diff --git a/Classes/PHPExcel/Calculation/DateTime.php b/Classes/PHPExcel/Calculation/DateTime.php
new file mode 100644
index 00000000..6c94f050
--- /dev/null
+++ b/Classes/PHPExcel/Calculation/DateTime.php
@@ -0,0 +1,1178 @@
+format('m');
+ $oYear = (int) $PHPDateObject->format('Y');
+
+ $adjustmentMonthsString = (string) $adjustmentMonths;
+ if ($adjustmentMonths > 0) {
+ $adjustmentMonthsString = '+'.$adjustmentMonths;
+ }
+ if ($adjustmentMonths != 0) {
+ $PHPDateObject->modify($adjustmentMonthsString.' months');
+ }
+ $nMonth = (int) $PHPDateObject->format('m');
+ $nYear = (int) $PHPDateObject->format('Y');
+
+ $monthDiff = ($nMonth - $oMonth) + (($nYear - $oYear) * 12);
+ if ($monthDiff != $adjustmentMonths) {
+ $adjustDays = (int) $PHPDateObject->format('d');
+ $adjustDaysString = '-'.$adjustDays.' days';
+ $PHPDateObject->modify($adjustDaysString);
+ }
+ return $PHPDateObject;
+ } // function _adjustDateByMonths()
+
+
+ /**
+ * DATETIMENOW
+ *
+ * @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
+ * depending on the value of the ReturnDateType flag
+ */
+ public static function DATETIMENOW() {
+ $saveTimeZone = date_default_timezone_get();
+ date_default_timezone_set('UTC');
+ $retValue = False;
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ $retValue = (float) PHPExcel_Shared_Date::PHPToExcel(time());
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ $retValue = (integer) time();
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ $retValue = new DateTime();
+ break;
+ }
+ date_default_timezone_set($saveTimeZone);
+
+ return $retValue;
+ } // function DATETIMENOW()
+
+
+ /**
+ * DATENOW
+ *
+ * @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
+ * depending on the value of the ReturnDateType flag
+ */
+ public static function DATENOW() {
+ $saveTimeZone = date_default_timezone_get();
+ date_default_timezone_set('UTC');
+ $retValue = False;
+ $excelDateTime = floor(PHPExcel_Shared_Date::PHPToExcel(time()));
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ $retValue = (float) $excelDateTime;
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ $retValue = (integer) PHPExcel_Shared_Date::ExcelToPHP($excelDateTime) - 3600;
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ $retValue = PHPExcel_Shared_Date::ExcelToPHPObject($excelDateTime);
+ break;
+ }
+ date_default_timezone_set($saveTimeZone);
+
+ return $retValue;
+ } // function DATENOW()
+
+
+ /**
+ * DATE
+ *
+ * @param long $year
+ * @param long $month
+ * @param long $day
+ * @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
+ * depending on the value of the ReturnDateType flag
+ */
+ public static function DATE($year = 0, $month = 1, $day = 1) {
+ $year = (integer) PHPExcel_Calculation_Functions::flattenSingleValue($year);
+ $month = (integer) PHPExcel_Calculation_Functions::flattenSingleValue($month);
+ $day = (integer) PHPExcel_Calculation_Functions::flattenSingleValue($day);
+
+ $baseYear = PHPExcel_Shared_Date::getExcelCalendar();
+ // Validate parameters
+ if ($year < ($baseYear-1900)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ((($baseYear-1900) != 0) && ($year < $baseYear) && ($year >= 1900)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ if (($year < $baseYear) && ($year >= ($baseYear-1900))) {
+ $year += 1900;
+ }
+
+ if ($month < 1) {
+ // Handle year/month adjustment if month < 1
+ --$month;
+ $year += ceil($month / 12) - 1;
+ $month = 13 - abs($month % 12);
+ } elseif ($month > 12) {
+ // Handle year/month adjustment if month > 12
+ $year += floor($month / 12);
+ $month = ($month % 12);
+ }
+
+ // Re-validate the year parameter after adjustments
+ if (($year < $baseYear) || ($year >= 10000)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ $excelDateValue = PHPExcel_Shared_Date::FormattedPHPToExcel($year, $month, $day);
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ return (float) $excelDateValue;
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ return (integer) PHPExcel_Shared_Date::ExcelToPHP($excelDateValue);
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ return PHPExcel_Shared_Date::ExcelToPHPObject($excelDateValue);
+ break;
+ }
+ } // function DATE()
+
+
+ /**
+ * TIME
+ *
+ * @param long $hour
+ * @param long $minute
+ * @param long $second
+ * @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
+ * depending on the value of the ReturnDateType flag
+ */
+ public static function TIME($hour = 0, $minute = 0, $second = 0) {
+ $hour = PHPExcel_Calculation_Functions::flattenSingleValue($hour);
+ $minute = PHPExcel_Calculation_Functions::flattenSingleValue($minute);
+ $second = PHPExcel_Calculation_Functions::flattenSingleValue($second);
+
+ if ($hour == '') { $hour = 0; }
+ if ($minute == '') { $minute = 0; }
+ if ($second == '') { $second = 0; }
+
+ if ((!is_numeric($hour)) || (!is_numeric($minute)) || (!is_numeric($second))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $hour = (integer) $hour;
+ $minute = (integer) $minute;
+ $second = (integer) $second;
+
+ if ($second < 0) {
+ $minute += floor($second / 60);
+ $second = 60 - abs($second % 60);
+ if ($second == 60) { $second = 0; }
+ } elseif ($second >= 60) {
+ $minute += floor($second / 60);
+ $second = $second % 60;
+ }
+ if ($minute < 0) {
+ $hour += floor($minute / 60);
+ $minute = 60 - abs($minute % 60);
+ if ($minute == 60) { $minute = 0; }
+ } elseif ($minute >= 60) {
+ $hour += floor($minute / 60);
+ $minute = $minute % 60;
+ }
+
+ if ($hour > 23) {
+ $hour = $hour % 24;
+ } elseif ($hour < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ $date = 0;
+ $calendar = PHPExcel_Shared_Date::getExcelCalendar();
+ if ($calendar != PHPExcel_Shared_Date::CALENDAR_WINDOWS_1900) {
+ $date = 1;
+ }
+ return (float) PHPExcel_Shared_Date::FormattedPHPToExcel($calendar, 1, $date, $hour, $minute, $second);
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ return (integer) PHPExcel_Shared_Date::ExcelToPHP(PHPExcel_Shared_Date::FormattedPHPToExcel(1970, 1, 1, $hour-1, $minute, $second)); // -2147468400; // -2147472000 + 3600
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ $dayAdjust = 0;
+ if ($hour < 0) {
+ $dayAdjust = floor($hour / 24);
+ $hour = 24 - abs($hour % 24);
+ if ($hour == 24) { $hour = 0; }
+ } elseif ($hour >= 24) {
+ $dayAdjust = floor($hour / 24);
+ $hour = $hour % 24;
+ }
+ $phpDateObject = new DateTime('1900-01-01 '.$hour.':'.$minute.':'.$second);
+ if ($dayAdjust != 0) {
+ $phpDateObject->modify($dayAdjust.' days');
+ }
+ return $phpDateObject;
+ break;
+ }
+ } // function TIME()
+
+
+ /**
+ * DATEVALUE
+ *
+ * @param string $dateValue
+ * @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
+ * depending on the value of the ReturnDateType flag
+ */
+ public static function DATEVALUE($dateValue = 1) {
+ $dateValue = trim(PHPExcel_Calculation_Functions::flattenSingleValue($dateValue),'"');
+ // Strip any ordinals because they're allowed in Excel (English only)
+ $dateValue = preg_replace('/(\d)(st|nd|rd|th)([ -\/])/Ui','$1$3',$dateValue);
+ // Convert separators (/ . or space) to hyphens (should also handle dot used for ordinals in some countries, e.g. Denmark, Germany)
+ $dateValue = str_replace(array('/','.','-',' '),array(' ',' ',' ',' '),$dateValue);
+
+ $yearFound = false;
+ $t1 = explode(' ',$dateValue);
+ foreach($t1 as &$t) {
+ if ((is_numeric($t)) && ($t > 31)) {
+ if ($yearFound) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } else {
+ if ($t < 100) { $t += 1900; }
+ $yearFound = true;
+ }
+ }
+ }
+ if ((count($t1) == 1) && (strpos($t,':') != false)) {
+ // We've been fed a time value without any date
+ return 0.0;
+ } elseif (count($t1) == 2) {
+ // We only have two parts of the date: either day/month or month/year
+ if ($yearFound) {
+ array_unshift($t1,1);
+ } else {
+ array_push($t1,date('Y'));
+ }
+ }
+ unset($t);
+ $dateValue = implode(' ',$t1);
+
+ $PHPDateArray = date_parse($dateValue);
+ if (($PHPDateArray === False) || ($PHPDateArray['error_count'] > 0)) {
+ $testVal1 = strtok($dateValue,'- ');
+ if ($testVal1 !== False) {
+ $testVal2 = strtok('- ');
+ if ($testVal2 !== False) {
+ $testVal3 = strtok('- ');
+ if ($testVal3 === False) {
+ $testVal3 = strftime('%Y');
+ }
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $PHPDateArray = date_parse($testVal1.'-'.$testVal2.'-'.$testVal3);
+ if (($PHPDateArray === False) || ($PHPDateArray['error_count'] > 0)) {
+ $PHPDateArray = date_parse($testVal2.'-'.$testVal1.'-'.$testVal3);
+ if (($PHPDateArray === False) || ($PHPDateArray['error_count'] > 0)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ }
+
+ if (($PHPDateArray !== False) && ($PHPDateArray['error_count'] == 0)) {
+ // Execute function
+ if ($PHPDateArray['year'] == '') { $PHPDateArray['year'] = strftime('%Y'); }
+ if ($PHPDateArray['month'] == '') { $PHPDateArray['month'] = strftime('%m'); }
+ if ($PHPDateArray['day'] == '') { $PHPDateArray['day'] = strftime('%d'); }
+ $excelDateValue = floor(PHPExcel_Shared_Date::FormattedPHPToExcel($PHPDateArray['year'],$PHPDateArray['month'],$PHPDateArray['day'],$PHPDateArray['hour'],$PHPDateArray['minute'],$PHPDateArray['second']));
+
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ return (float) $excelDateValue;
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ return (integer) PHPExcel_Shared_Date::ExcelToPHP($excelDateValue);
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ return new DateTime($PHPDateArray['year'].'-'.$PHPDateArray['month'].'-'.$PHPDateArray['day'].' 00:00:00');
+ break;
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function DATEVALUE()
+
+
+ /**
+ * TIMEVALUE
+ *
+ * @param string $timeValue
+ * @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
+ * depending on the value of the ReturnDateType flag
+ */
+ public static function TIMEVALUE($timeValue) {
+ $timeValue = trim(PHPExcel_Calculation_Functions::flattenSingleValue($timeValue),'"');
+ $timeValue = str_replace(array('/','.'),array('-','-'),$timeValue);
+
+ $PHPDateArray = date_parse($timeValue);
+ if (($PHPDateArray !== False) && ($PHPDateArray['error_count'] == 0)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $excelDateValue = PHPExcel_Shared_Date::FormattedPHPToExcel($PHPDateArray['year'],$PHPDateArray['month'],$PHPDateArray['day'],$PHPDateArray['hour'],$PHPDateArray['minute'],$PHPDateArray['second']);
+ } else {
+ $excelDateValue = PHPExcel_Shared_Date::FormattedPHPToExcel(1900,1,1,$PHPDateArray['hour'],$PHPDateArray['minute'],$PHPDateArray['second']) - 1;
+ }
+
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ return (float) $excelDateValue;
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ return (integer) $phpDateValue = PHPExcel_Shared_Date::ExcelToPHP($excelDateValue+25569) - 3600;;
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ return new DateTime('1900-01-01 '.$PHPDateArray['hour'].':'.$PHPDateArray['minute'].':'.$PHPDateArray['second']);
+ break;
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function TIMEVALUE()
+
+
+ /**
+ * DATEDIF
+ *
+ * @param long $startDate Excel date serial value or a standard date string
+ * @param long $endDate Excel date serial value or a standard date string
+ * @param string $unit
+ * @return long Interval between the dates
+ */
+ public static function DATEDIF($startDate = 0, $endDate = 0, $unit = 'D') {
+ $startDate = PHPExcel_Calculation_Functions::flattenSingleValue($startDate);
+ $endDate = PHPExcel_Calculation_Functions::flattenSingleValue($endDate);
+ $unit = strtoupper(PHPExcel_Calculation_Functions::flattenSingleValue($unit));
+
+ if (is_string($startDate = self::_getDateValue($startDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($endDate = self::_getDateValue($endDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Validate parameters
+ if ($startDate >= $endDate) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ $difference = $endDate - $startDate;
+
+ $PHPStartDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($startDate);
+ $startDays = $PHPStartDateObject->format('j');
+ $startMonths = $PHPStartDateObject->format('n');
+ $startYears = $PHPStartDateObject->format('Y');
+
+ $PHPEndDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($endDate);
+ $endDays = $PHPEndDateObject->format('j');
+ $endMonths = $PHPEndDateObject->format('n');
+ $endYears = $PHPEndDateObject->format('Y');
+
+ $retVal = PHPExcel_Calculation_Functions::NaN();
+ switch ($unit) {
+ case 'D':
+ $retVal = intval($difference);
+ break;
+ case 'M':
+ $retVal = intval($endMonths - $startMonths) + (intval($endYears - $startYears) * 12);
+ // We're only interested in full months
+ if ($endDays < $startDays) {
+ --$retVal;
+ }
+ break;
+ case 'Y':
+ $retVal = intval($endYears - $startYears);
+ // We're only interested in full months
+ if ($endMonths < $startMonths) {
+ --$retVal;
+ } elseif (($endMonths == $startMonths) && ($endDays < $startDays)) {
+ --$retVal;
+ }
+ break;
+ case 'MD':
+ if ($endDays < $startDays) {
+ $retVal = $endDays;
+ $PHPEndDateObject->modify('-'.$endDays.' days');
+ $adjustDays = $PHPEndDateObject->format('j');
+ if ($adjustDays > $startDays) {
+ $retVal += ($adjustDays - $startDays);
+ }
+ } else {
+ $retVal = $endDays - $startDays;
+ }
+ break;
+ case 'YM':
+ $retVal = intval($endMonths - $startMonths);
+ if ($retVal < 0) $retVal = 12 + $retVal;
+ // We're only interested in full months
+ if ($endDays < $startDays) {
+ --$retVal;
+ }
+ break;
+ case 'YD':
+ $retVal = intval($difference);
+ if ($endYears > $startYears) {
+ while ($endYears > $startYears) {
+ $PHPEndDateObject->modify('-1 year');
+ $endYears = $PHPEndDateObject->format('Y');
+ }
+ $retVal = $PHPEndDateObject->format('z') - $PHPStartDateObject->format('z');
+ if ($retVal < 0) { $retVal += 365; }
+ }
+ break;
+ }
+ return $retVal;
+ } // function DATEDIF()
+
+
+ /**
+ * DAYS360
+ *
+ * @param long $startDate Excel date serial value or a standard date string
+ * @param long $endDate Excel date serial value or a standard date string
+ * @param boolean $method US or European Method
+ * @return long PHP date/time serial
+ */
+ public static function DAYS360($startDate = 0, $endDate = 0, $method = false) {
+ $startDate = PHPExcel_Calculation_Functions::flattenSingleValue($startDate);
+ $endDate = PHPExcel_Calculation_Functions::flattenSingleValue($endDate);
+
+ if (is_string($startDate = self::_getDateValue($startDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($endDate = self::_getDateValue($endDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Execute function
+ $PHPStartDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($startDate);
+ $startDay = $PHPStartDateObject->format('j');
+ $startMonth = $PHPStartDateObject->format('n');
+ $startYear = $PHPStartDateObject->format('Y');
+
+ $PHPEndDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($endDate);
+ $endDay = $PHPEndDateObject->format('j');
+ $endMonth = $PHPEndDateObject->format('n');
+ $endYear = $PHPEndDateObject->format('Y');
+
+ return self::_dateDiff360($startDay, $startMonth, $startYear, $endDay, $endMonth, $endYear, !$method);
+ } // function DAYS360()
+
+
+ /**
+ * YEARFRAC
+ *
+ * Calculates the fraction of the year represented by the number of whole days between two dates (the start_date and the
+ * end_date). Use the YEARFRAC worksheet function to identify the proportion of a whole year's benefits or obligations
+ * to assign to a specific term.
+ *
+ * @param mixed $startDate Excel date serial value (float), PHP date timestamp (integer) or date object, or a standard date string
+ * @param mixed $endDate Excel date serial value (float), PHP date timestamp (integer) or date object, or a standard date string
+ * @param integer $method Method used for the calculation
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float fraction of the year
+ */
+ public static function YEARFRAC($startDate = 0, $endDate = 0, $method = 0) {
+ $startDate = PHPExcel_Calculation_Functions::flattenSingleValue($startDate);
+ $endDate = PHPExcel_Calculation_Functions::flattenSingleValue($endDate);
+ $method = PHPExcel_Calculation_Functions::flattenSingleValue($method);
+
+ if (is_string($startDate = self::_getDateValue($startDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($endDate = self::_getDateValue($endDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (((is_numeric($method)) && (!is_string($method))) || ($method == '')) {
+ switch($method) {
+ case 0 :
+ return self::DAYS360($startDate,$endDate) / 360;
+ break;
+ case 1 :
+ $days = self::DATEDIF($startDate,$endDate);
+ $startYear = self::YEAR($startDate);
+ $endYear = self::YEAR($endDate);
+ $years = $endYear - $startYear + 1;
+ $leapDays = 0;
+ if ($years == 1) {
+ if (self::_isLeapYear($endYear)) {
+ $startMonth = self::MONTHOFYEAR($startDate);
+ $endMonth = self::MONTHOFYEAR($endDate);
+ $endDay = self::DAYOFMONTH($endDate);
+ if (($startMonth < 3) ||
+ (($endMonth * 100 + $endDay) >= (2 * 100 + 29))) {
+ $leapDays += 1;
+ }
+ }
+ } else {
+ for($year = $startYear; $year <= $endYear; ++$year) {
+ if ($year == $startYear) {
+ $startMonth = self::MONTHOFYEAR($startDate);
+ $startDay = self::DAYOFMONTH($startDate);
+ if ($startMonth < 3) {
+ $leapDays += (self::_isLeapYear($year)) ? 1 : 0;
+ }
+ } elseif($year == $endYear) {
+ $endMonth = self::MONTHOFYEAR($endDate);
+ $endDay = self::DAYOFMONTH($endDate);
+ if (($endMonth * 100 + $endDay) >= (2 * 100 + 29)) {
+ $leapDays += (self::_isLeapYear($year)) ? 1 : 0;
+ }
+ } else {
+ $leapDays += (self::_isLeapYear($year)) ? 1 : 0;
+ }
+ }
+ if ($years == 2) {
+ if (($leapDays == 0) && (self::_isLeapYear($startYear)) && ($days > 365)) {
+ $leapDays = 1;
+ } elseif ($days < 366) {
+ $years = 1;
+ }
+ }
+ $leapDays /= $years;
+ }
+ return $days / (365 + $leapDays);
+ break;
+ case 2 :
+ return self::DATEDIF($startDate,$endDate) / 360;
+ break;
+ case 3 :
+ return self::DATEDIF($startDate,$endDate) / 365;
+ break;
+ case 4 :
+ return self::DAYS360($startDate,$endDate,True) / 360;
+ break;
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function YEARFRAC()
+
+
+ /**
+ * NETWORKDAYS
+ *
+ * @param mixed Start date
+ * @param mixed End date
+ * @param array of mixed Optional Date Series
+ * @return long Interval between the dates
+ */
+ public static function NETWORKDAYS($startDate,$endDate) {
+ // Retrieve the mandatory start and end date that are referenced in the function definition
+ $startDate = PHPExcel_Calculation_Functions::flattenSingleValue($startDate);
+ $endDate = PHPExcel_Calculation_Functions::flattenSingleValue($endDate);
+ // Flush the mandatory start and end date that are referenced in the function definition, and get the optional days
+ $dateArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ array_shift($dateArgs);
+ array_shift($dateArgs);
+
+ // Validate the start and end dates
+ if (is_string($startDate = $sDate = self::_getDateValue($startDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $startDate = (float) floor($startDate);
+ if (is_string($endDate = $eDate = self::_getDateValue($endDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $endDate = (float) floor($endDate);
+
+ if ($sDate > $eDate) {
+ $startDate = $eDate;
+ $endDate = $sDate;
+ }
+
+ // Execute function
+ $startDoW = 6 - self::DAYOFWEEK($startDate,2);
+ if ($startDoW < 0) { $startDoW = 0; }
+ $endDoW = self::DAYOFWEEK($endDate,2);
+ if ($endDoW >= 6) { $endDoW = 0; }
+
+ $wholeWeekDays = floor(($endDate - $startDate) / 7) * 5;
+ $partWeekDays = $endDoW + $startDoW;
+ if ($partWeekDays > 5) {
+ $partWeekDays -= 5;
+ }
+
+ // Test any extra holiday parameters
+ $holidayCountedArray = array();
+ foreach ($dateArgs as $holidayDate) {
+ if (is_string($holidayDate = self::_getDateValue($holidayDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (($holidayDate >= $startDate) && ($holidayDate <= $endDate)) {
+ if ((self::DAYOFWEEK($holidayDate,2) < 6) && (!in_array($holidayDate,$holidayCountedArray))) {
+ --$partWeekDays;
+ $holidayCountedArray[] = $holidayDate;
+ }
+ }
+ }
+
+ if ($sDate > $eDate) {
+ return 0 - ($wholeWeekDays + $partWeekDays);
+ }
+ return $wholeWeekDays + $partWeekDays;
+ } // function NETWORKDAYS()
+
+
+ /**
+ * WORKDAY
+ *
+ * @param mixed Start date
+ * @param mixed number of days for adjustment
+ * @param array of mixed Optional Date Series
+ * @return long Interval between the dates
+ */
+ public static function WORKDAY($startDate,$endDays) {
+ // Retrieve the mandatory start date and days that are referenced in the function definition
+ $startDate = PHPExcel_Calculation_Functions::flattenSingleValue($startDate);
+ $endDays = (int) PHPExcel_Calculation_Functions::flattenSingleValue($endDays);
+ // Flush the mandatory start date and days that are referenced in the function definition, and get the optional days
+ $dateArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ array_shift($dateArgs);
+ array_shift($dateArgs);
+
+ if ((is_string($startDate = self::_getDateValue($startDate))) || (!is_numeric($endDays))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $startDate = (float) floor($startDate);
+ // If endDays is 0, we always return startDate
+ if ($endDays == 0) { return $startDate; }
+
+ $decrementing = ($endDays < 0) ? True : False;
+
+ // Adjust the start date if it falls over a weekend
+
+ $startDoW = self::DAYOFWEEK($startDate,3);
+ if (self::DAYOFWEEK($startDate,3) >= 5) {
+ $startDate += ($decrementing) ? -$startDoW + 4: 7 - $startDoW;
+ ($decrementing) ? $endDays++ : $endDays--;
+ }
+
+ // Add endDays
+ $endDate = (float) $startDate + (intval($endDays / 5) * 7) + ($endDays % 5);
+
+ // Adjust the calculated end date if it falls over a weekend
+ $endDoW = self::DAYOFWEEK($endDate,3);
+ if ($endDoW >= 5) {
+ $endDate += ($decrementing) ? -$endDoW + 4: 7 - $endDoW;
+ }
+
+ // Test any extra holiday parameters
+ if (count($dateArgs) > 0) {
+ $holidayCountedArray = $holidayDates = array();
+ foreach ($dateArgs as $holidayDate) {
+ if ((!is_null($holidayDate)) && (trim($holidayDate) > '')) {
+ if (is_string($holidayDate = self::_getDateValue($holidayDate))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (self::DAYOFWEEK($holidayDate,3) < 5) {
+ $holidayDates[] = $holidayDate;
+ }
+ }
+ }
+ if ($decrementing) {
+ rsort($holidayDates, SORT_NUMERIC);
+ } else {
+ sort($holidayDates, SORT_NUMERIC);
+ }
+ foreach ($holidayDates as $holidayDate) {
+ if ($decrementing) {
+ if (($holidayDate <= $startDate) && ($holidayDate >= $endDate)) {
+ if (!in_array($holidayDate,$holidayCountedArray)) {
+ --$endDate;
+ $holidayCountedArray[] = $holidayDate;
+ }
+ }
+ } else {
+ if (($holidayDate >= $startDate) && ($holidayDate <= $endDate)) {
+ if (!in_array($holidayDate,$holidayCountedArray)) {
+ ++$endDate;
+ $holidayCountedArray[] = $holidayDate;
+ }
+ }
+ }
+ // Adjust the calculated end date if it falls over a weekend
+ $endDoW = self::DAYOFWEEK($endDate,3);
+ if ($endDoW >= 5) {
+ $endDate += ($decrementing) ? -$endDoW + 4: 7 - $endDoW;
+ }
+
+ }
+ }
+
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ return (float) $endDate;
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ return (integer) PHPExcel_Shared_Date::ExcelToPHP($endDate);
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ return PHPExcel_Shared_Date::ExcelToPHPObject($endDate);
+ break;
+ }
+ } // function WORKDAY()
+
+
+ /**
+ * DAYOFMONTH
+ *
+ * @param long $dateValue Excel date serial value or a standard date string
+ * @return int Day
+ */
+ public static function DAYOFMONTH($dateValue = 1) {
+ $dateValue = PHPExcel_Calculation_Functions::flattenSingleValue($dateValue);
+
+ if (is_string($dateValue = self::_getDateValue($dateValue))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ($dateValue == 0.0) {
+ return 0;
+ } elseif ($dateValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ $PHPDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($dateValue);
+
+ return (int) $PHPDateObject->format('j');
+ } // function DAYOFMONTH()
+
+
+ /**
+ * DAYOFWEEK
+ *
+ * @param long $dateValue Excel date serial value or a standard date string
+ * @return int Day
+ */
+ public static function DAYOFWEEK($dateValue = 1, $style = 1) {
+ $dateValue = PHPExcel_Calculation_Functions::flattenSingleValue($dateValue);
+ $style = floor(PHPExcel_Calculation_Functions::flattenSingleValue($style));
+
+ if (is_string($dateValue = self::_getDateValue($dateValue))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ($dateValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ $PHPDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($dateValue);
+ $DoW = $PHPDateObject->format('w');
+
+ $firstDay = 1;
+ switch ($style) {
+ case 1: ++$DoW;
+ break;
+ case 2: if ($DoW == 0) { $DoW = 7; }
+ break;
+ case 3: if ($DoW == 0) { $DoW = 7; }
+ $firstDay = 0;
+ --$DoW;
+ break;
+ default:
+ }
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_EXCEL) {
+ // Test for Excel's 1900 leap year, and introduce the error as required
+ if (($PHPDateObject->format('Y') == 1900) && ($PHPDateObject->format('n') <= 2)) {
+ --$DoW;
+ if ($DoW < $firstDay) {
+ $DoW += 7;
+ }
+ }
+ }
+
+ return (int) $DoW;
+ } // function DAYOFWEEK()
+
+
+ /**
+ * WEEKOFYEAR
+ *
+ * @param long $dateValue Excel date serial value or a standard date string
+ * @param boolean $method Week begins on Sunday or Monday
+ * @return int Week Number
+ */
+ public static function WEEKOFYEAR($dateValue = 1, $method = 1) {
+ $dateValue = PHPExcel_Calculation_Functions::flattenSingleValue($dateValue);
+ $method = floor(PHPExcel_Calculation_Functions::flattenSingleValue($method));
+
+ if (!is_numeric($method)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif (($method < 1) || ($method > 2)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ if (is_string($dateValue = self::_getDateValue($dateValue))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ($dateValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ $PHPDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($dateValue);
+ $dayOfYear = $PHPDateObject->format('z');
+ $dow = $PHPDateObject->format('w');
+ $PHPDateObject->modify('-'.$dayOfYear.' days');
+ $dow = $PHPDateObject->format('w');
+ $daysInFirstWeek = 7 - (($dow + (2 - $method)) % 7);
+ $dayOfYear -= $daysInFirstWeek;
+ $weekOfYear = ceil($dayOfYear / 7) + 1;
+
+ return (int) $weekOfYear;
+ } // function WEEKOFYEAR()
+
+
+ /**
+ * MONTHOFYEAR
+ *
+ * @param long $dateValue Excel date serial value or a standard date string
+ * @return int Month
+ */
+ public static function MONTHOFYEAR($dateValue = 1) {
+ $dateValue = PHPExcel_Calculation_Functions::flattenSingleValue($dateValue);
+
+ if (is_string($dateValue = self::_getDateValue($dateValue))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ($dateValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ $PHPDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($dateValue);
+
+ return (int) $PHPDateObject->format('n');
+ } // function MONTHOFYEAR()
+
+
+ /**
+ * YEAR
+ *
+ * @param long $dateValue Excel date serial value or a standard date string
+ * @return int Year
+ */
+ public static function YEAR($dateValue = 1) {
+ $dateValue = PHPExcel_Calculation_Functions::flattenSingleValue($dateValue);
+
+ if (is_string($dateValue = self::_getDateValue($dateValue))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ($dateValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Execute function
+ $PHPDateObject = PHPExcel_Shared_Date::ExcelToPHPObject($dateValue);
+
+ return (int) $PHPDateObject->format('Y');
+ } // function YEAR()
+
+
+ /**
+ * HOUROFDAY
+ *
+ * @param mixed $timeValue Excel time serial value or a standard time string
+ * @return int Hour
+ */
+ public static function HOUROFDAY($timeValue = 0) {
+ $timeValue = PHPExcel_Calculation_Functions::flattenSingleValue($timeValue);
+
+ if (!is_numeric($timeValue)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $testVal = strtok($timeValue,'/-: ');
+ if (strlen($testVal) < strlen($timeValue)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ $timeValue = self::_getTimeValue($timeValue);
+ if (is_string($timeValue)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ // Execute function
+ if ($timeValue >= 1) {
+ $timeValue = fmod($timeValue,1);
+ } elseif ($timeValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $timeValue = PHPExcel_Shared_Date::ExcelToPHP($timeValue);
+
+ return (int) gmdate('G',$timeValue);
+ } // function HOUROFDAY()
+
+
+ /**
+ * MINUTEOFHOUR
+ *
+ * @param long $timeValue Excel time serial value or a standard time string
+ * @return int Minute
+ */
+ public static function MINUTEOFHOUR($timeValue = 0) {
+ $timeValue = $timeTester = PHPExcel_Calculation_Functions::flattenSingleValue($timeValue);
+
+ if (!is_numeric($timeValue)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $testVal = strtok($timeValue,'/-: ');
+ if (strlen($testVal) < strlen($timeValue)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ $timeValue = self::_getTimeValue($timeValue);
+ if (is_string($timeValue)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ // Execute function
+ if ($timeValue >= 1) {
+ $timeValue = fmod($timeValue,1);
+ } elseif ($timeValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $timeValue = PHPExcel_Shared_Date::ExcelToPHP($timeValue);
+
+ return (int) gmdate('i',$timeValue);
+ } // function MINUTEOFHOUR()
+
+
+ /**
+ * SECONDOFMINUTE
+ *
+ * @param long $timeValue Excel time serial value or a standard time string
+ * @return int Second
+ */
+ public static function SECONDOFMINUTE($timeValue = 0) {
+ $timeValue = PHPExcel_Calculation_Functions::flattenSingleValue($timeValue);
+
+ if (!is_numeric($timeValue)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $testVal = strtok($timeValue,'/-: ');
+ if (strlen($testVal) < strlen($timeValue)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ $timeValue = self::_getTimeValue($timeValue);
+ if (is_string($timeValue)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ // Execute function
+ if ($timeValue >= 1) {
+ $timeValue = fmod($timeValue,1);
+ } elseif ($timeValue < 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $timeValue = PHPExcel_Shared_Date::ExcelToPHP($timeValue);
+
+ return (int) gmdate('s',$timeValue);
+ } // function SECONDOFMINUTE()
+
+
+ /**
+ * EDATE
+ *
+ * Returns the serial number that represents the date that is the indicated number of months before or after a specified date
+ * (the start_date). Use EDATE to calculate maturity dates or due dates that fall on the same day of the month as the date of issue.
+ *
+ * @param long $dateValue Excel date serial value or a standard date string
+ * @param int $adjustmentMonths Number of months to adjust by
+ * @return long Excel date serial value
+ */
+ public static function EDATE($dateValue = 1, $adjustmentMonths = 0) {
+ $dateValue = PHPExcel_Calculation_Functions::flattenSingleValue($dateValue);
+ $adjustmentMonths = floor(PHPExcel_Calculation_Functions::flattenSingleValue($adjustmentMonths));
+
+ if (!is_numeric($adjustmentMonths)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (is_string($dateValue = self::_getDateValue($dateValue))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Execute function
+ $PHPDateObject = self::_adjustDateByMonths($dateValue,$adjustmentMonths);
+
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ return (float) PHPExcel_Shared_Date::PHPToExcel($PHPDateObject);
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ return (integer) PHPExcel_Shared_Date::ExcelToPHP(PHPExcel_Shared_Date::PHPToExcel($PHPDateObject));
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ return $PHPDateObject;
+ break;
+ }
+ } // function EDATE()
+
+
+ /**
+ * EOMONTH
+ *
+ * Returns the serial number for the last day of the month that is the indicated number of months before or after start_date.
+ * Use EOMONTH to calculate maturity dates or due dates that fall on the last day of the month.
+ *
+ * @param long $dateValue Excel date serial value or a standard date string
+ * @param int $adjustmentMonths Number of months to adjust by
+ * @return long Excel date serial value
+ */
+ public static function EOMONTH($dateValue = 1, $adjustmentMonths = 0) {
+ $dateValue = PHPExcel_Calculation_Functions::flattenSingleValue($dateValue);
+ $adjustmentMonths = floor(PHPExcel_Calculation_Functions::flattenSingleValue($adjustmentMonths));
+
+ if (!is_numeric($adjustmentMonths)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (is_string($dateValue = self::_getDateValue($dateValue))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Execute function
+ $PHPDateObject = self::_adjustDateByMonths($dateValue,$adjustmentMonths+1);
+ $adjustDays = (int) $PHPDateObject->format('d');
+ $adjustDaysString = '-'.$adjustDays.' days';
+ $PHPDateObject->modify($adjustDaysString);
+
+ switch (PHPExcel_Calculation_Functions::getReturnDateType()) {
+ case PHPExcel_Calculation_Functions::RETURNDATE_EXCEL :
+ return (float) PHPExcel_Shared_Date::PHPToExcel($PHPDateObject);
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_NUMERIC :
+ return (integer) PHPExcel_Shared_Date::ExcelToPHP(PHPExcel_Shared_Date::PHPToExcel($PHPDateObject));
+ break;
+ case PHPExcel_Calculation_Functions::RETURNDATE_PHP_OBJECT :
+ return $PHPDateObject;
+ break;
+ }
+ } // function EOMONTH()
+
+} // class PHPExcel_Calculation_DateTime
diff --git a/Classes/PHPExcel/Calculation/Engineering.php b/Classes/PHPExcel/Calculation/Engineering.php
new file mode 100644
index 00000000..8d4e6141
--- /dev/null
+++ b/Classes/PHPExcel/Calculation/Engineering.php
@@ -0,0 +1,2174 @@
+ array( 'Group' => 'Mass', 'Unit Name' => 'Gram', 'AllowPrefix' => True ),
+ 'sg' => array( 'Group' => 'Mass', 'Unit Name' => 'Slug', 'AllowPrefix' => False ),
+ 'lbm' => array( 'Group' => 'Mass', 'Unit Name' => 'Pound mass (avoirdupois)', 'AllowPrefix' => False ),
+ 'u' => array( 'Group' => 'Mass', 'Unit Name' => 'U (atomic mass unit)', 'AllowPrefix' => True ),
+ 'ozm' => array( 'Group' => 'Mass', 'Unit Name' => 'Ounce mass (avoirdupois)', 'AllowPrefix' => False ),
+ 'm' => array( 'Group' => 'Distance', 'Unit Name' => 'Meter', 'AllowPrefix' => True ),
+ 'mi' => array( 'Group' => 'Distance', 'Unit Name' => 'Statute mile', 'AllowPrefix' => False ),
+ 'Nmi' => array( 'Group' => 'Distance', 'Unit Name' => 'Nautical mile', 'AllowPrefix' => False ),
+ 'in' => array( 'Group' => 'Distance', 'Unit Name' => 'Inch', 'AllowPrefix' => False ),
+ 'ft' => array( 'Group' => 'Distance', 'Unit Name' => 'Foot', 'AllowPrefix' => False ),
+ 'yd' => array( 'Group' => 'Distance', 'Unit Name' => 'Yard', 'AllowPrefix' => False ),
+ 'ang' => array( 'Group' => 'Distance', 'Unit Name' => 'Angstrom', 'AllowPrefix' => True ),
+ 'Pica' => array( 'Group' => 'Distance', 'Unit Name' => 'Pica (1/72 in)', 'AllowPrefix' => False ),
+ 'yr' => array( 'Group' => 'Time', 'Unit Name' => 'Year', 'AllowPrefix' => False ),
+ 'day' => array( 'Group' => 'Time', 'Unit Name' => 'Day', 'AllowPrefix' => False ),
+ 'hr' => array( 'Group' => 'Time', 'Unit Name' => 'Hour', 'AllowPrefix' => False ),
+ 'mn' => array( 'Group' => 'Time', 'Unit Name' => 'Minute', 'AllowPrefix' => False ),
+ 'sec' => array( 'Group' => 'Time', 'Unit Name' => 'Second', 'AllowPrefix' => True ),
+ 'Pa' => array( 'Group' => 'Pressure', 'Unit Name' => 'Pascal', 'AllowPrefix' => True ),
+ 'p' => array( 'Group' => 'Pressure', 'Unit Name' => 'Pascal', 'AllowPrefix' => True ),
+ 'atm' => array( 'Group' => 'Pressure', 'Unit Name' => 'Atmosphere', 'AllowPrefix' => True ),
+ 'at' => array( 'Group' => 'Pressure', 'Unit Name' => 'Atmosphere', 'AllowPrefix' => True ),
+ 'mmHg' => array( 'Group' => 'Pressure', 'Unit Name' => 'mm of Mercury', 'AllowPrefix' => True ),
+ 'N' => array( 'Group' => 'Force', 'Unit Name' => 'Newton', 'AllowPrefix' => True ),
+ 'dyn' => array( 'Group' => 'Force', 'Unit Name' => 'Dyne', 'AllowPrefix' => True ),
+ 'dy' => array( 'Group' => 'Force', 'Unit Name' => 'Dyne', 'AllowPrefix' => True ),
+ 'lbf' => array( 'Group' => 'Force', 'Unit Name' => 'Pound force', 'AllowPrefix' => False ),
+ 'J' => array( 'Group' => 'Energy', 'Unit Name' => 'Joule', 'AllowPrefix' => True ),
+ 'e' => array( 'Group' => 'Energy', 'Unit Name' => 'Erg', 'AllowPrefix' => True ),
+ 'c' => array( 'Group' => 'Energy', 'Unit Name' => 'Thermodynamic calorie', 'AllowPrefix' => True ),
+ 'cal' => array( 'Group' => 'Energy', 'Unit Name' => 'IT calorie', 'AllowPrefix' => True ),
+ 'eV' => array( 'Group' => 'Energy', 'Unit Name' => 'Electron volt', 'AllowPrefix' => True ),
+ 'ev' => array( 'Group' => 'Energy', 'Unit Name' => 'Electron volt', 'AllowPrefix' => True ),
+ 'HPh' => array( 'Group' => 'Energy', 'Unit Name' => 'Horsepower-hour', 'AllowPrefix' => False ),
+ 'hh' => array( 'Group' => 'Energy', 'Unit Name' => 'Horsepower-hour', 'AllowPrefix' => False ),
+ 'Wh' => array( 'Group' => 'Energy', 'Unit Name' => 'Watt-hour', 'AllowPrefix' => True ),
+ 'wh' => array( 'Group' => 'Energy', 'Unit Name' => 'Watt-hour', 'AllowPrefix' => True ),
+ 'flb' => array( 'Group' => 'Energy', 'Unit Name' => 'Foot-pound', 'AllowPrefix' => False ),
+ 'BTU' => array( 'Group' => 'Energy', 'Unit Name' => 'BTU', 'AllowPrefix' => False ),
+ 'btu' => array( 'Group' => 'Energy', 'Unit Name' => 'BTU', 'AllowPrefix' => False ),
+ 'HP' => array( 'Group' => 'Power', 'Unit Name' => 'Horsepower', 'AllowPrefix' => False ),
+ 'h' => array( 'Group' => 'Power', 'Unit Name' => 'Horsepower', 'AllowPrefix' => False ),
+ 'W' => array( 'Group' => 'Power', 'Unit Name' => 'Watt', 'AllowPrefix' => True ),
+ 'w' => array( 'Group' => 'Power', 'Unit Name' => 'Watt', 'AllowPrefix' => True ),
+ 'T' => array( 'Group' => 'Magnetism', 'Unit Name' => 'Tesla', 'AllowPrefix' => True ),
+ 'ga' => array( 'Group' => 'Magnetism', 'Unit Name' => 'Gauss', 'AllowPrefix' => True ),
+ 'C' => array( 'Group' => 'Temperature', 'Unit Name' => 'Celsius', 'AllowPrefix' => False ),
+ 'cel' => array( 'Group' => 'Temperature', 'Unit Name' => 'Celsius', 'AllowPrefix' => False ),
+ 'F' => array( 'Group' => 'Temperature', 'Unit Name' => 'Fahrenheit', 'AllowPrefix' => False ),
+ 'fah' => array( 'Group' => 'Temperature', 'Unit Name' => 'Fahrenheit', 'AllowPrefix' => False ),
+ 'K' => array( 'Group' => 'Temperature', 'Unit Name' => 'Kelvin', 'AllowPrefix' => False ),
+ 'kel' => array( 'Group' => 'Temperature', 'Unit Name' => 'Kelvin', 'AllowPrefix' => False ),
+ 'tsp' => array( 'Group' => 'Liquid', 'Unit Name' => 'Teaspoon', 'AllowPrefix' => False ),
+ 'tbs' => array( 'Group' => 'Liquid', 'Unit Name' => 'Tablespoon', 'AllowPrefix' => False ),
+ 'oz' => array( 'Group' => 'Liquid', 'Unit Name' => 'Fluid Ounce', 'AllowPrefix' => False ),
+ 'cup' => array( 'Group' => 'Liquid', 'Unit Name' => 'Cup', 'AllowPrefix' => False ),
+ 'pt' => array( 'Group' => 'Liquid', 'Unit Name' => 'U.S. Pint', 'AllowPrefix' => False ),
+ 'us_pt' => array( 'Group' => 'Liquid', 'Unit Name' => 'U.S. Pint', 'AllowPrefix' => False ),
+ 'uk_pt' => array( 'Group' => 'Liquid', 'Unit Name' => 'U.K. Pint', 'AllowPrefix' => False ),
+ 'qt' => array( 'Group' => 'Liquid', 'Unit Name' => 'Quart', 'AllowPrefix' => False ),
+ 'gal' => array( 'Group' => 'Liquid', 'Unit Name' => 'Gallon', 'AllowPrefix' => False ),
+ 'l' => array( 'Group' => 'Liquid', 'Unit Name' => 'Litre', 'AllowPrefix' => True ),
+ 'lt' => array( 'Group' => 'Liquid', 'Unit Name' => 'Litre', 'AllowPrefix' => True )
+ );
+
+ private static $_conversionMultipliers = array( 'Y' => array( 'multiplier' => 1E24, 'name' => 'yotta' ),
+ 'Z' => array( 'multiplier' => 1E21, 'name' => 'zetta' ),
+ 'E' => array( 'multiplier' => 1E18, 'name' => 'exa' ),
+ 'P' => array( 'multiplier' => 1E15, 'name' => 'peta' ),
+ 'T' => array( 'multiplier' => 1E12, 'name' => 'tera' ),
+ 'G' => array( 'multiplier' => 1E9, 'name' => 'giga' ),
+ 'M' => array( 'multiplier' => 1E6, 'name' => 'mega' ),
+ 'k' => array( 'multiplier' => 1E3, 'name' => 'kilo' ),
+ 'h' => array( 'multiplier' => 1E2, 'name' => 'hecto' ),
+ 'e' => array( 'multiplier' => 1E1, 'name' => 'deka' ),
+ 'd' => array( 'multiplier' => 1E-1, 'name' => 'deci' ),
+ 'c' => array( 'multiplier' => 1E-2, 'name' => 'centi' ),
+ 'm' => array( 'multiplier' => 1E-3, 'name' => 'milli' ),
+ 'u' => array( 'multiplier' => 1E-6, 'name' => 'micro' ),
+ 'n' => array( 'multiplier' => 1E-9, 'name' => 'nano' ),
+ 'p' => array( 'multiplier' => 1E-12, 'name' => 'pico' ),
+ 'f' => array( 'multiplier' => 1E-15, 'name' => 'femto' ),
+ 'a' => array( 'multiplier' => 1E-18, 'name' => 'atto' ),
+ 'z' => array( 'multiplier' => 1E-21, 'name' => 'zepto' ),
+ 'y' => array( 'multiplier' => 1E-24, 'name' => 'yocto' )
+ );
+
+ private static $_unitConversions = array( 'Mass' => array( 'g' => array( 'g' => 1.0,
+ 'sg' => 6.85220500053478E-05,
+ 'lbm' => 2.20462291469134E-03,
+ 'u' => 6.02217000000000E+23,
+ 'ozm' => 3.52739718003627E-02
+ ),
+ 'sg' => array( 'g' => 1.45938424189287E+04,
+ 'sg' => 1.0,
+ 'lbm' => 3.21739194101647E+01,
+ 'u' => 8.78866000000000E+27,
+ 'ozm' => 5.14782785944229E+02
+ ),
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+ 'lt' => array( 'tsp' => 2.02840000000000E+02,
+ 'tbs' => 6.76133333333333E+01,
+ 'oz' => 3.38066666666667E+01,
+ 'cup' => 4.22583333333333E+00,
+ 'pt' => 2.11291666666667E+00,
+ 'us_pt' => 2.11291666666667E+00,
+ 'uk_pt' => 1.75975569552166E+00,
+ 'qt' => 1.05645833333333E+00,
+ 'gal' => 2.64114583333333E-01,
+ 'l' => 1.0,
+ 'lt' => 1.0
+ )
+ )
+ );
+
+
+ public static function _parseComplex($complexNumber) {
+ $workString = (string) $complexNumber;
+
+ $realNumber = $imaginary = 0;
+ // Extract the suffix, if there is one
+ $suffix = substr($workString,-1);
+ if (!is_numeric($suffix)) {
+ $workString = substr($workString,0,-1);
+ } else {
+ $suffix = '';
+ }
+
+ // Split the input into its Real and Imaginary components
+ $leadingSign = 0;
+ if (strlen($workString) > 0) {
+ $leadingSign = (($workString{0} == '+') || ($workString{0} == '-')) ? 1 : 0;
+ }
+ $power = '';
+ $realNumber = strtok($workString, '+-');
+ if (strtoupper(substr($realNumber,-1)) == 'E') {
+ $power = strtok('+-');
+ ++$leadingSign;
+ }
+
+ $realNumber = substr($workString,0,strlen($realNumber)+strlen($power)+$leadingSign);
+
+ if ($suffix != '') {
+ $imaginary = substr($workString,strlen($realNumber));
+
+ if (($imaginary == '') && (($realNumber == '') || ($realNumber == '+') || ($realNumber == '-'))) {
+ $imaginary = $realNumber.'1';
+ $realNumber = '0';
+ } else if ($imaginary == '') {
+ $imaginary = $realNumber;
+ $realNumber = '0';
+ } elseif (($imaginary == '+') || ($imaginary == '-')) {
+ $imaginary .= '1';
+ }
+ }
+
+ return array( 'real' => $realNumber,
+ 'imaginary' => $imaginary,
+ 'suffix' => $suffix
+ );
+ } // function _parseComplex()
+
+
+ private static function _cleanComplex($complexNumber) {
+ if ($complexNumber{0} == '+') $complexNumber = substr($complexNumber,1);
+ if ($complexNumber{0} == '0') $complexNumber = substr($complexNumber,1);
+ if ($complexNumber{0} == '.') $complexNumber = '0'.$complexNumber;
+ if ($complexNumber{0} == '+') $complexNumber = substr($complexNumber,1);
+ return $complexNumber;
+ }
+
+
+ private static function _nbrConversionFormat($xVal,$places) {
+ if (!is_null($places)) {
+ if (strlen($xVal) <= $places) {
+ return substr(str_pad($xVal,$places,'0',STR_PAD_LEFT),-10);
+ } else {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ }
+
+ return substr($xVal,-10);
+ } // function _nbrConversionFormat()
+
+
+ /**
+ * BESSELI
+ *
+ * Returns the modified Bessel function, which is equivalent to the Bessel function evaluated for purely imaginary arguments
+ *
+ * @param float $x
+ * @param float $n
+ * @return int
+ */
+ public static function BESSELI($x, $n) {
+ $x = (is_null($x)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $n = (is_null($n)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($n);
+
+ if ((is_numeric($x)) && (is_numeric($n))) {
+ $n = floor($n);
+ if ($n < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $f_2_PI = 2 * M_PI;
+
+ if (abs($x) <= 30) {
+ $fTerm = pow($x / 2, $n) / PHPExcel_Calculation_MathTrig::FACT($n);
+ $nK = 1;
+ $fResult = $fTerm;
+ $fSqrX = ($x * $x) / 4;
+ do {
+ $fTerm *= $fSqrX;
+ $fTerm /= ($nK * ($nK + $n));
+ $fResult += $fTerm;
+ } while ((abs($fTerm) > 1e-10) && (++$nK < 100));
+ } else {
+ $fXAbs = abs($x);
+ $fResult = exp($fXAbs) / sqrt($f_2_PI * $fXAbs);
+ if (($n && 1) && ($x < 0)) {
+ $fResult = -$fResult;
+ }
+ }
+ return $fResult;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function BESSELI()
+
+
+ /**
+ * BESSELJ
+ *
+ * Returns the Bessel function
+ *
+ * @param float $x
+ * @param float $n
+ * @return int
+ */
+ public static function BESSELJ($x, $n) {
+ $x = (is_null($x)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $n = (is_null($n)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($n);
+
+ if ((is_numeric($x)) && (is_numeric($n))) {
+ $n = floor($n);
+ if ($n < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $f_PI_DIV_2 = M_PI / 2;
+ $f_PI_DIV_4 = M_PI / 4;
+
+ $fResult = 0;
+ if (abs($x) <= 30) {
+ $fTerm = pow($x / 2, $n) / PHPExcel_Calculation_MathTrig::FACT($n);
+ $nK = 1;
+ $fResult = $fTerm;
+ $fSqrX = ($x * $x) / -4;
+ do {
+ $fTerm *= $fSqrX;
+ $fTerm /= ($nK * ($nK + $n));
+ $fResult += $fTerm;
+ } while ((abs($fTerm) > 1e-10) && (++$nK < 100));
+ } else {
+ $fXAbs = abs($x);
+ $fResult = sqrt(M_2DIVPI / $fXAbs) * cos($fXAbs - $n * $f_PI_DIV_2 - $f_PI_DIV_4);
+ if (($n && 1) && ($x < 0)) {
+ $fResult = -$fResult;
+ }
+ }
+ return $fResult;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function BESSELJ()
+
+
+ private static function _Besselk0($fNum) {
+ if ($fNum <= 2) {
+ $fNum2 = $fNum * 0.5;
+ $y = ($fNum2 * $fNum2);
+ $fRet = -log($fNum2) * self::BESSELI($fNum, 0) +
+ (-0.57721566 + $y * (0.42278420 + $y * (0.23069756 + $y * (0.3488590e-1 + $y * (0.262698e-2 + $y *
+ (0.10750e-3 + $y * 0.74e-5))))));
+ } else {
+ $y = 2 / $fNum;
+ $fRet = exp(-$fNum) / sqrt($fNum) *
+ (1.25331414 + $y * (-0.7832358e-1 + $y * (0.2189568e-1 + $y * (-0.1062446e-1 + $y *
+ (0.587872e-2 + $y * (-0.251540e-2 + $y * 0.53208e-3))))));
+ }
+ return $fRet;
+ } // function _Besselk0()
+
+
+ private static function _Besselk1($fNum) {
+ if ($fNum <= 2) {
+ $fNum2 = $fNum * 0.5;
+ $y = ($fNum2 * $fNum2);
+ $fRet = log($fNum2) * self::BESSELI($fNum, 1) +
+ (1 + $y * (0.15443144 + $y * (-0.67278579 + $y * (-0.18156897 + $y * (-0.1919402e-1 + $y *
+ (-0.110404e-2 + $y * (-0.4686e-4))))))) / $fNum;
+ } else {
+ $y = 2 / $fNum;
+ $fRet = exp(-$fNum) / sqrt($fNum) *
+ (1.25331414 + $y * (0.23498619 + $y * (-0.3655620e-1 + $y * (0.1504268e-1 + $y * (-0.780353e-2 + $y *
+ (0.325614e-2 + $y * (-0.68245e-3)))))));
+ }
+ return $fRet;
+ } // function _Besselk1()
+
+
+ /**
+ * BESSELK
+ *
+ * Returns the modified Bessel function, which is equivalent to the Bessel functions evaluated for purely imaginary arguments.
+ *
+ * @param float $x
+ * @param float $ord
+ * @return float
+ */
+ public static function BESSELK($x, $ord) {
+ $x = (is_null($x)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $ord = (is_null($ord)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($ord);
+
+ if ((is_numeric($x)) && (is_numeric($ord))) {
+ if (($ord < 0) || ($x == 0.0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ switch(floor($ord)) {
+ case 0 : return self::_Besselk0($x);
+ break;
+ case 1 : return self::_Besselk1($x);
+ break;
+ default : $fTox = 2 / $x;
+ $fBkm = self::_Besselk0($x);
+ $fBk = self::_Besselk1($x);
+ for ($n = 1; $n < $ord; ++$n) {
+ $fBkp = $fBkm + $n * $fTox * $fBk;
+ $fBkm = $fBk;
+ $fBk = $fBkp;
+ }
+ }
+ return $fBk;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function BESSELK()
+
+
+ private static function _Bessely0($fNum) {
+ if ($fNum < 8.0) {
+ $y = ($fNum * $fNum);
+ $f1 = -2957821389.0 + $y * (7062834065.0 + $y * (-512359803.6 + $y * (10879881.29 + $y * (-86327.92757 + $y * 228.4622733))));
+ $f2 = 40076544269.0 + $y * (745249964.8 + $y * (7189466.438 + $y * (47447.26470 + $y * (226.1030244 + $y))));
+ $fRet = $f1 / $f2 + M_2DIVPI * self::BESSELJ($fNum, 0) * log($fNum);
+ } else {
+ $z = 8.0 / $fNum;
+ $y = ($z * $z);
+ $xx = $fNum - 0.785398164;
+ $f1 = 1 + $y * (-0.1098628627e-2 + $y * (0.2734510407e-4 + $y * (-0.2073370639e-5 + $y * 0.2093887211e-6)));
+ $f2 = -0.1562499995e-1 + $y * (0.1430488765e-3 + $y * (-0.6911147651e-5 + $y * (0.7621095161e-6 + $y * (-0.934945152e-7))));
+ $fRet = sqrt(M_2DIVPI / $fNum) * (sin($xx) * $f1 + $z * cos($xx) * $f2);
+ }
+ return $fRet;
+ } // function _Bessely0()
+
+
+ private static function _Bessely1($fNum) {
+ if ($fNum < 8.0) {
+ $y = ($fNum * $fNum);
+ $f1 = $fNum * (-0.4900604943e13 + $y * (0.1275274390e13 + $y * (-0.5153438139e11 + $y * (0.7349264551e9 + $y *
+ (-0.4237922726e7 + $y * 0.8511937935e4)))));
+ $f2 = 0.2499580570e14 + $y * (0.4244419664e12 + $y * (0.3733650367e10 + $y * (0.2245904002e8 + $y *
+ (0.1020426050e6 + $y * (0.3549632885e3 + $y)))));
+ $fRet = $f1 / $f2 + M_2DIVPI * ( self::BESSELJ($fNum, 1) * log($fNum) - 1 / $fNum);
+ } else {
+ $z = 8.0 / $fNum;
+ $y = ($z * $z);
+ $xx = $fNum - 2.356194491;
+ $f1 = 1 + $y * (0.183105e-2 + $y * (-0.3516396496e-4 + $y * (0.2457520174e-5 + $y * (-0.240337019e6))));
+ $f2 = 0.04687499995 + $y * (-0.2002690873e-3 + $y * (0.8449199096e-5 + $y * (-0.88228987e-6 + $y * 0.105787412e-6)));
+ $fRet = sqrt(M_2DIVPI / $fNum) * (sin($xx) * $f1 + $z * cos($xx) * $f2);
+ #i12430# ...but this seems to work much better.
+// $fRet = sqrt(M_2DIVPI / $fNum) * sin($fNum - 2.356194491);
+ }
+ return $fRet;
+ } // function _Bessely1()
+
+
+ /**
+ * BESSELY
+ *
+ * Returns the Bessel function, which is also called the Weber function or the Neumann function.
+ *
+ * @param float $x
+ * @param float $n
+ * @return int
+ */
+ public static function BESSELY($x, $ord) {
+ $x = (is_null($x)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $ord = (is_null($ord)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($ord);
+
+ if ((is_numeric($x)) && (is_numeric($ord))) {
+ if (($ord < 0) || ($x == 0.0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ switch(floor($ord)) {
+ case 0 : return self::_Bessely0($x);
+ break;
+ case 1 : return self::_Bessely1($x);
+ break;
+ default: $fTox = 2 / $x;
+ $fBym = self::_Bessely0($x);
+ $fBy = self::_Bessely1($x);
+ for ($n = 1; $n < $ord; ++$n) {
+ $fByp = $n * $fTox * $fBy - $fBym;
+ $fBym = $fBy;
+ $fBy = $fByp;
+ }
+ }
+ return $fBy;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function BESSELY()
+
+
+ /**
+ * BINTODEC
+ *
+ * Return a binary value as Decimal.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function BINTODEC($x) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+
+ if (is_bool($x)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $x = (int) $x;
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $x = floor($x);
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[01]/',$x,$out)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (strlen($x) > 10) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } elseif (strlen($x) == 10) {
+ // Two's Complement
+ $x = substr($x,-9);
+ return '-'.(512-bindec($x));
+ }
+ return bindec($x);
+ } // function BINTODEC()
+
+
+ /**
+ * BINTOHEX
+ *
+ * Return a binary value as Hex.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function BINTOHEX($x, $places=null) {
+ $x = floor(PHPExcel_Calculation_Functions::flattenSingleValue($x));
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $x = (int) $x;
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $x = floor($x);
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[01]/',$x,$out)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (strlen($x) > 10) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } elseif (strlen($x) == 10) {
+ // Two's Complement
+ return str_repeat('F',8).substr(strtoupper(dechex(bindec(substr($x,-9)))),-2);
+ }
+ $hexVal = (string) strtoupper(dechex(bindec($x)));
+
+ return self::_nbrConversionFormat($hexVal,$places);
+ } // function BINTOHEX()
+
+
+ /**
+ * BINTOOCT
+ *
+ * Return a binary value as Octal.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function BINTOOCT($x, $places=null) {
+ $x = floor(PHPExcel_Calculation_Functions::flattenSingleValue($x));
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $x = (int) $x;
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $x = floor($x);
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[01]/',$x,$out)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (strlen($x) > 10) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } elseif (strlen($x) == 10) {
+ // Two's Complement
+ return str_repeat('7',7).substr(strtoupper(decoct(bindec(substr($x,-9)))),-3);
+ }
+ $octVal = (string) decoct(bindec($x));
+
+ return self::_nbrConversionFormat($octVal,$places);
+ } // function BINTOOCT()
+
+
+ /**
+ * DECTOBIN
+ *
+ * Return an octal value as binary.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function DECTOBIN($x, $places=null) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $x = (int) $x;
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[-0123456789.]/',$x,$out)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) floor($x);
+ $r = decbin($x);
+ if (strlen($r) == 32) {
+ // Two's Complement
+ $r = substr($r,-10);
+ } elseif (strlen($r) > 11) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ return self::_nbrConversionFormat($r,$places);
+ } // function DECTOBIN()
+
+
+ /**
+ * DECTOHEX
+ *
+ * Return an octal value as binary.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function DECTOHEX($x, $places=null) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $x = (int) $x;
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[-0123456789.]/',$x,$out)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) floor($x);
+ $r = strtoupper(dechex($x));
+ if (strlen($r) == 8) {
+ // Two's Complement
+ $r = 'FF'.$r;
+ }
+
+ return self::_nbrConversionFormat($r,$places);
+ } // function DECTOHEX()
+
+
+ /**
+ * DECTOOCT
+ *
+ * Return an octal value as binary.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function DECTOOCT($x, $places=null) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $x = (int) $x;
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[-0123456789.]/',$x,$out)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) floor($x);
+ $r = decoct($x);
+ if (strlen($r) == 11) {
+ // Two's Complement
+ $r = substr($r,-10);
+ }
+
+ return self::_nbrConversionFormat($r,$places);
+ } // function DECTOOCT()
+
+
+ /**
+ * HEXTOBIN
+ *
+ * Return a hex value as binary.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function HEXTOBIN($x, $places=null) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[0123456789ABCDEF]/',strtoupper($x),$out)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $binVal = decbin(hexdec($x));
+
+ return substr(self::_nbrConversionFormat($binVal,$places),-10);
+ } // function HEXTOBIN()
+
+
+ /**
+ * HEXTODEC
+ *
+ * Return a hex value as octal.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function HEXTODEC($x) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+
+ if (is_bool($x)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[0123456789ABCDEF]/',strtoupper($x),$out)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return hexdec($x);
+ } // function HEXTODEC()
+
+
+ /**
+ * HEXTOOCT
+ *
+ * Return a hex value as octal.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function HEXTOOCT($x, $places=null) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) $x;
+ if (strlen($x) > preg_match_all('/[0123456789ABCDEF]/',strtoupper($x),$out)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $octVal = decoct(hexdec($x));
+
+ return self::_nbrConversionFormat($octVal,$places);
+ } // function HEXTOOCT()
+
+
+ /**
+ * OCTTOBIN
+ *
+ * Return an octal value as binary.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function OCTTOBIN($x, $places=null) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) $x;
+ if (preg_match_all('/[01234567]/',$x,$out) != strlen($x)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $r = decbin(octdec($x));
+
+ return self::_nbrConversionFormat($r,$places);
+ } // function OCTTOBIN()
+
+
+ /**
+ * OCTTODEC
+ *
+ * Return an octal value as binary.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function OCTTODEC($x) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+
+ if (is_bool($x)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) $x;
+ if (preg_match_all('/[01234567]/',$x,$out) != strlen($x)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return octdec($x);
+ } // function OCTTODEC()
+
+
+ /**
+ * OCTTOHEX
+ *
+ * Return an octal value as hex.
+ *
+ * @param string $x
+ * @return string
+ */
+ public static function OCTTOHEX($x, $places=null) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $places = PHPExcel_Calculation_Functions::flattenSingleValue($places);
+
+ if (is_bool($x)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $x = (string) $x;
+ if (preg_match_all('/[01234567]/',$x,$out) != strlen($x)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $hexVal = strtoupper(dechex(octdec($x)));
+
+ return self::_nbrConversionFormat($hexVal,$places);
+ } // function OCTTOHEX()
+
+
+ /**
+ * COMPLEX
+ *
+ * returns a complex number of the form x + yi or x + yj.
+ *
+ * @param float $realNumber
+ * @param float $imaginary
+ * @param string $suffix
+ * @return string
+ */
+ public static function COMPLEX($realNumber=0.0, $imaginary=0.0, $suffix='i') {
+ $realNumber = (is_null($realNumber)) ? 0.0 : (float) PHPExcel_Calculation_Functions::flattenSingleValue($realNumber);
+ $imaginary = (is_null($imaginary)) ? 0.0 : (float) PHPExcel_Calculation_Functions::flattenSingleValue($imaginary);
+ $suffix = (is_null($suffix)) ? 'i' : PHPExcel_Calculation_Functions::flattenSingleValue($suffix);
+
+ if (((is_numeric($realNumber)) && (is_numeric($imaginary))) &&
+ (($suffix == 'i') || ($suffix == 'j') || ($suffix == ''))) {
+ if ($suffix == '') $suffix = 'i';
+ if ($realNumber == 0.0) {
+ if ($imaginary == 0.0) {
+ return (string) '0';
+ } elseif ($imaginary == 1.0) {
+ return (string) $suffix;
+ } elseif ($imaginary == -1.0) {
+ return (string) '-'.$suffix;
+ }
+ return (string) $imaginary.$suffix;
+ } elseif ($imaginary == 0.0) {
+ return (string) $realNumber;
+ } elseif ($imaginary == 1.0) {
+ return (string) $realNumber.'+'.$suffix;
+ } elseif ($imaginary == -1.0) {
+ return (string) $realNumber.'-'.$suffix;
+ }
+ if ($imaginary > 0) { $imaginary = (string) '+'.$imaginary; }
+ return (string) $realNumber.$imaginary.$suffix;
+ }
+
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function COMPLEX()
+
+
+ /**
+ * IMAGINARY
+ *
+ * Returns the imaginary coefficient of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return real
+ */
+ public static function IMAGINARY($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+ return $parsedComplex['imaginary'];
+ } // function IMAGINARY()
+
+
+ /**
+ * IMREAL
+ *
+ * Returns the real coefficient of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return real
+ */
+ public static function IMREAL($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+ return $parsedComplex['real'];
+ } // function IMREAL()
+
+
+ /**
+ * IMABS
+ *
+ * Returns the absolute value (modulus) of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return real
+ */
+ public static function IMABS($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+ return sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary']));
+ } // function IMABS()
+
+
+ /**
+ * IMARGUMENT
+ *
+ * Returns the argument theta of a complex number, i.e. the angle in radians from the real axis to the representation of the number in polar coordinates.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMARGUMENT($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if ($parsedComplex['real'] == 0.0) {
+ if ($parsedComplex['imaginary'] == 0.0) {
+ return 0.0;
+ } elseif($parsedComplex['imaginary'] < 0.0) {
+ return M_PI / -2;
+ } else {
+ return M_PI / 2;
+ }
+ } elseif ($parsedComplex['real'] > 0.0) {
+ return atan($parsedComplex['imaginary'] / $parsedComplex['real']);
+ } elseif ($parsedComplex['imaginary'] < 0.0) {
+ return 0 - (M_PI - atan(abs($parsedComplex['imaginary']) / abs($parsedComplex['real'])));
+ } else {
+ return M_PI - atan($parsedComplex['imaginary'] / abs($parsedComplex['real']));
+ }
+ } // function IMARGUMENT()
+
+
+ /**
+ * IMCONJUGATE
+ *
+ * Returns the complex conjugate of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMCONJUGATE($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if ($parsedComplex['imaginary'] == 0.0) {
+ return $parsedComplex['real'];
+ } else {
+ return self::_cleanComplex(self::COMPLEX($parsedComplex['real'], 0 - $parsedComplex['imaginary'], $parsedComplex['suffix']));
+ }
+ } // function IMCONJUGATE()
+
+
+ /**
+ * IMCOS
+ *
+ * Returns the cosine of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMCOS($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if ($parsedComplex['imaginary'] == 0.0) {
+ return cos($parsedComplex['real']);
+ } else {
+ return self::IMCONJUGATE(self::COMPLEX(cos($parsedComplex['real']) * cosh($parsedComplex['imaginary']),sin($parsedComplex['real']) * sinh($parsedComplex['imaginary']),$parsedComplex['suffix']));
+ }
+ } // function IMCOS()
+
+
+ /**
+ * IMSIN
+ *
+ * Returns the sine of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMSIN($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if ($parsedComplex['imaginary'] == 0.0) {
+ return sin($parsedComplex['real']);
+ } else {
+ return self::COMPLEX(sin($parsedComplex['real']) * cosh($parsedComplex['imaginary']),cos($parsedComplex['real']) * sinh($parsedComplex['imaginary']),$parsedComplex['suffix']);
+ }
+ } // function IMSIN()
+
+
+ /**
+ * IMSQRT
+ *
+ * Returns the square root of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMSQRT($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ $theta = self::IMARGUMENT($complexNumber);
+ $d1 = cos($theta / 2);
+ $d2 = sin($theta / 2);
+ $r = sqrt(sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary'])));
+
+ if ($parsedComplex['suffix'] == '') {
+ return self::COMPLEX($d1 * $r,$d2 * $r);
+ } else {
+ return self::COMPLEX($d1 * $r,$d2 * $r,$parsedComplex['suffix']);
+ }
+ } // function IMSQRT()
+
+
+ /**
+ * IMLN
+ *
+ * Returns the natural logarithm of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMLN($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $logR = log(sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary'])));
+ $t = self::IMARGUMENT($complexNumber);
+
+ if ($parsedComplex['suffix'] == '') {
+ return self::COMPLEX($logR,$t);
+ } else {
+ return self::COMPLEX($logR,$t,$parsedComplex['suffix']);
+ }
+ } // function IMLN()
+
+
+ /**
+ * IMLOG10
+ *
+ * Returns the common logarithm (base 10) of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMLOG10($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } elseif (($parsedComplex['real'] > 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
+ return log10($parsedComplex['real']);
+ }
+
+ return self::IMPRODUCT(log10(EULER),self::IMLN($complexNumber));
+ } // function IMLOG10()
+
+
+ /**
+ * IMLOG2
+ *
+ * Returns the common logarithm (base 10) of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMLOG2($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } elseif (($parsedComplex['real'] > 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
+ return log($parsedComplex['real'],2);
+ }
+
+ return self::IMPRODUCT(log(EULER,2),self::IMLN($complexNumber));
+ } // function IMLOG2()
+
+
+ /**
+ * IMEXP
+ *
+ * Returns the exponential of a complex number in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMEXP($complexNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
+ return '1';
+ }
+
+ $e = exp($parsedComplex['real']);
+ $eX = $e * cos($parsedComplex['imaginary']);
+ $eY = $e * sin($parsedComplex['imaginary']);
+
+ if ($parsedComplex['suffix'] == '') {
+ return self::COMPLEX($eX,$eY);
+ } else {
+ return self::COMPLEX($eX,$eY,$parsedComplex['suffix']);
+ }
+ } // function IMEXP()
+
+
+ /**
+ * IMPOWER
+ *
+ * Returns a complex number in x + yi or x + yj text format raised to a power.
+ *
+ * @param string $complexNumber
+ * @return string
+ */
+ public static function IMPOWER($complexNumber,$realNumber) {
+ $complexNumber = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber);
+ $realNumber = PHPExcel_Calculation_Functions::flattenSingleValue($realNumber);
+
+ if (!is_numeric($realNumber)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ $parsedComplex = self::_parseComplex($complexNumber);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ $r = sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary']));
+ $rPower = pow($r,$realNumber);
+ $theta = self::IMARGUMENT($complexNumber) * $realNumber;
+ if ($theta == 0) {
+ return 1;
+ } elseif ($parsedComplex['imaginary'] == 0.0) {
+ return self::COMPLEX($rPower * cos($theta),$rPower * sin($theta),$parsedComplex['suffix']);
+ } else {
+ return self::COMPLEX($rPower * cos($theta),$rPower * sin($theta),$parsedComplex['suffix']);
+ }
+ } // function IMPOWER()
+
+
+ /**
+ * IMDIV
+ *
+ * Returns the quotient of two complex numbers in x + yi or x + yj text format.
+ *
+ * @param string $complexDividend
+ * @param string $complexDivisor
+ * @return real
+ */
+ public static function IMDIV($complexDividend,$complexDivisor) {
+ $complexDividend = PHPExcel_Calculation_Functions::flattenSingleValue($complexDividend);
+ $complexDivisor = PHPExcel_Calculation_Functions::flattenSingleValue($complexDivisor);
+
+ $parsedComplexDividend = self::_parseComplex($complexDividend);
+ if (!is_array($parsedComplexDividend)) {
+ return $parsedComplexDividend;
+ }
+
+ $parsedComplexDivisor = self::_parseComplex($complexDivisor);
+ if (!is_array($parsedComplexDivisor)) {
+ return $parsedComplexDividend;
+ }
+
+ if (($parsedComplexDividend['suffix'] != '') && ($parsedComplexDivisor['suffix'] != '') &&
+ ($parsedComplexDividend['suffix'] != $parsedComplexDivisor['suffix'])) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($parsedComplexDividend['suffix'] != '') && ($parsedComplexDivisor['suffix'] == '')) {
+ $parsedComplexDivisor['suffix'] = $parsedComplexDividend['suffix'];
+ }
+
+ $d1 = ($parsedComplexDividend['real'] * $parsedComplexDivisor['real']) + ($parsedComplexDividend['imaginary'] * $parsedComplexDivisor['imaginary']);
+ $d2 = ($parsedComplexDividend['imaginary'] * $parsedComplexDivisor['real']) - ($parsedComplexDividend['real'] * $parsedComplexDivisor['imaginary']);
+ $d3 = ($parsedComplexDivisor['real'] * $parsedComplexDivisor['real']) + ($parsedComplexDivisor['imaginary'] * $parsedComplexDivisor['imaginary']);
+
+ $r = $d1/$d3;
+ $i = $d2/$d3;
+
+ if ($i > 0.0) {
+ return self::_cleanComplex($r.'+'.$i.$parsedComplexDivisor['suffix']);
+ } elseif ($i < 0.0) {
+ return self::_cleanComplex($r.$i.$parsedComplexDivisor['suffix']);
+ } else {
+ return $r;
+ }
+ } // function IMDIV()
+
+
+ /**
+ * IMSUB
+ *
+ * Returns the difference of two complex numbers in x + yi or x + yj text format.
+ *
+ * @param string $complexNumber1
+ * @param string $complexNumber2
+ * @return real
+ */
+ public static function IMSUB($complexNumber1,$complexNumber2) {
+ $complexNumber1 = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber1);
+ $complexNumber2 = PHPExcel_Calculation_Functions::flattenSingleValue($complexNumber2);
+
+ $parsedComplex1 = self::_parseComplex($complexNumber1);
+ if (!is_array($parsedComplex1)) {
+ return $parsedComplex1;
+ }
+
+ $parsedComplex2 = self::_parseComplex($complexNumber2);
+ if (!is_array($parsedComplex2)) {
+ return $parsedComplex2;
+ }
+
+ if ((($parsedComplex1['suffix'] != '') && ($parsedComplex2['suffix'] != '')) &&
+ ($parsedComplex1['suffix'] != $parsedComplex2['suffix'])) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } elseif (($parsedComplex1['suffix'] == '') && ($parsedComplex2['suffix'] != '')) {
+ $parsedComplex1['suffix'] = $parsedComplex2['suffix'];
+ }
+
+ $d1 = $parsedComplex1['real'] - $parsedComplex2['real'];
+ $d2 = $parsedComplex1['imaginary'] - $parsedComplex2['imaginary'];
+
+ return self::COMPLEX($d1,$d2,$parsedComplex1['suffix']);
+ } // function IMSUB()
+
+
+ /**
+ * IMSUM
+ *
+ * Returns the sum of two or more complex numbers in x + yi or x + yj text format.
+ *
+ * @param array of mixed Data Series
+ * @return real
+ */
+ public static function IMSUM() {
+ // Return value
+ $returnValue = self::_parseComplex('0');
+ $activeSuffix = '';
+
+ // Loop through the arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ $parsedComplex = self::_parseComplex($arg);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+
+ if ($activeSuffix == '') {
+ $activeSuffix = $parsedComplex['suffix'];
+ } elseif (($parsedComplex['suffix'] != '') && ($activeSuffix != $parsedComplex['suffix'])) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ $returnValue['real'] += $parsedComplex['real'];
+ $returnValue['imaginary'] += $parsedComplex['imaginary'];
+ }
+
+ if ($returnValue['imaginary'] == 0.0) { $activeSuffix = ''; }
+ return self::COMPLEX($returnValue['real'],$returnValue['imaginary'],$activeSuffix);
+ } // function IMSUM()
+
+
+ /**
+ * IMPRODUCT
+ *
+ * Returns the product of two or more complex numbers in x + yi or x + yj text format.
+ *
+ * @param array of mixed Data Series
+ * @return real
+ */
+ public static function IMPRODUCT() {
+ // Return value
+ $returnValue = self::_parseComplex('1');
+ $activeSuffix = '';
+
+ // Loop through the arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ $parsedComplex = self::_parseComplex($arg);
+ if (!is_array($parsedComplex)) {
+ return $parsedComplex;
+ }
+ $workValue = $returnValue;
+ if (($parsedComplex['suffix'] != '') && ($activeSuffix == '')) {
+ $activeSuffix = $parsedComplex['suffix'];
+ } elseif (($parsedComplex['suffix'] != '') && ($activeSuffix != $parsedComplex['suffix'])) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $returnValue['real'] = ($workValue['real'] * $parsedComplex['real']) - ($workValue['imaginary'] * $parsedComplex['imaginary']);
+ $returnValue['imaginary'] = ($workValue['real'] * $parsedComplex['imaginary']) + ($workValue['imaginary'] * $parsedComplex['real']);
+ }
+
+ if ($returnValue['imaginary'] == 0.0) { $activeSuffix = ''; }
+ return self::COMPLEX($returnValue['real'],$returnValue['imaginary'],$activeSuffix);
+ } // function IMPRODUCT()
+
+
+ /**
+ * DELTA
+ *
+ * Tests whether two values are equal. Returns 1 if number1 = number2; returns 0 otherwise.
+ *
+ * @param float $a
+ * @param float $b
+ * @return int
+ */
+ public static function DELTA($a, $b=0) {
+ $a = PHPExcel_Calculation_Functions::flattenSingleValue($a);
+ $b = PHPExcel_Calculation_Functions::flattenSingleValue($b);
+
+ return (int) ($a == $b);
+ } // function DELTA()
+
+
+ /**
+ * GESTEP
+ *
+ * Returns 1 if number = step; returns 0 (zero) otherwise
+ *
+ * @param float $number
+ * @param float $step
+ * @return int
+ */
+ public static function GESTEP($number, $step=0) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+ $step = PHPExcel_Calculation_Functions::flattenSingleValue($step);
+
+ return (int) ($number >= $step);
+ } // function GESTEP()
+
+
+ //
+ // Private method to calculate the erf value
+ //
+ private static $_two_sqrtpi = 1.128379167095512574;
+
+ public static function _erfVal($x) {
+ if (abs($x) > 2.2) {
+ return 1 - self::_erfcVal($x);
+ }
+ $sum = $term = $x;
+ $xsqr = ($x * $x);
+ $j = 1;
+ do {
+ $term *= $xsqr / $j;
+ $sum -= $term / (2 * $j + 1);
+ ++$j;
+ $term *= $xsqr / $j;
+ $sum += $term / (2 * $j + 1);
+ ++$j;
+ if ($sum == 0.0) {
+ break;
+ }
+ } while (abs($term / $sum) > PRECISION);
+ return self::$_two_sqrtpi * $sum;
+ } // function _erfVal()
+
+
+ /**
+ * ERF
+ *
+ * Returns the error function integrated between lower_limit and upper_limit
+ *
+ * @param float $lower lower bound for integrating ERF
+ * @param float $upper upper bound for integrating ERF.
+ * If omitted, ERF integrates between zero and lower_limit
+ * @return int
+ */
+ public static function ERF($lower, $upper = null) {
+ $lower = PHPExcel_Calculation_Functions::flattenSingleValue($lower);
+ $upper = PHPExcel_Calculation_Functions::flattenSingleValue($upper);
+
+ if (is_numeric($lower)) {
+ if ($lower < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (is_null($upper)) {
+ return self::_erfVal($lower);
+ }
+ if (is_numeric($upper)) {
+ if ($upper < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return self::_erfVal($upper) - self::_erfVal($lower);
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function ERF()
+
+
+ //
+ // Private method to calculate the erfc value
+ //
+ private static $_one_sqrtpi = 0.564189583547756287;
+
+ private static function _erfcVal($x) {
+ if (abs($x) < 2.2) {
+ return 1 - self::_erfVal($x);
+ }
+ if ($x < 0) {
+ return 2 - self::ERFC(-$x);
+ }
+ $a = $n = 1;
+ $b = $c = $x;
+ $d = ($x * $x) + 0.5;
+ $q1 = $q2 = $b / $d;
+ $t = 0;
+ do {
+ $t = $a * $n + $b * $x;
+ $a = $b;
+ $b = $t;
+ $t = $c * $n + $d * $x;
+ $c = $d;
+ $d = $t;
+ $n += 0.5;
+ $q1 = $q2;
+ $q2 = $b / $d;
+ } while ((abs($q1 - $q2) / $q2) > PRECISION);
+ return self::$_one_sqrtpi * exp(-$x * $x) * $q2;
+ } // function _erfcVal()
+
+
+ /**
+ * ERFC
+ *
+ * Returns the complementary ERF function integrated between x and infinity
+ *
+ * @param float $x The lower bound for integrating ERF
+ * @return int
+ */
+ public static function ERFC($x) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+
+ if (is_numeric($x)) {
+ if ($x < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return self::_erfcVal($x);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function ERFC()
+
+
+ /**
+ * getConversionGroups
+ *
+ * @return array
+ */
+ public static function getConversionGroups() {
+ $conversionGroups = array();
+ foreach(self::$_conversionUnits as $conversionUnit) {
+ $conversionGroups[] = $conversionUnit['Group'];
+ }
+ return array_merge(array_unique($conversionGroups));
+ } // function getConversionGroups()
+
+
+ /**
+ * getConversionGroupUnits
+ *
+ * @return array
+ */
+ public static function getConversionGroupUnits($group = NULL) {
+ $conversionGroups = array();
+ foreach(self::$_conversionUnits as $conversionUnit => $conversionGroup) {
+ if ((is_null($group)) || ($conversionGroup['Group'] == $group)) {
+ $conversionGroups[$conversionGroup['Group']][] = $conversionUnit;
+ }
+ }
+ return $conversionGroups;
+ } // function getConversionGroupUnits()
+
+
+ /**
+ * getConversionGroupUnitDetails
+ *
+ * @return array
+ */
+ public static function getConversionGroupUnitDetails($group = NULL) {
+ $conversionGroups = array();
+ foreach(self::$_conversionUnits as $conversionUnit => $conversionGroup) {
+ if ((is_null($group)) || ($conversionGroup['Group'] == $group)) {
+ $conversionGroups[$conversionGroup['Group']][] = array( 'unit' => $conversionUnit,
+ 'description' => $conversionGroup['Unit Name']
+ );
+ }
+ }
+ return $conversionGroups;
+ } // function getConversionGroupUnitDetails()
+
+
+ /**
+ * getConversionGroups
+ *
+ * @return array
+ */
+ public static function getConversionMultipliers() {
+ return self::$_conversionMultipliers;
+ } // function getConversionGroups()
+
+
+ /**
+ * CONVERTUOM
+ *
+ * @param float $value
+ * @param string $fromUOM
+ * @param string $toUOM
+ * @return float
+ */
+ public static function CONVERTUOM($value, $fromUOM, $toUOM) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $fromUOM = PHPExcel_Calculation_Functions::flattenSingleValue($fromUOM);
+ $toUOM = PHPExcel_Calculation_Functions::flattenSingleValue($toUOM);
+
+ if (!is_numeric($value)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $fromMultiplier = 1;
+ if (isset(self::$_conversionUnits[$fromUOM])) {
+ $unitGroup1 = self::$_conversionUnits[$fromUOM]['Group'];
+ } else {
+ $fromMultiplier = substr($fromUOM,0,1);
+ $fromUOM = substr($fromUOM,1);
+ if (isset(self::$_conversionMultipliers[$fromMultiplier])) {
+ $fromMultiplier = self::$_conversionMultipliers[$fromMultiplier]['multiplier'];
+ } else {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ if ((isset(self::$_conversionUnits[$fromUOM])) && (self::$_conversionUnits[$fromUOM]['AllowPrefix'])) {
+ $unitGroup1 = self::$_conversionUnits[$fromUOM]['Group'];
+ } else {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ }
+ $value *= $fromMultiplier;
+
+ $toMultiplier = 1;
+ if (isset(self::$_conversionUnits[$toUOM])) {
+ $unitGroup2 = self::$_conversionUnits[$toUOM]['Group'];
+ } else {
+ $toMultiplier = substr($toUOM,0,1);
+ $toUOM = substr($toUOM,1);
+ if (isset(self::$_conversionMultipliers[$toMultiplier])) {
+ $toMultiplier = self::$_conversionMultipliers[$toMultiplier]['multiplier'];
+ } else {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ if ((isset(self::$_conversionUnits[$toUOM])) && (self::$_conversionUnits[$toUOM]['AllowPrefix'])) {
+ $unitGroup2 = self::$_conversionUnits[$toUOM]['Group'];
+ } else {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ }
+ if ($unitGroup1 != $unitGroup2) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+
+ if ($fromUOM == $toUOM) {
+ return 1.0;
+ } elseif ($unitGroup1 == 'Temperature') {
+ if (($fromUOM == 'F') || ($fromUOM == 'fah')) {
+ if (($toUOM == 'F') || ($toUOM == 'fah')) {
+ return 1.0;
+ } else {
+ $value = (($value - 32) / 1.8);
+ if (($toUOM == 'K') || ($toUOM == 'kel')) {
+ $value += 273.15;
+ }
+ return $value;
+ }
+ } elseif ((($fromUOM == 'K') || ($fromUOM == 'kel')) &&
+ (($toUOM == 'K') || ($toUOM == 'kel'))) {
+ return 1.0;
+ } elseif ((($fromUOM == 'C') || ($fromUOM == 'cel')) &&
+ (($toUOM == 'C') || ($toUOM == 'cel'))) {
+ return 1.0;
+ }
+ if (($toUOM == 'F') || ($toUOM == 'fah')) {
+ if (($fromUOM == 'K') || ($fromUOM == 'kel')) {
+ $value -= 273.15;
+ }
+ return ($value * 1.8) + 32;
+ }
+ if (($toUOM == 'C') || ($toUOM == 'cel')) {
+ return $value - 273.15;
+ }
+ return $value + 273.15;
+ }
+ return ($value * self::$_unitConversions[$unitGroup1][$fromUOM][$toUOM]) / $toMultiplier;
+ } // function CONVERTUOM()
+
+} // class PHPExcel_Calculation_Engineering
diff --git a/Classes/PHPExcel/Calculation/Financial.php b/Classes/PHPExcel/Calculation/Financial.php
new file mode 100644
index 00000000..509caaba
--- /dev/null
+++ b/Classes/PHPExcel/Calculation/Financial.php
@@ -0,0 +1,1818 @@
+modify('+1 day');
+ return ($date->format('d') == 1);
+ } // function _lastDayOfMonth()
+
+
+ private static function _firstDayOfMonth($testDate) {
+ $date = clone $testDate;
+ return ($date->format('d') == 1);
+ } // function _lastDayOfMonth()
+
+
+ private static function _coupFirstPeriodDate($settlement, $maturity, $frequency, $next) {
+ $months = 12 / $frequency;
+
+ $result = PHPExcel_Shared_Date::ExcelToPHPObject($maturity);
+ $eom = self::_lastDayOfMonth($result);
+
+ while ($settlement < PHPExcel_Shared_Date::PHPToExcel($result)) {
+ $result->modify('-'.$months.' months');
+ }
+ if ($next) {
+ $result->modify('+'.$months.' months');
+ }
+
+ if ($eom) {
+ $result->modify('-1 day');
+ }
+
+ return PHPExcel_Shared_Date::PHPToExcel($result);
+ } // function _coupFirstPeriodDate()
+
+
+ private static function _validFrequency($frequency) {
+ if (($frequency == 1) || ($frequency == 2) || ($frequency == 4)) {
+ return true;
+ }
+ if ((PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) &&
+ (($frequency == 6) || ($frequency == 12))) {
+ return true;
+ }
+ return false;
+ } // function _validFrequency()
+
+
+ private static function _daysPerYear($year,$basis) {
+ switch ($basis) {
+ case 0 :
+ case 2 :
+ case 4 :
+ $daysPerYear = 360;
+ break;
+ case 3 :
+ $daysPerYear = 365;
+ break;
+ case 1 :
+ if (PHPExcel_Calculation_DateTime::_isLeapYear($year)) {
+ $daysPerYear = 366;
+ } else {
+ $daysPerYear = 365;
+ }
+ break;
+ default :
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return $daysPerYear;
+ } // function _daysPerYear()
+
+
+ private static function _interestAndPrincipal($rate=0, $per=0, $nper=0, $pv=0, $fv=0, $type=0) {
+ $pmt = self::PMT($rate, $nper, $pv, $fv, $type);
+ $capital = $pv;
+ for ($i = 1; $i<= $per; ++$i) {
+ $interest = ($type && $i == 1) ? 0 : -$capital * $rate;
+ $principal = $pmt - $interest;
+ $capital += $principal;
+ }
+ return array($interest, $principal);
+ } // function _interestAndPrincipal()
+
+
+ /**
+ * ACCRINT
+ *
+ * Returns the discount rate for a security.
+ *
+ * @param mixed issue The security's issue date.
+ * @param mixed firstinter The security's first interest date.
+ * @param mixed settlement The security's settlement date.
+ * @param float rate The security's annual coupon rate.
+ * @param float par The security's par value.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function ACCRINT($issue, $firstinter, $settlement, $rate, $par=1000, $frequency=1, $basis=0) {
+ $issue = PHPExcel_Calculation_Functions::flattenSingleValue($issue);
+ $firstinter = PHPExcel_Calculation_Functions::flattenSingleValue($firstinter);
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $rate = (float) PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $par = (is_null($par)) ? 1000 : (float) PHPExcel_Calculation_Functions::flattenSingleValue($par);
+ $frequency = (is_null($frequency)) ? 1 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if ((is_numeric($rate)) && (is_numeric($par))) {
+ if (($rate <= 0) || ($par <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysBetweenIssueAndSettlement = PHPExcel_Calculation_DateTime::YEARFRAC($issue, $settlement, $basis);
+ if (!is_numeric($daysBetweenIssueAndSettlement)) {
+ // return date error
+ return $daysBetweenIssueAndSettlement;
+ }
+
+ return $par * $rate * $daysBetweenIssueAndSettlement;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function ACCRINT()
+
+
+ /**
+ * ACCRINTM
+ *
+ * Returns the discount rate for a security.
+ *
+ * @param mixed issue The security's issue date.
+ * @param mixed settlement The security's settlement date.
+ * @param float rate The security's annual coupon rate.
+ * @param float par The security's par value.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function ACCRINTM($issue, $settlement, $rate, $par=1000, $basis=0) {
+ $issue = PHPExcel_Calculation_Functions::flattenSingleValue($issue);
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $rate = (float) PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $par = (is_null($par)) ? 1000 : (float) PHPExcel_Calculation_Functions::flattenSingleValue($par);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if ((is_numeric($rate)) && (is_numeric($par))) {
+ if (($rate <= 0) || ($par <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysBetweenIssueAndSettlement = PHPExcel_Calculation_DateTime::YEARFRAC($issue, $settlement, $basis);
+ if (!is_numeric($daysBetweenIssueAndSettlement)) {
+ // return date error
+ return $daysBetweenIssueAndSettlement;
+ }
+ return $par * $rate * $daysBetweenIssueAndSettlement;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function ACCRINTM()
+
+
+ public static function AMORDEGRC($cost, $purchased, $firstPeriod, $salvage, $period, $rate, $basis=0) {
+ $cost = PHPExcel_Calculation_Functions::flattenSingleValue($cost);
+ $purchased = PHPExcel_Calculation_Functions::flattenSingleValue($purchased);
+ $firstPeriod = PHPExcel_Calculation_Functions::flattenSingleValue($firstPeriod);
+ $salvage = PHPExcel_Calculation_Functions::flattenSingleValue($salvage);
+ $period = floor(PHPExcel_Calculation_Functions::flattenSingleValue($period));
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ $fUsePer = 1.0 / $rate;
+
+ if ($fUsePer < 3.0) {
+ $amortiseCoeff = 1.0;
+ } elseif ($fUsePer < 5.0) {
+ $amortiseCoeff = 1.5;
+ } elseif ($fUsePer <= 6.0) {
+ $amortiseCoeff = 2.0;
+ } else {
+ $amortiseCoeff = 2.5;
+ }
+
+ $rate *= $amortiseCoeff;
+ $fNRate = round(PHPExcel_Calculation_DateTime::YEARFRAC($purchased, $firstPeriod, $basis) * $rate * $cost,0);
+ $cost -= $fNRate;
+ $fRest = $cost - $salvage;
+
+ for ($n = 0; $n < $period; ++$n) {
+ $fNRate = round($rate * $cost,0);
+ $fRest -= $fNRate;
+
+ if ($fRest < 0.0) {
+ switch ($period - $n) {
+ case 0 :
+ case 1 : return round($cost * 0.5,0);
+ break;
+ default : return 0.0;
+ break;
+ }
+ }
+ $cost -= $fNRate;
+ }
+ return $fNRate;
+ } // function AMORDEGRC()
+
+
+ public static function AMORLINC($cost, $purchased, $firstPeriod, $salvage, $period, $rate, $basis=0) {
+ $cost = PHPExcel_Calculation_Functions::flattenSingleValue($cost);
+ $purchased = PHPExcel_Calculation_Functions::flattenSingleValue($purchased);
+ $firstPeriod = PHPExcel_Calculation_Functions::flattenSingleValue($firstPeriod);
+ $salvage = PHPExcel_Calculation_Functions::flattenSingleValue($salvage);
+ $period = PHPExcel_Calculation_Functions::flattenSingleValue($period);
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ $fOneRate = $cost * $rate;
+ $fCostDelta = $cost - $salvage;
+ // Note, quirky variation for leap years on the YEARFRAC for this function
+ $purchasedYear = PHPExcel_Calculation_DateTime::YEAR($purchased);
+ $yearFrac = PHPExcel_Calculation_DateTime::YEARFRAC($purchased, $firstPeriod, $basis);
+
+ if (($basis == 1) && ($yearFrac < 1) && (PHPExcel_Calculation_DateTime::_isLeapYear($purchasedYear))) {
+ $yearFrac *= 365 / 366;
+ }
+
+ $f0Rate = $yearFrac * $rate * $cost;
+ $nNumOfFullPeriods = intval(($cost - $salvage - $f0Rate) / $fOneRate);
+
+ if ($period == 0) {
+ return $f0Rate;
+ } elseif ($period <= $nNumOfFullPeriods) {
+ return $fOneRate;
+ } elseif ($period == ($nNumOfFullPeriods + 1)) {
+ return ($fCostDelta - $fOneRate * $nNumOfFullPeriods - $f0Rate);
+ } else {
+ return 0.0;
+ }
+ } // function AMORLINC()
+
+
+ public static function COUPDAYBS($settlement, $maturity, $frequency, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $frequency = (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ if (is_string($settlement = PHPExcel_Calculation_DateTime::_getDateValue($settlement))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (($settlement > $maturity) ||
+ (!self::_validFrequency($frequency)) ||
+ (($basis < 0) || ($basis > 4))) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $daysPerYear = self::_daysPerYear(PHPExcel_Calculation_DateTime::YEAR($settlement),$basis);
+ $prev = self::_coupFirstPeriodDate($settlement, $maturity, $frequency, False);
+
+ return PHPExcel_Calculation_DateTime::YEARFRAC($prev, $settlement, $basis) * $daysPerYear;
+ } // function COUPDAYBS()
+
+
+ public static function COUPDAYS($settlement, $maturity, $frequency, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $frequency = (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ if (is_string($settlement = PHPExcel_Calculation_DateTime::_getDateValue($settlement))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (($settlement > $maturity) ||
+ (!self::_validFrequency($frequency)) ||
+ (($basis < 0) || ($basis > 4))) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ switch ($basis) {
+ case 3: // Actual/365
+ return 365 / $frequency;
+ case 1: // Actual/actual
+ if ($frequency == 1) {
+ $daysPerYear = self::_daysPerYear(PHPExcel_Calculation_DateTime::YEAR($maturity),$basis);
+ return ($daysPerYear / $frequency);
+ } else {
+ $prev = self::_coupFirstPeriodDate($settlement, $maturity, $frequency, False);
+ $next = self::_coupFirstPeriodDate($settlement, $maturity, $frequency, True);
+ return ($next - $prev);
+ }
+ default: // US (NASD) 30/360, Actual/360 or European 30/360
+ return 360 / $frequency;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function COUPDAYS()
+
+
+ public static function COUPDAYSNC($settlement, $maturity, $frequency, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $frequency = (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ if (is_string($settlement = PHPExcel_Calculation_DateTime::_getDateValue($settlement))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (($settlement > $maturity) ||
+ (!self::_validFrequency($frequency)) ||
+ (($basis < 0) || ($basis > 4))) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $daysPerYear = self::_daysPerYear(PHPExcel_Calculation_DateTime::YEAR($settlement),$basis);
+ $next = self::_coupFirstPeriodDate($settlement, $maturity, $frequency, True);
+
+ return PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $next, $basis) * $daysPerYear;
+ } // function COUPDAYSNC()
+
+
+ public static function COUPNCD($settlement, $maturity, $frequency, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $frequency = (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ if (is_string($settlement = PHPExcel_Calculation_DateTime::_getDateValue($settlement))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (($settlement > $maturity) ||
+ (!self::_validFrequency($frequency)) ||
+ (($basis < 0) || ($basis > 4))) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ return self::_coupFirstPeriodDate($settlement, $maturity, $frequency, True);
+ } // function COUPNCD()
+
+
+ public static function COUPNUM($settlement, $maturity, $frequency, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $frequency = (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ if (is_string($settlement = PHPExcel_Calculation_DateTime::_getDateValue($settlement))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (($settlement > $maturity) ||
+ (!self::_validFrequency($frequency)) ||
+ (($basis < 0) || ($basis > 4))) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $settlement = self::_coupFirstPeriodDate($settlement, $maturity, $frequency, True);
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity, $basis) * 365;
+
+ switch ($frequency) {
+ case 1: // annual payments
+ return ceil($daysBetweenSettlementAndMaturity / 360);
+ case 2: // half-yearly
+ return ceil($daysBetweenSettlementAndMaturity / 180);
+ case 4: // quarterly
+ return ceil($daysBetweenSettlementAndMaturity / 90);
+ case 6: // bimonthly
+ return ceil($daysBetweenSettlementAndMaturity / 60);
+ case 12: // monthly
+ return ceil($daysBetweenSettlementAndMaturity / 30);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function COUPNUM()
+
+
+ public static function COUPPCD($settlement, $maturity, $frequency, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $frequency = (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ if (is_string($settlement = PHPExcel_Calculation_DateTime::_getDateValue($settlement))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (($settlement > $maturity) ||
+ (!self::_validFrequency($frequency)) ||
+ (($basis < 0) || ($basis > 4))) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ return self::_coupFirstPeriodDate($settlement, $maturity, $frequency, False);
+ } // function COUPPCD()
+
+
+ /**
+ * CUMIPMT
+ *
+ * Returns the cumulative interest paid on a loan between start_period and end_period.
+ *
+ * @param float $rate Interest rate per period
+ * @param int $nper Number of periods
+ * @param float $pv Present Value
+ * @param int start The first period in the calculation.
+ * Payment periods are numbered beginning with 1.
+ * @param int end The last period in the calculation.
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function CUMIPMT($rate, $nper, $pv, $start, $end, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $nper = (int) PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $start = (int) PHPExcel_Calculation_Functions::flattenSingleValue($start);
+ $end = (int) PHPExcel_Calculation_Functions::flattenSingleValue($end);
+ $type = (int) PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($start < 1 || $start > $end) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Calculate
+ $interest = 0;
+ for ($per = $start; $per <= $end; ++$per) {
+ $interest += self::IPMT($rate, $per, $nper, $pv, 0, $type);
+ }
+
+ return $interest;
+ } // function CUMIPMT()
+
+
+ /**
+ * CUMPRINC
+ *
+ * Returns the cumulative principal paid on a loan between start_period and end_period.
+ *
+ * @param float $rate Interest rate per period
+ * @param int $nper Number of periods
+ * @param float $pv Present Value
+ * @param int start The first period in the calculation.
+ * Payment periods are numbered beginning with 1.
+ * @param int end The last period in the calculation.
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function CUMPRINC($rate, $nper, $pv, $start, $end, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $nper = (int) PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $start = (int) PHPExcel_Calculation_Functions::flattenSingleValue($start);
+ $end = (int) PHPExcel_Calculation_Functions::flattenSingleValue($end);
+ $type = (int) PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($start < 1 || $start > $end) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Calculate
+ $principal = 0;
+ for ($per = $start; $per <= $end; ++$per) {
+ $principal += self::PPMT($rate, $per, $nper, $pv, 0, $type);
+ }
+
+ return $principal;
+ } // function CUMPRINC()
+
+
+ /**
+ * DB
+ *
+ * Returns the depreciation of an asset for a specified period using the fixed-declining balance method.
+ * This form of depreciation is used if you want to get a higher depreciation value at the beginning of the depreciation
+ * (as opposed to linear depreciation). The depreciation value is reduced with every depreciation period by the
+ * depreciation already deducted from the initial cost.
+ *
+ * @param float cost Initial cost of the asset.
+ * @param float salvage Value at the end of the depreciation. (Sometimes called the salvage value of the asset)
+ * @param int life Number of periods over which the asset is depreciated. (Sometimes called the useful life of the asset)
+ * @param int period The period for which you want to calculate the depreciation. Period must use the same units as life.
+ * @param float month Number of months in the first year. If month is omitted, it defaults to 12.
+ * @return float
+ */
+ public static function DB($cost, $salvage, $life, $period, $month=12) {
+ $cost = (float) PHPExcel_Calculation_Functions::flattenSingleValue($cost);
+ $salvage = (float) PHPExcel_Calculation_Functions::flattenSingleValue($salvage);
+ $life = (int) PHPExcel_Calculation_Functions::flattenSingleValue($life);
+ $period = (int) PHPExcel_Calculation_Functions::flattenSingleValue($period);
+ $month = (int) PHPExcel_Calculation_Functions::flattenSingleValue($month);
+
+ // Validate
+ if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life)) && (is_numeric($period)) && (is_numeric($month))) {
+ if ($cost == 0) {
+ return 0.0;
+ } elseif (($cost < 0) || (($salvage / $cost) < 0) || ($life <= 0) || ($period < 1) || ($month < 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ // Set Fixed Depreciation Rate
+ $fixedDepreciationRate = 1 - pow(($salvage / $cost), (1 / $life));
+ $fixedDepreciationRate = round($fixedDepreciationRate, 3);
+
+ // Loop through each period calculating the depreciation
+ $previousDepreciation = 0;
+ for ($per = 1; $per <= $period; ++$per) {
+ if ($per == 1) {
+ $depreciation = $cost * $fixedDepreciationRate * $month / 12;
+ } elseif ($per == ($life + 1)) {
+ $depreciation = ($cost - $previousDepreciation) * $fixedDepreciationRate * (12 - $month) / 12;
+ } else {
+ $depreciation = ($cost - $previousDepreciation) * $fixedDepreciationRate;
+ }
+ $previousDepreciation += $depreciation;
+ }
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $depreciation = round($depreciation,2);
+ }
+ return $depreciation;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function DB()
+
+
+ /**
+ * DDB
+ *
+ * Returns the depreciation of an asset for a specified period using the double-declining balance method or some other method you specify.
+ *
+ * @param float cost Initial cost of the asset.
+ * @param float salvage Value at the end of the depreciation. (Sometimes called the salvage value of the asset)
+ * @param int life Number of periods over which the asset is depreciated. (Sometimes called the useful life of the asset)
+ * @param int period The period for which you want to calculate the depreciation. Period must use the same units as life.
+ * @param float factor The rate at which the balance declines.
+ * If factor is omitted, it is assumed to be 2 (the double-declining balance method).
+ * @return float
+ */
+ public static function DDB($cost, $salvage, $life, $period, $factor=2.0) {
+ $cost = (float) PHPExcel_Calculation_Functions::flattenSingleValue($cost);
+ $salvage = (float) PHPExcel_Calculation_Functions::flattenSingleValue($salvage);
+ $life = (int) PHPExcel_Calculation_Functions::flattenSingleValue($life);
+ $period = (int) PHPExcel_Calculation_Functions::flattenSingleValue($period);
+ $factor = (float) PHPExcel_Calculation_Functions::flattenSingleValue($factor);
+
+ // Validate
+ if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life)) && (is_numeric($period)) && (is_numeric($factor))) {
+ if (($cost <= 0) || (($salvage / $cost) < 0) || ($life <= 0) || ($period < 1) || ($factor <= 0.0) || ($period > $life)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ // Set Fixed Depreciation Rate
+ $fixedDepreciationRate = 1 - pow(($salvage / $cost), (1 / $life));
+ $fixedDepreciationRate = round($fixedDepreciationRate, 3);
+
+ // Loop through each period calculating the depreciation
+ $previousDepreciation = 0;
+ for ($per = 1; $per <= $period; ++$per) {
+ $depreciation = min( ($cost - $previousDepreciation) * ($factor / $life), ($cost - $salvage - $previousDepreciation) );
+ $previousDepreciation += $depreciation;
+ }
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ $depreciation = round($depreciation,2);
+ }
+ return $depreciation;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function DDB()
+
+
+ /**
+ * DISC
+ *
+ * Returns the discount rate for a security.
+ *
+ * @param mixed settlement The security's settlement date.
+ * The security settlement date is the date after the issue date when the security is traded to the buyer.
+ * @param mixed maturity The security's maturity date.
+ * The maturity date is the date when the security expires.
+ * @param int price The security's price per $100 face value.
+ * @param int redemption the security's redemption value per $100 face value.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function DISC($settlement, $maturity, $price, $redemption, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $price = (float) PHPExcel_Calculation_Functions::flattenSingleValue($price);
+ $redemption = (float) PHPExcel_Calculation_Functions::flattenSingleValue($redemption);
+ $basis = (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if ((is_numeric($price)) && (is_numeric($redemption)) && (is_numeric($basis))) {
+ if (($price <= 0) || ($redemption <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity, $basis);
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+
+ return ((1 - $price / $redemption) / $daysBetweenSettlementAndMaturity);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function DISC()
+
+
+ /**
+ * DOLLARDE
+ *
+ * Converts a dollar price expressed as an integer part and a fraction part into a dollar price expressed as a decimal number.
+ * Fractional dollar numbers are sometimes used for security prices.
+ *
+ * @param float $fractional_dollar Fractional Dollar
+ * @param int $fraction Fraction
+ * @return float
+ */
+ public static function DOLLARDE($fractional_dollar = Null, $fraction = 0) {
+ $fractional_dollar = PHPExcel_Calculation_Functions::flattenSingleValue($fractional_dollar);
+ $fraction = (int)PHPExcel_Calculation_Functions::flattenSingleValue($fraction);
+
+ // Validate parameters
+ if (is_null($fractional_dollar) || $fraction < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($fraction == 0) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $dollars = floor($fractional_dollar);
+ $cents = fmod($fractional_dollar,1);
+ $cents /= $fraction;
+ $cents *= pow(10,ceil(log10($fraction)));
+ return $dollars + $cents;
+ } // function DOLLARDE()
+
+
+ /**
+ * DOLLARFR
+ *
+ * Converts a dollar price expressed as a decimal number into a dollar price expressed as a fraction.
+ * Fractional dollar numbers are sometimes used for security prices.
+ *
+ * @param float $decimal_dollar Decimal Dollar
+ * @param int $fraction Fraction
+ * @return float
+ */
+ public static function DOLLARFR($decimal_dollar = Null, $fraction = 0) {
+ $decimal_dollar = PHPExcel_Calculation_Functions::flattenSingleValue($decimal_dollar);
+ $fraction = (int)PHPExcel_Calculation_Functions::flattenSingleValue($fraction);
+
+ // Validate parameters
+ if (is_null($decimal_dollar) || $fraction < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($fraction == 0) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $dollars = floor($decimal_dollar);
+ $cents = fmod($decimal_dollar,1);
+ $cents *= $fraction;
+ $cents *= pow(10,-ceil(log10($fraction)));
+ return $dollars + $cents;
+ } // function DOLLARFR()
+
+
+ /**
+ * EFFECT
+ *
+ * Returns the effective interest rate given the nominal rate and the number of compounding payments per year.
+ *
+ * @param float $nominal_rate Nominal interest rate
+ * @param int $npery Number of compounding payments per year
+ * @return float
+ */
+ public static function EFFECT($nominal_rate = 0, $npery = 0) {
+ $nominal_rate = PHPExcel_Calculation_Functions::flattenSingleValue($nominal_rate);
+ $npery = (int)PHPExcel_Calculation_Functions::flattenSingleValue($npery);
+
+ // Validate parameters
+ if ($nominal_rate <= 0 || $npery < 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ return pow((1 + $nominal_rate / $npery), $npery) - 1;
+ } // function EFFECT()
+
+
+ /**
+ * FV
+ *
+ * Returns the Future Value of a cash flow with constant payments and interest rate (annuities).
+ *
+ * @param float $rate Interest rate per period
+ * @param int $nper Number of periods
+ * @param float $pmt Periodic payment (annuity)
+ * @param float $pv Present Value
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function FV($rate = 0, $nper = 0, $pmt = 0, $pv = 0, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $nper = PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pmt = PHPExcel_Calculation_Functions::flattenSingleValue($pmt);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $type = PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Calculate
+ if (!is_null($rate) && $rate != 0) {
+ return -$pv * pow(1 + $rate, $nper) - $pmt * (1 + $rate * $type) * (pow(1 + $rate, $nper) - 1) / $rate;
+ } else {
+ return -$pv - $pmt * $nper;
+ }
+ } // function FV()
+
+
+ /**
+ * FVSCHEDULE
+ *
+ */
+ public static function FVSCHEDULE($principal, $schedule) {
+ $principal = PHPExcel_Calculation_Functions::flattenSingleValue($principal);
+ $schedule = PHPExcel_Calculation_Functions::flattenArray($schedule);
+
+ foreach($schedule as $n) {
+ $principal *= 1 + $n;
+ }
+
+ return $principal;
+ } // function FVSCHEDULE()
+
+
+ /**
+ * INTRATE
+ *
+ * Returns the interest rate for a fully invested security.
+ *
+ * @param mixed settlement The security's settlement date.
+ * The security settlement date is the date after the issue date when the security is traded to the buyer.
+ * @param mixed maturity The security's maturity date.
+ * The maturity date is the date when the security expires.
+ * @param int investment The amount invested in the security.
+ * @param int redemption The amount to be received at maturity.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function INTRATE($settlement, $maturity, $investment, $redemption, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $investment = (float) PHPExcel_Calculation_Functions::flattenSingleValue($investment);
+ $redemption = (float) PHPExcel_Calculation_Functions::flattenSingleValue($redemption);
+ $basis = (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if ((is_numeric($investment)) && (is_numeric($redemption)) && (is_numeric($basis))) {
+ if (($investment <= 0) || ($redemption <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity, $basis);
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+
+ return (($redemption / $investment) - 1) / ($daysBetweenSettlementAndMaturity);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function INTRATE()
+
+
+ /**
+ * IPMT
+ *
+ * Returns the interest payment for a given period for an investment based on periodic, constant payments and a constant interest rate.
+ *
+ * @param float $rate Interest rate per period
+ * @param int $per Period for which we want to find the interest
+ * @param int $nper Number of periods
+ * @param float $pv Present Value
+ * @param float $fv Future Value
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function IPMT($rate, $per, $nper, $pv, $fv = 0, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $per = (int) PHPExcel_Calculation_Functions::flattenSingleValue($per);
+ $nper = (int) PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $fv = PHPExcel_Calculation_Functions::flattenSingleValue($fv);
+ $type = (int) PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($per <= 0 || $per > $nper) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Calculate
+ $interestAndPrincipal = self::_interestAndPrincipal($rate, $per, $nper, $pv, $fv, $type);
+ return $interestAndPrincipal[0];
+ } // function IPMT()
+
+
+ public static function IRR($values, $guess = 0.1) {
+ if (!is_array($values)) return PHPExcel_Calculation_Functions::VALUE();
+ $values = PHPExcel_Calculation_Functions::flattenArray($values);
+ $guess = PHPExcel_Calculation_Functions::flattenSingleValue($guess);
+
+ // create an initial range, with a root somewhere between 0 and guess
+ $x1 = 0.0;
+ $x2 = $guess;
+ $f1 = self::NPV($x1, $values);
+ $f2 = self::NPV($x2, $values);
+ for ($i = 0; $i < FINANCIAL_MAX_ITERATIONS; ++$i) {
+ if (($f1 * $f2) < 0.0) break;
+ if (abs($f1) < abs($f2)) {
+ $f1 = self::NPV($x1 += 1.6 * ($x1 - $x2), $values);
+ } else {
+ $f2 = self::NPV($x2 += 1.6 * ($x2 - $x1), $values);
+ }
+ }
+ if (($f1 * $f2) > 0.0) return PHPExcel_Calculation_Functions::VALUE();
+
+ $f = self::NPV($x1, $values);
+ if ($f < 0.0) {
+ $rtb = $x1;
+ $dx = $x2 - $x1;
+ } else {
+ $rtb = $x2;
+ $dx = $x1 - $x2;
+ }
+
+ for ($i = 0; $i < FINANCIAL_MAX_ITERATIONS; ++$i) {
+ $dx *= 0.5;
+ $x_mid = $rtb + $dx;
+ $f_mid = self::NPV($x_mid, $values);
+ if ($f_mid <= 0.0) $rtb = $x_mid;
+ if ((abs($f_mid) < FINANCIAL_PRECISION) || (abs($dx) < FINANCIAL_PRECISION)) return $x_mid;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function IRR()
+
+
+ /**
+ * ISPMT
+ *
+ * Returns the interest payment for an investment based on an interest rate and a constant payment schedule.
+ *
+ * Excel Function:
+ * =ISPMT(interest_rate, period, number_payments, PV)
+ *
+ * interest_rate is the interest rate for the investment
+ *
+ * period is the period to calculate the interest rate. It must be betweeen 1 and number_payments.
+ *
+ * number_payments is the number of payments for the annuity
+ *
+ * PV is the loan amount or present value of the payments
+ */
+ public static function ISPMT() {
+ // Return value
+ $returnValue = 0;
+
+ // Get the parameters
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ $interestRate = array_shift($aArgs);
+ $period = array_shift($aArgs);
+ $numberPeriods = array_shift($aArgs);
+ $principleRemaining = array_shift($aArgs);
+
+ // Calculate
+ $principlePayment = ($principleRemaining * 1.0) / ($numberPeriods * 1.0);
+ for($i=0; $i <= $period; ++$i) {
+ $returnValue = $interestRate * $principleRemaining * -1;
+ $principleRemaining -= $principlePayment;
+ // principle needs to be 0 after the last payment, don't let floating point screw it up
+ if($i == $numberPeriods) {
+ $returnValue = 0;
+ }
+ }
+ return($returnValue);
+ } // function ISPMT()
+
+
+ public static function MIRR($values, $finance_rate, $reinvestment_rate) {
+ if (!is_array($values)) return PHPExcel_Calculation_Functions::VALUE();
+ $values = PHPExcel_Calculation_Functions::flattenArray($values);
+ $finance_rate = PHPExcel_Calculation_Functions::flattenSingleValue($finance_rate);
+ $reinvestment_rate = PHPExcel_Calculation_Functions::flattenSingleValue($reinvestment_rate);
+ $n = count($values);
+
+ $rr = 1.0 + $reinvestment_rate;
+ $fr = 1.0 + $finance_rate;
+
+ $npv_pos = $npv_neg = 0.0;
+ foreach($values as $i => $v) {
+ if ($v >= 0) {
+ $npv_pos += $v / pow($rr, $i);
+ } else {
+ $npv_neg += $v / pow($fr, $i);
+ }
+ }
+
+ if (($npv_neg == 0) || ($npv_pos == 0) || ($reinvestment_rate <= -1)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ $mirr = pow((-$npv_pos * pow($rr, $n))
+ / ($npv_neg * ($rr)), (1.0 / ($n - 1))) - 1.0;
+
+ return (is_finite($mirr) ? $mirr : PHPExcel_Calculation_Functions::VALUE());
+ } // function MIRR()
+
+
+ /**
+ * NOMINAL
+ *
+ * Returns the nominal interest rate given the effective rate and the number of compounding payments per year.
+ *
+ * @param float $effect_rate Effective interest rate
+ * @param int $npery Number of compounding payments per year
+ * @return float
+ */
+ public static function NOMINAL($effect_rate = 0, $npery = 0) {
+ $effect_rate = PHPExcel_Calculation_Functions::flattenSingleValue($effect_rate);
+ $npery = (int)PHPExcel_Calculation_Functions::flattenSingleValue($npery);
+
+ // Validate parameters
+ if ($effect_rate <= 0 || $npery < 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Calculate
+ return $npery * (pow($effect_rate + 1, 1 / $npery) - 1);
+ } // function NOMINAL()
+
+
+ /**
+ * NPER
+ *
+ * Returns the number of periods for a cash flow with constant periodic payments (annuities), and interest rate.
+ *
+ * @param float $rate Interest rate per period
+ * @param int $pmt Periodic payment (annuity)
+ * @param float $pv Present Value
+ * @param float $fv Future Value
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function NPER($rate = 0, $pmt = 0, $pv = 0, $fv = 0, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $pmt = PHPExcel_Calculation_Functions::flattenSingleValue($pmt);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $fv = PHPExcel_Calculation_Functions::flattenSingleValue($fv);
+ $type = PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Calculate
+ if (!is_null($rate) && $rate != 0) {
+ if ($pmt == 0 && $pv == 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return log(($pmt * (1 + $rate * $type) / $rate - $fv) / ($pv + $pmt * (1 + $rate * $type) / $rate)) / log(1 + $rate);
+ } else {
+ if ($pmt == 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return (-$pv -$fv) / $pmt;
+ }
+ } // function NPER()
+
+
+ /**
+ * NPV
+ *
+ * Returns the Net Present Value of a cash flow series given a discount rate.
+ *
+ * @param float Discount interest rate
+ * @param array Cash flow series
+ * @return float
+ */
+ public static function NPV() {
+ // Return value
+ $returnValue = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ // Calculate
+ $rate = array_shift($aArgs);
+ for ($i = 1; $i <= count($aArgs); ++$i) {
+ // Is it a numeric value?
+ if (is_numeric($aArgs[$i - 1])) {
+ $returnValue += $aArgs[$i - 1] / pow(1 + $rate, $i);
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function NPV()
+
+
+ /**
+ * PMT
+ *
+ * Returns the constant payment (annuity) for a cash flow with a constant interest rate.
+ *
+ * @param float $rate Interest rate per period
+ * @param int $nper Number of periods
+ * @param float $pv Present Value
+ * @param float $fv Future Value
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function PMT($rate = 0, $nper = 0, $pv = 0, $fv = 0, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $nper = PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $fv = PHPExcel_Calculation_Functions::flattenSingleValue($fv);
+ $type = PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Calculate
+ if (!is_null($rate) && $rate != 0) {
+ return (-$fv - $pv * pow(1 + $rate, $nper)) / (1 + $rate * $type) / ((pow(1 + $rate, $nper) - 1) / $rate);
+ } else {
+ return (-$pv - $fv) / $nper;
+ }
+ } // function PMT()
+
+
+ /**
+ * PPMT
+ *
+ * Returns the interest payment for a given period for an investment based on periodic, constant payments and a constant interest rate.
+ *
+ * @param float $rate Interest rate per period
+ * @param int $per Period for which we want to find the interest
+ * @param int $nper Number of periods
+ * @param float $pv Present Value
+ * @param float $fv Future Value
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function PPMT($rate, $per, $nper, $pv, $fv = 0, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $per = (int) PHPExcel_Calculation_Functions::flattenSingleValue($per);
+ $nper = (int) PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $fv = PHPExcel_Calculation_Functions::flattenSingleValue($fv);
+ $type = (int) PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($per <= 0 || $per > $nper) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Calculate
+ $interestAndPrincipal = self::_interestAndPrincipal($rate, $per, $nper, $pv, $fv, $type);
+ return $interestAndPrincipal[1];
+ } // function PPMT()
+
+
+ public static function PRICE($settlement, $maturity, $rate, $yield, $redemption, $frequency, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $rate = (float) PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $yield = (float) PHPExcel_Calculation_Functions::flattenSingleValue($yield);
+ $redemption = (float) PHPExcel_Calculation_Functions::flattenSingleValue($redemption);
+ $frequency = (int) PHPExcel_Calculation_Functions::flattenSingleValue($frequency);
+ $basis = (is_null($basis)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ if (is_string($settlement = PHPExcel_Calculation_DateTime::_getDateValue($settlement))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (($settlement > $maturity) ||
+ (!self::_validFrequency($frequency)) ||
+ (($basis < 0) || ($basis > 4))) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $dsc = self::COUPDAYSNC($settlement, $maturity, $frequency, $basis);
+ $e = self::COUPDAYS($settlement, $maturity, $frequency, $basis);
+ $n = self::COUPNUM($settlement, $maturity, $frequency, $basis);
+ $a = self::COUPDAYBS($settlement, $maturity, $frequency, $basis);
+
+ $baseYF = 1.0 + ($yield / $frequency);
+ $rfp = 100 * ($rate / $frequency);
+ $de = $dsc / $e;
+
+ $result = $redemption / pow($baseYF, (--$n + $de));
+ for($k = 0; $k <= $n; ++$k) {
+ $result += $rfp / (pow($baseYF, ($k + $de)));
+ }
+ $result -= $rfp * ($a / $e);
+
+ return $result;
+ } // function PRICE()
+
+
+ /**
+ * PRICEDISC
+ *
+ * Returns the price per $100 face value of a discounted security.
+ *
+ * @param mixed settlement The security's settlement date.
+ * The security settlement date is the date after the issue date when the security is traded to the buyer.
+ * @param mixed maturity The security's maturity date.
+ * The maturity date is the date when the security expires.
+ * @param int discount The security's discount rate.
+ * @param int redemption The security's redemption value per $100 face value.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function PRICEDISC($settlement, $maturity, $discount, $redemption, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $discount = (float) PHPExcel_Calculation_Functions::flattenSingleValue($discount);
+ $redemption = (float) PHPExcel_Calculation_Functions::flattenSingleValue($redemption);
+ $basis = (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if ((is_numeric($discount)) && (is_numeric($redemption)) && (is_numeric($basis))) {
+ if (($discount <= 0) || ($redemption <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity, $basis);
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+
+ return $redemption * (1 - $discount * $daysBetweenSettlementAndMaturity);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function PRICEDISC()
+
+
+ /**
+ * PRICEMAT
+ *
+ * Returns the price per $100 face value of a security that pays interest at maturity.
+ *
+ * @param mixed settlement The security's settlement date.
+ * The security's settlement date is the date after the issue date when the security is traded to the buyer.
+ * @param mixed maturity The security's maturity date.
+ * The maturity date is the date when the security expires.
+ * @param mixed issue The security's issue date.
+ * @param int rate The security's interest rate at date of issue.
+ * @param int yield The security's annual yield.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function PRICEMAT($settlement, $maturity, $issue, $rate, $yield, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $issue = PHPExcel_Calculation_Functions::flattenSingleValue($issue);
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $yield = PHPExcel_Calculation_Functions::flattenSingleValue($yield);
+ $basis = (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if (is_numeric($rate) && is_numeric($yield)) {
+ if (($rate <= 0) || ($yield <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysPerYear = self::_daysPerYear(PHPExcel_Calculation_DateTime::YEAR($settlement),$basis);
+ if (!is_numeric($daysPerYear)) {
+ return $daysPerYear;
+ }
+ $daysBetweenIssueAndSettlement = PHPExcel_Calculation_DateTime::YEARFRAC($issue, $settlement, $basis);
+ if (!is_numeric($daysBetweenIssueAndSettlement)) {
+ // return date error
+ return $daysBetweenIssueAndSettlement;
+ }
+ $daysBetweenIssueAndSettlement *= $daysPerYear;
+ $daysBetweenIssueAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($issue, $maturity, $basis);
+ if (!is_numeric($daysBetweenIssueAndMaturity)) {
+ // return date error
+ return $daysBetweenIssueAndMaturity;
+ }
+ $daysBetweenIssueAndMaturity *= $daysPerYear;
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity, $basis);
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+ $daysBetweenSettlementAndMaturity *= $daysPerYear;
+
+ return ((100 + (($daysBetweenIssueAndMaturity / $daysPerYear) * $rate * 100)) /
+ (1 + (($daysBetweenSettlementAndMaturity / $daysPerYear) * $yield)) -
+ (($daysBetweenIssueAndSettlement / $daysPerYear) * $rate * 100));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function PRICEMAT()
+
+
+ /**
+ * PV
+ *
+ * Returns the Present Value of a cash flow with constant payments and interest rate (annuities).
+ *
+ * @param float $rate Interest rate per period
+ * @param int $nper Number of periods
+ * @param float $pmt Periodic payment (annuity)
+ * @param float $fv Future Value
+ * @param int $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
+ * @return float
+ */
+ public static function PV($rate = 0, $nper = 0, $pmt = 0, $fv = 0, $type = 0) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $nper = PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pmt = PHPExcel_Calculation_Functions::flattenSingleValue($pmt);
+ $fv = PHPExcel_Calculation_Functions::flattenSingleValue($fv);
+ $type = PHPExcel_Calculation_Functions::flattenSingleValue($type);
+
+ // Validate parameters
+ if ($type != 0 && $type != 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ // Calculate
+ if (!is_null($rate) && $rate != 0) {
+ return (-$pmt * (1 + $rate * $type) * ((pow(1 + $rate, $nper) - 1) / $rate) - $fv) / pow(1 + $rate, $nper);
+ } else {
+ return -$fv - $pmt * $nper;
+ }
+ } // function PV()
+
+
+ /**
+ * RATE
+ *
+ **/
+ public static function RATE($nper, $pmt, $pv, $fv = 0.0, $type = 0, $guess = 0.1) {
+ $nper = (int) PHPExcel_Calculation_Functions::flattenSingleValue($nper);
+ $pmt = PHPExcel_Calculation_Functions::flattenSingleValue($pmt);
+ $pv = PHPExcel_Calculation_Functions::flattenSingleValue($pv);
+ $fv = (is_null($fv)) ? 0.0 : PHPExcel_Calculation_Functions::flattenSingleValue($fv);
+ $type = (is_null($type)) ? 0 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($type);
+ $guess = (is_null($guess)) ? 0.1 : PHPExcel_Calculation_Functions::flattenSingleValue($guess);
+
+ $rate = $guess;
+ if (abs($rate) < FINANCIAL_PRECISION) {
+ $y = $pv * (1 + $nper * $rate) + $pmt * (1 + $rate * $type) * $nper + $fv;
+ } else {
+ $f = exp($nper * log(1 + $rate));
+ $y = $pv * $f + $pmt * (1 / $rate + $type) * ($f - 1) + $fv;
+ }
+ $y0 = $pv + $pmt * $nper + $fv;
+ $y1 = $pv * $f + $pmt * (1 / $rate + $type) * ($f - 1) + $fv;
+
+ // find root by secant method
+ $i = $x0 = 0.0;
+ $x1 = $rate;
+ while ((abs($y0 - $y1) > FINANCIAL_PRECISION) && ($i < FINANCIAL_MAX_ITERATIONS)) {
+ $rate = ($y1 * $x0 - $y0 * $x1) / ($y1 - $y0);
+ $x0 = $x1;
+ $x1 = $rate;
+
+ if (abs($rate) < FINANCIAL_PRECISION) {
+ $y = $pv * (1 + $nper * $rate) + $pmt * (1 + $rate * $type) * $nper + $fv;
+ } else {
+ $f = exp($nper * log(1 + $rate));
+ $y = $pv * $f + $pmt * (1 / $rate + $type) * ($f - 1) + $fv;
+ }
+
+ $y0 = $y1;
+ $y1 = $y;
+ ++$i;
+ }
+ return $rate;
+ } // function RATE()
+
+
+ /**
+ * RECEIVED
+ *
+ * Returns the price per $100 face value of a discounted security.
+ *
+ * @param mixed settlement The security's settlement date.
+ * The security settlement date is the date after the issue date when the security is traded to the buyer.
+ * @param mixed maturity The security's maturity date.
+ * The maturity date is the date when the security expires.
+ * @param int investment The amount invested in the security.
+ * @param int discount The security's discount rate.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function RECEIVED($settlement, $maturity, $investment, $discount, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $investment = (float) PHPExcel_Calculation_Functions::flattenSingleValue($investment);
+ $discount = (float) PHPExcel_Calculation_Functions::flattenSingleValue($discount);
+ $basis = (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if ((is_numeric($investment)) && (is_numeric($discount)) && (is_numeric($basis))) {
+ if (($investment <= 0) || ($discount <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity, $basis);
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+
+ return $investment / ( 1 - ($discount * $daysBetweenSettlementAndMaturity));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function RECEIVED()
+
+
+ /**
+ * SLN
+ *
+ * Returns the straight-line depreciation of an asset for one period
+ *
+ * @param cost Initial cost of the asset
+ * @param salvage Value at the end of the depreciation
+ * @param life Number of periods over which the asset is depreciated
+ * @return float
+ */
+ public static function SLN($cost, $salvage, $life) {
+ $cost = PHPExcel_Calculation_Functions::flattenSingleValue($cost);
+ $salvage = PHPExcel_Calculation_Functions::flattenSingleValue($salvage);
+ $life = PHPExcel_Calculation_Functions::flattenSingleValue($life);
+
+ // Calculate
+ if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life))) {
+ if ($life < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return ($cost - $salvage) / $life;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SLN()
+
+
+ /**
+ * SYD
+ *
+ * Returns the sum-of-years' digits depreciation of an asset for a specified period.
+ *
+ * @param cost Initial cost of the asset
+ * @param salvage Value at the end of the depreciation
+ * @param life Number of periods over which the asset is depreciated
+ * @param period Period
+ * @return float
+ */
+ public static function SYD($cost, $salvage, $life, $period) {
+ $cost = PHPExcel_Calculation_Functions::flattenSingleValue($cost);
+ $salvage = PHPExcel_Calculation_Functions::flattenSingleValue($salvage);
+ $life = PHPExcel_Calculation_Functions::flattenSingleValue($life);
+ $period = PHPExcel_Calculation_Functions::flattenSingleValue($period);
+
+ // Calculate
+ if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life)) && (is_numeric($period))) {
+ if (($life < 1) || ($period > $life)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return (($cost - $salvage) * ($life - $period + 1) * 2) / ($life * ($life + 1));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SYD()
+
+
+ /**
+ * TBILLEQ
+ *
+ * Returns the bond-equivalent yield for a Treasury bill.
+ *
+ * @param mixed settlement The Treasury bill's settlement date.
+ * The Treasury bill's settlement date is the date after the issue date when the Treasury bill is traded to the buyer.
+ * @param mixed maturity The Treasury bill's maturity date.
+ * The maturity date is the date when the Treasury bill expires.
+ * @param int discount The Treasury bill's discount rate.
+ * @return float
+ */
+ public static function TBILLEQ($settlement, $maturity, $discount) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $discount = PHPExcel_Calculation_Functions::flattenSingleValue($discount);
+
+ // Use TBILLPRICE for validation
+ $testValue = self::TBILLPRICE($settlement, $maturity, $discount);
+ if (is_string($testValue)) {
+ return $testValue;
+ }
+
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ ++$maturity;
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity) * 360;
+ } else {
+ $daysBetweenSettlementAndMaturity = (PHPExcel_Calculation_DateTime::_getDateValue($maturity) - PHPExcel_Calculation_DateTime::_getDateValue($settlement));
+ }
+
+ return (365 * $discount) / (360 - $discount * $daysBetweenSettlementAndMaturity);
+ } // function TBILLEQ()
+
+
+ /**
+ * TBILLPRICE
+ *
+ * Returns the yield for a Treasury bill.
+ *
+ * @param mixed settlement The Treasury bill's settlement date.
+ * The Treasury bill's settlement date is the date after the issue date when the Treasury bill is traded to the buyer.
+ * @param mixed maturity The Treasury bill's maturity date.
+ * The maturity date is the date when the Treasury bill expires.
+ * @param int discount The Treasury bill's discount rate.
+ * @return float
+ */
+ public static function TBILLPRICE($settlement, $maturity, $discount) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $discount = PHPExcel_Calculation_Functions::flattenSingleValue($discount);
+
+ if (is_string($maturity = PHPExcel_Calculation_DateTime::_getDateValue($maturity))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Validate
+ if (is_numeric($discount)) {
+ if ($discount <= 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ ++$maturity;
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity) * 360;
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+ } else {
+ $daysBetweenSettlementAndMaturity = (PHPExcel_Calculation_DateTime::_getDateValue($maturity) - PHPExcel_Calculation_DateTime::_getDateValue($settlement));
+ }
+
+ if ($daysBetweenSettlementAndMaturity > 360) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $price = 100 * (1 - (($discount * $daysBetweenSettlementAndMaturity) / 360));
+ if ($price <= 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return $price;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function TBILLPRICE()
+
+
+ /**
+ * TBILLYIELD
+ *
+ * Returns the yield for a Treasury bill.
+ *
+ * @param mixed settlement The Treasury bill's settlement date.
+ * The Treasury bill's settlement date is the date after the issue date when the Treasury bill is traded to the buyer.
+ * @param mixed maturity The Treasury bill's maturity date.
+ * The maturity date is the date when the Treasury bill expires.
+ * @param int price The Treasury bill's price per $100 face value.
+ * @return float
+ */
+ public static function TBILLYIELD($settlement, $maturity, $price) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $price = PHPExcel_Calculation_Functions::flattenSingleValue($price);
+
+ // Validate
+ if (is_numeric($price)) {
+ if ($price <= 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ ++$maturity;
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity) * 360;
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+ } else {
+ $daysBetweenSettlementAndMaturity = (PHPExcel_Calculation_DateTime::_getDateValue($maturity) - PHPExcel_Calculation_DateTime::_getDateValue($settlement));
+ }
+
+ if ($daysBetweenSettlementAndMaturity > 360) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ return ((100 - $price) / $price) * (360 / $daysBetweenSettlementAndMaturity);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function TBILLYIELD()
+
+
+ public static function XIRR($values, $dates, $guess = 0.1) {
+ if ((!is_array($values)) && (!is_array($dates))) return PHPExcel_Calculation_Functions::VALUE();
+ $values = PHPExcel_Calculation_Functions::flattenArray($values);
+ $dates = PHPExcel_Calculation_Functions::flattenArray($dates);
+ $guess = PHPExcel_Calculation_Functions::flattenSingleValue($guess);
+ if (count($values) != count($dates)) return PHPExcel_Calculation_Functions::NaN();
+
+ // create an initial range, with a root somewhere between 0 and guess
+ $x1 = 0.0;
+ $x2 = $guess;
+ $f1 = self::XNPV($x1, $values, $dates);
+ $f2 = self::XNPV($x2, $values, $dates);
+ for ($i = 0; $i < FINANCIAL_MAX_ITERATIONS; ++$i) {
+ if (($f1 * $f2) < 0.0) break;
+ if (abs($f1) < abs($f2)) {
+ $f1 = self::XNPV($x1 += 1.6 * ($x1 - $x2), $values, $dates);
+ } else {
+ $f2 = self::XNPV($x2 += 1.6 * ($x2 - $x1), $values, $dates);
+ }
+ }
+ if (($f1 * $f2) > 0.0) return PHPExcel_Calculation_Functions::VALUE();
+
+ $f = self::XNPV($x1, $values, $dates);
+ if ($f < 0.0) {
+ $rtb = $x1;
+ $dx = $x2 - $x1;
+ } else {
+ $rtb = $x2;
+ $dx = $x1 - $x2;
+ }
+
+ for ($i = 0; $i < FINANCIAL_MAX_ITERATIONS; ++$i) {
+ $dx *= 0.5;
+ $x_mid = $rtb + $dx;
+ $f_mid = self::XNPV($x_mid, $values, $dates);
+ if ($f_mid <= 0.0) $rtb = $x_mid;
+ if ((abs($f_mid) < FINANCIAL_PRECISION) || (abs($dx) < FINANCIAL_PRECISION)) return $x_mid;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+
+ /**
+ * XNPV
+ *
+ * Returns the net present value for a schedule of cash flows that is not necessarily periodic.
+ * To calculate the net present value for a series of cash flows that is periodic, use the NPV function.
+ *
+ * Excel Function:
+ * =XNPV(rate,values,dates)
+ *
+ * @param float $rate The discount rate to apply to the cash flows.
+ * @param array of float $values A series of cash flows that corresponds to a schedule of payments in dates. The first payment is optional and corresponds to a cost or payment that occurs at the beginning of the investment. If the first value is a cost or payment, it must be a negative value. All succeeding payments are discounted based on a 365-day year. The series of values must contain at least one positive value and one negative value.
+ * @param array of mixed $dates A schedule of payment dates that corresponds to the cash flow payments. The first payment date indicates the beginning of the schedule of payments. All other dates must be later than this date, but they may occur in any order.
+ * @return float
+ */
+ public static function XNPV($rate, $values, $dates) {
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ if (!is_numeric($rate)) return PHPExcel_Calculation_Functions::VALUE();
+ if ((!is_array($values)) || (!is_array($dates))) return PHPExcel_Calculation_Functions::VALUE();
+ $values = PHPExcel_Calculation_Functions::flattenArray($values);
+ $dates = PHPExcel_Calculation_Functions::flattenArray($dates);
+ $valCount = count($values);
+ if ($valCount != count($dates)) return PHPExcel_Calculation_Functions::NaN();
+ if ((min($values) > 0) || (max($values) < 0)) return PHPExcel_Calculation_Functions::VALUE();
+
+ $xnpv = 0.0;
+ for ($i = 0; $i < $valCount; ++$i) {
+ if (!is_numeric($values[$i])) return PHPExcel_Calculation_Functions::VALUE();
+ $xnpv += $values[$i] / pow(1 + $rate, PHPExcel_Calculation_DateTime::DATEDIF($dates[0],$dates[$i],'d') / 365);
+ }
+ return (is_finite($xnpv)) ? $xnpv : PHPExcel_Calculation_Functions::VALUE();
+ } // function XNPV()
+
+
+ /**
+ * YIELDDISC
+ *
+ * Returns the annual yield of a security that pays interest at maturity.
+ *
+ * @param mixed settlement The security's settlement date.
+ * The security's settlement date is the date after the issue date when the security is traded to the buyer.
+ * @param mixed maturity The security's maturity date.
+ * The maturity date is the date when the security expires.
+ * @param int price The security's price per $100 face value.
+ * @param int redemption The security's redemption value per $100 face value.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function YIELDDISC($settlement, $maturity, $price, $redemption, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $price = PHPExcel_Calculation_Functions::flattenSingleValue($price);
+ $redemption = PHPExcel_Calculation_Functions::flattenSingleValue($redemption);
+ $basis = (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if (is_numeric($price) && is_numeric($redemption)) {
+ if (($price <= 0) || ($redemption <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysPerYear = self::_daysPerYear(PHPExcel_Calculation_DateTime::YEAR($settlement),$basis);
+ if (!is_numeric($daysPerYear)) {
+ return $daysPerYear;
+ }
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity,$basis);
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+ $daysBetweenSettlementAndMaturity *= $daysPerYear;
+
+ return (($redemption - $price) / $price) * ($daysPerYear / $daysBetweenSettlementAndMaturity);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function YIELDDISC()
+
+
+ /**
+ * YIELDMAT
+ *
+ * Returns the annual yield of a security that pays interest at maturity.
+ *
+ * @param mixed settlement The security's settlement date.
+ * The security's settlement date is the date after the issue date when the security is traded to the buyer.
+ * @param mixed maturity The security's maturity date.
+ * The maturity date is the date when the security expires.
+ * @param mixed issue The security's issue date.
+ * @param int rate The security's interest rate at date of issue.
+ * @param int price The security's price per $100 face value.
+ * @param int basis The type of day count to use.
+ * 0 or omitted US (NASD) 30/360
+ * 1 Actual/actual
+ * 2 Actual/360
+ * 3 Actual/365
+ * 4 European 30/360
+ * @return float
+ */
+ public static function YIELDMAT($settlement, $maturity, $issue, $rate, $price, $basis=0) {
+ $settlement = PHPExcel_Calculation_Functions::flattenSingleValue($settlement);
+ $maturity = PHPExcel_Calculation_Functions::flattenSingleValue($maturity);
+ $issue = PHPExcel_Calculation_Functions::flattenSingleValue($issue);
+ $rate = PHPExcel_Calculation_Functions::flattenSingleValue($rate);
+ $price = PHPExcel_Calculation_Functions::flattenSingleValue($price);
+ $basis = (int) PHPExcel_Calculation_Functions::flattenSingleValue($basis);
+
+ // Validate
+ if (is_numeric($rate) && is_numeric($price)) {
+ if (($rate <= 0) || ($price <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $daysPerYear = self::_daysPerYear(PHPExcel_Calculation_DateTime::YEAR($settlement),$basis);
+ if (!is_numeric($daysPerYear)) {
+ return $daysPerYear;
+ }
+ $daysBetweenIssueAndSettlement = PHPExcel_Calculation_DateTime::YEARFRAC($issue, $settlement, $basis);
+ if (!is_numeric($daysBetweenIssueAndSettlement)) {
+ // return date error
+ return $daysBetweenIssueAndSettlement;
+ }
+ $daysBetweenIssueAndSettlement *= $daysPerYear;
+ $daysBetweenIssueAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($issue, $maturity, $basis);
+ if (!is_numeric($daysBetweenIssueAndMaturity)) {
+ // return date error
+ return $daysBetweenIssueAndMaturity;
+ }
+ $daysBetweenIssueAndMaturity *= $daysPerYear;
+ $daysBetweenSettlementAndMaturity = PHPExcel_Calculation_DateTime::YEARFRAC($settlement, $maturity, $basis);
+ if (!is_numeric($daysBetweenSettlementAndMaturity)) {
+ // return date error
+ return $daysBetweenSettlementAndMaturity;
+ }
+ $daysBetweenSettlementAndMaturity *= $daysPerYear;
+
+ return ((1 + (($daysBetweenIssueAndMaturity / $daysPerYear) * $rate) - (($price / 100) + (($daysBetweenIssueAndSettlement / $daysPerYear) * $rate))) /
+ (($price / 100) + (($daysBetweenIssueAndSettlement / $daysPerYear) * $rate))) *
+ ($daysPerYear / $daysBetweenSettlementAndMaturity);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function YIELDMAT()
+
+} // class PHPExcel_Calculation_Financial
diff --git a/Classes/PHPExcel/Calculation/Logical.php b/Classes/PHPExcel/Calculation/Logical.php
new file mode 100644
index 00000000..97b2cb1d
--- /dev/null
+++ b/Classes/PHPExcel/Calculation/Logical.php
@@ -0,0 +1,290 @@
+ '') {
+ if (strpos($sheetText,' ') !== False) { $sheetText = "'".$sheetText."'"; }
+ $sheetText .='!';
+ }
+ if ((!is_bool($referenceStyle)) || $referenceStyle) {
+ $rowRelative = $columnRelative = '$';
+ $column = PHPExcel_Cell::stringFromColumnIndex($column-1);
+ if (($relativity == 2) || ($relativity == 4)) { $columnRelative = ''; }
+ if (($relativity == 3) || ($relativity == 4)) { $rowRelative = ''; }
+ return $sheetText.$columnRelative.$column.$rowRelative.$row;
+ } else {
+ if (($relativity == 2) || ($relativity == 4)) { $column = '['.$column.']'; }
+ if (($relativity == 3) || ($relativity == 4)) { $row = '['.$row.']'; }
+ return $sheetText.'R'.$row.'C'.$column;
+ }
+ } // function CELL_ADDRESS()
+
+
+ /**
+ * COLUMN
+ *
+ * Returns the column number of the given cell reference
+ * If the cell reference is a range of cells, COLUMN returns the column numbers of each column in the reference as a horizontal array.
+ * If cell reference is omitted, and the function is being called through the calculation engine, then it is assumed to be the
+ * reference of the cell in which the COLUMN function appears; otherwise this function returns 0.
+ *
+ * @param cellAddress A reference to a range of cells for which you want the column numbers
+ * @return integer or array of integer
+ */
+ public static function COLUMN($cellAddress=Null) {
+ if (is_null($cellAddress) || trim($cellAddress) === '') { return 0; }
+
+ if (is_array($cellAddress)) {
+ foreach($cellAddress as $columnKey => $value) {
+ $columnKey = preg_replace('/[^a-z]/i','',$columnKey);
+ return (integer) PHPExcel_Cell::columnIndexFromString($columnKey);
+ }
+ } else {
+ if (strpos($cellAddress,'!') !== false) {
+ list($sheet,$cellAddress) = explode('!',$cellAddress);
+ }
+ if (strpos($cellAddress,':') !== false) {
+ list($startAddress,$endAddress) = explode(':',$cellAddress);
+ $startAddress = preg_replace('/[^a-z]/i','',$startAddress);
+ $endAddress = preg_replace('/[^a-z]/i','',$endAddress);
+ $returnValue = array();
+ do {
+ $returnValue[] = (integer) PHPExcel_Cell::columnIndexFromString($startAddress);
+ } while ($startAddress++ != $endAddress);
+ return $returnValue;
+ } else {
+ $cellAddress = preg_replace('/[^a-z]/i','',$cellAddress);
+ return (integer) PHPExcel_Cell::columnIndexFromString($cellAddress);
+ }
+ }
+ } // function COLUMN()
+
+
+ /**
+ * COLUMNS
+ *
+ * Returns the number of columns in an array or reference.
+ *
+ * @param cellAddress An array or array formula, or a reference to a range of cells for which you want the number of columns
+ * @return integer
+ */
+ public static function COLUMNS($cellAddress=Null) {
+ if (is_null($cellAddress) || $cellAddress === '') {
+ return 1;
+ } elseif (!is_array($cellAddress)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ $x = array_keys($cellAddress);
+ $x = array_shift($x);
+ $isMatrix = (is_numeric($x));
+ list($columns,$rows) = PHPExcel_Calculation::_getMatrixDimensions($cellAddress);
+
+ if ($isMatrix) {
+ return $rows;
+ } else {
+ return $columns;
+ }
+ } // function COLUMNS()
+
+
+ /**
+ * ROW
+ *
+ * Returns the row number of the given cell reference
+ * If the cell reference is a range of cells, ROW returns the row numbers of each row in the reference as a vertical array.
+ * If cell reference is omitted, and the function is being called through the calculation engine, then it is assumed to be the
+ * reference of the cell in which the ROW function appears; otherwise this function returns 0.
+ *
+ * @param cellAddress A reference to a range of cells for which you want the row numbers
+ * @return integer or array of integer
+ */
+ public static function ROW($cellAddress=Null) {
+ if (is_null($cellAddress) || trim($cellAddress) === '') { return 0; }
+
+ if (is_array($cellAddress)) {
+ foreach($cellAddress as $columnKey => $rowValue) {
+ foreach($rowValue as $rowKey => $cellValue) {
+ return (integer) preg_replace('/[^0-9]/i','',$rowKey);
+ }
+ }
+ } else {
+ if (strpos($cellAddress,'!') !== false) {
+ list($sheet,$cellAddress) = explode('!',$cellAddress);
+ }
+ if (strpos($cellAddress,':') !== false) {
+ list($startAddress,$endAddress) = explode(':',$cellAddress);
+ $startAddress = preg_replace('/[^0-9]/','',$startAddress);
+ $endAddress = preg_replace('/[^0-9]/','',$endAddress);
+ $returnValue = array();
+ do {
+ $returnValue[][] = (integer) $startAddress;
+ } while ($startAddress++ != $endAddress);
+ return $returnValue;
+ } else {
+ list($cellAddress) = explode(':',$cellAddress);
+ return (integer) preg_replace('/[^0-9]/','',$cellAddress);
+ }
+ }
+ } // function ROW()
+
+
+ /**
+ * ROWS
+ *
+ * Returns the number of rows in an array or reference.
+ *
+ * @param cellAddress An array or array formula, or a reference to a range of cells for which you want the number of rows
+ * @return integer
+ */
+ public static function ROWS($cellAddress=Null) {
+ if (is_null($cellAddress) || $cellAddress === '') {
+ return 1;
+ } elseif (!is_array($cellAddress)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ $i = array_keys($cellAddress);
+ $isMatrix = (is_numeric(array_shift($i)));
+ list($columns,$rows) = PHPExcel_Calculation::_getMatrixDimensions($cellAddress);
+
+ if ($isMatrix) {
+ return $columns;
+ } else {
+ return $rows;
+ }
+ } // function ROWS()
+
+
+ /**
+ * HYPERLINK
+ *
+ * Excel Function:
+ * =HYPERLINK(linkURL,displayName)
+ *
+ * @access public
+ * @category Logical Functions
+ * @param string $linkURL Value to check, is also the value returned when no error
+ * @param string $displayName Value to return when testValue is an error condition
+ * @return mixed The value of errorpart or testValue determined by error condition
+ */
+ public static function HYPERLINK($linkURL = '', $displayName = null, PHPExcel_Cell $pCell = null) {
+ $args = func_get_args();
+ $pCell = array_pop($args);
+
+ $linkURL = (is_null($linkURL)) ? '' : PHPExcel_Calculation_Functions::flattenSingleValue($linkURL);
+ $displayName = (is_null($displayName)) ? '' : PHPExcel_Calculation_Functions::flattenSingleValue($displayName);
+
+ if ((!is_object($pCell)) || (trim($linkURL) == '')) {
+ return PHPExcel_Calculation_Functions::REF();
+ }
+
+ if ((is_object($displayName)) || trim($displayName) == '') {
+ $displayName = $linkURL;
+ }
+
+ $pCell->getHyperlink()->setUrl($linkURL);
+
+ return $displayName;
+ } // function HYPERLINK()
+
+
+ /**
+ * INDIRECT
+ *
+ * Returns the number of rows in an array or reference.
+ *
+ * @param cellAddress An array or array formula, or a reference to a range of cells for which you want the number of rows
+ * @return integer
+ */
+ public static function INDIRECT($cellAddress=Null, PHPExcel_Cell $pCell = null) {
+ $cellAddress = PHPExcel_Calculation_Functions::flattenSingleValue($cellAddress);
+ if (is_null($cellAddress) || $cellAddress === '') {
+ return PHPExcel_Calculation_Functions::REF();
+ }
+
+ $cellAddress1 = $cellAddress;
+ $cellAddress2 = NULL;
+ if (strpos($cellAddress,':') !== false) {
+ list($cellAddress1,$cellAddress2) = explode(':',$cellAddress);
+ }
+
+ if ((!preg_match('/^'.PHPExcel_Calculation::CALCULATION_REGEXP_CELLREF.'$/i', $cellAddress1, $matches)) ||
+ ((!is_null($cellAddress2)) && (!preg_match('/^'.PHPExcel_Calculation::CALCULATION_REGEXP_CELLREF.'$/i', $cellAddress2, $matches)))) {
+ return PHPExcel_Calculation_Functions::REF();
+ }
+
+ if (strpos($cellAddress,'!') !== false) {
+ list($sheetName,$cellAddress) = explode('!',$cellAddress);
+ $pSheet = $pCell->getParent()->getParent()->getSheetByName($sheetName);
+ } else {
+ $pSheet = $pCell->getParent();
+ }
+
+ return PHPExcel_Calculation::getInstance()->extractCellRange($cellAddress, $pSheet, False);
+ } // function INDIRECT()
+
+
+ /**
+ * OFFSET
+ *
+ * Returns a reference to a range that is a specified number of rows and columns from a cell or range of cells.
+ * The reference that is returned can be a single cell or a range of cells. You can specify the number of rows and
+ * the number of columns to be returned.
+ *
+ * @param cellAddress The reference from which you want to base the offset. Reference must refer to a cell or
+ * range of adjacent cells; otherwise, OFFSET returns the #VALUE! error value.
+ * @param rows The number of rows, up or down, that you want the upper-left cell to refer to.
+ * Using 5 as the rows argument specifies that the upper-left cell in the reference is
+ * five rows below reference. Rows can be positive (which means below the starting reference)
+ * or negative (which means above the starting reference).
+ * @param cols The number of columns, to the left or right, that you want the upper-left cell of the result
+ * to refer to. Using 5 as the cols argument specifies that the upper-left cell in the
+ * reference is five columns to the right of reference. Cols can be positive (which means
+ * to the right of the starting reference) or negative (which means to the left of the
+ * starting reference).
+ * @param height The height, in number of rows, that you want the returned reference to be. Height must be a positive number.
+ * @param width The width, in number of columns, that you want the returned reference to be. Width must be a positive number.
+ * @return string A reference to a cell or range of cells
+ */
+ public static function OFFSET($cellAddress=Null,$rows=0,$columns=0,$height=null,$width=null) {
+ $rows = PHPExcel_Calculation_Functions::flattenSingleValue($rows);
+ $columns = PHPExcel_Calculation_Functions::flattenSingleValue($columns);
+ $height = PHPExcel_Calculation_Functions::flattenSingleValue($height);
+ $width = PHPExcel_Calculation_Functions::flattenSingleValue($width);
+ if ($cellAddress == Null) {
+ return 0;
+ }
+
+ $args = func_get_args();
+ $pCell = array_pop($args);
+ if (!is_object($pCell)) {
+ return PHPExcel_Calculation_Functions::REF();
+ }
+
+ $sheetName = null;
+ if (strpos($cellAddress,"!")) {
+ list($sheetName,$cellAddress) = explode("!",$cellAddress);
+ }
+ if (strpos($cellAddress,":")) {
+ list($startCell,$endCell) = explode(":",$cellAddress);
+ } else {
+ $startCell = $endCell = $cellAddress;
+ }
+ list($startCellColumn,$startCellRow) = PHPExcel_Cell::coordinateFromString($startCell);
+ list($endCellColumn,$endCellRow) = PHPExcel_Cell::coordinateFromString($endCell);
+
+ $startCellRow += $rows;
+ $startCellColumn = PHPExcel_Cell::columnIndexFromString($startCellColumn) - 1;
+ $startCellColumn += $columns;
+
+ if (($startCellRow <= 0) || ($startCellColumn < 0)) {
+ return PHPExcel_Calculation_Functions::REF();
+ }
+ $endCellColumn = PHPExcel_Cell::columnIndexFromString($endCellColumn) - 1;
+ if (($width != null) && (!is_object($width))) {
+ $endCellColumn = $startCellColumn + $width - 1;
+ } else {
+ $endCellColumn += $columns;
+ }
+ $startCellColumn = PHPExcel_Cell::stringFromColumnIndex($startCellColumn);
+
+ if (($height != null) && (!is_object($height))) {
+ $endCellRow = $startCellRow + $height - 1;
+ } else {
+ $endCellRow += $rows;
+ }
+
+ if (($endCellRow <= 0) || ($endCellColumn < 0)) {
+ return PHPExcel_Calculation_Functions::REF();
+ }
+ $endCellColumn = PHPExcel_Cell::stringFromColumnIndex($endCellColumn);
+
+ $cellAddress = $startCellColumn.$startCellRow;
+ if (($startCellColumn != $endCellColumn) || ($startCellRow != $endCellRow)) {
+ $cellAddress .= ':'.$endCellColumn.$endCellRow;
+ }
+
+ if ($sheetName !== null) {
+ $pSheet = $pCell->getParent()->getParent()->getSheetByName($sheetName);
+ } else {
+ $pSheet = $pCell->getParent();
+ }
+
+ return PHPExcel_Calculation::getInstance()->extractCellRange($cellAddress, $pSheet, False);
+ } // function OFFSET()
+
+
+ public static function CHOOSE() {
+ $chooseArgs = func_get_args();
+ $chosenEntry = PHPExcel_Calculation_Functions::flattenArray(array_shift($chooseArgs));
+ $entryCount = count($chooseArgs) - 1;
+
+ if(is_array($chosenEntry)) {
+ $chosenEntry = array_shift($chosenEntry);
+ }
+ if ((is_numeric($chosenEntry)) && (!is_bool($chosenEntry))) {
+ --$chosenEntry;
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $chosenEntry = floor($chosenEntry);
+ if (($chosenEntry <= 0) || ($chosenEntry > $entryCount)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (is_array($chooseArgs[$chosenEntry])) {
+ return PHPExcel_Calculation_Functions::flattenArray($chooseArgs[$chosenEntry]);
+ } else {
+ return $chooseArgs[$chosenEntry];
+ }
+ } // function CHOOSE()
+
+
+ /**
+ * MATCH
+ *
+ * The MATCH function searches for a specified item in a range of cells
+ *
+ * @param lookup_value The value that you want to match in lookup_array
+ * @param lookup_array The range of cells being searched
+ * @param match_type The number -1, 0, or 1. -1 means above, 0 means exact match, 1 means below. If match_type is 1 or -1, the list has to be ordered.
+ * @return integer The relative position of the found item
+ */
+ public static function MATCH($lookup_value, $lookup_array, $match_type=1) {
+ $lookup_array = PHPExcel_Calculation_Functions::flattenArray($lookup_array);
+ $lookup_value = PHPExcel_Calculation_Functions::flattenSingleValue($lookup_value);
+ $match_type = (is_null($match_type)) ? 1 : (int) PHPExcel_Calculation_Functions::flattenSingleValue($match_type);
+ // MATCH is not case sensitive
+ $lookup_value = strtolower($lookup_value);
+
+ // lookup_value type has to be number, text, or logical values
+ if ((!is_numeric($lookup_value)) && (!is_string($lookup_value)) && (!is_bool($lookup_value))) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+
+ // match_type is 0, 1 or -1
+ if (($match_type !== 0) && ($match_type !== -1) && ($match_type !== 1)) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+
+ // lookup_array should not be empty
+ $lookupArraySize = count($lookup_array);
+ if ($lookupArraySize <= 0) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+
+ // lookup_array should contain only number, text, or logical values, or empty (null) cells
+ foreach($lookup_array as $i => $lookupArrayValue) {
+ // check the type of the value
+ if ((!is_numeric($lookupArrayValue)) && (!is_string($lookupArrayValue)) &&
+ (!is_bool($lookupArrayValue)) && (!is_null($lookupArrayValue))) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ // convert strings to lowercase for case-insensitive testing
+ if (is_string($lookupArrayValue)) {
+ $lookup_array[$i] = strtolower($lookupArrayValue);
+ }
+ if ((is_null($lookupArrayValue)) && (($match_type == 1) || ($match_type == -1))) {
+ $lookup_array = array_slice($lookup_array,0,$i-1);
+ }
+ }
+
+ // if match_type is 1 or -1, the list has to be ordered
+ if ($match_type == 1) {
+ asort($lookup_array);
+ $keySet = array_keys($lookup_array);
+ } elseif($match_type == -1) {
+ arsort($lookup_array);
+ $keySet = array_keys($lookup_array);
+ }
+
+ // **
+ // find the match
+ // **
+ // loop on the cells
+// var_dump($lookup_array);
+// echo '
';
+ foreach($lookup_array as $i => $lookupArrayValue) {
+ if (($match_type == 0) && ($lookupArrayValue == $lookup_value)) {
+ // exact match
+ return ++$i;
+ } elseif (($match_type == -1) && ($lookupArrayValue <= $lookup_value)) {
+// echo '$i = '.$i.' => ';
+// var_dump($lookupArrayValue);
+// echo '
';
+// echo 'Keyset = ';
+// var_dump($keySet);
+// echo '
';
+ $i = array_search($i,$keySet);
+// echo '$i='.$i.'
';
+ // if match_type is -1 <=> find the smallest value that is greater than or equal to lookup_value
+ if ($i < 1){
+ // 1st cell was allready smaller than the lookup_value
+ break;
+ } else {
+ // the previous cell was the match
+ return $keySet[$i-1]+1;
+ }
+ } elseif (($match_type == 1) && ($lookupArrayValue >= $lookup_value)) {
+// echo '$i = '.$i.' => ';
+// var_dump($lookupArrayValue);
+// echo '
';
+// echo 'Keyset = ';
+// var_dump($keySet);
+// echo '
';
+ $i = array_search($i,$keySet);
+// echo '$i='.$i.'
';
+ // if match_type is 1 <=> find the largest value that is less than or equal to lookup_value
+ if ($i < 1){
+ // 1st cell was allready bigger than the lookup_value
+ break;
+ } else {
+ // the previous cell was the match
+ return $keySet[$i-1]+1;
+ }
+ }
+ }
+
+ // unsuccessful in finding a match, return #N/A error value
+ return PHPExcel_Calculation_Functions::NA();
+ } // function MATCH()
+
+
+ /**
+ * INDEX
+ *
+ * Uses an index to choose a value from a reference or array
+ * implemented: Return the value of a specified cell or array of cells Array form
+ * not implemented: Return a reference to specified cells Reference form
+ *
+ * @param range_array a range of cells or an array constant
+ * @param row_num selects the row in array from which to return a value. If row_num is omitted, column_num is required.
+ * @param column_num selects the column in array from which to return a value. If column_num is omitted, row_num is required.
+ */
+ public static function INDEX($arrayValues,$rowNum = 0,$columnNum = 0) {
+
+ if (($rowNum < 0) || ($columnNum < 0)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (!is_array($arrayValues)) {
+ return PHPExcel_Calculation_Functions::REF();
+ }
+
+ $rowKeys = array_keys($arrayValues);
+ $columnKeys = @array_keys($arrayValues[$rowKeys[0]]);
+
+ if ($columnNum > count($columnKeys)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ($columnNum == 0) {
+ if ($rowNum == 0) {
+ return $arrayValues;
+ }
+ $rowNum = $rowKeys[--$rowNum];
+ $returnArray = array();
+ foreach($arrayValues as $arrayColumn) {
+ if (is_array($arrayColumn)) {
+ if (isset($arrayColumn[$rowNum])) {
+ $returnArray[] = $arrayColumn[$rowNum];
+ } else {
+ return $arrayValues[$rowNum];
+ }
+ } else {
+ return $arrayValues[$rowNum];
+ }
+ }
+ return $returnArray;
+ }
+ $columnNum = $columnKeys[--$columnNum];
+ if ($rowNum > count($rowKeys)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ($rowNum == 0) {
+ return $arrayValues[$columnNum];
+ }
+ $rowNum = $rowKeys[--$rowNum];
+
+ return $arrayValues[$rowNum][$columnNum];
+ } // function INDEX()
+
+
+ /**
+ * TRANSPOSE
+ *
+ * @param array $matrixData A matrix of values
+ * @return array
+ *
+ * Unlike the Excel TRANSPOSE function, which will only work on a single row or column, this function will transpose a full matrix.
+ */
+ public static function TRANSPOSE($matrixData) {
+ $returnMatrix = array();
+ if (!is_array($matrixData)) { $matrixData = array(array($matrixData)); }
+
+ $column = 0;
+ foreach($matrixData as $matrixRow) {
+ $row = 0;
+ foreach($matrixRow as $matrixCell) {
+ $returnMatrix[$row][$column] = $matrixCell;
+ ++$row;
+ }
+ ++$column;
+ }
+ return $returnMatrix;
+ } // function TRANSPOSE()
+
+
+ private static function _vlookupSort($a,$b) {
+ $f = array_keys($a);
+ $firstColumn = array_shift($f);
+ if (strtolower($a[$firstColumn]) == strtolower($b[$firstColumn])) {
+ return 0;
+ }
+ return (strtolower($a[$firstColumn]) < strtolower($b[$firstColumn])) ? -1 : 1;
+ } // function _vlookupSort()
+
+
+ /**
+ * VLOOKUP
+ * The VLOOKUP function searches for value in the left-most column of lookup_array and returns the value in the same row based on the index_number.
+ * @param lookup_value The value that you want to match in lookup_array
+ * @param lookup_array The range of cells being searched
+ * @param index_number The column number in table_array from which the matching value must be returned. The first column is 1.
+ * @param not_exact_match Determines if you are looking for an exact match based on lookup_value.
+ * @return mixed The value of the found cell
+ */
+ public static function VLOOKUP($lookup_value, $lookup_array, $index_number, $not_exact_match=true) {
+ $lookup_value = PHPExcel_Calculation_Functions::flattenSingleValue($lookup_value);
+ $index_number = PHPExcel_Calculation_Functions::flattenSingleValue($index_number);
+ $not_exact_match = PHPExcel_Calculation_Functions::flattenSingleValue($not_exact_match);
+
+ // index_number must be greater than or equal to 1
+ if ($index_number < 1) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // index_number must be less than or equal to the number of columns in lookup_array
+ if ((!is_array($lookup_array)) || (count($lookup_array) < 1)) {
+ return PHPExcel_Calculation_Functions::REF();
+ } else {
+ $f = array_keys($lookup_array);
+ $firstRow = array_pop($f);
+ if ((!is_array($lookup_array[$firstRow])) || ($index_number > count($lookup_array[$firstRow]))) {
+ return PHPExcel_Calculation_Functions::REF();
+ } else {
+ $columnKeys = array_keys($lookup_array[$firstRow]);
+ $returnColumn = $columnKeys[--$index_number];
+ $firstColumn = array_shift($columnKeys);
+ }
+ }
+
+ if (!$not_exact_match) {
+ uasort($lookup_array,array('self','_vlookupSort'));
+ }
+
+ $rowNumber = $rowValue = False;
+ foreach($lookup_array as $rowKey => $rowData) {
+ if (strtolower($rowData[$firstColumn]) > strtolower($lookup_value)) {
+ break;
+ }
+ $rowNumber = $rowKey;
+ $rowValue = $rowData[$firstColumn];
+ }
+
+ if ($rowNumber !== false) {
+ if ((!$not_exact_match) && ($rowValue != $lookup_value)) {
+ // if an exact match is required, we have what we need to return an appropriate response
+ return PHPExcel_Calculation_Functions::NA();
+ } else {
+ // otherwise return the appropriate value
+ return $lookup_array[$rowNumber][$returnColumn];
+ }
+ }
+
+ return PHPExcel_Calculation_Functions::NA();
+ } // function VLOOKUP()
+
+
+ /**
+ * LOOKUP
+ * The LOOKUP function searches for value either from a one-row or one-column range or from an array.
+ * @param lookup_value The value that you want to match in lookup_array
+ * @param lookup_vector The range of cells being searched
+ * @param result_vector The column from which the matching value must be returned
+ * @return mixed The value of the found cell
+ */
+ public static function LOOKUP($lookup_value, $lookup_vector, $result_vector=null) {
+ $lookup_value = PHPExcel_Calculation_Functions::flattenSingleValue($lookup_value);
+
+ if (!is_array($lookup_vector)) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ $lookupRows = count($lookup_vector);
+ $l = array_keys($lookup_vector);
+ $l = array_shift($l);
+ $lookupColumns = count($lookup_vector[$l]);
+ if ((($lookupRows == 1) && ($lookupColumns > 1)) || (($lookupRows == 2) && ($lookupColumns != 2))) {
+ $lookup_vector = self::TRANSPOSE($lookup_vector);
+ $lookupRows = count($lookup_vector);
+ $l = array_keys($lookup_vector);
+ $lookupColumns = count($lookup_vector[array_shift($l)]);
+ }
+
+ if (is_null($result_vector)) {
+ $result_vector = $lookup_vector;
+ }
+ $resultRows = count($result_vector);
+ $l = array_keys($result_vector);
+ $l = array_shift($l);
+ $resultColumns = count($result_vector[$l]);
+ if ((($resultRows == 1) && ($resultColumns > 1)) || (($resultRows == 2) && ($resultColumns != 2))) {
+ $result_vector = self::TRANSPOSE($result_vector);
+ $resultRows = count($result_vector);
+ $r = array_keys($result_vector);
+ $resultColumns = count($result_vector[array_shift($r)]);
+ }
+
+ if ($lookupRows == 2) {
+ $result_vector = array_pop($lookup_vector);
+ $lookup_vector = array_shift($lookup_vector);
+ }
+ if ($lookupColumns != 2) {
+ foreach($lookup_vector as &$value) {
+ if (is_array($value)) {
+ $k = array_keys($value);
+ $key1 = $key2 = array_shift($k);
+ $key2++;
+ $dataValue1 = $value[$key1];
+ } else {
+ $key1 = 0;
+ $key2 = 1;
+ $dataValue1 = $value;
+ }
+ $dataValue2 = array_shift($result_vector);
+ if (is_array($dataValue2)) {
+ $dataValue2 = array_shift($dataValue2);
+ }
+ $value = array($key1 => $dataValue1, $key2 => $dataValue2);
+ }
+ unset($value);
+ }
+
+ return self::VLOOKUP($lookup_value,$lookup_vector,2);
+ } // function LOOKUP()
+
+} // class PHPExcel_Calculation_LookupRef
diff --git a/Classes/PHPExcel/Calculation/MathTrig.php b/Classes/PHPExcel/Calculation/MathTrig.php
new file mode 100644
index 00000000..d12cffc1
--- /dev/null
+++ b/Classes/PHPExcel/Calculation/MathTrig.php
@@ -0,0 +1,1241 @@
+ 1; --$i) {
+ if (($value % $i) == 0) {
+ $factorArray = array_merge($factorArray,self::_factors($value / $i));
+ $factorArray = array_merge($factorArray,self::_factors($i));
+ if ($i <= sqrt($value)) {
+ break;
+ }
+ }
+ }
+ if (count($factorArray) > 0) {
+ rsort($factorArray);
+ return $factorArray;
+ } else {
+ return array((integer) $value);
+ }
+ } // function _factors()
+
+
+ private static function _romanCut($num, $n) {
+ return ($num - ($num % $n ) ) / $n;
+ } // function _romanCut()
+
+
+ /**
+ * ATAN2
+ *
+ * This function calculates the arc tangent of the two variables x and y. It is similar to
+ * calculating the arc tangent of y ÷ x, except that the signs of both arguments are used
+ * to determine the quadrant of the result.
+ * The arctangent is the angle from the x-axis to a line containing the origin (0, 0) and a
+ * point with coordinates (xCoordinate, yCoordinate). The angle is given in radians between
+ * -pi and pi, excluding -pi.
+ *
+ * Note that the Excel ATAN2() function accepts its arguments in the reverse order to the standard
+ * PHP atan2() function, so we need to reverse them here before calling the PHP atan() function.
+ *
+ * Excel Function:
+ * ATAN2(xCoordinate,yCoordinate)
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param float $xCoordinate The x-coordinate of the point.
+ * @param float $yCoordinate The y-coordinate of the point.
+ * @return float The inverse tangent of the specified x- and y-coordinates.
+ */
+ public static function ATAN2($xCoordinate, $yCoordinate) {
+ $xCoordinate = (float) PHPExcel_Calculation_Functions::flattenSingleValue($xCoordinate);
+ $yCoordinate = (float) PHPExcel_Calculation_Functions::flattenSingleValue($yCoordinate);
+
+ if (($xCoordinate == 0) && ($yCoordinate == 0)) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ return atan2($yCoordinate, $xCoordinate);
+ } // function REVERSE_ATAN2()
+
+
+ /**
+ * CEILING
+ *
+ * Returns number rounded up, away from zero, to the nearest multiple of significance.
+ *
+ * @param float $number Number to round
+ * @param float $significance Significance
+ * @return float Rounded Number
+ */
+ public static function CEILING($number,$significance=null) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+ $significance = PHPExcel_Calculation_Functions::flattenSingleValue($significance);
+
+ if ((is_null($significance)) && (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC)) {
+ $significance = $number/abs($number);
+ }
+
+ if ((is_numeric($number)) && (is_numeric($significance))) {
+ if (self::SIGN($number) == self::SIGN($significance)) {
+ if ($significance == 0.0) {
+ return 0;
+ }
+ return ceil($number / $significance) * $significance;
+ } else {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function CEILING()
+
+
+ /**
+ * COMBIN
+ *
+ * Returns the number of combinations for a given number of items. Use COMBIN to
+ * determine the total possible number of groups for a given number of items.
+ *
+ * @param int $numObjs Number of different objects
+ * @param int $numInSet Number of objects in each combination
+ * @return int Number of combinations
+ */
+ public static function COMBIN($numObjs,$numInSet) {
+ $numObjs = PHPExcel_Calculation_Functions::flattenSingleValue($numObjs);
+ $numInSet = PHPExcel_Calculation_Functions::flattenSingleValue($numInSet);
+
+ if ((is_numeric($numObjs)) && (is_numeric($numInSet))) {
+ if ($numObjs < $numInSet) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } elseif ($numInSet < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return round(self::FACT($numObjs) / self::FACT($numObjs - $numInSet)) / self::FACT($numInSet);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function COMBIN()
+
+
+ /**
+ * EVEN
+ *
+ * Returns number rounded up to the nearest even integer.
+ *
+ * @param float $number Number to round
+ * @return int Rounded Number
+ */
+ public static function EVEN($number) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+
+ if (is_null($number)) {
+ return 0;
+ } elseif (is_numeric($number)) {
+ $significance = 2 * self::SIGN($number);
+ return (int) self::CEILING($number,$significance);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function EVEN()
+
+
+ /**
+ * FACT
+ *
+ * Returns the factorial of a number.
+ *
+ * @param float $factVal Factorial Value
+ * @return int Factorial
+ */
+ public static function FACT($factVal) {
+ $factVal = PHPExcel_Calculation_Functions::flattenSingleValue($factVal);
+
+ if (is_numeric($factVal)) {
+ if ($factVal < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $factLoop = floor($factVal);
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ if ($factVal > $factLoop) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ }
+
+ $factorial = 1;
+ while ($factLoop > 1) {
+ $factorial *= $factLoop--;
+ }
+ return $factorial ;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function FACT()
+
+
+ /**
+ * FACTDOUBLE
+ *
+ * Returns the double factorial of a number.
+ *
+ * @param float $factVal Factorial Value
+ * @return int Double Factorial
+ */
+ public static function FACTDOUBLE($factVal) {
+ $factLoop = floor(PHPExcel_Calculation_Functions::flattenSingleValue($factVal));
+
+ if (is_numeric($factLoop)) {
+ if ($factVal < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $factorial = 1;
+ while ($factLoop > 1) {
+ $factorial *= $factLoop--;
+ --$factLoop;
+ }
+ return $factorial ;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function FACTDOUBLE()
+
+
+ /**
+ * FLOOR
+ *
+ * Rounds number down, toward zero, to the nearest multiple of significance.
+ *
+ * @param float $number Number to round
+ * @param float $significance Significance
+ * @return float Rounded Number
+ */
+ public static function FLOOR($number,$significance=null) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+ $significance = PHPExcel_Calculation_Functions::flattenSingleValue($significance);
+
+ if ((is_null($significance)) && (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC)) {
+ $significance = $number/abs($number);
+ }
+
+ if ((is_numeric($number)) && (is_numeric($significance))) {
+ if ((float) $significance == 0.0) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+ if (self::SIGN($number) == self::SIGN($significance)) {
+ return floor($number / $significance) * $significance;
+ } else {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function FLOOR()
+
+
+ /**
+ * GCD
+ *
+ * Returns the greatest common divisor of a series of numbers
+ *
+ * @param $array Values to calculate the Greatest Common Divisor
+ * @return int Greatest Common Divisor
+ */
+ public static function GCD() {
+ $returnValue = 1;
+ $allPoweredFactors = array();
+ // Loop through arguments
+ foreach(PHPExcel_Calculation_Functions::flattenArray(func_get_args()) as $value) {
+ if ($value == 0) {
+ break;
+ }
+ $myFactors = self::_factors($value);
+ $myCountedFactors = array_count_values($myFactors);
+ $allValuesFactors[] = $myCountedFactors;
+ }
+ $allValuesCount = count($allValuesFactors);
+ $mergedArray = $allValuesFactors[0];
+ for ($i=1;$i < $allValuesCount; ++$i) {
+ $mergedArray = array_intersect_key($mergedArray,$allValuesFactors[$i]);
+ }
+ $mergedArrayValues = count($mergedArray);
+ if ($mergedArrayValues == 0) {
+ return $returnValue;
+ } elseif ($mergedArrayValues > 1) {
+ foreach($mergedArray as $mergedKey => $mergedValue) {
+ foreach($allValuesFactors as $highestPowerTest) {
+ foreach($highestPowerTest as $testKey => $testValue) {
+ if (($testKey == $mergedKey) && ($testValue < $mergedValue)) {
+ $mergedArray[$mergedKey] = $testValue;
+ $mergedValue = $testValue;
+ }
+ }
+ }
+ }
+
+ $returnValue = 1;
+ foreach($mergedArray as $key => $value) {
+ $returnValue *= pow($key,$value);
+ }
+ return $returnValue;
+ } else {
+ $keys = array_keys($mergedArray);
+ $key = $keys[0];
+ $value = $mergedArray[$key];
+ foreach($allValuesFactors as $testValue) {
+ foreach($testValue as $mergedKey => $mergedValue) {
+ if (($mergedKey == $key) && ($mergedValue < $value)) {
+ $value = $mergedValue;
+ }
+ }
+ }
+ return pow($key,$value);
+ }
+ } // function GCD()
+
+
+ /**
+ * INT
+ *
+ * Casts a floating point value to an integer
+ *
+ * @param float $number Number to cast to an integer
+ * @return integer Integer value
+ */
+ public static function INT($number) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+
+ if (is_numeric($number)) {
+ return (int) floor($number);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function INT()
+
+
+ /**
+ * LCM
+ *
+ * Returns the lowest common multiplier of a series of numbers
+ *
+ * @param $array Values to calculate the Lowest Common Multiplier
+ * @return int Lowest Common Multiplier
+ */
+ public static function LCM() {
+ $returnValue = 1;
+ $allPoweredFactors = array();
+ // Loop through arguments
+ foreach(PHPExcel_Calculation_Functions::flattenArray(func_get_args()) as $value) {
+ if (!is_numeric($value)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if ($value == 0) {
+ return 0;
+ } elseif ($value < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $myFactors = self::_factors(floor($value));
+ $myCountedFactors = array_count_values($myFactors);
+ $myPoweredFactors = array();
+ foreach($myCountedFactors as $myCountedFactor => $myCountedPower) {
+ $myPoweredFactors[$myCountedFactor] = pow($myCountedFactor,$myCountedPower);
+ }
+ foreach($myPoweredFactors as $myPoweredValue => $myPoweredFactor) {
+ if (array_key_exists($myPoweredValue,$allPoweredFactors)) {
+ if ($allPoweredFactors[$myPoweredValue] < $myPoweredFactor) {
+ $allPoweredFactors[$myPoweredValue] = $myPoweredFactor;
+ }
+ } else {
+ $allPoweredFactors[$myPoweredValue] = $myPoweredFactor;
+ }
+ }
+ }
+ foreach($allPoweredFactors as $allPoweredFactor) {
+ $returnValue *= (integer) $allPoweredFactor;
+ }
+ return $returnValue;
+ } // function LCM()
+
+
+ /**
+ * LOG_BASE
+ *
+ * Returns the logarithm of a number to a specified base. The default base is 10.
+ *
+ * Excel Function:
+ * LOG(number[,base])
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param float $value The positive real number for which you want the logarithm
+ * @param float $base The base of the logarithm. If base is omitted, it is assumed to be 10.
+ * @return float
+ */
+ public static function LOG_BASE($number, $base=10) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+ $base = (is_null($base)) ? 10 : (float) PHPExcel_Calculation_Functions::flattenSingleValue($base);
+
+ return log($number, $base);
+ } // function LOG_BASE()
+
+
+ /**
+ * MDETERM
+ *
+ * @param array $matrixValues A matrix of values
+ * @return float
+ */
+ public static function MDETERM($matrixValues) {
+ $matrixData = array();
+ if (!is_array($matrixValues)) { $matrixValues = array(array($matrixValues)); }
+
+ $row = $maxColumn = 0;
+ foreach($matrixValues as $matrixRow) {
+ $column = 0;
+ foreach($matrixRow as $matrixCell) {
+ if ((is_string($matrixCell)) || ($matrixCell === null)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $matrixData[$column][$row] = $matrixCell;
+ ++$column;
+ }
+ if ($column > $maxColumn) { $maxColumn = $column; }
+ ++$row;
+ }
+ if ($row != $maxColumn) { return PHPExcel_Calculation_Functions::VALUE(); }
+
+ try {
+ $matrix = new PHPExcel_Shared_JAMA_Matrix($matrixData);
+ return $matrix->det();
+ } catch (Exception $ex) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ } // function MDETERM()
+
+
+ /**
+ * MINVERSE
+ *
+ * @param array $matrixValues A matrix of values
+ * @return array
+ */
+ public static function MINVERSE($matrixValues) {
+ $matrixData = array();
+ if (!is_array($matrixValues)) { $matrixValues = array(array($matrixValues)); }
+
+ $row = $maxColumn = 0;
+ foreach($matrixValues as $matrixRow) {
+ $column = 0;
+ foreach($matrixRow as $matrixCell) {
+ if ((is_string($matrixCell)) || ($matrixCell === null)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $matrixData[$column][$row] = $matrixCell;
+ ++$column;
+ }
+ if ($column > $maxColumn) { $maxColumn = $column; }
+ ++$row;
+ }
+ if ($row != $maxColumn) { return PHPExcel_Calculation_Functions::VALUE(); }
+
+ try {
+ $matrix = new PHPExcel_Shared_JAMA_Matrix($matrixData);
+ return $matrix->inverse()->getArray();
+ } catch (Exception $ex) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ } // function MINVERSE()
+
+
+ /**
+ * MMULT
+ *
+ * @param array $matrixData1 A matrix of values
+ * @param array $matrixData2 A matrix of values
+ * @return array
+ */
+ public static function MMULT($matrixData1,$matrixData2) {
+ $matrixAData = $matrixBData = array();
+ if (!is_array($matrixData1)) { $matrixData1 = array(array($matrixData1)); }
+ if (!is_array($matrixData2)) { $matrixData2 = array(array($matrixData2)); }
+
+ $rowA = 0;
+ foreach($matrixData1 as $matrixRow) {
+ $columnA = 0;
+ foreach($matrixRow as $matrixCell) {
+ if ((is_string($matrixCell)) || ($matrixCell === null)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $matrixAData[$rowA][$columnA] = $matrixCell;
+ ++$columnA;
+ }
+ ++$rowA;
+ }
+ try {
+ $matrixA = new PHPExcel_Shared_JAMA_Matrix($matrixAData);
+ $rowB = 0;
+ foreach($matrixData2 as $matrixRow) {
+ $columnB = 0;
+ foreach($matrixRow as $matrixCell) {
+ if ((is_string($matrixCell)) || ($matrixCell === null)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $matrixBData[$rowB][$columnB] = $matrixCell;
+ ++$columnB;
+ }
+ ++$rowB;
+ }
+ $matrixB = new PHPExcel_Shared_JAMA_Matrix($matrixBData);
+
+ if (($rowA != $columnB) || ($rowB != $columnA)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ return $matrixA->times($matrixB)->getArray();
+ } catch (Exception $ex) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ } // function MMULT()
+
+
+ /**
+ * MOD
+ *
+ * @param int $a Dividend
+ * @param int $b Divisor
+ * @return int Remainder
+ */
+ public static function MOD($a = 1, $b = 1) {
+ $a = PHPExcel_Calculation_Functions::flattenSingleValue($a);
+ $b = PHPExcel_Calculation_Functions::flattenSingleValue($b);
+
+ if ($b == 0.0) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ } elseif (($a < 0.0) && ($b > 0.0)) {
+ return $b - fmod(abs($a),$b);
+ } elseif (($a > 0.0) && ($b < 0.0)) {
+ return $b + fmod($a,abs($b));
+ }
+
+ return fmod($a,$b);
+ } // function MOD()
+
+
+ /**
+ * MROUND
+ *
+ * Rounds a number to the nearest multiple of a specified value
+ *
+ * @param float $number Number to round
+ * @param int $multiple Multiple to which you want to round $number
+ * @return float Rounded Number
+ */
+ public static function MROUND($number,$multiple) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+ $multiple = PHPExcel_Calculation_Functions::flattenSingleValue($multiple);
+
+ if ((is_numeric($number)) && (is_numeric($multiple))) {
+ if ($multiple == 0) {
+ return 0;
+ }
+ if ((self::SIGN($number)) == (self::SIGN($multiple))) {
+ $multiplier = 1 / $multiple;
+ return round($number * $multiplier) / $multiplier;
+ }
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function MROUND()
+
+
+ /**
+ * MULTINOMIAL
+ *
+ * Returns the ratio of the factorial of a sum of values to the product of factorials.
+ *
+ * @param array of mixed Data Series
+ * @return float
+ */
+ public static function MULTINOMIAL() {
+ $summer = 0;
+ $divisor = 1;
+ // Loop through arguments
+ foreach (PHPExcel_Calculation_Functions::flattenArray(func_get_args()) as $arg) {
+ // Is it a numeric value?
+ if (is_numeric($arg)) {
+ if ($arg < 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $summer += floor($arg);
+ $divisor *= self::FACT($arg);
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+
+ // Return
+ if ($summer > 0) {
+ $summer = self::FACT($summer);
+ return $summer / $divisor;
+ }
+ return 0;
+ } // function MULTINOMIAL()
+
+
+ /**
+ * ODD
+ *
+ * Returns number rounded up to the nearest odd integer.
+ *
+ * @param float $number Number to round
+ * @return int Rounded Number
+ */
+ public static function ODD($number) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+
+ if (is_null($number)) {
+ return 1;
+ } elseif (is_numeric($number)) {
+ $significance = self::SIGN($number);
+ if ($significance == 0) {
+ return 1;
+ }
+
+ $result = self::CEILING($number,$significance);
+ if ($result == self::EVEN($result)) {
+ $result += $significance;
+ }
+
+ return (int) $result;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function ODD()
+
+
+ /**
+ * POWER
+ *
+ * Computes x raised to the power y.
+ *
+ * @param float $x
+ * @param float $y
+ * @return float
+ */
+ public static function POWER($x = 0, $y = 2) {
+ $x = PHPExcel_Calculation_Functions::flattenSingleValue($x);
+ $y = PHPExcel_Calculation_Functions::flattenSingleValue($y);
+
+ // Validate parameters
+ if ($x == 0 && $y <= 0) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ // Return
+ return pow($x, $y);
+ } // function POWER()
+
+
+ /**
+ * PRODUCT
+ *
+ * PRODUCT returns the product of all the values and cells referenced in the argument list.
+ *
+ * Excel Function:
+ * PRODUCT(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function PRODUCT() {
+ // Return value
+ $returnValue = null;
+
+ // Loop through arguments
+ foreach (PHPExcel_Calculation_Functions::flattenArray(func_get_args()) as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if (is_null($returnValue)) {
+ $returnValue = $arg;
+ } else {
+ $returnValue *= $arg;
+ }
+ }
+ }
+
+ // Return
+ if (is_null($returnValue)) {
+ return 0;
+ }
+ return $returnValue;
+ } // function PRODUCT()
+
+
+ /**
+ * QUOTIENT
+ *
+ * QUOTIENT function returns the integer portion of a division. Numerator is the divided number
+ * and denominator is the divisor.
+ *
+ * Excel Function:
+ * QUOTIENT(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function QUOTIENT() {
+ // Return value
+ $returnValue = null;
+
+ // Loop through arguments
+ foreach (PHPExcel_Calculation_Functions::flattenArray(func_get_args()) as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if (is_null($returnValue)) {
+ $returnValue = ($arg == 0) ? 0 : $arg;
+ } else {
+ if (($returnValue == 0) || ($arg == 0)) {
+ $returnValue = 0;
+ } else {
+ $returnValue /= $arg;
+ }
+ }
+ }
+ }
+
+ // Return
+ return intval($returnValue);
+ } // function QUOTIENT()
+
+
+ /**
+ * RAND
+ *
+ * @param int $min Minimal value
+ * @param int $max Maximal value
+ * @return int Random number
+ */
+ public static function RAND($min = 0, $max = 0) {
+ $min = PHPExcel_Calculation_Functions::flattenSingleValue($min);
+ $max = PHPExcel_Calculation_Functions::flattenSingleValue($max);
+
+ if ($min == 0 && $max == 0) {
+ return (rand(0,10000000)) / 10000000;
+ } else {
+ return rand($min, $max);
+ }
+ } // function RAND()
+
+
+ public static function ROMAN($aValue, $style=0) {
+ $aValue = (integer) PHPExcel_Calculation_Functions::flattenSingleValue($aValue);
+ $style = (is_null($style)) ? 0 : (integer) PHPExcel_Calculation_Functions::flattenSingleValue($style);
+ if ((!is_numeric($aValue)) || ($aValue < 0) || ($aValue >= 4000)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if ($aValue == 0) {
+ return '';
+ }
+
+ $mill = Array('', 'M', 'MM', 'MMM', 'MMMM', 'MMMMM');
+ $cent = Array('', 'C', 'CC', 'CCC', 'CD', 'D', 'DC', 'DCC', 'DCCC', 'CM');
+ $tens = Array('', 'X', 'XX', 'XXX', 'XL', 'L', 'LX', 'LXX', 'LXXX', 'XC');
+ $ones = Array('', 'I', 'II', 'III', 'IV', 'V', 'VI', 'VII', 'VIII', 'IX');
+
+ $roman = '';
+ while ($aValue > 5999) {
+ $roman .= 'M';
+ $aValue -= 1000;
+ }
+ $m = self::_romanCut($aValue, 1000); $aValue %= 1000;
+ $c = self::_romanCut($aValue, 100); $aValue %= 100;
+ $t = self::_romanCut($aValue, 10); $aValue %= 10;
+
+ return $roman.$mill[$m].$cent[$c].$tens[$t].$ones[$aValue];
+ } // function ROMAN()
+
+
+ /**
+ * ROUNDUP
+ *
+ * Rounds a number up to a specified number of decimal places
+ *
+ * @param float $number Number to round
+ * @param int $digits Number of digits to which you want to round $number
+ * @return float Rounded Number
+ */
+ public static function ROUNDUP($number,$digits) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+ $digits = PHPExcel_Calculation_Functions::flattenSingleValue($digits);
+
+ if ((is_numeric($number)) && (is_numeric($digits))) {
+ $significance = pow(10,$digits);
+ if ($number < 0.0) {
+ return floor($number * $significance) / $significance;
+ } else {
+ return ceil($number * $significance) / $significance;
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function ROUNDUP()
+
+
+ /**
+ * ROUNDDOWN
+ *
+ * Rounds a number down to a specified number of decimal places
+ *
+ * @param float $number Number to round
+ * @param int $digits Number of digits to which you want to round $number
+ * @return float Rounded Number
+ */
+ public static function ROUNDDOWN($number,$digits) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+ $digits = PHPExcel_Calculation_Functions::flattenSingleValue($digits);
+
+ if ((is_numeric($number)) && (is_numeric($digits))) {
+ $significance = pow(10,$digits);
+ if ($number < 0.0) {
+ return ceil($number * $significance) / $significance;
+ } else {
+ return floor($number * $significance) / $significance;
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function ROUNDDOWN()
+
+
+ /**
+ * SERIESSUM
+ *
+ * Returns the sum of a power series
+ *
+ * @param float $x Input value to the power series
+ * @param float $n Initial power to which you want to raise $x
+ * @param float $m Step by which to increase $n for each term in the series
+ * @param array of mixed Data Series
+ * @return float
+ */
+ public static function SERIESSUM() {
+ // Return value
+ $returnValue = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ $x = array_shift($aArgs);
+ $n = array_shift($aArgs);
+ $m = array_shift($aArgs);
+
+ if ((is_numeric($x)) && (is_numeric($n)) && (is_numeric($m))) {
+ // Calculate
+ $i = 0;
+ foreach($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $returnValue += $arg * pow($x,$n + ($m * $i++));
+ } else {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ }
+ // Return
+ return $returnValue;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SERIESSUM()
+
+
+ /**
+ * SIGN
+ *
+ * Determines the sign of a number. Returns 1 if the number is positive, zero (0)
+ * if the number is 0, and -1 if the number is negative.
+ *
+ * @param float $number Number to round
+ * @return int sign value
+ */
+ public static function SIGN($number) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+
+ if (is_numeric($number)) {
+ if ($number == 0.0) {
+ return 0;
+ }
+ return $number / abs($number);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SIGN()
+
+
+ /**
+ * SQRTPI
+ *
+ * Returns the square root of (number * pi).
+ *
+ * @param float $number Number
+ * @return float Square Root of Number * Pi
+ */
+ public static function SQRTPI($number) {
+ $number = PHPExcel_Calculation_Functions::flattenSingleValue($number);
+
+ if (is_numeric($number)) {
+ if ($number < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return sqrt($number * M_PI) ;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SQRTPI()
+
+
+ /**
+ * SUBTOTAL
+ *
+ * Returns a subtotal in a list or database.
+ *
+ * @param int the number 1 to 11 that specifies which function to
+ * use in calculating subtotals within a list.
+ * @param array of mixed Data Series
+ * @return float
+ */
+ public static function SUBTOTAL() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ // Calculate
+ $subtotal = array_shift($aArgs);
+
+ if ((is_numeric($subtotal)) && (!is_string($subtotal))) {
+ switch($subtotal) {
+ case 1 :
+ return PHPExcel_Calculation_Statistical::AVERAGE($aArgs);
+ break;
+ case 2 :
+ return PHPExcel_Calculation_Statistical::COUNT($aArgs);
+ break;
+ case 3 :
+ return PHPExcel_Calculation_Statistical::COUNTA($aArgs);
+ break;
+ case 4 :
+ return PHPExcel_Calculation_Statistical::MAX($aArgs);
+ break;
+ case 5 :
+ return PHPExcel_Calculation_Statistical::MIN($aArgs);
+ break;
+ case 6 :
+ return self::PRODUCT($aArgs);
+ break;
+ case 7 :
+ return PHPExcel_Calculation_Statistical::STDEV($aArgs);
+ break;
+ case 8 :
+ return PHPExcel_Calculation_Statistical::STDEVP($aArgs);
+ break;
+ case 9 :
+ return self::SUM($aArgs);
+ break;
+ case 10 :
+ return PHPExcel_Calculation_Statistical::VARFunc($aArgs);
+ break;
+ case 11 :
+ return PHPExcel_Calculation_Statistical::VARP($aArgs);
+ break;
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SUBTOTAL()
+
+
+ /**
+ * SUM
+ *
+ * SUM computes the sum of all the values and cells referenced in the argument list.
+ *
+ * Excel Function:
+ * SUM(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function SUM() {
+ // Return value
+ $returnValue = 0;
+
+ // Loop through the arguments
+ foreach (PHPExcel_Calculation_Functions::flattenArray(func_get_args()) as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $returnValue += $arg;
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function SUM()
+
+
+ /**
+ * SUMIF
+ *
+ * Counts the number of cells that contain numbers within the list of arguments
+ *
+ * Excel Function:
+ * SUMIF(value1[,value2[, ...]],condition)
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @param string $condition The criteria that defines which cells will be summed.
+ * @return float
+ */
+ public static function SUMIF($aArgs,$condition,$sumArgs = array()) {
+ // Return value
+ $returnValue = 0;
+
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray($aArgs);
+ $sumArgs = PHPExcel_Calculation_Functions::flattenArray($sumArgs);
+ if (count($sumArgs) == 0) {
+ $sumArgs = $aArgs;
+ }
+ $condition = PHPExcel_Calculation_Functions::_ifCondition($condition);
+ // Loop through arguments
+ foreach ($aArgs as $key => $arg) {
+ if (!is_numeric($arg)) { $arg = PHPExcel_Calculation::_wrapResult(strtoupper($arg)); }
+ $testCondition = '='.$arg.$condition;
+ if (PHPExcel_Calculation::getInstance()->_calculateFormulaValue($testCondition)) {
+ // Is it a value within our criteria
+ $returnValue += $sumArgs[$key];
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function SUMIF()
+
+
+ /**
+ * SUMPRODUCT
+ *
+ * @param mixed $value Value to check
+ * @return float
+ */
+ public static function SUMPRODUCT() {
+ $arrayList = func_get_args();
+
+ $wrkArray = PHPExcel_Calculation_Functions::flattenArray(array_shift($arrayList));
+ $wrkCellCount = count($wrkArray);
+
+ foreach($arrayList as $matrixData) {
+ $array2 = PHPExcel_Calculation_Functions::flattenArray($matrixData);
+ $count = count($array2);
+ if ($wrkCellCount != $count) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ foreach ($array2 as $i => $val) {
+ if (((is_numeric($wrkArray[$i])) && (!is_string($wrkArray[$i]))) &&
+ ((is_numeric($val)) && (!is_string($val)))) {
+ $wrkArray[$i] *= $val;
+ }
+ }
+ }
+
+ return array_sum($wrkArray);
+ } // function SUMPRODUCT()
+
+
+ /**
+ * SUMSQ
+ *
+ * SUMSQ returns the sum of the squares of the arguments
+ *
+ * Excel Function:
+ * SUMSQ(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function SUMSQ() {
+ // Return value
+ $returnValue = 0;
+
+ // Loop through arguments
+ foreach (PHPExcel_Calculation_Functions::flattenArray(func_get_args()) as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $returnValue += ($arg * $arg);
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function SUMSQ()
+
+
+ /**
+ * SUMX2MY2
+ *
+ * @param mixed $value Value to check
+ * @return float
+ */
+ public static function SUMX2MY2($matrixData1,$matrixData2) {
+ $array1 = PHPExcel_Calculation_Functions::flattenArray($matrixData1);
+ $array2 = PHPExcel_Calculation_Functions::flattenArray($matrixData2);
+ $count1 = count($array1);
+ $count2 = count($array2);
+ if ($count1 < $count2) {
+ $count = $count1;
+ } else {
+ $count = $count2;
+ }
+
+ $result = 0;
+ for ($i = 0; $i < $count; ++$i) {
+ if (((is_numeric($array1[$i])) && (!is_string($array1[$i]))) &&
+ ((is_numeric($array2[$i])) && (!is_string($array2[$i])))) {
+ $result += ($array1[$i] * $array1[$i]) - ($array2[$i] * $array2[$i]);
+ }
+ }
+
+ return $result;
+ } // function SUMX2MY2()
+
+
+ /**
+ * SUMX2PY2
+ *
+ * @param mixed $value Value to check
+ * @return float
+ */
+ public static function SUMX2PY2($matrixData1,$matrixData2) {
+ $array1 = PHPExcel_Calculation_Functions::flattenArray($matrixData1);
+ $array2 = PHPExcel_Calculation_Functions::flattenArray($matrixData2);
+ $count1 = count($array1);
+ $count2 = count($array2);
+ if ($count1 < $count2) {
+ $count = $count1;
+ } else {
+ $count = $count2;
+ }
+
+ $result = 0;
+ for ($i = 0; $i < $count; ++$i) {
+ if (((is_numeric($array1[$i])) && (!is_string($array1[$i]))) &&
+ ((is_numeric($array2[$i])) && (!is_string($array2[$i])))) {
+ $result += ($array1[$i] * $array1[$i]) + ($array2[$i] * $array2[$i]);
+ }
+ }
+
+ return $result;
+ } // function SUMX2PY2()
+
+
+ /**
+ * SUMXMY2
+ *
+ * @param mixed $value Value to check
+ * @return float
+ */
+ public static function SUMXMY2($matrixData1,$matrixData2) {
+ $array1 = PHPExcel_Calculation_Functions::flattenArray($matrixData1);
+ $array2 = PHPExcel_Calculation_Functions::flattenArray($matrixData2);
+ $count1 = count($array1);
+ $count2 = count($array2);
+ if ($count1 < $count2) {
+ $count = $count1;
+ } else {
+ $count = $count2;
+ }
+
+ $result = 0;
+ for ($i = 0; $i < $count; ++$i) {
+ if (((is_numeric($array1[$i])) && (!is_string($array1[$i]))) &&
+ ((is_numeric($array2[$i])) && (!is_string($array2[$i])))) {
+ $result += ($array1[$i] - $array2[$i]) * ($array1[$i] - $array2[$i]);
+ }
+ }
+
+ return $result;
+ } // function SUMXMY2()
+
+
+ /**
+ * TRUNC
+ *
+ * Truncates value to the number of fractional digits by number_digits.
+ *
+ * @param float $value
+ * @param int $number_digits
+ * @return float Truncated value
+ */
+ public static function TRUNC($value = 0, $number_digits = 0) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $number_digits = PHPExcel_Calculation_Functions::flattenSingleValue($number_digits);
+
+ // Validate parameters
+ if ($number_digits < 0) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ // Truncate
+ if ($number_digits > 0) {
+ $value = $value * pow(10, $number_digits);
+ }
+ $value = intval($value);
+ if ($number_digits > 0) {
+ $value = $value / pow(10, $number_digits);
+ }
+
+ // Return
+ return $value;
+ } // function TRUNC()
+
+} // class PHPExcel_Calculation_MathTrig
diff --git a/Classes/PHPExcel/Calculation/Statistical.php b/Classes/PHPExcel/Calculation/Statistical.php
new file mode 100644
index 00000000..a603d321
--- /dev/null
+++ b/Classes/PHPExcel/Calculation/Statistical.php
@@ -0,0 +1,3643 @@
+ $value) {
+ if ((is_bool($value)) || (is_string($value)) || (is_null($value))) {
+ unset($array1[$key]);
+ unset($array2[$key]);
+ }
+ }
+ foreach($array2 as $key => $value) {
+ if ((is_bool($value)) || (is_string($value)) || (is_null($value))) {
+ unset($array1[$key]);
+ unset($array2[$key]);
+ }
+ }
+ $array1 = array_merge($array1);
+ $array2 = array_merge($array2);
+
+ return True;
+ } // function _checkTrendArrays()
+
+
+ /**
+ * Beta function.
+ *
+ * @author Jaco van Kooten
+ *
+ * @param p require p>0
+ * @param q require q>0
+ * @return 0 if p<=0, q<=0 or p+q>2.55E305 to avoid errors and over/underflow
+ */
+ private static function _beta($p, $q) {
+ if ($p <= 0.0 || $q <= 0.0 || ($p + $q) > LOG_GAMMA_X_MAX_VALUE) {
+ return 0.0;
+ } else {
+ return exp(self::_logBeta($p, $q));
+ }
+ } // function _beta()
+
+
+ /**
+ * Incomplete beta function
+ *
+ * @author Jaco van Kooten
+ * @author Paul Meagher
+ *
+ * The computation is based on formulas from Numerical Recipes, Chapter 6.4 (W.H. Press et al, 1992).
+ * @param x require 0<=x<=1
+ * @param p require p>0
+ * @param q require q>0
+ * @return 0 if x<0, p<=0, q<=0 or p+q>2.55E305 and 1 if x>1 to avoid errors and over/underflow
+ */
+ private static function _incompleteBeta($x, $p, $q) {
+ if ($x <= 0.0) {
+ return 0.0;
+ } elseif ($x >= 1.0) {
+ return 1.0;
+ } elseif (($p <= 0.0) || ($q <= 0.0) || (($p + $q) > LOG_GAMMA_X_MAX_VALUE)) {
+ return 0.0;
+ }
+ $beta_gam = exp((0 - self::_logBeta($p, $q)) + $p * log($x) + $q * log(1.0 - $x));
+ if ($x < ($p + 1.0) / ($p + $q + 2.0)) {
+ return $beta_gam * self::_betaFraction($x, $p, $q) / $p;
+ } else {
+ return 1.0 - ($beta_gam * self::_betaFraction(1 - $x, $q, $p) / $q);
+ }
+ } // function _incompleteBeta()
+
+
+ // Function cache for _logBeta function
+ private static $_logBetaCache_p = 0.0;
+ private static $_logBetaCache_q = 0.0;
+ private static $_logBetaCache_result = 0.0;
+
+ /**
+ * The natural logarithm of the beta function.
+ * @param p require p>0
+ * @param q require q>0
+ * @return 0 if p<=0, q<=0 or p+q>2.55E305 to avoid errors and over/underflow
+ * @author Jaco van Kooten
+ */
+ private static function _logBeta($p, $q) {
+ if ($p != self::$_logBetaCache_p || $q != self::$_logBetaCache_q) {
+ self::$_logBetaCache_p = $p;
+ self::$_logBetaCache_q = $q;
+ if (($p <= 0.0) || ($q <= 0.0) || (($p + $q) > LOG_GAMMA_X_MAX_VALUE)) {
+ self::$_logBetaCache_result = 0.0;
+ } else {
+ self::$_logBetaCache_result = self::_logGamma($p) + self::_logGamma($q) - self::_logGamma($p + $q);
+ }
+ }
+ return self::$_logBetaCache_result;
+ } // function _logBeta()
+
+
+ /**
+ * Evaluates of continued fraction part of incomplete beta function.
+ * Based on an idea from Numerical Recipes (W.H. Press et al, 1992).
+ * @author Jaco van Kooten
+ */
+ private static function _betaFraction($x, $p, $q) {
+ $c = 1.0;
+ $sum_pq = $p + $q;
+ $p_plus = $p + 1.0;
+ $p_minus = $p - 1.0;
+ $h = 1.0 - $sum_pq * $x / $p_plus;
+ if (abs($h) < XMININ) {
+ $h = XMININ;
+ }
+ $h = 1.0 / $h;
+ $frac = $h;
+ $m = 1;
+ $delta = 0.0;
+ while ($m <= MAX_ITERATIONS && abs($delta-1.0) > PRECISION ) {
+ $m2 = 2 * $m;
+ // even index for d
+ $d = $m * ($q - $m) * $x / ( ($p_minus + $m2) * ($p + $m2));
+ $h = 1.0 + $d * $h;
+ if (abs($h) < XMININ) {
+ $h = XMININ;
+ }
+ $h = 1.0 / $h;
+ $c = 1.0 + $d / $c;
+ if (abs($c) < XMININ) {
+ $c = XMININ;
+ }
+ $frac *= $h * $c;
+ // odd index for d
+ $d = -($p + $m) * ($sum_pq + $m) * $x / (($p + $m2) * ($p_plus + $m2));
+ $h = 1.0 + $d * $h;
+ if (abs($h) < XMININ) {
+ $h = XMININ;
+ }
+ $h = 1.0 / $h;
+ $c = 1.0 + $d / $c;
+ if (abs($c) < XMININ) {
+ $c = XMININ;
+ }
+ $delta = $h * $c;
+ $frac *= $delta;
+ ++$m;
+ }
+ return $frac;
+ } // function _betaFraction()
+
+
+ /**
+ * logGamma function
+ *
+ * @version 1.1
+ * @author Jaco van Kooten
+ *
+ * Original author was Jaco van Kooten. Ported to PHP by Paul Meagher.
+ *
+ * The natural logarithm of the gamma function.
+ * Based on public domain NETLIB (Fortran) code by W. J. Cody and L. Stoltz
+ * Applied Mathematics Division
+ * Argonne National Laboratory
+ * Argonne, IL 60439
+ *
+ * References:
+ *
+ * - W. J. Cody and K. E. Hillstrom, 'Chebyshev Approximations for the Natural
+ * Logarithm of the Gamma Function,' Math. Comp. 21, 1967, pp. 198-203.
+ * - K. E. Hillstrom, ANL/AMD Program ANLC366S, DGAMMA/DLGAMA, May, 1969.
+ * - Hart, Et. Al., Computer Approximations, Wiley and sons, New York, 1968.
+ *
+ *
+ *
+ * From the original documentation:
+ *
+ *
+ * This routine calculates the LOG(GAMMA) function for a positive real argument X.
+ * Computation is based on an algorithm outlined in references 1 and 2.
+ * The program uses rational functions that theoretically approximate LOG(GAMMA)
+ * to at least 18 significant decimal digits. The approximation for X > 12 is from
+ * reference 3, while approximations for X < 12.0 are similar to those in reference
+ * 1, but are unpublished. The accuracy achieved depends on the arithmetic system,
+ * the compiler, the intrinsic functions, and proper selection of the
+ * machine-dependent constants.
+ *
+ *
+ * Error returns:
+ * The program returns the value XINF for X .LE. 0.0 or when overflow would occur.
+ * The computation is believed to be free of underflow and overflow.
+ *
+ * @return MAX_VALUE for x < 0.0 or when overflow would occur, i.e. x > 2.55E305
+ */
+
+ // Function cache for logGamma
+ private static $_logGammaCache_result = 0.0;
+ private static $_logGammaCache_x = 0.0;
+
+ private static function _logGamma($x) {
+ // Log Gamma related constants
+ static $lg_d1 = -0.5772156649015328605195174;
+ static $lg_d2 = 0.4227843350984671393993777;
+ static $lg_d4 = 1.791759469228055000094023;
+
+ static $lg_p1 = array( 4.945235359296727046734888,
+ 201.8112620856775083915565,
+ 2290.838373831346393026739,
+ 11319.67205903380828685045,
+ 28557.24635671635335736389,
+ 38484.96228443793359990269,
+ 26377.48787624195437963534,
+ 7225.813979700288197698961 );
+ static $lg_p2 = array( 4.974607845568932035012064,
+ 542.4138599891070494101986,
+ 15506.93864978364947665077,
+ 184793.2904445632425417223,
+ 1088204.76946882876749847,
+ 3338152.967987029735917223,
+ 5106661.678927352456275255,
+ 3074109.054850539556250927 );
+ static $lg_p4 = array( 14745.02166059939948905062,
+ 2426813.369486704502836312,
+ 121475557.4045093227939592,
+ 2663432449.630976949898078,
+ 29403789566.34553899906876,
+ 170266573776.5398868392998,
+ 492612579337.743088758812,
+ 560625185622.3951465078242 );
+
+ static $lg_q1 = array( 67.48212550303777196073036,
+ 1113.332393857199323513008,
+ 7738.757056935398733233834,
+ 27639.87074403340708898585,
+ 54993.10206226157329794414,
+ 61611.22180066002127833352,
+ 36351.27591501940507276287,
+ 8785.536302431013170870835 );
+ static $lg_q2 = array( 183.0328399370592604055942,
+ 7765.049321445005871323047,
+ 133190.3827966074194402448,
+ 1136705.821321969608938755,
+ 5267964.117437946917577538,
+ 13467014.54311101692290052,
+ 17827365.30353274213975932,
+ 9533095.591844353613395747 );
+ static $lg_q4 = array( 2690.530175870899333379843,
+ 639388.5654300092398984238,
+ 41355999.30241388052042842,
+ 1120872109.61614794137657,
+ 14886137286.78813811542398,
+ 101680358627.2438228077304,
+ 341747634550.7377132798597,
+ 446315818741.9713286462081 );
+
+ static $lg_c = array( -0.001910444077728,
+ 8.4171387781295e-4,
+ -5.952379913043012e-4,
+ 7.93650793500350248e-4,
+ -0.002777777777777681622553,
+ 0.08333333333333333331554247,
+ 0.0057083835261 );
+
+ // Rough estimate of the fourth root of logGamma_xBig
+ static $lg_frtbig = 2.25e76;
+ static $pnt68 = 0.6796875;
+
+
+ if ($x == self::$_logGammaCache_x) {
+ return self::$_logGammaCache_result;
+ }
+ $y = $x;
+ if ($y > 0.0 && $y <= LOG_GAMMA_X_MAX_VALUE) {
+ if ($y <= EPS) {
+ $res = -log(y);
+ } elseif ($y <= 1.5) {
+ // ---------------------
+ // EPS .LT. X .LE. 1.5
+ // ---------------------
+ if ($y < $pnt68) {
+ $corr = -log($y);
+ $xm1 = $y;
+ } else {
+ $corr = 0.0;
+ $xm1 = $y - 1.0;
+ }
+ if ($y <= 0.5 || $y >= $pnt68) {
+ $xden = 1.0;
+ $xnum = 0.0;
+ for ($i = 0; $i < 8; ++$i) {
+ $xnum = $xnum * $xm1 + $lg_p1[$i];
+ $xden = $xden * $xm1 + $lg_q1[$i];
+ }
+ $res = $corr + $xm1 * ($lg_d1 + $xm1 * ($xnum / $xden));
+ } else {
+ $xm2 = $y - 1.0;
+ $xden = 1.0;
+ $xnum = 0.0;
+ for ($i = 0; $i < 8; ++$i) {
+ $xnum = $xnum * $xm2 + $lg_p2[$i];
+ $xden = $xden * $xm2 + $lg_q2[$i];
+ }
+ $res = $corr + $xm2 * ($lg_d2 + $xm2 * ($xnum / $xden));
+ }
+ } elseif ($y <= 4.0) {
+ // ---------------------
+ // 1.5 .LT. X .LE. 4.0
+ // ---------------------
+ $xm2 = $y - 2.0;
+ $xden = 1.0;
+ $xnum = 0.0;
+ for ($i = 0; $i < 8; ++$i) {
+ $xnum = $xnum * $xm2 + $lg_p2[$i];
+ $xden = $xden * $xm2 + $lg_q2[$i];
+ }
+ $res = $xm2 * ($lg_d2 + $xm2 * ($xnum / $xden));
+ } elseif ($y <= 12.0) {
+ // ----------------------
+ // 4.0 .LT. X .LE. 12.0
+ // ----------------------
+ $xm4 = $y - 4.0;
+ $xden = -1.0;
+ $xnum = 0.0;
+ for ($i = 0; $i < 8; ++$i) {
+ $xnum = $xnum * $xm4 + $lg_p4[$i];
+ $xden = $xden * $xm4 + $lg_q4[$i];
+ }
+ $res = $lg_d4 + $xm4 * ($xnum / $xden);
+ } else {
+ // ---------------------------------
+ // Evaluate for argument .GE. 12.0
+ // ---------------------------------
+ $res = 0.0;
+ if ($y <= $lg_frtbig) {
+ $res = $lg_c[6];
+ $ysq = $y * $y;
+ for ($i = 0; $i < 6; ++$i)
+ $res = $res / $ysq + $lg_c[$i];
+ }
+ $res /= $y;
+ $corr = log($y);
+ $res = $res + log(SQRT2PI) - 0.5 * $corr;
+ $res += $y * ($corr - 1.0);
+ }
+ } else {
+ // --------------------------
+ // Return for bad arguments
+ // --------------------------
+ $res = MAX_VALUE;
+ }
+ // ------------------------------
+ // Final adjustments and return
+ // ------------------------------
+ self::$_logGammaCache_x = $x;
+ self::$_logGammaCache_result = $res;
+ return $res;
+ } // function _logGamma()
+
+
+ //
+ // Private implementation of the incomplete Gamma function
+ //
+ private static function _incompleteGamma($a,$x) {
+ static $max = 32;
+ $summer = 0;
+ for ($n=0; $n<=$max; ++$n) {
+ $divisor = $a;
+ for ($i=1; $i<=$n; ++$i) {
+ $divisor *= ($a + $i);
+ }
+ $summer += (pow($x,$n) / $divisor);
+ }
+ return pow($x,$a) * exp(0-$x) * $summer;
+ } // function _incompleteGamma()
+
+
+ //
+ // Private implementation of the Gamma function
+ //
+ private static function _gamma($data) {
+ if ($data == 0.0) return 0;
+
+ static $p0 = 1.000000000190015;
+ static $p = array ( 1 => 76.18009172947146,
+ 2 => -86.50532032941677,
+ 3 => 24.01409824083091,
+ 4 => -1.231739572450155,
+ 5 => 1.208650973866179e-3,
+ 6 => -5.395239384953e-6
+ );
+
+ $y = $x = $data;
+ $tmp = $x + 5.5;
+ $tmp -= ($x + 0.5) * log($tmp);
+
+ $summer = $p0;
+ for ($j=1;$j<=6;++$j) {
+ $summer += ($p[$j] / ++$y);
+ }
+ return exp(0 - $tmp + log(SQRT2PI * $summer / $x));
+ } // function _gamma()
+
+
+ /***************************************************************************
+ * inverse_ncdf.php
+ * -------------------
+ * begin : Friday, January 16, 2004
+ * copyright : (C) 2004 Michael Nickerson
+ * email : nickersonm@yahoo.com
+ *
+ ***************************************************************************/
+ private static function _inverse_ncdf($p) {
+ // Inverse ncdf approximation by Peter J. Acklam, implementation adapted to
+ // PHP by Michael Nickerson, using Dr. Thomas Ziegler's C implementation as
+ // a guide. http://home.online.no/~pjacklam/notes/invnorm/index.html
+ // I have not checked the accuracy of this implementation. Be aware that PHP
+ // will truncate the coeficcients to 14 digits.
+
+ // You have permission to use and distribute this function freely for
+ // whatever purpose you want, but please show common courtesy and give credit
+ // where credit is due.
+
+ // Input paramater is $p - probability - where 0 < p < 1.
+
+ // Coefficients in rational approximations
+ static $a = array( 1 => -3.969683028665376e+01,
+ 2 => 2.209460984245205e+02,
+ 3 => -2.759285104469687e+02,
+ 4 => 1.383577518672690e+02,
+ 5 => -3.066479806614716e+01,
+ 6 => 2.506628277459239e+00
+ );
+
+ static $b = array( 1 => -5.447609879822406e+01,
+ 2 => 1.615858368580409e+02,
+ 3 => -1.556989798598866e+02,
+ 4 => 6.680131188771972e+01,
+ 5 => -1.328068155288572e+01
+ );
+
+ static $c = array( 1 => -7.784894002430293e-03,
+ 2 => -3.223964580411365e-01,
+ 3 => -2.400758277161838e+00,
+ 4 => -2.549732539343734e+00,
+ 5 => 4.374664141464968e+00,
+ 6 => 2.938163982698783e+00
+ );
+
+ static $d = array( 1 => 7.784695709041462e-03,
+ 2 => 3.224671290700398e-01,
+ 3 => 2.445134137142996e+00,
+ 4 => 3.754408661907416e+00
+ );
+
+ // Define lower and upper region break-points.
+ $p_low = 0.02425; //Use lower region approx. below this
+ $p_high = 1 - $p_low; //Use upper region approx. above this
+
+ if (0 < $p && $p < $p_low) {
+ // Rational approximation for lower region.
+ $q = sqrt(-2 * log($p));
+ return ((((($c[1] * $q + $c[2]) * $q + $c[3]) * $q + $c[4]) * $q + $c[5]) * $q + $c[6]) /
+ (((($d[1] * $q + $d[2]) * $q + $d[3]) * $q + $d[4]) * $q + 1);
+ } elseif ($p_low <= $p && $p <= $p_high) {
+ // Rational approximation for central region.
+ $q = $p - 0.5;
+ $r = $q * $q;
+ return ((((($a[1] * $r + $a[2]) * $r + $a[3]) * $r + $a[4]) * $r + $a[5]) * $r + $a[6]) * $q /
+ ((((($b[1] * $r + $b[2]) * $r + $b[3]) * $r + $b[4]) * $r + $b[5]) * $r + 1);
+ } elseif ($p_high < $p && $p < 1) {
+ // Rational approximation for upper region.
+ $q = sqrt(-2 * log(1 - $p));
+ return -((((($c[1] * $q + $c[2]) * $q + $c[3]) * $q + $c[4]) * $q + $c[5]) * $q + $c[6]) /
+ (((($d[1] * $q + $d[2]) * $q + $d[3]) * $q + $d[4]) * $q + 1);
+ }
+ // If 0 < p < 1, return a null value
+ return PHPExcel_Calculation_Functions::NULL();
+ } // function _inverse_ncdf()
+
+
+ private static function _inverse_ncdf2($prob) {
+ // Approximation of inverse standard normal CDF developed by
+ // B. Moro, "The Full Monte," Risk 8(2), Feb 1995, 57-58.
+
+ $a1 = 2.50662823884;
+ $a2 = -18.61500062529;
+ $a3 = 41.39119773534;
+ $a4 = -25.44106049637;
+
+ $b1 = -8.4735109309;
+ $b2 = 23.08336743743;
+ $b3 = -21.06224101826;
+ $b4 = 3.13082909833;
+
+ $c1 = 0.337475482272615;
+ $c2 = 0.976169019091719;
+ $c3 = 0.160797971491821;
+ $c4 = 2.76438810333863E-02;
+ $c5 = 3.8405729373609E-03;
+ $c6 = 3.951896511919E-04;
+ $c7 = 3.21767881768E-05;
+ $c8 = 2.888167364E-07;
+ $c9 = 3.960315187E-07;
+
+ $y = $prob - 0.5;
+ if (abs($y) < 0.42) {
+ $z = ($y * $y);
+ $z = $y * ((($a4 * $z + $a3) * $z + $a2) * $z + $a1) / (((($b4 * $z + $b3) * $z + $b2) * $z + $b1) * $z + 1);
+ } else {
+ if ($y > 0) {
+ $z = log(-log(1 - $prob));
+ } else {
+ $z = log(-log($prob));
+ }
+ $z = $c1 + $z * ($c2 + $z * ($c3 + $z * ($c4 + $z * ($c5 + $z * ($c6 + $z * ($c7 + $z * ($c8 + $z * $c9)))))));
+ if ($y < 0) {
+ $z = -$z;
+ }
+ }
+ return $z;
+ } // function _inverse_ncdf2()
+
+
+ private static function _inverse_ncdf3($p) {
+ // ALGORITHM AS241 APPL. STATIST. (1988) VOL. 37, NO. 3.
+ // Produces the normal deviate Z corresponding to a given lower
+ // tail area of P; Z is accurate to about 1 part in 10**16.
+ //
+ // This is a PHP version of the original FORTRAN code that can
+ // be found at http://lib.stat.cmu.edu/apstat/
+ $split1 = 0.425;
+ $split2 = 5;
+ $const1 = 0.180625;
+ $const2 = 1.6;
+
+ // coefficients for p close to 0.5
+ $a0 = 3.3871328727963666080;
+ $a1 = 1.3314166789178437745E+2;
+ $a2 = 1.9715909503065514427E+3;
+ $a3 = 1.3731693765509461125E+4;
+ $a4 = 4.5921953931549871457E+4;
+ $a5 = 6.7265770927008700853E+4;
+ $a6 = 3.3430575583588128105E+4;
+ $a7 = 2.5090809287301226727E+3;
+
+ $b1 = 4.2313330701600911252E+1;
+ $b2 = 6.8718700749205790830E+2;
+ $b3 = 5.3941960214247511077E+3;
+ $b4 = 2.1213794301586595867E+4;
+ $b5 = 3.9307895800092710610E+4;
+ $b6 = 2.8729085735721942674E+4;
+ $b7 = 5.2264952788528545610E+3;
+
+ // coefficients for p not close to 0, 0.5 or 1.
+ $c0 = 1.42343711074968357734;
+ $c1 = 4.63033784615654529590;
+ $c2 = 5.76949722146069140550;
+ $c3 = 3.64784832476320460504;
+ $c4 = 1.27045825245236838258;
+ $c5 = 2.41780725177450611770E-1;
+ $c6 = 2.27238449892691845833E-2;
+ $c7 = 7.74545014278341407640E-4;
+
+ $d1 = 2.05319162663775882187;
+ $d2 = 1.67638483018380384940;
+ $d3 = 6.89767334985100004550E-1;
+ $d4 = 1.48103976427480074590E-1;
+ $d5 = 1.51986665636164571966E-2;
+ $d6 = 5.47593808499534494600E-4;
+ $d7 = 1.05075007164441684324E-9;
+
+ // coefficients for p near 0 or 1.
+ $e0 = 6.65790464350110377720;
+ $e1 = 5.46378491116411436990;
+ $e2 = 1.78482653991729133580;
+ $e3 = 2.96560571828504891230E-1;
+ $e4 = 2.65321895265761230930E-2;
+ $e5 = 1.24266094738807843860E-3;
+ $e6 = 2.71155556874348757815E-5;
+ $e7 = 2.01033439929228813265E-7;
+
+ $f1 = 5.99832206555887937690E-1;
+ $f2 = 1.36929880922735805310E-1;
+ $f3 = 1.48753612908506148525E-2;
+ $f4 = 7.86869131145613259100E-4;
+ $f5 = 1.84631831751005468180E-5;
+ $f6 = 1.42151175831644588870E-7;
+ $f7 = 2.04426310338993978564E-15;
+
+ $q = $p - 0.5;
+
+ // computation for p close to 0.5
+ if (abs($q) <= split1) {
+ $R = $const1 - $q * $q;
+ $z = $q * ((((((($a7 * $R + $a6) * $R + $a5) * $R + $a4) * $R + $a3) * $R + $a2) * $R + $a1) * $R + $a0) /
+ ((((((($b7 * $R + $b6) * $R + $b5) * $R + $b4) * $R + $b3) * $R + $b2) * $R + $b1) * $R + 1);
+ } else {
+ if ($q < 0) {
+ $R = $p;
+ } else {
+ $R = 1 - $p;
+ }
+ $R = pow(-log($R),2);
+
+ // computation for p not close to 0, 0.5 or 1.
+ If ($R <= $split2) {
+ $R = $R - $const2;
+ $z = ((((((($c7 * $R + $c6) * $R + $c5) * $R + $c4) * $R + $c3) * $R + $c2) * $R + $c1) * $R + $c0) /
+ ((((((($d7 * $R + $d6) * $R + $d5) * $R + $d4) * $R + $d3) * $R + $d2) * $R + $d1) * $R + 1);
+ } else {
+ // computation for p near 0 or 1.
+ $R = $R - $split2;
+ $z = ((((((($e7 * $R + $e6) * $R + $e5) * $R + $e4) * $R + $e3) * $R + $e2) * $R + $e1) * $R + $e0) /
+ ((((((($f7 * $R + $f6) * $R + $f5) * $R + $f4) * $R + $f3) * $R + $f2) * $R + $f1) * $R + 1);
+ }
+ if ($q < 0) {
+ $z = -$z;
+ }
+ }
+ return $z;
+ } // function _inverse_ncdf3()
+
+
+ /**
+ * AVEDEV
+ *
+ * Returns the average of the absolute deviations of data points from their mean.
+ * AVEDEV is a measure of the variability in a data set.
+ *
+ * Excel Function:
+ * AVEDEV(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function AVEDEV() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+
+ // Return value
+ $returnValue = null;
+
+ $aMean = self::AVERAGE($aArgs);
+ if ($aMean != PHPExcel_Calculation_Functions::DIV0()) {
+ $aCount = 0;
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ ((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {
+ $arg = (integer) $arg;
+ }
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if (is_null($returnValue)) {
+ $returnValue = abs($arg - $aMean);
+ } else {
+ $returnValue += abs($arg - $aMean);
+ }
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if ($aCount == 0) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+ return $returnValue / $aCount;
+ }
+ return PHPExcel_Calculation_Functions::NaN();
+ } // function AVEDEV()
+
+
+ /**
+ * AVERAGE
+ *
+ * Returns the average (arithmetic mean) of the arguments
+ *
+ * Excel Function:
+ * AVERAGE(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function AVERAGE() {
+ $returnValue = $aCount = 0;
+
+ // Loop through arguments
+ foreach (PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args()) as $k => $arg) {
+ if ((is_bool($arg)) &&
+ ((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {
+ $arg = (integer) $arg;
+ }
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if (is_null($returnValue)) {
+ $returnValue = $arg;
+ } else {
+ $returnValue += $arg;
+ }
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if ($aCount > 0) {
+ return $returnValue / $aCount;
+ } else {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+ } // function AVERAGE()
+
+
+ /**
+ * AVERAGEA
+ *
+ * Returns the average of its arguments, including numbers, text, and logical values
+ *
+ * Excel Function:
+ * AVERAGEA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function AVERAGEA() {
+ // Return value
+ $returnValue = null;
+
+ $aCount = 0;
+ // Loop through arguments
+ foreach (PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args()) as $k => $arg) {
+ if ((is_bool($arg)) &&
+ (!PHPExcel_Calculation_Functions::isMatrixValue($k))) {
+ } else {
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) && ($arg != '')))) {
+ if (is_bool($arg)) {
+ $arg = (integer) $arg;
+ } elseif (is_string($arg)) {
+ $arg = 0;
+ }
+ if (is_null($returnValue)) {
+ $returnValue = $arg;
+ } else {
+ $returnValue += $arg;
+ }
+ ++$aCount;
+ }
+ }
+ }
+
+ // Return
+ if ($aCount > 0) {
+ return $returnValue / $aCount;
+ } else {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+ } // function AVERAGEA()
+
+
+ /**
+ * AVERAGEIF
+ *
+ * Returns the average value from a range of cells that contain numbers within the list of arguments
+ *
+ * Excel Function:
+ * AVERAGEIF(value1[,value2[, ...]],condition)
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @param string $condition The criteria that defines which cells will be checked.
+ * @return float
+ */
+ public static function AVERAGEIF($aArgs,$condition,$averageArgs = array()) {
+ // Return value
+ $returnValue = 0;
+
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray($aArgs);
+ $averageArgs = PHPExcel_Calculation_Functions::flattenArray($averageArgs);
+ if (count($averageArgs) == 0) {
+ $averageArgs = $aArgs;
+ }
+ $condition = PHPExcel_Calculation_Functions::_ifCondition($condition);
+ // Loop through arguments
+ $aCount = 0;
+ foreach ($aArgs as $key => $arg) {
+ if (!is_numeric($arg)) { $arg = PHPExcel_Calculation::_wrapResult(strtoupper($arg)); }
+ $testCondition = '='.$arg.$condition;
+ if (PHPExcel_Calculation::getInstance()->_calculateFormulaValue($testCondition)) {
+ if ((is_null($returnValue)) || ($arg > $returnValue)) {
+ $returnValue += $arg;
+ ++$aCount;
+ }
+ }
+ }
+
+ // Return
+ if ($aCount > 0) {
+ return $returnValue / $aCount;
+ } else {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+ } // function AVERAGEIF()
+
+
+ /**
+ * BETADIST
+ *
+ * Returns the beta distribution.
+ *
+ * @param float $value Value at which you want to evaluate the distribution
+ * @param float $alpha Parameter to the distribution
+ * @param float $beta Parameter to the distribution
+ * @param boolean $cumulative
+ * @return float
+ *
+ */
+ public static function BETADIST($value,$alpha,$beta,$rMin=0,$rMax=1) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $alpha = PHPExcel_Calculation_Functions::flattenSingleValue($alpha);
+ $beta = PHPExcel_Calculation_Functions::flattenSingleValue($beta);
+ $rMin = PHPExcel_Calculation_Functions::flattenSingleValue($rMin);
+ $rMax = PHPExcel_Calculation_Functions::flattenSingleValue($rMax);
+
+ if ((is_numeric($value)) && (is_numeric($alpha)) && (is_numeric($beta)) && (is_numeric($rMin)) && (is_numeric($rMax))) {
+ if (($value < $rMin) || ($value > $rMax) || ($alpha <= 0) || ($beta <= 0) || ($rMin == $rMax)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($rMin > $rMax) {
+ $tmp = $rMin;
+ $rMin = $rMax;
+ $rMax = $tmp;
+ }
+ $value -= $rMin;
+ $value /= ($rMax - $rMin);
+ return self::_incompleteBeta($value,$alpha,$beta);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function BETADIST()
+
+
+ /**
+ * BETAINV
+ *
+ * Returns the inverse of the beta distribution.
+ *
+ * @param float $probability Probability at which you want to evaluate the distribution
+ * @param float $alpha Parameter to the distribution
+ * @param float $beta Parameter to the distribution
+ * @param boolean $cumulative
+ * @return float
+ *
+ */
+ public static function BETAINV($probability,$alpha,$beta,$rMin=0,$rMax=1) {
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+ $alpha = PHPExcel_Calculation_Functions::flattenSingleValue($alpha);
+ $beta = PHPExcel_Calculation_Functions::flattenSingleValue($beta);
+ $rMin = PHPExcel_Calculation_Functions::flattenSingleValue($rMin);
+ $rMax = PHPExcel_Calculation_Functions::flattenSingleValue($rMax);
+
+ if ((is_numeric($probability)) && (is_numeric($alpha)) && (is_numeric($beta)) && (is_numeric($rMin)) && (is_numeric($rMax))) {
+ if (($alpha <= 0) || ($beta <= 0) || ($rMin == $rMax) || ($probability <= 0) || ($probability > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($rMin > $rMax) {
+ $tmp = $rMin;
+ $rMin = $rMax;
+ $rMax = $tmp;
+ }
+ $a = 0;
+ $b = 2;
+
+ $i = 0;
+ while ((($b - $a) > PRECISION) && ($i++ < MAX_ITERATIONS)) {
+ $guess = ($a + $b) / 2;
+ $result = self::BETADIST($guess, $alpha, $beta);
+ if (($result == $probability) || ($result == 0)) {
+ $b = $a;
+ } elseif ($result > $probability) {
+ $b = $guess;
+ } else {
+ $a = $guess;
+ }
+ }
+ if ($i == MAX_ITERATIONS) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ return round($rMin + $guess * ($rMax - $rMin),12);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function BETAINV()
+
+
+ /**
+ * BINOMDIST
+ *
+ * Returns the individual term binomial distribution probability. Use BINOMDIST in problems with
+ * a fixed number of tests or trials, when the outcomes of any trial are only success or failure,
+ * when trials are independent, and when the probability of success is constant throughout the
+ * experiment. For example, BINOMDIST can calculate the probability that two of the next three
+ * babies born are male.
+ *
+ * @param float $value Number of successes in trials
+ * @param float $trials Number of trials
+ * @param float $probability Probability of success on each trial
+ * @param boolean $cumulative
+ * @return float
+ *
+ * @todo Cumulative distribution function
+ *
+ */
+ public static function BINOMDIST($value, $trials, $probability, $cumulative) {
+ $value = floor(PHPExcel_Calculation_Functions::flattenSingleValue($value));
+ $trials = floor(PHPExcel_Calculation_Functions::flattenSingleValue($trials));
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+
+ if ((is_numeric($value)) && (is_numeric($trials)) && (is_numeric($probability))) {
+ if (($value < 0) || ($value > $trials)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($probability < 0) || ($probability > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ((is_numeric($cumulative)) || (is_bool($cumulative))) {
+ if ($cumulative) {
+ $summer = 0;
+ for ($i = 0; $i <= $value; ++$i) {
+ $summer += PHPExcel_Calculation_MathTrig::COMBIN($trials,$i) * pow($probability,$i) * pow(1 - $probability,$trials - $i);
+ }
+ return $summer;
+ } else {
+ return PHPExcel_Calculation_MathTrig::COMBIN($trials,$value) * pow($probability,$value) * pow(1 - $probability,$trials - $value) ;
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function BINOMDIST()
+
+
+ /**
+ * CHIDIST
+ *
+ * Returns the one-tailed probability of the chi-squared distribution.
+ *
+ * @param float $value Value for the function
+ * @param float $degrees degrees of freedom
+ * @return float
+ */
+ public static function CHIDIST($value, $degrees) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $degrees = floor(PHPExcel_Calculation_Functions::flattenSingleValue($degrees));
+
+ if ((is_numeric($value)) && (is_numeric($degrees))) {
+ if ($degrees < 1) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($value < 0) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ return 1;
+ }
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return 1 - (self::_incompleteGamma($degrees/2,$value/2) / self::_gamma($degrees/2));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function CHIDIST()
+
+
+ /**
+ * CHIINV
+ *
+ * Returns the one-tailed probability of the chi-squared distribution.
+ *
+ * @param float $probability Probability for the function
+ * @param float $degrees degrees of freedom
+ * @return float
+ */
+ public static function CHIINV($probability, $degrees) {
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+ $degrees = floor(PHPExcel_Calculation_Functions::flattenSingleValue($degrees));
+
+ if ((is_numeric($probability)) && (is_numeric($degrees))) {
+
+ $xLo = 100;
+ $xHi = 0;
+
+ $x = $xNew = 1;
+ $dx = 1;
+ $i = 0;
+
+ while ((abs($dx) > PRECISION) && ($i++ < MAX_ITERATIONS)) {
+ // Apply Newton-Raphson step
+ $result = self::CHIDIST($x, $degrees);
+ $error = $result - $probability;
+ if ($error == 0.0) {
+ $dx = 0;
+ } elseif ($error < 0.0) {
+ $xLo = $x;
+ } else {
+ $xHi = $x;
+ }
+ // Avoid division by zero
+ if ($result != 0.0) {
+ $dx = $error / $result;
+ $xNew = $x - $dx;
+ }
+ // If the NR fails to converge (which for example may be the
+ // case if the initial guess is too rough) we apply a bisection
+ // step to determine a more narrow interval around the root.
+ if (($xNew < $xLo) || ($xNew > $xHi) || ($result == 0.0)) {
+ $xNew = ($xLo + $xHi) / 2;
+ $dx = $xNew - $x;
+ }
+ $x = $xNew;
+ }
+ if ($i == MAX_ITERATIONS) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ return round($x,12);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function CHIINV()
+
+
+ /**
+ * CONFIDENCE
+ *
+ * Returns the confidence interval for a population mean
+ *
+ * @param float $alpha
+ * @param float $stdDev Standard Deviation
+ * @param float $size
+ * @return float
+ *
+ */
+ public static function CONFIDENCE($alpha,$stdDev,$size) {
+ $alpha = PHPExcel_Calculation_Functions::flattenSingleValue($alpha);
+ $stdDev = PHPExcel_Calculation_Functions::flattenSingleValue($stdDev);
+ $size = floor(PHPExcel_Calculation_Functions::flattenSingleValue($size));
+
+ if ((is_numeric($alpha)) && (is_numeric($stdDev)) && (is_numeric($size))) {
+ if (($alpha <= 0) || ($alpha >= 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($stdDev <= 0) || ($size < 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return self::NORMSINV(1 - $alpha / 2) * $stdDev / sqrt($size);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function CONFIDENCE()
+
+
+ /**
+ * CORREL
+ *
+ * Returns covariance, the average of the products of deviations for each data point pair.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @return float
+ */
+ public static function CORREL($yValues,$xValues=null) {
+ if ((is_null($xValues)) || (!is_array($yValues)) || (!is_array($xValues))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues);
+ return $bestFitLinear->getCorrelation();
+ } // function CORREL()
+
+
+ /**
+ * COUNT
+ *
+ * Counts the number of cells that contain numbers within the list of arguments
+ *
+ * Excel Function:
+ * COUNT(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return int
+ */
+ public static function COUNT() {
+ // Return value
+ $returnValue = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ ((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {
+ $arg = (integer) $arg;
+ }
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ ++$returnValue;
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function COUNT()
+
+
+ /**
+ * COUNTA
+ *
+ * Counts the number of cells that are not empty within the list of arguments
+ *
+ * Excel Function:
+ * COUNTA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return int
+ */
+ public static function COUNTA() {
+ // Return value
+ $returnValue = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ // Is it a numeric, boolean or string value?
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) && ($arg != '')))) {
+ ++$returnValue;
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function COUNTA()
+
+
+ /**
+ * COUNTBLANK
+ *
+ * Counts the number of empty cells within the list of arguments
+ *
+ * Excel Function:
+ * COUNTBLANK(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return int
+ */
+ public static function COUNTBLANK() {
+ // Return value
+ $returnValue = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ // Is it a blank cell?
+ if ((is_null($arg)) || ((is_string($arg)) && ($arg == ''))) {
+ ++$returnValue;
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function COUNTBLANK()
+
+
+ /**
+ * COUNTIF
+ *
+ * Counts the number of cells that contain numbers within the list of arguments
+ *
+ * Excel Function:
+ * COUNTIF(value1[,value2[, ...]],condition)
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @param string $condition The criteria that defines which cells will be counted.
+ * @return int
+ */
+ public static function COUNTIF($aArgs,$condition) {
+ // Return value
+ $returnValue = 0;
+
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray($aArgs);
+ $condition = PHPExcel_Calculation_Functions::_ifCondition($condition);
+ // Loop through arguments
+ foreach ($aArgs as $arg) {
+ if (!is_numeric($arg)) { $arg = PHPExcel_Calculation::_wrapResult(strtoupper($arg)); }
+ $testCondition = '='.$arg.$condition;
+ if (PHPExcel_Calculation::getInstance()->_calculateFormulaValue($testCondition)) {
+ // Is it a value within our criteria
+ ++$returnValue;
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function COUNTIF()
+
+
+ /**
+ * COVAR
+ *
+ * Returns covariance, the average of the products of deviations for each data point pair.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @return float
+ */
+ public static function COVAR($yValues,$xValues) {
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues);
+ return $bestFitLinear->getCovariance();
+ } // function COVAR()
+
+
+ /**
+ * CRITBINOM
+ *
+ * Returns the smallest value for which the cumulative binomial distribution is greater
+ * than or equal to a criterion value
+ *
+ * See http://support.microsoft.com/kb/828117/ for details of the algorithm used
+ *
+ * @param float $trials number of Bernoulli trials
+ * @param float $probability probability of a success on each trial
+ * @param float $alpha criterion value
+ * @return int
+ *
+ * @todo Warning. This implementation differs from the algorithm detailed on the MS
+ * web site in that $CumPGuessMinus1 = $CumPGuess - 1 rather than $CumPGuess - $PGuess
+ * This eliminates a potential endless loop error, but may have an adverse affect on the
+ * accuracy of the function (although all my tests have so far returned correct results).
+ *
+ */
+ public static function CRITBINOM($trials, $probability, $alpha) {
+ $trials = floor(PHPExcel_Calculation_Functions::flattenSingleValue($trials));
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+ $alpha = PHPExcel_Calculation_Functions::flattenSingleValue($alpha);
+
+ if ((is_numeric($trials)) && (is_numeric($probability)) && (is_numeric($alpha))) {
+ if ($trials < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($probability < 0) || ($probability > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($alpha < 0) || ($alpha > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($alpha <= 0.5) {
+ $t = sqrt(log(1 / ($alpha * $alpha)));
+ $trialsApprox = 0 - ($t + (2.515517 + 0.802853 * $t + 0.010328 * $t * $t) / (1 + 1.432788 * $t + 0.189269 * $t * $t + 0.001308 * $t * $t * $t));
+ } else {
+ $t = sqrt(log(1 / pow(1 - $alpha,2)));
+ $trialsApprox = $t - (2.515517 + 0.802853 * $t + 0.010328 * $t * $t) / (1 + 1.432788 * $t + 0.189269 * $t * $t + 0.001308 * $t * $t * $t);
+ }
+ $Guess = floor($trials * $probability + $trialsApprox * sqrt($trials * $probability * (1 - $probability)));
+ if ($Guess < 0) {
+ $Guess = 0;
+ } elseif ($Guess > $trials) {
+ $Guess = $trials;
+ }
+
+ $TotalUnscaledProbability = $UnscaledPGuess = $UnscaledCumPGuess = 0.0;
+ $EssentiallyZero = 10e-12;
+
+ $m = floor($trials * $probability);
+ ++$TotalUnscaledProbability;
+ if ($m == $Guess) { ++$UnscaledPGuess; }
+ if ($m <= $Guess) { ++$UnscaledCumPGuess; }
+
+ $PreviousValue = 1;
+ $Done = False;
+ $k = $m + 1;
+ while ((!$Done) && ($k <= $trials)) {
+ $CurrentValue = $PreviousValue * ($trials - $k + 1) * $probability / ($k * (1 - $probability));
+ $TotalUnscaledProbability += $CurrentValue;
+ if ($k == $Guess) { $UnscaledPGuess += $CurrentValue; }
+ if ($k <= $Guess) { $UnscaledCumPGuess += $CurrentValue; }
+ if ($CurrentValue <= $EssentiallyZero) { $Done = True; }
+ $PreviousValue = $CurrentValue;
+ ++$k;
+ }
+
+ $PreviousValue = 1;
+ $Done = False;
+ $k = $m - 1;
+ while ((!$Done) && ($k >= 0)) {
+ $CurrentValue = $PreviousValue * $k + 1 * (1 - $probability) / (($trials - $k) * $probability);
+ $TotalUnscaledProbability += $CurrentValue;
+ if ($k == $Guess) { $UnscaledPGuess += $CurrentValue; }
+ if ($k <= $Guess) { $UnscaledCumPGuess += $CurrentValue; }
+ if ($CurrentValue <= $EssentiallyZero) { $Done = True; }
+ $PreviousValue = $CurrentValue;
+ --$k;
+ }
+
+ $PGuess = $UnscaledPGuess / $TotalUnscaledProbability;
+ $CumPGuess = $UnscaledCumPGuess / $TotalUnscaledProbability;
+
+// $CumPGuessMinus1 = $CumPGuess - $PGuess;
+ $CumPGuessMinus1 = $CumPGuess - 1;
+
+ while (True) {
+ if (($CumPGuessMinus1 < $alpha) && ($CumPGuess >= $alpha)) {
+ return $Guess;
+ } elseif (($CumPGuessMinus1 < $alpha) && ($CumPGuess < $alpha)) {
+ $PGuessPlus1 = $PGuess * ($trials - $Guess) * $probability / $Guess / (1 - $probability);
+ $CumPGuessMinus1 = $CumPGuess;
+ $CumPGuess = $CumPGuess + $PGuessPlus1;
+ $PGuess = $PGuessPlus1;
+ ++$Guess;
+ } elseif (($CumPGuessMinus1 >= $alpha) && ($CumPGuess >= $alpha)) {
+ $PGuessMinus1 = $PGuess * $Guess * (1 - $probability) / ($trials - $Guess + 1) / $probability;
+ $CumPGuess = $CumPGuessMinus1;
+ $CumPGuessMinus1 = $CumPGuessMinus1 - $PGuess;
+ $PGuess = $PGuessMinus1;
+ --$Guess;
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function CRITBINOM()
+
+
+ /**
+ * DEVSQ
+ *
+ * Returns the sum of squares of deviations of data points from their sample mean.
+ *
+ * Excel Function:
+ * DEVSQ(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function DEVSQ() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+
+ // Return value
+ $returnValue = null;
+
+ $aMean = self::AVERAGE($aArgs);
+ if ($aMean != PHPExcel_Calculation_Functions::DIV0()) {
+ $aCount = -1;
+ foreach ($aArgs as $k => $arg) {
+ // Is it a numeric value?
+ if ((is_bool($arg)) &&
+ ((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {
+ $arg = (integer) $arg;
+ }
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if (is_null($returnValue)) {
+ $returnValue = pow(($arg - $aMean),2);
+ } else {
+ $returnValue += pow(($arg - $aMean),2);
+ }
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if (is_null($returnValue)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ } else {
+ return $returnValue;
+ }
+ }
+ return self::NA();
+ } // function DEVSQ()
+
+
+ /**
+ * EXPONDIST
+ *
+ * Returns the exponential distribution. Use EXPONDIST to model the time between events,
+ * such as how long an automated bank teller takes to deliver cash. For example, you can
+ * use EXPONDIST to determine the probability that the process takes at most 1 minute.
+ *
+ * @param float $value Value of the function
+ * @param float $lambda The parameter value
+ * @param boolean $cumulative
+ * @return float
+ */
+ public static function EXPONDIST($value, $lambda, $cumulative) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $lambda = PHPExcel_Calculation_Functions::flattenSingleValue($lambda);
+ $cumulative = PHPExcel_Calculation_Functions::flattenSingleValue($cumulative);
+
+ if ((is_numeric($value)) && (is_numeric($lambda))) {
+ if (($value < 0) || ($lambda < 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ((is_numeric($cumulative)) || (is_bool($cumulative))) {
+ if ($cumulative) {
+ return 1 - exp(0-$value*$lambda);
+ } else {
+ return $lambda * exp(0-$value*$lambda);
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function EXPONDIST()
+
+
+ /**
+ * FISHER
+ *
+ * Returns the Fisher transformation at x. This transformation produces a function that
+ * is normally distributed rather than skewed. Use this function to perform hypothesis
+ * testing on the correlation coefficient.
+ *
+ * @param float $value
+ * @return float
+ */
+ public static function FISHER($value) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+
+ if (is_numeric($value)) {
+ if (($value <= -1) || ($value >= 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return 0.5 * log((1+$value)/(1-$value));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function FISHER()
+
+
+ /**
+ * FISHERINV
+ *
+ * Returns the inverse of the Fisher transformation. Use this transformation when
+ * analyzing correlations between ranges or arrays of data. If y = FISHER(x), then
+ * FISHERINV(y) = x.
+ *
+ * @param float $value
+ * @return float
+ */
+ public static function FISHERINV($value) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+
+ if (is_numeric($value)) {
+ return (exp(2 * $value) - 1) / (exp(2 * $value) + 1);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function FISHERINV()
+
+
+ /**
+ * FORECAST
+ *
+ * Calculates, or predicts, a future value by using existing values. The predicted value is a y-value for a given x-value.
+ *
+ * @param float Value of X for which we want to find Y
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @return float
+ */
+ public static function FORECAST($xValue,$yValues,$xValues) {
+ $xValue = PHPExcel_Calculation_Functions::flattenSingleValue($xValue);
+ if (!is_numeric($xValue)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues);
+ return $bestFitLinear->getValueOfYForX($xValue);
+ } // function FORECAST()
+
+
+ /**
+ * GAMMADIST
+ *
+ * Returns the gamma distribution.
+ *
+ * @param float $value Value at which you want to evaluate the distribution
+ * @param float $a Parameter to the distribution
+ * @param float $b Parameter to the distribution
+ * @param boolean $cumulative
+ * @return float
+ *
+ */
+ public static function GAMMADIST($value,$a,$b,$cumulative) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $a = PHPExcel_Calculation_Functions::flattenSingleValue($a);
+ $b = PHPExcel_Calculation_Functions::flattenSingleValue($b);
+
+ if ((is_numeric($value)) && (is_numeric($a)) && (is_numeric($b))) {
+ if (($value < 0) || ($a <= 0) || ($b <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ((is_numeric($cumulative)) || (is_bool($cumulative))) {
+ if ($cumulative) {
+ return self::_incompleteGamma($a,$value / $b) / self::_gamma($a);
+ } else {
+ return (1 / (pow($b,$a) * self::_gamma($a))) * pow($value,$a-1) * exp(0-($value / $b));
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function GAMMADIST()
+
+
+ /**
+ * GAMMAINV
+ *
+ * Returns the inverse of the beta distribution.
+ *
+ * @param float $probability Probability at which you want to evaluate the distribution
+ * @param float $alpha Parameter to the distribution
+ * @param float $beta Parameter to the distribution
+ * @return float
+ *
+ */
+ public static function GAMMAINV($probability,$alpha,$beta) {
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+ $alpha = PHPExcel_Calculation_Functions::flattenSingleValue($alpha);
+ $beta = PHPExcel_Calculation_Functions::flattenSingleValue($beta);
+
+ if ((is_numeric($probability)) && (is_numeric($alpha)) && (is_numeric($beta))) {
+ if (($alpha <= 0) || ($beta <= 0) || ($probability < 0) || ($probability > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $xLo = 0;
+ $xHi = $alpha * $beta * 5;
+
+ $x = $xNew = 1;
+ $error = $pdf = 0;
+ $dx = 1024;
+ $i = 0;
+
+ while ((abs($dx) > PRECISION) && ($i++ < MAX_ITERATIONS)) {
+ // Apply Newton-Raphson step
+ $error = self::GAMMADIST($x, $alpha, $beta, True) - $probability;
+ if ($error < 0.0) {
+ $xLo = $x;
+ } else {
+ $xHi = $x;
+ }
+ $pdf = self::GAMMADIST($x, $alpha, $beta, False);
+ // Avoid division by zero
+ if ($pdf != 0.0) {
+ $dx = $error / $pdf;
+ $xNew = $x - $dx;
+ }
+ // If the NR fails to converge (which for example may be the
+ // case if the initial guess is too rough) we apply a bisection
+ // step to determine a more narrow interval around the root.
+ if (($xNew < $xLo) || ($xNew > $xHi) || ($pdf == 0.0)) {
+ $xNew = ($xLo + $xHi) / 2;
+ $dx = $xNew - $x;
+ }
+ $x = $xNew;
+ }
+ if ($i == MAX_ITERATIONS) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ return $x;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function GAMMAINV()
+
+
+ /**
+ * GAMMALN
+ *
+ * Returns the natural logarithm of the gamma function.
+ *
+ * @param float $value
+ * @return float
+ */
+ public static function GAMMALN($value) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+
+ if (is_numeric($value)) {
+ if ($value <= 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return log(self::_gamma($value));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function GAMMALN()
+
+
+ /**
+ * GEOMEAN
+ *
+ * Returns the geometric mean of an array or range of positive data. For example, you
+ * can use GEOMEAN to calculate average growth rate given compound interest with
+ * variable rates.
+ *
+ * Excel Function:
+ * GEOMEAN(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function GEOMEAN() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ $aMean = PHPExcel_Calculation_MathTrig::PRODUCT($aArgs);
+ if (is_numeric($aMean) && ($aMean > 0)) {
+ $aCount = self::COUNT($aArgs) ;
+ if (self::MIN($aArgs) > 0) {
+ return pow($aMean, (1 / $aCount));
+ }
+ }
+ return PHPExcel_Calculation_Functions::NaN();
+ } // GEOMEAN()
+
+
+ /**
+ * GROWTH
+ *
+ * Returns values along a predicted emponential trend
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @param array of mixed Values of X for which we want to find Y
+ * @param boolean A logical value specifying whether to force the intersect to equal 0.
+ * @return array of float
+ */
+ public static function GROWTH($yValues,$xValues=array(),$newValues=array(),$const=True) {
+ $yValues = PHPExcel_Calculation_Functions::flattenArray($yValues);
+ $xValues = PHPExcel_Calculation_Functions::flattenArray($xValues);
+ $newValues = PHPExcel_Calculation_Functions::flattenArray($newValues);
+ $const = (is_null($const)) ? True : (boolean) PHPExcel_Calculation_Functions::flattenSingleValue($const);
+
+ $bestFitExponential = trendClass::calculate(trendClass::TREND_EXPONENTIAL,$yValues,$xValues,$const);
+ if (count($newValues) == 0) {
+ $newValues = $bestFitExponential->getXValues();
+ }
+
+ $returnArray = array();
+ foreach($newValues as $xValue) {
+ $returnArray[0][] = $bestFitExponential->getValueOfYForX($xValue);
+ }
+
+ return $returnArray;
+ } // function GROWTH()
+
+
+ /**
+ * HARMEAN
+ *
+ * Returns the harmonic mean of a data set. The harmonic mean is the reciprocal of the
+ * arithmetic mean of reciprocals.
+ *
+ * Excel Function:
+ * HARMEAN(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function HARMEAN() {
+ // Return value
+ $returnValue = PHPExcel_Calculation_Functions::NA();
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ if (self::MIN($aArgs) < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $aCount = 0;
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if ($arg <= 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (is_null($returnValue)) {
+ $returnValue = (1 / $arg);
+ } else {
+ $returnValue += (1 / $arg);
+ }
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if ($aCount > 0) {
+ return 1 / ($returnValue / $aCount);
+ } else {
+ return $returnValue;
+ }
+ } // function HARMEAN()
+
+
+ /**
+ * HYPGEOMDIST
+ *
+ * Returns the hypergeometric distribution. HYPGEOMDIST returns the probability of a given number of
+ * sample successes, given the sample size, population successes, and population size.
+ *
+ * @param float $sampleSuccesses Number of successes in the sample
+ * @param float $sampleNumber Size of the sample
+ * @param float $populationSuccesses Number of successes in the population
+ * @param float $populationNumber Population size
+ * @return float
+ *
+ */
+ public static function HYPGEOMDIST($sampleSuccesses, $sampleNumber, $populationSuccesses, $populationNumber) {
+ $sampleSuccesses = floor(PHPExcel_Calculation_Functions::flattenSingleValue($sampleSuccesses));
+ $sampleNumber = floor(PHPExcel_Calculation_Functions::flattenSingleValue($sampleNumber));
+ $populationSuccesses = floor(PHPExcel_Calculation_Functions::flattenSingleValue($populationSuccesses));
+ $populationNumber = floor(PHPExcel_Calculation_Functions::flattenSingleValue($populationNumber));
+
+ if ((is_numeric($sampleSuccesses)) && (is_numeric($sampleNumber)) && (is_numeric($populationSuccesses)) && (is_numeric($populationNumber))) {
+ if (($sampleSuccesses < 0) || ($sampleSuccesses > $sampleNumber) || ($sampleSuccesses > $populationSuccesses)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($sampleNumber <= 0) || ($sampleNumber > $populationNumber)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($populationSuccesses <= 0) || ($populationSuccesses > $populationNumber)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return PHPExcel_Calculation_MathTrig::COMBIN($populationSuccesses,$sampleSuccesses) *
+ PHPExcel_Calculation_MathTrig::COMBIN($populationNumber - $populationSuccesses,$sampleNumber - $sampleSuccesses) /
+ PHPExcel_Calculation_MathTrig::COMBIN($populationNumber,$sampleNumber);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function HYPGEOMDIST()
+
+
+ /**
+ * INTERCEPT
+ *
+ * Calculates the point at which a line will intersect the y-axis by using existing x-values and y-values.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @return float
+ */
+ public static function INTERCEPT($yValues,$xValues) {
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues);
+ return $bestFitLinear->getIntersect();
+ } // function INTERCEPT()
+
+
+ /**
+ * KURT
+ *
+ * Returns the kurtosis of a data set. Kurtosis characterizes the relative peakedness
+ * or flatness of a distribution compared with the normal distribution. Positive
+ * kurtosis indicates a relatively peaked distribution. Negative kurtosis indicates a
+ * relatively flat distribution.
+ *
+ * @param array Data Series
+ * @return float
+ */
+ public static function KURT() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+ $mean = self::AVERAGE($aArgs);
+ $stdDev = self::STDEV($aArgs);
+
+ if ($stdDev > 0) {
+ $count = $summer = 0;
+ // Loop through arguments
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ (!PHPExcel_Calculation_Functions::isMatrixValue($k))) {
+ } else {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $summer += pow((($arg - $mean) / $stdDev),4) ;
+ ++$count;
+ }
+ }
+ }
+
+ // Return
+ if ($count > 3) {
+ return $summer * ($count * ($count+1) / (($count-1) * ($count-2) * ($count-3))) - (3 * pow($count-1,2) / (($count-2) * ($count-3)));
+ }
+ }
+ return PHPExcel_Calculation_Functions::DIV0();
+ } // function KURT()
+
+
+ /**
+ * LARGE
+ *
+ * Returns the nth largest value in a data set. You can use this function to
+ * select a value based on its relative standing.
+ *
+ * Excel Function:
+ * LARGE(value1[,value2[, ...]],entry)
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @param int $entry Position (ordered from the largest) in the array or range of data to return
+ * @return float
+ *
+ */
+ public static function LARGE() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ // Calculate
+ $entry = floor(array_pop($aArgs));
+
+ if ((is_numeric($entry)) && (!is_string($entry))) {
+ $mArgs = array();
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $mArgs[] = $arg;
+ }
+ }
+ $count = self::COUNT($mArgs);
+ $entry = floor(--$entry);
+ if (($entry < 0) || ($entry >= $count) || ($count == 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ rsort($mArgs);
+ return $mArgs[$entry];
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function LARGE()
+
+
+ /**
+ * LINEST
+ *
+ * Calculates the statistics for a line by using the "least squares" method to calculate a straight line that best fits your data,
+ * and then returns an array that describes the line.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @param boolean A logical value specifying whether to force the intersect to equal 0.
+ * @param boolean A logical value specifying whether to return additional regression statistics.
+ * @return array
+ */
+ public static function LINEST($yValues,$xValues=null,$const=True,$stats=False) {
+ $const = (is_null($const)) ? True : (boolean) PHPExcel_Calculation_Functions::flattenSingleValue($const);
+ $stats = (is_null($stats)) ? False : (boolean) PHPExcel_Calculation_Functions::flattenSingleValue($stats);
+ if (is_null($xValues)) $xValues = range(1,count(PHPExcel_Calculation_Functions::flattenArray($yValues)));
+
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return 0;
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues,$const);
+ if ($stats) {
+ return array( array( $bestFitLinear->getSlope(),
+ $bestFitLinear->getSlopeSE(),
+ $bestFitLinear->getGoodnessOfFit(),
+ $bestFitLinear->getF(),
+ $bestFitLinear->getSSRegression(),
+ ),
+ array( $bestFitLinear->getIntersect(),
+ $bestFitLinear->getIntersectSE(),
+ $bestFitLinear->getStdevOfResiduals(),
+ $bestFitLinear->getDFResiduals(),
+ $bestFitLinear->getSSResiduals()
+ )
+ );
+ } else {
+ return array( $bestFitLinear->getSlope(),
+ $bestFitLinear->getIntersect()
+ );
+ }
+ } // function LINEST()
+
+
+ /**
+ * LOGEST
+ *
+ * Calculates an exponential curve that best fits the X and Y data series,
+ * and then returns an array that describes the line.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @param boolean A logical value specifying whether to force the intersect to equal 0.
+ * @param boolean A logical value specifying whether to return additional regression statistics.
+ * @return array
+ */
+ public static function LOGEST($yValues,$xValues=null,$const=True,$stats=False) {
+ $const = (is_null($const)) ? True : (boolean) PHPExcel_Calculation_Functions::flattenSingleValue($const);
+ $stats = (is_null($stats)) ? False : (boolean) PHPExcel_Calculation_Functions::flattenSingleValue($stats);
+ if (is_null($xValues)) $xValues = range(1,count(PHPExcel_Calculation_Functions::flattenArray($yValues)));
+
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ foreach($yValues as $value) {
+ if ($value <= 0.0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ }
+
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return 1;
+ }
+
+ $bestFitExponential = trendClass::calculate(trendClass::TREND_EXPONENTIAL,$yValues,$xValues,$const);
+ if ($stats) {
+ return array( array( $bestFitExponential->getSlope(),
+ $bestFitExponential->getSlopeSE(),
+ $bestFitExponential->getGoodnessOfFit(),
+ $bestFitExponential->getF(),
+ $bestFitExponential->getSSRegression(),
+ ),
+ array( $bestFitExponential->getIntersect(),
+ $bestFitExponential->getIntersectSE(),
+ $bestFitExponential->getStdevOfResiduals(),
+ $bestFitExponential->getDFResiduals(),
+ $bestFitExponential->getSSResiduals()
+ )
+ );
+ } else {
+ return array( $bestFitExponential->getSlope(),
+ $bestFitExponential->getIntersect()
+ );
+ }
+ } // function LOGEST()
+
+
+ /**
+ * LOGINV
+ *
+ * Returns the inverse of the normal cumulative distribution
+ *
+ * @param float $value
+ * @return float
+ *
+ * @todo Try implementing P J Acklam's refinement algorithm for greater
+ * accuracy if I can get my head round the mathematics
+ * (as described at) http://home.online.no/~pjacklam/notes/invnorm/
+ */
+ public static function LOGINV($probability, $mean, $stdDev) {
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+ $mean = PHPExcel_Calculation_Functions::flattenSingleValue($mean);
+ $stdDev = PHPExcel_Calculation_Functions::flattenSingleValue($stdDev);
+
+ if ((is_numeric($probability)) && (is_numeric($mean)) && (is_numeric($stdDev))) {
+ if (($probability < 0) || ($probability > 1) || ($stdDev <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return exp($mean + $stdDev * self::NORMSINV($probability));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function LOGINV()
+
+
+ /**
+ * LOGNORMDIST
+ *
+ * Returns the cumulative lognormal distribution of x, where ln(x) is normally distributed
+ * with parameters mean and standard_dev.
+ *
+ * @param float $value
+ * @return float
+ */
+ public static function LOGNORMDIST($value, $mean, $stdDev) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $mean = PHPExcel_Calculation_Functions::flattenSingleValue($mean);
+ $stdDev = PHPExcel_Calculation_Functions::flattenSingleValue($stdDev);
+
+ if ((is_numeric($value)) && (is_numeric($mean)) && (is_numeric($stdDev))) {
+ if (($value <= 0) || ($stdDev <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return self::NORMSDIST((log($value) - $mean) / $stdDev);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function LOGNORMDIST()
+
+
+ /**
+ * MAX
+ *
+ * MAX returns the value of the element of the values passed that has the highest value,
+ * with negative numbers considered smaller than positive numbers.
+ *
+ * Excel Function:
+ * MAX(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function MAX() {
+ // Return value
+ $returnValue = null;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if ((is_null($returnValue)) || ($arg > $returnValue)) {
+ $returnValue = $arg;
+ }
+ }
+ }
+
+ // Return
+ if(is_null($returnValue)) {
+ return 0;
+ }
+ return $returnValue;
+ } // function MAX()
+
+
+ /**
+ * MAXA
+ *
+ * Returns the greatest value in a list of arguments, including numbers, text, and logical values
+ *
+ * Excel Function:
+ * MAXA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function MAXA() {
+ // Return value
+ $returnValue = null;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) && ($arg != '')))) {
+ if (is_bool($arg)) {
+ $arg = (integer) $arg;
+ } elseif (is_string($arg)) {
+ $arg = 0;
+ }
+ if ((is_null($returnValue)) || ($arg > $returnValue)) {
+ $returnValue = $arg;
+ }
+ }
+ }
+
+ // Return
+ if(is_null($returnValue)) {
+ return 0;
+ }
+ return $returnValue;
+ } // function MAXA()
+
+
+ /**
+ * MAXIF
+ *
+ * Counts the maximum value within a range of cells that contain numbers within the list of arguments
+ *
+ * Excel Function:
+ * MAXIF(value1[,value2[, ...]],condition)
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @param string $condition The criteria that defines which cells will be checked.
+ * @return float
+ */
+ public static function MAXIF($aArgs,$condition,$sumArgs = array()) {
+ // Return value
+ $returnValue = null;
+
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray($aArgs);
+ $sumArgs = PHPExcel_Calculation_Functions::flattenArray($sumArgs);
+ if (count($sumArgs) == 0) {
+ $sumArgs = $aArgs;
+ }
+ $condition = PHPExcel_Calculation_Functions::_ifCondition($condition);
+ // Loop through arguments
+ foreach ($aArgs as $key => $arg) {
+ if (!is_numeric($arg)) { $arg = PHPExcel_Calculation::_wrapResult(strtoupper($arg)); }
+ $testCondition = '='.$arg.$condition;
+ if (PHPExcel_Calculation::getInstance()->_calculateFormulaValue($testCondition)) {
+ if ((is_null($returnValue)) || ($arg > $returnValue)) {
+ $returnValue = $arg;
+ }
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function MAXIF()
+
+
+ /**
+ * MEDIAN
+ *
+ * Returns the median of the given numbers. The median is the number in the middle of a set of numbers.
+ *
+ * Excel Function:
+ * MEDIAN(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function MEDIAN() {
+ // Return value
+ $returnValue = PHPExcel_Calculation_Functions::NaN();
+
+ $mArgs = array();
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $mArgs[] = $arg;
+ }
+ }
+
+ $mValueCount = count($mArgs);
+ if ($mValueCount > 0) {
+ sort($mArgs,SORT_NUMERIC);
+ $mValueCount = $mValueCount / 2;
+ if ($mValueCount == floor($mValueCount)) {
+ $returnValue = ($mArgs[$mValueCount--] + $mArgs[$mValueCount]) / 2;
+ } else {
+ $mValueCount == floor($mValueCount);
+ $returnValue = $mArgs[$mValueCount];
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function MEDIAN()
+
+
+ /**
+ * MIN
+ *
+ * MIN returns the value of the element of the values passed that has the smallest value,
+ * with negative numbers considered smaller than positive numbers.
+ *
+ * Excel Function:
+ * MIN(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function MIN() {
+ // Return value
+ $returnValue = null;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if ((is_null($returnValue)) || ($arg < $returnValue)) {
+ $returnValue = $arg;
+ }
+ }
+ }
+
+ // Return
+ if(is_null($returnValue)) {
+ return 0;
+ }
+ return $returnValue;
+ } // function MIN()
+
+
+ /**
+ * MINA
+ *
+ * Returns the smallest value in a list of arguments, including numbers, text, and logical values
+ *
+ * Excel Function:
+ * MINA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function MINA() {
+ // Return value
+ $returnValue = null;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) && ($arg != '')))) {
+ if (is_bool($arg)) {
+ $arg = (integer) $arg;
+ } elseif (is_string($arg)) {
+ $arg = 0;
+ }
+ if ((is_null($returnValue)) || ($arg < $returnValue)) {
+ $returnValue = $arg;
+ }
+ }
+ }
+
+ // Return
+ if(is_null($returnValue)) {
+ return 0;
+ }
+ return $returnValue;
+ } // function MINA()
+
+
+ /**
+ * MINIF
+ *
+ * Returns the minimum value within a range of cells that contain numbers within the list of arguments
+ *
+ * Excel Function:
+ * MINIF(value1[,value2[, ...]],condition)
+ *
+ * @access public
+ * @category Mathematical and Trigonometric Functions
+ * @param mixed $arg,... Data values
+ * @param string $condition The criteria that defines which cells will be checked.
+ * @return float
+ */
+ public static function MINIF($aArgs,$condition,$sumArgs = array()) {
+ // Return value
+ $returnValue = null;
+
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray($aArgs);
+ $sumArgs = PHPExcel_Calculation_Functions::flattenArray($sumArgs);
+ if (count($sumArgs) == 0) {
+ $sumArgs = $aArgs;
+ }
+ $condition = PHPExcel_Calculation_Functions::_ifCondition($condition);
+ // Loop through arguments
+ foreach ($aArgs as $key => $arg) {
+ if (!is_numeric($arg)) { $arg = PHPExcel_Calculation::_wrapResult(strtoupper($arg)); }
+ $testCondition = '='.$arg.$condition;
+ if (PHPExcel_Calculation::getInstance()->_calculateFormulaValue($testCondition)) {
+ if ((is_null($returnValue)) || ($arg < $returnValue)) {
+ $returnValue = $arg;
+ }
+ }
+ }
+
+ // Return
+ return $returnValue;
+ } // function MINIF()
+
+
+ //
+ // Special variant of array_count_values that isn't limited to strings and integers,
+ // but can work with floating point numbers as values
+ //
+ private static function _modeCalc($data) {
+ $frequencyArray = array();
+ foreach($data as $datum) {
+ $found = False;
+ foreach($frequencyArray as $key => $value) {
+ if ((string) $value['value'] == (string) $datum) {
+ ++$frequencyArray[$key]['frequency'];
+ $found = True;
+ break;
+ }
+ }
+ if (!$found) {
+ $frequencyArray[] = array('value' => $datum,
+ 'frequency' => 1 );
+ }
+ }
+
+ foreach($frequencyArray as $key => $value) {
+ $frequencyList[$key] = $value['frequency'];
+ $valueList[$key] = $value['value'];
+ }
+ array_multisort($frequencyList, SORT_DESC, $valueList, SORT_ASC, SORT_NUMERIC, $frequencyArray);
+
+ if ($frequencyArray[0]['frequency'] == 1) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ return $frequencyArray[0]['value'];
+ } // function _modeCalc()
+
+
+ /**
+ * MODE
+ *
+ * Returns the most frequently occurring, or repetitive, value in an array or range of data
+ *
+ * Excel Function:
+ * MODE(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function MODE() {
+ // Return value
+ $returnValue = PHPExcel_Calculation_Functions::NA();
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ $mArgs = array();
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $mArgs[] = $arg;
+ }
+ }
+
+ if (count($mArgs) > 0) {
+ return self::_modeCalc($mArgs);
+ }
+
+ // Return
+ return $returnValue;
+ } // function MODE()
+
+
+ /**
+ * NEGBINOMDIST
+ *
+ * Returns the negative binomial distribution. NEGBINOMDIST returns the probability that
+ * there will be number_f failures before the number_s-th success, when the constant
+ * probability of a success is probability_s. This function is similar to the binomial
+ * distribution, except that the number of successes is fixed, and the number of trials is
+ * variable. Like the binomial, trials are assumed to be independent.
+ *
+ * @param float $failures Number of Failures
+ * @param float $successes Threshold number of Successes
+ * @param float $probability Probability of success on each trial
+ * @return float
+ *
+ */
+ public static function NEGBINOMDIST($failures, $successes, $probability) {
+ $failures = floor(PHPExcel_Calculation_Functions::flattenSingleValue($failures));
+ $successes = floor(PHPExcel_Calculation_Functions::flattenSingleValue($successes));
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+
+ if ((is_numeric($failures)) && (is_numeric($successes)) && (is_numeric($probability))) {
+ if (($failures < 0) || ($successes < 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (($probability < 0) || ($probability > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_GNUMERIC) {
+ if (($failures + $successes - 1) <= 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ }
+ return (PHPExcel_Calculation_MathTrig::COMBIN($failures + $successes - 1,$successes - 1)) * (pow($probability,$successes)) * (pow(1 - $probability,$failures)) ;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function NEGBINOMDIST()
+
+
+ /**
+ * NORMDIST
+ *
+ * Returns the normal distribution for the specified mean and standard deviation. This
+ * function has a very wide range of applications in statistics, including hypothesis
+ * testing.
+ *
+ * @param float $value
+ * @param float $mean Mean Value
+ * @param float $stdDev Standard Deviation
+ * @param boolean $cumulative
+ * @return float
+ *
+ */
+ public static function NORMDIST($value, $mean, $stdDev, $cumulative) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $mean = PHPExcel_Calculation_Functions::flattenSingleValue($mean);
+ $stdDev = PHPExcel_Calculation_Functions::flattenSingleValue($stdDev);
+
+ if ((is_numeric($value)) && (is_numeric($mean)) && (is_numeric($stdDev))) {
+ if ($stdDev < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ((is_numeric($cumulative)) || (is_bool($cumulative))) {
+ if ($cumulative) {
+ return 0.5 * (1 + PHPExcel_Calculation_Engineering::_erfVal(($value - $mean) / ($stdDev * sqrt(2))));
+ } else {
+ return (1 / (SQRT2PI * $stdDev)) * exp(0 - (pow($value - $mean,2) / (2 * ($stdDev * $stdDev))));
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function NORMDIST()
+
+
+ /**
+ * NORMINV
+ *
+ * Returns the inverse of the normal cumulative distribution for the specified mean and standard deviation.
+ *
+ * @param float $value
+ * @param float $mean Mean Value
+ * @param float $stdDev Standard Deviation
+ * @return float
+ *
+ */
+ public static function NORMINV($probability,$mean,$stdDev) {
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+ $mean = PHPExcel_Calculation_Functions::flattenSingleValue($mean);
+ $stdDev = PHPExcel_Calculation_Functions::flattenSingleValue($stdDev);
+
+ if ((is_numeric($probability)) && (is_numeric($mean)) && (is_numeric($stdDev))) {
+ if (($probability < 0) || ($probability > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ($stdDev < 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return (self::_inverse_ncdf($probability) * $stdDev) + $mean;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function NORMINV()
+
+
+ /**
+ * NORMSDIST
+ *
+ * Returns the standard normal cumulative distribution function. The distribution has
+ * a mean of 0 (zero) and a standard deviation of one. Use this function in place of a
+ * table of standard normal curve areas.
+ *
+ * @param float $value
+ * @return float
+ */
+ public static function NORMSDIST($value) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+
+ return self::NORMDIST($value, 0, 1, True);
+ } // function NORMSDIST()
+
+
+ /**
+ * NORMSINV
+ *
+ * Returns the inverse of the standard normal cumulative distribution
+ *
+ * @param float $value
+ * @return float
+ */
+ public static function NORMSINV($value) {
+ return self::NORMINV($value, 0, 1);
+ } // function NORMSINV()
+
+
+ /**
+ * PERCENTILE
+ *
+ * Returns the nth percentile of values in a range..
+ *
+ * Excel Function:
+ * PERCENTILE(value1[,value2[, ...]],entry)
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @param float $entry Percentile value in the range 0..1, inclusive.
+ * @return float
+ */
+ public static function PERCENTILE() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ // Calculate
+ $entry = array_pop($aArgs);
+
+ if ((is_numeric($entry)) && (!is_string($entry))) {
+ if (($entry < 0) || ($entry > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $mArgs = array();
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $mArgs[] = $arg;
+ }
+ }
+ $mValueCount = count($mArgs);
+ if ($mValueCount > 0) {
+ sort($mArgs);
+ $count = self::COUNT($mArgs);
+ $index = $entry * ($count-1);
+ $iBase = floor($index);
+ if ($index == $iBase) {
+ return $mArgs[$index];
+ } else {
+ $iNext = $iBase + 1;
+ $iProportion = $index - $iBase;
+ return $mArgs[$iBase] + (($mArgs[$iNext] - $mArgs[$iBase]) * $iProportion) ;
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function PERCENTILE()
+
+
+ /**
+ * PERCENTRANK
+ *
+ * Returns the rank of a value in a data set as a percentage of the data set.
+ *
+ * @param array of number An array of, or a reference to, a list of numbers.
+ * @param number The number whose rank you want to find.
+ * @param number The number of significant digits for the returned percentage value.
+ * @return float
+ */
+ public static function PERCENTRANK($valueSet,$value,$significance=3) {
+ $valueSet = PHPExcel_Calculation_Functions::flattenArray($valueSet);
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $significance = (is_null($significance)) ? 3 : (integer) PHPExcel_Calculation_Functions::flattenSingleValue($significance);
+
+ foreach($valueSet as $key => $valueEntry) {
+ if (!is_numeric($valueEntry)) {
+ unset($valueSet[$key]);
+ }
+ }
+ sort($valueSet,SORT_NUMERIC);
+ $valueCount = count($valueSet);
+ if ($valueCount == 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+
+ $valueAdjustor = $valueCount - 1;
+ if (($value < $valueSet[0]) || ($value > $valueSet[$valueAdjustor])) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+
+ $pos = array_search($value,$valueSet);
+ if ($pos === False) {
+ $pos = 0;
+ $testValue = $valueSet[0];
+ while ($testValue < $value) {
+ $testValue = $valueSet[++$pos];
+ }
+ --$pos;
+ $pos += (($value - $valueSet[$pos]) / ($testValue - $valueSet[$pos]));
+ }
+
+ return round($pos / $valueAdjustor,$significance);
+ } // function PERCENTRANK()
+
+
+ /**
+ * PERMUT
+ *
+ * Returns the number of permutations for a given number of objects that can be
+ * selected from number objects. A permutation is any set or subset of objects or
+ * events where internal order is significant. Permutations are different from
+ * combinations, for which the internal order is not significant. Use this function
+ * for lottery-style probability calculations.
+ *
+ * @param int $numObjs Number of different objects
+ * @param int $numInSet Number of objects in each permutation
+ * @return int Number of permutations
+ */
+ public static function PERMUT($numObjs,$numInSet) {
+ $numObjs = PHPExcel_Calculation_Functions::flattenSingleValue($numObjs);
+ $numInSet = PHPExcel_Calculation_Functions::flattenSingleValue($numInSet);
+
+ if ((is_numeric($numObjs)) && (is_numeric($numInSet))) {
+ $numInSet = floor($numInSet);
+ if ($numObjs < $numInSet) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return round(PHPExcel_Calculation_MathTrig::FACT($numObjs) / PHPExcel_Calculation_MathTrig::FACT($numObjs - $numInSet));
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function PERMUT()
+
+
+ /**
+ * POISSON
+ *
+ * Returns the Poisson distribution. A common application of the Poisson distribution
+ * is predicting the number of events over a specific time, such as the number of
+ * cars arriving at a toll plaza in 1 minute.
+ *
+ * @param float $value
+ * @param float $mean Mean Value
+ * @param boolean $cumulative
+ * @return float
+ *
+ */
+ public static function POISSON($value, $mean, $cumulative) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $mean = PHPExcel_Calculation_Functions::flattenSingleValue($mean);
+
+ if ((is_numeric($value)) && (is_numeric($mean))) {
+ if (($value <= 0) || ($mean <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ((is_numeric($cumulative)) || (is_bool($cumulative))) {
+ if ($cumulative) {
+ $summer = 0;
+ for ($i = 0; $i <= floor($value); ++$i) {
+ $summer += pow($mean,$i) / PHPExcel_Calculation_MathTrig::FACT($i);
+ }
+ return exp(0-$mean) * $summer;
+ } else {
+ return (exp(0-$mean) * pow($mean,$value)) / PHPExcel_Calculation_MathTrig::FACT($value);
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function POISSON()
+
+
+ /**
+ * QUARTILE
+ *
+ * Returns the quartile of a data set.
+ *
+ * Excel Function:
+ * QUARTILE(value1[,value2[, ...]],entry)
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @param int $entry Quartile value in the range 1..3, inclusive.
+ * @return float
+ */
+ public static function QUARTILE() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ // Calculate
+ $entry = floor(array_pop($aArgs));
+
+ if ((is_numeric($entry)) && (!is_string($entry))) {
+ $entry /= 4;
+ if (($entry < 0) || ($entry > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return self::PERCENTILE($aArgs,$entry);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function QUARTILE()
+
+
+ /**
+ * RANK
+ *
+ * Returns the rank of a number in a list of numbers.
+ *
+ * @param number The number whose rank you want to find.
+ * @param array of number An array of, or a reference to, a list of numbers.
+ * @param mixed Order to sort the values in the value set
+ * @return float
+ */
+ public static function RANK($value,$valueSet,$order=0) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $valueSet = PHPExcel_Calculation_Functions::flattenArray($valueSet);
+ $order = (is_null($order)) ? 0 : (integer) PHPExcel_Calculation_Functions::flattenSingleValue($order);
+
+ foreach($valueSet as $key => $valueEntry) {
+ if (!is_numeric($valueEntry)) {
+ unset($valueSet[$key]);
+ }
+ }
+
+ if ($order == 0) {
+ rsort($valueSet,SORT_NUMERIC);
+ } else {
+ sort($valueSet,SORT_NUMERIC);
+ }
+ $pos = array_search($value,$valueSet);
+ if ($pos === False) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+
+ return ++$pos;
+ } // function RANK()
+
+
+ /**
+ * RSQ
+ *
+ * Returns the square of the Pearson product moment correlation coefficient through data points in known_y's and known_x's.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @return float
+ */
+ public static function RSQ($yValues,$xValues) {
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues);
+ return $bestFitLinear->getGoodnessOfFit();
+ } // function RSQ()
+
+
+ /**
+ * SKEW
+ *
+ * Returns the skewness of a distribution. Skewness characterizes the degree of asymmetry
+ * of a distribution around its mean. Positive skewness indicates a distribution with an
+ * asymmetric tail extending toward more positive values. Negative skewness indicates a
+ * distribution with an asymmetric tail extending toward more negative values.
+ *
+ * @param array Data Series
+ * @return float
+ */
+ public static function SKEW() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+ $mean = self::AVERAGE($aArgs);
+ $stdDev = self::STDEV($aArgs);
+
+ $count = $summer = 0;
+ // Loop through arguments
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ (!PHPExcel_Calculation_Functions::isMatrixValue($k))) {
+ } else {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $summer += pow((($arg - $mean) / $stdDev),3) ;
+ ++$count;
+ }
+ }
+ }
+
+ // Return
+ if ($count > 2) {
+ return $summer * ($count / (($count-1) * ($count-2)));
+ }
+ return PHPExcel_Calculation_Functions::DIV0();
+ } // function SKEW()
+
+
+ /**
+ * SLOPE
+ *
+ * Returns the slope of the linear regression line through data points in known_y's and known_x's.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @return float
+ */
+ public static function SLOPE($yValues,$xValues) {
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues);
+ return $bestFitLinear->getSlope();
+ } // function SLOPE()
+
+
+ /**
+ * SMALL
+ *
+ * Returns the nth smallest value in a data set. You can use this function to
+ * select a value based on its relative standing.
+ *
+ * Excel Function:
+ * SMALL(value1[,value2[, ...]],entry)
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @param int $entry Position (ordered from the smallest) in the array or range of data to return
+ * @return float
+ */
+ public static function SMALL() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ // Calculate
+ $entry = array_pop($aArgs);
+
+ if ((is_numeric($entry)) && (!is_string($entry))) {
+ $mArgs = array();
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $mArgs[] = $arg;
+ }
+ }
+ $count = self::COUNT($mArgs);
+ $entry = floor(--$entry);
+ if (($entry < 0) || ($entry >= $count) || ($count == 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ sort($mArgs);
+ return $mArgs[$entry];
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SMALL()
+
+
+ /**
+ * STANDARDIZE
+ *
+ * Returns a normalized value from a distribution characterized by mean and standard_dev.
+ *
+ * @param float $value Value to normalize
+ * @param float $mean Mean Value
+ * @param float $stdDev Standard Deviation
+ * @return float Standardized value
+ */
+ public static function STANDARDIZE($value,$mean,$stdDev) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $mean = PHPExcel_Calculation_Functions::flattenSingleValue($mean);
+ $stdDev = PHPExcel_Calculation_Functions::flattenSingleValue($stdDev);
+
+ if ((is_numeric($value)) && (is_numeric($mean)) && (is_numeric($stdDev))) {
+ if ($stdDev <= 0) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ return ($value - $mean) / $stdDev ;
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function STANDARDIZE()
+
+
+ /**
+ * STDEV
+ *
+ * Estimates standard deviation based on a sample. The standard deviation is a measure of how
+ * widely values are dispersed from the average value (the mean).
+ *
+ * Excel Function:
+ * STDEV(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function STDEV() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+
+ // Return value
+ $returnValue = null;
+
+ $aMean = self::AVERAGE($aArgs);
+ if (!is_null($aMean)) {
+ $aCount = -1;
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ ((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {
+ $arg = (integer) $arg;
+ }
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if (is_null($returnValue)) {
+ $returnValue = pow(($arg - $aMean),2);
+ } else {
+ $returnValue += pow(($arg - $aMean),2);
+ }
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if (($aCount > 0) && ($returnValue >= 0)) {
+ return sqrt($returnValue / $aCount);
+ }
+ }
+ return PHPExcel_Calculation_Functions::DIV0();
+ } // function STDEV()
+
+
+ /**
+ * STDEVA
+ *
+ * Estimates standard deviation based on a sample, including numbers, text, and logical values
+ *
+ * Excel Function:
+ * STDEVA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function STDEVA() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+
+ // Return value
+ $returnValue = null;
+
+ $aMean = self::AVERAGEA($aArgs);
+ if (!is_null($aMean)) {
+ $aCount = -1;
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ (!PHPExcel_Calculation_Functions::isMatrixValue($k))) {
+ } else {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) & ($arg != '')))) {
+ if (is_bool($arg)) {
+ $arg = (integer) $arg;
+ } elseif (is_string($arg)) {
+ $arg = 0;
+ }
+ if (is_null($returnValue)) {
+ $returnValue = pow(($arg - $aMean),2);
+ } else {
+ $returnValue += pow(($arg - $aMean),2);
+ }
+ ++$aCount;
+ }
+ }
+ }
+
+ // Return
+ if (($aCount > 0) && ($returnValue >= 0)) {
+ return sqrt($returnValue / $aCount);
+ }
+ }
+ return PHPExcel_Calculation_Functions::DIV0();
+ } // function STDEVA()
+
+
+ /**
+ * STDEVP
+ *
+ * Calculates standard deviation based on the entire population
+ *
+ * Excel Function:
+ * STDEVP(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function STDEVP() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+
+ // Return value
+ $returnValue = null;
+
+ $aMean = self::AVERAGE($aArgs);
+ if (!is_null($aMean)) {
+ $aCount = 0;
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ ((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {
+ $arg = (integer) $arg;
+ }
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ if (is_null($returnValue)) {
+ $returnValue = pow(($arg - $aMean),2);
+ } else {
+ $returnValue += pow(($arg - $aMean),2);
+ }
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if (($aCount > 0) && ($returnValue >= 0)) {
+ return sqrt($returnValue / $aCount);
+ }
+ }
+ return PHPExcel_Calculation_Functions::DIV0();
+ } // function STDEVP()
+
+
+ /**
+ * STDEVPA
+ *
+ * Calculates standard deviation based on the entire population, including numbers, text, and logical values
+ *
+ * Excel Function:
+ * STDEVPA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function STDEVPA() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+
+ // Return value
+ $returnValue = null;
+
+ $aMean = self::AVERAGEA($aArgs);
+ if (!is_null($aMean)) {
+ $aCount = 0;
+ foreach ($aArgs as $k => $arg) {
+ if ((is_bool($arg)) &&
+ (!PHPExcel_Calculation_Functions::isMatrixValue($k))) {
+ } else {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) & ($arg != '')))) {
+ if (is_bool($arg)) {
+ $arg = (integer) $arg;
+ } elseif (is_string($arg)) {
+ $arg = 0;
+ }
+ if (is_null($returnValue)) {
+ $returnValue = pow(($arg - $aMean),2);
+ } else {
+ $returnValue += pow(($arg - $aMean),2);
+ }
+ ++$aCount;
+ }
+ }
+ }
+
+ // Return
+ if (($aCount > 0) && ($returnValue >= 0)) {
+ return sqrt($returnValue / $aCount);
+ }
+ }
+ return PHPExcel_Calculation_Functions::DIV0();
+ } // function STDEVPA()
+
+
+ /**
+ * STEYX
+ *
+ * Returns the standard error of the predicted y-value for each x in the regression.
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @return float
+ */
+ public static function STEYX($yValues,$xValues) {
+ if (!self::_checkTrendArrays($yValues,$xValues)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+ $yValueCount = count($yValues);
+ $xValueCount = count($xValues);
+
+ if (($yValueCount == 0) || ($yValueCount != $xValueCount)) {
+ return PHPExcel_Calculation_Functions::NA();
+ } elseif ($yValueCount == 1) {
+ return PHPExcel_Calculation_Functions::DIV0();
+ }
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues);
+ return $bestFitLinear->getStdevOfResiduals();
+ } // function STEYX()
+
+
+ /**
+ * TDIST
+ *
+ * Returns the probability of Student's T distribution.
+ *
+ * @param float $value Value for the function
+ * @param float $degrees degrees of freedom
+ * @param float $tails number of tails (1 or 2)
+ * @return float
+ */
+ public static function TDIST($value, $degrees, $tails) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $degrees = floor(PHPExcel_Calculation_Functions::flattenSingleValue($degrees));
+ $tails = floor(PHPExcel_Calculation_Functions::flattenSingleValue($tails));
+
+ if ((is_numeric($value)) && (is_numeric($degrees)) && (is_numeric($tails))) {
+ if (($value < 0) || ($degrees < 1) || ($tails < 1) || ($tails > 2)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ // tdist, which finds the probability that corresponds to a given value
+ // of t with k degrees of freedom. This algorithm is translated from a
+ // pascal function on p81 of "Statistical Computing in Pascal" by D
+ // Cooke, A H Craven & G M Clark (1985: Edward Arnold (Pubs.) Ltd:
+ // London). The above Pascal algorithm is itself a translation of the
+ // fortran algoritm "AS 3" by B E Cooper of the Atlas Computer
+ // Laboratory as reported in (among other places) "Applied Statistics
+ // Algorithms", editied by P Griffiths and I D Hill (1985; Ellis
+ // Horwood Ltd.; W. Sussex, England).
+ $tterm = $degrees;
+ $ttheta = atan2($value,sqrt($tterm));
+ $tc = cos($ttheta);
+ $ts = sin($ttheta);
+ $tsum = 0;
+
+ if (($degrees % 2) == 1) {
+ $ti = 3;
+ $tterm = $tc;
+ } else {
+ $ti = 2;
+ $tterm = 1;
+ }
+
+ $tsum = $tterm;
+ while ($ti < $degrees) {
+ $tterm *= $tc * $tc * ($ti - 1) / $ti;
+ $tsum += $tterm;
+ $ti += 2;
+ }
+ $tsum *= $ts;
+ if (($degrees % 2) == 1) { $tsum = M_2DIVPI * ($tsum + $ttheta); }
+ $tValue = 0.5 * (1 + $tsum);
+ if ($tails == 1) {
+ return 1 - abs($tValue);
+ } else {
+ return 1 - abs((1 - $tValue) - $tValue);
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function TDIST()
+
+
+ /**
+ * TINV
+ *
+ * Returns the one-tailed probability of the chi-squared distribution.
+ *
+ * @param float $probability Probability for the function
+ * @param float $degrees degrees of freedom
+ * @return float
+ */
+ public static function TINV($probability, $degrees) {
+ $probability = PHPExcel_Calculation_Functions::flattenSingleValue($probability);
+ $degrees = floor(PHPExcel_Calculation_Functions::flattenSingleValue($degrees));
+
+ if ((is_numeric($probability)) && (is_numeric($degrees))) {
+ $xLo = 100;
+ $xHi = 0;
+
+ $x = $xNew = 1;
+ $dx = 1;
+ $i = 0;
+
+ while ((abs($dx) > PRECISION) && ($i++ < MAX_ITERATIONS)) {
+ // Apply Newton-Raphson step
+ $result = self::TDIST($x, $degrees, 2);
+ $error = $result - $probability;
+ if ($error == 0.0) {
+ $dx = 0;
+ } elseif ($error < 0.0) {
+ $xLo = $x;
+ } else {
+ $xHi = $x;
+ }
+ // Avoid division by zero
+ if ($result != 0.0) {
+ $dx = $error / $result;
+ $xNew = $x - $dx;
+ }
+ // If the NR fails to converge (which for example may be the
+ // case if the initial guess is too rough) we apply a bisection
+ // step to determine a more narrow interval around the root.
+ if (($xNew < $xLo) || ($xNew > $xHi) || ($result == 0.0)) {
+ $xNew = ($xLo + $xHi) / 2;
+ $dx = $xNew - $x;
+ }
+ $x = $xNew;
+ }
+ if ($i == MAX_ITERATIONS) {
+ return PHPExcel_Calculation_Functions::NA();
+ }
+ return round($x,12);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function TINV()
+
+
+ /**
+ * TREND
+ *
+ * Returns values along a linear trend
+ *
+ * @param array of mixed Data Series Y
+ * @param array of mixed Data Series X
+ * @param array of mixed Values of X for which we want to find Y
+ * @param boolean A logical value specifying whether to force the intersect to equal 0.
+ * @return array of float
+ */
+ public static function TREND($yValues,$xValues=array(),$newValues=array(),$const=True) {
+ $yValues = PHPExcel_Calculation_Functions::flattenArray($yValues);
+ $xValues = PHPExcel_Calculation_Functions::flattenArray($xValues);
+ $newValues = PHPExcel_Calculation_Functions::flattenArray($newValues);
+ $const = (is_null($const)) ? True : (boolean) PHPExcel_Calculation_Functions::flattenSingleValue($const);
+
+ $bestFitLinear = trendClass::calculate(trendClass::TREND_LINEAR,$yValues,$xValues,$const);
+ if (count($newValues) == 0) {
+ $newValues = $bestFitLinear->getXValues();
+ }
+
+ $returnArray = array();
+ foreach($newValues as $xValue) {
+ $returnArray[0][] = $bestFitLinear->getValueOfYForX($xValue);
+ }
+
+ return $returnArray;
+ } // function TREND()
+
+
+ /**
+ * TRIMMEAN
+ *
+ * Returns the mean of the interior of a data set. TRIMMEAN calculates the mean
+ * taken by excluding a percentage of data points from the top and bottom tails
+ * of a data set.
+ *
+ * Excel Function:
+ * TRIMEAN(value1[,value2[, ...]],$discard)
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @param float $discard Percentage to discard
+ * @return float
+ */
+ public static function TRIMMEAN() {
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+
+ // Calculate
+ $percent = array_pop($aArgs);
+
+ if ((is_numeric($percent)) && (!is_string($percent))) {
+ if (($percent < 0) || ($percent > 1)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $mArgs = array();
+ foreach ($aArgs as $arg) {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $mArgs[] = $arg;
+ }
+ }
+ $discard = floor(self::COUNT($mArgs) * $percent / 2);
+ sort($mArgs);
+ for ($i=0; $i < $discard; ++$i) {
+ array_pop($mArgs);
+ array_shift($mArgs);
+ }
+ return self::AVERAGE($mArgs);
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function TRIMMEAN()
+
+
+ /**
+ * VARFunc
+ *
+ * Estimates variance based on a sample.
+ *
+ * Excel Function:
+ * VAR(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function VARFunc() {
+ // Return value
+ $returnValue = PHPExcel_Calculation_Functions::DIV0();
+
+ $summerA = $summerB = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ $aCount = 0;
+ foreach ($aArgs as $arg) {
+ if (is_bool($arg)) { $arg = (integer) $arg; }
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $summerA += ($arg * $arg);
+ $summerB += $arg;
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if ($aCount > 1) {
+ $summerA *= $aCount;
+ $summerB *= $summerB;
+ $returnValue = ($summerA - $summerB) / ($aCount * ($aCount - 1));
+ }
+ return $returnValue;
+ } // function VARFunc()
+
+
+ /**
+ * VARA
+ *
+ * Estimates variance based on a sample, including numbers, text, and logical values
+ *
+ * Excel Function:
+ * VARA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function VARA() {
+ // Return value
+ $returnValue = PHPExcel_Calculation_Functions::DIV0();
+
+ $summerA = $summerB = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+ $aCount = 0;
+ foreach ($aArgs as $k => $arg) {
+ if ((is_string($arg)) &&
+ (PHPExcel_Calculation_Functions::isValue($k))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ((is_string($arg)) &&
+ (!PHPExcel_Calculation_Functions::isMatrixValue($k))) {
+ } else {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) & ($arg != '')))) {
+ if (is_bool($arg)) {
+ $arg = (integer) $arg;
+ } elseif (is_string($arg)) {
+ $arg = 0;
+ }
+ $summerA += ($arg * $arg);
+ $summerB += $arg;
+ ++$aCount;
+ }
+ }
+ }
+
+ // Return
+ if ($aCount > 1) {
+ $summerA *= $aCount;
+ $summerB *= $summerB;
+ $returnValue = ($summerA - $summerB) / ($aCount * ($aCount - 1));
+ }
+ return $returnValue;
+ } // function VARA()
+
+
+ /**
+ * VARP
+ *
+ * Calculates variance based on the entire population
+ *
+ * Excel Function:
+ * VARP(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function VARP() {
+ // Return value
+ $returnValue = PHPExcel_Calculation_Functions::DIV0();
+
+ $summerA = $summerB = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ $aCount = 0;
+ foreach ($aArgs as $arg) {
+ if (is_bool($arg)) { $arg = (integer) $arg; }
+ // Is it a numeric value?
+ if ((is_numeric($arg)) && (!is_string($arg))) {
+ $summerA += ($arg * $arg);
+ $summerB += $arg;
+ ++$aCount;
+ }
+ }
+
+ // Return
+ if ($aCount > 0) {
+ $summerA *= $aCount;
+ $summerB *= $summerB;
+ $returnValue = ($summerA - $summerB) / ($aCount * $aCount);
+ }
+ return $returnValue;
+ } // function VARP()
+
+
+ /**
+ * VARPA
+ *
+ * Calculates variance based on the entire population, including numbers, text, and logical values
+ *
+ * Excel Function:
+ * VARPA(value1[,value2[, ...]])
+ *
+ * @access public
+ * @category Statistical Functions
+ * @param mixed $arg,... Data values
+ * @return float
+ */
+ public static function VARPA() {
+ // Return value
+ $returnValue = PHPExcel_Calculation_Functions::DIV0();
+
+ $summerA = $summerB = 0;
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());
+ $aCount = 0;
+ foreach ($aArgs as $k => $arg) {
+ if ((is_string($arg)) &&
+ (PHPExcel_Calculation_Functions::isValue($k))) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ } elseif ((is_string($arg)) &&
+ (!PHPExcel_Calculation_Functions::isMatrixValue($k))) {
+ } else {
+ // Is it a numeric value?
+ if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) & ($arg != '')))) {
+ if (is_bool($arg)) {
+ $arg = (integer) $arg;
+ } elseif (is_string($arg)) {
+ $arg = 0;
+ }
+ $summerA += ($arg * $arg);
+ $summerB += $arg;
+ ++$aCount;
+ }
+ }
+ }
+
+ // Return
+ if ($aCount > 0) {
+ $summerA *= $aCount;
+ $summerB *= $summerB;
+ $returnValue = ($summerA - $summerB) / ($aCount * $aCount);
+ }
+ return $returnValue;
+ } // function VARPA()
+
+
+ /**
+ * WEIBULL
+ *
+ * Returns the Weibull distribution. Use this distribution in reliability
+ * analysis, such as calculating a device's mean time to failure.
+ *
+ * @param float $value
+ * @param float $alpha Alpha Parameter
+ * @param float $beta Beta Parameter
+ * @param boolean $cumulative
+ * @return float
+ *
+ */
+ public static function WEIBULL($value, $alpha, $beta, $cumulative) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $alpha = PHPExcel_Calculation_Functions::flattenSingleValue($alpha);
+ $beta = PHPExcel_Calculation_Functions::flattenSingleValue($beta);
+
+ if ((is_numeric($value)) && (is_numeric($alpha)) && (is_numeric($beta))) {
+ if (($value < 0) || ($alpha <= 0) || ($beta <= 0)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ if ((is_numeric($cumulative)) || (is_bool($cumulative))) {
+ if ($cumulative) {
+ return 1 - exp(0 - pow($value / $beta,$alpha));
+ } else {
+ return ($alpha / pow($beta,$alpha)) * pow($value,$alpha - 1) * exp(0 - pow($value / $beta,$alpha));
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function WEIBULL()
+
+
+ /**
+ * ZTEST
+ *
+ * Returns the Weibull distribution. Use this distribution in reliability
+ * analysis, such as calculating a device's mean time to failure.
+ *
+ * @param float $value
+ * @param float $alpha Alpha Parameter
+ * @param float $beta Beta Parameter
+ * @param boolean $cumulative
+ * @return float
+ *
+ */
+ public static function ZTEST($dataSet, $m0, $sigma=null) {
+ $dataSet = PHPExcel_Calculation_Functions::flattenArrayIndexed($dataSet);
+ $m0 = PHPExcel_Calculation_Functions::flattenSingleValue($m0);
+ $sigma = PHPExcel_Calculation_Functions::flattenSingleValue($sigma);
+
+ if (is_null($sigma)) {
+ $sigma = self::STDEV($dataSet);
+ }
+ $n = count($dataSet);
+
+ return 1 - self::NORMSDIST((self::AVERAGE($dataSet) - $m0)/($sigma/SQRT($n)));
+ } // function ZTEST()
+
+} // class PHPExcel_Calculation_Statistical
diff --git a/Classes/PHPExcel/Calculation/TextData.php b/Classes/PHPExcel/Calculation/TextData.php
new file mode 100644
index 00000000..0e4d2c18
--- /dev/null
+++ b/Classes/PHPExcel/Calculation/TextData.php
@@ -0,0 +1,588 @@
+=0 && ord($c{0}) <= 127)
+ return ord($c{0});
+ if (ord($c{0}) >= 192 && ord($c{0}) <= 223)
+ return (ord($c{0})-192)*64 + (ord($c{1})-128);
+ if (ord($c{0}) >= 224 && ord($c{0}) <= 239)
+ return (ord($c{0})-224)*4096 + (ord($c{1})-128)*64 + (ord($c{2})-128);
+ if (ord($c{0}) >= 240 && ord($c{0}) <= 247)
+ return (ord($c{0})-240)*262144 + (ord($c{1})-128)*4096 + (ord($c{2})-128)*64 + (ord($c{3})-128);
+ if (ord($c{0}) >= 248 && ord($c{0}) <= 251)
+ return (ord($c{0})-248)*16777216 + (ord($c{1})-128)*262144 + (ord($c{2})-128)*4096 + (ord($c{3})-128)*64 + (ord($c{4})-128);
+ if (ord($c{0}) >= 252 && ord($c{0}) <= 253)
+ return (ord($c{0})-252)*1073741824 + (ord($c{1})-128)*16777216 + (ord($c{2})-128)*262144 + (ord($c{3})-128)*4096 + (ord($c{4})-128)*64 + (ord($c{5})-128);
+ if (ord($c{0}) >= 254 && ord($c{0}) <= 255) //error
+ return PHPExcel_Calculation_Functions::VALUE();
+ return 0;
+ } // function _uniord()
+
+ /**
+ * CHARACTER
+ *
+ * @param string $character Value
+ * @return int
+ */
+ public static function CHARACTER($character) {
+ $character = PHPExcel_Calculation_Functions::flattenSingleValue($character);
+
+ if ((!is_numeric($character)) || ($character < 0)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (function_exists('mb_convert_encoding')) {
+ return mb_convert_encoding('&#'.intval($character).';', 'UTF-8', 'HTML-ENTITIES');
+ } else {
+ return chr(intval($character));
+ }
+ }
+
+
+ /**
+ * TRIMNONPRINTABLE
+ *
+ * @param mixed $value Value to check
+ * @return string
+ */
+ public static function TRIMNONPRINTABLE($stringValue = '') {
+ $stringValue = PHPExcel_Calculation_Functions::flattenSingleValue($stringValue);
+
+ if (is_bool($stringValue)) {
+ $stringValue = ($stringValue) ? 'TRUE' : 'FALSE';
+ }
+
+ if (self::$_invalidChars == Null) {
+ self::$_invalidChars = range(chr(0),chr(31));
+ }
+
+ if (is_string($stringValue) || is_numeric($stringValue)) {
+ return str_replace(self::$_invalidChars,'',trim($stringValue,"\x00..\x1F"));
+ }
+ return Null;
+ } // function TRIMNONPRINTABLE()
+
+
+ /**
+ * TRIMSPACES
+ *
+ * @param mixed $value Value to check
+ * @return string
+ */
+ public static function TRIMSPACES($stringValue = '') {
+ $stringValue = PHPExcel_Calculation_Functions::flattenSingleValue($stringValue);
+
+ if (is_string($stringValue) || is_numeric($stringValue)) {
+ return trim(preg_replace('/ +/',' ',$stringValue));
+ }
+ return Null;
+ } // function TRIMSPACES()
+
+
+ /**
+ * ASCIICODE
+ *
+ * @param string $character Value
+ * @return int
+ */
+ public static function ASCIICODE($characters) {
+ $characters = PHPExcel_Calculation_Functions::flattenSingleValue($characters);
+ if (is_bool($characters)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $characters = (int) $characters;
+ } else {
+ if ($characters) {
+ $characters = 'True';
+ } else {
+ $characters = 'False';
+ }
+ }
+ }
+
+ $character = $characters;
+ if ((function_exists('mb_strlen')) && (function_exists('mb_substr'))) {
+ if (mb_strlen($characters, 'UTF-8') > 1) { $character = mb_substr($characters, 0, 1, 'UTF-8'); }
+ return self::_uniord($character);
+ } else {
+ if (strlen($characters) > 0) { $character = substr($characters, 0, 1); }
+ return ord($character);
+ }
+ } // function ASCIICODE()
+
+
+ /**
+ * CONCATENATE
+ *
+ * @return string
+ */
+ public static function CONCATENATE() {
+ // Return value
+ $returnValue = '';
+
+ // Loop through arguments
+ $aArgs = PHPExcel_Calculation_Functions::flattenArray(func_get_args());
+ foreach ($aArgs as $arg) {
+ if (is_bool($arg)) {
+ if (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE) {
+ $arg = (int) $arg;
+ } else {
+ if ($arg) {
+ $arg = 'TRUE';
+ } else {
+ $arg = 'FALSE';
+ }
+ }
+ }
+ $returnValue .= $arg;
+ }
+
+ // Return
+ return $returnValue;
+ } // function CONCATENATE()
+
+
+ /**
+ * DOLLAR
+ *
+ * This function converts a number to text using currency format, with the decimals rounded to the specified place.
+ * The format used is $#,##0.00_);($#,##0.00)..
+ *
+ * @param float $value The value to format
+ * @param int $decimals The number of digits to display to the right of the decimal point.
+ * If decimals is negative, number is rounded to the left of the decimal point.
+ * If you omit decimals, it is assumed to be 2
+ * @return string
+ */
+ public static function DOLLAR($value = 0, $decimals = 2) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $decimals = is_null($decimals) ? 0 : PHPExcel_Calculation_Functions::flattenSingleValue($decimals);
+
+ // Validate parameters
+ if (!is_numeric($value) || !is_numeric($decimals)) {
+ return PHPExcel_Calculation_Functions::NaN();
+ }
+ $decimals = floor($decimals);
+
+ if ($decimals > 0) {
+ return money_format('%.'.$decimals.'n',$value);
+ } else {
+ $round = pow(10,abs($decimals));
+ if ($value < 0) { $round = 0-$round; }
+ $value = PHPExcel_Calculation_MathTrig::MROUND($value,$round);
+ // The implementation of money_format used if the standard PHP function is not available can't handle decimal places of 0,
+ // so we display to 1 dp and chop off that character and the decimal separator using substr
+ return substr(money_format('%.1n',$value),0,-2);
+ }
+ } // function DOLLAR()
+
+
+ /**
+ * SEARCHSENSITIVE
+ *
+ * @param string $needle The string to look for
+ * @param string $haystack The string in which to look
+ * @param int $offset Offset within $haystack
+ * @return string
+ */
+ public static function SEARCHSENSITIVE($needle,$haystack,$offset=1) {
+ $needle = PHPExcel_Calculation_Functions::flattenSingleValue($needle);
+ $haystack = PHPExcel_Calculation_Functions::flattenSingleValue($haystack);
+ $offset = PHPExcel_Calculation_Functions::flattenSingleValue($offset);
+
+ if (!is_bool($needle)) {
+ if (is_bool($haystack)) {
+ $haystack = ($haystack) ? 'TRUE' : 'FALSE';
+ }
+
+ if (($offset > 0) && (strlen($haystack) > $offset)) {
+ if (function_exists('mb_strpos')) {
+ $pos = mb_strpos($haystack, $needle, --$offset,'UTF-8');
+ } else {
+ $pos = strpos($haystack, $needle, --$offset);
+ }
+ if ($pos !== false) {
+ return ++$pos;
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SEARCHSENSITIVE()
+
+
+ /**
+ * SEARCHINSENSITIVE
+ *
+ * @param string $needle The string to look for
+ * @param string $haystack The string in which to look
+ * @param int $offset Offset within $haystack
+ * @return string
+ */
+ public static function SEARCHINSENSITIVE($needle,$haystack,$offset=1) {
+ $needle = PHPExcel_Calculation_Functions::flattenSingleValue($needle);
+ $haystack = PHPExcel_Calculation_Functions::flattenSingleValue($haystack);
+ $offset = PHPExcel_Calculation_Functions::flattenSingleValue($offset);
+
+ if (!is_bool($needle)) {
+ if (is_bool($haystack)) {
+ $haystack = ($haystack) ? 'TRUE' : 'FALSE';
+ }
+
+ if (($offset > 0) && (strlen($haystack) > $offset)) {
+ if (function_exists('mb_stripos')) {
+ $pos = mb_stripos($haystack, $needle, --$offset,'UTF-8');
+ } else {
+ $pos = stripos($haystack, $needle, --$offset);
+ }
+ if ($pos !== false) {
+ return ++$pos;
+ }
+ }
+ }
+ return PHPExcel_Calculation_Functions::VALUE();
+ } // function SEARCHINSENSITIVE()
+
+
+ /**
+ * FIXEDFORMAT
+ *
+ * @param mixed $value Value to check
+ * @return boolean
+ */
+ public static function FIXEDFORMAT($value,$decimals=2,$no_commas=false) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $decimals = PHPExcel_Calculation_Functions::flattenSingleValue($decimals);
+ $no_commas = PHPExcel_Calculation_Functions::flattenSingleValue($no_commas);
+
+ $valueResult = round($value,$decimals);
+ if ($decimals < 0) { $decimals = 0; }
+ if (!$no_commas) {
+ $valueResult = number_format($valueResult,$decimals);
+ }
+
+ return (string) $valueResult;
+ } // function FIXEDFORMAT()
+
+
+ /**
+ * LEFT
+ *
+ * @param string $value Value
+ * @param int $chars Number of characters
+ * @return string
+ */
+ public static function LEFT($value = '', $chars = 1) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $chars = PHPExcel_Calculation_Functions::flattenSingleValue($chars);
+
+ if ($chars < 0) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (is_bool($value)) {
+ $value = ($value) ? 'TRUE' : 'FALSE';
+ }
+
+ if (function_exists('mb_substr')) {
+ return mb_substr($value, 0, $chars, 'UTF-8');
+ } else {
+ return substr($value, 0, $chars);
+ }
+ } // function LEFT()
+
+
+ /**
+ * MID
+ *
+ * @param string $value Value
+ * @param int $start Start character
+ * @param int $chars Number of characters
+ * @return string
+ */
+ public static function MID($value = '', $start = 1, $chars = null) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $start = PHPExcel_Calculation_Functions::flattenSingleValue($start);
+ $chars = PHPExcel_Calculation_Functions::flattenSingleValue($chars);
+
+ if (($start < 1) || ($chars < 0)) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (is_bool($value)) {
+ $value = ($value) ? 'TRUE' : 'FALSE';
+ }
+
+ if (function_exists('mb_substr')) {
+ return mb_substr($value, --$start, $chars, 'UTF-8');
+ } else {
+ return substr($value, --$start, $chars);
+ }
+ } // function MID()
+
+
+ /**
+ * RIGHT
+ *
+ * @param string $value Value
+ * @param int $chars Number of characters
+ * @return string
+ */
+ public static function RIGHT($value = '', $chars = 1) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $chars = PHPExcel_Calculation_Functions::flattenSingleValue($chars);
+
+ if ($chars < 0) {
+ return PHPExcel_Calculation_Functions::VALUE();
+ }
+
+ if (is_bool($value)) {
+ $value = ($value) ? 'TRUE' : 'FALSE';
+ }
+
+ if ((function_exists('mb_substr')) && (function_exists('mb_strlen'))) {
+ return mb_substr($value, mb_strlen($value, 'UTF-8') - $chars, $chars, 'UTF-8');
+ } else {
+ return substr($value, strlen($value) - $chars);
+ }
+ } // function RIGHT()
+
+
+ /**
+ * STRINGLENGTH
+ *
+ * @param string $value Value
+ * @param int $chars Number of characters
+ * @return string
+ */
+ public static function STRINGLENGTH($value = '') {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+
+ if (is_bool($value)) {
+ $value = ($value) ? 'TRUE' : 'FALSE';
+ }
+
+ if (function_exists('mb_strlen')) {
+ return mb_strlen($value, 'UTF-8');
+ } else {
+ return strlen($value);
+ }
+ } // function STRINGLENGTH()
+
+
+ /**
+ * LOWERCASE
+ *
+ * Converts a string value to upper case.
+ *
+ * @param string $mixedCaseString
+ * @return string
+ */
+ public static function LOWERCASE($mixedCaseString) {
+ $mixedCaseString = PHPExcel_Calculation_Functions::flattenSingleValue($mixedCaseString);
+
+ if (is_bool($mixedCaseString)) {
+ $mixedCaseString = ($mixedCaseString) ? 'TRUE' : 'FALSE';
+ }
+
+ if (function_exists('mb_convert_case')) {
+ return mb_convert_case($mixedCaseString, MB_CASE_LOWER, 'UTF-8');
+ } else {
+ return strtoupper($mixedCaseString);
+ }
+ } // function LOWERCASE()
+
+
+ /**
+ * UPPERCASE
+ *
+ * Converts a string value to upper case.
+ *
+ * @param string $mixedCaseString
+ * @return string
+ */
+ public static function UPPERCASE($mixedCaseString) {
+ $mixedCaseString = PHPExcel_Calculation_Functions::flattenSingleValue($mixedCaseString);
+
+ if (is_bool($mixedCaseString)) {
+ $mixedCaseString = ($mixedCaseString) ? 'TRUE' : 'FALSE';
+ }
+
+ if (function_exists('mb_convert_case')) {
+ return mb_convert_case($mixedCaseString, MB_CASE_UPPER, 'UTF-8');
+ } else {
+ return strtoupper($mixedCaseString);
+ }
+ } // function UPPERCASE()
+
+
+ /**
+ * PROPERCASE
+ *
+ * Converts a string value to upper case.
+ *
+ * @param string $mixedCaseString
+ * @return string
+ */
+ public static function PROPERCASE($mixedCaseString) {
+ $mixedCaseString = PHPExcel_Calculation_Functions::flattenSingleValue($mixedCaseString);
+
+ if (is_bool($mixedCaseString)) {
+ $mixedCaseString = ($mixedCaseString) ? 'TRUE' : 'FALSE';
+ }
+
+ if (function_exists('mb_convert_case')) {
+ return mb_convert_case($mixedCaseString, MB_CASE_TITLE, 'UTF-8');
+ } else {
+ return ucwords($mixedCaseString);
+ }
+ } // function PROPERCASE()
+
+
+ /**
+ * REPLACE
+ *
+ * @param string $value Value
+ * @param int $start Start character
+ * @param int $chars Number of characters
+ * @return string
+ */
+ public static function REPLACE($oldText = '', $start = 1, $chars = null, $newText) {
+ $oldText = PHPExcel_Calculation_Functions::flattenSingleValue($oldText);
+ $start = PHPExcel_Calculation_Functions::flattenSingleValue($start);
+ $chars = PHPExcel_Calculation_Functions::flattenSingleValue($chars);
+ $newText = PHPExcel_Calculation_Functions::flattenSingleValue($newText);
+
+ $left = self::LEFT($oldText,$start-1);
+ $right = self::RIGHT($oldText,self::STRINGLENGTH($oldText)-($start+$chars)+1);
+
+ return $left.$newText.$right;
+ } // function REPLACE()
+
+
+ /**
+ * SUBSTITUTE
+ *
+ * @param string $text Value
+ * @param string $fromText From Value
+ * @param string $toText To Value
+ * @param integer $instance Instance Number
+ * @return string
+ */
+ public static function SUBSTITUTE($text = '', $fromText = '', $toText = '', $instance = 0) {
+ $text = PHPExcel_Calculation_Functions::flattenSingleValue($text);
+ $fromText = PHPExcel_Calculation_Functions::flattenSingleValue($fromText);
+ $toText = PHPExcel_Calculation_Functions::flattenSingleValue($toText);
+ $instance = floor(PHPExcel_Calculation_Functions::flattenSingleValue($instance));
+
+ if ($instance == 0) {
+ if(function_exists('mb_str_replace')) {
+ return mb_str_replace($fromText,$toText,$text);
+ } else {
+ return str_replace($fromText,$toText,$text);
+ }
+ } else {
+ $pos = -1;
+ while($instance > 0) {
+ if (function_exists('mb_strpos')) {
+ $pos = mb_strpos($text, $fromText, $pos+1, 'UTF-8');
+ } else {
+ $pos = strpos($text, $fromText, $pos+1);
+ }
+ if ($pos === false) {
+ break;
+ }
+ --$instance;
+ }
+ if ($pos !== false) {
+ if (function_exists('mb_strlen')) {
+ return self::REPLACE($text,++$pos,mb_strlen($fromText, 'UTF-8'),$toText);
+ } else {
+ return self::REPLACE($text,++$pos,strlen($fromText),$toText);
+ }
+ }
+ }
+
+ return $left.$newText.$right;
+ } // function SUBSTITUTE()
+
+
+ /**
+ * RETURNSTRING
+ *
+ * @param mixed $value Value to check
+ * @return boolean
+ */
+ public static function RETURNSTRING($testValue = '') {
+ $testValue = PHPExcel_Calculation_Functions::flattenSingleValue($testValue);
+
+ if (is_string($testValue)) {
+ return $testValue;
+ }
+ return Null;
+ } // function RETURNSTRING()
+
+
+ /**
+ * TEXTFORMAT
+ *
+ * @param mixed $value Value to check
+ * @return boolean
+ */
+ public static function TEXTFORMAT($value,$format) {
+ $value = PHPExcel_Calculation_Functions::flattenSingleValue($value);
+ $format = PHPExcel_Calculation_Functions::flattenSingleValue($format);
+
+ if ((is_string($value)) && (!is_numeric($value)) && PHPExcel_Shared_Date::isDateTimeFormatCode($format)) {
+ $value = PHPExcel_Calculation_DateTime::DATEVALUE($value);
+ }
+
+ return (string) PHPExcel_Style_NumberFormat::toFormattedString($value,$format);
+ } // function TEXTFORMAT()
+
+} // class PHPExcel_Calculation_TextData