r6.1.1:lfds611_freelist
Source Files
/liblfds611/src/lfds611_freelist/lfds611_freelist_delete.c /liblfds611/src/lfds611_freelist/lfds611_freelist_get_and_set.c /liblfds611/src/lfds611_freelist/lfds611_freelist_new.c /liblfds611/src/lfds611_freelist/lfds611_freelist_pop_push.c /liblfds611/src/lfds611_freelist/lfds611_freelist_query.c /liblfds611/src/lfds611_freelist/lfds611_freelist_internal.h /liblfds611/inc/liblfds611.h
Incomplete Types
struct lfds611_freelist_state; struct lfds611_freelist_element;
Enums
enum lfds611_freelist_query_type { LFDS611_FREELIST_QUERY_ELEMENT_COUNT, LFDS611_FREELIST_QUERY_VALIDATE };
Prototypes
int lfds611_freelist_new( struct lfds611_freelist_state **fs, lfds611_atom_t number_elements, int (*user_data_init_function)(void **user_data, void *user_state), void *user_state ); void lfds611_freelist_use( struct lfds611_freelist_state *fs ); void lfds611_freelist_delete( struct lfds611_freelist_state **fs, void (*user_data_delete_function)(void *user_data, void *user_state), void *user_state ); lfds611_atom_t lfds611_freelist_new_elements( struct lfds611_freelist_state *fs, lfds611_atom_t number_elements ); struct lfds611_freelist_element *lfds611_freelist_pop( void *lfds611_freelist_state, struct lfds611_freelist_element **fe ); struct lfds611_freelist_element *lfds611_freelist_guaranteed_pop( struct lfds611_freelist_state *fs, struct lfds611_freelist_element **fe ); void lfds611_freelist_push( struct lfds611_freelist_state *fs, struct lfds611_freelist_element *fe ); void *lfds611_freelist_get_user_data_from_element( struct lfds611_freelist_element *fe, void **user_data ); void lfds611_freelist_set_user_data_in_element( struct lfds611_freelist_element *fe, void *user_data ); void lfds611_freelist_query( struct lfds611_freelist_state *fs, enum lfds611_freelist_query_type query_type, void *query_input, void *query_output );
Overview
This API implements a freelist. A new freelist is instantiated by the lfds611_freelist_new function, where the argument number_elements is the maximum number of elements which can be popped from the freelist at any one time. The caller then uses the freelist by pushing and popping, via the lfds611_freelist_push and lfds611_freelist_pop functions, respectively. A push or pop operation will push or pop a single freelist element. A freelist element contains a single void pointer of user data, which is read and written using the functions lfds611_freelist_get_user_data_from_element and lfds611_freelist_set_user_data_in_element, respectively. These void pointers are expected to point to user allocated state although of course they can be used directly to store a single value. Finally, the freelist is deleted using lfds611_freelist_delete.
The function lfds611_freelist_pop only fails when there are no elements available in the freelist. In this case, the function lfds611_freelist_guaranteed_pop can be called. This allocates a single new element and then provides that element. This permanently increases the maximum number of elements in the freelist by one. This function only fails when malloc fails.
Lock-free Specific Behaviour
The maximum number of elements in the freelist must be specified when the freelist is created and these elements are allocated in full when the freelist is created. It is possible after the freelist is created to increase the number of elements in the freelist, by using the function lfds611_freelist_guaranteed_pop, but it is never possible to decrease the number of elements in the freelist; the freelist can only grow. This is why there are only functions for adding elements to an existing freelist and no functions for deleting elements which have been removed from the freelist.
Note that the function for adding new elements to a freelist (lfds611_freelist_new_elements) is (as would be expected in a lock-free data structure) thread-safe. Multiple threads can concurrently be calling this function as well as other threads engaging in the normal push and pop operations.
Algorithm
This freelist implements Treiber's stack algorithm (a freelist is a pre-filled stack). As such it does not truly scale; contention for entry and exit to and from the stack ultimately reduces performance as the CPU count increases. Indeed, with enough CPUs, performance becomes less than with fewer CPUs, for there are so many threads, they almost always fail in their attempt to enter or leave the stack and so are prevented from doing other work.
There is a far more scalable stack, based on the work done by Hendler, Shavit and Yerushalmi, which I understand (I've not looked at in depth) is basically the Treiber stack but with a layer in front of the stack where any threads which at the same time wish to push and pop can exchange their respective operations (the pusher giving his element to the popper) and so avoid having to touch the freelist. I intend to implement this in the future.