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under the License.
Miscellaneous Mnesia Features
Claes Wikström, Hans Nilsson and Håkan Mattsson
Mnesia_chap5.xml
The previous sections describe how to get started
with Mnesia and how to build a Mnesia database. This
section describes the more advanced features available
when building a distributed, fault-tolerant Mnesia database.
The following topics are included:
- Indexing
- Distribution and fault tolerance
- Table fragmentation
- Local content tables
- Disc-less nodes
- More about schema management
- Mnesia event handling
- Debugging Mnesia applications
- Concurrent processes in Mnesia
- Prototyping
- Object-based programming with Mnesia
Indexing
Data retrieval and matching can be performed efficiently
if the key for the record is known. Conversely, if the key is
unknown, all records in a table must be searched. The larger the
table, the more time consuming it becomes. To remedy this
problem, Mnesia indexing capabilities are used to improve
data retrieval and matching of records.
The following two functions manipulate indexes on existing
tables:
- mnesia:add_table_index(Tab, AttributeName)
-> {aborted, R} |{atomic, ok}
- mnesia:del_table_index(Tab, AttributeName)
-> {aborted, R} |{atomic, ok}
These functions create or delete a table index on a field
defined by AttributeName. To illustrate this, add an
index to the table definition (employee, {emp_no, name,
salary, sex, phone, room_no}), which is the example table
from the Company database. The function that
adds an index on element salary can be expressed
as mnesia:add_table_index(employee, salary).
The indexing capabilities of Mnesia are used with the
following three functions, which retrieve and match records
based on index entries in the database:
-
mnesia:index_read(Tab, SecondaryKey, AttributeName)
-> transaction abort | RecordList
avoids an exhaustive search of the entire table, by looking up
SecondaryKey in the index to find the primary keys.
-
mnesia:index_match_object(Pattern, AttributeName)
-> transaction abort | RecordList
avoids an exhaustive search of the entire table, by looking up
the secondary key in the index to find the primary keys.
The secondary key is found in field AttributeName of
Pattern. The secondary key must be bound.
-
mnesia:match_object(Pattern)
-> transaction abort | RecordList
uses indexes to avoid exhaustive search of the entire table.
Unlike the previous functions, this function can use
any index as long as the secondary key is bound.
These functions are further described and exemplified in
Pattern Matching.
Distribution and Fault Tolerance
Mnesia is a distributed, fault-tolerant DBMS. Tables
can be replicated on different Erlang nodes in various
ways. The Mnesia programmer does not need to state
where the different tables reside, only the names of the
different tables need to be specified in the program code. This
is known as "location transparency" and is an important
concept. In particular:
A program works regardless of the data
location. It makes no difference whether the data
resides on the local node or on a remote node.
Notice that the program runs slower if the data
is located on a remote node.
- The database can be reconfigured, and tables can be
moved between nodes. These operations do not affect the user
programs.
It has previously been shown that each table has a number of
system attributes, such as index and type.
Table attributes are specified when the table is created. For
example, the following function creates a table with two
RAM replicas:
mnesia:create_table(foo,
[{ram_copies, [N1, N2]},
{attributes, record_info(fields, foo)}]).
Tables can also have the following properties,
where each attribute has a list of Erlang nodes as its value:
-
ram_copies. The value of the node list is a list
of Erlang nodes, and a RAM replica of the table resides on
each node in the list.
Notice that no disc operations are performed when
a program executes write operations to these replicas.
However, if permanent RAM replicas are required, the
following alternatives are available:
- The function
mnesia:dump_tables/1
can be used to dump RAM table replicas to disc.
- The table replicas can be backed up, either from
RAM, or from disc if dumped there with this function.
- disc_copies. The value of the attribute is a list
of Erlang nodes, and a replica of the table resides both
in RAM and on disc on each node in the list. Write operations
addressed to the table address both the RAM and the disc
copy of the table.
- disc_only_copies. The value of the attribute is a
list of Erlang nodes, and a replica of the table resides
only as a disc copy on each node in the list. The major
disadvantage of this type of table replica is the access
speed. The major advantage is that the table does not occupy
space in memory.
In addition, table properties can be set and changed.
For details, see
Define a Schema.
There are basically two reasons for using more than one table
replica: fault tolerance and speed. Notice
that table replication provides a solution to both of these
system requirements.
If there are two active table replicas, all information is
still available if one replica fails. This can be an
important property in many applications. Furthermore, if a table
replica exists at two specific nodes, applications that execute
at either of these nodes can read data from the table without
accessing the network. Network operations are considerably
slower and consume more resources than local operations.
It can be advantageous to create table replicas for a
distributed application that reads data often, but writes data
seldom, to achieve fast read operations on the local
node. The major disadvantage with replication is the increased
time to write data. If a table has two replicas, every write
operation must access both table replicas. Since one of these
write operations must be a network operation, it is considerably
more expensive to perform a write operation to a replicated
table than to a non-replicated table.
Table Fragmentation
Concept
A concept of table fragmentation has been introduced
to cope with large tables. The idea is to split a
table into several manageable fragments. Each fragment is
implemented as a first class Mnesia table and can be
replicated, have indexes, and so on, as any other table. But
the tables cannot have local_content or have the
snmp connection activated.
To be able to access a record in a fragmented
table, Mnesia must determine to which fragment the
actual record belongs. This is done by module
mnesia_frag, which implements the mnesia_access
callback behavior. It is recommended to read the
documentation about the function
mnesia:activity/4
to see how mnesia_frag
can be used as a mnesia_access callback module.
At each record access, mnesia_frag first computes
a hash value from the record key. Second, the name of the
table fragment is determined from the hash value.
Finally the actual table access is performed by the same
functions as for non-fragmented tables. When the key is
not known beforehand, all fragments are searched for
matching records.
Notice that in ordered_set tables, the records
are ordered per fragment, and the the order is undefined in
results returned by select and match_object.
The following code illustrates how a Mnesia table is
converted to be a fragmented table and how more fragments
are added later:
mnesia:start().
ok
(a@sam)2> mnesia:system_info(running_db_nodes).
[b@sam,c@sam,a@sam]
(a@sam)3> Tab = dictionary.
dictionary
(a@sam)4> mnesia:create_table(Tab, [{ram_copies, [a@sam, b@sam]}]).
{atomic,ok}
(a@sam)5> Write = fun(Keys) -> [mnesia:write({Tab,K,-K}) || K <- Keys], ok end.
#Fun
(a@sam)6> mnesia:activity(sync_dirty, Write, [lists:seq(1, 256)], mnesia_frag).
ok
(a@sam)7> mnesia:change_table_frag(Tab, {activate, []}).
{atomic,ok}
(a@sam)8> mnesia:table_info(Tab, frag_properties).
[{base_table,dictionary},
{foreign_key,undefined},
{n_doubles,0},
{n_fragments,1},
{next_n_to_split,1},
{node_pool,[a@sam,b@sam,c@sam]}]
(a@sam)9> Info = fun(Item) -> mnesia:table_info(Tab, Item) end.
#Fun
(a@sam)10> Dist = mnesia:activity(sync_dirty, Info, [frag_dist], mnesia_frag).
[{c@sam,0},{a@sam,1},{b@sam,1}]
(a@sam)11> mnesia:change_table_frag(Tab, {add_frag, Dist}).
{atomic,ok}
(a@sam)12> Dist2 = mnesia:activity(sync_dirty, Info, [frag_dist], mnesia_frag).
[{b@sam,1},{c@sam,1},{a@sam,2}]
(a@sam)13> mnesia:change_table_frag(Tab, {add_frag, Dist2}).
{atomic,ok}
(a@sam)14> Dist3 = mnesia:activity(sync_dirty, Info, [frag_dist], mnesia_frag).
[{a@sam,2},{b@sam,2},{c@sam,2}]
(a@sam)15> mnesia:change_table_frag(Tab, {add_frag, Dist3}).
{atomic,ok}
(a@sam)16> Read = fun(Key) -> mnesia:read({Tab, Key}) end.
#Fun
(a@sam)17> mnesia:activity(transaction, Read, [12], mnesia_frag).
[{dictionary,12,-12}]
(a@sam)18> mnesia:activity(sync_dirty, Info, [frag_size], mnesia_frag).
[{dictionary,64},
{dictionary_frag2,64},
{dictionary_frag3,64},
{dictionary_frag4,64}]
(a@sam)19>
]]>
Fragmentation Properties
The table property frag_properties can be read with
the function
mnesia:table_info(Tab, frag_properties).
The fragmentation properties are a list of tagged tuples with
arity 2. By default the list is empty, but when it is
non-empty it triggers Mnesia to regard the table as
fragmented. The fragmentation properties are as follows:
{n_fragments, Int}
-
n_fragments regulates how many fragments
that the table currently has. This property can explicitly
be set at table creation and later be changed with
{add_frag, NodesOrDist} or
del_frag. n_fragments defaults to 1.
{node_pool, List}
-
The node pool contains a list of nodes and can
explicitly be set at table creation and later be changed
with {add_node, Node} or {del_node, Node}.
At table creation Mnesia tries to distribute
the replicas of each fragment evenly over all the nodes in
the node pool. Hopefully all nodes end up with the
same number of replicas. node_pool defaults to the
return value from the function
mnesia:system_info(db_nodes).
{n_ram_copies, Int}
-
Regulates how many ram_copies replicas
that each fragment is to have. This property can
explicitly be set at table creation. Defaults is
0, but if n_disc_copies and
n_disc_only_copies also are 0,
n_ram_copies defaults to 1.
{n_disc_copies, Int}
-
Regulates how many disc_copies replicas that
each fragment is to have. This property can explicitly
be set at table creation. Default is 0.
{n_disc_only_copies, Int}
-
Regulates how many disc_only_copies replicas
that each fragment is to have. This property can
explicitly be set at table creation. Defaults is
0.
{foreign_key, ForeignKey}
-
ForeignKey can either be the atom
undefined or the tuple {ForeignTab, Attr},
where Attr denotes an attribute that is to be
interpreted as a key in another fragmented table named
ForeignTab. Mnesia ensures that the number of
fragments in this table and in the foreign table are
always the same.
When fragments are added or deleted, Mnesia
automatically propagates the operation to all
fragmented tables that have a foreign key referring to this
table. Instead of using the record key to determine which
fragment to access, the value of field Attr is
used. This feature makes it possible to colocate records
automatically in different tables to the same node.
foreign_key defaults to
undefined. However, if the foreign key is set to
something else, it causes the default values of the
other fragmentation properties to be the same values as
the actual fragmentation properties of the foreign table.
{hash_module, Atom}
-
Enables definition of an alternative hashing scheme.
The module must implement the
mnesia_frag_hash
callback behavior. This property can explicitly be set at
table creation. Default is mnesia_frag_hash.
Older tables, that were created before the concept of
user-defined hash modules was introduced, use module
mnesia_frag_old_hash to be backwards compatible.
mnesia_frag_old_hash still uses the poor
deprecated function erlang:hash/1.
{hash_state, Term}
-
Enables a table-specific parameterization of a
generic hash module. This property can explicitly be set
at table creation. Default is undefined.
mnesia:start().
ok
(a@sam)2> PrimProps = [{n_fragments, 7}, {node_pool, [node()]}].
[{n_fragments,7},{node_pool,[a@sam]}]
(a@sam)3> mnesia:create_table(prim_dict,
[{frag_properties, PrimProps},
{attributes,[prim_key,prim_val]}]).
{atomic,ok}
(a@sam)4> SecProps = [{foreign_key, {prim_dict, sec_val}}].
[{foreign_key,{prim_dict,sec_val}}]
(a@sam)5> mnesia:create_table(sec_dict,
[{frag_properties, SecProps},
(a@sam)5> {attributes, [sec_key, sec_val]}]).
{atomic,ok}
(a@sam)6> Write = fun(Rec) -> mnesia:write(Rec) end.
#Fun
(a@sam)7> PrimKey = 11.
11
(a@sam)8> SecKey = 42.
42
(a@sam)9> mnesia:activity(sync_dirty, Write,
[{prim_dict, PrimKey, -11}], mnesia_frag).
ok
(a@sam)10> mnesia:activity(sync_dirty, Write,
[{sec_dict, SecKey, PrimKey}], mnesia_frag).
ok
(a@sam)11> mnesia:change_table_frag(prim_dict, {add_frag, [node()]}).
{atomic,ok}
(a@sam)12> SecRead = fun(PrimKey, SecKey) ->
mnesia:read({sec_dict, PrimKey}, SecKey, read) end.
#Fun
(a@sam)13> mnesia:activity(transaction, SecRead,
[PrimKey, SecKey], mnesia_frag).
[{sec_dict,42,11}]
(a@sam)14> Info = fun(Tab, Item) -> mnesia:table_info(Tab, Item) end.
#Fun
(a@sam)15> mnesia:activity(sync_dirty, Info,
[prim_dict, frag_size], mnesia_frag).
[{prim_dict,0},
{prim_dict_frag2,0},
{prim_dict_frag3,0},
{prim_dict_frag4,1},
{prim_dict_frag5,0},
{prim_dict_frag6,0},
{prim_dict_frag7,0},
{prim_dict_frag8,0}]
(a@sam)16> mnesia:activity(sync_dirty, Info,
[sec_dict, frag_size], mnesia_frag).
[{sec_dict,0},
{sec_dict_frag2,0},
{sec_dict_frag3,0},
{sec_dict_frag4,1},
{sec_dict_frag5,0},
{sec_dict_frag6,0},
{sec_dict_frag7,0},
{sec_dict_frag8,0}]
(a@sam)17>
]]>
Management of Fragmented Tables
The function mnesia:change_table_frag(Tab, Change)
is intended to be used for reconfiguration of fragmented
tables. Argument Change is to have one of the
following values:
{activate, FragProps}
-
Activates the fragmentation properties of an
existing table. FragProps is either to contain
{node_pool, Nodes} or be empty.
deactivate
-
Deactivates the fragmentation properties of a
table. The number of fragments must be 1. No other
table can refer to this table in its foreign key.
{add_frag, NodesOrDist}
-
Adds a fragment to a fragmented table. All
records in one of the old fragments are rehashed and
about half of them are moved to the new (last)
fragment. All other fragmented tables, which refer to this
table in their foreign key, automatically get a new
fragment. Also, their records are dynamically
rehashed in the same manner as for the main table.
Argument NodesOrDist can either be a list of
nodes or the result from the function
mnesia:table_info(Tab, frag_dist).
Argument NodesOrDist is
assumed to be a sorted list with the best nodes to
host new replicas first in the list. The new fragment
gets the same number of replicas as the first
fragment (see n_ram_copies, n_disc_copies,
and n_disc_only_copies). The NodesOrDist
list must at least contain one element for each
replica that needs to be allocated.
del_frag
-
Deletes a fragment from a fragmented table. All
records in the last fragment are moved to one of the other
fragments. All other fragmented tables, which refer to
this table in their foreign key, automatically lose
their last fragment. Also, their records are
dynamically rehashed in the same manner as for the main
table.
{add_node, Node}
-
Adds a node to node_pool. The new
node pool affects the list returned from the function
mnesia:table_info(Tab, frag_dist).
{del_node, Node}
-
Deletes a node from node_pool. The new
node pool affects the list returned from the function
mnesia:table_info(Tab, frag_dist).
Extensions of Existing Functions
The function
mnesia:create_table/2
creates a brand new fragmented table, by setting table
property frag_properties to some proper values.
The function
mnesia:delete_table/1
deletes a fragmented table including all its
fragments. There must however not exist any other fragmented
tables that refer to this table in their foreign key.
The function
mnesia:table_info/2
now understands item frag_properties.
If the function mnesia:table_info/2 is started in
the activity context of module mnesia_frag,
information of several new items can be obtained:
base_table
- The name of the fragmented table
n_fragments
- The actual number of fragments
node_pool
- The pool of nodes
n_ram_copies
n_disc_copies
n_disc_only_copies
-
The number of replicas with storage type ram_copies,
disc_copies, and disc_only_copies,
respectively. The actual values are dynamically derived
from the first fragment. The first fragment serves as a
protype. When the actual values need to be computed
(for example, when adding new fragments) they are
determined by counting the number of each replica for
each storage type. This means that when the functions
mnesia:add_table_copy/3,
mnesia:del_table_copy/2,
and
mnesia:change_table_copy_type/2 are applied on the
first fragment, it affects the settings on
n_ram_copies, n_disc_copies, and
n_disc_only_copies.
foreign_key
-
The foreign key
foreigners
-
All other tables that refer to this table in
their foreign key
frag_names
-
The names of all fragments
frag_dist
-
A sorted list of {Node, Count} tuples
that are sorted in increasing Count order.
Count is the total number of replicas that this
fragmented table hosts on each Node. The list
always contains at least all nodes in
node_pool. Nodes that do not belong to
node_pool are put last in the list even if
their Count is lower.
frag_size
-
A list of {Name, Size} tuples, where
Name is a fragment Name, and Size is
how many records it contains
frag_memory
-
A list of {Name, Memory} tuples, where
Name is a fragment Name, and Memory is
how much memory it occupies
size
-
Total size of all fragments
memory
-
Total memory of all fragments
Load Balancing
There are several algorithms for distributing records
in a fragmented table evenly over a
pool of nodes. No one is best, it depends on the
application needs. The following examples of
situations need some attention:
- permanent change of nodes. When a new permanent
db_node is introduced or dropped, it can be time to
change the pool of nodes and redistribute the replicas
evenly over the new pool of nodes. It can also be time to
add or delete a fragment before the replicas are redistributed.
- size/memory threshold. When the total size or
total memory of a fragmented table (or a single
fragment) exceeds some application-specific threshold, it
can be time to add a new fragment dynamically to
obtain a better distribution of records.
- temporary node down. When a node temporarily goes
down, it can be time to compensate some fragments with new
replicas to keep the desired level of
redundancy. When the node comes up again, it can be time to
remove the superfluous replica.
- overload threshold. When the load on some node
exceeds some application-specific threshold, it can be time to
either add or move some fragment replicas to nodes with lower
load. Take extra care if the table has a foreign
key relation to some other table. To avoid severe
performance penalties, the same redistribution must be
performed for all the related tables.
Use the function
mnesia:change_table_frag/2 to add new fragments
and apply the usual schema manipulation functions (such as
mnesia:add_table_copy/3,
mnesia:del_table_copy/2,
and
mnesia:change_table_copy_type/2)
on each fragment to perform the actual redistribution.
Local Content Tables
Replicated tables have the same content on all nodes where
they are replicated. However, it is sometimes advantageous to
have tables, but different content on different nodes.
If attribute {local_content, true} is specified when
you create the table, the table resides on the nodes where you
specify the table to exist, but the write operations on the
table are only performed on the local copy.
Furthermore, when the table is initialized at startup, the
table is only initialized locally, and the table
content is not copied from another node.
Disc-Less Nodes
Mnesia can be run on nodes that do not have a disc.
Replicas of disc_copies or disc_only_copies are
not possible on such nodes. This is especially troublesome for
the schema table, as Mnesia needs the schema
to initialize itself.
The schema table can, as other tables, reside on one or
more nodes. The storage type of the schema table can either
be disc_copies or ram_copies
(but not disc_only_copies). At
startup, Mnesia uses its schema to determine with which
nodes it is to try to establish contact. If any
other node is started already, the starting node
merges its table definitions with the table definitions
brought from the other nodes. This also applies to the
definition of the schema table itself. Application
parameter extra_db_nodes contains a list of nodes that
Mnesia also is to establish contact with besides those
found in the schema. Default is [] (empty list).
Hence, when a disc-less node needs to find the schema
definitions from a remote node on the network, this
information must be supplied through application parameter
-mnesia extra_db_nodes NodeList. Without this
configuration parameter set, Mnesia starts as a single
node system. Also, the function
mnesia:change_config/2
can be used to assign a value to extra_db_nodes and force
a connection after Mnesia has been started, that is,
mnesia:change_config(extra_db_nodes, NodeList).
Application parameter schema_location controls where
Mnesia searches for its schema. The parameter can be one
of the following atoms:
disc
-
Mandatory disc. The schema is assumed to be located
in the Mnesia directory. If the schema cannot be found,
Mnesia refuses to start.
ram
-
Mandatory RAM. The schema resides in RAM
only. At startup, a tiny new schema is generated. This
default schema contains only the definition of the schema
table and resides on the local node only. Since no other
nodes are found in the default schema, configuration
parameter extra_db_nodes must be used to let the
node share its table definitions with other nodes. (Parameter
extra_db_nodes can also be used on disc-full nodes.)
opt_disc
-
Optional disc. The schema can reside on either disc or
RAM. If the schema is found on disc, Mnesia starts as
a disc-full node (the storage type of the schema table is
disc_copies). If no schema is found on disc, Mnesia
starts as a disc-less node (the storage type of the schema
table is ram_copies). The default for the
application parameter is opt_disc.
When schema_location is set to opt_disc, the
function
mnesia:change_table_copy_type/3
can be used to change the storage type of the schema.
This is illustrated as follows:
1> mnesia:start().
ok
2> mnesia:change_table_copy_type(schema, node(), disc_copies).
{atomic, ok}
Assuming that the call to
mnesia:start/0 does not
find any schema to read on the disc, Mnesia starts
as a disc-less node, and then change it to a node that
use the disc to store the schema locally.
More about Schema Management
Nodes can be added to and removed from a Mnesia system.
This can be done by adding a copy of the schema to those nodes.
The functions
mnesia:add_table_copy/3
and
mnesia:del_table_copy/2
can be used to add and delete
replicas of the schema table. Adding a node to the list of
nodes where the schema is replicated affects the following:
- It allows other tables to be replicated to this node.
- It causes Mnesia to try to contact the node at
startup of disc-full nodes.
The function call mnesia:del_table_copy(schema,
mynode@host) deletes node mynode@host from the
Mnesia system. The call fails if Mnesia is running
on mynode@host. The other Mnesia nodes never try to
connect to that node again. Notice that if there is a disc resident
schema on node mynode@host, the entire Mnesia
directory is to be deleted. This is done with the function
mnesia:delete_schema/1.
If Mnesia is started again
on node mynode@host and the directory has not been
cleared, the behavior of Mnesia is undefined.
If the storage type of the schema is ram_copies,
that is, a disc-less node, Mnesia
does not use the disc on that particular node. The disc
use is enabled by changing the storage type of table
schema to disc_copies.
New schemas are created explicitly with the function
mnesia:create_schema/1
or implicitly by starting
Mnesia without a disc resident schema. Whenever
a table (including the schema table) is created, it is
assigned its own unique cookie. The schema table is not created
with the function
mnesia:create_table/2
as normal tables.
At startup, Mnesia connects different nodes to each other,
then they exchange table definitions with each other, and the table
definitions are merged. During the merge procedure, Mnesia
performs a sanity test to ensure that the table definitions are
compatible with each other. If a table exists on several nodes,
the cookie must be the same, otherwise Mnesia shut down one
of the nodes. This unfortunate situation occurs if a table
has been created on two nodes independently of each other while
they were disconnected. To solve this, one of the tables
must be deleted (as the cookies differ, it is regarded to be two
different tables even if they have the same name).
Merging different versions of the schema table does not
always require the cookies to be the same. If the storage
type of the schema table is disc_copies, the cookie is
immutable, and all other db_nodes must have the same
cookie. When the schema is stored as type ram_copies,
its cookie can be replaced with a cookie from another node
(ram_copies or disc_copies). The cookie replacement
(during merge of the schema table definition) is performed each
time a RAM node connects to another node.
Further, the following applies:
- mnesia:system_info(schema_location)
and
mnesia:system_info(extra_db_nodes)
can be used to determine the actual values of schema_location
and extra_db_nodes, respectively.
- mnesia:system_info(use_dir)
can be used to determine whether Mnesia is actually
using the Mnesia directory.
- use_dir can be determined even before
Mnesia is started.
The function mnesia:info/0
can now be used to print
some system information even before Mnesia is started.
When Mnesia is started, the function prints more
information.
Transactions that update the definition of a table
requires that Mnesia is started on all nodes where the
storage type of the schema is disc_copies. All replicas of
the table on these nodes must also be loaded. There are a
few exceptions to these availability rules:
- Tables can be created and new replicas can be added
without starting all the disc-full nodes.
- New replicas can be added before all other replicas of
the table have been loaded, provided that at least one other
replica is active.
Mnesia Event Handling
System events and table events are the two event categories
that Mnesia generates in various situations.
A user process can subscribe on the events generated by
Mnesia. The following two functions are provided:
mnesia:subscribe(Event-Category)
- Ensures that a copy of all events of type
Event-Category are sent to the calling process
mnesia:unsubscribe(Event-Category)
- Removes the subscription on events of type
Event-Category
Event-Category can be either of the following:
- The atom system
- The atom activity
- The tuple {table, Tab, simple}
- The tuple {table, Tab, detailed}
The old event category {table, Tab} is the same
event category as {table, Tab, simple}.
The subscribe functions activate a subscription
of events. The events are delivered as messages to the process
evaluating the function
mnesia:subscribe/1
The syntax is as follows:
- {mnesia_system_event, Event} for system events
- {mnesia_activity_event, Event} for activity events
- {mnesia_table_event, Event} for table events
The event types are described in the next sections.
All system events are subscribed by the Mnesia
gen_event handler. The default gen_event handler
is mnesia_event, but it can be changed by using
application parameter event_module. The value of this
parameter must be the name of a module implementing a complete
handler, as specified by the
gen_event module
in STDLIB.
mnesia:system_info(subscribers)
and
mnesia:table_info(Tab, subscribers)
can be used to determine which processes are subscribed to
various events.
System Events
The system events are as follows:
{mnesia_up, Node}
- Mnesia is started on a node. Node is the node
name. By default this event is ignored.
{mnesia_down, Node}
- Mnesia is stopped on a node. Node is the node
name. By default this event is ignored.
{mnesia_checkpoint_activated, Checkpoint}
- A checkpoint with the name Checkpoint is
activated and the current node is involved in the
checkpoint. Checkpoints can be activated explicitly with
the function
mnesia:activate_checkpoint/1
or implicitly at
backup, when adding table replicas, at internal transfer of
data between nodes, and so on. By default this event is
ignored.
{mnesia_checkpoint_deactivated, Checkpoint}
- A checkpoint with the name Checkpoint is
deactivated and the current node is involved in the
checkpoint. Checkpoints can be deactivated explicitly with
the function
mnesia:deactivate/1
or implicitly when the last
replica of a table (involved in the checkpoint) becomes
unavailable, for example, at node-down. By default this
event is ignored.
{mnesia_overload, Details}
Mnesia on the current node is
overloaded and the subscriber is to take action.
A typical overload situation occurs when the
applications perform more updates on disc resident
tables than Mnesia can handle. Ignoring
this kind of overload can lead to a situation where
the disc space is exhausted (regardless of the size of
the tables stored on disc).
Each update is appended to the transaction log and
occasionally (depending on how it
is configured) dumped to the tables files. The
table file storage is more compact than the transaction
log storage, especially if the same record is updated
repeatedly. If the thresholds for dumping the
transaction log are reached before the previous
dump is finished, an overload event is triggered.
Another typical overload situation is when the
transaction manager cannot commit transactions at the
same pace as the applications perform updates of
disc resident tables. When this occurs, the message
queue of the transaction manager continues to grow
until the memory is exhausted or the load
decreases.
The same problem can occur for dirty updates. The overload
is detected locally on the current node, but its cause can
be on another node. Application processes can cause high
load if any table resides on another node (replicated
or not). By default this event
is reported to error_logger.
{inconsistent_database, Context, Node}
- Mnesia regards the database as potential
inconsistent and gives its applications a chance to
recover from the inconsistency. For example, by installing a
consistent backup as fallback and then restart the system.
An alternative is to pick a MasterNode from
mnesia:system_info(db_nodes)
and invoke
mnesia:set_master_node([MasterNode]).
By default an error is reported to error_logger.
{mnesia_fatal, Format, Args, BinaryCore}
-
Mnesia detected a fatal error and
terminates soon. The fault reason is explained in
Format and Args, which can be given as input
to io:format/2 or sent to error_logger. By
default it is sent to error_logger.
BinaryCore is a binary containing a summary of the
Mnesia internal state at the time when the fatal
error was detected. By default the binary is written to a
unique filename on the current directory. On RAM nodes, the
core is ignored.
{mnesia_info, Format, Args}
- Mnesia detected something that can be of
interest when debugging the system. This is explained in
Format and Args, which can appear as input
to io:format/2 or sent to error_logger. By
default this event is printed with io:format/2.
{mnesia_error, Format, Args}
- Mnesia has detected an error. The fault reason is
explained in Format and Args, which can be
given as input to io:format/2 or sent to
error_logger. By default this event is reported to
error_logger.
{mnesia_user, Event}
- An application started the function
mnesia:report_event(Event).
Event can be
any Erlang data structure. When tracing a system of
Mnesia applications, it is useful to be able to
interleave own events of Mnesia with application-related
events that give information about the application context.
Whenever the application starts with a new and demanding
Mnesia activity, or enters a new and interesting
phase in its execution, it can be a good idea to use
mnesia:report_event/1.
Activity Events
Currently, there is only one type of activity event:
{complete, ActivityID}
-
This event occurs when a transaction that caused a modification
to the database is completed. It is useful for determining when
a set of table events (see the next section), caused by a given
activity, have been sent. Once this event is received, it is
guaranteed that no further table events with the same
ActivityID will be received. Notice that this event can
still be received even if no table events with a corresponding
ActivityID were received, depending on
the tables to which the receiving process is subscribed.
Dirty operations always contain only one update and thus no
activity event is sent.
Table Events
Table events are events related to table updates. There are
two types of table events, simple and detailed.
The simple table events are tuples like
{Oper, Record, ActivityId}, where:
- Oper is the operation performed.
- Record is the record involved in the operation.
- ActivityId is the identity of the transaction
performing the operation.
Notice that the record name is the table name even when
record_name has another setting.
The table-related events that can occur are as follows:
{write, NewRecord, ActivityId}
- A new record has been written. NewRecord contains
the new record value.
{delete_object, OldRecord, ActivityId}
- A record has possibly been deleted with
mnesia:delete_object/1.
OldRecord
contains the value of the old record, as stated as argument
by the application. Notice that other records with the same
key can remain in the table if it is of type bag.
{delete, {Tab, Key}, ActivityId}
- One or more records have possibly been deleted.
All records with the key Key in the table
Tab have been deleted.
The detailed table events are tuples like
{Oper, Table, Data, [OldRecs], ActivityId}, where:
- Oper is the operation performed.
- Table is the table involved in the operation.
- Data is the record/OID written/deleted.
- OldRecs is the contents before the operation.
- ActivityId is the identity of the transaction
performing the operation.
The table-related events that can occur are as follows:
{write, Table, NewRecord, [OldRecords], ActivityId}
- A new record has been written. NewRecord contains
the new record value and OldRecords contains the
records before the operation is performed. Notice that the
new content depends on the table type.
{delete, Table, What, [OldRecords], ActivityId}
- Records have possibly been deleted. What is
either {Table, Key} or a record
{RecordName, Key, ...} that was deleted. Notice
that the new content depends on the table type.
Debugging Mnesia Applications
Debugging a Mnesia application can be difficult
for various reasons, primarily related
to difficulties in understanding how the transaction
and table load mechanisms work. Another source of
confusion can be the semantics of nested transactions.
The debug level of Mnesia is set by calling the function
mnesia:set_debug_level(Level),
where Levelis one of the following:
none
- No trace outputs. This is the default.
verbose
- Activates tracing of important debug events. These
events generate {mnesia_info, Format, Args}
system events. Processes can subscribe to these events with
the function
mnesia:subscribe/1.
The events are always sent to the Mnesia event handler.
debug
- Activates all events at the verbose level plus
traces of all debug events. These debug events generate
{mnesia_info, Format, Args} system events. Processes
can subscribe to these events with mnesia:subscribe/1.
The events are always sent to the Mnesia event handler.
On this debug level, the Mnesia event handler starts
subscribing to updates in the schema table.
trace
- Activates all events at the debug level. On this
level, the Mnesia event handler starts subscribing to
updates on all Mnesia tables. This level is intended
only for debugging small toy systems, as many large
events can be generated.
false
- An alias for none.
true
- An alias for debug.
The debug level of Mnesia itself is also an application
parameter, making it possible to start an Erlang system
to turn on Mnesia debug in the initial
startup phase by using the following code:
% erl -mnesia debug verbose
Concurrent Processes in Mnesia
Programming concurrent Erlang systems is the subject of
a separate book. However, it is worthwhile to draw attention to
the following features, which permit concurrent processes to
exist in a Mnesia system:
A group of functions or processes can be called within a
transaction. A transaction can include statements that read,
write, or delete data from the DBMS. Many such
transactions can run concurrently, and the programmer does not
need to explicitly synchronize the processes that manipulate
the data.
All programs accessing the database through the
transaction system can be written as if they had sole access to
the data. This is a desirable property, as all
synchronization is taken care of by the transaction handler. If
a program reads or writes data, the system ensures that no other
program tries to manipulate the same data at the same time.
- Tables can be moved or deleted, and the layout of a table
can be reconfigured in various ways. An important aspect of
the implementation of these functions is that user programs
can continue to use a table while it
is being reconfigured. For example, it is possible to move a
table and perform write operations to the table at the same
time. This is important for many applications that require
continuously available services. For more information, see
Transactions and Other Access Contexts.
Prototyping
If and when you would like to start and manipulate
Mnesia, it is often easier to write the definitions and
data into an ordinary text file.
Initially, no tables and no data exist, or which
tables are required. At the initial stages of prototyping, it
is prudent to write all data into one file, process that
file, and have the data in the file inserted into the database.
Mnesia can be initialized with data read from a text file.
The following two functions can be used to work with text
files.
-
mnesia:load_textfile(Filename)
loads a series of local table definitions and data found in the
file into Mnesia. This function also starts Mnesia
and possibly creates a new schema. The function operates
on the local node only.
-
mnesia:dump_to_textfile(Filename)
dumps all local
tables of a Mnesia system into a text file, which
can be edited (with a normal text editor) and later reloaded.
These functions are much slower than the ordinary store and
load functions of Mnesia. However, this is mainly intended
for minor experiments and initial prototyping. The major
advantage of these functions is that they are easy to use.
The format of the text file is as follows:
{tables, [{Typename, [Options]},
{Typename2 ......}]}.
{Typename, Attribute1, Attribute2 ....}.
{Typename, Attribute1, Attribute2 ....}.
Options is a list of {Key,Value} tuples conforming
to the options that you can give to
mnesia:create_table/2.
For example, to start playing with a small database for healthy
foods, enter the following data into file FRUITS:
The following session with the Erlang shell shows how
to load the FRUITS database:
mnesia:load_textfile("FRUITS").
New table fruit
New table vegetable
{atomic,ok}
2> mnesia:info().
---> Processes holding locks <---
---> Processes waiting for locks <---
---> Pending (remote) transactions <---
---> Active (local) transactions <---
---> Uncertain transactions <---
---> Active tables <---
vegetable : with 2 records occuping 299 words of mem
fruit : with 2 records occuping 291 words of mem
schema : with 3 records occuping 401 words of mem
===> System info in version "1.1", debug level = none <===
opt_disc. Directory "/var/tmp/Mnesia.nonode@nohost" is used.
use fallback at restart = false
running db nodes = [nonode@nohost]
stopped db nodes = []
remote = []
ram_copies = [fruit,vegetable]
disc_copies = [schema]
disc_only_copies = []
[{nonode@nohost,disc_copies}] = [schema]
[{nonode@nohost,ram_copies}] = [fruit,vegetable]
3 transactions committed, 0 aborted, 0 restarted, 2 logged to disc
0 held locks, 0 in queue; 0 local transactions, 0 remote
0 transactions waits for other nodes: []
ok
3>
]]>
It can be seen that the DBMS was initiated from a
regular text file.
Object-Based Programming with Mnesia
The Company database, introduced in
Getting Started,
has three tables that store records (employee,
dept, project), and three tables that store
relationships (manager, at_dep, in_proj).
This is a normalized data model, which has some advantages over
a non-normalized data model.
It is more efficient to do a
generalized search in a normalized database. Some operations are
also easier to perform on a normalized data model. For example,
one project can easily be removed, as the following example
illustrates:
In reality, data models are seldom fully normalized. A
realistic alternative to a normalized database model would be
a data model that is not even in first normal form. Mnesia
is suitable for applications such as telecommunications,
because it is easy to organize data in a flexible manner. A
Mnesia database is always organized as a set of tables.
Each table is filled with rows, objects, and records.
What sets Mnesia apart is that individual fields in
a record can contain any type of
compound data structures. An individual field in a record can
contain lists, tuples, functions, and even record code.
Many telecommunications applications have unique requirements
on lookup times for certain types of records. If the Company
database had been a part of a telecommunications system, it
could be to minimize the lookup time of an employee
together with a list of the projects the employee is
working on. If this is the case, a drastically different data model
without direct relationships can be chosen. You would then have
only the records themselves, and different records could contain
either direct references to other records, or contain other
records that are not part of the Mnesia schema.
The following record definitions can be created:
A record that describes an employee can look as follows:
Me = #employee{emp_no= 104732,
name = klacke,
salary = 7,
sex = male,
phone = 99586,
room_no = {221, 015},
dept = 'B/SFR',
projects = [erlang, mnesia, otp],
manager = 114872},
This model has only three different tables, and the employee
records contain references to other records. The record has the
following references:
- 'B/SFR' refers to a dept record.
- [erlang, mnesia, otp] is a list of three
direct references to three different projects records.
- 114872 refers to another employee record.
The Mnesia record identifiers ({Tab, Key}) can
also be used as references. In this case, attribute dept
would be set to value {dept, 'B/SFR'} instead of
'B/SFR'.
With this data model, some operations execute considerably
faster than they do with the normalized data model in the
Company database. However, some other operations
become much more complicated. In particular, it becomes more
difficult to ensure that records do not contain dangling
pointers to other non-existent, or deleted, records.
The following code exemplifies a search with a non-normalized
data model. To find all employees at department Dep with
a salary higher than Salary, use the following code:
This code is easier to write and to understand, and it
also executes much faster.
It is easy to show examples of code that executes faster if
a non-normalized data model is used, instead of a normalized
model. The main reason is that fewer tables are required.
Therefore, data from different tables can more easily be
combined in join operations. In the previous example, the
function get_emps/2 is transformed from a join operation
into a simple query, which consists of a selection and a
projection on one single table.