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<?php
namespace PhpOffice\PhpSpreadsheet\Calculation;
use PhpOffice\PhpSpreadsheet\Shared\Date;
class Financial
{
const FINANCIAL_MAX_ITERATIONS = 32;
const FINANCIAL_PRECISION = 1.0e-08;
/**
* isLastDayOfMonth.
*
* Returns a boolean TRUE/FALSE indicating if this date is the last date of the month
*
* @param \DateTime $testDate The date for testing
*
* @return bool
*/
private static function isLastDayOfMonth(\DateTime $testDate)
{
return $testDate->format('d') == $testDate->format('t');
}
private static function couponFirstPeriodDate($settlement, $maturity, $frequency, $next)
{
$months = 12 / $frequency;
$result = Date::excelToDateTimeObject($maturity);
$eom = self::isLastDayOfMonth($result);
while ($settlement < Date::PHPToExcel($result)) {
$result->modify('-' . $months . ' months');
}
if ($next) {
$result->modify('+' . $months . ' months');
}
if ($eom) {
$result->modify('-1 day');
}
return Date::PHPToExcel($result);
}
private static function isValidFrequency($frequency)
{
if (($frequency == 1) || ($frequency == 2) || ($frequency == 4)) {
return true;
}
if ((Functions::getCompatibilityMode() == Functions::COMPATIBILITY_GNUMERIC) &&
(($frequency == 6) || ($frequency == 12))) {
return true;
}
return false;
}
/**
* daysPerYear.
*
* Returns the number of days in a specified year, as defined by the "basis" value
*
* @param int|string $year The year against which we're testing
* @param int|string $basis The type of day count:
* 0 or omitted US (NASD) 360
* 1 Actual (365 or 366 in a leap year)
* 2 360
* 3 365
* 4 European 360
*
* @return int
*/
private static function daysPerYear($year, $basis = 0)
{
switch ($basis) {
case 0:
case 2:
case 4:
$daysPerYear = 360;
break;
case 3:
$daysPerYear = 365;
break;
case 1:
$daysPerYear = (DateTime::isLeapYear($year)) ? 366 : 365;
break;
default:
return Functions::NAN();
}
return $daysPerYear;
}
private static function interestAndPrincipal($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 += $principal;
}
return [$interest, $principal];
}
/**
* ACCRINT.
*
* Returns the accrued interest for a security that pays periodic interest.
*
* Excel Function:
* ACCRINT(issue,firstinterest,settlement,rate,par,frequency[,basis])
*
* @category Financial Functions
*
* @param mixed $issue the security's issue date
* @param mixed $firstinterest the security's first interest date
* @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 float $rate the security's annual coupon rate
* @param float $par The security's par value.
* If you omit par, ACCRINT uses $1,000.
* @param int $frequency the number of coupon payments per year.
* Valid frequency values are:
* 1 Annual
* 2 Semi-Annual
* 4 Quarterly
* If working in Gnumeric Mode, the following frequency options are
* also available
* 6 Bimonthly
* 12 Monthly
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float|string
*/
public static function ACCRINT($issue, $firstinterest, $settlement, $rate, $par = 1000, $frequency = 1, $basis = 0)
{
$issue = Functions::flattenSingleValue($issue);
$firstinterest = Functions::flattenSingleValue($firstinterest);
$settlement = Functions::flattenSingleValue($settlement);
$rate = Functions::flattenSingleValue($rate);
$par = ($par === null) ? 1000 : Functions::flattenSingleValue($par);
$frequency = ($frequency === null) ? 1 : Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : Functions::flattenSingleValue($basis);
// Validate
if ((is_numeric($rate)) && (is_numeric($par))) {
$rate = (float) $rate;
$par = (float) $par;
if (($rate <= 0) || ($par <= 0)) {
return Functions::NAN();
}
$daysBetweenIssueAndSettlement = DateTime::YEARFRAC($issue, $settlement, $basis);
if (!is_numeric($daysBetweenIssueAndSettlement)) {
// return date error
return $daysBetweenIssueAndSettlement;
}
return $par * $rate * $daysBetweenIssueAndSettlement;
}
return Functions::VALUE();
}
/**
* ACCRINTM.
*
* Returns the accrued interest for a security that pays interest at maturity.
*
* Excel Function:
* ACCRINTM(issue,settlement,rate[,par[,basis]])
*
* @category Financial Functions
*
* @param mixed $issue The security's issue date
* @param mixed $settlement The security's settlement (or maturity) date
* @param float $rate The security's annual coupon rate
* @param float $par The security's par value.
* If you omit par, ACCRINT uses $1,000.
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float|string
*/
public static function ACCRINTM($issue, $settlement, $rate, $par = 1000, $basis = 0)
{
$issue = Functions::flattenSingleValue($issue);
$settlement = Functions::flattenSingleValue($settlement);
$rate = Functions::flattenSingleValue($rate);
$par = ($par === null) ? 1000 : Functions::flattenSingleValue($par);
$basis = ($basis === null) ? 0 : Functions::flattenSingleValue($basis);
// Validate
if ((is_numeric($rate)) && (is_numeric($par))) {
$rate = (float) $rate;
$par = (float) $par;
if (($rate <= 0) || ($par <= 0)) {
return Functions::NAN();
}
$daysBetweenIssueAndSettlement = DateTime::YEARFRAC($issue, $settlement, $basis);
if (!is_numeric($daysBetweenIssueAndSettlement)) {
// return date error
return $daysBetweenIssueAndSettlement;
}
return $par * $rate * $daysBetweenIssueAndSettlement;
}
return Functions::VALUE();
}
/**
* AMORDEGRC.
*
* Returns the depreciation for each accounting period.
* This function is provided for the French accounting system. If an asset is purchased in
* the middle of the accounting period, the prorated depreciation is taken into account.
* The function is similar to AMORLINC, except that a depreciation coefficient is applied in
* the calculation depending on the life of the assets.
* This function will return the depreciation until the last period of the life of the assets
* or until the cumulated value of depreciation is greater than the cost of the assets minus
* the salvage value.
*
* Excel Function:
* AMORDEGRC(cost,purchased,firstPeriod,salvage,period,rate[,basis])
*
* @category Financial Functions
*
* @param float $cost The cost of the asset
* @param mixed $purchased Date of the purchase of the asset
* @param mixed $firstPeriod Date of the end of the first period
* @param mixed $salvage The salvage value at the end of the life of the asset
* @param float $period The period
* @param float $rate Rate of depreciation
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float
*/
public static function AMORDEGRC($cost, $purchased, $firstPeriod, $salvage, $period, $rate, $basis = 0)
{
$cost = Functions::flattenSingleValue($cost);
$purchased = Functions::flattenSingleValue($purchased);
$firstPeriod = Functions::flattenSingleValue($firstPeriod);
$salvage = Functions::flattenSingleValue($salvage);
$period = floor(Functions::flattenSingleValue($period));
$rate = Functions::flattenSingleValue($rate);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
// The depreciation coefficients are:
// Life of assets (1/rate) Depreciation coefficient
// Less than 3 years 1
// Between 3 and 4 years 1.5
// Between 5 and 6 years 2
// More than 6 years 2.5
$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;
$fNRate = round(DateTime::YEARFRAC($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);
default:
return 0.0;
}
}
$cost -= $fNRate;
}
return $fNRate;
}
/**
* AMORLINC.
*
* Returns the depreciation for each accounting period.
* This function is provided for the French accounting system. If an asset is purchased in
* the middle of the accounting period, the prorated depreciation is taken into account.
*
* Excel Function:
* AMORLINC(cost,purchased,firstPeriod,salvage,period,rate[,basis])
*
* @category Financial Functions
*
* @param float $cost The cost of the asset
* @param mixed $purchased Date of the purchase of the asset
* @param mixed $firstPeriod Date of the end of the first period
* @param mixed $salvage The salvage value at the end of the life of the asset
* @param float $period The period
* @param float $rate Rate of depreciation
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float
*/
public static function AMORLINC($cost, $purchased, $firstPeriod, $salvage, $period, $rate, $basis = 0)
{
$cost = Functions::flattenSingleValue($cost);
$purchased = Functions::flattenSingleValue($purchased);
$firstPeriod = Functions::flattenSingleValue($firstPeriod);
$salvage = Functions::flattenSingleValue($salvage);
$period = Functions::flattenSingleValue($period);
$rate = Functions::flattenSingleValue($rate);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
$fOneRate = $cost * $rate;
$fCostDelta = $cost - $salvage;
// Note, quirky variation for leap years on the YEARFRAC for this function
$purchasedYear = DateTime::YEAR($purchased);
$yearFrac = DateTime::YEARFRAC($purchased, $firstPeriod, $basis);
if (($basis == 1) && ($yearFrac < 1) && (DateTime::isLeapYear($purchasedYear))) {
$yearFrac *= 365 / 366;
}
$f0Rate = $yearFrac * $rate * $cost;
$nNumOfFullPeriods = (int) (($cost - $salvage - $f0Rate) / $fOneRate);
if ($period == 0) {
return $f0Rate;
} elseif ($period <= $nNumOfFullPeriods) {
return $fOneRate;
} elseif ($period == ($nNumOfFullPeriods + 1)) {
return $fCostDelta - $fOneRate * $nNumOfFullPeriods - $f0Rate;
}
return 0.0;
}
/**
* COUPDAYBS.
*
* Returns the number of days from the beginning of the coupon period to the settlement date.
*
* Excel Function:
* COUPDAYBS(settlement,maturity,frequency[,basis])
*
* @category Financial Functions
*
* @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 $frequency the number of coupon payments per year.
* Valid frequency values are:
* 1 Annual
* 2 Semi-Annual
* 4 Quarterly
* If working in Gnumeric Mode, the following frequency options are
* also available
* 6 Bimonthly
* 12 Monthly
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float|string
*/
public static function COUPDAYBS($settlement, $maturity, $frequency, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$frequency = (int) Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
if (is_string($settlement = DateTime::getDateValue($settlement))) {
return Functions::VALUE();
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (($settlement > $maturity) ||
(!self::isValidFrequency($frequency)) ||
(($basis < 0) || ($basis > 4))) {
return Functions::NAN();
}
$daysPerYear = self::daysPerYear(DateTime::YEAR($settlement), $basis);
$prev = self::couponFirstPeriodDate($settlement, $maturity, $frequency, false);
return DateTime::YEARFRAC($prev, $settlement, $basis) * $daysPerYear;
}
/**
* COUPDAYS.
*
* Returns the number of days in the coupon period that contains the settlement date.
*
* Excel Function:
* COUPDAYS(settlement,maturity,frequency[,basis])
*
* @category Financial Functions
*
* @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 mixed $frequency the number of coupon payments per year.
* Valid frequency values are:
* 1 Annual
* 2 Semi-Annual
* 4 Quarterly
* If working in Gnumeric Mode, the following frequency options are
* also available
* 6 Bimonthly
* 12 Monthly
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float|string
*/
public static function COUPDAYS($settlement, $maturity, $frequency, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$frequency = (int) Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
if (is_string($settlement = DateTime::getDateValue($settlement))) {
return Functions::VALUE();
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (($settlement > $maturity) ||
(!self::isValidFrequency($frequency)) ||
(($basis < 0) || ($basis > 4))) {
return Functions::NAN();
}
switch ($basis) {
case 3:
// Actual/365
return 365 / $frequency;
case 1:
// Actual/actual
if ($frequency == 1) {
$daysPerYear = self::daysPerYear(DateTime::YEAR($settlement), $basis);
return $daysPerYear / $frequency;
}
$prev = self::couponFirstPeriodDate($settlement, $maturity, $frequency, false);
$next = self::couponFirstPeriodDate($settlement, $maturity, $frequency, true);
return $next - $prev;
default:
// US (NASD) 30/360, Actual/360 or European 30/360
return 360 / $frequency;
}
}
/**
* COUPDAYSNC.
*
* Returns the number of days from the settlement date to the next coupon date.
*
* Excel Function:
* COUPDAYSNC(settlement,maturity,frequency[,basis])
*
* @category Financial Functions
*
* @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 mixed $frequency the number of coupon payments per year.
* Valid frequency values are:
* 1 Annual
* 2 Semi-Annual
* 4 Quarterly
* If working in Gnumeric Mode, the following frequency options are
* also available
* 6 Bimonthly
* 12 Monthly
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float|string
*/
public static function COUPDAYSNC($settlement, $maturity, $frequency, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$frequency = (int) Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
if (is_string($settlement = DateTime::getDateValue($settlement))) {
return Functions::VALUE();
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (($settlement > $maturity) ||
(!self::isValidFrequency($frequency)) ||
(($basis < 0) || ($basis > 4))) {
return Functions::NAN();
}
$daysPerYear = self::daysPerYear(DateTime::YEAR($settlement), $basis);
$next = self::couponFirstPeriodDate($settlement, $maturity, $frequency, true);
return DateTime::YEARFRAC($settlement, $next, $basis) * $daysPerYear;
}
/**
* COUPNCD.
*
* Returns the next coupon date after the settlement date.
*
* Excel Function:
* COUPNCD(settlement,maturity,frequency[,basis])
*
* @category Financial Functions
*
* @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 mixed $frequency the number of coupon payments per year.
* Valid frequency values are:
* 1 Annual
* 2 Semi-Annual
* 4 Quarterly
* If working in Gnumeric Mode, the following frequency options are
* also available
* 6 Bimonthly
* 12 Monthly
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
* depending on the value of the ReturnDateType flag
*/
public static function COUPNCD($settlement, $maturity, $frequency, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$frequency = (int) Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
if (is_string($settlement = DateTime::getDateValue($settlement))) {
return Functions::VALUE();
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (($settlement > $maturity) ||
(!self::isValidFrequency($frequency)) ||
(($basis < 0) || ($basis > 4))) {
return Functions::NAN();
}
return self::couponFirstPeriodDate($settlement, $maturity, $frequency, true);
}
/**
* COUPNUM.
*
* Returns the number of coupons payable between the settlement date and maturity date,
* rounded up to the nearest whole coupon.
*
* Excel Function:
* COUPNUM(settlement,maturity,frequency[,basis])
*
* @category Financial Functions
*
* @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 mixed $frequency the number of coupon payments per year.
* Valid frequency values are:
* 1 Annual
* 2 Semi-Annual
* 4 Quarterly
* If working in Gnumeric Mode, the following frequency options are
* also available
* 6 Bimonthly
* 12 Monthly
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return int|string
*/
public static function COUPNUM($settlement, $maturity, $frequency, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$frequency = (int) Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
if (is_string($settlement = DateTime::getDateValue($settlement))) {
return Functions::VALUE();
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (($settlement > $maturity) ||
(!self::isValidFrequency($frequency)) ||
(($basis < 0) || ($basis > 4))) {
return Functions::NAN();
}
$settlement = self::couponFirstPeriodDate($settlement, $maturity, $frequency, true);
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($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 Functions::VALUE();
}
/**
* COUPPCD.
*
* Returns the previous coupon date before the settlement date.
*
* Excel Function:
* COUPPCD(settlement,maturity,frequency[,basis])
*
* @category Financial Functions
*
* @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 mixed $frequency the number of coupon payments per year.
* Valid frequency values are:
* 1 Annual
* 2 Semi-Annual
* 4 Quarterly
* If working in Gnumeric Mode, the following frequency options are
* also available
* 6 Bimonthly
* 12 Monthly
* @param int $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return mixed Excel date/time serial value, PHP date/time serial value or PHP date/time object,
* depending on the value of the ReturnDateType flag
*/
public static function COUPPCD($settlement, $maturity, $frequency, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$frequency = (int) Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
if (is_string($settlement = DateTime::getDateValue($settlement))) {
return Functions::VALUE();
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (($settlement > $maturity) ||
(!self::isValidFrequency($frequency)) ||
(($basis < 0) || ($basis > 4))) {
return Functions::NAN();
}
return self::couponFirstPeriodDate($settlement, $maturity, $frequency, false);
}
/**
* CUMIPMT.
*
* Returns the cumulative interest paid on a loan between the start and end periods.
*
* Excel Function:
* CUMIPMT(rate,nper,pv,start,end[,type])
*
* @category Financial Functions
*
* @param float $rate The Interest rate
* @param int $nper The total number of payment 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 $type A number 0 or 1 and indicates when payments are due:
* 0 or omitted At the end of the period.
* 1 At the beginning of the period.
*
* @return float|string
*/
public static function CUMIPMT($rate, $nper, $pv, $start, $end, $type = 0)
{
$rate = Functions::flattenSingleValue($rate);
$nper = (int) Functions::flattenSingleValue($nper);
$pv = Functions::flattenSingleValue($pv);
$start = (int) Functions::flattenSingleValue($start);
$end = (int) Functions::flattenSingleValue($end);
$type = (int) Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
if ($start < 1 || $start > $end) {
return Functions::VALUE();
}
// Calculate
$interest = 0;
for ($per = $start; $per <= $end; ++$per) {
$interest += self::IPMT($rate, $per, $nper, $pv, 0, $type);
}
return $interest;
}
/**
* CUMPRINC.
*
* Returns the cumulative principal paid on a loan between the start and end periods.
*
* Excel Function:
* CUMPRINC(rate,nper,pv,start,end[,type])
*
* @category Financial Functions
*
* @param float $rate The Interest rate
* @param int $nper The total number of payment 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 $type A number 0 or 1 and indicates when payments are due:
* 0 or omitted At the end of the period.
* 1 At the beginning of the period.
*
* @return float|string
*/
public static function CUMPRINC($rate, $nper, $pv, $start, $end, $type = 0)
{
$rate = Functions::flattenSingleValue($rate);
$nper = (int) Functions::flattenSingleValue($nper);
$pv = Functions::flattenSingleValue($pv);
$start = (int) Functions::flattenSingleValue($start);
$end = (int) Functions::flattenSingleValue($end);
$type = (int) Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
if ($start < 1 || $start > $end) {
return Functions::VALUE();
}
// Calculate
$principal = 0;
for ($per = $start; $per <= $end; ++$per) {
$principal += self::PPMT($rate, $per, $nper, $pv, 0, $type);
}
return $principal;
}
/**
* 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.
*
* Excel Function:
* DB(cost,salvage,life,period[,month])
*
* @category Financial Functions
*
* @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 int $month Number of months in the first year. If month is omitted,
* it defaults to 12.
*
* @return float|string
*/
public static function DB($cost, $salvage, $life, $period, $month = 12)
{
$cost = Functions::flattenSingleValue($cost);
$salvage = Functions::flattenSingleValue($salvage);
$life = Functions::flattenSingleValue($life);
$period = Functions::flattenSingleValue($period);
$month = Functions::flattenSingleValue($month);
// Validate
if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life)) && (is_numeric($period)) && (is_numeric($month))) {
$cost = (float) $cost;
$salvage = (float) $salvage;
$life = (int) $life;
$period = (int) $period;
$month = (int) $month;
if ($cost == 0) {
return 0.0;
} elseif (($cost < 0) || (($salvage / $cost) < 0) || ($life <= 0) || ($period < 1) || ($month < 1)) {
return 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 (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_GNUMERIC) {
$depreciation = round($depreciation, 2);
}
return $depreciation;
}
return Functions::VALUE();
}
/**
* DDB.
*
* Returns the depreciation of an asset for a specified period using the
* double-declining balance method or some other method you specify.
*
* Excel Function:
* DDB(cost,salvage,life,period[,factor])
*
* @category Financial Functions
*
* @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 $factor The rate at which the balance declines.
* If factor is omitted, it is assumed to be 2 (the
* double-declining balance method).
*
* @return float|string
*/
public static function DDB($cost, $salvage, $life, $period, $factor = 2.0)
{
$cost = Functions::flattenSingleValue($cost);
$salvage = Functions::flattenSingleValue($salvage);
$life = Functions::flattenSingleValue($life);
$period = Functions::flattenSingleValue($period);
$factor = Functions::flattenSingleValue($factor);
// Validate
if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life)) && (is_numeric($period)) && (is_numeric($factor))) {
$cost = (float) $cost;
$salvage = (float) $salvage;
$life = (int) $life;
$period = (int) $period;
$factor = (float) $factor;
if (($cost <= 0) || (($salvage / $cost) < 0) || ($life <= 0) || ($period < 1) || ($factor <= 0.0) || ($period > $life)) {
return 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 (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_GNUMERIC) {
$depreciation = round($depreciation, 2);
}
return $depreciation;
}
return Functions::VALUE();
}
/**
* DISC.
*
* Returns the discount rate for a security.
*
* Excel Function:
* DISC(settlement,maturity,price,redemption[,basis])
*
* @category Financial Functions
*
* @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 $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float|string
*/
public static function DISC($settlement, $maturity, $price, $redemption, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$price = Functions::flattenSingleValue($price);
$redemption = Functions::flattenSingleValue($redemption);
$basis = Functions::flattenSingleValue($basis);
// Validate
if ((is_numeric($price)) && (is_numeric($redemption)) && (is_numeric($basis))) {
$price = (float) $price;
$redemption = (float) $redemption;
$basis = (int) $basis;
if (($price <= 0) || ($redemption <= 0)) {
return Functions::NAN();
}
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity, $basis);
if (!is_numeric($daysBetweenSettlementAndMaturity)) {
// return date error
return $daysBetweenSettlementAndMaturity;
}
return (1 - $price / $redemption) / $daysBetweenSettlementAndMaturity;
}
return Functions::VALUE();
}
/**
* 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.
*
* Excel Function:
* DOLLARDE(fractional_dollar,fraction)
*
* @category Financial Functions
*
* @param float $fractional_dollar Fractional Dollar
* @param int $fraction Fraction
*
* @return float|string
*/
public static function DOLLARDE($fractional_dollar = null, $fraction = 0)
{
$fractional_dollar = Functions::flattenSingleValue($fractional_dollar);
$fraction = (int) Functions::flattenSingleValue($fraction);
// Validate parameters
if ($fractional_dollar === null || $fraction < 0) {
return Functions::NAN();
}
if ($fraction == 0) {
return Functions::DIV0();
}
$dollars = floor($fractional_dollar);
$cents = fmod($fractional_dollar, 1);
$cents /= $fraction;
$cents *= pow(10, ceil(log10($fraction)));
return $dollars + $cents;
}
/**
* 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.
*
* Excel Function:
* DOLLARFR(decimal_dollar,fraction)
*
* @category Financial Functions
*
* @param float $decimal_dollar Decimal Dollar
* @param int $fraction Fraction
*
* @return float|string
*/
public static function DOLLARFR($decimal_dollar = null, $fraction = 0)
{
$decimal_dollar = Functions::flattenSingleValue($decimal_dollar);
$fraction = (int) Functions::flattenSingleValue($fraction);
// Validate parameters
if ($decimal_dollar === null || $fraction < 0) {
return Functions::NAN();
}
if ($fraction == 0) {
return Functions::DIV0();
}
$dollars = floor($decimal_dollar);
$cents = fmod($decimal_dollar, 1);
$cents *= $fraction;
$cents *= pow(10, -ceil(log10($fraction)));
return $dollars + $cents;
}
/**
* EFFECT.
*
* Returns the effective interest rate given the nominal rate and the number of
* compounding payments per year.
*
* Excel Function:
* EFFECT(nominal_rate,npery)
*
* @category Financial Functions
*
* @param float $nominal_rate Nominal interest rate
* @param int $npery Number of compounding payments per year
*
* @return float|string
*/
public static function EFFECT($nominal_rate = 0, $npery = 0)
{
$nominal_rate = Functions::flattenSingleValue($nominal_rate);
$npery = (int) Functions::flattenSingleValue($npery);
// Validate parameters
if ($nominal_rate <= 0 || $npery < 1) {
return Functions::NAN();
}
return pow((1 + $nominal_rate / $npery), $npery) - 1;
}
/**
* FV.
*
* Returns the Future Value of a cash flow with constant payments and interest rate (annuities).
*
* Excel Function:
* FV(rate,nper,pmt[,pv[,type]])
*
* @category Financial Functions
*
* @param float $rate The interest rate per period
* @param int $nper Total number of payment periods in an annuity
* @param float $pmt The payment made each period: it cannot change over the
* life of the annuity. Typically, pmt contains principal
* and interest but no other fees or taxes.
* @param float $pv present Value, or the lump-sum amount that a series of
* future payments is worth right now
* @param int $type A number 0 or 1 and indicates when payments are due:
* 0 or omitted At the end of the period.
* 1 At the beginning of the period.
*
* @return float|string
*/
public static function FV($rate = 0, $nper = 0, $pmt = 0, $pv = 0, $type = 0)
{
$rate = Functions::flattenSingleValue($rate);
$nper = Functions::flattenSingleValue($nper);
$pmt = Functions::flattenSingleValue($pmt);
$pv = Functions::flattenSingleValue($pv);
$type = Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
// Calculate
if ($rate !== null && $rate != 0) {
return -$pv * pow(1 + $rate, $nper) - $pmt * (1 + $rate * $type) * (pow(1 + $rate, $nper) - 1) / $rate;
}
return -$pv - $pmt * $nper;
}
/**
* FVSCHEDULE.
*
* Returns the future value of an initial principal after applying a series of compound interest rates.
* Use FVSCHEDULE to calculate the future value of an investment with a variable or adjustable rate.
*
* Excel Function:
* FVSCHEDULE(principal,schedule)
*
* @param float $principal the present value
* @param float[] $schedule an array of interest rates to apply
*
* @return float
*/
public static function FVSCHEDULE($principal, $schedule)
{
$principal = Functions::flattenSingleValue($principal);
$schedule = Functions::flattenArray($schedule);
foreach ($schedule as $rate) {
$principal *= 1 + $rate;
}
return $principal;
}
/**
* INTRATE.
*
* Returns the interest rate for a fully invested security.
*
* Excel Function:
* INTRATE(settlement,maturity,investment,redemption[,basis])
*
* @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 $basis The type of day count to use.
* 0 or omitted US (NASD) 30/360
* 1 Actual/actual
* 2 Actual/360
* 3 Actual/365
* 4 European 30/360
*
* @return float|string
*/
public static function INTRATE($settlement, $maturity, $investment, $redemption, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$investment = Functions::flattenSingleValue($investment);
$redemption = Functions::flattenSingleValue($redemption);
$basis = Functions::flattenSingleValue($basis);
// Validate
if ((is_numeric($investment)) && (is_numeric($redemption)) && (is_numeric($basis))) {
$investment = (float) $investment;
$redemption = (float) $redemption;
$basis = (int) $basis;
if (($investment <= 0) || ($redemption <= 0)) {
return Functions::NAN();
}
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity, $basis);
if (!is_numeric($daysBetweenSettlementAndMaturity)) {
// return date error
return $daysBetweenSettlementAndMaturity;
}
return (($redemption / $investment) - 1) / ($daysBetweenSettlementAndMaturity);
}
return Functions::VALUE();
}
/**
* IPMT.
*
* Returns the interest payment for a given period for an investment based on periodic, constant payments and a constant interest rate.
*
* Excel Function:
* IPMT(rate,per,nper,pv[,fv][,type])
*
* @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 $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
*
* @return float|string
*/
public static function IPMT($rate, $per, $nper, $pv, $fv = 0, $type = 0)
{
$rate = Functions::flattenSingleValue($rate);
$per = (int) Functions::flattenSingleValue($per);
$nper = (int) Functions::flattenSingleValue($nper);
$pv = Functions::flattenSingleValue($pv);
$fv = Functions::flattenSingleValue($fv);
$type = (int) Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
if ($per <= 0 || $per > $nper) {
return Functions::VALUE();
}
// Calculate
$interestAndPrincipal = self::interestAndPrincipal($rate, $per, $nper, $pv, $fv, $type);
return $interestAndPrincipal[0];
}
/**
* IRR.
*
* Returns the internal rate of return for a series of cash flows represented by the numbers in values.
* These cash flows do not have to be even, as they would be for an annuity. However, the cash flows must occur
* at regular intervals, such as monthly or annually. The internal rate of return is the interest rate received
* for an investment consisting of payments (negative values) and income (positive values) that occur at regular
* periods.
*
* Excel Function:
* IRR(values[,guess])
*
* @param float[] $values An array or a reference to cells that contain numbers for which you want
* to calculate the internal rate of return.
* Values must contain at least one positive value and one negative value to
* calculate the internal rate of return.
* @param float $guess A number that you guess is close to the result of IRR
*
* @return float|string
*/
public static function IRR($values, $guess = 0.1)
{
if (!is_array($values)) {
return Functions::VALUE();
}
$values = Functions::flattenArray($values);
$guess = Functions::flattenSingleValue($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; $i < self::FINANCIAL_MAX_ITERATIONS; ++$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 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; $i < self::FINANCIAL_MAX_ITERATIONS; ++$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) < self::FINANCIAL_PRECISION) || (abs($dx) < self::FINANCIAL_PRECISION)) {
return $x_mid;
}
}
return Functions::VALUE();
}
/**
* ISPMT.
*
* Returns the interest payment for an investment based on an interest rate and a constant payment schedule.
*
* Excel Function:
* =ISPMT(interest_rate, period, number_payments, PV)
*
* interest_rate is the interest rate for the investment
*
* period is the period to calculate the interest rate. It must be betweeen 1 and number_payments.
*
* number_payments is the number of payments for the annuity
*
* PV is the loan amount or present value of the payments
*/
public static function ISPMT(...$args)
{
// Return value
$returnValue = 0;
// Get the parameters
$aArgs = Functions::flattenArray($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;
}
/**
* MIRR.
*
* Returns the modified internal rate of return for a series of periodic cash flows. MIRR considers both
* the cost of the investment and the interest received on reinvestment of cash.
*
* Excel Function:
* MIRR(values,finance_rate, reinvestment_rate)
*
* @param float[] $values An array or a reference to cells that contain a series of payments and
* income occurring at regular intervals.
* Payments are negative value, income is positive values.
* @param float $finance_rate The interest rate you pay on the money used in the cash flows
* @param float $reinvestment_rate The interest rate you receive on the cash flows as you reinvest them
*
* @return float|string
*/
public static function MIRR($values, $finance_rate, $reinvestment_rate)
{
if (!is_array($values)) {
return Functions::VALUE();
}
$values = Functions::flattenArray($values);
$finance_rate = Functions::flattenSingleValue($finance_rate);
$reinvestment_rate = Functions::flattenSingleValue($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 Functions::VALUE();
}
$mirr = pow((-$npv_pos * pow($rr, $n))
/ ($npv_neg * ($rr)), (1.0 / ($n - 1))) - 1.0;
return is_finite($mirr) ? $mirr : Functions::VALUE();
}
/**
* 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 $npery Number of compounding payments per year
*
* @return float|string
*/
public static function NOMINAL($effect_rate = 0, $npery = 0)
{
$effect_rate = Functions::flattenSingleValue($effect_rate);
$npery = (int) Functions::flattenSingleValue($npery);
// Validate parameters
if ($effect_rate <= 0 || $npery < 1) {
return Functions::NAN();
}
// Calculate
return $npery * (pow($effect_rate + 1, 1 / $npery) - 1);
}
/**
* 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 $type Payment type: 0 = at the end of each period, 1 = at the beginning of each period
*
* @return float|string
*/
public static function NPER($rate = 0, $pmt = 0, $pv = 0, $fv = 0, $type = 0)
{
$rate = Functions::flattenSingleValue($rate);
$pmt = Functions::flattenSingleValue($pmt);
$pv = Functions::flattenSingleValue($pv);
$fv = Functions::flattenSingleValue($fv);
$type = Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
// Calculate
if ($rate !== null && $rate != 0) {
if ($pmt == 0 && $pv == 0) {
return Functions::NAN();
}
return log(($pmt * (1 + $rate * $type) / $rate - $fv) / ($pv + $pmt * (1 + $rate * $type) / $rate)) / log(1 + $rate);
}
if ($pmt == 0) {
return Functions::NAN();
}
return (-$pv - $fv) / $pmt;
}
/**
* NPV.
*
* Returns the Net Present Value of a cash flow series given a discount rate.
*
* @return float
*/
public static function NPV(...$args)
{
// Return value
$returnValue = 0;
// Loop through arguments
$aArgs = Functions::flattenArray($args);
// Calculate
$rate = array_shift($aArgs);
$countArgs = count($aArgs);
for ($i = 1; $i <= $countArgs; ++$i) {
// Is it a numeric value?
if (is_numeric($aArgs[$i - 1])) {
$returnValue += $aArgs[$i - 1] / pow(1 + $rate, $i);
}
}
// Return
return $returnValue;
}
/**
* PDURATION.
*
* Calculates the number of periods required for an investment to reach a specified value.
*
* @param float $rate Interest rate per period
* @param float $pv Present Value
* @param float $fv Future Value
*
* @return float|string
*/
public static function PDURATION($rate = 0, $pv = 0, $fv = 0)
{
$rate = Functions::flattenSingleValue($rate);
$pv = Functions::flattenSingleValue($pv);
$fv = Functions::flattenSingleValue($fv);
// Validate parameters
if (!is_numeric($rate) || !is_numeric($pv) || !is_numeric($fv)) {
return Functions::VALUE();
} elseif ($rate <= 0.0 || $pv <= 0.0 || $fv <= 0.0) {
return Functions::NAN();
}
return (log($fv) - log($pv)) / log(1 + $rate);
}
/**
* 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)
{
$rate = Functions::flattenSingleValue($rate);
$nper = Functions::flattenSingleValue($nper);
$pv = Functions::flattenSingleValue($pv);
$fv = Functions::flattenSingleValue($fv);
$type = Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
// Calculate
if ($rate !== null && $rate != 0) {
return (-$fv - $pv * pow(1 + $rate, $nper)) / (1 + $rate * $type) / ((pow(1 + $rate, $nper) - 1) / $rate);
}
return (-$pv - $fv) / $nper;
}
/**
* 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)
{
$rate = Functions::flattenSingleValue($rate);
$per = (int) Functions::flattenSingleValue($per);
$nper = (int) Functions::flattenSingleValue($nper);
$pv = Functions::flattenSingleValue($pv);
$fv = Functions::flattenSingleValue($fv);
$type = (int) Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
if ($per <= 0 || $per > $nper) {
return Functions::VALUE();
}
// Calculate
$interestAndPrincipal = self::interestAndPrincipal($rate, $per, $nper, $pv, $fv, $type);
return $interestAndPrincipal[1];
}
public static function PRICE($settlement, $maturity, $rate, $yield, $redemption, $frequency, $basis = 0)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$rate = (float) Functions::flattenSingleValue($rate);
$yield = (float) Functions::flattenSingleValue($yield);
$redemption = (float) Functions::flattenSingleValue($redemption);
$frequency = (int) Functions::flattenSingleValue($frequency);
$basis = ($basis === null) ? 0 : (int) Functions::flattenSingleValue($basis);
if (is_string($settlement = DateTime::getDateValue($settlement))) {
return Functions::VALUE();
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (($settlement > $maturity) ||
(!self::isValidFrequency($frequency)) ||
(($basis < 0) || ($basis > 4))) {
return 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;
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$discount = (float) Functions::flattenSingleValue($discount);
$redemption = (float) Functions::flattenSingleValue($redemption);
$basis = (int) Functions::flattenSingleValue($basis);
// Validate
if ((is_numeric($discount)) && (is_numeric($redemption)) && (is_numeric($basis))) {
if (($discount <= 0) || ($redemption <= 0)) {
return Functions::NAN();
}
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity, $basis);
if (!is_numeric($daysBetweenSettlementAndMaturity)) {
// return date error
return $daysBetweenSettlementAndMaturity;
}
return $redemption * (1 - $discount * $daysBetweenSettlementAndMaturity);
}
return Functions::VALUE();
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$issue = Functions::flattenSingleValue($issue);
$rate = Functions::flattenSingleValue($rate);
$yield = Functions::flattenSingleValue($yield);
$basis = (int) Functions::flattenSingleValue($basis);
// Validate
if (is_numeric($rate) && is_numeric($yield)) {
if (($rate <= 0) || ($yield <= 0)) {
return Functions::NAN();
}
$daysPerYear = self::daysPerYear(DateTime::YEAR($settlement), $basis);
if (!is_numeric($daysPerYear)) {
return $daysPerYear;
}
$daysBetweenIssueAndSettlement = DateTime::YEARFRAC($issue, $settlement, $basis);
if (!is_numeric($daysBetweenIssueAndSettlement)) {
// return date error
return $daysBetweenIssueAndSettlement;
}
$daysBetweenIssueAndSettlement *= $daysPerYear;
$daysBetweenIssueAndMaturity = DateTime::YEARFRAC($issue, $maturity, $basis);
if (!is_numeric($daysBetweenIssueAndMaturity)) {
// return date error
return $daysBetweenIssueAndMaturity;
}
$daysBetweenIssueAndMaturity *= $daysPerYear;
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($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 Functions::VALUE();
}
/**
* 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)
{
$rate = Functions::flattenSingleValue($rate);
$nper = Functions::flattenSingleValue($nper);
$pmt = Functions::flattenSingleValue($pmt);
$fv = Functions::flattenSingleValue($fv);
$type = Functions::flattenSingleValue($type);
// Validate parameters
if ($type != 0 && $type != 1) {
return Functions::NAN();
}
// Calculate
if ($rate !== null && $rate != 0) {
return (-$pmt * (1 + $rate * $type) * ((pow(1 + $rate, $nper) - 1) / $rate) - $fv) / pow(1 + $rate, $nper);
}
return -$fv - $pmt * $nper;
}
/**
* RATE.
*
* Returns the interest rate per period of an annuity.
* RATE is calculated by iteration and can have zero or more solutions.
* If the successive results of RATE do not converge to within 0.0000001 after 20 iterations,
* RATE returns the #NUM! error value.
*
* Excel Function:
* RATE(nper,pmt,pv[,fv[,type[,guess]]])
*
* @category Financial Functions
*
* @param float $nper The total number of payment periods in an annuity
* @param float $pmt The payment made each period and cannot change over the life
* of the annuity.
* Typically, pmt includes principal and interest but no other
* fees or taxes.
* @param float $pv The present value - the total amount that a series of future
* payments is worth now
* @param float $fv The future value, or a cash balance you want to attain after
* the last payment is made. If fv is omitted, it is assumed
* to be 0 (the future value of a loan, for example, is 0).
* @param int $type A number 0 or 1 and indicates when payments are due:
* 0 or omitted At the end of the period.
* 1 At the beginning of the period.
* @param float $guess Your guess for what the rate will be.
* If you omit guess, it is assumed to be 10 percent.
*
* @return float
*/
public static function RATE($nper, $pmt, $pv, $fv = 0.0, $type = 0, $guess = 0.1)
{
$nper = (int) Functions::flattenSingleValue($nper);
$pmt = Functions::flattenSingleValue($pmt);
$pv = Functions::flattenSingleValue($pv);
$fv = ($fv === null) ? 0.0 : Functions::flattenSingleValue($fv);
$type = ($type === null) ? 0 : (int) Functions::flattenSingleValue($type);
$guess = ($guess === null) ? 0.1 : Functions::flattenSingleValue($guess);
$rate = $guess;
if (abs($rate) < self::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 - $y1) > self::FINANCIAL_PRECISION) && ($i < self::FINANCIAL_MAX_ITERATIONS)) {
$rate = ($y1 * $x0 - $y0 * $x1) / ($y1 - $y0);
$x0 = $x1;
$x1 = $rate;
if (($nper * abs($pmt)) > ($pv - $fv)) {
$x1 = abs($x1);
}
if (abs($rate) < self::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;
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$investment = (float) Functions::flattenSingleValue($investment);
$discount = (float) Functions::flattenSingleValue($discount);
$basis = (int) Functions::flattenSingleValue($basis);
// Validate
if ((is_numeric($investment)) && (is_numeric($discount)) && (is_numeric($basis))) {
if (($investment <= 0) || ($discount <= 0)) {
return Functions::NAN();
}
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity, $basis);
if (!is_numeric($daysBetweenSettlementAndMaturity)) {
// return date error
return $daysBetweenSettlementAndMaturity;
}
return $investment / (1 - ($discount * $daysBetweenSettlementAndMaturity));
}
return Functions::VALUE();
}
/**
* RRI.
*
* Calculates the interest rate required for an investment to grow to a specified future value .
*
* @param float $nper The number of periods over which the investment is made
* @param float $pv Present Value
* @param float $fv Future Value
*
* @return float|string
*/
public static function RRI($nper = 0, $pv = 0, $fv = 0)
{
$nper = Functions::flattenSingleValue($nper);
$pv = Functions::flattenSingleValue($pv);
$fv = Functions::flattenSingleValue($fv);
// Validate parameters
if (!is_numeric($nper) || !is_numeric($pv) || !is_numeric($fv)) {
return Functions::VALUE();
} elseif ($nper <= 0.0 || $pv <= 0.0 || $fv < 0.0) {
return Functions::NAN();
}
return pow($fv / $pv, 1 / $nper) - 1;
}
/**
* SLN.
*
* Returns the straight-line depreciation of an asset for one period
*
* @param mixed $cost Initial cost of the asset
* @param mixed $salvage Value at the end of the depreciation
* @param mixed $life Number of periods over which the asset is depreciated
*
* @return float|string
*/
public static function SLN($cost, $salvage, $life)
{
$cost = Functions::flattenSingleValue($cost);
$salvage = Functions::flattenSingleValue($salvage);
$life = Functions::flattenSingleValue($life);
// Calculate
if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life))) {
if ($life < 0) {
return Functions::NAN();
}
return ($cost - $salvage) / $life;
}
return Functions::VALUE();
}
/**
* SYD.
*
* Returns the sum-of-years' digits depreciation of an asset for a specified period.
*
* @param mixed $cost Initial cost of the asset
* @param mixed $salvage Value at the end of the depreciation
* @param mixed $life Number of periods over which the asset is depreciated
* @param mixed $period Period
*
* @return float|string
*/
public static function SYD($cost, $salvage, $life, $period)
{
$cost = Functions::flattenSingleValue($cost);
$salvage = Functions::flattenSingleValue($salvage);
$life = Functions::flattenSingleValue($life);
$period = Functions::flattenSingleValue($period);
// Calculate
if ((is_numeric($cost)) && (is_numeric($salvage)) && (is_numeric($life)) && (is_numeric($period))) {
if (($life < 1) || ($period > $life)) {
return Functions::NAN();
}
return (($cost - $salvage) * ($life - $period + 1) * 2) / ($life * ($life + 1));
}
return Functions::VALUE();
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$discount = Functions::flattenSingleValue($discount);
// Use TBILLPRICE for validation
$testValue = self::TBILLPRICE($settlement, $maturity, $discount);
if (is_string($testValue)) {
return $testValue;
}
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
++$maturity;
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity) * 360;
} else {
$daysBetweenSettlementAndMaturity = (DateTime::getDateValue($maturity) - DateTime::getDateValue($settlement));
}
return (365 * $discount) / (360 - $discount * $daysBetweenSettlementAndMaturity);
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$discount = Functions::flattenSingleValue($discount);
if (is_string($maturity = DateTime::getDateValue($maturity))) {
return Functions::VALUE();
}
// Validate
if (is_numeric($discount)) {
if ($discount <= 0) {
return Functions::NAN();
}
if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
++$maturity;
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity) * 360;
if (!is_numeric($daysBetweenSettlementAndMaturity)) {
// return date error
return $daysBetweenSettlementAndMaturity;
}
} else {
$daysBetweenSettlementAndMaturity = (DateTime::getDateValue($maturity) - DateTime::getDateValue($settlement));
}
if ($daysBetweenSettlementAndMaturity > 360) {
return Functions::NAN();
}
$price = 100 * (1 - (($discount * $daysBetweenSettlementAndMaturity) / 360));
if ($price <= 0) {
return Functions::NAN();
}
return $price;
}
return Functions::VALUE();
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$price = Functions::flattenSingleValue($price);
// Validate
if (is_numeric($price)) {
if ($price <= 0) {
return Functions::NAN();
}
if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
++$maturity;
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity) * 360;
if (!is_numeric($daysBetweenSettlementAndMaturity)) {
// return date error
return $daysBetweenSettlementAndMaturity;
}
} else {
$daysBetweenSettlementAndMaturity = (DateTime::getDateValue($maturity) - DateTime::getDateValue($settlement));
}
if ($daysBetweenSettlementAndMaturity > 360) {
return Functions::NAN();
}
return ((100 - $price) / $price) * (360 / $daysBetweenSettlementAndMaturity);
}
return Functions::VALUE();
}
public static function XIRR($values, $dates, $guess = 0.1)
{
if ((!is_array($values)) && (!is_array($dates))) {
return Functions::VALUE();
}
$values = Functions::flattenArray($values);
$dates = Functions::flattenArray($dates);
$guess = Functions::flattenSingleValue($guess);
if (count($values) != count($dates)) {
return 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; $i < self::FINANCIAL_MAX_ITERATIONS; ++$i) {
if (($f1 * $f2) < 0.0) {
break;
} elseif (abs($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 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; $i < self::FINANCIAL_MAX_ITERATIONS; ++$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) < self::FINANCIAL_PRECISION) || (abs($dx) < self::FINANCIAL_PRECISION)) {
return $x_mid;
}
}
return 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)
{
$rate = Functions::flattenSingleValue($rate);
if (!is_numeric($rate)) {
return Functions::VALUE();
}
if ((!is_array($values)) || (!is_array($dates))) {
return Functions::VALUE();
}
$values = Functions::flattenArray($values);
$dates = Functions::flattenArray($dates);
$valCount = count($values);
if ($valCount != count($dates)) {
return Functions::NAN();
}
if ((min($values) > 0) || (max($values) < 0)) {
return Functions::VALUE();
}
$xnpv = 0.0;
for ($i = 0; $i < $valCount; ++$i) {
if (!is_numeric($values[$i])) {
return Functions::VALUE();
}
$xnpv += $values[$i] / pow(1 + $rate, DateTime::DATEDIF($dates[0], $dates[$i], 'd') / 365);
}
return (is_finite($xnpv)) ? $xnpv : Functions::VALUE();
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$price = Functions::flattenSingleValue($price);
$redemption = Functions::flattenSingleValue($redemption);
$basis = (int) Functions::flattenSingleValue($basis);
// Validate
if (is_numeric($price) && is_numeric($redemption)) {
if (($price <= 0) || ($redemption <= 0)) {
return Functions::NAN();
}
$daysPerYear = self::daysPerYear(DateTime::YEAR($settlement), $basis);
if (!is_numeric($daysPerYear)) {
return $daysPerYear;
}
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($settlement, $maturity, $basis);
if (!is_numeric($daysBetweenSettlementAndMaturity)) {
// return date error
return $daysBetweenSettlementAndMaturity;
}
$daysBetweenSettlementAndMaturity *= $daysPerYear;
return (($redemption - $price) / $price) * ($daysPerYear / $daysBetweenSettlementAndMaturity);
}
return Functions::VALUE();
}
/**
* 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)
{
$settlement = Functions::flattenSingleValue($settlement);
$maturity = Functions::flattenSingleValue($maturity);
$issue = Functions::flattenSingleValue($issue);
$rate = Functions::flattenSingleValue($rate);
$price = Functions::flattenSingleValue($price);
$basis = (int) Functions::flattenSingleValue($basis);
// Validate
if (is_numeric($rate) && is_numeric($price)) {
if (($rate <= 0) || ($price <= 0)) {
return Functions::NAN();
}
$daysPerYear = self::daysPerYear(DateTime::YEAR($settlement), $basis);
if (!is_numeric($daysPerYear)) {
return $daysPerYear;
}
$daysBetweenIssueAndSettlement = DateTime::YEARFRAC($issue, $settlement, $basis);
if (!is_numeric($daysBetweenIssueAndSettlement)) {
// return date error
return $daysBetweenIssueAndSettlement;
}
$daysBetweenIssueAndSettlement *= $daysPerYear;
$daysBetweenIssueAndMaturity = DateTime::YEARFRAC($issue, $maturity, $basis);
if (!is_numeric($daysBetweenIssueAndMaturity)) {
// return date error
return $daysBetweenIssueAndMaturity;
}
$daysBetweenIssueAndMaturity *= $daysPerYear;
$daysBetweenSettlementAndMaturity = DateTime::YEARFRAC($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 Functions::VALUE();
}
}