java.net.URI Maven / Gradle / Ivy
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package java.net;
import java.io.IOException;
import java.io.InvalidObjectException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.io.Serializable;
import java.lang.Character; // for javadoc
import java.lang.NullPointerException; // for javadoc
/**
* Represents a Uniform Resource Identifier (URI) reference.
*
* Aside from some minor deviations noted below, an instance of this
* class represents a URI reference as defined by
* RFC 2396: Uniform
* Resource Identifiers (URI): Generic Syntax, amended by RFC 2732: Format for
* Literal IPv6 Addresses in URLs. The Literal IPv6 address format
* also supports scope_ids. The syntax and usage of scope_ids is described
* here.
* This class provides constructors for creating URI instances from
* their components or by parsing their string forms, methods for accessing the
* various components of an instance, and methods for normalizing, resolving,
* and relativizing URI instances. Instances of this class are immutable.
*
*
*
URI syntax and components
*
* At the highest level a URI reference (hereinafter simply "URI") in string
* form has the syntax
*
*
* [scheme:]scheme-specific-part[#fragment]
*
*
* where square brackets [...] delineate optional components and the characters
* : and # stand for themselves.
*
* An absolute URI specifies a scheme; a URI that is not absolute is
* said to be relative. URIs are also classified according to whether
* they are opaque or hierarchical.
*
*
An opaque URI is an absolute URI whose scheme-specific part does
* not begin with a slash character ('/'). Opaque URIs are not
* subject to further parsing. Some examples of opaque URIs are:
*
*
* mailto:[email protected]
* news:comp.lang.java
* urn:isbn:096139210x
*
*
* A hierarchical URI is either an absolute URI whose
* scheme-specific part begins with a slash character, or a relative URI, that
* is, a URI that does not specify a scheme. Some examples of hierarchical
* URIs are:
*
*
* http://java.sun.com/j2se/1.3/
* docs/guide/collections/designfaq.html#28
* ../../../demo/jfc/SwingSet2/src/SwingSet2.java
* file:///~/calendar
*
*
* A hierarchical URI is subject to further parsing according to the syntax
*
*
* [scheme:][//authority][path][?query][#fragment]
*
*
* where the characters :, /,
* ?, and # stand for themselves. The
* scheme-specific part of a hierarchical URI consists of the characters
* between the scheme and fragment components.
*
* The authority component of a hierarchical URI is, if specified, either
* server-based or registry-based. A server-based authority
* parses according to the familiar syntax
*
*
* [user-info@]host[:port]
*
*
* where the characters @ and : stand for
* themselves. Nearly all URI schemes currently in use are server-based. An
* authority component that does not parse in this way is considered to be
* registry-based.
*
* The path component of a hierarchical URI is itself said to be absolute
* if it begins with a slash character ('/'); otherwise it is
* relative. The path of a hierarchical URI that is either absolute or
* specifies an authority is always absolute.
*
*
All told, then, a URI instance has the following nine components:
*
*
* Component Type
* scheme String
* scheme-specific-part String
* authority String
* user-info String
* host String
* port int
* path String
* query String
* fragment String
*
*
* In a given instance any particular component is either undefined or
* defined with a distinct value. Undefined string components are
* represented by null, while undefined integer components are
* represented by -1. A string component may be defined to have the
* empty string as its value; this is not equivalent to that component being
* undefined.
*
* Whether a particular component is or is not defined in an instance
* depends upon the type of the URI being represented. An absolute URI has a
* scheme component. An opaque URI has a scheme, a scheme-specific part, and
* possibly a fragment, but has no other components. A hierarchical URI always
* has a path (though it may be empty) and a scheme-specific-part (which at
* least contains the path), and may have any of the other components. If the
* authority component is present and is server-based then the host component
* will be defined and the user-information and port components may be defined.
*
*
*
Operations on URI instances
*
* The key operations supported by this class are those of
* normalization, resolution, and relativization.
*
* Normalization is the process of removing unnecessary "."
* and ".." segments from the path component of a hierarchical URI.
* Each "." segment is simply removed. A ".." segment is
* removed only if it is preceded by a non-".." segment.
* Normalization has no effect upon opaque URIs.
*
*
Resolution is the process of resolving one URI against another,
* base URI. The resulting URI is constructed from components of both
* URIs in the manner specified by RFC 2396, taking components from the
* base URI for those not specified in the original. For hierarchical URIs,
* the path of the original is resolved against the path of the base and then
* normalized. The result, for example, of resolving
*
*
* docs/guide/collections/designfaq.html#28 (1)
*
*
* against the base URI http://java.sun.com/j2se/1.3/ is the result
* URI
*
*
* http://java.sun.com/j2se/1.3/docs/guide/collections/designfaq.html#28
*
*
* Resolving the relative URI
*
*
* ../../../demo/jfc/SwingSet2/src/SwingSet2.java (2)
*
*
* against this result yields, in turn,
*
*
* http://java.sun.com/j2se/1.3/demo/jfc/SwingSet2/src/SwingSet2.java
*
*
* Resolution of both absolute and relative URIs, and of both absolute and
* relative paths in the case of hierarchical URIs, is supported. Resolving
* the URI file:///~calendar against any other URI simply yields the
* original URI, since it is absolute. Resolving the relative URI (2) above
* against the relative base URI (1) yields the normalized, but still relative,
* URI
*
*
* demo/jfc/SwingSet2/src/SwingSet2.java
*
*
* Relativization, finally, is the inverse of resolution: For any
* two normalized URIs u and v,
*
*
* u.relativize(u.resolve(v)).equals(v) and
* u.resolve(u.relativize(v)).equals(v) .
*
*
* This operation is often useful when constructing a document containing URIs
* that must be made relative to the base URI of the document wherever
* possible. For example, relativizing the URI
*
*
* http://java.sun.com/j2se/1.3/docs/guide/index.html
*
*
* against the base URI
*
*
* http://java.sun.com/j2se/1.3
*
*
* yields the relative URI docs/guide/index.html.
*
*
* Character categories
*
* RFC 2396 specifies precisely which characters are permitted in the
* various components of a URI reference. The following categories, most of
* which are taken from that specification, are used below to describe these
* constraints:
*
*
* alpha
* The US-ASCII alphabetic characters,
* 'A' through 'Z'
* and 'a' through 'z'
* digit
* The US-ASCII decimal digit characters,
* '0' through '9'
* alphanum
* All alpha and digit characters
* unreserved
* All alphanum characters together with those in the string
* "_-!.~'()*"
* punct
* The characters in the string ",;:$&+="
* reserved
* All punct characters together with those in the string
* "?/[]@"
* escaped
* Escaped octets, that is, triplets consisting of the percent
* character ('%') followed by two hexadecimal digits
* ('0'-'9', 'A'-'F', and
* 'a'-'f')
* other
* The Unicode characters that are not in the US-ASCII character set,
* are not control characters (according to the {@link
* java.lang.Character#isISOControl(char) Character.isISOControl}
* method), and are not space characters (according to the {@link
* java.lang.Character#isSpaceChar(char) Character.isSpaceChar}
* method) (Deviation from RFC 2396, which is
* limited to US-ASCII)
*
*
* The set of all legal URI characters consists of
* the unreserved, reserved, escaped, and other
* characters.
*
*
*
Escaped octets, quotation, encoding, and decoding
*
* RFC 2396 allows escaped octets to appear in the user-info, path, query, and
* fragment components. Escaping serves two purposes in URIs:
*
*
*
* To encode non-US-ASCII characters when a URI is required to
* conform strictly to RFC 2396 by not containing any other
* characters.
*
* To quote characters that are otherwise illegal in a
* component. The user-info, path, query, and fragment components differ
* slightly in terms of which characters are considered legal and illegal.
*
*
*
*
* These purposes are served in this class by three related operations:
*
*
*
* A character is encoded by replacing it
* with the sequence of escaped octets that represent that character in the
* UTF-8 character set. The Euro currency symbol ('\u20AC'),
* for example, is encoded as "%E2%82%AC". (Deviation from
* RFC 2396, which does not specify any particular character
* set.)
*
* An illegal character is quoted simply by
* encoding it. The space character, for example, is quoted by replacing it
* with "%20". UTF-8 contains US-ASCII, hence for US-ASCII
* characters this transformation has exactly the effect required by
* RFC 2396.
*
*
* A sequence of escaped octets is decoded by
* replacing it with the sequence of characters that it represents in the
* UTF-8 character set. UTF-8 contains US-ASCII, hence decoding has the
* effect of de-quoting any quoted US-ASCII characters as well as that of
* decoding any encoded non-US-ASCII characters. If a decoding error occurs
* when decoding the escaped octets then the erroneous octets are replaced by
* '\uFFFD', the Unicode replacement character.
*
*
*
* These operations are exposed in the constructors and methods of this class
* as follows:
*
*
*
* The {@link #URI(java.lang.String) single-argument
* constructor
} requires any illegal characters in its argument to be
* quoted and preserves any escaped octets and other characters that
* are present.
*
* The {@link
* #URI(java.lang.String,java.lang.String,java.lang.String,int,java.lang.String,java.lang.String,java.lang.String)
* multi-argument constructors
} quote illegal characters as
* required by the components in which they appear. The percent character
* ('%') is always quoted by these constructors. Any other
* characters are preserved.
*
* The {@link #getRawUserInfo() getRawUserInfo}, {@link #getRawPath()
* getRawPath}, {@link #getRawQuery() getRawQuery}, {@link #getRawFragment()
* getRawFragment}, {@link #getRawAuthority() getRawAuthority}, and {@link
* #getRawSchemeSpecificPart() getRawSchemeSpecificPart} methods return the
* values of their corresponding components in raw form, without interpreting
* any escaped octets. The strings returned by these methods may contain
* both escaped octets and other characters, and will not contain any
* illegal characters.
*
* The {@link #getUserInfo() getUserInfo}, {@link #getPath()
* getPath}, {@link #getQuery() getQuery}, {@link #getFragment()
* getFragment}, {@link #getAuthority() getAuthority}, and {@link
* #getSchemeSpecificPart() getSchemeSpecificPart} methods decode any escaped
* octets in their corresponding components. The strings returned by these
* methods may contain both other characters and illegal characters,
* and will not contain any escaped octets.
*
* The {@link #toString() toString} method returns a URI string with
* all necessary quotation but which may contain other characters.
*
*
* The {@link #toASCIIString() toASCIIString} method returns a fully
* quoted and encoded URI string that does not contain any other
* characters.
*
*
*
*
* Identities
*
* For any URI u, it is always the case that
*
*
* new URI(u.toString()).equals(u) .
*
*
* For any URI u that does not contain redundant syntax such as two
* slashes before an empty authority (as in file:///tmp/ ) or a
* colon following a host name but no port (as in
* http://java.sun.com: ), and that does not encode characters
* except those that must be quoted, the following identities also hold:
*
*
* new URI(u.getScheme(),
* u.getSchemeSpecificPart(),
* u.getFragment())
* .equals(u)
*
*
* in all cases,
*
*
* new URI(u.getScheme(),
* u.getUserInfo(), u.getAuthority(),
* u.getPath(), u.getQuery(),
* u.getFragment())
* .equals(u)
*
*
* if u is hierarchical, and
*
*
* new URI(u.getScheme(),
* u.getUserInfo(), u.getHost(), u.getPort(),
* u.getPath(), u.getQuery(),
* u.getFragment())
* .equals(u)
*
*
* if u is hierarchical and has either no authority or a server-based
* authority.
*
*
* URIs, URLs, and URNs
*
* A URI is a uniform resource identifier while a URL is a uniform
* resource locator. Hence every URL is a URI, abstractly speaking, but
* not every URI is a URL. This is because there is another subcategory of
* URIs, uniform resource names (URNs), which name resources but do not
* specify how to locate them. The mailto, news, and
* isbn URIs shown above are examples of URNs.
*
* The conceptual distinction between URIs and URLs is reflected in the
* differences between this class and the {@link URL} class.
*
*
An instance of this class represents a URI reference in the syntactic
* sense defined by RFC 2396. A URI may be either absolute or relative.
* A URI string is parsed according to the generic syntax without regard to the
* scheme, if any, that it specifies. No lookup of the host, if any, is
* performed, and no scheme-dependent stream handler is constructed. Equality,
* hashing, and comparison are defined strictly in terms of the character
* content of the instance. In other words, a URI instance is little more than
* a structured string that supports the syntactic, scheme-independent
* operations of comparison, normalization, resolution, and relativization.
*
*
An instance of the {@link URL} class, by contrast, represents the
* syntactic components of a URL together with some of the information required
* to access the resource that it describes. A URL must be absolute, that is,
* it must always specify a scheme. A URL string is parsed according to its
* scheme. A stream handler is always established for a URL, and in fact it is
* impossible to create a URL instance for a scheme for which no handler is
* available. Equality and hashing depend upon both the scheme and the
* Internet address of the host, if any; comparison is not defined. In other
* words, a URL is a structured string that supports the syntactic operation of
* resolution as well as the network I/O operations of looking up the host and
* opening a connection to the specified resource.
*
*
* @author Mark Reinhold
* @since 1.4
*
* @see RFC 2279: UTF-8, a
* transformation format of ISO 10646,
RFC 2373: IPv6 Addressing
* Architecture,
RFC 2396: Uniform
* Resource Identifiers (URI): Generic Syntax,
RFC 2732: Format for
* Literal IPv6 Addresses in URLs,
URISyntaxException
*/
public final class URI
implements Comparable, Serializable
{
// Note: Comments containing the word "ASSERT" indicate places where a
// throw of an InternalError should be replaced by an appropriate assertion
// statement once asserts are enabled in the build.
static final long serialVersionUID = -6052424284110960213L;
// -- Properties and components of this instance --
// Components of all URIs: [:][#]
private transient String scheme; // null ==> relative URI
private transient String fragment;
// Hierarchical URI components: [//][?]
private transient String authority; // Registry or server
// Server-based authority: [@][:]
private transient String userInfo;
private transient String host; // null ==> registry-based
private transient int port = -1; // -1 ==> undefined
// Remaining components of hierarchical URIs
private transient String path; // null ==> opaque
private transient String query;
// The remaining fields may be computed on demand
private volatile transient String schemeSpecificPart;
private volatile transient int hash; // Zero ==> undefined
private volatile transient String decodedUserInfo = null;
private volatile transient String decodedAuthority = null;
private volatile transient String decodedPath = null;
private volatile transient String decodedQuery = null;
private volatile transient String decodedFragment = null;
private volatile transient String decodedSchemeSpecificPart = null;
/**
* The string form of this URI.
*
* @serial
*/
private volatile String string; // The only serializable field
// -- Constructors and factories --
private URI() { } // Used internally
/**
* Constructs a URI by parsing the given string.
*
* This constructor parses the given string exactly as specified by the
* grammar in RFC 2396,
* Appendix A, except for the following deviations:
*
*
*
* An empty authority component is permitted as long as it is
* followed by a non-empty path, a query component, or a fragment
* component. This allows the parsing of URIs such as
* "file:///foo/bar", which seems to be the intent of
* RFC 2396 although the grammar does not permit it. If the
* authority component is empty then the user-information, host, and port
* components are undefined.
*
* Empty relative paths are permitted; this seems to be the
* intent of RFC 2396 although the grammar does not permit it. The
* primary consequence of this deviation is that a standalone fragment
* such as "#foo" parses as a relative URI with an empty path
* and the given fragment, and can be usefully resolved against a base URI.
*
*
IPv4 addresses in host components are parsed rigorously, as
* specified by RFC 2732: Each
* element of a dotted-quad address must contain no more than three
* decimal digits. Each element is further constrained to have a value
* no greater than 255.
*
* -
Hostnames in host components that comprise only a single
* domain label are permitted to start with an alphanum
* character. This seems to be the intent of RFC 2396
* section 3.2.2 although the grammar does not permit it. The
* consequence of this deviation is that the authority component of a
* hierarchical URI such as s://123, will parse as a server-based
* authority.
*
* IPv6 addresses are permitted for the host component. An IPv6
* address must be enclosed in square brackets ('[' and
* ']') as specified by RFC 2732. The
* IPv6 address itself must parse according to RFC 2373. IPv6
* addresses are further constrained to describe no more than sixteen
* bytes of address information, a constraint implicit in RFC 2373
* but not expressible in the grammar.
*
* Characters in the other category are permitted wherever
* RFC 2396 permits escaped octets, that is, in the
* user-information, path, query, and fragment components, as well as in
* the authority component if the authority is registry-based. This
* allows URIs to contain Unicode characters beyond those in the US-ASCII
* character set.
*
*
*
* @param str The string to be parsed into a URI
*
* @throws NullPointerException
* If str is null
*
* @throws URISyntaxException
* If the given string violates RFC 2396, as augmented
* by the above deviations
*/
public URI(String str) throws URISyntaxException {
new Parser(str).parse(false);
}
/**
* Constructs a hierarchical URI from the given components.
*
* If a scheme is given then the path, if also given, must either be
* empty or begin with a slash character ('/'). Otherwise a
* component of the new URI may be left undefined by passing null
* for the corresponding parameter or, in the case of the port
* parameter, by passing -1.
*
*
This constructor first builds a URI string from the given components
* according to the rules specified in RFC 2396,
* section 5.2, step 7:
*
*
*
* Initially, the result string is empty.
*
* If a scheme is given then it is appended to the result,
* followed by a colon character (':').
*
* If user information, a host, or a port are given then the
* string "//" is appended.
*
* If user information is given then it is appended, followed by
* a commercial-at character ('@'). Any character not in the
* unreserved, punct, escaped, or other
* categories is quoted.
*
* If a host is given then it is appended. If the host is a
* literal IPv6 address but is not enclosed in square brackets
* ('[' and ']') then the square brackets are added.
*
*
* If a port number is given then a colon character
* (':') is appended, followed by the port number in decimal.
*
*
* If a path is given then it is appended. Any character not in
* the unreserved, punct, escaped, or other
* categories, and not equal to the slash character ('/') or the
* commercial-at character ('@'), is quoted.
*
* If a query is given then a question-mark character
* ('?') is appended, followed by the query. Any character that
* is not a legal URI character is quoted.
*
*
* Finally, if a fragment is given then a hash character
* ('#') is appended, followed by the fragment. Any character
* that is not a legal URI character is quoted.
*
*
*
* The resulting URI string is then parsed as if by invoking the {@link
* #URI(String)} constructor and then invoking the {@link
* #parseServerAuthority()} method upon the result; this may cause a {@link
* URISyntaxException} to be thrown.
*
* @param scheme Scheme name
* @param userInfo User name and authorization information
* @param host Host name
* @param port Port number
* @param path Path
* @param query Query
* @param fragment Fragment
*
* @throws URISyntaxException
* If both a scheme and a path are given but the path is relative,
* if the URI string constructed from the given components violates
* RFC 2396, or if the authority component of the string is
* present but cannot be parsed as a server-based authority
*/
public URI(String scheme,
String userInfo, String host, int port,
String path, String query, String fragment)
throws URISyntaxException
{
String s = toString(scheme, null,
null, userInfo, host, port,
path, query, fragment);
checkPath(s, scheme, path);
new Parser(s).parse(true);
}
/**
* Constructs a hierarchical URI from the given components.
*
* If a scheme is given then the path, if also given, must either be
* empty or begin with a slash character ('/'). Otherwise a
* component of the new URI may be left undefined by passing null
* for the corresponding parameter.
*
*
This constructor first builds a URI string from the given components
* according to the rules specified in RFC 2396,
* section 5.2, step 7:
*
*
*
* Initially, the result string is empty.
*
* If a scheme is given then it is appended to the result,
* followed by a colon character (':').
*
* If an authority is given then the string "//" is
* appended, followed by the authority. If the authority contains a
* literal IPv6 address then the address must be enclosed in square
* brackets ('[' and ']'). Any character not in the
* unreserved, punct, escaped, or other
* categories, and not equal to the commercial-at character
* ('@'), is quoted.
*
* If a path is given then it is appended. Any character not in
* the unreserved, punct, escaped, or other
* categories, and not equal to the slash character ('/') or the
* commercial-at character ('@'), is quoted.
*
* If a query is given then a question-mark character
* ('?') is appended, followed by the query. Any character that
* is not a legal URI character is quoted.
*
*
* Finally, if a fragment is given then a hash character
* ('#') is appended, followed by the fragment. Any character
* that is not a legal URI character is quoted.
*
*
*
* The resulting URI string is then parsed as if by invoking the {@link
* #URI(String)} constructor and then invoking the {@link
* #parseServerAuthority()} method upon the result; this may cause a {@link
* URISyntaxException} to be thrown.
*
* @param scheme Scheme name
* @param authority Authority
* @param path Path
* @param query Query
* @param fragment Fragment
*
* @throws URISyntaxException
* If both a scheme and a path are given but the path is relative,
* if the URI string constructed from the given components violates
* RFC 2396, or if the authority component of the string is
* present but cannot be parsed as a server-based authority
*/
public URI(String scheme,
String authority,
String path, String query, String fragment)
throws URISyntaxException
{
String s = toString(scheme, null,
authority, null, null, -1,
path, query, fragment);
checkPath(s, scheme, path);
new Parser(s).parse(false);
}
/**
* Constructs a hierarchical URI from the given components.
*
* A component may be left undefined by passing null.
*
*
This convenience constructor works as if by invoking the
* seven-argument constructor as follows:
*
*
* new {@link #URI(String, String, String, int, String, String, String)
* URI}(scheme, null, host, -1, path, null, fragment);
*
*
* @param scheme Scheme name
* @param host Host name
* @param path Path
* @param fragment Fragment
*
* @throws URISyntaxException
* If the URI string constructed from the given components
* violates RFC 2396
*/
public URI(String scheme, String host, String path, String fragment)
throws URISyntaxException
{
this(scheme, null, host, -1, path, null, fragment);
}
/**
* Constructs a URI from the given components.
*
* A component may be left undefined by passing null.
*
*
This constructor first builds a URI in string form using the given
* components as follows:
*
*
*
* Initially, the result string is empty.
*
* If a scheme is given then it is appended to the result,
* followed by a colon character (':').
*
* If a scheme-specific part is given then it is appended. Any
* character that is not a legal URI character
* is quoted.
*
* Finally, if a fragment is given then a hash character
* ('#') is appended to the string, followed by the fragment.
* Any character that is not a legal URI character is quoted.
*
*
*
* The resulting URI string is then parsed in order to create the new
* URI instance as if by invoking the {@link #URI(String)} constructor;
* this may cause a {@link URISyntaxException} to be thrown.
*
* @param scheme Scheme name
* @param ssp Scheme-specific part
* @param fragment Fragment
*
* @throws URISyntaxException
* If the URI string constructed from the given components
* violates RFC 2396
*/
public URI(String scheme, String ssp, String fragment)
throws URISyntaxException
{
new Parser(toString(scheme, ssp,
null, null, null, -1,
null, null, fragment))
.parse(false);
}
/**
* Creates a URI by parsing the given string.
*
* This convenience factory method works as if by invoking the {@link
* #URI(String)} constructor; any {@link URISyntaxException} thrown by the
* constructor is caught and wrapped in a new {@link
* IllegalArgumentException} object, which is then thrown.
*
*
This method is provided for use in situations where it is known that
* the given string is a legal URI, for example for URI constants declared
* within in a program, and so it would be considered a programming error
* for the string not to parse as such. The constructors, which throw
* {@link URISyntaxException} directly, should be used situations where a
* URI is being constructed from user input or from some other source that
* may be prone to errors.
*
* @param str The string to be parsed into a URI
* @return The new URI
*
* @throws NullPointerException
* If str is null
*
* @throws IllegalArgumentException
* If the given string violates RFC 2396
*/
public static URI create(String str) {
try {
return new URI(str);
} catch (URISyntaxException x) {
throw new IllegalArgumentException(x.getMessage(), x);
}
}
// -- Operations --
/**
* Attempts to parse this URI's authority component, if defined, into
* user-information, host, and port components.
*
* If this URI's authority component has already been recognized as
* being server-based then it will already have been parsed into
* user-information, host, and port components. In this case, or if this
* URI has no authority component, this method simply returns this URI.
*
*
Otherwise this method attempts once more to parse the authority
* component into user-information, host, and port components, and throws
* an exception describing why the authority component could not be parsed
* in that way.
*
*
This method is provided because the generic URI syntax specified in
* RFC 2396
* cannot always distinguish a malformed server-based authority from a
* legitimate registry-based authority. It must therefore treat some
* instances of the former as instances of the latter. The authority
* component in the URI string "//foo:bar", for example, is not a
* legal server-based authority but it is legal as a registry-based
* authority.
*
*
In many common situations, for example when working URIs that are
* known to be either URNs or URLs, the hierarchical URIs being used will
* always be server-based. They therefore must either be parsed as such or
* treated as an error. In these cases a statement such as
*
*
* URI u = new URI(str).parseServerAuthority();
*
*
* can be used to ensure that u always refers to a URI that, if
* it has an authority component, has a server-based authority with proper
* user-information, host, and port components. Invoking this method also
* ensures that if the authority could not be parsed in that way then an
* appropriate diagnostic message can be issued based upon the exception
* that is thrown.
*
* @return A URI whose authority field has been parsed
* as a server-based authority
*
* @throws URISyntaxException
* If the authority component of this URI is defined
* but cannot be parsed as a server-based authority
* according to RFC 2396
*/
public URI parseServerAuthority()
throws URISyntaxException
{
// We could be clever and cache the error message and index from the
// exception thrown during the original parse, but that would require
// either more fields or a more-obscure representation.
if ((host != null) || (authority == null))
return this;
defineString();
new Parser(string).parse(true);
return this;
}
/**
* Normalizes this URI's path.
*
* If this URI is opaque, or if its path is already in normal form,
* then this URI is returned. Otherwise a new URI is constructed that is
* identical to this URI except that its path is computed by normalizing
* this URI's path in a manner consistent with RFC 2396,
* section 5.2, step 6, sub-steps c through f; that is:
*
*
*
*
* All "." segments are removed.
*
* If a ".." segment is preceded by a non-".."
* segment then both of these segments are removed. This step is
* repeated until it is no longer applicable.
*
* If the path is relative, and if its first segment contains a
* colon character (':'), then a "." segment is
* prepended. This prevents a relative URI with a path such as
* "a:b/c/d" from later being re-parsed as an opaque URI with a
* scheme of "a" and a scheme-specific part of "b/c/d".
* (Deviation from RFC 2396)
*
*
*
* A normalized path will begin with one or more ".." segments
* if there were insufficient non-".." segments preceding them to
* allow their removal. A normalized path will begin with a "."
* segment if one was inserted by step 3 above. Otherwise, a normalized
* path will not contain any "." or ".." segments.
*
* @return A URI equivalent to this URI,
* but whose path is in normal form
*/
public URI normalize() {
return normalize(this);
}
/**
* Resolves the given URI against this URI.
*
* If the given URI is already absolute, or if this URI is opaque, then
* the given URI is returned.
*
*
If the given URI's fragment component is
* defined, its path component is empty, and its scheme, authority, and
* query components are undefined, then a URI with the given fragment but
* with all other components equal to those of this URI is returned. This
* allows a URI representing a standalone fragment reference, such as
* "#foo", to be usefully resolved against a base URI.
*
*
Otherwise this method constructs a new hierarchical URI in a manner
* consistent with RFC 2396,
* section 5.2; that is:
*
*
*
* A new URI is constructed with this URI's scheme and the given
* URI's query and fragment components.
*
* If the given URI has an authority component then the new URI's
* authority and path are taken from the given URI.
*
* Otherwise the new URI's authority component is copied from
* this URI, and its path is computed as follows:
*
*
*
* If the given URI's path is absolute then the new URI's path
* is taken from the given URI.
*
* Otherwise the given URI's path is relative, and so the new
* URI's path is computed by resolving the path of the given URI
* against the path of this URI. This is done by concatenating all but
* the last segment of this URI's path, if any, with the given URI's
* path and then normalizing the result as if by invoking the {@link
* #normalize() normalize} method.
*
*
*
*
*
* The result of this method is absolute if, and only if, either this
* URI is absolute or the given URI is absolute.
*
* @param uri The URI to be resolved against this URI
* @return The resulting URI
*
* @throws NullPointerException
* If uri is null
*/
public URI resolve(URI uri) {
return resolve(this, uri);
}
/**
* Constructs a new URI by parsing the given string and then resolving it
* against this URI.
*
* This convenience method works as if invoking it were equivalent to
* evaluating the expression {@link #resolve(java.net.URI)
* resolve}(URI.{@link #create(String) create}(str)).
*
* @param str The string to be parsed into a URI
* @return The resulting URI
*
* @throws NullPointerException
* If str is null
*
* @throws IllegalArgumentException
* If the given string violates RFC 2396
*/
public URI resolve(String str) {
return resolve(URI.create(str));
}
/**
* Relativizes the given URI against this URI.
*
* The relativization of the given URI against this URI is computed as
* follows:
*
*
*
* If either this URI or the given URI are opaque, or if the
* scheme and authority components of the two URIs are not identical, or
* if the path of this URI is not a prefix of the path of the given URI,
* then the given URI is returned.
*
* Otherwise a new relative hierarchical URI is constructed with
* query and fragment components taken from the given URI and with a path
* component computed by removing this URI's path from the beginning of
* the given URI's path.
*
*
*
* @param uri The URI to be relativized against this URI
* @return The resulting URI
*
* @throws NullPointerException
* If uri is null
*/
public URI relativize(URI uri) {
return relativize(this, uri);
}
/**
* Constructs a URL from this URI.
*
* This convenience method works as if invoking it were equivalent to
* evaluating the expression new URL(this.toString()) after
* first checking that this URI is absolute.
*
* @return A URL constructed from this URI
*
* @throws IllegalArgumentException
* If this URL is not absolute
*
* @throws MalformedURLException
* If a protocol handler for the URL could not be found,
* or if some other error occurred while constructing the URL
*/
public URL toURL()
throws MalformedURLException {
if (!isAbsolute())
throw new IllegalArgumentException("URI is not absolute");
return new URL(toString());
}
// -- Component access methods --
/**
* Returns the scheme component of this URI.
*
* The scheme component of a URI, if defined, only contains characters
* in the alphanum category and in the string "-.+". A
* scheme always starts with an alpha character.
*
* The scheme component of a URI cannot contain escaped octets, hence this
* method does not perform any decoding.
*
* @return The scheme component of this URI,
* or null if the scheme is undefined
*/
public String getScheme() {
return scheme;
}
/**
* Tells whether or not this URI is absolute.
*
*
A URI is absolute if, and only if, it has a scheme component.
*
* @return true if, and only if, this URI is absolute
*/
public boolean isAbsolute() {
return scheme != null;
}
/**
* Tells whether or not this URI is opaque.
*
* A URI is opaque if, and only if, it is absolute and its
* scheme-specific part does not begin with a slash character ('/').
* An opaque URI has a scheme, a scheme-specific part, and possibly
* a fragment; all other components are undefined.
*
* @return true if, and only if, this URI is opaque
*/
public boolean isOpaque() {
return path == null;
}
/**
* Returns the raw scheme-specific part of this URI. The scheme-specific
* part is never undefined, though it may be empty.
*
* The scheme-specific part of a URI only contains legal URI
* characters.
*
* @return The raw scheme-specific part of this URI
* (never null)
*/
public String getRawSchemeSpecificPart() {
defineSchemeSpecificPart();
return schemeSpecificPart;
}
/**
* Returns the decoded scheme-specific part of this URI.
*
* The string returned by this method is equal to that returned by the
* {@link #getRawSchemeSpecificPart() getRawSchemeSpecificPart} method
* except that all sequences of escaped octets are decoded.
*
* @return The decoded scheme-specific part of this URI
* (never null)
*/
public String getSchemeSpecificPart() {
if (decodedSchemeSpecificPart == null)
decodedSchemeSpecificPart = decode(getRawSchemeSpecificPart());
return decodedSchemeSpecificPart;
}
/**
* Returns the raw authority component of this URI.
*
* The authority component of a URI, if defined, only contains the
* commercial-at character ('@') and characters in the
* unreserved, punct, escaped, and other
* categories. If the authority is server-based then it is further
* constrained to have valid user-information, host, and port
* components.
*
* @return The raw authority component of this URI,
* or null if the authority is undefined
*/
public String getRawAuthority() {
return authority;
}
/**
* Returns the decoded authority component of this URI.
*
* The string returned by this method is equal to that returned by the
* {@link #getRawAuthority() getRawAuthority} method except that all
* sequences of escaped octets are decoded.
*
* @return The decoded authority component of this URI,
* or null if the authority is undefined
*/
public String getAuthority() {
if (decodedAuthority == null)
decodedAuthority = decode(authority);
return decodedAuthority;
}
/**
* Returns the raw user-information component of this URI.
*
* The user-information component of a URI, if defined, only contains
* characters in the unreserved, punct, escaped, and
* other categories.
*
* @return The raw user-information component of this URI,
* or null if the user information is undefined
*/
public String getRawUserInfo() {
return userInfo;
}
/**
* Returns the decoded user-information component of this URI.
*
* The string returned by this method is equal to that returned by the
* {@link #getRawUserInfo() getRawUserInfo} method except that all
* sequences of escaped octets are decoded.
*
* @return The decoded user-information component of this URI,
* or null if the user information is undefined
*/
public String getUserInfo() {
if ((decodedUserInfo == null) && (userInfo != null))
decodedUserInfo = decode(userInfo);
return decodedUserInfo;
}
/**
* Returns the host component of this URI.
*
* The host component of a URI, if defined, will have one of the
* following forms:
*
*
*
* A domain name consisting of one or more labels
* separated by period characters ('.'), optionally followed by
* a period character. Each label consists of alphanum characters
* as well as hyphen characters ('-'), though hyphens never
* occur as the first or last characters in a label. The rightmost
* label of a domain name consisting of two or more labels, begins
* with an alpha character.
*
* A dotted-quad IPv4 address of the form
* digit+.digit+.digit+.digit+,
* where no digit sequence is longer than three characters and no
* sequence has a value larger than 255.
*
* An IPv6 address enclosed in square brackets ('[' and
* ']') and consisting of hexadecimal digits, colon characters
* (':'), and possibly an embedded IPv4 address. The full
* syntax of IPv6 addresses is specified in RFC 2373: IPv6
* Addressing Architecture.
*
*
*
* The host component of a URI cannot contain escaped octets, hence this
* method does not perform any decoding.
*
* @return The host component of this URI,
* or null if the host is undefined
*/
public String getHost() {
return host;
}
/**
* Returns the port number of this URI.
*
* The port component of a URI, if defined, is a non-negative
* integer.
*
* @return The port component of this URI,
* or -1 if the port is undefined
*/
public int getPort() {
return port;
}
/**
* Returns the raw path component of this URI.
*
* The path component of a URI, if defined, only contains the slash
* character ('/'), the commercial-at character ('@'),
* and characters in the unreserved, punct, escaped,
* and other categories.
*
* @return The path component of this URI,
* or null if the path is undefined
*/
public String getRawPath() {
return path;
}
/**
* Returns the decoded path component of this URI.
*
* The string returned by this method is equal to that returned by the
* {@link #getRawPath() getRawPath} method except that all sequences of
* escaped octets are decoded.
*
* @return The decoded path component of this URI,
* or null if the path is undefined
*/
public String getPath() {
if ((decodedPath == null) && (path != null))
decodedPath = decode(path);
return decodedPath;
}
/**
* Returns the raw query component of this URI.
*
* The query component of a URI, if defined, only contains legal URI
* characters.
*
* @return The raw query component of this URI,
* or null if the query is undefined
*/
public String getRawQuery() {
return query;
}
/**
* Returns the decoded query component of this URI.
*
* The string returned by this method is equal to that returned by the
* {@link #getRawQuery() getRawQuery} method except that all sequences of
* escaped octets are decoded.
*
* @return The decoded query component of this URI,
* or null if the query is undefined
*/
public String getQuery() {
if ((decodedQuery == null) && (query != null))
decodedQuery = decode(query);
return decodedQuery;
}
/**
* Returns the raw fragment component of this URI.
*
* The fragment component of a URI, if defined, only contains legal URI
* characters.
*
* @return The raw fragment component of this URI,
* or null if the fragment is undefined
*/
public String getRawFragment() {
return fragment;
}
/**
* Returns the decoded fragment component of this URI.
*
* The string returned by this method is equal to that returned by the
* {@link #getRawFragment() getRawFragment} method except that all
* sequences of escaped octets are decoded.
*
* @return The decoded fragment component of this URI,
* or null if the fragment is undefined
*/
public String getFragment() {
if ((decodedFragment == null) && (fragment != null))
decodedFragment = decode(fragment);
return decodedFragment;
}
// -- Equality, comparison, hash code, toString, and serialization --
/**
* Tests this URI for equality with another object.
*
* If the given object is not a URI then this method immediately
* returns false.
*
*
For two URIs to be considered equal requires that either both are
* opaque or both are hierarchical. Their schemes must either both be
* undefined or else be equal without regard to case. Their fragments
* must either both be undefined or else be equal.
*
*
For two opaque URIs to be considered equal, their scheme-specific
* parts must be equal.
*
*
For two hierarchical URIs to be considered equal, their paths must
* be equal and their queries must either both be undefined or else be
* equal. Their authorities must either both be undefined, or both be
* registry-based, or both be server-based. If their authorities are
* defined and are registry-based, then they must be equal. If their
* authorities are defined and are server-based, then their hosts must be
* equal without regard to case, their port numbers must be equal, and
* their user-information components must be equal.
*
*
When testing the user-information, path, query, fragment, authority,
* or scheme-specific parts of two URIs for equality, the raw forms rather
* than the encoded forms of these components are compared and the
* hexadecimal digits of escaped octets are compared without regard to
* case.
*
*
This method satisfies the general contract of the {@link
* java.lang.Object#equals(Object) Object.equals} method.
*
* @param ob The object to which this object is to be compared
*
* @return true if, and only if, the given object is a URI that
* is identical to this URI
*/
public boolean equals(Object ob) {
if (ob == this)
return true;
if (!(ob instanceof URI))
return false;
URI that = (URI)ob;
if (this.isOpaque() != that.isOpaque()) return false;
if (!equalIgnoringCase(this.scheme, that.scheme)) return false;
if (!equal(this.fragment, that.fragment)) return false;
// Opaque
if (this.isOpaque())
return equal(this.schemeSpecificPart, that.schemeSpecificPart);
// Hierarchical
if (!equal(this.path, that.path)) return false;
if (!equal(this.query, that.query)) return false;
// Authorities
if (this.authority == that.authority) return true;
if (this.host != null) {
// Server-based
if (!equal(this.userInfo, that.userInfo)) return false;
if (!equalIgnoringCase(this.host, that.host)) return false;
if (this.port != that.port) return false;
} else if (this.authority != null) {
// Registry-based
if (!equal(this.authority, that.authority)) return false;
} else if (this.authority != that.authority) {
return false;
}
return true;
}
/**
* Returns a hash-code value for this URI. The hash code is based upon all
* of the URI's components, and satisfies the general contract of the
* {@link java.lang.Object#hashCode() Object.hashCode} method.
*
* @return A hash-code value for this URI
*/
public int hashCode() {
if (hash != 0)
return hash;
int h = hashIgnoringCase(0, scheme);
h = hash(h, fragment);
if (isOpaque()) {
h = hash(h, schemeSpecificPart);
} else {
h = hash(h, path);
h = hash(h, query);
if (host != null) {
h = hash(h, userInfo);
h = hashIgnoringCase(h, host);
h += 1949 * port;
} else {
h = hash(h, authority);
}
}
hash = h;
return h;
}
/**
* Compares this URI to another object, which must be a URI.
*
* When comparing corresponding components of two URIs, if one
* component is undefined but the other is defined then the first is
* considered to be less than the second. Unless otherwise noted, string
* components are ordered according to their natural, case-sensitive
* ordering as defined by the {@link java.lang.String#compareTo(Object)
* String.compareTo} method. String components that are subject to
* encoding are compared by comparing their raw forms rather than their
* encoded forms.
*
*
The ordering of URIs is defined as follows:
*
*
*
* Two URIs with different schemes are ordered according the
* ordering of their schemes, without regard to case.
*
* A hierarchical URI is considered to be less than an opaque URI
* with an identical scheme.
*
* Two opaque URIs with identical schemes are ordered according
* to the ordering of their scheme-specific parts.
*
* Two opaque URIs with identical schemes and scheme-specific
* parts are ordered according to the ordering of their
* fragments.
*
* Two hierarchical URIs with identical schemes are ordered
* according to the ordering of their authority components:
*
*
*
* If both authority components are server-based then the URIs
* are ordered according to their user-information components; if these
* components are identical then the URIs are ordered according to the
* ordering of their hosts, without regard to case; if the hosts are
* identical then the URIs are ordered according to the ordering of
* their ports.
*
* If one or both authority components are registry-based then
* the URIs are ordered according to the ordering of their authority
* components.
*
*
*
* Finally, two hierarchical URIs with identical schemes and
* authority components are ordered according to the ordering of their
* paths; if their paths are identical then they are ordered according to
* the ordering of their queries; if the queries are identical then they
* are ordered according to the order of their fragments.
*
*
*
* This method satisfies the general contract of the {@link
* java.lang.Comparable#compareTo(Object) Comparable.compareTo}
* method.
*
* @param that
* The object to which this URI is to be compared
*
* @return A negative integer, zero, or a positive integer as this URI is
* less than, equal to, or greater than the given URI
*
* @throws ClassCastException
* If the given object is not a URI
*/
public int compareTo(URI that) {
int c;
if ((c = compareIgnoringCase(this.scheme, that.scheme)) != 0)
return c;
if (this.isOpaque()) {
if (that.isOpaque()) {
// Both opaque
if ((c = compare(this.schemeSpecificPart,
that.schemeSpecificPart)) != 0)
return c;
return compare(this.fragment, that.fragment);
}
return +1; // Opaque > hierarchical
} else if (that.isOpaque()) {
return -1; // Hierarchical < opaque
}
// Hierarchical
if ((this.host != null) && (that.host != null)) {
// Both server-based
if ((c = compare(this.userInfo, that.userInfo)) != 0)
return c;
if ((c = compareIgnoringCase(this.host, that.host)) != 0)
return c;
if ((c = this.port - that.port) != 0)
return c;
} else {
// If one or both authorities are registry-based then we simply
// compare them in the usual, case-sensitive way. If one is
// registry-based and one is server-based then the strings are
// guaranteed to be unequal, hence the comparison will never return
// zero and the compareTo and equals methods will remain
// consistent.
if ((c = compare(this.authority, that.authority)) != 0) return c;
}
if ((c = compare(this.path, that.path)) != 0) return c;
if ((c = compare(this.query, that.query)) != 0) return c;
return compare(this.fragment, that.fragment);
}
/**
* Returns the content of this URI as a string.
*
* If this URI was created by invoking one of the constructors in this
* class then a string equivalent to the original input string, or to the
* string computed from the originally-given components, as appropriate, is
* returned. Otherwise this URI was created by normalization, resolution,
* or relativization, and so a string is constructed from this URI's
* components according to the rules specified in RFC 2396,
* section 5.2, step 7.
*
* @return The string form of this URI
*/
public String toString() {
defineString();
return string;
}
/**
* Returns the content of this URI as a US-ASCII string.
*
* If this URI does not contain any characters in the other
* category then an invocation of this method will return the same value as
* an invocation of the {@link #toString() toString} method. Otherwise
* this method works as if by invoking that method and then encoding the result.
*
* @return The string form of this URI, encoded as needed
* so that it only contains characters in the US-ASCII
* charset
*/
public String toASCIIString() {
defineString();
return encode(string);
}
// -- Serialization support --
/**
* Saves the content of this URI to the given serial stream.
*
* The only serializable field of a URI instance is its string
* field. That field is given a value, if it does not have one already,
* and then the {@link java.io.ObjectOutputStream#defaultWriteObject()}
* method of the given object-output stream is invoked.
*
* @param os The object-output stream to which this object
* is to be written
*/
private void writeObject(ObjectOutputStream os)
throws IOException
{
defineString();
os.defaultWriteObject(); // Writes the string field only
}
/**
* Reconstitutes a URI from the given serial stream.
*
* The {@link java.io.ObjectInputStream#defaultReadObject()} method is
* invoked to read the value of the string field. The result is
* then parsed in the usual way.
*
* @param is The object-input stream from which this object
* is being read
*/
private void readObject(ObjectInputStream is)
throws ClassNotFoundException, IOException
{
port = -1; // Argh
is.defaultReadObject();
try {
new Parser(string).parse(false);
} catch (URISyntaxException x) {
IOException y = new InvalidObjectException("Invalid URI");
y.initCause(x);
throw y;
}
}
// -- End of public methods --
// -- Utility methods for string-field comparison and hashing --
// These methods return appropriate values for null string arguments,
// thereby simplifying the equals, hashCode, and compareTo methods.
//
// The case-ignoring methods should only be applied to strings whose
// characters are all known to be US-ASCII. Because of this restriction,
// these methods are faster than the similar methods in the String class.
// US-ASCII only
private static int toLower(char c) {
if ((c >= 'A') && (c <= 'Z'))
return c + ('a' - 'A');
return c;
}
private static boolean equal(String s, String t) {
if (s == t) return true;
if ((s != null) && (t != null)) {
if (s.length() != t.length())
return false;
if (s.indexOf('%') < 0)
return s.equals(t);
int n = s.length();
for (int i = 0; i < n;) {
char c = s.charAt(i);
char d = t.charAt(i);
if (c != '%') {
if (c != d)
return false;
i++;
continue;
}
i++;
if (toLower(s.charAt(i)) != toLower(t.charAt(i)))
return false;
i++;
if (toLower(s.charAt(i)) != toLower(t.charAt(i)))
return false;
i++;
}
return true;
}
return false;
}
// US-ASCII only
private static boolean equalIgnoringCase(String s, String t) {
if (s == t) return true;
if ((s != null) && (t != null)) {
int n = s.length();
if (t.length() != n)
return false;
for (int i = 0; i < n; i++) {
if (toLower(s.charAt(i)) != toLower(t.charAt(i)))
return false;
}
return true;
}
return false;
}
private static int hash(int hash, String s) {
if (s == null) return hash;
return hash * 127 + s.hashCode();
}
// US-ASCII only
private static int hashIgnoringCase(int hash, String s) {
if (s == null) return hash;
int h = hash;
int n = s.length();
for (int i = 0; i < n; i++)
h = 31 * h + toLower(s.charAt(i));
return h;
}
private static int compare(String s, String t) {
if (s == t) return 0;
if (s != null) {
if (t != null)
return s.compareTo(t);
else
return +1;
} else {
return -1;
}
}
// US-ASCII only
private static int compareIgnoringCase(String s, String t) {
if (s == t) return 0;
if (s != null) {
if (t != null) {
int sn = s.length();
int tn = t.length();
int n = sn < tn ? sn : tn;
for (int i = 0; i < n; i++) {
int c = toLower(s.charAt(i)) - toLower(t.charAt(i));
if (c != 0)
return c;
}
return sn - tn;
}
return +1;
} else {
return -1;
}
}
// -- String construction --
// If a scheme is given then the path, if given, must be absolute
//
private static void checkPath(String s, String scheme, String path)
throws URISyntaxException
{
if (scheme != null) {
if ((path != null)
&& ((path.length() > 0) && (path.charAt(0) != '/')))
throw new URISyntaxException(s,
"Relative path in absolute URI");
}
}
private void appendAuthority(StringBuffer sb,
String authority,
String userInfo,
String host,
int port)
{
if (host != null) {
sb.append("//");
if (userInfo != null) {
sb.append(quote(userInfo, L_USERINFO, H_USERINFO));
sb.append('@');
}
boolean needBrackets = ((host.indexOf(':') >= 0)
&& !host.startsWith("[")
&& !host.endsWith("]"));
if (needBrackets) sb.append('[');
sb.append(host);
if (needBrackets) sb.append(']');
if (port != -1) {
sb.append(':');
sb.append(port);
}
} else if (authority != null) {
sb.append("//");
if (authority.startsWith("[")) {
// authority should (but may not) contain an embedded IPv6 address
int end = authority.indexOf("]");
String doquote = authority, dontquote = "";
if (end != -1 && authority.indexOf(":") != -1) {
// the authority contains an IPv6 address
if (end == authority.length()) {
dontquote = authority;
doquote = "";
} else {
dontquote = authority.substring(0 , end + 1);
doquote = authority.substring(end + 1);
}
}
sb.append(dontquote);
sb.append(quote(doquote,
L_REG_NAME | L_SERVER,
H_REG_NAME | H_SERVER));
} else {
sb.append(quote(authority,
L_REG_NAME | L_SERVER,
H_REG_NAME | H_SERVER));
}
}
}
private void appendSchemeSpecificPart(StringBuffer sb,
String opaquePart,
String authority,
String userInfo,
String host,
int port,
String path,
String query)
{
if (opaquePart != null) {
/* check if SSP begins with an IPv6 address
* because we must not quote a literal IPv6 address
*/
if (opaquePart.startsWith("//[")) {
int end = opaquePart.indexOf("]");
if (end != -1 && opaquePart.indexOf(":")!=-1) {
String doquote, dontquote;
if (end == opaquePart.length()) {
dontquote = opaquePart;
doquote = "";
} else {
dontquote = opaquePart.substring(0,end+1);
doquote = opaquePart.substring(end+1);
}
sb.append (dontquote);
sb.append(quote(doquote, L_URIC, H_URIC));
}
} else {
sb.append(quote(opaquePart, L_URIC, H_URIC));
}
} else {
appendAuthority(sb, authority, userInfo, host, port);
if (path != null)
sb.append(quote(path, L_PATH, H_PATH));
if (query != null) {
sb.append('?');
sb.append(quote(query, L_URIC, H_URIC));
}
}
}
private void appendFragment(StringBuffer sb, String fragment) {
if (fragment != null) {
sb.append('#');
sb.append(quote(fragment, L_URIC, H_URIC));
}
}
private String toString(String scheme,
String opaquePart,
String authority,
String userInfo,
String host,
int port,
String path,
String query,
String fragment)
{
StringBuffer sb = new StringBuffer();
if (scheme != null) {
sb.append(scheme);
sb.append(':');
}
appendSchemeSpecificPart(sb, opaquePart,
authority, userInfo, host, port,
path, query);
appendFragment(sb, fragment);
return sb.toString();
}
private void defineSchemeSpecificPart() {
if (schemeSpecificPart != null) return;
StringBuffer sb = new StringBuffer();
appendSchemeSpecificPart(sb, null, getAuthority(), getUserInfo(),
host, port, getPath(), getQuery());
if (sb.length() == 0) return;
schemeSpecificPart = sb.toString();
}
private void defineString() {
if (string != null) return;
StringBuffer sb = new StringBuffer();
if (scheme != null) {
sb.append(scheme);
sb.append(':');
}
if (isOpaque()) {
sb.append(schemeSpecificPart);
} else {
if (host != null) {
sb.append("//");
if (userInfo != null) {
sb.append(userInfo);
sb.append('@');
}
boolean needBrackets = ((host.indexOf(':') >= 0)
&& !host.startsWith("[")
&& !host.endsWith("]"));
if (needBrackets) sb.append('[');
sb.append(host);
if (needBrackets) sb.append(']');
if (port != -1) {
sb.append(':');
sb.append(port);
}
} else if (authority != null) {
sb.append("//");
sb.append(authority);
}
if (path != null)
sb.append(path);
if (query != null) {
sb.append('?');
sb.append(query);
}
}
if (fragment != null) {
sb.append('#');
sb.append(fragment);
}
string = sb.toString();
}
// -- Normalization, resolution, and relativization --
// RFC2396 5.2 (6)
private static String resolvePath(String base, String child,
boolean absolute)
{
int i = base.lastIndexOf('/');
int cn = child.length();
String path = "";
if (cn == 0) {
// 5.2 (6a)
if (i >= 0)
path = base.substring(0, i + 1);
} else {
StringBuffer sb = new StringBuffer(base.length() + cn);
// 5.2 (6a)
if (i >= 0)
sb.append(base.substring(0, i + 1));
// 5.2 (6b)
sb.append(child);
path = sb.toString();
}
// 5.2 (6c-f)
String np = normalize(path);
// 5.2 (6g): If the result is absolute but the path begins with "../",
// then we simply leave the path as-is
return np;
}
// RFC2396 5.2
private static URI resolve(URI base, URI child) {
// check if child if opaque first so that NPE is thrown
// if child is null.
if (child.isOpaque() || base.isOpaque())
return child;
// 5.2 (2): Reference to current document (lone fragment)
if ((child.scheme == null) && (child.authority == null)
&& child.path.equals("") && (child.fragment != null)
&& (child.query == null)) {
if ((base.fragment != null)
&& child.fragment.equals(base.fragment)) {
return base;
}
URI ru = new URI();
ru.scheme = base.scheme;
ru.authority = base.authority;
ru.userInfo = base.userInfo;
ru.host = base.host;
ru.port = base.port;
ru.path = base.path;
ru.fragment = child.fragment;
ru.query = base.query;
return ru;
}
// 5.2 (3): Child is absolute
if (child.scheme != null)
return child;
URI ru = new URI(); // Resolved URI
ru.scheme = base.scheme;
ru.query = child.query;
ru.fragment = child.fragment;
// 5.2 (4): Authority
if (child.authority == null) {
ru.authority = base.authority;
ru.host = base.host;
ru.userInfo = base.userInfo;
ru.port = base.port;
String cp = (child.path == null) ? "" : child.path;
if ((cp.length() > 0) && (cp.charAt(0) == '/')) {
// 5.2 (5): Child path is absolute
ru.path = child.path;
} else {
// 5.2 (6): Resolve relative path
ru.path = resolvePath(base.path, cp, base.isAbsolute());
}
} else {
ru.authority = child.authority;
ru.host = child.host;
ru.userInfo = child.userInfo;
ru.host = child.host;
ru.port = child.port;
ru.path = child.path;
}
// 5.2 (7): Recombine (nothing to do here)
return ru;
}
// If the given URI's path is normal then return the URI;
// o.w., return a new URI containing the normalized path.
//
private static URI normalize(URI u) {
if (u.isOpaque() || (u.path == null) || (u.path.length() == 0))
return u;
String np = normalize(u.path);
if (np == u.path)
return u;
URI v = new URI();
v.scheme = u.scheme;
v.fragment = u.fragment;
v.authority = u.authority;
v.userInfo = u.userInfo;
v.host = u.host;
v.port = u.port;
v.path = np;
v.query = u.query;
return v;
}
// If both URIs are hierarchical, their scheme and authority components are
// identical, and the base path is a prefix of the child's path, then
// return a relative URI that, when resolved against the base, yields the
// child; otherwise, return the child.
//
private static URI relativize(URI base, URI child) {
// check if child if opaque first so that NPE is thrown
// if child is null.
if (child.isOpaque() || base.isOpaque())
return child;
if (!equalIgnoringCase(base.scheme, child.scheme)
|| !equal(base.authority, child.authority))
return child;
String bp = normalize(base.path);
String cp = normalize(child.path);
if (!bp.equals(cp)) {
if (!bp.endsWith("/"))
bp = bp + "/";
if (!cp.startsWith(bp))
return child;
}
URI v = new URI();
v.path = cp.substring(bp.length());
v.query = child.query;
v.fragment = child.fragment;
return v;
}
// -- Path normalization --
// The following algorithm for path normalization avoids the creation of a
// string object for each segment, as well as the use of a string buffer to
// compute the final result, by using a single char array and editing it in
// place. The array is first split into segments, replacing each slash
// with '\0' and creating a segment-index array, each element of which is
// the index of the first char in the corresponding segment. We then walk
// through both arrays, removing ".", "..", and other segments as necessary
// by setting their entries in the index array to -1. Finally, the two
// arrays are used to rejoin the segments and compute the final result.
//
// This code is based upon src/solaris/native/java/io/canonicalize_md.c
// Check the given path to see if it might need normalization. A path
// might need normalization if it contains duplicate slashes, a "."
// segment, or a ".." segment. Return -1 if no further normalization is
// possible, otherwise return the number of segments found.
//
// This method takes a string argument rather than a char array so that
// this test can be performed without invoking path.toCharArray().
//
static private int needsNormalization(String path) {
boolean normal = true;
int ns = 0; // Number of segments
int end = path.length() - 1; // Index of last char in path
int p = 0; // Index of next char in path
// Skip initial slashes
while (p <= end) {
if (path.charAt(p) != '/') break;
p++;
}
if (p > 1) normal = false;
// Scan segments
while (p <= end) {
// Looking at "." or ".." ?
if ((path.charAt(p) == '.')
&& ((p == end)
|| ((path.charAt(p + 1) == '/')
|| ((path.charAt(p + 1) == '.')
&& ((p + 1 == end)
|| (path.charAt(p + 2) == '/')))))) {
normal = false;
}
ns++;
// Find beginning of next segment
while (p <= end) {
if (path.charAt(p++) != '/')
continue;
// Skip redundant slashes
while (p <= end) {
if (path.charAt(p) != '/') break;
normal = false;
p++;
}
break;
}
}
return normal ? -1 : ns;
}
// Split the given path into segments, replacing slashes with nulls and
// filling in the given segment-index array.
//
// Preconditions:
// segs.length == Number of segments in path
//
// Postconditions:
// All slashes in path replaced by '\0'
// segs[i] == Index of first char in segment i (0 <= i < segs.length)
//
static private void split(char[] path, int[] segs) {
int end = path.length - 1; // Index of last char in path
int p = 0; // Index of next char in path
int i = 0; // Index of current segment
// Skip initial slashes
while (p <= end) {
if (path[p] != '/') break;
path[p] = '\0';
p++;
}
while (p <= end) {
// Note start of segment
segs[i++] = p++;
// Find beginning of next segment
while (p <= end) {
if (path[p++] != '/')
continue;
path[p - 1] = '\0';
// Skip redundant slashes
while (p <= end) {
if (path[p] != '/') break;
path[p++] = '\0';
}
break;
}
}
if (i != segs.length)
throw new InternalError(); // ASSERT
}
// Join the segments in the given path according to the given segment-index
// array, ignoring those segments whose index entries have been set to -1,
// and inserting slashes as needed. Return the length of the resulting
// path.
//
// Preconditions:
// segs[i] == -1 implies segment i is to be ignored
// path computed by split, as above, with '\0' having replaced '/'
//
// Postconditions:
// path[0] .. path[return value] == Resulting path
//
static private int join(char[] path, int[] segs) {
int ns = segs.length; // Number of segments
int end = path.length - 1; // Index of last char in path
int p = 0; // Index of next path char to write
if (path[p] == '\0') {
// Restore initial slash for absolute paths
path[p++] = '/';
}
for (int i = 0; i < ns; i++) {
int q = segs[i]; // Current segment
if (q == -1)
// Ignore this segment
continue;
if (p == q) {
// We're already at this segment, so just skip to its end
while ((p <= end) && (path[p] != '\0'))
p++;
if (p <= end) {
// Preserve trailing slash
path[p++] = '/';
}
} else if (p < q) {
// Copy q down to p
while ((q <= end) && (path[q] != '\0'))
path[p++] = path[q++];
if (q <= end) {
// Preserve trailing slash
path[p++] = '/';
}
} else
throw new InternalError(); // ASSERT false
}
return p;
}
// Remove "." segments from the given path, and remove segment pairs
// consisting of a non-".." segment followed by a ".." segment.
//
private static void removeDots(char[] path, int[] segs) {
int ns = segs.length;
int end = path.length - 1;
for (int i = 0; i < ns; i++) {
int dots = 0; // Number of dots found (0, 1, or 2)
// Find next occurrence of "." or ".."
do {
int p = segs[i];
if (path[p] == '.') {
if (p == end) {
dots = 1;
break;
} else if (path[p + 1] == '\0') {
dots = 1;
break;
} else if ((path[p + 1] == '.')
&& ((p + 1 == end)
|| (path[p + 2] == '\0'))) {
dots = 2;
break;
}
}
i++;
} while (i < ns);
if ((i > ns) || (dots == 0))
break;
if (dots == 1) {
// Remove this occurrence of "."
segs[i] = -1;
} else {
// If there is a preceding non-".." segment, remove both that
// segment and this occurrence of ".."; otherwise, leave this
// ".." segment as-is.
int j;
for (j = i - 1; j >= 0; j--) {
if (segs[j] != -1) break;
}
if (j >= 0) {
int q = segs[j];
if (!((path[q] == '.')
&& (path[q + 1] == '.')
&& (path[q + 2] == '\0'))) {
segs[i] = -1;
segs[j] = -1;
}
}
}
}
}
// DEVIATION: If the normalized path is relative, and if the first
// segment could be parsed as a scheme name, then prepend a "." segment
//
private static void maybeAddLeadingDot(char[] path, int[] segs) {
if (path[0] == '\0')
// The path is absolute
return;
int ns = segs.length;
int f = 0; // Index of first segment
while (f < ns) {
if (segs[f] >= 0)
break;
f++;
}
if ((f >= ns) || (f == 0))
// The path is empty, or else the original first segment survived,
// in which case we already know that no leading "." is needed
return;
int p = segs[f];
while ((p < path.length) && (path[p] != ':') && (path[p] != '\0')) p++;
if (p >= path.length || path[p] == '\0')
// No colon in first segment, so no "." needed
return;
// At this point we know that the first segment is unused,
// hence we can insert a "." segment at that position
path[0] = '.';
path[1] = '\0';
segs[0] = 0;
}
// Normalize the given path string. A normal path string has no empty
// segments (i.e., occurrences of "//"), no segments equal to ".", and no
// segments equal to ".." that are preceded by a segment not equal to "..".
// In contrast to Unix-style pathname normalization, for URI paths we
// always retain trailing slashes.
//
private static String normalize(String ps) {
// Does this path need normalization?
int ns = needsNormalization(ps); // Number of segments
if (ns < 0)
// Nope -- just return it
return ps;
char[] path = ps.toCharArray(); // Path in char-array form
// Split path into segments
int[] segs = new int[ns]; // Segment-index array
split(path, segs);
// Remove dots
removeDots(path, segs);
// Prevent scheme-name confusion
maybeAddLeadingDot(path, segs);
// Join the remaining segments and return the result
String s = new String(path, 0, join(path, segs));
if (s.equals(ps)) {
// string was already normalized
return ps;
}
return s;
}
// -- Character classes for parsing --
// RFC2396 precisely specifies which characters in the US-ASCII charset are
// permissible in the various components of a URI reference. We here
// define a set of mask pairs to aid in enforcing these restrictions. Each
// mask pair consists of two longs, a low mask and a high mask. Taken
// together they represent a 128-bit mask, where bit i is set iff the
// character with value i is permitted.
//
// This approach is more efficient than sequentially searching arrays of
// permitted characters. It could be made still more efficient by
// precompiling the mask information so that a character's presence in a
// given mask could be determined by a single table lookup.
// Compute the low-order mask for the characters in the given string
private static long lowMask(String chars) {
int n = chars.length();
long m = 0;
for (int i = 0; i < n; i++) {
char c = chars.charAt(i);
if (c < 64)
m |= (1L << c);
}
return m;
}
// Compute the high-order mask for the characters in the given string
private static long highMask(String chars) {
int n = chars.length();
long m = 0;
for (int i = 0; i < n; i++) {
char c = chars.charAt(i);
if ((c >= 64) && (c < 128))
m |= (1L << (c - 64));
}
return m;
}
// Compute a low-order mask for the characters
// between first and last, inclusive
private static long lowMask(char first, char last) {
long m = 0;
int f = Math.max(Math.min(first, 63), 0);
int l = Math.max(Math.min(last, 63), 0);
for (int i = f; i <= l; i++)
m |= 1L << i;
return m;
}
// Compute a high-order mask for the characters
// between first and last, inclusive
private static long highMask(char first, char last) {
long m = 0;
int f = Math.max(Math.min(first, 127), 64) - 64;
int l = Math.max(Math.min(last, 127), 64) - 64;
for (int i = f; i <= l; i++)
m |= 1L << i;
return m;
}
// Tell whether the given character is permitted by the given mask pair
private static boolean match(char c, long lowMask, long highMask) {
if (c == 0) // 0 doesn't have a slot in the mask. So, it never matches.
return false;
if (c < 64)
return ((1L << c) & lowMask) != 0;
if (c < 128)
return ((1L << (c - 64)) & highMask) != 0;
return false;
}
// Character-class masks, in reverse order from RFC2396 because
// initializers for static fields cannot make forward references.
// digit = "0" | "1" | "2" | "3" | "4" | "5" | "6" | "7" |
// "8" | "9"
private static final long L_DIGIT = lowMask('0', '9');
private static final long H_DIGIT = 0L;
// upalpha = "A" | "B" | "C" | "D" | "E" | "F" | "G" | "H" | "I" |
// "J" | "K" | "L" | "M" | "N" | "O" | "P" | "Q" | "R" |
// "S" | "T" | "U" | "V" | "W" | "X" | "Y" | "Z"
private static final long L_UPALPHA = 0L;
private static final long H_UPALPHA = highMask('A', 'Z');
// lowalpha = "a" | "b" | "c" | "d" | "e" | "f" | "g" | "h" | "i" |
// "j" | "k" | "l" | "m" | "n" | "o" | "p" | "q" | "r" |
// "s" | "t" | "u" | "v" | "w" | "x" | "y" | "z"
private static final long L_LOWALPHA = 0L;
private static final long H_LOWALPHA = highMask('a', 'z');
// alpha = lowalpha | upalpha
private static final long L_ALPHA = L_LOWALPHA | L_UPALPHA;
private static final long H_ALPHA = H_LOWALPHA | H_UPALPHA;
// alphanum = alpha | digit
private static final long L_ALPHANUM = L_DIGIT | L_ALPHA;
private static final long H_ALPHANUM = H_DIGIT | H_ALPHA;
// hex = digit | "A" | "B" | "C" | "D" | "E" | "F" |
// "a" | "b" | "c" | "d" | "e" | "f"
private static final long L_HEX = L_DIGIT;
private static final long H_HEX = highMask('A', 'F') | highMask('a', 'f');
// mark = "-" | "_" | "." | "!" | "~" | "*" | "'" |
// "(" | ")"
private static final long L_MARK = lowMask("-_.!~*'()");
private static final long H_MARK = highMask("-_.!~*'()");
// unreserved = alphanum | mark
private static final long L_UNRESERVED = L_ALPHANUM | L_MARK;
private static final long H_UNRESERVED = H_ALPHANUM | H_MARK;
// reserved = ";" | "/" | "?" | ":" | "@" | "&" | "=" | "+" |
// "$" | "," | "[" | "]"
// Added per RFC2732: "[", "]"
private static final long L_RESERVED = lowMask(";/?:@&=+$,[]");
private static final long H_RESERVED = highMask(";/?:@&=+$,[]");
// The zero'th bit is used to indicate that escape pairs and non-US-ASCII
// characters are allowed; this is handled by the scanEscape method below.
private static final long L_ESCAPED = 1L;
private static final long H_ESCAPED = 0L;
// uric = reserved | unreserved | escaped
private static final long L_URIC = L_RESERVED | L_UNRESERVED | L_ESCAPED;
private static final long H_URIC = H_RESERVED | H_UNRESERVED | H_ESCAPED;
// pchar = unreserved | escaped |
// ":" | "@" | "&" | "=" | "+" | "$" | ","
private static final long L_PCHAR
= L_UNRESERVED | L_ESCAPED | lowMask(":@&=+$,");
private static final long H_PCHAR
= H_UNRESERVED | H_ESCAPED | highMask(":@&=+$,");
// All valid path characters
private static final long L_PATH = L_PCHAR | lowMask(";/");
private static final long H_PATH = H_PCHAR | highMask(";/");
// Dash, for use in domainlabel and toplabel
private static final long L_DASH = lowMask("-");
private static final long H_DASH = highMask("-");
// Dot, for use in hostnames
private static final long L_DOT = lowMask(".");
private static final long H_DOT = highMask(".");
// userinfo = *( unreserved | escaped |
// ";" | ":" | "&" | "=" | "+" | "$" | "," )
private static final long L_USERINFO
= L_UNRESERVED | L_ESCAPED | lowMask(";:&=+$,");
private static final long H_USERINFO
= H_UNRESERVED | H_ESCAPED | highMask(";:&=+$,");
// reg_name = 1*( unreserved | escaped | "$" | "," |
// ";" | ":" | "@" | "&" | "=" | "+" )
private static final long L_REG_NAME
= L_UNRESERVED | L_ESCAPED | lowMask("$,;:@&=+");
private static final long H_REG_NAME
= H_UNRESERVED | H_ESCAPED | highMask("$,;:@&=+");
// All valid characters for server-based authorities
private static final long L_SERVER
= L_USERINFO | L_ALPHANUM | L_DASH | lowMask(".:@[]");
private static final long H_SERVER
= H_USERINFO | H_ALPHANUM | H_DASH | highMask(".:@[]");
// Special case of server authority that represents an IPv6 address
// In this case, a % does not signify an escape sequence
private static final long L_SERVER_PERCENT
= L_SERVER | lowMask("%");
private static final long H_SERVER_PERCENT
= H_SERVER | highMask("%");
private static final long L_LEFT_BRACKET = lowMask("[");
private static final long H_LEFT_BRACKET = highMask("[");
// scheme = alpha *( alpha | digit | "+" | "-" | "." )
private static final long L_SCHEME = L_ALPHA | L_DIGIT | lowMask("+-.");
private static final long H_SCHEME = H_ALPHA | H_DIGIT | highMask("+-.");
// uric_no_slash = unreserved | escaped | ";" | "?" | ":" | "@" |
// "&" | "=" | "+" | "$" | ","
private static final long L_URIC_NO_SLASH
= L_UNRESERVED | L_ESCAPED | lowMask(";?:@&=+$,");
private static final long H_URIC_NO_SLASH
= H_UNRESERVED | H_ESCAPED | highMask(";?:@&=+$,");
// -- Escaping and encoding --
private final static char[] hexDigits = {
'0', '1', '2', '3', '4', '5', '6', '7',
'8', '9', 'A', 'B', 'C', 'D', 'E', 'F'
};
private static void appendEscape(StringBuffer sb, byte b) {
sb.append('%');
sb.append(hexDigits[(b >> 4) & 0x0f]);
sb.append(hexDigits[(b >> 0) & 0x0f]);
}
private static void appendEncoded(StringBuffer sb, char c) {
/*
ByteBuffer bb = null;
try {
bb = ThreadLocalCoders.encoderFor("UTF-8")
.encode(CharBuffer.wrap("" + c));
} catch (CharacterCodingException x) {
assert false;
}
while (bb.hasRemaining()) {
int b = bb.get() & 0xff;
if (b >= 0x80)
appendEscape(sb, (byte)b);
else
sb.append((char)b);
}
*/
}
// Quote any characters in s that are not permitted
// by the given mask pair
//
private static String quote(String s, long lowMask, long highMask) {
int n = s.length();
StringBuffer sb = null;
boolean allowNonASCII = ((lowMask & L_ESCAPED) != 0);
for (int i = 0; i < s.length(); i++) {
char c = s.charAt(i);
if (c < '\u0080') {
if (!match(c, lowMask, highMask)) {
if (sb == null) {
sb = new StringBuffer();
sb.append(s.substring(0, i));
}
appendEscape(sb, (byte)c);
} else {
if (sb != null)
sb.append(c);
}
} else if (allowNonASCII
&& (Character.isSpaceChar(c)
|| Character.isISOControl(c))) {
if (sb == null) {
sb = new StringBuffer();
sb.append(s.substring(0, i));
}
appendEncoded(sb, c);
} else {
if (sb != null)
sb.append(c);
}
}
return (sb == null) ? s : sb.toString();
}
// Encodes all characters >= \u0080 into escaped, normalized UTF-8 octets,
// assuming that s is otherwise legal
//
private static String encode(String s) {
int n = s.length();
if (n == 0)
return s;
// First check whether we actually need to encode
for (int i = 0;;) {
if (s.charAt(i) >= '\u0080')
break;
if (++i >= n)
return s;
}
/*
String ns = Normalizer.normalize(s, Normalizer.Form.NFC);
ByteBuffer bb = null;
try {
bb = ThreadLocalCoders.encoderFor("UTF-8")
.encode(CharBuffer.wrap(ns));
} catch (CharacterCodingException x) {
assert false;
}
*/
StringBuffer sb = new StringBuffer();
/*
while (bb.hasRemaining()) {
int b = bb.get() & 0xff;
if (b >= 0x80)
appendEscape(sb, (byte)b);
else
sb.append((char)b);
}
*/
return sb.toString();
}
private static int decode(char c) {
if ((c >= '0') && (c <= '9'))
return c - '0';
if ((c >= 'a') && (c <= 'f'))
return c - 'a' + 10;
if ((c >= 'A') && (c <= 'F'))
return c - 'A' + 10;
assert false;
return -1;
}
private static byte decode(char c1, char c2) {
return (byte)( ((decode(c1) & 0xf) << 4)
| ((decode(c2) & 0xf) << 0));
}
// Evaluates all escapes in s, applying UTF-8 decoding if needed. Assumes
// that escapes are well-formed syntactically, i.e., of the form %XX. If a
// sequence of escaped octets is not valid UTF-8 then the erroneous octets
// are replaced with '\uFFFD'.
// Exception: any "%" found between "[]" is left alone. It is an IPv6 literal
// with a scope_id
//
private static String decode(String s) {
if (s == null)
return s;
int n = s.length();
if (n == 0)
return s;
if (s.indexOf('%') < 0)
return s;
StringBuffer sb = new StringBuffer(n);
/*
ByteBuffer bb = ByteBuffer.allocate(n);
CharBuffer cb = CharBuffer.allocate(n);
CharsetDecoder dec = ThreadLocalCoders.decoderFor("UTF-8")
.onMalformedInput(CodingErrorAction.REPLACE)
.onUnmappableCharacter(CodingErrorAction.REPLACE);
// This is not horribly efficient, but it will do for now
char c = s.charAt(0);
boolean betweenBrackets = false;
for (int i = 0; i < n;) {
assert c == s.charAt(i); // Loop invariant
if (c == '[') {
betweenBrackets = true;
} else if (betweenBrackets && c == ']') {
betweenBrackets = false;
}
if (c != '%' || betweenBrackets) {
sb.append(c);
if (++i >= n)
break;
c = s.charAt(i);
continue;
}
bb.clear();
int ui = i;
for (;;) {
assert (n - i >= 2);
bb.put(decode(s.charAt(++i), s.charAt(++i)));
if (++i >= n)
break;
c = s.charAt(i);
if (c != '%')
break;
}
bb.flip();
cb.clear();
dec.reset();
CoderResult cr = dec.decode(bb, cb, true);
assert cr.isUnderflow();
cr = dec.flush(cb);
assert cr.isUnderflow();
sb.append(cb.flip().toString());
}
*/
return sb.toString();
}
// -- Parsing --
// For convenience we wrap the input URI string in a new instance of the
// following internal class. This saves always having to pass the input
// string as an argument to each internal scan/parse method.
private class Parser {
private String input; // URI input string
private boolean requireServerAuthority = false;
Parser(String s) {
input = s;
string = s;
}
// -- Methods for throwing URISyntaxException in various ways --
private void fail(String reason) throws URISyntaxException {
throw new URISyntaxException(input, reason);
}
private void fail(String reason, int p) throws URISyntaxException {
throw new URISyntaxException(input, reason, p);
}
private void failExpecting(String expected, int p)
throws URISyntaxException
{
fail("Expected " + expected, p);
}
private void failExpecting(String expected, String prior, int p)
throws URISyntaxException
{
fail("Expected " + expected + " following " + prior, p);
}
// -- Simple access to the input string --
// Return a substring of the input string
//
private String substring(int start, int end) {
return input.substring(start, end);
}
// Return the char at position p,
// assuming that p < input.length()
//
private char charAt(int p) {
return input.charAt(p);
}
// Tells whether start < end and, if so, whether charAt(start) == c
//
private boolean at(int start, int end, char c) {
return (start < end) && (charAt(start) == c);
}
// Tells whether start + s.length() < end and, if so,
// whether the chars at the start position match s exactly
//
private boolean at(int start, int end, String s) {
int p = start;
int sn = s.length();
if (sn > end - p)
return false;
int i = 0;
while (i < sn) {
if (charAt(p++) != s.charAt(i)) {
break;
}
i++;
}
return (i == sn);
}
// -- Scanning --
// The various scan and parse methods that follow use a uniform
// convention of taking the current start position and end index as
// their first two arguments. The start is inclusive while the end is
// exclusive, just as in the String class, i.e., a start/end pair
// denotes the left-open interval [start, end) of the input string.
//
// These methods never proceed past the end position. They may return
// -1 to indicate outright failure, but more often they simply return
// the position of the first char after the last char scanned. Thus
// a typical idiom is
//
// int p = start;
// int q = scan(p, end, ...);
// if (q > p)
// // We scanned something
// ...;
// else if (q == p)
// // We scanned nothing
// ...;
// else if (q == -1)
// // Something went wrong
// ...;
// Scan a specific char: If the char at the given start position is
// equal to c, return the index of the next char; otherwise, return the
// start position.
//
private int scan(int start, int end, char c) {
if ((start < end) && (charAt(start) == c))
return start + 1;
return start;
}
// Scan forward from the given start position. Stop at the first char
// in the err string (in which case -1 is returned), or the first char
// in the stop string (in which case the index of the preceding char is
// returned), or the end of the input string (in which case the length
// of the input string is returned). May return the start position if
// nothing matches.
//
private int scan(int start, int end, String err, String stop) {
int p = start;
while (p < end) {
char c = charAt(p);
if (err.indexOf(c) >= 0)
return -1;
if (stop.indexOf(c) >= 0)
break;
p++;
}
return p;
}
// Scan a potential escape sequence, starting at the given position,
// with the given first char (i.e., charAt(start) == c).
//
// This method assumes that if escapes are allowed then visible
// non-US-ASCII chars are also allowed.
//
private int scanEscape(int start, int n, char first)
throws URISyntaxException
{
int p = start;
char c = first;
if (c == '%') {
// Process escape pair
if ((p + 3 <= n)
&& match(charAt(p + 1), L_HEX, H_HEX)
&& match(charAt(p + 2), L_HEX, H_HEX)) {
return p + 3;
}
fail("Malformed escape pair", p);
} else if ((c > 128)
&& !Character.isSpaceChar(c)
&& !Character.isISOControl(c)) {
// Allow unescaped but visible non-US-ASCII chars
return p + 1;
}
return p;
}
// Scan chars that match the given mask pair
//
private int scan(int start, int n, long lowMask, long highMask)
throws URISyntaxException
{
int p = start;
while (p < n) {
char c = charAt(p);
if (match(c, lowMask, highMask)) {
p++;
continue;
}
if ((lowMask & L_ESCAPED) != 0) {
int q = scanEscape(p, n, c);
if (q > p) {
p = q;
continue;
}
}
break;
}
return p;
}
// Check that each of the chars in [start, end) matches the given mask
//
private void checkChars(int start, int end,
long lowMask, long highMask,
String what)
throws URISyntaxException
{
int p = scan(start, end, lowMask, highMask);
if (p < end)
fail("Illegal character in " + what, p);
}
// Check that the char at position p matches the given mask
//
private void checkChar(int p,
long lowMask, long highMask,
String what)
throws URISyntaxException
{
checkChars(p, p + 1, lowMask, highMask, what);
}
// -- Parsing --
// [:][#]
//
void parse(boolean rsa) throws URISyntaxException {
requireServerAuthority = rsa;
int ssp; // Start of scheme-specific part
int n = input.length();
int p = scan(0, n, "/?#", ":");
if ((p >= 0) && at(p, n, ':')) {
if (p == 0)
failExpecting("scheme name", 0);
checkChar(0, L_ALPHA, H_ALPHA, "scheme name");
checkChars(1, p, L_SCHEME, H_SCHEME, "scheme name");
scheme = substring(0, p);
p++; // Skip ':'
ssp = p;
if (at(p, n, '/')) {
p = parseHierarchical(p, n);
} else {
int q = scan(p, n, "", "#");
if (q <= p)
failExpecting("scheme-specific part", p);
checkChars(p, q, L_URIC, H_URIC, "opaque part");
p = q;
}
} else {
ssp = 0;
p = parseHierarchical(0, n);
}
schemeSpecificPart = substring(ssp, p);
if (at(p, n, '#')) {
checkChars(p + 1, n, L_URIC, H_URIC, "fragment");
fragment = substring(p + 1, n);
p = n;
}
if (p < n)
fail("end of URI", p);
}
// [//authority][?]
//
// DEVIATION from RFC2396: We allow an empty authority component as
// long as it's followed by a non-empty path, query component, or
// fragment component. This is so that URIs such as "file:///foo/bar"
// will parse. This seems to be the intent of RFC2396, though the
// grammar does not permit it. If the authority is empty then the
// userInfo, host, and port components are undefined.
//
// DEVIATION from RFC2396: We allow empty relative paths. This seems
// to be the intent of RFC2396, but the grammar does not permit it.
// The primary consequence of this deviation is that "#f" parses as a
// relative URI with an empty path.
//
private int parseHierarchical(int start, int n)
throws URISyntaxException
{
int p = start;
if (at(p, n, '/') && at(p + 1, n, '/')) {
p += 2;
int q = scan(p, n, "", "/?#");
if (q > p) {
p = parseAuthority(p, q);
} else if (q < n) {
// DEVIATION: Allow empty authority prior to non-empty
// path, query component or fragment identifier
} else
failExpecting("authority", p);
}
int q = scan(p, n, "", "?#"); // DEVIATION: May be empty
checkChars(p, q, L_PATH, H_PATH, "path");
path = substring(p, q);
p = q;
if (at(p, n, '?')) {
p++;
q = scan(p, n, "", "#");
checkChars(p, q, L_URIC, H_URIC, "query");
query = substring(p, q);
p = q;
}
return p;
}
// authority = server | reg_name
//
// Ambiguity: An authority that is a registry name rather than a server
// might have a prefix that parses as a server. We use the fact that
// the authority component is always followed by '/' or the end of the
// input string to resolve this: If the complete authority did not
// parse as a server then we try to parse it as a registry name.
//
private int parseAuthority(int start, int n)
throws URISyntaxException
{
int p = start;
int q = p;
URISyntaxException ex = null;
boolean serverChars;
boolean regChars;
if (scan(p, n, "", "]") > p) {
// contains a literal IPv6 address, therefore % is allowed
serverChars = (scan(p, n, L_SERVER_PERCENT, H_SERVER_PERCENT) == n);
} else {
serverChars = (scan(p, n, L_SERVER, H_SERVER) == n);
}
regChars = (scan(p, n, L_REG_NAME, H_REG_NAME) == n);
if (regChars && !serverChars) {
// Must be a registry-based authority
authority = substring(p, n);
return n;
}
if (serverChars) {
// Might be (probably is) a server-based authority, so attempt
// to parse it as such. If the attempt fails, try to treat it
// as a registry-based authority.
try {
q = parseServer(p, n);
if (q < n)
failExpecting("end of authority", q);
authority = substring(p, n);
} catch (URISyntaxException x) {
// Undo results of failed parse
userInfo = null;
host = null;
port = -1;
if (requireServerAuthority) {
// If we're insisting upon a server-based authority,
// then just re-throw the exception
throw x;
} else {
// Save the exception in case it doesn't parse as a
// registry either
ex = x;
q = p;
}
}
}
if (q < n) {
if (regChars) {
// Registry-based authority
authority = substring(p, n);
} else if (ex != null) {
// Re-throw exception; it was probably due to
// a malformed IPv6 address
throw ex;
} else {
fail("Illegal character in authority", q);
}
}
return n;
}
// [@][:]
//
private int parseServer(int start, int n)
throws URISyntaxException
{
int p = start;
int q;
// userinfo
q = scan(p, n, "/?#", "@");
if ((q >= p) && at(q, n, '@')) {
checkChars(p, q, L_USERINFO, H_USERINFO, "user info");
userInfo = substring(p, q);
p = q + 1; // Skip '@'
}
// hostname, IPv4 address, or IPv6 address
if (at(p, n, '[')) {
// DEVIATION from RFC2396: Support IPv6 addresses, per RFC2732
p++;
q = scan(p, n, "/?#", "]");
if ((q > p) && at(q, n, ']')) {
// look for a "%" scope id
int r = scan (p, q, "", "%");
if (r > p) {
parseIPv6Reference(p, r);
if (r+1 == q) {
fail ("scope id expected");
}
checkChars (r+1, q, L_ALPHANUM, H_ALPHANUM,
"scope id");
} else {
parseIPv6Reference(p, q);
}
host = substring(p-1, q+1);
p = q + 1;
} else {
failExpecting("closing bracket for IPv6 address", q);
}
} else {
q = parseIPv4Address(p, n);
if (q <= p)
q = parseHostname(p, n);
p = q;
}
// port
if (at(p, n, ':')) {
p++;
q = scan(p, n, "", "/");
if (q > p) {
checkChars(p, q, L_DIGIT, H_DIGIT, "port number");
try {
port = Integer.parseInt(substring(p, q));
} catch (NumberFormatException x) {
fail("Malformed port number", p);
}
p = q;
}
}
if (p < n)
failExpecting("port number", p);
return p;
}
// Scan a string of decimal digits whose value fits in a byte
//
private int scanByte(int start, int n)
throws URISyntaxException
{
int p = start;
int q = scan(p, n, L_DIGIT, H_DIGIT);
if (q <= p) return q;
if (Integer.parseInt(substring(p, q)) > 255) return p;
return q;
}
// Scan an IPv4 address.
//
// If the strict argument is true then we require that the given
// interval contain nothing besides an IPv4 address; if it is false
// then we only require that it start with an IPv4 address.
//
// If the interval does not contain or start with (depending upon the
// strict argument) a legal IPv4 address characters then we return -1
// immediately; otherwise we insist that these characters parse as a
// legal IPv4 address and throw an exception on failure.
//
// We assume that any string of decimal digits and dots must be an IPv4
// address. It won't parse as a hostname anyway, so making that
// assumption here allows more meaningful exceptions to be thrown.
//
private int scanIPv4Address(int start, int n, boolean strict)
throws URISyntaxException
{
int p = start;
int q;
int m = scan(p, n, L_DIGIT | L_DOT, H_DIGIT | H_DOT);
if ((m <= p) || (strict && (m != n)))
return -1;
for (;;) {
// Per RFC2732: At most three digits per byte
// Further constraint: Each element fits in a byte
if ((q = scanByte(p, m)) <= p) break; p = q;
if ((q = scan(p, m, '.')) <= p) break; p = q;
if ((q = scanByte(p, m)) <= p) break; p = q;
if ((q = scan(p, m, '.')) <= p) break; p = q;
if ((q = scanByte(p, m)) <= p) break; p = q;
if ((q = scan(p, m, '.')) <= p) break; p = q;
if ((q = scanByte(p, m)) <= p) break; p = q;
if (q < m) break;
return q;
}
fail("Malformed IPv4 address", q);
return -1;
}
// Take an IPv4 address: Throw an exception if the given interval
// contains anything except an IPv4 address
//
private int takeIPv4Address(int start, int n, String expected)
throws URISyntaxException
{
int p = scanIPv4Address(start, n, true);
if (p <= start)
failExpecting(expected, start);
return p;
}
// Attempt to parse an IPv4 address, returning -1 on failure but
// allowing the given interval to contain [:] after
// the IPv4 address.
//
private int parseIPv4Address(int start, int n) {
int p;
try {
p = scanIPv4Address(start, n, false);
} catch (URISyntaxException x) {
return -1;
} catch (NumberFormatException nfe) {
return -1;
}
if (p > start && p < n) {
// IPv4 address is followed by something - check that
// it's a ":" as this is the only valid character to
// follow an address.
if (charAt(p) != ':') {
p = -1;
}
}
if (p > start)
host = substring(start, p);
return p;
}
// hostname = domainlabel [ "." ] | 1*( domainlabel "." ) toplabel [ "." ]
// domainlabel = alphanum | alphanum *( alphanum | "-" ) alphanum
// toplabel = alpha | alpha *( alphanum | "-" ) alphanum
//
private int parseHostname(int start, int n)
throws URISyntaxException
{
int p = start;
int q;
int l = -1; // Start of last parsed label
do {
// domainlabel = alphanum [ *( alphanum | "-" ) alphanum ]
q = scan(p, n, L_ALPHANUM, H_ALPHANUM);
if (q <= p)
break;
l = p;
if (q > p) {
p = q;
q = scan(p, n, L_ALPHANUM | L_DASH, H_ALPHANUM | H_DASH);
if (q > p) {
if (charAt(q - 1) == '-')
fail("Illegal character in hostname", q - 1);
p = q;
}
}
q = scan(p, n, '.');
if (q <= p)
break;
p = q;
} while (p < n);
if ((p < n) && !at(p, n, ':'))
fail("Illegal character in hostname", p);
if (l < 0)
failExpecting("hostname", start);
// for a fully qualified hostname check that the rightmost
// label starts with an alpha character.
if (l > start && !match(charAt(l), L_ALPHA, H_ALPHA)) {
fail("Illegal character in hostname", l);
}
host = substring(start, p);
return p;
}
// IPv6 address parsing, from RFC2373: IPv6 Addressing Architecture
//
// Bug: The grammar in RFC2373 Appendix B does not allow addresses of
// the form ::12.34.56.78, which are clearly shown in the examples
// earlier in the document. Here is the original grammar:
//
// IPv6address = hexpart [ ":" IPv4address ]
// hexpart = hexseq | hexseq "::" [ hexseq ] | "::" [ hexseq ]
// hexseq = hex4 *( ":" hex4)
// hex4 = 1*4HEXDIG
//
// We therefore use the following revised grammar:
//
// IPv6address = hexseq [ ":" IPv4address ]
// | hexseq [ "::" [ hexpost ] ]
// | "::" [ hexpost ]
// hexpost = hexseq | hexseq ":" IPv4address | IPv4address
// hexseq = hex4 *( ":" hex4)
// hex4 = 1*4HEXDIG
//
// This covers all and only the following cases:
//
// hexseq
// hexseq : IPv4address
// hexseq ::
// hexseq :: hexseq
// hexseq :: hexseq : IPv4address
// hexseq :: IPv4address
// :: hexseq
// :: hexseq : IPv4address
// :: IPv4address
// ::
//
// Additionally we constrain the IPv6 address as follows :-
//
// i. IPv6 addresses without compressed zeros should contain
// exactly 16 bytes.
//
// ii. IPv6 addresses with compressed zeros should contain
// less than 16 bytes.
private int ipv6byteCount = 0;
private int parseIPv6Reference(int start, int n)
throws URISyntaxException
{
int p = start;
int q;
boolean compressedZeros = false;
q = scanHexSeq(p, n);
if (q > p) {
p = q;
if (at(p, n, "::")) {
compressedZeros = true;
p = scanHexPost(p + 2, n);
} else if (at(p, n, ':')) {
p = takeIPv4Address(p + 1, n, "IPv4 address");
ipv6byteCount += 4;
}
} else if (at(p, n, "::")) {
compressedZeros = true;
p = scanHexPost(p + 2, n);
}
if (p < n)
fail("Malformed IPv6 address", start);
if (ipv6byteCount > 16)
fail("IPv6 address too long", start);
if (!compressedZeros && ipv6byteCount < 16)
fail("IPv6 address too short", start);
if (compressedZeros && ipv6byteCount == 16)
fail("Malformed IPv6 address", start);
return p;
}
private int scanHexPost(int start, int n)
throws URISyntaxException
{
int p = start;
int q;
if (p == n)
return p;
q = scanHexSeq(p, n);
if (q > p) {
p = q;
if (at(p, n, ':')) {
p++;
p = takeIPv4Address(p, n, "hex digits or IPv4 address");
ipv6byteCount += 4;
}
} else {
p = takeIPv4Address(p, n, "hex digits or IPv4 address");
ipv6byteCount += 4;
}
return p;
}
// Scan a hex sequence; return -1 if one could not be scanned
//
private int scanHexSeq(int start, int n)
throws URISyntaxException
{
int p = start;
int q;
q = scan(p, n, L_HEX, H_HEX);
if (q <= p)
return -1;
if (at(q, n, '.')) // Beginning of IPv4 address
return -1;
if (q > p + 4)
fail("IPv6 hexadecimal digit sequence too long", p);
ipv6byteCount += 2;
p = q;
while (p < n) {
if (!at(p, n, ':'))
break;
if (at(p + 1, n, ':'))
break; // "::"
p++;
q = scan(p, n, L_HEX, H_HEX);
if (q <= p)
failExpecting("digits for an IPv6 address", p);
if (at(q, n, '.')) { // Beginning of IPv4 address
p--;
break;
}
if (q > p + 4)
fail("IPv6 hexadecimal digit sequence too long", p);
ipv6byteCount += 2;
p = q;
}
return p;
}
}
}