Vivante Corporation
Vivante Corporation is a fabless semiconductor company headquartered in Sunnyvale, California, with an R&D center in Shanghai, China. The company was founded in 2004 as GiQuila and focused on the portable gaming market. The company's first product was a DirectX-compatible graphics processing unit (GPU) capable of playing PC games. In 2007, GiQuila changed its name to Vivante and changed the direction of the company to focus on the design and licensing of embedded graphics processing unit designs. The company is licensing its Mobile Visual Reality to semiconductor solution providers that serve embedded computing markets for mobile gaming, high-definition home entertainment, image processing, and automotive display and entertainment.
Founded | 2004 |
---|---|
Headquarters | , |
Products | Semiconductor intellectual property |
Website | www |
Vivante is named as a contributor to the HSA (Heterogeneous System Architecture) Foundation.[1]
In 2015, VeriSilicon Holdings Co., Ltd. acquired Vivante Corporation in All-Stock Transaction.[2]
Products
Since changing directions Vivante has developed a range of GPU cores that are compliant with the OpenGL ES 1.1 and 2.0 standards as well as the OpenVG standard. Created by VeriSilicon support for the Vulkan API 1.0 and for OpenVX 1.0 is provided for at least 6 major desktop and embedded operating systems.[3]
2D graphics products & Vector GPUs, summarized by the vendor under the term "Composition Processing Cores" (CPC),[4] sometimes mentioned with the feature of single pass composition blending capability of 8 or higher, are the GC300,[5] GC320, GC350[6] and GP355 (OpenVG core[7])with the additional listing of GC200 and GC420.[8] NXP further mentions GC255 in a presentation for their i.MX models.[9] The NXP i.MX8 series will come with 2 units of the GC7000Lite or GC7000 vector processor.[10] For 3D graphics products please see the table below.
Legend for the notes in below listing:
- Pipelined FP/INT double (64-bit), single/high (32-bit) and half precision/medium (16-bit) precision IEEE formats for GPU Compute and HDR graphics, Source:[11]
Series | Model | Date | Shader Cores SP/Half (mode) |
Silicon area (mm2) | Core Clock Max in MHz |
Shader Clock Max in MHz |
Fillrate | Bus width (bit) |
API (version) | Shader GFLOPS (High=SP / Medium=Half) |
Usage | |||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
M triangles/s | G vertices/s | (GP/s) | (GT/s) | OpenGL ES | OpenVG | OpenCL | OpenGL | Direct3D | ||||||||||
GCNano | GCNano Lite | 1 (VEC-4) | 0.3 @ 28 nm | 100–200
@ 28HPM |
100–200
@ 28HPM |
40 | 0.1 | 0.2 | N/A | 1.1 | N/A | N/A | N/A | 3.2? | ||||
GCNano | 1 (VEC-4) | 0.5 @ 28 nm | 200 @ 28HPM | 200 @ 28HPM | 40 | 0.1 | 0.2 | 2.0 | 3.2[12] | |||||||||
GCNano Ultra (Vega-Lite) | GCNano Ultra | 1 (VEC-4) | 1 @ 28 nm | 400 @ 28HPM | 800 @ 28HPM | 80 | 0.2 | 0.4 | 1.2
optional |
6.4 | NXP i.MX8M Mini | |||||||
GCNano Ultra3 | 1 (VEC-4) | 1.6 @ 28 nm | 400 @ 28HPM | 800 @ 28HPM | 80 | 0.2 | 0.4? | 3.0 | 6.4? | |||||||||
GC200 | GC200 | 0.57 @ 65 nm[13] | 250 @ 65nmLP 375 @ 65nmG+ | 0.375 | 32/16 | N/A | N/A | N/A | N/A | Jz4760[14] | ||||||||
GC400 | GC400 | 1 (VEC-4) 4 (VEC-1) |
1.4 2 @ 65 nm[15] | 250 @ 65nmLP 375 @ 65nmG+ | 19 | 0.094 | 0.188 | 32/16 | 2.0[16] | 1.1 EP[16] | N/A | 11 | 3[16] | NXP i.MX6 SoloX: GC400T | ||||
GC500[17] | 32/16 | PXA920: GC530 | ||||||||||||||||
GC600 | GC600 | 1 (VEC-4) 4 (VEC-1) |
32/16 | 1.2/1.1 | 3.0/2.1 | 11 | CuBox | |||||||||||
GC800 | GC800 | 1 (VEC-4) 4 (VEC-1) |
2.5 3.38 @ 65 nm[18] | 800 @ 28HPM 250 @ 65nmLP 375 @ 65nmG+ | 1000 @ 28HPM | 38 @ 65nmG+ | 0.188 @ 65nmG+ | 0.375 @ 65nmG+ | 32/16 | 3.0[19] | 1.2
optional |
3.0/2.1 | 11 | 8 / 16[20] | RK291x, ATM7013, ATM7019 | |||
GC860 | 1 (VEC-4) 4 (VEC-1) |
32/16 | 3.0/2.1 | 11 | Jz4770: GCW Zero NOVO7 | |||||||||||||
GC880 | 1 (VEC-4) 4 (VEC-1) |
35 | 0.1 | 0.266 | 32/16 | 3.0/2.1 | 11 | 3.2[21] | NXP i.MX6 Solo and DualLite | |||||||||
GCx000 | GC1000 (Vega-Lite) | 2 (VEC-4) 8 (VEC-1) |
3.5 4.26 @ 65 nm[22] | 800 @ 28HPM 500 @ 65nmLP 750 @ 65nmG+ | 1000 @ 28HPM | 123 58 @ 65nmG+ | 0.5 0.375 @ 65nmG+ | 0.8 0.75 @ 65nmG+ | 32/16 | 3.0/2.1 | 11 | 16 | ATM7029: GC1000+, Marvell PXA986,[23] PXA988, PXA1088[14] | |||||
GC2000 | 4 (VEC-4) 16 (VEC-1) |
6.9 | 800 @ 28HPM | 1000 @ 28HPM | 267 | 1 | 1.6 | 32/16 | 1.2 | 3.0/2.1 | 11 | 32 | NXP i.MX6 Dual and Quad | |||||
GC4000 | 8 (VEC-4) 32 (VEC-1) |
12.4[8] | 800 @ 28HPM | 1000 @ 28HPM | 267 | 2 | 1.6 | 8 | 3.0/2.1 | 11 | 64 | HiSilicon K3V2 | ||||||
Vega xX | GC3000 (Vega 1X) | 4/8 (VEC-4) 16/32 (VEC-1) |
800 @ 28HPM | 1000 @ 28HPM | 267 | 1 | 1.6 | 8/4 | 3.0/2.1 | 11 | 32 / 64[24] | NXP S32V234[25] | ||||||
GC5000 (Vega 2X) | 8/16 (VEC-4) 32/64 (VEC-1) |
800 @ 28HPM | 1000 @ 28HPM | 267 | 1 | 1.6 | 32/16 | 3.0/2.1 | 11 | 64 / 128 | Marvell PXA1928[26] | |||||||
GC6000 (Vega 4X) GC6400? | 16/32 (VEC-4) 64/128 (VEC-1) |
800 @ 28HPM | 1000 @ 28HPM | 533 | 4 | 3.2 | 32/16 | 3.0/2.1 | 11 | 128 / 256 | ||||||||
GC7000 (Vega 8X) [27] | GC7000 UltraLite GC1500?[28] | 8 Vega | 0.5 | 0.8 | 32/16 | 3.0/2.1 | 11 | 16 / 32 | Marvell PXA1908[29]NXP i.MX8M Nano[30] | |||||||||
GC7000 Lite GC7000L? | 16 Vega | 1 | 1.6 | 32/16 | 3.0/2.1 | 11 | 32 / 64 | Marvel PXA1936[28] NXP i.MX 8QuadPlus NXP i.MX 8Quad | ||||||||||
GC7000 | 32 Vega | 800 @ 28HPM | 1000 @ 28HPM | 1067 | 2 | 6.4 | 3.2 | 32/16 | 3.0/2.1 | 11 | 64 / 128 | NXP i.MX 8QuadMax | ||||||
GC7200 | 64 Vega | 4 | 6.4 | 32/16 | 3.0/2.1 | 11 | 128 / 256 | |||||||||||
GC7400 | 128 Vega | 8 | 12.8 | 32/16 | 3.0/2.1 | 11 | 256 / 512 | |||||||||||
GC7600 | 256 Vega | 16 | 25.6 | 32/16 | 3.0/2.1 | 11 | 512 / 1024 | |||||||||||
GC8000 | GC8000 | |||||||||||||||||
Series | Model | Date | Shader Cores SP/Half (mode) |
Silicon area (mm2) | Core Clock Max in MHz |
Shader Clock Max in MHz |
Fillrate | Bus width (bit) |
API (version) | Shader GFLOPS (High=SP / Medium=Half) |
Usage | |||||||
M triangles/s | G vertices/s | (GP/s) | (GT/s) | OpenGL ES | OpenVG | OpenCL | OpenGL | Direct3D |
Adoption
They have announced that as of 2009 they have at least fifteen licensees who have used their GPUs in twenty embedded designs.[31] Application processors using Vivante GPU technology:
- Marvell ARMADA range of SoCs[32]
- Freescale i.MX6 Series[33]
- Ingenic Semiconductor Jz4770[34]
- ICT Godson-2H[35][36]
- Rockchip RK2918
- Actions Semiconductor ATM7029
- HiSilicon K3V2
- InfoTM iMAP×210[37]
GC8000 Series
After Vivante was sold to Verisilicon the Arcturus GC8000 series was released by Verisilicon, which supports newer technologies such as OpenCL 2.0, OpenVX 1.1, OpenVG 1.1, OpenGL ES 3.2, OpenGL 4.0 and Vulkan 1.0.[38]
Linux support
There are no plans on writing a new DRM/KMS driver kernel driver for the Vivante hardware, since Vivante previously put out their Linux kernel component under the GNU General Public License (GPL), instead of maintaining it as a proprietary blob. The free Gallium3D-style device driver etna_viv
has surpassed Vivante's own proprietary user-space driver in some benchmarks. It supports Vivante's product line of GC400 Series, GC800 Series, GC1000 Series, GC2000 Series, GC3000 Series, GC4000 Series, and GC7000lite.[39]
See also
- PowerVR – available as SIP block to 3rd parties
- Mali – available as SIP block to 3rd parties
- Adreno – found only on Qualcomm Snapdragon, could be available as SIP block to 3rd parties
- Tegra – family of SoCs for mobile computers, the graphics core could be available as SIP block to 3rd parties
- Atom family of SoCs – with Intel graphics core, not licensed to 3rd parties
- AMD mobile APUs – with AMD graphics core, not licensed to 3rd parties
References
- http://hsafoundation.com/ HSA (Heterogeneous System Architecture) Foundation
- "VeriSilicon to Acquire Vivante Corporation in All-Stock Transaction". Vivante Corporation. October 12, 2015. Archived from the original on October 14, 2015. Retrieved October 14, 2015.
- VeriSilicon: Embedded Vivante Dedicated Vision IP
- "Composition Processing Cores (CPC)".
- "Vivante GC300 - ChipEstimate.com IP Catalog". www.chipestimate.com.
- "Vivante GC350 - ChipEstimate.com IP Catalog". www.chipestimate.com.
- "Recording Not Found". cc.readytalk.com.
- cnxsoft (January 19, 2013). "GPUs Comparison: ARM Mali vs Vivante GCxxx vs PowerVR SGX vs Nvidia Geforce ULP".
- 2D and 3D Graphics in Freescale Devices
- "i.MX8 Factsheet" (PDF). NXP. NXP. Retrieved October 6, 2016.
- ""Vivante Vega 3D Technology", section "Unified Shader Architecture"".
- "Vivante GPU « GPU Talk".
- "Vivante GC200 - ChipEstimate.com IP Catalog". www.chipestimate.com.
- Mobile GPU (Vivante Graphics ...)
- "Vivante GC400 - ChipEstimate.com IP Catalog". www.chipestimate.com.
- Vivante Product Brief
- "Company Profile for Vivante Corporation". www.businesswire.com. August 1, 2008.
- "Vivante GC800 - ChipEstimate.com IP Catalog". www.chipestimate.com.
- "Vivante shipping GPU cores designed to support the latest OpenGL ES 3.0 specification". Retrieved September 13, 2014.
- "Vivante GPU (Freescale i.MX6)".
- "i.MX6SDL GC880 performance. - NXP Community". community.nxp.com.
- "Vivante GC1000 - ChipEstimate.com IP Catalog". www.chipestimate.com.
- "Archived copy". Archived from the original on September 25, 2013. Retrieved September 25, 2013.CS1 maint: archived copy as title (link)
- "GPGPU - Vivante Corporation". www.vivantecorp.com.
- "S32V234 Vision and Sensor Fusion Processor Family-NXP". www.nxp.com.
- cnxsoft (February 26, 2014). "Marvell ARMADA Mobile PXA1928 SoC Features Four Cortex A53 Cores, Vivante GC5000 GPU, and LTE".
- cnxsoft (April 19, 2014). "Vivante Unveils Details About GC7000 Series GPU IP Family".
- "The Linley Group - Marvell Extends LTE Lineup". www.linleygroup.com.
- "GFXBench - Unified cross-platform 3D graphics benchmark database". The cross-platform performance site.
- Inc, NXP USA (February 26, 2019). "NXP Accelerates Edge Computing Revolution". GlobeNewswire News Room. Retrieved September 6, 2019.
- "Vivante Corporation Signs 15th GPU Licensee" (Press release). June 8, 2009. Retrieved July 8, 2009.
- "Vivante GPUs Power Marvell ARMADA Application Processors" (Press release). October 27, 2009. Retrieved February 1, 2010.
- "Vivante GPU IP Cores Power the Latest Freescale i.MX 6 Series of Application Processors" (Press release). April 26, 2011. Retrieved July 31, 2011.
- "Vivante GPU Core Brings Android 3.0 Honeycomb Support to Ingenic's Latest JZ4770 Application Processor" (Press release). June 13, 2011. Archived from the original on January 19, 2013. Retrieved December 13, 2011.
- "Chinese Academy of Sciences Selects Vivante as GPU Partner for Netbooks" (Press release). June 29, 2009. Retrieved December 13, 2011.
- "Guess what is ready for tape out: It has a MIPS core and a GPU from Vivante". April 28, 2011. Retrieved December 13, 2011.
- "盈方微电子股份有限公司". InfoTM. Retrieved October 6, 2015.
- "Verisilicon Arcturus GC8000 series".
- "etna_pipe is currently compatible with at least the following GC chips".