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[/] [or1k/] [trunk/] [uclinux/] [uClinux-2.0.x/] [fs/] [dcache.c] - Blame information for rev 1765

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Line No. Rev Author Line
1 199 simons
/*
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 *  linux/fs/dcache.c
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 *
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 *  (C) Copyright 1994 Linus Torvalds
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 */
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/*
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 * The directory cache is a "two-level" cache, each level doing LRU on
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 * its entries.  Adding new entries puts them at the end of the LRU
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 * queue on the first-level cache, while the second-level cache is
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 * fed by any cache hits.
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 *
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 * The idea is that new additions (from readdir(), for example) will not
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 * flush the cache of entries that have really been used.
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 *
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 * There is a global hash-table over both caches that hashes the entries
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 * based on the directory inode number and device as well as on a
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 * string-hash computed over the name.
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 */
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#include <linux/fs.h>
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#include <linux/string.h>
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/*
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 * Don't bother caching long names.. They just take up space in the cache, and
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 * for a name cache you just want to cache the "normal" names anyway which tend
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 * to be short.
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 */
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#define DCACHE_NAME_LEN 15
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#ifdef CONFIG_REDUCED_MEMORY
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#define DCACHE_SIZE 128
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#else /* !CONFIG_REDUCED_MEMORY */
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#define DCACHE_SIZE 32
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#endif /* !CONFIG_REDUCED_MEMORY */
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struct hash_list {
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        struct dir_cache_entry * next;
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        struct dir_cache_entry * prev;
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};
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/*
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 * The dir_cache_entry must be in this order: we do ugly things with the pointers
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 */
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struct dir_cache_entry {
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        struct hash_list h;
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        kdev_t dc_dev;
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        unsigned long dir;
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        unsigned long version;
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        unsigned long ino;
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        unsigned char name_len;
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        char name[DCACHE_NAME_LEN];
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        struct dir_cache_entry ** lru_head;
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        struct dir_cache_entry * next_lru,  * prev_lru;
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};
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#define dcache_offset(x) ((unsigned long)&((struct dir_cache_entry*)0)->x)
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#define dcache_datalen (dcache_offset(lru_head) - dcache_offset(dc_dev))
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#define COPYDATA(de, newde) \
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memcpy((void *) &newde->dc_dev, (void *) &de->dc_dev, dcache_datalen)
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static struct dir_cache_entry level1_cache[DCACHE_SIZE];
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static struct dir_cache_entry level2_cache[DCACHE_SIZE];
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/*
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 * The LRU-lists are doubly-linked circular lists, and do not change in size
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 * so these pointers always have something to point to (after _init)
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 */
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static struct dir_cache_entry * level1_head;
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static struct dir_cache_entry * level2_head;
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/*
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 * The hash-queues are also doubly-linked circular lists, but the head is
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 * itself on the doubly-linked list, not just a pointer to the first entry.
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 */
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#define DCACHE_HASH_QUEUES 32
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#define hash_fn(dev,dir,namehash) ((HASHDEV(dev) ^ (dir) ^ (namehash)) % DCACHE_HASH_QUEUES)
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static struct hash_list hash_table[DCACHE_HASH_QUEUES];
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static inline void remove_lru(struct dir_cache_entry * de)
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{
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        struct dir_cache_entry * next = de->next_lru;
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        struct dir_cache_entry * prev = de->prev_lru;
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        next->prev_lru = prev;
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        prev->next_lru = next;
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}
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static inline void add_lru(struct dir_cache_entry * de, struct dir_cache_entry *head)
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{
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        struct dir_cache_entry * prev = head->prev_lru;
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        de->next_lru = head;
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        de->prev_lru = prev;
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        prev->next_lru = de;
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        head->prev_lru = de;
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}
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static inline void update_lru(struct dir_cache_entry * de)
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{
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        if (de == *de->lru_head)
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                *de->lru_head = de->next_lru;
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        else {
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                remove_lru(de);
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                add_lru(de,*de->lru_head);
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        }
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}
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/*
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 * Stupid name"hash" algorithm. Write something better if you want to,
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 * but I doubt it matters that much
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 */
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static inline unsigned long namehash(const char * name, int len)
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{
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        return len +
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                ((const unsigned char *) name)[0]+
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                ((const unsigned char *) name)[len-1];
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}
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/*
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 * Hash queue manipulation. Look out for the casts..
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 */
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static inline void remove_hash(struct dir_cache_entry * de)
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{
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        struct dir_cache_entry * next = de->h.next;
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        if (next) {
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                struct dir_cache_entry * prev = de->h.prev;
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                next->h.prev = prev;
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                prev->h.next = next;
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                de->h.next = NULL;
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        }
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}
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static inline void add_hash(struct dir_cache_entry * de, struct hash_list * hash)
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{
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        struct dir_cache_entry * next = hash->next;
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        de->h.next = next;
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        de->h.prev = (struct dir_cache_entry *) hash;
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        next->h.prev = de;
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        hash->next = de;
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}
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/*
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 * Find a directory cache entry given all the necessary info.
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 */
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static inline struct dir_cache_entry * find_entry(struct inode * dir, const char * name, int len, struct hash_list * hash)
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{
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        struct dir_cache_entry * de = hash->next;
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        for (de = hash->next ; de != (struct dir_cache_entry *) hash ; de = de->h.next) {
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                if (de->dc_dev != dir->i_dev)
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                        continue;
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                if (de->dir != dir->i_ino)
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                        continue;
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                if (de->version != dir->i_version)
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                        continue;
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                if (de->name_len != len)
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                        continue;
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                if (memcmp(de->name, name, len))
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                        continue;
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                return de;
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        }
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        return NULL;
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}
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/*
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 * Move a successfully used entry to level2. If already at level2,
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 * move it to the end of the LRU queue..
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 */
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static inline void move_to_level2(struct dir_cache_entry * old_de, struct hash_list * hash)
173
{
174
        struct dir_cache_entry * de;
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176
        if (old_de->lru_head == &level2_head) {
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                update_lru(old_de);
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                return;
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        }
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        de = level2_head;
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        level2_head = de->next_lru;
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        remove_hash(de);
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        COPYDATA(old_de, de);
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        add_hash(de, hash);
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}
186
 
187
int dcache_lookup(struct inode * dir, const char * name, int len, unsigned long * ino)
188
{
189
        struct hash_list * hash;
190
        struct dir_cache_entry *de;
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192
        if (len > DCACHE_NAME_LEN)
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                return 0;
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        hash = hash_table + hash_fn(dir->i_dev, dir->i_ino, namehash(name,len));
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        de = find_entry(dir, name, len, hash);
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        if (!de)
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                return 0;
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        *ino = de->ino;
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        move_to_level2(de, hash);
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        return 1;
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}
202
 
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void dcache_add(struct inode * dir, const char * name, int len, unsigned long ino)
204
{
205
        struct hash_list * hash;
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        struct dir_cache_entry *de;
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208
        if (len > DCACHE_NAME_LEN)
209
                return;
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        hash = hash_table + hash_fn(dir->i_dev, dir->i_ino, namehash(name,len));
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        if ((de = find_entry(dir, name, len, hash)) != NULL) {
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                de->ino = ino;
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                update_lru(de);
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                return;
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        }
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        de = level1_head;
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        level1_head = de->next_lru;
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        remove_hash(de);
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        de->dc_dev = dir->i_dev;
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        de->dir = dir->i_ino;
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        de->version = dir->i_version;
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        de->ino = ino;
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        de->name_len = len;
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        memcpy(de->name, name, len);
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        add_hash(de, hash);
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}
227
 
228
unsigned long name_cache_init(unsigned long mem_start, unsigned long mem_end)
229
{
230
        int i;
231
        struct dir_cache_entry * p;
232
 
233
        /*
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         * Init level1 LRU lists..
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         */
236
        p = level1_cache;
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        do {
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                p[1].prev_lru = p;
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                p[0].next_lru = p+1;
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                p[0].lru_head = &level1_head;
241
        } while (++p < level1_cache + DCACHE_SIZE-1);
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        level1_cache[0].prev_lru = p;
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        p[0].next_lru = &level1_cache[0];
244
        p[0].lru_head = &level1_head;
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        level1_head = level1_cache;
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247
        /*
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         * Init level2 LRU lists..
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         */
250
        p = level2_cache;
251
        do {
252
                p[1].prev_lru = p;
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                p[0].next_lru = p+1;
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                p[0].lru_head = &level2_head;
255
        } while (++p < level2_cache + DCACHE_SIZE-1);
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        level2_cache[0].prev_lru = p;
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        p[0].next_lru = &level2_cache[0];
258
        p[0].lru_head = &level2_head;
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        level2_head = level2_cache;
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261
        /*
262
         * Empty hash queues..
263
         */
264
        for (i = 0 ; i < DCACHE_HASH_QUEUES ; i++)
265
                hash_table[i].next = hash_table[i].next =
266
                        (struct dir_cache_entry *) &hash_table[i];
267
        return mem_start;
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}

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