I am having a little issue regarding solving polynomial in python's sympy.solvers. What I want is to find the rational root, not irrational root. my attempt is given below -

from sympy.solvers import solve
from sympy import Symbol
from fractions import Fraction

b_4= -10


x = Symbol('x', real=True)
solution=solve(((4*x**3+b_2*x**2+2*b_4*x+b_6)*x_2p-(x**4-b_4*x**2-2*b_6*x-b_8)), x)
if len(R) != 0:

I got below error -

Traceback (most recent call last):
  File "C:\Users\Roy\Desktop\EXP_2704 - Copy.py", line 16, in <module>
  File "C:\Program Files\Python37\lib\fractions.py", line 161, in __new__
    raise TypeError("argument should be a string "
TypeError: argument should be a string or a Rational instance

Note that I need to get accurate fraction from floating.

How can I find rational root?

  • You gave up all hope of an exact answer the moment you wrote -7/4, which produces a floating-point value. It's a float that happens to be an exact representation of the value, but sympy has no way of knowing that - so it gives up on trying to give you an exact symbolic result, and just calculates floats. (And it's fundamentally impossible to tell whether a float is supposed to represent a rational or irrational value.) Apr 27, 2020 at 18:29
  • @jasonharper but the problem is not happening at x_2p=-7/4 but at print(Fraction(R[1]))
    – Michael
    Apr 27, 2020 at 18:45

1 Answer 1


If you use real_roots you will get a CRootOf instance that can be computed with arbitrary precision. Using your initialization and the following I get:

>>> from sympy import Rational, real_roots
>>> eq = ((4*x**3+b_2*x**2+2*b_4*x+b_6)*x_2p-(x**4-b_4*x**2-2*b_6*x-b_8)); eq
-x**4 - 7.0*x**3 - 10*x**2 + 99.0*x - 81.0
>>> real_roots(_)
[1, CRootOf(x**3 + 8*x**2 + 18*x - 81, 0)]
>>> r=_[1]
>>> Rational(r.n(2))
>>> Rational(r.n(20))
  • why we need eq -x**4 - 7.0*x**3 - 10*x**2 + 99.0*x - 81.0 ..... could you plz provide complete code according to my my code?
    – Michael
    Apr 27, 2020 at 21:44
  • I just defined eq to be your argument to solve and then I showed you what it looks like. And then I used real_roots instead of solve. In your code replace solve with real_roots and leave of , x...you will get the list of solutions that I show in the answer.
    – smichr
    Apr 27, 2020 at 21:55

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