/* * 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 * MIDROSYSTEMS, 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 net.java.games.gluegen; import java.io.*; import java.util.*; import java.text.MessageFormat; import net.java.games.gluegen.cgram.types.*; // PROBLEMS: // - what if something returns 'const int *'? Could we // return an IntBuffer that has read-only behavior? Or do we copy the array // (but we don't know its size!). What do we do if it returns a non-const // int*? Should the user be allowed to write back to the returned pointer? // // - Non-const array types must be properly released with JNI_COMMIT // in order to see side effects if the array was copied. public class JavaEmitter implements GlueEmitter { private StructLayout layout; private TypeDictionary typedefDictionary; private TypeDictionary structDictionary; private Map canonMap; private JavaConfiguration cfg; /** * Style of code emission. Can emit everything into one class * (AllStatic), separate interface and implementing classes * (InterfaceAndImpl), only the interface (InterfaceOnly), or only * the implementation (ImplOnly). */ static final int ALL_STATIC = 1; static final int INTERFACE_AND_IMPL = 2; static final int INTERFACE_ONLY = 3; static final int IMPL_ONLY = 4; private PrintWriter javaWriter; // Emits either interface or, in AllStatic mode, everything private PrintWriter javaImplWriter; // Only used in non-AllStatic modes for impl class private PrintWriter cWriter; private MachineDescription machDesc; public void readConfigurationFile(String filename) throws Exception { cfg = createConfig(); cfg.read(filename); } public void setMachineDescription(MachineDescription md) { machDesc = md; } public void beginEmission(GlueEmitterControls controls) throws IOException { try { openWriters(); } catch (Exception e) { throw new RuntimeException( "Unable to open files for writing", e); } emitAllFileHeaders(); // Request emission of any structs requested for (Iterator iter = cfg.forcedStructs().iterator(); iter.hasNext(); ) { controls.forceStructEmission((String) iter.next()); } } public void endEmission() { emitAllFileFooters(); try { closeWriters(); } catch (Exception e) { throw new RuntimeException( "Unable to close open files", e); } } public void beginDefines() throws Exception { if (cfg.allStatic() || cfg.emitInterface()) { javaWriter().println(); } } public void emitDefine(String name, String value, String optionalComment) throws Exception { if (cfg.allStatic() || cfg.emitInterface()) { // TODO: Some defines (e.g., GL_DOUBLE_EXT in gl.h) are defined in terms // of other defines -- should we emit them as references to the original // define (not even sure if the lexer supports this)? Right now they're // emitted as the numeric value of the original definition. If we decide // emit them as references we'll also have to emit them in the correct // order. It's probably not an issue right now because the emitter // currently only emits only numeric defines -- if it handled #define'd // objects it would make a bigger difference. if (!cfg.shouldIgnore(name)) { String type = null; // FIXME: need to handle when type specifier is in last char (e.g., // "1.0d or 2759L", because parseXXX() methods don't allow the type // specifier character in the string. // //char lastChar = value.charAt(value.length()-1); try { // see if it's a long or int int radix; String parseValue; // FIXME: are you allowed to specify hex/octal constants with // negation, e.g. "-0xFF" or "-056"? If so, need to modify the // following "if(..)" checks and parseValue computation if (value.startsWith("0x") || value.startsWith("0X")) { radix = 16; parseValue = value.substring(2); } else if (value.startsWith("0") && value.length() > 1) { // TODO: is "0" the prefix in C to indicate octal??? radix = 8; parseValue = value.substring(1); } else { radix = 10; parseValue = value; } //System.err.println("parsing " + value + " as long w/ radix " + radix); long longVal = Long.parseLong(parseValue, radix); type = "long"; // if constant is small enough, store it as an int instead of a long if (longVal > Integer.MIN_VALUE && longVal < Integer.MAX_VALUE) { type = "int"; } } catch (NumberFormatException e) { try { // see if it's a double or float double dVal = Double.parseDouble(value); type = "double"; // if constant is small enough, store it as a float instead of a double if (dVal > Float.MIN_VALUE && dVal < Float.MAX_VALUE) { type = "float"; } } catch (NumberFormatException e2) { throw new RuntimeException( "Cannot emit define \""+name+"\": value \""+value+ "\" cannot be assigned to a int, long, float, or double", e2); } } if (type == null) { throw new RuntimeException( "Cannot emit define (2) \""+name+"\": value \""+value+ "\" cannot be assigned to a int, long, float, or double"); } if (optionalComment != null && optionalComment.length() != 0) { javaWriter().println(" /** " + optionalComment + " */"); } javaWriter().println(" public static final " + type + " " + name + " = " + value + ";"); } } } public void endDefines() throws Exception { } public void beginFunctions(TypeDictionary typedefDictionary, TypeDictionary structDictionary, Map canonMap) throws Exception { this.typedefDictionary = typedefDictionary; this.structDictionary = structDictionary; this.canonMap = canonMap; if (cfg.allStatic() || cfg.emitInterface()) { javaWriter().println(); } } public Iterator emitFunctions(List/**/ originalCFunctions) throws Exception { // Sometimes headers will have the same function prototype twice, once // with the argument names and once without. We'll remember the signatures // we've already processed we don't generate duplicate bindings. // // Note: this code assumes that on the equals() method in FunctionSymbol // only considers function name and argument types (i.e., it does not // consider argument *names*) when comparing FunctionSymbols for equality Set funcsToBindSet = new HashSet(100); for (Iterator cIter = originalCFunctions.iterator(); cIter.hasNext(); ) { FunctionSymbol cFunc = (FunctionSymbol) cIter.next(); if (!funcsToBindSet.contains(cFunc)) { funcsToBindSet.add(cFunc); } } ArrayList funcsToBind = new ArrayList(funcsToBindSet.size()); funcsToBind.addAll(funcsToBindSet); // sort functions to make them easier to find in native code Collections.sort( funcsToBind, new Comparator() { public int compare(Object o1, Object o2) { return ((FunctionSymbol)o1).getName().compareTo( ((FunctionSymbol)o2).getName()); } public boolean equals(Object obj) { return obj.getClass() == this.getClass(); } }); // Bind all the C funcs to Java methods ArrayList/**/ methodBindingEmitters = new ArrayList(2*funcsToBind.size()); for (Iterator iter = funcsToBind.iterator(); iter.hasNext(); ) { FunctionSymbol cFunc = (FunctionSymbol) iter.next(); // Check to see whether this function should be ignored if (cfg.shouldIgnore(cFunc.getName())) { continue; // don't generate bindings for this symbol } Iterator allBindings = generateMethodBindingEmitters(cFunc); while (allBindings.hasNext()) { methodBindingEmitters.add(allBindings.next()); } } // Emit all the methods for (int i = 0; i < methodBindingEmitters.size(); ++i) { FunctionEmitter emitter = (FunctionEmitter)methodBindingEmitters.get(i); try { emitter.emit(); } catch (Exception e) { throw new RuntimeException( "Error while emitting binding for \"" + emitter.getName() + "\"", e); } emitter.getDefaultOutput().println(); // put newline after method body } // Return the list of FunctionSymbols that we generated gluecode for return funcsToBind.iterator(); } /** * Create the object that will read and store configuration information for * this JavaEmitter. */ protected JavaConfiguration createConfig() { return new JavaConfiguration(); } /** * Get the configuration information for this JavaEmitter. */ protected JavaConfiguration getConfig() { return cfg; } /** * Generate all appropriate Java bindings for the specified C function * symbols. */ protected Iterator generateMethodBindingEmitters(FunctionSymbol sym) throws Exception { ArrayList/**/ allEmitters = new ArrayList(1); try { // Get Java binding for the function MethodBinding mb = bindFunction(sym, null, null); // Expand all void* arguments List bindings = expandMethodBinding(mb); boolean overloaded = (bindings.size() > 1); if (overloaded) { // resize ahead of time for speed allEmitters.ensureCapacity(bindings.size()); } // List of the indices of the arguments in this function that should be // expanded to the same type when binding functions with multiple void* // arguments List mirrorIdxs = cfg.mirroredArgs(sym.getName()); for (Iterator iter = bindings.iterator(); iter.hasNext(); ) { MethodBinding binding = (MethodBinding) iter.next(); // Honor the MirrorExpandedBindingArgs directive in .cfg files if (mirrorIdxs != null) { assert(mirrorIdxs.size() >= 2); // sanity check. boolean typesMatch = true; int argIndex = ((Integer)mirrorIdxs.get(0)).intValue(); JavaType leftArgType = binding.getJavaArgumentType(argIndex); for (int i = 1; i < mirrorIdxs.size(); ++i) { argIndex = ((Integer)mirrorIdxs.get(i)).intValue(); JavaType rightArgType = binding.getJavaArgumentType(argIndex); if (!(leftArgType.equals(rightArgType))) { typesMatch = false; break; } leftArgType = rightArgType; } // Don't emit the binding if the specified args aren't the same type if (!typesMatch) { continue; } // skip this binding } // Try to create an NIOBuffer variant for this expanded binding. If // it's the same as the original binding, then we'll be able to emit // the binding like any normal binding because no special binding // generation (wrapper methods, etc) will be necessary. MethodBinding specialBinding = binding.createNIOBufferVariant(); if (cfg.allStatic() && binding.hasContainingType()) { // This should not currently happen since structs are emitted using a different mechanism throw new IllegalArgumentException("Cannot create binding in AllStatic mode because method has containing type: \"" + binding + "\""); } boolean isUnimplemented = cfg.isUnimplemented(binding.getName()); if (cfg.emitImpl()) { // Generate the emitter for the method which may do conversion // from type wrappers to NIO Buffers or which may call the // underlying function directly JavaMethodBindingImplEmitter entryPoint = new JavaMethodBindingImplEmitter(binding, (cfg.allStatic() ? javaWriter() : javaImplWriter()), cfg.runtimeExceptionType(), isUnimplemented); entryPoint.addModifier(JavaMethodBindingEmitter.PUBLIC); if (cfg.allStatic()) { entryPoint.addModifier(JavaMethodBindingEmitter.STATIC); } if (!isUnimplemented && !binding.needsBody()) { entryPoint.addModifier(JavaMethodBindingEmitter.NATIVE); } entryPoint.setReturnedArrayLengthExpression(cfg.returnedArrayLength(binding.getName())); allEmitters.add(entryPoint); } if (cfg.emitInterface()) { // Generate an emitter that will emit just the interface to the function JavaMethodBindingEmitter entryPointInterface = new JavaMethodBindingEmitter(binding, javaWriter(), cfg.runtimeExceptionType()); entryPointInterface.addModifier(JavaMethodBindingEmitter.PUBLIC); entryPointInterface.setReturnedArrayLengthExpression(cfg.returnedArrayLength(binding.getName())); allEmitters.add(entryPointInterface); } if (cfg.emitImpl()) { // If the user has stated that the function will be // manually implemented, then don't auto-generate a function body. if (!cfg.manuallyImplement(sym.getName()) && !isUnimplemented) { if (binding.needsBody()) { // Generate the method which calls the underlying function // after unboxing has occurred PrintWriter output = cfg.allStatic() ? javaWriter() : javaImplWriter(); JavaMethodBindingEmitter wrappedEntryPoint = new JavaMethodBindingEmitter(specialBinding, output, cfg.runtimeExceptionType(), true); wrappedEntryPoint.addModifier(JavaMethodBindingEmitter.PRIVATE); wrappedEntryPoint.addModifier(JavaMethodBindingEmitter.STATIC); // Doesn't really matter wrappedEntryPoint.addModifier(JavaMethodBindingEmitter.NATIVE); allEmitters.add(wrappedEntryPoint); } CMethodBindingEmitter cEmitter = makeCEmitter(specialBinding, overloaded, (binding != specialBinding), cfg.implPackageName(), cfg.implClassName(), cWriter()); allEmitters.add(cEmitter); } } } // end iteration over expanded bindings } catch (Exception e) { throw new RuntimeException( "Error while generating bindings for \"" + sym + "\"", e); } return allEmitters.iterator(); } public void endFunctions() throws Exception { if (cfg.allStatic() || cfg.emitInterface()) { emitCustomJavaCode(javaWriter(), cfg.className()); } if (!cfg.allStatic() && cfg.emitImpl()) { emitCustomJavaCode(javaImplWriter(), cfg.implClassName()); } } public void beginStructLayout() throws Exception {} public void layoutStruct(CompoundType t) throws Exception { getLayout().layout(t); } public void endStructLayout() throws Exception {} public void beginStructs(TypeDictionary typedefDictionary, TypeDictionary structDictionary, Map canonMap) throws Exception { this.typedefDictionary = typedefDictionary; this.structDictionary = structDictionary; this.canonMap = canonMap; } public void emitStruct(CompoundType structType, String alternateName) throws Exception { String name = structType.getName(); if (name == null && alternateName != null) { name = alternateName; } if (name == null) { System.err.println("WARNING: skipping emission of unnamed struct \"" + structType + "\""); return; } if (cfg.shouldIgnore(name)) { return; } Type containingCType = canonicalize(new PointerType(machDesc.pointerSizeInBytes(), structType, 0)); JavaType containingType = typeToJavaType(containingCType, false); if (!containingType.isCompoundTypeWrapper()) { return; } String containingTypeName = containingType.getName(); boolean needsNativeCode = false; for (int i = 0; i < structType.getNumFields(); i++) { if (structType.getField(i).getType().isFunctionPointer()) { needsNativeCode = true; break; } } String structClassPkg = cfg.packageForStruct(name); PrintWriter writer = null; PrintWriter cWriter = null; try { writer = openFile( cfg.javaOutputDir() + File.separator + CodeGenUtils.packageAsPath(structClassPkg) + File.separator + containingTypeName + ".java"); CodeGenUtils.emitAutogeneratedWarning(writer, this); if (needsNativeCode) { String nRoot = cfg.nativeOutputDir(); if (cfg.nativeOutputUsesJavaHierarchy()) { nRoot += File.separator + CodeGenUtils.packageAsPath(cfg.packageName()); } cWriter = openFile(nRoot + File.separator + containingTypeName + "_JNI.c"); CodeGenUtils.emitAutogeneratedWarning(cWriter, this); emitCHeader(cWriter, containingTypeName); } } catch(Exception e) { throw new RuntimeException( "Unable to open files for emission of struct class", e); } writer.println(); writer.println("package " + structClassPkg + ";"); writer.println(); writer.println("import java.nio.*;"); writer.println(); writer.println("import net.java.games.gluegen.runtime.*;"); writer.println(); List/**/ imports = cfg.imports(); for (Iterator iter = imports.iterator(); iter.hasNext(); ) { writer.print("import "); writer.print(iter.next()); writer.println(";"); } List/**/ javadoc = cfg.javadocForClass(containingTypeName); for (Iterator iter = javadoc.iterator(); iter.hasNext(); ) { writer.println((String) iter.next()); } writer.println(); writer.print("public class " + containingTypeName + " "); boolean firstIteration = true; List/**/ userSpecifiedInterfaces = cfg.implementedInterfaces(containingTypeName); for (Iterator iter = userSpecifiedInterfaces.iterator(); iter.hasNext(); ) { if (firstIteration) { writer.print("implements "); } firstIteration = false; writer.print(iter.next()); writer.print(" "); } writer.println("{"); writer.println(" private StructAccessor accessor;"); writer.println(); writer.println(" public static int size() {"); writer.println(" return " + structType.getSize() + ";"); writer.println(" }"); writer.println(); writer.println(" public " + containingTypeName + "() {"); writer.println(" this(BufferFactory.newDirectByteBuffer(size()));"); writer.println(" }"); writer.println(); writer.println(" public " + containingTypeName + "(ByteBuffer buf) {"); writer.println(" accessor = new StructAccessor(buf);"); writer.println(" }"); writer.println(); writer.println(" public ByteBuffer getBuffer() {"); writer.println(" return accessor.getBuffer();"); writer.println(" }"); for (int i = 0; i < structType.getNumFields(); i++) { Field field = structType.getField(i); Type fieldType = field.getType(); if (!cfg.shouldIgnore(name + " " + field.getName())) { if (fieldType.isFunctionPointer()) { try { // Emit method call and associated native code FunctionType funcType = fieldType.asPointer().getTargetType().asFunction(); FunctionSymbol funcSym = new FunctionSymbol(field.getName(), funcType); MethodBinding binding = bindFunction(funcSym, containingType, containingCType); binding.findThisPointer(); // FIXME: need to provide option to disable this on per-function basis MethodBinding specialBinding = binding.createNIOBufferVariant(); writer.println(); JavaMethodBindingEmitter entryPoint = new JavaMethodBindingImplEmitter(binding, writer, cfg.runtimeExceptionType()); entryPoint.addModifier(JavaMethodBindingEmitter.PUBLIC); if (!binding.needsBody() && !binding.hasContainingType()) { entryPoint.addModifier(JavaMethodBindingEmitter.NATIVE); } entryPoint.emit(); JavaMethodBindingEmitter wrappedEntryPoint = new JavaMethodBindingEmitter(specialBinding, writer, cfg.runtimeExceptionType(), true); wrappedEntryPoint.addModifier(JavaMethodBindingEmitter.PRIVATE); wrappedEntryPoint.addModifier(JavaMethodBindingEmitter.NATIVE); wrappedEntryPoint.emit(); CMethodBindingEmitter cEmitter = makeCEmitter(specialBinding, false, // overloaded true, // doing impl routine? structClassPkg, containingTypeName, cWriter); cEmitter.emit(); } catch (Exception e) { System.err.println("While processing field " + field + " of type " + name + ":"); throw(e); } } else if (fieldType.isCompound()) { // FIXME: will need to support this at least in order to // handle the union in jawt_Win32DrawingSurfaceInfo (fabricate // a name?) if (fieldType.getName() == null) { throw new RuntimeException("Anonymous structs as fields not supported yet (field \"" + field + "\" in type \"" + name + "\")"); } writer.println(); writer.println(" public " + fieldType.getName() + " " + field.getName() + "() {"); writer.println(" return new " + fieldType.getName() + "(accessor.slice(" + field.getOffset() + ", " + fieldType.getSize() + "));"); writer.println(" }"); // FIXME: add setter by autogenerating "copyTo" for all compound type wrappers } else if (fieldType.isArray()) { System.err.println("WARNING: Array fields (field \"" + field + "\" of type \"" + name + "\") not implemented yet"); } else { JavaType javaType = null; try { javaType = typeToJavaType(fieldType, false); } catch (Exception e) { System.err.println("Error occurred while creating accessor for field \"" + field.getName() + "\" in type \"" + name + "\""); e.printStackTrace(); throw(e); } if (javaType.isPrimitive()) { // Primitive type String externalJavaTypeName = javaType.getName(); String internalJavaTypeName = externalJavaTypeName; if (isOpaque(fieldType)) { internalJavaTypeName = compatiblePrimitiveJavaTypeName(fieldType, javaType); } String capitalized = "" + Character.toUpperCase(internalJavaTypeName.charAt(0)) + internalJavaTypeName.substring(1); int slot = slot(fieldType, (int) field.getOffset()); // Setter writer.println(); writer.println(" public " + containingTypeName + " " + field.getName() + "(" + externalJavaTypeName + " val) {"); writer.print (" accessor.set" + capitalized + "At(" + slot + ", "); if (!externalJavaTypeName.equals(internalJavaTypeName)) { writer.print("(" + internalJavaTypeName + ") "); } writer.println("val);"); writer.println(" return this;"); writer.println(" }"); // Getter writer.println(); writer.println(" public " + externalJavaTypeName + " " + field.getName() + "() {"); writer.print (" return "); if (!externalJavaTypeName.equals(internalJavaTypeName)) { writer.print("(" + externalJavaTypeName + ") "); } writer.println("accessor.get" + capitalized + "At(" + slot + ");"); writer.println(" }"); } else { // FIXME System.err.println("WARNING: Complicated fields (field \"" + field + "\" of type \"" + name + "\") not implemented yet"); // throw new RuntimeException("Complicated fields (field \"" + field + "\" of type \"" + t + // "\") not implemented yet"); } } } } emitCustomJavaCode(writer, containingTypeName); writer.println("}"); writer.flush(); writer.close(); if (needsNativeCode) { cWriter.flush(); cWriter.close(); } } public void endStructs() throws Exception {} //---------------------------------------------------------------------- // Internals only below this point // private CMethodBindingEmitter makeCEmitter(MethodBinding binding, boolean overloaded, boolean doingImplRoutine, String bindingJavaPackageName, String bindingJavaClassName, PrintWriter output) { MessageFormat returnValueCapacityFormat = null; MessageFormat returnValueLengthFormat = null; JavaType javaReturnType = binding.getJavaReturnType(); if (javaReturnType.isNIOBuffer()) { // See whether capacity has been specified String capacity = cfg.returnValueCapacity(binding.getName()); if (capacity != null) { returnValueCapacityFormat = new MessageFormat(capacity); } } else if (javaReturnType.isArray()) { // See whether length has been specified String len = cfg.returnValueLength(binding.getName()); if (len != null) { returnValueLengthFormat = new MessageFormat(len); } } CMethodBindingEmitter cEmitter; if (doingImplRoutine) { cEmitter = new CMethodBindingImplEmitter(binding, overloaded, bindingJavaPackageName, bindingJavaClassName, cfg.allStatic(), output); } else { cEmitter = new CMethodBindingEmitter(binding, overloaded, bindingJavaPackageName, bindingJavaClassName, cfg.allStatic(), output); } if (returnValueCapacityFormat != null) { cEmitter.setReturnValueCapacityExpression(returnValueCapacityFormat); } if (returnValueLengthFormat != null) { cEmitter.setReturnValueLengthExpression(returnValueLengthFormat); } cEmitter.setTemporaryCVariableDeclarations(cfg.temporaryCVariableDeclarations(binding.getName())); cEmitter.setTemporaryCVariableAssignments(cfg.temporaryCVariableAssignments(binding.getName())); return cEmitter; } private JavaType typeToJavaType(Type cType, boolean outgoingArgument) { // Recognize JNIEnv* case up front PointerType opt = cType.asPointer(); if ((opt != null) && (opt.getTargetType().getName() != null) && (opt.getTargetType().getName().equals("JNIEnv"))) { return JavaType.createForJNIEnv(); } // Opaque specifications override automatic conversions TypeInfo info = cfg.typeInfo(cType, typedefDictionary); if (info != null) { return info.javaType(); } Type t = cType; if (t.isInt() || t.isEnum()) { switch (t.getSize()) { case 1: return javaType(Byte.TYPE); case 2: return javaType(Short.TYPE); case 4: return javaType(Integer.TYPE); case 8: return javaType(Long.TYPE); default: throw new RuntimeException("Unknown integer type of size " + t.getSize() + " and name " + t.getName()); } } else if (t.isFloat()) { return javaType(Float.TYPE); } else if (t.isDouble()) { return javaType(Double.TYPE); } else if (t.isVoid()) { return javaType(Void.TYPE); } else { if (t.pointerDepth() > 0 || t.arrayDimension() > 0) { Type targetType; // target type if (t.isPointer()) { // t is *, we need to get targetType = t.asPointer().getTargetType(); } else { // t is [], we need to get targetType = t.asArray().getElementType(); } // Handle Types of form pointer-to-type or array-of-type, like // char* or int[]; these are expanded out into Java primitive // arrays, NIO buffers, or both in expandMethodBinding if (t.pointerDepth() == 1 || t.arrayDimension() == 1) { if (targetType.isVoid()) { return JavaType.createForVoidPointer(); } else if (targetType.isInt()) { switch (targetType.getSize()) { case 1: return JavaType.createForCCharPointer(); case 2: return JavaType.createForCShortPointer(); case 4: return JavaType.createForCInt32Pointer(); case 8: return JavaType.createForCInt64Pointer(); default: throw new RuntimeException("Unknown integer array type of size " + t.getSize() + " and name " + t.getName()); } } else if (targetType.isFloat()) { return JavaType.createForCFloatPointer(); } else if (targetType.isDouble()) { return JavaType.createForCDoublePointer(); } else if (targetType.isCompound()) { if (t.isArray()) { throw new RuntimeException("Arrays of compound types not handled yet"); } // Special cases for known JNI types (in particular for converting jawt.h) if (t.getName() != null && t.getName().equals("jobject")) { return javaType(java.lang.Object.class); } String name = targetType.getName(); if (name == null) { // Try containing pointer type for any typedefs name = t.getName(); if (name == null) { throw new RuntimeException("Couldn't find a proper type name for pointer type " + t); } } return JavaType.createForCStruct(cfg.renameJavaType(name)); } else { throw new RuntimeException("Don't know how to convert pointer/array type \"" + t + "\""); } } // Handle Types of form pointer-to-pointer-to-type or // array-of-arrays-of-type, like char** or int[][] else if (t.pointerDepth() == 2 || t.arrayDimension() == 2) { // Get the target type of the target type (targetType was computer earlier // as to be a pointer to the target type, so now we need to get its // target type) Type bottomType; if (targetType.isPointer()) { // t is**, targetType is *, we need to get bottomType = targetType.asPointer().getTargetType(); } else { // t is[][], targetType is [], we need to get bottomType = targetType.asArray().getElementType(); } if (bottomType.isPrimitive()) { if (bottomType.isInt()) { switch (bottomType.getSize()) { case 1: return javaType(ArrayTypes.byteBufferArrayClass); case 2: return javaType(ArrayTypes.shortBufferArrayClass); case 4: return javaType(ArrayTypes.intBufferArrayClass); case 8: return javaType(ArrayTypes.longBufferArrayClass); default: throw new RuntimeException("Unknown two-dimensional integer array type of element size " + bottomType.getSize() + " and name " + bottomType.getName()); } } else if (bottomType.isFloat()) { return javaType(ArrayTypes.floatBufferArrayClass); } else if (bottomType.isDouble()) { return javaType(ArrayTypes.doubleBufferArrayClass); } else { throw new RuntimeException("Unexpected primitive type " + bottomType.getName() + " in two-dimensional array"); } } else if (bottomType.isVoid()) { return javaType(ArrayTypes.bufferArrayClass); } else if (targetType.isPointer() && (targetType.pointerDepth() == 1) && targetType.asPointer().getTargetType().isCompound()) { // Array of pointers; convert as array of StructAccessors return JavaType.createForCArray(targetType); } else { throw new RuntimeException( "Could not convert C type \"" + t + "\" " + "to appropriate Java type; need to add more support for " + "depth=2 pointer/array types [debug info: targetType=\"" + targetType + "\"]"); } } else { // can't handle this type of pointer/array argument throw new RuntimeException( "Could not convert C pointer/array \"" + t + "\" to " + "appropriate Java type; types with pointer/array depth " + "greater than 2 are not yet supported [debug info: " + "pointerDepth=" + t.pointerDepth() + " arrayDimension=" + t.arrayDimension() + " targetType=\"" + targetType + "\"]"); } } else { throw new RuntimeException( "Could not convert C type \"" + t + "\" (class " + t.getClass().getName() + ") to appropriate Java type"); } } } private static boolean isIntegerType(Class c) { return ((c == Byte.TYPE) || (c == Short.TYPE) || (c == Character.TYPE) || (c == Integer.TYPE) || (c == Long.TYPE)); } private int slot(Type t, int byteOffset) { if (t.isInt()) { switch (t.getSize()) { case 1: case 2: case 4: case 8: return byteOffset / t.getSize(); default: throw new RuntimeException("Illegal type"); } } else if (t.isFloat()) { return byteOffset / 4; } else if (t.isDouble()) { return byteOffset / 8; } else if (t.isPointer()) { return byteOffset / machDesc.pointerSizeInBytes(); } else { throw new RuntimeException("Illegal type " + t); } } private StructLayout getLayout() { if (layout == null) { layout = StructLayout.createForCurrentPlatform(); } return layout; } protected PrintWriter openFile(String filename) throws IOException { //System.out.println("Trying to open: " + filename); File file = new File(filename); String parentDir = file.getParent(); if (parentDir != null) { File pDirFile = new File(parentDir); pDirFile.mkdirs(); } return new PrintWriter(new BufferedWriter(new FileWriter(file))); } private boolean isOpaque(Type type) { return (cfg.typeInfo(type, typedefDictionary) != null); } private String compatiblePrimitiveJavaTypeName(Type fieldType, JavaType javaType) { Class c = javaType.getJavaClass(); if (!isIntegerType(c)) { // FIXME throw new RuntimeException("Can't yet handle opaque definitions of structs' fields to non-integer types (byte, short, int, long, etc.)"); } switch (fieldType.getSize()) { case 1: return "byte"; case 2: return "short"; case 4: return "int"; case 8: return "long"; default: throw new RuntimeException("Can't handle opaque definitions if the starting type isn't compatible with integral types"); } } private void openWriters() throws IOException { String jRoot = cfg.javaOutputDir() + File.separator + CodeGenUtils.packageAsPath(cfg.packageName()); String jImplRoot = null; if (!cfg.allStatic()) { jImplRoot = cfg.javaOutputDir() + File.separator + CodeGenUtils.packageAsPath(cfg.implPackageName()); } String nRoot = cfg.nativeOutputDir(); if (cfg.nativeOutputUsesJavaHierarchy()) { nRoot += File.separator + CodeGenUtils.packageAsPath(cfg.packageName()); } if (cfg.allStatic() || cfg.emitInterface()) { javaWriter = openFile(jRoot + File.separator + cfg.className() + ".java"); } if (!cfg.allStatic() && cfg.emitImpl()) { javaImplWriter = openFile(jImplRoot + File.separator + cfg.implClassName() + ".java"); } if (cfg.emitImpl()) { cWriter = openFile(nRoot + File.separator + cfg.implClassName() + "_JNI.c"); } if (javaWriter != null) { CodeGenUtils.emitAutogeneratedWarning(javaWriter, this); } if (javaImplWriter != null) { CodeGenUtils.emitAutogeneratedWarning(javaImplWriter, this); } if (cWriter != null) { CodeGenUtils.emitAutogeneratedWarning(cWriter, this); } } protected PrintWriter javaWriter() { if (!cfg.allStatic() && !cfg.emitInterface()) { throw new InternalError("Should not call this"); } return javaWriter; } protected PrintWriter javaImplWriter() { if (cfg.allStatic() || !cfg.emitImpl()) { throw new InternalError("Should not call this"); } return javaImplWriter; } protected PrintWriter cWriter() { if (!cfg.emitImpl()) { throw new InternalError("Should not call this"); } return cWriter; } private void closeWriter(PrintWriter writer) throws IOException { writer.flush(); writer.close(); } private void closeWriters() throws IOException { if (javaWriter != null) { closeWriter(javaWriter); } if (javaImplWriter != null) { closeWriter(javaImplWriter); } if (cWriter != null) { closeWriter(cWriter); } javaWriter = null; javaImplWriter = null; cWriter = null; } /** * Returns the value that was specified by the configuration directive * "JavaOutputDir", or the default if none was specified. */ protected String getJavaOutputDir() { return cfg.javaOutputDir(); } /** * Returns the value that was specified by the configuration directive * "Package", or the default if none was specified. */ protected String getJavaPackageName() { return cfg.packageName(); } /** * Returns the value that was specified by the configuration directive * "ImplPackage", or the default if none was specified. */ protected String getImplPackageName() { return cfg.implPackageName(); } /** * Emit all the strings specified in the "CustomJavaCode" parameters of * the configuration file. */ protected void emitCustomJavaCode(PrintWriter writer, String className) throws Exception { List code = cfg.customJavaCodeForClass(className); if (code.size() == 0) return; writer.println(); writer.println(" // --- Begin CustomJavaCode .cfg declarations"); for (Iterator iter = code.iterator(); iter.hasNext(); ) { writer.println((String) iter.next()); } writer.println(" // ---- End CustomJavaCode .cfg declarations"); } /** * Write out any header information for the output files (class declaration * and opening brace, import statements, etc). */ protected void emitAllFileHeaders() throws IOException { try { if (cfg.allStatic() || cfg.emitInterface()) { String[] interfaces; List userSpecifiedInterfaces = null; if (cfg.emitInterface()) { userSpecifiedInterfaces = cfg.extendedInterfaces(cfg.className()); } else { userSpecifiedInterfaces = cfg.implementedInterfaces(cfg.className()); } interfaces = new String[userSpecifiedInterfaces.size()]; userSpecifiedInterfaces.toArray(interfaces); final List/**/ intfDocs = cfg.javadocForClass(cfg.className()); CodeGenUtils.EmissionCallback docEmitter = new CodeGenUtils.EmissionCallback() { public void emit(PrintWriter w) { for (Iterator iter = intfDocs.iterator(); iter.hasNext(); ) { w.println((String) iter.next()); } } }; CodeGenUtils.emitJavaHeaders( javaWriter, cfg.packageName(), cfg.className(), cfg.allStatic() ? true : false, (String[]) cfg.imports().toArray(new String[] {}), new String[] { "public" }, interfaces, null, docEmitter); } if (!cfg.allStatic() && cfg.emitImpl()) { final List/**/ implDocs = cfg.javadocForClass(cfg.className()); CodeGenUtils.EmissionCallback docEmitter = new CodeGenUtils.EmissionCallback() { public void emit(PrintWriter w) { for (Iterator iter = implDocs.iterator(); iter.hasNext(); ) { w.println((String) iter.next()); } } }; String[] interfaces; List userSpecifiedInterfaces = null; userSpecifiedInterfaces = cfg.implementedInterfaces(cfg.implClassName()); interfaces = new String[1 + userSpecifiedInterfaces.size()]; userSpecifiedInterfaces.toArray(interfaces); interfaces[userSpecifiedInterfaces.size()] = cfg.className(); CodeGenUtils.emitJavaHeaders( javaImplWriter, cfg.implPackageName(), cfg.implClassName(), true, (String[]) cfg.imports().toArray(new String[] {}), new String[] { "public" }, interfaces, null, docEmitter); } if (cfg.emitImpl()) { PrintWriter cWriter = cWriter(); emitCHeader(cWriter, cfg.implClassName()); } } catch (Exception e) { throw new RuntimeException( "Error emitting all file headers: cfg.allStatic()=" + cfg.allStatic() + " cfg.emitImpl()=" + cfg.emitImpl() + " cfg.emitInterface()=" + cfg.emitInterface(), e); } } protected void emitCHeader(PrintWriter cWriter, String className) { cWriter.println("#include "); cWriter.println(); if (getConfig().emitImpl()) { cWriter.println("#include "); cWriter.println(); } for (Iterator iter = cfg.customCCode().iterator(); iter.hasNext(); ) { cWriter.println((String) iter.next()); } cWriter.println(); } /** * Write out any footer information for the output files (closing brace of * class definition, etc). */ protected void emitAllFileFooters(){ if (cfg.allStatic() || cfg.emitInterface()) { javaWriter().println(); javaWriter().println("} // end of class " + cfg.className()); } if (!cfg.allStatic() && cfg.emitImpl()) { javaImplWriter().println(); javaImplWriter().println("} // end of class " + cfg.implClassName()); } } private JavaType javaType(Class c) { return JavaType.createForClass(c); } private MethodBinding bindFunction(FunctionSymbol sym, JavaType containingType, Type containingCType) { MethodBinding binding = new MethodBinding(sym, containingType, containingCType); if (cfg.returnsString(binding.getName())) { PointerType prt = sym.getReturnType().asPointer(); if (prt == null || prt.getTargetType().asInt() == null || prt.getTargetType().getSize() != 1) { throw new RuntimeException( "Cannot apply ReturnsString configuration directive to \"" + sym + "\". ReturnsString requires native method to have return type \"char *\""); } binding.setJavaReturnType(javaType(java.lang.String.class)); } else { binding.setJavaReturnType(typeToJavaType(sym.getReturnType(), false)); } // List of the indices of the arguments in this function that should be // converted from byte[] to String List stringArgIndices = cfg.stringArguments(binding.getName()); for (int i = 0; i < sym.getNumArguments(); i++) { Type cArgType = sym.getArgumentType(i); JavaType mappedType = typeToJavaType(cArgType, true); //System.out.println("C arg type -> \"" + cArgType + "\"" ); //System.out.println(" Java -> \"" + mappedType + "\"" ); // Take into account any ArgumentIsString configuration directives that apply if (stringArgIndices != null && stringArgIndices.contains(new Integer(i))) { //System.out.println("Forcing conversion of " + binding.getName() + " arg #" + i + " from byte[] to String "); if (mappedType.isCVoidPointerType() || mappedType.isCCharPointerType() || (mappedType.isArray() && mappedType.getJavaClass() == ArrayTypes.byteBufferArrayClass)) { // convert mapped type from void* and byte[] to String, or ByteBuffer[] to String[] if (mappedType.getJavaClass() == ArrayTypes.byteBufferArrayClass) { mappedType = javaType(ArrayTypes.stringArrayClass); } else { mappedType = javaType(String.class); } } else { throw new RuntimeException( "Cannot apply ArgumentIsString configuration directive to " + "argument " + i + " of \"" + sym + "\": argument type is not " + "a \"void*\", \"char *\", or \"char**\" equivalent"); } } binding.addJavaArgumentType(mappedType); //System.out.println("During binding of [" + sym + "], added mapping from C type: " + cArgType + " to Java type: " + mappedType); } //System.err.println("---> " + binding); //System.err.println(" ---> " + binding.getCSymbol()); return binding; } // Expands a MethodBinding containing C primitive pointer types into // multiple variants taking Java primitive arrays and NIO buffers, subject // to the per-function "NIO only" rule in the configuration file private List/**/ expandMethodBinding(MethodBinding binding) { List result = new ArrayList(); result.add(binding); int i = 0; while (i < result.size()) { MethodBinding mb = (MethodBinding) result.get(i); boolean shouldRemoveCurrent = false; for (int j = 0; j < mb.getNumArguments(); j++) { JavaType t = mb.getJavaArgumentType(j); if (t.isCPrimitivePointerType()) { // Remove original from list shouldRemoveCurrent = true; MethodBinding variant = null; // Non-NIO variants for void* and other C primitive pointer types if (!cfg.nioOnly(mb.getCSymbol().getName())) { if (t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.booleanArrayClass)); if (! result.contains(variant)) result.add(variant); variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.charArrayClass)); if (! result.contains(variant)) result.add(variant); } if (t.isCCharPointerType() || t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.byteArrayClass)); if (! result.contains(variant)) result.add(variant); } if (t.isCShortPointerType() || t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.shortArrayClass)); if (! result.contains(variant)) result.add(variant); } if (t.isCInt32PointerType() || t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.intArrayClass)); if (! result.contains(variant)) result.add(variant); } if (t.isCInt64PointerType() || t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.longArrayClass)); if (! result.contains(variant)) result.add(variant); } if (t.isCFloatPointerType() || t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.floatArrayClass)); if (! result.contains(variant)) result.add(variant); } if (t.isCDoublePointerType() || t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, javaType(ArrayTypes.doubleArrayClass)); if (! result.contains(variant)) result.add(variant); } } // NIO variants for void* and other C primitive pointer types if (!cfg.noNio(mb.getCSymbol().getName())) { if (t.isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(j, JavaType.forNIOBufferClass()); if (! result.contains(variant)) result.add(variant); } } if ((cfg.nioMode() == JavaConfiguration.NIO_MODE_ALL_POINTERS && !cfg.noNio(mb.getCSymbol().getName())) || (cfg.nioMode() == JavaConfiguration.NIO_MODE_VOID_ONLY && cfg.forcedNio(mb.getCSymbol().getName()))) { if (t.isCCharPointerType()) { variant = mb.createCPrimitivePointerVariant(j, JavaType.forNIOByteBufferClass()); if (! result.contains(variant)) result.add(variant); } if (t.isCShortPointerType()) { variant = mb.createCPrimitivePointerVariant(j, JavaType.forNIOShortBufferClass()); if (! result.contains(variant)) result.add(variant); } if (t.isCInt32PointerType()) { variant = mb.createCPrimitivePointerVariant(j, JavaType.forNIOIntBufferClass()); if (! result.contains(variant)) result.add(variant); } if (t.isCInt64PointerType()) { variant = mb.createCPrimitivePointerVariant(j, JavaType.forNIOLongBufferClass()); if (! result.contains(variant)) result.add(variant); } if (t.isCFloatPointerType()) { variant = mb.createCPrimitivePointerVariant(j, JavaType.forNIOFloatBufferClass()); if (! result.contains(variant)) result.add(variant); } if (t.isCDoublePointerType()) { variant = mb.createCPrimitivePointerVariant(j, JavaType.forNIODoubleBufferClass()); if (! result.contains(variant)) result.add(variant); } } } } if (mb.getJavaReturnType().isCPrimitivePointerType()) { MethodBinding variant = null; if (mb.getJavaReturnType().isCVoidPointerType()) { variant = mb.createCPrimitivePointerVariant(-1, JavaType.forNIOByteBufferClass()); if (! result.contains(variant)) result.add(variant); } else if (mb.getJavaReturnType().isCCharPointerType()) { variant = mb.createCPrimitivePointerVariant(-1, javaType(ArrayTypes.byteArrayClass)); if (! result.contains(variant)) result.add(variant); } else if (mb.getJavaReturnType().isCShortPointerType()) { variant = mb.createCPrimitivePointerVariant(-1, javaType(ArrayTypes.shortArrayClass)); if (! result.contains(variant)) result.add(variant); } else if (mb.getJavaReturnType().isCInt32PointerType()) { variant = mb.createCPrimitivePointerVariant(-1, javaType(ArrayTypes.intArrayClass)); if (! result.contains(variant)) result.add(variant); } else if (mb.getJavaReturnType().isCInt64PointerType()) { variant = mb.createCPrimitivePointerVariant(-1, javaType(ArrayTypes.longArrayClass)); if (! result.contains(variant)) result.add(variant); } else if (mb.getJavaReturnType().isCFloatPointerType()) { variant = mb.createCPrimitivePointerVariant(-1, javaType(ArrayTypes.floatArrayClass)); if (! result.contains(variant)) result.add(variant); } else if (mb.getJavaReturnType().isCDoublePointerType()) { variant = mb.createCPrimitivePointerVariant(-1, javaType(ArrayTypes.doubleArrayClass)); if (! result.contains(variant)) result.add(variant); } shouldRemoveCurrent = true; } if (shouldRemoveCurrent) { result.remove(i); --i; } ++i; } // Honor the flattenNIOVariants directive in the configuration file if (cfg.flattenNIOVariants()) { i = 0; while (i < result.size()) { boolean shouldRemoveCurrent = false; MethodBinding mb = (MethodBinding) result.get(i); for (int j = 0; j < binding.getNumArguments() && !shouldRemoveCurrent; j++) { JavaType t1 = binding.getJavaArgumentType(j); if (t1.isCPrimitivePointerType() && !t1.isCVoidPointerType()) { for (int k = j + 1; k < binding.getNumArguments() && !shouldRemoveCurrent; k++) { JavaType t2 = binding.getJavaArgumentType(k); if (t2.isCPrimitivePointerType() && !t2.isCVoidPointerType()) { // The "NIO-ness" of the converted arguments in the // new binding must match JavaType nt1 = mb.getJavaArgumentType(j); JavaType nt2 = mb.getJavaArgumentType(k); if (nt1.isNIOBuffer() != nt2.isNIOBuffer()) { shouldRemoveCurrent = true; } } } } } if (shouldRemoveCurrent) { result.remove(i); --i; } ++i; } } return result; } private String resultName() { return "_res"; } private Type canonicalize(Type t) { Type res = (Type) canonMap.get(t); if (res != null) { return res; } canonMap.put(t, t); return t; } }