Mercurial > hg > truffle
annotate src/share/vm/adlc/dict2.cpp @ 1293:51db1e4b379d
6932536: JSR 292 modified JDK MethodHandlesTest fails on x86_64
Summary: A modified MethodHandlesTest revealed two bugs on x86_64.
Reviewed-by: never, jrose
author | twisti |
---|---|
date | Mon, 08 Mar 2010 04:46:30 -0800 |
parents | 7bb995fbd3c0 |
children | c18cbe5936b8 |
rev | line source |
---|---|
0 | 1 /* |
579 | 2 * Copyright 1998-2009 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 // Dictionaries - An Abstract Data Type | |
26 | |
27 #include "adlc.hpp" | |
28 | |
29 // #include "dict.hpp" | |
30 | |
31 | |
32 //------------------------------data----------------------------------------- | |
33 // String hash tables | |
34 #define MAXID 20 | |
35 static char initflag = 0; // True after 1st initialization | |
36 static char shft[MAXID] = {1,2,3,4,5,6,7,1,2,3,4,5,6,7,1,2,3,4,5,6}; | |
37 static short xsum[MAXID + 1]; | |
38 | |
39 //------------------------------bucket--------------------------------------- | |
40 class bucket { | |
41 public: | |
42 int _cnt, _max; // Size of bucket | |
43 const void **_keyvals; // Array of keys and values | |
44 }; | |
45 | |
46 //------------------------------Dict----------------------------------------- | |
47 // The dictionary is kept has a hash table. The hash table is a even power | |
48 // of two, for nice modulo operations. Each bucket in the hash table points | |
49 // to a linear list of key-value pairs; each key & value is just a (void *). | |
50 // The list starts with a count. A hash lookup finds the list head, then a | |
51 // simple linear scan finds the key. If the table gets too full, it's | |
52 // doubled in size; the total amount of EXTRA times all hash functions are | |
53 // computed for the doubling is no more than the current size - thus the | |
54 // doubling in size costs no more than a constant factor in speed. | |
55 Dict::Dict(CmpKey initcmp, Hash inithash) : _hash(inithash), _cmp(initcmp), _arena(NULL) { | |
56 init(); | |
57 } | |
58 | |
59 Dict::Dict(CmpKey initcmp, Hash inithash, Arena *arena) : _hash(inithash), _cmp(initcmp), _arena(arena) { | |
60 init(); | |
61 } | |
62 | |
63 void Dict::init() { | |
64 int i; | |
65 | |
66 // Precompute table of null character hashes | |
67 if( !initflag ) { // Not initializated yet? | |
68 xsum[0] = (1<<shft[0])+1; // Initialize | |
69 for( i = 1; i < MAXID + 1; i++) { | |
70 xsum[i] = (1<<shft[i])+1+xsum[i-1]; | |
71 } | |
72 initflag = 1; // Never again | |
73 } | |
74 | |
75 _size = 16; // Size is a power of 2 | |
76 _cnt = 0; // Dictionary is empty | |
77 _bin = (bucket*)_arena->Amalloc_4(sizeof(bucket)*_size); | |
78 memset(_bin,0,sizeof(bucket)*_size); | |
79 } | |
80 | |
81 //------------------------------~Dict------------------------------------------ | |
82 // Delete an existing dictionary. | |
83 Dict::~Dict() { | |
84 } | |
85 | |
86 //------------------------------Clear---------------------------------------- | |
87 // Zap to empty; ready for re-use | |
88 void Dict::Clear() { | |
89 _cnt = 0; // Empty contents | |
90 for( int i=0; i<_size; i++ ) | |
91 _bin[i]._cnt = 0; // Empty buckets, but leave allocated | |
92 // Leave _size & _bin alone, under the assumption that dictionary will | |
93 // grow to this size again. | |
94 } | |
95 | |
96 //------------------------------doubhash--------------------------------------- | |
97 // Double hash table size. If can't do so, just suffer. If can, then run | |
98 // thru old hash table, moving things to new table. Note that since hash | |
99 // table doubled, exactly 1 new bit is exposed in the mask - so everything | |
100 // in the old table ends up on 1 of two lists in the new table; a hi and a | |
101 // lo list depending on the value of the bit. | |
102 void Dict::doubhash(void) { | |
103 int oldsize = _size; | |
104 _size <<= 1; // Double in size | |
105 _bin = (bucket*)_arena->Arealloc( _bin, sizeof(bucket)*oldsize, sizeof(bucket)*_size ); | |
106 memset( &_bin[oldsize], 0, oldsize*sizeof(bucket) ); | |
107 // Rehash things to spread into new table | |
108 for( int i=0; i < oldsize; i++) { // For complete OLD table do | |
109 bucket *b = &_bin[i]; // Handy shortcut for _bin[i] | |
110 if( !b->_keyvals ) continue; // Skip empties fast | |
111 | |
112 bucket *nb = &_bin[i+oldsize]; // New bucket shortcut | |
113 int j = b->_max; // Trim new bucket to nearest power of 2 | |
114 while( j > b->_cnt ) j >>= 1; // above old bucket _cnt | |
115 if( !j ) j = 1; // Handle zero-sized buckets | |
116 nb->_max = j<<1; | |
117 // Allocate worst case space for key-value pairs | |
118 nb->_keyvals = (const void**)_arena->Amalloc_4( sizeof(void *)*nb->_max*2 ); | |
119 int nbcnt = 0; | |
120 | |
121 for( j=0; j<b->_cnt; j++ ) { // Rehash all keys in this bucket | |
122 const void *key = b->_keyvals[j+j]; | |
123 if( (_hash( key ) & (_size-1)) != i ) { // Moving to hi bucket? | |
124 nb->_keyvals[nbcnt+nbcnt] = key; | |
125 nb->_keyvals[nbcnt+nbcnt+1] = b->_keyvals[j+j+1]; | |
126 nb->_cnt = nbcnt = nbcnt+1; | |
127 b->_cnt--; // Remove key/value from lo bucket | |
128 b->_keyvals[j+j ] = b->_keyvals[b->_cnt+b->_cnt ]; | |
129 b->_keyvals[j+j+1] = b->_keyvals[b->_cnt+b->_cnt+1]; | |
130 j--; // Hash compacted element also | |
131 } | |
132 } // End of for all key-value pairs in bucket | |
133 } // End of for all buckets | |
134 | |
135 | |
136 } | |
137 | |
138 //------------------------------Dict----------------------------------------- | |
139 // Deep copy a dictionary. | |
140 Dict::Dict( const Dict &d ) : _size(d._size), _cnt(d._cnt), _hash(d._hash),_cmp(d._cmp), _arena(d._arena) { | |
141 _bin = (bucket*)_arena->Amalloc_4(sizeof(bucket)*_size); | |
142 memcpy( _bin, d._bin, sizeof(bucket)*_size ); | |
143 for( int i=0; i<_size; i++ ) { | |
144 if( !_bin[i]._keyvals ) continue; | |
145 _bin[i]._keyvals=(const void**)_arena->Amalloc_4( sizeof(void *)*_bin[i]._max*2); | |
146 memcpy( _bin[i]._keyvals, d._bin[i]._keyvals,_bin[i]._cnt*2*sizeof(void*)); | |
147 } | |
148 } | |
149 | |
150 //------------------------------Dict----------------------------------------- | |
151 // Deep copy a dictionary. | |
152 Dict &Dict::operator =( const Dict &d ) { | |
153 if( _size < d._size ) { // If must have more buckets | |
154 _arena = d._arena; | |
155 _bin = (bucket*)_arena->Arealloc( _bin, sizeof(bucket)*_size, sizeof(bucket)*d._size ); | |
156 memset( &_bin[_size], 0, (d._size-_size)*sizeof(bucket) ); | |
157 _size = d._size; | |
158 } | |
159 for( int i=0; i<_size; i++ ) // All buckets are empty | |
160 _bin[i]._cnt = 0; // But leave bucket allocations alone | |
161 _cnt = d._cnt; | |
162 *(Hash*)(&_hash) = d._hash; | |
163 *(CmpKey*)(&_cmp) = d._cmp; | |
164 for(int k=0; k<_size; k++ ) { | |
165 bucket *b = &d._bin[k]; // Shortcut to source bucket | |
166 for( int j=0; j<b->_cnt; j++ ) | |
167 Insert( b->_keyvals[j+j], b->_keyvals[j+j+1] ); | |
168 } | |
169 return *this; | |
170 } | |
171 | |
172 //------------------------------Insert--------------------------------------- | |
173 // Insert or replace a key/value pair in the given dictionary. If the | |
174 // dictionary is too full, it's size is doubled. The prior value being | |
175 // replaced is returned (NULL if this is a 1st insertion of that key). If | |
176 // an old value is found, it's swapped with the prior key-value pair on the | |
177 // list. This moves a commonly searched-for value towards the list head. | |
178 const void *Dict::Insert(const void *key, const void *val) { | |
179 int hash = _hash( key ); // Get hash key | |
180 int i = hash & (_size-1); // Get hash key, corrected for size | |
181 bucket *b = &_bin[i]; // Handy shortcut | |
182 for( int j=0; j<b->_cnt; j++ ) | |
183 if( !_cmp(key,b->_keyvals[j+j]) ) { | |
184 const void *prior = b->_keyvals[j+j+1]; | |
185 b->_keyvals[j+j ] = key; // Insert current key-value | |
186 b->_keyvals[j+j+1] = val; | |
187 return prior; // Return prior | |
188 } | |
189 | |
190 if( ++_cnt > _size ) { // Hash table is full | |
191 doubhash(); // Grow whole table if too full | |
192 i = hash & (_size-1); // Rehash | |
193 b = &_bin[i]; // Handy shortcut | |
194 } | |
195 if( b->_cnt == b->_max ) { // Must grow bucket? | |
196 if( !b->_keyvals ) { | |
197 b->_max = 2; // Initial bucket size | |
198 b->_keyvals = (const void**)_arena->Amalloc_4( sizeof(void *)*b->_max*2 ); | |
199 } else { | |
200 b->_keyvals = (const void**)_arena->Arealloc( b->_keyvals, sizeof(void *)*b->_max*2, sizeof(void *)*b->_max*4 ); | |
201 b->_max <<= 1; // Double bucket | |
202 } | |
203 } | |
204 b->_keyvals[b->_cnt+b->_cnt ] = key; | |
205 b->_keyvals[b->_cnt+b->_cnt+1] = val; | |
206 b->_cnt++; | |
207 return NULL; // Nothing found prior | |
208 } | |
209 | |
210 //------------------------------Delete--------------------------------------- | |
211 // Find & remove a value from dictionary. Return old value. | |
212 const void *Dict::Delete(void *key) { | |
213 int i = _hash( key ) & (_size-1); // Get hash key, corrected for size | |
214 bucket *b = &_bin[i]; // Handy shortcut | |
215 for( int j=0; j<b->_cnt; j++ ) | |
216 if( !_cmp(key,b->_keyvals[j+j]) ) { | |
217 const void *prior = b->_keyvals[j+j+1]; | |
218 b->_cnt--; // Remove key/value from lo bucket | |
219 b->_keyvals[j+j ] = b->_keyvals[b->_cnt+b->_cnt ]; | |
220 b->_keyvals[j+j+1] = b->_keyvals[b->_cnt+b->_cnt+1]; | |
221 _cnt--; // One less thing in table | |
222 return prior; | |
223 } | |
224 return NULL; | |
225 } | |
226 | |
227 //------------------------------FindDict------------------------------------- | |
228 // Find a key-value pair in the given dictionary. If not found, return NULL. | |
229 // If found, move key-value pair towards head of list. | |
230 const void *Dict::operator [](const void *key) const { | |
231 int i = _hash( key ) & (_size-1); // Get hash key, corrected for size | |
232 bucket *b = &_bin[i]; // Handy shortcut | |
233 for( int j=0; j<b->_cnt; j++ ) | |
234 if( !_cmp(key,b->_keyvals[j+j]) ) | |
235 return b->_keyvals[j+j+1]; | |
236 return NULL; | |
237 } | |
238 | |
239 //------------------------------CmpDict-------------------------------------- | |
240 // CmpDict compares two dictionaries; they must have the same keys (their | |
241 // keys must match using CmpKey) and they must have the same values (pointer | |
242 // comparison). If so 1 is returned, if not 0 is returned. | |
243 int Dict::operator ==(const Dict &d2) const { | |
244 if( _cnt != d2._cnt ) return 0; | |
245 if( _hash != d2._hash ) return 0; | |
246 if( _cmp != d2._cmp ) return 0; | |
247 for( int i=0; i < _size; i++) { // For complete hash table do | |
248 bucket *b = &_bin[i]; // Handy shortcut | |
249 if( b->_cnt != d2._bin[i]._cnt ) return 0; | |
250 if( memcmp(b->_keyvals, d2._bin[i]._keyvals, b->_cnt*2*sizeof(void*) ) ) | |
251 return 0; // Key-value pairs must match | |
252 } | |
253 return 1; // All match, is OK | |
254 } | |
255 | |
256 | |
257 //------------------------------print---------------------------------------- | |
258 static void printvoid(const void* x) { printf("%p", x); } | |
259 void Dict::print() { | |
260 print(printvoid, printvoid); | |
261 } | |
262 void Dict::print(PrintKeyOrValue print_key, PrintKeyOrValue print_value) { | |
263 for( int i=0; i < _size; i++) { // For complete hash table do | |
264 bucket *b = &_bin[i]; // Handy shortcut | |
265 for( int j=0; j<b->_cnt; j++ ) { | |
266 print_key( b->_keyvals[j+j ]); | |
267 printf(" -> "); | |
268 print_value(b->_keyvals[j+j+1]); | |
269 printf("\n"); | |
270 } | |
271 } | |
272 } | |
273 | |
274 //------------------------------Hashing Functions---------------------------- | |
275 // Convert string to hash key. This algorithm implements a universal hash | |
276 // function with the multipliers frozen (ok, so it's not universal). The | |
277 // multipliers (and allowable characters) are all odd, so the resultant sum | |
605 | 278 // is odd - guaranteed not divisible by any power of two, so the hash tables |
0 | 279 // can be any power of two with good results. Also, I choose multipliers |
280 // that have only 2 bits set (the low is always set to be odd) so | |
281 // multiplication requires only shifts and adds. Characters are required to | |
282 // be in the range 0-127 (I double & add 1 to force oddness). Keys are | |
283 // limited to MAXID characters in length. Experimental evidence on 150K of | |
284 // C text shows excellent spreading of values for any size hash table. | |
285 int hashstr(const void *t) { | |
286 register char c, k = 0; | |
287 register int sum = 0; | |
288 register const char *s = (const char *)t; | |
289 | |
290 while( ((c = s[k]) != '\0') && (k < MAXID-1) ) { // Get characters till nul | |
291 c = (c<<1)+1; // Characters are always odd! | |
292 sum += c + (c<<shft[k++]); // Universal hash function | |
293 } | |
294 assert( k < (MAXID + 1), "Exceeded maximum name length"); | |
295 return (int)((sum+xsum[k]) >> 1); // Hash key, un-modulo'd table size | |
296 } | |
297 | |
298 //------------------------------hashptr-------------------------------------- | |
605 | 299 // Slimey cheap hash function; no guaranteed performance. Better than the |
0 | 300 // default for pointers, especially on MS-DOS machines. |
301 int hashptr(const void *key) { | |
302 #ifdef __TURBOC__ | |
303 return (int)((intptr_t)key >> 16); | |
304 #else // __TURBOC__ | |
305 return (int)((intptr_t)key >> 2); | |
306 #endif | |
307 } | |
308 | |
605 | 309 // Slimey cheap hash function; no guaranteed performance. |
0 | 310 int hashkey(const void *key) { |
311 return (int)((intptr_t)key); | |
312 } | |
313 | |
314 //------------------------------Key Comparator Functions--------------------- | |
315 int cmpstr(const void *k1, const void *k2) { | |
316 return strcmp((const char *)k1,(const char *)k2); | |
317 } | |
318 | |
562
1580954e694c
6798785: Crash in OopFlow::build_oop_map: incorrect comparison of 64bit pointers
never
parents:
0
diff
changeset
|
319 // Cheap key comparator. |
0 | 320 int cmpkey(const void *key1, const void *key2) { |
562
1580954e694c
6798785: Crash in OopFlow::build_oop_map: incorrect comparison of 64bit pointers
never
parents:
0
diff
changeset
|
321 if (key1 == key2) return 0; |
1580954e694c
6798785: Crash in OopFlow::build_oop_map: incorrect comparison of 64bit pointers
never
parents:
0
diff
changeset
|
322 intptr_t delta = (intptr_t)key1 - (intptr_t)key2; |
1580954e694c
6798785: Crash in OopFlow::build_oop_map: incorrect comparison of 64bit pointers
never
parents:
0
diff
changeset
|
323 if (delta > 0) return 1; |
1580954e694c
6798785: Crash in OopFlow::build_oop_map: incorrect comparison of 64bit pointers
never
parents:
0
diff
changeset
|
324 return -1; |
0 | 325 } |
326 | |
327 //============================================================================= | |
328 //------------------------------reset------------------------------------------ | |
329 // Create an iterator and initialize the first variables. | |
330 void DictI::reset( const Dict *dict ) { | |
331 _d = dict; // The dictionary | |
332 _i = (int)-1; // Before the first bin | |
333 _j = 0; // Nothing left in the current bin | |
334 ++(*this); // Step to first real value | |
335 } | |
336 | |
337 //------------------------------next------------------------------------------- | |
338 // Find the next key-value pair in the dictionary, or return a NULL key and | |
339 // value. | |
340 void DictI::operator ++(void) { | |
341 if( _j-- ) { // Still working in current bin? | |
342 _key = _d->_bin[_i]._keyvals[_j+_j]; | |
343 _value = _d->_bin[_i]._keyvals[_j+_j+1]; | |
344 return; | |
345 } | |
346 | |
347 while( ++_i < _d->_size ) { // Else scan for non-zero bucket | |
348 _j = _d->_bin[_i]._cnt; | |
349 if( !_j ) continue; | |
350 _j--; | |
351 _key = _d->_bin[_i]._keyvals[_j+_j]; | |
352 _value = _d->_bin[_i]._keyvals[_j+_j+1]; | |
353 return; | |
354 } | |
355 _key = _value = NULL; | |
356 } |