Mali

ARM Cortex A57 A53 big.LITTLE SoC with a Mali-T624 GPU
Release date	2005
Architecture	Utgard Midgard Bifrost Valhall
Models	SeeVariants
Cores	1 to 32 cores
Fabrication process	4 to 40nm
API support
Direct3D	9 to 12
OpenCL	1.1 to 3.0
OpenGL	2.0 to 3.0
Vulkan	1.0 to 1.3

TheMali and Immortalis series ofgraphics processing units (GPUs) and multimedia processors aresemiconductor intellectual property cores produced byArm Holdings for licensing in variousASIC designs by Arm partners.

Mali GPUs were developed byFalanx Microsystems A/S, which was aspin-off of a research project from theNorwegian University of Science and Technology.^[1]Arm Holdings acquired Falanx Microsystems A/S on June 23, 2006 and renamed the company toArm Norway.^[2]

It was originally namedMalaik, but the team shortened the name toMali,Serbo-Croatianfor "small", which was thought to be fitting for a mobile GPU.^[3]

On June 28, 2022, Arm announced their Immortalis series of GPUs with hardware-based Ray Tracing support.^[4]

In 2005, Falanx announced their Utgard GPU Architecture, the Mali-200 GPU.^[5] Arm followed up with the Mali-300, Mali-400, Mali-450, and Mali-470. Utgard was a non-unified GPU (discrete pixel and vertex shaders).^[1]

On November 10, 2010, Arm announced their Midgard 1st gen GPU Architecture, including the Mali-T604 and later the Mali-T658 GPU in 2011.^{[9][10][11][12]} Midgard uses a Hierarchical Tiling system.^[1]

On August 6, 2012, Arm announced their Midgard 2nd gen GPU Architecture, including the Mali-T678 GPU.^[13] Midgard 2nd gen introduced Forward Pixel Kill.^[1][14]

On October 29, 2013, Arm announced their Midgard 3rd gen GPU Architecture, including the Mali-T760 GPU.^{[15][1][16][17][18]}

On October 27, 2014, Arm announced their Midgard 4th gen GPU Architecture, including the Mali-T860, Mali-T830, Mali-T820. Their flagship Mali-T880 GPU was announced on February 3, 2015. New microarchitectural features include:^[19]

• Up to 16 cores for the Mali-T880, with 256KB – 2MB L2 cache

On May 27, 2016, Arm announced their Bifrost GPU Architecture, including the Mali-G71 GPU. New microarchitectural features include:^[20][21]

• Unified shaders with quad vectorization
• Scalar ISA
• Clauses execution
• Full cache coherency
• Up to 32 cores for the Mali-G71, with 128KB – 2MB L2 cache
• Arm claims the Mali-G71 has 40% more performance density and 20% better energy efficiency than the Mali-T880

On May 29, 2017, Arm announced their Bifrost 2nd gen GPU Architecture, including the Mali-G72 GPU. New microarchitectural features include:^[22][23]

• Arithmetic optimizations and increased caches
• Up to 32 cores for the Mali-G72, with 128KB – 2MB L2 cache
• Arm claims the Mali-G72 has 20% more performance density and 25% better energy efficiency than the Mali-G71

On May 31, 2018, Arm announced their Bifrost 3rd gen GPU Architecture, including the Mali-G76 GPU. New microarchitectural features include:^[24][25]

• 8 execution lanes per engine (up from 4). Doubled pixel and texel throughput
• Up to 20 cores for the Mali-G76, with 512KB – 4MB L2 cache
• Arm claims the Mali-G76 has 30% more performance density and 30% better energy efficiency than the Mali-G72

On May 27, 2019, Arm announced their Valhall GPU Architecture, including the Mali-G77 GPU, and in October Mali-G57 GPUs. New microarchitectural features include:^[26][27][28]

• New superscalar engine
• Simplified scalar ISA
• New dynamic scheduling
• Up to 16 cores for the Mali-G77, with 512KB – 2MB L2 cache
• Arm claims the Mali-G77 has 30% more performance density and 30% better energy efficiency than the Mali-G76

On May 26, 2020, Arm announced their Valhall 2nd Gen GPU Architecture, including the Mali-G78. New microarchitectural features include:^[29][30][31]

• Asynchronous clock domains
• New FMA units and increase Tiler throughput
• Up to 24 cores for the Mali-G78, with 512KB – 2MB L2 cache
• Arm Frame Buffer Compression (AFBC)
• Arm claims the Mali-G78 has 15% more performance density and 10% better energy efficiency than the Mali-G77

On May 25, 2021, Arm announced their Valhall 3rd Gen GPU Architecture (as part of TCS21), including the Mali-G710, Mali-G510, and Mali-G310 GPUs. New microarchitectural features include:^[32][33][34]

• Larger shader cores (2x compared to Valhall 2nd Gen)
• New GPU frontend, Command Stream Frontend (CSF) replaces the Job Manager
• Up to 16 cores for the Mali-G710, with 512KB – 2MB L2 cache
• Arm claims the Mali-G710 has 20% more performance density and 20% better energy efficiency than the Mali-G78

On June 28, 2022, Arm announced their Valhall 4th Gen GPU Architecture (as part of TCS22), including the Immortalis-G715, Mali-G715, and Mali-G615 GPUs. New microarchitectural features include:^[4][35]

• Ray Tracing support (hardware-based)
• Variable Rate Shading^[36]
• New Execution Engine, with doubled the FMA block, Matrix Multiply instruction support, and PPA improvements
• Arm Fixed Rate Compression (AFRC)
• Arm claims the Immortalis-G715 has 15% more performance & 15% better energy efficiency than the Mali-G710^[37]

On May 29, 2023, Arm announced their 5th Gen Arm GPU Architecture (as part of TCS23), including the Immortalis-G720, Mali-G720 and Mali-G620 GPUs.^[38][39][40] New microarchitectural features include:^[41]

• Deferred vertex shading (DVS) pipeline
• Arm claims the Immortalis-G720 has 15% more performance and uses up to 40% less memory bandwidth than the Immortalis-G715

Like other embedded IP cores for 3D renderingacceleration, the Mali GPU does not includedisplay controllers driving monitors, in contrast to common desktopvideo cards. Instead, the Mali ARM core is a pure 3D engine that renders graphics into memory and passes the rendered image over to another core to handle display.

ARM does, however, license display controllerSIP cores independently of the Mali 3D accelerator SIP block, e.g. Mali DP500, DP550 and DP650.^[42]

ARM also supplies tools to help in authoringOpenGL ESshaders namedMali GPU Shader Development Studio andMali GPU User Interface Engine.

Display controllers such as the ARM HDLCD display controller are available separately.^[43]

The Mali core grew out of the cores previously produced by Falanx and currently constitute:^[44]

Some microarchitectures (or just some chips?) supportcache coherency for the L2 cache with the CPU.^[61][62]

Adaptive Scalable Texture Compression (ASTC) is supported by Mali-T620, T720/T760, T820/T830/T860/T880^[63] and Mali-G series.

The Mali GPU variants can be found in the followingsystems on chips (SoCs):

Mali Video is the name given toARM Holdings' dedicatedvideo decoding andvideo encodingASIC. There are multiple versions implementing a number ofvideo codecs, such asHEVC,VP9,H.264 andVP8. As with all ARM products, the Mali video processor is asemiconductor intellectual property core licensed to third parties for inclusion in their chips. Real time encode-decode capability is central tovideotelephony. An interface to ARM'sTrustZone technology is also built-in to enabledigital rights management ofcopyrighted material.

The first version of a Mali Video processor was the V500, released in 2013 with the Mali-T622 GPU.^[118] The V500 is a multicore design, sporting 1–8 cores, with support for H.264 and a protected video path usingARM TrustZone. The 8 core version is sufficient for4K video decode at 120 frames per second (fps). The V500 can encode VP8 and H.264, and decode H.264, H.263, MPEG4, MPEG2, VC-1/WMV, Real, VP8.

Released with the Mali-T800 GPU, ARM V550 video processors added both encode and decode HEVC support, 10-bit color depth, and technologies to further reduced power consumption.^[119] The V550 also included technology improvements to better handle latency and save bandwidth.^[120] Again built around the idea of a scalable number of cores (1–8) the V550 could support between 1080p60 (1 core) to 4K120 (8 cores). The V550 supported HEVC Main, H.264, VP8, JPEG encode, and HEVC Main 10, HEVC Main, H.264, H.263, MPEG4, MPEG2, VC-1/WMV, Real, VP8, JPEG decode.

The Mali V61 video processor (formerly named Egil) was released with the Mali Bifrost GPU in 2016.^[121][122] V61 has been designed to improve video encoding, in particular HEVC and VP9, and to allow for encoding either a single or multiple streams simultaneously.^[123] The design continues the 1–8 variable core number design, with a single core supporting 1080p60 while 8 cores can drive 4Kp120. It can decode and encode VP9 10-bit, VP9 8-bit, HEVC Main 10, HEVC Main, H.264, VP8, JPEG and decode only MPEG4, MPEG2, VC-1/WMV, Real, H.263.^[124]

The Mali V52 video processor was released with the Mali G52 and G31 GPUs in March 2018.^[125] The processor is intended to support 4K (including HDR) video on mainstream devices.^[126]

The platform is scalable from 1 to 4 cores and doubles the decode performance relative to V61. It also adds High 10 H.264 encode (Level 5.0) and decode (Level 5.1) capabilities, as well as AVS Part 2 (Jizhun) and Part 16 (AVS+, Guangdian) decode capability for YUV420.^[127]

The Mali V76 video processor was released with the Mali G76 GPU andCortex-A76 CPU in 2018.^[128] The V76 was designed to improve video encoding and decoding performance. The design continues the 2–8 variable core number design, with 8 cores capable of 8Kp60 decoding and 8Kp30 encoding. It claims improves HEVC encode quality by 25% relative to Mali-V61 at launch.TheAV1 codec is not supported.

The Mali V77 video processor was released with the Mali G77 GPU andCortex-A77 CPU in 2019.

The Mali-D71 added Arm Framebuffer Compression (AFBC) 1.2 encoder, support for ARM CoreLink MMU-600 and Assertive Display 5. Assertive Display 5 has support forHDR10 andhybrid log–gamma (HLG).

The Mali-D77 added features includingasynchronous timewarp (ATW),lens distortion correction (LDC), and chromatic aberration correction (CAC)^{[broken anchor]}. The Mali-D77 is also capable of 3K (2880x1440) @ 120 Hz and 4K @ 90 Hz.^[133]

On April 25, 2017 the Mali-C71 was announced, ARM's first image signal processor (ISP).^{[145][146][147]}

On January 3, 2019 the Mali-C52 and C32 were announced, aimed at everyday devices including drones, smart home assistants and security, and internet protocol (IP) camera.^[148]

On September 29, 2020 the Mali-C71AE image signal processor was introduced, alongside the Cortex-A78AE CPU and Mali-G78AE GPU.^[149] It supports up to 4 real-time cameras or up to 16 virtual cameras with a maximum resolution of 4096 x 4096 each.^[150]

On June 8, 2022 the Mali-C55 ISP was introduced as successor to the C52.^[151][152] It is the smallest and most configurable image signal processor from Arm, and support up to 8 camera with a max resolution of 48 megapixel each. Arm claims improved tone mapping and spatial noise reduction compared to the C52. Multiple C55 ISPs can be combined to support higher than 48 megapixel resolutions.

On January 21, 2012,Phoronix reported thatLuc Verhaegen was driving a reverse-engineering attempt aimed at the Mali series of GPUs, specifically the Mali 200 and Mali 400 versions. The project was known asLima and targeted support forOpenGL ES 2.0.^[154] The reverse-engineering project was presented atFOSDEM, February 4, 2012,^[155][156] followed by the opening of a website^[157] demonstrating some renders. On February 2, 2013, Verhaegen demonstratedQuake III Arena in timedemo mode, running on top of the Lima driver.^[158] In May 2018, a Lima developer posted the driver for inclusion in the Linux kernel.^[159] In May 2019, the Lima driver became part of the mainline Linux kernel.^[160] TheMesa userspace counterpart was merged at the same time. It currently supportsOpenGL ES 1.1, 2.0 and parts of DesktopOpenGL 2.1, and the fallback emulation in MESA provides full support for graphical desktop environments.^[161]

Panfrost is a reverse-engineered driver effort for Mali Txxx (Midgard) and Gxx (Bifrost) GPUs. A talk introducing Panfrost was presented at X.Org Developer's Conference 2018.^[162] As of May 2019, the Panfrost driver is part of the mainline Linux kernel.^[163] and MESA. Panfrost supportsOpenGL ES 2.0, 3.0 and 3.1, as well as OpenGL 3.1.^[164]

LaterCollabora has developed^[165]panthor driver for G310, G510, G710 GPUs.

• Adreno – GPU developed by Qualcomm (formerly AMD, then Freescale)
• Atom family of SoCs – with Intel graphics core, not licensed to third parties
• AMD mobile APUs – with AMD graphics core, not licensed to third parties
• PowerVR – by Imagination Technologies
• Tegra – family of SoCs byNvidia with the graphics core available as a SIP block to third parties
• VideoCore – family of SoCs byBroadcom with the graphics core available as a SIP block to third parties
• Vivante – available as SIP block to third parties
• Imageon – oldAMD mobile GPU
• RDNA – by AMD, licensed toSamsung for use as GPUs inExynos SoCs under Xclipse name

• Graphics Processing from ARM website
• Mali Developer CenterArchived 2017-01-07 at theWayback Machine a developer focused site run by ARM
• V500
• V550
• Lima driver

• ARM architecture
• Graphics processing units
• Graphics chips

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