/*-------------------------------------------------------------------------
*
* parse_oper.c
* handle operator things for parser
*
* Portions Copyright (c) 1996-2018, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/parser/parse_oper.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "access/htup_details.h"
#include "catalog/pg_operator.h"
#include "catalog/pg_type.h"
#include "lib/stringinfo.h"
#include "nodes/nodeFuncs.h"
#include "parser/parse_coerce.h"
#include "parser/parse_func.h"
#include "parser/parse_oper.h"
#include "parser/parse_type.h"
#include "utils/builtins.h"
#include "utils/inval.h"
#include "utils/lsyscache.h"
#include "utils/syscache.h"
#include "utils/typcache.h"
/*
* The lookup key for the operator lookaside hash table. Unused bits must be
* zeroes to ensure hashing works consistently --- in particular, oprname
* must be zero-padded and any unused entries in search_path must be zero.
*
* search_path contains the actual search_path with which the entry was
* derived (minus temp namespace if any), or else the single specified
* schema OID if we are looking up an explicitly-qualified operator name.
*
* search_path has to be fixed-length since the hashtable code insists on
* fixed-size keys. If your search path is longer than that, we just punt
* and don't cache anything.
*/
/* If your search_path is longer than this, sucks to be you ... */
#define MAX_CACHED_PATH_LEN 16
typedef struct OprCacheKey
{
char oprname[NAMEDATALEN];
Oid left_arg; /* Left input OID, or 0 if prefix op */
Oid right_arg; /* Right input OID, or 0 if postfix op */
Oid search_path[MAX_CACHED_PATH_LEN];
} OprCacheKey;
typedef struct OprCacheEntry
{
/* the hash lookup key MUST BE FIRST */
OprCacheKey key;
Oid opr_oid; /* OID of the resolved operator */
} OprCacheEntry;
static Oid binary_oper_exact(List *opname, Oid arg1, Oid arg2);
static FuncDetailCode oper_select_candidate(int nargs,
Oid *input_typeids,
FuncCandidateList candidates,
Oid *operOid);
static const char *op_signature_string(List *op, char oprkind,
Oid arg1, Oid arg2);
static void op_error(ParseState *pstate, List *op, char oprkind,
Oid arg1, Oid arg2,
FuncDetailCode fdresult, int location);
static bool make_oper_cache_key(ParseState *pstate, OprCacheKey *key,
List *opname, Oid ltypeId, Oid rtypeId,
int location);
static Oid find_oper_cache_entry(OprCacheKey *key);
static void make_oper_cache_entry(OprCacheKey *key, Oid opr_oid);
static void InvalidateOprCacheCallBack(Datum arg, int cacheid, uint32 hashvalue);
/*
* LookupOperName
* Given a possibly-qualified operator name and exact input datatypes,
* look up the operator.
*
* Pass oprleft = InvalidOid for a prefix op, oprright = InvalidOid for
* a postfix op.
*
* If the operator name is not schema-qualified, it is sought in the current
* namespace search path.
*
* If the operator is not found, we return InvalidOid if noError is true,
* else raise an error. pstate and location are used only to report the
* error position; pass NULL/-1 if not available.
*/
Oid
LookupOperName(ParseState *pstate, List *opername, Oid oprleft, Oid oprright,
bool noError, int location)
{
Oid result;
result = OpernameGetOprid(opername, oprleft, oprright);
if (OidIsValid(result))
return result;
/* we don't use op_error here because only an exact match is wanted */
if (!noError)
{
char oprkind;
if (!OidIsValid(oprleft))
oprkind = 'l';
else if (!OidIsValid(oprright))
oprkind = 'r';
else
oprkind = 'b';
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_FUNCTION),
errmsg("operator does not exist: %s",
op_signature_string(opername, oprkind,
oprleft, oprright)),
parser_errposition(pstate, location)));
}
return InvalidOid;
}
/*
* LookupOperWithArgs
* Like LookupOperName, but the argument types are specified by
* a ObjectWithArg node.
*/
Oid
LookupOperWithArgs(ObjectWithArgs *oper, bool noError)
{
TypeName *oprleft,
*oprright;
Oid leftoid,
rightoid;
Assert(list_length(oper->objargs) == 2);
oprleft = linitial(oper->objargs);
oprright = lsecond(oper->objargs);
if (oprleft == NULL)
leftoid = InvalidOid;
else
leftoid = LookupTypeNameOid(NULL, oprleft, noError);
if (oprright == NULL)
rightoid = InvalidOid;
else
rightoid = LookupTypeNameOid(NULL, oprright, noError);
return LookupOperName(NULL, oper->objname, leftoid, rightoid,
noError, -1);
}
/*
* get_sort_group_operators - get default sorting/grouping operators for type
*
* We fetch the "<", "=", and ">" operators all at once to reduce lookup
* overhead (knowing that most callers will be interested in at least two).
* However, a given datatype might have only an "=" operator, if it is
* hashable but not sortable. (Other combinations of present and missing
* operators shouldn't happen, unless the system catalogs are messed up.)
*
* If an operator is missing and the corresponding needXX flag is true,
* throw a standard error message, else return InvalidOid.
*
* In addition to the operator OIDs themselves, this function can identify
* whether the "=" operator is hashable.
*
* Callers can pass NULL pointers for any results they don't care to get.
*
* Note: the results are guaranteed to be exact or binary-compatible matches,
* since most callers are not prepared to cope with adding any run-time type
* coercion steps.
*/
void
get_sort_group_operators(Oid argtype,
bool needLT, bool needEQ, bool needGT,
Oid *ltOpr, Oid *eqOpr, Oid *gtOpr,
bool *isHashable)
{
TypeCacheEntry *typentry;
int cache_flags;
Oid lt_opr;
Oid eq_opr;
Oid gt_opr;
bool hashable;
/*
* Look up the operators using the type cache.
*
* Note: the search algorithm used by typcache.c ensures that the results
* are consistent, ie all from matching opclasses.
*/
if (isHashable != NULL)
cache_flags = TYPECACHE_LT_OPR | TYPECACHE_EQ_OPR | TYPECACHE_GT_OPR |
TYPECACHE_HASH_PROC;
else
cache_flags = TYPECACHE_LT_OPR | TYPECACHE_EQ_OPR | TYPECACHE_GT_OPR;
typentry = lookup_type_cache(argtype, cache_flags);
lt_opr = typentry->lt_opr;
eq_opr = typentry->eq_opr;
gt_opr = typentry->gt_opr;
hashable = OidIsValid(typentry->hash_proc);
/* Report errors if needed */
if ((needLT && !OidIsValid(lt_opr)) ||
(needGT && !OidIsValid(gt_opr)))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_FUNCTION),
errmsg("could not identify an ordering operator for type %s",
format_type_be(argtype)),
errhint("Use an explicit ordering operator or modify the query.")));
if (needEQ && !OidIsValid(eq_opr))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_FUNCTION),
errmsg("could not identify an equality operator for type %s",
format_type_be(argtype))));
/* Return results as needed */
if (ltOpr)
*ltOpr = lt_opr;
if (eqOpr)
*eqOpr = eq_opr;
if (gtOpr)
*gtOpr = gt_opr;
if (isHashable)
*isHashable = hashable;
}
/* given operator tuple, return the operator OID */
Oid
oprid(Operator op)
{
return HeapTupleGetOid(op);
}
/* given operator tuple, return the underlying function's OID */
Oid
oprfuncid(Operator op)
{
Form_pg_operator pgopform = (Form_pg_operator) GETSTRUCT(op);
return pgopform->oprcode;
}
/* binary_oper_exact()
* Check for an "exact" match to the specified operand types.
*
* If one operand is an unknown literal, assume it should be taken to be
* the same type as the other operand for this purpose. Also, consider
* the possibility that the other operand is a domain type that needs to
* be reduced to its base type to find an "exact" match.
*/
static Oid
binary_oper_exact(List *opname, Oid arg1, Oid arg2)
{
Oid result;
bool was_unknown = false;
/* Unspecified type for one of the arguments? then use the other */
if ((arg1 == UNKNOWNOID) && (arg2 != InvalidOid))
{
arg1 = arg2;
was_unknown = true;
}
else if ((arg2 == UNKNOWNOID) && (arg1 != InvalidOid))
{
arg2 = arg1;
was_unknown = true;
}
result = OpernameGetOprid(opname, arg1, arg2);
if (OidIsValid(result))
return result;
if (was_unknown)
{
/* arg1 and arg2 are the same here, need only look at arg1 */
Oid basetype = getBaseType(arg1);
if (basetype != arg1)
{
result = OpernameGetOprid(opname, basetype, basetype);
if (OidIsValid(result))
return result;
}
}
return InvalidOid;
}
/* oper_select_candidate()
* Given the input argtype array and one or more candidates
* for the operator, attempt to resolve the conflict.
*
* Returns FUNCDETAIL_NOTFOUND, FUNCDETAIL_MULTIPLE, or FUNCDETAIL_NORMAL.
* In the success case the Oid of the best candidate is stored in *operOid.
*
* Note that the caller has already determined that there is no candidate
* exactly matching the input argtype(s). Incompatible candidates are not yet
* pruned away, however.
*/
static FuncDetailCode
oper_select_candidate(int nargs,
Oid *input_typeids,
FuncCandidateList candidates,
Oid *operOid) /* output argument */
{
int ncandidates;
/*
* Delete any candidates that cannot actually accept the given input
* types, whether directly or by coercion.
*/
ncandidates = func_match_argtypes(nargs, input_typeids,
candidates, &candidates);
/* Done if no candidate or only one candidate survives */
if (ncandidates == 0)
{
*operOid = InvalidOid;
return FUNCDETAIL_NOTFOUND;
}
if (ncandidates == 1)
{
*operOid = candidates->oid;
return FUNCDETAIL_NORMAL;
}
/*
* Use the same heuristics as for ambiguous functions to resolve the
* conflict.
*/
candidates = func_select_candidate(nargs, input_typeids, candidates);
if (candidates)
{
*operOid = candidates->oid;
return FUNCDETAIL_NORMAL;
}
*operOid = InvalidOid;
return FUNCDETAIL_MULTIPLE; /* failed to select a best candidate */
}
/* oper() -- search for a binary operator
* Given operator name, types of arg1 and arg2, return oper struct.
*
* IMPORTANT: the returned operator (if any) is only promised to be
* coercion-compatible with the input datatypes. Do not use this if
* you need an exact- or binary-compatible match; see compatible_oper.
*
* If no matching operator found, return NULL if noError is true,
* raise an error if it is false. pstate and location are used only to report
* the error position; pass NULL/-1 if not available.
*
* NOTE: on success, the returned object is a syscache entry. The caller
* must ReleaseSysCache() the entry when done with it.
*/
Operator
oper(ParseState *pstate, List *opname, Oid ltypeId, Oid rtypeId,
bool noError, int location)
{
Oid operOid;
OprCacheKey key;
bool key_ok;
FuncDetailCode fdresult = FUNCDETAIL_NOTFOUND;
HeapTuple tup = NULL;
/*
* Try to find the mapping in the lookaside cache.
*/
key_ok = make_oper_cache_key(pstate, &key, opname, ltypeId, rtypeId, location);
if (key_ok)
{
operOid = find_oper_cache_entry(&key);
if (OidIsValid(operOid))
{
tup = SearchSysCache1(OPEROID, ObjectIdGetDatum(operOid));
if (HeapTupleIsValid(tup))
return (Operator) tup;
}
}
/*
* First try for an "exact" match.
*/
operOid = binary_oper_exact(opname, ltypeId, rtypeId);
if (!OidIsValid(operOid))
{
/*
* Otherwise, search for the most suitable candidate.
*/
FuncCandidateList clist;
/* Get binary operators of given name */
clist = OpernameGetCandidates(opname, 'b', false);
/* No operators found? Then fail... */
if (clist != NULL)
{
/*
* Unspecified type for one of the arguments? then use the other
* (XXX this is probably dead code?)
*/
Oid inputOids[2];
if (rtypeId == InvalidOid)
rtypeId = ltypeId;
else if (ltypeId == InvalidOid)
ltypeId = rtypeId;
inputOids[0] = ltypeId;
inputOids[1] = rtypeId;
fdresult = oper_select_candidate(2, inputOids, clist, &operOid);
}
}
if (OidIsValid(operOid))
tup = SearchSysCache1(OPEROID, ObjectIdGetDatum(operOid));
if (HeapTupleIsValid(tup))
{
if (key_ok)
make_oper_cache_entry(&key, operOid);
}
else if (!noError)
op_error(pstate, opname, 'b', ltypeId, rtypeId, fdresult, location);
return (Operator) tup;
}
/* compatible_oper()
* given an opname and input datatypes, find a compatible binary operator
*
* This is tighter than oper() because it will not return an operator that
* requires coercion of the input datatypes (but binary-compatible operators
* are accepted). Otherwise, the semantics are the same.
*/
Operator
compatible_oper(ParseState *pstate, List *op, Oid arg1, Oid arg2,
bool noError, int location)
{
Operator optup;
Form_pg_operator opform;
/* oper() will find the best available match */
optup = oper(pstate, op, arg1, arg2, noError, location);
if (optup == (Operator) NULL)
return (Operator) NULL; /* must be noError case */
/* but is it good enough? */
opform = (Form_pg_operator) GETSTRUCT(optup);
if (IsBinaryCoercible(arg1, opform->oprleft) &&
IsBinaryCoercible(arg2, opform->oprright))
return optup;
/* nope... */
ReleaseSysCache(optup);
if (!noError)
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_FUNCTION),
errmsg("operator requires run-time type coercion: %s",
op_signature_string(op, 'b', arg1, arg2)),
parser_errposition(pstate, location)));
return (Operator) NULL;
}
/* compatible_oper_opid() -- get OID of a binary operator
*
* This is a convenience routine that extracts only the operator OID
* from the result of compatible_oper(). InvalidOid is returned if the
* lookup fails and noError is true.
*/
Oid
compatible_oper_opid(List *op, Oid arg1, Oid arg2, bool noError)
{
Operator optup;
Oid result;
optup = compatible_oper(NULL, op, arg1, arg2, noError, -1);
if (optup != NULL)
{
result = oprid(optup);
ReleaseSysCache(optup);
return result;
}
return InvalidOid;
}
/* right_oper() -- search for a unary right operator (postfix operator)
* Given operator name and type of arg, return oper struct.
*
* IMPORTANT: the returned operator (if any) is only promised to be
* coercion-compatible with the input datatype. Do not use this if
* you need an exact- or binary-compatible match.
*
* If no matching operator found, return NULL if noError is true,
* raise an error if it is false. pstate and location are used only to report
* the error position; pass NULL/-1 if not available.
*
* NOTE: on success, the returned object is a syscache entry. The caller
* must ReleaseSysCache() the entry when done with it.
*/
Operator
right_oper(ParseState *pstate, List *op, Oid arg, bool noError, int location)
{
Oid operOid;
OprCacheKey key;
bool key_ok;
FuncDetailCode fdresult = FUNCDETAIL_NOTFOUND;
HeapTuple tup = NULL;
/*
* Try to find the mapping in the lookaside cache.
*/
key_ok = make_oper_cache_key(pstate, &key, op, arg, InvalidOid, location);
if (key_ok)
{
operOid = find_oper_cache_entry(&key);
if (OidIsValid(operOid))
{
tup = SearchSysCache1(OPEROID, ObjectIdGetDatum(operOid));
if (HeapTupleIsValid(tup))
return (Operator) tup;
}
}
/*
* First try for an "exact" match.
*/
operOid = OpernameGetOprid(op, arg, InvalidOid);
if (!OidIsValid(operOid))
{
/*
* Otherwise, search for the most suitable candidate.
*/
FuncCandidateList clist;
/* Get postfix operators of given name */
clist = OpernameGetCandidates(op, 'r', false);
/* No operators found? Then fail... */
if (clist != NULL)
{
/*
* We must run oper_select_candidate even if only one candidate,
* otherwise we may falsely return a non-type-compatible operator.
*/
fdresult = oper_select_candidate(1, &arg, clist, &operOid);
}
}
if (OidIsValid(operOid))
tup = SearchSysCache1(OPEROID, ObjectIdGetDatum(operOid));
if (HeapTupleIsValid(tup))
{
if (key_ok)
make_oper_cache_entry(&key, operOid);
}
else if (!noError)
op_error(pstate, op, 'r', arg, InvalidOid, fdresult, location);
return (Operator) tup;
}
/* left_oper() -- search for a unary left operator (prefix operator)
* Given operator name and type of arg, return oper struct.
*
* IMPORTANT: the returned operator (if any) is only promised to be
* coercion-compatible with the input datatype. Do not use this if
* you need an exact- or binary-compatible match.
*
* If no matching operator found, return NULL if noError is true,
* raise an error if it is false. pstate and location are used only to report
* the error position; pass NULL/-1 if not available.
*
* NOTE: on success, the returned object is a syscache entry. The caller
* must ReleaseSysCache() the entry when done with it.
*/
Operator
left_oper(ParseState *pstate, List *op, Oid arg, bool noError, int location)
{
Oid operOid;
OprCacheKey key;
bool key_ok;
FuncDetailCode fdresult = FUNCDETAIL_NOTFOUND;
HeapTuple tup = NULL;
/*
* Try to find the mapping in the lookaside cache.
*/
key_ok = make_oper_cache_key(pstate, &key, op, InvalidOid, arg, location);
if (key_ok)
{
operOid = find_oper_cache_entry(&key);
if (OidIsValid(operOid))
{
tup = SearchSysCache1(OPEROID, ObjectIdGetDatum(operOid));
if (HeapTupleIsValid(tup))
return (Operator) tup;
}
}
/*
* First try for an "exact" match.
*/
operOid = OpernameGetOprid(op, InvalidOid, arg);
if (!OidIsValid(operOid))
{
/*
* Otherwise, search for the most suitable candidate.
*/
FuncCandidateList clist;
/* Get prefix operators of given name */
clist = OpernameGetCandidates(op, 'l', false);
/* No operators found? Then fail... */
if (clist != NULL)
{
/*
* The returned list has args in the form (0, oprright). Move the
* useful data into args[0] to keep oper_select_candidate simple.
* XXX we are assuming here that we may scribble on the list!
*/
FuncCandidateList clisti;
for (clisti = clist; clisti != NULL; clisti = clisti->next)
{
clisti->args[0] = clisti->args[1];
}
/*
* We must run oper_select_candidate even if only one candidate,
* otherwise we may falsely return a non-type-compatible operator.
*/
fdresult = oper_select_candidate(1, &arg, clist, &operOid);
}
}
if (OidIsValid(operOid))
tup = SearchSysCache1(OPEROID, ObjectIdGetDatum(operOid));
if (HeapTupleIsValid(tup))
{
if (key_ok)
make_oper_cache_entry(&key, operOid);
}
else if (!noError)
op_error(pstate, op, 'l', InvalidOid, arg, fdresult, location);
return (Operator) tup;
}
/*
* op_signature_string
* Build a string representing an operator name, including arg type(s).
* The result is something like "integer + integer".
*
* This is typically used in the construction of operator-not-found error
* messages.
*/
static const char *
op_signature_string(List *op, char oprkind, Oid arg1, Oid arg2)
{
StringInfoData argbuf;
initStringInfo(&argbuf);
if (oprkind != 'l')
appendStringInfo(&argbuf, "%s ", format_type_be(arg1));
appendStringInfoString(&argbuf, NameListToString(op));
if (oprkind != 'r')
appendStringInfo(&argbuf, " %s", format_type_be(arg2));
return argbuf.data; /* return palloc'd string buffer */
}
/*
* op_error - utility routine to complain about an unresolvable operator
*/
static void
op_error(ParseState *pstate, List *op, char oprkind,
Oid arg1, Oid arg2,
FuncDetailCode fdresult, int location)
{
if (fdresult == FUNCDETAIL_MULTIPLE)
ereport(ERROR,
(errcode(ERRCODE_AMBIGUOUS_FUNCTION),
errmsg("operator is not unique: %s",
op_signature_string(op, oprkind, arg1, arg2)),
errhint("Could not choose a best candidate operator. "
"You might need to add explicit type casts."),
parser_errposition(pstate, location)));
else
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_FUNCTION),
errmsg("operator does not exist: %s",
op_signature_string(op, oprkind, arg1, arg2)),
(!arg1 || !arg2) ?
errhint("No operator matches the given name and argument type. "
"You might need to add an explicit type cast.") :
errhint("No operator matches the given name and argument types. "
"You might need to add explicit type casts."),
parser_errposition(pstate, location)));
}
/*
* make_op()
* Operator expression construction.
*
* Transform operator expression ensuring type compatibility.
* This is where some type conversion happens.
*
* last_srf should be a copy of pstate->p_last_srf from just before we
* started transforming the operator's arguments; this is used for nested-SRF
* detection. If the caller will throw an error anyway for a set-returning
* expression, it's okay to cheat and just pass pstate->p_last_srf.
*/
Expr *
make_op(ParseState *pstate, List *opname, Node *ltree, Node *rtree,
Node *last_srf, int location)
{
Oid ltypeId,
rtypeId;
Operator tup;
Form_pg_operator opform;
Oid actual_arg_types[2];
Oid declared_arg_types[2];
int nargs;
List *args;
Oid rettype;
OpExpr *result;
/* Select the operator */
if (rtree == NULL)
{
/* right operator */
ltypeId = exprType(ltree);
rtypeId = InvalidOid;
tup = right_oper(pstate, opname, ltypeId, false, location);
}
else if (ltree == NULL)
{
/* left operator */
rtypeId = exprType(rtree);
ltypeId = InvalidOid;
tup = left_oper(pstate, opname, rtypeId, false, location);
}
else
{
/* otherwise, binary operator */
ltypeId = exprType(ltree);
rtypeId = exprType(rtree);
tup = oper(pstate, opname, ltypeId, rtypeId, false, location);
}
opform = (Form_pg_operator) GETSTRUCT(tup);
/* Check it's not a shell */
if (!RegProcedureIsValid(opform->oprcode))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_FUNCTION),
errmsg("operator is only a shell: %s",
op_signature_string(opname,
opform->oprkind,
opform->oprleft,
opform->oprright)),
parser_errposition(pstate, location)));
/* Do typecasting and build the expression tree */
if (rtree == NULL)
{
/* right operator */
args = list_make1(ltree);
actual_arg_types[0] = ltypeId;
declared_arg_types[0] = opform->oprleft;
nargs = 1;
}
else if (ltree == NULL)
{
/* left operator */
args = list_make1(rtree);
actual_arg_types[0] = rtypeId;
declared_arg_types[0] = opform->oprright;
nargs = 1;
}
else
{
/* otherwise, binary operator */
args = list_make2(ltree, rtree);
actual_arg_types[0] = ltypeId;
actual_arg_types[1] = rtypeId;
declared_arg_types[0] = opform->oprleft;
declared_arg_types[1] = opform->oprright;
nargs = 2;
}
/*
* enforce consistency with polymorphic argument and return types,
* possibly adjusting return type or declared_arg_types (which will be
* used as the cast destination by make_fn_arguments)
*/
rettype = enforce_generic_type_consistency(actual_arg_types,
declared_arg_types,
nargs,
opform->oprresult,
false);
/* perform the necessary typecasting of arguments */
make_fn_arguments(pstate, args, actual_arg_types, declared_arg_types);
/* and build the expression node */
result = makeNode(OpExpr);
result->opno = oprid(tup);
result->opfuncid = opform->oprcode;
result->opresulttype = rettype;
result->opretset = get_func_retset(opform->oprcode);
/* opcollid and inputcollid will be set by parse_collate.c */
result->args = args;
result->location = location;
/* if it returns a set, check that's OK */
if (result->opretset)
{
check_srf_call_placement(pstate, last_srf, location);
/* ... and remember it for error checks at higher levels */
pstate->p_last_srf = (Node *) result;
}
ReleaseSysCache(tup);
return (Expr *) result;
}
/*
* make_scalar_array_op()
* Build expression tree for "scalar op ANY/ALL (array)" construct.
*/
Expr *
make_scalar_array_op(ParseState *pstate, List *opname,
bool useOr,
Node *ltree, Node *rtree,
int location)
{
Oid ltypeId,
rtypeId,
atypeId,
res_atypeId;
Operator tup;
Form_pg_operator opform;
Oid actual_arg_types[2];
Oid declared_arg_types[2];
List *args;
Oid rettype;
ScalarArrayOpExpr *result;
ltypeId = exprType(ltree);
atypeId = exprType(rtree);
/*
* The right-hand input of the operator will be the element type of the
* array. However, if we currently have just an untyped literal on the
* right, stay with that and hope we can resolve the operator.
*/
if (atypeId == UNKNOWNOID)
rtypeId = UNKNOWNOID;
else
{
rtypeId = get_base_element_type(atypeId);
if (!OidIsValid(rtypeId))
ereport(ERROR,
(errcode(ERRCODE_WRONG_OBJECT_TYPE),
errmsg("op ANY/ALL (array) requires array on right side"),
parser_errposition(pstate, location)));
}
/* Now resolve the operator */
tup = oper(pstate, opname, ltypeId, rtypeId, false, location);
opform = (Form_pg_operator) GETSTRUCT(tup);
/* Check it's not a shell */
if (!RegProcedureIsValid(opform->oprcode))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_FUNCTION),
errmsg("operator is only a shell: %s",
op_signature_string(opname,
opform->oprkind,
opform->oprleft,
opform->oprright)),
parser_errposition(pstate, location)));
args = list_make2(ltree, rtree);
actual_arg_types[0] = ltypeId;
actual_arg_types[1] = rtypeId;
declared_arg_types[0] = opform->oprleft;
declared_arg_types[1] = opform->oprright;
/*
* enforce consistency with polymorphic argument and return types,
* possibly adjusting return type or declared_arg_types (which will be
* used as the cast destination by make_fn_arguments)
*/
rettype = enforce_generic_type_consistency(actual_arg_types,
declared_arg_types,
2,
opform->oprresult,
false);
/*
* Check that operator result is boolean
*/
if (rettype != BOOLOID)
ereport(ERROR,
(errcode(ERRCODE_WRONG_OBJECT_TYPE),
errmsg("op ANY/ALL (array) requires operator to yield boolean"),
parser_errposition(pstate, location)));
if (get_func_retset(opform->oprcode))
ereport(ERROR,
(errcode(ERRCODE_WRONG_OBJECT_TYPE),
errmsg("op ANY/ALL (array) requires operator not to return a set"),
parser_errposition(pstate, location)));
/*
* Now switch back to the array type on the right, arranging for any
* needed cast to be applied. Beware of polymorphic operators here;
* enforce_generic_type_consistency may or may not have replaced a
* polymorphic type with a real one.
*/
if (IsPolymorphicType(declared_arg_types[1]))
{
/* assume the actual array type is OK */
res_atypeId = atypeId;
}
else
{
res_atypeId = get_array_type(declared_arg_types[1]);
if (!OidIsValid(res_atypeId))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_OBJECT),
errmsg("could not find array type for data type %s",
format_type_be(declared_arg_types[1])),
parser_errposition(pstate, location)));
}
actual_arg_types[1] = atypeId;
declared_arg_types[1] = res_atypeId;
/* perform the necessary typecasting of arguments */
make_fn_arguments(pstate, args, actual_arg_types, declared_arg_types);
/* and build the expression node */
result = makeNode(ScalarArrayOpExpr);
result->opno = oprid(tup);
result->opfuncid = opform->oprcode;
result->useOr = useOr;
/* inputcollid will be set by parse_collate.c */
result->args = args;
result->location = location;
ReleaseSysCache(tup);
return (Expr *) result;
}
/*
* Lookaside cache to speed operator lookup. Possibly this should be in
* a separate module under utils/cache/ ?
*
* The idea here is that the mapping from operator name and given argument
* types is constant for a given search path (or single specified schema OID)
* so long as the contents of pg_operator and pg_cast don't change. And that
* mapping is pretty expensive to compute, especially for ambiguous operators;
* this is mainly because there are a *lot* of instances of popular operator
* names such as "=", and we have to check each one to see which is the
* best match. So once we have identified the correct mapping, we save it
* in a cache that need only be flushed on pg_operator or pg_cast change.
* (pg_cast must be considered because changes in the set of implicit casts
* affect the set of applicable operators for any given input datatype.)
*
* XXX in principle, ALTER TABLE ... INHERIT could affect the mapping as
* well, but we disregard that since there's no convenient way to find out
* about it, and it seems a pretty far-fetched corner-case anyway.
*
* Note: at some point it might be worth doing a similar cache for function
* lookups. However, the potential gain is a lot less since (a) function
* names are generally not overloaded as heavily as operator names, and
* (b) we'd have to flush on pg_proc updates, which are probably a good
* deal more common than pg_operator updates.
*/
/* The operator cache hashtable */
static HTAB *OprCacheHash = NULL;
/*
* make_oper_cache_key
* Fill the lookup key struct given operator name and arg types.
*
* Returns true if successful, false if the search_path overflowed
* (hence no caching is possible).
*
* pstate/location are used only to report the error position; pass NULL/-1
* if not available.
*/
static bool
make_oper_cache_key(ParseState *pstate, OprCacheKey *key, List *opname,
Oid ltypeId, Oid rtypeId, int location)
{
char *schemaname;
char *opername;
/* deconstruct the name list */
DeconstructQualifiedName(opname, &schemaname, &opername);
/* ensure zero-fill for stable hashing */
MemSet(key, 0, sizeof(OprCacheKey));
/* save operator name and input types into key */
strlcpy(key->oprname, opername, NAMEDATALEN);
key->left_arg = ltypeId;
key->right_arg = rtypeId;
if (schemaname)
{
ParseCallbackState pcbstate;
/* search only in exact schema given */
setup_parser_errposition_callback(&pcbstate, pstate, location);
key->search_path[0] = LookupExplicitNamespace(schemaname, false);
cancel_parser_errposition_callback(&pcbstate);
}
else
{
/* get the active search path */
if (fetch_search_path_array(key->search_path,
MAX_CACHED_PATH_LEN) > MAX_CACHED_PATH_LEN)
return false; /* oops, didn't fit */
}
return true;
}
/*
* find_oper_cache_entry
*
* Look for a cache entry matching the given key. If found, return the
* contained operator OID, else return InvalidOid.
*/
static Oid
find_oper_cache_entry(OprCacheKey *key)
{
OprCacheEntry *oprentry;
if (OprCacheHash == NULL)
{
/* First time through: initialize the hash table */
HASHCTL ctl;
MemSet(&ctl, 0, sizeof(ctl));
ctl.keysize = sizeof(OprCacheKey);
ctl.entrysize = sizeof(OprCacheEntry);
OprCacheHash = hash_create("Operator lookup cache", 256,
&ctl, HASH_ELEM | HASH_BLOBS);
/* Arrange to flush cache on pg_operator and pg_cast changes */
CacheRegisterSyscacheCallback(OPERNAMENSP,
InvalidateOprCacheCallBack,
(Datum) 0);
CacheRegisterSyscacheCallback(CASTSOURCETARGET,
InvalidateOprCacheCallBack,
(Datum) 0);
}
/* Look for an existing entry */
oprentry = (OprCacheEntry *) hash_search(OprCacheHash,
(void *) key,
HASH_FIND, NULL);
if (oprentry == NULL)
return InvalidOid;
return oprentry->opr_oid;
}
/*
* make_oper_cache_entry
*
* Insert a cache entry for the given key.
*/
static void
make_oper_cache_entry(OprCacheKey *key, Oid opr_oid)
{
OprCacheEntry *oprentry;
Assert(OprCacheHash != NULL);
oprentry = (OprCacheEntry *) hash_search(OprCacheHash,
(void *) key,
HASH_ENTER, NULL);
oprentry->opr_oid = opr_oid;
}
/*
* Callback for pg_operator and pg_cast inval events
*/
static void
InvalidateOprCacheCallBack(Datum arg, int cacheid, uint32 hashvalue)
{
HASH_SEQ_STATUS status;
OprCacheEntry *hentry;
Assert(OprCacheHash != NULL);
/* Currently we just flush all entries; hard to be smarter ... */
hash_seq_init(&status, OprCacheHash);
while ((hentry = (OprCacheEntry *) hash_seq_search(&status)) != NULL)
{
if (hash_search(OprCacheHash,
(void *) &hentry->key,
HASH_REMOVE, NULL) == NULL)
elog(ERROR, "hash table corrupted");
}
}