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/*
 * BSD-style license; for more info see http://pmd.sourceforge.net/license.html
 */

package net.sourceforge.pmd.lang.java.metrics;

import static net.sourceforge.pmd.internal.util.PredicateUtil.always;

import java.math.BigInteger;
import java.util.ArrayList;
import java.util.Collections;
import java.util.HashSet;
import java.util.List;
import java.util.Set;
import java.util.function.Function;
import java.util.function.Predicate;

import org.apache.commons.lang3.mutable.MutableInt;
import org.checkerframework.checker.nullness.qual.Nullable;

import net.sourceforge.pmd.lang.ast.Node;
import net.sourceforge.pmd.lang.ast.NodeStream;
import net.sourceforge.pmd.lang.document.FileLocation;
import net.sourceforge.pmd.lang.java.ast.ASTAssignableExpr.ASTNamedReferenceExpr;
import net.sourceforge.pmd.lang.java.ast.ASTExecutableDeclaration;
import net.sourceforge.pmd.lang.java.ast.ASTFieldDeclaration;
import net.sourceforge.pmd.lang.java.ast.ASTMethodDeclaration;
import net.sourceforge.pmd.lang.java.ast.ASTTypeDeclaration;
import net.sourceforge.pmd.lang.java.ast.JavaNode;
import net.sourceforge.pmd.lang.java.ast.ModifierOwner;
import net.sourceforge.pmd.lang.java.metrics.internal.AtfdBaseVisitor;
import net.sourceforge.pmd.lang.java.metrics.internal.ClassFanOutVisitor;
import net.sourceforge.pmd.lang.java.metrics.internal.CognitiveComplexityVisitor;
import net.sourceforge.pmd.lang.java.metrics.internal.CognitiveComplexityVisitor.State;
import net.sourceforge.pmd.lang.java.metrics.internal.CycloVisitor;
import net.sourceforge.pmd.lang.java.metrics.internal.NcssVisitor;
import net.sourceforge.pmd.lang.java.metrics.internal.NpathBaseVisitor;
import net.sourceforge.pmd.lang.java.rule.internal.JavaRuleUtil;
import net.sourceforge.pmd.lang.java.symbols.JClassSymbol;
import net.sourceforge.pmd.lang.java.symbols.JFieldSymbol;
import net.sourceforge.pmd.lang.java.symbols.JVariableSymbol;
import net.sourceforge.pmd.lang.metrics.Metric;
import net.sourceforge.pmd.lang.metrics.MetricOption;
import net.sourceforge.pmd.lang.metrics.MetricOptions;
import net.sourceforge.pmd.lang.metrics.MetricsUtil;

/**
 * Built-in Java metrics. See {@link Metric} and {@link MetricsUtil}
 * for usage doc.
 *
 * @see "Michele Lanza and Radu Marinescu. Object-Oriented Metrics in Practice:
 * Using Software Metrics to Characterize, Evaluate, and Improve the Design
 * of Object-Oriented Systems. Springer, Berlin, 1 edition, October 2006."
 */
public final class JavaMetrics {

    /**
     * Number of usages of foreign attributes, both directly and through accessors.
     * "Foreign" hier means "not belonging to {@code this}", although field accesses
     * to fields declared in the enclosing class are not considered foreign.
     *
     * 

High values of ATFD (> 3 for an operation) may suggest that the * class or operation breaks encapsulation by relying on the internal * representation of the classes it uses instead of the services they provide. */ public static final Metric ACCESS_TO_FOREIGN_DATA = Metric.of(JavaMetrics::computeAtfd, isJavaNode(), "Access To Foreign Data", "ATFD"); /** * Number of independent paths through a block of code. * Formally, given that the control flow graph of the block has n * vertices, e edges and p connected components, the cyclomatic complexity * of the block is given by {@code CYCLO = e - n + 2p}. In practice * it can be calculated by counting control flow statements following * the standard rules given below. * *

The standard version of the metric complies with McCabe’s original definition: *

    *
  • Methods have a base complexity of 1. *
  • +1 for every control flow statement (if, case, catch, throw, * do, while, for, break, continue) and conditional expression (?:). * Notice switch cases count as one, but not the switch itself: the * point is that a switch should have the same complexity value as * the equivalent series of if statements. *
  • else, finally and default do not count; *
  • +1 for every boolean operator ({@code &&}, {@code ||}) in * the guard condition of a control flow statement. That’s because * Java has short-circuit evaluation semantics for boolean operators, * which makes every boolean operator kind of a control flow statement in itself. *
* *

Code example: *

{@code
     * class Foo {
     *   void baseCyclo() {                // Cyclo = 1
     *     highCyclo();
     *   }
     *
     *   void highCyclo() {                // Cyclo = 10
     *     int x = 0, y = 2;
     *     boolean a = false, b = true;
     *
     *     if (a && (y == 1 ? b : true)) { // +3
     *       if (y == x) {                 // +1
     *         while (true) {              // +1
     *           if (x++ < 20) {           // +1
     *             break;                  // +1
     *           }
     *         }
     *       } else if (y == t && !d) {    // +2
     *         x = a ? y : x;              // +1
     *       } else {
     *         x = 2;
     *       }
     *     }
     *   }
     * }
     * }
* * @see CycloOption */ public static final Metric CYCLO = Metric.of(JavaMetrics::computeCyclo, asMethodOrCtor(), "Cyclomatic Complexity", "Cyclo"); /** * Cognitive complexity is a measure of how difficult it is for humans * to read and understand a method. Code that contains a break in the * control flow is more complex, whereas the use of language shorthands * doesn't increase the level of complexity. Nested control flows can * make a method more difficult to understand, with each additional * nesting of the control flow leading to an increase in cognitive * complexity. * *

Information about Cognitive complexity can be found in the original paper here: * CognitiveComplexity * *

Basic Idea

*
    *
  1. Ignore structures that allow multiple statements to be readably shorthanded into one *
  2. Increment (add one) for each break in the linear flow of the code *
  3. Increment when flow-breaking structures are nested *
* *

Increments

* There is an increment for each of the following: *
    *
  • `if`, `else if`, `else`, ternary operator *
  • `switch` *
  • `for`, `foreach` *
  • `while`, `do while` *
  • `catch` *
  • `goto LABEL`, `break LABEL`, `continue LABEL` *
  • sequences of binary logical operators *
  • each method in a recursion cycle *
* *

Nesting level

* The following structures increment the nesting level: *
    *
  • `if`, `else if`, `else`, ternary operator *
  • `switch` *
  • `for`, `foreach` *
  • `while`, `do while` *
  • `catch` *
  • nested methods and method-like structures such as lambdas *
* *

Nesting increments

* The following structures receive a nesting increment commensurate with their nested depth * inside nested structures: *
    *
  • `if`, ternary operator *
  • `switch` *
  • `for`, `foreach` *
  • `while`, `do while` *
  • `catch` *
* *

Code example

*
{@code
     * class Foo {
     *   void myMethod () {
     *     try {
     *       if (condition1) { // +1
     *         for (int i = 0; i < 10; i++) { // +2 (nesting=1)
     *           while (condition2) { } // +3 (nesting=2)
     *         }
     *       }
     *     } catch (ExcepType1 | ExcepType2 e) { // +1
     *       if (condition2) { } // +2 (nesting=1)
     *     }
     *   } // Cognitive Complexity 9
     * }
     * }
*/ public static final Metric COGNITIVE_COMPLEXITY = Metric.of(JavaMetrics::computeCognitive, asMethodOrCtor(), "Cognitive Complexity", "CognitiveComp"); /** * This counts the number of other classes a given class or operation * relies on. Classes from the package {@code java.lang} are ignored * by default (can be changed via options). Also primitives are not * included into the count. * *

Code example: *

{@code
     * import java.util.*;
     * import java.io.IOException;
     *
     * public class Foo { // total 8
     *     public Set set = new HashSet(); // +2
     *     public Map map = new HashMap(); // +2
     *     public String string = ""; // from java.lang -> does not count by default
     *     public Double number = 0.0; // from java.lang -> does not count by default
     *     public int[] intArray = new int[3]; // primitive -> does not count
     *
     *     \@Deprecated // from java.lang -> does not count by default
     *     public void foo(List list) throws Exception { // +1 (Exception is from java.lang)
     *         throw new IOException(); // +1
     *     }
     *
     *     public int getMapSize() {
     *         return map.size(); // +1 because it uses the Class from the 'map' field
     *     }
     * }
     * }
* * @see ClassFanOutOption */ public static final Metric FAN_OUT = Metric.of(JavaMetrics::computeFanOut, isJavaNode(), "Fan-Out", "CFO"); /** * Simply counts the number of lines of code the operation or class * takes up in the source. This metric doesn’t discount comments or blank lines. * See {@link #NCSS} for a less biased metric. */ public static final Metric LINES_OF_CODE = Metric.of(JavaMetrics::computeLoc, isJavaNode(), "Lines of code", "LOC"); /** * Number of statements in a class or operation. That’s roughly * equivalent to counting the number of semicolons and opening braces * in the program. Comments and blank lines are ignored, and statements * spread on multiple lines count as only one (e.g. {@code int\n a;} * counts a single statement). * *

The standard version of the metric is based off [JavaNCSS](http://www.kclee.de/clemens/java/javancss/): *

    *
  • +1 for any of the following statements: {@code if}, {@code else}, * {@code while}, {@code do}, {@code for}, {@code switch}, {@code break}, * {@code continue}, {@code return}, {@code throw}, {@code synchronized}, * {@code catch}, {@code finally}. *
  • +1 for each assignment, variable declaration (except for loop initializers) * or statement expression. We count variables declared on the same line (e.g. * {@code int a, b, c;}) as a single statement. *
  • Contrary to Sonarqube, but as JavaNCSS, we count type declarations (class, interface, enum, annotation), * and method and field declarations. *
  • Contrary to JavaNCSS, but as Sonarqube, we do not count package * declaration and import declarations as statements. This makes it * easier to compare nested classes to outer classes. Besides, it makes * for class metric results that actually represent the size of the class * and not of the file. If you don’t like that behaviour, use the {@link NcssOption#COUNT_IMPORTS} option. *
* *
{@code
     * import java.util.Collections;       // +0
     * import java.io.IOException;         // +0
     *
     * class Foo {                         // +1, total Ncss = 12
     *
     *   public void bigMethod()           // +1
     *       throws IOException {
     *     int x = 0, y = 2;               // +1
     *     boolean a = false, b = true;    // +1
     *
     *     if (a || b) {                   // +1
     *       try {                         // +1
     *         do {                        // +1
     *           x += 2;                   // +1
     *         } while (x < 12);
     *
     *         System.exit(0);             // +1
     *       } catch (IOException ioe) {   // +1
     *         throw new PatheticFailException(ioe); // +1
     *       }
     *     } else {
     *       assert false;                 // +1
     *     }
     *   }
     * }
     * }
*/ public static final Metric NCSS = Metric.of(JavaMetrics::computeNcss, isJavaNode(), "Non-commenting source statements", "NCSS"); /** * Number of acyclic execution paths through a piece of code. This * is related to cyclomatic complexity, but the two metrics don’t * count the same thing: NPath counts the number of distinct full * paths from the beginning to the end of the method, while Cyclo * only counts the number of decision points. NPath is not computed * as simply as {@link #CYCLO}. With NPath, two decision points appearing * sequentially have their complexity multiplied. * *

The fact that NPath multiplies the complexity of statements makes * it grow exponentially: 10 {@code if .. else} statements in a row * would give an NPath of 1024, while Cyclo would evaluate to 20. * Methods with an NPath complexity over 200 are generally considered * too complex. * *

We compute NPath recursively, with the following set of rules: *

    *
  • An empty block has a complexity of 1. *
  • The complexity of a block is the product of the NPath complexity * of its statements, calculated as follows: *
      *
    • The complexity of for, do and while statements is 1, plus the * complexity of the block, plus the complexity of the guard condition. *
    • The complexity of a cascading if statement ({@code if .. else if ..}) * is the number of if statements in the chain, plus the complexity of * their guard condition, plus the complexity of the unguarded else block * (or 1 if there is none). *
    • The complexity of a switch statement is the number of cases, * plus the complexity of each case block. It’s equivalent to the * complexity of the equivalent cascade of if statements. *
    • The complexity of a ternary expression ({@code ? :}) is the complexity * of the guard condition, plus the complexity of both expressions. * It’s equivalent to the complexity of the equivalent {@code if .. else} construct. *
    • The complexity of a {@code try .. catch} statement is the complexity * of the {@code try} block, plus the complexity of each catch block. *
    • The complexity of a return statement is the complexity of the * expression (or 1 if there is none). *
    • All other statements have a complexity of 1 and are discarded * from the product. *
    *
  • *
*/ public static final Metric NPATH = Metric.of(JavaMetrics::computeNpath, asMethodOrCtor(), "NPath Complexity", "NPath"); public static final Metric NUMBER_OF_ACCESSORS = Metric.of(JavaMetrics::computeNoam, asClass(always()), "Number of accessor methods", "NOAM"); public static final Metric NUMBER_OF_PUBLIC_FIELDS = Metric.of(JavaMetrics::computeNopa, asClass(always()), "Number of public attributes", "NOPA"); /** * The relative number of method pairs of a class that access in common * at least one attribute of the measured class. TCC only counts direct * attribute accesses, that is, only those attributes that are accessed * in the body of the method. * *

The value is a double between 0 and 1. * *

TCC is taken to be a reliable cohesion metric for a class. * High values (>70%) indicate a class with one basic function, * which is hard to break into subcomponents. On the other hand, low * values (<50%) may indicate that the class tries to do too much * and defines several unrelated services, which is undesirable. */ public static final Metric TIGHT_CLASS_COHESION = Metric.of(JavaMetrics::computeTcc, asClass(it -> !it.isInterface()), "Tight Class Cohesion", "TCC"); /** * Sum of the statistical complexity of the operations in the class. * We use CYCLO to quantify the complexity of an operation. * *

WMC uses the same options as CYCLO, which are provided to CYCLO when computing it ({@link CycloOption}). */ public static final Metric WEIGHED_METHOD_COUNT = Metric.of(JavaMetrics::computeWmc, asClass(it -> !it.isInterface()), "Weighed Method Count", "WMC"); /** * Number of “functional” public methods divided by the total number * of public methods. Our definition of “functional method” excludes * constructors, getters, and setters. * *

The value is a double between 0 and 1. * *

This metric tries to quantify whether the measured class’ interface * reveals more data than behaviour. Low values (less than 30%) indicate * that the class reveals much more data than behaviour, which is a * sign of poor encapsulation. */ public static final Metric WEIGHT_OF_CLASS = Metric.of(JavaMetrics::computeWoc, asClass(it -> !it.isInterface()), "Weight Of Class", "WOC"); private JavaMetrics() { // utility class } private static Function isJavaNode() { return n -> n instanceof JavaNode ? (JavaNode) n : null; } private static Function asMethodOrCtor() { return n -> n instanceof ASTExecutableDeclaration ? (ASTExecutableDeclaration) n : null; } private static Function filterMapNode(Class klass, Predicate pred) { return n -> n.asStream().filterIs(klass).filter(pred).first(); } private static Function asClass(Predicate pred) { return filterMapNode(ASTTypeDeclaration.class, pred); } private static int computeNoam(ASTTypeDeclaration node, MetricOptions ignored) { return node.getDeclarations() .filterIs(ASTMethodDeclaration.class) .filter(JavaRuleUtil::isGetterOrSetter) .count(); } private static int computeNopa(ASTTypeDeclaration node, MetricOptions ignored) { return node.getDeclarations() .filterIs(ASTFieldDeclaration.class) .filter(it -> it.hasVisibility(ModifierOwner.Visibility.V_PUBLIC)) .flatMap(ASTFieldDeclaration::getVarIds) .count(); } private static int computeNcss(JavaNode node, MetricOptions options) { MutableInt result = new MutableInt(0); node.acceptVisitor(new NcssVisitor(options, node), result); return result.getValue(); } private static int computeLoc(JavaNode node, MetricOptions ignored) { // the report location is now not necessarily the entire node. FileLocation loc = node.getTextDocument().toLocation(node.getTextRegion()); return 1 + loc.getEndLine() - loc.getStartLine(); } private static int computeCyclo(JavaNode node, MetricOptions options) { MutableInt counter = new MutableInt(0); node.acceptVisitor(new CycloVisitor(options, node), counter); return counter.getValue(); } private static BigInteger computeNpath(JavaNode node, MetricOptions ignored) { return node.acceptVisitor(NpathBaseVisitor.INSTANCE, null); } private static int computeCognitive(JavaNode node, MetricOptions ignored) { State state = new State(node); node.acceptVisitor(CognitiveComplexityVisitor.INSTANCE, state); return state.getComplexity(); } private static int computeWmc(ASTTypeDeclaration node, MetricOptions options) { return (int) MetricsUtil.computeStatistics(CYCLO, node.getOperations(), options).getSum(); } private static double computeTcc(ASTTypeDeclaration node, MetricOptions ignored) { List> usagesByMethod = attributeAccessesByMethod(node); int numPairs = numMethodsRelatedByAttributeAccess(usagesByMethod); int maxPairs = maxMethodPairs(usagesByMethod.size()); if (maxPairs == 0) { return 0; } return numPairs / (double) maxPairs; } /** * Collects the attribute accesses by method into a map, for TCC. */ private static List> attributeAccessesByMethod(ASTTypeDeclaration type) { final List> map = new ArrayList<>(); final JClassSymbol typeSym = type.getSymbol(); for (ASTMethodDeclaration decl : type.getDeclarations(ASTMethodDeclaration.class)) { Set attrs = new HashSet<>(); decl.descendants().crossFindBoundaries() .filterIs(ASTNamedReferenceExpr.class) .forEach(it -> { JVariableSymbol sym = it.getReferencedSym(); if (sym instanceof JFieldSymbol && typeSym.equals(((JFieldSymbol) sym).getEnclosingClass())) { attrs.add(sym.getSimpleName()); } }); map.add(attrs); } return map; } /** * Gets the number of pairs of methods that use at least one attribute in common. * * @param usagesByMethod Map of method name to names of local attributes accessed * * @return The number of pairs */ private static int numMethodsRelatedByAttributeAccess(List> usagesByMethod) { int methodCount = usagesByMethod.size(); int pairs = 0; if (methodCount > 1) { for (int i = 0; i < methodCount - 1; i++) { for (int j = i + 1; j < methodCount; j++) { if (!Collections.disjoint(usagesByMethod.get(i), usagesByMethod.get(j))) { pairs++; } } } } return pairs; } /** * Calculates the number of possible method pairs of two methods. * * @param methods Number of methods in the class * * @return Number of possible method pairs */ private static int maxMethodPairs(int methods) { return methods * (methods - 1) / 2; } /** * Options for {@link #NCSS}. */ public enum NcssOption implements MetricOption { /** Counts import and package statement. This makes the metric JavaNCSS compliant. */ COUNT_IMPORTS("countImports"); private final String vName; NcssOption(String valueName) { this.vName = valueName; } @Override public String valueName() { return vName; } } /** * Options for {@link #CYCLO}. */ public enum CycloOption implements MetricOption { /** Do not count the paths in boolean expressions as decision points. */ IGNORE_BOOLEAN_PATHS("ignoreBooleanPaths"), /** Consider assert statements as if they were {@code if (..) throw new AssertionError(..)}. */ CONSIDER_ASSERT("considerAssert"); private final String vName; CycloOption(String valueName) { this.vName = valueName; } @Override public String valueName() { return vName; } } private static int computeAtfd(JavaNode node, MetricOptions ignored) { MutableInt result = new MutableInt(0); node.acceptVisitor(new AtfdBaseVisitor(), result); return result.getValue(); } private static double computeWoc(ASTTypeDeclaration node, MetricOptions ignored) { NodeStream methods = node.getDeclarations() .filterIs(ASTMethodDeclaration.class) .filter(it -> !it.hasVisibility(ModifierOwner.Visibility.V_PRIVATE)); int notSetter = methods.filter(it -> !JavaRuleUtil.isGetterOrSetter(it)).count(); int total = methods.count(); if (total == 0) { return 0; } return notSetter / (double) total; } private static int computeFanOut(JavaNode node, MetricOptions options) { Set cfo = new HashSet<>(); node.acceptVisitor(ClassFanOutVisitor.getInstance(options), cfo); return cfo.size(); } /** * Options for {@link #FAN_OUT}. */ public enum ClassFanOutOption implements MetricOption { /** Whether to include classes in the {@code java.lang} package. */ INCLUDE_JAVA_LANG("includeJavaLang"); private final String vName; ClassFanOutOption(String valueName) { this.vName = valueName; } @Override public String valueName() { return vName; } } }





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