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 CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
/*** * 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 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */
package org.objectweb.asm;
Information about the input and output stack map frames of a basic block.
Author:Eric Bruneton
/** * Information about the input and output stack map frames of a basic block. * * @author Eric Bruneton */
class Frame { /* * Frames are computed in a two steps process: during the visit of each * instruction, the state of the frame at the end of current basic block is * updated by simulating the action of the instruction on the previous state * of this so called "output frame". In visitMaxs, a fix point algorithm is * used to compute the "input frame" of each basic block, i.e. the stack map * frame at the beginning of the basic block, starting from the input frame * of the first basic block (which is computed from the method descriptor), * and by using the previously computed output frames to compute the input * state of the other blocks. * * All output and input frames are stored as arrays of integers. Reference * and array types are represented by an index into a type table (which is * not the same as the constant pool of the class, in order to avoid adding * unnecessary constants in the pool - not all computed frames will end up * being stored in the stack map table). This allows very fast type * comparisons. * * Output stack map frames are computed relatively to the input frame of the * basic block, which is not yet known when output frames are computed. It * is therefore necessary to be able to represent abstract types such as * "the type at position x in the input frame locals" or "the type at * position x from the top of the input frame stack" or even "the type at * position x in the input frame, with y more (or less) array dimensions". * This explains the rather complicated type format used in output frames. * * This format is the following: DIM KIND VALUE (4, 4 and 24 bits). DIM is a * signed number of array dimensions (from -8 to 7). KIND is either BASE, * LOCAL or STACK. BASE is used for types that are not relative to the input * frame. LOCAL is used for types that are relative to the input local * variable types. STACK is used for types that are relative to the input * stack types. VALUE depends on KIND. For LOCAL types, it is an index in * the input local variable types. For STACK types, it is a position * relatively to the top of input frame stack. For BASE types, it is either * one of the constants defined below, or for OBJECT and UNINITIALIZED * types, a tag and an index in the type table. * * Output frames can contain types of any kind and with a positive or * negative dimension (and even unassigned types, represented by 0 - which * does not correspond to any valid type value). Input frames can only * contain BASE types of positive or null dimension. In all cases the type * table contains only internal type names (array type descriptors are * forbidden - dimensions must be represented through the DIM field). * * The LONG and DOUBLE types are always represented by using two slots (LONG * + TOP or DOUBLE + TOP), for local variable types as well as in the * operand stack. This is necessary to be able to simulate DUPx_y * instructions, whose effect would be dependent on the actual type values * if types were always represented by a single slot in the stack (and this * is not possible, since actual type values are not always known - cf LOCAL * and STACK type kinds). */
Mask to get the dimension of a frame type. This dimension is a signed integer between -8 and 7.
/** * Mask to get the dimension of a frame type. This dimension is a signed * integer between -8 and 7. */
static final int DIM = 0xF0000000;
Constant to be added to a type to get a type with one more dimension.
/** * Constant to be added to a type to get a type with one more dimension. */
static final int ARRAY_OF = 0x10000000;
Constant to be added to a type to get a type with one less dimension.
/** * Constant to be added to a type to get a type with one less dimension. */
static final int ELEMENT_OF = 0xF0000000;
Mask to get the kind of a frame type.
See Also:
/** * Mask to get the kind of a frame type. * * @see #BASE * @see #LOCAL * @see #STACK */
static final int KIND = 0xF000000;
Flag used for LOCAL and STACK types. Indicates that if this type happens to be a long or double type (during the computations of input frames), then it must be set to TOP because the second word of this value has been reused to store other data in the basic block. Hence the first word no longer stores a valid long or double value.
/** * Flag used for LOCAL and STACK types. Indicates that if this type happens * to be a long or double type (during the computations of input frames), * then it must be set to TOP because the second word of this value has been * reused to store other data in the basic block. Hence the first word no * longer stores a valid long or double value. */
static final int TOP_IF_LONG_OR_DOUBLE = 0x800000;
Mask to get the value of a frame type.
/** * Mask to get the value of a frame type. */
static final int VALUE = 0x7FFFFF;
Mask to get the kind of base types.
/** * Mask to get the kind of base types. */
static final int BASE_KIND = 0xFF00000;
Mask to get the value of base types.
/** * Mask to get the value of base types. */
static final int BASE_VALUE = 0xFFFFF;
Kind of the types that are not relative to an input stack map frame.
/** * Kind of the types that are not relative to an input stack map frame. */
static final int BASE = 0x1000000;
Base kind of the base reference types. The BASE_VALUE of such types is an index into the type table.
/** * Base kind of the base reference types. The BASE_VALUE of such types is an * index into the type table. */
static final int OBJECT = BASE | 0x700000;
Base kind of the uninitialized base types. The BASE_VALUE of such types in an index into the type table (the Item at that index contains both an instruction offset and an internal class name).
/** * Base kind of the uninitialized base types. The BASE_VALUE of such types * in an index into the type table (the Item at that index contains both an * instruction offset and an internal class name). */
static final int UNINITIALIZED = BASE | 0x800000;
Kind of the types that are relative to the local variable types of an input stack map frame. The value of such types is a local variable index.
/** * Kind of the types that are relative to the local variable types of an * input stack map frame. The value of such types is a local variable index. */
private static final int LOCAL = 0x2000000;
Kind of the the types that are relative to the stack of an input stack map frame. The value of such types is a position relatively to the top of this stack.
/** * Kind of the the types that are relative to the stack of an input stack * map frame. The value of such types is a position relatively to the top of * this stack. */
private static final int STACK = 0x3000000;
The TOP type. This is a BASE type.
/** * The TOP type. This is a BASE type. */
static final int TOP = BASE | 0;
The BOOLEAN type. This is a BASE type mainly used for array types.
/** * The BOOLEAN type. This is a BASE type mainly used for array types. */
static final int BOOLEAN = BASE | 9;
The BYTE type. This is a BASE type mainly used for array types.
/** * The BYTE type. This is a BASE type mainly used for array types. */
static final int BYTE = BASE | 10;
The CHAR type. This is a BASE type mainly used for array types.
/** * The CHAR type. This is a BASE type mainly used for array types. */
static final int CHAR = BASE | 11;
The SHORT type. This is a BASE type mainly used for array types.
/** * The SHORT type. This is a BASE type mainly used for array types. */
static final int SHORT = BASE | 12;
The INTEGER type. This is a BASE type.
/** * The INTEGER type. This is a BASE type. */
static final int INTEGER = BASE | 1;
The FLOAT type. This is a BASE type.
/** * The FLOAT type. This is a BASE type. */
static final int FLOAT = BASE | 2;
The DOUBLE type. This is a BASE type.
/** * The DOUBLE type. This is a BASE type. */
static final int DOUBLE = BASE | 3;
The LONG type. This is a BASE type.
/** * The LONG type. This is a BASE type. */
static final int LONG = BASE | 4;
The NULL type. This is a BASE type.
/** * The NULL type. This is a BASE type. */
static final int NULL = BASE | 5;
The UNINITIALIZED_THIS type. This is a BASE type.
/** * The UNINITIALIZED_THIS type. This is a BASE type. */
static final int UNINITIALIZED_THIS = BASE | 6;
The stack size variation corresponding to each JVM instruction. This stack variation is equal to the size of the values produced by an instruction, minus the size of the values consumed by this instruction.
/** * The stack size variation corresponding to each JVM instruction. This * stack variation is equal to the size of the values produced by an * instruction, minus the size of the values consumed by this instruction. */
static final int[] SIZE;
Computes the stack size variation corresponding to each JVM instruction.
/** * Computes the stack size variation corresponding to each JVM instruction. */
static { int i; int[] b = new int[202]; String s = "EFFFFFFFFGGFFFGGFFFEEFGFGFEEEEEEEEEEEEEEEEEEEEDEDEDDDDD" + "CDCDEEEEEEEEEEEEEEEEEEEEBABABBBBDCFFFGGGEDCDCDCDCDCDCDCDCD" + "CDCEEEEDDDDDDDCDCDCEFEFDDEEFFDEDEEEBDDBBDDDDDDCCCCCCCCEFED" + "DDCDCDEEEEEEEEEEFEEEEEEDDEEDDEE"; for (i = 0; i < b.length; ++i) { b[i] = s.charAt(i) - 'E'; } SIZE = b; // code to generate the above string // // int NA = 0; // not applicable (unused opcode or variable size opcode) // // b = new int[] { // 0, //NOP, // visitInsn // 1, //ACONST_NULL, // - // 1, //ICONST_M1, // - // 1, //ICONST_0, // - // 1, //ICONST_1, // - // 1, //ICONST_2, // - // 1, //ICONST_3, // - // 1, //ICONST_4, // - // 1, //ICONST_5, // - // 2, //LCONST_0, // - // 2, //LCONST_1, // - // 1, //FCONST_0, // - // 1, //FCONST_1, // - // 1, //FCONST_2, // - // 2, //DCONST_0, // - // 2, //DCONST_1, // - // 1, //BIPUSH, // visitIntInsn // 1, //SIPUSH, // - // 1, //LDC, // visitLdcInsn // NA, //LDC_W, // - // NA, //LDC2_W, // - // 1, //ILOAD, // visitVarInsn // 2, //LLOAD, // - // 1, //FLOAD, // - // 2, //DLOAD, // - // 1, //ALOAD, // - // NA, //ILOAD_0, // - // NA, //ILOAD_1, // - // NA, //ILOAD_2, // - // NA, //ILOAD_3, // - // NA, //LLOAD_0, // - // NA, //LLOAD_1, // - // NA, //LLOAD_2, // - // NA, //LLOAD_3, // - // NA, //FLOAD_0, // - // NA, //FLOAD_1, // - // NA, //FLOAD_2, // - // NA, //FLOAD_3, // - // NA, //DLOAD_0, // - // NA, //DLOAD_1, // - // NA, //DLOAD_2, // - // NA, //DLOAD_3, // - // NA, //ALOAD_0, // - // NA, //ALOAD_1, // - // NA, //ALOAD_2, // - // NA, //ALOAD_3, // - // -1, //IALOAD, // visitInsn // 0, //LALOAD, // - // -1, //FALOAD, // - // 0, //DALOAD, // - // -1, //AALOAD, // - // -1, //BALOAD, // - // -1, //CALOAD, // - // -1, //SALOAD, // - // -1, //ISTORE, // visitVarInsn // -2, //LSTORE, // - // -1, //FSTORE, // - // -2, //DSTORE, // - // -1, //ASTORE, // - // NA, //ISTORE_0, // - // NA, //ISTORE_1, // - // NA, //ISTORE_2, // - // NA, //ISTORE_3, // - // NA, //LSTORE_0, // - // NA, //LSTORE_1, // - // NA, //LSTORE_2, // - // NA, //LSTORE_3, // - // NA, //FSTORE_0, // - // NA, //FSTORE_1, // - // NA, //FSTORE_2, // - // NA, //FSTORE_3, // - // NA, //DSTORE_0, // - // NA, //DSTORE_1, // - // NA, //DSTORE_2, // - // NA, //DSTORE_3, // - // NA, //ASTORE_0, // - // NA, //ASTORE_1, // - // NA, //ASTORE_2, // - // NA, //ASTORE_3, // - // -3, //IASTORE, // visitInsn // -4, //LASTORE, // - // -3, //FASTORE, // - // -4, //DASTORE, // - // -3, //AASTORE, // - // -3, //BASTORE, // - // -3, //CASTORE, // - // -3, //SASTORE, // - // -1, //POP, // - // -2, //POP2, // - // 1, //DUP, // - // 1, //DUP_X1, // - // 1, //DUP_X2, // - // 2, //DUP2, // - // 2, //DUP2_X1, // - // 2, //DUP2_X2, // - // 0, //SWAP, // - // -1, //IADD, // - // -2, //LADD, // - // -1, //FADD, // - // -2, //DADD, // - // -1, //ISUB, // - // -2, //LSUB, // - // -1, //FSUB, // - // -2, //DSUB, // - // -1, //IMUL, // - // -2, //LMUL, // - // -1, //FMUL, // - // -2, //DMUL, // - // -1, //IDIV, // - // -2, //LDIV, // - // -1, //FDIV, // - // -2, //DDIV, // - // -1, //IREM, // - // -2, //LREM, // - // -1, //FREM, // - // -2, //DREM, // - // 0, //INEG, // - // 0, //LNEG, // - // 0, //FNEG, // - // 0, //DNEG, // - // -1, //ISHL, // - // -1, //LSHL, // - // -1, //ISHR, // - // -1, //LSHR, // - // -1, //IUSHR, // - // -1, //LUSHR, // - // -1, //IAND, // - // -2, //LAND, // - // -1, //IOR, // - // -2, //LOR, // - // -1, //IXOR, // - // -2, //LXOR, // - // 0, //IINC, // visitIincInsn // 1, //I2L, // visitInsn // 0, //I2F, // - // 1, //I2D, // - // -1, //L2I, // - // -1, //L2F, // - // 0, //L2D, // - // 0, //F2I, // - // 1, //F2L, // - // 1, //F2D, // - // -1, //D2I, // - // 0, //D2L, // - // -1, //D2F, // - // 0, //I2B, // - // 0, //I2C, // - // 0, //I2S, // - // -3, //LCMP, // - // -1, //FCMPL, // - // -1, //FCMPG, // - // -3, //DCMPL, // - // -3, //DCMPG, // - // -1, //IFEQ, // visitJumpInsn // -1, //IFNE, // - // -1, //IFLT, // - // -1, //IFGE, // - // -1, //IFGT, // - // -1, //IFLE, // - // -2, //IF_ICMPEQ, // - // -2, //IF_ICMPNE, // - // -2, //IF_ICMPLT, // - // -2, //IF_ICMPGE, // - // -2, //IF_ICMPGT, // - // -2, //IF_ICMPLE, // - // -2, //IF_ACMPEQ, // - // -2, //IF_ACMPNE, // - // 0, //GOTO, // - // 1, //JSR, // - // 0, //RET, // visitVarInsn // -1, //TABLESWITCH, // visiTableSwitchInsn // -1, //LOOKUPSWITCH, // visitLookupSwitch // -1, //IRETURN, // visitInsn // -2, //LRETURN, // - // -1, //FRETURN, // - // -2, //DRETURN, // - // -1, //ARETURN, // - // 0, //RETURN, // - // NA, //GETSTATIC, // visitFieldInsn // NA, //PUTSTATIC, // - // NA, //GETFIELD, // - // NA, //PUTFIELD, // - // NA, //INVOKEVIRTUAL, // visitMethodInsn // NA, //INVOKESPECIAL, // - // NA, //INVOKESTATIC, // - // NA, //INVOKEINTERFACE, // - // NA, //INVOKEDYNAMIC, // visitInvokeDynamicInsn // 1, //NEW, // visitTypeInsn // 0, //NEWARRAY, // visitIntInsn // 0, //ANEWARRAY, // visitTypeInsn // 0, //ARRAYLENGTH, // visitInsn // NA, //ATHROW, // - // 0, //CHECKCAST, // visitTypeInsn // 0, //INSTANCEOF, // - // -1, //MONITORENTER, // visitInsn // -1, //MONITOREXIT, // - // NA, //WIDE, // NOT VISITED // NA, //MULTIANEWARRAY, // visitMultiANewArrayInsn // -1, //IFNULL, // visitJumpInsn // -1, //IFNONNULL, // - // NA, //GOTO_W, // - // NA, //JSR_W, // - // }; // for (i = 0; i < b.length; ++i) { // System.err.print((char)('E' + b[i])); // } // System.err.println(); }
The label (i.e. basic block) to which these input and output stack map frames correspond.
/** * The label (i.e. basic block) to which these input and output stack map * frames correspond. */
Label owner;
The input stack map frame locals.
/** * The input stack map frame locals. */
int[] inputLocals;
The input stack map frame stack.
/** * The input stack map frame stack. */
int[] inputStack;
The output stack map frame locals.
/** * The output stack map frame locals. */
private int[] outputLocals;
The output stack map frame stack.
/** * The output stack map frame stack. */
private int[] outputStack;
Relative size of the output stack. The exact semantics of this field depends on the algorithm that is used. When only the maximum stack size is computed, this field is the size of the output stack relatively to the top of the input stack. When the stack map frames are completely computed, this field is the actual number of types in outputStack.
/** * Relative size of the output stack. The exact semantics of this field * depends on the algorithm that is used. * * When only the maximum stack size is computed, this field is the size of * the output stack relatively to the top of the input stack. * * When the stack map frames are completely computed, this field is the * actual number of types in {@link #outputStack}. */
int outputStackTop;
Number of types that are initialized in the basic block.
See Also:
  • initializations
/** * Number of types that are initialized in the basic block. * * @see #initializations */
private int initializationCount;
The types that are initialized in the basic block. A constructor invocation on an UNINITIALIZED or UNINITIALIZED_THIS type must replace every occurence of this type in the local variables and in the operand stack. This cannot be done during the first phase of the algorithm since, during this phase, the local variables and the operand stack are not completely computed. It is therefore necessary to store the types on which constructors are invoked in the basic block, in order to do this replacement during the second phase of the algorithm, where the frames are fully computed. Note that this array can contain types that are relative to input locals or to the input stack (see below for the description of the algorithm).
/** * The types that are initialized in the basic block. A constructor * invocation on an UNINITIALIZED or UNINITIALIZED_THIS type must replace * <i>every occurence</i> of this type in the local variables and in the * operand stack. This cannot be done during the first phase of the * algorithm since, during this phase, the local variables and the operand * stack are not completely computed. It is therefore necessary to store the * types on which constructors are invoked in the basic block, in order to * do this replacement during the second phase of the algorithm, where the * frames are fully computed. Note that this array can contain types that * are relative to input locals or to the input stack (see below for the * description of the algorithm). */
private int[] initializations;
Sets this frame to the given value.
Params:
  • cw – the ClassWriter to which this label belongs.
  • nLocal – the number of local variables.
  • local – the local variable types. Primitive types are represented by Opcodes.TOP, Opcodes.INTEGER, Opcodes.FLOAT, Opcodes.LONG, Opcodes.DOUBLE,Opcodes.NULL or Opcodes.UNINITIALIZED_THIS (long and double are represented by a single element). Reference types are represented by String objects (representing internal names), and uninitialized types by Label objects (this label designates the NEW instruction that created this uninitialized value).
  • nStack – the number of operand stack elements.
  • stack – the operand stack types (same format as the "local" array).
/** * Sets this frame to the given value. * * @param cw * the ClassWriter to which this label belongs. * @param nLocal * the number of local variables. * @param local * the local variable types. Primitive types are represented by * {@link Opcodes#TOP}, {@link Opcodes#INTEGER}, * {@link Opcodes#FLOAT}, {@link Opcodes#LONG}, * {@link Opcodes#DOUBLE},{@link Opcodes#NULL} or * {@link Opcodes#UNINITIALIZED_THIS} (long and double are * represented by a single element). Reference types are * represented by String objects (representing internal names), * and uninitialized types by Label objects (this label * designates the NEW instruction that created this uninitialized * value). * @param nStack * the number of operand stack elements. * @param stack * the operand stack types (same format as the "local" array). */
final void set(ClassWriter cw, final int nLocal, final Object[] local, final int nStack, final Object[] stack) { int i = convert(cw, nLocal, local, inputLocals); while (i < local.length) { inputLocals[i++] = TOP; } int nStackTop = 0; for (int j = 0; j < nStack; ++j) { if (stack[j] == Opcodes.LONG || stack[j] == Opcodes.DOUBLE) { ++nStackTop; } } inputStack = new int[nStack + nStackTop]; convert(cw, nStack, stack, inputStack); outputStackTop = 0; initializationCount = 0; }
Converts types from the MethodWriter.visitFrame() format to the Frame format.
Params:
  • cw – the ClassWriter to which this label belongs.
  • nInput – the number of types to convert.
  • input – the types to convert. Primitive types are represented by Opcodes.TOP, Opcodes.INTEGER, Opcodes.FLOAT, Opcodes.LONG, Opcodes.DOUBLE,Opcodes.NULL or Opcodes.UNINITIALIZED_THIS (long and double are represented by a single element). Reference types are represented by String objects (representing internal names), and uninitialized types by Label objects (this label designates the NEW instruction that created this uninitialized value).
  • output – where to store the converted types.
Returns:the number of output elements.
/** * Converts types from the MethodWriter.visitFrame() format to the Frame * format. * * @param cw * the ClassWriter to which this label belongs. * @param nInput * the number of types to convert. * @param input * the types to convert. Primitive types are represented by * {@link Opcodes#TOP}, {@link Opcodes#INTEGER}, * {@link Opcodes#FLOAT}, {@link Opcodes#LONG}, * {@link Opcodes#DOUBLE},{@link Opcodes#NULL} or * {@link Opcodes#UNINITIALIZED_THIS} (long and double are * represented by a single element). Reference types are * represented by String objects (representing internal names), * and uninitialized types by Label objects (this label * designates the NEW instruction that created this uninitialized * value). * @param output * where to store the converted types. * @return the number of output elements. */
private static int convert(ClassWriter cw, int nInput, Object[] input, int[] output) { int i = 0; for (int j = 0; j < nInput; ++j) { if (input[j] instanceof Integer) { output[i++] = BASE | ((Integer) input[j]).intValue(); if (input[j] == Opcodes.LONG || input[j] == Opcodes.DOUBLE) { output[i++] = TOP; } } else if (input[j] instanceof String) { output[i++] = type(cw, Type.getObjectType((String) input[j]) .getDescriptor()); } else { output[i++] = UNINITIALIZED | cw.addUninitializedType("", ((Label) input[j]).position); } } return i; }
Sets this frame to the value of the given frame. WARNING: after this method is called the two frames share the same data structures. It is recommended to discard the given frame f to avoid unexpected side effects.
Params:
  • f – The new frame value.
/** * Sets this frame to the value of the given frame. WARNING: after this * method is called the two frames share the same data structures. It is * recommended to discard the given frame f to avoid unexpected side * effects. * * @param f * The new frame value. */
final void set(final Frame f) { inputLocals = f.inputLocals; inputStack = f.inputStack; outputLocals = f.outputLocals; outputStack = f.outputStack; outputStackTop = f.outputStackTop; initializationCount = f.initializationCount; initializations = f.initializations; }
Returns the output frame local variable type at the given index.
Params:
  • local – the index of the local that must be returned.
Returns:the output frame local variable type at the given index.
/** * Returns the output frame local variable type at the given index. * * @param local * the index of the local that must be returned. * @return the output frame local variable type at the given index. */
private int get(final int local) { if (outputLocals == null || local >= outputLocals.length) { // this local has never been assigned in this basic block, // so it is still equal to its value in the input frame return LOCAL | local; } else { int type = outputLocals[local]; if (type == 0) { // this local has never been assigned in this basic block, // so it is still equal to its value in the input frame type = outputLocals[local] = LOCAL | local; } return type; } }
Sets the output frame local variable type at the given index.
Params:
  • local – the index of the local that must be set.
  • type – the value of the local that must be set.
/** * Sets the output frame local variable type at the given index. * * @param local * the index of the local that must be set. * @param type * the value of the local that must be set. */
private void set(final int local, final int type) { // creates and/or resizes the output local variables array if necessary if (outputLocals == null) { outputLocals = new int[10]; } int n = outputLocals.length; if (local >= n) { int[] t = new int[Math.max(local + 1, 2 * n)]; System.arraycopy(outputLocals, 0, t, 0, n); outputLocals = t; } // sets the local variable outputLocals[local] = type; }
Pushes a new type onto the output frame stack.
Params:
  • type – the type that must be pushed.
/** * Pushes a new type onto the output frame stack. * * @param type * the type that must be pushed. */
private void push(final int type) { // creates and/or resizes the output stack array if necessary if (outputStack == null) { outputStack = new int[10]; } int n = outputStack.length; if (outputStackTop >= n) { int[] t = new int[Math.max(outputStackTop + 1, 2 * n)]; System.arraycopy(outputStack, 0, t, 0, n); outputStack = t; } // pushes the type on the output stack outputStack[outputStackTop++] = type; // updates the maximum height reached by the output stack, if needed int top = owner.inputStackTop + outputStackTop; if (top > owner.outputStackMax) { owner.outputStackMax = top; } }
Pushes a new type onto the output frame stack.
Params:
  • cw – the ClassWriter to which this label belongs.
  • desc – the descriptor of the type to be pushed. Can also be a method descriptor (in this case this method pushes its return type onto the output frame stack).
/** * Pushes a new type onto the output frame stack. * * @param cw * the ClassWriter to which this label belongs. * @param desc * the descriptor of the type to be pushed. Can also be a method * descriptor (in this case this method pushes its return type * onto the output frame stack). */
private void push(final ClassWriter cw, final String desc) { int type = type(cw, desc); if (type != 0) { push(type); if (type == LONG || type == DOUBLE) { push(TOP); } } }
Returns the int encoding of the given type.
Params:
  • cw – the ClassWriter to which this label belongs.
  • desc – a type descriptor.
Returns:the int encoding of the given type.
/** * Returns the int encoding of the given type. * * @param cw * the ClassWriter to which this label belongs. * @param desc * a type descriptor. * @return the int encoding of the given type. */
private static int type(final ClassWriter cw, final String desc) { String t; int index = desc.charAt(0) == '(' ? desc.indexOf(')') + 1 : 0; switch (desc.charAt(index)) { case 'V': return 0; case 'Z': case 'C': case 'B': case 'S': case 'I': return INTEGER; case 'F': return FLOAT; case 'J': return LONG; case 'D': return DOUBLE; case 'L': // stores the internal name, not the descriptor! t = desc.substring(index + 1, desc.length() - 1); return OBJECT | cw.addType(t); // case '[': default: // extracts the dimensions and the element type int data; int dims = index + 1; while (desc.charAt(dims) == '[') { ++dims; } switch (desc.charAt(dims)) { case 'Z': data = BOOLEAN; break; case 'C': data = CHAR; break; case 'B': data = BYTE; break; case 'S': data = SHORT; break; case 'I': data = INTEGER; break; case 'F': data = FLOAT; break; case 'J': data = LONG; break; case 'D': data = DOUBLE; break; // case 'L': default: // stores the internal name, not the descriptor t = desc.substring(dims + 1, desc.length() - 1); data = OBJECT | cw.addType(t); } return (dims - index) << 28 | data; } }
Pops a type from the output frame stack and returns its value.
Returns:the type that has been popped from the output frame stack.
/** * Pops a type from the output frame stack and returns its value. * * @return the type that has been popped from the output frame stack. */
private int pop() { if (outputStackTop > 0) { return outputStack[--outputStackTop]; } else { // if the output frame stack is empty, pops from the input stack return STACK | -(--owner.inputStackTop); } }
Pops the given number of types from the output frame stack.
Params:
  • elements – the number of types that must be popped.
/** * Pops the given number of types from the output frame stack. * * @param elements * the number of types that must be popped. */
private void pop(final int elements) { if (outputStackTop >= elements) { outputStackTop -= elements; } else { // if the number of elements to be popped is greater than the number // of elements in the output stack, clear it, and pops the remaining // elements from the input stack. owner.inputStackTop -= elements - outputStackTop; outputStackTop = 0; } }
Pops a type from the output frame stack.
Params:
  • desc – the descriptor of the type to be popped. Can also be a method descriptor (in this case this method pops the types corresponding to the method arguments).
/** * Pops a type from the output frame stack. * * @param desc * the descriptor of the type to be popped. Can also be a method * descriptor (in this case this method pops the types * corresponding to the method arguments). */
private void pop(final String desc) { char c = desc.charAt(0); if (c == '(') { pop((Type.getArgumentsAndReturnSizes(desc) >> 2) - 1); } else if (c == 'J' || c == 'D') { pop(2); } else { pop(1); } }
Adds a new type to the list of types on which a constructor is invoked in the basic block.
Params:
  • var – a type on a which a constructor is invoked.
/** * Adds a new type to the list of types on which a constructor is invoked in * the basic block. * * @param var * a type on a which a constructor is invoked. */
private void init(final int var) { // creates and/or resizes the initializations array if necessary if (initializations == null) { initializations = new int[2]; } int n = initializations.length; if (initializationCount >= n) { int[] t = new int[Math.max(initializationCount + 1, 2 * n)]; System.arraycopy(initializations, 0, t, 0, n); initializations = t; } // stores the type to be initialized initializations[initializationCount++] = var; }
Replaces the given type with the appropriate type if it is one of the types on which a constructor is invoked in the basic block.
Params:
  • cw – the ClassWriter to which this label belongs.
  • t – a type
Returns:t or, if t is one of the types on which a constructor is invoked in the basic block, the type corresponding to this constructor.
/** * Replaces the given type with the appropriate type if it is one of the * types on which a constructor is invoked in the basic block. * * @param cw * the ClassWriter to which this label belongs. * @param t * a type * @return t or, if t is one of the types on which a constructor is invoked * in the basic block, the type corresponding to this constructor. */
private int init(final ClassWriter cw, final int t) { int s; if (t == UNINITIALIZED_THIS) { s = OBJECT | cw.addType(cw.thisName); } else if ((t & (DIM | BASE_KIND)) == UNINITIALIZED) { String type = cw.typeTable[t & BASE_VALUE].strVal1; s = OBJECT | cw.addType(type); } else { return t; } for (int j = 0; j < initializationCount; ++j) { int u = initializations[j]; int dim = u & DIM; int kind = u & KIND; if (kind == LOCAL) { u = dim + inputLocals[u & VALUE]; } else if (kind == STACK) { u = dim + inputStack[inputStack.length - (u & VALUE)]; } if (t == u) { return s; } } return t; }
Initializes the input frame of the first basic block from the method descriptor.
Params:
  • cw – the ClassWriter to which this label belongs.
  • access – the access flags of the method to which this label belongs.
  • args – the formal parameter types of this method.
  • maxLocals – the maximum number of local variables of this method.
/** * Initializes the input frame of the first basic block from the method * descriptor. * * @param cw * the ClassWriter to which this label belongs. * @param access * the access flags of the method to which this label belongs. * @param args * the formal parameter types of this method. * @param maxLocals * the maximum number of local variables of this method. */
final void initInputFrame(final ClassWriter cw, final int access, final Type[] args, final int maxLocals) { inputLocals = new int[maxLocals]; inputStack = new int[0]; int i = 0; if ((access & Opcodes.ACC_STATIC) == 0) { if ((access & MethodWriter.ACC_CONSTRUCTOR) == 0) { inputLocals[i++] = OBJECT | cw.addType(cw.thisName); } else { inputLocals[i++] = UNINITIALIZED_THIS; } } for (int j = 0; j < args.length; ++j) { int t = type(cw, args[j].getDescriptor()); inputLocals[i++] = t; if (t == LONG || t == DOUBLE) { inputLocals[i++] = TOP; } } while (i < maxLocals) { inputLocals[i++] = TOP; } }
Simulates the action of the given instruction on the output stack frame.
Params:
  • opcode – the opcode of the instruction.
  • arg – the operand of the instruction, if any.
  • cw – the class writer to which this label belongs.
  • item – the operand of the instructions, if any.
/** * Simulates the action of the given instruction on the output stack frame. * * @param opcode * the opcode of the instruction. * @param arg * the operand of the instruction, if any. * @param cw * the class writer to which this label belongs. * @param item * the operand of the instructions, if any. */
void execute(final int opcode, final int arg, final ClassWriter cw, final Item item) { int t1, t2, t3, t4; switch (opcode) { case Opcodes.NOP: case Opcodes.INEG: case Opcodes.LNEG: case Opcodes.FNEG: case Opcodes.DNEG: case Opcodes.I2B: case Opcodes.I2C: case Opcodes.I2S: case Opcodes.GOTO: case Opcodes.RETURN: break; case Opcodes.ACONST_NULL: push(NULL); break; case Opcodes.ICONST_M1: case Opcodes.ICONST_0: case Opcodes.ICONST_1: case Opcodes.ICONST_2: case Opcodes.ICONST_3: case Opcodes.ICONST_4: case Opcodes.ICONST_5: case Opcodes.BIPUSH: case Opcodes.SIPUSH: case Opcodes.ILOAD: push(INTEGER); break; case Opcodes.LCONST_0: case Opcodes.LCONST_1: case Opcodes.LLOAD: push(LONG); push(TOP); break; case Opcodes.FCONST_0: case Opcodes.FCONST_1: case Opcodes.FCONST_2: case Opcodes.FLOAD: push(FLOAT); break; case Opcodes.DCONST_0: case Opcodes.DCONST_1: case Opcodes.DLOAD: push(DOUBLE); push(TOP); break; case Opcodes.LDC: switch (item.type) { case ClassWriter.INT: push(INTEGER); break; case ClassWriter.LONG: push(LONG); push(TOP); break; case ClassWriter.FLOAT: push(FLOAT); break; case ClassWriter.DOUBLE: push(DOUBLE); push(TOP); break; case ClassWriter.CLASS: push(OBJECT | cw.addType("java/lang/Class")); break; case ClassWriter.STR: push(OBJECT | cw.addType("java/lang/String")); break; case ClassWriter.MTYPE: push(OBJECT | cw.addType("java/lang/invoke/MethodType")); break; // case ClassWriter.HANDLE_BASE + [1..9]: default: push(OBJECT | cw.addType("java/lang/invoke/MethodHandle")); } break; case Opcodes.ALOAD: push(get(arg)); break; case Opcodes.IALOAD: case Opcodes.BALOAD: case Opcodes.CALOAD: case Opcodes.SALOAD: pop(2); push(INTEGER); break; case Opcodes.LALOAD: case Opcodes.D2L: pop(2); push(LONG); push(TOP); break; case Opcodes.FALOAD: pop(2); push(FLOAT); break; case Opcodes.DALOAD: case Opcodes.L2D: pop(2); push(DOUBLE); push(TOP); break; case Opcodes.AALOAD: pop(1); t1 = pop(); push(ELEMENT_OF + t1); break; case Opcodes.ISTORE: case Opcodes.FSTORE: case Opcodes.ASTORE: t1 = pop(); set(arg, t1); if (arg > 0) { t2 = get(arg - 1); // if t2 is of kind STACK or LOCAL we cannot know its size! if (t2 == LONG || t2 == DOUBLE) { set(arg - 1, TOP); } else if ((t2 & KIND) != BASE) { set(arg - 1, t2 | TOP_IF_LONG_OR_DOUBLE); } } break; case Opcodes.LSTORE: case Opcodes.DSTORE: pop(1); t1 = pop(); set(arg, t1); set(arg + 1, TOP); if (arg > 0) { t2 = get(arg - 1); // if t2 is of kind STACK or LOCAL we cannot know its size! if (t2 == LONG || t2 == DOUBLE) { set(arg - 1, TOP); } else if ((t2 & KIND) != BASE) { set(arg - 1, t2 | TOP_IF_LONG_OR_DOUBLE); } } break; case Opcodes.IASTORE: case Opcodes.BASTORE: case Opcodes.CASTORE: case Opcodes.SASTORE: case Opcodes.FASTORE: case Opcodes.AASTORE: pop(3); break; case Opcodes.LASTORE: case Opcodes.DASTORE: pop(4); break; case Opcodes.POP: case Opcodes.IFEQ: case Opcodes.IFNE: case Opcodes.IFLT: case Opcodes.IFGE: case Opcodes.IFGT: case Opcodes.IFLE: case Opcodes.IRETURN: case Opcodes.FRETURN: case Opcodes.ARETURN: case Opcodes.TABLESWITCH: case Opcodes.LOOKUPSWITCH: case Opcodes.ATHROW: case Opcodes.MONITORENTER: case Opcodes.MONITOREXIT: case Opcodes.IFNULL: case Opcodes.IFNONNULL: pop(1); break; case Opcodes.POP2: case Opcodes.IF_ICMPEQ: case Opcodes.IF_ICMPNE: case Opcodes.IF_ICMPLT: case Opcodes.IF_ICMPGE: case Opcodes.IF_ICMPGT: case Opcodes.IF_ICMPLE: case Opcodes.IF_ACMPEQ: case Opcodes.IF_ACMPNE: case Opcodes.LRETURN: case Opcodes.DRETURN: pop(2); break; case Opcodes.DUP: t1 = pop(); push(t1); push(t1); break; case Opcodes.DUP_X1: t1 = pop(); t2 = pop(); push(t1); push(t2); push(t1); break; case Opcodes.DUP_X2: t1 = pop(); t2 = pop(); t3 = pop(); push(t1); push(t3); push(t2); push(t1); break; case Opcodes.DUP2: t1 = pop(); t2 = pop(); push(t2); push(t1); push(t2); push(t1); break; case Opcodes.DUP2_X1: t1 = pop(); t2 = pop(); t3 = pop(); push(t2); push(t1); push(t3); push(t2); push(t1); break; case Opcodes.DUP2_X2: t1 = pop(); t2 = pop(); t3 = pop(); t4 = pop(); push(t2); push(t1); push(t4); push(t3); push(t2); push(t1); break; case Opcodes.SWAP: t1 = pop(); t2 = pop(); push(t1); push(t2); break; case Opcodes.IADD: case Opcodes.ISUB: case Opcodes.IMUL: case Opcodes.IDIV: case Opcodes.IREM: case Opcodes.IAND: case Opcodes.IOR: case Opcodes.IXOR: case Opcodes.ISHL: case Opcodes.ISHR: case Opcodes.IUSHR: case Opcodes.L2I: case Opcodes.D2I: case Opcodes.FCMPL: case Opcodes.FCMPG: pop(2); push(INTEGER); break; case Opcodes.LADD: case Opcodes.LSUB: case Opcodes.LMUL: case Opcodes.LDIV: case Opcodes.LREM: case Opcodes.LAND: case Opcodes.LOR: case Opcodes.LXOR: pop(4); push(LONG); push(TOP); break; case Opcodes.FADD: case Opcodes.FSUB: case Opcodes.FMUL: case Opcodes.FDIV: case Opcodes.FREM: case Opcodes.L2F: case Opcodes.D2F: pop(2); push(FLOAT); break; case Opcodes.DADD: case Opcodes.DSUB: case Opcodes.DMUL: case Opcodes.DDIV: case Opcodes.DREM: pop(4); push(DOUBLE); push(TOP); break; case Opcodes.LSHL: case Opcodes.LSHR: case Opcodes.LUSHR: pop(3); push(LONG); push(TOP); break; case Opcodes.IINC: set(arg, INTEGER); break; case Opcodes.I2L: case Opcodes.F2L: pop(1); push(LONG); push(TOP); break; case Opcodes.I2F: pop(1); push(FLOAT); break; case Opcodes.I2D: case Opcodes.F2D: pop(1); push(DOUBLE); push(TOP); break; case Opcodes.F2I: case Opcodes.ARRAYLENGTH: case Opcodes.INSTANCEOF: pop(1); push(INTEGER); break; case Opcodes.LCMP: case Opcodes.DCMPL: case Opcodes.DCMPG: pop(4); push(INTEGER); break; case Opcodes.JSR: case Opcodes.RET: throw new RuntimeException( "JSR/RET are not supported with computeFrames option"); case Opcodes.GETSTATIC: push(cw, item.strVal3); break; case Opcodes.PUTSTATIC: pop(item.strVal3); break; case Opcodes.GETFIELD: pop(1); push(cw, item.strVal3); break; case Opcodes.PUTFIELD: pop(item.strVal3); pop(); break; case Opcodes.INVOKEVIRTUAL: case Opcodes.INVOKESPECIAL: case Opcodes.INVOKESTATIC: case Opcodes.INVOKEINTERFACE: pop(item.strVal3); if (opcode != Opcodes.INVOKESTATIC) { t1 = pop(); if (opcode == Opcodes.INVOKESPECIAL && item.strVal2.charAt(0) == '<') { init(t1); } } push(cw, item.strVal3); break; case Opcodes.INVOKEDYNAMIC: pop(item.strVal2); push(cw, item.strVal2); break; case Opcodes.NEW: push(UNINITIALIZED | cw.addUninitializedType(item.strVal1, arg)); break; case Opcodes.NEWARRAY: pop(); switch (arg) { case Opcodes.T_BOOLEAN: push(ARRAY_OF | BOOLEAN); break; case Opcodes.T_CHAR: push(ARRAY_OF | CHAR); break; case Opcodes.T_BYTE: push(ARRAY_OF | BYTE); break; case Opcodes.T_SHORT: push(ARRAY_OF | SHORT); break; case Opcodes.T_INT: push(ARRAY_OF | INTEGER); break; case Opcodes.T_FLOAT: push(ARRAY_OF | FLOAT); break; case Opcodes.T_DOUBLE: push(ARRAY_OF | DOUBLE); break; // case Opcodes.T_LONG: default: push(ARRAY_OF | LONG); break; } break; case Opcodes.ANEWARRAY: String s = item.strVal1; pop(); if (s.charAt(0) == '[') { push(cw, '[' + s); } else { push(ARRAY_OF | OBJECT | cw.addType(s)); } break; case Opcodes.CHECKCAST: s = item.strVal1; pop(); if (s.charAt(0) == '[') { push(cw, s); } else { push(OBJECT | cw.addType(s)); } break; // case Opcodes.MULTIANEWARRAY: default: pop(arg); push(cw, item.strVal1); break; } }
Merges the input frame of the given basic block with the input and output frames of this basic block. Returns true if the input frame of the given label has been changed by this operation.
Params:
  • cw – the ClassWriter to which this label belongs.
  • frame – the basic block whose input frame must be updated.
  • edge – the kind of the Edge between this label and 'label'. See Edge.info.
Returns:true if the input frame of the given label has been changed by this operation.
/** * Merges the input frame of the given basic block with the input and output * frames of this basic block. Returns <tt>true</tt> if the input frame of * the given label has been changed by this operation. * * @param cw * the ClassWriter to which this label belongs. * @param frame * the basic block whose input frame must be updated. * @param edge * the kind of the {@link Edge} between this label and 'label'. * See {@link Edge#info}. * @return <tt>true</tt> if the input frame of the given label has been * changed by this operation. */
final boolean merge(final ClassWriter cw, final Frame frame, final int edge) { boolean changed = false; int i, s, dim, kind, t; int nLocal = inputLocals.length; int nStack = inputStack.length; if (frame.inputLocals == null) { frame.inputLocals = new int[nLocal]; changed = true; } for (i = 0; i < nLocal; ++i) { if (outputLocals != null && i < outputLocals.length) { s = outputLocals[i]; if (s == 0) { t = inputLocals[i]; } else { dim = s & DIM; kind = s & KIND; if (kind == BASE) { t = s; } else { if (kind == LOCAL) { t = dim + inputLocals[s & VALUE]; } else { t = dim + inputStack[nStack - (s & VALUE)]; } if ((s & TOP_IF_LONG_OR_DOUBLE) != 0 && (t == LONG || t == DOUBLE)) { t = TOP; } } } } else { t = inputLocals[i]; } if (initializations != null) { t = init(cw, t); } changed |= merge(cw, t, frame.inputLocals, i); } if (edge > 0) { for (i = 0; i < nLocal; ++i) { t = inputLocals[i]; changed |= merge(cw, t, frame.inputLocals, i); } if (frame.inputStack == null) { frame.inputStack = new int[1]; changed = true; } changed |= merge(cw, edge, frame.inputStack, 0); return changed; } int nInputStack = inputStack.length + owner.inputStackTop; if (frame.inputStack == null) { frame.inputStack = new int[nInputStack + outputStackTop]; changed = true; } for (i = 0; i < nInputStack; ++i) { t = inputStack[i]; if (initializations != null) { t = init(cw, t); } changed |= merge(cw, t, frame.inputStack, i); } for (i = 0; i < outputStackTop; ++i) { s = outputStack[i]; dim = s & DIM; kind = s & KIND; if (kind == BASE) { t = s; } else { if (kind == LOCAL) { t = dim + inputLocals[s & VALUE]; } else { t = dim + inputStack[nStack - (s & VALUE)]; } if ((s & TOP_IF_LONG_OR_DOUBLE) != 0 && (t == LONG || t == DOUBLE)) { t = TOP; } } if (initializations != null) { t = init(cw, t); } changed |= merge(cw, t, frame.inputStack, nInputStack + i); } return changed; }
Merges the type at the given index in the given type array with the given type. Returns true if the type array has been modified by this operation.
Params:
  • cw – the ClassWriter to which this label belongs.
  • t – the type with which the type array element must be merged.
  • types – an array of types.
  • index – the index of the type that must be merged in 'types'.
Returns:true if the type array has been modified by this operation.
/** * Merges the type at the given index in the given type array with the given * type. Returns <tt>true</tt> if the type array has been modified by this * operation. * * @param cw * the ClassWriter to which this label belongs. * @param t * the type with which the type array element must be merged. * @param types * an array of types. * @param index * the index of the type that must be merged in 'types'. * @return <tt>true</tt> if the type array has been modified by this * operation. */
private static boolean merge(final ClassWriter cw, int t, final int[] types, final int index) { int u = types[index]; if (u == t) { // if the types are equal, merge(u,t)=u, so there is no change return false; } if ((t & ~DIM) == NULL) { if (u == NULL) { return false; } t = NULL; } if (u == 0) { // if types[index] has never been assigned, merge(u,t)=t types[index] = t; return true; } int v; if ((u & BASE_KIND) == OBJECT || (u & DIM) != 0) { // if u is a reference type of any dimension if (t == NULL) { // if t is the NULL type, merge(u,t)=u, so there is no change return false; } else if ((t & (DIM | BASE_KIND)) == (u & (DIM | BASE_KIND))) { // if t and u have the same dimension and same base kind if ((u & BASE_KIND) == OBJECT) { // if t is also a reference type, and if u and t have the // same dimension merge(u,t) = dim(t) | common parent of the // element types of u and t v = (t & DIM) | OBJECT | cw.getMergedType(t & BASE_VALUE, u & BASE_VALUE); } else { // if u and t are array types, but not with the same element // type, merge(u,t) = dim(u) - 1 | java/lang/Object int vdim = ELEMENT_OF + (u & DIM); v = vdim | OBJECT | cw.addType("java/lang/Object"); } } else if ((t & BASE_KIND) == OBJECT || (t & DIM) != 0) { // if t is any other reference or array type, the merged type // is min(udim, tdim) | java/lang/Object, where udim is the // array dimension of u, minus 1 if u is an array type with a // primitive element type (and similarly for tdim). int tdim = (((t & DIM) == 0 || (t & BASE_KIND) == OBJECT) ? 0 : ELEMENT_OF) + (t & DIM); int udim = (((u & DIM) == 0 || (u & BASE_KIND) == OBJECT) ? 0 : ELEMENT_OF) + (u & DIM); v = Math.min(tdim, udim) | OBJECT | cw.addType("java/lang/Object"); } else { // if t is any other type, merge(u,t)=TOP v = TOP; } } else if (u == NULL) { // if u is the NULL type, merge(u,t)=t, // or TOP if t is not a reference type v = (t & BASE_KIND) == OBJECT || (t & DIM) != 0 ? t : TOP; } else { // if u is any other type, merge(u,t)=TOP whatever t v = TOP; } if (u != v) { types[index] = v; return true; } return false; } }