Researchers have made significant strides in developing measurement-based quantum computing on qudits, a crucial step towards harnessing the power of quantum entanglement for computational purposes. By leveraging entangled resource states and successive product measurements, scientists can drive computations, albeit with inherent non-determinism due to the probabilistic nature of measurements. To mitigate this, adaptive correction procedures are necessary, which can be facilitated by flow structures that characterize cases where such corrections are possible1. The exploration of qudits, as opposed to traditional qubits, offers a more nuanced understanding of quantum computing's potential. This breakthrough has far-reaching implications, as it could potentially elevate the stakes of quantum computing from a purely technical pursuit to a geopolitical one, with state-aligned threat activity raising the calculus beyond immediate targets. The development of measurement-based quantum computing on qudits matters to practitioners because it underscores the need for a deeper understanding of quantum entanglement and its applications in computing.