CS5535-UDCF AMD (ADVANCED MICRO DEVICES), CS5535-UDCF Datasheet - Page 198

CS5535-UDCF

Manufacturer Part Number

CS5535-UDCF

Description

Manufacturer

AMD (ADVANCED MICRO DEVICES)

Datasheet

1.CS5535-UDCF.pdf (579 pages)

Specifications of CS5535-UDCF

Operating Temperature (min)

Operating Temperature (max)

85C

Operating Temperature Classification

Commercial

Mounting

Surface Mount

Lead Free Status / RoHS Status

Compliant

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5.20.4

This register contains 53 bits for a GeodeLink™ control

packet and the 17 bits for a GeodeLink data packet. The 17

bits from the data packet are updated if a GeodeLink read

is requested and is available for shifting out. The

GL_DATA description discusses the various conditions

under which a valid request packet is posted to the internal

GeodeLink. Note that since only one GL_ADDR request

packet can be sequenced in with JTAG, the special “read

with byte enable” 2-packet requests that GeodeLink sup-

ports cannot be triggered. Of course, 8, 16, 32, and 64-bit

reads can still be performed and reads of less than 64-bit

sizes will generate the appropriate byte enables at the

device. As with GeodeLink traffic, reads of less than 64 bits

must be to an aligned address, but the data will return in

the GL_DATA adjusted to 64-bit alignment (i.e., a 16-bit

read to address 102h should have address bit 1 set and

data will return in bits [31:16] of the 64-bit response).

Writes of less than 64 bits must always have 64-bit aligned

addresses and should use the byte enables in the data

packet (part of the GL_ADDR data register) to identify

which specific bytes are to be written.

5.20.5

The data transfer rate in and out of the JTAG port is limited

to about 90% of the TCK frequency by the GLCP design.

The GLCP is designed for up to 50 MHz TCKs, but typical

TCK rates for industry interfaces are about 15 MHz. As

such, the GLCP JTAG data rate is 14 Mbits/sec or 1.6

Mbytes/sec. Again, however, industry interface boxes will

limit this rate to about 500 kbytes/sec.

GeodeLink requests packets are triggered at these specific

moments:

• If GL_ADDR has been accessed more recently than

• If GL_ADDR_ACT register has been accessed more

Note that if both MSR accesses from the GLIU and JTAG

accesses are interfacing to these registers, the results will

be non-deterministic.

198

GL_ADDR_ACT and...

— the TYPE of the request is a read and the Update-DR

— the TYPE of the request is a write and the Update-

— the TYPE of the request is a read and the second

recently than GL_ADDR and...

— the GLCP debug logic triggers the GeodeLink_action

JTAG state is entered after loading the GL_ADDR

DR JTAG state is entered after loading the

GL_DATA register.

TCK in the Shift-DR state for shifting out the

GL_DATA register is received and the first two bits

shifted in (GL_DATA DR bits 1 and 0) are non-zero

and the first bit shifted out was non-zero.

due to a debug event occurring.

GL_ADDR

GL_DATA

31506B

5.20.6

Provides a test mode whereby USB interface signals or

memory BIST signals can be accessed by input/output

pads. This access is accomplished by writing to the Auxil-

iary Test Register.

5.20.7

This instruction provides direct access to an MSR used for

the ROM memory BIST test. At the conclusion of the test,

the resulting signature is then checked. A correct test will

result in MBIST_GO being logic-high.

5.20.8

This is the same data register as GL_ADDR, but it disables

any GeodeLink transaction from occurring either on this

access or a following access to the GL_DATA register.

Only the GLCP debug action that triggers a GeodeLink

cycle will cause these bits to be used.

5.20.9

Places the chip in a mode for running IDDQ tests (i.e., gen-

erates an internal signal to disable pull-ups and pull

downs). Also the transceiver is powered off.

5.20.10 REVID

The TAP instruction used to access the current 8-bit revi-

sion code of the chip.

5.20.11 TRISTATE

This instruction will TRI-STATE all of the tri-statable pri-

mary outputs. The DR accessed is the BYPASS register.

5.20.12 BISTDR

Can be used to run all memory BIST controllers in parallel.

5.20.13 IDCODE

This instruction accesses the 32-bit IDCODE register dur-

ing DR access.

5.20.14 BYPASS

In the IEEE 1149.1 specification, shifting all 1s into the IR

must connect the 1-bit BYPASS register. The register has

no function except as a storage flip-flop. This instruction

can also allow relatively easy connection of multiple GLCP

JTAG interface chips. On a board with two GLCP chips,

TMS and TCK of each chip should be wired together and

TDO of one chip should connect to TDI of the other chip.

Note: In parallel scan mode, “input” pads provide data

into the boundary scan cells (the boundary scan

cells provide data into the core). “Cowrie” pads will

behave as dictated by the internal core flops that

normally control the pad; the output data and

enable state will be latched into the boundary scan

cells. “Cheroot” pads will drive out data as dictated

by the internal core flop associated with the pad.

AMD Geode™ CS5535 Companion Device Data Book

PADACC

PROGMISR

MB_ADDR_ACT

TST_IDDQ

TAP Controller

CS5535-UDCF AMD (ADVANCED MICRO DEVICES), CS5535-UDCF Datasheet - Page 198

CS5535-UDCF

Specifications of CS5535-UDCF

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