hotspot/src/share/vm/classfile/stackMapFrame.hpp
author cfang
Thu, 20 Aug 2009 12:42:57 -0700
changeset 3686 69c1b5228547
parent 1 489c9b5090e2
child 5547 f4b087cbb361
permissions -rw-r--r--
6873116: Modify reexecute implementation to use pcDesc to record the reexecute bit Summary: use PcDesc to keep record of the reexecute bit instead of using DebugInfoStreams Reviewed-by: kvn, never, twisti

/*
 * Copyright 2003-2006 Sun Microsystems, Inc.  All Rights Reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
 * CA 95054 USA or visit www.sun.com if you need additional information or
 * have any questions.
 *
 */

// A StackMapFrame represents one frame in the stack map attribute.

enum {
  FLAG_THIS_UNINIT = 0x01
};

class StackMapFrame : public ResourceObj {
 private:
  int32_t _offset;

  // See comment in StackMapTable about _frame_count about why these
  // fields are int32_t instead of u2.
  int32_t _locals_size;  // number of valid type elements in _locals
  int32_t _stack_size;   // number of valid type elements in _stack

  int32_t _max_locals;
  int32_t _max_stack;

  u1 _flags;
  VerificationType* _locals; // local variable type array
  VerificationType* _stack;  // operand stack type array

  ClassVerifier* _verifier;  // the verifier verifying this method

 public:
  // constructors

  // This constructor is used by the type checker to allocate frames
  // in type state, which have _max_locals and _max_stack array elements
  // in _locals and _stack.
  StackMapFrame(u2 max_locals, u2 max_stack, ClassVerifier* verifier);

  // This constructor is used to initialize stackmap frames in stackmap table,
  // which have _locals_size and _stack_size array elements in _locals and _stack.
  StackMapFrame(int32_t offset,
                u1 flags,
                u2 locals_size,
                u2 stack_size,
                u2 max_locals,
                u2 max_stack,
                VerificationType* locals,
                VerificationType* stack,
                ClassVerifier* v) : _offset(offset), _flags(flags),
                                    _locals_size(locals_size),
                                    _stack_size(stack_size),
                                    _max_locals(max_locals),
                                    _max_stack(max_stack),
                                    _locals(locals), _stack(stack),
                                    _verifier(v) { }

  inline void set_offset(int32_t offset)      { _offset = offset; }
  inline void set_verifier(ClassVerifier* v)  { _verifier = v; }
  inline void set_flags(u1 flags)             { _flags = flags; }
  inline void set_locals_size(u2 locals_size) { _locals_size = locals_size; }
  inline void set_stack_size(u2 stack_size)   { _stack_size = stack_size; }
  inline void clear_stack()                   { _stack_size = 0; }
  inline int32_t offset()   const             { return _offset; }
  inline ClassVerifier* verifier() const      { return _verifier; }
  inline u1 flags() const                     { return _flags; }
  inline int32_t locals_size() const          { return _locals_size; }
  inline VerificationType* locals() const     { return _locals; }
  inline int32_t stack_size() const           { return _stack_size; }
  inline VerificationType* stack() const      { return _stack; }
  inline int32_t max_locals() const           { return _max_locals; }
  inline int32_t max_stack() const            { return _max_stack; }
  inline bool flag_this_uninit() const        { return _flags & FLAG_THIS_UNINIT; }

  // Set locals and stack types to bogus
  inline void reset() {
    int32_t i;
    for (i = 0; i < _max_locals; i++) {
      _locals[i] = VerificationType::bogus_type();
    }
    for (i = 0; i < _max_stack; i++) {
      _stack[i] = VerificationType::bogus_type();
    }
  }

  // Return a StackMapFrame with the same local variable array and empty stack.
  // Stack array is allocate with unused one element.
  StackMapFrame* frame_in_exception_handler(u1 flags);

  // Set local variable type array based on m's signature.
  VerificationType set_locals_from_arg(
    const methodHandle m, VerificationType thisKlass, TRAPS);

  // Search local variable type array and stack type array.
  // Return true if an uninitialized object is found.
  bool has_new_object() const;

  // Search local variable type array and stack type array.
  // Set every element with type of old_object to new_object.
  void initialize_object(
    VerificationType old_object, VerificationType new_object);

  // Copy local variable type array in src into this local variable type array.
  void copy_locals(const StackMapFrame* src);

  // Copy stack type array in src into this stack type array.
  void copy_stack(const StackMapFrame* src);

  // Return true if this stack map frame is assignable to target.
  bool is_assignable_to(const StackMapFrame* target, TRAPS) const;

  // Push type into stack type array.
  inline void push_stack(VerificationType type, TRAPS) {
    assert(!type.is_check(), "Must be a real type");
    if (_stack_size >= _max_stack) {
      verifier()->verify_error(_offset, "Operand stack overflow");
      return;
    }
    _stack[_stack_size++] = type;
  }

  inline void push_stack_2(
      VerificationType type1, VerificationType type2, TRAPS) {
    assert(type1.is_long() || type1.is_double(), "must be long/double");
    assert(type2.is_long2() || type2.is_double2(), "must be long/double_2");
    if (_stack_size >= _max_stack - 1) {
      verifier()->verify_error(_offset, "Operand stack overflow");
      return;
    }
    _stack[_stack_size++] = type1;
    _stack[_stack_size++] = type2;
  }

  // Pop and return the top type on stack without verifying.
  inline VerificationType pop_stack(TRAPS) {
    if (_stack_size <= 0) {
      verifier()->verify_error(_offset, "Operand stack underflow");
      return VerificationType::bogus_type();
    }
    // Put bogus type to indicate it's no longer valid.
    // Added to make it consistent with the other pop_stack method.
    VerificationType top = _stack[--_stack_size];
    NOT_PRODUCT( _stack[_stack_size] = VerificationType::bogus_type(); )
    return top;
  }

  // Pop and return the top type on stack type array after verifying it
  // is assignable to type.
  inline VerificationType pop_stack(VerificationType type, TRAPS) {
    if (_stack_size != 0) {
      VerificationType top = _stack[_stack_size - 1];
      bool subtype = type.is_assignable_from(
        top, verifier()->current_class(),
        CHECK_(VerificationType::bogus_type()));
      if (subtype) {
        _stack_size --;
        NOT_PRODUCT( _stack[_stack_size] = VerificationType::bogus_type(); )
        return top;
      }
    }
    return pop_stack_ex(type, THREAD);
  }

  inline void pop_stack_2(
      VerificationType type1, VerificationType type2, TRAPS) {
    assert(type1.is_long2() || type1.is_double2(), "must be long/double");
    assert(type2.is_long() || type2.is_double(), "must be long/double_2");
    if (_stack_size >= 2) {
      VerificationType top1 = _stack[_stack_size - 1];
      bool subtype1 = type1.is_assignable_from(
        top1, verifier()->current_class(), CHECK);
      VerificationType top2 = _stack[_stack_size - 2];
      bool subtype2 = type2.is_assignable_from(
        top2, verifier()->current_class(), CHECK);
      if (subtype1 && subtype2) {
        _stack_size -= 2;
        NOT_PRODUCT( _stack[_stack_size] = VerificationType::bogus_type(); )
        NOT_PRODUCT( _stack[_stack_size+1] = VerificationType::bogus_type(); )
        return;
      }
    }
    pop_stack_ex(type1, THREAD);
    pop_stack_ex(type2, THREAD);
  }

  // Uncommon case that throws exceptions.
  VerificationType pop_stack_ex(VerificationType type, TRAPS);

  // Return the type at index in local variable array after verifying
  // it is assignable to type.
  VerificationType get_local(int32_t index, VerificationType type, TRAPS);
  // For long/double.
  void get_local_2(
    int32_t index, VerificationType type1, VerificationType type2, TRAPS);

  // Set element at index in local variable array to type.
  void set_local(int32_t index, VerificationType type, TRAPS);
  // For long/double.
  void set_local_2(
    int32_t index, VerificationType type1, VerificationType type2, TRAPS);

  // Private auxiliary method used only in is_assignable_to(StackMapFrame).
  // Returns true if src is assignable to target.
  bool is_assignable_to(
    VerificationType* src, VerificationType* target, int32_t len, TRAPS) const;

  // Debugging
  void print() const PRODUCT_RETURN;
};