Litipk\BigNumbers\Decimal

Complexity

Total Complexity

200

Size/Duplication

Total Lines	1326
Duplicated Lines	0 %

Coupling/Cohesion

Components	1
Dependencies	4

Test Coverage

Coverage

96.96%

Importance

Changes	72
Bugs	12	Features	25

58 Methods

Rating	Name	Duplication	Size	Complexity
A	__clone()	0	4	1
A	getPositiveInfinite()	0	4	1
A	getNegativeInfinite()	0	4	1
A	fromDecimal()	0	14	4
A	sqrt()	0	17	4
A	log10()	0	15	4
A	isPositive()	0	4	2
A	isNegative()	0	4	1
A	isInteger()	0	4	1
A	isInfinite()	0	4	1
A	comp()	0	18	4
A	sin()	0	19	4
A	cos()	0	19	4
A	__construct()	0	5	1
B	create()	0	18	6
A	fromInteger()	0	14	3
C	fromFloat()	0	46	11
C	fromString()	0	58	13
A	add()	0	13	2
A	sub()	0	13	2
A	mul()	0	15	3
B	div()	0	35	5
C	pow()	0	62	11
A	isZero()	0	6	2
A	equals()	0	20	4
A	additiveInverse()	0	12	3
A	round()	0	8	2
A	ceil()	0	12	3
B	innerTruncate()	0	23	5
A	floor()	0	12	3
A	abs()	0	8	3
A	mod()	0	5	1
A	cosec()	0	11	2
A	sec()	0	11	2
C	arcsin()	0	26	7
C	arccos()	0	30	7
B	arctan()	0	22	5
B	arccot()	0	24	5
A	exp()	0	15	4
A	factorialSerie()	0	23	3
B	powerSerie()	0	40	5
B	simplePowerSerie()	0	29	5
A	tan()	0	10	2
A	cotan()	0	11	2
A	hasSameSign()	0	4	4
A	asFloat()	0	4	1
A	asInteger()	0	4	1
A	innerValue()	0	4	1
A	__toString()	0	4	1
A	innerRound()	0	17	4
B	innerLog10()	0	36	4
A	innerPowWithLittleExponent()	0	23	3
A	computeSquareIndex()	0	13	2
A	compute2NRoot()	0	10	2
B	paramsValidation()	0	10	5
A	normalizeSign()	0	8	2
A	removeTrailingZeros()	0	12	3
A	countSignificativeDigits()	0	6	3

<?php

namespace Litipk\BigNumbers;

use Litipk\BigNumbers\DecimalConstants as DecimalConstants;
use Litipk\BigNumbers\InfiniteDecimal as InfiniteDecimal;

use Litipk\Exceptions\NotImplementedException as NotImplementedException;
use Litipk\Exceptions\InvalidArgumentTypeException as InvalidArgumentTypeException;

/**
 * Immutable object that represents a rational number
 *
 * @author Andreu Correa Casablanca <castarco@litipk.com>
 */
class Decimal
{
    /**
     * Internal numeric value
     * @var string
     */
    protected $value;

    /**
     * Number of digits behind the point
     * @var integer
     */
    private $scale;

    /**
     * Private constructor
     * @param integer $scale
     * @param string $value
     */
    private function __construct($value, $scale)
    {
        $this->value = $value;
        $this->scale = $scale;
    }

    /**
     * Private clone method
     */
    private function __clone()
    {

    }

    /**
     * Returns a "Positive Infinite" object
     * @return Decimal
     */
    public static function getPositiveInfinite()
    {
        return InfiniteDecimal::getPositiveInfinite();
    }

    /**
     * Returns a "Negative Infinite" object
     * @return Decimal
     */
    public static function getNegativeInfinite()
    {
        return InfiniteDecimal::getNegativeInfinite();
    }

    /**
     * Decimal "constructor".
     *
     * @param  mixed   $value
     * @param  integer $scale
     * @param  boolean $removeZeros If true then removes trailing zeros from the number representation
     * @return Decimal
     */
    public static function create($value, $scale = null, $removeZeros = false)
    {
        if (is_int($value)) {
            return self::fromInteger($value);
        } elseif (is_float($value)) {
            return self::fromFloat($value, $scale, $removeZeros);
        } elseif (is_string($value)) {
            return self::fromString($value, $scale, $removeZeros);
        } elseif ($value instanceof Decimal) {
            return self::fromDecimal($value, $scale);
        } else {
            throw new InvalidArgumentTypeException(
                ['int', 'float', 'string', 'Decimal'],
                is_object($value) ? get_class($value) : gettype($value),
                'Invalid argument type.'
            );
        }
    }

    /**
     * @param  integer $intValue
     * @return Decimal
     */
    public static function fromInteger($intValue)
    {
        self::paramsValidation($intValue, null);

        if (!is_int($intValue)) {
            throw new InvalidArgumentTypeException(
                ['int'],
                is_object($intValue) ? get_class($intValue) : gettype($intValue),
                '$intValue must be of type int'
            );
        }

        return new static((string)$intValue, 0);
    }

    /**
     * @param  float   $fltValue
     * @param  integer $scale
     * @param  boolean $removeZeros If true then removes trailing zeros from the number representation
     * @return Decimal
     */
    public static function fromFloat($fltValue, $scale = null, $removeZeros = false)
    {
        self::paramsValidation($fltValue, $scale);

        if (!is_float($fltValue)) {
            throw new InvalidArgumentTypeException(
                ['float'],
                is_object($fltValue) ?
                    get_class($fltValue) :
                    gettype($fltValue),
                '$fltValue must be of type float'
            );
        } elseif ($fltValue === INF) {
            return InfiniteDecimal::getPositiveInfinite();
        } elseif ($fltValue === -INF) {
            return InfiniteDecimal::getNegativeInfinite();
        } elseif (is_nan($fltValue)) {
            throw new \DomainException(
                "To ensure consistency, this class doesn't handle NaN objects."
            );
        }

        $defaultScale = 16;

        $strValue = (string) $fltValue;
        if (preg_match("/^ (?P<int> \d*) (?: \. (?P<dec> \d+) ) E (?P<sign>[\+\-]) (?P<exp>\d+) $/x", $strValue, $capture)) {
            if ($scale === null) {
                if ($capture['sign'] == '-') {
                    $scale = $capture['exp'] + strlen($capture['dec']);
                } else {
                    $scale = $defaultScale;
                }
            }
            $strValue = number_format($fltValue, $scale, '.', '');
        }

        if ($scale === null) {
            $scale = $defaultScale;
        }

        if ($removeZeros) {
            $strValue = self::removeTrailingZeros($strValue, $scale);
        }

        return new static($strValue, $scale);
    }

    /**
     * @param  string  $strValue
     * @param  integer $scale
     * @param  boolean $removeZeros If true then removes trailing zeros from the number representation
     * @return Decimal
     */
    public static function fromString($strValue, $scale = null, $removeZeros = false)
    {
        self::paramsValidation($strValue, $scale);

        if (!is_string($strValue)) {
            throw new InvalidArgumentTypeException(
                ['string'],
                is_object($strValue) ? get_class($strValue) : gettype($strValue),
                '$strVlue must be of type string.'
            );
        } elseif (preg_match('/^([+\-]?)0*(([1-9][0-9]*|[0-9])(\.[0-9]+)?)$/', $strValue, $captures) === 1) {

            // Now it's time to strip leading zeros in order to normalize inner values
            $value = self::normalizeSign($captures[1]) . $captures[2];
            $min_scale = isset($captures[4]) ? max(0, strlen($captures[4]) - 1) : 0;

        } elseif (preg_match('/([+\-]?)0*([0-9](\.[0-9]+)?)[eE]([+\-]?)(\d+)/', $strValue, $captures) === 1) {

            $mantissa_scale = max(strlen($captures[3]) - 1, 0);

            $exp_val = (int)$captures[5];

            if (self::normalizeSign($captures[4]) === '') {
                $min_scale = max($mantissa_scale - $exp_val, 0);
                $tmp_multiplier = bcpow(10, $exp_val);
            } else {
                $min_scale = $mantissa_scale + $exp_val;
                $tmp_multiplier = bcpow(10, -$exp_val, $exp_val);
            }

            $value = self::normalizeSign($captures[1]) . bcmul(
                $captures[2],
                $tmp_multiplier,
                max($min_scale, $scale !== null ? $scale : 0)
            );

        } else if (preg_match('/([+\-]?)(inf|Inf|INF)/', $strValue, $captures) === 1) {
            if ($captures[1] === '-') {
                return InfiniteDecimal::getNegativeInfinite();
            } else {
                return InfiniteDecimal::getPositiveInfinite();
            }
        } else {
            throw new \InvalidArgumentException(
                '$strValue must be a string that represents uniquely a float point number.'
            );
        }

        $scale = ($scale!==null) ? $scale : $min_scale;
        if ($scale < $min_scale) {
            $value = self::innerRound($value, $scale);
        }
        if ($removeZeros) {
            $value = self::removeTrailingZeros($value, $scale);
        }

        return new static($value, $scale);
    }

    /**
     * Constructs a new Decimal object based on a previous one,
     * but changing it's $scale property.
     *
     * @param  Decimal  $decValue
     * @param  integer  $scale
     * @return Decimal
     */
    public static function fromDecimal(Decimal $decValue, $scale = null)
    {
        self::paramsValidation($decValue, $scale);

        // This block protect us from unnecessary additional instances
        if ($scale === null || $scale >= $decValue->scale || $decValue->isInfinite()) {
            return $decValue;
        }

        return new static(
            self::innerRound($decValue->value, $scale),
            $scale
        );
    }

    /**
     * Adds two Decimal objects
     * @param  Decimal $b
     * @param  integer $scale
     * @return Decimal
     */
    public function add(Decimal $b, $scale = null)
    {
        self::paramsValidation($b, $scale);

        if ($b->isInfinite()) {
            return $b;
        }

        return self::fromString(
            bcadd($this->value, $b->value, max($this->scale, $b->scale)),
            $scale
        );
    }

    /**
     * Subtracts two BigNumber objects
     * @param  Decimal $b
     * @param  integer $scale
     * @return Decimal
     */
    public function sub(Decimal $b, $scale = null)
    {
        self::paramsValidation($b, $scale);

        if ($b->isInfinite()) {
            return $b->additiveInverse();
        }

        return self::fromString(
            bcsub($this->value, $b->value, max($this->scale, $b->scale)),
            $scale
        );
    }

    /**
     * Multiplies two BigNumber objects
     * @param  Decimal $b
     * @param  integer $scale
     * @return Decimal
     */
    public function mul(Decimal $b, $scale = null)
    {
        self::paramsValidation($b, $scale);

        if ($b->isInfinite()) {
            return $b->mul($this);
        } elseif ($b->isZero()) {
            return DecimalConstants::Zero();
        }

        return self::fromString(
            bcmul($this->value, $b->value, $this->scale + $b->scale),
            $scale
        );
    }

    /**
     * Divides the object by $b .
     * Warning: div with $scale == 0 is not the same as
     *          integer division because it rounds the
     *          last digit in order to minimize the error.
     *
     * @param  Decimal $b
     * @param  integer $scale
     * @return Decimal
     */
    public function div(Decimal $b, $scale = null)
    {
        self::paramsValidation($b, $scale);

        if ($b->isZero()) {
            throw new \DomainException("Division by zero is not allowed.");
        } elseif ($this->isZero() || $b->isInfinite()) {
            return DecimalConstants::Zero();
        } else {
            if ($scale !== null) {
                $divscale = $scale;
            } else {
                // $divscale is calculated in order to maintain a reasonable precision
                $this_abs = $this->abs();
                $b_abs    = $b->abs();

                $log10_result =
                    self::innerLog10($this_abs->value, $this_abs->scale, 1) -
                    self::innerLog10($b_abs->value, $b_abs->scale, 1);

                $divscale = (int)max(
                    $this->scale + $b->scale,
                    max(
                        self::countSignificativeDigits($this, $this_abs),
                        self::countSignificativeDigits($b, $b_abs)
                    ) - max(ceil($log10_result), 0),
                    ceil(-$log10_result) + 1
                );
            }

            return self::fromString(
                bcdiv($this->value, $b->value, $divscale+1), $divscale
            );
        }
    }

    /**
     * Returns the square root of this object
     * @param  integer $scale
     * @return Decimal
     */
    public function sqrt($scale = null)
    {
        if ($this->isNegative()) {
            throw new \DomainException(
                "Decimal can't handle square roots of negative numbers (it's only for real numbers)."
            );
        } elseif ($this->isZero()) {
            return DecimalConstants::Zero();
        }

        $sqrt_scale = ($scale !== null ? $scale : $this->scale);

        return self::fromString(
            bcsqrt($this->value, $sqrt_scale+1),
            $sqrt_scale
        );
    }

    /**
     * Powers this value to $b
     *
     * @param  Decimal  $b      exponent
     * @param  integer  $scale
     * @return Decimal
     */
    public function pow(Decimal $b, $scale = null)
    {
        if ($this->isZero()) {
            if ($b->isPositive()) {
                return Decimal::fromDecimal($this, $scale);
            } else {
                throw new \DomainException(
                    "zero can't be powered to zero or negative numbers."
                );
            }
        } elseif ($b->isZero()) {
            return DecimalConstants::One();
        } else if ($b->isNegative()) {
            return DecimalConstants::One()->div(
                $this->pow($b->additiveInverse()), $scale
            );
        } elseif ($b->scale == 0) {
            $pow_scale = $scale === null ?
                max($this->scale, $b->scale) : max($this->scale, $b->scale, $scale);

            return self::fromString(
                bcpow($this->value, $b->value, $pow_scale+1),
                $pow_scale
            );
        } else {
            if ($this->isPositive()) {
                $pow_scale = $scale === null ?
                    max($this->scale, $b->scale) : max($this->scale, $b->scale, $scale);

                $truncated_b = bcadd($b->value, '0', 0);
                $remaining_b = bcsub($b->value, $truncated_b, $b->scale);

                $first_pow_approx = bcpow($this->value, $truncated_b, $pow_scale+1);
                $intermediate_root = self::innerPowWithLittleExponent(
                    $this->value,
                    $remaining_b,
                    $b->scale,
                    $pow_scale+1
                );

                return Decimal::fromString(
                    bcmul($first_pow_approx, $intermediate_root, $pow_scale+1),
                    $pow_scale
                );
            } else { // elseif ($this->isNegative())
                if ($b->isInteger()) {
                    if (preg_match('/^[+\-]?[0-9]*[02468](\.0+)?$/', $b->value, $captures) === 1) {
                        // $b is an even number
                        return $this->additiveInverse()->pow($b, $scale);
                    } else {
                        // $b is an odd number
                        return $this->additiveInverse()->pow($b, $scale)->additiveInverse();
                    }
                }

                throw new NotImplementedException(
                    "Usually negative numbers can't be powered to non integer numbers. " .
                    "The cases where is possible are not implemented."
                );
            }
        }
    }

    /**
     * Returns the object's logarithm in base 10
     * @param  integer $scale
     * @return Decimal
     */
    public function log10($scale = null)
    {
        if ($this->isNegative()) {
            throw new \DomainException(
                "Decimal can't handle logarithms of negative numbers (it's only for real numbers)."
            );
        } elseif ($this->isZero()) {
            return InfiniteDecimal::getNegativeInfinite();
        }

        return self::fromString(
            self::innerLog10($this->value, $this->scale, $scale !== null ? $scale+1 : $this->scale+1),
            $scale
        );
    }

    /**
     * @param  integer $scale
     * @return boolean
     */
    public function isZero($scale = null)
    {
        $cmp_scale = $scale !== null ? $scale : $this->scale;

        return (bccomp(self::innerRound($this->value, $cmp_scale), '0', $cmp_scale) === 0);
    }

    /**
     * @return boolean
     */
    public function isPositive()
    {
        return ($this->value[0] !== '-' && !$this->isZero());
    }

    /**
     * @return boolean
     */
    public function isNegative()
    {
        return ($this->value[0] === '-');
    }

    /**
     * @return boolean
     */
    public function isInteger()
    {
        return (preg_match('/^[+\-]?[0-9]+(\.0+)?$/', $this->value, $captures) === 1);
    }

    /**
     * @return boolean
     */
    public function isInfinite()
    {
        return false;
    }

    /**
     * Equality comparison between this object and $b
     * @param  Decimal $b
     * @param integer $scale
     * @return boolean
     */
    public function equals(Decimal $b, $scale = null)
    {
        self::paramsValidation($b, $scale);

        if ($this === $b) {
            return true;
        } elseif ($b->isInfinite()) {
            return false;
        } else {
            $cmp_scale = $scale !== null ? $scale : max($this->scale, $b->scale);

            return (
                bccomp(
                    self::innerRound($this->value, $cmp_scale),
                    self::innerRound($b->value, $cmp_scale),
                    $cmp_scale
                ) == 0
            );
        }
    }

    /**
     * $this > $b : returns 1 , $this < $b : returns -1 , $this == $b : returns 0
     *
     * @param  Decimal $b
     * @param  integer $scale
     * @return integer
     */
    public function comp(Decimal $b, $scale = null)
    {
        self::paramsValidation($b, $scale);

        if ($this === $b) {
            return 0;
        } elseif ($b->isInfinite()) {
            return -$b->comp($this);
        }

        $cmp_scale = $scale !== null ? $scale : max($this->scale, $b->scale);

        return bccomp(
            self::innerRound($this->value, $cmp_scale),
            self::innerRound($b->value, $cmp_scale),
            $cmp_scale
        );
    }

    /**
     * Returns the element's additive inverse.
     * @return Decimal
     */
    public function additiveInverse()
    {
        if ($this->isZero()) {
            return $this;
        } elseif ($this->isNegative()) {
            $value = substr($this->value, 1);
        } else { // if ($this->isPositive()) {
            $value = '-' . $this->value;
        }

        return new static($value, $this->scale);
    }


    /**
     * "Rounds" the Decimal to have at most $scale digits after the point
     * @param  integer $scale
     * @return Decimal
     */
    public function round($scale = 0)
    {
        if ($scale >= $this->scale) {
            return $this;
        }

        return self::fromString(self::innerRound($this->value, $scale));
    }

    /**
     * "Ceils" the Decimal to have at most $scale digits after the point
     * @param  integer $scale
     * @return Decimal
     */
    public function ceil($scale = 0)
    {
        if ($scale >= $this->scale) {
            return $this;
        }

        if ($this->isNegative()) {
            return self::fromString(bcadd($this->value, '0', $scale));
        }

        return $this->innerTruncate($scale);
    }

    private function innerTruncate($scale = 0, $ceil = true)
    {
        $rounded = bcadd($this->value, '0', $scale);

        $rlen = strlen($rounded);
        $tlen = strlen($this->value);

        $mustTruncate = false;
        for ($i=$tlen-1; $i >= $rlen; $i--) {
            if ((int)$this->value[$i] > 0) {
                $mustTruncate = true;
                break;
            }
        }

        if ($mustTruncate) {
            $rounded = $ceil ?
                bcadd($rounded, bcpow('10', -$scale, $scale), $scale) :
                bcsub($rounded, bcpow('10', -$scale, $scale), $scale);
        }

        return self::fromString($rounded, $scale);
    }

    /**
     * "Floors" the Decimal to have at most $scale digits after the point
     * @param  integer $scale
     * @return Decimal
     */
    public function floor($scale = 0)
    {
        if ($scale >= $this->scale) {
            return $this;
        }

        if ($this->isNegative()) {
            return $this->innerTruncate($scale, false);
        }

        return self::fromString(bcadd($this->value, '0', $scale));
    }

    /**
     * Returns the absolute value (always a positive number)
     * @return Decimal
     */
    public function abs()
    {
        if ($this->isZero() || $this->isPositive()) {
            return $this;
        }

        return $this->additiveInverse();
    }

    /**
     * Calculate modulo with a decimal
     * @param Decimal $d
     * @param integer $scale
     * @return $this % $d
     */
    public function mod(Decimal $d, $scale = null)
    {
        $div = $this->div($d, 1)->floor();
        return $this->sub($div->mul($d), $scale);
    }

    /**
     * Calculates the sine of this method with the highest possible accuracy
     * Note that accuracy is limited by the accuracy of predefined PI;
     *
     * @param integer $scale
     * @return Decimal sin($this)
     */
    public function sin($scale = null)
    {
        // First normalise the number in the [0, 2PI] domain
        $x = $this->mod(DecimalConstants::PI()->mul(Decimal::fromString("2")));

        // PI has only 32 significant numbers
        $scale = ($scale === null) ? 32 : $scale;

        return self::factorialSerie(
            $x,
            DecimalConstants::zero(),
            function ($i) {
                return ($i % 2 === 1) ? (
                ($i % 4 === 1) ? DecimalConstants::one() : DecimalConstants::negativeOne()
                ) : DecimalConstants::zero();
            },
            $scale
        );
    }

    /**
     * Calculates the cosecant of this with the highest possible accuracy
     * Note that accuracy is limited by the accuracy of predefined PI;
     *
     * @param integer $scale
     * @return Decimal
     */
    public function cosec($scale = null)
    {
        $sin = $this->sin($scale + 2);
        if ($sin->isZero()) {
            throw new \DomainException(
                "The cosecant of this 'angle' is undefined."
            );
        }

        return DecimalConstants::one()->div($sin)->round($scale);
    }

    /**
     * Calculates the cosine of this method with the highest possible accuracy
     * Note that accuracy is limited by the accuracy of predefined PI;
     *
     * @param integer $scale
     * @return Decimal cos($this)
     */
    public function cos($scale = null)
    {
        // First normalise the number in the [0, 2PI] domain
        $x = $this->mod(DecimalConstants::PI()->mul(Decimal::fromString("2")));

        // PI has only 32 significant numbers
        $scale = ($scale === null) ? 32 : $scale;

        return self::factorialSerie(
            $x,
            DecimalConstants::one(),
            function ($i) {
                return ($i % 2 === 0) ? (
                    ($i % 4 === 0) ? DecimalConstants::one() : DecimalConstants::negativeOne()
                ) : DecimalConstants::zero();
            },
            $scale
        );
    }

    /**
     * Calculates the secant of this with the highest possible accuracy
     * Note that accuracy is limited by the accuracy of predefined PI;
     *
     * @param integer $scale
     * @return Decimal
     */
    public function sec($scale = null)
    {
        $cos = $this->cos($scale + 2);
        if ($cos->isZero()) {
            throw new \DomainException(
                "The secant of this 'angle' is undefined."
            );
        }

        return DecimalConstants::one()->div($cos)->round($scale);
    }

    /**
     *	Calculates the arcsine of this with the highest possible accuracy
     *
     * @param integer $scale
     * @return Decimal
     */
    public function arcsin($scale = null)
    {
        if($this->comp(DecimalConstants::one(), $scale + 2) === 1 || $this->comp(DecimalConstants::negativeOne(), $scale + 2) === -1) {
            throw new \DomainException(
                "The arcsin of this number is undefined."
            );
        }

        if ($this->round($scale)->isZero()) {
            return DecimalConstants::zero;
        }
        if ($this->round($scale)->equals(DecimalConstants::one())) {
            return DecimalConstants::pi()->div(Decimal::fromInteger(2))->round($scale);
        }
        if ($this->round($scale)->equals(DecimalConstants::negativeOne())) {
            return DecimalConstants::pi()->div(Decimal::fromInteger(-2))->round($scale);
        }

        $scale = ($scale === null) ? 32 : $scale;

        return self::powerSerie(
            $this,
            DecimalConstants::zero(),
            $scale
        );
    }

    /**
     *	Calculates the arccosine of this with the highest possible accuracy
     *
     * @param integer $scale
     * @return Decimal
     */
    public function arccos($scale = null)
    {
        if($this->comp(DecimalConstants::one(), $scale + 2) === 1 || $this->comp(DecimalConstants::negativeOne(), $scale + 2) === -1) {
            throw new \DomainException(
                "The arccos of this number is undefined."
            );
        }

        $piOverTwo = DecimalConstants::pi()->div(Decimal::fromInteger(2), $scale + 2)->round($scale);

        if ($this->round($scale)->isZero()) {
            return $piOverTwo;
        }
        if ($this->round($scale)->equals(DecimalConstants::one())) {
            return DecimalConstants::zero();
        }
        if ($this->round($scale)->equals(DecimalConstants::negativeOne())) {
            return DecimalConstants::pi()->round($scale);
        }

        $scale = ($scale === null) ? 32 : $scale;

        return $piOverTwo->sub(
            self::powerSerie(
                $this,
                DecimalConstants::zero(),
                $scale
            )
        )->round($scale);
    }

    /**
     *	Calculates the arctangente of this with the highest possible accuracy
     *
     * @param integer $scale
     * @return Decimal
     */
    public function arctan($scale = null)
    {
        $piOverFour = DecimalConstants::pi()->div(Decimal::fromInteger(4), $scale + 2)->round($scale);

        if ($this->round($scale)->isZero()) {
            return DecimalConstants::zero();
        }
        if ($this->round($scale)->equals(DecimalConstants::one())) {
            return $piOverFour;
        }
        if ($this->round($scale)->equals(DecimalConstants::negativeOne())) {
            return DecimalConstants::negativeOne()->mul($piOverFour);
        }

        $scale = ($scale === null) ? 32 : $scale;

        return self::simplePowerSerie(
            $this,
            DecimalConstants::zero(),
            $scale + 2
        )->round($scale);
    }

    /**
     * Calculates the arccotangente of this with the highest possible accuracy
     *
     * @param integer $scale
     * @return Decimal
     */
    public function arccot($scale = null) {
        $scale = ($scale === null) ? 32 : $scale;

        $piOverTwo = DecimalConstants::pi()->div(Decimal::fromInteger(2), $scale + 2);
        if ($this->round($scale)->isZero()) {
            return $piOverTwo->round($scale);
        }

        $piOverFour = DecimalConstants::pi()->div(Decimal::fromInteger(4), $scale + 2);
        if ($this->round($scale)->equals(DecimalConstants::one())) {
            return $piOverFour->round($scale);
        }
        if ($this->round($scale)->equals(DecimalConstants::negativeOne())) {
            return DecimalConstants::negativeOne()->mul($piOverFour, $scale + 2)->round($scale);
        }

        return $piOverTwo->sub(
            self::simplePowerSerie(
                $this,
                DecimalConstants::zero(),
                $scale + 2
            )
        )->round($scale);
    }

    /**
     * Returns exp($this), said in other words: e^$this .
     *
     * @param integer $scale
     * @return Decimal
     */
    public function exp($scale = null)
    {
        if ($this->isZero()) {
            return DecimalConstants::one();
        }

        $scale = ($scale === null) ? max(
            $this->scale,
            (int)($this->isNegative() ? self::innerLog10($this->value, $this->scale, 0) : 16)
        ) : $scale;

        return self::factorialSerie(
            $this, DecimalConstants::one(), function ($i) { return DecimalConstants::one(); }, $scale

The parameter $i is not used and could be removed.

        );
    }

    /**
     * Internal method used to compute sin, cos and exp
     *
     * @param Decimal $x
     * @param Decimal $firstTerm
     * @param callable $generalTerm
     * @param $scale
     * @return Decimal
     */
    private static function factorialSerie (Decimal $x, Decimal $firstTerm, callable $generalTerm, $scale)
    {
        $approx = $firstTerm;
        $change = InfiniteDecimal::getPositiveInfinite();

        $faculty = DecimalConstants::One();    // Calculates the faculty under the sign
        $xPowerN = DecimalConstants::One();    // Calculates x^n

        for ($i = 1; !$change->floor($scale+1)->isZero(); $i++) {
            // update x^n and n! for this walkthrough
            $xPowerN = $xPowerN->mul($x);
            $faculty = $faculty->mul(Decimal::fromInteger($i));

            $multiplier = $generalTerm($i);

            if (!$multiplier->isZero()) {
                $change = $multiplier->mul($xPowerN, $scale + 2)->div($faculty, $scale + 2);
                $approx = $approx->add($change, $scale + 2);
            }
        }

        return $approx->round($scale);
    }


    /**
     * Internal method used to compute arcsine and arcosine
     *
     * @param Decimal $x
     * @param Decimal $firstTerm
     * @param $scale
     * @return Decimal
     */
    private static function powerSerie (Decimal $x, Decimal $firstTerm, $scale)
    {
        $approx = $firstTerm;
        $change = InfiniteDecimal::getPositiveInfinite();

        $xPowerN = DecimalConstants::One();     // Calculates x^n
        $factorN = DecimalConstants::One();      // Calculates a_n

$factorN is not used, you could remove the assignment.

        $numerator = DecimalConstants::one();
        $denominator = DecimalConstants::one();

        for ($i = 1; !$change->floor($scale + 2)->isZero(); $i++) {
            $xPowerN = $xPowerN->mul($x);

            if ($i % 2 == 0) {
                $factorN = DecimalConstants::zero();
            } elseif ($i == 1) {
                $factorN = DecimalConstants::one();
            } else {
                $incrementNum = Decimal::fromInteger($i - 2);
                $numerator = $numerator->mul($incrementNum, $scale +2);

                $incrementDen = Decimal::fromInteger($i - 1);
                $increment = Decimal::fromInteger($i);
                $denominator = $denominator
                    ->div($incrementNum, $scale +2)
                    ->mul($incrementDen, $scale +2)
                    ->mul($increment, $scale +2);

                $factorN = $numerator->div($denominator, $scale + 2);
            }

            if (!$factorN->isZero()) {
                $change = $factorN->mul($xPowerN, $scale + 2);
                $approx = $approx->add($change, $scale + 2);
            }
        }

        return $approx->round($scale);
    }

    /**
     * Internal method used to compute arctan and arccotan
     *
     * @param Decimal $x
     * @param Decimal $firstTerm
     * @param $scale
     * @return Decimal
     */
    private static function simplePowerSerie (Decimal $x, Decimal $firstTerm, $scale)
    {
        $approx = $firstTerm;
        $change = InfiniteDecimal::getPositiveInfinite();

        $xPowerN = DecimalConstants::One();     // Calculates x^n
        $sign = DecimalConstants::One();      // Calculates a_n

$sign is not used, you could remove the assignment.

        for ($i = 1; !$change->floor($scale + 2)->isZero(); $i++) {
            $xPowerN = $xPowerN->mul($x);

            if ($i % 2 === 0) {
                $factorN = DecimalConstants::zero();
            } else {
                 if ($i % 4 === 1) {
                     $factorN = DecimalConstants::one()->div(Decimal::fromInteger($i), $scale + 2);
                 } else {
                     $factorN = DecimalConstants::negativeOne()->div(Decimal::fromInteger($i), $scale + 2);
                 }
            }

            if (!$factorN->isZero()) {
                $change = $factorN->mul($xPowerN, $scale + 2);
                $approx = $approx->add($change, $scale + 2);
            }
        }

        return $approx->round($scale);
    }

    /**
     * Calculates the tangent of this method with the highest possible accuracy
     * Note that accuracy is limited by the accuracy of predefined PI;
     *
     * @param integer $scale
     * @return Decimal tan($this)
     */
    public function tan($scale = null) {
	    $cos = $this->cos($scale + 2);
	    if ($cos->isZero()) {
	        throw new \DomainException(
	            "The tangent of this 'angle' is undefined."
	        );
	    }

	    return $this->sin($scale + 2)->div($cos)->round($scale);
    }

    /**
     * Calculates the cotangent of this method with the highest possible accuracy
     * Note that accuracy is limited by the accuracy of predefined PI;
     *
     * @param integer $scale
     * @return Decimal cotan($this)
     */
    public function cotan($scale = null)
    {
	    $sin = $this->sin($scale + 2);
	    if ($sin->isZero()) {
	        throw new \DomainException(
	            "The cotangent of this 'angle' is undefined."
	        );
	    }

	    return $this->cos($scale + 2)->div($sin)->round($scale);
    }

    /**
     * Indicates if the passed parameter has the same sign as the method's bound object.
     *
     * @param Decimal $b
     * @return bool
     */
    public function hasSameSign(Decimal $b)
    {
        return $this->isPositive() && $b->isPositive() || $this->isNegative() && $b->isNegative();
    }

    /**
     * Return value as a float
     *
     * @return float
     */
    public function asFloat()
    {
        return floatval($this->value);
    }

    /**
     * Return value as a integer
     *
     * @return float
     */
    public function asInteger()
    {
        return intval($this->value);
    }

    /**
     * Return the inner representation of the class
     * use with caution
     *
     * @return number
     */
    public function innerValue()
    {
        return $this->value;
    }

    /**
     * @return string
     */
    public function __toString()
    {
        return $this->value;
    }

    /**
     * "Rounds" the decimal string to have at most $scale digits after the point
     *
     * @param  string  $value
     * @param  integer $scale
     * @return string
     */
    private static function innerRound($value, $scale = 0)
    {
        $rounded = bcadd($value, '0', $scale);

        $diffDigit = bcsub($value, $rounded, $scale+1);
        $diffDigit = (int)$diffDigit[strlen($diffDigit)-1];

        if ($diffDigit >= 5) {
            if ($diffDigit >= 5 && $value[0] !== '-') {
                $rounded = bcadd($rounded, bcpow('10', -$scale, $scale), $scale);
            } else {
                $rounded = bcsub($rounded, bcpow('10', -$scale, $scale), $scale);
            }
        }

        return $rounded;
    }

    /**
     * Calculates the logarithm (in base 10) of $value
     *
     * @param  string  $value     The number we want to calculate its logarithm (only positive numbers)
     * @param  integer $in_scale  Expected scale used by $value (only positive numbers)
     * @param  integer $out_scale Scale used by the return value (only positive numbers)
     * @return string
     */
    private static function innerLog10($value, $in_scale, $out_scale)
    {
        $value_len = strlen($value);

        $cmp = bccomp($value, '1', $in_scale);

        switch ($cmp) {
            case 1:
                $value_log10_approx = $value_len - ($in_scale > 0 ? ($in_scale+2) : 1);

                return bcadd(
                    $value_log10_approx,
                    log10(bcdiv(
                        $value,
                        bcpow('10', $value_log10_approx),
                        min($value_len, $out_scale)
                    )),
                    $out_scale
                );
            case -1:
                preg_match('/^0*\.(0*)[1-9][0-9]*$/', $value, $captures);
                $value_log10_approx = -strlen($captures[1])-1;

                return bcadd(
                    $value_log10_approx,
                    log10(bcmul(
                        $value,
                        bcpow('10', -$value_log10_approx),
                        $in_scale + $value_log10_approx
                    )),
                    $out_scale
                );
            default: // case 0:
                return '0';
        }
    }

    /**
     * Returns $base^$exponent
     *
     * @param  string $base
     * @param  string $exponent   0 < $exponent < 1
     * @param  integer $exp_scale Number of $exponent's significative digits
     * @param  integer $out_scale Number of significative digits that we want to compute
     * @return string
     */
    private static function innerPowWithLittleExponent($base, $exponent, $exp_scale, $out_scale)
    {
        $inner_scale = ceil($exp_scale*log(10)/log(2))+1;

        $result_a = '1';
        $result_b = '0';

        $actual_index = 0;
        $exponent_remaining = $exponent;

        while (bccomp($result_a, $result_b, $out_scale) !== 0 && bccomp($exponent_remaining, '0', $inner_scale) !== 0) {
            $result_b = $result_a;
            $index_info = self::computeSquareIndex($exponent_remaining, $actual_index, $exp_scale, $inner_scale);
            $exponent_remaining = $index_info[1];
            $result_a = bcmul(
                $result_a,
                self::compute2NRoot($base, $index_info[0], 2*($out_scale+1)),
                2*($out_scale+1)
            );
        }

        return self::innerRound($result_a, $out_scale);
    }

    /**
     * Auxiliar method. It helps us to decompose the exponent into many summands.
     *
     * @param  string  $exponent_remaining
     * @param  integer $actual_index
     * @param  integer $exp_scale           Number of $exponent's significative digits
     * @param  integer $inner_scale         ceil($exp_scale*log(10)/log(2))+1;
     * @return string
     */
    private static function computeSquareIndex($exponent_remaining, $actual_index, $exp_scale, $inner_scale)
    {
        $actual_rt = bcpow('0.5', $actual_index, $exp_scale);
        $r = bcsub($exponent_remaining, $actual_rt, $inner_scale);

        while (bccomp($r, 0, $exp_scale) === -1) {
            ++$actual_index;
            $actual_rt = bcmul('0.5', $actual_rt, $inner_scale);
            $r = bcsub($exponent_remaining, $actual_rt, $inner_scale);
        }

        return [$actual_index, $r];
    }

    /**
     * Auxiliar method. Computes $base^((1/2)^$index)
     *
     * @param  string  $base
     * @param  integer $index
     * @param  integer $out_scale
     * @return string
     */
    private static function compute2NRoot($base, $index, $out_scale)
    {
        $result = $base;

        for ($i=0; $i<$index; $i++) {
            $result = bcsqrt($result, ($out_scale+1)*($index-$i)+1);
        }

        return self::innerRound($result, $out_scale);
    }

    /**
     * Validates basic constructor's arguments
     * @param  mixed    $value
     * @param  integer  $scale
     */
    protected static function paramsValidation($value, $scale)
    {
        if ($value === null) {
            throw new \InvalidArgumentException('$value must be a non null number');
        }

        if ($scale !== null && (!is_int($scale) || $scale < 0)) {
            throw new \InvalidArgumentException('$scale must be a positive integer');
        }
    }

    /**
     * @return string
     */
    private static function normalizeSign($sign)
    {
        if ($sign==='+') {
            return '';
        }

        return $sign;
    }

    private static function removeTrailingZeros($strValue, &$scale)
    {
        preg_match('/^[+\-]?[0-9]+(\.([0-9]*[1-9])?(0+)?)?$/', $strValue, $captures);

        if (count($captures) === 4) {
            $toRemove = strlen($captures[3]);
            $scale = strlen($captures[2]);
            $strValue = substr($strValue, 0, strlen($strValue)-$toRemove-($scale===0 ? 1 : 0));
        }

        return $strValue;
    }

    /**
     * Counts the number of significative digits of $val.
     * Assumes a consistent internal state (without zeros at the end or the start).
     *
     * @param  Decimal $val
     * @param  Decimal $abs $val->abs()
     * @return integer
     */
    private static function countSignificativeDigits(Decimal $val, Decimal $abs)
    {
        return strlen($val->value) - (
            ($abs->comp(DecimalConstants::One()) === -1) ? 2 : max($val->scale, 1)
        ) - ($val->isNegative() ? 1 : 0);
    }
}