Intel Graphics Technology
Intel Graphics Technology[4] (GT)[lower-alpha 1] is the collective name for a series of integrated graphics processors (IGPs) produced by Intel that are manufactured on the same package or die as the central processing unit (CPU). It was first introduced in 2010 as Intel HD Graphics and renamed in 2017 as Intel UHD Graphics.
API support | |
---|---|
Direct3D |
|
OpenCL | Depending on version (see capabilities)[1] |
OpenGL | OpenGL 2.1+ (see capabilities)[1][2][3] |
Vulkan | Depending on version |
History | |
Predecessor | Intel GMA |
Intel Iris Graphics and Intel Iris Pro Graphics are the IGP series introduced in 2013 with some models of Haswell processors as the high-performance versions of HD Graphics. Iris Pro Graphics was the first in the series to incorporate embedded DRAM.[5] Since 2016 Intel refers to the technology as Intel Iris Plus Graphics with the release of Kaby Lake.
In the fourth quarter of 2013, Intel integrated graphics represented, in units, 65% of all PC graphics processor shipments.[6] However, this percentage does not represent actual adoption as a number of these shipped units end up in systems with discrete graphics cards.
History
Before the introduction of Intel HD Graphics, Intel integrated graphics were built into the motherboard's northbridge, as part of the Intel's Hub Architecture. They were known as Intel Extreme Graphics and Intel GMA. As part of the Platform Controller Hub (PCH) design, the northbridge was eliminated and graphics processing was moved to the same die as the central processing unit (CPU).
The previous Intel integrated graphics solution, Intel GMA, had a reputation of lacking performance and features, and therefore was not considered to be a good choice for more demanding graphics applications, such as 3D gaming. The performance increases brought by Intel's HD Graphics made the products competitive with integrated graphics adapters made by its rivals, Nvidia and ATI/AMD.[7] Intel HD Graphics, featuring minimal power consumption that is important in laptops, was capable enough that PC manufacturers often stopped offering discrete graphics options in both low-end and high-end laptop lines, where reduced dimensions and low power consumption are important.
Generations
Intel HD and Iris Graphics are divided into generations, and within each generation are divided into 'tiers' of increasing performance, denominated by the 'GTx' label. Each generation corresponds to the implementation of a Gen[8] graphics microarchitecture with a corresponding GEN instruction set architecture[9][10][11] since Gen4.[12]
Gen5 architecture
Westmere
In January 2010, Clarkdale and Arrandale processors with Ironlake graphics were released, and branded as Celeron, Pentium, or Core with HD Graphics. There was only one specification:[13] 12 execution units, up to 43.2 GFLOPS at 900 MHz. It can decode a H264 1080p video at up to 40 fps.
Its direct predecessor, the GMA X4500, featured 10 EUs at 800 MHz, but it lacked some capabilities.[14]
Model number | Execution units | Shading units | Base clock (MHz) | Boost clock (MHz) | GFLOPS (FP32) |
---|---|---|---|---|---|
HD Graphics | 12 | 24 | 500 | 900 | 24.0–43.2 |
Gen6 architecture
Sandy Bridge
In January 2011, the Sandy Bridge processors were released, introducing the "second generation" HD Graphics:
Model number | Tier | Execution units | Boost clock (MHz) |
Max GFLOPS | ||
---|---|---|---|---|---|---|
FP16 | FP32 | FP64 | ||||
HD Graphics | GT1 | 6 | 1000 | 192 | 96 | 24 |
HD Graphics 2000 | 1350 | 259 | 129.6 | 32 | ||
HD Graphics 3000 | GT2 | 12 | 1350 | 518 | 259.2 | 65 |
Sandy Bridge Celeron and Pentium have Intel HD, while Core i3 and above have either HD 2000 or HD 3000. HD Graphics 2000 and 3000 include hardware video encoding and HD postprocessing effects.
Gen7 architecture
Ivy Bridge
On 24 April 2012, Ivy Bridge was released, introducing the "third generation" of Intel's HD graphics:[15]
Model number | Tier | Execution units | Shading units | Boost clock (MHz) | Max GFLOPS (FP32) |
---|---|---|---|---|---|
HD Graphics [Mobile] | GT1 | 6 | 48 | 1050 | 100.8 |
HD Graphics 2500 | 1150 | 110.4 | |||
HD Graphics 4000 | GT2 | 16 | 128 | 1300 | 332.8 |
HD Graphics P4000 | GT2 | 16 | 128 | 1300 | 332.8 |
Ivy Bridge Celeron and Pentium have Intel HD, while Core i3 and above have either HD 2500 or HD 4000. HD Graphics 2500 and 4000 include hardware video encoding and HD postprocessing effects.
For some low-power mobile CPUs there is limited video decoding support, while none of the desktop CPUs have this limitation. HD P4000 is featured on the Ivy Bridge E3 Xeon processors with the 12X5 v2 descriptor, and supports unbuffered ECC RAM.
Gen7.5 architecture
Haswell
In June 2013, Haswell CPUs were announced, with four tiers of integrated GPUs:
Model number | Tier | Execution units |
Shading units |
eDRAM (MB) |
Boost clock (MHz) |
Max GFLOPS | ||
---|---|---|---|---|---|---|---|---|
FP16 | FP32 | FP64 | ||||||
Consumer | ||||||||
HD Graphics | GT1 | 10 | 80 | N/A | 1150 | 384 | 192 | 48 |
HD Graphics 4200 | GT2 | 20 | 160 | 850 | 544 | 272 | 68 | |
HD Graphics 4400 | 950–1150 | 608-736 | 304–368 | 76-92 | ||||
HD Graphics 4600 | 900–1350 | 576-864 | 288–432 | 72-108 | ||||
HD Graphics 5000 | GT3 | 40 | 320 | 1000–1100 | 1280-1408 | 640–704 | 160-176 | |
Iris Graphics 5100 | 1100–1200 | 1408-1536 | 704–768 | 176-192 | ||||
Iris Pro Graphics 5200 | GT3e | 128 | 1300 | 1280-1728 | 640-864 | 160-216 | ||
Professional | ||||||||
HD Graphics P4600 | GT2 | 20 | 160 | N/A | 1200–1250 | 768-800 | 384–400 | 96-100 |
HD Graphics P4700 | 1250–1300 | 800-832 | 400–416 | 100-104 |
The 128 MB of eDRAM in the Iris Pro GT3e is in the same package as the CPU, but on a separate die manufactured in a different process. Intel refers to this as a Level 4 cache, available to both CPU and GPU, naming it Crystalwell. The Linux drm/i915
driver is aware and capable of using this eDRAM since kernel version 3.12.[16][17][18]
Gen8 architecture
Broadwell
In November 2013, it was announced that Broadwell-K desktop processors (aimed at enthusiasts) would also carry Iris Pro Graphics.[19]
The following models of integrated GPU are announced for Broadwell processors:[20]
Model number | Tier | Execution units |
Shading units |
eDRAM (MB) |
Boost clock (MHz) |
Max GFLOPS (FP32) |
---|---|---|---|---|---|---|
Consumer | ||||||
HD Graphics | GT1 | 12 | 96 | — | 850 | 163.2 |
HD Graphics 5300 | GT2 | 24 | 192 | 900 | 345.6 | |
HD Graphics 5500 | 950 | 364.8 | ||||
HD Graphics 5600 | 1050 | 403.2 | ||||
HD Graphics 6000 | GT3 | 48 | 384 | 1000 | 768 | |
Iris Graphics 6100 | 1100 | 844.8 | ||||
Iris Pro Graphics 6200 | GT3e | 128 | 1150 | 883.2 | ||
Professional | ||||||
HD Graphics P5700 | GT2 | 24 | 192 | – | 1000 | 384 |
Iris Pro Graphics P6300 | GT3e | 48 | 384 | 128 | 1150 | 883.2 |
Braswell
Model number | CPU model |
Tier | Execution units |
Clock speed (MHz) |
---|---|---|---|---|
HD Graphics 400 | E8000 | GT1 | 12 | 320 |
N30xx | 320–600 | |||
N31xx | 320–640 | |||
J3xxx | 320–700 | |||
HD Graphics 405 | N37xx | 16 | 400–700 | |
J37xx | 18 | 400–740 |
Gen9 architecture
Skylake
The Skylake line of processors, launched in August 2015, retires VGA support, while supporting multi-monitor setups of up to three monitors connected via HDMI 1.4, DisplayPort 1.2 or Embedded DisplayPort (eDP) 1.3 interfaces.[21][22]
The following models of integrated GPU are available or announced for the Skylake processors:[23][24]
Model number | Tier | Execution units |
Shading units |
eDRAM (MB) |
Boost clock (MHz) |
Max GFLOPS (FP32) |
---|---|---|---|---|---|---|
Consumer | ||||||
HD Graphics 510 | GT1 | 12 | 96 | — | 1050 | 201.6 |
HD Graphics 515 | GT2 | 24 | 192 | 1000 | 384 | |
HD Graphics 520 | 1050 | 403.2 | ||||
HD Graphics 530 | 1150[21] | 441.6 | ||||
Iris Graphics 540 | GT3e | 48 | 384 | 64 | 1050 | 806.4 |
Iris Graphics 550 | 1100 | 844.8 | ||||
Iris Pro Graphics 580 | GT4e | 72 | 576 | 128 | 1000 | 1152 |
Professional | ||||||
HD Graphics P530 | GT2 | 24 | 192 | – | 1150 | 441.6 |
Iris Pro Graphics P555 | GT3e | 48 | 384 | 128 | 1000[25] | 768 |
Iris Pro Graphics P580 | GT4e | 72 | 576 | 1000 | 1152 |
Apollo Lake
The Apollo Lake line of processors was launched in August 2016.
Model number | CPU model |
Tier | Execution units |
Shading units |
Clock speed (MHz) |
---|---|---|---|---|---|
HD Graphics 500 | E3930 | GT1 | 12 | 96 | 400 – 550 |
E3940 | 400–600 | ||||
N3350 | 200–650 | ||||
N3450 | 200–700 | ||||
J3355 | 250–700 | ||||
J3455 | 250–750 | ||||
HD Graphics 505 | E3950 | 18 | 144 | 500–650 | |
N4200 | 200–750 | ||||
J4205 | 250–800 |
Gen9.5 architecture
Kaby Lake
The Kaby Lake line of processors was introduced in August 2016. New features: speed increases, support for 4K UHD "premium" (DRM encoded) streaming services, media engine with full hardware acceleration of 8- and 10-bit HEVC and VP9 decode.[26][27]
Model number | Tier | Execution units |
Shading units |
eDRAM (MB) |
Base clock (MHz) |
Boost clock (MHz) |
Max GFLOPS (FP32) |
Used in | |
---|---|---|---|---|---|---|---|---|---|
Consumer | |||||||||
HD Graphics 610 | GT1 | 12 | 96 | — | 300−350 | 900−1100 | 172.8–211.2 | Desktop Celeron, Desktop Pentium G4560, i3-7101 | |
HD Graphics 615 | GT2 | 24 | 192 | 300 | 900 – 1050 | 345.6 – 403.2 | m3-7Y30/32, i5-7Y54/57, i7-7Y75, Pentium 4415Y | ||
HD Graphics 620 | 1000–1050 | 384–403.2 | i3-7100U, i5-7200U, i5-7300U, i7-7500U, i7-7600U | ||||||
HD Graphics 630 | 350 | 1000–1150 | 384−441.6 | Desktop Pentium G46**, i3, i5 and i7, and Laptop H-series i3, i5 and i7 | |||||
Iris Plus Graphics 640 | GT3e | 48 | 384 | 64 | 300 | 950–1050 | 729.6−806.4 | i5-7260U, i5-7360U, i7-7560U, i7-7660U | |
Iris Plus Graphics 650 | 1050–1150 | 806.4−883.2 | i3-7167U, i5-7267U, i5-7287U, i7-7567U | ||||||
Professional | |||||||||
HD Graphics P630 | GT2 | 24 | 192 | – | 350 | 1000–1150 | 384−441.6 | Xeon E3-**** v6 |
Kaby Lake Refresh / Amber Lake / Coffee Lake / Coffee Lake Refresh / Whiskey Lake / Comet Lake
The Kaby Lake Refresh line of processors was introduced in October 2017. New features: HDCP 2.2 support[28]
Model number | Tier | Execution units |
Shading units |
eDRAM (MB) |
Base clock (MHz) |
Boost clock (MHz) |
Max GFLOPS (FP32) |
Used in |
---|---|---|---|---|---|---|---|---|
Consumer | ||||||||
UHD Graphics 610 | GT1 | 12 | 96 | – | 350 | 1050 | 201.6 | Pentium Gold G54**, Celeron G49**
i5-10200H |
UHD Graphics 615 | GT2 | 24 | 192 | 300 | 900–1050 | 345.6–403.2 | i7-8500Y, i5-8200Y, m3-8100Y | |
UHD Graphics 617 | 1050 | 403.2 | i7-8510Y, i5-8310Y, i5-8210Y | |||||
UHD Graphics 620 | 1000–1150 | 422.4–441.6 | i3-8130U, i5-8250U, i5-8350U, i7-8550U, i7-8650U, i3-8145U, i5-8265U, i5-8365U, i7-8565U, i7-8665U
i3-10110U, i5-10210U, i5-10310U, i7-10510U i7-10610U i7-10810U | |||||
UHD Graphics 630 | 23[29] | 184 | 350 | 1100–1150 | 404.8–423.2 | i3-8350K, i3-8100 with stepping B0 | ||
24 | 192 | 1050–1250 | 403.2–480 | i9, i7, i5, i3, Pentium Gold G56**, G55**
i5-10300H, i5-10400H, i5-10500H, i7-10750H, i7-10850H, i7-10870H, i7-10875H, i9-10885H, i9-10980HK | ||||
Iris Plus Graphics 645 | GT3e | 48 | 384 | 128 | 300 | 1050–1150 | 806.4-883.2 | i7-8557U, i5-8257U |
Iris Plus Graphics 655 | 1050–1200 | 806.4–921.6 | i7-8559U, i5-8269U, i5-8259U, i3-8109U | |||||
Professional | ||||||||
UHD Graphics P630 | GT2 | 24 | 192 | – | 350 | 1100–1200 | 422.4–460.8 | Xeon E 21**G, 21**M, 22**G, 22**M, Xeon W-108**M |
Gemini Lake/Gemini Lake Refresh
New features: HDMI 2.0 support, VP9 10-bit Profile2 hardware decoder[30]
Model number | Tier | Execution units |
Shading units |
CPU model |
Clock speed (MHz) |
GFLOPS (FP32) |
---|---|---|---|---|---|---|
UHD Graphics 600 | GT1 | 12 | 96 | N4000 | 200–650 | 38.4–124.8 |
N4100 | 200–700 | 38.4–134.4 | ||||
J4005 | 250–700 | 48.0–134.4 | ||||
J4105 | 250–750 | 48.0–144.0 | ||||
J4125 | 250–750 | 48.0–144.0 | ||||
UHD Graphics 605 | GT1.5 | 18 | N5000 | 200–750 | 57.6–216 | |
J5005 | 250–800 | 72.0–230.4 |
Gen11 architecture
Ice Lake
New features: 10 nm Gen 11 GPU microarchitecture, two HEVC 10-bit encode pipelines, three 4K display pipelines (or 2× 5K60, 1× 4K120), variable rate shading (VRS),[31][32][33] and integer scaling.[34]
While the microarchitecture continues to support double-precision floating-point as previous versions did, the mobile configurations of it do not include the feature and therefore on these it is supported only through emulation.[35]
Name | Tier | Execution units |
Shading units |
Base clock (MHz) |
Boost clock (MHz) |
GFLOPS | Used in | ||
---|---|---|---|---|---|---|---|---|---|
FP16 | FP32 | FP64 | |||||||
Consumer | |||||||||
UHD Graphics | G1 | 32 | 256 | 300 | 900–1050 | 921.6–1075.2 | 460.8–537.6 | 115.2 | Core i3-10**G1, i5-10**G1 |
Iris Plus Graphics | G4 | 48 | 384 | 300 | 900–1050 | 1382.4–1612.8[36] | 691.2–806.4 | 96-202 | Core i3-10**G4, i5-10**G4 |
G7 | 64 | 512 | 300 | 1050–1100 | 2150.4–2252.8[36] | 1075.2–1126.4 | 128-282 | Core i5-10**G7, i7-10**G7 |
Xe-LP architecture (Gen12)
Model | Process | Execution units |
Shading units |
Max boost clock (MHz) |
Processing power (GFLOPS) | Notes | |||
---|---|---|---|---|---|---|---|---|---|
FP16 | FP32 | FP64 | INT8 | ||||||
Intel UHD Graphics 730 | Intel 14++ nm | 24 | 192 | 1200–1300 | 922–998 | 461–499 | 231–250 | 1843–1997 | Used in Rocket Lake-S |
Intel UHD Graphics 750 | 32 | 256 | 1200–1300 | 1228–1332 | 614–666 | 307–333 | 2457–2662 | ||
Intel UHD Graphics P750 | 32 | 256 | 1300 | 1332 | 666 | 333 | 2662 | Used in Xeon W-1300 series | |
Intel UHD Graphics 710 | Intel 7 (previously 10ESF) |
16 | 128 | 1300–1350 | 666–692 | 333–346 | 167–173 | 1331–1382 | Used in Alder Lake-S & Raptor Lake-S |
Intel UHD Graphics 730 | 24 | 192 | 1400–1450 | 1076–1114 | 538–557 | 269–279 | 2150–2227 | ||
Intel UHD Graphics 770 | 32 | 256 | 1450–1550 | 1484–1588 | 742–794 | 371–397 | 2970–3174 | ||
Intel UHD Graphics for 11th Gen Intel Processors | Intel 10SF | 32 | 256 | 1400–1450 | 1434–1484 | 717–742 | 359–371 | 2867–2970 | Used in Tiger Lake-H |
Intel UHD Graphics for 11th Gen Intel Processors G4 | 48 | 384 | 1100–1250 | 1690–1920 | 845–960 | 422–480 | 3379–3840 | Used in Tiger Lake-U | |
Iris Xe Graphics G7 | 80 | 640 | 1100–1300 | 2816–3328 | 1408–1664 | 704–832 | 5632–6656 | ||
Iris Xe Graphics G7 | 96 | 768 | 1050–1450 | 3379–4454 | 1690–2227 | 845–1114 | 6758–8909 | ||
Intel UHD Graphics for 12th Gen Intel Processors Intel UHD Graphics for 13th Gen Intel Processors |
Intel 7 (previously 10ESF) |
48 | 384 | 700–1200 | 1075–1843 | 538–922 | 269–461 | 2151–3686 | Used in Alder Lake-H/P/U & Raptor Lake-H/P/U |
Intel UHD Graphics for 12th Gen Intel Processors Intel UHD Graphics for 13th Gen Intel Processors |
64 | 512 | 850–1400 | 1741–2867 | 870–1434 | 435–717 | 3482–5734 | ||
Iris Xe Graphics | 80 | 640 | 900–1400 | 2304–3584 | 1152–1792 | 0[37] | 4608–7168 | ||
Iris Xe Graphics | 96 | 768 | 900–1450 | 2765–4454 | 1382–2227 | 0 | 5530–8909 |
These are based on the Intel Xe-LP microarchitecture, the low power variant of the Intel Xe GPU architecture[38] also known as Gen 12.[39][40] New features include Sampler Feedback,[41] Dual Queue Support,[41] DirectX12 View Instancing Tier2,[41] and AV1 8-bit and 10-bit fixed-function hardware decoding.[42]
Features
Intel Insider
Beginning with Sandy Bridge, the graphics processors include a form of digital copy protection and digital rights management (DRM) called Intel Insider, which allows decryption of protected media within the processor.[47][48] Previously there was a similar technology called Protected Audio Video Path (PAVP).
HDCP
Intel Graphics Technology supports the HDCP technology, but the actual HDCP support depends on the computer's motherboard.
Intel Quick Sync Video
Intel Quick Sync Video is Intel's hardware video encoding and decoding technology, which is integrated into some of the Intel CPUs. The name "Quick Sync" refers to the use case of quickly transcoding ("syncing") a video from, for example, a DVD or Blu-ray Disc to a format appropriate to, for example, a smartphone. Quick Sync was introduced with the Gen 6 in Sandy Bridge microprocessors on 9 January 2011.
Graphics Virtualization Technology
Graphics Virtualization Technology (GVT) was announced 1 January 2014 and introduced at the same time as Intel Iris Pro. Intel integrated GPUs support the following sharing methods:[49][50]
- Direct passthrough (GVT-d): the GPU is available for a single virtual machine without sharing with other machines
- Paravirtualized API forwarding (GVT-s): the GPU is shared by multiple virtual machines using a virtual graphics driver; few supported graphics APIs (OpenGL, DirectX), no support for GPGPU
- Full GPU virtualization (GVT-g): the GPU is shared by multiple virtual machines (and by the host machine) on a time-sharing basis using a native graphics driver; similar to AMD's MxGPU and Nvidia's vGPU, which are available only on professional line cards (Radeon Pro and Nvidia Quadro)
- Full GPU virtualization in hardware (SR-IOV): The gpu can be partitioned and used/shared by multiple virtual machines and the host with support built-in hardware, unlike GVT-g that does this in software(driver).[51]
Gen9 (i.e. Graphics powering 6th through 9th generation Intel processors) is the last generation of the software-based vGPU solution GVT-G (Intel® Graphics Virtualization Technology –g). SR-IOV (Single Root IO Virtualization) is supported only on platforms with 11th Generation Intel® Core™ "G" Processors (products formerly known as Tiger Lake) or newer. This leaves Rocket Lake (11th Gen Intel Processors) without support for GVT-g and/or SR-IOV. This means Rocket Lake has no full virtualization support.[52]
Multiple monitors
Ivy Bridge
HD 2500 and HD 4000 GPUs in Ivy Bridge CPUs are advertised as supporting three active monitors, but this only works if two of the monitors are configured identically, which covers many[53] but not all three-monitor configurations. The reason for this is that the chipsets only include two phase-locked loops (PLLs) for generating the pixel clocks timing the data being transferred to the displays.[54]
Therefore, three simultaneously active monitors can only be achieved when at least two of them share the same pixel clock, such as:
- Using two or three DisplayPort connections, as they require only a single pixel clock for all connections.[55] Passive adapters from DisplayPort to some other connector do not count as a DisplayPort connection, as they rely on the chipset being able to emit a non-DisplayPort signal through the DisplayPort connector. Active adapters that contain additional logic to convert the DisplayPort signal to some other format count as a DisplayPort connection.
- Using two non-DisplayPort connections of the same connection type (for example, two HDMI connections) and the same clock frequency (like when connected to two identical monitors at the same resolution), so that a single unique pixel clock can be shared between both connections.[53]
Another possible three-monitor solution uses the Embedded DisplayPort on a mobile CPU (which does not use a chipset PLL at all) along with any two chipset outputs.[55]
Capabilities (GPU hardware)
Micro- architecture – Socket | Brand | Graphics | Vulkan | OpenGL | Direct3D | HLSL shader model | OpenCL | ||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Core | Xeon | Pentium | Celeron | Gen | Graphics brand | Linux | Windows | Linux | Windows | Linux | Windows | Linux | Windows | ||
Westmere – 1156 | i3/5/7-xxx | — | (G/P)6000 and U5000 | P4000 and U3000 | 5.5th[58] | HD | — | 2.1 | — | 10.1[1] | 4.1 | — | |||
Sandy Bridge – 1155 | i3/5/7-2000 | E3-1200 | (B)900, (G)800 and (G)600 | (B)800, (B)700, G500 and G400 | 6th[59] | HD 3000 and 2000 | 3.3[60] | 3.1[1] | |||||||
Ivy Bridge - 1155 | i3/5/7-3000 | E3-1200 v2 | (G)2000 and A1018 | G1600, 1000 and 900 | 7th[61][62] | HD 4000 and 2500 | 1.0 | — | 4.2[63] | 4.0[1][64] | 11.0 | 5.0 | 1.2 (Beignet) | 1.2[65] | |
Bay Trail – SoCs | — | — | J2000, N3500 and A1020 | J1000 and N2000 | HD Graphics (Bay Trail)[66] | ||||||||||
Haswell – 1150 | i3/5/7-4000 | E3-1200 v3 | (G)3000 | G1800 and 2000 | 7.5th[67] | HD 5000, 4600, 4400 and 4200; Iris Pro 5200, Iris 5000 and 5100 | 4.6[68] | 4.3[69] | 12 (fl 11_1)[70] | ||||||
Broadwell - 1150 | i3/5/7-5000 | E3-1200 v4 | 3800 | 3700 and 3200 | 8th[71] | Iris Pro 6200[72] and P6300, Iris 6100[73] and HD 6000,[74] P5700, 5600,[75] 5500,[76] 5300[77] and HD Graphics (Broadwell)[78] | 4.6[79] | 4.4[1] | 11[80] | 1.2 (Beignet) / 2.1 (Neo)[81] | 2.0 | ||||
Braswell – SoCs | — | — | N3700 | N3000, N3050, N3150 | HD Graphics (Braswell),[82] based on Broadwell graphics | 1.2 (Beignet) | |||||||||
— | — | (J/N)3710 | (J/N)3010, 3060, 3160 | (rebranded) HD Graphics 400, 405 | |||||||||||
Skylake - 1151 | i3/5/7-6000 | E3-1200 v5 E3-1500 v5 | (G)4000 | 3900 and 3800 | 9th | HD 510, 515, 520, 530 and 535; Iris 540 and 550; Iris Pro 580 | 1.3 Mesa 22.1[83] | 1.3[84] | 4.6[85] | 12 (fl 12_1) | 6.0 | 2.0 (Beignet)[86] / 3.0 (Neo)[81] | |||
Apollo Lake - SoCs | — | — | (J/N)4xxx | (J/N)3xxx | HD Graphics 500, 505 | ||||||||||
Gemini Lake – SoCs | — | — | Silver (J/N)5xxx | (J/N)4xxx | 9.5th[87] | UHD 600, 605 | |||||||||
Kaby Lake - 1151 | m3/i3/5/7-7000 | E3-1200 v6 E3-1500 v6 | (G)4000 | (G)3900 and 3800 | HD 610, 615, 620, 630, Iris Plus 640, Iris Plus 650 | 2.0 (Beignet)[86] / 3.0 (Neo)[81] | 2.1[84] | ||||||||
Kaby Lake Refresh – 1151 | i5/7-8000U | — | — | — | UHD 620 | ||||||||||
Whiskey Lake - 1151 | i3/5/7-8000U | — | — | — | |||||||||||
Coffee Lake - 1151 | i3/5/7/9-8000 i3/5/7/9-9000 | E-2100 E-2200 | Gold (G)5xxx | (G)49xx | UHD 630, Iris Plus 655 | ||||||||||
Ice Lake – 1526 | i3/5/7-10xx(N)Gx | — | — | — | 11th | UHD, Iris Plus | 3.0 (Neo)[81] | ||||||||
Tiger Lake | i3/5/7-11xx(N)Gx | W-11xxxM | Gold (G)7xxx | (G)6xxx | 12th | Iris Xe, UHD | 4.6[88] | 3.0 (Neo)[81] | 3.0 (Neo) |
OpenCL 2.1 and 2.2 possible with software update on OpenCL 2.0 hardware (Broadwell+) with future software updates.[89]
Support in Mesa is provided by two Gallium3D-style drivers, with the Iris driver supporting Broadwell hardware and later,[90] while the Crocus driver supports Haswell and earlier.[91] The classic Mesa i965 driver was removed in Mesa 22.0, although it would continue to see further maintenance as part of the Amber branch.[92]
New OpenCL driver is Mesa RustiCL and this driver written in new language Rust is OpenCL 3.0 conformant for Intel XE Graphics with Mesa 22.3. Intel Broadwell and higher will be also conformant to 3.0 with many 2.x features. For Intel Ivy Bridge and Haswell target is OpenCL 1.2. Actual development state is available in mesamatrix.
NEO compute runtime driver supports openCL 3.0 with 1.2, 2.0 and 2.1 included for Broadwell and higher and Level Zero API 1.3 for Skylake and higher.[93]
All GVT virtualization methods are supported since the Broadwell processor family with KVM[94] and Xen.[95]
Capabilities (GPU video acceleration)
Intel developed a dedicated SIP core which implements multiple video decompression and compression algorithms branded Intel Quick Sync Video. Some are implemented completely, some only partially.
Hardware-accelerated algorithms
CPU's microarchitecture |
Steps | video compression and decompression algorithms | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
H.265 (HEVC) | H.264 (MPEG-4 AVC) | H.262 (MPEG-2) | VC-1/WMV9 | JPEG / MJPEG | VP8 | VP9 | AV1 | |||
Westmere[96] | Decode | ✘ | ✓ | ✓ | ✓ | ✘ | ✘ | ✘ | ✘ | |
Encode | ✘ | ✘ | ✘ | |||||||
Sandy Bridge | Decode | Profiles | ✘ | ConstrainedBaseline, Main, High, StereoHigh | Simple, Main | Simple, Main, Advanced | ✘ | ✘ | ✘ | ✘ |
Levels | ||||||||||
Max. resolution | ||||||||||
Encode | Profiles | ConstrainedBaseline, Main, High | ✘ | ✘ | ✘ | ✘ | ✘ | ✘ | ||
Levels | ||||||||||
Max. resolution | ||||||||||
Ivy Bridge | Decode | Profiles | ✘ | ConstrainedBaseline, Main, High, StereoHigh | Simple, Main | Simple, Main, Advanced | Baseline | ✘ | ✘ | ✘ |
Levels | ||||||||||
Max. resolution | ||||||||||
Encode | Profiles | ConstrainedBaseline, Main, High | Simple, Main | ✘ | ✘ | ✘ | ✘ | ✘ | ||
Levels | ||||||||||
Max. resolution | ||||||||||
Haswell | Decode | Profiles | Partial 8-bit[97] | Main, High, SHP, MHP | Main | Simple, Main, Advanced | Baseline | ✘ | ✘ | ✘ |
Levels | 4.1 | Main, High | High, 3 | |||||||
Max. resolution | 1080/60p | 1080/60p | 16k×16k | |||||||
Encode | Profiles | ✘ | Main, High | Main | ✘ | Baseline | ✘ | ✘ | ✘ | |
Levels | 4.1 | High | - | |||||||
Max. resolution | 1080/60p | 1080/60p | 16k×16k | |||||||
Broadwell[98][99] | Decode | Profiles | Partial 8-bit & 10-bit[97] | Main | Simple, Main, Advanced | 0 | Partial[97] | ✘ | ||
Levels | Main, High | High, 3 | Unified | |||||||
Max. resolution | 1080/60p | 1080p | ||||||||
Encode | Profiles | ✘ | Main | - | ✘ | ✘ | ✘ | ✘ | ||
Levels | Main, High | |||||||||
Max. resolution | 1080/60p | |||||||||
Skylake[100] | Decode | Profiles | Main | Main, High, SHP, MHP | Main | Simple, Main, Advanced | Baseline | 0 | 0 | ✘ |
Levels | 5.2 | 5.2 | Main, High | High, 3 | Unified | Unified | Unified | |||
Max. resolution | 2160/60p | 2160/60p | 1080/60p | 3840×3840 | 16k×16k | 1080p | 4k/24p@15Mbit/s | |||
Encode | Profiles | Main | Main, High | Main | ✘ | Baseline | Unified | ✘ | ✘ | |
Levels | 5.2 | 5.2 | High | - | Unified | |||||
Max. resolution | 2160/60p | 2160/60p | 1080/60p | 16k×16k | - | |||||
Kaby Lake[101] Coffee Lake[102] Coffee Lake Refresh[102] Whiskey Lake[103] Ice Lake[104] Comet Lake[105] |
Decode | Profiles | Main, Main 10 | Main, High, MVC, Stereo | Main | Simple, Main, Advanced | Baseline | 0 | 0, 1, 2 | ✘ |
Levels | 5.2 | 5.2 | Main, High | Simple, High, 3 | Unified | Unified | Unified | |||
Max. resolution | 2160/60p | 1080/60p | 3840×3840 | 16k×16k | 1080p | |||||
Encode | Profiles | Main | Main, High | Main | ✘ | Baseline | Unified | Support 8 bits 4:2:0 BT.2020 may be obtained the pre/post processing | ✘ | |
Levels | 5.2 | 5.2 | High | - | Unified | |||||
Max. resolution | 2160/60p | 2160/60p | 1080/60p | 16k×16k | - | |||||
Tiger Lake[106] Rocket Lake |
Decode | Profiles | up to Main 4:4:4 12 | Main, High | Main | Simple, Main, Advanced | Baseline | ✘ | 0, 1, 2, partially 3 | 0 |
Levels | 6.2 | 5.2 | Main, High | Simple, High, 3 | Unified | Unified | 3 | |||
Max. resolution | 4320/60p | 2160/60p | 1080/60p | 3840×3840 | 16k×16k | 4320/60p | 4K×2K 16K×16K (still picture) | |||
Encode | Profiles | up to Main 4:4:4 10 | Main, High | Main | ✘ | Baseline | ✘ | 0, 1, 2, 3 | ✘ | |
Levels | 5.1 | 5.1 | High | - | - | |||||
Max. resolution | 4320p | 2160/60p | 1080/60p | 16k×16k | 4320p | |||||
Alder Lake[107] Raptor Lake[108] |
Decode | Profiles | up to Main 4:4:4 12 | Main, High | Main | Simple, Main, Advanced | Baseline | 0, 1, 2, 3 | 0 | |
Levels | 6.1 | 5.2 | Main, High | Simple, High, 3 | Unified | 6.1 | 3 | |||
Max. resolution | 4320/60p | 2160/60p | 1080/60p | 3840×3840 | 16k×16k | 4320/60p | 4320/60p 16K×16K (still picture) | |||
Encode | Profiles | up to Main 4:4:4 10 | Main, High | Main | Baseline | 0, 1, 2, 3 | ||||
Levels | 5.1 | 5.1 | High | - | - | |||||
Max. resolution | 4320p | 2160/60p | 1080/60p | 16k×16k | 4320p |
Intel Pentium and Celeron family
Intel Pentium & Celeron family | GPU video acceleration | ||||||||
---|---|---|---|---|---|---|---|---|---|
VED (Video Encode / Decode) | H.265/HEVC | H.264/MPEG-4 AVC | H.262 (MPEG-2) | VC-1/WMV9 | JPEG/MJPEG | VP8 | VP9 | ||
Braswell[109][lower-alpha 2][lower-alpha 3][lower-alpha 4] | Decode | Profile | Main | CBP, Main, High | Main, High | Advanced | 850 MP/s 4:2:0 640 MP/s 4:2:2 420 MP/s 4:4:4 | ||
Level | 5 | 5.2 | High | 4 | |||||
Max. resolution | 4k×2k/30p | 4k×2k/60p | 1080/60p | 1080/60p | 4k×2k/60p | 1080/30p | |||
Encode | Profile | ✘ | CBP, Main, High | Main, High | ✘ | 850 MP/s 4:2:0 640 MP/s 4:2:2 420 MP/s 4:4:4 | Up to 720p30 | ||
Level | 5.1 | High | |||||||
Max. resolution | 4k×2k/30p | 1080/30p | 4k×2k/30p | ||||||
Apollo Lake[110] | Decode | Profile | Main, Main 10 | CBP, Main, High | Main, High | Advanced | 1067 MP/s 4:2:0
800 MP/s 4:2:2 533 MP/s 4:4:4 |
0 | |
Level | 5.1 | 5.2 | High | 4 | |||||
Max. resolution | 1080p240, 4k×2k/60p | 1080/60p | 1080/60p | ||||||
Encode | Profile | Main | CBP, Main, High | ✘ | ✘ | 1067 MP/s 4:2:0
800 MP/s 4:2:2 533 MP/s 4:4:4 | |||
Level | 4 | 5.2 | |||||||
Max. resolution | 4kx2k/30p | 1080p240, 4k×2k/60p | 4k×2k/30p | 480p30 (SW only) | |||||
Gemini Lake[111] | Decode | Profile | Main, Main 10 | CBP, Main, High | Main, High | Advanced | 1067 MP/s 4:2:0
800 MP/s 4:2:2 533 MP/s 4:4:4 |
0, 2 | |
Level | 5.1 | 5.2 | High | 4 | |||||
Max. resolution | 1080p240, 4k×2k/60p | 1080/60p | 1080/60p | ||||||
Encode | Profile | Main | CBP, Main, High | Main, High | ✘ | 1067 MP/s 4:2:0
800 MP/s 4:2:2 533 MP/s 4:4:4 |
0 | ||
Level | 4 | 5.2 | High | ||||||
Max. resolution | 4kx2k/30p | 1080p240, 4k×2k/60p | 1080/60p | 4k×2k/30p |
Intel Atom family
Intel Atom family | GPU video acceleration | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
VED (Video Encode / Decode) | H.265/HEVC | H.264/MPEG-4 AVC | MPEG-4 Visual | H.263 | H.262 (MPEG-2) | VC-1/WMV9 | JPEG/MJPEG | VP8 | VP9 | ||
Bay Trail-T | Decode[112] | Profile | ✘ | Main, High | Main | 0 | ✘ | ||||
Level | 5.1 | High | |||||||||
Max. resolution | 4k×2k/30p | 1080/60p | 4k×2k/30p | 4k×2k/30p | |||||||
Encode[112] | Profile | Main, High | Main | - | - | ||||||
Level | 5.1 | High | - | - | |||||||
Max. resolution | 4k×2k/30p | 1080/60p | 1080/30p | - | 1080/30p | ||||||
Cherry Trail-T[113] | Decode | Profile | Main | CBP, Main, High | Simple | Main | Advanced | 1067 Mbit/s – 4:2:0
800 Mbit/s – 4:2:2 |
|||
Level | 5 | 5.2 | High | 4 | |||||||
Max. resolution | 4k×2k/30p | 4k×2k/60p, 1080@240p | 480/30p | 480/30p | 1080/60p | 1080/60p | 4k×2k/30p | 1080/30p | |||
Encode | Profile | ✘ | Constrained Baseline, Main, High (MVC) | 1067 Mbit/s – 4:2:0
800 Mbit/s – 4:2:2 |
✘ | ||||||
Level | 5.1 (4.2) | ||||||||||
Max. resolution | 4k×2k/30p, 1080@120p | 480/30p | 4k×2k/30p |
Documentation
Intel releases programming manuals for most of Intel HD Graphics devices via its Open Source Technology Center.[114] This allows various open source enthusiasts and hackers to contribute to driver development, and port drivers to various operating systems, without the need for reverse engineering.
See also
Notes
- The abbreviation "GT" appears in certain monitoring tools, such as Intel Power Gadget in reference to the graphics core on Intel processors.
- VP9 media codec GPU accelerator to be supported post TTM, for non-Windows operating systems only.
- Resolution details for media codec on open source Linux OS depends on platform features and drivers used. Decode/Encode features may not align to Table 8-4 that is specific to Win8.1 and Win7 operating systems.
- All capabilities dependent on OS. Here HW support is mentioned. For more info, see Table 8-4 on page 80 of PDF.
References
- "Supported APIs and Features for Intel Graphics Drivers". Intel. Retrieved 2016-05-19.
- Michael Larabel (18 October 2013). "OpenGL 3.3 Support Lands In Mesa! Possible Mesa 11.0". Phoronix.
- "The Khronos Group". The Khronos Group. July 18, 2020.
- "Experience Visual Perfection with Intel Graphics Technology". Intel. Retrieved 31 July 2018.
- "Intel Iris Pro 5200 Graphics Review: Core i7-4950HQ Tested". AnandTech. Retrieved 2014-01-12.
- "GPU market up—Intel and Nvidia graphics winners in Q4, AMD down". Jon Peddie Research. 2014-02-18. Retrieved 2014-05-14.
- "AMD Radeon HD 7310". Notebookcheck.net. 2013-01-17. Retrieved 2014-04-20.
- Junkins, Stephen (14 August 2015). The Compute Architecture of Intel Processor Graphics Gen9 (PDF) (White Paper). Intel. p. 2. Retrieved 9 September 2020.
At Intel, architects colloquially refer to Intel processor graphics architecture as simply 'Gen', shorthand for Generation.
- Intel OpenSource HD Graphics Programmer's Reference Manual (PRM) Volume 4 Part 3: Execution Unit ISA (Ivy Bridge) – For the 2012 Intel Core Processor Family (PDF) (Manual). Intel. May 2012. p. 29. Retrieved 9 September 2020.
The GEN instruction set is a general-purpose data-parallel instruction set optimized for graphics and media computations.
- Ioffe, Robert (22 January 2016). Introduction to GEN Assembly (Article). Intel. Retrieved 9 September 2020.
- Larabel, Michael (6 September 2019). "Intel Graphics Compiler Changes For Gen12 - Biggest Changes To The ISA Since i965". Phoronix. Retrieved 9 September 2020.
- Intel 965 Express Chipset Family and Intel G35 Express Chipset Graphics Controller PRM – Programmer's Reference Manual (PRM) Volume 1: Graphics Core (PDF) (Manual). Revision 1.0a. Intel. January 2008. p. 24. Retrieved 9 September 2020.
The GEN4 ISA describes the instructions supported by a GEN4 EU.
- J. F. Amprimoz (2009-02-22). "The Delayed Mobile Nehalems: Clarksfield, Arrandale, and the Calpella Platform". Bright Hub. Retrieved 2014-01-15.
- Shimpi, Anand Lal. "The Clarkdale Review: Intel's Core i5 661, i3 540 & i3 530". AnandTech.
- Pop, Sebastian (24 April 2012). "Intel's Official Ivy Bridge CPU Announcement Finally Live". Softpedia.
- Larabel, Michael (September 2, 2013). "Linux 3.12 Enables Haswell's Iris eLLC Cache Support". Phoronix. Retrieved October 25, 2013.
- Widawsky, Ben (July 16, 2013). "drm/i915: Use eLLC/LLC by default when available". git.kernel.org. Retrieved October 25, 2013.
- Wilson, Chris (August 22, 2013). "drm/i915: Use Write-Through cacheing for the display plane on Iris". git.kernel.org. Retrieved October 25, 2013.
- Shilov, Anton (November 20, 2013). "First Details Regarding Intel 'Broadwell-K' Microprocessors Emerge". Xbit. Archived from the original on January 12, 2014. Retrieved September 25, 2022.
- "Intel will announce Broadwell U 14nm cpu at CES 2014". chinese.vr-zone.com. Archived from the original on September 29, 2014. Retrieved June 12, 2014.
- Cutress, Ian (August 5, 2015). "Skylake's iGPU: Intel Gen9 – The Intel 6th Gen Skylake Review: Core i7-6700K and i5-6600K Tested". AnandTech. Retrieved August 6, 2015.
- Larabel, Michael (September 10, 2014). "Intel Publishes Initial Skylake Linux Graphics Support". Phoronix. Retrieved September 16, 2014.
- "Khronos Products: Conformant Products". Khronos. July 11, 2015. Retrieved August 8, 2015.
- Cutress, Ian (September 1, 2015). "Intel's Generation 9 Graphics – The Intel Skylake Mobile and Desktop Launch, with Architecture Analysis". AnandTech. Retrieved September 2, 2015.
- Cutress, Ian (May 31, 2016). "Intel Announces Xeon E3-1500 v5: Iris Pro and eDRAM for Streaming Video". AnandTech. Retrieved May 31, 2016.
- Shenoy, Navin (August 30, 2016). "New 7th Gen Intel Core Processor: Built for the Immersive Internet". Intel Newsroom. Retrieved August 4, 2018.
- Alcorn, Paul (August 30, 2016). "Intel Kaby Lake: 14nm+, Higher Clocks, New Media Engine". Tom's Hardware. Retrieved August 4, 2018.
- Cutress, Ian (August 21, 2017). "Intel Launches 8th Generation Core CPUs, Starting with Kaby Lake Refresh for 15W Mobile". AnandTech. Retrieved September 25, 2022.
- "Intel Product Specification Comparison". Intel. 7 October 2017. Archived from the original on 7 October 2017. Retrieved 27 May 2018.
- Shilov, Anton. "Intel Launches New Pentium Silver and Celeron Atom Processors: Gemini Lake is Here". AnandTech.
- Cutress, Ian (July 31, 2019). "Examining Intel's Ice Lake Processors: Taking a Bite of the Sunny Cove Microarchitecture". AnandTech. Retrieved August 1, 2019.
- "Intel Processor Graphics Gen11 Architecture" (PDF). Intel. Retrieved September 25, 2022.
- "Developer and Optimization Guide for Intel Processor Graphics Gen11..." Intel.
- Intel Graphics [@IntelGraphics] (August 31, 2019). "Our community suggested it and we are making it a reality. Retro scaling is now available in the new Intel Graphics Command Center (in beta for Gen11 Graphics). Let us know what you think!" (Tweet). Retrieved July 1, 2021 – via Twitter.
- "Intel Iris Plus Graphics and UHD Graphics Open Source Programmer's Reference Manual" (PDF). Intel. 2020.
- "Intel Gen11 Architecture, Page 10" (PDF). Intel. Retrieved November 2, 2020.
- "Intel® Processor Graphics Xᵉ-LP API Developer and Optimization Guide".
- Smith, Ryan (August 13, 2020). "The Intel Xe-LP GPU Architecture Deep Dive: Building Up The Next Generation". AnandTech. Retrieved April 10, 2021.
- Cutress, Ian (12 December 2018). "Intel's Architecture Day 2018: The Future of Core, Intel GPUs, 10nm, and Hybrid x86". AnandTech. p. 5.
Intel will use the Xe branding for its range of graphics that were unofficially called 'Gen12' in previous discussions
- Hill, Brandon (September 9, 2019). "Intel Says Tiger Lake Gen12 Xe Graphics Is Its Biggest Architectural Revamp In A Decade". Hot Hardware. Retrieved October 5, 2022.
- "Intel Processor Graphics Xe-LP API Developer and Optimization Guide". Intel. June 22, 2021. Retrieved October 5, 2022.
- Kucukgoz, Mehmet (October 9, 2020). "AV1 Hardware Accelerated Video on Windows 10". Microsoft. Retrieved October 5, 2022.
- "Intel Technology Roadmaps and Milestones". Intel.
- "Intel Meteor Lake Client Processors to use Arc Graphics Chiplets".
- "[Intel-gfx] [PATCH 0/2] i915: Introduce Meteorlake". Lists.freedesktop.org. 7 July 2022. Retrieved 2022-09-01.
- Nautiyal, Ankit (November 7, 2022). "[Intel-gfx] [RFC 00/15] Add support for HDMI2.1 FRL". Free Desktop. Retrieved November 15, 2022.
- Knupffer, Nick. "Intel Insider – What Is It? (IS it DRM? And yes it delivers top quality movies to your PC)". Archived from the original on 2013-06-22. Retrieved 2011-02-02.
- Agam Shah (2011-01-06). "Intel: Sandy Bridge's Insider is not DRM". Computerworld. Retrieved 2014-03-22.
- Sunil Jain (May 2014). "Intel Graphics Virtualization Update". Intel. Archived from the original on 2014-05-08. Retrieved 2014-05-11.
- "Bringing New Use Cases and Workloads to the Cloud with Intel Graphics Virtualization Technology (Intel GVT-g)" (PDF). Intel Open Source Technology Center. 2016. Retrieved 14 August 2020.
- "Graphics Virtualization Technologies Supported on Each Intel®". Archived from the original on 2022-08-14. Retrieved 2022-08-14.
- "Do 11th Generation Intel® Processors Support GVT-g Technology?".
- Michael Larabel (2011-10-06). "Details On Intel Ivy Bridge Triple Monitor Support". Phoronix.
A limitation of this triple monitor support for Ivy Bridge is that two of the pipes need to share a PLL. Ivy Bridge has three planes, three pipes, three transcoders, and three FDI (Flexible Display Interface) interfaces for this triple monitor support, but there's only two pipe PLLs. This means that two of the three outputs need to have the same connection type and same timings. However, most people in a triple monitor environment will have at least two — if not all three — of the monitors be identical and configured the same, so this shouldn't be a terribly huge issue.
- LG Nilsson (2012-03-12). "Most desktop Ivy Bridge systems won't support three displays". VRZone. Archived from the original on 2012-04-01.
Despite the fact that Intel has been banging its drums about support for up to three displays on the upcoming 7-series motherboards in combination with a shiny new Ivy Bridge based CPU, this isn't likely to be the case. The simple reason behind this is that very few, if any motherboards will sport a pair of DisplayPort connectors.
- David Galus (February 2013). "Migration to New Display Technologies on Intel Embedded Platforms" (PDF). Intel. Archived from the original (PDF) on 2013-02-01.
The Intel 7 Series Chipset based platform allows for the support of up to three concurrent displays with independent or replicated content. However, this comes with the requirement that either one of the displays is eDP running off the CPU or two DP interfaces are being used off the PCH. When configuring the 2 DP interfaces from the PCH, one may be an eDP if using Port D. This limitation exists because the 7 Series Intel PCH contains only two display PLLs (the CPU has one display PLL also) which will control the clocking for the respective displays. All display types other than DP have an external variable clock frequency associated with the display resolution that is being used. The DP interface has an embedded clocking scheme that is semi- variable, either at 162 or 270 MHz depending on the bandwidth required. Therefore, Intel only allows sharing of a display PLL with DP related interfaces.
Alt URL - "Z87E-ITX". ASRock.
This motherboard supports Triple Monitor. You may choose up to three display interfaces to connect monitors and use them simultaneously.
- "H87I-PLUS". Asus.
Connect up to three independent monitors at once using video outputs such as DisplayPort, Mini DisplayPort, HDMI, DVI, or VGA. Choose your outputs and set displays to either mirror mode or collage mode.
- "Techpowerup GPU database". Techpowerup. Retrieved 2018-04-22.
- "2nd Generation Intel Core : Datasheet, Volume 1" (PDF). Intel.com. Retrieved 27 May 2018.
- Michael Larabel (2014-09-20). "OpenGL 3.3 / GLSL 3.30 Lands For Intel Sandy Bridge On Mesa". Phoronix.
- "Desktop 3rd Gen Intel Core Processor Family: Datasheet". Intel. Retrieved 2015-06-18.
- "Intel Pentium Processor N3500-series, J2850, J2900, and Intel Celeron Processor N2900-series, N2800-series, J1800-series, J1900, J1750 – Datasheet" (PDF). Intel. 2014-11-01. p. 19. Retrieved 2016-02-08.
- Francisco Jerez (14 April 2017). "mark GL_ARB_vertex_attrib_64bit and OpenGL 4.2 as supported by i965/gen7+". freedesktop.org.
- "Release Notes Driver version: 15.33.22.64.3621" (PDF). 2014-06-02. Retrieved 2014-07-21.
- "Archived copy" (PDF). Archived from the original (PDF) on 2015-04-02. Retrieved 2015-03-07.
{{cite web}}
: CS1 maint: archived copy as title (link) - "Intel HD Graphics (Bay Trail)". notebookcheck.net. Retrieved 2016-01-26.
- "Desktop 4th Generation Intel Core: Datasheet" (PDF). Intel. Retrieved 27 May 2018.
- Michael Larabel (15 June 2021). "Mesa's New "Crocus" OpenGL Driver Is Performing Well For Old Intel Hardware". Phoronix. Retrieved 2023-07-03.
Crocus does allow for OpenGL 4.6 on Haswell compared to OpenGL 4.5 being exposed on the i965 driver. Additionally, Crocus allows for OpenGL ES 3.2 rather than OpenGL ES 3.1 on Haswell. Aside from that the drivers are in similar shape for the most part.
- "Release Notes Driver version: 15.36.3.64.3907" (PDF). 2014-09-07. Retrieved 2014-09-05.
- "Intel Graphics Driver PV 15.40.36.4703 Release Notes" (PDF). Intel. June 23, 2017. Archived from the original (PDF) on October 3, 2017. Retrieved October 2, 2017.
- "5th Generation Intel Core Processor Family, Intel Core M Processor Family, Mobile Intel Pentium Processor Family, and Mobile Intel Celeron Processor Family Datasheet – Volume 1 of 2" (PDF). Intel. 2015-06-01. p. 22. Retrieved 2016-02-11.
- "Intel Iris Pro Graphics 6200". notebookcheck.net. Retrieved 2016-02-09.
- "Intel Iris Graphics 6100". notebookcheck.net. Retrieved 2016-02-09.
- "Intel HD Graphics 6000". notebookcheck.net. Retrieved 2016-02-09.
- "Intel HD Graphics 5600". Notebookcheck. Retrieved 2016-02-09.
- "Intel HD Graphics 5500". notebookcheck.net. Retrieved 2016-02-09.
- "Intel HD Graphics 5300". notebookcheck.net. Retrieved 2016-02-09.
- "Intel HD Graphics (Broadwell)". notebookcheck.net. Retrieved 2016-02-09.
- Michael Larabel (21 August 2019). "Intel's OpenGL Linux Driver Now Has OpenGL 4.6 Support For Mesa 19.2". Phoronix.
- Michael Larabel (9 March 2019). "Intel's New Driver Is Now Working With Gallium's Direct3D 9 State Tracker". Phoronix.
- Intel. "Intel compute-runtime, Supported Platforms". GitHub. Retrieved 16 April 2021.
- "Intel HD Graphics (Braswell)". notebookcheck.net. Retrieved 2016-01-26.
- "Khronos Vulkan Conformant Products".
- "Khronos Vulkan Conformant Products".
- "Driver Version: 31.0.101.2114". Intel. Retrieved October 20, 2022.
- Michael Larabel (20 January 2017). "Beignet 1.3 Released With OpenCL 2.0 Support". Phoronix.
- Michael Larabel (27 October 2015). "Intel Is Already Publishing Open-Source 'Kabylake' Graphics Driver Patches". Phoronix.
- "Driver Version: 31.0.101.3729". Intel. Retrieved October 20, 2022.
- "OpenCL - The open standard for parallel programming of heterogeneous systems". 21 July 2013.
- "iris: Add a new experimental Gallium driver for Intel Gen8+ GPUs (!283) · Merge Requests · Mesa / mesa". GitLab. 20 February 2019. Retrieved 2023-07-03.
- "initial crocus driver submission (!11146) · Merge Requests · Mesa / mesa". GitLab. 2 June 2021. Retrieved 2023-07-03.
- Michael Larabel (3 December 2021). "Mesa's Classic Drivers Have Been Retired - Affecting ATI R100/R200 & More". Phoronix. Retrieved 2023-07-03.
- https://github.com/intel/compute-runtime/releases?page=1
- Wang, Hongbo (18 October 2018). "2018-Q3 release of KVMGT (Intel GVT-g for KVM)" (Press release). Intel Open Source Technology Center. Archived from the original on 16 January 2021. Retrieved 14 August 2020.
- Wang, Hongbo (18 October 2018). "2018-Q3 release of XenGT (Intel GVT-g for Xen)" (Press release). Intel Open Source Technology Center. Archived from the original on 16 January 2021. Retrieved 14 August 2020.
- "Intel Core i5-600, i3-500 Desktop Processor Series, Intel Pentium Desktop Processor 6000 Series" (PDF) (PDF). Intel. January 2011. Retrieved 11 May 2017.
- Robert_U (19 January 2015). "Intel Iris and HD Graphics Driver update posted for Haswell and Broadwell version 15.36.14.4080". Intel Communities. Intel. Retrieved 16 April 2016.
- "5th Generation Intel Core Processor Family Datasheet Vol. 1" (PDF) (PDF). Intel. 1 June 2015. Retrieved 16 April 2016.
- "Desktop 5th Gen Intel Core Processor Family Datasheet, Vol. 1" (PDF) (PDF). Intel. 27 May 2015. Retrieved 16 April 2016.
- "6th Generation Intel Processor Datasheet" (PDF). Intel. October 2015. Retrieved 12 February 2016.
- "Datasheet, Vol. 1: 7th Gen Intel Core Processor U/Y-Platforms" (PDF). Intel. August 2016. Retrieved 2020-01-24.
- "8th and 9th Generation Intel Core Processor Families Datasheet, Volume 1 of 2". Intel. Retrieved 2020-01-24.
- "8th Gen Intel Core Processor Family Datasheet, Vol. 1". Intel. Retrieved 2020-07-19.
- "10th Gen Intel Core Processor Families Datasheet, Vol. 1". Intel (in Spanish). Retrieved 2020-07-19.
- "10th Gen Intel Core Processor Families Datasheet, Vol. 1". Intel. Retrieved 2020-07-19.
- "11th Generation Intel Core ProcessorDatasheet, Volume 1 of 2 Supporting 11th Generation Intel Core Processor Families, IntelPentium Processors, Intel Celeron Processors for UP3, UP4, and H35 Platform, formerly known as Tiger Lake". January 2021. Retrieved 2021-03-17.
- "12th Generation Intel Core Processors". March 2022. Retrieved 2022-03-27.
- "Hardware Accelerated Video Decode - 002 - ID:743844 | 13th Generation Intel® Core™ Processors". edc.intel.com. Retrieved 2022-12-24.
- "N-series Intel Pentium Processors and Intel Celeron Processors Datasheet – Volume 1 of 3" (PDF). Intel. 2015-04-01. pp. 77–79. Retrieved 2016-02-08.
- "Intel Pentium and Celeron Processor N- and J- Series" (PDF). Intel. Retrieved 2017-06-03.
- "2017Q2 Intel Graphics Stack Recipe". 01.org. 2017-07-06. Archived from the original on 2018-02-25. Retrieved 2017-08-14.
- "Intel Atom Processor Z3600 and Z3700 Series Datasheet" (PDF). Intel. December 2014. Retrieved 12 February 2016.
- "Intel Atom Z8000 Processor Series Datasheet (Volume 1 of 2)" (PDF). Intel. 2016-03-01. p. 130. Retrieved 2016-04-24.
- "Linux Graphics, Documentation". Intel Open Source Technology Center. 01.org. 2014-01-12. Retrieved 2014-01-12.