We present DeGAS, a differentiable Gaussian approximate semantics for loopless probabilistic programs that enables sample-free, gradient-based optimization in models with both continuous and discrete components. DeGAS evaluates programs under a Gaussian-mixture semantics and replaces measure-zero predicates and discrete branches with a vanishing smoothing, yielding closed-form expressions for posterior and path probabilities. We prove differentiability of these quantities with respect to program parameters, enabling end-to-end optimization via standard automatic differentiation, without Monte Carlo estimators. On thirteen benchmark programs, DeGAS achieves accuracy and runtime competitive with variational inference and MCMC. Importantly, it reliably tackles optimization problems where sampling-based baselines fail to converge due to conditioning involving continuous variables.
DeGAS: Gradient-Based Optimization of Probabilistic Programs without Sampling / Randone, F., Doz, R., Tribastone, M., Bortolussi, L.. - 16505:(2026), pp. 566-585. (TACAS 2026 - 32nd International Conference on Tools and Algorithms for the Construction and Analysis of Systems Turin, Italy 11-16/04/2026) [10.1007/978-3-032-22752-2_29].
DeGAS: Gradient-Based Optimization of Probabilistic Programs without Sampling
Tribastone M.;
2026
Abstract
We present DeGAS, a differentiable Gaussian approximate semantics for loopless probabilistic programs that enables sample-free, gradient-based optimization in models with both continuous and discrete components. DeGAS evaluates programs under a Gaussian-mixture semantics and replaces measure-zero predicates and discrete branches with a vanishing smoothing, yielding closed-form expressions for posterior and path probabilities. We prove differentiability of these quantities with respect to program parameters, enabling end-to-end optimization via standard automatic differentiation, without Monte Carlo estimators. On thirteen benchmark programs, DeGAS achieves accuracy and runtime competitive with variational inference and MCMC. Importantly, it reliably tackles optimization problems where sampling-based baselines fail to converge due to conditioning involving continuous variables.| File | Dimensione | Formato | |
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Descrizione: DeGAS: Gradient-Based Optimization of Probabilistic Programs without Sampling
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