If you’re interested in a slightly wider-ranging review of the new MacBook Pros, I’ll point you toward reviews of the M1, M3, and M4 generation models, as well as the one for the low-end 14-inch MacBook Pro with the standard M5 (now $100 more expensive than it was before, but with 1TB of base storage instead of 512GB).
Apple is using the same external design for these laptops that it has been using since 2021—it’s aging pretty well, and we still mostly like it, especially compared to late-Intel-era MacBook Pros. There’s just not much else to say about the design that hasn’t been said.
M5 Max benchmarks
In our testing, the fully enabled M5 Max’s single-core performance is about 10 percent higher than the fully enabled version of the M4 Max in last year’s 16-inch MacBook Pro. The multi-core performance improvements are more variable (Cinebench R23, which shows a 30 percent improvement, seems to be an outlier), but most tests also show a modest 10 or 12 percent improvement.
Graphics performance improvements are slightly more robust, measuring between 20 and 35 percent depending on the test. Apple suggests you may see more uplift on GPU compute workloads that can leverage the neural accelerator Apple has built into each M5-family GPU core.
The jump from the M4 Max to the M5 Max isn’t quite as large, expressed as a percentage, as it has been for the last couple generations; both M3 Max and M4 Max were big leaps from what had come before. But assuming you’re upgrading from an M1 or M2-based Pro, you’ll still be taking a big leap. Fears that stepping down from 12 of Apple’s best-performing CPU cores (in M4 Max) to just six of the best-performing cores are also a bit overblown, based on these results.
Compared to the basic M5 in the 14-inch MacBook Pro, the M5 Max’s single-core performance is roughly the same, which is in keeping with how Apple usually does things—stepping up to higher-end chips gets you better multi-core and graphics performance, but Apple doesn’t push the clock speeds upward on the individual cores the way that Intel or AMD do with their higher-end processors.