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1 /*
2 * Copyright © 2008 Ryan Lortie
3 * Copyright © 2010 Codethink Limited
4 *
5 * This library is free software; you can redistribute it and/or
6 * modify it under the terms of the GNU Lesser General Public
7 * License as published by the Free Software Foundation; either
8 * version 2.1 of the License, or (at your option) any later version.
9 *
10 * This library is distributed in the hope that it will be useful,
11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
13 * Lesser General Public License for more details.
14 *
15 * You should have received a copy of the GNU Lesser General Public
16 * License along with this library; if not, see <http://www.gnu.org/licenses/>.
17 *
18 * Author: Ryan Lortie <desrt@desrt.ca>
19 */
25 #include <glib/gtestutils.h>
26 #include <glib/gthread.h>
27 #include <glib/gslice.h>
28 #include <glib/ghash.h>
30 /* < private >
31 * GVariantTypeInfo:
32 *
33 * This structure contains the necessary information to facilitate the
34 * serialisation and fast deserialisation of a given type of GVariant
35 * value. A GVariant instance holds a pointer to one of these
36 * structures to provide for efficient operation.
37 *
38 * The GVariantTypeInfo structures for all of the base types, plus the
39 * "variant" type are stored in a read-only static array.
40 *
41 * For container types, a hash table and reference counting is used to
42 * ensure that only one of these structures exists for any given type.
43 * In general, a container GVariantTypeInfo will exist for a given type
44 * only if one or more GVariant instances of that type exist or if
45 * another GVariantTypeInfo has that type as a subtype. For example, if
46 * a process contains a single GVariant instance with type "(asv)", then
47 * container GVariantTypeInfo structures will exist for "(asv)" and
48 * for "as" (note that "s" and "v" always exist in the static array).
49 *
50 * The trickiest part of GVariantTypeInfo (and in fact, the major reason
51 * for its existence) is the storage of somewhat magical constants that
52 * allow for O(1) lookups of items in tuples. This is described below.
53 *
54 * 'container_class' is set to 'a' or 'r' if the GVariantTypeInfo is
55 * contained inside of an ArrayInfo or TupleInfo, respectively. This
56 * allows the storage of the necessary additional information.
57 *
58 * 'fixed_size' is set to the fixed size of the type, if applicable, or
59 * 0 otherwise (since no type has a fixed size of 0).
60 *
61 * 'alignment' is set to one less than the alignment requirement for
62 * this type. This makes many operations much more convenient.
63 */
64 struct _GVariantTypeInfo
65 {
66 gsize fixed_size;
67 guchar alignment;
68 guchar container_class;
69 };
71 /* Container types are reference counted. They also need to have their
72 * type string stored explicitly since it is not merely a single letter.
73 */
75 {
76 GVariantTypeInfo info;
79 gint ref_count;
82 /* For 'array' and 'maybe' types, we store some extra information on the
83 * end of the GVariantTypeInfo struct -- the element type (ie: "s" for
84 * "as"). The container GVariantTypeInfo structure holds a reference to
85 * the element typeinfo.
86 */
88 {
89 ContainerInfo container;
94 /* For 'tuple' and 'dict entry' types, we store extra information for
95 * each member -- its type and how to find it inside the serialised data
96 * in O(1) time using 4 variables -- 'i', 'a', 'b', and 'c'. See the
97 * comment on GVariantMemberInfo in gvarianttypeinfo.h.
98 */
100 {
101 ContainerInfo container;
104 gsize n_members;
108 /* Hard-code the base types in a constant array */
110 #define fixed_aligned(x) x, x - 1
111 #define not_a_type 0,
112 #define unaligned 0, 0
113 #define aligned(x) 0, x - 1
138 #undef fixed_aligned
139 #undef not_a_type
140 #undef unaligned
141 #undef aligned
142 };
144 /* We need to have type strings to return for the base types. We store
145 * those in another array. Since all base type strings are single
146 * characters this is easy. By not storing pointers to strings into the
147 * GVariantTypeInfo itself, we save a bunch of relocations.
148 */
152 };
154 /* sanity checks to make debugging easier */
155 static void
158 {
161 /* alignment can only be one of these */
166 {
169 /* extra checks for containers */
172 }
173 else
174 {
175 gint index;
177 /* if not a container, then ensure that it is a valid member of
178 * the basic types table
179 */
186 }
187 }
189 /* < private >
190 * g_variant_type_info_get_type_string:
191 * @info: a #GVariantTypeInfo
192 *
193 * Gets the type string for @info. The string is nul-terminated.
194 */
197 {
201 {
204 /* containers have their type string stored inside them */
206 }
207 else
208 {
209 gint index;
211 /* look up the type string in the base type array. the call to
212 * g_variant_type_info_check() above already ensured validity.
213 */
217 }
218 }
220 /* < private >
221 * g_variant_type_info_query:
222 * @info: a #GVariantTypeInfo
223 * @alignment: (nullable): the location to store the alignment, or %NULL
224 * @fixed_size: (nullable): the location to store the fixed size, or %NULL
225 *
226 * Queries @info to determine the alignment requirements and fixed size
227 * (if any) of the type.
228 *
229 * @fixed_size, if non-%NULL is set to the fixed size of the type, or 0
230 * to indicate that the type is a variable-sized type. No type has a
231 * fixed size of 0.
232 *
233 * @alignment, if non-%NULL, is set to one less than the required
234 * alignment of the type. For example, for a 32bit integer, @alignment
235 * would be set to 3. This allows you to round an integer up to the
236 * proper alignment by performing the following efficient calculation:
237 *
238 * offset += ((-offset) & alignment);
239 */
240 void
244 {
252 }
254 /* == array == */
258 {
262 }
264 static void
266 {
274 }
278 {
289 }
291 /* < private >
292 * g_variant_type_info_element:
293 * @info: a #GVariantTypeInfo for an array or maybe type
294 *
295 * Returns the element type for the array or maybe type. A reference is
296 * not added, so the caller must add their own.
297 */
298 GVariantTypeInfo *
300 {
302 }
304 /* < private >
305 * g_variant_type_query_element:
306 * @info: a #GVariantTypeInfo for an array or maybe type
307 * @alignment: (nullable): the location to store the alignment, or %NULL
308 * @fixed_size: (nullable): the location to store the fixed size, or %NULL
309 *
310 * Returns the alignment requires and fixed size (if any) for the
311 * element type of the array. This call is a convenience wrapper around
312 * g_variant_type_info_element() and g_variant_type_info_query().
313 */
314 void
318 {
321 }
323 /* == tuple == */
327 {
331 }
333 static void
335 {
337 gint i;
348 }
350 static void
354 {
363 {
373 else
375 }
378 }
380 /* this is g_variant_type_info_query for a given member of the tuple.
381 * before the access is done, it is ensured that the item is within
382 * range and %FALSE is returned if not.
383 */
384 static gboolean
389 {
396 }
398 /* Read the documentation for #GVariantMemberInfo in gvarianttype.h
399 * before attempting to understand this.
400 *
401 * This function adds one set of "magic constant" values (for one item
402 * in the tuple) to the table.
403 *
404 * The algorithm in tuple_generate_table() calculates values of 'a', 'b'
405 * and 'c' for each item, such that the procedure for finding the item
406 * is to start at the end of the previous variable-sized item, add 'a',
407 * then round up to the nearest multiple of 'b', then then add 'c'.
408 * Note that 'b' is stored in the usual "one less than" form. ie:
409 *
410 * start = ROUND_UP(prev_end + a, (b + 1)) + c;
411 *
412 * We tweak these values a little to allow for a slightly easier
413 * computation and more compact storage.
414 */
415 static void
417 gsize i,
418 gsize a,
419 gsize b,
420 gsize c)
421 {
424 /* We can shift multiples of the alignment size from 'c' into 'a'.
425 * As long as we're shifting whole multiples, it won't affect the
426 * result. This means that we can take the "aligned" portion off of
427 * 'c' and add it into 'a'.
428 *
429 * Imagine (for sake of clarity) that ROUND_10 rounds up to the
430 * nearest 10. It is clear that:
431 *
432 * ROUND_10(a) + c == ROUND_10(a + 10*(c / 10)) + (c % 10)
433 *
434 * ie: remove the 10s portion of 'c' and add it onto 'a'.
435 *
436 * To put some numbers on it, imagine we start with a = 34 and c = 27:
437 *
438 * ROUND_10(34) + 27 = 40 + 27 = 67
439 *
440 * but also, we can split 27 up into 20 and 7 and do this:
441 *
442 * ROUND_10(34 + 20) + 7 = ROUND_10(54) + 7 = 60 + 7 = 67
443 * ^^ ^
444 * without affecting the result. We do that here.
445 *
446 * This reduction in the size of 'c' means that we can store it in a
447 * gchar instead of a gsize. Due to how the structure is packed, this
448 * ends up saving us 'two pointer sizes' per item in each tuple when
449 * allocating using GSlice.
450 */
455 /* Finally, we made one last adjustment. Recall:
456 *
457 * start = ROUND_UP(prev_end + a, (b + 1)) + c;
458 *
459 * Forgetting the '+ c' for the moment:
460 *
461 * ROUND_UP(prev_end + a, (b + 1));
462 *
463 * we can do a "round up" operation by adding 1 less than the amount
464 * to round up to, then rounding down. ie:
465 *
466 * #define ROUND_UP(x, y) ROUND_DOWN(x + (y-1), y)
467 *
468 * Of course, for rounding down to a power of two, we can just mask
469 * out the appropriate number of low order bits:
470 *
471 * #define ROUND_DOWN(x, y) (x & ~(y - 1))
472 *
473 * Which gives us
474 *
475 * #define ROUND_UP(x, y) (x + (y - 1) & ~(y - 1))
476 *
477 * but recall that our alignment value 'b' is already "one less".
478 * This means that to round 'prev_end + a' up to 'b' we can just do:
479 *
480 * ((prev_end + a) + b) & ~b
481 *
482 * Associativity, and putting the 'c' back on:
483 *
484 * (prev_end + (a + b)) & ~b + c
485 *
486 * Now, since (a + b) is constant, we can just add 'b' to 'a' now and
487 * store that as the number to add to prev_end. Then we use ~b as the
488 * number to take a bitwise 'and' with. Finally, 'c' is added on.
489 *
490 * Note, however, that all the low order bits of the 'aligned' value
491 * are masked out and that all of the high order bits of 'c' have been
492 * "moved" to 'a' (in the previous step). This means that there are
493 * no overlapping bits in the addition -- so we can do a bitwise 'or'
494 * equivalently.
495 *
496 * This means that we can now compute the start address of a given
497 * item in the tuple using the algorithm given in the documentation
498 * for #GVariantMemberInfo:
499 *
500 * item_start = ((prev_end + a) & b) | c;
501 */
507 }
509 static gsize
511 guint alignment)
512 {
514 }
516 /* This function is the heart of the algorithm for calculating 'i', 'a',
517 * 'b' and 'c' for each item in the tuple.
518 *
519 * Imagine we want to find the start of the "i" in the type "(su(qx)ni)".
520 * That's a string followed by a uint32, then a tuple containing a
521 * uint16 and a int64, then an int16, then our "i". In order to get to
522 * our "i" we:
523 *
524 * Start at the end of the string, align to 4 (for the uint32), add 4.
525 * Align to 8, add 16 (for the tuple). Align to 2, add 2 (for the
526 * int16). Then we're there. It turns out that, given 3 simple rules,
527 * we can flatten this iteration into one addition, one alignment, then
528 * one more addition.
529 *
530 * The loop below plays through each item in the tuple, querying its
531 * alignment and fixed_size into 'd' and 'e', respectively. At all
532 * times the variables 'a', 'b', and 'c' are maintained such that in
533 * order to get to the current point, you add 'a', align to 'b' then add
534 * 'c'. 'b' is kept in "one less than" form. For each item, the proper
535 * alignment is applied to find the values of 'a', 'b' and 'c' to get to
536 * the start of that item. Those values are recorded into the table.
537 * The fixed size of the item (if applicable) is then added on.
538 *
539 * These 3 rules are how 'a', 'b' and 'c' are modified for alignment and
540 * addition of fixed size. They have been proven correct but are
541 * presented here, without proof:
542 *
543 * 1) in order to "align to 'd'" where 'd' is less than or equal to the
544 * largest level of alignment seen so far ('b'), you align 'c' to
545 * 'd'.
546 * 2) in order to "align to 'd'" where 'd' is greater than the largest
547 * level of alignment seen so far, you add 'c' aligned to 'b' to the
548 * value of 'a', set 'b' to 'd' (ie: increase the 'largest alignment
549 * seen') and reset 'c' to 0.
550 * 3) in order to "add 'e'", just add 'e' to 'c'.
551 */
552 static void
554 {
558 /* iterate over each item in the tuple.
559 * 'd' will be the alignment of the item (in one-less form)
560 * 'e' will be the fixed size (or 0 for variable-size items)
561 */
563 {
564 /* align to 'd' */
567 else
570 /* the start of the item is at this point (ie: right after we
571 * have aligned for it). store this information in the table.
572 */
575 /* "move past" the item by adding in its size. */
577 /* variable size:
578 *
579 * we'll have an offset stored to mark the end of this item, so
580 * just bump the offset index to give us a new starting point
581 * and reset all the counters.
582 */
584 else
585 /* fixed size */
587 }
588 }
590 static void
592 {
596 {
599 /* the alignment requirement of the tuple is the alignment
600 * requirement of its largest item.
601 */
604 /* can find the max of a list of "one less than" powers of two
605 * by 'or'ing them
606 */
611 /* the structure only has a fixed size if no variable-size
612 * offsets are stored and the last item is fixed-sized too (since
613 * an offset is never stored for the last item).
614 */
616 /* in that case, the fixed size can be found by finding the
617 * start of the last item (in the usual way) and adding its
618 * fixed size.
619 *
620 * if a tuple has a fixed size then it is always a multiple of
621 * the alignment requirement (to make packing into arrays
622 * easier) so we round up to that here.
623 */
627 else
628 /* else, the tuple is not fixed size */
630 }
631 else
632 {
633 /* the empty tuple: '()'.
634 *
635 * has a size of 1 and an no alignment requirement.
636 *
637 * It has a size of 1 (not 0) for two practical reasons:
638 *
639 * 1) So we can determine how many of them are in an array
640 * without dividing by zero or without other tricks.
641 *
642 * 2) Even if we had some trick to know the number of items in
643 * the array (as GVariant did at one time) this would open a
644 * potential denial of service attack: an attacker could send
645 * you an extremely small array (in terms of number of bytes)
646 * containing trillions of zero-sized items. If you iterated
647 * over this array you would effectively infinite-loop your
648 * program. By forcing a size of at least one, we bound the
649 * amount of computation done in response to a message to a
650 * reasonable function of the size of that message.
651 */
654 }
655 }
659 {
670 }
672 /* < private >
673 * g_variant_type_info_n_members:
674 * @info: a #GVariantTypeInfo for a tuple or dictionary entry type
675 *
676 * Returns the number of members in a tuple or dictionary entry type.
677 * For a dictionary entry this will always be 2.
678 */
679 gsize
681 {
683 }
685 /* < private >
686 * g_variant_type_info_member_info:
687 * @info: a #GVariantTypeInfo for a tuple or dictionary entry type
688 * @index: the member to fetch information for
689 *
690 * Returns the #GVariantMemberInfo for a given member. See
691 * documentation for that structure for why you would want this
692 * information.
693 *
694 * @index must refer to a valid child (ie: strictly less than
695 * g_variant_type_info_n_members() returns).
696 */
699 gsize index)
700 {
707 }
709 /* == new/ref/unref == */
713 /* < private >
714 * g_variant_type_info_get:
715 * @type: a #GVariantType
716 *
717 * Returns a reference to a #GVariantTypeInfo for @type.
718 *
719 * If an info structure already exists for this type, a new reference is
720 * returned. If not, the required calculations are performed and a new
721 * info structure is returned.
722 *
723 * It is appropriate to call g_variant_type_info_unref() on the return
724 * value.
725 */
726 GVariantTypeInfo *
728 {
737 {
747 g_str_equal);
751 {
756 {
758 }
760 {
762 }
770 }
771 else
779 }
780 else
781 {
794 }
795 }
797 /* < private >
798 * g_variant_type_info_ref:
799 * @info: a #GVariantTypeInfo
800 *
801 * Adds a reference to @info.
802 */
803 GVariantTypeInfo *
805 {
809 {
814 }
817 }
819 /* < private >
820 * g_variant_type_info_unref:
821 * @info: a #GVariantTypeInfo
822 *
823 * Releases a reference held on @info. This may result in @info being
824 * freed.
825 */
826 void
828 {
832 {
837 {
841 {
844 }
855 else
857 }
858 else
860 }
861 }
863 void
865 {
867 }