Verified efficiency data across thousands of real production jobs.
Nine real-world benchmarks run against each tool with identical inputs: same parts, same stock dimensions, same kerf. Results show boards required to fit all parts — fewer boards means less material waste. Times measured end-to-end including network round-trips where applicable.
| Benchmark | SC Fast | SC Max | MagiCut | Opticutter | CutList Optimizer |
|---|---|---|---|---|---|
| 9 parts2400 × 2000 mm | 2 boards0.1 s | 2 boards0.1 s | 2 boards | 2 boards2.6 s | 2 boards27.6 s |
| 10 parts2400 × 2000 mm | 1 board76 ms | 1 board85 ms | 1 board | 1 board2.6 s | 1 board8.3 s |
| 20 parts2400 × 2000 mm | 2 boards0.2 s | 1 board38.5 s | 2 boards | 1 board8.3 s | 1 board103 s |
| 22 parts2400 × 2000 mm | 2 boards0.3 s | 2 boards0.3 s | 2 boards | 2 boards10.5 s | 2 boards95.9 s |
| 39 parts7 shapes · 2800 × 2050 mm | 2 boards0.4 s | 2 boards32.4 s | 1 board | 2 boards11 s | 2 boards121 s |
| 60 parts2785 × 2055 mm | 10 boards0.5 s | 9 boards1.0 s | 9 boards | 10 boards4.5 s | 10 boards122 s |
| 96 parts6 shapes · 2400 × 2000 mm | 5 boards0.7 s | 5 boards47.8 s | 4 boards | 5 boards12.9 s | 5 boards122 s |
| 160 parts4 shapes · 2785 × 2055 mm | 5 boards1.2 s | 4 boards29.3 s | 4 boards | 5 boards28.9 s | 5 boards122 s |
| 256 parts2785 × 2055 mm | 14 boards2.7 s | 13 boards50.2 s | 13 boards | 14 boards24 s | — |
SmartCut Fast completes in under 3 seconds on all nine jobs — 10–100× faster than web-based tools. SmartCut Max matches or beats MagiCut on 7 of 9 benchmarks — including a single-board solution on the 20-part job the others miss — and beats Opticutter and CutList Optimizer on every job where the tools differ. MagiCut is a Windows desktop application, so its timing isn't directly comparable (board counts use the same saw input format). CutList Optimizer returns results on 8 of 9 benchmarks; the 256-part job exceeds its part limit, and it hits an internal ~2-minute ceiling on larger jobs regardless of budget.
Fast mode returns a result in under 3 seconds and is right for most jobs. Max mode (150 s budget) runs deeper search passes and recovers material on larger jobs. Across 147 large production jobs, Max saves 59 boards versus Fast — a consistent gain at the recommended budget. Returns diminish sharply above 150 s.
Static layouts from the benchmark suite. Colours distinguish part families within each job.
All 160 parts packed onto four boards at up to 96% density — one fewer board than Opticutter and CutList Optimizer. Fast mode returns in 1.2 s; Max mode finds the tighter four-board layout in around 20 s.
Six part families across 96 pieces on 2400 × 2000 mm stock, every board packed edge to edge. SmartCut Fast returns the full layout in 0.7 seconds.
"DFF-optimal" means a job's result matches the Dual First-Fit lower bound — a provably tight floor on the minimum number of boards required by any packing algorithm. When SmartCut reaches DFF for a job, no algorithm anywhere can do better on that input.
Measured across 2,083 real beam-saw jobs: 82% hit the DFF floor outright. The remaining 18% are jobs where the geometry leaves a genuine gap — typically very large panels, unusual aspect ratios, or head-cut-heavy patterns — not algorithm inefficiency.
SmartCut's beam algorithm is benchmarked against industry tools including MagiCut, Ardis, Opticutter, and CutList Optimizer, using identically configured jobs, sheet sizes, kerf widths and trim margins.
Typical beam-saw job
150 s budget for the hardest cases
SmartCut is available via a REST API. Submit a job, get a layout — no installation.
We measure against the Dual First-Fit (DFF) lower bound — a provably tight floor on the minimum number of boards any algorithm could use for a given job. When a result matches the DFF floor, no tool anywhere can do better on that input. Across 2,083 real jobs, SmartCut reaches it on 82%.
On nine real benchmarks with identical inputs, SmartCut Max matches or beats MagiCut on 7 of 9 jobs and beats Opticutter and CutList Optimizer on every job where the tools differ — while returning results 10–100× faster than web-based tools.
Most beam-saw jobs finish in under two seconds in Fast mode. Max mode uses a larger budget (150 seconds by default) to recover extra material on the hardest jobs.
Yes — efficiency is measured across 2,083 real customer jobs, not synthetic test cases, and every competitor comparison uses the same parts, stock and kerf.