Header And Logo
|
#include "postgres.h"#include "access/htup_details.h"#include "catalog/pg_cast.h"#include "catalog/pg_class.h"#include "catalog/pg_inherits_fn.h"#include "catalog/pg_proc.h"#include "catalog/pg_type.h"#include "nodes/makefuncs.h"#include "nodes/nodeFuncs.h"#include "parser/parse_coerce.h"#include "parser/parse_relation.h"#include "parser/parse_type.h"#include "utils/builtins.h"#include "utils/lsyscache.h"#include "utils/syscache.h"#include "utils/typcache.h"
Go to the source code of this file.
Functions | |
| static Node * | coerce_type_typmod (Node *node, Oid targetTypeId, int32 targetTypMod, CoercionForm cformat, int location, bool isExplicit, bool hideInputCoercion) |
| static void | hide_coercion_node (Node *node) |
| static Node * | build_coercion_expression (Node *node, CoercionPathType pathtype, Oid funcId, Oid targetTypeId, int32 targetTypMod, CoercionForm cformat, int location, bool isExplicit) |
| static Node * | coerce_record_to_complex (ParseState *pstate, Node *node, Oid targetTypeId, CoercionContext ccontext, CoercionForm cformat, int location) |
| static bool | is_complex_array (Oid typid) |
| static bool | typeIsOfTypedTable (Oid reltypeId, Oid reloftypeId) |
| Node * | coerce_to_target_type (ParseState *pstate, Node *expr, Oid exprtype, Oid targettype, int32 targettypmod, CoercionContext ccontext, CoercionForm cformat, int location) |
| Node * | coerce_type (ParseState *pstate, Node *node, Oid inputTypeId, Oid targetTypeId, int32 targetTypeMod, CoercionContext ccontext, CoercionForm cformat, int location) |
| bool | can_coerce_type (int nargs, Oid *input_typeids, Oid *target_typeids, CoercionContext ccontext) |
| Node * | coerce_to_domain (Node *arg, Oid baseTypeId, int32 baseTypeMod, Oid typeId, CoercionForm cformat, int location, bool hideInputCoercion, bool lengthCoercionDone) |
| Node * | coerce_to_boolean (ParseState *pstate, Node *node, const char *constructName) |
| Node * | coerce_to_specific_type (ParseState *pstate, Node *node, Oid targetTypeId, const char *constructName) |
| int | parser_coercion_errposition (ParseState *pstate, int coerce_location, Node *input_expr) |
| Oid | select_common_type (ParseState *pstate, List *exprs, const char *context, Node **which_expr) |
| Node * | coerce_to_common_type (ParseState *pstate, Node *node, Oid targetTypeId, const char *context) |
| bool | check_generic_type_consistency (Oid *actual_arg_types, Oid *declared_arg_types, int nargs) |
| Oid | enforce_generic_type_consistency (Oid *actual_arg_types, Oid *declared_arg_types, int nargs, Oid rettype, bool allow_poly) |
| Oid | resolve_generic_type (Oid declared_type, Oid context_actual_type, Oid context_declared_type) |
| TYPCATEGORY | TypeCategory (Oid type) |
| bool | IsPreferredType (TYPCATEGORY category, Oid type) |
| bool | IsBinaryCoercible (Oid srctype, Oid targettype) |
| CoercionPathType | find_coercion_pathway (Oid targetTypeId, Oid sourceTypeId, CoercionContext ccontext, Oid *funcid) |
| CoercionPathType | find_typmod_coercion_function (Oid typeId, Oid *funcid) |
| static Node * build_coercion_expression | ( | Node * | node, | |
| CoercionPathType | pathtype, | |||
| Oid | funcId, | |||
| Oid | targetTypeId, | |||
| int32 | targetTypMod, | |||
| CoercionForm | cformat, | |||
| int | location, | |||
| bool | isExplicit | |||
| ) | [static] |
Definition at line 760 of file parse_coerce.c.
References CoerceViaIO::arg, ArrayCoerceExpr::arg, Assert, BoolGetDatum, BOOLOID, CoerceViaIO::coerceformat, ArrayCoerceExpr::coerceformat, COERCION_PATH_ARRAYCOERCE, COERCION_PATH_COERCEVIAIO, COERCION_PATH_FUNC, ArrayCoerceExpr::elemfuncid, elog, ERROR, GETSTRUCT, HeapTupleIsValid, Int32GetDatum, INT4OID, InvalidOid, ArrayCoerceExpr::isExplicit, lappend(), list_make1, CoerceViaIO::location, ArrayCoerceExpr::location, FuncExpr::location, makeConst(), makeFuncExpr(), makeNode, ObjectIdGetDatum, OidIsValid, PROCOID, ReleaseSysCache(), CoerceViaIO::resulttype, ArrayCoerceExpr::resulttype, ArrayCoerceExpr::resulttypmod, and SearchSysCache1.
Referenced by coerce_type(), and coerce_type_typmod().
{
int nargs = 0;
if (OidIsValid(funcId))
{
HeapTuple tp;
Form_pg_proc procstruct;
tp = SearchSysCache1(PROCOID, ObjectIdGetDatum(funcId));
if (!HeapTupleIsValid(tp))
elog(ERROR, "cache lookup failed for function %u", funcId);
procstruct = (Form_pg_proc) GETSTRUCT(tp);
/*
* These Asserts essentially check that function is a legal coercion
* function. We can't make the seemingly obvious tests on prorettype
* and proargtypes[0], even in the COERCION_PATH_FUNC case, because of
* various binary-compatibility cases.
*/
/* Assert(targetTypeId == procstruct->prorettype); */
Assert(!procstruct->proretset);
Assert(!procstruct->proisagg);
Assert(!procstruct->proiswindow);
nargs = procstruct->pronargs;
Assert(nargs >= 1 && nargs <= 3);
/* Assert(procstruct->proargtypes.values[0] == exprType(node)); */
Assert(nargs < 2 || procstruct->proargtypes.values[1] == INT4OID);
Assert(nargs < 3 || procstruct->proargtypes.values[2] == BOOLOID);
ReleaseSysCache(tp);
}
if (pathtype == COERCION_PATH_FUNC)
{
/* We build an ordinary FuncExpr with special arguments */
FuncExpr *fexpr;
List *args;
Const *cons;
Assert(OidIsValid(funcId));
args = list_make1(node);
if (nargs >= 2)
{
/* Pass target typmod as an int4 constant */
cons = makeConst(INT4OID,
-1,
InvalidOid,
sizeof(int32),
Int32GetDatum(targetTypMod),
false,
true);
args = lappend(args, cons);
}
if (nargs == 3)
{
/* Pass it a boolean isExplicit parameter, too */
cons = makeConst(BOOLOID,
-1,
InvalidOid,
sizeof(bool),
BoolGetDatum(isExplicit),
false,
true);
args = lappend(args, cons);
}
fexpr = makeFuncExpr(funcId, targetTypeId, args,
InvalidOid, InvalidOid, cformat);
fexpr->location = location;
return (Node *) fexpr;
}
else if (pathtype == COERCION_PATH_ARRAYCOERCE)
{
/* We need to build an ArrayCoerceExpr */
ArrayCoerceExpr *acoerce = makeNode(ArrayCoerceExpr);
acoerce->arg = (Expr *) node;
acoerce->elemfuncid = funcId;
acoerce->resulttype = targetTypeId;
/*
* Label the output as having a particular typmod only if we are
* really invoking a length-coercion function, ie one with more than
* one argument.
*/
acoerce->resulttypmod = (nargs >= 2) ? targetTypMod : -1;
/* resultcollid will be set by parse_collate.c */
acoerce->isExplicit = isExplicit;
acoerce->coerceformat = cformat;
acoerce->location = location;
return (Node *) acoerce;
}
else if (pathtype == COERCION_PATH_COERCEVIAIO)
{
/* We need to build a CoerceViaIO node */
CoerceViaIO *iocoerce = makeNode(CoerceViaIO);
Assert(!OidIsValid(funcId));
iocoerce->arg = (Expr *) node;
iocoerce->resulttype = targetTypeId;
/* resultcollid will be set by parse_collate.c */
iocoerce->coerceformat = cformat;
iocoerce->location = location;
return (Node *) iocoerce;
}
else
{
elog(ERROR, "unsupported pathtype %d in build_coercion_expression",
(int) pathtype);
return NULL; /* keep compiler quiet */
}
}
| bool can_coerce_type | ( | int | nargs, | |
| Oid * | input_typeids, | |||
| Oid * | target_typeids, | |||
| CoercionContext | ccontext | |||
| ) |
Definition at line 489 of file parse_coerce.c.
References ANYOID, check_generic_type_consistency(), COERCION_PATH_NONE, find_coercion_pathway(), i, is_complex_array(), ISCOMPLEX, IsPolymorphicType, RECORDARRAYOID, RECORDOID, typeInheritsFrom(), typeIsOfTypedTable(), and UNKNOWNOID.
Referenced by ATAddForeignKeyConstraint(), coerce_to_common_type(), coerce_to_target_type(), func_match_argtypes(), func_select_candidate(), and select_common_type().
{
bool have_generics = false;
int i;
/* run through argument list... */
for (i = 0; i < nargs; i++)
{
Oid inputTypeId = input_typeids[i];
Oid targetTypeId = target_typeids[i];
CoercionPathType pathtype;
Oid funcId;
/* no problem if same type */
if (inputTypeId == targetTypeId)
continue;
/* accept if target is ANY */
if (targetTypeId == ANYOID)
continue;
/* accept if target is polymorphic, for now */
if (IsPolymorphicType(targetTypeId))
{
have_generics = true; /* do more checking later */
continue;
}
/*
* If input is an untyped string constant, assume we can convert it to
* anything.
*/
if (inputTypeId == UNKNOWNOID)
continue;
/*
* If pg_cast shows that we can coerce, accept. This test now covers
* both binary-compatible and coercion-function cases.
*/
pathtype = find_coercion_pathway(targetTypeId, inputTypeId, ccontext,
&funcId);
if (pathtype != COERCION_PATH_NONE)
continue;
/*
* If input is RECORD and target is a composite type, assume we can
* coerce (may need tighter checking here)
*/
if (inputTypeId == RECORDOID &&
ISCOMPLEX(targetTypeId))
continue;
/*
* If input is a composite type and target is RECORD, accept
*/
if (targetTypeId == RECORDOID &&
ISCOMPLEX(inputTypeId))
continue;
#ifdef NOT_USED /* not implemented yet */
/*
* If input is record[] and target is a composite array type, assume
* we can coerce (may need tighter checking here)
*/
if (inputTypeId == RECORDARRAYOID &&
is_complex_array(targetTypeId))
continue;
#endif
/*
* If input is a composite array type and target is record[], accept
*/
if (targetTypeId == RECORDARRAYOID &&
is_complex_array(inputTypeId))
continue;
/*
* If input is a class type that inherits from target, accept
*/
if (typeInheritsFrom(inputTypeId, targetTypeId)
|| typeIsOfTypedTable(inputTypeId, targetTypeId))
continue;
/*
* Else, cannot coerce at this argument position
*/
return false;
}
/* If we found any generic argument types, cross-check them */
if (have_generics)
{
if (!check_generic_type_consistency(input_typeids, target_typeids,
nargs))
return false;
}
return true;
}
Definition at line 1346 of file parse_coerce.c.
References ANYARRAYOID, ANYELEMENTOID, ANYENUMOID, ANYNONARRAYOID, ANYRANGEOID, get_element_type(), get_range_subtype(), getBaseType(), OidIsValid, type_is_array_domain, type_is_enum(), and UNKNOWNOID.
Referenced by can_coerce_type().
{
int j;
Oid elem_typeid = InvalidOid;
Oid array_typeid = InvalidOid;
Oid array_typelem;
Oid range_typeid = InvalidOid;
Oid range_typelem;
bool have_anyelement = false;
bool have_anynonarray = false;
bool have_anyenum = false;
/*
* Loop through the arguments to see if we have any that are polymorphic.
* If so, require the actual types to be consistent.
*/
for (j = 0; j < nargs; j++)
{
Oid decl_type = declared_arg_types[j];
Oid actual_type = actual_arg_types[j];
if (decl_type == ANYELEMENTOID ||
decl_type == ANYNONARRAYOID ||
decl_type == ANYENUMOID)
{
have_anyelement = true;
if (decl_type == ANYNONARRAYOID)
have_anynonarray = true;
else if (decl_type == ANYENUMOID)
have_anyenum = true;
if (actual_type == UNKNOWNOID)
continue;
if (OidIsValid(elem_typeid) && actual_type != elem_typeid)
return false;
elem_typeid = actual_type;
}
else if (decl_type == ANYARRAYOID)
{
if (actual_type == UNKNOWNOID)
continue;
actual_type = getBaseType(actual_type); /* flatten domains */
if (OidIsValid(array_typeid) && actual_type != array_typeid)
return false;
array_typeid = actual_type;
}
else if (decl_type == ANYRANGEOID)
{
if (actual_type == UNKNOWNOID)
continue;
actual_type = getBaseType(actual_type); /* flatten domains */
if (OidIsValid(range_typeid) && actual_type != range_typeid)
return false;
range_typeid = actual_type;
}
}
/* Get the element type based on the array type, if we have one */
if (OidIsValid(array_typeid))
{
if (array_typeid == ANYARRAYOID)
{
/* Special case for ANYARRAY input: okay iff no ANYELEMENT */
if (have_anyelement)
return false;
return true;
}
array_typelem = get_element_type(array_typeid);
if (!OidIsValid(array_typelem))
return false; /* should be an array, but isn't */
if (!OidIsValid(elem_typeid))
{
/*
* if we don't have an element type yet, use the one we just got
*/
elem_typeid = array_typelem;
}
else if (array_typelem != elem_typeid)
{
/* otherwise, they better match */
return false;
}
}
/* Get the element type based on the range type, if we have one */
if (OidIsValid(range_typeid))
{
range_typelem = get_range_subtype(range_typeid);
if (!OidIsValid(range_typelem))
return false; /* should be a range, but isn't */
if (!OidIsValid(elem_typeid))
{
/*
* if we don't have an element type yet, use the one we just got
*/
elem_typeid = range_typelem;
}
else if (range_typelem != elem_typeid)
{
/* otherwise, they better match */
return false;
}
}
if (have_anynonarray)
{
/* require the element type to not be an array or domain over array */
if (type_is_array_domain(elem_typeid))
return false;
}
if (have_anyenum)
{
/* require the element type to be an enum */
if (!type_is_enum(elem_typeid))
return false;
}
/* Looks valid */
return true;
}
| static Node * coerce_record_to_complex | ( | ParseState * | pstate, | |
| Node * | node, | |||
| Oid | targetTypeId, | |||
| CoercionContext | ccontext, | |||
| CoercionForm | cformat, | |||
| int | location | |||
| ) | [static] |
Definition at line 896 of file parse_coerce.c.
References arg, RowExpr::args, tupleDesc::attrs, COERCE_IMPLICIT_CAST, coerce_to_target_type(), RowExpr::colnames, ereport, errcode(), errdetail(), errmsg(), ERROR, expandRTE(), exprType(), format_type_be(), GetRTEByRangeTablePosn(), i, INT4OID, InvalidOid, IsA, lappend(), lfirst, list_head(), lnext, RowExpr::location, lookup_rowtype_tupdesc(), makeNode, makeNullConst(), tupleDesc::natts, NULL, parser_coercion_errposition(), RECORDOID, ReleaseTupleDesc, RowExpr::row_format, and RowExpr::row_typeid.
Referenced by coerce_type().
{
RowExpr *rowexpr;
TupleDesc tupdesc;
List *args = NIL;
List *newargs;
int i;
int ucolno;
ListCell *arg;
if (node && IsA(node, RowExpr))
{
/*
* Since the RowExpr must be of type RECORD, we needn't worry about it
* containing any dropped columns.
*/
args = ((RowExpr *) node)->args;
}
else if (node && IsA(node, Var) &&
((Var *) node)->varattno == InvalidAttrNumber)
{
int rtindex = ((Var *) node)->varno;
int sublevels_up = ((Var *) node)->varlevelsup;
int vlocation = ((Var *) node)->location;
RangeTblEntry *rte;
rte = GetRTEByRangeTablePosn(pstate, rtindex, sublevels_up);
expandRTE(rte, rtindex, sublevels_up, vlocation, false,
NULL, &args);
}
else
ereport(ERROR,
(errcode(ERRCODE_CANNOT_COERCE),
errmsg("cannot cast type %s to %s",
format_type_be(RECORDOID),
format_type_be(targetTypeId)),
parser_coercion_errposition(pstate, location, node)));
tupdesc = lookup_rowtype_tupdesc(targetTypeId, -1);
newargs = NIL;
ucolno = 1;
arg = list_head(args);
for (i = 0; i < tupdesc->natts; i++)
{
Node *expr;
Node *cexpr;
Oid exprtype;
/* Fill in NULLs for dropped columns in rowtype */
if (tupdesc->attrs[i]->attisdropped)
{
/*
* can't use atttypid here, but it doesn't really matter what type
* the Const claims to be.
*/
newargs = lappend(newargs,
makeNullConst(INT4OID, -1, InvalidOid));
continue;
}
if (arg == NULL)
ereport(ERROR,
(errcode(ERRCODE_CANNOT_COERCE),
errmsg("cannot cast type %s to %s",
format_type_be(RECORDOID),
format_type_be(targetTypeId)),
errdetail("Input has too few columns."),
parser_coercion_errposition(pstate, location, node)));
expr = (Node *) lfirst(arg);
exprtype = exprType(expr);
cexpr = coerce_to_target_type(pstate,
expr, exprtype,
tupdesc->attrs[i]->atttypid,
tupdesc->attrs[i]->atttypmod,
ccontext,
COERCE_IMPLICIT_CAST,
-1);
if (cexpr == NULL)
ereport(ERROR,
(errcode(ERRCODE_CANNOT_COERCE),
errmsg("cannot cast type %s to %s",
format_type_be(RECORDOID),
format_type_be(targetTypeId)),
errdetail("Cannot cast type %s to %s in column %d.",
format_type_be(exprtype),
format_type_be(tupdesc->attrs[i]->atttypid),
ucolno),
parser_coercion_errposition(pstate, location, expr)));
newargs = lappend(newargs, cexpr);
ucolno++;
arg = lnext(arg);
}
if (arg != NULL)
ereport(ERROR,
(errcode(ERRCODE_CANNOT_COERCE),
errmsg("cannot cast type %s to %s",
format_type_be(RECORDOID),
format_type_be(targetTypeId)),
errdetail("Input has too many columns."),
parser_coercion_errposition(pstate, location, node)));
ReleaseTupleDesc(tupdesc);
rowexpr = makeNode(RowExpr);
rowexpr->args = newargs;
rowexpr->row_typeid = targetTypeId;
rowexpr->row_format = cformat;
rowexpr->colnames = NIL; /* not needed for named target type */
rowexpr->location = location;
return (Node *) rowexpr;
}
| Node* coerce_to_boolean | ( | ParseState * | pstate, | |
| Node * | node, | |||
| const char * | constructName | |||
| ) |
Definition at line 1024 of file parse_coerce.c.
References BOOLOID, COERCE_IMPLICIT_CAST, coerce_to_target_type(), COERCION_ASSIGNMENT, ereport, errcode(), errmsg(), ERROR, expression_returns_set(), exprLocation(), exprType(), format_type_be(), NULL, and parser_errposition().
Referenced by cookConstraint(), domainAddConstraint(), transformAExprAnd(), transformAExprIn(), transformAExprNot(), transformAExprOr(), transformBooleanTest(), transformCaseExpr(), transformJoinUsingClause(), transformWhereClause(), and transformXmlExpr().
{
Oid inputTypeId = exprType(node);
if (inputTypeId != BOOLOID)
{
Node *newnode;
newnode = coerce_to_target_type(pstate, node, inputTypeId,
BOOLOID, -1,
COERCION_ASSIGNMENT,
COERCE_IMPLICIT_CAST,
-1);
if (newnode == NULL)
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
/* translator: first %s is name of a SQL construct, eg WHERE */
errmsg("argument of %s must be type boolean, not type %s",
constructName, format_type_be(inputTypeId)),
parser_errposition(pstate, exprLocation(node))));
node = newnode;
}
if (expression_returns_set(node))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
/* translator: %s is name of a SQL construct, eg WHERE */
errmsg("argument of %s must not return a set",
constructName),
parser_errposition(pstate, exprLocation(node))));
return node;
}
| Node* coerce_to_common_type | ( | ParseState * | pstate, | |
| Node * | node, | |||
| Oid | targetTypeId, | |||
| const char * | context | |||
| ) |
Definition at line 1275 of file parse_coerce.c.
References can_coerce_type(), COERCE_IMPLICIT_CAST, coerce_type(), COERCION_IMPLICIT, ereport, errcode(), errmsg(), ERROR, exprLocation(), exprType(), format_type_be(), and parser_errposition().
Referenced by generate_setop_tlist(), transformAExprIn(), transformArrayExpr(), transformCaseExpr(), transformCoalesceExpr(), transformMinMaxExpr(), transformSetOperationTree(), and transformValuesClause().
{
Oid inputTypeId = exprType(node);
if (inputTypeId == targetTypeId)
return node; /* no work */
if (can_coerce_type(1, &inputTypeId, &targetTypeId, COERCION_IMPLICIT))
node = coerce_type(pstate, node, inputTypeId, targetTypeId, -1,
COERCION_IMPLICIT, COERCE_IMPLICIT_CAST, -1);
else
ereport(ERROR,
(errcode(ERRCODE_CANNOT_COERCE),
/* translator: first %s is name of a SQL construct, eg CASE */
errmsg("%s could not convert type %s to %s",
context,
format_type_be(inputTypeId),
format_type_be(targetTypeId)),
parser_errposition(pstate, exprLocation(node))));
return node;
}
| Node* coerce_to_domain | ( | Node * | arg, | |
| Oid | baseTypeId, | |||
| int32 | baseTypeMod, | |||
| Oid | typeId, | |||
| CoercionForm | cformat, | |||
| int | location, | |||
| bool | hideInputCoercion, | |||
| bool | lengthCoercionDone | |||
| ) |
Definition at line 610 of file parse_coerce.c.
References CoerceToDomain::arg, COERCE_IMPLICIT_CAST, coerce_type_typmod(), CoerceToDomain::coercionformat, getBaseTypeAndTypmod(), hide_coercion_node(), InvalidOid, CoerceToDomain::location, makeNode, CoerceToDomain::resulttype, and CoerceToDomain::resulttypmod.
Referenced by coerce_type(), expand_targetlist(), ReplaceVarsFromTargetList_callback(), rewriteTargetListIU(), and rewriteValuesRTE().
{
CoerceToDomain *result;
/* Get the base type if it hasn't been supplied */
if (baseTypeId == InvalidOid)
baseTypeId = getBaseTypeAndTypmod(typeId, &baseTypeMod);
/* If it isn't a domain, return the node as it was passed in */
if (baseTypeId == typeId)
return arg;
/* Suppress display of nested coercion steps */
if (hideInputCoercion)
hide_coercion_node(arg);
/*
* If the domain applies a typmod to its base type, build the appropriate
* coercion step. Mark it implicit for display purposes, because we don't
* want it shown separately by ruleutils.c; but the isExplicit flag passed
* to the conversion function depends on the manner in which the domain
* coercion is invoked, so that the semantics of implicit and explicit
* coercion differ. (Is that really the behavior we want?)
*
* NOTE: because we apply this as part of the fixed expression structure,
* ALTER DOMAIN cannot alter the typtypmod. But it's unclear that that
* would be safe to do anyway, without lots of knowledge about what the
* base type thinks the typmod means.
*/
if (!lengthCoercionDone)
{
if (baseTypeMod >= 0)
arg = coerce_type_typmod(arg, baseTypeId, baseTypeMod,
COERCE_IMPLICIT_CAST, location,
(cformat != COERCE_IMPLICIT_CAST),
false);
}
/*
* Now build the domain coercion node. This represents run-time checking
* of any constraints currently attached to the domain. This also ensures
* that the expression is properly labeled as to result type.
*/
result = makeNode(CoerceToDomain);
result->arg = (Expr *) arg;
result->resulttype = typeId;
result->resulttypmod = -1; /* currently, always -1 for domains */
/* resultcollid will be set by parse_collate.c */
result->coercionformat = cformat;
result->location = location;
return (Node *) result;
}
| Node* coerce_to_specific_type | ( | ParseState * | pstate, | |
| Node * | node, | |||
| Oid | targetTypeId, | |||
| const char * | constructName | |||
| ) |
Definition at line 1070 of file parse_coerce.c.
References COERCE_IMPLICIT_CAST, coerce_to_target_type(), COERCION_ASSIGNMENT, ereport, errcode(), errmsg(), ERROR, expression_returns_set(), exprLocation(), exprType(), format_type_be(), NULL, and parser_errposition().
Referenced by examine_parameter_list(), transformFrameOffset(), transformLimitClause(), transformXmlExpr(), and transformXmlSerialize().
{
Oid inputTypeId = exprType(node);
if (inputTypeId != targetTypeId)
{
Node *newnode;
newnode = coerce_to_target_type(pstate, node, inputTypeId,
targetTypeId, -1,
COERCION_ASSIGNMENT,
COERCE_IMPLICIT_CAST,
-1);
if (newnode == NULL)
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
/* translator: first %s is name of a SQL construct, eg LIMIT */
errmsg("argument of %s must be type %s, not type %s",
constructName,
format_type_be(targetTypeId),
format_type_be(inputTypeId)),
parser_errposition(pstate, exprLocation(node))));
node = newnode;
}
if (expression_returns_set(node))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
/* translator: %s is name of a SQL construct, eg LIMIT */
errmsg("argument of %s must not return a set",
constructName),
parser_errposition(pstate, exprLocation(node))));
return node;
}
| Node* coerce_to_target_type | ( | ParseState * | pstate, | |
| Node * | expr, | |||
| Oid | exprtype, | |||
| Oid | targettype, | |||
| int32 | targettypmod, | |||
| CoercionContext | ccontext, | |||
| CoercionForm | cformat, | |||
| int | location | |||
| ) |
Definition at line 76 of file parse_coerce.c.
References CollateExpr::arg, arg, can_coerce_type(), COERCE_IMPLICIT_CAST, coerce_type(), coerce_type_typmod(), CollateExpr::collOid, IsA, CollateExpr::location, and makeNode.
Referenced by ATExecAddColumn(), ATExecAlterColumnType(), ATPrepAlterColumnType(), build_column_default(), coerce_record_to_complex(), coerce_to_boolean(), coerce_to_specific_type(), cookDefault(), EvaluateParams(), transformArrayExpr(), transformArraySubscripts(), transformAssignedExpr(), transformAssignmentIndirection(), transformAssignmentSubscripts(), transformTypeCast(), and transformXmlSerialize().
{
Node *result;
Node *origexpr;
if (!can_coerce_type(1, &exprtype, &targettype, ccontext))
return NULL;
/*
* If the input has a CollateExpr at the top, strip it off, perform the
* coercion, and put a new one back on. This is annoying since it
* duplicates logic in coerce_type, but if we don't do this then it's too
* hard to tell whether coerce_type actually changed anything, and we
* *must* know that to avoid possibly calling hide_coercion_node on
* something that wasn't generated by coerce_type. Note that if there are
* multiple stacked CollateExprs, we just discard all but the topmost.
*/
origexpr = expr;
while (expr && IsA(expr, CollateExpr))
expr = (Node *) ((CollateExpr *) expr)->arg;
result = coerce_type(pstate, expr, exprtype,
targettype, targettypmod,
ccontext, cformat, location);
/*
* If the target is a fixed-length type, it may need a length coercion as
* well as a type coercion. If we find ourselves adding both, force the
* inner coercion node to implicit display form.
*/
result = coerce_type_typmod(result,
targettype, targettypmod,
cformat, location,
(cformat != COERCE_IMPLICIT_CAST),
(result != expr && !IsA(result, Const)));
if (expr != origexpr)
{
/* Reinstall top CollateExpr */
CollateExpr *coll = (CollateExpr *) origexpr;
CollateExpr *newcoll = makeNode(CollateExpr);
newcoll->arg = (Expr *) result;
newcoll->collOid = coll->collOid;
newcoll->location = coll->location;
result = (Node *) newcoll;
}
return result;
}
| Node* coerce_type | ( | ParseState * | pstate, | |
| Node * | node, | |||
| Oid | inputTypeId, | |||
| Oid | targetTypeId, | |||
| int32 | targetTypeMod, | |||
| CoercionContext | ccontext, | |||
| CoercionForm | cformat, | |||
| int | location | |||
| ) |
Definition at line 155 of file parse_coerce.c.
References ANYARRAYOID, ANYELEMENTOID, ANYENUMOID, ANYNONARRAYOID, ANYOID, ANYRANGEOID, ConvertRowtypeExpr::arg, CollateExpr::arg, build_coercion_expression(), cancel_parser_errposition_callback(), COERCE_IMPLICIT_CAST, coerce_record_to_complex(), coerce_to_domain(), coerce_type(), COERCION_PATH_NONE, COERCION_PATH_RELABELTYPE, CollateExpr::collOid, Const::constbyval, Const::constcollid, Const::constisnull, Const::constlen, Const::consttype, Const::consttypmod, Const::constvalue, ConvertRowtypeExpr::convertformat, DatumGetCString, elog, ERROR, exprIsLengthCoercion(), find_coercion_pathway(), format_type_be(), getBaseType(), getBaseTypeAndTypmod(), INTERVALOID, InvalidOid, is_complex_array(), IsA, ISCOMPLEX, ConvertRowtypeExpr::location, CollateExpr::location, Const::location, RelabelType::location, makeNode, makeRelabelType(), NULL, ParseState::p_coerce_param_hook, RECORDARRAYOID, RECORDOID, ReleaseSysCache(), ConvertRowtypeExpr::resulttype, setup_parser_errposition_callback(), stringTypeDatum(), typeByVal(), typeidType(), typeInheritsFrom(), typeIsOfTypedTable(), typeLen(), typeTypeCollation(), and UNKNOWNOID.
Referenced by addTargetToGroupList(), addTargetToSortList(), buildMergedJoinVar(), coerce_to_common_type(), coerce_to_target_type(), coerce_type(), make_fn_arguments(), and ParseFuncOrColumn().
{
Node *result;
CoercionPathType pathtype;
Oid funcId;
if (targetTypeId == inputTypeId ||
node == NULL)
{
/* no conversion needed */
return node;
}
if (targetTypeId == ANYOID ||
targetTypeId == ANYELEMENTOID ||
targetTypeId == ANYNONARRAYOID)
{
/*
* Assume can_coerce_type verified that implicit coercion is okay.
*
* Note: by returning the unmodified node here, we are saying that
* it's OK to treat an UNKNOWN constant as a valid input for a
* function accepting ANY, ANYELEMENT, or ANYNONARRAY. This should be
* all right, since an UNKNOWN value is still a perfectly valid Datum.
*
* NB: we do NOT want a RelabelType here: the exposed type of the
* function argument must be its actual type, not the polymorphic
* pseudotype.
*/
return node;
}
if (targetTypeId == ANYARRAYOID ||
targetTypeId == ANYENUMOID ||
targetTypeId == ANYRANGEOID)
{
/*
* Assume can_coerce_type verified that implicit coercion is okay.
*
* These cases are unlike the ones above because the exposed type of
* the argument must be an actual array, enum, or range type. In
* particular the argument must *not* be an UNKNOWN constant. If it
* is, we just fall through; below, we'll call anyarray_in,
* anyenum_in, or anyrange_in, which will produce an error. Also, if
* what we have is a domain over array, enum, or range, we have to
* relabel it to its base type.
*
* Note: currently, we can't actually see a domain-over-enum here,
* since the other functions in this file will not match such a
* parameter to ANYENUM. But that should get changed eventually.
*/
if (inputTypeId != UNKNOWNOID)
{
Oid baseTypeId = getBaseType(inputTypeId);
if (baseTypeId != inputTypeId)
{
RelabelType *r = makeRelabelType((Expr *) node,
baseTypeId, -1,
InvalidOid,
cformat);
r->location = location;
return (Node *) r;
}
/* Not a domain type, so return it as-is */
return node;
}
}
if (inputTypeId == UNKNOWNOID && IsA(node, Const))
{
/*
* Input is a string constant with previously undetermined type. Apply
* the target type's typinput function to it to produce a constant of
* the target type.
*
* NOTE: this case cannot be folded together with the other
* constant-input case, since the typinput function does not
* necessarily behave the same as a type conversion function. For
* example, int4's typinput function will reject "1.2", whereas
* float-to-int type conversion will round to integer.
*
* XXX if the typinput function is not immutable, we really ought to
* postpone evaluation of the function call until runtime. But there
* is no way to represent a typinput function call as an expression
* tree, because C-string values are not Datums. (XXX This *is*
* possible as of 7.3, do we want to do it?)
*/
Const *con = (Const *) node;
Const *newcon = makeNode(Const);
Oid baseTypeId;
int32 baseTypeMod;
int32 inputTypeMod;
Type targetType;
ParseCallbackState pcbstate;
/*
* If the target type is a domain, we want to call its base type's
* input routine, not domain_in(). This is to avoid premature failure
* when the domain applies a typmod: existing input routines follow
* implicit-coercion semantics for length checks, which is not always
* what we want here. The needed check will be applied properly
* inside coerce_to_domain().
*/
baseTypeMod = targetTypeMod;
baseTypeId = getBaseTypeAndTypmod(targetTypeId, &baseTypeMod);
/*
* For most types we pass typmod -1 to the input routine, because
* existing input routines follow implicit-coercion semantics for
* length checks, which is not always what we want here. Any length
* constraint will be applied later by our caller. An exception
* however is the INTERVAL type, for which we *must* pass the typmod
* or it won't be able to obey the bizarre SQL-spec input rules. (Ugly
* as sin, but so is this part of the spec...)
*/
if (baseTypeId == INTERVALOID)
inputTypeMod = baseTypeMod;
else
inputTypeMod = -1;
targetType = typeidType(baseTypeId);
newcon->consttype = baseTypeId;
newcon->consttypmod = inputTypeMod;
newcon->constcollid = typeTypeCollation(targetType);
newcon->constlen = typeLen(targetType);
newcon->constbyval = typeByVal(targetType);
newcon->constisnull = con->constisnull;
/*
* We use the original literal's location regardless of the position
* of the coercion. This is a change from pre-9.2 behavior, meant to
* simplify life for pg_stat_statements.
*/
newcon->location = con->location;
/*
* Set up to point at the constant's text if the input routine throws
* an error.
*/
setup_parser_errposition_callback(&pcbstate, pstate, con->location);
/*
* We assume here that UNKNOWN's internal representation is the same
* as CSTRING.
*/
if (!con->constisnull)
newcon->constvalue = stringTypeDatum(targetType,
DatumGetCString(con->constvalue),
inputTypeMod);
else
newcon->constvalue = stringTypeDatum(targetType,
NULL,
inputTypeMod);
cancel_parser_errposition_callback(&pcbstate);
result = (Node *) newcon;
/* If target is a domain, apply constraints. */
if (baseTypeId != targetTypeId)
result = coerce_to_domain(result,
baseTypeId, baseTypeMod,
targetTypeId,
cformat, location, false, false);
ReleaseSysCache(targetType);
return result;
}
if (IsA(node, Param) &&
pstate != NULL && pstate->p_coerce_param_hook != NULL)
{
/*
* Allow the CoerceParamHook to decide what happens. It can return a
* transformed node (very possibly the same Param node), or return
* NULL to indicate we should proceed with normal coercion.
*/
result = (*pstate->p_coerce_param_hook) (pstate,
(Param *) node,
targetTypeId,
targetTypeMod,
location);
if (result)
return result;
}
if (IsA(node, CollateExpr))
{
/*
* If we have a COLLATE clause, we have to push the coercion
* underneath the COLLATE. This is really ugly, but there is little
* choice because the above hacks on Consts and Params wouldn't happen
* otherwise. This kluge has consequences in coerce_to_target_type.
*/
CollateExpr *coll = (CollateExpr *) node;
CollateExpr *newcoll = makeNode(CollateExpr);
newcoll->arg = (Expr *)
coerce_type(pstate, (Node *) coll->arg,
inputTypeId, targetTypeId, targetTypeMod,
ccontext, cformat, location);
newcoll->collOid = coll->collOid;
newcoll->location = coll->location;
return (Node *) newcoll;
}
pathtype = find_coercion_pathway(targetTypeId, inputTypeId, ccontext,
&funcId);
if (pathtype != COERCION_PATH_NONE)
{
if (pathtype != COERCION_PATH_RELABELTYPE)
{
/*
* Generate an expression tree representing run-time application
* of the conversion function. If we are dealing with a domain
* target type, the conversion function will yield the base type,
* and we need to extract the correct typmod to use from the
* domain's typtypmod.
*/
Oid baseTypeId;
int32 baseTypeMod;
baseTypeMod = targetTypeMod;
baseTypeId = getBaseTypeAndTypmod(targetTypeId, &baseTypeMod);
result = build_coercion_expression(node, pathtype, funcId,
baseTypeId, baseTypeMod,
cformat, location,
(cformat != COERCE_IMPLICIT_CAST));
/*
* If domain, coerce to the domain type and relabel with domain
* type ID. We can skip the internal length-coercion step if the
* selected coercion function was a type-and-length coercion.
*/
if (targetTypeId != baseTypeId)
result = coerce_to_domain(result, baseTypeId, baseTypeMod,
targetTypeId,
cformat, location, true,
exprIsLengthCoercion(result,
NULL));
}
else
{
/*
* We don't need to do a physical conversion, but we do need to
* attach a RelabelType node so that the expression will be seen
* to have the intended type when inspected by higher-level code.
*
* Also, domains may have value restrictions beyond the base type
* that must be accounted for. If the destination is a domain
* then we won't need a RelabelType node.
*/
result = coerce_to_domain(node, InvalidOid, -1, targetTypeId,
cformat, location, false, false);
if (result == node)
{
/*
* XXX could we label result with exprTypmod(node) instead of
* default -1 typmod, to save a possible length-coercion
* later? Would work if both types have same interpretation of
* typmod, which is likely but not certain.
*/
RelabelType *r = makeRelabelType((Expr *) result,
targetTypeId, -1,
InvalidOid,
cformat);
r->location = location;
result = (Node *) r;
}
}
return result;
}
if (inputTypeId == RECORDOID &&
ISCOMPLEX(targetTypeId))
{
/* Coerce a RECORD to a specific complex type */
return coerce_record_to_complex(pstate, node, targetTypeId,
ccontext, cformat, location);
}
if (targetTypeId == RECORDOID &&
ISCOMPLEX(inputTypeId))
{
/* Coerce a specific complex type to RECORD */
/* NB: we do NOT want a RelabelType here */
return node;
}
#ifdef NOT_USED
if (inputTypeId == RECORDARRAYOID &&
is_complex_array(targetTypeId))
{
/* Coerce record[] to a specific complex array type */
/* not implemented yet ... */
}
#endif
if (targetTypeId == RECORDARRAYOID &&
is_complex_array(inputTypeId))
{
/* Coerce a specific complex array type to record[] */
/* NB: we do NOT want a RelabelType here */
return node;
}
if (typeInheritsFrom(inputTypeId, targetTypeId)
|| typeIsOfTypedTable(inputTypeId, targetTypeId))
{
/*
* Input class type is a subclass of target, so generate an
* appropriate runtime conversion (removing unneeded columns and
* possibly rearranging the ones that are wanted).
*/
ConvertRowtypeExpr *r = makeNode(ConvertRowtypeExpr);
r->arg = (Expr *) node;
r->resulttype = targetTypeId;
r->convertformat = cformat;
r->location = location;
return (Node *) r;
}
/* If we get here, caller blew it */
elog(ERROR, "failed to find conversion function from %s to %s",
format_type_be(inputTypeId), format_type_be(targetTypeId));
return NULL; /* keep compiler quiet */
}
| static Node * coerce_type_typmod | ( | Node * | node, | |
| Oid | targetTypeId, | |||
| int32 | targetTypMod, | |||
| CoercionForm | cformat, | |||
| int | location, | |||
| bool | isExplicit, | |||
| bool | hideInputCoercion | |||
| ) | [static] |
Definition at line 690 of file parse_coerce.c.
References build_coercion_expression(), COERCION_PATH_NONE, exprTypmod(), find_typmod_coercion_function(), and hide_coercion_node().
Referenced by coerce_to_domain(), and coerce_to_target_type().
{
CoercionPathType pathtype;
Oid funcId;
/*
* A negative typmod is assumed to mean that no coercion is wanted. Also,
* skip coercion if already done.
*/
if (targetTypMod < 0 || targetTypMod == exprTypmod(node))
return node;
pathtype = find_typmod_coercion_function(targetTypeId, &funcId);
if (pathtype != COERCION_PATH_NONE)
{
/* Suppress display of nested coercion steps */
if (hideInputCoercion)
hide_coercion_node(node);
node = build_coercion_expression(node, pathtype, funcId,
targetTypeId, targetTypMod,
cformat, location,
isExplicit);
}
return node;
}
| Oid enforce_generic_type_consistency | ( | Oid * | actual_arg_types, | |
| Oid * | declared_arg_types, | |||
| int | nargs, | |||
| Oid | rettype, | |||
| bool | allow_poly | |||
| ) |
Definition at line 1543 of file parse_coerce.c.
References ANYARRAYOID, ANYELEMENTOID, ANYENUMOID, ANYNONARRAYOID, ANYRANGEOID, ereport, errcode(), errdetail(), errmsg(), ERROR, format_type_be(), get_array_type(), get_element_type(), get_range_subtype(), getBaseType(), OidIsValid, type_is_array_domain, type_is_enum(), and UNKNOWNOID.
Referenced by count_agg_clauses_walker(), ExecInitAgg(), initialize_peragg(), lookup_agg_function(), make_op(), make_scalar_array_op(), ParseFuncOrColumn(), and recheck_cast_function_args().
{
int j;
bool have_generics = false;
bool have_unknowns = false;
Oid elem_typeid = InvalidOid;
Oid array_typeid = InvalidOid;
Oid range_typeid = InvalidOid;
Oid array_typelem;
Oid range_typelem;
bool have_anyelement = (rettype == ANYELEMENTOID ||
rettype == ANYNONARRAYOID ||
rettype == ANYENUMOID);
bool have_anynonarray = (rettype == ANYNONARRAYOID);
bool have_anyenum = (rettype == ANYENUMOID);
/*
* Loop through the arguments to see if we have any that are polymorphic.
* If so, require the actual types to be consistent.
*/
for (j = 0; j < nargs; j++)
{
Oid decl_type = declared_arg_types[j];
Oid actual_type = actual_arg_types[j];
if (decl_type == ANYELEMENTOID ||
decl_type == ANYNONARRAYOID ||
decl_type == ANYENUMOID)
{
have_generics = have_anyelement = true;
if (decl_type == ANYNONARRAYOID)
have_anynonarray = true;
else if (decl_type == ANYENUMOID)
have_anyenum = true;
if (actual_type == UNKNOWNOID)
{
have_unknowns = true;
continue;
}
if (allow_poly && decl_type == actual_type)
continue; /* no new information here */
if (OidIsValid(elem_typeid) && actual_type != elem_typeid)
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("arguments declared \"anyelement\" are not all alike"),
errdetail("%s versus %s",
format_type_be(elem_typeid),
format_type_be(actual_type))));
elem_typeid = actual_type;
}
else if (decl_type == ANYARRAYOID)
{
have_generics = true;
if (actual_type == UNKNOWNOID)
{
have_unknowns = true;
continue;
}
if (allow_poly && decl_type == actual_type)
continue; /* no new information here */
actual_type = getBaseType(actual_type); /* flatten domains */
if (OidIsValid(array_typeid) && actual_type != array_typeid)
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("arguments declared \"anyarray\" are not all alike"),
errdetail("%s versus %s",
format_type_be(array_typeid),
format_type_be(actual_type))));
array_typeid = actual_type;
}
else if (decl_type == ANYRANGEOID)
{
have_generics = true;
if (actual_type == UNKNOWNOID)
{
have_unknowns = true;
continue;
}
if (allow_poly && decl_type == actual_type)
continue; /* no new information here */
actual_type = getBaseType(actual_type); /* flatten domains */
if (OidIsValid(range_typeid) && actual_type != range_typeid)
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("arguments declared \"anyrange\" are not all alike"),
errdetail("%s versus %s",
format_type_be(range_typeid),
format_type_be(actual_type))));
range_typeid = actual_type;
}
}
/*
* Fast Track: if none of the arguments are polymorphic, return the
* unmodified rettype. We assume it can't be polymorphic either.
*/
if (!have_generics)
return rettype;
/* Get the element type based on the array type, if we have one */
if (OidIsValid(array_typeid))
{
if (array_typeid == ANYARRAYOID && !have_anyelement)
{
/* Special case for ANYARRAY input: okay iff no ANYELEMENT */
array_typelem = ANYELEMENTOID;
}
else
{
array_typelem = get_element_type(array_typeid);
if (!OidIsValid(array_typelem))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("argument declared \"anyarray\" is not an array but type %s",
format_type_be(array_typeid))));
}
if (!OidIsValid(elem_typeid))
{
/*
* if we don't have an element type yet, use the one we just got
*/
elem_typeid = array_typelem;
}
else if (array_typelem != elem_typeid)
{
/* otherwise, they better match */
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("argument declared \"anyarray\" is not consistent with argument declared \"anyelement\""),
errdetail("%s versus %s",
format_type_be(array_typeid),
format_type_be(elem_typeid))));
}
}
/* Get the element type based on the range type, if we have one */
if (OidIsValid(range_typeid))
{
if (range_typeid == ANYRANGEOID && !have_anyelement)
{
/* Special case for ANYRANGE input: okay iff no ANYELEMENT */
range_typelem = ANYELEMENTOID;
}
else
{
range_typelem = get_range_subtype(range_typeid);
if (!OidIsValid(range_typelem))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("argument declared \"anyrange\" is not a range type but type %s",
format_type_be(range_typeid))));
}
if (!OidIsValid(elem_typeid))
{
/*
* if we don't have an element type yet, use the one we just got
*/
elem_typeid = range_typelem;
}
else if (range_typelem != elem_typeid)
{
/* otherwise, they better match */
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("argument declared \"anyrange\" is not consistent with argument declared \"anyelement\""),
errdetail("%s versus %s",
format_type_be(range_typeid),
format_type_be(elem_typeid))));
}
}
if (!OidIsValid(elem_typeid))
{
if (allow_poly)
{
elem_typeid = ANYELEMENTOID;
array_typeid = ANYARRAYOID;
range_typeid = ANYRANGEOID;
}
else
{
/* Only way to get here is if all the generic args are UNKNOWN */
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("could not determine polymorphic type because input has type \"unknown\"")));
}
}
if (have_anynonarray && elem_typeid != ANYELEMENTOID)
{
/* require the element type to not be an array or domain over array */
if (type_is_array_domain(elem_typeid))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("type matched to anynonarray is an array type: %s",
format_type_be(elem_typeid))));
}
if (have_anyenum && elem_typeid != ANYELEMENTOID)
{
/* require the element type to be an enum */
if (!type_is_enum(elem_typeid))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("type matched to anyenum is not an enum type: %s",
format_type_be(elem_typeid))));
}
/*
* If we had any unknown inputs, re-scan to assign correct types
*/
if (have_unknowns)
{
for (j = 0; j < nargs; j++)
{
Oid decl_type = declared_arg_types[j];
Oid actual_type = actual_arg_types[j];
if (actual_type != UNKNOWNOID)
continue;
if (decl_type == ANYELEMENTOID ||
decl_type == ANYNONARRAYOID ||
decl_type == ANYENUMOID)
declared_arg_types[j] = elem_typeid;
else if (decl_type == ANYARRAYOID)
{
if (!OidIsValid(array_typeid))
{
array_typeid = get_array_type(elem_typeid);
if (!OidIsValid(array_typeid))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_OBJECT),
errmsg("could not find array type for data type %s",
format_type_be(elem_typeid))));
}
declared_arg_types[j] = array_typeid;
}
else if (decl_type == ANYRANGEOID)
{
if (!OidIsValid(range_typeid))
{
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_OBJECT),
errmsg("could not find range type for data type %s",
format_type_be(elem_typeid))));
}
declared_arg_types[j] = range_typeid;
}
}
}
/* if we return ANYARRAY use the appropriate argument type */
if (rettype == ANYARRAYOID)
{
if (!OidIsValid(array_typeid))
{
array_typeid = get_array_type(elem_typeid);
if (!OidIsValid(array_typeid))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_OBJECT),
errmsg("could not find array type for data type %s",
format_type_be(elem_typeid))));
}
return array_typeid;
}
/* if we return ANYRANGE use the appropriate argument type */
if (rettype == ANYRANGEOID)
{
if (!OidIsValid(range_typeid))
{
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_OBJECT),
errmsg("could not find range type for data type %s",
format_type_be(elem_typeid))));
}
return range_typeid;
}
/* if we return ANYELEMENT use the appropriate argument type */
if (rettype == ANYELEMENTOID ||
rettype == ANYNONARRAYOID ||
rettype == ANYENUMOID)
return elem_typeid;
/* we don't return a generic type; send back the original return type */
return rettype;
}
| CoercionPathType find_coercion_pathway | ( | Oid | targetTypeId, | |
| Oid | sourceTypeId, | |||
| CoercionContext | ccontext, | |||
| Oid * | funcid | |||
| ) |
Definition at line 2095 of file parse_coerce.c.
References CASTSOURCETARGET, COERCION_ASSIGNMENT, COERCION_CODE_ASSIGNMENT, COERCION_CODE_EXPLICIT, COERCION_CODE_IMPLICIT, COERCION_EXPLICIT, COERCION_METHOD_BINARY, COERCION_METHOD_FUNCTION, COERCION_METHOD_INOUT, COERCION_PATH_ARRAYCOERCE, COERCION_PATH_COERCEVIAIO, COERCION_PATH_NONE, elog, ERROR, find_coercion_pathway(), get_base_element_type(), get_element_type(), getBaseType(), GETSTRUCT, HeapTupleIsValid, INT2VECTOROID, InvalidOid, ObjectIdGetDatum, OidIsValid, OIDVECTOROID, ReleaseSysCache(), SearchSysCache2, TYPCATEGORY_STRING, and TypeCategory().
Referenced by can_coerce_type(), coerce_type(), find_coercion_pathway(), findFkeyCast(), func_get_detail(), and ri_HashCompareOp().
{
CoercionPathType result = COERCION_PATH_NONE;
HeapTuple tuple;
*funcid = InvalidOid;
/* Perhaps the types are domains; if so, look at their base types */
if (OidIsValid(sourceTypeId))
sourceTypeId = getBaseType(sourceTypeId);
if (OidIsValid(targetTypeId))
targetTypeId = getBaseType(targetTypeId);
/* Domains are always coercible to and from their base type */
if (sourceTypeId == targetTypeId)
return COERCION_PATH_RELABELTYPE;
/* Look in pg_cast */
tuple = SearchSysCache2(CASTSOURCETARGET,
ObjectIdGetDatum(sourceTypeId),
ObjectIdGetDatum(targetTypeId));
if (HeapTupleIsValid(tuple))
{
Form_pg_cast castForm = (Form_pg_cast) GETSTRUCT(tuple);
CoercionContext castcontext;
/* convert char value for castcontext to CoercionContext enum */
switch (castForm->castcontext)
{
case COERCION_CODE_IMPLICIT:
castcontext = COERCION_IMPLICIT;
break;
case COERCION_CODE_ASSIGNMENT:
castcontext = COERCION_ASSIGNMENT;
break;
case COERCION_CODE_EXPLICIT:
castcontext = COERCION_EXPLICIT;
break;
default:
elog(ERROR, "unrecognized castcontext: %d",
(int) castForm->castcontext);
castcontext = 0; /* keep compiler quiet */
break;
}
/* Rely on ordering of enum for correct behavior here */
if (ccontext >= castcontext)
{
switch (castForm->castmethod)
{
case COERCION_METHOD_FUNCTION:
result = COERCION_PATH_FUNC;
*funcid = castForm->castfunc;
break;
case COERCION_METHOD_INOUT:
result = COERCION_PATH_COERCEVIAIO;
break;
case COERCION_METHOD_BINARY:
result = COERCION_PATH_RELABELTYPE;
break;
default:
elog(ERROR, "unrecognized castmethod: %d",
(int) castForm->castmethod);
break;
}
}
ReleaseSysCache(tuple);
}
else
{
/*
* If there's no pg_cast entry, perhaps we are dealing with a pair of
* array types. If so, and if the element types have a suitable cast,
* report that we can coerce with an ArrayCoerceExpr.
*
* Note that the source type can be a domain over array, but not the
* target, because ArrayCoerceExpr won't check domain constraints.
*
* Hack: disallow coercions to oidvector and int2vector, which
* otherwise tend to capture coercions that should go to "real" array
* types. We want those types to be considered "real" arrays for many
* purposes, but not this one. (Also, ArrayCoerceExpr isn't
* guaranteed to produce an output that meets the restrictions of
* these datatypes, such as being 1-dimensional.)
*/
if (targetTypeId != OIDVECTOROID && targetTypeId != INT2VECTOROID)
{
Oid targetElem;
Oid sourceElem;
if ((targetElem = get_element_type(targetTypeId)) != InvalidOid &&
(sourceElem = get_base_element_type(sourceTypeId)) != InvalidOid)
{
CoercionPathType elempathtype;
Oid elemfuncid;
elempathtype = find_coercion_pathway(targetElem,
sourceElem,
ccontext,
&elemfuncid);
if (elempathtype != COERCION_PATH_NONE &&
elempathtype != COERCION_PATH_ARRAYCOERCE)
{
*funcid = elemfuncid;
if (elempathtype == COERCION_PATH_COERCEVIAIO)
result = COERCION_PATH_COERCEVIAIO;
else
result = COERCION_PATH_ARRAYCOERCE;
}
}
}
/*
* If we still haven't found a possibility, consider automatic casting
* using I/O functions. We allow assignment casts to string types and
* explicit casts from string types to be handled this way. (The
* CoerceViaIO mechanism is a lot more general than that, but this is
* all we want to allow in the absence of a pg_cast entry.) It would
* probably be better to insist on explicit casts in both directions,
* but this is a compromise to preserve something of the pre-8.3
* behavior that many types had implicit (yipes!) casts to text.
*/
if (result == COERCION_PATH_NONE)
{
if (ccontext >= COERCION_ASSIGNMENT &&
TypeCategory(targetTypeId) == TYPCATEGORY_STRING)
result = COERCION_PATH_COERCEVIAIO;
else if (ccontext >= COERCION_EXPLICIT &&
TypeCategory(sourceTypeId) == TYPCATEGORY_STRING)
result = COERCION_PATH_COERCEVIAIO;
}
}
return result;
}
| CoercionPathType find_typmod_coercion_function | ( | Oid | typeId, | |
| Oid * | funcid | |||
| ) |
Definition at line 2256 of file parse_coerce.c.
References CASTSOURCETARGET, GETSTRUCT, HeapTupleIsValid, InvalidOid, ObjectIdGetDatum, OidIsValid, ReleaseSysCache(), SearchSysCache2, and typeidType().
Referenced by coerce_type_typmod().
{
CoercionPathType result;
Type targetType;
Form_pg_type typeForm;
HeapTuple tuple;
*funcid = InvalidOid;
result = COERCION_PATH_FUNC;
targetType = typeidType(typeId);
typeForm = (Form_pg_type) GETSTRUCT(targetType);
/* Check for a varlena array type */
if (typeForm->typelem != InvalidOid && typeForm->typlen == -1)
{
/* Yes, switch our attention to the element type */
typeId = typeForm->typelem;
result = COERCION_PATH_ARRAYCOERCE;
}
ReleaseSysCache(targetType);
/* Look in pg_cast */
tuple = SearchSysCache2(CASTSOURCETARGET,
ObjectIdGetDatum(typeId),
ObjectIdGetDatum(typeId));
if (HeapTupleIsValid(tuple))
{
Form_pg_cast castForm = (Form_pg_cast) GETSTRUCT(tuple);
*funcid = castForm->castfunc;
ReleaseSysCache(tuple);
}
if (!OidIsValid(*funcid))
result = COERCION_PATH_NONE;
return result;
}
| static void hide_coercion_node | ( | Node * | node | ) | [static] |
Definition at line 732 of file parse_coerce.c.
References COERCE_IMPLICIT_CAST, elog, ERROR, IsA, and nodeTag.
Referenced by coerce_to_domain(), and coerce_type_typmod().
{
if (IsA(node, FuncExpr))
((FuncExpr *) node)->funcformat = COERCE_IMPLICIT_CAST;
else if (IsA(node, RelabelType))
((RelabelType *) node)->relabelformat = COERCE_IMPLICIT_CAST;
else if (IsA(node, CoerceViaIO))
((CoerceViaIO *) node)->coerceformat = COERCE_IMPLICIT_CAST;
else if (IsA(node, ArrayCoerceExpr))
((ArrayCoerceExpr *) node)->coerceformat = COERCE_IMPLICIT_CAST;
else if (IsA(node, ConvertRowtypeExpr))
((ConvertRowtypeExpr *) node)->convertformat = COERCE_IMPLICIT_CAST;
else if (IsA(node, RowExpr))
((RowExpr *) node)->row_format = COERCE_IMPLICIT_CAST;
else if (IsA(node, CoerceToDomain))
((CoerceToDomain *) node)->coercionformat = COERCE_IMPLICIT_CAST;
else
elog(ERROR, "unsupported node type: %d", (int) nodeTag(node));
}
Definition at line 2306 of file parse_coerce.c.
References get_element_type(), ISCOMPLEX, and OidIsValid.
Referenced by can_coerce_type(), coerce_type(), and IsBinaryCoercible().
{
Oid elemtype = get_element_type(typid);
return (OidIsValid(elemtype) && ISCOMPLEX(elemtype));
}
Definition at line 2002 of file parse_coerce.c.
References ANYARRAYOID, ANYENUMOID, ANYNONARRAYOID, ANYRANGEOID, CASTSOURCETARGET, COERCION_METHOD_BINARY, getBaseType(), GETSTRUCT, HeapTupleIsValid, is_complex_array(), ISCOMPLEX, ObjectIdGetDatum, OidIsValid, RECORDARRAYOID, RECORDOID, ReleaseSysCache(), SearchSysCache2, type_is_array, type_is_enum(), and type_is_range().
Referenced by AggregateCreate(), check_sql_fn_retval(), compatible_oper(), CreateCast(), ExecInitAgg(), findRangeSubOpclass(), GetDefaultOpClass(), GetIndexOpClass(), initialize_peragg(), lookup_agg_function(), ri_HashCompareOp(), and tupledesc_match().
{
HeapTuple tuple;
Form_pg_cast castForm;
bool result;
/* Fast path if same type */
if (srctype == targettype)
return true;
/* If srctype is a domain, reduce to its base type */
if (OidIsValid(srctype))
srctype = getBaseType(srctype);
/* Somewhat-fast path for domain -> base type case */
if (srctype == targettype)
return true;
/* Also accept any array type as coercible to ANYARRAY */
if (targettype == ANYARRAYOID)
if (type_is_array(srctype))
return true;
/* Also accept any non-array type as coercible to ANYNONARRAY */
if (targettype == ANYNONARRAYOID)
if (!type_is_array(srctype))
return true;
/* Also accept any enum type as coercible to ANYENUM */
if (targettype == ANYENUMOID)
if (type_is_enum(srctype))
return true;
/* Also accept any range type as coercible to ANYRANGE */
if (targettype == ANYRANGEOID)
if (type_is_range(srctype))
return true;
/* Also accept any composite type as coercible to RECORD */
if (targettype == RECORDOID)
if (ISCOMPLEX(srctype))
return true;
/* Also accept any composite array type as coercible to RECORD[] */
if (targettype == RECORDARRAYOID)
if (is_complex_array(srctype))
return true;
/* Else look in pg_cast */
tuple = SearchSysCache2(CASTSOURCETARGET,
ObjectIdGetDatum(srctype),
ObjectIdGetDatum(targettype));
if (!HeapTupleIsValid(tuple))
return false; /* no cast */
castForm = (Form_pg_cast) GETSTRUCT(tuple);
result = (castForm->castmethod == COERCION_METHOD_BINARY &&
castForm->castcontext == COERCION_CODE_IMPLICIT);
ReleaseSysCache(tuple);
return result;
}
| bool IsPreferredType | ( | TYPCATEGORY | category, | |
| Oid | type | |||
| ) |
Definition at line 1967 of file parse_coerce.c.
References get_type_category_preferred(), and TYPCATEGORY_INVALID.
Referenced by func_select_candidate(), and GetDefaultOpClass().
{
char typcategory;
bool typispreferred;
get_type_category_preferred(type, &typcategory, &typispreferred);
if (category == typcategory || category == TYPCATEGORY_INVALID)
return typispreferred;
else
return false;
}
| int parser_coercion_errposition | ( | ParseState * | pstate, | |
| int | coerce_location, | |||
| Node * | input_expr | |||
| ) |
Definition at line 1120 of file parse_coerce.c.
References exprLocation(), and parser_errposition().
Referenced by coerce_record_to_complex(), and transformTypeCast().
{
if (coerce_location >= 0)
return parser_errposition(pstate, coerce_location);
else
return parser_errposition(pstate, exprLocation(input_expr));
}
Definition at line 1853 of file parse_coerce.c.
References ANYARRAYOID, ANYELEMENTOID, ANYENUMOID, ANYNONARRAYOID, ANYRANGEOID, elog, ereport, errcode(), errmsg(), ERROR, format_type_be(), get_array_type(), get_element_type(), get_range_subtype(), getBaseType(), and OidIsValid.
Referenced by resolve_polymorphic_argtypes(), and resolve_polymorphic_tupdesc().
{
if (declared_type == ANYARRAYOID)
{
if (context_declared_type == ANYARRAYOID)
{
/*
* Use actual type, but it must be an array; or if it's a domain
* over array, use the base array type.
*/
Oid context_base_type = getBaseType(context_actual_type);
Oid array_typelem = get_element_type(context_base_type);
if (!OidIsValid(array_typelem))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("argument declared \"anyarray\" is not an array but type %s",
format_type_be(context_base_type))));
return context_base_type;
}
else if (context_declared_type == ANYELEMENTOID ||
context_declared_type == ANYNONARRAYOID ||
context_declared_type == ANYENUMOID ||
context_declared_type == ANYRANGEOID)
{
/* Use the array type corresponding to actual type */
Oid array_typeid = get_array_type(context_actual_type);
if (!OidIsValid(array_typeid))
ereport(ERROR,
(errcode(ERRCODE_UNDEFINED_OBJECT),
errmsg("could not find array type for data type %s",
format_type_be(context_actual_type))));
return array_typeid;
}
}
else if (declared_type == ANYELEMENTOID ||
declared_type == ANYNONARRAYOID ||
declared_type == ANYENUMOID ||
declared_type == ANYRANGEOID)
{
if (context_declared_type == ANYARRAYOID)
{
/* Use the element type corresponding to actual type */
Oid context_base_type = getBaseType(context_actual_type);
Oid array_typelem = get_element_type(context_base_type);
if (!OidIsValid(array_typelem))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("argument declared \"anyarray\" is not an array but type %s",
format_type_be(context_base_type))));
return array_typelem;
}
else if (context_declared_type == ANYRANGEOID)
{
/* Use the element type corresponding to actual type */
Oid context_base_type = getBaseType(context_actual_type);
Oid range_typelem = get_range_subtype(context_base_type);
if (!OidIsValid(range_typelem))
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
errmsg("argument declared \"anyrange\" is not a range type but type %s",
format_type_be(context_base_type))));
return range_typelem;
}
else if (context_declared_type == ANYELEMENTOID ||
context_declared_type == ANYNONARRAYOID ||
context_declared_type == ANYENUMOID)
{
/* Use the actual type; it doesn't matter if array or not */
return context_actual_type;
}
}
else
{
/* declared_type isn't polymorphic, so return it as-is */
return declared_type;
}
/* If we get here, declared_type is polymorphic and context isn't */
/* NB: this is a calling-code logic error, not a user error */
elog(ERROR, "could not determine polymorphic type because context isn't polymorphic");
return InvalidOid; /* keep compiler quiet */
}
| Oid select_common_type | ( | ParseState * | pstate, | |
| List * | exprs, | |||
| const char * | context, | |||
| Node ** | which_expr | |||
| ) |
Definition at line 1146 of file parse_coerce.c.
References Assert, can_coerce_type(), COERCION_IMPLICIT, ereport, errcode(), errmsg(), ERROR, exprLocation(), exprType(), for_each_cell, format_type_be(), get_type_category_preferred(), getBaseType(), lfirst, linitial, list_head(), lnext, NIL, NULL, parser_errposition(), and UNKNOWNOID.
Referenced by buildMergedJoinVar(), transformAExprIn(), transformArrayExpr(), transformCaseExpr(), transformCoalesceExpr(), transformMinMaxExpr(), transformSetOperationTree(), and transformValuesClause().
{
Node *pexpr;
Oid ptype;
TYPCATEGORY pcategory;
bool pispreferred;
ListCell *lc;
Assert(exprs != NIL);
pexpr = (Node *) linitial(exprs);
lc = lnext(list_head(exprs));
ptype = exprType(pexpr);
/*
* If all input types are valid and exactly the same, just pick that type.
* This is the only way that we will resolve the result as being a domain
* type; otherwise domains are smashed to their base types for comparison.
*/
if (ptype != UNKNOWNOID)
{
for_each_cell(lc, lc)
{
Node *nexpr = (Node *) lfirst(lc);
Oid ntype = exprType(nexpr);
if (ntype != ptype)
break;
}
if (lc == NULL) /* got to the end of the list? */
{
if (which_expr)
*which_expr = pexpr;
return ptype;
}
}
/*
* Nope, so set up for the full algorithm. Note that at this point, lc
* points to the first list item with type different from pexpr's; we need
* not re-examine any items the previous loop advanced over.
*/
ptype = getBaseType(ptype);
get_type_category_preferred(ptype, &pcategory, &pispreferred);
for_each_cell(lc, lc)
{
Node *nexpr = (Node *) lfirst(lc);
Oid ntype = getBaseType(exprType(nexpr));
/* move on to next one if no new information... */
if (ntype != UNKNOWNOID && ntype != ptype)
{
TYPCATEGORY ncategory;
bool nispreferred;
get_type_category_preferred(ntype, &ncategory, &nispreferred);
if (ptype == UNKNOWNOID)
{
/* so far, only unknowns so take anything... */
pexpr = nexpr;
ptype = ntype;
pcategory = ncategory;
pispreferred = nispreferred;
}
else if (ncategory != pcategory)
{
/*
* both types in different categories? then not much hope...
*/
if (context == NULL)
return InvalidOid;
ereport(ERROR,
(errcode(ERRCODE_DATATYPE_MISMATCH),
/*------
translator: first %s is name of a SQL construct, eg CASE */
errmsg("%s types %s and %s cannot be matched",
context,
format_type_be(ptype),
format_type_be(ntype)),
parser_errposition(pstate, exprLocation(nexpr))));
}
else if (!pispreferred &&
can_coerce_type(1, &ptype, &ntype, COERCION_IMPLICIT) &&
!can_coerce_type(1, &ntype, &ptype, COERCION_IMPLICIT))
{
/*
* take new type if can coerce to it implicitly but not the
* other way; but if we have a preferred type, stay on it.
*/
pexpr = nexpr;
ptype = ntype;
pcategory = ncategory;
pispreferred = nispreferred;
}
}
}
/*
* If all the inputs were UNKNOWN type --- ie, unknown-type literals ---
* then resolve as type TEXT. This situation comes up with constructs
* like SELECT (CASE WHEN foo THEN 'bar' ELSE 'baz' END); SELECT 'foo'
* UNION SELECT 'bar'; It might seem desirable to leave the construct's
* output type as UNKNOWN, but that really doesn't work, because we'd
* probably end up needing a runtime coercion from UNKNOWN to something
* else, and we usually won't have it. We need to coerce the unknown
* literals while they are still literals, so a decision has to be made
* now.
*/
if (ptype == UNKNOWNOID)
ptype = TEXTOID;
if (which_expr)
*which_expr = pexpr;
return ptype;
}
| TYPCATEGORY TypeCategory | ( | Oid | type | ) |
Definition at line 1948 of file parse_coerce.c.
References Assert, get_type_category_preferred(), and TYPCATEGORY_INVALID.
Referenced by array_to_json_internal(), composite_to_json(), find_coercion_pathway(), func_get_detail(), func_select_candidate(), GetDefaultOpClass(), json_agg_transfn(), and to_json().
{
char typcategory;
bool typispreferred;
get_type_category_preferred(type, &typcategory, &typispreferred);
Assert(typcategory != TYPCATEGORY_INVALID);
return (TYPCATEGORY) typcategory;
}
Definition at line 2320 of file parse_coerce.c.
References elog, ERROR, GETSTRUCT, HeapTupleIsValid, ObjectIdGetDatum, ReleaseSysCache(), RELOID, SearchSysCache1, and typeidTypeRelid().
Referenced by can_coerce_type(), and coerce_type().
{
Oid relid = typeidTypeRelid(reltypeId);
bool result = false;
if (relid)
{
HeapTuple tp;
Form_pg_class reltup;
tp = SearchSysCache1(RELOID, ObjectIdGetDatum(relid));
if (!HeapTupleIsValid(tp))
elog(ERROR, "cache lookup failed for relation %u", relid);
reltup = (Form_pg_class) GETSTRUCT(tp);
if (reltup->reloftype == reloftypeId)
result = true;
ReleaseSysCache(tp);
}
return result;
}
1.7.1