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 src/backend/utils/fmgr/README

 Function Manager
 ================

 [This file originally explained the transition from the V0 to the V1
 interface.  Now it just explains some internals and rationale for the V1
 interface, while the V0 interface has been removed.]

 The V1 Function-Manager Interface
 ---------------------------------

 The core of the design is data structures for representing the result of a
 function lookup and for representing the parameters passed to a specific
 function invocation.  (We want to keep function lookup separate from
 function call, since many parts of the system apply the same function over
 and over; the lookup overhead should be paid once per query, not once per
 tuple.)


 When a function is looked up in pg_proc, the result is represented as

 typedef struct
 {
     PGFunction  fn_addr;    /* pointer to function or handler to be called */
     Oid         fn_oid;     /* OID of function (NOT of handler, if any) */
     short       fn_nargs;   /* number of input args (0..FUNC_MAX_ARGS) */
     bool        fn_strict;  /* function is "strict" (NULL in => NULL out) */
     bool        fn_retset;  /* function returns a set (over multiple calls) */
     unsigned char fn_stats; /* collect stats if track_functions > this */
     void       *fn_extra;   /* extra space for use by handler */
     MemoryContext fn_mcxt;  /* memory context to store fn_extra in */
     Node       *fn_expr;    /* expression parse tree for call, or NULL */
 } FmgrInfo;

 For an ordinary built-in function, fn_addr is just the address of the C
 routine that implements the function.  Otherwise it is the address of a
 handler for the class of functions that includes the target function.
 The handler can use the function OID and perhaps also the fn_extra slot
 to find the specific code to execute.  (fn_oid = InvalidOid can be used
 to denote a not-yet-initialized FmgrInfo struct.  fn_extra will always
 be NULL when an FmgrInfo is first filled by the function lookup code, but
 a function handler could set it to avoid making repeated lookups of its
 own when the same FmgrInfo is used repeatedly during a query.)  fn_nargs
 is the number of arguments expected by the function, fn_strict is its
 strictness flag, and fn_retset shows whether it returns a set; all of
 these values come from the function's pg_proc entry.  fn_stats is also
 set up to control whether or not to track runtime statistics for calling
 this function.

 If the function is being called as part of a SQL expression, fn_expr will
 point to the expression parse tree for the function call; this can be used
 to extract parse-time knowledge about the actual arguments.  Note that this
 field really is information about the arguments rather than information
 about the function, but it's proven to be more convenient to keep it in
 FmgrInfo than in FunctionCallInfoBaseData where it might more logically go.


 During a call of a function, the following data structure is created
 and passed to the function:

 typedef struct
 {
     FmgrInfo   *flinfo;         /* ptr to lookup info used for this call */
     Node       *context;        /* pass info about context of call */
     Node       *resultinfo;     /* pass or return extra info about result */
     Oid         fncollation;    /* collation for function to use */
     bool        isnull;         /* function must set true if result is NULL */
     short       nargs;          /* # arguments actually passed */
     NullableDatum args[];       /* Arguments passed to function */
 } FunctionCallInfoBaseData;
 typedef FunctionCallInfoBaseData* FunctionCallInfo;

 flinfo points to the lookup info used to make the call.  Ordinary functions
 will probably ignore this field, but function class handlers will need it
 to find out the OID of the specific function being called.

 context is NULL for an "ordinary" function call, but may point to additional
 info when the function is called in certain contexts.  (For example, the
 trigger manager will pass information about the current trigger event here.)
 If context is used, it should point to some subtype of Node; the particular
 kind of context is indicated by the node type field.  (A callee should
 always check the node type before assuming it knows what kind of context is
 being passed.)  fmgr itself puts no other restrictions on the use of this
 field.

 resultinfo is NULL when calling any function from which a simple Datum
 result is expected.  It may point to some subtype of Node if the function
 returns more than a Datum.  (For example, resultinfo is used when calling a
 function that returns a set, as discussed below.)  Like the context field,
 resultinfo is a hook for expansion; fmgr itself doesn't constrain the use
 of the field.

 fncollation is the input collation derived by the parser, or InvalidOid
 when there are no inputs of collatable types or they don't share a common
 collation.  This is effectively a hidden additional argument, which
 collation-sensitive functions can use to determine their behavior.

 nargs and args[] hold the arguments being passed to the function.
 Notice that all the arguments passed to a function (as well as its result
 value) will now uniformly be of type Datum.  As discussed below, callers
 and callees should apply the standard Datum-to-and-from-whatever macros
 to convert to the actual argument types of a particular function.  The
 value in args[i].value is unspecified when args[i].isnull is true.

 It is generally the responsibility of the caller to ensure that the
 number of arguments passed matches what the callee is expecting; except
 for callees that take a variable number of arguments, the callee will
 typically ignore the nargs field and just grab values from args[].

 The isnull field will be initialized to "false" before the call.  On
 return from the function, isnull is the null flag for the function result:
 if it is true the function's result is NULL, regardless of the actual
 function return value.  Note that simple "strict" functions can ignore
 both isnull and args[i].isnull, since they won't even get called when there
 are any TRUE values in args[].isnull.

 FunctionCallInfo replaces FmgrValues plus a bunch of ad-hoc parameter
 conventions, global variables (fmgr_pl_finfo and CurrentTriggerData at
 least), and other uglinesses.


 Callees, whether they be individual functions or function handlers,
 shall always have this signature:

 Datum function (FunctionCallInfo fcinfo);

 which is represented by the typedef

 typedef Datum (*PGFunction) (FunctionCallInfo fcinfo);

 The function is responsible for setting fcinfo->isnull appropriately
 as well as returning a result represented as a Datum.  Note that since
 all callees will now have exactly the same signature, and will be called
 through a function pointer declared with exactly that signature, we
 should have no portability or optimization problems.


 Function Coding Conventions
 ---------------------------

 Here are the proposed macros and coding conventions:

 The definition of an fmgr-callable function will always look like

 Datum
 function_name(PG_FUNCTION_ARGS)
 {
 	...
 }

 "PG_FUNCTION_ARGS" just expands to "FunctionCallInfo fcinfo".  The main
 reason for using this macro is to make it easy for scripts to spot function
 definitions.  However, if we ever decide to change the calling convention
 again, it might come in handy to have this macro in place.

 A nonstrict function is responsible for checking whether each individual
 argument is null or not, which it can do with PG_ARGISNULL(n) (which is
 just "fcinfo->args[n].isnull").  It should avoid trying to fetch the value
 of any argument that is null.

 Both strict and nonstrict functions can return NULL, if needed, with
 	PG_RETURN_NULL();
 which expands to
 	{ fcinfo->isnull = true; return (Datum) 0; }

 Argument values are ordinarily fetched using code like
 	int32	name = PG_GETARG_INT32(number);

 For float4, float8, and int8, the PG_GETARG macros will hide whether the
 types are pass-by-value or pass-by-reference.  For example, if float8 is
 pass-by-reference then PG_GETARG_FLOAT8 expands to
 	(* (float8 *) DatumGetPointer(fcinfo->args[number].value))
 and would typically be called like this:
 	float8  arg = PG_GETARG_FLOAT8(0);
 For what are now historical reasons, the float-related typedefs and macros
 express the type width in bytes (4 or 8), whereas we prefer to label the
 widths of integer types in bits.

 Non-null values are returned with a PG_RETURN_XXX macro of the appropriate
 type.  For example, PG_RETURN_INT32 expands to
 	return Int32GetDatum(x)
 PG_RETURN_FLOAT4, PG_RETURN_FLOAT8, and PG_RETURN_INT64 hide whether their
 data types are pass-by-value or pass-by-reference, by doing a palloc if
 needed.

 fmgr.h will provide PG_GETARG and PG_RETURN macros for all the basic data
 types.  Modules or header files that define specialized SQL datatypes
 (eg, timestamp) should define appropriate macros for those types, so that
 functions manipulating the types can be coded in the standard style.

 For non-primitive data types (particularly variable-length types) it won't
 be very practical to hide the pass-by-reference nature of the data type,
 so the PG_GETARG and PG_RETURN macros for those types won't do much more
 than DatumGetPointer/PointerGetDatum plus the appropriate typecast (but see
 TOAST discussion, below).  Functions returning such types will need to
 palloc() their result space explicitly.  I recommend naming the GETARG and
 RETURN macros for such types to end in "_P", as a reminder that they
 produce or take a pointer.  For example, PG_GETARG_TEXT_P yields "text *".

 When a function needs to access fcinfo->flinfo or one of the other auxiliary
 fields of FunctionCallInfo, it should just do it.  I doubt that providing
 syntactic-sugar macros for these cases is useful.


 Support for TOAST-Able Data Types
 ---------------------------------

 For TOAST-able data types, the PG_GETARG macro will deliver a de-TOASTed
 data value.  There might be a few cases where the still-toasted value is
 wanted, but the vast majority of cases want the de-toasted result, so
 that will be the default.  To get the argument value without causing
 de-toasting, use PG_GETARG_RAW_VARLENA_P(n).

 Some functions require a modifiable copy of their input values.  In these
 cases, it's silly to do an extra copy step if we copied the data anyway
 to de-TOAST it.  Therefore, each toastable datatype has an additional
 fetch macro, for example PG_GETARG_TEXT_P_COPY(n), which delivers a
 guaranteed-fresh copy, combining this with the detoasting step if possible.

 There is also a PG_FREE_IF_COPY(ptr,n) macro, which pfree's the given
 pointer if and only if it is different from the original value of the n'th
 argument.  This can be used to free the de-toasted value of the n'th
 argument, if it was actually de-toasted.  Currently, doing this is not
 necessary for the majority of functions because the core backend code
 releases temporary space periodically, so that memory leaked in function
 execution isn't a big problem.  However, as of 7.1 memory leaks in
 functions that are called by index searches will not be cleaned up until
 end of transaction.  Therefore, functions that are listed in pg_amop or
 pg_amproc should be careful not to leak detoasted copies, and so these
 functions do need to use PG_FREE_IF_COPY() for toastable inputs.

 A function should never try to re-TOAST its result value; it should just
 deliver an untoasted result that's been palloc'd in the current memory
 context.  When and if the value is actually stored into a tuple, the
 tuple toaster will decide whether toasting is needed.


 Functions Accepting or Returning Sets
 -------------------------------------

 If a function is marked in pg_proc as returning a set, then it is called
 with fcinfo->resultinfo pointing to a node of type ReturnSetInfo.  A
 function that desires to return a set should raise an error "called in
 context that does not accept a set result" if resultinfo is NULL or does
 not point to a ReturnSetInfo node.

 There are currently two modes in which a function can return a set result:
 value-per-call, or materialize.  In value-per-call mode, the function returns
 one value each time it is called, and finally reports "done" when it has no
 more values to return.  In materialize mode, the function's output set is
 instantiated in a Tuplestore object; all the values are returned in one call.
 Additional modes might be added in future.

 ReturnSetInfo contains a field "allowedModes" which is set (by the caller)
 to a bitmask that's the OR of the modes the caller can support.  The actual
 mode used by the function is returned in another field "returnMode".  For
 backwards-compatibility reasons, returnMode is initialized to value-per-call
 and need only be changed if the function wants to use a different mode.
 The function should ereport() if it cannot use any of the modes the caller is
 willing to support.

 Value-per-call mode works like this: ReturnSetInfo contains a field
 "isDone", which should be set to one of these values:

     ExprSingleResult             /* expression does not return a set */
     ExprMultipleResult           /* this result is an element of a set */
     ExprEndResult                /* there are no more elements in the set */

 (the caller will initialize it to ExprSingleResult).  If the function simply
 returns a Datum without touching ReturnSetInfo, then the call is over and a
 single-item set has been returned.  To return a set, the function must set
 isDone to ExprMultipleResult for each set element.  After all elements have
 been returned, the next call should set isDone to ExprEndResult and return a
 null result.  (Note it is possible to return an empty set by doing this on
 the first call.)

 Value-per-call functions MUST NOT assume that they will be run to completion;
 the executor might simply stop calling them, for example because of a LIMIT.
 Therefore, it's unsafe to attempt to perform any resource cleanup in the
 final call.  It's usually not necessary to clean up memory, anyway.  If it's
 necessary to clean up other types of resources, such as file descriptors,
 one can register a shutdown callback function in the ExprContext pointed to
 by the ReturnSetInfo node.  (But note that file descriptors are a limited
 resource, so it's generally unwise to hold those open across calls; SRFs
 that need file access are better written to do it in a single call using
 Materialize mode.)

 Materialize mode works like this: the function creates a Tuplestore holding
 the (possibly empty) result set, and returns it.  There are no multiple calls.
 The function must also return a TupleDesc that indicates the tuple structure.
 The Tuplestore and TupleDesc should be created in the context
 econtext->ecxt_per_query_memory (note this will *not* be the context the
 function is called in).  The function stores pointers to the Tuplestore and
 TupleDesc into ReturnSetInfo, sets returnMode to indicate materialize mode,
 and returns null.  isDone is not used and should be left at ExprSingleResult.

 The Tuplestore must be created with randomAccess = true if
 SFRM_Materialize_Random is set in allowedModes, but it can (and preferably
 should) be created with randomAccess = false if not.  Callers that can support
 both ValuePerCall and Materialize mode will set SFRM_Materialize_Preferred,
 or not, depending on which mode they prefer.

 If available, the expected tuple descriptor is passed in ReturnSetInfo;
 in other contexts the expectedDesc field will be NULL.  The function need
 not pay attention to expectedDesc, but it may be useful in special cases.

 There is no support for functions accepting sets; instead, the function will
 be called multiple times, once for each element of the input set.


 Notes About Function Handlers
 -----------------------------

 Handlers for classes of functions should find life much easier and
 cleaner in this design.  The OID of the called function is directly
 reachable from the passed parameters; we don't need the global variable
 fmgr_pl_finfo anymore.  Also, by modifying fcinfo->flinfo->fn_extra,
 the handler can cache lookup info to avoid repeat lookups when the same
 function is invoked many times.  (fn_extra can only be used as a hint,
 since callers are not required to re-use an FmgrInfo struct.
 But in performance-critical paths they normally will do so.)

 If the handler wants to allocate memory to hold fn_extra data, it should
 NOT do so in CurrentMemoryContext, since the current context may well be
 much shorter-lived than the context where the FmgrInfo is.  Instead,
 allocate the memory in context flinfo->fn_mcxt, or in a long-lived cache
 context.  fn_mcxt normally points at the context that was
 CurrentMemoryContext at the time the FmgrInfo structure was created;
 in any case it is required to be a context at least as long-lived as the
 FmgrInfo itself.
	src/backend/utils/fmgr/README

	Function Manager
	================

	[This file originally explained the transition from the V0 to the V1
	interface. Now it just explains some internals and rationale for the V1
	interface, while the V0 interface has been removed.]

	The V1 Function-Manager Interface
	---------------------------------

	The core of the design is data structures for representing the result of a
	function lookup and for representing the parameters passed to a specific
	function invocation. (We want to keep function lookup separate from
	function call, since many parts of the system apply the same function over
	and over; the lookup overhead should be paid once per query, not once per
	tuple.)


	When a function is looked up in pg_proc, the result is represented as

	typedef struct
	{
	PGFunction fn_addr; /* pointer to function or handler to be called */
	Oid fn_oid; /* OID of function (NOT of handler, if any) */
	short fn_nargs; /* number of input args (0..FUNC_MAX_ARGS) */
	bool fn_strict; /* function is "strict" (NULL in => NULL out) */
	bool fn_retset; /* function returns a set (over multiple calls) */
	unsigned char fn_stats; /* collect stats if track_functions > this */
	void fn_extra; / extra space for use by handler */
	MemoryContext fn_mcxt; /* memory context to store fn_extra in */
	Node fn_expr; / expression parse tree for call, or NULL */
	} FmgrInfo;

	For an ordinary built-in function, fn_addr is just the address of the C
	routine that implements the function. Otherwise it is the address of a
	handler for the class of functions that includes the target function.
	The handler can use the function OID and perhaps also the fn_extra slot
	to find the specific code to execute. (fn_oid = InvalidOid can be used
	to denote a not-yet-initialized FmgrInfo struct. fn_extra will always
	be NULL when an FmgrInfo is first filled by the function lookup code, but
	a function handler could set it to avoid making repeated lookups of its
	own when the same FmgrInfo is used repeatedly during a query.) fn_nargs
	is the number of arguments expected by the function, fn_strict is its
	strictness flag, and fn_retset shows whether it returns a set; all of
	these values come from the function's pg_proc entry. fn_stats is also
	set up to control whether or not to track runtime statistics for calling
	this function.

	If the function is being called as part of a SQL expression, fn_expr will
	point to the expression parse tree for the function call; this can be used
	to extract parse-time knowledge about the actual arguments. Note that this
	field really is information about the arguments rather than information
	about the function, but it's proven to be more convenient to keep it in
	FmgrInfo than in FunctionCallInfoBaseData where it might more logically go.


	During a call of a function, the following data structure is created
	and passed to the function:

	typedef struct
	{
	FmgrInfo flinfo; / ptr to lookup info used for this call */
	Node context; / pass info about context of call */
	Node resultinfo; / pass or return extra info about result */
	Oid fncollation; /* collation for function to use */
	bool isnull; /* function must set true if result is NULL */
	short nargs; /* # arguments actually passed */
	NullableDatum args[]; /* Arguments passed to function */
	} FunctionCallInfoBaseData;
	typedef FunctionCallInfoBaseData* FunctionCallInfo;

	flinfo points to the lookup info used to make the call. Ordinary functions
	will probably ignore this field, but function class handlers will need it
	to find out the OID of the specific function being called.

	context is NULL for an "ordinary" function call, but may point to additional
	info when the function is called in certain contexts. (For example, the
	trigger manager will pass information about the current trigger event here.)
	If context is used, it should point to some subtype of Node; the particular
	kind of context is indicated by the node type field. (A callee should
	always check the node type before assuming it knows what kind of context is
	being passed.) fmgr itself puts no other restrictions on the use of this
	field.

	resultinfo is NULL when calling any function from which a simple Datum
	result is expected. It may point to some subtype of Node if the function
	returns more than a Datum. (For example, resultinfo is used when calling a
	function that returns a set, as discussed below.) Like the context field,
	resultinfo is a hook for expansion; fmgr itself doesn't constrain the use
	of the field.

	fncollation is the input collation derived by the parser, or InvalidOid
	when there are no inputs of collatable types or they don't share a common
	collation. This is effectively a hidden additional argument, which
	collation-sensitive functions can use to determine their behavior.

	nargs and args[] hold the arguments being passed to the function.
	Notice that all the arguments passed to a function (as well as its result
	value) will now uniformly be of type Datum. As discussed below, callers
	and callees should apply the standard Datum-to-and-from-whatever macros
	to convert to the actual argument types of a particular function. The
	value in args[i].value is unspecified when args[i].isnull is true.

	It is generally the responsibility of the caller to ensure that the
	number of arguments passed matches what the callee is expecting; except
	for callees that take a variable number of arguments, the callee will
	typically ignore the nargs field and just grab values from args[].

	The isnull field will be initialized to "false" before the call. On
	return from the function, isnull is the null flag for the function result:
	if it is true the function's result is NULL, regardless of the actual
	function return value. Note that simple "strict" functions can ignore
	both isnull and args[i].isnull, since they won't even get called when there
	are any TRUE values in args[].isnull.

	FunctionCallInfo replaces FmgrValues plus a bunch of ad-hoc parameter
	conventions, global variables (fmgr_pl_finfo and CurrentTriggerData at
	least), and other uglinesses.


	Callees, whether they be individual functions or function handlers,
	shall always have this signature:

	Datum function (FunctionCallInfo fcinfo);

	which is represented by the typedef

	typedef Datum (*PGFunction) (FunctionCallInfo fcinfo);

	The function is responsible for setting fcinfo->isnull appropriately
	as well as returning a result represented as a Datum. Note that since
	all callees will now have exactly the same signature, and will be called
	through a function pointer declared with exactly that signature, we
	should have no portability or optimization problems.


	Function Coding Conventions
	---------------------------

	Here are the proposed macros and coding conventions:

	The definition of an fmgr-callable function will always look like

	Datum
	function_name(PG_FUNCTION_ARGS)
	{
	...
	}

	"PG_FUNCTION_ARGS" just expands to "FunctionCallInfo fcinfo". The main
	reason for using this macro is to make it easy for scripts to spot function
	definitions. However, if we ever decide to change the calling convention
	again, it might come in handy to have this macro in place.

	A nonstrict function is responsible for checking whether each individual
	argument is null or not, which it can do with PG_ARGISNULL(n) (which is
	just "fcinfo->args[n].isnull"). It should avoid trying to fetch the value
	of any argument that is null.

	Both strict and nonstrict functions can return NULL, if needed, with
	PG_RETURN_NULL();
	which expands to
	{ fcinfo->isnull = true; return (Datum) 0; }

	Argument values are ordinarily fetched using code like
	int32 name = PG_GETARG_INT32(number);

	For float4, float8, and int8, the PG_GETARG macros will hide whether the
	types are pass-by-value or pass-by-reference. For example, if float8 is
	pass-by-reference then PG_GETARG_FLOAT8 expands to
	(* (float8 *) DatumGetPointer(fcinfo->args[number].value))
	and would typically be called like this:
	float8 arg = PG_GETARG_FLOAT8(0);
	For what are now historical reasons, the float-related typedefs and macros
	express the type width in bytes (4 or 8), whereas we prefer to label the
	widths of integer types in bits.

	Non-null values are returned with a PG_RETURN_XXX macro of the appropriate
	type. For example, PG_RETURN_INT32 expands to
	return Int32GetDatum(x)
	PG_RETURN_FLOAT4, PG_RETURN_FLOAT8, and PG_RETURN_INT64 hide whether their
	data types are pass-by-value or pass-by-reference, by doing a palloc if
	needed.

	fmgr.h will provide PG_GETARG and PG_RETURN macros for all the basic data
	types. Modules or header files that define specialized SQL datatypes
	(eg, timestamp) should define appropriate macros for those types, so that
	functions manipulating the types can be coded in the standard style.

	For non-primitive data types (particularly variable-length types) it won't
	be very practical to hide the pass-by-reference nature of the data type,
	so the PG_GETARG and PG_RETURN macros for those types won't do much more
	than DatumGetPointer/PointerGetDatum plus the appropriate typecast (but see
	TOAST discussion, below). Functions returning such types will need to
	palloc() their result space explicitly. I recommend naming the GETARG and
	RETURN macros for such types to end in "_P", as a reminder that they
	produce or take a pointer. For example, PG_GETARG_TEXT_P yields "text *".

	When a function needs to access fcinfo->flinfo or one of the other auxiliary
	fields of FunctionCallInfo, it should just do it. I doubt that providing
	syntactic-sugar macros for these cases is useful.


	Support for TOAST-Able Data Types
	---------------------------------

	For TOAST-able data types, the PG_GETARG macro will deliver a de-TOASTed
	data value. There might be a few cases where the still-toasted value is
	wanted, but the vast majority of cases want the de-toasted result, so
	that will be the default. To get the argument value without causing
	de-toasting, use PG_GETARG_RAW_VARLENA_P(n).

	Some functions require a modifiable copy of their input values. In these
	cases, it's silly to do an extra copy step if we copied the data anyway
	to de-TOAST it. Therefore, each toastable datatype has an additional
	fetch macro, for example PG_GETARG_TEXT_P_COPY(n), which delivers a
	guaranteed-fresh copy, combining this with the detoasting step if possible.

	There is also a PG_FREE_IF_COPY(ptr,n) macro, which pfree's the given
	pointer if and only if it is different from the original value of the n'th
	argument. This can be used to free the de-toasted value of the n'th
	argument, if it was actually de-toasted. Currently, doing this is not
	necessary for the majority of functions because the core backend code
	releases temporary space periodically, so that memory leaked in function
	execution isn't a big problem. However, as of 7.1 memory leaks in
	functions that are called by index searches will not be cleaned up until
	end of transaction. Therefore, functions that are listed in pg_amop or
	pg_amproc should be careful not to leak detoasted copies, and so these
	functions do need to use PG_FREE_IF_COPY() for toastable inputs.

	A function should never try to re-TOAST its result value; it should just
	deliver an untoasted result that's been palloc'd in the current memory
	context. When and if the value is actually stored into a tuple, the
	tuple toaster will decide whether toasting is needed.


	Functions Accepting or Returning Sets
	-------------------------------------

	If a function is marked in pg_proc as returning a set, then it is called
	with fcinfo->resultinfo pointing to a node of type ReturnSetInfo. A
	function that desires to return a set should raise an error "called in
	context that does not accept a set result" if resultinfo is NULL or does
	not point to a ReturnSetInfo node.

	There are currently two modes in which a function can return a set result:
	value-per-call, or materialize. In value-per-call mode, the function returns
	one value each time it is called, and finally reports "done" when it has no
	more values to return. In materialize mode, the function's output set is
	instantiated in a Tuplestore object; all the values are returned in one call.
	Additional modes might be added in future.

	ReturnSetInfo contains a field "allowedModes" which is set (by the caller)
	to a bitmask that's the OR of the modes the caller can support. The actual
	mode used by the function is returned in another field "returnMode". For
	backwards-compatibility reasons, returnMode is initialized to value-per-call
	and need only be changed if the function wants to use a different mode.
	The function should ereport() if it cannot use any of the modes the caller is
	willing to support.

	Value-per-call mode works like this: ReturnSetInfo contains a field
	"isDone", which should be set to one of these values:

	ExprSingleResult /* expression does not return a set */
	ExprMultipleResult /* this result is an element of a set */
	ExprEndResult /* there are no more elements in the set */

	(the caller will initialize it to ExprSingleResult). If the function simply
	returns a Datum without touching ReturnSetInfo, then the call is over and a
	single-item set has been returned. To return a set, the function must set
	isDone to ExprMultipleResult for each set element. After all elements have
	been returned, the next call should set isDone to ExprEndResult and return a
	null result. (Note it is possible to return an empty set by doing this on
	the first call.)

	Value-per-call functions MUST NOT assume that they will be run to completion;
	the executor might simply stop calling them, for example because of a LIMIT.
	Therefore, it's unsafe to attempt to perform any resource cleanup in the
	final call. It's usually not necessary to clean up memory, anyway. If it's
	necessary to clean up other types of resources, such as file descriptors,
	one can register a shutdown callback function in the ExprContext pointed to
	by the ReturnSetInfo node. (But note that file descriptors are a limited
	resource, so it's generally unwise to hold those open across calls; SRFs
	that need file access are better written to do it in a single call using
	Materialize mode.)

	Materialize mode works like this: the function creates a Tuplestore holding
	the (possibly empty) result set, and returns it. There are no multiple calls.
	The function must also return a TupleDesc that indicates the tuple structure.
	The Tuplestore and TupleDesc should be created in the context
	econtext->ecxt_per_query_memory (note this will not be the context the
	function is called in). The function stores pointers to the Tuplestore and
	TupleDesc into ReturnSetInfo, sets returnMode to indicate materialize mode,
	and returns null. isDone is not used and should be left at ExprSingleResult.

	The Tuplestore must be created with randomAccess = true if
	SFRM_Materialize_Random is set in allowedModes, but it can (and preferably
	should) be created with randomAccess = false if not. Callers that can support
	both ValuePerCall and Materialize mode will set SFRM_Materialize_Preferred,
	or not, depending on which mode they prefer.

	If available, the expected tuple descriptor is passed in ReturnSetInfo;
	in other contexts the expectedDesc field will be NULL. The function need
	not pay attention to expectedDesc, but it may be useful in special cases.

	There is no support for functions accepting sets; instead, the function will
	be called multiple times, once for each element of the input set.


	Notes About Function Handlers
	-----------------------------

	Handlers for classes of functions should find life much easier and
	cleaner in this design. The OID of the called function is directly
	reachable from the passed parameters; we don't need the global variable
	fmgr_pl_finfo anymore. Also, by modifying fcinfo->flinfo->fn_extra,
	the handler can cache lookup info to avoid repeat lookups when the same
	function is invoked many times. (fn_extra can only be used as a hint,
	since callers are not required to re-use an FmgrInfo struct.
	But in performance-critical paths they normally will do so.)

	If the handler wants to allocate memory to hold fn_extra data, it should
	NOT do so in CurrentMemoryContext, since the current context may well be
	much shorter-lived than the context where the FmgrInfo is. Instead,
	allocate the memory in context flinfo->fn_mcxt, or in a long-lived cache
	context. fn_mcxt normally points at the context that was
	CurrentMemoryContext at the time the FmgrInfo structure was created;
	in any case it is required to be a context at least as long-lived as the
	FmgrInfo itself.