || _root == NULL, "root should be NULL"); | |
582 return TreeChunk::as_TreeChunk(retTC); | |
583 } | |
584 | |
585 // Remove the leftmost node (lm) in the tree and return it. | |
586 // If lm has a right child, link it to the left node of | |
587 // the parent of lm. | |
588 TreeList* BinaryTreeDictionary::removeTreeMinimum(TreeList* tl) { | |
589 assert(tl != NULL && tl->parent() != NULL, "really need a proper sub-tree"); | |
590 // locate the subtree minimum by walking down left branches | |
591 TreeList* curTL = tl; | |
592 for (; curTL->left() != NULL; curTL = curTL->left()); | |
593 // obviously curTL now has at most one child, a right child | |
594 if (curTL != root()) { // Should this test just be removed? | |
595 TreeList* parentTL = curTL->parent(); | |
596 if (parentTL->left() == curTL) { // curTL is a left child | |
597 parentTL->setLeft(curTL->right()); | |
598 } else { | |
599 // If the list tl has no left child, then curTL may be | |
600 // the right child of parentTL. | |
601 assert(parentTL->right() == curTL, "should be a right child"); | |
602 parentTL->setRight(curTL->right()); | |
603 } | |
604 } else { | |
605 // The only use of this method would not pass the root of the | |
606 // tree (as indicated by the assertion above that the tree list | |
607 // has a parent) but the specification does not explicitly exclude the | |
608 // passing of the root so accomodate it. | |
609 set_root(NULL); | |
610 } | |
611 debug_only( | |
612 curTL->clearParent(); // Test if this needs to be cleared | |
613 curTL->clearRight(); // recall, above, left child is already null | |
614 ) | |
615 // we just excised a (non-root) node, we should still verify all tree invariants | |
616 if (FLSVerifyDictionary) { | |
617 verifyTree(); | |
618 } | |
619 return curTL; | |
620 } | |
621 | |
622 // Based on a simplification of the algorithm by Sleator and Tarjan (JACM 1985). | |
623 // The simplifications are the following: | |
624 // . we splay only when we delete (not when we insert) | |
625 // . we apply a single spay step per deletion/access | |
626 // By doing such partial splaying, we reduce the amount of restructuring, | |
627 // while getting a reasonably efficient search tree (we think). | |
628 // [Measurements will be needed to (in)validate this expectation.] | |
629 | |
630 void BinaryTreeDictionary::semiSplayStep(TreeList* tc) { | |
631 // apply a semi-splay step at the given node: | |
632 // . if root, norting needs to be done | |
633 // . if child of root, splay once | |
634 // . else zig-zig or sig-zag depending on path from grandparent | |
635 if (root() == tc) return; | |
636 warning("*** Splaying not yet implemented; " | |
637 "tree operations may be inefficient ***"); | |
638 } | |
639 | |
640 void BinaryTreeDictionary::insertChunkInTree(FreeChunk* fc) { | |
641 TreeList *curTL, *prevTL; | |
642 size_t size = fc->size(); | |
643 | |
644 assert(size >= MIN_TREE_CHUNK_SIZE, "too small to be a TreeList"); | |
645 if (FLSVerifyDictionary) { | |
646 verifyTree(); | |
647 } | |
648 // XXX: do i need to clear the FreeChunk fields, let me do it just in case | |
649 // Revisit this later | |
650 | |
651 fc->clearNext(); | |
652 fc->linkPrev(NULL); | |
653 | |
654 // work down from the _root, looking for insertion point | |
655 for (prevTL = curTL = root(); curTL != NULL;) { | |
656 if (curTL->size() == size) // exact match | |
657 break; | |
658 prevTL = curTL; | |
659 if (curTL->size() > size) { // follow left branch | |
660 curTL = curTL->left(); | |
661 } else { // follow right branch | |
662 assert(curTL->size() < size, "size inconsistency"); | |
663 curTL = curTL->right(); | |
664 } | |
665 } | |
666 TreeChunk* tc = TreeChunk::as_TreeChunk(fc); | |
667 // This chunk is being returned to the binary try. It's embedded | |
668 // TreeList should be unused at this point. | |
669 tc->initialize(); | |
670 if (curTL != NULL) { // exact match | |
671 tc->set_list(curTL); | |
672 curTL->returnChunkAtTail(tc); | |
673 } else { // need a new node in tree | |
674 tc->clearNext(); | |
675 tc->linkPrev(NULL); | |
676 TreeList* newTL = TreeList::as_TreeList(tc); | |
677 assert(((TreeChunk*)tc)->list() == newTL, | |
678 "List was not initialized correctly"); | |
679 if (prevTL == NULL) { // we are the only tree node | |
680 assert(root() == NULL, "control point invariant"); | |
681 set_root(newTL); | |
682 } else { // insert under prevTL ... | |
683 if (prevTL->size() < size) { // am right child | |
684 assert(prevTL->right() == NULL, "control point invariant"); | |
685 prevTL->setRight(newTL); | |
686 } else { // am left child | |
687 assert(prevTL->size() > size && prevTL->left() == NULL, "cpt pt inv"); | |
688 prevTL->setLeft(newTL); | |
689 } | |
690 } | |
691 } | |
692 assert(tc->list() != NULL, "Tree list should be set"); | |
693 | |
694 inc_totalSize(size); | |
695 // Method 'totalSizeInTree' walks through the every block in the | |
696 // tree, so it can cause significant performance loss if there are | |
697 // many blocks in the tree | |
698 assert(!FLSVerifyDictionary || totalSizeInTree(root()) == totalSize(), "_totalSize inconsistency"); | |
699 set_totalFreeBlocks(totalFreeBlocks() + 1); | |
700 if (FLSVerifyDictionary) { | |
701 verifyTree(); | |
702 } | |
703 } | |
704 | |
705 size_t BinaryTreeDictionary::maxChunkSize() const { | |
706 verify_par_locked(); | |
707 TreeList* tc = root(); | |
708 if (tc == NULL) return 0; | |
709 for (; tc->right() != NULL; tc = tc->right()); | |
710 return tc->size(); | |
711 } | |
712 | |
713 size_t BinaryTreeDictionary::totalListLength(TreeList* tl) const { | |
714 size_t res; | |
715 res = tl->count(); | |
716 #ifdef ASSERT | |
717 size_t cnt; | |
718 FreeChunk* tc = tl->head(); | |
719 for (cnt = 0; tc != NULL; tc = tc->next(), cnt++); | |
720 assert(res == cnt, "The count is not being maintained correctly"); | |
721 #endif | |
722 return res; | |
723 } | |
724 | |
725 size_t BinaryTreeDictionary::totalSizeInTree(TreeList* tl) const { | |
726 if (tl == NULL) | |
727 return 0; | |
728 return (tl->size() * totalListLength(tl)) + | |
729 totalSizeInTree(tl->left()) + | |
730 totalSizeInTree(tl->right()); | |
731 } | |
732 | |
733 double BinaryTreeDictionary::sum_of_squared_block_sizes(TreeList* const tl) const { | |
734 if (tl == NULL) { | |
735 return 0.0; | |
736 } | |
737 double size = (double)(tl->size()); | |
738 double curr = size * size * totalListLength(tl); | |
739 curr += sum_of_squared_block_sizes(tl->left()); | |
740 curr += sum_of_squared_block_sizes(tl->right()); | |
741 return curr; | |
742 } | |
743 | |
744 size_t BinaryTreeDictionary::totalFreeBlocksInTree(TreeList* tl) const { | |
745 if (tl == NULL) | |
746 return 0; | |
747 return totalListLength(tl) + | |
748 totalFreeBlocksInTree(tl->left()) + | |
749 totalFreeBlocksInTree(tl->right()); | |
750 } | |
751 | |
752 size_t BinaryTreeDictionary::numFreeBlocks() const { | |
753 assert(totalFreeBlocksInTree(root()) == totalFreeBlocks(), | |
754 "_totalFreeBlocks inconsistency"); | |
755 return totalFreeBlocks(); | |
756 } | |
757 | |
758 size_t BinaryTreeDictionary::treeHeightHelper(TreeList* tl) const { | |
759 if (tl == NULL) | |
760 return 0; | |
761 return 1 + MAX2(treeHeightHelper(tl->left()), | |
762 treeHeightHelper(tl->right())); | |
763 } | |
764 | |
765 size_t BinaryTreeDictionary::treeHeight() const { | |
766 return treeHeightHelper(root()); | |
767 } | |
768 | |
769 size_t BinaryTreeDictionary::totalNodesHelper(TreeList* tl) const { | |
770 if (tl == NULL) { | |
771 return 0; | |
772 } | |
773 return 1 + totalNodesHelper(tl->left()) + | |
774 totalNodesHelper(tl->right()); | |
775 } | |
776 | |
777 size_t BinaryTreeDictionary::totalNodesInTree(TreeList* tl) const { | |
778 return totalNodesHelper(root()); | |
779 } | |
780 | |
781 void BinaryTreeDictionary::dictCensusUpdate(size_t size, bool split, bool birth){ | |
782 TreeList* nd = findList(size); | |
783 if (nd) { | |
784 if (split) { | |
785 if (birth) { | |
786 nd->increment_splitBirths(); | |
787 nd->increment_surplus(); | |
788 } else { | |
789 nd->increment_splitDeaths(); | |
790 nd->decrement_surplus(); | |
791 } | |
792 } else { | |
793 if (birth) { | |
794 nd->increment_coalBirths(); | |
795 nd->increment_surplus(); | |
796 } else { | |
797 nd->increment_coalDeaths(); | |
798 nd->decrement_surplus(); | |
799 } | |
800 } | |
801 } | |
802 // A list for this size may not be found (nd == 0) if | |
803 // This is a death where the appropriate list is now | |
804 // empty and has been removed from the list. | |
805 // This is a birth associated with a LinAB. The chunk | |
806 // for the LinAB is not in the dictionary. | |
807 } | |
808 | |
809 bool BinaryTreeDictionary::coalDictOverPopulated(size_t size) { | |
810 TreeList* list_of_size = findList(size); | |
811 // None of requested size implies overpopulated. | |
812 return list_of_size == NULL || list_of_size->coalDesired() <= 0 || | |
813 list_of_size->count() > list_of_size->coalDesired(); | |
814 } | |
815 | |
816 // Closures for walking the binary tree. | |
817 // do_list() walks the free list in a node applying the closure | |
818 // to each free chunk in the list | |
819 // do_tree() walks the nodes in the binary tree applying do_list() | |
820 // to each list at each node. | |
821 | |
822 class TreeCensusClosure : public StackObj { | |
823 protected: | |
824 virtual void do_list(FreeList* fl) = 0; | |
825 public: | |
826 virtual void do_tree(TreeList* tl) = 0; | |
827 }; | |
828 | |
829 class AscendTreeCensusClosure : public TreeCensusClosure { | |
830 public: | |
831 void do_tree(TreeList* tl) { | |
832 if (tl != NULL) { | |
833 do_tree(tl->left()); | |
834 do_list(tl); | |
835 do_tree(tl->right()); | |
836 } | |
837 } | |
838 }; | |
839 | |
840 class DescendTreeCensusClosure : public TreeCensusClosure { | |
841 public: | |
842 void do_tree(TreeList* tl) { | |
843 if (tl != NULL) { | |
844 do_tree(tl->right()); | |
845 do_list(tl); | |
846 do_tree(tl->left()); | |
847 } | |
848 } | |
849 }; | |
850 | |
851 // For each list in the tree, calculate the desired, desired | |
852 // coalesce, count before sweep, and surplus before sweep. | |
853 class BeginSweepClosure : public AscendTreeCensusClosure { | |
854 double _percentage; | |
855 float _inter_sweep_current; | |
856 float _inter_sweep_estimate; | |
857 | |
858 public: | |
859 BeginSweepClosure(double p, float inter_sweep_current, | |
860 float inter_sweep_estimate) : | |
861 _percentage(p), | |
862 _inter_sweep_current(inter_sweep_current), | |
863 _inter_sweep_estimate(inter_sweep_estimate) { } | |
864 | |
865 void do_list(FreeList* fl) { | |
866 double coalSurplusPercent = _percentage; | |
867 fl->compute_desired(_inter_sweep_current, _inter_sweep_estimate); | |
868 fl->set_coalDesired((ssize_t)((double)fl->desired() * coalSurplusPercent)); | |
869 fl->set_beforeSweep(fl->count()); | |
870 fl->set_bfrSurp(fl->surplus()); | |
871 } | |
872 }; | |
873 | |
874 // Used to search the tree until a condition is met. | |
875 // Similar to TreeCensusClosure but searches the | |
876 // tree and returns promptly when found. | |
877 | |
878 class TreeSearchClosure : public StackObj { | |
879 protected: | |
880 virtual bool do_list(FreeList* fl) = 0; | |
881 public: | |
882 virtual bool do_tree(TreeList* tl) = 0; | |
883 }; | |
884 | |
885 #if 0 // Don't need this yet but here for symmetry. | |
886 class AscendTreeSearchClosure : public TreeSearchClosure { | |
887 public: | |
888 bool do_tree(TreeList* tl) { | |
889 if (tl != NULL) { | |
890 if (do_tree(tl->left())) return true; | |
891 if (do_list(tl)) return true; | |
892 if (do_tree(tl->right())) return true; | |
893 } | |
894 return false; | |
895 } | |
896 }; | |
897 #endif | |
898 | |
899 class DescendTreeSearchClosure : public TreeSearchClosure { | |
900 public: | |
901 bool do_tree(TreeList* tl) { | |
902 if (tl != NULL) { | |
903 if (do_tree(tl->right())) return true; | |
904 if (do_list(tl)) return true; | |
905 if (do_tree(tl->left())) return true; | |
906 } | |
907 return false; | |
908 } | |
909 }; | |
910 | |
911 // Searches the tree for a chunk that ends at the | |
912 // specified address. | |
913 class EndTreeSearchClosure : public DescendTreeSearchClosure { | |
914 HeapWord* _target; | |
915 FreeChunk* _found; | |
916 | |
917 public: | |
918 EndTreeSearchClosure(HeapWord* target) : _target(target), _found(NULL) {} | |
919 bool do_list(FreeList* fl) { | |
920 FreeChunk* item = fl->head(); | |
921 while (item != NULL) { | |
922 if (item->end() == _target) { | |
923 _found = item; | |
924 return true; | |
925 } | |
926 item = item->next(); | |
927 } | |
928 return false; | |
929 } | |
930 FreeChunk* found() { return _found; } | |
931 }; | |
932 | |
933 FreeChunk* BinaryTreeDictionary::find_chunk_ends_at(HeapWord* target) const { | |
934 EndTreeSearchClosure etsc(target); | |
935 bool found_target = etsc.do_tree(root()); | |
936 assert(found_target || etsc.found() == NULL, "Consistency check"); | |
937 assert(!found_target || etsc.found() != NULL, "Consistency check"); | |
938 return etsc.found(); | |
939 } | |
940 | |
941 void BinaryTreeDictionary::beginSweepDictCensus(double coalSurplusPercent, | |
942 float inter_sweep_current, float inter_sweep_estimate) { | |
943 BeginSweepClosure bsc(coalSurplusPercent, inter_sweep_current, | |
944 inter_sweep_estimate); | |
945 bsc.do_tree(root()); | |
946 } | |
947 | |
948 // Closures and methods for calculating total bytes returned to the | |
949 // free lists in the tree. | |
950 NOT_PRODUCT( | |
951 class InitializeDictReturnedBytesClosure : public AscendTreeCensusClosure { | |
952 public: | |
953 void do_list(FreeList* fl) { | |
954 fl->set_returnedBytes(0); | |
955 } | |
956 }; | |
957 | |
958 void BinaryTreeDictionary::initializeDictReturnedBytes() { | |
959 InitializeDictReturnedBytesClosure idrb; | |
960 idrb.do_tree(root()); | |
961 } | |
962 | |
963 class ReturnedBytesClosure : public AscendTreeCensusClosure { | |
964 size_t _dictReturnedBytes; | |
965 public: | |
966 ReturnedBytesClosure() { _dictReturnedBytes = 0; } | |
967 void do_list(FreeList* fl) { | |
968 _dictReturnedBytes += fl->returnedBytes(); | |
969 } | |
970 size_t dictReturnedBytes() { return _dictReturnedBytes; } | |
971 }; | |
972 | |
973 size_t BinaryTreeDictionary::sumDictReturnedBytes() { | |
974 ReturnedBytesClosure rbc; | |
975 rbc.do_tree(root()); | |
976 | |
977 return rbc.dictReturnedBytes(); | |
978 } | |
979 | |
980 // Count the number of entries in the tree. | |
981 class treeCountClosure : public DescendTreeCensusClosure { | |
982 public: | |
983 uint count; | |
984 treeCountClosure(uint c) { count = c; } | |
985 void do_list(FreeList* fl) { | |
986 count++; | |
987 } | |
988 }; | |
989 | |
990 size_t BinaryTreeDictionary::totalCount() { | |
991 treeCountClosure ctc(0); | |
992 ctc.do_tree(root()); | |
993 return ctc.count; | |
994 } | |
995 ) | |
996 | |
997 // Calculate surpluses for the lists in the tree. | |
998 class setTreeSurplusClosure : public AscendTreeCensusClosure { | |
999 double percentage; | |
1000 public: | |
1001 setTreeSurplusClosure(double v) { percentage = v; } | |
1002 void do_list(FreeList* fl) { | |
1003 double splitSurplusPercent = percentage; | |
1004 fl->set_surplus(fl->count() - | |
1005 (ssize_t)((double)fl->desired() * splitSurplusPercent)); | |
1006 } | |
1007 }; | |
1008 | |
1009 void BinaryTreeDictionary::setTreeSurplus(double splitSurplusPercent) { | |
1010 setTreeSurplusClosure sts(splitSurplusPercent); | |
1011 sts.do_tree(root()); | |
1012 } | |
1013 | |
1014 // Set hints for the lists in the tree. | |
1015 class setTreeHintsClosure : public DescendTreeCensusClosure { | |
1016 size_t hint; | |
1017 public: | |
1018 setTreeHintsClosure(size_t v) { hint = v; } | |
1019 void do_list(FreeList* fl) { | |
1020 fl->set_hint(hint); | |
1021 assert(fl->hint() == 0 || fl->hint() > fl->size(), | |
1022 "Current hint is inconsistent"); | |
1023 if (fl->surplus() > 0) { | |
1024 hint = fl->size(); | |
1025 } | |
1026 } | |
1027 }; | |
1028 | |
1029 void BinaryTreeDictionary::setTreeHints(void) { | |
1030 setTreeHintsClosure sth(0); | |
1031 sth.do_tree(root()); | |
1032 } | |
1033 | |
1034 // Save count before previous sweep and splits and coalesces. | |
1035 class clearTreeCensusClosure : public AscendTreeCensusClosure { | |
1036 void do_list(FreeList* fl) { | |
1037 fl->set_prevSweep(fl->count()); | |
1038 fl->set_coalBirths(0); | |
1039 fl->set_coalDeaths(0); | |
1040 fl->set_splitBirths(0); | |
1041 fl->set_splitDeaths(0); | |
1042 } | |
1043 }; | |
1044 | |
1045 void BinaryTreeDictionary::clearTreeCensus(void) { | |
1046 clearTreeCensusClosure ctc; | |
1047 ctc.do_tree(root()); | |
1048 } | |
1049 | |
1050 // Do reporting and post sweep clean up. | |
1051 void BinaryTreeDictionary::endSweepDictCensus(double splitSurplusPercent) { | |
1052 // Does walking the tree 3 times hurt? | |
1053 setTreeSurplus(splitSurplusPercent); | |
1054 setTreeHints(); | |
1055 if (PrintGC && Verbose) { | |
1056 reportStatistics(); | |
1057 } | |
1058 clearTreeCensus(); | |
1059 } | |
1060 | |
1061 // Print summary statistics | |
1062 void BinaryTreeDictionary::reportStatistics() const { | |
1063 verify_par_locked(); | |
1064 gclog_or_tty->print("Statistics for BinaryTreeDictionary:\n" | |
1065 "------------------------------------\n"); | |
1066 size_t totalSize = totalChunkSize(debug_only(NULL)); | |
1067 size_t freeBlocks = numFreeBlocks(); | |
1068 gclog_or_tty->print("Total Free Space: %d\n", totalSize); | |
1069 gclog_or_tty->print("Max Chunk Size: %d\n", maxChunkSize()); | |
1070 gclog_or_tty->print("Number of Blocks: %d\n", freeBlocks); | |
1071 if (freeBlocks > 0) { | |
1072 gclog_or_tty->print("Av. Block Size: %d\n", totalSize/freeBlocks); | |
1073 } | |
1074 gclog_or_tty->print("Tree Height: %d\n", treeHeight()); | |
1075 } | |
1076 | |
1077 // Print census information - counts, births, deaths, etc. | |
1078 // for each list in the tree. Also print some summary | |
1079 // information. | |
1080 class printTreeCensusClosure : public AscendTreeCensusClosure { | |
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1081 int _print_line; |
0 | 1082 size_t _totalFree; |
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1083 FreeList _total; |
0 | 1084 |
1085 public: | |
1086 printTreeCensusClosure() { | |
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1087 _print_line = 0; |
0 | 1088 _totalFree = 0; |
1089 } | |
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1090 FreeList* total() { return &_total; } |
0 | 1091 size_t totalFree() { return _totalFree; } |
1092 void do_list(FreeList* fl) { | |
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1093 if (++_print_line >= 40) { |
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1094 FreeList::print_labels_on(gclog_or_tty, "size"); |
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1095 _print_line = 0; |
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1096 } |
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1097 fl->print_on(gclog_or_tty); |
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1098 _totalFree += fl->count() * fl->size() ; |
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1099 total()->set_count( total()->count() + fl->count() ); |
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1100 total()->set_bfrSurp( total()->bfrSurp() + fl->bfrSurp() ); |
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1101 total()->set_surplus( total()->splitDeaths() + fl->surplus() ); |
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1102 total()->set_desired( total()->desired() + fl->desired() ); |
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1103 total()->set_prevSweep( total()->prevSweep() + fl->prevSweep() ); |
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1104 total()->set_beforeSweep(total()->beforeSweep() + fl->beforeSweep()); |
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1105 total()->set_coalBirths( total()->coalBirths() + fl->coalBirths() ); |
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1106 total()->set_coalDeaths( total()->coalDeaths() + fl->coalDeaths() ); |
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1107 total()->set_splitBirths(total()->splitBirths() + fl->splitBirths()); |
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1108 total()->set_splitDeaths(total()->splitDeaths() + fl->splitDeaths()); |
0 | 1109 } |
1110 }; | |
1111 | |
1112 void BinaryTreeDictionary::printDictCensus(void) const { | |
1113 | |
1114 gclog_or_tty->print("\nBinaryTree\n"); | |
12
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1115 FreeList::print_labels_on(gclog_or_tty, "size"); |
0 | 1116 printTreeCensusClosure ptc; |
1117 ptc.do_tree(root()); | |
1118 | |
12
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1119 FreeList* total = ptc.total(); |
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1120 FreeList::print_labels_on(gclog_or_tty, " "); |
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1121 total->print_on(gclog_or_tty, "TOTAL\t"); |
0 | 1122 gclog_or_tty->print( |
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1123 "totalFree(words): " SIZE_FORMAT_W(16) |
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1124 " growth: %8.5f deficit: %8.5f\n", |
0 | 1125 ptc.totalFree(), |
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1126 (double)(total->splitBirths() + total->coalBirths() |
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1127 - total->splitDeaths() - total->coalDeaths()) |
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1128 /(total->prevSweep() != 0 ? (double)total->prevSweep() : 1.0), |
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1129 (double)(total->desired() - total->count()) |
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1130 /(total->desired() != 0 ? (double)total->desired() : 1.0)); |
0 | 1131 } |
1132 | |
1133 // Verify the following tree invariants: | |
1134 // . _root has no parent | |
1135 // . parent and child point to each other | |
1136 // . each node's key correctly related to that of its child(ren) | |
1137 void BinaryTreeDictionary::verifyTree() const { | |
1138 guarantee(root() == NULL || totalFreeBlocks() == 0 || | |
1139 totalSize() != 0, "_totalSize should't be 0?"); | |
1140 guarantee(root() == NULL || root()->parent() == NULL, "_root shouldn't have parent"); | |
1141 verifyTreeHelper(root()); | |
1142 } | |
1143 | |
1144 size_t BinaryTreeDictionary::verifyPrevFreePtrs(TreeList* tl) { | |
1145 size_t ct = 0; | |
1146 for (FreeChunk* curFC = tl->head(); curFC != NULL; curFC = curFC->next()) { | |
1147 ct++; | |
1148 assert(curFC->prev() == NULL || curFC->prev()->isFree(), | |
1149 "Chunk should be free"); | |
1150 } | |
1151 return ct; | |
1152 } | |
1153 | |
1154 // Note: this helper is recursive rather than iterative, so use with | |
1155 // caution on very deep trees; and watch out for stack overflow errors; | |
1156 // In general, to be used only for debugging. | |
1157 void BinaryTreeDictionary::verifyTreeHelper(TreeList* tl) const { | |
1158 if (tl == NULL) | |
1159 return; | |
1160 guarantee(tl->size() != 0, "A list must has a size"); | |
1161 guarantee(tl->left() == NULL || tl->left()->parent() == tl, | |
1162 "parent<-/->left"); | |
1163 guarantee(tl->right() == NULL || tl->right()->parent() == tl, | |
1164 "parent<-/->right");; | |
1165 guarantee(tl->left() == NULL || tl->left()->size() < tl->size(), | |
1166 "parent !> left"); | |
1167 guarantee(tl->right() == NULL || tl->right()->size() > tl->size(), | |
1168 "parent !< left"); | |
1169 guarantee(tl->head() == NULL || tl->head()->isFree(), "!Free"); | |
1170 guarantee(tl->head() == NULL || tl->head_as_TreeChunk()->list() == tl, | |
1171 "list inconsistency"); | |
1172 guarantee(tl->count() > 0 || (tl->head() == NULL && tl->tail() == NULL), | |
1173 "list count is inconsistent"); | |
1174 guarantee(tl->count() > 1 || tl->head() == tl->tail(), | |
1175 "list is incorrectly constructed"); | |
1176 size_t count = verifyPrevFreePtrs(tl); | |
1177 guarantee(count == (size_t)tl->count(), "Node count is incorrect"); | |
1178 if (tl->head() != NULL) { | |
1179 tl->head_as_TreeChunk()->verifyTreeChunkList(); | |
1180 } | |
1181 verifyTreeHelper(tl->left()); | |
1182 verifyTreeHelper(tl->right()); | |
1183 } | |
1184 | |
1185 void BinaryTreeDictionary::verify() const { | |
1186 verifyTree(); | |
1187 guarantee(totalSize() == totalSizeInTree(root()), "Total Size inconsistency"); | |
1188 } |