/*------------------------------------------------------------------------- * * subscripting.h * API for generic type subscripting * * Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * src/include/nodes/subscripting.h * *------------------------------------------------------------------------- */ #ifndef SUBSCRIPTING_H #define SUBSCRIPTING_H #include "nodes/primnodes.h" /* Forward declarations, to avoid including other headers */ struct ParseState; struct SubscriptingRefState; struct SubscriptExecSteps; /* * The SQL-visible function that defines a subscripting method is declared * subscripting_function(internal) returns internal * but it actually is not passed any parameter. It must return a pointer * to a "struct SubscriptRoutines" that provides pointers to the individual * subscript parsing and execution methods. Typically the pointer will point * to a "static const" variable, but at need it can point to palloc'd space. * The type (after domain-flattening) of the head variable or expression * of a subscripting construct determines which subscripting function is * called for that construct. * * In addition to the method pointers, struct SubscriptRoutines includes * several bool flags that specify properties of the subscripting actions * this data type can perform: * * fetch_strict indicates that a fetch SubscriptRef is strict, i.e., returns * NULL if any input (either the container or any subscript) is NULL. * * fetch_leakproof indicates that a fetch SubscriptRef is leakproof, i.e., * will not throw any data-value-dependent errors. Typically this requires * silently returning NULL for invalid subscripts. * * store_leakproof similarly indicates whether an assignment SubscriptRef is * leakproof. (It is common to prefer throwing errors for invalid subscripts * in assignments; that's fine, but it makes the operation not leakproof. * In current usage there is no advantage in making assignments leakproof.) * * There is no store_strict flag. Such behavior would generally be * undesirable, since for example a null subscript in an assignment would * cause the entire container to become NULL. * * Regardless of these flags, all SubscriptRefs are expected to be immutable, * that is they must always give the same results for the same inputs. * They are expected to always be parallel-safe, as well. */ /* * The transform method is called during parse analysis of a subscripting * construct. The SubscriptingRef node has been constructed, but some of * its fields still need to be filled in, and the subscript expression(s) * are still in raw form. The transform method is responsible for doing * parse analysis of each subscript expression (using transformExpr), * coercing the subscripts to whatever type it needs, and building the * refupperindexpr and reflowerindexpr lists from those results. The * reflowerindexpr list must be empty for an element operation, or the * same length as refupperindexpr for a slice operation. Insert NULLs * (that is, an empty parse tree, not a null Const node) for any omitted * subscripts in a slice operation. (Of course, if the transform method * does not care to support slicing, it can just throw an error if isSlice.) * See array_subscript_transform() for sample code. * * The transform method is also responsible for identifying the result type * of the subscripting operation. At call, refcontainertype and reftypmod * describe the container type (this will be a base type not a domain), and * refelemtype is set to the container type's pg_type.typelem value. The * transform method must set refrestype and reftypmod to describe the result * of subscripting. For arrays, refrestype is set to refelemtype for an * element operation or refcontainertype for a slice, while reftypmod stays * the same in either case; but other types might use other rules. The * transform method should ignore refcollid, as that's determined later on * during parsing. * * At call, refassgnexpr has not been filled in, so the SubscriptingRef node * always looks like a fetch; refrestype should be set as though for a * fetch, too. (The isAssignment parameter is typically only useful if the * transform method wishes to throw an error for not supporting assignment.) * To complete processing of an assignment, the core parser will coerce the * element/slice source expression to the returned refrestype and reftypmod * before putting it into refassgnexpr. It will then set refrestype and * reftypmod to again describe the container type, since that's what an * assignment must return. */ typedef void (*SubscriptTransform) (SubscriptingRef *sbsref, List *indirection, struct ParseState *pstate, bool isSlice, bool isAssignment); /* * The exec_setup method is called during executor-startup compilation of a * SubscriptingRef node in an expression. It must fill *methods with pointers * to functions that can be called for execution of the node. Optionally, * exec_setup can initialize sbsrefstate->workspace to point to some palloc'd * workspace for execution. (Typically, such workspace is used to hold * looked-up catalog data and/or provide space for the check_subscripts step * to pass data forward to the other step functions.) See executor/execExpr.h * for the definitions of these structs and other ones used in expression * execution. * * The methods to be provided are: * * sbs_check_subscripts: examine the just-computed subscript values available * in sbsrefstate's arrays, and possibly convert them into another form * (stored in sbsrefstate->workspace). Return TRUE to continue with * evaluation of the subscripting construct, or FALSE to skip it and return an * overall NULL result. If this is a fetch and the data type's fetch_strict * flag is true, then sbs_check_subscripts must return FALSE if there are any * NULL subscripts. Otherwise it can choose to throw an error, or return * FALSE, or let sbs_fetch or sbs_assign deal with the null subscripts. * * sbs_fetch: perform a subscripting fetch, using the container value in * *op->resvalue and the subscripts from sbs_check_subscripts. If * fetch_strict is true then all these inputs can be assumed non-NULL, * otherwise sbs_fetch must check for null inputs. Place the result in * *op->resvalue / *op->resnull. * * sbs_assign: perform a subscripting assignment, using the original * container value in *op->resvalue / *op->resnull, the subscripts from * sbs_check_subscripts, and the new element/slice value in * sbsrefstate->replacevalue/replacenull. Any of these inputs might be NULL * (unless sbs_check_subscripts rejected null subscripts). Place the result * (an entire new container value) in *op->resvalue / *op->resnull. * * sbs_fetch_old: this is only used in cases where an element or slice * assignment involves an assignment to a sub-field or sub-element * (i.e., nested containers are involved). It must fetch the existing * value of the target element or slice. This is exactly the same as * sbs_fetch except that (a) it must cope with a NULL container, and * with NULL subscripts if sbs_check_subscripts allows them (typically, * returning NULL is good enough); and (b) the result must be placed in * sbsrefstate->prevvalue/prevnull, without overwriting *op->resvalue. * * Subscripting implementations that do not support assignment need not * provide sbs_assign or sbs_fetch_old methods. It might be reasonable * to also omit sbs_check_subscripts, in which case the sbs_fetch method must * combine the functionality of sbs_check_subscripts and sbs_fetch. (The * main reason to have a separate sbs_check_subscripts method is so that * sbs_fetch_old and sbs_assign need not duplicate subscript processing.) * Set the relevant pointers to NULL for any omitted methods. */ typedef void (*SubscriptExecSetup) (const SubscriptingRef *sbsref, struct SubscriptingRefState *sbsrefstate, struct SubscriptExecSteps *methods); /* Struct returned by the SQL-visible subscript handler function */ typedef struct SubscriptRoutines { SubscriptTransform transform; /* parse analysis function */ SubscriptExecSetup exec_setup; /* expression compilation function */ bool fetch_strict; /* is fetch SubscriptRef strict? */ bool fetch_leakproof; /* is fetch SubscriptRef leakproof? */ bool store_leakproof; /* is assignment SubscriptRef leakproof? */ } SubscriptRoutines; #endif /* SUBSCRIPTING_H */