First, there is a small inclarity in the question with the meaning of "restriction of the base-locus". Since the base locus is in general just a closed set, of possibly arbitrary codimension, it is not clear to me whether "restriction" is just meant to mean set-theoretic intersection, or something more sophisticated.

In any case, even in the simplest situation where the base locus is a codimension 1, the answer to both questions is no. 

For the first version, let $X$ be $\mathbf P^2$ blown up in 9 points which are the intersection of two smooth cubics. Let $X \rightarrow \mathbf P^1$ be the elliptic fibration, and let $D$ be one of the exceptional divisors of $X \rightarrow \mathbf P^2$. Then $mD$ is fixed for all $m \geq 0$, but for a smooth fibre $F$ the restriction $D_{|F}$ is a point on an elliptic curve, so $2D_{|F}$ is basepoint free.

For the second version, fix an ample divisor $A$ on $X$ as above. For $D$ as before and for any $n \geq 1$, the divisor $A+nD$ is big. For $n$ sufficiently large, we have $(A + nD) \cdot D = A \cdot D -n <0$, so for such $n$ and sufficiently large $m$, the base locus of $m(A+nD)$ is again $D$. On the other hand, for any $n \geq 1$ the restriction of $A+nD$ to $F$ is basepoint free.

**Update:** Jérémy asks further for an example where the stable base locus of $D$ is codimension 2. This is a little trickier, but I think one can cook it up starting from the example constructed by Totaro in Theorem 6.1 of the paper:

<cite authors="Totaro, Burt">_Totaro, Burt_, [**Hilbert’s 14th problem over finite fields and a conjecture on the cone of curves**](http://dx.doi.org/10.1112/S0010437X08003667), Compos. Math. 144, No. 5, 1176-1198 (2008). [ZBL1157.13006](https://zbmath.org/?q=an:1157.13006).</cite>

In this example we have a fibration $W \rightarrow \mathbf P^3$ whose general fibre $F$ is an abelian surface. The key point is that there is a pseudo-isomorphism $X \dashrightarrow \mathbf W$ given by the inverse flip of 45 disjoint curves on another variety $X$, which is the blowup of $\mathbf P^5$ in a certain arrangement of 9 points.

So start with a very ample divisor $H$ on $X$ say. Then its proper transform $\widetilde{H}$ on $W$ will be movable, with stable base locus $Bs(\widetilde{H})$ consisting of exactly the indeterminacy locus of $W \dashrightarrow X$. This is a union of 45 copies of $\mathbf P^3$ on $W$, each of them a section of $W \rightarrow \mathbf P^3$. So the intersection of $Bs(\widetilde{H})$ with a general fibre $F$ consists of 45 points on $F$. 

On the the other hand the restriction $\widetilde{H}_{|F}$ is an effective divisor on the abelian surface $F$, so it is semi-ample. 

Now I missed one condition of the original question, namely that the base $Y$ should be a curve. So take $Y \subset \mathbf P^3$ to be a general line, and restrict the fibration $W \rightarrow \mathbf P^3$ to $Y$, to get a fibration $V \rightarrow Y$ say. Then taking the divisor $\widetilde{H}_{|V}$ the same argument as before will work.