A permission represents access to a system resource. In order for a resource access to be allowed for an applet (or an application running with a security manager), the corresponding permission must be explicitly granted to the code attempting the access.
A permission typically has a name (often referred to as a
"target name") and, in some cases, a comma-separated list of one or
more actions. For example, the following code creates a
FilePermission object representing read access to the file named
abc
in the /tmp
directory:
perm = new java.io.FilePermission("/tmp/abc", "read");
In this, the target name is "/tmp/abc
" and the
action string is "read
".
Important Note: The above statement creates a permission object. A permission object represents, but does not grant access to, a system resource. Permission objects are constructed and assigned ("granted") to code based on the policy in effect. When a permission object is assigned to some code, that code is granted the permission to access the system resource specified in the permission object, in the specified manner. A permission object may also be constructed by the current security manager when making access decisions. In this case, the (target) permission object is created based on the requested access, and checked against the permission objects granted to and held by the code making the request.
The policy for a Java application environment is represented by
a Policy object. In the "JavaPolicy"
Policy
implementation, the policy can be specified within one or more
policy configuration files. The policy file(s) specify what
permissions are allowed for code from specified code sources. A
sample policy file entry that grants code from the
/home/sysadmin
directory read access to the file
/tmp/abc
is
grant codeBase "file:/home/sysadmin/" { permission java.io.FilePermission "/tmp/abc", "read"; };
For information about policy file locations and granting permissions in policy files, see Default Policy Implementation and Policy File Syntax. For information about using the Policy Tool to specify the permissions, see the Policy Tool documentation (for Solaris, Linux, or Mac OS X) (for Windows). Using the Policy Tool saves typing and eliminates the need for you to know the required syntax of policy files.
Technically, whenever a resource access is attempted, all code traversed by the execution thread up to that point must have permission for that resource access, unless some code on the thread has been marked as "privileged." See API for Privileged Blocks for more information about "privileged" code.
This document contains tables that describe the built-in JDK permission types and discuss the risks of granting each permission. It also contains tables showing the methods that require permissions to be in effect in order to be successful, and for each lists the required permission.
The following topics are covered:
java.awt.AWTPermission
java.io.FilePermission
java.io.SerializablePermission
java.lang.management.ManagementPermission
java.lang.reflect.ReflectPermission
java.lang.RuntimePermission
java.net.NetPermission
java.net.SocketPermission
java.net.URLPermission
java.nio.file.LinkPermission
java.security.AllPermission
java.security.SecurityPermission
java.security.UnresolvedPermission
java.sql.SQLPermission
java.util.logging.LoggingPermission
java.util.PropertyPermission
javax.management.MBeanPermission
javax.management.MBeanServerPermission
javax.management.MBeanTrustPermission
javax.management.remote.SubjectDelegationPermission
javax.net.ssl.SSLPermission
javax.security.auth.AuthPermission
javax.security.auth.kerberos.DelegationPermission
javax.security.auth.kerberos.ServicePermission
javax.security.auth.PrivateCredentialPermission
javax.sound.sampled.AudioPermission
javax.xml.bind.JAXBPermission
javax.xml.ws.WebServicePermission
For more information about permissions, including the
superclasses java.security.Permission
and
java.security.BasicPermission
, and examples of
creating permission objects and granting permissions, see the
Security Architecture
Specification.
The following tables describe the built-in JDK permission types and discuss the risks of granting each permission.
AWTPermission
A java.awt.AWTPermission
is for AWT permissions.
The following table lists all the possible
AWTPermission
target names, and for each provides a
description of what the permission allows and a discussion of the
risks of granting code the permission.
java.awt.AWTPermission Target Name |
What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
accessClipboard |
Posting and retrieval of information to and from the AWT clipboard | This would allow malfeasant code to share potentially sensitive or confidential information. |
accessEventQueue |
Access to the AWT event queue | After retrieving the AWT event queue, malicious code may peek at and even remove existing events from the system, as well as post bogus events which may purposefully cause the application or applet to misbehave in an insecure manner. |
accessSystemTray |
Access to the AWT SystemTray instance | This would allow malicious code to add tray icons to the system tray. First, such an icon may look like the icon of some known application (such as a firewall or anti-virus) and order a user to do something unsafe (with help of balloon messages). Second, the system tray may be glutted with tray icons so that no one could add a tray icon anymore. |
createRobot |
Create java.awt.Robot objects |
The java.awt.Robot object allows code to generate
native-level mouse and keyboard events as well as read the screen.
It could allow malicious code to control the system, run other
programs, read the display, and deny mouse and keyboard access to
the user. |
fullScreenExclusive |
Enter full-screen exclusive mode | Entering full-screen exclusive mode allows direct access to low-level graphics card memory. This could be used to spoof the system, since the program is in direct control of rendering. |
listenToAllAWTEvents |
Listen to all AWT events, system-wide | After adding an AWT event listener, malicious code may scan all
AWT events dispatched in the system, allowing it to read all user
input (such as passwords). Each AWT event listener is called from
within the context of that event queue's
EventDispatchThread , so if the accessEventQueue
permission is also enabled, malicious code could modify the
contents of AWT event queues system-wide, causing the application
or applet to misbehave in an insecure manner. |
readDisplayPixels |
Readback of pixels from the display screen | Interfaces such as the java.awt.Composite
interface which allow arbitrary code to examine pixels on the
display enable malicious code to snoop on the activities of the
user. |
replaceKeyboardFocusManager |
Sets the KeyboardFocusManager for a particular
thread. |
When a SecurityManager is installed, the invoking thread must be granted this permission in order to replace the current KeyboardFocusManager. If permission is not granted, a SecurityException will be thrown. |
setAppletStub |
Setting the stub which implements Applet container services | Malicious code could set an applet's stub and result in unexpected behavior or denial of service to an applet. |
setWindowsAlwaysOnTop |
Setting always-on-top property of the window:
Window.setAlwaysOnTop(boolean) |
The malicious window might make itself look and behave like a real full desktop, so that information entered by the unsuspecting user is captured and subsequently misused. |
showWindowWithoutWarningBanner |
Display of a window without also displaying a banner warning that the window was created by an applet | Without this warning, an applet may pop up windows without the user knowing that they belong to an applet. Since users may make security-sensitive decisions based on whether or not the window belongs to an applet (entering a username and password into a dialog box, for example), disabling this warning banner may allow applets to trick the user into entering such information. |
toolkitModality |
Creating TOOLKIT_MODAL dialogs and setting the TOOLKIT_EXCLUDE window property. | When a toolkit-modal dialog is shown from an applet, it blocks all other applets in the browser. When launching applications from Java Web Start, its windows (such as the security dialog) may also be blocked by toolkit-modal dialogs, shown from these applications. |
watchMousePointer |
Getting the information about the mouse pointer position at any time | Constantly watching the mouse pointer, an applet can make guesses about what the user is doing, i.e. moving the mouse to the lower left corner of the screen most likely means that the user is about to launch an application. If a virtual keypad is used so that keyboard is emulated using the mouse, an applet may guess what is being typed. |
FilePermission
A java.io.FilePermission
represents access to a file or directory. A
FilePermission
consists of a pathname and a set of
actions valid for that pathname.
Pathname is the pathname of the file or directory granted the
specified actions. A pathname that ends in "/*" (where "/" is the
file separator character, File.separatorChar
)
indicates a directory and all the files contained in that
directory. A pathname that ends with "/-" indicates (recursively) all files and
subdirectories contained in that directory. A pathname consisting of the special token "<<ALL
FILES>>" matches any file.
A pathname consisting of a single "*" indicates all the files in the current directory, while a pathname consisting of a single "-" indicates all the files in the current directory and (recursively) all files and subdirectories contained in the current directory.
The actions to be granted are passed to the constructor in a string containing a list of zero or more comma-separated keywords. The possible keywords are "read", "write", "execute", "delete", and "readLink." Their meanings are defined as follows:
Keyword | Meaning |
---|---|
read |
Permission to read. |
write |
Permission to write (which includes permission to create). |
execute |
Permission to execute. Allows
Runtime.exec to be called. Corresponds to
SecurityManager.checkExec . |
delete |
Permission to delete. Allows
File.delete to be called. Corresponds to
SecurityManager.checkDelete . |
readLink |
Permission to read links. Allows
the target of a symbolic link to be read by
invoking the readSymbolicLink method.
|
The actions string is converted to lowercase before processing.
Be careful when granting FilePermission
s. Think
about the implications of granting read and especially write access
to various files and directories. The "<<ALL FILES>>"
permission with write action is especially dangerous. This grants
permission to write to the entire file system. One thing this
effectively allows is replacement of the system binary, including
the JVM runtime environment.
Note: Code can always read a file from the same directory it is in (or a subdirectory of that directory); it does not need explicit permission to do so. Code can also obtain the pathname of the directory it is executed from, and this pathname may contain sensitive information. For example, if code is executed from a home directory (or a subdirectory of the home directory), the pathname may reveal the name of the current user.
SerializablePermission
A java.io.SerializablePermission
is for serializable permissions. A
SerializablePermission
contains a name (also referred
to as a "target name") but no actions list; you either have the
named permission or you don't.
The target name is the name of the Serializable permission (see below).
The following table lists all the possible
SerializablePermission
target names, and for each
provides a description of what the permission allows and a
discussion of the risks of granting code the permission.
java.io.SerializablePermission Target Name |
What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
enableSubclassImplementation |
Implementing a subclass of ObjectOutputStream or
ObjectInputStream to override the default
serialization or deserialization, respectively, of objects |
Code can use this to serialize or deserialize classes in a purposefully malfeasant manner. For example, during serialization, malicious code can use this to purposefully store confidential private field data in a way easily accessible to attackers. Or, during deserializaiton it could, for example, deserialize a class with all its private fields zeroed out. |
enableSubstitution |
Substitution of one object for another during serialization or deserialization | This is dangerous because malicious code can replace the actual object with one which has incorrect or malignant data. |
ManagementPermission
The permission which the SecurityManager
will check when code
that is running with a SecurityManager
calls methods defined
in the management interface for the Java platform.
The following table provides a summary description of what the permission allows, and discusses the risks of granting code the permission.
java.lang.management.ManagementPermission Target Name | What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
control |
Ability to control the runtime characteristics of the Java virtual
machine, for example, enabling and disabling the verbose output for
the class loading or memory system, setting the threshold of a memory
pool, and enabling and disabling the thread contention monitoring
support. Some actions controlled by this permission can disclose
information about the running application, like the -verbose:class
flag.
|
This allows an attacker to control the runtime characteristics of the Java virtual machine and cause the system to misbehave. An attacker can also access some information related to the running application. |
monitor |
Ability to retrieve runtime information about the Java virtual machine such as thread stack trace, a list of all loaded class names, and input arguments to the Java virtual machine. | This allows malicious code to monitor runtime information and uncover vulnerabilities. |
Programmers do not normally create ManagementPermission
objects directly.
Instead they are created by the security policy code based on reading
the security policy file.
ReflectPermission
A java.lang.reflect.ReflectPermission
is for reflective operations. A ReflectPermission is a named
permission and has no actions. The
suppressAccessChecks
name allows suppressing the
standard language access checks -- for public, default (package)
access, protected, and private members -- performed by reflected
objects at their point of use. The newProxyInPackage.{package name}
provide the ability to create a proxy instance in the specified package of
which the non-public interface that the proxy class implements.
The following table provides a summary description of what the permission allows, and discusses the risks of granting code the permission.
java.lang.reflect.ReflectPermission Target Name |
What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
suppressAccessChecks |
Warning: Extreme caution should be taken before granting this permission to code, for it provides the ability to access fields and invoke methods in a class. This includes not only public, but protected and private fields and methods as well. | This is dangerous in that information (possibly confidential) and methods normally unavailable would be accessible to malicious code. |
newProxyInPackage.{package name} |
Ability to create a proxy instance in the specified package of which the non-public interface that the proxy class implements. | This gives code access to classes in packages to which it normally does not have access and the dynamic proxy class is in the system protection domain. Malicious code may use these classes to help in its attempt to compromise security in the system. |
RuntimePermission
A java.lang.RuntimePermission
is for runtime permissions. A RuntimePermission
contains a name (also referred to as a "target name") but no
actions list; you either have the named permission or you
don't.
The target name is the name of the runtime permission (see
below). The naming convention follows the hierarchical property
naming convention. Also, an asterisk may appear at the end of the
name, following a ".
", or by itself, to signify a
wildcard match. For example: "loadLibrary.*
" or
"*
" is valid, "*loadLibrary
" or
"a*b
" is not valid.
The following table lists all the possible
RuntimePermission
target names, and for each provides
a description of what the permission allows and a discussion of the
risks of granting code the permission.
java.lang.RuntimePermission Target Name | What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
createClassLoader |
Creation of a class loader | This is an extremely dangerous permission to grant. Malicious applications that can instantiate their own class loaders could then load their own rogue classes into the system. These newly loaded classes could be placed into any protection domain by the class loader, thereby automatically granting the classes the permissions for that domain. |
getClassLoader |
Retrieval of a class loader (e.g., the class loader for the calling class) | This would grant an attacker permission to get the class loader for a particular class. This is dangerous because having access to a class's class loader allows the attacker to load other classes available to that class loader. The attacker would typically otherwise not have access to those classes. |
setContextClassLoader |
Setting of the context class loader used by a thread | The context class loader is used by system code and extensions when they need to lookup resources that might not exist in the system class loader. Granting setContextClassLoader permission would allow code to change which context class loader is used for a particular thread, including system threads. |
enableContextClassLoaderOverride |
Subclass implementation of the thread context class loader methods | The context class loader is used by system code and extensions when they need to lookup resources that might not exist in the system class loader. Granting enableContextClassLoaderOverride permission would allow a subclass of Thread to override the methods that are used to get or set the context class loader for a particular thread. |
closeClassLoader |
Closing of a ClassLoader | Granting this permission allows code to close any URLClassLoader that it has a reference to. |
setSecurityManager |
Setting of the security manager (possibly replacing an existing one) | The security manager is a class that allows applications to implement a security policy. Granting the setSecurityManager permission would allow code to change which security manager is used by installing a different, possibly less restrictive security manager, thereby bypassing checks that would have been enforced by the original security manager. |
createSecurityManager |
Creation of a new security manager | This gives code access to protected, sensitive methods that may disclose information about other classes or the execution stack. |
getenv.{variable name} |
Reading of the value of the specified environment variable | This would allow code to read the value, or determine the existence, of a particular environment variable. This is dangerous if the variable contains confidential data. |
exitVM.{exit status} |
Halting of the Java Virtual Machine with the specified exit status | This allows an attacker to mount a denial-of-service attack by automatically forcing the virtual machine to halt. Note: The "exitVM.*" permission is automatically granted to all code loaded from the application class path, thus enabling applications to terminate themselves. Also, the "exitVM" permission is equivalent to "exitVM.*". |
shutdownHooks |
Registration and cancellation of virtual-machine shutdown hooks | This allows an attacker to register a malicious shutdown hook that interferes with the clean shutdown of the virtual machine. |
setFactory |
Setting of the socket factory used by ServerSocket or Socket, or of the stream handler factory used by URL | This allows code to set the actual implementation for the socket, server socket, stream handler, or RMI socket factory. An attacker may set a faulty implementation which mangles the data stream. |
setIO |
Setting of System.out, System.in, and System.err | This allows changing the value of the standard system streams. An attacker may change System.in to monitor and steal user input, or may set System.err to a "null" OutputSteam, which would hide any error messages sent to System.err. |
modifyThread |
Modification of threads, e.g., via calls to Thread
interrupt , stop , suspend ,
resume , setDaemon ,
setPriority , setName and
setUncaughtExceptionHandler methods |
This allows an attacker to modify the behavior of any thread in the system. |
stopThread |
Stopping of threads via calls to the Thread stop
method |
This allows code to stop any thread in the system provided that it is already granted permission to access that thread. This poses as a threat, because that code may corrupt the system by killing existing threads. |
modifyThreadGroup |
Modification of thread groups, e.g., via calls to ThreadGroup
destroy , getParent , resume ,
setDaemon , setMaxPriority ,
stop , and suspend methods |
This allows an attacker to create thread groups and set their run priority. |
getProtectionDomain |
Retrieval of the ProtectionDomain for a class |
This allows code to obtain policy information for a particular code source. While obtaining policy information does not compromise the security of the system, it does give attackers additional information, such as local file names for example, to better aim an attack. |
getFileSystemAttributes |
Retrieval of file system attributes | This allows code to obtain file system information such as disk usage or disk space available to the caller. This is potentially dangerous because it discloses information about the system hardware configuration and some information about the caller's privilege to write files. |
readFileDescriptor |
Reading of file descriptors | This would allow code to read the particular file associated with the file descriptor read. This is dangerous if the file contains confidential data. |
writeFileDescriptor |
Writing to file descriptors | This allows code to write to a particular file associated with the descriptor. This is dangerous because it may allow malicous code to plant viruses or at the very least, fill up your entire disk. |
loadLibrary.{library name} |
Dynamic linking of the specified library | It is dangerous to allow an applet permission to load native code libraries, because the Java security architecture is not designed to and does not prevent malicious behavior at the level of native code. |
accessClassInPackage. |
Access to the specified package via a class loader's
loadClass method when that class loader calls the
SecurityManager checkPackageAcesss method |
This gives code access to classes in packages to which it normally does not have access. Malicious code may use these classes to help in its attempt to compromise security in the system. |
defineClassInPackage. |
Definition of classes in the specified package, via a class
loader's defineClass method when that class loader
calls the SecurityManager checkPackageDefinition
method. |
This grants code permission to define a class in a particular
package. This is dangerous because malicious code with this
permission may define rogue classes in trusted packages like
java.security or java.lang , for
example. |
accessDeclaredMembers |
Warning: Extreme caution should be taken before granting this permission to code, for it provides access to the declared members of a class. | This grants code permission to query a class for its public, protected, default (package) access, and private fields and/or methods. Although the code would have access to the private and protected field and method names, it would not have access to the private/protected field data and would not be able to invoke any private methods. Nevertheless, malicious code may use this information to better aim an attack. Additionally, it may invoke any public methods and/or access public fields in the class. This could be dangerous if the code would normally not be able to invoke those methods and/or access the fields because it can't cast the object to the class/interface with those methods and fields. |
queuePrintJob |
Initiation of a print job request | This could print sensitive information to a printer, or simply waste paper. |
getStackTrace |
Retrieval of the stack trace information of another thread. | This allows retrieval of the stack trace information of another thread. This might allow malicious code to monitor the execution of threads and discover vulnerabilities in applications. |
setDefaultUncaughtExceptionHandler |
Setting the default handler to be used when a thread terminates abruptly due to an uncaught exception. | This allows an attacker to register a malicious uncaught exception handler that could interfere with termination of a thread. |
preferences |
Represents the permission required to get access to the java.util.prefs.Preferences implementations user or system root which in turn allows retrieval or update operations within the Preferences persistent backing store. | This permission allows the user to read from or write to the preferences backing store if the user running the code has sufficient OS privileges to read/write to that backing store. The actual backing store may reside within a traditional filesystem directory or within a registry depending on the platform OS. |
usePolicy |
Granting this permission disables the Java Plug-In's default security prompting behavior. | For more information, refer to Java Plug-In's guides, Applet Security Basics and usePolicy Permission. |
RuntimePermission
targets were added
in the 1.4 release of the JavaSE JDK:
selectorProvider charsetProviderThese
RuntimePermission
s are required to be granted to
classes which subclass and implement
java.nio.channel.spi.SelectorProvider
or
java.nio.charset.spi.CharsetProvider
. The permission
is checked during invocation of the abstract base class
constructor. These permissions ensure trust in classes which
implement these security-sensitive provider mechanisms.
See java.nio.channels.spi.SelectorProvider
and java.nio.channels.spi.CharsetProvider
for more information.
NetPermission
A java.net.NetPermission
is for various network permissions. A NetPermission
contains a name but no actions list; you either have the named
permission or you don't.
The following table lists all the possible
NetPermission
target names, and for each provides a
description of what the permission allows and a discussion of the
risks of granting code the permission.
java.net.NetPermission Target Name |
What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
setDefaultAuthenticator |
The ability to set the way authentication information is retrieved when a proxy or HTTP server asks for authentication | Malicious code can set an authenticator that monitors and steals user authentication input as it retrieves the input from the user. |
requestPasswordAuthentication |
The ability to ask the authenticator registered with the system for a password | Malicious code may steal this password. |
specifyStreamHandler |
The ability to specify a stream handler when constructing a URL | Malicious code may create a URL with resources that it would normally not have access to (like file:/foo/fum/), specifying a stream handler that gets the actual bytes from someplace it does have access to. Thus it might be able to trick the system into creating a ProtectionDomain/CodeSource for a class even though that class really didn't come from that location. |
setProxySelector |
The ability to set the proxy selector used to make decisions on which proxies to use when making network connections. | Malicious code can set a ProxySelector that directs network traffic to an arbitrary network host. |
getProxySelector |
The ability to get the proxy selector used to make decisions on which proxies to use when making network connections. | Malicious code can get a ProxySelector to discover proxy hosts and ports on internal networks, which could then become targets for attack. |
setCookieHandler |
The ability to set the cookie handler that processes highly security sensitive cookie information for an Http session. | Malicious code can set a cookie handler to obtain access to highly security sensitive cookie information. Some web servers use cookies to save user private information such as access control information, or to track user browsing habit. |
getCookieHandler |
The ability to get the cookie handler that processes highly security sensitive cookie information for an Http session. | Malicious code can get a cookie handler to obtain access to highly security sensitive cookie information. Some web servers use cookies to save user private information such as access control information, or to track user browsing habit. |
setResponseCache |
The ability to set the response cache that provides access to a local response cache. | Malicious code getting access to the local response cache could access security sensitive information, or create false entries in the response cache. |
getResponseCache |
The ability to get the response cache that provides access to a local response cache. | Malicious code getting access to the local response cache could access security sensitive information. |
SocketPermission
A java.net.SocketPermission
represents access to a network via sockets. A SocketPermission
consists of a host specification and a set of "actions" specifying
ways to connect to that host. The host is specified as
host = (hostname | IPaddress)[:portrange] portrange = portnumber | -portnumber | portnumber-[portnumber]
The host is expressed as a DNS name, as a numerical IP address, or as "localhost" (for the local machine). The wildcard "*" may be included once in a DNS name host specification. If it is included, it must be in the leftmost position, as in "*.sun.com".
The port or portrange is optional. A port specification of the form "N-", where N is a port number, signifies all ports numbered N and above, while a specification of the form "-N" indicates all ports numbered N and below.
The possible ways to connect to the host are
accept connect listen resolve
The "listen" action is only meaningful when used with "localhost". The "resolve" (resolve host/ip name service lookups) action is implied when any of the other actions are present.
As an example of the creation and meaning of SocketPermissions, note that if you have the following entry in your policy file:
grant signedBy "mrm" { permission java.net.SocketPermission "puffin.example.com:7777", "connect, accept"; };
this causes the following permission object to be generated and granted to code signed by "mrm."
p1 = new SocketPermission("puffin.example.com:7777", "connect,accept");
p1
represents a permission allowing connections to
port 7777 on puffin.example.com
, and also accepting
connections on that port.
Similarly, if you have the following entry in your policy:
grant signedBy "paul" { permission java.net.SocketPermission "localhost:1024-", "accept, connect, listen"; };
this causes the following permission object to be generated and granted to code signed by "paul."
p2 = new SocketPermission("localhost:1024-", "accept,connect,listen");
p2
represents a permission allowing accepting
connections on, connecting to, or listening on any port between
1024 and 65535 on the local host.
Note: Granting code permission to accept or make connections to remote hosts may be dangerous because malevolent code can then more easily transfer and share confidential data among parties who may not otherwise have access to the data.
URLPermission
The url
The url string has the following expected structure.
scheme : // authority [ / path ]scheme will typically be http or https, but is not restricted by this class. authority is specified as:
authority = [ userinfo @ ] hostrange [ : portrange ] portrange = portnumber | -portnumber | portnumber-[portnumber] | * hostrange = ([*.] dnsname) | IPv4address | IPv6addressdnsname is a standard DNS host or domain name, ie. one or more labels separated by ".". IPv4address is a standard literal IPv4 address and IPv6address is as defined in RFC 2732. Literal IPv6 addresses must however, be enclosed in '[]' characters. The dnsname specification can be preceded by "*." which means the name will match any hostname whose right-most domain labels are the same as this name. For example, "*.oracle.com" matches "foo.bar.oracle.com"
portrange is used to specify a port number, or a bounded or unbounded range of ports
that this permission applies to. If portrange is absent or invalid, then a default
port number is assumed if the scheme is http
(default 80) or https
(default 443). No default is assumed for other schemes. A wildcard may be specified
which means all ports.
userinfo is optional. A userinfo component if present, is ignored when creating a URLPermission, and has no effect on any other methods defined by this class.
The path component comprises a sequence of path segments,
separated by '/' characters. path may also be empty. The path is specified
in a similar way to the path in FilePermission
. There are
three different ways as the following examples show:
Example url | Description |
---|---|
http://www.oracle.com/a/b/c.html | A url which identifies a specific (single) resource |
http://www.oracle.com/a/b/* | The '*' character refers to all resources in the same "directory" - in other words all resources with the same number of path components, and which only differ in the final path component, represented by the '*'. |
http://www.oracle.com/a/b/- | The '-' character refers to all resources recursively below the preceding path (eg. http://www.oracle.com/a/b/c/d/e.html matches this example). |
The '*' and '-' may only be specified in the final segment of a path and must be the only character in that segment. Any query or fragment components of the url are ignored when constructing URLPermissions.
As a special case, urls of the form, "scheme:*" are accepted to mean any url of the given scheme.
The scheme and authority components of the url string are handled
without regard to case. This means equals(Object)
,
hashCode()
and implies(Permission)
are case insensitive with respect
to these components. If the authority contains a literal IP address,
then the address is normalized for comparison. The path component is case sensitive.
The actions string
The actions string of a URLPermission is a concatenation of the method list and the request headers list. These are lists of the permitted request methods and permitted request headers of the permission (respectively). The two lists are separated by a colon ':' character and elements of each list are comma separated. Some examples are:
"POST,GET,DELETE" "GET:X-Foo-Request,X-Bar-Request" "POST,GET:Header1,Header2"The first example specifies the methods: POST, GET and DELETE, but no request headers. The second example specifies one request method and two headers. The third example specifies two request methods, and two headers.
The colon separator need not be present if the request headers list is empty. No white-space is permitted in the actions string. The action strings supplied to the URLPermission constructors are case-insensitive and are normalized by converting method names to upper-case and header names to the form defines in RFC2616 (lower case with initial letter of each word capitalized). Either list can contain a wild-card '*' character which signifies all request methods or headers respectively.
Note: Depending on the context of use, some request methods and headers may be permitted at all times, and others may not be permitted at any time. For example, the HTTP protocol handler might disallow certain headers such as Content-Length from being set by application code, regardless of whether the security policy in force, permits it.
Note: Granting code permission to access resources on remote hosts may be dangerous because malevolent code can then more easily transfer and share confidential data among parties who may not otherwise have access to the data.
LinkPermission
The Permission
class for link creation operations.
The following table provides a summary description of what the permission allows, and discusses the risks of granting code the permission.
java.nio.file.LinkPermission Target Name | What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
hard |
Ability to add an existing file to a directory. This is sometimes known as creating a link, or hard link. | Extreme care should be taken when granting this permission. It allows linking to any file or directory in the file system thus allowing the attacker access to all files. |
symbolic |
Ability to create symbolic links. | Extreme care should be taken when granting this permission. It allows linking to any file or directory in the file system thus allowing the attacker to access to all files. |
AllPermission
The java.security.AllPermission
is a permission that implies all other permissions.
Note: Granting AllPermission
should be done
with extreme care, as it implies all other permissions. Thus, it
grants code the ability to run with security disabled. Extreme
caution should be taken before granting such a permission to code.
This permission should be used only during testing, or in extremely
rare cases where an application or applet is completely trusted and
adding the necessary permissions to the policy is prohibitively
cumbersome.
SecurityPermission
A java.security.SecurityPermission
is for security permissions. A SecurityPermission
contains a name (also referred to as a "target name") but no
actions list; you either have the named permission or you
don't.
The target name is the name of a security configuration
parameter (see below). Currently the
SecurityPermission
object is used to guard access to
the Policy
, Security
,
Provider
, Signer
, and
Identity
objects.
The following table lists all the possible
SecurityPermission
target names, and for each provides
a description of what the permission allows and a discussion of the
risks of granting code the permission.
java.security.SecurityPermission Target Name |
What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
createAccessControlContext |
Creation of an AccessControlContext |
This allows someone to instantiate an
AccessControlContext with a
DomainCombiner . Extreme care must be taken when
granting this permission. Malicious code could create a
DomainCombiner that augments the set of permissions
granted to code, and even grant the code
AllPermission . |
getDomainCombiner |
Retrieval of an AccessControlContext 's
DomainCombiner |
This allows someone to query the policy via the getPermissions call, which discloses which permissions would be granted to a given CodeSource. While revealing the policy does not compromise the security of the system, it does provide malicious code with additional information which it may use to better aim an attack. It is wise not to divulge more information than necessary. |
getPolicy |
Retrieval of the system-wide security policy (specifically, of the currently-installed Policy object) | This allows someone to query the policy via the
getPermissions call, which discloses which permissions
would be granted to a given CodeSource . While
revealing the policy does not compromise the security of the
system, it does provide malicious code with additional information
which it may use to better aim an attack. It is wise not to divulge
more information than necessary. |
setPolicy |
Setting of the system-wide security policy (specifically, the Policy object) | Granting this permission is extremely dangerous, as malicious code may grant itself all the necessary permissions it needs to successfully mount an attack on the system. |
createPolicy.{policy type} |
Getting an instance of a Policy via Policy.getInstance | Granting this permission enables code to obtain a Policy object. Malicious code may query the Policy object to determine what permissions have been granted to code other than itself. |
getProperty.{key} |
Retrieval of the security property with the specified key | Depending on the particular key for which access has been granted, the code may have access to the list of security providers, as well as the location of the system-wide and user security policies. while revealing this information does not compromise the security of the system, it does provide malicious code with additional information which it may use to better aim an attack. |
setProperty.{key} |
Setting of the security property with the specified key | This could include setting a security provider or defining the location of the system-wide security policy. Malicious code that has permission to set a new security provider may set a rogue provider that steals confidential information such as cryptographic private keys. In addition, malicious code with permission to set the location of the system-wide security policy may point it to a security policy that grants the attacker all the necessary permissions it requires to successfully mount an attack on the system. |
insertProvider |
Addition of a new provider | This would allow somebody to introduce a possibly malicious provider (e.g., one that discloses the private keys passed to it) as the highest-priority provider. This would be possible because the Security object (which manages the installed providers) currently does not check the integrity or authenticity of a provider before attaching it. The "insertProvider" permission subsumes the "insertProvider.{provider name}" permission (see the section below for more information). |
removeProvider.{provider name} |
Removal of the specified provider | This may change the behavior or disable execution of other parts of the program. If a provider subsequently requested by the program has been removed, execution may fail. Also, if the removed provider is not explicitly requested by the rest of the program, but it would normally be the provider chosen when a cryptography service is requested (due to its previous order in the list of providers), a different provider will be chosen instead, or no suitable provider will be found, thereby resulting in program failure. |
clearProviderProperties.{provider name} |
"Clearing" of a Provider so that it no longer contains the properties used to look up services implemented by the provider | This disables the lookup of services implemented by the provider. This may thus change the behavior or disable execution of other parts of the program that would normally utilize the Provider, as described under the "removeProvider.{provider name}" permission. |
putProviderProperty.{provider name} |
Setting of properties for the specified Provider | The provider properties each specify the name and location of a particular service implemented by the provider. By granting this permission, you let code replace the service specification with another one, thereby specifying a different implementation. |
removeProviderProperty.{provider name} |
Removal of properties from the specified Provider | This disables the lookup of services implemented by the provider. They are no longer accessible due to removal of the properties specifying their names and locations. This may change the behavior or disable execution of other parts of the program that would normally utilize the Provider, as described under the "removeProvider.{provider name}" permission. |
The following permissions are associated with classes that have
been deprecated: Identity
, IdentityScope
,
Signer
. Use of them is discouraged. See the applicable
classes for more information.
java.security.SecurityPermission Target Name |
What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
insertProvider.{provider name} |
Addition of a new provider, with the specified name | This would allow somebody to introduce a possibly malicious provider (e.g., one that discloses the private keys passed to it) as the highest-priority provider. This would be possible because the Security object (which manages the installed providers) currently does not check the integrity or authenticity of a provider before attaching it. |
setSystemScope |
Setting of the system identity scope | This would allow an attacker to configure the system identity scope with certificates that should not be trusted, thereby granting applet or application code signed with those certificates privileges that would have been denied by the system's original identity scope. |
setIdentityPublicKey |
Setting of the public key for an Identity | If the identity is marked as "trusted", this allows an attacker to introduce a different public key (e.g., its own) that is not trusted by the system's identity scope, thereby granting applet or application code signed with that public key privileges that would have been denied otherwise. |
setIdentityInfo |
Setting of a general information string for an Identity | This allows attackers to set the general description for an identity. This may trick applications into using a different identity than intended or may prevent applications from finding a particular identity. |
addIdentityCertificate |
Addition of a certificate for an Identity | This allows attackers to set a certificate for an identity's public key. This is dangerous because it affects the trust relationship across the system. This public key suddenly becomes trusted to a wider audience than it otherwise would be. |
removeIdentityCertificate |
Removal of a certificate for an Identity | This allows attackers to remove a certificate for an identity's public key. This is dangerous because it affects the trust relationship across the system. This public key suddenly becomes considered less trustworthy than it otherwise would be. |
printIdentity |
Viewing the name of a principal and optionally the scope in which it is used, and whether or not it is considered "trusted" in that scope. | The scope that is printed out may be a filename, in which case
it may convey local system information. For example, here's a
sample printout of an identity named "carol", who is marked not
trusted in the user's identity database: carol[/home/luehe/identitydb.obj][not trusted] |
getSignerPrivateKey |
Retrieval of a Signer's private key | It is very dangerous to allow access to a private key; private keys are supposed to be kept secret. Otherwise, code can use the private key to sign various files and claim the signature came from the Signer. |
setSignerKeyPair |
Setting of the key pair (public key and private key) for a Signer | This would allow an attacker to replace somebody else's (the "target's") keypair with a possibly weaker keypair (e.g., a keypair of a smaller keysize). This also would allow the attacker to listen in on encrypted communication between the target and its peers. The target's peers might wrap an encryption session key under the target's "new" public key, which would allow the attacker (who possesses the corresponding private key) to unwrap the session key and decipher the communication data encrypted under that session key. |
UnresolvedPermission
The java.security.UnresolvedPermission
class is used to hold Permission
s that were
"unresolved" when the Policy
was initialized. An
unresolved permission is one whose actual Permission
class does not yet exist at the time the Policy
is
initialized (see below).
The policy for a Java runtime (specifying which permissions are
available for code from various principals) is represented by a
Policy
object. Whenever a Policy
is
initialized or refreshed, Permission
objects of
appropriate classes are created for all permissions allowed by the
Policy
.
Many permission class types referenced by the policy
configuration are ones that exist locally (i.e., ones that can be
found on CLASSPATH). Objects for such permissions can be
instantiated during Policy
initialization. For
example, it is always possible to instantiate a
java.io.FilePermission
, since the
FilePermission
class is found on the CLASSPATH.
Other permission classes may not yet exist during
Policy
initialization. For example, a referenced
permission class may be in a JAR file that will later be loaded.
For each such class, an UnresolvedPermission
is
instantiated. Thus, an UnresolvedPermission
is
essentially a "placeholder" containing information about the
permission.
Later, when code calls
AccessController.checkPermission
on a permission of a
type that was previously unresolved, but whose class has since been
loaded, previously-unresolved permissions of that type are
"resolved". That is, for each such
UnresolvedPermission
, a new object of the appropriate
class type is instantiated, based on the information in the
UnresolvedPermission
. This new object replaces the
UnresolvedPermission
, which is removed.
SQLPermission
The permission for which the SecurityManager
will
check when code that is running in an applet, or an application
with an instance of SecurityManager
enabled, calls one
of the following methods:
java.sql.DriverManager.setLogWriter
java.sql.DriverManager.setLogStream
(deprecated)javax.sql.rowset.spi.SyncFactory.setJNDIContext
javax.sql.rowset.spi.SyncFactory.setLogger
java.sql.Connection.setNetworktimeout
java.sql.Connection.abort
If there is no SQLPermission
object, these methods
throw a java.lang.SecurityException
as a runtime
exception.
A SQLPermission
object contains a name (also
referred to as a "target name") but no actions list; there is
either a named permission or there is not. The target name is the
name of the permission (see the following table that lists all the
possible SQLPermission
names). The naming convention
follows the hierarchical property naming convention. In addition,
an asterisk (*
) may appear at the end of the name,
following a dot (.
), or by itself, to signify a
wildcard match. For example: loadLibrary.*
or
*
is valid, but *loadLibrary
or
a*b
is not valid.
The following table lists all the possible
SQLPermission
target names. The table gives a
description of what the permission allows and a discussion of the
risks of granting code the permission.
java.sql.SQLPermission Target Name | What Permission Allows | Risks of Allowing This Permission |
---|---|---|
setLog |
Setting of the logging stream | This is a dangerous permission to grant. The contents of the log can contain usernames and passwords, SQL statements, and SQL data. |
callAbort |
Invocation of the Connection method
abort |
Permits an application to terminate a physical connection to a database. |
setSyncFactory |
Invocation of the SyncFactory methods
setJNDIContext and setLogger |
Permits an application to specify the JNDI context from which
the SyncProvider implementations can be retrieved from
and the logging object to be used by the SyncProvider
implementation. |
setNetworkTimeout |
Invocation of the Connection method
setNetworkTimeout |
Permits an application to specify the maximum period a
Connection or objects created from the
Connection object will wait for the database to reply
to any one request. |
deregisterDriver |
Allows the invocation of the DriverManager method deregisterDriver .
|
Permits an application to remove a JDBC driver from the list of registered Drivers and release its resources. |
LoggingPermission
SecurityManager
will check the java.util.logging.LoggingPermission
object when code running with a SecurityManager
calls
one of the logging control methods (such as
Logger.setLevel
).
Currently there is only one named
LoggingPermission
, "control
".
control
grants the ability to control the logging
configuration; for example by adding or removing Handlers, by
adding or removing Filters, or by changing logging levels.
Normally you do not create LoggingPermission
objects directly; instead they are created by the security policy
code based on reading the security policy file.
PropertyPermission
A java.util.PropertyPermission
is for property permissions.
The name is the name of the property ("java.home", "os.name", etc). The naming convention follows the hierarchical property naming convention. Also, an asterisk may appear at the end of the name, following a ".", or by itself, to signify a wildcard match. For example: "java.*" or "*" is valid, "*java" or "a*b" is not valid.
The actions to be granted are passed to the constructor in a string containing a list of zero or more comma-separated keywords. The possible keywords are "read" and "write". Their meaning is defined as follows:
Keyword | Meaning |
---|---|
read |
Permission to read. Allows
System.getProperty to be called. |
write |
Permission to write. Allows
System.setProperty to be called. |
The actions string is converted to lowercase before processing.
Care should be taken before granting code permission to access certain system properties. For example, granting permission to access the "java.home" system property gives potentially malevolent code sensitive information about the system environment (the location of the runtime environment's directory). Also, granting permission to access the "user.name" and "user.home" system properties gives potentially malevolent code sensitive information about the user environment (the user's account name and home directory).
MBeanPermission
Permission controlling access to MBeanServer
operations. If a
security manager has been set using System.setSecurityManager(java.lang.SecurityManager)
,
most operations on the MBeanServer
require that the caller's permissions imply an MBeanPermission
appropriate for the operation. This is described in detail in the
documentation for the MBeanServer
interface.
As with other Permission
objects, an MBeanPermission
can
represent either a permission that you have or a
permission that you need. When a sensitive operation is
being checked for permission, an MBeanPermission
is constructed
representing the permission you need. The operation is only
allowed if the permissions you have imply the
permission you need.
An MBeanPermission
contains four items of information:
The action. For a permission you need,
this is one of the actions in the list below. For a permission you have, this is
a comma-separated list of those actions, or *
,
representing all actions.
The action is returned by getActions()
.
The class name.
For a permission you need, this is the class name of an MBean
you are accessing, as returned by MBeanServer.getMBeanInfo(name)
.getClassName()
. Certain operations do not reference a class name,
in which case the class name is null.
For a permission you have, this is either empty or a class
name pattern. A class name pattern is a string following the
Java conventions for dot-separated class names. It may end with
".*
" meaning that the permission grants access to any
class that begins with the string preceding ".*
". For
instance, "javax.management.*
" grants access to
javax.management.MBeanServerDelegate
and
javax.management.timer.Timer
, among other classes.
A class name pattern can also be empty or the single character
"*
", both of which grant access to any class.
The member.
For a permission you need, this is the name of the attribute or operation you are accessing. For operations that do not reference an attribute or operation, the member is null.
For a permission you have, this is either the name of an attribute
or operation you can access, or it is empty or the single character
"*
", both of which grant access to any member.
The object name.
For a permission you need, this is the ObjectName
of the
MBean
you are accessing. For operations that do not reference a
single MBean
, it is null. It is never an object name pattern.
For a permission you have, this is the ObjectName
of the
MBean
or MBean
s you can access. It may be an object name pattern
to grant access to all MBean
s whose names match the pattern. It
may also be empty, which grants access to all MBeans whatever their
name.
If you have an MBeanPermission
, it allows operations only if all
four of the items match.
The class name, member, and object name can be written together
as a single string, which is the name of this permission.
The name of the permission is the string returned by getName()
. The format of the string is:
className#member[objectName]
The object name is written using the usual syntax for ObjectName
. It may contain any legal characters, including
]
. It is terminated by a ]
character
that is the last character in the string.
One or more of the className
, member
,
or objectName
may be omitted. If the
member
is omitted, the #
may be too (but
does not have to be). If the objectName
is omitted,
the []
may be too (but does not have to be). It is
not legal to omit all three items, that is to have a name
that is the empty string.
One or more of the className
, member
,
or objectName
may be the character "-
",
which is equivalent to a null value. A null value is implied by
any value (including another null value) but does not imply any
other value.
The possible actions are these:
addNotificationListener
getAttribute
getClassLoader
getClassLoaderFor
getClassLoaderRepository
getDomains
getMBeanInfo
getObjectInstance
instantiate
invoke
isInstanceOf
queryMBeans
queryNames
registerMBean
removeNotificationListener
setAttribute
unregisterMBean
In a comma-separated list of actions, spaces are allowed before and after each action.
MBeanServerPermission
MBeanServer
s.
The name of the permission specifies the operation requested
or granted by the permission. For a granted permission, it can be
*
to allow all of the MBeanServer
operations specified below.
Otherwise, for a granted or requested permission, it must be one of the
following:
createMBeanServer
MBeanServerFactory.createMBeanServer()
or
MBeanServerFactory.createMBeanServer(java.lang.String)
.
findMBeanServer
MBeanServer
with a given name, or all MBeanServer
s in this
JVM, using the method MBeanServerFactory.findMBeanServer(java.lang.String)
.
newMBeanServer
MBeanServer
object without keeping a reference to it,
using the method MBeanServerFactory.newMBeanServer()
or
MBeanServerFactory.newMBeanServer(java.lang.String)
.
releaseMBeanServer
MBeanServerFactory
's reference to an MBeanServer
,
using the method MBeanServerFactory.releaseMBeanServer(javax.management.MBeanServer)
.
MBeanServerPermission("createMBeanServer")
implies
MBeanServerPermission("newMBeanServer")
.
MBeanTrustPermission
This permission represents "trust" in a signer or codebase.
MBeanTrustPermission
contains a target name but no actions list. A single target name, "register", is defined for this permission.
The target "*" is also allowed, permitting "register" and any future targets that may be defined. Only the null value or the empty
string are allowed for the action to allow the policy object to create the permissions specified in the policy file.
If a signer, or codesource is granted this permission, then it is considered a trusted source for MBean
s.
Only MBean
s from trusted sources may be registered in the MBeanServer
.
SubjectDelegationPermission
Permission required by an authentication identity to perform operations on behalf of an authorization identity.
A SubjectDelegationPermission
contains a name (also referred
to as a "target name") but no actions list; you either have the
named permission or you don't.
The target name is the name of the authorization principal
classname followed by a period and the authorization principal
name, that is
"PrincipalClassName.PrincipalName"
.
An asterisk may appear by itself, or if immediately preceded by a "." may appear at the end of the target name, to signify a wildcard match.
For example, "*"
, "javax.management.remote.JMXPrincipal.*"
and
"javax.management.remote.JMXPrincipal.delegate"
are valid target
names. The first one denotes any principal name from any principal
class, the second one denotes any principal name of the concrete
principal class javax.management.remote.JMXPrincipal
and the third one denotes a concrete principal name
delegate
of the concrete principal class
javax.management.remote.JMXPrincipal
.
SSLPermission
The javax.net.ssl.SSLPermission
class is for various network permissions. An
SSLPermission
contains a name (also referred to as a
"target name") but no actions list; you either have the named
permission or you don't.
The target name is the name of the network permission (see
below). The naming convention follows the hierarchical property
naming convention. Also, an asterisk may appear at the end of the
name, following a ".
", or by itself, to signify a
wildcard match. For example: "foo.*
" or
"*
" is valid, "*foo
" or
"a*b
" is not valid.
The following table lists all the possible SSLPermission target names, and for each provides a description of what the permission allows and a discussion of the risks of granting code the permission.
Permission Target Name | What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
setHostnameVerifier |
The ability to set a callback which can decide whether to allow
a mismatch between the host being connected to by an
HttpsURLConnection and the common name field in server
certificate. |
Malicious code can set a verifier that monitors host names
visited by HttpsURLConnection requests or that allows
server certificates with invalid common names. |
getSSLSessionContext |
The ability to get the SSLSessionContext of an
SSLSession . |
Malicious code may monitor sessions which have been established with SSL peers or might invalidate sessions to slow down performance. |
setDefaultSSLContext |
The ability to set the default SSL context. | When applications use default SSLContext, by setting the default SSL context, malicious code may use unproved trust material, key material and random generator, or use dangerous SSL socket factory and SSL server socket factory. |
AuthPermission
The javax.security.auth.AuthPermission
class is for authentication permissions. An
AuthPermission
contains a name (also referred to as a
"target name") but no actions list; you either have the named
permission or you don't.
Currently the AuthPermission
object is used to
guard access to the Subject
,
SubjectDomainCombiner
, LoginContext
and
Configuration
objects.
The following table lists all the possible
AuthPermission
target names, and for each provides a
description of what the permission allows and a discussion of the
risks of granting code the permission.
Permission Target Name | What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
doAs |
Invocation of the Subject.doAs methods |
This enables an application to invoke code (Actions) under the
identity of any Subject specified to the
doAs method. |
doAsPrivileged |
Invocation of the Subject.doAsPrivileged
methods |
This enables an application to invoke code (Actions) under the
identity of any Subject specified to the
doAsPrivileged method. Additionally, the caller may
remove itself from the call stack (and hence from subsequent
security decisions) if it passes null as the
AccessControlContext . |
getSubject |
Retrieving the Subject from the provided
AccessControlContext |
This permits an application to gain access to an authenticated
Subject . The application can then access the Subject's
authenticated Principals and public credentials. |
getSubjectFromDomainCombiner |
Retrieving the Subject from a
SubjectDomainCombiner |
This permits an application to gain access to the authenticated
Subject associated with a
SubjectDomainCombiner . The application can then access
the Subject's authenticated Principals and public credentials. |
setReadOnly |
Setting a Subject read-only |
This permits an application to set a Subject's
Principal , public credential and private credential
sets to be read-only. This can be potentially used as a type of
denial of service attack. |
modifyPrincipals |
Make modifications to a Subject's Principal
set |
Access control decisions are based on the Principals associated
with a Subject . This permission permits an application
to make any modifications to a Subject's Principal
set, thereby affecting subsequent security decisions. |
modifyPublicCredentials |
Make modifications to a Subject's public credential set | This permission permits an application to add or remove public
credentials from a Subject . This may affect code that
relies on the proper set of private credentials to exist in that
Subject . |
modifyPrivateCredentials |
Make modifications to a Subject's private credential set | This permission permits an application to add or remove private
credentials from a Subject . This may affect code that
relies on the proper set of private credentials to exist in that
Subject . |
refreshCredential |
Refresh a credential Object that implements the
Refreshable interface |
This permission permits an application to refresh a credential that is intended to expire. |
destroyCredential |
Destroy a credential Object that implements the
Destroyable interface |
This permission permits an application to potentially destroy a credential as a denial of service attack. |
createLoginContext.{name} |
Instantiate a LoginContext with the specified
name |
For security purposes, an administrator might not want an
application to be able to authenticate to any
LoginModule . This permission permits an application to
authenticate to the LoginModules configured for the specified
name. |
getLoginConfiguration |
Retrieve the system-wide login Configuration |
Allows an application to determine all the LoginModules that are configured for every application in the system. |
setLoginConfiguration |
Set the system-wide login Configuration |
Allows an application to configure the LoginModules for every application in the system. |
createLoginConfiguration.{configuration type} |
Obtain a Configuration object via Configuration.getInstance | Allows an application to see all the LoginModules that are specified in the configuration. |
refreshLoginConfiguration |
Refresh the system-wide login Configuration |
Allows an application to refresh the login
Configuration . |
DelegationPermission
javax.security.auth.kerberos.DelegationPermission
class is used to restrict the usage of the Kerberos delegation
model; ie, forwardable and proxiable tickets.
The target name of this Permission specifies a pair of kerberos
service principals. The first is the subordinate service principal
being entrusted to use the Ticket Granting Ticket (TGT). The second
service principal designates the target service the subordinate
service principal is to interact with on behalf of the initiating
KerberosPrincipal
. This latter service principal is
specified to restrict the use of a proxiable ticket.
For example, to specify the "host" service use of a forwardable TGT, the target permission is specified as follows:
DelegationPermission("\"host/[email protected]\" \"krbtgt/[email protected]\"");To give the "backup" service a proxiable NFS service ticket, the target permission might be specified:
DelegationPermission("\"backup/[email protected]\" \"nfs/[email protected]\"");
ServicePermission
javax.security.auth.kerberos.ServicePermission
class is
used to protect Kerberos services and the credentials necessary to
access those services. There is a one to one mapping of a service
principal and the credentials necessary to access the service.
Therefore granting access to a service principal implicitly grants
access to the credential necessary to establish a security context
with the service principal. This applies regardless of whether the
credentials are in a cache or acquired via an exchange with the
KDC. The credential can be either a ticket granting ticket, a
service ticket or a secret key from a key table.
A ServicePermission
contains a service principal
name and a list of actions which specify the context the credential
can be used within.
The service principal name is the canonical name of the
KereberosPrincipal supplying the service, that is the
KerberosPrincipal
represents a Kerberos service
principal. This name is treated in a case sensitive manner.
Granting this permission implies that the caller can use a
cached credential (Ticket Granting Ticket, service ticket or secret
key) within the context designated by the action. In the case of
the TGT, granting this permission also implies that the TGT can be
obtained by an Authentication Service
exchange.
The possible actions are:
Action | Meaning |
---|---|
initiate |
Allows the caller to use the credential to initiate a security context with a service principal. |
accept |
Allows the caller to use the credential to accept security context as a particular principal. |
ServicePermission("krbtgt/[email protected]", "initiate");To obtain a service ticket to initiate a context with the "host" service the permission is constructed as follows:
ServicePermission("host/[email protected]", "initiate");For a Kerberized server the action is "accept". For example, the permission necessary to access and use the secret key of the Kerberized "host" service (telnet and the likes) would be constructed as follows:
ServicePermission("host/[email protected]", "accept");
PrivateCredentialPermission
javax.security.auth.PrivateCredentialPermission
class is used to protect access to private Credentials belonging to
a particular Subject. The Subject is represented
by a Set of Principals.
The target name of this Permission specifies a
Credential
class name, and a Set of Principals. The
only valid value for this Permission
's actions is,
"read". The target name must abide by the following syntax:
CredentialClass {PrincipalClass "PrincipalName"}*For example, the following permission grants access to the
com.sun.PrivateCredential
owned by
Subject
s which have a com.sun.Principal
with the name, "duke
".
Note: Although this example, as well as all the examples
below, do not contain Codebase
, SignedBy
,
or Principal
information in the grant statement (for
simplicity reasons), actual policy configurations should specify
that information when appropriate.
grant { permission javax.security.auth.PrivateCredentialPermission "com.sun.PrivateCredential com.sun.Principal \"duke\"", "read"; };If
CredentialClass
is "*
", then access is
granted to all private Credential
s belonging to the
specified Subject. If "PrincipalName
" is
"*
", then access is granted to the specified
Credential
owned by any Subject that has the
specified Principal (the actual PrincipalName
doesn't matter). For example, the following grants access to the
a.b.Credential
owned by any Subject that has
an a.b.Principal
.
grant { permission javax.security.auth.PrivateCredentialPermission "a.b.Credential a.b.Principal "*"", "read"; };If both the
PrincipalClass
and
"PrincipalName
" are "*
", then access is
granted to the specified Credential
owned by any
Subject. In addition, the
PrincipalClass
/PrincipalName
pairing may
be repeated:
grant { permission javax.security.auth.PrivateCredentialPermission "a.b.Credential a.b.Principal "duke" c.d.Principal "dukette"", "read"; };The above code grants access to the private
Credential
, "a.b.Credential
", belonging
to a Subject with at least two associated
Principal
s: "a.b.Principal
" with the
name, "duke
", and "c.d.Principal
", with
the name, "dukette
".
AudioPermission
The javax.sound.sampled.AudioPermission
class represents access rights to the audio system resources. An
AudioPermission
contains a target name but no actions
list; you either have the named permission or you don't.
The target name is the name of the audio permission (see the table below). The names follow the hierarchical property-naming convention. Also, an asterisk can be used to represent all the audio permissions.
The following table lists the possible
AudioPermission
target names. For each name, the table
provides a description of exactly what that permission allows, as
well as a discussion of the risks of granting code the
permission.
Permission Target Name | What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
play |
Audio playback through the audio device or devices on the system. Allows the application to obtain and manipulate lines and mixers for audio playback (rendering). | In some cases use of this permission may affect other applications because the audio from one line may be mixed with other audio being played on the system, or because manipulation of a mixer affects the audio for all lines using that mixer. |
record |
Audio recording through the audio device or devices on the system. Allows the application to obtain and manipulate lines and mixers for audio recording (capture). | In some cases use of this permission may affect other applications because manipulation of a mixer affects the audio for all lines using that mixer. This permission can enable an applet or application to eavesdrop on a user. |
JAXBPermission
JAXBPermission
contains a name (also referred to as a "target name") but
no actions list; you either have the named permission
or you don't.
The target name is the name of the JAXB permission (see below).
The following table lists all the possible JAXBPermission
target names,
and for each provides a description of what the permission allows
and a discussion of the risks of granting code the permission.
javax.xml.bind.JAXBPermission Target Name | What the Permission Allows | Risks of Allowing this Permission |
---|---|---|
setDatatypeConverter |
Allows the code to set VM-wide DatatypeConverterInterface
via the setDatatypeConverter method
that all the methods on DatatypeConverter uses.
|
Malicious code can set DatatypeConverterInterface , which has
VM-wide singleton semantics, before a genuine JAXB implementation sets one.
This allows malicious code to gain access to objects that it may otherwise
not have access to, such as Frame.getFrames() that belongs to
another application running in the same JVM.
|
WebServicePermission
Web service Permissions are identified by name (also referred to as a "target name") alone. There are no actions associated with them.
The following permission target name is defined:
publishEndpoint
The publishEndpoint
permission allows publishing a
web service endpoint using the publish
methods
defined by the javax.xml.ws.Endpoint
class.
Granting publishEndpoint
allows the application to be
exposed as a network service. Depending on the security of the runtime and
the security of the application, this may introduce a security hole that
is remotely exploitable.
The following table contains a list of all the methods that require permissions, and for each tells which SecurityManager
method it calls
and which permission is checked for by the default implementation of that
SecurityManager
method.
Note: This list is not complete and does not include several new methods that require permissions that have been introduced in recent versions of the JDK.
See the the API Specification for additional information on methods that throw SecurityException
and the permissions that are required.
Thus, with the default SecurityManager
method implementations, a call to a method in the left-hand column can only be successful if the permission specified in the corresponding entry in the right-hand column is allowed by the policy currently in effect. For example, the following row:
Method | SecurityManager Method Called | Permission |
---|---|---|
java.awt.Toolkit getSystemEventQueue(); |
checkPermission |
java.awt.AWTPermission "accessEventQueue"; |
specifies that a call to the getSystemEventQueue
method in the java.awt.Toolkit
class results in a call
to the checkPermission
SecurityManager
method, which can only be successful if the following permission is
granted to code on the call stack:
java.awt.AWTPermission "accessEventQueue";
The convention of:
Method | SecurityManager Method Called | Permission |
---|---|---|
some.package.class public static void someMethod(String foo); |
checkXXX |
SomePermission "{foo}"; |
means the runtime value of foo
replaces the string {foo}
in the permission name.
As an example, here is one table entry:
Method | SecurityManager Method Called | Permission |
---|---|---|
java.io.FileInputStream FileInputStream(String name) |
checkRead(String) |
java.io.FilePermission "{name}", "read"; |
If the FileInputStream
method (in this case, a constructor) is called with "/test/MyTestFile" as the name
argument, as in
FileInputStream("/test/MyTestFile");
then in order for the call to succeed, the following permission must be set in the current policy, allowing read access to the file "/test/MyTestFile":
java.io.FilePermission "/test/MyTestFile", "read";
More specifically, the permission must either be explicitly set, as above, or implied by another permission, such as the following:
java.io.FilePermission "/test/*", "read";
which allows read access to any files in the "/test"
directory.
In some cases, a term in braces is not exactly the same as the name of a specific method argument but is meant to represent the relevant value. Here is an example:
Method | SecurityManager Method Called | Permission |
---|---|---|
java.net.DatagramSocket public synchronized void receive(DatagramPacket p); |
checkAccept({host}, {port}) |
java.net.SocketPermission "{host}:{port}",
"accept"; |
Here, the appropriate host and port values are calculated by the receive
method and passed to checkAccept
.
In most cases, just the name of the SecurityManager method called is listed. Where the method is one of multiple methods of the same name, the argument types are also listed, for example for checkRead(String)
and checkRead(FileDescriptor)
. In other cases where arguments may be relevant, they are also listed.
The following table is ordered by package name. That is, the methods in classes in the java.awt
package are listed first, followed by methods in classes in the java.io
package, and so on.
Method | SecurityManager Method Called | Permission |
---|---|---|
java.awt.Graphics2d public abstract void setComposite(Composite comp) |
checkPermission | java.awt.AWTPermission "readDisplayPixels" if this Graphics2D context is drawing to a Component on the display screen and the Composite is a custom object rather than an instance of the AlphaComposite class. Note: The setComposite method is actually abstract and thus can't invoke security checks. Each actual implementation of the method should call the java.lang.SecurityManager checkPermission method with a java.awt.AWTPermission("readDisplayPixels") permission under the conditions noted. |
java.awt.Robot public Robot() public Robot(GraphicsDevice screen) |
checkPermission | java.awt.AWTPermission "createRobot" |
java.awt.Toolkit public void addAWTEventListener( AWTEventListener listener, long eventMask) public void removeAWTEventListener( AWTEventListener listener) |
checkPermission | java.awt.AWTPermission "listenToAllAWTEvents" |
java.awt.Toolkit public abstract PrintJob getPrintJob( Frame frame, String jobtitle, Properties props) |
checkPrintJobAccess |
java.lang.RuntimePermission "queuePrintJob" Note: The getPrintJob method is actually abstract and thus can't invoke security checks. Each actual implementation of the method should call the java.lang.SecurityManager checkPrintJobAccess method, which is successful only if the java.lang.RuntimePermission "queuePrintJob" permission is currently allowed. |
java.awt.Toolkit public abstract Clipboard getSystemClipboard() |
checkPermission |
java.awt.AWTPermission "accessClipboard" Note: The getSystemClipboard method is actually abstract and thus can't invoke security checks. Each actual implementation of the method should call the checkPermission method, which is successful only if the java.awt.AWTPermission "accessClipboard" permission is currently allowed. |
java.awt.Toolkit public final EventQueue getSystemEventQueue() |
checkPermission | java.awt.AWTPermission "accessEventQueue" |
java.awt.Window Window() |
checkPermission | If java.awt.AWTPermission "showWindowWithoutWarningBanner" is set, the window will be displayed without a banner warning that the window was created by an applet. It it's not set, such a banner will be displayed. |
java.beans.Beans public static void setDesignTime( boolean isDesignTime) public static void setGuiAvailable( boolean isGuiAvailable) java.beans.Introspector public static synchronized void setBeanInfoSearchPath(String path[]) java.beans.PropertyEditorManager public static void registerEditor( Class targetType, Class editorClass) public static synchronized void setEditorSearchPath(String path[]) |
checkPropertiesAccess | java.util.PropertyPermission "*", "read,write" |
java.io.File public boolean delete() public void deleteOnExit() |
checkDelete(String) | java.io.FilePermission "{name}", "delete" |
java.io.FileInputStream FileInputStream(FileDescriptor fdObj) |
checkRead(FileDescriptor) | java.lang.RuntimePermission "readFileDescriptor" |
java.io.FileInputStream FileInputStream(String name) FileInputStream(File file) java.io.File public boolean exists() public boolean canRead() public boolean isFile() public boolean isDirectory() public boolean isHidden() public long lastModified() public long length() public String[] list() public String[] list( FilenameFilter filter) public File[] listFiles() public File[] listFiles( FilenameFilter filter) public File[] listFiles( FileFilter filter) java.io.RandomAccessFile RandomAccessFile(String name, String mode) RandomAccessFile(File file, String mode) (where mode is "r" in both of these) |
checkRead(String) | java.io.FilePermission "{name}", "read" |
java.io.FileOutputStream FileOutputStream(FileDescriptor fdObj) |
checkWrite(FileDescriptor) | java.lang.RuntimePermission "writeFileDescriptor" |
java.io.FileOutputStream FileOutputStream(File file) FileOutputStream(String name) FileOutputStream(String name, boolean append) java.io.File public boolean canWrite() public boolean createNewFile() public static File createTempFile( String prefix, String suffix) public static File createTempFile( String prefix, String suffix, File directory) public boolean mkdir() public boolean mkdirs() public boolean renameTo(File dest) public boolean setLastModified(long time) public boolean setReadOnly() |
checkWrite(String) | java.io.FilePermission "{name}", "write" |
java.io.ObjectInputStream protected final boolean enableResolveObject(boolean enable); java.io.ObjectOutputStream protected final boolean enableReplaceObject(boolean enable) |
checkPermission | java.io.SerializablePermission "enableSubstitution" |
java.io.ObjectInputStream protected ObjectInputStream() java.io.ObjectOutputStream protected ObjectOutputStream() |
checkPermission | java.io.SerializablePermission "enableSubclassImplementation" |
java.io.RandomAccessFile RandomAccessFile(String name, String mode) (where mode is "rw") |
checkRead(String) and checkWrite(String) | java.io.FilePermission "{name}", "read,write" |
java.lang.Class public static Class forName( String name, boolean initialize, ClassLoader loader) |
checkPermission | If loader is null, and the caller's class loader
is not null, then
java.lang.RuntimePermission("getClassLoader") |
java.lang.Class public ClassLoader getClassLoader() |
checkPermission | If the caller's class loader is null, or is the same as or an
ancestor of the class loader for the class whose class loader is
being requested, no permission is needed. Otherwise, java.lang.RuntimePermission "getClassLoader" is required. |
java.lang.Class public Class[] getDeclaredClasses() public Field[] getDeclaredFields() public Method[] getDeclaredMethods() public Constructor[] getDeclaredConstructors() public Field getDeclaredField( String name) public Method getDeclaredMethod(...) public Constructor getDeclaredConstructor(...) |
checkMemberAccess(this, Member.DECLARED) and, if this class is in a package, checkPackageAccess({pkgName}) | Default checkMemberAccess does not require any permissions if "this" class's classloader is the same as that of the caller. Otherwise, it requires java.lang.RuntimePermission "accessDeclaredMembers". If this class is in a package, java.lang.RuntimePermission "accessClassInPackage.{pkgName}" is also required. |
java.lang.Class public Class[] getClasses() public Field[] getFields() public Method[] getMethods() public Constructor[] getConstructors() public Field getField(String name) public Method getMethod(...) public Constructor getConstructor(...) |
checkMemberAccess(this, Member.PUBLIC) and, if class is in a package, checkPackageAccess({pkgName}) | Default checkMemberAccess does not require any permissions when the access type is Member.PUBLIC. If this class is in a package, java.lang.RuntimePermission "accessClassInPackage.{pkgName}" is required. |
java.lang.Class public ProtectionDomain getProtectionDomain() |
checkPermission | java.lang.RuntimePermission "getProtectionDomain" |
java.lang.ClassLoader ClassLoader() ClassLoader(ClassLoader parent) |
checkCreateClassLoader | java.lang.RuntimePermission "createClassLoader" |
java.lang.ClassLoader public static ClassLoader getSystemClassLoader() public ClassLoader getParent() |
checkPermission | If the caller's class loader is null, or is the same as or an
ancestor of the class loader for the class whose class loader is
being requested, no permission is needed. Otherwise, java.lang.RuntimePermission "getClassLoader" is required. |
java.lang.Runtime public Process exec(String command) public Process exec(String command, String envp[]) public Process exec(String cmdarray[]) public Process exec(String cmdarray[], String envp[]) |
checkExec | java.io.FilePermission "{command}", "execute" |
java.lang.Runtime public void exit(int status) public static void runFinalizersOnExit(boolean value) java.lang.System public static void exit(int status) public static void runFinalizersOnExit(boolean value) |
checkExit(status) where status is 0 for runFinalizersOnExit | java.lang.RuntimePermission "exitVM.{status}" |
java.lang.Runtime public void addShutdownHook(Thread hook) public boolean removeShutdownHook(Thread hook) |
checkPermission | java.lang.RuntimePermission "shutdownHooks" |
java.lang.Runtime public void load(String lib) public void loadLibrary(String lib) java.lang.System public static void load(String filename) public static void loadLibrary( String libname) |
checkLink({libName}) where {libName} is the lib, filename or libname argument | java.lang.RuntimePermission "loadLibrary.{libName}" |
java.lang.SecurityManager methods |
checkPermission | See the next table. |
java.lang.System public static Properties getProperties() public static void setProperties(Properties props) |
checkPropertiesAccess | java.util.PropertyPermission "*", "read,write" |
java.lang.System public static String getProperty(String key) public static String getProperty(String key, String def) |
checkPropertyAccess | java.util.PropertyPermission "{key}", "read" |
java.lang.System public static void setIn(InputStream in) public static void setOut(PrintStream out) public static void setErr(PrintStream err) |
checkPermission | java.lang.RuntimePermission "setIO" |
java.lang.System public static String setProperty(String key, String value) |
checkPermission | java.util.PropertyPermission "{key}", "write" |
java.lang.System public static synchronized void setSecurityManager(SecurityManager s) |
checkPermission | java.lang.RuntimePermission "setSecurityManager" |
java.lang.Thread public ClassLoader getContextClassLoader() |
checkPermission | If the caller's class loader is null, or is the same as or an
ancestor of the context class loader for the thread whose context
class loader is being requested, no permission is needed.
Otherwise, java.lang.RuntimePermission "getClassLoader" is required. |
java.lang.Thread public void setContextClassLoader (ClassLoader cl) |
checkPermission | java.lang.RuntimePermission "setContextClassLoader" |
java.lang.Thread public final void checkAccess() public void interrupt() public final void suspend() public final void resume() public final void setPriority (int newPriority) public final void setName(String name) public final void setDaemon(boolean on) |
checkAccess(this) | java.lang.RuntimePermission "modifyThread" |
java.lang.Thread public static int enumerate(Thread tarray[]) |
checkAccess({threadGroup}) | java.lang.RuntimePermission "modifyThreadGroup" |
java.lang.Thread public final void stop() |
checkAccess(this). Also checkPermission if the current thread is trying to stop a thread other than itself. | java.lang.RuntimePermission "modifyThread". Also java.lang.RuntimePermission "stopThread" if the current thread is trying to stop a thread other than itself. |
java.lang.Thread public final synchronized void stop(Throwable obj) |
checkAccess(this). Also checkPermission if the current thread is trying to stop a thread other than itself or obj is not an instance of ThreadDeath. | java.lang.RuntimePermission "modifyThread". Also java.lang.RuntimePermission "stopThread" if the current thread is trying to stop a thread other than itself or obj is not an instance of ThreadDeath. |
java.lang.Thread Thread() Thread(Runnable target) Thread(String name) Thread(Runnable target, String name) java.lang.ThreadGroup ThreadGroup(String name) ThreadGroup(ThreadGroup parent, String name) |
checkAccess({parentThreadGroup}) | java.lang.RuntimePermission "modifyThreadGroup" |
java.lang.Thread Thread(ThreadGroup group, ...) java.lang.ThreadGroup public final void checkAccess() public int enumerate(Thread list[]) public int enumerate(Thread list[], boolean recurse) public int enumerate(ThreadGroup list[]) public int enumerate(ThreadGroup list[], boolean recurse) public final ThreadGroup getParent() public final void setDaemon(boolean daemon) public final void setMaxPriority(int pri) public final void suspend() public final void resume() public final void destroy() |
checkAccess(this) for ThreadGroup methods, or checkAccess(group) for Thread methods | java.lang.RuntimePermission "modifyThreadGroup" |
java.lang.ThreadGroup public final void interrupt() |
checkAccess(this) | Requires java.lang.RuntimePermission "modifyThreadGroup". Also requires java.lang.RuntimePermission "modifyThread", since the java.lang.Thread interrupt() method is called for each thread in the thread group and in all of its subgroups. See the Thread interrupt() method. |
java.lang.ThreadGroup public final void stop() |
checkAccess(this) | Requires java.lang.RuntimePermission "modifyThreadGroup". Also requires java.lang.RuntimePermission "modifyThread" and possibly java.lang.RuntimePermission "stopThread", since the java.lang.Thread stop() method is called for each thread in the thread group and in all of its subgroups. See the Thread stop() method. |
java.lang.reflect.AccessibleObject public static void setAccessible(...) public void setAccessible(...) |
checkPermission | java.lang.reflect.ReflectPermission "suppressAccessChecks" |
java.net.Authenticator public static PasswordAuthentication requestPasswordAuthentication( InetAddress addr, int port, String protocol, String prompt, String scheme) |
checkPermission | java.net.NetPermission "requestPasswordAuthentication" |
java.net.Authenticator public static void setDefault(Authenticator a) |
checkPermission | java.net.NetPermission "setDefaultAuthenticator" |
java.net.MulticastSocket public void joinGroup(InetAddress mcastaddr) public void leaveGroup(InetAddress mcastaddr) |
checkMulticast(InetAddress) | java.net.SocketPermission( mcastaddr.getHostAddress(), "accept,connect") |
java.net.DatagramSocket public void send(DatagramPacket p) |
checkMulticast(p.getAddress()) or checkConnect( p.getAddress().getHostAddress(), p.getPort()) |
if (p.getAddress().isMulticastAddress()) { java.net.SocketPermission( (p.getAddress()).getHostAddress(), "accept,connect") } else { port = p.getPort(); host = p.getAddress().getHostAddress(); if (port == -1) java.net.SocketPermission "{host}","resolve"; else java.net.SocketPermission "{host}:{port}","connect" } |
java.net.MulticastSocket public synchronized void send(DatagramPacket p, byte ttl) |
checkMulticast(p.getAddress(), ttl) or checkConnect( p.getAddress().getHostAddress(), p.getPort()) |
if (p.getAddress().isMulticastAddress()) { java.net.SocketPermission( (p.getAddress()).getHostAddress(), "accept,connect") } else { port = p.getPort(); host = p.getAddress().getHostAddress(); if (port == -1) java.net.SocketPermission "{host}","resolve"; else java.net.SocketPermission "{host}:{port}","connect" } |
java.net.InetAddress public String getHostName() public static InetAddress[] getAllByName(String host) public static InetAddress getLocalHost() java.net.DatagramSocket public InetAddress getLocalAddress() |
checkConnect({host}, -1) | java.net.SocketPermission "{host}", "resolve" |
java.net.ServerSocket ServerSocket(...) java.net.DatagramSocket DatagramSocket(...) java.net.MulticastSocket MulticastSocket(...) |
checkListen({port}) | java.net.SocketPermission "localhost:{port}","listen"; |
java.net.ServerSocket public Socket accept() protected final void implAccept(Socket s) |
checkAccept({host}, {port}) | java.net.SocketPermission "{host}:{port}", "accept" |
java.net.ServerSocket public static synchronized void setSocketFactory(...) java.net.Socket public static synchronized void setSocketImplFactory(...) java.net.URL public static synchronized void setURLStreamHandlerFactory(...) java.net.URLConnection public static synchronized void setContentHandlerFactory(...) public static void setFileNameMap(FileNameMap map) java.net.HttpURLConnection public static void setFollowRedirects(boolean set) java.rmi.activation.ActivationGroup public static synchronized ActivationGroup createGroup(...) public static synchronized void setSystem(ActivationSystem system) java.rmi.server.RMISocketFactory public synchronized static void setSocketFactory(...) |
checkSetFactory | java.lang.RuntimePermission "setFactory" |
java.net.Socket Socket(...) |
checkConnect({host}, {port}) | java.net.SocketPermission "{host}:{port}", "connect" |
java.net.DatagramSocket public synchronized void receive(DatagramPacket p) |
checkAccept({host}, {port}) | java.net.SocketPermission "{host}:{port}", "accept" |
java.net.URL URL(...) |
checkPermission | java.net.NetPermission "specifyStreamHandler" |
java.net.URLClassLoader URLClassLoader(...) |
checkCreateClassLoader | java.lang.RuntimePermission "createClassLoader" |
java.security.AccessControlContext public AccessControlContext(AccessControlContext acc, DomainCombiner combiner) public DomainCombiner getDomainCombiner() |
checkPermission | java.security.SecurityPermission "createAccessControlContext" |
java.security.Identity public void addCertificate(...) |
checkSecurityAccess( "addIdentityCertificate") |
java.security.SecurityPermission "addIdentityCertificate" |
java.security.Identity public void removeCertificate(...) |
checkSecurityAccess( "removeIdentityCertificate") |
java.security.SecurityPermission "removeIdentityCertificate" |
java.security.Identity public void setInfo(String info) |
checkSecurityAccess( "setIdentityInfo") |
java.security.SecurityPermission "setIdentityInfo" |
java.security.Identity public void setPublicKey(PublicKey key) |
checkSecurityAccess( "setIdentityPublicKey") |
java.security.SecurityPermission "setIdentityPublicKey" |
java.security.Identity public String toString(...) |
checkSecurityAccess( "printIdentity") |
java.security.SecurityPermission "printIdentity" |
java.security.IdentityScope protected static void setSystemScope() |
checkSecurityAccess( "setSystemScope") |
java.security.SecurityPermission "setSystemScope" |
java.security.Permission public void checkGuard(Object object) |
checkPermission(this) | this Permission object is the permission checked |
java.security.Policy public static Policy getPolicy() |
checkPermission | java.security.SecurityPermission "getPolicy" |
java.security.Policy public static void setPolicy(Policy policy) |
checkPermission | java.security.SecurityPermission "setPolicy" |
java.security.Policy public static Policy getInstance(String type, SpiParameter params) getInstance(String type, SpiParameter params, String provider) getInstance(String type, SpiParameter params, Provider provider) |
checkPermission | java.security.SecurityPermission "createPolicy.{type}" |
java.security.Provider public synchronized void clear() |
checkSecurityAccess( "clearProviderProperties."+{name}) |
java.security.SecurityPermission "clearProviderProperties.{name}" where name is the provider name. |
java.security.Provider public synchronized Object put(Object key, Object value) |
checkSecurityAccess( "putProviderProperty."+{name}) |
java.security.SecurityPermission "putProviderProperty.{name}" where name is the provider name. |
java.security.Provider public synchronized Object remove(Object key) |
checkSecurityAccess( "removeProviderProperty."+{name}) |
java.security.SecurityPermission "removeProviderProperty.{name}" where name is the provider name. |
java.security.SecureClassLoader SecureClassLoader(...) |
checkCreateClassLoader | java.lang.RuntimePermission "createClassLoader" |
java.security.Security public static void getProperty(String key) |
checkPermission | java.security.SecurityPermission "getProperty.{key}" |
java.security.Security public static int addProvider(Provider provider) public static int insertProviderAt(Provider provider, int position); |
checkSecurityAccess( "insertProvider."+provider.getName()) |
java.security.SecurityPermission "insertProvider.{name}" |
java.security.Security public static void removeProvider(String name) |
checkSecurityAccess( "removeProvider."+name) |
java.security.SecurityPermission "removeProvider.{name}" |
java.security.Security public static void setProperty(String key, String datum) |
checkSecurityAccess( "setProperty."+key) |
java.security.SecurityPermission "setProperty.{key}" |
java.security.Signer public PrivateKey getPrivateKey() |
checkSecurityAccess( "getSignerPrivateKey") |
java.security.SecurityPermission "getSignerPrivateKey" |
java.security.Signer public final void setKeyPair(KeyPair pair) |
checkSecurityAccess( "setSignerKeypair") |
java.security.SecurityPermission "setSignerKeypair" |
java.sql.DriverManager public static synchronized void setLogWriter(PrintWriter out) |
checkPermission | java.sql.SQLPermission "setLog" |
java.sql.DriverManager public static synchronized void setLogStream(PrintWriter out) |
checkPermission | java.sql.SQLPermission "setLog" |
java.util.Locale public static synchronized void setDefault(Locale newLocale) |
checkPermission | java.util.PropertyPermission "user.language","write" |
java.util.zip.ZipFile ZipFile(String name) |
checkRead | java.io.FilePermission "{name}","read" |
javax.security.auth.Subject public static Subject getSubject(final AccessControlContext acc) |
checkPermission | javax.security.auth.AuthPermission "getSubject" |
javax.security.auth.Subject public void setReadOnly() |
checkPermission | javax.security.auth.AuthPermission "setReadOnly" |
javax.security.auth.Subject public static Object doAs(final Subject subject, final PrivilegedAction action) |
checkPermission | javax.security.auth.AuthPermission "doAs" |
javax.security.auth.Subject public static Object doAs(final Subject subject, final PrivilegedExceptionAction action) throws java.security.PrivilegedActionException |
checkPermission | javax.security.auth.AuthPermission "doAs" |
javax.security.auth.Subject public static Object doAsPrivileged(final Subject subject, final PrivilegedAction action, final AccessControlContext acc) |
checkPermission | javax.security.auth.AuthPermission "doAsPrivileged" |
javax.security.auth.Subject public static Object doAsPrivileged(final Subject subject, final PrivilegedExceptionAction action, final AccessControlContext acc) throws java.security.PrivilegedActionException |
checkPermission | javax.security.auth.AuthPermission "doAsPrivileged" |
javax.security.auth.SubjectDomainCombiner public Subject getSubject() |
checkPermission | javax.security.auth.AuthPermission "getSubjectFromDomainCombiner" |
javax.security.auth.SubjectDomainCombiner public Subject getSubject() |
checkPermission | javax.security.auth.AuthPermission "getSubjectFromDomainCombiner" |
javax.security.auth.login.LoginContext public LoginContext(String name) throws LoginException |
checkPermission | javax.security.auth.AuthPermission "createLoginContext.{name}" |
javax.security.auth.login.LoginContext public LoginContext(String name, Subject subject) throws LoginException |
checkPermission | javax.security.auth.AuthPermission "createLoginContext.{name}" |
javax.security.auth.login.LoginContext public LoginContext(String name, CallbackHandler callbackHandler) throws LoginException |
checkPermission | javax.security.auth.AuthPermission "createLoginContext.{name}" |
javax.security.auth.login.LoginContext public LoginContext(String name, Subject subject, CallbackHandler callbackHandler) throws LoginException |
checkPermission | javax.security.auth.AuthPermission "createLoginContext.{name}" |
javax.security.auth.login.Configuration public static Configuration getConfiguration() |
checkPermission | javax.security.auth.AuthPermission "getLoginConfiguration" |
javax.security.auth.login.Configuration public static void setConfiguration(Configuration configuration) |
checkPermission | javax.security.auth.AuthPermission "setLoginConfiguration" |
javax.security.auth.login.Configuration public static void refresh() |
checkPermission | javax.security.auth.AuthPermission "refreshLoginConfiguration" |
javax.security.auth.login.Configuration public static Configuration getInstance(String type, SpiParameter params) getInstance(String type, SpiParameter params, String provider) getInstance(String type, SpiParameter params, Provider provider) |
checkPermission | javax.security.auth.AuthPermission "createLoginConfiguration.{type}" |
This table shows which permissions are checked for by the
default implementations of the
java.lang.SecurityManager
methods.
Each of the specified check
methods calls the
SecurityManager
checkPermission
method
with the specified permission, except for the
checkConnect
and checkRead
methods that
take a context argument. Those methods expect the context to be an
AccessControlContext
and they call the context's
checkPermission
method with the specified
permission.
Method | Permission |
---|---|
public void checkAccept(String host, int port); | java.net.SocketPermission "{host}:{port}", "accept"; |
public void checkAccess(Thread t); | java.lang.RuntimePermission "modifyThread"; |
public void checkAccess(ThreadGroup g); | java.lang.RuntimePermission "modifyThreadGroup"; |
public void checkAwtEventQueueAccess(); Note: This method is deprecated; use instead public void checkPermission(Permission perm); |
java.awt.AWTPermission "accessEventQueue"; |
public void checkConnect(String host, int port); | if (port == -1) java.net.SocketPermission
"{host}","resolve"; else java.net.SocketPermission "{host}:{port}","connect"; |
public void checkConnect(String host, int port, Object context); | if (port == -1) java.net.SocketPermission
"{host}","resolve"; else java.net.SocketPermission "{host}:{port}","connect"; |
public void checkCreateClassLoader(); | java.lang.RuntimePermission "createClassLoader"; |
public void checkDelete(String file); | java.io.FilePermission "{file}", "delete"; |
public void checkExec(String cmd); | if cmd is an absolute path: java.io.FilePermission "{cmd}",
"execute"; else java.io.FilePermission "<<ALL_FILES>>", "execute"; |
public void checkExit(int status); | java.lang.RuntimePermission "exitVM.{status}"; |
public void checkLink(String lib); | java.lang.RuntimePermission "loadLibrary.{lib}"; |
public void checkListen(int port); | java.net.SocketPermission "localhost:{port}","listen"; |
public void checkMemberAccess(Class clazz, int which); Note: This method is deprecated; use instead public void checkPermission(Permission perm); |
if (which != Member.PUBLIC) { if (currentClassLoader() != clazz.getClassLoader()) { checkPermission( new java.lang.RuntimePermission("accessDeclaredMembers")); } } |
public void checkMulticast(InetAddress maddr); | java.net.SocketPermission(maddr.getHostAddress(),"accept,connect"); |
public void checkMulticast(InetAddress maddr, byte ttl);
Note: This method is deprecated; use instead public void checkPermission(Permission perm); |
java.net.SocketPermission(maddr.getHostAddress(),"accept,connect"); |
public void checkPackageAccess(String pkg); | java.lang.RuntimePermission "accessClassInPackage.{pkg}"; |
public void checkPackageDefinition(String pkg); | java.lang.RuntimePermission "defineClassInPackage.{pkg}"; |
public void checkPrintJobAccess(); | java.lang.RuntimePermission "queuePrintJob"; |
public void checkPropertiesAccess(); | java.util.PropertyPermission "*", "read,write"; |
public void checkPropertyAccess(String key); | java.util.PropertyPermission "{key}", "read,write"; |
public void checkRead(FileDescriptor fd); | java.lang.RuntimePermission "readFileDescriptor"; |
public void checkRead(String file); | java.io.FilePermission "{file}", "read"; |
public void checkRead(String file, Object context); | java.io.FilePermission "{file}", "read"; |
public void checkSecurityAccess(String target); | java.security.SecurityPermission "{target}"; |
public void checkSetFactory(); | java.lang.RuntimePermission "setFactory"; |
public void checkSystemClipboardAccess(); Note: This method is deprecated; use instead public void checkPermission(Permission perm); |
java.awt.AWTPermission "accessClipboard"; |
public boolean checkTopLevelWindow(Object window); Note: This method is deprecated; use instead public void checkPermission(Permission perm); |
java.awt.AWTPermission "showWindowWithoutWarningBanner"; |
public void checkWrite(FileDescriptor fd); | java.lang.RuntimePermission "writeFileDescriptor"; |
public void checkWrite(String file); | java.io.FilePermission "{file}", "write"; |
public SecurityManager(); | java.lang.RuntimePermission "createSecurityManager"; |