This chapter introduces user-defined operators and then demonstrates how to use them, both with and without indextypes.
This chapter contains these topics:
A user-defined operator is a top-level schema object. In many ways, user-defined operators act like the built-in operators such as <, >, and =; for instance, they can be invoked in all the same situations. They contribute to ease of use by simplifying SQL statements, making them shorter and more readable.
User-defined operators are:
Identified by names, which are in the same namespace as tables, views, types, and standalone functions
Bound to functions, which define operator behavior in specified contexts
Controlled by privileges, which indicate the circumstances in which each operator can be used
Often associated with indextypes, which can be used to define indexes that are not built into the database
See Also:Oracle Database SQL Language Reference for detailed information on syntax and privileges
An operator binding associates the operator with the signature of a function that implements the operator. A signature consists of a list of the data types of the arguments of the function, in order of occurrence, and the function's return type. Operator bindings tell Oracle which function to execute when the operator is invoked. An operator can be bound to several functions if each function has a different signature. To be considered different, functions must have different argument lists. Functions whose argument lists match, but whose return data types do not match, are not considered different and cannot be bound to the same operator.
Operators can be bound to:
User-defined type member methods
Operators can be bound to functions and methods in any accessible schema. Each operator must have at least one binding when you create it. If you attempt to specify non-unique operator bindings, the Oracle server raises an error.
To create an operator and its bindings, you must have:
EXECUTE privilege on the function, operator, package, or type referenced
To drop a user-defined operator, you must own the operator or have the
To invoke a user-defined operator in an expression, you must own the operator or have
EXECUTE privilege on it.
To create an operator, specify its name and its bindings with the
CREATE OPERATOR statement. Example 9-1 creates the operator
Contains(), binding it to functions that provide implementations in the Text and Spatial domains.
To drop an operator and all its bindings, specify its name with the
OPERATOR statement. Example 9-2 drops the operator
DROP behavior is
RESTRICT: if there are dependent indextypes or ancillary operators for any of the operator bindings, then the
DROP operation is disallowed.
To override the default behavior, use the
FORCE option. Example 9-3 drops the operator and all its bindings and marks any dependent indextype objects and dependent ancillary operators invalid.
You can add bindings to or drop bindings from an existing operator with the
ALTER OPERATOR statement. Example 9-4 adds a binding to the operator
ALTER OPERATOR Contains ADD BINDING (music.artist, music.artist) RETURN NUMBER USING music.contains;
You need certain privileges to perform alteration operations:
To alter an operator, the operator must be in your own schema, or you must have the
ALTER ANY OPERATOR privilege.
You must have
EXECUTE privileges on the operators and functions referenced.
The following restrictions apply to the
ALTER OPERATOR statement:
You can only issue
ALTER OPERATOR statements that relate to existing operators.
You can only add or drop one binding in each
ALTER OPERATOR statement.
You cannot drop an operator's only binding with
ALTER OPERATOR; use the
DROP OPERATOR statement to drop the operator. An operator cannot exist without any bindings.
If you add a binding to an operator associated with an indextype, the binding is not associated to the indextype unless you also issue the
ALTER INDEXTYPE ADD OPERATOR statement
To add comment text to an operator, specify the name and text with the
COMMENT statement. Example 9-5 supplies information about the
COMMENT ON OPERATOR Contains IS 'a number that indicates if the text contains the key';
Comments on operators are available in the data dictionary through these views:
You can only comment operators in your own schema unless you have the
COMMENT ANY OPERATOR privilege.
Like built-in operators, user-defined operators can be invoked wherever expressions can occur. For example, user-defined operators can be used in:
The select list of a
The condition of a
When an operator is invoked, Oracle evaluates the operator by executing a function bound to it. When several functions are bound to the operator, Oracle executes the function whose argument data types match those of the invocation (after any implicit type conversions). Invoking an operator with an argument list that does not match the signature of any function bound to that operator causes an error to be raised. Because user-defined operators can have multiple bindings, they can be used as overloaded functions.
Assume that Example 9-6 creates the operator
CREATE OPERATOR Contains BINDING (VARCHAR2, VARCHAR2) RETURN NUMBER USING text.contains, (spatial.geo, spatial.geo) RETURN NUMBER USING spatial.contains;
Contains() is used in Example 9-7, the operator invocation
'Oracle') causes Oracle to execute the function
'Oracle') because the signature of the function matches the data types of the operator arguments. Similarly, the operator invocation
:bay_area) executes the function
SELECT * FROM MyEmployees WHERE Contains(resume, 'Oracle')=1 AND Contains(location, :bay_area)=1;
Executing the statement in Example 9-8 raises an error because none of the operator bindings satisfy the argument data types.
Operators are often defined in connection with indextypes. After creating the operators with their functional implementations, you can create an indextype that supports evaluations of these operators using an index scan.
Operators that occur outside
WHERE clauses are essentially stand-ins for the functions that implement them; the meaning of such an operator is determined by its functional implementation. Operators that occur in
WHERE clauses are sometimes evaluated using functional implementations; at other times they are evaluated by index scans. This section describes the various situations and the methods of evaluation.
Operators appearing in the
WHERE clause can be evaluated efficiently by an index scan using the scan methods provided by the indextype. This process involves:
Creating an indextype that supports the evaluation of the operator
Recognizing operator predicates of a certain form
Selecting a domain index
Setting up an appropriate index scan
Executing the index scan methods
The following sections describe each of these steps in detail.
An indextype supports efficient evaluation of operator predicates that can be represented by a range of lower and upper bounds on the operator return values. Specifically, predicates of the forms listed in Example 9-9 are candidates for index scan-based evaluation.
op(...) LIKE value_expression op(...) relop value_expression
value_expression must evaluated to a constant (not a column) that can be used as a domain index key, and
relop is one of
Operator predicates that Oracle can convert internally into one of the forms in Example 9-9 can also make use of the index scan-based evaluation.
Using the operators in expressions, such as
op(...) + 2 = 3, precludes index scan-based evaluation.
Predicates of the form
op() is NULL are evaluated using the functional implementation.
An index scan-based evaluation of an operator is only possible if the operator operates on a column or object attribute indexed by an indextype. The optimizer makes the final decision between the indexed implementation and the functional implementation, taking into account the selectivity and cost while generating the query execution plan.
Consider the query in Example 9-10.
SELECT * FROM MyEmployees WHERE Contains(resume, 'Oracle') = 1;
The optimizer can choose to use a domain index in evaluating the
Contains() operator if
resume column has a defined index.
The index is of type
TextIndexType supports the appropriate
If any of these conditions do not hold, Oracle performs a complete scan of the
MyEmployees table and applies the functional implementation of
Contains() as a post-filter. However, if all these conditions are met, the optimizer uses selectivity and cost functions to compare the cost of index-based evaluation with the full table scan and generates the appropriate execution plan.
Consider a slightly different query in Example 9-11.
SELECT * FROM MyEmployees WHERE Contains(resume, 'Oracle') =1 AND id =100;
Here, you can access the
MyEmployees table through an index on the
id column, one on the
resume column, or a bitmap merge of the two. The optimizer estimates the costs of the three plans and picks the least expensive variant one, which could be to use the index on
id and apply the
Contains() operator on the resulting rows. In that case, Oracle would use the functional implementation of
Contains() rather than the domain index.
If a domain index is selected for the evaluation of an operator predicate, an index scan is set up. The index scan is performed by the scan methods ODCIIndexStart(), ODCIIndexFetch(), and ODCIIndexClose(), specified as part of the corresponding indextype implementation. The ODCIIndexStart() method is invoked with the operator-related information, including name and arguments and the lower and upper bounds describing the predicate. After the ODCIIndexStart() call, a series of fetches are performed to obtain row identifiers of rows satisfying the predicate, and finally the ODCIIndexClose() is called when the SQL cursor is destroyed.
To implement the index scan routines, you must understand how they are invoked and how multiple sets of invocations can be combined.
As an example, consider the query in Example 9-12.
SELECT * FROM MyEmployees1, MyEmployees2 WHERE Contains(MyEmployees1.resume, 'Oracle') =1 AND Contains(MyEmployees2.resume, 'UNIX') =1 AND MyEmployees1.employee_id = MyEmployees2.employee_id;
If the optimizer choses to use the domain indexes on the
resume columns of both tables, the indextype routines might be invoked in the sequence demonstrated in Example 9-13.
start(ctx1, ...); /* corr. to Contains(MyEmployees1.resume, 'Oracle') */ start(ctx2, ...); /* corr. to Contains(MyEmployees2.resume, 'UNIX'); fetch(ctx1, ...); fetch(ctx2, ...); fetch(ctx1, ...); ... close(ctx1); close(ctx2);
In this example, a single indextype routine is invoked several times for different instances of the
Contains() operator. It is possible that many operators are being evaluated concurrently through the same indextype routines. A routine that gets all the information it needs through its parameters, such as the
CREATE routine, does not maintain any state across calls, so evaluating multiple operators concurrently is not a problem. Other routines that must maintain state across calls, like the
FETCH routine, must know which row to return next. These routines should maintain state information in the
SELF parameter that is passed in to each call. The
SELF parameter, an instance of the implementation type, can be used to store either the entire state or a handle to the cursor-duration memory that stores the state (if the state information is large).
Operators that are used outside the
WHERE clause are evaluated using the functional implementation. To execute the statement in Example 9-14, Oracle scans the
MyEmployees table and invokes the functional implementation for
Contains() on each instance of
resume, passing it the actual value of the
resume, the text data, in the current row. Note that this function would not make use of any domain indexes built on the
SELECT Contains(resume, 'Oracle') FROM MyEmployees;
Because functional implementations can make use of domain indexes, the following sections discuss how to write functions that use domain indexes and how they are invoked by the system.
For many domain-specific operators, such as
Contains(), the functional implementation has two options:
If the operator is operating on a column or
OBJECT attribute that has a domain index, the function can evaluate the operator by looking at the index data rather than the actual argument value.
For example, when
'Oracle') is invoked on a particular row of the
MyEmployees table, it is easier for the function to look up the text domain index defined on the
resume column and evaluate the operator based on the row identifier for the row containing the
resume than to work on the
resume text data argument.
If the operator is operating on a column that does not have an appropriate domain index defined on it or if the operator is invoked with literal values (non-columns), the functional implementation evaluates the operator based on the argument values. This is the default behavior for all operator bindings.
To make your operator handle both options, provide a functional implementation that has three arguments in addition to the original arguments to the operator:
Index context: domain index information and the row identifier of the row on which the operator is being evaluated
Scan context: a context value to share state with subsequent invocations of the same operator operating on other rows of the table
Scan flag: indicates whether the current call is the last invocation during which all cleanup operations should be performed
TextContains() in Example 9-15 provides the index-based functional implementation for the
CREATE FUNCTION TextContains (Text IN VARCHAR2, Key IN VARCHAR2, indexctx IN ODCIIndexCtx, scanctx IN OUT TextIndexMethods, scanflg IN NUMBER) RETURN NUMBER AS BEGIN ....... END TextContains;
Contains() operator is bound to the functional implementation, as demonstrated in Example 9-16.
CREATE OPERATOR Contains BINDING (VARCHAR2, VARCHAR2) RETURN NUMBER WITH INDEX CONTEXT, SCAN CONTEXT TextIndexMethods USING TextContains;
WITH INDEX CONTEXT clause specifies that the functional implementation can make use of any applicable domain indexes. The
SCAN CONTEXT specifies the data type of the scan context argument, which must be identical to the implementation type of the indextype that supports this operator.
Oracle invokes the functional implementation for the operator if the operator appears outside the
WHERE clause. If the functional implementation is index-based, or defined to use an indextype, the additional index information is passed in as arguments , but only if the operator's first argument is a column or object attribute with a domain index of the appropriate indextype.
For example, in the query
SELECT Contains(resume, 'Oracle & Unix') FROM MyEmployees, Oracle evaluates the operator
Contains() using the index-based functional implementation, passing it the index information about the domain index on the
resume column instead of the
To execute the index-based functional implementation, Oracle sets up the arguments in the following manner:
The initial set of arguments is identical to those specified by the user for the operator.
If the first argument is not a column, the
ODCIIndexCtx attributes are set to
If the first argument is a column, the
ODCIIndexCtx attributes are set up as follows.
If there is an applicable domain index, the
ODCIIndexInfo attribute contains information about it; otherwise the attribute is set to
rowid attribute holds the row identifier of the row being operated on.
The scan context is set to
NULL on the first invocation of the operator. Because it is an
OUT parameter, the return value from the first invocation is passed in to the second invocation and so on.
The scan flag is set to
RegularCall for all normal invocations of the operator. After the last invocation, the functional implementation is invoked one more time, at which time any cleanup actions can be performed. During this call, the scan flag is set to
CleanupCall and all other arguments except the scan context are set to
When index information is passed in, the implementation can compute the operator value with a domain index lookup using the row identifier as key. The index metadata is used to identify the index structures associated with the domain index. The scan context is typically used to share state with the subsequent invocations of the same operator.
If there is no indextype that supports the operator, or if there is no domain index on the column passed to the operator as its first argument, then the index context argument is null. However, the scan context argument is still available and can be used as described in this section. Thus, the operator can maintain state between invocations even if no index is used by the query.
In addition to filtering rows, operators in
WHERE clauses sometimes must return ancillary data. Ancillary data is modeled as one or more operators, each of which has
A single literal number argument, which ties it to the corresponding primary operator
A functional implementation with access to state generated by the index scan-based implementation of the primary operator
In the query in Example 9-17, the primary operator,
Contains(), can be evaluated using an index scan that determines which rows satisfy the predicate, and computes a score value for each row. The functional implementation for the
Score operator accesses the state generated by the index scan to obtain the score for a given row identified by its row identifier. The literal argument
1 associates the ancillary operator
Score to the primary operator
Contains(), which generates the ancillary data.
SELECT Score(1) FROM MyEmployees WHERE Contains(resume, 'OCI & UNIX', 1) =1;
The functional implementation of an ancillary operator can use either the domain index or the state generated by the primary operator. When invoked, the functional implementation is passed three extra arguments:
The index context, which contains the domain index information
The scan context, which provides access to the state generated by the primary operator
A scan flag to indicate whether the functional implementation is being invoked for the last time
The following sections discuss how operators modeling ancillary data are defined and invoked.
An operator binding that computes ancillary data is called a primary binding. Example 9-18 defines a primary binding for the operator
CREATE OPERATOR Contains BINDING (VARCHAR2, VARCHAR2) RETURN NUMBER WITH INDEX CONTEXT, SCAN CONTEXT TextIndexMethods COMPUTE ANCILLARY DATA USING TextContains;
This definition registers two bindings for
VARCHAR2), used when ancillary data is not required
NUMBER), used when ancillary data is required (the
NUMBER argument associates this binding with the ancillary operator binding)
The two bindings have a single functional implementation, as shown in Example 9-19:
An operator binding that models ancillary data is called an ancillary binding. Functional implementations for ancillary data operators are similar to index-based functional implementations. When you have defined the function, you bind it to the operator with an additional
TO attribute, indicating that the functional implementation must share its state with the primary operator binding.
Note that the functional implementation for the ancillary operator binding must have the same signature as the functional implementation for the primary operator binding.
Example 9-20 demonstrates how to evaluate the ancillary operator inside a
CREATE FUNCTION TextScore (Text IN VARCHAR2, Key IN VARCHAR2, indexctx IN ODCIIndexCtx, scanctx IN OUT TextIndexMethods, scanflg IN NUMBER) RETURN NUMBER AS BEGIN ....... END TextScore;
TextScore() definition, you could create an ancillary binding, as in Example 9-21.
CREATE OPERATOR Score BINDING (NUMBER) RETURN NUMBER ANCILLARY TO Contains(VARCHAR2, VARCHAR2) USING TextScore;
TO clause specifies that
Score shares state with the primary operator binding
The ancillary operator binding is invoked with a single literal number argument, such as
Score(2), and so on.
The operators corresponding to ancillary data are invoked by the user with a single number argument. This number argument must be a literal in both the ancillary operation, and in the primary operator invocation, so that the operator association can be done at query compilation time.
To determine the corresponding primary operator, Oracle matches the number passed to the ancillary operator with the number passed as the last argument to the primary operator. It is an error to find zero or more than one matching primary operator invocation. After the matching primary operator invocation is found,
The arguments to the primary operator become operands of the ancillary operator.
The ancillary and primary operator executions are passed the same scan context.
For example, in the Example 9-17 query, the invocation of
Score is determined to be ancillary to
Contains() based on the number argument
1, and the functional implementation for
Score gets the operands
scanctx, scanflg), where
scanctx is shared with the invocation of
Operator execution uses an index scan to process the
Contains() operator. For each of the rows returned by the
fetch() call of the index scan, the functional implementation of
Score is invoked by passing to it the
ODCIIndexCtx argument, which contains the index information, row identifier, and a handle to the index scan state. The functional implementation can use the handle to the index scan state to compute the score.