Just recently, we covered a juicy new leak regarding the Geekbench performance of the upcoming Ryzen AI Max+ 395 "Strix Halo" APU. It is no secret that AMD plans on launching the Strix Halo lineup at CES 2025, which happens to be less than a month away. Unsurprisingly, leaked listings of upcoming laptops and other products have been steadily popping up on the internet, with the ASUS ROG Flow Z13 being the rumor mill's latest victim.

As revealed by the product listings by retailers, the ASUS ROG Flow Z13 will indeed pack some truly impressive specifications. Needless to say, the product will feature a variant with the highest-end Ryzen AI Max+ 395 APU with 16 cores and 32 threads, along with an RDNA 3.5-based iGPU with 40 CUs, likely named the Radeon 8060S, which is expected to match mid-range discrete graphics in performance. A slightly lower-tier variant is also listed, with a 12-core Ryzen AI Max 390 APU.

CES 2025 is less than a month away and leaks about AMD Strix Halo APUs are starting to emerge. Today we have confirmation via a leaked Geekbench Vulcan test that AMD will launch the Ryzen AI MAX+ PRO 395 w/ Radeon 8060S "Strix Halo" APU. Information reveals that this APU is equipped with 16 Zen 5 cores with 32 threads, a 3 GHz base frequency (4.4 GHz max), and a boost up to 5.1 GHz. It sports a 32 MB L3 cache per CCD for a total of 64 MB since it uses a dual CCD chip design. The TDP should be between 55-130 W. Moreover, the "PRO" in the product naming suggests that AMD could release non-PRO models at a later date.

The integrated Radeon 8060S iGPU adopts the RDNA 3.5 architecture with 40 computing units and was tested using an AMD reference board design codenamed AMD MAPLE-STXH and 64 GB of memory scoring 67,004 points in the Geekbench Vulkan test. This initial result is lower than AMD Radeon RX 7600 RDNA 3 discrete entry-level products (despite having more cores 40CU vs 32CU), and higher than NVIDIA GeForce RTX 3050. However, since the benchmark was run on an evaluation platform without optimized drivers and more likely using an early test sample product, we can expect the actual performance of the Radeon 8060S iGPU to be higher.

AMD has published a blog post about its latest AMD Ryzen AI 300 series processors, claiming they are changing the game for portable devices. To back these claims, Team Red has compared its Ryzen AI 9 HX 370 processor to Intel's latest Core Ultra 7 258V, using the following games: Assassin's Creed Mirage, Baldur's Gate 3, Borderlands 3, Call of Duty: Black Ops 6, Cyberpunk 2077, Doom Eternal, Dying Light 2 Stay Human, F1 24, Far Cry 6, Forza Horizon 5, Ghost of Tsushima, Hitman 3, Hogwarts Legacy, Shadow of the Tomb Raider, Spider-Man Remastered, and Tiny Tina's Wonderlands. The conclusion was that AMD's Ryzen AI 9 HX 370, with its integrated Radeon 890M graphics powerhouse, outperformed the Intel "Lunar Lake" Core Ultra 7 258V with Intel Arc Graphics 140V by 75% on average.

To support this performance leap, AMD also relies on software technologies, including FidelityFX Super Resolution 3 (FSR 3) and HYPR-RX, to unlock additional power and gaming efficiency. FSR 3 alone enhances visuals in over 95 games, while HYPR-RX, with features like AMD Fluid Motion Frames 2 (AFMF 2) and Radeon Anti-Lag, provides substantial performance boosts across thousands of games. The company has also compared its FSR/HYPR-RS combination with Intel's XeSS, which is available in around 130 games. AMD claims its broader suite supports 415+ games and is optimized for smoother gameplay. The AFMF 2 claims support with thousands of titles, while Intel's GPU software stack lacks a comparison point. Of course, these marketing claims are to be taken with a grain of salt, so independent testing is always the best to compare the two.

AMD Ryzen AI MAX 300-series processors, codenamed "Strix Halo," have been on in the news for close to a year now. These mobile processors combine "Zen 5" CPU cores with an oversized iGPU that offers performance rivaling discrete GPUs, with the idea behind these chips being to rival the Apple M3 Pro and M3 Max processors powering MacBook Pros. The "Strix Halo" mobile processor is an MCM that combines one or two "Zen 5" CCDs (some ones featured on "Granite Ridge" desktop processors and "Turin" server processors), with a large SoC die. This die is built either on the 5 nm (TSMC N5) or 4 nm (TSMC N4P) node. It packs a large iGPU based on the RDNA 3.5 graphics architecture, with 40 compute units (CU), and a 50 TOPS-class XDNA 2 NPU carried over from "Strix Point." The memory interface is a 256-bit wide LPDDR5X-8000 for sufficient memory bandwidth for the up to 16 "Zen 5" CPU cores, the 50 TOPS NPU, and the large 40 CU iGPU.

Golden Pig Upgrade leaked what looks like a company slide from a notebook OEM, which reveals the iGPU model names for the various Ryzen AI MAX 300-series SKUs. Leading the pack is the Ryzen AI MAX+ 395. This is a maxed out SKU with a 16-core/32-thread "Zen 5" CPU that uses two CCDs. All 16 cores are full-sized "Zen 5." The CPU has 64 MB of L3 cache (32 MB per CCD), each of the 16 cores has 1 MB of dedicated L2 cache. The iGPU is branded Radeon 8060S, it comes with all 40 CU (2,560 stream processors) enabled, besides 80 AI accelerators, and 40 Ray accelerators. The Ryzen AI MAX 390 is the next processor SKU, it comes with a 12-core/24-thread "Zen 5" CPU. Like the 395, the 390 is a dual-CCD processor, all 12 cores are full-sized "Zen 5." There's 64 MB of L3 cache, and 1 MB of L2 cache per core. The Radeon 8060S graphics solution is the same as the one on the Ryzen AI MAX+ 395, it comes with all 40 CU enabled.

AMD's answer to Intel's "Lunar Lake" is here. According to Olrak29, who discovered a strange entry on the OpenBenchmark benchmarking suite made by Phoronix, we have preliminary information on AMD's "Krackan / Kraken Point" APU. Spotted in the benchmark trials is the "100-000000713" model, which corresponds to an eight-core, sixteen-threaded CPU with four regular Zen 5 and four smaller (but not less potent) Zen 5c cores clocked at 3.95 GHz. Do note that this is just an engineering sample in the wild, so final clock speeds will depend mainly on AMD and its OEMs, given by TDP they plan to support with Kraken Point.

Accompanying the 8C/16T CPU configuration is the 32 GB of LPDDR5X memory from SK Hynix. According to the benchmark reading, four 8 GB modules were present, so we expect it to be on the system board, unlike on-chip like Intel does with Lunar Lake. The memory is running at 8000 MT/s, which is a 500 MT/s improvement over Strix Point and slower than its competitor, Lunar Lake, which has LPDDR5X running at 8533 MT/s. Lastly, the Krackan / Kraken Point APU has been spotted with eight RDNA 3.5 Compute Units. Where this exactly lands in AMD's product stack is still unclear. We expect to hear more about it as we enter 2025, so by then, remain patient until the next leak.

The second generation of AMD Ryzen Z-series processors for handheld gaming consoles, will be led by the Ryzen Z2 Extreme. There will also be an affordable Ryzen Z2 (non-Extreme). We've known for some time that the Z2 Extreme is based on the 4 nm "Strix Point" monolithic silicon, with some optimization (the highest bins to facilitate the best energy efficiency); but now we have a few more details thanks to a leak by Golden Pig Upgrade. AMD's engineering effort with the Z2 Extreme will be to give the console the most generational performance uplift from the iGPU, rather than the CPU.

The "Strix Point" silicon features a significantly updated iGPU from the previous-generation "Phoenix." It's based on the more efficient RDNA 3.5 graphics architecture, which is better optimized for LPDDR5 memory; and comes with 16 compute units (CU), compared to 12 on the "Phoenix." The Ryzen Z2 Extreme will come with all 16 CU enabled. The CPU is where some interesting changes are planned. The "Strix Point" silicon features a dual-CCX CPU, one of these contains four "Zen 5" CPU cores sharing a 16 MB L3 cache, while the other features eight "Zen 5c" cores sharing an 8 MB L3 cache. For the Ryzen Z2 Extreme, AMD is going with an odd 3+5 core configuration. What this means is that the Ryzen Z2 Extreme will have 3 "Zen 5" cores, and 5 "Zen 5c" cores. The L3 cache on the CCX with "Zen 5" cores has been reduced to 8 MB in size. On paper, this is still an 8-core/16-thread CPU with 16 MB of L3 cache (same as "Phoenix,") but now you know that there's more going on.

In case you missed it, AMD's new madcap enthusiast silicon engineering effort, the "Strix Halo," is real, and comes with the Ryzen AI Max 300 series branding. These are chiplet-based mobile processors with one or two "Zen 5" CCDs—same ones found in "Granite Ridge" desktop processors—paired with a large SoC die that has an oversized iGPU. This arrangement lets AMD give the processor up to 16 full-sized "Zen 5" CPU cores, and an iGPU with as many as 40 RDNA 3.5 compute units (2,560 stream processors), and a 256-bit LPDDR5/x memory interface for UMA.

"Strix Halo" is designed for ultraportable gaming notebooks or mobile workstations where low PCB footprint is of the essence, and discrete GPU is not an option. For enthusiast gaming notebooks with discrete GPUs, AMD is designing the "Fire Range" processor, which is essentially a mobile BGA version of "Granite Ridge," and a successor to the Ryzen 7045 series "Dragon Range." The Ryzen AI Max series has three models based on CPU and iGPU CU counts—the Ryzen AI Max 395+ (16-core/32-thread with 40 CU), the Ryzen AI Max 390 (12-core/24-thread with 40 CU), and the Ryzen AI Max 385 (8-core/16-thread, 32 CU). An alleged Ryzen AI Max 390 engineering sample surfaced on the Geekbench AI benchmark online database.

AMD today released early driver support for the Radeon 800M series integrated graphics of Ryzen AI 300 series mobile processors to use AMD Fluid Motion Frames 2 (AFMF 2), and Variable Graphics Memory (VGM) technologies. The two technologies receive optimization for the RDNA 3.5 graphics architecture driving the iGPU of the "Strix Point" silicon on which the Ryzen AI 300 series processors are based on. AFMF 2 is the second generation of AMD Fluid Motion Frames, a technology that lets you nearly double frame-rates on any Direct3D 11 or later game, without the gaming having explicit support for a frame generation technology, such as FSR 3 Frame Generation. AFMF operates out of the game's graphics pipeline, which adds a tiny bit of system latency. AFMF 2 seeks to reduce this latency.

Variable Graphics Memory (VGM) is another interesting feature that builds on top of the UMA (unified memory architecture) implementation of AMD processors with iGPUs. Depending on a 3D application's demands, the technology dynamically allocates up to 75% of the system memory as video memory for the iGPU, while ensuring the game doesn't run into unintentional performance bottlenecks arising from paging main memory if too much of it is used up by the iGPU. For VGM to work, a system needs at least 16 GB of main memory. VGM is not meant to be confused with the shared memory area that the processor allots to the iGPU by default (which ranges between 512 MB and 2 GB), it's designed to augment to this by eating into the system memory.

AMD is about to extend its mobile CPU lineup with the introduction of new Ryzen AI APUs, which are going to include the Krackan Point series which has been greatly expected. These CPUs are aimed at mainstream platforms and are targeted to bring performance, AI capabilities, and memory support to a new level. Krackan Point is supposed to be a cheaper alternative to the premium Strix Point series. Jack Huynh, Senior Vice President and General Manager of the Computing and Graphics Business Group of AMD confirmed at IFA 2024 that Krackan will be released to the mass market early in 2025.

One of the highlights is the support for LPDDR5X-8000 memory, this feature is expected to place the Krackan Point APUs close to AMD's Strix Halo series and compete directly with Intel's Lunar Lake processors. The XDNA2 Neural Processing Unit and also the certification of AMD for Microsoft Copilot+PC will be the advantages of this enhancement of the product.

AMD is readying a major update to its category-defining Ryzen Z-series SoCs, with the new Ryzen Z2. Designed for handheld game consoles, the Ryzen Z-series chips are typically power-optimized variants of its mobile processors designed for ultra-low board footprint, allowing PC OEMs to build handheld game consoles with them. Facing competition from Intel's upcoming Core Ultra 200V "Lunar Lake-MX" SoCs in this segment, AMD is readying the Ryzen Z2 chip. The Z2 is based on the 4 nm "Strix Point" silicon, which gives it a significantly updated iGPU, as well as a higher core-count CPU.

Perhaps the biggest sub-system performance uplift console designers can expect from the Ryzen Z2 is graphics—AMD has given the "Strix Point" a larger iGPU with 16 compute units in place of 12 on "Phoenix," which is a 33% increase in just numerical terms. Then there's also the update to the newer RDNA 3.5 graphics architecture, which incorporates several architecture-level performance and battery-efficiency improvements. It's also better optimized for LPDDR5 memory. With CPU, AMD has given "Strix Point" a heterogeneous multicore setup with four "Zen 5" and eight "Zen 5c" cores. At this point, we don't know if all 12 cores are enabled on the Z2. ASUS is designing its next generation of ROG Ally consoles powered by the Ryzen Z2, and its designers hint that the console should be able to offer over 1 hour of "Black Myth: Wukong" gameplay on a full charge of battery—something current-gen ROG Ally X powered by the Z1 doesn't.

AMD "Strix Halo" isn't just a mobile processor with an oversized iGPU meant to power "gaming ultraportables," it has other potential applications such as game consoles (both handheld and standalone). Not willing to cede this market to AMD, Intel is reportedly readying its own such chip, which is being reported as the "Arrow Lake Halo" for the lack of an official name. This chip will feature a large iGPU based on the Xe2 "Battlemage" graphics architecture, the variant of Xe2 Intel plans to use for its next-generation Arc discrete GPUs. The CPU compute complex will be carried over from the regular "Arrow Lake" chips, and feature a mix of "Lion Cove" P-cores, and "Skymont" E-core clusters.

To meet the higher memory bandwidth demand that arises from a high-performance iGPU and CPU, AMD designed the RDNA 3.5 graphics architecture to be more LPDDR5-aware, since at the physical layer, LPDDR operates differently from GDDR. Intel will probably do something similar, and deploy a 256-bit wide LPDDR5/x memory interface replacing the 128-bit wide interface the regular "Arrow Lake" mobile chips come with. Whether "Arrow Lake Halo" and "Strix Halo" remain competitive will depend a lot on which gaming experiences the two companies want to sell. The way the iGPU of "Strix Halo" is rumored to be specced suggests something that is 1440p-capable, or 4K-capable with FSR 3.

The first die shot of AMD's new 4 nm "Strix Point" mobile processor surfaced, thanks to an enthusiast on Chinese social media. "Strix Point" is a significantly larger die than "Phoenix." It measures 12.06 mm x 18.71 mm (L x W), compared to the 9.06 mm x 15.01 mm of "Phoenix." Much of this die size increase comes from the larger CPU, iGPU, and NPU. The process has been improved from TSMC N4 on "Phoenix" and its derivative "Hawk Point," to the newer TSMC N4P node.

Nemez (GPUsAreMagic) annotated the die shot in great detail. The CPU now has 12 cores spread across two CCX, one of which contains four "Zen 5" cores sharing a 16 MB L3 cache; and the other with eight "Zen 5c" cores sharing an 8 MB L3 cache. The two CCXs connect to the rest of the chip over Infinity Fabric. The rather large iGPU takes up the central region of the die. It is based on the RDNA 3.5 graphics architecture, and features 8 workgroup processors (WGPs), or 16 compute units (CU) worth 1,024 stream processors. Other key components include four render backends worth 16 ROPs, and control logic. The GPU has its own 2 MB of L2 cache that cushions transfers to the Infinity Fabric.

Since its reveal last week, we got a slightly more technical deep-dive from AMD on its two upcoming processors—the "Strix Point" silicon powering its Ryzen AI 300 series mobile processors; and the "Granite Ridge" chiplet MCM powering its Ryzen 9000 desktop processors. We present a closer look into the "Strix Point" SoC in this article. It turns out that "Strix Point" takes a significantly different approach to heterogeneous multicore than "Phoenix 2." AMD gave us a close look at how this works. AMD built the "Strix Point" monolithic silicon on the TSMC N4P foundry node, with a die-area of around 232 mm².

The "Strix Point" silicon sees the company's Infinity Fabric interconnect as its omnipresent ether. This is a point-to-point interconnect, unlike the ringbus on some Intel processors. The main compute machinery on the "Strix Point" SoC are its two CPU compute complexes (CCX), each with a 32b (read)/16b (write) per cycle data-path to the fabric. The concept of CCX makes a comeback with "Strix Point" after nearly two generations of "Zen." The first CCX contains the chip's four full-sized "Zen 5" CPU cores, which share a 16 MB L3 cache among themselves. The second CCX contains the chip's eight "Zen 5c" cores that share a smaller 8 MB L3 cache. Each of the 12 cores has a 1 MB dedicated L2 cache.

AMD presented a closer look at the Radeon 890M iGPU powering the Ryzen AI 300 series "Strix Point" mobile processor. The iGPU introduces the new RDNA 3.5 graphics architecture, with several architecture-level improvements built around the existing RDNA 3 SIMD, to yield performance/Watt improvements that AMD could trade in to increase the SIMD muscle for its processors, and proportionately increase performance. The iGPU features one Shader Engine with 8 workgroup processors (WGPs), which amount to 16 CU (compute units), for a total of 1,024 stream processors, 32 AI accelerators, and 16 Ray accelerators. The iGPU also has 4 render backends+, for 16 ROPs. It is specced with a maximum engine clock of 2.90 GHz, which yields over 11 TFLOP/s of FP32 throughput, which is around 30% higher than the iGPU of "Phoenix" (12 CU, RDNA 3), at comparable power.

AMD goes into the finer points of how it yielded the performance/Watt gains. The company worked on the texture subsystem to double the texture sampler rate, and introduced point-sampling acceleration. The shader sub-system features interpolation and comparison rate doubling. The raster sub-system introduces sub-batching of batch raster operations, with a programmable bin order, for the hardware to be more efficient. Lastly, AMD worked on the iGPU's memory-management, to be more aware of LPDDR5 (which has a different physical layer or way of writing/fetching than GDDR6). The company worked on improving the memory compression technologies, to improve performance, and reduce the iGPU's memory footprint.

AMD's upcoming "Strix Halo" mobile processor that features up to 16 "Zen 5" CPU cores and a powerful iGPU with 40 compute units, is beginning to surface in online benchmark databases. We've gone into the juicy technical bits about the processor in our older articles, but put simply, it is a powerful mobile processor meant to square off against the likes of the Apple M3 Pro and M3 Max. A chiplet-based processor, much like the upcoming "Granite Ridge" desktop processor and "Fire Range" mobile processor, "Strix Halo" features up to 16 full-sized "Zen 5" cores, as it uses up to two of the same "Eldora" CCDs as them; but wired to a large I/O die that contains the oversized iGPU, and an NPU, besides the memory controllers. The iGPU has 40 compute units (2,560 stream processors), and is based on the RDNA 3.5 graphics architecture, while the NPU is the same 50 TOPS-class unit carried over from "Strix Point."

A prototype HP laptop powered by a "Strix Halo" processor that uses a single 8-core "Zen 5" CCD, was spied on the web. This chip has eight full-sized "Zen 5" cores that share a 32 MB L3 cache. The iGPU on the I/O die has its own 32 MB Infinity Cache memory that cushions memory transfers. In our older reports, we speculated as to what the memory interface of "Strix Halo" would be. It turns out that the chip exclusively features a 256-bit wide LPDDR5X memory interface, which is double the bus width of "Strix Point." This is essentially what a "quad-channel DDR5" memory interface would be, and AMD is using a memory speed standard of at least LPDDR5X-8000. From the machine's point of view, this would be just a couple of hardwired LPDDR5X chips, or a pair of LPCAMM 2 modules. Back to the benchmarks, and we are shown a single-thread CPU score of 2099 to 2177 points, and a multithreaded score ranging between 5477 points to 13993 points. The laptop was tested with an unknown version and distribution of Linux. The CPU cores are shown boosting up to 5.35 GHz.

Apparently the AMD "Strix Halo" processor is real, and it's large. The chip is designed to square off against the likes of the Apple M3 Pro and M3 Max, in letting ultraportable notebooks have powerful graphics performance. A chiplet-based processor, not unlike the desktop socketed "Raphael," and mobile BGA "Dragon Range," the "Strix Halo" processor consists of one or two CCDs containing CPU cores, wired to a large die, that's technically the cIOD (client I/O die), but containing an oversized iGPU, and an NPU. The point behind "Strix Halo" is to eliminate the need for a performance-segment discrete GPU, and conserve its PCB footprint.

According to leaks by Harukaze5719, a reliable source with AMD leaks, "Strix Halo" comes in a BGA package dubbed FP11, measuring 37.5 mm x 45 mm, which is significantly larger than the 25 mm x 40 mm size of the FP8 BGA package that the regular "Strix Point," "Hawk Point," and "Phoenix" mobile processors are built on. It is larger in area than the 40 mm x 40 mm FL1 BGA package of "Dragon Range" and upcoming "Fire Range" gaming notebook processors. "Strix Halo" features one or two of the same 4 nm "Zen 5" CCDs featured on the "Granite Ridge" desktop and "Fire Range" mobile processors, but connected to a much larger I/O die, as we mentioned.

ASUS announced a press event on July 17 to launch at least nine notebook designs powered by AMD Ryzen AI 300 series "Strix Point" mobile processors. All these notebooks are AI PCs that meet Microsoft Copilot+ requirements. Each of the 9 designs will have several variants based on the processor model, discrete graphics, and other hardware differentiators, making up dozens of individual SKUs. The AMD "Strix Point" mobile processor is based on a 4 nm monolithic die. It combines a 12-core/24-thread CPU based on a combination of "Zen 5" and "Zen 5c" cores, a 50 TOPS-class NPU, and a powerful iGPU based on the RDNA 3.5 graphics architecture, with 16 compute units.

Among the notebook designs ASUS plans to announce on July 17 are the ROG Zephyrus G16 (GA605), the TUF Gaming A14 (FA401), the TUF Gaming A16 (FA608), the Zenbook S16 (UM5606), Vivobook S14 (M5406), Vivobook S16 (M5506 and M5606), ProArt P16 (HN7606) and ProArt PX13 (HN7306). With these, ASUS is covering pretty much all its notebook market segments, including enthusiast gaming, performance gaming, boutique ultraportability, mainstream, and creative professional.

The top-spec AMD Ryzen AI 9 300 series "Strix Point" processor, the Ryzen AI 9 HX 370, is expected to post a 20% performance improvement over both the CPU and integrated graphics fronts, over its predecessor, the Ryzen 9 8945HS "Hawk Point," according to leak by Golden Pig Upgrade. On the CPU front, the HX 370 packs a 12-core/24-thread CPU based on a combination of four "Zen 5" and eight "Zen 5c" cores. The single-thread performance gains on the basis of the "Zen 5" microarchitecture's generational IPC increase, besides higher clock speeds; while the multithreaded performance increases on account on more cores. This performance increase isn't linearly scaling with the 50% increase in core-count.

On "Hawk Point," all eight cores are "Zen 4," capable of boosting to high frequencies, with two of them being marked as CPPC preferred cores, capable of boosting the highest. On "Strix Point," however, only four cores are based on the "Zen 5" architecture and capable of boosting to high frequency bands; while the other eight are "Zen 5c," which don't boost as high. While the IPC of "Zen 5c" is identical to "Zen 5," the fact that it doesn't boost as high, means that the generational multithreaded performance gain from the core-count increase is expected to be closer to 20%, with Golden Pig Upgrade talking about a Cinebench R23 nT score of over 20000 points, with "Hawk Point" scoring around 16000 points.

Dr. Lisa Su introduced AMD's "next-gen AMD Ryzen" processor series during a recent presentation at the Beijing AI PC Innovation Summit—this announcement confirms that Team Red's RDNA 3+ (AKA 3.5) graphics technology is destined to arrive (on board) with the launch of "Strix Point" processors. Product roadmaps remain unchanged—when compared to slides from last December—AMD still anticipates a 2024 launch window. China has been introduced to current-gen "Hawk Point" Ryzen 8040 mobile and 8000G (AM5) desktop processors—key AMD personnel presented a variety of products, including region-specific budget options.

David Wang, SVP of GPU Technology and Engineering R&D, covered the RDNA 3+ and XDNA 2 architectures (very briefly) during his on-stage appearance—he dedicated most of his attention to current-gen "Hawk Point" processors. The Strix Point integrated solution—a GFX1150 target—has been linked to "RDNA 3.5" for a while, a lot of this information was gleaned from publicly visible AMD patch notices. The latest Team Red software engineering activities indicate that Zen 5 CPU enablement is nearing a possible finish line.

AMD Linux engineers have been working on "GFX1150" and "GFX1151" targets for a while—official references to "Strix 1/Strix Point" and "Strix Point Halo" have appeared several times on official development channels. Phoronix's head honcho—Michael Larabel—monitors these activities with keen interest, his latest finding indicates that Team Red is preparing open-source RadeonSI/RADV driver support for the GFX1151 IP. Their MESA 24.1 update merges in GPU enablement for possible high-end "Strix Point Halo" laptop processors—tech tipsters believe that these chiplet variants could sport up to sixteen Zen 5 CPU cores and forty RDNA 3.5 GPU cores.

AMD's enablement of the "GFX1150/Strix Point" GPU appeared online late last month—these monolithic laptop chips are alleged to sit below "Strix Point Halo" in Team Red's product hierarchy. Insiders suggest that the best configurations could house twelve Zen 5 CPU cores and sixteen RDNA 3.5 GPU cores. Phoronix posited that the "RDNA 3 refresh" graphics solution: "is just rumored for select APUs, while ultimately we'll see where this GFX 11.5.1 IP is found if for some further upgraded APU or something more special. In any event the open-source Linux driver support is coming together." According to official product roadmaps, the initial batch of "Strix Point" mobile chips are expected ship later this year—representing a proper next-gen upgrade over current "Hawk Point" offerings.

Everest (@Olrak29_) has kept track of many AMD processor families over the past couple of years—his latest insight provides an early look at the alleged internal makeup of Team Red's "Kraken Point" APU series. The rumor mill has designated these next-gen mobile processors as 2025 follow-ups to the recently launched Ryzen 8040 "Hawk Point" family of mainstream laptop APUs. The tipster's initial social media post only mentioned the presence of both Zen 5 and Zen 5c cores within Kraken Point processors, but he later clarified that a total of eight cores would include four large units and four smaller types. TPU's past coverage of Kraken Point pointed to rumors of an 8-core, 16-thread configuration, but leaked slides (from late 2023) did not mention the integration of efficiency-tuned Zen 5c "Prometheus" cores, along with presumed Zen 5 "Nirvana" cores.

Everest's continuous flow of insider information reveals that "Kraken Point" shares many "Hawk Point" traits—four workgroup processors (WGP) could be present on final retail products, granting eight compute units (8 CUs in total). He responded to a query regarding AMD's choice of integrated graphics technology—the succinct answer being RDNA 3.5. Past leaks allege that XDNA 2 will drive the NPU side of things—offering a performance range of around 45 to 50 TOPS. The Kraken Point APU is believed to be sticking with a safe monolithic die design, manufactured on a non-specific 4 nm process. Team Red is rumored to be in TSMC's order books for all sorts of next generation silicon.

References to GFX1150 & GFX1151 targets have been spotted again—this time in a ROCm Github repository—by renowned hardware sleuth; Kepler_L2. These references were first spotted last summer, in an AMDGPU LLVM backend/compiler (reported by Phoronix)—industry experts immediately linked these target codes to next generation "Strix" APU families. The latest leak provides confirmation that the GFX1150 ID is tied to "Strix Point 1," while GFX1151 is an internal IP for "Strix Point Halo," or simply "Strix Halo." The freshly published ROCm Github's commit is titled: "Strix Halo Support and Strix support in staging," which corroborates previous rumors regarding Team Red's engineers being deep into development of Zen 5 (and RDNA 3.5)-based accelerated processing units.

AMD has published several processor product roadmaps with references to "Strix Point" next-gen APUs, with a targeted 2024 launch window. Their December 2023 "Advancing AI Event" confirmed that the "Strix Point" mobile family will sport "XDNA 2" NPUs—previous generation "Phoenix" and recently released "Hawk Point" processors are on the first iteration of XDNA (a spatial dataflow NPU architecture). It is speculated that a typical "Strix Point" laptop processor will pack 12 Zen 5 CPU cores and 16 RDNA 3.5 GPU cores. Team Red has kept quiet about "Strix Halo" (also known as "Sarlak") when conducting public-facing presentations—a loose 2025 launch window is being touted by the rumor mill. The most advanced examples could feature up to 16 Zen 5 CPU cores and 40 RDNA 3.5 GPU cores.