9
Object-Relational Datatypes

The OCI datatype mapping and manipulation functions provide OCI programs with the ability to manipulate instances of Oracle predefined datatypes in a C application. This chapter discusses those functions, and also includes information about how object types are stored in the database. For information about bind and define operations using the Oracle8 C datatypes, refer to Chapter 10, "Binding and Defining in Object Applications".

The following topics are covered in this chapter:

• Overview
• Mapping Oracle8 Datatypes to C
• Manipulating C Datatypes With OCI
• Date (OCIDate)
• Number (OCINumber)
• Fixed or Variable-Length String (OCIString)
• Raw (OCIRaw)
• Collections (OCITable, OCIArray, OCIColl, OCIIter)
• REF (OCIRef)
• Object Type Information Storage and Access

Note: The functionality described in this chapter is only available if you have purchased the Oracle8 Enterprise Edition with the Objects Option.

Overview

The OCI datatype mapping and manipulation functions provide the ability to manipulate instances of predefined Oracle8 C datatypes. These datatypes are used to represent the attributes of user-defined datatypes, including object types in Oracle8.

Each group of functions within the OCI is distinguished by a particular naming convention. The datatype mapping and manipulation functions, for example, can be easily recognized because the function names start with the prefix "OCI", followed by the name of a datatype, as in OCIDateFromText() and OCIRawSize(). As will be explained later, the names can be further broken down into function groups that operate on a particular type of data.

Additionally, the predefined Oracle8 C types on which these functions operate are also distinguished by names which begin with the prefix "OCI", as in OCIDate or OCIString.

The datatype mapping and manipulation functions are used when an application needs to manipulate, bind, or define attributes of objects that are stored in an Oracle8 database, or which have been retrieved by a SQL query. Retrieved objects are stored in the client-side object cache, as was described in Chapter 6.

This chapter describes the purpose and structure of each of the datatypes that can be manipulated by the OCI datatype mapping and manipulation functions. It also summarizes the different function groups, and gives lists of available functions and their purposes.

This chapter also provides information about how to use these datatypes in bind and define operations within an OCI application.

These functions are valid only when an OCI application is running in object mode. For information about initializing the OCI in object mode, and creating an OCI application that accesses and manipulates objects, refer to the section "Initializing Environment and Object Cache" on page 8-10.

For detailed information about object types, attributes, and collection datatypes, refer to Oracle8 Concepts.

Mapping Oracle8 Datatypes to C

Oracle8 provides a rich set of predefined datatypes with which you can create tables and specify user-defined datatypes (including object types). Object types extend the functionality of Oracle8 by allowing you to create datatypes that precisely model the types of data with which they work. This can provide increased efficiency and ease-of-use for programmers who are accessing the data.

Database tables and object types are based upon the datatypes supplied by Oracle. These tables and types are created with SQL statements and stored using a specific set of Oracle internal datatypes, like VARCHAR2 or NUMBER. For example, the following SQL statements create a user-defined address datatype and an object table to store instances of that type:

CREATE TYPE address AS OBJECT
(street1        varchar2(50),
street2         varchar2(50),
city                varchar2(30),
state              char(2),
zip                  number(5));
CREATE TABLE address_table OF address;

The new address type could also be used to create a regular table with an object column:

CREATE TABLE employees
(name                  varchar2(30),
birthday            date,
home_addr          address);

An OCI application can manipulate information in the name and birthday columns of the employees table using straightforward bind and define operations in association with SQL statements. Accessing information stored as attributes of objects requires some extra steps.

The OCI application first needs a way to represent the objects in a C-language format. This is accomplished by using the Object Type Translator (OTT) to generate C struct representations of user-defined types. The elements of these structs have datatypes that represent C language mappings of Oracle8 datatypes. The following table lists the available Oracle types you can use as object attribute types and their C mappings:

Table 9-1 C Language Mappings of Object Type Attributes

Attribute Type	C Mapping
VARCHAR2(N)	OCIString *
VARCHAR(N)	OCIString *
CHAR(N), CHARACTER(N)	OCIString *
NUMBER, NUMBER(N), NUMBER(N,N)	OCINumber
NUMERIC, NUMERIC(N), NUMERIC(N,N)	OCINumber
REAL	OCINumber
INT, INTEGER, SMALLINT	OCINumber
FLOAT, FLOAT(N), DOUBLE PRECISION	OCINumber
DEC, DEC(N), DEC(N,N)	OCINumber
DECIMAL, DECIMAL(N), DECIMAL(N,N)	OCINumber
DATE	OCIDate
BLOB	OCILobLocator * or OCIBlobLocator *
CLOB	OCILobLocator * or OCIClobLocator *
BFILE	OCIBFileLocator*
REF	OCIRef *
RAW(N)	OCIRaw *
VARRAY	OCIArray *
Nested Table	OCITable *

An additional C type, OCIInd, is used to represent null indicator information corresponding to attributes of object types.

See Also: For more information and examples regarding the use of the OTT, refer to Chapter 12.

OCI Type Mapping Methodology

Oracle followed a distinct design philosophy when specifying the mappings of Oracle predefined types. The current system has the following benefits and advantages:

• The actual representation of datatypes like OCINumber is opaque to client applications, and the datatypes are manipulated with a set of predefined functions. This allows for the internal representation to change to accommodate future enhancements without breaking user code.
• The implementation is consistent with object-oriented paradigms in which class implementation is hidden and only the required operations are exposed.
• This implementation can have advantages for programmers. Consider a C program that wants to manipulate Oracle number variables without losing the accuracy provided by Oracle numbers. To do this in Oracle7, you would have had to issue a "SELECT...FROM DUAL" statement. In Oracle8, this is accomplished by invoking the OCINumber*() functions.

Manipulating C Datatypes With OCI

In an OCI application, the manipulation of data may be as simple as adding together two integer variables and storing the result in a third variable:

integer        int_1, int_2, sum;
...
/* some initialization occurs */
...
sum = int_1 + int_2;

The C language provides a set of predefined operations on simple types like integer. However, the C datatypes listed in Table 9-1 are not simple C primitives. Types like OCIString and OCINumber are actually structs with a specific Oracle-defined internal structure. It is not possible to simply add together two OCINumbers and store the value in the third.

The following is not valid:

OCINumber        num_1, num_2, sum;
...
/* some initialization occurs */
...
sum = num_1 + num_2;                     /* NOT A VALID OPERATION */

The OCI datatype mapping and manipulation functions are provided to enable you to perform operations on these new datatypes. For example, the above addition of OCINumbers could be accomplished as follows, using the OCINumberAdd() function:

OCINumber        num_1, num_2, sum;
...
/* some initialization occurs */
...
OCINumberAdd(errhp, &num_1, &num_2, &sum): /* errhp is error handle */

The OCI provides functions to operate on each of the new datatypes. The names of the functions provide information about the datatype on which they operate. The first three letters, "OCI", indicate that the function is part of the OCI. The next part of the name indicates the datatype on which the function operates. The following table shows the various function prefixes, along with example function names and the datatype on which those functions operate:

Function Prefix	Example	Operates On
OCIDate	OCIDateDaysBetween()	OCIDate
OCINumber	OCINumberAdd()	OCINumber
OCIString	OCIStringSize()	OCIString *
OCIRef	OCIRefAssign()	OCIRef *
OCIRaw	OCIRawResize()	OCIRaw *
OCIColl	OCICollGetElem()	OCIColl, OCIIter, OCITable, OCIArray
OCIIter	OCIIterInit()	OCIIter
OCITable	OCITableLast()	OCITable *

The structure of each of the datatypes is described later in this chapter, along with a list of the functions that manipulate that type.

Precision of Oracle Number Operations

Oracle numbers have a precision of 38 decimal digits. All Oracle number operations are accurate to the full precision, with the following exceptions:

• Inverse trigonometric functions are accurate to 28 decimal digits.
• Other transcendental functions, including trigonometric functions, are accurate to approximately 37 decimal digits.
• Conversions to and from native floating-point types have the precision of the relevant floating-point type, not to exceed 38 decimal digits.

Date (OCIDate)

The Oracle date format is mapped in C by the OCIDate type, which is an opaque C struct. Elements of the struct represent the year, month, day, hour, minute, and second of the date. The specific elements can be set and retrieved using the appropriate OCI functions.

The OCIDate datatype can be bound or defined directly using the external typecode SQLT_ODT in the bind or define call.

The OCI date manipulation functions are listed in the following tables, which are organized according to functionality. Unless otherwise specified, the term "date" in these tables refers to a value of type OCIDate.

See Also: The prototypes and descriptions for all the functions are provided in Chapter 15, "OCI Datatype Mapping and Manipulation Functions".

Date Conversion Functions

The following functions perform date conversion.

Function	Purpose
OCIDateToText()	convert date to string
OCIDateFromText()	convert text string to date
OCIDateZoneToZone()	convert date from one time zone to another

Date Assignment and Retrieval Functions

The following functions retrieve and assign date elements.

Function	Purpose
OCIDateAssign()	OCIDate assignment
OCIDateGetDate()	get the date portion of an OCIDate
OCIDateSetDate()	set the date portion of an OCIDate
OCIDateGetTime()	get the time portion of an OCIDate
OCIDateSetTime()	set the time portion of an OCIDate

Date Arithmetic and Comparison Functions

The following functions perform date arithmetic and comparison.

Function	Purpose
OCIDateAddDays()	add days
OCIDateAddMonths()	add months
OCIDateCompare()	compare dates
OCIDateDaysBetween()	calculate the number of days between two dates

Date Information Accessor Functions

The following functions access date information.

Function	Purpose
OCIDateLastDay()	the last day of the month
OCIDateNextDay()	the first named day after a given date
OCIDateSysDate()	the system date

Date Validity Checking Functions

The following function checks date validity.

Function	Purpose
OCIDateCheck()	check whether a given date is valid

Date Example

The following code provides examples of how to manipulate an attribute of type OCIDate using OCI calls.

#define FMT "DAY, MONTH DD, YYYY"
#define LANG "American"
struct person
{
OCIDate start_date;
};
typedef struct person person;

OCIError *err;
person *tim;
sword status;                      /* error status */
uword invalid;
OCIDate last_day, next_day;
text buf[100], last_day_buf[100], next_day_buf[100];
ub4 buflen = sizeof(buf);
     
/* For this example, assume the OCIEnv and OCIError have been
* initialized as described in Chapter 2. */
/* Pin tim person object in the object cache. See Chapter 6 for
* information about pinning. For this example, assume that
* tim is pointing to the pinned object. */
/* set the start date of tim */
OCIDateSetTime(&tim->start_date,8,0,0);
OCIDateSetDate(&tim->start_date,1990,10,5)

/* check if the date is valid */
if (OCIDateCheck(err, &tim->start_date, &invalid) != OCI_SUCCESS)
/* error handling code */

if (invalid)
/* error handling code */

/* get the last day of start_date's month */
if (OCIDateLastDay(err, &tim->start_date, &last_day) != OCI_SUCCESS)
/* error handling code */

/* get date of next named day */
if (OCIDateNextDay(err, &tim->start_date, "Wednesday",       strlen("Wednesday"), 
&next_day) != OCI_SUCCESS)
/* error handling code */
/* convert dates to strings and print the information out */
/* first convert the date itself*/
buflen = sizeof(buf);
if (OCIDateToText(err, &tim->start_date, FMT, sizeof(FMT)-1, LANG, 
        sizeof(LANG)-1, 		&buflen, buf) != OCI_SUCCESS)
/* error handling code */

/* now the last day of the month */
buflen = sizeof(last_day_buf);
if (OCIDateToText(err, &last_day, FMT, sizeof(FMT)-1, LANG,       sizeof(LANG)-1, 
&buflen, last_day_buf) != OCI_SUCCESS)
/* error handling code */

/* now the first Wednesday after this date */
buflen = sizeof(next_day_out);
if (OCIDateToText(err, &next_day, FMT, sizeof(FMT)-1, LANG,
      sizeof(LANG)-1, &buflen, next_day_buf) != OCI_SUCCESS)
/* error handling code */

/* print out the info */
printf("For: %s\n", buf);
printf("The last day of the month is: %s\n", last_day_buf);
printf("The next Wednesday is: %s\n", next_day_buf);

The output will be:

For: Monday, May 13, 1996
The last day of the month is: Friday, May 31
The next Wednesday is: Wednesday, May 15

Number (OCINumber)

The OCINumber datatype is an opaque structure used to represent Oracle numeric datatypes (NUMBER, FLOAT, DECIMAL, and so forth).

This type can be bound and defined using the external typecode SQLT_VNU in the bind or define call.

The OCINumber manipulation functions are listed in the following tables, which are organized according to functionality. Unless otherwise specified, the term "number" in these tables refers to a value of type OCINumber.

See Also: The prototypes and descriptions for all the functions are provided in Chapter 15, "OCI Datatype Mapping and Manipulation Functions".

Number Arithmetic Functions

The following functions perform arithmetic operations.

Function	Purpose
OCINumberAbs()	get the absolute value of a number
OCINumberAdd()	add two numbers together
OCINumberCeil()	get the ceiling value of a number
OCINumberDiv()	divide one number by another
OCINumberFloor()	get the floor value of a number
OCINumberMod()	get the modulus from the division of two numbers
OCINumberMul()	multiply two numbers together
OCINumberNeg()	negate a number
OCINumberRound()	round a number to a specified decimal place
OCINumberSign()	get the sign of a number
OCINumberSqrt()	get the square root of a number
OCINumberSub()	subtract one number from another
OCINumberTrunc()	truncate a number to a specified decimal place
OCINumberSIgn()	returns the sign of a given number

Number Conversion Functions

The following functions perform conversions between numbers and reals, integers, and strings.

Function	Purpose
OCINumberToInt()	convert number to integer
OCINumberFromInt()	convert integer to number
OCINumberToReal()	convert number to real
OCINumberFromReal()	convert real to number
OCINumberToText()	convert number to string
OCINumberFromText()	convert string to number

Exponential and Logarithmic Functions

The following functions perform exponential and logarithmic operations.

Function	Purpose
OCINumberPower()	take a number base to a given number exponent
OCINumberExp()	take the exponent with base e
OCINumberLog()	take the logarithm of a given base
OCINumberLn()	take the natural logarithm (base e)
OCINumberIntPower()	take a number base to a given integer power

Trigonometric Functions

The following functions perform trigonometric operations on numbers.

Function	Purpose
OCINumberArcCos()	calculate arc cosine
OCINumberArcSin()	calculate arc sine
OCINumberArcTan() / OCINumberArcTan2()	calculate arc tangent / of two numbers
OCINumberCos()	calculate cosine
OCINumberHypCos()	calculate cosine hyperbolic
OCINumberSin()	calculate sine
OCINumberHypSin()	calculate sine hyperbolic
OCINumberTan()	calculate tangent
OCINumberHypTan()	calculate tangent hyperbolic

Number Assignment and Comparison Functions

The following functions perform assign and compare operations on numbers.

Function	Purpose
OCINumberAssign()	assign one number to another
OCINumberCmp()	compare two numbers
OCINumberIsZero()	test if equal to zero
OCINumberSetZero()	initialize number to zero

Number Example

The following example shows how to manipulate an attribute of type OCINumber.

struct person
{
OCINumber sal;
};
typedef struct person person;
OCIError *err;
person* steve;
person* scott;
person* jason;
OCINumber  *stevesal;
OCINumber  *scottsal;
OCINumber *debsal;
sword   status;
int     inum;
double  dnum;
OCINumber ornum;
char    buffer[21];
ub4     buflen;
sword   result;

/* For this example, assume OCIEnv and OCIError are initialized. */
/* For this example, assume that steve, scott and jason are pointing to 
    person objects which have been pinned in the object cache. */
stevesal = &steve->sal;
scottsal = &scott->sal;
debsal = &jason->sal;

/* initialize steve's salary to be $12,000 */
OCINumberInit(err, stevesal);
inum = 12000;
status = OCINumberFromInt(err, &inum, sizeof(inum), OCI_NUMBER_SIGNED, 
        stevesal);
if (status != OCI_SUCCESS)  /* handle error from OCINumberFromInt */;

/* initialize scott's salary to be same as steve */
OCINumberAssign(err, stevesal, scottsal);

/* initialize jason's salary to be 20% more than steve's */
dnum = 1.2;
status = OCINumberFromReal(err, &dnum, DBL_DIG, &ornum);
if (status != OCI_SUCCESS)  /* handle error from OCINumberFromReal */;
status = OCINumberMul(err, stevesal, &ornum, debsal);
if (status != OCI_SUCCESS)  /* handle error from OCINumberMul */;

/* give scott a 50% raise */
dnum = 1.5;
status = OCINumberFromReal(err, &dnum, DBL_DIG, &ornum);
if (status != OCI_SUCCESS)  /* handle error from OCINumberFromReal */;
status = OCINumberMul(err, scottsal, &ornum, scottsal);
if (status != OCI_SUCCESS)  /* handle error from OCINumberMul */;

/* double steve's salary */
status = OCINumberAdd(err, stevesal, stevesal, stevesal);
if (status != OCI_SUCCESS)  /* handle error from OCINumberAdd */;

/* get steve's salary in integer */
status = OCINumberToInt(err, stevesal, sizeof(inum), OCI_NUMBER_SIGNED, 
        &inum);
if (status != OCI_SUCCESS)  /* handle error from OCINumberToInt */;

/* inum is set to 24000 */
/* get jason's salary in double */
status = OCINumberToReal(err, debsal, sizeof(dnum), &dnum);
if (status != OCI_SUCCESS)  /* handle error from OCINumberToReal */;

/* dnum is set to 14400 */
/* print scott's salary as DEM0001\Q8000.00 */
buflen = sizeof(buffer);
status = OCINumberToText(err, scottsal, "C0999G9999D99", 13, 
        "NLS_NUMERIC_CHARACTERS='.\Q' NLS_ISO_CURRENCY='Germany'", 
        54, &buflen, buffer);
if (status != OCI_SUCCESS)  /* handle error from OCINumberToText */;
printf("scott's salary = %s\n", buffer);

/* compare steve and scott's salaries */
status = OCINumberCmp(err, stevesal, scottsal, &result);
if (status != OCI_SUCCESS)  /* handle error from OCINumberCmp */;

/* result is positive */
/* read jason's new salary from string */
status = OCINumberFromText(err, "48\Q000.00", 9, "99G999D99", 9,
        "NLS_NUMERIC_CHARACTERS='.\Q'", 27, debsal);
if (status != OCI_SUCCESS)  /* handle error from OCINumberFromText */;
/* jason's salary is now 48000.00 */

Fixed or Variable-Length String (OCIString)

Fixed or variable-length string data is represented to C programs as an OCIString *.

The length of the string does not include the null character.

For binding and defining variables of type OCIString * use the external typecode SQLT_VST.

See Also: The prototypes and descriptions for all the functions are provided in Chapter 15, "OCI Datatype Mapping and Manipulation Functions".

String Functions

The following functions allow the C programmer to manipulate an instance of a string.

Function	Purpose
OCIStringAssign()	assign one string to another
OCIStringAssignText()	assign text string to string
OCIStringAllocSize()	get allocated size of string memory in bytes
OCIStringPtr()	get pointer to string part of string
OCIStringSize()	get string size
OCIStringResize()	resize string memory

String Example

This example assigns a text string to a string, then gets a pointer to the string part of the string, as well as the string size, and prints it out.

Note the double indirection used in passing the vstring1 parameter in OCIStringAssignText().

OCIEnv       *envhp;
OCIError     *errhp;
OCIString     *vstring1 = (OCIString *)0;
OCIString     *vstring2 = (OCIString *)0;
text          c_string[20];
text         *text_ptr;
sword        status;

strcpy(c_string, "hello world");
/* Assign a text string to an OCIString */
status = OCIStringAssignText(envhp, errhp, c_string, 
      (ub4)strlen(c_string),&vstring1);
/* Memory for vstring1 is allocated as part of string assignment */

status = OCIStringAssignText(envhp, errhp, "hello again", 
       (ub4)strlen("This is a longer string."),&vstring1);
/* vstring1 is automatically resized to store the longer string */

/* Get a pointer to the string part of vstring1 */
text_ptr = OCIStringPtr(envhp, vstring1);
/* text_ptr now points to "hello world" */
printf("%s\n", text_ptr);

Raw (OCIRaw)

Variable-length raw data is represented in C using the OCIRaw * datatype.

For binding and defining variables of type OCIRaw *, use the external typecode SQLT_LVB.

See Also: The prototypes and descriptions for all the functions are provided in Chapter 15, "OCI Datatype Mapping and Manipulation Functions".

Raw Functions

The following functions perform OCIRaw operations.

Function	Purpose
OCIRawAssignBytes()	assign raw data (ub1 *) to OCIRaw *
OCIRawAssignRaw()	assign one OCIRaw * to another
OCIRawAllocSize()	get the allocated size of raw memory in bytes
OCIRawPtr()	get pointer to raw data
OCIRawSize()	get size of raw data
OCIRawResize()	resize memory of variable-length raw data

Raw Example

In this example, a raw data block is set up and a pointer to its data is obtained.

Note the double indirection in the call to OCIRawAssignBytes().

OCIEnv      *envhp;
OCIError    *errhp;
sword       status;
ub1         data_block[10000];
ub4         data_block_len = 10000;
OCIRaw      *raw1;
ub1 *raw1_pointer;

/* Set up the RAW */
/* assume 'data_block' has been initialized */
status = OCIRawAssignBytes(envhp, errhp, data_block, data_block_len, &raw);

/* Get a pointer to the data part of the RAW */
raw1_pointer = OCIRawPtr(envhp, raw1);

Collections (OCITable, OCIArray, OCIColl, OCIIter)

Oracle8 provides two types of collections: variable-length arrays (varrays) and nested tables. In C applications, varrays are represented as OCIArray *, and nested tables are represented as OCITable *. Both of these datatypes (along with OCIColl and OCIIter, described later) are opaque structures.

A variety of generic collection functions enable you to manipulate collection data. You can use these functions on both varrays and nested tables. In addition, there is a set of functions specific to nested tables; see "Nested Table Manipulation Functions" on page 9-20.

You can allocate an instance of a varray or nested table using OCIObjectNew() and free it using OCIObjectFree().

See Also: The prototypes and descriptions for all the functions are provided in Chapter 15, "OCI Datatype Mapping and Manipulation Functions".

Generic Collection Functions

Oracle8 provides two types of collections: variable-length arrays (varrays) and nested tables. Both varrays and nested tables can be viewed as sub-types of a generic collection type.

In C, a generic collection is represented as OCIColl *, a varray is represented as OCIArray *, and a nested table as OCITable *. Oracle provides a set of functions to operated on generic collections (such as OCIColl *). These functions start with the prefix OCIColl, as in OCICollGetElem(). The OCIColl*() functions can also be called to operate on varrays and nested tables.

The generic collection functions are grouped into two main categories:

• manipulating varray or nested table data
• scanning through a collection with a collection iterator

The generic collection functions represent a complete set of functions for manipulating varrays. Additional functions are provided to operate specifically on nested tables. They are identified by the prefix OCITable, as in OCITableExists(). These are described in the section "Nested Table Manipulation Functions" on page 9-20.

Note: Indexes passed to collection functions are zero-based.

Collection Data Manipulation Functions

The following generic functions manipulate collection data:

Function	Purpose
OCICollAppend()	append an element
OCICollAssignElem()	assign element at given index
OCICollAssign()	assign one collection to another
OCICollGetElem()	get pointer to an element given its index
OCICollMax()	get upper bound of collection
OCICollSize()	get current size of collection
OCICollTrim()	trim n elements from the end of the collection

Collection Scanning Functions

The following generic functions enable you to scan collections with a collection iterator. The iterator is of type OCIIter, and is created by first calling OCIIterCreate().

Function	Purpose
OCIIterCreate()	create an iterator for scanning collection
OCIIterDelete()	delete iterator
OCIIterGetCurrent()	get pointer to current element pointed by iterator
OCIIterInit()	initialize iterator to scan the given collection
OCIIterNext()	get pointer to next element
OCIIterPrev()	get pointer to previous element

Varray/Collection Iterator Example

This example creates and uses a collection iterator to scan through a varray.

OCIEnv       *envhp; 
OCIError     *errhp; 
text         *text_ptr; 
sword        status; 
OCIArray     *clients; 
OCIString    *client_elem; 
OCIIter      *iterator; 
boolean      eoc; 
dvoid        *elem;
OCIInd       *elemind;
 
/* Assume envhp, errhp have been initialized */
/* Assume clients points to a varray */ 

/* Print the elements of clients */ 
/* To do this, create an iterator to scan the varray */ 
status = OCIIterCreate(envhp, errhp, clients, &iterator); 

/* Get the first element of the clients varray */ 
printf("Clients' list:\n"); 
status = OCIIterNext(envhp, errhp, iterator, &elem,
                    (dvoid **) &elemind, &eoc);

while (!eoc && (status == OCI_SUCCESS))
{
  client_elem = *(OCIString)**elem; 
                             /* client_elem points to the string */ 

 /* 
    the element pointer type returned by OCIIterNext() via 'elem' is
    the same as that of OCICollGetElem(). Refer to OCICollGetElem() for
    details.  */

  /* 
    client_elem points to an OCIString descriptor, so to print it out, 
    get a pointer to where the text begins
  */ 
  text_ptr = OCIStringPtr(envhp, client_elem);

  /* 
    text_ptr now points to the text part of the client OCIString, which is a 
NULL-terminated string
  */ 
  printf("  %s\n", text_ptr); 
  status = OCIIterNext(envhp, errhp, iterator, &elem,
                      (dvoid **)&elemind, &eoc);
}

if (status != OCI_SUCCESS)
{
  /* handle error */
}

/* destroy the iterator */
status = OCIIterDelete(envhp, errhp, &iterator);

Nested Table Manipulation Functions

As its name implies, one table may be nested or contained within another, as a variable, attribute, parameter or column. Nested tables may have elements deleted, by means of the OCITableDelete() function.

For example, suppose a table is created with 10 elements, and OCITableDelete() is used to delete elements at index 0 through 4 and 9. The first existing element is now element 5, and the last existing element is element 8.

As noted above, the generic collection functions may be used to map to and manipulate nested tables. In addition, the following functions are specific to nested tables. They should not be used on varrays.

Function	Purpose
OCITableDelete()	delete an element at a given index
OCITableExists()	test whether an element exists at a given index
OCITableFirst()	return index for first existing element of table
OCITableLast()	return index for last existing element of table
OCITableNext()	return index for next existing element of table
OCITablePrev()	return index for previous existing element of table
OCITableSize()	return table size, not including deleted elements

Nested Table Element Ordering

When a nested table is fetched into the object cache, its elements are given a transient ordering, numbered from zero to the number of elements, minus 1. For example, a table with 40 elements would be numbered from 0 to 39.

You can use these position ordinals to fetch and assign the values of elements (for example, fetch to element i, or assign to element j, where i and j are valid position ordinals for the given table).

When the table is copied back to the database, its transient ordering is lost. Delete operations may be performed against elements of the table. Delete operations create transient "holes"; that is, they do not change the position ordinals of the remaining table elements.

REF (OCIRef)

In Oracle8, a REF (reference) is an identifier to an object. It is an opaque structure that uniquely locates the object. An object may point to another object by way of a REF.

In C applications, the REF is represented by OCIRef *.

See Also: The prototypes and descriptions for all the functions are provided in Chapter 15, "OCI Datatype Mapping and Manipulation Functions".

REF Manipulation Functions

The following functions perform REF operations.

Function	Purpose
OCIRefToHex()	convert REF to a hexadecimal string
OCIRefAssign()	assign one REF to another
OCIRefClear()	clear or nullify a REF
OCIRefIsEqual()	compare two REFs for equality
OCIRefFromHex()	convert hexadecimal string to a REF
OCIRefIsNull()	test whether a REF is NULL
OCIRefHexSize()	return size of hex string representation of REF

REF Example

This example tests two REFs for NULL, compares them for equality, and assigns one REF to another.

Note the double indirection in the call to OCIRefAssign().

OCIEnv       *envhp;
OCIError     *errhp;
sword        status;
boolean      refs_equal;
OCIRef       *ref1, ref2;

/* assume refs have been initialized to point to valid objects */
/*Compare two REFs for equality */
refs_equal = OCIRefIsEqual(envhp, ref1, ref2);
printf("After first OCIRefIsEqual:\n");
if(refs_equal)
   printf("REFs equal\n");
else
   printf("REFs not equal\n");

/*Assign ref1 to ref2 */
status = OCIRefAssign (envhp, errhp, ref1, &ref2);
if(status != OCI_SUCCESS) 
/*error handling*/

/*Compare the two REFs again for equality */
refs_equal = OCIRefIsEqual(envhp, ref1, ref2);
printf("After second OCIRefIsEqual:\n");
if(refs_equal)
   printf("REFs equal\n");
else
   printf("REFs not equal\n");

Object Type Information Storage and Access

Descriptor Objects

When a given type is created with the CREATE TYPE statement, it is stored in the server and associated with a type descriptor object (TDO). In addition, the database stores descriptor objects for each data attribute of the type, each method of the type, each parameter of each method, and the results returned by methods. The following table lists the OCI datatypes associated with each type of descriptor object.

Information Type	OCI Datatype
Type	OCIType
Type Attributes Collection Elements Method Parameters Method Results	OCITypeElem
Method	OCITypeMethod

Several OCI functions (including OCIBindObject() and OCIObjectNew()) require a TDO as an input parameter. An application can obtain the TDO by calling OCITypeByName(), which gets the type's TDO in an OCIType variable. Once you obtain the TDO, you can pass it, as necessary to other calls.

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