AMD 8151 Translation from AGP requests to link requests, AGP transaction Link transaction

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24888 Rev 3.03 - July 12, 2004

AMD-8151TMAGP Tunnel Data Sheet

All AGP transactions are compliant to AGP ordering rules. APG transactions are translated into link transac- tions as follows:

AGP transaction

Link transaction

 

 

High priority write

WrSized, posted channel, PassPW = 1

 

 

High priority read

RdSized, PassPW = 1, response PassPW = 1

 

 

Low priority write

WrSized, posted channel, PassPW = 0

 

 

Low priority read

RdSized, PassPW = 0, response PassPW = 1

 

 

Low priority flush

Flush, PassPW = 0

 

 

Low priority fence

None (wait for all outstanding read responses)

 

 

Table 2: Translation from AGP requests to link requests.

4.5.2Various Behaviors

The AGP bridge does not claim link special cycles. However, special cycles that are encoded in configura- tion cycles to device 31 of the AGP secondary bus number (per the PCI-to-PCI bridge specification) are translated to AGP bus special cycles.

AGP and PCI read transactions that receive NXA responses from the host complete onto the AGP bus with the data provided by the host (which is required to be all 1’s, per the link specification).

In the translation from type 1 link configuration cycles to secondary bus type 0 configuration cycles, the IC converts the device number to IDSEL AD signal as follows: device 0 maps to AD[16]; device 1 maps to AD[17]; and so forth. Device numbers 16 through 31 are not valid.

The compensation values for drive strength and input impedance that are assigned to non-clock forwarded AGP signals are automatically determined and set by the IC during the first compensation cycle after RESET#. Once set, they do not change until the next RESET# assertion.

Per the link protocol, when the COMPAT bit is set in the transaction, the IC does not ever claim the transac- tion. Such transactions are automatically passed to the other side of the tunnel (or master aborted if the IC is at the end of the chain). This is true of all transactions within address space that is otherwise claimed by the IC, including the space defined by DevB:0x3C[VGAEN].

4.5.2.1AGP Compensation And Calibration Cycles

The AGP PHY includes one compensation circuit for the clock forwarded data signals, A_AD[31:0],

A_CBE_L[3:0], and A_DBI[H, L], and one compensation circuit for the strobes, A_ADSTB[1:0]. Each com- pensation circuit calculates the required rising-edge (P) and falling-edge (N) signal drive strength through a free-running state machine that generates a new value approximately every four microseconds. These values are provided in DevA:0x[50, 54][NCOMP, PCOMP].

Programmable skew values between data signals and strobes are also provided in DevA:0x58.

The compensation values provided to the AGP PHY are software selectable between the calculated compensa- tion values, fixed programmable bypass values, or fixed programmable offsets from the calculated values. Regardless of which value is selected, the value presented to the PHY is never updated until there is a calibra- tion cycle.

Calibration cycles consist of taking control of the AGP bus, updating the AGP PHY compensation values, and then releasing (see DevA:0xA8[PCALCYC]). If enabled by DevA:0xB0[CALDIS], they occur periodically with the period specified by DevA:0xA8[PCALCYC].

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Contents Overview Device FeaturesCover AMD-8151TMDeviceAMD-8151 TM AGP Tunnel Data Sheet Table of Contents Rev 3.03 July 12 System block diagram Configuration space Ball designationsList of Tables IO signal types Tunnel Link Signals ACALD, S and ACALD, S#. Compensation pins for AGP SignalsSERR# and PERR# signals are not supported on the AGP bridge Power and Ground Test and Miscellaneous SignalsPower Plane Sequencing Functional Operation Overview Reset And InitializationClocking Clock GatingLink PHY Tunnel LinksAGP Tags, UnitIDs, And OrderingAGP transaction Link transaction Translation from AGP requests to link requestsVarious Behaviors AGP Compensation And Calibration CyclesRegisters Register Overview Configuration SpaceRegister Naming and Description Conventions AGP Device AGP BridgeMemory mapped address spaces Configuration spacesRegister attributes RESET# AGP Device Status And Command Register DevA0x04AGP Device Revision and Class Code Register DevA0x08 REVISION. Read onlyDefault 0000 00A0h Attribute Read only Default 0000 0000h Attribute Read write onceAGP Device Subsystem ID and Subsystem Vendor ID Register AGP Capabilities Pointer24888 Rev 3.03 July 12 Default 0000 0000h Attribute See belowAGP Miscellaneous Control Register DevA0x40 Nctl 1514 Updated by the hardware approximately every 8 microsecondsPctl 1Fh, then 1Fh is applied 11bAGP Status Register AGP Revision and Capability RegisterBit Gart support. This bit fixed low Host translation#. This bit fixed lowDefault 0000 0000h Attribute Read-write AGP Command RegisterRates Pcalcyc and then DevA0xB0CALDIS should be cleared afterwardAGP3MD Drate Default 0001 0F00h Attribute See belowAGP Control Register AGP Aperture Size RegisterGarthi Gart base address register high Link Command RegisterGartlo Gart base address register low Slave/primary interface type. Read onlyLink Configuration And Control Register Rev 3.03 July 12 Link Frequency Capability 1 Register DevA0xD0 Link Frequency Capability 0 Register DevA0xCCLink Enumeration Scratchpad Register DevA0xD4 Behavior 3021 Reserved 2016 Default See below Attribute See belowBctl Sum exceeds 1Fh, then 1Fh is applied 11b ActlClock Control Register Must be high. See .3.1 for detailsAGP Bridge Status And Command Register DevB0x04 AGP Bridge Configuration RegistersAGP Bridge Vendor And Device ID Register DevB0x00 AGP Bridge Revision and Class Code Register DevB0x08AGP Bridge Memory Base-Limit Registers DevB0x301C 3130 Reserved Default 0000 00FFh Attribute See below DevB0x24. Default 0000 FFF0h Attribute Read-writeDevB0x3C Operating ranges Absolute maximum ratingsElectrical Data Absolute Ratings Operating RangesDC characteristics for signals on the VDD33 power plane Current and power consumptionDC Characteristics Symbol Parameter Description Min Max Units CommentsInput high voltage VDD15 + VDD15 AC Characteristics AC data for common clock operation of AGP signalsSymbol Parameter Description Min Max Units AC data for clocksAGP AC data for clock-forwarded operation of AGP signalsTop side view Ball DesignationsSignal name Ball Signal BGA positionsSignal Ball Name Power and ground BGA positionsPackage mechanical drawing Package SpecificationNand Tree Mode High Impedance ModeTest modes TestNand tree 2 output signal is STRAPL4 Revision Appendix Revision History

8151 specifications

The AMD 8151 is a notable member of AMD's family of chipsets, designed to complement the AMD K5 and K6 processors. Released in the late 1990s, this chipset was primarily targeted at performance-driven PCs. The AMD 8151 provided users with an array of features and technologies that enhanced the overall computing experience, making it a popular choice among system builders and enthusiasts at the time.

One of the standout features of the AMD 8151 is its support for a 64-bit data bus. This significant design choice allowed for faster data transfer rates and better communication between the CPU and other critical components, such as memory. The chipset was capable of supporting multiple memory configurations, including ECC (Error-Correcting Code) memory, which enhanced system reliability, particularly for servers and workstations.

In terms of connectivity, the AMD 8151 included several integrated controllers, such as the PCI controller, which facilitated connections to various peripherals and expansion cards. With its support for the PCI bus, users could take advantage of high-speed devices, such as graphics cards, sound cards, and network adapters, enhancing the overall functionality of their systems.

Another important characteristic of the AMD 8151 is its power management capabilities. The chipset featured advanced power management technologies, which allowed systems to use energy more efficiently. This not only helped reduce operational costs but also contributed to less heat production, extending the longevity of the components within the PC.

The AMD 8151 also offered robust support for a range of bus speeds, which provided flexibility for users looking to customize their systems. With a maximum bus speed of 66 MHz, it was well-suited for the processors of its time, ensuring compatibility and optimal performance.

Moreover, the AMD 8151 played a crucial role in the development of 3D graphics capabilities. It was designed to work seamlessly with AMD's 3D graphics technology, which allowed for improved visual performance in gaming and multimedia applications. This made it an appealing choice for users who prioritized graphics performance.

Overall, the AMD 8151 chipset embodied the technological advancements of its era, providing enhanced performance, flexibility, and reliability. It stood as a testament to AMD's commitment to innovation in the computing space, marking a significant chapter in the evolution of PC architecture.
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