예제 #1
0
  public static void dumpcode(final MethodEditor m) {

    final PrintWriter out = new PrintWriter(System.out, true);
    final StackHeightCounter shc = new StackHeightCounter(m);

    out.println("Code for method " + m.name() + m.type());
    final List instructions = m.code();
    final ListIterator iter = instructions.listIterator();
    while (iter.hasNext()) {
      final Object obj = iter.next();
      if (obj instanceof Label) {
        shc.handle((Label) obj);
      } else if (obj instanceof Instruction) {
        shc.handle((Instruction) obj);
      }

      System.out.println("        " + obj + " (sh: " + shc.height() + ")");
    }
  }
예제 #2
0
  /** Runs BLOAT on a method. */
  public static void bloatMethod(final MethodEditor m, final BloatContext context) {
    try {
      if (Main.COMPACT_ARRAY_INIT) {
        // Compact the initialization of arrays of the basic types by
        // putting the values of the array into a string in the constant
        // pool. The initialization code is replaced with a loop that
        // loads the array from the string in the constant pool.

        if (Main.TRACE) {
          System.out.println("  Compacting Arrays: " + Main.dateFormat.format(new Date()));
        }

        CompactArrayInitializer.transform(m);

        if (Main.DEBUG) {
          System.out.println("---------- After compaction:");
          m.print(System.out);
          System.out.println("---------- end print");
        }
      }

      FlowGraph cfg; // The control flow graph for a method

      if (Main.TRACE) {
        System.out.println("  Constructing CFG: " + Main.dateFormat.format(new Date()));
      }

      try {
        // Construct the control flow graph for method m
        cfg = new FlowGraph(m);
      } catch (final ClassFormatException ex) {
        System.err.println(ex.getMessage());
        context.release(m.methodInfo());
        return;
      }

      // We separate out initialization since before this the FlowGraph
      // more exactly represents the input program.
      cfg.initialize();

      if (Main.TRACE) {
        System.out.println("  Transforming to SSA: " + Main.dateFormat.format(new Date()));
      }

      SSA.transform(cfg);

      if (FlowGraph.DEBUG) {
        System.out.println("---------- After SSA:");
        cfg.print(System.out);
        System.out.println("---------- end print");
      }

      if (Main.DEBUG) {
        cfg.visit(new VerifyCFG(false));
      }

      if (!Tree.USE_STACK) {
        // Do copy propagation and value numbering first to get rid of
        // all the extra copies inserted for dups. If they're left in,
        // it really slows down value numbering.
        if (Main.PROP) {
          if (Main.DEBUG) {
            System.out.println("-----Before Copy Propagation-----");
          }

          if (Main.TRACE) {
            System.out.println("  Copy propagation: " + Main.dateFormat.format(new Date()));
          }

          final ExprPropagation copy = new ExprPropagation(cfg);
          copy.transform();

          if (Main.DEBUG) {
            cfg.visit(new VerifyCFG(false));
          }

          if (Main.DEBUG) {
            System.out.println("------After Copy Propagation-----");
            cfg.print(System.out);
          }
        }
      }

      DeadCodeElimination dce = null;

      if (Main.DCE) {

        if (Main.TRACE) {
          System.out.println("  Dead Code Elimination: " + Main.dateFormat.format(new Date()));
        }

        if (Main.DEBUG) {
          System.out.println("---Before Dead Code Elimination--");
        }

        dce = new DeadCodeElimination(cfg);
        dce.transform();

        if (Main.DEBUG) {
          cfg.visit(new VerifyCFG(false));
        }

        if (Main.DEBUG) {
          System.out.println("---After Dead Code Elimination---");
          cfg.print(System.out);
        }
      }

      if (Main.INFER) {

        if (Main.DEBUG) {
          System.out.println("---------Doing type inference--------");
        }

        if (Main.TRACE) {
          System.out.println("  Type Inferencing: " + Main.dateFormat.format(new Date()));
        }

        TypeInference.transform(cfg, context.getHierarchy());
      }

      if (Main.NUMBER) {

        if (Main.TRACE) {
          System.out.println("  Value Numbering: " + Main.dateFormat.format(new Date()));
        }

        if (Main.DEBUG) {
          System.out.println("--------Doing value numbering--------");
        }

        (new ValueNumbering()).transform(cfg);
      }

      if (Main.FOLD) {
        if (Main.DEBUG) {
          System.out.println("--------Before Value Folding---------");
        }

        if (Main.TRACE) {
          System.out.println("  Value Folding: " + Main.dateFormat.format(new Date()));
        }

        (new ValueFolding()).transform(cfg);

        if (Main.DEBUG) {
          cfg.visit(new VerifyCFG());
        }

        if (Main.DEBUG) {
          System.out.println("---------After Value Folding---------");
          cfg.print(System.out);
        }
      }

      if (Main.PRE) {
        if (Main.DEBUG) {
          System.out.println("-------------Before SSAPRE-----------");
        }

        if (Main.TRACE) {
          System.out.println("  SSAPRE: " + Main.dateFormat.format(new Date()));
        }

        final SSAPRE pre = new SSAPRE(cfg, context);
        pre.transform();

        if (Main.DEBUG) {
          cfg.visit(new VerifyCFG());
        }

        if (Main.DEBUG) {
          System.out.println("-------------After SSAPRE------------");
          cfg.print(System.out);
        }
      }

      if (Main.FOLD) {
        if (Main.DEBUG) {
          System.out.println("--------Before Value Folding---------");
        }

        if (Main.TRACE) {
          System.out.println("  Value Folding: " + Main.dateFormat.format(new Date()));
        }

        (new ValueFolding()).transform(cfg);

        if (Main.DEBUG) {
          cfg.visit(new VerifyCFG());
        }

        if (Main.DEBUG) {
          System.out.println("---------After Value Folding---------");
          cfg.print(System.out);
        }
      }

      if (Main.PROP) {
        if (Main.DEBUG) {
          System.out.println("-------Before Copy Propagation-------");
        }

        if (Main.TRACE) {
          System.out.println("  Copy Propagation " + Main.dateFormat.format(new Date()));
        }

        final ExprPropagation copy = new ExprPropagation(cfg);
        copy.transform();

        if (Main.DEBUG) {
          cfg.visit(new VerifyCFG());
        }

        if (Main.DEBUG) {
          System.out.println("--------After Copy Propagation-------");
          cfg.print(System.out);
        }
      }

      // make sure we've done at least one thing since the last DCE
      if (Main.DCE && (Main.INFER || Main.NUMBER || Main.FOLD || Main.PRE || Main.PROP)) {
        if (Main.DEBUG) {
          System.out.println("-----Before Dead Code Elimination----");
        }

        if (Main.TRACE) {
          System.out.println("  Dead Code Elimination: " + Main.dateFormat.format(new Date()));
        }

        dce = new DeadCodeElimination(cfg);
        dce.transform();

        if (Main.DEBUG) {
          cfg.visit(new VerifyCFG());
        }

        if (Main.DEBUG) {
          System.out.println("-----After Dead Code Elimination-----");
          cfg.print(System.out);
        }
      }

      if (Main.PERSIST) {
        (new PersistentCheckElimination()).transform(cfg);
      }

      if (Main.DIVA) {
        if (Main.DEBUG) {
          System.out.println("-----Before DIVA------");
        }

        if (Main.TRACE) {
          System.out.println("  DIVA: " + Main.dateFormat.format(new Date()));
        }

        (new InductionVarAnalyzer()).transform(cfg);

        if (Main.DEBUG) {
          System.out.println("-----After DIVA-----");
          cfg.print(System.out);
        }
      }

      /*
       * if (STACK_ALLOC) { if (DEBUG) {
       * System.out.println("------------Before StackPRE----------"); }
       *
       * StackPRE pre = new StackPRE(cfg); pre.transform();
       *
       * if (DEBUG) { cfg.visit(new VerifyCFG()); }
       *
       * if (DEBUG) { System.out.println("------------After
       * StackPRE-----------"); cfg.print(System.out); } }
       */

      // Do the new stack optimization
      if (Main.OPT_STACK_2) {

        if (Main.TRACE) {
          System.out.println("  New stack optimization: " + Main.dateFormat.format(new Date()));
        }

        // generate code without doing liveness or register allocation
        final CodeGenerator codegen = new CodeGenerator(m);
        codegen.replacePhis(cfg);
        m.clearCode2();
        cfg.visit(codegen);
        // do stack optimization on the bytecode

        final StackOpt so = new StackOpt();
        so.transform(m);

        // convert it back to a cfg
        cfg = new FlowGraph(m);
        cfg.initialize();

        // convert it back to SSA
        SSA.transform(cfg);

        // do more dead code elimination (eliminate stores)
        dce = new DeadCodeElimination(cfg);
        dce.transform();
      }

      if (Main.TRACE) {
        System.out.println("  Register allocation: " + Main.dateFormat.format(new Date()));
      }

      if (Main.VERIFY) {
        try {
          cfg.visit(new VerifyCFG());
        } catch (final IllegalArgumentException ee) {
          System.out.println(
              " NOTE: CFG did not verify while "
                  + "bloating "
                  + m.name()
                  + " after all optimizations. Exception: "
                  + ee);
        }
      }

      // We're all done performing optimizations. Let's generate some code
      // and go home.

      // Perform liveness analysis of variables in the method.
      // Assign local variables ("registers") to expression values.
      final Liveness liveness = new Liveness(cfg);
      final RegisterAllocator alloc = new RegisterAllocator(cfg, liveness);

      // Gather information which can be used to optimize use of the stack
      if (CodeGenerator.OPT_STACK) {
        if (Main.TRACE) {
          System.out.println("  Old stack optimization: " + Main.dateFormat.format(new Date()));
        }
        StackOptimizer.optimizeCFG(cfg);
      }

      if (Main.TRACE) {
        System.out.println("  Code Generation: " + Main.dateFormat.format(new Date()));
      }

      // Start the code generation process.
      final CodeGenerator codegen = new CodeGenerator(m);
      codegen.replacePhis(cfg);

      if (Main.DEBUG) {
        System.out.println("After fixing Phis------------------------");
        cfg.print(System.out);
        System.out.println("End print--------------------------------");
      }

      codegen.simplifyControlFlow(cfg);
      codegen.allocReturnAddresses(cfg, alloc);

      if (Main.DEBUG) {
        System.out.println("After removing empty blocks--------------");
        cfg.print(System.out);
        System.out.println("End print--------------------------------");
      }

      // Clear the old contents of the bytecode store and generate new
      // code.
      // Code is generated using a visitor pattern on the CFG.
      m.clearCode();
      cfg.visit(codegen);

      Peephole.transform(m);

      // Commit any changes that have been made to the method
      context.commit(m.methodInfo());

    } catch (final Exception ex99) {
      final String msg =
          "** Exception while optimizing "
              + m.name()
              + m.type()
              + " of class "
              + m.declaringClass().name();
      System.err.println(msg);
      System.err.println(ex99.getMessage());
      ex99.printStackTrace(System.err);
      System.exit(1);
    }
  }
예제 #3
0
  /**
   * Performs the actual editing of a class. Does a whole mess of stuff including reading in the
   * classfile, building data structures to represent the class file, converting the CFG for each
   * method in the class into SSA form, perform some anlayses and optimizations on the method, and
   * finally committing it back to the class file. Phew.
   */
  private static void editClass(final String className) {
    ClassFile classFile; // Holds info about a class (implements
    // ClassInfo)

    // Get information about the class className
    try {
      classFile = (ClassFile) Main.context.loadClass(className);
    } catch (final ClassNotFoundException ex) {
      System.err.println("** Couldn't find class: " + ex.getMessage());
      return;
    }

    if (!Main.FORCE) {
      // Check to see if the file is up-to-date (i.e. has been
      // recompiled since it was last optimized). If so, do nothing
      // because the FORCE flag is false.

      final File source = classFile.file();
      final File target = classFile.outputFile();

      if ((source != null)
          && (target != null)
          && source.exists()
          && target.exists()
          && (source.lastModified() < target.lastModified())) {

        if (Main.VERBOSE) {
          System.out.println(classFile.name() + " is up to date");
        }

        return;
      }
    }

    if (Main.DEBUG) {
      // Print the contents of the class file to System.out
      classFile.print(System.out);
    }

    final ClassEditor c = Main.context.editClass(classFile);

    boolean skip = false;

    final String name = c.type().className();
    final String qual = c.type().qualifier() + "/*";

    // Edit only classes explicitly mentioned.
    if (Main.ONLY.size() > 0) {
      skip = true;

      // Only edit classes we explicitly don't name.
      for (int i = 0; i < Main.ONLY.size(); i++) {
        final String pkg = (String) Main.ONLY.get(i);

        if (name.equals(pkg) || qual.equals(pkg)) {
          skip = false;
          break;
        }
      }
    }

    // Don't edit classes we explicitly skip.
    if (!skip) {
      for (int i = 0; i < Main.SKIP.size(); i++) {
        final String pkg = (String) Main.SKIP.get(i);

        if (name.equals(pkg) || qual.equals(pkg)) {
          skip = true;
          break;
        }
      }
    }

    if (skip) {
      if (Main.VERBOSE) {
        System.out.println("Skipping " + c.type().className());
      }

      // We're done with this class file, decrement its reference count
      Main.context.release(classFile);
      return;
    }

    // Touch the output file first. That is, create the file, but make
    // it empty, just to make sure we can create it.

    try {
      final File f = classFile.outputFile();

      if (f.exists()) {
        f.delete();
      }

      final File dir = new File(f.getParent());
      dir.mkdirs();

      if (!dir.exists()) {
        throw new RuntimeException("Couldn't create directory: " + dir);
      }

      final DataOutputStream out = new DataOutputStream(new FileOutputStream(f));
      new PrintStream(out).println();
      out.close();
    } catch (final IOException e) {
      e.printStackTrace();
      System.exit(1);
    }

    if (Main.VERBOSE) {
      System.out.println("Optimizing " + c.type().className());
    }

    // Finally, we can start playing with the methods...
    final MethodInfo[] methods = c.methods();

    final int numMethods = methods.length + 1;
    ;
    int whichMethod = 0;

    for (int j = 0; j < methods.length; j++) {
      final MethodEditor m;

      try {
        m = Main.context.editMethod(methods[j]);
      } catch (final ClassFormatException ex) {
        System.err.println(ex.getMessage());
        continue;
      }

      if (Main.TRACE) {
        whichMethod++;
        System.out.println(
            "Optimizing "
                + name
                + "."
                + m.name()
                + " (method "
                + whichMethod
                + " of "
                + numMethods
                + ")");
      }

      if (Main.METHOD != null) {
        // A method name has been specified on the command line using
        // -only-method.
        boolean pass = true;

        String t = m.name() + m.type();

        if (t.equals(Main.METHOD)) {
          pass = false;
        }

        t = m.name();

        if (t.equals(Main.METHOD)) {
          pass = false;
        }

        if (pass) {
          // This isn't the method we're looking for.
          // Decrement its reference count.
          Main.context.release(methods[j]);
          continue;
        }
      }

      if (Main.DEBUG) {
        m.print(System.out);
      }

      if (m.isNative() || m.isAbstract()) {
        // We can't edit native or abstract methods
        Main.context.release(methods[j]);
        continue;
      }

      Main.bloatMethod(m, Main.context);
    }

    if (Main.ANNO) {
      String s = "Optimized with: EDU.purdue.cs.bloat.optimize.Main";

      for (int i = 0; i < Main.ARGS.length; i++) {
        if ((Main.ARGS[i].indexOf(' ') >= 0)
            || (Main.ARGS[i].indexOf('\t') >= 0)
            || (Main.ARGS[i].indexOf('\r') >= 0)
            || (Main.ARGS[i].indexOf('\n') >= 0)) {
          s += " '" + Main.ARGS[i] + "'";
        } else {
          s += " " + Main.ARGS[i];
        }
      }

      System.out.println(s);
      // c.constants().addConstant(Constant.UTF8, s);
    }

    Main.context.commit(classFile);
    Main.context.release(classFile);

    if (Main.TRACE) {
      System.out.println(Main.context.toString());
    }
  }