- String Processing
- Introduction
- Data Types for Character Strings
- Declaring Character-Like Data Objects
- Assigning Values
- String Templates
- Determining the Length of Strings
- Concatenating Strings
- Splitting Strings
- Modifying Strings
- Processing Substrings
- Searching and Replacing
- Pattern-Based Searching and Replacing in Strings
- More String Functions
- Excursions
- Executable Example
ABAP offers plenty of options for processing character strings.
The options include ABAP statements (e. g. FIND
),
character string expressions
(concatenations and string templates)
and built-in string functions
(e. g. strlen
).
💡 Note
- Compared to statements, expressions and string functions can help make your ABAP code more concise and straightforward. For example, you can perform string operations directly in operand position, allowing you to avoid temporary variables.
- In ABAP statements, modification operations on strings are often performed in read/write positions, meaning that the source and target fields of an operation are the same. When working with string functions, the source field is passed as an input parameter and the modified value is returned as a return value, meaning that the function itself does not modify the source field. Of course, you can assign the function to the source field to achieve its modification.
- In most cases, string functions provide the same functionality as the corresponding ABAP statements, or even more. The return value of string functions that return character strings is always of type
string
.
ABAP provides the following built-in data types for data objects that contain character strings. They are distinguished as follows:
Type | Details | Length | Value Range | Initial Value |
---|---|---|---|---|
string |
For variable length character strings. Data objects of this type are dynamic data objects, i. e. the length of a variable can change during the execution of an ABAP program and thus it can contain character strings of different lengths. A data object of type string is called text string or, in short, just string. |
No standard length; length is variable | Any Unicode characters that can be encoded in ABAP language's code page UCS-2. The most common content are alphanumeric characters or special characters. | Empty string with length 0 |
c |
For fixed length character strings. Data objects of this type are static data objects, i. e. the length of a variable must be defined during its declaration and does not change during the execution of an ABAP program. Thus, it always contains character strings of the same length. A data object of type c is called text field. |
Data objects of this type can contain a string of fixed length (between 1 and 262143 characters); standard length: 1 | Same as for string |
A blank for each position |
In addition to these main data types for character strings, there are several other fixed length data types with special meanings:
n
for fixed length numerical character strings- Data objects of this type are technically almost the same as text fields. However, the only valid characters are the digits 0 to 9. Validity is not checked for assigning values in a regular way but only for lossless assignments. Thus, such numeric text fields can contain invalid data, but should only be used for digits that are not intended for arithmetic calculations, such as zip codes or article numbers. The initial value for each position is 0.
d
andt
for date and time fields- These data types have a predefiend length of 6 and 8. Data objects of these types are used for character representations of dates and times in a predefined format. You can use them directly in date and time calculations. However, these fields can also contain invalid values.
These data types are not covered further in this cheat sheet. The same is true for the byte-like data types x
and xstring
that are closely related to c
and string
but contain raw byte strings.
⚡ Differences between text strings (variable length) and text fields (fixed length)
- Initial value: The initial value of a text string is an empty string of length 0. The initial value of text field is represented by blanks at each position.
- Internal representation: Data objects of type
c
andstring
are both elementary data objects. However, while text fields occupy a block of memory according to their length, text strings are so-called deep data objects. Internally, they are managed by a reference that points to the actual character. This fact has restrictive consequences for the use of strings as components of structures, but can also improve the performance of assignments due to the concept of sharing of deep data objects.- Length: Theoretically, a text string can use up to 2 GB (one character occupies 2 bytes). The maximum length of a text field is 262143 characters.
- Trailing blanks: For text strings, trailing blanks are preserved in all operations. For text fields, it depends on the operand position whether trailing blanks are respected or not. In most operand positions, trailing blanks are truncated when working with text fields, even when using text field literals. For example, if a text field is assigned to a text string, the resulting target string will never contain trailing blanks. See the Condensing Strings section in this context.
- Flexibility: Text strings are more flexible than text fields because you can easily shorten or lengthen them without worrying that, for example, parts of the character string will be truncated during processing. On the other hand, when accessing substrings of a string, you have to make sure that the string is long enough, whereas with text fields you always know their length.
So, when to use what? Text fields are useful when actually specifying a maximum or mandatory length, e.g. a country code that must be a maximum of two characters, or for input fields in forms that should not exceed a certain length. If limiting a string is not relevant, text strings are a good choice.
- To work with character strings, you need character-like data objects based on the character-like types mentioned above.
- The simplest way of producing text in an ABAP program are character literals.
The following code snippet shows a global class implementing the interface
if_oo_adt_classrun
.- Using the
write
method, you can display output in the ADT console. In the example, two untyped literals without a dedicated name (unnamed data object) are included. - In the case below, the data type of the character literals are defined by the delimiters.
- Using the
- Text string literals are enclosed in backquotes (
`...`
) and have the data typestring
. - Text field literals are enclosed in single quotes (
'...'
) and have the data typec
. - The literals can be (but should not according to the programming guidelines on literals (F1 docu for standard ABAP)) used like constants of these types in operand positions. They should be only used for start values when declaring named data objects.
CLASS zcl_some_test_class DEFINITION PUBLIC FINAL CREATE PUBLIC.
PUBLIC SECTION.
INTERFACES if_oo_adt_classrun.
ENDCLASS.
CLASS zcl_some_test_class IMPLEMENTATION.
METHOD if_oo_adt_classrun~main.
out->write( `I am a text string literal` ). "text string literal of type string
out->write( 'I am a text field literal' ). "text field literal of type c
ENDMETHOD.
ENDCLASS.
- Named character-like data types and objects can be declared like other types and objects using
TYPES
,DATA
CONSTANTS
and by referring to a character-like data type. - In addition, character-like data objects can be declared inline with the operators
DATA
andFINAL
.
Syntax examples:
"Type declarations using built-in types
TYPES: c_type TYPE c LENGTH 3, "Explicit length specification
str_type TYPE string.
"Data object declarations using built-in, local and DDIC types
DATA: flag TYPE c LENGTH 1, "Built-in type
str1 TYPE string, "Built-in type
char1 TYPE c_type, "Local type
str2 LIKE str1, "Deriving type from a local data object
str3 TYPE str_type, "Local type
tstmp TYPE timestampl, "DDIC type
char3 TYPE zdemo_abap_flsch-carrid. "Using the type of a DDIC table component
"You may also encounter declarations with type c and the length
"specified in parentheses. This is not recommended, to avoid confusion
"with the use of parentheses in dynamic programming.
DATA char(4) TYPE c.
"Just a TYPE c specification without length means LENGTH 1.
DATA char_len_one TYPE c.
"No type and length specification: TYPE c LENGTH 1 by default
DATA char_no_type_len.
- When you declare character-like data objects, you can specify start values directly with the
VALUE
addition, e.g.DATA chars TYPE c LENGTH 3 VALUE 'abc'.
. - You can do value assignments to data objects using the the assignment operator
=
. - As mentioned above, you can declare character-like data objects inline using the operators
DATA
orFINAL
. - You can use the operators at many write positions.
- Unlike the
VALUE
addition of the declaration statements, inline declarations allow you to declare variables for the results of expressions or at other positions where character strings are returned. - In the case below, a variable specified in parentheses preceded by
DATA
(orFINAL
) on the left side of the assignment operator automatically derives a data type from the operand on the right. This helps to make your programs leaner.
Syntax examples:
"Data object declarations including default values with VALUE
"Note the chained statement: DATA followed by a colon, listing the data object declarations,
"separated by a comma.
DATA: flag TYPE c LENGTH 1 VALUE 'X',
str1 TYPE string VALUE `Hallo!`.
"Examples for type n
DATA zip_code TYPE n LENGTH 5 VALUE '12345'.
DATA isbn_number TYPE n LENGTH 13 VALUE '1234567890123'.
"Constant; content cannot be changed at runtime
CONSTANTS pi TYPE p LENGTH 8 DECIMALS 14 VALUE '3.14159265358979'.
"More data object declarations
DATA: char1 TYPE c LENGTH 5,
html TYPE string,
str2 LIKE html.
"Value assignments
char1 = 'ab123'.
html = `<p>hallo</p>`.
"Escaping backquotes in text string literals with another one
str1 = `This is a backquote: ``.`.
"If possible, avoid unnecessary type conversion; in principle, every
"convertible type can be specified
str2 = 'abc'. "Fixed length string assigned to data object of type string
DATA str3 TYPE string VALUE 'X'. "type c length 1
DATA str4 TYPE string VALUE -1. "type i
"Inline declarations
DATA(char2) = 'abcd'. "Type c length 4
DATA(str5) = `efgh`.
"You can use FINAL to create immutable variables.
FINAL(final_string) = `zyx`.
"Since char2 is of type c length 4 (the length is also derived),
"characters are truncated in the following example assignment
char2 = 'ijklmnopq'. "ijkl
"Trailing blanks after assigning fixed length to variable length string
DATA(char3) = 'ab '.
DATA(str6) = `cdefgh`.
str6 = char3. "'ab' (trailing blanks are not respected due to conversion rule)
- When assigning strings, not only data objects can be placed on the right
side. Various expressions and strings can be concatenated using the
concatenation
operator
&&
. - Alternatively, you can concatenate strings using string templates, as described in the Concatenating Strings section.
str5 = str3 && ` ` && str4 && `!`. "X 1-!
"Note the output for str4 that includes the conversion of type i to
"string above demonstrating a possibly inadvertent specification
"of an integer value for str4 that is of type string.
Note that there is also the literal
operator
&
that joins text string
literals,
however, with significant
differences
to &&
.
- Using string templates, you can construct strings very elegantly from
literal text and - which is the primary use case - by including
embedded ABAP
expressions
within a pair of delimiters (
|...|
) if these expressions can be converted tostring
. - To embed expressions, you enclose them in curly brackets:
{ ... }
. - Among the expressions that can be specified in the curly brackets are data objects and functional method calls that have a return value. The expression result must be convertible to type
string
.
💡 Note
- String templates form a string expression that is compiled at runtime. Therefore, a string template that contains only literal text is treated as an expression, which has a performance impact. In such a case, it is preferable to use a text string literal with backquotes.
- It is possible to dynamically specify formatting options. For more information, refer to the Dynamic Formatting Option Specifications in String Templates section of the Dynamic Programming cheat sheet.
Syntax examples:
"Value assignment with string templates
"The expression must be convertible to a string. A blank (not within the curly brackets)
"means a blank in the resulting string.
DATA(s1) = |Hallo { cl_abap_context_info=>get_user_technical_name( ) }!|.
DATA(s2) = `How are you?`. "Literal text only with backquotes
DATA(s3) = |{ s1 } { s2 }|. "Hallo NAME! How are you?
"Chaining of string templates using &&
DATA(s4) = |{ s1 }| && ` ` && |{ s2 }|. "Hallo NAME! How are you?
"Selection of possible expressions:
"Data objects, as in the examples above
DATA(dobj1) = `Hallo`.
DATA(dobj2) = '!'.
"Hallo!
DATA(s5) = |{ dobj1 }{ dobj2 }|.
"NOT INITIAL
DATA(s6) = |{ COND #( WHEN s5 IS INITIAL THEN `INITIAL` ELSE `NOT INITIAL` ) }|.
"Functional method calls, built-in functions
"User alias: XXXX...
DATA(s7) = |User alias: { cl_abap_context_info=>get_user_alias( ) }|.
"Some random number: 39 (example)
DATA(s8) = |Some random number: { cl_abap_random_int=>create( seed = cl_abap_random=>seed( ) min = 1 max = 100 )->get_next( ) }|.
"Length of string s5: 6
DATA(s9) = |Length of string s5: { strlen( s5 ) }|.
"Current UTC time stamp: 2024-01-11 14:27:54.1514090 (example)
DATA(s10) = |Current UTC time stamp: { utclong_current( ) }|.
"HALLO!
DATA(s11) = |{ to_upper( s5 ) }|.
- String templates interpret certain character combinations as control characters.
- For example,
\n
is interpreted as a newline. A new line is started. - String templates also support various formatting options.
- Refer to the ABAP Keyword Documentation for all options.
The following syntax examples demonstrate a selection:
"Control characters
s4 = |{ s1 }\n{ s2 }\nSee you.|. "\n is interpreted as a line feed
"Excursion: Class CL_ABAP_CHAR_UTILITIES provides attributes and methods as utilities for string processing.
"See the class documentation
"The following examples demonstrate that attributes that contain control characters can be replaced by
"a representation of control characters in a string template.
ASSERT cl_abap_char_utilities=>newline = |\n|.
ASSERT cl_abap_char_utilities=>horizontal_tab = |\t|.
ASSERT cl_abap_char_utilities=>cr_lf = |\r\n|.
"Various formatting options
"DATE: Defining the format of a date
"The output is just an example and depends on your settings.
DATA(d) = |The date is { cl_abap_context_info=>get_system_date( ) DATE = USER }.|. "The date is 01/01/2024.
d = |{ cl_abap_context_info=>get_system_date( ) DATE = RAW }|. "20240101
d = |{ cl_abap_context_info=>get_system_date( ) DATE = ISO }|. "2024-01-01
d = |{ cl_abap_context_info=>get_system_date( ) DATE = ENVIRONMENT }|. "01/01/2024
"TIME: Defining the format of a time
"The output is just an example and depends on your settings.
DATA(tm) = |The time is { cl_abap_context_info=>get_system_time( ) TIME = ISO }.|. "The time is 14:37:24.
tm = |{ cl_abap_context_info=>get_system_time( ) TIME = RAW }|. "143724
tm = |{ cl_abap_context_info=>get_system_time( ) TIME = USER }|. "14:37:24
tm = |{ cl_abap_context_info=>get_system_time( ) TIME = ENVIRONMENT }|. "14:37:24
"TIMESTAMP: Defining the format of a time stamp
"The output is just an example and depends on your settings.
DATA(ts) = |{ utclong_current( ) TIMESTAMP = SPACE }|. "2024-01-01 14:39:50.4069170
ts = |{ utclong_current( ) TIMESTAMP = ISO }|. "2024-01-01T14:39:50,4071110
ts = |{ utclong_current( ) TIMESTAMP = USER }|. "01/01/2024 14:39:50.4072010
ts = |{ utclong_current( ) TIMESTAMP = ENVIRONMENT }|. "01/01/2024 14:39:50.4073230
ts = |{ utclong_current( ) }|. "2024-01-01 14:39:50.4074060
"TIMEZONE: Defining the format of a time stamp using the rules for time zones
DATA(tz) = |{ utclong_current( ) TIMEZONE = 'UTC' }|. "2024-12-30 14:43:20.6534640
tz = |{ utclong_current( ) TIMEZONE = 'CET' COUNTRY = 'DE ' }|. "30.12.2024 15:43:20,6536320
tz = |{ utclong_current( ) TIMEZONE = 'EST' COUNTRY = 'US ' }|. "12/30/2024 09:43:20.6889180 AM
"CASE: Lowercase and uppercase
s1 = |AbCdEfG|.
s2 = |{ s1 CASE = LOWER }|. "abcdefg
s2 = |{ s1 CASE = UPPER }|. "ABCDEFG
"WIDTH/ALIGN
s1 = `##`.
s2 = |{ s1 WIDTH = 10 ALIGN = LEFT }<---|. "'## <---'
s2 = |{ s1 WIDTH = 10 ALIGN = CENTER }<---|. "' ## <---'
"PAD: Used to pad any surplus places in the result with the specified character.
s2 = |{ s1 WIDTH = 10 ALIGN = RIGHT PAD = `.` }<---|. "'........##<---'
"DECIMALS
s1 = |{ CONV decfloat34( - 1 / 3 ) DECIMALS = 3 }|. "'-0.333'
"SIGN: Defining the format of the +/- sign when the string represented
"by the embedded expression represents a numeric value
"- left without space, no +
s1 = |{ +1 SIGN = LEFT }|. "1
"- and + left without space
s1 = |{ 1 SIGN = LEFTPLUS }|. "+1
"- left without space, blank left for +
s1 = |{ 1 SIGN = LEFTSPACE }|. " 1
"- right without space, no +
s1 = |{ -1 SIGN = RIGHT }|. "1-
"- and + right without space
s1 = |{ 1 SIGN = RIGHTPLUS }|. "1+
"- left without space, blank right for +
s1 = |{ +1 SIGN = RIGHTSPACE }|. "1
"ZERO: Defining the format of the numeric value zero.
"Only to be specified if the embedded expression has a numeric data type.
s1 = |'{ 0 ZERO = NO }' and '{ 0 ZERO = YES }'|. "'' and '0'
"XSD: Formatting is applied to an embedded expression (elementary data types) in asXML format that is
"assigned to its data type. Check the information in the ABAP Keyword Documentation about the asXML
"mapping of elementary ABAP types.
DATA xstr TYPE xstring VALUE `41424150`.
DATA dat type d value '20240101'.
DATA tim type t value '123456'.
DATA(utc) = utclong_current( ). "e.g. 2024-01-01 13:51:38.5708800
s1 = |{ xstr XSD = YES }|. "QUJBUA==
s1 = |{ dat XSD = YES }|. "2024-01-01
s1 = |{ tim XSD = YES }|. "12:34:56
s1 = |{ utc XSD = YES }|. "2024-01-01T13:51:38.57088Z
"STYLE: Defining the style of decimal floating point numbers;
"see the details in the ABAP Keyword Documentation.
DATA(dcfl34) = CONV decfloat34( '-123.45600' ).
s1 = |{ dcfl34 }|. "-123.456
"Creates the predefined format
s1 = |{ dcfl34 STYLE = SIMPLE }|. "-123.456
"+/- added to the right, removes trailing zeros
s1 = |{ dcfl34 STYLE = SIGN_AS_POSTFIX }|. "123.456-
"Retains trailing zeros
s1 = |{ dcfl34 STYLE = SCALE_PRESERVING }|. "-123.45600
"Scientific notation; at least a two digit exponent with a plus/minus sign
s1 = |{ dcfl34 STYLE = SCIENTIFIC }|. "-1.23456E+02
"Scientific notation; only one integer digit with the value 0
s1 = |{ dcfl34 STYLE = SCIENTIFIC_WITH_LEADING_ZERO }|. "-0.123456E+03
"Scientific notation; exponent has 3 digits for decfloat16 and 4 digits for decfloat34
s1 = |{ dcfl34 STYLE = SCALE_PRESERVING_SCIENTIFIC }|. "-1.2345600E+0002
"Technical format
s1 = |{ dcfl34 STYLE = ENGINEERING }|. "-123.456E+00
"ALPHA: Adds or removes leading zeros from strings of digits; the data type
"must be string, c, or n
"Adding leading zeros
"Additionally specifying WIDTH
"Note: The specified length is only used if it is greater than
"the length of provided string (without leading zeros)
s1 = |{ '1234' ALPHA = IN WIDTH = 10 }|. "0000001234
s1 = |{ '00000000000000000000000012' ALPHA = IN WIDTH = 10 }|. "0000000012
"Fixed-length string provided, WIDTH not specified
s1 = |{ ' 12' ALPHA = IN }|. "00012
"Removing leading zeros
s1 = |{ '00001234' ALPHA = OUT }|. "1234
"Do not apply formatting
s1 = |{ '00001234' ALPHA = RAW }|. "00001234
💡 Note
Escape\|{}
in string templates using\
, i. e.\\
means\
.
- To determine the length of a string, you can use the string function
strlen
. - Note that the result depends on the type of the string, i. e. the result for a data object of type
string
includes trailing blanks. A fixed-length string does not include them. - To exclude trailing blanks in all cases, regardless of the data type, you can use the built-in
numofchar
function.
Syntax examples:
"strlen
DATA(len_c) = strlen( 'abc ' ). "3
DATA(len_str) = strlen( `abc ` ). "6
"numofchar
len_c = numofchar( 'abc ' ). "3
len_str = numofchar( `abc ` ). "3
- Two or more strings can be concatenated using the concatenation operator
&&
and string templates. Alternatively, you can useCONCATENATE
statements. - It is also possible to concatenate lines from internal tables into a string to avoid a loop.
- A more modern way is to use
the string function
concat_lines_of
.
Syntax examples:
"&& and string template
DATA(s1) = `AB` && `AP`. "ABAP
DATA(s2) = `ab` && `ap` && ` ` && s1. "abap ABAP
DATA(s3) = |{ s1 }. { s2 }!|. "ABAP. abap ABAP!
"CONCATENATE statements
CONCATENATE s1 s2 INTO s3. "ABAPabap ABAP
"Multiple data objects and target declared inline
CONCATENATE s1 ` ` s2 INTO DATA(s5). "ABAP abap ABAP
CONCATENATE s1 s2 s5 INTO DATA(s6). "ABAPabap ABAPABAP abap ABAP
"You can also add a separation sign using the addition SEPARATED BY
CONCATENATE s1 s2 INTO s3 SEPARATED BY ` `. "ABAP abap ABAP
CONCATENATE s1 s2 INTO s3 SEPARATED BY `#`. "ABAP#abap ABAP
"Keeping trailing blanks in the result when concatenating fixed length
"strings. The ones of variable length strings are respected by default.
CONCATENATE 'a ' 'b ' 'c ' INTO DATA(ch) RESPECTING BLANKS. "'a b c '
"Concatenating lines of internal tables into a string
CONCATENATE LINES OF itab INTO t SEPARATED BY ` `.
"Using concat_lines_of
s1 = concat_lines_of( table = itab ). "Without separator
s1 = concat_lines_of( table = itab sep = ` ` ). "With separator
- You can use
SPLIT
statements to split strings in multiple segments. - The result of the split can be stored in separate data objects or internal tables that have a character-like line type.
- Note that if the number of specified targets is less than the number of segments returned by the split, the last target receives the remaining unsplit segements. If more targets are specified, the targets that do not receive a segment are initialized.
- Therefore, specifying individual targets with
SPLIT
statements is useful if the number of expected segments is known. Otherwise, splitting into tables is a good choice. - If you want to get the value of a particular segment, you can use the
string function
segment
.
Syntax examples:
DATA(s1) = `Hallo,world,123`.
DATA: s2 TYPE string,
s3 TYPE string,
s4 TYPE string.
SPLIT s1 AT `,` INTO s2 s3 s4. "s2 = Hallo / s3 = world / s4 = 123
"Less data objects than possible splittings
SPLIT s1 AT `,` INTO s2 s3. "s2 = Hallo / s3 = world,123
"Splitting into internal table
DATA itab TYPE TABLE OF string.
SPLIT s1 AT ',' INTO TABLE itab. "Strings are added to itab in individual lines without comma
"String function segment returning the occurrence of a segment
"index parameter: number of segment
s2 = segment( val = s1 index = 2 sep = `,` ). "world
- The string functions
to_lower
andto_upper
transform characters of a string to either lowercase or uppercase and store the result in a target variable. - If you want to apply the transformation to the source directly, you can use
TRANSLATE
statements.
Syntax examples:
"String functions
DATA(s1) = to_upper( `abap` ). "ABAP
s1 = to_lower( `SOME_FILE.Txt` ). "some_file.txt
"TRANSLATE statements
s1 = `Hallo`.
TRANSLATE s1 TO UPPER CASE. "HALLO
TRANSLATE s1 TO LOWER CASE. "hallo
"For the transformation of the source directly, you can
"also specify an existing, changeable data object as
"the source in a simple assignment as follows.
s1 = to_upper( s1 ).
- You can shift content within a string to a specific position on the left
or right of a string.
SHIFT
statements have various additions for specific use cases. - In a more modern way, you can use the string functions
shift_left
andshift_right
, which store the result in a variable.- These functions provide additional
functionality. The
sub
parameter can be used to specify a substring. All substrings in the string that match the value specified insub
on either the left or right side of the string are removed.
- These functions provide additional
functionality. The
Syntax examples:
"SHIFT statements
"Note that all results below refer to s1 = `hallo`.
DATA(s1) = `hallo`. "Type string
SHIFT s1. "No addition; string shifted one place to the left: allo
SHIFT s1 BY 2 PLACES. "Without direction, left by default: llo
SHIFT s1 BY 3 PLACES RIGHT. "With direction, variable length strings are extended: ' hallo'
"Note that all results below refer to ch4 = 'hallo'.
DATA(ch4) = 'hallo'. "Type c length 5
SHIFT ch4 BY 3 PLACES RIGHT. "Fixed length string: ' ha'
"CIRCULAR addition: characters that are moved out of the string are
"added at the other end again
SHIFT ch4 BY 3 PLACES LEFT CIRCULAR. "lohal
SHIFT ch4 UP TO `ll`. "Shift characters up to a specific character set: llo
"Deleting leading and trailing characters
DATA(s2) = ` hallo `.
DATA(s3) = s2.
SHIFT s2 LEFT DELETING LEADING ` `. "'hallo '
SHIFT s3 RIGHT DELETING TRAILING ` `. "' hallo' (length is kept)
"Removing trailing blanks in strings without leading blanks;
"you can use the following sequence of statements
DATA(s4) = `hallo `.
SHIFT s4 RIGHT DELETING TRAILING ` `. "' hallo'
SHIFT s4 LEFT DELETING LEADING ` `. "'hallo'
"String functions with parameters
s1 = `hallo`.
s2 = shift_left( val = s1 places = 3 ). "lo
s2 = shift_left( val = s1 circular = 2 ). "lloha
"Note that shift_right does not extend a variable length string.
s2 = shift_right( val = s1 places = 3 ). "ha
s2 = shift_right( val = `abc ` sub = ` ` ). "'abc'
s2 = shift_right( val = `abc ` ). "'abc' (same result as above)
- You can use
CONDENSE
statements or the string functioncondense
to remove blanks from strings. - The advantage of using the string function is that you can specify any character to remove, not just blanks.
Syntax examples:
"CONDENSE statements
DATA(s1) = ` ab cd `.
DATA(s2) = ` ef gh ij `.
DATA(s3) = ` kl mn op `.
CONDENSE s1. "Trailing and leading blanks are removed: 'ab cd'
CONDENSE s2. "It also replaces sequences of multiple blanks with a single blank: 'ef gh ij'
CONDENSE s3 NO-GAPS. "Removes all blanks: 'klmnop'
"String function condense
s1 = ` ab cd `.
"No parameters specified, i. e. their default values are provided.
"Works like CONDENSE statement without the NO-GAPS addition.
s2 = condense( s1 ). "ab cd
"Parameters del/to not specified. from parameter with initial string
"(could also be a text field literal: from = ' '). This way, leading and
"trailing blanks are removed.
s2 = condense( val = s1 from = `` ). "ab cd
"Parameter to specified with an initial string. No other parameters.
"Works like CONDENSE statement with the NO-GAPS addition.
s2 = condense( val = s1 to = `` ). "abcd
"Parameter del specifies the leading/trailing characters to be removed.
s2 = condense( val = `##see###you##` del = `#` ). "see###you
"If from and to are specified along with del, leading/trailing
"characters specified in del are first removed. Then, in the remaining string, all
"substrings composed of characters specified in from are replaced with
"the first character of the string specified in the to parameter
s2 = condense( val = ` Rock'xxx'Roller`
del = `re `
from = `x`
to = `n` ). "Rock'n'Roll
The string function
reverse
reverses a string:
"Result: 'abap'
DATA(s1) = reverse( `paba` ).
- The string function
insert
inserts a substring at any position within a given string. You can use various parameters to construct the string you want:val
: Original string.sub
: Substring.off
: Optionally sets the offset, i.e. the position where the substring should be added. The default value is 0. When using the function with the default value, the result is like concatenating a string with&&
(likeres = sub && text
).
- Inserting substrings can also be accomplished using the string function
replace
orREPLACE
statements, which are are covered below.
Syntax examples:
"Result: 'abcdefghi'
DATA(s1) = insert( val = `abcghi` sub = `def` off = 3 ).
"Result: 'defabcghi'
s1 = insert( val = `abcghi` sub = `def` ).
You can use OVERLAY
statements to replace characters in one variable with characters in another variable that are in the same place there.
Syntax examples:
DATA(incl) = '==============================CP'.
DATA(cl_name) = 'CL_SOME_CLASS '.
"Addition ONLY is not specified: All blanks are replaced
OVERLAY cl_name WITH incl.
"cl_name: CL_SOME_CLASS=================CP
DATA(txt1) = 'a.b.c.a.b.c.A'.
DATA(txt2) = 'z.x.y.Z.x.y.z'.
"Addition ONLY is specified: All characters that are specified after ONLY and that
"occur in the operand are replaced. Note that this is case-sensitive.
OVERLAY txt1 WITH txt2 ONLY 'ab'.
"txt1: z.x.c.Z.x.c.A
- The string function
substring
allows you to specify the position (parameteroff
) and the length (len
) of a substring to be extracted from a given string (val
).- At least one of the two parameters
off
orlen
must be specified. The default value ofoff
is 0, i.e. when using the default value, the substring is extracted from the beginning of the string. - If
len
is not specified, the rest of the remaining characters is respected. If the offset and length are greater than the actual length of the string, the exceptionCX_SY_RANGE_OUT_OF_BOUNDS
is raised.
- At least one of the two parameters
- You may also encounter the syntax for accessing substrings by specifying the offset
and length using the
+
character after a variable.- The length is specified in parentheses. Specifying an asterisk (
*
) means that the rest of the remaining string is respected. - This syntax option even allows write access to substrings for fixed-length strings. Read access is possible for both fixed-length and variable-length strings.
- However, this syntax can be confused with the use of tokens in the context of dynamic programming.
- The length is specified in parentheses. Specifying an asterisk (
- There are other string functions available for dealing with substrings, such as
substring_after
,substring_before
,substring_from
andsubstring_to
.- These functions offer more options in terms of parameters, such as the use of PCRE regular expressions, which are covered below.
Syntax examples:
DATA(s1) = `Lorem ipsum dolor sit amet`. "Type string
"Extracting substring starting at a specific position
"'len' not specified means the rest of the remaining characters is
"respected
DATA(s2) = substring( val = s1 off = 6 ). "ipsum dolor sit amet
"Extracting substring with a specific length
"'off' is not specified and has the default value 0.
s2 = substring( val = s1 len = 5 ). "Lorem
"Specifying both off and len parameters
s2 = substring( val = s1 off = 6 len = 5 ). "ipsum
DATA(txt) = 'Lorem ipsum dolor sit amet'. "Type c
"Offset and length specification using the + sign after a variable
DATA(ch6) = txt+0(5). "Lorem
"* means respecting the rest of the remaining string
DATA(ch7) = txt+12(*). "dolor sit amet
CLEAR txt+11(*). "Lorem ipsum
txt+0(5) = 'Hallo'. "Hallo ipsum dolor sit amet
"Further string functions
s1 = `aa1bb2aa3bb4`.
"Extracting a substring ...
"... after a specified substring
s2 = substring_after( val = s1 sub = `aa` ). "1bb2aa3bb4 (only the first occurrence is respected)
"... after a specified substring specifying the occurence in a string
"and restricting the length
s2 = substring_after( val = s1 sub = `aA` occ = 2 len = 4 case = abap_false ). "3bb4
"... before a specified substring
s2 = substring_before( val = s1 sub = `b2` ). "aa1b
"... from a specified substring on. It includes the substring specified
"in sub. len/off and other parameters are possible.
s2 = substring_from( val = s1 sub = `a3` ). "a3bb4
"... up to a specified substring. It includes the substring specified
"in sub. len/off and other parameters are possible.
s2 = substring_to( val = s1 sub = `3b` ). "aa1bb2aa3b
- In ABAP, there are many ways to perform search and replace
operations on strings. These include the use of comparison
operators
or the ABAP statements
FIND
andREPLACE
, or the more modern built-in string functionsfind
andreplace
, among others, with their considerable number of additions and parameters. - Many of these options support rather simple operations on single characters only or more complex, pattern-based operations on character sequences using PCRE regular expressions.
- You can use the comparison
operators
CA
(contains any) or its negationNA
(contains not any) in comparison expressions to determine whether any character of a given character set is contained in a string. Such an expression is true if at least one character is found.- The search is case-sensitive.
- The system variable
sy-fdpos
contains the offset of the first character found. If nothing is found,sy-fdpos
contains the length of the string. - Note that offset 0 represents the very first position.
- The string functions
find_any_of
and its negationfind_any_not_of
return the offset of the occurrence of any character contained in a substring. They are special variants of the string functionfind
, which is shown below.- If nothing is found, the value -1 is returned.
- Other optional parameters are possible. For example, the
specification of
occ
determines the search direction, i.e. a positive value means that the search is performed from left to right. A negative value means to search from right to left.
- If you are not interested in the position of characters, but rather how
often they occur in a string, you can use the string function
count
, as well as the special variantscount_any_of
and its negationcount_any_not_of
. - To determine whether a string contains only a certain set of characters,
you can use the comparison operators
CO
(contains only) or its negationCN
(contains not only) in comparison expressions.- For
CO
, a comparison is true if the left operand contains only characters that are also contained in the right operand. If the comparison returns false, you can usesy-fdpos
to get the position of the first character from text that is not contained in the character. - For
CN
, a comparison is true if a string contains characters other than those in the character set.
- For
Syntax examples:
DATA(s1) = `cheers`.
IF s1 CA `aeiou` ... "true, sy-fdpos = 2
IF s1 NA `xyz`... "true, sy-fdpos = 6
IF s1 CO `rs` ... "false, sy-fdpos = 0
IF s1 CN `cheers` ... "false, sy-fdpos = 6
Built-in functions:
"Note that the functions may contain more parameters than those covered in the snippet.
DATA(str) = `Pieces of cakes.`.
DATA res TYPE i.
"find_end returns the sum of the offset of the occurrence plus the length of the match
res = find_end( val = str sub = `of` ). "9
"find_any_of returns the offset of the occurrence of any character contained in substring
"The search is always case-sensitive.
res = find_any_of( val = str sub = `x523z4e` ). "2 (character e is found)
res = find_any_of( val = str sub = `zwq85t` ). "-1
"find_any_not_of: Negation of the one above
"The search is always case-sensitive.
res = find_any_not_of( val = str sub = `ieces` ). "0 (very first character in the searched string)
res = find_any_not_of( val = str sub = `P` ). "1
"count returns the number of all occurrences
res = count( val = str sub = `e` ). "3
res = count( val = str sub = `x` ). "0
"count_any_of
res = count_any_of( val = str sub = `x523z4e` ). "3
res = count_any_of( val = str sub = `eco` ). "6
"count_any_not_of
res = count_any_not_of( val = str sub = `fP` ). "14
res = count_any_not_of( val = str sub = `Piecs ofak.` ). "0
- You can use the string function
translate
to replace certain characters with others.- The
from
parameter specifies the characters to be placed in a string, and theto
parameter specifies the target characters. - Note: The
replacement is performed as follows: Each character specified in
from
is replaced by the character into
that is at the same position, i.e. the second character infrom
is replaced by the second character specified into
. If there is no equivalent into
, the character infrom
is removed from the result.
- The
- You can use
TRANSLATE
statements to perform replacements directly on the source field.
Syntax examples:
DATA(s1) = `___abc_def_____ghi_`.
DATA(s2) = translate( val = s1 from = `hi_` to = `##` ). "abcdefg##
s2 = translate( val = s1 from = `_` to = `##` ). "###abc#def#####ghi#
"TRANSLATE statement. The value after USING is interpreted as a string composed of character pairs.
"Starting with the first pair, a search is performed in text for the
"first character in every pair and each occurrence is replaced with the
"second character of the pair.
TRANSLATE s1 USING `_.a#g+`. "...#bc.def.....+hi.
- For simple substring searches, you can use the comparison
operators
CS
(contains string) or its negationNS
(contains no string) in comparison expressions. The search is not case-sensitive. - The system variable
sy-fdpos
contains the offset of the found substring. If the substring is not found,sy-fdpos
contains the length of the searched string.
DATA(s3) = `cheers`.
IF s3 CS `rs` ... "true, sy-fdpos = 4 (offset)
IF s3 CS `xy`... "false, sy-fdpos = 6 (length of string)
IF s3 NS `ee`... "false, sy-fdpos = 2 (offset)
IF s3 NS `xy`... "true, sy-fdpos = 6 (length of string)
For more complex and iterative searches, you may want to use FIND
statements or the string functions below.
FIND
- Used to search for a character sequence.
- Has a rich set of additions, a selection of which is covered in this cheat sheet. See here for more information. Byte string processing is not included (there are special additions).
- Sets the system fields
sy-subrc
: 0 (search pattern found at least once) or 4 (search pattern not found).
Syntax Overview (see the syntax diagram in the ABAP Keyword Documentation):
FIND
FIRST OCCURRENCE OF "(or) ALL OCCURRENCES OF
"1. Only the first occurrence is searched
"2. All occurrences are searched
"Note: If none of these two additions is specified, only the first occurrence is searched for.
SUBSTRING some_substring "(or) PCRE some_regex
"1. Searching for exactly one string, specifying SUBSTRING is optional (e.g. for emphasis);
" some_substring is a character-like operand; note: Trailing blanks are not ignored if it is of type string
"2. Searching for a substring matching a regular expression; only the PCRE addition should be used;
" some_regex = character-like operand; note: PCRE syntax is compiled in an extended mode, i.e. unescaped whitespaces
" are ignored; if the regex is too complex, a catchable exception of the class CX_SY_REGEX_TOO_COMPLEX is raised
IN
SECTION
OFFSET off
LENGTH len
OF
"- Restricting the search to a specific section from an offset specified in off with the length len
"- When using SECTION, at least one of the two options must be specified
" - No OFFSET specification: offset 0 is used implicitly
" - No LENGTH specification: search from specified offset to end of string
" - Note: off and len are of type i; it must be a positive integer value;
" exception: len = -1 (same effect as not using the LENGTH addition)
"- Without the addition SECTION ... OF, the entire data object dobj is searched
"Character-like data object
dobj
"Further additional options for advanced evaluation options:
"Specifying whether the search is case-sensitive; not specified means RESEPECTING CASE by default
RESPECTING CASE "(or) IGNORING CASE
"Determining the number of sequences found, number stored in cnt that is of type i (e.g. a variable declared inline)
"When searching for the first occurrence, the value is always 1 (not found -> 0)
MATCH COUNT cnt
"Determining position of sequences found
"Note: off holds the position of the last occurrence when searching for all occurrences and if
"there are multiple occurrences (not found -> 0 or the previous value of a finding is retained).
MATCH OFFSET off
"Determining the length of sequences found
"Note: Similar to above, not finding an occurrence means 0 for len or the previous value of a finding is retained
MATCH LENGTH len
"Storing offset, length, submatches (only relevant for regular expressions) information in a table or a structure
"tab: of type MATCH_RESULT_TAB; especially for using with ALL OCCURRENCES
"struc: of type MATCH_RESULT; especially for using with FIRST OCCURRENCE
"Note on submatches: table of type SUBMATCH_RESULT_TAB; holds offset and length information of substrings of occurrences
"that are stored in subgroup registers of regular expressions; in FIND IN TABLE statements, the additional component LINE
"is available
RESULTS tab "(or) RESULTS struc
"Storing content of subgroup register of a regular expression in character-like data objects;
"only to be used if a regular expression pattern is specified.
"Note: Only the last occurrence is evaluated when using ALL OCCURRENCES; the number of the operands specified should match
"the number of subgroups specified
SUBMATCHES sub1 sub2 ...
.
Examples:
"Note: The code snippets mainly use inline declarations.
DATA(str) = `She sells seashells by the seashore.`.
"Determining if a substring is found
"Simple find statement
FIND `se` IN str.
IF sy-subrc = 0.
"found
ELSE.
"not found
ENDIF.
"Addition SUBSTRING is optional
FIND SUBSTRING `hi` IN str.
IF sy-subrc = 0.
"found
ELSE.
"not found
ENDIF.
"The following examples use the additions MATCH COUNT and MATCH OFFSET to determine
"the number of occurrences and offset
"Addition FIRST OCCURRENCE OF: Explicit specification to search for the first occurrence
FIND FIRST OCCURRENCE OF `se` IN str
MATCH COUNT DATA(cnt2) "1 (always 1 when searching and finding the first occurrence)
MATCH OFFSET DATA(off2). "4
"Omitting FIRST OCCURRENCE OF and ALL OCCURRENCES OF addition means searching for the
"first occurrence by default; same effect as the previous statement
FIND `se` IN str
MATCH COUNT DATA(cnt1) "1
MATCH OFFSET DATA(off1). "4
"Addition ALL OCCURRENCES: Searching for all occurrences
FIND ALL OCCURRENCES OF `se` IN str
MATCH COUNT DATA(cnt3) "3
MATCH OFFSET DATA(off3). "27 (value for the last occurrence)
"Addition IN SECTION ... OF:
"Searching in a specified section; both additions OFFSET and LENGTH are specified
FIND ALL OCCURRENCES OF `se`
IN SECTION OFFSET 9 LENGTH 5 OF str
MATCH COUNT DATA(cnt4) "1
MATCH OFFSET DATA(off4). "10
"Only LENGTH specified (OFFSET is 0 by default)
FIND ALL OCCURRENCES OF `se`
IN SECTION LENGTH 7 OF str
MATCH COUNT DATA(cnt5) "1
MATCH OFFSET DATA(off5). "4
"Only OFFSET specified (LENGTH: up to end of string)
FIND ALL OCCURRENCES OF `se`
IN SECTION OFFSET 7 OF str
MATCH COUNT DATA(cnt6). "2
"Another string to be searched
DATA(str_abap) = `abap ABAP abap`.
"Further additional options for advanced evaluation options
"Specifying the case-sensitivity of the search
"Not specifying the CASE addition means RESPECTING CASE is used by default.
"Here, it is explicitly specified.
FIND FIRST OCCURRENCE OF `A` IN str_abap
MATCH OFFSET DATA(off7) "5
RESPECTING CASE.
"Making search case-insensitive
FIND FIRST OCCURRENCE OF `A` IN str_abap
MATCH OFFSET DATA(off8) "0
IGNORING CASE.
"MATCH LENGTH addition
"The example uses a regular expression: Non-greedy search for
"a substring starting with lower case a up to an upper case P
FIND FIRST OCCURRENCE OF PCRE `a.*?P` IN str_abap
MATCH LENGTH DATA(len8) "9
RESPECTING CASE.
"RESULTS addition
"Example: Because of using ALL OCCURRENCES, the data object declared inline automatically
"has the type match_result_tab
FIND ALL OCCURRENCES OF `ab` IN str_abap
RESULTS DATA(res9)
IGNORING CASE.
"3 entries in table res9 (tables in SUBMATCHES are initial since no regular expression is used)
"line: always 0 (it's not a table); length: always 2 (search for concrete occurrence of `se`)
"1. line: 0, offset: 0, length: 2, submatches: (initial)
"2. line: 0, offset: 5, length: 2, ...
"3. line: 0, offset: 10, length: 2, ...
"Example: Because of using FIRST OCCURRENCE, the data object declared inline automatically
"has the type match_result
FIND FIRST OCCURRENCE OF `ab` IN str_abap
RESULTS DATA(res10)
IGNORING CASE.
"res10: line: 0, offset: 0, length: 2, submatches: (initial)
You can use FIND ... IN TABLE
statements to search for substrings in internal tables (standard tables without secondary table keys; with character-like line type) line by line.
DATA(str_table) = VALUE string_table( ( `aZbzZ` ) ( `cdZze` ) ( `Zzzf` ) ( `ghz` ) ).
"Finding all occurrences in a table
"Note: res_tab is of type match_result_tab
"You can also restrict the search range in an internal table; see an example in REPLACE ... IN TABLE
FIND ALL OCCURRENCES OF `Z`
IN TABLE str_table
RESULTS DATA(res_tab)
RESPECTING CASE.
"4 entries in table res_tab (tables in SUBMATCHES are initial since no regular expression is used)
"1. line: 1, offset: 1, length: 1, submatches: (initial)
"2. line: 1, offset: 4, length: 1, ...
"3. line: 2, offset: 2, length: 1, ...
"4. line: 3, offset: 0, length: 1, ...
"Finding the first occurrence in a table
"Note: res_struc, which is declared inline here, is of type match_result
FIND FIRST OCCURRENCE OF `Z`
IN TABLE str_table
RESULTS DATA(res_struc)
RESPECTING CASE.
"Entries in structure res_struc
"line: 1, offset: 1, length: 1, submatches: (initial)
"Alternative to the statement above (storing the information in individual data objects)
FIND FIRST OCCURRENCE OF `Z`
IN TABLE str_table
MATCH LINE DATA(line) "1
MATCH OFFSET DATA(off) "1
MATCH LENGTH DATA(len) "1
RESPECTING CASE.
- Built-in search functions, such as
find
, are available for searching strings. - They return a return value of type i and contain multiple (optional) parameters.
FIND
covers the same functionality and more with the many addition options.- For more information, see here
Parameters of the find
function:
val
:- Character-like data object
- Note: If a fixed length string is specified, any trailing blanks are ignored.
sub
:- Contains what is searched for
- A character like expression position; expects arguments with elementary types
- Similar to above, trailing blanks are ignored in fixed length strings
case
:- Search is case-sensitive by default
occ
:- Specifies the occurrence of a match
- Must be of type
i
- Values:
- 1: default value, searches for the first occurrence from the left
- any positive value: searches for the nth occurrence from the left
- any negative value: searches for the nth occurrence from the right
- 0: raises an exception (
CX_SY_STRG_PAR_VAL
), note: in the context of thereplace
function, 0 means replace all occurrences
- Note: Specifying
occ
affects the default values ofoff
andlen
off
:- Specifies the offset
- Must be of type
i
- The default value is 0 (search from the beginning of the string)
- Exception
CX_SY_RANGE_OUT_OF_BOUNDS
is raised for a negative offset specified and an offset that is longer than the searched string
len
:- Specifies the length
- Must be of type
i
- The default value is the length of the string (minus a defined offset in
off
) - The exception
CX_SY_RANGE_OUT_OF_BOUNDS
is raised if the offset is negative and a range is not contained in the searched string
pcre
: Regular expression
DATA(str) = `Pieces of cakes.`.
DATA res TYPE i.
"Searching for substring
"Returns offset of substring found
res = find( val = str sub = `ca` ). "10
"Substring not found returns -1
res = find( val = str sub = `xy` ). "-1
"Actual parameter of sub must not be initial when using the find function
TRY.
res = find( val = str sub = `` ).
CATCH cx_sy_strg_par_val.
...
ENDTRY.
"The search is case-sensitive by default
res = find( val = str sub = `OF` ). "-1
"Making search case-insensitive
res = find( val = str sub = `OF` case = abap_false ). "7
"Specifying occ
res = find( val = str sub = `c` ). "3
res = find( val = str sub = `c` occ = 2 ). "10
res = find( val = str sub = `e` occ = -1 ). "13
res = find( val = str sub = `e` occ = -3 ). "2
"Specifying off and len
"Specifying a subarea in which a string is searched
res = find( val = str sub = `e` off = 5 ). "13
res = find( val = str sub = `e` off = 5 len = 7 ). "-1
res = find( val = str sub = `e` len = 2 ). "-1
TRY.
res = find( val = str sub = `e` off = 5 len = 15 ).
CATCH cx_sy_range_out_of_bounds.
...
ENDTRY.
REPLACE
andREPLACE ... IN TABLE
statements have a similar syntax asFIND
andFIND ... IN TABLE
statements. Refer to the ABAP Keyword Documentation for all possible additions. The following code snippets cover a selection.sy-subrc
is set: 0 (search pattern or section was replaced by the specified content, result was not truncated on the right), 2 (search pattern or section was replaced, result was truncated on the right), 4 (search pattern was not found).REPLACE
statements can be used to directly replace strings (including substrings, which is not possible with the string function).
"Examples for pattern-based replacements in which data objects are searched for character strings
"specified in a pattern and the occurrences are replaced
DATA(str_original) = `abap ABAP abap`.
DATA(str) = str_original.
"Simple REPLACE statement
"Omitting the FIRST OCCURRENCE and ALL OCCURRENCES OF additions means
"replacing the first occurrence by default.
REPLACE `ab` IN str WITH `##`. "##ap ABAP abap
str = str_original.
"Addition SUBSTRING is optional
REPLACE SUBSTRING `ab` IN str WITH `##`. "##ap ABAP abap
str = str_original.
"Addition FIRST OCCURRENCE OF: Explicit specification to replace the
"first occurrence; same effect as the statements above
REPLACE FIRST OCCURRENCE OF `ab` IN str WITH `##`. "##ap ABAP abap
str = str_original.
"Addition ALL OCCURRENCES OF: All occurrences are replaced
"Note that the replacement is case-sensitive by default.
REPLACE ALL OCCURRENCES OF `ab` IN str WITH `##`. "##ap ABAP ##ap
str = str_original.
"Further additional options for advanced evaluation options
"IGNORING CASE addition: Making replacements case-insensitive
REPLACE ALL OCCURRENCES OF `ab`
IN str WITH `##`
IGNORING CASE. "##ap ##AP ##ap
str = str_original.
"REPLACEMENT COUNT addition
REPLACE ALL OCCURRENCES OF `ab`
IN str WITH `##`
REPLACEMENT COUNT DATA(cnt1) "3
IGNORING CASE.
str = str_original.
"REPLACEMENT OFFSET and LENGTH additions
REPLACE FIRST OCCURRENCE OF `ap`
IN str WITH `##`
REPLACEMENT COUNT DATA(cnt2) "1 (always 1 for replaced first occurrence)
REPLACEMENT OFFSET DATA(off2) "2
REPLACEMENT LENGTH DATA(len2) "2
IGNORING CASE. "ab## ABAP abap
str = str_original.
"SECTION ... OF addition: Replacing within a specified area
REPLACE ALL OCCURRENCES OF `ap`
IN SECTION OFFSET 4 LENGTH 5
OF str WITH `##`
REPLACEMENT COUNT DATA(cnt3) "1
REPLACEMENT OFFSET DATA(off3) "2
REPLACEMENT LENGTH DATA(len3) "2
IGNORING CASE. "abap AB## abap
str = str_original.
"RESULTS additions with ...
"... ALL OCCURRENCES OF
"Note: repl_tab, which is declared inline here, is of type repl_result_tab
REPLACE ALL OCCURRENCES OF `ap`
IN str WITH `##`
RESULTS DATA(repl_tab)
IGNORING CASE. "ab## AB## ab##
"repl_tab:
"LINE OFFSET LENGTH
"0 2 2
"0 7 2
"0 12 2
str = str_original.
"... FIRST OCCURRENCE OF
"Note: repl_struc, which is declared inline here, is of type repl_result
REPLACE FIRST OCCURRENCE OF `ap`
IN str WITH `##`
RESULTS DATA(repl_struc)
IGNORING CASE.
"repl_struc:
"LINE OFFSET LENGTH
"0 2 2
You can use REPLACE SECTION ... OF
statements for position-based replacements, that is, to replace a section in a string starting at a specified offset for a specified length.
DATA(str_original) = `abap ABAP abap`.
DATA(str) = str_original.
"OFFSET + LENGTH specified
REPLACE SECTION OFFSET 5 LENGTH 4 OF str WITH `#`. "abap # abap
str = str_original.
"Only OFFSET (LENGTH: up to the end of the string)
REPLACE SECTION OFFSET 5 OF str WITH `#`. "abap #
str = str_original.
"Only LENGTH (OFFSET: starting from the leftmost position)
REPLACE SECTION LENGTH 6 OF str WITH `#`. "#BAP abap
Replacements in internal tables with REPLACE ... IN TABLE
(see the notes above for searching in internal tables):
DATA(str_table_original) = VALUE string_table( ( `aZbzZ` ) ( `cdZze` ) ( `Zzzf` ) ( `ghz` ) ).
DATA(str_table) = str_table_original.
"Replacing all occurrences in a table
"RESULTS addition: Storing information in an internal table of type repl_result_tab
REPLACE ALL OCCURRENCES OF `Z`
IN TABLE str_table
WITH `#`
RESULTS DATA(res_table)
RESPECTING CASE.
"str_table: a#bz# / cd#ze / #zzf / ghz
"res_table:
"LINE OFFSET LENGTH
"1 1 1
"1 4 1
"2 2 1
"3 0 1
str_table = str_table_original.
"Replacing the first occurrence in a table
"RESULTS addition: Storing information in a structure of type repl_result
REPLACE FIRST OCCURRENCE OF `Z`
IN TABLE str_table
WITH `#`
RESULTS DATA(res_structure)
RESPECTING CASE.
"str_table: a#bzZ / cdZze / Zzzf / ghz
"res_structure:
"LINE OFFSET LENGTH
"1 1 1
str_table = str_table_original.
"Restricting the search range in an internal table
REPLACE ALL OCCURRENCES OF `Z`
IN TABLE str_table
FROM 1 TO 2
WITH `#`
RESPECTING CASE.
"str_table: a#bz# / cd#ze / Zzzf / ghz
str_table = str_table_original.
"Offsets can be optionally specified (also only the offset of start or end line possible)
REPLACE ALL OCCURRENCES OF `Z`
IN TABLE str_table
FROM 1 OFFSET 3 TO 2 OFFSET 2
WITH `#`
RESPECTING CASE.
"str_table: aZbz# / cdZze / Zzzf / ghz
- The string function
replace
, allows you to store the result of a substring replacement in a separate variable. - What makes it especially powerful is that it returns a value, so it can be used at almost any read positions.
- The parameters of the
replace
string functions are similar to those of thefind
function. In addition, there is thewith
parameter for the replacement. Settingocc
to0
means that all occurrences are respected for the replacement.
Syntax examples:
DATA(str) = `abap ABAP abap`.
DATA res TYPE string.
"Note that here only the first occurrence is replaced.
res = replace( val = str sub = `ap` with = `#` ). "ab# ABAP abap
"Making the search case-insensitive
res = replace( val = str sub = `AB` with = `#` case = abap_false ). "#ap ABAP abap
"Setting occ
res = replace( val = str sub = `ab` with = `#` occ = 2 case = abap_false ). "abap #AP abap
"Replacing all occurrences: Setting occ to 0
res = replace( val = str sub = `ab` with = `#` occ = 0 case = abap_false ). "#ap #AP #ap
"Negative value for occ: Occurrences are counted from the right
res = replace( val = str sub = `ab` with = `#` occ = -1 ). "abap ABAP #ap
"Setting off and len for determining a subarea for replacements
"Note: When using off/len, sub and occ cannot be specified.
"Specifying both off and len
res = replace( val = str with = `#` off = 5 len = 3 ). "abap #P abap
"Specifying only off (len is 0 by default)
res = replace( val = str with = `#` off = 2 ). "ab#ap ABAP abap
"Note: When specifying only off and not specifying len or len = 0,
"replace works like insert
res = insert( val = str sub = `#` off = 2 ). "ab#ap ABAP abap
"Specifying only len (off is 0 by default): First segment of length in len is replaced
res = replace( val = str with = `#` len = 3 ). "#p ABAP abap
"Special case
"- off: equal to the length of the string
"- len: not specified or 0
"- Result: Value specified for 'with' is appended to the end of the string
res = replace( val = str with = `#` off = strlen( str ) ). "abap ABAP abap#
You can perform complex search and replace operations based on patterns. PCRE regular expressions help you process strings effectively.
💡 Note
Do not use POSIX regular expressions anymore, they are obsolete.
For simple patterns, you can use the comparison
operators
CP
(conforms to pattern) or its negation
NP
(does not conform to pattern) in comparison
expressions
to determine whether a set of characters is contained in a string that
matches a particular pattern. You can use the following
special characters as patterns:
Special Character | Details |
---|---|
* |
Any character sequence (including blanks). |
+ |
Any character (only one character, including blanks). |
# |
Escape character. The following character is marked for an exact comparison. |
Patterns are not case-sensitive except for characters marked with
#
. If a pattern is found, the system variable
sy-fdpos
returns the offset of the first occurrence.
Otherwise, it contains the length of the searched string.
DATA(s1) = `abc_def_ghi`.
"Pattern: f is preceded by any character sequence, must be followed
"by '_' and then followed by any character sequence
IF s1 CP `*f#_*`. ... "true; sy-fdpos = 6
"Pattern: 'i' is not followed by another character
IF s1 NP `i+`. ... "true; sy-fdpos = 11 (length of searched string)
There are several ways to perform complex searches in strings using PCRE expressions. They can be quite complex. The following overview shows common PCRE expressions with simple examples. For more information, see here.
Characters and character types
Expression | Represents | Example Regex | Example String | Matches | Does not Match |
---|---|---|---|---|---|
x |
Specific character | a |
abcdef | a | Anything else |
. |
Anything except a line break | . |
ab 1# | a, b, the blank, 1, # | ab, 1# |
\d |
Any digit (0-9), alternative: [0-9] |
\d |
a1-b2 3-4c9 | 1, 2, 3, 4, 9 | a, b, c, the blank and hyphens |
\D |
Any non-digit, alternative: [^0-9] |
\D |
a1-b2 3-4c9 | a, b, c, the blank and hyphens | 1, 2, 3, 4, 9 |
\s |
Any whitespace character such as a blank, tab and new line | \s |
(hi X ) | The blanks | h, i, X, (, ) |
\S |
Any character that is not a whitespace | \S |
(hi X ) | h, i, X, (, ) | The blanks |
\w |
Any word character (letter, digit or the underscore), alternative: [a-zA-Z0-9_] |
\w |
(ab 12_c) | a, b, c, 1, 2, _ | (, ), the blank |
\W |
Any character that is not a word character, alternative: [^a-zA-Z0-9_] |
\W |
(ab 12_c) | (, ), the blank | a, b, c, 1, 2, _ |
\ |
To include special characters like [] \ / ^ , use \ to escape them. Use \. to match a period ("."). |
.\. |
ab.cd.ef | ab.cd.ef | ab.cd.ef |
Repetitions and Alternatives
Expression | Represents | Example Regex | Example String | Matches | Does not Match |
---|---|---|---|---|---|
x* |
Zero or more repetitions of x |
ab* |
abc abbc abbbc a ac | abc abbc abbbc a ac | abc abbc abbbc a ac |
x+ |
One or more repetitions of x |
ab+ |
abc abbc abbbc a ac | abc abbc abbbc a ac | ... a ac |
x{m,n} |
Between m and n repetitions of x |
ab{2,3} |
abc abbc abbbc a ac | abc abbc abbbc a ac | abc ... |
x{m} |
Exactly m repetitions |
ab{3} |
abc abbc abbbc a ac | abc abbc abbbc a ac | abc abbc ... |
x{m,} |
Exactly m or more repetitions |
ab{2,} |
abc abbc abbbc a ac | abc abbc abbbc a ac | abc ... |
x? |
Optional x , i.e. zero or one time |
ab? |
abc abbc abbbc a ac | abc abbc abbbc a ac | ... ac |
x|y |
Matching alternatives, i. e. x or y |
1. b|2 2. b(a|u)t |
1. abc 123 2. bit bat but bet |
1. b, 2 2. bat, but |
1. a, c, 1, 3 2. bit, bet |
x*? |
x* captures greedily, i.e. as much as possible, while x*? captures non-greedily, i.e. as few as possible |
1. bc*? 2. a.*?# |
1. abcd abccccd ab 2. abc#defgh#i |
1. abcd abccccd ab 2. abc#defgh#i |
1. abcd abccccd ab (result for bc* ) 2. abc#defgh#i (result for a.*# ) |
x+? |
Same as above: x+ (greedy), x+? (non-greedy) |
1. bc+? 2. <.+?> |
1. abcd abccccd ab 2. <span>Hallo</span> html. |
1. abcd abccccd ab 2. <span>Hallo</span> html. |
1. abcd abccccd ab (result for bc+ ) 2. <span>Hallo</span> html. (result for <.+> ) |
Character Sets, Ranges, Subgroups and Lookarounds
Expression | Represents | Example Regex | Example String | Matches | Does not Match |
---|---|---|---|---|---|
[xy] |
Character set, matches a single character present in the list | b[iu] |
bit bat but bet | bit bat but bet | bit bat but bet |
[x-y] |
Character range, matches a single character in the specified range, note that ranges may be locale-dependent | a[a-c0-5] |
aa1 ab2 ba3 cac4 da56 a7 | aa1 ab2 ba3 cac4 da56 a7 | aa1 ab2 ba3 cac4 da56 a7 |
[^xy] |
Negation, matches any single character not present in the list | [^Ap] |
ABap | B, a | A, p |
[^x-y] |
Negation, matches any single character not within the range | [^A-Ca-c1-4] |
ABCDabcd123456 | D, d, 5, 6 | A, B, C, a, b, c, 1, 2, 3, 4 |
(...) |
Capturing group to group parts of patterns together | b(a|u)t |
bit bat but bet | bat, but | bit, bet |
(?=...) |
Positive lookahead, returns characters that are followed by a specified pattern without including this pattern | a(?=b) |
abc ade | abc ade | abc ade |
(?!...) |
Negative lookahead, returns characters that are not followed by a specified pattern without including this pattern | a(?!b) |
abc ade | abc ade | abc ade |
(?<=...) |
Positive lookbehind, returns characters that are preceded by a specified pattern without including this pattern | (?<=\s)c |
ab c abcd | ab c abcd (it is preceded by a blank) | ab c abcd |
(?<!...) |
Negative lookbehind, returns characters that are not preceded by a specified pattern without including this pattern | (?<!\s)c |
ab c abcd | ab c abcd (it is not preceded by a blank) | ab c abcd |
\1 |
Backreference, refers to a previous capturing group; 1 represents the number of the group index (the group index starts with 1) | (a.)(\w*)\1 |
abcdefabghij | abcdefabghij Note: Capturing group 1 holds ab in the example. The second capturing group captures all word characters until ab is found. |
abcdefabghij |
\K |
Resets the starting point of a match, i.e. findings are excluded from the final match | a.\Kc |
abcd | abcd | abcd |
💡 Note
- Subgroups are useful in replacements. By using an expression with
$
and a number, such as$1
, you can refer to a specific group. For example, you have a stringabcde
. A PCRE expression might be(ab|xy)c(d.)
, where two subgroups are specified within two pairs of parentheses. In a replacement pattern, you can refer to the first group with$1
and the second group with$2
. Thus, the replacement pattern$2Z$1
results indeZab
.(?:x)
creates a group but it is not captured. Example regular expression:(?:ab)(ap)
. Example string: 'abap'. It matches 'abap', but$1
will only contain 'ap'.- Note that
.
does not include new line feeds among others. If you want to capture a new line, you can use\n
as regular expression. The following example string includes a new line. All content between the HTML p tags should be replaced. You could use a regular expression to capture any character or new line as follows:DATA(str_a) = |<p>Hallo\n</p><p>Ciao!</p><p>Salut.</p>|. DATA(str_b) = str_a. REPLACE ALL OCCURRENCES OF PCRE `(<p>)(.*?)(<\/p>)` IN str_a WITH `$1Hi$3`. "<p>Hallo "</p><p>Hi</p><p>Hi</p> "Regular expression: any character or a new line with zero or more repretitions REPLACE ALL OCCURRENCES OF PCRE `(<p>)(.|\n)*?(<\/p>)` IN str_b WITH `$1Hi$3`. "<p>Hi</p><p>Hi</p><p>Hi</p>- Regarding special characters, check the Special Characters topic in the ABAP Keyword Documentation. For example, a non-breaking space whose hex code is U+00A0. You can replace all of the non-breaking space occurrences in a string as follows:
REPLACE ALL OCCURRENCES OF PCRE `\x{00A0}` IN some_string WITH ``. "Alternative REPLACE ALL OCCURRENCES OF PCRE `(*UTF)\N{U+00A0}` IN some_string WITH ``.
Anchors and Positions
Expression | Represents | Example Regex | Example String | Matches | Does not Match |
---|---|---|---|---|---|
^ |
Start of line, alternative: \A |
^. or \A. |
abc def | abc def | abc def |
$ |
End of line, alternative: \Z |
.$ or .\Z |
abc def | abc def | abc def |
\b |
Start or end of word | 1. \ba. 2. \Dd\b 3. \b.d\b |
abcd a12d ed | 1. abcd a12d ed 2. abcd a12d ed 3. abcd a12d ed |
1. abcd a12d ed 2. abcd a12d ed 3. abcd a12d ed |
\B |
Negation of \b , not at the start or end of words |
\Be\B |
see an elefant | see an elefant | see an elefant |
- Multiple string functions support PCRE expressions by offering the
pcre
parameter, which you can use to specify such an expression.FIND
andREPLACE
statements support regular expressions with thePCRE
addition. - The string function
match
works only with regular expressions. It returns a substring that matches a regular expression within a string. - For comparisons, you can
also use the predicate
function
matches
, which returns true or false if a string matches a given pattern or not.
Syntax examples:
DATA(s1) = `Cathy's black cat on the mat played with Matt.`.
"Determining the position of the first occurrence
"Here, the parameter occ is 1 by default.
DATA(int) = find( val = s1 pcre = `at.` ). "1
"Determining the number of all occurrences.
"Respects all 'a' characters not followed by 't', all 'at' plus 'att'
int = count( val = s1 pcre = `at*` ). "6
"Respects all 'at' plus 'att'
int = count( val = s1 pcre = `at+` ). "4
"Extracting a substring matching a given pattern
DATA(s2) = match( val = `The email address is [email protected].`
pcre = `\w+(\.\w+)*@(\w+\.)+(\w{2,4})` ). "[email protected]
"Predicate function matches
"Checking the validitiy of an email address
IF matches( val = `[email protected]`
pcre = `\w+(\.\w+)*@(\w+\.)+(\w{2,4})` ). "true
...
ENDIF.
"Examples with the FIND statement
"SUBMATCHES addition: Storing submatches in variables
"Pattern: anything before and after ' on '
FIND PCRE `(.*)\son\s(.*)` IN s1 IGNORING CASE SUBMATCHES DATA(a) DATA(b).
"a: 'Cathy's black cat' / b: 'the mat played with Matt.'.
"Determining the number of letters in a string
FIND ALL OCCURRENCES OF PCRE `[A-Za-z]` IN s1 MATCH COUNT DATA(c). "36
"Searching in an internal table and retrieving line, offset, length information
DATA(itab) = value string_table( ( `Cathy's black cat on the mat played with the friend of Matt.` ) ).
"Pattern: 't' at the beginning of a word followed by another character
FIND FIRST OCCURRENCE OF PCRE `\bt.` IN TABLE itab
IGNORING CASE MATCH LINE DATA(d) MATCH OFFSET DATA(e) MATCH LENGTH DATA(f). "d: 1, e: 21, f: 2
- You can create an object-oriented representation of regular expressions using the
CL_ABAP_REGEX
system class. - For example, the
CREATE_PCRE
method creates instances of regular expressions with PCRE syntax. - The instances can be used, for example, with the
CL_ABAP_MATCHER
class, which applies the regular expressions. - A variety of methods and parameters can be specified to accomplish various things and to further specify the handling of the regular expression.
- More information can be found here and in the class documentation (choose F2 on the class in ADT).
DATA(str) = `a1 # B2 ? cd . E3`.
"Creating a regex instance for PCRE regular expressions
"In the example, regex_inst has the type ref to cl_abap_regex.
DATA(regex_inst) = cl_abap_regex=>create_pcre( pattern = `\D\d` "any-non digit followed by a digit
ignore_case = abap_true ).
"Creating an instance of CL_ABAP_MATCHER using the method CREATE_MATCHER of the class CL_ABAP_REGEX
"You can also specify internal tables with the 'table' parameter and more.
DATA(matcher) = regex_inst->create_matcher( text = str ).
"Finding all results using the 'find_all' method
"In the example, result has the type match_result_tab containing the findings.
DATA(result) = matcher->find_all( ).
"Using method chaining
DATA(res) = cl_abap_regex=>create_pcre( pattern = `\s\w` "any blank followed by any word character
ignore_case = abap_true )->create_matcher( text = str )->find_all( ).
- To perform replacement operations using regular expressions, you can use both
the string function
replace
andREPLACE
statements with thepcre
parameter or thePCRE
addition. - Like the
find
function, among others, andFIND
statements, thereplace
function andREPLACE
statements offer a number of parameters and additions that you can use to further restrict the area to be replaced. - For more detailed information, refer to the ABAP Keyword Documentation.
- The executable example covers many of the PCRE expressions listed above.
Syntax examples:
DATA(s1) = `ab apppc app`.
DATA s2 TYPE string.
"Replaces 'p' with 2 - 4 repetitions, all occurences
s2 = replace( val = s1 pcre = `p{2,4}` with = `#` occ = 0 ). "ab a#c a#
"Replaces any single character not present in the list, all occurences
s2 = replace( val = s1 pcre = `[^ac]` with = `#` occ = 0 ). " "a##a###c#a##
"Replaces first occurence of a blank
s2 = replace( val = s1 pcre = `\s` with = `#` ). "ab#apppc app
"Greedy search
"The pattern matches anything before 'p'. The matching is carried out as
"often as possible. Hence, in this example the search stretches until the
"end of the string since 'p' is the final character, i. e. this 'p' and
"anything before is replaced.
s2 = replace( val = s1 pcre = `.*p` with = `#` ). "#
"Non-greedy search
"The pattern matches anything before 'p'. The matching proceeds until
"the first 'p' is found and does not go beyond. It matches as few as
"possible. Hence, the first found 'p' including the content before
"is replaced.
s2 = replace( val = s1 pcre = `.*?p` with = `#` ). "#ppc app
"Replacements with subgroups
"Replaces 'pp' (case-insensitive here) with '#', the content before and after 'pp' is switched
s2 = replace( val = s1
pcre = `(.*?)PP(.*)`
with = `$2#$1`
case = abap_false ). "pc app#ab a
"Changing the source field directly with a REPLACE statement; same as above
REPLACE PCRE `(.*?)PP(.*)` IN s1 WITH `$2#$1` IGNORING CASE. "pc app#ab a
"ALL OCCURRENCES addition
REPLACE ALL OCCURRENCES OF PCRE `\s` IN s1 WITH `?`. "pc?app#ab?a
REPLACE ALL OCCURRENCES OF PCRE `p.` IN s1 WITH `XY` "XY?aXY#ab?a
REPLACEMENT COUNT DATA(repl_cnt) "2
RESULTS DATA(repl_res).
"repl_res:
"LINE OFFSET LENGTH
"0 0 2
"0 4 2
As also covered in the Misc Built-in Functions cheat sheet, the following sections show more string functions available.
distance
returns the Levenshtein distance between two strings, which reflects their similarity.- Unlike other string functions, the return value has the type
i
. - Optional addition
max
: Positive integer. The calculation of the Levenshtein distance will stop if the calculated value is greater than this integer.
DATA(str_to_check) = `abap`.
DATA(dist1) = distance( val1 = str_to_check val2 = `abap` ). "0
DATA(dist2) = distance( val1 = str_to_check val2 = `axbap` ). "1
DATA(dist3) = distance( val1 = str_to_check val2 = `yabyyapy` ). "4
DATA(dist4) = distance( val1 = str_to_check val2 = `zabapzzzzzzzzzzzz` max = 5 ). "5
"If the value of max is 0 or less, an exception is raised.
TRY.
DATA(dist5) = distance( val1 = str_to_check val2 = `#ab#ap#` max = 0 ).
CATCH cx_sy_strg_par_val.
...
ENDTRY.
repeat
returns a string that contains the content of a specified string for parameterval
as many times as specified in the parameterocc
.- An empty string is returned when
occ
has the value 0 orval
is empty.
DATA(repeat1) = repeat( val = `abap` occ = 5 ). "abapabapabapabapabap
DATA(repeat2) = |#{ repeat( val = ` ` occ = 10 ) }#|. "# #
DATA(repeat3) = COND #( WHEN repeat( val = `a` occ = 0 ) = `` THEN `Y` ELSE `Z` ). "Y (initial value returned)
"If occ has a negative value, an exception is raised.
TRY.
DATA(repeat4) = repeat( val = `X` occ = -3 ).
CATCH cx_sy_strg_par_val.
...
ENDTRY.
cmin/cmax
returns a string that contains the content of the smallest or biggest of a set of character-like arguments- 'Set' means at least two arguments and a maximum of nine argeuments are passed (
valn
operators) for comparison. - The comparison is made from left to right, and the first different character found determines the smaller or bigger argument.
DATA(min) = cmin( val1 = `zzzzzzz`
val2 = `zzazzzzzzzz` "smallest argument
val3 = `zzzzabc` ).
DATA(max) = cmax( val1 = `abcdef` "biggest argument
val2 = `aaghij`
val3 = `aaaaklmn`
val4 = `aaaaaaopqrs`
val5 = `aaaaaaaaaatuvwxy`
val6 = `aaaaaaaaaaaaaz` ).
escape
returns a string that is provided for theval
parameter by escaping special characters according to the specification in theformat
parameter.- Suitable values for the
format
parameter (which expects a data object of typei
) are available in theCL_ABAP_FORMAT
class (the constants starting withE_
). - Special rules apply to different contexts, such as URLS and JSON. Also note the prevention of Cross Site Scripting (XSS) attacks on web applications. For more information, refer to the documentation.
"Context: URLs
DATA(esc1) = escape( val = '...test: 5@8...'
format = cl_abap_format=>e_url_full ).
"...test%3A%205%408...
"Context: JSON
DATA(esc2) = escape( val = 'some "test" json \ with backslash and double quotes'
format = cl_abap_format=>e_json_string ).
"some \"test\" json \\ with backslash and double quotes
"Context: String templates
DATA(esc3) = escape( val = 'Special characters in string templates: |, \, {, }'
format = cl_abap_format=>e_string_tpl ).
"Special characters in string templates: \|, \\, \{, \}
"Invalid value for the format parameter
TRY.
DATA(esc4) = escape( val = 'This will raise an exception due to an invalid format value.'
format = 123 ).
CATCH cx_sy_strg_par_val.
ENDTRY.
The comparison operators have already been covered in different sections above. This is a summary of the operators.
Comparison Operator | Details | Example |
---|---|---|
CA |
Contains any To determine whether any character of a given character set is contained in a string. Note: The search is case-sensitive. sy-fdpos contains the offset of the first character found, while 0 stands for the very first position. If nothing is found, sy-fdpos contains the length of the string. |
DATA(s1) = `cheers`.
IF s1 CA `aeiou`. ... "true; sy-fdpos: 2
IF s1 CA `xy`. ... "false; sy-fdpos: 6 |
NA |
Contains not any To determine whether any character of a given character set is not contained in a string. See the note above. |
DATA(s2) = `Hallo`.
IF s2 NA `bcdeh`. ... "true; sy-fdpos: 5
IF s2 NA `bcdeH`. ... "false; sy-fdpos: 0 |
CO |
Contains only To determine whether a string contains only a certain set of characters. See the note above. |
DATA(s3) = `abcd`.
IF s3 CO `abcd`. ... "true; sy-fdpos: 4
IF s3 CO `abCd`. ... "false; sy-fdpos: 2 |
CN |
Contains not only To determine whether a string does not only contain a certain set of characters, i.e. whether a string contains characters other than those in the character set. See the note above. |
DATA(s4) = `abap`.
IF s4 CN `ab`. ... "true; sy-fdpos: 3
IF s4 CN `abp`. ... "false; sy-fdpos: 4 |
CS |
Contains string For simple substring searches and determining whether a string contains a substring. Note: The search is not case-sensitive. sy-fdpos contains the offset of the first substring found. If it is not found, sy-fdpos contains the length of the string searched. |
DATA(s5) = `Lorem ipsum dolor sit amet.`.
IF s5 CS `or`. ... "true; sy-fdpos: 1
IF s5 CS `zz`. ... "false; sy-fdpos: 27 |
NS |
Contains no string To determine whether a substring is not contained in a string. See the note for CS . |
DATA(s6) = `some test string`.
IF s6 NS `tests`. ... "true; sy-fdpos: 16
IF s6 NS `TEST`. ... "false; sy-fdpos: 5 |
CP |
Conforms to pattern For simple pattern searches and determining whether a set of characters is contained in a string that matches a particular pattern. You can use the following special characters as patterns:
# . If a pattern is found, sy-fdpos returns the offset of the first occurrence. Otherwise, it contains the length of the string searched.
|
DATA(s7) = `abc_def_ghi`.
"Pattern: f is preceded by any character sequence, must be followed
"by '_' and then followed by any character sequence
IF s7 CP `*f#_*`. ... "true; sy-fdpos: 6
"Pattern: i is preceded by any character sequence, must be followed
"by any character or a blank
IF s7 CP `*i+`. ... "false; sy-fdpos: 11 |
NP |
Does not conform to pattern Negation of CP . See the previous notes. |
DATA(s8) = `abcDEFghi`.
"Pattern: c is preceded by any character sequence, must be followed
"by a small letter d, and then followed by any character sequence
IF s8 NP `*c#d*`. ... "true; sy-fdpos: 9
"Pattern: c is preceded by any character sequence, must be followed
"by a capital letter D, and then followed by any character sequence
IF s8 NP `*c#D*`. ... "false; sy-fdpos: 2 |
The following list (as also covered in the Misc ABAP Classes cheat sheet) shows a selected set of classes that support string processing.
-
CL_ABAP_CHAR_UTILITIES
: As previously mentioned, this class provides utilities for string processing, such as attributes that represent new lines and horizontal tabs.DATA(tabbed) = `#` && cl_abap_char_utilities=>horizontal_tab && `#`. "The following attributes can be replaced by a representation of "the control characters in a string template. ASSERT cl_abap_char_utilities=>newline = |\n|. ASSERT cl_abap_char_utilities=>horizontal_tab = |\t|. ASSERT cl_abap_char_utilities=>cr_lf = |\r\n|.
-
CL_ABAP_STRING_UTILITIES
: For processing text strings, such as handling trailing blanks in character strings (i.e. data objects of typestring
).DATA(string) = `ABAP `. "Removing trailing blanks cl_abap_string_utilities=>del_trailing_blanks( CHANGING str = string ). "`ABAP` "Preserving trailing blanks when assigning text fields to data objects of "type string DATA(chars) = 'ABAP '. cl_abap_string_utilities=>c2str_preserving_blanks( EXPORTING source = chars IMPORTING dest = DATA(str_w_blanks) ). "`ABAP ` DATA(str_no_blanks) = CONV string( chars ). "`ABAP`
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XCO_CP
: The Extension Components Library (XCO) library provides released APIs and offers various development utilities. Find more information here. The following code snippet demonstrates several methods of the class that deal with string processing."--------- Extracting a substring from a string --------- DATA(some_string) = `abcdefghijklmnopqrstuvwxyz`. "Creating an encapsulation of a string using XCO DATA(str) = xco_cp=>string( some_string ). "Using the FROM and TO methods, you can determine "the character position. Note that the value includes the "character at the position specified. "The character index pattern for the example string above "is (the string has 26 characters in total): "a = 1, b = 2, c = 3 ... z = 26 "a = -26, b = -25, c = -24 ... z = -1 "Providing a value that is out of bounds means that "the first (or the last) character of the string is used "by default. "Note: When combining FROM and TO, e.g. with method "chaining ...->from( ...)->to( ... ), note that another "instance is created with the first 'from', and another "character index pattern is created based on the new "and adjusted string value. "bcdefghijklmnopqrstuvwxyz DATA(sub1) = str->from( 2 )->value. "defghijklmnopqrstuvwxyz DATA(sub2) = str->from( -23 )->value. "vwxyz DATA(sub3) = str->from( -5 )->value. "abcde DATA(sub4) = str->to( 5 )->value. "ab DATA(sub5) = str->to( -25 )->value. "Result of 1st 'from' method call: bcdefghijklmnopqrstuvwxyz "Based on this result, the 'to' method call is "applied. "bcdefg DATA(sub6) = str->from( 2 )->to( 6 )->value. "Result of 1st 'to' method call: abcdefghijklmnopq "Based on this result, the 'from' method call is "applied. "defghijklmnopq DATA(sub7) = str->to( -10 )->from( 4 )->value. "Values that are out of bounds. "In the example, the first and last character of the "string are used. "abcdefghijklmnopqrstuvwxyz DATA(sub8) = str->from( 0 )->to( 100 )->value. "--------- Splitting and joining --------- "Splitting a string into a string table DATA(str_table) = xco_cp=>string( `Hello.World.ABAP` )->split( `.` )->value. "Hello "World "ABAP "Concatenating a string table into a string; specifying a delimiter str_table = VALUE #( ( `a` ) ( `b` ) ( `c` ) ). "a, b, c DATA(conc_str1) = xco_cp=>strings( str_table )->join( `, ` )->value. "Concatenating a string table into a string; specifying a delimiter and "reversing the table order "c / b / a DATA(conc_str2) = xco_cp=>strings( str_table )->reverse( )->join( ` / ` )->value. "--------- Prepending and appending strings --------- DATA(name) = xco_cp=>string( `Max Mustermann` ). "Max Mustermann, Some Street 1, 12345 Someplace DATA(address) = name->append( `, Some Street 1, 12345 Someplace` )->value. "Mr. Max Mustermann DATA(title) = name->prepend( `Mr. ` )->value. "--------- Transforming to lowercase and uppercase --------- "ABAP DATA(to_upper) = xco_cp=>string( `abap` )->to_upper_case( )->value. "hallo world DATA(to_lower) = xco_cp=>string( `HALLO WORLD` )->to_lower_case( )->value. "--------- Checking if a string starts/ends with a specific string --------- DATA check TYPE string. DATA(str_check) = xco_cp=>string( `Max Mustermann` ). "yes IF str_check->ends_with( `mann` ). check = `yes`. ELSE. check = `no`. ENDIF. "no IF str_check->starts_with( `John` ). check = `yes`. ELSE. check = `no`. ENDIF. "--------- Converting strings to xstrings using a codepage --------- "536F6D6520737472696E67 DATA(xstr) = xco_cp=>string( `Some string` )->as_xstring( xco_cp_character=>code_page->utf_8 )->value. "--------- Camel case compositions and decompositions with split and join operations --------- "Pascal case is also possible "someValue DATA(comp) = xco_cp=>string( `some_value` )->split( `_` )->compose( xco_cp_string=>composition->camel_case )->value. "Camel case decomposition "some_value DATA(decomp) = xco_cp=>string( `someValue` )->decompose( xco_cp_string=>decomposition->camel_case )->join( `_` )->value. "--------- Matching string against regular expression --------- DATA match TYPE string. "yes IF xco_cp=>string( ` 1` )->matches( `\s\d` ). match = 'yes'. ELSE. match = 'no'. ENDIF. "no IF xco_cp=>string( ` X` )->matches( `\s\d` ). match = 'yes'. ELSE. match = 'no'. ENDIF.
💡 Note
- The executable example ...
- covers the following topics:
- Creating strings and assigning values
- String templates
- Operations with strings operations: chaining, concatenating, splitting, modifying
- Searching and replacing
- Regular expressions
- The steps to import and run the code are outlined here.
- Disclaimer