| blob | 84a709adaa1a11493fe65516881ab1616bfc00d7 |
1 /* Medium-level subroutines: convert bit-field store and extract
2 and shifts, multiplies and divides to rtl instructions.
3 Copyright (C) 1987, 1988, 1989, 1992, 1993, 1994, 1995, 1996, 1997, 1998,
4 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007
5 Free Software Foundation, Inc.
7 This file is part of GCC.
9 GCC is free software; you can redistribute it and/or modify it under
10 the terms of the GNU General Public License as published by the Free
11 Software Foundation; either version 3, or (at your option) any later
12 version.
14 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
15 WARRANTY; without even the implied warranty of MERCHANTABILITY or
16 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
17 for more details.
19 You should have received a copy of the GNU General Public License
20 along with GCC; see the file COPYING3. If not see
21 <http://www.gnu.org/licenses/>. */
59 /* Test whether a value is zero of a power of two. */
60 #define EXACT_POWER_OF_2_OR_ZERO_P(x) (((x) & ((x) - 1)) == 0)
62 /* Nonzero means divides or modulus operations are relatively cheap for
63 powers of two, so don't use branches; emit the operation instead.
64 Usually, this will mean that the MD file will emit non-branch
65 sequences. */
70 #ifndef SLOW_UNALIGNED_ACCESS
71 #define SLOW_UNALIGNED_ACCESS(MODE, ALIGN) STRICT_ALIGNMENT
72 #endif
74 /* For compilers that support multiple targets with different word sizes,
75 MAX_BITS_PER_WORD contains the biggest value of BITS_PER_WORD. An example
76 is the H8/300(H) compiler. */
78 #ifndef MAX_BITS_PER_WORD
79 #define MAX_BITS_PER_WORD BITS_PER_WORD
80 #endif
82 /* Reduce conditional compilation elsewhere. */
83 #ifndef HAVE_insv
84 #define HAVE_insv 0
85 #define CODE_FOR_insv CODE_FOR_nothing
86 #define gen_insv(a,b,c,d) NULL_RTX
87 #endif
88 #ifndef HAVE_extv
89 #define HAVE_extv 0
90 #define CODE_FOR_extv CODE_FOR_nothing
91 #define gen_extv(a,b,c,d) NULL_RTX
92 #endif
93 #ifndef HAVE_extzv
94 #define HAVE_extzv 0
95 #define CODE_FOR_extzv CODE_FOR_nothing
96 #define gen_extzv(a,b,c,d) NULL_RTX
97 #endif
99 /* Cost of various pieces of RTL. Note that some of these are indexed by
100 shift count and some by mode. */
113 void
115 {
116 struct
117 {
144 {
147 }
152 /* Avoid using hard regs in ways which may be unsupported. */
212 {
240 {
248 }
255 {
262 }
263 }
264 }
266 /* Return an rtx representing minus the value of X.
267 MODE is the intended mode of the result,
268 useful if X is a CONST_INT. */
270 rtx
272 {
279 }
281 /* Report on the availability of insv/extv/extzv and the desired mode
282 of each of their operands. Returns MAX_MACHINE_MODE if HAVE_foo
283 is false; else the mode of the specified operand. If OPNO is -1,
284 all the caller cares about is whether the insn is available. */
285 enum machine_mode
287 {
291 {
294 {
297 }
302 {
305 }
310 {
313 }
318 }
323 /* Everyone who uses this function used to follow it with
324 if (result == VOIDmode) result = word_mode; */
328 }
330 /* Return true if X, of mode MODE, matches the predicate for operand
331 OPNO of instruction ICODE. Allow volatile memories, regardless of
332 the ambient volatile_ok setting. */
334 static bool
337 {
344 }
345 \f
346 /* A subroutine of store_bit_field, with the same arguments. Return true
347 if the operation could be implemented.
349 If FALLBACK_P is true, fall back to store_fixed_bit_field if we have
350 no other way of implementing the operation. If FALLBACK_P is false,
351 return false instead. */
353 static bool
357 {
358 unsigned int unit
363 rtx orig_value;
368 {
369 /* The following line once was done only if WORDS_BIG_ENDIAN,
370 but I think that is a mistake. WORDS_BIG_ENDIAN is
371 meaningful at a much higher level; when structures are copied
372 between memory and regs, the higher-numbered regs
373 always get higher addresses. */
379 /* Paradoxical subregs need special handling on big endian machines. */
381 {
388 }
389 else
394 }
396 /* No action is needed if the target is a register and if the field
397 lies completely outside that register. This can occur if the source
398 code contains an out-of-bounds access to a small array. */
402 /* Use vec_set patterns for inserting parts of vectors whenever
403 available. */
411 {
432 /* We could handle this, but we should always be called with a pseudo
433 for our targets and all insns should take them as outputs. */
441 {
445 }
446 }
448 /* If the target is a register, overwriting the entire object, or storing
449 a full-word or multi-word field can be done with just a SUBREG.
451 If the target is memory, storing any naturally aligned field can be
452 done with a simple store. For targets that support fast unaligned
453 memory, any naturally sized, unit aligned field can be done directly. */
469 {
474 byte_offset);
477 }
479 /* Make sure we are playing with integral modes. Pun with subregs
480 if we aren't. This must come after the entire register case above,
481 since that case is valid for any mode. The following cases are only
482 valid for integral modes. */
483 {
486 {
489 else
490 {
493 }
494 }
495 }
497 /* We may be accessing data outside the field, which means
498 we can alias adjacent data. */
500 {
504 }
506 /* If OP0 is a register, BITPOS must count within a word.
507 But as we have it, it counts within whatever size OP0 now has.
508 On a bigendian machine, these are not the same, so convert. */
514 /* Storing an lsb-aligned field in a register
515 can be done with a movestrict instruction. */
522 {
525 /* Get appropriate low part of the value being stored. */
537 {
538 /* Else we've got some float mode source being extracted into
539 a different float mode destination -- this combination of
540 subregs results in Severe Tire Damage. */
545 }
551 value));
554 }
556 /* Handle fields bigger than a word. */
559 {
560 /* Here we transfer the words of the field
561 in the order least significant first.
562 This is because the most significant word is the one which may
563 be less than full.
564 However, only do that if the value is not BLKmode. */
569 rtx last;
571 /* This is the mode we must force value to, so that there will be enough
572 subwords to extract. Note that fieldmode will often (always?) be
573 VOIDmode, because that is what store_field uses to indicate that this
574 is a bit field, but passing VOIDmode to operand_subword_force
575 is not allowed. */
582 {
583 /* If I is 0, use the low-order word in both field and target;
584 if I is 1, use the next to lowest word; and so on. */
597 {
600 }
601 }
603 }
605 /* From here on we can assume that the field to be stored in is
606 a full-word (whatever type that is), since it is shorter than a word. */
608 /* OFFSET is the number of words or bytes (UNIT says which)
609 from STR_RTX to the first word or byte containing part of the field. */
612 {
615 {
617 {
618 /* Since this is a destination (lvalue), we can't copy
619 it to a pseudo. We can remove a SUBREG that does not
620 change the size of the operand. Such a SUBREG may
621 have been added above. */
626 }
629 }
631 }
633 /* If VALUE has a floating-point or complex mode, access it as an
634 integer of the corresponding size. This can occur on a machine
635 with 64 bit registers that uses SFmode for float. It can also
636 occur for unaligned float or complex fields. */
641 {
644 }
646 /* Now OFFSET is nonzero only if OP0 is memory
647 and is therefore always measured in bytes. */
656 VOIDmode)
658 {
660 rtx value1;
663 rtx pat;
665 /* Add OFFSET into OP0's address. */
669 /* If xop0 is a register, we need it in OP_MODE
670 to make it acceptable to the format of insv. */
672 /* We can't just change the mode, because this might clobber op0,
673 and we will need the original value of op0 if insv fails. */
678 /* On big-endian machines, we count bits from the most significant.
679 If the bit field insn does not, we must invert. */
684 /* We have been counting XBITPOS within UNIT.
685 Count instead within the size of the register. */
691 /* Convert VALUE to op_mode (which insv insn wants) in VALUE1. */
694 {
696 {
697 /* Optimization: Don't bother really extending VALUE
698 if it has all the bits we will actually use. However,
699 if we must narrow it, be sure we do it correctly. */
702 {
703 rtx tmp;
709 value1),
712 }
713 else
715 }
718 else
719 /* Parse phase is supposed to make VALUE's data type
720 match that of the component reference, which is a type
721 at least as wide as the field; so VALUE should have
722 a mode that corresponds to that type. */
724 }
726 /* If this machine's insv insists on a register,
727 get VALUE1 into a register. */
734 {
737 }
739 }
741 /* If OP0 is a memory, try copying it to a register and seeing if a
742 cheap register alternative is available. */
744 {
747 /* Get the mode to use for inserting into this field. If OP0 is
748 BLKmode, get the smallest mode consistent with the alignment. If
749 OP0 is a non-BLKmode object that is no wider than OP_MODE, use its
750 mode. Otherwise, use the smallest mode containing the field. */
759 else
766 {
772 /* Adjust address to point to the containing unit of
773 that mode. Compute the offset as a multiple of this unit,
774 counting in bytes. */
780 /* Fetch that unit, store the bitfield in it, then store
781 the unit. */
785 {
788 }
790 }
791 }
798 }
800 /* Generate code to store value from rtx VALUE
801 into a bit-field within structure STR_RTX
802 containing BITSIZE bits starting at bit BITNUM.
803 FIELDMODE is the machine-mode of the FIELD_DECL node for this field. */
805 void
808 rtx value)
809 {
812 }
813 \f
814 /* Use shifts and boolean operations to store VALUE
815 into a bit field of width BITSIZE
816 in a memory location specified by OP0 except offset by OFFSET bytes.
817 (OFFSET must be 0 if OP0 is a register.)
818 The field starts at position BITPOS within the byte.
819 (If OP0 is a register, it may be a full word or a narrower mode,
820 but BITPOS still counts within a full word,
821 which is significant on bigendian machines.) */
823 static void
827 {
830 rtx temp;
834 /* There is a case not handled here:
835 a structure with a known alignment of just a halfword
836 and a field split across two aligned halfwords within the structure.
837 Or likewise a structure with a known alignment of just a byte
838 and a field split across two bytes.
839 Such cases are not supposed to be able to occur. */
842 {
844 /* Special treatment for a bit field split across two registers. */
846 {
849 }
850 }
851 else
852 {
853 /* Get the proper mode to use for this field. We want a mode that
854 includes the entire field. If such a mode would be larger than
855 a word, we won't be doing the extraction the normal way.
856 We don't want a mode bigger than the destination. */
866 {
867 /* The only way this should occur is if the field spans word
868 boundaries. */
870 value);
872 }
876 /* Make sure bitpos is valid for the chosen mode. Adjust BITPOS to
877 be in the range 0 to total_bits-1, and put any excess bytes in
878 OFFSET. */
880 {
884 }
886 /* Get ref to an aligned byte, halfword, or word containing the field.
887 Adjust BITPOS to be position within a word,
888 and OFFSET to be the offset of that word.
889 Then alter OP0 to refer to that word. */
893 }
897 /* Now MODE is either some integral mode for a MEM as OP0,
898 or is a full-word for a REG as OP0. TOTAL_BITS corresponds.
899 The bit field is contained entirely within OP0.
900 BITPOS is the starting bit number within OP0.
901 (OP0's mode may actually be narrower than MODE.) */
904 /* BITPOS is the distance between our msb
905 and that of the containing datum.
906 Convert it to the distance from the lsb. */
909 /* Now BITPOS is always the distance between our lsb
910 and that of OP0. */
912 /* Shift VALUE left by BITPOS bits. If VALUE is not constant,
913 we must first convert its mode to MODE. */
916 {
930 }
931 else
932 {
937 {
941 else
943 }
952 }
954 /* Now clear the chosen bits in OP0,
955 except that if VALUE is -1 we need not bother. */
956 /* We keep the intermediates in registers to allow CSE to combine
957 consecutive bitfield assignments. */
962 {
967 }
969 /* Now logical-or VALUE into OP0, unless it is zero. */
972 {
976 }
980 }
981 \f
982 /* Store a bit field that is split across multiple accessible memory objects.
984 OP0 is the REG, SUBREG or MEM rtx for the first of the objects.
985 BITSIZE is the field width; BITPOS the position of its first bit
986 (within the word).
987 VALUE is the value to store.
989 This does not yet handle fields wider than BITS_PER_WORD. */
991 static void
994 {
998 /* Make sure UNIT isn't larger than BITS_PER_WORD, we can only handle that
999 much at a time. */
1002 else
1005 /* If VALUE is a constant other than a CONST_INT, get it into a register in
1006 WORD_MODE. If we can do this using gen_lowpart_common, do so. Note
1007 that VALUE might be a floating-point constant. */
1009 {
1014 else
1019 }
1022 {
1031 /* THISSIZE must not overrun a word boundary. Otherwise,
1032 store_fixed_bit_field will call us again, and we will mutually
1033 recurse forever. */
1038 {
1041 /* We must do an endian conversion exactly the same way as it is
1042 done in extract_bit_field, so that the two calls to
1043 extract_fixed_bit_field will have comparable arguments. */
1046 else
1049 /* Fetch successively less significant portions. */
1054 else
1055 /* The args are chosen so that the last part includes the
1056 lsb. Give extract_bit_field the value it needs (with
1057 endianness compensation) to fetch the piece we want. */
1061 }
1062 else
1063 {
1064 /* Fetch successively more significant portions. */
1069 else
1072 }
1074 /* If OP0 is a register, then handle OFFSET here.
1076 When handling multiword bitfields, extract_bit_field may pass
1077 down a word_mode SUBREG of a larger REG for a bitfield that actually
1078 crosses a word boundary. Thus, for a SUBREG, we must find
1079 the current word starting from the base register. */
1081 {
1086 }
1088 {
1091 }
1092 else
1095 /* OFFSET is in UNITs, and UNIT is in bits.
1096 store_fixed_bit_field wants offset in bytes. */
1100 }
1101 }
1102 \f
1103 /* A subroutine of extract_bit_field_1 that converts return value X
1104 to either MODE or TMODE. MODE, TMODE and UNSIGNEDP are arguments
1105 to extract_bit_field. */
1107 static rtx
1110 {
1114 /* If the x mode is not a scalar integral, first convert to the
1115 integer mode of that size and then access it as a floating-point
1116 value via a SUBREG. */
1118 {
1125 }
1128 }
1130 /* A subroutine of extract_bit_field, with the same arguments.
1131 If FALLBACK_P is true, fall back to extract_fixed_bit_field
1132 if we can find no other means of implementing the operation.
1133 if FALLBACK_P is false, return NULL instead. */
1135 static rtx
1140 {
1141 unsigned int unit
1155 {
1158 }
1160 /* If we have an out-of-bounds access to a register, just return an
1161 uninitialized register of the required mode. This can occur if the
1162 source code contains an out-of-bounds access to a small array. */
1170 {
1171 /* We're trying to extract a full register from itself. */
1173 }
1175 /* See if we can get a better vector mode before extracting. */
1179 {
1193 else
1203 }
1205 /* Use vec_extract patterns for extracting parts of vectors whenever
1206 available. */
1213 {
1242 /* We could handle this, but we should always be called with a pseudo
1243 for our targets and all insns should take them as outputs. */
1252 {
1258 }
1259 }
1261 /* Make sure we are playing with integral modes. Pun with subregs
1262 if we aren't. */
1263 {
1266 {
1269 else
1270 {
1274 /* If we got a SUBREG, force it into a register since we
1275 aren't going to be able to do another SUBREG on it. */
1278 }
1279 }
1280 }
1282 /* We may be accessing data outside the field, which means
1283 we can alias adjacent data. */
1285 {
1289 }
1291 /* Extraction of a full-word or multi-word value from a structure
1292 in a register or aligned memory can be done with just a SUBREG.
1293 A subword value in the least significant part of a register
1294 can also be extracted with a SUBREG. For this, we need the
1295 byte offset of the value in op0. */
1301 /* If OP0 is a register, BITPOS must count within a word.
1302 But as we have it, it counts within whatever size OP0 now has.
1303 On a bigendian machine, these are not the same, so convert. */
1309 /* ??? We currently assume TARGET is at least as big as BITSIZE.
1310 If that's wrong, the solution is to test for it and set TARGET to 0
1311 if needed. */
1313 /* Only scalar integer modes can be converted via subregs. There is an
1314 additional problem for FP modes here in that they can have a precision
1315 which is different from the size. mode_for_size uses precision, but
1316 we want a mode based on the size, so we must avoid calling it for FP
1317 modes. */
1325 /* ??? The big endian test here is wrong. This is correct
1326 if the value is in a register, and if mode_for_size is not
1327 the same mode as op0. This causes us to get unnecessarily
1328 inefficient code from the Thumb port when -mbig-endian. */
1329 && (BYTES_BIG_ENDIAN
1341 {
1343 {
1346 else
1347 {
1349 byte_offset);
1353 }
1354 }
1358 }
1359 no_subreg_mode_swap:
1361 /* Handle fields bigger than a word. */
1364 {
1365 /* Here we transfer the words of the field
1366 in the order least significant first.
1367 This is because the most significant word is the one which may
1368 be less than full. */
1376 /* Indicate for flow that the entire target reg is being set. */
1380 {
1381 /* If I is 0, use the low-order word in both field and target;
1382 if I is 1, use the next to lowest word; and so on. */
1383 /* Word number in TARGET to use. */
1384 unsigned int wordnum
1385 = (WORDS_BIG_ENDIAN
1388 /* Offset from start of field in OP0. */
1394 rtx result_part
1398 word_mode);
1404 }
1407 {
1408 /* Unless we've filled TARGET, the upper regs in a multi-reg value
1409 need to be zero'd out. */
1411 {
1416 emit_move_insn
1420 const0_rtx);
1421 }
1423 }
1425 /* Signed bit field: sign-extend with two arithmetic shifts. */
1434 }
1436 /* From here on we know the desired field is smaller than a word. */
1438 /* Check if there is a correspondingly-sized integer field, so we can
1439 safely extract it as one size of integer, if necessary; then
1440 truncate or extend to the size that is wanted; then use SUBREGs or
1441 convert_to_mode to get one of the modes we really wanted. */
1446 /* Should probably push op0 out to memory and then do a load. */
1449 /* OFFSET is the number of words or bytes (UNIT says which)
1450 from STR_RTX to the first word or byte containing part of the field. */
1452 {
1455 {
1460 }
1462 }
1464 /* Now OFFSET is nonzero only for memory operands. */
1470 /* If op0 is a register, we need it in EXT_MODE to make it
1471 acceptable to the format of ext(z)v. */
1476 {
1484 rtx pat;
1486 /* If op0 is a register, we need it in EXT_MODE to make it
1487 acceptable to the format of ext(z)v. */
1491 /* Get ref to first byte containing part of the field. */
1494 /* On big-endian machines, we count bits from the most significant.
1495 If the bit field insn does not, we must invert. */
1499 /* Now convert from counting within UNIT to counting in EXT_MODE. */
1509 {
1511 {
1516 }
1517 else
1519 }
1521 /* If this machine's ext(z)v insists on a register target,
1522 make sure we have one. */
1529 pat = (unsignedp
1533 {
1540 }
1542 }
1544 /* If OP0 is a memory, try copying it to a register and seeing if a
1545 cheap register alternative is available. */
1547 {
1550 /* Get the mode to use for inserting into this field. If
1551 OP0 is BLKmode, get the smallest mode consistent with the
1552 alignment. If OP0 is a non-BLKmode object that is no
1553 wider than EXT_MODE, use its mode. Otherwise, use the
1554 smallest mode containing the field. */
1563 else
1569 {
1572 /* Compute the offset as a multiple of this unit,
1573 counting in bytes. */
1578 /* Make sure the register is big enough for the whole field. */
1581 {
1586 /* Fetch it to a register in that size. */
1596 }
1597 }
1598 }
1606 }
1608 /* Generate code to extract a byte-field from STR_RTX
1609 containing BITSIZE bits, starting at BITNUM,
1610 and put it in TARGET if possible (if TARGET is nonzero).
1611 Regardless of TARGET, we return the rtx for where the value is placed.
1613 STR_RTX is the structure containing the byte (a REG or MEM).
1614 UNSIGNEDP is nonzero if this is an unsigned bit field.
1615 MODE is the natural mode of the field value once extracted.
1616 TMODE is the mode the caller would like the value to have;
1617 but the value may be returned with type MODE instead.
1619 If a TARGET is specified and we can store in it at no extra cost,
1620 we do so, and return TARGET.
1621 Otherwise, we return a REG of mode TMODE or MODE, with TMODE preferred
1622 if they are equally easy. */
1624 rtx
1628 {
1631 }
1632 \f
1633 /* Extract a bit field using shifts and boolean operations
1634 Returns an rtx to represent the value.
1635 OP0 addresses a register (word) or memory (byte).
1636 BITPOS says which bit within the word or byte the bit field starts in.
1637 OFFSET says how many bytes farther the bit field starts;
1638 it is 0 if OP0 is a register.
1639 BITSIZE says how many bits long the bit field is.
1640 (If OP0 is a register, it may be narrower than a full word,
1641 but BITPOS still counts within a full word,
1642 which is significant on bigendian machines.)
1644 UNSIGNEDP is nonzero for an unsigned bit field (don't sign-extend value).
1645 If TARGET is nonzero, attempts to store the value there
1646 and return TARGET, but this is not guaranteed.
1647 If TARGET is not used, create a pseudo-reg of mode TMODE for the value. */
1649 static rtx
1655 {
1660 {
1661 /* Special treatment for a bit field split across two registers. */
1664 }
1665 else
1666 {
1667 /* Get the proper mode to use for this field. We want a mode that
1668 includes the entire field. If such a mode would be larger than
1669 a word, we won't be doing the extraction the normal way. */
1675 /* The only way this should occur is if the field spans word
1676 boundaries. */
1679 unsignedp);
1683 /* Make sure bitpos is valid for the chosen mode. Adjust BITPOS to
1684 be in the range 0 to total_bits-1, and put any excess bytes in
1685 OFFSET. */
1687 {
1691 }
1693 /* Get ref to an aligned byte, halfword, or word containing the field.
1694 Adjust BITPOS to be position within a word,
1695 and OFFSET to be the offset of that word.
1696 Then alter OP0 to refer to that word. */
1700 }
1705 /* BITPOS is the distance between our msb and that of OP0.
1706 Convert it to the distance from the lsb. */
1709 /* Now BITPOS is always the distance between the field's lsb and that of OP0.
1710 We have reduced the big-endian case to the little-endian case. */
1713 {
1715 {
1716 /* If the field does not already start at the lsb,
1717 shift it so it does. */
1719 /* Maybe propagate the target for the shift. */
1720 /* But not if we will return it--could confuse integrate.c. */
1724 }
1725 /* Convert the value to the desired mode. */
1729 /* Unless the msb of the field used to be the msb when we shifted,
1730 mask out the upper bits. */
1737 }
1739 /* To extract a signed bit-field, first shift its msb to the msb of the word,
1740 then arithmetic-shift its lsb to the lsb of the word. */
1745 /* Find the narrowest integer mode that contains the field. */
1750 {
1753 }
1756 {
1757 tree amount
1760 /* Maybe propagate the target for the shift. */
1763 }
1769 }
1770 \f
1771 /* Return a constant integer (CONST_INT or CONST_DOUBLE) mask value
1772 of mode MODE with BITSIZE ones followed by BITPOS zeros, or the
1773 complement of that if COMPLEMENT. The mask is truncated if
1774 necessary to the width of mode MODE. The mask is zero-extended if
1775 BITSIZE+BITPOS is too small for MODE. */
1777 static rtx
1779 {
1786 else
1795 else
1803 else
1807 {
1810 }
1813 }
1815 /* Return a constant integer (CONST_INT or CONST_DOUBLE) rtx with the value
1816 VALUE truncated to BITSIZE bits and then shifted left BITPOS bits. */
1818 static rtx
1820 {
1828 {
1831 }
1832 else
1833 {
1836 }
1839 }
1840 \f
1841 /* Extract a bit field from a memory by forcing the alignment of the
1842 memory. This efficient only if the field spans at least 4 boundaries.
1844 OP0 is the MEM.
1845 BITSIZE is the field width; BITPOS is the position of the first bit.
1846 UNSIGNEDP is true if the result should be zero-extended. */
1848 static rtx
1852 {
1858 /* Choose a mode that will fit BITSIZE. */
1863 /* Choose a mode twice as wide. Fail if no such mode exists. */
1871 /* At the end, we'll need an additional shift to deal with sign/zero
1872 extension. By default this will be a left+right shift of the
1873 appropriate size. But we may be able to eliminate one of them. */
1877 {
1881 /* We load two values to be concatenate. There's an edge condition
1882 that bears notice -- an aligned value at the end of a page can
1883 only load one value lest we segfault. So the two values we load
1884 are at "base & -size" and "(base + size - 1) & -size". If base
1885 is unaligned, the addresses will be aligned and sequential; if
1886 base is aligned, the addresses will both be equal to base. */
1904 /* Combine these two values into a double-word value. */
1906 {
1911 }
1912 else
1913 {
1928 }
1935 {
1940 }
1941 }
1942 else
1943 {
1947 /* When strict alignment is not required, we can just load directly
1948 from memory without masking. If the remaining BITPOS offset is
1949 small enough, we may be able to do all operations in MODE as
1950 opposed to DMODE. */
1958 }
1960 /* Shift down the double-word such that the requested value is at bit 0. */
1967 /* If the field exactly matches MODE, then all we need to do is return the
1968 lowpart. Otherwise, shift to get the sign bits set properly. */
1982 fail:
1985 }
1987 /* Extract a bit field that is split across two words
1988 and return an RTX for the result.
1990 OP0 is the REG, SUBREG or MEM rtx for the first of the two words.
1991 BITSIZE is the field width; BITPOS, position of its first bit, in the word.
1992 UNSIGNEDP is 1 if should zero-extend the contents; else sign-extend. */
1994 static rtx
1997 {
2003 /* Make sure UNIT isn't larger than BITS_PER_WORD, we can only handle that
2004 much at a time. */
2007 else
2008 {
2011 {
2013 unsignedp);
2016 }
2017 }
2020 {
2029 /* THISSIZE must not overrun a word boundary. Otherwise,
2030 extract_fixed_bit_field will call us again, and we will mutually
2031 recurse forever. */
2035 /* If OP0 is a register, then handle OFFSET here.
2037 When handling multiword bitfields, extract_bit_field may pass
2038 down a word_mode SUBREG of a larger REG for a bitfield that actually
2039 crosses a word boundary. Thus, for a SUBREG, we must find
2040 the current word starting from the base register. */
2042 {
2047 }
2049 {
2052 }
2053 else
2056 /* Extract the parts in bit-counting order,
2057 whose meaning is determined by BYTES_PER_UNIT.
2058 OFFSET is in UNITs, and UNIT is in bits.
2059 extract_fixed_bit_field wants offset in bytes. */
2065 /* Shift this part into place for the result. */
2067 {
2072 }
2073 else
2074 {
2079 }
2083 else
2084 /* Combine the parts with bitwise or. This works
2085 because we extracted each part as an unsigned bit field. */
2087 OPTAB_LIB_WIDEN);
2090 }
2092 /* Unsigned bit field: we are done. */
2095 /* Signed bit field: sign-extend with two arithmetic shifts. */
2102 }
2103 \f
2104 /* Add INC into TARGET. */
2106 void
2108 {
2114 }
2116 /* Subtract DEC from TARGET. */
2118 void
2120 {
2126 }
2127 \f
2128 /* Output a shift instruction for expression code CODE,
2129 with SHIFTED being the rtx for the value to shift,
2130 and AMOUNT the tree for the amount to shift by.
2131 Store the result in the rtx TARGET, if that is convenient.
2132 If UNSIGNEDP is nonzero, do a logical shift; otherwise, arithmetic.
2133 Return the rtx for where the value is. */
2135 rtx
2138 {
2144 /* Previously detected shift-counts computed by NEGATE_EXPR
2145 and shifted in the other direction; but that does not work
2146 on all machines. */
2151 {
2160 }
2165 /* Check whether its cheaper to implement a left shift by a constant
2166 bit count by a sequence of additions. */
2174 {
2177 {
2181 }
2183 }
2186 {
2193 else
2197 {
2198 /* Widening does not work for rotation. */
2202 {
2203 /* If we have been unable to open-code this by a rotation,
2204 do it as the IOR of two shifts. I.e., to rotate A
2205 by N bits, compute (A << N) | ((unsigned) A >> (C - N))
2206 where C is the bitsize of A.
2208 It is theoretically possible that the target machine might
2209 not be able to perform either shift and hence we would
2210 be making two libcalls rather than just the one for the
2211 shift (similarly if IOR could not be done). We will allow
2212 this extremely unlikely lossage to avoid complicating the
2213 code below. */
2217 rtx temp1;
2223 other_amount
2226 new_amount);
2236 }
2241 }
2247 /* Do arithmetic shifts.
2248 Also, if we are going to widen the operand, we can just as well
2249 use an arithmetic right-shift instead of a logical one. */
2252 {
2255 /* If trying to widen a log shift to an arithmetic shift,
2256 don't accept an arithmetic shift of the same size. */
2260 /* Arithmetic shift */
2265 }
2267 /* We used to try extzv here for logical right shifts, but that was
2268 only useful for one machine, the VAX, and caused poor code
2269 generation there for lshrdi3, so the code was deleted and a
2270 define_expand for lshrsi3 was added to vax.md. */
2271 }
2275 }
2276 \f
2278 alg_unknown,
2279 alg_zero,
2281 alg_add_t_m2,
2282 alg_sub_t_m2,
2283 alg_add_factor,
2284 alg_sub_factor,
2285 alg_add_t2_m,
2286 alg_sub_t2_m,
2287 alg_impossible
2288 };
2290 /* This structure holds the "cost" of a multiply sequence. The
2291 "cost" field holds the total rtx_cost of every operator in the
2292 synthetic multiplication sequence, hence cost(a op b) is defined
2293 as rtx_cost(op) + cost(a) + cost(b), where cost(leaf) is zero.
2294 The "latency" field holds the minimum possible latency of the
2295 synthetic multiply, on a hypothetical infinitely parallel CPU.
2296 This is the critical path, or the maximum height, of the expression
2297 tree which is the sum of rtx_costs on the most expensive path from
2298 any leaf to the root. Hence latency(a op b) is defined as zero for
2299 leaves and rtx_cost(op) + max(latency(a), latency(b)) otherwise. */
2304 };
2306 /* This macro is used to compare a pointer to a mult_cost against an
2307 single integer "rtx_cost" value. This is equivalent to the macro
2308 CHEAPER_MULT_COST(X,Z) where Z = {Y,Y}. */
2309 #define MULT_COST_LESS(X,Y) ((X)->cost < (Y) \
2310 || ((X)->cost == (Y) && (X)->latency < (Y)))
2312 /* This macro is used to compare two pointers to mult_costs against
2313 each other. The macro returns true if X is cheaper than Y.
2314 Currently, the cheaper of two mult_costs is the one with the
2315 lower "cost". If "cost"s are tied, the lower latency is cheaper. */
2316 #define CHEAPER_MULT_COST(X,Y) ((X)->cost < (Y)->cost \
2317 || ((X)->cost == (Y)->cost \
2318 && (X)->latency < (Y)->latency))
2320 /* This structure records a sequence of operations.
2321 `ops' is the number of operations recorded.
2322 `cost' is their total cost.
2323 The operations are stored in `op' and the corresponding
2324 logarithms of the integer coefficients in `log'.
2326 These are the operations:
2327 alg_zero total := 0;
2328 alg_m total := multiplicand;
2329 alg_shift total := total * coeff
2330 alg_add_t_m2 total := total + multiplicand * coeff;
2331 alg_sub_t_m2 total := total - multiplicand * coeff;
2332 alg_add_factor total := total * coeff + total;
2333 alg_sub_factor total := total * coeff - total;
2334 alg_add_t2_m total := total * coeff + multiplicand;
2335 alg_sub_t2_m total := total * coeff - multiplicand;
2337 The first operand must be either alg_zero or alg_m. */
2339 struct algorithm
2340 {
2343 /* The size of the OP and LOG fields are not directly related to the
2344 word size, but the worst-case algorithms will be if we have few
2345 consecutive ones or zeros, i.e., a multiplicand like 10101010101...
2346 In that case we will generate shift-by-2, add, shift-by-2, add,...,
2347 in total wordsize operations. */
2350 };
2352 /* The entry for our multiplication cache/hash table. */
2354 /* The number we are multiplying by. */
2357 /* The mode in which we are multiplying something by T. */
2360 /* The best multiplication algorithm for t. */
2363 /* The cost of multiplication if ALG_CODE is not alg_impossible.
2364 Otherwise, the cost within which multiplication by T is
2365 impossible. */
2367 };
2369 /* The number of cache/hash entries. */
2370 #if HOST_BITS_PER_WIDE_INT == 64
2371 #define NUM_ALG_HASH_ENTRIES 1031
2372 #else
2373 #define NUM_ALG_HASH_ENTRIES 307
2374 #endif
2376 /* Each entry of ALG_HASH caches alg_code for some integer. This is
2377 actually a hash table. If we have a collision, that the older
2378 entry is kicked out. */
2381 /* Indicates the type of fixup needed after a constant multiplication.
2382 BASIC_VARIANT means no fixup is needed, NEGATE_VARIANT means that
2383 the result should be negated, and ADD_VARIANT means that the
2384 multiplicand should be added to the result. */
2400 /* Compute and return the best algorithm for multiplying by T.
2401 The algorithm must cost less than cost_limit
2402 If retval.cost >= COST_LIMIT, no algorithm was found and all
2403 other field of the returned struct are undefined.
2404 MODE is the machine mode of the multiplication. */
2406 static void
2409 {
2421 /* Indicate that no algorithm is yet found. If no algorithm
2422 is found, this value will be returned and indicate failure. */
2430 /* Restrict the bits of "t" to the multiplication's mode. */
2433 /* t == 1 can be done in zero cost. */
2435 {
2441 }
2443 /* t == 0 sometimes has a cost. If it does and it exceeds our limit,
2444 fail now. */
2446 {
2449 else
2450 {
2456 }
2457 }
2459 /* We'll be needing a couple extra algorithm structures now. */
2465 /* Compute the hash index. */
2468 /* See if we already know what to do for T. */
2472 {
2476 {
2477 /* The cache tells us that it's impossible to synthesize
2478 multiplication by T within alg_hash[hash_index].cost. */
2480 /* COST_LIMIT is at least as restrictive as the one
2481 recorded in the hash table, in which case we have no
2482 hope of synthesizing a multiplication. Just
2483 return. */
2486 /* If we get here, COST_LIMIT is less restrictive than the
2487 one recorded in the hash table, so we may be able to
2488 synthesize a multiplication. Proceed as if we didn't
2489 have the cache entry. */
2490 }
2491 else
2492 {
2494 /* The cached algorithm shows that this multiplication
2495 requires more cost than COST_LIMIT. Just return. This
2496 way, we don't clobber this cache entry with
2497 alg_impossible but retain useful information. */
2503 {
2523 }
2524 }
2525 }
2527 /* If we have a group of zero bits at the low-order part of T, try
2528 multiplying by the remaining bits and then doing a shift. */
2531 {
2532 do_alg_shift:
2535 {
2537 /* The function expand_shift will choose between a shift and
2538 a sequence of additions, so the observed cost is given as
2539 MIN (m * add_cost[mode], shift_cost[mode][m]). */
2550 {
2556 }
2557 }
2560 }
2562 /* If we have an odd number, add or subtract one. */
2564 {
2567 do_alg_addsub_t_m2:
2569 ;
2570 /* If T was -1, then W will be zero after the loop. This is another
2571 case where T ends with ...111. Handling this with (T + 1) and
2572 subtract 1 produces slightly better code and results in algorithm
2573 selection much faster than treating it like the ...0111 case
2574 below. */
2577 /* Reject the case where t is 3.
2578 Thus we prefer addition in that case. */
2580 {
2581 /* T ends with ...111. Multiply by (T + 1) and subtract 1. */
2591 {
2597 }
2598 }
2599 else
2600 {
2601 /* T ends with ...01 or ...011. Multiply by (T - 1) and add 1. */
2611 {
2617 }
2618 }
2621 }
2623 /* Look for factors of t of the form
2624 t = q(2**m +- 1), 2 <= m <= floor(log2(t - 1)).
2625 If we find such a factor, we can multiply by t using an algorithm that
2626 multiplies by q, shift the result by m and add/subtract it to itself.
2628 We search for large factors first and loop down, even if large factors
2629 are less probable than small; if we find a large factor we will find a
2630 good sequence quickly, and therefore be able to prune (by decreasing
2631 COST_LIMIT) the search. */
2633 do_alg_addsub_factor:
2635 {
2641 {
2642 /* If the target has a cheap shift-and-add instruction use
2643 that in preference to a shift insn followed by an add insn.
2644 Assume that the shift-and-add is "atomic" with a latency
2645 equal to its cost, otherwise assume that on superscalar
2646 hardware the shift may be executed concurrently with the
2647 earlier steps in the algorithm. */
2650 {
2653 }
2654 else
2666 {
2672 }
2673 /* Other factors will have been taken care of in the recursion. */
2675 }
2680 {
2681 /* If the target has a cheap shift-and-subtract insn use
2682 that in preference to a shift insn followed by a sub insn.
2683 Assume that the shift-and-sub is "atomic" with a latency
2684 equal to it's cost, otherwise assume that on superscalar
2685 hardware the shift may be executed concurrently with the
2686 earlier steps in the algorithm. */
2689 {
2692 }
2693 else
2705 {
2711 }
2713 }
2714 }
2718 /* Try shift-and-add (load effective address) instructions,
2719 i.e. do a*3, a*5, a*9. */
2721 {
2722 do_alg_add_t2_m:
2727 {
2736 {
2742 }
2743 }
2747 do_alg_sub_t2_m:
2752 {
2761 {
2767 }
2768 }
2771 }
2773 done:
2774 /* If best_cost has not decreased, we have not found any algorithm. */
2776 {
2777 /* We failed to find an algorithm. Record alg_impossible for
2778 this case (that is, <T, MODE, COST_LIMIT>) so that next time
2779 we are asked to find an algorithm for T within the same or
2780 lower COST_LIMIT, we can immediately return to the
2781 caller. */
2787 }
2789 /* Cache the result. */
2791 {
2797 }
2799 /* If we are getting a too long sequence for `struct algorithm'
2800 to record, make this search fail. */
2804 /* Copy the algorithm from temporary space to the space at alg_out.
2805 We avoid using structure assignment because the majority of
2806 best_alg is normally undefined, and this is a critical function. */
2813 }
2814 \f
2815 /* Find the cheapest way of multiplying a value of mode MODE by VAL.
2816 Try three variations:
2818 - a shift/add sequence based on VAL itself
2819 - a shift/add sequence based on -VAL, followed by a negation
2820 - a shift/add sequence based on VAL - 1, followed by an addition.
2822 Return true if the cheapest of these cost less than MULT_COST,
2823 describing the algorithm in *ALG and final fixup in *VARIANT. */
2825 static bool
2829 {
2834 /* Fail quickly for impossible bounds. */
2838 /* Ensure that mult_cost provides a reasonable upper bound.
2839 Any constant multiplication can be performed with less
2840 than 2 * bits additions. */
2850 /* This works only if the inverted value actually fits in an
2851 `unsigned int' */
2853 {
2856 {
2859 }
2860 else
2861 {
2864 }
2871 }
2873 /* This proves very useful for division-by-constant. */
2876 {
2879 }
2880 else
2881 {
2884 }
2893 }
2895 /* A subroutine of expand_mult, used for constant multiplications.
2896 Multiply OP0 by VAL in mode MODE, storing the result in TARGET if
2897 convenient. Use the shift/add sequence described by ALG and apply
2898 the final fixup specified by VARIANT. */
2900 static rtx
2904 {
2905 HOST_WIDE_INT val_so_far;
2910 /* Avoid referencing memory over and over and invalid sharing
2911 on SUBREGs. */
2914 /* ACCUM starts out either as OP0 or as a zero, depending on
2915 the first operation. */
2918 {
2921 }
2923 {
2926 }
2927 else
2931 {
2934 rtx add_target
2941 {
2970 shift_subtarget,
3000 (add_target
3007 }
3009 /* Write a REG_EQUAL note on the last insn so that we can cse
3010 multiplication sequences. Note that if ACCUM is a SUBREG,
3011 we've set the inner register and must properly indicate
3012 that. */
3016 {
3019 }
3025 }
3028 {
3031 }
3033 {
3036 }
3038 /* Compare only the bits of val and val_so_far that are significant
3039 in the result mode, to avoid sign-/zero-extension confusion. */
3045 }
3047 /* Perform a multiplication and return an rtx for the result.
3048 MODE is mode of value; OP0 and OP1 are what to multiply (rtx's);
3049 TARGET is a suggestion for where to store the result (an rtx).
3051 We check specially for a constant integer as OP1.
3052 If you want this check for OP0 as well, then before calling
3053 you should swap the two operands if OP0 would be constant. */
3055 rtx
3058 {
3063 /* Handling const0_rtx here allows us to use zero as a rogue value for
3064 coeff below. */
3076 /* These are the operations that are potentially turned into a sequence
3077 of shifts and additions. */
3080 {
3084 /* synth_mult does an `unsigned int' multiply. As long as the mode is
3085 less than or equal in size to `unsigned int' this doesn't matter.
3086 If the mode is larger than `unsigned int', then synth_mult works
3087 only if the constant value exactly fits in an `unsigned int' without
3088 any truncation. This means that multiplying by negative values does
3089 not work; results are off by 2^32 on a 32 bit machine. */
3092 {
3093 /* Attempt to handle multiplication of DImode values by negative
3094 coefficients, by performing the multiplication by a positive
3095 multiplier and then inverting the result. */
3098 {
3099 /* Its safe to use -INTVAL (op1) even for INT_MIN, as the
3100 result is interpreted as an unsigned coefficient.
3101 Exclude cost of op0 from max_cost to match the cost
3102 calculation of the synth_mult. */
3108 {
3111 variant);
3113 }
3114 }
3116 }
3118 {
3119 /* If we are multiplying in DImode, it may still be a win
3120 to try to work with shifts and adds. */
3125 {
3131 }
3132 }
3134 /* We used to test optimize here, on the grounds that it's better to
3135 produce a smaller program when -O is not used. But this causes
3136 such a terrible slowdown sometimes that it seems better to always
3137 use synth_mult. */
3139 {
3140 /* Special case powers of two. */
3146 /* Exclude cost of op0 from max_cost to match the cost
3147 calculation of the synth_mult. */
3150 max_cost))
3153 }
3154 }
3157 {
3161 }
3163 /* Expand x*2.0 as x+x. */
3166 {
3167 REAL_VALUE_TYPE d;
3171 {
3175 }
3176 }
3178 /* This used to use umul_optab if unsigned, but for non-widening multiply
3179 there is no difference between signed and unsigned. */
3181 ! unsignedp
3187 }
3188 \f
3189 /* Return the smallest n such that 2**n >= X. */
3191 int
3193 {
3195 }
3197 /* Choose a minimal N + 1 bit approximation to 1/D that can be used to
3198 replace division by D, and put the least significant N bits of the result
3199 in *MULTIPLIER_PTR and return the most significant bit.
3201 The width of operations is N (should be <= HOST_BITS_PER_WIDE_INT), the
3202 needed precision is in PRECISION (should be <= N).
3204 PRECISION should be as small as possible so this function can choose
3205 multiplier more freely.
3207 The rounded-up logarithm of D is placed in *lgup_ptr. A shift count that
3208 is to be used for a final right shift is placed in *POST_SHIFT_PTR.
3210 Using this function, x/D will be equal to (x * m) >> (*POST_SHIFT_PTR),
3211 where m is the full HOST_BITS_PER_WIDE_INT + 1 bit multiplier. */
3213 static
3214 unsigned HOST_WIDE_INT
3217 {
3225 /* lgup = ceil(log2(divisor)); */
3233 /* We could handle this with some effort, but this case is much
3234 better handled directly with a scc insn, so rely on caller using
3235 that. */
3238 /* mlow = 2^(N + lgup)/d */
3240 {
3243 }
3244 else
3245 {
3248 }
3252 /* mhigh = (2^(N + lgup) + 2^N + lgup - precision)/d */
3255 else
3262 /* Assert that mlow < mhigh. */
3266 /* If precision == N, then mlow, mhigh exceed 2^N
3267 (but they do not exceed 2^(N+1)). */
3269 /* Reduce to lowest terms. */
3271 {
3281 }
3286 {
3290 }
3291 else
3292 {
3295 }
3296 }
3298 /* Compute the inverse of X mod 2**n, i.e., find Y such that X * Y is
3299 congruent to 1 (mod 2**N). */
3301 static unsigned HOST_WIDE_INT
3303 {
3304 /* Solve x*y == 1 (mod 2^n), where x is odd. Return y. */
3306 /* The algorithm notes that the choice y = x satisfies
3307 x*y == 1 mod 2^3, since x is assumed odd.
3308 Each iteration doubles the number of bits of significance in y. */
3319 {
3322 }
3324 }
3326 /* Emit code to adjust ADJ_OPERAND after multiplication of wrong signedness
3327 flavor of OP0 and OP1. ADJ_OPERAND is already the high half of the
3328 product OP0 x OP1. If UNSIGNEDP is nonzero, adjust the signed product
3329 to become unsigned, if UNSIGNEDP is zero, adjust the unsigned product to
3330 become signed.
3332 The result is put in TARGET if that is convenient.
3334 MODE is the mode of operation. */
3336 rtx
3339 {
3340 rtx tem;
3347 adj_operand
3349 adj_operand);
3356 target);
3359 }
3361 /* Subroutine of expand_mult_highpart. Return the MODE high part of OP. */
3363 static rtx
3365 {
3377 }
3379 /* Like expand_mult_highpart, but only consider using a multiplication
3380 optab. OP1 is an rtx for the constant operand. */
3382 static rtx
3385 {
3388 optab moptab;
3389 rtx tem;
3397 /* Firstly, try using a multiplication insn that only generates the needed
3398 high part of the product, and in the sign flavor of unsignedp. */
3400 {
3406 }
3408 /* Secondly, same as above, but use sign flavor opposite of unsignedp.
3409 Need to adjust the result after the multiplication. */
3413 {
3418 /* We used the wrong signedness. Adjust the result. */
3421 }
3423 /* Try widening multiplication. */
3427 {
3432 }
3434 /* Try widening the mode and perform a non-widening multiplication. */
3438 {
3441 /* We need to widen the operands, for example to ensure the
3442 constant multiplier is correctly sign or zero extended.
3443 Use a sequence to clean-up any instructions emitted by
3444 the conversions if things don't work out. */
3454 {
3457 }
3458 }
3460 /* Try widening multiplication of opposite signedness, and adjust. */
3466 {
3470 {
3472 /* We used the wrong signedness. Adjust the result. */
3475 }
3476 }
3479 }
3481 /* Emit code to multiply OP0 and OP1 (where OP1 is an integer constant),
3482 putting the high half of the result in TARGET if that is convenient,
3483 and return where the result is. If the operation can not be performed,
3484 0 is returned.
3486 MODE is the mode of operation and result.
3488 UNSIGNEDP nonzero means unsigned multiply.
3490 MAX_COST is the total allowed cost for the expanded RTL. */
3492 static rtx
3495 {
3502 rtx tem;
3505 /* We can't support modes wider than HOST_BITS_PER_INT. */
3510 /* We can't optimize modes wider than BITS_PER_WORD.
3511 ??? We might be able to perform double-word arithmetic if
3512 mode == word_mode, however all the cost calculations in
3513 synth_mult etc. assume single-word operations. */
3520 /* Check whether we try to multiply by a negative constant. */
3522 {
3525 }
3527 /* See whether shift/add multiplication is cheap enough. */
3530 {
3531 /* See whether the specialized multiplication optabs are
3532 cheaper than the shift/add version. */
3542 /* Adjust result for signedness. */
3547 }
3550 }
3553 /* Expand signed modulus of OP0 by a power of two D in mode MODE. */
3555 static rtx
3557 {
3565 /* Avoid conditional branches when they're expensive. */
3568 {
3572 {
3577 /* Use the rtx_cost of a LSHIFTRT instruction to determine
3578 which instruction sequence to use. If logical right shifts
3579 are expensive the use 2 XORs, 2 SUBs and an AND, otherwise
3580 use a LSHIFTRT, 1 ADD, 1 SUB and an AND. */
3585 {
3596 }
3597 else
3598 {
3609 }
3611 }
3612 }
3614 /* Mask contains the mode's signbit and the significant bits of the
3615 modulus. By including the signbit in the operation, many targets
3616 can avoid an explicit compare operation in the following comparison
3617 against zero. */
3621 {
3624 }
3625 else
3651 }
3653 /* Expand signed division of OP0 by a power of two D in mode MODE.
3654 This routine is only called for positive values of D. */
3656 static rtx
3658 {
3660 tree shift;
3667 {
3673 }
3675 #ifdef HAVE_conditional_move
3677 {
3678 rtx temp2;
3680 /* ??? emit_conditional_move forces a stack adjustment via
3681 compare_from_rtx so, if the sequence is discarded, it will
3682 be lost. Do it now instead. */
3691 /* Construct "temp2 = (temp2 < 0) ? temp : temp2". */
3695 {
3700 }
3702 }
3703 #endif
3706 {
3714 else
3721 }
3729 }
3730 \f
3731 /* Emit the code to divide OP0 by OP1, putting the result in TARGET
3732 if that is convenient, and returning where the result is.
3733 You may request either the quotient or the remainder as the result;
3734 specify REM_FLAG nonzero to get the remainder.
3736 CODE is the expression code for which kind of division this is;
3737 it controls how rounding is done. MODE is the machine mode to use.
3738 UNSIGNEDP nonzero means do unsigned division. */
3740 /* ??? For CEIL_MOD_EXPR, can compute incorrect remainder with ANDI
3741 and then correct it by or'ing in missing high bits
3742 if result of ANDI is nonzero.
3743 For ROUND_MOD_EXPR, can use ANDI and then sign-extend the result.
3744 This could optimize to a bfexts instruction.
3745 But C doesn't use these operations, so their optimizations are
3746 left for later. */
3747 /* ??? For modulo, we don't actually need the highpart of the first product,
3748 the low part will do nicely. And for small divisors, the second multiply
3749 can also be a low-part only multiply or even be completely left out.
3750 E.g. to calculate the remainder of a division by 3 with a 32 bit
3751 multiply, multiply with 0x55555556 and extract the upper two bits;
3752 the result is exact for inputs up to 0x1fffffff.
3753 The input range can be reduced by using cross-sum rules.
3754 For odd divisors >= 3, the following table gives right shift counts
3755 so that if a number is shifted by an integer multiple of the given
3756 amount, the remainder stays the same:
3757 2, 4, 3, 6, 10, 12, 4, 8, 18, 6, 11, 20, 18, 0, 5, 10, 12, 0, 12, 20,
3758 14, 12, 23, 21, 8, 0, 20, 18, 0, 0, 6, 12, 0, 22, 0, 18, 20, 30, 0, 0,
3759 0, 8, 0, 11, 12, 10, 36, 0, 30, 0, 0, 12, 0, 0, 0, 0, 44, 12, 24, 0,
3760 20, 0, 7, 14, 0, 18, 36, 0, 0, 46, 60, 0, 42, 0, 15, 24, 20, 0, 0, 33,
3761 0, 20, 0, 0, 18, 0, 60, 0, 0, 0, 0, 0, 40, 18, 0, 0, 12
3763 Cross-sum rules for even numbers can be derived by leaving as many bits
3764 to the right alone as the divisor has zeros to the right.
3765 E.g. if x is an unsigned 32 bit number:
3766 (x mod 12) == (((x & 1023) + ((x >> 8) & ~3)) * 0x15555558 >> 2 * 3) >> 28
3767 */
3769 rtx
3772 {
3774 rtx tquotient;
3776 rtx last;
3787 {
3793 }
3795 /*
3796 This is the structure of expand_divmod:
3798 First comes code to fix up the operands so we can perform the operations
3799 correctly and efficiently.
3801 Second comes a switch statement with code specific for each rounding mode.
3802 For some special operands this code emits all RTL for the desired
3803 operation, for other cases, it generates only a quotient and stores it in
3804 QUOTIENT. The case for trunc division/remainder might leave quotient = 0,
3805 to indicate that it has not done anything.
3807 Last comes code that finishes the operation. If QUOTIENT is set and
3808 REM_FLAG is set, the remainder is computed as OP0 - QUOTIENT * OP1. If
3809 QUOTIENT is not set, it is computed using trunc rounding.
3811 We try to generate special code for division and remainder when OP1 is a
3812 constant. If |OP1| = 2**n we can use shifts and some other fast
3813 operations. For other values of OP1, we compute a carefully selected
3814 fixed-point approximation m = 1/OP1, and generate code that multiplies OP0
3815 by m.
3817 In all cases but EXACT_DIV_EXPR, this multiplication requires the upper
3818 half of the product. Different strategies for generating the product are
3819 implemented in expand_mult_highpart.
3821 If what we actually want is the remainder, we generate that by another
3822 by-constant multiplication and a subtraction. */
3824 /* We shouldn't be called with OP1 == const1_rtx, but some of the
3825 code below will malfunction if we are, so check here and handle
3826 the special case if so. */
3830 /* When dividing by -1, we could get an overflow.
3831 negv_optab can handle overflows. */
3833 {
3838 }
3841 /* Don't use the function value register as a target
3842 since we have to read it as well as write it,
3843 and function-inlining gets confused by this. */
3845 /* Don't clobber an operand while doing a multi-step calculation. */
3853 /* Get the mode in which to perform this computation. Normally it will
3854 be MODE, but sometimes we can't do the desired operation in MODE.
3855 If so, pick a wider mode in which we can do the operation. Convert
3856 to that mode at the start to avoid repeated conversions.
3858 First see what operations we need. These depend on the expression
3859 we are evaluating. (We assume that divxx3 insns exist under the
3860 same conditions that modxx3 insns and that these insns don't normally
3861 fail. If these assumptions are not correct, we may generate less
3862 efficient code in some cases.)
3864 Then see if we find a mode in which we can open-code that operation
3865 (either a division, modulus, or shift). Finally, check for the smallest
3866 mode for which we can do the operation with a library call. */
3868 /* We might want to refine this now that we have division-by-constant
3869 optimization. Since expand_mult_highpart tries so many variants, it is
3870 not straightforward to generalize this. Maybe we should make an array
3871 of possible modes in init_expmed? Save this for GCC 2.7. */
3877 ? optab1
3893 /* If we still couldn't find a mode, use MODE, but expand_binop will
3894 probably die. */
3900 else
3904 #if 0
3905 /* It should be possible to restrict the precision to GET_MODE_BITSIZE
3906 (mode), and thereby get better code when OP1 is a constant. Do that
3907 later. It will require going over all usages of SIZE below. */
3909 #endif
3911 /* Only deduct something for a REM if the last divide done was
3912 for a different constant. Then set the constant of the last
3913 divide. */
3921 /* Now convert to the best mode to use. */
3923 {
3927 /* convert_modes may have placed op1 into a register, so we
3928 must recompute the following. */
3930 op1_is_pow2 = (op1_is_constant
3932 || (! unsignedp
3934 }
3936 /* If one of the operands is a volatile MEM, copy it into a register. */
3943 /* If we need the remainder or if OP1 is constant, we need to
3944 put OP0 in a register in case it has any queued subexpressions. */
3950 /* Promote floor rounding to trunc rounding for unsigned operations. */
3952 {
3959 }
3963 {
3967 {
3969 {
3973 rtx ml;
3978 {
3981 {
3982 remainder
3986 OPTAB_LIB_WIDEN);
3989 }
3992 pre_shift),
3994 }
3996 {
3998 {
3999 /* Most significant bit of divisor is set; emit an scc
4000 insn. */
4005 }
4006 else
4007 {
4008 /* Find a suitable multiplier and right shift count
4009 instead of multiplying with D. */
4014 /* If the suggested multiplier is more than SIZE bits,
4015 we can do better for even divisors, using an
4016 initial right shift. */
4018 {
4024 }
4025 else
4029 {
4035 extra_cost
4046 NULL_RTX);
4047 t3 = expand_shift
4053 NULL_RTX);
4054 quotient = expand_shift
4058 }
4059 else
4060 {
4067 t1 = expand_shift
4071 extra_cost
4079 quotient = expand_shift
4083 }
4084 }
4085 }
4094 REG_EQUAL,
4096 }
4098 {
4101 rtx mlr;
4105 /* Since d might be INT_MIN, we have to cast to
4106 unsigned HOST_WIDE_INT before negating to avoid
4107 undefined signed overflow. */
4112 /* n rem d = n rem -d */
4114 {
4117 }
4125 {
4126 /* This case is not handled correctly below. */
4131 }
4135 /* We assume that cheap metric is true if the
4136 optab has an expander for this mode. */
4139 compute_mode)->insn_code
4142 compute_mode)
4144 ;
4146 {
4148 {
4152 }
4162 compute_mode),
4164 else
4167 /* We have computed OP0 / abs(OP1). If OP1 is negative,
4168 negate the quotient. */
4170 {
4178 REG_EQUAL,
4180 op0,
4181 GEN_INT
4182 (trunc_int_for_mode
4184 compute_mode))));
4188 }
4189 }
4191 {
4196 {
4211 t2 = expand_shift
4215 t3 = expand_shift
4220 quotient
4223 tquotient);
4224 else
4225 quotient
4228 tquotient);
4229 }
4230 else
4231 {
4250 NULL_RTX);
4251 t3 = expand_shift
4255 t4 = expand_shift
4260 quotient
4263 tquotient);
4264 else
4265 quotient
4268 tquotient);
4269 }
4270 }
4279 REG_EQUAL,
4281 }
4283 }
4284 fail1:
4290 /* We will come here only for signed operations. */
4292 {
4296 rtx ml;
4299 {
4300 /* We could just as easily deal with negative constants here,
4301 but it does not seem worth the trouble for GCC 2.6. */
4303 {
4306 {
4312 }
4313 quotient = expand_shift
4317 }
4318 else
4319 {
4328 {
4329 t1 = expand_shift
4342 {
4343 t4 = expand_shift
4349 OPTAB_WIDEN);
4350 }
4351 }
4352 }
4353 }
4354 else
4355 {
4361 nsign = expand_shift
4366 NULL_RTX);
4370 {
4371 rtx t5;
4376 tquotient);
4377 }
4378 }
4379 }
4385 /* Try using an instruction that produces both the quotient and
4386 remainder, using truncation. We can easily compensate the quotient
4387 or remainder to get floor rounding, once we have the remainder.
4388 Notice that we compute also the final remainder value here,
4389 and return the result right away. */
4394 {
4395 remainder
4398 }
4399 else
4400 {
4401 quotient
4404 }
4408 {
4409 /* This could be computed with a branch-less sequence.
4410 Save that for later. */
4411 rtx tem;
4421 }
4423 /* No luck with division elimination or divmod. Have to do it
4424 by conditionally adjusting op0 *and* the result. */
4425 {
4427 rtx adjusted_op0;
4428 rtx tem;
4466 }
4472 {
4474 {
4487 {
4488 rtx lab;
4494 }
4495 else
4498 tquotient);
4500 }
4502 /* Try using an instruction that produces both the quotient and
4503 remainder, using truncation. We can easily compensate the
4504 quotient or remainder to get ceiling rounding, once we have the
4505 remainder. Notice that we compute also the final remainder
4506 value here, and return the result right away. */
4511 {
4515 }
4516 else
4517 {
4521 }
4525 {
4526 /* This could be computed with a branch-less sequence.
4527 Save that for later. */
4535 }
4537 /* No luck with division elimination or divmod. Have to do it
4538 by conditionally adjusting op0 *and* the result. */
4539 {
4560 }
4561 }
4563 {
4566 {
4567 /* This is extremely similar to the code for the unsigned case
4568 above. For 2.7 we should merge these variants, but for
4569 2.6.1 I don't want to touch the code for unsigned since that
4570 get used in C. The signed case will only be used by other
4571 languages (Ada). */
4585 {
4586 rtx lab;
4592 }
4593 else
4596 tquotient);
4598 }
4600 /* Try using an instruction that produces both the quotient and
4601 remainder, using truncation. We can easily compensate the
4602 quotient or remainder to get ceiling rounding, once we have the
4603 remainder. Notice that we compute also the final remainder
4604 value here, and return the result right away. */
4608 {
4612 }
4613 else
4614 {
4618 }
4622 {
4623 /* This could be computed with a branch-less sequence.
4624 Save that for later. */
4625 rtx tem;
4636 }
4638 /* No luck with division elimination or divmod. Have to do it
4639 by conditionally adjusting op0 *and* the result. */
4640 {
4642 rtx adjusted_op0;
4643 rtx tem;
4683 }
4684 }
4689 {
4693 rtx t1;
4706 REG_EQUAL,
4708 compute_mode,
4710 }
4716 {
4717 rtx tem;
4718 rtx label;
4723 {
4724 rtx tem;
4730 }
4739 }
4740 else
4741 {
4743 rtx label;
4748 {
4749 rtx tem;
4755 }
4778 }
4783 }
4786 {
4791 {
4792 /* Try to produce the remainder without producing the quotient.
4793 If we seem to have a divmod pattern that does not require widening,
4794 don't try widening here. We should really have a WIDEN argument
4795 to expand_twoval_binop, since what we'd really like to do here is
4796 1) try a mod insn in compute_mode
4797 2) try a divmod insn in compute_mode
4798 3) try a div insn in compute_mode and multiply-subtract to get
4799 remainder
4800 4) try the same things with widening allowed. */
4801 remainder
4804 unsignedp,
4809 {
4810 /* No luck there. Can we do remainder and divide at once
4811 without a library call? */
4814 ? udivmod_optab
4819 }
4823 }
4825 /* Produce the quotient. Try a quotient insn, but not a library call.
4826 If we have a divmod in this mode, use it in preference to widening
4827 the div (for this test we assume it will not fail). Note that optab2
4828 is set to the one of the two optabs that the call below will use. */
4829 quotient
4832 unsignedp,
4838 {
4839 /* No luck there. Try a quotient-and-remainder insn,
4840 keeping the quotient alone. */
4845 {
4848 /* Still no luck. If we are not computing the remainder,
4849 use a library call for the quotient. */
4854 }
4855 }
4856 }
4859 {
4864 {
4865 /* No divide instruction either. Use library for remainder. */
4869 /* No remainder function. Try a quotient-and-remainder
4870 function, keeping the remainder. */
4872 {
4880 }
4881 }
4882 else
4883 {
4884 /* We divided. Now finish doing X - Y * (X / Y). */
4889 OPTAB_LIB_WIDEN);
4890 }
4891 }
4894 }
4895 \f
4896 /* Return a tree node with data type TYPE, describing the value of X.
4897 Usually this is an VAR_DECL, if there is no obvious better choice.
4898 X may be an expression, however we only support those expressions
4899 generated by loop.c. */
4901 tree
4903 {
4904 tree t;
4907 {
4909 {
4921 }
4927 else
4928 {
4929 REAL_VALUE_TYPE d;
4933 }
4938 {
4945 /* Build a tree with vector elements. */
4947 {
4950 }
4953 }
4989 else
5014 /* else fall through. */
5019 /* If TYPE is a POINTER_TYPE, X might be Pmode with TYPE_MODE being
5020 ptr_mode. So convert. */
5024 /* Note that we do *not* use SET_DECL_RTL here, because we do not
5025 want set_decl_rtl to go adjusting REG_ATTRS for this temporary. */
5029 }
5030 }
5031 \f
5032 /* Compute the logical-and of OP0 and OP1, storing it in TARGET
5033 and returning TARGET.
5035 If TARGET is 0, a pseudo-register or constant is returned. */
5037 rtx
5039 {
5052 }
5053 \f
5054 /* Helper function for emit_store_flag. */
5055 static rtx
5058 {
5059 rtx op0;
5062 /* If we are converting to a wider mode, first convert to
5063 TARGET_MODE, then normalize. This produces better combining
5064 opportunities on machines that have a SIGN_EXTRACT when we are
5065 testing a single bit. This mostly benefits the 68k.
5067 If STORE_FLAG_VALUE does not have the sign bit set when
5068 interpreted in MODE, we can do this conversion as unsigned, which
5069 is usually more efficient. */
5071 {
5079 }
5080 else
5083 /* If we want to keep subexpressions around, don't reuse our last
5084 target. */
5088 /* Now normalize to the proper value in MODE. Sometimes we don't
5089 have to do anything. */
5091 ;
5092 /* STORE_FLAG_VALUE might be the most negative number, so write
5093 the comparison this way to avoid a compiler-time warning. */
5097 /* We don't want to use STORE_FLAG_VALUE < 0 below since this makes
5098 it hard to use a value of just the sign bit due to ANSI integer
5099 constant typing rules. */
5101 && (STORE_FLAG_VALUE
5106 else
5107 {
5113 }
5115 /* If we were converting to a smaller mode, do the conversion now. */
5117 {
5120 }
5121 else
5123 }
5125 /* Emit a store-flags instruction for comparison CODE on OP0 and OP1
5126 and storing in TARGET. Normally return TARGET.
5127 Return 0 if that cannot be done.
5129 MODE is the mode to use for OP0 and OP1 should they be CONST_INTs. If
5130 it is VOIDmode, they cannot both be CONST_INT.
5132 UNSIGNEDP is for the case where we have to widen the operands
5133 to perform the operation. It says to use zero-extension.
5135 NORMALIZEP is 1 if we should convert the result to be either zero
5136 or one. Normalize is -1 if we should convert the result to be
5137 either zero or -1. If NORMALIZEP is zero, the result will be left
5138 "raw" out of the scc insn. */
5140 rtx
5143 {
5144 rtx subtarget;
5148 rtx tem;
5155 /* If one operand is constant, make it the second one. Only do this
5156 if the other operand is not constant as well. */
5159 {
5164 }
5169 /* For some comparisons with 1 and -1, we can convert this to
5170 comparisons with zero. This will often produce more opportunities for
5171 store-flag insns. */
5174 {
5201 }
5203 /* If we are comparing a double-word integer with zero or -1, we can
5204 convert the comparison into one involving a single word. */
5208 {
5211 {
5214 /* Do a logical OR or AND of the two words and compare the
5215 result. */
5221 OPTAB_DIRECT);
5226 }
5228 {
5229 rtx op0h;
5231 /* If testing the sign bit, can just test on high word. */
5234 mode));
5237 }
5238 }
5240 /* If this is A < 0 or A >= 0, we can do this by taking the ones
5241 complement of A (for GE) and shifting the sign bit to the low bit. */
5249 {
5252 /* If the result is to be wider than OP0, it is best to convert it
5253 first. If it is to be narrower, it is *incorrect* to convert it
5254 first. */
5256 {
5259 }
5270 /* If we are supposed to produce a 0/1 value, we want to do
5271 a logical shift from the sign bit to the low-order bit; for
5272 a -1/0 value, we do an arithmetic shift. */
5281 }
5286 {
5287 insn_operand_predicate_fn pred;
5289 /* We think we may be able to do this with a scc insn. Emit the
5290 comparison and then the scc insn. */
5295 comparison
5298 {
5300 {
5306 #ifdef FLOAT_STORE_FLAG_VALUE
5311 #endif
5314 }
5321 }
5323 /* The code of COMPARISON may not match CODE if compare_from_rtx
5324 decided to swap its operands and reverse the original code.
5326 We know that compare_from_rtx returns either a CONST_INT or
5327 a new comparison code, so it is safe to just extract the
5328 code from COMPARISON. */
5331 /* Get a reference to the target in the proper mode for this insn. */
5340 {
5343 normalizep);
5344 }
5345 }
5346 else
5347 {
5348 /* We don't have an scc insn, so try a cstore insn. */
5352 {
5356 }
5359 {
5360 enum machine_mode result_mode
5369 {
5371 unsignedp);
5373 unsignedp);
5374 }
5377 compare_mode))
5381 compare_mode))
5385 cstore_op1);
5393 cstore_op1);
5396 {
5399 normalizep);
5400 }
5401 }
5402 }
5406 /* If optimizing, use different pseudo registers for each insn, instead
5407 of reusing the same pseudo. This leads to better CSE, but slows
5408 down the compiler, since there are more pseudos */
5409 subtarget = (!optimize
5412 /* If we reached here, we can't do this with a scc insn. However, there
5413 are some comparisons that can be done directly. For example, if
5414 this is an equality comparison of integers, we can try to exclusive-or
5415 (or subtract) the two operands and use a recursive call to try the
5416 comparison with zero. Don't do any of these cases if branches are
5417 very cheap. */
5422 {
5424 OPTAB_WIDEN);
5428 OPTAB_WIDEN);
5435 }
5437 /* Some other cases we can do are EQ, NE, LE, and GT comparisons with
5438 the constant zero. Reject all other comparisons at this point. Only
5439 do LE and GT if branches are expensive since they are expensive on
5440 2-operand machines. */
5448 /* See what we need to return. We can only return a 1, -1, or the
5449 sign bit. */
5452 {
5459 ;
5460 else
5462 }
5464 /* Try to put the result of the comparison in the sign bit. Assume we can't
5465 do the necessary operation below. */
5469 /* To see if A <= 0, compute (A | (A - 1)). A <= 0 iff that result has
5470 the sign bit set. */
5473 {
5474 /* This is destructive, so SUBTARGET can't be OP0. */
5479 OPTAB_WIDEN);
5482 OPTAB_WIDEN);
5483 }
5485 /* To see if A > 0, compute (((signed) A) << BITS) - A, where BITS is the
5486 number of bits in the mode of OP0, minus one. */
5489 {
5497 OPTAB_WIDEN);
5498 }
5501 {
5502 /* For EQ or NE, one way to do the comparison is to apply an operation
5503 that converts the operand into a positive number if it is nonzero
5504 or zero if it was originally zero. Then, for EQ, we subtract 1 and
5505 for NE we negate. This puts the result in the sign bit. Then we
5506 normalize with a shift, if needed.
5508 Two operations that can do the above actions are ABS and FFS, so try
5509 them. If that doesn't work, and MODE is smaller than a full word,
5510 we can use zero-extension to the wider mode (an unsigned conversion)
5511 as the operation. */
5513 /* Note that ABS doesn't yield a positive number for INT_MIN, but
5514 that is compensated by the subsequent overflow when subtracting
5515 one / negating. */
5522 {
5525 }
5528 {
5532 else
5534 }
5536 /* If we couldn't do it that way, for NE we can "or" the two's complement
5537 of the value with itself. For EQ, we take the one's complement of
5538 that "or", which is an extra insn, so we only handle EQ if branches
5539 are expensive. */
5542 {
5548 OPTAB_WIDEN);
5552 }
5553 }
5561 {
5563 {
5566 }
5568 {
5571 }
5572 }
5573 else
5577 }
5579 /* Like emit_store_flag, but always succeeds. */
5581 rtx
5584 {
5587 /* First see if emit_store_flag can do the job. */
5595 /* If this failed, we have to do this with set/compare/jump/set code. */
5610 }
5611 \f
5612 /* Perform possibly multi-word comparison and conditional jump to LABEL
5613 if ARG1 OP ARG2 true where ARG1 and ARG2 are of mode MODE. This is
5614 now a thin wrapper around do_compare_rtx_and_jump. */
5616 static void
5618 rtx label)
5619 {
5623 }