\(\int \frac {1-x^3}{x^3 (1-x^3+x^6)} \, dx\) [58]

Optimal result

Integrand size = 23, antiderivative size = 418 \[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=-\frac {1}{2 x^2}+\frac {\left (i+\sqrt {3}\right ) \arctan \left (\frac {1+\frac {2 x}{\sqrt [3]{\frac {1}{2} \left (1-i \sqrt {3}\right )}}}{\sqrt {3}}\right )}{3 \sqrt [3]{2} \left (1-i \sqrt {3}\right )^{2/3}}-\frac {\left (i-\sqrt {3}\right ) \arctan \left (\frac {1+\frac {2 x}{\sqrt [3]{\frac {1}{2} \left (1+i \sqrt {3}\right )}}}{\sqrt {3}}\right )}{3 \sqrt [3]{2} \left (1+i \sqrt {3}\right )^{2/3}}-\frac {\left (3+i \sqrt {3}\right ) \log \left (\sqrt [3]{1-i \sqrt {3}}-\sqrt [3]{2} x\right )}{9 \sqrt [3]{2} \left (1-i \sqrt {3}\right )^{2/3}}-\frac {\left (3-i \sqrt {3}\right ) \log \left (\sqrt [3]{1+i \sqrt {3}}-\sqrt [3]{2} x\right )}{9 \sqrt [3]{2} \left (1+i \sqrt {3}\right )^{2/3}}+\frac {\left (3+i \sqrt {3}\right ) \log \left (\left (1-i \sqrt {3}\right )^{2/3}+\sqrt [3]{2 \left (1-i \sqrt {3}\right )} x+2^{2/3} x^2\right )}{18 \sqrt [3]{2} \left (1-i \sqrt {3}\right )^{2/3}}+\frac {\left (3-i \sqrt {3}\right ) \log \left (\left (1+i \sqrt {3}\right )^{2/3}+\sqrt [3]{2 \left (1+i \sqrt {3}\right )} x+2^{2/3} x^2\right )}{18 \sqrt [3]{2} \left (1+i \sqrt {3}\right )^{2/3}} \] Output:

-1/2/x^2+1/6*(3^(1/2)+I)*arctan(1/3*(1+2*x/(1/2-1/2*I*3^(1/2))^(1/3))*3^(1 
/2))*2^(2/3)/(1-I*3^(1/2))^(2/3)-1/6*(I-3^(1/2))*arctan(1/3*(1+2*x/(1/2+1/ 
2*I*3^(1/2))^(1/3))*3^(1/2))*2^(2/3)/(1+I*3^(1/2))^(2/3)-1/18*(3+I*3^(1/2) 
)*ln((1-I*3^(1/2))^(1/3)-2^(1/3)*x)*2^(2/3)/(1-I*3^(1/2))^(2/3)-1/18*(3-I* 
3^(1/2))*ln((1+I*3^(1/2))^(1/3)-2^(1/3)*x)*2^(2/3)/(1+I*3^(1/2))^(2/3)+1/3 
6*(3+I*3^(1/2))*ln((1-I*3^(1/2))^(2/3)+(2-2*I*3^(1/2))^(1/3)*x+2^(2/3)*x^2 
)*2^(2/3)/(1-I*3^(1/2))^(2/3)+1/36*(3-I*3^(1/2))*ln((1+I*3^(1/2))^(2/3)+(2 
+2*I*3^(1/2))^(1/3)*x+2^(2/3)*x^2)*2^(2/3)/(1+I*3^(1/2))^(2/3)
 

Mathematica [C] (verified)

Result contains higher order function than in optimal. Order 9 vs. order 3 in optimal.

Time = 0.01 (sec) , antiderivative size = 47, normalized size of antiderivative = 0.11 \[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=-\frac {1}{2 x^2}-\frac {1}{3} \text {RootSum}\left [1-\text {$\#$1}^3+\text {$\#$1}^6\&,\frac {\log (x-\text {$\#$1}) \text {$\#$1}}{-1+2 \text {$\#$1}^3}\&\right ] \] Input:

Integrate[(1 - x^3)/(x^3*(1 - x^3 + x^6)),x]
 

Output:

-1/2*1/x^2 - RootSum[1 - #1^3 + #1^6 & , (Log[x - #1]*#1)/(-1 + 2*#1^3) & 
]/3
 

Rubi [A] (verified)

Time = 0.56 (sec) , antiderivative size = 356, normalized size of antiderivative = 0.85, number of steps used = 11, number of rules used = 10, \(\frac {\text {number of rules}}{\text {integrand size}}\) = 0.435, Rules used = {1828, 27, 1710, 750, 16, 25, 1142, 1082, 217, 1103}

Below are the steps used by Rubi to obtain the solution. The rule number used for the transformation is given above next to the arrow. The rules definitions used are listed below.

Input:

Int[(1 - x^3)/(x^3*(1 - x^3 + x^6)),x]
 

Output:

-1/2*1/x^2 - ((3 + I*Sqrt[3])*(Log[(1 - I*Sqrt[3])^(1/3) - 2^(1/3)*x]/(3*( 
(1 - I*Sqrt[3])/2)^(2/3)) - (Sqrt[3]*ArcTan[(1 + (2*x)/((1 - I*Sqrt[3])/2) 
^(1/3))/Sqrt[3]] + Log[(1 - I*Sqrt[3])^(2/3) + (2*(1 - I*Sqrt[3]))^(1/3)*x 
 + 2^(2/3)*x^2]/2)/(3*((1 - I*Sqrt[3])/2)^(2/3))))/6 - ((3 - I*Sqrt[3])*(L 
og[(1 + I*Sqrt[3])^(1/3) - 2^(1/3)*x]/(3*((1 + I*Sqrt[3])/2)^(2/3)) - (Sqr 
t[3]*ArcTan[(1 + (2*x)/((1 + I*Sqrt[3])/2)^(1/3))/Sqrt[3]] + Log[(1 + I*Sq 
rt[3])^(2/3) + (2*(1 + I*Sqrt[3]))^(1/3)*x + 2^(2/3)*x^2]/2)/(3*((1 + I*Sq 
rt[3])/2)^(2/3))))/6
 

Defintions of rubi rules used

Int[(c_.)/((a_.) + (b_.)*(x_)), x_Symbol] :> Simp[c*(Log[RemoveContent[a + 
b*x, x]]/b), x] /; FreeQ[{a, b, c}, x]
 

Int[-(Fx_), x_Symbol] :> Simp[Identity[-1]   Int[Fx, x], x]
 

Int[(a_)*(Fx_), x_Symbol] :> Simp[a   Int[Fx, x], x] /; FreeQ[a, x] &&  !Ma 
tchQ[Fx, (b_)*(Gx_) /; FreeQ[b, x]]
 

Int[((a_) + (b_.)*(x_)^2)^(-1), x_Symbol] :> Simp[(-(Rt[-a, 2]*Rt[-b, 2])^( 
-1))*ArcTan[Rt[-b, 2]*(x/Rt[-a, 2])], x] /; FreeQ[{a, b}, x] && PosQ[a/b] & 
& (LtQ[a, 0] || LtQ[b, 0])
 

Int[((a_) + (b_.)*(x_)^3)^(-1), x_Symbol] :> Simp[1/(3*Rt[a, 3]^2)   Int[1/ 
(Rt[a, 3] + Rt[b, 3]*x), x], x] + Simp[1/(3*Rt[a, 3]^2)   Int[(2*Rt[a, 3] - 
 Rt[b, 3]*x)/(Rt[a, 3]^2 - Rt[a, 3]*Rt[b, 3]*x + Rt[b, 3]^2*x^2), x], x] /; 
 FreeQ[{a, b}, x]
 

Int[((a_) + (b_.)*(x_) + (c_.)*(x_)^2)^(-1), x_Symbol] :> With[{q = 1 - 4*S 
implify[a*(c/b^2)]}, Simp[-2/b   Subst[Int[1/(q - x^2), x], x, 1 + 2*c*(x/b 
)], x] /; RationalQ[q] && (EqQ[q^2, 1] ||  !RationalQ[b^2 - 4*a*c])] /; Fre 
eQ[{a, b, c}, x]
 

Int[((d_) + (e_.)*(x_))/((a_.) + (b_.)*(x_) + (c_.)*(x_)^2), x_Symbol] :> S 
imp[d*(Log[RemoveContent[a + b*x + c*x^2, x]]/b), x] /; FreeQ[{a, b, c, d, 
e}, x] && EqQ[2*c*d - b*e, 0]
 

Int[((d_.) + (e_.)*(x_))/((a_) + (b_.)*(x_) + (c_.)*(x_)^2), x_Symbol] :> S 
imp[(2*c*d - b*e)/(2*c)   Int[1/(a + b*x + c*x^2), x], x] + Simp[e/(2*c) 
Int[(b + 2*c*x)/(a + b*x + c*x^2), x], x] /; FreeQ[{a, b, c, d, e}, x]
 

Int[((d_.)*(x_))^(m_)/((a_) + (c_.)*(x_)^(n2_.) + (b_.)*(x_)^(n_)), x_Symbo 
l] :> With[{q = Rt[b^2 - 4*a*c, 2]}, Simp[(d^n/2)*(b/q + 1)   Int[(d*x)^(m 
- n)/(b/2 + q/2 + c*x^n), x], x] - Simp[(d^n/2)*(b/q - 1)   Int[(d*x)^(m - 
n)/(b/2 - q/2 + c*x^n), x], x]] /; FreeQ[{a, b, c, d}, x] && EqQ[n2, 2*n] & 
& NeQ[b^2 - 4*a*c, 0] && IGtQ[n, 0] && GeQ[m, n]
 

Int[((f_.)*(x_))^(m_.)*((d_) + (e_.)*(x_)^(n_))*((a_) + (b_.)*(x_)^(n_) + ( 
c_.)*(x_)^(n2_))^(p_), x_Symbol] :> Simp[d*(f*x)^(m + 1)*((a + b*x^n + c*x^ 
(2*n))^(p + 1)/(a*f*(m + 1))), x] + Simp[1/(a*f^n*(m + 1))   Int[(f*x)^(m + 
 n)*(a + b*x^n + c*x^(2*n))^p*Simp[a*e*(m + 1) - b*d*(m + n*(p + 1) + 1) - 
c*d*(m + 2*n*(p + 1) + 1)*x^n, x], x], x] /; FreeQ[{a, b, c, d, e, f, p}, x 
] && EqQ[n2, 2*n] && NeQ[b^2 - 4*a*c, 0] && IGtQ[n, 0] && LtQ[m, -1] && Int 
egerQ[p]
 

Maple [C] (verified)

Result contains higher order function than in optimal. Order 9 vs. order 3.

Time = 0.04 (sec) , antiderivative size = 38, normalized size of antiderivative = 0.09

Input:

int((-x^3+1)/x^3/(x^6-x^3+1),x,method=_RETURNVERBOSE)
 

Output:

-1/2/x^2+1/3*sum(_R*ln(-18*_R^4+3*_R+x),_R=RootOf(27*_Z^6-9*_Z^3+1))
 

Fricas [A] (verification not implemented)

Time = 0.07 (sec) , antiderivative size = 255, normalized size of antiderivative = 0.61 \[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=\frac {2 \, x^{2} {\left (\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} \log \left (x - 3 \, \sqrt {-\frac {1}{3}} {\left (\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}}\right ) + 2 \, x^{2} {\left (-\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} \log \left (x + 3 \, \sqrt {-\frac {1}{3}} {\left (-\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}}\right ) - {\left (\sqrt {-3} x^{2} + x^{2}\right )} {\left (\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} \log \left (3 \, \sqrt {-\frac {1}{3}} {\left (\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} {\left (\sqrt {-3} + 1\right )} + 2 \, x\right ) - {\left (\sqrt {-3} x^{2} + x^{2}\right )} {\left (-\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} \log \left (-3 \, \sqrt {-\frac {1}{3}} {\left (-\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} {\left (\sqrt {-3} + 1\right )} + 2 \, x\right ) + {\left (\sqrt {-3} x^{2} - x^{2}\right )} {\left (\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} \log \left (-3 \, \sqrt {-\frac {1}{3}} {\left (\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} {\left (\sqrt {-3} - 1\right )} + 2 \, x\right ) + {\left (\sqrt {-3} x^{2} - x^{2}\right )} {\left (-\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} \log \left (3 \, \sqrt {-\frac {1}{3}} {\left (-\frac {1}{6} \, \sqrt {-\frac {1}{3}} + \frac {1}{6}\right )}^{\frac {1}{3}} {\left (\sqrt {-3} - 1\right )} + 2 \, x\right ) - 3}{6 \, x^{2}} \] Input:

integrate((-x^3+1)/x^3/(x^6-x^3+1),x, algorithm="fricas")
 

Output:

1/6*(2*x^2*(1/6*sqrt(-1/3) + 1/6)^(1/3)*log(x - 3*sqrt(-1/3)*(1/6*sqrt(-1/ 
3) + 1/6)^(1/3)) + 2*x^2*(-1/6*sqrt(-1/3) + 1/6)^(1/3)*log(x + 3*sqrt(-1/3 
)*(-1/6*sqrt(-1/3) + 1/6)^(1/3)) - (sqrt(-3)*x^2 + x^2)*(1/6*sqrt(-1/3) + 
1/6)^(1/3)*log(3*sqrt(-1/3)*(1/6*sqrt(-1/3) + 1/6)^(1/3)*(sqrt(-3) + 1) + 
2*x) - (sqrt(-3)*x^2 + x^2)*(-1/6*sqrt(-1/3) + 1/6)^(1/3)*log(-3*sqrt(-1/3 
)*(-1/6*sqrt(-1/3) + 1/6)^(1/3)*(sqrt(-3) + 1) + 2*x) + (sqrt(-3)*x^2 - x^ 
2)*(1/6*sqrt(-1/3) + 1/6)^(1/3)*log(-3*sqrt(-1/3)*(1/6*sqrt(-1/3) + 1/6)^( 
1/3)*(sqrt(-3) - 1) + 2*x) + (sqrt(-3)*x^2 - x^2)*(-1/6*sqrt(-1/3) + 1/6)^ 
(1/3)*log(3*sqrt(-1/3)*(-1/6*sqrt(-1/3) + 1/6)^(1/3)*(sqrt(-3) - 1) + 2*x) 
 - 3)/x^2
 

Sympy [A] (verification not implemented)

Time = 0.08 (sec) , antiderivative size = 32, normalized size of antiderivative = 0.08 \[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=- \operatorname {RootSum} {\left (19683 t^{6} + 243 t^{3} + 1, \left ( t \mapsto t \log {\left (- 1458 t^{4} - 9 t + x \right )} \right )\right )} - \frac {1}{2 x^{2}} \] Input:

integrate((-x**3+1)/x**3/(x**6-x**3+1),x)
 

Output:

-RootSum(19683*_t**6 + 243*_t**3 + 1, Lambda(_t, _t*log(-1458*_t**4 - 9*_t 
 + x))) - 1/(2*x**2)
 

Maxima [F]

\[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=\int { -\frac {x^{3} - 1}{{\left (x^{6} - x^{3} + 1\right )} x^{3}} \,d x } \] Input:

integrate((-x^3+1)/x^3/(x^6-x^3+1),x, algorithm="maxima")
 

Output:

-1/2/x^2 - integrate(x^3/(x^6 - x^3 + 1), x)
 

Giac [B] (verification not implemented)

Both result and optimal contain complex but leaf count of result is larger than twice the leaf count of optimal. 645 vs. \(2 (260) = 520\).

Time = 0.14 (sec) , antiderivative size = 645, normalized size of antiderivative = 1.54 \[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=\text {Too large to display} \] Input:

integrate((-x^3+1)/x^3/(x^6-x^3+1),x, algorithm="giac")
 

Output:

1/9*(2*sqrt(3)*cos(4/9*pi)^4 - 12*sqrt(3)*cos(4/9*pi)^2*sin(4/9*pi)^2 + 2* 
sqrt(3)*sin(4/9*pi)^4 + 8*cos(4/9*pi)^3*sin(4/9*pi) - 8*cos(4/9*pi)*sin(4/ 
9*pi)^3 + sqrt(3)*cos(4/9*pi) + sin(4/9*pi))*arctan(1/2*((-I*sqrt(3) - 1)* 
cos(4/9*pi) + 2*x)/((1/2*I*sqrt(3) + 1/2)*sin(4/9*pi))) + 1/9*(2*sqrt(3)*c 
os(2/9*pi)^4 - 12*sqrt(3)*cos(2/9*pi)^2*sin(2/9*pi)^2 + 2*sqrt(3)*sin(2/9* 
pi)^4 + 8*cos(2/9*pi)^3*sin(2/9*pi) - 8*cos(2/9*pi)*sin(2/9*pi)^3 + sqrt(3 
)*cos(2/9*pi) + sin(2/9*pi))*arctan(1/2*((-I*sqrt(3) - 1)*cos(2/9*pi) + 2* 
x)/((1/2*I*sqrt(3) + 1/2)*sin(2/9*pi))) + 1/9*(2*sqrt(3)*cos(1/9*pi)^4 - 1 
2*sqrt(3)*cos(1/9*pi)^2*sin(1/9*pi)^2 + 2*sqrt(3)*sin(1/9*pi)^4 - 8*cos(1/ 
9*pi)^3*sin(1/9*pi) + 8*cos(1/9*pi)*sin(1/9*pi)^3 - sqrt(3)*cos(1/9*pi) + 
sin(1/9*pi))*arctan(-1/2*((-I*sqrt(3) - 1)*cos(1/9*pi) - 2*x)/((1/2*I*sqrt 
(3) + 1/2)*sin(1/9*pi))) + 1/18*(8*sqrt(3)*cos(4/9*pi)^3*sin(4/9*pi) - 8*s 
qrt(3)*cos(4/9*pi)*sin(4/9*pi)^3 - 2*cos(4/9*pi)^4 + 12*cos(4/9*pi)^2*sin( 
4/9*pi)^2 - 2*sin(4/9*pi)^4 + sqrt(3)*sin(4/9*pi) - cos(4/9*pi))*log((-I*s 
qrt(3)*cos(4/9*pi) - cos(4/9*pi))*x + x^2 + 1) + 1/18*(8*sqrt(3)*cos(2/9*p 
i)^3*sin(2/9*pi) - 8*sqrt(3)*cos(2/9*pi)*sin(2/9*pi)^3 - 2*cos(2/9*pi)^4 + 
 12*cos(2/9*pi)^2*sin(2/9*pi)^2 - 2*sin(2/9*pi)^4 + sqrt(3)*sin(2/9*pi) - 
cos(2/9*pi))*log((-I*sqrt(3)*cos(2/9*pi) - cos(2/9*pi))*x + x^2 + 1) - 1/1 
8*(8*sqrt(3)*cos(1/9*pi)^3*sin(1/9*pi) - 8*sqrt(3)*cos(1/9*pi)*sin(1/9*pi) 
^3 + 2*cos(1/9*pi)^4 - 12*cos(1/9*pi)^2*sin(1/9*pi)^2 + 2*sin(1/9*pi)^4...
 

Mupad [B] (verification not implemented)

Time = 20.88 (sec) , antiderivative size = 332, normalized size of antiderivative = 0.79 \[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=\frac {\ln \left (x+\frac {2^{2/3}\,3^{5/6}\,{\left (3-\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,1{}\mathrm {i}}{6}\right )\,{\left (36-\sqrt {3}\,12{}\mathrm {i}\right )}^{1/3}}{18}+\frac {\ln \left (x-\frac {2^{2/3}\,3^{5/6}\,{\left (3+\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,1{}\mathrm {i}}{6}\right )\,{\left (36+\sqrt {3}\,12{}\mathrm {i}\right )}^{1/3}}{18}-\frac {1}{2\,x^2}-\frac {2^{2/3}\,\ln \left (x-\frac {2^{2/3}\,3^{1/3}\,{\left (3-\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}}{2}+\frac {2^{2/3}\,3^{1/3}\,{\left (3-\sqrt {3}\,1{}\mathrm {i}\right )}^{4/3}}{12}\right )\,{\left (3-\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,\left (3^{1/3}-3^{5/6}\,1{}\mathrm {i}\right )}{36}-\frac {2^{2/3}\,\ln \left (x-\frac {2^{2/3}\,3^{1/3}\,{\left (3+\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}}{2}+\frac {2^{2/3}\,3^{1/3}\,{\left (3+\sqrt {3}\,1{}\mathrm {i}\right )}^{4/3}}{12}\right )\,{\left (3+\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,\left (3^{1/3}+3^{5/6}\,1{}\mathrm {i}\right )}{36}-\frac {2^{2/3}\,\ln \left (x+\frac {2^{2/3}\,3^{1/3}\,{\left (3-\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}}{4}-\frac {2^{2/3}\,3^{5/6}\,{\left (3-\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,1{}\mathrm {i}}{12}\right )\,{\left (3-\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,\left (3^{1/3}+3^{5/6}\,1{}\mathrm {i}\right )}{36}-\frac {2^{2/3}\,\ln \left (x+\frac {2^{2/3}\,3^{1/3}\,{\left (3+\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}}{4}+\frac {2^{2/3}\,3^{5/6}\,{\left (3+\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,1{}\mathrm {i}}{12}\right )\,{\left (3+\sqrt {3}\,1{}\mathrm {i}\right )}^{1/3}\,\left (3^{1/3}-3^{5/6}\,1{}\mathrm {i}\right )}{36} \] Input:

int(-(x^3 - 1)/(x^3*(x^6 - x^3 + 1)),x)
 

Output:

(log(x + (2^(2/3)*3^(5/6)*(3 - 3^(1/2)*1i)^(1/3)*1i)/6)*(36 - 3^(1/2)*12i) 
^(1/3))/18 + (log(x - (2^(2/3)*3^(5/6)*(3^(1/2)*1i + 3)^(1/3)*1i)/6)*(3^(1 
/2)*12i + 36)^(1/3))/18 - 1/(2*x^2) - (2^(2/3)*log(x - (2^(2/3)*3^(1/3)*(3 
 - 3^(1/2)*1i)^(1/3))/2 + (2^(2/3)*3^(1/3)*(3 - 3^(1/2)*1i)^(4/3))/12)*(3 
- 3^(1/2)*1i)^(1/3)*(3^(1/3) - 3^(5/6)*1i))/36 - (2^(2/3)*log(x - (2^(2/3) 
*3^(1/3)*(3^(1/2)*1i + 3)^(1/3))/2 + (2^(2/3)*3^(1/3)*(3^(1/2)*1i + 3)^(4/ 
3))/12)*(3^(1/2)*1i + 3)^(1/3)*(3^(1/3) + 3^(5/6)*1i))/36 - (2^(2/3)*log(x 
 + (2^(2/3)*3^(1/3)*(3 - 3^(1/2)*1i)^(1/3))/4 - (2^(2/3)*3^(5/6)*(3 - 3^(1 
/2)*1i)^(1/3)*1i)/12)*(3 - 3^(1/2)*1i)^(1/3)*(3^(1/3) + 3^(5/6)*1i))/36 - 
(2^(2/3)*log(x + (2^(2/3)*3^(1/3)*(3^(1/2)*1i + 3)^(1/3))/4 + (2^(2/3)*3^( 
5/6)*(3^(1/2)*1i + 3)^(1/3)*1i)/12)*(3^(1/2)*1i + 3)^(1/3)*(3^(1/3) - 3^(5 
/6)*1i))/36
 

Reduce [F]

\[ \int \frac {1-x^3}{x^3 \left (1-x^3+x^6\right )} \, dx=\frac {-2 \left (\int \frac {x^{3}}{x^{6}-x^{3}+1}d x \right ) x^{2}-1}{2 x^{2}} \] Input:

int((-x^3+1)/x^3/(x^6-x^3+1),x)
 

Output:

( - 2*int(x**3/(x**6 - x**3 + 1),x)*x**2 - 1)/(2*x**2)