CIRRUS CS8900A-IQ3

CS8900A
Product Data Sheet
&U\VWDO/$1™ ISA Ethernet
Controller
FEATURES
■ Single-Chip IEEE 802.3 Ethernet Controller with
Direct ISA-Bus Interface
■ Maximum Current Consumption = 55 mA (5V Supply)
DESCRIPTION
■ 3 V Operation
The CS8900A is a low-cost Ethernet LAN Controller optimized for Industry Standard Architecture (ISA)
Personal Computers. Its highly-integrated design eliminates the need for costly external components required
by other Ethernet controllers. The CS8900A includes
on-chip RAM, 10BASE-T transmit and receive filters,
and a direct ISA-Bus interface with 24 mA Drivers.
■ Industrial Temperature Range
■ Comprehensive Suite of Software Drivers Available
■ Efficient PacketPage™ Architecture Operates in
I/O and Memory Space, and as DMA Slave
■ Full Duplex Operation
■ On-Chip RAM Buffers Transmit and Receive Frames
In addition to high integration, the CS8900A offers a
broad range of performance features and configurationoptions.
Its
unique
PacketPage
architecture
automatically adapts to changing network traffic patterns and available system resources. The result is
increased system efficiency.
■ 10BASE-T Port with Analog Filters, Provides:
— Automatic Polarity Detection and Correction
■ AUI Port for 10BASE2, 10BASE5 and 10BASE-F
■ Programmable Transmit Features:
— Automatic Re-transmission on Collision
— Automatic Padding and CRC Generation
The CS8900A is available in a 100-pin TQFP packageideally suited for small form-factor, cost-sensitive
Ethernet applications. With the CS8900A, system engineers can design a complete Ethernet circuit that
occupies less than 1.5 square inches (10 sq. cm) of
board space.
■ Programmable Receive Features:
—
—
—
—
Stream Transfer™ for Reduced CPU Overhead
Auto-Switch Between DMA and On-Chip Memory
Early Interrupts for Frame Pre-Processing
Automatic Rejection of Erroneous Packets
■ EEPROM Support for Jumperless Configuration
ORDERING INFORMATION
CS8900A-CQ 0° to 70° C
CS8900A-IQ
-40° to 85° C
CS8900A-CQ3 0° to 70° C
CS8900A-IQ3 -40° to 85° C
CRD8900A-1
■ Boot PROM Support for Diskless Systems
■ Boundary Scan and Loopback Test
■ LED Drivers for Link Status and LAN Activity
■ Standby and Suspend Sleep Modes
5V
TQFP-100
5V
TQFP-100
3.3V TQFP-100
3.3V TQFP-100
Evaluation Kit
20 MHz
XTAL
EEPROM
CS8900A ISA Ethernet Controller
LED
Control
EEPROM
Control
I
S
A
Clock
RAM
Encoder/
Decoder
&
PLL
ISA
Bus
Logic
Memory
Manager
802.3
MAC
Engine
Boundary
Power
Scan
Manager
Test Logic
10BASE-T
RX Filters &
Receiver
10BASE-T
TX Filters &
Transmitter
AUI
Transmitter
AUI
Collision
AUI
Receiver
RJ-45
10BASE-T
Attachment
Unit
Interface
(AUI)
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
Copyright  Cirrus Logic, Inc. 1999
(All Rights Reserved)
MAR ‘99
CS8900A
Crystal LAN™ ISA Ethernet Controller
TABLE OF CONTENTS
1.0 INTRODUCTION ......................................................................................................................................... 8
1.1 General Description............................................................................................................................... 8
1.1.1 Direct ISA-Bus Interface .............................................................................................................. 8
1.1.2 Integrated Memory....................................................................................................................... 8
1.1.3 802.3 Ethernet MAC Engine ........................................................................................................ 8
1.1.4 EEPROM Interface ...................................................................................................................... 8
1.1.5 Complete Analog Front End ........................................................................................................ 8
1.2 System Applications .............................................................................................................................. 8
1.2.1 Motherboard LANs....................................................................................................................... 8
1.2.2 Ethernet Adapter Cards ............................................................................................................... 9
1.3 Key Features and Benefits .................................................................................................................. 10
1.3.1 Very Low Cost ........................................................................................................................... 10
1.3.2 High Performance ...................................................................................................................... 10
1.3.3 Low Power and Low Noise ........................................................................................................ 10
1.3.4 Complete Support ...................................................................................................................... 10
2.0 PIN DESCRIPTION ................................................................................................................................ 12
3.0 FUNCTIONAL DESCRIPTION .................................................................................................................. 17
3.1 Overview ............................................................................................................................................. 17
3.1.1 Configuration ............................................................................................................................. 17
3.1.2 Packet Transmission.................................................................................................................. 17
3.1.3 Packet Reception....................................................................................................................... 17
3.2 ISA Bus Interface ................................................................................................................................ 18
3.2.1 Memory Mode Operation ........................................................................................................... 18
3.2.2 I/O Mode Operation ................................................................................................................... 18
3.2.3 Interrupt Request Signals .......................................................................................................... 18
3.2.4 DMA Signals .............................................................................................................................. 18
3.3 Reset and Initialization ........................................................................................................................ 19
3.3.1 Reset ......................................................................................................................................... 19
3.3.1.1 External Reset, or ISA Reset ........................................................................................... 19
3.3.1.2 Power-Up Reset ............................................................................................................... 19
3.3.1.3 Power-Down Reset .......................................................................................................... 19
3.3.1.4 EEPROM Reset ............................................................................................................... 19
3.3.1.5 Software Initiated Reset ................................................................................................... 19
3.3.1.6 Hardware (HW) Standby or Suspend............................................................................... 19
3.3.1.7 Sof tware (SW) Suspend.................................................................................................. 19
3.3.2 Allowing Time for Reset Operation ............................................................................................ 19
3.3.3 Bus Reset Considerations ......................................................................................................... 19
3.3.4 Initialization ................................................................................................................................ 20
3.4 Configurations with EEPROM ............................................................................................................. 21
3.4.1 EEPROM Interface .................................................................................................................... 21
3.4.2 EEPROM Memory Organization ................................................................................................ 21
3.4.3 Reset Configuration Block ......................................................................................................... 21
3.4.3.1 Reset Configuration Block Structure ................................................................................ 21
3.4.3.2 Reset Configuration Block Header ................................................................................... 21
3.4.3.3 Determining the EEPROM Type ...................................................................................... 21
3.4.3.4 Checking EEPROM for presence of Reset Configuration Block ...................................... 21
3.4.3.5 Determining Number of Bytes in the Reset Configuration Block ...................................... 22
3.4.4 Groups of Configuration Data .................................................................................................... 22
3.4.4.1 Group Header................................................................................................................... 23
3.4.5 Reset Configuration Block Checksum ....................................................................................... 23
3.4.6 EEPROM Example .................................................................................................................... 23
3.4.7 EEPROM Read-out ................................................................................................................... 23
CIRRUS LOGIC PRODUCT DATA SHEET
2
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
3.4.7.1 Determining EEPROM Size ............................................................................................. 23
3.4.7.2 Loading Configuration Data ............................................................................................. 24
3.4.8 EEPROM Read-out Completion ................................................................................................ 24
3.5 Programming the EEPROM ................................................................................................................ 24
3.5.1 EEPROM Commands................................................................................................................ 24
3.5.2 EEPROM Command Execution................................................................................................. 24
3.5.3 Enabling Access to the EEPROM ............................................................................................. 25
3.5.4 Writing and Erasing the EEPROM............................................................................................. 25
3.6 Boot PROM Operation ........................................................................................................................ 25
3.6.1 Accessing the Boot PROM ........................................................................................................ 25
3.6.2 Configuring the CS8900A for Boot PROM Operation................................................................ 25
3.7 Low-Power Modes .............................................................................................................................. 26
3.7.1 Hardware Standby ..................................................................................................................... 26
3.7.2 Hardware Suspend.................................................................................................................... 26
3.7.3 Software Suspend ..................................................................................................................... 27
3.8 LED Outputs........................................................................................................................................ 28
3.8.0.1 LANLED ........................................................................................................................... 28
3.8.0.2 LINKLED or HC0.............................................................................................................. 28
3.8.0.3 BSTATUS or HC1 ............................................................................................................ 28
3.8.1 LED Connection ........................................................................................................................ 28
3.9 Media Access Control ......................................................................................................................... 28
3.9.1 Overview.................................................................................................................................... 28
3.9.2 Frame Encapsulation and Decapsulation .................................................................................. 29
3.9.2.1 Transmission.................................................................................................................... 29
3.9.2.2 Reception ......................................................................................................................... 29
3.9.2.3 Enforcing Minimum Frame Size ....................................................................................... 29
3.9.3 Transmit Error Detection and Handling ..................................................................................... 30
3.9.3.1 Loss of Carrier.................................................................................................................. 30
3.9.3.2 SQE Error......................................................................................................................... 30
3.9.3.3 Out-of-Window (Late) Collision ........................................................................................ 30
3.9.3.4 Jabber Error ..................................................................................................................... 30
3.9.3.5 Transmit Collision............................................................................................................. 30
3.9.3.6 Transmit Underrun ........................................................................................................... 30
3.9.4 Receive Error Detection and Handling ...................................................................................... 31
3.9.4.1 CRC Error ........................................................................................................................ 31
3.9.4.2 Runt Frame ...................................................................................................................... 31
3.9.4.3 Extra Data ........................................................................................................................ 31
3.9.4.4 Dribble Bits and Alignment Error...................................................................................... 31
3.9.5 Media Access Management ...................................................................................................... 31
3.9.5.1 Collision Avoidance.......................................................................................................... 31
3.9.5.2 Two-Part Deferral............................................................................................................. 31
3.9.5.3 Simple Deferral ................................................................................................................ 32
3.9.5.4 Collision Resolution.......................................................................................................... 32
3.9.5.5 Normal Collisions ............................................................................................................. 32
3.9.5.6 Late Collisions.................................................................................................................. 33
3.9.5.7 Backoff ............................................................................................................................. 33
3.9.5.8 Standard Backoff.............................................................................................................. 33
3.9.5.9 Modified Backoff............................................................................................................... 33
3.9.5.10 SQE Test........................................................................................................................ 33
3.10 Encoder/Decoder (ENDEC) .............................................................................................................. 34
3.10.1 Encoder ................................................................................................................................... 34
3.10.2 Carrier Detection ..................................................................................................................... 34
3.10.3 Clock and Data Recovery ........................................................................................................ 34
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
3
CS8900A
Crystal LAN™ ISA Ethernet Controller
3.10.4 Interface Selection ................................................................................................................... 35
3.10.4.1 10BASE-T Only .............................................................................................................. 35
3.10.4.2 AUI Only ......................................................................................................................... 35
3.10.4.3 Auto-Select..................................................................................................................... 35
3.11 10BASE-T Transceiver...................................................................................................................... 35
3.11.1 10BASE-T Filters ..................................................................................................................... 35
3.11.2 Transmitter............................................................................................................................... 36
3.11.3 Receiver................................................................................................................................... 36
3.11.3.1 Squelch Circuit ............................................................................................................... 36
3.11.3.2 Extended Range............................................................................................................. 36
3.11.4 Link Pulse Detection ................................................................................................................ 36
3.11.5 Receive Polarity Detection and Correction .............................................................................. 37
3.11.6 Collision Detection ................................................................................................................... 37
3.12 Attachment Unit Interface (AUI) ........................................................................................................ 37
3.12.1 AUI Transmitter........................................................................................................................ 37
3.12.2 AUI Receiver............................................................................................................................ 38
3.12.3 Collision Detection ................................................................................................................... 38
3.13 External Clock Oscillator ................................................................................................................... 38
4.0 PACKETPAGE ARCHITECTURE ............................................................................................................ 39
4.1 PacketPage Overview ......................................................................................................................... 39
4.1.1 Integrated Memory..................................................................................................................... 39
4.1.2 Bus Interface Registers ............................................................................................................. 39
4.1.3 Status and Control Registers ..................................................................................................... 39
4.1.4 Initiate Transmit Registers ......................................................................................................... 39
4.1.5 Address Filter Registers............................................................................................................. 39
4.1.6 Receive and Transmit Frame Locations .................................................................................... 39
4.2 PacketPage Memory Map ................................................................................................................... 40
4.3 Bus Interface Registers ....................................................................................................................... 42
4.3.1 Product Identification Code ....................................................................................................... 42
4.3.2 I/O Base Address ...................................................................................................................... 42
4.3.3 Interrupt Number ....................................................................................................................... 43
4.3.4 DMA Channel Number .............................................................................................................. 43
4.3.5 DMA Start of Frame .................................................................................................................. 44
4.3.6 DMA Frame Count ................................................................................................................... 44
4.3.7 RxDMA Byte Count .................................................................................................................. 44
4.3.8 Memory Base Address .............................................................................................................. 44
4.3.9 Boot PROM Base Address ....................................................................................................... 45
4.3.10 Boot PROM Address Mask ..................................................................................................... 45
4.3.11 EEPROM Command ............................................................................................................... 46
4.3.12 EEPROM Data ........................................................................................................................ 46
4.3.13 Receive Frame Byte Counter .................................................................................................. 46
4.4 Status and Control Registers .............................................................................................................. 47
4.4.1 Configuration and Control Registers.......................................................................................... 47
4.4.2 Status and Event Registers ....................................................................................................... 47
4.4.3 Status and Control Bit Definitions .............................................................................................. 47
4.4.3.1 Act-Once Bits ................................................................................................................... 48
4.4.3.2 Temporal Bits ................................................................................................................... 48
4.4.3.3 Interrupt Enable Bits and Events...................................................................................... 48
4.4.3.4 Accept Bits ....................................................................................................................... 48
4.4.4 Status and Control Register Summary ...................................................................................... 49
4.4.5 Register 0: Interrupt Status Queue .......................................................................................... 52
4.4.6 Register 3: Receiver Configuration .......................................................................................... 53
4.4.7 Register 4: Receiver Event ...................................................................................................... 54
CIRRUS LOGIC PRODUCT DATA SHEET
4
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.8 Register 5: Receiver Control ................................................................................................... 55
4.4.9 Register 7: Transmit Configuration .......................................................................................... 56
4.4.10 Register 8: Transmitter Event ................................................................................................ 57
4.4.11 Register 9: Transmit Command Status ................................................................................. 58
4.4.12 Register B: Buffer Configuration ............................................................................................ 59
4.4.13 Register C: Buffer Event ........................................................................................................ 60
4.4.14 Register 10: Receiver Miss Counter ...................................................................................... 61
4.4.15 Register 10: Transmit Collision Counter ................................................................................ 62
4.4.16 Register 13: Line Control ....................................................................................................... 63
4.4.17 Register 14: Line Status ........................................................................................................ 64
4.4.18 Register 15: Self Control ....................................................................................................... 65
4.4.19 Register 16: Self Status ......................................................................................................... 66
4.4.20 Register 17: Bus Control ....................................................................................................... 67
4.4.21 Register 18: Bus Status ......................................................................................................... 68
4.4.22 Register 19: Test Control ....................................................................................................... 69
4.4.23 Register 1C: AUI Time Domain Reflectometer ...................................................................... 70
4.5 Initiate Transmit Registers .................................................................................................................. 71
4.5.1 Transmit Command Request - TxCMD .................................................................................... 71
4.5.2 Transmit Length ........................................................................................................................ 71
4.6 Address Filter Registers...................................................................................................................... 72
4.6.1 Logical Address Filter (hash table) ........................................................................................... 72
4.6.2 Individual Address (IEEE address) ........................................................................................... 72
4.7 Receive and Transmit Frame Locations ............................................................................................. 73
4.7.1 Receive PacketPage Locations ................................................................................................. 73
4.7.2 Transmit Locations .................................................................................................................... 73
4.8 Eight and Sixteen Bit Transfers........................................................................................................... 73
4.8.1 Transferring Odd-Byte-Aligned Data ......................................................................................... 74
4.8.2 Random Access to CS8900A Memory ...................................................................................... 74
4.9 Memory Mode Operation .................................................................................................................... 74
4.9.1 Accesses in Memory Mode ....................................................................................................... 74
4.9.2 Configuring the CS8900A for Memory Mode............................................................................. 74
4.9.3 Basic Memory Mode Transmit ................................................................................................... 75
4.9.4 Basic Memory Mode Receive .................................................................................................... 75
4.9.5 Polling the CS8900A in Memory Mode...................................................................................... 76
4.10 I/O Space Operation ......................................................................................................................... 76
4.10.1 Receive/Transmit Data Ports 0 and 1...................................................................................... 76
4.10.2 TxCMD Port............................................................................................................................. 76
4.10.3 TxLength Port .......................................................................................................................... 76
4.10.4 Interrupt Status Queue Port..................................................................................................... 76
4.10.5 PacketPage Pointer Port ......................................................................................................... 76
4.10.6 PacketPage Data Ports 0 and 1 .............................................................................................. 77
4.10.7 I/O Mode Operation ................................................................................................................. 77
4.10.8 Basic I/O Mode Transmit ......................................................................................................... 77
4.10.9 Basic I/O Mode Receive .......................................................................................................... 77
4.10.10 Accessing Internal Registers ................................................................................................. 78
4.10.11 Polling the CS8900A in I/O Mode.......................................................................................... 78
5.0 OPERATION ............................................................................................................................................. 79
5.1 Managing Interrupts and Servicing the Interrupt Status Queue .......................................................... 79
5.2 Basic Receive Operation..................................................................................................................... 79
5.2.0.1 Overview .......................................................................................................................... 79
5.2.1 Terminology: Packet, Frame, and Transfer ............................................................................... 81
5.2.1.1 Packet .............................................................................................................................. 81
5.2.1.2 Frame............................................................................................................................... 81
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
5
CS8900A
Crystal LAN™ ISA Ethernet Controller
5.3
5.4
5.5
5.6
5.7
5.2.1.3 Transfer ............................................................................................................................ 81
5.2.2 Receive Configuration ............................................................................................................... 81
5.2.2.1 Configuring the Physical Interface.................................................................................... 81
5.2.2.2 Choosing which Frame Types to Accept.......................................................................... 81
5.2.2.3 Selecting which Events Cause Interrupts ......................................................................... 82
5.2.2.4 Choosing How to Transfer Frames .................................................................................. 82
5.2.3 Receive Frame Pre-Processing ................................................................................................. 83
5.2.3.1 Destination Address Filtering ........................................................................................... 83
5.2.3.2 Early Interrupt Generation ................................................................................................ 84
5.2.3.3 Acceptance Filtering......................................................................................................... 84
5.2.3.4 Normal Interrupt Generation............................................................................................. 84
5.2.4 Held vs. DMAed Receive Frames.............................................................................................. 84
5.2.5 Buffering Held Receive Frames ................................................................................................. 84
5.2.6 Transferring Held Receive Frames ............................................................................................ 86
5.2.7 Receive Frame Visibility............................................................................................................. 86
5.2.8 Example of Memory Mode Receive Operation .......................................................................... 86
5.2.9 Receive Frame Byte Counter..................................................................................................... 87
Receive Frame Address Filtering ........................................................................................................ 87
5.3.0.1 Individual Address Frames............................................................................................... 88
5.3.0.2 Multicast Frames .............................................................................................................. 88
5.3.0.3 Broadcast Frames ............................................................................................................ 88
5.3.1 Configuring the Destination Address Filter ................................................................................ 88
5.3.2 Hash Filter ................................................................................................................................. 89
5.3.2.1 Hash Filter Operation ....................................................................................................... 89
5.3.3 Broadcast Frame Hashing Exception ........................................................................................ 89
Receive DMA ...................................................................................................................................... 90
5.4.1 Overview .................................................................................................................................... 90
5.4.2 Configuring the CS8900A for DMA Operation ........................................................................... 90
5.4.3 DMA Receive Buffer Size .......................................................................................................... 90
5.4.4 Receive-DMA-Only Operation ................................................................................................... 91
5.4.5 Committing Buffer Space to a DMAed Frame............................................................................ 92
5.4.6 DMA Buffer Organization ........................................................................................................... 92
5.4.7 RxDMAFrame Bit ....................................................................................................................... 92
5.4.8 Receive DMA Example Without Wrap-Around .......................................................................... 92
5.4.9 Receive DMA Operation for RxDMA-Only Mode ....................................................................... 92
Auto-Switch DMA ................................................................................................................................ 93
5.5.1 Overview .................................................................................................................................... 93
5.5.2 Configuring the CS8900A for Auto-Switch DMA........................................................................ 94
5.5.3 Auto-Switch DMA Operation ...................................................................................................... 94
5.5.4 DMA Channel Speed vs. Missed Frames .................................................................................. 95
5.5.5 Exit From DMA........................................................................................................................... 95
5.5.6 Auto-Switch DMA Example........................................................................................................ 96
StreamTransfer ................................................................................................................................... 96
5.6.1 Overview .................................................................................................................................... 96
5.6.2 Configuring the CS8900A for StreamTransfer ........................................................................... 96
5.6.3 StreamTransfer Operation ......................................................................................................... 96
5.6.4 Keeping StreamTransfer Mode Active ....................................................................................... 96
5.6.5 Example of StreamTransfer ....................................................................................................... 98
5.6.6 Receive DMA Summary............................................................................................................. 98
Transmit Operation.............................................................................................................................. 99
5.7.1 Overview .................................................................................................................................... 99
5.7.2 Transmit Configuration............................................................................................................... 99
5.7.2.1 Configuring the Physical Interface.................................................................................... 99
CIRRUS LOGIC PRODUCT DATA SHEET
6
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
6.0
7.0
8.0
9.0
5.7.2.2 Selecting which Events Cause Interrupts......................................................................... 99
5.7.3 Changing the Configuration....................................................................................................... 99
5.7.4 Enabling CRC Generation and Padding.................................................................................. 100
5.7.5 Individual Packet Transmission ............................................................................................... 100
5.7.6 Transmit in Poll Mode .............................................................................................................. 101
5.7.7 Transmit in Interrupt Mode ...................................................................................................... 101
5.7.8 Completing Transmission ........................................................................................................ 103
5.7.9 Rdy4TxNOW vs. Rdy4Tx ........................................................................................................ 103
5.7.10 Committing Buffer Space to a Transmit Frame ..................................................................... 103
5.7.11 Transmit Frame Length ......................................................................................................... 105
5.8 Full duplex Considerations................................................................................................................ 105
5.9 Auto-Negotiation Considerations ...................................................................................................... 105
TEST MODES ......................................................................................................................................... 106
6.0.1 Loopback & Collision Diagnostic Tests ................................................................................... 106
6.0.2 Internal Tests ........................................................................................................................... 106
6.0.3 External Tests.......................................................................................................................... 106
6.0.4 Loopback Tests ....................................................................................................................... 106
6.0.5 10BASE-T Loopback and Collision Tests................................................................................ 106
6.0.6 AUI Loopback and Collision Tests........................................................................................... 106
6.1 Boundary Scan.................................................................................................................................. 107
6.1.1 Output Cycle ............................................................................................................................ 107
6.1.2 Input Cycle............................................................................................................................... 107
6.1.3 Continuity Cycle....................................................................................................................... 108
CHARACTERISTICS/SPECIFICATIONS ............................................................................................... 111
7.1 ABSOLUTE MAXIMUM RATINGS.................................................................................................... 111
7.2 RECOMMENDED OPERATING CONDITIONS ............................................................................... 111
7.3 DC CHARACTERISTICS .................................................................................................................. 111
7.4 SWITCHING CHARACTERISTICS................................................................................................... 113
7.5 10BASE-T WIRING........................................................................................................................... 120
7.6 AUI WIRING ................................................................................................................................... 121
7.7 QUARTZ CRYSTAL REQUIREMENTS............................................................................................ 121
PHYSICAL DIMENSIONS....................................................................................................................... 122
GLOSSARY OF TERMS......................................................................................................................... 123
9.1 Acronyms .......................................................................................................................................... 123
9.2 Definitions ......................................................................................................................................... 124
9.3 Acronyms Specific to the CS8900A .................................................................................................. 125
9.4 Terms Specific to the CS8900A ........................................................................................................ 125
9.5 Suffixes Specific to the CS8900A. .................................................................................................... 126
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
7
CS8900A
Crystal LAN™ ISA Ethernet Controller
1.0 INTRODUCTION
1.1 General Description
The CS8900A is a true single-chip, full-duplex,
Ethernet solution, incorporating all of the analog
and digital circuitry needed for a complete Ethernet
circuit. Major functional blocks include: a direct
ISA-bus interface; an 802.3 MAC engine; integrated buffer memory; a serial EEPROM interface; and
a complete analog front end with both 10BASE-T
and AUI.
1.1.1 Direct ISA-Bus Interface
Included in the CS8900A is a direct ISA-bus interface with full 24 mA drive capability. Its configuration options include a choice of four interrupts
and three DMA channels (one of each selected during initialization). In Memory Mode, it supports
Standard or Ready Bus cycles without introducing
additional wait states.
1.1.2 Integrated Memory
The CS8900A incorporates a 4-Kbyte page of onchip memory, eliminating the cost and board area
associated with external memory chips. Unlike
most other Ethernet controllers, the CS8900A buffers entire transmit and receive frames on chip,
eliminating the need for complex, inefficient memory management schemes. In addition, the
CS8900A operates in either Memory space, I/O
space, or with external DMA controllers, providing
maximum design flexibility.
1.1.3 802.3 Ethernet MAC Engine
The CS8900A’s Ethernet Media Access Control
(MAC) engine is fully compliant with the IEEE
802.3 Ethernet standard (ISO/IEC 8802-3, 1993),
and supports full-duplex operation. It handles all
aspects of Ethernet frame transmission and reception, including: collision detection, preamble generation and detection, and CRC generation and test.
Programmable MAC features include automatic re-
transmission on collision, and automatic padding
of transmitted frames.
1.1.4 EEPROM Interface
The CS8900A provides a simple and efficient serial EEPROM interface that allows configuration information to be stored in an optional EEPROM,
and then loaded automatically at power-up. This
eliminates the need for costly and cumbersome
switches and jumpers.
1.1.5 Complete Analog Front End
The CS8900A’s analog front end incorporates a
Manchester encoder/decoder, clock recovery circuit, 10BASE-T transceiver, and complete Attachment Unit Interface (AUI). It provides manual and
automatic selection of either 10BASE-T or AUI,
and offers three on-chip LED drivers for link status, bus status, and Ethernet line activity.
The 10BASE-T transceiver includes drivers, receivers, and analog filters, allowing direct connection to low-cost isolation transformers. It supports
100, 120, and 150 Ω shielded and unshielded cables, extended cable lengths, and automatic receive
polarity reversal detection and correction.
The AUI port provides a direct interface to
10BASE-2, 10BASE-5 and 10BASE-FL networks,
and is capable of driving a full 50-meter AUI cable.
1.2 System Applications
The CS8900A is designed to work well in either
motherboard or adapter applications.
1.2.1 Motherboard LANs
The CS8900A requires the minimum number of
external components needed for a full Ethernet
node. Its small-footprint package and high level of
integration allow System Engineers to design a
complete Ethernet circuit that occupies as little as
1.5 square inches of PCB area (Figure 1). In addition, the CS8900A’s power-saving features and
CMOS design make it a perfect fit for power-sensi-
CIRRUS LOGIC PRODUCT DATA SHEET
8
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
(2.0 sq. in.)
EEPROM 20 MHz
XTAL
I
S
A
CS8900A
RJ-45
10BASE-T
Figure 1. Complete Ethernet Motherboard Solution
tive portable and desktop PCs. Motherboard design
options include:
•
•
An EEPROM can be used to store node-specific information, such as the Ethernet Individual
Address and node configuration.
The 20 MHz crystal oscillator may be replaced
by a 20 MHz clock signal.
1.2.2 Ethernet Adapter Cards
The CS8900A’s highly efficient PacketPage architecture, with StreamTransfer™ and Auto-Switch
DMA options, make it an excellent choice for highperformance, low-cost ISA adapter cards
(Figure 2). The CS8900A’s wide range of configuration options and performance features allow en-
gineers to design Ethernet solutions that meet their
particular system requirements. Adapter card design options include:
•
A Boot PROM can be added to support diskless
applications.
•
The 10BASE-T transmitter and receiver impedance can be adjusted to support 100, 120, or
150 Ohm twisted pair cables.
•
An external Latchable-Address-bus decode circuit can be added to operate the CS8900A in
Upper-Memory space.
•
On-chip LED ports can be used for either optional LEDs, or as programmable outputs.
LED
RJ-45
EEPROM
’245
20 MHz
XTAL
CS8900A
Boot PROM
Attachment
Unit
Interface
(AUI)
Figure 2. Full-Featured ISA Adapter Solution
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
9
CS8900A
Crystal LAN™ ISA Ethernet Controller
1.3 Key Features and Benefits
1.3.1 Very Low Cost
The CS8900A is designed to provide the lowestcost Ethernet solution available for embedded applications, portable motherboards, non-ISA bus
systems and adapter cards. Cost-saving features include:
older I/O-space designs, PacketPage is faster, simpler and more efficient.
To boost performance further, the CS8900A includes several key features that increase throughput
and lower CPU overhead, including:
•
StreamTransfer cuts up to 87% of interrupts to
the host CPU during large block transfers.
•
Integrated RAM eliminates the need for expensive external memory chips.
•
•
On-chip 10BASE-T filters allow designers to
use simple isolation transformers instead of
more costly filter/transformer packages.
Auto-Switch DMA allows the CS8900A to
maximize throughput while minimizing missed
frames.
•
Early interrupts allow the host to preprocess incoming frames.
On-chip buffering of full frames cuts the
amount of host bandwidth needed to manage
Ethernet traffic.
•
The serial EEPROM port, used for configuration and initialization, eliminates the need for
expensive switches and jumpers.
•
•
The CS8900A is designed to be used on a 2layer circuit board instead of a more expensive
multilayer board.
•
The 8900A-based solution offers the smallest
footprint available, saving valuable printed circuit board area.
•
A set of certified software drivers is available at
no charge, eliminating the need for costly software development.
1.3.3 Low Power and Low Noise
For low power needs, the CS8900A offers three
power-down options: Hardware Standby, Hardware Suspend, and Software Suspend. In Standby
mode, the chip is powered down with the exception
of the 10BASE-T receiver, which is enabled to listen for link activity. In either Hardware or Software
Suspend mode, the receiver is disabled and power
consumption drops to the micro-ampere range.
1.3.2 High Performance
The CS8900A is a full 16-bit Ethernet controller
designed to provide optimal system performance
by minimizing time on the ISA bus and CPU overhead per frame. It offers equal or superior performance for less money when compared to other
Ethernet controllers. The CS8900A’s PacketPage
architecture allows software to select whichever
access method is best suited to each particular
CPU/ISA-bus configuration. When compared to
In addition, the CS8900A has been designed for
very low noise emission, thus shortening the time
required for EMI testing and qualification.
1.3.4 Complete Support
The CS8900A comes with a suite of software drivers for immediate use with most industry standard
network operating systems. In addition, complete
evaluation kits and manufacturing packages are
available, significantly reducing the cost and time
required to produce new Ethernet products.
CIRRUS LOGIC PRODUCT DATA SHEET
10
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
20 MHz
4.7 kΩ
97
98
77
XTAL1 XTAL2 SLEEP
EEPROM
93C46
CS
DO
DI
CLK
ISA
BUS
LA[20:23]
5V
1
3
4
6
3
5
2
4
7
BALE
RXD-
EECS
EEDATAIN
1
92
10 BASE T
Isolation
Transformer
100 Ω, 1%
3
RXD+
24.3 Ω, 1%
6
TXD- 88
68 pF
EESK
1: 2
8
87
20
CHIPSEL
MEMW
29
MEMR
62
IOW
61
49
IOR
REFRESH
36
SBHE
63
AEN
75
RESET
34
MEMCS16
33
IOCS16
64
IOCHRDY
16
SD[0:15]
IRQ10
32
INTRQ0
IRQ11
31
INTRQ1
IRQ12
30
INTRQ2
IRQ5
35
INTRQ3
15
DRQ5
16
DACK5
13
DRQ6
14
DACK6
11
DRQ7
12
DACK7
6
14
3
11
10
2
9
24.3 Ω, 1%
SA[0:19]
28
16
CS8900A
DMARQ0
DMACK0
DMARQ1
4
5
1
12 V
13
1:1
7
8
39.2 Ω, 1%
39.2 Ω, 1%
39.2 Ω, 1%
1:1
39.2 Ω, 1%
0.1 µF
BSTATUS/HCI
.1 µF
AUI Isolation
1 Transformer 16
1:1
2
15
DO- 84
DO+ 83
CI- 82
81
CI+
80
DIDI+ 79
RJ45
1:1
91
EEDATAOUT
ELCS
SA[0:19]
SD[0:7]
93
76
TEST RES
TXD+
Address
Decoder
4
PAL
SA[0:14]
4.99 kΩ, 1%
13 15 pin D
10
3
9
12
2
10
12
9
5
4, 6
0.1 µF
78
5V
LANLED
LINKLED
100
99
680 Ω
680 Ω
17
CSOUT
Boot-PROM
27C256
CE
22
OE
20
74LS245
19
1
OE
DIR
DMACK1
DMARQ2
PD[0:7]
DMACK2
15
8
Figure 3. Typical Connection Diagram
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
11
CS8900A
Crystal LAN™ ISA Ethernet Controller
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
LANLED
LINKLED or HC0
XTAL2
XTAL1
AVSS4
AVDD3
AVSS3
RES
RXD RXD +
AVDD1
AVSS1
TXD TXD +
AVSS2
AVDD2
DODO+
CICI+
DIDI+
BSTATUS or HC1
SLEEP
TEST
2.0 PIN DESCRIPTION
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
CS8900A
100-pin
TQFP
(Q)
Top View
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
RESET
SD7
SD6
SD5
SD4
DVSS4
DVDD4
SD3
SD2
SD1
SD0
IOCHRDY
AEN
IOW
IOR
SA19
SA18
SA17
DVSS3A
DVDD3
DVSS3
SA16
SA15
SA14
SA13
SD09
SD08
MEMW
MEMR
INTRQ2
INTRQ1
INTRQ0
IOCS16
MEMCS16
INTRQ3
SBHE
SA0
SA1
SA2
SA3
SA4
SA5
SA6
SA7
SA8
SA9
SA10
SA11
REFRESH
SA12
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
AVSS0
ELCS
EECS
EESK
EEDataOut
EEDataIn
CHIPSEL
DVSS1
DVDD1
DVSS1A
DMARQ2
DMACK2
DMARQ1
DMACK1
DMARQ0
DMACK0
CSOUT
SD15
SD14
SD13
SD12
DVDD2
DVSS2
SD11
SD10
CIRRUS LOGIC PRODUCT DATA SHEET
12
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
ISA Bus Interface
SA[0:19] - System Address Bus, Input PINS 37-48, 50-54, 58-60.
Lower 20 bits of the 24-bit System Address Bus used to decode accesses to CS8900A I/O and
Memory space, and attached Boot PROM. SA0-SA15 are used for I/O Read and Write
operations. SA0-SA19 are used in conjunction with external decode logic for Memory Read
and Write operations.
SD[0:15] - System Data Bus, Bi-Directional with 3-State Output PINS 65-68, 71-74, 27-24, 21-18.
Bi-directional 16-bit System Data Bus used to transfer data between the CS8900A and the host.
RESET - Reset, Input PIN 75.
Active-high asynchronous input used to reset the CS8900A. Must be stable for at least 400 ns
before the CS8900A recognizes the signal as a valid reset.
AEN - Address Enable, Input PIN 63.
When TEST is high, this active-high input indicates to the CS8900A that the system DMA
controller has control of the ISA bus. When AEN is high, the CS8900A will not perform slave
I/O space operations. When TEST is low, this pin becomes the shift clock input for the
Boundary Scan Test. AEN should be inactive when performing an IO or memory access and it
should be active during a DMA cycle.
MEMR - Memory Read, Input PIN 29.
Active-low input indicates that the host is executing a Memory Read operation.
MEMW - Memory Write, Input PIN 28.
Active-low input indicates that the host is executing a Memory Write operation.
MEMCS16 - Memory Chip Select 16-bit, Open Drain Output PIN 34.
Open-drain, active-low output generated by the CS8900A when it recognizes an address on the
ISA bus that corresponds to its assigned Memory space (CS8900A must be in Memory Mode
with the MemoryE bit (Register 17, BusCTL, Bit A) set for MEMCS16 to go active). 3-Stated
when not active.
REFRESH - Refresh, Input PIN 49.
Active-low input indicates to the CS8900A that a DRAM refresh cycle is in progress. When
REFRESH is low, MEMR, MEMW, IOR, IOW, DMACK0, DMACK1, and DMACK2 are
ignored.
IOR - I/O Read, Input PIN 61.
When IOR is low and a valid address is detected, the CS8900A outputs the contents of the
selected 16-bit I/O register onto the System Data Bus. IOR is ignored if REFRESH is low.
IOW - I/O Write, Input PIN 62.
When IOW is low and a valid address is detected, the CS8900A writes the data on the System
Data Bus into the selected 16-bit I/O register. IOW is ignored if REFRESH is low.
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
13
CS8900A
Crystal LAN™ ISA Ethernet Controller
IOCS16 - I/O Chip Select 16-bit, Open Drain Output PIN 33.
Open-drain, active-low output generated by the CS8900A when it recognizes an address on the
ISA bus that corresponds to its assigned I/O space. 3-Stated when not active.
IOCHRDY - I/O Channel Ready, Open Drain Output PIN 64.
When driven low, this open-drain, active-high output extends I/O Read and Memory Read
cycles to the CS8900A. This output is functional when the IOCHRDYE bit in the Bus Control
register (Register 17) is clear. This pin is always 3-Stated when the IOCHRDYE bit is set.
SBHE - System Bus High Enable, Input PIN 36.
Active-low input indicates a data transfer on the high byte of the System Data Bus (SD8SD15). After a hardware or a software reset, provide a HIGH to LOW and then LOW to HIGH
transition on SBHE signal before any IO or memory access is done to the CS8900A.
INTRQ[0:2] - Interrupt Request, 3-State PINS 30-32, 35.
Active-high output indicates the presence of an interrupt event. Interrupt Request goes low once
the Interrupt Status Queue (ISQ) is read as all 0’s. Only one Interrupt Request output is used
(one is selected during configuration). All non-selected Interrupt Request outputs are placed in
a high-impedance state. (Section 3.2 on page 18 and Section 5.1 on page 79.)
DMARQ[0:2] - DMA Request, 3-State PINS 11, 13, and 15.
Active-high, 3-Stateable output used by the CS8900A to request a DMA transfer. Only one
DMA Request output is used (one is selected during configuration). All non-selected DMA
Request outputs are placed in a high-impedance state.
DMACK[0:2] - DMA Acknowledge, Input PINS 12, 14, and 16.
Active-low input indicates acknowledgment by the host of the corresponding DMA Request
output.
CHIPSEL - Chip Select, Input PIN 7.
Active-low input generated by external Latchable Address bus decode logic when a valid
memory address is present on the ISA bus. If Memory Mode operation is not needed,
CHIPSEL should be tied low. The CHIPSEL is ignored for IO and DMA mode of the
CS8900A.
EEPROM and Boot PROM Interface
EESK - EEPROM Serial Clock, PIN 4.
Serial clock used to clock data into or out of the EEPROM.
EECS - EEPROM Chip Select, PIN 3.
Active-high output used to select the EEPROM.
CIRRUS LOGIC PRODUCT DATA SHEET
14
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
EEDataIn - EEPROM Data In, Input Internal Weak Pullup PIN 6.
Serial input used to receive data from the EEPROM. Connects to the DO pin on the EEPROM.
EEDataIn is also used to sense the presence of the EEPROM.
ELCS - External Logic Chip Select, Internal Weak Pullup PIN 2.
Bi-directional signal used to configure external Latchable Address (LA) decode logic. If
external LA decode logic is not needed, ELCS should be tied low.
EEDataOut - EEPROM Data Out,PIN 5.
Serial output used to send data to the EEPROM. Connects to the DI pin on the EEPROM.
When TEST is low, this pin becomes the output for the Boundary Scan Test.
CSOUT - Chip Select for External Boot PROM, PIN 17.
Active-low output used to select an external Boot PROM when the CS8900A decodes a valid
Boot PROM memory address.
10BASE-T Interface
TXD+/TXD- - 10BASE-T Transmit, Differential Output Pair PINS 87 and 88.
Differential output pair drives 10 Mb/s Manchester-encoded data to the 10BASE-T transmit
pair.
RXD+/RXD- - 10BASE-T Receive, Differential Input Pair PINS 91 and 92.
Differential input pair receives 10 Mb/s Manchester-encoded data from the 10BASE-T receive
pair.
Attachment Unit Interface (AUI)
DO+/DO- - AUI Data Out, Differential Output Pair PINS 83 and 84.
Differential output pair drives 10 Mb/s Manchester-encoded data to the AUI transmit pair.
DI+/DI- - AUI Data In, Differential Input Pair PINS 79 and 80.
Differential input pair receives 10 Mb/s Manchester-encoded data from the AUI receive pair.
CI+/CI- - AUI Collision In, Differential Input Pair PINS 81 and 82.
Differential input pair connects to the AUI collision pair. A collision is indicated by the
presence of a 10 MHz ± 15% signal with duty cycle no worse than 60/40.
General Pins
XTAL[1:2] - Crystal, Input/Output PINS 97 and 98.
A 20 MHz crystal should be connected across these pins. If a crystal is not used, a 20 MHz
signal should be connected to XTAL1 and XTAL2 should be left open. (See Section 7.3 on
page 111 and Section 7.7 on page 121.)
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
15
CS8900A
Crystal LAN™ ISA Ethernet Controller
SLEEP - Hardware Sleep, Input Internal Weak Pullup PIN 77.
Active-low input used to enable the two hardware sleep modes: Hardware Suspend and
Hardware Standby. (See Section 3.7 on page 26.)
LINKLED or HC0 - Link Good LED or Host Controlled Output 0, Open Drain Output PIN 99.
When the HCE0 bit of the Self Control register (Register 15) is clear, this active-low output is
low when the CS8900A detects the presence of valid link pulses. When the HC0E bit is set, the
host may drive this pin low by setting the HCBO in the Self Control register.
BSTATUS or HC1 - Bus Status or Host Controlled Output 1, Open Drain Output PIN 78.
When the HC1E bit of the Self Control register (Register 15) is clear, this active-low output is
low when receive activity causes an ISA bus access. When the HC1E bit is set, the host may
drive this pin low by setting the HCB1 in the Self Control register.
LANLED - LAN Activity LED, Open Drain Output PIN 100.
During normal operation, this active-low output goes low for 6 ms whenever there is a receive
packet, a transmit packet, or a collision. During Hardware Standby mode, this output is driven
low when the receiver detects network activity.
TEST - Test Enable, Input Internal Weak Pullup PIN 76.
Active-low input used to put the CS8900A in Boundary Scan Test mode. For normal operation,
this pin should be high.
RES - Reference Resistor, Input PIN 93.
This input should be connected to a 4.99KΩ ± 1% resistor needed for biasing of internal analog
circuits.
DVDD[1:4] - Digital Power, Power PINS 9, 22, 56, and 69.
Provides 5 V ± 5% power to the digital circuits of the CS8900A.
DVSS[1:4} and DVSS1A, DVSS3A - Digital Ground, Ground PINS 8, 10, 23, 55, 57, and 70.
Provides ground reference (0 V) to the digital circuits of the CS8900A.
AVDD[1:3] - Analog Power, Power PINS 90, 85, and 95.
Provides 5 V ± 5% power to the analog circuits of the CS8900A.
AVSS[0:4] - Analog Ground, Ground PINS 1, 89, 86, 94, 96.
Provide ground reference (0 V) to the analog circuits of the CS8900A.
CIRRUS LOGIC PRODUCT DATA SHEET
16
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
3.0 FUNCTIONAL DESCRIPTION
3.1 Overview
During normal operation, the CS8900A performs
two basic functions: Ethernet packet transmission
and reception. Before transmission or reception is
possible, the CS8900A must be configured.
3.1.1 Configuration
The CS8900A must be configured for packet transmission and reception at power-up or reset. Various
parameters must be written into its internal Configuration and Control registers such as Memory Base
Address; Ethernet Physical Address; what frame
types to receive; and which media interface to use.
Configuration data can either be written to the
CS8900A by the host (across the ISA bus), or loaded automatically from an external EEPROM. Operation can begin after configuration is complete.
Section 3.3 on page 19 and Section 3.4 on page 21
describe the configuration process in detail.
Section 4.4 on page 47 provides a detailed description of the bits in the Configuration and Control
Registers.
3.1.2 Packet Transmission
Packet transmission occurs in two phases. In the
first phase, the host moves the Ethernet frame into
the CS8900A’s buffer memory. The first phase begins with the host issuing a Transmit Command.
This informs the CS8900A that a frame is to be
transmitted and tells the chip when to start transmission (i.e. after 5, 381, 1021 or all bytes have
been transferred) and how the frame should be sent
(i.e. with or without CRC, with or without pad bits,
etc.). The Host follows the Transmit Command
with the Transmit Length, indicating how much
buffer space is required. When buffer space is
available, the host writes the Ethernet frame into
the CS8900A’s internal memory, either as a Memory or I/O space operation.
In the second phase of transmission, the CS8900A
converts the frame into an Ethernet packet then
transmits it onto the network. The second phase begins with the CS8900A transmitting the preamble
and Start-of-Frame delimiter as soon as the proper
number of bytes has been transferred into its transmit buffer (5, 381, 1021 bytes or full frame, depending on configuration). The preamble and Startof-Frame delimiter are followed by the Destination
Address, Source Address, Length field and LLC
data (all supplied by the host). If the frame is less
than 64 bytes, including CRC, the CS8900A adds
pad bits if configured to do so. Finally, the
CS8900A appends the proper 32-bit CRC value.
The Section 5.7 on page 99 provides a detailed description of packet transmission.
3.1.3 Packet Reception
Like packet transmission, packet reception occurs
in two phases. In the first phase, the CS8900A receives an Ethernet packet and stores it in on-chip
memory. The first phase of packet reception begins
with the receive frame passing through the analog
front end and Manchester decoder where Manchester data is converted to NRZ data. Next, the preamble and Start-of-Frame delimiter are stripped off
and the receive frame is sent through the address
filter. If the frame’s Destination Address matches
the criteria programmed into the address filter, the
packet is stored in the CS8900A’s internal memory. The CS8900A then checks the CRC, and depending on the configuration, informs the
processor that a frame has been received.
In the second phase, the host transfers the receive
frame across the ISA bus and into host memory.
Receive frames can be transferred as Memory
space operations, I/O space operations, or as DMA
operations using host DMA. Also, the CS8900A
provides the capability to switch between Memory
or I/O operation and DMA operation by using
Auto-Switch DMA and StreamTransfer.
The Section 5.2 on page 79 through Section 5.6 on
page 96 provide a detailed description of packet reception.
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
17
CS8900A
Crystal LAN™ ISA Ethernet Controller
3.2 ISA Bus Interface
The CS8900A provides a direct interface to ISA
buses running at clock rates from 8 to 11 MHz. Its
on-chip bus drivers are capable of delivering
24 mA of drive current, allowing the CS8900A to
drive the ISA bus directly, without added external
"glue logic".
The CS8900A is optimized for 16-bit data transfers, operating in either Memory space, I/O space,
or as a DMA slave.
Note that ISA-bus operation below 8 MHz should
use the CS8900A’s Receive DMA mode to minimize missed frames. See Section 5.4 on page 90 for
a description of Receive DMA operation.
3.2.1 Memory Mode Operation
When configured for Memory Mode operation, the
CS8900A’s internal registers and frame buffers are
mapped into a contiguous 4-Kbyte block of host
memory, providing the host with direct access to
the CS8900A’s internal registers and frame buffers. The host initiates Read operations by driving
the MEMR pin low and Write operations by driving the MEMW pin low.
For additional information about Memory Mode,
see Section 4.9 on page 74.
3.2.2 I/O Mode Operation
When configured for I/O Mode operation, the
CS8900A is accessed through eight, 16-bit I/O
ports that are mapped into sixteen contiguous I/O
locations in the host system’s I/O space. I/O Mode
is the default configuration for the CS8900A and is
always enabled.
For an I/O Read or Write operation, the AEN pin
must be low, and the 16-bit I/O address on the ISA
System Address bus (SA0 - SA15) must match the
address space of the CS8900A. For a Read, IOR
must be low, and for a Write, IOW must be low.
For additional information about I/O Mode, see
Section 4.10 on page 76.
3.2.3 Interrupt Request Signals
The CS8900A has four interrupt request output
pins that can be connected directly to any four of
the ISA bus Interrupt Request signals. Only one interrupt output is used at a time. It is selected during
initialization by writing the interrupt number (0 to
3) into PacketPage Memory base + 0022h. Unused
interrupt request pins are placed in a high-impedance state. The selected interrupt request pin goes
high when an enabled interrupt is triggered. The
pin goes low after the Interrupt Status Queue (ISQ)
is read as all 0’s (see Section 5.1 on page 79 for a
description of the ISQ).
Table 1 presents one possible way of connecting
the interrupt request pins to the ISA bus that utilizes commonly available interrupts and facilitates
board layout.
CS8900A Interrupt
Request Pin
ISA Bus
Interrupt
PacketPage
base + 0022h
INTRQ3 (Pin 35)
IRQ5
0003h
INTRQ0 (Pin 32)
IRQ10
0000h
INTRQ1 (Pin 31)
IRQ11
0001h
INTRQ2 (Pin 30)
IRQ12
0002h
Table 1. Interrupt Assignments
3.2.4 DMA Signals
The CS8900A interfaces directly to the host DMA
controller to provide DMA transfers of receive
frames from CS8900A memory to host memory.
The CS8900A has three pairs of DMA pins that can
be connected directly to the three 16-bit DMA
channels of the ISA bus. Only one DMA channel is
used at a time. It is selected during initialization by
writing the number of the desired channel (0, 1 or
2) into PacketPage Memory base + 0024h. Unused
DMA pins are placed in a high-impedance state.
The selected DMA request pin goes high when the
CS8900A has received frames to transfer to the
host memory via DMA. If the DMABurst bit (register 17, BusCTL, Bit B) is clear, the pin goes low
after the DMA operation is complete. If the
CIRRUS LOGIC PRODUCT DATA SHEET
18
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
DMABurst bit is set, the pin goes low 32 µs after
the start of a DMA transfer.
The DMA pin pairs are arranged on the CS8900A
to facilitate board layout. Crystal recommends the
configuration in Table 2 when connecting these
pins to the ISA bus.
CS8900A DMA
Signal (Pin #)
ISA DMA
Signal
PacketPage
base + 0024h
DMARQ0 (Pin 15)
DRQ5
0000h
DMACK0 (Pin 16)
DACK5
DMARQ1 (Pin 13)
DRQ6
DMACK1 (Pin 14)
DACK6
DMARQ2 (Pin 11)
DRQ7
DMACK2 (Pin 12)
DACK7
0001h
0002h
Table 2. DMA Assignments
For a description of DMA mode, see Section 5.4 on
page 90.
3.3 Reset and Initialization
3.3.1 Reset
Seven different conditions cause the CS8900A to
reset its internal registers and circuits.
3.3.1.1 External Reset, or ISA Reset
There is a chip-wide reset whenever the RESET pin
is high for at least 400 ns. During a chip-wide reset,
all circuitry and registers in the CS8900A are reset.
3.3.1.2 Power-Up Reset
When power is applied, the CS8900A maintains reset until the voltage at the supply pins reaches approximately 2.5 V. The CS8900A comes out of
reset once Vcc is greater than approximately 2.5 V
and the crystal oscillator has stabilized.
3.3.1.3 Power-Down Reset
If the supply voltage drops below approximately
2.5 V, there is a chip-wide reset. The CS8900A
comes out of reset once the power supply returns to
a level greater than approximately 2.5 V and the
crystal oscillator has stabilized.
3.3.1.4 EEPROM Reset
There is a chip-wide reset if an EEPROM checksum error is detected (see Section 3.4 on page 21).
3.3.1.5 Software Initiated Reset
There is a chip-wide reset whenever the RESET bit
(Register 15, SelfCTL, Bit 6) is set.
3.3.1.6 Hardware (HW) Standby or Suspend
The CS8900A goes though a chip-wide reset whenever it enters or exits either HW Standby mode or
HW Suspend mode (see Section 3.7 on page 26 for
more information about HW Standby and Suspend).
3.3.1.7 Sof tware (SW) Suspend
Whenever the CS8900A enters SW Suspend mode,
all registers and circuits are reset except for the ISA
I/O Base Address register (located at PacketPage
base + 0020h) and the SelfCTL register (Register
15). Upon exit, there is a chip-wide reset (see
Section 3.7 on page 26 for more information about
SW Suspend).
3.3.2 Allowing Time for Reset Operation
After a reset, the CS8900A goes through a self configuration. This includes calibrating on-chip analog
circuitry, and reading EEPROM for validity and
configuration. Time required for the reset calibration is typically 10 ms. Software drivers should not
access registers internal to the CS8900A during
this time. When calibration is done, bit INITD in
the Self Status Register (register 16) is set indicating that initialization is complete, and the SIBUSY
bit in the same register is cleared indicating the EEPROM is no longer being read or programmed.
3.3.3 Bus Reset Considerations
The CS8900A reads 3000h from IObase+0Ah after
the reset, until the software writes a non-zero value
at IObase+0Ah. The 3000h value can be used as
part of the CS8900A signature when the system
scans for the CS8900A. See Section 4.10 on
page 76.
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
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CS8900A
Crystal LAN™ ISA Ethernet Controller
After a reset, the ISA bus outputs INTRx and
DMARQx are 3-Stated, thus avoiding any interrupt
or DMA channel conflicts on the ISA bus at powerup time.
PacketPage
Address
Register
Contents
Register Descriptions
0020h
0300h
0022h
XXXX XXXX Interrupt Number
XXXX X100
0024h
XXXX XXXX DMA Channel
XXXX XX11
0026h
0000h
DMA Start of Frame
Offset
0028h
X000h
DMA Frame Count
002Ah
0000h
DMA Byte Count
002Ch
XXX0 0000h Memory Base Address
0030h
XXX0 0000h Boot PROM Base
Address
A low-cost serial EEPROM can be used to store
configuration information that is automatically
loaded into the CS8900A after each reset (except
EEPROM reset). The use of an EEPROM is optional.
0034h
XXX0 0000h Boot PROM Address
Mask
0102h
0003h
Register 3 - RxCFG
0104h
0005h
Register 5 - RxCTL
0106h
0007h
Register 7 - TxCFG
The CS8900A operates with any of six standard
EEPROM’s shown in Table 4.
0108h
0009h
Register 9 - TxCMD
010Ah
000Bh
Register B - BufCFG
010Ch
Undefined
Reserved
010Eh
Undefined
Reserved
0110h
Undefined
Reserved
0112h
00013h
Register 13 - LineCTL
0114h
0015h
Register 15 - SelfCTL
0116h
0017h
Register 17 - BusCTL
3.3.4 Initialization
After each reset (except EEPROM Reset), the
CS8900A checks the sense of the EEDataIn pin to
see if an external EEPROM is present. If EEDI is
high, an EEPROM is present and the CS8900A automatically loads the configuration data stored in
the EEPROM into its internal registers (see next
section). If EEDI is low, an EEPROM is not
present and the CS8900A comes out of reset with
the default configuration shown in Table 3.
0118h
0019h
I/O Base Address*
Register 19 - TestCTL
* I/O base address is unaffected by Software Suspend mode.
Table 3. Default Configuration
EEPROM Type
Size (16-bit words)
‘C46 (non-sequential)
64
‘CS46 (sequential)
64
‘C56 (non-sequential)
128
‘CS56 (sequential)
128
‘C66 (non-sequential)
256
‘CS66 (sequential)
256
Table 4. Supported EEPROM Types
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Crystal LAN™ ISA Ethernet Controller
3.4 Configurations with EEPROM
3.4.1 EEPROM Interface
The interface to the EEPROM consists of the four
signals shown in Table 5.
CS8900A Pin
(Pin #)
CS8900A Function
EEPROM
Pin
EECS (Pin 3)
EEPROM Chip Select
Chip Select
EESK (PIN 4)
1 MHz EEPROM
Serial Clock output
Clock
EEDO (Pin 5)
EEPROM Data Out
(data to EEPROM)
Data In
EEDI (Pin 6)
EEPROM Data in
(data from EEPROM)
Data Out
Table 5. EEPROM Interface
3.4.2 EEPROM Memory Organization
If an EEPROM is used to store initial configuration
information for the CS8900A, the EEPROM is organized in one or more blocks of 16-bit words. The
first block in EEPROM, referred to as the Configuration Block, is used to configure the CS8900A after reset. An example of a typical Configuration
Block is shown in Table 6. Additional blocks containing user data may be stored in the EEPROM.
However, the Configuration Block must always
start at address 00h and be stored in contiguous
memory locations.
3.4.3 Reset Configuration Block
The first block in EEPROM, referred to as the Reset Configuration Block, is used to automatically
program the CS8900A with an initial configuration
after a reset. Additional user data may also be
stored in the EEPROM if space is available. The
additional data are stored as 16-bit words and can
occupy any EEPROM address space beginning immediately after the end of the Reset Configuration
Block up to address 7Fh, depending on EEPROM
size. This additional data can only be accessed
through software control (refer to Section 3.5 on
page 24 for more information on accessing the EEPROM). Address space 80h to AFh is reserved.
3.4.3.1 Reset Configuration Block Structure
The Reset Configuration Block is a block of contiguous 16-bit words starting at EEPROM address
00h. It can be divided into three logical sections: a
header, one or more groups of configuration data
words, and a checksum value. All of the words in
the Reset Configuration Block are read sequentially by the CS8900A after each reset, starting with
the header and ending with the checksum. Each
group of configuration data is used to program a
PacketPage register (or set of PacketPage registers
in some cases) with an initial non-default value.
3.4.3.2 Reset Configuration Block Header
The header (first word of the block located at EEPROM address 00h) specifies the type of EEPROM used, whether or not a Reset Configuration
block is present, and if so, how many bytes of configuration data are stored in the Reset Configuration Block.
3.4.3.3 Determining the EEPROM Type
The LSB of the high byte of the header indicates
the type of EEPROM attached: sequential or nonsequential. An LSB of 0 (XXXX-XXX0) indicates
a sequential EEPROM. An LSB of 1 (XXXXXXX1) indicates a non-sequential EEPROM. The
CS8900A works equally well with either type of
EEPROM. The CS8900A will automatically generate sequential addresses while reading the Reset
Configuration Block if a non-sequential EEPROM
is used.
3.4.3.4 Checking EEPROM for presence of Reset
Configuration Block
The read-out of either a binary 101X-XXX0 or
101X-XXX1 (X = do not care) from the high byte
of the header indicates the presence of configuration data. Any other readout value terminates initialization from the EEPROM. If an EEPROM is
attached but not used for configuration, Crystal recommends that the high byte of the first word be
programmed with 00h in order to ensure that the
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CS8900A
Crystal LAN™ ISA Ethernet Controller
Word Address
Value
FIRST WORD in DATA BLOCK
00h
A120h
FIRST GROUP of WORDS
01h
2020h
02h
0300h
03h
0003h
04h
0001h
SECOND GROUP of WORDS
05h
502Ch
06h
E000h
07
000Fh
08h
0000h
09h
000Dh
0Ah
C000h
0Bh
000Fh
THIRD GROUP of WORDS
0Ch
2158h
0Dh
0Eh
0Fh
CHECKSUM Value
10h
0010h
0000h
0000h
2800h
Description
Configuration Block Header.
The high byte, A1h, indicates a ‘C46 EEPROM is attached. The Link Byte,
20h, indicates the number of bytes to be used in this block of configuration
data.
Group Header for first group of words.
Three words to be loaded, beginning at 0020h in PacketPage memory.
I/O Base Address
Interrupt Number
DMA Channel Number
Group Header for second group of words.
Six words to be loaded, beginning at 002Ch in PacketPage memory.
Memory Base Address - low word
Memory Base Address - high word
Boot PROM Base Address - low word
Boot PROM Base Address - high word
Boot PROM Address Mask - low word
Boot PROM Address Mask - high word
Group Header for third group of words.
Three words to be loaded, beginning at 0158 in PacketPage memory.
Individual Address - Octet 0 and 1
Individual Address - Octet 2 and 3
Individual Address - Octet 4 and 5
The high byte, 28h, is the Checksum Value. In this example, the checksum includes word addresses 00h through 0Fh. The hexadecimal sum of
the bytes is D8h, resulting in a 2’s complement of 28h. The low byte, 00h,
provides a pad to the word boundary.
* FFFFh is a special code indicating that there are no more words in the EEPROM.
Table 6. EEPROM Configuration Block Example
CS8900A will not attempt to read configuration
data from the EEPROM.
3.4.3.5 Determining Number of Bytes in the Reset
Configuration Block
The low byte of the Reset Configuration Block
header is known as the link byte. The value of the
Link Byte represents the number of bytes of configuration data in the Reset Configuration Block. The
two bytes used for the header are excluded when
calculating the Link Byte value.
For example, a Reset Configuration Block header
of A104h indicates a non-sequential EEPROM programmed with a Reset Configuration Block containing 4 bytes of configuration data. This Reset
Configuration Block occupies 6 bytes (3 words) of
EEPROM space (2 bytes for the header and 4 bytes
of configuration data).
3.4.4 Groups of Configuration Data
Configuration data are arranged as groups of
words. Each group contains one or more words of
data that are to be loaded into PacketPage registers.
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Crystal LAN™ ISA Ethernet Controller
The first word of each group is referred to as the
Group Header. The Group Header indicates the
number of words in the group and the address of the
PacketPage register into which the first data word
in the group is to be loaded. Any remaining words
in the group are stored in successive PacketPage
registers.
3.4.4.1 Group Header
Bits F through C of the Group Header specify the
number of words in each group that are to be transferred to PacketPage registers (see Figure 4). This
value is two less than the total number of words in
the group, including the Group Header. For example, if bits F through C contain 0001, there are three
words in the group (a Group Header and two words
of configuration data).
First Word of a Group of Words
F E D C B A 9 8 7 6 5 4 3 2 1 0
0
Number of Words
in Group
0
3.4.5 Reset Configuration Block Checksum
A checksum is stored in the high byte position of
the word immediately following the last group of
data in the Reset Configuration Block. (The EEPROM address of the checksum value can be determined by dividing the value stored in the Link Byte
by two). The checksum value is the 2’s complement of the 8-bit sum (any carry out of eighth bit is
ignored) of all the bytes in the Reset Configuration
Block, excluding the checksum byte. This sum includes the Reset Configuration Block header at address 00h. Since the checksum is calculated as the
2’s complement of the sum of all preceding bytes in
the Reset Configuration Block, a total of 0 should
result when the checksum value is added to the sum
of the previous bytes.
3.4.6 EEPROM Example
Table 6 shows an example of a Reset Configuration
Block stored in a C46 EEPROM. Note that littleendian word ordering is used, i.e., the least significant word of a multiword datum is located at the
lowest address.
3.4.7 EEPROM Read-out
If the EEDI pin is asserted high at the end of reset,
the CS8900A reads the first word of EEPROM data
by:
0
9-bit PacketPage Address
Figure 4. Group Header
Bits 8 through 0 of the Group Header specify a 9bit PacketPage Address. This address defines the
PacketPage register that will be loaded with the
first word of configuration data from the group.
Bits B though 9 of the Group Header are forced to
0, restricting the destination address range to the
first 512 bytes of PacketPage memory. Figure 4
shows the format of the Group header.
1) Asserting EECS
2) Clocking out a Read-Register-00h command
on EEDO (EESK provides a 1MHz serial clock
signal)
3) Clocking the data in on EEDI.
If the EEDI pin is low at the end of the reset signal,
the CS8900A does not perform an EEPROM readout (uses its default configuration).
3.4.7.1 Determining EEPROM Size
The CS8900A determines the size of the EEPROM
by checking the sense of EEDI on the tenth rising
edge of EESK. If EEDI is low, the EEPROM is a
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’C46 or ’CS46. If EEDI is high, the EEPROM is a
’C56, ’CS56, ’C66, or ’CS66.
3.4.7.2 Loading Configuration Data
The CS8900A reads in the first word from the EEPROM to determine if configuration data is contained in the EEPROM. If configuration data is not
stored in the EEPROM, the CS8900A terminates
initialization from EEPROM and operates using its
default configuration (See Table 3). If configuration data is stored in EEPROM, the CS8900A automatically loads all configuration data stored in the
Reset Configuration Block into its internal PacketPage registers.
3.4.8 EEPROM Read-out Completion
Once all the configuration data are transferred to
the appropriate PacketPage registers, the CS8900A
performs a checksum calculation to verify the Reset Configuration Blocks data are valid. If the resulting total is 0, the read-out is considered valid.
Otherwise, the CS8900A initiates a partial reset to
restore the default configuration.
If the read-out is valid, the EEPROMOK bit (Register 16, SelfST, bit A) is set. EEPROMOK is
cleared if a checksum error is detected. In this case,
the CS8900A performs a partial reset and is re-
stored to its default. Once initialization is complete
(configuration loaded from EEPROM or reset to
default configuration) the INITD bit is set (Register
16, SelfST, bit 7).
3.5 Programming the EEPROM
After initialization, the host can access the EEPROM through the CS8900A by writing one of
seven commands to the EEPROM Command register (PacketPage base + 0040h). Figure 5 shows the
format of the EEPROM Command register.
3.5.1 EEPROM Commands
The seven commands used to access the EEPROM
are: Read, Write, Erase, Erase/Write Enable,
Erase/Write Disable, Erase-All, and Write-All.
They are described in Table 7.
3.5.2 EEPROM Command Execution
During the execution of a command, the two Opcode bits, followed by the six bits of address (for a
’C46 or ’CS46) or eight bits of address (for a ’C56,
’CS56, ’C66 or ’CS66), are shifted out of the
CS8900A, into the EEPROM. If the command is a
Write, the data in the EEPROM Data register
(PacketPage base + 0042h) follows. If the command is a Read, the data in the specified EEPROM
AD7 - AD0 used with ’C56,
’CS56, ’C66 and ’CS66
F
E
D
C
B
X
X
X
X
X
A
9
8
7
6
5
4
3
2
1
0
ELSEL OP1 OP0 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0
AD5 - AD0 used with
’C46 and ’CS46
Bit
[F:B]
[A]
Name
ELSEL
[9:8]
[7:0]
OP1, OP0
AD7 to AD0
Description
Reserved
External Logic Select: When clear, the EECS pin is used to select the EEPROM.
When set, the ELCS pin is used to select the external LA decode circuit.
Opcode: Indicates what command is being executed (see next section).
EEPROM Address: Address of EEPROM word being accessed.
Figure 5. EEPROM Command Register Format
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DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
Command
Opcode
(bits 9,8)
EEPROM Address
(bits 7 to 0)
Data
EEPROM Type
Execution
Time
Read Register
1,0
word address
yes
all
25 µs
Write Register
0,1
word address
yes
all
10 ms
Erase Register
1.1
word address
no
all
10 ms
Erase/Write Enable
0,0
XX11-XXXX
no
‘CS46, ‘C46
9 µs
11XX-XXXX
no
‘CS56, ‘C56, ‘CS66, ‘C66
9 µs
no
‘CS46, ‘C46
9 µs
Erase/Write Disable
0,0
0,0
XX00-XXXX
00XX-XXXX
no
‘CS56, ‘C56, ‘CS66, ‘C66
9 µs
Erase-All Registers
0,0
0,0
XX10-XXXX
no
‘CS46, ‘C46
10 ms
10XX-XXXX
no
‘CS56, ‘C56, ‘CS66, ‘C66
9 µs
0,0
0,0
XX01-XXXX
yes
‘CS46, ‘C46
10 ms
01XX-XXXX
yes
‘CS56, ‘C56, ‘CS66, ‘C66
10 ms
Write-All Register
Table 7. EEPROM Commands
location is written into the EEPROM Data register.
If the command is an Erase or Erase-All, no data is
transferred to or from the EEPROM Data register.
Before issuing any command, the host must wait
for the SIBUSY bit (Register 16, SelfST, bit 8) to
clear. After each command has been issued, the
host must wait again for SIBUSY to clear.
3.5.3 Enabling Access to the EEPROM
The Erase/Write Enable command provides protection from accidental writes to the EEPROM. The
host must write an Erase/Write Enable command
before it attempts to write to or erase any EEPROM
memory location. Once the host has finished altering the contents of the EEPROM, it must write an
Erase/Write Disable command to prevent unwanted modification of the EEPROM.
3.5.4 Writing and Erasing the EEPROM
To write data to the EEPROM, the host must execute the following series of commands:
1) Issue an Erase/Write Enable command.
2) Load the data into the EEPROM Data register.
3) Issue a Write command.
4) Issue an Erase/Write Disable command.
During the Erase command, the CS8900A writes
FFh to the specified EEPROM location. During the
Erase-All command, the CS8900A writes FFh to
all locations.
3.6 Boot PROM Operation
The CS8900A supports an optional Boot PROM
used to store code for remote booting from a network server.
3.6.1 Accessing the Boot PROM
To retrieve the data stored in the Boot PROM, the
host issues a Read command to the Boot PROM as
a Memory space access. The CS8900A decodes the
command and drives the CSOUT pin low, causing
the data stored in the Boot PROM to be shifted into
the bus transceiver. The bus transceiver then drives
the data out onto the ISA bus.
3.6.2 Configuring the CS8900A for Boot PROM
Operation
Figure 6 shows how the CS8900A should be connected to the Boot PROM and ’245 driver. To configure the CS8900A’s internal registers for Boot
PROM operation, the Boot PROM Base Address
must be loaded into the Boot PROM Base Address
register (PacketPage base + 0030h) and the Boot
PROM Address Mask must be loaded into the
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Crystal LAN™ ISA Ethernet Controller
BootPROM Address Mask register (PacketPage
base + 0034h). The Boot PROM Base Address provides the starting location in host memory where
the Boot PROM is mapped. The Boot PROM Address Mask indicates the size of the attached Boot
PROM and is limited to 4-Kbyte increments. The
lower 12 bits of the Address Mask are ignored and
should be 000h.
CS8900A
CSOUT
(Pin 17)
27C256
20
22
SA(0:14)
CE
OE
19
74LS245
OE
DIR
B1
.
.
.
B8
A1
.
. SD(0:7)
.
A8
ISA
BUS
Figure 6. Boot PROM Connection Diagram
In the EEPROM example shown in Table 6, the
Boot PROM starting address is D0000h and the
Address Mask is FC000h. This configuration describes a 16-Kbyte (128 Kbit) PROM mapped into
host memory from D0000h to D3FFFh.
3.7 Low-Power Modes
For power-sensitive applications, the CS8900A
supports three low-power modes: Hardware Standby, Hardware Suspend, and Software Suspend. All
three low-power modes are controlled through the
SelfCTL register (Register 15). See also
Section 4.4.4 on page 49.
An internal reset occurs when the CS8900A comes
out of any suspend or standby mode. After a reset
(internal or external), the CS8900A goes through a
self configuration. This includes calibrating onchip analog circuitry, and reading EEPROM for validity and configuration. When the calibration is
done, bit InitD in Register 16 (Self Status register)
is set indicating that initialization is complete, and
the SIBUSY bit in the same register is cleared (in-
dicating that the EEPROM is no longer being read
or programmed. Time required for the reset calibration is typically 10 ms. Software drivers should not
access registers internal to CS8900A during this
time.
3.7.1 Hardware Standby
Hardware (HW) Standby is designed for use in systems, such as portable PC’s, that may be temporarily disconnected from the 10BASE-T cable. It
allows the system to conserve power while the
LAN is not in use, and then automatically restore
Ethernet operation once the cable is reconnected.
In HW Standby mode, all analog and digital circuitry in the CS8900A is turned off, except for the
10BASE-T receiver which remains active to listen
for link activity. If link activity is detected, the
LANLED pin is driven low, providing an indication to the host that the network connection is active. The host can then activate the CS8900A by
deasserting the SLEEP pin. During this mode, all
ISA bus accesses are ignored.
To enter HW Standby mode, the SLEEP pin must
be low and the HWSleepE bit (Register 15, SelfCTL, Bit 9) and the HWStandbyE bit (Register 15,
SelfCTL, Bit A) must be set. When the CS8900A
enters HW Standby, all registers and circuits are reset except for the SelfCTL register. Upon exit from
HW Standby, the CS8900A performs a complete
reset, and then goes through normal initialization.
3.7.2 Hardware Suspend
During Hardware Suspend mode, the CS8900A
uses the least amount of current of the three lowpower modes. All internal circuits are turned off
and the CS8900A’s core is electronically isolated
from the rest of the system. Accesses from the ISA
bus and Ethernet activity are both ignored.
HW Suspend mode is entered by driving the
SLEEP pin low and setting the HWSleepE bit
(Register 15, SelfCTL, bit 9) while the HWStandbyE bit (Register 15, SelfCTL, bit A) is clear. To
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Crystal LAN™ ISA Ethernet Controller
exit from this mode, the SLEEP pin must be driven
high. Upon exit, the CS8900A performs a complete
reset, and then goes through a normal initialization
procedure.
3.7.3 Software Suspend
Software (SW) Suspend mode can be used to conserve power in applications, like adapter cards, that
do not have power management circuitry available.
During this mode, all internal circuits are shut off
except the I/O Base Address register (PacketPage
base + 0020h) and the SelfCTL register (Register
15).
To enter SW Suspend mode, the host must set the
SWSuspend bit (Register 15, SelfCTL, bit 8). To
exit SW Suspend, the host must write to the
CS8900A’s assigned I/O space (the Write is only
used to wake the CS8900A, the Write itself is ignored). Upon exit, the CS8900A performs a complete reset, and then goes through a normal
initialization procedure.
Any hardware reset takes the chip out of any sleep
mode.
Table 8 summarizes the operation of the three lowpower modes.
CS8900A Configuration
CS8900A Operation
SLEEP
HWStandbyE
HWSleepE
SWSuspend
(Pin 77) (SelfCTL, Bit A) (SelfCTL, Bit 9) (SelfCTL, Bit 8) Link Activity
Low
1
1
N/A
Not Present HW Standby mode: 10BASE-T
receiver listens for link activity
Low
1
1
N/A
Present
HW Standby mode: LANLED low
Low
0
1
N/A
N/A
HW Suspend mode
Low to
N/A
1
0
N/A
CS8900A resets and goes through
High
initialization
High
N/A
N/A
0
N/A
Not in low-power mode
High
N/A
N/A
N/A
SW Suspend mode
Low
N/A
0
1
N/A
SW Suspend mode
Low
N/A
0
0
N/A
Not in low-power mode
Notes: 1. Both HW and HW Suspend take precedence over SW Suspend.
Table 8. Low-Power Mode Operation
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CS8900A
Crystal LAN™ ISA Ethernet Controller
3.8 LED Outputs
The CS8900A provides three output pins that can
be used to control LEDs or external logic.
3.8.0.1 LANLED
LANLED goes low whenever the CS8900A transmits or receives a frame, or when it detects a collision. LANLED remains low until there has been no
activity for 6 ms (i.e. each transmission, reception,
or collision produces a pulse lasting a minimum of
6 ms).
3.8.0.2 LINKLED or HC0
LINKLED or HC0 can be controlled by either the
CS8900A or the host. When controlled by the
CS8900A, LINKLED is low whenever the
CS8900A receives valid 10BASE-T link pulses. To
configure this pin for CS8900A control, the HC0E
bit (Register 15, SelfCTL, Bit C) must be clear.
When controlled by the host, LINKLED is low
whenever the HCB0 bit (Register 15, SelfCTL, Bit
E) is set. To configure it for host control, the HC0E
bit must be set. Table 9 summarizes this operation.
HC0E HCB0
Pin Function
(Bit C) (Bit E)
0
N/A Pin configured as LINKLED: Output is
low when valid 10BASE-T link pulses
are detected. Output is high if valid link
pulses are not detected
1
0
Pin configured as HC0:
Output is high
1
1
Pin configured as HC0:
Output is low
Table 9. LINKLED/HC0 Pin Operation
3.8.0.3 BSTATUS or HC1
BSTATUS or HC1 can be controlled by either the
CS8900A or the host. When controlled by the
CS8900A, BSTATUS is low whenever the host
reads the RxEvent register (PacketPage base +
0124h), signaling the transfer of a receive frame
across the ISA bus. To configure this pin for
CS8900A control, the HC1E bit (Register 15, SelfCTL, Bit D) must be clear. When controlled by the
host, BSTATUS is low whenever the HCB1 bit
(Register 15, SelfCTL, Bit F) is set. To configure it
for host control, HC1E must be set. Table 10 summarizes this operation.
HC1E HCB1
Pin Function
(Bit D) (Bit F)
0
N/A Pin configured as BSTATUS: Output is
low when a receive frame begins transfer across the ISA bus. Output is high
otherwise
1
0
Pin configured as HC1:
Output is high
1
1
Pin configured as HC1:
Output is low
Table 10. BSTATUS/HCI Pin Operation
3.8.1 LED Connection
Each LED output is capable of sinking 10 mA to
drive an LED directly through a series resistor. The
output voltage of each pin is less than 0.4 V when
the pin is low. Figure 7 shows a typical LED circuit.
+5V
LANLED
LINKLED
Figure 7. LED Connection Diagram
3.9 Media Access Control
3.9.1 Overview
The CS8900A’s Ethernet Media Access Control
(MAC) engine is fully compliant with the IEEE
802.3 Ethernet standard (ISO/IEC 8802-3, 1993). It
handles all aspects of Ethernet frame transmission
and reception, including: collision detection, preamble generation and detection, and CRC genera-
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Crystal LAN™ ISA Ethernet Controller
tion and test. Programmable MAC features include
automatic retransmission on collision, and padding
of transmitted frames.
Figure 8 shows how the MAC engine interfaces to
other CS8900A functions. On the host side, it interfaces to the CS8900A’s internal data/address/control bus. On the network side, it interfaces to the
internal Manchester encoder/decoder (ENDEC).
The primary functions of the MAC are: frame encapsulation and decapsulation; error detection and
handling; and, media access management.
Figure 9 shows the Ethernet frame format.
LED
Logic
CS8900A
Internal Bus
1021 bytes, or full frame), and providing that access to the network is permitted, the MAC automatically transmits the 7-byte preamble (1010101b...),
followed by the Start-of-Frame Delimiter (SFD,
10101011b), and then the serialized frame data. It
then transmits the Frame Check Sequence (FCS).
The data after the SFD and before the FCS (Destination Address, Source Address, Length, and data
field) is supplied by the host. FCS generation by the
CS8900A may be disabled by setting the InhibitCRC bit (Register 9, TxCMD, bit C).
Encoder/
Decoder
&
PLL
802.3
MAC
Engine
10BASE-T
& AUI
Figure 8. MAC Interface
3.9.2 Frame Encapsulation and Decapsulation
The CS8900A’s MAC engine automatically assembles transmit packets and disassembles receive
packets. It also determines if transmit and receive
frames are of legal minimum size.
3.9.2.1 Transmission
Once the proper number of bytes have been transferred to the CS8900A’s memory (either 5, 381,
3.9.2.2 Reception
The MAC receives the incoming packet as a serial
stream of NRZ data from the Manchester encoder/decoder. It begins by checking for the SFD.
Once the SFD is detected, the MAC assumes all
subsequent bits are frame data. It reads the DA and
compares it to the criteria programmed into the address filter (see Section 5.3 on page 87 for a description of Address Filtering). If the DA passes the
address filter, the frame is loaded into the
CS8900A’s memory. If the BufferCRC bit (Register 3, RxCFG, bit B) is set, the received FCS is also
loaded into memory. Once the entire packet has
been received, the MAC validates the FCS. If an error is detected, the CRCerror bit (Register 4, RxEvent, Bit C) is set.
3.9.2.3 Enforcing Minimum Frame Size
The MAC provides minimum frame size enforce-
Packet
Frame
up to 7 bytes
alternating 1s / 0s
1 byte
SFD
6 bytes
6 bytes
DA
SA
preamble
2 bytes
Length Field
4 bytes
LLC data
Pad
FCS
frame length
min 64 bytes
max 1518 bytes
Direction of Transmission
SFD = Start of Frame Delimiter
DA = Destination Address
SA = Source Address
LLC = Logical Link Control
FCS = Frame Check Sequence (also
called Cyclic Redundancy Check, or CRC)
Figure 9. Ethernet Frame Format
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ment of both transmit and receive packets. When
the TxPadDis bit (Register 9, TxCMD, Bit D) is
clear, transmit frames will be padded with additional bits to ensure that the receiving station receives a
legal frame (64 bytes, including CRC). When TxPadDis is set, the CS8900A will not add pad bits
and will transmit frames less that 64 bytes. If a
frame is received that is less than 64 bytes (including CRC), the Runt bit (Register 4, RxEvent, Bit D)
will be set indicating the arrival of an illegal frame.
3.9.3 Transmit Error Detection and Handling
The MAC engine monitors Ethernet activity and
reports and recovers from a number of error conditions. For transmission, the MAC reports the following errors in the TxEvent register (Register 8)
and BufEvent register (Register C):
3.9.3.1 Loss of Carrier
Whenever the CS8900A is transmitting on the AUI
port, it expects to see its own transmission "looped
back" to its receiver. If it is unable to monitor its
transmission after the end of the preamble, the
MAC reports a loss-of-carrier error by setting the
Loss-of-CRS bit (Register 8, TxEvent, Bit 6). If the
Loss-of-CRSiE bit (Register 7, TxCFG, Bit 6) is
set, the host will be interrupted.
3.9.3.2 SQE Error
After the end of transmission on the AUI port, the
MAC expects to see a collision within 64 bit times.
If no collision is detected, the SQEerror bit (Register 8, TxEvent, Bit 7) is set. If the SQEerroriE bit is
set (Register 7, TxCFG, Bit 7), the host is interrupted. An SQE error may indicate a fault on the AUI
cable or a faulty transceiver (it is assumed that the
attached transceiver supports this function).
3.9.3.3 Out-of-Window (Late) Collision
If a collision is detected after the first 512 bits have
been transmitted, the MAC reports a late collision
by setting the Out-of-window bit (Register 8, TxEvent, Bit 9). The MAC then forces a bad CRC and
terminates the transmission. If the Out-of-window-
iE bit (Register 7, TxCFG, Bit 9) is set, the host is
interrupted. A late collision may indicate an illegal
network configuration.
3.9.3.4 Jabber Error
If a transmission continues longer than about
26 ms, the MAC disables the transmitter and sets
the Jabber bit (Register 8, TxEvent, Bit A). The
output of the transmitter returns to idle and remains
there until the host issues a new Transmit Command. If the JabberiE bit (Register 7, TxCFG, Bit
A) is set, the host is interrupted. A Jabber condition
indicates that there may be something wrong with
the CS8900A transmit function. To prevent possible network faults, the host should clear the transmit buffer. Possible options include:
Reset the chip with either software or hardware reset (see Section 3.3 on page 19).
Issue a Force Transmit Command by setting the
Force bit (Register 9, TxCMD, bit 8).
Issue a Transmit Command with the TxLength
field set to zero.
3.9.3.5 Transmit Collision
The MAC counts the number of times an individual
packet must be retransmitted due to network collisions. The collision count is stored in bits B
through E of the TxEvent register (Register 8). If
the packet collides 16 times, transmission of that
packet is terminated and the 16coll bit (Register 8,
TxEvent, Bit F) is set. If the 16colliE bit (Register
7, TxCFG, Bit F) is set, the host will be interrupted
on the 16th collision. A running count of transmit
collisions is recorded in the TxCOL register.
3.9.3.6 Transmit Underrun
If the CS8900A starts transmission of a packet but
runs out of data before reaching the end of frame,
the TxUnderrun bit (Register C, BufEvent, Bit 9) is
set. The MAC then forces a bad CRC and terminates the transmission. If the TxUnderruniE bit
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(Register B, BufCFG, Bit 9) is set, the host is interrupted.
3.9.4 Receive Error Detection and Handling
The following receive errors are reported in the RxEvent register (Register 4):
3.9.4.1 CRC Error
If a frame is received with a bad CRC, the CRCerror bit (Register 4, RxEvent, Bit C) is set. If the
CRCerrorA bit (Register 5, RxCTL, Bit C) is set,
the frame will be buffered by CS8900A. If the
CRCerroriE bit (Register 3, RxCFG. Bit C) is set,
the host is interrupted.
3.9.4.2 Runt Frame
If a frame is received that is shorter than 64 bytes,
the Runt bit (Register 4, RxEvent, Bit D) is set. If
the RuntA bit (Register 5, RxCTL, Bit D) is set, the
frame will still be buffered by CS8900A. If the
RuntiE bit (Register 3, RxCFG. Bit D) is set, the
host is interrupted.
3.9.4.3 Extra Data
If a frame is received that is longer than 1518 bytes,
the Extradata bit (Register 4, RxEvent, Bit E) is set.
If the ExtradataA bit (Register 5, RxCTL, Bit E) is
set, the first 1518 bytes of the frame will still be
buffered by CS8900A. If the ExtradataiE bit (Register 3, RxCFG. Bit E) is set, the host is interrupted.
3.9.4.4 Dribble Bits and Alignment Error
Under normal operating conditions, the MAC may
detect up to 7 additional bits after the last full byte
of a receive packet. These bits, known as dribble
bits, are ignored. If dribble bits are detected, the
Dribblebit bit (Register 4, RxEvent, Bit 7) is set. If
both the Dribblebits bit and CRCerror bit
(Register 4, RxEvent, Bit C) are set at the same
time, an alignment error has occurred.
3.9.5 Media Access Management
The Ethernet network topology is a single shared
medium with several attached stations. The Ether-
net protocol is designed to allow each station equal
access to the network at any given time. Any node
can attempt to gain access to the network by first
completing a deferral process (described below) after the last network activity, and then transmitting a
packet that will be received by all other stations. If
two nodes transmit simultaneously, a collision occurs and the colliding packets are corrupted. Two
primary tasks of the MAC are to avoid network collisions, and then recover from them when they occur. In addition, when the CS8900A is using the
AUI, the MAC must support the SQE Test function
described in section 7.2.4.6 of the Ethernet standard.
3.9.5.1 Collision Avoidance
The MAC continually monitors network traffic by
checking for the presence of carrier activity (carrier
activity is indicated by the assertion of the internal
Carrier Sense signal generated by the ENDEC). If
carrier activity is detected, the network is assumed
busy and the MAC must wait until the current
packet is finished before attempting transmission.
The CS8900A supports two schemes for determining when to initiate transmission: Two-Part Deferral, and Simple Deferral. Selection of the deferral
scheme is determined by the 2-partDefDis bit
(Register 13, LineCTL, Bit D). If the 2-partDefDis
bit is clear, the MAC uses a two-part deferral process defined in section 4.2.3.2.1 of the Ethernet
standard (ISO/IEC 8802-3, 1993). If the 2-partDefDis bit is set, the MAC uses a simplified deferral
scheme. Both schemes are described below:
3.9.5.2 Two-Part Deferral
In the two-part deferral process, the 9.6 µs Inter
Packet Gap (IPG) timer is started whenever the internal Carrier Sense signal is deasserted. If activity
is detected during the first 6.4 µs of the IPG timer,
the timer is reset and then restarted once the activity has stopped. If there is no activity during the first
6.4 µs of the IPG timer, the IPG timer is allowed to
time out (even if network activity is detected during
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the final 3.2 µs). The MAC then begins transmission if a transmit packet is ready and if it is not in
Backoff (Backoff is described later in this section).
If no transmit packet is pending, the MAC continues to monitor the network. If activity is detected
before a transmit frame is ready, the MAC defers to
the transmitting station and resumes monitoring the
network.
mit a packet a total of 16 times (the initial attempt
plus 15 retransmissions) due to normal collisions.
On the 16th collision, it sets the 16coll bit
(Register 8, TxEvent, Bit F) and discards the packet. If the Onecoll bit is set, the MAC discards the
packet without attempting any retransmission.
The two-part deferral scheme was developed to
prevent the possibility of the IPG being shortened
due to a temporary loss of carrier. Figure 10 diagrams the two-part deferral process.
Start Monitoring
Network Activity
3.9.5.3 Simple Deferral
In the simple deferral scheme, the IPG timer is
started whenever Carrier Sense is deasserted. Once
the IPG timer is finished (after 9.6 µs), if a transmit
frame is pending and if the MAC is not in Backoff,
transmission begins the 9.6 µs IPG). If no transmit
packet is pending, the MAC continues to monitor
the network. If activity is detected before a transmit
frame is ready, the MAC defers to the transmitting
station and resumes monitoring the network. Figure 11 diagrams the simple deferral process.
3.9.5.4 Collision Resolution
If a collision is detected while the CS8900A is
transmitting, the MAC responds in one of three
ways depending on whether it is a normal collision
(within the first 512 bits of transmission) or a late
collision (after the first 512 bits of transmission):
3.9.5.5 Normal Collisions
If a collision is detected before the end of the preamble and SFD, the MAC finishes the preamble
and SFD, transmits the jam sequence (32-bit pattern of all 0’s), and then initiates Backoff. If a collision is detected after the transmission of the
preamble and SFD but before 512 bit times, the
MAC immediately terminates transmission, transmits the jam sequence, and then initiates Backoff.
In either case, if the Onecoll bit (Register 9, TxCMD, Bit 9) is clear, the MAC will attempt to trans-
Yes
Network
Active?
No
Start IPG
Timer
Yes
Wait
3.2 µs
IPG
Timer =
6.4 µs?
No
Network
Active?
No
Yes
No
Tx
Frame
No
Ready and Not
in Backoff?
Network
Active?
Yes
Yes
Transmit
Frame
Figure 10. Two-Part Deferral
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3.9.5.6 Late Collisions
If a collision is detected after the first 512 bits have
been transmitted, the MAC immediately terminates
transmission, transmits the jam sequence, discards
the packet, and sets the Out-of-window bit (Register 8, TxEvent, Bit 9). The CS8900A does not initiate backoff or attempt to retransmit the frame. For
additional information about Late Collisions, see
Out-of-Window Error in this section.
gorithms: the Standard Backoff algorithm
(ISO/IEC 4.2.3.2.5) or the Modified Backoff algorithm. The host selects which algorithm through
the ModBackoffE bit (Register 13, LineCTL,
Bit B).
3.9.5.7 Backoff
After the MAC has completed transmitting the jam
sequence, it must wait, or "Back off", before attempting to transmit again. The amount of time it
must wait is determined by one of two Backoff al-
0 ≤ r ≤ 2k
3.9.5.8 Standard Backoff
The Standard Backoff algorithm, also called the
"Truncated Binary Exponential Backoff", is described by the equation:
where r (a random integer) is the number of slot
times the MAC must wait (1 slot time = 512 bit
times), and k is the smaller of n or 10, where n is the
number of retransmission attempts.
3.9.5.9 Modified Backoff
The Modified Backoff is described by the equation:
Start Monitoring
Network Activity
0 ≤ r ≤ 2k
Yes
where r (a random integer) is the number of slot
times the MAC must wait, and k is 3 for n < 3 and
k is the smaller of n or 10 for n ≥ 3, where n is the
number of retransmission attempts.
Network
Active?
No
The advantage of the Modified Backoff algorithm
over the Standard Backoff algorithm is that it reduces the possibility of multiple collisions on the
first three retries. The disadvantage is that it extends the maximum time needed to gain access to
the network for the first three retries.
Wait
9.6 µs
No
Tx
Frame
No
Ready and Not
in Backoff?
Network
Active?
Yes
Transmit
Frame
Figure 11. Simple Deferral
Yes
The host may choose to disable the Backoff algorithm altogether by setting the DisableBackoff bit
(Register 19, TestCTL, Bit B). When disabled, the
CS8900A only waits the 9.6 µs IPG time before
starting transmission.
3.9.5.10 SQE Test
If the CS8900A is transmitting on the AUI, the external transceiver should generate an SQE Test signal on the CI+/CI- pair following each
transmission. The SQE Test is a 10 MHz signal
lasting 5 to 15 bit times and starting within 0.6 to
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1.6 µs after the end of transmission. During this period, the CS8900A ignores receive carrier activity
(see SQE Error in this section for more information).
routed to either the 10BASE-T transceiver or AUI,
depending on configuration.
3.10.2 Carrier Detection
The internal Carrier Detection circuit informs the
MAC that valid receive data is present by asserting
the internal Carrier Sense signal as soon it detects a
valid bit pattern (1010b or 0101b for 10BASE-T,
and 1b or 0b for AUI). During normal packet reception, Carrier Sense remains asserted while the
frame is being received, and is deasserted 1.3 to 2.3
bit times after the last low-to-high transition of the
End-of-Frame (EOF) sequence. Whenever the receiver is idle (no receive activity), Carrier Sense is
deasserted. The CRS bit (Register 14, LineST,
Bit E) reports the state of the Carrier Sense signal.
3.10 Encoder/Decoder (ENDEC)
The CS8900A’s integrated encoder/decoder (ENDEC) circuit is compliant with the relevant portions of section 7 of the Ethernet standard (ISO/IEC
8802-3, 1993). Its primary functions include:
Manchester encoding of transmit data; informing
the MAC when valid receive data is present (Carrier Detection); and, recovering the clock and NRZ
data from incoming Manchester-encoded data.
Figure 12 provides a block diagram of the ENDEC
and how it interfaces to the MAC, AUI and
10BASE-T transceiver.
3.10.3 Clock and Data Recovery
When the receiver is idle, the phase-lock loop
(PLL) is locked to the internal clock signal. The assertion of the Carrier Sense signal interrupts the
PLL. When it restarts, it locks on the incoming data. The receive clock is then compared to the incoming data at the bit cell center and any phase
difference is corrected. The PLL remains locked as
long as the receiver input signal is valid. Once the
PLL has locked on the incoming data, the ENDEC
converts the Manchester data to NRZ and passes
the decoded data and the recovered clock to the
MAC for further processing.
3.10.1 Encoder
The encoder converts NRZ data from the MAC and
a 20 MHz Transmit Clock signal into a serial
stream of Manchester data. The Transmit Clock is
produced by an on-chip oscillator circuit that is
driven by either an external 20 MHz quartz crystal
or a TTL-level CMOS clock input. If a CMOS input is used, the clock should be 20 MHz ±0.01%
with a duty cycle between 40% and 60%. The specifications for the crystal are described in
Section 7.7 on page 121. The encoded signal is
ENDEC
Carrier Sense
RXSQL
Carrier
Detector
RX
RX CLK
RX NRZ
MAC
TXCLK
TX NRZ
TEN
Port Select
Decoder
& PLL
Encoder
RX
MUX
TX
MUX
TX
10BASE-T
Transceiver
AUISQL
AUIRX
AUITX
AUI
AUICol
Collision
Clock
Figure 12. ENDEC
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LinkOK
(to MAC)
10BASE-T Transceiver
Link Pulse
Detector
RX Squelch
RXSQL
RX
ENDEC
TX PreDistortion
TX
RX
Comparator
RX Filters
TX Filters
TX Drivers
RXDRXD+
TXDTXD+
Filter Tuning
Figure 13. 10BASE-T Transceiver
3.10.4 Interface Selection
Physical interface selection is determined by AUIonly bit (Bit 8) and the AutoAUI/10BT (Bit 9) in
the LineCTL register (Register 13). Table 11 describes the possible configurations.
AUIonly
(Bit 8)
0
1
0
AutoAUI/10BT
(Bit 9)
0
N/A
1
Physical
Interface
10BASE-T Only
AUI Only
Auto-Select
Table 11. Interface Selection
3.10.4.1 10BASE-T Only
When configured for 10BASE-T only operation,
the 10BASE-T transceiver and its interface to the
ENDEC are active, and the AUI is powered down.
3.10.4.2 AUI Only
When configured for AUI-only operation, the AUI
and its interface to the ENDEC are active, and the
10BASE-T transceiver is powered down.
3.10.4.3 Auto-Select
In Auto-Select mode, the CS8900A automatically
selects the 10BASE-T interface and powers down
the AUI if valid packets or link pulses are detected
by the 10BASE-T receiver. If valid packets and
link pulses are not detected, the CS8900A selects
the AUI. Whenever the AUI is selected, the
10BASE-T receiver remains active to listen for link
pulses or packets. If 10BASE-T activity is detected, the CS8900A switches back to 10BASE-T.
3.11 10BASE-T Transceiver
The CS8900A includes an integrated 10BASE-T
transceiver that is compliant with the relevant portions of section 14 of the Ethernet standard
(ISO/IEC 8802-3, 1993). It includes all analog and
digital circuitry needed to interface the CS8900A
directly to a simple isolation transformer (see
Section 7.5 on page 120 for a connection diagram).
Figure 13 provides a block diagram of the
10BASE-T transceiver.
3.11.1 10BASE-T Filters
The CS8900A’s 10BASE-T transceiver includes
integrated low-pass transmit and receive filters,
eliminating the need for external filters or a filter/transformer hybrid. On-chip filters are gm/c implementations of fifth-order Butterworth low-pass
filters. Internal tuning circuits keep the gm/c ratio
tightly controlled, even when large temperature,
supply, and IC process variations occur. The nominal 3 dB cutoff frequency of the filters is 16 MHz,
and the nominal attenuation at 30 MHz (3rd harmonic) is -27 dB.
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3.11.2 Transmitter
When configured for 10BASE-T operation,
Manchester encoded data from the ENDEC is fed
into the transmitter’s predistortion circuit where
initial wave shaping and preequalization is performed. The output of the predistortion circuit is
fed into the transmit filter where final wave shaping
occurs and unwanted noise is removed. The signal
then passes to the differential driver where it is amplified and driven out of the TXD+/TXD- pins.
In the absence of transmit packets, the transmitter
generates link pulses in accordance with section
14.2.1.1. of the Ethernet standard. Transmitted link
pulses are positive pulses, one bit time wide, typically generated at a rate of one every 16 ms. The
16 ms timer starts whenever the transmitter completes an End-of-Frame (EOF) sequence. Thus,
there is a link pulse 16 ms after an EOF unless there
is another transmitted packet. Figure 14 diagrams
the operation of the Link Pulse Generator.
If no link pulses are being received on the receiver,
the 10BASE-T transmitter is internally forced to an
inactive state unless bit DisableLT in register 19
(Test Control register) is set to one.
3.11.3 Receiver
The 10BASE-T receive section consists of the receive filter, squelch circuit, polarity detection and
correction circuit, and link pulse detector.
3.11.3.1 Squelch Circuit
The 10BASE-T squelch circuit determines when
valid data is present on the RXD+/RXD- pair. Incoming signals passing through the receive filter
are tested by the squelch circuit. Any signal with
amplitude less than the squelch threshold (either
positive or negative, depending on polarity) is rejected.
3.11.3.2 Extended Range
The CS8900A supports an Extended Range feature
that reduces the 10BASE-T receive squelch threshold by approximately 6 dB. This allows the
CS8900A to operate with 10BASE-T cables that
are longer than 100 meters (100 meters is the maximum length specified by the Ethernet standard).
The exact additional distance depends on the quality of the cable and the amount of electromagnetic
noise in the surrounding environment. To activate
this feature, the host must set the LoRxSquelch bit
(Register 13, LineCTL, Bit E).
3.11.4 Link Pulse Detection
To prevent disruption of network operation due to
a faulty link segment, the CS8900A continually
monitors the 10BASE-T receive pair (RXD+/
RXD-) for packets and link pulses. After each
packet or link pulse is received, an internal LinkLoss timer is started. As long as a packet or link
pulse is received before the Link-Loss timer finishes (between 25 and 150 ms), the CS8900A maintains normal operation. If no receive activity is
detected, the CS8900A disables packet transmission to prevent "blind" transmissions onto the network (link pulses are still sent while packet
transmission is disabled). To reactivate transmission, the receiver must detect a single packet (the
packet itself is ignored), or two link pulses separat-
Time
Link
Pulse
Packet
Link
Pulse
Packet
Less Than
16ms
16ms
16ms
Figure 14. Link Pulse Transmission
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ed by more than 2 to 7 ms and no more than 25 to
150 ms (see Section 7.4 on page 113 for 10BASET timing).
The state of the link segment is reported in the
LinkOK bit (Register 14, LineST, Bit 7). If the
HC0E bit (Register 15, SelfCTL, Bit D) is clear, it
is also indicated by the output of the LINKLED
pin. If the link is "good", the LinkOK bit is set and
the LINKLED pin is driven low. If the link is "bad"
the LinkOK bit is clear and the LINKLED pin is
high. To disable this feature, the host must set the
DisableLT bit (Register 19, TestCTL, Bit 7). If
DisableLT is set, the CS8900A will transmit and
receive packets independent of the link segment.
3.11.5 Receive Polarity Detection and Correction
The CS8900A automatically checks the polarity of
the receive half of the twisted pair cable. If the polarity is correct, the PolarityOK bit (Register 14,
LineST, bit C) is set. If the polarity is reversed, the
PolarityOK bit is clear. If the PolarityDis bit (Register 13, LineCTL, Bit C) is clear, the CS8900A automatically corrects a reversal. If the PolarityDis
bit is set, the CS8900A does not correct a reversal.
The PolarityOK bit and the PolarityDis bit are independent.
To detect a reversed pair, the receiver examines received link pulses and the End-of-Frame (EOF) sequence of incoming packets. If it detects at least
one reversed link pulse and at least four frames in a
row with negative polarity after the EOF, the receive pair is considered reversed. Any data received before the correction of the reversal is
ignored.
3.11.6 Collision Detection
If half-duplex operation is selected (Register 19,
Bit E, FDX), the CS8900A detects a 10BASE-T
collision whenever the receiver and transmitter are
active simultaneously. When a collision is present,
the Collision Detection circuit informs the MAC by
asserting the internal Collision signal (see
Section 3.9 on page 28 for collision handling).
3.12 Attachment Unit Interface (AUI)
The CS8900A Attachment Unit Interface (AUI)
provides a direct interface to external 10BASE2,
10BASE5, and 10BASE-FL Ethernet transceivers.
It is fully compliant with Section 7 of the Ethernet
standard (ISO/IEC 8802-3), and as such, is capable
of driving a full 50-meter AUI cable.
The AUI consists of three pairs of signals: Data Out
(DO+/DO-), Data In (DI+/DI-), and Collision In
(CI+/CI-). To select the AUI, the host should set
the AUI bit (Register 13, LineCTL, Bit 8). The AUI
can also be selected automatically as described in
the previous section (Section 3.10.4 on page 35).
Figure 15 provides a block diagram of the AUI.
(For a connection diagram, see Section 7.6 on
page 121).
AUI
CL+
CL-
-+
Collision
Detect
AUICol (to MAC)
AUIRX
DI+
DI-
AUISQL ENDEC
-+
DO+
DO-
AUITX
Figure 15. AUI
3.12.1 AUI Transmitter
The AUI transmitter is a differential driver designed to drive a 78 Ω cable. It accepts data from
the ENDEC and transmits it directly on the
DO+/DO- pins. After transmission has started, the
CS8900A expects to see the packet "looped-back"
(or echoed) to the receiver, causing the Carrier
Sense signal to be asserted. This Carrier Sense
presence indicates that the transmit signal is getting
through to the transceiver. If the Carrier Sense signal remains deasserted throughout the transmis-
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sion, or if the Carrier Sense signal is deasserted
before the end of the transmission, there is a Lossof-Carrier error and the Loss-of-CRS bit (Register
8, TxEvent, Bit 6) is set.
3.12.2 AUI Receiver
The AUI receiver is a differential pair circuit that
connects directly to the DI+/DI- pins. It is designed
to distinguish between transient noise pulses and
incoming Ethernet packets. Incoming packets with
proper amplitude and pulse width are passed on to
the ENDEC section, while unwanted noise is rejected.
3.12.3 Collision Detection
The AUI collision circuit is a differential pair receiver that detects the presence of collision signals
on the CI+/CI- pins. The collision signal is generat-
ed by an external Ethernet transceiver whenever a
collision is detected on the Ethernet segment. (Section 7.3.1.2 of ISO/IEC 8802-3, 1993, defines the
collision signal as a 10 MHz ± 15% signal with a
duty cycle no worse than 60/40). When a collision
is present, the AUI Collision circuit informs the
MAC by asserting the internal Collision signal.
3.13 External Clock Oscillator
A 20-MHz quartz crystal or CMOS clock input is
required by the CS8900A. If a CMOS clock input
is used, it should be connected the to XTAL1 pin,
with the XTAL2 pin left open. The clock signal
should be 20 MHz ±0.01% with a duty cycle between 40% and 60%. The specifications for the
crystal are described in Section 7.7 on page 121.
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4.0 PACKETPAGE ARCHITECTURE
4.1 PacketPage Overview
The CS8900A architecture is based on a unique,
highly-efficient method of accessing internal registers and buffer memory known as PacketPage.
PacketPage provides a unified way of controlling
the CS8900A in Memory or I/O space that minimizes CPU overhead and simplifies software. It
provides a flexible set of performance features and
configuration options, allowing designers to develop Ethernet circuits that meet their particular system requirements.
4.1.1 Integrated Memory
Central to the CS8900A architecture is a 4-Kbyte
page of integrated RAM known as PacketPage
memory. PacketPage memory is used for temporary storage of transmit and receive frames, and for
internal registers. Access to this memory is done
directly, through Memory space operations
(Section 4.9 on page 74), or indirectly, through I/O
space operations (Section 4.10 on page 76). In
most cases, Memory Mode will provide the best
overall performance, because ISA Memory operations require fewer cycles than I/O operations. I/O
Mode is the CS8900A’s default configuration and
is used when memory space is not available or
when special operations are required (e.g. waking
the CS8900A from the Software Suspend State requires the host to write to the CS8900A’s assigned
I/O space).
The user-accessible portion of PacketPage memory
is organized into the following six sections:
PacketPage
Address
0000h - 0045h
0100h - 013Fh
0140h - 014Fh
0150h - 015Dh
0400h
0A00h
Contents
Bus Interface Registers
Status and Control Registers
Initiate Transmit Registers
Address Filter Registers
Receive Frame Location
Transmit Frame Location
4.1.2 Bus Interface Registers
The Bus Interface registers are used to configure
the CS8900A’s ISA-bus interface and to map the
CS8900A into the host system’s I/O and Memory
space. Most of these registers are written only during initialization, remaining unchanged while the
CS8900A is in normal operating mode. The exceptions to this are the DMA registers which are modified continually whenever the CS8900A is using
DMA. These registers are described in more detail
in Section 4.3 on page 42.
4.1.3 Status and Control Registers
The Status and Control registers are the primary
means of controlling and getting status of the
CS8900A. They are described in more detail in
Section 4.4 on page 47.
4.1.4 Initiate Transmit Registers
The TxCMD/TxLength registers are used to initiate
Ethernet frame transmission. These registers are
described in more detail in Section 4.5 on page 71.
(See Section 5.7 on page 99 for a description of
frame transmission.)
4.1.5 Address Filter Registers
The Filter registers store the Individual Address filter and Logical Address filter used by the Destination Address (DA) filter. These registers are
described in more detail in Section 4.6 on page 72.
For a description of the DA filter, see Section 5.3
on page 87.
4.1.6 Receive and Transmit Frame Locations
The Receive and Transmit Frame PacketPage locations are used to transfer Ethernet frames to and
from the host. The host simply writes to and reads
from these locations and internal buffer memory is
dynamically allocated between transmit and receive as needed. This provides more efficient use
of buffer memory and better overall network performance. As a result of this dynamic allocation,
only one receive frame (starting at PacketPage base
+ 0400h) and one transmit frame (starting at Pack-
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CS8900A
Crystal LAN™ ISA Ethernet Controller
etPage base + 0A00h) are directly accessible. See
Section 4.7 on page 73.
4.2 PacketPage Memory Map
Table 12 shows the CS8900A PacketPage memory
address map: s
PacketPage # of
Type
Description
Address Bytes
Bus Interface Registers
0000h
4
Read-only Product Identification Code
0004h
28
Reserved
0020h
2
Read/Write I/O Base Address
0022h
2
Read/Write Interrupt Number (0,1,2,or 3)
0024h
2
Read/Write DMA Channel Number (0, 1, or 2)
0026h
2
Read-only DMA Start of Frame
0028h
2
Read-only DMA Frame Count (12 Bits)
002Ah
2
Read-only RxDMA Byte Count
002Ch
4
0030h
4
Read/Write Memory Base Address Register
(20 Bit)
Read/Write Boot PROM Base Address
0034h
4
Read/Write Boot PROM Address Mask
0038h
0040h
8
2
Reserved
Read/Write EEPROM Command
0042h
2
Read/Write EEPROM Data
0044h
0050h
12
2
Reserved
Read only Received Frame Byte Counter
0052h
174
Reserved
Status and Control Registers
0100h
32 Read/Write Configuration & Control Registers
(2 bytes per regiseter)
0120h
32
Read-only Status & Event Registers
(2 bytes per register)
0140h
4
Reserved
Initiate Transmit Registers
Cross Reference
Section 4.3 on page 42
Note 2
Section 4.3 on page 42,
Section 4.7 on page 73
Section 3.2 on page 18,
Section 4.3 on page 42
Section 3.2 on page 18,
Section 4.3 on page 42
Section 4.3 on page 42,
Section 5.4 on page 90
Sections Section 4.3 on page 42,
”Receive DMA”
Section 4.3 on page 42,
Section 5.4 on page 90
Section 4.3 on page 42,
Section 4.9 on page 74
Section 3.6 on page 25,
Section 4.3 on page 42
Section 3.6 on page 25,
Section 4.3 on page 42
Note 2
Section 3.5 on page 24,
Section 4.3 on page 42
Section 3.5 on page 24,
Section 4.3 on page 42
Note 2
Section 4.3 on page 42,
Section 5.2.9 on page 87
Note 2
Section 4.4 on page 47
Section 4.4 on page 47
Note 2
Notes: 1. All registers are accessed as words only.
2. Read operation from the reserved location provides undefined data. Writing to a reserved location or
undefined bits may result in unpredictable operation of the CS8900A.
Table 12. PacketPage Memory Address Map
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DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
PacketPage # of
Type
Description
Address Bytes
0144h
2
Write-only TxCMD (transmit command)
0146h
2
Write-only TxLength (transmit length)
0148h
8
Reserved
Address Filter Registers
0150h
8
Read/Write Logical Address Filter (hash table)
0158h
6
015Eh
674
Frame Location
0400h
2
Read/Write Individual Address
-
Reserved
Read-only RXStatus (receive status)
0402h
2
Read-only RxLength (receive length, in bytes)
0404h
-
Read-only Receive Frame Location
0A00
-
Write-only Transmit Frame Location
Cross Reference
Section 4.5 on page 71,
Section 5.7 on page 99
Section 4.5 on page 71,
Section 5.7 on page 99
Note 2
Section 4.6 on page 72,
Section 5.3 on page 87
Section 4.6 on page 72,
Section 5.3 on page 87
Note 2
Section 4.7 on page 73,
Section 5.2 on page 79
Section 4.7 on page 73,
Section 5.2 on page 79
Section 4.7 on page 73,
Section 5.2 on page 79
Section 4.7 on page 73,
Section 5.7 on page 99
Notes: 1. All registers are accessed as words only.
2. Read operation from the reserved location provides undefined data. Writing to a reserved location or
undefined bits may result in unpredictable operation of the CS8900A.
Table 12. PacketPage Memory Address Map (continued)
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CS8900A
Crystal LAN™ ISA Ethernet Controller
4.3 Bus Interface Registers
4.3.1 Product Identification Code
(Read only, Address: PacketPage base + 0000h)
Address 0000h
First byte of EISA registration
number for
Crystal Semiconductor
Adress 0001h
Second byte of EISA
registration number for Crystal Semiconductor
Address 0002h
First 8 bits of
Product ID number
Address 00003h
Last 3 bits of the Product ID
number (5 “X” bits are the revision number)
The Product Identification Code Register is located in the first four bytes of the PacketPage (0000h to 0003h). The
register contains a unique 32-bit product ID code that identifies the chip as a CS8900A. The host can use this number to determine which software driver to load and to check which features are available.
Reset value is: 0000 1110 0110 0011 0000 0000 000X XXXX
The X XXXX codes for the CS8900A are:
Rev B: 0 0111
4.3.2 I/O Base Address
(Read/Write, Address: PacketPage base + 0020h)
Address 0021h
Most significant byte of I/O Base Address
Address 0020h
Least significant byte of I/O Base Address
The I/O Base Address Register describes the base address for the sixteen contiguous locations in the host system’s
I/O space, which are used to access the PacketPage registers. See Section 4.10 on page 76. The default location
is 0300h.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0011 0000 0000
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Crystal LAN™ ISA Ethernet Controller
4.3.3 Interrupt Number
(Read/Write, Address: PacketPage base + 0022h)
Address 0023h
Address 0022h
Interrupt number assignment:
0000 0000b= pin INTRQ0
0000 0001b= pin INTRQ1
0000 0010b= pin INTRQ2
0000 0011b= pin INTRQ3
0000 01XXb= All INTRQ pins high-impedence
00h
The Interrupt Number Register defines the interrupt pin selected by the CS8900A. In a typical application the following bus signals are tied to the following pins:
Bus signal
IRQ5
IRQ10
IRQ11
IRQ12
Typical pin connection
INTRQ3
INTRQ0
INTRQ1
INTRQ2
See Section 3.2 on page 18.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state, which corresponds to placing all the INTRQ pins in a high-impedance state. If an EEPROM is found, then the register’s initial
value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: XXXX XXXX XXXX X100
4.3.4 DMA Channel Number
(Read/Write, Address: PacketPage base + 0024h)
Address 0025h
Address 0024h
DMA channel assignment:
0000 0000b= pin DMRQ0 and DMACK0
0000 0001b= pin DMRQ1 and DMACK1
0000 0010b= pin DMRQ2 and DMACK2
0000 0011b= All DMRQ pins high-impedence
00h
The DMA Channel register defines the DMA pins selected by the CS8900A. In the typical application, the following
bus signals are tied to the following pins:
Bus signal
DRQ5
DACK5
DRQ6
DACK6
DRQ7
DACK7
Typical pin connection
DMRQ0
DMACK0
DMRQ1
DMACK1
DMRQ2
DMACK2
See Section 3.2 on page 18 and Section 5.4 on page 90.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state which corresponds to setting all DMRQ pins to high-impedance. If a EEPROM is found, then the register’s initial value may be
set by the EEPROM. See Section 3.3 on page 19.
Reset value is: XXXX XXXX XXXX XX11
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CS8900A
Crystal LAN™ ISA Ethernet Controller
4.3.5 DMA Start of Frame
(Read only, Address: PacketPage base + 0026h)
Address 0027h
Most significant byte of offset value
Address 0026h
Least significant byte of offset value
The DMA Start of Frame Register contains a 16-bit value which defines the offset from the DMA base address to
the start of the most recently transferred received frame. See Section 5.4 on page 90.
Reset value is: 0000 0000 0000 0000
4.3.6 DMA Frame Count
(Read only, Address: PacketPage base + 0028h)
Address 0029h
Most significant byte of frame count
(most-significnant nibble always 0h)
Address 0028h
Least significant byte of frame count
The lower 12 bits of the DMA Frame Count register define the number of valid frames transferred via DMA since the
last readout of this register. The upper 4 bits are reserved. See Section 5.4 on page 90.
Reset value is: XXXX 0000 0000 0000
4.3.7 RxDMA Byte Count
(Read only, Address: PacketPage base + 002Ah)
Address 002Bh
Most significant byte of byte count
Address 002Ah
Least significant byte of byte count
The RxDMA Byte Count register describes the valid number of bytes DMAed since the last readout. See Section 5.4
on page 90.
Reset value is: 0000 0000 0000 0000
4.3.8 Memory Base Address
(Read/Write, Address: PacketPage base + 002Ch)
Address 002Fh
Reserved
Address 002Eh
The most significant nibble of
memory base address. The
high-order nibble is reserved.
Address 002Dh
Address 002Ch
Contains portion of memory
base address.
The least significant byte of
the memory base address.
Memory Base Address: The lower three bytes (002Ch, 002Dh, and 002Eh) are used for the 20-bit memory base
address. The upper three nibbles are reserved.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: XXXX XXXX XXXX 0000 0000 0000 0000 0000
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DS271PP3
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Crystal LAN™ ISA Ethernet Controller
4.3.9 Boot PROM Base Address
(Read/Write, Address: PacketPage base + 0030h)
Address 0033h
Reserved
Address 0032h
Address 0031h
The most significant nibble of
Boot PROM base address. Contains portion of Boot PROM
The high-order nibble is
base address.
reserved.
Address 0030h
The least significant byte of
the Boot PROM base
address.
The lower three bytes (0030h, 0031h, and 0032h) of the Boot PROM Base Address register are used for the 20-bit
Boot PROM base address. The upper three nibbles are reserved. See Section 3.6 on page 25.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: XXXX XXXX XXXX 0000 0000 0000 0000 0000
4.3.10 Boot PROM Address Mask
(Read/Write, Address: PacketPage base + 0034h)
Address 0037h
Reserved
Address 0036h
Address 0035h
Address 0034h
The most significant nibble of
The least significant byte of
Contains portion of Boot PROM
Boot PROM mask address.
the Boot PROM mask
mask address. The lower-order
The high-order nibble is
address. Must be written as
nibble must be written as 0h.
reserved.
00h.
The Boot PROM address mask register indicates the size of the attached Boot PROM and is limited to 4K bit increments. The lower 12 bits of the Address Mask are ignored, and should be 000h. The next lowest-order bits describe
the size of the PROM. The upper three nibbles are reserved.
For example:
Size of Boot PROM
4k bits
8k bits
16k bits
Register value
XXXX XXXX XXXX 1111 1111 0000 0000 0000
XXXX XXXX XXXX 1111 1110 0000 0000 0000
XXXX XXXX XXXX 1111 1100 0000 0000 0000
See Section 3.6 on page 25.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: XXXX XXXX XXXX 0000 0000 0000 0000 0000
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CS8900A
Crystal LAN™ ISA Ethernet Controller
4.3.11 EEPROM Command
(Read/Write, Address: PacketPage base + 0040h)
7
6
5
F
E
D
Reserved
4
3
ADD7 to ADD0
C
B
2
1
0
A
ELSEL
9
OB1
8
OB0
This register is used to control the reading, writing and erasing of the EEPROM. See Section 3.5.
ADD7-ADD0
Address of the EEPROM word being accessed.
OB1,OB0
Indicates the Opcode of the command being executed. See Table 7.
ELSEL
External logic select: When clear, the EECS pin is used to select the EEPROM. When set, the
ELCS pin is used to select the external LA decode circuit.
Reserved
Reserved and must be written as 0.
Reset value is: XXXX XXXX XXXX XXXX
4.3.12 EEPROM Data
(Read/Write, Address: PacketPage base + 0042h)
Address 0043h
Most significant byte of the EEPROM data.
Address 0042h
Least significant byte of the EEPROM data.
This register contains the word being written to, or read from, the EEPROM. See Section 3.5 on page 24.
Reset value is: XXXX XXXX XXXX XXXX
4.3.13 Receive Frame Byte Counter
(Read only, Address: PacketPage base + 0050h)
Address 0051h
Most significant byte of the byte count.
Address 0050h
Least significant byte of the byte count.
This register contains the count of the total number bytes received in the the current received frame. This count continuously increments as more bytes in this frame are received. See Section 5.2.9 on page 87.
Reset value is: XXXX XXXX XXXX XXXX
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DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4 Status and Control Registers
The Status and Control registers are the primary
registers used to control and check the status of the
CS8900A. They are organized into two groups:
Configuration/Control Registers and Status/Event
Registers. All Status and Control Registers are 16bit words as shown in Figure 16. Bit 0 indicates
whether it is a Configuration/Control Register
(Bit 0 = 1) or a Status/Event Register (Bit 0 = 0).
Bits 0 through 5 provide an internal address code
that describes the exact function of the register.
Bits 6 through F are the actual Configuration/Control and Status/Event bits.
4.4.1 Configuration and Control Registers
Configuration and Control registers are used to setup the following:
•
how frames will be transmitted and received;
•
which frames will be transmitted and received;
•
which events will cause interrupts to the host
processor; and,
•
how the Ethernet physical interface will be
configured.
These registers are read/write and are designated
by odd numbers (e.g. Register 1, Register 3, etc.).
The Transmit Command Register (TxCMD) is a
special type of register. It appears in two separate
locations in the PacketPage memory map. The first
location, PacketPage base + 0108h, is within the
block of Configuration/Control Registers and is
read-only. The second location, PacketPage base +
0144h, is where the actual transmit commands are
issued and is write-only. See Section 4.4.4 on
page 49 (Register 9) and Section 5.7 on page 99 for
a more detailed description of the TxCMD register.
4.4.2 Status and Event Registers
Status and Event registers report the status of transmitted and received frames, as well as information
about the configuration of the CS8900A. They are
read-only and are designated by even numbers (e.g.
Register 2, Register 4, etc.).
The Interrupt Status Queue (ISQ) is a special type
of Status/Event register. It is located at PacketPage
base + 0120h and is the first register the host reads
when responding to an Interrupt.
A more detailed description of the ISQ can be
found in Section 5.1 on page 79.
Three 10-bit counters are included with the Status
and Event registers. RxMISS counts missed receive frames, TxCOL counts transmit collisions,
and TDR is a time domain reflectometer useful in
locating cable faults. The following sections contain more information about these counters.
Table 13 provides a summary of PacketPage Register types.
4.4.3 Status and Control Bit Definitions
This section provides a description of the special
bit types used in the Status and Control registers.
16-bit Register Word
Bit Number
F E D C B A 9 8 7 6 5 4 3 2 1 0
Internal Address
(bits 0 - 5)
1 = Control/Configuration
0 = Status/Event
10 Register Bits
Figure 16. Status and Control Register Format
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CS8900A
Crystal LAN™ ISA Ethernet Controller
Suffix
CMD
CFG
Type
Read/Write
Read/Write
CTL
Read/Write
Event
Read-only
ST
Read-only
Read-only
Description
Command: Written once per frame to initiate transmit.
Configuration: Written at setup and used to determine
what frames will be transmitted and received and what
events will cause interrupts.
Control: Written at setup and used to determine what
frames will be transmitted and received and how the physical interface will be configured.
Event: Reports the status of transmitted and received
frames.
Status: Reports information about the configuration of the
CS8900A.
Counters: Counts missed receive frames and collisions.
Provides time domain for locating coax cable faults.
Comments
cleared when read
cleared when read
Table 13. PacketPage Register Types
Section 4.4.4 on page 49 provides a detailed description of the bits in each register.
4.4.3.1 Act-Once Bits
There are four bits that cause the CS8900A to take
a certain action only once when set. These "ActOnce" bits are: Skip_1 (Register 3, RxCFG, Bit 6),
RESET (Register 15, SelfCTL, Bit 6), ResetRxDMA (Register 17, BusCTL, Bit 6), and SWint-X
(Register B, BufCFG, Bit 6). To cause the action
again, the host must set the bit again. Act-Once bits
are always read as clear.
4.4.3.2 Temporal Bits
Temporal bits are bits that are set and cleared by the
CS8900A without intervention of the host processor. This includes all status bits in the three status
registers (Register 14, LineST; Register 16,
SelfST; and, Register 18, BusST), the RxDest bit
(Register C, BufEvent, Bit F), and the Rx128 bit
(Register C, BufEvent, Bit B). Like all Event bits,
RxDest and Rx128 are cleared when read by the
host.
4.4.3.3 Interrupt Enable Bits and Events
Interrupt Enable bits end with the suffix iE and are
located in three Configuration registers: RxCFG
(Register 3), TxCFG (Register 7), and BufCFG
(Register B). Each Interrupt Enable bit corresponds
to a specific event. If an Interrupt Enable bit is set
and its corresponding event occurs, the CS8900A
generates an interrupt to the host processor.
The bits that report when various events occur are
located in three Event registers and two counters.
The Event registers are RxEvent (Register 4), TxEvent (Register 8), and BufEvent (Register C). The
counters are RxMISS (Register 10) and TxCOL
(Register 12). Each Interrupt Enable bit and its associated Event are identified in Table 14.
An Event bit will be set whenever the specified
event happens, whether or not the associated Interrupt Enable bit is set. All Event registers are cleared
upon read-out by the host.
4.4.3.4 Accept Bits
There are nine Accept bits located in the RxCTL
register (Register 5), each of which is followed by
the suffix A. Accept bits indicate which types of
frames will be accepted by the CS8900A. (A frame
is said to be "accepted" by the CS8900A when the
frame data are placed in either on-chip memory, or
in host memory by DMA.) Four of these bits have
corresponding Interrupt Enable (iE) bits. An Accept bit and an Interrupt Enable bit are independent
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DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
Interrupt Enable Bit
(register name)
Event Bit or Counter
(register name)
ExtradataiE (RxCFG)
RuntiE (RxCFG)
CRCerroriE (RxCFG)
RxOKiE (RxCFG)
Extradata (RxEvent)
Runt (RxEvent)
CRCerror (RxEvent)
RxOK (RxEvent)
16colliE (TxCFG)
AnycolliE (TxCFG)
16coll (TxEvent)
“Number-of Tx-collisions”
counter is incremented
(TxEvent)
JabberiE (TxCFG)
Jabber (TxEvent)
Out-of-windowiE (TxCFG) Out-of-window (TxEvent)
TxOKiE (TxCFG)
TxOK (TXEvent)
SQEerroriE (TxCFG)
SQEerror (TxEvent)
Loss-of-CRSiE (TxCFG)
Loss-of-CRS (TxEvent)
MissOvfloiE (BufCFG)
TxColOvfloiE (BufCFG)
RxDestiE (BufCFG)
Rx128iE (BufCFG)
RxMissiE (BufCFG)
TxUnderruniE (BufCFG)
Rdy4TxiE (BufCFG)
RxDMAiE (BufCFG)
event occurs, but then does not accept the receive
frame (the length of the receive frame is set to zero).
The other five Accept bits in RxCTL are used for
destination address filtering (see Section 5.3 on
page 87). The Accept mechanism is explained in
more detail in Section 5.2 on page 79.
4.4.4 Status and Control Register Summary
The table on the following page (Table 15) provides a summary of the Status and Control registers. Section 4.4.4 on page 49 gives a detailed
description of each Status and Control register.
RxMISS counter overflows past 1FFh
TxCOL counter overflows
past 1FFh
RxDest (BufEvent)
Rx128 (BufEvent)
RxMISS (BufEvent)
TxUnderrun (BufEvent)
Rdy4Tx (BufEvent)
RxDMAFrame (BufEvent)
Table 14. Interrupt Enable Bits and Events
operations. It is possible to set either, neither, or
both bits. The four corresponding pairs of bits are:
IE Bit in RxCFG
ExtradataiE
RuntiE
CRCerroriE
RxOKiE
A Bit in RxCTL
ExtradataA
RuntA
CRCerrorA
RxOKA
If one of the above Interrupt Enable bits is set and
the corresponding Accept bit is clear, the CS8900A
generates an interrupt when the associated receive
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CS8900A
Crystal LAN™ ISA Ethernet Controller
Control and Configuration Bits
F
E
Extra
dataiE
Extra
dataA
D
RuntiE
RuntA
16colli
E
TxPadDis
Miss
OvfloiE
RxDestiE
LoRx
2-part
Squelch DefDis
HCB1 HCB0 HC1E
Enabl
e IRQ
RxDMA
size
FDX
C
B
A
9
Register
8
Reserved (register contents undefined)
CRC
Buffer
AutoRx RxDMA RxOKiE
erroriE
CRC
DMAE
only
CRC
Broad
Individ
Multi
RxOKA
errorA
castA
ualA
castA
AnycolliE
Jab
Out-of- TxOKiE
beriE windowiE
InhibitOnecoll
Force
CRC
TxCol Rx128iE Rxmis- TxUnder- Rdy4Txi
OvfloiE
siE
runiE
E
Reserved (register contents undefined)
Polarity
Mod
AutoAUI/ AUIonly
Dis
BackoffE
10BT
HC0E
HWStan
HW
SW SusdbyE
SleepE
pend
IOCH
DMA
Memo- UseSA DMAexRDYE
Burst
ryE
tend
Disable AUIloop ENDEC
Backoff
loop
Reserved (register contents undefined)
7
6
StreamE Skip_1
Promis IAHash
cuousA
A
SQErro- Loss-ofriE
CRSiE
TxStart
RxDMAiE
SWint-X
Ser
TxON
Ser
RxON
RESET
Reset
RxDMA
Disable
LT
Number
(Offset)
1
3
(0102h)
5
(0104h)
7
(0106h)
9
(0108h)
B
(010Ah)
D-11
13
(0112h)
15
(0114h)
17
(0116)
19
(0118)
1B -1F
Name
RxCFG
RxCTL
TxCFG
TxCMD
BufCFG
Line
CTL
SelfCTL
BusCTL
TestCTL
Table 15. Status and Control Register Descriptions
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DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
Status and Event Bits
F
E
D
C
B
A
Register
9
8
7
6
Number
(Offset)
Interrupt Status Queue
0
(0120h)
Reserved (register contents undefined)
2
Extra
Runt
CRC
Broad- Individ- Hashed RxOK Dribble IAHash
4
data
error
cast
ual Adr
bits
(0124h)
Hash Table Index (alternate RxEvent meaning if
Hashed RxOK Dribble IAHash
4
Hashed = 1 and RxOK = 1)
bits
(0124h)
Reserved (register contents undefined)
6
16coll
Number-of-Tx-collisions
Jabber Out-ofTxOK
SQE Loss-of8
Window
error
CRS
(0128h)
Reserved (register contents undefined)
A
Rx
Rx128 RxMiss TxUnder- Rdy4Tx RxDMA SWint
C
Dest
run
Frame
(012Ch)
Reserved (register contents undefined)
E
10-bit Receive Miss (RxMISS) counter, cleared when read
10
(0130h)
10-bit Transmit Collision (TxCOL) counter, cleared when read
12
(0132h)
CRS
Polarity
10BT
AUI
LinkOK
14
OK
(0134h)
EESize
EL
EEPRO EEPRO SIBUSY INITD
3.3 V
16
present
M OK Mpresent
Active (0136h)
Rdy4Tx TxBid
18
NOW
Err
(0138h)
Reserved (register contents undefined)
1A
10-bit AUI Time Domain Reflectometer (TDR) counter, cleared when read
1C
(013Ch)
Reserved (register contents undefined)
1E
Name
ISQ
Rx
Event
Rx
Eventalt
TxEvent
Buf
Event
RxMISS
TxCOL
LineST
SelfST
BusST
TDR
Table 15. Status and Control Register Descriptions (continued)
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
51
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.5 Register 0: Interrupt Status Queue
(ISQ, Read-only, Address: PacketPage base + 0120h)
7
6
5
4
3
RegContent
F
2
1
0
A
9
8
RegNum
E
D
C
B
RegContent
The Interrupt Status Queue Register is used in both Memory Mode and I/O Mode to provide the host with interrupt
information. Whenever an event occurs that triggers an enabled interrupt, the CS8900A sets the appropriate bit(s)
in one of five registers, maps the contents of that register to the ISQ register, and drives an IRQ pin high. Three of
the registers mapped to ISQ are event registers: RxEvent (Register 4), TxEvent (Register 8), and BufEvent (Register
C). The other two registers are counter-overflow reports: RxMISS (Register 10) and TxCOL (Register 12). In Memory Mode, ISQ is located at PacketPage base + 120h. In I/O Mode, ISQ is located at I/O Base + 0008h. See
Section 5.1 on page 79.
RegNum
The lower six bits describe which register (4, 8, C, 10 or 12) is contained in the ISQ.
RegContent
The upper ten bits contain the register data contents.
Reset value is: 0000 0000 0000 0000
CIRRUS LOGIC PRODUCT DATA SHEET
52
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.6 Register 3: Receiver Configuration
(RxCFG, Read/Write, Address: PacketPage base + 0102h)
7
StreamE
6
Skip_1
5
F
E
ExtradataiE
D
RuntiE
4
3
2
1
0
A
AutoRx DMAE
9
RxDMA only
8
RxOKiE
000011
C
CRCerroriE
B
BufferCRC
RxCFG determines how frames will be transferred to the host and what frame types will cause interrupts.
000011
These bits provide an internal address used by the CS8900A to identify this as the Reveiver
Configuration Register.
Skip_1
When set, this bit causes the last committed received frame to be deleted from the receive buffer. To skip another frame, the host must rewrite a “1” to this bit. This bit is not to be used if
RxDMAonly (Bit 9) is set. Skip_1 is an Act-Once bit. See Section 5.2.5 on page 84.
StreamE
When set, StreamTransfer mode is used to transfer receive frames that are back-to-back and
that pass the Destination Address filter (see Section 5.3 on page 87). When StreamE is clear,
StreamTransfer mode is not used. This bit must not be set unless either bit AutoRxDMA or bit
RXDMAonly is set.
RxOKiE
When set, there is an RxOK Interrupt if a frame is received without errors. RxOK interrupt is
not generated when DMA mode is used for frame reception.
RxDMAonly
The Receive-DMA mode is used for all receive frames when this bit is set.
AutoRxDMAE
When set, the CS8900A will automatically switch to Receive-DMA mode if the conditions specified in Section 5.5 on page 93 are met. RxDMAonly (Bit 9) has precedence over AutoRxDMAE.
BufferCRC
When set, the received CRC is included with the data stored in the receive-frame buffer, and
the four CRC bytes are included in the receive-frame length (PacketPage base + 0402h). When
clear, neither the receive buffer nor the receive length include the CRC.
CRCerroriE
When set, there is a CRCerror Interrupt if a frame is received with a bad CRC.
RuntiE
When set, ther is a Runt Interrupt if a frame is received that is shorter than 64 bytes. The
CS8900A always discards any frame that is shorter than 8 bytes.
ExtradataiE
When set, there is an Extradata Interrupt if a frame is received that is longer than 1518 bytes.
The operation of this bit is independent of the received packet integrity (good or bad CRC).
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0000 0000 0011
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
53
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.7 Register 4: Receiver Event
(RxEvent, Read-only, Address: PacketPage base + 0124h)
7
Dribblebits
6
IAHash
5
F
E
Extradata
D
Runt
4
3
2
1
0
A
Individual Adr
9
Hashed
8
RxOK
000100
C
CRCerror
B
Broadcast
Alternate meaning if bits 8 and 9 are both set (see Section 5.3 on page 87 for exception regarding Broadcast
frames).
7
Dribblebits
F
6
IAHash
5
4
3
2
1
0
A
9
Hashed = 1
8
RxOK = 1
000100
E
D
C
B
Hash Table Index (see Section 5.3 on page 87)
RxEvent reports the status of the current received frame.
000100
These bits identify this as the Receiver Event Register. When reading this register, these bits
will be 000100, where the LSB corresponds to Bit 0.
IAHash
If the received frame’s Destination Address is accepted by the hash filter, then this bit is set if,
and only if IAHashA (Register 5, RxCTL, Bit 6) is set, and Hashed (Bit 9) is set. See Section 5.3
on page 87.
Dribblebits
If set, the received frame had from one to seven bits after the last received full byte. An "Alignment Error" occurs when Dribblebits and CRCerror (Bit C) are both set.
RxOK
If set, the received frame had a good CRC and valid length (i.e., there is not a CRC error, Runt
error, or Extradata error). When RxOK is set, then the length of the received frame is contained
at PacketPage base + 0402h. If RxOKiE (Register 3, RxCFG, Bit 8) is set, there is an interrupt.
Hashed
If set, the received frame had a Destination Address that was accepted by the hash filter. If
Hashed and RxOK (Bit 8) are set, Bits F through A of RxEvent become the Hash Table Index
for this frame [See Section 5.3 on page 87 for an exception regarding broadcast frames!].If
Hashed and RxOK are not both set, then Bits F through A are individual event bits as defined
below.
IndividualAdr
If the received frame had a Destination Address which matched the Individual Address found
at PacketPage base + 0158h, then this bit is set if, and only if, RxOK (Bit 8) is set and IndividualA (Register 5, RxCTL, Bit A) is set.
Broadcast
If the received frame had a Broadcast Address (FFFF FFFF FFFFh) as the Destination Address, then this bit is set if, and only if, RxOK is set and BroadcastA (Register 5, RxCTL, Bit B)
is set.
CRCerror
If set, the received frame had a bad CRC. If CRCerroriE (Register 3, RxCFG, Bit C) is set, there
is an interrupt
Runt
If set, the received frame was shorter than 64 bytes. If RuntiE (Register 3, RxCFG, Bit D) is set,
there is an interrupt.
Extradata
If set, the received frame was longer than 1518 bytes. All bytes beyond 1518 are discarded. If
ExtradataiE (Register 3, RxCFG, Bit E) is set, there is an interrupt.
Reset value is: 0000 0000 0000 0100
Notes: 3. All RxEvent bits are cleared upon readout. The host is responsible for processing all event bits.
4. RxStatus register (PacketPage base + 0400h) is the same as the RxEvent register except RxStatus is
not cleared when RxEvent is read. See Section 5.2 on page 79. The value in the RxEvent register is
undefined when RxDMAOnly bit (Bit 9, Register 3, RxCFG) is set.
CIRRUS LOGIC PRODUCT DATA SHEET
54
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.8 Register 5: Receiver Control
(RxCTL, Read/Write, Address: PacketPage base +0104h)
7
PromiscuousA
6
IAHashA
5
F
E
ExtradataA
D
RuntA
4
3
2
1
0
A
IndividualA
9
MulticastA
8
RxOKA
000101
C
CRCerrorA
B
BroadcastA
RxCTL has two functions: Bits 8, C, D, and E define what types of frames to accept. Bits 6, 7, 9, A, and B configure
the Destination Address filter. See Section 5.3 on page 87.
000101
These bits provide an internal address used by the CS8900A to identify this as the Receiver
Control Register. For a received frame to be accepted, the Destination Address of that frame
must pass the filter criteria found in Bits 6, 7, 9, A, and B (see Section 5.3 on page 87).
IAHashA
When set, receive frames are accepted when the Destination Address is an Individual Address
that passes the hash filter.
PromiscuousA
Frames with any address are accepted when this bit is set.
RxOKA
When set, the CS8900A accepts frames with correct CRC and valid length (valid length is: 64
bytes <= length <= 1518 bytes).
MulticastA
When set, receive frames are accepted if the Destination Address is an Multicast Address that
passes the hash filter.
IndividualA
When set, receive frames are accepted if the Destination Address matches the Individual Address found at PacketPage base + 0158h to PacketPage base + 015Dh.
BroadcastA
When set, receive frames are accepted if the Destination Address is FFFF FFFF FFFFh.
CRCerrorA
When set, receive frames that pass the Destination Address filter, but have a bad CRC, are accepted. When clear, frames with bad CRC are discarded. See Note 5.
RuntA
When set, receive frames that are smaller than 64 bytes, and that pass the Destination Address
filter are accepted. When clear, received frames less that 64 bytes in length are discarded. The
CS8900A discards any frame that is less than 8 bytes. See Note 5.
ExtradataA
When set, receive frames longer than 1518 bytes and that pass the Destination Address filter
are accepted. The CS8900A accepts only the first 1518 bytes and ignores the rest. When clear,
frames longer than 1518 bytes are discarded. See Note 5.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 5.3 on page 87.
Reset value is: 0000 0000 0000 0101
Notes: 5. Typically, when bits CRCerrorA, RuntA and ExtradataA are cleared (meaning bad frames are being
discarded), then the corresponding bits CRCerroriE, RuntiE and ExtradataiE should be set in register 3
(Receiver Configuration register) to allow the device driver to keep track of discarded frames.
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
55
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.9 Register 7: Transmit Configuration
(TxCFG, Read/Write, Address: PacketPage base + 0106h)
7
SQE erroriE
6
Loss-of-CRSiE
5
F
16colliE
E
D
4
3
2
1
0
A
JabberiE
9
Out-of-window
8
TxOKiE
000111
C
B
AnycolliE
Each bit in TxCFG is an interrupt enable. When set, the interrupt is enabled as described below. When clear, there
is no interrupt.
000111
These bits provide an internal address used by the CS8900A to identify this as the Transmit
Configuration Register.
Loss-of-CRSiE
If the CS8900A starts transmitting on the AUI and does not see the Carrier Sense signal at the
end of the preamble, an interrupt is generated if this bit is set. Carrier Sense activity is reported
by the CRS bit (Register 14, LineST, Bit E).
SQErroriE
When set, an interrupt is generated if there is an SQE error. (At the end of a transmission on
the AUI, the CS8900A expects to see a collision within 64 bit times. If this does not happen,
there is an SQE error.)
TxOKiE
When set, an interrupt is generated if a packet is completely transmitted.
Out-of-windowiE
When set, an interrupt is generated if a late collision occurs (a late collision is a collision which
occurs after the first 512 bit times). When this occurs, the CS8900A forces a bad CRC and terminates the transmission.
JabberiE
When set, an interrupt is generated if a transmission is longer than approximately 26 ms.
AnycolliE
When set, if one or more collisions occur during the transmission of a packet, an interrupt occurs at the end of the transmission
16colliE
If the CS8900A encounters 16 normal collisions while attempting to transmit a particular packet,
the CS8900A stops attempting to transmit that packet. When this bit is set, there is an interrupt
upon detecting the 16th collision.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0000 0000 0111
Notes: Bit 8 (TxOKiE) and Bit B (AnycolliE) are interrupts for normal transmit operation. Bits 6, 7, 9, A, and FNotes:
are interrupts for abnormal transmit operation.
CIRRUS LOGIC PRODUCT DATA SHEET
56
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.10 Register 8: Transmitter Event
(TxEvent, Read-only, Address: PacketPage base + 0218h)
7
SQEerror
6
Loss-of-CRS
F
16coll
E
5
4
3
2
1
0
A
Jabber
9
Out-of-window
8
TxOK
001000
D
C
Number-of-Tx-collisions
B
TxEvent gives the event status of the last packet transmitted.
001000
These bits provide an internal address used by the CS8900A to identify this as the Transmitter
Event Register.
Loss-of-CRS
If the CS8900A is transmitting on the AUI and doesn’t see Carrier Sense (CRS) at the end of
the preamble, there is a Loss-of-Carrier error and this bit is set. If Loss-of-CRSiE (Register 7,
TxCFG, Bit 6) is set, there is an interrupt.
SQEerror
At the end of a transmission on the AUI, the CS8900A expects to see a collision within 64 bit
times. If this does not happen, there is an SQE error and this bit is set. If SQEerroriE (Register
7, TxCFG, Bit 7) is set, there is an interrupt.
TxOK
This bit is set if the last packet was completely transmitted (Jabber (Bit A), out-of-window-collision (Bit 9), and 16Coll (Bit F) must all be clear). If TxOKiE (Register 7, TxCFG, Bit 8) is set,
there is an interrupt.
Out-of-Window
This bit is set if a collision occurs more than 512 bit times after the first bit of the preamble. When
this occurs, the CS8900A forces a bad CRC and terminates the transmission. If Out-of-windowiE (Register 7, TxCFG, Bit 9) is set, there is an interrupt
Jabber
If the last transmission is longer than 26 msec, then the packet output is terminated by the jabber logic and this bit is set. If JabberiE (Register 7, TxCFG, Bit A) is set, there is an interrupt.
#-of-TX-collisions
These bits give the number of transmit collisions that occurred on the last transmitted packet.
Bit B is the LSB. If AnycolliE (Register 7, TxCFG, Bit B) is set, there is an interrupt when any
collision occurs.
16coll
This bit is set if the CS8900A encounters 16 normal collisions while attempting to transmit a
particular packet. When this happens, the CS8900A stops further attempts to send that packet.
If 16colliE (Register 7, TxCFG, Bit F) is set, there is an interrupt.
Reset value is:
Notes:
0000 0000 0000 1000
1.In any event register, like TxEvent, all bits are cleared upon readout. The host is responsible for
processing all event bits.
2.TxOK (Bit 8) and the Number-of-Tx-Collisions (Bits E-B) are used in normal packet transmission.All
other bits (6, 7, 9, A, and F) give the status of abnormal transmit operation.
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
57
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.11 Register 9: Transmit Command Status
(TxCMD, Read-only, Address: PacketPage base + 0108h)
7
6
5
4
3
TxStart
F
2
1
0
A
9
Onecoll
8
Force
001001
E
D
TxPadDis
C
InhibitCRC
B
This register contains the latest transmit command which tells the CS8900A how the next packet should be sent.
The command must be written to PacketPage base + 0144h in order to initiate a transmission. The host can read
the command from register 9 (PacketPage base + 0108h). See Section 5.7 on page 99.
001001
These bits provide an internal address used by the CS8900A to identify this as the Transmit
Command Register. When reading this register, these bits will be 001001, where the LSB corresponds to Bit 0.
TxStart
This pair of bits determines how many bytes are transferred to the CS8900A before the MAC
starts the packet transmit process.
Bit 7 Bit 6
0
0
Start transmission after 5 bytes are in the CS8900A
0
1
Start transmission after 381 bytes are in the CS8900A
1
0
Start transmission after 1021 bytes are in the CS8900A
1
1
Start transmission after the entire frame is in the CS8900A
Force
When set in conjunction with a new transmit command, any transmit frames waiting in the transmit buffer are deleted. If a previous packet has started transmission, that packet is terminated
within 64 bit times with a bad CRC.
Onecoll
When this bit is set, any transmission will be terminated after only one collision. When clear, the
CS8900A allows up to 16 normal collisions before terminating the transmission.
InhibitCRC
When set, the CRC is not appended to the transmission.
TxPadDis
When TxPadDis is clear, if the host gives a transmit length less than 60 bytes and InhibitCRC
is set, then the CS8900A pads to 60 bytes. If the host gives a transmit length less than 60 bytes
and InhibitCRC is clear, then the CS8900A pads to 60 bytes and appends the CRC.
When TxPadDis is set, the CS8900A allows the transmission of runt frames (a frame less than
64 bytes). If InhibitCRC is clear, the CS8900A appends the CRC. If InhibitCRC is set, the
CS8900A does not append the CRC
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Regster value is: 0000 0000 0000 1001
Notes: The CS8900A does not transmit a frame if TxLength < 3
CIRRUS LOGIC PRODUCT DATA SHEET
58
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.12 Register B: Buffer Configuration
(BufCFG, Read/Write, Address: PacketPage base + 010Ah)
7
RxDMAiE
6
SWint-X
5
F
RxDestiE
E
D
Miss OvfloiE
4
3
2
1
0
A
RxMissiE
9
TxUnder runtiE
8
Rdy4TxiE
001011
C
TxCol OvfloiE
B
Rx128iE
Each bit in BufCFG is an interrupt enable. When set, the interrupt described below is enabled. When clear, there is
no interrupt.
001011
These bits provide an internal address used by the CS8900A to identify this as the Buffer Configuration Register.
SWint-X
When set, there is an interrupt requested by the host software. The CS8900A provides the interrupt, and sets the SWint (Register C, BufEvent, Bit 6) bit. The CS8900A acts upon this command at once. SWint-X is an Act-Once bit. To generate another interrupt, rewrite a "1" to this bit.
RxDMAiE
When set, there is an interrupt when a frame has been received and DMA is complete. With
this interrupt, the RxDMAFrame bit (Register C, BufEvent, Bit 7) is set.
Rdy4TxiE
When set, there is an interrupt when the CS8900A is ready to accept a frame from the host for
transmission. (See Section 5.7 on page 99 for a description of the transmit bid process.)
TxUnderruniE
When set, there is an interrupt if the CS8900A runs out of data before it reaches the end of the
frame (called a transmit underrun). When this happens, event bit TXUnderrun (Register C,
BufEvent, Bit 9) is set and the CS8900A makes no further attempts to transmit that frame. If the
host still wants to transmit that particular frame, the host must go through the transmit request
process again.
RxMissiE
When set, there is an interrupt if one or more received frames is lost due to slow movement of
receive data out of the receive buffer (called a receive miss). When this happens, the RxMiss
bit (Register C, BufEvent, Bit A) is set.
Rx128iE
When set, there is an interrupt after the first 128 bytes of a frame have been received. This allows a host processor to examine the Destination Address, Source Address, Length, Sequence
Number, and other information before the entire frame is received. This interrupt should not be
used with DMA. Thus, if either AutoRxDMA (Register 3, RxCFG, Bit A) or RxDMAonly (Register
3, RxCFG, Bit 9) is set, the Rx128iE bit must be clear.
TxColOvfiE
If set, there is an interrupt when the TxCOL counter increments from 1FFh to 200h. (The TxCOL
counter (Register 18) is incremented whenever the CS8900A sees that the RXD+/RXD- pins
(10BASE-T) or the CI+/CI- pins (AUI) go active while a packet is being transmitted.)
MissOvfloiE
If MissOvfloiE is set, there is an interrupt when the RxMISS counter increments from 1FFh to
200h. (A receive miss is said to have occurred if packets are lost due to slow movement of receive data out of the receive buffers. When this happens, the RxMiss bit (Register C, BufEvent,
Bit A) is set, and the RxMISS counter (Register 10) is incremented.)
RxDestiE
When set, there is an interrupt when a receive frame passes the Destination Address filter criteria defined in the RxCTL register (Register 5). This bit provides an early indication of an incoming frame. It is earlier than Rx128 (Register C, BufEvent, Bit B). If RxDestiE is set, the
BufEvent could be RxDest or Rx128. After 128 bytes are received, the BufEvent changes from
RxDest to Rx128.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state after reset. If an
EEPROM is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0000 0000 1011
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
59
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.13 Register C: Buffer Event
(BufEvent, Read-only, Address: PacketPage base + 012Ch)
7
RxDMA frame
6
SWint
5
F
RxDest
E
D
4
3
2
1
0
A
RxMiss
9
TxUnder run
8
Rdy4Tx
001100
C
B
Rx128
BufEvent gives the status of the transmit and receive buffers.
001100
These bits provide an internal address used by the CS8900A to identify this as the Buffer Event
Register. When reading this register, these bits will be 001100, where the LSB corresponds to
Bit 0.
SWint
If set, there has been a software initiated interrupt. This bit is used in conjunction with the SWintX bit (Register B, BufCFG, Bit 6).
RxDMAFrame
If set, one or more received frames have been transferred by slave DMA. If RxDMAiE (Register
B, BufCFG, Bit 7) is set, there is an interrupt.
Rdy4Tx
If set, the CS8900A is ready to accept a frame from the host for transmission. If Rdy4TxiE (Register B, BufCFG, Bit 8) is set, there is an interrupt. (See Section 5.7 on page 99 for a description
of the transmit bid process.)
TxUnderrun
This bit is set if CS8900A runs out of data before it reaches the end of the frame (called a transmit underrun). If TxUnderruniE (Register B, BufCFG, Bit 9) is set, there is an interrupt.
RxMiss
If set, one or more receive frames have been lost due to slow movement of data out of the receive buffers. If RxMissiE (Register B, BufCFG, Bit A) is set, there is an interrupt.
Rx128
This bit is set after the first 128 bytes of an incoming frame have been received. This bit will
allow the host the option of preprocessing frame data before the entire frame is received. If
Rx128iE (Register B, BufCFG, Bit B) is set, there is an interrupt.
RxDest
When set, this bit shows that a receive frame has passed the Destination Address Filter criteria
as defined in the RxCTL register (Register 5). This bit is useful as an early indication of an incoming frame. It will be earlier than Rx128 (Register C, BufEvent, Bit B). If RxDestiE (Register
B, BufCFG, Bit F) is set, there is an interrupt.
Reset value is:
0000 0000 0000 1100
Notes: With any event register, like BufEvent, all bits are cleared upon readout. The host is responsible for
processing all event bits.
CIRRUS LOGIC PRODUCT DATA SHEET
60
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.14 Register 10: Receiver Miss Counter
(RxMISS, Read-only, Address: PacketPage base + 0130h)
7
6
5
4
3
MissCount
F
2
1
0
A
9
8
010000
E
D
C
B
MissCount
The RxMISS counter (Bits 6 through F) records the number of receive frames that are lost (missed) due to the lack
of available buffer space. If the MissOvfloiE bit (Register B, BufCFG, Bit D) is set, there is an interrupt when RxMISS
increments from 1FFh to 200h. This interrupt provides the host with an early warning that the RxMISS counter should
be read before it reaches 3FFh and starts over (by interrupting at 200h, the host has an additional 512 counts before
RxMISS actually overflows). The RxMISS counter is cleared when read.
010000
These bits provide an internal address used by the CS8900A to identify this as the Receiver
Miss Counter. When reading this register, these bits will be 010000, where the LSB corresponds to Bit 0.
MissCount
The upper ten bits contain the number of missed frames.
Register’s value is: 0000 0000 0001 0000
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
61
CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.15 Register 10: Transmit Collision Counter
(TxCOL, Read-only, Address: PacketPage base + 0132h)
7
6
5
4
3
ColCount
F
2
1
0
A
9
8
010010
E
D
C
B
ColCount
The TxCOL counter (Bits 6 through F) is incremented whenever the 10BASE-T Receive Pair (RXD+ / RXD-) or AUI
Collision Pair (CI+ / CI-) becomes active while a packet is being transmitted. If the TxColOvfiE bit (Register B,
BufCFG, Bit C) is set, there is an interrupt when TxCOL increments from 1FFh to 200h. This interrupt provides the
host with an early warning that the TxCOL counter should be read before it reaches 3FFh and starts over (by interrupting at 200h, the host has an additional 512 counts before TxCOL actually overflows). The TxCOL counter is
cleared when read.
010010
These bits provide an internal address used by the CS8900A to identify this as the Transmit
Collision Counter. When reading this register, these bits will be 010010, where the LSB corresponds to Bit 0.
ColCount
The upper ten bits contain the number of collisions.
Reset value is: 0000 0000 0001 0010
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Crystal LAN™ ISA Ethernet Controller
4.4.16 Register 13: Line Control
(LineCTL, Read/Write, Address: PacketPage base + 0112h)
7
SerTxOn
F
6
SerRxON
5
4
3
2
1
0
A
9
Auto AUI/10BT
8
AUIonly
010011
E
D
LoRx Squelch 2-part DefDis
C
PolarityDis
B
Mod BackoffE
LineCTL determines the configuration of the MAC engine and physical interface.
010011
These bits provide an internal address used by the CS8900A to identify this as the Line Control
Register.
SerRxON
When set, the receiver is enabled. When clear, no incoming packets pass through the receiver.
If SerRxON is cleared while a packet is being received, reception is completed and no subsequent receive packets are allowed until SerRxON is set again.
SerTxON
When set, the transmitter is enabled. When clear, no transmissions are allowed. If SerTxON is
cleared while a packet is being transmitted, transmission is completed and no subsequent
packets are transmitted until SerTxON is set again.
AUIonly
Bits 8 and 9 are used to select either the AUI or the 10BASE-T interface according to the following: [Note: 10BASE-T transmitter will be inactive even when selected unless link pulses are
detected or bit DisableLT (register 19) is set.
AUIonly (Bit 8)
AutoAUI/10BT (Bit 9)
1
0>
0
N/A
0
1
Physical Interface
AUI
10BASE-T
Auto-Select
AutoAUI/10BT
See AUIonly (Bit 8) description above.
ModBackoffE
When clear, the ISO/IEC standard backoff algorithm is used (see Section 3.9 on page 28).
When set, the Modified Backoff algorithm is used. (The Modified Backoff algorithm extends the
backoff delay after each of the first three Tx collisions.)
PolarityDis
The 10BASE-T receiver automatically determines the polarity of the received signal at the
RXD+/RXD- input (see Section 3.11 on page 35). When this bit is clear, the polarity is corrected, if necessary. When set, no effort is made to correct the polarity. This bit is independent of
the PolarityOK bit (Register 14, LineST, Bit C), which reports whether the polarity is normal or
reversed.
2-partDefDis
Before a transmission can begin, the CS8900A follows a deferral procedure. With the 2-partDefDis bit clear, the CS8900A uses the standard two-part deferral as defined in ISO/IEC 88023 paragraph 4.2.3.2.1. With the 2-partDefDis bit set, the two-part deferral is disabled.
LoRxSquelch
When clear, the 10BASE-T receiver squelch thresholds are set to levels defined by the ISO/IEC
8802-3 specification. When set, the thresholds are reduced by approximately 6dB. This is useful for operating with "quiet" cables that are longer than 100 meters.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0000 0001 0011
CIRRUS LOGIC PRODUCT DATA SHEET
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CS8900A
Crystal LAN™ ISA Ethernet Controller
4.4.17 Register 14: Line Status
(LineST, Read-only, Address: PacketPage base + 0134h)
7
LinkOK
6
F
E
CRS
5
4
3
2
1
0
A
9
10BT
8
AUI
010100
D
C
PolarityOK
B
LineST reports the status of the Ethernet physical interface.
010100
These bits provide an internal address used by the CS8900A to identify this as the Line Status
Register. When reading this register, these bits will be 010100, where the LSB corresponds to
Bit 0.
LinkOK
If set, the 10BASE-T link has not failed. When clear, the link has failed, either because the
CS8900A has just come out of reset, or because the receiver has not detected any activity (link
pulses or received packets) for at least 50 ms.
AUI
If set, the CS8900A is using the AUI.
10BT
If set, the CS8900A is using the 10BASE-T interface.
PolarityOK
If set, the polarity of the 10BASE-T receive signal (at the RXD+ / RXD- inputs) is correct. If clear,
the polarity is reversed. If PolarityDis (Register 13, LineCTL, Bit C) is clear, the polarity is automatically corrected, if needed. The PolarityOK status bit shows the true state of the incoming
polarity independent of the PolarityDis control bit. Thus, if PolarityDis is clear and PolarityOK is
clear, then the receive polarity is inverted, and corrected.
CRS
This bit tells the host the status of an incoming frame. If CRS is set, a frame is currently being
received. CRS remains asserted until the end of frame (EOF). At EOF, CRS goes inactive in
about 1.3 to 2.3 bit times after the last low-to-high transition of the recovered data.
Reset value is:
0000 0000 0001 0100
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Crystal LAN™ ISA Ethernet Controller
4.4.18 Register 15: Self Control
(SelfCTL, Read/Write, Address: PacketPage base + 0114h)
7
F
HCB1
6
RESET
5
E
HCB0
D
HC1E
4
3
2
1
0
A
HW Standby
9
HWSleepE
8
SW Suspend
010101
C
HC0E
B
SelfCTL controls the operation of the LED outputs and the lower-power modes.
010101
These bits provide an internal address used by the CS8900A to identify this as the Chip Self
Control Register.
RESET
When set, a chip-wide reset is initiated immediately. RESET is an Act-Once bit. This bit is
cleared as a result of the reset.
SWSuspend
When set, the CS8900A enters the software initiated Suspend mode. Upon entering this mode,
there is a partial reset. All registers and circuits are reset except for the ISA I/O Base Address
Register and the SelfCTL Register. There is no transmit nor receive activity in this mode. To
come out of software Suspend, the host issues an I/O Write within the CS8900A’s assigned I/O
space (see Section 3.7 on page 26 for a complete description of the CS8900A’s low-power
modes).
HWSleepE
When set, the SLEEP input pin is enabled. If SLEEP is high, the CS8900A is "awake", or operative (unless in SWSuspend mode, as shown above). If SLEEP is low, the CS8900A enters either the Hardware Standby or Hardware Suspend mode. When clear, the CS8900A ignores the
SLEEP input pin (see Section 3.7 on page 26 for a complete description of the CS8900A’s lowpower modes).
HWStandbyE
If HWSleepE is set and the SLEEP input pin is low, then when HWStandbyE is set, the
CS8900A enters the Hardware Standby mode. When clear, the CS8900A enters the Hardware
Suspend mode (see Section 3.7 on page 26 for a complete description of the CS8900A’s lowpower modes).
HC0E
The LINKLED or HC0 output pin is selected with this control bit. When HC0E is clear, the output
pin is LINKLED. When HC0E is set, the output pin is HC0 and the HCB0 bit (Bit E) controls the
pin.
HC1E
The BSTATUS or HC1 output pin is selected with this control bit. When HC1E is clear, the output pin is BSTATUS and indicates receiver ISA Bus activity. When HC1E is set, the output pin
is HC1 and the HCB1 bit (Bit F) controls the pin.
HCB0
When HC0E (Bit C) is set, this bit controls the HC0 pin. If HCB0 is set, HC0 is low. If HCB0 is
clear, HC0 is high. HC0 may drive an LED or a logic gate. When HC0E (Bit C) is clear, this control bit is ignored.
HCB1
When HC1E (Bit D) is set, this bit controls the HC1 pin. If HCB1 is set, HC1 is low. If HCB1 is
clear, HC1 is high. HC1 may drive an LED or a logic gate. When HC1E (Bit D) is clear, this control bit is ignored.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0000 0001 0101
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4.4.19 Register 16: Self Status
(SelfST, Read-only, Address: PacketPage base + 0136h)
7
INITD
6
3.3V Active
5
F
E
D
4
3
2
1
0
9
EEPROM
present
8
010110
C
B
A
EEsize
ELPresent
EEPROM OK
SIBUSY
SelfST reports the status of the EEPROM interface and the initialization process.
010110
These bits provide an internal address used by the CS8900A to identify this as the Chip Self
Status Register. When reading this register, these bits will be 010110, where the LSB corresponds to Bit 0.
3,3VActive
If the CS8900A is operating on a 3.3V supply, this bit is set. If the CS8900A is operating on a
5V supply, this bit is clear.
INITD
If set, the CS8900A initialization, including read-in of the EEPROM, is complete.
SIBUSY
If set, the EECS output pin is high indicating that the EEPROM is currently being read or programmed. The host must not write to PacketPage base + 0040h nor 0042h until SIBUSY is
clear.
EEPROMpresent
If the EEDataIn pin is low after reset, there is no EEPROM present, and the EEPROMpresent
bit is clear. If the EEDataIn pin is high after reset, the CS8900A "assumes" that an EEPROM
is present, and this bit is set.
EEPROMOK
If set, the checksum of the EEPROM readout was OK.
ELpresent
If set, external logic for Latchable Address bus decode is present.
EEsize
This bit shows the size of the attached EEPROM and is valid only if the EEPROMpresent bit
(Bit 9) and EEPROMOK bit (Bit A) are both set. If clear, the EEPROM size is either 128 words
(’C56 or ’CS56) or 256 words (C66 or ’CS66). If set, the EEPROM size is 64 words (’C46 or
’CS46).
Reset value is: 0000 0000 0001 0110
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Crystal LAN™ ISA Ethernet Controller
4.4.20 Register 17: Bus Control
(BusCTL, Read/Write, Address: PacketPage base + 0116h)
7
F
EnableIRQ
6
Reset RxDMA
5
E
D
RxDMA size
4
3
2
1
0
A
MemoryE
9
UseSA
8
DMAextend
010111
C
IOCH RDYE
B
DMABurst
BusCTL controls the operation of the ISA-bus interface.
010111
These bits provide an internal address used by the CS8900A to identify this as the Bus Control
Register.
ResetRxDMA
When set, the RxDMA offset pointer at PacketPage base + 0026h is reset to zero. When the
host sets this bit, the CS8900A does the following:
1.Terminates the current receive DMA activity, if any.
2.Clears all internal receive buffers.
3.Zeroes the RxDMA offset pointer.
DMAextend
When set, DMARQx goes inactive on the falling edge of IORN instead of the rising edge of
IORN-1. See Switching Characteristics, DMA Read, tDMAR5. Setting this bit also enables single
transfer mode DMA. Normal operation is demand mode DMA in which DMACKx cannot deassert until after DMARQx deasserts, i.e. until a full ethernet frame is transferred. Single transfer
mode allows DMACKx to deassert between each DMA read.
UseSA
When set, the MEMCS16 pin goes low whenever the address on SA bus [12..19] match the
CS8900A’s assigned Memory base address and the CHIPSEL pin is low (internal address decode).
When clear, MEMCS16 is driven low whenever CHIPSEL goes low. (external address decode).
see Section 4.9 on page 74.
For MEMCS16 pin to be enabled, the CS8900A must be in Memory Mode with the MemoryE
bit (Register 17, BusCTL, Bit A) set.
MemoryE
When set, the CS8900A may operate in Memory Mode. When clear, Memory Mode is disabled.
I/O Mode is always enabled.
DMABurst
When clear, the CS8900A performs continuous DMA until the receive frame is completely
transferred from the CS8900A to host memory. When set, each DMA access is limited to 28us,
after which time the CS8900A gives up the bus for 1.3us before making a new DMA request.
IOCHRDYE
When set, the CS8900A does not use the IOCHRDY output pin, and the pin is always high-impedance. This allows external pull-up to force the output high. When clear, the CS8900A drives
IOCHRDY low to request additional time during I/O Read and Memory Read cycles. IOCHRDY
does not affect I/O Write, Memory Write, nor DMA Read.
RxDMAsize
This bit determines the size of the receive DMA buffer (located in host memory). When set, the
DMA buffer size is 64 Kbytes. When clear, it is 16 Kbytes.
EnableRQ
When set, the CS8900A will generate an interrupt in response to an interrupt event
(Section 5.1). When cleared, the CS8900A will not generate any interrupts.
After reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM
is found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0000 0001 0111
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4.4.21 Register 18: Bus Status
(BusST, Read-only, Address: PacketPage base + 0138h)
7
TxBidErr
6
F
E
5
4
3
2
1
0
A
9
8
Rdy4Tx NOW
011000
D
C
B
BusST describes the status of the current transmit operation.
011000
These bits provide an internal address used by the CS8900A to identify this as the Bus Status
Register. When reading this register, these bits will be 011000, where the LSB corresponds to
Bit 0.
TxBidErr
If set, the host has commanded the CS8900A to transmit a frame that the CS8900A will not
send. Frames that the CS8900A will not send are:
1) Any frame greater than 1514 bytes, provided that InhibitCRC
(Register 9, TxCMD, Bit C) is clear.
2) Any frame greater than 1518 bytes.
Note that this bit is not set when transmit frames are too short.
Rdy4TxNOW
Rdy4TxNOW signals the host that the CS8900A is ready to accept a frame from the host for
transmission. This bit is similar to Rdy4Tx (Register C, BufEvent, Bit 8) except that there is no
interrupt associated with Rdy4TxNOW. The host can poll the CS8900A and check
Rdy4TxNOW to determine if the CS8900A is ready for transmit. (See Section 5.7 on page 99
for a description of the transmit bid process.)
Reset value is: 0000 0000 0001 1000
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Crystal LAN™ ISA Ethernet Controller
4.4.22 Register 19: Test Control
(TestCTL, Read/Write, Address: PacketPage base + 0118h)
7
DisableLT
6
F
E
5
4
3
2
1
0
A
9
8
AUIloop
ENDEC loop
011001
D
C
FDX
B
Disable Backoff
TestCTL controls the diagnostic test modes of the CS8900A.
011001
These bits provide an internal address used by the CS8900A to identify this as the Test Control
Register.
DisableLT
When set, the 10BASE-T interface allows packet transmission and reception regardless of the
link status. DisableLT is used in conjunction with the LinkOK (Register 14, LineST, Bit 7) as follows:
LinkOK
0
DisableLT
0
No packet transmission for reception
allowed. Transmitter sends link impulses.
0
1
DisableLT overrides LinkOK to allow packet
transmission and reception. Transmitter
does not send link pulses.
1
N/A
Disable has no meaning if LinkOK = 1.
ENDECloop
When set, the CS8900A enters internal loopback mode where the internal Manchester encoder
output is connected to the decoder input. The 10BASE-T and AUI transmitters and receivers
are disabled. When clear, the CS8900A is configured for normal operation.
AUIloop
When set, the CS8900A allows reception while transmitting. This facilitates loopback tests for
the AUI. When clear, the CS8900A is configured for normal AUI operation.
Disable Backoff
When set, the backoff algorithm is disabled. The CS8900A transmitter looks only for completion
of the inter packet gap before starting transmission. When clear, the backoff algorithm is used.
FDX
When set, 10BASE-T full duplex mode is enabled and CRS (Register 14, LineST, Bit E) is ignored. This bit must be set when performing loopback tests on the 10BASE-T port. When clear,
the CS8900A is configured for standard half-duplex 10BASE-T operation.
At reset, if no EEPROM is found by the CS8900A, then the register has the following initial state. If an EEPROM is
found, then the register’s initial value may be set by the EEPROM. See Section 3.3 on page 19.
Reset value is: 0000 0000 0001 1001
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4.4.23 Register 1C: AUI Time Domain Reflectometer
(Read-only, Address: PacketPage base + 013Ch)
7
6
5
4
3
AUI Delay
F
2
1
0
A
9
8
011100
E
D
C
B
AUI Delay
The TDR counter (Bits 6 through F) is a time domain reflectometer useful in locating cable faults in 10BASE-2 and
10BASE-5 coax networks. It counts at a 10 MHz rate from the beginning of transmission on the AUI to when a collision or Loss-of-Carrier error occurs. The TDR counter is cleared when read.
011100
These bits provide an internal address used by the CS8900A to identify this as the Bus Status
Register. When reading this register, these bits will be 011100, where the LSB corresponds to
Bit 0.
AUI-Delay
The upper ten bits contains the number of 10 MHz clock periods between the beginning of
transmission on the AUI to when a collision or Loss-of-Carrier error occurs.
Reset value is: 0000 0000 0001 1100
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Crystal LAN™ ISA Ethernet Controller
4.5 Initiate Transmit Registers
4.5.1 Transmit Command Request - TxCMD
(Write-only, Address: PacketPage base + 0144h)
7
6
5
4
3
TxStart
F
2
1
0
A
9
Onecoll
8
Force
001001
E
D
TxPadDis
C
InhibitCRC
B
The word written to PacketPage base + 0144h tells the CS8900A how the next packet should be transmitted. This
PacketPage location is write-only, and the written word can be read from Register 9, at PacketPage base + 0108h.
The CS8900A does not transmit a frame if TxLength (at PacketPage location base + 0146h) is less than 3. See
Section 5.7 on page 99.
001001
These bits provide an internal address used by the CS8900A to identify this as the Transmit
Command Register. When reading this register, these bits will be 001001, where the LSB corresponds to Bit 0.
TxStart
This pair of bits determines how many bytes are transferred to the CS8900A before the MAC
starts the packet transmit process.
Bit 7
0
0
1
1
Bit 6
0
1
0
1
Start transmission after 5 bytes are in the CS8900A
Start transmission after 381 bytes are in the CS8900A
Start transmission after 1021 bytes are in the CS8900A
Start transmission after the entire frame is in the CS8900A
Force
When set in conjunction with a new transmit command, any transmit frames waiting in the transmit buffer are deleted. If a previous packet has started transmission, that packet is terminated
within 64 bit times with a bad CRC.
Onecoll
When this bit is set, any transmission will be terminated after only one collision. When clear, the
CS8900A allows up to 16 normal collisions before terminating the transmission.
InhibitCRC
When set, the CRC is not appended to the transmission.
TxPadDis
When TxPadDis is clear, if the host gives a transmit length less than 60 bytes and InhibitCRC
is set, then the CS8900A pads to 60 bytes. If the host gives a transmit length less than 60 bytes
and InhibitCRC is clear, then the CS8900A pads to 60 bytes and appends the CRC.
When TxPadDis is set, the CS8900A allows the transmission of runt frames (a frame less than
64 bytes). If InhibitCRC is clear, the CS8900A appends the CRC. If InhibitCRC is set, the
CS8900A does not append the CRC.
Since this register is write-only, it’s initial state after reset is undefined.
4.5.2 Transmit Length
(Write-only, Address: PacketPage base + 0146h)
Address 0147h
Most-significant byte of Transmit Frame Length
Address 0146h
Least-significant byte of Transmit Frame Length
This register is used in conjunction with register 9, TxCMD. When a transmission is initiated via a command in TxCMD, the the length of the transmitted frame is written into this register. The length of the transmitted frame may be
modified by the configuration of the TxPadDis and InhibitCRC bits in the TxCMD register. See Table 35, and
Section 5.7 on page 99. TxLength must be >3 and < 1519.
Since this register is write-only, it’s initial state after reset is undefined.
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4.6 Address Filter Registers
4.6.1 Logical Address Filter (hash table)
(Read/Write, Address: PacketPage base + 0150h)
Address 0157h Address 0156h Address 0155h Address 0154h Address 0153h Address 0152h Address 0151h Address 0150h
Most-signifiLeast-significant byte of
cant byte of
hash filter.
hash filter.
The CS8900A hashing decoder circuitry compares its output with one bit of the Logical Address Filter Register. If
the decoder output and the Logical Address Filter bit match, the frame passes the hash filter and the Hashed bit
(Register 4, RxEvent, Bit 9) is set. See Section 5.3 on page 87.
Reset value is: 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000
4.6.2 Individual Address (IEEE address)
(Read/Write, Address: PacketPage base + 0158h)
Address 0015Dh
Octet 5 of IA
Address 0015Ch
Address 0015Bh
Address 0015Ah
Address 0159h
Address 00158h
Octet 0 of IA
The unique, IEEE 48-bit Individual Address (IA) begins at 0158h. The first bit of the IA (Bit IA[00]) must be "0". See
Section 5.3 on page 87.
The value of this register must be loaded from external storage, for example, from the EEPROM. See Section 3.3
on page 19. If the CS8900A is not able to load the IA from the EEPROM, then after a reset this register is undefined,
and the driver must write an address to this register.
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4.7 Receive and Transmit Frame Locations
The Receive and Transmit Frame PacketPage locations are used to transfer Ethernet frames to and
from the host. The host sequentially writes to and
reads from these locations, and internal buffer
memory is dynamically allocated between transmit
and receive as needed. One receive frame and one
transmit frame are accessible at a time.
4.7.1 Receive PacketPage Locations
In IO mode, the receive status/length/frame locations are read through repetitive reads from one IO
port at the IO base address. See Section 4.10 on
page 76.
In memory mode, the receive status/length/frame
locations are read using memory reads of a block of
memory starting at memory base address + 0400h.
Typically the memory locations are read sequentially using repetitive Move instructions (REP
MOVS). See Section 4.9 on page 74.
Random access is not needed. However, the first
118 bytes of the receive frame can be accessed randomly if word reads, on even word boundaries, are
used. Beyond 118 bytes, the memory reads must be
sequential. Byte reads, or reads on odd-word
boundaries, can be performed only in sequential
read mode. See Section 4.8 on page 73.
The RxStatus word reports the status of the current
received frame. RxEvent register 4 (PacketPage
base + 0124h) has the same contents as the RxStatus register, except RxEvent is cleared when RxEvent is read.
The RxLength (receive length) word is the length,
in bytes, of the data to be transferred to the host
across the ISA bus. The register describes the
length from the start of Destination Address to the
end of CRC, assuming that CRC has been selected
(via Register 3 RxCFG, bit BufferCRC). If CRC
has not been selected, then the length does not include the CRC, and the CRC is not present in the
receive buffer.
After the RxLength has been read, the receive
frame can be read. When some portion of the frame
is read, the entire frame should be read before reading the RxEvent register either directly or through
the ISQ register. Reading the RxEvent register signals to the CS8900A that the host is finished with
the current frame, and wants to start processing the
next frame. In this case, the current frame will no
longer be accessible to the host. The current frame
will also become inaccessible if a Skip command is
issued, or if the entire frame has been read. See
Section 5.2 on page 79.
4.7.2 Transmit Locations
The host can write frames into the CS8900A buffer
using Memory writes using REP MOVS to the TxFrame location. See Section 5.7 on page 99.
4.8 Eight and Sixteen Bit Transfers
A data transfer to or from the CS8900A can be
done in either I/O or Memory space, and can be either 16 bits wide (word transfers) or 8 bits wide
(byte transfers). Because the CS8900A’s internal
architecture is based on a 16-bit data bus, word
transfers are the most efficient.
To transfer transmit frames to the CS8900A and receive frames from the CS8900A, the host may mix
word and byte transfers, provided it follows three
rules:
1) The primary method used to access CS8900A
memory is word access.
2) Word accesses to the CS8900A’s internal
memory are kept on even-byte boundaries.
3) When switching from byte accesses to word accesses, a byte access to an even byte address
must be followed by a byte access to an oddbyte address before the host may execute a
word access (this will realign the word transfers
to even-byte boundaries). On the other hand, a
byte access to an odd-byte address may be followed by a word access.
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Failure to observe these three rules may cause data
corruption.
all of the CS8900A’s registers can be accessed directly.
4.8.1 Transferring Odd-Byte-Aligned Data
Some applications gather transmit data from more
than one section of host memory. The boundary between the various memory locations may be either
even- or odd-byte aligned. When such a boundary
is odd-byte aligned, the host should transfer the last
byte of the first block to an even address, followed
by the first byte of the second block to the following odd address. It can then resume word transfers.
An example of this is shown in Figure 17.
In Memory Mode, the CS8900A supports Standard
or Ready Bus cycles without introducing additional
wait states.
Memory moves can use MOVD (double-word
transfers) as long as the CS8900A’s memory base
address is on a double word boundary. Since 286
processors don’t support the MOVD instruction,
word and byte transfers must be used with a 286.
Description Mnemonic Read/Write
RxStatus
Read-only
Location:
PocketPage
base +
0400h-0401h
RxLength
Read-only
0402h-0403h
RxFrame
Read-only starts at 0404h
TxFrame
Write-only starts at 0A00h
Word Transfer
Receive
Status
Receive
Length
Receive
Frame
Transmit
Frame
First Block of Data
Word Transfer
Word Transfer
Byte Transfer
Byte Transfer
Word Transfer
Word Transfer
Second Block of Data
Table 16. Receive/Transmit Memory Locations
Word Transfer
Figure 17. Odd-Byte Aligned Data
4.8.2 Random Access to CS8900A Memory
The first 118 bytes of a receive frame held in the
CS8900A’s on-chip memory may be randomly accessed in Memory mode. After the first 118 bytes,
only sequential access of received data is allowed.
Either byte or word access is permitted, as long as
all word accesses are executed to even-byte boundaries.
4.9 Memory Mode Operation
To configure the CS8900A for Memory Mode, the
PacketPage memory must be mapped into a contiguous 4-kbyte block of host memory. The block
must start at an X000h boundary, with the PacketPage base address mapped to X000h. When the
CS8900A comes out of reset, its default configuration is I/O Mode. Once Memory Mode is selected,
4.9.1 Accesses in Memory Mode
The CS8900A allows Read/Write access to the internal PacketPage memory, and Read access of the
optional Boot PROM. (See Section 3.7 on page 26
for a description of the optional Boot PROM.)
A memory access occurs when all of the following
are true:
•
The address on the ISA System Address bus
(SA0 - SA19) is within the Memory space
range of the CS8900A or Boot PROM.
•
The CHIPSEL input pin is low.
•
Either the MEMR pin or the MEMW pin is low.
4.9.2 Configuring the CS8900A for Memory
Mode
There are two different methods of configuring the
CS8900A for Memory Mode operation. One method allows the CS8900A's internal memory to be
mapped anywhere within the host system's 24-bit
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memory space. The other method limits memory
mapping to the first 1 Mbyte of host memory space.
•
the ISA-bus SMEMW signal must be connected to the MEMW pin;
General Memory Mode Operation: Configuring the
CS8900A so that its internal memory can be
mapped anywhere within host Memory space requires the following:
•
the host must write the memory base address
into the Memory Base Address register (PacketPage base + 002Ch);
•
the host must set the MemoryE bit (Register 17,
BusCTL, Bit A); and
•
the host must clear the UseSA bit (Register 17,
BusCTL, Bit 9).
•
•
a simple circuit must be added to decode the
Latchable Address bus (LA20 - LA23) and the
BALE signal.
the host must configure the external logic with
the correct address range as follows:
1) Check to see if the INITD bit (Register 16,
SelfST, bit 7) is set, indicating that initialization is complete.
2) Check to see if the ELpresent bit (Register
16, SelfST, bit B) is set. This bit indicates
that external logic for the LA bus decode is
present.
3) Set the ELSEL bit of the EEPROM Command Register to activate the ELCS pin for
use with the external decode circuit.
4) Configure the external logic serially.
•
the host must write the memory base address
into the Memory Base Address register (PacketPage base + 002Ch);
•
the host must set the MemoryE bit (Register 17,
BusCTL, Bit A); and
•
the host must set the UseSA bit (Register 17,
BusCTL, Bit 9).
Limiting Memory Mode to the First 1 Mbyte of
Host Memory Space: Configuring the CS8900A so
that its internal memory can be mapped only within
the first 1 Mbyte of host memory space requires the
following:
•
the CHIPSEL pin must be tied low;
•
the ISA-bus SMEMR signal must be connected
to the MEMR pin;
4.9.3 Basic Memory Mode Transmit
Memory Mode transmit operations occur in the following order (using interrupts):
1) The host bids for storage of the frame by writing the Transmit Command to the TxCMD register (memory base + 0144h) and the transmit
frame length to the TxLength register (memory
base + 0146h). If the transmit length is erroneous, the command is discarded and the TxBidErr bit (Register 18, BusST, Bit 7) is set.
2) The host reads the BusST register (Register 18,
memory base + 0138h). If the Rdy4TxNOW bit
(Bit 8) is set, the frame can be written. If clear,
the host must wait for CS8900A buffer memory
to become available. If Rdy4TxiE (Register B,
BufCFG, Bit 8) is set, the host will be interrupted when Rdy4Tx (Register C, BufEvent, Bit 8)
becomes set.
3) Once the CS8900A is ready to accept the
frame, the host executes repetitive memory-tomemory move instructions (REP MOVS) to
memory base + 0A00h to transfer the entire
frame from host memory to CS8900A memory.
For a more detailed description of transmit, see
Section 5.7 on page 99.
4.9.4 Basic Memory Mode Receive
Memory Mode receive operations occur in the following order (interrupts used to signal the presence
of a valid receive frame):
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1) A frame is received by the CS8900A, triggering
an enabled interrupt.
2) The host reads the Interrupt Status Queue
(memory base + 0120h) and is informed of the
receive frame.
3) The host reads RxStatus (memory base +
0400h) to learn the status of the receive frame.
4) The host reads RxLength (memory base +
0402h) to learn the frame’s length.
5) The host reads the frame data by executing repetitive memory-to-memory move instructions
(REP MOVS) from memory base + 0404h to
transfer the entire frame from CS8900A memory to host memory.
For a more detailed description of receive, see
Section 5.2 on page 79.
4.9.5 Polling the CS8900A in Memory Mode
If interrupts are not used, the host can poll the
CS8900A to check if receive frames are present
and if memory space is available for transmit.
However, this is beyond the scope of this data
sheet.
4.10 I/O Space Operation
In I/O Mode, PacketPage memory is accessed
through eight 16-bit I/O ports that are mapped into
16 contiguous I/O locations in the host system’s I/O
space. I/O Mode is the default configuration for the
CS8900A and is always enabled. On power up, the
default value of the I/O base address is set at 300h.
(Note that 300h is typically assigned to LAN peripherals). The I/O base address may be changed to
any available XXX0h location, either by loading
configuration data from the EEPROM, or during
system setup. Table 17 shows the CS8900A I/O
Mode mapping.
Offset
Type
Description
0000h Read/Write Receive/Transmit Data (Port 0)
0002h Read/Write Receive/Transmit Data (Port 1)
Table 17. I/O Mode Mapping
Offset
Type
0004h Write-only
0006h Write-only
0008h Read-only
000Ah Read/Write
000Ch Read/Write
000Eh Read/Write
Description
TxCMD (Transmit Command)
TxLength (Transmit Length)
Interrupt Status Queue
PacketPage Pointer
PacketPage Data (Port 0)
PacketPage Data (Port 1)
Table 17. I/O Mode Mapping
4.10.1 Receive/Transmit Data Ports 0 and 1
These two ports are used when transferring transmit data to the CS8900A and receive data from the
CS8900A. Port 0 is used for 16-bit operations and
Ports 0 and 1 are used for 32-bit operations (lowerorder word in Port 0).
4.10.2 TxCMD Port
The host writes the Transmit Command (TxCMD)
to this port at the start of each transmit operation.
The Transmit Command tells the CS8900A that the
host has a frame to be transmitted, as well as how
that frame should be transmitted. This port is
mapped into PacketPage base + 0144h. See Register 9 in Section 4.4 on page 47 for more information.
4.10.3 TxLength Port
The length of the frame to be transmitted is written
here immediately after the Transmit Command is
written. This port is mapped into PacketPage base
+ 0146h.
4.10.4 Interrupt Status Queue Port
This port contains the current value of the Interrupt
Status Queue (ISQ). The ISQ is located at PacketPage base + 0120h. For a more detailed description of the ISQ, see Section 5.1 on page 79.
4.10.5 PacketPage Pointer Port
The PacketPage Pointer Port is written whenever
the host wishes to access any of the CS8900A’s internal registers. The first 12 bits (bits 0 through B)
provide the internal address of the target register to
be accessed during the current operation. The next
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three bits (C, D, and E) are read-only and will always read as 011b. Any convenient value may be
written to these bits when writing to the PacketPage
Pointer Port. The last bit (Bit F) indicates whether
or not the PacketPage Pointer should be auto-incremented to the next word location. Figure 18 shows
the structure of the PacketPage Pointer.
I/O base + 000Bh
I/O base + 000Ah
F E D C B A 9 8 7 6 5 4 3 2 1 0
PacketPage Register Address
Bit F: 0 = Pointer remains fixed
1 = Auto-Increments to next word location
Figure 18. PacketPage Pointer
4.10.6 PacketPage Data Ports 0 and 1
The PacketPage Data Ports are used to transfer data
to and from any of the CS8900A’s internal registers. Port 0 is used for 16-bit operations and Port 0
and 1 are used for 32-bit operations (lower-order
word in Port 0).
4.10.7 I/O Mode Operation
For an I/O Read or Write operation, the AEN pin
must be low, and the 16-bit I/O address on the ISA
System Address bus (SA0 - SA15) must match the
address space of the CS8900A. For a Read, the IOR
pin must be low, and for a Write, the IOW pin must
be low.
Note: The ISA Latchable Address Bus (LA17 LA23) is not needed for applications that use only
I/O Mode and Receive DMA operation.
4.10.8 Basic I/O Mode Transmit
I/O Mode transmit operations occur in the following order (using interrupts):
1) The host bids for storage of the frame by writing the Transmit Command to the TxCMD Port
(I/O base + 0004h) and the transmit frame
length to the TxLength Port (I/O base + 0006h).
2) The host reads the BusST register (Register 18)
to see if the Rdy4TxNOW bit (Bit 8) is set. To
read the BusST register, the host must first set
the PacketPage Pointer at the correct location
by writing 0138h to the PacketPage Pointer
Port (I/O base + 000Ah). It can then read the
BusST register from the PacketPage Data Port
(I/O base + 000Ch). If Rdy4TxNOW is set, the
frame can be written. If clear, the host must
wait for CS8900A buffer memory to become
available. If Rdy4TxiE (Register B, BufCFG,
Bit 8) is set, the host will be interrupted when
Rdy4Tx (Register C, BufEvent, Bit 8) becomes
set. If the TxBidErr bit (Register 18, BusST, Bit
7) is set, the transmit length is not valid.
3) Once the CS8900A is ready to accept the
frame, the host executes repetitive write instructions (REP OUT) to the Receive/Transmit
Data Port (I/O base + 0000h) to transfer the entire frame from host memory to CS8900A
memory.
For a more detailed description of transmit, see
Section 5.7 on page 99.
4.10.9 Basic I/O Mode Receive
I/O Mode receive operations occur in the following
order (In this example, interrupts are enabled to
signal the presence of a valid receive frame):
1) A frame is received by the CS8900A, triggering
an enabled interrupt.
2) The host reads the Interrupt Status Queue Port
(I/O base + 0008h) and is informed of the receive frame.
3) The host reads the frame data by executing repetitive read instructions (REP IN) from the
Receive/Transmit Data Port (I/O base + 0000h)
to transfer the frame from CS8900A memory to
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host memory. Preceding the frame data are the
contents of the RxStatus register (PacketPage
base + 0400h) and the RxLength register (PacketPage base + 0402h).
For a more detailed description of receive, see
Section 5.2 on page 79.
4.10.10 Accessing Internal Registers
To access any of the CS8900A’s internal registers
in I/O Mode, the host must first setup the PacketPage Pointer. It does this by writing the PacketPage address of the target register to the
PacketPage Pointer Port (I/O base + 000Ah). The
contents of the target register is then mapped into
the PacketPage Data Port (I/O base + 000Ch).
If the host needs to access a sequential block of registers, the MSB of the PacketPage address of the
first word to be accessed should be set to "1". The
PacketPage Pointer will then move to the next word
location automatically, eliminating the need to setup the PacketPage Pointer between successive accesses (see Figure 18).
4.10.11 Polling the CS8900A in I/O Mode
If interrupts are not used, the host can poll the
CS8900A to check if receive frames are present
and if memory space is available for transmit.
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5.0 OPERATION
5.1 Managing Interrupts and Servicing the
Interrupt Status Queue
The Interrupt Status Queue (ISQ) is used by the
CS8900A to communicate Event reports to the host
processor. Whenever an event occurs that triggers
an enabled interrupt, the CS8900A sets the appropriate bit(s) in one of five registers, maps the contents of that register to the ISQ, and drives the
selected interrupt request pin high (if an earlier interrupt is waiting in the queue, the interrupt request
pin will already be high). When the host services
the interrupt, it must first read the ISQ to learn the
nature of the interrupt. It can then process the interrupt (the first read to the ISQ causes the interrupt
request pin to go low.)
Three of the registers mapped to the ISQ are event
registers: RxEvent (Register 4), TxEvent (Register
8), and BufEvent (Register C). The other two registers are counter-overflow reports: RxMISS (Register 10) and TxCOL (Register 12). There may be
more than one RxEvent report and/or more than
one TxEvent report in the ISQ at a time. However,
there may be only one BufEvent report, one RxMISS report and one TxCOL report in the ISQ at a
time.
Event reports stored in the ISQ are read out in the
order of priority, with RxEvent first, followed by
TxEvent, BufEvent, RxMiss, and then TxCOL.
The host only needs to read from one location to get
the interrupt currently at the front of the queue. In
Memory Mode, the ISQ is located at PacketPage
base + 0120h. In I/O Mode, it is located at I/O base
+ 0008h. Each time the host reads the ISQ, the bits
in the corresponding register are cleared and the
next report in the queue moves to the front.
When the host starts reading the ISQ, it must read
and process all Event reports in the queue. A readout of a null word (0000h) indicates that all interrupts have been read.
The ISQ is read as a 16-bit word. The lower six bits
(0 through 5) contain the register number (4, 8, C,
10, or 12). The upper ten bits (6 through F) contain
the register contents. The host must always read the
entire 16-bit word.
The active interrupt pin (INTRQx) is selected via
the Interrupt Number register (PacketPage base +
22h). As an additional option, all of the interrupt
pins can be 3-Stated using the same register. see
Section 4.3 on page 42.
An event triggers an interrupt only when the EnableIRQ bit of the Bus Control register (bit F of
register 17) is set. After the CS8900A has generated an interrupt, the first read of the ISQ makes the
INTRQ output pin go low (inactive). INTRQ remains low until the null word (0000h) is read from
the ISQ, or for 1.6us, whichever is longer.
5.2 Basic Receive Operation
5.2.0.1 Overview
Once an incoming packet has passed through the
analog front end and Manchester decoder, it goes
through the following three-step receive process:
1) Pre-Processing
2) Temporary Buffering
3) Transfer to Host
Figure 20 shows the steps in frame reception.
As shown in the figure, all receive frames go
through the same pre-processing and temporary
buffering phases, regardless of transfer method
Once a frame has been pre-processed and buffered,
it can be accessed by the host in either Memory or
I/O space. In addition, the CS8900A can transfer
receive frames to host memory via host DMA. This
section describes receive frame pre-processing and
Memory and I/O space receive operation.
Section 5.4 on page 90 through Section 5.5 on
page 93 describe DMA operation.
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An enabled interrupt occurs.
The selected interrupt
request pin is driven high
(active) if not already high.
The host reads the ISQ.
The selected interrupt
request pin is driven low.
EXIT.
Interrupts
re-enabled.
(Interrupts
will be
disabled
for at least
1.6 us.)
Yes
ISQ = 0000h?
No
Which
Event
report
type?
RxEvent
Process applicable
RxEvent bits: Extradata,
Runt, CRCerror, RxOK.
TxEvent
Process applicable
TxEvent bits: 16coll, Jabber,
Out-of-window, TxOK.
BufEvent
Process applicable BufEvent
bits: RxDest, Rx128, RxMiss,
TxUnderrun, Rdy4Tx,
RxDMAFrame, SWint.
RxMISS
TxCOL
Process RxMISS counter.
Process TxCOL counter.
None of the above
Service
Default
Figure 19. Interrupt Status Queue
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Packet Received
Preamble and
Start-of-Frame
Delimiter Removed
Frame PreProcessed
Frame
Temporarily
Buffered
No
Use
DMA?
Yes
Frame Held
On Chip
Frame DMAed
to Host Memory
Host Reads
Frame from
CS8900A Memory
Host Reads
Frame from
Host Memory
Figure 20. Frame Reception
5.2.1 Terminology: Packet, Frame, and Transfer
The terms Packet, Frame, and Transfer are used extensively in the following sections. They are defined below for clarity:
5.2.1.1 Packet
The term "packet" refers to the entire serial string
of bits transmitted over an Ethernet network. This
includes the preamble, Start-of-Frame Delimiter
(SFD), Destination Address (DA), Source Address
(SA), Length field, Data field, pad bits (if necessary), and Frame Check Sequence (FCS, also
called CRC). Figure 9 shows the format of a packet.
5.2.1.2 Frame
The term "frame" refers to the portion of a packet
from the DA to the FCS. This includes the Destina-
tion Address (DA), Source Address (SA), Length
field, Data field, pad bits (if necessary), and Frame
Check Sequence (FCS, also called CRC). Figure 9
shows the format of a frame. The term "frame data"
refers to all the data from the DA to the FCS that is
to be transmitted, or that has been received.
5.2.1.3 Transfer
The term "transfer" refers to moving data across the
ISA bus, to and from the CS8900A. During receive
operations, only frame data are transferred from the
CS8900A to the host (the preamble and SFD are
stripped off by the CS8900A’s MAC engine). The
FCS may or may not be transferred, depending on
the configuration. All transfers to and from the
CS8900A are counted in bytes, but may be padded
for double word alignment.
5.2.2 Receive Configuration
After each reset, the CS8900A must be configured
for receive operation. This can be done automatically using an attached EEPROM or by writing
configuration commands to the CS8900A’s internal
registers (see Section 3.4 on page 21). The items
that must be configured include:
•
which physical interface to use;
•
which types of frames to accept;
•
which receive events cause interrupts; and,
•
how received frames are transferred.
5.2.2.1 Configuring the Physical Interface
Configuring the physical interface consists of determining which Ethernet interface should be active, and enabling the receive logic for serial
reception. This is done via the LineCTL register
(Register 13) and is described in Table18.
5.2.2.2 Choosing which Frame Types to Accept
The RxCTL register (Register 5) is used to determine which frame types will be accepted by the
CS8900A (a receive frame is said to be "accepted"
when the frame is buffered, either on chip or in host
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Register 13, LineCTL
Bit
6
8
Bit Name
SerRxON
AUIonly
Operation
When set, reception enabled.
When set, AUI selected (takes
precedence over AutoAUI/10BT).
9 AutoAUI/10BT When set, automatic interface
selection enabled. When both bits
8 and 9 are clear, 10BASE-T
selected.
E LoRx Squelch When set, receiver squelch level
reduced by approximately 6 dB.
Table 18. Physical Interface Configuration
memory via DMA). Table 19 describes the configuration bits in this register. Refer to Section 5.3 on
page 87 for a detailed description of Destination
Address filtering.
Register 5, LRxCTL
Bit Bit Name
Operation
6
IAHashA When set, Individual Address frames
that pass the hash filter are
accepted*.
7
Promis When set, all frames are accepted*.
cuousA
8
RxOKA When set, frames with valid length
and CRC and that pass the DA filter
are accepted.
9 MulticastA When set, Multicast frames that pass
the hash filter are accepted*.
A IndividualA When set, frames with DA that
matches the IA at PacketPage base
+ 0158h are accepted*.
B
Broad- When set, all broadcast frames are
castA
accepted*.
C CRCerrorA When set, frames with bad CRC that
pass the DA filter are accepted.
D
RuntA
When set, frames shorter than 64
bytes that pass the DA filter are
accepted.
E ExtradataA When set, frames longer than 1518
bytes that pass the DA filter are
accepted (only the first 1518 bytes
are buffered).
* Must also meet the criteria programmed into bits 8, C, D,
and E.
Table 19. Frame Acceptance Criteria
5.2.2.3 Selecting which Events Cause Interrupts
The RxCFG register (Register 3) and the BufCFG
register (Register B) are used to determine which
receive events will cause interrupts to the host processor. Table 21 describes the interrupt enable (iE)
bits in these registers.
Register 3, RxCFG
Bit
8
Bit Name
Operation
RxOKiE When set, there is an interrupt if a
frame is received with valid length
and CRC*.
C CRCerroriE When set, there is an interrupt if a
frame is received with bad CRC*.
D
RuntiE
When set, there is an interrupt if a
frame is received that is shorter than
64 bytes*.
E ExtradataiE When set, there is an interrupt if a
frame is received that is longer than
1518 bytes*.
* Must also pass the DA filter before there is an interrupt.
Table 20.
Register B, BufCFG
Bit
7
A
B
D
F
Bit Name
Operation
RxDMAiE When set, there is an interrupt if
one or more frames are transferred via DMA.
RxMissiE When set, there is an interrupt if a
frame is missed due to insufficient
receive buffer space.
Rx128iE When set, there is an interrupt
after the first 128 bytes of receive
data have been buffered.
MissOvfloiE When set, there is an interrupt if
the RxMISS counter overflows.
RxDestiE When set, there is an interrupt
after the DA of an incoming frame
has been buffered.
Table 21. Registers 3 and B Interrupt Configuration
5.2.2.4 Choosing How to Transfer Frames
The RxCFG register (Register 3) and the BusCTL
register (Register 17) are used to determine how
frames will be transferred to host memory, as described in Table 22.
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Register 3, RxCFG
Bit
7
9
A
B
Receive Frame
Bit Name
StreamE
Operation
When set, Stream Transfer
enabled.
RxDMAonly
When set, DMA slave operation used for all receive
frames.
AutoRX DMAE When set, Auto-Switch DMA
enabled.
BufferCRC
When set, the received CRC
is buffered.
Destination
Address Filter
Check:
- PromiscuousA?
- IAHashA?
- MulticastA?
- IndividualA?
- BroadcastA?
Register 17, BusCTL
Bit
B
D
Bit Name
DMABurst
RxDMAsize
Pass
DA Filter?
Operation
When set, DMA operations
hold the bus for up to approximately 28 µs. When clear,
DMA operations are continuous.
When set, DMA buffer size is
64 Kbytes. When clear, DMA
buffer size is 16 Kbytes.
Generate Early
Interrupts if Enabled
(see next figure)
Acceptance Filter
Check:
- RxOKA?
- ExtradataA?
- RuntA?
- CRCerrorA?
5.2.3 Receive Frame Pre-Processing
The CS8900A pre-processes all receive frames using a four step process:
1) Destination Address filtering;
Yes
2) Early Interrupt Generation;
4) Normal Interrupt Generation.
Figure 21 provides a diagram of frame pre-processing.
5.2.3.1 Destination Address Filtering
All incoming frames are passed through the Destination Address filter (DA filter). If the frame’s DA
passes the DA filter, the frame is passed on for further pre-processing. If it fails the DA filter, the
frame is discarded. See Section 5.3 on page 87 for
a more detailed description of DA filtering.
Discard Frame
Yes
Table 22. Receive Frame Pre-Processing
3) Acceptance filtering; and,
No
Pass
Accept.
Filter?
No
Status of receive
frame reported in
RxEvent register,
frame discarded.
Status of receive
frame reported in
RxEvent register,
frame accepted
into on-chip RAM
Generate Interrupts
Check:
- RxOKiE?
- ExtradataiE?
- CRCerroriE?
- RuntiE?
- RxDMAiE?
Pre-Processing
Complete
Figure 21. Receive Frame Pre-Processing
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5.2.3.2 Early Interrupt Generation
The CS8900A support the following two early interrupts that can be used to inform the host that a
frame is being received:
•
•
RxDest: The RxDest bit (Register C, BufEvent,
Bit F) is set as soon as the Destination Address
(DA) of the incoming frame passes the DA filter. If the RxDestiE bit (Register B, BufCFG,
bit F) is set, the CS8900A generates a corresponding interrupt. Once RxDest is set, the host
is allowed to read the incoming frame's DA (the
first 6 bytes of the frame).
Rx128: The Rx128 bit (Register C, BufEvent,
Bit B) is set as soon as the first 128 bytes of the
incoming frame have been received. If the
Rx128iE bit (Register B, BufCFG, bit B) is set,
the CS8900A generates a corresponding interrupt. Once the Rx128 bit is set, the RxDest bit
is cleared and the host is allowed to read the
first 128 bytes of the incoming frame. The
Rx128 bit is cleared by the host reading the
BufEvent register (either directly or through the
Interrupt Status Queue) or by the CS8900A detecting the incoming frame's End-of-Frame
(EOF) sequence.
Like all Event bits, RxDest and Rx128 are set by
the CS8900A whenever the appropriate event occurs. Unlike other Event bits, RxDest and Rx128
may be cleared by the CS8900A without host intervention. All other event bits are cleared only by the
host reading the appropriate event register, either
directly or through the Interrupt Status Queue
(ISQ). (RxDest and Rx128 can also be cleared by
the host reading the BufEvent register, either directly or through the Interrupt Status Queue). Figure 22 provides a diagram of the Early Interrupt
process.
5.2.3.3 Acceptance Filtering
The third step of pre-processing is to determine
whether or not to accept the frame by comparing
the frame with the criteria programmed into the Rx-
CTL register (Register 5). If the receive frame
passes the Acceptance filter, the frame is buffered,
either on chip or in host memory via DMA. If the
frame fails the Acceptance filter, it is discarded.
The results of the Acceptance filter are reported in
the RxEvent register (Register 4).
5.2.3.4 Normal Interrupt Generation
The final step of pre-processing is to generate any
enabled interrupts that are triggered by the incoming frame. Interrupt generation occurs when the entire frame has been buffered (up to the first 1518
bytes). For more information about interrupt generation, see Section 5.1 on page 79.
5.2.4 Held vs. DMAed Receive Frames
All accepted frames are either held in on-chip
RAM until processed by the host, or stored in host
memory via DMA. A receive frame that is held in
on-chip RAM is referred to as a held receive frame.
A frame that is stored in host memory via DMA is
a DMAed receive frame. This section describes
buffering and transferring held receive frames.
Section 5.4 on page 90 through Section 5.6 on
page 96 describe DMAed receive frames.
5.2.5 Buffering Held Receive Frames
If space is available, an incoming frame will be
temporarily stored in on-chip RAM, where it
awaits processing by the host. Although this receive frame now occupies on-chip memory, the
CS8900A does not commit the memory space to it
until one of the following two conditions is true:
1) The entire frame has been received and the host
has learned about the frame by reading the RxEvent register (Register 4), either directly or
through the ISQ.
Or:
2) The frame has been partially received, causing
either the RxDest bit (Register C, BufEvent, Bit
F) or the Rx128 bit (Register C, BufEvent, Bit
B) to become set, and the host has learned about
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Receive Frame
Yes
DA Filter
Passed?
No
Discard Frame
RxDest set.
Host may read the DA
(first 6 received bytes).
Yes
64 bytes
Received?
No
EOF
Received?
No
RxDest cleared
and Runt set.
If RuntA is set,
frame accepted and
Host may read frame.
Yes
Yes
128 bytes
Received?
No
Rx128 set and
RxDest cleared.
Host may read first
128 received bytes.
EOF
Received?
No
RxDest cleared and
RxOK or CRCerror
set, as appropriate.
If RxOKA or CRCerrorA
is set, frame accepted and
Host may read frame.
Yes
EOF
Received?
Yes
No
Rx128 cleared and
RxOK, CRCerror or
Extradata set, as
appropriate. If ExtradataA,
RxOKA or CRCerrorA is
set, frame is accepted and
Host may read frame.
Figure 22. Early Interrupt Generation
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the receive frame by reading the BufEvent register (Register C), either directly or through the
ISQ.
There are three possible ways that the host can
learn the status of a particular frame. It can:
When the CS8900A commits buffer space to a particular held receive frame (termed a committed received frame), no data from subsequent frames can
be written to that buffer space until the frame is
freed from commitment. (The committed received
frame may or may not have been received error
free.)
2) Read the RxEvent register directly (Register4);
or
A received frame is freed from commitment by any
one of the following conditions:
1) The host reads the entire frame sequentially in
the order that it was received (first byte in, first
byte out).
Or:
2) The host reads part or none of the frame, and
then issues a Skip command by setting the
Skip_1 bit (Register 3, RxCFG, bit 6).
Or:
3) The host reads part of the frame and then reads
the RxEvent register (Register 5), either directly or through the ISQ, and learns of another receive frame. This condition is called an
"implied Skip". Ensure that the host does not do
“implied skips.”
Both early interrupts are disabled whenever there is
a committed receive frame waiting to be processed
by the host.
5.2.6 Transferring Held Receive Frames
The host can read-out held receive frames in Memory or I/O space. To transfer frames in Memory
space, the host executes repetitive Move instructions (REP MOVS) from PacketPage base +
0404h. To transfer frames in I/O space, the host executes repetitive In instructions (REP IN) from I/O
base + 0000h, with status and length preceding the
frame.
1) Read the Interrupt Status Queue;
3) Read the RxStatus register (PacketPage base +
0400h).
5.2.7 Receive Frame Visibility
Only one receive frame is visible to the host at a
time. The receive frame's status can be read from
the RxStatus register (PacketPage base + 0400h),
and its length can be read from the RxLength register (PacketPage base + 0402h). For more information about Memory space operation, see
Section 4.9 on page 74. For more information
about I/O space operation, see Section 4.10 on
page 76.
5.2.8 Example of Memory Mode Receive Operation
A common length for short frames is 64 bytes, including the 4-byte CRC. Suppose that such a frame
has been received with the CS8900A configured as
follows:
•
The BufferCRC bit (Register 3, RxCFG, Bit B)
is set causing the 4-byte CRC to be buffered
with the rest of the receive data.
•
The RxOKA bit (Register 5, RxCTL, Bit 8) is
set, causing the CS8900A to accept good
frames (a good frame is one with legal length
and valid CRC).
•
The RxOKiE bit (Register 3, RxCFG, Bit 8) is
set, causing an interrupt to be generated whenever a good frame is received.
Then the transfer to the host would proceed as follows:
1) The CS8900A generates an RxOK interrupt to
the host to signal the arrival of a good frame.
2) The host reads the ISQ (PacketPage base +
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0120h) to assess the status of the receive frame
and sees the contents of the RxEvent register
(Register 4) with the RxOK bit (Bit 8) set.
3) The host reads the receive frame’s length from
the RxLength register (PacketPage base +
0402h).
4) The host reads the frame data by executing 32
consecutive MOV instructions starting with
PacketPage base + 0404h.
The memory map of the 64-byte frame is given in
Table 23.
Memory Space Description of Data Stored in OnWord Offset
chip RAM
0400h
RxStatus Register (the host may
skip reading 0400h since RxEvent
was read from the ISQ.)
0402h
RxLength Register (In this example,
the length is 40h bytes. The frame
starts at 0404h, and runs through
0443h.)
0404h to 0409h 6-byte Source Address.
040Ah to 040Fh 6-byte Destination Address.
0410h to 011h 2-byte Length or Type Field.
0412h to 043Fh 46 bytes of data.
0440h
CRC, bytes 1 and 2
0442h
CRC, bytes 3 and 4
Table 23. Example Memory Map
5.2.9 Receive Frame Byte Counter
The receive frame byte counter describes the number of bytes received for the current frame. The
counter is incremented in real time as bytes are received from the Ethernet. The byte counter can be
used by the driver to determine how many bytes are
available for reading out of the CS8900A. Maximum Ethernet throughput can be achieved by using
I/O or memory modes, and by dedicating the CPU
to reading this counter, and using the count to read
the frame out of the CS8900A at the same time it is
being received by the CS8900A from the Ethernet
(parallel frame-reception and frame-read-out
tasks).
The byte count register resides at PacketPage base
+ 50h.
Following an RxDest or Rx128 interrupt the register contains the number of bytes which are available to be read by the CPU. When the end of frame
is reached, the count contains the final count value
for the frame, including the allowance for the BufferCRC option. When this final count is read by the
CPU the count register is set to zero. Therefore to
read a complete frame using the byte count register,
the register can be read and the data moved until a
count of zero is detected. Then the RxEvent register can be read to determine the final frame status.
The sequence is as follows:
1) At the start of a frame, the byte counter matches
the incoming character counter. The byte
counter will have an even value prior to the end
of the frame.
2) At the end of the frame, the final count, including the allowance for the CRC (if the BufferCRC option is enabled), is held until the byte
counter is read.
3) When a read of the byte counter returns a count
of zero, the previous count was the final count.
The count may now have an odd value.
4) RxEvent should be read to obtain a final status
of the frame, followed by a Skip command to
complete the operation.
Note that all RxEvent’s should be processed before
using the byte counter. The byte counter should be
used following a BufEvent when RxDest or Rx128
interrupts are enabled.
5.3 Receive Frame Address Filtering
The CS8900A is equipped with a Destination Address (DA) filter used to determine which receive
frames will be accepted. (A receive frame is said to
be "accepted" by the CS8900A when the frame
data are placed in either on-chip memory, or in host
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memory by DMA). The DA filter can be configured to accept the following frame types:
5.3.1 Configuring the Destination Address Filter
The DA filter is configured by programming five
DA filter bits in the RxCTL register (Register 5):
IAHashA, PromiscuousA, MulticastA, IndividualA, and BroadcastA. Four of these bits are associated with four status bits in the RxEvent register
(Register 4): IAHash, Hashed, IndividualAdr, and
Broadcast. The RxEvent register reports the results
of the DA filter for a given receive frame. The bits
associated with DA filtering are summarized below:
5.3.0.1 Individual Address Frames
For all Individual Address frames, the first bit of
the DA is a "0" (DA[0] = 0), indicating that the address is a Physical Address. The address filter accepts Individual Address frames whose DA
matches the Individual Address (IA) stored at
PacketPage base + 0158h, or whose hash-filtered
DA matches one of the bits programmed into the
Logical Address Filter (the hash filter is described
later in this section).
Bit #
5.3.0.2 Multicast Frames
For Multicast Frames, the first bit of the DA is a "1"
(DA[0] = 1), indicating that the frame is a Logical
Address. The address filter accepts Multicast
frames whose hash-filtered DA matches one of the
bits programmed into the Logical Address Filter
(the hash filter is described later is this section). As
shown in Table 25, Broadcast Frames can be accepted as Multicast frames under a very specific set
of conditions.
PromiscuousA MulticastA
0
0
7
9
A
PromiscuousA
MulticastA
IndividualA
B
BroadcastA
RxEvent
Register 4
IAHash
(used only if IAHashA = 1)
Hashed
IndividualAdr
(used only if IndividualA = 1)
Broadcast
(used only if BroadcastA = 1)
The IAHashA, MulticastA, IndividualA, and
BroadcastA bits are used independently. As a result, many DA filter combinations are possible. For
example, if MulticastA and IndividualA are set,
then all frames that are either Multicast or Individual Address frames are accepted. The PromiscuousA bit, when set, overrides the other four DA
bits, and allows all valid frames to be accepted. Table 24 summarizes the configuration options available for DA filtering.
5.3.0.3 Broadcast Frames
Frames with DA equal to FFFF FFFF FFFFh are
broadcast frames. In addition, the CS8900A can be
configured for Promiscuous Mode, in which case it
will accept all receive frames, irrespective of DA.
IAHashA
0
6
RxCTL
Register 5
IAHashA
IndividualA
1
BroadcastA
0
1
0
0
0
0
0
0
1
0
0
0
X
0
1
0
X
0
X
1
X
Frames Accepted
Individual Address frames with
DA matching the IA at PacketPage base + 0158h
Individual Address frames with
DA that pass the hash filter
(DA[0] must be “0”)
Multicast frames with DA that
pass the hash filter (DA[0] must
be “1”)
Broadcast frames
All frames
Table 24. DA Filtering Options
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It may become necessary for the host to change the
Destination Address (DA) filter criteria without resetting the CS8900A. This can be done as follows:
1) Clear SerRxON (Register 13, LineCTL, Bit 6)
to prevent any additional receive frames while
the filter is being changed.
2) Modify the DA filter bits (B, A, 9, 7, and 6) in
the RxCTL register. Modify the Logical AddressFilteratPacketPagebase+0150h,ifnecessary.
Modify the Individual Address at PacketPage
base + 0158h, if necessary.
3) Set SerRxON to re-enable the receiver.
Because the receiver has been disabled, the
CS8900A will ignore frames while the host is
changing the DA filter.
5.3.2 Hash Filter
The hash filter is used to help determine which
Multicast frames and which Individual Address
frames should be accepted by the CS8900A.
5.3.2.1 Hash Filter Operation
See Figure 23. The DA of the incoming frame is
passed through the CRC logic, generating a 32-bit
CRC value. The six most-significant bits of the
CRC are latched into the 6-bit hash register (HR).
The contents of the HR are passed through a 6-to64-bit decoder, asserting one of the decoder’s outputs. The asserted output is compared with a corre-
sponding bit in the 64-bit Logical Address Filter,
located at PacketPage base + 0150h. If the decoder
output and the Logical Address Filter bit match, the
frame passes the hash filter and the Hashed bit
(Register 4, RxEvent, Bit 9) is set. If the two do not
match, the frame fails the filter and the Hashed bit
is clear.
Whenever the hash filter is passed by a "good"
frame, the RxOK bit (Register 4, RxEvent, Bit 8) is
set and the bits in the HR are mapped to the Hash
Table Index bits (Register 4, RxEvent, Bits A
through F).
5.3.3 Broadcast Frame Hashing Exception
Table 25 describes in detail the content of the RxEvent register for each output of the hash and address filters, and describes an exception to normal
processing. That exception can occur when when
the hash-filter Broadcast address matches a bit in
the Logical Address Filter. To properly account for
this exception, the software driver should use the
following test to determine if the RxEvent register
contains a normal RxEvent (meaning bits E-A are
used for Extra data, Runt, CRC Error, Broadcast
and IndividualAdr) or a hash-table RxEvent (meaning bits F-A contain the Hash Table Index).
If bit Hashed =0, or bit RxOK=0, or (bits F-A = 02h
and the destination address is all ones) then RxEvent contains a normal RxEvent, else RxEvent
contained a hash RxEvent.
(MSB)
Destination Address (DA)
from incoming frame
32-bit CRC value
CS8900A
CRC
Logic
(LSB)
6-bit Hash Register (HR)
[Hash Table Index]
6-to-64 decoder
to
Hashed
bit
1
64
64-input
OR gate
64-bit Logical Address Filter (LAF)
Written into PacketPage base + 150h
Figure 23. Hash Filter Operation
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Passes
Contents of RxEvent
Address Erred
Hash
Type of Frame?
Bits F-A
Bit 9
Bit 8
Bit 6
Filter?
Received
Hashed RxOK IAHash
Frame
Individual
no
yes
Hash Table Index
1
1
1
Address
no
no
ExtraData Runt CRC Error Broadcast Individual Adr
0
1
0
yes
don’t care ExtraData Runt CRC Error Broadcast Individual Adr
0
0
0
Multicast
no
yes
Hash table index
1
1
0
Address
no
no
ExtraData Runt CRC Error Broadcast Individual Adr
0
1
0
yes
don’t care ExtraData Runt CRC Error Broadcast Individual Adr
0
0
0
Broadno
yes
ExtraData Runt CRC Error Broadcast Individual Adr
1
1
0
cast
(Note 6)
(actual value X00010)
Address
no
yes
ExtraData Runt CRC Error Broadcast Individual Adr
0
1
0
(Note 7)
no
no
ExtraData Runt CRC Error Broadcast Individual Adr
0
1
0
yes
don’t care ExtraData Runt CRC Error Broadcast Individual Adr
0
0
0
Notes: 6. Broadcast frames are accepted as Multicast frames if and only if all the following conditions are met
simultaneously:
a) the Logical Address Filter is programmed as: (MSB) 0000 8000 0000 0000h (LSB). Note that this
LAF value corresponds to a Multicast Addresses of both all 1s and 03-00-00-00-00-01.
b) the Rx Control Register (register 5) is programmed to accept IndividualA, MulticastA, RxOK-only,
and the following address filters were enabled: IAHashA and BroadcastA.
7. NOT (Note 1).
Table 25. Contents of RxEvent Upon Various Conditions
5.4 Receive DMA
5.4.1 Overview
The CS8900A supports a direct interface to the host
DMA controller allowing it to transfer receive
frames to host memory via slave DMA. The DMA
option applies only to receive frames, and not
transmit operation. The CS8900A offers three possible Receive DMA modes:
5.4.2 Configuring the CS8900A for DMA Operation
The CS8900A interfaces to the host DMA controller through one pair of the DMA request/acknowledge pins (see Section 3.2 on page 18 for a
description of the CS8900A’s DMA interface).
Four 16-bit registers are used for DMA operation.
These are described in Table 26.
1) Receive-DMA-only mode: All receive frames
are transferred via DMA.
Receive-DMA-only mode is enabled by setting the
RxDMAonly bit (Register 3, RxCFG, Bit 9).
2) Auto-Switch DMA: DMA is used only when
needed to help prevent missed frames.
3) StreamTransfer: DMA is used to minimize the
number of interrupts to the host.
Note: If the RxDMAonly bit and the AutoRxDMAE bit (Register 3, RxCFG, Bit A) are both set,
then RxDMAonly takes precedence, and the
CS8900A is in DMA mode for all receive frames.
This section provides a description of ReceiveDMA-only mode. Section 5.5 on page 93 describes
Auto-Switch DMA and Section 5.6 on page 96 describes StreamTransfer.
5.4.3 DMA Receive Buffer Size
In receive DMA mode, the CS8900A stores received frames (along with their status and length)
in a circular buffer located in host memory space.
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PacketPage
Register Description
Address
0024h
DMA Channel Number: DMA channel number (0, 1, or 2) that defines the
DMARQ/DMACK pin pair used.
0026h
DMA Start of Frame: 16-bit value that
defines the offset from the DMA base
address to the start of the most
recently transferred received frame.
0028h
DMA Frame Count: The lower 12 bits
define the number of valid frames
transferred via DMA since the last
read-out of this register. The upper 4
bits are reserved and not applicable.
002Ah
DMA Byte Count: Defines the number of bytes that have been transferred
via DMA since the last read-out of this
register.
Table 26. Receive DMA Registers
The size of the circular buffer is determined by the
RxDMAsize bit (Register 17, BusCTL, Bit D).
When RxDMAsize is clear, the buffer size is 16
Kbytes. When RxDMAsize is set, the buffer is 64
Kbytes. It is the host’s task to locate and keep track
of the DMA receive buffer’s base address. The
DMA Start-of-Frame register is the only circuit affected by this bit.
APPLICATION NOTE: As a result of the PC architecture, DMA cannot occur across a 128K
boundary in memory. Thus, the DMA buffer reserved for the CS8900A must not cross a 128K
boundary in host memory if DMA operation is desired. Requesting a 64K, rather than a 16K buffer,
increases the probability of crossing a 128K boundary. After the driver requests a DMA buffer, the
driver must check for a boundary crossing. If the
boundary is crossed, then the driver must disable
DMA functionality.
5.4.4 Receive-DMA-Only Operation
If space is available, an incoming frame is temporarily stored in on-chip RAM. When the entire
frame has been received, pre-processed, and accepted, the CS8900A signals the DMA controller
that a frame is to be transferred to host memory by
driving the selected DMA Request pin high. The
DMA controller acknowledges the request by driving the DMA Acknowledge pin low. The CS8900A
then transfers the contents of the RxStatus register
(PacketPage base + 0400h) and the RxLength register (PacketPage base + 0402h) to host memory,
followed by the frame data. If the DMABurst bit
(Register 17, BusCTL, Bit B) is clear, the DMA
Request pin remains high until the entire frame is
transferred. If the DMABurst bit is set, the DMA
Request pin (DMARQ) remains high for approximately 28 ms then goes low for approximately 1.3
ms to give the CPU and other peripherals access to
the bus.
When the transfer is complete, the CS8900A does
the following:
•
updates the DMA Start-of-Frame register
(PacketPage base + 0026h);
•
updates the DMA Frame Count register (PacketPage base + 0028h);
•
updates DMA Byte Count register (PacketPage
base + 002Ah);
•
sets the RxDMAFrame bit (Register C, BufEvent, Bit 7); and,
•
deallocates the buffer space used by the transferred frame.
In addition, if the RxDMAiE bit (Register B,
BufCFG, Bit 7) is set, a corresponding interrupt occurs.
When the host processes DMAed frames, it must
read the DMA Frame Count register.
Whenever a receive frame is missed (lost) due to
insufficient receive buffer space, the RxMISS
counter (Register 10) is incremented. A missed receive frame causes the counter to increment in either DMA or non-DMA modes.
Note that when in DMA mode, reading the contents
of the RxEvent register will return 0000h. Status
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information should be obtained from the DMA
buffer.
5.4.5 Committing Buffer Space to a DMAed
Frame
Although a receive frame may occupy space in the
host memory’s circular DMA buffer, the
CS8900A’s Memory Manager does not commit the
buffer space to the receive frame until the entire
frame has been transferred and the host learns of
the frame’s existence by reading the Frame Count
register (PacketPage base + 0028h).
When the CS8900A commits DMA buffer space to
a particular DMAed receive frame (termed a committed received frame), no data from subsequent
frames can be written to that buffer space until the
committed received frame is freed from commitment. (The committed received frame may or may
not have been received error free.)
A committed DMAed receive frame is freed from
commitment by any one of the following conditions:
1) The host rereads the DMA Frame Count register (PacketPage base + 0028h).
2) New frames have been transferred via DMA,
and the host reads the BufEvent register (either
directly or from the ISQ) and sees that the RxDMAFrame bit is set (this condition is termed an
"implied Skip").
3) The host issues a Reset-DMA command by setting the ResetRxDMA bit (Register 17, BusCTL, Bit 6).
5.4.6 DMA Buffer Organization
When DMA is used to transfer receive frames, the
DMA Start-of-Frame register (PacketPage Base +
0026h) defines the offset from the DMA base to the
start of the most recently transferred received
frame. Frames stored in the DMA buffer are transferred as words and maintain double-word (32-bit)
alignment. Unfilled memory space between suc-
cessive frames stored in the DMA buffer may result
from double-word alignment. These "holes" may
be 1, 2, or 3 bytes, depending on the length of the
frame preceding the hole.
5.4.7 RxDMAFrame Bit
The RxDMAFrame bit (Register C, BufEvent, bit
7) is controlled by the CS8900A and is set whenever the value in the DMA Frame Count register is
non-zero. The host cannot clear RxDMAFrame by
reading the BufEvent register (Register C).
Table 27 summarizes the criteria used to set and
clear RxDMAFrame.
Non-Stream
Transfer Mode
Stream Transfer
Mode (see
Section 5.6)
The RxDMAFrame
bit is set at the end
of a Stream Transfer
cycle.
To set RxD- The RxDMAFrame
MAFrame bit is set whenever
the DMA Frame
Count register
(PacketPage base +
0028h) transitions to
non-zero.
To Clear
The DMA Frame
The DMA Frame
RxDMACount is zero.
Count is zero.
Frame
Table 27. RxDMAFrame Bit
5.4.8 Receive DMA Example Without WrapAround
Figure 24 shows three frames stored in host memory by DMA without wrap-around.
5.4.9 Receive DMA Operation for RxDMA-Only
Mode
In an RxDMAOnly mode, a system DMA moves
all the received frames from the on-chip memory to
an external 16- or 64-Kbyte buffer memory. The
received frame must have passed the destination
address filter, and must be completely received.
Usually, the DMA receive frame interrupt (RxDMAiE, bit 7, Register B, BufCFG) is set so that the
CS8900A generates an interrupt when a frame is
transferred by DMA. Figure 25 shows how a DMA
Receive Frame interrupt is processed.
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In the interrupt service routine, the BufEvent register (register C), bit RxDMA Frame (bit 7) indicates
that one or more receive frames were transferred
using DMA. The software driver should maintain a
pointer (e.g. PDMA_START) that will point to the
beginning of a new frame. After the CS8900A is
initialized and before any frame is received, pointer
PDMA_START points to the beginning of the
DMA buffer memory area. The first read of the
DMA Frame Count, CDMA, commits the memory
covered by the CDMA count, and the DMA cannot
overwrite this committed space until the space is
freed. The driver then processes the frames described by the CDMA count and makes a second
read of the DMA frame count. This second read
frees the buffer memory space described by the
CDMA counter.
DMA Buffer
Base Address
During the frame processing, the software should
advance the PDMA_START pointer. At the end of
processing a frame, pointer PDMA_START
should be made to align with a double-word boundary. The software remains in the loop until the
DMA frame count read is zero.
5.5 Auto-Switch DMA
5.5.1 Overview
The CS8900A supports a unique feature, AutoSwitch DMA, that allows it to switch between
Memory or I/O mode and Receive DMA automatically. Auto-Switch DMA allows the CS8900A to
realize the performance advantages of Memory or
I/O mode while minimizing the number of missed
frames that could result due to slow processing by
the host.
RxStatus - Frame 1
RxLength - Frame 1
Frame 1
DMA Byte Count
(PacketPage base + 012Ah)
RxStatus - Frame 2
RxLength - Frame 2
Frame 2
"Holes" due to
double-word
alignment
RxStatus - Frame 3
DMA Start of Frame
register (PacketPage
base + 0126H)
points here.
RxLength - Frame 3
Frame 3
Figure 24. Example of Frames Stored in DMA Buffer
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Host Enters Interrupt Routine
RxDMA
Frame
bit set?
No
Process other events
that caused interrupt
Yes
Read the DMA frame Count (C DMA)
(PacketPage base + 0028h)
Yes
CDMA
=0?
Process other events
that caused interrupt
No
Process the
CDMA Frames
Figure 25. RxDMA Only Operation
5.5.2 Configuring the CS8900A for Auto-Switch
DMA
Auto-Switch DMA mode requires the same configuration as Receive-DMA-only mode, with one exception: the AutoRxDMAE bit (Register 3,
RxCFG, Bit A) must be set, and the RxDMAonly
bit (Register 3, RxCFG, Bit 9) must be clear (see
Section 5.4 on page 90, Configuring the CS8900A
for DMA Operation). In Auto-Switch DMA mode,
the CS8900A operates in non-DMA mode if possible, only switching to slave DMA if necessary.
Note that if the AutoRxDMAE bit and the RxDMAonly bit (Register 3, RxCFG, bit 9) are both set,
the CS8900A uses DMA for all receive frames.
5.5.3 Auto-Switch DMA Operation
Whenever a frame begins to be received in AutoSwitch DMA mode, the CS8900A checks to see if
there is enough on-chip buffer space to store a maximum length frame. If there is, the incoming frame
is pre-processed and buffered as normal. If there
isn’t, the CS8900A’s MAC engine compares the
frame’s Destination Address (DA) to the criteria
programmed into the DA filter. If the incoming DA
fails the DA filter, the frame is discarded. If the DA
passes the DA filter, the CS8900A automatically
switches to DMA mode and starts transferring the
frame(s) currently being held in the on-chip buffer
into host memory. This frees up buffer space for the
incoming frame.
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Figure 26 shows the steps the CS8900A goes
through in determining when to automatically
switch to DMA.
Packet Received
Frame
Passed the No
DA filter?
Frame
Discarded
Yes
RxDMA only
Bit=1
Yes
All Frames
use DMA
No
More
Yes
Buffer Space
Available?
Frame Buffered
in On-chip RAM
No
AutoRxDMA
Bit=1?
No
Auto-Switch
DMA Disabled
Yes
Auto-Switch to DMA
Figure 26. Conditions for Switching to DMA
Whenever the CS8900A automatically enters
DMA, at least one complete frame is already stored
in the on-chip buffer. Because frames are transferred to the host in the same order as received (first
in, first out), the beginning of the received frame
that triggered the switch to DMA is not the first
frame to be transferred. Instead, the oldest noncommitted frame in the on-chip buffer is the first frame
to use DMA. When DMA begins, any pending RxEvent reports in the Interrupt Status Queue are discarded because the host cannot process those
events until the corresponding frames have been
completely DMAed.
Auto-Switch DMA works only on entire received
frames. The CS8900A does not use Auto-Switch
DMA to transfer partial frames. Also, when a frame
has been committed (see Section 5.2.5 on page 84),
the CS8900A will not switch to DMA mode until
the committed frame has been transferred completely or skipped.
After a complete frame has been moved to host
memory, the CS8900A updates the DMA Start-ofFrame register (PacketPage base + 0126h), the
DMA Frame Count register (PacketPage base +
0128h), and the DMA Byte Count register, then
sets the RxDMAFrame bit (Register C, BufEvent,
bit 7). If RxDMAiE (Register B, BufCFG, bit 7) is
set, a corresponding interrupt occurs.
5.5.4 DMA Channel Speed vs. Missed Frames
When the CS8900A starts DMA, the entire oldest,
noncommitted frame must be placed in host memory before on-chip buffer space will be freed for the
next incoming frame. If the oldest frame is relatively large, and the next incoming frame also large,
the incoming frame may be missed, depending on
the speed of the DMA channel. If this happens, the
CS8900A will increment the RxMiss counter (Register 10) and clear any event reports (RxEvent and
BufEvent) associated with the missed frame.
5.5.5 Exit From DMA
When the CS8900A has activated receive DMA, it
remains in DMA mode until all of the following are
true:
•
The host processes all RxEvent and BufEvent
reports pending in the ISQ.
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•
The host reads a zero value from the DMA
Frame Count register (PacketPage base +
0028h).
•
The CS8900A is not in the process of transferring a frame via DMA.
5.5.6 Auto-Switch DMA Example
Figure 27 shows how the CS8900A enters and exits
Auto-Switch DMA mode.
Register Name
Register 3, RxCFG
Register 5, RxCTL
Register B, BufCFG
5.6 StreamTransfer
Bit
7
8
9
or
A
8
7
F
B
Bit Name
StreamE
RxOKiE
RxDMAonly
or
AutoRxDMA
RxOKA
RxDMAiE
RxDestiE
Rx128iE
Value
1
1
1
or
1
1
1
0
0
Table 28. Stream Transfer Configuration
5.6.1 Overview
The CS8900A supports an optional feature,
StreamTransfer, that can reduce the amount of
CPU overhead associated with frame reception.
StreamTransfer works during periods of high receive activity by grouping multiple receive events
into a single interrupt, thereby reducing the number
of receive interrupts to the host processor. During
periods of peak loading, StreamTransfer will eliminate 7 out of every 8 interrupts, cutting interrupt
overhead by up to 87%.
or more frames with the following characteristics
are received:
•
delays the normal RxOK interrupt associated
with the first receive frame;
5.6.2 Configuring the CS8900A for
StreamTransfer
StreamTransfer is enabled by setting the StreamE
bit along with either the AutoRxDMAE bit or the
RxDMAonly bit in register Receiver Configuration
(register 3). (StreamTransfer must not be selected
unless either one of AutoRxDMAE or RxDMAonly is selected.)StreamTransfer only applies to
"good" frames (frames of legal length with valid
CRC). Therefore, the RxOKA bit and the RxOKiE
bit must both be set. Finally, StreamTransfer works
on whole packets and is not compatible with early
interrupts. This requires that the RxDestiE bit and
the Rx128iE bit both be clear.
•
switches to receive DMA mode;
•
transfers up to eight receive frames into host
memory via DMA;
•
updates the DMA Start-of-Frame register
(PacketPage base + 0026h);
•
updates the DMA Frame Count register (PacketPage base + 0028h);
•
updates DMA Byte Count register (PacketPage
base + 002Ah);
•
sets the RxDMAFrame bit (Register C, BufEvent, Bit 7); and,
•
generates an RxDMAFrame interrupt.
Table 28 summarizes how to configure the
CS8900A for StreamTransfer.
5.6.4 Keeping StreamTransfer Mode Active
When the CS8900A initiates a StreamTransfer cycle, it will continue to execute cycles as long as the
following conditions hold true:
5.6.3 StreamTransfer Operation
When StreamTransfer is enabled, the CS8900A
will initiate a StreamTransfer cycle whenever two
1) pass the Destination Address filter;
2) are of legal length with valid CRC; and,
3) are spaced "back-to-back" (between 9.6 and 52
µs apart).
During a StreamTransfer cycle the CS8900A does
the following:
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Crystal LAN™ ISA Ethernet Controller
Enter Example Here
Fra
me
1
Fra
me
2
Entering this example, the receive buffer is empty and the
DMA Frame Count (PacketPage base + 0028h) is zero.
Frame 1 received and completely stored in on-chip RAM.
Frame 2 received and completely stored in on-chip RAM.
Time
At this point, the CS8900A does not have sufficient buffer
space for another complete large frame (1518 bytes).
Fra
me
3
Frame 3 starts to be received and passes the DA filter.
This activates Auto-Switch DMA.
Frame 1 is placed in host memory via DMA freeing
space for the incoming Frame 3. The CS8900A updates
the DMA Frame Count, DMA Start of Frame and DMA
Byte Count registers. It then sets the RxDMA DMAFrame
bit and generates an interrupt.
Receive DMA used
during this time.
Frame 2 is placed in host memory via DMA and the
CS8900A updates the DMA registers.
The host responds to the RxDMAFrame interrupt, and
reads the Frame Count register, which is cleared when
read. Since there are no receive interrupts pending, the
CS8900A exits DMA (assumes Frame 3 is still coming in).
Frame 3 is completely buffered in on-chip RAM, and
awaits processing by the host.
Exit Example
Figure 27. Example of Auto-Switch DMA
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•
all packets received are of legal length with valid CRC;
•
each packet follows its predecessor by less than
52 ms; and,
•
the DA of each packet passes the DA filter.
If any of these conditions are not met, the CS8900A
exits StreamTransfer by generating RxOK and
RxDMA interrupts. The CS8900A then returns to
either Memory, I/O, or DMA mode, depending on
configuration.
5.6.5 Example of StreamTransfer
Figure 28 shows how four back-to-back frames,
followed by five back-to-back frames, would be received without StreamTransfer. Figure 29 shows
how the same sequence of frames would be received with StreamTransfer.
5.6.6 Receive DMA Summary
Table 29 summarize the Receive DMA configuration options supported by the CS8900A.
RxDMAonly AutoRxDMAiE
RxDMAiE
RxOKiE
CS8900A Configuration
(Register 3, (Register 3,
(Register B, (Register 3,
RxCFG,Bit 9) RxCFG, Bit A) BufCFG, Bit 7) RxCFG, Bit 8)
1
NA
0
NA
Receive DMA used for all receive frames, without
interrupts.
1
NA
1
NA
Receive DMA used for all receive frames, with
BufEvent interrupts.
0
1
0
0
Auto-Switch DMA used if necessary, without interrupts.
0
1
1
1
Auto-Switch DMA used if necessary, with RxEvent
and BufEvent interrupts possible.
0
0
NA
NA
Memory or I/O Mode only.
Table 29. Receive DMA Configuration Options
4 Back-to-Back Frames
T > 52 us
5 Back-to-Back Frames
Interrupt
Request
Time
9 Interrupts for 9 "Good" Packets
Figure 28. Receive Example Without Stream Transfer
4 Back-to-Back Frames
T > 52 us
5 Back-to-Back Frames
Interrupt
Request
2 Interrupts for 9 "Good" Packets
Time
Figure 29. Receive DMA Configuration Options
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5.7 Transmit Operation
5.7.1 Overview
Packet transmission occurs in two phases. In the
first phase, the host moves the Ethernet frame into
the CS8900A’s buffer memory. The first phase begins with the host issuing a Transmit Command.
This informs the CS8900A that a frame is to be
transmitted and tells the chip when (i.e. after 5,
381, or 1021 bytes have been transferred or after
the full frame has been transferred to the CS8900A)
and how the frame should be sent (i.e. with or without CRC, with or without pad bits, etc.). The host
follows the Transmit Command with the Transmit
Length, indicating how much buffer space is required. When buffer space is available, the host
writes the Ethernet frame into the CS8900A’s internal memory, using either Memory or I/O space.
In the second phase of transmission, the CS8900A
converts the frame into an Ethernet packet then
transmits it onto the network. The second phase begins with the CS8900A transmitting the preamble
and Start-of-Frame delimiter as soon as the proper
number of bytes has been transferred into its transmit buffer (5, 381, 1021 bytes or full frame, depending on configuration). The preamble and Startof-Frame delimiter are followed by the data transferred into the on-chip buffer by the host (Destination Address, Source Address, Length field and
LLC data). If the frame is less than 64 bytes, including CRC, the CS8900A adds pad bits if configured to do so. Finally, the CS8900A appends the
proper 32-bit CRC value.
5.7.2 Transmit Configuration
After each reset, the CS8900A must be configured
for transmit operation. This can be done automatically using an attached EEPROM, or by writing
configuration commands to the CS8900A’s internal
registers (see Section 3.4 on page 21). The items
that must be configured include which physical interface to use and which transmit events cause interrupts.
5.7.2.1 Configuring the Physical Interface
Configuring the physical interface consists of determining which Ethernet interface should be active (10BASE-T or AUI), and enabling the transmit
logic for serial transmission. Configuring the Physical Interface is accomplished via the LineCTL register (Register 13) and is described in Table 30.
Register 13, LineCTL
Bit
7
8
9
B
D
Bit Name
SerTxON
AUIonly
Operation
When set, transmission enabled.
When set, AUI selected (takes
precedence over AutoAUI/10BT).
When clear, 10BASE-T selected.
AutoAUI/10BT When set, automatic interface
selection enabled.
Mod
When set, the modified backoff
BackoffE
algorithm is used. When clear,
the standard backoff algorithm is
used.
2-part
When set, two-part deferral is
DefDis
disabled.
Table 30. Physical Interface Configuration
Note that the CS8900A transmits in 10BASE-T
mode when no link pulses are being received only
if bit DisableLT is set in register Test Control (Register 19).
5.7.2.2 Selecting which Events Cause Interrupts
The TxCFG register (Register 7) and the BufCFG
register (Register B) are used to determine which
transmit events will cause interrupts to the host processor. Tables 31 and 32 describe the interrupt enable (iE) bits in these registers.
5.7.3 Changing the Configuration
When the host configures these registers it does not
need to change them for subsequent packet transmissions. If the host does choose to change the TxCFG or BufCFG registers, it may do so at any time.
The effects of the change are noticed immediately.
That is, any changes in the Interrupt Enable (iE)
bits may affect the packet currently being transmitted.
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Register 7, TxCFG
Bit
6
Bit Name
Loss-ofCRSiE
7
SQErroriE
8
TxOKiE
9
Out-ofwindowiE
A
JabberiE
B
AnycolliE
F
16colliE
Operation
When set, there is an interrupt
whenever the CS8900A fails to
detect Carrier Sense after transmitting the preamble (applies to
the AUI only).
When set, there is an interrupt
whenever there is an SQE error.
When set, there is an interrupt
whenever a frame is transmitted
successfully..
When set, there is an interrupt
whenever a late collision is
detected.
When set, there is an interrupt
whenever there is a jabber condition.
When set, there is an interrupt
whenever there is a collision.
When set, there is an interrupt
whenever the CS8900A attempts
to transmit a single frame 16
times.
Table 31. Transmitting Interrupt Configuration
Register B, BufCFG
Bit
8
Bit Name
Rdy4TxiE
9
TxUnder
runiE
C
TxCol
OvfloiE
Operation
When set, there is an interrupt
whenever buffer space becomes
available for a transmit frame
(used with a Transmit Request).
When set, there is an interrupt
whenever ther CS8900A runs out
of data after transmit has started.
When set, there is an interrupt
whenever the TxCol counter
overflows.
Table 32. Transmit Interrupt Configuration
If the host chooses to change bits in the LineCTL
register after initialization, the ModBackoffE bit
and any receive related bit (LoRxSquelch, SerRxON) may be changed at any time. However, the
Auto AUI/10BT and AUIonly bits should not be
changed while the SerTxON bit is set. If any of
these three bits are to be changed, the host should
first clear the SerTxON bit (Register 13, LineCTL,
Bit 7), and then set it when the changes are complete.
5.7.4 Enabling CRC Generation and Padding
Whenever the host issues a Transmit Request command, it must indicate whether or not the Cyclic
Redundancy Check (CRC) value should be appended to the transmit frame, and whether or not
pad bits should be added (if needed). Table 33 describes how to configure the CS8900A for CRC
generating and padding.
Register 9, TxCMD
Inhibit
CRC
(Bit C)
0
1
0
1
TxPad
Operation
Dis
(Bit D)
0
Pad to 64 bytes if necessary
(including CRC).
0
Send a runt frame if specified
length less than 60 bytes.
1
Pad to 60 bytes if necessary (without CRC).
1
Send runt if specified length less
than 64. The CS8900A will not
transmit a frame that is less than 3
bytes.
Table 33. CRC and Paddling Configuration
5.7.5 Individual Packet Transmission
Whenever the host has a packet to transmit, it must
issue a Transmit Request to the CS8900A consisting of the following three operations in the exact
order shown:
1) The host must write a Transmit Command to
the TxCMD register (PacketPage base +
0144h). The contents of the TxCMD register
may be read back from the TxCMD register
(Register 9).
2) The host must write the frame’s length to the
TxLength register (PacketPage base + 0146h).
3) The host must read the BusST register (Register 18)
The information written to the TxCMD register
tells the CS8900A how to transmit the next frame.
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The bits that must be programmed in the TxCMD
register are described in Table 34.
Register 9, TxCMD
Bit
6
7
clear clear
clear
set
set
clear
set
set
8
9
C
D
Bit Name
Tx Start
Operation
Start preamble after 5 bytes
have been transferred to the
CS8900A.
Start preamble after 381
bytes have been transferred to the CS8900A.
Start preamble after 1021
bytes have been transferred to the CS8900A.
Start preamble after entire
frame has been transferred
to the CS8900A.
Force
When set, the CS8900A discards any frame data currently in the transmit buffer.
Onecoll
When set, the CS8900A will
not attempt to retransmit
any packet after a collision.
InhibitCRC When set, the CS8900A
does not append the 32-bit
CRC value to the end of any
transmit packet.
TxPadDis When set, the CS8900A will
not add pad bits to short
frames.
Table 34. Tx Command Configuration
For each individual packet transmission, the host
must issue a complete Transmit Request. Furthermore, the host must write to the TxCMD register
before each packet transmission, even if the contents of the TxCMD register does not change. The
Transmit Request described above may be in either
Memory Space or I/O Space.
5.7.6 Transmit in Poll Mode
In poll mode, Rdy4TxiE bit (Register B, BufCFG,
Bit 8) must be clear (Interrupt Disabled). The transmit operation occurs in the following order and is
shown in Figure 30.
1) The host bids for frame storage by writing the
Transmit Command to the TxCMD register
(memory base+ 0144h in memory mode and
I/O base + 0004h in I/O mode).
2) The host writes the transmit frame length to the
TxLength register (memory base + 0146h in
memory mode and I/O base + 0006h in I/O
mode). If the transmit length is erroneous, the
command is discarded and the TxBidErr bit
(Register 18, BusST, Bit 7) is set.
3) The host reads the BusST register. This read is
performed in memory mode by reading Register 18, at memory base + 0138h. In I/O mode,
the host must first set the PacketPage Pointer at
the correct location by writing 0138h to the
PacketPage Pointer Port (I/O base + 000Ah).
The host can then read the BusST register from
the PacketPage Data Port (I/O base + 000Ch).
4) After reading the register, the Rdy4TxNOW bit
(Bit 8) is checked. If the bit is set, the frame can
be written. If the bit is clear, the host must continue reading the BusST register (Register 18)
and checking the Rdy4TxNOW bit (Bit 8) until
the bit is set.
When the CS8900A is ready to accept the frame,
the host transfers the entire frame from host memory to CS8900A memory using “REP” instruction
(REP MOVS starting at memory base + 0A00h in
memory mode, and REP OUT to Receive/Transmit
Data Port (I/O base + 0000h) in I/O mode).
5.7.7 Transmit in Interrupt Mode
In interrupt mode, Rdy4TxiE bit (Register B,
BufCFG, Bit 8) must be set for transmit operation.
Transmit operation occurs in the following order
and is shown in Figure 31.
1) The host bids for frame storage by writing the
Transmit Command to the TxCMD register
(memory base + 0144h in memory mode and
I/O base + 0004h in I/O mode).
2) The host writes the transmit frame length to the
TxLength register (memory base + 0146h in
memory mode and I/O base + 0006h in I/O
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Enter Packet Transmit Process
Exit: can’t Issue command
Yes
Note: Issuing a command
at this point will cause
previous transmit frame
to be lost.
Is
TxCMD
pending?
No
Host Writes Transmit Command
to the TxCMD Register
Host Writes Transmit Frame
Length to the TxLength Register
Transmit Request
Host Reads the BusST
Register (Register 18)
Rdy4
TxNOW
bit = 1?
No
Polling Loop
Yes
CS8900A Commits
Buffer Space to
Transmit Frame
Host Writes
Transmit Frame
to CS8900A
CS8900A
Transmits Frame
Exit Transmit Process
Figure 30. Transmit Operation in Polling Mode
mode). If the transmit length is erroneous, the
command is discarded and the TxBidErr, bit 7,
in BusST register is set.
3) The host reads the BusST register. This read is
performed in memory mode by reading Register 18, at memory base + 0138h. In I/O mode,
the host must first set the PacketPage Pointer at
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the correct location by writing 0138h to the
PacketPage Pointer Port (I/O base + 000Ah), it
than can read the BusST register from the PacketPage Data Port (I/O base + 000Ch).After
reading the register, the Rdy4TxNOW bit is
checked. If the bit is set, the frame can be written to CS8900A memory. If Rdy4TxNOW is
clear, the host will have to wait for the
CS8900A buffer memory to become available
at which time the host will be interrupted. On
interrupt, the host enters the interrupt service
routine and reads ISQ register (Memory base +
0120h in memory mode and I/O base + 0008h
in I/O) and checks the Rdy4Tx bit (bit 8). If
Rdy4Tx is clear then the CS8900A waits for the
next interrupt. If Rdy4Tx is set, then the
CS8900A is ready to accept the frame.
4) When the CS8900A is ready to accept the
frame, the host transfers the entire frame from
host memory to CS8900A memory using REP
instruction (REP MOVS to memory base +
0A00h in memory mode, and REP OUT to Receive/Transmit Data Port (I/O base + 0000h) in
I/O mode).
5.7.8 Completing Transmission
When the CS8900A successfully completes transmitting a frame, it sets the TxOK bit (Register 8,
TxEvent, Bit 8). If the TxOKiE bit (Register 7, TxCFG, bit 8) is set, the CS8900A generates a corresponding interrupt.
5.7.9 Rdy4TxNOW vs. Rdy4Tx
The Rdy4TxNOW bit (Register 18, BusST, bit 8) is
used to tell the host that the CS8900A is ready to
accept a frame for transmission. This bit is used
during the Transmit Request process or after the
Transmit Request process to signal the host that
space has become available when interrupts are not
being used (i.e. the Rdy4TxiE bit (Register B,
BufCFG, Bit 8) is not set). Also, the Rdy4Tx bit is
used with interrupts and requires the Rdy4TxiE bit
be set.
Figure 30 provides a diagram of error free transmission without collision.
5.7.10 Committing Buffer Space to a Transmit
Frame
When the host issues a transmit request, the
CS8900A checks the length of the transmit frame
to see if there is sufficient on-chip buffer space. If
there is, the CS8900A sets the Rdy4TxNOW bit. If
not, and the Rdy4TxiE bit is set, the CS8900A
waits for buffer space to free up and then sets the
Rdy4Tx bit. If Rdy4TxiE is not set, the CS8900A
sets the Rdy4TxNOW bit when space becomes
available.
Even though transmit buffer space may be available, the CS8900A does not commit buffer space to
a transmit frame until all of the following are true:
1) The host must issues a Transmit Request;
2) The Transmit Request must be successful; and,
3) Either the host reads that the Rdy4TxNOW bit
(Register 18, BusST, Bit 8) is set, or the host
reads that the Rdy4Tx bit (Register C, BufEvent, bit 8) is set.
If the CS8900A commits buffer space to a particular transmit frame, it will not allow subsequent
frames to be written to that buffer space as long as
the transmit frame is committed.
After buffer space is committed, the frame is subsequently transmitted unless any of the following
occur:
1) The host completely writes the frame data, but
transmission failed on the Ethernet line. There
are three such failures, and these are indicated
by three transmit error bits in the TxEvent register (Register 8): 16coll, Jabber, or Out-ofWindow.
Or:
2) The host aborts the transmission by setting the
Force (Register 9, TxCMD, bit 8) bit. In this
case, the committed transmit frame, as well as
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Enter Packet Transmit Process
Exit: can’t Issue command
Yes
Note: Issuing a command
at this point will cause
previous transmit frame
to be lost.
Is
TxCMD
pending?
No
Host Writes Transmit Command
to the TxCMD Register
Host Writes Transmit Frame
Length to the TxLength Register
Transmit Request
Host Reads the BusST
Register (Register 18)
Rdy4
TxNOW
bit = 1?
Yes
No
Exit WAIT-for-interrupt
Host Enters Interrupt Routine
Host Reads
ISQ
No
Yes
Rdy4Tx
bit = 1?
Process other events
that caused interrupt
CS8900A Commits
Buffer Space to
Transmit Frame
Host Writes
Transmit Frame
to CS8900A
CS8900A
Transmits Frame
Exit Transmit Process
Figure 31. Transmit Operation in Interrupt Mode
any yet-to-be-transmitted frames queued in the
on-chip memory, are cleared and not transmitted. The host should make TxLength = 0 when
using the Force bit.
Or:
3) There is a transmit under-run, and the TxUnderrun bit (Register C, BufEvent, Bit 9) is
set.
Successful transmission is indicated when the
TxOK bit (Register 8, TxEvent, Bit 8) is set.
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5.7.11 Transmit Frame Length
The length of the frame transmitted is determined
by the value written into the TxLength register
(PacketPage base + 0146h) during the Transmit
Request. The length of the transmit frame may be
modified by the configuration of the TxPadDis bit
(Register 9, TxCMD, Bit D) and the InhibitCRC bit
(Register 9, TxCMD, Bit C). Table 35 defines how
these bits affect the length of the transmit frame. In
addition, it shows which frames the CS8900A will
send.
5.8 Full duplex Considerations
The driver should not bid to transmit a long frame
(i.e., a frame greater than 118 bytes) if the prior
transmit frame is still being transmitted. The end of
the transmission of this prior frame is indicated by
a TxOK bit being set in the TxEvent register (register 8).
5.9 Auto-Negotiation Considerations
When the CS8900A is connected to an auto negotiation hub, and if auto-media detection is selected
(bits 8 and 9 of register 13), then the CS8900A may
not auto-select the 10BASE-T media. The cause of
this situation is described in the following paragraphs.
The original IEEE 802.3 specification requires the
MAC to wait until 4 valid link-pulses are received
before asserting Link-OK. Any time an invalid
link-pulse is received, the count is restarted. When
auto-negotiation occurs, a transmitter sends FLPs
(auto-negotiation Fast Link Pulses) bursts instead
of the original IEEE 802.3 NLP (Normal Link
Pulses).
If the hub is attempting to auto-negotiate with the
CS8900A, the CS8900A will never get more than 1
"valid" link pulse (valid NLP). This is not a problem if the CS8900A is already sending link-pulses,
because when the hub receives NLPs from the
CS8900A, the hub is required to stop sending FLPs
and start sending NLPs. The NLP transmitted by
the hub will put the CS8900A into Link-OK.
However, if the CS8900A is in Auto-Switch mode,
the CS8900A will never send any link-pulses, and
the hub will never change from sending FLPs to
sending NLPs.
Register 9, TxCMD
Host specified transmit length at 0146h (in bytes)
TxPad- InhibitCRC 3 < TxLength < 60
60 < TxLength <
1514 < TxLength < 1518 TxLength > 1518
Dis (Bit D)
(Bit C)
1514
0
0
Pad to 60 and add Send frame and add
Will not send
Will not send
CRC
CRC [Normal Mode]
0
1
Pad to 60 and
Send frame without
Send frame without
Will not send
send without CRC
CRC
CRC
1
0
Send without
Send frame and add
Will not send
Will not send
pads, and add
CRC
CRC
1
1
Send without
Send frame without
Send frame without
Wiill not send
pads and without
CRC
CRC
CRC
Notes: 8. If the TxPadDis bit is clear and InhibitCRC is set and the CS8900A is commanded to send a frame of
length less than 60 bytes, the CS8900A pads.
9. The CS8900A will not send a frame with TxLength less than 3 bytes.
Table 35. Transmit Frame Length
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
105
CS8900A
Crystal LAN™ ISA Ethernet Controller
6.0 TEST MODES
6.0.1 Loopback & Collision Diagnostic Tests
Internal and external Loopback and Collision tests
can be used to verify the CS8900A’s functionality
when configured for either 10BASE-T or AUI operation.
6.0.2 Internal Tests
Internal tests allow the major digital functions to be
tested, independent of the analog functions. During
these tests, the Manchester encoder is connected to
the decoder. All digital circuits are operational, and
the transmitter and receiver are disabled.
6.0.3 External Tests
External test modes allow the complete chip to be
tested without connecting it directly to an Ethernet
network.
Test Mode
10BASE-T Internal Loopback
10BASE-T Internal Collision
FDX
1
ENDECloop
1
0
1
10BASE-T
External Loopback
10BASE-T
External Collision
1
0
0
0
6.0.4 Loopback Tests
During Loopback tests, the internal Carrier Sense
(CRS) signal, used to detect collisions, is ignored,
allowing packet reception during packet transmission.
6.0.5 10BASE-T Loopback and Collision Tests
10BASE-T Loopback and Collision Tests are controlled by two bits in the Test Control register:
FDX (Register 19, TestCTL, Bit E) and ENDECloop (Register 19, TestCTL, Bit 9). Table 36 describes these tests.
6.0.6 AUI Loopback and Collision Tests
AUI Loopback and Collision tests are controlled by
two bits in the Test Control register: AUIloop
(Register 19, TestCTL, Bit A) and ENDECloop
(Register 19, TestCTL, Bit 9). Table 37 describes
these tests.
Description of Test
Transmit a frame and verify that the frame is received without
error.
Transmit frames and verify that collisions are detected and
that the internal counters function properly. After 16 colllisions, verify that 16coll (Register 8, TxEvent, Bit F) is set.
Connect TXD+ to RXD+ and TXD- to RXD-. Transmit a frame
and verify that the frame is received without error.
Connect TXD+ to RXD+ and TXD- to RXD-. Transmit frames
and verify that collisions are detected and that internal
counters function properly. After 16 collisions, verify that
16coll (Register 8, TxEvent, Bit F) is set.
Table 36. 10BASE-T Loopback and Collision Tests
Test Mode
AUI Internal
Loopback
AUI External
Loopback
AUI Collision
AUIloop ENDECloop
Description of Test
1
1
Transmit a frame and verify that the frame is received without error.
1
0
0
0
Connect DO+ to DI+ and DO- to DI-. Transmit a frame and verify
that the frame is received without error (since there is no collision
signal, an SQE error will occur).
Start transmission and observe DO+/DO- activity. Input a 10 MHz
sine wave to Cl+/Cl- pins and observe collisions.
Table 37. AUI Loopback and Collision Tests
CIRRUS LOGIC PRODUCT DATA SHEET
106
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
6.1 Boundary Scan
Boundary Scan test mode provides an easy and efficient board-level test for verifying that the
CS8900A has been installed properly. Boundary
Scan will check to see if the orientation of the chip
is correct, and if there are any open or short circuits.
Boundary Scan is controlled by the TEST pin.
When TEST is high, the CS8900A is configured
for normal operation. When TEST is low, the following occurs:
•
the CS8900A enters Boundary Scan test mode
and stays in this mode as long as TEST is low;
•
the CS8900A goes through an internal reset and
remains in internal reset as long as TEST is
low;
•
the AEN pin, normally the ISA bus Address
Enable, is redefined to become the Boundary
Scan shift clock input; and
•
all digital outputs and bi-directional pins are
placed in a high-impedance state (this electrically isolates the CS8900A digital outputs from
the rest of the circuit board).
For Boundary Scan to be enabled, AEN must be
low before TEST is driven low.
A complete Boundary Scan test is made up of two
separate cycles. The first cycle, known as the Output Cycle, tests all digital output pins and all bi-directional pins. The second cycle, known as the
Input Cycle, tests all digital input pins and all bi-directional pins.
6.1.1 Output Cycle
During the Output Cycle, the falling edge of AEN
causes each of the 17 digital output pins and each
of the 17 bi-directional pins to be driven low, one
at a time. The cycle begins with LINKLED and advances in order counterclockwise around the chip
through all 34 pins. This test is referred to as a
"walking 0" test.
The following is a list of output pins and bi-directional pins that are tested during the Output Cycle:
Pin Name
Pin #
Pin Name
Pin #
ELCS
2
INTRQ1
31
EECS
3
INTRQ0
32
EESK
4
IOCS16
33
EEDataOut
5
MEMCS16
34
DMARQ2
11
INTRQ3
35
DMARQ1
13
IOCHRDY
64
DMARQ0
15
SD0 - SD7 65-68, 71-74
CSOUT
17
BSTATUS
78
SD08-SD15 27-24, 21-18 LINKLED
99
INTRQ2
30
LANLED
100
Table 38.
The output pins not included in this test are:
Pin Name
DO+
DOTXD+
Pin #
83
84
87
Pin Name
TXDRES
XTAL2
Pin #
88
93
98
Table 39.
6.1.2 Input Cycle
During the Input Cycle, the falling edge of AEN
causes the state of each selected pin to be transferred to EEDataOut (that is, EEDataOut will be
high or low depending on the input level of the selected pin). This cycle begins with SLEEP and advances clockwise through each of 33 input pins (all
digital input pins except for AEN) and each of the
17 bi-directional pins, one pin at a time.
The following is a list of input pins and bi-directional pins that are tested during the Input Cycle:
Pin Name
Pin #
ELCS
2
EEDataIn
6
CHIPSEL
7
DMACK2
12
DMACK1
14
DMACK0
16
SD08-SD15 27-24, 21-18
MEMW
28
MEMR
29
Pin Name
Pin #
SBHE
36
SA0 - SA11
37-48
REFRESH
49
SA12 - SA19 50-54, 58-60
IOR
61
IOW
62
SD0 - SD7 65-68, 71-74
RESET
75
SLEEP
77
Table 40.
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
107
CS8900A
Crystal LAN™ ISA Ethernet Controller
The input pins not included in this test are:
Pin Name
AEN
TEST
Dl+
DlCl+
Pin #
63
76
79
80
81
Pin Name
ClRXD+
RXDXTAL1
Pin #
82
91
92
97
Table 41.
After the Input Cycle is complete, one more cycle
of AEN returns all digital output pins and bi-directional pins to a high-impedance state.
6.1.3 Continuity Cycle
The combination of a complete Output Cycle, a
complete Input Cycle, and an additional AEN cycle
is called a Continuity Cycle. Each Continuity Cycle
lasts for 85 AEN clock cycles. The first Continuity
Cycle can be followed by additional Continuity
Cycles by keeping TEST low and continuing to cycle AEN. When TEST is driven high, the CS8900A
exits Boundary Scan mode and AEN is again used
as the ISA-bus Address Enable.
Figure 32 shows a complete Boundary Scan Continuity Cycle.
Figure 33 shows Boundary Scan timing.
CIRRUS LOGIC PRODUCT DATA SHEET
108
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
Not in Boundary Scan
Test Mode
TEST switches low (AEN must be low)
ENTER BOUNDARY SCAN:
CS8900A resets, all digital
output pins and bi-directional
pins enter High-Z state,
and AEN becomes shift clock
AEN switches high
AEN switches low
34 cycles
OUTPUT CYCLE
AEN switches high
AEN switches low
50 cycles
INPUT CYCLE
AEN switches high
Selected output
goes low
Selected input
copied out
to the
EEDataOut
pin
AEN switches low
AEN switches high
All digital output pins and
bi-directional pins enters
High-Z state
TEST switches high
EXIT BOUNDARY SCAN:
AEN becomes ISA bus
Address Enable
Figure 32. Boundary Scan Continuity Cycle
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
109
CS8900A
Crystal LAN™ ISA Ethernet Controller
TESTSEL
AEN
Outputs
All outputs
tri-state
LINKLED LANLED
low
low
BSTATUS
low
EEDataOut
SLEEP
copied
out
OUTPUTS
Hi Z
OUTPUT
TEST
34 Clocks
RESET
copied
out
INPUT
TEST
50 Clocks
ELCS
copied
out
OUTPUTS
Hi Z
1 clock
COMPLETE CONTINUITY CYCLE
85 Clocks
Figure 33. Boundary Scan Timing
CIRRUS LOGIC PRODUCT DATA SHEET
110
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
7.0 CHARACTERISTICS/SPECIFICATIONS
7.1 ABSOLUTE MAXIMUM RATINGS (AVSS, DVSS = 0 V, all voltages with respect to 0 V.)
Parameter
Symbol
Min
Max
Unit
DVDD
-0.3
-0.3
6.0
6.0
V
V
-
±10.0
mA
Analog Input Voltage
-0.3
(AVDD+) + 0.3
V
Digital Input Voltage
-0.3
(DVDD) + 0.3
V
-55
+125
°C
-65
+150
°C
Power Supply
Digital
Analog
Input Current
AVDD
(Except Supply Pins)
Ambient Temperature
(Power Applied)
Storage Temperature
WARNING:
Normal operation is not guaranteed at these extremes.
7.2 RECOMMENDED OPERATING CONDITIONS (AVSS, DVSS = 0 V, all voltages with
respect to 0 V.)
Parameter
Symbol
Min
Max
Unit
Digital
Analog
DVDD
4.75
4.75
5.25
5.25
V
V
Digital
Analog
DVDD
AVDD
3.135
3.135
3.465
3.465
V
V
Operating Ambient Temperature CS8900A-CQ & -CQ3
TA
0
+70
°C
Operating Ambient Temperature CS8900A-IQ & -IQ3
TA
-40
+85
°C
5.0V Power Supply CS8900A-CQ & -IQ
3.3V Power Supply CS8900A-CQ3 & -IQ3
AVDD
7.3 DC CHARACTERISTICS (TA = 25 °C; VDD = 5.0 V or VDD = 3.3V)
Parameter
Symbol
Min
Max
Unit
XTAL1 Input Low Voltage
VIXH
-0.5
0.4
V
XTAL1 Input High Voltage
VIXH
3.5
XTAL1 Input Low Current
IIXL
-40
-
µA
XTAL1 Input High Current
IIXH
-
40
µA
Power Supply Current while Active 5.0V
IDD
-
55
mA
Power Supply Current while Active 3.3V
IDD
-
45
mA
Crystal (when using external clock - square wave)
DVDD
+ 0.5
V
Power Supply
Hardware Standby Mode Current
(Note 1) IDDSTNDBY
-
1.0
mA
Hardware Suspend Mode Current
(Note 1) IDDHWSUS
-
100
µA
Software Suspend Mode Current
(Note 1) IDDSWSUS
-
1.0
mA
Notes: 1. With digital outputs connected to CMOS loads.
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
111
CS8900A
Crystal LAN™ ISA Ethernet Controller
DC CHARACTERISTICS (Continued)
Parameter
Symbol
Min
Typ
Max
Unit
OD24, B24, O24ts
OD10
B4w, O4
VOL
-
-
0.4
0.4
0.4
V
V
V
Output Low Voltage (all outputs) VDD = 3.3V and TA = >70°C
VOL
0.425
V
V
V
Digital Inputs and Outputs
Output Low Voltage
(Note 2)
IOL = 24 mA
IOL = 10 mA
IOL = 4 mA
Output High Voltage
IOH = -12 mA
IOH = -2 mA
Output Leakage Current
0 ≤ VOUT ≤ VCC
OD24, OD10, B24, O24ts
B4w
ILL
Input Low Voltage
I, Iw
Input High Voltage
I, Iw
Input Leakage Current
B24
B4w, O24ts, O4
0 ≤ VIN ≤ VCC
2.4
2.4
-
-
-10
-20
-
10
10
VIL
-
-
0.8
V
VIH
2.4
-
-
V
-10
-20
-
10
10
VOH
µA
IL
I
Iw
µA
10BASE-T Interface
Transmitter Differential Output Voltage (Peak)
VOD
2.2
-
2.8
V
Receiver Normal Squelch Level (Peak)
VISQ
300
-
525
mV
Receiver Low Squelch Level (LoRxSquelch bit set)
VSQL
125
-
290
mV
Transmitter Differential Output Voltage (DO+/DO- Peak)
VAOD
±0.45
-
±1.2
V
Transmitter Undershoot Voltage
VAODU
-
-
100
mV
Transmitter Differential Idle Voltage (DO+/DO- Peak)
VIDLE
-
-
40
mV
Receiver Squelch Level (DI+/DI- Peak)
VAISQ
180
-
300
mV
AUI Interface
Notes: 2. OD24: Open Drain Output with 24 mA Drive
OD10: Open Drain Output with 10 mA Drive
B24: Bi-Directional with 3-State Output and 24 mA Drive
B4w: Bi-Directional with 3-State Output, Internal Weak Pullup, and 4 mA Drive
O24ts: 3-State Output with 24 mA Drive
O4: Output with 4 mA Drive
I: Input
Iw: Input with Internal Weak Pullup
CIRRUS LOGIC PRODUCT DATA SHEET
112
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
7.4 SWITCHING CHARACTERISTICS (TA = 25 °C; VDD = 5.0 V or VDD = 3.3V)
Parameter
Symbol
Min
Typ
Max
Unit
Address, AEN, SBHE active to IOCS16 low
tIOR1
-
-
35
ns
Address, AEN, SBHE active to IOR active
tIOR2
10
-
-
ns
IOR low to SD valid
tIOR3
-
-
135
ns
Address, AEN, SBHE hold after IOR inactive
tIOR4
0
-
-
ns
IOR inactive to active
tIOR5
35
-
-
ns
IOR inactive to SD 3-state
tIOR6
-
30
-
ns
IOR active to IORCHRDY inactive
tIOR7
-
30
-
ns
IOCHRDY low pulse width
tIOR8
125
-
175
ns
IOCHRDY active to SD valid
tIOR9
-
-
0
ns
16-Bit I/O Read, IOCHRDY Not Used
16-Bit I/O Read, With IOCHRDY
DIRECTION:
IN or OUT of chip
SA [15:0],
AEN, SBHE
Valid Address
IN
t IOR1
t IOR4
OUT
IOCS16
t IOR5
t IOR2
IOR
IN
t IOR6
t IOR3
SD [15:0]
OUT
Valid Data
16-Bit I/O Read, IOCHRDY not used
DIRECTION:
IN or OUT of chip
SA [15:0],
AEN, SBHE
Valid Address
IN
IOCS16
OUT
IOR
IN
t IOR7
IOCHRDY
OUT
t IOR8
SD [15:0]
Valid Data
OUT
t IOR9
16-Bit I/O Read, with IOCHRDY
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
113
CS8900A
Crystal LAN™ ISA Ethernet Controller
SWITCHING CHARACTERISTICS (Continued)
Parameter
Symbol
Min
Typ
Max
Unit
SA [19:0], SBHE, CHIPSEL, active to MEMCS16 low
tMEMR1
-
-
30
ns
Address, SBHE, CHIPSEL active to MEMR active
tMEMR2
10
-
-
ns
MEMR low to SD valid
tMEMR3
-
-
135
ns
Address, SBHE, CHIPSEL hold after MEMR inactive
tMEMR4
0
-
-
ns
MEMR inactive to SD 3-state
tMEMR5
-
30
-
ns
MEMR inactive to active
tMEMR6
35
-
-
ns
MEMR low to IOCHRDY inactive
tMEMR7
-
35
-
ns
IOCHRDY low pulse width
tMEMR8
125
-
175
ns
IOCHRDY active to SD valid
tMEMR9
-
-
0
ns
16-Bit Memory Read, IOCHRDY Not Used
16-Bit Memory Read, With IOCHRDY
DIRECTION:
IN or OUT of chip
SA [19:0],
SBHE,
CHIPSEL
Valid Address
IN
t MEMR1
t MEMR4
MEMCS16
OUT
t MEMR6
t MEMR2
MEMR
IN
t MEMR3
SD [15:0]
t MEMR5
Valid Data
OUT
16-Bit Memory Read, IOCHRDY not used
DIRECTION:
IN or OUT of chip
SA [19:0],
SBHE,
CHIPSEL
Valid Address
IN
MEMCS16
OUT
MEMR
IN
t MEMR7
IOCHRDY
OUT
t MEMR8
SD [15:0]
Valid Data
OUT
t MEMR9
16-Bit Memory Read, with IOCHRDY
CIRRUS LOGIC PRODUCT DATA SHEET
114
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
SWITCHING CHARACTERISTICS (Continued)
Parameter
Symbol
Min
Typ
Max
Unit
DMACKx active to IOR active
tDMAR1
60
-
-
ns
AEN active to IOR active
tDMAR2
10
-
-
ns
IOR active to Data Valid
tDMAR3
-
-
135
ns
IOR inactive to SD 3-state
tDMAR4
-
30
-
ns
IOR n-1 high to DMARQx inactive
tDMAR5
-
-
20
ns
DMACKx, AEN hold after IOR high
tDMAR6
20
Address, AEN, SBHE valid to IOCS16 low
tIOW1
-
-
35
ns
Address, AEN, SBHE valid to IOW low
tIOW2
20
-
-
ns
IOW pulse width
tIOW3
110
-
-
ns
SD hold after IOW high
tIOW4
0
-
-
ns
IOW low to SD valid
tIOW5
-
-
10
ns
IOW inactive to active
tIOW6
35
-
-
ns
Address hold after IOW high
tIOW7
0
-
-
ns
DMA Read
ns
16-Bit I/O Write
DIRECTION:
IN or OUT of chip
tDMA5
OUT
DMARQx
tDMA6
tDMA1
DMACKx
IN
IN
AEN
tDMA2
IORn-1
IOR
tDMA3
IORn
IN
tDMA4
Valid
Data
SD[15:0]
Valid
Data
Valid
Data
OUT
16-Bit DMA Read
DIRECTION:
IN or OUT of chip
SA [15:0],
AEN, SBHE
Valid Address
t IOW1
IN
t IOW7
IOCS16
OUT
t IOW3
t IOW2
t IOW6
IOW
IN
t IOW4
t IOW5
SD [15:0]
Valid Data In
IN
16-Bit I/O Write
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
115
CS8900A
Crystal LAN™ ISA Ethernet Controller
SWITCHING CHARACTERISTICS (Continued)
Parameter
Symbol
Min
Typ
Max
Unit
Address, SBHE, CHIPSEL valid to MEMCS16 low
tMEMW1
-
-
30
ns
Address, SBHE, CHIPSEL valid to MEMW low
tMEMW2
20
-
-
ns
MEMW pulse width
tMEMW3
110
-
-
ns
MEMW low to SD valid
tMEMW4
-
-
40
ns
SD hold after MEMW high
tMEMW5
0
-
-
ns
Address hold after MEMW inactive
tMEMW6
0
-
-
ns
MEMW inactive to active
tMEMW7
35
-
-
ns
TXD Pair Jitter into 100 Ω Load
tTTX1
-
-
8
ns
TXD Pair Return to ≤ 50 mV after Last Positive Transition
tTTX2
-
-
4.5
µs
TXD Pair Positive Hold Time at End of Packet
tTTX3
250
-
-
ns
16-Bit Memory Write
10BASE-T Transmit
DIRECTION:
IN or OUT of chip
SA [19:0],
SBHE,
CHIPSEL
Valid Address
IN
t MEMW1
t MEMW6
MEMCS16
OUT
t MEMW2
t MEMW3
t MEMW7
MEMW
IN
t MEMW4
SD [15:0]
t MEMW5
Valid Data In
IN
16-Bit Memory Write
tTTX2
TXD±
tTTX3
tTTX1
10BASE-T Transmit
CIRRUS LOGIC PRODUCT DATA SHEET
116
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
SWITCHING CHARACTERISTICS (Continued)
Parameter
Symbol
Min
Typ
Max
Unit
Allowable Received Jitter at Bit Cell Center
tTRX1
-
-
±13.5
ns
Allowable Received Jitter at Bit Cell Boundary
tTRX2
-
-
±13.5
ns
Carrier Sense Assertion Delay
tTRX3
-
540
-
ns
Invalid Preamble Bits after Assertion of Carrier Sense
tTRX4
1
-
2
bits
Carrier Sense Deassertion Delay
tTRX5
-
270
-
ns
First Transmitted Link Pulse after Last Transmitted Packet
tLN1
8
16
24
ms
Time Between Transmitted Link Pulses
tLN2
8
16
24
ms
Width of Transmitted Link Pulses
tLN3
60
100
200
ns
Minimum Received Link Pulse Separation
tLN4
2
-
7
ms
Maximum Received Link Pulse Separation
tLN5
25
-
150
ms
Last Receive Activity to Link Fail (Link Loss Timer)
tLN6
50
-
150
ms
10BASE-T Receive
10BASE-T Link Integrity
RXD±
tTRX1
tTRX3
tTRX2
tTRX5
tTRX4
Carrier Sense (internal)
10BASE-T Receive
t LN1
t LN2
t LN3
TXD±
t LN4
t LN5
RXD±
t LN6
LINKLED
10BASE-T Link Integrity
CIRRUS LOGIC PRODUCT DATA SHEET
DS271PP3
117
CS8900A
Crystal LAN™ ISA Ethernet Controller
SWITCHING CHARACTERISTICS (Continued)
Parameter
Symbol
Min
Typ
Max
Unit
DO Pair Rise and Fall Times
tATX1
-
-
5
ns
DO Pair Jitter at Bit Cell Center
tATX2
-
-
0.5
ns
DO Pair Postitive Hold Time at Start of Idle
tATX3
200
-
-
ns
DO Pair Return to ≤ 40 mVp affter Last Positive Transition
tATX4
-
-
8.0
µs
DI Pair Rise and Fall Time
tARX1
-
-
10
ns
Allowable Bit Cell Center and Boundary Jitter in Data
tARX2
-
-
±18
ns
Carrier Sense Assertion Delay
tARX3
-
240
-
ns
Invalid Preamble Bits after Carrier Sense Asserts
tARX4
1
-
2
bits
Carrier Sense Deassertion Delay
tARX5
150
-
250
ns
CI Pair Cycle Time
tACL1
85
100
115
ns
CI Pair Rise and Fall Times
tACL2
-
-
10
ns
CI Pair Return to Zero from Last Positive Transition
tACL3
160
-
-
ns
Collision Assertion Delay
tACL4
50
-
200
ns
Collision Deassertion Delay
tACL5
150
-
300
ns
AUI Transmit
AUI Receive
AUI Collision
0
0
0
1
t ATX4
DO±
t ATX1
t ATX1
t ATX3
t ATX2
AUI Transmit
0
1
0
1
DI±
t ARX1
t ARX2
t ARX1
t ARX3
t ARX4
t ARX5
Carrier Sense (Internal)
AUI Receive
CI±
t ACL1
t ACL4
t ACL3
t ACL2
t ACL2
t ACL5
Collision (Internal)
AUI Collision
CIRRUS LOGIC PRODUCT DATA SHEET
118
DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
SWITCHING CHARACTERISTICS (Continued)
Parameter
Symbol
Min
Typ
Max
Unit
Address active to MEMR
tBPROM1
20
-
-
ns
MEMR active to CSOUT low
tBPROM2
-
-
35
ns
MEMR inactive to CSOUT high
tBPROM3
-
-
40
ns
EESK Setup time relative to EECS
tSKS
100
-
-
ns
EECS/ELCS_b Setup time wrt ↑ EESK
tCCS
250
-
-
ns
EEDataOut Setup time wrt ↑ EESK
tDIS
250
-
-
ns
EEDataOut Hold time wrt ↑ EESK
tDIH
500
-
-
ns
EEDataIn Hold time wrt ↑ EESK
tDH
10
-
-
ns
EECS Hold time wrt ↓ EESK
tCSH
100
-
-
ns
Min EECS Low time during programming
tCS
1000
-
-
ns
External Boot PROM Access
EEPROM
CS
SA [19:0]
t BPROM1
MEMR
t BPROM2
t BPROM3
CSOUT
External Boot PROM Access
EESK
t SKS
EECS
t CSS
t CSH
t CS
t DIH
t DIS
EEData Out
t DH
EEData In
(Read)
EEPROM
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CS8900A
Crystal LAN™ ISA Ethernet Controller
7.5 10BASE-T WIRING
1:
CS8900A
TXD +
2
TD +
Rt
1
68 pF
TXD -
Rt
TD -
0.01 µF
2
RJ45
1:1
RXD+
+
-
RXD-
0.01 µF
RD +
3
Rr
Rr
RD -
6
•
If a center tap transformer is used on the RXD+ and RXD- inputs, replace the pair of Rr resistors with
a single 2xRr resistor.
•
The Rt and Rr resistors are ±1% tolerance.
•
The CS8900A supports 100, 120, and 150 Ω unshielded twisted pair cables. The proper values of Rt
and Rr, for a given cable impedence, are shown below:
•
Cable Impedance (Ω)
Rt (Ω)
Rr (Ω)
100
24.3
49.9
120
30.1
60.4
150
37.4
75
Note: for 3.3V operation the turns ratio on TXD+ and TXD- is 1:2.5, rt is 8Ω for 100Ω cable and the
68pF cap changes to 560pF.
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DS271PP3
CS8900A
Crystal LAN™ ISA Ethernet Controller
7.6 AUI WIRING
CS8900A
DB15
1:1
DO +
Tx
3
DO -
10
4
1:1
CI +
+
Col
-
0.01 uF
CI -
2
39.2 Ω
39.2 Ω
9
1:1
DI +
+
Rx
-
0.01 uF
DI -
5
39.2 Ω
39.2 Ω
12
13
6
+12 V
7.7 QUARTZ CRYSTAL REQUIREMENTS (If a 20 MHz quartz crystal is used, it must meet the
following specifications)
Parameter
Min
Typ
Max
Unit
-
20
-
MHz
Resonant Frequency Error (CL = 18 pF)
-50
-
+50
ppm
Resonant Frequency Change Over Operating Temperature
-40
-
+40
ppm
Crystal Capacitance
-
-
18
pF
Motional Crystal Capacitance
-
0.022
-
pF
Series Resistance
-
-
50
Ohm
Shunt Capacitance
-
-
7
pF
Parallel Resonant Frequency
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CS8900A
Crystal LAN™ ISA Ethernet Controller
8.0 PHYSICAL DIMENSIONS
100L TQFP PACKAGE DRAWING
E
E1
D D1
1
e
B
∝
A
A1
L
INCHES
MIN
MAX
--0.063
0.002
0.006
0.007
0.011
0.618
0.642
0.547
0.555
0.618
0.642
0.547
0.555
0.016
0.024
0.018
0.030
∝
0.000°
7.000°
* Nominal pin pitch is 0.50 mm
DIM
A
A1
B
D
D1
E
E1
e*
L
MILLIMETERS
MIN
MAX
--1.60
0.05
0.15
0.17
0.27
15.70
16.30
13.90
14.10
15.70
16.30
13.90
14.10
0.40
0.60
0.45
0.75
0.00°
7.00°
Controlling dimension is mm.
JEDEC Designation: MS026
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CS8900A
Crystal LAN™ ISA Ethernet Controller
9.0 GLOSSARY OF TERMS
9.1 Acronyms
AUI
CRC
CS
CSMA/CD
DA
EEPROM
EOF
FCS
FDX
IA
IPG
ISA
LA
LLC
MAC
MAU
MIB
RX
SA
SFD
SNMP
SOF
SQE
TDR
TX
UTP
Attachment Unit Interface
Cyclic Redundancy Check
Carrier Sense
Carrier Sense Multiple Access with Collision Detection
Destination Address
Electrically Erasable Programmable Read Only Memory
End-of-Frame
Frame Check Sequence
Full Duplex
Individual Address
Inter-Packet Gap
Industry Standard Architecture
ISA Latchable Address Bus (LA17 - LA23)
Logical Link Control
Media Access Control
Medium Attachment Unit
Management Information Base
Receive
Source Address or ISA System Address Bus (SA0 - SA19)
Start-of-Frame Delimiter
Simple Network Management Protocol
Start-of-Frame
Signal Quality Error
Time Domain Reflectometer
Transmit
Unshielded Twisted Pair
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CS8900A
Crystal LAN™ ISA Ethernet Controller
9.2 Definitions
Cyclic Redundancy Check
The method used to compute the 32-bit frame check sequence (FCS).
Frame Check Sequence
The 32-bit field at the end of a frame that contains the result of the cyclic redundancy check
(CRC).
Frame
An Ethernet string of data bits that includes the Destination Address (DA), Source Address
(SA), optional length field, Logical Link Control data (LLC data), pad bits (if needed) and
Frame Check Sequence (FCS).
Individual Address
The specific Ethernet address assigned to a device attached to the Ethernet media.
Inter-Packet Gap
Time interval between packets on the Ethernet. Minimum interval is 9.6 ms.
Jabber
A condition that results when a Ethernet node transmits longer than between 20 ms and 150
ms.
Packet
An Ethernet string of data bits that includes the Preamble, Start-of-Frame Delimiter (SFD),
Destination Address (DA), Source Address (SA), optional length field, Logical Link Control
data (LLC data), pad bits (if needed) and Frame Check Sequence (FCS). A packet is a frame
plus the Preamble and SFD.
Receive Collision
A receive collision occurs when the CI+/CI- inputs are active while a packet is being received.
Applies only to the AUI.
Signal Quality Error
When transmitting on the AUI, the MAC expects to see a collision signal on the CI+/CI- pair
within 64 bit times after the end of a transmission. If no collision occurs, there is said to be an
"SQE error". Applies only to the AUI.
Slot Time
Time required for an Ethernet Frame to cross a maximum length Ethernet network. One Slot
Time equals 512 bit times.
Transmit Collision
A transmit collision occurs when the receive inputs, RXD+/RXD- (10BASE-T) or CI+/CI(AUI) are active while a packet is being transmitted.
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CS8900A
Crystal LAN™ ISA Ethernet Controller
9.3 Acronyms Specific to the CS8900A
BufCFG
Buffer Configuration - Register B
BufEvent
Buffer Event - Register C
BusCTL
Bus Control - Register 17
BusST
Bus State - Register 18
ENDEC
Manchester encoder/decoder
ISQ
Interrupt Status Queue - register 0
LineCTL
Ethernet Line Control - Register 13
LineST
Ethernet Line Status - Register 14
RxCFG
Receive Configuration - Register 3
RxCTL
Receive Control - Register 5
RxEvent
Receive Event - Register 4
SelfCTL
Self Control - Register 15
SelfST
Self Status - Register 16
TestCTL
Test Control - Register 19
TxCFG
Transmit Configuration - Register 7
TxCMD
Transmit Command - Register 9
TxEvent
Transmit Event - Register 8
9.4 Terms Specific to the CS8900A
Act-Once bit
A control bit that causes the CS8900A to take a certain action once when a logic "1" is written
to that bit. To cause the action again, the host must rewrite a "1".
Committed Receive Frame
A receive frame is said to be "committed" after the frame has been buffered by the CS8900A,
and the host has been notified, but the frame has not yet been transferred by the host.
Committed Transmit Frame
A transmit frame is said to be "committed" after the host has issued a Transmit Command, and
the CS8900A has reserved buffer space and notified the host that it is ready for transmit.
Event or Interrupt Event
The term "Event" is used in this document to refer to something that can trigger an interrupt.
Items that are considered "Events" are reported in the three Event registers (RxEvent, TxEvent,
or BufEvent) and in two counter-overflow bits (RxMISS and TxCOL).
StreamTransfer
A method used to significantly reduce the number of interrupts to the host processor during
block data transfers (Patent Pending).
PacketPage
A unified, highly-efficient method of controlling and getting status of a peripheral controller in
I/O or Memory space.
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Crystal LAN™ ISA Ethernet Controller
Standby
A feature of the CS8900A used to conserve power. When in Standby mode, the CS8900A can
be awakened either by 10BASE-T activity or host command.
Suspend
A feature of the CS8900A used to conserve power. When in Suspend mode, the CS8900A can
be awakened only by host command.
Transfer
The term "transfer" refers to moving frame data across the ISA bus to or from the CS8900A.
Transmit Request
A Transmit Request is issued by the host to initiate the start of a new packet transmission. A
Transmit Request consists of the following three steps in exactly the order shown:
1) The host writes a Transmit Command to the TxCMD register (PacketPage base + 0144h).
2) The host writes the transmit frame’s length to the TxLength register (PacketPage base + 0146h).
3) The host reads BusST (Register 18) to see in the Rdy4TxNOW bit (Bit 8) is set.
9.5 Suffixes Specific to the CS8900A.
These terms have meaning only at the end of a term:
A
CMD
CFG
CTL
Dis
E
h
iE
ST
Accept
Command
Configure
Control
Disable
Enable
Indicates the number is hexadecimal
Interrupt Enable
Status
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• Notes •
Preliminary product information describes products which are in production, but for which full characterization data is not yet available. Advance product information
describes products which are in development and subject to development changes. Cirrus Logic, Inc. has made best efforts to ensure that the information contained
in this document is accurate and reliable. However, the information is subject to change without notice and is provided “AS IS” without warranty of any kind (express
or implied). No responsibility is assumed by Cirrus Logic, Inc. for the use of this information, nor for infringements of patents or other rights of third parties. This
document is the property of Cirrus Logic, Inc. and implies no license under patents, copyrights, trademarks, or trade secrets. No part of this publication may be copied,
reproduced, stored in a retrieval system, or transmitted, in any form or by any means (electronic, mechanical, photographic, or otherwise) without the prior written
consent of Cirrus Logic, Inc. Items from any Cirrus Logic website or disk may be printed for use by the user. However, no part of the printout or electronic files may
be copied, reproduced, stored in a retrieval system, or transmitted, in any form or by any means (electronic, mechanical, photographic, or otherwise) without the prior
written consent of Cirrus Logic, Inc.Furthermore, no part of this publication may be used as a basis for manufacture or sale of any items without the prior written consent
of Cirrus Logic, Inc. The names of products of Cirrus Logic, Inc. or other vendors and suppliers appearing in this document may be trademarks or service marks of
their respective owners which may be registered in some jurisdictions. A list of Cirrus Logic, Inc. trademarks and service marks can be found at http://www.cirrus.com.