If `f:R->R` is defined by `f(x)=[x−3]+|x−4|` for `x in R`, then `lim_(x->3) f(x)` is equal to (where [.] represents the greatest integer function)

If f:R rarr R is defined by f(x)=[x-3]+|x-4| for x in R, then lim_(x rarr3)f(x) is equal to (where [.] represents the greatest integer function)

If f:R rarrR is defined by f(x)=[x-3]+|x-4| for x in R , then lim_(xrarr3^(-)) f(x) is equal to (where [.] represents the greatest integer function)

If f : R rarr R is defined by f(x) = [x-3]+|x-4| for x in R , then lim_(x rarr 3^(-)) f(x) is equal to

If f: R to R is defined by f(x) = |x-3| + |x-4| for x in R then lim_(x to 3^-) f(x) is equal to …………………. .

If f:R rarr R is defined by f(x)= floor(x-3)+|x+4| for xepsilonR,then lim_(xrarr3^-)f(x) is equal to:

f:R rarr R defined by f(x)=x^(3)-4

f:(2,3)rarr(0,1) defined by f(x)=x-[x], where [.] represents the greatest integer function.

If f: R to R is defined by f(x)=lfloorx-3rfloor+lfloorx-4rfloor for x in R then lim_(x to 3^-) f(x) is equal to