Beispiel #1
0
 @JRubyMethod(rest = true, name = "start", meta = true, compat = RUBY1_9)
 public static RubyThread start19(IRubyObject recv, IRubyObject[] args, Block block) {
   Ruby runtime = recv.getRuntime();
   // The error message may appear incongruous here, due to the difference
   // between JRuby's Thread model and MRI's.
   // We mimic MRI's message in the name of compatibility.
   if (!block.isGiven())
     throw runtime.newArgumentError("tried to create Proc object without a block");
   return startThread(recv, args, false, block);
 }
Beispiel #2
0
  private static RubyTime createTime(IRubyObject recv, IRubyObject[] args, boolean gmt) {
    Ruby runtime = recv.getRuntime();
    int len = ARG_SIZE;
    Boolean isDst = null;

    DateTimeZone dtz;
    if (gmt) {
      dtz = DateTimeZone.UTC;
    } else if (args.length == 10 && args[9] instanceof RubyString) {
      dtz = getTimeZone(runtime, ((RubyString) args[9]).toString());
    } else {
      dtz = getLocalTimeZone(runtime);
    }

    if (args.length == 10) {
      if (args[8] instanceof RubyBoolean) {
        isDst = ((RubyBoolean) args[8]).isTrue();
      }
      args =
          new IRubyObject[] {
            args[5], args[4], args[3], args[2], args[1], args[0], runtime.getNil()
          };
    } else {
      // MRI accepts additional wday argument which appears to be ignored.
      len = args.length;

      if (len < ARG_SIZE) {
        IRubyObject[] newArgs = new IRubyObject[ARG_SIZE];
        System.arraycopy(args, 0, newArgs, 0, args.length);
        for (int i = len; i < ARG_SIZE; i++) {
          newArgs[i] = runtime.getNil();
        }
        args = newArgs;
        len = ARG_SIZE;
      }
    }

    if (args[0] instanceof RubyString) {
      args[0] = RubyNumeric.str2inum(runtime, (RubyString) args[0], 10, false);
    }

    int year = (int) RubyNumeric.num2long(args[0]);
    int month = 1;

    if (len > 1) {
      if (!args[1].isNil()) {
        IRubyObject tmp = args[1].checkStringType();
        if (!tmp.isNil()) {
          String monthString = tmp.toString().toLowerCase();
          Integer monthInt = MONTHS_MAP.get(monthString);

          if (monthInt != null) {
            month = monthInt;
          } else {
            try {
              month = Integer.parseInt(monthString);
            } catch (NumberFormatException nfExcptn) {
              throw runtime.newArgumentError("Argument out of range.");
            }
          }
        } else {
          month = (int) RubyNumeric.num2long(args[1]);
        }
      }
      if (1 > month || month > 12) {
        throw runtime.newArgumentError("Argument out of range: for month: " + month);
      }
    }

    int[] int_args = {1, 0, 0, 0, 0, 0};

    for (int i = 0; int_args.length >= i + 2; i++) {
      if (!args[i + 2].isNil()) {
        if (!(args[i + 2] instanceof RubyNumeric)) {
          args[i + 2] = args[i + 2].callMethod(runtime.getCurrentContext(), "to_i");
        }

        long value = RubyNumeric.num2long(args[i + 2]);
        if (time_min[i] > value || value > time_max[i]) {
          throw runtime.newArgumentError("argument out of range.");
        }
        int_args[i] = (int) value;
      }
    }

    if (!runtime.is1_9()) {
      if (0 <= year && year < 39) {
        year += 2000;
      } else if (69 <= year && year < 139) {
        year += 1900;
      }
    }

    DateTime dt;
    // set up with min values and then add to allow rolling over
    try {
      dt = new DateTime(year, 1, 1, 0, 0, 0, 0, DateTimeZone.UTC);

      dt =
          dt.plusMonths(month - 1)
              .plusDays(int_args[0] - 1)
              .plusHours(int_args[1])
              .plusMinutes(int_args[2])
              .plusSeconds(int_args[3]);
      if (runtime.is1_9() && !args[5].isNil()) {
        double millis = RubyFloat.num2dbl(args[5]);
        int int_millis = (int) (millis * 1000) % 1000;
        dt = dt.plusMillis(int_millis);
      }

      dt = dt.withZoneRetainFields(dtz);

      // we might need to perform a DST correction
      if (isDst != null) {
        // the instant at which we will ask dtz what the difference between DST and
        // standard time is
        long offsetCalculationInstant = dt.getMillis();

        // if we might be moving this time from !DST -> DST, the offset is assumed
        // to be the same as it was just before we last moved from DST -> !DST
        if (dtz.isStandardOffset(dt.getMillis())) {
          offsetCalculationInstant = dtz.previousTransition(offsetCalculationInstant);
        }

        int offset =
            dtz.getStandardOffset(offsetCalculationInstant)
                - dtz.getOffset(offsetCalculationInstant);

        if (!isDst && !dtz.isStandardOffset(dt.getMillis())) {
          dt = dt.minusMillis(offset);
        }
        if (isDst && dtz.isStandardOffset(dt.getMillis())) {
          dt = dt.plusMillis(offset);
        }
      }
    } catch (org.joda.time.IllegalFieldValueException e) {
      throw runtime.newArgumentError("time out of range");
    }

    RubyTime time = new RubyTime(runtime, (RubyClass) recv, dt);
    // Ignores usec if 8 args (for compatibility with parsedate) or if not supplied.
    if (args.length != 8 && !args[6].isNil()) {
      int usec = int_args[4] % 1000;
      int msec = int_args[4] / 1000;

      if (int_args[4] < 0) {
        msec -= 1;
        usec += 1000;
      }
      time.dt = dt.withMillis(dt.getMillis() + msec);
      time.setUSec(usec);
    }

    time.callInit(IRubyObject.NULL_ARRAY, Block.NULL_BLOCK);
    return time;
  }
Beispiel #3
0
  @JRubyMethod(required = 2, optional = 4)
  public IRubyObject primitive_convert(ThreadContext context, IRubyObject[] args) {
    Ruby runtime = context.runtime;

    RubyString input;
    RubyString output;
    int outputByteoffset = -1;
    int outputBytesize = 0;
    int flags = 0;

    int hashArg = -1;

    if (args.length > 2 && !args[2].isNil()) {
      if (args.length == 3 && args[2] instanceof RubyHash) {
        hashArg = 2;
      } else {
        outputByteoffset = (int) args[2].convertToInteger().getLongValue();
        if (outputByteoffset < 0) throw runtime.newArgumentError("negative offset");
      }
    }

    if (args.length > 3 && !args[3].isNil()) {
      if (args.length == 4 && args[3] instanceof RubyHash) {
        hashArg = 3;
      } else {
        outputBytesize = (int) args[3].convertToInteger().getLongValue();
        if (outputBytesize < 0) throw runtime.newArgumentError("negative bytesize");
      }
    }

    if (args.length > 4 && !args[4].isNil()) {
      if (args.length > 5 && !args[5].isNil()) {
        throw runtime.newArgumentError(args.length, 5);
      }

      if (args[4] instanceof RubyHash) {
        hashArg = 4;
      } else {
        flags = (int) args[4].convertToInteger().getLongValue();
      }
    }

    IRubyObject opt = context.nil;
    if (hashArg != -1 && !(opt = TypeConverter.checkHashType(runtime, args[hashArg])).isNil()) {
      IRubyObject v = ((RubyHash) opt).op_aref(context, runtime.newSymbol("partial_input"));
      if (v.isTrue()) {
        flags |= EncodingUtils.ECONV_PARTIAL_INPUT;
      }
      v = ((RubyHash) opt).op_aref(context, runtime.newSymbol("after_output"));
      if (v.isTrue()) {
        flags |= EncodingUtils.ECONV_AFTER_OUTPUT;
      }
    } else {
      flags = 0;
    }

    ByteList inBytes;
    ByteList outBytes;

    if (args[0].isNil()) {
      inBytes = new ByteList();
    } else {
      input = args[0].convertToString();
      input.modify19();
      inBytes = input.getByteList();
    }

    output = args[1].convertToString();
    output.modify19();
    outBytes = output.getByteList();

    if (outputByteoffset == -1) {
      outputByteoffset = outBytes.getRealSize();
    } else if (outputByteoffset > outBytes.getRealSize()) {
      throw runtime.newArgumentError("offset too big");
    }

    int outputByteEnd = outputByteoffset + outputBytesize;

    if (outputByteEnd > outBytes.getRealSize()) {
      outBytes.ensure(outputByteEnd);
    }

    RubyCoderResult result =
        transcoder.primitiveConvert(
            context,
            inBytes,
            output.getByteList(),
            outputByteoffset,
            outputBytesize,
            inBytes.getEncoding(),
            inBytes.getEncoding().isAsciiCompatible(),
            flags);

    outBytes.setEncoding(
        transcoder.outEncoding != null ? transcoder.outEncoding : inBytes.getEncoding());

    return symbolFromResult(result, runtime, flags, context);
  }