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11g Release 2 (11.2)

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9 SQL*Loader Control File Reference

This chapter describes the SQL*Loader control file. The following topics are discussed:

Control File Contents

The SQL*Loader control file is a text file that contains data definition language (DDL) instructions. DDL is used to control the following aspects of a SQL*Loader session:

See Appendix A for syntax diagrams of the SQL*Loader DDL.

To create the SQL*Loader control file, use a text editor such as vi or xemacs.

In general, the control file has three main sections, in the following order:

Example 9-1 shows a sample control file.

Example 9-1 Sample Control File

1    -- This is a sample control file
2    LOAD DATA
3    INFILE 'sample.dat'
4    BADFILE 'sample.bad'
5    DISCARDFILE 'sample.dsc'
6    APPEND
7    INTO TABLE emp
8    WHEN (57) = '.'
9    TRAILING NULLCOLS
10  (hiredate SYSDATE,
      deptno POSITION(1:2)  INTEGER EXTERNAL(2)
              NULLIF deptno=BLANKS,
       job    POSITION(7:14)  CHAR  TERMINATED BY WHITESPACE
              NULLIF job=BLANKS  "UPPER(:job)",
       mgr    POSITION(28:31) INTEGER EXTERNAL 
              TERMINATED BY WHITESPACE, NULLIF mgr=BLANKS,
       ename  POSITION(34:41) CHAR 
              TERMINATED BY WHITESPACE  "UPPER(:ename)",
       empno  POSITION(45) INTEGER EXTERNAL 
              TERMINATED BY WHITESPACE,
       sal    POSITION(51) CHAR  TERMINATED BY WHITESPACE
              "TO_NUMBER(:sal,'$99,999.99')",
       comm   INTEGER EXTERNAL  ENCLOSED BY '(' AND '%'
              ":comm * 100"
    )

In this sample control file, the numbers that appear to the left would not appear in a real control file. They are keyed in this sample to the explanatory notes in the following list:

  1. This is how comments are entered in a control file. See "Comments in the Control File".

  2. The LOAD DATA statement tells SQL*Loader that this is the beginning of a new data load. See Appendix A for syntax information.

  3. The INFILE clause specifies the name of a data file containing the data you want to load. See "Specifying Data Files".

  4. The BADFILE clause specifies the name of a file into which rejected records are placed. See "Specifying the Bad File".

  5. The DISCARDFILE clause specifies the name of a file into which discarded records are placed. See "Specifying the Discard File".

  6. The APPEND clause is one of the options you can use when loading data into a table that is not empty. See "Loading Data into Nonempty Tables".

    To load data into a table that is empty, you would use the INSERT clause. See "Loading Data into Empty Tables".

  7. The INTO TABLE clause enables you to identify tables, fields, and datatypes. It defines the relationship between records in the data file and tables in the database. See "Specifying Table Names".

  8. The WHEN clause specifies one or more field conditions. SQL*Loader decides whether to load the data based on these field conditions. See "Loading Records Based on a Condition".

  9. The TRAILING NULLCOLS clause tells SQL*Loader to treat any relatively positioned columns that are not present in the record as null columns. See "Handling Short Records with Missing Data".

  10. The remainder of the control file contains the field list, which provides information about column formats in the table being loaded. See Chapter 10 for information about that section of the control file.

Comments in the Control File

Comments can appear anywhere in the command section of the file, but they should not appear within the data. Precede any comment with two hyphens, for example:

--This is a comment

All text to the right of the double hyphen is ignored, until the end of the line.

Specifying Command-Line Parameters in the Control File

You can specify command-line parameters in the SQL*Loader control file using the OPTIONS clause. This can be useful when you typically invoke a control file with the same set of options. The OPTIONS clause precedes the LOAD DATA statement.

OPTIONS Clause

The following command-line parameters can be specified using the OPTIONS clause. These parameters are described in greater detail in Chapter 8.

BINDSIZE = n
COLUMNARRAYROWS = n
DATE_CACHE = n
DIRECT = {TRUE | FALSE} 
ERRORS = n
EXTERNAL_TABLE = {NOT_USED | GENERATE_ONLY | EXECUTE}
FILE
LOAD = n 
MULTITHREADING = {TRUE | FALSE}
PARALLEL = {TRUE | FALSE}
READSIZE = n
RESUMABLE = {TRUE | FALSE}
RESUMABLE_NAME = 'text string'
RESUMABLE_TIMEOUT = n
ROWS = n 
SILENT = {HEADER | FEEDBACK | ERRORS | DISCARDS | PARTITIONS | ALL} 
SKIP = n   
SKIP_INDEX_MAINTENANCE = {TRUE | FALSE}
SKIP_UNUSABLE_INDEXES = {TRUE | FALSE}
STREAMSIZE = n

The following is an example use of the OPTIONS clause that you could use in a SQL*Loader control file:

OPTIONS (BINDSIZE=100000, SILENT=(ERRORS, FEEDBACK) )

Note:

Parameter values specified on the command line override parameter values specified in the control file OPTIONS clause.

Specifying File Names and Object Names

In general, SQL*Loader follows the SQL standard for specifying object names (for example, table and column names). The information in this section discusses the following topics:

File Names That Conflict with SQL and SQL*Loader Reserved Words

SQL and SQL*Loader reserved words must be specified within double quotation marks. The only SQL*Loader reserved word is CONSTANT.

You must use double quotation marks if the object name contains special characters other than those recognized by SQL ($, #, _), or if the name is case sensitive.

Specifying SQL Strings

You must specify SQL strings within double quotation marks. The SQL string applies SQL operators to data fields.

Operating System Considerations

The following sections discuss situations in which your course of action may depend on the operating system you are using.

Specifying a Complete Path

If you encounter problems when trying to specify a complete path name, it may be due to an operating system-specific incompatibility caused by special characters in the specification. In many cases, specifying the path name within single quotation marks prevents errors.

Backslash Escape Character

In DDL syntax, you can place a double quotation mark inside a string delimited by double quotation marks by preceding it with the escape character, "\" (if the escape character is allowed on your operating system). The same rule applies when single quotation marks are required in a string delimited by single quotation marks.

For example, homedir\data"norm\mydata contains a double quotation mark. Preceding the double quotation mark with a backslash indicates that the double quotation mark is to be taken literally:

INFILE 'homedir\data\"norm\mydata'

You can also put the escape character itself into a string by entering it twice.

For example:

"so'\"far"     or  'so\'"far'     is parsed as   so'"far 
"'so\\far'"    or  '\'so\\far\''  is parsed as  'so\far' 
"so\\\\far"    or  'so\\\\far'    is parsed as   so\\far 

Note:

A double quotation mark in the initial position cannot be preceded by an escape character. Therefore, you should avoid creating strings with an initial quotation mark.

Nonportable Strings

There are two kinds of character strings in a SQL*Loader control file that are not portable between operating systems: filename and file processing option strings. When you convert to a different operating system, you will probably need to modify these strings. All other strings in a SQL*Loader control file should be portable between operating systems.

Using the Backslash as an Escape Character

If your operating system uses the backslash character to separate directories in a path name, and if the release of the Oracle database running on your operating system implements the backslash escape character for file names and other nonportable strings, then you must specify double backslashes in your path names and use single quotation marks.

Escape Character Is Sometimes Disallowed

The release of the Oracle database running on your operating system may not implement the escape character for nonportable strings. When the escape character is disallowed, a backslash is treated as a normal character, rather than as an escape character (although it is still usable in all other strings). Then path names such as the following can be specified normally:

INFILE 'topdir\mydir\myfile'

Double backslashes are not needed.

Because the backslash is not recognized as an escape character, strings within single quotation marks cannot be embedded inside another string delimited by single quotation marks. This rule also holds for double quotation marks. A string within double quotation marks cannot be embedded inside another string delimited by double quotation marks.

Identifying XMLType Tables

As of Oracle Database 10g, the XMLTYPE clause is available for use in a SQL*Loader control file. This clause is of the format XMLTYPE(field name). It is used to identify XMLType tables so that the correct SQL statement can be constructed. Example 9-2 shows how the XMLTYPE clause can be used in a SQL*Loader control file to load data into a schema-based XMLType table.

Example 9-2 Identifying XMLType Tables in the SQL*Loader Control File

The XML schema definition is as follows. It registers the XML schema, xdb_user.xsd, in the Oracle XML DB, and then creates the table, xdb_tab5.

begin dbms_xmlschema.registerSchema('xdb_user.xsd',
'<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema"
            xmlns:xdb="http://xmlns.oracle.com/xdb">
 <xs:element name = "Employee"
        xdb:defaultTable="EMP31B_TAB">
   <xs:complexType>
    <xs:sequence>
      <xs:element name = "EmployeeId" type = "xs:positiveInteger"/>
      <xs:element name = "Name" type = "xs:string"/>
      <xs:element name = "Salary" type = "xs:positiveInteger"/>
      <xs:element name = "DeptId" type = "xs:positiveInteger"
             xdb:SQLName="DEPTID"/>
    </xs:sequence>
   </xs:complexType>
 </xs:element>
</xs:schema>',
TRUE, TRUE, FALSE); end;
/

The table is defined as follows:

CREATE TABLE xdb_tab5 OF XMLTYPE XMLSCHEMA "xdb_user.xsd" ELEMENT "Employee";

The control file used to load data into the table, xdb_tab5, looks as follows. It loads XMLType data using the registered XML schema, xdb_user.xsd. The XMLTYPE clause is used to identify this table as an XMLType table. Either direct path or conventional mode can be used to load the data into the table.

LOAD DATA
INFILE *
INTO TABLE xdb_tab5 TRUNCATE
xmltype(xmldata)
(
  xmldata   char(4000)
)
BEGINDATA
<Employee>  <EmployeeId>111</EmployeeId>  <Name>Ravi</Name>  <Salary>100000</Sal
ary>  <DeptId>12</DeptId></Employee>
<Employee>  <EmployeeId>112</EmployeeId>  <Name>John</Name>  <Salary>150000</Sal
ary>  <DeptId>12</DeptId></Employee>
<Employee>  <EmployeeId>113</EmployeeId>  <Name>Michael</Name>  <Salary>75000</S
alary>  <DeptId>12</DeptId></Employee>
<Employee>  <EmployeeId>114</EmployeeId>  <Name>Mark</Name>  <Salary>125000</Sal
ary>  <DeptId>16</DeptId></Employee>
<Employee>  <EmployeeId>115</EmployeeId>  <Name>Aaron</Name>  <Salary>600000</Sa
lary>  <DeptId>16</DeptId></Employee>

See Also:

Oracle XML DB Developer's Guide for more information about loading XML data using SQL*Loader

Specifying Data Files

To specify a data file that contains the data to be loaded, use the INFILE keyword, followed by the file name and optional file processing options string. You can specify multiple files by using multiple INFILE keywords.

Note:

You can also specify the data file from the command line, using the DATA parameter described in "Command-Line Parameters". A file name specified on the command line overrides the first INFILE clause in the control file.

If no file name is specified, then the file name defaults to the control file name with an extension or file type of .dat.

If the control file itself contains the data to be loaded, then specify an asterisk (*). This specification is described in "Identifying Data in the Control File with BEGINDATA" .

Note:

The information in this section applies only to primary data files. It does not apply to LOBFILEs or SDFs.

For information about LOBFILES, see "Loading LOB Data from LOBFILEs".

For information about SDFs, see "Secondary Data Files (SDFs)".

The syntax for INFILE is as follows:

Description of infile.gif follows
Description of the illustration infile.gif

Table 9-1 describes the parameters for the INFILE keyword.

Table 9-1 Parameters for the INFILE Keyword

Parameter Description

INFILE

Specifies that a data file specification follows.

input_filename

Name of the file containing the data.

Any spaces or punctuation marks in the file name must be enclosed in single quotation marks. See "Specifying File Names and Object Names".

*

If your data is in the control file itself, then use an asterisk instead of the file name. If you have data in the control file and in data files, then you must specify the asterisk first in order for the data to be read.

os_file_proc_clause

This is the file-processing options string. It specifies the data file format. It also optimizes data file reads. The syntax used for this string is specific to your operating system. See "Specifying Data File Format and Buffering".


Examples of INFILE Syntax

The following list shows different ways you can specify INFILE syntax:

  • Data contained in the control file itself:

    INFILE  *
    
  • Data contained in a file named sample with a default extension of .dat:

    INFILE  sample
    
  • Data contained in a file named datafile.dat with a full path specified:

    INFILE 'c:/topdir/subdir/datafile.dat' 
    

    Note:

    file names that include spaces or punctuation marks must be enclosed in single quotation marks.

Specifying Multiple Data Files

To load data from multiple data files in one SQL*Loader run, use an INFILE clause for each data file. Data files need not have the same file processing options, although the layout of the records must be identical. For example, two files could be specified with completely different file processing options strings, and a third could consist of data in the control file.

You can also specify a separate discard file and bad file for each data file. In such a case, the separate bad files and discard files must be declared immediately after each data file name. For example, the following excerpt from a control file specifies four data files with separate bad and discard files:

INFILE  mydat1.dat  BADFILE  mydat1.bad  DISCARDFILE mydat1.dis 
INFILE  mydat2.dat 
INFILE  mydat3.dat  DISCARDFILE  mydat3.dis 
INFILE  mydat4.dat  DISCARDMAX  10 0
  • For mydat1.dat, both a bad file and discard file are explicitly specified. Therefore both files are created, as needed.

  • For mydat2.dat, neither a bad file nor a discard file is specified. Therefore, only the bad file is created, as needed. If created, the bad file has the default file name and extension mydat2.bad. The discard file is not created, even if rows are discarded.

  • For mydat3.dat, the default bad file is created, if needed. A discard file with the specified name (mydat3.dis) is created, as needed.

  • For mydat4.dat, the default bad file is created, if needed. Because the DISCARDMAX option is used, SQL*Loader assumes that a discard file is required and creates it with the default name mydat4.dsc.

Identifying Data in the Control File with BEGINDATA

If the data is included in the control file itself, then the INFILE clause is followed by an asterisk rather than a file name. The actual data is placed in the control file after the load configuration specifications.

Specify the BEGINDATA statement before the first data record. The syntax is:

BEGINDATA 
data

Keep the following points in mind when using the BEGINDATA statement:

Specifying Data File Format and Buffering

When configuring SQL*Loader, you can specify an operating system-dependent file processing options string (os_file_proc_clause) in the control file to specify file format and buffering.

For example, suppose that your operating system has the following option-string syntax:

Description of recsize_spec.gif follows
Description of the illustration recsize_spec.gif

In this syntax, RECSIZE is the size of a fixed-length record, and BUFFERS is the number of buffers to use for asynchronous I/O.

To declare a file named mydata.dat as a file that contains 80-byte records and instruct SQL*Loader to use 8 I/O buffers, you would use the following control file entry:

INFILE 'mydata.dat' "RECSIZE 80 BUFFERS 8" 

Note:

This example uses the recommended convention of single quotation marks for file names and double quotation marks for everything else.

See Also:

Oracle Database Platform Guide for Microsoft Windows for information about using the os_file_proc_clause on Windows systems.

Specifying the Bad File

When SQL*Loader executes, it can create a file called a bad file or reject file in which it places records that were rejected because of formatting errors or because they caused Oracle errors. If you have specified that a bad file is to be created, then the following applies:

To specify the name of the bad file, use the BADFILE clause, followed by a file name. If you do not specify a name for the bad file, then the name defaults to the name of the data file with an extension or file type of .bad. You can also specify the bad file from the command line with the BAD parameter described in "Command-Line Parameters".

A file name specified on the command line is associated with the first INFILE clause in the control file, overriding any bad file that may have been specified as part of that clause.

The bad file is created in the same record and file format as the data file so that you can reload the data after you correct it. For data files in stream record format, the record terminator that is found in the data file is also used in the bad file.

The syntax for the bad file is as follows:

Description of badfile.gif follows
Description of the illustration badfile.gif

The BADFILE clause specifies that a file name for the bad file follows.

The filename parameter specifies a valid file name specification for your platform. Any spaces or punctuation marks in the file name must be enclosed in single quotation marks.

Examples of Specifying a Bad File Name

To specify a bad file with file name sample and default file extension or file type of .bad, enter the following in the control file:

BADFILE sample 

To specify a bad file with file name bad0001 and file extension or file type of .rej, enter either of the following lines:

BADFILE bad0001.rej
BADFILE '/REJECT_DIR/bad0001.rej' 

How Bad Files Are Handled with LOBFILEs and SDFs

Data from LOBFILEs and SDFs is not written to a bad file when there are rejected rows. If there is an error loading a LOB, then the row is not rejected. Rather, the LOB column is left empty (not null with a length of zero (0) bytes). However, when the LOBFILE is being used to load an XML column and there is an error loading this LOB data, then the XML column is left as null.

Criteria for Rejected Records

A record can be rejected for the following reasons:

  1. Upon insertion, the record causes an Oracle error (such as invalid data for a given datatype).

  2. The record is formatted incorrectly so that SQL*Loader cannot find field boundaries.

  3. The record violates a constraint or tries to make a unique index non-unique.

If the data can be evaluated according to the WHEN clause criteria (even with unbalanced delimiters), then it is either inserted or rejected.

Neither a conventional path nor a direct path load will write a row to any table if it is rejected because of reason number 2 in the previous list.

A conventional path load will not write a row to any tables if reason number 1 or 3 in the previous list is violated for any one table. The row is rejected for that table and written to the reject file.

In a conventional path load, if the data file has a record that is being loaded into multiple tables and that record is rejected from at least one of the tables, then that record is not loaded into any of the tables.

The log file indicates the Oracle error for each rejected record. Case study 4 demonstrates rejected records. (See "SQL*Loader Case Studies" for information on how to access case studies.)

Specifying the Discard File

During execution, SQL*Loader can create a discard file for records that do not meet any of the loading criteria. The records contained in this file are called discarded records. Discarded records do not satisfy any of the WHEN clauses specified in the control file. These records differ from rejected records. Discarded records do not necessarily have any bad data. No insert is attempted on a discarded record.

A discard file is created according to the following rules:

To create a discard file from within a control file, specify any of the following: DISCARDFILE filename, DISCARDS, or DISCARDMAX.

To create a discard file from the command line, specify either DISCARD or DISCARDMAX.

You can specify the discard file directly by specifying its name, or indirectly by specifying the maximum number of discards.

The discard file is created in the same record and file format as the data file. For data files in stream record format, the same record terminator that is found in the data file is also used in the discard file.

Specifying the Discard File in the Control File

To specify the name of the file, use the DISCARDFILE clause, followed by the file name.

Description of discard.gif follows
Description of the illustration discard.gif

The DISCARDFILE clause specifies that a discard file name follows.

The filename parameter specifies a valid file name specification for your platform. Any spaces or punctuation marks in the file name must be enclosed in single quotation marks.

The default file name is the name of the data file, and the default file extension or file type is .dsc. A discard file name specified on the command line overrides one specified in the control file. If a discard file with that name already exists, then it is either overwritten or a new version is created, depending on your operating system.

Specifying the Discard File from the Command Line

See "DISCARD (file name)" for information about how to specify a discard file from the command line.

A file name specified on the command line overrides any discard file that you may have specified in the control file.

Examples of Specifying a Discard File Name

The following list shows different ways you can specify a name for the discard file from within the control file:

  • To specify a discard file with file name circular and default file extension or file type of .dsc:

    DISCARDFILE  circular 
    
  • To specify a discard file named notappl with the file extension or file type of .may:

    DISCARDFILE notappl.may 
    
  • To specify a full path to the discard file forget.me:

    DISCARDFILE  '/discard_dir/forget.me'
    

Criteria for Discarded Records

If there is no INTO TABLE clause specified for a record, then the record is discarded. This situation occurs when every INTO TABLE clause in the SQL*Loader control file has a WHEN clause and, either the record fails to match any of them, or all fields are null.

No records are discarded if an INTO TABLE clause is specified without a WHEN clause. An attempt is made to insert every record into such a table. Therefore, records may be rejected, but none are discarded.

Case study 7, Extracting Data from a Formatted Report, provides an example of using a discard file. (See "SQL*Loader Case Studies" for information on how to access case studies.)

How Discard Files Are Handled with LOBFILEs and SDFs

Data from LOBFILEs and SDFs is not written to a discard file when there are discarded rows.

Limiting the Number of Discarded Records

You can limit the number of records to be discarded for each data file by specifying an integer for either the DISCARDS or DISCARDMAX keyword.

When the discard limit is reached, processing of the data file terminates and continues with the next data file, if one exists.

You can specify a different number of discards for each data file. Or, if you specify the number of discards only once, then the maximum number of discards specified applies to all files.

If you specify a maximum number of discards, but no discard file name, then SQL*Loader creates a discard file with the default file name and file extension or file type.

Handling Different Character Encoding Schemes

SQL*Loader supports different character encoding schemes (called character sets, or code pages). SQL*Loader uses features of Oracle's globalization support technology to handle the various single-byte and multibyte character encoding schemes available today.

The following sections provide a brief introduction to some of the supported character encoding schemes.

Multibyte (Asian) Character Sets

Multibyte character sets support Asian languages. Data can be loaded in multibyte format, and database object names (fields, tables, and so on) can be specified with multibyte characters. In the control file, comments and object names can also use multibyte characters.

Unicode Character Sets

SQL*Loader supports loading data that is in a Unicode character set.

Unicode is a universal encoded character set that supports storage of information from most languages in a single character set. Unicode provides a unique code value for every character, regardless of the platform, program, or language. There are two different encodings for Unicode, UTF-16 and UTF-8.

Note:

In this manual, you will see the terms UTF-16 and UTF16 both used. The term UTF-16 is a general reference to UTF-16 encoding for Unicode. The term UTF16 (no hyphen) is the specific name of the character set and is what you should specify for the CHARACTERSET parameter when you want to use UTF-16 encoding. This also applies to UTF-8 and UTF8.

The UTF-16 Unicode encoding is a fixed-width multibyte encoding in which the character codes 0x0000 through 0x007F have the same meaning as the single-byte ASCII codes 0x00 through 0x7F.

The UTF-8 Unicode encoding is a variable-width multibyte encoding in which the character codes 0x00 through 0x7F have the same meaning as ASCII. A character in UTF-8 can be 1 byte, 2 bytes, or 3 bytes long.

See Also:

Database Character Sets

The Oracle database uses the database character set for data stored in SQL CHAR datatypes (CHAR, VARCHAR2, CLOB, and LONG), for identifiers such as table names, and for SQL statements and PL/SQL source code. Only single-byte character sets and varying-width character sets that include either ASCII or EBCDIC characters are supported as database character sets. Multibyte fixed-width character sets (for example, AL16UTF16) are not supported as the database character set.

An alternative character set can be used in the database for data stored in SQL NCHAR datatypes (NCHAR, NVARCHAR, and NCLOB). This alternative character set is called the database national character set. Only Unicode character sets are supported as the database national character set.

Data File Character Sets

By default, the data file is in the character set defined by the NLS_LANG parameter. The data file character sets supported with NLS_LANG are the same as those supported as database character sets. SQL*Loader supports all Oracle-supported character sets in the data file (even those not supported as database character sets).

For example, SQL*Loader supports multibyte fixed-width character sets (such as AL16UTF16 and JA16EUCFIXED) in the data file. SQL*Loader also supports UTF-16 encoding with little-endian byte ordering. However, the Oracle database supports only UTF-16 encoding with big-endian byte ordering (AL16UTF16) and only as a database national character set, not as a database character set.

The character set of the data file can be set up by using the NLS_LANG parameter or by specifying a SQL*Loader CHARACTERSET parameter.

Input Character Conversion

The default character set for all data files, if the CHARACTERSET parameter is not specified, is the session character set defined by the NLS_LANG parameter. The character set used in input data files can be specified with the CHARACTERSET parameter.

SQL*Loader can automatically convert data from the data file character set to the database character set or the database national character set, when they differ.

When data character set conversion is required, the target character set should be a superset of the source data file character set. Otherwise, characters that have no equivalent in the target character set are converted to replacement characters, often a default character such as a question mark (?). This causes loss of data.

The sizes of the database character types CHAR and VARCHAR2 can be specified in bytes (byte-length semantics) or in characters (character-length semantics). If they are specified in bytes, and data character set conversion is required, then the converted values may take more bytes than the source values if the target character set uses more bytes than the source character set for any character that is converted. This will result in the following error message being reported if the larger target value exceeds the size of the database column:

ORA-01401: inserted value too large for column

You can avoid this problem by specifying the database column size in characters and also by using character sizes in the control file to describe the data. Another way to avoid this problem is to ensure that the maximum column size is large enough, in bytes, to hold the converted value.

See Also:

Considerations When Loading Data into VARRAYs or Primary-Key-Based REFs

If you use SQL*Loader conventional path or the Oracle Call Interface (OCI) to load data into VARRAYs or into primary-key-based REFs, and the data being loaded is in a different character set than the database character set, then problems such as the following might occur:

  • Rows might be rejected because a field is too large for the database column, but in reality the field is not too large.

  • A load might be abnormally terminated without any rows being loaded, when only the field that really was too large should have been rejected.

  • Rows might be reported as loaded correctly, but the primary-key-based REF columns are returned as blank when they are selected with SQL*Plus.

To avoid these problems, set the client character set (using the NLS_LANG environment variable) to the database character set before you load the data.

CHARACTERSET Parameter

Specifying the CHARACTERSET parameter tells SQL*Loader the character set of the input data file. The default character set for all data files, if the CHARACTERSET parameter is not specified, is the session character set defined by the NLS_LANG parameter. Only character data (fields in the SQL*Loader datatypes CHAR, VARCHAR, VARCHARC, numeric EXTERNAL, and the datetime and interval datatypes) is affected by the character set of the data file.

The CHARACTERSET syntax is as follows:

CHARACTERSET char_set_name 

The char_set_name variable specifies the character set name. Normally, the specified name must be the name of an Oracle-supported character set.

For UTF-16 Unicode encoding, use the name UTF16 rather than AL16UTF16. AL16UTF16, which is the supported Oracle character set name for UTF-16 encoded data, is only for UTF-16 data that is in big-endian byte order. However, because you are allowed to set up data using the byte order of the system where you create the data file, the data in the data file can be either big-endian or little-endian. Therefore, a different character set name (UTF16) is used. The character set name AL16UTF16 is also supported. But if you specify AL16UTF16 for a data file that has little-endian byte order, then SQL*Loader issues a warning message and processes the data file as big-endian.

The CHARACTERSET parameter can be specified for primary data files and also for LOBFILEs and SDFs. All primary data files are assumed to be in the same character set. A CHARACTERSET parameter specified before the INFILE parameter applies to the entire list of primary data files. If the CHARACTERSET parameter is specified for primary data files, then the specified value will also be used as the default for LOBFILEs and SDFs. This default setting can be overridden by specifying the CHARACTERSET parameter with the LOBFILE or SDF specification.

The character set specified with the CHARACTERSET parameter does not apply to data in the control file (specified with INFILE). To load data in a character set other than the one specified for your session by the NLS_LANG parameter, you must place the data in a separate data file.

See Also:

Control File Character Set

The SQL*Loader control file itself is assumed to be in the character set specified for your session by the NLS_LANG parameter. If the control file character set is different from the data file character set, then keep the following issue in mind. Delimiters and comparison clause values specified in the SQL*Loader control file as character strings are converted from the control file character set to the data file character set before any comparisons are made. To ensure that the specifications are correct, you may prefer to specify hexadecimal strings, rather than character string values.

If hexadecimal strings are used with a data file in the UTF-16 Unicode encoding, then the byte order is different on a big-endian versus a little-endian system. For example, "," (comma) in UTF-16 on a big-endian system is X'002c'. On a little-endian system it is X'2c00'. SQL*Loader requires that you always specify hexadecimal strings in big-endian format. If necessary, SQL*Loader swaps the bytes before making comparisons. This allows the same syntax to be used in the control file on both a big-endian and a little-endian system.

Record terminators for data files that are in stream format in the UTF-16 Unicode encoding default to "\n" in UTF-16 (that is, 0x000A on a big-endian system and 0x0A00 on a little-endian system). You can override these default settings by using the "STR 'char_str'" or the "STR x'hex_str'" specification on the INFILE line. For example, you could use either of the following to specify that 'ab' is to be used as the record terminator, instead of '\n'.

INFILE myfile.dat "STR 'ab'"

INFILE myfile.dat "STR x'00410042'"

Any data included after the BEGINDATA statement is also assumed to be in the character set specified for your session by the NLS_LANG parameter.

For the SQL*Loader datatypes (CHAR, VARCHAR, VARCHARC, DATE, and EXTERNAL numerics), SQL*Loader supports lengths of character fields that are specified in either bytes (byte-length semantics) or characters (character-length semantics). For example, the specification CHAR(10) in the control file can mean 10 bytes or 10 characters. These are equivalent if the data file uses a single-byte character set. However, they are often different if the data file uses a multibyte character set.

To avoid insertion errors caused by expansion of character strings during character set conversion, use character-length semantics in both the data file and the target database columns.

Character-Length Semantics

Byte-length semantics are the default for all data files except those that use the UTF16 character set (which uses character-length semantics by default). To override the default you can specify CHAR or CHARACTER, as shown in the following syntax:

Description of char_length.gif follows
Description of the illustration char_length.gif

The LENGTH parameter is placed after the CHARACTERSET parameter in the SQL*Loader control file. The LENGTH parameter applies to the syntax specification for primary data files and also to LOBFILEs and secondary data files (SDFs). A LENGTH specification before the INFILE parameters applies to the entire list of primary data files. The LENGTH specification specified for the primary data file is used as the default for LOBFILEs and SDFs. You can override that default by specifying LENGTH with the LOBFILE or SDF specification. Unlike the CHARACTERSET parameter, the LENGTH parameter can also apply to data contained within the control file itself (that is, INFILE * syntax).

You can specify CHARACTER instead of CHAR for the LENGTH parameter.

If character-length semantics are being used for a SQL*Loader data file, then the following SQL*Loader datatypes will use character-length semantics:

  • CHAR

  • VARCHAR

  • VARCHARC

  • DATE

  • EXTERNAL numerics (INTEGER, FLOAT, DECIMAL, and ZONED)

For the VARCHAR datatype, the length subfield is still a binary SMALLINT length subfield, but its value indicates the length of the character string in characters.

The following datatypes use byte-length semantics even if character-length semantics are being used for the data file, because the data is binary, or is in a special binary-encoded form in the case of ZONED and DECIMAL:

  • INTEGER

  • SMALLINT

  • FLOAT

  • DOUBLE

  • BYTEINT

  • ZONED

  • DECIMAL

  • RAW

  • VARRAW

  • VARRAWC

  • GRAPHIC

  • GRAPHIC EXTERNAL

  • VARGRAPHIC

The start and end arguments to the POSITION parameter are interpreted in bytes, even if character-length semantics are in use in a data file. This is necessary to handle data files that have a mix of data of different datatypes, some of which use character-length semantics, and some of which use byte-length semantics. It is also needed to handle position with the VARCHAR datatype, which has a SMALLINT length field and then the character data. The SMALLINT length field takes up a certain number of bytes depending on the system (usually 2 bytes), but its value indicates the length of the character string in characters.

Character-length semantics in the data file can be used independent of whether character-length semantics are used for the database columns. Therefore, the data file and the database columns can use either the same or different length semantics.

Shift-sensitive Character Data

In general, loading shift-sensitive character data can be much slower than loading simple ASCII or EBCDIC data. The fastest way to load shift-sensitive character data is to use fixed-position fields without delimiters. To improve performance, remember the following points:

  • The field data must have an equal number of shift-out/shift-in bytes.

  • The field must start and end in single-byte mode.

  • It is acceptable for the first byte to be shift-out and the last byte to be shift-in.

  • The first and last characters cannot be multibyte.

  • If blanks are not preserved and multibyte-blank-checking is required, then a slower path is used. This can happen when the shift-in byte is the last byte of a field after single-byte blank stripping is performed.

Interrupted Loads

Loads are interrupted and discontinued for several reasons. A primary reason is space errors, in which SQL*Loader runs out of space for data rows or index entries. A load might also be discontinued because the maximum number of errors was exceeded, an unexpected error was returned to SQL*Loader from the server, a record was too long in the data file, or a Ctrl+C was executed.

The behavior of SQL*Loader when a load is discontinued varies depending on whether it is a conventional path load or a direct path load, and on the reason the load was interrupted. Additionally, when an interrupted load is continued, the use and value of the SKIP parameter can vary depending on the particular case. The following sections explain the possible scenarios.

Discontinued Conventional Path Loads

In a conventional path load, data is committed after all data in the bind array is loaded into all tables. If the load is discontinued, then only the rows that were processed up to the time of the last commit operation are loaded. There is no partial commit of data.

Discontinued Direct Path Loads

In a direct path load, the behavior of a discontinued load varies depending on the reason the load was discontinued:

Load Discontinued Because of Space Errors

If a load is discontinued because of space errors, then the behavior of SQL*Loader depends on whether you are loading data into multiple subpartitions.

  • Space errors when loading data into multiple subpartitions (that is, loading into a partitioned table, a composite partitioned table, or one partition of a composite partitioned table):

    If space errors occur when loading into multiple subpartitions, then the load is discontinued and no data is saved unless ROWS has been specified (in which case, all data that was previously committed will be saved). The reason for this behavior is that it is possible rows might be loaded out of order. This is because each row is assigned (not necessarily in order) to a partition and each partition is loaded separately. If the load discontinues before all rows assigned to partitions are loaded, then the row for record "n" may have been loaded, but not the row for record "n-1". Therefore, the load cannot be continued by simply using SKIP=N .

  • Space errors when loading data into an unpartitioned table, one partition of a partitioned table, or one subpartition of a composite partitioned table:

    If there is one INTO TABLE statement in the control file, then SQL*Loader commits as many rows as were loaded before the error occurred.

    If there are multiple INTO TABLE statements in the control file, then SQL*Loader loads data already read from the data file into other tables and then commits the data.

    In either case, this behavior is independent of whether the ROWS parameter was specified. When you continue the load, you can use the SKIP parameter to skip rows that have already been loaded. In the case of multiple INTO TABLE statements, a different number of rows could have been loaded into each table, so to continue the load you would need to specify a different value for the SKIP parameter for every table. SQL*Loader only reports the value for the SKIP parameter if it is the same for all tables.

Load Discontinued Because Maximum Number of Errors Exceeded

If the maximum number of errors is exceeded, then SQL*Loader stops loading records into any table and the work done to that point is committed. This means that when you continue the load, the value you specify for the SKIP parameter may be different for different tables. SQL*Loader reports the value for the SKIP parameter only if it is the same for all tables.

Load Discontinued Because of Fatal Errors

If a fatal error is encountered, then the load is stopped and no data is saved unless ROWS was specified at the beginning of the load. In that case, all data that was previously committed is saved. SQL*Loader reports the value for the SKIP parameter only if it is the same for all tables.

Load Discontinued Because a Ctrl+C Was Issued

If SQL*Loader is in the middle of saving data when a Ctrl+C is issued, then it continues to do the save and then stops the load after the save completes. Otherwise, SQL*Loader stops the load without committing any work that was not committed already. This means that the value of the SKIP parameter will be the same for all tables.

Status of Tables and Indexes After an Interrupted Load

When a load is discontinued, any data already loaded remains in the tables, and the tables are left in a valid state. If the conventional path is used, then all indexes are left in a valid state.

If the direct path load method is used, then any indexes on the table are left in an unusable state. You can either rebuild or re-create the indexes before continuing, or after the load is restarted and completes.

Other indexes are valid if no other errors occurred. See "Indexes Left in an Unusable State" for other reasons why an index might be left in an unusable state.

Using the Log File to Determine Load Status

The SQL*Loader log file tells you the state of the tables and indexes and the number of logical records already read from the input data file. Use this information to resume the load where it left off.

Continuing Single-Table Loads

When SQL*Loader must discontinue a direct path or conventional path load before it is finished, some rows have probably already been committed or marked with savepoints. To continue the discontinued load, use the SKIP parameter to specify the number of logical records that have already been processed by the previous load. At the time the load is discontinued, the value for SKIP is written to the log file in a message similar to the following:

Specify SKIP=1001 when continuing the load.

This message specifying the value of the SKIP parameter is preceded by a message indicating why the load was discontinued.

Note that for multiple-table loads, the value of the SKIP parameter is displayed only if it is the same for all tables.

Assembling Logical Records from Physical Records

As of Oracle9i, user-defined record sizes larger than 64 KB are supported (see "READSIZE (read buffer size)"). This reduces the need to break up logical records into multiple physical records. However, there may still be situations in which you may want to do so. At some point, when you want to combine those multiple physical records back into one logical record, you can use one of the following clauses, depending on your data:

Using CONCATENATE to Assemble Logical Records

Use CONCATENATE when you want SQL*Loader to always combine the same number of physical records to form one logical record. In the following example, integer specifies the number of physical records to combine.

CONCATENATE  integer 

The integer value specified for CONCATENATE determines the number of physical record structures that SQL*Loader allocates for each row in the column array. In direct path loads, the default value for COLUMNARRAYROWS is large, so if you also specify a large value for CONCATENATE, then excessive memory allocation can occur. If this happens, you can improve performance by reducing the value of the COLUMNARRAYROWS parameter to lower the number of rows in a column array.

Using CONTINUEIF to Assemble Logical Records

Use CONTINUEIF if the number of physical records to be combined varies. The CONTINUEIF clause is followed by a condition that is evaluated for each physical record, as it is read. For example, two records might be combined if a pound sign (#) were in byte position 80 of the first record. If any other character were there, then the second record would not be added to the first.

The full syntax for CONTINUEIF adds even more flexibility:

Description of continueif.gif follows
Description of the illustration continueif.gif

Table 9-2 describes the parameters for the CONTINUEIF clause.

Table 9-2 Parameters for the CONTINUEIF Clause

Parameter Description

THIS

If the condition is true in the current record, then the next physical record is read and concatenated to the current physical record, continuing until the condition is false. If the condition is false, then the current physical record becomes the last physical record of the current logical record. THIS is the default.

NEXT

If the condition is true in the next record, then the current physical record is concatenated to the current logical record, continuing until the condition is false.

operator

The supported operators are equal (=) and not equal (!= or <>).

For the equal operator, the field and comparison string must match exactly for the condition to be true. For the not equal operator, they can differ in any character.

LAST

This test is similar to THIS, but the test is always against the last nonblank character. If the last nonblank character in the current physical record meets the test, then the next physical record is read and concatenated to the current physical record, continuing until the condition is false. If the condition is false in the current record, then the current physical record is the last physical record of the current logical record.

LAST allows only a single character-continuation field (as opposed to THIS and NEXT, which allow multiple character-continuation fields).

pos_spec

Specifies the starting and ending column numbers in the physical record.

Column numbers start with 1. Either a hyphen or a colon is acceptable (start-end or start:end).

If you omit end, then the length of the continuation field is the length of the byte string or character string. If you use end, and the length of the resulting continuation field is not the same as that of the byte string or the character string, then the shorter one is padded. Character strings are padded with blanks, hexadecimal strings with zeros.

str

A string of characters to be compared to the continuation field defined by start and end, according to the operator. The string must be enclosed in double or single quotation marks. The comparison is made character by character, blank padding on the right if necessary.

X'hex-str'

A string of bytes in hexadecimal format used in the same way as str.X'1FB033' would represent the three bytes with values 1F, B0, and 33 (hexadecimal).

PRESERVE

Includes 'char_string' or X'hex_string' in the logical record. The default is to exclude them.


The positions in the CONTINUEIF clause refer to positions in each physical record. This is the only time you refer to positions in physical records. All other references are to logical records.

For CONTINUEIF THIS and CONTINUEIF LAST, if the PRESERVE parameter is not specified, then the continuation field is removed from all physical records when the logical record is assembled. That is, data values are allowed to span the records with no extra characters (continuation characters) in the middle. For example, if CONTINUEIF THIS(3:5)='***' is specified, then positions 3 through 5 are removed from all records. This means that the continuation characters are removed if they are in positions 3 through 5 of the record. It also means that the characters in positions 3 through 5 are removed from the record even if the continuation characters are not in positions 3 through 5.

For CONTINUEIF THIS and CONTINUEIF LAST, if the PRESERVE parameter is used, then the continuation field is kept in all physical records when the logical record is assembled.

CONTINUEIF LAST differs from CONTINUEIF THIS and CONTINUEIF NEXT. For CONTINUEIF LAST, where the positions of the continuation field vary from record to record, the continuation field is never removed, even if PRESERVE is not specified.

Example 9-3 through Example 9-6 show the use of CONTINUEIF THIS and CONTINUEIF NEXT, with and without the PRESERVE parameter.

Example 9-3 CONTINUEIF THIS Without the PRESERVE Parameter

Assume that you have physical records 14 bytes long and that a period represents a space:

%%aaaaaaaa....
        %%bbbbbbbb....
        ..cccccccc....
        %%dddddddddd..
        %%eeeeeeeeee..
        ..ffffffffff..

In this example, the CONTINUEIF THIS clause does not use the PRESERVE parameter:

CONTINUEIF THIS (1:2) = '%%'

Therefore, the logical records are assembled as follows:

aaaaaaaa....bbbbbbbb....cccccccc....
        dddddddddd..eeeeeeeeee..ffffffffff..

Note that columns 1 and 2 (for example, %% in physical record 1) are removed from the physical records when the logical records are assembled.

Example 9-4 CONTINUEIF THIS with the PRESERVE Parameter

Assume that you have the same physical records as in Example 9-3.

In this example, the CONTINUEIF THIS clause uses the PRESERVE parameter:

CONTINUEIF THIS PRESERVE (1:2) = '%%'

Therefore, the logical records are assembled as follows:

%%aaaaaaaa....%%bbbbbbbb......cccccccc....
        %%dddddddddd..%%eeeeeeeeee....ffffffffff..

Note that columns 1 and 2 are not removed from the physical records when the logical records are assembled.

Example 9-5 CONTINUEIF NEXT Without the PRESERVE Parameter

Assume that you have physical records 14 bytes long and that a period represents a space:

..aaaaaaaa....
        %%bbbbbbbb....
        %%cccccccc....
        ..dddddddddd..
        %%eeeeeeeeee..
        %%ffffffffff..

In this example, the CONTINUEIF NEXT clause does not use the PRESERVE parameter:

CONTINUEIF NEXT (1:2) = '%%'

Therefore, the logical records are assembled as follows (the same results as for Example 9-3).

aaaaaaaa....bbbbbbbb....cccccccc....
        dddddddddd..eeeeeeeeee..ffffffffff..

Example 9-6 CONTINUEIF NEXT with the PRESERVE Parameter

Assume that you have the same physical records as in Example 9-5.

In this example, the CONTINUEIF NEXT clause uses the PRESERVE parameter:

CONTINUEIF NEXT PRESERVE (1:2) = '%%'

Therefore, the logical records are assembled as follows:

..aaaaaaaa....%%bbbbbbbb....%%cccccccc....
        ..dddddddddd..%%eeeeeeeeee..%%ffffffffff..

See Also:

Case study 4, Loading Combined Physical Records, for an example of the CONTINUEIF clause. (See "SQL*Loader Case Studies" for information on how to access case studies.)

Loading Logical Records into Tables

This section describes the way in which you specify:

Specifying Table Names

The INTO TABLE clause of the LOAD DATA statement enables you to identify tables, fields, and datatypes. It defines the relationship between records in the data file and tables in the database. The specification of fields and datatypes is described in later sections.

INTO TABLE Clause

Among its many functions, the INTO TABLE clause enables you to specify the table into which you load data. To load multiple tables, you include one INTO TABLE clause for each table you want to load.

To begin an INTO TABLE clause, use the keywords INTO TABLE, followed by the name of the Oracle table that is to receive the data.

The syntax is as follows:

Description of into_table1.gif follows
Description of the illustration into_table1.gif

The table must already exist. The table name should be enclosed in double quotation marks if it is the same as any SQL or SQL*Loader reserved keyword, if it contains any special characters, or if it is case sensitive.

INTO TABLE scott."CONSTANT"
INTO TABLE scott."Constant" 
INTO TABLE scott."-CONSTANT" 

The user must have INSERT privileges for the table being loaded. If the table is not in the user's schema, then the user must either use a synonym to reference the table or include the schema name as part of the table name (for example, scott.emp refers to the table emp in the scott schema).

Note:

SQL*Loader considers the default schema to be whatever schema is current after your connect to the database finishes executing. This means that the default schema will not necessarily be the one you specified in the connect string, if there are logon triggers present that get executed during connection to a database.

If you have a logon trigger that changes your current schema to a different one when you connect to a certain database, then SQL*Loader uses that new schema as the default.

Table-Specific Loading Method

When you are loading a table, you can use the INTO TABLE clause to specify a table-specific loading method (INSERT, APPEND, REPLACE, or TRUNCATE) that applies only to that table. That method overrides the global table-loading method. The global table-loading method is INSERT, by default, unless a different method was specified before any INTO TABLE clauses. The following sections discuss using these options to load data into empty and nonempty tables.

Loading Data into Empty Tables

If the tables you are loading into are empty, then use the INSERT option.

INSERT

This is SQL*Loader's default method. It requires the table to be empty before loading. SQL*Loader terminates with an error if the table contains rows. Case study 1, Loading Variable-Length Data, provides an example. (See "SQL*Loader Case Studies" for information on how to access case studies.)

Loading Data into Nonempty Tables

If the tables you are loading into already contain data, then you have three options:

  • APPEND

  • REPLACE

  • TRUNCATE

    Caution:

    When REPLACE or TRUNCATE is specified, the entire table is replaced, not just individual rows. After the rows are successfully deleted, a COMMIT statement is issued. You cannot recover the data that was in the table before the load, unless it was saved with Export or a comparable utility.
APPEND

If data already exists in the table, then SQL*Loader appends the new rows to it. If data does not already exist, then the new rows are simply loaded. You must have SELECT privilege to use the APPEND option. Case study 3, Loading a Delimited Free-Format File, provides an example. (See "SQL*Loader Case Studies" for information on how to access case studies.)

REPLACE

The REPLACE option executes a SQL DELETE FROM TABLE statement. All rows in the table are deleted and the new data is loaded. The table must be in your schema, or you must have DELETE privilege on the table. Case study 4, Loading Combined Physical Records, provides an example. (See "SQL*Loader Case Studies" for information on how to access case studies.)

The row deletes cause any delete triggers defined on the table to fire. If DELETE CASCADE has been specified for the table, then the cascaded deletes are carried out. For more information about cascaded deletes, see the information about data integrity in Oracle Database Concepts.

Updating Existing Rows

The REPLACE method is a table replacement, not a replacement of individual rows. SQL*Loader does not update existing records, even if they have null columns. To update existing rows, use the following procedure:

  1. Load your data into a work table.

  2. Use the SQL UPDATE statement with correlated subqueries.

  3. Drop the work table.

TRUNCATE

The TRUNCATE option executes a SQL TRUNCATE TABLE table_name REUSE STORAGE statement, which means that the table's extents will be reused. The TRUNCATE option quickly and efficiently deletes all rows from a table or cluster, to achieve the best possible performance. For the TRUNCATE statement to operate, the table's referential integrity constraints must first be disabled. If they have not been disabled, then SQL*Loader returns an error.

Once the integrity constraints have been disabled, DELETE CASCADE is no longer defined for the table. If the DELETE CASCADE functionality is needed, then the contents of the table must be manually deleted before the load begins.

The table must be in your schema, or you must have the DROP ANY TABLE privilege.

See Also:

Oracle Database SQL Language Reference for more information about the SQL statements discussed in this section

Table-Specific OPTIONS Parameter

The OPTIONS parameter can be specified for individual tables in a parallel load. (It is valid only for a parallel load.)

The syntax for the OPTIONS parameter is as follows:

Description of into_table3.gif follows
Description of the illustration into_table3.gif

Loading Records Based on a Condition

You can choose to load or discard a logical record by using the WHEN clause to test a condition in the record.

The WHEN clause appears after the table name and is followed by one or more field conditions. The syntax for field_condition is as follows:

Description of fld_cond.gif follows
Description of the illustration fld_cond.gif

For example, the following clause indicates that any record with the value "q" in the fifth column position should be loaded:

WHEN (5) = 'q' 

A WHEN clause can contain several comparisons, provided each is preceded by AND. Parentheses are optional, but should be used for clarity with multiple comparisons joined by AND. For example:

WHEN (deptno = '10') AND (job = 'SALES') 

See Also:

Using the WHEN Clause with LOBFILEs and SDFs

If a record with a LOBFILE or SDF is discarded, then SQL*Loader skips the corresponding data in that LOBFILE or SDF.

Specifying Default Data Delimiters

If all data fields are terminated similarly in the data file, then you can use the FIELDS clause to indicate the default delimiters. The syntax for the fields_spec, termination_spec, and enclosure_spec clauses is as follows:

termination_spec

Description of terminat.gif follows
Description of the illustration terminat.gif

Note:

Terminator strings can contain one or more characters. Also, TERMINATED BY EOF applies only to loading LOBs from a LOBFILE.

enclosure_spec

Description of enclose.gif follows
Description of the illustration enclose.gif

Note:

Enclosure strings can contain one or more characters.

You can override the delimiter for any given column by specifying it after the column name. Case study 3, Loading a Delimited Free-Format File, provides an example. (See "SQL*Loader Case Studies" for information on how to access case studies.)

See Also:

Handling Short Records with Missing Data

When the control file definition specifies more fields for a record than are present in the record, SQL*Loader must determine whether the remaining (specified) columns should be considered null or whether an error should be generated.

If the control file definition explicitly states that a field's starting position is beyond the end of the logical record, then SQL*Loader always defines the field as null. If a field is defined with a relative position (such as dname and loc in the following example), and the record ends before the field is found, then SQL*Loader could either treat the field as null or generate an error. SQL*Loader uses the presence or absence of the TRAILING NULLCOLS clause (shown in the following syntax diagram) to determine the course of action.

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Description of the illustration into_table6.gif

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Description of the illustration into_table7.gif

TRAILING NULLCOLS Clause

The TRAILING NULLCOLS clause tells SQL*Loader to treat any relatively positioned columns that are not present in the record as null columns.

For example, consider the following data:

10 Accounting 

Assume that the preceding data is read with the following control file and the record ends after dname:

INTO TABLE dept 
    TRAILING NULLCOLS 
( deptno CHAR TERMINATED BY " ", 
  dname  CHAR TERMINATED BY WHITESPACE, 
  loc    CHAR TERMINATED BY WHITESPACE 
) 

In this case, the remaining loc field is set to null. Without the TRAILING NULLCOLS clause, an error would be generated due to missing data.

See Also:

Case study 7, Extracting Data from a Formatted Report, for an example of using TRAILING NULLCOLS (see "SQL*Loader Case Studies" for information on how to access case studies)

Index Options

This section describes the following SQL*Loader options that control how index entries are created:

SORTED INDEXES Clause

The SORTED INDEXES clause applies to direct path loads. It tells SQL*Loader that the incoming data has already been sorted on the specified indexes, allowing SQL*Loader to optimize performance.

SINGLEROW Option

The SINGLEROW option is intended for use during a direct path load with APPEND on systems with limited memory, or when loading a small number of records into a large table. This option inserts each index entry directly into the index, one record at a time.

By default, SQL*Loader does not use SINGLEROW to append records to a table. Instead, index entries are put into a separate, temporary storage area and merged with the original index at the end of the load. This method achieves better performance and produces an optimal index, but it requires extra storage space. During the merge operation, the original index, the new index, and the space for new entries all simultaneously occupy storage space.

With the SINGLEROW option, storage space is not required for new index entries or for a new index. The resulting index may not be as optimal as a freshly sorted one, but it takes less space to produce. It also takes more time because additional UNDO information is generated for each index insert. This option is suggested for use when either of the following situations exists:

  • Available storage is limited.

  • The number of records to be loaded is small compared to the size of the table (a ratio of 1:20 or less is recommended).

Benefits of Using Multiple INTO TABLE Clauses

Multiple INTO TABLE clauses enable you to:

In the first case, it is common for the INTO TABLE clauses to refer to the same table. This section illustrates the different ways to use multiple INTO TABLE clauses and shows you how to use the POSITION parameter.

Note:

A key point when using multiple INTO TABLE clauses is that field scanning continues from where it left off when a new INTO TABLE clause is processed. The remainder of this section details important ways to make use of that behavior. It also describes alternative ways of using fixed field locations or the POSITION parameter.

Extracting Multiple Logical Records

Some data storage and transfer media have fixed-length physical records. When the data records are short, more than one can be stored in a single, physical record to use the storage space efficiently.

In this example, SQL*Loader treats a single physical record in the input file as two logical records and uses two INTO TABLE clauses to load the data into the emp table. For example, assume the data is as follows:

1119 Smith      1120 Yvonne 
1121 Albert     1130 Thomas 

The following control file extracts the logical records:

INTO TABLE emp 
     (empno POSITION(1:4)  INTEGER EXTERNAL, 
      ename POSITION(6:15) CHAR) 
INTO TABLE emp 
     (empno POSITION(17:20) INTEGER EXTERNAL, 
      ename POSITION(21:30) CHAR) 

Relative Positioning Based on Delimiters

The same record could be loaded with a different specification. The following control file uses relative positioning instead of fixed positioning. It specifies that each field is delimited by a single blank (" ") or with an undetermined number of blanks and tabs (WHITESPACE):

INTO TABLE emp 
     (empno INTEGER EXTERNAL TERMINATED BY " ", 
      ename CHAR             TERMINATED BY WHITESPACE) 
INTO TABLE emp 
     (empno INTEGER EXTERNAL TERMINATED BY " ", 
      ename CHAR)            TERMINATED BY WHITESPACE) 

The important point in this example is that the second empno field is found immediately after the first ename, although it is in a separate INTO TABLE clause. Field scanning does not start over from the beginning of the record for a new INTO TABLE clause. Instead, scanning continues where it left off.

To force record scanning to start in a specific location, you use the POSITION parameter. That mechanism is described in "Distinguishing Different Input Record Formats" and in "Loading Data into Multiple Tables".

Distinguishing Different Input Record Formats

A single data file might contain records in a variety of formats. Consider the following data, in which emp and dept records are intermixed:

1 50   Manufacturing       — DEPT record 
2 1119 Smith      50       — EMP record 
2 1120 Snyder     50 
1 60   Shipping 
2 1121 Stevens    60 

A record ID field distinguishes between the two formats. Department records have a 1 in the first column, while employee records have a 2. The following control file uses exact positioning to load this data:

INTO TABLE dept 
   WHEN recid = 1 
   (recid  FILLER POSITION(1:1)  INTEGER EXTERNAL,
    deptno POSITION(3:4)  INTEGER EXTERNAL, 
    dname  POSITION(8:21) CHAR) 
INTO TABLE emp 
   WHEN recid <> 1 
   (recid  FILLER POSITION(1:1)   INTEGER EXTERNAL,
    empno  POSITION(3:6)   INTEGER EXTERNAL, 
    ename  POSITION(8:17)  CHAR, 
    deptno POSITION(19:20) INTEGER EXTERNAL) 

Relative Positioning Based on the POSITION Parameter

The records in the previous example could also be loaded as delimited data. In this case, however, it is necessary to use the POSITION parameter. The following control file could be used:

INTO TABLE dept 
   WHEN recid = 1 
   (recid  FILLER INTEGER EXTERNAL TERMINATED BY WHITESPACE, 
    deptno INTEGER EXTERNAL TERMINATED BY WHITESPACE, 
    dname  CHAR TERMINATED BY WHITESPACE) 
INTO TABLE emp 
   WHEN recid <> 1 
   (recid  FILLER POSITION(1) INTEGER EXTERNAL TERMINATED BY ' ', 
    empno  INTEGER EXTERNAL TERMINATED BY ' ' 
    ename  CHAR TERMINATED BY WHITESPACE, 
    deptno INTEGER EXTERNAL TERMINATED BY ' ') 

The POSITION parameter in the second INTO TABLE clause is necessary to load this data correctly. It causes field scanning to start over at column 1 when checking for data that matches the second format. Without it, SQL*Loader would look for the recid field after dname.

Distinguishing Different Input Row Object Subtypes

A single data file may contain records made up of row objects inherited from the same base row object type. For example, consider the following simple object type and object table definitions, in which a nonfinal base object type is defined along with two object subtypes that inherit their row objects from the base type:

CREATE TYPE person_t AS OBJECT 
 (name    VARCHAR2(30), 
  age     NUMBER(3)) not final; 

CREATE TYPE employee_t UNDER person_t 
 (empid   NUMBER(5), 
  deptno  NUMBER(4), 
  dept    VARCHAR2(30)) not final; 

CREATE TYPE student_t UNDER person_t 
 (stdid   NUMBER(5), 
  major   VARCHAR2(20)) not final; 

CREATE TABLE persons OF person_t;

The following input data file contains a mixture of these row objects subtypes. A type ID field distinguishes between the three subtypes. person_t objects have a P in the first column, employee_t objects have an E, and student_t objects have an S.

P,James,31, 
P,Thomas,22, 
E,Pat,38,93645,1122,Engineering, 
P,Bill,19, 
P,Scott,55, 
S,Judy,45,27316,English, 
S,Karen,34,80356,History, 
E,Karen,61,90056,1323,Manufacturing, 
S,Pat,29,98625,Spanish, 
S,Cody,22,99743,Math, 
P,Ted,43, 
E,Judy,44,87616,1544,Accounting, 
E,Bob,50,63421,1314,Shipping, 
S,Bob,32,67420,Psychology, 
E,Cody,33,25143,1002,Human Resources,

The following control file uses relative positioning based on the POSITION parameter to load this data. Note the use of the TREAT AS clause with a specific object type name. This informs SQL*Loader that all input row objects for the object table will conform to the definition of the named object type.

Note:

Multiple subtypes cannot be loaded with the same INTO TABLE statement. Instead, you must use multiple INTO TABLE statements and have each one load a different subtype.
INTO TABLE persons 
REPLACE 
WHEN typid = 'P' TREAT AS person_t 
FIELDS TERMINATED BY "," 
 (typid   FILLER  POSITION(1) CHAR, 
  name            CHAR, 
  age             CHAR) 

INTO TABLE persons 
REPLACE 
WHEN typid = 'E' TREAT AS employee_t 
FIELDS TERMINATED BY "," 
 (typid   FILLER  POSITION(1) CHAR, 
  name            CHAR, 
  age             CHAR, 
  empid           CHAR, 
  deptno          CHAR, 
  dept            CHAR) 

INTO TABLE persons 
REPLACE 
WHEN typid = 'S' TREAT AS student_t 
FIELDS TERMINATED BY "," 
 (typid   FILLER  POSITION(1) CHAR, 
  name            CHAR, 
  age             CHAR, 
  stdid           CHAR, 
  major           CHAR)

See Also:

"Loading Column Objects" for more information about loading object types

Loading Data into Multiple Tables

By using the POSITION parameter with multiple INTO TABLE clauses, data from a single record can be loaded into multiple normalized tables. See case study 5, Loading Data into Multiple Tables, for an example. (See "SQL*Loader Case Studies" for information about how to access case studies.).

Summary

Multiple INTO TABLE clauses allow you to extract multiple logical records from a single input record and recognize different record formats in the same file.

For delimited data, proper use of the POSITION parameter is essential for achieving the expected results.

When the POSITION parameter is not used, multiple INTO TABLE clauses process different parts of the same (delimited data) input record, allowing multiple tables to be loaded from one record. When the POSITION parameter is used, multiple INTO TABLE clauses can process the same record in different ways, allowing multiple formats to be recognized in one input file.

Bind Arrays and Conventional Path Loads

SQL*Loader uses the SQL array-interface option to transfer data to the database. Multiple rows are read at one time and stored in the bind array. When SQL*Loader sends the Oracle database an INSERT command, the entire array is inserted at one time. After the rows in the bind array are inserted, a COMMIT statement is issued.

The determination of bind array size pertains to SQL*Loader's conventional path option. It does not apply to the direct path load method because a direct path load uses the direct path API, rather than Oracle's SQL interface.

See Also:

Oracle Call Interface Programmer's Guide for more information about the concepts of direct path loading

Size Requirements for Bind Arrays

The bind array must be large enough to contain a single row. If the maximum row length exceeds the size of the bind array, as specified by the BINDSIZE parameter, then SQL*Loader generates an error. Otherwise, the bind array contains as many rows as can fit within it, up to the limit set by the value of the ROWS parameter. (The maximum value for ROWS in a conventional path load is 65534.)

Although the entire bind array need not be in contiguous memory, the buffer for each field in the bind array must occupy contiguous memory. If the operating system cannot supply enough contiguous memory to store a field, then SQL*Loader generates an error.

Performance Implications of Bind Arrays

Large bind arrays minimize the number of calls to the Oracle database and maximize performance. In general, you gain large improvements in performance with each increase in the bind array size up to 100 rows. Increasing the bind array size to be greater than 100 rows generally delivers more modest improvements in performance. The size (in bytes) of 100 rows is typically a good value to use.

In general, any reasonably large size permits SQL*Loader to operate effectively. It is not usually necessary to perform the detailed calculations described in this section. Read this section when you need maximum performance or an explanation of memory usage.

Specifying Number of Rows Versus Size of Bind Array

When you specify a bind array size using the command-line parameter BINDSIZE or the OPTIONS clause in the control file, you impose an upper limit on the bind array. The bind array never exceeds that maximum.

As part of its initialization, SQL*Loader determines the size in bytes required to load a single row. If that size is too large to fit within the specified maximum, then the load terminates with an error.

SQL*Loader then multiplies that size by the number of rows for the load, whether that value was specified with the command-line parameter ROWS or the OPTIONS clause in the control file.

If that size fits within the bind array maximum, then the load continues—SQL*Loader does not try to expand the number of rows to reach the maximum bind array size. If the number of rows and the maximum bind array size are both specified, then SQL*Loader always uses the smaller value for the bind array.

If the maximum bind array size is too small to accommodate the initial number of rows, then SQL*Loader uses a smaller number of rows that fits within the maximum.

Calculations to Determine Bind Array Size

The bind array's size is equivalent to the number of rows it contains times the maximum length of each row. The maximum length of a row equals the sum of the maximum field lengths, plus overhead, as follows:

bind array size =
    (number of rows) * (  SUM(fixed field lengths)
                        + SUM(maximum varying field lengths)
                        + ( (number of varying length fields)
                             * (size of length indicator) )
                       )

Many fields do not vary in size. These fixed-length fields are the same for each loaded row. For these fields, the maximum length of the field is the field size, in bytes, as described in "SQL*Loader Datatypes". There is no overhead for these fields.

The fields that can vary in size from row to row are:

  • CHAR

  • DATE

  • INTERVAL DAY TO SECOND

  • INTERVAL DAY TO YEAR

  • LONG VARRAW

  • numeric EXTERNAL

  • TIME

  • TIMESTAMP

  • TIME WITH TIME ZONE

  • TIMESTAMP WITH TIME ZONE

  • VARCHAR

  • VARCHARC

  • VARGRAPHIC

  • VARRAW

  • VARRAWC

The maximum length of these datatypes is described in "SQL*Loader Datatypes". The maximum lengths describe the number of bytes that the fields can occupy in the input data record. That length also describes the amount of storage that each field occupies in the bind array, but the bind array includes additional overhead for fields that can vary in size.

When the character datatypes (CHAR, DATE, and numeric EXTERNAL) are specified with delimiters, any lengths specified for these fields are maximum lengths. When specified without delimiters, the size in the record is fixed, but the size of the inserted field may still vary, due to whitespace trimming. So internally, these datatypes are always treated as varying-length fields—even when they are fixed-length fields.

A length indicator is included for each of these fields in the bind array. The space reserved for the field in the bind array is large enough to hold the longest possible value of the field. The length indicator gives the actual length of the field for each row.

Note:

In conventional path loads, LOBFILEs are not included when allocating the size of a bind array.

Determining the Size of the Length Indicator

On most systems, the size of the length indicator is 2 bytes. On a few systems, it is 3 bytes. To determine its size, use the following control file:

OPTIONS (ROWS=1) 
LOAD DATA 
INFILE * 
APPEND 
INTO TABLE DEPT 
(deptno POSITION(1:1) CHAR(1)) 
BEGINDATA 
a 

This control file loads a 1-byte CHAR using a 1-row bind array. In this example, no data is actually loaded because a conversion error occurs when the character a is loaded into a numeric column (deptno). The bind array size shown in the log file, minus one (the length of the character field) is the value of the length indicator.

Note:

A similar technique can determine bind array size without doing any calculations. Run your control file without any data and with ROWS=1 to determine the memory requirements for a single row of data. Multiply by the number of rows you want in the bind array to determine the bind array size.

Calculating the Size of Field Buffers

Table 9-3 through Table 9-6 summarize the memory requirements for each datatype. "L" is the length specified in the control file. "P" is precision. "S" is the size of the length indicator. For more information about these values, see "SQL*Loader Datatypes".

Table 9-3 Fixed-Length Fields

Datatype Size in Bytes (Operating System-Dependent)

INTEGER

The size of the INT datatype, in C

INTEGER(N)

N bytes

SMALLINT

The size of SHORT INT datatype, in C

FLOAT

The size of the FLOAT datatype, in C

DOUBLE

The size of the DOUBLE datatype, in C

BYTEINT

The size of UNSIGNED CHAR, in C

VARRAW

The size of UNSIGNED SHORT, plus 4096 bytes or whatever is specified as max_length

LONG VARRAW

The size of UNSIGNED INT, plus 4096 bytes or whatever is specified as max_length

VARCHARC

Composed of 2 numbers. The first specifies length, and the second (which is optional) specifies max_length (default is 4096 bytes).

VARRAWC

This datatype is for RAW data. It is composed of 2 numbers. The first specifies length, and the second (which is optional) specifies max_length (default is 4096 bytes).


Table 9-4 Nongraphic Fields

Datatype Default Size Specified Size

(packed) DECIMAL

None

(N+1)/2, rounded up

ZONED

None

P

RAW

None

L

CHAR (no delimiters)

1

L + S

datetime and interval (no delimiters)

None

L + S

numeric EXTERNAL (no delimiters)

None

L + S


Table 9-5 Graphic Fields

Datatype Default Size Length Specified with POSITION Length Specified with DATATYPE

GRAPHIC

None

L

2*L

GRAPHIC EXTERNAL

None

L - 2

2*(L-2)

VARGRAPHIC

4KB*2

L+S

(2*L)+S


Table 9-6 Variable-Length Fields

Datatype Default Size Maximum Length Specified (L)

VARCHAR

4 KB

L+S

CHAR (delimited)

255

L+S

datetime and interval (delimited)

255

L+S

numeric EXTERNAL (delimited)

255

L+S


Minimizing Memory Requirements for Bind Arrays

Pay particular attention to the default sizes allocated for VARCHAR, VARGRAPHIC, and the delimited forms of CHAR, DATE, and numeric EXTERNAL fields. They can consume enormous amounts of memory—especially when multiplied by the number of rows in the bind array. It is best to specify the smallest possible maximum length for these fields. Consider the following example:

CHAR(10) TERMINATED BY "," 

With byte-length semantics, this example uses (10 + 2) * 64 = 768 bytes in the bind array, assuming that the length indicator is 2 bytes long and that 64 rows are loaded at a time.

With character-length semantics, the same example uses ((10 * s) + 2) * 64 bytes in the bind array, where "s" is the maximum size in bytes of a character in the data file character set.

Now consider the following example:

CHAR TERMINATED BY "," 

Regardless of whether byte-length semantics or character-length semantics are used, this example uses (255 + 2) * 64 = 16,448 bytes, because the default maximum size for a delimited field is 255 bytes. This can make a considerable difference in the number of rows that fit into the bind array.

Calculating Bind Array Size for Multiple INTO TABLE Clauses

When calculating a bind array size for a control file that has multiple INTO TABLE clauses, calculate as if the INTO TABLE clauses were not present. Imagine all of the fields listed in the control file as one, long data structure—that is, the format of a single row in the bind array.

If the same field in the data record is mentioned in multiple INTO TABLE clauses, then additional space in the bind array is required each time it is mentioned. It is especially important to minimize the buffer allocations for such fields.

Note:

Generated data is produced by the SQL*Loader functions CONSTANT, EXPRESSION, RECNUM, SYSDATE, and SEQUENCE. Such generated data does not require any space in the bind array.