Jump to content

RSX Reality Synthesizer

From Wikipedia, the free encyclopedia
The RSX 'Reality Synthesizer' on a PlayStation 3 motherboard

The RSX 'Reality Synthesizer' is a proprietary graphics processing unit (GPU) codeveloped by Nvidia and Sony for the PlayStation 3 game console. It is based on the Nvidia 7800GTX graphics processor and, according to Nvidia, is a G70/G71 (previously known as NV47) hybrid architecture with some modifications. The RSX has separate vertex and pixel shader pipelines. The GPU makes use of 256 MB GDDR3 RAM clocked at 650 MHz with an effective transmission rate of 1.3 GHz and up to 224 MB of the 3.2 GHz XDR main memory via the CPU (480 MB max). Although it carries the majority of the graphics processing, the Cell Broadband Engine, the console's CPU, is also used complementarily for some graphics-related computational loads of the console.


Specifications

[edit]
Length of chip at bottom: 4.28 cm

Unless otherwise noted, the following specifications are based on a press release by Sony at the E3 2005 conference,[1] slides from the same conference,[2] and slides from a Sony presentation at the 2006 Game Developer's Conference.[citation needed]

The RSX has a floating-point performance of 192 GFLOPS.[3]

  • 550 MHz Pixel shader clock / 500 MHz Vertex shader clock on 90 nm process (shrunk to 65 nm in 2008[4] to 40 nm in 2010[5]), and to 28 nm in 2013, 300+ million transistors
  • Based on NV47 (Nvidia GeForce 7800 architecture)
  • Little Endian
  • 24 texture filtering units (TF) and 8 vertex texture addressing units (TA)
    • 24 filtered samples per clock
    • Maximum Texel fillrate: 13.2 Gigatexels per second (24 textures * 550 MHz)
    • 32 unfiltered texture samples per clock (8 TA * 4 texture samples)
    • 8 render output units (ROPs) / pixel rendering pipelines
      • Peak pixel fillrate (theoretical): 4.4 Gigapixel per second
      • Maximum Z-buffering sample rate: 8.8 Gigasamples per second (2 Z-samples * 8 ROPs * 550 MHz)
    • Maximum dot product operations: 51 billion per second (combined with Cell CPU)
    • 128-bit pixel precision offers High Dynamic Range rendering
  • 256 MB GDDR3 RAM at 650 MHz
    • 128-bit memory bus width
    • 20.8 GB/s read and write bandwidth
  • Cell FlexIO bus interface
    • Rambus XDR Memory interface bus width: 56bit out of 64bit (serial)
    • 20 GB/s read to the Cell and XDR memory
    • 15 GB/s write to the Cell and XDR memory
  • 576 KB texture cache (96 KB per quad of pixel pipelines)
  • Support for PSGL (OpenGL ES 1.1 + Nvidia Cg)
  • Support for S3 Texture Compression[6]

Other features: Support for Bilinear, trilinear, anisotropic, quincunx texture filtering, quincunx antialiasing, up to 4xMSAA, SSAA, Alpha to Coverage and Alphakill.

Model numbers

[edit]

90nm:

  • CXD2971AGB
  • CXD2971DGB
  • CXD2971 GB
  • CXD2971-1 GB
  • CXD297BGe

65nm:

  • CXD2982
  • CXD2982 GB
  • CXD2991 GB
  • CXD2991BGB
  • CXD2991GGB
  • CXD2991CGB
  • CXD2991EGB

40nm:

  • CXD5300AGB
  • CXD5300A1 GB
  • CXD5301DGB
  • CXD5302DGB
  • CXD5302A1 GB

Local GDDR3 physical memory structure

[edit]
  • Total Memory - 256 MB
  • 2 Partitions (128 MB)
  • 64bit bus per partition
  • 8 Banks per partition (16 MB)
  • 4096 Pages per bank (4 KB) -> 12bit Row Address
  • Memory block in a page -> 9bit Column Address
  • Minimum access granularity = 8 bytes -> same as buswidth between RSX <> GDDR

RSX memory map

[edit]

Although the RSX has 256 MB of GDDR3 RAM, not all of it is usable. The last 4 MB is reserved for keeping track of the RSX internal state and issued commands. The 4 MB of GPU Data contains RAMIN, RAMHT, RAMFC, DMA Objects, Graphic Objects, and the Graphic Context. The following is a breakdown of the address within 256 MB of the RSX.

Address Range Size Comment
0000000-FBFFFFF 252 MB Framebuffer
FC00000-FFFFFFF 4 MB GPU Data
FF80000-FFFFFFF 512KB RAMIN: Instance Memory
FF90000-FF93FFF 16KB RAMHT: Hash Table
FFA0000-FFA0FFF 4KB RAMFC: FIFO Context
FFC0000-FFCFFFF 64KB DMA Objects
FFD0000-FFDFFFF 64KB Graphic Objects
FFE0000-FFFFFFF 128KB GRAPH: Graphic Context

Besides local GDDR3 memory, main XDR memory can be accessed by RSX too, which is limited to either:

  • 0 MB - 256 MB (0x00000000 - 0x0FFFFFFF)
-or-
  • 0 MB - 512 MB (0x00000000 - 0x1FFFFFFF)

Speed, bandwidth and latency

[edit]

System bandwidth (theoretical maximum):

  • Cell to/from 256 MB XDR : 25.6 GB/s
  • Cell to RSX (IOIFO): 20 GB/s (practical : 15.8 GB/s @ packetsize 128B)
  • Cell from RSX (IOIFI) : 15 GB/s (practical : 11.9 GB/s @ packetsize 128B)
  • RSX to/from 256 MB GDDR3 : 20.8 GB/s (@ 650 MHz)

Because of the aforementioned layout of the communication path between the different chips, and the latency and bandwidth differences between the various components, there are different access speeds depending on the direction of the access in relation to the source and destination. The following is a chart showing the speed of reads and writes to the GDDR3 and XDR memory from the viewpoint of the Cell and RSX. Note that these are measured speeds (rather than calculated speeds) and they should be worse if RSX and GDDR3 access are involved because these figures were measured when the RSX was clocked at 550Mhz and the GDDR3 memory was clocked at 700Mhz. The shipped PS3 has the RSX clocked in at 500Mhz (front and back end, although the pixel shaders run separately inside at 550Mhz). In addition, the GDDR3 memory was also clocked lower at 650Mhz.

Speed table

[edit]
Processor 256 MB XDR 256 MB GDDR3
Cell Read 16.8GB/s 16MB/s (15.6MB/s @ 650 MHz)
Cell Write 24.9GB/s 4GB/s
RSX Read 15.5GB/s 22.4GB/s (20.8GB/s @ 650 MHz)
RSX Write 10.6GB/s 22.4GB/s (20.8GB/s @ 650 MHz)

Because of the very slow Cell Read speed from the 256 MB GDDR3 memory, it is more efficient for the Cell to work in XDR and then have the RSX pull data from XDR and write to GDDR3 for output to the HDMI display. This is why extra texture lookup instructions were included in the RSX to allow loading data from XDR memory (as opposed to the local GDDR3 memory).

RSX libraries

[edit]

The RSX is dedicated to 3D graphics, and developers are able to use different API libraries to access its features. The easiest way is to use high level PSGL, which is basically OpenGL|ES with programmable pipeline added in, however this is unpopular due to the performance overhead on a relatively weak console CPU. At a lower level developers can use LibGCM, which is an API that builds RSX command buffers at a lower level. (PSGL is actually implemented on top of LibGCM). This is done by setting up commands (via FIFO Context) and DMA Objects and issuing them to the RSX via DMA calls.

Differences with the G70 architecture

[edit]

The RSX 'Reality Synthesizer' is based on the G70 architecture, but features a few changes to the core.[7] The biggest difference between the two chips is the way the memory bandwidth works. The G70 only supports rendering to local memory, while the RSX is able to render to both system and local memory. Since rendering from system memory has a much higher latency compared to rendering from local memory, the chip's architecture had to be modified to avoid a performance penalty. This was achieved by enlarging the chip size to accommodate larger buffers and caches in order to keep the graphics pipeline full. The result was that the RSX only has 60% of the local memory bandwidth of the G70, making it necessary for developers to use the system memory in order to achieve performance targets.[7]

Difference RSX nVidia 7800GTX
GDDR3 Memory bus 128bit 256bit
ROPs 8 16
Post Transform and Lighting Cache 63 max vertices 45 max vertices
Total Texture Cache Per Quad of Pixel Pipes (L1 and L2) 96kB 48kB
CPU interface FlexIO PCI-Express 16x
Technology 28 nm/40 nm/65 nm/90 nm 110 nm

Other RSX features/differences include:

  • More shader instructions
  • Extra texture lookup logic (helps RSX transport data from XDR)
  • Fast vector normalize

Press releases

[edit]

Sony staff were quoted in PlayStation Magazine saying that the "RSX shares a lot of inner workings with NVIDIA 7800 which is based on G70 architecture."[citation needed] Since the G70 is capable of carrying out 136 shader operations per clock cycle, the RSX was expected to feature the same number of parallel pixel and vertex shader pipelines as the G70, which contains 24 pixel and 8 vertex pipelines.

Nvidia CEO Jen-Hsun Huang stated during Sony's pre-show press conference at E3 2005 that the RSX is twice as powerful as the GeForce 6800 Ultra.[2]

Bumpgate

[edit]

In the case of the PlayStation 3, the RSX was originally manufactured with the 90nm process. before transitioning to the 65nm, 40nm and finally the 28nm process. The 90nm version of the RSX was packaged (in the context of thermal strain) with incompatible die packaging elements. These factors lead to the Ball Grid Array (BGA) between the chip's interposer and its die failing at an abnormally fast rate.

Some of the factors of failure include

  • Different Coefficient of Thermal Expansions (CTEs) of different components on and in the interposer and die. This leads to these components expanding at different rates which puts shear stress on the BGA.[8]
  • Different transistor densities on the die as well as the usage of specific parts more than others which leads to parts of the die heating up faster than others. This leads to different parts expanding at different rates, ultimately leading to parts of the RSX's BGA failing faster compared to other parts[9]
  • Electromigration of the BGA which leads to voids inside of the solder. These voids hasten the failure of the BGA.[10]
  • In the PS3 the RSX was packaged with the Flip Chip Ball Grid Array (FCBGA) process. The die underfill that is present in the RSX has a very low Tg in comparison to the PlayStation 3's running temperatures during intense gameplay.[11] This leads to it transitioning to a state in which it does not support the solder in between the die and the interposer.[12]

See also

[edit]

References

[edit]
  1. ^ "SONY COMPUTER ENTERTAINMENT INC. TO LAUNCH ITS NEXT GENERATION COMPUTER ENTERTAINMENT SYSTEM, PLAYSTATION3 IN SPRING 2006" (Press release). Sony Computer Entertainment Inc. 2005-05-16.
  2. ^ a b "Sony Introduces PlayStation 3, to launch in 2006". AnandTech. 2005-05-16.
  3. ^ Klug, Anand Lal Shimpi, Brian. "NVIDIA Tegra K1 Preview & Architecture Analysis". www.anandtech.com. Retrieved 2024-08-13.{{cite web}}: CS1 maint: multiple names: authors list (link)
  4. ^ "PS3 Graphics Chip Goes 65nm in Fall". Edge Online. 2008-06-26.
  5. ^ "Sony PS3 upgraded with cooler 40-nm RSX graphics chip, profits await (updated)". Engadget. 2010-04-26.
  6. ^ Gantayat, Anoop (2006-01-30). "New PS3 tools". IGN.com. Retrieved 2006-08-28.
  7. ^ a b "Microsoft's Xbox 360, Sony's PS3 - A Hardware Discussion". Retrieved 2014-03-08.
  8. ^ Young Yang, Se; Kim, Ilho; Lee, Soon-Bok (2008). "A Study on the Thermal Fatigue Behavior of Solder Joints Under Power Cycling Conditions". IEEE Transactions on Components and Packaging Technologies. 31: 3–12. doi:10.1109/TCAPT.2007.906294.
  9. ^ Demerjian, Charlie (2008-09-01). "Why Nvidia's chips are defective". The Inquirer. Archived from the original on 2009-05-25. Retrieved 2023-11-12.
  10. ^ Hau-Riege, Christine; Yau, YouWen (2018). Electromigration Reliability of Solder Balls. doi:10.1109/IPFA.2018.8452576.
  11. ^ Hillman, C; Blattau, N; Sharon, G. "Low Tg Underfill: The Good, The Bad, and The Ugly" (PDF). Retrieved March 19, 2024.
  12. ^ Vissa, U; Butel, N; Rowatt, J; Thielen, C. (2006). A systematic approach to qualification of 90 nm low-K flip-chip packaging. doi:10.1109/ECTC.2006.1645618.