ontologies/src/main/resources/org/apache/clerezza/ontologies/xsd.n3 - clerezza - Git at Google

 @prefix xsd:  <http://www.w3.org/2001/XMLSchema#> .
 @prefix rdfs: <http://www.w3.org/2000/01/rdf-schema#> .
 @prefix foaf: <http://xmlns.com/foaf/0.1/> .
 @prefix owl: <http://www.w3.org/2002/07/owl#> .

 <http://www.w3.org/2001/XMLSchema> a owl:Ontology .

 <> foaf:creator <http://bblfish.net/people/henry/card#me> .

 xsd:int a rdfs:Datatype;
     rdfs:comment "int is ·derived· from long by setting the value of ·maxInclusive· to be 2147483647 and ·minInclusive· to be -2147483648. The ·base type· of int is long." .

 xsd:string a rdfs:Datatype;
     rdfs:comment "The string datatype represents character strings in XML. The ·value space· of string is the set of finite-length sequences of characters (as defined in [XML 1.0 (Second Edition)]) that ·match· the Char production from [XML 1.0 (Second Edition)]. A character is an atomic unit of communication; it is not further specified except to note that every character has a corresponding Universal Character Set code point, which is an integer." .

 xsd:boolean a rdfs:Datatype;
     rdfs:comment "boolean has the ·value space· required to support the mathematical concept of binary-valued logic: {true, false}." .

 xsd:decimal a rdfs:Datatype;
     rdfs:comment """decimal represents arbitrary precision decimal numbers. The ·value space· of decimal is the set of the values i × 10^-n, where i and n are integers such that n >= 0. The ·order-relation· on decimal is: x < y iff y - x is positive.

 [Definition:]   The ·value space· of types derived from decimal with a value for ·totalDigits· of p is the set of values i × 10^-n, where n and i are integers such that p >= n >= 0 and the number of significant decimal digits in i is less than or equal to p.

 [Definition:]   The ·value space· of types derived from decimal with a value for ·fractionDigits· of s is the set of values i × 10^-n, where i and n are integers such that 0 <= n <= s.""" .

 xsd:float a rdfs:Datatype;
     rdfs:comment "float corresponds to the IEEE single-precision 32-bit floating point type [IEEE 754-1985]. The basic ·value space· of float consists of the values m × 2^e, where m is an integer whose absolute value is less than 2^24, and e is an integer between -149 and 104, inclusive. In addition to the basic ·value space· described above, the ·value space· of float also contains the following special values: positive and negative zero, positive and negative infinity and not-a-number. The ·order-relation· on float is: x < y iff y - x is positive. Positive zero is greater than negative zero. Not-a-number equals itself and is greater than all float values including positive infinity." .

 xsd:double a rdfs:Datatype;
     rdfs:comment "The double datatype corresponds to IEEE double-precision 64-bit floating point type [IEEE 754-1985]. The basic ·value space· of double consists of the values m × 2^e, where m is an integer whose absolute value is less than 2^53, and e is an integer between -1075 and 970, inclusive. In addition to the basic ·value space· described above, the ·value space· of double also contains the following special values: positive and negative zero, positive and negative infinity and not-a-number. The ·order-relation· on double is: x < y iff y - x is positive. Positive zero is greater than negative zero. Not-a-number equals itself and is greater than all double values including positive infinity." .

 xsd:dateTime a rdfs:Datatype;
     rdfs:comment "dateTime represents a specific instant of time. The ·value space· of dateTime is the space of Combinations of date and time of day values as defined in § 5.4 of [ISO 8601]." .

 xsd:time a rdfs:Datatype;
     rdfs:comment "  time represents an instant of time that recurs every day. The ·value space· of time is the space of time of day values as defined in § 5.3 of [ISO 8601]. Specifically, it is a set of zero-duration daily time instances." .

 xsd:date a rdfs:Datatype;
     rdfs:comment "date represents a calendar date. The ·value space· of date is the set of Gregorian calendar dates as defined in § 5.2.1 of [ISO 8601]. Specifically, it is a set of one-day long, non-periodic instances e.g. lexical 1999-10-26 to represent the calendar date 1999-10-26, independent of how many hours this day has." .

 xsd:gYearMonth a rdfs:Datatype;
     rdfs:comment "gYearMonth represents a specific gregorian month in a specific gregorian year. The ·value space· of gYearMonth is the set of Gregorian calendar months as defined in § 5.2.1 of [ISO 8601]. Specifically, it is a set of one-month long, non-periodic instances e.g. 1999-10 to represent the whole month of 1999-10, independent of how many days this month has." .

 xsd:gMonthDay a rdfs:Datatype;
     rdfs:comment "gMonthDay is a gregorian date that recurs, specifically a day of the year such as the third of May. Arbitrary recurring dates are not supported by this datatype. The ·value space· of gMonthDay is the set of calendar dates, as defined in § 3 of [ISO 8601]. Specifically, it is a set of one-day long, annually periodic instances." .

 xsd:gDay a rdfs:Datatype;
     rdfs:comment "gDay is a gregorian day that recurs, specifically a day of the month such as the 5th of the month. Arbitrary recurring days are not supported by this datatype. The ·value space· of gDay is the space of a set of calendar dates as defined in § 3 of [ISO 8601]. Specifically, it is a set of one-day long, monthly periodic instances." .

 xsd:gMonth a rdfs:Datatype;
     rdfs:comment " gMonth is a gregorian month that recurs every year. The ·value space· of gMonth is the space of a set of calendar months as defined in § 3 of [ISO 8601]. Specifically, it is a set of one-month long, yearly periodic instances." .

 xsd:hexBinary a rdfs:Datatype;
     rdfs:comment "hexBinary represents arbitrary hex-encoded binary data. The ·value space· of hexBinary is the set of finite-length sequences of binary octets." .

 xsd:base64Binary a rdfs:Datatype;
     rdfs:comment " base64Binary represents Base64-encoded arbitrary binary data. The ·value space· of base64Binary is the set of finite-length sequences of binary octets. For base64Binary data the entire binary stream is encoded using the Base64 Content-Transfer-Encoding defined in Section 6.8 of [RFC 2045]." .

 xsd:anyURI a rdfs:Datatype;
     rdfs:comment "anyURI represents a Uniform Resource Identifier Reference (URI). An anyURI value can be absolute or relative, and may have an optional fragment identifier (i.e., it may be a URI Reference). This type should be used to specify the intention that the value fulfills the role of a URI as defined by [RFC 2396], as amended by [RFC 2732]." .

 xsd:normalizedString a rdfs:Datatype;
     rdfs:comment "normalizedString represents white space normalized strings. The ·value space· of normalizedString is the set of strings that do not contain the carriage return (#xD), line feed (#xA) nor tab (#x9) characters. The ·lexical space· of normalizedString is the set of strings that do not contain the carriage return (#xD) nor tab (#x9) characters. The ·base type· of normalizedString is string.  " .

 xsd:token a rdfs:Datatype;
     rdfs:comment " token represents tokenized strings. The ·value space· of token is the set of strings that do not contain the line feed (#xA) nor tab (#x9) characters, that have no leading or trailing spaces (#x20) and that have no internal sequences of two or more spaces. The ·lexical space· of token is the set of strings that do not contain the line feed (#xA) nor tab (#x9) characters, that have no leading or trailing spaces (#x20) and that have no internal sequences of two or more spaces. The ·base type· of token is normalizedString." .

 xsd:language a rdfs:Datatype;
     rdfs:comment "anguage represents natural language identifiers as defined by [RFC 1766]. The ·value space· of language is the set of all strings that are valid language identifiers as defined in the language identification section of [XML 1.0 (Second Edition)]. The ·lexical space· of language is the set of all strings that are valid language identifiers as defined in the language identification section of [XML 1.0 (Second Edition)]. The ·base type· of language is token." .

 xsd:NMTOKEN a rdfs:Datatype;
     rdfs:comment "NMTOKEN represents the NMTOKEN attribute type from [XML 1.0 (Second Edition)]. The ·value space· of NMTOKEN is the set of tokens that ·match· the Nmtoken production in [XML 1.0 (Second Edition)]. The ·lexical space· of NMTOKEN is the set of strings that ·match· the Nmtoken production in [XML 1.0 (Second Edition)]. The ·base type· of NMTOKEN is token." .

 xsd:Name a rdfs:Datatype;
     rdfs:comment "Name represents XML Names. The ·value space· of Name is the set of all strings which ·match· the Name production of [XML 1.0 (Second Edition)]. The ·lexical space· of Name is the set of all strings which ·match· the Name production of [XML 1.0 (Second Edition)]. The ·base type· of Name is token." .

 xsd:NCName a rdfs:Datatype;
     rdfs:comment "NCName represents XML \"non-colonized\" Names. The ·value space· of NCName is the set of all strings which ·match· the NCName production of [Namespaces in XML]. The ·lexical space· of NCName is the set of all strings which ·match· the NCName production of [Namespaces in XML]. The ·base type· of NCName is Name." .

 xsd:integer a rdfs:Datatype;
     rdfs:comment "integer is ·derived· from decimal by fixing the value of ·fractionDigits· to be 0. This results in the standard mathematical concept of the integer numbers. The ·value space· of integer is the infinite set {...,-2,-1,0,1,2,...}. The ·base type· of integer is decimal." .

 xsd:nonPositiveInteger a rdfs:Datatype;
     rdfs:comment "nonPositiveInteger is ·derived· from integer by setting the value of ·maxInclusive· to be 0. This results in the standard mathematical concept of the non-positive integers. The ·value space· of nonPositiveInteger is the infinite set {...,-2,-1,0}. The ·base type· of nonPositiveInteger is integer." .

 xsd:negativeInteger a rdfs:Datatype;
     rdfs:comment "negativeInteger is ·derived· from nonPositiveInteger by setting the value of ·maxInclusive· to be -1. This results in the standard mathematical concept of the negative integers. The ·value space· of negativeInteger is the infinite set {...,-2,-1}. The ·base type· of negativeInteger is nonPositiveInteger." .

 xsd:long a rdfs:Datatype;
     rdfs:comment "long is ·derived· from integer by setting the value of ·maxInclusive· to be 9223372036854775807 and ·minInclusive· to be -9223372036854775808. The ·base type· of long is integer." .

 xsd:int a rdfs:Datatype;
     rdfs:comment "int is ·derived· from long by setting the value of ·maxInclusive· to be 2147483647 and ·minInclusive· to be -2147483648. The ·base type· of int is long." .

 xsd:short a rdfs:Datatype;
     rdfs:comment "short is ·derived· from int by setting the value of ·maxInclusive· to be 32767 and ·minInclusive· to be -32768. The ·base type· of short is int." .

 xsd:byte a rdfs:Datatype;
     rdfs:comment " byte is ·derived· from short by setting the value of ·maxInclusive· to be 127 and ·minInclusive· to be -128. The ·base type· of byte is short." .

 xsd:nonNegativeInteger a rdfs:Datatype;
     rdfs:comment "nonNegativeInteger is ·derived· from integer by setting the value of ·minInclusive· to be 0. This results in the standard mathematical concept of the non-negative integers. The ·value space· of nonNegativeInteger is the infinite set {0,1,2,...}. The ·base type· of nonNegativeInteger is integer." .

 xsd:unsignedLong a rdfs:Datatype;
     rdfs:comment "unsignedLong is ·derived· from nonNegativeInteger by setting the value of ·maxInclusive· to be 18446744073709551615. The ·base type· of unsignedLong is nonNegativeInteger." .

 xsd:unsignedInt a rdfs:Datatype;
     rdfs:comment " unsignedInt is ·derived· from unsignedLong by setting the value of ·maxInclusive· to be 4294967295. The ·base type· of unsignedInt is unsignedLong." .

 xsd:unsignedShort a rdfs:Datatype;
     rdfs:comment "unsignedShort is ·derived· from unsignedInt by setting the value of ·maxInclusive· to be 65535. The ·base type· of unsignedShort is unsignedInt." .

 xsd:unsignedByte a rdfs:Datatype;
     rdfs:comment "unsignedByte is ·derived· from unsignedShort by setting the value of ·maxInclusive· to be 255. The ·base type· of unsignedByte is unsignedShort." .

 xsd:positiveInteger  a rdfs:Datatype;
     rdfs:comment "positiveInteger is ·derived· from nonNegativeInteger by setting the value of ·minInclusive· to be 1. This results in the standard mathematical concept of the positive integer numbers. The ·value space· of positiveInteger is the infinite set {1,2,...}. The ·base type· of positiveInteger is nonNegativeInteger." .
	@prefix xsd: <http://www.w3.org/2001/XMLSchema#> .
	@prefix rdfs: <http://www.w3.org/2000/01/rdf-schema#> .
	@prefix foaf: <http://xmlns.com/foaf/0.1/> .
	@prefix owl: <http://www.w3.org/2002/07/owl#> .

	<http://www.w3.org/2001/XMLSchema> a owl:Ontology .

	<> foaf:creator <http://bblfish.net/people/henry/card#me> .

	xsd:int a rdfs:Datatype;
	rdfs:comment "int is ·derived· from long by setting the value of ·maxInclusive· to be 2147483647 and ·minInclusive· to be -2147483648. The ·base type· of int is long." .

	xsd:string a rdfs:Datatype;
	rdfs:comment "The string datatype represents character strings in XML. The ·value space· of string is the set of finite-length sequences of characters (as defined in [XML 1.0 (Second Edition)]) that ·match· the Char production from [XML 1.0 (Second Edition)]. A character is an atomic unit of communication; it is not further specified except to note that every character has a corresponding Universal Character Set code point, which is an integer." .

	xsd:boolean a rdfs:Datatype;
	rdfs:comment "boolean has the ·value space· required to support the mathematical concept of binary-valued logic: {true, false}." .

	xsd:decimal a rdfs:Datatype;
	rdfs:comment """decimal represents arbitrary precision decimal numbers. The ·value space· of decimal is the set of the values i × 10^-n, where i and n are integers such that n >= 0. The ·order-relation· on decimal is: x < y iff y - x is positive.

	[Definition:] The ·value space· of types derived from decimal with a value for ·totalDigits· of p is the set of values i × 10^-n, where n and i are integers such that p >= n >= 0 and the number of significant decimal digits in i is less than or equal to p.

	[Definition:] The ·value space· of types derived from decimal with a value for ·fractionDigits· of s is the set of values i × 10^-n, where i and n are integers such that 0 <= n <= s.""" .

	xsd:float a rdfs:Datatype;
	rdfs:comment "float corresponds to the IEEE single-precision 32-bit floating point type [IEEE 754-1985]. The basic ·value space· of float consists of the values m × 2^e, where m is an integer whose absolute value is less than 2^24, and e is an integer between -149 and 104, inclusive. In addition to the basic ·value space· described above, the ·value space· of float also contains the following special values: positive and negative zero, positive and negative infinity and not-a-number. The ·order-relation· on float is: x < y iff y - x is positive. Positive zero is greater than negative zero. Not-a-number equals itself and is greater than all float values including positive infinity." .

	xsd:double a rdfs:Datatype;
	rdfs:comment "The double datatype corresponds to IEEE double-precision 64-bit floating point type [IEEE 754-1985]. The basic ·value space· of double consists of the values m × 2^e, where m is an integer whose absolute value is less than 2^53, and e is an integer between -1075 and 970, inclusive. In addition to the basic ·value space· described above, the ·value space· of double also contains the following special values: positive and negative zero, positive and negative infinity and not-a-number. The ·order-relation· on double is: x < y iff y - x is positive. Positive zero is greater than negative zero. Not-a-number equals itself and is greater than all double values including positive infinity." .

	xsd:dateTime a rdfs:Datatype;
	rdfs:comment "dateTime represents a specific instant of time. The ·value space· of dateTime is the space of Combinations of date and time of day values as defined in § 5.4 of [ISO 8601]." .

	xsd:time a rdfs:Datatype;
	rdfs:comment " time represents an instant of time that recurs every day. The ·value space· of time is the space of time of day values as defined in § 5.3 of [ISO 8601]. Specifically, it is a set of zero-duration daily time instances." .

	xsd:date a rdfs:Datatype;
	rdfs:comment "date represents a calendar date. The ·value space· of date is the set of Gregorian calendar dates as defined in § 5.2.1 of [ISO 8601]. Specifically, it is a set of one-day long, non-periodic instances e.g. lexical 1999-10-26 to represent the calendar date 1999-10-26, independent of how many hours this day has." .

	xsd:gYearMonth a rdfs:Datatype;
	rdfs:comment "gYearMonth represents a specific gregorian month in a specific gregorian year. The ·value space· of gYearMonth is the set of Gregorian calendar months as defined in § 5.2.1 of [ISO 8601]. Specifically, it is a set of one-month long, non-periodic instances e.g. 1999-10 to represent the whole month of 1999-10, independent of how many days this month has." .

	xsd:gMonthDay a rdfs:Datatype;
	rdfs:comment "gMonthDay is a gregorian date that recurs, specifically a day of the year such as the third of May. Arbitrary recurring dates are not supported by this datatype. The ·value space· of gMonthDay is the set of calendar dates, as defined in § 3 of [ISO 8601]. Specifically, it is a set of one-day long, annually periodic instances." .

	xsd:gDay a rdfs:Datatype;
	rdfs:comment "gDay is a gregorian day that recurs, specifically a day of the month such as the 5th of the month. Arbitrary recurring days are not supported by this datatype. The ·value space· of gDay is the space of a set of calendar dates as defined in § 3 of [ISO 8601]. Specifically, it is a set of one-day long, monthly periodic instances." .

	xsd:gMonth a rdfs:Datatype;
	rdfs:comment " gMonth is a gregorian month that recurs every year. The ·value space· of gMonth is the space of a set of calendar months as defined in § 3 of [ISO 8601]. Specifically, it is a set of one-month long, yearly periodic instances." .

	xsd:hexBinary a rdfs:Datatype;
	rdfs:comment "hexBinary represents arbitrary hex-encoded binary data. The ·value space· of hexBinary is the set of finite-length sequences of binary octets." .

	xsd:base64Binary a rdfs:Datatype;
	rdfs:comment " base64Binary represents Base64-encoded arbitrary binary data. The ·value space· of base64Binary is the set of finite-length sequences of binary octets. For base64Binary data the entire binary stream is encoded using the Base64 Content-Transfer-Encoding defined in Section 6.8 of [RFC 2045]." .

	xsd:anyURI a rdfs:Datatype;
	rdfs:comment "anyURI represents a Uniform Resource Identifier Reference (URI). An anyURI value can be absolute or relative, and may have an optional fragment identifier (i.e., it may be a URI Reference). This type should be used to specify the intention that the value fulfills the role of a URI as defined by [RFC 2396], as amended by [RFC 2732]." .

	xsd:normalizedString a rdfs:Datatype;
	rdfs:comment "normalizedString represents white space normalized strings. The ·value space· of normalizedString is the set of strings that do not contain the carriage return (#xD), line feed (#xA) nor tab (#x9) characters. The ·lexical space· of normalizedString is the set of strings that do not contain the carriage return (#xD) nor tab (#x9) characters. The ·base type· of normalizedString is string. " .

	xsd:token a rdfs:Datatype;
	rdfs:comment " token represents tokenized strings. The ·value space· of token is the set of strings that do not contain the line feed (#xA) nor tab (#x9) characters, that have no leading or trailing spaces (#x20) and that have no internal sequences of two or more spaces. The ·lexical space· of token is the set of strings that do not contain the line feed (#xA) nor tab (#x9) characters, that have no leading or trailing spaces (#x20) and that have no internal sequences of two or more spaces. The ·base type· of token is normalizedString." .

	xsd:language a rdfs:Datatype;
	rdfs:comment "anguage represents natural language identifiers as defined by [RFC 1766]. The ·value space· of language is the set of all strings that are valid language identifiers as defined in the language identification section of [XML 1.0 (Second Edition)]. The ·lexical space· of language is the set of all strings that are valid language identifiers as defined in the language identification section of [XML 1.0 (Second Edition)]. The ·base type· of language is token." .

	xsd:NMTOKEN a rdfs:Datatype;
	rdfs:comment "NMTOKEN represents the NMTOKEN attribute type from [XML 1.0 (Second Edition)]. The ·value space· of NMTOKEN is the set of tokens that ·match· the Nmtoken production in [XML 1.0 (Second Edition)]. The ·lexical space· of NMTOKEN is the set of strings that ·match· the Nmtoken production in [XML 1.0 (Second Edition)]. The ·base type· of NMTOKEN is token." .

	xsd:Name a rdfs:Datatype;
	rdfs:comment "Name represents XML Names. The ·value space· of Name is the set of all strings which ·match· the Name production of [XML 1.0 (Second Edition)]. The ·lexical space· of Name is the set of all strings which ·match· the Name production of [XML 1.0 (Second Edition)]. The ·base type· of Name is token." .

	xsd:NCName a rdfs:Datatype;
	rdfs:comment "NCName represents XML \"non-colonized\" Names. The ·value space· of NCName is the set of all strings which ·match· the NCName production of [Namespaces in XML]. The ·lexical space· of NCName is the set of all strings which ·match· the NCName production of [Namespaces in XML]. The ·base type· of NCName is Name." .

	xsd:integer a rdfs:Datatype;
	rdfs:comment "integer is ·derived· from decimal by fixing the value of ·fractionDigits· to be 0. This results in the standard mathematical concept of the integer numbers. The ·value space· of integer is the infinite set {...,-2,-1,0,1,2,...}. The ·base type· of integer is decimal." .

	xsd:nonPositiveInteger a rdfs:Datatype;
	rdfs:comment "nonPositiveInteger is ·derived· from integer by setting the value of ·maxInclusive· to be 0. This results in the standard mathematical concept of the non-positive integers. The ·value space· of nonPositiveInteger is the infinite set {...,-2,-1,0}. The ·base type· of nonPositiveInteger is integer." .

	xsd:negativeInteger a rdfs:Datatype;
	rdfs:comment "negativeInteger is ·derived· from nonPositiveInteger by setting the value of ·maxInclusive· to be -1. This results in the standard mathematical concept of the negative integers. The ·value space· of negativeInteger is the infinite set {...,-2,-1}. The ·base type· of negativeInteger is nonPositiveInteger." .

	xsd:long a rdfs:Datatype;
	rdfs:comment "long is ·derived· from integer by setting the value of ·maxInclusive· to be 9223372036854775807 and ·minInclusive· to be -9223372036854775808. The ·base type· of long is integer." .

	xsd:int a rdfs:Datatype;
	rdfs:comment "int is ·derived· from long by setting the value of ·maxInclusive· to be 2147483647 and ·minInclusive· to be -2147483648. The ·base type· of int is long." .

	xsd:short a rdfs:Datatype;
	rdfs:comment "short is ·derived· from int by setting the value of ·maxInclusive· to be 32767 and ·minInclusive· to be -32768. The ·base type· of short is int." .

	xsd:byte a rdfs:Datatype;
	rdfs:comment " byte is ·derived· from short by setting the value of ·maxInclusive· to be 127 and ·minInclusive· to be -128. The ·base type· of byte is short." .

	xsd:nonNegativeInteger a rdfs:Datatype;
	rdfs:comment "nonNegativeInteger is ·derived· from integer by setting the value of ·minInclusive· to be 0. This results in the standard mathematical concept of the non-negative integers. The ·value space· of nonNegativeInteger is the infinite set {0,1,2,...}. The ·base type· of nonNegativeInteger is integer." .

	xsd:unsignedLong a rdfs:Datatype;
	rdfs:comment "unsignedLong is ·derived· from nonNegativeInteger by setting the value of ·maxInclusive· to be 18446744073709551615. The ·base type· of unsignedLong is nonNegativeInteger." .

	xsd:unsignedInt a rdfs:Datatype;
	rdfs:comment " unsignedInt is ·derived· from unsignedLong by setting the value of ·maxInclusive· to be 4294967295. The ·base type· of unsignedInt is unsignedLong." .

	xsd:unsignedShort a rdfs:Datatype;
	rdfs:comment "unsignedShort is ·derived· from unsignedInt by setting the value of ·maxInclusive· to be 65535. The ·base type· of unsignedShort is unsignedInt." .

	xsd:unsignedByte a rdfs:Datatype;
	rdfs:comment "unsignedByte is ·derived· from unsignedShort by setting the value of ·maxInclusive· to be 255. The ·base type· of unsignedByte is unsignedShort." .

	xsd:positiveInteger a rdfs:Datatype;
	rdfs:comment "positiveInteger is ·derived· from nonNegativeInteger by setting the value of ·minInclusive· to be 1. This results in the standard mathematical concept of the positive integer numbers. The ·value space· of positiveInteger is the infinite set {1,2,...}. The ·base type· of positiveInteger is nonNegativeInteger." .