Here, the compound itself appears to be non-aromatic, but if the double bond between the ring and the oxygen is broken into a single bond, with oxygen pulling the electrons towards itself and acquiring a negative charge, and the ring acquiring a positive charge, it appears to be aromatic. Does that make the overall compound aromatic?
Not always.
Consider, for example, 4-pyrone. It is possible to draw canonical structures containing the pyrylium heterocycle, which is aromatic. However, the contribution of this aromatic resonance form is rather small, as it requires creating separate opposing charges which could otherwise cancel out, and in particular places a formal positive charge on an electronegative oxygen atom. But more than just argumentation or application of simplistic rules of thumb (e.g. Hückel's rule), certain physical measurements can give an indication for or against aromaticity. The response of compounds to magnetic fields, in particular, is often used. In the case of 4-pyrone, there is indication it may not be aromatic.
In the case of cyclopropenone, however, it seems that aromaticity is important. Even though its reactivity is completely different to most standard aromatic compounds (due to its ring strain), the heavily deshielded $\mathrm{^1H}$ NMR signal at a chemical shift of 9.11 ppm in $\ce{CDCl3}$ (see note 7) is suggestive of an aromatic ring current (another magnetic field effect), with the particularly high value being attributable to the positive charge in an aromatic cyclopropenium ring.
It is cyclic, planar and conjugated, so the last criteria to meet is the Huckel rule. In this case you have 2 $\pi$ electrons, because you can consider the O takes one out of the ring so the O - C bond will be polarized as $\ce{O-}-{C}+$:
$$\ 4n + 2 = 2 $$ $$\ 4n = 0 $$ $$\ n = 0 $$
So I would say the molecule is aromatic
