- Joined
- Oct 9, 2007
- Messages
- 47,298 (7.53/day)
- Location
- Hyderabad, India
System Name | RBMK-1000 |
---|---|
Processor | AMD Ryzen 7 5700G |
Motherboard | ASUS ROG Strix B450-E Gaming |
Cooling | DeepCool Gammax L240 V2 |
Memory | 2x 8GB G.Skill Sniper X |
Video Card(s) | Palit GeForce RTX 2080 SUPER GameRock |
Storage | Western Digital Black NVMe 512GB |
Display(s) | BenQ 1440p 60 Hz 27-inch |
Case | Corsair Carbide 100R |
Audio Device(s) | ASUS SupremeFX S1220A |
Power Supply | Cooler Master MWE Gold 650W |
Mouse | ASUS ROG Strix Impact |
Keyboard | Gamdias Hermes E2 |
Software | Windows 11 Pro |
An Intel 12th Gen Core "Alder Lake-P" sample surfaced on the Geekbench online results database. The "Alder Lake" microarchitecture introduces heterogenous multi-core to the desktop platform, following its long march from Arm big.LITTLE in 2013, through to laptops with Intel's "Lakefield" in 2019. Intel will build both desktop- and mobile processors using the microarchitecture. The concept is unchanged from big.LITTLE. A processor has two kinds of cores—performance and low-power. Under lower processing loads, the low-power cores are engaged, and the performance cores are only woken up as needed. In theory, this brings about tremendous energy-efficiency gains, as the low-power cores operate within a much higher performance/Watt band than the high-performance cores.
The "Alder Lake" silicon features two kinds of cores—eight "Golden Cove" performance cores, and eight "Gracemont" low-power cores. The "Golden Cove" cores can be configured with HyperThreading (2 logical processors per core). Intel's product managers can create multiple combinations of performance and low-power cores, to achieve total core counts of up to 16, and logical processor counts of up to 24. This also warrants close attention to the composition of the core types, beyond an abstract core-count. A 14-core processor with 6 performance- and 8 low-power cores will perform vastly different from a 14-core processor with 8 performance- and 6 low-power cores. One way to derive core counts is by paying attention to the logical processor (thread) counts, as only the performance "Golden Cove" cores support HTT.
Back to the Geekbench v5.31 database entry, and we see a 14-core/20-thread "Alder Lake-P" processor. This chip features 6 performance "Golden Cove" cores, and 8 low-power "Gracemont" ones. As a mobile chip, it's paired with LPDDR4X memory, and its clock speed ranges between 800 MHz idle, and 4.70 GHz max Turbo Boost. The chip yields an OpenCL compute performance of 13438 points.
View at TechPowerUp Main Site
The "Alder Lake" silicon features two kinds of cores—eight "Golden Cove" performance cores, and eight "Gracemont" low-power cores. The "Golden Cove" cores can be configured with HyperThreading (2 logical processors per core). Intel's product managers can create multiple combinations of performance and low-power cores, to achieve total core counts of up to 16, and logical processor counts of up to 24. This also warrants close attention to the composition of the core types, beyond an abstract core-count. A 14-core processor with 6 performance- and 8 low-power cores will perform vastly different from a 14-core processor with 8 performance- and 6 low-power cores. One way to derive core counts is by paying attention to the logical processor (thread) counts, as only the performance "Golden Cove" cores support HTT.
Back to the Geekbench v5.31 database entry, and we see a 14-core/20-thread "Alder Lake-P" processor. This chip features 6 performance "Golden Cove" cores, and 8 low-power "Gracemont" ones. As a mobile chip, it's paired with LPDDR4X memory, and its clock speed ranges between 800 MHz idle, and 4.70 GHz max Turbo Boost. The chip yields an OpenCL compute performance of 13438 points.
View at TechPowerUp Main Site