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/*
 * Copyright (C) 2001 Ximian Inc.
 *
 * Authors: Michael Zucchi <notzed@ximian.com>
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of version 2 of the GNU General Public
 * License as published by the Free Software Foundation.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * General Public License for more details.
 *
 * You should have received a copy of the GNU General Public
 * License along with this program; if not, write to the
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 * Boston, MA 02111-1307, USA.
 */

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

#include <sys/stat.h>
#include <sys/uio.h>
#include <unistd.h>
#include <errno.h>
#include <string.h>
#include <stdlib.h>

#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>

#include "e-util/e-msgport.h"

#include "camel-block-file.h"
#include "camel-partition-table.h"

/* Do we synchronously write table updates - makes the
   tables consistent after program crash without sync */
#define SYNC_UPDATES

#ifdef ENABLE_THREADS
#include <pthread.h>
#endif

#define d(x) /*(printf("%s(%d):%s: ",  __FILE__, __LINE__, __PRETTY_FUNCTION__),(x))*/
/* key index debug */
#define k(x) /*(printf("%s(%d):%s: ",  __FILE__, __LINE__, __PRETTY_FUNCTION__),(x))*/

#ifdef ENABLE_THREADS

struct _CamelPartitionTablePrivate {
    pthread_mutex_t lock;   /* for locking partition */
};

#define CAMEL_PARTITION_TABLE_LOCK(kf, lock) (pthread_mutex_lock(&(kf)->priv->lock))
#define CAMEL_PARTITION_TABLE_UNLOCK(kf, lock) (pthread_mutex_unlock(&(kf)->priv->lock))
#else
#define CAMEL_PARTITION_TABLE_LOCK(kf, lock)
#define CAMEL_PARTITION_TABLE_UNLOCK(kf, lock)
#endif

static void
camel_partition_table_class_init(CamelPartitionTableClass *klass)
{
}

static void
camel_partition_table_init(CamelPartitionTable *cpi)
{
    struct _CamelPartitionTablePrivate *p;

    e_dlist_init(&cpi->partition);

    p = cpi->priv = g_malloc0(sizeof(*cpi->priv));
#ifdef ENABLE_THREADS
    pthread_mutex_init(&p->lock, NULL);
#endif
}

static void
camel_partition_table_finalise(CamelPartitionTable *cpi)
{
    CamelBlock *bl;
    struct _CamelPartitionTablePrivate *p;

    p = cpi->priv;

    if (cpi->blocks) {
        camel_block_file_sync(cpi->blocks);
        while ((bl = (CamelBlock *)e_dlist_remhead(&cpi->partition))) {
            camel_block_file_sync_block(cpi->blocks, bl);
            camel_block_file_unref_block(cpi->blocks, bl);
        }

        camel_object_unref((CamelObject *)cpi->blocks);
    }

#ifdef ENABLE_THREADS
    pthread_mutex_destroy(&p->lock);
#endif
    g_free(p);

}

CamelType
camel_partition_table_get_type(void)
{
    static CamelType type = CAMEL_INVALID_TYPE;
    
    if (type == CAMEL_INVALID_TYPE) {
        type = camel_type_register(camel_object_get_type(), "CamelPartitionTable",
                       sizeof (CamelPartitionTable),
                       sizeof (CamelPartitionTableClass),
                       (CamelObjectClassInitFunc) camel_partition_table_class_init,
                       NULL,
                       (CamelObjectInitFunc) camel_partition_table_init,
                       (CamelObjectFinalizeFunc) camel_partition_table_finalise);
    }
    
    return type;
}

/* ********************************************************************** */

/*
  Have 2 hashes:
  Name -> nameid
  Word -> wordid

nameid is pointer to name file, includes a bit to say if name is deleted
wordid is a pointer to word file, includes pointer to start of word entries

delete a name -> set it as deleted, do nothing else though

lookup word, if nameid is deleted, mark it in wordlist as unused and mark for write (?)
*/

/* ********************************************************************** */

/* This simple hash seems to work quite well */
static camel_hash_t hash_key(const char *key)
{
    camel_hash_t hash = 0xABADF00D;

    while (*key) {
        hash = hash * (*key) ^ (*key);
        key++;
    }

    return hash;
}

/* Call with lock held */
static CamelBlock *find_partition(CamelPartitionTable *cpi, camel_hash_t id, int *indexp)
{
    int index, jump;
    CamelBlock *bl;
    CamelPartitionMapBlock *ptb;
    CamelPartitionMap *part;

    /* first, find the block this key might be in, then binary search the block */
    bl = (CamelBlock *)cpi->partition.head;
    while (bl->next) {
        ptb = (CamelPartitionMapBlock *)&bl->data;
        part = ptb->partition;
        if (ptb->used > 0 && id <= part[ptb->used-1].hashid) {
            index = ptb->used/2;
            jump = ptb->used/4;

            if (jump == 0)
                jump = 1;

            while (1) {
                if (id <= part[index].hashid) {
                    if (index == 0 || id > part[index-1].hashid)
                        break;
                    index -= jump;
                } else {
                    if (index >= ptb->used-1)
                        break;
                    index += jump;
                }
                jump = jump/2;
                if (jump == 0)
                    jump = 1;
            }
            *indexp = index;

            return bl;
        }
        bl = bl->next;
    }

    g_warning("could not find a partition that could fit !  partition table corrupt!");

    /* This should never be reached */

    return NULL;
}

CamelPartitionTable *camel_partition_table_new(struct _CamelBlockFile *bs, camel_block_t root)
{
    CamelPartitionTable *cpi;
    CamelPartitionMapBlock *ptb;
    CamelPartitionKeyBlock *kb;
    CamelBlock *block, *pblock;

    cpi = (CamelPartitionTable *)camel_object_new(camel_partition_table_get_type());
    cpi->rootid = root;
    cpi->blocks = bs;
    camel_object_ref((CamelObject *)bs);

    /* read the partition table into memory */
    do {
        block = camel_block_file_get_block(bs, root);
        if (block == NULL)
            goto fail;

        ptb = (CamelPartitionMapBlock *)&block->data;

        d(printf("Adding partition block, used = %d, hashid = %08x\n", ptb->used, ptb->partition[0].hashid));

        /* if we have no data, prime initial block */
        if (ptb->used == 0 && e_dlist_empty(&cpi->partition) && ptb->next == 0) {
            pblock = camel_block_file_new_block(bs);
            if (pblock == NULL) {
                camel_block_file_unref_block(bs, block);
                goto fail;
            }
            kb = (CamelPartitionKeyBlock *)&pblock->data;
            kb->used = 0;
            ptb->used = 1;
            ptb->partition[0].hashid = 0xffffffff;
            ptb->partition[0].blockid = pblock->id;
            camel_block_file_touch_block(bs, pblock);
            camel_block_file_unref_block(bs, pblock);
            camel_block_file_touch_block(bs, block);
#ifdef SYNC_UPDATES
            camel_block_file_sync_block(bs, block);
#endif
        }

        root = ptb->next;
        camel_block_file_detach_block(bs, block);
        e_dlist_addtail(&cpi->partition, (EDListNode *)block);
    } while (root);

    return cpi;

fail:
    camel_object_unref((CamelObject *)cpi);
    return NULL;
}

camel_key_t camel_partition_table_lookup(CamelPartitionTable *cpi, const char *key)
{
    CamelPartitionKeyBlock *pkb;
    CamelPartitionMapBlock *ptb;
    CamelBlock *block, *ptblock;
    camel_hash_t hashid;
    camel_key_t keyid = 0;
    int index, i;

    hashid = hash_key(key);

    CAMEL_PARTITION_TABLE_LOCK(cpi, lock);

    ptblock = find_partition(cpi, hashid, &index);
    if (ptblock == NULL) {
        CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
        return 0;
    }
    ptb = (CamelPartitionMapBlock *)&ptblock->data;
    block = camel_block_file_get_block(cpi->blocks, ptb->partition[index].blockid);
    if (block == NULL) {
        CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
        return 0;
    }

    pkb = (CamelPartitionKeyBlock *)&block->data;

    /* What to do about duplicate hash's? */
    for (i=0;i<pkb->used;i++) {
        if (pkb->keys[i].hashid == hashid) {
            /* !! need to: lookup and compare string value */
            /* get_key() if key == key ... */
            keyid = pkb->keys[i].keyid;
            break;
        }
    }

    CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
    
    camel_block_file_unref_block(cpi->blocks, block);

    return keyid;
}

void camel_partition_table_remove(CamelPartitionTable *cpi, const char *key)
{
    CamelPartitionKeyBlock *pkb;
    CamelPartitionMapBlock *ptb;
    CamelBlock *block, *ptblock;
    camel_hash_t hashid;
    camel_key_t keyid = 0;
    int index, i;

    hashid = hash_key(key);

    CAMEL_PARTITION_TABLE_LOCK(cpi, lock);
    
    ptblock = find_partition(cpi, hashid, &index);
    if (ptblock == NULL) {
        CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
        return;
    }
    ptb = (CamelPartitionMapBlock *)&ptblock->data;
    block = camel_block_file_get_block(cpi->blocks, ptb->partition[index].blockid);
    if (block == NULL) {
        CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
        return;
    }
    pkb = (CamelPartitionKeyBlock *)&block->data;

    /* What to do about duplicate hash's? */
    for (i=0;i<pkb->used;i++) {
        if (pkb->keys[i].hashid == hashid) {
            /* !! need to: lookup and compare string value */
            /* get_key() if key == key ... */
            keyid = pkb->keys[i].keyid;

            /* remove this key */
            pkb->used--;
            for (;i<pkb->used;i++) {
                pkb->keys[i].keyid = pkb->keys[i+1].keyid;
                pkb->keys[i].hashid = pkb->keys[i+1].hashid;
            }
            camel_block_file_touch_block(cpi->blocks, block);
            break;
        }
    }

    CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
    
    camel_block_file_unref_block(cpi->blocks, block);
}

static int
keys_cmp(const void *ap, const void *bp)
{
    const CamelPartitionKey *a = ap;
    const CamelPartitionKey *b = bp;

    if (a->hashid < b->hashid)
        return -1;
    else if (a->hashid > b->hashid)
        return 1;

    return 0;
}

int
camel_partition_table_add(CamelPartitionTable *cpi, const char *key, camel_key_t keyid)
{
    camel_hash_t hashid, partid;
    int index, newindex = 0; /* initialisation of this and pkb/nkb is just to silence compiler */
    CamelPartitionMapBlock *ptb, *ptn;
    CamelPartitionKeyBlock *kb, *newkb, *nkb = NULL, *pkb = NULL;
    CamelBlock *block, *ptblock, *ptnblock;
    int i, half, len;
    struct _CamelPartitionKey keys[CAMEL_BLOCK_SIZE/4];
    int ret = -1;

#define KEY_SIZE (sizeof(kb->keys)/sizeof(kb->keys[0]))

    hashid = hash_key(key);

    CAMEL_PARTITION_TABLE_LOCK(cpi, lock);
    ptblock = find_partition(cpi, hashid, &index);
    if (ptblock == NULL) {
        CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
        return -1;
    }
    ptb = (CamelPartitionMapBlock *)&ptblock->data;
    block = camel_block_file_get_block(cpi->blocks, ptb->partition[index].blockid);
    if (block == NULL) {
        CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);
        return -1;
    }
    kb = (CamelPartitionKeyBlock *)&block->data;

    /* TODO: Keep the key array in sorted order, cheaper lookups and split operation */

    if (kb->used < sizeof(kb->keys)/sizeof(kb->keys[0])) {
        /* Have room, just put it in */
        kb->keys[kb->used].hashid = hashid;
        kb->keys[kb->used].keyid = keyid;
        kb->used++;
    } else {
        CamelBlock *newblock = NULL, *nblock = NULL, *pblock = NULL;

        /* Need to split?  See if previous or next has room, then split across that instead */

        /* TODO: Should look at next/previous partition table block as well ... */

        if (index > 0) {
            pblock = camel_block_file_get_block(cpi->blocks, ptb->partition[index-1].blockid);
            if (pblock == NULL)
                goto fail;
            pkb = (CamelPartitionKeyBlock *)&pblock->data;
        }
        if (index < (ptb->used-1)) {
            nblock = camel_block_file_get_block(cpi->blocks, ptb->partition[index+1].blockid);
            if (nblock == NULL) {
                if (pblock)
                    camel_block_file_unref_block(cpi->blocks, pblock);
                goto fail;
            }
            nkb = (CamelPartitionKeyBlock *)&nblock->data;
        }

        if (pblock && pkb->used < KEY_SIZE) {
            if (nblock && nkb->used < KEY_SIZE) {
                if (pkb->used < nkb->used) {
                    newindex = index+1;
                    newblock = nblock;
                } else {
                    newindex = index-1;
                    newblock = pblock;
                }
            } else {
                newindex = index-1;
                newblock = pblock;
            }
        } else {
            if (nblock && nkb->used < KEY_SIZE) {
                newindex = index+1;
                newblock = nblock;
            }
        }

        /* We had no room, need to split across another block */
        if (newblock == NULL) {
            /* See if we have room in the partition table for this block or need to split that too */
            if (ptb->used >= sizeof(ptb->partition)/sizeof(ptb->partition[0])) {
                /* TODO: Could check next block to see if it'll fit there first */
                ptnblock = camel_block_file_new_block(cpi->blocks);
                if (ptnblock == NULL) {
                    if (nblock)
                        camel_block_file_unref_block(cpi->blocks, nblock);
                    if (pblock)
                        camel_block_file_unref_block(cpi->blocks, pblock);
                    goto fail;
                }
                camel_block_file_detach_block(cpi->blocks, ptnblock);

                /* split block and link on-disk, always sorted */
                ptn = (CamelPartitionMapBlock *)&ptnblock->data;
                ptn->next = ptb->next;
                ptb->next = ptnblock->id;
                len = ptb->used / 2;
                ptn->used = ptb->used - len;
                ptb->used = len;
                memcpy(ptn->partition, &ptb->partition[len], ptn->used * sizeof(ptb->partition[0]));

                /* link in-memory */
                ptnblock->next = ptblock->next;
                ptblock->next->prev = ptblock;
                ptblock->next = ptnblock;
                ptnblock->prev = ptblock;

                /* write in right order to ensure structure */
                camel_block_file_touch_block(cpi->blocks, ptnblock);
#ifdef SYNC_UPDATES
                camel_block_file_sync_block(cpi->blocks, ptnblock);
#endif
                if (index > len) {
                    camel_block_file_touch_block(cpi->blocks, ptblock);
#ifdef SYNC_UPDATES
                    camel_block_file_sync_block(cpi->blocks, ptblock);
#endif
                    index -= len;
                    ptb = ptn;
                    ptblock = ptnblock;
                }
            }

            /* try get newblock before modifying existing */
            newblock = camel_block_file_new_block(cpi->blocks);
            if (newblock == NULL) {
                if (nblock)
                    camel_block_file_unref_block(cpi->blocks, nblock);
                if (pblock)
                    camel_block_file_unref_block(cpi->blocks, pblock);
                goto fail;
            }

            for (i=ptb->used-1;i>index;i--) {
                ptb->partition[i+1].hashid = ptb->partition[i].hashid;
                ptb->partition[i+1].blockid = ptb->partition[i].blockid;
            }
            ptb->used++;

            newkb = (CamelPartitionKeyBlock *)&newblock->data;
            newkb->used = 0;
            newindex = index+1;

            ptb->partition[newindex].hashid = ptb->partition[index].hashid;
            ptb->partition[newindex].blockid = newblock->id;

            if (nblock)
                camel_block_file_unref_block(cpi->blocks, nblock);
            if (pblock)
                camel_block_file_unref_block(cpi->blocks, pblock);
        } else {
            newkb = (CamelPartitionKeyBlock *)&newblock->data;

            if (newblock == pblock) {
                if (nblock)
                    camel_block_file_unref_block(cpi->blocks, nblock);
            } else {
                if (pblock)
                    camel_block_file_unref_block(cpi->blocks, pblock);
            }
        }

        /* sort keys to find midpoint */
        len = kb->used;
        memcpy(keys, kb->keys, sizeof(kb->keys[0])*len);
        memcpy(keys+len, newkb->keys, sizeof(newkb->keys[0])*newkb->used);
        len += newkb->used;
        keys[len].hashid = hashid;
        keys[len].keyid = keyid;
        len++;
        qsort(keys, len, sizeof(keys[0]), keys_cmp);

        /* Split keys, fix partition table */
        half = len/2;
        partid = keys[half-1].hashid;

        if (index < newindex) {
            memcpy(kb->keys, keys, sizeof(keys[0])*half);
            kb->used = half;
            memcpy(newkb->keys, keys+half, sizeof(keys[0])*(len-half));
            newkb->used = len-half;
            ptb->partition[index].hashid = partid;
        } else {
            memcpy(newkb->keys, keys, sizeof(keys[0])*half);
            newkb->used = half;
            memcpy(kb->keys, keys+half, sizeof(keys[0])*(len-half));
            kb->used = len-half;
            ptb->partition[newindex].hashid = partid;
        }

        camel_block_file_touch_block(cpi->blocks, ptblock);
#ifdef SYNC_UPDATES
        camel_block_file_sync_block(cpi->blocks, ptblock);
#endif
        camel_block_file_touch_block(cpi->blocks, newblock);
        camel_block_file_unref_block(cpi->blocks, newblock);
    }

    camel_block_file_touch_block(cpi->blocks, block);
    camel_block_file_unref_block(cpi->blocks, block);

    ret = 0;
fail:
    CAMEL_PARTITION_TABLE_UNLOCK(cpi, lock);

    return ret;
}

/* ********************************************************************** */


#ifdef ENABLE_THREADS

struct _CamelKeyTablePrivate {
    pthread_mutex_t lock;   /* for locking key */
};

#define CAMEL_KEY_TABLE_LOCK(kf, lock) (pthread_mutex_lock(&(kf)->priv->lock))
#define CAMEL_KEY_TABLE_UNLOCK(kf, lock) (pthread_mutex_unlock(&(kf)->priv->lock))
#else
#define CAMEL_KEY_TABLE_LOCK(kf, lock)
#define CAMEL_KEY_TABLE_UNLOCK(kf, lock)
#endif

static void
camel_key_table_class_init(CamelKeyTableClass *klass)
{
}

static void
camel_key_table_init(CamelKeyTable *ki)
{
    struct _CamelKeyTablePrivate *p;

    p = ki->priv = g_malloc0(sizeof(*ki->priv));
#ifdef ENABLE_THREADS
    pthread_mutex_init(&p->lock, NULL);
#endif
}

static void
camel_key_table_finalise(CamelKeyTable *ki)
{
    struct _CamelKeyTablePrivate *p;

    p = ki->priv;

    if (ki->blocks) {
        if (ki->root_block)
            camel_block_file_unref_block(ki->blocks, ki->root_block);
        camel_block_file_sync(ki->blocks);
        camel_object_unref((CamelObject *)ki->blocks);
    }

#ifdef ENABLE_THREADS
    pthread_mutex_destroy(&p->lock);
#endif
    g_free(p);

}

CamelType
camel_key_table_get_type(void)
{
    static CamelType type = CAMEL_INVALID_TYPE;
    
    if (type == CAMEL_INVALID_TYPE) {
        type = camel_type_register(camel_object_get_type(), "CamelKeyTable",
                       sizeof (CamelKeyTable),
                       sizeof (CamelKeyTableClass),
                       (CamelObjectClassInitFunc) camel_key_table_class_init,
                       NULL,
                       (CamelObjectInitFunc) camel_key_table_init,
                       (CamelObjectFinalizeFunc) camel_key_table_finalise);
    }
    
    return type;
}


CamelKeyTable *
camel_key_table_new(CamelBlockFile *bs, camel_block_t root)
{
    CamelKeyTable *ki;

    ki = (CamelKeyTable *)camel_object_new(camel_key_table_get_type());

    ki->blocks = bs;
    camel_object_ref((CamelObject *)bs);
    ki->rootid = root;

    ki->root_block = camel_block_file_get_block(bs, ki->rootid);
    if (ki->root_block == NULL) {
        camel_object_unref((CamelObject *)ki);
        ki = NULL;
    } else {
        camel_block_file_detach_block(bs, ki->root_block);
        ki->root = (CamelKeyRootBlock *)&ki->root_block->data;

        k(printf("Opening key index\n"));
        k(printf(" first %u\n last %u\n free %u\n", ki->root->first, ki->root->last, ki->root->free));
    }

    return ki;
}

camel_key_t
camel_key_table_add(CamelKeyTable *ki, const char *key, camel_block_t data, unsigned int flags)
{
    CamelBlock *last, *next;
    CamelKeyBlock *kblast, *kbnext;
    int len, left;
    unsigned int offset;
    camel_key_t keyid = 0;

    /* Maximum key size = 128 chars */
    len = strlen(key);
    if (len > CAMEL_KEY_TABLE_MAX_KEY)
        len = 128;

    CAMEL_KEY_TABLE_LOCK(ki, lock);

    if (ki->root->last == 0) {
        last = camel_block_file_new_block(ki->blocks);
        if (last == NULL)
            goto fail;
        ki->root->last = ki->root->first = last->id;
        camel_block_file_touch_block(ki->blocks, ki->root_block);
        k(printf("adding first block, first = %u\n", ki->root->first));
    } else {
        last = camel_block_file_get_block(ki->blocks, ki->root->last);
        if (last == NULL)
            goto fail;
    }

    kblast = (CamelKeyBlock *)&last->data;

    if (kblast->used >= 127)
        goto fail;

    if (kblast->used > 0) {
        left = &kblast->u.keydata[kblast->u.keys[kblast->used-1].offset] - (char *)(&kblast->u.keys[kblast->used+1]);
        d(printf("used = %d (%d), filled = %d, left = %d  len = %d?\n",
             kblast->used, kblast->used * sizeof(kblast->u.keys[0]),
             sizeof(kblast->u.keydata) - kblast->u.keys[kblast->used-1].offset,
             left, len));
        if (left < len) {
            next = camel_block_file_new_block(ki->blocks);
            if (next == NULL) {
                camel_block_file_unref_block(ki->blocks, last);
                goto fail;
            }
            kbnext = (CamelKeyBlock *)&next->data;
            kblast->next = next->id;
            ki->root->last = next->id;
            k(printf("adding new block, first = %u, last = %u\n", ki->root->first, ki->root->last));
            camel_block_file_touch_block(ki->blocks, ki->root_block);
            camel_block_file_touch_block(ki->blocks, last);
            camel_block_file_unref_block(ki->blocks, last);
            kblast = kbnext;
            last = next;
        }
    }

    if (kblast->used > 0)
        offset = kblast->u.keys[kblast->used-1].offset - len;
    else
        offset = sizeof(kblast->u.keydata)-len;

    kblast->u.keys[kblast->used].flags = flags;
    kblast->u.keys[kblast->used].data = data;
    kblast->u.keys[kblast->used].offset = offset;
    memcpy(kblast->u.keydata + offset, key, len);

    keyid = (last->id & (~(CAMEL_BLOCK_SIZE-1))) | kblast->used;

    kblast->used++;

    g_assert(kblast->used < 127);

    camel_block_file_touch_block(ki->blocks, last);
    camel_block_file_unref_block(ki->blocks, last);

#ifdef SYNC_UPDATES
    camel_block_file_sync_block(ki->blocks, ki->root_block);
#endif
fail:
    CAMEL_KEY_TABLE_UNLOCK(ki, lock);

    return keyid;
}

void
camel_key_table_set_data(CamelKeyTable *ki, camel_key_t keyid, camel_block_t data)
{
    CamelBlock *bl;
    camel_block_t blockid;
    int index;
    CamelKeyBlock *kb;

    if (keyid == 0)
        return;

    blockid =  keyid & (~(CAMEL_BLOCK_SIZE-1));
    index = keyid & (CAMEL_BLOCK_SIZE-1);

    bl = camel_block_file_get_block(ki->blocks, blockid);
    if (bl == NULL)
        return;
    kb = (CamelKeyBlock *)&bl->data;

    CAMEL_KEY_TABLE_LOCK(ki, lock);

    if (kb->u.keys[index].data != data) {
        kb->u.keys[index].data = data;
        camel_block_file_touch_block(ki->blocks, bl);
    }

    CAMEL_KEY_TABLE_UNLOCK(ki, lock);

    camel_block_file_unref_block(ki->blocks, bl);
}

void
camel_key_table_set_flags(CamelKeyTable *ki, camel_key_t keyid, unsigned int flags, unsigned int set)
{
    CamelBlock *bl;
    camel_block_t blockid;
    int index;
    CamelKeyBlock *kb;
    unsigned int old;

    if (keyid == 0)
        return;

    blockid =  keyid & (~(CAMEL_BLOCK_SIZE-1));
    index = keyid & (CAMEL_BLOCK_SIZE-1);

    bl = camel_block_file_get_block(ki->blocks, blockid);
    if (bl == NULL)
        return;
    kb = (CamelKeyBlock *)&bl->data;

    g_assert(kb->used < 127);
    g_assert(index < kb->used);

    CAMEL_KEY_TABLE_LOCK(ki, lock);

    old = kb->u.keys[index].flags;
    if ((old & set) != (flags & set)) {
        kb->u.keys[index].flags = (old & (~set)) | (flags & set);
        camel_block_file_touch_block(ki->blocks, bl);
    }

    CAMEL_KEY_TABLE_UNLOCK(ki, lock);

    camel_block_file_unref_block(ki->blocks, bl);
}

camel_block_t
camel_key_table_lookup(CamelKeyTable *ki, camel_key_t keyid, char **keyp, unsigned int *flags)
{
    CamelBlock *bl;
    camel_block_t blockid;
    int index, len, off;
    char *key;
    CamelKeyBlock *kb;

    if (keyp)
        *keyp = 0;
    if (flags)
        *flags = 0;
    if (keyid == 0)
        return 0;

    blockid =  keyid & (~(CAMEL_BLOCK_SIZE-1));
    index = keyid & (CAMEL_BLOCK_SIZE-1);

    bl = camel_block_file_get_block(ki->blocks, blockid);
    if (bl == NULL)
        return 0;

    kb = (CamelKeyBlock *)&bl->data;

    g_assert(kb->used < 127);
    g_assert(index < kb->used);

    CAMEL_KEY_TABLE_LOCK(ki, lock);

    blockid = kb->u.keys[index].data;
    if (flags)
        *flags = kb->u.keys[index].flags;

    if (keyp) {
        off = kb->u.keys[index].offset;
        if (index == 0)
            len = sizeof(kb->u.keydata) - off;
        else
            len = kb->u.keys[index-1].offset - off;
        *keyp = key = g_malloc(len+1);
        memcpy(key, kb->u.keydata + off, len);
        key[len] = 0;
    }

    CAMEL_KEY_TABLE_UNLOCK(ki, lock);

    camel_block_file_unref_block(ki->blocks, bl);

    return blockid;
}

/* iterate through all keys */
camel_key_t
camel_key_table_next(CamelKeyTable *ki, camel_key_t next, char **keyp, unsigned int *flagsp, camel_block_t *datap)
{
    CamelBlock *bl;
    CamelKeyBlock *kb;
    camel_block_t blockid;
    int index;

    if (next == 0) {
        next = ki->root->first;
        if (next == 0)
            return 0;
    } else
        next++;

    do {
        blockid =  next & (~(CAMEL_BLOCK_SIZE-1));
        index = next & (CAMEL_BLOCK_SIZE-1);
        
        bl = camel_block_file_get_block(ki->blocks, blockid);
        if (bl == NULL)
            return 0;

        kb = (CamelKeyBlock *)&bl->data;

        /* see if we need to goto the next block */
        if (index >= kb->used) {
            /* FIXME: check for loops */
            next = kb->next;
            camel_block_file_unref_block(ki->blocks, bl);
            bl = NULL;
        }
    } while (bl == NULL);

    CAMEL_KEY_TABLE_LOCK(ki, lock);

    /* invalid block data */
    if ((kb->u.keys[index].offset >= sizeof(kb->u.keydata)
         || kb->u.keys[index].offset < kb->u.keydata - (char *)&kb->u.keys[kb->used])
        || (index > 0 &&
        (kb->u.keys[index-1].offset >= sizeof(kb->u.keydata)
         || kb->u.keys[index-1].offset < kb->u.keydata - (char *)&kb->u.keys[kb->used]))) {
        g_warning("Block %u invalid scanning keys", bl->id);
        camel_block_file_unref_block(ki->blocks, bl);
        CAMEL_KEY_TABLE_UNLOCK(ki, lock);
        return 0;
    }

    if (datap)
        *datap = kb->u.keys[index].data;

    if (flagsp)
        *flagsp = kb->u.keys[index].flags;

    if (keyp) {
        int len, off = kb->u.keys[index].offset;
        char *key;

        if (index == 0)
            len = sizeof(kb->u.keydata) - off;
        else
            len = kb->u.keys[index-1].offset - off;
        *keyp = key = g_malloc(len+1);
        memcpy(key, kb->u.keydata + off, len);
        key[len] = 0;
    }

    CAMEL_KEY_TABLE_UNLOCK(ki, lock);

    camel_block_file_unref_block(ki->blocks, bl);

    return next;
}

/* ********************************************************************** */