1src/backend/utils/mmgr/README
2
3Memory Context System Design Overview
4=====================================
5
6Background
7----------
8
9We do most of our memory allocation in "memory contexts", which are usually
10AllocSets as implemented by src/backend/utils/mmgr/aset.c. The key to
11successful memory management without lots of overhead is to define a useful
12set of contexts with appropriate lifespans.
13
14The basic operations on a memory context are:
15
16* create a context
17
18* allocate a chunk of memory within a context (equivalent of standard
19 C library's malloc())
20
21* delete a context (including freeing all the memory allocated therein)
22
23* reset a context (free all memory allocated in the context, but not the
24 context object itself)
25
26Given a chunk of memory previously allocated from a context, one can
27free it or reallocate it larger or smaller (corresponding to standard C
28library's free() and realloc() routines). These operations return memory
29to or get more memory from the same context the chunk was originally
30allocated in.
31
32At all times there is a "current" context denoted by the
33CurrentMemoryContext global variable. palloc() implicitly allocates space
34in that context. The MemoryContextSwitchTo() operation selects a new current
35context (and returns the previous context, so that the caller can restore the
36previous context before exiting).
37
38The main advantage of memory contexts over plain use of malloc/free is
39that the entire contents of a memory context can be freed easily, without
40having to request freeing of each individual chunk within it. This is
41both faster and more reliable than per-chunk bookkeeping. We use this
42fact to clean up at transaction end: by resetting all the active contexts
43of transaction or shorter lifespan, we can reclaim all transient memory.
44Similarly, we can clean up at the end of each query, or after each tuple
45is processed during a query.
46
47
48Some Notes About the palloc API Versus Standard C Library
49---------------------------------------------------------
50
51The behavior of palloc and friends is similar to the standard C library's
52malloc and friends, but there are some deliberate differences too. Here
53are some notes to clarify the behavior.
54
55* If out of memory, palloc and repalloc exit via elog(ERROR). They
56never return NULL, and it is not necessary or useful to test for such
57a result. With palloc_extended() that behavior can be overridden
58using the MCXT_ALLOC_NO_OOM flag.
59
60* palloc(0) is explicitly a valid operation. It does not return a NULL
61pointer, but a valid chunk of which no bytes may be used. However, the
62chunk might later be repalloc'd larger; it can also be pfree'd without
63error. Similarly, repalloc allows realloc'ing to zero size.
64
65* pfree and repalloc do not accept a NULL pointer. This is intentional.
66
67
68The Current Memory Context
69--------------------------
70
71Because it would be too much notational overhead to always pass an
72appropriate memory context to called routines, there always exists the
73notion of the current memory context CurrentMemoryContext. Without it,
74for example, the copyObject routines would need to be passed a context, as
75would function execution routines that return a pass-by-reference
76datatype. Similarly for routines that temporarily allocate space
77internally, but don't return it to their caller? We certainly don't
78want to clutter every call in the system with "here is a context to
79use for any temporary memory allocation you might want to do".
80
81The upshot of that reasoning, though, is that CurrentMemoryContext should
82generally point at a short-lifespan context if at all possible. During
83query execution it usually points to a context that gets reset after each
84tuple. Only in *very* circumscribed code should it ever point at a
85context having greater than transaction lifespan, since doing so risks
86permanent memory leaks.
87
88
89pfree/repalloc Do Not Depend On CurrentMemoryContext
90----------------------------------------------------
91
92pfree() and repalloc() can be applied to any chunk whether it belongs
93to CurrentMemoryContext or not --- the chunk's owning context will be
94invoked to handle the operation, regardless.
95
96
97"Parent" and "Child" Contexts
98-----------------------------
99
100If all contexts were independent, it'd be hard to keep track of them,
101especially in error cases. That is solved by creating a tree of
102"parent" and "child" contexts. When creating a memory context, the
103new context can be specified to be a child of some existing context.
104A context can have many children, but only one parent. In this way
105the contexts form a forest (not necessarily a single tree, since there
106could be more than one top-level context; although in current practice
107there is only one top context, TopMemoryContext).
108
109Deleting a context deletes all its direct and indirect children as
110well. When resetting a context it's almost always more useful to
111delete child contexts, thus MemoryContextReset() means that, and if
112you really do want a tree of empty contexts you need to call
113MemoryContextResetOnly() plus MemoryContextResetChildren().
114
115These features allow us to manage a lot of contexts without fear that
116some will be leaked; we only need to keep track of one top-level
117context that we are going to delete at transaction end, and make sure
118that any shorter-lived contexts we create are descendants of that
119context. Since the tree can have multiple levels, we can deal easily
120with nested lifetimes of storage, such as per-transaction,
121per-statement, per-scan, per-tuple. Storage lifetimes that only
122partially overlap can be handled by allocating from different trees of
123the context forest (there are some examples in the next section).
124
125For convenience we also provide operations like "reset/delete all children
126of a given context, but don't reset or delete that context itself".
127
128
129Memory Context Reset/Delete Callbacks
130-------------------------------------
131
132A feature introduced in Postgres 9.5 allows memory contexts to be used
133for managing more resources than just plain palloc'd memory. This is
134done by registering a "reset callback function" for a memory context.
135Such a function will be called, once, just before the context is next
136reset or deleted. It can be used to give up resources that are in some
137sense associated with an object allocated within the context. Possible
138use-cases include
139* closing open files associated with a tuplesort object;
140* releasing reference counts on long-lived cache objects that are held
141 by some object within the context being reset;
142* freeing malloc-managed memory associated with some palloc'd object.
143That last case would just represent bad programming practice for pure
144Postgres code; better to have made all the allocations using palloc,
145in the target context or some child context. However, it could well
146come in handy for code that interfaces to non-Postgres libraries.
147
148Any number of reset callbacks can be established for a memory context;
149they are called in reverse order of registration. Also, callbacks
150attached to child contexts are called before callbacks attached to
151parent contexts, if a tree of contexts is being reset or deleted.
152
153The API for this requires the caller to provide a MemoryContextCallback
154memory chunk to hold the state for a callback. Typically this should be
155allocated in the same context it is logically attached to, so that it
156will be released automatically after use. The reason for asking the
157caller to provide this memory is that in most usage scenarios, the caller
158will be creating some larger struct within the target context, and the
159MemoryContextCallback struct can be made "for free" without a separate
160palloc() call by including it in this larger struct.
161
162
163Memory Contexts in Practice
164===========================
165
166Globally Known Contexts
167-----------------------
168
169There are a few widely-known contexts that are typically referenced
170through global variables. At any instant the system may contain many
171additional contexts, but all other contexts should be direct or indirect
172children of one of these contexts to ensure they are not leaked in event
173of an error.
174
175TopMemoryContext --- this is the actual top level of the context tree;
176every other context is a direct or indirect child of this one. Allocating
177here is essentially the same as "malloc", because this context will never
178be reset or deleted. This is for stuff that should live forever, or for
179stuff that the controlling module will take care of deleting at the
180appropriate time. An example is fd.c's tables of open files. Avoid
181allocating stuff here unless really necessary, and especially avoid
182running with CurrentMemoryContext pointing here.
183
184PostmasterContext --- this is the postmaster's normal working context.
185After a backend is spawned, it can delete PostmasterContext to free its
186copy of memory the postmaster was using that it doesn't need.
187Note that in non-EXEC_BACKEND builds, the postmaster's copy of pg_hba.conf
188and pg_ident.conf data is used directly during authentication in backend
189processes; so backends can't delete PostmasterContext until that's done.
190(The postmaster has only TopMemoryContext, PostmasterContext, and
191ErrorContext --- the remaining top-level contexts are set up in each
192backend during startup.)
193
194CacheMemoryContext --- permanent storage for relcache, catcache, and
195related modules. This will never be reset or deleted, either, so it's
196not truly necessary to distinguish it from TopMemoryContext. But it
197seems worthwhile to maintain the distinction for debugging purposes.
198(Note: CacheMemoryContext has child contexts with shorter lifespans.
199For example, a child context is the best place to keep the subsidiary
200storage associated with a relcache entry; that way we can free rule
201parsetrees and so forth easily, without having to depend on constructing
202a reliable version of freeObject().)
203
204MessageContext --- this context holds the current command message from the
205frontend, as well as any derived storage that need only live as long as
206the current message (for example, in simple-Query mode the parse and plan
207trees can live here). This context will be reset, and any children
208deleted, at the top of each cycle of the outer loop of PostgresMain. This
209is kept separate from per-transaction and per-portal contexts because a
210query string might need to live either a longer or shorter time than any
211single transaction or portal.
212
213TopTransactionContext --- this holds everything that lives until end of the
214top-level transaction. This context will be reset, and all its children
215deleted, at conclusion of each top-level transaction cycle. In most cases
216you don't want to allocate stuff directly here, but in CurTransactionContext;
217what does belong here is control information that exists explicitly to manage
218status across multiple subtransactions. Note: this context is NOT cleared
219immediately upon error; its contents will survive until the transaction block
220is exited by COMMIT/ROLLBACK.
221
222CurTransactionContext --- this holds data that has to survive until the end
223of the current transaction, and in particular will be needed at top-level
224transaction commit. When we are in a top-level transaction this is the same
225as TopTransactionContext, but in subtransactions it points to a child context.
226It is important to understand that if a subtransaction aborts, its
227CurTransactionContext is thrown away after finishing the abort processing;
228but a committed subtransaction's CurTransactionContext is kept until top-level
229commit (unless of course one of the intermediate levels of subtransaction
230aborts). This ensures that we do not keep data from a failed subtransaction
231longer than necessary. Because of this behavior, you must be careful to clean
232up properly during subtransaction abort --- the subtransaction's state must be
233delinked from any pointers or lists kept in upper transactions, or you will
234have dangling pointers leading to a crash at top-level commit. An example of
235data kept here is pending NOTIFY messages, which are sent at top-level commit,
236but only if the generating subtransaction did not abort.
237
238PortalContext --- this is not actually a separate context, but a
239global variable pointing to the per-portal context of the currently active
240execution portal. This can be used if it's necessary to allocate storage
241that will live just as long as the execution of the current portal requires.
242
243ErrorContext --- this permanent context is switched into for error
244recovery processing, and then reset on completion of recovery. We arrange
245to have a few KB of memory available in it at all times. In this way, we
246can ensure that some memory is available for error recovery even if the
247backend has run out of memory otherwise. This allows out-of-memory to be
248treated as a normal ERROR condition, not a FATAL error.
249
250
251Contexts For Prepared Statements And Portals
252--------------------------------------------
253
254A prepared-statement object has an associated private context, in which
255the parse and plan trees for its query are stored. Because these trees
256are read-only to the executor, the prepared statement can be re-used many
257times without further copying of these trees.
258
259An execution-portal object has a private context that is referenced by
260PortalContext when the portal is active. In the case of a portal created
261by DECLARE CURSOR, this private context contains the query parse and plan
262trees (there being no other object that can hold them). Portals created
263from prepared statements simply reference the prepared statements' trees,
264and don't actually need any storage allocated in their private contexts.
265
266
267Logical Replication Worker Contexts
268-----------------------------------
269
270ApplyContext --- permanent during whole lifetime of apply worker. It
271is possible to use TopMemoryContext here as well, but for simplicity
272of memory usage analysis we spin up different context.
273
274ApplyMessageContext --- short-lived context that is reset after each
275logical replication protocol message is processed.
276
277
278Transient Contexts During Execution
279-----------------------------------
280
281When creating a prepared statement, the parse and plan trees will be built
282in a temporary context that's a child of MessageContext (so that it will
283go away automatically upon error). On success, the finished plan is
284copied to the prepared statement's private context, and the temp context
285is released; this allows planner temporary space to be recovered before
286execution begins. (In simple-Query mode we don't bother with the extra
287copy step, so the planner temp space stays around till end of query.)
288
289The top-level executor routines, as well as most of the "plan node"
290execution code, will normally run in a context that is created by
291ExecutorStart and destroyed by ExecutorEnd; this context also holds the
292"plan state" tree built during ExecutorStart. Most of the memory
293allocated in these routines is intended to live until end of query,
294so this is appropriate for those purposes. The executor's top context
295is a child of PortalContext, that is, the per-portal context of the
296portal that represents the query's execution.
297
298The main memory-management consideration in the executor is that
299expression evaluation --- both for qual testing and for computation of
300targetlist entries --- needs to not leak memory. To do this, each
301ExprContext (expression-eval context) created in the executor has a
302private memory context associated with it, and we switch into that context
303when evaluating expressions in that ExprContext. The plan node that owns
304the ExprContext is responsible for resetting the private context to empty
305when it no longer needs the results of expression evaluations. Typically
306the reset is done at the start of each tuple-fetch cycle in the plan node.
307
308Note that this design gives each plan node its own expression-eval memory
309context. This appears necessary to handle nested joins properly, since
310an outer plan node might need to retain expression results it has computed
311while obtaining the next tuple from an inner node --- but the inner node
312might execute many tuple cycles and many expressions before returning a
313tuple. The inner node must be able to reset its own expression context
314more often than once per outer tuple cycle. Fortunately, memory contexts
315are cheap enough that giving one to each plan node doesn't seem like a
316problem.
317
318A problem with running index accesses and sorts in a query-lifespan context
319is that these operations invoke datatype-specific comparison functions,
320and if the comparators leak any memory then that memory won't be recovered
321till end of query. The comparator functions all return bool or int32,
322so there's no problem with their result data, but there can be a problem
323with leakage of internal temporary data. In particular, comparator
324functions that operate on TOAST-able data types need to be careful
325not to leak detoasted versions of their inputs. This is annoying, but
326it appeared a lot easier to make the comparators conform than to fix the
327index and sort routines, so that's what was done for 7.1. This remains
328the state of affairs in btree and hash indexes, so btree and hash support
329functions still need to not leak memory. Most of the other index AMs
330have been modified to run opclass support functions in short-lived
331contexts, so that leakage is not a problem; this is necessary in view
332of the fact that their support functions tend to be far more complex.
333
334There are some special cases, such as aggregate functions. nodeAgg.c
335needs to remember the results of evaluation of aggregate transition
336functions from one tuple cycle to the next, so it can't just discard
337all per-tuple state in each cycle. The easiest way to handle this seems
338to be to have two per-tuple contexts in an aggregate node, and to
339ping-pong between them, so that at each tuple one is the active allocation
340context and the other holds any results allocated by the prior cycle's
341transition function.
342
343Executor routines that switch the active CurrentMemoryContext may need
344to copy data into their caller's current memory context before returning.
345However, we have minimized the need for that, because of the convention
346of resetting the per-tuple context at the *start* of an execution cycle
347rather than at its end. With that rule, an execution node can return a
348tuple that is palloc'd in its per-tuple context, and the tuple will remain
349good until the node is called for another tuple or told to end execution.
350This parallels the situation with pass-by-reference values at the table
351scan level, since a scan node can return a direct pointer to a tuple in a
352disk buffer that is only guaranteed to remain good that long.
353
354A more common reason for copying data is to transfer a result from
355per-tuple context to per-query context; for example, a Unique node will
356save the last distinct tuple value in its per-query context, requiring a
357copy step.
358
359
360Mechanisms to Allow Multiple Types of Contexts
361----------------------------------------------
362
363To efficiently allow for different allocation patterns, and for
364experimentation, we allow for different types of memory contexts with
365different allocation policies but similar external behavior. To
366handle this, memory allocation functions are accessed via function
367pointers, and we require all context types to obey the conventions
368given here.
369
370A memory context is represented by struct MemoryContextData (see
371memnodes.h). This struct identifies the exact type of the context, and
372contains information common between the different types of
373MemoryContext like the parent and child contexts, and the name of the
374context.
375
376This is essentially an abstract superclass, and the behavior is
377determined by the "methods" pointer is its virtual function table
378(struct MemoryContextMethods). Specific memory context types will use
379derived structs having these fields as their first fields. All the
380contexts of a specific type will have methods pointers that point to
381the same static table of function pointers.
382
383While operations like allocating from and resetting a context take the
384relevant MemoryContext as a parameter, operations like free and
385realloc are trickier. To make those work, we require all memory
386context types to produce allocated chunks that are immediately,
387without any padding, preceded by a pointer to the corresponding
388MemoryContext.
389
390If a type of allocator needs additional information about its chunks,
391like e.g. the size of the allocation, that information can in turn
392precede the MemoryContext. This means the only overhead implied by
393the memory context mechanism is a pointer to its context, so we're not
394constraining context-type designers very much.
395
396Given this, routines like pfree determine their corresponding context
397with an operation like (although that is usually encapsulated in
398GetMemoryChunkContext())
399
400 MemoryContext context = *(MemoryContext*) (((char *) pointer) - sizeof(void *));
401
402and then invoke the corresponding method for the context
403
404 context->methods->free_p(pointer);
405
406
407More Control Over aset.c Behavior
408---------------------------------
409
410By default aset.c always allocates an 8K block upon the first
411allocation in a context, and doubles that size for each successive
412block request. That's good behavior for a context that might hold
413*lots* of data. But if there are dozens if not hundreds of smaller
414contexts in the system, we need to be able to fine-tune things a
415little better.
416
417The creator of a context is able to specify an initial block size and
418a maximum block size. Selecting smaller values can prevent wastage of
419space in contexts that aren't expected to hold very much (an example
420is the relcache's per-relation contexts).
421
422Also, it is possible to specify a minimum context size, in case for some
423reason that should be different from the initial size for additional
424blocks. An aset.c context will always contain at least one block,
425of size minContextSize if that is specified, otherwise initBlockSize.
426
427We expect that per-tuple contexts will be reset frequently and typically
428will not allocate very much space per tuple cycle. To make this usage
429pattern cheap, the first block allocated in a context is not given
430back to malloc() during reset, but just cleared. This avoids malloc
431thrashing.
432
433
434Alternative Memory Context Implementations
435------------------------------------------
436
437aset.c is our default general-purpose implementation, working fine
438in most situations. We also have two implementations optimized for
439special use cases, providing either better performance or lower memory
440usage compared to aset.c (or both).
441
442* slab.c (SlabContext) is designed for allocations of fixed-length
443 chunks, and does not allow allocations of chunks with different size.
444
445* generation.c (GenerationContext) is designed for cases when chunks
446 are allocated in groups with similar lifespan (generations), or
447 roughly in FIFO order.
448
449Both memory contexts aim to free memory back to the operating system
450(unlike aset.c, which keeps the freed chunks in a freelist, and only
451returns the memory when reset/deleted).
452
453These memory contexts were initially developed for ReorderBuffer, but
454may be useful elsewhere as long as the allocation patterns match.
455