The spaces $\mathcal{L}^2(\mathbb{R})$ (square-integrable functions) and $\mathcal{L}^2(\mathbb{T})$ (1-periodic square-integrable functions, considered over the real line $\mathbb{R}$) are two subspaces of the space of tempered distributions $\mathcal{S}'(\mathbb{R})$ and one can easily show that the sum $\mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T})$ is direct. 

The duals of $\mathcal{L}^2(\mathbb{R})$ and $\mathcal{L}^2(\mathbb{T})$ are isometrically isomorphic to $\mathcal{L}^2(\mathbb{R})$ and $\mathcal{L}^2(\mathbb{T})$, respectively (Riesz representation theorem). Therefore, the continuous dual of the direct sum is simply $\mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T})$ in the sense that (1) an element $g_1 + g_2 \in \mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T})$ defines a continuous linear functional over $\mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T})$ via 
$$(f_1 + f_2) \mapsto \langle f_1 , g_1 \rangle_{\mathcal{L}^2(\mathbb{R})} +  \langle f_2 , g_2 \rangle_{\mathcal{L}^2(\mathbb{T})}$$ 
(which uses that both decompositions $f = f_1 + f_2$ and $g = g_1+g_2$ are unique), and that (2) any element of $(\mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T}))')$ is of this form. 

I would like to identify the subset $\mathcal{X}\subset \mathcal{S}'(\mathbb{R})$ of functions $g$ such that 
$$ \mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T})   \ni f_1 + f_2 \mapsto \int_{\mathbb{R}} g(x) (f_1 + f_2)(x)\mathrm{d}x$$
specifies a continuous linear functional over $\mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T})$. 
Clearly, by restricting it to $\mathcal{L}^2(\mathbb{R})$ (i.e. setting $f_2=0$), we need to have $g \in\mathcal{L}^2(\mathbb{R})$.  Moreover, $\mathcal{X}$ contains any square-integrable compactly supported functions, but also functions that are not compactly supported but that have sufficiently nice asymptotic properties such that the integral $\int_{\mathbb{R}} g (x) f_2(x)\mathrm{d}x$ is well-defined for any square-integrable periodic $f_2$ and defines a continuous functional over $\mathcal{L}^2(\mathbb{T})$. 

**Question:** Is there a way to identify the space $\mathcal{X}$ I am depicting? Can we reach any linear functionals over $\mathcal{L}^2(\mathbb{R}) \oplus \mathcal{L}^2(\mathbb{T})$ by doing so? I am also interested by generalization to other direct sums between spaces of periodic and non-periodic functions (e.g., $\mathcal{L}^p$-spaces, or spaces of continuous-functions for the supremum norm).