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jdk.lang.instrument.Instrumentation

This class provides services needed to instrument Java programming language code. Instrumentation is the addition of byte-codes to methods for the purpose of gathering data to be utilized by tools. Since the changes are purely additive, these tools do not modify application state or behavior. Examples of such benign tools include monitoring agents, profilers, coverage analyzers, and event loggers.

There are two ways to obtain an instance of the Instrumentation interface:

When a JVM is launched in a way that indicates an agent class. In that case an Instrumentation instance is passed to the premain method of the agent class.

When a JVM provides a mechanism to start agents sometime after the JVM is launched. In that case an Instrumentation instance is passed to the agentmain method of the agent code.

These mechanisms are described in the package specification.

Once an agent acquires an Instrumentation instance, the agent may call methods on the instance at any time.

This class provides services needed to instrument Java
programming language code.
Instrumentation is the addition of byte-codes to methods for the
purpose of gathering data to be utilized by tools.
Since the changes are purely additive, these tools do not modify
application state or behavior.
Examples of such benign tools include monitoring agents, profilers,
coverage analyzers, and event loggers.


There are two ways to obtain an instance of the
Instrumentation interface:


   When a JVM is launched in a way that indicates an agent
    class. In that case an Instrumentation instance
    is passed to the premain method of the agent class.

   When a JVM provides a mechanism to start agents sometime
    after the JVM is launched. In that case an Instrumentation
    instance is passed to the agentmain method of the
    agent code.


These mechanisms are described in the
package specification.

Once an agent acquires an Instrumentation instance,
the agent may call methods on the instance at any time.
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add-transformerclj

(add-transformer this transformer)
(add-transformer this transformer can-retransform)

Registers the supplied transformer. All future class definitions will be seen by the transformer, except definitions of classes upon which any registered transformer is dependent. The transformer is called when classes are loaded, when they are redefined. and if canRetransform is true, when they are retransformed. See ClassFileTransformer.transform for the order of transform calls. If a transformer throws an exception during execution, the JVM will still call the other registered transformers in order. The same transformer may be added more than once, but it is strongly discouraged -- avoid this by creating a new instance of transformer class.

This method is intended for use in instrumentation, as described in the java.lang.instrument.class specification.

transformer - the transformer to register - java.lang.instrument.ClassFileTransformer can-retransform - can this transformer's transformations be retransformed - boolean

throws: java.lang.NullPointerException - if passed a null transformer

Registers the supplied transformer. All future class definitions
 will be seen by the transformer, except definitions of classes upon which any
 registered transformer is dependent.
 The transformer is called when classes are loaded, when they are
 redefined. and if canRetransform is true,
 when they are retransformed.
 See ClassFileTransformer.transform for the order
 of transform calls.
 If a transformer throws
 an exception during execution, the JVM will still call the other registered
 transformers in order. The same transformer may be added more than once,
 but it is strongly discouraged -- avoid this by creating a new instance of
 transformer class.

 This method is intended for use in instrumentation, as described in the
 java.lang.instrument.class specification.

transformer - the transformer to register - `java.lang.instrument.ClassFileTransformer`
can-retransform - can this transformer's transformations be retransformed - `boolean`

throws: java.lang.NullPointerException - if passed a null transformer
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(append-to-bootstrap-class-loader-search this jarfile)

Specifies a JAR file with instrumentation classes to be defined by the bootstrap class loader.

When the virtual machine's built-in class loader, known as the "bootstrap class loader", unsuccessfully searches for a class, the entries in the JAR file will be searched as well.

This method may be used multiple times to add multiple JAR files to be searched in the order that this method was invoked.

The agent should take care to ensure that the JAR does not contain any classes or resources other than those to be defined by the bootstrap class loader for the purpose of instrumentation. Failure to observe this warning could result in unexpected behavior that is difficult to diagnose. For example, suppose there is a loader L, and L's parent for delegation is the bootstrap class loader. Furthermore, a method in class C, a class defined by L, makes reference to a non-public accessor class C$1. If the JAR file contains a class C$1 then the delegation to the bootstrap class loader will cause C$1 to be defined by the bootstrap class loader. In this example an IllegalAccessError will be thrown that may cause the application to fail. One approach to avoiding these types of issues, is to use a unique package name for the instrumentation classes.

The Java™ Virtual Machine Specification specifies that a subsequent attempt to resolve a symbolic reference that the Java virtual machine has previously unsuccessfully attempted to resolve always fails with the same error that was thrown as a result of the initial resolution attempt. Consequently, if the JAR file contains an entry that corresponds to a class for which the Java virtual machine has unsuccessfully attempted to resolve a reference, then subsequent attempts to resolve that reference will fail with the same error as the initial attempt.

jarfile - The JAR file to be searched when the bootstrap class loader unsuccessfully searches for a class. - java.util.jar.JarFile

throws: java.lang.NullPointerException - If jarfile is null.

Specifies a JAR file with instrumentation classes to be defined by the
 bootstrap class loader.

  When the virtual machine's built-in class loader, known as the "bootstrap
 class loader", unsuccessfully searches for a class, the entries in the JAR file will be searched as well.

  This method may be used multiple times to add multiple JAR files to be
 searched in the order that this method was invoked.

  The agent should take care to ensure that the JAR does not contain any
 classes or resources other than those to be defined by the bootstrap
 class loader for the purpose of instrumentation.
 Failure to observe this warning could result in unexpected
 behavior that is difficult to diagnose. For example, suppose there is a
 loader L, and L's parent for delegation is the bootstrap class loader.
 Furthermore, a method in class C, a class defined by L, makes reference to
 a non-public accessor class C$1. If the JAR file contains a class C$1 then
 the delegation to the bootstrap class loader will cause C$1 to be defined
 by the bootstrap class loader. In this example an IllegalAccessError
 will be thrown that may cause the application to fail. One approach to
 avoiding these types of issues, is to use a unique package name for the
 instrumentation classes.


 The Java™ Virtual Machine Specification
 specifies that a subsequent attempt to resolve a symbolic
 reference that the Java virtual machine has previously unsuccessfully attempted
 to resolve always fails with the same error that was thrown as a result of the
 initial resolution attempt. Consequently, if the JAR file contains an entry
 that corresponds to a class for which the Java virtual machine has
 unsuccessfully attempted to resolve a reference, then subsequent attempts to
 resolve that reference will fail with the same error as the initial attempt.

jarfile - The JAR file to be searched when the bootstrap class loader unsuccessfully searches for a class. - `java.util.jar.JarFile`

throws: java.lang.NullPointerException - If jarfile is null.
raw docstring

(append-to-system-class-loader-search this jarfile)

Specifies a JAR file with instrumentation classes to be defined by the system class loader.

When the system class loader for delegation (see getSystemClassLoader()) unsuccessfully searches for a class, the entries in the JarFile will be searched as well.

This method may be used multiple times to add multiple JAR files to be searched in the order that this method was invoked.

The agent should take care to ensure that the JAR does not contain any classes or resources other than those to be defined by the system class loader for the purpose of instrumentation. Failure to observe this warning could result in unexpected behavior that is difficult to diagnose (see appendToBootstrapClassLoaderSearch).

The system class loader supports adding a JAR file to be searched if it implements a method named appendToClassPathForInstrumentation which takes a single parameter of type java.lang.String. The method is not required to have public access. The name of the JAR file is obtained by invoking the getName() method on the jarfile and this is provided as the parameter to the appendToClassPathForInstrumentation method.

The Java™ Virtual Machine Specification specifies that a subsequent attempt to resolve a symbolic reference that the Java virtual machine has previously unsuccessfully attempted to resolve always fails with the same error that was thrown as a result of the initial resolution attempt. Consequently, if the JAR file contains an entry that corresponds to a class for which the Java virtual machine has unsuccessfully attempted to resolve a reference, then subsequent attempts to resolve that reference will fail with the same error as the initial attempt.

This method does not change the value of java.class.path system property.

jarfile - The JAR file to be searched when the system class loader unsuccessfully searches for a class. - java.util.jar.JarFile

throws: java.lang.UnsupportedOperationException - If the system class loader does not support appending a a JAR file to be searched.

Specifies a JAR file with instrumentation classes to be defined by the
 system class loader.

 When the system class loader for delegation (see
 getSystemClassLoader())
 unsuccessfully searches for a class, the entries in the JarFile will be searched as well.

  This method may be used multiple times to add multiple JAR files to be
 searched in the order that this method was invoked.

  The agent should take care to ensure that the JAR does not contain any
 classes or resources other than those to be defined by the system class
 loader for the purpose of instrumentation.
 Failure to observe this warning could result in unexpected
 behavior that is difficult to diagnose (see
 appendToBootstrapClassLoaderSearch).

  The system class loader supports adding a JAR file to be searched if
 it implements a method named appendToClassPathForInstrumentation
 which takes a single parameter of type java.lang.String. The
 method is not required to have public access. The name of
 the JAR file is obtained by invoking the getName() method on the jarfile and this is provided as the
 parameter to the appendToClassPathForInstrumentation method.


 The Java™ Virtual Machine Specification
 specifies that a subsequent attempt to resolve a symbolic
 reference that the Java virtual machine has previously unsuccessfully attempted
 to resolve always fails with the same error that was thrown as a result of the
 initial resolution attempt. Consequently, if the JAR file contains an entry
 that corresponds to a class for which the Java virtual machine has
 unsuccessfully attempted to resolve a reference, then subsequent attempts to
 resolve that reference will fail with the same error as the initial attempt.

  This method does not change the value of java.class.path
 system property.

jarfile - The JAR file to be searched when the system class loader unsuccessfully searches for a class. - `java.util.jar.JarFile`

throws: java.lang.UnsupportedOperationException - If the system class loader does not support appending a a JAR file to be searched.
raw docstring

get-all-loaded-classesclj

(get-all-loaded-classes this)

Returns an array of all classes currently loaded by the JVM.

returns: an array containing all the classes loaded by the JVM, zero-length if there are none - java.lang.Class[]

Returns an array of all classes currently loaded by the JVM.

returns: an array containing all the classes loaded by the JVM, zero-length if there are none - `java.lang.Class[]`
raw docstring

get-initiated-classesclj

(get-initiated-classes this loader)

Returns an array of all classes for which loader is an initiating loader. If the supplied loader is null, classes initiated by the bootstrap class loader are returned.

loader - the loader whose initiated class list will be returned - java.lang.ClassLoader

returns: an array containing all the classes for which loader is an initiating loader, zero-length if there are none - java.lang.Class[]

Returns an array of all classes for which loader is an initiating loader.
 If the supplied loader is null, classes initiated by the bootstrap class
 loader are returned.

loader - the loader whose initiated class list will be returned - `java.lang.ClassLoader`

returns: an array containing all the classes for which loader is an initiating loader,
          zero-length if there are none - `java.lang.Class[]`
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get-object-sizeclj

(get-object-size this object-to-size)

Returns an implementation-specific approximation of the amount of storage consumed by the specified object. The result may include some or all of the object's overhead, and thus is useful for comparison within an implementation but not between implementations.

The estimate may change during a single invocation of the JVM.

object-to-size - the object to size - java.lang.Object

returns: an implementation-specific approximation of the amount of storage consumed by the specified object - long

throws: java.lang.NullPointerException - if the supplied Object is null.

Returns an implementation-specific approximation of the amount of storage consumed by
 the specified object. The result may include some or all of the object's overhead,
 and thus is useful for comparison within an implementation but not between implementations.

 The estimate may change during a single invocation of the JVM.

object-to-size - the object to size - `java.lang.Object`

returns: an implementation-specific approximation of the amount of storage consumed by the specified object - `long`

throws: java.lang.NullPointerException - if the supplied Object is null.
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modifiable-class?clj

(modifiable-class? this the-class)

Determines whether a class is modifiable by retransformation or redefinition. If a class is modifiable then this method returns true. If a class is not modifiable then this method returns false.

For a class to be retransformed, isRetransformClassesSupported() must also be true. But the value of isRetransformClassesSupported() does not influence the value returned by this function. For a class to be redefined, isRedefineClassesSupported() must also be true. But the value of isRedefineClassesSupported() does not influence the value returned by this function.

Primitive classes (for example, java.lang.Integer.TYPE) and array classes are never modifiable.

the-class - the class to check for being modifiable - java.lang.Class

returns: whether or not the argument class is modifiable - boolean

throws: java.lang.NullPointerException - if the specified class is null.

Determines whether a class is modifiable by
 retransformation
 or redefinition.
 If a class is modifiable then this method returns true.
 If a class is not modifiable then this method returns false.

 For a class to be retransformed, isRetransformClassesSupported() must also be true.
 But the value of isRetransformClassesSupported() does not influence the value
 returned by this function.
 For a class to be redefined, isRedefineClassesSupported() must also be true.
 But the value of isRedefineClassesSupported() does not influence the value
 returned by this function.

 Primitive classes (for example, java.lang.Integer.TYPE)
 and array classes are never modifiable.

the-class - the class to check for being modifiable - `java.lang.Class`

returns: whether or not the argument class is modifiable - `boolean`

throws: java.lang.NullPointerException - if the specified class is null.
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native-method-prefix-supported?clj

(native-method-prefix-supported? this)

Returns whether the current JVM configuration supports setting a native method prefix. The ability to set a native method prefix is an optional capability of a JVM. Setting a native method prefix will only be supported if the Can-Set-Native-Method-Prefix manifest attribute is set to true in the agent JAR file (as described in the package specification) and the JVM supports this capability. During a single instantiation of a single JVM, multiple calls to this method will always return the same answer.

returns: true if the current JVM configuration supports setting a native method prefix, false if not. - boolean

Returns whether the current JVM configuration supports
 setting a native method prefix.
 The ability to set a native method prefix is an optional
 capability of a JVM.
 Setting a native method prefix will only be supported if the
 Can-Set-Native-Method-Prefix manifest attribute is set to
 true in the agent JAR file (as described in the
 package specification) and the JVM supports
 this capability.
 During a single instantiation of a single JVM, multiple
 calls to this method will always return the same answer.

returns: true if the current JVM configuration supports
 setting a native method prefix, false if not. - `boolean`
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redefine-classesclj

(redefine-classes this definitions)

Redefine the supplied set of classes using the supplied class files.

This method is used to replace the definition of a class without reference to the existing class file bytes, as one might do when recompiling from source for fix-and-continue debugging. Where the existing class file bytes are to be transformed (for example in bytecode instrumentation) retransformClasses should be used.

This method operates on a set in order to allow interdependent changes to more than one class at the same time (a redefinition of class A can require a redefinition of class B).

If a redefined method has active stack frames, those active frames continue to run the bytecodes of the original method. The redefined method will be used on new invokes.

This method does not cause any initialization except that which would occur under the customary JVM semantics. In other words, redefining a class does not cause its initializers to be run. The values of static variables will remain as they were prior to the call.

Instances of the redefined class are not affected.

The redefinition may change method bodies, the constant pool and attributes. The redefinition must not add, remove or rename fields or methods, change the signatures of methods, or change inheritance. These restrictions maybe be lifted in future versions. The class file bytes are not checked, verified and installed until after the transformations have been applied, if the resultant bytes are in error this method will throw an exception.

If this method throws an exception, no classes have been redefined.

This method is intended for use in instrumentation, as described in the java.lang.instrument.class specification.

definitions - array of classes to redefine with corresponding definitions; a zero-length array is allowed, in this case, this method does nothing - java.lang.instrument.ClassDefinition

throws: java.lang.NullPointerException - if the supplied definitions array or any of its components is null

Redefine the supplied set of classes using the supplied class files.


 This method is used to replace the definition of a class without reference
 to the existing class file bytes, as one might do when recompiling from source
 for fix-and-continue debugging.
 Where the existing class file bytes are to be transformed (for
 example in bytecode instrumentation)
 retransformClasses
 should be used.


 This method operates on
 a set in order to allow interdependent changes to more than one class at the same time
 (a redefinition of class A can require a redefinition of class B).


 If a redefined method has active stack frames, those active frames continue to
 run the bytecodes of the original method.
 The redefined method will be used on new invokes.


 This method does not cause any initialization except that which would occur
 under the customary JVM semantics. In other words, redefining a class
 does not cause its initializers to be run. The values of static variables
 will remain as they were prior to the call.


 Instances of the redefined class are not affected.


 The redefinition may change method bodies, the constant pool and attributes.
 The redefinition must not add, remove or rename fields or methods, change the
 signatures of methods, or change inheritance.  These restrictions maybe be
 lifted in future versions.  The class file bytes are not checked, verified and installed
 until after the transformations have been applied, if the resultant bytes are in
 error this method will throw an exception.


 If this method throws an exception, no classes have been redefined.

 This method is intended for use in instrumentation, as described in the
 java.lang.instrument.class specification.

definitions - array of classes to redefine with corresponding definitions; a zero-length array is allowed, in this case, this method does nothing - `java.lang.instrument.ClassDefinition`

throws: java.lang.NullPointerException - if the supplied definitions array or any of its components is null
raw docstring

redefine-classes-supported?clj

(redefine-classes-supported? this)

Returns whether or not the current JVM configuration supports redefinition of classes. The ability to redefine an already loaded class is an optional capability of a JVM. Redefinition will only be supported if the Can-Redefine-Classes manifest attribute is set to true in the agent JAR file (as described in the package specification) and the JVM supports this capability. During a single instantiation of a single JVM, multiple calls to this method will always return the same answer.

returns: true if the current JVM configuration supports redefinition of classes, false if not. - boolean

Returns whether or not the current JVM configuration supports redefinition
 of classes.
 The ability to redefine an already loaded class is an optional capability
 of a JVM.
 Redefinition will only be supported if the
 Can-Redefine-Classes manifest attribute is set to
 true in the agent JAR file (as described in the
 package specification) and the JVM supports
 this capability.
 During a single instantiation of a single JVM, multiple calls to this
 method will always return the same answer.

returns: true if the current JVM configuration supports redefinition of classes,
 false if not. - `boolean`
raw docstring

remove-transformerclj

(remove-transformer this transformer)

Unregisters the supplied transformer. Future class definitions will not be shown to the transformer. Removes the most-recently-added matching instance of the transformer. Due to the multi-threaded nature of class loading, it is possible for a transformer to receive calls after it has been removed. Transformers should be written defensively to expect this situation.

transformer - the transformer to unregister - java.lang.instrument.ClassFileTransformer

returns: true if the transformer was found and removed, false if the transformer was not found - boolean

throws: java.lang.NullPointerException - if passed a null transformer

Unregisters the supplied transformer. Future class definitions will
 not be shown to the transformer. Removes the most-recently-added matching
 instance of the transformer. Due to the multi-threaded nature of
 class loading, it is possible for a transformer to receive calls
 after it has been removed. Transformers should be written defensively
 to expect this situation.

transformer - the transformer to unregister - `java.lang.instrument.ClassFileTransformer`

returns: true if the transformer was found and removed, false if the
           transformer was not found - `boolean`

throws: java.lang.NullPointerException - if passed a null transformer
raw docstring

retransform-classesclj

(retransform-classes this classes)

Retransform the supplied set of classes.

This function facilitates the instrumentation of already loaded classes. When classes are initially loaded or when they are redefined, the initial class file bytes can be transformed with the ClassFileTransformer. This function reruns the transformation process (whether or not a transformation has previously occurred). This retransformation follows these steps:

starting from the initial class file bytes

for each transformer that was added with canRetransform
  false, the bytes returned by
  transform
  during the last class load or redefine are
  reused as the output of the transformation; note that this is
  equivalent to reapplying the previous transformation, unaltered;
  except that
  transform
  is not called

for each transformer that was added with canRetransform
  true, the
  transform
  method is called in these transformers

the transformed class file bytes are installed as the new
  definition of the class

The order of transformation is described in the transform method. This same order is used in the automatic reapplication of retransformation incapable transforms.

The initial class file bytes represent the bytes passed to ClassLoader.defineClass or redefineClasses (before any transformations were applied), however they might not exactly match them. The constant pool might not have the same layout or contents. The constant pool may have more or fewer entries. Constant pool entries may be in a different order; however, constant pool indices in the bytecodes of methods will correspond. Some attributes may not be present. Where order is not meaningful, for example the order of methods, order might not be preserved.

This method operates on a set in order to allow interdependent changes to more than one class at the same time (a retransformation of class A can require a retransformation of class B).

If a retransformed method has active stack frames, those active frames continue to run the bytecodes of the original method. The retransformed method will be used on new invokes.

This method does not cause any initialization except that which would occur under the customary JVM semantics. In other words, redefining a class does not cause its initializers to be run. The values of static variables will remain as they were prior to the call.

Instances of the retransformed class are not affected.

The retransformation may change method bodies, the constant pool and attributes. The retransformation must not add, remove or rename fields or methods, change the signatures of methods, or change inheritance. These restrictions maybe be lifted in future versions. The class file bytes are not checked, verified and installed until after the transformations have been applied, if the resultant bytes are in error this method will throw an exception.

If this method throws an exception, no classes have been retransformed.

This method is intended for use in instrumentation, as described in the java.lang.instrument.class specification.

classes - array of classes to retransform; a zero-length array is allowed, in this case, this method does nothing - java.lang.Class

throws: java.lang.instrument.UnmodifiableClassException - if a specified class cannot be modified (isModifiableClass(java.lang.Class<?>) would return false)

Retransform the supplied set of classes.


 This function facilitates the instrumentation
 of already loaded classes.
 When classes are initially loaded or when they are
 redefined,
 the initial class file bytes can be transformed with the
 ClassFileTransformer.
 This function reruns the transformation process
 (whether or not a transformation has previously occurred).
 This retransformation follows these steps:

    starting from the initial class file bytes

    for each transformer that was added with canRetransform
      false, the bytes returned by
      transform
      during the last class load or redefine are
      reused as the output of the transformation; note that this is
      equivalent to reapplying the previous transformation, unaltered;
      except that
      transform
      is not called

    for each transformer that was added with canRetransform
      true, the
      transform
      method is called in these transformers

    the transformed class file bytes are installed as the new
      definition of the class




 The order of transformation is described in the
 transform method.
 This same order is used in the automatic reapplication of retransformation
 incapable transforms.


 The initial class file bytes represent the bytes passed to
 ClassLoader.defineClass or
 redefineClasses
 (before any transformations
  were applied), however they might not exactly match them.
  The constant pool might not have the same layout or contents.
  The constant pool may have more or fewer entries.
  Constant pool entries may be in a different order; however,
  constant pool indices in the bytecodes of methods will correspond.
  Some attributes may not be present.
  Where order is not meaningful, for example the order of methods,
  order might not be preserved.


 This method operates on
 a set in order to allow interdependent changes to more than one class at the same time
 (a retransformation of class A can require a retransformation of class B).


 If a retransformed method has active stack frames, those active frames continue to
 run the bytecodes of the original method.
 The retransformed method will be used on new invokes.


 This method does not cause any initialization except that which would occur
 under the customary JVM semantics. In other words, redefining a class
 does not cause its initializers to be run. The values of static variables
 will remain as they were prior to the call.


 Instances of the retransformed class are not affected.


 The retransformation may change method bodies, the constant pool and attributes.
 The retransformation must not add, remove or rename fields or methods, change the
 signatures of methods, or change inheritance.  These restrictions maybe be
 lifted in future versions.  The class file bytes are not checked, verified and installed
 until after the transformations have been applied, if the resultant bytes are in
 error this method will throw an exception.


 If this method throws an exception, no classes have been retransformed.

 This method is intended for use in instrumentation, as described in the
 java.lang.instrument.class specification.

classes - array of classes to retransform; a zero-length array is allowed, in this case, this method does nothing - `java.lang.Class`

throws: java.lang.instrument.UnmodifiableClassException - if a specified class cannot be modified (isModifiableClass(java.lang.Class<?>) would return false)
raw docstring

retransform-classes-supported?clj

(retransform-classes-supported? this)

Returns whether or not the current JVM configuration supports retransformation of classes. The ability to retransform an already loaded class is an optional capability of a JVM. Retransformation will only be supported if the Can-Retransform-Classes manifest attribute is set to true in the agent JAR file (as described in the package specification) and the JVM supports this capability. During a single instantiation of a single JVM, multiple calls to this method will always return the same answer.

returns: true if the current JVM configuration supports retransformation of classes, false if not. - boolean

Returns whether or not the current JVM configuration supports retransformation
 of classes.
 The ability to retransform an already loaded class is an optional capability
 of a JVM.
 Retransformation will only be supported if the
 Can-Retransform-Classes manifest attribute is set to
 true in the agent JAR file (as described in the
 package specification) and the JVM supports
 this capability.
 During a single instantiation of a single JVM, multiple calls to this
 method will always return the same answer.

returns: true if the current JVM configuration supports retransformation of
          classes, false if not. - `boolean`
raw docstring

set-native-method-prefixclj

(set-native-method-prefix this transformer prefix)

This method modifies the failure handling of native method resolution by allowing retry with a prefix applied to the name. When used with the ClassFileTransformer, it enables native methods to be instrumented.

Since native methods cannot be directly instrumented (they have no bytecodes), they must be wrapped with a non-native method which can be instrumented. For example, if we had:

native boolean foo(int x);

We could transform the class file (with the ClassFileTransformer during the initial definition of the class) so that this becomes:

boolean foo(int x) { ... record entry to foo ... return wrapped_foo(x); }

native boolean wrapped_foo(int x);

Where foo becomes a wrapper for the actual native method with the appended prefix "wrapped_". Note that "wrapped_" would be a poor choice of prefix since it might conceivably form the name of an existing method thus something like "$$$MyAgentWrapped$$$_" would be better but would make these examples less readable.

The wrapper will allow data to be collected on the native method call, but now the problem becomes linking up the wrapped method with the native implementation. That is, the method wrapped_foo needs to be resolved to the native implementation of foo, which might be:

Java_somePackage_someClass_foo(JNIEnv* env, jint x)

This function allows the prefix to be specified and the proper resolution to occur. Specifically, when the standard resolution fails, the resolution is retried taking the prefix into consideration. There are two ways that resolution occurs, explicit resolution with the JNI function RegisterNatives and the normal automatic resolution. For RegisterNatives, the JVM will attempt this association:

method(foo) -> nativeImplementation(foo)

When this fails, the resolution will be retried with the specified prefix prepended to the method name, yielding the correct resolution:

method(wrapped_foo) -> nativeImplementation(foo)

For automatic resolution, the JVM will attempt:

method(wrapped_foo) -> nativeImplementation(wrapped_foo)

When this fails, the resolution will be retried with the specified prefix deleted from the implementation name, yielding the correct resolution:

method(wrapped_foo) -> nativeImplementation(foo)

Note that since the prefix is only used when standard resolution fails, native methods can be wrapped selectively.

Since each ClassFileTransformer can do its own transformation of the bytecodes, more than one layer of wrappers may be applied. Thus each transformer needs its own prefix. Since transformations are applied in order, the prefixes, if applied, will be applied in the same order (see addTransformer). Thus if three transformers applied wrappers, foo might become $trans3_$trans2_$trans1_foo. But if, say, the second transformer did not apply a wrapper to foo it would be just $trans3_$trans1_foo. To be able to efficiently determine the sequence of prefixes, an intermediate prefix is only applied if its non-native wrapper exists. Thus, in the last example, even though $trans1_foo is not a native method, the $trans1_ prefix is applied since $trans1_foo exists.

transformer - The ClassFileTransformer which wraps using this prefix. - java.lang.instrument.ClassFileTransformer prefix - The prefix to apply to wrapped native methods when retrying a failed native method resolution. If prefix is either null or the empty string, then failed native method resolutions are not retried for this transformer. - java.lang.String

throws: java.lang.NullPointerException - if passed a null transformer.

This method modifies the failure handling of
 native method resolution by allowing retry
 with a prefix applied to the name.
 When used with the
 ClassFileTransformer,
 it enables native methods to be
 instrumented.

 Since native methods cannot be directly instrumented
 (they have no bytecodes), they must be wrapped with
 a non-native method which can be instrumented.
 For example, if we had:


   native boolean foo(int x);

 We could transform the class file (with the
 ClassFileTransformer during the initial definition
 of the class) so that this becomes:


   boolean foo(int x) {
     ... record entry to foo ...
     return wrapped_foo(x);
   }

   native boolean wrapped_foo(int x);

 Where foo becomes a wrapper for the actual native
 method with the appended prefix "wrapped_".  Note that
 "wrapped_" would be a poor choice of prefix since it
 might conceivably form the name of an existing method
 thus something like "$$$MyAgentWrapped$$$_" would be
 better but would make these examples less readable.

 The wrapper will allow data to be collected on the native
 method call, but now the problem becomes linking up the
 wrapped method with the native implementation.
 That is, the method wrapped_foo needs to be
 resolved to the native implementation of foo,
 which might be:


   Java_somePackage_someClass_foo(JNIEnv* env, jint x)

 This function allows the prefix to be specified and the
 proper resolution to occur.
 Specifically, when the standard resolution fails, the
 resolution is retried taking the prefix into consideration.
 There are two ways that resolution occurs, explicit
 resolution with the JNI function RegisterNatives
 and the normal automatic resolution.  For
 RegisterNatives, the JVM will attempt this
 association:


   method(foo) -> nativeImplementation(foo)

 When this fails, the resolution will be retried with
 the specified prefix prepended to the method name,
 yielding the correct resolution:


   method(wrapped_foo) -> nativeImplementation(foo)

 For automatic resolution, the JVM will attempt:


   method(wrapped_foo) -> nativeImplementation(wrapped_foo)

 When this fails, the resolution will be retried with
 the specified prefix deleted from the implementation name,
 yielding the correct resolution:


   method(wrapped_foo) -> nativeImplementation(foo)

 Note that since the prefix is only used when standard
 resolution fails, native methods can be wrapped selectively.

 Since each ClassFileTransformer
 can do its own transformation of the bytecodes, more
 than one layer of wrappers may be applied. Thus each
 transformer needs its own prefix.  Since transformations
 are applied in order, the prefixes, if applied, will
 be applied in the same order
 (see addTransformer).
 Thus if three transformers applied
 wrappers, foo might become
 $trans3_$trans2_$trans1_foo.  But if, say,
 the second transformer did not apply a wrapper to
 foo it would be just
 $trans3_$trans1_foo.  To be able to
 efficiently determine the sequence of prefixes,
 an intermediate prefix is only applied if its non-native
 wrapper exists.  Thus, in the last example, even though
 $trans1_foo is not a native method, the
 $trans1_ prefix is applied since
 $trans1_foo exists.

transformer - The ClassFileTransformer which wraps using this prefix. - `java.lang.instrument.ClassFileTransformer`
prefix - The prefix to apply to wrapped native methods when retrying a failed native method resolution. If prefix is either null or the empty string, then failed native method resolutions are not retried for this transformer. - `java.lang.String`

throws: java.lang.NullPointerException - if passed a null transformer.
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