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Chris Lattnere54c0b52009-03-09 06:57:46 +00001Block Implementation Specification
2
Blaine Garsta98c27b2010-03-16 22:02:16 +00003Copyright 2008-2010 Apple, Inc.
Chris Lattnere54c0b52009-03-09 06:57:46 +00004Permission is hereby granted, free of charge, to any person obtaining a copy
5of this software and associated documentation files (the "Software"), to deal
6in the Software without restriction, including without limitation the rights
7to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
8copies of the Software, and to permit persons to whom the Software is
9furnished to do so, subject to the following conditions:
10
11The above copyright notice and this permission notice shall be included in
12all copies or substantial portions of the Software.
13
14THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
15IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
16FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
17AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
18LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
19OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
20THE SOFTWARE.
21
220. History
23
242008/7/14 - created
252008/8/21 - revised, C++
262008/9/24 - add NULL isa field to __block storage
272008/10/1 - revise block layout to use a static descriptor structure
282008/10/6 - revise block layout to use an unsigned long int flags
292008/10/28 - specify use of _Block_object_assign/dispose for all "Object" types in helper functions
302008/10/30 - revise new layout to have invoke function in same place
312008/10/30 - add __weak support
32
Blaine Garst6757aaa2010-03-16 21:21:07 +0000332010/3/16 - rev for stret return, signature field
Blaine Garst69ecbdb2010-04-06 17:46:43 +0000342010/4/6 - improved wording
Blaine Garst6757aaa2010-03-16 21:21:07 +000035
Chris Lattnere54c0b52009-03-09 06:57:46 +000036This document describes the Apple ABI implementation specification of Blocks.
37
Blaine Garst69ecbdb2010-04-06 17:46:43 +000038The first shipping version of this ABI is found in Mac OS X 10.6, and shall be referred to as 10.6.ABI. As of 2010/3/16, the following describes the ABI contract with the runtime and the compiler, and, as necessary, will be referred to as ABI.2010.3.16.
Blaine Garst6757aaa2010-03-16 21:21:07 +000039
40Since the Apple ABI references symbols from other elements of the system, any attempt to use this ABI on systems prior to SnowLeopard is undefined.
41
Chris Lattnere54c0b52009-03-09 06:57:46 +0000421. High Level
43
Blaine Garst6757aaa2010-03-16 21:21:07 +000044The ABI of blocks consist of their layout and the runtime functions required by the compiler.
Chris Lattnere54c0b52009-03-09 06:57:46 +000045A Block consists of a structure of the following form:
46
47struct Block_literal_1 {
48 void *isa; // initialized to &_NSConcreteStackBlock or &_NSConcreteGlobalBlock
49 int flags;
50 int reserved;
51 void (*invoke)(void *, ...);
52 struct Block_descriptor_1 {
53 unsigned long int reserved; // NULL
Blaine Garst6757aaa2010-03-16 21:21:07 +000054 unsigned long int size; // sizeof(struct Block_literal_1)
Chris Lattnere54c0b52009-03-09 06:57:46 +000055 // optional helper functions
Blaine Garst6757aaa2010-03-16 21:21:07 +000056 void (*copy_helper)(void *dst, void *src); // IFF (1<<25)
57 void (*dispose_helper)(void *src); // IFF (1<<25)
Blaine Garst69ecbdb2010-04-06 17:46:43 +000058 // required ABI.2010.3.16
Blaine Garst6757aaa2010-03-16 21:21:07 +000059 const char *signature; // IFF (1<<30)
Chris Lattnere54c0b52009-03-09 06:57:46 +000060 } *descriptor;
61 // imported variables
62};
63
Blaine Garst69ecbdb2010-04-06 17:46:43 +000064The following flags bits are in use thusly for a possible ABI.2010.3.16:
Chris Lattnere54c0b52009-03-09 06:57:46 +000065
66enum {
67 BLOCK_HAS_COPY_DISPOSE = (1 << 25),
68 BLOCK_HAS_CTOR = (1 << 26), // helpers have C++ code
69 BLOCK_IS_GLOBAL = (1 << 28),
Blaine Garst6757aaa2010-03-16 21:21:07 +000070 BLOCK_HAS_STRET = (1 << 29),
71 BLOCK_HAS_SIGNATURE = (1 << 30),
Chris Lattnere54c0b52009-03-09 06:57:46 +000072};
73
Blaine Garst6757aaa2010-03-16 21:21:07 +000074In 10.6.ABI the (1<<29) was unconditionally set and ignored by the runtime - it was a transitional marker that did not get deleted after the transition. This bit is now paired with (1<<30), and represented as the pair (3<<30), for the following combinations of valid bit settings, and their meanings.
75
76switch (flags & (3<<29)) {
77 case (0<<29): <unused> , error
78 case (1<<29): 10.6.ABI, no signature field available
Blaine Garst69ecbdb2010-04-06 17:46:43 +000079 case (2<<29): ABI.2010.3.16, regular calling convention, presence of signature field
80 case (3<<29): ABI.2010.3.16, stret calling convention, presence of signature field,
Blaine Garst6757aaa2010-03-16 21:21:07 +000081}
82
83The following discussions are presented as 10.6.ABI otherwise.
84
Chris Lattnere54c0b52009-03-09 06:57:46 +000085Block literals may occur within functions where the structure is created in stack local memory. They may also appear as initialization expressions for Block variables of global or static local variables.
86
87When a Block literal expression is evaluated the stack based structure is initialized as follows:
88
891) static descriptor structure is declared and initialized as follows:
901a) the invoke function pointer is set to a function that takes the Block structure as its first argument and the rest of the arguments (if any) to the Block and executes the Block compound statement.
911b) the size field is set to the size of the following Block literal structure.
921c) the copy_helper and dispose_helper function pointers are set to respective helper functions if they are required by the Block literal
932) a stack (or global) Block literal data structure is created and initialized as follows:
942a) the isa field is set to the address of the external _NSConcreteStackBlock, which is a block of uninitialized memory supplied in libSystem, or _NSConcreteGlobalBlock if this is a static or file level block literal.
952) The flags field is set to zero unless there are variables imported into the block that need helper functions for program level Block_copy() and Block_release() operations, in which case the (1<<25) flags bit is set.
96
Blaine Garst6757aaa2010-03-16 21:21:07 +000097
Chris Lattnere54c0b52009-03-09 06:57:46 +000098As an example, the Block literal expression
99 ^ { printf("hello world\n"); }
100would cause to be created on a 32-bit system:
101
102struct __block_literal_1 {
103 void *isa;
104 int flags;
105 int reserved;
106 void (*invoke)(struct __block_literal_1 *);
107 struct __block_descriptor_1 *descriptor;
108};
109
110void __block_invoke_1(struct __block_literal_1 *_block) {
111 printf("hello world\n");
112}
113
114static struct __block_descriptor_1 {
115 unsigned long int reserved;
116 unsigned long int Block_size;
117} __block_descriptor_1 = { 0, sizeof(struct __block_literal_1), __block_invoke_1 };
118
119and where the block literal appeared
120
121 struct __block_literal_1 _block_literal = {
122 &_NSConcreteStackBlock,
123 (1<<29), <uninitialized>,
124 __block_invoke_1,
125 &__block_descriptor_1
126 };
127
128Blocks import other Block references, const copies of other variables, and variables marked __block. In Objective-C variables may additionally be objects.
129
130When a Block literal expression used as the initial value of a global or static local variable it is initialized as follows:
131 struct __block_literal_1 __block_literal_1 = {
132 &_NSConcreteGlobalBlock,
133 (1<<28)|(1<<29), <uninitialized>,
134 __block_invoke_1,
135 &__block_descriptor_1
136 };
137that is, a different address is provided as the first value and a particular (1<<28) bit is set in the flags field, and otherwise it is the same as for stack based Block literals. This is an optimization that can be used for any Block literal that imports no const or __block storage variables.
138
139
1402. Imported Variables
141
142Variables of "auto" storage class are imported as const copies. Variables of "__block" storage class are imported as a pointer to an enclosing data structure. Global variables are simply referenced and not considered as imported.
143
1442.1 Imported const copy variables
145
146Automatic storage variables not marked with __block are imported as const copies.
147
148The simplest example is that of importing a variable of type int.
149
150 int x = 10;
151 void (^vv)(void) = ^{ printf("x is %d\n", x); }
152 x = 11;
153 vv();
154
155would be compiled
156
157struct __block_literal_2 {
158 void *isa;
159 int flags;
160 int reserved;
161 void (*invoke)(struct __block_literal_2 *);
162 struct __block_descriptor_2 *descriptor;
163 const int x;
164};
165
166void __block_invoke_2(struct __block_literal_2 *_block) {
167 printf("x is %d\n", _block->x);
168}
169
170static struct __block_descriptor_2 {
171 unsigned long int reserved;
172 unsigned long int Block_size;
173} __block_descriptor_2 = { 0, sizeof(struct __block_literal_2) };
174
175and
176
177 struct __block_literal_2 __block_literal_2 = {
178 &_NSConcreteStackBlock,
179 (1<<29), <uninitialized>,
180 __block_invoke_2,
181 &__block_descriptor_2,
182 x
183 };
184
185In summary, scalars, structures, unions, and function pointers are generally imported as const copies with no need for helper functions.
186
1872.2 Imported const copy of Block reference
188
189The first case where copy and dispose helper functions are required is for the case of when a block itself is imported. In this case both a copy_helper function and a dispose_helper function are needed. The copy_helper function is passed both the existing stack based pointer and the pointer to the new heap version and should call back into the runtime to actually do the copy operation on the imported fields within the block. The runtime functions are all described in Section 5.0 Runtime Helper Functions.
190
191An example:
192
193 void (^existingBlock)(void) = ...;
194 void (^vv)(void) = ^{ existingBlock(); }
195 vv();
196
197struct __block_literal_3 {
198 ...; // existing block
199};
200
201struct __block_literal_4 {
202 void *isa;
203 int flags;
204 int reserved;
205 void (*invoke)(struct __block_literal_4 *);
206 struct __block_literal_3 *const existingBlock;
207};
208
209void __block_invoke_4(struct __block_literal_2 *_block) {
210 __block->existingBlock->invoke(__block->existingBlock);
211}
212
213void __block_copy_4(struct __block_literal_4 *dst, struct __block_literal_4 *src) {
214 //_Block_copy_assign(&dst->existingBlock, src->existingBlock, 0);
215 _Block_object_assign(&dst->existingBlock, src->existingBlock, BLOCK_FIELD_IS_BLOCK);
216}
217
218void __block_dispose_4(struct __block_literal_4 *src) {
219 // was _Block_destroy
220 _Block_object_dispose(src->existingBlock, BLOCK_FIELD_IS_BLOCK);
221}
222
223static struct __block_descriptor_4 {
224 unsigned long int reserved;
225 unsigned long int Block_size;
226 void (*copy_helper)(struct __block_literal_4 *dst, struct __block_literal_4 *src);
227 void (*dispose_helper)(struct __block_literal_4 *);
228} __block_descriptor_4 = {
229 0,
230 sizeof(struct __block_literal_4),
231 __block_copy_4,
232 __block_dispose_4,
233};
234
235and where it is used
236
237 struct __block_literal_4 _block_literal = {
238 &_NSConcreteStackBlock,
239 (1<<25)|(1<<29), <uninitialized>
240 __block_invoke_4,
241 & __block_descriptor_4
242 existingBlock,
243 };
244
2452.2.1 Importing __attribute__((NSObject)) variables.
246
247GCC introduces __attribute__((NSObject)) on structure pointers to mean "this is an object". This is useful because many low level data structures are declared as opaque structure pointers, e.g. CFStringRef, CFArrayRef, etc. When used from C, however, these are still really objects and are the second case where that requires copy and dispose helper functions to be generated. The copy helper functions generated by the compiler should use the _Block_object_assign runtime helper function and in the dispose helper the _Block_object_dispose runtime helper function should be called.
248
249For example, block xyzzy in the following
250
251 struct Opaque *__attribute__((NSObject)) objectPointer = ...;
252 ...
253 void (^xyzzy)(void) = ^{ CFPrint(objectPointer); };
254
255would have helper functions
256
257void __block_copy_xyzzy(struct __block_literal_5 *dst, struct __block_literal_5 *src) {
258 _Block_object_assign(&dst->objectPointer, src-> objectPointer, BLOCK_FIELD_IS_OBJECT);
259}
260
261void __block_dispose_xyzzy(struct __block_literal_5 *src) {
262 _Block_object_dispose(src->objectPointer, BLOCK_FIELD_IS_OBJECT);
263}
264
265generated.
266
267
2682.3 Imported __block marked variables.
269
2702.3.1 Layout of __block marked variables
271
272The compiler must embed variables that are marked __block in a specialized structure of the form:
273
274struct _block_byref_xxxx {
275 void *isa;
276 struct Block_byref *forwarding;
277 int flags; //refcount;
278 int size;
279 typeof(marked_variable) marked_variable;
280};
281
282Variables of certain types require helper functions for when Block_copy() and Block_release() are performed upon a referencing Block. At the "C" level only variables that are of type Block or ones that have __attribute__((NSObject)) marked require helper functions. In Objective-C objects require helper functions and in C++ stack based objects require helper functions. Variables that require helper functions use the form:
283
284struct _block_byref_xxxx {
285 void *isa;
286 struct _block_byref_xxxx *forwarding;
287 int flags; //refcount;
288 int size;
289 // helper functions called via Block_copy() and Block_release()
290 void (*byref_keep)(void *dst, void *src);
291 void (*byref_dispose)(void *);
292 typeof(marked_variable) marked_variable;
293};
294
295The structure is initialized such that
296 a) the forwarding pointer is set to the beginning of its enclosing structure,
297 b) the size field is initialized to the total size of the enclosing structure,
298 c) the flags field is set to either 0 if no helper functions are needed or (1<<25) if they are,
299 d) the helper functions are initialized (if present)
300 e) the variable itself is set to its initial value.
301 f) the isa field is set to NULL
302
3032.3.2 Access to __block variables from within its lexical scope.
304
305In order to "move" the variable to the heap upon a copy_helper operation the compiler must rewrite access to such a variable to be indirect through the structures forwarding pointer. For example:
306
307 int __block i = 10;
308 i = 11;
309
310would be rewritten to be:
311
312 struct _block_byref_i {
313 void *isa;
314 struct _block_byref_i *forwarding;
315 int flags; //refcount;
316 int size;
317 int captured_i;
Zhongxing Xu77f41652009-12-08 05:05:26 +0000318 } i = { NULL, &i, 0, sizeof(struct _block_byref_i), 11 };
Chris Lattnere54c0b52009-03-09 06:57:46 +0000319
320 i.forwarding->captured_i = 11;
321
322In the case of a Block reference variable being marked __block the helper code generated must use the _Block_object_assign and _Block_object_dispose routines supplied by the runtime to make the copies. For example:
323
324 __block void (voidBlock)(void) = blockA;
325 voidBlock = blockB;
326
327would translate into
328
329struct _block_byref_voidBlock {
330 void *isa;
331 struct _block_byref_voidBlock *forwarding;
332 int flags; //refcount;
333 int size;
334 void (*byref_keep)(struct _block_byref_voidBlock *dst, struct _block_byref_voidBlock *src);
335 void (*byref_dispose)(struct _block_byref_voidBlock *);
336 void (^captured_voidBlock)(void);
337};
338
339void _block_byref_keep_helper(struct _block_byref_voidBlock *dst, struct _block_byref_voidBlock *src) {
340 //_Block_copy_assign(&dst->captured_voidBlock, src->captured_voidBlock, 0);
341 _Block_object_assign(&dst->captured_voidBlock, src->captured_voidBlock, BLOCK_FIELD_IS_BLOCK | BLOCK_BYREF_CALLER);
342}
343
344void _block_byref_dispose_helper(struct _block_byref_voidBlock *param) {
345 //_Block_destroy(param->captured_voidBlock, 0);
346 _Block_object_dispose(param->captured_voidBlock, BLOCK_FIELD_IS_BLOCK | BLOCK_BYREF_CALLER)}
347
348and
349 struct _block_byref_voidBlock voidBlock = {( .forwarding=&voidBlock, .flags=(1<<25), .size=sizeof(struct _block_byref_voidBlock *),
350 .byref_keep=_block_byref_keep_helper, .byref_dispose=_block_byref_dispose_helper,
351 .captured_voidBlock=blockA };
352
353 voidBlock.forwarding->captured_voidBlock = blockB;
354
355
3562.3.3 Importing __block variables into Blocks
357
358A Block that uses a __block variable in its compound statement body must import the variable and emit copy_helper and dispose_helper helper functions that, in turn, call back into the runtime to actually copy or release the byref data block using the functions _Block_object_assign and _Block_object_dispose.
359
360For example:
361
362 int __block i = 2;
363 functioncall(^{ i = 10; });
364
365would translate to
366
367struct _block_byref_i {
368 void *isa; // set to NULL
369 struct _block_byref_voidBlock *forwarding;
370 int flags; //refcount;
371 int size;
372 void (*byref_keep)(struct _block_byref_i *dst, struct _block_byref_i *src);
373 void (*byref_dispose)(struct _block_byref_i *);
374 int captured_i;
375};
376
377
378struct __block_literal_5 {
379 void *isa;
380 int flags;
381 int reserved;
382 void (*invoke)(struct __block_literal_5 *);
383 struct __block_descriptor_5 *descriptor;
384 struct _block_byref_i *i_holder;
385};
386
387void __block_invoke_5(struct __block_literal_5 *_block) {
388 _block->forwarding->captured_i = 10;
389}
390
391void __block_copy_5(struct __block_literal_5 *dst, struct __block_literal_5 *src) {
392 //_Block_byref_assign_copy(&dst->captured_i, src->captured_i);
393 _Block_object_assign(&dst->captured_i, src->captured_i, BLOCK_FIELD_IS_BYREF | BLOCK_BYREF_CALLER);
394}
395
396void __block_dispose_5(struct __block_literal_5 *src) {
397 //_Block_byref_release(src->captured_i);
398 _Block_object_dispose(src->captured_i, BLOCK_FIELD_IS_BYREF | BLOCK_BYREF_CALLER);
399}
400
401static struct __block_descriptor_5 {
402 unsigned long int reserved;
403 unsigned long int Block_size;
404 void (*copy_helper)(struct __block_literal_5 *dst, struct __block_literal_5 *src);
405 void (*dispose_helper)(struct __block_literal_5 *);
406} __block_descriptor_5 = { 0, sizeof(struct __block_literal_5) __block_copy_5, __block_dispose_5 };
407
408and
409
410 struct _block_byref_i i = {( .forwarding=&i, .flags=0, .size=sizeof(struct _block_byref_i) )};
411 struct __block_literal_5 _block_literal = {
412 &_NSConcreteStackBlock,
413 (1<<25)|(1<<29), <uninitialized>,
414 __block_invoke_5,
415 &__block_descriptor_5,
416 2,
417 };
418
4192.3.4 Importing __attribute__((NSObject)) __block variables
420
421A __block variable that is also marked __attribute__((NSObject)) should have byref_keep and byref_dispose helper functions that use _Block_object_assign and _Block_object_dispose.
422
4232.3.5 __block escapes
424
425Because Blocks referencing __block variables may have Block_copy() performed upon them the underlying storage for the variables may move to the heap. In Objective-C Garbage Collection Only compilation environments the heap used is the garbage collected one and no further action is required. Otherwise the compiler must issue a call to potentially release any heap storage for __block variables at all escapes or terminations of their scope.
426
427
4282.3.6 Nesting
429
430Blocks may contain Block literal expressions. Any variables used within inner blocks are imported into all enclosing Block scopes even if the variables are not used. This includes const imports as well as __block variables.
431
4323. Objective C Extensions to Blocks
433
4343.1 Importing Objects
435
436Objects should be treated as __attribute__((NSObject)) variables; all copy_helper, dispose_helper, byref_keep, and byref_dispose helper functions should use _Block_object_assign and _Block_object_dispose. There should be no code generated that uses -retain or -release methods.
437
438
4393.2 Blocks as Objects
440
441The compiler will treat Blocks as objects when synthesizing property setters and getters, will characterize them as objects when generating garbage collection strong and weak layout information in the same manner as objects, and will issue strong and weak write-barrier assignments in the same manner as objects.
442
4433.3 __weak __block Support
444
445Objective-C (and Objective-C++) support the __weak attribute on __block variables. Under normal circumstances the compiler uses the Objective-C runtime helper support functions objc_assign_weak and objc_read_weak. Both should continue to be used for all reads and writes of __weak __block variables:
446 objc_read_weak(&block->byref_i->forwarding->i)
447
448The __weak variable is stored in a _block_byref_xxxx structure and the Block has copy and dispose helpers for this structure that call:
449 _Block_object_assign(&dest->_block_byref_i, src-> _block_byref_i, BLOCK_FIELD_IS_WEAK | BLOCK_FIELD_IS_BYREF);
450and
451 _Block_object_dispose(src->_block_byref_i, BLOCK_FIELD_IS_WEAK | BLOCK_FIELD_IS_BYREF);
452
453
454In turn, the block_byref copy support helpers distinguish between whether the __block variable is a Block or not and should either call:
455 _Block_object_assign(&dest->_block_byref_i, src->_block_byref_i, BLOCK_FIELD_IS_WEAK | BLOCK_FIELD_IS_OBJECT | BLOCK_BYREF_CALLER);
456for something declared as an object or
457 _Block_object_assign(&dest->_block_byref_i, src->_block_byref_i, BLOCK_FIELD_IS_WEAK | BLOCK_FIELD_IS_BLOCK | BLOCK_BYREF_CALLER);
458for something declared as a Block.
459
460A full example follows:
461
462
463 __block __weak id obj = <initialization expression>;
464 functioncall(^{ [obj somemessage]; });
465
466would translate to
467
468struct _block_byref_obj {
469 void *isa; // uninitialized
470 struct _block_byref_obj *forwarding;
471 int flags; //refcount;
472 int size;
473 void (*byref_keep)(struct _block_byref_i *dst, struct _block_byref_i *src);
474 void (*byref_dispose)(struct _block_byref_i *);
475 int captured_obj;
476};
477
478void _block_byref_obj_keep(struct _block_byref_voidBlock *dst, struct _block_byref_voidBlock *src) {
479 //_Block_copy_assign(&dst->captured_obj, src->captured_obj, 0);
480 _Block_object_assign(&dst->captured_obj, src->captured_obj, BLOCK_FIELD_IS_OBJECT | BLOCK_FIELD_IS_WEAK | BLOCK_BYREF_CALLER);
481}
482
483void _block_byref_obj_dispose(struct _block_byref_voidBlock *param) {
484 //_Block_destroy(param->captured_obj, 0);
485 _Block_object_dispose(param->captured_obj, BLOCK_FIELD_IS_OBJECT | BLOCK_FIELD_IS_WEAK | BLOCK_BYREF_CALLER);
486};
487
488for the block byref part and
489
490struct __block_literal_5 {
491 void *isa;
492 int flags;
493 int reserved;
494 void (*invoke)(struct __block_literal_5 *);
495 struct __block_descriptor_5 *descriptor;
496 struct _block_byref_obj *byref_obj;
497};
498
499void __block_invoke_5(struct __block_literal_5 *_block) {
500 [objc_read_weak(&_block->byref_obj->forwarding->captured_obj) somemessage];
501}
502
503void __block_copy_5(struct __block_literal_5 *dst, struct __block_literal_5 *src) {
504 //_Block_byref_assign_copy(&dst->byref_obj, src->byref_obj);
505 _Block_object_assign(&dst->byref_obj, src->byref_obj, BLOCK_FIELD_IS_BYREF | BLOCK_FIELD_IS_WEAK);
506}
507
508void __block_dispose_5(struct __block_literal_5 *src) {
509 //_Block_byref_release(src->byref_obj);
510 _Block_object_dispose(src->byref_obj, BLOCK_FIELD_IS_BYREF | BLOCK_FIELD_IS_WEAK);
511}
512
513static struct __block_descriptor_5 {
514 unsigned long int reserved;
515 unsigned long int Block_size;
516 void (*copy_helper)(struct __block_literal_5 *dst, struct __block_literal_5 *src);
517 void (*dispose_helper)(struct __block_literal_5 *);
518} __block_descriptor_5 = { 0, sizeof(struct __block_literal_5), __block_copy_5, __block_dispose_5 };
519
520and within the compound statement:
521
522 struct _block_byref_obj obj = {( .forwarding=&obj, .flags=(1<<25), .size=sizeof(struct _block_byref_obj),
523 .byref_keep=_block_byref_obj_keep, .byref_dispose=_block_byref_obj_dispose,
524 .captured_obj = <initialization expression> )};
525
526 struct __block_literal_5 _block_literal = {
527 &_NSConcreteStackBlock,
528 (1<<25)|(1<<29), <uninitialized>,
529 __block_invoke_5,
530 &__block_descriptor_5,
531 &obj, // a reference to the on-stack structure containing "captured_obj"
532 };
533
534
535 functioncall(_block_literal->invoke(&_block_literal));
536
537
5384.0 C++ Support
539
540Within a block stack based C++ objects are copied as const copies using the const copy constructor. It is an error if a stack based C++ object is used within a block if it does not have a const copy constructor. In addition both copy and destroy helper routines must be synthesized for the block to support the Block_copy() operation, and the flags work marked with the (1<<26) bit in addition to the (1<<25) bit. The copy helper should call the constructor using appropriate offsets of the variable within the supplied stack based block source and heap based destination for all const constructed copies, and similarly should call the destructor in the destroy routine.
541
542As an example, suppose a C++ class FOO existed with a const copy constructor. Within a code block a stack version of a FOO object is declared and used within a Block literal expression:
543
544{
545 FOO foo;
546 void (^block)(void) = ^{ printf("%d\n", foo.value()); };
547}
548
549The compiler would synthesize
550
551struct __block_literal_10 {
552 void *isa;
553 int flags;
554 int reserved;
555 void (*invoke)(struct __block_literal_10 *);
556 struct __block_descriptor_10 *descriptor;
557 const FOO foo;
558};
559
560void __block_invoke_10(struct __block_literal_10 *_block) {
561 printf("%d\n", _block->foo.value());
562}
563
564void __block_literal_10(struct __block_literal_10 *dst, struct __block_literal_10 *src) {
565 comp_ctor(&dst->foo, &src->foo);
566}
567
568void __block_dispose_10(struct __block_literal_10 *src) {
569 comp_dtor(&src->foo);
570}
571
572static struct __block_descriptor_10 {
573 unsigned long int reserved;
574 unsigned long int Block_size;
575 void (*copy_helper)(struct __block_literal_10 *dst, struct __block_literal_10 *src);
576 void (*dispose_helper)(struct __block_literal_10 *);
577} __block_descriptor_10 = { 0, sizeof(struct __block_literal_10), __block_copy_10, __block_dispose_10 };
578
579and the code would be:
580{
581 FOO foo;
582 comp_ctor(&foo); // default constructor
583 struct __block_literal_10 _block_literal = {
584 &_NSConcreteStackBlock,
585 (1<<25)|(1<<26)|(1<<29), <uninitialized>,
586 __block_invoke_10,
587 &__block_descriptor_10,
588 };
589 comp_ctor(&_block_literal->foo, &foo); // const copy into stack version
590 struct __block_literal_10 &block = &_block_literal; // assign literal to block variable
591 block->invoke(block); // invoke block
592 comp_dtor(&_block_literal->foo); // destroy stack version of const block copy
593 comp_dtor(&foo); // destroy original version
594}
595
596
597C++ objects stored in __block storage start out on the stack in a block_byref data structure as do other variables. Such objects (if not const objects) must support a regular copy constructor. The block_byref data structure will have copy and destroy helper routines synthesized by the compiler. The copy helper will have code created to perform the copy constructor based on the initial stack block_byref data structure, and will also set the (1<<26) bit in addition to the (1<<25) bit. The destroy helper will have code to do the destructor on the object stored within the supplied block_byref heap data structure.
598
599To support member variable and function access the compiler will synthesize a const pointer to a block version of the this pointer.
600
6015.0 Runtime Helper Functions
602
603The runtime helper functions are described in /usr/local/include/Block_private.h. To summarize their use, a block requires copy/dispose helpers if it imports any block variables, __block storage variables, __attribute__((NSObject)) variables, or C++ const copied objects with constructor/destructors. The (1<<26) bit is set and functions are generated.
604
605The block copy helper function should, for each of the variables of the type mentioned above, call
606 _Block_object_assign(&dst->target, src->target, BLOCK_FIELD_<appropo>);
607in the copy helper and
608 _Block_object_dispose(->target, BLOCK_FIELD_<appropo>);
609in the dispose helper where
610 <appropo> is
611
612enum {
613 BLOCK_FIELD_IS_OBJECT = 3, // id, NSObject, __attribute__((NSObject)), block, ...
614 BLOCK_FIELD_IS_BLOCK = 7, // a block variable
615 BLOCK_FIELD_IS_BYREF = 8, // the on stack structure holding the __block variable
616
617 BLOCK_FIELD_IS_WEAK = 16, // declared __weak
618
619 BLOCK_BYREF_CALLER = 128, // called from byref copy/dispose helpers
620};
621
622and of course the CTORs/DTORs for const copied C++ objects.
623
624The block_byref data structure similarly requires copy/dispose helpers for block variables, __attribute__((NSObject)) variables, or C++ const copied objects with constructor/destructors, and again the (1<<26) bit is set and functions are generated in the same manner.
625
626Under ObjC we allow __weak as an attribute on __block variables, and this causes the addition of BLOCK_FIELD_IS_WEAK orred onto the BLOCK_FIELD_IS_BYREF flag when copying the block_byref structure in the block copy helper, and onto the BLOCK_FIELD_<appropo> field within the block_byref copy/dispose helper calls.
627
628The prototypes, and summary, of the helper functions are
629
630/* Certain field types require runtime assistance when being copied to the heap. The following function is used
631 to copy fields of types: blocks, pointers to byref structures, and objects (including __attribute__((NSObject)) pointers.
632 BLOCK_FIELD_IS_WEAK is orthogonal to the other choices which are mutually exclusive.
633 Only in a Block copy helper will one see BLOCK_FIELD_IS_BYREF.
634 */
635void _Block_object_assign(void *destAddr, const void *object, const int flags);
636
637/* Similarly a compiler generated dispose helper needs to call back for each field of the byref data structure.
638 (Currently the implementation only packs one field into the byref structure but in principle there could be more).
639 The same flags used in the copy helper should be used for each call generated to this function:
640 */
641void _Block_object_dispose(const void *object, const int flags);
642
643The following functions have been used and will continue to be supported until new compiler support is complete.
644
645// Obsolete functions.
646// Copy helper callback for copying a block imported into a Block
647// Called by copy_helper helper functions synthesized by the compiler.
648// The address in the destination block of an imported Block is provided as the first argument
649// and the value of the existing imported Block is the second.
650// Use: _Block_object_assign(dest, src, BLOCK_FIELD_IS_BLOCK {| BLOCK_FIELD_IS_WEAK});
651void _Block_copy_assign(struct Block_basic **dest, const struct Block_basic *src, const int flags);
652
653// Destroy helper callback for releasing Blocks imported into a Block
654// Called by dispose_helper helper functions synthesized by the compiler.
655// The value of the imported Block variable is passed back.
656// Use: _Block_object_dispose(src, BLOCK_FIELD_IS_BLOCK {| BLOCK_FIELD_IS_WEAK});
657void _Block_destroy(const struct Block_basic *src, const int flags);
658
659// Byref data block copy helper callback
660// Called by block copy helpers when copying __block structures
661// Use: _Block_object_assign(dest, src, BLOCK_FIELD_IS_BYREF {| BLOCK_FIELD_IS_WEAK});
662void _Block_byref_assign_copy(struct Block_byref **destp, struct Block_byref *src);
663
664// Byref data block release helper callback
665// Called by block release helpers when releasing a Block
666// Called at escape points in scope where __block variables live (under non-GC-only conditions)
667// Use: _Block_object_dispose(src, BLOCK_FIELD_IS_BYREF {| BLOCK_FIELD_IS_WEAK});
668void ยง(struct Block_byref *shared_struct);
669
670