| blob | bf8a978c06247ab176f805965b127e78a6d6c03f |
1 /* C-compiler utilities for types and variables storage layout
2 Copyright (C) 1987-2016 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it under
7 the terms of the GNU General Public License as published by the Free
8 Software Foundation; either version 3, or (at your option) any later
9 version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
44 /* Data type for the expressions representing sizes of data types.
45 It is the first integer type laid out. */
48 /* If nonzero, this is an upper limit on alignment of structure fields.
49 The value is measured in bits. */
59 \f
60 /* Given a size SIZE that may not be a constant, return a SAVE_EXPR
61 to serve as the actual size-expression for a type or decl. */
63 tree
65 {
66 /* Obviously. */
70 /* If the size is self-referential, we can't make a SAVE_EXPR (see
71 save_expr for the rationale). But we can do something else. */
75 /* If we are in the global binding level, we can't make a SAVE_EXPR
76 since it may end up being shared across functions, so it is up
77 to the front-end to deal with this case. */
82 }
84 /* An array of functions used for self-referential size computation. */
87 /* Return true if T is a self-referential component reference. */
89 static bool
91 {
99 }
101 /* Similar to copy_tree_r but do not copy component references involving
102 PLACEHOLDER_EXPRs. These nodes are spotted in find_placeholder_in_expr
103 and substituted in substitute_in_expr. */
105 static tree
107 {
110 /* Stop at types, decls, constants like copy_tree_r. */
114 {
117 }
119 /* This is the pattern built in ada/make_aligning_type. */
122 {
125 }
127 /* Default case: the component reference. */
129 {
132 }
134 /* We're not supposed to have them in self-referential size trees
135 because we wouldn't properly control when they are evaluated.
136 However, not creating superfluous SAVE_EXPRs requires accurate
137 tracking of readonly-ness all the way down to here, which we
138 cannot always guarantee in practice. So punt in this case. */
146 }
148 /* Given a SIZE expression that is self-referential, return an equivalent
149 expression to serve as the actual size expression for a type. */
151 static tree
153 {
162 /* Do not factor out simple operations. */
167 /* Collect the list of self-references in the expression. */
171 /* Obtain a private copy of the expression. */
177 /* Build the parameter and argument lists in parallel; also
178 substitute the former for the latter in the expression. */
181 {
185 {
186 /* We shouldn't have true variables here. */
189 }
190 /* This is the pattern built in ada/make_aligning_type. */
193 /* Default case: the component reference. */
194 else
200 param_decl
211 }
215 /* Append 'void' to indicate that the number of parameters is fixed. */
218 /* The 3 lists have been created in reverse order. */
222 /* Build the function type. */
226 /* Build the function declaration. */
237 /* The function has been created by the compiler and we don't
238 want to emit debug info for it. */
242 /* It is supposed to be "const" and never throw. */
246 /* We want it to be inlined when this is deemed profitable, as
247 well as discarded if every call has been integrated. */
250 /* It is made up of a unique return statement. */
257 /* Put it onto the list of size functions. */
260 /* Replace the original expression with a call to the size function. */
262 }
264 /* Take, queue and compile all the size functions. It is essential that
265 the size functions be gimplified at the very end of the compilation
266 in order to guarantee transparent handling of self-referential sizes.
267 Otherwise the GENERIC inliner would not be able to inline them back
268 at each of their call sites, thus creating artificial non-constant
269 size expressions which would trigger nasty problems later on. */
271 void
273 {
275 tree fndecl;
278 {
283 /* As these functions are used to describe the layout of variable-length
284 structures, debug info generation needs their implementation. */
288 }
291 }
292 \f
293 /* Return the machine mode to use for a nonscalar of SIZE bits. The
294 mode must be in class MCLASS, and have exactly that many value bits;
295 it may have padding as well. If LIMIT is nonzero, modes of wider
296 than MAX_FIXED_MODE_SIZE will not be used. */
298 machine_mode
300 {
301 machine_mode mode;
307 /* Get the first mode which has this size, in the specified class. */
320 }
322 /* Similar, except passed a tree node. */
324 machine_mode
326 {
337 }
339 /* Similar, but never return BLKmode; return the narrowest mode that
340 contains at least the requested number of value bits. */
342 machine_mode
344 {
348 /* Get the first mode which has at least this size, in the
349 specified class. */
366 }
368 /* Find an integer mode of the exact same size, or BLKmode on failure. */
370 machine_mode
372 {
374 {
401 /* ... fall through ... */
406 }
409 }
411 /* Find a mode that can be used for efficient bitwise operations on MODE.
412 Return BLKmode if no such mode exists. */
414 machine_mode
416 {
417 /* Quick exit if we already have a suitable mode. */
422 /* Reuse the sanity checks from int_mode_for_mode. */
425 /* Try to replace complex modes with complex modes. In general we
426 expect both components to be processed independently, so we only
427 care whether there is a register for the inner mode. */
429 {
436 }
438 /* Try to replace vector modes with vector modes. Also try using vector
439 modes if an integer mode would be too big. */
441 {
449 }
451 /* Otherwise fall back on integers while honoring MAX_FIXED_MODE_SIZE. */
453 }
455 /* Find a type that can be used for efficient bitwise operations on MODE.
456 Return null if no such mode exists. */
458 tree
460 {
476 }
478 /* Find a mode that is suitable for representing a vector with
479 NUNITS elements of mode INNERMODE. Returns BLKmode if there
480 is no suitable mode. */
482 machine_mode
484 {
485 machine_mode mode;
487 /* First, look for a supported vector type. */
498 else
501 /* Do not check vector_mode_supported_p here. We'll do that
502 later in vector_type_mode. */
508 /* For integers, try mapping it to a same-sized scalar mode. */
520 }
522 /* Return the alignment of MODE. This will be bounded by 1 and
523 BIGGEST_ALIGNMENT. */
525 unsigned int
527 {
529 }
531 /* Return the natural mode of an array, given that it is SIZE bytes in
532 total and has elements of type ELEM_TYPE. */
534 static machine_mode
536 {
537 tree elem_size;
541 /* One-element arrays get the component type's mode. */
548 {
556 }
558 }
559 \f
560 /* Subroutine of layout_decl: Force alignment required for the data type.
561 But if the decl itself wants greater alignment, don't override that. */
565 {
567 {
571 }
572 }
574 /* Set the size, mode and alignment of a ..._DECL node.
575 TYPE_DECL does need this for C++.
576 Note that LABEL_DECL and CONST_DECL nodes do not need this,
577 and FUNCTION_DECL nodes have them set up in a special (and simple) way.
578 Don't call layout_decl for them.
580 KNOWN_ALIGN is the amount of alignment we can assume this
581 decl has with no special effort. It is relevant only for FIELD_DECLs
582 and depends on the previous fields.
583 All that matters about KNOWN_ALIGN is which powers of 2 divide it.
584 If KNOWN_ALIGN is 0, it means, "as much alignment as you like":
585 the record will be aligned to suit. */
587 void
589 {
606 /* Usually the size and mode come from the data type without change,
607 however, the front-end may set the explicit width of the field, so its
608 size may not be the same as the size of its type. This happens with
609 bitfields, of course (an `int' bitfield may be only 2 bits, say), but it
610 also happens with other fields. For example, the C++ front-end creates
611 zero-sized fields corresponding to empty base classes, and depends on
612 layout_type setting DECL_FIELD_BITPOS correctly for the field. Set the
613 size in bytes from the size in bits. If we have already set the mode,
614 don't set it again since we can be called twice for FIELD_DECLs. */
621 {
624 }
629 bitsize_unit_node));
632 /* For non-fields, update the alignment from the type. */
634 else
635 /* For fields, it's a bit more complicated... */
636 {
643 {
646 /* A zero-length bit-field affects the alignment of the next
647 field. In essence such bit-fields are not influenced by
648 any packing due to #pragma pack or attribute packed. */
651 {
656 else
657 {
658 #ifdef EMPTY_FIELD_BOUNDARY
660 {
663 }
664 #endif
665 }
666 }
668 /* See if we can use an ordinary integer mode for a bit-field.
669 Conditions are: a fixed size that is correct for another mode,
670 occupying a complete byte or bytes on proper boundary. */
674 {
675 machine_mode xmode
682 {
686 }
687 }
689 /* Turn off DECL_BIT_FIELD if we won't need it set. */
694 }
696 /* Don't touch DECL_ALIGN. For other packed fields, go ahead and
697 round up; we'll reduce it again below. We want packing to
698 supersede USER_ALIGN inherited from the type, but defer to
700 else
703 /* If the field is packed and not explicitly aligned, give it the
704 minimum alignment. Note that do_type_align may set
705 DECL_USER_ALIGN, so we need to check old_user_align instead. */
711 {
712 /* Some targets (i.e. i386, VMS) limit struct field alignment
713 to a lower boundary than alignment of variables unless
714 it was overridden by attribute aligned. */
715 #ifdef BIGGEST_FIELD_ALIGNMENT
718 #endif
719 #ifdef ADJUST_FIELD_ALIGN
721 #endif
722 }
726 else
728 /* Should this be controlled by DECL_USER_ALIGN, too? */
731 }
733 /* Evaluate nonconstant size only once, either now or as soon as safe. */
740 /* If requested, warn about definitions of large data objects. */
744 {
749 {
754 else
757 }
758 }
760 /* If the RTL was already set, update its mode and mem attributes. */
762 {
768 }
769 }
771 /* Given a VAR_DECL, PARM_DECL or RESULT_DECL, clears the results of
772 a previous call to layout_decl and calls it again. */
774 void
776 {
784 }
785 \f
786 /* Begin laying out type T, which may be a RECORD_TYPE, UNION_TYPE, or
787 QUAL_UNION_TYPE. Return a pointer to a struct record_layout_info which
788 is to be passed to all other layout functions for this record. It is the
789 responsibility of the caller to call `free' for the storage returned.
790 Note that garbage collection is not permitted until we finish laying
791 out the record. */
793 record_layout_info
795 {
800 /* If the type has a minimum specified alignment (via an attribute
801 declaration, for example) use it -- otherwise, start with a
802 one-byte alignment. */
807 #ifdef STRUCTURE_SIZE_BOUNDARY
808 /* Packed structures don't need to have minimum size. */
810 {
813 /* #pragma pack overrides STRUCTURE_SIZE_BOUNDARY. */
818 }
819 #endif
829 }
831 /* Return the combined bit position for the byte offset OFFSET and the
832 bit position BITPOS.
834 These functions operate on byte and bit positions present in FIELD_DECLs
835 and assume that these expressions result in no (intermediate) overflow.
836 This assumption is necessary to fold the expressions as much as possible,
837 so as to avoid creating artificially variable-sized types in languages
838 supporting variable-sized types like Ada. */
840 tree
842 {
847 else
851 }
853 /* Return the combined truncated byte position for the byte offset OFFSET and
854 the bit position BITPOS. */
856 tree
858 {
859 tree bytepos;
863 else
866 }
868 /* Split the bit position POS into a byte offset *POFFSET and a bit
869 position *PBITPOS with the byte offset aligned to OFF_ALIGN bits. */
871 void
873 tree pos)
874 {
878 {
883 }
884 else
885 {
889 toff_align)),
892 }
893 }
895 /* Given a pointer to bit and byte offsets and an offset alignment,
896 normalize the offsets so they are within the alignment. */
898 void
900 {
901 /* If the bit position is now larger than it should be, adjust it
902 downwards. */
904 {
909 }
910 }
912 /* Print debugging information about the information in RLI. */
914 DEBUG_FUNCTION void
916 {
925 /* The ms_struct code is the only that uses this. */
933 {
936 }
937 }
939 /* Given an RLI with a possibly-incremented BITPOS, adjust OFFSET and
940 BITPOS if necessary to keep BITPOS below OFFSET_ALIGN. */
942 void
944 {
946 }
948 /* Returns the size in bytes allocated so far. */
950 tree
952 {
954 }
956 /* Returns the size in bits allocated so far. */
958 tree
960 {
962 }
964 /* FIELD is about to be added to RLI->T. The alignment (in bits) of
965 the next available location within the record is given by KNOWN_ALIGN.
966 Update the variable alignment fields in RLI, and return the alignment
967 to give the FIELD. */
969 unsigned int
972 {
973 /* The alignment required for FIELD. */
975 /* The type of this field. */
977 /* True if the field was explicitly aligned by the user. */
981 /* Do not attempt to align an ERROR_MARK node */
985 /* Lay out the field so we know what alignment it needs. */
994 /* Record must have at least as much alignment as any field.
995 Otherwise, the alignment of the field within the record is
996 meaningless. */
998 {
999 /* Here, the alignment of the underlying type of a bitfield can
1000 affect the alignment of a record; even a zero-sized field
1001 can do this. The alignment should be to the alignment of
1002 the type, except that for zero-size bitfields this only
1003 applies if there was an immediately prior, nonzero-size
1004 bitfield. (That's the way it is, experimentally.) */
1012 {
1019 }
1020 }
1022 {
1023 /* Named bit-fields cause the entire structure to have the
1024 alignment implied by their type. Some targets also apply the same
1025 rules to unnamed bitfields. */
1028 {
1031 #ifdef ADJUST_FIELD_ALIGN
1034 #endif
1036 /* Targets might chose to handle unnamed and hence possibly
1037 zero-width bitfield. Those are not influenced by #pragmas
1038 or packed attributes. */
1040 {
1044 }
1050 /* The alignment of the record is increased to the maximum
1051 of the current alignment, the alignment indicated on the
1052 field (i.e., the alignment specified by an __aligned__
1053 attribute), and the alignment indicated by the type of
1054 the field. */
1061 }
1062 }
1063 else
1064 {
1067 }
1072 }
1074 /* Called from place_field to handle unions. */
1076 static void
1078 {
1085 /* If this is an ERROR_MARK return *after* having set the
1086 field at the start of the union. This helps when parsing
1087 invalid fields. */
1091 /* We assume the union's size will be a multiple of a byte so we don't
1092 bother with BITPOS. */
1098 }
1100 /* A bitfield of SIZE with a required access alignment of ALIGN is allocated
1101 at BYTE_OFFSET / BIT_OFFSET. Return nonzero if the field would span more
1102 units of alignment than the underlying TYPE. */
1103 static int
1106 {
1107 /* Note that the calculation of OFFSET might overflow; we calculate it so
1108 that we still get the right result as long as ALIGN is a power of two. */
1114 }
1116 /* RLI contains information about the layout of a RECORD_TYPE. FIELD
1117 is a FIELD_DECL to be added after those fields already present in
1118 T. (FIELD is not actually added to the TYPE_FIELDS list here;
1119 callers that desire that behavior must manually perform that step.) */
1121 void
1123 {
1124 /* The alignment required for FIELD. */
1126 /* The alignment FIELD would have if we just dropped it into the
1127 record as it presently stands. */
1130 /* The type of this field. */
1135 /* If FIELD is static, then treat it like a separate variable, not
1136 really like a structure field. If it is a FUNCTION_DECL, it's a
1137 method. In both cases, all we do is lay out the decl, and we do
1138 it *after* the record is laid out. */
1140 {
1143 }
1145 /* Enumerators and enum types which are local to this class need not
1146 be laid out. Likewise for initialized constant fields. */
1150 /* Unions are laid out very differently than records, so split
1151 that code off to another function. */
1153 {
1156 }
1159 {
1160 /* Place this field at the current allocation position, so we
1161 maintain monotonicity. */
1166 }
1168 /* Work out the known alignment so far. Note that A & (-A) is the
1169 value of the least-significant bit in A that is one. */
1176 known_align = (BITS_PER_UNIT
1179 else
1187 {
1189 {
1191 {
1195 /* Don't warn if DECL_PACKED was set by the type. */
1199 }
1200 }
1201 else
1203 }
1205 /* Does this field automatically have alignment it needs by virtue
1206 of the fields that precede it and the record's own alignment? */
1208 {
1209 /* No, we need to skip space before this field.
1210 Bump the cumulative size to multiple of field alignment. */
1216 /* If the alignment is still within offset_align, just align
1217 the bit position. */
1220 else
1221 {
1222 /* First adjust OFFSET by the partial bits, then align. */
1223 rli->offset
1227 bitsize_unit_node)));
1231 }
1237 }
1239 /* Handle compatibility with PCC. Note that if the record has any
1240 variable-sized fields, we need not worry about compatibility. */
1247 /* Enter for these packed fields only to issue a warning. */
1254 {
1261 #ifdef ADJUST_FIELD_ALIGN
1264 #endif
1266 /* A bit field may not span more units of alignment of its type
1267 than its type itself. Advance to next boundary if necessary. */
1269 {
1271 {
1273 inform
1276 field);
1277 }
1278 else
1280 }
1284 }
1286 #ifdef BITFIELD_NBYTES_LIMITED
1297 {
1304 #ifdef ADJUST_FIELD_ALIGN
1307 #endif
1311 /* ??? This test is opposite the test in the containing if
1312 statement, so this code is unreachable currently. */
1316 /* A bit field may not span the unit of alignment of its type.
1317 Advance to next boundary if necessary. */
1322 }
1323 #endif
1325 /* See the docs for TARGET_MS_BITFIELD_LAYOUT_P for details.
1326 A subtlety:
1327 When a bit field is inserted into a packed record, the whole
1328 size of the underlying type is used by one or more same-size
1329 adjacent bitfields. (That is, if its long:3, 32 bits is
1330 used in the record, and any additional adjacent long bitfields are
1331 packed into the same chunk of 32 bits. However, if the size
1332 changes, a new field of that size is allocated.) In an unpacked
1333 record, this is the same as using alignment, but not equivalent
1334 when packing.
1336 Note: for compatibility, we use the type size, not the type alignment
1337 to determine alignment, since that matches the documentation */
1340 {
1344 /* This is a bitfield if it exists. */
1346 {
1347 /* If both are bitfields, nonzero, and the same size, this is
1348 the middle of a run. Zero declared size fields are special
1349 and handled as "end of run". (Note: it's nonzero declared
1350 size, but equal type sizes!) (Since we know that both
1351 the current and previous fields are bitfields by the
1352 time we check it, DECL_SIZE must be present for both.) */
1359 {
1360 /* We're in the middle of a run of equal type size fields; make
1361 sure we realign if we run out of bits. (Not decl size,
1362 type size!) */
1366 {
1369 /* out of bits; bump up to next 'word'. */
1370 rli->bitpos
1376 else
1378 }
1379 else
1381 }
1382 else
1383 {
1384 /* End of a run: if leaving a run of bitfields of the same type
1385 size, we have to "use up" the rest of the bits of the type
1386 size.
1388 Compute the new position as the sum of the size for the prior
1389 type and where we first started working on that type.
1390 Note: since the beginning of the field was aligned then
1391 of course the end will be too. No round needed. */
1394 {
1395 rli->bitpos
1398 }
1399 else
1400 /* We "use up" size zero fields; the code below should behave
1401 as if the prior field was not a bitfield. */
1404 /* Cause a new bitfield to be captured, either this time (if
1405 currently a bitfield) or next time we see one. */
1409 }
1412 }
1414 /* If we're starting a new run of same type size bitfields
1415 (or a run of non-bitfields), set up the "first of the run"
1416 fields.
1418 That is, if the current field is not a bitfield, or if there
1419 was a prior bitfield the type sizes differ, or if there wasn't
1420 a prior bitfield the size of the current field is nonzero.
1422 Note: we must be sure to test ONLY the type size if there was
1423 a prior bitfield and ONLY for the current field being zero if
1424 there wasn't. */
1430 {
1431 /* Never smaller than a byte for compatibility. */
1434 /* (When not a bitfield), we could be seeing a flex array (with
1435 no DECL_SIZE). Since we won't be using remaining_in_alignment
1436 until we see a bitfield (and come by here again) we just skip
1437 calculating it. */
1441 {
1442 unsigned HOST_WIDE_INT bitsize
1444 unsigned HOST_WIDE_INT typesize
1449 else
1451 }
1453 /* Now align (conventionally) for the new type. */
1461 /* If we really aligned, don't allow subsequent bitfields
1462 to undo that. */
1464 }
1465 }
1467 /* Offset so far becomes the position of this field after normalizing. */
1473 /* Evaluate nonconstant offsets only once, either now or as soon as safe. */
1477 /* If this field ended up more aligned than we thought it would be (we
1478 approximate this by seeing if its position changed), lay out the field
1479 again; perhaps we can use an integral mode for it now. */
1486 actual_align = (BITS_PER_UNIT
1489 else
1491 /* ACTUAL_ALIGN is still the actual alignment *within the record* .
1492 store / extract bit field operations will check the alignment of the
1493 record against the mode of bit fields. */
1501 /* Now add size of this field to the size of the record. If the size is
1502 not constant, treat the field as being a multiple of bytes and just
1503 adjust the offset, resetting the bit position. Otherwise, apportion the
1504 size amongst the bit position and offset. First handle the case of an
1505 unspecified size, which can happen when we have an invalid nested struct
1506 definition, such as struct j { struct j { int i; } }. The error message
1507 is printed in finish_struct. */
1512 {
1513 rli->offset
1517 bitsize_unit_node)));
1518 rli->offset
1522 }
1524 {
1527 /* If we ended a bitfield before the full length of the type then
1528 pad the struct out to the full length of the last type. */
1537 }
1538 else
1539 {
1542 }
1543 }
1545 /* Assuming that all the fields have been laid out, this function uses
1546 RLI to compute the final TYPE_SIZE, TYPE_ALIGN, etc. for the type
1547 indicated by RLI. */
1549 static void
1551 {
1554 /* Now we want just byte and bit offsets, so set the offset alignment
1555 to be a byte and then normalize. */
1559 /* Determine the desired alignment. */
1560 #ifdef ROUND_TYPE_ALIGN
1563 #else
1565 #endif
1567 /* Compute the size so far. Be sure to allow for extra bits in the
1568 size in bytes. We have guaranteed above that it will be no more
1569 than a single byte. */
1573 unpadded_size_unit
1576 /* Round the size up to be a multiple of the required alignment. */
1589 {
1590 tree unpacked_size;
1592 #ifdef ROUND_TYPE_ALIGN
1593 rli->unpacked_align
1595 #else
1597 #endif
1601 {
1603 {
1604 tree name;
1608 else
1614 else
1617 }
1618 else
1619 {
1623 else
1625 }
1626 }
1627 }
1628 }
1630 /* Compute the TYPE_MODE for the TYPE (which is a RECORD_TYPE). */
1632 void
1634 {
1635 tree field;
1638 /* Most RECORD_TYPEs have BLKmode, so we start off assuming that.
1639 However, if possible, we use a mode that fits in a register
1640 instead, in order to allow for better optimization down the
1641 line. */
1647 /* A record which has any BLKmode members must itself be
1648 BLKmode; it can't go in a register. Unless the member is
1649 BLKmode only because it isn't aligned. */
1651 {
1665 /* If this field is the whole struct, remember its mode so
1666 that, say, we can put a double in a class into a DF
1667 register instead of forcing it to live in the stack. */
1671 /* With some targets, it is sub-optimal to access an aligned
1672 BLKmode structure as a scalar. */
1675 }
1677 /* If we only have one real field; use its mode if that mode's size
1678 matches the type's size. This only applies to RECORD_TYPE. This
1679 does not apply to unions. */
1684 else
1687 /* If structure's known alignment is less than what the scalar
1688 mode would need, and it matters, then stick with BLKmode. */
1690 && STRICT_ALIGNMENT
1693 {
1694 /* If this is the only reason this type is BLKmode, then
1695 don't force containing types to be BLKmode. */
1698 }
1699 }
1701 /* Compute TYPE_SIZE and TYPE_ALIGN for TYPE, once it has been laid
1702 out. */
1704 static void
1706 {
1707 /* Normally, use the alignment corresponding to the mode chosen.
1708 However, where strict alignment is not required, avoid
1709 over-aligning structures, since most compilers do not do this
1710 alignment. */
1714 {
1717 /* Don't override a larger alignment requirement coming from a user
1718 alignment of one of the fields. */
1720 {
1723 }
1724 }
1726 /* Do machine-dependent extra alignment. */
1727 #ifdef ROUND_TYPE_ALIGN
1730 #endif
1732 /* If we failed to find a simple way to calculate the unit size
1733 of the type, find it by division. */
1735 /* TYPE_SIZE (type) is computed in bitsizetype. After the division, the
1736 result will fit in sizetype. We will get more efficient code using
1737 sizetype, so we force a conversion. */
1741 bitsize_unit_node));
1744 {
1748 }
1750 /* Evaluate nonconstant sizes only once, either now or as soon as safe. */
1757 /* Also layout any other variants of the type. */
1760 {
1761 tree variant;
1762 /* Record layout info of this variant. */
1770 /* Copy it into all variants. */
1774 {
1780 else
1785 }
1786 }
1787 }
1789 /* Return a new underlying object for a bitfield started with FIELD. */
1791 static tree
1793 {
1796 /* Force the representative to begin at a BITS_PER_UNIT aligned
1797 boundary - C++ may use tail-padding of a base object to
1798 continue packing bits so the bitfield region does not start
1799 at bit zero (see g++.dg/abi/bitfield5.C for example).
1800 Unallocated bits may happen for other reasons as well,
1801 for example Ada which allows explicit bit-granular structure layout. */
1812 }
1814 /* Finish up a bitfield group that was started by creating the underlying
1815 object REPR with the last field in the bitfield group FIELD. */
1817 static void
1819 {
1821 machine_mode mode;
1834 /* Round up bitsize to multiples of BITS_PER_UNIT. */
1837 /* Now nothing tells us how to pad out bitsize ... */
1842 {
1843 tree maxsize;
1844 /* If there was an error, the field may be not laid out
1845 correctly. Don't bother to do anything. */
1851 {
1855 /* If the group ends within a bitfield nextf does not need to be
1856 aligned to BITS_PER_UNIT. Thus round up. */
1858 }
1859 else
1861 }
1862 else
1863 {
1864 /* ??? If you consider that tail-padding of this struct might be
1865 re-used when deriving from it we cannot really do the following
1866 and thus need to set maxsize to bitsize? Also we cannot
1867 generally rely on maxsize to fold to an integer constant, so
1868 use bitsize as fallback for this case. */
1874 else
1876 }
1878 /* Only if we don't artificially break up the representative in
1879 the middle of a large bitfield with different possibly
1880 overlapping representatives. And all representatives start
1881 at byte offset. */
1884 /* Find the smallest nice mode to use. */
1895 {
1896 /* We really want a BLKmode representative only as a last resort,
1897 considering the member b in
1898 struct { int a : 7; int b : 17; int c; } __attribute__((packed));
1899 Otherwise we simply want to split the representative up
1900 allowing for overlaps within the bitfield region as required for
1901 struct { int a : 7; int b : 7;
1902 int c : 10; int d; } __attribute__((packed));
1903 [0, 15] HImode for a and b, [8, 23] HImode for c. */
1909 }
1910 else
1911 {
1917 }
1919 /* Remember whether the bitfield group is at the end of the
1920 structure or not. */
1922 }
1924 /* Compute and set FIELD_DECLs for the underlying objects we should
1925 use for bitfield access for the structure T. */
1927 void
1929 {
1933 /* Unions would be special, for the ease of type-punning optimizations
1934 we could use the underlying type as hint for the representative
1935 if the bitfield would fit and the representative would not exceed
1936 the union in size. */
1942 {
1946 /* In the C++ memory model, consecutive bit fields in a structure are
1947 considered one memory location and updating a memory location
1948 may not store into adjacent memory locations. */
1951 {
1952 /* Start new representative. */
1954 }
1957 {
1958 /* Finish off new representative. */
1961 }
1963 {
1966 /* Zero-size bitfields finish off a representative and
1967 do not have a representative themselves. This is
1968 required by the C++ memory model. */
1970 {
1973 }
1975 /* We assume that either DECL_FIELD_OFFSET of the representative
1976 and each bitfield member is a constant or they are equal.
1977 This is because we need to be able to compute the bit-offset
1978 of each field relative to the representative in get_bit_range
1979 during RTL expansion.
1980 If these constraints are not met, simply force a new
1981 representative to be generated. That will at most
1982 generate worse code but still maintain correctness with
1983 respect to the C++ memory model. */
1988 {
1991 }
1992 }
1993 else
2000 }
2004 }
2006 /* Do all of the work required to layout the type indicated by RLI,
2007 once the fields have been laid out. This function will call `free'
2008 for RLI, unless FREE_P is false. Passing a value other than false
2009 for FREE_P is bad practice; this option only exists to support the
2010 G++ 3.2 ABI. */
2012 void
2014 {
2015 tree variant;
2017 /* Compute the final size. */
2020 /* Compute the TYPE_MODE for the record. */
2023 /* Perform any last tweaks to the TYPE_SIZE, etc. */
2026 /* Compute bitfield representatives. */
2029 /* Propagate TYPE_PACKED and TYPE_REVERSE_STORAGE_ORDER to variants.
2030 With C++ templates, it is too early to do this when the attribute
2031 is being parsed. */
2034 {
2038 }
2040 /* Lay out any static members. This is done now because their type
2041 may use the record's type. */
2045 /* Clean up. */
2047 {
2050 }
2051 }
2052 \f
2054 /* Finish processing a builtin RECORD_TYPE type TYPE. It's name is
2055 NAME, its fields are chained in reverse on FIELDS.
2057 If ALIGN_TYPE is non-null, it is given the same alignment as
2058 ALIGN_TYPE. */
2060 void
2062 tree align_type)
2063 {
2067 {
2071 }
2075 {
2078 }
2083 #else
2086 #endif
2089 }
2091 /* Calculate the mode, size, and alignment for TYPE.
2092 For an array type, calculate the element separation as well.
2093 Record TYPE on the chain of permanent or temporary types
2094 so that dbxout will find out about it.
2096 TYPE_SIZE of a type is nonzero if the type has been laid out already.
2097 layout_type does nothing on such a type.
2099 If the type is incomplete, its TYPE_SIZE remains zero. */
2101 void
2103 {
2109 /* We don't want finalize_type_size to copy an alignment attribute to
2110 variants that don't have it. */
2113 /* Do nothing if type has been laid out before. */
2118 {
2120 /* This kind of type is the responsibility
2121 of the language-specific code. */
2130 /* Don't set TYPE_PRECISION here, as it may be set by a bitfield. */
2142 /* TYPE_MODE (type) has been set already. */
2150 /* build_complex_type and fortran's gfc_build_complex_type have set the
2151 expected mode to allow having multiple complex types for multiple
2152 floating point types that have the same size such as the PowerPC with
2153 __ibm128 and __float128. */
2161 {
2167 /* Find an appropriate mode for the vector type. */
2174 /* Several boolean vector elements may fit in a single unit. */
2179 else
2187 /* For vector types, we do not default to the mode's alignment.
2188 Instead, query a target hook, defaulting to natural alignment.
2189 This prevents ABI changes depending on whether or not native
2190 vector modes are supported. */
2193 /* However, if the underlying mode requires a bigger alignment than
2194 what the target hook provides, we cannot use the mode. For now,
2195 simply reject that case. */
2199 }
2202 /* This is an incomplete type and so doesn't have a size. */
2216 /* A pointer might be MODE_PARTIAL_INT, but ptrdiff_t must be
2217 integral, which may be an __intN. */
2224 /* It's hard to see what the mode and size of a function ought to
2225 be, but we do know the alignment is FUNCTION_BOUNDARY, so
2226 make it consistent with that. */
2234 {
2240 }
2244 {
2248 /* We need to know both bounds in order to compute the size. */
2251 {
2255 tree length;
2257 /* Make sure that an array of zero-sized element is zero-sized
2258 regardless of its extent. */
2262 /* The computation should happen in the original signedness so
2263 that (possible) negative values are handled appropriately
2264 when determining overflow. */
2265 else
2266 {
2267 /* ??? When it is obvious that the range is signed
2268 represent it using ssizetype. */
2273 {
2278 }
2279 length
2284 }
2286 /* ??? We have no way to distinguish a null-sized array from an
2287 array spanning the whole sizetype range, so we arbitrarily
2288 decide that [0, -1] is the only valid representation. */
2296 length));
2298 /* If we know the size of the element, calculate the total size
2299 directly, rather than do some division thing below. This
2300 optimization helps Fortran assumed-size arrays (where the
2301 size of the array is determined at runtime) substantially. */
2305 }
2307 /* Now round the alignment and size,
2308 using machine-dependent criteria if any. */
2313 else
2315 #ifdef ROUND_TYPE_ALIGN
2317 #else
2319 #endif
2324 /* BLKmode elements force BLKmode aggregate;
2325 else extract/store fields may lose. */
2328 {
2334 {
2337 }
2338 }
2339 /* When the element size is constant, check that it is at least as
2340 large as the element alignment. */
2343 /* If TYPE_SIZE_UNIT overflowed, then it is certainly larger than
2344 TYPE_ALIGN_UNIT. */
2351 }
2356 {
2357 tree field;
2358 record_layout_info rli;
2360 /* Initialize the layout information. */
2363 /* If this is a QUAL_UNION_TYPE, we want to process the fields
2364 in the reverse order in building the COND_EXPR that denotes
2365 its size. We reverse them again later. */
2369 /* Place all the fields. */
2376 /* Finish laying out the record. */
2378 }
2383 }
2385 /* Compute the final TYPE_SIZE, TYPE_ALIGN, etc. for TYPE. For
2386 records and unions, finish_record_layout already called this
2387 function. */
2391 /* We should never see alias sets on incomplete aggregates. And we
2392 should not call layout_type on not incomplete aggregates. */
2395 }
2397 /* Return the least alignment required for type TYPE. */
2399 unsigned int
2401 {
2404 {
2406 #ifdef BIGGEST_FIELD_ALIGNMENT
2408 #endif
2410 #ifdef ADJUST_FIELD_ALIGN
2414 #endif
2416 }
2418 }
2420 /* Vector types need to re-check the target flags each time we report
2421 the machine mode. We need to do this because attribute target can
2422 change the result of vector_mode_supported_p and have_regs_of_mode
2423 on a per-function basis. Thus the TYPE_MODE of a VECTOR_TYPE can
2424 change on a per-function basis. */
2425 /* ??? Possibly a better solution is to run through all the types
2426 referenced by a function and re-compute the TYPE_MODE once, rather
2427 than make the TYPE_MODE macro call a function. */
2429 machine_mode
2431 {
2432 machine_mode mode;
2440 {
2443 /* For integers, try mapping it to a same-sized scalar mode. */
2445 {
2451 }
2454 }
2457 }
2458 \f
2459 /* Create and return a type for signed integers of PRECISION bits. */
2461 tree
2463 {
2470 }
2472 /* Create and return a type for unsigned integers of PRECISION bits. */
2474 tree
2476 {
2483 }
2484 \f
2485 /* Create and return a type for fract of PRECISION bits, UNSIGNEDP,
2486 and SATP. */
2488 tree
2490 {
2498 /* Lay out the type: set its alignment, size, etc. */
2500 {
2503 }
2504 else
2509 }
2511 /* Create and return a type for accum of PRECISION bits, UNSIGNEDP,
2512 and SATP. */
2514 tree
2516 {
2524 /* Lay out the type: set its alignment, size, etc. */
2526 {
2529 }
2530 else
2535 }
2537 /* Initialize sizetypes so layout_type can use them. */
2539 void
2541 {
2544 /* Get sizetypes precision from the SIZE_TYPE target macro. */
2553 else
2554 {
2560 {
2565 {
2567 }
2568 }
2571 }
2573 bprecision
2575 bprecision
2580 /* Create stubs for sizetype and bitsizetype so we can create constants. */
2590 /* Now layout both types manually. */
2604 /* Create the signed variants of *sizetype. */
2609 }
2610 \f
2611 /* TYPE is an integral type, i.e., an INTEGRAL_TYPE, ENUMERAL_TYPE
2612 or BOOLEAN_TYPE. Set TYPE_MIN_VALUE and TYPE_MAX_VALUE
2613 for TYPE, based on the PRECISION and whether or not the TYPE
2614 IS_UNSIGNED. PRECISION need not correspond to a width supported
2615 natively by the hardware; for example, on a machine with 8-bit,
2616 16-bit, and 32-bit register modes, PRECISION might be 7, 23, or
2617 61. */
2619 void
2622 signop sgn)
2623 {
2624 /* For bitfields with zero width we end up creating integer types
2625 with zero precision. Don't assign any minimum/maximum values
2626 to those types, they don't have any valid value. */
2634 }
2636 /* Set the extreme values of TYPE based on its precision in bits,
2637 then lay it out. Used when make_signed_type won't do
2638 because the tree code is not INTEGER_TYPE.
2639 E.g. for Pascal, when the -fsigned-char option is given. */
2641 void
2643 {
2648 /* Lay out the type: set its alignment, size, etc. */
2650 }
2652 /* Set the extreme values of TYPE based on its precision in bits,
2653 then lay it out. This is used both in `make_unsigned_type'
2654 and for enumeral types. */
2656 void
2658 {
2665 /* Lay out the type: set its alignment, size, etc. */
2667 }
2668 \f
2669 /* Construct an iterator for a bitfield that spans BITSIZE bits,
2670 starting at BITPOS.
2672 BITREGION_START is the bit position of the first bit in this
2673 sequence of bit fields. BITREGION_END is the last bit in this
2674 sequence. If these two fields are non-zero, we should restrict the
2675 memory access to that range. Otherwise, we are allowed to touch
2676 any adjacent non bit-fields.
2678 ALIGN is the alignment of the underlying object in bits.
2679 VOLATILEP says whether the bitfield is volatile. */
2681 bit_field_mode_iterator
2683 HOST_WIDE_INT bitregion_start,
2684 HOST_WIDE_INT bitregion_end,
2690 {
2692 {
2693 /* We can assume that any aligned chunk of ALIGN bits that overlaps
2694 the bitfield is mapped and won't trap, provided that ALIGN isn't
2695 too large. The cap is the biggest required alignment for data,
2696 or at least the word size. And force one such chunk at least. */
2697 unsigned HOST_WIDE_INT units
2703 }
2704 }
2706 /* Calls to this function return successively larger modes that can be used
2707 to represent the bitfield. Return true if another bitfield mode is
2708 available, storing it in *OUT_MODE if so. */
2710 bool
2712 {
2714 {
2717 /* Skip modes that don't have full precision. */
2721 /* Stop if the mode is too wide to handle efficiently. */
2725 /* Don't deliver more than one multiword mode; the smallest one
2726 should be used. */
2730 /* Skip modes that are too small. */
2736 /* Stop if the mode goes outside the bitregion. */
2744 /* Stop if the mode requires too much alignment. */
2751 m_count++;
2753 }
2755 }
2757 /* Return true if smaller modes are generally preferred for this kind
2758 of bitfield. */
2760 bool
2762 {
2766 }
2768 /* Find the best machine mode to use when referencing a bit field of length
2769 BITSIZE bits starting at BITPOS.
2771 BITREGION_START is the bit position of the first bit in this
2772 sequence of bit fields. BITREGION_END is the last bit in this
2773 sequence. If these two fields are non-zero, we should restrict the
2774 memory access to that range. Otherwise, we are allowed to touch
2775 any adjacent non bit-fields.
2777 The underlying object is known to be aligned to a boundary of ALIGN bits.
2778 If LARGEST_MODE is not VOIDmode, it means that we should not use a mode
2779 larger than LARGEST_MODE (usually SImode).
2781 If no mode meets all these conditions, we return VOIDmode.
2783 If VOLATILEP is false and SLOW_BYTE_ACCESS is false, we return the
2784 smallest mode meeting these conditions.
2786 If VOLATILEP is false and SLOW_BYTE_ACCESS is true, we return the
2787 largest mode (but a mode no wider than UNITS_PER_WORD) that meets
2788 all the conditions.
2790 If VOLATILEP is true the narrow_volatile_bitfields target hook is used to
2791 decide which of the above modes should be used. */
2793 machine_mode
2799 {
2803 machine_mode mode;
2805 /* ??? For historical reasons, reject modes that would normally
2806 receive greater alignment, even if unaligned accesses are
2807 acceptable. This has both advantages and disadvantages.
2808 Removing this check means that something like:
2810 struct s { unsigned int x; unsigned int y; };
2811 int f (struct s *s) { return s->x == 0 && s->y == 0; }
2813 can be implemented using a single load and compare on
2814 64-bit machines that have no alignment restrictions.
2815 For example, on powerpc64-linux-gnu, we would generate:
2817 ld 3,0(3)
2818 cntlzd 3,3
2819 srdi 3,3,6
2820 blr
2822 rather than:
2824 lwz 9,0(3)
2825 cmpwi 7,9,0
2826 bne 7,.L3
2827 lwz 3,4(3)
2828 cntlzw 3,3
2829 srwi 3,3,5
2830 extsw 3,3
2831 blr
2832 .p2align 4,,15
2833 .L3:
2834 li 3,0
2835 blr
2837 However, accessing more than one field can make life harder
2838 for the gimple optimizers. For example, gcc.dg/vect/bb-slp-5.c
2839 has a series of unsigned short copies followed by a series of
2840 unsigned short comparisons. With this check, both the copies
2841 and comparisons remain 16-bit accesses and FRE is able
2842 to eliminate the latter. Without the check, the comparisons
2843 can be done using 2 64-bit operations, which FRE isn't able
2844 to handle in the same way.
2846 Either way, it would probably be worth disabling this check
2847 during expand. One particular example where removing the
2848 check would help is the get_best_mode call in store_bit_field.
2849 If we are given a memory bitregion of 128 bits that is aligned
2850 to a 64-bit boundary, and the bitfield we want to modify is
2851 in the second half of the bitregion, this check causes
2852 store_bitfield to turn the memory into a 64-bit reference
2853 to the _first_ half of the region. We later use
2854 adjust_bitfield_address to get a reference to the correct half,
2855 but doing so looks to adjust_bitfield_address as though we are
2856 moving past the end of the original object, so it drops the
2857 associated MEM_EXPR and MEM_OFFSET. Removing the check
2858 causes store_bit_field to keep a 128-bit memory reference,
2859 so that the final bitfield reference still has a MEM_EXPR
2860 and MEM_OFFSET. */
2864 {
2868 }
2870 }
2872 /* Gets minimal and maximal values for MODE (signed or unsigned depending on
2873 SIGN). The returned constants are made to be usable in TARGET_MODE. */
2875 void
2877 machine_mode target_mode,
2879 {
2885 /* Special case BImode, which has values 0 and STORE_FLAG_VALUE. */
2887 {
2889 {
2892 }
2893 else
2894 {
2897 }
2898 }
2900 {
2903 }
2904 else
2905 {
2908 }
2912 }