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171bdaca69
The sha1_entry_pos function tries to be smart about selecting the middle of a range for its binary search by looking at the value differences between the "lo" and "hi" constraints. However, it is unable to cope with entries with duplicate keys in the sorted list. We may hit a point in the search where both our "lo" and "hi" point to the same key. In this case, the range of values between our endpoints is 0, and trying to scale the difference between our key and the endpoints over that range is undefined (i.e., divide by zero). The current code catches this with an "assert(lov < hiv)". Moreover, after seeing that the first 20 byte of the key are the same, we will try to establish a value from the 21st byte. Which is nonsensical. Instead, we can detect the case that we are in a run of duplicates, and simply do a final comparison against any one of them (since they are all the same, it does not matter which). If the keys match, we have found our entry (or one of them, anyway). If not, then we know that we do not need to look further, as we must be in a run of the duplicate key. Signed-off-by: Jeff King <peff@peff.net> Acked-by: Nicolas Pitre <nico@fluxnic.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
320 lines
9.3 KiB
C
320 lines
9.3 KiB
C
#include "cache.h"
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#include "sha1-lookup.h"
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static uint32_t take2(const unsigned char *sha1)
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{
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return ((sha1[0] << 8) | sha1[1]);
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}
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/*
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* Conventional binary search loop looks like this:
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*
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* do {
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* int mi = (lo + hi) / 2;
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* int cmp = "entry pointed at by mi" minus "target";
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* if (!cmp)
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* return (mi is the wanted one)
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* if (cmp > 0)
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* hi = mi; "mi is larger than target"
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* else
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* lo = mi+1; "mi is smaller than target"
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* } while (lo < hi);
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*
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* The invariants are:
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*
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* - When entering the loop, lo points at a slot that is never
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* above the target (it could be at the target), hi points at a
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* slot that is guaranteed to be above the target (it can never
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* be at the target).
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*
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* - We find a point 'mi' between lo and hi (mi could be the same
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* as lo, but never can be the same as hi), and check if it hits
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* the target. There are three cases:
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*
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* - if it is a hit, we are happy.
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*
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* - if it is strictly higher than the target, we update hi with
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* it.
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*
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* - if it is strictly lower than the target, we update lo to be
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* one slot after it, because we allow lo to be at the target.
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*
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* When choosing 'mi', we do not have to take the "middle" but
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* anywhere in between lo and hi, as long as lo <= mi < hi is
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* satisfied. When we somehow know that the distance between the
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* target and lo is much shorter than the target and hi, we could
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* pick mi that is much closer to lo than the midway.
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*/
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/*
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* The table should contain "nr" elements.
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* The sha1 of element i (between 0 and nr - 1) should be returned
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* by "fn(i, table)".
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*/
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int sha1_pos(const unsigned char *sha1, void *table, size_t nr,
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sha1_access_fn fn)
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{
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size_t hi = nr;
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size_t lo = 0;
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size_t mi = 0;
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if (!nr)
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return -1;
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if (nr != 1) {
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size_t lov, hiv, miv, ofs;
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for (ofs = 0; ofs < 18; ofs += 2) {
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lov = take2(fn(0, table) + ofs);
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hiv = take2(fn(nr - 1, table) + ofs);
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miv = take2(sha1 + ofs);
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if (miv < lov)
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return -1;
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if (hiv < miv)
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return -1 - nr;
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if (lov != hiv) {
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/*
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* At this point miv could be equal
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* to hiv (but sha1 could still be higher);
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* the invariant of (mi < hi) should be
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* kept.
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*/
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mi = (nr - 1) * (miv - lov) / (hiv - lov);
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if (lo <= mi && mi < hi)
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break;
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die("BUG: assertion failed in binary search");
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}
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}
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if (18 <= ofs)
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die("cannot happen -- lo and hi are identical");
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}
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do {
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int cmp;
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cmp = hashcmp(fn(mi, table), sha1);
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if (!cmp)
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return mi;
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if (cmp > 0)
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hi = mi;
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else
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lo = mi + 1;
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mi = (hi + lo) / 2;
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} while (lo < hi);
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return -lo-1;
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}
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/*
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* Conventional binary search loop looks like this:
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*
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* unsigned lo, hi;
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* do {
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* unsigned mi = (lo + hi) / 2;
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* int cmp = "entry pointed at by mi" minus "target";
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* if (!cmp)
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* return (mi is the wanted one)
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* if (cmp > 0)
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* hi = mi; "mi is larger than target"
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* else
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* lo = mi+1; "mi is smaller than target"
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* } while (lo < hi);
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*
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* The invariants are:
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*
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* - When entering the loop, lo points at a slot that is never
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* above the target (it could be at the target), hi points at a
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* slot that is guaranteed to be above the target (it can never
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* be at the target).
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*
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* - We find a point 'mi' between lo and hi (mi could be the same
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* as lo, but never can be as same as hi), and check if it hits
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* the target. There are three cases:
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*
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* - if it is a hit, we are happy.
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*
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* - if it is strictly higher than the target, we set it to hi,
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* and repeat the search.
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*
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* - if it is strictly lower than the target, we update lo to
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* one slot after it, because we allow lo to be at the target.
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*
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* If the loop exits, there is no matching entry.
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*
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* When choosing 'mi', we do not have to take the "middle" but
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* anywhere in between lo and hi, as long as lo <= mi < hi is
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* satisfied. When we somehow know that the distance between the
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* target and lo is much shorter than the target and hi, we could
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* pick mi that is much closer to lo than the midway.
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*
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* Now, we can take advantage of the fact that SHA-1 is a good hash
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* function, and as long as there are enough entries in the table, we
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* can expect uniform distribution. An entry that begins with for
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* example "deadbeef..." is much likely to appear much later than in
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* the midway of the table. It can reasonably be expected to be near
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* 87% (222/256) from the top of the table.
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*
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* However, we do not want to pick "mi" too precisely. If the entry at
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* the 87% in the above example turns out to be higher than the target
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* we are looking for, we would end up narrowing the search space down
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* only by 13%, instead of 50% we would get if we did a simple binary
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* search. So we would want to hedge our bets by being less aggressive.
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*
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* The table at "table" holds at least "nr" entries of "elem_size"
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* bytes each. Each entry has the SHA-1 key at "key_offset". The
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* table is sorted by the SHA-1 key of the entries. The caller wants
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* to find the entry with "key", and knows that the entry at "lo" is
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* not higher than the entry it is looking for, and that the entry at
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* "hi" is higher than the entry it is looking for.
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*/
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int sha1_entry_pos(const void *table,
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size_t elem_size,
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size_t key_offset,
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unsigned lo, unsigned hi, unsigned nr,
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const unsigned char *key)
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{
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const unsigned char *base = table;
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const unsigned char *hi_key, *lo_key;
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unsigned ofs_0;
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static int debug_lookup = -1;
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if (debug_lookup < 0)
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debug_lookup = !!getenv("GIT_DEBUG_LOOKUP");
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if (!nr || lo >= hi)
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return -1;
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if (nr == hi)
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hi_key = NULL;
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else
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hi_key = base + elem_size * hi + key_offset;
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lo_key = base + elem_size * lo + key_offset;
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ofs_0 = 0;
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do {
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int cmp;
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unsigned ofs, mi, range;
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unsigned lov, hiv, kyv;
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const unsigned char *mi_key;
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range = hi - lo;
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if (hi_key) {
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for (ofs = ofs_0; ofs < 20; ofs++)
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if (lo_key[ofs] != hi_key[ofs])
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break;
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ofs_0 = ofs;
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/*
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* byte 0 thru (ofs-1) are the same between
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* lo and hi; ofs is the first byte that is
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* different.
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*
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* If ofs==20, then no bytes are different,
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* meaning we have entries with duplicate
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* keys. We know that we are in a solid run
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* of this entry (because the entries are
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* sorted, and our lo and hi are the same,
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* there can be nothing but this single key
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* in between). So we can stop the search.
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* Either one of these entries is it (and
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* we do not care which), or we do not have
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* it.
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*
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* Furthermore, we know that one of our
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* endpoints must be the edge of the run of
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* duplicates. For example, given this
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* sequence:
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*
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* idx 0 1 2 3 4 5
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* key A C C C C D
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*
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* If we are searching for "B", we might
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* hit the duplicate run at lo=1, hi=3
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* (e.g., by first mi=3, then mi=0). But we
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* can never have lo > 1, because B < C.
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* That is, if our key is less than the
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* run, we know that "lo" is the edge, but
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* we can say nothing of "hi". Similarly,
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* if our key is greater than the run, we
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* know that "hi" is the edge, but we can
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* say nothing of "lo".
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*
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* Therefore if we do not find it, we also
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* know where it would go if it did exist:
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* just on the far side of the edge that we
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* know about.
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*/
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if (ofs == 20) {
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mi = lo;
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mi_key = base + elem_size * mi + key_offset;
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cmp = memcmp(mi_key, key, 20);
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if (!cmp)
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return mi;
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if (cmp < 0)
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return -1 - hi;
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else
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return -1 - lo;
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}
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hiv = hi_key[ofs_0];
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if (ofs_0 < 19)
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hiv = (hiv << 8) | hi_key[ofs_0+1];
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} else {
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hiv = 256;
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if (ofs_0 < 19)
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hiv <<= 8;
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}
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lov = lo_key[ofs_0];
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kyv = key[ofs_0];
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if (ofs_0 < 19) {
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lov = (lov << 8) | lo_key[ofs_0+1];
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kyv = (kyv << 8) | key[ofs_0+1];
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}
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assert(lov < hiv);
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if (kyv < lov)
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return -1 - lo;
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if (hiv < kyv)
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return -1 - hi;
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/*
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* Even if we know the target is much closer to 'hi'
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* than 'lo', if we pick too precisely and overshoot
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* (e.g. when we know 'mi' is closer to 'hi' than to
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* 'lo', pick 'mi' that is higher than the target), we
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* end up narrowing the search space by a smaller
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* amount (i.e. the distance between 'mi' and 'hi')
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* than what we would have (i.e. about half of 'lo'
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* and 'hi'). Hedge our bets to pick 'mi' less
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* aggressively, i.e. make 'mi' a bit closer to the
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* middle than we would otherwise pick.
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*/
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kyv = (kyv * 6 + lov + hiv) / 8;
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if (lov < hiv - 1) {
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if (kyv == lov)
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kyv++;
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else if (kyv == hiv)
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kyv--;
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}
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mi = (range - 1) * (kyv - lov) / (hiv - lov) + lo;
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if (debug_lookup) {
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printf("lo %u hi %u rg %u mi %u ", lo, hi, range, mi);
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printf("ofs %u lov %x, hiv %x, kyv %x\n",
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ofs_0, lov, hiv, kyv);
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}
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if (!(lo <= mi && mi < hi))
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die("assertion failure lo %u mi %u hi %u %s",
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lo, mi, hi, sha1_to_hex(key));
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mi_key = base + elem_size * mi + key_offset;
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cmp = memcmp(mi_key + ofs_0, key + ofs_0, 20 - ofs_0);
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if (!cmp)
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return mi;
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if (cmp > 0) {
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hi = mi;
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hi_key = mi_key;
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} else {
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lo = mi + 1;
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lo_key = mi_key + elem_size;
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}
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} while (lo < hi);
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return -lo-1;
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}
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