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abap-cheat-sheets/src/zcl_demo_abap_xml_json.clas.abap
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***********************************************************************
*
* ABAP cheat sheet: Working with XML and JSON in ABAP
*
* -------------------------- PURPOSE ----------------------------------
* - Example that demonstrates working with XML and JSON in ABAP.
* - The following topics are covered:*
* - Processing XML using class libraries (iXML, sXML)
* - XML Transformations using XSLT and Simple Transformations
* - CALL TRANSFORMATION syntax
* - Dealing with JSON data, XCO classes for JSON
* - Excursions: Converting string <-> xstring, compressing and
* decompressing binary data
*
* ----------------------- GETTING STARTED -----------------------------
* - Open the class with the ABAP development tools for Eclipse (ADT).
* - Choose F9 to run the class.
* - Check the console output.
* - To understand the context and the ABAP syntax used, refer to the
* notes included in the class as comments or refer to the respective
* topic in the ABAP Keyword Documentation.
* - Due to the amount of console output, the examples contain numbers
* (e.g. 1) ..., 2) ..., 3) ...) for the individual example sections.
* Also, the variable name is displayed in most cases. So to find
* the relevant output in the console easier and faster, just search
* for the number/variable name in the console (CTRL+F in the console)
* or use the debugger.
*
* ----------------------------- NOTE -----------------------------------
* The code presented in this class is intended only to support the ABAP
* cheat sheets. It is not intended for direct use in a production system
* environment. The code examples in the ABAP cheat sheets are primarily
* intended to provide a better explanation and visualization of the
* syntax and semantics of ABAP statements, not to solve concrete
* programming tasks. For production application programs, you should
* always work out your own solution for each individual case. There is
* no guarantee for the correctness or completeness of the code.
* Furthermore, there is no legal responsibility or liability for any
* errors or their consequences that may occur when using the the example
* code.
*
***********************************************************************
"! <p class="shorttext synchronized">ABAP cheat sheet: Working with XML and JSON in ABAP</p>
"! Example that demonstrates working with XML and JSON in ABAP..<br>Choose F9 in ADT to run the class.
CLASS zcl_demo_abap_xml_json DEFINITION
PUBLIC
FINAL
CREATE PUBLIC .
PUBLIC SECTION.
INTERFACES: if_oo_adt_classrun,
"This interface is implemented for serializing and
"deserialzing instances of classes (objects).
if_serializable_object.
CLASS-METHODS class_constructor.
PROTECTED SECTION.
PRIVATE SECTION.
CLASS-METHODS format IMPORTING input TYPE data
xml TYPE abap_bool DEFAULT abap_true
RETURNING VALUE(string) TYPE string.
TYPES c50 TYPE c LENGTH 50.
TYPES c50_tab_type TYPE TABLE OF c50 WITH EMPTY KEY.
TYPES x30 TYPE x LENGTH 30.
TYPES x30_tab_type TYPE TABLE OF x30 WITH EMPTY KEY.
"The following instance attribues and methods are used for serializing and
"deserialzing instances of classes (objects)
DATA: attr_string_a TYPE string,
attr_string_b TYPE string,
attr_concat_string TYPE string,
attr_lowercase_str TYPE string.
METHODS: concatenate_string,
lowercase_string,
"The following method can only have output parameters.
"For each output parameter of the serialize_helper method, you must specify
"an identically named input parameter of the deserialize_helper method
"with the same type.
serialize_helper EXPORTING attr_string_a TYPE string
attr_string_b TYPE string
attr_concat_string TYPE string,
"This method can only have input parameters.
deserialize_helper IMPORTING attr_string_a TYPE string
attr_string_b TYPE string
attr_concat_string TYPE string.
ENDCLASS.
CLASS zcl_demo_abap_xml_json IMPLEMENTATION.
METHOD if_oo_adt_classrun~main.
out->write( |ABAP Cheat Sheet Example: Working with XML and JSON in ABAP\n\n| ).
out->write( |1) Excursion: Converting string <-> xstring| ).
"In the following examples, many operations are performed using binary data.
"This excursion shows the conversion of string to xstring and the other way round
"using a codepage. The examples use UTF-8.
"For this purpose, you can, for example, use the cl_abap_conv_codepage class
"and the XCO library.
"Storing XML data in a data object of type string
DATA(xml_string) =
`<flights>` &&
` <flight>` &&
` <carrier>LH</carrier>` &&
` <flightnumber>400</flightnumber>` &&
` <departure>` &&
` <city>Frankfurt</city>` &&
` <airport>FRA</airport>` &&
` <time>2023-12-23T10:30:00</time>` &&
` </departure>` &&
` <arrival>` &&
` <city>Berlin</city>` &&
` <airport>SXF</airport>` &&
` <time>2023-12-23T11:35:00</time>` &&
` </arrival>` &&
` </flight>` &&
` <flight>` &&
` <carrier>DL</carrier>` &&
` <flightnumber>1984</flightnumber>` &&
` <departure>` &&
` <city>San Francisco</city>` &&
` <airport>SFO</airport>` &&
` <time>2023-07-19T10:00:00</time>` &&
` </departure>` &&
` <arrival>` &&
` <city>New York</city>` &&
` <airport>JFK</airport>` &&
` <time>2023-07-19T18:25:00</time>` &&
` </arrival>` &&
` </flight>` &&
`</flights>`.
"string -> xstring
"Note: UTF-8 is used by default. Here, it is specified explicitly.
"Conversion errors are caught using the cx_sy_conversion_codepage class.
TRY.
DATA(conv_xstring) = cl_abap_conv_codepage=>create_out( codepage = `UTF-8` )->convert( xml_string ).
CATCH cx_sy_conversion_codepage.
ENDTRY.
"xstring -> string
DATA(conv_string) = cl_abap_conv_codepage=>create_in( )->convert( conv_xstring ).
"As an alternative, you can use methods of the XCO library.
"string -> xstring
DATA(conv_xstring_xco) = xco_cp=>string( xml_string
)->as_xstring( xco_cp_character=>code_page->utf_8
)->value.
"xstring -> string
DATA(conv_string_xco) = xco_cp=>xstring( conv_xstring_xco
)->as_string( xco_cp_character=>code_page->utf_8
)->value.
conv_string = format( conv_string ).
conv_string_xco = format( conv_string_xco ).
out->write( |\n| ).
out->write( `Results of the xstring to string conversions:` ).
out->write( |\n| ).
out->write( conv_string ).
out->write( |\n| ).
out->write( conv_string_xco ).
**********************************************************************
out->write( zcl_demo_abap_aux=>heading( `2) Processing XML Using Class Libraries` ) ).
out->write( |Excursion: Usable iXML/sXML Classes and Interfaces\n\n| ).
"Using a released CDS view, classes and interfaces are retrieved that
"have 'ixml' and 'sxml' in the name for you to explore the released classes
"and interfaces in this context.
SELECT ReleasedObjectType, ReleasedObjectName, ReleaseState
FROM i_apisforclouddevelopment
WHERE releasestate = 'RELEASED'
AND
( ReleasedObjectType = 'CLAS' OR ReleasedObjectType = 'INTF' )
AND
( ReleasedObjectName LIKE '%IXML%' OR ReleasedObjectName LIKE '%SXML%' )
INTO TABLE @DATA(released_xml_libs).
out->write( `No output. You can check the internal table content in the debugger to view the usable artifacts.` ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `3) Creating XML Data Using iXML` ) ).
"In the following example, XML data is created using the iXML library.
"This is done by creating DOM nodes step by step. The nodes are created as
"elements and attributes. Content is inserted into the XML data.
"The example uses an appropriate attribute setting so that the result
"represents XML data in asXML format.
"Note: You can check out more examples in the system by choosing CTRL +
"SHIFT + A in ADT and search for *demo_ixml*.
"For more information on the classes/methods used, check the documentation
"by choosing F2 in ADT when placing the cursor on a class/methods.
"Creating one factory object of the access class cl_ixml_core using the
"create method. The object is used to access the iXML library.
DATA(ixml_cr) = cl_ixml_core=>create( ).
"Creating a document
DATA(document_cr) = ixml_cr->create_document( ).
"Step-by-step creation of DOM nodes
"Creating a root node
DATA(root) = document_cr->create_element_ns( name = 'abap'
prefix = 'asx' ).
root->set_attribute_ns( name = 'asx'
prefix = 'xmlns'
value = 'http://www.sap.com/abapxml' ).
root->set_attribute_ns( name = 'version'
value = '1.0' ).
document_cr->append_child( root ).
DATA(xml_node1) = document_cr->create_element_ns( prefix = 'asx'
name = 'values' ).
root->append_child( xml_node1 ).
DATA(xml_node2) = document_cr->create_element_ns( name = 'STRING' ).
xml_node1->append_child( xml_node2 ).
xml_node2->append_child( document_cr->create_text( 'Hello ABAP' ) ).
"Creating a renderer (for rendering the XML document into the output stream)
DATA xml_doc TYPE xstring.
ixml_cr->create_renderer( document = document_cr
ostream = ixml_cr->create_stream_factory( )->create_ostream_xstring( string = xml_doc )
)->render( ).
"Getting XML data
DATA(xml_output) = format( cl_abap_conv_codepage=>create_in( )->convert( xml_doc ) ).
out->write( xml_output ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `4) Parsing XML Data Using iXML` ) ).
"The example covers the following aspects:
"- Parsing XML data to a DOM object in one go
"- Directly reading nodes using various iXML methods
"- Directly reading nodes using element names
"- Reading using iterators, i.e. going over the XML nodes one after another
"- During the iteration, ...
" ... node properties are extracted using various iXML methods
" (and stored in an internal table for display purposes).
" ... the XML data is modified.
" ... a new element is created.
"- Rendering XML data
"Internal table to store node properties for display purposes
DATA properties TYPE string_table.
"Creating simple demo XML data to be used in the example
TRY.
DATA(some_xml) = cl_abap_conv_codepage=>create_out( )->convert(
`<hi>` &&
` <word1>hallo</word1>` &&
` <word2>how</word2>` &&
` <word3>are</word3>` &&
`</hi>` ).
CATCH cx_sy_conversion_codepage.
ENDTRY.
"Creating one factory object of the access class cl_ixml_core using the
"create method. It is used to access the iXML library.
DATA(ixml_pa) = cl_ixml_core=>create( ).
"Creaing an input stream that is used for the input of XML data
DATA(stream_factory_pa) = ixml_pa->create_stream_factory( ).
"Creating an XML document stored in DOM format in the memory
DATA(document_pa) = ixml_pa->create_document( ).
"Creating a parser
"It requires the following input parameters: input stream to be parsed,
"the XML document to which the stream is parsed, a factory required to create a stream
DATA(parser_pa) = ixml_pa->create_parser(
istream = stream_factory_pa->create_istream_xstring( string = some_xml )
document = document_pa
stream_factory = stream_factory_pa ).
"Parsing XML data to a DOM representation in one go. It is put in the memory.
"Note: You can also parse sequentially, and not in one go.
DATA(parsing_check) = parser_pa->parse( ).
IF parsing_check = 0. "Parsing was successful
"Directly reading nodes using various iXML methods
"Accessing the root element of the DOM. It can be used as the initial node
"for accessing subnodes.
"You can check the content of the variables in the debugger.
"Note: Multiple methods are available to further process the nodes.
DATA(root_element) = document_pa->get_root_element( ).
"First subnode
DATA(child_element) = root_element->get_first_child( ).
"Getting the value of that node
DATA(child_element_value) = child_element->get_value( ).
"Next adjacent node/getting the value
DATA(next_element_value) = child_element->get_next( )->get_value( ).
"Directly reading nodes using element names
"The result is the first element searched for.
DATA(element_by_name) = document_pa->find_from_name( name = `word3` )->get_value( ).
"A lot more options are available such as access by attributes.
"Reading using iterators, i.e. going over the XML nodes sequentially
"Creating an iterator
DATA(iterator_pa) = document_pa->create_iterator( ).
DO.
"For the iteration, you can use the get_next method to process the nodes one after another.
"Note: Here, all nodes are respected. You can also create filters to go over specific nodes.
DATA(node_i) = iterator_pa->get_next( ).
IF node_i IS INITIAL.
EXIT.
ELSE.
"Extracting properties
"For display purposes, the properties are stored in an internal table.
APPEND |gid: { node_i->get_gid( ) } / type: { node_i->get_type( ) } / name: { node_i->get_name( ) } / value: { node_i->get_value( ) }| TO properties.
ENDIF.
IF node_i->get_type( ) = if_ixml_node=>co_node_text.
"Modifying values
"Here, the values are capitalized.
node_i->set_value( to_upper( node_i->get_value( ) ) ).
ENDIF.
"Creating a new element
IF node_i->get_value( ) = 'are'.
document_pa->create_simple_element_ns( name = 'word4'
value = 'you'
parent = node_i->get_parent( ) ).
ENDIF.
ENDDO.
"Creating a renderer
DATA xml_pa TYPE xstring.
ixml_pa->create_renderer( document = document_pa
ostream = ixml_pa->create_stream_factory( )->create_ostream_xstring( string = xml_pa )
)->render( ).
"Getting XML
DATA(output_ixml_parsing) = format( cl_abap_conv_codepage=>create_in( )->convert( xml_pa ) ).
out->write( output_ixml_parsing ).
out->write( |\n| ).
out->write( `Node properties:` ).
out->write( properties ).
ELSE.
out->write( `Parsing was not successful.` ).
ENDIF.
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `5) Creating XML Data Using sXML (Token-Based Rendering)` ) ).
"For sXML, there are specialized writer classes, such as CL_SXML_STRING_WRITE.
"Writers created with this class render XML data to a byte string.
"The XML 1.0 format and UTF-8 are used by default in the create method.
"Here, the parameters are specified explicitly.
"Note: The interface IF_SXML_WRITER contains the components that are valid
"for all readers (the abstract superclass CL_SXML_WRITER includes this
"interface as well as implementations for all readers). In the example below,
"a cast is required so as to access special methods (such as open_element).
DATA(writer) = CAST if_sxml_writer( cl_sxml_string_writer=>create( type = if_sxml=>co_xt_xml10
encoding = 'UTF-8' ) ).
TRY.
"Creating nodes (the order of the nodes is important)
writer->open_element( name = 'flights' ).
writer->open_element( name = 'flight' ).
writer->open_element( name = 'carrier' ).
writer->write_value( 'LH' ).
writer->close_element( ).
writer->open_element( name = 'flightnumber' ).
writer->write_value( '400' ).
writer->close_element( ).
writer->close_element( ).
writer->open_element( name = 'flight' ).
writer->open_element( name = 'carrier' ).
writer->write_value( 'DL' ).
writer->close_element( ).
writer->open_element( name = 'flightnumber' ).
writer->write_value( '1984' ).
writer->close_element( ).
writer->close_element( ).
writer->close_element( ).
CATCH cx_sxml_state_error INTO DATA(error_token).
out->write( error_token->get_text( ) ).
ENDTRY.
"Getting XML data
"The XML data can be retrieved with the GET_OUTPUT method.
"Also here, a cast is required. The result is of type xstring.
DATA(xml_sxml) = CAST cl_sxml_string_writer( writer )->get_output( ).
DATA(output_sxml_token_rendering) = format( cl_abap_conv_codepage=>create_in( )->convert( xml_sxml ) ).
out->write( output_sxml_token_rendering ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `6) Creating XML Data using sXML (Object-Oriented Rendering)` ) ).
DATA(writer_oo) = CAST if_sxml_writer( cl_sxml_string_writer=>create( type = if_sxml=>co_xt_xml10
encoding = 'UTF-8' ) ).
TRY.
writer_oo->write_node( writer_oo->new_open_element( name = 'flights' ) ).
writer_oo->write_node( writer_oo->new_open_element( name = 'flight' ) ).
writer_oo->write_node( writer_oo->new_open_element( name = 'carrier' ) ).
DATA(val) = writer_oo->new_value( ).
val->set_value( 'AZ' ).
writer_oo->write_node( val ).
writer_oo->write_node( writer_oo->new_close_element( ) ).
writer_oo->write_node( writer_oo->new_open_element( name = 'flightnumber' ) ).
val = writer_oo->new_value( ).
val->set_value( '788' ).
writer_oo->write_node( val ).
writer_oo->write_node( writer_oo->new_close_element( ) ).
writer_oo->write_node( writer_oo->new_close_element( ) ).
writer_oo->write_node( writer_oo->new_open_element( name = 'flight' ) ).
writer_oo->write_node( writer_oo->new_open_element( name = 'carrier' ) ).
val = writer_oo->new_value( ).
val->set_value( 'JL' ).
writer_oo->write_node( val ).
writer_oo->write_node( writer_oo->new_close_element( ) ).
writer_oo->write_node( writer_oo->new_open_element( name = 'flightnumber' ) ).
val = writer_oo->new_value( ).
val->set_value( '407' ).
writer_oo->write_node( val ).
writer_oo->write_node( writer_oo->new_close_element( ) ).
writer_oo->write_node( writer_oo->new_close_element( ) ).
writer_oo->write_node( writer_oo->new_close_element( ) ).
CATCH cx_sxml_state_error INTO DATA(error_oo).
out->write( error_oo->get_text( ) ).
ENDTRY.
DATA(xml_sxml_oo_rendering) = CAST cl_sxml_string_writer( writer_oo )->get_output( ).
DATA(output_sxml_oo_rendering) = format( cl_abap_conv_codepage=>create_in( )->convert( xml_sxml_oo_rendering ) ).
out->write( output_sxml_oo_rendering ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `7) Parsing XML Data using sXML (Token-Based Parsing)` ) ).
"Creating demo XML data to be used in the example
TRY.
DATA(xml_to_parse) = cl_abap_conv_codepage=>create_out( )->convert(
`<?xml version="1.0"?>` &&
`<node attr_a="123">` &&
` <subnode1>` &&
` <letter>A</letter>` &&
` <date format="mm-dd-yyyy">01-01-2024</date>` &&
` </subnode1>` &&
` <subnode2>` &&
` <text attr_b="1" attr_c="a">abc</text>` &&
` <text attr_b="2" attr_c="b">def</text>` &&
` <text attr_b="3" attr_c="c">ghi</text>` &&
` <text attr_b="4" attr_c="d">jkl</text>` &&
` </subnode2>` &&
`</node>` ).
CATCH cx_sy_conversion_codepage.
ENDTRY.
"Creating an internal table for display purposes
DATA: BEGIN OF node_info,
node_type TYPE string,
prefix TYPE string,
name TYPE string,
nsuri TYPE string,
value_type TYPE string,
value TYPE string,
value_raw TYPE xstring,
END OF node_info,
nodes_tab LIKE TABLE OF node_info.
"Creating reader
"Note: See the comments for the writer above which is similar. For readers,
"the interface IF_SXML_READER exists. In this example, no special methods
"are used. Therefore, a cast is not carried out.
DATA(reader) = cl_sxml_string_reader=>create( xml_to_parse ).
"DATA(reader_cast) = CAST if_sxml_reader( cl_sxml_string_reader=>create( xml_oo ) ).
"To iterate accros all nodes, you can call the NEXT_NODE method.
TRY.
DO.
"Check out other available methods in ADT by placing the cursor behind ->
"and choosing CTRL + Space.
reader->next_node( ).
"When reaching the end of the XML data, the loop is exited.
IF reader->node_type = if_sxml_node=>co_nt_final.
EXIT.
ENDIF.
"You can access the properties of the node directly.
"For display purposes, the property information is stored in an internal table.
"The demo XML data that is used here does not include all properties. Therefore,
"the values for these are initial.
"Node type, see the interface if_sxml_node
DATA(node_type) = SWITCH #( reader->node_type WHEN if_sxml_node=>co_nt_initial THEN `CO_NT_INITIAL`
WHEN if_sxml_node=>co_nt_element_open THEN `CO_NT_ELEMENT_OPEN`
WHEN if_sxml_node=>co_nt_element_close THEN `CO_NT_ELEMENT_CLOSE`
WHEN if_sxml_node=>co_nt_value THEN `CO_NT_VALUE`
WHEN if_sxml_node=>co_nt_attribute THEN `CO_NT_ATTRIBUTE`
ELSE `Error` ).
DATA(prefix) = reader->prefix. "Namespace prefix
DATA(name) = reader->name. "Name of the element
DATA(nsuri) = reader->nsuri. "Namespace URI
"Value type, see the interface if_sxml_value
DATA(value_type) = SWITCH #( reader->value_type WHEN 0 THEN `Initial`
WHEN if_sxml_value=>co_vt_none THEN `CO_VT_NONE`
WHEN if_sxml_value=>co_vt_text THEN `CO_VT_TEXT`
WHEN if_sxml_value=>co_vt_raw THEN `CO_VT_RAW`
WHEN if_sxml_value=>co_vt_any THEN `CO_VT_ANY`
ELSE `Error` ).
DATA(value) = reader->value. "Character-like value (if it is textual data)
DATA(value_raw) = reader->value_raw. "Byte-like value (if it is raw data)
APPEND VALUE #( node_type = node_type
prefix = prefix
name = name
nsuri = nsuri
value_type = value_type
value = value
value_raw = value_raw ) TO nodes_tab.
"Once the method is called, you can directly access the attributes of the reader with the required
"properties of the node. When the parser is on the node of an element opening, you can use the method
"NEXT_ATTRIBUTE to iterate across the XML element attributes.
IF reader->node_type = if_sxml_node=>co_nt_element_open.
DO.
reader->next_attribute( ).
IF reader->node_type <> if_sxml_node=>co_nt_attribute.
EXIT.
ENDIF.
APPEND VALUE #( node_type = `attribute`
prefix = reader->prefix
name = reader->name
nsuri = reader->nsuri
value = reader->value
value_raw = reader->value_raw ) TO nodes_tab.
ENDDO.
ENDIF.
ENDDO.
CATCH cx_sxml_state_error INTO DATA(error_parse_token).
out->write( error_parse_token->get_text( ) ).
ENDTRY.
out->write( `Node properties:` ).
out->write( nodes_tab ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `8) Parsing XML Data using sXML (Object-Oriented Parsing)` ) ).
CLEAR nodes_tab.
DATA(reader_oo) = cl_sxml_string_reader=>create( xml_to_parse ).
TRY.
DO.
"To iterate accros all nodes, you can call the READ_NEXT_NODE method.
"When the end of the XML data is reached, the returned value is initial.
DATA(node_oo) = reader_oo->read_next_node( ).
IF node_oo IS INITIAL.
EXIT.
ENDIF.
"In object-oriented parsing, methods for token-based parsing are wrapped.
"An object-oriented access to the node is provided.
"References to objects that represent the current node are returned.
"Getting the node type
DATA(n_type) = node_oo->type.
"If the parser is currently on the node of an element opening,
"the node object has the class CL_SXML_OPEN_ELEMENT that implements the
"interface IF_SXML_OPEN_ELEMENT. With the methods included, you can
"access the XML attributes of the element, e.g. using the GET_ATTRIBUTES
"method to put the references for all attributes into an internal table.
"To access the attributes, a downcast is required.
CASE n_type.
WHEN if_sxml_node=>co_nt_element_open.
DATA(open_element) = CAST if_sxml_open_element( node_oo ).
APPEND VALUE #( node_type = `open element`
prefix = open_element->prefix
name = open_element->qname-name
nsuri = open_element->qname-namespace
) TO nodes_tab.
DATA(attributes) = open_element->get_attributes( ).
LOOP AT attributes INTO DATA(attribute).
APPEND VALUE #( node_type = `attribute`
prefix = open_element->prefix
name = open_element->qname-name
nsuri = open_element->qname-namespace
value = SWITCH #( attribute->value_type WHEN if_sxml_value=>co_vt_text THEN attribute->get_value( ) )
value_raw = SWITCH #( attribute->value_type WHEN if_sxml_value=>co_vt_raw THEN attribute->get_value_raw( ) )
) TO nodes_tab.
ENDLOOP.
WHEN if_sxml_node=>co_nt_element_close.
DATA(close_element) = CAST if_sxml_close_element( node_oo ).
APPEND VALUE #( node_type = `close element`
prefix = open_element->prefix
name = open_element->qname-name
nsuri = open_element->qname-namespace
) TO nodes_tab.
WHEN if_sxml_node=>co_nt_value.
DATA(value_node_oo) = CAST if_sxml_value_node( node_oo ).
APPEND VALUE #( node_type = `value`
value = SWITCH #( value_node_oo->value_type WHEN if_sxml_value=>co_vt_text THEN value_node_oo->get_value( ) )
value_raw = SWITCH #( value_node_oo->value_type WHEN if_sxml_value=>co_vt_raw THEN value_node_oo->get_value_raw( ) )
) TO nodes_tab.
WHEN OTHERS.
APPEND VALUE #( node_type = `Error` ) TO nodes_tab.
ENDCASE.
ENDDO.
CATCH cx_sxml_state_error INTO DATA(error_parse_oo).
out->write( error_parse_oo->get_text( ) ).
ENDTRY.
out->write( `Node properties:` ).
out->write( nodes_tab ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `XML Transformations` ) ).
out->write( |9) Excursion: Available ABAP Cheat Sheet Transformations in the System\n\n| ).
"Excursion using the XCO library. In this example, tranformation programs are retrieved.
"A filter is applied. Because of a filter that is applied, only the ABAP cheat sheet
"transformation programs are returned.
DATA(filter) = xco_cp_abap_repository=>object_name->get_filter(
xco_cp_abap_sql=>constraint->contains_pattern( 'ZDEMO_ABAP_%' ) ).
DATA(filtered_transformations) = xco_cp_abap_repository=>objects->xslt->where( VALUE #( ( filter )
) )->in( xco_cp_abap=>repository )->get( ).
IF filtered_transformations IS NOT INITIAL.
TYPES cst TYPE TABLE OF sxco_tf_object_name WITH EMPTY KEY.
DATA(cheat_sheet_transformations) = VALUE cst( FOR tr IN filtered_transformations ( tr->name ) ).
out->write( cheat_sheet_transformations ).
out->write( |\n| ).
out->write( `The code contains an implementation that gets all the transformations in the system.` ).
out->write( `You can check the content of the variable in the debugger. Among the transformations is the predefined identity transformation ID.` ).
ENDIF.
"Getting all transformations in the system
"You can check the table content in the debugger.
DATA(all_transformations) = xco_cp_abap_repository=>objects->xslt->all->in( xco_cp_abap=>repository )->get( ).
IF all_transformations IS NOT INITIAL.
DATA(all_transformations_in_system) = VALUE cst( FOR tr IN all_transformations ( tr->name ) ).
ENDIF.
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `10) Transforming XML to XML Using XSLT` ) ).
"In this example, XML is transformed to XML. For this purpose, a simple XSLT
"program does the following:
"- All nodes and attributes are copied from the source XML to the target XML
" without any changes.
"- A match on two elements is performed. If matched, two new elements are created
" in the target XML. In this operation, calculations are carried out (free seats
" and the occupancy rate based on the values of maximum and occupied seats).
"Note:
"- The element names in the demo XML data are capitalized on purpose because the
" XML data is used in another example that uses the asXML format. In deserializations
" of XML data to ABAP data, the elements that are deserialized must be capitalized
" so that they can be identified.
"Tranformations are performed using CALL TRANSFORMATION statements.
"Creating demo XML data to be used in the example
TRY.
DATA(xml_flights) = cl_abap_conv_codepage=>create_out( codepage = `UTF-8` )->convert(
`<FLIGHTS>` &&
` <FLIGHT>` &&
` <CARRIER>AA</CARRIER>` &&
` <CONNECTIONID>17</CONNECTIONID>` &&
` <MAXSEATS>385</MAXSEATS>` &&
` <OCCSEATS>369</OCCSEATS>` &&
` </FLIGHT>` &&
` <FLIGHT>` &&
` <CARRIER>LH</CARRIER>` &&
` <CONNECTIONID>400</CONNECTIONID>` &&
` <MAXSEATS>330</MAXSEATS>` &&
` <OCCSEATS>319</OCCSEATS>` &&
` </FLIGHT>` &&
`</FLIGHTS>` ).
CATCH cx_sy_conversion_codepage.
ENDTRY.
DATA xml_a TYPE xstring.
CALL TRANSFORMATION zdemo_abap_xslt_fl
SOURCE XML xml_flights
RESULT XML xml_a.
DATA(conv_xml_a) = format( cl_abap_conv_codepage=>create_in( )->convert( xml_a ) ).
out->write( conv_xml_a ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `11) Transforming ABAP to XML Using XSLT` ) ).
"In the example, data entries are retrieved from a database table. Appropriate names for the
"table columns are used with the AS addition so that the transformation can be carried
"out based on the selected data.
"Note: The resulting XML has the asXML format.
SELECT carrid AS carrier,
connid AS connectionid,
seatsmax AS maxSeats,
seatsocc AS occSeats
FROM zdemo_abap_fli
WHERE carrid = 'AZ'
INTO TABLE @DATA(fli_itab)
UP TO 2 ROWS.
DATA xml_b TYPE xstring.
CALL TRANSFORMATION zdemo_abap_xslt_fl
SOURCE flights = fli_itab
RESULT XML xml_b.
DATA(conv_xml_b) = format( cl_abap_conv_codepage=>create_in( )->convert( xml_b ) ).
out->write( conv_xml_b ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `12) ABAP <-> XML using Simple Transformations (1)` ) ).
"The following simple transformation examples transform ABAP to XML and back. The
"Simple Transformation is implemented in a way to transform to the HTML format.
"This example transforms string tables to html.
DATA(string_table_a) = VALUE string_table( ( `abc` ) ( `def` ) ( `ghi` ) ).
DATA xml_c TYPE xstring.
"ABAP -> XML
CALL TRANSFORMATION zdemo_abap_st_strhtml
SOURCE string_table = string_table_a
RESULT XML xml_c.
DATA(conv_xml_c) = format( cl_abap_conv_codepage=>create_in( )->convert( xml_c ) ).
out->write( `ABAP -> XML` ).
out->write( conv_xml_c ).
out->write( |\n| ).
"XML -> ABAP
DATA string_table_b TYPE string_table.
CALL TRANSFORMATION zdemo_abap_st_strhtml
SOURCE XML xml_c
RESULT string_table = string_table_b.
out->write( `XML -> ABAP` ).
out->write( string_table_b ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `13) ABAP <-> XML using Simple Transformations (2)` ) ).
"In this example, an internal table is transformed to XML using Simple Transformation.
"HTML tags are inserted into the XML data as literals.
SELECT carrid, carrname, currcode, url
FROM zdemo_abap_carr
INTO TABLE @DATA(carr_tab_a)
UP TO 2 ROWS.
"ABAP -> XML
DATA str_a TYPE string.
"The following CALL TRANSFORMATION statement includes the OPTIONS
"addition. In this example, the XML header should not be added.
"So, you can take the resulting html and test it in an HTML viewer.
CALL TRANSFORMATION zdemo_abap_st_carrhtml
SOURCE carrier_info = carr_tab_a
RESULT XML str_a
OPTIONS xml_header = 'NO'.
out->write( `ABAP -> XML` ).
out->write( format( str_a ) ).
out->write( |\n| ).
"XML -> ABAP
DATA carr_tab_b LIKE carr_tab_a.
CALL TRANSFORMATION zdemo_abap_st_carrhtml
SOURCE XML str_a
RESULT carrier_info = carr_tab_b.
out->write( `XML -> ABAP` ).
out->write( carr_tab_b ).
***********************************************************************
out->write( zcl_demo_abap_aux=>heading( `ABAP <-> XML using XSLT (Using the Predefined Identity Transformation ID)` ) ).
"The following examples demonstrate serializations (ABAP to XML) and deserializations (XML to ABAP)
"using the predefined identity transformation ID.
"Note: In doing so, ABAP data is transformed to their asXML representations that can be used as an
" intermediate format and which define a mapping between ABAP data and XML.
out->write( |14) Elementary type\n\n| ).
"The example uses type string as an elementary type.
"ABAP -> XML
DATA xml_d TYPE xstring.
DATA(str_b) = `This is some string.`.
CALL TRANSFORMATION id SOURCE txt = str_b
RESULT XML xml_d.
DATA(conv_xml_d) = cl_abap_conv_codepage=>create_in( )->convert( xml_d ).
out->write( `ABAP -> XML` ).
out->write( format( conv_xml_d ) ).
out->write( |\n| ).
"XML -> ABAP
DATA str_c TYPE string.
CALL TRANSFORMATION id SOURCE XML xml_d
RESULT txt = str_c.
out->write( `XML -> ABAP` ).
out->write( str_c ).
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `15) Structures` ) ).
SELECT SINGLE carrid, carrname, currcode, url
FROM zdemo_abap_carr
WHERE carrid = 'LH'
INTO @DATA(carr_struc_a).
"ABAP -> XML
DATA xml_e TYPE xstring.
CALL TRANSFORMATION id SOURCE structure = carr_struc_a
RESULT XML xml_e.
DATA(conv_xml_e) = cl_abap_conv_codepage=>create_in( )->convert( xml_e ).
out->write( `ABAP -> XML` ).
out->write( format( conv_xml_e ) ).
out->write( |\n| ).
"XML -> ABAP
DATA carr_struc_b LIKE carr_struc_a.
CALL TRANSFORMATION id SOURCE XML xml_e
RESULT structure = carr_struc_b.
out->write( `XML -> ABAP` ).
out->write( carr_struc_b ).
out->write( |\n| ).
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `16) Internal tables` ) ).
SELECT carrid, connid, fldate, price, currency
FROM zdemo_abap_fli
WHERE carrid = 'JL'
INTO TABLE @DATA(fli_tab_a)
UP TO 2 ROWS.
"ABAP -> XML
DATA xml_f TYPE xstring.
CALL TRANSFORMATION id SOURCE itab = fli_tab_a
RESULT XML xml_f.
DATA(conv_xml_f) = cl_abap_conv_codepage=>create_in( )->convert( xml_f ).
out->write( `ABAP -> XML` ).
out->write( format( conv_xml_f ) ).
out->write( |\n| ).
"XML -> ABAP
DATA fli_tab_b LIKE fli_tab_a.
CALL TRANSFORMATION id SOURCE XML xml_f
RESULT itab = fli_tab_b.
out->write( `XML -> ABAP` ).
out->write( fli_tab_b ).
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `17) Data References` ) ).
DATA(dref_a) = NEW i( 123 ).
"ABAP -> XML
DATA xml_g TYPE xstring.
CALL TRANSFORMATION id SOURCE dref = dref_a
RESULT XML xml_g.
DATA(conv_xml_g) = cl_abap_conv_codepage=>create_in( )->convert( xml_g ).
out->write( `ABAP -> XML` ).
out->write( format( conv_xml_g ) ).
out->write( |\n| ).
"XML -> ABAP
DATA dref_b LIKE dref_a.
CALL TRANSFORMATION id SOURCE XML xml_g
RESULT dref = dref_b.
out->write( `XML -> ABAP` ).
out->write( dref_b->* ).
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `18) Object References` ) ).
"The following example demonstrates the serialization and deserialization of
"instances of classes (objects). For example, to serialize instance attributes,
"classes must implement the if_serializable_object interface. By default, all instance
"attributes of an object are serialized, regardless of their visibility section.
"However, you can change this behavior using the serialize_helper and deserialize_helper
"instance methods. As a result of the transformation, you get an asXML representation of
"the object.
"The example is implemented as follows:
"- The class implements the if_serializable_object interface.
"- There are 4 instance attributes of type string.
"- There are two instance methods:
" - One method concatenates two of the strings and assigns the resulting string to
" another string.
" - Another method concatenates two strings and converts the string to lowercase.
" The result is assigned to another string.
"- Serialization preserves instance attribute values in the asXML representation of the
" object.
"- During deserialization, the instance attribute values are transformed back and can
" be accessed.
"- The example includes the implementation of the serialize_helper and deserialize_helper
" instance methods. Without implementation, all instance attributes would be
" serialized/deserialized. The sample implementation limits serialization/deserialization.
" The fourth instance attribute, which is converted to a lowercase string when calling the
" method, is not part of the serialization/deserialization. See the implementation of the
" serialize_helper and deserialize_helper instance methods. They explicitly specify what
" to serialize and deserialize.
"- Note: For each output parameter of the serialize_helper method, you must specify an
" identically-named input parameter of the deserialize_helper method. The parameters must
" have the same type.
DATA(oref_a) = NEW zcl_demo_abap_xml_json( ).
oref_a->attr_string_a = `AB`.
oref_a->attr_string_b = `AP`.
oref_a->concatenate_string( ).
oref_a->lowercase_string( ).
out->write( `Value of instance attribute attr_lowercase_str for the created instance (before serialization/deserialization):` ).
out->write( oref_a->attr_lowercase_str ).
out->write( |\n| ).
"ABAP -> XML
DATA xml_oref_a TYPE xstring.
CALL TRANSFORMATION id SOURCE oref = oref_a
RESULT XML xml_oref_a.
DATA(conv_xml_oref_a) = cl_abap_conv_codepage=>create_in( )->convert( xml_oref_a ).
out->write( `ABAP -> XML` ).
out->write( format( conv_xml_oref_a ) ).
out->write( |\n| ).
"XML -> ABAP
DATA oref_b LIKE oref_a.
CALL TRANSFORMATION id SOURCE XML xml_oref_a
RESULT oref = oref_b.
out->write( `XML -> ABAP` ).
out->write( oref_b->attr_string_a ).
out->write( oref_b->attr_string_b ).
out->write( oref_b->attr_concat_string ).
out->write( |\n| ).
IF oref_b->attr_lowercase_str IS INITIAL.
out->write( `The instance attribute attr_lowercase_str is initial. The serialization/deserialization is restricted.` ).
ENDIF.
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `19) CALL TRANSFORMATION Syntax: Specifying Transformations` ) ).
"As already covered in the examples above, transformations are specified after
"CALL TRANSFORMATION. They are either ...
"... XSLT programs
CALL TRANSFORMATION zdemo_abap_st_carrhtml SOURCE carrier_info = carr_tab_a
RESULT XML str_a.
"... predefined identity transformations
CALL TRANSFORMATION id SOURCE dref = dref_a
RESULT XML xml_g.
"... dynamically specified transformation (valid for both XSLT and ST). In the examples above,
"the transformation is specified statically. Dynamic specifications are possible. A
"character-like data object in uppercase letters is expected in parentheses (either a named
"or unnamed data objects).
CALL TRANSFORMATION ('ID') SOURCE dref = dref_a
RESULT XML xml_g.
"If a dynamically specified transformation is not found, an exception of the class
"CX_INVALID_TRANSFORMATION is raied. The example uses a named data object.
DATA(notr) = 'NON_EXISTENT_TRANSFORMATION'.
TRY.
CALL TRANSFORMATION (notr) SOURCE dref = dref_a
RESULT XML xml_g.
CATCH cx_invalid_transformation INTO DATA(error_non).
out->write( error_non->get_text( ) ).
ENDTRY.
"... Simple Transformation
CALL TRANSFORMATION zdemo_abap_st_carrhtml SOURCE XML str_a
RESULT carrier_info = carr_tab_b.
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `20) CALL TRANSFORMATION Syntax: Sources of Transformations` ) ).
"The following examples use the predefined identity transformation ID.
"The result is asXML data and stored in a variable of type xstring.
"Multiple options and variants are possible. The examples cover a selection.
out->write( `********** Source options for transforming XML data **********` ).
out->write( |\n| ).
"Source: XML data in a data object of type string. It is implicitly transformed to
"XML in this case.
"Note: It must have character-like XML data in XML 1.0 format.
DATA(str_d) = `<TXT>Hello world</TXT>`.
DATA xml_h TYPE xstring.
CALL TRANSFORMATION id SOURCE XML str_d
RESULT XML xml_h.
DATA(conv_xml_h) = cl_abap_conv_codepage=>create_in( )->convert( xml_h ).
out->write( `Source: XML data in data object of type string` ).
out->write( format( conv_xml_h ) ).
out->write( |\n| ).
"Source: XML data in a data object of type xstring
DATA(xml_i) = cl_abap_conv_codepage=>create_out( )->convert( `<TEXT name="TXT">Hi ABAP</TEXT>` ).
DATA xml_j TYPE xstring.
CALL TRANSFORMATION id SOURCE XML xml_i
RESULT XML xml_j.
DATA(conv_xml_j) = cl_abap_conv_codepage=>create_in( )->convert( xml_j ).
out->write( `Source: XML data in a data object of type xstring` ).
out->write( format( conv_xml_j ) ).
out->write( |\n| ).
"Source: Standard table with character-like data type
DATA(stdtab_clike) = VALUE c50_tab_type( ( 'Hi' ) ( 'ABAP' ) ).
DATA xml_k TYPE xstring.
CALL TRANSFORMATION id SOURCE tab = stdtab_clike
RESULT XML xml_k.
DATA(conv_xml_k) = cl_abap_conv_codepage=>create_in( )->convert( xml_k ).
out->write( `Source: Standard table with character-like data type` ).
out->write( format( conv_xml_k ) ).
out->write( |\n| ).
"Source: Standard table with byte-like data type
DATA(stdtab_bytelike) = VALUE x30_tab_type( ( cl_abap_conv_codepage=>create_out( )->convert( `Hello` ) )
( cl_abap_conv_codepage=>create_out( )->convert( `ABAP` ) ) ).
DATA xml_l TYPE xstring.
CALL TRANSFORMATION id SOURCE xtab = stdtab_bytelike
RESULT XML xml_l.
DATA(conv_xml_l) = cl_abap_conv_codepage=>create_in( )->convert( xml_l ).
out->write( `Source: Standard table with byte-like data type` ).
out->write( format( conv_xml_l ) ).
out->write( |\n| ).
"Furthermore, some references to iXML and sXML libraries are possible.
"The following example covers sXML (an interface reference variable of type if_sxml_reader).
DATA(sxml_reader) = cl_sxml_string_reader=>create( xml_h ).
DATA xml_m TYPE xstring.
CALL TRANSFORMATION id SOURCE XML sxml_reader
RESULT XML xml_m.
DATA(conv_xml_m) = cl_abap_conv_codepage=>create_in( )->convert( xml_m ).
out->write( `Source: Interface reference variable with TYPE REF TO if_sxml_reader` ).
out->write( format( conv_xml_m ) ).
out->write( |\n| ).
out->write( `********** Source options for transforming ABAP data **********` ).
out->write( |\n| ).
"Using ... SOURCE ... without specifying XML
"One or multiple ABAP data objects can be specified.
"Source: Data object of type string
"elem stands for the name of an XML element.
DATA(str_e) = `abcdef`.
DATA xml_n TYPE xstring.
CALL TRANSFORMATION id SOURCE elem = str_e
RESULT XML xml_n.
DATA(conv_xml_n) = cl_abap_conv_codepage=>create_in( )->convert( xml_n ).
out->write( `Source: Character string in data object of type string` ).
out->write( format( conv_xml_n ) ).
out->write( |\n| ).
"Source: Data object of type string
DATA(str_f) = `some string`.
DATA xml_o TYPE xstring.
CALL TRANSFORMATION id SOURCE txt = str_f
RESULT XML xml_o.
DATA(conv_xml_o) = cl_abap_conv_codepage=>create_in( )->convert( xml_o ).
out->write( `Source: Character string of type string` ).
out->write( format( conv_xml_o ) ).
out->write( |\n| ).
"Source: Multiple data objects
DATA a_i TYPE i VALUE 123.
DATA b_str TYPE string VALUE `Hallo`.
DATA c_p TYPE p LENGTH 5 DECIMALS 2 VALUE `4.56`.
DATA xml_p TYPE xstring.
CALL TRANSFORMATION id SOURCE x = a_i
y = b_str
z = c_p
RESULT XML xml_p.
DATA(conv_xml_p) = cl_abap_conv_codepage=>create_in( )->convert( xml_p ).
out->write( `Source: Multiple ABAP data objects in a static parameter list` ).
out->write( format( conv_xml_p ) ).
out->write( |\n| ).
"Source: Dynamic specification of ABAP data objects in an internal table of
"type abap_trans_srcbind_tab
DATA(srctab) = VALUE abap_trans_srcbind_tab(
( name = 'X' value = REF #( a_i ) )
( name = 'Y' value = REF #( b_str ) )
( name = 'Z' value = REF #( c_p ) ) ).
DATA xml_q TYPE xstring.
CALL TRANSFORMATION id SOURCE (srctab)
RESULT XML xml_q.
DATA(conv_xml_q) = cl_abap_conv_codepage=>create_in( )->convert( xml_q ).
out->write( `Source: Multiple ABAP data objects in an internal table` ).
out->write( format( conv_xml_q ) ).
*************************************************************************
out->write( zcl_demo_abap_aux=>heading( `21) CALL TRANSFORMATION Syntax: Results of Transformations` ) ).
"As in the examples above, the predefined identity transformation is used here.
"Creating demo XML data to be used in the example as the source.
DATA(demo_xml) = cl_abap_conv_codepage=>create_out( )->convert( `<TEXT name="TXT">Hi ABAP</TEXT>` ).
out->write( `********** Result options for transforming to XML data ********** ` ).
out->write( |\n| ).
"Result: Data object of type string
"The example uses the OPTIONS addition. The XML header should not be added.
DATA str_g TYPE string.
CALL TRANSFORMATION id SOURCE XML demo_xml
RESULT XML str_g
OPTIONS xml_header = 'NO'.
out->write( `Result: Data object of type string` ).
out->write( str_g ).
out->write( |\n| ).
"Data object of type xstring
DATA xml_r TYPE xstring.
CALL TRANSFORMATION id SOURCE XML demo_xml
RESULT XML xml_r.
DATA(conv_xml_r) = cl_abap_conv_codepage=>create_in( )->convert( xml_r ).
out->write( `Result: Data object of type xstring` ).
out->write( format( conv_xml_r ) ).
out->write( |\n| ).
"Data object declared inline (e.g. DATA(a) or FINAL(b)), which has then the type xstring
CALL TRANSFORMATION id SOURCE XML demo_xml
RESULT XML DATA(xml_s).
DATA(conv_xml_s) = cl_abap_conv_codepage=>create_in( )->convert( xml_s ).
out->write( `Result: Data object declared inline (type xstring)` ).
out->write( format( conv_xml_s ) ).
out->write( |\n| ).
"Standard table with character-like line type
DATA stdtab_clike_b TYPE c50_tab_type.
CALL TRANSFORMATION id SOURCE XML demo_xml
RESULT XML stdtab_clike_b
OPTIONS xml_header = 'NO'.
out->write( `Result: Standard table with character-like line type` ).
out->write( stdtab_clike_b ).
out->write( |\n| ).
"Standard table with byte-like line type
DATA stdtab_bytelike_b TYPE x30_tab_type.
CALL TRANSFORMATION id SOURCE XML demo_xml
RESULT XML stdtab_bytelike_b.
out->write( `Result: Standard table with byte-like line type` ).
out->write( stdtab_bytelike_b ).
out->write( |\n| ).
"Furthermore, some references to iXML and sXML libraries are possible.
"The following example covers sXML (an object reference variable of type ref to cl_sxml_string_writer)
"Other types are possible, for example JSON writers.
DATA(writer4tr) = cl_sxml_string_writer=>create( type = if_sxml=>co_xt_xml10 ).
CALL TRANSFORMATION id SOURCE XML demo_xml
RESULT XML writer4tr.
DATA(xml_t) = writer4tr->get_output( ).
DATA(conv_xml_t) = cl_abap_conv_codepage=>create_in( )->convert( xml_t ).
out->write( `Result: Object reference variable with type ref to cl_sxml_string_writer` ).
out->write( format( conv_xml_t ) ).
out->write( |\n| ).
out->write( `********** Result options for transforming to ABAP data **********` ).
out->write( |\n| ).
"Similar to above, multiple ABAP data objects can be specified as a static parameter list.
"Here, the example from above is used. The tranformation is performed the other way round.
DATA d_i LIKE a_i.
DATA e_str LIKE b_str.
DATA f_p LIKE c_p.
CALL TRANSFORMATION id SOURCE XML xml_p
RESULT x = d_i
y = e_str
z = f_p.
out->write( `Result: Multiple ABAP data objects in a static parameter list` ).
out->write( d_i ).
out->write( e_str ).
out->write( f_p ).
out->write( |\n| ).
"Specifying an internal table of type abap_trans_resbind_tab
DATA g_i LIKE a_i.
DATA h_str LIKE b_str.
DATA i_p LIKE c_p.
"Note: Only bound parts are deserialized, i.e. the result table must be
"filled accordingly.
DATA(restab) = VALUE abap_trans_resbind_tab(
( name = 'X' value = REF #( d_i ) )
( name = 'Y' value = REF #( e_str ) )
( name = 'Z' value = REF #( f_p ) ) ).
CALL TRANSFORMATION id SOURCE XML xml_q
RESULT (restab).
out->write( `Result: Multiple ABAP data objects in an internal table` ).
out->write( restab ).
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `22) Dealing with JSON Data` ) ).
"Note: When the identity transformation ID is used, the format is asJSON.
"Elementary type
DATA str_h TYPE string VALUE `Hello`.
"ABAP -> JSON
"Creating a JSON writer
DATA(json_wr_a) = cl_sxml_string_writer=>create( type = if_sxml=>co_xt_json ).
CALL TRANSFORMATION id SOURCE hi = str_h
RESULT XML json_wr_a.
DATA(json_a) = cl_abap_conv_codepage=>create_in( )->convert( json_wr_a->get_output( ) ).
out->write( `ABAP -> JSON: Elementary type` ).
out->write( json_a ).
out->write( |\n| ).
"JSON -> ABAP
DATA str_i TYPE string.
"Note: CALL TRANSFORMATION handles JSON sources implicitly.
CALL TRANSFORMATION id SOURCE XML json_a
RESULT hi = str_i.
out->write( `JSON -> ABAP: Elementary type` ).
out->write( str_i ).
out->write( |\n| ).
"Structure
SELECT SINGLE carrid, carrname, currcode, url
FROM zdemo_abap_carr
WHERE carrid = 'AZ'
INTO @DATA(carr_struc_c).
"ABAP -> JSON
DATA(json_wr_b) = cl_sxml_string_writer=>create( type = if_sxml=>co_xt_json ).
CALL TRANSFORMATION id SOURCE structure = carr_struc_c
RESULT XML json_wr_b.
DATA(json_b) = cl_abap_conv_codepage=>create_in( )->convert( json_wr_b->get_output( ) ).
out->write( `ABAP -> JSON: Structure` ).
out->write( json_b ).
out->write( |\n| ).
"JSON -> ABAP
DATA carr_struc_d LIKE carr_struc_c.
CALL TRANSFORMATION id SOURCE XML json_b
RESULT structure = carr_struc_d.
out->write( `JSON -> ABAP: Structure` ).
out->write( carr_struc_d ).
out->write( |\n| ).
"Internal table
SELECT carrid, carrname, currcode, url
FROM zdemo_abap_carr
INTO TABLE @DATA(carr_tab_c)
UP TO 2 ROWS.
"ABAP -> JSON
"This examples uses a cast to get access to further methods.
DATA(json_wr_c) = cl_sxml_string_writer=>create( type = if_sxml=>co_xt_json ).
DATA(json_wr_cast) = CAST if_sxml_writer( json_wr_c ).
"With the following method calls, the result is formatted.
json_wr_cast->set_option( option = if_sxml_writer=>co_opt_linebreaks ).
json_wr_cast->set_option( option = if_sxml_writer=>co_opt_indent ).
CALL TRANSFORMATION id SOURCE itab = carr_tab_c
RESULT XML json_wr_c.
DATA(json_c) = cl_abap_conv_codepage=>create_in( )->convert( json_wr_c->get_output( ) ).
out->write( `ABAP -> JSON: Internal table` ).
out->write( json_c ).
out->write( |\n| ).
"JSON -> ABAP
DATA carr_tab_d LIKE carr_tab_c.
CALL TRANSFORMATION id SOURCE XML json_c
RESULT itab = carr_tab_d.
out->write( `JSON -> ABAP: Internal table` ).
out->write( carr_tab_d ).
out->write( |\n| ).
"JSON -> XML
DATA(str_j) =
`{` &&
`"flights": [` &&
` {` &&
` "carrier": "LH",` &&
` "connectionid": "400",` &&
` "from": "Frankfurt",` &&
` "to": "Berlin"` &&
` },` &&
` {` &&
` "carrier": "DL",` &&
` "connectionid": "400",` &&
` "from": "San Francisco",` &&
` "to": "New York"` &&
` }` &&
`]` &&
`}`.
DATA(json_d) = cl_abap_conv_codepage=>create_out( )->convert( str_j ).
DATA(json_wr_d) = cl_sxml_string_reader=>create( json_d ).
DATA json2xml_ct TYPE xstring.
"JSON -> XML using CALL TRANSFORMATION
CALL TRANSFORMATION id SOURCE XML json_wr_d
RESULT XML json2xml_ct.
DATA(conv_json2xml_ct) = cl_abap_conv_codepage=>create_in( )->convert( json2xml_ct ).
out->write( `JSON -> XML using CALL TRANSFORMATION` ).
out->write( format( conv_json2xml_ct ) ).
out->write( |\n| ).
"JSON -> XML using sXML
DATA(reader_a) = cl_sxml_string_reader=>create( cl_abap_conv_codepage=>create_out(
)->convert( str_j ) ).
"XML writer (note the type specification in contrast to the previous examples)
DATA(xml_wr) = cl_sxml_string_writer=>create( type = if_sxml=>co_xt_xml10 ).
TRY.
reader_a->next_node( ).
"The reader parses the data in one go by calling the SKIP_NODE method.
"The data is passed to an XML writer.
reader_a->skip_node( xml_wr ).
CATCH cx_sxml_parse_error INTO DATA(err_pa).
out->write( err_pa->get_text( ) ).
ENDTRY.
DATA(json2xml_sxml) = cl_abap_conv_codepage=>create_in( )->convert( xml_wr->get_output( ) ).
out->write( `JSON -> XML using sXML` ).
out->write( format( json2xml_sxml ) ).
out->write( |\n| ).
"XML -> JSON using CALL TRANSFORMATION
DATA(json_wr_f) = cl_sxml_string_writer=>create( type = if_sxml=>co_xt_json ).
CALL TRANSFORMATION id SOURCE XML json2xml_sxml
RESULT XML json_wr_f.
DATA(xml2json_ct) = cl_abap_conv_codepage=>create_in( )->convert( json_wr_f->get_output( ) ).
out->write( `XML -> JSON using CALL TRANSFORMATION` ).
out->write( xml2json_ct ).
out->write( |\n| ).
"XML -> JSON using sXML
DATA(reader_b) = cl_sxml_string_reader=>create( cl_abap_conv_codepage=>create_out( )->convert( xml2json_ct ) ).
DATA(json_wr) = cl_sxml_string_writer=>create( type = if_sxml=>co_xt_json ).
TRY.
reader_b->next_node( ).
reader_b->skip_node( json_wr ).
CATCH cx_sxml_parse_error INTO DATA(err_xj).
out->write( err_xj->get_text( ) ).
ENDTRY.
DATA(xml2json_sxml) = cl_abap_conv_codepage=>create_in( )->convert( json_wr->get_output( ) ).
out->write( `XML -> JSON using sXML` ).
out->write( xml2json_sxml ).
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `23) XCO Classes for JSON` ) ).
"Note: Unlike above, the following snippets do not work with asJSON as intermediate
"format.
DATA: BEGIN OF carrier_struc,
carrier_id TYPE c length 3,
connection_id TYPE n length 4,
city_from TYPE c length 20,
city_to TYPE c length 20,
END OF carrier_struc.
DATA carriers_tab like TABLE OF carrier_struc WITH EMPTY KEY.
carrier_struc = VALUE #( carrier_id = 'AA' connection_id = '17' city_from = 'New York' city_to = 'San Francisco' ).
carriers_tab = VALUE #( ( carrier_id = 'AZ' connection_id = '788' city_from = 'Rome' city_to = 'Tokyo' )
( carrier_id = 'JL' connection_id = '408' city_from = 'Frankfurt' city_to = 'Tokyo' )
( carrier_id = 'LH' connection_id = '2402' city_from = 'Frankfurt' city_to = 'Berlin' ) ).
"ABAP (structure) -> JSON using XCO
DATA(struc2json_xco) = xco_cp_json=>data->from_abap( carrier_struc )->to_string( ).
out->write( `ABAP (structure) -> JSON using XCO` ).
out->write( format( input = struc2json_xco xml = abap_false ) ).
out->write( |\n| ).
"ABAP (internal table) -> JSON using XCO
DATA(itab2json_xco) = xco_cp_json=>data->from_abap( carriers_tab )->to_string( ).
out->write( `ABAP (internal table) -> JSON using XCO` ).
out->write( format( input = itab2json_xco xml = abap_false ) ).
out->write( |\n| ).
"JSON -> ABAP (structure) using XCO
DATA json2struc_xco LIKE carrier_struc.
xco_cp_json=>data->from_string( struc2json_xco )->write_to( REF #( json2struc_xco ) ).
out->write( `JSON -> ABAP (structure) using XCO` ).
out->write( json2struc_xco ).
out->write( |\n| ).
"JSON -> ABAP (internal table) using XCO
DATA json2itab_xco LIKE carriers_tab.
xco_cp_json=>data->from_string( itab2json_xco )->write_to( REF #( json2itab_xco ) ).
out->write( `JSON -> ABAP (internal table) using XCO` ).
out->write( json2itab_xco ).
out->write( |\n| ).
"Creating JSON using XCO
"Check out more methods that offer more options to build the JSON by clicking
"CTRL + Space after '->' in ADT.
DATA(json_builder_xco) = xco_cp_json=>data->builder( ).
json_builder_xco->begin_object(
)->add_member( 'CarrierId' )->add_string( 'DL'
)->add_member( 'ConnectionId' )->add_string( '1984'
)->add_member( 'CityFrom' )->add_string( 'San Francisco'
)->add_member( 'CityTo' )->add_string( 'New York'
)->end_object( ).
"Getting JSON data
DATA(json_created_xco) = json_builder_xco->get_data( )->to_string( ).
out->write( `Creating JSON using XCO` ).
out->write( format( input = json_created_xco xml = abap_false ) ).
out->write( |\n| ).
"Transforming the created JSON to ABAP (structure)
"Note: The JSON was intentionally created without the underscores in the
"name to demonstrate the 'apply' method. The following example demonstrates
"a transformation of camel case and underscore notation. As above, check out
"more options by clicking CTRL + Space after '...transformation->'.
CLEAR json2struc_xco.
xco_cp_json=>data->from_string( json_created_xco )->apply( VALUE #(
( xco_cp_json=>transformation->pascal_case_to_underscore ) ) )->write_to( REF #( json2struc_xco ) ).
out->write( `JSON -> ABAP (structure) using XCO demonstrating the apply method` ).
out->write( json2struc_xco ).
************************************************************************
out->write( zcl_demo_abap_aux=>heading( `24) Excursion: Compressing and Decompressing Binary Data` ) ).
"You may want to process or store binary data. The data can be very large.
"You can compress the data in gzip format and decompress it for further processing using
"the cl_abap_gzip class. Check out appropriate exceptions to be caught. The simple example
"just specifies cx_root. See the class documentation for more information.
"This example uses a data object of type xstring from a previous example.
"Compressing binary data
DATA xstr_comp TYPE xstring.
TRY.
cl_abap_gzip=>compress_binary( EXPORTING raw_in = xml_oref_a
IMPORTING gzip_out = xstr_comp ).
CATCH cx_root INTO DATA(error_comp).
out->write( error_comp->get_text( ) ).
ENDTRY.
"Decompressing binary data
DATA xstr_decomp TYPE xstring.
TRY.
cl_abap_gzip=>decompress_binary( EXPORTING gzip_in = xstr_comp
IMPORTING raw_out = xstr_decomp ).
CATCH cx_root INTO DATA(error_decomp).
out->write( error_decomp->get_text( ) ).
ENDTRY.
"Checking the xstring length of the variables used and comparing the result
DATA(strlen_original_xstring) = xstrlen( xml_oref_a ).
out->write( |Length of original binary data object: { strlen_original_xstring }| ).
DATA(strlen_comp) = xstrlen( xstr_comp ).
out->write( |Length of compressed binary data object: { strlen_comp }| ).
DATA(strlen_decomp) = xstrlen( xstr_decomp ).
out->write( |Length of decompressed binary data object: { strlen_decomp }| ).
IF xml_oref_a = xstr_decomp.
out->write( `The decompressed binary data object has the same value as the original binary data object.` ).
ENDIF.
ENDMETHOD.
METHOD format.
TRY.
DATA(xstr) = cl_abap_conv_codepage=>create_out( )->convert( input ).
DATA(reader) = cl_sxml_string_reader=>create( xstr ).
DATA(writer) = CAST if_sxml_writer( cl_sxml_string_writer=>create(
type = COND #( WHEN xml = abap_true THEN if_sxml=>co_xt_xml10 ELSE if_sxml=>co_xt_json ) ) ).
writer->set_option( option = if_sxml_writer=>co_opt_linebreaks ).
writer->set_option( option = if_sxml_writer=>co_opt_indent ).
reader->next_node( ).
reader->skip_node( writer ).
string = cl_abap_conv_codepage=>create_in( )->convert( CAST cl_sxml_string_writer( writer )->get_output( ) ).
CATCH cx_root.
string = `Issue when formatting.`.
ENDTRY.
ENDMETHOD.
METHOD class_constructor.
"Filling demo database tables.
zcl_demo_abap_aux=>fill_dbtabs( ).
ENDMETHOD.
METHOD concatenate_string.
attr_concat_string = attr_string_a && attr_string_b.
ENDMETHOD.
METHOD deserialize_helper.
me->attr_string_a = attr_string_a.
me->attr_string_b = attr_string_b.
me->attr_concat_string = attr_concat_string.
ENDMETHOD.
METHOD serialize_helper.
attr_string_a = me->attr_string_a.
attr_string_b = me->attr_string_b.
attr_concat_string = me->attr_concat_string.
ENDMETHOD.
METHOD lowercase_string.
attr_lowercase_str = to_lower( attr_string_a && attr_string_b ).
ENDMETHOD.
ENDCLASS.
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