Whilst holding great promise for low noise, ease of operation and networking, useful photonic quantum computing has been precluded by the need for beyond-state-of-the-art components, manufactured by the millions. Here we introduce a manufacturable platform for quantum computing with photons. We benchmark a set of monolithically-integrated silicon photonics-based modules to generate, manipulate, network, and detect photonic qubits, demonstrating dual-rail photonic qubits with (99.98% \pm 0.01%) state preparation and measurement fidelity, Hong-Ou-Mandel quantum interference between independent photon sources with (99.50%\pm0.25%) visibility, two-qubit fusion with (99.22%\pm0.12%) fidelity, and a chip-to-chip qubit interconnect with (99.72%\pm0.04%) fidelity, not accounting for loss. In addition, we preview a selection of next generation technologies, demonstrating low-loss silicon nitride waveguides and components, fabrication-tolerant photon sources, high-efficiency photon-number-resolving detectors, low-loss chip-to-fiber coupling, and barium titanate electro-optic phase shifters.