R Intel® 852GM/852GMV Chipset Graphics and Memory Controller Hub (GMCH) Datasheet June 2004 Order Number: 252407-004 R Information in this document is provided in connection with Intel products. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document. Except as provided in Intel’s Terms and Conditions of Sale for such products, Intel assumes no liability whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not intended for use in medical, life saving, or life sustaining applications. Actual system-level properties, such as skin temperature, are a function of various factors, including component placement, component power characteristics, system power and thermal management techniques, software application usage and general system design. Intel is not responsible for its customers’ system designs, nor is Intel responsible for ensuring that its customers’ products comply with all applicable laws and regulations. Intel provides this and other thermal design information for informational purposes only. System design is the sole responsibility of Intel’s customers, and Intel’s customers should not rely on any Intel-provided information as either an endorsement or recommendation of any particular system design characteristics. Intel may make changes to specifications and product descriptions at any time, without notice. Designers must not rely on the absence or characteristics of any features or instructions marked "reserved" or "undefined." Intel reserves these for future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them. The Intel 852GM/852GMV Chipset Graphics and Memory Controller Hub (GMCH) may contain design defects or errors known as errata which may cause the product to deviate from published specifications. Current characterized errata are available on request. Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order. I2C is a 2-wire communications bus/protocol developed by Philips*. SMBus is a subset of the I2C bus/protocol and was developed by Intel. Implementations of the I2C bus/protocol may require licenses from various entities, including Philips Electronics N.V. and North American Philips Corporation. Alert on LAN* is a result of the Intel and IBM* Advanced Manageability Alliance and a trademark of IBM. Copies of documents which have an ordering number and are referenced in this document, or other Intel literature, may be obtained from: Intel Corporation www.intel.com or call 1-800-548-4725 Intel, Celeron, the Intel logo, Pentium, and Intel SpeedStep are registered trademarks or trademarks of Intel Corporation and its subsidiaries in the United States and other countries. *Other brands and names may be claimed as the property of others. Copyright © Intel Corporation 2003-2004 2 Intel® 852GM/852GMV Chipset GMCH Datasheet R Contents 1. Introduction .................................................................................................................................19 1.1. Terminology ...................................................................................................................19 1.2. Reference Documents ...................................................................................................20 1.3. System Architecture Overview.......................................................................................21 1.3.1. Intel 852GM GMCH System Architecture.........................................................21 1.3.2. Intel 852GMV GMCH System Architecture ......................................................21 1.4. Processor Host Interface ...............................................................................................23 1.4.1. Intel 852GM GMCH Processor Host Interface .................................................23 1.4.2. Intel 852GMV GMCH Processor Host Interface...............................................24 1.5. Intel 852GM/852GMV GMCH Host Bus Error Checking ...............................................24 1.6. Intel 852GM/852GMV GMCH System Memory Interface..............................................24 1.7. Intel 852GM/852GMV GMCH Internal Graphics ...........................................................25 1.7.1. Intel 852GM/852GMV GMCH Analog Display Port ..........................................25 1.7.2. Intel 852GM/852GMV GMCH Integrated LVDS Port .......................................25 1.7.3. Intel 852GM/852GMV GMCH Integrated DVO Port .........................................26 1.8. Hub Interface .................................................................................................................26 1.9. Address Decode Policies ...............................................................................................26 1.10. Intel 852GM/852GMV GMCH Clocking .........................................................................26 1.11. System Interrupts...........................................................................................................27 2. Signal Description.......................................................................................................................29 2.1. Host Interface Signals....................................................................................................30 2.2. DDR SDRAM Interface ..................................................................................................33 2.3. Hub Interface Signals.....................................................................................................34 2.4. Clocks ............................................................................................................................35 2.5. Internal Graphics Display Signals..................................................................................37 2.5.1. Dedicated LFP LVDS Interface ........................................................................37 2.5.2. Digital Video Port C (DVOC) ............................................................................38 2.5.3. Analog Display..................................................................................................39 2.5.4. General Purpose Input/Output Signals.............................................................40 2.6. Voltage References, PLL Power....................................................................................42 3. Register Description ...................................................................................................................45 3.1. Conceptual Overview of the Platform Configuration Structure ......................................45 3.2. Nomenclature for Access Attributes ..............................................................................46 3.3. Standard PCI Bus Configuration Mechanism ................................................................47 3.4. Routing Configuration Accesses....................................................................................47 3.4.1. PCI Bus #0 Configuration Mechanism .............................................................47 3.4.2. Primary PCI and Downstream Configuration Mechanism................................47 3.5. Register Definitions........................................................................................................48 3.6. I/O Mapped Registers ....................................................................................................49 3.6.1. CONFIG_ADDRESS – Configuration Address Register..................................49 3.6.2. CONFIG_DATA – Configuration Data Register ...............................................51 3.7. VGA I/O Mapped Registers ...........................................................................................52 3.8. Intel 852GM/852GMV GMCH Host-Hub Interface Bridge Device Registers (Device #0, Function #0) ...............................................................................................53 3.8.1. VID – Vendor Identification...............................................................................54 3.8.2. DID – Device Identification ...............................................................................54 Intel® 852GM/852GMV Chipset GMCH Datasheet 3 R 3.9. 3.10. 4 3.8.3. PCICMD – PCI Command Register................................................................. 55 3.8.4. PCI Status Register.......................................................................................... 56 3.8.5. RID – Register Identification ............................................................................ 57 3.8.6. SUBC – Sub Class Code ................................................................................. 57 3.8.7. BCC – Base Class Code.................................................................................. 58 3.8.8. HDR – Header Type......................................................................................... 58 3.8.9. SVID – Subsystem Vendor Identification ......................................................... 58 3.8.10. SID – Subsystem Identification ........................................................................ 59 3.8.11. CAPPTR – Capabilities Pointer ....................................................................... 59 3.8.12. CAPID Capability Identification Register (Device 0) ..................................... 60 3.8.13. RRBAR – Register Range Base Address Register (Device 0) ........................ 61 3.8.14. GMC – GMCH Miscellaneous Control Register (Device 0) ............................. 62 3.8.15. GGC – GMCH Graphics Control Register (Device 0)...................................... 63 3.8.16. DAFC – Device and Function Control Register (Device 0).............................. 64 3.8.17. FDHC – Fixed DRAM Hole Control Register (Device 0).................................. 64 3.8.18. PAM(6:0) – Programmable Attribute Map Register (Device 0)........................ 65 3.8.19. SMRAM – System Management RAM Ctrl Register (Device 0) ...................... 69 3.8.20. ESMRAMC – Extended System Management RAM Control (Device 0) ......... 70 3.8.21. ERRSTS – Error Status Register (Device 0) ................................................... 71 3.8.22. ERRCMD – Error Command Register (Device 0)............................................ 72 3.8.23. SMICMD – SMI Error Command Register (Device 0) ..................................... 74 3.8.24. SCICMD – SCI Error Command Register (Device 0) ...................................... 75 3.8.25. CAPD – Capability Disable Bits ....................................................................... 75 Intel 852GM/852GMV GMCH Main Memory Control, Memory I/O Control Registers (Device #0, Function #1) ............................................................................................... 76 3.9.1. VID – Vendor Identification .............................................................................. 77 3.9.2. DID – Device Identification............................................................................... 77 3.9.3. PCICMD – PCI Command Register................................................................. 78 3.9.4. PCISTS – PCI Status Register ........................................................................ 79 3.9.5. RID – Revision Identification............................................................................ 80 3.9.6. SUBC – Sub-Class Code ................................................................................. 80 3.9.7. BCC – Base Class Code.................................................................................. 80 3.9.8. HDR – Header Type......................................................................................... 81 3.9.9. SVID – Subsystem Vendor Identification ......................................................... 81 3.9.10. SID – Subsystem Identification ........................................................................ 81 3.9.11. CAPPTR – Capabilities Pointer ....................................................................... 82 3.9.12. DRB – DRAM Row Boundary Register - Device #0 ........................................ 82 3.9.13. DRA – DRAM Row Attribute Register - Device #0 .......................................... 83 3.9.14. DRT – DRAM Timing Register - Device #0...................................................... 84 3.9.15. PWRMG – DRAM Controller Power Management Control Register - Device #087 3.9.16. DRC – DRAM Controller Mode Register - Device #0 ...................................... 88 3.9.17. DTC – DRAM Throttling Control Register (Device 0) ...................................... 90 Intel 852GM/852GMV GMCH Configuration Process and Registers (Device #0, Function #3) .................................................................................................................. 94 3.10.1. VID – Vendor Identification .............................................................................. 94 3.10.2. DID – Device Identification............................................................................... 95 3.10.3. PCICMD – PCI Command Register................................................................. 96 3.10.4. PCISTS – PCI Status Register ........................................................................ 97 3.10.5. RID – Revision Identification............................................................................ 98 3.10.6. SUBC – Sub-Class Code ................................................................................. 98 3.10.7. BCC – Base Class Code.................................................................................. 98 3.10.8. HDR – Header Type......................................................................................... 99 3.10.9. SVID – Subsystem Vendor Identification ......................................................... 99 3.10.10. ID – Subsystem Identification .......................................................................... 99 Intel® 852GM/852GMV Chipset GMCH Datasheet R 3.11. 4. 3.10.11. CAPPTR – Capabilities Pointer ......................................................................100 3.10.12. HPLLCC – HPLL Clock Control Register (Device 0)......................................100 Intel 852GM/852GMV GMCH Integrated Graphics Device Registers (Device #2, Function #0).................................................................................................................101 3.11.1. VID2 – Vendor Identification Register – Device #2 ........................................102 3.11.2. DID2 – Device Identification Register - Device #2 .........................................102 3.11.3. PCICMD2 – PCI Command Register - Device #2 ..........................................103 3.11.4. PCISTS2 – PCI Status Register - Device #2..................................................104 3.11.5. RID2 – Revision Identification Register - Device #2.......................................104 3.11.6. CC – Class Code Register - Device #2 ..........................................................105 3.11.7. CLS – Cache Line Size Register - Device #2.................................................105 3.11.8. MLT2 – Master Latency Timer Register - Device #2......................................105 3.11.9. HDR2 – Header Type Register - Device #2 ...................................................106 3.11.10. GMADR – Graphics Memory Range Address Register - Device #2 ..............106 3.11.11. MMADR – Memory Mapped Range Address Register - Device #2 ...............107 3.11.12. IOBAR – I/O Base Address Register - (Device #2) ........................................107 3.11.13. SVID2 – Subsystem Vendor Identification Register - Device #2....................108 3.11.14. SID2 – Subsystem Identification Register - Device #2...................................108 3.11.15. ROMADR – Video BIOS ROM Base Address Registers - Device #2 ............108 3.11.16. INTRLINE Interrupt Line Register - Device #2.............................................109 3.11.17. INTRPIN Interrupt Pin Register - Device #2 ................................................109 3.11.18. MINGNT – Minimum Grant Register - Device #2 ...........................................109 3.11.19. MAXLAT – Maximum Latency Register - Device #2 ......................................109 3.11.20. PMCAP – Power Management Capabilities Register - Device #2 .................110 3.11.21. PMCS – Power Management Control/Status Register - Device #2 ...............110 Intel 852GM/852GMV GMCH System Address Map ...............................................................111 4.1. System Memory Address Ranges ...............................................................................111 4.2. Compatibility Area........................................................................................................113 4.3. Extended System Memory Area ..................................................................................115 4.4. Main System Memory Address Range (0010_0000h to Top of Main Memory) ..........116 4.4.1. 15 MB-16 MB Window....................................................................................116 4.4.2. Pre-allocated System Memory .......................................................................116 4.4.2.1. Extended SMRAM Address Range (HSEG and TSEG) ...............117 4.4.2.2. HSEG ............................................................................................117 4.4.2.3. TSEG.............................................................................................117 4.4.2.4. Intel Dynamic Video Memory Technology (DVMT).......................117 4.4.2.5. PCI Memory Address Range (Top of Main System Memory to 4 GB) .........................................................................................117 4.4.2.6. APIC Configuration Space (FEC0_0000h -FECF_FFFFh, FEE0_0000h- FEEF_FFFFh)........................................................118 4.4.2.7. High BIOS Area (FFE0_0000h -FFFF_FFFFh) ............................118 4.4.3. System Management Mode (SMM) Memory Range ......................................118 4.4.3.1. SMM Space Restrictions...............................................................119 4.4.3.2. SMM Space Definition...................................................................119 4.4.4. System Memory Shadowing...........................................................................119 4.4.5. I/O Address Space .........................................................................................119 4.4.6. GMCH Decode Rules and Cross-Bridge Address Mapping...........................120 4.4.7. Hub Interface Decode Rules ..........................................................................120 4.4.7.1. Hub Interface Accesses to GMCH that Cross Device Boundaries ....................................................................................121 Intel® 852GM/852GMV Chipset GMCH Datasheet 5 R 5. Functional Description.............................................................................................................. 123 5.1. Host Interface Overview .............................................................................................. 123 5.2. Dynamic Bus Inversion................................................................................................ 123 5.2.1. System Bus Interrupt Delivery ....................................................................... 123 5.2.2. Upstream Interrupt Messages........................................................................ 124 5.3. System Memory Interface ........................................................................................... 124 5.3.1. DDR SDRAM Interface Overview .................................................................. 124 5.3.2. System Memory Organization and Configuration .......................................... 124 5.3.2.1. Configuration Mechanism for SO-DIMMs..................................... 124 5.3.2.2. System Memory Register Programming....................................... 125 5.3.3. DDR SDRAM Performance Description......................................................... 125 5.4. Integrated Graphics Overview..................................................................................... 126 5.4.1. 3D/2D Instruction Processing ........................................................................ 126 5.4.2. 3D Engine ...................................................................................................... 127 5.4.2.1. Setup Engine ................................................................................ 127 5.4.2.2. Viewport Transform and Perspective Divide ................................ 127 5.4.2.3. 3D Primitives and Data Formats Support..................................... 127 5.4.2.4. Pixel Accurate Fast Scissoring and Clipping Operation ............... 128 5.4.2.5. Backface Culling ........................................................................... 128 5.4.2.6. Scan Converter............................................................................. 128 5.4.2.7. Texture Engine ............................................................................. 128 5.4.2.8. Perspective Correct Texture Support ........................................... 128 5.4.2.9. Texture Decompression ............................................................... 128 5.4.2.10. Texture Chromakey ...................................................................... 129 5.4.2.11. Anti-Aliasing.................................................................................. 129 5.4.2.12. Texture Map Filtering.................................................................... 129 5.4.2.13. Multiple Texture Composition ....................................................... 130 5.4.2.14. Cubic Environment Mapping ........................................................ 130 5.4.2.15. Bump Mapping.............................................................................. 130 5.4.3. Raster Engine ................................................................................................ 130 5.4.3.1. Texture Map Blending .................................................................. 131 5.4.3.2. Combining Intrinsic and Specular Color Components.................. 131 5.4.3.3. Color Shading Modes ................................................................... 132 5.4.3.4. Color Dithering.............................................................................. 132 5.4.3.5. Vertex and Per Pixel Fogging....................................................... 132 5.4.3.6. Alpha Blending.............................................................................. 132 5.4.3.7. Color Buffer Formats: (Destination Alpha) ................................... 133 5.4.3.8. Depth Buffer.................................................................................. 133 5.4.3.9. Stencil Buffer ................................................................................ 133 5.4.3.10. Projective Textures ....................................................................... 134 5.4.4. 2D Engine ...................................................................................................... 134 5.4.4.1. 256-Bit Pattern Fill and BLT Engine ............................................. 134 5.4.4.2. Alpha Stretch BLT......................................................................... 134 5.4.5. Planes and Engines ....................................................................................... 135 5.4.5.1. Dual Pipe Independent Display Functionality............................... 135 5.4.6. Hardware Cursor Plane.................................................................................. 135 5.4.6.1. Cursor Color Formats ................................................................... 135 5.4.6.2. Popup Plane (Second Cursor)...................................................... 135 5.4.6.3. Popup Color Formats ................................................................... 136 5.4.7. Overlay Plane................................................................................................. 136 5.4.7.1. Multiple Overlays (Display C) ....................................................... 136 5.4.7.2. Source/Destination Color/Chromakeying ..................................... 136 5.4.7.3. Gamma Correction ....................................................................... 136 6 Intel® 852GM/852GMV Chipset GMCH Datasheet R 5.5. YUV to RGB Conversion...............................................................136 5.4.7.4. 5.4.7.5. Color Control .................................................................................136 5.4.7.6. Dynamic Bob and Weave..............................................................136 5.4.8. Video Functionality .........................................................................................137 5.4.8.1. MPEG-2 Decoding ........................................................................137 5.4.8.2. Hardware Motion Compensation ..................................................137 5.4.8.3. Sub-picture Support ......................................................................137 Display Interface ..........................................................................................................138 5.5.1. Analog Display Port Characteristics ...............................................................138 5.5.1.1. Integrated RAMDAC .....................................................................138 5.5.1.2. DDC (Display Data Channel) ........................................................138 5.5.2. Digital Display Interface..................................................................................138 5.5.2.1. Dedicated LVDS Interface.............................................................138 5.5.2.2. LVDS Interface Signals .................................................................139 5.5.2.3. LVDS Pair States ..........................................................................139 5.5.2.4. Single Channel versus Dual Channel Mode .................................140 5.5.2.5. LVDS Channel Skew.....................................................................140 5.5.2.6. LVDS PLL .....................................................................................140 5.5.2.7. SSC Support .................................................................................140 5.5.2.8. Panel Power Sequencing..............................................................140 5.5.2.9. Back Light Inverter Control ...........................................................142 5.5.2.10. Digital Video Output Port...............................................................142 6. Power and Thermal Management ............................................................................................143 6.1. General Description of Supported CPU States ...........................................................144 6.2. General Description of ACPI States ............................................................................144 6.3. Enhanced Intel SpeedStep Technology Overview ......................................................145 6.4. Internal Thermal Sensor ..............................................................................................145 6.4.1. Hardware Throttling ........................................................................................145 6.4.2. Register Locking.............................................................................................145 6.4.3. Hysteresis Operation ......................................................................................146 6.5. External Thermal Sensor Input ....................................................................................146 6.5.1. Usage .............................................................................................................146 7. Testability..................................................................................................................................147 7.1. XOR Test Mode Entry..................................................................................................147 7.2. XOR Chain Differential Pairs .......................................................................................149 7.3. XOR Chain Exclusion List............................................................................................149 7.4. XOR Chain Connectivity/Ordering ...............................................................................150 7.4.1. VCC/VSS Voltage Groups..............................................................................162 8. Intel 852GM/852GMV GMCH Strap Pins .................................................................................163 8.1. Strapping Configuration ...............................................................................................163 9. Ballout and Package Information..............................................................................................165 9.1. Package Mechanical Information.................................................................................173 Intel® 852GM/852GMV Chipset GMCH Datasheet 7 R Figures Figure 1. Configuration Address Register................................................................................ 49 Figure 2. Configuration Data Register ..................................................................................... 51 Figure 3. PAM Registers .......................................................................................................... 67 Figure 4. Simplified View of System Address Map ................................................................ 112 Figure 5. Detailed View of System Address Map................................................................... 113 Figure 6. Intel 852GM/852GMV GMCH Graphics Block Diagram ......................................... 126 Figure 7. Panel Power Sequencing ....................................................................................... 141 Figure 8. XOR–Tree Chain .................................................................................................... 147 Figure 9. XOR Chain Test Mode Entry Events Diagram ....................................................... 148 Figure 10. ALLZ Test Mode Entry Events Diagram ............................................................... 148 Figure 11. Intel 852GM/852GMV GMCH Ballout Diagram (Top View).................................. 165 Figure 12. Intel 852GM/852GMV GMCH Micro-FCBGA Package Dimensions ( Top View)................................................................................................................ 173 Figure 13. Intel 852GM/852GMV GMCH Micro-FCBGA Package Dimensions (Side View) ............................................................................................................. 174 Figure 14. Intel 852GM/852GMV GMCH Micro-FCBGA Package Dimensions (Bottom View) ......................................................................................................... 175 8 Intel® 852GM/852GMV Chipset GMCH Datasheet R Tables Table 1. DDR Memory Capacity.............................................................................................. 24 Table 2. Intel 852GM/852GMV GMCH Interface Clocks......................................................... 27 Table 3. Host Interface Signal Descriptions ............................................................................ 30 Table 4. DDR SDRAM Interface Descriptions......................................................................... 33 Table 5. Hub Interface Signals ................................................................................................ 34 Table 6. Clock Signals ............................................................................................................. 35 Table 7. Dedicated LVDS Flat Panel Interface Signal Descriptions........................................ 37 Table 8. Digital Video Port C (DVOC) Signal Descriptions ..................................................... 38 Table 9. Analog Display Signal Descriptions........................................................................... 39 Table 10. Intel 852GM/852GMV GMCH GPIO (DDC, I2C, etc.) Signal Descriptions............. 40 Table 11. Voltage References, PLL Power ............................................................................. 42 Table 12. Device Number Assignment .................................................................................... 45 Table 13. Nomenclature for Access Attributes ........................................................................ 46 Table 14. VGA I/O Mapped Register List ................................................................................ 52 Table 15. Index – Data Registers ............................................................................................ 52 Table 16. GMCH Configuration Space - Device #0, Function#0............................................. 53 Table 17. Attribute Bit Assignment .......................................................................................... 66 Table 18. PAM Registers and Associated System Memory Segments .................................. 67 Table 19. Host-Hub I/F Bridge/System Memory Controller Configuration Space (Device #0, Function#1)........................................................................................... 76 Table 20. Configuration Process Configuration Space (Device#0, Function #3) .................... 94 Table 21. Intel 852GM/852GMV GMCH Configurations ....................................................... 100 Table 22. Integrated Graphics Device Configuration Space (Device #2, Function#0).......... 101 Table 23. System Memory Segments and Their Attributes................................................... 114 Table 24. Pre-allocated System Memory .............................................................................. 116 Table 25. SMM Space Transaction Handling........................................................................ 119 Table 26. Relation of DBI Bits to Data Bits............................................................................ 123 Table 27. Data Bytes on SO-DIMM Used for Programming DRAM Registers...................... 125 Table 28. Dual Display Usage Model (Intel 852GM/852GMV GMCH).................................. 135 Table 29. Panel Power Sequencing Timing Parameters....................................................... 142 Table 30. Enhanced Intel SpeedStep Technology Overview................................................ 145 Table 31. Differential Signals in the XOR Chains.................................................................. 149 Table 32. XOR Chain Exclusion List of Pins ......................................................................... 149 Table 33. XOR Mapping ........................................................................................................ 151 Table 34. Voltage Levels and Ball Out for Voltage Groups................................................... 162 Table 35. Strapping Signals and Configuration..................................................................... 163 Table 36. Ballout Table.......................................................................................................... 166 Intel® 852GM/852GMV Chipset GMCH Datasheet 9 R Revision History Document No. Rev. Description Date 252407 001 Initial release January 2003 252407 002 Revisions include: January 2004 Added support for Intel Celeron M processor 252407 003 Revisions include: Added 852GMV features and system diagram to features section 252407 004 Revisions include: February 2004 June 2004 Added support for Intel Celeron D processor on 90 nm process and in the 478-pin package 10 Intel® 852GM/852GMV Chipset GMCH Datasheet R Intel® 852GM Chipset GMCH Product Features Processor/Host Bus Support Intel® Celeron® processor (478-pin package) Supports the processor subset of the Enhanced Mode Scalable bus protocol 2X Address, 4X data Intel Celeron processor System Bus interrupt delivery Mobile Intel® Pentium® 4 Processor-M (478-pin package) Supports the subset of the Enhanced Mode Scalable bus protocol Mobile Intel Pentium 4 Processor-M System Bus interrupt delivery Supports system bus at 400-MHz or 3.2 GB/s Supports host Dynamic Bus Inversion (DBI) Supports 32-bit host bus addressing 12-deep In-Order-Queue AGTL+ bus driver technology with integrated AGTL termination resistors Supports Enhanced Intel SpeedStep® technology Intel® Celeron® M processor 400-MHz front side bus frequency. Source synchronous double pumped address (2X) Source synchronous quad pumped data (4X) FSB interrupt delivery Supports Host bus dynamic bus inversion (DBI) Supports 32-bit host bus addressing 8-deep in-order queue AGTL+ bus driver technology with integrated AGTL+ termination resistors Memory System Directly supports one DDR SDRAM channel, 64-bits wide Supports 200/266-MHz DDR SDRAM devices with max of 2 Double-Sided SODIMMs (4 rows populated) with unbuffered PC1600/PC2100 DDR Triangle Lists, Strips and Fans support Intel® 852GM/852GMV Chipset GMCH Datasheet SDRAM (without ECC) Supports 128-Mbit, 256-Mbit, and 512Mbit technologies providing maximum capacity of 1-GB with x16 devices and up to 2-GB with high density 512-Mbit technology All supported devices have 4 banks Supports up to 16 simultaneous open pages Supports page sizes of 2-kB, 4-kB, 8-kB, and 16-kB. Page size is individually selected for every row (UMA support only) System Interrupts Supports Intel 8259 and FSB interrupt delivery mechanism Supports interrupts signaled as upstream Memory Writes from PCI and Hub Interface MSI sent to the CPU through the System Bus Internal Graphics Features Up to 64-MB of Dynamic Video Memory Allocation Display Image Rotation Core Frequency Display Core frequency of 133-MHz Render Core frequency of 133-MHz 2D Graphics Engine Optimized 128-bit BLT engine Ten programmable and predefined monochrome patterns Alpha Stretch Blt (via 3D pipeline) Anti-aliased lines Hardware-based BLT Clipping and Scissoring 32-bit Alpha Blended cursor Programmable 64 x 64 3-color Transparent cursor Color Space Conversion 3 Operand Raster BLTs 8-bit, 16-bit, and 32-bit color ROP support DIB translation and Linear/Tile addressing 3D Graphics Engine 3D Setup and Render Engine Viewpoint Transform and Perspective Divide 11 R 12 Indexed Vertex and Flexible Vertex formats Pixel accurate Fast Scissoring and Clipping operation Backface Culling support DirectX* and OGL Pixelization rules Anti-Aliased Lines support and Sprite Points support Provides the highest sustained fill rate performance in 32-bit color and 24-bit W mode High quality performance Texture Engine 266-Mega Texel/s peak performance Per Pixel Perspective Corrected Texture Mapping Single Pass Texture Compositing(Multi-Textures) at rate Enhanced Texture Blending functions IOxAPIC in ICH4-M provides redirection for upstream interrupts to the System Bus Video Stream Decoder HW Motion Compensation for MPEG2 All format decoder (18 ATSC formats) supported Dynamic Bob and Weave support for Video Streams Support for standard definition DVD quality encoding at low CPU utilization Video Overlay Single high quality scalable Overlay and second Sprite to support second Overlay Multiple Overlay functionality provided via Arithmetic Stretch BLT (Block Transfer) 5-tap horizontal, 3-tap vertical filtered scaling Multiple Overlay formats Direct YUV from Overlay to TV-out Independent Gamma Correction Independent Brightness / Contrast / Saturation Independent Tint / Hue support Color Specular Lighting Z Bias support Dithering Line and Full-Scene Anti-Aliasing 16 and 24-bit Z Buffering Destination Colorkeying Source Chromakeying Multiple hardware color cursor support (32-bit with alpha and legacy 2-bpp mode) Accompanying I2C and DDC channels provided through multiplexed interface Display Analog Display Support 350-MHz integrated 24-bit RAMDAC that can drive a standard progressive scan analog monitor with pixel resolution up to 1600x1200 at 85-Hz and up to 1920x1440 at 60-Hz Dual independent pipe support Concurrent: Different images and native display timings on each display device DVO (DVOC) support Digital video out port DVOC with 165-MHz dot clock on 12-bit double pumped interface Digital video out port DVOC with 165-MHz dot clock on 12-bit double pumped interface Variety of DVO devices supported Compliant with DVI Specification 1.0 Support display resolution up to 1400x1050 @ 75 Hz Dedicated LFP (local flat panel) LVDS interface Twelve Level of Detail MIP Map Sizes from 1x1 to 2 Kx2 K Numerous Texture formats including 32-bit RGBA Alpha and Luminance Maps Texture Chromakeying Bilinear, Trilinear, and Anisotropic MIP-Mapped Filtering Cubic Environment Reflection Mapping Embossed Bump-Mapping DXTn Texture Decompression FX1 Texture Compression 3D Graphics Rasterization enhancements One Pixel per clock Flat and Gouraud Shading Color Alpha Blending for Transparency Vertex and Programmable Pixel Fog Atmospheric effects Compliant with ANSI/TIA/EIA –644-1995 Intel® 852GM/852GMV Chipset GMCH Datasheet R 16 and 24-bit W Buffering 8-bit Stencil Buffering Double and Triple Render Buffer support 16 and 32-bit color Destination Alpha Vertex Cache Maximum 3D resolution of backlight inverter control Bi-linear Panel fitting 1600x1200 at 85-Hz (contact your Intel Field Representative for detailed display information, i.e. pixel depths, etc.) Optimal 3D resolution supported Fast Clear support ROP support Hub Interface to ICH4-M 266 MB/s point-to-point Hub Interface to ICH4-M 66-MHz base clock Intel® 852GM/852GMV Chipset GMCH Datasheet specification Integrated PWM interface for LCD backlight inverter control Bi-linear Panel fitting Package 732-pin Micro-FCBGA (37.5 x 37.5 mm) Power Management SMRAM space remapping to A0000h (128 kB) Supports extended SMRAM space above 256-MB, additional 1-MB TSEG from Top of Memory, cacheable (cacheability controlled by CPU) APM Rev 1.2 compliant power management Supports Suspend to System Memory (S3), Suspend to Disk (S4) and Hard Off/Total Reboot (S5) ACPI 1.0b, 2.0 Support Single or dual channel LVDS panel support up to SXGA+(1400x1050 60-Hz) panel resolution with frequency range from 25-MHz to 112-MHz (single channel/dual channel) SSC support of 0.5%, 1.0%, and 2.5% center and down spread with external SSC clock Supports data format of 18-bpp LCD panel power sequencing compliant with SPWG timing specification 13 R Intel® 852GMV Chipset GMCH Product Features Note: The Intel 852GMV chipset GMCH shares the same chipset features as the Intel 852GM chipset along with the additional features: 14 Processor/Host Bus Support Intel Celeron processor (478-pin FCPGA package, 0.13 micron process) 2X Address, 4X data Intel Celeron processor FSB interrupt delivery Supports system bus at 400 MHz with Intel Celeron processor (0.13 micron process) Supports system bus at 533 MHz with Intel Celeron D processor on 90 nm process and in the 478-pin package Memory System Supports 200/266-MHz DDR SDRAM devices with max of 2 Double-Sided SODIMMs (4 rows populated) with unbuffered PC1600/PC2100 DDR SDRAM Intel® 852GM/852GMV Chipset GMCH Datasheet R Mobile Intel Pentium 4 Processor-M or Mobile Intel Celeron Processor and Intel 852GM Chipset Block Diagram Mobile Intel Pentium 4 Processor-M or Mobile Intel Celeron processor CRT RGB 400MHz LVDS Panel DVO Device DVO PC1600/PC2100 852GM GMCH 732 Micro-FCBGA 200/266MHz DDR 266 MHz HUB Interface ATA100 IDE (2) LAN USB 2.0/1.1 (6) Audio Codec ICH4-M 421 BGA PCI 33MHz AC’97 2.2 Moon2 Cardbus LPC Audio Codec FWH SIO KBC Intel® 852GM/852GMV Chipset GMCH Datasheet 15 R Intel Celeron M Processor and Intel 852GM GMCH Chipset System Block Diagram Intel Celeron M Processor CRT RGB 400MHz LVDS Panel DVO Device DVO PC1600/PC2100 852GM GMCH 732 Micro-FCBGA 200/266MHz DDR 266 MHz HUB Interface ATA100 IDE (2) LAN USB 2.0/1.1 (6) Audio Codec ICH4-M 421 BGA PCI 33MHz AC’97 2.2 Moon2 Cardbus LPC I/P Audio Codec FWH SIO KBC 16 Intel® 852GM/852GMV Chipset GMCH Datasheet R Intel Celeron Processor, Intel Celeron D Processor on 90 nm process and in the 478-pin package and Intel 852GMV GMCH Chipset System Block Diagram Intel Celeron processor or Intel Celeron D processor CRT RGB 400/533MHz LVDS Panel DVO Device DVO PC1600/PC2100 852GMV GMCH 732 Micro-FCBGA 200/266MHz DDR 266 MHz HUB Interface ATA100 IDE (2) LAN USB 2.0/1.1 (6) Audio Codec ICH4-M 421 BGA PCI 33MHz AC’97 2.2 Moon2 Cardbus LPC Audio Codec FWH SIO KBC Intel® 852GM/852GMV Chipset GMCH Datasheet 17 R This page intentionally left blank 18 Intel® 852GM/852GMV Chipset GMCH Datasheet Introduction R 1. Introduction This document provides the design specifications for the Intel® 852GM/GMVchipsets. 1.1. Terminology Term Description BLI Back Light Inverter Core The internal base logic in the Intel 852GM/852GMV GMCH CPIS Common Panel Interface Specification CPU Central Processing Unit DBI Dynamic Bus inversion DBL Display Brightness Link DVO Digital Video Out DVI* Digital Visual Interface is the interface specified by the DDWG (Digital Display Working Group) DVI Spec. Rev. 1.0 utilizing only the Silicon Image developed T.M.D.S. protocol DVMT Intel Dynamic Video Memory Technology EDID Extended Display Identification Data Full Reset A Full Intel 852GM/852GMV GMCH Reset is defined in this document when RSTIN# is asserted GMCH Graphics Memory Controller Hub Hub Interface (HI) The proprietary interconnect between the Intel 852GM/852GMV GMCH and the component. In this document, the Hub Interface cycles originating from or destined for the ICH4-M are generally referred to as Hub Interface cycles. Hub cycles originating from or destined for the primary PCI interface on are sometimes referred to as Hub Interface/PCI cycles Host This term is used synonymously with processor IGD Integrated Graphics Device Intel 852GM/852GMV GMCH Refers to the GMCH component Intel 82801DBM ICH4-M The component contains the primary PCI interface, LPC interface, USB 2.0, ATA-100, AC’97, and other I/O functions. It communicates with the Intel 852GM/852GMV GMCH over a proprietary interconnect called the Hub Interface. Throughout this datasheet, the Intel 82801DBM ICH4-M component will be referred to as the ICH4-M IPI Inter Processor Interrupt LFP Local Flat Panel LVDS Low voltage differential signals used for interfacing to LCD panels MSI Message Signaled Interrupts. MSI allow a device to request interrupt service via a standard memory write transaction instead of through a hardware signal Primary PCI Physical PCI bus that is driven directly by the component. It supports only 5-V, 33-MHz PCI or PCI0 2.2 compliant components. Communication between PCI0 and Intel Intel® 852GM/852GMV Chipset GMCH Datasheet 19 Introduction R Term Description 852GM/852GMV GMCH occurs over the Hub Interface. Note that although the Primary PCI bus is referred to as PCI0, it is not PCI Bus #0 from a configuration standpoint 1.2. FSB Processor System Bus. Connection between Intel 852GM/852GMV GMCH and the CPU. Also known as the Front Side Bus (FSB) or Host interface PWM Pulse Width Modulation SSC Spread Spectrum Clocking System Bus Processor-to-Intel 852GM/852GMV GMCH interface. The Enhanced Mode of the Scalable Bus is the P6 Bus plus enhancements, consisting of source synchronous transfers for address and data, and system bus interrupt delivery. The Mobile Pentium 4 Processor-M processor implements a subset of Enhanced Mode UMA Unified Memory Architecture with graphics memory for the IGD inside System Memory VDL Video Data Link Reference Documents Document ® Location ® http://developer.intel.com Mobile Intel Pentium 4 Processor –M Datasheet (250686), Mobile Intel Celeron® processor(251308), Intel Celeron® processor(290749) ® ® http://developer.intel.com Intel Celeron D Processor on 90 nm Process and in the 478-pin Package Datasheet ® ® http://developer.intel.com PCI Local Bus Specification 2.2 www.pcisig.com Intel Celeron M Processor Datasheet(300302) ® Intel 82801DBM I/O Controller Hub 4 Mobile (ICH4-M) Datasheet (252337) ® ® ® Mobile Intel Pentium 4 Processor-M, Intel ® ® ® Celeron M Processor, Mobile Intel Celeron Processor, and Intel® 852GME, Intel® 852GMV and Intel® 852PM Chipset Platforms Design Guide(25302601) http://developer.intel.com Advanced Configuration and Power Management(ACPI) Specification 1.0b & 2.0 http://www.teleport.com/~acpi/ Advanced Power Management (APM) Specification 1.2 http://www.microsoft.com/hwdev/busbios/amp_12.htm ® IA-32 Intel Architecture Software Developer Manual Volume 3: System Programming Guide ® 20 http://developer.intel.com/design/mobile/datashts/252337.htm http://developer.intel.com/design/Pentium4/manuals/24547203.pdf Intel Graphics Software PC 12.0 Product Requirements Contact your Intel Field Representative Common Panel Interface Specification Version 1.5 Contact your Intel Field Representative Intel® 852GM/852GMV Chipset GMCH Datasheet Introduction R 1.3. System Architecture Overview 1.3.1. Intel 852GM GMCH System Architecture The Intel 852GM GMCH component provides the processor interface, DDR SDRAM interface, display interface, and Hub Interface in an Intel 852GM chipset platform. The Intel 852GM GMCH is optimized for the Mobile Intel Pentium 4 Processor-M, Mobile Intel Celeron processor and Intel Celeron M processor. It supports a single channel of DDR SDRAM memory. Intel 852GM Chipset contains advanced power management logic. The Intel 852GM Chipset platform supports the fourth generation mobile I/O Controller Hub to provide the features required by a mobile platform. The Intel 852GM GMCH is in a 732-pin Micro-FCBGA package and contains the following functionality: Supports single Intel processor configurations at 400-MHz or 3 GB/s 1.2-1.30-V AGTL+ host bus supporting 32-bit host bus addressing with Enhanced Intel SpeedStep® technology (Intel Celeron M processor and Intel Celeron Processor do not support Enhanced Intel SpeedStep Technology). System Memory supports 200/266-MHz (SSTL_2) DDR DRAM Up to 1 GB (with 256-Mb technology and two SO-DIMMs) of PC1600/2100 DDR SDRAM without ECC Integrated graphics capabilities, including 3D rendering acceleration and 2D hardware acceleration Integrated 350-MHz, 24-bit RAMDAC with pixel resolution up to 1600x1200 at 85-Hz and up to 1920x1440 @ 60 Hz One Dedicated Dual Channel LFP LVDS interface with frequency range of 25 MHz to 112 MHz (single channel/dual channel) for support up to SXGA+ (1400x1050 @ 60 Hz) panel resolutions with maximum pixel depth of 18-bpp Integrated PWM (Pulse Width Modulation) interface for LFP backlight inverter control for panel brightness One 165-MHz, 12-bit, DVO interface for TV-out encoder and DVI (LVDS transmitter and TMDS transmitter) support I2C and DDC channels supported Dual Pipe Independent Display with Tri-view support through LFP, DVO, and CRT Deeper Sleep state support Distributed arbitration for highly concurrent operation 1.3.2. Intel 852GMV GMCH System Architecture The Intel 852GMV GMCH component provides the processor interface, DDR SDRAM interface, display interface, and Hub interface in an Intel 852GMV chipset platform. All features listed for Intel 852GM is supported for the Intel 852GMV. The GMCH is optimized for use with the Intel Celeron processor. It supports a single channel of DDR SDRAM memory. The 852GMV GMCH contains advanced power management logic. The Intel 852GMV chipset platform supports the fourth generation mobile I/O Controller Hub (ICH4-M) to provide the features required by a mobile platform. Intel® 852GM/852GMV Chipset GMCH Datasheet 21 Introduction R The Intel 852GMV GMCH is in a 732-pin Micro-FCBGA package and contain the following functionality: Supports a single Intel Celeron processor configuration at 400 MHz Supports a single Intel Celeron D processor on 90 nm process and in the 478-pin package configuration at 533 MHz System SDRAM supports 200/266 MHz (SSTL_2) DDR SDRAM Up to 1-GB (with 512 Mb technology and two SO-DIMMs) of PC1600/2100DDR SDRAM without ECC One 165-MHz, 12-bit, DVO interface for TV-out encoder and DVI (LVDS transmitter and TMDS transmitter) support Integrated 350-MHz, 24-bit RAMDAC with maximum pixel resolution support up to 1600x1200 at 85 Hz and up to 2048x1536 at 75 Hz One Dedicated Dual Channel LFP LVDS interface with frequency range of 25 MHz to 112 MHz (single channel/dual channel) for support up to UXGA (1600 x 1200 60 Hz) panel resolutions with maximum pixel depth of 18 bpp 22 Intel® 852GM/852GMV Chipset GMCH Datasheet Introduction R 1.4. Processor Host Interface 1.4.1. Intel 852GM GMCH Processor Host Interface Mobile Intel Pentium 4 Processor-M key features include: Source synchronous double pumped address (2X) Source synchronous quad pumped data (4X) System bus interrupt and side-band signal delivery In this mode, Intel 852GM GMCH supports: A 64B cache line size A Front Side Bus frequency of 400-MHz (dual processor is not supported) AGTL+ termination resistors on all of the AGTL+ signals 32-bit host bus addressing allowing the CPU to access the entire 4 GB of the Intel 852GM GMCH memory address space Mobile Intel Celeron processor key features include: Support for a 400-MHz Front Side Bus frequency Source synchronous double pumped address (2X) Source synchronous quad pumped data (4X) System bus interrupt and side-band signal delivery AGTL+ termination resistors on all of the AGTL+ signals 32-bit host bus addressing allowing the CPU to access the entire 4-GB of the memory address space Intel Celeron M processor key features include: Support for a 400-MHz Front Side Bus frequency Source synchronous double pumped address (2X) Source synchronous quad pumped data (4X) Front side bus interrupt delivery Low voltage swing Vtt (1.05V) Dynamic Power Down (DPWR#) support Integrates AGTL+ termination resistors on all of the AGTL+ signals Supports 32-bit host bus addressing allowing the CPU to access the entire 4 GB of the GMCH memory address space An 8-deep, In-Order queue Support DPWR# signal Supports one outstanding defer cycle at a time to any particular I/O interface Intel 852GM GMCH has an In-Order Queue to support outstanding pipelined address requests on the host bus. Intel 852GM GMCH supports one outstanding defer cycle at a time; however, it supports only one to any particular I/O interface. Host initiated I/O cycles are positively decoded to the Intel 852GM GMCH configuration space and subtractively decoded to the Hub Interface. Host initiated memory Intel® 852GM/852GMV Chipset GMCH Datasheet 23 Introduction R cycles are positively decoded to the DDR SDRAM. Memory accesses initiated from the Hub Interface to DDR SDRAM will be snooped on the system bus. 1.4.2. Intel 852GMV GMCH Processor Host Interface Intel Celeron processor (400 MHz) and Intel Celeron D processor on 90 nm process and in the 478-pin package (533 MHz) key features include: Source synchronous double pumped address Source synchronous quad pumped data System bus interrupt and side-band signal delivery AGTL+ termination resistors on all of the AGTL+ signals 32-bit host bus addressing allowing the CPU to access the entire 4-GB of the memory address space Intel 852GMV GMCH has an In-Order Queue to support up to twelve outstanding pipelined address requests on the host bus. Intel 852GMV GMCH supports one outstanding defer cycle at a time; however, it supports only one to any particular I/O interface. Host initiated I/O cycles are positively decoded to the Intel 852GMV GMCH configuration space and subtractively decoded to the Hub Interface. Host initiated memory cycles are positively decoded to the DDR SDRAM. Memory accesses initiated from the Hub Interface to DDR SDRAM will be snooped on the system bus. 1.5. Intel 852GM/852GMV GMCH Host Bus Error Checking The Intel 852GM/852GMV GMCH does not generate nor check parity for Data, Address/Request, and Response signals on the processor bus. 1.6. Intel 852GM/852GMV GMCH System Memory Interface The Intel 852GM/852GMV GMCH System Memory controller directly supports the following: One channel of PC1600/2100 SO-DIMM DDR SDRAM memory DDR SDRAM devices with densities of 128-Mb, 256-Mb, and 512-Mb technology Maximum system memory support of two, double-sided SO-DIMMs (four rows populated) with up to 1 GB memory Variable page sizes of 2-kB, 4-kB, 8-kB, and 16-kB. Page size is individually selected for every row and a maximum of 16 pages may be opened simultaneously Table 1. DDR Memory Capacity 24 Technology Width System Memory Capacity 128 Mb 8 256 MB 256 Mb 8 512 MB 512 Mb 8 1 GB 128 Mb 16 256 MB Intel® 852GM/852GMV Chipset GMCH Datasheet Introduction R Technology Width System Memory Capacity 256 Mb 16 512 MB 512 Mb 16 1 GB The Intel 852GM/852GMV GMCH System Memory interface supports a thermal throttling scheme to selectively throttle reads and/or writes. Throttling can be triggered either by on-die thermal sensor, or by preset write bandwidth limits. Read throttle can also be triggered by an external input pin. The memory controller logic supports aggressive dynamic row power down features (SCKE) to help reduce power and supports Address and Control lines Tri-stating when DDR SDRAM is in active power down or self refresh. The Intel 852GM/852GMV GMCH System Memory architecture is optimized to maintain open pages (up to 16-kB page size) across multiple rows. As a result, up to 16 pages across four rows. To complement this, the GMCH will tend to keep pages open within rows, or will only close a single bank on a page miss. Intel 852GM/852GMV GMCH supports only two bank memory technologies. 1.7. Intel 852GM/852GMV GMCH Internal Graphics The GMCH IGD provides a highly integrated graphics accelerator delivering high performance 3D, 2D, and video capabilities. With its interfaces to UMA using a DVMT configuration, analog display, LVDS, and digital display (e.g. flat panel), the GMCH provides a complete graphics solution. The GMCH contains an extensive set of instructions for the following: The GMCH also provides 2D hardware acceleration for block transfers of data (BLTs). The BLT engine provides the ability to copy a source block of data to a destination and perform raster operations (e.g., ROP1, ROP2, and ROP3) on the data using a pattern, and/or another destination. Performing these common tasks in hardware reduces CPU load, and thus improves performance. High bandwidth access to data is provided through the System Memory ports. The GMCH uses Tiling architecture to increase System Memory efficiency and thus maximize effective rendering bandwidth. The Intel 852GM/852GMV GMCH has three display ports, one analog and two digital. These provide support for a progressive scan analog monitor, a dedicated dual channel LVDS panel and a DVO device. Each port can transmit data according to one or more protocols. The DVO port is connected to an external device that converts one protocol to another. Examples of this are TV-out encoders, external DACs, LVDS transmitters, and TMDS transmitters. Each display port has control signals that may be used to control, configure and/or determine the capabilities of an external device. The data that is sent out the display port is selected from one of the two possible sources, pipe A or pipe B. 1.7.1. Intel 852GM/852GMV GMCH Analog Display Port Intel 852GM/852GMV GMCH has an integrated 350-MHz, 24-bit RAMDAC that can directly drive a progressive scan analog monitor pixel resolution up to 1600x1200 at 85-Hz refresh and up to 1920x1440 at 60-Hz refresh. The DAC port can be driven on Pipe A or Pipe B. 1.7.2. Intel 852GM/852GMV GMCH Integrated LVDS Port The Intel 852GM/852GMV GMCH has an integrated dual channel LFP Transmitter interface to support LVDS LCD panel resolutions up to SXGA+ with center and down spread SSC support of 0.5%, 1%, and 2.5% utilizing an external SSC clock. The display pipe provides panel up-scaling to fit a source image Intel® 852GM/852GMV Chipset GMCH Datasheet 25 Introduction R into a specific panel size as well as panning and centering support. The LVDS port is only supported on Pipe B. The LVDS port can only be driven on Pipe B, either independently or simultaneously with the DAC port. 1.7.3. Intel 852GM/852GMV GMCH Integrated DVO Port The DVO C interface is compliant with the DVI Specification 1.0. When combined with a DVI compliant external device (e.g. TMDS Flat Panel Transmitter, TV-out encoder, etc.), the GMCH provides a high-speed interface to a digital or analog display (e.g. flat panel, TV monitor, etc.). Intel 852GM/852GMV GMCH provides a DVO port that is capable of driving a 165-MHz pixel clock at the DVO C interface. The DVO C port can be driven on Pipe A or Pipe B. If driven on port B, then the LVDS port must be disabled. 1.8. Hub Interface A proprietary interconnect connects the GMCH to the ICH4-M Chipset. All communication between the GMCH and the ICH4-M occurs over the Hub Interface. The Hub Interface runs at 66- MHz or 266MB/s. 1.9. Address Decode Policies Host initiated I/O cycles are positively decoded to the GMCH configuration space and subtractively decoded to Hub Interface. Host initiated System Memory cycles are positively decoded to DDR SDRAM and are again subtractively decoded to Hub Interface if under 4 GB. System Memory accesses from Hub Interface to DDR SDRAM will be snooped on the FSB. 1.10. Intel 852GM/852GMV GMCH Clocking The GMCH has the following clock input/output pins: 400 MHz, Spread Spectrum, Low Voltage (1.3 V) Differential BCLK, BCLK# for Processor System Bus 66-MHz Spread Spectrum, 3.3-V GCLKIN for Hub Interface buffers Four pairs of differential output clocks (SCK[4,3,1:0], SCK[4,3,1:0]#), 200/266 MHz, 2.5 V for System Memory interface 48-MHz, non-Spread Spectrum, 3.3-V DREFCLK for the Display Frequency Synthesis 48-MHz or 66-MHz, Spread Spectrum, 3.3-V DREFSSCLK for the Display Frequency Synthesis Up to 85-MHz, 1.5-V DVOBCCLKINT for TV-Out mode DPMS clock for S1-M Clock Synthesizer chip(s) are responsible for generating the system host clocks, display and Hub Interface clocks, PCI clocks, and System Memory clocks. The host target speed is 400 MHz. The GMCH does not require any relationship between the BCLK host clock and the 66-MHz clock generated for Hub Interface; they are asynchronous from each other. The Hub Interface runs at a constant 66-MHz base frequency. Table 2 indicates the frequency ratios between the various interfaces that the GMCH supports. Please see Section 5.5.2.7 for details on the Intel 852GM/852GMV GMCH SSC Usage Model. 26 Intel® 852GM/852GMV Chipset GMCH Datasheet Introduction R Table 2. Intel 852GM/852GMV GMCH Interface Clocks Interface Clock Speed CPU Bus CPU Bus (852GMV Only) DDR SDRAM 1.11. CPU System Bus Frequency Ratio Samples Per Clock Data Rate (Megasamples/s) Data Width (Bytes) Peak Bandwidth (MB/s) 100 MHz Reference 4 400 8 3200 133 MHz Reference 4 533 8 4264 100 MHz 1:1 Synchronous 2 200 8 1600 133 MHz 1:1 Synchronous 2 266 8 2128 LVDS Flat Panel 25 MHz-112 MHz (single channel) Asynchronous 1 112 2.25 252 DVO C Up to 165 MHz Asynchronous 2 330 1.5 495 DAC Interface 350 MHz Asynchronous 1 350 3 1050 System Interrupts The Intel 852GM/852GMV GMCH supports both the legacy Intel 8259 Programmable Interrupt delivery mechanism and the processor side bus interrupt delivery mechanism. The serial APIC Interrupt mechanism is not supported. The Intel 8259 Interrupt delivery mechanism support consists of flushing in bound Hub Interface write buffers when an Interrupt Acknowledge cycle is forwarded from the system bus to the Hub Interface. PCI MSI interrupts are generated as Memory Writes. The GMCH decodes upstream Memory Writes to the range 0FEE0_0000h - 0FEEF_FFFFh from the Hub Interface as message based interrupts. The GMCH forwards the Memory Writes along with the associated write data to the system bus as an Interrupt Message transaction. Since this address does not decode as part of main System Memory, the write cycle and the write data does not get forwarded to System Memory via the write buffer. The GMCH provides the response and HTRDY# for all Interrupt Message cycles including the ones originating from the GMCH. The GMCH also supports interrupt re-direction for upstream interrupt memory writes. For message based interrupts, system write buffer coherency is maintained by relying on strict ordering of Memory Writes. The GMCH ensures that all Memory Writes received from a given interface prior to an interrupt message Memory Write are delivered to the system bus for snooping in the same order that they occur on the given interface. Intel® 852GM/852GMV Chipset GMCH Datasheet 27 Introduction R This page intentionally left blank. 28 Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R 2. Signal Description This section describes the GMCH signals. These signals are arranged in functional groups according to their associated interface. The following notations are used to describe the signal type: I Input pin O Output pin I/O Bi-directional Input/Output pin The signal description also includes the type of buffer used for the particular signal: AGTL+ Open Drain GTL+ interface signal. Refer to the GTL+ I/O Specification for complete details. The GMCH integrates AGTL+ termination resistors, and supports Vtt of 1.2-1.30 V ± 5%. AGTL+ signals are “inverted bus” style where a low voltage represents a logical “1”. DVO DVO buffers. These are 1.5-V tolerant 1.5 V 1.5-V compatible DC and AC Specification voltage levels SSTL_2 Stub Series Termination Logic compatible signals. These are 2.5-V tolerant. LVTTL Low Voltage TTL compatible signals. These are 3.3-V tolerant. CMOS CMOS buffers. These are 3.3-V tolerant LVDS Low Voltage Differential signal interface Analog Analog signal interface Ref Voltage reference signal Note: System address and data bus signals are logically inverted signals. In other words, the actual values are inverted of what appears on the system bus. This must be taken into account and the addresses and data bus signals must be inverted inside the GMCH. All processor control signals follow normal convention. A “0” indicates an active level (low voltage), and a “1” indicates an active level (high voltage). Intel® 852GM/852GMV Chipset GMCH Datasheet 29 Signal Description R 2.1. Host Interface Signals Table 3. Host Interface Signal Descriptions Signal Name Type Description ADS# I/O AGTL+ Address Strobe: The system bus owner asserts ADS# to indicate the first of two cycles of a request phase. The GMCH can assert this signal for snoop cycles and interrupt messages. BNR# I/O AGTL+ Block Next Request: Used to block the current request bus owner from issuing a new request. This signal is used to dynamically control the CPU bus pipeline depth. BPRI# O AGTL+ Bus Priority Request: The GMCH is the only Priority Agent on the system bus. It asserts this signal to obtain the ownership of the address bus. This signal has priority over symmetric bus requests and will cause the current symmetric owner to stop issuing new transactions unless the HLOCK# signal was asserted. BREQ0# I/O AGTL+ Bus Request 0B: The GMCH pulls the processor bus BREQ0# signal low during CPURST#. The signal is sampled by the processor on the active-to-inactive transition of CPURST#. The minimum setup time for this signal is 4 BCLKs. The minimum hold time is 2 clocks and the maximum hold time is 20 BCLKs. BREQ0# should be tristated after the hold time requirement has been satisfied. During regular operation, the GMCH will use BREQ0# as an early indication for FSB Address and Ctl input buffer and sense amp activation. CPURST# O AGTL+ CPU Reset: The CPURST# pin is an output from the GMCH. The GMCH asserts CPURST# while RESET# (PCIRSTB# from ICH4-M) is asserted and for approximately 1 ms after RESET# is deasserted. The CPURST# allows the processor to begin execution in a known state. Note that the ICH4-M must provide CPU strap set-up and hold-times around CPURST#. This requires strict synchronization between GMCH, CPURST# deassertion and ICH4-M driving the straps. DBSY# I/O AGTL+ Data Bus Busy: Used by the data bus owner to hold the data bus for transfers requiring more than one cycle. DEFER# O AGTL+ Defer: GMCH will generate a deferred response as defined by the rules of the GMCH’s dynamic defer policy. The GMCH will also use the DEFER# signal to indicate a CPU retry response. DINV[3:0]# I/O AGTL+ Dynamic Bus Inversion: Driven along with the HD[63:0]# signals. Indicates if the associated signals are inverted or not. DINV[3:0]# are asserted such that the number of data bits driven electrically low (low voltage) within the corresponding 16bit group never exceeds 8. DPSLP# I CMOS DPWR# O AGTL+ DINV# Data Bits DINV[3]# HD[63:48]# DINV[2]# HD[47:32]# DINV[1]# HD[31:16]# DINV[0]# HD[16:0]# Deep Sleep: This signal comes from the ICH4-M device, providing an indication of C3 and C4 state control to the CPU. Negation of this signal is used as an early indication for C3 and C4 wake up (to active HPLL). Note that this is a low-voltage CMOS buffer operating on the FSB VTT power plane. Data Power: Asserted by GMCH to indicate that a data return cycle is pending within 2 HCLK cycles or more. CPU should use this signal during a read-cycle to activate the data input buffers and sense-amps in preparation for DRDY# and the related data. 30 Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R Signal Name DRDY# Type I/O Description Data Ready: Asserted for each cycle that data is transferred. AGTL+ HA[31:3]# I/O AGTL+ Host Address Bus: HA[31:3]# connects to the CPU address bus. During processor cycles the HA[31:3]# are inputs. The GMCH drives HA[31:3]# during snoop cycles on behalf of Hub Interface. HA[31:3]# are transferred at 2x rate. Note that the address is inverted on the CPU bus. HADSTB[1:0]# I/O AGTL+ Host Address Strobe: HA[31:3]# connects to the CPU address bus. During CPU cycles, the source synchronous strobes are used to transfer HA[31:3]# and HREQ[4:0]# at the 2x transfer rate. Strobe Address Bits HADSTB[0]# HA[16:3]#, HREQ[4:0]# HADSTB[1]# HA[31:17]# HD[63:0]# I/O AGTL+ Host Data: These signals are connected to the CPU data bus. HD[63:0]# are transferred at 4x rate. Note that the data signals are inverted on the CPU bus. HDSTBP[3:0]# I/O AGTL+ Differential Host Data Strobes: The differential source synchronous strobes are used to transfer HD[63:0]# and DINV[3:0]# at the 4x transfer rate. HDSTBN[3:0]# Strobe Data Bits HDSTBP[3]#, HDSTBN[3]# HD[63:48]#, DINV[3]# HDSTBP[2]#, HDSTBN[2]# HD[47:32]#, DINV[2]# HDSTBP[1]#, HDSTBN[1]# HD[31:16]#, DINV[1]# HDSTBP[0]#, HDSTBN[0]# HD[15:0]#, DINV[0]# HIT# I/O AGTL+ Hit: Indicates that a caching agent holds an unmodified version of the requested line. Also, driven in conjunction with HITM# by the target to extend the snoop window. HITM# I/O AGTL+ Hit Modified: Indicates that a caching agent holds a modified version of the requested line and that this agent assumes responsibility for providing the line. Also, driven in conjunction with HIT# to extend the snoop window. HLOCK# I/O AGTL+ Host Lock: All CPU bus cycles sampled with the assertion of HLOCK# and ADS#, until the negation of HLOCK# must be atomic, i.e. no Hub Interface snoopable access to DRAM are allowed when HLOCK# is asserted by the CPU. HREQ[4:0]# I/O AGTL+ Host Request Command: Defines the attributes of the request. HREQ[4:0]# are transferred at 2x rate. Asserted by the requesting agent during both halves of Request Phase. In the first half the signals define the transaction type to a level of detail that is sufficient to begin a snoop request. In the second half the signals carry additional information to define the complete transaction type. The transactions supported by the GMCH Host Bridge are defined in the Host Interface section of this document. HTRDY# O AGTL+ Host Target Ready: Indicates that the target of the processor transaction is able to enter the data transfer phase. Intel® 852GM/852GMV Chipset GMCH Datasheet 31 Signal Description R Signal Name RS[2:0]# 32 Type Description O AGTL+ Response Status: Indicates type of response according to the following the table: RS[2:0]# Response type 000 Idle state 001 Retry response 010 Deferred response 011 Reserved (not driven by GMCH) 100 Hard Failure (not driven by GMCH) 101 No data response 110 Implicit Write back 111 Normal data response Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R 2.2. DDR SDRAM Interface Table 4. DDR SDRAM Interface Descriptions Signal Name SCS[3:0]# Type O SSTL_2 Description Chip Select: These pins select the particular DDR SDRAM components during the active state. NOTE: There is one SCS# per DDR-SDRAM Physical SO-DIMM device row. These signals can be toggled on every rising System Memory Clock edge (SCMDCLK). SMA[12:0] O SSTL_2 Multiplexed Memory Address: These signals are used to provide the multiplexed row and column address to DDR SDRAM. SBA[1:0] O SSTL_2 Bank Select (Memory Bank Address): These signals define which banks are selected within each DDR SDRAM row. The SMA and SBA signals combine to address every possible location within a DDR SDRAM device. SRAS# O SSTL_2 DDR Row Address Strobe: SRAS# may be heavily loaded and requires 2 DDR SDRAM clock cycles for setup time to the DDR SDRAMs. Used with SCAS# and SWE# (along with SCS#) to define the System Memory commands. SCAS# O SSTL_ DDR Column Address Strobe: SCAS# may be heavily loaded and requires 2 DDR clock cycles for setup time to the DDR SDRAMs. Used with SRAS# and SWE# (along with SCS#) to define the System Memory commands. SWE# O SSTL_2 Write Enable: Used with SCAS# and SRAS# (along with SCS#) to define the DDR SDRAM commands. SWE# is asserted during writes to DDR SDRAM. SWE# may be heavily loaded and requires two DDR SDRAM clock cycles for setup time to the DDR SDRAMs. SDQ[71:0] I/O SSTL_2 Data Lines: These signals are used to interface to the DDR SDRAM data bus. SDQS[8:0] I/O SSTL_2 NOTE: ECC error detection is NOT supported: SDQ[71:64] signals should be left as NC (“No Connect”) on Intel 852GM/852GMV GMCH. Data Strobes: Data strobes are used for capturing data. During writes, SDQS is centered in data. During reads, SDQS is edge aligned with data. The following list matches the data strobe with the data bytes. There is an associated data strobe (DQS) for each data strobe (DQ) and check bit (CB) group. SDQS[7] -> SDQ[63:56] SDQS[6] -> SDQ[55:48] SDQS[5] -> SDQ[47:40] SDQS[4] -> SDQ[39:32] SDQS[3] -> SDQ[31:24] SDQS[2] -> SDQ[23:16] SDQS[1] -> SDQ[15:8] SDQS[0] -> SDQ[7:0] NOTE: ECC error detection is NOT supported: SDQS[8] signal should be left as NC (“No Connect”) on the Intel 852GM/852GMV GMCH. SCKE[3:0] O SSTL_2 Clock Enable: These pins are used to signal a self-refresh or power down command to a DDR SDRAM array when entering system suspend. SCKE is also used to dynamically power down inactive DDR SDRAM rows. There is one SCKE per DDR SDRAM row. These signals can be toggled on every rising SCK edge. Intel® 852GM/852GMV Chipset GMCH Datasheet 33 Signal Description R Signal Name SMAB[5,4,2,1] Type Description O Memory Address Copies: These signals are identical to SMA[5,4,2,1] and are used to reduce loading for selective CPC(clock-per-command). These copies are not inverted. SSTL_2 SDM[8:0] O SSTL_2 Data Mask: When activated during writes, the corresponding data groups in the DDR SDRAM are masked. There is one SDM for every eight data lines. SDM can be sampled on both edges of the data strobes. NOTE: ECC error detection is NOT supported: SDM[8] signal should be left as NC (“No Connect”) on the Intel 852GM/852GMV GMCH. RCVENOUT# O Clock Output: Used to emulate source-synch clocking for reads. This pin is a NC. SSTL_2 RCVENIN# O Clock Input: Used to emulate source-synch clocking for reads. This is pin is a NC. SSTL_2 2.3. Hub Interface Signals Table 5. Hub Interface Signals Signal Name HL[10:0] Type I/O Description Packet Data: Data signals used for HI read and write operations. 1.5 HLSTB I/O 1.5 HLSTB# I/O 1.5 34 Packet Strobe: One of two differential strobe signals used to transmit or receive packet data over HI. Packet Strobe Complement: One of two differential strobe signals used to transmit or receive packet data over HI. Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R 2.4. Clocks Table 6. Clock Signals Signal Name Type Description Host Processor Clocking BCLK I BCLK# CMOS Differential Host Clock In: These pins receive a buffered host clock from the external clock synthesizer. This clock is used by all of the GMCH logic that is in the Host clock domain (host, Hub and System Memory). The clock is also the reference clock for the graphics core PLL. This is a low voltage differential input. System Memory Clocking O SCK[5:0] SSTL_2 Differential DDR Clock: SCK and SCK# pairs are differential clock outputs. The crossing of the positive edge of SCK and the negative edge of SCK# is used to sample the address and control signals on the DDR SDRAM. There are 3 pairs to each SO-DIMM. NOTE: ECC error detection is NOT supported: SCK[2], SCK[5] signals should be left as NC (“No Connect”) on the Intel 852GM/852GMV GMCH. O SCK[5:0]# SSTL_2 Complementary Differential DDR Clock: These are the complimentary differential DDR SDRAM clock signals. NOTE: ECC error detection is NOT supported: SCK[2]#, SCK[5]# signals should be left as NC (“No Connect”) on the Intel 852GM/852GMV GMCH. DVO/Hub Input Clocking GCLKIN I Input Clock: 66-MHz, 3.3-V input clock from external buffer DVO/Hub Interface. CMOS DVO Clocking DVOCCLK DVOCCLK# O DVO Differential DVO Clock Output: These pins provide a differential pair reference clock that can run up to 165 MHz. DVOCCLK corresponds to the primary clock out. DVOCCLK# corresponds to the primary complementary clock out. DVOCCLK and DVOCCLK# should be left as NC (“Not Connected”) if the DVO C port is not implemented. DVOBCCLKINT I DVO DVOBC Pixel Clock Input/Interrupt: This signal may be selected as the reference input to either dot clock PLL (DPLL) or may be configured as an interrupt input. A TV-out device can provide the clock reference. The maximum input frequency for this signal is 85 MHz. DVOBC Pixel Clock Input: When selected as the dot clock PLL (DPLL) reference input, this clock reference input supports SSC clocking for DVO LVDS devices. DVOBC Interrupt: When configured as an interrupt input, this interrupt can support for either of the DVOB or DVOC. DVOBCCLKINT needs to be pulled down if the signal is NOT used. DPMS I DVO Display Power Management Signaling: This signal is used only in mobile systems to act as the DREFCLK in certain power management states(i.e. display power down mode); DPMS Clock is used to refresh video during S1-M. Clock Chip is powered down in S1-M. DPMS should come from a clock source that runs during S1-M and needs to be 1.5 V. So, an example would be to use a 1.5-V version of SUSCLK from ICH4-M. DAC Clocking Intel® 852GM/852GMV Chipset GMCH Datasheet 35 Signal Description R Signal Name DREFCLK Type I LVTTL Description Display Clock Input: This pin is used to provide a 48-MHz input clock to the Display PLL that is used for 2D/Video and DAC. LFP LVDS Clocking DREFSSCLK I LVTTL 36 Display SSC Clock Input: This pin provides a 48-MHz or 66-MHz input clock (SSC or non-SSC) to the Display PLL B. Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R 2.5. Internal Graphics Display Signals The internal graphics device has support for a dedicated LFP LVDS interface, DVOC interface, and an analog VGA port. 2.5.1. Dedicated LFP LVDS Interface Table 7. Dedicated LVDS Flat Panel Interface Signal Descriptions Name ICLKAP Type O Voltage Description 1.25 V± 225 mV Channel A differential clock pair output (true): 245-800 MHz 1.25 V±225 mV Channel A differential clock pair output (compliment): 245800 MHz. 1.25 V±225 mV Channel A differential data pair 3:0 output (true): 245-800 MHz. 1.25 V±225 mV Channel A differential data pair 3:0 output (compliment): 245800 MHz. 1.25 V±225 mV Channel B differential clock pair output (true): 245-800 MHz. 1.25 V±225 mV Channel B differential clock pair output (compliment): 245800 MHz. 1.25 V±225 mV Channel B differential data pair 3:0 output (true): 245-800 MHz. 1.25 V± 225 mV Channel B differential data pair 3:0 output (compliment): 245800 MHz. LVDS ICLKAM O LVDS IYAP[3:0] O LVDS IYAM[3:0] O LVDS ICLKBP O LVDS ICLKBM O LVDS IYBP[3:0] O LVDS IYBM[3:0] O LVDS Intel® 852GM/852GMV Chipset GMCH Datasheet 37 Signal Description R 2.5.2. Digital Video Port C (DVOC) Table 8. Digital Video Port C (DVOC) Signal Descriptions Name DVOCD[11:0] Type O DVO Description DVOC Data: This data bus is used to drive 12-bit RGB data on each edge of the differential clock signals, DVOCCLK and DVOCCLK#. This provides 24-bits of data per clock period. In dual channel mode, this provides the upper 12-bits of pixel data. DVOCD[11:0] should be left as left as NC (“Not Connected”) if not used. DVOCHSYNC O DVO DVOCVSYNC DVOCBLANK# O Horizontal Sync: HSYNC signal for the DVOC interface. DVOCHSYNC should be left as left as NC (“Not Connected”) if not used. Vertical Sync: VSYNC signal for the DVOC interface. DVO DVOCVSYNC should be left as left as NC (“Not Connected”) if the signal is NOT used when using internal graphics device. O Flicker Blank or Border Period Indication: DVOCBLANK# is a programmable output pin driven by the Intel 852GM/852GMV GMCH. DVO When programmed as a blank period indication, this pin indicates active pixels excluding the border. When programmed as a border period indication, this pin indicates active pixel including the border pixels. DVOCBLANK# should be left as left as NC (“Not Connected”) if not used. DVOBCINTR# I DVO DVOCFLDSTL I DVO DVOBC Interrupt: This pin is used to signal an interrupt, typically used to indicate a hot plug or unplug of a digital display. TV Field and Flat Panel Stall Signal. This input can be programmed to be either a TV Field input from the TV encoder or Stall input from the flat panel. DVOC TV Field Signal: When used as a Field input, it synchronizes the overlay field with the TV encoder field when the overlay is displaying an interleaved source. DVOC Flat Panel Stall Signal: When used as the Stall input, it indicates that the pixel pipeline should stall one horizontal line. The signal changes during horizontal blanking. The panel fitting logic, when expanding the image vertically, uses this. DVOCFLDSTL needs to be pulled down if not used. ADDID[7:0] I DVO ADDID[7:0]: These pins are used to communicate to the Video BIOS when an external device is interfaced to the DVO port. Note: Bit[7] needs to be strapped low when a DVO device is present. The other pins should be left as NC. DVODETECT I DVO 38 DVODETECT: This strapping signal indicates to the GMCH whether a DVO device is plugged in or not. When a DVO device is connected, then DVODETECT = 0. Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R 2.5.3. Analog Display Table 9. Analog Display Signal Descriptions Pin Name VSYNC Type O CMOS HSYNC O CMOS RED O Analog RED# O Description CRT Vertical Synchronization: This signal is used as the vertical sync signal. Refer to Table 36. CRT Horizontal Synchronization: This signal is used as the horizontal sync signal. Refer to Table 36. Red (Analog Video Output): This signal is a CRT Analog video output from the internal color palette DAC. The DAC is designed for a 37.5-Ω equivalent load on each pin (e.g., 75-Ω resistor on the board, in parallel with the 75-Ω CRT load). Red# (Analog Output): Tied to ground. Analog GREEN O Analog GREEN# O Green (Analog Video Output): This signal is a CRT analog video output from the internal color palette DAC. The DAC is designed for a 37.5-Ω equivalent load on each pin (e.g., 75-Ω resistor on the board, in parallel with the 75- Ω CRT load). Green# (Analog Output): Tied to ground. Analog BLUE O Analog BLUE# O Blue (Analog Video Output) : This signal is a CRT Analog video output from the internal color palette DAC. The DAC is designed for a 37.5-Ω equivalent load on each pin (e.g., 75ohm resistor on the board, in parallel with the 75-Ω (CRT load). Blue# (Analog Output): Tied to ground. Analog Intel® 852GM/852GMV Chipset GMCH Datasheet 39 Signal Description R 2.5.4. General Purpose Input/Output Signals Table 10. Intel 852GM/852GMV GMCH GPIO (DDC, I2C, etc.) Signal Descriptions GPIO I/F Total RSTIN# Type I Comments Reset: Primary Reset CMOS PWROK I Power OK: Indicates that power to GMCH is stable. CMOS AGPBUSY# EXTTS_0 LCLKCTLA O AGPBUSY: Output of the GMCH graphics controller to the ICH4-M, which indicates that CMOS certain graphics activity is taking place. It will indicate to the ACPI software to not enter the C3 state. It will also cause a C3/C4 exit if C3/C4 was being entered, or was already entered when AGPBUSY# went active. Not active when the graphics controller is in any ACPI state other than D0. I External Thermal Sensor Input: This signal is an active low input to the GMCH and is CMOS used to monitor the thermal condition around the System Memory and is used for triggering a read throttle. The GMCH can be optionally programmed to send a SERR, SCI, or SMI message to the ICH4-M upon the triggering of this signal. O SSC Chip Clock Control: Can be used to control an external clock chip with SSC control. CMOS LCLKCTLB O SSC Chip Data Control: Can be used to control an external clock chip for SSC control. CMOS PANELVDDEN O LVDS Panel power control: This signal is used enable power to the panel interface. CMOS PANELBKLTEN O LVDS Panel backlight enable: This signal is used to enable the back light inverter(BLI). CMOS PANELBKLTCTL O LVDS Panel backlight brightness control: This signal is used as power control. CMOS DDCACLK I/O CRT DDC Clock: This signal is used as the DDC clock signal between the CRT monitor CMOS and the GMCH. DDCADATA I/O CRT DDC Data: This signal is used as the DDC data signal between the CRT monitor and CMOS the GMCH. DDCPCLK I/O Panel DDC Clock: This signal is used as the DDC clock signal between the LFP and the CMOS GMCH. DDCPDATA I/O Panel DDC Data: This signal is used as the DDC data signal between the LFP and the CMOS GMCH. MI2CCLK I/O DVO MI2CDATA I/O DVO MDVICLK I/O DVO MDVIDATA 40 I/O DVO I2C Clock: The specific function is I2C_CLK for a digital display (i.e. TV-Out Encoder, TMDS transmitter). This signal is tri-stated during a hard reset. DVO I2C Data: The specific function is I2C_DATA for a digital display (i.e. TV-Out Encoder, TMDS transmitter). This signal is tri-stated during a hard reset. DVI DDC Clock: The specific function is DDC clock for a digital display connector (i.e. primary digital monitor). This signal is tri-stated during a hard reset. DVI DDC Data: The specific function is DDC data for a digital display connector (i.e. Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R GPIO I/F Total Type DVO MDDCDATA I/O DVO MDDCCLK I/O DVO Comments primary digital monitor). This signal is tri-stated during a hard reset. DVI DDC Clock: The specific function is DDC data for a digital display connector (i.e. secondary digital monitor). This signal is tri-stated during a hard reset. DVI DDC Data: The specific function is DDC clock for a digital display connector (i.e. secondary digital monitor). This signal is tri-stated during a hard reset. Intel® 852GM/852GMV Chipset GMCH Datasheet 41 Signal Description R 2.6. Voltage References, PLL Power Table 11. Voltage References, PLL Power Signal Name Type Description Host Processor HXRCOMP Analog Host RCOMP: Used to calibrate the host AGTL+ I/O buffers. HYRCOMP Analog Host RCOMP: Used to calibrate the host AGTL+ I/O buffers. HXSWING Analog Host Voltage Swing (RCOMP reference voltage): These signals provide a reference voltage used by the FSB RCOMP circuit. HYSWING Analog Host Voltage Swing (RCOMP reference voltage): These signals provide a reference voltage used by the FSB RCOMP circuit. HDVREF[2:0] Ref Analog Host Data (input buffer) VREF: Reference voltage input for the data signals of the host AGTL+ interface. Input buffer differential amplifier to determine a high versus low input voltage. HAVREF Ref Analog Host Address input buffer VREF: Reference voltage input for the address signals of the host AGTL+ interface. This signal is connected to the input buffer differential amplifier to determine a high versus low input voltage. HCCVREF Ref Analog Host Common Clock (Command input buffer) VREF: Reference voltage input for the common clock signals of the host AGTL+ interface. This signal is connected to the input buffer differential amplifier to determine a high versus low input voltage. VTTLF Power FSB Power Supply: VTTLF is the low frequency connection from the board. This signal is the primary connection of power for GMCH. VTTHF Power FSB Power Supply: VTTHF is the high frequency supply. It is for direct connection from an internal package plane to a capacitor placed immediately adjacent to the GMCH. Note: Not to be connected to power rail. System Memory SMRCOMP Analog System Memory RCOMP: This signal is used to calibrate the memory I/O buffers. SMVREF_0 Ref Analog Memory Reference Voltage(Input buffer VREF):Reference voltage input for memory interface. Input buffer differential amplifier to determine a high versus low input voltage. SMVSWINGH Ref Analog RCOMP reference voltage: This is connected to the RCOMP buffer differential amplifier and is used to calibrate the I/O buffers. SMVSWINGL Ref Analog RCOMP reference voltage: This is connected to the RCOMP buffer differential amplifier and is used to calibrate the I/O buffers. VCCSM Power Power supply for Memory I/O. VCCQSM Power Power supply for System Memory clock buffers. VCCASM Power Power supply for System Memory logic running at the core voltage (isolated supply, not connected to the core). HLRCOMP Analog Hub Interface RCOMP: This signal is connected to a reference resistor in order to calibrate the buffers. PSWING Analog RCOMP reference voltage: This is connected to the RCOMP buffer differential amplifier and is used to calibrate the buffers. Hub Interface 42 Intel® 852GM/852GMV Chipset GMCH Datasheet Signal Description R Signal Name HLVREF VCCHL Type Description Ref Analog Input buffer VREF: Input buffer differential amplifier to determine a high versus low input voltage. Power Power supply for Hub Interface buffers Analog Compensation for DVO: This signal is used to calibrate the DVO I/O buffers. DVO DVORCOMP Analog GVREF Ref Analog Input buffer VREF: Input buffer differential amplifier to determine a high versus low input voltage. VCCDVO Power Power supply for DVO. Power Power supply for GPIO buffers GPIO VCCGPIO DAC REFSET Ref Resistor Set: Set point resistor for the internal color palette DAC. Analog VCCADAC Power Power supply for the DAC VSSADAC Power Ground supply for the DAC LIBG Analog LVDS reference current: signal connected to reference resistor. VCCDLVDS Power Digital power supply. VCCTXLVDS Power Data/Clk Tx power supply. VCCALVDS Power Analog power supply. VSSALVDS Power Ground supply for LVDS. VCCAHPLL Power Power supply for the Host PLL. VCCAGPLL Power Power supply for the Hub/DVO PLL. VCCADPLLA Power Power supply for the display PLL A. VCCADPLLB Power Power supply for the display PLL B. VCC Power Power supply for the core. VSS Power Ground supply for the chip. LVDS Clocks Core Intel® 852GM/852GMV Chipset GMCH Datasheet 43 Signal Description R This page intentionally left blank. 44 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3. Register Description 3.1. Conceptual Overview of the Platform Configuration Structure The Intel 852GM/852GMV GMCH and ICH4-M are physically connected by Hub Interface A. From a configuration standpoint, the Hub Interface A is logically PCI bus #0. As a result, all devices internal to the GMCH and ICH4-M appear to be on PCI bus #0. The system’s primary PCI expansion bus is physically attached to the ICH4-M and from a configuration perspective, appears to be a hierarchical PCI bus behind a PCI-to-PCI bridge and therefore has a programmable PCI Bus number. Note that the primary PCI bus is referred to as PCI_A in this document and is not PCI bus #0 from a configuration standpoint. The GMCH contains two PCI devices within a single physical component. The configuration registers for the two devices are mapped as devices residing on PCI bus #0. Device #0: Host-Hub Interface Bridge/DDR SDRAM Controller. Logically this appears as a PCI device residing on PCI bus #0. Physically, Device 0 contains the standard PCI registers, DDR SDRAM registers, the Graphics Aperture controller, HI control and other GMCH specific registers. Device 0 is divided into functions as follows: Function #0: Host Bridge Legacy Registers, including Graphics Aperture control, HI configuration and Interrupt control registers Function #1: DDR SDRAM Interface Registers Function #3: Intel Reserved Registers Device #2: Integrated Graphics Controller. Logically this appears as a PCI device residing on PCI bus #0. Physically Device #2 contains the configuration registers for 3D, 2D, and display functions. Table 12 shows the Device # assignment for the various internal GMCH devices. Table 12. Device Number Assignment GMCH Function Bus #0, Device# Host-Hl, DDR SDRAM I/f, Legacy control. Device #0 Integrated Graphics Controller Device #2 Intel® 852GM/852GMV Chipset GMCH Datasheet 45 Register Description R 3.2. Nomenclature for Access Attributes Table 13 provides the nomenclature for the access attributes. Table 13. Nomenclature for Access Attributes RO Read Only. If a register is read only, writes to this register have no effect. R/W Read/Write. A register with this attribute can be read and written. R/W/L Read/Write/Lock. A register with this attribute can be read, written, and Lock. R/WC Read/Write Clear. A register bit with this attribute can be read and written. However, a write of a 1 clears (sets to 0) the corresponding bit and a write of a 0 has no effect. R/WO Read/Write Once. A register bit with this attribute can be written to only once after power up. After the first write, the bit becomes read only. L Lock. A register bit with this attribute becomes Read Only after a lock bit is set. Reserved Bits Some of the GMCH registers described in this section contain reserved bits. These bits are labeled "Reserved”. Software must deal correctly with fields that are reserved. On reads, software must use appropriate masks to extract the defined bits and not rely on reserved bits being any particular value. On writes, software must ensure that the values of reserved bit positions are preserved. That is, the values of reserved bit positions must first be read, merged with the new values for other bit positions and then written back. Note the software does not need to perform read, merge, and write operation for the Configuration Address register. Reserved Registers In addition to reserved bits within a register, the GMCH contains address locations in the configuration space of the Host-Hub Interface Bridge entity that are marked either "Reserved" or “Intel Reserved”. The GMCH responds to accesses to “Reserved” address locations by completing the host cycle. When a “Reserved” register location is read, a zero value is returned. (“Reserved” registers can be 8-bit, 16-bit, or 32-bit in size). Writes to “Reserved” registers have no effect on the GMCH. Registers that are marked as “Intel Reserved” must not be modified by system software. Writes to “Intel Reserved” registers may cause system failure. Reads to “Intel Reserved” registers may return a non-zero value. Default Value upon a Reset Upon Reset, the GMCH sets all of its internal configuration registers to predetermined default states. Some register values at reset are determined by external strapping options. The default state represents the minimum functionality feature set required to successfully bringing up the system. Hence, it does not represent the optimal system configuration. It is the responsibility of the system initialization software (usually BIOS) to properly determine the DRAM configurations, operating parameters and optional system features that are applicable, and to program the GMCH registers accordingly. S SW Semaphore. A physical PCI bus #0 does not exist. The Hub Interface and the internal devices in the GMCH and ICH4-M logically constitute PCI Bus #0 to configuration software. 46 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.3. Standard PCI Bus Configuration Mechanism The PCI Bus defines a slot based “configuration space” that allows each device to contain up to eight functions with each function containing up to 256, 8-bit configuration registers. The PCI specification defines two bus cycles to access the PCI configuration space: Configuration Read and Configuration Write. Memory and I/O spaces are supported directly by the CPU. Configuration space is supported by a mapping mechanism implemented within the GMCH. The PCI 2.2 specification defines two mechanisms to access configuration space, Mechanism #1 and Mechanism #2. The GMCH supports only Mechanism #1. The configuration access mechanism makes use of the CONFIG_ADDRESS Register (at I/O address 0CF8h though 0CFBh) and CONFIG_DATA Register (at I/O address 0CFCh though 0CFFh). To reference a configuration register a Dword I/O write cycle is used to place a value into CONFIG_ADDRESS that specifies the PCI bus, the device on that bus, the function within the device, and a specific configuration register of the device function being accessed. CONFIG_ADDRESS[31] must be 1 to enable a configuration cycle. CONFIG_DATA then becomes a window into the four bytes of configuration space specified by the contents of CONFIG_ADDRESS. Any read or write to CONFIG_DATA will result in the GMCH translating the CONFIG_ADDRESS into the appropriate configuration cycle. The GMCH is responsible for translating and routing the CPU’s I/O accesses to the CONFIG_ADDRESS and CONFIG_DATA registers to internal GMCH configuration registers and Hub Interface. 3.4. Routing Configuration Accesses The GMCH supports one bus interface: the Hub Interface. PCI configuration cycles are selectively routed to this interface. The GMCH is responsible for routing PCI configuration cycles to the proper interface. PCI configuration cycles to the ICH4-M internal devices, and Primary PCI (including downstream devices) are routed to the ICH4-M via the Hub Interface. A detailed description of the mechanism for translating CPU I/O bus cycles to configuration cycles on one of the buses is described in the following section. 3.4.1. PCI Bus #0 Configuration Mechanism The GMCH decodes the Bus Number (bits 23:16) and the Device Number fields of the CONFIG_ADDRESS register. If the Bus Number field of CONFIG_ADDRESS is 0 the configuration cycle is targeting a PCI Bus #0 device. The Host-Hub Interface Bridge entity within the GMCH is hardwired as Device #0 on PCI Bus #0. Configuration cycles to any of the GMCH’s internal devices are confined to the GMCH and not sent over Hub Interface. Accesses to disabled GMCH internal devices will be forwarded over the Hub Interface as Type 0 Configuration Cycles. 3.4.2. Primary PCI and Downstream Configuration Mechanism The ICH4-M compares the non-zero Bus Number with the SECONDARY BUS NUMBER and SUBORDINATE BUS NUMBER registers of its P2P bridges to determine if the configuration cycle is meant for Primary PCI or a downstream PCI bus. Intel® 852GM/852GMV Chipset GMCH Datasheet 47 Register Description R 3.5. Register Definitions The GMCH contains four sets of software accessible registers accessed via the Host CPU I/O address space, and they are as follows: Control registers: I/O mapped into the CPU I/O space, which control access to PCI configuration space via Configuration Mechanism #1 in the PCI 2.2 specification. Internal configuration registers: residing within the GMCH, they are partitioned into two logical device register sets (“logical” since they reside within the single physical device). The first register set is dedicated to Host-HI Bridge functionality (i.e. DDR SDRAM configuration, other chip-set operating parameters and optional features). The second register block is for the integrated graphics functions. Internal Memory Mapped configuration registers: residing in GMCH Device #0. Internal Memory Mapped configuration registers and Legacy VGA registers: residing in the GMCH Device #2 that controls the Integrated Graphics Controller. The GMCH internal registers (I/O Mapped and Configuration registers) are accessible by the Host CPU. The registers can be accessed as Byte, Word (16-bit), or Dword (32-bit) quantities, with the exception of CONFIG_ADDRESS, which can only be accessed as a Dword. All multi-byte numeric fields use “littleendian” ordering (i.e., lower addresses contain the least significant parts of the field). Reserved Bits Some of the GMCH registers described in this section contain reserved bits. These bits are labeled “Reserved”. Software must deal correctly with fields that are reserved. On reads, software must use appropriate masks to extract the defined bits and not rely on reserved bits being any particular value. On writes, software must ensure that the values of reserved bit positions are preserved. That is, the values of reserved bit positions must first be read, merged with the new values for other bit positions and then written back. Note: The software does not need to perform read, merge, and write operation for the configuration address register. Default Value upon Reset Upon a full Reset, the GMCH sets all of its internal configuration registers to predetermined default states. Some register values at reset are determined by external strapping options. The default state represents the minimum functionality feature set required to successfully bring up the system. Hence, it does not represent the optimal system configuration. It is the responsibility of the system initialization software (usually BIOS) to properly determine the DDR SDRAM configurations, operating parameters, and optional system features that are applicable, and to program the GMCH registers accordingly. 48 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.6. I/O Mapped Registers The GMCH contains two registers that reside in the CPU I/O address space: the Configuration Address (CONFIG_ADDRESS) Register and the Configuration Data (CONFIG_DATA) Register. The Configuration Address Register enables/disables the configuration space and determines what portion of configuration space is visible through the Configuration Data window. 3.6.1. CONFIG_ADDRESS – Configuration Address Register I/O Address: Default Value: Access: Size: 0CF8h Accessed as a Dword 00000000h Read/Write 32 bits CONFIG_ADDRESS is a 32-bit register that can be accessed only as a Dword. A Byte or Word reference will “pass through” the Configuration Address Register and the Hub Interface, onto the PCI bus as an I/O cycle. The CONFIG_ADDRESS register contains the Bus Number, Device Number, Function Number, and Register Number for which a subsequent configuration access is intended. Figure 1. Configuration Address Register 31 30 0 24 23 R 16 15 0 11 10 0 8 7 0 0 2 1 0 Bit R Default Reserved Register Number Function Number Device Number Bus Number Reserved Enable Intel® 852GM/852GMV Chipset GMCH Datasheet 49 Register Description R Bit Descriptions 31 Configuration Enable (CFGE): When this bit is set to 1, accesses to PCI configuration space are enabled. If this bit is reset to 0, accesses to PCI configuration space are disabled. 30:24 Reserved 23:16 Bus Number: When the Bus Number is programmed to 00h the target of the Configuration Cycle is a Hub Interface agent (GMCH, ICH4-M, etc.). The Configuration Cycle is forwarded to Hub Interface if the Bus Number is programmed to 00h and the GMCH is not the target (the device number is >= 2). 15:11 Device Number: This field selects one agent on the PCI bus selected by the Bus Number. When the Bus Number field is “00” the GMCH decodes the Device Number field. The GMCH is always Device Number 0 for the Host-Hub Interface bridge entity. Therefore, when the Bus Number =0 and the Device Number=0-1 the internal GMCH devices are selected. For Bus Numbers resulting in Hub Interface configuration cycles, the GMCH propagates the device number field as A[15:11]. 50 10:8 Function Number: This field is mapped to A[10:8] during Hub Interface configuration cycles. This allows the configuration registers of a particular function in a multi-function device to be accessed. The GMCH ignores configuration cycles to its internal Devices if the function number is not equal to 0. 7:2 Register Number: This field selects one register within a particular Bus, Device, and Function as specified by the other fields in the Configuration Address Register. This field is mapped to A[7:2] during Hub Interface Configuration cycles. 1:0 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.6.2. CONFIG_DATA – Configuration Data Register I/O Address: Default Value: Access: Size: 0CFCh 00000000h Read/Write 32 bits CONFIG_DATA is a 32-bit read/write window into configuration space. The portion of configuration space that is referenced by CONFIG_DATA is determined by the contents of CONFIG_ADDRESS. Figure 2. Configuration Data Register 31 0 0 Bit Default Configuration Data Window Bit 31:0 Descriptions Configuration Data Window (CDW). If bit 31 of CONFIG_ADDRESS is 1 any I/O access that to the CONFIG_DATA register will be mapped to configuration space using the contents of CONFIG_ADDRESS. Intel® 852GM/852GMV Chipset GMCH Datasheet 51 Register Description R 3.7. VGA I/O Mapped Registers If Device 2 is enabled, and Function 0 within device 2 is enabled for VGA, and IO_EN is set within Function 0 then GMCH claims a set of I/O registers for legacy VGA function. Table 14 lists direct CPU access registers and Table 15 lists registers that are index – data registers that are used to access internal VGA register. Table 14. VGA I/O Mapped Register List Name Function Read @ Write @ ST00 VGA Input Status Register 0 3C2h ST01 VGA Input Status Register 1 3BAh/3Dah FCR VGA Feature Control Register 3CAh 3BAh/3DAh MSR VGA Miscellaneous Output Register 3CCh 3C2h Table 15. Index – Data Registers Name Function Index IO Data IO SRX Sequencer Registers 3C4 3C5 GRX Graphics Controller Registers 3CE 3CF ARX Attribute Control Registers 3C0 3C0: Write 3C1: Read DACMASK Pixel Data Mask Register -- 3C6h DACSTATE DAC State Register -- 3C7 Read Only -- DACRX Palette Read Index Register 3C7 Write Only DACWX Palette Write Index Register 3C8 Write Only DACDATA CRX 52 Palette Data Register CRT Registers 3C9 3B4/3D4 3B5/3D5 (MDA/CGA) (MDA/CGA) Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8. Intel 852GM/852GMV GMCH Host-Hub Interface Bridge Device Registers (Device #0, Function #0) Table 16 summarizes the configuration space for Device #0, Function#0. Table 16. GMCH Configuration Space - Device #0, Function#0 Register Symbol Register Start Register End Default Value Access Vendor Identification VID 00 01 8086h RO Device Identification DID 02 03 3580h RO PCI Command Register PCICMD 04 05 0006h RO,R/W PCI Status Register PCISTS 06 07 0090h RO,R/WC RID 08 08 01h RO Sub-Class Code SUBC 0A 0A 00h RO Base Class Code BCC 0B 0B 06h RO Header Type HDR 0E 0E 80h RO Subsystem Vendor Identification SVID 2C 2D 0000h R/WO SID 2E 2F 0000h R/WO CAPPTR 34 34 40h RO Capability Identification (Product Specific) CAPID 40 44 00000000A0h RO Registers-RCOMP Base Address RRBAR 48 4B 00000000h R/W, RO GMCH Misc. Control GMC 50 51 0000h R/W, RO GMCH Graphics Control GGC 52 53 0030h R/W, RO Device and Function Control Register DAFC 54 55 0000h R/W Fixed Dram Hole Control FDHC 58 58 00h R/W, RO PAM (6:0) 59 5F 00h Each R/W, RO System Management RAM Control SMRAM 60 60 02h R/W-L, RO Extended System Management RAM Control ESMRAMC 61 61 38h RO-R/WRWC-L Error Status Register ERRSTS 62 63 0000h R/WC Error Command Register ERRCMD 64 65 0000h RO, R/W SMI Command Register SMICMD 66 66 00h RO, R/W SCI Command Register SCICMD 67 67 00h RO, R/W WCC 80 83 A4000002h RO, R/W Register Name Revision Identification Subsystem Identification Capabilities Pointer Programmable Attribute MAP Write Cache Control Intel® 852GM/852GMV Chipset GMCH Datasheet 53 Register Description R Register Name Capability Disable 3.8.1. Register Symbol Register Start Register End Default Value Access CAPD F4 F7 00000000h R/W VID – Vendor Identification Address Offset: Default Value: Access: Size: 00h 8086h Read Only 16 bits The VID Register contains the vendor identification number. This 16-bit register, combined with the Device Identification Register, uniquely identifies any PCI device. Writes to this register have no effect. 3.8.2. Bit Descriptions 15:0 Vendor Identification (VID): This register field contains the PCI standard identification for Intel, 8086h. DID – Device Identification Address Offset: Default Value: Access: Size: 02h 3580h Read Only 16 bits This 16-bit register combined with the Vendor Identification register uniquely identifies any PCI device. Writes to this register have no effect. 54 Bit Descriptions 15:0 Device Identification Number (DID): This is a 16-bit value assigned to the GMCH Host-Hub Interface bridge, Device #0. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.3. PCICMD – PCI Command Register Address Offset: Default Value: Access: Size: 04h 0006h Read Only, Read/Write 16 bits Since GMCH Device #0 does not physically reside on PCI_A many of the bits are not implemented. Bit Descriptions 15:10 Reserved 9 Fast Back-to-Back Enable (FB2B): This bit controls whether or not the master can do fast back-to-back write. Since Device #0 is strictly a target this bit is not implemented and is hardwired to 0. Writes to this bit position have no affect. Default Value=0. 8 SERR Enable (SERRE): This bit is a global enable bit for Device #0 SERR messaging. The GMCH does not have an SERR# signal, but communicates the SERR# condition by sending an SERR message to the ICH4-M. 1 = Enable. GMCH is enabled to generate SERR messages over Hub Interface for specific Device 0 error conditions that are individually enabled in the ERRCMD register. The error status is reported in the ERRSTS and PCISTS registers. 0= SERR message is not generated by the GMCH for Device #0. NOTE: This bit only controls SERR messaging for the Device #0. Device #1 has its own SERRE bit to control error reporting for error conditions occurring on Device #1. The two control bits are used in a logical OR manner to enable the SERR Hub Interface message mechanism. Default Value=0. 7 Address/Data Stepping Enable (ADSTEP): Address/data stepping is not implemented in the GMCH, and this bit is hardwired to 0. Writes to this bit position have no effect. Default Value=0. 6 Parity Error Enable (PERRE): PERR# is not implemented by GMCH and this bit is hardwired to 0. Writes to this bit position have no effect. Default Value=0. 5 VGA Palette Snoop Enable (VGASNOOP): The GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value=0. 4 Memory Write and Invalidate Enable (MWIE): The GMCH will never issue memory write and invalidate commands. This bit is therefore hardwired to 0. Writes to this bit position will have no effect. Default Value=0. 3 Special Cycle Enable (SCE): The GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value=0. 2 Bus Master Enable (BME): The GMCH is always enabled as a master on HI. This bit is hardwired to a “1”. Writes to this bit position have no effect. Default Value=1. 1 Memory Access Enable (MAE): The GMCH always allows access to main System Memory. This bit is not implemented and is hardwired to 1. Writes to this bit position have no effect. Default Value=1. Intel® 852GM/852GMV Chipset GMCH Datasheet 55 Register Description R 3.8.4. Bit Descriptions 0 I/O Access Enable (IOAE): This bit is not implemented in the GMCH and is hardwired to a 0. Writes to this bit position have no effect. PCI Status Register Address Offset: Default Value: Access: Size: 06h 0090h Read Only, Read/Write/Clear 16 bits PCISTS is a 16-bit status register that reports the occurrence of error events on Device #0’s PCI interface. Bit 14 is read/write clear. All other bits are Read Only. Since GMCH Device #0 does not physically reside on PCI_A many of the bits are not implemented. Bit 15 Descriptions Detected Parity Error (DPE): The GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value=0. 14 Signaled System Error (SSE): R/WC: This bit is set to 1 when GMCH Device #0 generates an SERR message over HI for any enabled Device #0 error condition. Device #0 error conditions are enabled in the PCICMD and ERRCMD registers. Device #0 error flags are read/reset from the PCISTS or ERRSTS registers. Software sets SSE to 0 by writing a 1 to this bit. Default Value=0. 13 Received Master Abort Status (RMAS): R/WC: This bit is set when the GMCH generates a HI request that receives a Master Abort completion packet or Master Abort Special Cycle. Software clears this bit by writing a 1 to it. Default Value=0. 12 Received Target Abort Status (RTAS): R/WC: This bit is set when the GMCH generates a HI request that receives a Target Abort completion packet or Target Abort Special Cycle. Software clears this bit by writing a 1 to it. If bit 6 in the ERRCMD is set to a one and an Serr# special cycle is generated on the HL bus. Default Value=0. 11 Signaled Target Abort Status (STAS): The GMCH will not generate a Target Abort HI completion packet or Special Cycle. This bit is not implemented in the GMCH and is hardwired to a 0. Writes to this bit position have no effect. Default Value=0. 10:9 DEVSEL Timing (DEVT): These bits are hardwired to “00”. Writes to these bit positions have no affect. Device #0 does not physically connect to PCI_A. These bits are set to “00” (fast decode) so that the GMCH does not limit optimum DEVSEL timing for PCI_A. Default Value=0. 8 Master Data Parity Error Detected (DPD): PERR signaling and messaging are not implemented by the GMCH therefore this bit is hardwired to 0. Writes to this bit position have no effect. Default Value=0. 7 Fast Back-to-Back (FB2B): This bit is hardwired to 1. Writes to these bit positions have no effect. Device #0 does not physically connect to PCI_A. This bit is set to 1 (indicating fast back-to-back capability) so that the GMCH does not limit the optimum setting for PCI_A. Default Value=1. 6:5 56 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Bit 4 Descriptions Capability List (CLIST): This bit is hardwired to 1 to indicate to the configuration software that this device/function implements a list of new capabilities. A list of new capabilities is accessed via register CAPPTR at configuration address offset 34h. Default Value=1. 3:0 3.8.5. Reserved RID – Register Identification Address Offset: Default Value: Access: Size: 08h 01h Read Only 8 bits This register contains the revision number of the GMCH Device #0. These bits are read only and writes to this register have no effect. Bit 7:0 Descriptions Revision Identification Number (RID): This is an 8-bit value that indicates the revision identification number for the GMCH Device #0. Default Value=01h 3.8.6. SUBC – Sub Class Code Address Offset: Default Value: Access: Size: 0Ah 00h Read Only 8 bits This register contains the Sub-Class Code for the GMCH Device #0. This code is 00h indicating a Host Bridge device. Bit 7:0 Descriptions Sub-Class Code (SUBC): This is an 8-bit value that indicates the category of Bridge into which the GMCH falls. The code is 00h indicating a Host Bridge. Default Value=0 Intel® 852GM/852GMV Chipset GMCH Datasheet 57 Register Description R 3.8.7. BCC – Base Class Code Address Offset: Default Value: Access: Size: 0Bh 06h Read Only 8 bits This register contains the Base Class Code of the Intel 852GM/852GMV GMCH Device #0. This code is 06h indicating a Bridge device. Bit 7:0 3.8.8. Descriptions Base Class Code (BASEC): This is an 8-bit value that indicates the Base Class Code for the Intel 852GM/852GMV GMCH. This code has the value 06h, indicating a Bridge device. HDR – Header Type Address Offset: Default Value: Access: Size: 0Eh 80h Read Only 8 bits This register identifies the header layout of the configuration space. No physical register exists at this location. Bit 7:0 3.8.9. Descriptions PCI Header (HDR): This field always returns 80 to indicate that Device 0 is a multifunction device. If Functions other than 0 are disabled this field returns a 00 to indicate that the Intel 852GM/852GMV GMCH is a single function device with standard header layout. The default is 80; Writes to this location have no effect. SVID – Subsystem Vendor Identification Address Offset: Default Value: Access: Size: 2Ch 0000h Read/Write Once 16 bits This value is used to identify the vendor of the subsystem. Bit 15:0 Descriptions Subsystem Vendor ID (SUBVID): This field should be programmed during boot-up to indicate the vendor of the system board. After it has been written once, it becomes read only. Default Value=0 58 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.10. SID – Subsystem Identification Address Offset: Default Value: Access: Size: 2Eh 0000h Read/Write Once 16 bits This value is used to identify a particular subsystem. Bit 15:0 Descriptions Subsystem ID (SUBID): This field should be programmed during BIOS initialization. After it has been written once, it becomes read only. Default Value=0 3.8.11. CAPPTR – Capabilities Pointer Address Offset: Default Value: Access: Size: 34h 40h Read Only 8 bits The CAPPTR provides the offset that is the pointer to the location of the first device capability in the capability list. Bit 7:0 Descriptions Pointer to the offset of the first capability ID register block: In this case the first capability is the Product-Specific Capability, which is located at offset 40h. Intel® 852GM/852GMV Chipset GMCH Datasheet 59 Register Description R 3.8.12. CAPID Capability Identification Register (Device 0) Address Offset: Default: Access: Size 40h – 44h 0F_F105_F009h Read Only 40 bits The Capability Identification Register uniquely identifies chipset capabilities as defined in the table below. The bits in this register are intended to define a capability ceiling for each feature, not a capability select. The capability selection for each feature is implemented elsewhere. The mechanism to select the capability for each feature must comprehend these capabilities registers and not allow a selected setting above the ceiling specified in these registers. The BIOS must read this register to identify the SKU of the part and comprehend the capabilities specified within when configuring the effected portions of the GMCH. The default setting, in most cases, allows the maximum capability. Exceptions are noted in the individual bits. This register is Read Only. Writes to this register have no effect. Bit 39:37 Descriptions Capability ID [2:0]: 000-100 =reserved 101= Intel 852GM/852GMV GMCH 110-111 = reserved 36:30 29 Reserved 0 = Reserved 1 = Device #1 and associated System Memory and IO spaces are disabled. In addition, Next_Pointer = 00h, APBASE is read only, and Aperture Global Access is Disabled. 28 Reserved 27:24 CAPREG Version: This field has the value 0001b to identify the first revision of the CAPREG definition. 23:16 Cap_length: This field has the value 05h indicating the structure length. 15:8 Reserved 7:5 CAP_ID: 000 = Reserved 100 = Reserved 101 = Intel 852GM/852GMV GMCH 4:0 60 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.13. RRBAR – Register Range Base Address Register (Device 0) Address Offset: Default Value: Access: Size: 48 4Bh 00000000h Read/Write, Read Only 32 bits This register requests a 64-kB allocation for the Device registers. The base address is defined by bits 31 to 16 and can be used to access device configuration registers. Only Dword aligned writes are allowed to this space. See the table below for address map within the 64-kB space. This addressing mechanism may be used to write to registers that modify the device address map (includes all the BARs, PAMs, SMM registers, Pre-Allocated System Memory registers etc). However, before using or allowing the use of the modified address map the bios must synchronize using an IO or Read cycle. Note: The GTLB cannot be enabled/disabled using this mechanism. Bit Description 31:16 Memory Base Address—R/W: Set by the OS, these bits correspond to address signals [31:16]. 15:0 Reserved Address Range 0000h to FFFFh Space Description Sub Ranges 0000h to 00FFh Read/Write (As in Configuration Space): Maps to 00–FFh of Device 0, Function 0 register space. 0100h to 01FFh Read/Write (As in Configuration Space): Maps to 00–FFh of Device 0, Function 1 register space. 0200h to 02FFh Reserved 0300h to 03FFh Read/Write (As in Configuration Space): Maps to 00–FFh of Device 0, Function 3 register space. 0400h to 07FFh Reserved 0800h to 08FFh Read/Write (As in Configuration Space): Maps to 00–FFh of Device 1, Function 0 register space. 0900h to 0FFFh Reserved 1000h to 10FFh Read/Write (As in Configuration Space): Maps to 00–FFh of Device 2, Function 0 register space. 1100h to 11FFh Read/Write (As in Configuration Space): Maps to 00–FFh of Device 2, Function 1 register space. 1200h to 7FFFh Reserved 8000h to 8FFFh System Memory RCOMP memory Range. 9000h to FFFFh Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 61 Register Description R 3.8.14. GMC – GMCH Miscellaneous Control Register (Device 0) Address Offset: Default Value: Access: Size: 50–51h 0000h Read/Write, Read Only 16 bits Bit Descriptions 15:10 Reserved 9 Reserved 8 RRBAR Access Enable—R/W: 1 = Enables the RRBAR space. 0 = Disable 7:1 Reserved 0 MDA Present (MDAP)—R/W: This bit should not be set when the VGA Enable bit is not set. If the VGA enable bit is set, then accesses to IO address range x3BCh–x3BFh are forwarded to Hub Interface. If the VGA enable bit is not set then accesses to IO address range x3BCh–x3BFh are treated just like any other IO accesses. MDA resources are defined as the following: Memory: 0B0000h – 0B7FFFh I/O: 3B4h, 3B5h, 3B8h, 3B9h, 3BAh, 3BFh, (including ISA address aliases, A[15:10] are not used in decode) Any I/O reference that includes the I/O locations listed above, or their aliases, will be forwarded to Hub Interface even if the reference includes I/O locations not listed above. The following table shows the behavior for all combinations of MDA and VGA: VGA MDA Behavior 0 0 All References to MDA and VGA go to Hub Interface (Default) 0 1 Reserved 1 0 All References to VGA go to PCI. MDA-only references (I/O address 3BF and aliases) will go to Hub Interface. 1 1 VGA References go to PCI; MDA References go to Hub Interface 62 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.15. GGC – GMCH Graphics Control Register (Device 0) Address Offset: Default Value: Access: Size: Bit 52–53h 0030h Read/Write, Read Only 16 bits Descriptions 15:7 Reserved 6:4 Graphics Mode Select (GMS): This field is used to select the amount of Main System Memory that is preallocated to support the Internal Graphics Device in VGA (non-linear) and Native (linear) modes. The BIOS ensures that System Memory is pre-allocated only when Internal Graphics is enabled. 000 = No System Memory pre-allocated. Device #2 (IGD) does not claim VGA cycles (Mem and IO), and the Sub-Class Code field within Device #2 Function #0 Class Code register is 80. 001 = DVMT (UMA) mode, 1 MB of System Memory pre-allocated for frame buffer. 010 = DVMT (UMA) mode, 4 MB of System Memory pre-allocated for frame buffer. 011 = DVMT (UMA) mode, 8 MB of System Memory pre-allocated for frame buffer. 100 = DVMT (UMA) mode, 16 MB of System Memory pre-allocated for frame buffer. 101 = DVMT (UMA) mode, 32 MB of System Memory pre-allocated for frame buffer. All other combinations reserved. 3:2 Reserved 1 IGD VGA Disable (IVD): 1 = Disable. Device #2 (IGD) does not claim VGA cycles (Mem and IO), and the Sub-Class Code field within Device #2 Function #0 Class Code register is 80. 0 = Enable (Default). Device #2 (IGD) claims VGA memory and IO cycles, the Sub-Class Code within Device #2 Class Code register is 00. 0 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 63 Register Description R 3.8.16. DAFC – Device and Function Control Register (Device 0) Address Offset: Default Value: Access: Size: 54–55h 0000h Read/Write 16 bits This 16-bit register controls the visibility of devices and functions within the GMCH to configurations software. Bit Description 15:8 Reserved 7 Device #2 Disable: 1 = Disabled. 0 = Enabled. 6:3 Reserved 2 Device #0 Function #3 Disable. 1 = Disable Function #3 registers within Device #0 and all associated DDR SDRAM and I/O ranges. 0 = Default is #0, Function #1 within Device #0 is enabled. 1 Reserved 0 Device #0 Function #1 Disable: 1 = Disable Function #1 within Device #0. 0 = Default is 0, Function #1 within Device #0 is enabled. 3.8.17. FDHC – Fixed DRAM Hole Control Register (Device 0) Address Offset: Default Value: Access: Size: 58h 00h Read/Write 8 bits This 8-bit register controls a single fixed DDR SDRAM hole: 15–16 MB. Bit 7 Description Hole Enable (HEN): This field enables a memory hole in DDR SDRAM space. Host cycles matching an enabled hole are passed on to ICH4-M through Hub Interface. The Intel 852GM/852GMV GMCH will ignore Hub Interface cycles matching an enabled hole. NOTE: A selected hole is not re-mapped. 0 = None 1 = 15 MB–16 MB (1MBs) 6:0 64 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.18. PAM(6:0) – Programmable Attribute Map Register (Device 0) Address Offset: Default Value: Attribute: Size: 59–5Fh 00h Each Read/Write 4 bits/register, 14 registers The Intel 852GM/852GMV GMCH allows programmable DDR SDRAM attributes on 13 Legacy System Memory segments of various sizes in the 640 kB –1 MB address range. Seven Programmable Attribute Map (PAM) Registers are used to support these features. Cacheability of these areas is controlled via the MTRR registers in the P6 processor. Two bits are used to specify System Memory attributes for each System Memory segment. These bits apply to both host and Hub Interface initiator accesses to the PAM areas. These attributes are: RE - Read Enable. When RE = 1, the CPU read accesses to the corresponding System Memory segment are claimed by the Intel 852GM/852GMV GMCH and directed to main System Memory. Conversely, when RE = 0, the host read accesses are directed to PCI0. WE - Write Enable. When WE = 1, the host write accesses to the corresponding System Memory segment are claimed by the Intel 852GM/852GMV GMCH and directed to main System Memory. Conversely, when WE = 0, the host write accesses are directed to PCI0. The RE and WE attributes permit a System Memory segment to be Read Only, Write Only, Read/Write, or disabled. For example, if a System Memory segment has RE = 1 and WE = 0, the segment is Read Only. Each PAM Register controls two regions, typically 16 kB in size. Each of these regions has a 4-bit field. The four bits that control each region have the same encoding and are defined in the following table. Intel® 852GM/852GMV Chipset GMCH Datasheet 65 Register Description R Table 17. Attribute Bit Assignment Bits [7, 3] Reserved Bits [6, 2] Reserved Bits [5, 1] WE Bits [4, 0] RE Description X X 0 0 Disabled. DDR SDRAM is disabled and all accesses are directed to Hub Interface. The Intel 852GM/852GMV GMCH does not respond as a Hub Interface target for any read or write access to this area. X X 0 1 Read Only. Reads are forwarded to DDR SDRAM and writes are forwarded to Hub Interface for termination. This write protects the corresponding DDR SDRAM segment. The Intel 852GM/852GMV GMCH will respond as a Hub Interface target for read accesses but not for any write accesses. X X 1 0 Write Only. Writes are forwarded to DDR SDRAM and reads are forwarded to the Hub Interface for termination. The Intel 852GM/852GMV GMCH will respond as a Hub Interface target for write accesses but not for any read accesses. X X 1 1 Read/Write. This is the normal operating mode of main System Memory. Both read and write cycles from the host are claimed by the Intel 852GM/852GMV GMCH and forwarded to DDR SDRAM. The Intel 852GM/852GMV GMCH will respond as a Hub Interface target for both read and write accesses. As an example, consider a BIOS that is implemented on the expansion bus. During the initialization process, the BIOS can be shadowed in main System Memory to increase the system performance. When BIOS is shadowed in main System Memory, it should be copied to the same address location. To shadow the BIOS, the attributes for that address range should be set to write only. The BIOS is shadowed by first doing a read of that address. This read is forwarded to the expansion bus. The host then does a write of the same address, which is directed to main System Memory. After the BIOS is shadowed, the attributes for that System Memory area are set to read only so that all writes are forwarded to the expansion bus. Figure 3 and Table 18 show the PAM registers and the associated attribute bits. 66 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Figure 3. PAM Registers O ffset PAM6 5Fh PAM5 5E h PAM4 5D h PAM3 5C h PAM2 5B h PAM1 5A h PAM0 59h 7 6 5 4 3 2 1 0 R R WE RE R R WE RE R ead E nable (R /W ) 1=E nable 0=D isable R eserved R eserved W rite E nable (R /W ) 1=E nable 0=D isable W rite E nable (R /W ) 1=E nable 0=D isable R ead E nable (R /W ) 1=E nable 0=D isable R eserved R eserved pam Table 18. PAM Registers and Associated System Memory Segments PAM Reg Attribute Bits System Memory Segment PAM0[3:0] Comments Offset 59h Reserved PAM0[7:4] R R WE RE 0F0000h–0FFFFFh BIOS Area 59h PAM1[3:0] R R WE RE 0C0000h–0C3FFFh ISA Add-on BIOS 5Ah PAM1[7:4] R R WE RE 0C4000h–0C7FFFh ISA Add-on BIOS 5Ah PAM2[3:0] R R WE RE 0C8000h–0CBFFFh ISA Add-on BIOS 5Bh PAM2[7:4] R R WE RE 0CC000h–0CFFFFh ISA Add-on BIOS 5Bh PAM3[3:0] R R WE RE 0D0000h–0D3FFFh ISA Add-on BIOS 5Ch PAM3[7:4] R R WE RE 0D4000h–0D7FFFh ISA Add-on BIOS 5Ch PAM4[3:0] R R WE RE 0D8000h–0DBFFFh ISA Add-on BIOS 5Dh PAM4[7:4] R R WE RE 0DC000h–0DFFFFh ISA Add-on BIOS 5Dh PAM5[3:0] R R WE RE 0E0000h–0E3FFFh BIOS Extension 5Eh PAM5[7:4] R R WE RE 0E4000h–0E7FFFh BIOS Extension 5Eh PAM6[3:0] R R WE RE 0E8000h–0EBFFFh BIOS Extension 5Fh PAM6[7:4] R R WE RE 0EC000h–0EFFFFh BIOS Extension 5Fh For details on overall system address mapping scheme see the Address Decoding section of this document. Intel® 852GM/852GMV Chipset GMCH Datasheet 67 Register Description R DOS Application Area (00000h–9FFFh) The DOS area is 640 kB in size and it is further divided into two parts. The 512-kB area at 0 to 7FFFFh is always mapped to the main System Memory controlled by the Intel 852GM/852GMV GMCH, while the 128-kB address range from 080000 to 09FFFFh can be mapped to PCI0 or to main DDR SDRAM. By default this range is mapped to main System Memory and can be declared as a main System Memory hole (accesses forwarded to PCI0) via Intel 852GM/852GMV GMCH’s FDHC configuration register. Video Buffer Area (A0000h–BFFFFh) Attribute bits do not control this 128-kB area. The host -initiated cycles in this region are always forwarded to either PCI0 or PCI2 unless this range is accessed in SMM mode. Routing of accesses is controlled by the Legacy VGA control mechanism of the “virtual” PCI-PCI bridge device embedded within the Intel 852GM/852GMV GMCH. This area can be programmed as SMM area via the SMRAM register. When used as an SMM space, this range can not be accessed from Hub Interface. Expansion Area (C0000h–DFFFFh) This 128-kB area is divided into eight 16-kB segments that can be assigned with different attributes via PAM control register as defined in table 17 and table 18. Extended System BIOS Area (E0000h–EFFFFh) This 64-kB area is divided into four 16-kB segments that can be assigned with different attributes via PAM control register as defined in table 17 and table 18. System BIOS Area (F0000h–FFFFFh) This area is a single 64-kB segment that can be assigned with different attributes via PAM control register as defined in table 17 and table 18. 68 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.19. SMRAM – System Management RAM Ctrl Register (Device 0) Address Offset: Default Value: Access: Size: 60h 02h Read/Write/Lock, Read Only 8 bits The SMRAM register controls how accesses to Compatible and Extended SMRAM spaces are treated. The Open, Close, and Lock bits function only when G_SMRAME bit is set to a 1. Also, the Open bit must be reset before the LOCK bit is set. Bit Description 7 Reserved 6 SMM Space Open (D_OPEN): When D_OPEN=1 and D_LCK=0, the SMM space DDR SDRAM is made visible even when SMM decode is not active. This is intended to help BIOS initialize SMM space. Software should ensure that D_OPEN=1 and D_CLS=1 are not set at the same time. When D_LCK is set to a 1, D_OPEN is reset to 0 and becomes read only. 5 SMM Space Closed (D_CLS): When D_CLS = 1 SMM space DDR SDRAM is not accessible to data references, even if SMM decode is active. Code references may still access SMM space DDR SDRAM. This will allow SMM software to reference “through” SMM space to update the display even when SMM is mapped over the VGA range. Software should ensure that D_OPEN=1 and D_CLS=1 are not set at the same time. D_CLS applies to all SMM spaces (Cseg, Hseg, and Tseg). 4 SMM Space Locked (D_LCK): When D_LCK is set to 1 then D_OPEN is reset to 0 and D_LCK, D_OPEN, G_SMRAME, C_BASE_SEG, GMS, DRB, DRA, H_SMRAM_EN, TSEG_SZ and TSEG_EN become read only. D_LCK can be set to 1 via a normal configuration space write but can only be cleared by a Full Reset. The combination of D_LCK and D_OPEN provide convenience with security. The BIOS can use the D_OPEN function to initialize SMM space and then use D_LCK to “lock down” SMM space in the future so that no application software (or BIOS itself) can violate the integrity of SMM space, even if the program has knowledge of the D_OPEN function. 3 Global SMRAM Enable (G_SMRAME): If set to a 1, then Compatible SMRAM functions is enabled, providing 128 kB of DRAM accessible at the A0000h address while in SMM (ADS# with SMM decode). To enable Extended SMRAM function this bit has be set to 1. Refer to the section on SMM for more details. Once D_LCK is set, this bit becomes read only. 2:0 Compatible SMM Space Base Segment (C_BASE_SEG)—RO: This field indicates the location of SMM space. “SMM DRAM” is not remapped. It is simply “made visible” if the conditions are right to access SMM space, otherwise the access is forwarded to Hub Interface. C_BASE_SEG is hardwired to 010 to indicate that the Intel 852GM/852GMV GMCH supports the SMM space at A0000h–BFFFFh. Intel® 852GM/852GMV Chipset GMCH Datasheet 69 Register Description R 3.8.20. ESMRAMC – Extended System Management RAM Control (Device 0) Address Offset: Default Value: Access: Size: 61h 38h Read/Write 8 bits The Extended SMRAM register controls the configuration of Extended SMRAM space. The Extended SMRAM (E_SMRAM) memory provides a write-back cacheable SMRAM memory space that is above 1 MB. Bit 7 Description H_SMRAM_EN (H_SMRAME): Controls the SMM memory space location (i.e., above 1 MB or below 1 MB). When G_SMRAME is 1 and H_SMRAME this bit is set to 1, the high SMRAM memory space is enabled. SMRAM accesses from 0FEDA0000h to 0FEDBFFFFh are remapped to DDR SDRAM address 000A0000h to 000BFFFFh. Once D_LCK is set, this bit becomes read only. 6 E_SMRAM_ERR (E_SMERR): This bit is set when CPU accesses the defined DDR SDRAM ranges in Extended SMRAM (High System Memory and T-segment) while not in SMM space. It is software’s responsibility to clear this bit. The software must write a 1 to this bit to clear it. 5 SMRAM_Cache (SM_CACHE): Intel 852GM/852GMV GMCH forces this bit to 1. 4 SMRAM_L1_EN (SM_L1): Intel 852GM/852GMV GMCH forces this bit to 1. 3 SMRAM_L2_EN (SM_L2): Intel 852GM/852GMV GMCH forces this bit to 1. 2:1 Reserved 0 TSEG_EN (T_EN): Enabling of SMRAM memory (TSEG, 1 Mbytes of additional SMRAM memory) for Extended SMRAM space only. When G_SMRAME =1 and TSEG_EN = 1, the TSEG is enabled to appear in the appropriate physical address space. Once D_LCK is set, this bit becomes read only. 70 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.21. ERRSTS – Error Status Register (Device 0) Address Offset: Default Value: Access: Size: 62–63h 0000h Read/Write Clear 16 bits This register is used to report various error conditions via Hub Interface special cycles. An SERR, SMI, or SCI Error Hub Interface special cycle may be generated on a zero to one transition of any of these flags when enabled in the PCICMD/ERRCMD, SMICMD, or SCICMD registers respectively. Bit Description 15:14 Reserved 13 FSB Strobe Glitch Detected (FSBAGL): When this bit is set to 1 the Intel 852GM/852GMV GMCH has detected a glitch on one of the FSB strobes. Writing a 1 to it clears this bit. 12 Intel 852GM/852GMV GMCH Software Generated Event for SMI: 1 = This indicates the source of the SMI was a Device #2 Software Event. 0 = Software must write a 1 to clear this bit. 11 Intel 852GM/852GMV GMCH Thermal Sensor Event for SMI/SCI/SERR: 1 = Indicates that a Intel 852GM/852GMV GMCH Thermal Sensor trip has occurred and an SMI, SCI or SERR has been generated. Note that the status bit is set only if a message is sent based on Thermal event enables in Error command, SMI command and SCI command registers. Note that a trip point can generate one of SMI. SCI or SERR interrupts (two or more per event is illegal). Multiple trip points can generate the same interrupt, if software chooses this mode subsequent trips may be lost. 0 = Software must write a 1 to clear this status bit. If this bit is set then an interrupt message will not be sent on a new thermal sensor event. 10 Reserved 9 LOCK to non-DDR SDRAM Memory Flag (LCKF)—R/WC: 1 = Indicates that a CPU initiated LOCK cycle targeting non-DDR SDRAM memory space occurred. 0 = Software must write a 1 to clear this status bit 8 Received Refresh Timeout—R/WC: 1 = This bit is set when 1024 memory core refresh are Queued up. 0 = Software must write a 1 to clear this status bit. 7 DRAM Throttle Flag (DTF)—R/WC: 1 = Indicates that the DDR SDRAM Throttling condition occurred. 0 = Software must write a 1 to clear this status bit. 6 Reserved 5 Received Unimplemented Special Cycle Hub Interface Completion Packet FLAG (UNSC)—R/WC: 1 = Indicates that the Intel 852GM/852GMV GMCH initiated a Hub Interface request that was terminated with an Unimplemented Special Cycle completion packet. 0 = Software must write a 1 to clear this status bit. 4:0 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 71 Register Description R 3.8.22. ERRCMD – Error Command Register (Device 0) Address Offset: Default Value: Access: Size: 64–65h 0000h Read/Write 16 bits This register enables various errors to generate a SERR Hub Interface special cycle. Since the Intel 852GM/852GMV GMCH does not have a SERR# signal, SERR messages are passed from the Intel 852GM/852GMV GMCH to the ICH4-M over Hub Interface. The actual generation of the SERR message is globally enabled for Device #0 via the PCI Command register. Note: An error can generate one and only one Hub Interface error special cycle. It is software’s responsibility to make sure that when an SERR error message is enabled for an error condition, SMI and SCI error messages are disabled for that same error condition. Bit Description 15:14 Reserved 13 SERR on FSB Strobe Glitch : When this bit is asserted, the Intel 852GM/852GMV GMCH will generate a HI SERR message when a glitch is detected on one of the FSB Strobes. 12 Reserved 11 SERR on Intel 852GM/852GMV GMCH Thermal Sensor Event: 1 = The Intel 852GM/852GMV GMCH generates a SERR Hub Interface special cycle on a thermal sensor trip that requires an SERR. The SERR must not be enabled at the same time as the SMI/SCI for a thermal sensor trip event. 0 = Software must write a 1 to clear this status bit. 10 Reserved 9 SERR on LOCK to non-DDR SDRAM Memory: 1 = The Intel 852GM/852GMV GMCH generates an SERR Hub Interface special cycle when a CPU initiated LOCK transaction targeting non-DDR SDRAM memory space occurs. 0 = Disable. Reporting of this condition is disabled. 8 SERR on DDR SDRAM Refresh timeout: 1 = The Intel 852GM/852GMV GMCH generates an SERR Hub Interface special cycle when a DDR SDRAM Refresh timeout occurs. 0 = Disable. Reporting of this condition is disabled. 7 SERR on DDR SDRAM Throttle Condition: 1 = The Intel 852GM/852GMV GMCH generates an SERR Hub Interface special cycle when a DDR SDRAM Read or Write Throttle condition occurs. 0 = Disable. Reporting of this condition is disabled. 6 SERR on Receiving Target Abort on Hub Interface: 1 = The Intel 852GM/852GMV GMCH generates an SERR Hub Interface special cycle when an Intel 852GM/852GMV GMCH originated Hub Interface cycle is terminated with a Target Abort. 0 = Disable. Reporting of this condition is disabled. 72 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Bit 5 Description SERR on Receiving Unimplemented Special Cycle Hub Interface Completion Packet: 1 = The Intel 852GM/852GMV GMCH generates an SERR Hub Interface special cycle when an Intel 852GM/852GMV GMCH initiated Hub Interface request is terminated with a Unimplemented Special Cycle completion packet. 0 = Disable. Reporting of this condition is disabled. 4:2 Reserved 1 SERR on Multiple-bit ECC Error: 1 = Reserved 0 = For systems that do not support ECC, this field must be set to 0 (Intel 852GM/852GMV GMCH only). 0 SERR on Single-bit ECC Error: 1 = Reserved 0 = For systems that do not support ECC, this field must be set to 0 (Intel 852GM/852GMV GMCH only). Intel® 852GM/852GMV Chipset GMCH Datasheet 73 Register Description R 3.8.23. SMICMD – SMI Error Command Register (Device 0) Address Offset: Default Value: Access: Size: 66h 00h Read/Write 8 bits This register enables various errors to generate an SMI Hub Interface special cycle. When an error flag is set in the ERRSTS register it can generate a SERR, SMI, or SCI Hub Interface special cycle when enabled in the ERRCMD, SMICMD, or SCICMD registers respectively. Note: An error can generate one and only one Hub Interface error special cycle. It is software’s responsibility to make sure that when an SMI error message is enabled for an error condition, SERR and SCI error messages are disabled for that same error condition. Bit 7:4 3 Description Reserved SMI on Intel 852GM/852GMV GMCH Thermal Sensor Trip: 1 = An SMI Hub Interface special cycle is generated by Intel 852GM/852GMV GMCH when the thermal sensor trip requires an SMI. A thermal sensor trip point cannot generate more than one special cycle. 2 Reserved 1 SMI on Multiple-bit ECC Error: 1 = Reserved 0 = For systems that do not support ECC, this field must be set to 0(Intel 852GM/852GMV GMCH only). 0 SMI on Single-bit ECC Error: 1 = Reserved 0 = For systems that do not support ECC, this field must be set to 0 (Intel 852GM/852GMV GMCH only). 74 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.8.24. SCICMD – SCI Error Command Register (Device 0) Address Offset: Default Value: Access: Size: 67h 00h Read/Write 8 bits This register enables various errors to generate a SCI Hub Interface special cycle. When an error flag is set in the ERRSTS register it can generate a SERR, SMI, or SCI Hub Interface special cycle when enabled in the ERRCMD, SMICMD, or SCICMD registers respectively. Note: An error can generate one and only one Hub Interface error special cycle. It is software’s responsibility to make sure that when an SCI error message is enabled for an error condition, SERR and SMI error messages are disabled for that same error condition. Bit Description 7:4 Reserved 3 SCI on Intel 852GM/852GMV GMCH Thermal Sensor Trip: 1 = An SCI Hub Interface special cycle is generated by Intel 852GM/852GMV GMCH when the thermal sensor trip requires an SCI. A thermal sensor trip point cannot generate more than one special cycle. 2 Reserved 1 SCI on Multiple-bit ECC Error: 1 = Reserved 0 = For systems that do not support ECC, this field must be set to 0 (Intel 852GM/852GMV GMCH only). 0 SCI on Single-bit ECC Error: 1 = Reserved 0 = For systems that do not support ECC, this field must be set to 0 (Intel 852GM/852GMV GMCH only). 3.8.25. CAPD – Capability Disable Bits Address Offset: Default Value: Access: Size: Bit F4h-F7h 00000000h Read/Write 32 bits Descriptions 31:12 Reserved 11:0 Capability Disable bits corresponding to Capability Register 39:28. This bit is logically ORed with the corresponding strap and result of the “OR” is read through the capability register. Note that this register cannot be used to enhance capability. 0 = Normal Operation. 1 = Forces Corresponding Capability to be disabled. Intel® 852GM/852GMV Chipset GMCH Datasheet 75 Register Description R 3.9. Intel 852GM/852GMV GMCH Main Memory Control, Memory I/O Control Registers (Device #0, Function #1) The following table shows the Intel 852GM/852GMV GMCH configuration space for Device #0, Function #1. See Section 3.2 for access nomenclature. Table 19. Host-Hub I/F Bridge/System Memory Controller Configuration Space (Device #0, Function#1) 76 Register Name Register Symbol Register Start Register End Default Value Access Vendor Identification VID 00 01 8086h RO Device Identification DID 02 03 3584h RO PCI Command Register PCICMD 04 05 0006h RO R/W PCI Status Register PCISTS 06 07 0080h RO R/WC Revision Identification RID 08 08 01h RO Sub-Class Code SUBC 0A 0A 80h RO Base Class Code BCC 0B 0B 08h RO Header Type HDR 0E 0E 00h RO Subsystem Vendor Identification SVID 2C 2D 0000h R/WO Subsystem Identification SID 2E 2F 0000h R/WO Capabilities Pointer CAPPTR 34 34 00h RO DRAM Row 0-3 Boundaries DRB 0-3 40 43 00000000h RW DRAM Row 0-3 Attributes DRA 0-3 50 51 7777h RW DRAM Timing Register DRT 60 63 18004425h RW DRAM Controller Power Management Control Register PWRMG 68 6B 00000000h R/W Dram Controller Mode DRC 70 73 00000081h R/W DRAM Throttle Control DTC A0 A3 00000000h R/W/L Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.9.1. VID – Vendor Identification Address Offset: Default Value: Access: Size: 00h 8086h Read Only 16 bits The VID Register contains the vendor identification number. This 16-bit register combined with the Device Identification Register uniquely identifies any PCI device. Writes to this register have no effect. Bit 15:0 3.9.2. Descriptions Vendor Identification (VID): This register field contains the PCI standard identification for Intel, 8086h. DID – Device Identification Address Offset: Default Value: Access: Size: 02h 3584h Read Only 16 bits This 16-bit register combined with the Vendor Identification register uniquely identifies any PCI device. Writes to this register have no effect. Bit 15:0 Descriptions Device Identification Number (DID): This is a 16-bit value assigned to the Intel 852GM/852GMV GMCH Host– HI Bridge Function #1. Device ID Product 00 = Intel 852GM/852GMV GMCH 01-11 = Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet Device ID 0x3584 77 Register Description R 3.9.3. PCICMD – PCI Command Register Address Offset: Default Value: Access: Size: 04h 0006h Read Only, Read/Write 16 bits Since Intel 852GM/852GMV Chipset Device #0 does not physically reside on PCI_A, many of the bits are not implemented. Bit Descriptions 15:10 Reserved 9 Fast Back-to-Back Enable (FB2B): This bit controls whether or not the master can do fast back-to-back write. Since Device #0 is strictly a target this bit is not implemented and is hardwired to 0. Writes to this bit position have no affect. Default Value= 0 8 SERR Enable (SERRE): SERR# is not implemented by Function #1 of Device #0 of the Intel 852GM/852GMV GMCH and this bit is hardwired to 0. Writes to this bit position have no effect. Default Value = 0 7 Address/Data Stepping Enable (ADSTEP): Address/data stepping is not implemented in the Intel 852GM/852GMV GMCH, and this bit is hardwired to 0. Writes to this bit position have no effect. Default Value = 0 6 Parity Error Enable (PERRE): PERR# is not implemented by Intel 852GM/852GMV GMCH and this bit is hardwired to 0. Writes to this bit position have no effect. Default Value = 0 5 VGA Palette Snoop Enable (VGASNOOP): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 4 Memory Write and Invalidate Enable (MWIE): The Intel 852GM/852GMV GMCH will never issue memory write and invalidate commands. This bit is therefore hardwired to 0. Writes to this bit position will have no effect. Default Value = 0 3 Special Cycle Enable (SCE): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 2 Bus Master Enable (BME): The Intel 852GM/852GMV GMCH is always enabled as a master on HI. This bit is hardwired to a “1”. Writes to this bit position have no effect. Default Value = 1 1 Memory Access Enable (MAE): The Intel 852GM/852GMV GMCH always allows access to main System Memory. This bit is not implemented and is hardwired to 1. Writes to this bit position have no effect. Default Value = 1 0 I/O Access Enable (IOAE): This bit is not implemented in the Intel 852GM/852GMV GMCH and is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 78 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.9.4. PCISTS – PCI Status Register Address Offset: Default Value: Access: Size: 06h 0080h Read Only, Read/Write/Clear 16 bits PCISTS is a 16-bit status register that reports the occurrence of error events on Device #0’s PCI interface. Bit 14 is read/write clear. All other bits are Read Only. Since Intel 852GM/852GMV GMCH Device #0 does not physically reside on PCI_A, many of the bits are not implemented. Bit 15 Descriptions Detected Parity Error (DPE): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 14 Signaled System Error (SSE): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 13 Received Master Abort Status (RMAS): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 12 Received Target Abort Status (RTAS): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 11 Signaled Target Abort Status (STAS): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 10:9 DEVSEL Timing (DEVT): These bits are hardwired to “00”. Writes to these bit positions have no affect. Device 0 does not physically connect to PCI_A. These bits are set to “00” (fast decode) so that the Intel 852GM/852GMV GMCH does not limit optimum DEVSEL timing for PCI_A. Default Value = 0 8 Master Data Parity Error Detected (DPD): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. Default Value = 0 7 Fast Back-to-Back (FB2B): This bit is hardwired to 1. Writes to these bit positions have no effect. Device 0 does not physically connect to PCI_A. This bit is set to 1 (indicating fast back-to-back capability) so that the Intel 852GM/852GMV GMCH does not limit the optimum setting for PCI_A. Default Value = 1 6:5 Reserved 4 Capability List (CLIST): This bit is hardwired to 0 to indicate to the configuration software that this device/function does not implement new capabilities. Default Value = 0 3:0 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 79 Register Description R 3.9.5. RID – Revision Identification Address Offset: Default Value: Access: Size: 08h 01h Read Only 8 bits This register contains the revision number of the Intel 852GM/852GMV GMCH Device #0. These bits are read only and writes to this register have no effect. Bit 7:0 3.9.6. Descriptions Revision Identification Number (RID): This is an 8-bit value that indicates the revision identification number for the Intel 852GM/852GMV GMCH Device #0. SUBC – Sub-Class Code Address Offset: Default Value: Access: Size: 0Ah 80h Read Only 8 bits This register contains the Sub-Class Code for the Intel 852GM/852GMV GMCH Device #0. This code is 80h indicating Other Peripheral device. 3.9.7. Bit Descriptions 7:0 Sub-Class Code (SUBC): This is an 8-bit value that indicates the category of Peripheral device into which the Intel 852GM/852GMV GMCH Function #1 falls. The code is 80h indicating Other Peripheral device. BCC – Base Class Code Address Offset: Default Value: Access: Size: 0Bh 08h Read Only 8 bits This register contains the Base Class Code of the Intel 852GM/852GMV GMCH Device #0 Function #1. This code is 08h indicating Other Peripheral device. Bit 7:0 80 Descriptions Base Class Code (BASEC): This is an 8-bit value that indicates the Base Class Code for the Intel 852GM/852GMV GMCH. This code has the value 08h, indicating Other Peripheral device. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.9.8. HDR – Header Type Address Offset: Default Value: Access: Size: 0Eh 80h Read Only 8 bits This register identifies the header layout of the configuration space. No physical register exists at this location. Bit 7:0 3.9.9. Descriptions PCI Header (HDR): This field always returns 80 to indicate that Device #0 is a multifunction device. The default is 80 Reads and writes to this location have no effect. SVID – Subsystem Vendor Identification Address Offset: Default Value: Access: Size: 2Ch 0000h Write Once 16 bits This value is used to identify the vendor of the subsystem. Bit 15:0 3.9.10. Descriptions Subsystem Vendor ID (SUBVID): This field should be programmed during boot-up to indicate the vendor of the system board. After it has been written once, it becomes read only. SID – Subsystem Identification Address Offset: Default Value: Access: Size: 2Eh 0000h Write Once 16 bits This value is used to identify a particular subsystem. Bit 15:0 Descriptions Subsystem ID (SUBID): This field should be programmed during BIOS initialization. After it has been written once, it becomes read only. Intel® 852GM/852GMV Chipset GMCH Datasheet 81 Register Description R 3.9.11. CAPPTR – Capabilities Pointer Address Offset: Default Value: Access: Size: 34h 00h Read Only 8 bits The CAPPTR provides the offset that is the pointer to the location of the first device capability in the capability list. Bit 7:0 3.9.12. Descriptions Pointer to the offset of the first capability ID register block: In this case there are no capabilities, therefore these bits are hardwired to 00h to indicate the end of the capability linked list. DRB – DRAM Row Boundary Register - Device #0 Address Offset: Default Value: Access: Size: 40-43h 00h Each Read/Write 8 bits The DDR SDRAM Row Boundary Register defines the upper boundary address of each DDR SDRAM row with a granularity of 32-MB. Each row has its own single-byte DRB register. For example, a value of 1 in DRB0 indicates that 32-MB of DDR SDRAM has been populated in the first row. Since Intel 852GM/852GMV GMCH supports a total of 4 rows of System Memory, DRB0-3 are used. The registers from 44h-4Fh are reserved for DRBs 4-15. Row0:40h Row1:41h Row2:42h Row3:43h 44h to 4F is reserved. DRB0 DRB1 DRB2 DRB3 = Total System Memory in row0 (in 32 -MB increments) = Total System Memory in row0 + row1 (in 32 -MB increments) = Total System Memory in row0 + row1 + row2 (in 32 -MB increments) = Total System Memory in row0 + row1 + row2 + row3 (in 32- MB increments) Each Row is represented by a byte. Each byte has the following format. Bit 7:0 82 Description DDR SDRAM Row Boundary Address: This 8-bit value defines the upper and lower addresses for each DDR SDRAM row. This 8-bit value is compared against a set of address lines to determine the upper address limit of a particular row. Also the minimum System Memory supported is 64-MB in 64-Mb granularity; hence bit 0 of this register must be programmed to a zero. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.9.13. DRA – DRAM Row Attribute Register - Device #0 Address Offset: Default Value: Access: Size: 50-51h 77h Each Read/Write 8 bits The DDR SDRAM Row Attribute Register defines the page sizes to be used when accessing different pairs of rows. Each nibble of information in the DRA registers describes the page size of a pair of rows: Row0, 1: 50h Row2, 3: 51h 52h-5Fh: Reserved. 7 6 4 R 7 Row attribute for Row1 6 4 R Row attribute for Row3 Bit 3 R 2 3 R 2 0 Row Attribute for Row0 0 Row Attribute for Row2 Description 7 Reserved 6:4 Row Attribute for odd-numbered row: This field defines the page size of the corresponding row. 000: Reserved 001: 4 kB 010: 8 kB 011: 16 kB 111: Not Populated Others: Reserved 3 Reserved 2:0 Row Attribute for even-numbered row: This field defines the page size of the corresponding row. 000: Reserved 001: 4 kB 010: 8 kB 011: 16 kB 111: Not Populated Others: Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 83 Register Description R 3.9.14. DRT – DRAM Timing Register - Device #0 Address Offset: Default Value: Access: Size: 60-63h 18004425h Read/Write 32 bits This register controls the timing of the DDR SDRAM Controller. Bit 31 Description DDR Internal Write to Read Command delay (tWTR): The tWTR is a std. DDR SDRAM timing parameter with a value of 1 CK for CL=2 and 2.5. The tWTR is used to time RD command after a WR command (to same row): ‘0’: tWTR is set to 1 Clock (CK), used for DDR SDRAM CL=2 or 2.5 ‘1’: Reserved 30 DDR Write Recovery time (tWR): Write recovery time is a std. DDR timing parameter with the value of 15 ns. It should be set to 2 CK when DDR200 is used. The tWR is used to time PRE command launch after a WR command, when DDR SDRAM components are populated. ‘0’: tWR is set to 2 Clocks (CK) ‘1’: tWR is set to 3 Clocks (CK) 29:28 Back To Back Write-Read commands spacing (DDR different rows/bank): This field determines the WR-RD command spacing, in terms of common clocks for DDR SDRAM based on the following formula: DQSS + 0.5xBL + TA (wr-rd) – CL DQSS: is time from write command to data and is always 1 CK BL: is burst length and can be set to 4. TA (wr-rd): is required DQ turn-around, can be set to 1 or 2 CK CL: is CAS latency, can be set to 2 or 2.5 Examples of usage: For BL=4, with single DQ turn-around and CL=2, this field must be set to 2 CK (1+2+1-2) Encoding CK between WR and RD commands BL=4 84 00: 4 01: 3 10: 2 11: Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Bit Description 27:26 Back To Back Read-Write commands spacing (DDR, same or different rows/bank): This field determines the RD-WR command spacing, in terms of common clocks based on the following formula: CL + 0.5xBL + TA (rd-wr) – DQSS DQSS: is time from write command to data and is always 1 CK BL: is burst length which is set to 4 TA (rd-wr): is required DQ turn-around, can be set to 1, 2 or 3 CK CL: is CAS latency, can be set to 2 or 2.5 Examples of usage: For BL=4, with single DQ turn-around and CL=2, this field must be set to 4 CK (2+2+1-1) Encoding CK between RD and WR commands BL=4 00: 7 01: 6 10: 5 11: 4 NOTES: Since reads in DDR SDRAM cannot be terminated by writes, the space between commands is not a function of cycle length but of burst length. 25 Back To Back Read-Read commands spacing (DDR, different rows): This field determines the RD-RD command spacing, in terms of common clocks based on the following formula: 0.5xBL + TA(rd-rd) BL: is burst length and can be set to 4. TA (rd-rd): is required DQ turn-around, can be set to 1 or 2 CK Examples of usage: For BL=4, with single DQ turn-around, this field must be set to 3 CK (2+1) Encoding CK between RD and RD commands BL=4 0: 4 1: 3 NOTES: Since a read to a different row doesn’t terminate a read, the space between commands is not a function of cycle length but of burst length. 24:15 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 85 Register Description R Bit 14:12 Description Refresh Cycle Time (tRFC): Refresh cycle time is measured for a given row from REF command (to perform a refresh) until following ACT to same row (to perform a read or write). It is tracked separately from tRC for DDR SDRAM. Current DDR SDRAM spec requires tRFC of 75 ns (DDR266) and 80nS (DDR200). Therefore, this field will be set to 8 clocks for DDR200, 10 clocks for DDR266. Encoding 11 tRFC “000”: 14 clocks “001”: 13 clocks “010”: 12 clocks “011”: 11 clocks “100”: 10 clocks “101”: 9 clocks “110”: 8 clocks “111”: 7 clocks Activate to Precharge delay (tRAS), MAX: This bit controls the maximum number of clocks that a DDR SDRAM bank can remain open. After this time period, the System Memory controller will guarantee to pre-charge the bank. Note that this time period may or may not be set to overlap with time period that requires a refresh to happen. The DDR SDRAM controller includes a separate tRAS-MAX counter for every supported bank. With a maximum of four row and four banks per row, there are 16 counters. ‘0’: 120 micro-seconds ‘1’: Reserved. 10:9 Activate to Precharge delay (tRAS), MIN: This bit controls the number of DDR SDRAM clocks for tRAS MIN 00: 8 Clocks 01: 7 Clocks 10: 6 Clocks 11: 5 Clocks 8:7 Reserved 6:5 CAS# Latency (tCL): Encoding 00: 2.5 01: 2 10: Reserved 11: Reserved 4 Reserved 3:2 DDR SDRAM RAS# to CAS# Delay (tRCD): This bit controls the number of clocks inserted between a row activate command and a read or write command to that row Encoding 86 DDR SDRAM CL tRCD 00: Reserved 01: 3 DDR SDRAM Clocks 10: 2 DDR SDRAM Clocks 11: Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Bit 1:0 Description DDR SDRAM RAS# Precharge (tRP): This bit controls the number of clocks that are inserted between a row precharge command and an activate command to the same row Encoding 3.9.15. tRP 00: Reserved 01: 3 DDR SDRAM Clocks 10: 2 DDR SDRAM Clocks 11: Reserved PWRMG – DRAM Controller Power Management Control Register - Device #0 Address Offset: Default Value: Access: Size: 68h-6Bh 00000000h Read/Write 32 bits Bit Description 31:24 Reserved 23:20 Row State Control: This field determines the number of clocks the DDR SDRAM controller will retain in the idle state before it begins pre-charging all pages or powering down rows. PDEn: Power Down Enable PCEn: Page Close Enable TC: Timer Control PDEn(23): PCEn(22): TC(21:20)Function 0 0 XX All disabled 0 1 XX Reserved 1 0 XX Reserved 1 1 0X Reserved 10 Reserved 11 Precharge and Power Down after 64 DDR SDRAM Clocks of idle time 19:0 Intel® 852GM/852GMV Chipset GMCH Datasheet 87 Register Description R 3.9.16. DRC – DRAM Controller Mode Register - Device #0 Address Offset: Default Value: Access: Size: 70-73h 00000081h Read/Write, read-only 32 bits Bit Description 31:30 Revision Number (REV): Reflects the revision number of the format used for DDR SDRAM register definition. 29 Initialization Complete (IC): This bit is used for communication of software state between the memory controller and the BIOS. BIOS sets this bit to 1 after initialization of the DDR SDRAM memory array is complete. Setting this bit to a “1” enables DDR SDRAM refreshes. On power up and S3 exit, the BIOS initializes the DDR SDRAM array and sets this bit to a “1”. This bit works in combination with the RMS bits in controlling refresh state: IC Refresh State 0 OFF 1 ON 28:24 Reserved 23:22 Number of Channels (CHAN): Reflects that Intel 852GM/852GMV GMCH supports only one System Memory channel. 00 One channel is populated appropriately Others: Reserved 21:20 DDIM DDR SDRAM Data Integrity Mode: No-ECC. No read-merge-write on partial writes. ECC data sense-amps are disabled and the data output is tristate. (Default) 19:16 Reserved 15 RAS Lock-Out Enable: Set to a ‘1’ if all populated rows support RAS Lock-Out. Defaults to ‘0’. If this bit is set to a ‘1’ the DDR SDRAM controller assumes that the DDR SDRAM guarantees tRAS min before an auto precharge (AP) completes (Note that an AP is sent with a read or a write command). Also, the DDR SDRAM controller does not issue an activate command to the auto pre-charged bank for tRP. If this bit is set to a ‘0’ the DDR SDRAM controller does not schedule an AP if tRAS min is not met. 14:10 Reserved 9:7 Refresh Mode Select (RMS): This field determines whether refresh is enabled and, if so, at what rate refreshes will be executed. 000: Refresh disabled 001: Refresh enabled. Refresh interval 15.6 µsec 010: Refresh enabled. Refresh interval 7.8 µsec 011: Reserved. 111: Refresh enabled. Refresh interval 64 clocks (fast refresh mode) Other: Reserved Any change in the programming of this field resets the refresh counter to zero. This function is for testing purposes, it allows test program to align refresh events with the test and thus improve failure repeatability. 6:4 88 Mode Select (SMS). These bits select the special operational mode of the DDR SDRAM interface. The special modes are intended for initialization at power up. 000: Post Reset state – When the Intel 852GM/852GMV GMCH exits reset (power-up or otherwise), the mode select field is cleared to “000”. Software not expected to write this value, however if this value is written there are no side effects (no self refresh or any other special DDR SDRAM cycle). During any reset sequence, while power is applied and reset is active, the Intel 852GM/852GMV GMCH deasserts all CKE signals. After internal reset is deasserted, CKE signals remain deasserted until this field is Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Bit Description written to a value different than “000”. On this event, all CKE signals are asserted. During suspend (S3, S4), Intel 852GM/852GMV GMCH internal signal triggers DDR SDRAM controller to flush pending commands and enter all rows into Self-Refresh mode. As part of resume sequence, Intel 852GM/852GMV GMCH will be reset – which will clear this bit field to “000” and maintain CKE signals deasserted. After internal reset is deasserted, CKE signals remain deasserted until this field is written to a value different than “000”. On this event, all CKE signals are asserted. During entry to other low power states (C3, S1-M), Intel 852GM/852GMV GMCH internal signal triggers DDR SDRAM controller to flush pending commands and enter all rows in S1 and relevant rows in C3 (Based on RPDNC3) into Self-Refresh mode. During exit to normal mode, the GMCH signal triggers DDR SDRAM controller to exit Self-Refresh and resume normal operation without S/W involvement. 001: NOP Command Enable – All CPU cycles to DDR SDRAM result in a NOP command on the DDR SDRAM interface. 010: All Banks Pre-charge Enable – All CPU cycles to DDR SDRAM result in an “all banks precharge” command on the DDR SDRAM interface. 011: Mode Register Set Enable – All CPU cycles to DDR SDRAM result in a “mode register” set command on the DDR SDRAM interface. Host address lines are mapped to DDR SDRAM address lines in order to specify the command sent. Host address HA[13:3] are mapped to memory address MA[11, 9:0]. MA3 must be driven to 1 for interleave wrap type. For Double Data Rate MA[6:4] needs to be driven based on the value programmed in the CAS# Latency field. CAS Latency MA[6:4] 1.5 Clocks 001 2.0 Clocks 010 2.5 Clocks 110 MA[7] should always be driven to a 0. MA[8] Should be driven to a 1 for DLL Reset and 1 for Normal Operation. MA[12:9] must be driven to 00000. BIOS must calculate and drive the correct host address for each row of memory such that the correct command is driven on the MA[12:0] lines. Note that MAB[7:4]# are inverted from MAA[7:4]; BIOS must account for this. 100: Extended Mode Register Set Enable – All CPU cycles to DDR SDRAM result in an “extended mode register set” command on the DDR SDRAM interface. Host address lines are mapped to DDR SDRAM address lines in order to specify the command sent. Host address lines are mapped to DDR SDRAM address lines in order to specify the command sent. Host address HA[13:3] are mapped to memory address [9:0]. MA[0] = 0 for DLL enable and 1 for DLL disable. All the other MA lines are driven to 0s. Note that MAB[7:4]# are inverted from MAA[7:4]; BIOS must account for this. 101: Reserved 110: CBR Refresh Enable – In this mode all CPU cycles to DDR SDRAM result in a CBR cycle on the DDR SDRAM interface 111: Normal operation 3:0 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 89 Register Description R 3.9.17. DTC – DRAM Throttling Control Register (Device 0) Offset Address: Default Value: Access: Size: A0–A3h 00000000h Read/Write/Lock 32 bits Throttling is independent for System Memory Banks, Intel 852GM/852GMV GMCH Writes, and thermal sensor trips. Read and Write Bandwidth is measured independently for each Bank. If the number of Octal -Words (16 bytes) read/written during the window defined below (Global DDR SDRAM Sampling Window: GDSW) exceeds the DDR SDRAM Bandwidth Threshold, then the DDR SDRAM throttling mechanism will be invoked to limit DDR SDRAM reads/writes to a lower bandwidth checked over smaller time windows. The throttling will be active for the remainder of the current GDSW and for the next GDSW after which it will return to non-throttling mode. The throttling mechanism accounts for the actual bandwidth consumed during the sampling window, by reducing the allowed bandwidth within the smaller throttling window based on the bandwidth consumed during the sampling period. Although bandwidth from/to independent rows and Intel 852GM/852GMV GMCH write bandwidth is measured independently, once tripped all transactions except high priority graphics reads are subject to throttling. 90 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Bit 31:28 Description DDR SDRAM Throttle Mode (TMODE): Four bits control which mechanisms for throttling are enabled in an “OR” fashion. Counter-based throttling is lower priority than thermal trips throttling when both are enabled and tripped. Counter-based trips point throttling values and Thermal-based trip point throttling values are specified in this register. If the counter and thermal mechanisms for either rank or Intel 852GM/852GMV GMCH are both enabled, throttle settings for the one that trips first is used until the end of the second gdsw. [Rank Counter, Intel 852GM/852GMV GMCH Write Counter, Rank Thermal Sensor, Intel 852GM/852GMV GMCH Thermal Sensor] 0000 = Throttling turned off. This is the default setting. All Counters are off. 0001 = Only Intel 852GM/852GMV GMCH Thermal Sensor based throttling is enabled. If Intel 852GM/852GMV GMCH thermal sensor is tripped, write throttling begins based on the setting in WTTC. 0010 = Only Rank Thermal Sensor based throttling enabled. When the external SO-DIMM thermal sensor is tripped DDR SDRAM throttling begins based on the setting in RTTC. 0011 = Both Rank and Intel 852GM/852GMV GMCH Thermal Sensor based throttling enabled. When the external SO-DIMM thermal sensor is tripped DDR SDRAM throttling begins based on the setting in RTTC. If the Intel 852GM/852GMV GMCH thermal sensor is tripped, write throttling begins based on the setting in WTTC. 0100 = Only the Intel 852GM/852GMV GMCH Write Counter mechanism is enabled. When the threshold set in the GDT field is reached, DDR SDRAM throttling begins based on the setting in WCTC. 0101 = Intel 852GM/852GMV GMCH Thermal Sensor and Intel 852GM/852GMV GMCH Write DDR SDRAM Counter mechanisms are both enabled. If the Intel 852GM/852GMV GMCH write DDR SDRAM counter mechanism threshold is reached, DDR SDRAM throttling begins based on the setting in WCTC. If the Intel 852GM/852GMV GMCH thermal sensor is tripped, DDR SDRAM throttling begins based on the setting in WTTC. If both threshold mechanisms are tripped, the DDR SDRAM throttling begins based on the settings in WTTC. 0110 = Rank Thermal Sensor and Intel 852GM/852GMV GMCH Write DDR SDRAM Counter mechanisms are both enabled. If the Intel 852GM/852GMV GMCH write DDR SDRAM counter mechanism threshold is reached, DDR SDRAM throttling begins based on setting in WCTC. If the external SO-DIMM thermal sensor is tripped, Rank DRAM throttling begins based on the setting in RTTC. 0111 = Similar to 0101 for writes and when the Rank thermal sensor is tripped DDR SDRAM throttling begins based on the setting in RTTC. 1000 = Only Rank Counter mechanism is enabled. When the threshold set in the GDT field is reached, DDR SDRAM throttling begins based on the setting in RCTC. 1001 = Rank Counter mechanism is enabled and Intel 852GM/852GMV GMCH Thermal Sensor based throttling are both enabled. If Intel 852GM/852GMV GMCH thermal sensor is tripped, write throttling begins based on the setting in WTTC. When the threshold set in the GDT field is reached, DDR SDRAM throttling begins based on the setting in RCTC. 1010 = Rank thermal Sensor and Rank DDR SDRAM Counter mechanisms are both enabled. If the rank DDR SDRAM counter mechanism threshold is reached, DDR SDRAM throttling begins based on the setting in RCTC. If the external SO-DIMM thermal sensor is tripped, DRAM throttling begins based on the setting in RTTC. 1011 = Similar to 1010 and If the Intel 852GM/852GMV GMCH thermal sensor is tripped, write throttling begins based on the setting in WTTC. 1111 = Rank and Intel 852GM/852GMV GMCH Thermal Sensor based throttling and Rank and Intel 852GM/852GMV GMCH Write Counter based throttling are enabled. If both the write counter and Intel 852GM/852GMV GMCH thermal sensor based mechanisms are tripped, DDR SDRAM throttling begins based on the setting allowed in WTTC. If both the rank counter and rank thermal sensor based mechanisms are tripped, DDR SDRAM throttling begins based on the setting allowed in RTTC. 27:24 Read Counter Based Power Throttle Control (RCTC): These bits select the Counter based Power Throttle Bandwidth Limits for Read operations to System Memory. Intel® 852GM/852GMV Chipset GMCH Datasheet 91 Register Description R Bit Description R/W, RO if Throttle Lock. 0h = 85% 1h = 70% 2h = 65% 3h = 60% 4h = 55% 5h = 50% 6h = 45% 7h = 40% 8h = 35% 9h = 30% Ah = 20% B-Fh = Reserved 23:20 Write Counter Based Power Throttle Control (WCTC): These bits select the Counter based Power Throttle Bandwidth Limits for Write operations to System Memory. R/W, RO if Throttle Lock 0h = 85% 1h = 70% 2h = 65% 3h = 60% 4h = 55% 5h = 50% 6h = 45% 7h = 40% 8h = 35% 9h = 30% Ah = 20% B-Fh = Reserved 19:16 Read Thermal Based Power Throttle Control (RTTC): These bits select the thermal sensor based Power Throttle Bandwidth Limits for Read operations to System Memory. R/W, RO if Throttle Lock. 0h = 85% 1h = 70% 2h = 65% 3h = 60% 4h = 55% 5h = 50% 6h = 45% 7h = 40% 8h = 35% 9h = 30% Ah = 20% B-Fh = Reserved 15:12 Write Thermal Based Power Throttle Control (WTTC): These bits select the thermal based Power Throttle Bandwidth Limits for Write operations to System Memory. R/W, RO if Throttle Lock 92 Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R Bit Description 0h = 85% 1h = 70% 2h = 65% 3h = 60% 4h = 55% 5h = 50% 6h = 45% 7h = 40% 8h = 35% 9h = 30% Ah = 20% B-Fh = Reserved 11 Counter Based Throttle Lock (CTLOCK): This bit secures RCTC and WCTC. This bit defaults to 0. Once a 1 is written to this bit, RCTC and WCTC (including CTLOCK) become read-only. 10 Thermal Throttle Lock (TTLOCK): This bit secures the DDR SDRAM throttling control register. This bit defaults to 0. Once a 1 is written to this bit, all of the configuration register bits in DTC (including TTLOCK) except CTLOCK, RCTC and WCTC become read-only. 9 Thermal Power Throttle Control fields Enable: 0 = RTTC and WTTC are not used. RCTC and WTCT are used for both counter and thermal based throttling. 1 = RTTC and WTTC are used for thermal based throttling. 8 High Priority Stream Throttling Enable: Normally High Priority Streams are not throttled when either the counter based mechanism or thermal sensor mechanism demands throttling. 0 = Normal operation. 1 = Block High priority streams during throttling. 7:0 Global DDR SDRAM Sampling Window (GDSW): This 8-bit value is multiplied by 4 to define the length of time in milliseconds (0–1020) over which the number of Octal Words (16 bytes) read/written is counted and throttling is imposed. Note that programming this field to “00h” disables System Memory throttling. Recommended values are between 0.25 and 0.75 seconds. Intel® 852GM/852GMV Chipset GMCH Datasheet 93 Register Description R 3.10. Intel 852GM/852GMV GMCH Configuration Process and Registers (Device #0, Function #3) See Section 3.2 for access nomenclature. Table 20 summarizes all Device#0, Function #3 registers. Table 20. Configuration Process Configuration Space (Device#0, Function #3) Register Symbol Register Start Register End Default Value Access Vendor Identification VID 00 01 8086h RO Device Identification DID 02 03 3585 RO PCI Command Register PCICMD 04 05 0006h RO R/W PCI Status Register PCISTS 06 07 0080h RO R/WC RID 08 08 01h RO Sub-Class Code SUBC 0A 0A 80h RO Base Class Code BCC 0B 0B 08h RO Header Type HDR 0E 0E 80h RO Subsystem Vendor Identification SVID 2C 2D 0000h R/WO SID 2E 2F 0000h R/WO Capabilities Pointer CAPPTR 34 34 00h RO HPLL Clock Control Register HPLLCC C0 C1 00h RO Register Name Revision Identification Subsystem Identification 3.10.1. VID – Vendor Identification Address Offset: Default Value: Access: Size: 00h 8086h Read Only 16 bits The VID Register contains the vendor identification number. This 16-bit register combined with the Device Identification Register uniquely identifies any PCI device. Writes to this register have no effect. 94 Bit Descriptions 15:0 Vendor Identification (VID): This register field contains the PCI standard identification for Intel 8086h. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.10.2. DID – Device Identification Address Offset: Default Value: Access: Size: 02h 3585h Read Only 16 bits This 16-bit register combined with the Vendor Identification register uniquely identifies any PCI device. Writes to this register have no effect. Bit Descriptions 15:0 Device Identification Number (DID): This is a 16-bit value assigned to the Intel 852GM/852GMV GMCH Host-HI Bridge Function #3. Product Device ID 00 = Intel 852GM/852GMV GMCH (Default) = 3585h 01-11 = Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 95 Register Description R 3.10.3. PCICMD – PCI Command Register Address Offset: Default Value: Access: Size: 04h 0006h Read Only, Read/Write 16 bits Since Intel 852GM/852GMV GMCH Device #0 does not physically reside on PCI_A many of the bits are not implemented. 96 Bit Descriptions 15:10 Reserved 9 Fast Back-to-Back Enable (FB2B): This bit controls whether or not the master can do fast back-to-back write. Since device 0 is strictly a target this bit is not implemented and is hardwired to 0. Writes to this bit position have no affect. 8 SERR Enable (SERRE): SERR# is not implemented by Function 1 of Device 0 of the Intel 852GM/852GMV GMCH and this bit is hardwired to 0. Writes to this bit position have no effect. 7 Address/Data Stepping Enable (ADSTEP): Address/data stepping is not implemented in the Intel 852GM/852GMV GMCH, and this bit is hardwired to 0. Writes to this bit position have no effect. 6 Parity Error Enable (PERRE): PERR# is not implemented by Intel 852GM/852GMV GMCH and this bit is hardwired to 0. Writes to this bit position have no effect. 5 VGA Palette Snoop Enable (VGASNOOP): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 4 Memory Write and Invalidate Enable (MWIE): The Intel 852GM/852GMV GMCH will never issue memory write and invalidate commands. This bit is therefore hardwired to 0. Writes to this bit position will have no effect. 3 Special Cycle Enable (SCE): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 2 Bus Master Enable (BME): The Intel 852GM/852GMV GMCH is always enabled as a master on HI. This bit is hardwired to a "1". Writes to this bit position have no effect. 1 Memory Access Enable (MAE): The Intel 852GM/852GMV GMCH always allows access to main memory. This bit is not implemented and is hardwired to 1. Writes to this bit position have no effect. 0 I/O Access Enable (IOAE): This bit is not implemented in the Intel 852GM/852GMV GMCH and is hardwired to a 0. Writes to this bit position have no effect. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.10.4. PCISTS – PCI Status Register Address Offset: Default Value: Access: Size: 06h 0080h Read Only, Read/Write/Clear 16 bits PCISTS is a 16-bit status register that reports the occurrence of error events on Device #0’s PCI interface. Bit 14 is read/write clear. All other bits are Read Only. Since Intel 852GM/852GMV GMCH Device #0 does not physically reside on PCI_A many of the bits are not implemented. Bit Descriptions 15 Detected Parity Error (DPE): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 14 Signaled System Error (SSE): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 13 Received Master Abort Status (RMAS): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 12 Received Target Abort Status (RTAS): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 11 Signaled Target Abort Status (STAS): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 10:9 DEVSEL Timing (DEVT): These bits are hardwired to "00". Writes to these bit positions have no affect. Device #0 does not physically connect to PCI_A. These bits are set to "00" (fast decode) so that the Intel 852GM/852GMV GMCH does not limit optimum DEVSEL timing for PCI_A. 8 Master Data Parity Error Detected (DPD): The Intel 852GM/852GMV GMCH does not implement this bit and it is hardwired to a 0. Writes to this bit position have no effect. 7 Fast Back-to-Back (FB2B): This bit is hardwired to 1. Writes to these bit positions have no effect. Device #0 does not physically connect to PCI_A. This bit is set to 1 (indicating fast back-to-back capability) so that the Intel 852GM/852GMV GMCH does not limit the optimum setting for PCI_A. 6:5 Reserved 4 Capability List (CLIST): This bit is hardwired to 0 to indicate to the configuration software that this device/function does not implement new capabilities. 3:0 Reserved Intel® 852GM/852GMV Chipset GMCH Datasheet 97 Register Description R 3.10.5. RID – Revision Identification Address Offset: Default Value: Access: Size: 08h 01h Read Only 8 bits This register contains the revision number of the Intel 852GM/852GMV GMCH. These bits are read only and writes to this register have no effect. 3.10.6. Bit Descriptions 7:0 Revision Identification Number (RID): This is an 8-bit value that indicates the revision identification number for the Intel 852GM/852GMV GMCH. SUBC – Sub-Class Code Address Offset: Default Value: Access: Size: 0Ah 80h Read Only 8 bits This register contains the Sub-Class Code for the Intel 852GM/852GMV GMCH Device #0. This code is 80h indicating a peripheral device. 3.10.7. Bit Descriptions 7:0 Sub-Class Code (SUBC): This is an 8-bit value that indicates the category of Bridge into which the Intel 852GM/852GMV GMCH falls. The code is 80h indicating other peripheral device. BCC – Base Class Code Address Offset: Default Value: Access: Size: 0Bh 08h Read Only 8 bits This register contains the Base Class Code of the Intel 852GM/852GMV GMCH Device #0 Function #3. This code is 08h indicating a peripheral device. 98 Bit Descriptions 7:0 Base Class Code (BASEC): This is an 8-bit value that indicates the Base Class Code for the Intel 852GM/852GMV GMCH. This code has the value 08h, indicating other peripheral device. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.10.8. HDR – Header Type Address Offset: Default Value: Access: Size: 0Eh 080h Read Only 8 bits This register identifies the header layout of the configuration space. No physical register exists at this location. 3.10.9. Bit Descriptions 7:0 PCI Header (HDR): This field always returns 80 to indicate that Device 0 is a multifunction device. If Functions other than #0 are disabled this field returns a 00 to indicate that the Intel 852GM/852GMV GMCH is a single function device with standard header layout. The default is 80 Reads and writes to this location have no effect. SVID – Subsystem Vendor Identification Address Offset: Default Value: Access: Size: 2Ch 0000h Write Once 16 bits This value is used to identify the vendor of the subsystem. 3.10.10. Bit Descriptions 15:0 Subsystem Vendor ID (SUBVID): This field should be programmed during boot-up to indicate the vendor of the system board. After it has been written once, it becomes read only. ID – Subsystem Identification Address Offset: Default Value: Access: Size: 2Eh 0000h Write Once 16 bits This value is used to identify a particular subsystem. Bit Descriptions 15:0 Subsystem ID (SUBID): This field should be programmed during BIOS initialization. After it has been written once, it becomes read only. Intel® 852GM/852GMV Chipset GMCH Datasheet 99 Register Description R 3.10.11. CAPPTR – Capabilities Pointer Address Offset: Default Value: Access: Size: 34h 00h Read Only 8 bits The CAPPTR provides the offset that is the pointer to the location of the first device capability in the capability list. 3.10.12. Bit Descriptions 7:0 Pointer to the offset of the first capability ID register block: In this case there are no capabilities therefore these bits are hardwired to 00h to indicate the end of the capability-linked list. HPLLCC – HPLL Clock Control Register (Device 0) Address Offset: Default Value: Access: Size: C0–C1h 00h Read Only 16 bits Descriptions Bit 15:11 Reserved 10 HPLL VCO Change Sequence Initiate Bit: Software must write a '0' to clear this bit and then write a '1' to initiate sequence again. 9 Hphase Reset Bit: 1 = Assert 0 = Deassert (default) 8 Reserved 7:2 Reserved 1:0 HPLL Clock Control: Software is allowed to update this register. See Table 21 for Clock definitions. Table 21. Intel 852GM/852GMV GMCH Configurations 100 Straps Read Through HPLLCC[1:0]: D0:F3:Register Offset C0-C1h, bits[1:0] FSB Frequency System Memory Frequency GFX Core Clock(Low) GFX Core Clock (High) 00 400 MHz 266 MHz 133 MHz 133 MHz 10 400 MHz 200 MHz 133 MHz 133 MHz Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.11. Intel 852GM/852GMV GMCH Integrated Graphics Device Registers (Device #2, Function #0) This section contains the PCI configuration registers listed in order of ascending offset address. Device #2 incorporates Function #0. See Section 3.2 for access nomenclature. Table 22. Integrated Graphics Device Configuration Space (Device #2, Function#0) Register Name Register Symbol Address Offset Register End Default Value Access Regs in Function#1 Vendor Identification VID2 00h 01h 8086h RO C0F0 Device Identification DID2 02h 03h 3582h RO C0F0 PCI Command Register PCICMD2 04h 05h 0000h RO,R/W U1F1 PCI Status Register PCISTS2 06h 07h 0090h RO U1F1 Revision Identification RID2 08h 08h 01h RO C0F0 Class Code CC 09h 0Bh 030000h RO U1F1 Cache Line Size Register CLS 0Ch 0Ch 00h RO C0F0 Master Latency Timer MLT2 0Dh 0Dh 00h RO C0F0 Header Type HDR2 0Eh 0Eh 00h RO C0F0 Graphics Memory Range Address GMADR 10h 13h 00000008h R/W,RO U1F1 Memory Mapped Range Address MMADR 14h 17h 00000000h R/W,RO U1F1 IO Range Register IOBAR 18h 1Bh 00000001h R/W,RO Subsystem Vendor ID SVID2 2Ch 2Dh 0000h R/WO C0F0 Subsystem ID SID2 2Eh 2Fh 0000h R/ WO C0F0 Video Bios ROM Base Address ROMADR 30h 33h 00000000h RO C0F0 Interrupt Line Register INTRLINE 3Ch 3Ch 00h R/W, RO in F #1 Interrupt Pin Register INTRPIN 3Dh 3Dh 01h RO, Reserved In F#1 Minimum Grant Register MINGNT 3Eh 3Eh 00h RO C0F0 Maximum Latency Register MAXLAT 3Fh 3Fh 00h RO C0F0 Mirror of GMCH Misc Control MGMiscC 50h 51h --- RO Power Management Capabilities PMCAP D2h D3h 0221h RO COFO Power Management Control PMCS D4h D5h 0000h R/W,RO U1F1 CODO FO GMCH Misc Control Register Intel® 852GM/852GMV Chipset GMCH Datasheet 101 Register Description R 3.11.1. VID2 – Vendor Identification Register – Device #2 Address Offset: Default Value: Access Attributes: Size: 00h 01h 8086h Read Only 16 bits The VID Register contains the vendor identification number. This 16-bit register combined with the Device Identification Register uniquely identifies any PCI device. Writes to this register have no effect. Bit 15:0 3.11.2. Description Vendor Identification Number: This is a 16-bit value assigned to Intel. DID2 – Device Identification Register - Device #2 Address Offset: Default Value: Access Attributes: Size: 16 bits 02h 03h 3582h Read Only This 16-bit register combined with the Vendor Identification register uniquely identifies any PCI device. Writes to this register have no effect. Bit 15:0 102 Description Device Identification Number: This is a 16-bit value assigned to the Intel 852GM/852GMV GMCH IGD. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.11.3. PCICMD2 – PCI Command Register - Device #2 Address Offset: Default: Access: Size: 04h 05h 0000h Read Only, Read/Write 16 bits This 16-bit register provides basic control over the IGD’s ability to respond to PCI cycles. The PCICMD Register in the IGD disables the IGD PCI compliant master accesses to main System Memory. Bit Description 15:10 Reserved 9 Fast Back-to-Back (FB2B) 8 SERR# Enable (SERRE) 7 Address/Data Stepping 6 Parity Error Enable (PERRE) 5 Video Palette Snooping (VPS) 4 Memory Write and Invalidate Enable (MWIE) 3 Special Cycle Enable (SCE) 2 RO. RO. RO. Bus Master Enable (BME) RO. RO. RO. RO. R/W: This bit determines if the IGD is to function as a PCI compliant master. 0= Disable IGD bus mastering (default). 1 = Enable IGD bus mastering. 1 Memory Access Enable (MAE) accesses. R/W: This bit controls the IGD’s response to System Memory space 0= Disable (default). 1 = Enable. 0 I/O Access Enable (IOAE) R/W: This bit controls the IGD’s response to I/O space accesses. 0 = Disable (default). 1 = Enable. Intel® 852GM/852GMV Chipset GMCH Datasheet 103 Register Description R 3.11.4. PCISTS2 – PCI Status Register - Device #2 Address Offset: Default Value: Access: Size: 06h 07h 0090h Read Only 16 bits PCISTS is a 16-bit status register that reports the occurrence of a PCI compliant master abort and PCI compliant target abort. PCISTS also indicates the DEVSEL# timing that has been set by the IGD. Bit 3.11.5. Description 15 Detected Parity Error (DPE): Since the IGD does not detect parity, this bit is always set to 0. 14 Signaled System Error (SSE) – RO 13 Received Master Abort Status (RMAS) – RO 12 Received Target Abort Status (RTAS) – RO 11 Signaled Target Abort Status (STAS) – RO 10:9 DEVSEL# Timing (DEVT) – RO 8 Data Parity Detected (DPD) – RO 7 Fast Back-to-Back (FB2B) – RO 6 User Defined Format (UDF) – RO 5 66-MHz PCI Capable (66C) – RO 4 CAP LIST: This bit is set to 1 to indicate that the register at 34h provides an offset into the function’s PCI Configuration Space containing a pointer to the location of the first item in the list. 3:0 Reserved RID2 – Revision Identification Register - Device #2 Address Offset: Default Value: Access: Size: 08h 01h Read Only 8 bits This register contains the revision number of the IGD. These bits are read only and writes to this register have no effect. Bit 7:0 104 Description Revision Identification Number: This is an 8-bit value that indicates the revision identification number for the Intel 852GM/852GMV GMCH. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.11.6. CC – Class Code Register - Device #2 Address Offset: Default Value: Access: Size: 09h 0Bh 030000h Read Only 24 bits This register contains the device programming interface information related to the Sub-Class Code and Base Class Code definition for the IGD. This register also contains the Base Class Code and the function sub-class in relation to the Base Class Code. Bit Description 23:16 Base Class Code (BASEC): 03=Display controller 15:8 Sub-Class Code (SCC): Function 0: 00h=VGA compatible or 80h=Non VGA Function 1: 80h=Non VGA 7:0 3.11.7. Programming Interface (PI): 00h=Hardwired as a Display controller. CLS – Cache Line Size Register - Device #2 Address Offset: Default Value: Access: Size: 0Ch 00h Read only 8 bits The IGD does not support this register as a PCI slave. Bit 7:0 3.11.8. Description Cache Line Size (CLS) – RO MLT2 – Master Latency Timer Register - Device #2 Address Offset: Default Value: Access: Size: 0Dh 00h Read Only 8 bits The IGD does not support the programmability of the master latency timer because it does not perform bursts. Bit Description 7:0 Master Latency Timer Count Value – RO Intel® 852GM/852GMV Chipset GMCH Datasheet 105 Register Description R 3.11.9. HDR2 – Header Type Register - Device #2 Address Offset: Default Value: Access: Size: 0Eh 00h Read Only 8 bits This register contains the Header Type of the IGD. Bit 3.11.10. Description 7 Multi Function Status (MFunc): Indicates if the device is a Multi-Function Device. 6:0 Header Code (H): This is a 7-bit value that indicates the Header Code for the IGD. This code has the value 00h, indicating a type 0 configuration space format. GMADR – Graphics Memory Range Address Register - Device #2 Address Offset: Default Value: Access: Size: 10 13h 00000008h Read/Write, Read Only 32 bits IGD graphics System Memory base address is specified in this register. Bit 106 Description 31:27 Memory Base Address R/W: Set by the OS, these bits correspond to address signals [31:26]. 26 128-MB Address Mask – RO: 0 indicates 128-MB address 25:4 Address Mask 3 Prefetchable Memory 2:1 Memory Type 0 Memory/IO Space RO: Indicates (at least) a 32-MB address range. RO: Enable prefetching. RO: Indicate 32-bit address. RO: Indicate System Memory space. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.11.11. MMADR – Memory Mapped Range Address Register - Device #2 Address Offset: Default Value: Access: Size: 14 17h 00000000h Read/Write, Read Only 32 bits This register requests allocation for the IGD registers and instruction ports. The allocation is for 512-kB and the base address is defined by bits [31:19]. Bit 3.11.12. Description 31:19 Memory Base Address 18:4 Address Mask 3 Prefetchable Memory 2:1 Memory Type 0 Memory / IO Space R/W: Set by the OS, these bits correspond to address signals [31:19]. RO: Indicate 512 -kB address range. RO: Prevents prefetching. RO: Indicates 32-bit address. RO: Indicates System Memory space. IOBAR – I/O Base Address Register - (Device #2) Address offset: Default: Access: Size: 18-1Bh 00000001h Read/Write 16-bits This register provides the Base offset of the I/O registers within Device #2. Bits 15:3 are programmable allowing the I/O Base to be located anywhere in 16-bit I/O Address Space. Bits 2:1 are fixed and return zero, bit 0 is hardwired to a one indicating that 8-bytes of I/O space are decoded. Access to the 8Bs of IO space is allowed in PM state D0 when IO Enable (PCICMD bit 0) set. Access is disallowed in PM states D1-D3 or if IO Enable is clear or if Device #2 is turned off or if internal graphics is disabled. Note that access to this IO BAR is independent of VGA functionality within Device #2. Also note that this mechanism is available only through Function #0 of Device#2 and is not duplicated in Function #1. If accesses to this IO bar are allowed, then the Intel 852GM/852GMV GMCH claims all 8-bit, 16-bit, or 32-bit IO cycles from the CPU that falls within the 8B claimed. Bit Description 31:16 Reserved 15:3 IO Base Address 2:1 Memory Type 0 Memory / IO Space R/W: Set by the OS, these bits correspond to address signals [15:3]. RO: Indicates 32-bit address. RO Intel® 852GM/852GMV Chipset GMCH Datasheet 107 Register Description R 3.11.13. SVID2 – Subsystem Vendor Identification Register - Device #2 Address Offset: Default Value: Access: Size: 3.11.14. 2C 2Dh 0000h Read/Write Once 16 bits Bit Description 15:0 Subsystem Vendor ID: This value is used to identify the vendor of the subsystem. This register should be programmed by BIOS during boot-up. Once written, this register becomes Read_Only. This register can only be cleared by a Reset. SID2 – Subsystem Identification Register - Device #2 Address Offset: Default Value: Access: Size: 2E 2Fh 0000h Read/Write Once 16 bits Bit 15:0 3.11.15. Description Subsystem Identification: This value is used to identify a particular subsystem. This field should be programmed by BIOS during boot-up. Once written, this register becomes Read_Only. This register can only be cleared by a Reset. ROMADR – Video BIOS ROM Base Address Registers - Device #2 Address Offset: Default Value: Access: Size: 30 33h 00000000h Read Only 32 bits The IGD does not use a separate BIOS ROM, therefore this register is hardwired to 0’s. Bit 108 Description 31:18 ROM Base Address 17:11 Address Mask 10:1 Reserved 0 ROM BIOS Enable RO RO: Indicates 256 kB address range. RO: Indicates ROM not accessible. Intel® 852GM/852GMV Chipset GMCH Datasheet Register Description R 3.11.16. INTRLINE Interrupt Line Register - Device #2 Address Offset: Default Value: Access: Size: 3Ch 00h Read/Write 8 bits Bit 7:0 3.11.17. Description Interrupt Connection: Used to communicate interrupt line routing information. POST software writes the routing information into this register as it initializes and configures the system. The value in this register indicates which input of the system interrupt controller that the device’s interrupt pin is connected to. INTRPIN Interrupt Pin Register - Device #2 Address Offset: Default Value: Access: Size: Bit 7:0 3.11.18. Description Interrupt Pin: As a single function device, the IGD (Integrated GFX Device) specifies INTA# as its interrupt pin. 01h=INTA#. For Function #1, this register is set to 00h. MINGNT – Minimum Grant Register - Device #2 Address Offset: Default Value: Access: Size: Bit 7:0 3.11.19. 3Dh 01h, 00h for Function #1 Read Only 8 bits 3Eh 00h Read Only 8 bits Description Minimum Grant Value: The IGD does not burst as a PCI compliant master. MAXLAT – Maximum Latency Register - Device #2 Address Offset: Default Value: Access: Size: Bit 7:0 3Fh 00h Read Only 8 bits Description Maximum Latency Value: Bits[7:0]=00h. The IGD has no specific requirements for how often it needs to access the PCI bus. Intel® 852GM/852GMV Chipset GMCH Datasheet 109 Register Description R 3.11.20. PMCAP – Power Management Capabilities Register - Device #2 Address Offset: Default Value: Access: Size: D2h D3h 0221h Read Only 16 bits Bit 3.11.21. Description 15:11 PME Support: This field indicates the power states in which the IGD may assert PME#. Hardwired to 0 to indicate that the IGD does not assert the PME# signal. 10:6 Reserved 5 Device Specific Initialization (DSI): Hardwired to 1 to indicate that special initialization of the IGD is required before generic class device driver is to use it. 4 Auxiliary Power Source: Hardwired to 0. 3 PME Clock: Hardwired to 0 to indicate IGD does not support PME# generation. 2:0 Version: Hardwired to 001b to indicate there are 4 bytes of power management registers implemented. PMCS – Power Management Control/Status Register - Device #2 Address Offset: Default Value: Access: Size: D4h D5h 0000h Read/Write, Read Only 16 bits Bit Description 15 PME_Status (cold). RO: This bit is 0 to indicate that IGD does not support PME# generation from D3 14:9 Reserved 8 PME_En 7:2 Reserved 1:0 PowerState R/W: This field indicates the current power state of the IGD and can be used to set the IGD into a new power state. If software attempts to write an unsupported state to this field, write operation must complete normally on the bus, but the data is discarded and no state change occurs. RO: This bit is 0 to indicate that PME# assertion from D3 (cold) is disabled. On a transition from D3 to D0 the graphics controller is optionally reset to initial values. 110 Bits[1:0] Power State 00 D0 01 D1 10 D2 11 D3 Default Not Supported Intel® 852GM/852GMV Chipset GMCH Datasheet Intel 852GM/852GMV GMCH System Address Map R 4. Intel 852GM/852GMV GMCH System Address Map A system based on the GMCH supports 4 GB of addressable System Memory space and 64 kB+3B of addressable I/O space. The I/O and System Memory spaces are divided by system configuration software into regions. The System Memory ranges are useful either as System Memory or as specialized System Memory, while the I/O regions are used solely to control the operation of devices in the system. When the GMCH receives a write request whose address targets an invalid space, the data is ignored. For reads, the GMCH responds by returning all zeros on the requesting interface. 4.1. System Memory Address Ranges The GMCH provides a maximum System Memory of 1-GB. The GMCH does not remap APIC memory space and does not limit DDR SDRAM space in hardware. It is the BIOS or system designer’s responsibility to limit System Memory population so that adequate PCI High BIOS and APIC memory space can be allocated. Figure 4 and Figure 5 represent System Memory address map in a simplified form and provide details on mapping specific System Memory regions as defined and supported by the GMCH. Intel® 852GM/852GMV Chipset GMCH Datasheet 111 Intel 852GM/852GMV GMCH System Address Map R Figure 4. Simplified View of System Address Map 4 GB PCI Memory Address Range Graphic ( Local) Memory Top of the M ain Memory Independently Programm able Non-Overlapping M em ory W indows Main Memory Address Range 0 GMCH System Memory Space 112 Intel® 852GM/852GMV Chipset GMCH Datasheet Intel 852GM/852GMV GMCH System Address Map R Figure 5. Detailed View of System Address Map Extended P6 Memory 64 G 4 G max TOM 0FFFFFh 0F0000h PCI Memory Range Optional ISA Hole Upper BIOS Area (64 kB) 1 MB 0EFFFFh Lower BIOS 960 kB 0DFFFFh 1G 0C0000h 0BFFFFh 16 M 15 M Area (64 kB) 16 kB x 41 Expansion 896 kB Card BIOS and Buffer Area (128 kB) 16 kBx8 0A0000h 1M DOS Compatibility Memory DOS Compatibility Memory Standard PCI/ISA Video Memory (SMM Memory) 128 kB 768 kB 640 kB 09FFFFh 640 k DOS Area SYSMAP. DS4 4.2. 0M 000000h Compatibility Area This area is divided into the following address regions: 0 - 640 kB DOS Area 640 – 768 kB Video Buffer Area 768 - 896 kB in 16-kB sections (total of 8 sections) - Expansion Area 896 –960 kB in 16-kB sections (total of 4 sections) - Extended System BIOS Area 960 kB - 1 MB System Memory (BIOS Area) - System BIOS Area There are 16 System Memory segments in the compatibility area. Thirteen of the System Memory ranges can be enabled or disabled independently for both read and write cycles. Intel® 852GM/852GMV Chipset GMCH Datasheet 113 Intel 852GM/852GMV GMCH System Address Map R Table 23. System Memory Segments and Their Attributes System Memory Segments Attributes Comments 000000H - 09FFFFH Fixed - always mapped to main DDR SDRAM 0 to 640 kB – DOS Region 0A0000H - 0BFFFFH Mapped to Hub Interface or IGD configurable as SMM space Video Buffer (physical DDR SDRAM configurable as SMM space) 0C0000H - 0C3FFFH WE RE Add-on BIOS 0C4000H - 0C7FFFH WE RE Add-on BIOS 0C8000H - 0CBFFFH WE RE Add-on BIOS 0CC000H - 0CFFFFH WE RE Add-on BIOS 0D0000H - 0D3FFFH WE RE Add-on BIOS 0D4000H - 0D7FFFH WE RE Add-on BIOS 0D8000H - 0DBFFFH WE RE Add-on BIOS 0DC000H - 0DFFFFH WE RE Add-on BIOS 0E0000H - 0E3FFFH WE RE BIOS Extension 0E4000H - 0E7FFFH WE RE BIOS Extension 0E8000H - 0EBFFFH WE RE BIOS Extension 0EC000H - 0EFFFFH WE RE BIOS Extension 0F0000H - 0FFFFFH WE RE BIOS Area DOS Area (00000h-9FFFFh) The DOS area is 640-kB in size and is always mapped to the main System Memory controlled by the GMCH. Legacy VGA Ranges (A0000h-BFFFFh) The legacy 128-kB VGA memory range A0000h-BFFFFh (Frame Buffer) can be mapped to IGD (Device #2) and to the Hub Interface depending on the programming of the VGA steering bits. Priority for VGA mapping is constant in that the GMCH always decodes internally mapped devices first. Internal to the GMCH, decode precedence is always given to IGD. The GMCH always positively decodes internally mapped devices, namely the IGD. Subsequent decoding of regions mapped to the Hub Interface depends on the Legacy VGA configurations bits (VGA Enable and MDAP). This region is also the default for SMM space. Compatible SMRAM Address Range (A0000h-BFFFFh) When compatible SMM space is enabled, SMM-mode CPU accesses to this range are routed to physical DDR SDRAM at this address. Non-SMM-mode CPU accesses to this range are considered to be to the video buffer area as described above. Hub Interface originated cycles to enabled SMM space are not allowed and are considered to be to the video buffer area. 114 Intel® 852GM/852GMV Chipset GMCH Datasheet Intel 852GM/852GMV GMCH System Address Map R Monochrome Adapter (MDA) Range (B0000h - B7FFFh) Legacy support requires the ability to have a second graphics controller (monochrome) in the system. Accesses in the standard VGA range are forwarded to IGD and the Hub Interface (depending on configuration bits). Since the monochrome adapter may be mapped to anyone of these devices, the GMCH must decode cycles in the MDA range and forward them either to IGD or to Hub Interface. This capability is controlled by a VGA steering bits and the legacy configuration bit (MDAP bit). In addition to the System Memory range B0000h to B7FFFh, the GMCH decodes IO cycles at 3B4h, 3B5h, 3B8h, 3B9h, 3BAh, and 3BFh and forwards them to the either the IGD or the Hub Interface. Expansion Area (C0000h-DFFFFh) This 128-kByte ISA Expansion region is divided into eight 16-kByte segments. Each segment can be assigned one of four Read/Write states: read-only, write-only, read/write, or disabled. Typically, these blocks are mapped through GMCH and are subtractively decoded to ISA space. System Memory that is disabled is not remapped. Extended System BIOS Area (E0000h-EFFFFh) This 64-kByte area is divided into four 16-kByte segments. Each segment can be assigned independent read and write attributes so it can be mapped either to main DDR SDRAM or to Hub Interface. Typically, this area is used for RAM or ROM. System Memory segments that are disabled are not remapped elsewhere. System BIOS Area (F0000h-FFFFFh) This area is a single 64-kByte segment. This segment can be assigned read and write attributes. It is by default (after reset) Read/Write disabled and cycles are forwarded to Hub Interface. By manipulating the Read/Write attributes, the GMCH can “shadow” BIOS into the main DDR SDRAM. When disabled, this segment is not remapped. 4.3. Extended System Memory Area This System Memory area covers 100000h (1 MB) to FFFFFFFFh (4 GB-1) address range and it is divided into the following regions: Main System Memory from 1 MByte to the Top of System Memory; maximum 512 MB. PCI Memory space from the Top of System Memory to 4 GB with two specific ranges. APIC Configuration Space from FEC0_0000h (4 GB-20 MB) to FECF_FFFFh and FEE0_0000h to FEEF_FFFFh High BIOS area from 4 GByte to 4 GByte - 2 MB Intel® 852GM/852GMV Chipset GMCH Datasheet 115 Intel 852GM/852GMV GMCH System Address Map R 4.4. Main System Memory Address Range (0010_0000h to Top of Main Memory) The address range from 1 MB to the top of main system memory is mapped to main DDR SDRAM address range controlled by the GMCH. The Top of Memory (TOM) is limited to 512-MB DDR SDRAM. The GMCH will forward all accesses to addresses within this range to the DDR SDRAM unless a hole in this range is created using the fixed hole as controlled by the FDHC register. Accesses within this hole are forwarded to Hub interface. The GMCH provides a maximum DDR SDRAM address decode space of 4 GB. The GMCH does not remap APIC memory space. The GMCH does not limit DDR SDRAM address space in hardware. 4.4.1. 15 MB-16 MB Window A hole can be created at 15 MB-16 MB as controlled by the fixed hole enable (FDHC register) in Device 0 space. Accesses within this hole are forwarded to the Hub Interface. The range of physical DDR SDRAM disabled by opening the hole is not remapped to the Top of the memory – that physical DDR SDRAM space is not accessible. This 15 MB-16 MB hole is an optionally enabled ISA hole. Video accelerators originally used this hole. Validation and customer SV teams also use it for some of their test cards. That is why it is being supported. There is no inherent BIOS request for the 15-16 hole. 4.4.2. Pre-allocated System Memory Voids of physical addresses that are not accessible as general System Memory and reside within System Memory address range (< TOM) are created for SMM-mode and legacy VGA graphics compatibility. It is the responsibility of BIOS to properly initialize these regions. The number of UMA options has been extended. Allocation is at a fixed address in terms of rigid positioning of UMA System Memory ÆTOM-TSEG-UMA(size), but it is mapped at any available address by a PCI allocation algorithm. GMADR and MMADR are requested through BARs. The following table details the location and attributes of the regions. Table 24. Pre-allocated System Memory System Memory Segments Attributes Comments 00000000H - 03E7FFFFH R/W Available System Memory 62.5 MB 03E80000H - 03F7FFFFH R/W Pre-allocated Graphics VGA memory. 1-MB (or 4/8/16/32- MB) when IGD is enabled. 116 03F80000H - 03FFFFFFH SMM Mode Only - CPU Reads TSEG Address Range 03F80000H - 03FFFFFFH SMM Mode Only - CPU Reads TSEG Pre-allocated System Memory Intel® 852GM/852GMV Chipset GMCH Datasheet Intel 852GM/852GMV GMCH System Address Map R 4.4.2.1. Extended SMRAM Address Range (HSEG and TSEG) The HSEG and TSEG SMM transaction address spaces reside in this extended System Memory area. 4.4.2.2. HSEG SMM mode CPU accesses to enabled HSEG are remapped to 000A0000h-000BFFFFh. Non-SMM mode CPU accesses to enabled HSEG are considered invalid are terminated immediately on the FSB. The exceptions to this rule are Non-SMM mode Write Back cycles that are remapped to SMM space to maintain cache coherency. Hub Interface originated cycles to enabled SMM space are not allowed. Physical DDR SDRAM behind the HSEG transaction address is not remapped and is not accessible. 4.4.2.3. TSEG TSEG is 1-MB in size and is at the top of physical System Memory. SMM mode CPU accesses to enabled TSEG access the physical DDR SDRAM at the same address. Non-SMM mode CPU accesses to enabled TSEG are considered invalid and are terminated immediately on the FSB. The exceptions to this rule are Non-SMM-mode Write Back cycles that are directed to the physical SMM space to maintain cache coherency. Hub Interface originated cycles that enable SMM space are not allowed. The size of the SMRAM space is determined by the USMM value in the SMRAM register. When the extended SMRAM space is enabled, non-SMM CPU accesses and all other accesses in this range are forwarded to the Hub Interface. When SMM is enabled the amount of System Memory available to the system is equal to the amount of physical DDR SDRAM minus the value in the TSEG register. 4.4.2.4. Intel Dynamic Video Memory Technology (DVMT) The IGD supports DVMT in a non-graphics System Memory configuration. DVMT is a mechanism that manages System Memory and the internal graphics device for optimal graphics performance. DVMTenabled software drivers, working with the memory arbiter and the operating system, utilize the System Memory to support 2D graphics and 3D applications. DVMT dynamically responds to application requirements by allocating the proper amount of display and texturing memory. 4.4.2.5. PCI Memory Address Range (Top of Main System Memory to 4 GB) The address range from the top of main DDR SDRAM to 4-GB (top of physical System Memory space supported by the GMCH) is normally mapped via the Hub Interface to PCI. As an internal graphics configuration, there are two exceptions to this rule. 1. The first exception is addresses decoded to the Graphics Memory Range. One per function in device #2. 2. The second exception is addresses decoded to the System Memory Mapped Range of the Internal Graphics Device. One per function in device #2. Both exception cases are forwarded to the Internal Graphics Device. There are two sub-ranges within the PCI Memory address range defined as APIC Configuration Space and High BIOS Address Range. As an Internal Graphics Device, the Graphics Memory Range and the Memory Mapped Range of the Internal Graphics Device MUST NOT overlap with these two ranges. These ranges are described in detail in the following paragraphs. Intel® 852GM/852GMV Chipset GMCH Datasheet 117 Intel 852GM/852GMV GMCH System Address Map R 4.4.2.6. APIC Configuration Space (FEC0_0000h -FECF_FFFFh, FEE0_0000hFEEF_FFFFh) This range is reserved for APIC configuration space that includes the default I/O APIC configuration space. The default Local APIC configuration space is FEE0_0000h to FEEF_0FFFh. CPU accesses to the Local APIC configuration space do not result in external bus activity since the Local APIC configuration space is internal to the CPU. However, an MTRR must be programmed to make the Local APIC range uncacheable (UC). The Local APIC base address in each CPU should be relocated to the FEC0_0000h (4 GB-20 MB) to FECF_FFFFh range so that one MTRR can be programmed to 64-kB for the Local and I/O APICs. The I/O APIC(s) usually resides in the ICH4-M portion of the chip-set or as a stand-alone component(s). I/O APIC units will be located beginning at the default address FEC0_0000h. The first I/O APIC will be located at FEC0_0000h. Each I/O APIC unit is located at FEC0_x000h where x is I/O APIC unit number 0 through F(hex). This address range will be normally mapped to Hub Interface. The address range between the APIC configuration space and the High BIOS (FED0_0000h to FFDF_FFFFh) is always mapped to the Hub Interface. 4.4.2.7. High BIOS Area (FFE0_0000h -FFFF_FFFFh) The top 2-MB of the Extended Memory Region is reserved for System BIOS (High BIOS), extended BIOS for PCI devices, and the A20 alias of the system BIOS. CPU begins execution from the High BIOS after reset. This region is mapped to Hub Interface so that the upper subset of this region aliases to 16 MB to 256-kB range. The actual address space required for the BIOS is less than 2 MB but the minimum CPU MTRR range for this region is 2-MB so that full 2-MB must be considered. 4.4.3. System Management Mode (SMM) Memory Range The GMCH supports the use of main System Memory as System Management RAM (SMM RAM) enabling the use of System Management Mode. The GMCH supports three SMM options: Compatible SMRAM (C_SMRAM), High Segment (HSEG), and Top of Memory Segment (TSEG). System Management RAM space provides a System Memory area that is available for the SMI handler’s and code and data storage. This System Memory resource is normally hidden from the system OS so that the processor has immediate access to this System Memory space upon entry to SMM. The GMCH provides three SMRAM options: Below 1 -MByte option that supports compatible SMI handlers. Above 1 -MByte option that allows new SMI handlers to execute with write-back cacheable SMRAM. Above 1-MByte solutions require changes to compatible SMRAM handlers code to properly execute above 1-MByte. Note: Hub Interface is not allowed to access the SMM space. 118 Intel® 852GM/852GMV Chipset GMCH Datasheet Intel 852GM/852GMV GMCH System Address Map R 4.4.3.1. SMM Space Restrictions If any of the following conditions are violated the results of SMM accesses are unpredictable and may cause the system to hang: 1. The Compatible SMM space must not be set-up as cacheable. 2. High or TSEG SMM transaction address space must not overlap address space assigned to DDR SDRAM or to any “PCI” devices (including Hub Interface and graphics devices). This is a BIOS responsibility. 3. Both D_OPEN and D_CLOSE must not be set to 1 at the same time. 4. When TSEG SMM space is enabled, the TSEG space must not be reported to the OS as available . This is a BIOS responsibility. 4.4.3.2. SMM Space Definition SMM space is defined by its addressed SMM space and its DDR SDRAM SMM space. The addressed SMM space is defined as the range of bus addresses used by the CPU to access SMM space. DDR SDRAM SMM space is defined as the range of physical DDR SDRAM locations containing the SMM code. SMM space can be accessed at one of three transaction address ranges: Compatible, High, and TSEG. The Compatible and TSEG SMM space is not remapped and therefore the addressed and DDR SDRAM SMM space is the same address range. Since the High SMM space is remapped the addressed and DDR SDRAM SMM space is a different address range. Note that the High DDR SDRAM space is the same as the Compatible Transaction Address space. The table below describes three unique address ranges: 1. Compatible Transaction Address (Adr C) 2. High Transaction Address (Adr H) 3. TSEG Transaction Address (Adr T) These abbreviations are used later in Table 25. Table 25. SMM Space Transaction Handling 4.4.4. SMM Space Enabled Transaction Address Space (Adr) DRAM Space (DRAM) Compatible (C) A0000h to BFFFFh A0000h to BFFFFh High (H) 0FEDA0000h to 0FEDBFFFFh A0000h to BFFFFh TSEG (T) (TOM-TSEG_SZ) to TOM (TOM-TSEG_SZ) to TOM System Memory Shadowing Any block of System Memory that can be designated as read-only or write-only can be “shadowed” into GMCH DDR SDRAM. Typically this is done to allow ROM code to execute more rapidly out of main DDR SDRAM. ROM is used as a read-only during the copy process while DDR SDRAM at the same time is designated write-only. After copying, the DDR SDRAM is designated read-only so that ROM is shadowed. CPU bus transactions are routed accordingly. 4.4.5. I/O Address Space The GMCH does not support the existence of any other I/O devices beside itself on the CPU bus. The GMCH generates Hub Interface or PCI bus cycles for all CPU I/O accesses that it does not claim. Within Intel® 852GM/852GMV Chipset GMCH Datasheet 119 Intel 852GM/852GMV GMCH System Address Map R the host bridge the GMCH contains two internal registers in the CPU I/O space, Configuration Address Register (CONFIG_ADDRESS) and the Configuration Data Register (CONFIG_DATA). These locations are used to implement configuration space access mechanism and as described in the Configuration register section. The CPU allows 64kB +3B to be addressed within the I/O space. The GMCH propagates the CPU I/O address without any translation on to the destination bus and therefore provides addressability for 64 k+3 byte locations. Note that the upper 3 locations can be accessed only during I/O address wrap-around when CPU bus A16# address signal is asserted. A16# is asserted on the CPU bus whenever an I/O access is made to 4 bytes from address 0FFFDh, 0FFFEh, or 0FFFFh. A16# is also asserted when an I/O access is made to 2 bytes from address 0FFFFh. A set of I/O accesses (other than ones used for configuration space access) is consumed by the internal graphics device if it is enabled. The mechanisms for internal graphics IO decode and the associated control is explained later. The I/O accesses (other than ones used for configuration space access) are forwarded normally to the Hub Interface. The GMCH will not post I/O write cycles to IDE. 4.4.6. GMCH Decode Rules and Cross-Bridge Address Mapping The address map described above applies globally to accesses arriving on any of the three interfaces i.e. Host bus, IGD, and Hub Interface. 4.4.7. Hub Interface Decode Rules The GMCH accepts accesses from Hub Interface to the following address ranges: All memory read and write accesses to Main DDR SDRAM including PAM region (except SMM space) All memory read/write accesses to the Graphics Aperture (DRAM) defined by APBASE and APSIZE. Memory writes to VGA range. All memory reads from the Hub Interface A that are targeted > 4-GB System Memory range will be terminated with Master Abort completion, and all memory writes (>4-GB) from the Hub Interface will be ignored. Hub Interface System Memory accesses that fall elsewhere within the System Memory range are considered invalid and will be remapped to System Memory address 0h, snooped on the host bus, and dispatched to DDR SDRAM. Reads will return all 1’s with Master Abort completion. Writes will have BE’s deasserted and will terminate with Master Abort if completion is required. I/O cycles will not be accepted. They are terminated with Master Abort completion packets. 120 Intel® 852GM/852GMV Chipset GMCH Datasheet Intel 852GM/852GMV GMCH System Address Map R 4.4.7.1. Hub Interface Accesses to GMCH that Cross Device Boundaries Hublink accesses are limited to 256-bytes but have no restrictions on crossing address boundaries. A single Hublink request may therefore span device boundaries (DDR SDRAM) or cross from valid addresses to invalid addresses (or vise versa). The GMCH does not support transactions that cross device boundaries. For reads and for writes requiring completion, the GMCH will provide separate completion status for each naturally aligned 32 -or 64 -byte block. If the starting address of a transaction hits a valid address, the portion of a request that hits that target device (DDR SDRAM) will complete normally. The remaining portion of the access that crosses a device boundary (targets a different device than that of the starting address) or hits an invalid address will be remapped to System Memory address 0h, snooped on the host bus, and dispatched to DDR SDRAM. Reads will return all 1’s with Master Abort completion. Writes will have BE’s deasserted and will terminate with Master Abort if completion is required. If the starting address of a transaction hits an invalid address the entire transaction will be remapped to System Memory address 0h, snooped on the host bus, and dispatched to DDR SDRAM. Reads will return all 1’s with Master Abort completion. Writes will have BE’s deasserted and will terminate with Master Abort if completion is required. Intel® 852GM/852GMV Chipset GMCH Datasheet 121 Intel 852GM/852GMV GMCH System Address Map R This page intentionally left blank. 122 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R 5. Functional Description 5.1. Host Interface Overview The GMCH Processor System Bus uses source synchronous transfer for the address and data signals. The address signals are double pumped and two addresses can be generated every bus clock. At 100MHz bus frequency, the two address signals run at 200-MT/s for a maximum address queue rate of 50M addresses/sec. The data is quad pumped and an entire 64B cache line can be transferred in two bus clocks. At 100-MHz bus frequency, the data signals run at 400 MHz for a maximum bandwidth of 3.2GB/s. The 852GM/852GMV GMCH has In-Order Queue to support outstanding pipelined address requests on the host bus. 5.2. Dynamic Bus Inversion The GMCH supports Dynamic Bus Inversion (DBI) when driving and receiving data from the Host Bus. DBI limits the number of data signals that are driven to a low voltage on each quad pumped data phase. This decreases the power consumption of the GMCH. DINV[3:0] indicates if the corresponding 16 bits of data are inverted on the bus for each quad pumped data phase: Table 26. Relation of DBI Bits to Data Bits DINV[3:0] Data Bits DINV[0]# HD[15:0]# DINV[1]# HD[31:16]# DINV[2]# HD[47:32]# DINV[3]# HD[63:48]# Whenever the CPU or the GMCH drives data, each 16-bit segment is analyzed. If more than eight of the 16 signals would normally be driven low on the bus the corresponding DINV# signal will be asserted and the data will be inverted prior to being driven on the bus. Whenever the CPU or the GMCH receives data it monitors DINV[3:0]# to determine if the corresponding data segment should be inverted. 5.2.1. System Bus Interrupt Delivery Each processor supports System Bus interrupt delivery. It does not support the APIC serial bus interrupt delivery mechanism. Interrupt related messages are encoded on the System Bus as “Interrupt Message Transactions”. In a GMCH platform, System Bus interrupts may originate from the processor on the System Bus, or from a downstream device on Hub Interface. In a GMCH platform, the ICH4-M contains IOxAPICs and its interrupts are generated as upstream Hub Interface Memory Writes. Furthermore, PCI 2.2 defines MSI’s (Message Signaled Interrupts) that are also in the form of Memory Writes. A PCI 2.2 device may generate an interrupt as an MSI cycle on its PCI bus instead of asserting a hardware signal to the IOxAPIC. The MSI may be directed to the IOxAPIC, which in turn generates an interrupt as an upstream Hub Interface Memory Write. Alternatively the MSI may be directed directly to the System bus. The target of an MSI is dependent on Intel® 852GM/852GMV Chipset GMCH Datasheet 123 Functional Description R the address of the interrupt Memory Write. The GMCH forwards inbound Hub Interface Memory Writes to address 0FEEx_xxxxh, to the System bus as “Interrupt Message Transactions”. 5.2.2. Upstream Interrupt Messages The GMCH accepts message based interrupts from its Hub Interface and forwards them to the System bus as Interrupt Message Transactions. The interrupt messages presented to the GMCH are in the form of Memory Writes to address 0FEEx_xxxxh. At the Hub Interface the Memory Write interrupt message is treated like any other Memory Write; it is either posted into the inbound data buffer (if space is available) or retried (if data buffer space is not immediately available). Once posted, the Memory Write from the Hub Interface, to address 0FEEx_xxxxh, is decoded as a cycle that needs to be propagated by the GMCH to the System bus as an Interrupt Message Transaction. 5.3. System Memory Interface 5.3.1. DDR SDRAM Interface Overview The GMCH supports DDR SDRAM at 200/266-MHz and includes the following support: Up to 1-GB of PC1600/PC2100 DDR SDRAM (Intel 852GM/852GMV GMCH) PC1600/2100 unbuffered 200-pin DDR SDRAM SO-DIMMs Maximum of two SO-DIMMs, single-sided and/or double-sided The 2-bank select lines SBA[1:0] and the 13 Address lines SMA[12:0] allow the GMCH to support 64bit wide SO-DIMMs using 128-Mb, 256-Mb, and 512-Mb DDR SDRAM technology. While address lines SMA[9:0] determine the starting address for a burst, burst length can only be 4. Four chip selects SCS[3:0]# lines allow a maximum of two rows of single-sided DDR SDRAM SO-DIMMs and four rows of double-sided DDR SDRAM SO-DIMMs. The GMCH main System Memory controller targets CAS latencies of 2 and 2.5 for DDR SDRAM. The GMCH provides refresh functionality with a programmable rate (normal DDR SDRAM rate is 1 refresh/15.6 s). For write operations of less than a full cache line, GMCH will perform a cache-line read and into the write buffer and perform byte-wise write-merging in the write buffer. 5.3.2. System Memory Organization and Configuration 5.3.2.1. Configuration Mechanism for SO-DIMMs Detection of the type of DDR SDRAM installed on the SO-DIMM is supported via Serial Presence Detect mechanism as defined in the JEDEC 200-pin SO- DIMM specification. Before any cycles to the System Memory interface can be supported, the GMCH DDR SDRAM registers must be initialized. The GMCH must be configured for operation with the installed System Memory types. Detection of System Memory type and size is done via the System Management Bus (SMB) interface on the ICH4-M. This two-wire bus is used to extract the DDR SDRAM type and size information from the Serial Presence Detect port on the DDR SDRAM SO-DIMMs. DDR SDRAM SODIMMs contain a 5-pin Serial Presence Detect interface, including SCL (serial clock), SDA (serial data) and SA[2:0]. Devices on the SMBus have a 7-bit address. For the DDR SDRAM SO-DIMMs, the upper four bits are fixed at 1010. The lower three bits are strapped on the SA[2:0] pins. SCL and SDA are connected directly to the System Management Bus on the ICH4-M. Thus data is read from the Serial 124 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R Presence Detect port on the SO-DIMMs via a series of I/O cycles to the south bridge. The BIOS needs to determine the size and type of System Memory used for each of the rows of System Memory in order to properly configure the GMCH System Memory interface. For SMBus Configuration and Access of the Serial Presence Detect Ports, refer to the Intel 82801DBM I/O Controller Hub 4 Mobile (ICH4-M) Datasheet (order number: 252337) for more detail. 5.3.2.2. System Memory Register Programming This section provides an overview of how the required information for programming the DDR SDRAM registers is obtained from the Serial Presence Detect ports on the SO-DIMMs. The Serial Presence Detect ports are used to determine Refresh Rate, MA and MD Buffer Strength, Row Type (on a row by row basis), DDR SDRAM Timings, Row Sizes and Row Page Sizes. The following table lists a subset of the data available through the on board Serial Presence Detect ROM on each SO-DIMM. Table 27. Data Bytes on SO-DIMM Used for Programming DRAM Registers Byte Function 2 System Memory Type (DDR SDRAM) 3 Number of Row Addresses, not counting Bank Addresses 4 Number of Column Addresses 5 Number of SO-DIMM banks 11 No ECC 12 Refresh Rate/Type 17 Number Banks on each Device The above table is only a subset of the defined SPD bytes on the SO-DIMMs. These bytes collectively provide enough data for programming the GMCH DDR SDRAM registers. 5.3.3. DDR SDRAM Performance Description The overall System Memory performance is controlled by the DDR SDRAM timing register, pipelining depth used in GMCH, System Memory speed grade and the type of DDR SDRAM used in the system. Besides this, the exact performance in a system is also dependent on the total System Memory supported, external buffering and System Memory array layout. The most important contribution to overall performance by the System Memory controller is to minimize the latency required to initiate and complete requests to System Memory, and to support the highest possible bandwidth (full streaming, quick turn-arounds). One measure of performance is the total flight time to complete a cache line request. A true discussion of performance really involves the entire chipset, not just the System Memory controller. Intel® 852GM/852GMV Chipset GMCH Datasheet 125 Functional Description R 5.4. Integrated Graphics Overview The GMCH provides a highly integrated graphics accelerator and PCI set while allowing a flexible Integrated System Graphics solution. Figure 6. Intel 852GM/852GMV GMCH Graphics Block Diagram DDR/SDRAM Memory Control DAC Overlay Video Engine (MPEG2 Decode) Instr./ Data Sprite Cursor 3D Engine Primary Display Scan Conversion Texture Engine Raster Engine LVDS Cursor 2D Engine Setup/Transform Pipe A Alpha Blend/ Gamma/ CRC Pipe B Cntl Mux Port DVOC Secondary Display Display C 2nd Overlay DDC A_gmch_blk High bandwidth access to data is provided through the System Memory port. The GMCH uses a tiling architecture to minimize page miss latencies and thus maximize effective rendering bandwidth. 5.4.1. 3D/2D Instruction Processing The GMCH contains an extensive set of instructions that control various functions including 3D rendering, BLT operations, display, MPEG decode acceleration, and overlay. The 3D instructions set 3D pipeline states and control the processing functions. The 2D instructions provide an efficient method for invoking BLT operations. 126 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R 5.4.2. 3D Engine The 3D engine of the GMCH has been designed with a deeply pipelined architecture, where performance is maximized by allowing each stage of the pipeline to simultaneously operate on different primitives or portions of the same primitive. The GMCH supports the following: Perspective-correct Texture Mapping, Multitextures Embossed and Dot-Product Bump-Mapping Cubic Environment Maps Bilinear, Trilinear, and Anisotropic MIP mapped filtering Gouraud shading Alpha-blending Per-Vertex and Per- Pixel Fog Z/W Buffering These features are independently controlled via a set of 3D instructions. The 3D pipeline subsystem performs the 3D rendering acceleration. The main blocks of the pipeline are the Setup Engine, Scan Converter, Texture Pipeline, and Raster Pipeline. A typical programming sequence would be to send instructions to set the state of the pipeline followed by rendering instructions containing 3D primitive vertex data. 5.4.2.1. Setup Engine The GMCH 3D setup engine takes the input data associated with each vertex of a 3D primitive and computes the various parameters required for scan conversion. In formatting this data, the GMCH maintains sub-pixel accuracy. The per-vertex data is converted into gradients that can be used to interpolate the data at any pixel within a polygon (colors, alpha, Z or W depth, fog, and texture coordinates). The pixels covered by a polygon are identified and per-pixel texture addresses are calculated. 5.4.2.2. Viewport Transform and Perspective Divide A 3D-geometry pipeline typically involves transformation of vertices from model space to clipping space followed by clip test and clipping. Lighting can be performed during the transformation or at any other point in the pipeline. After clipping, the next stage involves perspective divide followed by transformation to the viewport or screen space. The GMCH can support Viewport Transform and Perspective Divide portion of the 3D geometry pipeline in hardware. 5.4.2.3. 3D Primitives and Data Formats Support The 3D primitives rendered by the GMCH are points, lines, discrete triangles, line strips, triangle strips, triangle fans, and polygons. In addition to this, the GMCH supports DirectX’s* Flexible Vertex Format* (FVF), which enables the application to specify a variable length parameter list, obviating the need for sending unused information to the hardware. Strips, Fans, and Indexed Vertices as well as FVF improves delivered vertex rate to the setup engine significantly. Intel® 852GM/852GMV Chipset GMCH Datasheet 127 Functional Description R 5.4.2.4. Pixel Accurate Fast Scissoring and Clipping Operation The GMCH supports clipping to a scissoring rectangle within the drawing window. The GMCH clipping and scissoring in hardware reduce the need for software to process polygons, and thus improves performance. During the setup stage, the GMCH clips polygons to the drawing window. The scissor rectangle accelerates the clipping process by allowing the driver to clip to a bigger region than the hardware renders to. The scissor rectangle is pixel accurate, and independent of line and point width. The GMCH supports a single scissor box rectangle. 5.4.2.5. Backface Culling As part of the setup, the GMCH can discard polygons from further processing, if they are either facing away from or towards the user’s viewpoint. This operation, referred to as “Back Face Culling” is accomplished based on the “clockwise” or “counter-clockwise” orientation of the vertices on a primitive. This can be enabled or disabled by the driver. 5.4.2.6. Scan Converter The Scan Converter takes the vertex and edge information is used to identify all pixels that are affected by features being rendered. It works on a per-polygon basis, and one polygon may be entering the pipeline while calculations finish on another. 5.4.2.7. Texture Engine The GMCH allows an image pattern, or video to be placed on the surface of a 3D polygon. The texture engine performs texture color or chromakey matching texture filtering (an-isotropic, tri-linear, and bilinear), and YUV to RGB conversion. As texture sizes increase beyond the bounds of graphics memory, executing textures from graphics memory becomes impractical. Every rendering pass would require copying each and every texture in a scene from System Memory to graphics memory, then using the texture, and finally overwriting the local memory copy of the texture by copying the next texture into graphics memory. The GMCH, using Intel’s Direct Memory Execution model, simplifies this process by rendering each scene using the texture located in System Memory. The GMCH includes a cache controller to avoid frequent memory fetches of recently used texture data. 5.4.2.8. Perspective Correct Texture Support A textured polygon is generated by mapping a 2D texture pattern onto each pixel of the polygon. A texture map is like wallpaper pasted onto the polygon. Since polygons are rendered in perspective, it is important that texture be mapped in perspective as well. Without perspective correction, texture is distorted when an object recedes into the distance. Perspective correction involves a compute-intensive “per-pixel-divide” operation on each pixel. Perspective correction is necessary for realistic 3D graphics. 5.4.2.9. Texture Decompression As the textures’ average size gets larger with higher color depth and multiple textures become the norm, it becomes increasingly important to provide support for compressed textures. DirectX* supports Texture Compression/Decompression to reduce the bandwidth required to deliver textures. The GMCH supports several compressed texture formats (DirectX: DXT1, DXT2, DXT3, DXT4, DXT5) and OpenGL FXT1 formats. 128 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R 5.4.2.10. Texture Chromakey Chromakey is a method for removing a specific color or range of colors from a texture map before it is applied to an object. For “nearest” texture filter modes, removing a color simply makes those portions of the object transparent (the previous contents of the back buffer show through). For “linear “ texture filtering modes, the texture filter is modified if only the non-nearest neighbor texels match the key (range). Chromakeying can be performed for both paletted and non-paletted textures, and removes texels that fall within a specified color range. The Chromakey mode refers to testing the ARGB or YUV components to see if they fall between high and low state variable values. If the color of a texel contribution is in this range and chromakey is enabled, then this contribution is removed from the resulting pixel color. 5.4.2.11. Anti-Aliasing Aliasing is one of the artifacts that degrade image quality. In its simplest manifestation, aliasing causes the jagged staircase effects on sloped lines and polygon edges. Another artifact is the moiré patterns, which occur as a result of the fact that there is very small number of pixels available on screen to contain the data of a high-resolution texture map. Full Scene Anti-Aliasing uses super-sampling, which means that the image is rendered internally at a higher resolution than it is displayed on screen. The GMCH can render internally at 1600x1200 and then this image is down-sampled (via a Bilinear filter) to the screen resolution of 640x480 and 800x600. Full Scene Anti-aliasing removes jaggies at the edges as well as moiré patterns. The GMCH renders the super-sampled image up to 2K x 2K pixel dimensions. The GMCH then reads it as a texture and bilinear filters it to the final resolution. 5.4.2.12. Texture Map Filtering Many texture-mapping modes are supported. Perspective correct mapping is always performed. As the map is fitted across the polygon, the map can be tiled, mirrored in either the U or V directions, or mapped up to the end of the texture and no longer placed on the object (this is known as clamp mode). The way a texture is combined with other object attributes is also definable. The GMCH supports up to 12 Levels-of-Detail (LODs) ranging in size from 2048x2048 to 1x1 texels. (A texel is defined as a texture map element.) Included in the texture processor is a texture cache, which provides efficient MIP-mapping. The GMCH supports 7 types of texture filtering: Nearest (also known as Point Filtering): Texel with coordinates nearest to the desired pixel is used. (This is used if only one LOD is present.) Linear (also known as Bilinear Filtering): A weighted average of a 2x2 area of texels surrounding the desired pixel is used. (This is used if only one LOD is present.) Nearest MIP Nearest (also known as Point Filtering): This is used if many LODs are present. The nearest LOD is chosen and the texel with coordinates nearest to the desired pixel are used. Linear MIP Nearest (Bilinear MIP Mapping): This is used if many LODs are present. The nearest LOD is chosen and a weighted average of a 2x2 area of texels surrounding the desired pixel is used (four texels). This is also referred to as Bilinear MIP Mapping. Nearest MIP Linear (Point MIP Mapping): This is used if many LODs are present. Two appropriate LODs are selected and within each LOD the texel with coordinates nearest to the desired pixel are selected. The Final texture value is generated by linear interpolation between the two texels selected from each of the MIP Maps. Intel® 852GM/852GMV Chipset GMCH Datasheet 129 Functional Description R Linear MIP Linear (Trilinear MIP Mapping): This is used if many LODs are present. Two appropriate LODs are selected and a weighted average of a 2x2 area of texels surrounding the desired pixel in each MIP Map is generated (four texels per MIP Map). The Final texture value is generated by linear interpolation between the two texels generated for each of the MIP Maps. Trilinear MIP Mapping is used minimize the visibility of LOD transitions across the polygon. Anisotropic MIP Nearest (Anisotropic Filtering): This filter can be used when textured object pixels map back to significantly non-square regions of the texture (e.g., when the texture is scaled in one screen direction than the other screen direction). Both DirectX and OGL (Rev.1.1) allow support for all these filtering modes. 5.4.2.13. Multiple Texture Composition The GMCH also performs multiple texture composition. This allows the combination of two or greater MIP maps to produce a new one with new LODs and texture attributes in a single or iterated pass. The setup engine supports up to four texture map coordinates in as single pass. The GMCH allows up to two Bilinear MIP Maps or a single Trilinear MIP Map to be composited in a single pass. Greater than two Bilinear MIP Maps or more than one Trilinear MIP Map would require multiple passes. The actual blending or composition of the MIP Maps is done in the raster engine. The texture engine provides the required texels including blending information. Flexible vertex format support allows multi-texturing because it makes it possible to pass more than one texture in the vertex structure. 5.4.2.14. Cubic Environment Mapping Environment maps allow applications to render scenes with complex lighting and reflections while significantly decreasing CPU load. There are several methods to generate environment maps such as spherical, circular and cubic. The GMCH supports cubic reflection mapping over spherical and circular since it is the best choice to provide real-time environment mapping for complex lighting and reflections. Cubic Mapping supports a texture map for each of the 6 cube faces. These can be generated by pointing a camera with a 90-degree field-of-view in the appropriate direction. Per-vertex vectors (normal, reflection or refraction) are interpolated across the polygon and the intersection of these vectors with the cube texture faces are calculated. Texel values are then read from the intersection point on the appropriate face and filtered accordingly. 5.4.2.15. Bump Mapping The GMCH only supports embossed and dot product bump mapping, not environment bump mapping. 5.4.3. Raster Engine The Raster Engine is where the color data such as fogging, specular RGB, texture map blending, etc. is processed. The final color of the pixel is calculated and the RGB value combined with the corresponding components resulting from the Texture Engine. These textured pixels are modified by the specular and fog parameters. These specular highlighted, fogged, textured pixels are color blended with the existing values in the frame buffer. In parallel, stencil, alpha, and depth buffer tests are conducted which will determine whether the Frame and Depth Buffers will be updated with the new pixel values. 130 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R 5.4.3.1. Texture Map Blending Multiple Textures can be blended together in an iterative process and applied to a primitive. The GMCH allows up to four distinct or shared texture coordinates and texture maps to be specified onto the same polygon. Also, the GMCH supports a texture coordinate set to access multiple texture maps. State variables in multiple textures are bound to texture coordinates, texture map or texture blending. 5.4.3.2. Combining Intrinsic and Specular Color Components The GMCH allows an independently specified and interpolated “specular RGB” attribute to be added to the post-texture blended pixel color. This feature provides a full RGB specular highlight to be applied to a textured surface, permitting a high quality reflective colored lighting effect not available in devices, which apply texture after the lighting components have been combined. If specular-add state variable is disabled, only the resultant colors from the map blending are used. If this state variable is enabled, the specular RGB color is added to the RGB values from the output of the map blending. Intel® 852GM/852GMV Chipset GMCH Datasheet 131 Functional Description R 5.4.3.3. Color Shading Modes The Raster Engine supports the flat and Gouraud shading modes. These shading modes are programmed by the appropriate state variables issued through the command stream. Flat shading is performed by smoothly interpolating the vertex intrinsic color components (Red, Green, Blue), Specular (R, G, B), Fog, and Alpha to the pixel, where each vertex color has the same value. The setup engine substitutes one of the vertex’s attribute values for the other two vertices attribute values thereby creating the correct flat shading terms. This condition is set up by the appropriate state variables issued prior to rendering the primitive. Gouraud shading is performed by smoothly interpolating the vertex intrinsic color components (Red, Green, Blue). Specular (RGB), Fog, and Alpha to the pixel, where each vertex color has a different value. All the attributes can be selected independently to one of the shading mode by setting the appropriate value state variables. 5.4.3.4. Color Dithering Color Dithering in the GMCH helps to hide color quantization errors for 16-bit color buffers. Color Dithering takes advantage of the human eye’s propensity to “average” the colors in a small area. Input color, alpha, and fog components are converted from 8-bit components to 5-bit or 6-bit component by dithering. Dithering is performed on blended textured pixels. In 32-bit mode, dithering is not performed. 5.4.3.5. Vertex and Per Pixel Fogging Fogging is used to create atmospheric effects such as low visibility conditions in flight simulator-type games. It adds another level of realism to computer-generated scenes. Fog can be used for depth cueing or hiding distant objects. With fog, distant objects can be rendered with fewer details (less polygons), thereby improving the rendering speed or frame rate. Fog is simulated by attenuating the color of an object with the fog color as a function of distance, and the greater the distance, the higher the density (lower visibility for distant objects). There are two ways to implement the fogging technique: per-vertex (linear) fogging and per-pixel (non-linear) fogging. The per-vertex method interpolates the fog value at the vertices of a polygon to determine the fog factor at each pixel within the polygon. This method provides realistic fogging as long as the polygons are small. With large polygons (such as a ground plane depicting an airport runway), the per-vertex technique results in unnatural fogging. The GMCH supports both types of fog operations, vertex and per pixel or table fog. If fog is disabled, the incoming color intensities are passed unchanged to the destination blend unit. If fog is enabled, the incoming pixel color is blended with the fog color based on a fog coefficient on a per pixel basis using the following equation before sending to the destination blend unit. 5.4.3.6. Alpha Blending Alpha Blending in the GMCH adds the material property of transparency or opacity to an object. Alpha blending combines a source pixel color and alpha component with a destination pixel color and alpha component. For example, this is so that a glass surface on top (source) of a red surface (destination) would allow much of the red base color to show through. Blending allows the source and destination color values to be multiplied by programmable factors and then combined via a programmable blend function. The combined and independent selection of factors and blend functions for color and alpha is supported. 132 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R 5.4.3.7. Color Buffer Formats: (Destination Alpha) The Raster Engine supports 8-bit, 16-bit, and 32-bit Color Buffer Formats. The 8-bit format is used to support planar YUV420 format, which is used only in Motion Compensation and Arithmetic Stretch format. The bit format of Color and Z is allowed to mix. The GMCH can support an 8-bit destination alpha in 32-bit mode. Destination alpha is supported in 16bit mode in 1555 or 4444 format. The Intel 852GM/852GMV GMCH does not support general 3D rendering to 8-bit surfaces. 8-bit destinations are supported for operations on planar YUV surfaces (e.g., stretch Blts) where each 8-bit color component is written in a separate pass. The GMCH also supports a mode where both U and V planar surfaces can be operated on simultaneously. The frame buffer of the GMCH contains at least two hardware buffers - the Front Buffer (display buffer) and the Back Buffer (rendering buffer). While the back buffer may actually coincide with (or be part of) the visible display surface, a separate (screen or window-sized) back buffer is typically used to permit double-buffered drawing. That is, the image being drawn is not visible until the scene is complete and the back buffer made visible or copied to the front buffer via a 2D BLT operation. Rendering to one buffer and displaying from the other buffer removes image tearing artifacts. Additionally, more than two back buffers (e.g., triple-buffering) can be supported. 5.4.3.8. Depth Buffer The Raster Engine is able to read and write from this buffer and use the data in per fragment operations that determine resultant color and depth value of the pixel for the fragment are to be updated or not. Typical applications for entertainment or visual simulations with exterior scenes require far/near ratios of 1000 to 10000. At 1000, 98% of the range is spent on the first 2% of the depth. This can cause hidden surface artifacts in distant objects, especially when using 16-bit depth buffers. A 24-bit Z-buffer provides 16 million Z-values as opposed to only 64 k with a 16-bit Z-buffer. With lower Z-resolution, two distant overlapping objects may be assigned the same Z-value. As a result, the rendering hardware may have a problem resolving the order of the objects, and the object in the back may appear through the object in the front. By contrast, when w (or eye-relative z) is used, the buffer bits can be more evenly allocated between the near and far clip planes in world space. The key benefit is that the ratio of far and near is no longer an issue, and allows applications to support a maximum range of miles, yet still get reasonably accurate depth buffering within inches of the eye point. The selection of depth buffer size is relatively independent of the color buffer. A 16-bit Z/W or 24-bit Z/W buffer can be selected with a 16-bit color buffer. Z buffer is not supported in 8-bit mode. 5.4.3.9. Stencil Buffer The Raster Engine provides 8-bit stencil buffer storage in 32-bit mode and the ability to perform stencil testing. Stencil testing controls 3D drawing on a per pixel basis and conditionally eliminates a pixel on the outcome of a comparison between a stencil reference value and the value in the stencil buffer at the location of the source pixel being processed. They are typically used in multipass algorithms to achieve special effects, such as decals, outlining, shadows, and constructive solid geometry rendering. One of three possible stencil operations is performed when stencil testing is enabled. The stencil operation specifies how the stencil buffer is modified when a fragment passes or fails the stencil test. The selection of the stencil operation to be performed is based upon the result of the stencil test and the depth test. A stencil write mask is also included that controls the writing of particular bits into the stencil buffer. It selects between the destination value and the updated value on a per-bit basis. The mask is 8bit wide. Intel® 852GM/852GMV Chipset GMCH Datasheet 133 Functional Description R 5.4.3.10. Projective Textures The GMCH supports two simultaneous projective textures at full rate processing. These textures require three floating-point texture coordinates to be included in the FVF format. Projective textures enable special effects such as projecting spot light textures obliquely onto walls, etc. 5.4.4. 2D Engine The GMCH provides an extensive set of 2D instructions and 2D HW acceleration for block transfers of data (BLTs). The BLT engine provides the ability to copy a source block of data to a destination and perform operations (e.g., ROP1, ROP2, and ROP3) on the data using a pattern, and/or another destination. The Stretch BLT engine is used to move source data to a destination that need not be the same size, with source transparency. Performing these common tasks in hardware reduces CPU load, and thus improves performance. 5.4.4.1. 256-Bit Pattern Fill and BLT Engine Use of this BLT engine accelerates the Graphical User Interface (GUI) of Microsoft* Windows*. The GMCH BLT Engine provides hardware acceleration of block transfers of pixel data for many common Windows operations. The term BLT refers to a block transfer of pixel data between System Memory locations. The BLT engine can be used for the following: Move rectangular blocks of data between System Memory locations Data Alignment Perform logical operations (raster ops) The rectangular block of data does not change as it is transferred between System Memory locations. Data to be transferred can consist of regions of System Memory, patterns, or solid color fills. A pattern will always be 8x8 pixels wide and may be 8-bits, 16-bits, or 32-bits per pixel. The GMCH BLT engine has the ability to expand monochrome data into a color depth of 8-bits, 16-bits, or 32-bits. BLTs can be either opaque or transparent. Opaque transfers, move the data specified to the destination. Transparent transfers compare destination color to source color and write according to the mode of transparency selected. Data is horizontally and vertically aligned at the destination. If the destination for the BLT overlaps with the source System Memory location, the GMCH can specify which area in System Memory to begin the BLT transfer. Hardware is included for all 256 raster operations (Source, Pattern, and Destination) defined by Microsoft, including transparent BLT. The GMCH has instructions to invoke BLT operations, permitting software to set up instruction buffers and use batch processing as described in the Instruction Processing Section. The GMCH can perform hardware clipping during BLTs. 5.4.4.2. Alpha Stretch BLT The stretch BLT function can stretch source data in the X and Y directions to a destination larger or smaller than the source. Stretch BLT functionality expands a region of System Memory into a larger or smaller region using replication and interpolation. The stretch BLT function also provides format conversion and data alignment. 134 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R 5.4.5. Planes and Engines The GMCH display can be functionally delineated into Planes and Engines (Pipes and Ports). A plane consists of rectangular shaped image that has characteristics such as source, size, position, method, and format. These planes get attached to source surfaces, which are rectangular System Memory surfaces with a similar set of characteristics. They are also associated with a particular destination pipe. A pipe consists of a set of planes that will be combined and a timing generator. A port is the destination for the result of the pipe. Therefore, planes are associated with pipes and pipes are associated with ports. 5.4.5.1. Dual Pipe Independent Display Functionality The display consists of two display pipes, A and B. Pipes have a set of planes that are assigned to them as sources. The analog display port may only use Pipe A or Pipe B, the DVO C port may use either Pipe A or Pipe B, and the LFP LVDS interface may only use Pipe B. This limits the resolutions available on a digital display when an analog CRT is active. Table 28. Dual Display Usage Model (Intel 852GM/852GMV GMCH) 5.4.6. Display Pipe A Display Pipe B CRT LVDS DVO C CRT CRT DVO C DVO C LVDS CRT/DVO C LVDS Hardware Cursor Plane The GMCH supports two hardware cursors. The cursor plane is one of the simplest display planes. With a few exceptions, has a fixed size of 64 x 64 and a fixed Z-order (top). In legacy modes, cursor can cause the display data below it to be inverted. In the alpha blend mode, true color cursor data can be alpha blended into the display stream. It can be assigned to either display pipe A or display pipe B and dynamically flipped from one to the other when both are running. 5.4.6.1. Cursor Color Formats Color data can be in an indexed format or a true color format. Indexed data uses the entries in the fourentry cursor palette to convert the two-bit index to a true color format before being passed to the blenders. The index can optionally specify that a cursor pixel be transparent or cause an inversion of the pixel value below it or one of two colors from the cursor palette. Blending of YUV or RGB data is only supported with planes that have data of the same format. 5.4.6.2. Popup Plane (Second Cursor) The popup plane is used for control functions in mobile applications. Only the hardware cursor has a higher Z-order precedence over the hardware icon. In standard modes (non-VGA) either cursor A or cursor B can be used as a Popup Icon. For VGA modes, 32-bpp data format is not supported. Intel® 852GM/852GMV Chipset GMCH Datasheet 135 Functional Description R 5.4.6.3. Popup Color Formats Source color data for the popup is in an indexed format. Indexed data uses the entries in the four-entry cursor palette to convert the two-bit index to a true color format before being passed to the blenders. Blending of color data is only supported with data of the same format. 5.4.7. Overlay Plane The overlay engine provides a method of merging either video capture data (from an external Video Capture device) or data delivered by the CPU, with the graphics data on the screen. 5.4.7.1. Multiple Overlays (Display C) A single overlay plane and scalar is implemented. This overlay plane can be connected to the primary display, secondary display or in bypass mode. In the default mode, it appears on the primary display. The overlay may be displayed in a multi-monitor scenario for single-pipe simultaneous displays only. Picture-in-Picture feature is supported via software through the arithmetic stretch blitter. 5.4.7.2. Source/Destination Color/Chromakeying Overlay source/destination chromakeying enables blending of the overlay with the underlying graphics background. Destination color-/chromakeying can be used to handle occluded portions of the overlay window on a pixel-by-pixel basis that is actually an underlay. Destination color keying supports a specific color (8-bit or 15-bit) mode as well as 32-bit alpha blending. Source color/chromakeying is used to handle transparency based on the overlay window on a pixel-bypixel basis. This is used when “blue screening” an image to overlay the image on a new background later. 5.4.7.3. Gamma Correction To compensate for overlay color intensity loss, the overlay engine supports independent gamma correction. This allows the overlay data to be converted to linear data or corrected for the display device when not blending. 5.4.7.4. YUV to RGB Conversion The format conversion can be bypassed in the case of RGB source data. 5.4.7.5. Color Control Color control provides a method of changing the color characteristics of the pixel data. It is applied to the data while in YUV format and uses input parameters such as brightness, saturation, hue (tint) and contrast. This feature is supplied for the overlay only and works in YUV formats only. 5.4.7.6. Dynamic Bob and Weave Interlaced data that originates from a video camera creates two fields that are temporally offset by 1/60 of a second. There are several schemes to de-interlace the video stream: line replication, vertical filtering, field merging, and vertical temporal filtering. Field merging takes lines from the previous field and inserts them into the current field to construct the frame – this is known as Weaving. This is the best solution for images with little motion; however, showing a frame that consists of the two fields will have 136 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R serration or feathering of moving edges when there is motion in the scene. Vertical filtering or “Bob” interpolates adjacent lines rather replicating the nearest neighbor. This is the best solution for images with motion however, it will have reduced spatial resolution in areas that have no motion and introduce jaggies. In absence of any other de-interlacing, these form the baseline and are supported by the GMCH. 5.4.8. Video Functionality The GMCH supports MPEG-2 decoding hardware, sub-picture support and DTV all format decode. 5.4.8.1. MPEG-2 Decoding The GMCH MPEG2 Decoding supports Hardware Motion Compensation (HWMC). The GMCH can accelerate video decoding for the following video coding standards: MPEG-2 support MPEG-1: Full feature support H.263 support MPEG-4: Only supports some features in the simple profile. The GMCH HWMC interface is optimized for Microsoft’s* VA API. Hardware Video Acceleration API (HVA) is a generic DirectDraw and DirectShow interface supported in Windows 2000 and Windows 98 Millennium to provide video decoding acceleration. Direct VA is the open standard implementation of HVA, which is natively supported by the GMCH hardware. 5.4.8.2. Hardware Motion Compensation The Hardware Motion Compensation (HWMC) process consists of reconstructing a new picture by predicting (either forward, backward, or bi-directional) the resulting pixel colors from one or more reference pictures. The GMCH receives the video stream and implements Motion Compensation and subsequent steps in hardware. Performing Motion Compensation in hardware reduces the processor demand of software-based MPEG-2 decoding, and thus improves system performance. 5.4.8.3. Sub-picture Support Sub-picture is used for two purposes: Subtitles for movie captions, which are superimposed on a main picture, and for Menus to provide some visual operation environments for the user. DVD allows movie subtitles to be recorded as Sub-pictures. On a DVD disc, it is called “Subtitle” because it has been prepared for storing captions. Since the disc can have a maximum of 32 tracks for Subtitles, they can be used for various applications, for example, as Subtitles in different languages. There are two kinds of Menus, the System Menus and other In-Title Menus. First, the System Menus are displayed and operated at startup of or during the playback of the disc or from the stop state. Second, InTitle menus can be programmed as a combination of Sub-picture and Highlight commands to be displayed during playback of the disc. The GMCH supports sub-picture for DVD and DBS by mixing the two video streams via alpha blending. Unlike color keying, alpha blending provides a softer effect and each pixel that is displayed is a composite between the two video stream pixels. The GMCH can utilize four methods when dealing with sub-pictures. This flexibility means that the GMCH can work with all sub-picture formats. Intel® 852GM/852GMV Chipset GMCH Datasheet 137 Functional Description R 5.5. Display Interface The GMCH has three dedicated display ports: the analog port, the LFP LVDS interface, and Digital display port, DVOC. DVOC can support TV-out encoders, external DACs, LVDS transmitters, and TMDS transmitters. Each display port has control signals that may be used to control, configure and/or determine the capabilities of an external device. The data that is sent out the display ports are selected from one of the two possible sources, display pipe A or display pipe B, except for the LVDS port which can only be driven on Pipe B. The GMCH’s digital display port is capable of driving a 165-MHz pixel clock on a single DVO port. 5.5.1. Analog Display Port Characteristics The analog display port provides an RGB signal output along with an HSYNC and VSYNC signal. There is an associated DDC signal pair that is implemented using GPIO pins dedicated to the analog port. The intended target device is for a CRT based monitor with a VGA connector. 5.5.1.1. Integrated RAMDAC The display function contains a 350-MHz integrated 24-bit RAM-based Digital-to-Analog Converter (RAMDAC) that transforms up to 1600X1200 digital pixels (Intel 852GM/852GMV GMCH) at a maximum refresh rate of 85 Hz. Three 8-bit DACs provide the R, G, and B signals to the monitor. 5.5.1.2. DDC (Display Data Channel) DDC is defined by VESA. It allows communication between the host system and display. Both configuration and control information can be exchanged allowing plug-and-play systems to be realized. Support for DDC 1 and 2 is implemented. 5.5.2. Digital Display Interface 5.5.2.1. Dedicated LVDS Interface The GMCH has a dedicated ANSI/TIA/EIA –644-1995 Specification compliant dual channel LFP LVDS interface that can support TFT panel resolutions up to SXGA+ with a maximum pixel format of 18 bpp (with SSC supported frequency range from 25-MHz to 112-MHz (single channel/dual channel). The display pipe selected by the LVDS display port is programmed with the panel timing parameters that are determined by installed panel specifications or read from an onboard EDID ROM. The programmed timing values are then “locked” into the registers to prevent unwanted corruption of the values. From that point on, the display modes are changed by selecting a different source size for that pipe, programming the VGA registers, or selecting a source size and enabling the VGA. The timing signals will remain stable and active through mode changes. These mode changes include VGA to VGA, VGA to HiRes, HiRes to VGA, and HiRes to HiRes. The transmitter can operate in a variety of modes and supports several data formats. The serializer supports 6-bit or 8-bit color and single or dual channel operating modes. The display stream from the display pipe is sent to the LVDS transmitter port at the dot clock frequency, which is determined by the panel timing requirements. The output of LVDS is running at a fixed multiple of the dot clock frequency, which is determined by the mode of operation; single or dual channel. 138 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R Depending on configuration and mode, a single channel can take 18-bits of RGB pixel data plus 3 bits of timing control (HSYNC/VSYNC/DE) and output them on three differential data pair outputs; or 24 bits of RGB plus 3 bits of timing control output on four differential data pair outputs. A dual channel interface converts 36 bits or 48 bits of color information plus the 3 bits of timing control and outputs it on six or eight sets of differential data outputs. This display port is normally used in conjunction with the pipe functions of panel scaling and a 6-bit to 8-bit dither. This display port is also used in conjunction with the panel power sequencing and additional associated functions. When enabled, the LVDS constant current drivers consume significant power. Individual pairs or sets of pairs can be selected to be powered down when not used. When disabled, individual or sets of pairs will enter a low power state. When the port is disabled all pairs enters a low power mode. The panel power sequencing can be set to override the selected power state of the drivers during power sequencing. For more details on using the GMCH’s LFP LVDS interface for TFT Panel support, please refer to the Common Panel Interface Specification, Rev 1.5 for details on: CPIS Supported Resolutions CPIS DC/AC Specifications CPIS Pin Lists and Connectors CPIS EDID Table Outline CPIS Reference EDID Formats (XGA at 60-Hz Refresh Rate) Sample CPIS EDID DTD’s (Primary Resolution at 60-Hz Refresh Rate) Video Serialization Formats References and External Standards 5.5.2.2. LVDS Interface Signals LVDS for flat panel is compatible with the ANSI/TIA/EIA-644 specification. This is an electrical standard only defining driver output characteristics and receiver input characteristics. There are two LVDS transmitter channels (channel A and channel B) in the LVDS interface. Each channel consists of four data pairs and a clock pair. The interface consists of a total of ten differential signal pairs of which eight are data and two are clocks. The phase locked transmit clock is transmitted in parallel with the data being sent out over the data pairs and over the LVDS clock pair. Each channel supports transmit clock frequency ranges from 25-MHz to 112-MHz, which provides a throughput of up to 784-Mbps on each data output and up to 112-MP/s on the input. When using both channels, they each operate at the same frequency each carrying a portion of the data. The maximum pixel rate is increased to 224-MP/s but may be limited to less than that due to restrictions elsewhere in the circuit. The LVDS Port Enable bit enables or disables the entire LVDS interface. When the port is disabled, it will be in a low power state. Once the port is enabled, individual driver pairs will be disabled based on the operating mode. Disabled drivers can be powered down for reduced power consumption or optionally fixed to forced 0’s output. 5.5.2.3. LVDS Pair States The LVDS pairs can be put into one of the following five states: powered down tri-state, powered down Zero Volts, common mode, send zeros, or active. When in the active state, several data formats are supported. When in powered down state, the circuit enters a low power state and drives out 0 V or tristates on both the output pins for the entire channel. The common mode tri-state is both pins of the pair Intel® 852GM/852GMV Chipset GMCH Datasheet 139 Functional Description R set to the common mode voltage. When in the send zeros state, the circuit is powered up but sends only zero for the pixel color data regardless what the actual data is with the clock lines and timing signals sending the normal clock and timing data. 5.5.2.4. Single Channel versus Dual Channel Mode Both single channel and dual channel modes are available to allow interfacing to either single or dual channel panel interfaces. This LVDS port can operate in single channel or dual channel mode. Dual channel mode uses twice the number of LVDS pairs and transfers the pixel data at twice the rate of the single channel. In general, one channel will be used for even pixels and the other for odd pixel data. The first pixel of the line is determined by the display enable going active and that pixel will be sent out channel A. All horizontal timings for active, sync, and blank will be limited to be on two pixel boundaries in the two channel modes. 5.5.2.5. LVDS Channel Skew When in dual channel mode, the two channels must meet the panel requirements with respect to the inter channel skew. 5.5.2.6. LVDS PLL The Display PLL is used to synthesize the clocks that control transmission of the data across the LVDS interface. The three operations that are controlled are the pixel rate, the load rate, and the IO shift rate. These are synchronized to each other and have specific ratios based on single channel or dual channel mode. If the pixel clock is considered the 1x rate, a 7x or 3.5x speed IO_shift clock needed for the highspeed, serial outputs setting the data rate of the transmitters. The load clock will have either a 1x or .5x ratio to the pixel clock. 5.5.2.7. SSC Support The GMCH is designed to tolerate 0.5%, 1.0%, and 2.5% down/center spread at a modulation rate from 30-50kHz triangle. An external SSC clock synthesizer can be used to provide the 48/66-MHz reference clock into the GMCH Pipe B PLL. 5.5.2.8. Panel Power Sequencing This section provides details for the power sequence timing relationship of the panel power, the backlight enable and the LVDS data timing delivery. In order to meet the panel power timing specification requirements, two signals, PANELVDDEN and PANELBKLTEN are provided to control the timing sequencing function of the panel and the backlight power supplies. 5.5.2.8.1. Panel Power Sequence States A defined power sequence is recommended when enabling the panel or disabling the panel. The set of timing parameters can vary from panel to panel vendor, provided that they stay within a predefined range of values. The panel VDD power, the backlight on/off state and the LVDS clock and data lines are all managed by an internal power sequencer. A requested power-up sequence is only allowed to begin after the power cycle delay time requirement T4 is met. 140 Intel® 852GM/852GMV Chipset GMCH Datasheet Functional Description R Figure 7. Panel Power Sequencing T4 T1+T2 TX T5 T3 T4 Panel On Panel VDD Enable Panel BackLight Enable Off Clock/Data Lines Valid Off Power On Sequence from off state and Power Off Sequence after full On Intel® 852GM/852GMV Chipset GMCH Datasheet 141 Functional Description R Table 29. Panel Power Sequencing Timing Parameters Panel Power Sequence Timing Parameters Name Spec Name T1+T2 From Vdd On to LVDS Active To .1 Vdd LVDS Active LVDS Active Backlight on Backlight Off LVDS off LVDS Off Start power off Power Off Power On Sequence Start Panel Vdd must be on for a minimum time before the LVDS data stream is enabled. T5 Backlight LVDS data must be enabled for a minimum time before the backlight is turned on. TX Backlight State Backlight must be disabled for a minimum time before the LVDS data stream is stopped. T3 LVDS State Data must be off for a minimum time before the panel VDD is turned off. T4 Power cycle Delay When panel VDD is turned from On to Off, a minimum wait must be satisfied before the panel VDD is enabled again. 5.5.2.9. Back Light Inverter Control The GMCH offers integrated PWM for TFT panel Backlight Inverter control. Other methods of control are specified in the Common Panel Interface Specification, Version 1.5. PWM – based Backlight Brightness Control SMBus-based Backlight Brightness Control DBL (Display Brightness Link) –to- VDL (Video Data Link) Power Sequencing 5.5.2.10. Digital Video Output Port The GMCH has the capability to support additional digital display devices (e.g. TMDS transmitter, LVDS transmitter or TV-out encoder) through its digital video output port. DVOC can deliver a 165MHz dot clock on its 12-bit interface. The digital display port consists of a digital data bus, VSYNC, HSYNC, and BLANK# signals. The data bus can operate only in a 12-bit mode. Embedded sync information or HSYNC and VSYNC signals can optionally provide the basic timing information to the external device and the BLANK# signal indicates which clock cycles contain valid data. The BLANK# signal can be optionally selected to include the border area of the timing. The VSYNC and HSYNC signals can be disabled when embedded sync information is to be used or to support DPMS. Optionally a STALL signal can cause the next line of data to not be sent until the STALL signal is removed. Optionally the FIELD pin can indicate to the overlay which field is currently being displayed at the display device. 142 Intel® 852GM/852GMV Chipset GMCH Datasheet Power and Thermal Management R 6. Power and Thermal Management The Intel 852GM/852GMV GMCH platform is intended to be compliant with the following specifications and technologies: APM Rev 1.2 PCI Power Management Rev 1.0 PC’99, Rev 1.0, PC’99A, and PC’01, Rev 1.0 ACPI 1.0b and 2.0 support ACPI S0, S1-M, S3, S4, S5, C0, C1, C2, C3 states Internal Graphics Adapter D0, D1, D3 (Hot/Cold) Enhanced Intel SpeedStep® Technology On Die Thermal Sensor, enabling core and System Memory write thermal throttling for prevention of catastrophic thermal conditions External Thermal Sensor Input pin Enabling SO-DIMM thermal throttling C4 compatible (C4 = Deeper sleep) is same as C3 from the GMCH perspective, but from platform perspective, CPU voltage is reduced during C3 and S1-M entry to minimum to maintain state) The GMCH also reduces I/O power dynamically, by disabling sense amps on input buffers, as well as tristating output buffers when possible Intel® 852GM/852GMV Chipset GMCH Datasheet 143 Power and Thermal Management R 6.1. General Description of Supported CPU States C0 (Full On): This is the only state that runs software. All clocks are running, STPCLK is deasserted, and the processor core is active. The processor can service snoops and maintain cache coherency in this state. C1 (Auto Halt): The first level of power reduction occurs when the processor executes an Auto-Halt instruction. This stops the execution of the instruction stream and reduces the processor’s power consumption. The processor can service snoops and maintain cache coherency in this state. C2 (Stop Grant): To enter this low power state, STPCLK is asserted. The processor can still service snoops and maintain cache coherency in this state. C3 (Sleep or Deep Sleep): In these states the processor clock is stopped. The GMCH assumes that no Hub Interface cycles (except special cycles) will occur while the GMCH is in this state. The processor cannot snoop its caches to maintain coherency while in the C3 state. The GMCH will transition from the C0 state to the C3 state when software reads the Level 3 Register. This is an ACPI defined register but BIOS or APM (via BIOS) can use this facility when entering a low power state. The Host Clock PLL within the GMCH can be programmed to be shut off for increased power savings and the GMCH uses the DPSLP signal input for this purpose. C4 (Deeper Sleep): The C4 state appears to the GMCH as identical to the C3 state, but in this state the processor core voltage is lowered. There are no internal events in GMCH for the C4 state that differ from the C3 state (this state is not supported for Intel Celeron M processor and mobile Intel Celeron processor). 6.2. General Description of ACPI States Internal Graphics Adapter: D0 Full on, display active D1 Low power state, low latency recovery. No display, System Memory retained D3 Hot - All state lost other than PCI config. System Memory lost (optionally) D3 Cold - Power off CPU: C0 Full On C1 Auto Halt C2 DesktopStop Clock. Clk to CPU still running. Clock stopped to CPU core. C3 Deep Sleep. Clock to CPU stopped. C4 Deeper Sleep. Same as C3 with reduced voltage on the CPU. System States •G0/S0 Full On •G1/S1-M Power On Suspend (POS). System Context Preserved •G1/S2 Not supported. •G1/S3 Suspend to RAM (STR). Power and context lost to chipset. •G1/S4 Suspend to Disk (STD). All power lost (except wakeup on ICH4-M) 144 Intel® 852GM/852GMV Chipset GMCH Datasheet Power and Thermal Management R •G2/S5 Hard off. Total reboot. 6.3. Enhanced Intel SpeedStep Technology Overview With Enhanced Intel SpeedStep Technology the processor core voltage changes and allows true CPU core frequency changes versus only clock throttling. Note: Enhanced Intel Speed Step technology is not supported for Intel Celeron M processor, mobile Intel Celeron processor and Intel Celeron D processor on 90 nm process and in the 478-pin package. Table 30. Enhanced Intel SpeedStep Technology Overview 6.4. CPU Mobile Intel Pentium 4 Processor-M Benefit Over Non-power Managed CPU Additional lower voltages and frequencies Transition Prompt OS based on CPU load demand, thermal control, or user event based CPU Availability CPU unavailability can be restricted to ~250 µs (CPU dependent) by s/w Internal Thermal Sensor This section describes the new on-die thermal sensor capability. The thermal sensor functions are provided below: Catastrophic Trip Point: This trip point is programmed through the BIOS during initialization. This trip point is set at the temperature at which the GMCH should be shut down immediately with minimal software support. The settings for this are lockable. High Temperature Trip Point: This trip point is nominally 14ºC below the Catastrophic Trip Point. The BIOS can be programmed to provide an interrupt when it is crossed in either direction. Upon the trip event, hardware throttling may be enabled when the temperature is exceeded. 6.4.1. Hardware Throttling The Hot trip points’ crossings events may be used to trigger throttling without intervention by software. System Memory write throttling may be enabled on Hot trip points. The HTC register selects whether it is Catastrophic or both that enable throttling. System Memory write throttling registers in Device #0 configuration space determine whether throttling is enabled at all. 6.4.2. Register Locking TCO contains a lock bit that locks the catastrophic programming interface, including TCO, TCTS, and two bits in TSCR that could disable the sensor or alter the trip point. HTC has a lock bit for the hardware throttling settings. Intel® 852GM/852GMV Chipset GMCH Datasheet 145 Power and Thermal Management R 6.4.3. Hysteresis Operation Hysteresis provides a small amount of positive feedback to the thermal sensor circuit to prevent a trip point from flipping back and forth rapidly when the temperature is right at the trip point. 6.5. External Thermal Sensor Input An external thermal sensor with a serial interface may be placed next to DDR SDRAM SO-DIMM (or any other appropriate platform location), or a remote Thermal Diode may be placed next to the SODIMM (or any other appropriate platform location) and connected to the external Thermal sensor. Intel advises that the external Thermal sensor contains some form of hysteresis, since none is provided by the GMCH hardware. The external sensor can be connected to the ICH4-M via the SMBus Interface to allow programming and setup by BIOS software over the serial interface. The external sensor’s output should include an ActiveLow Open-Drain signal indicating an Over-Temp condition, which remains asserted for as long as the Over-Temp Condition exists, and deasserts when temperature has returned to within normal operating range. This external sensor output will be connected to the GMCH input (EXTTS_0) and will trigger a preset interrupt and/or read-throttle on a level-sensitive basis. Additional external thermal sensor’s outputs, for multiple sensors, can be wire-ORed together allow signaling from multiple sensors located physically separately. Software can, if necessary, distinguish which SO-DIMM(s) is the source of the over-temp through the serial interface. However, since the SODIMM(s) will be located on the same System Memory Bus Data lines, any GMCH-based Read Throttle will apply equally. Note: The use of external sensors that include an internal pull-up resistor on the open-drain thermal trip output is discouraged. However, it may be possible depending on the size of the pull-up and the voltage of the sensor. Please refer to the platform design guide for more information. 6.5.1. Usage External Sensor(s) Used for Dynamic Temperature Feedback Control in production releases: Sensor on SO-DIMMs, which can be used to dynamically control read throttling. 146 Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R 7. Testability In the Intel 852GM/852GMV GMCH, testability for Automated Test Equipment (ATE) board level testing has been implemented as an XOR chain. An XOR-tree is a chain of XOR gates, each with one input pin connected to it. The XOR Chain test mode is used by product engineers during manufacturing and OEMs during board level connectivity tests. The main purpose of this test mode is to detect connectivity shorts between adjacent pins and to check proper bonding between I/O pads and I/O pins. Figure 8. XOR–Tree Chain VCC1_2 XOR Out Input Input Input Input Input xor.vsd The algorithm used for in–circuit test is as follows: 1. Drive all input pins to an initial logic level 1. Observe the output corresponding to scan chain being tested. 2. Toggle pins one at a time starting from the first pin in the chain, continuing to the last pin, from its initial logic level to the opposite logic level. Observe the output changes with each pin toggle. 7.1. XOR Test Mode Entry Please refer to XOR Chain Test Mode Entry Events Diagram in Figure 9. Intel® 852GM/852GMV Chipset GMCH Datasheet 147 Testability R Figure 9. XOR Chain Test Mode Entry Events Diagram powerok VSYNC Don't care HSYNC Don't care LCLKCTLA Don't care RSTIN# (PCI reset) Note: HSYNC and LCLKCTLA = XOR Chain Test Mode Activation; No clock is required for XOR Chain Test Mode. A minimum of 50 ns PWROK assertion prior to RSTIN# assertion is recommended. A minimum of 10 ns VSYNC/HSYNC/LCLKCTLA assertion prior to PWROK assertion is recommended. Please refer to ALLZ Test Mode Entry Events Diagram in Figure 10. Figure 10. ALLZ Test Mode Entry Events Diagram powerok VSYNC Don't care HSYNC Don't care LCLKCTLA Don't care RSTIN# (PCI reset) NOTE: 148 VSYNC and LCLKCTLA = ALL Z Test Mode Activation; No clock is required for ALLZ Test Mode Activation. A minimum of 50 ns PWROK assertion prior to RSTIN# assertion is recommended. A minimum of 10 ns VSYNC/HSYNC/LCLKCTLA assertion prior to PWROK assertion is recommended. Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R 7.2. XOR Chain Differential Pairs Table 31 provides differential signals in the XOR chains that must be treated as pairs. Pin1 and Pin2 as shown below need to drive to the opposite value always. Table 31. Differential Signals in the XOR Chains 7.3. Pin1 Pin2 XOR Chain DVOCCLK# DVOCCLK DVO XOR 2 HLSTB# HLSTB HUB XOR XOR Chain Exclusion List See Table 32 for a list of pins that are not included in the XOR chains (excluding all VCC/VSS/VTT). Note: Connectivity column is used to identify what need to be driven on that particular pin during XOR chain test mode. Table 32. XOR Chain Exclusion List of Pins Item# IN/OUT Ball Pin/VHDL I/O Type Voltage Connectivity 1 IN Y3 GCLKIN PLL CLK 3.3 0 2 - W1 HLVREF Analog 1/3 VCCHL 0.4 3 - T2 HLRCOMP Analog N/A N/A 4 - U2 PSWING Analog N/A N/A 5 - F1 GVREF Analog 1/2 VCCDVO 0.75 6 - D1 DVORCOMP Analog N/A N/A 7 IN J11 PWROK CMOS 3.3 N/A 8 IN B7 DREFCLK PLL CLK 3.3 0 9 - E8 REFSET Analog N/A N/A 10 - C9 BLUE Analog N/A N/A 11 - D9 BLUE# Analog N/A N/A 12 - C8 GREEN Analog N/A N/A 13 - D8 GREEN# Analog N/A N/A A7 RED Analog N/A N/A 14 15 - A8 RED# Analog N/A N/A 16 - D12 LVREFH Analog 1.1 1.1 17 - A10 LIBG Analog N/A N/A 18 - B12 LVBG Analog N/A N/A 19 - F12 LVREFL Analog 1.1 1.1 20 IN B17 DREFSSCLK PLL CLK 3.3 0 21 - J17 HDVREF[2] Analog 2/3 VTTLF 1.0 Intel® 852GM/852GMV Chipset GMCH Datasheet 149 Testability R 7.4. Item# IN/OUT Ball Pin/VHDL I/O Type Voltage Connectivity 22 - B20 HXRCOMP Analog N/A N/A 23 - B18 HXSWING Analog N/A N/A 24 - J21 HDVREF[1] Analog 2/3 VTTLF 1.0 25 IN AD29 BCLK# Diff 0.7 0 26 IN AE29 BCLK Diff 0.7 0.7 27 - K21 HDVREF[0] Analog 2/3 VTTLF 1.0 28 - Y28 HCCVREF Analog 2/3 VTTLF 1.0 29 - Y22 HAVREF Analog 2/3 VTTLF 1.0 30 - H28 HYRCOMP Analog N/A N/A 31 - K28 HYSWING Analog N/A N/A 32 IN D28 RSTIN# CMOS 3.3 N/A 33 - AJ24 SMVREF_0 Analog 1/2 VCCSM 1.25 34 - AB1 SMRCOMP Analog N/A N/A XOR Chain Connectivity/Ordering The following tables contain the ordering for all of the Intel 852GM/852GMV GMCH XOR chains and pin to ball mapping information: 150 Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R Table 33. XOR Mapping XOR Chain DVO 1 DVO IN/OUT Ball Pin/VHDL I/O Type Voltage OUT AB5 SMA[12] SSTL_2 2.5 1 INOUT T6 RSVD DVO 1.5 2 INOUT T5 RSVD DVO 1.5 3 INOUT T7 MDDCDATA DVO 1.5 4 INOUT R3 RSVD DVO 1.5 5 INOUT R4 RSVD DVO 1.5 6 INOUT R6 RSVD DVO 1.5 7 INOUT R5 RSVD DVO 1.5 8 INOUT P2 RSVD DVO 1.5 9 INOUT P4 RSVD DVO 1.5 10 INOUT P3 RSVD DVO 1.5 11 INOUT P6 RSVD N/A N/A 12 INOUT P5 RSVD N/A N/A 13 INOUT N2 RSVD N/A N/A 14 INOUT N3 RSVD N/A N/A 15 INOUT M1 RSVD N/A N/A 16 INOUT N5 RSVD N/A N/A 17 INOUT M2 RSVD N/A N/A 18 INOUT M5 RSVD N/A N/A 19 INOUT M3 DVOBCCLKINT DVO 1.5 20 INOUT L2 RSVD N/A N/A 21 INOUT P7 MDDCCLK DVO 1.5 22 INOUT N6 MI2CDATA DVO 1.5 23 INOUT M6 MDVIDATA DVO 1.5 24 INOUT N7 MDVICLK DVO 1.5 25 INOUT L7 DVODETECT DVO 1.5 26 INOUT K7 MI2CCLK DVO 1.5 27 OUT B2 RSVD N/A N/A 28 IN B3 RSVD N/A N/A DVO IN/OUT Ball Pin/VHDL I/O Type Voltage OUT AD5 SMA[11] SSTL_2 2.5 INOUT L3 DVOCBLANK# DVO 1.5 XOR Out XOR Chain DVO 2 XOR Out 1 Intel® 852GM/852GMV Chipset GMCH Datasheet 151 Testability R 152 2 INOUT K1 DVOCD[1] DVO 1.5 3 INOUT L4 RSVD DVO N/A 4 INOUT L5 DVOCVSYNC DVO 1.5 5 INOUT K2 DVOCD[3] DVO 1.5 6 INOUT K5 DVOCD[0] DVO 1.5 7 INOUT K3 DVOCD[2] DVO 1.5 8 INOUT J2 DVOCCLK# DVO 1.5 9 INOUT J3 DVOCCLK DVO 1.5 10 INOUT H2 DVOCD[6] DVO 1.5 11 INOUT J5 DVOCD[5] DVO 1.5 12 INOUT H1 DVOCD[7] DVO 1.5 13 INOUT J6 DVOCD[4] DVO 1.5 14 INOUT K6 DVOCHSYNC DVO 1.5 15 INOUT H4 DVOCD[9] DVO 1.5 16 INOUT H3 DVOCD[8] DVO 1.5 17 INOUT H5 DVOCFLDSTL DVO 1.5 18 INOUT H6 DVOCD[10] DVO 1.5 19 INOUT G2 DVOBCINT# DVO 1.5 20 INOUT G3 DVOCD[11] DVO 1.5 21 IN D2 RSVD N/A N/A 22 IN D3 RSVD N/A N/A 23 IN F4 ADDID[5] DVO 1.5 24 IN F5 ADDID[1] DVO 1.5 25 IN F6 ADDID[7] DVO 1.5 26 IN E2 ADDID[3] DVO 1.5 27 IN E5 ADDID[0] DVO 1.5 28 IN F3 RSVD N/A N/A 29 IN F2 RSVD N/A N/A 30 OUT C2 RSVD N/A N/A 31 IN E3 ADDID[2] DVO 1.5 32 OUT C3 GST[1] DVO 1.5 33 OUT C4 GST[0] DVO 1.5 34 IN G5 ADDID[4] DVO 1.5 35 IN G6 ADDID[6] DVO 1.5 36 IN D5 DPMS DVO 1.5 Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R XOR Chain FSB 1 IN/OUT Ball Pin I/O Type Voltage OUT AC19 SMA[10] SSTL_2 2.5 1 INOUT D16 HD[62]# GTL+ 1.5 2 INOUT C16 HD[60]# GTL+ 1.5 3 INOUT G16 HD[58]# GTL+ 1.5 4 INOUT C17 HD[55]# GTL+ 1.5 5 INOUT E17 HD[61]# GTL+ 1.5 6 INOUT E16 HD[59]# GTL+ 1.5 7 INOUT F17 HD[56]# GTL+ 1.5 8 INOUT B19 HD[57]# GTL+ 1.5 9 INOUT E18 HDSTBP[3]# GTL+ 1.5 10 INOUT D18 HDSTBN[3]# GTL+ 1.5 11 INOUT C18 HD[63]# GTL+ 1.5 12 INOUT G17 HD[51]# GTL+ 1.5 13 INOUT C19 HD[54]# GTL+ 1.5 14 INOUT D20 HD[52]# GTL+ 1.5 15 INOUT E20 HD[50]# GTL+ 1.5 16 INOUT E19 HD[49]# GTL+ 1.5 17 INOUT G19 DINV[3]# GTL+ 1.5 18 INOUT F19 HD[53]# GTL+ 1.5 19 INOUT G18 HD[48]# GTL+ 1.5 20 INOUT B21 HD[32]# GTL+ 1.5 21 INOUT C20 HD[46]# GTL+ 1.5 22 INOUT C23 HD[35]# GTL+ 1.5 23 INOUT B23 HD[43]# GTL+ 1.5 24 INOUT B22 HD[42]# GTL+ 1.5 25 INOUT B25 DINV[2]# GTL+ 1.5 26 INOUT D22 HD[36]# GTL+ 1.5 27 INOUT C24 HD[34]# GTL+ 1.5 28 INOUT C21 HD[47]# GTL+ 1.5 29 INOUT E21 HDSTBP[2]# GTL+ 1.5 30 INOUT E22 HDSTBN[2]# GTL+ 1.5 31 INOUT D24 HD[39]# GTL+ 1.5 32 INOUT C25 HD[37]# GTL+ 1.5 33 INOUT F21 HD[45]# GTL+ 1.5 34 INOUT E24 HD[38]# GTL+ 1.5 XOR Out Intel® 852GM/852GMV Chipset GMCH Datasheet 153 Testability R 35 INOUT E23 HD[41]# GTL+ 1.5 36 INOUT G21 HD[33]# GTL+ 1.5 37 INOUT F23 HD[44]# GTL+ 1.5 38 INOUT G20 HD[40]# GTL+ 1.5 39 OUT M27 RS[2]# GTL+ 1.5 40 OUT P28 BPRI# GTL+ 1.5 41 OUT AA22 DPWR# GTL+ 1.5 42 INOUT AA26 HADSTB[1]# GTL+ 1.5 IN/OUT Ball Pin I/O Type Voltage OUT AC5 SMA[9] SSTL_2 2.5 1 INOUT E25 DINV[1]# GTL+ 1.5 2 INOUT B26 HD[26]# GTL+ 1.5 3 INOUT C26 HD[28]# GTL+ 1.5 4 INOUT B27 HD[18]# GTL+ 1.5 5 INOUT B28 HD[31]# GTL+ 1.5 6 INOUT G23 HD[30]# GTL+ 1.5 7 INOUT E26 HD[9]# GTL+ 1.5 8 INOUT D26 HDSTBP[1]# GTL+ 1.5 9 INOUT C27 HDSTBN[1]# GTL+ 1.5 10 INOUT G22 HD[27]# GTL+ 1.5 11 INOUT G24 HD[24]# GTL+ 1.5 12 INOUT C28 HD[25]# GTL+ 1.5 13 INOUT E27 HD[20]# GTL+ 1.5 14 INOUT F2 HD[17]# GTL+ 1.5 15 INOUT D27 HD[23]# GTL+ 1.5 16 INOUT G25 HD[21]# GTL+ 1.5 17 INOUT F25 HD[16]# GTL+ 1.5 18 INOUT H23 HD[19]# GTL+ 1.5 19 INOUT F28 HD[22]# GTL+ 1.5 20 INOUT K23 HD[11]# GTL+ 1.5 21 INOUT J23 HD[14]# GTL+ 1.5 22 INOUT H25 HD[10]# GTL+ 1.5 23 INOUT G27 HD[12]# GTL+ 1.5 24 INOUT K22 HD[0]# GTL+ 1.5 25 INOUT H26 HD[15]# GTL+ 1.5 26 INOUT G28 HD[5]# GTL+ 1.5 27 INOUT H27 HD[1]# GTL+ 1.5 XOR Chain FSB 2 XOR Out 154 Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R 28 INOUT J24 HD[9]# GTL+ 1.5 29 INOUT L23 HD[7]# GTL+ 1.5 30 INOUT K25 HD[2]# GTL+ 1.5 31 INOUT K27 HDSTBP[0]# GTL+ 1.5 32 INOUT J28 HDSTBN[0]# GTL+ 1.5 33 INOUT J25 DINV[0]# GTL+ 1.5 34 INOUT K26 HD[13]# GTL+ 1.5 35 INOUT L24 HD[3]# GTL+ 1.5 36 INOUT L25 HD[8]# GTL+ 1.5 37 INOUT L27 HD[6]# GTL+ 1.5 38 INOUT J27 HD[4]# GTL+ 1.5 39 OUT M28 DEFER# GTL+ 1.5 40 OUT N23 RS[0]# GTL+ 1.5 41 OUT P26 RS[1]# GTL+ 1.5 42 INOUT T26 HADSTB[0]# GTL+ 1.5 IN/OUT Ball Pin I/O Type Voltage OUT AC6 SMA[8] SSTL_2 2.5 1 OUT F15 CPURST# GTL+ 1.5 2 IN Y23 DPSLP# CMOS 1.5 3 INOUT N27 HIT# GTL+ 1.5 4 INOUT N28 HITM# GTL+ 1.5 5 INOUT N25 BNR# GTL+ 1.5 6 INOUT N24 DRDY# GTL+ 1.5 7 IN P27 HLOCK# GTL+ 1.5 8 INOUT M23 BREQ0# GTL+ 1.5 9 OUT M25 HTRDY# GTL+ 1.5 10 INOUT M26 DBSY# GTL+ 1.5 11 INOUT L28 ADS# GTL+ 1.5 12 INOUT R28 HREQ[0]# GTL+ 1.5 13 INOUT P25 HREQ[1]# GTL+ 1.5 14 INOUT T28 HA[5]# GTL+ 1.5 15 INOUT R27 HA[6]# GTL+ 1.5 16 INOUT R23 HREQ[2]# GTL+ 1.5 17 INOUT R24 HA[9]# GTL+ 1.5 18 INOUT T27 HA[13]# GTL+ 1.5 19 INOUT U28 HA[10]# GTL+ 1.5 XOR Chain FSB 3 XOR Out Intel® 852GM/852GMV Chipset GMCH Datasheet 155 Testability R 20 INOUT P23 HA[3]# GTL+ 1.5 21 INOUT T25 HA[4]# GTL+ 1.5 22 INOUT R25 HREQ[3]# GTL+ 1.5 23 INOUT V27 HA[14]# GTL+ 1.5 24 INOUT U27 HA[12]# GTL+ 1.5 25 INOUT V28 HA[11]# GTL+ 1.5 26 INOUT T23 HREQ[4]# GTL+ 1.5 27 INOUT U24 HA[8]# GTL+ 1.5 28 INOUT U23 HA[7]# GTL+ 1.5 29 INOUT V26 HA[16]# GTL+ 1.5 30 INOUT U25 HA[15]# GTL+ 1.5 31 INOUT V25 HA[18]# GTL+ 1.5 32 INOUT Y26 HA[30]# GTL+ 1.5 33 INOUT W28 HA[28]# GTL+ 1.5 34 INOUT W25 HA[20]# GTL+ 1.5 35 INOUT V23 HA[19]# GTL+ 1.5 36 INOUT W27 HA[25]# GTL+ 1.5 37 INOUT Y25 HA[21] GTL+ 1.5 38 INOUT W24 HA[23]# GTL+ 1.5 39 INOUT Y27 HA[26]# GTL+ 1.5 40 INOUT Y24 HA[17]# GTL+ 1.5 41 INOUT AA27 HA[22]# GTL+ 1.5 42 INOUT W23 HA[24]# GTL+ 1.5 43 INOUT AB28 HA[31]# GTL+ 1.5 44 INOUT AB27 HA[29]# GTL+ 1.5 45 INOUT AA28 HA[27] GTL+ 1.5 IN/OUT Ball Pin I/O Type Voltage OUT AD7 SMA[7] SSTL_2 2.5 1 OUT G8 PANELBKLTCTL CMOS 3.3 2 OUT F8 PANELBKLTEN CMOS 3.3 3 OUT C6 LCLKCTLB CMOS 3.3 4 IN D6 EXTTS_0 CMOS 3.3 5 OUT F7 AGPBUSY# CMOS 3.3 6 IN D7 RSVD N/A N/A 7 INOUT C5 DDCPDATA CMOS 3.3 8 INOUT B4 DDCPCLK CMOS 3.3 9 OUT H10 HSYNC CMOS 3.3 XOR Chain GPIO XOR Out 156 Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R 10 OUT A5 PANELVDDEN CMOS 3.3 11 INOUT B6 DDCACLK CMOS 3.3 12 OUT J9 VSYNC CMOS 3.3 13 INOUT G9 DDCADATA CMOS 3.3 14 OUT H9 LCLKCTLA CMOS 3.3 IN/OUT Ball Pin I/O Type Voltage OUT AD8 SMA[6] SSTL_2 2.5 1 INOUT W2 HL[4] HL1.5 1.2 2 INOUT W6 HL[5] HL1.5 1.2 3 INOUT W7 HL[7] HL1.5 1.2 4 INOUT V6 HL[6] HL1.5 1.2 5 INOUT W3 HLSTB HL1.5 1.2 6 INOUT V2 HLSTB# HL1.5 1.2 7 IN V5 Hl[9] HL1.5 1.2 8 INOUT V4 HL[10] HL1.5 1.2 9 INOUT V3 HL[3] HL1.5 1.2 10 INOUT U4 HL[1] HL1.5 1.2 11 INOUT U3 HL[2] HL1.5 1.2 12 INOUT U7 HL[0] HL1.5 1.2 13 OUT T3 HL[8] HL1.5 1.2 IN/OUT Ball Pin I/O Type Voltage OUT AD17 SMA[3] SSTL_2 2.5 1 INOUT F10 ICLKBP LVDS 1.5 2 INOUT E10 ICLKBM LVDS 1.5 3 INOUT G10 IYBP[3] LVDS 1.5 4 INOUT G11 IYBM[3] LVDS 1.5 5 INOUT G12 IYBP[0] LVDS 1.5 6 INOUT H12 IYBM[0] LVDS 1.5 7 INOUT E11 IYBP[1] LVDS 1.5 8 INOUT E12 IYBM[1] LVDS 1.5 9 INOUT C11 IYBP[2] LVDS 1.5 10 INOUT C12 IYBM[2] LVDS 1.5 11 INOUT E13 ICLKAP LVDS 1.5 12 INOUT D14 ICLKAM LVDS 1.5 13 INOUT B13 IYAP[3] LVDS 1.5 XOR Chain HUB XOR Out XOR Chain LVDS XOR Out Intel® 852GM/852GMV Chipset GMCH Datasheet 157 Testability R 14 INOUT C13 IYAM[3] LVDS 1.5 15 INOUT F14 IYAP[0] LVDS 1.5 16 INOUT G14 IYAM[0] LVDS 1.5 17 INOUT C14 IYAP[2] LVDS 1.5 18 INOUT C15 IYAM[2] LVDS 1.5 19 INOUT E14 IYAP[1] LVDS 1.5 20 INOUT E15 IYAM[1] LVDS 1.5 DDR SDRAM IN/OUT Ball Pin I/O Type Voltage OUT AD23 SCS[0]# SSTL_2 2.5 1 INOUT AE27 SDQ[62] SSTL_2 2.5 2 INOUT AD27 SDQ[63] SSTL_2 2.5 3 INOUT AF26 SDQ[61] SSTL_2 2.5 4 INOUT AG26 SDQ[60] SSTL_2 2.5 5 OUT AC25 SCS[3]# SSTL_2 2.5 6 OUT AD24 SDM[6] SSTL_2 2.5 7 INOUT AH24 SDQS[6] SSTL_2 2.5 8 OUT AD25 SWE# SSTL_2 2.5 9 OUT AC18 SMA[0] SSTL_2 2.5 10 INOUT AH17 SDQS[4] SSTL_2 2.5 11 OUT AD19 SDM[4] SSTL_2 2.5 12 CLK AC26 SCK[1] SSTL_2 2.5 13 CLK AB23 SCK[4] SSTL_2 2.5 14 CLK AA3 SCK[5] SSTL_2 2.5 15 CLK AC2 SCK[3] SSTL_2 2.5 16 CLK AB2 SCK[0] SSTL_2 2.5 17 CLK AC3 SCK[2] SSTL_2 2.5 18 OUT AH15 SDM[8] SSTL_2 2.5 19 INOUT AF17 RSVD N/A N/A 20 INOUT AF16 RSVD N/A N/A 21 INOUT AG16 RSVD N/A N/A 22 INOUT AE15 RSVD N/A N/A 23 INOUT AH14 RSVD N/A N/A 24 INOUT AE17 RSVD N/A N/A 25 INOUT AD15 SDQS[8] SSTL_2 2.5 26 INOUT AE14 RSVD N/A N/A 27 INUT AG14 RSVD N/A N/A XOR Chain SM1 XOR Out 158 Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R 28 INOUT AH8 SDQS[2] SSTL_2 2.5 29 OUT AE9 SDM[2] SSTL_2 2.5 30 OUT AC7 SCKE[0] SSTL_2 2.5 31 INOUT AG2 SDQS[0] SSTL_2 2.5 32 OUT AE5 SDM[0] SSTL_2 2.5 DDR SDRAM IN/OUT Ball Pin I/O Type Voltage OUT AD26 SCS[1]# SSTL_2 2.5 1 INOUT AF28 SDQ[59] SSTL_2 2.5 2 INOUT AG28 SDQ[58] SSTL_2 2.5 3 INOUT AH27 SDQS[7] SSTL_2 2.5 4 OUT AH28 SDM[7] SSTL_2 2.5 5 INOUT AE26 SDQ[57] SSTL_2 2.5 6 INOUT AH26 SDQ[56] SSTL_2 2.5 7 INOUT AH25 SDQ[51] SSTL_2 2.5 8 INOUT AG25 SDQ[55] SSTL_2 2.5 9 INOUT AF25 SDQ[54] SSTL_2 2.5 10 INOUT AE24 SDQ[50] SSTL_2 2.5 11 INOUT AH23 SDQ[49] SSTL_2 2.5 12 INOUT AF23 SDQ[53] SSTL_2 2.5 13 INOUT AE23 SDQ[48] SSTL_2 2.5 14 INOUT AG23 SDQ[52] SSTL_2 2.5 15 INOUT AE21 SDQS[5] SSTL_2 2.5 16 OUT AD21 SDM[5] SSTL_2 2.5 17 OUT AD20 SBA[1] SSTL_2 2.5 18 OUT AD22 SBA[0] SSTL_2 2.5 19 OUT AC21 SRAS# SSTL_2 2.5 20 OUT AC15 RCVENOUT# SSTL_2 2.5 21 INOUT AC16 RCVENIN# SSTL_2 2.5 22 CLK AB24 SCK[4]# SSTL_2 2.5 23 CLK AB25 SCK[1]# SSTL_2 2.5 24 CLK AB4 SCK[5]# SSTL_2 2.5 25 CLK AA2 SCK[0]# SSTL_2 2.5 26 CLK AD2 SCK[3]# SSTL_2 2.5 27 CLK AD4 SCK[2]# SSTL_2 2.5 28 OUT AD10 SMAB[5] SSTL_2 2.5 29 OUT AD14 SMA[1] SSTL_2 2.5 XOR Chain SM2 XOR Out Intel® 852GM/852GMV Chipset GMCH Datasheet 159 Testability R 30 OUT AD16 SMAB[1] SSTL_2 2.5 31 OUT AD13 SMA[2] SSTL_2 2.5 32 OUT AF11 SMAB[4] SSTL_2 2.5 33 OUT AC12 SMAB[2] SSTL_2 2.5 34 OUT AC13 SMA[5] SSTL_2 2.5 35 INOUT AE12 SDQS[3] SSTL_2 2.5 36 OUT AH12 SDM[3] SSTL_2 2.5 37 OUT AD11 SMA[4] SSTL_2 2.5 38 OUT AC10 SCKE[3] SSTL_2 2.5 39 OUT AE6 SDM[1] SSTL_2 2.5 40 INOUT AH5 SDQS[1] SSTL_2 2.5 41 OUT AC9 SCKE[2] SSTL_2 2.5 42 OUT AB7 SCKE[1] SSTL_2 2.5 DDR SDRAM IN/OUT Ball Pin I/O Type Voltage OUT AC22 SCS[2]# SSTL_2 2.5 1 OUT AC24 SCAS# SSTL_2 2.5 2 INOUT AG22 SDQ[47] SSTL_2 2.5 3 INOUT AH22 SDQ[43] SSTL_2 2.5 4 INOUT AF22 SDQ[42] SSTL_2 2.5 5 INOUT AG20 SDQ[41] SSTL_2 2.5 6 INOUT AF20 SDQ[44] SSTL_2 2.5 7 INOUT AH21 SDQ[46] SSTL_2 2.5 8 INOUT AH19 SDQ[45] SSTL_2 2.5 9 INOUT AH20 SDQ[40] SSTL_2 2.5 10 INOUT AH16 SDQ[32] SSTL_2 2.5 11 INOUT AD18 SDQ[36] SSTL_2 2.5 12 INOUT AG19 SDQ[39] SSTL_2 2.5 13 INOUT AH18 SDQ[38] SSTL_2 2.5 14 INOUT AF19 SDQ[34] SSTL_2 2.5 15 INOUT AE18 SDQ[37] SSTL_2 2.5 16 INOUT AG17 SDQ[33] SSTL_2 2.5 17 INOUT AE20 SDQ[35] SSTL_2 2.5 18 INOUT AG13 SDQ[26] SSTL_2 2.5 19 INOUT AF14 SDQ[27] SSTL_2 2.5 20 INOUT AF13 SDQ[30] SSTL_2 2.5 21 INOUT AH13 SDQ[31] SSTL_2 2.5 XOR Chain SM 3 XOR Out 160 Intel® 852GM/852GMV Chipset GMCH Datasheet Testability R 22 INOUT AD12 SDQ[29] SSTL_2 2.5 23 INOUT AH10 SDQ[24] SSTL_2 2.5 24 INOUT AH11 SDQ[25] SSTL_2 2.5 25 INOUT AG11 SDQ[28] SSTL_2 2.5 26 INOUT AF10 SDQ[22] SSTL_2 2.5 27 INOUT AE11 SDQ[23] SSTL_2 2.5 28 INOUT AG10 SDQ[19] SSTL_2 2.5 29 INOUT AF8 SDQ[16] SSTL_2 2.5 30 INOUT AH9 SDQ[18] SSTL_2 2.5 31 INOUT AD9 SDQ[21] SSTL_2 2.5 32 INOUT AH7 SDQ[20] SSTL_2 2.5 33 INOUT AG8 SDQ[17] SSTL_2 2.5 34 INOUT AF7 SDQ[14] SSTL_2 2.5 35 INOUT AG7 SDQ[10] SSTL_2 2.5 36 INOUT AE8 SDQ[11] SSTL_2 2.5 37 INOUT AH6 SDQ[15] SSTL_2 2.5 38 INOUT AF5 SDQ[12] SSTL_2 2.5 39 INOUT AD6 SDQ[8] SSTL_2 2.5 40 INOUT AH4 SDQ[13] SSTL_2 2.5 41 INOUT AG5 SDQ[9] SSTL_2 2.5 42 INOUT AH2 SDQ[3] SSTL_2 2.5 43 INOUT AF4 SDQ[2] SSTL_2 2.5 44 INOUT AG4 SDQ[6] SSTL_2 2.5 45 INOUT AH3 SDQ[7] SSTL_2 2.5 46 INOUT AF2 SDQ[0] SSTL_2 2.5 47 INOUT AD3 SDQ[4] SSTL_2 2.5 48 INOUT AE3 SDQ[1] SSTL_2 2.5 49 INOUT AE2 SDQ[5] SSTL_2 2.5 Intel® 852GM/852GMV Chipset GMCH Datasheet 161 Testability R 7.4.1. VCC/VSS Voltage Groups Table 34. Voltage Levels and Ball Out for Voltage Groups Name Voltage Level Ball out VCC 1.2 H14,J15,N14,N16,P13,P15,P17,R14,R16,T13,T15, T17,U14,U16,W21,AA15,AA17,AA19 VCCADAC 1.5 A9,B9 VCCDVO 1.5 E1,E4,E6,H7,J1,J4,J8,K9,L8,M4,M8,M9,N1,N8,P9,R8 VCCASM 1.2 AD1,AF1 VCCDLVDS 1.5 B14,B15,G13,J13 VCCGPIO 3.3 A3,A4 VCCHL 1.2 U6,U8,V1,V7,V9,W5,W8,Y1 VCCQSM 2.5 AJ6,AJ8 VCCSM 2.5 Y4,Y7,Y9,AA6,AA8,AA11,AA13,AB3,AB6,AB8,AB10, AB12,AB14,AB16,AB18,AB20,AB22,AC1,AC29,AF3, AF6,AF9,AF12,AF15,AF18,AF21,AF24,AF27,AF29, AG1,AG29,AJ5,AJ9,AJ13,AJ17,AJ21,AJ25 VCCTXLVDS 2.5 A12,B10,D10,F9 VTTHF 1.5 A22,A24,H29,M29,V29 VTTLF 1.5 A18,A20,A26,F29,G15,H16,H18,H20,H22,J19,K29,L21, M22,N21,P22,R21,T22,U21,V22,Y29,AB29 VSS 0 A13,A17,A19,A21,A23,A25,A27,B5,B24,C1,C7,C10,C22,C29, D4,D11,D13,D15,D17,D19,D21,D23,D25,D28,E7,E9,E28,E29, F11,F13,F16,F18,F20,F22,F24,F27,G1,G4,G7,G26,G29,H8,H11, H13,H15,H17,H19,H21,H24,J7,J10,J12,J14,J16,J18,J20,J22,J26, J29,K4,K8,K24,L1,L6,L9,L22,L26,L29,M7,M21,M24,N4,N9,N13, N15,N17,N22,N26,N29,P8,P14,P16,P21,P24,R2,R7,R9,R13,R15, R17,R22,R26,T4,T8,T9,T14,T16,T21,T24,U1,U5,U9,U13,U15, U17,U22,U26,U29,V8,V21,V24,W4,W9,W22,W26,W29,Y5,Y6, Y8,Y21,AA1,AA4,AA7,AA10,AA12,AA14,AA16,AA18,AA20, AA21,AA23,AA24,AA25,AA29,AB9,AB11,AB13,AB15,AB17, AB19,AB21,AB26,AC4,AC8,AC11,AC14,AC17,AC20,AC23, AC27,AC28,AE1,AE4,AE7,AE10,AE13,AE16,AE19,AE22,AE25, AE28,AG3,AG6,AG9,AG12,AG15,AG18,AG21,AG24,AG27,AJ1, AJ3,AJ7,AJ10,AJ11,AJ12,AJ18,AJ20,AJ23,AJ26,AJ27 162 Intel® 852GM/852GMV Chipset GMCH Datasheet Intel 852GM/852GMV GMCH Strap Pins R 8. Intel 852GM/852GMV GMCH Strap Pins 8.1. Strapping Configuration Table 35. Strapping Signals and Configuration Pin Name HSYNC Strap Description XOR Chain Test Configuration Low = Normal Ops (Default) I/F Type Buffer Type GPIO OUT GPIO OUT High = XOR Test On VSYNC ALL Z Test Low = Normal Ops (Default) High = AllZ Test On LCLKCTLB VTT Voltage Select High = Mobile Intel Pentium 4 Processor–M/ Mobile Intel Celeron processor/Intel Celeron M processor/Intel Celeron D processor on 90 nm process and in the 478-pin package GPIO OUT DVODETECT *DVO Select (If DVODETECT=0 during Reset, ADDID[7:0] is latched to the ADDID Register) Low = DVO (Default) DVO BI * Clock Config: Bit_1 Please refer to Device #0 Function #3 (HPLLCC Register) for proper GST[1:0] settings DVO Out: GST[1] High = Reserved 0) Before CPURST#, there is internal pulldown 1) Just out of CPURST#: These pins are Hi-Z GST[0] * Clock Config: Bit_0 2) C3: these pins are Hi-Z 3) S1-M: these pins are Hi-Z 4) Internal GFX D1/D3: these pins are Hi-Z 5) S3: these pins are Power down 6) S4/S5: these pins are Power down * External pull-ups/downs will be required on the board to enable the non-default state of the straps. Intel® 852GM/852GMV Chipset GMCH Datasheet 163 Intel 852GM/852GMV GMCH Strap Pins R NOTE: All strap signals are sampled with respect to the leading edge of the Intel 852GM/852GMV GMCH PWROK In signal. This page intentionally left blank 164 Intel® 852GM/852GMV Chipset GMCH Datasheet Ballout and Package Information R 9. Ballout and Package Information Figure 11. Intel 852GM/852GMV GMCH Ballout Diagram (Top View) 29 28 27 26 25 24 23 AJ NC NC VSS VSS VCCSM SMVREF _0 VSS AH NC 22 21 SMVSWI VCCSM NGL 20 19 18 17 VSS SMVSWI NGH VSS VCCSM 16 15 SDM[7] SDQS[7] SDQ[56] SDQ[51] SDQS[6] SDQ[49] SDQ[43] SDQ[46] SDQ[40] SDQ[45] SDQ[38] SDQS[4] SDQ[32] SDM[8] VSS VSS VSS VCCSM VCCQS M VSS 5 VCCQS VCCSM M 4 3 2 NC VSS NC SDQ[7] SDQ[3] SDQ[68] SDQ[31] SDM[3] SDQ[25] SDQ[24] SDQ[18] SDQS[2] SDQ[20] SDQ[15] SDQS[1] SDQ[13] SDQ[64] SDQ[26] SDQ[28] SDQ[19] SDQ[2] VCCSM SDQ[0] VSS SDQ[1] SDQ[5] AD BCLK# AC VCCSM AB VTTLF AA Y VSS RSTIN# SDQ[63] SCS[1]# VSS VSS HA[31]# HA[29]# SCK[1] VSS HADSTB HA[27]# HA[22]# [1]# SWE# SCS[3]# SDM[6] SCAS# SCK[1]# SCK[4]# VSS VSS SCS[0]# SBA[0] VSS V VTTHF U VSS HA[28]# HA[25]# VSS HA[10]# HA[12]# SDM[4] VSS SDQ[69] SDQ[65] SDQ[36] SMA[3] SMAB[1] SDQS[8] SMA[1] VSS SMA[2] VSS SCS[2]# SRAS# VSS SMA[10] SMA[0] VSS SCK[4] VCCSM VSS VCCSM VSS VCCSM VSS VCCSM VSS VCCSM VSS VSS DPW R# VSS VSS VCC VSS VCC VSS VCC VSS VCCSM HA[20]# HA[23]# HA[24]# HA[11]# HA[14]# HA[16]# HA[18]# SBA[1] SDQ[37] SDQ[66] RCVENI RCVEN N# OUT HCCVRE VTTLF HA[26]# HA[30]# HA[21]# HA[17]# DPSLP# HAVREF F W SDM[5] VSS VSS VCCSM 6 VCCSM SDQ[59] VCCSM SDQ[61] SDQ[54] VCCSM SDQ[53] SDQ[42] VCCSM SDQ[44] SDQ[34] VCCSM SDQ[71] SDQ[70] VCCSM SDQ[27] SDQ[30] VCCSM SMAB[4] SDQ[22] VCCSM SDQ[16] SDQ[14] VCCSM SDQ[12] SDQS[5] SDQ[35] SDQ[33] SDQ[67] 7 AF VSS VSS 8 SDQS[0] SDQ[50] SDQ[48] SDQ[41] SDQ[39] 9 VSS VSS VSS 10 SDQ[6] SDQ[62] SDQ[57] SDQ[52] SDQ[47] 11 SDQ[9] VSS VSS 12 VCCSM SDQ[58] BCLK SDQ[60] SDQ[55] 13 AG AE VSS 14 VSS VSS SDQS[3] SDQ[23] SDQ[29] SMA[5] SMAB[2] VSS VSS SDM[2] SMA[4] SMAB[5] SDQ[21] SDQ[17] SDQ[10] VSS SDQ[11] VSS SDM[1] SDM[0] SMA[6] SMA[7] SDQ[8] SMA[11] SCK[2]# SDQ[4] SCK[3]# VSS SCKE[0] SMA[8] SMA[9] SCK[2] SCK[3] VSS SCKE[3] SCKE[2] VCCSM VSS VCCSM VSS VCCSM SCKE[1] VCCSM SMA[12] SCK[5]# VCCSM SCK[0] VSS VCCSM VSS NC VCCSM SCK[0]# VSS VCCSM RSVD VSS VSS SCK[5] VCCAGP VCCSM GCLKIN LL VSS VCCSM VSS VCCSM VSS VSS VSS VCC VSS VCCHL HL[7] HL[5] VCCHL VSS HLSTB HL[4] VCCHL VSS VCCHL HL[6] HL[9] HL[10] HL[3] HLSTB# VSS HA[19]# VTTLF VSS VSS HA[15]# HA[8]# HA[7]# VSS VTTLF VSS VCC VSS VCC VSS VSS VCCHL HL[0] VCCHL VSS HL[1] HL[2] PSWING MDDCD ATA RSVD RSVD VSS HL[8] HLRCO MP T HA[5]# HA[13]# HADSTB [0]# HA[4]# VSS HREQ[4] # VTTLF VSS VCC VSS VCC VSS VCC VSS VSS R HREQ[0] # HA[6]# VSS HREQ[3] # HA[9]# HREQ[2] # VSS VTTLF VSS VCC VSS VCC VSS VSS VCCDV O VSS RSVD RSVD RSVD RSVD VSS RS[1]# HREQ[1] # VCC VCCDV O VSS MDDCC LK RSVD RSVD RSVD RSVD RSVD P N M BPRI# VSS HITM# VTTHF DEFER# HIT# RS[2]# L VSS K VTTLF J VSS H VTTHF HYRCO MP HD[1]# G VSS HD[5]# HD[12]# F VTTLF HD[22]# VSS E VSS D VCCAHP LL C B A VSS NC ADS# HLOCK# HD[6]# VSS DBSY# HTRDY# VSS HYSWIN HDSTBP HD[13]# G [0]# HDSTBN HD[4]# [0]# BNR# VSS DRDY# VSS HA[3]# RS[0]# BREQ0# VTTLF VSS VTTLF VSS VCC VTTLF VSS VSS VCC VCC VSS VSS VCC VSS VSS VCCDV O VSS VCCDV MDVICL MI2CDA O K TA VCCDV O VSS VCCDV DVODET O ECT RSVD VSS RSVD RSVD MDVIDA TA RSVD VCCDV O DVOBC CLKINT RSVD VSS DVOCVS YNC RSVD DVOCBL ANK# RSVD HD[8]# HD[3]# HD[7]# VSS VTTLF VSS HD[2]# VSS HD[11]# HD[0]# HDVREF [0] VCCDV O VSS DINV[0]# HD[9]# HD[14]# VSS HDVREF [1] VSS VTTLF VSS HDVREF [2] VSS VCC VSS VCCDLV DS VSS PW ROK VSS VSYNC VCCDV O VSS HD[19]# VTTLF VSS VTTLF VSS VTTLF VSS VTTLF VSS VCC VSS IYBM[0] VSS HSYNC LCLKCT LA VSS VTTLF IYAM[0] IYBM[3] IYBP[3] DDCADA PANELB TA KLTCTL VSS ICLKBP VCCTXL PANELB AGPBUS ADDID[7] ADDID[1] ADDID[5] VDS KLTEN Y# HD[15]# HD[10]# VSS VSS HD[21]# HD[24]# HD[30]# HD[27]# HD[33]# HD[40]# DINV[3]# HD[48]# HD[51]# HD[58]# HD[17]# HD[16]# VSS HD[44]# VSS HD[45]# VSS HD[53]# VSS HD[56]# VSS CPURST IYAP[0] # VSS HDSTBN HDSTBP HDSTBP HD[20]# HD[29]# DINV[1]# HD[38]# HD[41]# HD[50]# HD[49]# HD[61]# HD[59]# IYAM[1] [2]# [2]# [3]# VSS HDSTBP HD[23]# [1]# VSS HD[39]# VSS HDSTBN HD[25]# HD[28]# HD[37]# HD[34]# HD[35]# [1]# HD[31]# HD[18]# HD[26]# DINV[2]# VSS HD[36]# VSS VSS HD[52]# VSS HDSTBN [3]# VSS HD[62]# VSS HD[47]# HD[46]# HD[54]# HD[63]# HD[55]# HD[60]# IYAM[2] IYAP[1] ICLKAM IYAP[2] VCCDLV IYBP[0] DS VSS ICLKAP VSS IYAM[3] HXRCO HXSWIN DREFSS VCCADP VCCDLV VCCDLV HD[43]# HD[42]# HD[32]# HD[57]# IYAP[3] MP G CLK LLB DS DS NC NC VSS VTTLF VSS VTTHF VSS VTTHF VSS VTTLF VSS VTTLF VSS 29 28 27 26 25 24 23 22 21 20 19 18 17 Intel® 852GM/852GMV Chipset GMCH Datasheet VSS 16 15 14 13 RSVD IYBM[1] RSVD IYBM[2] RSVD IYBP[1] ICLKBM VSS VCCTXL VDS IYBP[2] REFSET BLUE# GREEN# BLUE GREEN VSS 11 VSS DVOCD[ DVOCD[ 2] 3] DVOCD[ DVOCD[ VCCDV DVOCCL DVOCCL K K# 4] 5] O VCCDV DVOCD[ DVOCFL DVOCD[ DVOCD[ DVOCD[ O 10] DSTL 9] 8] 6] VSS VSS RSVD VSS ADDID[6] ADDID[4] LIBG VCCADA C RED# RED 10 9 8 7 VSS DVOCD[ DVOBCI 11] NTR# RSVD RSVD VCCDV VCCDV ADDID[0] ADDID[2] ADDID[3] O O EXTTS_ 0 DPMS VSS LCLKCT DDCPDA GST[0] TA LB VSSALV VCCTXL VCCADA VSSADA DREFCL DDCACL C C K K DS VDS VCCTXL VCCALV VDS DS 12 VSS VSS MI2CCL DVOCH DVOCD[ K SYNC 0] VSS DDCPCL K RSVD RSVD GST[1] RSVD RSVD RSVD VCCADP PANELV VCCGPI VCCGPI LLA DDEN O O 6 5 4 3 NC 2 165 Ballout and Package Information R Table 36. Ballout Table Row Column Signal Name Row Column Signal Name Signal Name M 3 DVOBCCLKINT V 23 HA[19]# G 2 DVOBCINTR# W 25 HA[20]# P 3 RSVD Y 25 HA[21]# P 4 RSVD AA 27 HA[22]# R 3 RSVD W 24 HA[23]# R 5 RSVD W 23 HA[24]# M 1 RSVD W 27 HA[25]# M 5 RSVD Y 27 HA[26]# AA 28 HA[27]# W 28 HA[28]# AB 27 HA[29]# P 23 HA[3]# Y 26 HA[30]# AB 28 HA[31]# T 25 HA[4]# T 28 HA[5]# R 27 HA[6]# U 23 HA[7]# U 24 HA[8]# R 24 HA[9]# T 26 HADSTB[0]# AA 26 HADSTB[1]# Y 22 HAVREF Y 28 HCCVREF K 22 HD[0]# H 27 HD[1]# H 25 HD[10]# K 23 HD[11]# G 27 HD[12]# K 26 HD[13]# J 23 HD[14]# H 26 HD[15]# F 25 HD[16]# F 26 HD[17]# B 27 HD[18]# H 23 HD[19]# E 5 ADDID[0] F 5 ADDID[1] E 3 ADDID[2] E 2 ADDID[3] G 5 ADDID[4] F 4 ADDID[5] G 6 ADDID[6] F 6 ADDID[7] R 6 RSVD L 28 ADS# R 4 RSVD F 7 AGPBUSY# P 6 RSVD AE 29 BCLK P 5 RSVD AD 29 BCLK# N 5 RSVD C 9 BLUE P 2 RSVD D 9 BLUE# N 2 RSVD N 25 BNR# N 3 RSVD P 28 BPRI# M 2 RSVD M 23 BREQ0# T 6 RSVD F 15 CPURST# T 5 RSVD M 26 DBSY# L 7 DVODETECT B 6 DDCACLK D 1 DVORCOMP G 9 DDCADATA D 6 EXTTS_0 B 4 DDCPCLK Y 3 GCLKIN C 5 DDCPDATA C 8 GREEN M 28 DEFER# D 8 GREEN# J 25 DINV[0]# F 1 GVREF E 25 DINV[1]# U 28 HA[10]# B 25 DINV[2]# V 28 HA[11]# G 19 DINV[3]# U 27 HA[12]# D 5 DPMS T 27 HA[13]# Y 23 DPSLP# V 27 HA[14]# N 24 DRDY# U 25 HA[15]# B 7 DREFCLK V 26 HA[16]# B 17 DREFSSCLK Y 24 HA[17]# L 2 DVOBBLANK# V 25 HA[18]# 166 Row Column Intel® 852GM Chipset GMCH Datasheet Ballout and Package Information R Row Column Signal Name Row Column Signal Name Row Column Signal Name K 25 HD[2]# G 17 HD[51]# W 2 HL[4] E 27 HD[20]# D 20 HD[52]# W 6 HL[5] G 25 HD[21]# F 19 HD[53]# V 6 HL[6] F 28 HD[22]# C 19 HD[54]# W 7 HL[7] D 27 HD[23]# C 17 HD[55]# T 3 HL[8] G 24 HD[24]# F 17 HD[56]# V 5 HL[9] C 28 HD[25]# B 19 HD[57]# P 27 HLOCK# B 26 HD[26]# G 16 HD[58]# T 2 HLRCOMP G 22 HD[27]# E 16 HD[59]# W 3 HLSTB C 26 HD[28]# L 27 HD[6]# V 2 HLSTB# E 26 HD[29]# C 16 HD[60]# W 1 HLVREF L 24 HD[3]# E 17 HD[61]# R 28 HREQ[0]# G 23 HD[30]# D 16 HD[62]# P 25 HREQ[1]# B 28 HD[31]# C 18 HD[63]# R 23 HREQ[2]# B 21 HD[32]# L 23 HD[7]# R 25 HREQ[3]# G 21 HD[33]# L 25 HD[8]# T 23 HREQ[4]# C 24 HD[34]# J 24 HD[9]# H 10 HSYNC C 23 HD[35]# J 28 HDSTBN[0]# M 25 HTRDY# D 22 HD[36]# C 27 HDSTBN[1]# B 20 HXRCOMP C 25 HD[37]# E 22 HDSTBN[2]# B 18 HXSWING E 24 HD[38]# D 18 HDSTBN[3]# H 28 HYRCOMP D 24 HD[39]# K 27 HDSTBP[0]# K 28 HYSWING J 27 HD[4]# D 26 HDSTBP[1]# D 14 ICLKAM G 20 HD[40]# E 21 HDSTBP[2]# E 13 ICLKAP E 23 HD[41]# E 18 HDSTBP[3]# E 10 ICLKBM B 22 HD[42]# K 21 HDVREF[0] F 10 ICLKBP B 23 HD[43]# J 21 HDVREF[1] G 14 IYAM[0] F 23 HD[44]# J 17 HDVREF[2] E 15 IYAM[1] F 21 HD[45]# N 27 HIT# C 15 IYAM[2] C 20 HD[46]# N 28 HITM# C 13 IYAM[3] C 21 HD[47]# U 7 HL[0] F 14 IYAP[0] G 18 HD[48]# U 4 HL[1] E 14 IYAP[1] E 19 HD[49]# V 4 HL[10] C 14 IYAP[2] G 28 HD[5]# U 3 HL[2] B 13 IYAP[3] E 20 HD[50]# V 3 HL[3] H 12 IYBM[0] Intel® 852GM/852GMV Chipset GMCH Datasheet 167 Ballout and Package Information R Row Column Signal Name Row Column Signal Name Row Column Signal Name E 12 IYBM[1] A 8 RED# D 2 RSVD C 12 IYBM[2] E 8 REFSET C 2 RSVD G 11 IYBM[3] N 23 RS[0]# B 2 RSVD G 12 IYBP[0] P 26 RS[1]# D 7 RSVD E 11 IYBP[1] M 27 RS[2]# AD 22 SBA[0] C 11 IYBP[2] AD 28 RSTIN# AD 20 SBA[1] G 10 IYBP[3] AA 22 DPWR# AC 24 SCAS# H 9 LCLKCTLA L 3 DVOCBLANK# AB 2 SCK[0] C 6 LCLKCTLB J 3 DVOCCLK AA 2 SCK[0]# A 10 LIBG J 2 DVOCCLK# AC 26 SCK[1] P 7 MDDCCLK K 5 DVOCD[0] AB 25 SCK[1]# T 7 MDDCDATA K 1 DVOCD[1] AC 3 SCK[2] N 7 MDVICLK H 6 DVOCD[10] AD 4 SCK[2]# M 6 MDVIDATA G 3 DVOCD[11] AC 2 SCK[3] K 7 MI2CCLK K 3 DVOCD[2] AD 2 SCK[3]# N 6 MI2CDATA K 2 DVOCD[3] AB 23 SCK[4] AJ 29 NC J 6 DVOCD[4] AB 24 SCK[4]# AH 29 NC J 5 DVOCD[5] AA 3 SCK[5] B 29 NC H 2 DVOCD[6] AB 4 SCK[5]# A 29 NC H 1 DVOCD[7] AC 7 SCKE[0] AJ 28 NC H 3 DVOCD[8] AB 7 SCKE[1] A 28 NC H 4 DVOCD[9] AC 9 SCKE[2] AA 9 NC H 5 DVOCFLDSTL AC 10 SCKE[3] AJ 4 NC K 6 DVOCHSYNC AD 23 SCS[0]# AJ 2 NC L 5 DVOCVSYNC AD 26 SCS[1]# A 2 NC F 12 RSVD AC 22 SCS[2]# AH 1 NC D 12 RSVD AC 25 SCS[3]# B 1 NC B 12 RSVD AE 5 SDM[0] G 8 PANELBKLTCTL AA 5 RSVD AE 6 SDM[1] F 8 PANELBKLTEN L 4 RSVD AE 9 SDM[2] A 5 PANELVDDEN C 4 GST[0] AH 12 SDM[3] U 2 PSWING F 3 RSVD AD 19 SDM[4] J 11 PWROK D 3 RSVD AD 21 SDM[5] AC 16 RCVENIN# C 3 GST[1] AD 24 SDM[6] AC 15 RCVENOUT B 3 RSVD AH 28 SDM[7] A 7 RED F 2 RSVD AH 15 SDM[8] 168 Intel® 852GM/852GMV Chipset GMCH Datasheet Ballout and Package Information R Row Column Signal Name Row Column Signal Name Row Column Signal Name AF 2 SDQ[0] AH 20 SDQ[40] AD 6 SDQ[8] AE 3 SDQ[1] AG 20 SDQ[41] AG 5 SDQ[9] AG 7 SDQ[10] AF 22 SDQ[42] AG 2 SDQS[0] AE 8 SDQ[11] AH 22 SDQ[43] AH 5 SDQS[1] AF 5 SDQ[12] AF 20 SDQ[44] AH 8 SDQS[2] AH 4 SDQ[13] AH 19 SDQ[45] AE 12 SDQS[3] AF 7 SDQ[14] AH 21 SDQ[46] AH 17 SDQS[4] AH 6 SDQ[15] AG 22 SDQ[47] AE 21 SDQS[5] AF 8 SDQ[16] AE 23 SDQ[48] AH 24 SDQS[6] AG 8 SDQ[17] AH 23 SDQ[49] AH 27 SDQS[7] AH 9 SDQ[18] AE 2 SDQ[5] AD 15 SDQS[8] AG 10 SDQ[19] AE 24 SDQ[50] AC 18 SMA[0] AF 4 SDQ[2] AH 25 SDQ[51] AD 14 SMA[1] AH 7 SDQ[20] AG 23 SDQ[52] AC 19 SMA[10] AD 9 SDQ[21] AF 23 SDQ[53] AD 5 SMA[11] AF 10 SDQ[22] AF 25 SDQ[54] AB 5 SMA[12] AE 11 SDQ[23] AG 25 SDQ[55] AD 13 SMA[2] AH 10 SDQ[24] AH 26 SDQ[56] AD 17 SMA[3] AH 11 SDQ[25] AE 26 SDQ[57] AD 11 SMA[4] AG 13 SDQ[26] AG 28 SDQ[58] AC 13 SMA[5] AF 14 SDQ[27] AF 28 SDQ[59] AD 8 SMA[6] AG 11 SDQ[28] AG 4 SDQ[6] AD 7 SMA[7] AD 12 SDQ[29] AG 26 SDQ[60] AC 6 SMA[8] AH 2 SDQ[3] AF 26 SDQ[61] AC 5 SMA[9] AF 13 SDQ[30] AE 27 SDQ[62] AD 16 SMAB[1] AH 13 SDQ[31] AD 27 SDQ[63] AC 12 SMAB[2] AH 16 SDQ[32] AG 14 SDQ[64] AF 11 SMAB[4] AG 17 SDQ[33] AE 14 SDQ[65] AD 10 SMAB[5] AF 19 SDQ[34] AE 17 SDQ[66] AB 1 SMRCOMP AE 20 SDQ[35] AG 16 SDQ[67] AJ 24 SMVREF_0 AD 18 SDQ[36] AH 14 SDQ[68] AJ 19 SMVSWINGH AE 18 SDQ[37] AE 15 SDQ[69] AJ 22 SMVSWINGL AH 18 SDQ[38] AH 3 SDQ[7] AC 21 SRAS# AG 19 SDQ[39] AF 16 SDQ[70] AD 25 SWE# AD 3 SDQ[4] AF 17 SDQ[71] W 21 VCC Intel® 852GM/852GMV Chipset GMCH Datasheet 169 Ballout and Package Information R Row Column Signal Name Row Column Signal Name Row Column Signal Name AA 19 VCC L 8 VCCDVO AF 15 VCCSM AA 17 VCC J 8 VCCDVO AB 14 VCCSM T 17 VCC H 7 VCCDVO AJ 13 VCCSM P 17 VCC E 6 VCCDVO AA 13 VCCSM U 16 VCC M 4 VCCDVO AF 12 VCCSM R 16 VCC J 4 VCCDVO AB 12 VCCSM N 16 VCC E 4 VCCDVO AA 11 VCCSM AA 15 VCC N 1 VCCDVO AB 10 VCCSM T 15 VCC J 1 VCCDVO AJ 9 VCCSM P 15 VCC E 1 VCCDVO AF 9 VCCSM J 15 VCC A 4 VCCGPIO Y 9 VCCSM U 14 VCC A 3 VCCGPIO AB 8 VCCSM R 14 VCC V 9 VCCHL AA 8 VCCSM N 14 VCC W 8 VCCHL Y 7 VCCSM H 14 VCC U 8 VCCHL AF 6 VCCSM T 13 VCC V 7 VCCHL AB 6 VCCSM P 13 VCC U 6 VCCHL AA 6 VCCSM B 9 VCCADAC W 5 VCCHL AJ 5 VCCSM A 9 VCCADAC Y 1 VCCHL Y 4 VCCSM A 6 VCCADPLLA V 1 VCCHL AF 3 VCCSM B 16 VCCADPLLB AJ 8 VCCQSM AB 3 VCCSM Y 2 VCCAGPLL AJ 6 VCCQSM AG 1 VCCSM D 29 VCCAHPLL AG 29 VCCSM AC 1 VCCSM A 11 VCCALVDS AF 29 VCCSM A 12 VCCTXLVDS AF 1 VCCASM AC 29 VCCSM D 10 VCCTXLVDS AD 1 VCCASM AF 27 VCCSM B 10 VCCTXLVDS B 15 VCCDLVDS AJ 25 VCCSM F 9 VCCTXLVDS B 14 VCCDLVDS AF 24 VCCSM AA 29 VSS J 13 VCCDLVDS AB 22 VCCSM W 29 VSS G 13 VCCDLVDS AJ 21 VCCSM U 29 VSS P 9 VCCDVO AF 21 VCCSM N 29 VSS M 9 VCCDVO AB 20 VCCSM L 29 VSS K 9 VCCDVO AF 18 VCCSM J 29 VSS R 8 VCCDVO AB 18 VCCSM G 29 VSS N 8 VCCDVO AJ 17 VCCSM E 29 VSS M 8 VCCDVO AB 16 VCCSM C 29 VSS 170 Intel® 852GM/852GMV Chipset GMCH Datasheet Ballout and Package Information R Row Column Signal Name Row Column Signal Name Row Column Signal Name AE 28 VSS D 23 VSS J 18 VSS AC 28 VSS A 23 VSS F 18 VSS E 28 VSS AE 22 VSS AC 17 VSS D 28 VSS W 22 VSS AB 17 VSS AJ 27 VSS U 22 VSS U 17 VSS AG 27 VSS R 22 VSS R 17 VSS AC 27 VSS N 22 VSS N 17 VSS F 27 VSS L 22 VSS H 17 VSS A 27 VSS J 22 VSS D 17 VSS AJ 26 VSS F 22 VSS A 17 VSS AB 26 VSS C 22 VSS AE 16 VSS W 26 VSS AG 21 VSS AA 16 VSS U 26 VSS AB 21 VSS T 16 VSS R 26 VSS AA 21 VSS P 16 VSS N 26 VSS Y 21 VSS J 16 VSS L 26 VSS V 21 VSS F 16 VSS J 26 VSS T 21 VSS AG 15 VSS G 26 VSS P 21 VSS AB 15 VSS AE 25 VSS M 21 VSS U 15 VSS AA 25 VSS H 21 VSS R 15 VSS D 25 VSS D 21 VSS N 15 VSS A 25 VSS A 21 VSS H 15 VSS AG 24 VSS AJ 20 VSS D 15 VSS AA 24 VSS AC 20 VSS AC 14 VSS V 24 VSS AA 20 VSS AA 14 VSS T 24 VSS J 20 VSS T 14 VSS P 24 VSS F 20 VSS P 14 VSS M 24 VSS AE 19 VSS J 14 VSS K 24 VSS AB 19 VSS AE 13 VSS H 24 VSS H 19 VSS AB 13 VSS F 24 VSS D 19 VSS U 13 VSS B 24 VSS A 19 VSS R 13 VSS AJ 23 VSS AJ 18 VSS N 13 VSS AC 23 VSS AG 18 VSS H 13 VSS AA 23 VSS AA 18 VSS F 13 VSS Intel® 852GM/852GMV Chipset GMCH Datasheet 171 Ballout and Package Information R Row Column Signal Name Row Column Signal Name Row Column Signal Name D 13 VSS AJ 7 VSS C 1 VSS A 13 VSS AE 7 VSS B 8 VSSADAC AJ 12 VSS AA 7 VSS B 11 VSSALVDS AG 12 VSS R 7 VSS J 9 VSYNC AA 12 VSS M 7 VSS V 29 VTTHF J 12 VSS J 7 VSS M 29 VTTHF AJ 11 VSS G 7 VSS H 29 VTTHF AC 11 VSS E 7 VSS A 24 VTTHF AB 11 VSS C 7 VSS A 22 VTTHF H 11 VSS AG 6 VSS AB 29 VTTLF F 11 VSS Y 6 VSS Y 29 VTTLF D 11 VSS L 6 VSS K 29 VTTLF AJ 10 VSS Y 5 VSS F 29 VTTLF AE 10 VSS U 5 VSS A 26 VTTLF AA 10 VSS B 5 VSS V 22 VTTLF J 10 VSS AE 4 VSS T 22 VTTLF C 10 VSS AC 4 VSS P 22 VTTLF AG 9 VSS AA 4 VSS M 22 VTTLF AB 9 VSS W 4 VSS H 22 VTTLF W 9 VSS T 4 VSS U 21 VTTLF U 9 VSS N 4 VSS R 21 VTTLF T 9 VSS K 4 VSS N 21 VTTLF R 9 VSS G 4 VSS L 21 VTTLF N 9 VSS D 4 VSS H 20 VTTLF L 9 VSS AJ 3 VSS A 20 VTTLF E 9 VSS AG 3 VSS J 19 VTTLF AC 8 VSS R 2 VSS H 18 VTTLF Y 8 VSS AJ 1 VSS A 18 VTTLF V 8 VSS AE 1 VSS H 16 VTTLF T 8 VSS AA 1 VSS G 15 VTTLF P 8 VSS U 1 VSS K 8 VSS L 1 VSS H 8 VSS G 1 VSS 172 Intel® 852GM/852GMV Chipset GMCH Datasheet Ballout and Package Information R 9.1. Package Mechanical Information The following figures provide detail on the package information and dimensions of the Intel 852GM/852GMV GMCH. The Intel 852GM/852GMV GMCH comes in a Micro-FCBGA package, which is similar to the mobile processors. The package consists of a silicon die mounted face down on an organic substrate populated with solder balls on the bottom side. Capacitors may be placed in the area surrounding the die. Because the die-side capacitors are electrically conductive, and only slightly shorter than the die height, care should be taken to avoid contacting the capacitors with electrically conductive materials. Doing so may short the capacitors and possibly damage the device or render it inactive. The use of an insulating material between the capacitors and any thermal solution should be considered to prevent capacitor shorting. An exclusion, or keepout area, surrounds the die and capacitors, and identifies the contact area for the package. Care should be taken to avoid contact with the package inside this area. Figure 12. Intel 852GM/852GMV GMCH Micro-FCBGA Package Dimensions (Top View) Intel® 852GM852GMV Chipset GMCH Datasheet 173 Ballout and Package Information R Figure 13. Intel 852GM/852GMV GMCH Micro-FCBGA Package Dimensions (Side View) 174 Intel® 852GM/852GMV Chipset GMCH Datasheet Ballout and Package Information R Figure 14. Intel 852GM/852GMV GMCH Micro-FCBGA Package Dimensions (Bottom View) Intel® 852GM/852GMV Chipset GMCH Datasheet 175 Ballout and Package Information R This page intentionally left blank 176 Intel® 852GM/852GMV Chipset GMCH Datasheet