SC2200UFH-300 AMD (ADVANCED MICRO DEVICES), SC2200UFH-300 Datasheet - Page 154

SC2200UFH-300

Manufacturer Part Number

SC2200UFH-300

Description

Manufacturer

AMD (ADVANCED MICRO DEVICES)

Datasheet

1.SC2200UFH-300.pdf (429 pages)

Specifications of SC2200UFH-300

Operating Temperature (min)

Operating Temperature (max)

85C

Operating Temperature Classification

Commercial

Mounting

Surface Mount

Lead Free Status / RoHS Status

Not Compliant

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DMA Addressing Capability

DMA transfers occur over the entire 32-bit address range of

the PCI bus. This is accomplished by using the DMA con-

troller’s 16-bit memory address registers in conjunction

with an 8-bit DMA Low Page register and an 8-bit DMA

High Page register. These registers, associated with each

channel, provide the 32-bit memory address capability. A

write to the Low Page register clears the High Page regis-

ter, for backward compatibility with the PC/AT standard.

The starting address for the DMA transfer must be pro-

grammed into the DMA controller registers and the chan-

nel’s respective Low and High Page registers prior to

beginning the DMA transfer.

DMA Page Registers and Extended Addressing

The DMA Page registers provide the upper address bits

during DMA cycles. DMA addresses do not increment or

decrement across page boundaries. Page boundaries for

the 8-bit channels (Channels 0 through 3) are every 64 KB

and page boundaries for the 16-bit channels (Channels 5,

6, and 7) are every 128 KB.

Before any DMA operations are performed, the Page regis-

ters must be written at the I/O Port addresses in the DMA

controller registers to select the correct page for each DMA

channel. The other address locations between 080h and

08Fh and 480h and 48Fh are not used by the DMA chan-

nels, but can be read or written by a PCI bus master. These

registers are reset to zero at POR. A write to the Low Page

patibility with the PC/AT standard.

For most DMA transfers, the High Page register is set to

zeros and is driven onto PCI address bits AD[31:24] during

DMA cycles. This mode is backward compatible with the

PC/AT standard. For DMA extended transfers, the High

Page register is programmed and the values are driven

onto the PCI addresses AD[31:24] during DMA cycles to

allow access to the full 4 GB PCI address space.

DMA Address Generation

The DMA addresses are formed such that there is an

upper address, a middle address, and a lower address por-

tion.

The upper address portion, which selects a specific page,

is generated by the Page registers. The Page registers for

each channel must be set up by the system before a DMA

operation. The DMA Page register values are driven on

PCI address bits AD[31:16] for 8-bit channels and

AD[31:17] for 16-bit channels.

The middle address portion, which selects a block within

the page, is generated by the DMA controller at the begin-

ning of a DMA operation and any time the DMA address

increments or decrements through a block boundary. Block

sizes are 256 bytes for 8-bit channels (Channels 0 through

3) and 512 bytes for 16-bit channels (Channels 5, 6, and

7). The middle address bits are is driven on PCI address

bits AD[15:8] for 8-bit channels and AD[16:9] for 16-bit

channels.

162

32580B

The lower address portion is generated directly by the DMA

controller during DMA operations. The lower address bits

are output on PCI address bits AD[7:0] for 8-bit channels

and AD[8:1] for 16-bit channels.

BHE# is configured as an output during all DMA opera-

tions. It is driven as the inversion of AD0 during 8-bit DMA

cycles and forced low for all 16-bit DMA cycles.

6.2.6.2

The Core Logic module contains an 8254-equivalent Pro-

grammable Interval Timer (PIT) configured as shown in

Figure 6-7. The PIT has three timers/counters, each with

an input frequency of 1.19318 MHz (OSC divided by 12),

and individually programmable to different modes.

The gates of Counter 0 and 1 are usually enabled, how-

ever, they can be controlled via F0 Index 50h. The gate of

Counter 2 is connected to I/O Port 061h[0]. The output of

Counter 0 is connected internally to IRQ0. This timer is typ-

ically configured in Mode 3 (square wave output), and used

to generate IRQ0 at a periodic rate to be used as a system

timer function. The output of Counter 1 is connected to I/O

Port 061h[4]. The reset state of I/O Port 061h[4] is 0 and

every falling edge of Counter 1 output causes I/O Port

061h[4] to flip states. The output of Counter 2 is brought

out to the PC_BEEP output. This output is gated with I/O

Port 061h[1].

PIT Shadow Register

The PIT registers are shadowed to allow for 0V Suspend to

save/restore the PIT state by reading the PIT’s counter and

write only registers. The read sequence for the shadow

198).

I/O Port 061h[0]

F0 Index 50h[3]

F0 Index 50h[5]

1.19318 MHz

XD[7:0]

A[1:0]

IOW#

Programmable Interval Timer

IOR#

AMD Geode™ SC2200 Processor Data Book

Figure 6-7. PIT Timer

CLK0

CLK1

CLK2

GATE0

GATE1

GATE2

WR#

RD#

OUT0

OUT1

OUT2

F0 Index 50h[4]

F0 Index 50h[6]

I/O Port 061h[1]

Core Logic Module

IRQ0

I/O Port

061h[4]

PC_BEEP

SC2200UFH-300 AMD (ADVANCED MICRO DEVICES), SC2200UFH-300 Datasheet - Page 154

SC2200UFH-300

Specifications of SC2200UFH-300

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