/*------------------------------------------------------------------------- * * nodes.h * Definitions for tagged nodes. * * * Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * src/include/nodes/nodes.h * *------------------------------------------------------------------------- */ #ifndef NODES_H #define NODES_H /* * The first field of every node is NodeTag. Each node created (with makeNode) * will have one of the following tags as the value of its first field. * * Note that inserting or deleting node types changes the numbers of other * node types later in the list. This is no problem during development, since * the node numbers are never stored on disk. But don't do it in a released * branch, because that would represent an ABI break for extensions. */ typedef enum NodeTag { T_Invalid = 0, #include "nodes/nodetags.h" } NodeTag; /* * pg_node_attr() - Used in node definitions to set extra information for * gen_node_support.pl * * Attributes can be attached to a node as a whole (place the attribute * specification on the first line after the struct's opening brace) * or to a specific field (place it at the end of that field's line). The * argument is a comma-separated list of attributes. Unrecognized attributes * cause an error. * * Valid node attributes: * * - abstract: Abstract types are types that cannot be instantiated but that * can be supertypes of other types. We track their fields, so that * subtypes can use them, but we don't emit a node tag, so you can't * instantiate them. * * - custom_copy_equal: Has custom implementations in copyfuncs.c and * equalfuncs.c. * * - custom_read_write: Has custom implementations in outfuncs.c and * readfuncs.c. * * - custom_query_jumble: Has custom implementation in queryjumblefuncs.c. * * - no_copy: Does not support copyObject() at all. * * - no_equal: Does not support equal() at all. * * - no_copy_equal: Shorthand for both no_copy and no_equal. * * - no_query_jumble: Does not support JumbleQuery() at all. * * - no_read: Does not support nodeRead() at all. * * - nodetag_only: Does not support copyObject(), equal(), jumbleQuery() * outNode() or nodeRead(). * * - special_read_write: Has special treatment in outNode() and nodeRead(). * * - nodetag_number(VALUE): assign the specified nodetag number instead of * an auto-generated number. Typically this would only be used in stable * branches, to give a newly-added node type a number without breaking ABI * by changing the numbers of existing node types. * * Node types can be supertypes of other types whether or not they are marked * abstract: if a node struct appears as the first field of another struct * type, then it is the supertype of that type. The no_copy, no_equal, * no_query_jumble and no_read node attributes are automatically inherited * from the supertype. (Notice that nodetag_only does not inherit, so it's * not quite equivalent to a combination of other attributes.) * * Valid node field attributes: * * - array_size(OTHERFIELD): This field is a dynamically allocated array with * size indicated by the mentioned other field. The other field is either a * scalar or a list, in which case the length of the list is used. * * - copy_as(VALUE): In copyObject(), replace the field's value with VALUE. * * - copy_as_scalar: In copyObject(), copy the field as a scalar value * (e.g. a pointer) even if it is a node-type pointer. * * - equal_as_scalar: In equal(), compare the field as a scalar value * even if it is a node-type pointer. * * - equal_ignore: Ignore the field for equality. * * - equal_ignore_if_zero: Ignore the field for equality if it is zero. * (Otherwise, compare normally.) * * - query_jumble_ignore: Ignore the field for the query jumbling. Note * that typmod and collation information are usually irrelevant for the * query jumbling. * * - query_jumble_location: Mark the field as a location to track. This is * only allowed for integer fields that include "location" in their name. * * - read_as(VALUE): In nodeRead(), replace the field's value with VALUE. * * - read_write_ignore: Ignore the field for read/write. This is only allowed * if the node type is marked no_read or read_as() is also specified. * * - write_only_relids, write_only_nondefault_pathtarget, write_only_req_outer: * Special handling for Path struct; see there. * */ #define pg_node_attr(...) /* * The first field of a node of any type is guaranteed to be the NodeTag. * Hence the type of any node can be gotten by casting it to Node. Declaring * a variable to be of Node * (instead of void *) can also facilitate * debugging. */ typedef struct Node { NodeTag type; } Node; #define nodeTag(nodeptr) (((const Node*)(nodeptr))->type) /* * newNode - * create a new node of the specified size and tag the node with the * specified tag. * * !WARNING!: Avoid using newNode directly. You should be using the * macro makeNode. eg. to create a Query node, use makeNode(Query) * * Note: the size argument should always be a compile-time constant, so the * apparent risk of multiple evaluation doesn't matter in practice. */ #ifdef __GNUC__ /* With GCC, we can use a compound statement within an expression */ #define newNode(size, tag) \ ({ Node *_result; \ AssertMacro((size) >= sizeof(Node)); /* need the tag, at least */ \ _result = (Node *) palloc0fast(size); \ _result->type = (tag); \ _result; \ }) #else /* * There is no way to dereference the palloc'ed pointer to assign the * tag, and also return the pointer itself, so we need a holder variable. * Fortunately, this macro isn't recursive so we just define * a global variable for this purpose. */ extern PGDLLIMPORT Node *newNodeMacroHolder; #define newNode(size, tag) \ ( \ AssertMacro((size) >= sizeof(Node)), /* need the tag, at least */ \ newNodeMacroHolder = (Node *) palloc0fast(size), \ newNodeMacroHolder->type = (tag), \ newNodeMacroHolder \ ) #endif /* __GNUC__ */ #define makeNode(_type_) ((_type_ *) newNode(sizeof(_type_),T_##_type_)) #define NodeSetTag(nodeptr,t) (((Node*)(nodeptr))->type = (t)) #define IsA(nodeptr,_type_) (nodeTag(nodeptr) == T_##_type_) /* * castNode(type, ptr) casts ptr to "type *", and if assertions are enabled, * verifies that the node has the appropriate type (using its nodeTag()). * * Use an inline function when assertions are enabled, to avoid multiple * evaluations of the ptr argument (which could e.g. be a function call). */ #ifdef USE_ASSERT_CHECKING static inline Node * castNodeImpl(NodeTag type, void *ptr) { Assert(ptr == NULL || nodeTag(ptr) == type); return (Node *) ptr; } #define castNode(_type_, nodeptr) ((_type_ *) castNodeImpl(T_##_type_, nodeptr)) #else #define castNode(_type_, nodeptr) ((_type_ *) (nodeptr)) #endif /* USE_ASSERT_CHECKING */ /* ---------------------------------------------------------------- * extern declarations follow * ---------------------------------------------------------------- */ /* * nodes/{outfuncs.c,print.c} */ struct Bitmapset; /* not to include bitmapset.h here */ struct StringInfoData; /* not to include stringinfo.h here */ extern void outNode(struct StringInfoData *str, const void *obj); extern void outToken(struct StringInfoData *str, const char *s); extern void outBitmapset(struct StringInfoData *str, const struct Bitmapset *bms); extern void outDatum(struct StringInfoData *str, uintptr_t value, int typlen, bool typbyval); extern char *nodeToString(const void *obj); extern char *bmsToString(const struct Bitmapset *bms); /* * nodes/{readfuncs.c,read.c} */ extern void *stringToNode(const char *str); #ifdef WRITE_READ_PARSE_PLAN_TREES extern void *stringToNodeWithLocations(const char *str); #endif extern struct Bitmapset *readBitmapset(void); extern uintptr_t readDatum(bool typbyval); extern bool *readBoolCols(int numCols); extern int *readIntCols(int numCols); extern Oid *readOidCols(int numCols); extern int16 *readAttrNumberCols(int numCols); /* * nodes/copyfuncs.c */ extern void *copyObjectImpl(const void *from); /* cast result back to argument type, if supported by compiler */ #ifdef HAVE_TYPEOF #define copyObject(obj) ((typeof(obj)) copyObjectImpl(obj)) #else #define copyObject(obj) copyObjectImpl(obj) #endif /* * nodes/equalfuncs.c */ extern bool equal(const void *a, const void *b); /* * Typedefs for identifying qualifier selectivities and plan costs as such. * These are just plain "double"s, but declaring a variable as Selectivity * or Cost makes the intent more obvious. * * These could have gone into plannodes.h or some such, but many files * depend on them... */ typedef double Selectivity; /* fraction of tuples a qualifier will pass */ typedef double Cost; /* execution cost (in page-access units) */ typedef double Cardinality; /* (estimated) number of rows or other integer * count */ /* * CmdType - * enums for type of operation represented by a Query or PlannedStmt * * This is needed in both parsenodes.h and plannodes.h, so put it here... */ typedef enum CmdType { CMD_UNKNOWN, CMD_SELECT, /* select stmt */ CMD_UPDATE, /* update stmt */ CMD_INSERT, /* insert stmt */ CMD_DELETE, /* delete stmt */ CMD_MERGE, /* merge stmt */ CMD_UTILITY, /* cmds like create, destroy, copy, vacuum, * etc. */ CMD_NOTHING /* dummy command for instead nothing rules * with qual */ } CmdType; /* * JoinType - * enums for types of relation joins * * JoinType determines the exact semantics of joining two relations using * a matching qualification. For example, it tells what to do with a tuple * that has no match in the other relation. * * This is needed in both parsenodes.h and plannodes.h, so put it here... */ typedef enum JoinType { /* * The canonical kinds of joins according to the SQL JOIN syntax. Only * these codes can appear in parser output (e.g., JoinExpr nodes). */ JOIN_INNER, /* matching tuple pairs only */ JOIN_LEFT, /* pairs + unmatched LHS tuples */ JOIN_FULL, /* pairs + unmatched LHS + unmatched RHS */ JOIN_RIGHT, /* pairs + unmatched RHS tuples */ /* * Semijoins and anti-semijoins (as defined in relational theory) do not * appear in the SQL JOIN syntax, but there are standard idioms for * representing them (e.g., using EXISTS). The planner recognizes these * cases and converts them to joins. So the planner and executor must * support these codes. NOTE: in JOIN_SEMI output, it is unspecified * which matching RHS row is joined to. In JOIN_ANTI output, the row is * guaranteed to be null-extended. */ JOIN_SEMI, /* 1 copy of each LHS row that has match(es) */ JOIN_ANTI, /* 1 copy of each LHS row that has no match */ JOIN_RIGHT_ANTI, /* 1 copy of each RHS row that has no match */ /* * These codes are used internally in the planner, but are not supported * by the executor (nor, indeed, by most of the planner). */ JOIN_UNIQUE_OUTER, /* LHS path must be made unique */ JOIN_UNIQUE_INNER /* RHS path must be made unique */ /* * We might need additional join types someday. */ } JoinType; /* * OUTER joins are those for which pushed-down quals must behave differently * from the join's own quals. This is in fact everything except INNER and * SEMI joins. However, this macro must also exclude the JOIN_UNIQUE symbols * since those are temporary proxies for what will eventually be an INNER * join. * * Note: semijoins are a hybrid case, but we choose to treat them as not * being outer joins. This is okay principally because the SQL syntax makes * it impossible to have a pushed-down qual that refers to the inner relation * of a semijoin; so there is no strong need to distinguish join quals from * pushed-down quals. This is convenient because for almost all purposes, * quals attached to a semijoin can be treated the same as innerjoin quals. */ #define IS_OUTER_JOIN(jointype) \ (((1 << (jointype)) & \ ((1 << JOIN_LEFT) | \ (1 << JOIN_FULL) | \ (1 << JOIN_RIGHT) | \ (1 << JOIN_ANTI) | \ (1 << JOIN_RIGHT_ANTI))) != 0) /* * AggStrategy - * overall execution strategies for Agg plan nodes * * This is needed in both pathnodes.h and plannodes.h, so put it here... */ typedef enum AggStrategy { AGG_PLAIN, /* simple agg across all input rows */ AGG_SORTED, /* grouped agg, input must be sorted */ AGG_HASHED, /* grouped agg, use internal hashtable */ AGG_MIXED /* grouped agg, hash and sort both used */ } AggStrategy; /* * AggSplit - * splitting (partial aggregation) modes for Agg plan nodes * * This is needed in both pathnodes.h and plannodes.h, so put it here... */ /* Primitive options supported by nodeAgg.c: */ #define AGGSPLITOP_COMBINE 0x01 /* substitute combinefn for transfn */ #define AGGSPLITOP_SKIPFINAL 0x02 /* skip finalfn, return state as-is */ #define AGGSPLITOP_SERIALIZE 0x04 /* apply serialfn to output */ #define AGGSPLITOP_DESERIALIZE 0x08 /* apply deserialfn to input */ /* Supported operating modes (i.e., useful combinations of these options): */ typedef enum AggSplit { /* Basic, non-split aggregation: */ AGGSPLIT_SIMPLE = 0, /* Initial phase of partial aggregation, with serialization: */ AGGSPLIT_INITIAL_SERIAL = AGGSPLITOP_SKIPFINAL | AGGSPLITOP_SERIALIZE, /* Final phase of partial aggregation, with deserialization: */ AGGSPLIT_FINAL_DESERIAL = AGGSPLITOP_COMBINE | AGGSPLITOP_DESERIALIZE } AggSplit; /* Test whether an AggSplit value selects each primitive option: */ #define DO_AGGSPLIT_COMBINE(as) (((as) & AGGSPLITOP_COMBINE) != 0) #define DO_AGGSPLIT_SKIPFINAL(as) (((as) & AGGSPLITOP_SKIPFINAL) != 0) #define DO_AGGSPLIT_SERIALIZE(as) (((as) & AGGSPLITOP_SERIALIZE) != 0) #define DO_AGGSPLIT_DESERIALIZE(as) (((as) & AGGSPLITOP_DESERIALIZE) != 0) /* * SetOpCmd and SetOpStrategy - * overall semantics and execution strategies for SetOp plan nodes * * This is needed in both pathnodes.h and plannodes.h, so put it here... */ typedef enum SetOpCmd { SETOPCMD_INTERSECT, SETOPCMD_INTERSECT_ALL, SETOPCMD_EXCEPT, SETOPCMD_EXCEPT_ALL } SetOpCmd; typedef enum SetOpStrategy { SETOP_SORTED, /* input must be sorted */ SETOP_HASHED /* use internal hashtable */ } SetOpStrategy; /* * OnConflictAction - * "ON CONFLICT" clause type of query * * This is needed in both parsenodes.h and plannodes.h, so put it here... */ typedef enum OnConflictAction { ONCONFLICT_NONE, /* No "ON CONFLICT" clause */ ONCONFLICT_NOTHING, /* ON CONFLICT ... DO NOTHING */ ONCONFLICT_UPDATE /* ON CONFLICT ... DO UPDATE */ } OnConflictAction; /* * LimitOption - * LIMIT option of query * * This is needed in both parsenodes.h and plannodes.h, so put it here... */ typedef enum LimitOption { LIMIT_OPTION_COUNT, /* FETCH FIRST... ONLY */ LIMIT_OPTION_WITH_TIES, /* FETCH FIRST... WITH TIES */ LIMIT_OPTION_DEFAULT, /* No limit present */ } LimitOption; #endif /* NODES_H */