/*

 * hash.c: hash tables

 *

 * Hash table with open addressing, linear probing and

 * Robin Hood reordering.

 *

 * See Copyright for the status of this software.

 */

#define IN_LIBXML

#include "libxml.h"

#include <string.h>

#include <limits.h>

#include <libxml/parser.h>

#include <libxml/hash.h>

#include <libxml/dict.h>

#include <libxml/xmlmemory.h>

#include <libxml/xmlstring.h>

#include "private/dict.h"

#ifndef SIZE_MAX

  #define SIZE_MAX ((size_t) -1)

#endif

#define MAX_FILL_NUM 7

#define MAX_FILL_DENOM 8

#define MIN_HASH_SIZE 8

#define MAX_HASH_SIZE (1u << 31)

/*

 * A single entry in the hash table

 */

typedef struct {

    unsigned hashValue; /* 0 means unoccupied, occupied entries have the

                         * MAX_HASH_SIZE bit set to 1 */

    xmlChar *key;

    xmlChar *key2; /* TODO: Don't allocate possibly empty keys */

    xmlChar *key3;

    void *payload;

} xmlHashEntry;

/*

 * The entire hash table

 */

struct _xmlHashTable {

    xmlHashEntry *table;

    unsigned size; /* power of two */

    unsigned nbElems;

    xmlDictPtr dict;

    unsigned randomSeed;

};

static int

xmlHashGrow(xmlHashTablePtr hash, unsigned size);

ATTRIBUTE_NO_SANITIZE_INTEGER

static unsigned

xmlHashValue(unsigned seed, const xmlChar *key, const xmlChar *key2,

             const xmlChar *key3, size_t *lengths) {

    unsigned h1, h2;

    size_t i;

    HASH_INIT(h1, h2, seed);

    for (i = 0; key[i] != 0; i++) {

        HASH_UPDATE(h1, h2, key[i]);

    }

    if (lengths)

        lengths[0] = i;

    HASH_UPDATE(h1, h2, 0);

    if (key2 != NULL) {

        for (i = 0; key2[i] != 0; i++) {

            HASH_UPDATE(h1, h2, key2[i]);

        }

        if (lengths)

            lengths[1] = i;

    }

    HASH_UPDATE(h1, h2, 0);

    if (key3 != NULL) {

        for (i = 0; key3[i] != 0; i++) {

            HASH_UPDATE(h1, h2, key3[i]);

        }

        if (lengths)

            lengths[2] = i;

    }

    HASH_FINISH(h1, h2);

    return(h2);

}

ATTRIBUTE_NO_SANITIZE_INTEGER

static unsigned

xmlHashQNameValue(unsigned seed,

                  const xmlChar *prefix, const xmlChar *name,

                  const xmlChar *prefix2, const xmlChar *name2,

                  const xmlChar *prefix3, const xmlChar *name3) {

    unsigned h1, h2, ch;

    HASH_INIT(h1, h2, seed);

    if (prefix != NULL) {

        while ((ch = *prefix++) != 0) {

            HASH_UPDATE(h1, h2, ch);

        }

        HASH_UPDATE(h1, h2, ':');

    }

    if (name != NULL) {

        while ((ch = *name++) != 0) {

            HASH_UPDATE(h1, h2, ch);

        }

    }

    HASH_UPDATE(h1, h2, 0);

    if (prefix2 != NULL) {

        while ((ch = *prefix2++) != 0) {

            HASH_UPDATE(h1, h2, ch);

        }

        HASH_UPDATE(h1, h2, ':');

    }

    if (name2 != NULL) {

        while ((ch = *name2++) != 0) {

            HASH_UPDATE(h1, h2, ch);

        }

    }

    HASH_UPDATE(h1, h2, 0);

    if (prefix3 != NULL) {

        while ((ch = *prefix3++) != 0) {

            HASH_UPDATE(h1, h2, ch);

        }

        HASH_UPDATE(h1, h2, ':');

    }

    if (name3 != NULL) {

        while ((ch = *name3++) != 0) {

            HASH_UPDATE(h1, h2, ch);

        }

    }

    HASH_FINISH(h1, h2);

    return(h2);

}

/**

 * Create a new hash table. Set size to zero if the number of entries

 * can't be estimated.

 *

 * @param size  initial size of the hash table

 * @returns the newly created object, or NULL if a memory allocation failed.

 */

xmlHashTable *

xmlHashCreate(int size) {

    xmlHashTablePtr hash;

    xmlInitParser();

    hash = xmlMalloc(sizeof(*hash));

    if (hash == NULL)

        return(NULL);

    hash->dict = NULL;

    hash->size = 0;

    hash->table = NULL;

    hash->nbElems = 0;

    hash->randomSeed = xmlRandom();

#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION

    hash->randomSeed = 0;

#endif

    /*

     * Unless a larger size is passed, the backing table is created

     * lazily with MIN_HASH_SIZE capacity. In practice, there are many

     * hash tables which are never filled.

     */

    if (size > MIN_HASH_SIZE) {

        unsigned newSize = MIN_HASH_SIZE * 2;

        while ((newSize < (unsigned) size) && (newSize < MAX_HASH_SIZE))

            newSize *= 2;

        if (xmlHashGrow(hash, newSize) != 0) {

            xmlFree(hash);

            return(NULL);

        }

    }

    return(hash);

}

/**

 * Create a new hash table backed by a dictionary. This can reduce

 * resource usage considerably if most keys passed to API functions

 * originate from this dictionary.

 *

 * @param size  the size of the hash table

 * @param dict  a dictionary to use for the hash

 * @returns the newly created object, or NULL if a memory allocation failed.

 */

xmlHashTable *

xmlHashCreateDict(int size, xmlDict *dict) {

    xmlHashTablePtr hash;

    hash = xmlHashCreate(size);

    if (hash != NULL) {

        hash->dict = dict;

        xmlDictReference(dict);

    }

    return(hash);

}

/**

 * Free the hash and its contents. The payload is deallocated with

 * `dealloc` if provided.

 *

 * @param hash  hash table

 * @param dealloc  deallocator function or NULL

 */

void

xmlHashFree(xmlHashTable *hash, xmlHashDeallocator dealloc) {

    if (hash == NULL)

        return;

    if (hash->table) {

        const xmlHashEntry *end = &hash->table[hash->size];

        const xmlHashEntry *entry;

        for (entry = hash->table; entry < end; entry++) {

            if (entry->hashValue == 0)

                continue;

            if ((dealloc != NULL) && (entry->payload != NULL))

                dealloc(entry->payload, entry->key);

            if (hash->dict == NULL) {

                if (entry->key)

                    xmlFree(entry->key);

                if (entry->key2)

                    xmlFree(entry->key2);

                if (entry->key3)

                    xmlFree(entry->key3);

            }

        }

        xmlFree(hash->table);

    }

    if (hash->dict)

        xmlDictFree(hash->dict);

    xmlFree(hash);

}

/**

 * Compare two strings for equality, allowing NULL values.

 *

 * @param s1  string

 * @param s2  string

 */

static int

xmlFastStrEqual(const xmlChar *s1, const xmlChar *s2) {

    if (s1 == NULL)

        return(s2 == NULL);

    else

        return((s2 != NULL) &&

               (strcmp((const char *) s1, (const char *) s2) == 0));

}

/**

 * Try to find a matching hash table entry. If an entry was found, set

 * `found` to 1 and return the entry. Otherwise, set `found` to 0 and return

 * the location where a new entry should be inserted.

 *

 * @param hash  hash table, non-NULL, size > 0

 * @param key  first string key, non-NULL

 * @param key2  second string key

 * @param key3  third string key

 * @param hashValue  valid hash value of keys

 * @param pfound  result of search

 */

ATTRIBUTE_NO_SANITIZE_INTEGER

static xmlHashEntry *

xmlHashFindEntry(const xmlHashTable *hash, const xmlChar *key,

                 const xmlChar *key2, const xmlChar *key3,

                 unsigned hashValue, int *pfound) {

    xmlHashEntry *entry;

    unsigned mask, pos, displ;

    int found = 0;

    mask = hash->size - 1;

    pos = hashValue & mask;

    entry = &hash->table[pos];

    if (entry->hashValue != 0) {

        /*

         * Robin hood hashing: abort if the displacement of the entry

         * is smaller than the displacement of the key we look for.

         * This also stops at the correct position when inserting.

         */

        displ = 0;

        hashValue |= MAX_HASH_SIZE;

        do {

            if (entry->hashValue == hashValue) {

                if (hash->dict) {

                    if ((entry->key == key) &&

                        (entry->key2 == key2) &&

                        (entry->key3 == key3)) {

                        found = 1;

                        break;

                    }

                }

                if ((strcmp((const char *) entry->key,

                            (const char *) key) == 0) &&

                    (xmlFastStrEqual(entry->key2, key2)) &&

                    (xmlFastStrEqual(entry->key3, key3))) {

                    found = 1;

                    break;

                }

            }

            displ++;

            pos++;

            entry++;

            if ((pos & mask) == 0)

                entry = hash->table;

        } while ((entry->hashValue != 0) &&

                 (((pos - entry->hashValue) & mask) >= displ));

    }

    *pfound = found;

    return(entry);

}

/**

 * Resize the hash table.

 *

 * @param hash  hash table

 * @param size  new size of the hash table

 * @returns 0 in case of success, -1 if a memory allocation failed.

 */

static int

xmlHashGrow(xmlHashTablePtr hash, unsigned size) {

    const xmlHashEntry *oldentry, *oldend, *end;

    xmlHashEntry *table;

    unsigned oldsize, i;

    /* Add 0 to avoid spurious -Wtype-limits warning on 64-bit GCC */

    if ((size_t) size + 0 > SIZE_MAX / sizeof(table[0]))

        return(-1);

    table = xmlMalloc(size * sizeof(table[0]));

    if (table == NULL)

        return(-1);

    memset(table, 0, size * sizeof(table[0]));

    oldsize = hash->size;

    if (oldsize == 0)

        goto done;

    oldend = &hash->table[oldsize];

    end = &table[size];

    /*

     * Robin Hood sorting order is maintained if we

     *

     * - compute hash indices with modulo

     * - resize by an integer factor

     * - start to copy from the beginning of a probe sequence

     */

    oldentry = hash->table;

    while (oldentry->hashValue != 0) {

        if (++oldentry >= oldend)

            oldentry = hash->table;

    }

    for (i = 0; i < oldsize; i++) {

        if (oldentry->hashValue != 0) {

            xmlHashEntry *entry = &table[oldentry->hashValue & (size - 1)];

            while (entry->hashValue != 0) {

                if (++entry >= end)

                    entry = table;

            }

            *entry = *oldentry;

        }

        if (++oldentry >= oldend)

            oldentry = hash->table;

    }

    xmlFree(hash->table);

done:

    hash->table = table;

    hash->size = size;

    return(0);

}

/**

 * Internal function to add or update hash entries.

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param key3  third string key

 * @param payload  pointer to the payload

 * @param dealloc  deallocator function for replaced item or NULL

 * @param update  whether existing entries should be updated

 */

ATTRIBUTE_NO_SANITIZE_INTEGER

static int

xmlHashUpdateInternal(xmlHashTable *hash, const xmlChar *key,

                      const xmlChar *key2, const xmlChar *key3,

                      void *payload, xmlHashDeallocator dealloc, int update) {

    xmlChar *copy, *copy2, *copy3;

    xmlHashEntry *entry = NULL;

    size_t lengths[3] = {0, 0, 0};

    unsigned hashValue, newSize;

    if ((hash == NULL) || (key == NULL))

        return(-1);

    hashValue = xmlHashValue(hash->randomSeed, key, key2, key3, lengths);

    /*

     * Check for an existing entry

     */

    if (hash->size == 0) {

        newSize = MIN_HASH_SIZE;

    } else {

        int found = 0;

        entry = xmlHashFindEntry(hash, key, key2, key3, hashValue, &found);

        if (found) {

            if (update) {

                if (dealloc)

                    dealloc(entry->payload, entry->key);

                entry->payload = payload;

            }

            return(0);

        }

        if (hash->nbElems + 1 > hash->size / MAX_FILL_DENOM * MAX_FILL_NUM) {

            /* This guarantees that nbElems < INT_MAX */

            if (hash->size >= MAX_HASH_SIZE)

                return(-1);

            newSize = hash->size * 2;

        } else {

            newSize = 0;

        }

    }

    /*

     * Grow the hash table if needed

     */

    if (newSize > 0) {

        unsigned mask, displ, pos;

        if (xmlHashGrow(hash, newSize) != 0)

            return(-1);

        /*

         * Find new entry

         */

        mask = hash->size - 1;

        displ = 0;

        pos = hashValue & mask;

        entry = &hash->table[pos];

        if (entry->hashValue != 0) {

            do {

                displ++;

                pos++;

                entry++;

                if ((pos & mask) == 0)

                    entry = hash->table;

            } while ((entry->hashValue != 0) &&

                     ((pos - entry->hashValue) & mask) >= displ);

        }

    }

    /*

     * Copy keys

     */

    if (hash->dict != NULL) {

        if (xmlDictOwns(hash->dict, key)) {

            copy = (xmlChar *) key;

        } else {

            copy = (xmlChar *) xmlDictLookup(hash->dict, key, -1);

            if (copy == NULL)

                return(-1);

        }

        if ((key2 == NULL) || (xmlDictOwns(hash->dict, key2))) {

            copy2 = (xmlChar *) key2;

        } else {

            copy2 = (xmlChar *) xmlDictLookup(hash->dict, key2, -1);

            if (copy2 == NULL)

                return(-1);

        }

        if ((key3 == NULL) || (xmlDictOwns(hash->dict, key3))) {

            copy3 = (xmlChar *) key3;

        } else {

            copy3 = (xmlChar *) xmlDictLookup(hash->dict, key3, -1);

            if (copy3 == NULL)

                return(-1);

        }

    } else {

        copy = xmlMalloc(lengths[0] + 1);

        if (copy == NULL)

            return(-1);

        memcpy(copy, key, lengths[0] + 1);

        if (key2 != NULL) {

            copy2 = xmlMalloc(lengths[1] + 1);

            if (copy2 == NULL) {

                xmlFree(copy);

                return(-1);

            }

            memcpy(copy2, key2, lengths[1] + 1);

        } else {

            copy2 = NULL;

        }

        if (key3 != NULL) {

            copy3 = xmlMalloc(lengths[2] + 1);

            if (copy3 == NULL) {

                xmlFree(copy);

                xmlFree(copy2);

                return(-1);

            }

            memcpy(copy3, key3, lengths[2] + 1);

        } else {

            copy3 = NULL;

        }

    }

    /*

     * Shift the remainder of the probe sequence to the right

     */

    if (entry->hashValue != 0) {

        const xmlHashEntry *end = &hash->table[hash->size];

        const xmlHashEntry *cur = entry;

        do {

            cur++;

            if (cur >= end)

                cur = hash->table;

        } while (cur->hashValue != 0);

        if (cur < entry) {

            /*

             * If we traversed the end of the buffer, handle the part

             * at the start of the buffer.

             */

            memmove(&hash->table[1], hash->table,

                    (char *) cur - (char *) hash->table);

            cur = end - 1;

            hash->table[0] = *cur;

        }

        memmove(&entry[1], entry, (char *) cur - (char *) entry);

    }

    /*

     * Populate entry

     */

    entry->key = copy;

    entry->key2 = copy2;

    entry->key3 = copy3;

    entry->payload = payload;

    /* OR with MAX_HASH_SIZE to make sure that the value is non-zero */

    entry->hashValue = hashValue | MAX_HASH_SIZE;

    hash->nbElems++;

    return(1);

}

/**

 * Free a hash table entry with xmlFree.

 *

 * @param entry  hash table entry

 * @param key  the entry's string key

 */

void

xmlHashDefaultDeallocator(void *entry, const xmlChar *key ATTRIBUTE_UNUSED) {

    xmlFree(entry);

}

/**

 * Add a hash table entry. If an entry with this key already exists,

 * payload will not be updated and 0 is returned. This return value

 * can't be distinguished from out-of-memory errors, so this function

 * should be used with care.

 *

 * @since 2.13.0

 *

 * @param hash  hash table

 * @param key  string key

 * @param payload  pointer to the payload

 * @returns 1 on success, 0 if an entry exists and -1 in case of error.

 */

int

xmlHashAdd(xmlHashTable *hash, const xmlChar *key, void *payload) {

    return(xmlHashUpdateInternal(hash, key, NULL, NULL, payload, NULL, 0));

}

/**

 * Add a hash table entry with two strings as key.

 *

 * See #xmlHashAdd.

 *

 * @since 2.13.0

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param payload  pointer to the payload

 * @returns 1 on success, 0 if an entry exists and -1 in case of error.

 */

int

xmlHashAdd2(xmlHashTable *hash, const xmlChar *key,

                 const xmlChar *key2, void *payload) {

    return(xmlHashUpdateInternal(hash, key, key2, NULL, payload, NULL, 0));

}

/**

 * Add a hash table entry with three strings as key.

 *

 * See #xmlHashAdd.

 *

 * @since 2.13.0

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param key3  third string key

 * @param payload  pointer to the payload

 * @returns 1 on success, 0 if an entry exists and -1 in case of error.

 */

int

xmlHashAdd3(xmlHashTable *hash, const xmlChar *key,

                 const xmlChar *key2, const xmlChar *key3,

                 void *payload) {

    return(xmlHashUpdateInternal(hash, key, key2, key3, payload, NULL, 0));

}

/**

 * Add a hash table entry. If an entry with this key already exists,

 * payload will not be updated and -1 is returned. This return value

 * can't be distinguished from out-of-memory errors, so this function

 * should be used with care.

 *

 * NOTE: This function doesn't allow to distinguish malloc failures from

 *       existing entries. Use #xmlHashAdd instead.

 *

 * @param hash  hash table

 * @param key  string key

 * @param payload  pointer to the payload

 * @returns 0 on success and -1 in case of error.

 */

int

xmlHashAddEntry(xmlHashTable *hash, const xmlChar *key, void *payload) {

    int res = xmlHashUpdateInternal(hash, key, NULL, NULL, payload, NULL, 0);

    if (res == 0)

        res = -1;

    else if (res == 1)

        res = 0;

    return(res);

}

/**

 * Add a hash table entry with two strings as key.

 *

 * See #xmlHashAddEntry.

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param payload  pointer to the payload

 * @returns 0 on success and -1 in case of error.

 */

int

xmlHashAddEntry2(xmlHashTable *hash, const xmlChar *key,

                 const xmlChar *key2, void *payload) {

    int res = xmlHashUpdateInternal(hash, key, key2, NULL, payload, NULL, 0);

    if (res == 0)

        res = -1;

    else if (res == 1)

        res = 0;

    return(res);

}

/**

 * Add a hash table entry with three strings as key.

 *

 * See #xmlHashAddEntry.

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param key3  third string key

 * @param payload  pointer to the payload

 * @returns 0 on success and -1 in case of error.

 */

int

xmlHashAddEntry3(xmlHashTable *hash, const xmlChar *key,

                 const xmlChar *key2, const xmlChar *key3,

                 void *payload) {

    int res = xmlHashUpdateInternal(hash, key, key2, key3, payload, NULL, 0);

    if (res == 0)

        res = -1;

    else if (res == 1)

        res = 0;

    return(res);

}

/**

 * Add a hash table entry. If an entry with this key already exists,

 * the old payload will be freed and updated with the new value.

 *

 * @param hash  hash table

 * @param key  string key

 * @param payload  pointer to the payload

 * @param dealloc  deallocator function for replaced item or NULL

 * @returns 0 in case of success, -1 if a memory allocation failed.

 */

int

xmlHashUpdateEntry(xmlHashTable *hash, const xmlChar *key,

                   void *payload, xmlHashDeallocator dealloc) {

    int res = xmlHashUpdateInternal(hash, key, NULL, NULL, payload,

                                    dealloc, 1);

    if (res == 1)

        res = 0;

    return(res);

}

/**

 * Add a hash table entry with two strings as key.

 *

 * See #xmlHashUpdateEntry.

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param payload  pointer to the payload

 * @param dealloc  deallocator function for replaced item or NULL

 * @returns 0 on success and -1 in case of error.

 */

int

xmlHashUpdateEntry2(xmlHashTable *hash, const xmlChar *key,

                   const xmlChar *key2, void *payload,

                   xmlHashDeallocator dealloc) {

    int res = xmlHashUpdateInternal(hash, key, key2, NULL, payload,

                                    dealloc, 1);

    if (res == 1)

        res = 0;

    return(res);

}

/**

 * Add a hash table entry with three strings as key.

 *

 * See #xmlHashUpdateEntry.

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param key3  third string key

 * @param payload  pointer to the payload

 * @param dealloc  deallocator function for replaced item or NULL

 * @returns 0 on success and -1 in case of error.

 */

int

xmlHashUpdateEntry3(xmlHashTable *hash, const xmlChar *key,

                   const xmlChar *key2, const xmlChar *key3,

                   void *payload, xmlHashDeallocator dealloc) {

    int res = xmlHashUpdateInternal(hash, key, key2, key3, payload,

                                    dealloc, 1);

    if (res == 1)

        res = 0;

    return(res);

}

/**

 * Find the entry specified by `key`.

 *

 * @param hash  hash table

 * @param key  string key

 * @returns a pointer to the payload or NULL if no entry was found.

 */

void *

xmlHashLookup(xmlHashTable *hash, const xmlChar *key) {

    return(xmlHashLookup3(hash, key, NULL, NULL));

}

/**

 * Find the payload specified by the (`key`, `key2`) tuple.

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @returns a pointer to the payload or NULL if no entry was found.

 */

void *

xmlHashLookup2(xmlHashTable *hash, const xmlChar *key,

              const xmlChar *key2) {

    return(xmlHashLookup3(hash, key, key2, NULL));

}

/**

 * Find the payload specified by the QName `prefix:name` or `name`.

 *

 * @param hash  hash table

 * @param prefix  prefix of the string key

 * @param name  local name of the string key

 * @returns a pointer to the payload or NULL if no entry was found.

 */

void *

xmlHashQLookup(xmlHashTable *hash, const xmlChar *prefix,

               const xmlChar *name) {

    return(xmlHashQLookup3(hash, prefix, name, NULL, NULL, NULL, NULL));

}

/**

 * Find the payload specified by the QNames tuple.

 *

 * @param hash  hash table

 * @param prefix  first prefix

 * @param name  first local name

 * @param prefix2  second prefix

 * @param name2  second local name

 * @returns a pointer to the payload or NULL if no entry was found.

 */

void *

xmlHashQLookup2(xmlHashTable *hash, const xmlChar *prefix,

                const xmlChar *name, const xmlChar *prefix2,

                const xmlChar *name2) {

    return(xmlHashQLookup3(hash, prefix, name, prefix2, name2, NULL, NULL));

}

/**

 * Find the payload specified by the (`key`, `key2`, `key3`) tuple.

 *

 * @param hash  hash table

 * @param key  first string key

 * @param key2  second string key

 * @param key3  third string key

 * @returns a pointer to the payload or NULL if no entry was found.

 */

void *

xmlHashLookup3(xmlHashTable *hash, const xmlChar *key,

               const xmlChar *key2, const xmlChar *key3) {

    const xmlHashEntry *entry;

    unsigned hashValue;

    int found;

    if ((hash == NULL) || (hash->size == 0) || (key == NULL))

        return(NULL);

    hashValue = xmlHashValue(hash->randomSeed, key, key2, key3, NULL);

    entry = xmlHashFindEntry(hash, key, key2, key3, hashValue, &found);

    if (found)

        return(entry->payload);

    return(NULL);

}

/**

 * Find the payload specified by the QNames tuple.

 *

 * @param hash  hash table

 * @param prefix  first prefix

 * @param name  first local name

 * @param prefix2  second prefix

 * @param name2  second local name

 * @param prefix3  third prefix

 * @param name3  third local name

 * @returns a pointer to the payload or NULL if no entry was found.

 */

ATTRIBUTE_NO_SANITIZE_INTEGER

void *

xmlHashQLookup3(xmlHashTable *hash,

                const xmlChar *prefix, const xmlChar *name,

                const xmlChar *prefix2, const xmlChar *name2,

                const xmlChar *prefix3, const xmlChar *name3) {

    const xmlHashEntry *entry;

    unsigned hashValue, mask, pos, displ;

    if ((hash == NULL) || (hash->size == 0) || (name == NULL))

        return(NULL);

    hashValue = xmlHashQNameValue(hash->randomSeed, prefix, name, prefix2,

                                  name2, prefix3, name3);

    mask = hash->size - 1;

    pos = hashValue & mask;

    entry = &hash->table[pos];

    if (entry->hashValue != 0) {

        displ = 0;

        hashValue |= MAX_HASH_SIZE;

        do {

            if ((hashValue == entry->hashValue) &&

                (xmlStrQEqual(prefix, name, entry->key)) &&

                (xmlStrQEqual(prefix2, name2, entry->key2)) &&

                (xmlStrQEqual(prefix3, name3, entry->key3)))

                return(entry->payload);

            displ++;

            pos++;

            entry++;

            if ((pos & mask) == 0)

                entry = hash->table;

        } while ((entry->hashValue != 0) &&

                 (((pos - entry->hashValue) & mask) >= displ));

    }

    return(NULL);

}

typedef struct {

    xmlHashScanner scan;

    void *data;

} stubData;

static void

stubHashScannerFull(void *payload, void *data, const xmlChar *key,

                    const xmlChar *key2 ATTRIBUTE_UNUSED,

                    const xmlChar *key3 ATTRIBUTE_UNUSED) {

    stubData *sdata = (stubData *) data;

    sdata->scan(payload, sdata->data, key);

}

/**

 * Scan the hash `table` and apply `scan` to each value.

 *

 * @param hash  hash table

 * @param scan  scanner function for items in the hash

 * @param data  extra data passed to `scan`

 */

void

xmlHashScan(xmlHashTable *hash, xmlHashScanner scan, void *data) {

    stubData sdata;

    sdata.data = data;

    sdata.scan = scan;

    xmlHashScanFull(hash, stubHashScannerFull, &sdata);

}

/**

 * Scan the hash `table` and apply `scan` to each value.

 *

 * @param hash  hash table

 * @param scan  scanner function for items in the hash

 * @param data  extra data passed to `scan`

 */

void

xmlHashScanFull(xmlHashTable *hash, xmlHashScannerFull scan, void *data) {

    const xmlHashEntry *entry, *end;

    xmlHashEntry old;

    unsigned i;

    if ((hash == NULL) || (hash->size == 0) || (scan == NULL))

        return;

    /*

     * We must handle the case that a scanned entry is removed when executing

     * the callback (xmlCleanSpecialAttr and possibly other places).

     *

     * Find the start of a probe sequence to avoid scanning entries twice if

     * a deletion happens.

     */

    entry = hash->table;

    end = &hash->table[hash->size];

    while (entry->hashValue != 0) {

        if (++entry >= end)

            entry = hash->table;

    }

    for (i = 0; i < hash->size; i++) {

        if ((entry->hashValue != 0) && (entry->payload != NULL)) {

            /*

             * Make sure to rescan after a possible deletion.

             */

            do {

                old = *entry;

                scan(entry->payload, data, entry->key, entry->key2, entry->key3);

            } while ((entry->hashValue != 0) &&

                     (entry->payload != NULL) &&

                     ((entry->key != old.key) ||

                      (entry->key2 != old.key2) ||

                      (entry->key3 != old.key3)));

        }

        if (++entry >= end)

            entry = hash->table;

    }

}

/**

 * Scan the hash `table` and apply `scan` to each value matching

 * (`key`, `key2`, `key3`) tuple. If one of the keys is null,

 * the comparison is considered to match.

 *

 * @param hash  hash table

 * @param key  first string key or NULL

 * @param key2  second string key or NULL

 * @param key3  third string key or NULL

 * @param scan  scanner function for items in the hash

 * @param data  extra data passed to `scan`

 */

void

xmlHashScan3(xmlHashTable *hash, const xmlChar *key,

             const xmlChar *key2, const xmlChar *key3,

             xmlHashScanner scan, void *data) {

    stubData sdata;

    sdata.data = data;

    sdata.scan = scan;

    xmlHashScanFull3(hash, key, key2, key3, stubHashScannerFull, &sdata);

}

/**

 * Scan the hash `table` and apply `scan` to each value matching

 * (`key`, `key2`, `key3`) tuple. If one of the keys is null,

 * the comparison is considered to match.

 *

 * @param hash  hash table

 * @param key  first string key or NULL

 * @param key2  second string key or NULL

 * @param key3  third string key or NULL

 * @param scan  scanner function for items in the hash

 * @param data  extra data passed to `scan`

 */

void

xmlHashScanFull3(xmlHashTable *hash, const xmlChar *key,

                 const xmlChar *key2, const xmlChar *key3,

                 xmlHashScannerFull scan, void *data) {