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/*
 * Javassist, a Java-bytecode translator toolkit.
 * Copyright (C) 1999- Shigeru Chiba. All Rights Reserved.
 *
 * The contents of this file are subject to the Mozilla Public License Version
 * 1.1 (the "License"); you may not use this file except in compliance with
 * the License.  Alternatively, the contents of this file may be used under
 * the terms of the GNU Lesser General Public License Version 2.1 or later,
 * or the Apache License Version 2.0.
 *
 * Software distributed under the License is distributed on an "AS IS" basis,
 * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
 * for the specific language governing rights and limitations under the
 * License.
 */

package javassist.bytecode;

import java.util.ArrayList;

/**
 * An iterator for editing a code attribute.
 *
 * 

To directly read or edit a bytecode sequence, call {@link #byteAt(int)}, {@link #s16bitAt(int)}, * {@link #writeByte(int, int)}, {@link #write16bit(int, int)}, and other methods. * For example, if method refers to a CtMethod object, * the following code substitutes the NOP instruction for the first * instruction of the method: * *

 * CodeAttribute ca = method.getMethodInfo().getCodeAttribute();
 * CodeIterator ci = ca.iterator();
 * ci.writeByte(Opcode.NOP, 0);
* *

To visit every instruction, call {@link #next()} on a CodeIterator. * It returns the index of the first byte of the next instruction. * *

If there are multiple CodeIterators referring to the * same Code_attribute, then inserting a gap by one * CodeIterator will break the other * CodeIterator. * *

This iterator does not provide remove(). * If a piece of code in a Code_attribute is unnecessary, * it should be overwritten with NOP. * * @see CodeAttribute#iterator() */ public class CodeIterator implements Opcode { protected CodeAttribute codeAttr; protected byte[] bytecode; protected int endPos; protected int currentPos; protected int mark; protected CodeIterator(CodeAttribute ca) { codeAttr = ca; bytecode = ca.getCode(); begin(); } /** * Moves to the first instruction. */ public void begin() { currentPos = mark = 0; endPos = getCodeLength(); } /** * Moves to the given index. * *

The index of the next instruction is set to the given index. * The successive call to next() * returns the index that has been given to move(). * *

Note that the index is into the byte array returned by * get().getCode(). * * @see CodeAttribute#getCode() */ public void move(int index) { currentPos = index; } /** * Sets a mark to the bytecode at the given index. * The mark can be used to track the position of that bytecode * when code blocks are inserted. * If a code block is inclusively inserted at the position of the * bytecode, the mark is set to the inserted code block. * * @see #getMark() * @since 3.11 */ public void setMark(int index) { mark = index; } /** * Gets the index of the position of the mark set by * setMark. * * @return the index of the position. * @see #setMark(int) * @since 3.11 */ public int getMark() { return mark; } /** * Returns a Code attribute read with this iterator. */ public CodeAttribute get() { return codeAttr; } /** * Returns code_length of Code_attribute. */ public int getCodeLength() { return bytecode.length; } /** * Returns the unsigned 8bit value at the given index. */ public int byteAt(int index) { return bytecode[index] & 0xff; } /** * Returns the signed 8bit value at the given index. */ public int signedByteAt(int index) { return bytecode[index]; } /** * Writes an 8bit value at the given index. */ public void writeByte(int value, int index) { bytecode[index] = (byte)value; } /** * Returns the unsigned 16bit value at the given index. */ public int u16bitAt(int index) { return ByteArray.readU16bit(bytecode, index); } /** * Returns the signed 16bit value at the given index. */ public int s16bitAt(int index) { return ByteArray.readS16bit(bytecode, index); } /** * Writes a 16 bit integer at the index. */ public void write16bit(int value, int index) { ByteArray.write16bit(value, bytecode, index); } /** * Returns the signed 32bit value at the given index. */ public int s32bitAt(int index) { return ByteArray.read32bit(bytecode, index); } /** * Writes a 32bit integer at the index. */ public void write32bit(int value, int index) { ByteArray.write32bit(value, bytecode, index); } /** * Writes a byte array at the index. * * @param code may be a zero-length array. */ public void write(byte[] code, int index) { int len = code.length; for (int j = 0; j < len; ++j) bytecode[index++] = code[j]; } /** * Returns true if there is more instructions. */ public boolean hasNext() { return currentPos < endPos; } /** * Returns the index of the next instruction * (not the operand following the current opcode). * *

Note that the index is into the byte array returned by * get().getCode(). * * @see CodeAttribute#getCode() * @see CodeIterator#byteAt(int) */ public int next() throws BadBytecode { int pos = currentPos; currentPos = nextOpcode(bytecode, pos); return pos; } /** * Obtains the value that the next call * to next() will return. * *

This method is side-effects free. * Successive calls to lookAhead() return the * same value until next() is called. */ public int lookAhead() { return currentPos; } /** * Moves to the instruction for * either super() or this(). * *

This method skips all the instructions for computing arguments * to super() or this(), which should be * placed at the beginning of a constructor body. * *

This method returns the index of INVOKESPECIAL instruction * executing super() or this(). * A successive call to next() returns the * index of the next instruction following that INVOKESPECIAL. * *

This method works only for a constructor. * * @return the index of the INVOKESPECIAL instruction, or -1 * if a constructor invocation is not found. */ public int skipConstructor() throws BadBytecode { return skipSuperConstructor0(-1); } /** * Moves to the instruction for super(). * *

This method skips all the instructions for computing arguments to * super(), which should be * placed at the beginning of a constructor body. * *

This method returns the index of INVOKESPECIAL instruction * executing super(). * A successive call to next() returns the * index of the next instruction following that INVOKESPECIAL. * *

This method works only for a constructor. * * @return the index of the INVOKESPECIAL instruction, or -1 * if a super constructor invocation is not found * but this() is found. */ public int skipSuperConstructor() throws BadBytecode { return skipSuperConstructor0(0); } /** * Moves to the instruction for this(). * *

This method skips all the instructions for computing arguments to * this(), which should be * placed at the beginning of a constructor body. * *

This method returns the index of INVOKESPECIAL instruction * executing this(). * A successive call to next() returns the * index of the next instruction following that INVOKESPECIAL. * *

This method works only for a constructor. * * @return the index of the INVOKESPECIAL instruction, or -1 * if a explicit constructor invocation is not found * but super() is found. */ public int skipThisConstructor() throws BadBytecode { return skipSuperConstructor0(1); } /* skipSuper 1: this(), 0: super(), -1: both. */ private int skipSuperConstructor0(int skipThis) throws BadBytecode { begin(); ConstPool cp = codeAttr.getConstPool(); String thisClassName = codeAttr.getDeclaringClass(); int nested = 0; while (hasNext()) { int index = next(); int c = byteAt(index); if (c == NEW) ++nested; else if (c == INVOKESPECIAL) { int mref = ByteArray.readU16bit(bytecode, index + 1); if (cp.getMethodrefName(mref).equals(MethodInfo.nameInit)) if (--nested < 0) { if (skipThis < 0) return index; String cname = cp.getMethodrefClassName(mref); if (cname.equals(thisClassName) == (skipThis > 0)) return index; else break; } } } begin(); return -1; } /** * Inserts the given bytecode sequence * before the next instruction that would be returned by * next() (not before the instruction returned * by the last call to next()). * Branch offsets and the exception table are also updated. * *

If the next instruction is at the beginning of a block statement, * then the bytecode is inserted within that block. * *

An extra gap may be inserted at the end of the inserted * bytecode sequence for adjusting alignment if the code attribute * includes LOOKUPSWITCH or TABLESWITCH. * * @param code inserted bytecode sequence. * @return the index indicating the first byte of the * inserted byte sequence. */ public int insert(byte[] code) throws BadBytecode { return insert0(currentPos, code, false); } /** * Inserts the given bytecode sequence * before the instruction at the given index pos. * Branch offsets and the exception table are also updated. * *

If the instruction at the given index is at the beginning * of a block statement, * then the bytecode is inserted within that block. * *

An extra gap may be inserted at the end of the inserted * bytecode sequence for adjusting alignment if the code attribute * includes LOOKUPSWITCH or TABLESWITCH. * *

The index at which the byte sequence is actually inserted * might be different from pos since some other bytes might be * inserted at other positions (e.g. to change GOTO * to GOTO_W). * * @param pos the index at which a byte sequence is inserted. * @param code inserted bytecode sequence. */ public void insert(int pos, byte[] code) throws BadBytecode { insert0(pos, code, false); } /** * Inserts the given bytecode sequence * before the instruction at the given index pos. * Branch offsets and the exception table are also updated. * *

If the instruction at the given index is at the beginning * of a block statement, * then the bytecode is inserted within that block. * *

An extra gap may be inserted at the end of the inserted * bytecode sequence for adjusting alignment if the code attribute * includes LOOKUPSWITCH or TABLESWITCH. * * @param pos the index at which a byte sequence is inserted. * @param code inserted bytecode sequence. * @return the index indicating the first byte of the * inserted byte sequence, which might be * different from pos. * @since 3.11 */ public int insertAt(int pos, byte[] code) throws BadBytecode { return insert0(pos, code, false); } /** * Inserts the given bytecode sequence exclusively * before the next instruction that would be returned by * next() (not before the instruction returned * by tha last call to next()). * Branch offsets and the exception table are also updated. * *

If the next instruction is at the beginning of a block statement, * then the bytecode is excluded from that block. * *

An extra gap may be inserted at the end of the inserted * bytecode sequence for adjusting alignment if the code attribute * includes LOOKUPSWITCH or TABLESWITCH. * * @param code inserted bytecode sequence. * @return the index indicating the first byte of the * inserted byte sequence. */ public int insertEx(byte[] code) throws BadBytecode { return insert0(currentPos, code, true); } /** * Inserts the given bytecode sequence exclusively * before the instruction at the given index pos. * Branch offsets and the exception table are also updated. * *

If the instruction at the given index is at the beginning * of a block statement, * then the bytecode is excluded from that block. * *

An extra gap may be inserted at the end of the inserted * bytecode sequence for adjusting alignment if the code attribute * includes LOOKUPSWITCH or TABLESWITCH. * *

The index at which the byte sequence is actually inserted * might be different from pos since some other bytes might be * inserted at other positions (e.g. to change GOTO * to GOTO_W). * * @param pos the index at which a byte sequence is inserted. * @param code inserted bytecode sequence. */ public void insertEx(int pos, byte[] code) throws BadBytecode { insert0(pos, code, true); } /** * Inserts the given bytecode sequence exclusively * before the instruction at the given index pos. * Branch offsets and the exception table are also updated. * *

If the instruction at the given index is at the beginning * of a block statement, * then the bytecode is excluded from that block. * *

An extra gap may be inserted at the end of the inserted * bytecode sequence for adjusting alignment if the code attribute * includes LOOKUPSWITCH or TABLESWITCH. * * @param pos the index at which a byte sequence is inserted. * @param code inserted bytecode sequence. * @return the index indicating the first byte of the * inserted byte sequence, which might be * different from pos. * @since 3.11 */ public int insertExAt(int pos, byte[] code) throws BadBytecode { return insert0(pos, code, true); } /** * @return the index indicating the first byte of the * inserted byte sequence. */ private int insert0(int pos, byte[] code, boolean exclusive) throws BadBytecode { int len = code.length; if (len <= 0) return pos; // currentPos will change. pos = insertGapAt(pos, len, exclusive).position; int p = pos; for (int j = 0; j < len; ++j) bytecode[p++] = code[j]; return pos; } /** * Inserts a gap * before the next instruction that would be returned by * next() (not before the instruction returned * by the last call to next()). * Branch offsets and the exception table are also updated. * The inserted gap is filled with NOP. The gap length may be * extended to a multiple of 4. * *

If the next instruction is at the beginning of a block statement, * then the gap is inserted within that block. * * @param length gap length * @return the index indicating the first byte of the inserted gap. */ public int insertGap(int length) throws BadBytecode { return insertGapAt(currentPos, length, false).position; } /** * Inserts a gap in front of the instruction at the given * index pos. * Branch offsets and the exception table are also updated. * The inserted gap is filled with NOP. The gap length may be * extended to a multiple of 4. * *

If the instruction at the given index is at the beginning * of a block statement, * then the gap is inserted within that block. * * @param pos the index at which a gap is inserted. * @param length gap length. * @return the length of the inserted gap. * It might be bigger than length. */ public int insertGap(int pos, int length) throws BadBytecode { return insertGapAt(pos, length, false).length; } /** * Inserts an exclusive gap * before the next instruction that would be returned by * next() (not before the instruction returned * by the last call to next()). * Branch offsets and the exception table are also updated. * The inserted gap is filled with NOP. The gap length may be * extended to a multiple of 4. * *

If the next instruction is at the beginning of a block statement, * then the gap is excluded from that block. * * @param length gap length * @return the index indicating the first byte of the inserted gap. */ public int insertExGap(int length) throws BadBytecode { return insertGapAt(currentPos, length, true).position; } /** * Inserts an exclusive gap in front of the instruction at the given * index pos. * Branch offsets and the exception table are also updated. * The inserted gap is filled with NOP. The gap length may be * extended to a multiple of 4. * *

If the instruction at the given index is at the beginning * of a block statement, * then the gap is excluded from that block. * * @param pos the index at which a gap is inserted. * @param length gap length. * @return the length of the inserted gap. * It might be bigger than length. */ public int insertExGap(int pos, int length) throws BadBytecode { return insertGapAt(pos, length, true).length; } /** * An inserted gap. * * @since 3.11 */ public static class Gap { /** * The position of the gap. */ public int position; /** * The length of the gap. */ public int length; } /** * Inserts an inclusive or exclusive gap in front of the instruction * at the given index pos. * Branch offsets and the exception table in the method body * are also updated. The inserted gap is filled with NOP. * The gap length may be extended to a multiple of 4. * *

Suppose that the instruction at the given index is at the * beginning of a block statement. If the gap is inclusive, * then it is included within that block. If the gap is exclusive, * then it is excluded from that block. * *

The index at which the gap is actually inserted * might be different from pos since some other bytes might be * inserted at other positions (e.g. to change GOTO * to GOTO_W). The index is available from the Gap * object returned by this method. * *

Suppose that the gap is inserted at the position of * the next instruction that would be returned by * next() (not the last instruction returned * by the last call to next()). The next * instruction returned by next() after the gap is * inserted is still the same instruction. It is not NOP * at the first byte of the inserted gap. * * @param pos the index at which a gap is inserted. * @param length gap length. * @param exclusive true if exclusive, otherwise false. * @return the position and the length of the inserted gap. * @since 3.11 */ public Gap insertGapAt(int pos, int length, boolean exclusive) throws BadBytecode { /** * cursorPos indicates the next bytecode whichever exclusive is * true or false. */ Gap gap = new Gap(); if (length <= 0) { gap.position = pos; gap.length = 0; return gap; } byte[] c; int length2; if (bytecode.length + length > Short.MAX_VALUE) { // currentPos might change after calling insertGapCore0w(). c = insertGapCore0w(bytecode, pos, length, exclusive, get().getExceptionTable(), codeAttr, gap); pos = gap.position; length2 = length; // == gap.length } else { int cur = currentPos; c = insertGapCore0(bytecode, pos, length, exclusive, get().getExceptionTable(), codeAttr); // insertGapCore0() never changes pos. length2 = c.length - bytecode.length; gap.position = pos; gap.length = length2; if (cur >= pos) currentPos = cur + length2; if (mark > pos || (mark == pos && exclusive)) mark += length2; } codeAttr.setCode(c); bytecode = c; endPos = getCodeLength(); updateCursors(pos, length2); return gap; } /** * Is called when a gap is inserted. The default implementation is empty. * A subclass can override this method so that cursors will be updated. * * @param pos the position where a gap is inserted. * @param length the length of the gap. */ protected void updateCursors(int pos, int length) { // empty } /** * Copies and inserts the entries in the given exception table * at the beginning of the exception table in the code attribute * edited by this object. * * @param offset the value added to the code positions included * in the entries. */ public void insert(ExceptionTable et, int offset) { codeAttr.getExceptionTable().add(0, et, offset); } /** * Appends the given bytecode sequence at the end. * * @param code the bytecode appended. * @return the position of the first byte of the appended bytecode. */ public int append(byte[] code) { int size = getCodeLength(); int len = code.length; if (len <= 0) return size; appendGap(len); byte[] dest = bytecode; for (int i = 0; i < len; ++i) dest[i + size] = code[i]; return size; } /** * Appends a gap at the end of the bytecode sequence. * * @param gapLength gap length */ public void appendGap(int gapLength) { byte[] code = bytecode; int codeLength = code.length; byte[] newcode = new byte[codeLength + gapLength]; int i; for (i = 0; i < codeLength; ++i) newcode[i] = code[i]; for (i = codeLength; i < codeLength + gapLength; ++i) newcode[i] = NOP; codeAttr.setCode(newcode); bytecode = newcode; endPos = getCodeLength(); } /** * Copies and appends the entries in the given exception table * at the end of the exception table in the code attribute * edited by this object. * * @param offset the value added to the code positions included * in the entries. */ public void append(ExceptionTable et, int offset) { ExceptionTable table = codeAttr.getExceptionTable(); table.add(table.size(), et, offset); } /* opcodeLegth is used for implementing nextOpcode(). */ private static final int opcodeLength[] = { 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 2, 3, 2, 3, 3, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 3, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 2, 0, 0, 1, 1, 1, 1, 1, 1, 3, 3, 3, 3, 3, 3, 3, 5, 5, 3, 2, 3, 1, 1, 3, 3, 1, 1, 0, 4, 3, 3, 5, 5 }; // 0 .. LOOKUPSWITCH, TABLESWITCH, WIDE /** * Calculates the index of the next opcode. */ static int nextOpcode(byte[] code, int index) throws BadBytecode { int opcode; try { opcode = code[index] & 0xff; } catch (IndexOutOfBoundsException e) { throw new BadBytecode("invalid opcode address"); } try { int len = opcodeLength[opcode]; if (len > 0) return index + len; else if (opcode == WIDE) if (code[index + 1] == (byte)IINC) // WIDE IINC return index + 6; else return index + 4; // WIDE ... else { int index2 = (index & ~3) + 8; if (opcode == LOOKUPSWITCH) { int npairs = ByteArray.read32bit(code, index2); return index2 + npairs * 8 + 4; } else if (opcode == TABLESWITCH) { int low = ByteArray.read32bit(code, index2); int high = ByteArray.read32bit(code, index2 + 4); return index2 + (high - low + 1) * 4 + 8; } // else // throw new BadBytecode(opcode); } } catch (IndexOutOfBoundsException e) { } // opcode is UNUSED or an IndexOutOfBoundsException was thrown. throw new BadBytecode(opcode); } // methods for implementing insertGap(). static class AlignmentException extends Exception {} /** * insertGapCore0() inserts a gap (some NOPs). * It cannot handle a long code sequence more than 32K. All branch offsets must be * signed 16bits. * * If "where" is the beginning of a block statement and exclusive is false, * then the inserted gap is also included in the block statement. * "where" must indicate the first byte of an opcode. * The inserted gap is filled with NOP. gapLength may be extended to * a multiple of 4. * * This method was also called from CodeAttribute.LdcEntry.doit(). * * @param where It must indicate the first byte of an opcode. */ static byte[] insertGapCore0(byte[] code, int where, int gapLength, boolean exclusive, ExceptionTable etable, CodeAttribute ca) throws BadBytecode { if (gapLength <= 0) return code; try { return insertGapCore1(code, where, gapLength, exclusive, etable, ca); } catch (AlignmentException e) { try { return insertGapCore1(code, where, (gapLength + 3) & ~3, exclusive, etable, ca); } catch (AlignmentException e2) { throw new RuntimeException("fatal error?"); } } } private static byte[] insertGapCore1(byte[] code, int where, int gapLength, boolean exclusive, ExceptionTable etable, CodeAttribute ca) throws BadBytecode, AlignmentException { int codeLength = code.length; byte[] newcode = new byte[codeLength + gapLength]; insertGap2(code, where, gapLength, codeLength, newcode, exclusive); etable.shiftPc(where, gapLength, exclusive); LineNumberAttribute na = (LineNumberAttribute)ca.getAttribute(LineNumberAttribute.tag); if (na != null) na.shiftPc(where, gapLength, exclusive); LocalVariableAttribute va = (LocalVariableAttribute)ca.getAttribute( LocalVariableAttribute.tag); if (va != null) va.shiftPc(where, gapLength, exclusive); LocalVariableAttribute vta = (LocalVariableAttribute)ca.getAttribute( LocalVariableAttribute.typeTag); if (vta != null) vta.shiftPc(where, gapLength, exclusive); StackMapTable smt = (StackMapTable)ca.getAttribute(StackMapTable.tag); if (smt != null) smt.shiftPc(where, gapLength, exclusive); StackMap sm = (StackMap)ca.getAttribute(StackMap.tag); if (sm != null) sm.shiftPc(where, gapLength, exclusive); return newcode; } private static void insertGap2(byte[] code, int where, int gapLength, int endPos, byte[] newcode, boolean exclusive) throws BadBytecode, AlignmentException { int nextPos; int i = 0; int j = 0; for (; i < endPos; i = nextPos) { if (i == where) { int j2 = j + gapLength; while (j < j2) newcode[j++] = NOP; } nextPos = nextOpcode(code, i); int inst = code[i] & 0xff; // if, if_icmp, if_acmp, goto, jsr if ((153 <= inst && inst <= 168) || inst == IFNULL || inst == IFNONNULL) { /* 2bytes *signed* offset */ int offset = (code[i + 1] << 8) | (code[i + 2] & 0xff); offset = newOffset(i, offset, where, gapLength, exclusive); newcode[j] = code[i]; ByteArray.write16bit(offset, newcode, j + 1); j += 3; } else if (inst == GOTO_W || inst == JSR_W) { /* 4bytes offset */ int offset = ByteArray.read32bit(code, i + 1); offset = newOffset(i, offset, where, gapLength, exclusive); newcode[j++] = code[i]; ByteArray.write32bit(offset, newcode, j); j += 4; } else if (inst == TABLESWITCH) { if (i != j && (gapLength & 3) != 0) throw new AlignmentException(); int i2 = (i & ~3) + 4; // 0-3 byte padding // IBM JVM 1.4.2 cannot run the following code: // int i0 = i; // while (i0 < i2) // newcode[j++] = code[i0++]; // So extracting this code into an external method. // see JIRA JASSIST-74. j = copyGapBytes(newcode, j, code, i, i2); int defaultbyte = newOffset(i, ByteArray.read32bit(code, i2), where, gapLength, exclusive); ByteArray.write32bit(defaultbyte, newcode, j); int lowbyte = ByteArray.read32bit(code, i2 + 4); ByteArray.write32bit(lowbyte, newcode, j + 4); int highbyte = ByteArray.read32bit(code, i2 + 8); ByteArray.write32bit(highbyte, newcode, j + 8); j += 12; int i0 = i2 + 12; i2 = i0 + (highbyte - lowbyte + 1) * 4; while (i0 < i2) { int offset = newOffset(i, ByteArray.read32bit(code, i0), where, gapLength, exclusive); ByteArray.write32bit(offset, newcode, j); j += 4; i0 += 4; } } else if (inst == LOOKUPSWITCH) { if (i != j && (gapLength & 3) != 0) throw new AlignmentException(); int i2 = (i & ~3) + 4; // 0-3 byte padding // IBM JVM 1.4.2 cannot run the following code: // int i0 = i; // while (i0 < i2) // newcode[j++] = code[i0++]; // So extracting this code into an external method. // see JIRA JASSIST-74. j = copyGapBytes(newcode, j, code, i, i2); int defaultbyte = newOffset(i, ByteArray.read32bit(code, i2), where, gapLength, exclusive); ByteArray.write32bit(defaultbyte, newcode, j); int npairs = ByteArray.read32bit(code, i2 + 4); ByteArray.write32bit(npairs, newcode, j + 4); j += 8; int i0 = i2 + 8; i2 = i0 + npairs * 8; while (i0 < i2) { ByteArray.copy32bit(code, i0, newcode, j); int offset = newOffset(i, ByteArray.read32bit(code, i0 + 4), where, gapLength, exclusive); ByteArray.write32bit(offset, newcode, j + 4); j += 8; i0 += 8; } } else while (i < nextPos) newcode[j++] = code[i++]; } } private static int copyGapBytes(byte[] newcode, int j, byte[] code, int i, int iEnd) { switch (iEnd - i) { case 4: newcode[j++] = code[i++]; case 3: newcode[j++] = code[i++]; case 2: newcode[j++] = code[i++]; case 1: newcode[j++] = code[i++]; default: } return j; } private static int newOffset(int i, int offset, int where, int gapLength, boolean exclusive) { int target = i + offset; if (i < where) { if (where < target || (exclusive && where == target)) offset += gapLength; } else if (i == where) { // This code is different from the code in Branch#shiftOffset(). // see JASSIST-124. if (target < where) offset -= gapLength; } else if (target < where || (!exclusive && where == target)) offset -= gapLength; return offset; } static class Pointers { int cursor; int mark0, mark; ExceptionTable etable; LineNumberAttribute line; LocalVariableAttribute vars, types; StackMapTable stack; StackMap stack2; Pointers(int cur, int m, int m0, ExceptionTable et, CodeAttribute ca) { cursor = cur; mark = m; mark0 = m0; etable = et; // non null line = (LineNumberAttribute)ca.getAttribute(LineNumberAttribute.tag); vars = (LocalVariableAttribute)ca.getAttribute(LocalVariableAttribute.tag); types = (LocalVariableAttribute)ca.getAttribute(LocalVariableAttribute.typeTag); stack = (StackMapTable)ca.getAttribute(StackMapTable.tag); stack2 = (StackMap)ca.getAttribute(StackMap.tag); } void shiftPc(int where, int gapLength, boolean exclusive) throws BadBytecode { if (where < cursor || (where == cursor && exclusive)) cursor += gapLength; if (where < mark || (where == mark && exclusive)) mark += gapLength; if (where < mark0 || (where == mark0 && exclusive)) mark0 += gapLength; etable.shiftPc(where, gapLength, exclusive); if (line != null) line.shiftPc(where, gapLength, exclusive); if (vars != null) vars.shiftPc(where, gapLength, exclusive); if (types != null) types.shiftPc(where, gapLength, exclusive); if (stack != null) stack.shiftPc(where, gapLength, exclusive); if (stack2 != null) stack2.shiftPc(where, gapLength, exclusive); } void shiftForSwitch(int where, int gapLength) throws BadBytecode { if (stack != null) stack.shiftForSwitch(where, gapLength); if (stack2 != null) stack2.shiftForSwitch(where, gapLength); } } /* * This method is called from CodeAttribute.LdcEntry.doit(). */ static byte[] changeLdcToLdcW(byte[] code, ExceptionTable etable, CodeAttribute ca, CodeAttribute.LdcEntry ldcs) throws BadBytecode { Pointers pointers = new Pointers(0, 0, 0, etable, ca); ArrayList jumps = makeJumpList(code, code.length, pointers); while (ldcs != null) { addLdcW(ldcs, jumps); ldcs = ldcs.next; } byte[] r = insertGap2w(code, 0, 0, false, jumps, pointers); return r; } private static void addLdcW(CodeAttribute.LdcEntry ldcs, ArrayList jumps) { int where = ldcs.where; LdcW ldcw = new LdcW(where, ldcs.index); int s = jumps.size(); for (int i = 0; i < s; i++) if (where < ((Branch)jumps.get(i)).orgPos) { jumps.add(i, ldcw); return; } jumps.add(ldcw); } /* * insertGapCore0w() can handle a long code sequence more than 32K. * It guarantees that the length of the inserted gap (NOPs) is equal to * gapLength. No other NOPs except some NOPs following TABLESWITCH or * LOOKUPSWITCH will not be inserted. * * Note: currentPos might be moved. * * @param where It must indicate the first byte of an opcode. * @param newWhere It contains the updated index of the position where a gap * is inserted and the length of the gap. * It must not be null. */ private byte[] insertGapCore0w(byte[] code, int where, int gapLength, boolean exclusive, ExceptionTable etable, CodeAttribute ca, Gap newWhere) throws BadBytecode { if (gapLength <= 0) return code; Pointers pointers = new Pointers(currentPos, mark, where, etable, ca); ArrayList jumps = makeJumpList(code, code.length, pointers); byte[] r = insertGap2w(code, where, gapLength, exclusive, jumps, pointers); currentPos = pointers.cursor; mark = pointers.mark; int where2 = pointers.mark0; if (where2 == currentPos && !exclusive) currentPos += gapLength; if (exclusive) where2 -= gapLength; newWhere.position = where2; newWhere.length = gapLength; return r; } private static byte[] insertGap2w(byte[] code, int where, int gapLength, boolean exclusive, ArrayList jumps, Pointers ptrs) throws BadBytecode { int n = jumps.size(); if (gapLength > 0) { ptrs.shiftPc(where, gapLength, exclusive); for (int i = 0; i < n; i++) ((Branch)jumps.get(i)).shift(where, gapLength, exclusive); } boolean unstable = true; do { while (unstable) { unstable = false; for (int i = 0; i < n; i++) { Branch b = (Branch)jumps.get(i); if (b.expanded()) { unstable = true; int p = b.pos; int delta = b.deltaSize(); ptrs.shiftPc(p, delta, false); for (int j = 0; j < n; j++) ((Branch)jumps.get(j)).shift(p, delta, false); } } } for (int i = 0; i < n; i++) { Branch b = (Branch)jumps.get(i); int diff = b.gapChanged(); if (diff > 0) { unstable = true; int p = b.pos; ptrs.shiftPc(p, diff, false); for (int j = 0; j < n; j++) ((Branch)jumps.get(j)).shift(p, diff, false); } } } while (unstable); return makeExapndedCode(code, jumps, where, gapLength); } private static ArrayList makeJumpList(byte[] code, int endPos, Pointers ptrs) throws BadBytecode { ArrayList jumps = new ArrayList(); int nextPos; for (int i = 0; i < endPos; i = nextPos) { nextPos = nextOpcode(code, i); int inst = code[i] & 0xff; // if, if_icmp, if_acmp, goto, jsr if ((153 <= inst && inst <= 168) || inst == IFNULL || inst == IFNONNULL) { /* 2bytes *signed* offset */ int offset = (code[i + 1] << 8) | (code[i + 2] & 0xff); Branch b; if (inst == GOTO || inst == JSR) b = new Jump16(i, offset); else b = new If16(i, offset); jumps.add(b); } else if (inst == GOTO_W || inst == JSR_W) { /* 4bytes offset */ int offset = ByteArray.read32bit(code, i + 1); jumps.add(new Jump32(i, offset)); } else if (inst == TABLESWITCH) { int i2 = (i & ~3) + 4; // 0-3 byte padding int defaultbyte = ByteArray.read32bit(code, i2); int lowbyte = ByteArray.read32bit(code, i2 + 4); int highbyte = ByteArray.read32bit(code, i2 + 8); int i0 = i2 + 12; int size = highbyte - lowbyte + 1; int[] offsets = new int[size]; for (int j = 0; j < size; j++) { offsets[j] = ByteArray.read32bit(code, i0); i0 += 4; } jumps.add(new Table(i, defaultbyte, lowbyte, highbyte, offsets, ptrs)); } else if (inst == LOOKUPSWITCH) { int i2 = (i & ~3) + 4; // 0-3 byte padding int defaultbyte = ByteArray.read32bit(code, i2); int npairs = ByteArray.read32bit(code, i2 + 4); int i0 = i2 + 8; int[] matches = new int[npairs]; int[] offsets = new int[npairs]; for (int j = 0; j < npairs; j++) { matches[j] = ByteArray.read32bit(code, i0); offsets[j] = ByteArray.read32bit(code, i0 + 4); i0 += 8; } jumps.add(new Lookup(i, defaultbyte, matches, offsets, ptrs)); } } return jumps; } private static byte[] makeExapndedCode(byte[] code, ArrayList jumps, int where, int gapLength) throws BadBytecode { int n = jumps.size(); int size = code.length + gapLength; for (int i = 0; i < n; i++) { Branch b = (Branch)jumps.get(i); size += b.deltaSize(); } byte[] newcode = new byte[size]; int src = 0, dest = 0, bindex = 0; int len = code.length; Branch b; int bpos; if (0 < n) { b = (Branch)jumps.get(0); bpos = b.orgPos; } else { b = null; bpos = len; // src will be never equal to bpos } while (src < len) { if (src == where) { int pos2 = dest + gapLength; while (dest < pos2) newcode[dest++] = NOP; } if (src != bpos) newcode[dest++] = code[src++]; else { int s = b.write(src, code, dest, newcode); src += s; dest += s + b.deltaSize(); if (++bindex < n) { b = (Branch)jumps.get(bindex); bpos = b.orgPos; } else { b = null; bpos = len; } } } return newcode; } static abstract class Branch { int pos, orgPos; Branch(int p) { pos = orgPos = p; } void shift(int where, int gapLength, boolean exclusive) { if (where < pos || (where == pos && exclusive)) pos += gapLength; } static int shiftOffset(int i, int offset, int where, int gapLength, boolean exclusive) { int target = i + offset; if (i < where) { if (where < target || (exclusive && where == target)) offset += gapLength; } else if (i == where) { // This code is different from the code in CodeIterator#newOffset(). // see JASSIST-124. if (target < where && exclusive) offset -= gapLength; else if (where < target && !exclusive) offset += gapLength; } else if (target < where || (!exclusive && where == target)) offset -= gapLength; return offset; } boolean expanded() { return false; } int gapChanged() { return 0; } int deltaSize() { return 0; } // newSize - oldSize // This returns the original instruction size. abstract int write(int srcPos, byte[] code, int destPos, byte[] newcode) throws BadBytecode; } /* used by changeLdcToLdcW() and CodeAttribute.LdcEntry. */ static class LdcW extends Branch { int index; boolean state; LdcW(int p, int i) { super(p); index = i; state = true; } boolean expanded() { if (state) { state = false; return true; } else return false; } int deltaSize() { return 1; } int write(int srcPos, byte[] code, int destPos, byte[] newcode) { newcode[destPos] = LDC_W; ByteArray.write16bit(index, newcode, destPos + 1); return 2; } } static abstract class Branch16 extends Branch { int offset; int state; static final int BIT16 = 0; static final int EXPAND = 1; static final int BIT32 = 2; Branch16(int p, int off) { super(p); offset = off; state = BIT16; } void shift(int where, int gapLength, boolean exclusive) { offset = shiftOffset(pos, offset, where, gapLength, exclusive); super.shift(where, gapLength, exclusive); if (state == BIT16) if (offset < Short.MIN_VALUE || Short.MAX_VALUE < offset) state = EXPAND; } boolean expanded() { if (state == EXPAND) { state = BIT32; return true; } else return false; } abstract int deltaSize(); abstract void write32(int src, byte[] code, int dest, byte[] newcode); int write(int src, byte[] code, int dest, byte[] newcode) { if (state == BIT32) write32(src, code, dest, newcode); else { newcode[dest] = code[src]; ByteArray.write16bit(offset, newcode, dest + 1); } return 3; } } // GOTO or JSR static class Jump16 extends Branch16 { Jump16(int p, int off) { super(p, off); } int deltaSize() { return state == BIT32 ? 2 : 0; } void write32(int src, byte[] code, int dest, byte[] newcode) { newcode[dest] = (byte)(((code[src] & 0xff) == GOTO) ? GOTO_W : JSR_W); ByteArray.write32bit(offset, newcode, dest + 1); } } // if, if_icmp, or if_acmp static class If16 extends Branch16 { If16(int p, int off) { super(p, off); } int deltaSize() { return state == BIT32 ? 5 : 0; } void write32(int src, byte[] code, int dest, byte[] newcode) { newcode[dest] = (byte)opcode(code[src] & 0xff); newcode[dest + 1] = 0; newcode[dest + 2] = 8; // branch_offset = 8 newcode[dest + 3] = (byte)GOTO_W; ByteArray.write32bit(offset - 3, newcode, dest + 4); } int opcode(int op) { if (op == IFNULL) return IFNONNULL; else if (op == IFNONNULL) return IFNULL; else { if (((op - IFEQ) & 1) == 0) return op + 1; else return op - 1; } } } static class Jump32 extends Branch { int offset; Jump32(int p, int off) { super(p); offset = off; } void shift(int where, int gapLength, boolean exclusive) { offset = shiftOffset(pos, offset, where, gapLength, exclusive); super.shift(where, gapLength, exclusive); } int write(int src, byte[] code, int dest, byte[] newcode) { newcode[dest] = code[src]; ByteArray.write32bit(offset, newcode, dest + 1); return 5; } } static abstract class Switcher extends Branch { int gap, defaultByte; int[] offsets; Pointers pointers; Switcher(int pos, int defaultByte, int[] offsets, Pointers ptrs) { super(pos); this.gap = 3 - (pos & 3); this.defaultByte = defaultByte; this.offsets = offsets; this.pointers = ptrs; } void shift(int where, int gapLength, boolean exclusive) { int p = pos; defaultByte = shiftOffset(p, defaultByte, where, gapLength, exclusive); int num = offsets.length; for (int i = 0; i < num; i++) offsets[i] = shiftOffset(p, offsets[i], where, gapLength, exclusive); super.shift(where, gapLength, exclusive); } int gapChanged() { int newGap = 3 - (pos & 3); if (newGap > gap) { int diff = newGap - gap; gap = newGap; return diff; } return 0; } int deltaSize() { return gap - (3 - (orgPos & 3)); } int write(int src, byte[] code, int dest, byte[] newcode) throws BadBytecode { int padding = 3 - (pos & 3); int nops = gap - padding; int bytecodeSize = 5 + (3 - (orgPos & 3)) + tableSize(); if (nops > 0) adjustOffsets(bytecodeSize, nops); newcode[dest++] = code[src]; while (padding-- > 0) newcode[dest++] = 0; ByteArray.write32bit(defaultByte, newcode, dest); int size = write2(dest + 4, newcode); dest += size + 4; while (nops-- > 0) newcode[dest++] = NOP; return 5 + (3 - (orgPos & 3)) + size; } abstract int write2(int dest, byte[] newcode); abstract int tableSize(); /* If the new bytecode size is shorter than the original, some NOPs * are appended after this branch instruction (tableswitch or * lookupswitch) to fill the gap. * This method changes a branch offset to point to the first NOP * if the offset originally points to the bytecode next to this * branch instruction. Otherwise, the bytecode would contain * dead code. It complicates the generation of StackMap and * StackMapTable. */ void adjustOffsets(int size, int nops) throws BadBytecode { pointers.shiftForSwitch(pos + size, nops); if (defaultByte == size) defaultByte -= nops; for (int i = 0; i < offsets.length; i++) if (offsets[i] == size) offsets[i] -= nops; } } static class Table extends Switcher { int low, high; Table(int pos, int defaultByte, int low, int high, int[] offsets, Pointers ptrs) { super(pos, defaultByte, offsets, ptrs); this.low = low; this.high = high; } int write2(int dest, byte[] newcode) { ByteArray.write32bit(low, newcode, dest); ByteArray.write32bit(high, newcode, dest + 4); int n = offsets.length; dest += 8; for (int i = 0; i < n; i++) { ByteArray.write32bit(offsets[i], newcode, dest); dest += 4; } return 8 + 4 * n; } int tableSize() { return 8 + 4 * offsets.length; } } static class Lookup extends Switcher { int[] matches; Lookup(int pos, int defaultByte, int[] matches, int[] offsets, Pointers ptrs) { super(pos, defaultByte, offsets, ptrs); this.matches = matches; } int write2(int dest, byte[] newcode) { int n = matches.length; ByteArray.write32bit(n, newcode, dest); dest += 4; for (int i = 0; i < n; i++) { ByteArray.write32bit(matches[i], newcode, dest); ByteArray.write32bit(offsets[i], newcode, dest + 4); dest += 8; } return 4 + 8 * n; } int tableSize() { return 4 + 8 * matches.length; } } }





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