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215 lines
5.2 KiB
V
215 lines
5.2 KiB
V
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module math
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import math.internal
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const (
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f64_max_exp = f64(1024)
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f64_min_exp = f64(-1021)
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threshold = 7.09782712893383973096e+02 // 0x40862E42FEFA39EF
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ln2_x56 = 3.88162421113569373274e+01 // 0x4043687a9f1af2b1
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ln2_halfx3 = 1.03972077083991796413e+00 // 0x3ff0a2b23f3bab73
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ln2_half = 3.46573590279972654709e-01 // 0x3fd62e42fefa39ef
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ln2hi = 6.93147180369123816490e-01 // 0x3fe62e42fee00000
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ln2lo = 1.90821492927058770002e-10 // 0x3dea39ef35793c76
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inv_ln2 = 1.44269504088896338700e+00 // 0x3ff71547652b82fe
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// scaled coefficients related to expm1
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expm1_q1 = -3.33333333333331316428e-02 // 0xBFA11111111110F4
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expm1_q2 = 1.58730158725481460165e-03 // 0x3F5A01A019FE5585
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expm1_q3 = -7.93650757867487942473e-05 // 0xBF14CE199EAADBB7
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expm1_q4 = 4.00821782732936239552e-06 // 0x3ED0CFCA86E65239
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expm1_q5 = -2.01099218183624371326e-07 // 0xBE8AFDB76E09C32D
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)
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// exp returns e**x, the base-e exponential of x.
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//
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// special cases are:
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// exp(+inf) = +inf
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// exp(nan) = nan
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// Very large values overflow to 0 or +inf.
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// Very small values underflow to 1.
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pub fn exp(x f64) f64 {
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log2e := 1.44269504088896338700e+00
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overflow := 7.09782712893383973096e+02
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underflow := -7.45133219101941108420e+02
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near_zero := 1.0 / (1 << 28) // 2**-28
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// special cases
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if is_nan(x) || is_inf(x, 1) {
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return x
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}
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if is_inf(x, -1) {
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return 0.0
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}
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if x > overflow {
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return inf(1)
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}
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if x < underflow {
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return 0.0
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}
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if -near_zero < x && x < near_zero {
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return 1.0 + x
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}
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// reduce; computed as r = hi - lo for extra precision.
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mut k := 0
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if x < 0 {
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k = int(log2e * x - 0.5)
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}
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if x > 0 {
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k = int(log2e * x + 0.5)
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}
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hi := x - f64(k) * math.ln2hi
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lo := f64(k) * math.ln2lo
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// compute
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return expmulti(hi, lo, k)
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}
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// exp2 returns 2**x, the base-2 exponential of x.
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//
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// special cases are the same as exp.
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pub fn exp2(x f64) f64 {
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overflow := 1.0239999999999999e+03
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underflow := -1.0740e+03
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if is_nan(x) || is_inf(x, 1) {
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return x
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}
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if is_inf(x, -1) {
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return 0
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}
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if x > overflow {
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return inf(1)
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}
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if x < underflow {
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return 0
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}
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// argument reduction; x = r×lg(e) + k with |r| ≤ ln(2)/2.
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// computed as r = hi - lo for extra precision.
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mut k := 0
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if x > 0 {
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k = int(x + 0.5)
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}
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if x < 0 {
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k = int(x - 0.5)
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}
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mut t := x - f64(k)
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hi := t * math.ln2hi
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lo := -t * math.ln2lo
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// compute
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return expmulti(hi, lo, k)
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}
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pub fn ldexp(x f64, e int) f64 {
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if x == 0.0 {
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return x
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} else {
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mut y, ex := frexp(x)
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mut e2 := f64(e + ex)
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if e2 >= math.f64_max_exp {
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y *= pow(2.0, e2 - math.f64_max_exp + 1.0)
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e2 = math.f64_max_exp - 1.0
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} else if e2 <= math.f64_min_exp {
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y *= pow(2.0, e2 - math.f64_min_exp - 1.0)
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e2 = math.f64_min_exp + 1.0
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}
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return y * pow(2.0, e2)
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}
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}
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// frexp breaks f into a normalized fraction
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// and an integral power of two.
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// It returns frac and exp satisfying f == frac × 2**exp,
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// with the absolute value of frac in the interval [½, 1).
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//
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// special cases are:
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// frexp(±0) = ±0, 0
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// frexp(±inf) = ±inf, 0
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// frexp(nan) = nan, 0
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// pub fn frexp(f f64) (f64, int) {
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// // special cases
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// if f == 0.0 {
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// return f, 0 // correctly return -0
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// }
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// if is_inf(f, 0) || is_nan(f) {
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// return f, 0
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// }
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// f_norm, mut exp := normalize(f)
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// mut x := f64_bits(f_norm)
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// exp += int((x>>shift)&mask) - bias + 1
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// x &= ~(mask << shift)
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// x |= (-1 + bias) << shift
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// return f64_from_bits(x), exp
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pub fn frexp(x f64) (f64, int) {
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if x == 0.0 {
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return 0.0, 0
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} else if !is_finite(x) {
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return x, 0
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} else if abs(x) >= 0.5 && abs(x) < 1 { // Handle the common case
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return x, 0
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} else {
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ex := ceil(log(abs(x)) / ln2)
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mut ei := int(ex) // Prevent underflow and overflow of 2**(-ei)
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if ei < int(math.f64_min_exp) {
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ei = int(math.f64_min_exp)
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}
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if ei > -int(math.f64_min_exp) {
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ei = -int(math.f64_min_exp)
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}
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mut f := x * pow(2.0, -ei)
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if !is_finite(f) { // This should not happen
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return f, 0
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}
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for abs(f) >= 1.0 {
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ei++
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f /= 2.0
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}
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for abs(f) > 0 && abs(f) < 0.5 {
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ei--
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f *= 2.0
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}
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return f, ei
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}
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}
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// special cases are:
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// expm1(+inf) = +inf
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// expm1(-inf) = -1
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// expm1(nan) = nan
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pub fn expm1(x f64) f64 {
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if is_inf(x, 1) || is_nan(x) {
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return x
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}
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if is_inf(x, -1) {
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return f64(-1)
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}
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// FIXME: this should be improved
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if abs(x) < ln2 { // Compute the taylor series S = x + (1/2!) x^2 + (1/3!) x^3 + ...
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mut i := 1.0
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mut sum := x
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mut term := x / 1.0
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i++
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term *= x / f64(i)
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sum += term
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for abs(term) > abs(sum) * internal.f64_epsilon {
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i++
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term *= x / f64(i)
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sum += term
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}
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return sum
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} else {
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return exp(x) - 1
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}
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}
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// exp1 returns e**r × 2**k where r = hi - lo and |r| ≤ ln(2)/2.
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fn expmulti(hi f64, lo f64, k int) f64 {
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exp_p1 := 1.66666666666666657415e-01 // 0x3FC55555; 0x55555555
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exp_p2 := -2.77777777770155933842e-03 // 0xBF66C16C; 0x16BEBD93
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exp_p3 := 6.61375632143793436117e-05 // 0x3F11566A; 0xAF25DE2C
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exp_p4 := -1.65339022054652515390e-06 // 0xBEBBBD41; 0xC5D26BF1
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exp_p5 := 4.13813679705723846039e-08 // 0x3E663769; 0x72BEA4D0
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r := hi - lo
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t := r * r
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c := r - t * (exp_p1 + t * (exp_p2 + t * (exp_p3 + t * (exp_p4 + t * exp_p5))))
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y := 1 - ((lo - (r * c) / (2 - c)) - hi)
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// TODO(rsc): make sure ldexp can handle boundary k
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return ldexp(y, k)
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}
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