Let $G$ be a commutative connected algebraic group over $\mathbb{C}$. A theorem of Serre says that there exists an exact sequence $$1\to \mathbb{G}_a^n\times \mathbb{G}_m^m\to G\to A\to 1,$$ where $A$ is an abelian variety. (See here, for example.)
I wonder what are some examples of such groups $G$ where this extension is non-trivial. That is, such that $G\ncong \mathbb{G}_a^n\times \mathbb{G}_m^m\times A$.
One example is provided by the generalized Jacobian. For a smooth projective curve $C$ and a divisor $D$ on $C$, the generalized Jacobian is defined to be the moduli space parameterizing pairs consisting of a line bundle of degree $0$ on $C$ together with a trivialization of that line bundle over $D$.
This admits a map to the usual Jacobian, whose kernel is a product of $\mathbb G_m$s and $\mathbb G_a$s depending on the multiplicity of points of $D$.
If this were trivial, than we could define a section of this map, which would give for an arbitrary line bundle a canonical trivialization at each point of $D$. That would mean that for each point $x\in D$, the line bundle on the usual Jacobian whose fiber at a point $L \in J$ is the fiber of $L$ at $x$ would admit a section and thus be trivial. But from the duality theory of abelian varieties, these line bundles are different for distinct points $x\in C$, so they cannot all be trivial as long as $D$ contains two or more points.
