xsdcxx (1) - Linux Manuals
xsdcxx: W3C XML Schema to C++ Compiler
NAME
xsdcxx - W3C XML Schema to C++ CompilerSYNOPSIS
xsdcxx command [ options ] file [ file ...] xsdcxx help [ command ] xsdcxx versionDESCRIPTION
xsdcxx generates vocabulary-specific, statically-typed C++ mapping from W3C XML Schema definitions. Particular mapping to produce is selected by a command. Each mapping has a number of mapping-specific options that should appear, if any, after the command. Input files should be W3C XML Schema definitions. The exact set of the generated files depends on the selected mapping and options.COMMANDS
- cxx-tree
-
Generate the C++/Tree mapping. For each input file in the form
name.xsd
the following C++ files are generated:
name.hxx
(header file),
name.ixx
(inline file, generated only if the
--generate-inline
option is specified),
name.cxx
(source file), and
name-fwd.hxx
(forward declaration file, generated only if the
--generate-forward
option is specified).
- cxx-parser
-
Generate the C++/Parser mapping. For each input file in the form
name.xsd
the following C++ files are generated:
name-pskel.hxx
(parser skeleton header file),
name-pskel.ixx
(parser skeleton inline file, generated only if the
--generate-inline
option is specified), and
name-pskel.cxx
(parser skeleton source file). If the
--generate-noop-impl
or
--generate-print-impl
option is specified, the following additional sample implementation files
are generated:
name-pimpl.hxx
(parser implementation header file) and
name-pimpl.cxx
(parser implementation source file). If the
--generate-test-driver
option is specified, the additional
name-driver.cxx
test driver file is generated.
- help
- Print usage information and exit. Use
-
- xsdcxx help command
for command-specific help.
- version
- Print version and exit.
OPTIONS
Command-specific options, if any, should appear after the corresponding command.common options
- --std version
-
Specify the C++ standard that the generated code should conform to. Valid
values are c++98 (default) and c++11.
The C++ standard affects various aspects of the generated code that are discussed in more detail in various mapping-specific documentation. Overall, when C++11 is selected, the generated code relies on the move semantics and uses std::unique_ptr instead of deprecated std::auto_ptr.
When the C++11 mode is selected, you normally don't need to perform any extra steps other than enable C++11 in your C++ compiler, if required. The XSDCXX compiler will automatically add the necessary macro defines to the generated header files that will switch the header-only XSDCXX runtime library (libxsd) to the C++11 mode. However, if you include any of the XSDCXX runtime headers directly in your application (normally you just include the generated headers), then you will need to define the XSD_CXX11 macro for your entire project.
- --char-type type
-
Generate code using the provided character type instead of the default
char. Valid values are char and wchar_t.
- --char-encoding enc
-
Specify the character encoding that should be used in the generated code.
Valid values for the char character type are utf8 (default),
iso8859-1, lcp (Xerces-C++ local code page), and custom.
If you pass custom as the value then you will need to include the
transcoder implementation header for your encoding at the beginning of the
generated header files (see the --hxx-prologue option).
For the wchar_t character type the only valid value is auto and the encoding is automatically selected between UTF-16 and UTF-32/UCS-4, depending on the wchar_t type size.
- --output-dir dir
-
Write generated files to dir instead of the current directory.
- --generate-inline
-
Generate simple functions inline. This option triggers creation of the
inline file.
- --generate-xml-schema
-
Generate a C++ header file as if the schema being compiled defines the XML
Schema namespace. For the C++/Tree mapping, the resulting file will contain
definitions for all XML Schema built-in types. For the C++/Parser mapping,
the resulting file will contain definitions for all the parser skeletons and
implementations corresponding to the XML Schema built-in types.
The schema file provided to the compiler need not exist and is only used to derive the name of the resulting header file. Use the --extern-xml-schema option to include this file in the generated files for other schemas.
- --extern-xml-schema file
-
Include a header file derived from file instead of generating the XML
Schema namespace mapping inline. The provided file need not exist and is
only used to derive the name of the included header file. Use the
--generate-xml-schema option to generate this header file.
- --namespace-map xns=cns
-
Map XML Schema namespace xns to C++ namespace cns. Repeat this
option to specify mapping for more than one XML Schema namespace. For
example, the following option:
--namespace-map http://example.com/foo/bar=foo::bar
Will map the http://example.com/foo/bar XML Schema namespace to the foo::bar C++ namespace.
- --namespace-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema namespace names to C++ namespace names. regex is a Perl-like
regular expression in the form
/pattern/replacement/. Any character can be
used as a delimiter instead of /. Escaping of the delimiter character
in pattern or replacement is not supported.
All the regular expressions are pushed into a stack with the last specified expression considered first. The first match that succeeds is used. Regular expressions are applied to a string in the form
filename namespace
For example, if you have file hello.xsd with namespace http://example.com/hello and you run xsd on this file, then the string in question will be:
hello.xsd. http://example.com/hello
For the built-in XML Schema namespace the string is:
XMLSchema.xsd http://www.w3.org/2001/XMLSchema
The following three steps are performed for each regular expression until the match is found:
1. The expression is applied and if the result is empty the next expression is considered.
2. All / are replaced with ::.
3. The result is verified to be a valid C++ scope name (e.g., foo::bar). If this test succeeds, the result is used as a C++ namespace name.
As an example, the following expression maps XML Schema namespaces in the form http://example.com/foo/bar to C++ namespaces in the form foo::bar:
%.* http://example.com/(.+)%$1%
See also the REGEX AND SHELL QUOTING section below.
- --namespace-regex-trace
-
Trace the process of applying regular expressions specified with the
--namespace-regex option. Use this option to find out why your
regular expressions don't do what you expected them to do.
- --reserved-name n[=r]
-
Add name n to the list of names that should not be used as
identifiers. The name can optionally be followed by = and the
replacement name r that should be used instead. All the C++ keywords
are already in this list.
- --include-with-brackets
-
Use angle brackets (<>) instead of quotes ("") in generated #include
directives.
- --include-prefix prefix
-
Add prefix to generated #include directive paths.
For example, if you had the following import element in your schema
<import namespace="..." schemaLocation="base.xsd"/>
and compiled this fragment with --include-prefix schemas/, then the include directive in the generated code would be:
#include "schemas/base.hxx"
- --include-regex regex
-
Add regex to the list of regular expressions used to transform
#include directive paths. regex is a Perl-like regular
expression in the form /pattern/replacement/.
Any character can be used as a delimiter instead of /. Escaping of
the delimiter character in pattern or replacement is not
supported.
All the regular expressions are pushed into a stack with the last specified expression considered first. The first match that succeeds is used.
As an example, the following expression transforms paths in the form schemas/foo/bar to paths in the form generated/foo/bar:
%schemas/(.+)%generated/$1%
See also the REGEX AND SHELL QUOTING section below.
- --include-regex-trace
-
Trace the process of applying regular expressions specified with the
--include-regex option. Use this option to find out why your regular
expressions don't do what you expected them to do.
- --guard-prefix prefix
-
Add prefix to generated header inclusion guards. The prefix is
transformed to upper case and characters that are illegal in a preprocessor
macro name are replaced with underscores. If this option is not specified
then the directory part of the input schema file is used as a prefix.
- --hxx-suffix suffix
-
Use the provided suffix instead of the default .hxx to
construct the name of the header file. Note that this suffix is also used
to construct names of header files corresponding to included/imported
schemas.
- --ixx-suffix suffix
-
Use the provided suffix instead of the default .ixx to
construct the name of the inline file.
- --cxx-suffix suffix
-
Use the provided suffix instead of the default .cxx to
construct the name of the source file.
- --fwd-suffix suffix
-
Use the provided suffix instead of the default -fwd.hxx to
construct the name of the forward declaration file.
- --hxx-regex regex
-
Use the provided expression to construct the name of the header file.
regex is a Perl-like regular expression in the form
/pattern/replacement/. Note that this
expression is also used to construct names of header files corresponding to
included/imported schemas. See also the REGEX AND SHELL QUOTING section
below.
- --ixx-regex regex
-
Use the provided expression to construct the name of the inline file.
regex is a Perl-like regular expression in the form
/pattern/replacement/. See also the REGEX AND
SHELL QUOTING section below.
- --cxx-regex regex
-
Use the provided expression to construct the name of the source file.
regex is a Perl-like regular expression in the form
/pattern/replacement/. See also the REGEX AND
SHELL QUOTING section below.
- --fwd-regex regex
-
Use the provided expression to construct the name of the forward declaration
file. regex is a Perl-like regular expression in the form
/pattern/replacement/. See also the REGEX AND
SHELL QUOTING section below.
- --hxx-prologue text
-
Insert text at the beginning of the header file.
- --ixx-prologue text
-
Insert text at the beginning of the inline file.
- --cxx-prologue text
-
Insert text at the beginning of the source file.
- --fwd-prologue text
-
Insert text at the beginning of the forward declaration file.
- --prologue text
-
Insert text at the beginning of each generated file for which there is
no file-specific prologue.
- --hxx-epilogue text
-
Insert text at the end of the header file.
- --ixx-epilogue text
-
Insert text at the end of the inline file.
- --cxx-epilogue text
-
Insert text at the end of the source file.
- --fwd-epilogue text
-
Insert text at the end of the forward declaration file.
- --epilogue text
-
Insert text at the end of each generated file for which there is no
file-specific epilogue.
- --hxx-prologue-file file
-
Insert the content of the file at the beginning of the header file.
- --ixx-prologue-file file
-
Insert the content of the file at the beginning of the inline file.
- --cxx-prologue-file file
-
Insert the content of the file at the beginning of the source file.
- --fwd-prologue-file file
-
Insert the content of the file at the beginning of the forward
declaration file.
- --prologue-file file
-
Insert the content of the file at the beginning of each generated file
for which there is no file-specific prologue file.
- --hxx-epilogue-file file
-
Insert the content of the file at the end of the header file.
- --ixx-epilogue-file file
-
Insert the content of the file at the end of the inline file.
- --cxx-epilogue-file file
-
Insert the content of the file at the end of the source file.
- --fwd-epilogue-file file
-
Insert the content of the file at the end of the forward declaration
file.
- --epilogue-file file
-
Insert the content of the file at the end of each generated file for
which there is no file-specific epilogue file.
- --export-symbol symbol
-
Insert symbol in places where DLL export/import control statements
(__declspec(dllexport/dllimport)) are necessary.
- --export-xml-schema
-
Export/import types in the XML Schema namespace using the export symbol
provided with the --export-symbol option. The XSD_NO_EXPORT
macro can be used to omit this code during C++ compilation, which may be
useful if you would like to use the same generated code across multiple
platforms.
- --export-maps
-
Export polymorphism support maps from a Win32 DLL into which this generated
code is placed. This is necessary when your type hierarchy is split across
several DLLs since otherwise each DLL will have its own set of maps. In
this situation the generated code for the DLL which contains base types
and/or substitution group heads should be compiled with this option and the
generated code for all other DLLs should be compiled with
--import-maps. This option is only valid together with
--generate-polymorphic. The XSD_NO_EXPORT macro can be used to
omit this code during C++ compilation, which may be useful if you would like
to use the same generated code across multiple platforms.
- --import-maps
-
Import polymorphism support maps to a Win32 DLL or executable into which
this generated code is linked. See the --export-maps option
documentation for details. This options is only valid together with
--generate-polymorphic. The XSD_NO_EXPORT macro can be used to
omit this code during C++ compilation, which may be useful if you would like
to use the same generated code across multiple platforms.
- --generate-dep
-
Generate make dependency information. This option triggers the
creation of the .d file containing the dependencies of the generated
files on the main schema file as well as all the schema files that it
includes/imports, transitively. This dependency file is then normally
included into the main makefile to implement automatic dependency
tracking.
Note also that automatic dependency generation is not supported in the file-per-type mode (--file-per-type). In this case, all the generated files are produced with a single compiler invocation and depend on all the schemas. As a result, it is easier to establish such a dependency manually, perhaps with the help of the --file-list* options.
- --generate-dep-only
-
Generate make dependency information only.
- --dep-phony
-
Generate phony targets for included/imported schema files, causing each to
depend on nothing. Such dummy rules work around make errors caused by
the removal of schema files without also updating the dependency file to
match.
- --dep-target target
-
Change the target of the dependency rule. By default it contains all the
generated C++ files as well as the dependency file itself, without any
directory prefixes. If you require multiple targets, then you can specify
them as a single, space-separated argument or you can repeat this option
multiple times.
- --dep-suffix suffix
-
Use the provided suffix instead of the default .d to construct
the name of the dependency file.
- --dep-regex regex
-
Use the provided expression to construct the name of the dependency file.
regex is a Perl-like regular expression in the form
/pattern/replacement/. See also the REGEX AND
SHELL QUOTING section below.
- --disable-warning warn
-
Disable printing warning with id warn. If all is specified for
the warning id then all warnings are disabled.
- --options-file file
-
Read additional options from file. Each option should appearing on a
separate line optionally followed by space and an option value. Empty lines
and lines starting with # are ignored. Option values can be enclosed
in double (") or single (') quotes to preserve leading and
trailing whitespaces as well as to specify empty values. If the value
itself contains trailing or leading quotes, enclose it with an extra pair of
quotes, for example '"x"'. Non-leading and non-trailing quotes are
interpreted as being part of the option value.
The semantics of providing options in a file is equivalent to providing the same set of options in the same order on the command line at the point where the --options-file option is specified except that the shell escaping and quoting is not required. You can repeat this option to specify more than one options file.
- --show-sloc
-
Show the number of generated physical source lines of code (SLOC).
- --sloc-limit num
-
Check that the number of generated physical source lines of code (SLOC) does
not exceed num.
- --proprietary-license
-
Indicate that the generated code is licensed under a proprietary license
instead of the GPL.
- --custom-literals file
-
Load custom XML string to C++ literal mappings from file. This
mechanism can be useful if you are using a custom character encoding and
some of the strings in your schemas, for example element/attribute names or
enumeration values, contain non-ASCII characters. In this case you will
need to provide a custom mapping to C++ literals for such strings. The
format of this file is specified in the custom-literals.xsd XML
Schema file that can be found in the documentation directory.
- --preserve-anonymous
-
Preserve anonymous types. By default anonymous types are automatically
named with names derived from the enclosing elements/attributes. Because
mappings implemented by this compiler require all types to be named, this
option is only useful if you want to make sure your schemas don't have
anonymous types.
- --show-anonymous
-
Show elements and attributes that are of anonymous types. This option only
makes sense together with the --preserve-anonymous option.
- --anonymous-regex regex
-
Add regex to the list of regular expressions used to derive names for
anonymous types from the enclosing attributes/elements. regex is a
Perl-like regular expression in the form
/pattern/replacement/. Any character can be
used as a delimiter instead of /. Escaping of the delimiter character
in pattern or replacement is not supported.
All the regular expressions are pushed into a stack with the last specified expression considered first. The first match that succeeds is used. Regular expressions are applied to a string in the form
filename namespace xpath
For instance:
hello.xsd http://example.com/hello element
hello.xsd http://example.com/hello type/element
As an example, the following expression makes all the derived names start with capital letters. This could be useful when your naming convention requires type names to start with capital letters:
%.* .* (.+/)*(.+)%\u$2%
See also the REGEX AND SHELL QUOTING section below.
- --anonymous-regex-trace
-
Trace the process of applying regular expressions specified with the
--anonymous-regex option. Use this option to find out why your
regular expressions don't do what you expected them to do.
- --location-map ol=nl
-
Map the original schema location ol that is specified in the XML
Schema include or import elements to new schema location nl. Repeat
this option to map more than one schema location. For example, the
following option maps the http://example.com/foo.xsd URL to the
foo.xsd local file.
--location-map http://example.com/foo.xsd=foo.xsd
- --location-regex regex
-
Add regex to the list of regular expressions used to map schema
locations that are specified in the XML Schema include or import elements.
regex is a Perl-like regular expression in the form
/pattern/replacement/. Any character can be
used as a delimiter instead of /. Escaping of the delimiter character
in pattern or replacement is not supported. All the regular
expressions are pushed into a stack with the last specified expression
considered first. The first match that succeeds is used.
For example, the following expression maps URL locations in the form http://example.com/foo/bar.xsd to local files in the form bar.xsd:
See also the REGEX AND SHELL QUOTING section below.
- --location-regex-trace
-
Trace the process of applying regular expressions specified with the
--location-regex option. Use this option to find out why your regular
expressions don't do what you expected them to do.
- --file-per-type
-
Generate a separate set of C++ files for each type defined in XML Schema.
Note that in this mode you only need to compile the root schema(s) and the
code will be generated for all included and imported schemas. This
compilation mode is primarily useful when some of your schemas cannot be
compiled separately or have cyclic dependencies which involve type
inheritance. Other options related to this mode are:
--type-file-regex, --schema-file-regex, --fat-type-file,
and --file-list.
- --type-file-regex regex
-
Add regex to the list of regular expressions used to translate type
names to file names when the --file-per-type option is specified.
regex is a Perl-like regular expression in the form
/pattern/replacement/. Any character can be
used as a delimiter instead of /. Escaping of the delimiter character
in pattern or replacement is not supported. All the regular
expressions are pushed into a stack with the last specified expression
considered first. The first match that succeeds is used. Regular
expressions are applied to a string in the form
namespace type-name
For example, the following expression maps type foo that is defined in the http://example.com/bar namespace to file name bar-foo:
%http://example.com/(.+) (.+)%$1-$2%
See also the REGEX AND SHELL QUOTING section below.
- --type-file-regex-trace
-
Trace the process of applying regular expressions specified with the
--type-file-regex option. Use this option to find out why your
regular expressions don't do what you expected them to do.
- --schema-file-regex regex
-
Add regex to the list of regular expressions used to translate schema
file names when the --file-per-type option is specified. regex
is a Perl-like regular expression in the form
/pattern/replacement/. Any character can be
used as a delimiter instead of /. Escaping of the delimiter character
in pattern or replacement is not supported. All the regular
expressions are pushed into a stack with the last specified expression
considered first. The first match that succeeds is used. Regular
Expressions are applied to the absolute filesystem path of a schema file and
the result, including the directory part, if any, is used to derive the
#include directive paths as well as the generated C++ file paths.
This option, along with --type-file-regex are primarily useful to
place the generated files into subdirectories or to resolve file name
conflicts.
For example, the following expression maps schema files in the foo/1.0.0/ subdirectory to the files in the foo/ subdirectory. As a result, the #include directive paths for such schemas will be in the foo/schema.hxx form and the generated C++ files will be placed into the foo/ subdirectory:
%.*/foo/1.0.0/(.+)%foo/$1%
See also the REGEX AND SHELL QUOTING section below.
- --schema-file-regex-trace
-
Trace the process of applying regular expressions specified with the
--schema-file-regex option. Use this option to find out why your
regular expressions don't do what you expected them to do.
- --fat-type-file
-
Generate code corresponding to global elements into type files instead of
schema files when the --type-file-regex option is specified. This
option is primarily useful when trying to minimize the amount of object code
that is linked to an executable by packaging compiled generated code into a
static (archive) library.
- --file-list file
-
Write a list of generated C++ files to file. This option is primarily
useful in the file-per-type compilation mode (--file-per-type) to
create a list of generated C++ files, for example, as a makefile fragment.
- --file-list-prologue text
-
Insert text at the beginning of the file list. As a convenience, all
occurrences of the \n character sequence in text are replaced
with new lines. This option can, for example, be used to assign the
generated file list to a makefile variable.
- --file-list-epilogue text
-
Insert text at the end of the file list. As a convenience, all
occurrences of the \n character sequence in text are replaced
with new lines.
- --file-list-delim text
-
Delimit file names written to the file list with text instead of new
lines. As a convenience, all occurrences of the \n character
sequence in text are replaced with new lines.
cxx-tree command options
- --generate-polymorphic
-
Generate polymorphism-aware code. Specify this option if you use
substitution groups or xsi:type. Use the --polymorphic-type or
--polymorphic-type-all option to specify which type hierarchies are
polymorphic.
- --polymorphic-type type
-
Indicate that type is a root of a polymorphic type hierarchy. The
compiler can often automatically determine which types are polymorphic based
on the substitution group declarations. However, you may need to use this
option if you are not using substitution groups or if substitution groups
are defined in another schema. You need to specify this option when
compiling every schema file that references type. The type
argument is an XML Schema type name that can be optionally qualified with a
namespace in the namespace#name form.
- --polymorphic-type-all
-
Indicate that all types should be treated as polymorphic.
- --polymorphic-plate num
-
Specify the polymorphic map plate the generated code should register on.
This functionality is primarily useful to segregate multiple schemas that
define the same polymorphic types.
- --ordered-type type
-
Indicate that element order in type is significant. An example would
be a complex type with unbounded choice as a content model where the element
order in XML has application-specific semantics. For ordered types the
compiler generates a special container data member and a corresponding set
of accessors and modifiers that are used to capture the order of elements
and, for mixed content, of text.
The type argument is an XML Schema type name that can be optionally qualified with a namespace in the namespace#name form. Note also that you will need to specify this option when compiling every schema file that has other ordered types derived from this type.
- --ordered-type-derived
-
Automatically treat types derived from ordered bases as also ordered. This
is primarily useful if you would like to be able to iterate over the
complete content using the content order container.
- --ordered-type-mixed
-
Automatically treat complex types with mixed content as ordered.
- --ordered-type-all
-
Indicate that element order in all types is significant.
- --order-container type
-
Specify a custom class template that should be used as a container for the
content order in ordered types instead of the default std::vector.
See --ordered-type for more information on ordered type. This option
is primarily useful if you need to perform more complex lookups in the
content order container, for example by element id. In this case, a
container like Boost multi-index may be more convenient. Note that if using
a custom container, you will also most likely need to include the relevant
headers using the --hxx-prologue* options.
- --generate-serialization
-
Generate serialization functions. Serialization functions convert the
object model back to XML.
- --generate-ostream
-
Generate ostream insertion operators (operator<<) for generated
types. This allows one to easily print a fragment or the whole object model
for debugging or logging.
- --generate-doxygen
-
Generate documentation comments suitable for extraction by the Doxygen
documentation system. Documentation from annotations is added to the
comments if present in the schema.
- --generate-comparison
-
Generate comparison operators (operator== and operator!=) for
complex types. Comparison is performed member-wise.
- --generate-default-ctor
-
Generate default constructors even for types that have required members.
Required members of an instance constructed using such a constructor are not
initialized and accessing them results in undefined behavior.
- --generate-from-base-ctor
-
Generate constructors that expect an instance of a base type followed by all
required members.
- --suppress-assignment
-
Suppress the generation of copy assignment operators for complex types. If
this option is specified, the copy assignment operators for such types are
declared private and left unimplemented.
- --generate-detach
-
Generate detach functions for required elements and attributes. Detach
functions for optional and sequence cardinalities are provided by the
respective containers. These functions, for example, allow you to move
sub-trees in the object model either within the same tree or between
different trees.
- --generate-wildcard
-
Generate accessors and modifiers as well as parsing and serialization code
for XML Schema wildcards (any and anyAttribute). XML content
matched by wildcards is presented as DOM fragments. Note that you need to
initialize the Xerces-C++ runtime if you are using this option.
- --generate-any-type
-
Extract and store content of the XML Schema anyType type as a DOM
fragment. Note that you need to initialize the Xerces-C++ runtime if you
are using this option.
- --generate-insertion os
-
Generate data representation stream insertion operators for the os
output stream type. Repeat this option to specify more than one stream
type. The ACE CDR stream (ACE_OutputCDR) and RPC XDR are recognized
by the compiler and the necessary #include directives are
automatically generated. For custom stream types use the
--hxx-prologue* options to provide the necessary declarations.
- --generate-extraction is
-
Generate data representation stream extraction constructors for the is
input stream type. Repeat this option to specify more than one stream
type. The ACE CDR stream (ACE_InputCDR) and RPC XDR are recognized by
the compiler and the necessary #include directives are automatically
generated. For custom stream types use the --hxx-prologue* options to
provide the necessary declarations.
- --generate-forward
-
Generate a separate header file with forward declarations for the types
being generated.
- --suppress-parsing
-
Suppress the generation of the parsing functions and constructors. Use this
option to reduce the generated code size when parsing from XML is not
needed.
- --generate-element-type
-
Generate types instead of parsing and serialization functions for root
elements. This is primarily useful to distinguish object models with the
same root type but with different root elements.
- --generate-element-map
-
Generate a root element map that allows uniform parsing and serialization of
multiple root elements. This option is only valid together with
--generate-element-type.
- --generate-intellisense
-
Generate workarounds for IntelliSense bugs in Visual Studio 2005 (8.0).
When this option is used, the resulting code is slightly more verbose.
IntelliSense in Visual Studio 2008 (9.0) and later does not require these
workarounds. Support for IntelliSense in Visual Studio 2003 (7.1) is
improved with this option but is still incomplete.
- --omit-default-attributes
-
Omit attributes with default and fixed values from serialized XML
documents.
- --type-naming style
-
Specify the type naming convention that should be used in the generated
code. Valid styles are knr (default), ucc, and java. See
the NAMING CONVENTION section below for more information.
- --function-naming style
-
Specify the function naming convention that should be used in the generated
code. Valid styles are knr (default), lcc, and java. See
the NAMING CONVENTION section below for more information.
- --type-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema type names to C++ type names. See the NAMING CONVENTION section
below for more information.
- --accessor-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes to C++ accessor function names. See the
NAMING CONVENTION section below for more information.
- --one-accessor-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes with cardinality one to C++ accessor
function names. See the NAMING CONVENTION section below for more
information.
- --opt-accessor-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes with cardinality optional to C++
accessor function names. See the NAMING CONVENTION section below for more
information.
- --seq-accessor-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes with cardinality sequence to C++
accessor function names. See the NAMING CONVENTION section below for more
information.
- --modifier-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes to C++ modifier function names. See the
NAMING CONVENTION section below for more information.
- --one-modifier-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes with cardinality one to C++ modifier
function names. See the NAMING CONVENTION section below for more
information.
- --opt-modifier-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes with cardinality optional to C++
modifier function names. See the NAMING CONVENTION section below for more
information.
- --seq-modifier-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema names of elements/attributes with cardinality sequence to C++
modifier function names. See the NAMING CONVENTION section below for more
information.
- --parser-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema element names to C++ parsing function names. See the NAMING
CONVENTION section below for more information.
- --serializer-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema element names to C++ serialization function names. See the NAMING
CONVENTION section below for more information.
- --const-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema-derived names to C++ constant names. See the NAMING CONVENTION
section below for more information.
- --enumerator-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema enumeration values to C++ enumerator names. See the NAMING
CONVENTION section below for more information.
- --element-type-regex regex
-
Add regex to the list of regular expressions used to translate XML
Schema element names to C++ element type names. See the NAMING CONVENTION
section below for more information.
- --name-regex-trace
-
Trace the process of applying regular expressions specified with the name
transformation options. Use this option to find out why your regular
expressions don't do what you expected them to do.
- --root-element-first
-
Treat only the first global element as a document root. By default all
global elements are considered document roots.
- --root-element-last
-
Treat only the last global element as a document root. By default all
global elements are considered document roots.
- --root-element-all
-
Treat all global elements as document roots. This is the default behavior.
By explicitly specifying this option you can suppress the warning that is
issued if more than one global element is defined.
- --root-element-none
-
Do not treat any global elements as document roots. By default all global
elements are considered document roots.
- --root-element element
-
Treat only element as a document root. Repeat this option to specify
more than one root element.
- --custom-type map
-
Use a custom C++ type instead of the generated class. The map
argument is in the form name[=type[/base]],
where name is a type name as defined in XML Schema and type is a
C++ type name that should be used instead. If type is not present or
empty then the custom type is assumed to have the same name and be defined
in the same namespace as the generated class would have. If base is
specified then the generated class is still generated but with that name.
- --custom-type-regex regex
-
Use custom C++ types instead of the generated classes. The regex
argument is in the form
/name-pat/[type-sub/[base-sub/]],
where name-pat is a regex pattern that will be matched against type
names as defined in XML Schema and type-sub is a C++ type name
substitution that should be used instead. If type-sub is not present
or its substitution results in an empty string then the custom type is
assumed to have the same name and be defined in the same namespace as the
generated class would have. If base-sub is present and its
substitution results in a non-empty string then the generated class is still
generated but with the result of this substitution as its name. The pattern
and substitutions are in the Perl regular expression format. See also the
REGEX AND SHELL QUOTING section below.
- --parts num
-
Split generated source code into num parts. This is useful when
translating large, monolithic schemas and a C++ compiler is not able to
compile the resulting source code at once (usually due to insufficient
memory).
- --parts-suffix suffix
-
Use suffix instead of the default '-' to separate the file name
from the part number.
cxx-parser command options
- --type-map mapfile
-
Read XML Schema to C++ type mapping information from mapfile. Repeat
this option to specify several type maps. Type maps are considered in order
of appearance and the first match is used. By default all user-defined
types are mapped to void. See the TYPE MAP section below for more
information.
- --xml-parser parser
-
Use parser as the underlying XML parser. Valid values are
xerces for Xerces-C++ (default) and expat for Expat.
- --generate-validation
-
Generate validation code. The validation code ("perfect parser") ensures
that instance documents conform to the schema. Validation code is generated
by default when the selected underlying XML parser is non-validating
(expat).
- --suppress-validation
-
Suppress the generation of validation code. Validation is suppressed by
default when the selected underlying XML parser is validating
(xerces).
- --generate-polymorphic
-
Generate polymorphism-aware code. Specify this option if you use
substitution groups or xsi:type.
- --generate-noop-impl
-
Generate a sample parser implementation that does nothing (no operation).
The sample implementation can then be filled with the application-specific
code. For an input file in the form name.xsd this option triggers
the generation of two additional C++ files in the form:
name-pimpl.hxx (parser implementation header file) and
name-pimpl.cxx (parser implementation source file).
- --generate-print-impl
-
Generate a sample parser implementation that prints the XML data to STDOUT.
For an input file in the form name.xsd this option triggers the
generation of two additional C++ files in the form: name-pimpl.hxx
(parser implementation header file) and name-pimpl.cxx (parser
implementation source file).
- --generate-test-driver
-
Generate a test driver for the sample parser implementation. For an input
file in the form name.xsd this option triggers the generation of an
additional C++ file in the form name-driver.cxx.
- --force-overwrite
-
Force overwriting of the existing implementation and test driver files. Use
this option only if you do not mind loosing the changes you have made in the
sample implementation or test driver files.
- --root-element-first
-
Indicate that the first global element is the document root. This
information is used to generate the test driver for the sample
implementation.
- --root-element-last
-
Indicate that the last global element is the document root. This
information is used to generate the test driver for the sample
implementation.
- --root-element element
-
Indicate that element is the document root. This information is used
to generate the test driver for the sample implementation.
- --skel-type-suffix suffix
-
Use the provided suffix instead of the default _pskel to
construct the names of the generated parser skeletons.
- --skel-file-suffix suffix
-
Use the provided suffix instead of the default -pskel to
construct the names of the generated parser skeleton files.
- --impl-type-suffix suffix
-
Use the provided suffix instead of the default _pimpl to
construct the names of the parser implementations for the built-in XML
Schema types as well as sample parser implementations.
- --impl-file-suffix suffix
-
Use the provided suffix instead of the default -pimpl to
construct the names of the generated sample parser implementation files.
NAMING CONVENTION
The compiler can be instructed to use a particular naming convention in the generated code. A number of widely-used conventions can be selected using the --type-naming and --function-naming options. A custom naming convention can be achieved using the --type-regex, --accessor-regex, --one-accessor-regex, --opt-accessor-regex, --seq-accessor-regex, --modifier-regex, --one-modifier-regex, --opt-modifier-regex, --seq-modifier-regex, --parser-regex, --serializer-regex, --const-regex, --enumerator-regex, and --element-type-regex options.The --type-naming option specifies the convention that should be used for naming C++ types. Possible values for this option are knr (default), ucc, and java. The knr value (stands for K&R) signifies the standard, lower-case naming convention with the underscore used as a word delimiter, for example: foo, foo_bar. The ucc (stands for upper-camel-case) and java values a synonyms for the same naming convention where the first letter of each word in the name is capitalized, for example: Foo, FooBar.
Similarly, the --function-naming option specifies the convention that should be used for naming C++ functions. Possible values for this option are knr (default), lcc, and java. The knr value (stands for K&R) signifies the standard, lower-case naming convention with the underscore used as a word delimiter, for example: foo(), foo_bar(). The lcc value (stands for lower-camel-case) signifies a naming convention where the first letter of each word except the first is capitalized, for example: foo(), fooBar(). The java naming convention is similar to the lower-camel-case one except that accessor functions are prefixed with get, modifier functions are prefixed with set, parsing functions are prefixed with parse, and serialization functions are prefixed with serialize, for example: getFoo(), setFooBar(), parseRoot(), serializeRoot().
Note that the naming conventions specified with the --type-naming and --function-naming options perform only limited transformations on the names that come from the schema in the form of type, attribute, and element names. In other words, to get consistent results, your schemas should follow a similar naming convention as the one you would like to have in the generated code. Alternatively, you can use the --*-regex options (discussed below) to perform further transformations on the names that come from the schema.
The --type-regex, --accessor-regex, --one-accessor-regex, --opt-accessor-regex, --seq-accessor-regex, --modifier-regex, --one-modifier-regex, --opt-modifier-regex, --seq-modifier-regex, --parser-regex, --serializer-regex, --const-regex, --enumerator-regex, and --element-type-regex options allow you to specify extra regular expressions for each name category in addition to the predefined set that is added depending on the --type-naming and --function-naming options. Expressions that are provided with the --*-regex options are evaluated prior to any predefined expressions. This allows you to selectively override some or all of the predefined transformations. When debugging your own expressions, it is often useful to see which expressions match which names. The --name-regex-trace option allows you to trace the process of applying regular expressions to names.
The value for the --*-regex options should be a perl-like regular expression in the form /pattern/replacement/. Any character can be used as a delimiter instead of /. Escaping of the delimiter character in pattern or replacement is not supported. All the regular expressions for each category are pushed into a category-specific stack with the last specified expression considered first. The first match that succeeds is used. For the --one-accessor-regex (accessors with cardinality one), --opt-accessor-regex (accessors with cardinality optional), and --seq-accessor-regex (accessors with cardinality sequence) categories the --accessor-regex expressions are used as a fallback. For the --one-modifier-regex, --opt-modifier-regex, and --seq-modifier-regex categories the --modifier-regex expressions are used as a fallback. For the --element-type-regex category the --type-regex expressions are used as a fallback.
The type name expressions (--type-regex) are evaluated on the name string that has the following format:
[namespace ]name[,name][,name][,name]
The element type name expressions (--element-type-regex), effective only when the --generate-element-type option is specified, are evaluated on the name string that has the following format:
namespace name
In the type name format the namespace part followed by a space is only present for global type names. For global types and elements defined in schemas without a target namespace, the namespace part is empty but the space is still present. In the type name format after the initial name component, up to three additional name components can be present, separated by commas. For example:
foo
foo,iterator
foo,const,iterator
The following set of predefined regular expressions is used to transform type names when the upper-camel-case naming convention is selected:
/(?:[^ ]* )?([^,]+)/\\u$1/
/(?:[^ ]* )?([^,]+),([^,]+)/\\u$1\\u$2/
/(?:[^ ]* )?([^,]+),([^,]+),([^,]+)/\\u$1\\u$2\\u$3/
/(?:[^ ]* )?([^,]+),([^,]+),([^,]+),([^,]+)/\\u$1\\u$2\\u$3\\u$4/
The accessor and modifier expressions (--*accessor-regex and --*modifier-regex) are evaluated on the name string that has the following format:
name[,name][,name]
After the initial name component, up to two additional name components can be present, separated by commas. For example:
foo
dom,document
foo,default,value
The following set of predefined regular expressions is used to transform accessor names when the java naming convention is selected:
/([^,]+)/get\\u$1/
/([^,]+),([^,]+)/get\\u$1\\u$2/
/([^,]+),([^,]+),([^,]+)/get\\u$1\\u$2\\u$3/
For the parser, serializer, and enumerator categories, the corresponding regular expressions are evaluated on local names of elements and on enumeration values, respectively. For example, the following predefined regular expression is used to transform parsing function names when the java naming convention is selected:
/(.+)/parse\\u$1/
The const category is used to create C++ constant names for the element/wildcard/text content ids in ordered types.
See also the REGEX AND SHELL QUOTING section below.
TYPE MAP
Type map files are used in C++/Parser to define a mapping between XML Schema and C++ types. The compiler uses this information to determine the return types of post_* functions in parser skeletons corresponding to XML Schema types as well as argument types for callbacks corresponding to elements and attributes of these types.The compiler has a set of predefined mapping rules that map built-in XML Schema types to suitable C++ types (discussed below) and all other types to void. By providing your own type maps you can override these predefined rules. The format of the type map file is presented below:
-
namespace
schema-namespace
[
cxx-namespace
]
{
( include file-name; )*
([ type ] schema-type cxx-ret-type [ cxx-arg-type ]; )*
}
Both schema-namespace and schema-type are regex patterns while cxx-namespace, cxx-ret-type, and cxx-arg-type are regex pattern substitutions. All names can be optionally enclosed in " ", for example, to include white-spaces.
schema-namespace determines XML Schema namespace. Optional cxx-namespace is prefixed to every C++ type name in this namespace declaration. cxx-ret-type is a C++ type name that is used as a return type for the post_* functions. Optional cxx-arg-type is an argument type for callback functions corresponding to elements and attributes of this type. If cxx-arg-type is not specified, it defaults to cxx-ret-type if cxx-ret-type ends with * or & (that is, it is a pointer or a reference) and const cxx-ret-type& otherwise. file-name is a file name either in the " " or < > format and is added with the #include directive to the generated code.
The # character starts a comment that ends with a new line or end of file. To specify a name that contains # enclose it in " ". For example:
-
namespace http://www.example.com/xmlns/my my
{
include "my.hxx";
# Pass apples by value.
#
apple apple;
# Pass oranges as pointers.
#
orange orange_t*;
}
In the example above, for the http://www.example.com/xmlns/my#orange XML Schema type, the my::orange_t* C++ type will be used as both return and argument types.
Several namespace declarations can be specified in a single file. The namespace declaration can also be completely omitted to map types in a schema without a namespace. For instance:
-
include "my.hxx";
apple apple;
namespace http://www.example.com/xmlns/my
{
orange "const orange_t*";
}
The compiler has a number of predefined mapping rules that can be presented as the following map files. The string-based XML Schema built-in types are mapped to either std::string or std::wstring depending on the character type selected with the --char-type option (char by default).
-
namespace http://www.w3.org/2001/XMLSchema
{
boolean bool bool;
byte "signed char" "signed char";
unsignedByte "unsigned char" "unsigned char";
short short short;
unsignedShort "unsigned short" "unsigned short";
int int int;
unsignedInt "unsigned int" "unsigned int";
long "long long" "long long";
unsignedLong "unsigned long long" "unsigned long long";
integer "long long" "long long";
negativeInteger "long long" "long long";
nonPositiveInteger "long long" "long long";
positiveInteger "unsigned long long" "unsigned long long";
nonNegativeInteger "unsigned long long" "unsigned long long";
float float float;
double double double;
decimal double double;
string std::string;
normalizedString std::string;
token std::string;
Name std::string;
NMTOKEN std::string;
NCName std::string;
ID std::string;
IDREF std::string;
language std::string;
anyURI std::string;
NMTOKENS xml_schema::string_sequence;
IDREFS xml_schema::string_sequence;
QName xml_schema::qname;
base64Binary std::auto_ptr<xml_schema::buffer>
std::auto_ptr<xml_schema::buffer>;
hexBinary std::auto_ptr<xml_schema::buffer>
std::auto_ptr<xml_schema::buffer>;
date xml_schema::date;
dateTime xml_schema::date_time;
duration xml_schema::duration;
gDay xml_schema::gday;
gMonth xml_schema::gmonth;
gMonthDay xml_schema::gmonth_day;
gYear xml_schema::gyear;
gYearMonth xml_schema::gyear_month;
time xml_schema::time;
}
The last predefined rule maps anything that wasn't mapped by previous rules to void:
-
namespace .*
{
.* void void;
}
When you provide your own type maps with the --type-map option, they are evaluated first. This allows you to selectively override predefined rules.
REGEX AND SHELL QUOTING
When entering a regular expression argument in the shell command line it is often necessary to use quoting (enclosing the argument in " " or ' ') in order to prevent the shell from interpreting certain characters, for example, spaces as argument separators and $ as variable expansions.Unfortunately it is hard to achieve this in a manner that is portable across POSIX shells, such as those found on GNU/Linux and UNIX, and Windows shell. For example, if you use " " for quoting you will get a wrong result with POSIX shells if your expression contains $. The standard way of dealing with this on POSIX systems is to use ' ' instead. Unfortunately, Windows shell does not remove ' ' from arguments when they are passed to applications. As a result you may have to use ' ' for POSIX and " " for Windows ($ is not treated as a special character on Windows).
Alternatively, you can save regular expression options into a file, one option per line, and use this file with the --options-file option. With this approach you don't need to worry about shell quoting.
DIAGNOSTICS
If the input file is not a valid W3C XML Schema definition, xsdcxx will issue diagnostic messages to STDERR and exit with non-zero exit code.BUGS
Send bug reports to the xsd-users [at] codesynthesis.com mailing list.COPYRIGHT
Copyright (c) 2005-2014 Code Synthesis Tools CC.Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, version 1.2; with no Invariant Sections, no Front-Cover Texts and no Back-Cover Texts. Copy of the license can be obtained from http://codesynthesis.com/licenses/fdl-1.2.txt