André has given you a calculus solution; here’s one that uses no calculus.
The graph of $y=\sqrt{2-x^2}$ is the upper half of a circle of radius $\sqrt2$ centred at the origin; that of $y=\sqrt{2x-x^2}=\sqrt{1-(x-1)^2}$ is the upper half of a circle of radius $1$ centred at $(1,0)$. Thus, $\int_0^1 \sqrt{2x-x^2} dx=\frac{\pi}4\;,$ a quarter of the area of a circle of radius $1$. We can also get $\int_0^1 \sqrt{2-x^2} dx$ without calculus, but it requires a little more cleverness. If you sketch the quarter-disk in the first quadrant bounded by $y=\sqrt{2-x^2}$, you’ll see that it’s the union of the unit square $S=\{(x,y):0\le x,y\le 1\}\;,$ the region $T$ bounded by the $y$-axis, the line $y=1$, and the curve $y=\sqrt{2-x^2}$, and the region $R$ bounded by the $x$-axis, the line $x=1$, and the curve $y=\sqrt{2-x^2}$. Regions $T$ and $R$ are clearly congruent, so they have the same area. The area of the whole quarter-disk is $\pi/2$, so $\frac{\pi}2=1+2\operatorname{area}(T)\;,$ and $\operatorname{area}(T)=\frac12\left(\frac{\pi}2-1\right)=\frac{\pi-2}4\;.$ Finally, $\int_0^1 \sqrt{2-x^2} dx=\operatorname{area}(S)+\operatorname{area}(T)=1+\frac{\pi-2}4=\frac{\pi+2}4\;,$ and $\int_{0}^{1}\left(\sqrt{2-x^2}-\sqrt{2x-x^2}\right)dx=\frac{\pi+2}4-\frac{\pi}4=\frac12\;.$