This chapter discusses the Object Type Translator (OTT), which is used to map database object types and named collection types to C structs for use in OCI applications.
This chapter contains these topics:
The Object Type Translator (OTT) assists in the development of C language applications that make use of user-defined types in an Oracle database.
With SQL CREATE TYPE
statements, you can create object types. The definitions of these types are stored in the database, and can be used in the creation of database tables. Once these tables are populated, an OCI programmer can access objects stored in the tables.
An application that accesses object data must be able to represent the data in a host language format. This is accomplished by representing object types as C structs. Although it is possible for a programmer to code struct declarations by hand to represent database object types, this can be very time-consuming and error-prone if many types are involved. OTT obviates the need for such manual coding by automatically generating appropriate struct declarations. In OCI, the application also must call an initialization function generated by OTT.
In addition to creating structs that represent stored data types, OTT generates parallel indicator structs that indicate whether an object type or its fields are NULL
.
The Object Type Translator (OTT) converts database definitions of object types and named collection types into C struct declarations that can be included in an OCI application.
You must explicitly invoke OTT to translate database types to C representations.
On most operating systems, OTT is invoked on the command line. It takes as input an intype file, and it generates an outtype file and one or more C header files and an optional implementation file. The following is an example of a command that invokes OTT:
ott userid=scott intype=demoin.typ outtype=demoout.typ code=c hfile=demo.h\ initfile=demov.c
This command causes OTT to connect to the database with user name scott
. The user is prompted for the password.
The implementation file (demov.c
) contains the function to initialize the type version table with information about the user-defined types translated.
Later sections of this chapter describe each of these parameters in more detail.
Sample demoin.typ
file:
CASE=LOWER TYPE emptype
Sample demoout.typ
file:
CASE = LOWER TYPE SCOTT.EMPTYPE AS emptype VERSION = "$8.0" HFILE = demo.h
In this example, the demoin.typ
file contains the type to be translated, preceded by TYPE
(for example, TYPE emptype
). The structure of the outtype file is similar to the intype file, with the addition of information obtained by OTT.
Once OTT has completed the translation, the header file contains a C struct representation of each type specified in the intype file, and a NULL
indicator struct corresponding to each type. Suppose for example, that the employee type listed in the intype file was defined as shown in Example 15-1.
Example 15-1 Definition of the Employee Object Type Listed in the Intype File
CREATE TYPE emptype AS OBJECT ( name VARCHAR2(30), empno NUMBER, deptno NUMBER, hiredate DATE, salary NUMBER );
Then the header file generated by OTT (demo.h
) includes, among other items, the declarations shown in Example 15-2.
Example 15-2 Contents of the Generated Header File demo.h
struct emptype { OCIString * name; OCINumber empno; OCINumber deptno; OCIDate hiredate; OCINumber salary; }; typedef struct emptype emptype; struct emptype_ind { OCIInd _atomic; OCIInd name; OCIInd empno; OCIInd deptno; OCIInd hiredate; OCIInd salary; }; typedef struct employee_ind employee_ind;
Example 15-3 shows what a sample implementation file (demov.c
) produced by this command contains.
Example 15-3 Contents of the demov.c File
#ifndef OCI_ORACLE #include <oci.h> #endif sword demov(OCIEnv *env, OCIError *err) { sword status = OCITypeVTInit(env, err); if (status == OCI_SUCCESS) status = OCITypeVTInsert(env, err, "HR", 2, "EMPTYPE", 7, "$8.0", 4); return status; }
Parameters in the intype file control the way generated structs are named. In this example, the struct name emptype
matches the database type name emptype
. The struct name is in lowercase because of the line CASE=lower
in the intype file.
The data types that appear in the struct declarations (for example, OCIString
, OCIInd
) are special data types.
See Also:
"OTT Data Type Mappings" for more information about these typesThe remaining sections of this chapter discuss the use of OTT with OCI, followed by a reference section that describes command-line syntax, parameters, intype file structure, nested #include
file generation, schema names usage, default name mapping, and restrictions.
The first step in using OTT is to create object types or named collection types and store them in the database. This is accomplished through the use of the SQL CREATE TYPE
statement.
See Also:
Oracle Database SQL Language Reference for information about theCREATE
TYPE
statementThe next step is to invoke OTT. OTT parameters can be specified on the command line, or in a file called a configuration file. Certain parameters can also be specified in the intype file.
If a parameter is specified in more than one place, its value on the command line takes precedence over its value in the intype file, which takes precedence over its value in a user-defined configuration file, which takes precedence over its value in the default configuration file.
For global options — that is, options on the command line or options at the beginning of the intype file before any TYPE
statements — the value on the command line overrides the value in the intype file. (The options that can be specified globally in the intype file are CASE,
CODE,
INITFILE
, and INITFUNC
, but not HFILE
.) However, anything in the intype file in a TYPE
specification applies to a particular type only, and overrides anything on the command line that would otherwise apply to the type. So if you enter TYPE person HFILE=p.h
, it applies to person
only and overrides the HFILE
on the command line. The statement is not considered a command-line parameter.
Parameters (also called options) set on the command line override any set elsewhere.
See Also:
"OTT Command Line"A configuration file is a text file that contains OTT parameters. Each nonblank line in the file contains one parameter, with its associated value or values. If more than one parameter is put on a line, only the first one is used. Whitespace is not allowed on any nonblank line of a configuration file.
A configuration file can be named on the command line. In addition, a default configuration file is always read. This default configuration file must always exist, but can be empty. The name of the default configuration file is ottcfg.cfg
, and the location of the file is system-specific. For example, on Solaris, the file specification is $ORACLE_HOME/precomp/admin/ottcfg.cfg
. See your operating system-specific documentation for further information.
The intype file gives a list of user-defined types for OTT to translate.
The parameters CASE, HFILE, INITFUNC
, and INITFILE
can appear in the intype file.
See Also:
"Intype File"On most operating systems, OTT is invoked on the command line. You can specify the input and output files, and the database connection information, among other things. Consult your operating system-specific documentation to see how to invoke OTT.
Example 15-4 shows how to invoke OTT from the command line.
Example 15-4 Invoking OTT from the Command Line
ott userid=bren intype=demoin.typ outtype=demoout.typ code=c \ hfile=demo.h initfile=demov.c
Note:
No spaces are permitted around the equal sign (=).The following sections describe the elements of the command line used in this example.
See Also:
"OTT Reference" for a detailed discussion of the various OTT command-line optionsSpecifies the database connection information that OTT uses.
In Example 15-4, OTT attempts to connect with user name bren
and is then prompted for the password.
Specifies the name of the intype file that is used.
In Example 15-4, the name of the intype file is specified as demoin.typ
.
Specifies the name of the outtype file. When OTT generates the C header file, it also writes information about the translated types into the outtype file. This file contains an entry for each of the types that is translated, including its version string, and the header file to which its C representation was written.
In Example 15-4, the name of the outtype file is specified as demoout.typ
.
Note:
If the file specified by the outtype keyword exists, it is overwritten when OTT runs. If the name of the outtype file is the same as the name of the intype file, the outtype information overwrites the intype file.Specifies the target language for the translation. The following options are available:
C (equivalent to ANSI_C)
ANSI_C (for ANSI C)
KR_C (for Kernighan & Ritchie C)
There is currently no default option, so this parameter is required.
Struct declarations are identical in both C dialects. The style in the initialization function defined in the INITFILE
file depends on whether KR_C
is used. If the INITFILE
option is not used, all three options are equivalent.
Specifies the name of the C header file to which the generated structs should be written.
In Example 15-4, the generated structs are stored in a file called demo.h
.
Note:
If the file specified by thehfile
keyword exists, it is overwritten when OTT runs, with one exception: if the contents of the file as generated by OTT are identical to the previous contents of the file, OTT does not actually write to the file. This preserves the modification time of the file so that Linux and UNIX make
and similar facilities on other operating systems do not perform unnecessary recompilations.Specifies the name of the C source file into which the type initialization function is to be written.
Note:
If the file specified by theinitfile
keyword exists, it is overwritten when OTT runs, with one exception: if the contents of the file as generated by OTT are identical to the previous contents of the file, OTT does not actually write to the file. This preserves the modification time of the file so that Linux and UNIX make
and similar facilities on other operating systems do not perform unnecessary recompilations.When OTT runs, the intype file tells OTT which database types should be translated. It can also control the naming of the generated structs. The intype file can be a user-created file, or it can be the outtype file of a previous invocation of OTT. If the intype
parameter is not used, all types in the schema to which OTT connects are translated.
Example 15-5 shows a simple user-created intype file.
Example 15-5 Contents of a User-Created Intype File
CASE=LOWER TYPE employee TRANSLATE SALARY$ AS salary DEPTNO AS department TYPE ADDRESS TYPE item TYPE "Person" TYPE PURCHASE_ORDER AS p_o
Example 15-5 is further described as follows.
The first line, with the CASE
keyword, indicates that generated C identifiers should be in lowercase. However, this CASE
option is only applied to those identifiers that are not explicitly mentioned in the intype file. Thus, employee
and ADDRESS
would always result in C structures employee
and ADDRESS
, respectively. The members of these structures would be named in lowercase.
See Also:
"CASE"In the lines that begin with the TYPE
keyword specify which types in the database should be translated: in this case, the employee, ADDRESS, item, Person
, and PURCHASE_ORDER
types.
The TRANSLATE ... AS
keywords specify that the name of an object attribute should be changed when the type is translated into a C struct. In this case, the SALARY$
attribute of the employee type is translated to salary
.
The AS
keyword in the final line specifies that the name of an object type should be changed when it is translated into a struct. In this case, the PURCHASE_ORDER
database type is translated into a struct called p_o
.
If AS
is not used to translate a type or attribute name, the database name of the type or attribute is used as the C identifier name, except that the CASE
option is observed, and any character that cannot be mapped to a legal C identifier character is replaced by an underscore. Reasons for translating a type or attribute name include the following:
The name contains characters other than letters, digits, and underscores
The name conflicts with a C keyword.
The type name conflicts with another identifier in the same scope. This can happen, for example, if the program uses two types with the same name from different schemas.
The programmer prefers a different name.
OTT may need to translate additional types that are not listed in the intype file. This is because OTT analyzes the types in the intype file for type dependencies before performing the translation, and translates other types as necessary. For example, if the ADDRESS
type were not listed in the intype file, but the "Person"
type had an attribute of type ADDRESS
, OTT would still translate ADDRESS
because it is required to define the "Person"
type.
If you specify FALSE
as the value of the TRANSITIVE
parameter, then OTT does not generate types that are not specified in the intype file.
A normal case-insensitive SQL identifier can be spelled in any combination of uppercase and lowercase in the intype file, and is not enclosed within quotation marks.
Use quotation marks, such as TYPE
"Person"
, to reference SQL identifiers that have been created in a case-sensitive manner (for example, CREATE TYPE "Person"
). A SQL identifier is case-sensitive if it was enclosed within quotation marks when it was declared. Quotation marks can also be used to refer to a SQL identifier that is an OTT-reserved word (for example, TYPE "CASE"
). Therefore, when a name is enclosed within quotation marks, the name enclosed within quotation marks must be in uppercase if the SQL identifier was created in a case-insensitive manner (for example, CREATE TYPE Case
). If an OTT-reserved word is used to refer to the name of a SQL identifier but is not enclosed within quotation marks, OTT reports a syntax error in the intype file.
See Also:
"Structure of the Intype File" for a more detailed specification of the structure of the intype file and the available optionsWhen OTT generates a C struct from a database type, the struct contains one element corresponding to each attribute of the object type. The data types of the attributes are mapped to types that are used in Oracle's object data types. The data types found in Oracle Database include a set of predefined, primitive types. These data types provide for the creation of user-defined types, such as object types and collections.
Oracle Database also includes a set of predefined types that are used to represent object type attributes in C structs. As an example, consider the object type definition in Example 15-6, and its corresponding OTT-generated struct declarations in Example 15-7.
Example 15-6 Object Type Definition for Employee
CREATE TYPE employee AS OBJECT ( name VARCHAR2(30), empno NUMBER, deptno NUMBER, hiredate DATE, salary$ NUMBER);
The OTT output, assuming CASE=LOWER
and no explicit mappings of type or attribute names, is shown in Example 15-7.
Example 15-7 OTT-Generated Struct Declarations
struct employee { OCIString * name; OCINumber empno; OCINumber deptno; OCIDate hiredate; OCINumber salary_; }; typedef struct emp_type emp_type; struct employee_ind { OCIInd _atomic; OCIInd name; OCIInd empno; OCIInd deptno; OCIInd hiredate; OCIInd salary_; } typedef struct employee_ind employee_ind;
The data types in the struct declarations—OCIString
, OCINumber
, OCIDate
, and OCIInd
—are used here to map the data types of the object type attributes. The NUMBER
data type of the empno
attribute maps to the OCINumber
data type, for example. These data types can also be used as the types of bind and define variables.
This section describes the mappings of Oracle object attribute types to C types generated by OTT. The "OTT Type Mapping Example" includes examples of many of these different mappings. Table 15-1 lists the mappings from types that you can use as attributes to object data types that are generated by OTT.
Table 15-1 Object Data Type Mappings for Object Type Attributes
Object Attribute Types | C Mapping |
---|---|
BFILE |
OCIBFileLocator* |
BLOB |
OCILobLocator * or OCIBlobLocator * |
CHAR(N), CHARACTER(N), NCHAR(N) |
OCIString * |
CLOB, NCLOB |
OCILobLocator * or OCIClobLocator * |
DATE |
OCIDate |
ANSI DATE |
OCIDateTime * |
TIMESTAMP, TIMESTAMP WITH TIME ZONE, TIMESTAMP WITH LOCAL TIME ZONE |
OCIDateTime * |
INTERVAL YEAR TO MONTH, INTERVAL DAY TO SECOND |
OCIInterval * |
DEC, DEC(N), DEC(N,N) |
OCINumber |
DECIMAL, DECIMAL(N), DECIMAL(N,N) |
OCINumber |
FLOAT, FLOAT(N), DOUBLE PRECISION |
OCINumber |
BINARY_FLOAT |
float |
BINARY_DOUBLE |
double |
INT, INTEGER, SMALLINT |
OCINumber |
Nested Object Type |
C name of the nested object type |
Nested Table |
OCITable * |
NUMBER, NUMBER(N), NUMBER(N,N) |
OCINumber |
NUMERIC, NUMERIC(N), NUMERIC(N,N) |
OCINumber |
RAW(N) |
OCIRaw * |
REAL |
OCINumber |
REF |
OCIRef * |
VARCHAR(N) |
OCIString * |
VARCHAR2(N), NVARCHAR2(N) |
OCIString * |
OCIArray * |
Note:
ForREF
, varray
, and nested table
types, OTT generates a typedef. The type declared in the typedef is then used as the type of the data member in the struct declaration. For an example, see "OTT Type Mapping Example".If an object type includes an attribute of a REF
or collection type, a typedef for the REF
or collection type is first generated. Then the struct declaration corresponding to the object type is generated. The struct includes an element whose type is a pointer to the REF
or collection type.
If an object type includes an attribute whose type is another object type, OTT first generates the nested type (if TRANSITIVE=TRUE
). It then maps the object type attribute to a nested struct of the type of the nested object type.
The Oracle C data types to which OTT maps non-object database attribute types are structures, which, except for OCIDate
, are opaque.
Example 15-9 demonstrates the various type mappings created by OTT when given the database types shown in Example 15-8.
Example 15-8 Object Type Definitions for the OTT Type Mapping Example
CREATE TYPE my_varray AS VARRAY(5) of integer; CREATE TYPE object_type AS OBJECT (object_name VARCHAR2(20)); CREATE TYPE my_table AS TABLE OF object_type; CREATE TYPE other_type AS OBJECT (object_number NUMBER); CREATE TYPE many_types AS OBJECT ( the_varchar VARCHAR2(30), the_char CHAR(3), the_blob BLOB, the_clob CLOB, the_object object_type, another_ref REF other_type, the_ref REF many_types, the_varray my_varray, the_table my_table, the_date DATE, the_num NUMBER, the_raw RAW(255));
The intype file includes the following:
CASE = LOWER TYPE many_types
OTT generates the C structs shown in Example 15-9.
Note:
Comments are provided in Example 15-9 to help explain the structs. These comments are not part of actual OTT output.Example 15-9 Various Type Mappings Created by OTT from Object Type Definitions
#ifndef MYFILENAME_ORACLE #define MYFILENAME_ORACLE #ifndef OCI_ORACLE #include <oci.h> #endif typedef OCIRef many_types_ref; typedef OCIRef object_type_ref; typedef OCIArray my_varray; /* used in many_types */ typedef OCITable my_table; /* used in many_types*/ typedef OCIRef other_type_ref; struct object_type /* used in many_types */ { OCIString * object_name; }; typedef struct object_type object_type; struct object_type_ind /*indicator struct for*/ { /*object_types*/ OCIInd _atomic; OCIInd object_name; }; typedef struct object_type_ind object_type_ind; struct many_types { OCIString * the_varchar; OCIString * the_char; OCIBlobLocator * the_blob; OCIClobLocator * the_clob; struct object_type the_object; other_type_ref * another_ref; many_types_ref * the_ref; my_varray * the_varray; my_table * the_table; OCIDate the_date; OCINumber the_num; OCIRaw * the_raw; }; typedef struct many_types many_types; struct many_types_ind /*indicator struct for*/ { /*many_types*/ OCIInd _atomic; OCIInd the_varchar; OCIInd the_char; OCIInd the_blob; OCIInd the_clob; struct object_type_ind the_object; /*nested*/ OCIInd another_ref; OCIInd the_ref; OCIInd the_varray; OCIInd the_table; OCIInd the_date; OCIInd the_num; OCIInd the_raw; }; typedef struct many_types_ind many_types_ind; #endif
Notice that although only one item was listed for translation in the intype file, two object types and two named collection types were translated. This is because the OTT parameter "TRANSITIVE" has the default value of TRUE
. As described in that section, when TRANSITIVE=TRUE
, OTT automatically translates any types that are used as attributes of a type being translated, to complete the translation of the listed type.
This is not the case for types that are only accessed by a pointer or REF
in an object type attribute. For example, although the many_types
type contains the attribute another_ref REF other_type
, a declaration of struct other_type
was not generated.
This example also illustrates how typedefs are used to declare varray, nested table
, and REF
types.
The typedefs occur near the beginning:
typedef OCIRef many_types_ref; typedef OCIRef object_type_ref; typedef OCIArray my_varray; typedef OCITable my_table; typedef OCIRef other_type_ref;
In the struct many_types
, the varray, nested table
, and REF
attributes are declared:
struct many_types { ... other_type_ref * another_ref; many_types_ref * the_ref; my_varray * the_varray; my_table * the_table; ... }
Each time OTT generates a C struct to represent a database object type, it also generates a corresponding NULL
indicator struct. When an object type is selected into a C struct, NULL
indicator information may be selected into a parallel struct.
For example, the following NULL
indicator struct was generated in Example 15-9.
struct many_types_ind { OCIInd _atomic; OCIInd the_varchar; OCIInd the_char; OCIInd the_blob; OCIInd the_clob; struct object_type_ind the_object; OCIInd another_ref; OCIInd the_ref; OCIInd the_varray; OCIInd the_table; OCIInd the_date; OCIInd the_num; OCIInd the_raw; }; typedef struct many_types_ind many_types_ind;
The layout of the NULL
struct is important. The first element in the struct (_atomic
) is the atomic null indicator. This value indicates the NULL
status for the object type as a whole. The atomic null indicator is followed by an indicator element corresponding to each element in the OTT-generated struct representing the object type.
Notice that when an object type contains another object type as part of its definition (in the preceding example it is the object_type
attribute), the indicator entry for that attribute is the NULL
indicator struct (object_type_ind
) corresponding to the nested object type (if TRANSITIVE=TRUE
).
The varrays
and nested tables
contain the NULL
information for their elements.
The data type for all other elements of a NULL
indicator struct is OCIInd
.
See Also:
"NULL Indicator Structure" for more information about atomic nullityTo support type inheritance of objects, OTT generates a C struct to represent an object subtype by declaring the inherited attributes in an encapsulated struct with the special name "_super
", before declaring the new attributes. Thus, for an object subtype that inherits from a supertype, the first element in the struct is named "_super
", followed by elements corresponding to each attribute of the subtype. The type of the element named "_super
" is the name of the supertype.
For example, suppose that you have a type Person_t
, with subtype Student_t
and subtype Employee_t
, as shown in Example 15-10.
Example 15-10 Object Type and Subtype Definitions
CREATE TYPE Person_t AS OBJECT ( ssn NUMBER, name VARCHAR2(30), address VARCHAR2(100)) NOT FINAL; CREATE TYPE Student_t UNDER Person_t ( deptid NUMBER, major VARCHAR2(30)) NOT FINAL; CREATE TYPE Employee_t UNDER Person_t ( empid NUMBER, mgr VARCHAR2(30));
Suppose that you also have an intype file with the content shown in Example 15-11.
Then, OTT generates the C structs for Person_t
, Student_t
, and Employee_t
, and their NULL
indicator structs, as shown in Example 15-12.
Example 15-12 OTT Generates C Structs for the Types and Null Indicator Structs
#ifndef MYFILENAME_ORACLE #define MYFILENAME_ORACLE #ifndef OCI_ORACLE #include <oci.h> #endif typedef OCIRef EMPLOYEE_T_ref; typedef OCIRef STUDENT_T_ref; typedef OCIRef PERSON_T_ref; struct PERSON_T { OCINumber SSN; OCIString * NAME; OCIString * ADDRESS; }; typedef struct PERSON_T PERSON_T; struct PERSON_T_ind { OCIInd _atomic; OCIInd SSN; OCIInd NAME; OCIInd ADDRESS; }; typedef struct PERSON_T_ind PERSON_T_ind; struct EMPLOYEE_T { PERSON_T_ind; OCINumber EMPID; OCIString * MGR; }; typedef struct EMPLOYEE_T EMPLOYEE_T; struct EMPLOYEE_T_ind { PERSON_T _super; OCIInd EMPID; OCIInd MGR; }; typedef struct EMPLOYEE_T_ind EMPLOYEE_T_ind; struct STUDENT_T { PERSON_T _super; OCINumber DEPTID; OCIString * MAJOR; }; typedef struct STUDENT_T STUDENT_T; struct STUDENT_T_ind { PERSON_T _super; OCIInd DEPTID; OCIInd MAJOR; }; typedef struct STUDENT_T_ind STUDENT_T_ind; #endif
The preceding C mapping convention allows simple upcasting from an instance of a subtype to an instance of a supertype in C to work properly. For example:
STUDENT_T *stu_ptr = some_ptr; /* some STUDENT_T instance */ PERSON_T *pers_ptr = (PERSON_T *)stu_ptr; /* upcasting */
The NULL
indicator structs are generated similarly. Note that for the supertype Person_t
NULL
indicator struct, the first element is "_atomic
", and that for the subtypes Employee_t
and Student_t
NULL
indicator structs, the first element is "_super
" (no atomic element is generated for subtypes).
For attributes of NOT FINAL
types (potentially substitutable), the embedded attribute is represented as a pointer.
Consider a type Book_t
created as follows:
CREATE TYPE Book_t AS OBJECT ( title VARCHAR2(30), author Person_t /* substitutable */);
The corresponding C struct generated by OTT contains a pointer to Person_t
:
struct Book_t { OCIString *title; Person_t *author; /* pointer to Person_t struct */ }
The NULL
indicator struct corresponding to the preceding type is as follows:
struct Book_t_ind { OCIInd _atomic; OCIInd title; OCIInd author; }
Note that the NULL
indicator struct corresponding to the author
attribute can be obtained from the author
object itself. See OCIObjectGetInd().
If a type is defined to be FINAL
, it cannot have any subtypes. An attribute of a FINAL
type is therefore not substitutable. In such cases, the mapping is as before: the attribute struct is inline. Now, if the type is altered and defined to be NOT FINAL
, the mapping must change. The new mapping is generated by running OTT again.
The outtype file is named on the OTT command line. When OTT generates the C header file, it also writes the results of the translation into the outtype file. This file contains an entry for each of the types that is translated, including its version string, and the header file to which its C representation was written.
The outtype file from one OTT run can be used as the intype file for a subsequent OTT invocation.
For example, suppose that you have a simple intype file, as shown in Example 15-13, which was used in Example 15-5.
Example 15-13 Contents of an Intype File
CASE=LOWER TYPE employee TRANSLATE SALARY$ AS salary DEPTNO AS department TYPE ADDRESS TYPE item TYPE "Person" TYPE PURCHASE_ORDER AS p_o
The user has chosen to specify the case for the OTT-generated C identifiers, and has provided a list of types to be translated. In two of these types, naming conventions are specified.
Example 15-14 shows what the outtype file might look like after running OTT.
Example 15-14 Contents of the Outtype File After Running OTT
CASE = LOWER TYPE EMPLOYEE AS employee VERSION = "$8.0" HFILE = demo.h TRANSLATE SALARY$ AS salary DEPTNO AS department TYPE ADDRESS AS ADDRESS VERSION = "$8.0" HFILE = demo.h TYPE ITEM AS item VERSION = "$8.0" HFILE = demo.h TYPE "Person" AS Person VERSION = "$8.0" HFILE = demo.h TYPE PURCHASE_ORDER AS p_o VERSION = "$8.0" HFILE = demo.h
When examining the contents of the outtype file, you might discover types listed that were not included in the intype specification. For example, suppose that the intype file only specified that the person
type was to be translated as follows:
CASE = LOWER TYPE PERSON
However, because the definition of the person
type includes an attribute of type address
, the outtype file includes entries for both PERSON
and ADDRESS
. The person
type cannot be translated completely without first translating address
.
When the parameter TRANSITIVE
has been set to TRUE
(it is the default), OTT analyzes the types in the intype file for type dependencies before performing the translation, and translates other types as necessary.
An OCI application that accesses objects in an Oracle server can use C header and implementation files that have been generated by OTT. The header file is incorporated into the OCI code with an #include
statement.
Once the header file has been included, the OCI application can access and manipulate object data in the host language format.
Figure 15-1 shows the steps involved in using OTT with OCI for the simplest applications:
SQL is used to create type definitions in the database.
OTT generates a header file containing C representations of object types and named collection types. It also generates an implementation file, as named with the INITFILE
option.
The application is written. User-written code in the OCI application declares and calls the INITFUNC
function.
The header file is included in an OCI source code file.
The OCI application, including the implementation file generated by OTT, is compiled and linked with the OCI libraries.
The OCI executable is run against the Oracle database.
Within the application, the OCI program can perform bind and define operations using program variables declared to be of types that appear in the OTT-generated header file.
For example, an application might fetch a REF
to an object using a SQL SELECT
statement and then pin that object using the appropriate OCI function. Once the object has been pinned, its attribute data can be accessed and manipulated with other OCI functions.
OCI includes a set of data type mapping and manipulation functions that are specifically designed to work on attributes of object types and named collection types.
The following are examples of the available functions:
OCIStringSize() gets the size of an OCIString
string.
OCINumberAdd() adds two OCINumber
numbers together.
OCILobIsEqual() compares two LOB locators for equality.
OCIRawPtr() gets a pointer to an OCIRaw
raw data type.
OCICollAppend() appends an element to a collection type (OCIArray
or OCITable
).
OCITableFirst() returns the index for the first existing element of a nested table (OCITable
).
OCIRefIsNull() tests if a REF
(OCIRef
) is NULL
.
These functions are described in detail in other chapters of this guide.
OTT generates a C initialization function if requested. The initialization function tells the environment, for each object type used in the program, which version of the type is used. You can specify a name for the initialization function when you invoke OTT with the INITFUNC
option, or you can allow OTT to select a default name based on the name of the implementation file (INITFILE
) containing the function.
The initialization function takes two arguments; an environment handle pointer and an error handle pointer. There is typically a single initialization function, but this is not required. If a program has several separately compiled pieces requiring different types, you may want to execute OTT separately for each piece, requiring for each piece, one initialization file containing an initialization function.
After an environment handle is created by an explicit OCI object call (for example, by calling OCIEnvCreate()) you must also explicitly call the initialization functions. All the initialization functions must be called for each explicitly created environment handle. This gives each handle access to all the Oracle data types used in the entire program.
If an environment handle is implicitly created by embedded SQL statements, such as EXEC SQL CONTEXT USE
and EXEC SQL CONNECT
, the handle is initialized implicitly, and the initialization functions need not be called. This is only relevant when Pro*C/C++ is being combined with OCI applications.
The following example shows an initialization function.
Suppose that you have an intype file, ex2c.typ
, containing the content shown in Example 15-15.
Then you invoke OTT from the command line and specify the initialization function, as shown in Example 15-16.
Example 15-16 Invoking OTT and Specifying the Initialization Function
ott userid=bren intype=ex2c outtype=ex2co hfile=ex2ch.h initfile=ex2cv.c
OTT generates the ex2cv.c
file with the contents shown in Example 15-17.
Example 15-17 Content of an OTT-Generated File Named ex2cv.c
#ifndef OCI_ORACLE #include <oci.h> #endif sword ex2cv(OCIEnv *env, OCIError *err) { sword status = OCITypeVTInit(env, err); if (status == OCI_SUCCESS) status = OCITypeVTInsert(env, err, "BREN", 5, "PERSON", 6, "$8.0", 4); if (status == OCI_SUCCESS) status = OCITypeVTInsert(env, err, "BREN", 5, "ADDRESS", 7, "$8.0", 4); return status; }
The function ex2cv()
creates the type version table and inserts the types BREN.PERSON
and BREN.ADDRESS
.
If a program explicitly creates an environment handle, all the initialization functions must be generated, compiled, and linked, because they must be called for each explicitly created handle. If a program does not explicitly create any environment handles, initialization functions are not required.
A program that uses an OTT-generated header file must also use the initialization function generated at the same time. When a header file is generated by OTT and an environment handle is explicitly created in the program, then the implementation file must also be compiled and linked into the executable.
The C initialization function supplies version information about the types processed by OTT. It adds to the type-version table the name and version identifier of every OTT-processed object data type.
The type-version table is used by the Oracle database type manager to determine which version of a type a particular program uses. Different initialization functions generated by OTT at different times can add some of the same types to the type version table. When a type is added more than once, Oracle Database ensures that the same version of the type is registered each time.
It is the OCI programmer's responsibility to declare a function prototype for the initialization function, and to call the function.
Note:
In the current release of Oracle Database, each type has only one version. Initialization of the type version table is required only for compatibility with future releases of Oracle Database.Parameters that can appear on the OTT command line or in a CONFIG
file control the behavior of OTT. Certain parameters can also appear in the intype file.
This section provides detailed information about the following topics:
The following conventions are used in this section to describe OTT syntax:
Italic strings are variables or parameters to be supplied by the user.
Strings in UPPERCASE are entered as shown, except that case is not significant.
OTT keywords are listed in a lowercase monospaced font in examples and headings, but are printed in uppercase in text to make them more distinctive.
Square brackets [...] enclose optional items.
An ellipsis (...) immediately following an item (or items enclosed in brackets) means that the item can be repeated any number of times.
Punctuation symbols other than those described earlier are entered as shown. These include ".", "@", and so on.
The OTT command-line interface is used when explicitly invoking OTT to translate database types into C structs. This is always required when you develop OCI applications that use objects.
An OTT command-line statement consists of the keyword OTT
, followed by a list of OTT parameters.
The parameters that can appear on an OTT command-line statement are as follows:
[userid=username/password[@db_name]] [intype=filename] outtype=filename code=C|ANSI_C|KR_C [hfile=filename] [errtype=filename] [config=filename] [initfile=filename] [initfunc=filename] [case=SAME|LOWER|UPPER|OPPOSITE] [schema_name=ALWAYS|IF_NEEDED|FROM_INTYPE] [transitive=TRUE|FALSE] [URL=url]
Note:
Generally, the order of the parameters following theOTT
command does not matter. Only the OUTTYPE
and CODE
parameters are always required.The HFILE
parameter is almost always used. If omitted from the command line, HFILE
must be specified individually for each type in the intype file. If OTT determines that a type not listed in the intype file must be translated, an error is reported. Therefore, it is safe to omit the HFILE
parameter only if the intype file was previously generated as an OTT outtype file.
If the intype file is omitted, the entire schema is translated. See the parameter descriptions in "OTT Parameters" for more information.
The following is an example of an OTT command-line statement (you are prompted for the password):
OTT userid=marc intype=in.typ outtype=out.typ code=c hfile=demo.h\ errtype=demo.tls case=lower
The following sections describe each of the OTT command-line parameters.
Enter parameters on the OTT command line using the following format:
parameter=value
In this format, parameter
is the literal parameter string and value
is a valid parameter setting. The literal parameter string is not case-sensitive.
Separate command-line parameters by using either spaces or tabs.
Parameters can also appear within a configuration file, but, in that case, no whitespace is permitted within a line, and each parameter must appear on a separate line. Additionally, the parameters CASE,
HFILE,INITFUNC
, and INITFILE
can appear in the intype file.
The USERID
parameter specifies the database user name, password, and optional database name (Oracle Net Services database specification string). If the database name is omitted, the default database is assumed. The syntax of this parameter is:
userid=username/password[@db_name]
The USERID
parameter is optional. If it is omitted, OTT automatically attempts to connect to the default database as user OPS$username
, where username
is the user's operating system user name. If this is the first parameter, "USERID=
" and the password and the database name can be omitted, as shown here:
OTT username ...
For security purposes, when you enter only the user name you are prompted for the rest of the entry.
The INTYPE
parameter specifies the name of the file from which to read the list of object type specifications. OTT translates each type in the list.
The syntax for this parameter is
intype=filename
"INTYPE=
" can be omitted if USERID
and INTYPE
are the first two parameters, in that order, and "USERID=
" is omitted. If the INTYPE
parameter is not specified, all types in the user's schema are translated.
OTT username filename...
The intype file can be thought of as a makefile for type declarations. It lists the types for which C struct declarations are needed.
See Also:
"Structure of the Intype File" for a description of the format of the intype fileIf the file name on the command line or in the intype file does not include an extension, an operating system-specific extension such as "TYP
" or ".typ
" is added.
The OUTTYPE
parameter specifies the name of a file into which OTT writes type information for all the object data types it processes. This includes all types explicitly named in the intype file, and can include additional types that are translated because they are used in the declarations of other types that must be translated (if TRANSITIVE=TRUE
). This file must be used as an intype file in a future invocation of OTT.
outtype=filename
If the INTYPE
and OUTTYPE
parameters refer to the same file, the new INTYPE
parameter information replaces the old information in the intype file. This provides a convenient way for the same intype file to be used repeatedly in the cycle of altering types, generating type declarations, editing source code, precompiling, compiling, and debugging.
The parameter OUTTYPE
must be specified.
If the file name on the command line or in the outtype file does not include an extension, an operating system-specific extension such as "TYP
" or ".typ
" is added.
This is the desired host language for OTT output, which is specified as CODE=C, CODE=KR_C,
or CODE=ANSI_C
. "CODE=C
" is equivalent to "CODE=ANSI_C
".
CODE=C|KR_C|ANSI_C
There is no default value for this parameter; it must be supplied.
The INITFILE
parameter specifies the name of the file where the OTT-generated initialization file is to be written. The initialization function is not generated if this parameter is omitted.
For Pro*C/C++ programs, the INITFILE
is not necessary, because the SQLLIB runtime library performs the necessary initializations. An OCI program user must compile and link the INITFILE
files, and must call the initialization file functions when an environment handle is created.
If the file name of an INITFILE
on the command line or in the intype file does not include an extension, an operating system-specific extension such as "C
" or ".c
" is added.
initfile=filename
The INITFUNC
parameter is only used in OCI programs. It specifies the name of the initialization function generated by OTT. If this parameter is omitted, the name of the initialization function is derived from the name of the INITFILE
.
initfunc=filename
The HFILE
parameter specifies the name of the include (.h
) file to be generated by OTT for the declarations of types that are mentioned in the intype file but whose include files are not specified there. This parameter is required unless the include file for each type is specified individually in the intype file. This parameter is also required if a type not mentioned in the intype file must be generated because other types require it, and these other types are declared in two or more different files, and TRANSITIVE=TRUE
.
If the file name of an HFILE
on the command line or in the intype file does not include an extension, an operating system-specific extension such as "H
" or ".h
" is added.
hfile=filename
The CONFIG
parameter specifies the name of the OTT configuration file, which lists commonly used parameter specifications. Parameter specifications are also read from a system configuration file in an operating system-dependent location. All remaining parameter specifications must appear on the command line, or in the intype file.
config=filename
Note:
ACONFIG
parameter is not allowed in the CONFIG
file.If the ERRTYPE
parameter is supplied, OTT writes a listing of the intype file to the ERRTYPE
file, along with all informational and error messages. Informational and error messages are sent to the standard output whether ERRTYPE
parameter is specified or not.
Essentially, the ERRTYPE
file is a copy of the intype file with error messages added. In most cases, an error message includes a pointer to the text that caused the error.
If the file name of an ERRTYPE
on the command line or in the intype file does not include an extension, an operating system-specific extension such as "TLS
" or ".tls
" is added.
errtype=filename
This CASE
parameter affects the case of certain C identifiers generated by OTT. The possible values of CASE
are SAME, LOWER, UPPER
, and OPPOSITE
. If CASE = SAME
, the case of letters is not changed when converting database type and attribute names to C identifiers. If CASE=LOWER
, all uppercase letters are converted to lowercase. If CASE=UPPER
, all lowercase letters are converted to uppercase. If CASE=OPPOSITE
, all uppercase letters are converted to lowercase, and vice versa.
CASE=[SAME|LOWER|UPPER|OPPOSITE]
This option affects only those identifiers (attributes or types not explicitly listed) not mentioned in the intype file. Case conversion occurs after a legal identifier has been generated.
Note that the case of the C struct identifier for a type specifically mentioned in the INTYPE
parameter option is the same as its case in the intype file. For example, if the intype file includes the following line:
TYPE Worker
Then OTT generates the following line:
struct Worker {...};
However, suppose that the intype file is written as follows:
TYPE wOrKeR
Then OTT generates the following line, following the case specified in the intype file.
struct wOrKeR {...};
Case-insensitive SQL identifiers not mentioned in the intype file appear in uppercase if CASE=SAME
, and in lowercase if CASE=OPPOSITE
. A SQL identifier is case-insensitive if it was not enclosed in quotation marks when it was declared.
The SCHEMA_NAMES
parameter offers control in qualifying the database name of a type from the default schema with a schema name in the outtype file. The outtype file generated by OTT contains information about the types processed by OTT, including the type names.
See Also:
"SCHEMA_NAMES Usage"The TRANSITIVE
parameter takes the values TRUE
(the default) or FALSE
. It indicates whether type dependencies not explicitly listed in the intype file are to be translated or not.
If TRANSITIVE=TRUE
is specified, then types needed by other types but not mentioned in the intype file are generated.
If TRANSITIVE=FALSE
is specified, then types not mentioned in the intype file are not generated, even if they were used as attribute types of other generated types.
For the URL
parameter, OTT uses JDBC (Java Database Connectivity), the Java interface for connecting to the database. The default value of parameter URL
is:
URL=jdbc:oracle:oci8:@
The OCI8 driver is for client-side use with an Oracle Database installation.
To specify the JDBC Thin driver (the Java driver for client-side use without an Oracle Database installation), use the following URL
parameter syntax:
URL=jdbc:oracle:thin:@host:port:sid
The host
is the name of the host on which the database is running, port
is the port number, and sid
is the Oracle SID.
OTT parameters can appear on the command line, in a CONFIG
file named on the command line, or both. Some parameters are also allowed in the intype file.
OTT is invoked as follows:
OTT username/password parameters
If one of the parameters on the command line is the following, then additional parameters are read from the configuration file filename
:
config=filename
In addition, parameters are also read from a default configuration file in an operating system-dependent location. This file must exist, but can be empty. Parameters in a configuration file must appear one in each line, with no whitespace on the line.
If OTT is executed without any arguments, an online parameter reference is displayed.
The types for OTT to translate are named in the file specified by the INTYPE
parameter. The parameters CASE, INITFILE, INITFUNC
, and HFILE
can also appear in the intype file. The outtype files generated by OTT include the CASE
parameter, and include the INITFILE
, and INITFUNC
parameters if an initialization file was generated. The outtype file specifies the HFILE
individually for each type.
The case of the OTT command is operating system-dependent.
The intype and outtype files list the types translated by OTT, and provide all the information needed to determine how a type or attribute name is translated to a legal C identifier. These files contain one or more type specifications. These files also can contain specifications of the following options:
CASE
HFILE
INITFILE
INITFUNC
If the CASE, INITFILE
, or INITFUNC
options are present, they must precede any type specifications. If these options appear both on the command line and in the intype file, the value on the command line is used.
See Also:
"Outtype File" for an example of a simple user-defined intype file, and of the full outtype file that OTT generates from itA type specification in the intype file names an object data type that is to be translated. A type specification in the outtype file names an object data type that has been translated.
TYPE employee TRANSLATE SALARY$ AS salary DEPTNO AS department TYPE ADDRESS TYPE PURCHASE_ORDER AS p_o
The structure of a type specification is as follows, where [] indicates optional inputs inside:
TYPE type_name [AS type_identifier] [VERSION [=] version_string] [HFILE [=] hfile_name] [TRANSLATE{member_name [AS identifier]}...]
The syntax of type_name
is:
[schema_name.]type_name
The schema_name
is the name of the schema that owns the given object data type, and type_name
is the name of the type. The default schema is that of the user running OTT. The default database is the local database.
The components of a type specification are described as follows:
type_name
is the name of an Oracle Database object data type.
type_identifier
is the C identifier used to represent the type. If type_identifier
is omitted, the default name mapping algorithm is used.
version_string
is the version string of the type that was used when the code was generated by a previous invocation of OTT. The version string is generated by OTT and written to the outtype file, which can be used as the intype file when OTT is executed later. The version string does not affect the operation of OTT, but is eventually used to select the version of the object data type that should be used in the running program.
See Also:
"Default Name Mapping"hfile_name
is the name of the header file in which the declarations of the corresponding struct or class appear. If hfile_name
is omitted, the file named by the command-line HFILE
parameter is used if a declaration is generated.
member_name
is the name of an attribute (data member) that is to be translated to the identifier
.
identifier
is the C identifier used to represent the attribute in the user program. Identifiers can be specified in this way for any number of attributes. The default name mapping algorithm is used for the attributes that are not mentioned.
An object data type may need to be translated for one of two reasons:
It appears in the intype file.
It is required to declare another type that must be translated, and TRANSITIVE=TRUE
.
If a type that is not mentioned explicitly is required by types declared in exactly one file, OTT writes the translation of the required type to the same file or files as the explicitly declared types that require it.
If a type that is not mentioned explicitly is required by types declared in two or more different files, OTT writes the translation of the required type to the global HFILE
file.
Every HFILE
generated by OTT uses #include
directives to include other necessary files and #define
directives to define a symbol constructed from the name of the file, which can be used to determine if the HFILE
has been included. Consider, for example, a database with the types shown in Example 15-18.
Example 15-18 Object Type Definition to Demonstrate How OTT Generates Include Files
create type px1 AS OBJECT (col1 number, col2 integer); create type px2 AS OBJECT (col1 px1); create type px3 AS OBJECT (col1 px1);
The intype file content is shown in Example 15-19.
Example 15-19 Content of the Intype File
CASE=lower type pxl hfile tott95a.h type px3 hfile tott95b.h
If you invoke OTT with the command shown in Example 15-20, then it generates the header files shown in Example 15-21 and Example 15-22.
The content of the header file tott95b.h
is shown in Example 15-21.
Example 15-21 Content of the Header File tott95b.h
#ifndef TOTT95B_ORACLE #define TOTT95B_ORACLE #ifndef OCI_ORACLE #include <oci.h> #endif #ifndef TOTT95A_ORACLE #include "tott95a.h" #endif typedef OCIRef px3_ref; struct px3 { struct px1 col1; }; typedef struct px3 px3; struct px3_ind { OCIInd _atomic; struct px1_ind col1 }; typedef struct px3_ind px3_ind; #endif
The content of the header file tott95a.h is shown in Example 15-22.
Example 15-22 Content of the Header File tott95a.h
#ifndef TOTT95A_ORACLE #define TOTT95A_ORACLE #ifndef OCI_ORACLE #include <oci.h> #endif typedef OCIRef px1_ref; struct px1 { OCINumber col1; OCINumber col2; } typedef struct px1 px1; struct px1_ind { OCIInd _atomic; OCIInd col1; OCIInd col2; } typedef struct px1_ind px1_ind; #endif
In Example 15-21, the symbol TOTT95B_ORACLE
is defined first so that the programmer can conditionally include tott95b.h
without having to worry whether tott95b.h
depends on the include file using the construct, as shown in Example 15-23.
Example 15-23 Construct to Use to Conditionally Include the Header File tott95b.h
#ifndef TOTT95B_ORACLE #include "tott95b.h" #endif
Using this technique, the programmer can include tott95b.h
from some file, say foo.h
, without having to know whether some other file included by foo.h
also includes tott95b.h
.
After the definition of the symbol TOTT95B_ORACLE
, the file oci.h
is included. Every HFILE
generated by OTT includes oci.h
, which contains type and function declarations that the Pro*C/C++ or OCI programmer can use. This is the only case in which OTT uses angle brackets in an #include
directive.
Next, the file tott95a.h
is included. This file is included because it contains the declaration of "struct px1
", which tott95b.h
requires. When the user's intype file requests that type declarations be written to more than one file, OTT determines which other files each HFILE
must include, and generates the necessary #includes
directives.
Note that OTT uses quotation marks in this #include
directive. When a program including tott95b.h
is compiled, the search for tott95a.h
begins where the source program was found, and thereafter follows an implementation-defined search rule. If tott95a.h
cannot be found in this way, a complete file name (for example, a Linux or UNIX absolute path name beginning with /) should be used in the intype file to specify the location of tott95a.h
.
This parameter affects whether the name of a type from the default schema to which OTT is connected is qualified with a schema name in the outtype file.
The name of a type from a schema other than the default schema is always qualified with a schema name in the outtype file.
The schema name, or its absence, determines in which schema the type is found during program execution.
There are three settings:
schema_names=ALWAYS
(default)
All type names in the outtype file are qualified with a schema name.
schema_names=IF_NEEDED
The type names in the outtype file that belong to the default schema are not qualified with a schema name. As always, type names belonging to other schemas are qualified with the schema name.
schema_names=FROM_INTYPE
A type mentioned in the intype file is qualified with a schema name in the outtype file if, and only if, it was qualified with a schema name in the intype file. A type in the default schema that is not mentioned in the intype file but that must be generated because of type dependencies is written with a schema name only if the first type encountered by OTT that depends on it was written with a schema name. However, a type that is not in the default schema to which OTT is connected is always written with an explicit schema name.
The outtype file generated by OTT is an input parameter to Pro*C/C++. From the point of view of Pro*C/C++, it is the Pro*C/C++ intype file. This file matches database type names to C struct names. This information is used at runtime to ensure that the correct database type is selected into the struct. If a type appears with a schema name in the outtype file (Pro*C/C++ intype file), the type is found in the named schema during program execution. If the type appears without a schema name, the type is found in the default schema to which the program connects, which can be different from the default schema that OTT used.
Suppose that SCHEMA_NAMES
is set to FROM_INTYPE
, and the intype file reads as follows:
TYPE Person TYPE david.Dept TYPE sam.Company
Then the Pro*C/C++ application that uses the OTT-generated structs uses the types sam.Company
, david.Dept
, and Person
. Using Person
without a schema name refers to the Person
type in the schema to which the application is connected.
If OTT and the application both connect to schema david
, the application uses the same type (david.Person
) that OTT used. If OTT connected to schema david
but the application connects to schema jana
, the application uses the type jana.Person
. This behavior is appropriate only if the same "CREATE TYPE Person
" statement has been executed in schema david
and schema jana
.
In contrast, the application uses type david.Dept
regardless of to which schema the application is connected. If this is the behavior that you want, be sure to include schema names with your type names in the intype file.
In some cases, OTT translates a type that the user did not explicitly name. For example, consider the following SQL declarations:
CREATE TYPE Address AS OBJECT ( street VARCHAR2(40), city VARCHAR(30), state CHAR(2), zip_code CHAR(10) ); CREATE TYPE Person AS OBJECT ( name CHAR(20), age NUMBER, addr ADDRESS );
Now suppose that OTT connects to schema david
, SCHEMA_NAMES=FROM_INTYPE
is specified, and the user's intype files include either TYPE Person
or TYPE david.Person
.
However, the intype file does not mention the type david.Address
, which is used as a nested object type in type david.Person
. If "TYPE david.Person
" appeared in the intype file, then "TYPE david.Person
" and "TYPE david.Address
" appear in the outtype file. If "Type Person
" appeared in the intype file, then "TYPE Person
" and "TYPE Address
" appear in the outtype file.
If the david.Address
type is embedded in several types translated by OTT, but is not explicitly mentioned in the intype file, the decision of whether to use a schema name is made the first time OTT encounters the embedded david.Address
type. If, for some reason, the user wants type david.Address
to have a schema name but does not want type Person
to have one, the user should explicitly specify the following in the intype file:
TYPE david.Address
In the usual case in which each type is declared in a single schema, it is safest for the user to qualify all type names with schema names in the intype file.
When OTT creates a C identifier name for an object type or attribute, it translates the name from the database character set to a legal C identifier. First, the name is translated from the database character set to the character set used by OTT. Next, if a translation of the resulting name is supplied in the intype file, that translation is used. Otherwise, OTT translates the name character-by-character to the compiler character set, applying the CASE
option. The following describes this process in more detail.
When OTT reads the name of a database entity, the name is automatically translated from the database character set to the character set used by OTT. In order for OTT to read the name of the database entity successfully, all the characters of the name must be found in the OTT character set, although a character can have different encodings in the two character sets.
The easiest way to guarantee that the character set used by OTT contains all the necessary characters is to make it the same as the database character set. Note, however, that the OTT character set must be a superset of the compiler character set. That is, if the compiler character set is 7-bit ASCII, the OTT character set must include 7-bit ASCII as a subset, and if the compiler character set is 7-bit EBCDIC, the OTT character set must include 7-bit EBCDIC as a subset. The user specifies the character set that OTT uses by setting the NLS_LANG
environment variable, or by some other operating system-specific mechanism.
Once OTT has read the name of a database entity, it translates the name from the character set used by OTT to the compiler's character set. If a translation of the name appears in the intype file, OTT uses that translation.
Otherwise, OTT attempts to translate the name by using the following steps:
If the OTT character set is a multibyte character set, all multibyte characters in the name that have single-byte equivalents are converted to those single-byte equivalents.
The name is converted from the OTT character set to the compiler character set. The compiler character set is a single-byte character set such as US7ASCII.
The case of letters is set according to the CASE
option in effect, and any character that is not legal in a C identifier, or that has no translation in the compiler character set, is replaced by an underscore. If at least one character is replaced by an underscore, OTT gives a warning message. If all the characters in a name are replaced by underscores, OTT gives an error message.
Character-by-character name translation does not alter underscores, digits, or single-byte letters that appear in the compiler character set, so legal C identifiers are not altered.
Name translation can, for example, translate accented single-byte characters such as "o" with an umlaut or "a" with an accent grave to "o" or "a", and can translate a multibyte letter to its single-byte equivalent. Name translation typically fails if the name contains multibyte characters that lack single-byte equivalents. In this case, the user must specify name translations in the intype file.
OTT does not detect a naming clash caused by two or more database identifiers being mapped to the same C name, nor does it detect a naming problem where a database identifier is mapped to a C keyword.
Currently, OTT determines if two files are the same by comparing the file names provided by the user on the command line or in the intype file. But one potential problem can occur when OTT needs to know if two file names refer to the same file. For example, if the OTT-generated file foo.h
requires a type declaration written to foo1.h
, and another type declaration written to /private/elias/foo1.h
, OTT should generate one #include
directive if the two files are the same, and two #includes
directives if the files are different. In practice, though, it would conclude that the two files are different, and would generate two #includes
directives, as follows:
#ifndef FOO1_ORACLE #include "foo1.h" #endif #ifndef FOO1_ORACLE #include "/private/elias/foo1.h" #endif
If foo1.h
and /private/elias/foo1.h
are different files, only the first one is included. If foo1.h
and /private/elias/foo1.h
are the same file, a redundant #include
directive is written.
Therefore, if a file is mentioned several times on the command line or in the intype file, each mention of the file should use exactly the same file name.