.. _api:
API
===
.. module:: jnius
This part of the documentation covers all the interfaces of *jtypes.pyjnius*.
Reflection classes
------------------
.. class:: JavaClass
Base for reflecting a Java class. The idea is to subclass this JavaClass,
add few :class:`JavaMethod`, :class:`JavaStaticMethod`, :class:`JavaField`,
:class:`JavaStaticField`, and you're done.
You need to define at minimum the :data:`__javaclass__` attribute, and set
the :data:`__metaclass__` to :class:`MetaJavaClass`.
So the minimum class definition would look like::
from jt.jnius import JavaClass, MetaJavaClass
class Stack(JavaClass):
__javaclass__ = 'java/util/Stack'
__metaclass__ = MetaJavaClass
.. attribute:: __metaclass__
Must be set to :class:`MetaJavaClass`, otherwise, all the
methods/fields declared will be not linked to the JavaClass.
.. note::
Make sure to choose the right metaclass specifier. In Python 2
there is ``__metaclass__`` class attribute, in Python 3 there is
a new syntax ``class Stack(JavaClass, metaclass=MetaJavaClass)``.
For more info see `PEP 3115
`_.
.. attribute:: __javaclass__
Represents the Java class name, in the format 'org/lang/Class' (e.g.
'java/util/Stack'), not 'org.lang.Class'.
.. attribute:: __javaconstructor__
If not set, we assume the default constructor takes no parameters.
Otherwise, it can be a list of all possible signatures of the
constructor. For example, a reflection of the String java class would
look like::
class String(JavaClass):
__javaclass__ = 'java/lang/String'
__metaclass__ = MetaJavaClass
__javaconstructor__ = (
'()V',
'(Ljava/lang/String;)V',
'([C)V',
'([CII)V',
# ...
)
.. class:: JavaMethod
Reflection of a Java method.
.. method:: __init__(signature, static=False)
Create a reflection of a Java method. The signature is in the JNI
format. For example::
class Stack(JavaClass):
__javaclass__ = 'java/util/Stack'
__metaclass__ = MetaJavaClass
peek = JavaMethod('()Ljava/lang/Object;')
empty = JavaMethod('()Z')
The name associated with the method is automatically set from the
declaration within the JavaClass itself.
The signature can be found with `javap -s`. For example, if you
want to fetch the signatures available for `java.util.Stack`::
$ javap -s java.util.Stack
Compiled from "Stack.java"
public class java.util.Stack extends java.util.Vector{
public java.util.Stack();
Signature: ()V
public java.lang.Object push(java.lang.Object);
Signature: (Ljava/lang/Object;)Ljava/lang/Object;
public synchronized java.lang.Object pop();
Signature: ()Ljava/lang/Object;
public synchronized java.lang.Object peek();
Signature: ()Ljava/lang/Object;
public boolean empty();
Signature: ()Z
public synchronized int search(java.lang.Object);
Signature: (Ljava/lang/Object;)I
}
.. class:: JavaStaticMethod
Reflection of a static Java method.
.. class:: JavaField
Reflection of a Java field.
.. method:: __init__(signature, static=False)
Create a reflection of a Java field. The signature is in the JNI
format. For example::
class System(JavaClass):
__javaclass__ = 'java/lang/System'
__metaclass__ = MetaJavaClass
out = JavaField('()Ljava/io/InputStream;', static=True)
The name associated to the method is automatically set from the
declaration within the JavaClass itself.
.. class:: JavaStaticField
Reflection of a static Java field.
.. class:: JavaMultipleMethod
Reflection of a Java method that can be called from multiple signatures.
For example, the method `getBytes` in the `String` class can be called
from::
public byte[] getBytes(java.lang.String)
public byte[] getBytes(java.nio.charset.Charset)
public byte[] getBytes()
Let's see how you could declare that method::
class String(JavaClass):
__javaclass__ = 'java/lang/String'
__metaclass__ = MetaJavaClass
getBytes = JavaMultipleMethod([
'(Ljava/lang/String;)[B',
'(Ljava/nio/charset/Charset;)[B',
'()[B'])
Then, when you try to access this method, it will choose the best
method available according to the type of the arguments you're using.
Internally, we calculate a "match" score for each available
signature, and take the best one. Without going into the details, the score
calculation looks something like:
* a direct type match is +10
* a indirect type match (like using a `float` for an `int` argument) is +5
* object with unknown type (:class:`JavaObject`) is +1
* otherwise, it's considered as an error case, and returns -1
Reflection functions
--------------------
.. function:: autoclass(name)
Return a :class:`JavaClass` that represents the class passed from `name`.
The name must be written in the format `a.b.c`, not `a/b/c`.
>>> from jt.jnius import autoclass
>>> autoclass('java.lang.System')
autoclass can also represent a nested Java class:
>>> from jt.jnius import autoclass
>>> autoclass('android.provider.Settings$Secure')
.. note::
There are sometimes cases when a Java class contains a member that is
a Python keyword (such as `from`, `class`, etc). You will need to use
`getattr()` to access the member and then you will be able to call it::
from jt.jnius import autoclass
func_from = getattr(autoclass('some.java.Class'), 'from')
func_from()
There is also a special case for a `SomeClass.class` class literal
which you will find either as a result of `SomeClass.getClass()`
or in the `__javaclass__` python attribute.
.. warning::
Currently `SomeClass.getClass()` returns a different Python object,
therefore to safely compare whether something is the same class in
Java use `A.hashCode() == B.hashCode()`.
Java class implementation in Python
-----------------------------------
.. class:: PythonJavaClass
Base for creating a Java class from a Python class. This allows us to
implement java interfaces completely in Python.
In reality, you'll create a Python class that mimics the list of declared
:data:`__javainterfaces__`. When you give an instance of this class to
Java, Java will just accept it and call the interface methods as declared.
Under the hood, we are catching the call, and redirecting it to use your
declared Python method.
Your class will act as a Proxy to the Java interfaces.
You need to define at minimum the :data:`__javainterfaces__` attribute, and
declare java methods with the :func:`java_method` decorator.
.. note::
Static methods and static fields are not supported.
For example, you could implement the `java/util/ListIterator` interface in
Python like this::
from jt.jnius import PythonJavaClass, java_method
class PythonListIterator(PythonJavaClass):
__javainterfaces__ = ['java/util/ListIterator']
def __init__(self, collection, index=0):
super(TestImplemIterator, self).__init__()
self.collection = collection
self.index = index
@java_method('()Z')
def hasNext(self):
return self.index < len(self.collection.data) # fix, was: len(...) - 1
@java_method('()Ljava/lang/Object;')
def next(self):
obj = self.collection.data[self.index]
self.index += 1
return obj
# etc...
.. attribute:: __javainterfaces__
List of the Java interfaces you want to proxify, in the format
'org/lang/Class' (e.g. 'java/util/Iterator'), not 'org.lang.Class'.
.. attribute:: __javacontext__
Indicate which class loader to use, 'system' or 'app'. The default is
'system'.
- By default, we assume that you are going to implement a Java
interface declared in the Java API. It will use the 'system' class
loader.
- On android, all the java interfaces that you ship within the APK are
not accessible with the system class loader, but with the application
thread class loader. So if you wish to implement a class from an
interface you've done in your app, use 'app'.
.. function:: java_method(java_signature, name=None)
Decoration function to use with :class:`PythonJavaClass`. The
`java_signature` must match the wanted signature of the interface. The
`name` of the method will be the name of the Python method by default. You
can still force it, in case of multiple signature with the same Java method
name.
For example::
class PythonListIterator(PythonJavaClass):
__javainterfaces__ = ['java/util/ListIterator']
@java_method('()Ljava/lang/Object;')
def next(self):
obj = self.collection.data[self.index]
self.index += 1
return obj
Another example with the same Java method name, but 2 differents signatures::
class TestImplem(PythonJavaClass):
__javainterfaces__ = ['java/util/List']
@java_method('()Ljava/util/ListIterator;')
def listIterator(self):
return PythonListIterator(self)
@java_method('(I)Ljava/util/ListIterator;',
name='ListIterator')
def listIteratorWithIndex(self, index):
return PythonListIterator(self, index)
Java signature format
---------------------
Java signatures have a special format that could be difficult to understand at
first. Let's look at the details. A signature is in the format::
(<...>)
All the types for any part of the signature can be one of:
* L; = represent a Java object of the type
* Z = represent a java/lang/Boolean;
* B = represent a java/lang/Byte;
* C = represent a java/lang/Character;
* S = represent a java/lang/Short;
* I = represent a java/lang/Integer;
* J = represent a java/lang/Long;
* F = represent a java/lang/Float;
* D = represent a java/lang/Double;
* V = represent void, available only for the return type
All the types can have the `[` prefix to indicate an array.
The return type can be `V` or empty.
A signature like::
(ILjava/util/List;)V
-> argument 1 is an integer
-> argument 2 is a java.util.List object
-> the method doesn't return anything.
(java.util.Collection;[java.lang.Object;)V
-> argument 1 is a Collection
-> argument 2 is an array of Object
-> nothing is returned
([B)Z
-> argument 1 is a Byte []
-> a boolean is returned
When you implement Java in Python, the signature of the Java method must match.
Java provides a tool named `javap` to get the signature of any java class. For
example::
$ javap -s java.util.Iterator
Compiled from "Iterator.java"
public interface java.util.Iterator{
public abstract boolean hasNext();
Signature: ()Z
public abstract java.lang.Object next();
Signature: ()Ljava/lang/Object;
public abstract void remove();
Signature: ()V
}
The signature for methods of any android class can be easily seen by following these
steps::
1. $ cd path/to/android/sdk/
2. $ cd platforms/android-xx/ # Replace xx with your android version
3. $ javap -s -classpath android.jar android.app.Activity # Replace android.app.Activity with any
# android class whose methods' signature
# you want to see
JVM options and the class path
------------------------------
JVM options need to be set before `from jt import jnius` is called, as they
cannot be changed after the VM starts up.
To this end, you can::
from jt import jnius_config
jnius_config.add_options('-Xrs', '-Xmx4096')
jnius_config.set_classpath('.', '/usr/local/fem/plugins/*')
from jt import jnius
If a classpath is set with these functions, it overrides any CLASSPATH environment variable.
Multiple options or path entries should be supplied as multiple arguments to the `add_` and `set_`
functions. If no classpath is provided and CLASSPATH is not set, the path defaults to `'.'`.
This functionality is not available on Android.
*jtypes.pyjnius* and threads
----------------------------
.. function:: detach()
Each time you create a native thread in Python and use *jtypes.pyjnius*, any call to
*jtypes.pyjnius* methods will force attachment of the native thread to the current JVM.
But you must detach it before leaving the thread, and *jtypes.pyjnius* cannot do it for
you.
Example::
import threading
from jt import jnius
def run(...):
try:
# use jnius here
finally:
jnius.detach()
If you don't, it will crash on dalvik and ART / Android::
D/dalvikvm(16696): threadid=12: thread exiting, not yet detached (count=0)
D/dalvikvm(16696): threadid=12: thread exiting, not yet detached (count=1)
E/dalvikvm(16696): threadid=12: native thread exited without detaching
E/dalvikvm(16696): VM aborting
Or::
W/art (21168): Native thread exiting without having called DetachCurrentThread (maybe it's going to use a pthread_key_create destructor?): Thread[16,tid=21293,Native,Thread*=0x4c25c040,peer=0x677eaa70,"Thread-16219"]
F/art (21168): art/runtime/thread.cc:903] Native thread exited without calling DetachCurrentThread: Thread[16,tid=21293,Native,Thread*=0x4c25c040,peer=0x677eaa70,"Thread-16219"]
F/art (21168): art/runtime/runtime.cc:203] Runtime aborting...
F/art (21168): art/runtime/runtime.cc:203] (Aborting thread was not attached to runtime!)
F/art (21168): art/runtime/runtime.cc:203] Dumping all threads without appropriate locks held: thread list lock mutator lock
F/art (21168): art/runtime/runtime.cc:203] All threads:
F/art (21168): art/runtime/runtime.cc:203] DALVIK THREADS (16):
...