LibHashSet is a simple hash set implementation for C99.
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Introduction

LibHashSet is a hash set and hash map implementation for C99. It uses open addressing and double hashing.

At this time, the only types of elements supported are uint16_t, uint32_t and uint64_t.

This hash set implementation has successfully been tested to efficiently handle several billions of items 😏

Getting Started

Here is a simple example of how to use LibHashSet in your application:

#include <hash_set.h>
#include <stdio.h>

int main(void)
{
	uint64_t item;
	uintptr_t cursor = 0U;

	/* create new hash set instance */
	hash_set64_t* const hash_set = hash_set_create64(0U, -1.0, 42U);
	if (!hash_set)
	{
		fputs("Allocation has failed!\n", stderr);
		return EXIT_FAILURE;
	}

	/* add a number of items to the hash set, the set will grow as needed */
	puts("Insertign items, please wait...");
	while (have_more_items())
	{
		const errno_t error = hash_set_insert64(hash_set, get_next_item());
		if (error)
		{
			fprintf(stderr, "Insert operation has failed! (error: %d)\n", error);
			return EXIT_FAILURE;
		}
	}
	puts("Done.\n");

	/* print total number of items in the hash set*/
	printf("Total number of items: %zu\n\n", hash_set_size64(hash_set));

	/* print all items in the set */
	while (hash_set_iterate64(hash_set, &cursor, &item) == 0)
	{
		printf("Item: %016llX\n", item);
	}

	/* destroy the hash set, when it is no longer needed! */
	hash_set_destroy64(hash_set);
	return EXIT_SUCCESS;
}

API Reference

This section describes the LibHashSet programming interface. The functions for managing hash sets are declared in <hash_set.h>, whereas the functions for managing to hash maps are declared in <hash_map.h>.

LibHashSet supports sets and maps containing elements of different integral types. For each element type, separate functions are provided. The functions for uint16_t, uint32_t and uint64_t can be distinguished by the suffix …16, …32 and …64, respectively. In the following, the functions are described in their "generic" form.

Note: On Microsoft Windows (Visual C++), when using LibHashSet as a "shared" library (DLL file), the macro HASHSET_DLL must be defined before including the <hash_set.h> or <hash_map.h> header files!

Types

hash_set_t

A struct that represents a LibHashSet hash set instance. Hash set instances can be allocated and de-allocated via the hash_set_create() and hash_set_destroy() functions, respectively.

Note: Application code shall treat this struct as opaque. The internals may change in future versions!

typedef struct _hash_set hash_set_t;

hash_map_t

A struct that represents a LibHashSet hash map instance. Hash map instances can be allocated and de-allocated via the hash_map_create() and hash_map_destroy() functions, respectively.

Note: Application code shall treat this struct as opaque! The internals may change in future versions!

typedef struct _hash_map hash_map_t;

Globals

Version information

The major, minor and patch version of the LibHashSet library:

extern const uint16_t HASHSET_VERSION_MAJOR;
extern const uint16_t HASHSET_VERSION_MINOR;
extern const uint16_t HASHSET_VERSION_PATCH;

Build information

The build date and time of the LibHashSet library:

extern const char *const HASHSET_BUILD_DATE;
extern const char *const HASHSET_BUILD_TIME;

Set Functions

This section describes all functions for managing hash_set_t instances.

hash_set_create()

Allocates a new hash set instance. The new hash set instance is empty initially.

hash_set_t *hash_set_create(
	const size_t initial_capacity,
	const double load_factor,
	const uint64_t seed
);

Parameters

  • initial_capacity
    The initial capacity of the hash set (number of items). The given count will be rounded to the next power of two. If the number of items to be inserted into the hash set can be estimated beforehand, then the initial capacity should be adjusted accordingly to avoid unnecessary re-allocations. In any case, the hash set will be able to grow dynamically as needed. If this parameter is set to zero, the the default initial capacity (8192) is used.

  • load_factor
    The load factor to be applied to the hash set. The given load factor will be clipped to the 0.1 to 1.0 range. Generally, the default load factor (0.75) offers a good trade-off between performance and memory usage. Higher load factors decrease the memory overhead, but also may increase the time required for insert, lookup and remove operations. If this parameter is less than or equal to zero, the default load factor is used.

  • seed
    The "seed" value that is used to tweak the internal hash computation. The application should set this parameter to a value that is hard to predict and that is unlikely to repeat (e.g., a high-resolution timer is suitable here).

Return value

On success, this function returns a pointer to a new hash set instance. On error, a NULL pointer is returned.

Note: To avoid a memory leak, the returned pointer must be de-allocated by the application using the hash_set_destroy() function, as soon as the instance is not needed anymore!

hash_set_destroy()

De-allocates an existing hash set instance. All items in the hash set are discarded.

void hash_set_destroy(
	hash_set_t *instance
);

Parameters

  • instance
    A pointer to the hash set instance that is to be destroyed, as returned by the hash_set_create() function.
    Note: The given pointer is invalidated by this function, and it must not be used afterwards!

hash_set_insert()

Tries to insert the given item into the hash set. The operation fails, if the set already contains the given item.

Note: If the item is actually inserted, then the hash set may need to grow.

errno_t hash_set_insert(
	hash_set_t *const instance,
	const value_t item
);

Parameters

  • instance
    A pointer to the hash set instance to be modified, as returned by the hash_set_create() function.

  • item
    The item to be inserted into the hash set.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was set to NULL.

  • EEXIST
    The given item was not inserted into the hash set (again), because it was already present.

  • ENOMEM
    The set failed to grow, because the required amount of memory could not be allocated (out of memory).

  • EFBIG
    The set needs to grow, but doing so would exceed the maximum size supported by the underlying system.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_set_remove()

Tries to remove the given item from the hash set. The operation fails, if the set does not contain the given item.

Note: If the item is actually removed, then the hash set may shrink.

errno_t hash_set_remove(
	hash_set_t *const instance,
	const value_t item
);

Parameters

  • instance
    A pointer to the hash set instance to be modified, as returned by the hash_set_create() function.

  • item
    The item to be removed from the hash set.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was set to NULL.

  • ENOENT
    The given item could not be removed from the hash set, because no such item was present.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_set_clear()

Discards all items from the hash set at once.

errno_t hash_set_clear(
	hash_set_t *const instance
);

Parameters

  • instance
    A pointer to the hash set instance to be modified, as returned by the hash_set_create() function.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was set to NULL.

  • EAGAIN
    The hash set was not cleared, because it already was empty. Please try again later!

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_set_contains()

Tests whether the hash set contains an item. The operation fails, if the set does not contain the given item.

errno_t hash_set_contains(
	const hash_set_t *const instance,
	const value_t item
);

Parameters

  • instance
    A pointer to the hash set instance to be examined, as returned by the hash_set_create() function.

  • item
    The item to be searched in the hash set.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was set to NULL.

  • ENOENT
    The hash set does not contain the specified item.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_set_iterate()

Iterates through the items stored in the hash set. The elements are iterated in no particular order.

This function returns one item at a time. It should be called repeatedly, until the end of the set is encountered.

Warning: The result is undefined, if the set is modified while the iteration is in progress!

errno_t hash_set_iterate(
	const hash_set_t *const instance,
	size_t *const cursor,
	value_t *const item
);

Parameters

  • instance
    A pointer to the hash set instance to be examined, as returned by the hash_set_create() function.

  • cursor
    A pointer to a variable of type size_t where the current iterator state (position) is saved.
    This variable must be initialized to the value 0U, by the calling application, prior to the the first invocation!
    Each invocation will update the value of *cursor. This value shall not be altered by the application.

  • item
    A pointer to a variable of type value_t where the next item in the set is stored on success.
    The content of the variable should be considered undefined, if the invocation has failed.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was set to NULL.

  • ENOENT
    No more items. The end of the set has been encountered.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_set_size()

Returns the current number of (distinct) items in the hash set.

size_t hash_set_size(
	const hash_set_t *const instance
);

Parameters

  • instance
    A pointer to the hash set instance to be examined, as returned by the hash_set_create() function.

Return value

This function returns the number of (distinct) items in the hash set.

hash_set_info()

Returns technical information about the hash set.

errno_t hash_set_info(
	const hash_set_t *const instance,
	size_t *const capacity,
	size_t *const valid,
	size_t *const deleted,
	size_t *const limit
);

Parameters

  • instance
    A pointer to the hash set instance to be examined, as returned by the hash_set_create() function.

  • capacity
    A pointer to a variable of type size_t where the current total capacity of the hash set is stored.
    This value will always be greater than or equal to the sum of the valid and deleted entries.

  • valid
    A pointer to a variable of type size_t where the current number of valid entries in the hash set is stored.
    This value is equivalent to the return value of the hash_set_size() function.

  • deleted
    A pointer to a variable of type size_t where the current number of deleted entries in the hash set is stored.
    For technical reasons, entires are not removed from the set immediately, but are marked as "deleted".

  • limit
    A pointer to a variable of type size_t where the current "grow" limit of the hash set is stored.
    The hash set is grown automatically, as soon as the sum of the valid and deleted entries exceeds this limit.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was set to NULL.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_set_dump()

Dump the current status and content of all "slots" of the hash set.

errno_t hash_set_dump(
	const hash_set_t *const instance,
	const hash_map_callback_t callback
);

Parameters

  • instance
    A pointer to the hash set instance to be examined, as returned by the hash_set_create() function.

  • callback
    A pointer to the callback function that will be invoked once for every "slot" in the hash set.

    The callback function is defined as follows:

    typedef int (*hash_map_callback_t)(
    	const size_t index,
    	const char status,
    	const value_t key,
    	const value_t value
    );
    
    Parameters
    • index
      The index of the current "slot" within the hash set.

    • status
      Indicates the status of the current "slot":

      • 'u' the slot is unused
      • 'v' the slot is valid
      • 'd' the slot is deleted
    • item
      The item that is stored at the current "slot" index.

    Return value

    If the function returns a non-zero value, the iteration continues; otherwise it is cancelled.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was set to NULL.

  • ECANCELED
    The operation was cancelled by the calling application.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

Map Functions

This section describes all functions for managing hash_map_t instances.

hash_map_create()

Allocates a new hash map instance. The new hash map instance is empty initially.

hash_map_t *hash_map_create(
	const size_t initial_capacity,
	const double load_factor,
	const uint64_t seed
);

Parameters

  • initial_capacity
    The initial capacity of the hash map. The given count will be rounded to the next power of two. If the number of key-value pairs to be inserted into the hash map can be estimated beforehand, then the initial capacity should be adjusted accordingly to avoid unnecessary re-allocations. In any case, the hash map will be able to grow dynamically as needed. If this parameter is map to zero, the the default initial capacity (8192) is used.

  • load_factor
    The load factor to be applied to the hash map. The given load factor will be clipped to the 0.1 to 1.0 range. Generally, the default load factor (0.75) offers a good trade-off between performance and memory usage. Higher load factors decrease the memory overhead, but also may increase the time required for insert, lookup and remove operations. If this parameter is less than or equal to zero, the default load factor is used.

  • seed
    The "seed" value that is used to tweak the internal hash computation. The application should set this parameter to a value that is hard to predict and that is unlikely to repeat (e.g., a high-resolution timer is suitable here).

Return value

On success, this function returns a pointer to a new hash map instance. On error, a NULL pointer is returned.

Note: To avoid a memory leak, the returned pointer must be de-allocated by the application using the hash_map_destroy() function, as soon as the instance is not needed anymore!

hash_map_destroy()

De-allocates an existing hash map instance. All key-value pairs in the hash map are discarded.

void hash_map_destroy(
	hash_map_t *instance
);

Parameters

  • instance
    A pointer to the hash map instance that is to be destroyed, as returned by the hash_map_create() function.
    Note: The given pointer is invalidated by this function, and it must not be used afterwards!

hash_map_insert()

Tries to insert the given key-value pair into the hash map.

Note: If the key is actually inserted, then the hash map may need to grow.

errno_t hash_map_insert(
	hash_map_t *const instance,
	const value_t key,
	const value_t value,
	const int update
);

Parameters

  • instance
    A pointer to the hash map instance to be modified, as returned by the hash_map_create() function.

  • key
    The key to be inserted into the hash map.

  • value
    The value to be associated with the given key.

  • update
    If the map already contains the specified key, then if this parameter is non-zero, the value associated with the existing key will be updated; otherwise, the value currently associated with key remains unchanged.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • EEXIST
    The given key was not inserted into the hash map (again), because it was already present.
    Nonetheless, if update was non-zero, the value associated with the existing key has been updated.

  • ENOMEM
    The map failed to grow, because the required amount of memory could not be allocated (out of memory).

  • EFBIG
    The map needs to grow, but doing so would exceed the maximum size supported by the underlying system.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_map_remove()

Tries to remove the given key from the hash map. The operation fails, if the map does not contain the given key.

The value associated with the removed key is discarded.

Note: If the key is actually removed, then the hash map may shrink.

errno_t hash_map_remove(
	hash_map_t *const instance,
	const value_t key,
	value_t *const value
);

Parameters

  • instance
    A pointer to the hash map instance to be modified, as returned by the hash_map_create() function.

  • key
    The key to be removed from the hash map.

  • value
    A pointer to a variable of type value_t where the value that was associated with the deleted key is stored.
    The content of the variable should be considered undefined, if the key could not be removed.
    Note: This parameter can be set to NULL, in which case the value will not be reported to the application.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • ENOENT
    The given key could not be removed from the hash map, because no such key was present.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_map_clear()

Discards all key-value pairs from the hash map at once.

errno_t hash_map_clear(
	hash_map_t *const instance
);

Parameters

  • instance
    A pointer to the hash map instance to be modified, as returned by the hash_map_create() function.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • EAGAIN
    The hash map was not cleared, because it already was empty. Please try again later!

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_map_contains()

Tests whether the hash map contains a key. The operation fails, if the map does not contain the given key.

errno_t hash_map_contains(
	const hash_map_t *const instance,
	const value_t key
);

Parameters

  • instance
    A pointer to the hash map instance to be examined, as returned by the hash_map_create() function.

  • key
    The key to be searched in the hash map.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • ENOENT
    The hash map does not contain the specified key.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_map_get()

Retrieves the value that is associated with the given key. The operation fails, if the map does not contain the key.

errno_t hash_map_get(
	const hash_map_t *const instance,
	const value_t key,
	value_t *const value
);

Parameters

  • instance
    A pointer to the hash map instance to be examined, as returned by the hash_map_create() function.

  • key
    The key to be searched in the hash map.

  • value
    A pointer to a variable of type value_t where the value associated with the key is stored on success.
    The content of the variable should be considered undefined, if the invocation has failed.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • ENOENT
    The hash map does not contain the specified key.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_map_iterate()

Iterates through the key-value pairs stored in the hash map. The entries are iterated in no particular order.

This function returns one key-value pair at a time. It should be called repeatedly, until the end of the map is encountered.

Warning: The result is undefined, if the map is modified while the iteration is in progress!

errno_t hash_map_iterate(
	const hash_map_t *const instance,
	size_t *const cursor,
	value_t *const key,
	value_t *const value
);

Parameters

  • instance
    A pointer to the hash map instance to be examined, as returned by the hash_map_create() function.

  • cursor
    A pointer to a variable of type size_t where the current iterator state (position) is saved.
    This variable must be initialized to the value 0U, by the calling application, prior to the the first invocation!
    Each invocation will update the value of *cursor. This value shall not be altered by the application.

  • key
    A pointer to a variable of type value_t where the next key in the map is stored on success.
    The content of the variable should be considered undefined, if the invocation has failed.

  • value
    A pointer to a variable of type value_t where the next value in the map is stored on success.
    The content of the variable should be considered undefined, if the invocation has failed.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • ENOENT
    No more entries. The end of the map has been encountered.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_map_size()

Returns the current number of (distinct) keys in the hash map.

size_t hash_map_size(
	const hash_map_t *const instance
);

Parameters

  • instance
    A pointer to the hash map instance to be examined, as returned by the hash_map_create() function.

Return value

This function returns the number of (distinct) keys in the hash map.

hash_map_info()

Returns technical information about the hash map.

errno_t hash_map_info(
	const hash_map_t *const instance,
	size_t *const capacity,
	size_t *const valid,
	size_t *const deleted,
	size_t *const limit
);

Parameters

  • instance
    A pointer to the hash map instance to be examined, as returned by the hash_map_create() function.

  • capacity
    A pointer to a variable of type size_t where the current total capacity of the hash map is stored.
    This value will always be greater than or equal to the sum of the valid and deleted entries.

  • valid
    A pointer to a variable of type size_t where the current number of valid entries in the hash map is stored.
    This value is equivalent to the return value of the hash_map_size() function.

  • deleted
    A pointer to a variable of type size_t where the current number of deleted entries in the hash map is stored.
    For technical reasons, entires are not removed from the map immediately, but are marked as "deleted".

  • limit
    A pointer to a variable of type size_t where the current "grow" limit of the hash map is stored.
    The hash map is grown automatically, as soon as the sum of the valid and deleted entries exceeds this limit.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

hash_map_dump()

Dump the current status and content of all "slots" of the hash map.

errno_t hash_map_dump(
	const hash_map_t *const instance,
	const hash_map_callback_t callback
);

Parameters

  • instance
    A pointer to the hash map instance to be examined, as returned by the hash_map_create() function.

  • callback
    A pointer to the callback function that will be invoked once for every "slot" in the hash map.

    The callback function is defined as follows:

    typedef int (*hash_map_callback_t)(
    	const size_t index,
    	const char status,
    	const value_t key,
    	const value_t value
    );
    
    Parameters
    • index
      The index of the current "slot" within the hash map.

    • status
      Indicates the status of the current "slot":

      • 'u' the slot is unused
      • 'v' the slot is valid
      • 'd' the slot is deleted
    • key
      The key that is stored at the current "slot" index.

    • value
      The value that is stored at the current "slot" index.

    Return value

    If the function returns a non-zero value, the iteration continues; otherwise it is cancelled.

Return value

On success, this function returns zero. On error, the appropriate error code is returned. Possible error codes include:

  • EINVAL
    An invalid argument was given, e.g. instance was map to NULL.

  • ECANCELED
    The operation was cancelled by the calling application.

  • EFAULT
    Something else went wrong. This usually indicates an internal error and is not supposed to happen.

Thread Safety

LibHashSet is thread-safe, in the sense that all public functions operate exclusively on the given hash_set_t or hash_map_t instance; there is no implicit shared "global" state. This means that no synchronization is required in multi-threaded applications, provided that each instance is created and accessed only by a single thread.

However, LibHashSet does nothing to synchronize access to a particular hash_set_t or hash_map_t instance! Consequently, in situations where the same instance needs to be shared across multiple concurrent threads, the calling application is responsible for serializing all access to the "shared" instance, e.g. by using a mutex lock!

Source Codes

The "official" Git repository is mirrored at:

  • git clone https://github.com/lordmulder/HashSet.git (Browse)

  • git clone https://punkindrublic.mooo.com:3000/Muldersoft/LibHashSet.git (Browse)

  • git clone https://gitlab.com/lord_mulder/libhashset.git (Browse)

Build Instructions

This section describes how to build LibHashSet from the source codes.

Windows

On Microsoft Windows, project/solution files are provided to build LibHashSet with Microsoft Visual Studio.

LibHashSet also can be built using GCC or Clang via MSYS2/Mingw-w64 or Cygwin. Be sure that GCC (or Clang) and GNU make are installed. Then run make from the project base directory, in the MSYS2 (or Cygwin) shell!

Linux and *BSD

On Linux or *BSD, building LibHashSet with GCC or Clang is recommended. Also GNU make is required to build.

Simply run make (or gmake, if on *BSD) from the project base directory. That's it!

Influential environment variables

The following environment variables can be used to control the build process:

  • CC specifies the C compiler (default is cc)

  • STRIP set to a non-zero value in order to strip the generated binaries

  • STATIC set to a non-zero value in order to enable static linking

  • FLTO set to a non-zero value in order to enable link-time optimizer (-flto)

  • DEBUG set to a non-zero value in order to enable "debug" build

  • ASAN set to a non-zero value in order to enable the address-sanitizer

License

This work has been released under the CC0 1.0 Universal license.

For details, please refer to:
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