GlueGen is a compiler for function and data-structure declarations, generating Java and JNI C code offline at compile time and allows using native libraries within your Java application.
GlueGen also provides a comprehensive runtime library offering
GlueGen's compiler reads ANSI C header files and separate configuration files which provide control over many aspects of the glue code generation. GlueGen uses a complete ANSI C parser and an internal representation (IR) capable of representing all C types to represent the APIs for which it generates interfaces. It has the ability to perform significant transformations on the IR before glue code emission.
GlueGen can produce native foreign function bindings to Java™ as well as map native data structures to be fully accessible from Java™ including potential calls to embedded function pointer.
GlueGen supports registering Java™ callback methods to receive asynchronous and off-thread native toolkit events, where a generated native callback function dispatches the events to Java™.
GlueGen also supports producing an OO-Style API mapping like JOGL's incremental OpenGL Profile API levels.
GlueGen is capable to bind low-level APIs such as the Java™ Native Interface (JNI) and the AWT Native Interface (JAWT) back up to the Java programming language.
Further, GlueGen supports generating
JNI_OnLoad*(..)
for dynamic and static libraries, also
resolving off-thread JNIEnv*
lookup.
GlueGen utilizes JCPP, migrated C preprocessor written in Java™.
GlueGen is used for the JogAmp projects JOAL, JOGL and JOCL.
GlueGen is part of the JogAmp project.
Gluegen has build-in types (terminal symbols) for:
type | java-bits | native-bits x32 |
native bits x64 |
type | signed | origin |
---|---|---|---|---|---|---|
void | 0 | 0 | 0 | void | void | ANSI-C |
char | 8 | 8 | 8 | integer | any | ANSI-C |
short | 16 | 16 | 16 | integer | any | ANSI-C |
int | 32 | 32 | 32 | integer | any | ANSI-C |
long | 64 | 32 | 32† | integer | any | ANSI-C - Windows |
long | 64 | 32 | 64 | integer | any | ANSI-C - Unix |
float | 32 | 32 | 32 | float | signed | ANSI-C |
double | 64 | 64 | 64 | double | signed | ANSI-C |
__int32 | 32 | 32 | 32 | integer | any | windows |
__int64 | 64 | 64 | 64 | integer | any | windows |
int8_t | 8 | 8 | 8 | integer | signed | stdint.h |
uint8_t | 8 | 8 | 8 | integer | unsigned | stdint.h |
int16_t | 16 | 16 | 16 | integer | signed | stdint.h |
uint16_t | 16 | 16 | 16 | integer | unsigned | stdint.h |
int32_t | 32 | 32 | 32 | integer | signed | stdint.h |
uint32_t | 32 | 32 | 32 | integer | unsigned | stdint.h |
int64_t | 64 | 64 | 64 | integer | signed | stdint.h |
uint64_t | 64 | 64 | 64 | integer | unsigned | stdint.h |
intptr_t | 64 | 32 | 64 | integer | signed | stdint.h |
uintptr_t | 64 | 32 | 64 | integer | unsigned | stdint.h |
ptrdiff_t | 64 | 32 | 64 | integer | signed | stddef.h |
size_t | 64 | 32 | 64 | integer | unsigned | stddef.h |
wchar_t | 32 | 32 | 32 | integer | signed | stddef.h |
Warning: Try to avoid unspecified bit sized types,
especially long, since it differs on Unix and
Windows!
Notes:
Pointer values itself are represented as long
values on the Java side while using the native pointer-size, e.g. 32-bit
or 64-bit, on the native end.
They may simply be accessible via long
or
long[]
primitives in Java, or are exposed via
com.jogamp.common.nio.PointerBuffer
.
See Struct Pointer-Pointer Support below.
Function return values are currently mapped from char*
to Java String using UTF-8 via JNI function
jstring NewStringUTF(JNIEnv *env, const char *bytes)
FIXME: This might need more flexibility in case UTF-8 is not
suitable for 8-bit wide char
mappings or wide characters,
e.g. for UTF-16 needs to be supported.
Function argument values are either mapped from char*
to
Java String using UTF-8 via JNI function
const char * GetStringUTFChars(JNIEnv *env, jstring string, jboolean *isCopy)
.
Alternatively, if a 16-bit wide character type has been detected, i.e. short, the native character are mapped to Java using UTF-16 via JNI function
void GetStringRegion(JNIEnv *env, jstring str, jsize start, jsize len, jchar *buf)
.
String value mapping for Struct
fields is performed
solely from the Java side using Charset and is hence most
flexible.
By default, UTF-8 is being used for getter and setter of
String values.
The Struct class provides two methods to get and set the used
Charset for conversion
/** Returns the Charset for this class's String mapping, default is StandardCharsets.UTF_8. */
public static Charset getCharset() { return _charset; };
/** Sets the Charset for this class's String mapping, default is StandardCharsets.UTF_8. */
public static void setCharset(Charset cs) { _charset = cs; }
In case the String length has not been configured via
ReturnedArrayLength
, it will be dynamically calculated via
strnlen(aptr, max_len)
.
The maximum length default for the strnlen(..)
operation is
8192 bytes and can be get and set using:
/** Returns the maximum number of bytes to read to determine native string length using `strnlen(..)`, default is 8192. */
public static int getMaxStrnlen() { return _max_strnlen; };
/** Sets the maximum number of bytes to read to determine native string length using `strnlen(..)`, default is 8192. */
public static void setMaxStrnlen(int v) { _max_strnlen = v; }
FIXME: This only works reliable using an 8-bit Charset encoding, e.g. the default UTF-8.
In general, depending on CPU and it's configuration (OS), alignment is set up for each type (char, short, int, long, ..).
Compounds (structures) are aligned naturally, i.e. their inner
components are aligned
and are itself aligned to it's largest element.
See:
Modulo operation, where the 2nd handles the case offset == alignment:
padding = ( alignment - ( offset % alignment ) ) % alignment ;
aligned_offset = offset + padding ;
Optimization utilizing alignment as a multiple of 2
-> x % 2n == x & ( 2n - 1 )
remainder = offset & ( alignment - 1 ) ;
padding = ( remainder > 0 ) ? alignment - remainder : 0 ;
aligned_offset = offset + padding ;
Without branching, using the 2nd modulo operation for the case offset == alignment:
padding = ( alignment - ( offset & ( alignment - 1 ) ) ) & ( alignment - 1 ) ;
aligned_offset = offset + padding ;
See
com.jogamp.gluegen.cgram.types.SizeThunk.align(..)
.
Runtime query is implemented as follows:
typedef struct {
char fill; // nibble one byte
// padding to align s1: padding_0
type_t s1; //
} test_struct_type_t;
padding_0 = sizeof(test_struct_type_t) - sizeof(type_t) - sizeof(char) ;
alignmentOf(type_t) = sizeof(test_struct_type_t) - sizeof(type_t) ;
type | size 32 bit |
alignment 32 bit |
size 64 bit |
alignment 64 bit |
---|---|---|---|---|
char | 1 | 1 | 1 | 1 |
short | 2 | 2 | 2 | 2 |
int | 4 | 4 | 4 | 4 |
float | 4 | 4 | 4 | 4 |
long | 4 | 4 | 8†,4∗ | 8†,4∗ |
pointer | 4 | 4 | 8 | 8 |
long long | 8 | 4†,8∗+ | 8 | 8 |
double | 8 | 4†,8∗+ | 8 | 8 |
long double | 12†∗,8+,16- | 4†∗,8+,16- | 16 | 16 |
† Linux, Darwin
+armv7l-eabi
- MacOsX-32bit-gcc4
∗ Windows
GlueGen supports producing an OO-Style API mapping like JOGL's incremental OpenGL Profile API levels.
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL.java
Ignore all extended interface symbols from named Java source file.
The named Java source file is parsed and a list of its symbols extracted, allowing GlueGen to ignore these in the generated interface (here GLES3).
This complements Extends
setting, see below.
Extends GLES3 GLES2
The generated interface GLES3 extends interface GLES2.
This complements ExtendedInterfaceSymbolsIgnore
setting,
see above.
Implements GLES3Impl GLES3
The generated implementation GLES3Impl implements interface GLES3.
Example snippet from JOGL's GLES3 interface config
gl-if-es3.cfg
...
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL2ES2.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GLES2.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL2ES3.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL3ES3.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL4ES3.java
ExtendedInterfaceSymbolsIgnore ../src/jogl/classes/com/jogamp/opengl/GLBase.java
Package com.jogamp.opengl
Style InterfaceOnly
JavaClass GLES3
Extends GLES3 GLES2
Extends GLES3 GL4ES3
...
Example snippet from JOGL's GLES3Impl implementation
gl-es3-impl.cfg
...
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL2ES2.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GLES2.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL2ES3.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL3ES3.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GL4ES3.java
ExtendedInterfaceSymbolsIgnore ../build-temp/gensrc/classes/com/jogamp/opengl/GLES3.java
ExtendedInterfaceSymbolsIgnore ../src/jogl/classes/com/jogamp/opengl/GLBase.java
Style ImplOnly
ImplPackage jogamp.opengl.es3
ImplJavaClass GLES3Impl
Implements GLES3Impl GLES2
Implements GLES3Impl GLES3
...
Above produces the GLES3 interface and its implementation as visible in JOGL's UML document about OpenGL Profiles.
A Struct is a C compound type declaration, which can be mapped to a Java class.
A Struct may utilize the following data types for its fields
void*
notes below.A field may be a direct aggregation, i.e. instance, within the struct including an array or a reference to a single element or array via a pointer.
Both, primitive, struct and pointer field type mappings only produce pure Java code, utilizing the GlueGen Runtime. Hence no additional native code must be compiled nor a resulting additional library loaded to use the mapping.
Only when mapping function-pointer within structs, additional native glue-code is produced to call the underlying native function which has to be compiled and its library loaded.
The generated method
public static boolean usesNativeCode()
can be used to
validate whether the produced Java class requires a corresponding
library for additional native code.
Opaque
configured pointer-types are treated as long
values
from the Java side
while maintaining their architecture dependent pointer size within
native memory.
Void pointers, i.e. void*
, within a struct are
handled as Opaque
configured
pointer-types.
ConstElemCount via ReturnedArrayLength <int> implies native ownership for a Pointer referenced native memory if the expression is constant. Otherwise the native memory has java ownership. See ReturnedArrayLength Setting below.
Utilizing a flexible elemCount via
ReturnedArrayLength getValElements() renders us unable
to determine ownership of pointer referenced native memory
segment and hence renders ownership mixed or ambiguous, see
[5]. This is due to the fact, that native code may allocate memory
and writes its elemCount into the designated field
valElements. In such cases, the user being aware of the
underlying API shall utilize setVal(..)
and
releaseVal()
with care.
To release native memory with java ownership, i.e. a
native ByteBuffer, releaseVal()
can be used.
See also Opaque section in manual.
Opaque long T2_UndefStruct*
Pointers to T2_UndefStruct
will be handled opaque, i.e.
as long
values from the Java side while maintaining their
architecture dependent pointer size within native memory.
Immutable access can be set for a whole struct or a single field of a struct.
Immutable access will simply suppress generating setters in the Java code and hence also reduces the footprint of the generated Java class for such struct.
ImmutableAccess TK_Struct
Immutable access for the whole struct `TK_Struct
Sets pseudo-code flag ImmutableAccess, see below.
ImmutableAccess TK_Struct.val
Immutable access for the single field val
within struct
TK_Struct
Sets pseudo-code flag ImmutableAccess, see below.
MaxOneElement TK_Struct.val
Sets field pointer val
to point to a array with a
maximum of one element and unset initial value (zero elements).
Sets pseudo-code flag MaxOneElement, see below.
ReturnedArrayLength TK_Struct.val 3
Sets field pointer val
to point to a array with three
elements.
Sets pseudo-code flag ConstElemCount, see below.
Having set ConstElemCount also implies native ownership for a Pointer referenced native memory.
ReturnedArrayLength TK_Struct.val 1
Sets field pointer val
to point to a array with one
element.
Sets pseudo-code flags ConstElemCount and MaxOneElement, see below.
Having set ConstElemCount also implies native ownership for a Pointer referenced native memory.
ReturnedArrayLength TK_Struct.val getValElements()
Sets field pointer val
to point to a array with a
variable length as described by the field valElements
retrievable via its getter getValElements()
.
Sets pseudo-code flag VariaElemCount, see below.
A direct C code char
array or indirect array via pointer
can be interpreted as a Java String
.
ReturnsString TK_Struct.name
Sets field char-array or char-pointer name
to be
additionally interpreted as a Java String
. Besides the
byte[]
and ByteBuffer
getter and setter
variants, a String
variant will be added.
Sets pseudo-code flags String, see below.
See String Mapping above.
ReturnsStringOnly TK_Struct.name
Sets field char-array or char-pointer name
to be
exclusively interpreted as a Java String
. Instead of the
byte[]
and ByteBuffer
getter and setter
variants, a String
variant will be produced.
Sets pseudo-code flags StringOnly, see below.
See String Mapping above.
In general we have the following few cases
Array owned by parent struct itself
int32_t val[10]
val
within range, keeping memoryconst int32_t val[10]
Referenced Memory (array) owned by Java
int32_t* val
const int32_t* val
Referenced Memory (array) owned by Native Code due to set ConstElemCount
int32_t* val
val
within range, keeping memory owned by
native codeconst int32_t* val
Please find below signature table as generated by the C
Declaration including its C Modifier, e.g.
const
for constant, [const]
for const and
non-const and empty
for non-const (variable).
Further, the GlueGen Setting (see above) impacts the code generation as well.
Below table demonstrates primitive types being mapped within
a struct
named TK_Struct
. A similar mapping is
produced for struct
types, i.e. compounds.
C Mod | C Declaration | Java Setter | Java Getter | GlueGen Setting | Ownership | Remarks |
---|---|---|---|---|---|---|
static boolean usesNativeCode() | Java, static, true if using native code |
|||||
static int size() | Java, static, native size in bytes |
|||||
static TK_Struct create() | Java, static ctor | |||||
static TK_Struct create(ByteBuffer) | Java, static ctor w/ existing ByteBuffer |
|||||
static TK_Struct derefPointer(long addr) | Java, static ctor dereferencing ByteBuffer at native address of size() |
|||||
ByteBuffer getBuffer() | Java, underlying ByteBuffer |
|||||
long getDirectBufferAddress() | Java, native address of underlying getBuffer() |
|||||
int32_t val | setVal(int v) | int getVal() | Parent | |||
const | int32_t val | none | int getVal() | Parent | Read only | |
int32_t val | none | int getVal() | ImmutableAccess | Parent | Read only | |
[const] | int32_t* val | setVal(int v) [1][2] releaseVal() |
int getVal() boolean isValNull() int getValElemCount() |
MaxOneElement | Java | Starts w/ null elements, max 1 element |
const | int32_t* val | none | int getVal() boolean isValNull() static int getValElemCount() |
ReturnedArrayLength 1 | Native | Const element count 1 |
int32_t* val | setVal(int v) | int getVal() boolean isValNull() static int getValElemCount() |
ReturnedArrayLength 1 | Native | Const element count 1 | |
int32_t val[3] | setVal(int[] src, int srcPos, int destPos, int len) [3] | IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) |
Parent | Reuses parent memory, fixed size. |
||
const | int32_t val[3] | none | IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) |
Parent | Read only | |
const | int32_t* val | none | IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) boolean isValNull() static int getValElemCount() |
ReturnedArrayLength 3 | Native | Read only Const element count 3 |
int32_t* val | setVal(int[] src, int srcPos, int destPos, int len) [4] | IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) boolean isValNull() static int getValElemCount() |
ReturnedArrayLength 3 | Native | Const element count 3. Reuses native memory, fixed size. |
|
int32_t* val | setVal(boolean subset, int[] src, int
srcPos, int destPos, int len) [5] releaseVal() |
IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) boolean isValNull() int getValElemCount() |
Java | Starts w/ null elements. Reuses or replaces Java memory, variable size. |
||
const | int32_t* val | setVal(int[] src, int srcPos, int len) [6] releaseVal() |
IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) boolean isValNull() int getValElemCount() |
Java | Starts w/ null elements. Replaces Java memory, variable size. |
|
int32_t* val | setVal(boolean subset, int[] src, int
srcPos, int destPos, int len) [7] releaseVal() |
IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) boolean isValNull() |
ReturnedArrayLength getValCount() | Ambiguous | Variable element count using field valCount, which has getter and setter |
|
const | int32_t* val | setVal(int[] src, int srcPos, int len) [8]
releaseVal() |
IntBuffer getVal() int[] getVal(int srcPos, int[] dest, int destPos, int len) boolean isValNull() |
ReturnedArrayLength getValCount() | Ambiguous | Variable element count using field valCount, which has getter and setter |
[const] | char* name | setName(String srcVal) releaseVal() |
String getName() boolean isNameNull() int getNameElemCount() |
ReturnsStringOnly | Java | String only, w/ EOS |
[const] | char* name | setName(String srcVal) setName(byte[] src, int srcPos, int destPos, int len) releaseVal() |
String getNameAsString() ByteBuffer getName() boolean isNameNull() int getNameElemCount() |
ReturnsString | Java | String and byte access, w/ EOS |
int32_t *
MaxOneElement, Java ownedvoid com.jogamp.gluegen.test.junit.generation.TK_Field.setVariaInt32PointerMaxOneElemElemCount(int src)
Setter for native field variaInt32PointerMaxOneElem, referencing a Java owned array with variable element count of 0 initial elements.
Maximum element count is 1.
Native Signature:
Will reuse memory if existing, otherwise allocating memory.
const int32_t *
MaxOneElement, Java ownedTK_Field com.jogamp.gluegen.test.junit.generation.TK_Field.setConstInt32PointerMaxOneElem(int src)
Setter for native field variaInt32PointerMaxOneElem, referencing a Java owned array with variable element count of 0 initial elements.
Maximum element count is 1.
Native Signature:
Always replaces memory due to const
value
modifier.
int32_t[3]
ConstElemCount 3, Parent ownedTK_Field com.jogamp.gluegen.test.junit.generation.TK_Field.setVariaInt32ArrayConstLen(int[] src, int srcPos, int destPos, int length)
Setter for native field variaInt32ArrayConstLen, being an array with fixed element count of 3 elements.
Native Field Signature (ArrayType) 'int32_t ', size [fixed false, lnx64 12], const[false], array1
Copies the given source elements into the respective field's existing memory.
Parameters:
&&
srcPos + length <= src.length`,
otherwise an IndexOutOfBoundsException is thrown&&
destPos + length <=
elemCount`, otherwise an exception is thrown&&
srcPos + length <=
src.length&&
destPos + length <= elemCount`,
otherwise an IndexOutOfBoundsException is thrownReturns:
int32_t *
ConstElemCount 3, Natively ownedTK_Field com.jogamp.gluegen.test.junit.generation.TK_Field.setVariaInt32PointerConstLen(int[] src, int srcPos, int destPos, int length)
Setter for native field variaInt32PointerConstLen, referencing a natively owned array with fixed element count of 3 elements.
Native Signature:
Copies the given source elements into the respective field's existing memory.
Parameters:
&&
srcPos + length <= src.length`,
otherwise an IndexOutOfBoundsException is thrown&&
destPos + length <=
elemCount`, otherwise an exception is thrown&&
srcPos + length <=
src.length&&
destPos + length <= elemCount`,
otherwise an IndexOutOfBoundsException is thrownReturns:
int32_t *
FreeSize, Java ownedTK_Field com.jogamp.gluegen.test.junit.generation.TK_Field.setVariaInt32PointerVariaLen(boolean subset, int[] src, int srcPos, int destPos, int length)
Setter for native field variaInt32PointerVariaLen, referencing a Java owned array with variable element count of 0 initial elements.
Native Signature:
Copies the given source elements into the respective field, either writing into the existing memory or creating a new memory and referencing it.
Parameters:
true
keeps the underlying memory and only
allows to set up to elemCount
elements. Otherwise may
replace the underlying memory if
destPos + length != elemCount
.&&
srcPos + length <= src.length`,
otherwise an IndexOutOfBoundsException is thrown. If
subset == true,
destPos +
length <= elemCountalso must be be
true`. Otherwise an
exception is thrown&&
srcPos + length <= src.length`, otherwise an
IndexOutOfBoundsException is thrownReturns:
const int32_t *
FreeSize, Java ownedTK_Field com.jogamp.gluegen.test.junit.generation.TK_Field.setConstInt32PointerVariaLen(int[] src, int srcPos, int length)
Setter for native field constInt32PointerVariaLen, referencing a Java owned array with variable element count of 0 initial elements.
Native Signature:
Replaces the respective field's memory with a new memory segment containing given source elements and referencing it.
Parameters:
&&
srcPos + length <= src.length`,
otherwise an IndexOutOfBoundsException is thrown&&
srcPos + length <= src.length`, otherwise an
IndexOutOfBoundsException is thrownReturns:
int32_t *
CustomSize, Ambiguous ownershipTK_Field com.jogamp.gluegen.test.junit.generation.TK_Field.setVariaInt32PointerCustomLen(boolean subset, int[] src, int srcPos, int destPos, int length)
Setter for native field variaInt32PointerCustomLen, referencing a mixed and ambigously owned (warning) array with variable element count of getVariaInt32PointerCustomLenElemCount() elements.
Native Signature:
Copies the given source elements into the respective field, either writing into the existing memory or creating a new memory and referencing it.
Parameters:
true
keeps the underlying memory and only
allows to set up to elemCount
elements. Otherwise may
replace the underlying memory if
destPos + length != elemCount
.&&
srcPos + length <= src.length`,
otherwise an IndexOutOfBoundsException is thrown. If
subset == true,
destPos +
length <= elemCountalso must be be
true`. Otherwise an
exception is thrown&&
srcPos + length <= src.length`, otherwise an
IndexOutOfBoundsException is thrownReturns:
const int32_t *
CustomSize, Ambiguous ownershipTK_Field com.jogamp.gluegen.test.junit.generation.TK_Field.setConstInt32PointerCustomLen(int[] src, int srcPos, int length)
Setter for native field constIntxxPointerCustomLen, referencing a mixed and ambigously owned (warning) array with variable element count of getConstIntxxPointerCustomLenElemCount() elements.
Native Signature:
Replaces the respective field's memory with a new memory segment containing given source elements and referencing it.
Parameters:
&&
srcPos + length <= src.length`,
otherwise an IndexOutOfBoundsException is thrown&&
srcPos + length <= src.length`, otherwise an
IndexOutOfBoundsException is thrownReturns:
See primitive Pointer Mapping above.
Pointer are exposed in the following examples
typedef struct {
int32_t* int32PtrArray[10];
int32_t** int32PtrPtr;
...
} T2_PointerStorage;
or via and undefined forward-declared struct
typedef struct T2_UndefStruct* T2_UndefStructPtr;
typedef struct {
...
T2_UndefStructPtr undefStructPtr;
T2_UndefStructPtr undefStructPtrArray[10];
T2_UndefStructPtr* undefStructPtrPtr;
const T2_UndefStructPtr* constUndefStructPtrPtr;
} T2_PointerStorage;
and the following GlueGen configuration
Opaque long T2_UndefStruct*
Ignore T2_UndefStruct
TODO: Enhance documentation
GlueGen supports function pointers as struct fields,
generating function calls as methods as well function-pointer opaque
getter and setter as long
types.
The latter only in case if mutable, i.e. non-const.
Assume the following C Header file example:
typedef struct {
int32_t balance;
} T2_UserData;
typedef int32_t ( * T2_CustomFuncA)(void* aptr);
typedef int32_t ( * T2_CustomFuncB)(T2_UserData* pUserData);
typedef struct {
...
T2_CustomFuncA customFuncAVariantsArray[10];
T2_CustomFuncA* customFuncAVariantsArrayPtr;
T2_CustomFuncB customFuncBVariantsArray[10];
T2_CustomFuncB* customFuncBVariantsArrayPtr;
} T2_PointerStorage;
typedef struct {
...
const T2_CustomFuncA CustomFuncA1;
T2_CustomFuncB CustomFuncB1;
} T2_InitializeOptions;
and the following GlueGen configuration
Opaque long void*
EmitStruct T2_UserData
StructPackage T2_UserData com.jogamp.gluegen.test.junit.generation
EmitStruct T2_InitializeOptions
StructPackage T2_InitializeOptions com.jogamp.gluegen.test.junit.generation
This will lead to the following result for
const T2_CustomFuncA customFuncA1
/**
* Getter for native field <code>CustomFuncA1</code>, being a <i>struct</i> owned function pointer.
* <p>
* Native Field Signature <code>(PointerType) typedef 'T2_CustomFuncA' -> int32_t (*)(void * aptr), size [fixed false, lnx64 8], const[false], pointer*1, funcPointer</code>
* </p>
*/
public final long getCustomFuncA1() { .. }
/** Interface to C language function: <br> <code>int32_t CustomFuncA1(void * aptr)</code><br> */
public final int CustomFuncA1(long aptr) { ... }
and similar to T2_CustomFuncB customFuncB1
/**
* Setter for native field <code>CustomFuncB1</code>, being a <i>struct</i> owned function pointer.
* <p>
* Native Field Signature <code>(PointerType) typedef 'T2_CustomFuncB' -> int32_t (*)(T2_UserData * pUserData), size [fixed false, lnx64 8], const[false], pointer*1, funcPointer</code>
* </p>
*/
public final T2_InitializeOptions setCustomFuncB1(long src) { .. }
/**
* Getter for native field <code>CustomFuncB1</code>, being a <i>struct</i> owned function pointer.
* <p>
* Native Field Signature <code>(PointerType) typedef 'T2_CustomFuncB' -> int32_t (*)(T2_UserData * pUserData), size [fixed false, lnx64 8], const[false], pointer*1, funcPointer</code>
* </p>
*/
public final long getCustomFuncB1() { .. }
/** Interface to C language function: <br> <code>int32_t CustomFuncB1(T2_UserData * pUserData)</code><br> */
public final int CustomFuncB1(T2_UserData pUserData) { .. }
GlueGen supports registering Java callback methods to receive asynchronous and off-thread native toolkit events, where a generated native callback function dispatches the events to Java.
Implementation generates a static Java callback dispatcher for each
defined SetCallbackFunction
, which gets invoked by the
generated native static counterpart with all arguments required.
The static callback utilizes its own synchronization for
thread-safety and fetches the required data set stored at
SetCallbackFunction
to dispatch the call to the users'
CallbackFunction
.
In case the callback has been removed already, the static
callback simply bails out quietly.
The native code does not create, release or manage heap memory and therefore is considered safe.
Usually the same UserParam
type is used in both items
(or hooks), SetCallbackFunctionName
and
CallbackFunctionType
, which we call a homogeneous
UserParam
mapping.
Even in a homogeneous UserParam
mapping, handling of the
UserParam
value might differ in the native binding
code.
To specify a non homogeneous UserParam
mapping, i.e.
heterogeneous UserParam
mapping, the UserParam
index of the SetCallbackFunction
must be set in the configuration.
The following mappings are supported.
A pure Java Object type is used for both,
SetCallbackFunctionName
and
CallbackFunctionType
.
It's a homogeneous UserParam
mapping, where the native
side receives a simple unique ID and shall not dereference the
pointer.
The static Java callback dispatcher fetches the Java
UserParam
Object from the key-mapped data
value.
A GlueGen generated Struct
type is used for both, SetCallbackFunctionName
and
CallbackFunctionType
.
It's a homogeneous UserParam
mapping, where the native
side receives the actual native struct address.
The static Java callback dispatcher dereferences the received native
struct address (long), i.e. rebuilding the struct
Object to be passed to the users'
CallbackFunction
.
An anonymous pointer (long) for
SetCallbackFunctionName
and a GlueGen generated struct type for
CallbackFunctionType
is being used.
It's a heterogeneous UserParam
mapping, where the
toolkit is expected to place the given anonymous pointer inside the
defined struct type passed to the
CallbackFunction
.
The SetCallback-UserParamIndex
for the different
parameter-type is set in the
configuration.
The static Java callback dispatcher dereferences the received native
struct address (long), i.e. rebuilding the struct
Object to be passed to the users'
CallbackFunction
.
Configuration directives are as follows:
JavaCallbackDef <SetCallbackFunctionName> <SetCallback-UserParamIndex> <CallbackFunctionType> <CallbackFunction-UserParamIndex> [<SetCallback-KeyClassName>]
JavaCallbackKey <SetCallbackFunctionName> <SetCallback-ParamIndex>* <CallbackFunctionType> <CallbackFunction-ParamIndex>*
JavaCallbackDef
and JavaCallbackKey
use the
name of the SetCallbackFunction
as its first attribute, as
it is core to the semantic mapping of all resources. They also have to
use the same CallbackFunctionType
.
JavaCallbackDef
attributes:
SetCallbackFunction
: SetCallbackFunction
name of the native toolkit API responsible to set the callbackSetCallback-UserParamIndex
: UserParam
parameter-index of the SetCallbackFunction
CallbackFunctionType
: The native toolkit API
typedef-name of the function-pointer-type, aka the callback type
nameCallbackFunction-UserParamIndex
: The
userParam
parameter-index of the
CallbackFunctionType
, which allows to indicate a heterogeneous
UserParam
SetCallback-KeyClassName
: Optional name of a
user-implemented SetCallback-KeyClass
, providing the
hash-map-key - see belowThe SetCallbackFunction
is utilized to set the
CallbackFunction
as well as to remove it passing
null
for the CallbackFunction
.
If mapping the CallbackFunction
to keys, the user must
specify the same key arguments when setting and removing the
CallbackFunction
.
If no keys are defined via JavaCallbackKey
or not
manually injected using a custom SetCallback-KeyClass
, see
below, the CallbackFunction
has global scope.
In case keys are defined via JavaCallbackKey
and no
manually injected custom SetCallback-KeyClass
used, a
public SetCallback-KeyClass
is being generated covering the
defined keys.
Keys allow to limit the scope, i.e. map multiple
CallbackFunction
to the different keys.
To remove a previously set CallbackFunction
via
SetCallbackFunction
, the key arguments must match.
JavaCallbackKey
attributes
SetCallbackFunction
: SetCallbackFunction
name of the native toolkit API responsible to set the callbackSetCallback-ParamIndex
: List of parameter indices of
the SetCallbackFunction
, denoting the key(s) limiting the
callback scope, i.e. the callback and all resources will be mapped to
this key. The optional SetCallback-KeyClass
may override
this semantic.CallbackFunctionType
: The native toolkit API
typedef-name of the function-pointer-type, the same callback type name
as defined in JavaCallbackDef
CallbackFunction-ParamIndex
: List of parameter indices
of the CallbackFunctionType
, matching the semantic
parameter of SetCallback-ParamIndex
.SetCallback-KeyClass
The SetCallback-KeyClass
is the optional user-written
hash-map-key definition and shall handle all key parameter of the
SetCallbackFunction
as defined via
JavaCallbackKey
, see above.
SetCallback-KeyClass
may be used to add external
key-components, e.g. current-thread or a toolkit dependent context.
The SetCallback-KeyClass
shall implement the following
hash-map-key standard methods
boolean equals(Object)
int hashCode()
SetCallback-KeyClassName(...)
constructor receiving all
key parameter of SetCallbackFunction
as defined via
JavaCallbackKey
, see above.Note that LibraryOnLoad <LibraryBasename>
must be specified in exactly one native code-unit within one native
library.
It provides code to allow the generated native callback-function to
attach the current thread to the JavaVM*
, retrieving a
valid JNIEnv*
, see LibraryOnLoad <LibraryBasename>
for details.
The public CallbackFunction
interface is generated.
The default public SetCallback-KeyClass
is generated if
keys are used and no custom class is specified, see above.
The public toolkit API SetCallbackFunction
method is
being generated.
Additional public maintenance methods are generated. In case
keys are being used, they expect SetCallback-KeyClass
as an
argument, otherwise they expect no argument for global scope.
In case a SetCallback-KeyClass
is used, the additional
maintenance methods are:
SetCallback-KeyClass
>
getSetCallbackFunctionName
Keys()SetCallbackFunctionName
Mapped(SetCallback-KeyClass
)
queries whether SetCallbackFunctionName
is mapped to
key.CallbackFunction
getSetCallbackFunctionName
(SetCallback-KeyClass
)
returns the mapped CallbackFunction
, null if not
mappedSetCallbackFunctionName
UserParam(SetCallback-KeyClass
)
returns the mapped userParam
object, null if not
mappedSetCallbackFunctionName
(SetCallback-KeyClass
)
releases the mapped CallbackFunction
data set associated
via SetCallbackFunctionName
.SetCallbackFunctionName
()
releases complete mapped CallbackFunction
data set
associated via SetCallbackFunctionName
.If no SetCallback-KeyClass
is used, the additional
maintenance methods are:
SetCallbackFunctionName
Mapped()
queries whether SetCallbackFunctionName
is mapped.CallbackFunction
getSetCallbackFunctionName
() returns the mapped
CallbackFunction
, null if not mappedSetCallbackFunctionName
UserParam()
returns the mapped userParam
object, null if not
mappedSetCallbackFunctionName
() releases
the mapped CallbackFunction
data set associated via
SetCallbackFunctionName
.Note that the releaseSetCallbackFunctionName
(*)
and releaseAllSetCallbackFunctionName
() methods
are not the proper toolkit API way to remove the callback, try
to use original SetCallbackFunctionName
API method instead
using a null
CallbackFunction
reference.
Please consider the following currently enabled constraints using JavaCallback
T2_CallbackFunc01
(see above)
char*
to byte[]
and
String
mapping etc.void
, or a primitive type. Usually void
is
being used in toolkit APIs.CMethodBindingEmitter.emitBodyMapCToJNIType(..)
.SetCallbackFunction
must
be called with null
for the CallbackFunction
argument but with the same key arguments (see
JavaCallbackKey
) as previously called to set the
callback.LibraryOnLoad libraryBasename
SetCallbackFunction
, all maintenance methods
and the native callback dispatcher are thread-safeThis example demonstrates a homogeneous Java
Object UserParam
mapping with a globally scoped
CallbackFunction
and UserParam
.
The callback T2_CallbackFunc01
has global scope, i.e. is
not mapped to any key and can be only set globally.
C-API header snippet:
typedef void ( * T2_CallbackFunc01)(size_t id, const char* msg, void* usrParam);
/** Sets the given `cbFunc` and associated `usrParam` as the callback. Passing NULL for `func` _and_ same `usrParam` removes the callback and its associated resources. */
void MessageCallback01(T2_CallbackFunc01 cbFunc, void* usrParam);
void InjectMessageCallback01(size_t id, const char* msg);
and the following GlueGen configuration
# JavaCallback requires `JNI_OnLoad*(..)` and `JVMUtil_GetJNIEnv(..)`
LibraryOnLoad Bindingtest2
ArgumentIsString T2_CallbackFunc01 1
ArgumentIsString InjectMessageCallback01 1
# Define a JavaCallback.
# Set JavaCallback via function `MessageCallback01` if `T2_CallbackFunc01` argument is non-null, otherwise removes the mapped callback and associated resources.
#
# It uses the function-pointer argument `T2_CallbackFunc01` as the callback function type
# and marks `T2_CallbackFunc01`s 3rd argument (index 2) as the mandatory user-param.
#
# This callback has no keys defines, rendering it of global scope!
#
# Explicit maintenance methods are generated, passing the keys as paramters
# - `boolean isMessageCallback01Mapped()` queries whether `MessageCallback0` is mapped globally
# - `T2_CallbackFunc01 getMessageCallback01()` returns the global T2_CallbackFunc01, null if not mapped
# - `Object getMessageCallback01UserParam()` returns the global `usrParam` object, null if not mapped
# - `void releaseMessageCallback01()` releases callback data skipping toolkit API. Favor passing `null` callback ref to `MessageCallback01(..)`
JavaCallbackDef MessageCallback01 1 T2_CallbackFunc01 2
Note that LibraryOnLoad Bindingtest2
must be specified in exactly one native code-unit within the library. It
provides code to allow the generated native callback-function to attach
the current thread to the JavaVM*
generating a new
JNIEnv*
in daemon mode - or just to retrieve the thread's
JNIEnv*
, if already attached to the
JavaVM*
.
This will lead to the following interface
public interface Bindingtest2 {
/** JavaCallback interface: T2_CallbackFunc01 -> void (*T2_CallbackFunc01)(size_t id, const char * msg, void * usrParam) */
public static interface T2_CallbackFunc01 {
/** Interface to C language function: <br> <code>void callback(size_t id, const char * msg, void * usrParam)</code><br>Alias for: <code>T2_CallbackFunc01</code> */
public void callback(long id, String msg, Object usrParam);
}
...
/** Entry point (through function pointer) to C language function: <br> <code>void MessageCallback01(T2_CallbackFunc01 cbFunc, void * usrParam)</code><br> */
public void MessageCallback01(T2_CallbackFunc01 cbFunc, Object usrParam);
/** Returns if callback is mapped for <br> <code> public void MessageCallback01(T2_CallbackFunc01 cbFunc, Object usrParam)</code> **/
public boolean isMessageCallback01Mapped();
/** Returns T2_CallbackFunc01 callback for <br> <code> public void MessageCallback01(T2_CallbackFunc01 cbFunc, Object usrParam)</code> **/
public T2_CallbackFunc01 getMessageCallback01();
/** Returns user-param for <br> <code> public void MessageCallback01(T2_CallbackFunc01 cbFunc, Object usrParam)</code> **/
public Object getMessageCallback01UserParam();
/** Releases callback data skipping toolkit API. Favor passing `null` callback ref to <br> <code> public void MessageCallback01(T2_CallbackFunc01 cbFunc, Object usrParam)</code> **/
public void releaseMessageCallback01();
/** Entry point (through function pointer) to C language function: <br> <code>void InjectMessageCallback01(size_t id, const char * msg)</code><br> */
public void InjectMessageCallback01(long id, String msg);
This example demonstrates a homogeneous Java
Object UserParam
mapping with a key-mapped
CallbackFunction
and UserParam
.
This example is derived from OpenAL's
AL_SOFT_callback_buffer
extension.
The callback ALBUFFERCALLBACKTYPESOFT
is mapped to
buffer
name, i.e. one callback can be set for each
buffer.
C-API Header snipped
typedef void ( * ALBUFFERCALLBACKTYPESOFT)(int buffer /* key */, void *userptr, int sampledata, int numbytes);
void alBufferCallback0(int buffer /* key */, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, void *userptr);
void alBufferCallback0Inject(int buffer, int sampledata, int numbytes);
and the following GlueGen configuration
# Define a JavaCallback.
# Set JavaCallback via function `alBufferCallback0` if `ALBUFFERCALLBACKTYPESOFT` argument is non-null, otherwise removes the mapped callback and associated resources.
#
# It uses the function-pointer argument `ALBUFFERCALLBACKTYPESOFT` as the callback function type
# and marks `ALBUFFERCALLBACKTYPESOFT`s 2nd argument (index 1) as the mandatory user-param.
#
# This callback defines one key, `buffer`, index 0 of alBufferCallback0(..) parameter list, limiting it to buffer-name scope!
# The `buffer` key allows setting one callback per buffer-name, compatible with the `AL_SOFT_callback_buffer` spec.
#
# Explicit queries are generated, passing the keys as paramters
# - `Set<AlBufferCallback0Key> getAlBufferCallback0Keys()` returns set of Key { int buffer }
# - `boolean isAlBufferCallback0Mapped(AlBufferCallback0Key)` queries whether `alBufferCallback0` is mapped to `buffer`.
# - `ALBUFFERCALLBACKTYPESOFT getAlBufferCallback0(AlBufferCallback0Key)` returns the `buffer` mapped ALEVENTPROCSOFT, null if not mapped
# - `Object getAlBufferCallback0UserParam(AlBufferCallback0Key)` returns the `buffer` mapped `userptr` object, null if not mapped
# - `void releaseAllAlBufferCallback0()` releases all callback data mapped via Key { int buffer } skipping toolkit API. Favor passing `null` callback ref to `alBufferCallback0(..)`
# - `void releaseAlBufferCallback0(AlBufferCallback0Key)` releases callback data mapped to Key { int buffer } skipping toolkit API. Favor passing `null` callback ref to `alBufferCallback0(..)`
JavaCallbackDef alBufferCallback0 4 ALBUFFERCALLBACKTYPESOFT 1
JavaCallbackKey alBufferCallback0 0 ALBUFFERCALLBACKTYPESOFT 0
leading to the following interface
/** JavaCallback interface: ALBUFFERCALLBACKTYPESOFT -> void (*ALBUFFERCALLBACKTYPESOFT)(int buffer, void * userptr, int sampledata, int numbytes) */
public static interface ALBUFFERCALLBACKTYPESOFT {
/** Interface to C language function: <br> <code>void callback(int buffer, void * userptr, int sampledata, int numbytes)</code><br>Alias for: <code>ALBUFFERCALLBACKTYPESOFT</code> */
public void callback(int buffer, Object userptr, int sampledata, int numbytes);
}
...
/** Key { int buffer } for <br> <code> public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)</code> **/
public static class AlBufferCallback0Key {
public final int buffer;
public AlBufferCallback0Key(int buffer) {
this.buffer = buffer;
}
@Override
public boolean equals(final Object o) {
if( this == o ) {
return true;
}
if( !(o instanceof AlBufferCallback0Key) ) {
return false;
}
final AlBufferCallback0Key o2 = (AlBufferCallback0Key)o;
return buffer == o2.buffer;
}
@Override
public int hashCode() {
// 31 * x == (x << 5) - x
int hash = buffer;
return hash;
}
}
...
/** Entry point (through function pointer) to C language function: <br> <code>void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, void * userptr)</code><br> */
public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr);
/** Returns set of Key { int buffer } for <br> <code> public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)</code> **/
public Set<AlBufferCallback0Key> getAlBufferCallback0Keys();
/** Returns whether callback Key { int buffer } is mapped for <br> <code> public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)</code> **/
public boolean isAlBufferCallback0Mapped(AlBufferCallback0Key key);
/** Returns ALBUFFERCALLBACKTYPESOFT callback mapped to Key { int buffer } for <br> <code> public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)</code> **/
public ALBUFFERCALLBACKTYPESOFT getAlBufferCallback0(AlBufferCallback0Key key);
/** Returns user-param mapped to Key { int buffer } for <br> <code> public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)</code> **/
public Object getAlBufferCallback0UserParam(AlBufferCallback0Key key);
/** Releases all callback data mapped via Key { int buffer } skipping toolkit API. Favor passing `null` callback ref to <br> <code> public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)</code> **/
public int releaseAllAlBufferCallback0();
/** Releases callback data mapped to Key { int buffer } skipping toolkit API. Favor passing `null` callback ref to <br> <code> public void alBufferCallback0(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)</code> **/
public void releaseAlBufferCallback0(AlBufferCallback0Key key);
/** Entry point (through function pointer) to C language function: <br> <code>void alEventCallbackInject(int eventType, int object, int param, const char * msg)</code><br> */
public void alEventCallbackInject(int eventType, int object, int param, String msg);
Similar example as example 2a, but using a custom KeyClass to map
CallbackFunction
and UserParam
and also
accommodating a different key-parameter order between
SetCallbackFunction
and CallbackFunction
.
C-API Header snipped
typedef void ( * ALBUFFERCALLBACKTYPESOFT)(int buffer /* key */, void *userptr, int sampledata, int numbytes);
void alBufferCallback1(void *user_ptr, int buffer_key /* key */, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback);
void alBufferCallback1Inject(int buffer, int sampledata, int numbytes);
GlueGen configuration snippet with the added option attribute for the
SetCallback-KeyClass
in directive
JavaCallbackDef
.
JavaCallbackDef alBufferCallback1 0 ALBUFFERCALLBACKTYPESOFT 1 com.jogamp.gluegen.test.junit.generation.Test4JavaCallback.CustomAlBufferCallback1Key
JavaCallbackKey alBufferCallback1 1 ALBUFFERCALLBACKTYPESOFT 0
Implementation utilizes a custom SetCallback-KeyClass
implementation for
void alBufferCallback1(int buffer, int format, int freq, ALBUFFERCALLBACKTYPESOFT callback, Object userptr)
,
which uses one key, i.e. buffer
.
public static class CustomAlBufferCallback1Key {
private final int buffer;
public CustomAlBufferCallback1Key(final int buffer) {
this.buffer = buffer;
}
@Override
public boolean equals(final Object o) {
if( this == o ) {
return true;
}
if( !(o instanceof CustomAlBufferCallback1Key) ) {
return false;
}
final CustomAlBufferCallback1Key o2 = (CustomAlBufferCallback1Key)o;
return buffer == o2.buffer;
}
@Override
public int hashCode() {
return buffer;
}
@Override
public String toString() {
return "CustomALKey[this "+toHexString(System.identityHashCode(this))+", buffer "+buffer+"]";
}
}
This example demonstrates a homogeneous Struct
UserParam
mapping with a key-mapped
CallbackFunction
and UserParam
.
The callback T2_CallbackFunc11
is passed by the toolkit
to the CallbackFunction
and by the user to the registration
method MessageCallback11b(..)
.
C-API Header snipped
typedef struct {
int32_t ApiVersion;
void* Data;
long i;
long r;
size_t id;
} T2_Callback11UserType;
typedef void ( * T2_CallbackFunc11)(size_t id, const T2_Callback11UserType* usrParam, long val);
void MessageCallback11a(size_t id /* key */, T2_CallbackFunc11 cbFunc, const T2_Callback11UserType* usrParam);
void MessageCallback11aInject(size_t id, long val);
and the following GlueGen configuration
JavaCallbackDef MessageCallback11a 2 T2_CallbackFunc11 1
JavaCallbackKey MessageCallback11a 0 T2_CallbackFunc11 0
leading to the following interface
/** JavaCallback interface: T2_CallbackFunc11 -> void (*T2_CallbackFunc11)(size_t id, const T2_Callback11UserType * usrParam, long val) */
public static interface T2_CallbackFunc11 {
/** Interface to C language function: <br> <code>void callback(size_t id, const T2_Callback11UserType * usrParam, long val)</code><br>Alias for: <code>T2_CallbackFunc11</code> */
public void callback(long id, T2_Callback11UserType usrParam, long val);
}
...
public static class MessageCallback11aKey { ... }
...
/** Returns set of Key { long id } for <br> <code> void MessageCallback11a(long id, T2_CallbackFunc11 cbFunc, T2_Callback11UserType usrParam)</code> */
public Set<MessageCallback11aKey> getMessageCallback11aKeys();
/** Returns whether callback Key { long id } is mapped for <br> <code> void MessageCallback11a(long id, T2_CallbackFunc11 cbFunc, T2_Callback11UserType usrParam)</code> */
public boolean isMessageCallback11aMapped(MessageCallback11aKey key);
/** Returns T2_CallbackFunc11 callback mapped to Key { long id } for <br> <code> void MessageCallback11a(long id, T2_CallbackFunc11 cbFunc, T2_Callback11UserType usrParam)</code> */
public T2_CallbackFunc11 getMessageCallback11a(MessageCallback11aKey key);
/** Returns user-param mapped to Key { long id } for <br> <code> void MessageCallback11a(long id, T2_CallbackFunc11 cbFunc, T2_Callback11UserType usrParam)</code> */
public Object getMessageCallback11aUserParam(MessageCallback11aKey key);
/** Releases all callback data mapped via Key { long id } skipping toolkit API. Favor passing `null` callback ref to <br> <code> void MessageCallback11a(long id, T2_CallbackFunc11 cbFunc, T2_Callback11UserType usrParam)</code> */
public int releaseAllMessageCallback11a();
/** Releases callback data mapped to Key { long id } skipping toolkit API. Favor passing `null` callback ref to <br> <code> void MessageCallback11a(long id, T2_CallbackFunc11 cbFunc, T2_Callback11UserType usrParam)</code> */
public void releaseMessageCallback11a(MessageCallback11aKey key);
/** Entry point (through function pointer) to C language function: <br> <code>void MessageCallback11a(size_t id, T2_CallbackFunc11 cbFunc, const T2_Callback11UserType * usrParam)</code><br> */
public void MessageCallback11a(long id, T2_CallbackFunc11 cbFunc, T2_Callback11UserType usrParam);
/** Entry point (through function pointer) to C language function: <br> <code>void MessageCallback11aInject(size_t id, long val)</code><br> */
public void MessageCallback11aInject(long id, long val);
This example demonstrates a heterogeneous
Struct UserParam
mapping with a key-mapped
CallbackFunction
and UserParam
.
The callback T2_CallbackFunc11
is managed by the toolkit
and passed to the callback function, while user passes a
void*
as a long
value to the registration
method MessageCallback11b(..)
. The toolkit associates the
users' void*
pointer with the
T2_CallbackFunc11
.
C-API Header snipped
typedef struct {
int32_t ApiVersion;
void* Data;
long i;
long r;
size_t id;
} T2_Callback11UserType;
typedef void ( * T2_CallbackFunc11)(size_t id, const T2_Callback11UserType* usrParam, long val);
void MessageCallback11b(size_t id /* key */, T2_CallbackFunc11 cbFunc, void* Data);
void MessageCallback11bInject(size_t id, long val);
and the following GlueGen configuration
JavaCallbackDef MessageCallback11b 2 T2_CallbackFunc11 1
JavaCallbackKey MessageCallback11b 0 T2_CallbackFunc11 0
leading to the following interface
/** JavaCallback interface: T2_CallbackFunc11 -> void (*T2_CallbackFunc11)(size_t id, const T2_Callback11UserType * usrParam, long val) */
public static interface T2_CallbackFunc11 {
/** Interface to C language function: <br> <code>void callback(size_t id, const T2_Callback11UserType * usrParam, long val)</code><br>Alias for: <code>T2_CallbackFunc11</code> */
public void callback(long id, T2_Callback11UserType usrParam, long val);
}
...
public static class MessageCallback11bKey { ... }
...
/** Returns set of Key { long id } for <br> <code> void MessageCallback11b(long id, T2_CallbackFunc11 cbFunc, long Data)</code> */
public Set<MessageCallback11bKey> getMessageCallback11bKeys();
/** Returns whether callback Key { long id } is mapped for <br> <code> void MessageCallback11b(long id, T2_CallbackFunc11 cbFunc, long Data)</code> */
public boolean isMessageCallback11bMapped(MessageCallback11bKey key);
/** Returns T2_CallbackFunc11 callback mapped to Key { long id } for <br> <code> void MessageCallback11b(long id, T2_CallbackFunc11 cbFunc, long Data)</code> */
public T2_CallbackFunc11 getMessageCallback11b(MessageCallback11bKey key);
/** Returns user-param mapped to Key { long id } for <br> <code> void MessageCallback11b(long id, T2_CallbackFunc11 cbFunc, long Data)</code> */
public Object getMessageCallback11bUserParam(MessageCallback11bKey key);
/** Releases all callback data mapped via Key { long id } skipping toolkit API. Favor passing `null` callback ref to <br> <code> void MessageCallback11b(long id, T2_CallbackFunc11 cbFunc, long Data)</code> */
public int releaseAllMessageCallback11b();
/** Releases callback data mapped to Key { long id } skipping toolkit API. Favor passing `null` callback ref to <br> <code> void MessageCallback11b(long id, T2_CallbackFunc11 cbFunc, long Data)</code> */
public void releaseMessageCallback11b(MessageCallback11bKey key);
/** Entry point (through function pointer) to C language function: <br> <code>void MessageCallback11b(size_t id, T2_CallbackFunc11 cbFunc, void * Data)</code><br> */
public void MessageCallback11b(long id, T2_CallbackFunc11 cbFunc, long Data);
/** Entry point (through function pointer) to C language function: <br> <code>void MessageCallback11bInject(size_t id, long val)</code><br> */
public void MessageCallback11bInject(long id, long val);
TODO: Enhance documentation
LibraryOnLoad <LibraryBasename>
for JNI_OnLoad*(..)
...LibraryOnLoad <LibraryBasename>
can be
specified in one native code-unit within one native library maximum,
otherwise multiple function definitions would occur.
In case Java™ callback methods are used,
it is required to have
LibraryOnLoad <LibraryBasename>
specified in exactly
one native code-unit within one native library.
LibraryOnLoad <LibraryBasename>
generates native
JNI code to handle the JavaVM*
instance
JavaVM* JVMUtil_GetJavaVM()
returning the static
JavaVM*
instance for LibraryBasename
set by
JNI_OnLoad*()
JNI_OnLoad(..)
setting the static JavaVM*
instance for LibraryBasename
, used for dynamic
libraries,JNI_OnLoad_<LibraryBasename>(..)
setting the
static JavaVM*
instance for LibraryBasename
,
used for static libraries,Further the following functions are produced to attach and detach the
current thread to and from the JVM, getting and releasing the
JNIEnv*
JNIEnv* JVMUtil_GetJNIEnv(int asDaemon, int* jvmAttached)
returns the JNIEnv*
with current thread being newly
attached to the JavaVM*
if result
*jvmAttached == true
, otherwise the current thread was
already attached to the JavaVM*
void JVMUtil_ReleaseJNIEnv(JNIEnv* env, int detachJVM)
releases the JNIEnv*
, i.e. detaching the current thread
from the JavaVM*
if
detachJVM == true
, otherwise funtion does nothing.GlueGen provides convenient platform headers,
which can be included in your C header files for native compilation and
GlueGen code generation.
Example:
#include <gluegen_stdint.h>
#include <gluegen_stddef.h>
uint64_t test64;
size_t size1;
ptrdiff_t ptr1;
To compile this file you have to include the following folder to your
compilers system includes, ie -I
:
gluegen/make/stub_includes/platform
To generate code for this file you have to include the following
folder to your GlueGen includeRefid
element:
gluegen/make/stub_includes/gluegen
To identity a GlueGen code generation run, GlueGen defines the following macros:
#define __GLUEGEN__ 2