class BigDecimal

BigDecimal provides arbitrary-precision floating point decimal arithmetic.

Introduction

Ruby provides built-in support for arbitrary precision integer arithmetic.

For example:

42**13  #=>   1265437718438866624512

BigDecimal provides similar support for very large or very accurate floating point numbers.

Decimal arithmetic is also useful for general calculation, because it provides the correct answers people expect–whereas normal binary floating point arithmetic often introduces subtle errors because of the conversion between base 10 and base 2.

For example, try:

sum = 0
10_000.times do
  sum = sum + 0.0001
end
print sum #=> 0.9999999999999062

and contrast with the output from:

require 'bigdecimal'

sum = BigDecimal("0")
10_000.times do
  sum = sum + BigDecimal("0.0001")
end
print sum #=> 0.1E1

Similarly:

(BigDecimal("1.2") - BigDecimal("1.0")) == BigDecimal("0.2") #=> true

(1.2 - 1.0) == 0.2 #=> false

A Note About Precision

For a calculation using a BigDecimal and another value, the precision of the result depends on the type of value:

Special features of accurate decimal arithmetic

Because BigDecimal is more accurate than normal binary floating point arithmetic, it requires some special values.

Infinity

BigDecimal sometimes needs to return infinity, for example if you divide a value by zero.

BigDecimal("1.0") / BigDecimal("0.0")  #=> Infinity
BigDecimal("-1.0") / BigDecimal("0.0")  #=> -Infinity

You can represent infinite numbers to BigDecimal using the strings 'Infinity', '+Infinity' and '-Infinity' (case-sensitive)

Not a Number

When a computation results in an undefined value, the special value NaN (for ‘not a number’) is returned.

Example:

BigDecimal("0.0") / BigDecimal("0.0") #=> NaN

You can also create undefined values.

NaN is never considered to be the same as any other value, even NaN itself:

n = BigDecimal('NaN')
n == 0.0 #=> false
n == n #=> false

Positive and negative zero

If a computation results in a value which is too small to be represented as a BigDecimal within the currently specified limits of precision, zero must be returned.

If the value which is too small to be represented is negative, a BigDecimal value of negative zero is returned.

BigDecimal("1.0") / BigDecimal("-Infinity") #=> -0.0

If the value is positive, a value of positive zero is returned.

BigDecimal("1.0") / BigDecimal("Infinity") #=> 0.0

(See BigDecimal.mode for how to specify limits of precision.)

Note that -0.0 and 0.0 are considered to be the same for the purposes of comparison.

Note also that in mathematics, there is no particular concept of negative or positive zero; true mathematical zero has no sign.

bigdecimal/util

When you require bigdecimal/util, the to_d method will be available on BigDecimal and the native Integer, Float, Rational, and String classes:

require 'bigdecimal/util'

42.to_d         # => 0.42e2
0.5.to_d        # => 0.5e0
(2/3r).to_d(3)  # => 0.667e0
"0.5".to_d      # => 0.5e0

License

Copyright © 2002 by Shigeo Kobayashi <shigeo@tinyforest.gr.jp>.

BigDecimal is released under the Ruby and 2-clause BSD licenses. See LICENSE.txt for details.

Maintained by mrkn <mrkn@mrkn.jp> and ruby-core members.

Documented by zzak <zachary@zacharyscott.net>, mathew <meta@pobox.com>, and many other contributors.

Constants

BASE

Base value used in internal calculations. On a 32 bit system, BASE is 10000, indicating that calculation is done in groups of 4 digits. (If it were larger, BASE**2 wouldn’t fit in 32 bits, so you couldn’t guarantee that two groups could always be multiplied together without overflow.)

EXCEPTION_ALL

Determines whether overflow, underflow or zero divide result in an exception being thrown. See BigDecimal.mode.

EXCEPTION_INFINITY

Determines what happens when the result of a computation is infinity. See BigDecimal.mode.

EXCEPTION_NaN

Determines what happens when the result of a computation is not a number (NaN). See BigDecimal.mode.

EXCEPTION_OVERFLOW

Determines what happens when the result of a computation is an overflow (a result too large to be represented). See BigDecimal.mode.

EXCEPTION_UNDERFLOW

Determines what happens when the result of a computation is an underflow (a result too small to be represented). See BigDecimal.mode.

EXCEPTION_ZERODIVIDE

Determines what happens when a division by zero is performed. See BigDecimal.mode.

INFINITY

Special value constants

NAN
ROUND_CEILING

Round towards +Infinity. See BigDecimal.mode.

ROUND_DOWN

Indicates that values should be rounded towards zero. See BigDecimal.mode.

ROUND_FLOOR

Round towards -Infinity. See BigDecimal.mode.

ROUND_HALF_DOWN

Indicates that digits >= 6 should be rounded up, others rounded down. See BigDecimal.mode.

ROUND_HALF_EVEN

Round towards the even neighbor. See BigDecimal.mode.

ROUND_HALF_UP

Indicates that digits >= 5 should be rounded up, others rounded down. See BigDecimal.mode.

ROUND_MODE

Determines what happens when a result must be rounded in order to fit in the appropriate number of significant digits. See BigDecimal.mode.

ROUND_UP

Indicates that values should be rounded away from zero. See BigDecimal.mode.

SIGN_NEGATIVE_FINITE

Indicates that a value is negative and finite. See BigDecimal.sign.

SIGN_NEGATIVE_INFINITE

Indicates that a value is negative and infinite. See BigDecimal.sign.

SIGN_NEGATIVE_ZERO

Indicates that a value is -0. See BigDecimal.sign.

SIGN_NaN

Indicates that a value is not a number. See BigDecimal.sign.

SIGN_POSITIVE_FINITE

Indicates that a value is positive and finite. See BigDecimal.sign.

SIGN_POSITIVE_INFINITE

Indicates that a value is positive and infinite. See BigDecimal.sign.

SIGN_POSITIVE_ZERO

Indicates that a value is +0. See BigDecimal.sign.

VERSION

The version of bigdecimal library

Public Class Methods

_load(p1) click to toggle source

Internal method used to provide marshalling support. See the Marshal module.

static VALUE
BigDecimal_load(VALUE self, VALUE str)
{
    ENTER(2);
    Real *pv;
    unsigned char *pch;
    unsigned char ch;
    unsigned long m=0;

    pch = (unsigned char *)StringValueCStr(str);
    /* First get max prec */
    while((*pch) != (unsigned char)'\0' && (ch = *pch++) != (unsigned char)':') {
        if(!ISDIGIT(ch)) {
            rb_raise(rb_eTypeError, "load failed: invalid character in the marshaled string");
        }
        m = m*10 + (unsigned long)(ch-'0');
    }
    if (m > VpBaseFig()) m -= VpBaseFig();
    GUARD_OBJ(pv, VpNewRbClass(m, (char *)pch, self, true, true));
    m /= VpBaseFig();
    if (m && pv->MaxPrec > m) {
        pv->MaxPrec = m+1;
    }
    return VpCheckGetValue(pv);
}
double_fig() click to toggle source
inline VALUE
BigDecimal_double_fig(VALUE self)
{
    return INT2FIX(VpDblFig());
}
interpret_loosely(p1) click to toggle source
static VALUE
BigDecimal_s_interpret_loosely(VALUE klass, VALUE str)
{
    char const *c_str = StringValueCStr(str);
    Real *vp = VpNewRbClass(0, c_str, klass, false, true);
    if (!vp)
        return Qnil;
    else
        return VpCheckGetValue(vp);
}
json_create(object) click to toggle source

Import a JSON Marshalled object.

method used for JSON marshalling support.

# File ext/json/lib/json/add/bigdecimal.rb, line 11
def self.json_create(object)
  BigDecimal._load object['b']
end
limit(digits) click to toggle source

Limit the number of significant digits in newly created BigDecimal numbers to the specified value. Rounding is performed as necessary, as specified by BigDecimal.mode.

A limit of 0, the default, means no upper limit.

The limit specified by this method takes less priority over any limit specified to instance methods such as ceil, floor, truncate, or round.

static VALUE
BigDecimal_limit(int argc, VALUE *argv, VALUE self)
{
    VALUE  nFig;
    VALUE  nCur = SIZET2NUM(VpGetPrecLimit());

    if (rb_scan_args(argc, argv, "01", &nFig) == 1) {
        int nf;
        if (NIL_P(nFig)) return nCur;
        nf = NUM2INT(nFig);
        if (nf < 0) {
            rb_raise(rb_eArgError, "argument must be positive");
        }
        VpSetPrecLimit(nf);
    }
    return nCur;
}
mode(mode, setting = nil) → integer click to toggle source

Returns an integer representing the mode settings for exception handling and rounding.

These modes control exception handling:

  • BigDecimal::EXCEPTION_NaN.

  • BigDecimal::EXCEPTION_INFINITY.

  • BigDecimal::EXCEPTION_UNDERFLOW.

  • BigDecimal::EXCEPTION_OVERFLOW.

  • BigDecimal::EXCEPTION_ZERODIVIDE.

  • BigDecimal::EXCEPTION_ALL.

Values for setting for exception handling:

  • true: sets the given mode to true.

  • false: sets the given mode to false.

  • nil: does not modify the mode settings.

You can use method BigDecimal.save_exception_mode to temporarily change, and then automatically restore, exception modes.

For clarity, some examples below begin by setting all exception modes to false.

This mode controls the way rounding is to be performed:

  • BigDecimal::ROUND_MODE

You can use method BigDecimal.save_rounding_mode to temporarily change, and then automatically restore, the rounding mode.

NaNs

Mode BigDecimal::EXCEPTION_NaN controls behavior when a BigDecimal NaN is created.

Settings:

Examples:

BigDecimal.mode(BigDecimal::EXCEPTION_ALL, false) # => 0
BigDecimal('NaN')                                 # => NaN
BigDecimal.mode(BigDecimal::EXCEPTION_NaN, true)  # => 2
BigDecimal('NaN') # Raises FloatDomainError

Infinities

Mode BigDecimal::EXCEPTION_INFINITY controls behavior when a BigDecimal Infinity or -Infinity is created. Settings:

  • false (default): Returns BigDecimal('Infinity') or BigDecimal('-Infinity').

  • true: Raises FloatDomainError.

Examples:

BigDecimal.mode(BigDecimal::EXCEPTION_ALL, false)     # => 0
BigDecimal('Infinity')                                # => Infinity
BigDecimal('-Infinity')                               # => -Infinity
BigDecimal.mode(BigDecimal::EXCEPTION_INFINITY, true) # => 1
BigDecimal('Infinity')  # Raises FloatDomainError
BigDecimal('-Infinity') # Raises FloatDomainError

Underflow

Mode BigDecimal::EXCEPTION_UNDERFLOW controls behavior when a BigDecimal underflow occurs. Settings:

  • false (default): Returns BigDecimal('0') or BigDecimal('-Infinity').

  • true: Raises FloatDomainError.

Examples:

BigDecimal.mode(BigDecimal::EXCEPTION_ALL, false)      # => 0
def flow_under
  x = BigDecimal('0.1')
  100.times { x *= x }
end
flow_under                                             # => 100
BigDecimal.mode(BigDecimal::EXCEPTION_UNDERFLOW, true) # => 4
flow_under # Raises FloatDomainError

Overflow

Mode BigDecimal::EXCEPTION_OVERFLOW controls behavior when a BigDecimal overflow occurs. Settings:

  • false (default): Returns BigDecimal('Infinity') or BigDecimal('-Infinity').

  • true: Raises FloatDomainError.

Examples:

BigDecimal.mode(BigDecimal::EXCEPTION_ALL, false)     # => 0
def flow_over
  x = BigDecimal('10')
  100.times { x *= x }
end
flow_over                                             # => 100
BigDecimal.mode(BigDecimal::EXCEPTION_OVERFLOW, true) # => 1
flow_over # Raises FloatDomainError

Zero Division

Mode BigDecimal::EXCEPTION_ZERODIVIDE controls behavior when a zero-division occurs. Settings:

  • false (default): Returns BigDecimal('Infinity') or BigDecimal('-Infinity').

  • true: Raises FloatDomainError.

Examples:

BigDecimal.mode(BigDecimal::EXCEPTION_ALL, false)       # => 0
one = BigDecimal('1')
zero = BigDecimal('0')
one / zero                                              # => Infinity
BigDecimal.mode(BigDecimal::EXCEPTION_ZERODIVIDE, true) # => 16
one / zero # Raises FloatDomainError

All Exceptions

Mode BigDecimal::EXCEPTION_ALL controls all of the above:

BigDecimal.mode(BigDecimal::EXCEPTION_ALL, false) # => 0
BigDecimal.mode(BigDecimal::EXCEPTION_ALL, true)  # => 23

Rounding

Mode BigDecimal::ROUND_MODE controls the way rounding is to be performed; its setting values are:

  • ROUND_UP: Round away from zero. Aliased as :up.

  • ROUND_DOWN: Round toward zero. Aliased as :down and :truncate.

  • ROUND_HALF_UP: Round toward the nearest neighbor; if the neighbors are equidistant, round away from zero. Aliased as :half_up and :default.

  • ROUND_HALF_DOWN: Round toward the nearest neighbor; if the neighbors are equidistant, round toward zero. Aliased as :half_down.

  • ROUND_HALF_EVEN (Banker’s rounding): Round toward the nearest neighbor; if the neighbors are equidistant, round toward the even neighbor. Aliased as :half_even and :banker.

  • ROUND_CEILING: Round toward positive infinity. Aliased as :ceiling and :ceil.

  • ROUND_FLOOR: Round toward negative infinity. Aliased as :floor:.

static VALUE
BigDecimal_mode(int argc, VALUE *argv, VALUE self)
{
    VALUE which;
    VALUE val;
    unsigned long f,fo;

    rb_scan_args(argc, argv, "11", &which, &val);
    f = (unsigned long)NUM2INT(which);

    if (f & VP_EXCEPTION_ALL) {
        /* Exception mode setting */
        fo = VpGetException();
        if (val == Qnil) return INT2FIX(fo);
        if (val != Qfalse && val!=Qtrue) {
            rb_raise(rb_eArgError, "second argument must be true or false");
            return Qnil; /* Not reached */
        }
        if (f & VP_EXCEPTION_INFINITY) {
            VpSetException((unsigned short)((val == Qtrue) ? (fo | VP_EXCEPTION_INFINITY) :
                        (fo & (~VP_EXCEPTION_INFINITY))));
        }
        fo = VpGetException();
        if (f & VP_EXCEPTION_NaN) {
            VpSetException((unsigned short)((val == Qtrue) ? (fo | VP_EXCEPTION_NaN) :
                        (fo & (~VP_EXCEPTION_NaN))));
        }
        fo = VpGetException();
        if (f & VP_EXCEPTION_UNDERFLOW) {
            VpSetException((unsigned short)((val == Qtrue) ? (fo | VP_EXCEPTION_UNDERFLOW) :
                        (fo & (~VP_EXCEPTION_UNDERFLOW))));
        }
        fo = VpGetException();
        if(f & VP_EXCEPTION_ZERODIVIDE) {
            VpSetException((unsigned short)((val == Qtrue) ? (fo | VP_EXCEPTION_ZERODIVIDE) :
                        (fo & (~VP_EXCEPTION_ZERODIVIDE))));
        }
        fo = VpGetException();
        return INT2FIX(fo);
    }
    if (VP_ROUND_MODE == f) {
        /* Rounding mode setting */
        unsigned short sw;
        fo = VpGetRoundMode();
        if (NIL_P(val)) return INT2FIX(fo);
        sw = check_rounding_mode(val);
        fo = VpSetRoundMode(sw);
        return INT2FIX(fo);
    }
    rb_raise(rb_eTypeError, "first argument for BigDecimal.mode invalid");
    return Qnil;
}
save_exception_mode { ... } click to toggle source

Execute the provided block, but preserve the exception mode

BigDecimal.save_exception_mode do
  BigDecimal.mode(BigDecimal::EXCEPTION_OVERFLOW, false)
  BigDecimal.mode(BigDecimal::EXCEPTION_NaN, false)

  BigDecimal(BigDecimal('Infinity'))
  BigDecimal(BigDecimal('-Infinity'))
  BigDecimal(BigDecimal('NaN'))
end

For use with the BigDecimal::EXCEPTION_*

See BigDecimal.mode

static VALUE
BigDecimal_save_exception_mode(VALUE self)
{
    unsigned short const exception_mode = VpGetException();
    int state;
    VALUE ret = rb_protect(rb_yield, Qnil, &state);
    VpSetException(exception_mode);
    if (state) rb_jump_tag(state);
    return ret;
}
save_limit { ... } click to toggle source

Execute the provided block, but preserve the precision limit

BigDecimal.limit(100)
puts BigDecimal.limit
BigDecimal.save_limit do
    BigDecimal.limit(200)
    puts BigDecimal.limit
end
puts BigDecimal.limit
static VALUE
BigDecimal_save_limit(VALUE self)
{
    size_t const limit = VpGetPrecLimit();
    int state;
    VALUE ret = rb_protect(rb_yield, Qnil, &state);
    VpSetPrecLimit(limit);
    if (state) rb_jump_tag(state);
    return ret;
}
save_rounding_mode { ... } click to toggle source

Execute the provided block, but preserve the rounding mode

BigDecimal.save_rounding_mode do
  BigDecimal.mode(BigDecimal::ROUND_MODE, :up)
  puts BigDecimal.mode(BigDecimal::ROUND_MODE)
end

For use with the BigDecimal::ROUND_*

See BigDecimal.mode

static VALUE
BigDecimal_save_rounding_mode(VALUE self)
{
    unsigned short const round_mode = VpGetRoundMode();
    int state;
    VALUE ret = rb_protect(rb_yield, Qnil, &state);
    VpSetRoundMode(round_mode);
    if (state) rb_jump_tag(state);
    return ret;
}

Public Instance Methods

a % b click to toggle source

Returns the modulus from dividing by b.

See BigDecimal#divmod.

static VALUE
BigDecimal_mod(VALUE self, VALUE r) 
Also aliased as: modulo
*(p1) click to toggle source
static VALUE
BigDecimal_mult(VALUE self, VALUE r)
{
    ENTER(5);
    Real *c, *a, *b;
    size_t mx;

    GUARD_OBJ(a, GetVpValue(self, 1));
    if (RB_TYPE_P(r, T_FLOAT)) {
        b = GetVpValueWithPrec(r, 0, 1);
    }
    else if (RB_TYPE_P(r, T_RATIONAL)) {
        b = GetVpValueWithPrec(r, a->Prec*VpBaseFig(), 1);
    }
    else {
        b = GetVpValue(r,0);
    }

    if (!b) return DoSomeOne(self, r, '*');
    SAVE(b);

    mx = a->Prec + b->Prec;
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx * (VpBaseFig() + 1)));
    VpMult(c, a, b);
    return VpCheckGetValue(c);
}
self ** other → bigdecimal click to toggle source

Returns the BigDecimal value of self raised to power other:

b = BigDecimal('3.14')
b ** 2              # => 0.98596e1
b ** 2.0            # => 0.98596e1
b ** Rational(2, 1) # => 0.98596e1

Related: BigDecimal#power.

static VALUE
BigDecimal_power_op(VALUE self, VALUE exp)
{
    return BigDecimal_power(1, &exp, self);
}
self + value → bigdecimal click to toggle source

Returns the BigDecimal sum of self and value:

b = BigDecimal('111111.111') # => 0.111111111e6
b + 2                        # => 0.111113111e6
b + 2.0                      # => 0.111113111e6
b + Rational(2, 1)           # => 0.111113111e6
b + Complex(2, 0)            # => (0.111113111e6+0i)

See the Note About Precision.

static VALUE
BigDecimal_add(VALUE self, VALUE r)
{
    ENTER(5);
    Real *c, *a, *b;
    size_t mx;

    GUARD_OBJ(a, GetVpValue(self, 1));
    if (RB_TYPE_P(r, T_FLOAT)) {
        b = GetVpValueWithPrec(r, 0, 1);
    }
    else if (RB_TYPE_P(r, T_RATIONAL)) {
        b = GetVpValueWithPrec(r, a->Prec*VpBaseFig(), 1);
    }
    else {
        b = GetVpValue(r, 0);
    }

    if (!b) return DoSomeOne(self,r,'+');
    SAVE(b);

    if (VpIsNaN(b)) return b->obj;
    if (VpIsNaN(a)) return a->obj;

    mx = GetAddSubPrec(a, b);
    if (mx == (size_t)-1L) {
        GUARD_OBJ(c, NewZeroWrapLimited(1, VpBaseFig() + 1));
        VpAddSub(c, a, b, 1);
    }
    else {
        GUARD_OBJ(c, NewZeroWrapLimited(1, mx * (VpBaseFig() + 1)));
        if (!mx) {
            VpSetInf(c, VpGetSign(a));
        }
        else {
            VpAddSub(c, a, b, 1);
        }
    }
    return VpCheckGetValue(c);
}
+big_decimal → self click to toggle source

Returns self:

+BigDecimal(5)  # => 0.5e1
+BigDecimal(-5) # => -0.5e1
static VALUE
BigDecimal_uplus(VALUE self)
{
    return self;
}
self - value → bigdecimal click to toggle source

Returns the BigDecimal difference of self and value:

b = BigDecimal('333333.333') # => 0.333333333e6
b - 2                        # => 0.333331333e6
b - 2.0                      # => 0.333331333e6
b - Rational(2, 1)           # => 0.333331333e6
b - Complex(2, 0)            # => (0.333331333e6+0i)

See the Note About Precision.

static VALUE
BigDecimal_sub(VALUE self, VALUE r)
{
    ENTER(5);
    Real *c, *a, *b;
    size_t mx;

    GUARD_OBJ(a, GetVpValue(self,1));
    if (RB_TYPE_P(r, T_FLOAT)) {
        b = GetVpValueWithPrec(r, 0, 1);
    }
    else if (RB_TYPE_P(r, T_RATIONAL)) {
        b = GetVpValueWithPrec(r, a->Prec*VpBaseFig(), 1);
    }
    else {
        b = GetVpValue(r,0);
    }

    if (!b) return DoSomeOne(self,r,'-');
    SAVE(b);

    if (VpIsNaN(b)) return b->obj;
    if (VpIsNaN(a)) return a->obj;

    mx = GetAddSubPrec(a,b);
    if (mx == (size_t)-1L) {
        GUARD_OBJ(c, NewZeroWrapLimited(1, VpBaseFig() + 1));
        VpAddSub(c, a, b, -1);
    }
    else {
        GUARD_OBJ(c, NewZeroWrapLimited(1, mx *(VpBaseFig() + 1)));
        if (!mx) {
            VpSetInf(c,VpGetSign(a));
        }
        else {
            VpAddSub(c, a, b, -1);
        }
    }
    return VpCheckGetValue(c);
}
-self → bigdecimal click to toggle source

Returns the BigDecimal negation of self:

b0 = BigDecimal('1.5')
b1 = -b0 # => -0.15e1
b2 = -b1 # => 0.15e1
static VALUE
BigDecimal_neg(VALUE self)
{
    ENTER(5);
    Real *c, *a;
    GUARD_OBJ(a, GetVpValue(self, 1));
    GUARD_OBJ(c, NewZeroWrapLimited(1, a->Prec *(VpBaseFig() + 1)));
    VpAsgn(c, a, -1);
    return VpCheckGetValue(c);
}
a / b → bigdecimal click to toggle source

Divide by the specified value.

The result precision will be the precision of the larger operand, but its minimum is 2*Float::DIG.

See BigDecimal#div. See BigDecimal#quo.

static VALUE
BigDecimal_div(VALUE self, VALUE r)
/* For c = self/r: with round operation */
{
    ENTER(5);
    Real *c=NULL, *res=NULL, *div = NULL;
    r = BigDecimal_divide(self, r, &c, &res, &div);
    if (!NIL_P(r)) return r; /* coerced by other */
    SAVE(c); SAVE(res); SAVE(div);
    /* a/b = c + r/b */
    /* c xxxxx
       r 00000yyyyy  ==> (y/b)*BASE >= HALF_BASE
     */
    /* Round */
    if (VpHasVal(div)) { /* frac[0] must be zero for NaN,INF,Zero */
        VpInternalRound(c, 0, c->frac[c->Prec-1], (DECDIG)(VpBaseVal() * (DECDIG_DBL)res->frac[0] / div->frac[0]));
    }
    return VpCheckGetValue(c);
}
self < other → true or false click to toggle source

Returns true if self is less than other, false otherwise:

b = BigDecimal('1.5') # => 0.15e1
b < 2                 # => true
b < 2.0               # => true
b < Rational(2, 1)    # => true
b < 1.5               # => false

Raises an exception if the comparison cannot be made.

static VALUE
BigDecimal_lt(VALUE self, VALUE r)
{
    return BigDecimalCmp(self, r, '<');
}
self <= other → true or false click to toggle source

Returns true if self is less or equal to than other, false otherwise:

b = BigDecimal('1.5') # => 0.15e1
b <= 2                # => true
b <= 2.0              # => true
b <= Rational(2, 1)   # => true
b <= 1.5              # => true
b < 1                 # => false

Raises an exception if the comparison cannot be made.

static VALUE
BigDecimal_le(VALUE self, VALUE r)
{
    return BigDecimalCmp(self, r, 'L');
}
<=>(p1) click to toggle source

The comparison operator. a <=> b is 0 if a == b, 1 if a > b, -1 if a < b.

static VALUE
BigDecimal_comp(VALUE self, VALUE r)
{
    return BigDecimalCmp(self, r, '*');
}
==(p1) click to toggle source

Tests for value equality; returns true if the values are equal.

The == and === operators and the eql? method have the same implementation for BigDecimal.

Values may be coerced to perform the comparison:

BigDecimal('1.0') == 1.0  #=> true
static VALUE
BigDecimal_eq(VALUE self, VALUE r)
{
    return BigDecimalCmp(self, r, '=');
}
Also aliased as: ===, eql?
===(p1)

Tests for value equality; returns true if the values are equal.

The == and === operators and the eql? method have the same implementation for BigDecimal.

Values may be coerced to perform the comparison:

BigDecimal('1.0') == 1.0  #=> true
Alias for: ==
self > other → true or false click to toggle source

Returns true if self is greater than other, false otherwise:

b = BigDecimal('1.5')
b > 1              # => true
b > 1.0            # => true
b > Rational(1, 1) # => true
b > 2              # => false

Raises an exception if the comparison cannot be made.

static VALUE
BigDecimal_gt(VALUE self, VALUE r)
{
    return BigDecimalCmp(self, r, '>');
}
self >= other → true or false click to toggle source

Returns true if self is greater than or equal to other, false otherwise:

b = BigDecimal('1.5')
b >= 1              # => true
b >= 1.0            # => true
b >= Rational(1, 1) # => true
b >= 1.5            # => true
b > 2               # => false

Raises an exception if the comparison cannot be made.

static VALUE
BigDecimal_ge(VALUE self, VALUE r)
{
    return BigDecimalCmp(self, r, 'G');
}
_dump → string click to toggle source

Returns a string representing the marshalling of self. See module Marshal.

inf = BigDecimal('Infinity') # => Infinity
dumped = inf._dump           # => "9:Infinity"
BigDecimal._load(dumped)     # => Infinity
static VALUE
BigDecimal_dump(int argc, VALUE *argv, VALUE self)
{
    ENTER(5);
    Real *vp;
    char *psz;
    VALUE dummy;
    volatile VALUE dump;
    size_t len;

    rb_scan_args(argc, argv, "01", &dummy);
    GUARD_OBJ(vp,GetVpValue(self, 1));
    dump = rb_str_new(0, VpNumOfChars(vp, "E")+50);
    psz = RSTRING_PTR(dump);
    snprintf(psz, RSTRING_LEN(dump), "%"PRIuSIZE":", VpMaxPrec(vp)*VpBaseFig());
    len = strlen(psz);
    VpToString(vp, psz+len, RSTRING_LEN(dump)-len, 0, 0);
    rb_str_resize(dump, strlen(psz));
    return dump;
}
abs → bigdecimal click to toggle source

Returns the BigDecimal absolute value of self:

BigDecimal('5').abs  # => 0.5e1
BigDecimal('-3').abs # => 0.3e1
static VALUE
BigDecimal_abs(VALUE self)
{
    ENTER(5);
    Real *c, *a;
    size_t mx;

    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec *(VpBaseFig() + 1);
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpAsgn(c, a, 1);
    VpChangeSign(c, 1);
    return VpCheckGetValue(c);
}
add(value, ndigits) → new_bigdecimal click to toggle source

Returns the BigDecimal sum of self and value with a precision of ndigits decimal digits.

When ndigits is less than the number of significant digits in the sum, the sum is rounded to that number of digits, according to the current rounding mode; see BigDecimal.mode.

Examples:

# Set the rounding mode.
BigDecimal.mode(BigDecimal::ROUND_MODE, :half_up)
b = BigDecimal('111111.111')
b.add(1, 0)               # => 0.111112111e6
b.add(1, 3)               # => 0.111e6
b.add(1, 6)               # => 0.111112e6
b.add(1, 15)              # => 0.111112111e6
b.add(1.0, 15)            # => 0.111112111e6
b.add(Rational(1, 1), 15) # => 0.111112111e6
static VALUE
BigDecimal_add2(VALUE self, VALUE b, VALUE n)
{
    ENTER(2);
    Real *cv;
    SIGNED_VALUE mx = check_int_precision(n);
    if (mx == 0) return BigDecimal_add(self, b);
    else {
        size_t pl = VpSetPrecLimit(0);
        VALUE   c = BigDecimal_add(self, b);
        VpSetPrecLimit(pl);
        GUARD_OBJ(cv, GetVpValue(c, 1));
        VpLeftRound(cv, VpGetRoundMode(), mx);
        return VpCheckGetValue(cv);
    }
}
as_json(*) click to toggle source

Marshal the object to JSON.

method used for JSON marshalling support.

# File ext/json/lib/json/add/bigdecimal.rb, line 18
def as_json(*)
  {
    JSON.create_id => self.class.name,
    'b'            => _dump,
  }
end
ceil(n) click to toggle source

Return the smallest integer greater than or equal to the value, as a BigDecimal.

BigDecimal('3.14159').ceil #=> 4
BigDecimal('-9.1').ceil #=> -9

If n is specified and positive, the fractional part of the result has no more than that many digits.

If n is specified and negative, at least that many digits to the left of the decimal point will be 0 in the result.

BigDecimal('3.14159').ceil(3) #=> 3.142
BigDecimal('13345.234').ceil(-2) #=> 13400.0
static VALUE
BigDecimal_ceil(int argc, VALUE *argv, VALUE self)
{
    ENTER(5);
    Real *c, *a;
    int iLoc;
    VALUE vLoc;
    size_t mx, pl = VpSetPrecLimit(0);

    if (rb_scan_args(argc, argv, "01", &vLoc) == 0) {
        iLoc = 0;
    } else {
        iLoc = NUM2INT(vLoc);
    }

    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec * (VpBaseFig() + 1);
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpSetPrecLimit(pl);
    VpActiveRound(c, a, VP_ROUND_CEIL, iLoc);
    if (argc == 0) {
        return BigDecimal_to_i(VpCheckGetValue(c));
    }
    return VpCheckGetValue(c);
}
clone() click to toggle source
static VALUE
BigDecimal_clone(VALUE self)
{
  return self;
}
Also aliased as: dup
coerce(p1) click to toggle source

The coerce method provides support for Ruby type coercion. It is not enabled by default.

This means that binary operations like + * / or - can often be performed on a BigDecimal and an object of another type, if the other object can be coerced into a BigDecimal value.

e.g.

a = BigDecimal("1.0")
b = a / 2.0 #=> 0.5

Note that coercing a String to a BigDecimal is not supported by default; it requires a special compile-time option when building Ruby.

static VALUE
BigDecimal_coerce(VALUE self, VALUE other)
{
    ENTER(2);
    VALUE obj;
    Real *b;

    if (RB_TYPE_P(other, T_FLOAT)) {
        GUARD_OBJ(b, GetVpValueWithPrec(other, 0, 1));
        obj = rb_assoc_new(VpCheckGetValue(b), self);
    }
    else {
        if (RB_TYPE_P(other, T_RATIONAL)) {
            Real* pv = DATA_PTR(self);
            GUARD_OBJ(b, GetVpValueWithPrec(other, pv->Prec*VpBaseFig(), 1));
        }
        else {
            GUARD_OBJ(b, GetVpValue(other, 1));
        }
        obj = rb_assoc_new(b->obj, self);
    }

    return obj;
}
div(value) → integer click to toggle source
div(value, digits) → bigdecimal or integer

Divide by the specified value.

digits

If specified and less than the number of significant digits of the result, the result is rounded to that number of digits, according to BigDecimal.mode.

If digits is 0, the result is the same as for the / operator or quo.

If digits is not specified, the result is an integer, by analogy with Float#div; see also BigDecimal#divmod.

See BigDecimal#/. See BigDecimal#quo.

Examples:

a = BigDecimal("4")
b = BigDecimal("3")

a.div(b, 3)  # => 0.133e1

a.div(b, 0)  # => 0.1333333333333333333e1
a / b        # => 0.1333333333333333333e1
a.quo(b)     # => 0.1333333333333333333e1

a.div(b)     # => 1
static VALUE
BigDecimal_div3(int argc, VALUE *argv, VALUE self)
{
    VALUE b,n;

    rb_scan_args(argc, argv, "11", &b, &n);

    return BigDecimal_div2(self, b, n);
}
divmod(value) click to toggle source

Divides by the specified value, and returns the quotient and modulus as BigDecimal numbers. The quotient is rounded towards negative infinity.

For example:

require 'bigdecimal'

a = BigDecimal("42")
b = BigDecimal("9")

q, m = a.divmod(b)

c = q * b + m

a == c  #=> true

The quotient q is (a/b).floor, and the modulus is the amount that must be added to q * b to get a.

static VALUE
BigDecimal_divmod(VALUE self, VALUE r)
{
    ENTER(5);
    Real *div = NULL, *mod = NULL;

    if (BigDecimal_DoDivmod(self, r, &div, &mod)) {
        SAVE(div); SAVE(mod);
        return rb_assoc_new(VpCheckGetValue(div), VpCheckGetValue(mod));
    }
    return DoSomeOne(self,r,rb_intern("divmod"));
}
dup()
Alias for: clone
eql?(p1)

Tests for value equality; returns true if the values are equal.

The == and === operators and the eql? method have the same implementation for BigDecimal.

Values may be coerced to perform the comparison:

BigDecimal('1.0') == 1.0  #=> true
Alias for: ==
exponent() click to toggle source

Returns the exponent of the BigDecimal number, as an Integer.

If the number can be represented as 0.xxxxxx*10**n where xxxxxx is a string of digits with no leading zeros, then n is the exponent.

static VALUE
BigDecimal_exponent(VALUE self)
{
    ssize_t e = VpExponent10(GetVpValue(self, 1));
    return SSIZET2NUM(e);
}
finite?() click to toggle source

Returns True if the value is finite (not NaN or infinite).

static VALUE
BigDecimal_IsFinite(VALUE self)
{
    Real *p = GetVpValue(self, 1);
    if (VpIsNaN(p)) return Qfalse;
    if (VpIsInf(p)) return Qfalse;
    return Qtrue;
}
fix() click to toggle source

Return the integer part of the number, as a BigDecimal.

static VALUE
BigDecimal_fix(VALUE self)
{
    ENTER(5);
    Real *c, *a;
    size_t mx;

    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec *(VpBaseFig() + 1);
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpActiveRound(c, a, VP_ROUND_DOWN, 0); /* 0: round off */
    return VpCheckGetValue(c);
}
floor(n) click to toggle source

Return the largest integer less than or equal to the value, as a BigDecimal.

BigDecimal('3.14159').floor #=> 3
BigDecimal('-9.1').floor #=> -10

If n is specified and positive, the fractional part of the result has no more than that many digits.

If n is specified and negative, at least that many digits to the left of the decimal point will be 0 in the result.

BigDecimal('3.14159').floor(3) #=> 3.141
BigDecimal('13345.234').floor(-2) #=> 13300.0
static VALUE
BigDecimal_floor(int argc, VALUE *argv, VALUE self)
{
    ENTER(5);
    Real *c, *a;
    int iLoc;
    VALUE vLoc;
    size_t mx, pl = VpSetPrecLimit(0);

    if (rb_scan_args(argc, argv, "01", &vLoc)==0) {
        iLoc = 0;
    }
    else {
        iLoc = NUM2INT(vLoc);
    }

    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec * (VpBaseFig() + 1);
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpSetPrecLimit(pl);
    VpActiveRound(c, a, VP_ROUND_FLOOR, iLoc);
#ifdef BIGDECIMAL_DEBUG
    VPrint(stderr, "floor: c=%\n", c);
#endif
    if (argc == 0) {
        return BigDecimal_to_i(VpCheckGetValue(c));
    }
    return VpCheckGetValue(c);
}
frac() click to toggle source

Return the fractional part of the number, as a BigDecimal.

static VALUE
BigDecimal_frac(VALUE self)
{
    ENTER(5);
    Real *c, *a;
    size_t mx;

    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec * (VpBaseFig() + 1);
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpFrac(c, a);
    return VpCheckGetValue(c);
}
hash → integer click to toggle source

Returns the integer hash value for self.

Two instances of BigDecimal have the same hash value if and only if they have equal:

  • Sign.

  • Fractional part.

  • Exponent.

static VALUE
BigDecimal_hash(VALUE self)
{
    ENTER(1);
    Real *p;
    st_index_t hash;

    GUARD_OBJ(p, GetVpValue(self, 1));
    hash = (st_index_t)p->sign;
    /* hash!=2: the case for 0(1),NaN(0) or +-Infinity(3) is sign itself */
    if(hash == 2 || hash == (st_index_t)-2) {
        hash ^= rb_memhash(p->frac, sizeof(DECDIG)*p->Prec);
        hash += p->exponent;
    }
    return ST2FIX(hash);
}
infinite?() click to toggle source

Returns nil, -1, or +1 depending on whether the value is finite, -Infinity, or +Infinity.

static VALUE
BigDecimal_IsInfinite(VALUE self)
{
    Real *p = GetVpValue(self, 1);
    if (VpIsPosInf(p)) return INT2FIX(1);
    if (VpIsNegInf(p)) return INT2FIX(-1);
    return Qnil;
}
inspect() click to toggle source

Returns a string representation of self.

BigDecimal("1234.5678").inspect
  #=> "0.12345678e4"
static VALUE
BigDecimal_inspect(VALUE self)
{
    ENTER(5);
    Real *vp;
    volatile VALUE str;
    size_t nc;

    GUARD_OBJ(vp, GetVpValue(self, 1));
    nc = VpNumOfChars(vp, "E");

    str = rb_str_new(0, nc);
    VpToString(vp, RSTRING_PTR(str), RSTRING_LEN(str), 0, 0);
    rb_str_resize(str, strlen(RSTRING_PTR(str)));
    return str;
}
modulo(b)

Returns the modulus from dividing by b.

See BigDecimal#divmod.

Alias for: %
mult(other, ndigits) → bigdecimal click to toggle source

Returns the BigDecimal product of self and value with a precision of ndigits decimal digits.

When ndigits is less than the number of significant digits in the sum, the sum is rounded to that number of digits, according to the current rounding mode; see BigDecimal.mode.

Examples:

# Set the rounding mode.
BigDecimal.mode(BigDecimal::ROUND_MODE, :half_up)
b = BigDecimal('555555.555')
b.mult(3, 0)              # => 0.1666666665e7
b.mult(3, 3)              # => 0.167e7
b.mult(3, 6)              # => 0.166667e7
b.mult(3, 15)             # => 0.1666666665e7
b.mult(3.0, 0)            # => 0.1666666665e7
b.mult(Rational(3, 1), 0) # => 0.1666666665e7
b.mult(Complex(3, 0), 0)  # => (0.1666666665e7+0.0i)
static VALUE
BigDecimal_mult2(VALUE self, VALUE b, VALUE n)
{
    ENTER(2);
    Real *cv;
    SIGNED_VALUE mx = check_int_precision(n);
    if (mx == 0) return BigDecimal_mult(self, b);
    else {
        size_t pl = VpSetPrecLimit(0);
        VALUE   c = BigDecimal_mult(self, b);
        VpSetPrecLimit(pl);
        GUARD_OBJ(cv, GetVpValue(c, 1));
        VpLeftRound(cv, VpGetRoundMode(), mx);
        return VpCheckGetValue(cv);
    }
}
n_significant_digits → integer click to toggle source

Returns the number of decimal significant digits in self.

BigDecimal("0").n_significant_digits         # => 0
BigDecimal("1").n_significant_digits         # => 1
BigDecimal("1.1").n_significant_digits       # => 2
BigDecimal("3.1415").n_significant_digits    # => 5
BigDecimal("-1e20").n_significant_digits     # => 1
BigDecimal("1e-20").n_significant_digits     # => 1
BigDecimal("Infinity").n_significant_digits  # => 0
BigDecimal("-Infinity").n_significant_digits # => 0
BigDecimal("NaN").n_significant_digits       # => 0
static VALUE
BigDecimal_n_significant_digits(VALUE self)
{
    ENTER(1);

    Real *p;
    GUARD_OBJ(p, GetVpValue(self, 1));
    if (VpIsZero(p) || !VpIsDef(p)) {
        return INT2FIX(0);
    }

    ssize_t n = p->Prec;  /* The length of frac without trailing zeros. */
    for (n = p->Prec; n > 0 && p->frac[n-1] == 0; --n);
    if (n == 0) return INT2FIX(0);

    DECDIG x;
    int nlz = BASE_FIG;
    for (x = p->frac[0]; x > 0; x /= 10) --nlz;

    int ntz = 0;
    for (x = p->frac[n-1]; x > 0 && x % 10 == 0; x /= 10) ++ntz;

    ssize_t n_significant_digits = BASE_FIG*n - nlz - ntz;
    return SSIZET2NUM(n_significant_digits);
}
nan?() click to toggle source

Returns True if the value is Not a Number.

static VALUE
BigDecimal_IsNaN(VALUE self)
{
    Real *p = GetVpValue(self, 1);
    if (VpIsNaN(p))  return Qtrue;
    return Qfalse;
}
nonzero?() click to toggle source

Returns self if the value is non-zero, nil otherwise.

static VALUE
BigDecimal_nonzero(VALUE self)
{
    Real *a = GetVpValue(self, 1);
    return VpIsZero(a) ? Qnil : self;
}
power(n) click to toggle source
power(n, prec)

Returns the value raised to the power of n.

Note that n must be an Integer.

Also available as the operator **.

static VALUE
BigDecimal_power(int argc, VALUE*argv, VALUE self)
{
    ENTER(5);
    VALUE vexp, prec;
    Real* exp = NULL;
    Real *x, *y;
    ssize_t mp, ma, n;
    SIGNED_VALUE int_exp;
    double d;

    rb_scan_args(argc, argv, "11", &vexp, &prec);

    GUARD_OBJ(x, GetVpValue(self, 1));
    n = NIL_P(prec) ? (ssize_t)(x->Prec*VpBaseFig()) : NUM2SSIZET(prec);

    if (VpIsNaN(x)) {
        y = NewZeroWrapLimited(1, n);
        VpSetNaN(y);
        RB_GC_GUARD(y->obj);
        return VpCheckGetValue(y);
    }

  retry:
    switch (TYPE(vexp)) {
      case T_FIXNUM:
        break;

      case T_BIGNUM:
        break;

      case T_FLOAT:
        d = RFLOAT_VALUE(vexp);
        if (d == round(d)) {
            if (FIXABLE(d)) {
                vexp = LONG2FIX((long)d);
            }
            else {
                vexp = rb_dbl2big(d);
            }
            goto retry;
        }
        if (NIL_P(prec)) {
            n += BIGDECIMAL_DOUBLE_FIGURES;
        }
        exp = GetVpValueWithPrec(vexp, 0, 1);
        break;

      case T_RATIONAL:
        if (is_zero(rb_rational_num(vexp))) {
            if (is_positive(vexp)) {
                vexp = INT2FIX(0);
                goto retry;
            }
        }
        else if (is_one(rb_rational_den(vexp))) {
            vexp = rb_rational_num(vexp);
            goto retry;
        }
        exp = GetVpValueWithPrec(vexp, n, 1);
        if (NIL_P(prec)) {
            n += n;
        }
        break;

      case T_DATA:
        if (is_kind_of_BigDecimal(vexp)) {
            VALUE zero = INT2FIX(0);
            VALUE rounded = BigDecimal_round(1, &zero, vexp);
            if (RTEST(BigDecimal_eq(vexp, rounded))) {
                vexp = BigDecimal_to_i(vexp);
                goto retry;
            }
            if (NIL_P(prec)) {
                GUARD_OBJ(y, GetVpValue(vexp, 1));
                n += y->Prec*VpBaseFig();
            }
            exp = DATA_PTR(vexp);
            break;
        }
        /* fall through */
      default:
        rb_raise(rb_eTypeError,
                 "wrong argument type %"PRIsVALUE" (expected scalar Numeric)",
                 RB_OBJ_CLASSNAME(vexp));
    }

    if (VpIsZero(x)) {
        if (is_negative(vexp)) {
            y = NewZeroWrapNolimit(1, n);
            if (BIGDECIMAL_NEGATIVE_P(x)) {
                if (is_integer(vexp)) {
                    if (is_even(vexp)) {
                        /* (-0) ** (-even_integer)  -> Infinity */
                        VpSetPosInf(y);
                    }
                    else {
                        /* (-0) ** (-odd_integer)  -> -Infinity */
                        VpSetNegInf(y);
                    }
                }
                else {
                    /* (-0) ** (-non_integer)  -> Infinity */
                    VpSetPosInf(y);
                }
            }
            else {
                /* (+0) ** (-num)  -> Infinity */
                VpSetPosInf(y);
            }
            RB_GC_GUARD(y->obj);
            return VpCheckGetValue(y);
        }
        else if (is_zero(vexp)) {
            return VpCheckGetValue(NewOneWrapLimited(1, n));
        }
        else {
            return VpCheckGetValue(NewZeroWrapLimited(1, n));
        }
    }

    if (is_zero(vexp)) {
        return VpCheckGetValue(NewOneWrapLimited(1, n));
    }
    else if (is_one(vexp)) {
        return self;
    }

    if (VpIsInf(x)) {
        if (is_negative(vexp)) {
            if (BIGDECIMAL_NEGATIVE_P(x)) {
                if (is_integer(vexp)) {
                    if (is_even(vexp)) {
                        /* (-Infinity) ** (-even_integer) -> +0 */
                        return VpCheckGetValue(NewZeroWrapLimited(1, n));
                    }
                    else {
                        /* (-Infinity) ** (-odd_integer) -> -0 */
                        return VpCheckGetValue(NewZeroWrapLimited(-1, n));
                    }
                }
                else {
                    /* (-Infinity) ** (-non_integer) -> -0 */
                    return VpCheckGetValue(NewZeroWrapLimited(-1, n));
                }
            }
            else {
                return VpCheckGetValue(NewZeroWrapLimited(1, n));
            }
        }
        else {
            y = NewZeroWrapLimited(1, n);
            if (BIGDECIMAL_NEGATIVE_P(x)) {
                if (is_integer(vexp)) {
                    if (is_even(vexp)) {
                        VpSetPosInf(y);
                    }
                    else {
                        VpSetNegInf(y);
                    }
                }
                else {
                    /* TODO: support complex */
                    rb_raise(rb_eMathDomainError,
                            "a non-integral exponent for a negative base");
                }
            }
            else {
                VpSetPosInf(y);
            }
            return VpCheckGetValue(y);
        }
    }

    if (exp != NULL) {
        return bigdecimal_power_by_bigdecimal(x, exp, n);
    }
    else if (RB_TYPE_P(vexp, T_BIGNUM)) {
        VALUE abs_value = BigDecimal_abs(self);
        if (is_one(abs_value)) {
            return VpCheckGetValue(NewOneWrapLimited(1, n));
        }
        else if (RTEST(rb_funcall(abs_value, '<', 1, INT2FIX(1)))) {
            if (is_negative(vexp)) {
                y = NewZeroWrapLimited(1, n);
                VpSetInf(y, (is_even(vexp) ? 1 : -1) * VpGetSign(x));
                return VpCheckGetValue(y);
            }
            else if (BIGDECIMAL_NEGATIVE_P(x) && is_even(vexp)) {
                return VpCheckGetValue(NewZeroWrapLimited(-1, n));
            }
            else {
                return VpCheckGetValue(NewZeroWrapLimited(1, n));
            }
        }
        else {
            if (is_positive(vexp)) {
                y = NewZeroWrapLimited(1, n);
                VpSetInf(y, (is_even(vexp) ? 1 : -1) * VpGetSign(x));
                return VpCheckGetValue(y);
            }
            else if (BIGDECIMAL_NEGATIVE_P(x) && is_even(vexp)) {
                return VpCheckGetValue(NewZeroWrapLimited(-1, n));
            }
            else {
                return VpCheckGetValue(NewZeroWrapLimited(1, n));
            }
        }
    }

    int_exp = FIX2LONG(vexp);
    ma = int_exp;
    if (ma <  0) ma = -ma;
    if (ma == 0) ma = 1;

    if (VpIsDef(x)) {
        mp = x->Prec * (VpBaseFig() + 1);
        GUARD_OBJ(y, NewZeroWrapLimited(1, mp * (ma + 1)));
    }
    else {
        GUARD_OBJ(y, NewZeroWrapLimited(1, 1));
    }
    VpPowerByInt(y, x, int_exp);
    if (!NIL_P(prec) && VpIsDef(y)) {
        VpMidRound(y, VpGetRoundMode(), n);
    }
    return VpCheckGetValue(y);
}
precision → integer click to toggle source

Returns the number of decimal digits in self:

BigDecimal("0").precision         # => 0
BigDecimal("1").precision         # => 1
BigDecimal("1.1").precision       # => 2
BigDecimal("3.1415").precision    # => 5
BigDecimal("-1e20").precision     # => 21
BigDecimal("1e-20").precision     # => 20
BigDecimal("Infinity").precision  # => 0
BigDecimal("-Infinity").precision # => 0
BigDecimal("NaN").precision       # => 0
static VALUE
BigDecimal_precision(VALUE self)
{
    ssize_t precision;
    BigDecimal_count_precision_and_scale(self, &precision, NULL);
    return SSIZET2NUM(precision);
}
precision_scale → [integer, integer] click to toggle source

Returns a 2-length array; the first item is the result of BigDecimal#precision and the second one is of BigDecimal#scale.

See BigDecimal#precision. See BigDecimal#scale.

static VALUE
BigDecimal_precision_scale(VALUE self)
{
    ssize_t precision, scale;
    BigDecimal_count_precision_and_scale(self, &precision, &scale);
    return rb_assoc_new(SSIZET2NUM(precision), SSIZET2NUM(scale));
}
precs → array click to toggle source

Returns an Array of two Integer values that represent platform-dependent internal storage properties.

This method is deprecated and will be removed in the future. Instead, use BigDecimal#n_significant_digits for obtaining the number of significant digits in scientific notation, and BigDecimal#precision for obtaining the number of digits in decimal notation.

static VALUE
BigDecimal_prec(VALUE self)
{
    ENTER(1);
    Real *p;
    VALUE obj;

    rb_category_warn(RB_WARN_CATEGORY_DEPRECATED,
                     "BigDecimal#precs is deprecated and will be removed in the future; "
                     "use BigDecimal#precision instead.");

    GUARD_OBJ(p, GetVpValue(self, 1));
    obj = rb_assoc_new(SIZET2NUM(p->Prec*VpBaseFig()),
                       SIZET2NUM(p->MaxPrec*VpBaseFig()));
    return obj;
}
quo(value) → bigdecimal click to toggle source
quo(value, digits) → bigdecimal

Divide by the specified value.

digits

If specified and less than the number of significant digits of the result, the result is rounded to the given number of digits, according to the rounding mode indicated by BigDecimal.mode.

If digits is 0 or omitted, the result is the same as for the / operator.

See BigDecimal#/. See BigDecimal#div.

static VALUE
BigDecimal_quo(int argc, VALUE *argv, VALUE self)
{
    VALUE value, digits, result;
    SIGNED_VALUE n = -1;

    argc = rb_scan_args(argc, argv, "11", &value, &digits);
    if (argc > 1) {
        n = check_int_precision(digits);
    }

    if (n > 0) {
        result = BigDecimal_div2(self, value, digits);
    }
    else {
        result = BigDecimal_div(self, value);
    }

    return result;
}
remainder(value) click to toggle source

Returns the remainder from dividing by the value.

x.remainder(y) means x-y*(x/y).truncate

static VALUE
BigDecimal_remainder(VALUE self, VALUE r) /* remainder */
{
    VALUE  f;
    Real  *d, *rv = 0;
    f = BigDecimal_divremain(self, r, &d, &rv);
    if (!NIL_P(f)) return f;
    return VpCheckGetValue(rv);
}
round(n, mode) click to toggle source

Round to the nearest integer (by default), returning the result as a BigDecimal if n is specified, or as an Integer if it isn’t.

BigDecimal('3.14159').round #=> 3
BigDecimal('8.7').round #=> 9
BigDecimal('-9.9').round #=> -10

BigDecimal('3.14159').round(2).class.name #=> "BigDecimal"
BigDecimal('3.14159').round.class.name #=> "Integer"

If n is specified and positive, the fractional part of the result has no more than that many digits.

If n is specified and negative, at least that many digits to the left of the decimal point will be 0 in the result, and return value will be an Integer.

BigDecimal('3.14159').round(3) #=> 3.142
BigDecimal('13345.234').round(-2) #=> 13300

The value of the optional mode argument can be used to determine how rounding is performed; see BigDecimal.mode.

static VALUE
BigDecimal_round(int argc, VALUE *argv, VALUE self)
{
    ENTER(5);
    Real   *c, *a;
    int    iLoc = 0;
    VALUE  vLoc;
    VALUE  vRound;
    int    round_to_int = 0;
    size_t mx, pl;

    unsigned short sw = VpGetRoundMode();

    switch (rb_scan_args(argc, argv, "02", &vLoc, &vRound)) {
      case 0:
        iLoc = 0;
        round_to_int = 1;
        break;
      case 1:
        if (RB_TYPE_P(vLoc, T_HASH)) {
            sw = check_rounding_mode_option(vLoc);
        }
        else {
            iLoc = NUM2INT(vLoc);
            if (iLoc < 1) round_to_int = 1;
        }
        break;
      case 2:
        iLoc = NUM2INT(vLoc);
        if (RB_TYPE_P(vRound, T_HASH)) {
            sw = check_rounding_mode_option(vRound);
        }
        else {
            sw = check_rounding_mode(vRound);
        }
        break;
      default:
        break;
    }

    pl = VpSetPrecLimit(0);
    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec * (VpBaseFig() + 1);
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpSetPrecLimit(pl);
    VpActiveRound(c, a, sw, iLoc);
    if (round_to_int) {
        return BigDecimal_to_i(VpCheckGetValue(c));
    }
    return VpCheckGetValue(c);
}
scale → integer click to toggle source

Returns the number of decimal digits following the decimal digits in self.

BigDecimal("0").scale         # => 0
BigDecimal("1").scale         # => 1
BigDecimal("1.1").scale       # => 1
BigDecimal("3.1415").scale    # => 4
BigDecimal("-1e20").precision # => 0
BigDecimal("1e-20").precision # => 20
BigDecimal("Infinity").scale  # => 0
BigDecimal("-Infinity").scale # => 0
BigDecimal("NaN").scale       # => 0
static VALUE
BigDecimal_scale(VALUE self)
{
    ssize_t scale;
    BigDecimal_count_precision_and_scale(self, NULL, &scale);
    return SSIZET2NUM(scale);
}
sign() click to toggle source

Returns the sign of the value.

Returns a positive value if > 0, a negative value if < 0. It behaves the same with zeros - it returns a positive value for a positive zero (BigDecimal(‘0’)) and a negative value for a negative zero (BigDecimal(‘-0’)).

The specific value returned indicates the type and sign of the BigDecimal, as follows:

BigDecimal::SIGN_NaN

value is Not a Number

BigDecimal::SIGN_POSITIVE_ZERO

value is +0

BigDecimal::SIGN_NEGATIVE_ZERO

value is -0

BigDecimal::SIGN_POSITIVE_INFINITE

value is +Infinity

BigDecimal::SIGN_NEGATIVE_INFINITE

value is -Infinity

BigDecimal::SIGN_POSITIVE_FINITE

value is positive

BigDecimal::SIGN_NEGATIVE_FINITE

value is negative

static VALUE
BigDecimal_sign(VALUE self)
{ /* sign */
    int s = GetVpValue(self, 1)->sign;
    return INT2FIX(s);
}
split() click to toggle source

Splits a BigDecimal number into four parts, returned as an array of values.

The first value represents the sign of the BigDecimal, and is -1 or 1, or 0 if the BigDecimal is Not a Number.

The second value is a string representing the significant digits of the BigDecimal, with no leading zeros.

The third value is the base used for arithmetic (currently always 10) as an Integer.

The fourth value is an Integer exponent.

If the BigDecimal can be represented as 0.xxxxxx*10**n, then xxxxxx is the string of significant digits with no leading zeros, and n is the exponent.

From these values, you can translate a BigDecimal to a float as follows:

sign, significant_digits, base, exponent = a.split
f = sign * "0.#{significant_digits}".to_f * (base ** exponent)

(Note that the to_f method is provided as a more convenient way to translate a BigDecimal to a Float.)

static VALUE
BigDecimal_split(VALUE self)
{
    ENTER(5);
    Real *vp;
    VALUE obj,str;
    ssize_t e, s;
    char *psz1;

    GUARD_OBJ(vp, GetVpValue(self, 1));
    str = rb_str_new(0, VpNumOfChars(vp, "E"));
    psz1 = RSTRING_PTR(str);
    VpSzMantissa(vp, psz1, RSTRING_LEN(str));
    s = 1;
    if(psz1[0] == '-') {
        size_t len = strlen(psz1 + 1);

        memmove(psz1, psz1 + 1, len);
        psz1[len] = '\0';
        s = -1;
    }
    if (psz1[0] == 'N') s = 0; /* NaN */
    e = VpExponent10(vp);
    obj = rb_ary_new2(4);
    rb_ary_push(obj, INT2FIX(s));
    rb_ary_push(obj, str);
    rb_str_resize(str, strlen(psz1));
    rb_ary_push(obj, INT2FIX(10));
    rb_ary_push(obj, SSIZET2NUM(e));
    return obj;
}
sqrt(n) click to toggle source

Returns the square root of the value.

Result has at least n significant digits.

static VALUE
BigDecimal_sqrt(VALUE self, VALUE nFig)
{
    ENTER(5);
    Real *c, *a;
    size_t mx, n;

    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec * (VpBaseFig() + 1);

    n = check_int_precision(nFig);
    n += VpDblFig() + VpBaseFig();
    if (mx <= n) mx = n;
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpSqrt(c, a);
    return VpCheckGetValue(c);
}
sub(value, digits) → bigdecimal click to toggle source

Subtract the specified value.

e.g.

c = a.sub(b,n)
digits

If specified and less than the number of significant digits of the result, the result is rounded to that number of digits, according to BigDecimal.mode.

static VALUE
BigDecimal_sub2(VALUE self, VALUE b, VALUE n)
{
    ENTER(2);
    Real *cv;
    SIGNED_VALUE mx = check_int_precision(n);
    if (mx == 0) return BigDecimal_sub(self, b);
    else {
        size_t pl = VpSetPrecLimit(0);
        VALUE   c = BigDecimal_sub(self, b);
        VpSetPrecLimit(pl);
        GUARD_OBJ(cv, GetVpValue(c, 1));
        VpLeftRound(cv, VpGetRoundMode(), mx);
        return VpCheckGetValue(cv);
    }
}
to_d → bigdecimal click to toggle source

Returns self.

require 'bigdecimal/util'

d = BigDecimal("3.14")
d.to_d                       # => 0.314e1
# File ext/bigdecimal/lib/bigdecimal/util.rb, line 110
def to_d
  self
end
to_digits → string click to toggle source

Converts a BigDecimal to a String of the form “nnnnnn.mmm”. This method is deprecated; use BigDecimal#to_s(“F”) instead.

require 'bigdecimal/util'

d = BigDecimal("3.14")
d.to_digits                  # => "3.14"
# File ext/bigdecimal/lib/bigdecimal/util.rb, line 90
def to_digits
  if self.nan? || self.infinite? || self.zero?
    self.to_s
  else
    i       = self.to_i.to_s
    _,f,_,z = self.frac.split
    i + "." + ("0"*(-z)) + f
  end
end
to_f() click to toggle source

Returns a new Float object having approximately the same value as the BigDecimal number. Normal accuracy limits and built-in errors of binary Float arithmetic apply.

static VALUE
BigDecimal_to_f(VALUE self)
{
    ENTER(1);
    Real *p;
    double d;
    SIGNED_VALUE e;
    char *buf;
    volatile VALUE str;

    GUARD_OBJ(p, GetVpValue(self, 1));
    if (VpVtoD(&d, &e, p) != 1)
        return rb_float_new(d);
    if (e > (SIGNED_VALUE)(DBL_MAX_10_EXP+BASE_FIG))
        goto overflow;
    if (e < (SIGNED_VALUE)(DBL_MIN_10_EXP-BASE_FIG))
        goto underflow;

    str = rb_str_new(0, VpNumOfChars(p, "E"));
    buf = RSTRING_PTR(str);
    VpToString(p, buf, RSTRING_LEN(str), 0, 0);
    errno = 0;
    d = strtod(buf, 0);
    if (errno == ERANGE) {
        if (d == 0.0) goto underflow;
        if (fabs(d) >= HUGE_VAL) goto overflow;
    }
    return rb_float_new(d);

overflow:
    VpException(VP_EXCEPTION_OVERFLOW, "BigDecimal to Float conversion", 0);
    if (BIGDECIMAL_NEGATIVE_P(p))
        return rb_float_new(VpGetDoubleNegInf());
    else
        return rb_float_new(VpGetDoublePosInf());

underflow:
    VpException(VP_EXCEPTION_UNDERFLOW, "BigDecimal to Float conversion", 0);
    if (BIGDECIMAL_NEGATIVE_P(p))
        return rb_float_new(-0.0);
    else
        return rb_float_new(0.0);
}
to_i() click to toggle source

Returns the value as an Integer.

If the BigDecimal is infinity or NaN, raises FloatDomainError.

static VALUE
BigDecimal_to_i(VALUE self)
{
    ENTER(5);
    ssize_t e, nf;
    Real *p;

    GUARD_OBJ(p, GetVpValue(self, 1));
    BigDecimal_check_num(p);

    e = VpExponent10(p);
    if (e <= 0) return INT2FIX(0);
    nf = VpBaseFig();
    if (e <= nf) {
        return LONG2NUM((long)(VpGetSign(p) * (DECDIG_DBL_SIGNED)p->frac[0]));
    }
    else {
        VALUE a = BigDecimal_split(self);
        VALUE digits = RARRAY_AREF(a, 1);
        VALUE numerator = rb_funcall(digits, rb_intern("to_i"), 0);
        VALUE ret;
        ssize_t dpower = e - (ssize_t)RSTRING_LEN(digits);

        if (BIGDECIMAL_NEGATIVE_P(p)) {
            numerator = rb_funcall(numerator, '*', 1, INT2FIX(-1));
        }
        if (dpower < 0) {
            ret = rb_funcall(numerator, rb_intern("div"), 1,
                              rb_funcall(INT2FIX(10), rb_intern("**"), 1,
                                         INT2FIX(-dpower)));
        }
        else {
            ret = rb_funcall(numerator, '*', 1,
                             rb_funcall(INT2FIX(10), rb_intern("**"), 1,
                                        INT2FIX(dpower)));
        }
        if (RB_TYPE_P(ret, T_FLOAT)) {
            rb_raise(rb_eFloatDomainError, "Infinity");
        }
        return ret;
    }
}
Also aliased as: to_int
to_int()

Returns the value as an Integer.

If the BigDecimal is infinity or NaN, raises FloatDomainError.

Alias for: to_i
to_json(*args) click to toggle source

return the JSON value

# File ext/json/lib/json/add/bigdecimal.rb, line 26
def to_json(*args)
  as_json.to_json(*args)
end
to_r() click to toggle source

Converts a BigDecimal to a Rational.

static VALUE
BigDecimal_to_r(VALUE self)
{
    Real *p;
    ssize_t sign, power, denomi_power;
    VALUE a, digits, numerator;

    p = GetVpValue(self, 1);
    BigDecimal_check_num(p);

    sign = VpGetSign(p);
    power = VpExponent10(p);
    a = BigDecimal_split(self);
    digits = RARRAY_AREF(a, 1);
    denomi_power = power - RSTRING_LEN(digits);
    numerator = rb_funcall(digits, rb_intern("to_i"), 0);

    if (sign < 0) {
        numerator = rb_funcall(numerator, '*', 1, INT2FIX(-1));
    }
    if (denomi_power < 0) {
        return rb_Rational(numerator,
                           rb_funcall(INT2FIX(10), rb_intern("**"), 1,
                                      INT2FIX(-denomi_power)));
    }
    else {
        return rb_Rational1(rb_funcall(numerator, '*', 1,
                                       rb_funcall(INT2FIX(10), rb_intern("**"), 1,
                                                  INT2FIX(denomi_power))));
    }
}
to_s(s) click to toggle source

Converts the value to a string.

The default format looks like 0.xxxxEnn.

The optional parameter s consists of either an integer; or an optional ‘+’ or ‘ ’, followed by an optional number, followed by an optional ‘E’ or ‘F’.

If there is a ‘+’ at the start of s, positive values are returned with a leading ‘+’.

A space at the start of s returns positive values with a leading space.

If s contains a number, a space is inserted after each group of that many fractional digits.

If s ends with an ‘E’, engineering notation (0.xxxxEnn) is used.

If s ends with an ‘F’, conventional floating point notation is used.

Examples:

BigDecimal('-123.45678901234567890').to_s('5F')
  #=> '-123.45678 90123 45678 9'

BigDecimal('123.45678901234567890').to_s('+8F')
  #=> '+123.45678901 23456789'

BigDecimal('123.45678901234567890').to_s(' F')
  #=> ' 123.4567890123456789'
static VALUE
BigDecimal_to_s(int argc, VALUE *argv, VALUE self)
{
    ENTER(5);
    int   fmt = 0;   /* 0: E format, 1: F format */
    int   fPlus = 0; /* 0: default, 1: set ' ' before digits, 2: set '+' before digits. */
    Real  *vp;
    volatile VALUE str;
    char  *psz;
    char   ch;
    size_t nc, mc = 0;
    SIGNED_VALUE m;
    VALUE  f;

    GUARD_OBJ(vp, GetVpValue(self, 1));

    if (rb_scan_args(argc, argv, "01", &f) == 1) {
        if (RB_TYPE_P(f, T_STRING)) {
            psz = StringValueCStr(f);
            if (*psz == ' ') {
                fPlus = 1;
                psz++;
            }
            else if (*psz == '+') {
                fPlus = 2;
                psz++;
            }
            while ((ch = *psz++) != 0) {
                if (ISSPACE(ch)) {
                    continue;
                }
                if (!ISDIGIT(ch)) {
                    if (ch == 'F' || ch == 'f') {
                        fmt = 1; /* F format */
                    }
                    break;
                }
                mc = mc*10 + ch - '0';
            }
        }
        else {
            m = NUM2INT(f);
            if (m <= 0) {
                rb_raise(rb_eArgError, "argument must be positive");
            }
            mc = (size_t)m;
        }
    }
    if (fmt) {
        nc = VpNumOfChars(vp, "F");
    }
    else {
        nc = VpNumOfChars(vp, "E");
    }
    if (mc > 0) {
        nc += (nc + mc - 1) / mc + 1;
    }

    str = rb_usascii_str_new(0, nc);
    psz = RSTRING_PTR(str);

    if (fmt) {
        VpToFString(vp, psz, RSTRING_LEN(str), mc, fPlus);
    }
    else {
        VpToString (vp, psz, RSTRING_LEN(str), mc, fPlus);
    }
    rb_str_resize(str, strlen(psz));
    return str;
}
truncate(n) click to toggle source

Truncate to the nearest integer (by default), returning the result as a BigDecimal.

BigDecimal('3.14159').truncate #=> 3
BigDecimal('8.7').truncate #=> 8
BigDecimal('-9.9').truncate #=> -9

If n is specified and positive, the fractional part of the result has no more than that many digits.

If n is specified and negative, at least that many digits to the left of the decimal point will be 0 in the result.

BigDecimal('3.14159').truncate(3) #=> 3.141
BigDecimal('13345.234').truncate(-2) #=> 13300.0
static VALUE
BigDecimal_truncate(int argc, VALUE *argv, VALUE self)
{
    ENTER(5);
    Real *c, *a;
    int iLoc;
    VALUE vLoc;
    size_t mx, pl = VpSetPrecLimit(0);

    if (rb_scan_args(argc, argv, "01", &vLoc) == 0) {
        iLoc = 0;
    }
    else {
        iLoc = NUM2INT(vLoc);
    }

    GUARD_OBJ(a, GetVpValue(self, 1));
    mx = a->Prec * (VpBaseFig() + 1);
    GUARD_OBJ(c, NewZeroWrapLimited(1, mx));
    VpSetPrecLimit(pl);
    VpActiveRound(c, a, VP_ROUND_DOWN, iLoc); /* 0: truncate */
    if (argc == 0) {
        return BigDecimal_to_i(VpCheckGetValue(c));
    }
    return VpCheckGetValue(c);
}
zero?() click to toggle source

Returns True if the value is zero.

static VALUE
BigDecimal_zero(VALUE self)
{
    Real *a = GetVpValue(self, 1);
    return VpIsZero(a) ? Qtrue : Qfalse;
}