With two variables, you are defining a line segment in $\mathbb{R}^2$, as you pointed out. However, due to the simplex constraint, one of these two variables is redundant in terms of specifying the density, since there is a one-to-one relationship between $x_1$ and $x_2$. Therefore, the density is specified over $K-1$ free variables (i.e., in $\mathbb{R}$)
This is actually pointed out in the first line of this section of the Wikipedia article, albeit very subtly.
Therefore, your density function becomes:.
$$Dir_{1,1}(x_1,1-x_1)=\frac{\Gamma(2)}{\Gamma(1)^2}(x_1)^0(1-x_1)^0=1$$
Therefore,
$$\int_0^1 Dir_{1,1}(x_1,1-x_1) dx_1 = 1$$
Response to OP Comment
Due to the simplex constraints, the two-variable Dirichlet density is actually degenerate in $\mathbb{R}^2$, as shown by my construction above (it only requires one variable). While it is true it has a density of $1$, it does not have a density of $1$ on the line segment connecting $(1,0)$ with $(0,1)$. What the above construction shows is that the marginal density has a value of $1$. Your confusion comes from thinking of $x_2$ as a free variable, in which case the support of the Dirichlet on $\mathbb{R}^2$ would have a non-zero area. This intuition is fine in cases like the the bivariate gaussian, where the two variables are not perfectly correlated, but not in this case.
We can formally derive this as follows:
Let $L$ be some number in $[0,\sqrt{2}]$ specifying the distance from $(1,0)$ to $(0,1)$ along the connecting line segment. Thus, each value of $L$ identifies a unique $(x_
1,x_2)$ pair. Using this notation, your assumption that the density is $1$ along this line boils down to:
$$P(L \in [a,b] \subset)=b-a$$
However, we can show this is not the case through a formal treatment of the joint density of $x_1,x_2$:
$$P_L(L\in [a,b])=P_{X_1,X_2}[(x_1,x_2) \in A_{[a,b]}]$$
Where $A_{[a,b]}:= \{(u,v): u \in [1-\frac{b}{\sqrt{2}},1-\frac{a}{\sqrt{2}}], v = 1- u]$
Now, let's calculate $P_L(L\in [a,b])$:
$$P_L(L\in [a,b])= \int_{A_{[a,b]}} dP_{X_1,X_2}= \int_{A_{[a,b]}} dP_{X_1}dP_{X_2|X_1} =\int_{A_{[a,b]}} 1 \;dP_{X_1} = \int_{1-\frac{b}{\sqrt{2}}}^{1-\frac{a}{\sqrt{2}}}1\; du = $$
$$\left(1-\frac{a}{\sqrt{2}}\right) - \left(1-\frac{b}{\sqrt{2}}\right) = \frac{1}{\sqrt{2}}(b-a)$$
Where the third equality comes about because $dP_{X_2|X_1} = 1$ for $X_2=1-X_1$ (i.e., its not a density, but a point probability mass at $1-X_1$)
As you can see, we've recovered the $\frac{1}{\sqrt{2}}$ normalizing constant for the density along the line segment in $\mathbb{R}^2$. Effectively, this (degenerate) joint density is just a linear transformation of one of the two marginals (either one will work). This results in the domain of the probability density to go from $1$ to $\sqrt{2}$, hence the density must decrease to compensate.