src/hash_map.c

Tue, 07 Feb 2023 21:53:06 +0100

author
Mike Becker <universe@uap-core.de>
date
Tue, 07 Feb 2023 21:53:06 +0100
changeset 652
bf817b825ed2
parent 630
ac5e7f789048
child 658
56c62780582e
permissions
-rw-r--r--

fix README showing how tests were run in the automake era

/*
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER.
 *
 * Copyright 2021 Mike Becker, Olaf Wintermann All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are met:
 *
 *   1. Redistributions of source code must retain the above copyright
 *      notice, this list of conditions and the following disclaimer.
 *
 *   2. Redistributions in binary form must reproduce the above copyright
 *      notice, this list of conditions and the following disclaimer in the
 *      documentation and/or other materials provided with the distribution.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 * POSSIBILITY OF SUCH DAMAGE.
 */

#include <string.h>
#include "cx/hash_map.h"
#include "cx/utils.h"

static void cx_hash_map_clear(struct cx_map_s *map) {
    struct cx_hash_map_s *hash_map = (struct cx_hash_map_s *) map;
    cx_for_n(i, hash_map->bucket_count) {
        struct cx_hash_map_element_s *elem = hash_map->buckets[i];
        if (elem != NULL) {
            do {
                struct cx_hash_map_element_s *next = elem->next;
                // free the key data
                cxFree(map->allocator, elem->key.data.obj);
                // free the node
                cxFree(map->allocator, elem);
                // proceed
                elem = next;
            } while (elem != NULL);

            // do not leave a dangling pointer
            hash_map->buckets[i] = NULL;
        }
    }
    map->size = 0;
}

static void cx_hash_map_destructor(struct cx_map_s *map) {
    struct cx_hash_map_s *hash_map = (struct cx_hash_map_s *) map;

    // free the buckets
    cx_hash_map_clear(map);
    cxFree(map->allocator, hash_map->buckets);

    // free the map structure
    cxFree(map->allocator, map);
}

static int cx_hash_map_put(
        CxMap *map,
        CxHashKey key,
        void *value
) {
    struct cx_hash_map_s *hash_map = (struct cx_hash_map_s *) map;
    CxAllocator *allocator = map->allocator;

    unsigned hash = key.hash;
    if (hash == 0) {
        cx_hash_murmur(&key);
        hash = key.hash;
    }

    size_t slot = hash % hash_map->bucket_count;
    struct cx_hash_map_element_s *elm = hash_map->buckets[slot];
    struct cx_hash_map_element_s *prev = NULL;

    while (elm != NULL && elm->key.hash < hash) {
        prev = elm;
        elm = elm->next;
    }

    if (elm != NULL && elm->key.hash == hash && elm->key.len == key.len &&
        memcmp(elm->key.data.obj, key.data.obj, key.len) == 0) {
        // overwrite existing element
        elm->data = value;
    } else {
        // allocate new element
        struct cx_hash_map_element_s *e = cxMalloc(allocator, sizeof(struct cx_hash_map_element_s));
        if (e == NULL) {
            return -1;
        }

        // write the value
        // TODO: depending on future map features, we may want to copy here
        e->data = value;

        // copy the key
        void *kd = cxMalloc(allocator, key.len);
        if (kd == NULL) {
            return -1;
        }
        memcpy(kd, key.data.obj, key.len);
        e->key.data.obj = kd;
        e->key.len = key.len;
        e->key.hash = hash;

        // insert the element into the linked list
        if (prev == NULL) {
            hash_map->buckets[slot] = e;
        } else {
            prev->next = e;
        }
        e->next = elm;

        // increase the size
        map->size++;
    }

    return 0;
}

static void cx_hash_map_unlink(
        struct cx_hash_map_s *hash_map,
        size_t slot,
        struct cx_hash_map_element_s *prev,
        struct cx_hash_map_element_s *elm
) {
    // unlink
    if (prev == NULL) {
        hash_map->buckets[slot] = elm->next;
    } else {
        prev->next = elm->next;
    }
    // free element
    cxFree(hash_map->base.allocator, elm->key.data.obj);
    cxFree(hash_map->base.allocator, elm);
    // decrease size
    hash_map->base.size--;
}

/**
 * Helper function to avoid code duplication.
 *
 * @param map the map
 * @param key the key to look up
 * @param remove flag indicating whether the looked up entry shall be removed
 * @return the value corresponding to the key or \c NULL
 */
static void *cx_hash_map_get_remove(
        CxMap *map,
        CxHashKey key,
        bool remove
) {
    struct cx_hash_map_s *hash_map = (struct cx_hash_map_s *) map;

    unsigned hash = key.hash;
    if (hash == 0) {
        cx_hash_murmur(&key);
        hash = key.hash;
    }

    size_t slot = hash % hash_map->bucket_count;
    struct cx_hash_map_element_s *elm = hash_map->buckets[slot];
    struct cx_hash_map_element_s *prev = NULL;
    while (elm && elm->key.hash <= hash) {
        if (elm->key.hash == hash && elm->key.len == key.len) {
            if (memcmp(elm->key.data.obj, key.data.obj, key.len) == 0) {
                void *data = elm->data;
                if (remove) {
                    cx_hash_map_unlink(hash_map, slot, prev, elm);
                }
                return data;
            }
        }
        prev = elm;
        elm = prev->next;
    }

    return NULL;
}

static void *cx_hash_map_get(
        CxMap const *map,
        CxHashKey key
) {
    // we can safely cast, because we know when remove=false, the map stays untouched
    return cx_hash_map_get_remove((CxMap *) map, key, false);
}

static void *cx_hash_map_remove(
        CxMap *map,
        CxHashKey key
) {
    return cx_hash_map_get_remove(map, key, true);
}

static void *cx_hash_map_iter_current_entry(void const *it) {
    struct cx_iterator_s const *iter = it;
    // struct has to have a compatible signature
    return (struct cx_map_entry_s *) &(iter->kv_data);
}

static void *cx_hash_map_iter_current_key(void const *it) {
    struct cx_iterator_s const *iter = it;
    struct cx_hash_map_element_s *elm = iter->elem_handle;
    return &elm->key;
}

static void *cx_hash_map_iter_current_value(void const *it) {
    struct cx_iterator_s const *iter = it;
    struct cx_hash_map_element_s *elm = iter->elem_handle;
    // TODO: return a pointer to data if this map is storing copies
    return elm->data;
}

static bool cx_hash_map_iter_valid(void const *it) {
    struct cx_iterator_s const *iter = it;
    return iter->elem_handle != NULL;
}

static void cx_hash_map_iter_next(void *it) {
    struct cx_iterator_s *iter = it;
    struct cx_hash_map_element_s *elm = iter->elem_handle;

    // remove current element, if asked
    if (iter->base.remove) {
        // obtain mutable pointer to the map
        struct cx_mut_iterator_s *miter = it;
        struct cx_hash_map_s *map = miter->src_handle;

        // clear the flag
        iter->base.remove = false;

        // determine the next element
        struct cx_hash_map_element_s *next = elm->next;

        // search the previous element
        struct cx_hash_map_element_s *prev = NULL;
        if (map->buckets[iter->slot] != elm) {
            prev = map->buckets[iter->slot];
            while (prev->next != elm) {
                prev = prev->next;
            }
        }

        // unlink
        cx_hash_map_unlink(map, iter->slot, prev, elm);

        // advance
        elm = next;
    } else {
        // just advance
        elm = elm->next;
        iter->index++;
    }

    // search the next bucket, if required
    struct cx_hash_map_s const *map = iter->src_handle;
    while (elm == NULL && ++iter->slot < map->bucket_count) {
        elm = map->buckets[iter->slot];
    }

    // fill the struct with the next element
    iter->elem_handle = elm;
    if (elm == NULL) {
        iter->kv_data.key = NULL;
        iter->kv_data.value = NULL;
    } else {
        iter->kv_data.key = &elm->key;
        // TODO: pointer to data if this map is storing copies
        iter->kv_data.value = elm->data;
    }
}

static bool cx_hash_map_iter_flag_rm(void *it) {
    struct cx_iterator_base_s *iter = it;
    if (iter->mutating) {
        iter->remove = true;
        return true;
    } else {
        return false;
    }
}

static CxIterator cx_hash_map_iterator(CxMap const *map) {
    CxIterator iter;

    iter.src_handle = map;
    iter.base.valid = cx_hash_map_iter_valid;
    iter.base.next = cx_hash_map_iter_next;
    iter.base.current = cx_hash_map_iter_current_entry;
    iter.base.flag_removal = cx_hash_map_iter_flag_rm;
    iter.base.remove = false;
    iter.base.mutating = false;

    iter.slot = 0;
    iter.index = 0;

    if (map->size > 0) {
        struct cx_hash_map_s *hash_map = (struct cx_hash_map_s *) map;
        struct cx_hash_map_element_s *elm = hash_map->buckets[0];
        for (; elm == NULL; iter.slot++) {
            elm = hash_map->buckets[iter.slot];
        }
        iter.elem_handle = elm;
        iter.kv_data.key = &elm->key;
        // TODO: pointer to data if this map is storing copies
        iter.kv_data.value = elm->data;
    } else {
        iter.elem_handle = NULL;
        iter.kv_data.key = NULL;
        iter.kv_data.value = NULL;
    }

    return iter;
}

static CxIterator cx_hash_map_iterator_keys(CxMap const *map) {
    CxIterator iter = cx_hash_map_iterator(map);
    iter.base.current = cx_hash_map_iter_current_key;
    return iter;
}

static CxIterator cx_hash_map_iterator_values(CxMap const *map) {
    CxIterator iter = cx_hash_map_iterator(map);
    iter.base.current = cx_hash_map_iter_current_value;
    return iter;
}

static CxMutIterator cx_hash_map_mut_iterator(CxMap *map) {
    CxIterator it = cx_hash_map_iterator(map);
    it.base.mutating = true;

    // we know the iterators share the same memory layout
    CxMutIterator iter;
    memcpy(&iter, &it, sizeof(CxMutIterator));
    return iter;
}

static CxMutIterator cx_hash_map_mut_iterator_keys(CxMap *map) {
    CxMutIterator iter = cx_hash_map_mut_iterator(map);
    iter.base.current = cx_hash_map_iter_current_key;
    return iter;
}

static CxMutIterator cx_hash_map_mut_iterator_values(CxMap *map) {
    CxMutIterator iter = cx_hash_map_mut_iterator(map);
    iter.base.current = cx_hash_map_iter_current_value;
    return iter;
}

static cx_map_class cx_hash_map_class = {
        cx_hash_map_destructor,
        cx_hash_map_clear,
        cx_hash_map_put,
        cx_hash_map_get,
        cx_hash_map_remove,
        cx_hash_map_iterator,
        cx_hash_map_iterator_keys,
        cx_hash_map_iterator_values,
        cx_hash_map_mut_iterator,
        cx_hash_map_mut_iterator_keys,
        cx_hash_map_mut_iterator_values,
};

CxMap *cxHashMapCreate(
        CxAllocator *allocator,
        size_t buckets
) {
    if (buckets == 0) {
        // implementation defined default
        buckets = 16;
    }

    struct cx_hash_map_s *map = cxMalloc(allocator, sizeof(struct cx_hash_map_s));
    if (map == NULL) return NULL;

    // initialize hash map members
    map->bucket_count = buckets;
    map->buckets = cxCalloc(allocator, buckets, sizeof(struct cx_hash_map_element_s *));
    if (map->buckets == NULL) {
        cxFree(allocator, map);
        return NULL;
    }

    // initialize base members
    map->base.cl = &cx_hash_map_class;
    map->base.allocator = allocator;
    map->base.size = 0;

    return (CxMap *) map;
}

int cxMapRehash(CxMap *map) {
    struct cx_hash_map_s *hash_map = (struct cx_hash_map_s *) map;
    if (map->size > ((hash_map->bucket_count * 3) >> 2)) {

        size_t new_bucket_count = (map->size * 5) >> 1;
        struct cx_hash_map_element_s **new_buckets = cxCalloc(map->allocator,
                                                              new_bucket_count, sizeof(struct cx_hash_map_element_s *));

        if (new_buckets == NULL) {
            return 1;
        }

        // iterate through the elements and assign them to their new slots
        cx_for_n(slot, hash_map->bucket_count) {
            struct cx_hash_map_element_s *elm = hash_map->buckets[slot];
            while (elm != NULL) {
                struct cx_hash_map_element_s *next = elm->next;
                size_t new_slot = elm->key.hash % new_bucket_count;

                // find position where to insert
                struct cx_hash_map_element_s *bucket_next = new_buckets[new_slot];
                struct cx_hash_map_element_s *bucket_prev = NULL;
                while (bucket_next != NULL && bucket_next->key.hash < elm->key.hash) {
                    bucket_prev = bucket_next;
                    bucket_next = bucket_next->next;
                }

                // insert
                if (bucket_prev == NULL) {
                    elm->next = new_buckets[new_slot];
                    new_buckets[new_slot] = elm;
                } else {
                    bucket_prev->next = elm;
                    elm->next = bucket_next;
                }

                // advance
                elm = next;
            }
        }

        // assign result to the map
        hash_map->bucket_count = new_bucket_count;
        cxFree(map->allocator, hash_map->buckets);
        hash_map->buckets = new_buckets;
    }
    return 0;
}

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