Core Logic Module

32579B

6.2.5.6ROM Interface

The Core Logic module positively decodes memory addresses 000F0000h-000FFFFFh (64 KB) and FFFC0000h-FFFFFFFFh (256 KB) at reset. These memory cycles cause the Core Logic module to claim the cycle, and generate an ISA bus memory cycle with ROMCS# asserted. The Core Logic module can also be configured to respond to memory addresses FF000000h-FFFFFFFFh (16 MB) and 000E0000h-000FFFFFh (128 KB).

8- or 16-bit wide ROM is supported. BOOT16 strap deter- mines the width after reset. MCR[14,3] (Offset 34h) in the General Configuration Block (see Table 4-2 on page 72 for bit details) allows program control of the width.

Flash ROM is supported in the Core Logic module by enabling the ROMCS# signal on write accesses to the ROM region. Normally only read cycles are passed to the ISA bus, and the ROMCS# signal is suppressed for write cycles. When the ROM Write Enable bit (F0 Index 52h[1]) is set, a write access to the ROM address region causes a write cycle to occur with MEMW#, WR# and ROMCS# asserted.

6.2.5.7PCI and Sub-ISA Signal Cycle Multiplexing

The SC1200/SC1201 processor multiplexes most PCI and Sub-ISA signals on the balls listed in Table 6-3,in order to reduce the number of balls on the device. Cycle multiplex- ing is on a bus-cycle by bus-cycle basis (see Figure 6-6 on page 152), where the internal Core Logic PCI bridge arbi- trates between PCI cycles and Sub-ISA cycles. Other PCI and Sub-ISA signals remain non-shared, however, some Sub-ISA signals may be muxed with GPIO.

Sub-ISA cycles are only generated as a result of GX1 mod- ule accesses to the following addresses or conditions:

ROMCS# address range.

DOCCS# address range.

IOCS0# address range.

IOCS1# address range.

An I/O write to address 80h or to 84h.

Internal ISA is programmed to be the subtractive decode agent and no other agents claim the cycle.

If the Sub-ISA and PCI bus have more than four compo- nents, the Sub-ISA components can be buffered using 74HCT245 or 74FCT245 type transceivers. The RD# (an AND of IOR#, MEMR#) signal can be used as DIR control while TRDE# is used as enable control.

Table 6-3. Cycle Multiplexed PCI / Sub-ISA Balls

PCI

Sub-ISA

Ball No.

 

 

 

AD0

A0

U1

 

 

 

AD1

A1

P3

 

 

 

AD2

A2

U3

 

 

 

AD3

A3

N1

 

 

 

AD4

A4

P1

 

 

 

AD5

A5

N3

 

 

 

AD6

A6

N2

 

 

 

AD7

A7

M2

 

 

 

AD8

A8

M4

 

 

 

AD9

A9

L2

 

 

 

AD10

A10

L3

 

 

 

AD11

A11

K1

 

 

 

AD12

A12

L4

 

 

 

AD13

A13

J1

 

 

 

AD14

A14

K4

 

 

 

AD15

A15

J3

 

 

 

AD16

A16

E1

 

 

 

AD17

A17

F4

 

 

 

AD18

A18

E3

 

 

 

AD19

A19

E2

 

 

 

AD20

A20

D3

 

 

 

AD21

A21

D1

 

 

 

AD22

A22

D2

 

 

 

AD23

A23

B6

 

 

 

AD24

D0

C2

 

 

 

AD25

D1

C4

 

 

 

AD26

D2

C1

 

 

 

AD27

D3

D4

 

 

 

AD28

D4

B4

 

 

 

AD29

D5

B3

 

 

 

AD30

D6

A3

 

 

 

AD31

D7

D5

 

 

 

C/BE0#

D8

L1

 

 

 

C/BE1#

D9

J2

 

 

 

C/BE2#

D10

F3

 

 

 

C/BE3#

D11

H4

 

 

 

PAR

D12

J4

 

 

 

TRDY#

D13

F1

 

 

 

IRDY#

D14

F2

 

 

 

STOP#

D15

G1

 

 

 

DEVSEL#

BHE#

E4

 

 

 

AMD Geode™ SC1200/SC1201 Processor Data Book

151

Page 151
Image 151
AMD SC1201, SC1200 Cycle Multiplexed PCI / Sub-ISA Balls, ROM Interface, PCI and Sub-ISA Signal Cycle Multiplexing, Pci