If {.} represents fractional part function and `{x}+{-x}=x^2+x-6` , then integral roots are `-2a n d3` number of non-integral roots is 2 number of solutions is 4 equation has exactly two integral roots

If {.} represents fractional part function and {x}+{-x}=x^(2)+x-6, then integral roots are -2 and 3 number of non-integral roots is 2 number of solutions is 4 equation has exactly two integral roots

If {.} represents fractional part function and {x}+{-x}=x^2+x-6 , then (a) integral roots are -2 and 3 (b) number of non-integral roots is 2 (c) number of solutions is 4 (d) equation has exactly two integral roots

If {.} represents fractional part function and {x}+{-x}=x^2+x-6 , then (a) integral roots are -2 and 3 (b) number of non-integral roots is 2 (c) number of solutions is 4 (d) equation has exactly two integral roots

Number of integral roots of |x-1||x^2-2|=2 is

Number of integral values of a such that the quadratic equation x^(2)+a x+a+1=0 has integral roots is

The number of integral values of n such that the equation 2n{x}=3x+2[x]has exactly 5 solutions.

Sum of integral roots of the equation |x^(2)-x-6|=x+2 is

The number of integral values of b, for which the equation x^(2) + bx - 16 = 0 has integral roots is

Sum of integral roots of the equation |x^2-x-6|=x+2 is