/* * Copyright (c) 2003 Sun Microsystems, Inc. All Rights Reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * - Redistribution of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * - Redistribution in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Sun Microsystems, Inc. or the names of * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * This software is provided "AS IS," without a warranty of any kind. ALL * EXPRESS OR IMPLIED CONDITIONS, REPRESENTATIONS AND WARRANTIES, * INCLUDING ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A * PARTICULAR PURPOSE OR NON-INFRINGEMENT, ARE HEREBY EXCLUDED. SUN * MICROSYSTEMS, INC. ("SUN") AND ITS LICENSORS SHALL NOT BE LIABLE FOR * ANY DAMAGES SUFFERED BY LICENSEE AS A RESULT OF USING, MODIFYING OR * DISTRIBUTING THIS SOFTWARE OR ITS DERIVATIVES. IN NO EVENT WILL SUN OR * ITS LICENSORS BE LIABLE FOR ANY LOST REVENUE, PROFIT OR DATA, OR FOR * DIRECT, INDIRECT, SPECIAL, CONSEQUENTIAL, INCIDENTAL OR PUNITIVE * DAMAGES, HOWEVER CAUSED AND REGARDLESS OF THE THEORY OF LIABILITY, * ARISING OUT OF THE USE OF OR INABILITY TO USE THIS SOFTWARE, EVEN IF * SUN HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. * * You acknowledge that this software is not designed or intended for use * in the design, construction, operation or maintenance of any nuclear * facility. * * Sun gratefully acknowledges that this software was originally authored * and developed by Kenneth Bradley Russell and Christopher John Kline. */ package com.sun.gluegen; import java.io.*; import java.util.*; import java.text.MessageFormat; import com.sun.gluegen.cgram.types.*; import com.sun.gluegen.cgram.*; /** * An emitter that emits only the interface for a Java<->C JNI binding. */ public class JavaMethodBindingEmitter extends FunctionEmitter { public static final EmissionModifier PUBLIC = new EmissionModifier("public"); public static final EmissionModifier PROTECTED = new EmissionModifier("protected"); public static final EmissionModifier PRIVATE = new EmissionModifier("private"); public static final EmissionModifier ABSTRACT = new EmissionModifier("abstract"); public static final EmissionModifier FINAL = new EmissionModifier("final"); public static final EmissionModifier NATIVE = new EmissionModifier("native"); public static final EmissionModifier SYNCHRONIZED = new EmissionModifier("synchronized"); protected final CommentEmitter defaultJavaCommentEmitter = new DefaultCommentEmitter(); protected final CommentEmitter defaultInterfaceCommentEmitter = new InterfaceCommentEmitter(); // Exception type raised in the generated code if runtime checks fail private String runtimeExceptionType; private String unsupportedExceptionType; protected boolean emitBody; protected boolean eraseBufferAndArrayTypes; protected boolean directNIOOnly; protected boolean forImplementingMethodCall; protected boolean forDirectBufferImplementation; protected boolean forIndirectBufferAndArrayImplementation; protected boolean isUnimplemented; protected boolean tagNativeBinding; protected MethodBinding binding; // Manually-specified prologue and epilogue code protected List/**/ prologue; protected List/**/ epilogue; // A non-null value indicates that rather than returning a compound // type accessor we are returning an array of such accessors; this // expression is a MessageFormat string taking the names of the // incoming Java arguments as parameters and computing as an int the // number of elements of the returned array. private String returnedArrayLengthExpression; // A suffix used to create a temporary outgoing array of Buffers to // represent an array of compound type wrappers private static final String COMPOUND_ARRAY_SUFFIX = "_buf_array_copy"; // Only present to provide more clear comments private JavaConfiguration cfg; public JavaMethodBindingEmitter(MethodBinding binding, PrintWriter output, String runtimeExceptionType, String unsupportedExceptionType, boolean emitBody, boolean tagNativeBinding, boolean eraseBufferAndArrayTypes, boolean directNIOOnly, boolean forImplementingMethodCall, boolean forDirectBufferImplementation, boolean forIndirectBufferAndArrayImplementation, boolean isUnimplemented, boolean isInterface, JavaConfiguration configuration) { super(output, isInterface); this.binding = binding; this.runtimeExceptionType = runtimeExceptionType; this.unsupportedExceptionType = unsupportedExceptionType; this.emitBody = emitBody; this.tagNativeBinding = tagNativeBinding; this.eraseBufferAndArrayTypes = eraseBufferAndArrayTypes; this.directNIOOnly = directNIOOnly; this.forImplementingMethodCall = forImplementingMethodCall; this.forDirectBufferImplementation = forDirectBufferImplementation; this.forIndirectBufferAndArrayImplementation = forIndirectBufferAndArrayImplementation; this.isUnimplemented = isUnimplemented; if (forImplementingMethodCall) { setCommentEmitter(defaultJavaCommentEmitter); } else { setCommentEmitter(defaultInterfaceCommentEmitter); } cfg = configuration; } public JavaMethodBindingEmitter(JavaMethodBindingEmitter arg) { super(arg); binding = arg.binding; runtimeExceptionType = arg.runtimeExceptionType; unsupportedExceptionType = arg.unsupportedExceptionType; emitBody = arg.emitBody; tagNativeBinding = arg.tagNativeBinding; eraseBufferAndArrayTypes = arg.eraseBufferAndArrayTypes; directNIOOnly = arg.directNIOOnly; forImplementingMethodCall = arg.forImplementingMethodCall; forDirectBufferImplementation = arg.forDirectBufferImplementation; forIndirectBufferAndArrayImplementation = arg.forIndirectBufferAndArrayImplementation; isUnimplemented = arg.isUnimplemented; prologue = arg.prologue; epilogue = arg.epilogue; returnedArrayLengthExpression = arg.returnedArrayLengthExpression; cfg = arg.cfg; } public final MethodBinding getBinding() { return binding; } public boolean isForImplementingMethodCall() { return forImplementingMethodCall; } public boolean isForDirectBufferImplementation() { return forDirectBufferImplementation; } public boolean isForIndirectBufferAndArrayImplementation() { return forIndirectBufferAndArrayImplementation; } public String getName() { return binding.getRenamedMethodName(); } protected String getArgumentName(int i) { return binding.getArgumentName(i); } /** The type of exception (must subclass java.lang.RuntimeException) raised if runtime checks fail in the generated code. */ public String getRuntimeExceptionType() { return runtimeExceptionType; } public String getUnsupportedExceptionType() { return unsupportedExceptionType; } /** If the underlying function returns an array (currently only arrays of compound types are supported) as opposed to a pointer to an object, this method should be called to provide a MessageFormat string containing an expression that computes the number of elements of the returned array. The parameters to the MessageFormat expression are the names of the incoming Java arguments. */ public void setReturnedArrayLengthExpression(String expr) { returnedArrayLengthExpression = expr; } /** Sets the manually-generated prologue code for this emitter. */ public void setPrologue(List/**/ prologue) { this.prologue = prologue; } /** Sets the manually-generated epilogue code for this emitter. */ public void setEpilogue(List/**/ epilogue) { this.epilogue = epilogue; } /** Indicates whether this emitter will print only a signature, or whether it will emit Java code for the body of the method as well. */ public boolean signatureOnly() { return !emitBody; } /** Accessor for subclasses. */ public void setEmitBody(boolean emitBody) { this.emitBody = emitBody; } /** Accessor for subclasses. */ public void setEraseBufferAndArrayTypes(boolean erase) { this.eraseBufferAndArrayTypes = erase; } /** Accessor for subclasses. */ public void setForImplementingMethodCall(boolean impl) { this.forImplementingMethodCall = impl; } /** Accessor for subclasses. */ public void setForDirectBufferImplementation(boolean direct) { this.forDirectBufferImplementation = direct; } /** Accessor for subclasses. */ public void setForIndirectBufferAndArrayImplementation(boolean indirect) { this.forIndirectBufferAndArrayImplementation = indirect; } protected void emitReturnType(PrintWriter writer) { writer.print(getReturnTypeString(false)); } protected String erasedTypeString(JavaType type, boolean skipBuffers) { if (eraseBufferAndArrayTypes) { if (type.isNIOBuffer()) { if (!skipBuffers) { // Direct buffers and arrays sent down as Object (but // returned as e.g. ByteBuffer) return "Object"; } if (!type.isNIOByteBuffer()) { // Return buffer requiring change of view from ByteBuffer to e.g. LongBuffer return "java.nio.ByteBuffer"; } } else if (type.isPrimitiveArray()) { if (!skipBuffers) { // Direct buffers and arrays sent down as Object (but // returned as e.g. ByteBuffer) return "Object"; } } else if (type.isNIOBufferArray()) { // Arrays of direct Buffers sent down as Object[] // (Note we don't yet support returning void**) return "Object[]"; } else if (type.isCompoundTypeWrapper()) { // Compound type wrappers are unwrapped to ByteBuffer return "java.nio.ByteBuffer"; } else if (type.isArrayOfCompoundTypeWrappers()) { if (skipBuffers) { return "java.nio.ByteBuffer"; } else { // In the case where this is called with a false skipBuffers // argument we want to erase the array of compound type // wrappers to ByteBuffer[] return "java.nio.ByteBuffer[]"; } } } if (type.isArrayOfCompoundTypeWrappers()) { // We don't want to bake the array specification into the type name return type.getName() + "[]"; } return type.getName(); } protected String getReturnTypeString(boolean skipArray) { // The first arm of the "if" clause is used by the glue code // generation for arrays of compound type wrappers if (skipArray || // The following arm is used by most other kinds of return types (getReturnedArrayLengthExpression() == null && !binding.getJavaReturnType().isArrayOfCompoundTypeWrappers()) || // The following arm is used specifically to get the splitting up // of one returned ByteBuffer into an array of compound type // wrappers to work (e.g., XGetVisualInfo) (eraseBufferAndArrayTypes && binding.getJavaReturnType().isCompoundTypeWrapper() && (getReturnedArrayLengthExpression() != null))) { return erasedTypeString(binding.getJavaReturnType(), true); } return erasedTypeString(binding.getJavaReturnType(), true) + "[]"; } protected void emitName(PrintWriter writer) { if (forImplementingMethodCall) { if (forIndirectBufferAndArrayImplementation) { writer.print(getImplMethodName(false)); } else { writer.print(getImplMethodName(true)); } } else { writer.print(getName()); } } protected int emitArguments(PrintWriter writer) { boolean needComma = false; int numEmitted = 0; if (forImplementingMethodCall && binding.hasContainingType()) { // Always emit outgoing "this" argument writer.print("java.nio.ByteBuffer "); writer.print(javaThisArgumentName()); ++numEmitted; needComma = true; } for (int i = 0; i < binding.getNumArguments(); i++) { JavaType type = binding.getJavaArgumentType(i); if (type.isVoid()) { // Make sure this is the only param to the method; if it isn't, // there's something wrong with our parsing of the headers. if (binding.getNumArguments() != 1) { throw new InternalError( "\"void\" argument type found in " + "multi-argument function \"" + binding + "\""); } continue; } if (type.isJNIEnv() || binding.isArgumentThisPointer(i)) { // Don't need to expose these at the Java level continue; } if (needComma) { writer.print(", "); } writer.print(erasedTypeString(type, false)); writer.print(" "); writer.print(getArgumentName(i)); ++numEmitted; needComma = true; // Add Buffer and array index offset arguments after each associated argument if (forDirectBufferImplementation || forIndirectBufferAndArrayImplementation) { if (type.isNIOBuffer()) { writer.print(", int " + byteOffsetArgName(i)); } else if (type.isNIOBufferArray()) { writer.print(", int[] " + byteOffsetArrayArgName(i)); } } // Add offset argument after each primitive array if (type.isPrimitiveArray()) { writer.print(", int " + offsetArgName(i)); } } return numEmitted; } protected String getImplMethodName(boolean direct) { if (direct) { return binding.getRenamedMethodName() + "0"; } else { return binding.getRenamedMethodName() + "1"; } } protected String byteOffsetArgName(int i) { return byteOffsetArgName(getArgumentName(i)); } protected String byteOffsetArgName(String s) { return s + "_byte_offset"; } protected String byteOffsetArrayArgName(int i) { return getArgumentName(i) + "_byte_offset_array"; } protected String offsetArgName(int i) { return getArgumentName(i) + "_offset"; } protected void emitBody(PrintWriter writer) { if (!emitBody) { writer.println(';'); } else { MethodBinding binding = getBinding(); writer.println(); writer.println(" {"); if (isUnimplemented) { writer.println(" throw new " + getUnsupportedExceptionType() + "(\"Unimplemented\");"); } else { emitPrologueOrEpilogue(prologue, writer); emitPreCallSetup(binding, writer); //emitReturnVariableSetup(binding, writer); emitReturnVariableSetupAndCall(binding, writer); } writer.println(" }"); } } protected void emitPrologueOrEpilogue(List/**/ code, PrintWriter writer) { if (code != null) { String[] argumentNames = argumentNameArray(); for (Iterator iter = code.iterator(); iter.hasNext(); ) { MessageFormat fmt = new MessageFormat((String) iter.next()); writer.println(" " + fmt.format(argumentNames)); } } } protected void emitPreCallSetup(MethodBinding binding, PrintWriter writer) { emitArrayLengthAndNIOBufferChecks(binding, writer); emitCompoundArrayCopies(binding, writer); } protected void emitArrayLengthAndNIOBufferChecks(MethodBinding binding, PrintWriter writer) { int numBufferOffsetArrayArgs = 0; boolean firstBuffer = true; // Check lengths of any incoming arrays if necessary for (int i = 0; i < binding.getNumArguments(); i++) { Type type = binding.getCArgumentType(i); if (type.isArray()) { ArrayType arrayType = type.asArray(); writer.println(" if (" + getArgumentName(i) + ".length < " + arrayType.getLength() + ")"); writer.println(" throw new " + getRuntimeExceptionType() + "(\"Length of array \\\"" + getArgumentName(i) + "\\\" was less than the required " + arrayType.getLength() + "\");"); } else { JavaType javaType = binding.getJavaArgumentType(i); if (javaType.isNIOBuffer()) { if (directNIOOnly) { writer.println(" if (!BufferFactory.isDirect(" + getArgumentName(i) + "))"); writer.println(" throw new " + getRuntimeExceptionType() + "(\"Argument \\\"" + getArgumentName(i) + "\\\" was not a direct buffer\");"); } else { if(firstBuffer) { firstBuffer = false; writer.println(" boolean _direct = BufferFactory.isDirect(" + getArgumentName(i) + ");"); } else { writer.println(" if (" + getArgumentName(i) + " != null && _direct != BufferFactory.isDirect(" + getArgumentName(i) + "))"); writer.println(" throw new " + getRuntimeExceptionType() + "(\"Argument \\\"" + getArgumentName(i) + "\\\" : Buffers passed to this method must all be either direct or indirect\");"); } } } else if (javaType.isNIOBufferArray()) { // All buffers passed down in an array of NIO buffers must be direct String argName = getArgumentName(i); String arrayName = byteOffsetArrayArgName(i); writer.println(" int[] " + arrayName + " = new int[" + argName + ".length];"); // Check direct buffer properties of all buffers within writer.println(" if (" + argName + " != null) {"); writer.println(" for (int _ctr = 0; _ctr < " + argName + ".length; _ctr++) {"); writer.println(" if (!BufferFactory.isDirect(" + argName + "[_ctr])) {"); writer.println(" throw new " + getRuntimeExceptionType() + "(\"Element \" + _ctr + \" of argument \\\"" + getArgumentName(i) + "\\\" was not a direct buffer\");"); writer.println(" }"); // get the Buffer Array offset values and save them into another array to send down to JNI writer.print (" " + arrayName + "[_ctr] = BufferFactory.getDirectBufferByteOffset("); writer.println(argName + "[_ctr]);"); writer.println(" }"); writer.println(" }"); } else if (javaType.isPrimitiveArray()) { String argName = getArgumentName(i); String offsetArg = offsetArgName(i); writer.println(" if(" + argName + " != null && " + argName + ".length <= " + offsetArg + ")"); writer.print (" throw new " + getRuntimeExceptionType()); writer.println("(\"array offset argument \\\"" + offsetArg + "\\\" (\" + " + offsetArg + " + \") equals or exceeds array length (\" + " + argName + ".length + \")\");"); } } } } protected void emitCompoundArrayCopies(MethodBinding binding, PrintWriter writer) { // If the method binding uses outgoing arrays of compound type // wrappers, we need to generate a temporary copy of this array // into a ByteBuffer[] for processing by the native code if (binding.signatureUsesArraysOfCompoundTypeWrappers()) { for (int i = 0; i < binding.getNumArguments(); i++) { JavaType javaType = binding.getJavaArgumentType(i); if (javaType.isArrayOfCompoundTypeWrappers()) { String argName = getArgumentName(i); String tempArrayName = argName + COMPOUND_ARRAY_SUFFIX; writer.println(" ByteBuffer[] " + tempArrayName + " = new ByteBuffer[" + argName + ".length];"); writer.println(" for (int _ctr = 0; _ctr < + " + argName + ".length; _ctr++) {"); writer.println(" " + javaType.getName() + " _tmp = " + argName + "[_ctr];"); writer.println(" " + tempArrayName + "[_ctr] = ((_tmp == null) ? null : _tmp.getBuffer());"); writer.println(" }"); } } } } protected void emitCall(MethodBinding binding, PrintWriter writer, boolean direct) { writer.print(getImplMethodName(direct)); writer.print("("); emitCallArguments(binding, writer, direct); writer.print(")"); } protected void emitReturnVariableSetupAndCall(MethodBinding binding, PrintWriter writer) { writer.print(" "); JavaType returnType = binding.getJavaReturnType(); boolean needsResultAssignment = false; if (!returnType.isVoid()) { if (returnType.isCompoundTypeWrapper() || returnType.isNIOBuffer()) { writer.println("java.nio.ByteBuffer _res;"); needsResultAssignment = true; } else if (returnType.isArrayOfCompoundTypeWrappers()) { writer.println("java.nio.ByteBuffer[] _res;"); needsResultAssignment = true; } else if (((epilogue != null) && (epilogue.size() > 0)) || binding.signatureUsesArraysOfCompoundTypeWrappers()) { emitReturnType(writer); writer.println(" _res;"); needsResultAssignment = true; } } if (binding.signatureCanUseIndirectNIO() && !directNIOOnly) { // Must generate two calls for this gated on whether the NIO // buffers coming in are all direct or indirect writer.println("if (_direct) {"); writer.print (" "); } if (needsResultAssignment) { writer.print(" _res = "); } else { writer.print(" "); if (!returnType.isVoid()) { writer.print("return "); } } if (binding.signatureUsesJavaPrimitiveArrays() && !binding.signatureCanUseIndirectNIO()) { // FIXME: what happens with a C function of the form // void foo(int* arg0, void* arg1); // ? // Only one call being made in this body, going to indirect // buffer / array entry point emitCall(binding, writer, false); writer.print(";"); writer.println(); } else { emitCall(binding, writer, true); writer.print(";"); } if (binding.signatureCanUseIndirectNIO() && !directNIOOnly) { // Must generate two calls for this gated on whether the NIO // buffers coming in are all direct or indirect writer.println(); writer.println(" } else {"); writer.print (" "); if (needsResultAssignment) { writer.print(" _res = "); } else { writer.print(" "); if (!returnType.isVoid()) { writer.print("return "); } } emitCall(binding, writer, false); writer.print(";"); writer.println(); writer.println(" }"); } else { writer.println(); } emitPostCallCleanup(binding, writer); emitPrologueOrEpilogue(epilogue, writer); if (needsResultAssignment) { emitCallResultReturn(binding, writer); } } protected int emitCallArguments(MethodBinding binding, PrintWriter writer, boolean direct) { boolean needComma = false; int numArgsEmitted = 0; if (binding.hasContainingType()) { // Emit this pointer assert(binding.getContainingType().isCompoundTypeWrapper()); writer.print("getBuffer()"); needComma = true; ++numArgsEmitted; } for (int i = 0; i < binding.getNumArguments(); i++) { JavaType type = binding.getJavaArgumentType(i); if (type.isJNIEnv() || binding.isArgumentThisPointer(i)) { // Don't need to expose these at the Java level continue; } if (type.isVoid()) { // Make sure this is the only param to the method; if it isn't, // there's something wrong with our parsing of the headers. assert(binding.getNumArguments() == 1); continue; } if (needComma) { writer.print(", "); } if (type.isCompoundTypeWrapper()) { writer.print("(("); } if (type.isNIOBuffer() && !direct) { writer.print("BufferFactory.getArray(" + getArgumentName(i) + ")"); } else if (type.isArrayOfCompoundTypeWrappers()) { writer.print(getArgumentName(i) + COMPOUND_ARRAY_SUFFIX); } else { writer.print(getArgumentName(i)); } if (type.isCompoundTypeWrapper()) { writer.print(" == null) ? null : "); writer.print(getArgumentName(i)); writer.print(".getBuffer())"); } if (type.isNIOBuffer()) { if (direct) { writer.print(", BufferFactory.getDirectBufferByteOffset(" + getArgumentName(i) + ")"); } else { writer.print(", BufferFactory.getIndirectBufferByteOffset(" + getArgumentName(i) + ")"); } } else if (type.isNIOBufferArray()) { writer.print(", " + byteOffsetArrayArgName(i)); } // Add Array offset parameter for primitive arrays if (type.isPrimitiveArray()) { if(type.isFloatArray()) { writer.print(", BufferFactory.SIZEOF_FLOAT * "); } else if(type.isDoubleArray()) { writer.print(", BufferFactory.SIZEOF_DOUBLE * "); } else if(type.isByteArray()) { writer.print(", "); } else if(type.isLongArray()) { writer.print(", BufferFactory.SIZEOF_LONG * "); } else if(type.isShortArray()) { writer.print(", BufferFactory.SIZEOF_SHORT * "); } else if(type.isIntArray()) { writer.print(", BufferFactory.SIZEOF_INT * "); } else { throw new RuntimeException("Unsupported type for calculating array offset argument for " + getArgumentName(i) + " -- error occurred while processing Java glue code for " + getName()); } writer.print(offsetArgName(i)); } needComma = true; ++numArgsEmitted; } return numArgsEmitted; } protected void emitPostCallCleanup(MethodBinding binding, PrintWriter writer) { if (binding.signatureUsesArraysOfCompoundTypeWrappers()) { // For each such array, we need to take the ByteBuffer[] that // came back from the C method invocation and wrap the // ByteBuffers back into the wrapper types for (int i = 0; i < binding.getNumArguments(); i++) { JavaType javaArgType = binding.getJavaArgumentType(i); if (javaArgType.isArrayOfCompoundTypeWrappers()) { String argName = binding.getArgumentName(i); writer.println(" for (int _ctr = 0; _ctr < " + argName + ".length; _ctr++) {"); writer.println(" if ((" + argName + "[_ctr] == null && " + argName + COMPOUND_ARRAY_SUFFIX + "[_ctr] == null) ||"); writer.println(" (" + argName + "[_ctr] != null && " + argName + "[_ctr].getBuffer() == " + argName + COMPOUND_ARRAY_SUFFIX + "[_ctr])) {"); writer.println(" // No copy back needed"); writer.println(" } else {"); writer.println(" if (" + argName + COMPOUND_ARRAY_SUFFIX + "[_ctr] == null) {"); writer.println(" " + argName + "[_ctr] = null;"); writer.println(" } else {"); writer.println(" " + argName + "[_ctr] = " + javaArgType.getName() + ".create(" + argName + COMPOUND_ARRAY_SUFFIX + "[_ctr]);"); writer.println(" }"); writer.println(" }"); writer.println(" }"); } } } } protected void emitCallResultReturn(MethodBinding binding, PrintWriter writer) { JavaType returnType = binding.getJavaReturnType(); if (returnType.isCompoundTypeWrapper()) { String fmt = getReturnedArrayLengthExpression(); writer.println(" if (_res == null) return null;"); if (fmt == null) { writer.print(" return " + returnType.getName() + ".create(BufferFactory.nativeOrder(_res))"); } else { writer.println(" BufferFactory.nativeOrder(_res);"); String expr = new MessageFormat(fmt).format(argumentNameArray()); PointerType cReturnTypePointer = binding.getCReturnType().asPointer(); CompoundType cReturnType = null; if (cReturnTypePointer != null) { cReturnType = cReturnTypePointer.getTargetType().asCompound(); } if (cReturnType == null) { throw new RuntimeException("ReturnedArrayLength directive currently only supported for pointers to compound types " + "(error occurred while generating Java glue code for " + getName() + ")"); } writer.println(" " + getReturnTypeString(false) + " _retarray = new " + getReturnTypeString(true) + "[" + expr + "];"); writer.println(" for (int _count = 0; _count < " + expr + "; _count++) {"); // Create temporary ByteBuffer slice // FIXME: probably need Type.getAlignedSize() for arrays of // compound types (rounding up to machine-dependent alignment) writer.println(" _res.position(_count * " + getReturnTypeString(true) + ".size());"); writer.println(" _res.limit ((1 + _count) * " + getReturnTypeString(true) + ".size());"); writer.println(" java.nio.ByteBuffer _tmp = _res.slice();"); writer.println(" BufferFactory.nativeOrder(_tmp);"); writer.println(" _res.position(0);"); writer.println(" _res.limit(_res.capacity());"); writer.println(" _retarray[_count] = " + getReturnTypeString(true) + ".create(_tmp);"); writer.println(" }"); writer.print (" return _retarray"); } writer.println(";"); } else if (returnType.isNIOBuffer()) { writer.println(" if (_res == null) return null;"); writer.println(" BufferFactory.nativeOrder(_res);"); if (!returnType.isNIOByteBuffer()) { // See whether we have to expand pointers to longs if (getBinding().getCReturnType().pointerDepth() >= 2) { if (!returnType.isNIOLongBuffer()) { throw new RuntimeException("While emitting glue code for " + getName() + ": can not legally make pointers opaque to anything but longs"); } writer.println(" return BufferFactory.asPointerBuffer(_res);"); } else { String returnTypeName = returnType.getName().substring("java.nio.".length()); writer.println(" return _res.as" + returnTypeName + "();"); } } else { writer.println(" return _res;"); } } else if (returnType.isArrayOfCompoundTypeWrappers()) { writer.println(" if (_res == null) return null;"); writer.println(" " + getReturnTypeString(false) + " _retarray = new " + getReturnTypeString(true) + "[_res.length];"); writer.println(" for (int _count = 0; _count < _res.length; _count++) {"); writer.println(" _retarray[_count] = " + getReturnTypeString(true) + ".create(_res[_count]);"); writer.println(" }"); writer.println(" return _retarray;"); } else { // Assume it's a primitive type or other type we don't have to // do any conversion on writer.println(" return _res;"); } } protected String[] argumentNameArray() { String[] argumentNames = new String[binding.getNumArguments()]; for (int i = 0; i < binding.getNumArguments(); i++) { argumentNames[i] = getArgumentName(i); if (binding.getJavaArgumentType(i).isPrimitiveArray()) { // Add on _offset argument in comma-separated expression argumentNames[i] = argumentNames[i] + ", " + offsetArgName(i); } } return argumentNames; } public static String javaThisArgumentName() { return "jthis0"; } protected String getCommentStartString() { return "/** "; } protected String getBaseIndentString() { return " "; } protected String getReturnedArrayLengthExpression() { return returnedArrayLengthExpression; } /** * Class that emits a generic comment for JavaMethodBindingEmitters; the comment * includes the C signature of the native method that is being bound by the * emitter java method. */ protected class DefaultCommentEmitter implements CommentEmitter { public void emit(FunctionEmitter emitter, PrintWriter writer) { emitBeginning(emitter, writer); emitBindingCSignature(((JavaMethodBindingEmitter)emitter).getBinding(), writer); emitEnding(emitter, writer); } protected void emitBeginning(FunctionEmitter emitter, PrintWriter writer) { writer.print("Entry point to C language function: "); } protected void emitBindingCSignature(MethodBinding binding, PrintWriter writer) { writer.print(" "); writer.print(binding.getCSymbol().toString(tagNativeBinding)); writer.print(" "); } protected void emitEnding(FunctionEmitter emitter, PrintWriter writer) { // If argument type is a named enum, then emit a comment detailing the // acceptable values of that enum. // If we're emitting a direct buffer variant only, then declare // that the NIO buffer arguments must be direct. MethodBinding binding = ((JavaMethodBindingEmitter)emitter).getBinding(); for (int i = 0; i < binding.getNumArguments(); i++) { Type type = binding.getCArgumentType(i); JavaType javaType = binding.getJavaArgumentType(i); // don't emit param comments for anonymous enums, since we can't // distinguish between the values found within multiple anonymous // enums in the same C translation unit. if (type.isEnum() && type.getName() != HeaderParser.ANONYMOUS_ENUM_NAME) { EnumType enumType = (EnumType)type; writer.println(); writer.print(emitter.getBaseIndentString()); writer.print(" "); writer.print("@param "); writer.print(getArgumentName(i)); writer.print(" valid values are: "); for (int j = 0; j < enumType.getNumEnumerates(); ++j) { if (j>0) writer.print(", "); writer.print(enumType.getEnumName(j)); } writer.println(""); } else if (directNIOOnly && javaType.isNIOBuffer()) { writer.println(); writer.print(emitter.getBaseIndentString()); writer.print(" "); writer.print("@param "); writer.print(getArgumentName(i)); writer.print(" a direct {@link " + javaType.getName() + "}"); } } } } protected class InterfaceCommentEmitter extends JavaMethodBindingEmitter.DefaultCommentEmitter { protected void emitBeginning(FunctionEmitter emitter, PrintWriter writer) { writer.print("Interface to C language function:
"); } } }