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/*
 * Copyright (C) 2012 The Android Open Source Project
 *
 * Licensed 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 com.android.tools.lint.checks;

import com.android.annotations.NonNull;
import com.android.annotations.Nullable;
import com.google.common.collect.Maps;
import com.google.common.collect.Sets;

import org.objectweb.asm.Opcodes;
import org.objectweb.asm.tree.AbstractInsnNode;
import org.objectweb.asm.tree.ClassNode;
import org.objectweb.asm.tree.FieldInsnNode;
import org.objectweb.asm.tree.FrameNode;
import org.objectweb.asm.tree.InsnList;
import org.objectweb.asm.tree.IntInsnNode;
import org.objectweb.asm.tree.JumpInsnNode;
import org.objectweb.asm.tree.LabelNode;
import org.objectweb.asm.tree.LdcInsnNode;
import org.objectweb.asm.tree.LineNumberNode;
import org.objectweb.asm.tree.MethodInsnNode;
import org.objectweb.asm.tree.MethodNode;
import org.objectweb.asm.tree.TryCatchBlockNode;
import org.objectweb.asm.tree.TypeInsnNode;
import org.objectweb.asm.tree.analysis.Analyzer;
import org.objectweb.asm.tree.analysis.AnalyzerException;
import org.objectweb.asm.tree.analysis.BasicInterpreter;

import java.lang.reflect.Field;
import java.util.ArrayList;
import java.util.List;
import java.util.Map;
import java.util.Set;

//import org.objectweb.asm.util.Printer;

/**
 * A {@linkplain ControlFlowGraph} is a graph containing a node for each
 * instruction in a method, and an edge for each possible control flow; usually
 * just "next" for the instruction following the current instruction, but in the
 * case of a branch such as an "if", multiple edges to each successive location,
 * or with a "goto", a single edge to the jumped-to instruction.
 * 

* It also adds edges for abnormal control flow, such as the possibility of a * method call throwing a runtime exception. */ public class ControlFlowGraph { /** Map from instructions to nodes */ private Map mNodeMap; private MethodNode mMethod; /** * Creates a new {@link ControlFlowGraph} and populates it with the flow * control for the given method. If the optional {@code initial} parameter is * provided with an existing graph, then the graph is simply populated, not * created. This allows subclassing of the graph instance, if necessary. * * @param initial usually null, but can point to an existing instance of a * {@link ControlFlowGraph} in which that graph is reused (but * populated with new edges) * @param classNode the class containing the method to be analyzed * @param method the method to be analyzed * @return a {@link ControlFlowGraph} with nodes for the control flow in the * given method * @throws AnalyzerException if the underlying bytecode library is unable to * analyze the method bytecode */ @NonNull public static ControlFlowGraph create( @Nullable ControlFlowGraph initial, @NonNull ClassNode classNode, @NonNull MethodNode method) throws AnalyzerException { final ControlFlowGraph graph = initial != null ? initial : new ControlFlowGraph(); final InsnList instructions = method.instructions; graph.mNodeMap = Maps.newHashMapWithExpectedSize(instructions.size()); graph.mMethod = method; // Create a flow control graph using ASM5's analyzer. According to the ASM 4 guide // (download.forge.objectweb.org/asm/asm4-guide.pdf) there are faster ways to construct // it, but those require a lot more code. Analyzer analyzer = new Analyzer(new BasicInterpreter()) { @Override protected void newControlFlowEdge(int insn, int successor) { // Update the information as of whether the this object has been // initialized at the given instruction. AbstractInsnNode from = instructions.get(insn); AbstractInsnNode to = instructions.get(successor); graph.add(from, to); } @Override protected boolean newControlFlowExceptionEdge(int insn, TryCatchBlockNode tcb) { AbstractInsnNode from = instructions.get(insn); graph.exception(from, tcb); return super.newControlFlowExceptionEdge(insn, tcb); } @Override protected boolean newControlFlowExceptionEdge(int insn, int successor) { AbstractInsnNode from = instructions.get(insn); AbstractInsnNode to = instructions.get(successor); graph.exception(from, to); return super.newControlFlowExceptionEdge(insn, successor); } }; analyzer.analyze(classNode.name, method); return graph; } /** * Checks whether there is a path from the given source node to the given * destination node */ @SuppressWarnings("MethodMayBeStatic") private boolean isConnected(@NonNull Node from, @NonNull Node to, @NonNull Set seen) { if (from == to) { return true; } else if (seen.contains(from)) { return false; } seen.add(from); List successors = from.successors; List exceptions = from.exceptions; if (exceptions != null) { for (Node successor : exceptions) { if (isConnected(successor, to, seen)) { return true; } } } if (successors != null) { for (Node successor : successors) { if (isConnected(successor, to, seen)) { return true; } } } return false; } /** * Checks whether there is a path from the given source node to the given * destination node */ public boolean isConnected(@NonNull Node from, @NonNull Node to) { return isConnected(from, to, Sets.newIdentityHashSet()); } /** * Checks whether there is a path from the given instruction to the given * instruction node */ public boolean isConnected(@NonNull AbstractInsnNode from, @NonNull AbstractInsnNode to) { return isConnected(getNode(from), getNode(to)); } /** A {@link Node} is a node in the control flow graph for a method, pointing to * the instruction and its possible successors */ public static class Node { /** The instruction */ public final AbstractInsnNode instruction; /** Any normal successors (e.g. following instruction, or goto or conditional flow) */ public final List successors = new ArrayList(2); /** Any abnormal successors (e.g. the handler to go to following an exception) */ public final List exceptions = new ArrayList(1); /** A tag for use during depth-first-search iteration of the graph etc */ public int visit; /** * Constructs a new control graph node * * @param instruction the instruction to associate with this node */ public Node(@NonNull AbstractInsnNode instruction) { this.instruction = instruction; } void addSuccessor(@NonNull Node node) { if (!successors.contains(node)) { successors.add(node); } } void addExceptionPath(@NonNull Node node) { if (!exceptions.contains(node)) { exceptions.add(node); } } /** * Represents this instruction as a string, for debugging purposes * * @param includeAdjacent whether it should include a display of * adjacent nodes as well * @return a string representation */ @NonNull public String toString(boolean includeAdjacent) { StringBuilder sb = new StringBuilder(100); sb.append(getId(instruction)); sb.append(':'); if (instruction instanceof LabelNode) { //LabelNode l = (LabelNode) instruction; //sb.append('L' + l.getLabel().getOffset() + ":"); //sb.append('L' + l.getLabel().info + ":"); sb.append("LABEL"); } else if (instruction instanceof LineNumberNode) { sb.append("LINENUMBER ").append(((LineNumberNode)instruction).line); } else if (instruction instanceof FrameNode) { sb.append("FRAME"); } else { int opcode = instruction.getOpcode(); String opcodeName = getOpcodeName(opcode); sb.append(opcodeName); if (instruction.getType() == AbstractInsnNode.METHOD_INSN) { sb.append('(').append(((MethodInsnNode)instruction).name).append(')'); } } if (includeAdjacent) { if (successors != null && !successors.isEmpty()) { sb.append(" Next:"); for (Node successor : successors) { sb.append(' '); sb.append(successor.toString(false)); } } if (exceptions != null && !exceptions.isEmpty()) { sb.append(" Exceptions:"); for (Node exception : exceptions) { sb.append(' '); sb.append(exception.toString(false)); } } sb.append('\n'); } return sb.toString(); } } /** Adds an exception flow to this graph */ protected void add(@NonNull AbstractInsnNode from, @NonNull AbstractInsnNode to) { getNode(from).addSuccessor(getNode(to)); } /** Adds an exception flow to this graph */ protected void exception(@NonNull AbstractInsnNode from, @NonNull AbstractInsnNode to) { // For now, these edges appear useless; we also get more specific // information via the TryCatchBlockNode which we use instead. //getNode(from).addExceptionPath(getNode(to)); } /** Adds an exception try block node to this graph */ protected void exception(@NonNull AbstractInsnNode from, @NonNull TryCatchBlockNode tcb) { // Add tcb's to all instructions in the range LabelNode start = tcb.start; LabelNode end = tcb.end; // exclusive // Add exception edges for all method calls in the range AbstractInsnNode curr = start; Node handlerNode = getNode(tcb.handler); while (curr != end && curr != null) { // A method can throw can exception, or a throw instruction directly if (curr.getType() == AbstractInsnNode.METHOD_INSN || (curr.getType() == AbstractInsnNode.INSN && curr.getOpcode() == Opcodes.ATHROW)) { // Method call; add exception edge to handler if (tcb.type == null) { // finally block: not an exception path getNode(curr).addSuccessor(handlerNode); } getNode(curr).addExceptionPath(handlerNode); } curr = curr.getNext(); } } /** * Looks up (and if necessary) creates a graph node for the given instruction * * @param instruction the instruction * @return the control flow graph node corresponding to the given * instruction */ @NonNull public Node getNode(@NonNull AbstractInsnNode instruction) { Node node = mNodeMap.get(instruction); if (node == null) { node = new Node(instruction); mNodeMap.put(instruction, node); } return node; } /** * Creates a human readable version of the graph * * @param start the starting instruction, or null if not known or to use the * first instruction * @return a string version of the graph */ @NonNull public String toString(@Nullable Node start) { StringBuilder sb = new StringBuilder(400); AbstractInsnNode curr; if (start != null) { curr = start.instruction; } else { if (mNodeMap.isEmpty()) { return ""; } else { curr = mNodeMap.keySet().iterator().next(); while (curr.getPrevious() != null) { curr = curr.getPrevious(); } } } while (curr != null) { Node node = mNodeMap.get(curr); if (node != null) { sb.append(node.toString(true)); } curr = curr.getNext(); } return sb.toString(); } @Override public String toString() { return toString(null); } // ---- For debugging only ---- private static Map sIds = null; private static int sNextId = 1; private static String getId(Object object) { if (sIds == null) { sIds = Maps.newHashMap(); } String id = sIds.get(object); if (id == null) { id = Integer.toString(sNextId++); sIds.put(object, id); } return id; } /** * Generates dot output of the graph. This can be used with * graphwiz to visualize the graph. For example, if you * save the output as graph1.gv you can run *

     * $ dot -Tps graph1.gv -o graph1.ps
     * 
* to generate a postscript file, which you can then view * with "gv graph1.ps". * * (There are also some online web sites where you can * paste in dot graphs and see the visualization right * there in the browser.) * * @return a dot description of this control flow graph, * useful for debugging */ @SuppressWarnings("unused") public String toDot(@Nullable Set highlight) { StringBuilder sb = new StringBuilder(); sb.append("digraph G {\n"); AbstractInsnNode instruction = mMethod.instructions.getFirst(); // Special start node sb.append(" start -> ").append(getId(mNodeMap.get(instruction))).append(";\n"); sb.append(" start [shape=plaintext];\n"); while (instruction != null) { Node node = mNodeMap.get(instruction); if (node != null) { if (node.successors != null) { for (Node to : node.successors) { sb.append(" ").append(getId(node)).append(" -> ").append(getId(to)); if (node.instruction instanceof JumpInsnNode) { sb.append(" [label=\""); if (((JumpInsnNode)node.instruction).label == to.instruction) { sb.append("yes"); } else { sb.append("no"); } sb.append("\"]"); } sb.append(";\n"); } } if (node.exceptions != null) { for (Node to : node.exceptions) { sb.append(getId(node)).append(" -> ").append(getId(to)); sb.append(" [label=\"exception\"];\n"); } } } instruction = instruction.getNext(); } // Labels sb.append("\n"); for (Node node : mNodeMap.values()) { instruction = node.instruction; sb.append(" ").append(getId(node)).append(" "); sb.append("[label=\"").append(dotDescribe(node)).append("\""); if (highlight != null && highlight.contains(node)) { sb.append(",shape=box,style=filled"); } else if (instruction instanceof LineNumberNode || instruction instanceof LabelNode || instruction instanceof FrameNode) { sb.append(",shape=oval,style=dotted"); } else { sb.append(",shape=box"); } sb.append("];\n"); } sb.append("}"); return sb.toString(); } private static String dotDescribe(Node node) { AbstractInsnNode instruction = node.instruction; if (instruction instanceof LabelNode) { return "Label"; } else if (instruction instanceof LineNumberNode) { LineNumberNode lineNode = (LineNumberNode)instruction; return "Line " + lineNode.line; } else if (instruction instanceof FrameNode) { return "Stack Frame"; } else if (instruction instanceof MethodInsnNode) { MethodInsnNode method = (MethodInsnNode)instruction; String cls = method.owner.substring(method.owner.lastIndexOf('/') + 1); cls = cls.replace('$','.'); return "Call " + cls + "#" + method.name; } else if (instruction instanceof FieldInsnNode) { FieldInsnNode field = (FieldInsnNode) instruction; String cls = field.owner.substring(field.owner.lastIndexOf('/') + 1); cls = cls.replace('$','.'); return "Field " + cls + "#" + field.name; } else if (instruction instanceof TypeInsnNode && instruction.getOpcode() == Opcodes.NEW) { return "New " + ((TypeInsnNode)instruction).desc; } StringBuilder sb = new StringBuilder(); String opcodeName = getOpcodeName(instruction.getOpcode()); sb.append(opcodeName); if (instruction instanceof IntInsnNode) { IntInsnNode in = (IntInsnNode) instruction; sb.append(" ").append(Integer.toString(in.operand)); } else if (instruction instanceof LdcInsnNode) { LdcInsnNode ldc = (LdcInsnNode) instruction; sb.append(" "); if (ldc.cst instanceof String) { sb.append("\\\""); } sb.append(ldc.cst); if (ldc.cst instanceof String) { sb.append("\\\""); } } return sb.toString(); } private static String getOpcodeName(int opcode) { if (sOpcodeNames == null) { sOpcodeNames = new String[255]; try { Field[] fields = Opcodes.class.getDeclaredFields(); for (Field field : fields) { if (field.getType() == int.class) { String name = field.getName(); if (name.startsWith("ASM") || name.startsWith("V1_") || name.startsWith("ACC_") || name.startsWith("T_") || name.startsWith("H_") || name.startsWith("F_")) { continue; } int val = field.getInt(null); if (val >= 0 && val < sOpcodeNames.length) { sOpcodeNames[val] = field.getName(); } } } } catch (Exception e) { e.printStackTrace(); } } if (opcode >= 0 && opcode < sOpcodeNames.length) { String name = sOpcodeNames[opcode]; if (name != null) { return name; } } return Integer.toString(opcode); } private static String[] sOpcodeNames; }




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