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// ASM: a very small and fast Java bytecode manipulation framework
// Copyright (c) 2000-2011 INRIA, France Telecom
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
// 1. Redistributions of source code must retain the above copyright
//    notice, this list of conditions and the following disclaimer.
// 2. Redistributions 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.
// 3. Neither the name of the copyright holders nor the names of its
//    contributors may be used to endorse or promote products derived from
//    this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
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// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
// THE POSSIBILITY OF SUCH DAMAGE.
package scala.tools.asm.util;

import java.util.Collections;
import java.util.List;
import scala.tools.asm.Opcodes;
import scala.tools.asm.Type;
import scala.tools.asm.tree.AbstractInsnNode;
import scala.tools.asm.tree.FrameNode;
import scala.tools.asm.tree.InsnList;
import scala.tools.asm.tree.InsnNode;
import scala.tools.asm.tree.JumpInsnNode;
import scala.tools.asm.tree.LabelNode;
import scala.tools.asm.tree.LookupSwitchInsnNode;
import scala.tools.asm.tree.MethodNode;
import scala.tools.asm.tree.TableSwitchInsnNode;
import scala.tools.asm.tree.TryCatchBlockNode;
import scala.tools.asm.tree.TypeInsnNode;
import scala.tools.asm.tree.analysis.Analyzer;
import scala.tools.asm.tree.analysis.AnalyzerException;
import scala.tools.asm.tree.analysis.Frame;
import scala.tools.asm.tree.analysis.Interpreter;
import scala.tools.asm.tree.analysis.Value;

/**
 * An {@link Analyzer} subclass which checks that methods provide stack map frames where expected
 * (i.e. at jump target and after instructions without immediate successor), and that these stack
 * map frames are valid (for the provided interpreter; they may still be invalid for the JVM, if the
 * {@link Interpreter} uses a simplified type system compared to the JVM verifier). This is done in
 * two steps:
 *
 * 
    *
  • First, the stack map frames in {@link FrameNode}s are expanded, and stored at their * respective instruction offsets. The expansion process uncompresses the APPEND, CHOP and * SAME frames to FULL frames. It also converts the stack map frame verification types to * {@link Value}s, via the provided {@link Interpreter}. The expansion is done in {@link * #expandFrames}, by looking at each {@link FrameNode} in sequence (compressed frames are * defined relatively to the previous {@link FrameNode}, or the implicit first frame). The * actual decompression is done in {@link #expandFrame}, and the type conversion in {@link * #newFrameValue}. *
  • Next, the method instructions are checked in sequence. Starting from the implicit initial * frame, the execution of each instruction i is simulated on the current stack map * frame, with the {@link Frame#execute} method. This gives a new stack map frame f, * representing the stack map frame state after the execution of i. Then: *
      *
    • If there is a next instruction and if the control flow cannot continue to it (e.g. if * i is a RETURN or an ATHROW, for instance): an existing stack map frame * f0 (coming from the first step) is expected after i. *
    • If there is a next instruction and if the control flow can continue to it (e.g. if * i is a ALOAD, for instance): either there an existing stack map frame * f0 (coming from the first step) after i, or there is none. In the * first case f and f0 must be compatible: the types in * f must be sub types of the corresponding types in the existing frame * f0 (otherwise an exception is thrown). In the second case, f0 is * simply set to the value of f. *
    • If the control flow can continue to some instruction j (e.g. if i * is an IF_EQ, for instance): an existing stack map frame f0 (coming from the * first step) is expected at j, which must be compatible with f (as * defined previously). *
    * The sequential loop over the instructions is done in {@link #init}, which is called from * the {@link Analyzer#analyze} method. Cases where the control flow cannot continue to the * next instruction are handled in {@link #endControlFlow}. Cases where the control flow can * continue to the next instruction, or jump to another instruction, are handled in {@link * #checkFrame}. This method checks that an existing stack map frame is present when required, * and checks the stack map frames compatibility with {@link #checkMerge}. *
* * @author Eric Bruneton * @param type of the {@link Value} used for the analysis. */ class CheckFrameAnalyzer extends Analyzer { /** The interpreter to use to symbolically interpret the bytecode instructions. */ private final Interpreter interpreter; /** The instructions of the currently analyzed method. */ private InsnList insnList; /** * The number of locals in the last stack map frame processed by {@link expandFrame}. Long and * double values are represented with two elements. */ private int currentLocals; CheckFrameAnalyzer(final Interpreter interpreter) { super(interpreter); this.interpreter = interpreter; } @Override protected void init(final String owner, final MethodNode method) throws AnalyzerException { insnList = method.instructions; currentLocals = Type.getArgumentsAndReturnSizes(method.desc) >> 2; Frame[] frames = getFrames(); Frame currentFrame = frames[0]; expandFrames(owner, method, currentFrame); for (int insnIndex = 0; insnIndex < insnList.size(); ++insnIndex) { Frame oldFrame = frames[insnIndex]; // Simulate the execution of this instruction. AbstractInsnNode insnNode = null; try { insnNode = method.instructions.get(insnIndex); int insnOpcode = insnNode.getOpcode(); int insnType = insnNode.getType(); if (insnType == AbstractInsnNode.LABEL || insnType == AbstractInsnNode.LINE || insnType == AbstractInsnNode.FRAME) { checkFrame(insnIndex + 1, oldFrame, /* requireFrame = */ false); } else { currentFrame.init(oldFrame).execute(insnNode, interpreter); if (insnNode instanceof JumpInsnNode) { if (insnOpcode == JSR) { throw new AnalyzerException(insnNode, "JSR instructions are unsupported"); } JumpInsnNode jumpInsn = (JumpInsnNode) insnNode; int targetInsnIndex = insnList.indexOf(jumpInsn.label); checkFrame(targetInsnIndex, currentFrame, /* requireFrame = */ true); if (insnOpcode == GOTO) { endControlFlow(insnIndex); } else { checkFrame(insnIndex + 1, currentFrame, /* requireFrame = */ false); } } else if (insnNode instanceof LookupSwitchInsnNode) { LookupSwitchInsnNode lookupSwitchInsn = (LookupSwitchInsnNode) insnNode; int targetInsnIndex = insnList.indexOf(lookupSwitchInsn.dflt); checkFrame(targetInsnIndex, currentFrame, /* requireFrame = */ true); for (int i = 0; i < lookupSwitchInsn.labels.size(); ++i) { LabelNode label = lookupSwitchInsn.labels.get(i); targetInsnIndex = insnList.indexOf(label); currentFrame.initJumpTarget(insnOpcode, label); checkFrame(targetInsnIndex, currentFrame, /* requireFrame = */ true); } endControlFlow(insnIndex); } else if (insnNode instanceof TableSwitchInsnNode) { TableSwitchInsnNode tableSwitchInsn = (TableSwitchInsnNode) insnNode; int targetInsnIndex = insnList.indexOf(tableSwitchInsn.dflt); currentFrame.initJumpTarget(insnOpcode, tableSwitchInsn.dflt); checkFrame(targetInsnIndex, currentFrame, /* requireFrame = */ true); newControlFlowEdge(insnIndex, targetInsnIndex); for (int i = 0; i < tableSwitchInsn.labels.size(); ++i) { LabelNode label = tableSwitchInsn.labels.get(i); currentFrame.initJumpTarget(insnOpcode, label); targetInsnIndex = insnList.indexOf(label); checkFrame(targetInsnIndex, currentFrame, /* requireFrame = */ true); } endControlFlow(insnIndex); } else if (insnOpcode == RET) { throw new AnalyzerException(insnNode, "RET instructions are unsupported"); } else if (insnOpcode != ATHROW && (insnOpcode < IRETURN || insnOpcode > RETURN)) { checkFrame(insnIndex + 1, currentFrame, /* requireFrame = */ false); } else { endControlFlow(insnIndex); } } List insnHandlers = getHandlers(insnIndex); if (insnHandlers != null) { for (TryCatchBlockNode tryCatchBlock : insnHandlers) { Type catchType; if (tryCatchBlock.type == null) { catchType = Type.getObjectType("java/lang/Throwable"); } else { catchType = Type.getObjectType(tryCatchBlock.type); } Frame handler = newFrame(oldFrame); handler.clearStack(); handler.push(interpreter.newExceptionValue(tryCatchBlock, handler, catchType)); checkFrame(insnList.indexOf(tryCatchBlock.handler), handler, /* requireFrame = */ true); } } if (!hasNextJvmInsnOrFrame(insnIndex)) { break; } } catch (AnalyzerException e) { throw new AnalyzerException( e.node, "Error at instruction " + insnIndex + ": " + e.getMessage(), e); } catch (RuntimeException e) { // DontCheck(IllegalCatch): can't be fixed, for backward compatibility. throw new AnalyzerException( insnNode, "Error at instruction " + insnIndex + ": " + e.getMessage(), e); } } } /** * Expands the {@link FrameNode} "instructions" of the given method into {@link Frame} objects and * stores them at the corresponding indices of the {@link #frames} array. The expanded frames are * also associated with the label and line number nodes immediately preceding each frame node. * * @param owner the internal name of the class to which 'method' belongs. * @param method the method whose frames must be expanded. * @param initialFrame the implicit initial frame of 'method'. * @throws AnalyzerException if the stack map frames of 'method', i.e. its FrameNode * "instructions", are invalid. */ private void expandFrames( final String owner, final MethodNode method, final Frame initialFrame) throws AnalyzerException { int lastJvmOrFrameInsnIndex = -1; Frame currentFrame = initialFrame; int currentInsnIndex = 0; for (AbstractInsnNode insnNode : method.instructions) { if (insnNode instanceof FrameNode) { try { currentFrame = expandFrame(owner, currentFrame, (FrameNode) insnNode); } catch (AnalyzerException e) { throw new AnalyzerException( e.node, "Error at instruction " + currentInsnIndex + ": " + e.getMessage(), e); } for (int index = lastJvmOrFrameInsnIndex + 1; index <= currentInsnIndex; ++index) { getFrames()[index] = currentFrame; } } if (isJvmInsnNode(insnNode) || insnNode instanceof FrameNode) { lastJvmOrFrameInsnIndex = currentInsnIndex; } currentInsnIndex += 1; } } /** * Returns the expanded representation of the given {@link FrameNode}. * * @param owner the internal name of the class to which 'frameNode' belongs. * @param previousFrame the frame before 'frameNode', in expanded form. * @param frameNode a possibly compressed stack map frame. * @return the expanded version of 'frameNode'. * @throws AnalyzerException if 'frameNode' is invalid. */ private Frame expandFrame( final String owner, final Frame previousFrame, final FrameNode frameNode) throws AnalyzerException { Frame frame = newFrame(previousFrame); List locals = frameNode.local == null ? Collections.emptyList() : frameNode.local; int currentLocal = currentLocals; switch (frameNode.type) { case Opcodes.F_NEW: case Opcodes.F_FULL: currentLocal = 0; // fall through case Opcodes.F_APPEND: for (Object type : locals) { V value = newFrameValue(owner, frameNode, type); if (currentLocal + value.getSize() > frame.getLocals()) { throw new AnalyzerException(frameNode, "Cannot append more locals than maxLocals"); } frame.setLocal(currentLocal++, value); if (value.getSize() == 2) { frame.setLocal(currentLocal++, interpreter.newValue(null)); } } break; case Opcodes.F_CHOP: for (Object unusedType : locals) { if (currentLocal <= 0) { throw new AnalyzerException(frameNode, "Cannot chop more locals than defined"); } if (currentLocal > 1 && frame.getLocal(currentLocal - 2).getSize() == 2) { currentLocal -= 2; } else { currentLocal -= 1; } } break; case Opcodes.F_SAME: case Opcodes.F_SAME1: break; default: throw new AnalyzerException(frameNode, "Illegal frame type " + frameNode.type); } currentLocals = currentLocal; while (currentLocal < frame.getLocals()) { frame.setLocal(currentLocal++, interpreter.newValue(null)); } List stack = frameNode.stack == null ? Collections.emptyList() : frameNode.stack; frame.clearStack(); for (Object type : stack) { frame.push(newFrameValue(owner, frameNode, type)); } return frame; } /** * Creates a new {@link Value} that represents the given stack map frame type. * * @param owner the internal name of the class to which 'frameNode' belongs. * @param frameNode the stack map frame to which 'type' belongs. * @param type an Integer, String or LabelNode object representing a primitive, reference or * uninitialized a stack map frame type, respectively. See {@link FrameNode}. * @return a value that represents the given type. * @throws AnalyzerException if 'type' is an invalid stack map frame type. */ private V newFrameValue(final String owner, final FrameNode frameNode, final Object type) throws AnalyzerException { if (type == Opcodes.TOP) { return interpreter.newValue(null); } else if (type == Opcodes.INTEGER) { return interpreter.newValue(Type.INT_TYPE); } else if (type == Opcodes.FLOAT) { return interpreter.newValue(Type.FLOAT_TYPE); } else if (type == Opcodes.LONG) { return interpreter.newValue(Type.LONG_TYPE); } else if (type == Opcodes.DOUBLE) { return interpreter.newValue(Type.DOUBLE_TYPE); } else if (type == Opcodes.NULL) { return interpreter.newOperation(new InsnNode(Opcodes.ACONST_NULL)); } else if (type == Opcodes.UNINITIALIZED_THIS) { return interpreter.newValue(Type.getObjectType(owner)); } else if (type instanceof String) { return interpreter.newValue(Type.getObjectType((String) type)); } else if (type instanceof LabelNode) { AbstractInsnNode referencedNode = (LabelNode) type; while (referencedNode != null && !isJvmInsnNode(referencedNode)) { referencedNode = referencedNode.getNext(); } if (referencedNode == null || referencedNode.getOpcode() != Opcodes.NEW) { throw new AnalyzerException(frameNode, "LabelNode does not designate a NEW instruction"); } return interpreter.newValue(Type.getObjectType(((TypeInsnNode) referencedNode).desc)); } throw new AnalyzerException(frameNode, "Illegal stack map frame value " + type); } /** * Checks that the given frame is compatible with the frame at the given instruction index, if * any. If there is no frame at this instruction index and none is required, the frame at * 'insnIndex' is set to the given frame. Otherwise, if the merge of the two frames is not equal * to the current frame at 'insnIndex', an exception is thrown. * * @param insnIndex an instruction index. * @param frame a frame. This frame is left unchanged by this method. * @param requireFrame whether a frame must already exist or not in {@link #frames} at * 'insnIndex'. * @throws AnalyzerException if the frames have incompatible sizes or if the frame at 'insnIndex' * is missing (if required) or not compatible with 'frame'. */ private void checkFrame(final int insnIndex, final Frame frame, final boolean requireFrame) throws AnalyzerException { Frame oldFrame = getFrames()[insnIndex]; if (oldFrame == null) { if (requireFrame) { throw new AnalyzerException(null, "Expected stack map frame at instruction " + insnIndex); } getFrames()[insnIndex] = newFrame(frame); } else { String error = checkMerge(frame, oldFrame); if (error != null) { throw new AnalyzerException( null, "Stack map frame incompatible with frame at instruction " + insnIndex + " (" + error + ")"); } } } /** * Checks that merging the two given frames would not produce any change, i.e. that the types in * the source frame are sub types of the corresponding types in the destination frame. * * @param srcFrame a source frame. This frame is left unchanged by this method. * @param dstFrame a destination frame. This frame is left unchanged by this method. * @return an error message if the frames have incompatible sizes, or if a type in the source * frame is not a sub type of the corresponding type in the destination frame. Returns * {@literal null} otherwise. */ private String checkMerge(final Frame srcFrame, final Frame dstFrame) { int numLocals = srcFrame.getLocals(); if (numLocals != dstFrame.getLocals()) { throw new AssertionError(); } for (int i = 0; i < numLocals; ++i) { V v = interpreter.merge(srcFrame.getLocal(i), dstFrame.getLocal(i)); if (!v.equals(dstFrame.getLocal(i))) { return "incompatible types at local " + i + ": " + srcFrame.getLocal(i) + " and " + dstFrame.getLocal(i); } } int numStack = srcFrame.getStackSize(); if (numStack != dstFrame.getStackSize()) { return "incompatible stack heights"; } for (int i = 0; i < numStack; ++i) { V v = interpreter.merge(srcFrame.getStack(i), dstFrame.getStack(i)); if (!v.equals(dstFrame.getStack(i))) { return "incompatible types at stack item " + i + ": " + srcFrame.getStack(i) + " and " + dstFrame.getStack(i); } } return null; } /** * Ends the control flow graph at the given instruction. This method checks that there is an * existing frame for the next instruction, if any. * * @param insnIndex an instruction index. * @throws AnalyzerException if 'insnIndex' is not the last instruction and there is no frame at * 'insnIndex' + 1 in {@link #getFrames}. */ private void endControlFlow(final int insnIndex) throws AnalyzerException { if (hasNextJvmInsnOrFrame(insnIndex) && getFrames()[insnIndex + 1] == null) { throw new AnalyzerException( null, "Expected stack map frame at instruction " + (insnIndex + 1)); } } /** * Returns true if the given instruction is followed by a JVM instruction or a by stack map frame. * * @param insnIndex an instruction index. * @return true if 'insnIndex' is followed by a JVM instruction or a by stack map frame. */ private boolean hasNextJvmInsnOrFrame(final int insnIndex) { AbstractInsnNode insn = insnList.get(insnIndex).getNext(); while (insn != null) { if (isJvmInsnNode(insn) || insn instanceof FrameNode) { return true; } insn = insn.getNext(); } return false; } /** * Returns true if the given instruction node corresponds to a real JVM instruction. * * @param insnNode an instruction node. * @return true except for label, line number and stack map frame nodes. */ private static boolean isJvmInsnNode(final AbstractInsnNode insnNode) { return insnNode.getOpcode() >= 0; } }