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1 /*
2 * Copyright (c) 2008 Apple Inc. All rights reserved.
3 *
4 * @APPLE_LICENSE_HEADER_START@
5 *
6 * This file contains Original Code and/or Modifications of Original Code
7 * as defined in and that are subject to the Apple Public Source License
8 * Version 2.0 (the 'License'). You may not use this file except in
9 * compliance with the License. Please obtain a copy of the License at
10 * http://www.opensource.apple.com/apsl/ and read it before using this
11 * file.
12 *
13 * The Original Code and all software distributed under the License are
14 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
15 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
16 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
17 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
18 * Please see the License for the specific language governing rights and
19 * limitations under the License.
20 *
21 * @APPLE_LICENSE_HEADER_END@
22 */
23 /* CFArray.c
24 Copyright 1998-2002, Apple, Inc. All rights reserved.
25 Responsibility: Christopher Kane
26 */
27
28 #include <CoreFoundation/CFArray.h>
29 #include "CFStorage.h"
30 #include "CFPriv.h"
31 #include "CFInternal.h"
32 #include <string.h>
33
34 __private_extern__ void _CFStorageSetWeak(CFStorageRef storage);
35
36 const CFArrayCallBacks kCFTypeArrayCallBacks = {0, __CFTypeCollectionRetain, __CFTypeCollectionRelease, CFCopyDescription, CFEqual};
37 static const CFArrayCallBacks __kCFNullArrayCallBacks = {0, NULL, NULL, NULL, NULL};
38
39 struct __CFArrayBucket {
40 const void *_item;
41 };
42
43 enum {
44 __CF_MAX_BUCKETS_PER_DEQUE = 262140
45 };
46
47 CF_INLINE CFIndex __CFArrayDequeRoundUpCapacity(CFIndex capacity) {
48 if (capacity < 4) return 4;
49 return __CFMin((1 << flsl(capacity)), __CF_MAX_BUCKETS_PER_DEQUE);
50 }
51
52 struct __CFArrayDeque {
53 uint32_t _leftIdx;
54 uint32_t _capacity;
55 int32_t _bias;
56 #if __LP64__
57 uint32_t _pad; // GC: pointers must be 8-byte aligned for the collector to find them.
58 #endif
59 /* struct __CFArrayBucket buckets follow here */
60 };
61
62 struct __CFArray {
63 CFRuntimeBase _base;
64 CFIndex _count; /* number of objects */
65 CFIndex _mutations;
66 void *_store; /* can be NULL when MutableDeque */
67 };
68
69 /* Flag bits */
70 enum { /* Bits 0-1 */
71 __kCFArrayImmutable = 0,
72 __kCFArrayDeque = 2,
73 __kCFArrayStorage = 3
74 };
75
76 enum { /* Bits 2-3 */
77 __kCFArrayHasNullCallBacks = 0,
78 __kCFArrayHasCFTypeCallBacks = 1,
79 __kCFArrayHasCustomCallBacks = 3 /* callbacks are at end of header */
80 };
81
82 /*
83 Bits 4 & 5 are reserved for GC use.
84 Bit 4, if set, indicates that the array is weak.
85 Bit 5 marks whether finalization has occured and, thus, whether to continue to do special retain/release processing of elements.
86 */
87
88 CF_INLINE bool isStrongMemory(CFTypeRef collection) {
89 return __CFBitfieldGetValue(((const CFRuntimeBase *)collection)->_cfinfo[CF_INFO_BITS], 4, 4) == 0;
90 }
91
92 CF_INLINE bool isWeakMemory(CFTypeRef collection) {
93 return __CFBitfieldGetValue(((const CFRuntimeBase *)collection)->_cfinfo[CF_INFO_BITS], 4, 4) != 0;
94 }
95
96 CF_INLINE bool hasBeenFinalized(CFTypeRef collection) {
97 return __CFBitfieldGetValue(((const CFRuntimeBase *)collection)->_cfinfo[CF_INFO_BITS], 5, 5) != 0;
98 }
99
100 CF_INLINE void markFinalized(CFTypeRef collection) {
101 __CFBitfieldSetValue(((CFRuntimeBase *)collection)->_cfinfo[CF_INFO_BITS], 5, 5, 1);
102 }
103
104 CF_INLINE CFIndex __CFArrayGetType(CFArrayRef array) {
105 return __CFBitfieldGetValue(((const CFRuntimeBase *)array)->_cfinfo[CF_INFO_BITS], 1, 0);
106 }
107
108 CF_INLINE CFIndex __CFArrayGetSizeOfType(CFIndex t) {
109 CFIndex size = 0;
110 size += sizeof(struct __CFArray);
111 if (__CFBitfieldGetValue(t, 3, 2) == __kCFArrayHasCustomCallBacks) {
112 size += sizeof(CFArrayCallBacks);
113 }
114 return size;
115 }
116
117 CF_INLINE CFIndex __CFArrayGetCount(CFArrayRef array) {
118 return array->_count;
119 }
120
121 CF_INLINE void __CFArraySetCount(CFArrayRef array, CFIndex v) {
122 ((struct __CFArray *)array)->_count = v;
123 }
124
125 /* Only applies to immutable and mutable-deque-using arrays;
126 * Returns the bucket holding the left-most real value in the latter case. */
127 CF_INLINE struct __CFArrayBucket *__CFArrayGetBucketsPtr(CFArrayRef array) {
128 switch (__CFArrayGetType(array)) {
129 case __kCFArrayImmutable:
130 return (struct __CFArrayBucket *)((uint8_t *)array + __CFArrayGetSizeOfType(((CFRuntimeBase *)array)->_cfinfo[CF_INFO_BITS]));
131 case __kCFArrayDeque: {
132 struct __CFArrayDeque *deque = (struct __CFArrayDeque *)array->_store;
133 return (struct __CFArrayBucket *)((uint8_t *)deque + sizeof(struct __CFArrayDeque) + deque->_leftIdx * sizeof(struct __CFArrayBucket));
134 }
135 }
136 return NULL;
137 }
138
139 /* This shouldn't be called if the array count is 0. */
140 CF_INLINE struct __CFArrayBucket *__CFArrayGetBucketAtIndex(CFArrayRef array, CFIndex idx) {
141 switch (__CFArrayGetType(array)) {
142 case __kCFArrayImmutable:
143 case __kCFArrayDeque:
144 return __CFArrayGetBucketsPtr(array) + idx;
145 case __kCFArrayStorage: {
146 CFStorageRef store = (CFStorageRef)array->_store;
147 return (struct __CFArrayBucket *)CFStorageGetValueAtIndex(store, idx, NULL);
148 }
149 }
150 return NULL;
151 }
152
153 CF_INLINE CFArrayCallBacks *__CFArrayGetCallBacks(CFArrayRef array) {
154 CFArrayCallBacks *result = NULL;
155 switch (__CFBitfieldGetValue(((const CFRuntimeBase *)array)->_cfinfo[CF_INFO_BITS], 3, 2)) {
156 case __kCFArrayHasNullCallBacks:
157 return (CFArrayCallBacks *)&__kCFNullArrayCallBacks;
158 case __kCFArrayHasCFTypeCallBacks:
159 return (CFArrayCallBacks *)&kCFTypeArrayCallBacks;
160 case __kCFArrayHasCustomCallBacks:
161 break;
162 }
163 switch (__CFArrayGetType(array)) {
164 case __kCFArrayImmutable:
165 result = (CFArrayCallBacks *)((uint8_t *)array + sizeof(struct __CFArray));
166 break;
167 case __kCFArrayDeque:
168 case __kCFArrayStorage:
169 result = (CFArrayCallBacks *)((uint8_t *)array + sizeof(struct __CFArray));
170 break;
171 }
172 return result;
173 }
174
175 CF_INLINE bool __CFArrayCallBacksMatchNull(const CFArrayCallBacks *c) {
176 return (NULL == c ||
177 (c->retain == __kCFNullArrayCallBacks.retain &&
178 c->release == __kCFNullArrayCallBacks.release &&
179 c->copyDescription == __kCFNullArrayCallBacks.copyDescription &&
180 c->equal == __kCFNullArrayCallBacks.equal));
181 }
182
183 CF_INLINE bool __CFArrayCallBacksMatchCFType(const CFArrayCallBacks *c) {
184 return (&kCFTypeArrayCallBacks == c ||
185 (c->retain == kCFTypeArrayCallBacks.retain &&
186 c->release == kCFTypeArrayCallBacks.release &&
187 c->copyDescription == kCFTypeArrayCallBacks.copyDescription &&
188 c->equal == kCFTypeArrayCallBacks.equal));
189 }
190
191 struct _releaseContext {
192 void (*release)(CFAllocatorRef, const void *);
193 CFAllocatorRef allocator;
194 };
195
196 static void __CFArrayStorageRelease(const void *itemptr, void *context) {
197 struct _releaseContext *rc = (struct _releaseContext *)context;
198 INVOKE_CALLBACK2(rc->release, rc->allocator, *(const void **)itemptr);
199 *(const void **)itemptr = NULL; // GC: clear item to break strong reference.
200 }
201
202 static void __CFArrayReleaseValues(CFArrayRef array, CFRange range, bool releaseStorageIfPossible) {
203 const CFArrayCallBacks *cb = __CFArrayGetCallBacks(array);
204 CFAllocatorRef allocator;
205 CFIndex idx;
206 switch (__CFArrayGetType(array)) {
207 case __kCFArrayImmutable:
208 if (NULL != cb->release && 0 < range.length && !hasBeenFinalized(array)) {
209 // if we've been finalized then we know that
210 // 1) we're using the standard callback on GC memory
211 // 2) the slots don't' need to be zeroed
212 struct __CFArrayBucket *buckets = __CFArrayGetBucketsPtr(array);
213 allocator = __CFGetAllocator(array);
214 for (idx = 0; idx < range.length; idx++) {
215 INVOKE_CALLBACK2(cb->release, allocator, buckets[idx + range.location]._item);
216 buckets[idx + range.location]._item = NULL; // GC: break strong reference.
217 }
218 }
219 break;
220 case __kCFArrayDeque: {
221 struct __CFArrayDeque *deque = (struct __CFArrayDeque *)array->_store;
222 if (0 < range.length && NULL != deque && !hasBeenFinalized(array)) {
223 struct __CFArrayBucket *buckets = __CFArrayGetBucketsPtr(array);
224 if (NULL != cb->release) {
225 allocator = __CFGetAllocator(array);
226 for (idx = 0; idx < range.length; idx++) {
227 INVOKE_CALLBACK2(cb->release, allocator, buckets[idx + range.location]._item);
228 buckets[idx + range.location]._item = NULL; // GC: break strong reference.
229 }
230 } else {
231 for (idx = 0; idx < range.length; idx++) {
232 buckets[idx + range.location]._item = NULL; // GC: break strong reference.
233 }
234 }
235 }
236 if (releaseStorageIfPossible && 0 == range.location && __CFArrayGetCount(array) == range.length) {
237 allocator = __CFGetAllocator(array);
238 if (NULL != deque) _CFAllocatorDeallocateGC(allocator, deque);
239 __CFArraySetCount(array, 0); // GC: _count == 0 ==> _store == NULL.
240 ((struct __CFArray *)array)->_store = NULL;
241 }
242 break;
243 }
244 case __kCFArrayStorage: {
245 CFStorageRef store = (CFStorageRef)array->_store;
246 if (NULL != cb->release && 0 < range.length && !hasBeenFinalized(array)) {
247 struct _releaseContext context;
248 allocator = __CFGetAllocator(array);
249 context.release = cb->release;
250 context.allocator = allocator;
251 CFStorageApplyFunction(store, range, __CFArrayStorageRelease, &context);
252 }
253 if (releaseStorageIfPossible && 0 == range.location && __CFArrayGetCount(array) == range.length) {
254 _CFReleaseGC(store);
255 __CFArraySetCount(array, 0); // GC: _count == 0 ==> _store == NULL.
256 ((struct __CFArray *)array)->_store = NULL;
257 __CFBitfieldSetValue(((CFRuntimeBase *)array)->_cfinfo[CF_INFO_BITS], 1, 0, __kCFArrayDeque);
258 }
259 break;
260 }
261 }
262 }
263
264 #if defined(DEBUG)
265 CF_INLINE void __CFArrayValidateRange(CFArrayRef array, CFRange range, const char *func) {
266 CFAssert3(0 <= range.location && range.location <= CFArrayGetCount(array), __kCFLogAssertion, "%s(): range.location index (%d) out of bounds (0, %d)", func, range.location, CFArrayGetCount(array));
267 CFAssert2(0 <= range.length, __kCFLogAssertion, "%s(): range.length (%d) cannot be less than zero", func, range.length);
268 CFAssert3(range.location + range.length <= CFArrayGetCount(array), __kCFLogAssertion, "%s(): ending index (%d) out of bounds (0, %d)", func, range.location + range.length, CFArrayGetCount(array));
269 }
270 #else
271 #define __CFArrayValidateRange(a,r,f)
272 #endif
273
274 static Boolean __CFArrayEqual(CFTypeRef cf1, CFTypeRef cf2) {
275 CFArrayRef array1 = (CFArrayRef)cf1;
276 CFArrayRef array2 = (CFArrayRef)cf2;
277 const CFArrayCallBacks *cb1, *cb2;
278 CFIndex idx, cnt;
279 if (array1 == array2) return true;
280 cnt = __CFArrayGetCount(array1);
281 if (cnt != __CFArrayGetCount(array2)) return false;
282 cb1 = __CFArrayGetCallBacks(array1);
283 cb2 = __CFArrayGetCallBacks(array2);
284 if (cb1->equal != cb2->equal) return false;
285 if (0 == cnt) return true; /* after function comparison! */
286 for (idx = 0; idx < cnt; idx++) {
287 const void *val1 = __CFArrayGetBucketAtIndex(array1, idx)->_item;
288 const void *val2 = __CFArrayGetBucketAtIndex(array2, idx)->_item;
289 if (val1 != val2) {
290 if (NULL == cb1->equal) return false;
291 if (!INVOKE_CALLBACK2(cb1->equal, val1, val2)) return false;
292 }
293 }
294 return true;
295 }
296
297 static CFHashCode __CFArrayHash(CFTypeRef cf) {
298 CFArrayRef array = (CFArrayRef)cf;
299 return __CFArrayGetCount(array);
300 }
301
302 static CFStringRef __CFArrayCopyDescription(CFTypeRef cf) {
303 CFArrayRef array = (CFArrayRef)cf;
304 CFMutableStringRef result;
305 const CFArrayCallBacks *cb;
306 CFAllocatorRef allocator;
307 CFIndex idx, cnt;
308 cnt = __CFArrayGetCount(array);
309 allocator = CFGetAllocator(array);
310 result = CFStringCreateMutable(allocator, 0);
311 switch (__CFArrayGetType(array)) {
312 case __kCFArrayImmutable:
313 CFStringAppendFormat(result, NULL, CFSTR("<CFArray %p [%p]>{type = immutable, count = %u, values = (\n"), cf, allocator, cnt);
314 break;
315 case __kCFArrayDeque:
316 CFStringAppendFormat(result, NULL, CFSTR("<CFArray %p [%p]>{type = mutable-small, count = %u, values = (\n"), cf, allocator, cnt);
317 break;
318 case __kCFArrayStorage:
319 CFStringAppendFormat(result, NULL, CFSTR("<CFArray %p [%p]>{type = mutable-large, count = %u, values = (\n"), cf, allocator, cnt);
320 break;
321 }
322 cb = __CFArrayGetCallBacks(array);
323 for (idx = 0; idx < cnt; idx++) {
324 CFStringRef desc = NULL;
325 const void *val = __CFArrayGetBucketAtIndex(array, idx)->_item;
326 if (NULL != cb->copyDescription) {
327 desc = (CFStringRef)INVOKE_CALLBACK1(cb->copyDescription, val);
328 }
329 if (NULL != desc) {
330 CFStringAppendFormat(result, NULL, CFSTR("\t%u : %@\n"), idx, desc);
331 CFRelease(desc);
332 } else {
333 CFStringAppendFormat(result, NULL, CFSTR("\t%u : <%p>\n"), idx, val);
334 }
335 }
336 CFStringAppend(result, CFSTR(")}"));
337 return result;
338 }
339
340
341 static void __CFResourceRelease(CFTypeRef cf, const void *ignored) {
342 kCFTypeArrayCallBacks.release(kCFAllocatorSystemDefault, cf);
343 }
344
345 static void __CFArrayDeallocate(CFTypeRef cf) {
346 CFArrayRef array = (CFArrayRef)cf;
347 // Under GC, keep contents alive when we know we can, either standard callbacks or NULL
348 // if (__CFBitfieldGetValue(cf->info, 5, 4)) return; // bits only ever set under GC
349 CFAllocatorRef allocator = __CFGetAllocator(array);
350 if (CF_IS_COLLECTABLE_ALLOCATOR(allocator)) {
351 // XXX_PCB keep array intact during finalization.
352 const CFArrayCallBacks *cb = __CFArrayGetCallBacks(array);
353 if (cb->retain == NULL && cb->release == NULL)
354 return;
355 if (cb == &kCFTypeArrayCallBacks || cb->release == kCFTypeArrayCallBacks.release) {
356 markFinalized(cf);
357 CFArrayApplyFunction((CFArrayRef)cf, CFRangeMake(0, __CFArrayGetCount(array)), (CFArrayApplierFunction)__CFResourceRelease, 0);
358 return;
359 }
360 }
361 __CFArrayReleaseValues(array, CFRangeMake(0, __CFArrayGetCount(array)), true);
362 }
363
364 static CFTypeID __kCFArrayTypeID = _kCFRuntimeNotATypeID;
365
366 static const CFRuntimeClass __CFArrayClass = {
367 _kCFRuntimeScannedObject,
368 "CFArray",
369 NULL, // init
370 NULL, // copy
371 __CFArrayDeallocate,
372 __CFArrayEqual,
373 __CFArrayHash,
374 NULL, //
375 __CFArrayCopyDescription
376 };
377
378 __private_extern__ void __CFArrayInitialize(void) {
379 __kCFArrayTypeID = _CFRuntimeRegisterClass(&__CFArrayClass);
380 }
381
382 CFTypeID CFArrayGetTypeID(void) {
383 return __kCFArrayTypeID;
384 }
385
386 static CFArrayRef __CFArrayInit(CFAllocatorRef allocator, UInt32 flags, CFIndex capacity, const CFArrayCallBacks *callBacks) {
387 struct __CFArray *memory;
388 UInt32 size;
389 __CFBitfieldSetValue(flags, 31, 2, 0);
390 if (CF_IS_COLLECTABLE_ALLOCATOR(allocator)) {
391 if (!callBacks || (callBacks->retain == NULL && callBacks->release == NULL)) {
392 __CFBitfieldSetValue(flags, 4, 4, 1); // setWeak
393 }
394 }
395 if (__CFArrayCallBacksMatchNull(callBacks)) {
396 __CFBitfieldSetValue(flags, 3, 2, __kCFArrayHasNullCallBacks);
397 } else if (__CFArrayCallBacksMatchCFType(callBacks)) {
398 __CFBitfieldSetValue(flags, 3, 2, __kCFArrayHasCFTypeCallBacks);
399 } else {
400 __CFBitfieldSetValue(flags, 3, 2, __kCFArrayHasCustomCallBacks);
401 }
402 size = __CFArrayGetSizeOfType(flags) - sizeof(CFRuntimeBase);
403 switch (__CFBitfieldGetValue(flags, 1, 0)) {
404 case __kCFArrayImmutable:
405 size += capacity * sizeof(struct __CFArrayBucket);
406 break;
407 case __kCFArrayDeque:
408 case __kCFArrayStorage:
409 break;
410 }
411 memory = (struct __CFArray*)_CFRuntimeCreateInstance(allocator, __kCFArrayTypeID, size, NULL);
412 if (NULL == memory) {
413 return NULL;
414 }
415 __CFBitfieldSetValue(memory->_base._cfinfo[CF_INFO_BITS], 6, 0, flags);
416 __CFArraySetCount((CFArrayRef)memory, 0);
417 switch (__CFBitfieldGetValue(flags, 1, 0)) {
418 case __kCFArrayImmutable:
419 if (isWeakMemory(memory)) { // if weak, don't scan
420 auto_zone_set_layout_type(__CFCollectableZone, memory, AUTO_OBJECT_UNSCANNED);
421 }
422 if (__CFOASafe) __CFSetLastAllocationEventName(memory, "CFArray (immutable)");
423 break;
424 case __kCFArrayDeque:
425 case __kCFArrayStorage:
426 if (__CFOASafe) __CFSetLastAllocationEventName(memory, "CFArray (mutable-variable)");
427 ((struct __CFArray *)memory)->_mutations = 1;
428 ((struct __CFArray*)memory)->_store = NULL;
429 break;
430 }
431 if (__kCFArrayHasCustomCallBacks == __CFBitfieldGetValue(flags, 3, 2)) {
432 CFArrayCallBacks *cb = (CFArrayCallBacks *)__CFArrayGetCallBacks((CFArrayRef)memory);
433 *cb = *callBacks;
434 FAULT_CALLBACK((void **)&(cb->retain));
435 FAULT_CALLBACK((void **)&(cb->release));
436 FAULT_CALLBACK((void **)&(cb->copyDescription));
437 FAULT_CALLBACK((void **)&(cb->equal));
438 }
439 return (CFArrayRef)memory;
440 }
441
442 CFArrayRef CFArrayCreate(CFAllocatorRef allocator, const void **values, CFIndex numValues, const CFArrayCallBacks *callBacks) {
443 CFArrayRef result;
444 const CFArrayCallBacks *cb;
445 struct __CFArrayBucket *buckets;
446 CFAllocatorRef bucketsAllocator;
447 void* bucketsBase;
448 CFIndex idx;
449 CFAssert2(0 <= numValues, __kCFLogAssertion, "%s(): numValues (%d) cannot be less than zero", __PRETTY_FUNCTION__, numValues);
450 result = __CFArrayInit(allocator, __kCFArrayImmutable, numValues, callBacks);
451 cb = __CFArrayGetCallBacks(result);
452 buckets = __CFArrayGetBucketsPtr(result);
453 bucketsAllocator = isStrongMemory(result) ? allocator : kCFAllocatorNull;
454 bucketsBase = CF_IS_COLLECTABLE_ALLOCATOR(bucketsAllocator) ? (void *)auto_zone_base_pointer(__CFCollectableZone, buckets) : NULL;
455 if (NULL != cb->retain) {
456 for (idx = 0; idx < numValues; idx++) {
457 CF_WRITE_BARRIER_BASE_ASSIGN(bucketsAllocator, bucketsBase, buckets->_item, (void *)INVOKE_CALLBACK2(cb->retain, allocator, *values));
458 values++;
459 buckets++;
460 }
461 }
462 else {
463 for (idx = 0; idx < numValues; idx++) {
464 CF_WRITE_BARRIER_BASE_ASSIGN(bucketsAllocator, bucketsBase, buckets->_item, *values);
465 values++;
466 buckets++;
467 }
468 }
469 __CFArraySetCount(result, numValues);
470 return result;
471 }
472
473 CFMutableArrayRef CFArrayCreateMutable(CFAllocatorRef allocator, CFIndex capacity, const CFArrayCallBacks *callBacks) {
474 CFAssert2(0 <= capacity, __kCFLogAssertion, "%s(): capacity (%d) cannot be less than zero", __PRETTY_FUNCTION__, capacity);
475 CFAssert2(capacity <= LONG_MAX / sizeof(void *), __kCFLogAssertion, "%s(): capacity (%d) is too large for this architecture", __PRETTY_FUNCTION__, capacity);
476 return (CFMutableArrayRef)__CFArrayInit(allocator, __kCFArrayDeque, capacity, callBacks);
477 }
478
479 // This creates an array which is for CFTypes or NSObjects, with an ownership transfer --
480 // the array does not take a retain, and the caller does not need to release the inserted objects.
481 // The incoming objects must also be collectable if allocated out of a collectable allocator.
482 CFArrayRef _CFArrayCreate_ex(CFAllocatorRef allocator, Boolean isMutable, const void **values, CFIndex numValues) {
483 CFArrayRef result;
484 result = __CFArrayInit(allocator, isMutable ? __kCFArrayDeque : __kCFArrayImmutable, numValues, &kCFTypeArrayCallBacks);
485 if (!isMutable) {
486 struct __CFArrayBucket *buckets = __CFArrayGetBucketsPtr(result);
487 CF_WRITE_BARRIER_MEMMOVE(buckets, values, numValues * sizeof(struct __CFArrayBucket));
488 } else {
489 if (__CF_MAX_BUCKETS_PER_DEQUE <= numValues) {
490 CFStorageRef store = (CFStorageRef)CFMakeCollectable(CFStorageCreate(allocator, sizeof(const void *)));
491 if (__CFOASafe) __CFSetLastAllocationEventName(store, "CFArray (store-storage)");
492 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, result, result->_store, store);
493 CFStorageInsertValues(store, CFRangeMake(0, numValues));
494 CFStorageReplaceValues(store, CFRangeMake(0, numValues), values);
495 __CFBitfieldSetValue(((CFRuntimeBase *)result)->_cfinfo[CF_INFO_BITS], 1, 0, __kCFArrayStorage);
496 } else if (0 <= numValues) {
497 struct __CFArrayDeque *deque;
498 struct __CFArrayBucket *raw_buckets;
499 CFIndex capacity = __CFArrayDequeRoundUpCapacity(numValues);
500 CFIndex size = sizeof(struct __CFArrayDeque) + capacity * sizeof(struct __CFArrayBucket);
501 deque = (struct __CFArrayDeque *)_CFAllocatorAllocateGC(allocator, size, isStrongMemory(result) ? __kCFAllocatorGCScannedMemory : 0);
502 if (__CFOASafe) __CFSetLastAllocationEventName(deque, "CFArray (store-deque)");
503 deque->_leftIdx = (capacity - numValues) / 2;
504 deque->_capacity = capacity;
505 deque->_bias = 0;
506 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, result, result->_store, deque);
507 raw_buckets = (struct __CFArrayBucket *)((uint8_t *)deque + sizeof(struct __CFArrayDeque));
508 CF_WRITE_BARRIER_MEMMOVE(raw_buckets + deque->_leftIdx + 0, values, numValues * sizeof(struct __CFArrayBucket));
509 __CFBitfieldSetValue(((CFRuntimeBase *)result)->_cfinfo[CF_INFO_BITS], 1, 0, __kCFArrayDeque);
510 }
511 }
512 __CFArraySetCount(result, numValues);
513 return result;
514 }
515
516 CFArrayRef CFArrayCreateCopy(CFAllocatorRef allocator, CFArrayRef array) {
517 CFArrayRef result;
518 const CFArrayCallBacks *cb;
519 struct __CFArrayBucket *buckets;
520 CFAllocatorRef bucketsAllocator;
521 void* bucketsBase;
522 CFIndex numValues = CFArrayGetCount(array);
523 CFIndex idx;
524 if (CF_IS_OBJC(__kCFArrayTypeID, array)) {
525 cb = &kCFTypeArrayCallBacks;
526 } else {
527 cb = __CFArrayGetCallBacks(array);
528 }
529 result = __CFArrayInit(allocator, __kCFArrayImmutable, numValues, cb);
530 cb = __CFArrayGetCallBacks(result); // GC: use the new array's callbacks so we don't leak.
531 buckets = __CFArrayGetBucketsPtr(result);
532 bucketsAllocator = isStrongMemory(result) ? allocator : kCFAllocatorNull;
533 bucketsBase = CF_IS_COLLECTABLE_ALLOCATOR(bucketsAllocator) ? (void *)auto_zone_base_pointer(__CFCollectableZone, buckets) : NULL;
534 for (idx = 0; idx < numValues; idx++) {
535 const void *value = CFArrayGetValueAtIndex(array, idx);
536 if (NULL != cb->retain) {
537 value = (void *)INVOKE_CALLBACK2(cb->retain, allocator, value);
538 }
539 CF_WRITE_BARRIER_BASE_ASSIGN(bucketsAllocator, bucketsBase, buckets->_item, value);
540 buckets++;
541 }
542 __CFArraySetCount(result, numValues);
543 return result;
544 }
545
546 CFMutableArrayRef CFArrayCreateMutableCopy(CFAllocatorRef allocator, CFIndex capacity, CFArrayRef array) {
547 CFMutableArrayRef result;
548 const CFArrayCallBacks *cb;
549 CFIndex idx, numValues = CFArrayGetCount(array);
550 UInt32 flags;
551 if (CF_IS_OBJC(__kCFArrayTypeID, array)) {
552 cb = &kCFTypeArrayCallBacks;
553 }
554 else {
555 cb = __CFArrayGetCallBacks(array);
556 }
557 flags = __kCFArrayDeque;
558 result = (CFMutableArrayRef)__CFArrayInit(allocator, flags, capacity, cb);
559 if (0 == capacity) _CFArraySetCapacity(result, numValues);
560 for (idx = 0; idx < numValues; idx++) {
561 const void *value = CFArrayGetValueAtIndex(array, idx);
562 CFArrayAppendValue(result, value);
563 }
564 return result;
565 }
566
567 CFIndex CFArrayGetCount(CFArrayRef array) {
568 CF_OBJC_FUNCDISPATCH0(__kCFArrayTypeID, CFIndex, array, "count");
569 __CFGenericValidateType(array, __kCFArrayTypeID);
570 return __CFArrayGetCount(array);
571 }
572
573
574 CFIndex CFArrayGetCountOfValue(CFArrayRef array, CFRange range, const void *value) {
575 const CFArrayCallBacks *cb;
576 CFIndex idx, count = 0;
577 // CF: this ignores range
578 CF_OBJC_FUNCDISPATCH1(__kCFArrayTypeID, CFIndex, array, "countOccurrences:", value);
579 __CFGenericValidateType(array, __kCFArrayTypeID);
580 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
581 cb = __CFArrayGetCallBacks(array);
582 for (idx = 0; idx < range.length; idx++) {
583 const void *item = __CFArrayGetBucketAtIndex(array, range.location + idx)->_item;
584 if (value == item || (cb->equal && INVOKE_CALLBACK2(cb->equal, value, item))) {
585 count++;
586 }
587 }
588 return count;
589 }
590
591 Boolean CFArrayContainsValue(CFArrayRef array, CFRange range, const void *value) {
592 CFIndex idx;
593 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, char, array, "containsObject:inRange:", value, range);
594 __CFGenericValidateType(array, __kCFArrayTypeID);
595 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
596 for (idx = 0; idx < range.length; idx++) {
597 const void *item = __CFArrayGetBucketAtIndex(array, range.location + idx)->_item;
598 if (value == item) {
599 return true;
600 }
601 }
602 const CFArrayCallBacks *cb = __CFArrayGetCallBacks(array);
603 if (cb->equal) {
604 for (idx = 0; idx < range.length; idx++) {
605 const void *item = __CFArrayGetBucketAtIndex(array, range.location + idx)->_item;
606 if (INVOKE_CALLBACK2(cb->equal, value, item)) {
607 return true;
608 }
609 }
610 }
611 return false;
612 }
613
614 const void *CFArrayGetValueAtIndex(CFArrayRef array, CFIndex idx) {
615 CF_OBJC_FUNCDISPATCH1(__kCFArrayTypeID, void *, array, "objectAtIndex:", idx);
616 __CFGenericValidateType(array, __kCFArrayTypeID);
617 CFAssert2(0 <= idx && idx < __CFArrayGetCount(array), __kCFLogAssertion, "%s(): index (%d) out of bounds", __PRETTY_FUNCTION__, idx);
618 return __CFArrayGetBucketAtIndex(array, idx)->_item;
619 }
620
621 // This is for use by NSCFArray; it avoids ObjC dispatch, and checks for out of bounds
622 const void *_CFArrayCheckAndGetValueAtIndex(CFArrayRef array, CFIndex idx) {
623 if (0 <= idx && idx < __CFArrayGetCount(array)) return __CFArrayGetBucketAtIndex(array, idx)->_item;
624 return (void *)(-1);
625 }
626
627
628 void CFArrayGetValues(CFArrayRef array, CFRange range, const void **values) {
629 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, void, array, "getObjects:range:", values, range);
630 __CFGenericValidateType(array, __kCFArrayTypeID);
631 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
632 CFAssert1(NULL != values, __kCFLogAssertion, "%s(): pointer to values may not be NULL", __PRETTY_FUNCTION__);
633 if (0 < range.length) {
634 switch (__CFArrayGetType(array)) {
635 case __kCFArrayImmutable:
636 case __kCFArrayDeque:
637 CF_WRITE_BARRIER_MEMMOVE(values, __CFArrayGetBucketsPtr(array) + range.location, range.length * sizeof(struct __CFArrayBucket));
638 break;
639 case __kCFArrayStorage: {
640 CFStorageRef store = (CFStorageRef)array->_store;
641 CFStorageGetValues(store, range, values);
642 break;
643 }
644 }
645 }
646 }
647
648
649 unsigned long _CFArrayFastEnumeration(CFArrayRef array, struct __objcFastEnumerationStateEquivalent *state, void *stackbuffer, unsigned long count) {
650 if (array->_count == 0) return 0;
651 enum { ATSTART = 0, ATEND = 1 };
652 switch (__CFArrayGetType(array)) {
653 case __kCFArrayImmutable:
654 if (state->state == ATSTART) { /* first time */
655 static const unsigned long const_mu = 1;
656 state->state = ATEND;
657 state->mutationsPtr = (unsigned long *)&const_mu;
658 state->itemsPtr = (unsigned long *)__CFArrayGetBucketsPtr(array);
659 return array->_count;
660 }
661 return 0;
662 case __kCFArrayDeque:
663 if (state->state == ATSTART) { /* first time */
664 state->state = ATEND;
665 state->mutationsPtr = (unsigned long *)&array->_mutations;
666 state->itemsPtr = (unsigned long *)__CFArrayGetBucketsPtr(array);
667 return array->_count;
668 }
669 return 0;
670 case __kCFArrayStorage:
671 state->mutationsPtr = (unsigned long *)&array->_mutations;
672 return _CFStorageFastEnumeration((CFStorageRef)array->_store, state, stackbuffer, count);
673 }
674 return 0;
675 }
676
677
678 void CFArrayApplyFunction(CFArrayRef array, CFRange range, CFArrayApplierFunction applier, void *context) {
679 CFIndex idx;
680 FAULT_CALLBACK((void **)&(applier));
681 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, void, array, "apply:context:", applier, context);
682 __CFGenericValidateType(array, __kCFArrayTypeID);
683 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
684 CFAssert1(NULL != applier, __kCFLogAssertion, "%s(): pointer to applier function may not be NULL", __PRETTY_FUNCTION__);
685 for (idx = 0; idx < range.length; idx++) {
686 const void *item = __CFArrayGetBucketAtIndex(array, range.location + idx)->_item;
687 INVOKE_CALLBACK2(applier, item, context);
688 }
689 }
690
691 CFIndex CFArrayGetFirstIndexOfValue(CFArrayRef array, CFRange range, const void *value) {
692 const CFArrayCallBacks *cb;
693 CFIndex idx;
694 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, CFIndex, array, "_cfindexOfObject:inRange:", value, range);
695 __CFGenericValidateType(array, __kCFArrayTypeID);
696 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
697 cb = __CFArrayGetCallBacks(array);
698 for (idx = 0; idx < range.length; idx++) {
699 const void *item = __CFArrayGetBucketAtIndex(array, range.location + idx)->_item;
700 if (value == item || (cb->equal && INVOKE_CALLBACK2(cb->equal, value, item)))
701 return idx + range.location;
702 }
703 return kCFNotFound;
704 }
705
706 CFIndex CFArrayGetLastIndexOfValue(CFArrayRef array, CFRange range, const void *value) {
707 const CFArrayCallBacks *cb;
708 CFIndex idx;
709 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, CFIndex, array, "_cflastIndexOfObject:inRange:", value, range);
710 __CFGenericValidateType(array, __kCFArrayTypeID);
711 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
712 cb = __CFArrayGetCallBacks(array);
713 for (idx = range.length; idx--;) {
714 const void *item = __CFArrayGetBucketAtIndex(array, range.location + idx)->_item;
715 if (value == item || (cb->equal && INVOKE_CALLBACK2(cb->equal, value, item)))
716 return idx + range.location;
717 }
718 return kCFNotFound;
719 }
720
721 void CFArrayAppendValue(CFMutableArrayRef array, const void *value) {
722 CF_OBJC_FUNCDISPATCH1(__kCFArrayTypeID, void, array, "addObject:", value);
723 __CFGenericValidateType(array, __kCFArrayTypeID);
724 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
725 _CFArrayReplaceValues(array, CFRangeMake(__CFArrayGetCount(array), 0), &value, 1);
726 }
727
728 void CFArraySetValueAtIndex(CFMutableArrayRef array, CFIndex idx, const void *value) {
729 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, void, array, "setObject:atIndex:", value, idx);
730 __CFGenericValidateType(array, __kCFArrayTypeID);
731 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
732 CFAssert2(0 <= idx && idx <= __CFArrayGetCount(array), __kCFLogAssertion, "%s(): index (%d) out of bounds", __PRETTY_FUNCTION__, idx);
733 if (idx == __CFArrayGetCount(array)) {
734 _CFArrayReplaceValues(array, CFRangeMake(idx, 0), &value, 1);
735 } else {
736 const void *old_value;
737 const CFArrayCallBacks *cb = __CFArrayGetCallBacks(array);
738 CFAllocatorRef allocator = __CFGetAllocator(array);
739 CFAllocatorRef bucketsAllocator = isStrongMemory(array) ? allocator : kCFAllocatorNull;
740 struct __CFArrayBucket *bucket = __CFArrayGetBucketAtIndex(array, idx);
741 if (NULL != cb->retain && !hasBeenFinalized(array)) {
742 value = (void *)INVOKE_CALLBACK2(cb->retain, allocator, value);
743 }
744 old_value = bucket->_item;
745 CF_WRITE_BARRIER_ASSIGN(bucketsAllocator, bucket->_item, value); // GC: handles deque/CFStorage cases.
746 if (NULL != cb->release && !hasBeenFinalized(array)) {
747 INVOKE_CALLBACK2(cb->release, allocator, old_value);
748 }
749 array->_mutations++;
750 }
751 }
752
753 void CFArrayInsertValueAtIndex(CFMutableArrayRef array, CFIndex idx, const void *value) {
754 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, void, array, "insertObject:atIndex:", value, idx);
755 __CFGenericValidateType(array, __kCFArrayTypeID);
756 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
757 CFAssert2(0 <= idx && idx <= __CFArrayGetCount(array), __kCFLogAssertion, "%s(): index (%d) out of bounds", __PRETTY_FUNCTION__, idx);
758 _CFArrayReplaceValues(array, CFRangeMake(idx, 0), &value, 1);
759 }
760
761 void CFArrayExchangeValuesAtIndices(CFMutableArrayRef array, CFIndex idx1, CFIndex idx2) {
762 const void *tmp;
763 struct __CFArrayBucket *bucket1, *bucket2;
764 CFAllocatorRef bucketsAllocator;
765 CF_OBJC_FUNCDISPATCH2(__kCFArrayTypeID, void, array, "exchange::", idx1, idx2);
766 __CFGenericValidateType(array, __kCFArrayTypeID);
767 CFAssert2(0 <= idx1 && idx1 < __CFArrayGetCount(array), __kCFLogAssertion, "%s(): index #1 (%d) out of bounds", __PRETTY_FUNCTION__, idx1);
768 CFAssert2(0 <= idx2 && idx2 < __CFArrayGetCount(array), __kCFLogAssertion, "%s(): index #2 (%d) out of bounds", __PRETTY_FUNCTION__, idx2);
769 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
770 bucket1 = __CFArrayGetBucketAtIndex(array, idx1);
771 bucket2 = __CFArrayGetBucketAtIndex(array, idx2);
772 tmp = bucket1->_item;
773 bucketsAllocator = isStrongMemory(array) ? __CFGetAllocator(array) : kCFAllocatorNull;
774 // XXX these aren't needed.
775 CF_WRITE_BARRIER_ASSIGN(bucketsAllocator, bucket1->_item, bucket2->_item);
776 CF_WRITE_BARRIER_ASSIGN(bucketsAllocator, bucket2->_item, tmp);
777 array->_mutations++;
778
779 }
780
781 void CFArrayRemoveValueAtIndex(CFMutableArrayRef array, CFIndex idx) {
782 CF_OBJC_FUNCDISPATCH1(__kCFArrayTypeID, void, array, "removeObjectAtIndex:", idx);
783 __CFGenericValidateType(array, __kCFArrayTypeID);
784 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
785 CFAssert2(0 <= idx && idx < __CFArrayGetCount(array), __kCFLogAssertion, "%s(): index (%d) out of bounds", __PRETTY_FUNCTION__, idx);
786 _CFArrayReplaceValues(array, CFRangeMake(idx, 1), NULL, 0);
787 }
788
789 void CFArrayRemoveAllValues(CFMutableArrayRef array) {
790 CF_OBJC_FUNCDISPATCH0(__kCFArrayTypeID, void, array, "removeAllObjects");
791 __CFGenericValidateType(array, __kCFArrayTypeID);
792 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
793 __CFArrayReleaseValues(array, CFRangeMake(0, __CFArrayGetCount(array)), true);
794 __CFArraySetCount(array, 0);
795 array->_mutations++;
796 }
797
798 static void __CFArrayConvertDequeToStore(CFMutableArrayRef array) {
799 struct __CFArrayDeque *deque = (struct __CFArrayDeque *)array->_store;
800 struct __CFArrayBucket *raw_buckets = (struct __CFArrayBucket *)((uint8_t *)deque + sizeof(struct __CFArrayDeque));
801 CFStorageRef store;
802 CFIndex count = CFArrayGetCount(array);
803 CFAllocatorRef allocator = __CFGetAllocator(array);
804 store = (CFStorageRef)CFMakeCollectable(CFStorageCreate(allocator, sizeof(const void *)));
805 if (__CFOASafe) __CFSetLastAllocationEventName(store, "CFArray (store-storage)");
806 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, array, array->_store, store);
807 CFStorageInsertValues(store, CFRangeMake(0, count));
808 CFStorageReplaceValues(store, CFRangeMake(0, count), raw_buckets + deque->_leftIdx);
809 _CFAllocatorDeallocateGC(__CFGetAllocator(array), deque);
810 __CFBitfieldSetValue(((CFRuntimeBase *)array)->_cfinfo[CF_INFO_BITS], 1, 0, __kCFArrayStorage);
811 }
812
813 static void __CFArrayConvertStoreToDeque(CFMutableArrayRef array) {
814 CFStorageRef store = (CFStorageRef)array->_store;
815 struct __CFArrayDeque *deque;
816 struct __CFArrayBucket *raw_buckets;
817 CFIndex count = CFStorageGetCount(store);// storage, not array, has correct count at this point
818 // do not resize down to a completely tight deque
819 CFIndex capacity = __CFArrayDequeRoundUpCapacity(count + 6);
820 CFIndex size = sizeof(struct __CFArrayDeque) + capacity * sizeof(struct __CFArrayBucket);
821 CFAllocatorRef allocator = __CFGetAllocator(array);
822 deque = (struct __CFArrayDeque *)_CFAllocatorAllocateGC(allocator, size, isStrongMemory(array) ? __kCFAllocatorGCScannedMemory : 0);
823 if (__CFOASafe) __CFSetLastAllocationEventName(deque, "CFArray (store-deque)");
824 deque->_leftIdx = (capacity - count) / 2;
825 deque->_capacity = capacity;
826 deque->_bias = 0;
827 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, array, array->_store, deque);
828 raw_buckets = (struct __CFArrayBucket *)((uint8_t *)deque + sizeof(struct __CFArrayDeque));
829 CFStorageGetValues(store, CFRangeMake(0, count), raw_buckets + deque->_leftIdx);
830 _CFReleaseGC(store); // GC: balances CFMakeCollectable() above.
831 __CFBitfieldSetValue(((CFRuntimeBase *)array)->_cfinfo[CF_INFO_BITS], 1, 0, __kCFArrayDeque);
832 }
833
834 // may move deque storage, as it may need to grow deque
835 static void __CFArrayRepositionDequeRegions(CFMutableArrayRef array, CFRange range, CFIndex newCount) {
836 // newCount elements are going to replace the range, and the result will fit in the deque
837 struct __CFArrayDeque *deque = (struct __CFArrayDeque *)array->_store;
838 struct __CFArrayBucket *buckets;
839 CFIndex cnt, futureCnt, numNewElems;
840 CFIndex L, A, B, C, R;
841
842 buckets = (struct __CFArrayBucket *)((uint8_t *)deque + sizeof(struct __CFArrayDeque));
843 cnt = __CFArrayGetCount(array);
844 futureCnt = cnt - range.length + newCount;
845
846 L = deque->_leftIdx; // length of region to left of deque
847 A = range.location; // length of region in deque to left of replaced range
848 B = range.length; // length of replaced range
849 C = cnt - B - A; // length of region in deque to right of replaced range
850 R = deque->_capacity - cnt - L; // length of region to right of deque
851 numNewElems = newCount - B;
852
853 CFIndex wiggle = deque->_capacity >> 17;
854 if (wiggle < 4) wiggle = 4;
855 if (deque->_capacity < (uint32_t)futureCnt || (cnt < futureCnt && L + R < wiggle)) {
856 // must be inserting or space is tight, reallocate and re-center everything
857 CFIndex capacity = __CFArrayDequeRoundUpCapacity(futureCnt + wiggle);
858 CFIndex size = sizeof(struct __CFArrayDeque) + capacity * sizeof(struct __CFArrayBucket);
859 CFAllocatorRef allocator = __CFGetAllocator(array);
860 struct __CFArrayDeque *newDeque = (struct __CFArrayDeque *)_CFAllocatorAllocateGC(allocator, size, isStrongMemory(array) ? __kCFAllocatorGCScannedMemory : 0);
861 if (__CFOASafe) __CFSetLastAllocationEventName(newDeque, "CFArray (store-deque)");
862 struct __CFArrayBucket *newBuckets = (struct __CFArrayBucket *)((uint8_t *)newDeque + sizeof(struct __CFArrayDeque));
863 CFIndex oldL = L;
864 CFIndex newL = (capacity - futureCnt) / 2;
865 CFIndex oldC0 = oldL + A + B;
866 CFIndex newC0 = newL + A + newCount;
867 newDeque->_leftIdx = newL;
868 newDeque->_capacity = capacity;
869 newDeque->_bias = 0;
870 if (0 < A) CF_WRITE_BARRIER_MEMMOVE(newBuckets + newL, buckets + oldL, A * sizeof(struct __CFArrayBucket));
871 if (0 < C) CF_WRITE_BARRIER_MEMMOVE(newBuckets + newC0, buckets + oldC0, C * sizeof(struct __CFArrayBucket));
872 if (deque) _CFAllocatorDeallocateGC(allocator, deque);
873 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, array, array->_store, newDeque);
874 return;
875 }
876
877 if ((numNewElems < 0 && C < A) || (numNewElems <= R && C < A)) { // move C
878 // deleting: C is smaller
879 // inserting: C is smaller and R has room
880 CFIndex oldC0 = L + A + B;
881 CFIndex newC0 = L + A + newCount;
882 if (0 < C) CF_WRITE_BARRIER_MEMMOVE(buckets + newC0, buckets + oldC0, C * sizeof(struct __CFArrayBucket));
883 // GrP GC: zero-out newly exposed space on the right, if any
884 if (oldC0 > newC0) bzero(buckets + newC0 + C, (oldC0 - newC0) * sizeof(struct __CFArrayBucket));
885 } else if ((numNewElems < 0) || (numNewElems <= L && A <= C)) { // move A
886 // deleting: A is smaller or equal (covers remaining delete cases)
887 // inserting: A is smaller and L has room
888 CFIndex oldL = L;
889 CFIndex newL = L - numNewElems;
890 deque->_leftIdx = newL;
891 if (0 < A) CF_WRITE_BARRIER_MEMMOVE(buckets + newL, buckets + oldL, A * sizeof(struct __CFArrayBucket));
892 // GrP GC: zero-out newly exposed space on the left, if any
893 if (newL > oldL) bzero(buckets + oldL, (newL - oldL) * sizeof(struct __CFArrayBucket));
894 } else {
895 // now, must be inserting, and either:
896 // A<=C, but L doesn't have room (R might have, but don't care)
897 // C<A, but R doesn't have room (L might have, but don't care)
898 // re-center everything
899 CFIndex oldL = L;
900 CFIndex newL = (L + R - numNewElems) / 2;
901 CFIndex oldBias = deque->_bias;
902 deque->_bias = (newL < oldL) ? -1 : 1;
903 if (oldBias < 0) {
904 newL = newL - newL / 2;
905 } else if (0 < oldBias) {
906 newL = newL + newL / 2;
907 }
908 CFIndex oldC0 = oldL + A + B;
909 CFIndex newC0 = newL + A + newCount;
910 deque->_leftIdx = newL;
911 if (newL < oldL) {
912 if (0 < A) CF_WRITE_BARRIER_MEMMOVE(buckets + newL, buckets + oldL, A * sizeof(struct __CFArrayBucket));
913 if (0 < C) CF_WRITE_BARRIER_MEMMOVE(buckets + newC0, buckets + oldC0, C * sizeof(struct __CFArrayBucket));
914 // GrP GC: zero-out newly exposed space on the right, if any
915 if (oldC0 > newC0) bzero(buckets + newC0 + C, (oldC0 - newC0) * sizeof(struct __CFArrayBucket));
916 } else {
917 if (0 < C) CF_WRITE_BARRIER_MEMMOVE(buckets + newC0, buckets + oldC0, C * sizeof(struct __CFArrayBucket));
918 if (0 < A) CF_WRITE_BARRIER_MEMMOVE(buckets + newL, buckets + oldL, A * sizeof(struct __CFArrayBucket));
919 // GrP GC: zero-out newly exposed space on the left, if any
920 if (newL > oldL) bzero(buckets + oldL, (newL - oldL) * sizeof(struct __CFArrayBucket));
921 }
922 }
923 }
924
925 static void __CFArrayHandleOutOfMemory(CFTypeRef obj, CFIndex numBytes) {
926 CFStringRef msg = CFStringCreateWithFormat(kCFAllocatorSystemDefault, NULL, CFSTR("Attempt to allocate %ld bytes for CFArray failed"), numBytes);
927 CFBadErrorCallBack cb = _CFGetOutOfMemoryErrorCallBack();
928 if (NULL == cb || !cb(obj, CFSTR("NS/CFArray"), msg)) {
929 CFLog(kCFLogLevelCritical, CFSTR("%@"), msg);
930 HALT;
931 }
932 CFRelease(msg);
933 }
934
935 // This function is for Foundation's benefit; no one else should use it.
936 void _CFArraySetCapacity(CFMutableArrayRef array, CFIndex cap) {
937 if (CF_IS_OBJC(__kCFArrayTypeID, array)) return;
938 __CFGenericValidateType(array, __kCFArrayTypeID);
939 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
940 CFAssert3(__CFArrayGetCount(array) <= cap, __kCFLogAssertion, "%s(): desired capacity (%d) is less than count (%d)", __PRETTY_FUNCTION__, cap, __CFArrayGetCount(array));
941 // Currently, attempting to set the capacity of an array which is the CFStorage
942 // variant, or set the capacity larger than __CF_MAX_BUCKETS_PER_DEQUE, has no
943 // effect. The primary purpose of this API is to help avoid a bunch of the
944 // resizes at the small capacities 4, 8, 16, etc.
945 if (__CFArrayGetType(array) == __kCFArrayDeque) {
946 struct __CFArrayDeque *deque = (struct __CFArrayDeque *)array->_store;
947 CFIndex capacity = __CFArrayDequeRoundUpCapacity(cap);
948 CFIndex size = sizeof(struct __CFArrayDeque) + capacity * sizeof(struct __CFArrayBucket);
949 CFAllocatorRef allocator = __CFGetAllocator(array);
950 if (NULL == deque) {
951 deque = (struct __CFArrayDeque *)_CFAllocatorAllocateGC(allocator, size, isStrongMemory(array) ? __kCFAllocatorGCScannedMemory : 0);
952 if (NULL == deque) __CFArrayHandleOutOfMemory(array, size);
953 if (__CFOASafe) __CFSetLastAllocationEventName(deque, "CFArray (store-deque)");
954 deque->_leftIdx = capacity / 2;
955 } else {
956 struct __CFArrayDeque *olddeque = deque;
957 CFIndex oldcap = deque->_capacity;
958 deque = (struct __CFArrayDeque *)_CFAllocatorAllocateGC(allocator, size, isStrongMemory(array) ? __kCFAllocatorGCScannedMemory : 0);
959 if (NULL == deque) __CFArrayHandleOutOfMemory(array, size);
960 CF_WRITE_BARRIER_MEMMOVE(deque, olddeque, sizeof(struct __CFArrayDeque) + oldcap * sizeof(struct __CFArrayBucket));
961 _CFAllocatorDeallocateGC(allocator, olddeque);
962 if (__CFOASafe) __CFSetLastAllocationEventName(deque, "CFArray (store-deque)");
963 }
964 deque->_capacity = capacity;
965 deque->_bias = 0;
966 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, array, array->_store, deque);
967 }
968 }
969
970
971 void CFArrayReplaceValues(CFMutableArrayRef array, CFRange range, const void **newValues, CFIndex newCount) {
972 CF_OBJC_FUNCDISPATCH3(__kCFArrayTypeID, void, array, "replaceObjectsInRange:withObjects:count:", range, (void **)newValues, newCount);
973 __CFGenericValidateType(array, __kCFArrayTypeID);
974 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
975 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
976 CFAssert2(0 <= newCount, __kCFLogAssertion, "%s(): newCount (%d) cannot be less than zero", __PRETTY_FUNCTION__, newCount);
977 return _CFArrayReplaceValues(array, range, newValues, newCount);
978 }
979
980 // This function does no ObjC dispatch or argument checking;
981 // It should only be called from places where that dispatch and check has already been done, or NSCFArray
982 void _CFArrayReplaceValues(CFMutableArrayRef array, CFRange range, const void **newValues, CFIndex newCount) {
983 const CFArrayCallBacks *cb;
984 CFAllocatorRef allocator;
985 CFIndex idx, cnt, futureCnt;
986 const void **newv, *buffer[256];
987 cnt = __CFArrayGetCount(array);
988 futureCnt = cnt - range.length + newCount;
989 CFAssert1(newCount <= futureCnt, __kCFLogAssertion, "%s(): internal error 1", __PRETTY_FUNCTION__);
990 cb = __CFArrayGetCallBacks(array);
991 allocator = __CFGetAllocator(array);
992 /* Retain new values if needed, possibly allocating a temporary buffer for them */
993 if (NULL != cb->retain && !hasBeenFinalized(array)) {
994 newv = (newCount <= 256) ? (const void **)buffer : (const void **)CFAllocatorAllocate(allocator, newCount * sizeof(void *), 0); // GC OK
995 if (newv != buffer && __CFOASafe) __CFSetLastAllocationEventName(newv, "CFArray (temp)");
996 for (idx = 0; idx < newCount; idx++) {
997 newv[idx] = (void *)INVOKE_CALLBACK2(cb->retain, allocator, (void *)newValues[idx]);
998 }
999 } else {
1000 newv = newValues;
1001 }
1002 array->_mutations++;
1003
1004 /* Now, there are three regions of interest, each of which may be empty:
1005 * A: the region from index 0 to one less than the range.location
1006 * B: the region of the range
1007 * C: the region from range.location + range.length to the end
1008 * Note that index 0 is not necessarily at the lowest-address edge
1009 * of the available storage. The values in region B need to get
1010 * released, and the values in regions A and C (depending) need
1011 * to get shifted if the number of new values is different from
1012 * the length of the range being replaced.
1013 */
1014 if (0 < range.length) {
1015 __CFArrayReleaseValues(array, range, false);
1016 }
1017 // region B elements are now "dead"
1018 if (__kCFArrayStorage == __CFArrayGetType(array)) {
1019 CFStorageRef store = (CFStorageRef)array->_store;
1020 // reposition regions A and C for new region B elements in gap
1021 if (range.length < newCount) {
1022 CFStorageInsertValues(store, CFRangeMake(range.location + range.length, newCount - range.length));
1023 } else if (newCount < range.length) {
1024 CFStorageDeleteValues(store, CFRangeMake(range.location + newCount, range.length - newCount));
1025 }
1026 if (futureCnt <= __CF_MAX_BUCKETS_PER_DEQUE / 2) {
1027 __CFArrayConvertStoreToDeque(array);
1028 }
1029 } else if (NULL == array->_store) {
1030 if (__CF_MAX_BUCKETS_PER_DEQUE <= futureCnt) {
1031 CFStorageRef store = (CFStorageRef)CFMakeCollectable(CFStorageCreate(allocator, sizeof(const void *)));
1032 if (! isStrongMemory(array)) _CFStorageSetWeak(store);
1033 if (__CFOASafe) __CFSetLastAllocationEventName(store, "CFArray (store-storage)");
1034 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, array, array->_store, store);
1035 CFStorageInsertValues(store, CFRangeMake(0, newCount));
1036 __CFBitfieldSetValue(((CFRuntimeBase *)array)->_cfinfo[CF_INFO_BITS], 1, 0, __kCFArrayStorage);
1037 } else if (0 <= futureCnt) {
1038 struct __CFArrayDeque *deque;
1039 CFIndex capacity = __CFArrayDequeRoundUpCapacity(futureCnt);
1040 CFIndex size = sizeof(struct __CFArrayDeque) + capacity * sizeof(struct __CFArrayBucket);
1041 deque = (struct __CFArrayDeque *)_CFAllocatorAllocateGC(allocator, size, isStrongMemory(array) ? __kCFAllocatorGCScannedMemory : 0);
1042 if (__CFOASafe) __CFSetLastAllocationEventName(deque, "CFArray (store-deque)");
1043 deque->_leftIdx = (capacity - newCount) / 2;
1044 deque->_capacity = capacity;
1045 deque->_bias = 0;
1046 CF_WRITE_BARRIER_BASE_ASSIGN(allocator, array, array->_store, deque);
1047 }
1048 } else { // Deque
1049 // reposition regions A and C for new region B elements in gap
1050 if (__CF_MAX_BUCKETS_PER_DEQUE <= futureCnt) {
1051 CFStorageRef store;
1052 __CFArrayConvertDequeToStore(array);
1053 store = (CFStorageRef)array->_store;
1054 if (range.length < newCount) {
1055 CFStorageInsertValues(store, CFRangeMake(range.location + range.length, newCount - range.length));
1056 } else if (newCount < range.length) { // this won't happen, but is here for completeness
1057 CFStorageDeleteValues(store, CFRangeMake(range.location + newCount, range.length - newCount));
1058 }
1059 } else if (range.length != newCount) {
1060 __CFArrayRepositionDequeRegions(array, range, newCount);
1061 }
1062 }
1063 // copy in new region B elements
1064 if (0 < newCount) {
1065 if (__kCFArrayStorage == __CFArrayGetType(array)) {
1066 CFStorageRef store = (CFStorageRef)array->_store;
1067 CFStorageReplaceValues(store, CFRangeMake(range.location, newCount), newv);
1068 } else { // Deque
1069 struct __CFArrayDeque *deque = (struct __CFArrayDeque *)array->_store;
1070 struct __CFArrayBucket *raw_buckets = (struct __CFArrayBucket *)((uint8_t *)deque + sizeof(struct __CFArrayDeque));
1071 CFAllocatorRef bucketsAllocator = isStrongMemory(array) ? allocator : kCFAllocatorNull;
1072 if (newCount == 1)
1073 CF_WRITE_BARRIER_ASSIGN(bucketsAllocator, *((const void **)raw_buckets + deque->_leftIdx + range.location), newv[0]);
1074 else
1075 CF_WRITE_BARRIER_MEMMOVE(raw_buckets + deque->_leftIdx + range.location, newv, newCount * sizeof(struct __CFArrayBucket));
1076 }
1077 }
1078 __CFArraySetCount(array, futureCnt);
1079 if (newv != buffer && newv != newValues) CFAllocatorDeallocate(allocator, newv);
1080 }
1081
1082 struct _acompareContext {
1083 CFComparatorFunction func;
1084 void *context;
1085 };
1086
1087 static CFComparisonResult __CFArrayCompareValues(const void *v1, const void *v2, struct _acompareContext *context) {
1088 const void **val1 = (const void **)v1;
1089 const void **val2 = (const void **)v2;
1090 return (CFComparisonResult)(INVOKE_CALLBACK3(context->func, *val1, *val2, context->context));
1091 }
1092
1093 void CFArraySortValues(CFMutableArrayRef array, CFRange range, CFComparatorFunction comparator, void *context) {
1094 FAULT_CALLBACK((void **)&(comparator));
1095 CF_OBJC_FUNCDISPATCH3(__kCFArrayTypeID, void, array, "sortUsingFunction:context:range:", comparator, context, range);
1096 __CFGenericValidateType(array, __kCFArrayTypeID);
1097 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
1098 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
1099 CFAssert1(NULL != comparator, __kCFLogAssertion, "%s(): pointer to comparator function may not be NULL", __PRETTY_FUNCTION__);
1100 array->_mutations++;
1101
1102 if (1 < range.length) {
1103 struct _acompareContext ctx;
1104 struct __CFArrayBucket *bucket;
1105 ctx.func = comparator;
1106 ctx.context = context;
1107 switch (__CFArrayGetType(array)) {
1108 case __kCFArrayDeque:
1109 bucket = __CFArrayGetBucketsPtr(array) + range.location;
1110 if (CF_USING_COLLECTABLE_MEMORY && isStrongMemory(array)) {
1111 size_t size = range.length * sizeof(void*);
1112 __CFObjCWriteBarrierRange(bucket, size);
1113 CFQSortArray(bucket, range.length, sizeof(void *), (CFComparatorFunction)__CFArrayCompareValues, &ctx);
1114 } else {
1115 CFQSortArray(bucket, range.length, sizeof(void *), (CFComparatorFunction)__CFArrayCompareValues, &ctx);
1116 }
1117 break;
1118 case __kCFArrayStorage: {
1119 CFStorageRef store = (CFStorageRef)array->_store;
1120 CFAllocatorRef allocator = __CFGetAllocator(array);
1121 const void **values, *buffer[256];
1122 values = (range.length <= 256) ? (const void **)buffer : (const void **)CFAllocatorAllocate(allocator, range.length * sizeof(void *), 0); // GC OK
1123 if (values != buffer && __CFOASafe) __CFSetLastAllocationEventName(values, "CFArray (temp)");
1124 CFStorageGetValues(store, range, values);
1125 CFQSortArray(values, range.length, sizeof(void *), (CFComparatorFunction)__CFArrayCompareValues, &ctx);
1126 CFStorageReplaceValues(store, range, values);
1127 if (values != buffer) CFAllocatorDeallocate(allocator, values); // GC OK
1128 break;
1129 }
1130 }
1131 }
1132 }
1133
1134 CFIndex CFArrayBSearchValues(CFArrayRef array, CFRange range, const void *value, CFComparatorFunction comparator, void *context) {
1135 __CFGenericValidateType(array, __kCFArrayTypeID);
1136 __CFArrayValidateRange(array, range, __PRETTY_FUNCTION__);
1137 CFAssert1(NULL != comparator, __kCFLogAssertion, "%s(): pointer to comparator function may not be NULL", __PRETTY_FUNCTION__);
1138 bool isObjC = CF_IS_OBJC(__kCFArrayTypeID, array);
1139 FAULT_CALLBACK((void **)&(comparator));
1140 CFIndex idx = 0;
1141 if (range.length <= 0) return range.location;
1142 if (isObjC || __kCFArrayStorage == __CFArrayGetType(array)) {
1143 const void *item;
1144 SInt32 lg;
1145 item = CFArrayGetValueAtIndex(array, range.location + range.length - 1);
1146 if ((CFComparisonResult)(INVOKE_CALLBACK3(comparator, item, value, context)) < 0) {
1147 return range.location + range.length;
1148 }
1149 item = CFArrayGetValueAtIndex(array, range.location);
1150 if ((CFComparisonResult)(INVOKE_CALLBACK3(comparator, value, item, context)) < 0) {
1151 return range.location;
1152 }
1153 lg = flsl(range.length) - 1; // lg2(range.length)
1154 item = CFArrayGetValueAtIndex(array, range.location + -1 + (1 << lg));
1155 idx = range.location + ((CFComparisonResult)(INVOKE_CALLBACK3(comparator, item, value, context)) < 0) ? range.length - (1 << lg) : -1;
1156 while (lg--) {
1157 item = CFArrayGetValueAtIndex(array, range.location + idx + (1 << lg));
1158 if ((CFComparisonResult)(INVOKE_CALLBACK3(comparator, item, value, context)) < 0) {
1159 idx += (1 << lg);
1160 }
1161 }
1162 idx++;
1163 } else {
1164 struct _acompareContext ctx;
1165 ctx.func = comparator;
1166 ctx.context = context;
1167 idx = CFBSearch(&value, sizeof(void *), __CFArrayGetBucketsPtr(array) + range.location, range.length, (CFComparatorFunction)__CFArrayCompareValues, &ctx);
1168 }
1169 return idx + range.location;
1170 }
1171
1172 void CFArrayAppendArray(CFMutableArrayRef array, CFArrayRef otherArray, CFRange otherRange) {
1173 CFIndex idx;
1174 __CFGenericValidateType(array, __kCFArrayTypeID);
1175 __CFGenericValidateType(otherArray, __kCFArrayTypeID);
1176 CFAssert1(__CFArrayGetType(array) != __kCFArrayImmutable, __kCFLogAssertion, "%s(): array is immutable", __PRETTY_FUNCTION__);
1177 __CFArrayValidateRange(otherArray, otherRange, __PRETTY_FUNCTION__);
1178 for (idx = otherRange.location; idx < otherRange.location + otherRange.length; idx++) {
1179 CFArrayAppendValue(array, CFArrayGetValueAtIndex(otherArray, idx));
1180 }
1181 }