src/hashmap.c

#include <bh/internal/hashmap.h>
#include <stdlib.h>
#include <string.h>

bh_hashmap_t *bh_hashmap_new(bh_equal_cb_t equal,
                             bh_hash_cb_t hash)
{
    bh_hashmap_t *result;

    result = malloc(sizeof(*result));
    if (result)
        bh_hashmap_init(result, equal, hash);

    return result;
}

void bh_hashmap_free(bh_hashmap_t *hashmap)
{
    bh_hashmap_destroy(hashmap);
    free(hashmap);
}

void bh_hashmap_init(bh_hashmap_t *hashmap,
                     bh_equal_cb_t equal,
                     bh_hash_cb_t hash)
{
    memset(hashmap, 0, sizeof(*hashmap));
    hashmap->factor = 0.75f;
    hashmap->equal = equal;
    hashmap->hash = hash;
}

void bh_hashmap_destroy(bh_hashmap_t *hashmap)
{
    if (hashmap->capacity)
    {
        free(hashmap->data);
        free(hashmap->psls);
    }
}

void bh_hashmap_clear(bh_hashmap_t *hashmap)
{
    if (hashmap->capacity)
        memset(hashmap->psls, 0, hashmap->capacity * sizeof(size_t));
    hashmap->size = 0;
}

int bh_hashmap_reserve(bh_hashmap_t *hashmap,
                        size_t size)
{
    bh_hashmap_t other;
    size_t capacity, max_capacity, threshold;

    /* Calculate hashmap max capacity and capacity threshold */
    capacity = hashmap->capacity;
    threshold = hashmap->capacity * hashmap->factor;
    max_capacity = ((size_t)-1) / sizeof(bh_hashmap_node_t);

    /* New capacity can't be smaller then current hashmap size */
    if (size < hashmap->size)
        size = hashmap->size;

    /* Find new hashmap capacity */
    if (!size)
    {
        /* No capacity needed */
        capacity = 0;
        threshold = 0;
    }
    else if (size > threshold)
    {
        /* Bigger capacity needed - grow the hashmap */
        while (size > threshold)
        {
            capacity = (capacity) ? (capacity * 2) : (16);
            threshold = capacity * hashmap->factor;

            /* Capacity can't be bigger than max capacity and overflow */
            if (capacity > max_capacity || capacity < 16)
                return -1;
        }
    }
    else
    {
        /* Smaller capacity needed - shrink the hashmap */
        while (size <= threshold / 2 && capacity > 16)
        {
            capacity /= 2;
            threshold = capacity * hashmap->factor;
        }
    }

    /* Prevent same size reallocation */
    if (capacity == hashmap->capacity)
        return 0;

    /* Initialize new hashmap */
    bh_hashmap_init(&other, hashmap->equal, hashmap->hash);
    other.factor = hashmap->factor;

    if (capacity)
    {
        void *iter;

        /* Allocate new memory for the hashmap */
        other.data = malloc(sizeof(*other.data) * capacity);

        other.psls = malloc(sizeof(size_t) * capacity);
        other.threshold = threshold;
        other.capacity = capacity;

        /* Check for allocations failure */
        if (!other.data || !other.psls)
        {
            if (other.data)
                free(other.data);
            if (other.psls)
                free(other.psls);
            return -1;
        }

        /* Reset probe sequence lengths */
        memset(other.psls, 0, sizeof(size_t) * other.capacity);

        /* Iterate and insert data into hashmap */
        iter = bh_hashmap_iter_next(hashmap, NULL);
        while (iter)
        {
            void *key, *value;

            key = bh_hashmap_iter_key(iter);
            value = bh_hashmap_iter_value(iter);
            bh_hashmap_insert(&other, key, value);

            iter = bh_hashmap_iter_next(hashmap, iter);
        }
    }

    /* Swap hashmaps */
    bh_hashmap_destroy(hashmap);
    *hashmap = other;
    return 0;
}

int bh_hashmap_insert(bh_hashmap_t *hashmap,
                      void *key,
                      void *value)
{
    size_t bucket, psl, tmp_psl;
    bh_hashmap_node_t item, tmp;

    /* Try to stay below hashmap threshold */
    if (hashmap->size + 1 > hashmap->threshold)
        if (bh_hashmap_reserve(hashmap, hashmap->size + 1))
            if (hashmap->size >= hashmap->capacity)
                return -1;

    /* Prepare inserted data and set PSL to 1 */
    item.key = key;
    item.value = value;
    psl = 1;

    /* Calculate prefered bucket index */
    bucket = hashmap->hash(key) & (hashmap->capacity - 1);

    /* Find empty bucket */
    while (hashmap->psls[bucket])
    {
        /* Current bucket is richer then us - swap elements */
        if (psl > hashmap->psls[bucket])
        {
            tmp = hashmap->data[bucket];
            tmp_psl = hashmap->psls[bucket];
            hashmap->data[bucket] = item;
            hashmap->psls[bucket] = psl;
            item = tmp;
            psl = tmp_psl;
        }

        bucket = (bucket + 1) & (hashmap->capacity - 1);
        psl++;
    }

    /* Found empty bucket - place item here */
    hashmap->data[bucket] = item;
    hashmap->psls[bucket] = psl;
    hashmap->size++;

    return 0;
}

void bh_hashmap_remove(bh_hashmap_t *hashmap,
                       void *key)
{
    void *iter;

    iter = bh_hashmap_iter_at(hashmap, key);
    if (iter)
        bh_hashmap_iter_remove(hashmap, iter);
}

void *bh_hashmap_at(bh_hashmap_t *hashmap,
                    void *key,
                    int *exists)
{
    void *iter;

    iter = bh_hashmap_iter_at(hashmap, key);
    if (iter)
    {
        /* If exists flag passed - set to 1 */
        if (exists)
            *exists = 1;
        return bh_hashmap_iter_value(iter);
    }

    /* If exists flag passed - set to 0 */
    if (exists)
        *exists = 0;
    return NULL;
}

int bh_hashmap_empty(bh_hashmap_t *hashmap)
{
    return !hashmap->size;
}

size_t bh_hashmap_size(bh_hashmap_t *hashmap)
{
    return hashmap->size;
}

size_t bh_hashmap_capacity(bh_hashmap_t *hashmap)
{
    return hashmap->capacity;
}

float bh_hashmap_factor(bh_hashmap_t *hashmap)
{
    return hashmap->factor;
}

void bh_hashmap_set_factor(bh_hashmap_t *hashmap,
                           float factor)
{
    factor = (factor > 1.0f) ? (1.0f) : (factor);
    factor = (factor < 0.15f) ? (0.15f) : (factor);

    hashmap->factor = factor;
    hashmap->threshold = hashmap->capacity * factor;
}

void *bh_hashmap_iter_at(bh_hashmap_t *hashmap,
                         void *key)
{
    size_t bucket, psl;

    /* Nothing can be in empty map */
    if (!hashmap->size)
        return NULL;

    /* Calculate prefered bucket index and set PSL to 1 */
    bucket = hashmap->hash(key) & (hashmap->capacity - 1);
    psl = 1;

    /* Iterate hashmap until we find element or find richer bucket */
    while (hashmap->psls[bucket] >= psl && hashmap->equal(hashmap->data[bucket].key, key))
    {
        bucket = (bucket + 1) & (hashmap->capacity - 1);
        psl++;
    }

    /* If bucket is poorer or equal to us - we found our element */
    if (hashmap->psls[bucket] >= psl)
        return hashmap->data + bucket;

    return NULL;
}

void *bh_hashmap_iter_next(bh_hashmap_t *hashmap,
                           void *iter)
{
    bh_hashmap_node_t *item;

    item = (bh_hashmap_node_t *)iter;
    while (1)
    {
        /* Advance or set iterator to the first element */
        if (item)
            item++;
        else
            item = hashmap->data;

        /* Check iterator for validity */
        if (item >= hashmap->data + hashmap->capacity)
            return NULL;

        /* Check iterator's item PSL */
        if (hashmap->psls[item - hashmap->data])
            return item;
    }
}

void bh_hashmap_iter_remove(bh_hashmap_t *hashmap,
                            void *iter)
{
    size_t bucket, next_bucket;

    /* Check if hashmap is empty or we are given NULL iterator */
    if (!iter || !hashmap->size)
        return;

    /* Adjust hashmap size, calculate current and next bucket index */
    hashmap->size--;
    bucket = (bh_hashmap_node_t *)iter - hashmap->data;
    next_bucket = (bucket + 1) & (hashmap->capacity - 1);

    /* Shift all elements toward their preffered place */
    while (hashmap->psls[next_bucket] > 1)
    {
        /* Copy item and adjust PSL */
        hashmap->data[bucket] = hashmap->data[next_bucket];
        hashmap->psls[bucket] = hashmap->psls[next_bucket] - 1;

        /* Calculate next bucket index */
        bucket = next_bucket;
        next_bucket = (bucket + 1) & (hashmap->capacity - 1);
    }

    /* Reset bucket's PSL (mark empty) */
    hashmap->psls[bucket] = 0;
}

void *bh_hashmap_iter_key(void *iter)
{
    return ((bh_hashmap_node_t *)iter)->key;
}

void *bh_hashmap_iter_value(void *iter)
{
    return ((bh_hashmap_node_t *)iter)->value;
}
Initial commit 2024-04-13 14:52:29 +03:00			`#include <bh/internal/hashmap.h>`
			`#include <stdlib.h>`
			`#include <string.h>`

			`bh_hashmap_t *bh_hashmap_new(bh_equal_cb_t equal,`
			`bh_hash_cb_t hash)`
			`{`
			`bh_hashmap_t *result;`

			`result = malloc(sizeof(*result));`
			`if (result)`
			`bh_hashmap_init(result, equal, hash);`

			`return result;`
			`}`

			`void bh_hashmap_free(bh_hashmap_t *hashmap)`
			`{`
			`bh_hashmap_destroy(hashmap);`
			`free(hashmap);`
			`}`

			`void bh_hashmap_init(bh_hashmap_t *hashmap,`
			`bh_equal_cb_t equal,`
			`bh_hash_cb_t hash)`
			`{`
			`memset(hashmap, 0, sizeof(*hashmap));`
			`hashmap->factor = 0.75f;`
			`hashmap->equal = equal;`
			`hashmap->hash = hash;`
			`}`

			`void bh_hashmap_destroy(bh_hashmap_t *hashmap)`
			`{`
			`if (hashmap->capacity)`
			`{`
			`free(hashmap->data);`
			`free(hashmap->psls);`
			`}`
			`}`

			`void bh_hashmap_clear(bh_hashmap_t *hashmap)`
			`{`
			`if (hashmap->capacity)`
			`memset(hashmap->psls, 0, hashmap->capacity * sizeof(size_t));`
			`hashmap->size = 0;`
			`}`

			`int bh_hashmap_reserve(bh_hashmap_t *hashmap,`
			`size_t size)`
			`{`
			`bh_hashmap_t other;`
			`size_t capacity, max_capacity, threshold;`

			`/* Calculate hashmap max capacity and capacity threshold */`
			`capacity = hashmap->capacity;`
			`threshold = hashmap->capacity * hashmap->factor;`
			`max_capacity = ((size_t)-1) / sizeof(bh_hashmap_node_t);`

			`/* New capacity can't be smaller then current hashmap size */`
			`if (size < hashmap->size)`
			`size = hashmap->size;`

			`/* Find new hashmap capacity */`
			`if (!size)`
			`{`
			`/* No capacity needed */`
			`capacity = 0;`
			`threshold = 0;`
			`}`
			`else if (size > threshold)`
			`{`
			`/* Bigger capacity needed - grow the hashmap */`
			`while (size > threshold)`
			`{`
			`capacity = (capacity) ? (capacity * 2) : (16);`
			`threshold = capacity * hashmap->factor;`

			`/* Capacity can't be bigger than max capacity and overflow */`
			`if (capacity > max_capacity \|\| capacity < 16)`
			`return -1;`
			`}`
			`}`
			`else`
			`{`
			`/* Smaller capacity needed - shrink the hashmap */`
			`while (size <= threshold / 2 && capacity > 16)`
			`{`
			`capacity /= 2;`
			`threshold = capacity * hashmap->factor;`
			`}`
			`}`

			`/* Prevent same size reallocation */`
			`if (capacity == hashmap->capacity)`
			`return 0;`

			`/* Initialize new hashmap */`
			`bh_hashmap_init(&other, hashmap->equal, hashmap->hash);`
			`other.factor = hashmap->factor;`

			`if (capacity)`
			`{`
			`void *iter;`

			`/* Allocate new memory for the hashmap */`
			`other.data = malloc(sizeof(other.data) capacity);`

			`other.psls = malloc(sizeof(size_t) * capacity);`
			`other.threshold = threshold;`
			`other.capacity = capacity;`

			`/* Check for allocations failure */`
			`if (!other.data \|\| !other.psls)`
			`{`
			`if (other.data)`
			`free(other.data);`
			`if (other.psls)`
			`free(other.psls);`
			`return -1;`
			`}`

			`/* Reset probe sequence lengths */`
			`memset(other.psls, 0, sizeof(size_t) * other.capacity);`

			`/* Iterate and insert data into hashmap */`
			`iter = bh_hashmap_iter_next(hashmap, NULL);`
			`while (iter)`
			`{`
			`void key, value;`

			`key = bh_hashmap_iter_key(iter);`
			`value = bh_hashmap_iter_value(iter);`
			`bh_hashmap_insert(&other, key, value);`

			`iter = bh_hashmap_iter_next(hashmap, iter);`
			`}`
			`}`

			`/* Swap hashmaps */`
			`bh_hashmap_destroy(hashmap);`
			`*hashmap = other;`
			`return 0;`
			`}`

			`int bh_hashmap_insert(bh_hashmap_t *hashmap,`
			`void *key,`
			`void *value)`
			`{`
			`size_t bucket, psl, tmp_psl;`
			`bh_hashmap_node_t item, tmp;`

			`/* Try to stay below hashmap threshold */`
			`if (hashmap->size + 1 > hashmap->threshold)`
			`if (bh_hashmap_reserve(hashmap, hashmap->size + 1))`
			`if (hashmap->size >= hashmap->capacity)`
			`return -1;`

			`/* Prepare inserted data and set PSL to 1 */`
			`item.key = key;`
			`item.value = value;`
			`psl = 1;`

			`/* Calculate prefered bucket index */`
			`bucket = hashmap->hash(key) & (hashmap->capacity - 1);`

			`/* Find empty bucket */`
			`while (hashmap->psls[bucket])`
			`{`
			`/* Current bucket is richer then us - swap elements */`
			`if (psl > hashmap->psls[bucket])`
			`{`
			`tmp = hashmap->data[bucket];`
			`tmp_psl = hashmap->psls[bucket];`
			`hashmap->data[bucket] = item;`
			`hashmap->psls[bucket] = psl;`
			`item = tmp;`
			`psl = tmp_psl;`
			`}`

			`bucket = (bucket + 1) & (hashmap->capacity - 1);`
			`psl++;`
			`}`

			`/* Found empty bucket - place item here */`
			`hashmap->data[bucket] = item;`
			`hashmap->psls[bucket] = psl;`
			`hashmap->size++;`

			`return 0;`
			`}`

			`void bh_hashmap_remove(bh_hashmap_t *hashmap,`
			`void *key)`
			`{`
			`void *iter;`

			`iter = bh_hashmap_iter_at(hashmap, key);`
			`if (iter)`
			`bh_hashmap_iter_remove(hashmap, iter);`
			`}`

			`void bh_hashmap_at(bh_hashmap_t hashmap,`
			`void *key,`
			`int *exists)`
			`{`
			`void *iter;`

			`iter = bh_hashmap_iter_at(hashmap, key);`
			`if (iter)`
			`{`
			`/* If exists flag passed - set to 1 */`
			`if (exists)`
			`*exists = 1;`
			`return bh_hashmap_iter_value(iter);`
			`}`

			`/* If exists flag passed - set to 0 */`
			`if (exists)`
			`*exists = 0;`
			`return NULL;`
			`}`

			`int bh_hashmap_empty(bh_hashmap_t *hashmap)`
			`{`
			`return !hashmap->size;`
			`}`

			`size_t bh_hashmap_size(bh_hashmap_t *hashmap)`
			`{`
			`return hashmap->size;`
			`}`

			`size_t bh_hashmap_capacity(bh_hashmap_t *hashmap)`
			`{`
			`return hashmap->capacity;`
			`}`

			`float bh_hashmap_factor(bh_hashmap_t *hashmap)`
			`{`
			`return hashmap->factor;`
			`}`

			`void bh_hashmap_set_factor(bh_hashmap_t *hashmap,`
			`float factor)`
			`{`
			`factor = (factor > 1.0f) ? (1.0f) : (factor);`
			`factor = (factor < 0.15f) ? (0.15f) : (factor);`

			`hashmap->factor = factor;`
			`hashmap->threshold = hashmap->capacity * factor;`
			`}`

			`void bh_hashmap_iter_at(bh_hashmap_t hashmap,`
			`void *key)`
			`{`
			`size_t bucket, psl;`

			`/* Nothing can be in empty map */`
			`if (!hashmap->size)`
			`return NULL;`

			`/* Calculate prefered bucket index and set PSL to 1 */`
			`bucket = hashmap->hash(key) & (hashmap->capacity - 1);`
			`psl = 1;`

			`/* Iterate hashmap until we find element or find richer bucket */`
			`while (hashmap->psls[bucket] >= psl && hashmap->equal(hashmap->data[bucket].key, key))`
			`{`
			`bucket = (bucket + 1) & (hashmap->capacity - 1);`
			`psl++;`
			`}`

			`/* If bucket is poorer or equal to us - we found our element */`
			`if (hashmap->psls[bucket] >= psl)`
			`return hashmap->data + bucket;`

			`return NULL;`
			`}`

			`void bh_hashmap_iter_next(bh_hashmap_t hashmap,`
			`void *iter)`
			`{`
			`bh_hashmap_node_t *item;`

			`item = (bh_hashmap_node_t *)iter;`
			`while (1)`
			`{`
			`/* Advance or set iterator to the first element */`
			`if (item)`
			`item++;`
			`else`
			`item = hashmap->data;`

			`/* Check iterator for validity */`
			`if (item >= hashmap->data + hashmap->capacity)`
			`return NULL;`

			`/* Check iterator's item PSL */`
			`if (hashmap->psls[item - hashmap->data])`
			`return item;`
			`}`
			`}`

			`void bh_hashmap_iter_remove(bh_hashmap_t *hashmap,`
			`void *iter)`
			`{`
			`size_t bucket, next_bucket;`

			`/* Check if hashmap is empty or we are given NULL iterator */`
			`if (!iter \|\| !hashmap->size)`
			`return;`

			`/* Adjust hashmap size, calculate current and next bucket index */`
			`hashmap->size--;`
			`bucket = (bh_hashmap_node_t *)iter - hashmap->data;`
			`next_bucket = (bucket + 1) & (hashmap->capacity - 1);`

			`/* Shift all elements toward their preffered place */`
			`while (hashmap->psls[next_bucket] > 1)`
			`{`
			`/* Copy item and adjust PSL */`
			`hashmap->data[bucket] = hashmap->data[next_bucket];`
			`hashmap->psls[bucket] = hashmap->psls[next_bucket] - 1;`

			`/* Calculate next bucket index */`
			`bucket = next_bucket;`
			`next_bucket = (bucket + 1) & (hashmap->capacity - 1);`
			`}`

			`/* Reset bucket's PSL (mark empty) */`
			`hashmap->psls[bucket] = 0;`
			`}`

			`void bh_hashmap_iter_key(void iter)`
			`{`
			`return ((bh_hashmap_node_t *)iter)->key;`
			`}`

			`void bh_hashmap_iter_value(void iter)`
			`{`
			`return ((bh_hashmap_node_t *)iter)->value;`
			`}`