This chapter explains the interface between the core PostgreSQL system and table access methods, which manage the storage for tables. The core system knows little about these access methods beyond what is specified here, so it is possible to develop entirely new access method types by writing add-on code.
Each table access method is described by a row in the pg_am
system
catalog. The pg_am
entry specifies a name and a
handler function for the table access method. These
entries can be created and deleted using the CREATE ACCESS METHOD and DROP ACCESS METHOD SQL commands.
A table access method handler function must be declared to accept a single
argument of type internal
and to return the pseudo-type
table_am_handler
. The argument is a dummy value that simply
serves to prevent handler functions from being called directly from SQL commands.
The result of the function must be a pointer to a struct of type
TableAmRoutine
, which contains everything that the
core code needs to know to make use of the table access method. The return
value needs to be of server lifetime, which is typically achieved by
defining it as a static const
variable in global
scope. The TableAmRoutine
struct, also called the
access method's API struct, defines the behavior of
the access method using callbacks. These callbacks are pointers to plain C
functions and are not visible or callable at the SQL level. All the
callbacks and their behavior is defined in the
TableAmRoutine
structure (with comments inside the
struct defining the requirements for callbacks). Most callbacks have
wrapper functions, which are documented from the point of view of a user
(rather than an implementor) of the table access method. For details,
please refer to the
src/include/access/tableam.h
file.
To implement an access method, an implementor will typically need to
implement an AM-specific type of tuple table slot (see
src/include/executor/tuptable.h
), which allows
code outside the access method to hold references to tuples of the AM, and
to access the columns of the tuple.
Currently, the way an AM actually stores data is fairly unconstrained. For example, it's possible, but not required, to use postgres' shared buffer cache. In case it is used, it likely makes sense to use PostgreSQL's standard page layout as described in Section 71.6.
One fairly large constraint of the table access method API is that,
currently, if the AM wants to support modifications and/or indexes, it is
necessary for each tuple to have a tuple identifier (TID)
consisting of a block number and an item number (see also Section 71.6). It is not strictly necessary that the
sub-parts of TIDs have the same meaning they e.g., have
for heap
, but if bitmap scan support is desired (it is
optional), the block number needs to provide locality.
For crash safety, an AM can use postgres' WAL, or a custom implementation.
If WAL is chosen, either Generic WAL Records can be used,
or a new type of WAL records can be implemented.
Generic WAL Records are easy, but imply higher WAL volume.
Implementation of a new type of WAL record
currently requires modifications to core code (specifically,
src/include/access/rmgrlist.h
).
To implement transactional support in a manner that allows different table
access methods be accessed within a single transaction, it likely is
necessary to closely integrate with the machinery in
src/backend/access/transam/xlog.c
.
Any developer of a new table access method
can refer to
the existing heap
implementation present in
src/backend/access/heap/heapam_handler.c
for details of
its implementation.