Exemple #1
0
  /**
   * Recursively process the file with the specified name. This method {@link #locate(String)
   * locates} the specified file, opens it, {@link #parse(Reader,File) parses} it, closes it, and
   * then {@link #process(Node) processes} the resulting AST node.
   *
   * @param name The file name.
   * @throws IllegalArgumentException Signals an inappropriate file (e.g., one that is too large).
   * @throws FileNotFoundException Signals that the file was not found.
   * @throws IOException Signals an I/O error while accessing the file.
   * @throws ParseException Signals a parse error.
   * @throws VisitingException Signals an error while visiting a node.
   */
  public void process(String name) throws IOException, ParseException {
    // Locate the file.
    File file = locate(name);

    // Open the file.
    Reader in = runtime.getReader(file);

    // Parse the file.
    Node root;
    try {
      root = parse(in, file);
    } finally {
      // Close the file.
      try {
        in.close();
      } catch (IOException x) {
        // Ignore.
      }
    }

    // Process the AST.
    process(root);
  }
Exemple #2
0
  /**
   * Run this tool with the specified command line arguments. This method works as following:
   *
   * <ol>
   *   <li>It calls {@link #init()} to initialize this tool.
   *   <li>It prints the {@link #getName() name}, {@link #getVersion() version}, and {@link
   *       #getCopy() copyright} to the {@link Runtime#console() console}.
   *   <li>If this tool has been invoked without arguments, it prints a description of all command
   *       line {@link Runtime#printOptions() options} and, optionally, an {@link #getExplanation()
   *       explanation}. It then exits.
   *   <li>It {@link Runtime#process(String[]) processes} the specified command line arguments and
   *       {@link #prepare() prepares} for processing the files. If any errors have been {@link
   *       Runtime#seenError() reported} during the two method calls, it exits.
   *   <li>For each file name specified on the command line, it {@link #locate(String) locates} the
   *       file, {@link #parse(Reader,File) parses} the contents, and {@link #process(Node)
   *       processes} the resulting AST. If the <code>-performance</code> command line option has
   *       been specified, it repeatedly parses and processes each file, measuring both latency and
   *       heap utilization. It then exits.
   * </ol>
   *
   * @param args The command line arguments.
   */
  public void run(String[] args) {
    // Initialize this tool.
    init();

    // Print the tool description and exit if there are no arguments.
    if (0 == args.length) {
      runtime.console().p(getName()).p(", v. ").p(getVersion()).p(", ").pln(getCopy());
      runtime.console().pln().pln("Usage: <option>* <file-name>+").pln().pln("Options are:");
      runtime.printOptions();

      final String explanation = getExplanation();
      if (null != explanation) {
        runtime.console().pln().wrap(0, explanation).pln();
      }
      runtime.console().pln().flush();
      if (runtime.hasValue("optionNoExit") && runtime.test("optionNoExit")) {
        return;
      } else {
        runtime.exit();
      }
    }

    // Process the command line arguments and print tool name.
    int index = runtime.process(args);

    if ((!runtime.hasValue("optionSilent")) || (!runtime.test("optionSilent"))) {
      runtime.console().p(getName()).p(", v. ").p(getVersion()).p(", ").pln(getCopy()).flush();
    }

    final boolean diagnose =
        runtime.hasValue("optionDiagnostics") && runtime.test("optionDiagnostics");

    if (index >= args.length && !diagnose) {
      runtime.error("no file names specified");
    }

    // Prepare for processing the files.
    prepare();

    // Print diagnostics.
    if (diagnose) diagnose();

    // Stop if there have been errors already.
    if (runtime.seenError()) {
      if (runtime.test("optionNoExit")) {
        return;
      } else {
        runtime.exit();
      }
    }

    // Process the files.
    final boolean silent = runtime.test("optionSilent");
    final boolean doGC = runtime.test("optionGC");
    final boolean measure = runtime.test("optionPerformance");
    final boolean parserOnly = runtime.test("optionMeasureParser");
    final boolean processOnly = runtime.test("optionMeasureProcessing");
    final int warmUp = measure ? runtime.getInt("runsWarmUp") : 0;
    final int total = measure ? runtime.getInt("runsTotal") : 1;
    final Statistics time = measure ? new Statistics() : null;
    final Statistics memory = measure ? new Statistics() : null;
    final Statistics fileSizes = measure ? new Statistics() : null;
    final Statistics latencies = measure ? new Statistics() : null;
    final Statistics heapSizes = measure ? new Statistics() : null;

    // If measuring, we need to print a legend.
    if (measure) {
      runtime
          .console()
          .p("Legend: file, size, time (ave, med, stdev), ")
          .pln("memory (ave, med, stdev)")
          .pln()
          .flush();
    }

    while (index < args.length) {
      // If we are neither silent nor measuring, report on activity.
      if ((!silent) && (!measure)) {
        runtime.console().p("Processing ").p(args[index]).pln(" ...").flush();
      }

      // Locate the file.
      File file = null;

      try {
        file = locate(args[index]);

      } catch (IllegalArgumentException x) {
        runtime.error(x.getMessage());

      } catch (FileNotFoundException x) {
        runtime.error(x.getMessage());

      } catch (IOException x) {
        if (null == x.getMessage()) {
          runtime.error(args[index] + ": I/O error");
        } else {
          runtime.error(args[index] + ": " + x.getMessage());
        }

      } catch (Throwable x) {
        runtime.error();
        x.printStackTrace();
      }

      // Parse and process the file.
      if (null != file) {
        if (measure) {
          time.reset();
          memory.reset();
        }

        for (int i = 0; i < total; i++) {
          Node ast = null;
          boolean success = false;

          // Perform GC if requested.
          if (doGC) {
            System.gc();
          }

          // Measure performance if requested.
          long startTime = 0;
          long startMemory = 0;
          if (measure && (!processOnly)) {
            startMemory = java.lang.Runtime.getRuntime().freeMemory();
            startTime = System.currentTimeMillis();
          }

          // Parse the input.
          Reader in = null;
          try {
            in = runtime.getReader(file);
            ast = parse(in, file);
            success = true;

          } catch (IllegalArgumentException x) {
            runtime.error(x.getMessage());

          } catch (FileNotFoundException x) {
            runtime.error(x.getMessage());

          } catch (UnsupportedEncodingException x) {
            runtime.error(x.getMessage());

          } catch (IOException x) {
            if (null == x.getMessage()) {
              runtime.error(args[index] + ": I/O error");
            } else {
              runtime.error(args[index] + ": " + x.getMessage());
            }

          } catch (ParseException x) {
            runtime.error();
            System.err.print(x.getMessage());

          } catch (Throwable x) {
            runtime.error();
            x.printStackTrace();

          } finally {
            if (null != in) {
              try {
                in.close();
              } catch (IOException x) {
                // Nothing to see here. Move on.
              }
            }
          }

          if (success && (null != ast) && (!parserOnly)) {
            // Measure processing only if requested.
            if (measure && processOnly) {
              startMemory = java.lang.Runtime.getRuntime().freeMemory();
              startTime = System.currentTimeMillis();
            }

            // Process the AST.
            try {
              process(ast);
            } catch (VisitingException x) {
              runtime.error();
              x.getCause().printStackTrace();
            } catch (Throwable x) {
              runtime.error();
              x.printStackTrace();
            }
          }

          // Collect performance data for this run if requested.
          if (measure) {
            final long endTime = System.currentTimeMillis();
            final long endMemory = java.lang.Runtime.getRuntime().freeMemory();

            if (i >= warmUp) {
              time.add(endTime - startTime);
              memory.add(startMemory - endMemory);
            }
          }
        }

        // Collect performance data for all the file's runs if
        // requested.
        if (measure) {
          final long fileSize = file.length();
          final double latency = time.mean();
          final double heapSize = memory.mean();

          fileSizes.add(fileSize / 1024.0);
          latencies.add(latency);
          heapSizes.add(heapSize / 1024.0);

          runtime
              .console()
              .p(args[index])
              .p(' ')
              .p(fileSize)
              .p(' ')
              .p(Statistics.round(latency))
              .p(' ')
              .p(time.median())
              .p(' ')
              .p(Statistics.round(time.stdev()))
              .p(' ')
              .p(Statistics.round(heapSize))
              .p(' ')
              .p(memory.median())
              .p(' ')
              .pln(Statistics.round(memory.stdev()))
              .flush();
        }
      }

      // Next file.
      index++;
    }

    // Wrap up.
    wrapUp();

    // Print overall statistics, if requested.
    if (measure) {
      final double totalTime = latencies.sum();
      final double totalMemory = heapSizes.sum();
      final double throughput = 1000.0 / Statistics.fitSlope(fileSizes, latencies);
      final double heapUtil = Statistics.fitSlope(fileSizes, heapSizes);

      runtime
          .console()
          .pln()
          .p("Total time               : ")
          .p(Statistics.round(totalTime))
          .pln(" ms")
          .p("Total memory             : ")
          .p(Statistics.round(totalMemory))
          .pln(" KB")
          .p("Average throughput       : ")
          .p(Statistics.round(throughput))
          .pln(" KB/s")
          .p("Average heap utilization : ")
          .p(Statistics.round(heapUtil))
          .pln(":1")
          .flush();
    }

    // Done.
    if (!runtime.test("optionNoExit")) runtime.exit();
  }