Yes: Just take $u(x,y):=v(x)$. 

Indeed, one can use Green's formula to show this, as is done in [Christian Remling's answer][1]. 

More generally, the result holds for any convex function $v$, without requiring it to be in $C^2$ -- of course, if $u$ is not required to be in $C^2$ and if the derivative $v'(x)$ is understood as (say) the right derivative of $v$ at $x$ for $x\in[-1,1)$. Indeed, then the convex function $v$ is a mixture of the constant functions, the identity function, 
and the functions of the form $v_a$ with $a\in[-1,1)$, where $v_a(x):=\max(0,x-a)$, and for any one of these functions the inequality in question is straightforward to check. 

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**Detail:** The mentioned mixture representation of the convex function $v$ is as follows: for $x\in(-1,1)$, 
$$\begin{aligned}
&v(x) \\ 
&=v(-1+)+\int_{[-1,x)}dz\,v'(z) \\ 
&=v(-1+)+\int_{[-1,1)}dz\,1(z<x)\,v'(z) \\ 
&=v(-1+)+\int_{[-1,1)}dz\,1(z<x)\,\Big(v'(-1)+\int_{[-1,z]}\,dv'(a)\Big) \\ 
&=v(-1+)+v'(-1)(x+1) \\ 
&\qquad\qquad+\int_{[-1,1)}dz\,1(z<x)\,\int_{[-1,z]}\,dv'(a) \\ 
&=v(-1+)+v'(-1)(x+1) \\ 
&\qquad\qquad+\int_{[-1,1)}\,dv'(a)\int_{[-1,1)}dz\,1(a\le z<x)\, \\ 
&=[v(-1+)+v'(-1)]+v'(-1)x+\int_{[-1,1)}\,dv'(a)\,v_a(x), 
\end{aligned}$$
and the Lebesgue--Stieltjes measure $dv'$ for the nondecreasing function $v'$ is $\ge0$. 

  [1]: https://mathoverflow.net/a/463229/36721