mnesia_frag_hash
Defines mnesia_frag_hash callback behaviour
The module mnesia_frag_hash
defines a callback
behaviour for user defined hash functions of fragmented tables.
Which module that is selected to implement the mnesia_frag_hash
behaviour for a particular fragmented table is specified together
with the other frag_properties
. The hash_module
defines
the module name. The hash_state
defines the initial hash state.
It implements dynamic hashing which is a kind of hashing that grows nicely when new fragments are added. It is well suited for scalable hash tables
Functions
init_state(Tab, State) -> NewState | abort(Reason)
Tab = atom()
State = term()
NewState = term()
Reason = term()
This function is invoked when a fragmented table is
created with mnesia:create_table/2
or when a
normal (un-fragmented) table is converted to be a
fragmented table with mnesia:change_table_frag/2
.
Note that the add_frag/2
function will be invoked
one time each for the rest of the fragments (all but number 1)
as a part of the table creation procedure.
State
is the initial value of the hash_state
frag_property
. The NewState
will be stored as
hash_state
among the other frag_properties
.
add_frag(State) -> {NewState, IterFrags, AdditionalLockFrags} | abort(Reason)
State = term()
NewState = term()
IterFrags = [integer()]
AdditionalLockFrags = [integer()]
Reason = term()
In order to scale well, it is a good idea ensure that the records are evenly distributed over all fragments including the new one.
The NewState
will be stored as hash_state
among the
other frag_properties
.
As a part of the add_frag
procedure, Mnesia will iterate
over all fragments corresponding to the IterFrags
numbers
and invoke key_to_frag_number(NewState,RecordKey)
for
each record. If the new fragment differs from the old
fragment, the record will be moved to the new fragment.
As the add_frag
procedure is a part of a schema
transaction Mnesia will acquire a write locks on the
affected tables. That is both the fragments corresponding
to IterFrags
and those corresponding to
AdditionalLockFrags
.
del_frag(State) -> {NewState, IterFrags, AdditionalLockFrags} | abort(Reason)
State = term()
NewState = term()
IterFrags = [integer()]
AdditionalLockFrags = [integer()]
Reason = term()
The NewState
will be stored as hash_state
among the
other frag_properties
.
As a part of the del_frag
procedure, Mnesia will iterate
over all fragments corresponding to the IterFrags
numbers
and invoke key_to_frag_number(NewState,RecordKey)
for
each record. If the new fragment differs from the old
fragment, the record will be moved to the new fragment.
Note that all records in the last fragment must be moved to another fragment as the entire fragment will be deleted.
As the del_frag
procedure is a part of a schema
transaction Mnesia will acquire a write locks on the
affected tables. That is both the fragments corresponding
to IterFrags
and those corresponding to
AdditionalLockFrags
.
key_to_frag_number(State, Key) -> FragNum | abort(Reason)
FragNum = integer()()
Reason = term()
This function is invoked whenever Mnesia needs to determine which fragment a certain record belongs to. It is typically invoked at read, write and delete.
match_spec_to_frag_numbers(State, MatchSpec) -> FragNums | abort(Reason)
MatcSpec = ets_select_match_spec()
FragNums = [FragNum]
FragNum = integer()
Reason = term()
This function is invoked whenever Mnesia needs to determine which fragments that needs to be searched for a MatchSpec. It is typically invoked at select and match_object.
See Also
mnesia(3)