| blob | c4cb48f77f0c6ab157ba41ec0411644a44a39ca9 |
1 /*
2 * lib/bitmap.c
3 * Helper functions for bitmap.h.
4 *
5 * This source code is licensed under the GNU General Public License,
6 * Version 2. See the file COPYING for more details.
7 */
8 #include <linux/module.h>
9 #include <linux/ctype.h>
10 #include <linux/errno.h>
11 #include <linux/bitmap.h>
12 #include <linux/bitops.h>
13 #include <asm/uaccess.h>
15 /*
16 * bitmaps provide an array of bits, implemented using an an
17 * array of unsigned longs. The number of valid bits in a
18 * given bitmap does _not_ need to be an exact multiple of
19 * BITS_PER_LONG.
20 *
21 * The possible unused bits in the last, partially used word
22 * of a bitmap are 'don't care'. The implementation makes
23 * no particular effort to keep them zero. It ensures that
24 * their value will not affect the results of any operation.
25 * The bitmap operations that return Boolean (bitmap_empty,
26 * for example) or scalar (bitmap_weight, for example) results
27 * carefully filter out these unused bits from impacting their
28 * results.
29 *
30 * These operations actually hold to a slightly stronger rule:
31 * if you don't input any bitmaps to these ops that have some
32 * unused bits set, then they won't output any set unused bits
33 * in output bitmaps.
34 *
35 * The byte ordering of bitmaps is more natural on little
36 * endian architectures. See the big-endian headers
37 * include/asm-ppc64/bitops.h and include/asm-s390/bitops.h
38 * for the best explanations of this ordering.
39 */
42 {
53 }
57 {
68 }
73 {
84 }
88 {
95 }
98 /**
99 * __bitmap_shift_right - logical right shift of the bits in a bitmap
100 * @dst : destination bitmap
101 * @src : source bitmap
102 * @shift : shift by this many bits
103 * @bits : bitmap size, in bits
104 *
105 * Shifting right (dividing) means moving bits in the MS -> LS bit
106 * direction. Zeros are fed into the vacated MS positions and the
107 * LS bits shifted off the bottom are lost.
108 */
111 {
118 /*
119 * If shift is not word aligned, take lower rem bits of
120 * word above and make them the top rem bits of result.
121 */
128 }
135 }
138 }
142 /**
143 * __bitmap_shift_left - logical left shift of the bits in a bitmap
144 * @dst : destination bitmap
145 * @src : source bitmap
146 * @shift : shift by this many bits
147 * @bits : bitmap size, in bits
148 *
149 * Shifting left (multiplying) means moving bits in the LS -> MS
150 * direction. Zeros are fed into the vacated LS bit positions
151 * and those MS bits shifted off the top are lost.
152 */
156 {
162 /*
163 * If shift is not word aligned, take upper rem bits of
164 * word below and make them the bottom rem bits of result.
165 */
168 else
176 }
179 }
184 {
190 }
195 {
201 }
206 {
212 }
217 {
223 }
228 {
238 }
243 {
253 }
257 {
267 }
270 /*
271 * Bitmap printing & parsing functions: first version by Bill Irwin,
272 * second version by Paul Jackson, third by Joe Korty.
273 */
275 #define CHUNKSZ 32
276 #define nbits_to_hold_value(val) fls(val)
280 /**
281 * bitmap_scnprintf - convert bitmap to an ASCII hex string.
282 * @buf: byte buffer into which string is placed
283 * @buflen: reserved size of @buf, in bytes
284 * @maskp: pointer to bitmap to convert
285 * @nmaskbits: size of bitmap, in bits
286 *
287 * Exactly @nmaskbits bits are displayed. Hex digits are grouped into
288 * comma-separated sets of eight digits per set.
289 */
292 {
297 u32 chunkmask;
313 }
315 }
318 /**
319 * bitmap_scnprintf_len - return buffer length needed to convert
320 * bitmap to an ASCII hex string.
321 * @len: number of bits to be converted
322 */
324 {
325 /* we need 9 chars per word for 32 bit words (8 hexdigits + sep/null) */
331 }
334 /**
335 * __bitmap_parse - convert an ASCII hex string into a bitmap.
336 * @buf: pointer to buffer containing string.
337 * @buflen: buffer size in bytes. If string is smaller than this
338 * then it must be terminated with a \0.
339 * @is_user: location of buffer, 0 indicates kernel space
340 * @maskp: pointer to bitmap array that will contain result.
341 * @nmaskbits: size of bitmap, in bits.
342 *
343 * Commas group hex digits into chunks. Each chunk defines exactly 32
344 * bits of the resultant bitmask. No chunk may specify a value larger
345 * than 32 bits (%-EOVERFLOW), and if a chunk specifies a smaller value
346 * then leading 0-bits are prepended. %-EINVAL is returned for illegal
347 * characters and for grouping errors such as "1,,5", ",44", "," and "".
348 * Leading and trailing whitespace accepted, but not embedded whitespace.
349 */
353 {
355 u32 chunk;
364 /* Get the next chunk of the bitmap */
370 }
371 else
373 buflen--;
377 /*
378 * If the last character was a space and the current
379 * character isn't '\0', we've got embedded whitespace.
380 * This is a no-no, so throw an error.
381 */
385 /* A '\0' or a ',' signal the end of the chunk */
392 /*
393 * Make sure there are at least 4 free bits in 'chunk'.
394 * If not, this hexdigit will overflow 'chunk', so
395 * throw an error.
396 */
402 }
410 nchunks++;
417 }
420 /**
421 * bitmap_parse_user()
422 *
423 * @ubuf: pointer to user buffer containing string.
424 * @ulen: buffer size in bytes. If string is smaller than this
425 * then it must be terminated with a \0.
426 * @maskp: pointer to bitmap array that will contain result.
427 * @nmaskbits: size of bitmap, in bits.
428 *
429 * Wrapper for __bitmap_parse(), providing it with user buffer.
430 *
431 * We cannot have this as an inline function in bitmap.h because it needs
432 * linux/uaccess.h to get the access_ok() declaration and this causes
433 * cyclic dependencies.
434 */
438 {
442 }
445 /*
446 * bscnl_emit(buf, buflen, rbot, rtop, bp)
447 *
448 * Helper routine for bitmap_scnlistprintf(). Write decimal number
449 * or range to buf, suppressing output past buf+buflen, with optional
450 * comma-prefix. Return len of what would be written to buf, if it
451 * all fit.
452 */
454 {
459 else
462 }
464 /**
465 * bitmap_scnlistprintf - convert bitmap to list format ASCII string
466 * @buf: byte buffer into which string is placed
467 * @buflen: reserved size of @buf, in bytes
468 * @maskp: pointer to bitmap to convert
469 * @nmaskbits: size of bitmap, in bits
470 *
471 * Output format is a comma-separated list of decimal numbers and
472 * ranges. Consecutively set bits are shown as two hyphen-separated
473 * decimal numbers, the smallest and largest bit numbers set in
474 * the range. Output format is compatible with the format
475 * accepted as input by bitmap_parselist().
476 *
477 * The return value is the number of characters which would be
478 * generated for the given input, excluding the trailing '\0', as
479 * per ISO C99.
480 */
483 {
485 /* current bit is 'cur', most recently seen range is [rbot, rtop] */
499 }
500 }
502 }
505 /**
506 * bitmap_parselist - convert list format ASCII string to bitmap
507 * @bp: read nul-terminated user string from this buffer
508 * @maskp: write resulting mask here
509 * @nmaskbits: number of bits in mask to be written
510 *
511 * Input format is a comma-separated list of decimal numbers and
512 * ranges. Consecutively set bits are shown as two hyphen-separated
513 * decimal numbers, the smallest and largest bit numbers set in
514 * the range.
515 *
516 * Returns 0 on success, -errno on invalid input strings.
517 * Error values:
518 * %-EINVAL: second number in range smaller than first
519 * %-EINVAL: invalid character in string
520 * %-ERANGE: bit number specified too large for mask
521 */
523 {
532 bp++;
536 }
543 a++;
544 }
546 bp++;
549 }
552 /**
553 * bitmap_pos_to_ord(buf, pos, bits)
554 * @buf: pointer to a bitmap
555 * @pos: a bit position in @buf (0 <= @pos < @bits)
556 * @bits: number of valid bit positions in @buf
557 *
558 * Map the bit at position @pos in @buf (of length @bits) to the
559 * ordinal of which set bit it is. If it is not set or if @pos
560 * is not a valid bit position, map to -1.
561 *
562 * If for example, just bits 4 through 7 are set in @buf, then @pos
563 * values 4 through 7 will get mapped to 0 through 3, respectively,
564 * and other @pos values will get mapped to 0. When @pos value 7
565 * gets mapped to (returns) @ord value 3 in this example, that means
566 * that bit 7 is the 3rd (starting with 0th) set bit in @buf.
567 *
568 * The bit positions 0 through @bits are valid positions in @buf.
569 */
571 {
581 ord++;
582 }
586 }
588 /**
589 * bitmap_ord_to_pos(buf, ord, bits)
590 * @buf: pointer to bitmap
591 * @ord: ordinal bit position (n-th set bit, n >= 0)
592 * @bits: number of valid bit positions in @buf
593 *
594 * Map the ordinal offset of bit @ord in @buf to its position in @buf.
595 * Value of @ord should be in range 0 <= @ord < weight(buf), else
596 * results are undefined.
597 *
598 * If for example, just bits 4 through 7 are set in @buf, then @ord
599 * values 0 through 3 will get mapped to 4 through 7, respectively,
600 * and all other @ord values return undefined values. When @ord value 3
601 * gets mapped to (returns) @pos value 7 in this example, that means
602 * that the 3rd set bit (starting with 0th) is at position 7 in @buf.
603 *
604 * The bit positions 0 through @bits are valid positions in @buf.
605 */
607 {
616 ord--;
619 }
622 }
624 /**
625 * bitmap_remap - Apply map defined by a pair of bitmaps to another bitmap
626 * @dst: remapped result
627 * @src: subset to be remapped
628 * @old: defines domain of map
629 * @new: defines range of map
630 * @bits: number of bits in each of these bitmaps
631 *
632 * Let @old and @new define a mapping of bit positions, such that
633 * whatever position is held by the n-th set bit in @old is mapped
634 * to the n-th set bit in @new. In the more general case, allowing
635 * for the possibility that the weight 'w' of @new is less than the
636 * weight of @old, map the position of the n-th set bit in @old to
637 * the position of the m-th set bit in @new, where m == n % w.
638 *
639 * If either of the @old and @new bitmaps are empty, or if @src and
640 * @dst point to the same location, then this routine copies @src
641 * to @dst.
642 *
643 * The positions of unset bits in @old are mapped to themselves
644 * (the identify map).
645 *
646 * Apply the above specified mapping to @src, placing the result in
647 * @dst, clearing any bits previously set in @dst.
648 *
649 * For example, lets say that @old has bits 4 through 7 set, and
650 * @new has bits 12 through 15 set. This defines the mapping of bit
651 * position 4 to 12, 5 to 13, 6 to 14 and 7 to 15, and of all other
652 * bit positions unchanged. So if say @src comes into this routine
653 * with bits 1, 5 and 7 set, then @dst should leave with bits 1,
654 * 13 and 15 set.
655 */
659 {
673 else
675 }
676 }
679 /**
680 * bitmap_bitremap - Apply map defined by a pair of bitmaps to a single bit
681 * @oldbit: bit position to be mapped
682 * @old: defines domain of map
683 * @new: defines range of map
684 * @bits: number of bits in each of these bitmaps
685 *
686 * Let @old and @new define a mapping of bit positions, such that
687 * whatever position is held by the n-th set bit in @old is mapped
688 * to the n-th set bit in @new. In the more general case, allowing
689 * for the possibility that the weight 'w' of @new is less than the
690 * weight of @old, map the position of the n-th set bit in @old to
691 * the position of the m-th set bit in @new, where m == n % w.
692 *
693 * The positions of unset bits in @old are mapped to themselves
694 * (the identify map).
695 *
696 * Apply the above specified mapping to bit position @oldbit, returning
697 * the new bit position.
698 *
699 * For example, lets say that @old has bits 4 through 7 set, and
700 * @new has bits 12 through 15 set. This defines the mapping of bit
701 * position 4 to 12, 5 to 13, 6 to 14 and 7 to 15, and of all other
702 * bit positions unchanged. So if say @oldbit is 5, then this routine
703 * returns 13.
704 */
707 {
712 else
714 }
717 /**
718 * bitmap_onto - translate one bitmap relative to another
719 * @dst: resulting translated bitmap
720 * @orig: original untranslated bitmap
721 * @relmap: bitmap relative to which translated
722 * @bits: number of bits in each of these bitmaps
723 *
724 * Set the n-th bit of @dst iff there exists some m such that the
725 * n-th bit of @relmap is set, the m-th bit of @orig is set, and
726 * the n-th bit of @relmap is also the m-th _set_ bit of @relmap.
727 * (If you understood the previous sentence the first time your
728 * read it, you're overqualified for your current job.)
729 *
730 * In other words, @orig is mapped onto (surjectively) @dst,
731 * using the the map { <n, m> | the n-th bit of @relmap is the
732 * m-th set bit of @relmap }.
733 *
734 * Any set bits in @orig above bit number W, where W is the
735 * weight of (number of set bits in) @relmap are mapped nowhere.
736 * In particular, if for all bits m set in @orig, m >= W, then
737 * @dst will end up empty. In situations where the possibility
738 * of such an empty result is not desired, one way to avoid it is
739 * to use the bitmap_fold() operator, below, to first fold the
740 * @orig bitmap over itself so that all its set bits x are in the
741 * range 0 <= x < W. The bitmap_fold() operator does this by
742 * setting the bit (m % W) in @dst, for each bit (m) set in @orig.
743 *
744 * Example [1] for bitmap_onto():
745 * Let's say @relmap has bits 30-39 set, and @orig has bits
746 * 1, 3, 5, 7, 9 and 11 set. Then on return from this routine,
747 * @dst will have bits 31, 33, 35, 37 and 39 set.
748 *
749 * When bit 0 is set in @orig, it means turn on the bit in
750 * @dst corresponding to whatever is the first bit (if any)
751 * that is turned on in @relmap. Since bit 0 was off in the
752 * above example, we leave off that bit (bit 30) in @dst.
753 *
754 * When bit 1 is set in @orig (as in the above example), it
755 * means turn on the bit in @dst corresponding to whatever
756 * is the second bit that is turned on in @relmap. The second
757 * bit in @relmap that was turned on in the above example was
758 * bit 31, so we turned on bit 31 in @dst.
759 *
760 * Similarly, we turned on bits 33, 35, 37 and 39 in @dst,
761 * because they were the 4th, 6th, 8th and 10th set bits
762 * set in @relmap, and the 4th, 6th, 8th and 10th bits of
763 * @orig (i.e. bits 3, 5, 7 and 9) were also set.
764 *
765 * When bit 11 is set in @orig, it means turn on the bit in
766 * @dst corresponding to whatever is the twelth bit that is
767 * turned on in @relmap. In the above example, there were
768 * only ten bits turned on in @relmap (30..39), so that bit
769 * 11 was set in @orig had no affect on @dst.
770 *
771 * Example [2] for bitmap_fold() + bitmap_onto():
772 * Let's say @relmap has these ten bits set:
773 * 40 41 42 43 45 48 53 61 74 95
774 * (for the curious, that's 40 plus the first ten terms of the
775 * Fibonacci sequence.)
776 *
777 * Further lets say we use the following code, invoking
778 * bitmap_fold() then bitmap_onto, as suggested above to
779 * avoid the possitility of an empty @dst result:
780 *
781 * unsigned long *tmp; // a temporary bitmap's bits
782 *
783 * bitmap_fold(tmp, orig, bitmap_weight(relmap, bits), bits);
784 * bitmap_onto(dst, tmp, relmap, bits);
785 *
786 * Then this table shows what various values of @dst would be, for
787 * various @orig's. I list the zero-based positions of each set bit.
788 * The tmp column shows the intermediate result, as computed by
789 * using bitmap_fold() to fold the @orig bitmap modulo ten
790 * (the weight of @relmap).
791 *
792 * @orig tmp @dst
793 * 0 0 40
794 * 1 1 41
795 * 9 9 95
796 * 10 0 40 (*)
797 * 1 3 5 7 1 3 5 7 41 43 48 61
798 * 0 1 2 3 4 0 1 2 3 4 40 41 42 43 45
799 * 0 9 18 27 0 9 8 7 40 61 74 95
800 * 0 10 20 30 0 40
801 * 0 11 22 33 0 1 2 3 40 41 42 43
802 * 0 12 24 36 0 2 4 6 40 42 45 53
803 * 78 102 211 1 2 8 41 42 74 (*)
804 *
805 * (*) For these marked lines, if we hadn't first done bitmap_fold()
806 * into tmp, then the @dst result would have been empty.
807 *
808 * If either of @orig or @relmap is empty (no set bits), then @dst
809 * will be returned empty.
810 *
811 * If (as explained above) the only set bits in @orig are in positions
812 * m where m >= W, (where W is the weight of @relmap) then @dst will
813 * once again be returned empty.
814 *
815 * All bits in @dst not set by the above rule are cleared.
816 */
819 {
826 /*
827 * The following code is a more efficient, but less
828 * obvious, equivalent to the loop:
829 * for (m = 0; m < bitmap_weight(relmap, bits); m++) {
830 * n = bitmap_ord_to_pos(orig, m, bits);
831 * if (test_bit(m, orig))
832 * set_bit(n, dst);
833 * }
834 */
840 /* m == bitmap_pos_to_ord(relmap, n, bits) */
843 m++;
844 }
845 }
848 /**
849 * bitmap_fold - fold larger bitmap into smaller, modulo specified size
850 * @dst: resulting smaller bitmap
851 * @orig: original larger bitmap
852 * @sz: specified size
853 * @bits: number of bits in each of these bitmaps
854 *
855 * For each bit oldbit in @orig, set bit oldbit mod @sz in @dst.
856 * Clear all other bits in @dst. See further the comment and
857 * Example [2] for bitmap_onto() for why and how to use this.
858 */
861 {
872 }
875 /*
876 * Common code for bitmap_*_region() routines.
877 * bitmap: array of unsigned longs corresponding to the bitmap
878 * pos: the beginning of the region
879 * order: region size (log base 2 of number of bits)
880 * reg_op: operation(s) to perform on that region of bitmap
881 *
882 * Can set, verify and/or release a region of bits in a bitmap,
883 * depending on which combination of REG_OP_* flag bits is set.
884 *
885 * A region of a bitmap is a sequence of bits in the bitmap, of
886 * some size '1 << order' (a power of two), aligned to that same
887 * '1 << order' power of two.
888 *
889 * Returns 1 if REG_OP_ISFREE succeeds (region is all zero bits).
890 * Returns 0 in all other cases and reg_ops.
891 */
897 };
900 {
910 /*
911 * Either nlongs_reg == 1 (for small orders that fit in one long)
912 * or (offset == 0 && mask == ~0UL) (for larger multiword orders.)
913 */
920 /*
921 * Can't do "mask = (1UL << nbitsinlong) - 1", as that
922 * overflows if nbitsinlong == BITS_PER_LONG.
923 */
933 }
946 }
947 done:
949 }
951 /**
952 * bitmap_find_free_region - find a contiguous aligned mem region
953 * @bitmap: array of unsigned longs corresponding to the bitmap
954 * @bits: number of bits in the bitmap
955 * @order: region size (log base 2 of number of bits) to find
956 *
957 * Find a region of free (zero) bits in a @bitmap of @bits bits and
958 * allocate them (set them to one). Only consider regions of length
959 * a power (@order) of two, aligned to that power of two, which
960 * makes the search algorithm much faster.
961 *
962 * Return the bit offset in bitmap of the allocated region,
963 * or -errno on failure.
964 */
966 {
976 }
979 /**
980 * bitmap_release_region - release allocated bitmap region
981 * @bitmap: array of unsigned longs corresponding to the bitmap
982 * @pos: beginning of bit region to release
983 * @order: region size (log base 2 of number of bits) to release
984 *
985 * This is the complement to __bitmap_find_free_region() and releases
986 * the found region (by clearing it in the bitmap).
987 *
988 * No return value.
989 */
991 {
993 }
996 /**
997 * bitmap_allocate_region - allocate bitmap region
998 * @bitmap: array of unsigned longs corresponding to the bitmap
999 * @pos: beginning of bit region to allocate
1000 * @order: region size (log base 2 of number of bits) to allocate
1001 *
1002 * Allocate (set bits in) a specified region of a bitmap.
1003 *
1004 * Return 0 on success, or %-EBUSY if specified region wasn't
1005 * free (not all bits were zero).
1006 */
1008 {
1013 }