Note that the constant function $f=c$ satisfies your conditions for any real $c\le-1$. So, 
$$\inf\int_0^1 f=-\infty.$$

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Consider now the same problem but with the additional condition $f\ge0$. 
Then, for all $x\in[0,1]$ (using your condition on $f$ with $x_1=x=x_2$), we have 
$$f(x)\ge\sqrt{1-x^2},$$
whence 
$$\int_0^1 f\ge\int_0^1 dx\,\sqrt{1-x^2}=\frac\pi4=0.78539\ldots.$$ 

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With a bit more effort, we can do better than that: for all $x\in[0,1]$ (using your condition on $f$ with $x_1=x$ and $x_2=1-x$), we have 
$$\sqrt{1-x(1-x)}\le\sqrt{f(x)f(1-x)}\le\frac{f(x)+f(1-x)}2,$$
whence 
$$\int_0^1 f\ge\int_0^1 dx\,\sqrt{1-x(1-x)} 
=c:=\frac{1}{8} (4+\ln27)=0.9119\ldots.$$

On the other hand, if $f(x)=c_1\sqrt{1-x(1-x)}$ for 
$c_1:=\sqrt{\frac{2}{\sqrt{3}}}$ and all $x\in[0,1]$, then your conditions of $f$ will hold. So, the lower bound $c$ on $\int_0^1 f$ is optimal up to the factor $c_1=1.0745\ldots.$ 

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The upper bound $c_1c=0.97998\ldots$ on $\inf\int_0^1$ can be further improved a bit, by letting 
$$ f(x)=f_a(x):=c_1(a)\sqrt{1-ax(1-x)}$$
for $a\in(0,4)$, $c_1(a):=\sqrt{2 \sqrt{\frac{1}{4-a}}}$, and all $x\in[0,1]$. Then your condition on $f$ holds, and the minimum of 
$\int_0^1 f_a$ over $a\in(0,4)$ is $c_*=0.96360\ldots$ (attained at $a=2.3331\ldots$). So, the lower bound $c$ on $\int_0^1 f$ is optimal up to the factor $c_*/c=1.0566\ldots<c_1=1.0745\ldots.$  

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I would be much (and pleasantly) surprised if $\inf \int_0^1 f$ is explicitly determined (assuming additionally that $f\ge0$).