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/*
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF licenses this file
 * to you under the Apache License, Version 2.0 (the
 * "License"); you may not use this file except in compliance
 * with the License.  You may obtain a copy of the License at
 *
 *   http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing,
 * software distributed under the License is distributed on an
 * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
 * KIND, either express or implied.  See the License for the
 * specific language governing permissions and limitations
 * under the License.
 */
package freemarker.ext.beans;

import java.io.Serializable;
import java.util.ArrayList;
import java.util.Iterator;
import java.util.LinkedList;
import java.util.List;
import java.util.Map;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;

import edu.umd.cs.findbugs.annotations.SuppressFBWarnings;
import freemarker.template.TemplateModelException;
import freemarker.template.utility.ClassUtil;
import freemarker.template.utility.NullArgumentException;

/**
 * Encapsulates the rules and data structures (including cache) for choosing of the best matching callable member for
 * a parameter list, from a given set of callable members. There are two subclasses of this, one for non-varags methods,
 * and one for varargs methods.
 */
abstract class OverloadedMethodsSubset {
    
    /** 
     * Used for an optimization trick to substitute an array of whatever size that contains only 0-s. Since this array
     * is 0 long, this means that the code that reads the int[] always have to check if the int[] has this value, and
     * then it has to act like if was all 0-s.  
     */
    static final int[] ALL_ZEROS_ARRAY = new int[0];

    private static final int[][] ZERO_PARAM_COUNT_TYPE_FLAGS_ARRAY = new int[1][];
    static {
        ZERO_PARAM_COUNT_TYPE_FLAGS_ARRAY[0] = ALL_ZEROS_ARRAY;
    }

    private Class[/*number of args*/][/*arg index*/] unwrappingHintsByParamCount;
    
    /**
     * Tells what types occur at a given parameter position with a bit field. See {@link TypeFlags}.
     */
    private int[/*number of args*/][/*arg index*/] typeFlagsByParamCount;
    
    // TODO: This can cause memory-leak when classes are re-loaded. However, first the genericClassIntrospectionCache
    // and such need to be fixed in this regard. 
    private final Map/**/ argTypesToMemberDescCache
            = new ConcurrentHashMap(6, 0.75f, 1);
    
    private final List/**/ memberDescs = new LinkedList();
    
    /** Enables 2.3.21 {@link BeansWrapper} incompatibleImprovements */
    protected final boolean bugfixed;
    
    OverloadedMethodsSubset(boolean bugfixed) {
        this.bugfixed = bugfixed;
    }
    
    void addCallableMemberDescriptor(ReflectionCallableMemberDescriptor memberDesc) {
        memberDescs.add(memberDesc);
        
        // Warning: Do not modify this array, or put it into unwrappingHintsByParamCount by reference, as the arrays
        // inside that are modified!
        final Class[] prepedParamTypes = preprocessParameterTypes(memberDesc);
        final int paramCount = prepedParamTypes.length;  // Must be the same as the length of the original param list
        
        // Merge these unwrapping hints with the existing table of hints:
        if (unwrappingHintsByParamCount == null) {
            unwrappingHintsByParamCount = new Class[paramCount + 1][];
            unwrappingHintsByParamCount[paramCount] = prepedParamTypes.clone();
        } else if (unwrappingHintsByParamCount.length <= paramCount) {
            Class[][] newUnwrappingHintsByParamCount = new Class[paramCount + 1][];
            System.arraycopy(unwrappingHintsByParamCount, 0, newUnwrappingHintsByParamCount, 0,
                    unwrappingHintsByParamCount.length);
            unwrappingHintsByParamCount = newUnwrappingHintsByParamCount;
            unwrappingHintsByParamCount[paramCount] = prepedParamTypes.clone();
        } else {
            Class[] unwrappingHints = unwrappingHintsByParamCount[paramCount]; 
            if (unwrappingHints == null) {
                unwrappingHintsByParamCount[paramCount] = prepedParamTypes.clone();
            } else {
                for (int paramIdx = 0; paramIdx < prepedParamTypes.length; paramIdx++) {
                    // For each parameter list length, we merge the argument type arrays into a single Class[] that
                    // stores the most specific common types for each position. Hence we will possibly use a too generic
                    // hint for the unwrapping. For correct behavior, for each overloaded methods its own parameter
                    // types should be used as a hint. But without unwrapping the arguments, we couldn't select the
                    // overloaded method. So we had to unwrap with all possible target types of each parameter position,
                    // which would be slow and its result would be uncacheable (as we don't have anything usable as
                    // a lookup key). So we just use this compromise.
                    unwrappingHints[paramIdx] = getCommonSupertypeForUnwrappingHint(
                            unwrappingHints[paramIdx], prepedParamTypes[paramIdx]);
                }
            }
        }

        int[] typeFlagsByParamIdx = ALL_ZEROS_ARRAY;
        if (bugfixed) {
            // Fill typeFlagsByParamCount (if necessary)
            for (int paramIdx = 0; paramIdx < paramCount; paramIdx++) {
                final int typeFlags = TypeFlags.classToTypeFlags(prepedParamTypes[paramIdx]);
                if (typeFlags != 0) {
                    if (typeFlagsByParamIdx == ALL_ZEROS_ARRAY) {
                        typeFlagsByParamIdx = new int[paramCount];
                    }
                    typeFlagsByParamIdx[paramIdx] = typeFlags;
                }
            }
            mergeInTypesFlags(paramCount, typeFlagsByParamIdx);
        }
        
        afterWideningUnwrappingHints(
                bugfixed ? prepedParamTypes : unwrappingHintsByParamCount[paramCount],
                typeFlagsByParamIdx);
    }
    
    Class[][] getUnwrappingHintsByParamCount() {
        return unwrappingHintsByParamCount;
    }
    
    @SuppressFBWarnings(value="JLM_JSR166_UTILCONCURRENT_MONITORENTER",
            justification="Locks for member descriptor creation only")
    final MaybeEmptyCallableMemberDescriptor getMemberDescriptorForArgs(Object[] args, boolean varArg) {
        ArgumentTypes argTypes = new ArgumentTypes(args, bugfixed);
        MaybeEmptyCallableMemberDescriptor memberDesc
                = (MaybeEmptyCallableMemberDescriptor) argTypesToMemberDescCache.get(argTypes);
        if (memberDesc == null) {
            // Synchronized so that we won't unnecessarily create the same member desc. for multiple times in parallel.
            synchronized (argTypesToMemberDescCache) {
                memberDesc = (MaybeEmptyCallableMemberDescriptor) argTypesToMemberDescCache.get(argTypes);
                if (memberDesc == null) {
                    memberDesc = argTypes.getMostSpecific(memberDescs, varArg);
                    argTypesToMemberDescCache.put(argTypes, memberDesc);
                }
            }
        }
        return memberDesc;
    }
    
    Iterator/**/ getMemberDescriptors() {
        return memberDescs.iterator();
    }
    
    abstract Class[] preprocessParameterTypes(CallableMemberDescriptor memberDesc);
    abstract void afterWideningUnwrappingHints(Class[] paramTypes, int[] paramNumericalTypes);
    
    abstract MaybeEmptyMemberAndArguments getMemberAndArguments(List/**/ tmArgs, 
            BeansWrapper unwrapper) throws TemplateModelException;

    /**
     * Returns the most specific common class (or interface) of two parameter types for the purpose of unwrapping.
     * This is trickier than finding the most specific overlapping superclass of two classes, because:
     * 
    *
  • It considers primitive classes as the subclasses of the boxing classes.
  • *
  • If the only common class is {@link Object}, it will try to find a common interface. If there are more * of them, it will start removing those that are known to be uninteresting as unwrapping hints.
  • *
* * @param c1 Parameter type 1 * @param c2 Parameter type 2 */ protected Class getCommonSupertypeForUnwrappingHint(Class c1, Class c2) { if (c1 == c2) return c1; // This also means that the hint for (Integer, Integer) will be Integer, not just Number. This is consistent // with how non-overloaded method hints work. if (bugfixed) { // c1 primitive class to boxing class: final boolean c1WasPrim; if (c1.isPrimitive()) { c1 = ClassUtil.primitiveClassToBoxingClass(c1); c1WasPrim = true; } else { c1WasPrim = false; } // c2 primitive class to boxing class: final boolean c2WasPrim; if (c2.isPrimitive()) { c2 = ClassUtil.primitiveClassToBoxingClass(c2); c2WasPrim = true; } else { c2WasPrim = false; } if (c1 == c2) { // If it was like int and Integer, boolean and Boolean, etc., we return the boxing type (as that's the // less specific, because it allows null.) // (If it was two equivalent primitives, we don't get here, because of the 1st line of the method.) return c1; } else if (Number.class.isAssignableFrom(c1) && Number.class.isAssignableFrom(c2)) { // We don't want the unwrapper to convert to a numerical super-type [*] as it's not yet known what the // actual number type of the chosen method will be. We will postpone the actual numerical conversion // until that, especially as some conversions (like fixed point to floating point) can be lossy. // * Numerical super-type: Like long > int > short > byte. return Number.class; } else if (c1WasPrim || c2WasPrim) { // At this point these all stand: // - At least one of them was primitive // - No more than one of them was numerical // - They don't have the same wrapper (boxing) class return Object.class; } // Falls through } else { // old buggy behavior if (c2.isPrimitive()) { if (c2 == Byte.TYPE) c2 = Byte.class; else if (c2 == Short.TYPE) c2 = Short.class; else if (c2 == Character.TYPE) c2 = Character.class; else if (c2 == Integer.TYPE) c2 = Integer.class; else if (c2 == Float.TYPE) c2 = Float.class; else if (c2 == Long.TYPE) c2 = Long.class; else if (c2 == Double.TYPE) c2 = Double.class; } } // We never get to this point if buxfixed is true and any of these stands: // - One of classes was a primitive type // - One of classes was a numerical type (either boxing type or primitive) Set commonTypes = _MethodUtil.getAssignables(c1, c2); commonTypes.retainAll(_MethodUtil.getAssignables(c2, c1)); if (commonTypes.isEmpty()) { // Can happen when at least one of the arguments is an interface, as // they don't have Object at the root of their hierarchy return Object.class; } // Gather maximally specific elements. Yes, there can be more than one // thank to interfaces. I.e., if you call this method for String.class // and Number.class, you'll have Comparable, Serializable, and Object as // maximal elements. List max = new ArrayList(); listCommonTypes: for (Iterator commonTypesIter = commonTypes.iterator(); commonTypesIter.hasNext(); ) { Class clazz = (Class) commonTypesIter.next(); for (Iterator maxIter = max.iterator(); maxIter.hasNext(); ) { Class maxClazz = (Class) maxIter.next(); if (_MethodUtil.isMoreOrSameSpecificParameterType(maxClazz, clazz, false /*bugfixed [1]*/, 0) != 0) { // clazz can't be maximal, if there's already a more specific or equal maximal than it. continue listCommonTypes; } if (_MethodUtil.isMoreOrSameSpecificParameterType(clazz, maxClazz, false /*bugfixed [1]*/, 0) != 0) { // If it's more specific than a currently maximal element, // that currently maximal is no longer a maximal. maxIter.remove(); } // 1: We don't use bugfixed at the "[1]"-marked points because it's slower and doesn't make any // difference here as it's ensured that nor c1 nor c2 is primitive or numerical. The bugfix has only // affected the treatment of primitives and numerical types. } // If we get here, no current maximal is more specific than the // current class, so clazz is a new maximal so far. max.add(clazz); } if (max.size() > 1) { // we have an ambiguity if (bugfixed) { // Find the non-interface class for (Iterator it = max.iterator(); it.hasNext(); ) { Class maxCl = (Class) it.next(); if (!maxCl.isInterface()) { if (maxCl != Object.class) { // This actually shouldn't ever happen, but to be sure... // If it's not Object, we use it as the most specific return maxCl; } else { // Otherwise remove Object, and we will try with the interfaces it.remove(); } } } // At this point we only have interfaces left. // Try removing interfaces about which we know that they are useless as unwrapping hints: max.remove(Cloneable.class); if (max.size() > 1) { // Still have an ambiguity... max.remove(Serializable.class); if (max.size() > 1) { // Still had an ambiguity... max.remove(Comparable.class); if (max.size() > 1) { return Object.class; // Still had an ambiguity... no luck. } } } } else { return Object.class; } } return (Class) max.get(0); } /** * Gets the "type flags" of each parameter positions, or {@code null} if there's no method with this parameter * count or if we are in pre-2.3.21 mode, or {@link #ALL_ZEROS_ARRAY} if there were no parameters that turned * on a flag. The returned {@code int}-s are one or more {@link TypeFlags} constants binary "or"-ed together. */ final protected int[] getTypeFlags(int paramCount) { return typeFlagsByParamCount != null && typeFlagsByParamCount.length > paramCount ? typeFlagsByParamCount[paramCount] : null; } /** * Updates the content of the {@link #typeFlagsByParamCount} field with the parameter type flags of a method. * Don't call this when {@link #bugfixed} is {@code false}! * * @param dstParamCount The parameter count for which we want to merge in the type flags * @param srcTypeFlagsByParamIdx If shorter than {@code dstParamCount}, its last item will be repeated until * dstParamCount length is reached. If longer, the excessive items will be ignored. * Maybe {@link #ALL_ZEROS_ARRAY}. Maybe a 0-length array. Can't be {@code null}. */ final protected void mergeInTypesFlags(int dstParamCount, int[] srcTypeFlagsByParamIdx) { NullArgumentException.check("srcTypesFlagsByParamIdx", srcTypeFlagsByParamIdx); // Special case of 0 param count: if (dstParamCount == 0) { if (typeFlagsByParamCount == null) { typeFlagsByParamCount = ZERO_PARAM_COUNT_TYPE_FLAGS_ARRAY; } else if (typeFlagsByParamCount != ZERO_PARAM_COUNT_TYPE_FLAGS_ARRAY) { typeFlagsByParamCount[0] = ALL_ZEROS_ARRAY; } return; } // Ensure that typesFlagsByParamCount[dstParamCount] exists: if (typeFlagsByParamCount == null) { typeFlagsByParamCount = new int[dstParamCount + 1][]; } else if (typeFlagsByParamCount.length <= dstParamCount) { int[][] newTypeFlagsByParamCount = new int[dstParamCount + 1][]; System.arraycopy(typeFlagsByParamCount, 0, newTypeFlagsByParamCount, 0, typeFlagsByParamCount.length); typeFlagsByParamCount = newTypeFlagsByParamCount; } int[] dstTypeFlagsByParamIdx = typeFlagsByParamCount[dstParamCount]; if (dstTypeFlagsByParamIdx == null) { // This is the first method added with this number of params => no merging if (srcTypeFlagsByParamIdx != ALL_ZEROS_ARRAY) { int srcParamCount = srcTypeFlagsByParamIdx.length; dstTypeFlagsByParamIdx = new int[dstParamCount]; for (int paramIdx = 0; paramIdx < dstParamCount; paramIdx++) { dstTypeFlagsByParamIdx[paramIdx] = srcTypeFlagsByParamIdx[paramIdx < srcParamCount ? paramIdx : srcParamCount - 1]; } } else { dstTypeFlagsByParamIdx = ALL_ZEROS_ARRAY; } typeFlagsByParamCount[dstParamCount] = dstTypeFlagsByParamIdx; } else { // dstTypeFlagsByParamIdx != null, so we need to merge into it. if (srcTypeFlagsByParamIdx == dstTypeFlagsByParamIdx) { // Used to occur when both are ALL_ZEROS_ARRAY return; } // As we will write dstTypeFlagsByParamIdx, it can't remain ALL_ZEROS_ARRAY anymore. if (dstTypeFlagsByParamIdx == ALL_ZEROS_ARRAY && dstParamCount > 0) { dstTypeFlagsByParamIdx = new int[dstParamCount]; typeFlagsByParamCount[dstParamCount] = dstTypeFlagsByParamIdx; } for (int paramIdx = 0; paramIdx < dstParamCount; paramIdx++) { final int srcParamTypeFlags; if (srcTypeFlagsByParamIdx != ALL_ZEROS_ARRAY) { int srcParamCount = srcTypeFlagsByParamIdx.length; srcParamTypeFlags = srcTypeFlagsByParamIdx[paramIdx < srcParamCount ? paramIdx : srcParamCount - 1]; } else { srcParamTypeFlags = 0; } final int dstParamTypesFlags = dstTypeFlagsByParamIdx[paramIdx]; if (dstParamTypesFlags != srcParamTypeFlags) { int mergedTypeFlags = dstParamTypesFlags | srcParamTypeFlags; if ((mergedTypeFlags & TypeFlags.MASK_ALL_NUMERICALS) != 0) { // Must not be set if we don't have numerical type at this index! mergedTypeFlags |= TypeFlags.WIDENED_NUMERICAL_UNWRAPPING_HINT; } dstTypeFlagsByParamIdx[paramIdx] = mergedTypeFlags; } } } } protected void forceNumberArgumentsToParameterTypes( Object[] args, Class[] paramTypes, int[] typeFlagsByParamIndex) { final int paramTypesLen = paramTypes.length; final int argsLen = args.length; for (int argIdx = 0; argIdx < argsLen; argIdx++) { final int paramTypeIdx = argIdx < paramTypesLen ? argIdx : paramTypesLen - 1; final int typeFlags = typeFlagsByParamIndex[paramTypeIdx]; // Forcing the number type can only be interesting if there are numerical parameter types on that index, // and the unwrapping was not to an exact numerical type. if ((typeFlags & TypeFlags.WIDENED_NUMERICAL_UNWRAPPING_HINT) != 0) { final Object arg = args[argIdx]; // If arg isn't a number, we can't do any conversions anyway, regardless of the param type. if (arg instanceof Number) { final Class targetType = paramTypes[paramTypeIdx]; final Number convertedArg = BeansWrapper.forceUnwrappedNumberToType( (Number) arg, targetType, bugfixed); if (convertedArg != null) { args[argIdx] = convertedArg; } } } } } }




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