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A bundle project producing JAX-RS RI bundles. The primary artifact is an "all-in-one" OSGi-fied JAX-RS RI bundle (jaxrs-ri.jar). Attached to that are two compressed JAX-RS RI archives. The first archive (jaxrs-ri.zip) consists of binary RI bits and contains the API jar (under "api" directory), RI libraries (under "lib" directory) as well as all external RI dependencies (under "ext" directory). The secondary archive (jaxrs-ri-src.zip) contains buildable JAX-RS RI source bundle and contains the API jar (under "api" directory), RI sources (under "src" directory) as well as all external RI dependencies (under "ext" directory). The second archive also contains "build.xml" ANT script that builds the RI sources. To build the JAX-RS RI simply unzip the archive, cd to the created jaxrs-ri directory and invoke "ant" from the command line.

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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
// 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 jersey.repackaged.org.objectweb.asm;

/**
 * The JVM opcodes, access flags and array type codes. This interface does not define all the JVM
 * opcodes because some opcodes are automatically handled. For example, the xLOAD and xSTORE opcodes
 * are automatically replaced by xLOAD_n and xSTORE_n opcodes when possible. The xLOAD_n and
 * xSTORE_n opcodes are therefore not defined in this interface. Likewise for LDC, automatically
 * replaced by LDC_W or LDC2_W when necessary, WIDE, GOTO_W and JSR_W.
 *
 * @see JVMS 6
 * @author Eric Bruneton
 * @author Eugene Kuleshov
 */
// DontCheck(InterfaceIsType): can't be fixed (for backward binary compatibility).
public interface Opcodes {

  // ASM API versions.

  int ASM4 = 4 << 16 | 0 << 8;
  int ASM5 = 5 << 16 | 0 << 8;
  int ASM6 = 6 << 16 | 0 << 8;
  int ASM7 = 7 << 16 | 0 << 8;
  int ASM8 = 8 << 16 | 0 << 8;
  int ASM9 = 9 << 16 | 0 << 8;

  /**
   * Experimental, use at your own risk. This field will be renamed when it becomes stable, this
   * will break existing code using it. Only code compiled with --enable-preview can use this.
   *
   * @deprecated This API is experimental.
   */
  @Deprecated int ASM10_EXPERIMENTAL = 1 << 24 | 10 << 16 | 0 << 8;

  /*
   * Internal flags used to redirect calls to deprecated methods. For instance, if a visitOldStuff
   * method in API_OLD is deprecated and replaced with visitNewStuff in API_NEW, then the
   * redirection should be done as follows:
   *
   * 
   * public class StuffVisitor {
   *   ...
   *
   *   @Deprecated public void visitOldStuff(int arg, ...) {
   *     // SOURCE_DEPRECATED means "a call from a deprecated method using the old 'api' value".
   *     visitNewStuf(arg | (api < API_NEW ? SOURCE_DEPRECATED : 0), ...);
   *   }
   *
   *   public void visitNewStuff(int argAndSource, ...) {
   *     if (api < API_NEW && (argAndSource & SOURCE_DEPRECATED) == 0) {
   *       visitOldStuff(argAndSource, ...);
   *     } else {
   *       int arg = argAndSource & ~SOURCE_MASK;
   *       [ do stuff ]
   *     }
   *   }
   * }
   * 
* *

If 'api' is equal to API_NEW, there are two cases: * *

    *
  • call visitNewStuff: the redirection test is skipped and 'do stuff' is executed directly. *
  • call visitOldSuff: the source is not set to SOURCE_DEPRECATED before calling * visitNewStuff, but the redirection test is skipped anyway in visitNewStuff, which * directly executes 'do stuff'. *
* *

If 'api' is equal to API_OLD, there are two cases: * *

    *
  • call visitOldSuff: the source is set to SOURCE_DEPRECATED before calling visitNewStuff. * Because of this visitNewStuff does not redirect back to visitOldStuff, and instead * executes 'do stuff'. *
  • call visitNewStuff: the call is redirected to visitOldStuff because the source is 0. * visitOldStuff now sets the source to SOURCE_DEPRECATED and calls visitNewStuff back. This * time visitNewStuff does not redirect the call, and instead executes 'do stuff'. *
* *

User subclasses

* *

If a user subclass overrides one of these methods, there are only two cases: either 'api' is * API_OLD and visitOldStuff is overridden (and visitNewStuff is not), or 'api' is API_NEW or * more, and visitNewStuff is overridden (and visitOldStuff is not). Any other case is a user * programming error. * *

If 'api' is equal to API_NEW, the class hierarchy is equivalent to * *

   * public class StuffVisitor {
   *   @Deprecated public void visitOldStuff(int arg, ...) { visitNewStuf(arg, ...); }
   *   public void visitNewStuff(int arg, ...) { [ do stuff ] }
   * }
   * class UserStuffVisitor extends StuffVisitor {
   *   @Override public void visitNewStuff(int arg, ...) {
   *     super.visitNewStuff(int arg, ...); // optional
   *     [ do user stuff ]
   *   }
   * }
   * 
* *

It is then obvious that whether visitNewStuff or visitOldStuff is called, 'do stuff' and 'do * user stuff' will be executed, in this order. * *

If 'api' is equal to API_OLD, the class hierarchy is equivalent to * *

   * public class StuffVisitor {
   *   @Deprecated public void visitOldStuff(int arg, ...) {
   *     visitNewStuff(arg | SOURCE_DEPRECATED, ...);
   *   }
   *   public void visitNewStuff(int argAndSource...) {
   *     if ((argAndSource & SOURCE_DEPRECATED) == 0) {
   *       visitOldStuff(argAndSource, ...);
   *     } else {
   *       int arg = argAndSource & ~SOURCE_MASK;
   *       [ do stuff ]
   *     }
   *   }
   * }
   * class UserStuffVisitor extends StuffVisitor {
   *   @Override public void visitOldStuff(int arg, ...) {
   *     super.visitOldStuff(int arg, ...); // optional
   *     [ do user stuff ]
   *   }
   * }
   * 
* *

and there are two cases: * *

    *
  • call visitOldStuff: in the call to super.visitOldStuff, the source is set to * SOURCE_DEPRECATED and visitNewStuff is called. Here 'do stuff' is run because the source * was previously set to SOURCE_DEPRECATED, and execution eventually returns to * UserStuffVisitor.visitOldStuff, where 'do user stuff' is run. *
  • call visitNewStuff: the call is redirected to UserStuffVisitor.visitOldStuff because the * source is 0. Execution continues as in the previous case, resulting in 'do stuff' and 'do * user stuff' being executed, in this order. *
* *

ASM subclasses

* *

In ASM packages, subclasses of StuffVisitor can typically be sub classed again by the user, * and can be used with API_OLD or API_NEW. Because of this, if such a subclass must override * visitNewStuff, it must do so in the following way (and must not override visitOldStuff): * *

   * public class AsmStuffVisitor extends StuffVisitor {
   *   @Override public void visitNewStuff(int argAndSource, ...) {
   *     if (api < API_NEW && (argAndSource & SOURCE_DEPRECATED) == 0) {
   *       super.visitNewStuff(argAndSource, ...);
   *       return;
   *     }
   *     super.visitNewStuff(argAndSource, ...); // optional
   *     int arg = argAndSource & ~SOURCE_MASK;
   *     [ do other stuff ]
   *   }
   * }
   * 
* *

If a user class extends this with 'api' equal to API_NEW, the class hierarchy is equivalent * to * *

   * public class StuffVisitor {
   *   @Deprecated public void visitOldStuff(int arg, ...) { visitNewStuf(arg, ...); }
   *   public void visitNewStuff(int arg, ...) { [ do stuff ] }
   * }
   * public class AsmStuffVisitor extends StuffVisitor {
   *   @Override public void visitNewStuff(int arg, ...) {
   *     super.visitNewStuff(arg, ...);
   *     [ do other stuff ]
   *   }
   * }
   * class UserStuffVisitor extends StuffVisitor {
   *   @Override public void visitNewStuff(int arg, ...) {
   *     super.visitNewStuff(int arg, ...);
   *     [ do user stuff ]
   *   }
   * }
   * 
* *

It is then obvious that whether visitNewStuff or visitOldStuff is called, 'do stuff', 'do * other stuff' and 'do user stuff' will be executed, in this order. If, on the other hand, a user * class extends AsmStuffVisitor with 'api' equal to API_OLD, the class hierarchy is equivalent to * *

   * public class StuffVisitor {
   *   @Deprecated public void visitOldStuff(int arg, ...) {
   *     visitNewStuf(arg | SOURCE_DEPRECATED, ...);
   *   }
   *   public void visitNewStuff(int argAndSource, ...) {
   *     if ((argAndSource & SOURCE_DEPRECATED) == 0) {
   *       visitOldStuff(argAndSource, ...);
   *     } else {
   *       int arg = argAndSource & ~SOURCE_MASK;
   *       [ do stuff ]
   *     }
   *   }
   * }
   * public class AsmStuffVisitor extends StuffVisitor {
   *   @Override public void visitNewStuff(int argAndSource, ...) {
   *     if ((argAndSource & SOURCE_DEPRECATED) == 0) {
   *       super.visitNewStuff(argAndSource, ...);
   *       return;
   *     }
   *     super.visitNewStuff(argAndSource, ...); // optional
   *     int arg = argAndSource & ~SOURCE_MASK;
   *     [ do other stuff ]
   *   }
   * }
   * class UserStuffVisitor extends StuffVisitor {
   *   @Override public void visitOldStuff(int arg, ...) {
   *     super.visitOldStuff(arg, ...);
   *     [ do user stuff ]
   *   }
   * }
   * 
* *

and, here again, whether visitNewStuff or visitOldStuff is called, 'do stuff', 'do other * stuff' and 'do user stuff' will be executed, in this order (exercise left to the reader). * *

Notes

* *
    *
  • the SOURCE_DEPRECATED flag is set only if 'api' is API_OLD, just before calling * visitNewStuff. By hypothesis, this method is not overridden by the user. Therefore, user * classes can never see this flag. Only ASM subclasses must take care of extracting the * actual argument value by clearing the source flags. *
  • because the SOURCE_DEPRECATED flag is immediately cleared in the caller, the caller can * call visitOldStuff or visitNewStuff (in 'do stuff' and 'do user stuff') on a delegate * visitor without any risks (breaking the redirection logic, "leaking" the flag, etc). *
  • all the scenarios discussed above are unit tested in MethodVisitorTest. *
*/ int SOURCE_DEPRECATED = 0x100; int SOURCE_MASK = SOURCE_DEPRECATED; // Java ClassFile versions (the minor version is stored in the 16 most significant bits, and the // major version in the 16 least significant bits). int V1_1 = 3 << 16 | 45; int V1_2 = 0 << 16 | 46; int V1_3 = 0 << 16 | 47; int V1_4 = 0 << 16 | 48; int V1_5 = 0 << 16 | 49; int V1_6 = 0 << 16 | 50; int V1_7 = 0 << 16 | 51; int V1_8 = 0 << 16 | 52; int V9 = 0 << 16 | 53; int V10 = 0 << 16 | 54; int V11 = 0 << 16 | 55; int V12 = 0 << 16 | 56; int V13 = 0 << 16 | 57; int V14 = 0 << 16 | 58; int V15 = 0 << 16 | 59; int V16 = 0 << 16 | 60; int V17 = 0 << 16 | 61; int V18 = 0 << 16 | 62; int V19 = 0 << 16 | 63; int V20 = 0 << 16 | 64; int V21 = 0 << 16 | 65; /** * Version flag indicating that the class is using 'preview' features. * *

{@code version & V_PREVIEW == V_PREVIEW} tests if a version is flagged with {@code * V_PREVIEW}. */ int V_PREVIEW = 0xFFFF0000; // Access flags values, defined in // - https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-4.html#jvms-4.1-200-E.1 // - https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-4.html#jvms-4.5-200-A.1 // - https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-4.html#jvms-4.6-200-A.1 // - https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-4.html#jvms-4.7.25 int ACC_PUBLIC = 0x0001; // class, field, method int ACC_PRIVATE = 0x0002; // class, field, method int ACC_PROTECTED = 0x0004; // class, field, method int ACC_STATIC = 0x0008; // field, method int ACC_FINAL = 0x0010; // class, field, method, parameter int ACC_SUPER = 0x0020; // class int ACC_SYNCHRONIZED = 0x0020; // method int ACC_OPEN = 0x0020; // module int ACC_TRANSITIVE = 0x0020; // module requires int ACC_VOLATILE = 0x0040; // field int ACC_BRIDGE = 0x0040; // method int ACC_STATIC_PHASE = 0x0040; // module requires int ACC_VARARGS = 0x0080; // method int ACC_TRANSIENT = 0x0080; // field int ACC_NATIVE = 0x0100; // method int ACC_INTERFACE = 0x0200; // class int ACC_ABSTRACT = 0x0400; // class, method int ACC_STRICT = 0x0800; // method int ACC_SYNTHETIC = 0x1000; // class, field, method, parameter, module * int ACC_ANNOTATION = 0x2000; // class int ACC_ENUM = 0x4000; // class(?) field inner int ACC_MANDATED = 0x8000; // field, method, parameter, module, module * int ACC_MODULE = 0x8000; // class // ASM specific access flags. // WARNING: the 16 least significant bits must NOT be used, to avoid conflicts with standard // access flags, and also to make sure that these flags are automatically filtered out when // written in class files (because access flags are stored using 16 bits only). int ACC_RECORD = 0x10000; // class int ACC_DEPRECATED = 0x20000; // class, field, method // Possible values for the type operand of the NEWARRAY instruction. // See https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-6.html#jvms-6.5.newarray. int T_BOOLEAN = 4; int T_CHAR = 5; int T_FLOAT = 6; int T_DOUBLE = 7; int T_BYTE = 8; int T_SHORT = 9; int T_INT = 10; int T_LONG = 11; // Possible values for the reference_kind field of CONSTANT_MethodHandle_info structures. // See https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-4.html#jvms-4.4.8. int H_GETFIELD = 1; int H_GETSTATIC = 2; int H_PUTFIELD = 3; int H_PUTSTATIC = 4; int H_INVOKEVIRTUAL = 5; int H_INVOKESTATIC = 6; int H_INVOKESPECIAL = 7; int H_NEWINVOKESPECIAL = 8; int H_INVOKEINTERFACE = 9; // ASM specific stack map frame types, used in {@link ClassVisitor#visitFrame}. /** An expanded frame. See {@link ClassReader#EXPAND_FRAMES}. */ int F_NEW = -1; /** A compressed frame with complete frame data. */ int F_FULL = 0; /** * A compressed frame where locals are the same as the locals in the previous frame, except that * additional 1-3 locals are defined, and with an empty stack. */ int F_APPEND = 1; /** * A compressed frame where locals are the same as the locals in the previous frame, except that * the last 1-3 locals are absent and with an empty stack. */ int F_CHOP = 2; /** * A compressed frame with exactly the same locals as the previous frame and with an empty stack. */ int F_SAME = 3; /** * A compressed frame with exactly the same locals as the previous frame and with a single value * on the stack. */ int F_SAME1 = 4; // Standard stack map frame element types, used in {@link ClassVisitor#visitFrame}. Integer TOP = Frame.ITEM_TOP; Integer INTEGER = Frame.ITEM_INTEGER; Integer FLOAT = Frame.ITEM_FLOAT; Integer DOUBLE = Frame.ITEM_DOUBLE; Integer LONG = Frame.ITEM_LONG; Integer NULL = Frame.ITEM_NULL; Integer UNINITIALIZED_THIS = Frame.ITEM_UNINITIALIZED_THIS; // The JVM opcode values (with the MethodVisitor method name used to visit them in comment, and // where '-' means 'same method name as on the previous line'). // See https://docs.oracle.com/javase/specs/jvms/se9/html/jvms-6.html. int NOP = 0; // visitInsn int ACONST_NULL = 1; // - int ICONST_M1 = 2; // - int ICONST_0 = 3; // - int ICONST_1 = 4; // - int ICONST_2 = 5; // - int ICONST_3 = 6; // - int ICONST_4 = 7; // - int ICONST_5 = 8; // - int LCONST_0 = 9; // - int LCONST_1 = 10; // - int FCONST_0 = 11; // - int FCONST_1 = 12; // - int FCONST_2 = 13; // - int DCONST_0 = 14; // - int DCONST_1 = 15; // - int BIPUSH = 16; // visitIntInsn int SIPUSH = 17; // - int LDC = 18; // visitLdcInsn int ILOAD = 21; // visitVarInsn int LLOAD = 22; // - int FLOAD = 23; // - int DLOAD = 24; // - int ALOAD = 25; // - int IALOAD = 46; // visitInsn int LALOAD = 47; // - int FALOAD = 48; // - int DALOAD = 49; // - int AALOAD = 50; // - int BALOAD = 51; // - int CALOAD = 52; // - int SALOAD = 53; // - int ISTORE = 54; // visitVarInsn int LSTORE = 55; // - int FSTORE = 56; // - int DSTORE = 57; // - int ASTORE = 58; // - int IASTORE = 79; // visitInsn int LASTORE = 80; // - int FASTORE = 81; // - int DASTORE = 82; // - int AASTORE = 83; // - int BASTORE = 84; // - int CASTORE = 85; // - int SASTORE = 86; // - int POP = 87; // - int POP2 = 88; // - int DUP = 89; // - int DUP_X1 = 90; // - int DUP_X2 = 91; // - int DUP2 = 92; // - int DUP2_X1 = 93; // - int DUP2_X2 = 94; // - int SWAP = 95; // - int IADD = 96; // - int LADD = 97; // - int FADD = 98; // - int DADD = 99; // - int ISUB = 100; // - int LSUB = 101; // - int FSUB = 102; // - int DSUB = 103; // - int IMUL = 104; // - int LMUL = 105; // - int FMUL = 106; // - int DMUL = 107; // - int IDIV = 108; // - int LDIV = 109; // - int FDIV = 110; // - int DDIV = 111; // - int IREM = 112; // - int LREM = 113; // - int FREM = 114; // - int DREM = 115; // - int INEG = 116; // - int LNEG = 117; // - int FNEG = 118; // - int DNEG = 119; // - int ISHL = 120; // - int LSHL = 121; // - int ISHR = 122; // - int LSHR = 123; // - int IUSHR = 124; // - int LUSHR = 125; // - int IAND = 126; // - int LAND = 127; // - int IOR = 128; // - int LOR = 129; // - int IXOR = 130; // - int LXOR = 131; // - int IINC = 132; // visitIincInsn int I2L = 133; // visitInsn int I2F = 134; // - int I2D = 135; // - int L2I = 136; // - int L2F = 137; // - int L2D = 138; // - int F2I = 139; // - int F2L = 140; // - int F2D = 141; // - int D2I = 142; // - int D2L = 143; // - int D2F = 144; // - int I2B = 145; // - int I2C = 146; // - int I2S = 147; // - int LCMP = 148; // - int FCMPL = 149; // - int FCMPG = 150; // - int DCMPL = 151; // - int DCMPG = 152; // - int IFEQ = 153; // visitJumpInsn int IFNE = 154; // - int IFLT = 155; // - int IFGE = 156; // - int IFGT = 157; // - int IFLE = 158; // - int IF_ICMPEQ = 159; // - int IF_ICMPNE = 160; // - int IF_ICMPLT = 161; // - int IF_ICMPGE = 162; // - int IF_ICMPGT = 163; // - int IF_ICMPLE = 164; // - int IF_ACMPEQ = 165; // - int IF_ACMPNE = 166; // - int GOTO = 167; // - int JSR = 168; // - int RET = 169; // visitVarInsn int TABLESWITCH = 170; // visiTableSwitchInsn int LOOKUPSWITCH = 171; // visitLookupSwitch int IRETURN = 172; // visitInsn int LRETURN = 173; // - int FRETURN = 174; // - int DRETURN = 175; // - int ARETURN = 176; // - int RETURN = 177; // - int GETSTATIC = 178; // visitFieldInsn int PUTSTATIC = 179; // - int GETFIELD = 180; // - int PUTFIELD = 181; // - int INVOKEVIRTUAL = 182; // visitMethodInsn int INVOKESPECIAL = 183; // - int INVOKESTATIC = 184; // - int INVOKEINTERFACE = 185; // - int INVOKEDYNAMIC = 186; // visitInvokeDynamicInsn int NEW = 187; // visitTypeInsn int NEWARRAY = 188; // visitIntInsn int ANEWARRAY = 189; // visitTypeInsn int ARRAYLENGTH = 190; // visitInsn int ATHROW = 191; // - int CHECKCAST = 192; // visitTypeInsn int INSTANCEOF = 193; // - int MONITORENTER = 194; // visitInsn int MONITOREXIT = 195; // - int MULTIANEWARRAY = 197; // visitMultiANewArrayInsn int IFNULL = 198; // visitJumpInsn int IFNONNULL = 199; // - }





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