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FINAL
AM79C940
Media Access Controller for Ethernet (MACETM)
DISTINCTIVE CHARACTERISTICS
s s s s Integrated Controller with 10BASE-T transceiver and AUI port Supports IEEE 802.3/ANSI 8802-3 and Ethernet standards 84-pin PLCC and 100-pin PQFP Packages 80-pin Thin Quad Flat Pack (TQFP) package available for space critical applications such as PCMCIA Modular architecture allows easy tuning to specific applications High speed, 16-bit synchronous host system interface with 2 or 3 cycles/transfer Individual transmit (136 byte) and receive (128 byte) FlFOs provide increase of system latency and support the following features: - Automatic retransmission with no FIFO reload - Automatic receive stripping and transmit padding (individually programmable) - Automatic runt packet rejection - Automatic deletion of collision frames - Automatic retransmission with no FIFO reload s Direct slave access to all on board configuration/status registers and transmit/ receive FlFOs Direct FIFO read/write access for simple interface to DMA controllers or l/O processors s s s s s
Advanced Micro Devices
s
s s s
s s
s
Arbitrary byte alignment and little/big endian memory interface supported Internal/external loopback capabilities External Address Detection Interface (EADITM) for external hardware address filtering in bridge/router applications JTAG Boundary Scan (IEEE 1149.1 ) test access port interface for board level production test Integrated Manchester Encoder/Decoder Digital Attachment Interface (DAITM) allows by-passing of differential Attachment Unit Interface (AUI) Supports the following types of network interface: - AUI to external 10BASE2, 10BASE5 or 10BASE-F MAU - DAI port to external 10BASE2, 10BASE5, 10BASE-T, 10BASE-F MAU - General Purpose Serial Interface (GPSI) to external encoding/decoding scheme - Internal 10BASE-T transceiver with automatic selection of 10BASE-T or AUI port Sleep mode allows reduced power consumption for critical battery powered applications 1 MHz - 25 MHz system clock speed
s
GENERAL DESCRIPTION
The Media Access Controller for Ethernet (MACE) chip is a CMOS VLSI device designed to provide flexibility in customized LAN design. The MACE device is specifically designed to address applications where multiple I/O peripherals are present, and a centralized or system specific DMA is required. The high speed, 16-bit synchronous system interface is optimized for an external DMA or I/O processor system, and is similar to many existing peripheral devices, such as SCSI and serial link controllers. The MACE device is a slave register based peripheral. All transfers to and from the system are performed using simple memory or I/O read and write commands. In conjunction with a user defined DMA engine, the MACE chip provides an IEEE 802.3 interface tailored to a specific application. Its superior modular architecture and versatile system interface allow the MACE device to be configured as a stand-alone device or as a connectivity cell incorporated into a larger, integrated system. The MACE device provides a complete Ethernet node solution with an integrated 10BASE-T transceiver, and supports up to 25-MHz system clocks. The MACE device embodies the Media Access Control (MAC) and Physical Signaling (PLS) sub-layers of the IEEE 802.3 standard, and provides an IEEE defined Attachment Unit Interface (AUI) for coupling to an external Medium Attachment Unit (MAU). The MACE device is compliant with 10BASE2, 10BASE5, 10BASE-T, and 10BASE-F transceivers.
Publication#16235 Rev. C Issue Date: June 1994
Amendment /0
AMD Additional features also enhance over-all system design. The individual transmit and receive FIFOs optimize system overhead, providing substantial latency during packet transmission and reception, and minimizing intervention during normal network error recovery. The integrated Manchester encoder/decoder eliminates the need for an external Serial Interface Adapter (SIA) in the node system. If support for an external encoding/decoding scheme is desired, the General Purpose Serial Interface (GPSI) allows direct access to/from the MAC. In addition, the Digital Attachment Interface (DAI), which is a simplified electrical attachment specification, allows implementation of MAUs that do not require DC isolation between the MAU and DTE. The DAI port can also be used to indicate transmit, receive, or collision status by connecting LEDs to the port. The MACE device also provides an External Address Detection Interface (EADI) to allow external hardware address applications. filtering in internetworking
The AM79C940 MACE chip is offered in a Plastic Leadless Chip Carrier (84-pin PLCC), a Plastic Quad Flat Package (100-pin PQFP), and a Thin Quad Flat Package (TQFP 80-pin). There are several small functional and physical differences between the 80-pin TQFP and the 84-pin PLCC and 100-pin PQFP configurations. Because of the smaller number of pins in the TQFP configuration versus the PLCC configuration, four pins are not bonded out. Though the die is identical in all three package configurations, the removal of these four pins does cause some functionality differences between the TQFP and the PLCC and PQFP configurations. Depending on the application, the removal of these pins will or will not have an effect.
BLOCK DIAGRAM
XTAL1 XTAL2
ENCODER/ DECODER (PLS) EADI Port Control DBUS 15-0 ADD 4-0 R/W CS FDS DTV EOF RDTREQ TDTREQ BE 1-0 INTR SCLK EDSEL TC SLEEP RESET RCV FIFO XMT FIFO FIFO Control Bus Interface Unit Command & Status Registers 802.3 MAC Core AUI Port
DXCVR CLSN SRDCLK SRD SF/BD EAM/R DO DI CI TXD TXP RXD LNKST RXPOL TXDAT TXEN RXDAT RXCRS STDCLK TXDAT+ TXEN SRDCLK RXDAT RXCRS CLSN
EADI Port
AUI
10BASE-T MAU
10BASE-T
DAI Port
DAI Port
GPSI Port JTAG PORT CNTRL
GPSI
TDI
TDO
16235C-1
Notes:
TCK
TMS
1. Only one of the network ports AUI, 10BASE-T, DAI port or GPSI can be active at any time. Some shared signals are active regardless of which network port is active, and some are reconfigured. 2. The EADI port is active at all times.
2
AM79C940
AMD
RELATED PRODUCTS
Part No. Am7996 Am79C90 Am79C98 Am79C100 Am79C981 Am79C987 Am79C900 Am79C961 Am79C965 Am79C970 Am79C974 Description IEEE 802.3/Ethernet/Cheapernet Transceiver CMOS Local Area Network Controller for Ethernet (C-LANCE) Twisted Pair Ethernet Transceiver (TPEX) Twisted Pair Ethernet Transceiver Plus (TPEX+) Integrated Multiport Repeater PlusTM (IMR+TM) Hardware Implemented Management Information BaseTM (HIMIBTM) Integrated Local Area Communications ControllerTM (ILACCTM) PCnet-ISA+ Single-Chip Ethernet Controller for ISA (with Microsoft(R) Plug n' Play Support) PCnet-32 Single-Chip 32-Bit Ethernet Controller PCnet-PCI Single-Chip Ethernet Controller (for PCI bus) PCnet-SCSI Combination Ethernet and SCSI Controller for PCI Systems
AM79C940
3
AMD TABLE OF CONTENTS DISTINCTIVE CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-64 GENERAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-64 BLOCK DIAGRAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-65 RELATED PRODUCTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-66 CONNECTION DIAGRAMS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PLCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PQR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PQT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-70 1-70 1-71 1-72
ORDERING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-73 PIN/PACKAGE SUMMARY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-74 PIN DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Network Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Attachment Unit Interface (AUI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Digital Attachment Interface (DAITM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10BASE-T Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Purpose Serial Interface (GPSI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . External Address Detection Interface (EADITM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Host System Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IEEE 1149.1 Test Access Port (TAP) Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-82 1-82 1-82 1-82 1-85 1-85 1-86 1-88 1-89 1-89 1-90
FUNCTIONAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-92 Network Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-92 System Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-92 DETAILED FUNCTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-93 Block Level Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-93 Bus Interface Unit (BIU) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-93 BIU to FIFO Data Path . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-93 BIU to Control and Status Register Data Path . . . . . . . . . . . . . . . . . . . . . . . . . 1-94 FIFO Sub-System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-94 Media Access Control (MAC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-96 Manchester Encoder/Decoder (MENDEC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-100 Attachment Unit Interface (AUI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-103 Digital Attachment Interface (DAI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-103 10BASE-T Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-104 Twisted Pair Transmit Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-104 Twisted Pair Receive Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-104 Link Test Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-105 Polarity Detection and Reversal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-105 Twisted Pair Interface Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-106 Collision Detect Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-106 Signal Quality Error (SQE) Test (Heartbeat) Function . . . . . . . . . . . . . . . . . . 1-106 Jabber Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-106 4 AM79C940
AMD
External Address Detection Interface (EADI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Purpose Serial Interface (GPSI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IEEE 1149.1 Test Access Port Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Slave Access Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Read Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Write Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reinitialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit FIFO Write . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit Function Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Automatic Pad Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit FCS Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit Status Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit Exception Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive FIFO Read . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Function Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Automatic Pad Stripping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive FCS Checking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Status Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Exception Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Loopback Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . USER ACCESSIBLE REGISTERS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive FIFO (RCVFIFO) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit FIFO (XMTFIFO) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit Frame Control (XMTFC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit Frame Status (XMTFS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transmit Retry Count (XMTRC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Frame Control (RCVFC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Frame Status (RCVFS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RFS0--Receive Message Byte Count (RCVCNT) . . . . . . . . . . . . . . . . . . . . . . . . . RFS1--Receive Status (RCVSTS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RFS2--Runt Packet Count (RNTPC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RFS3--Receive Collision Count (RCVCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FIFO Frame Count (FIFOFC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interrupt Register (IR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interrupt Mask Register (IMR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Poll Register (PR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BIU Configuration Control (BIUCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FIFO Configuration Control (FIFOCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . MAC Configuration Control (MACCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PLS Configuration Control (PLSCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PHY Configuration Control (PHYCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Chip Identification Register (CHIPID [15-00]) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Internal Address Configuration (IAC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Logical Address Filter (LADRF [63-00]) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AM79C940
1-107 1-108 1-108 1-109 1-109 1-110 1-110 1-110 1-110 1-111 1-111 1-112 1-113 1-113 1-113 1-115 1-115 1-116 1-116 1-117 1-117 1-117 1-118 1-120 1-120 1-120 1-120 1-121 1-122 1-122 1-123 1-123 1-123 1-124 1-124 1-124 1-124 1-126 1-126 1-127 1-127 1-129 1-130 1-130 1-131 1-131 1-132 5
AMD Physical Address (PADR [47-00]) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Missed Packet Count (MPC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Runt Packet Count (RNTPC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Collision Count (RCVCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . User Test Register (UTR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reserved Test Register 1 (RTR1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reserved Test Register 2 (RTR2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Register Table Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Register Bit Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-Bit Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-Bit Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Receive Frame Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Programmer's Register Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SYSTEM APPLICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HOST SYSTEM EXAMPLES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Motherboard DMA Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . System Interface-Motherboard DMA Example . . . . . . . . . . . . . . . . . . . . . . . . PC/AT Ethernet Adapter Card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . System Interface-Simple PC/AT Ethernet Hypercard Example . . . . . . . . . . . NETWORK INTERFACES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . External Address Detection Interface (EADI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Attachment Unit Interface (AUI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10BASE-T Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10BASE -T and 10BASE2 Configuration of AM79C940 . . . . . . . . . . . . . . . . . . . . . 10BASE -T and AUI Implementation of AM79C940 . . . . . . . . . . . . . . . . . . . . . . . . MACE Device Compatible AUI Isolation Transformers . . . . . . . . . . . . . . . . . . . . . MACE Device Compatible 10BASE-T Media Interface Modules . . . . . . . . . . . . . . 1-134 1-134 1-134 1-135 1-135 1-136 1-136 1-137 1-138 1-138 1-138 1-138 1-139 1-142 1-142 1-142 1-143 1-144 1-145 1-145 1-145 1-146 1-147 1-148 1-149 1-150 1-150
ABSOLUTE MAXIMUM RATINGS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-152 OPERATING RANGES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-152 DC CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-152 AC CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-155 BIU Output Valid Delay vs. Load Chart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-159 KEY TO SWITCHING WAVEFORMS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-159 SWITCHING TEST CIRCUITS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-160 AC WAVEFORMS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-161 APPENDIX A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-179 LOGICAL ADDRESS FILTERING FOR ETHERNET . . . . . . . . . . . . . . . . . . . . . . . . . . 1-179 MAPPING OF LOGICAL ADDRESS TO FILTER MASK . . . . . . . . . . . . . . . . . . . . . . . 1-180 APPENDIX B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-181 BSDL DESCRIPTION OF AM79C940 MACE JTAG STRUCTURE . . . . . . . . . . . . . . . 1-181
6
AM79C940
AMD
CONNECTION DIAGRAMS PL 084 PLCC Package
SRDCLK EAM/R SRD SF/BD RESET SLEEP DVDD INTR TC DBUS0 DVSS DBUS1 DBUS2 DBUS3 DBUS4 DVSS DBUS5 DBUS6 DBUS7 DBUS8 DBUS9
11 10 9 8 7 6 5 4 12 13 14 15 16 17 18
RXCRS RXDAT CLSN TXEN/TXEN STDCLK DVSS TXDATTXDAT+ DVSS EDSEL DXCVR DVDD AVDD CI+ CIDI+ DIAVDD DO+ DOAVSS
3 2 1 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67
19 66 20 AM79C940 21 65 MACE MACE 64 22 AM79C940JC 63 23 62 24 61 25 60 26 59 27 58 28 57 29 56 30 55 31 54 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53
XTAL2 AVSS XTAL1 AVDD TXD+ TXP+ TXDTXPAVDD RXD+ RXDDVDD TDI DVSS TCK TMS TDO LNKST RXPOL CS R/W
DBUS10 DBUS11 DBUS12 DBUS13 DVDD DBUS14 DBUS15 DVSS EOF DTV FDS BE0 BE1 SCLK TDTREQ RDTREQ ADD0 ADD1 ADD2 ADD3 ADD4
16235C-2
AM79C940
7
AMD
CONNECTION DIAGRAMS PQR 100 PQFP Package
NC NC NC NC SRDCLK EAM/R SRD SF/BD RESET SLEEP DVDD INTR TC DBUS0 DVSS DBUS1 DBUS2 DBUS3 DBUS4 DVSS DBUS5 DBUS6 DBUS7 DBUS8 DBUS9 NC NC NC DBUS10 NC
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 26 27 28 29 30
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 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
RXCRS RXDAT CLSN TXEN/TXEN STDCLK DVSS TXDATTXDAT+ DVSS EDSEL DXCVR DVDD AVDD CI+ CIDI+ DIAVDD DO+ DO-
MACE AM79C940KC MACE AM79C940KC
NC AVSS NC NC NC XTAL2 AVSS XTAL1 AVDD TXD+ TXP+ TXDTXPAVDD RXD+ RXDDVDD TDI DVSS TCK TMS TDO LNKST RXPOL CS R/W NC NC NC NC
DBUS11 DBUS12 DBUS13 DVDD DBUS14 DBUS15 DVSS EOF DTV FDS BE0 BE1 SCLK TDTREQ RDTREQ ADD0 ADD1 ADD2 ADD3 ADD4
31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50
16235C-3
8
AM79C940
AMD
CONNECTION DIAGRAMS PQT 080 TQFP Package
RXCRS RXDAT CLSN TXEN/TXEN STDCLK DVSS TXDAT+ DVSS EDSEL DXCVR DVDD AVDD CI+ CIDI+ DIAVDD DO+ DOAVSS 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 SRDCLK EAM/R SF/BD RESET SLEEP DVDD INTR TC DBUS0 DVSS DBUS1 DBUS2 DBUS3 DBUS4 DVSS DBUS5 DBUS6 DBUS7 DBUS8 DBUS9 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 XTAL2 AVSS XTAL1 AVDD TXD+ TXP+ TXDTXPAVDD RXD+ RXDDVDD TDI DVSS TCK TMS TD0 LNKST CS R/W
16235C-4
MACE AM79C940VC
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
Note: Four pin functions available on the PLCC and PQFP packages are not available with the TQFP package. (See page 27 "Pin Functions not available with the 80-pin TQFP Package").
DBUS10 DBUS11 DBUS12 DBUS13 DVDD DBUS14 DBUS15 DVSS EOF FDS BE0 BE1 SCLK TDTREQ RDTREQ ADD0 ADD1 ADD2 ADD3 ADD4
AM79C940
9
AMD
ORDERING INFORMATION Standard Products
AMD standard products are available in several packages and operating ranges. The order number (Valid Combination) is formed by a combination of: AM79C940 V C /W ALTERNATE PACKAGING OPTION /W = Trimmed and Formed in a Tray OPTIONAL PROCESSING Blank = Standard Processing TEMPERATURE RANGE C = Commercial (0 to +70C) PACKAGE TYPE (per Prod. Nomenclature/16-038) J = 84-Pin Plastic Leaded Chip Carrier (PL 084) K = 100-Pin Plastic Quad Flat Pack (PQR100) V = 80-Pin Thin Quad Flat Package (PQT080) SPEED Not Applicable DEVICE NUMBER/DESCRIPTION (include revision letter) AM79C940 Media Access Controller for Ethernet Valid Combinations AM79C940 JC, KC, KC/W, VC, VC/W Valid Combinations The Valid Combinations table lists configurations planned to be supported in volume for this device. Consult the local AMD sales office to confirm availability of specific valid combinations and to check on newly released combinations.
10
AM79C940
AMD
PIN/PACKAGE SUMMARY
PLCC Pin # 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 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 Pin Name DXCVR EDSEL DVSS TXDAT+ TXDAT- DVSS STDCLK TXEN/TXEN CLSN RXDAT RXCRS SRDCLK EAM/R SRD SF/BD RESET SLEEP DVDD INTR TC DBUS0 DVSS DBUS1 DBUS2 DBUS3 DBUS4 DVSS DBUS5 DBUS6 DBUS7 DBUS8 DBUS9 DBUS10 DBUS11 DBUS12 DBUS13 DVDD DBUS14 DBUS15 DVSS EOF DTV Pin Function Disable Transceiver Edge Select Digital Ground Transmit Data + Transmit Data - Digital Ground Serial Transmit Data Clock Transmit Enable Collision Receive Data Receive Carrier Sense Serial Receive Data Clock External Address Match/Reject Serial Receive Data Start Frame/Byte Delimiter Reset Sleep Mode Digital Power Interrupt Timing Control Data Bus0 Digital Ground Data Bus1 Data Bus2 Data Bus3 Data Bus4 Digital Ground Data Bus5 Data Bus6 Data Bus7 Data Bus8 Data Bus9 Data Bus10 Data Bus11 Data Bus12 Data Bus13 Digital Power Data Bus14 Data Bus15 Digital Ground End Of Frame Data Transfer Valid
AM79C940
11
AMD
PIN/PACKAGE SUMMARY (continued)
PLCC Pin # 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 Pin Name FDS BE0 BE1 SCLK TDTREQ RDTREQ ADD0 ADD1 ADD2 ADD3 ADD4 R/W CS RXPOL LNKST TDO TMS TCK DVSS TDI DVDD RXD- RXD+ AVDD TXP- TXD- TXP+ TXD+ AVDD XTAL1 AVSS XTAL2 AVSS DO- DO+ AVDD DI- DI+ CI- CI+ AVDD DVDD Pin Function FIFO Data Strobe Byte Enable0 Byte Enable1 System Clock Transmit Data Transfer Request Receive Data Transfer Request Address0 Address1 Address2 Address3 Address4 Read/Write Chip Select Receive Polarity Link Status Test Data Out Test Mode Select Test Clock Digital Ground Test Data Input Digital Power Receive Data- Receive Data+ Analog Power Transmit Pre-distortion Transmit Data- Transmit Pre-distortion+ Transmit Data+ Analog Power Crystal Input Analog Ground Crystal Output Analog Ground Data Out- Data Out+ Analog Power Data In- Data In+ Control In- Control In+ Analog Power Digital Power
12
AM79C940
AMD
PIN/PACKAGE SUMMARY (continued)
PQFP Pin # 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 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 Pin Name NC NC NC NC SRDCLK EAM/R SRD SF/BD RESET SLEEP DVDD INTR TC DBUS0 DVSS DBUS1 DBUS2 DBUS3 DBUS4 DVSS DBUS5 DBUS6 DBUS7 DBUS8 DBUS9 NC NC NC DBUS10 NC DBUS11 DBUS12 DBUS13 DVDD DBUS14 DBUS15 DVSS EOF DTV FDS BE0 BE1 No Connect No Connect No Connect No Connect Serial Receive Data Clock External Address Match/Reject Serial Receive Data Start Frame/Byte Delimiter Reset Sleep Mode Digital Power Interrupt Timing Control Data Bus0 Digital Ground Data Bus1 Data Bus2 Data Bus3 Data Bus4 Digital Ground Data Bus5 Data Bus6 Data Bus7 Data Bus8 Data Bus9 No Connect No Connect No Connect Data Bus10 No Connect Data Bus11 Data Bus12 Data Bus13 Digital Power Data Bus14 Data Bus15 Digital Ground End Of Frame Data Transfer Valid FIFO Data Strobe Byte Enable0 Byte Enable1 Pin Function
AM79C940
13
AMD
PIN/PACKAGE SUMMARY (continued)
PQFP Pin # 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 Pin Name SCLK TDTREQ RDTREQ ADD0 ADD1 ADD2 ADD3 ADD4 NC NC NC NC R/W CS RXPOL LNKST TDO TMS TCK DVSS TDI DVDD RXD- RXD+ AVDD TXP- TXD- TXP+ TXD+ AVDD XTAL1 AVSS XTAL2 NC NC NC AVSS NC DO- DO+ AVDD DI- DI+ Pin Function System Clock Transmit Data Transfer Request Receive Data Transfer Request Address0 Address1 Address2 Address3 Address4 No Connect No Connect No Connect No Connect Read/Write Chip Select Receive Polarity Link Status Test Data Out Test Mode Select Test Clock Digital Ground Test Data Input Digital Power Receive Data- Receive Data+ Analog Power Transmit Pre-distortion- Transmit Data- Transmit Pre-distortion+ Transmit Data+ Analog Power Crystal Input Analog Ground Crystal Output No Connect No Connect No Connect Analog Ground No Connect Data Out- Data Out+ Analog Power Data In- Data In+
14
AM79C940
AMD
PIN/PACKAGE SUMMARY (continued)
PQFP Pin # 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 Pin Name CI- CI+ AVDD DVDD DXCVR EDSEL DVSS TXDAT+ TXDAT- DVSS STDCLK TXEN/TXEN CLSN RXDAT RXCRS Control In- Control In+ Analog Power Digital Power Disable Transceiver Edge Select Digital Ground Transmit Data + Transmit Data - Digital Ground Serial Transmit Data Clock Transmit Enable Collision Receive Data Receive Carrier Sense Pin Function
AM79C940
15
AMD
PIN/PACKAGE SUMMARY (continued)
TQFP Pin Number 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 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 Pin Name SRDCLK EAM/R SF/BD RESET SLEEP DVDD INTR TC DBUS0 DVSS DBUS1 DBUS2 DBUS3 DBUS4 DVSS DBUS5 DBUS6 DBUS7 DBUS8 DBUS9 DBUS10 DBUS11 DBUS12 DBUS13 DVDD DBUS14 DBUS15 DVSS EOF FDS BE0 BE1 SCLK TDTREQ RDTREQ ADD0 ADD1 ADD2 ADD3 ADD4 Pin Function Serial Receive Data Clock External Address Match/Reject Start Frame/Byte Delimiter Reset Sleep Mode Digital Power Interrupt Timing Control Data Bus0 Digital Ground Data Bus1 Data Bus2 Data Bus3 Data Bus4 Digital Ground Data Bus5 Data Bus6 Data Bus7 Data Bus8 Data Bus9 Data Bus10 Data Bus11 Data Bus12 Data Bus13 Digital Power Data Bus14 Data Bus15 Digital Ground End of Frame FIFO Data Strobe Byte Enable0 Byte Enable1 System Clock Transmit Data Transfer Request Receive Data Transfer Request Address0 Address1 Address2 Address3 Address4 TQFP Pin Number 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 Pin Name R/W CS LNKST TDO TMS TCK DVSS TDI DVDD RXD- RXD+ AVDD TXP- TXD- TXP+ TXD+ AVDD XTAL1 AVSS XTAL2 AVSS DO- DO+ AVDD DI- DI+ CI- CI+ AVDD DVDD DXCVR EDSEL DVSS TXDAT+ DVSS STDCLK TXEN/TXEN CLSN RXDAT RXCRS Pin Function Read/Write Chip/Select Link Status Test Data Out Test Mode Select Test Clock Digital Ground Test Data Input Digital Power Receive Data- Receive Data+ Analog Power Transmit Pre-distortion- Transmit Data- Transmit Pre-distortion+ Transmit Data+ Analog Power Crystal Output Analog Ground Crystal Output Analog Ground Data Out- Data Out+ Analog Power Data In- Data Out+ Control In- Control In+ Analog Power Digital Power Disable Transceiver Edge Select Digital Ground Transmit Data+ Digital Ground Serial Transmit Data Clock Transmit Enable Collision Receive Data Receive Carrier Sense
16
AM79C940
AMD
PIN SUMMARY
Pin Name DO+/DO- DI+/DI- CI+/CI- RXCRS TXEN CLSN DXCVR STDCLK SRDCLK TXDAT+ TXDAT- TXEN RXDAT RXCRS CLSN DXCVR STDCLK SRDCLK TXD+/TXD- TXP+/TXP- RXD+/RXD- LNKST RXPOL TXEN RXCRS CLSN DXCVR STDCLK SRDCLK STDCLK TXDAT+ TXEN SRDCLK RXDAT RXCRS CLSN DXCVR Data Out Data In Control In Receive Carrier Sense Transmit Enable Collision Disable Transceiver Serial Transmit Data Clock Serial Receive Data Clock Transmit Data + Transmit Data - Transmit Enable Receive Data Receive Carrier Sense Collision Disable Transceiver Serial Transmit Data Clock Serial Receive Data Clock Transmit Data Transmit Pre-distortion Receive Data Link Status Receive Polarity Transmit Enable Receive Carrier Sense Collision Disable Transceiver Serial Transmit Data Clock Serial Receive Data Clock Serial Transmit Data Clock Transmit Data + Transmit Enable Serial Receive Data Clock Receive Data Receive Carrier Sense Collision Disable Transceiver Pin Function Type O I I I/O O I/O O I/O I/O O O O I I/O I/O O I/O I/O O O I O O O I/O I/O O I/O I/O I/O O O I/O I I/O I/O O High High Low High High Low Low High High High High Open Drain Open Drain TTL. TXEN in DAI port TTL output. Input in DAI, GPSI port TTL output. Input in GPSI TTL high Output. Input in GPSI Output. Input in GPSI Input TTL. See also DAI port TTL. TXEN in DAI port Input. See also EADI port TTL. See also DAI port TTL input. Output in AUI TTL input TTL low High High High High Low Low High High High Low Active Comment Pseudo-ECL Pseudo-ECL Pseudo-ECL TTL output. Input in DAI, GPSI port TTL. TXEN in DAI port TTL output. Input in GPSI TTL low Output. Input in GPSI Output. Input in GPSI TTL. See also GPSI TTL TTL. See TXEN in GPSI TTL. See also GPSI TTL input. Output in AUI TTL output. Input in GPSI TTL high Output. Input in GPSI Output. Input in GPSI
Attachment Unit Interface (AUI)
Digital Attachment Interface (DAI)
10BASE-T Interface
General Purpose Serial Interface (GPSI)
AM79C940
17
AMD
PIN SUMMARY (continued)
Pin Name SF/BD SRD EAM/R SRDCLK DBUS15-0 ADD4-0 R/W RDTREQ TDTREQ DTV EOF BE0 BE1 CS FDS INTR EDSEL TC SCLK RESET TCK TMS TDI TDO XTAL1 XTAL2 SLEEP DVDD DVSS AVDD AVSS Pin Function Start Frame/Byte Delimiter Serial Receive Data External Address Match/Reject Serial Receive Data Clock Data Bus Address Read/Write Receive Data Transfer Request Transmit Data Transfer Request Data Transfer Valid End Of Frame Byte Enable 0 Byte Enable 1 Chip Select FIFO Data Strobe Interrupt Edge Select Timing Control System Clock Reset Test Clock Test Mode Select Test Data Input Test Data Out Crystal Input Crystal Output Sleep Mode Digital Power (4 pins) Digital Ground (6 pins) Analog Power (4 pins) Analog Ground (2 pins) Type O O I I/O I/O I I O O O I/O I I I I O I I I I I I I O I O I P P P P Low CMOS CMOS TTL High High High/Low Low Low Low Low Low Low Low Low Low High Low High Low Internal pull-up Internal pull-up Internal pull-up Internal pull-up Open Drain Tristate Active High High Low Output except in GPSI Comment
External Address Detection Interface (EADI)
Host System Interface
IEEE 1149.1 Test Access Port (TAP) Interface
General Interface
18
AM79C940
AMD
PIN DESCRIPTION Network Interfaces
The MACE device has five potential network interfaces. Only one of the interfaces that provides physical network attachment can be used (active) at any time. Selection between the AUI, 10BASE-T, DAI or GPSI ports is provided by programming the PHY Configuration Control register. The EADI port is effectively active at all times. Some signals, primarily used for status reporting, are active for more than one single interface (the CLSN pin for instance). Under each of the descriptions for the network interfaces, the primary signals which are unique to that interface are described. Where signals are active for multiple interfaces, they are described once under the interface most appropriate.
DO+/DO
Data Out (Output) A differential output pair from the MACE device for transmitting Manchester encoded data to the network. Operates at pseudo-ECL levels.
Digital Attachment Interface (DAI) TXDAT+/TXDAT-
Transmit Data (Output) When the DAI port is selected, TXDAT are configured as a complementary pair for Manchester encoded data output from the MACE device, used to transmit data to a local external network transceiver. During valid transmission (indicated by TXEN low), a logical 1 is indicated by the TXDAT+ pin being in the high state and TXDAT- in the low state; and a logical 0 is indicated by the TXDAT+ pin being in the low state and TXDAT- in the high state. During idle (TXEN high), TXDAT+ will be in the high state, and TXDAT- in the low state. When the GPSI port is selected, TXDAT+ will provide NRZ data output from the MAC core, and TXDAT- will be held in the LOW state. Operates at TTL levels. The operations of TXDAT+ and TXDAT- are defined in the following tables:
Attachment Unit Interface (AUI) CI+/CI
Control In (Input) A differential input pair, signalling the MACE device that a collision has been detected on the network media, indicated by the CI inputs being exercised with 10 MHz pattern of sufficient amplitude and duration. Operates at pseudo-ECL levels.
DI+/DI
Data In (Input) A differential input pair to the MACE device for receiving Manchester encoded data from the network. Operates at pseudo-ECL levels.
TXDAT+ Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance High Impedance (Note 2) High Impedance (Note 2) TXDAT+ Output TXDAT+ Output High Impedance (Note 2)
TXDAT- Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance High Impedance High Impedance TXDAT- Output LOW High Impedance
Notes: 1. PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). 2. This pin should be externally terminated, if unused, to reduce power consumption.
AM79C940
19
AMD
TXEN/TXEN
Transmit Enable (Output) When the AUI port is selected (PORTSEL [1-0] = 00), an output indicating that the AUI DO differential output has valid Manchester encoded data is presented. When the 10BASE-T port is selected (PORTSEL [1-0] = 01), indicates that Manchester data is being output on the TXD/TXP complementary outputs. When the DAI port is selected (PORTSEL [1-0] = 10), indicates that Manchester data is being output on the DAI port TXDAT complementary outputs. When the GPSI port is selected (PORTSEL [1-0] =11), indicates that NRZ data is being output from the MAC core of the MACE device, to an external Manchester encoder/decoder, on the TXDAT+ output. Active low when the DAI port is selected, active high when the AUI, 10 BASE-T or GPSI is selected. Operates at TTL levels.
decoded data input to the MAC core of the MACE device, from an external Manchester encoder/decoder. Operates at TTL levels.
RXCRS
Receive Carrier Sense (Input/Output) When the AUI port is selected (PORTSEL [1-0] = 00), an output indicating that the DI input pair is receiving valid Manchester encoded data from the external transceiver which meets the signal amplitude and pulse width requirements. When the 10BASE-T port is selected (PORTSEL [1-0] = 01), an output indicating that the RXD input pair is receiving valid Manchester encoded data from the twisted pair cable which meets the signal amplitude and pulse width requirements. RXCRS will be asserted high for the entire duration of the receive message. When the DAI port is selected (PORTSEL [1-0] = 10), an input signaling the MACE device that a receive carrier condition has been detected on the network, and valid Manchester encoded data is being presented to the MACE device on the RXDAT line. When the GPSI port is selected (PORTSEL [1-0] = 11), an input signalling the internal MAC core that valid NRZ data is being presented on the RXDAT input. Operates at TTL levels.
RXDAT
Receive Data (Input) When the DAI port is selected (PORTSEL [1-0] = 10), the Manchester encoded data input to the integrated clock recovery and Manchester decoder of the MACE device, from an external network transceiver. When the GPSI port is selected (PORTSEL [1-0] =11), the NRZ
TXEN/TXEN Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance TXEN Output TXEN Output TXEN Output TXEN Output High Impedance (Note 3)
Notes: 1. PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). 2. When the GPSI port is selected, TXEN should have an external pull-down attached (e.g. 3.3k) to ensure the output is held inactivebefore ENPLSIO is set. 3. This pin should be externally terminated, if unused, to reduce power consumption.
RXDAT Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance High Impedance (Note 2) High Impedance (Note 2) RXDAT Input RXDAT Input High Impedance (Note 2)
Notes: 1. PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). 2. This pin should be externally terminated, if unused, to reduce power consumption.
20
AM79C940
AMD RXCRS Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance RXCRS Output RXCRS Output RXCRS Input RXCRS Input High Impedance (Note 2)
Notes: 1. PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). 2. This pin should be externally terminated, if unused, to reduce power consumption.
DXCVR
Disable Transceiver (Output) An output from the MACE device to indicate the network port in use, as programmed by the ASEL bit or the PORTSEL [1-0] bits. The output is provided to allow power down of an external DC-to-DC converter, typically used to provide the voltage requirements for an external 10BASE2 transceiver. When the Auto Select (ASEL) feature is enabled, the state of the PORTSEL [1-0] bits is overridden, and the network interface will be selected by the MACE device, dependent only on the status of the 10BASE-T link. If the
link is active (LNKST pin driven LOW) the 10BASE-T port will be used as the active network interface. If the link is inactive (LNKST pin pulled HIGH) the AUI port will be used as the active network interface. Auto Select will continue to operate even when the SLEEP pin is asserted if the RWAKE bit has been set. The AWAKE bit does not allow the Auto Select function, and only the receive section of 10BASE-T port will be active (DXCVR = HIGH). Active (HIGH) when either the 10BASE-T or DAI port is selected. Inactive (LOW) when the AUI or GPSI port is selected.
DXCVR Configuration--SLEEP Operation
SLEEP Pin 0 0 0 0 0 0 0 0 0 0 RWAKE AWAKE Bit Bit 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 ASEL Bit X 0 0 0 0 1 1 1 1 X LNKST Pin High Impedance High Impedance High Impedance High Impedance High Impedance High Impedance High Impedance HIGH LOW X PORTSEL [1-0] Bits XX 00 01 10 11 0X 0X 0X 0X 0X Interface Description Sleep Mode AUI with EADI port 10BASE-T with EADI port Invalid Invalid AUI with EADI port 10BASE-T with EADI port AUI with EADI port 10BASE-T with EADI port 10BASE-T Pin Function High Impedance LOW HIGH HIGH LOW LOW HIGH LOW HIGH HIGH
Note: RWAKE and ASEL are located in the PHY Configuration Control register (REG ADDR 15). PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). All bits must be programmed prior to the assertion of the SLEEP pin.
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AMD DXCVR Configuration--Normal Operation
SLEEP Pin 1 1 1 1 1 1 1 ASEL Bit X 0 0 0 0 1 1 LNKST Pin X X X X X HIGH LOW PORTSEL [1-0] Bits XX 00 01 10 11 0X 0X ENPLSIO Bit X X X X X X X Interface Description SIA Test Mode AUI 10BASE-T DAI Port GPSI AUI 10BASE-T Pin Function High Impedance LOW HIGH HIGH LOW LOW HIGH
Note: RWAKE and ASEL are located in the PHY Configuration Control register (REG ADDR 15). PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14).
10BASE-T Interface TXD+, TXD-
Transmit Data (Output) 10BASE-T port differential drivers.
RXPOL
Receive Polarity (Output, Open Drain) The twisted pair receiver is capable of detecting a receive signal with reversed polarity (wiring error). The RXPOL pin is normally in the LOW state, indicating correct polarity of the received signal. If the receiver detects a received packet with reversed polarity, then this pin is not driven (requires external pull-up) and the polarity of subsequent packets are inverted. In the LOW output state, this pin is capable of sinking a maximum of 12mA and can be used to drive an LED. The polarity correction feature can be disabled by setting the Disable Auto Polarity Correction (DAPC) bit in the PHY Configuration Control register. In this case, the Receive Polarity correction circuit is disabled and the internal receive signal remains non-inverted, irrespective of the received signal. Note that RXPOL will continue to reflect the polarity detected by the receiver.
TXP+, TXP-
Transmit Pre-Distortion (Output) Transmit wave form differential driver for pre-distortion.
RXD+, RXD-
Receive Data (Input) 10BASE-T port differential receiver. These pins should be externally terminated to reduce power consumption if the 10BASE-T interface is not used.
LNKST
Link Status (Output Open Drain) This pin is driven LOW if the link is identified as functional. If the link is determined to be nonfunctional, due to missing idle link pulses or data packets, then this pin is not driven (requires external pull-up). In the LOW output state, the pin is capable of sinking a maximum of 12 mA and can be used to drive an LED. This feature can be disabled by setting the Disable Link Test (DLNKTST) bit in the PHY Configuration Control register. In this case the internal Link Test Receive function is disabled, the LNKST pin will be driven LOW, and the Transmit and Receive functions will remain active regardless of arriving idle link pulses and data. The internal 10BASE-T MAU will continue to generate idle link pulses irrespective of the status of the DLNKTST bit.
General Purpose Serial Interface (GPSI) STDCLK
Serial Transmit Data Clock (Input/Output) When either the AUI, 10BASE-T or DAI port is selected, STDCLK is an output operating at one half the crystal or XTAL1 frequency. STDCLK is the encoding clock for Manchester data transferred to the output of either the AUI DO pair, the 10BASE-T TXD/TXP pairs, or the DAI port TXDAT pair. When using the GPSI port, STDCLK is an input at the network data rate, provided by the external Manchester encode/decoder, to strobe out the NRZ data presented on the TXDAT+ output.
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SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance STDCLK Output STDCLK Output STDCLK Output STDCLK Input High Impedance (Note 2)
Notes: 1. PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). 2. This pin should be externally terminated, if unused, to reduce power consumption.
CLSN
Collision (Input/Output) An external indication that a collision condition has been detected by the (internal or external) Medium Attachment Unit (MAU), and that signals from two or more nodes are present on the network. When the AUI port is selected (PORTSEL [1-0] = 00), CLSN will be activated when the CI input pair is receiving a collision indication from the external transceiver. CLSN will be asserted high for the entire duration of the collision detection, but will not be asserted during the SQE Test message following a transmit message on the AUI. When the 10BASE-T port is selected (PORTSEL [1-0] = 01), CLSN will be asserted high when simultaneous transmit and receive activity is detected (logically detected when TXD/TXP and RXD are both active). When the DAI port is selected (PORTSEL [1-0] = 10), CLSN will be asserted high when simultaneous transmit and receive activity is detected (logically detected when RXCRS and TXEN are both active). When the GPSI port is selected (PORTSEL [1-0] = 11), an input from the external Manchester encoder/decoder signaling the MACE device that a collision condition has been detected on the network, and any receive frame in progress should be aborted.
External Address Detection Interface (EADI ) SF/BD
Start Frame/Byte Delimiter (Output) The external indication that a start of frame delimiter has been received. The serial bit stream will follow on the Serial Receive Data pin (SRD), commencing with the destination address field. SF/BD will go high for 4 bit times (400 ns) after detecting the second 1 in the SFD of a received frame. SF/BD will subsequently toggle every 400 ns (1.25 MHz frequency) with the rising edge indicating the start (first bit) in each subsequent byte of the received serial bit stream. SF/BD will be inactive during frame transmission.
SRD
Serial Receive Data (Output) SRD is the decoded NRZ data from the network. It is available for external address detection. Note that when the 10BASE-T port is selected, transition on SRD will only occur during receive activity. When the AUI or DAI port is selected, transition on SRD will occur during both transmit and receive activity.
CLSN Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance CLSN Output CLSN Output CLSN Output CLSN Input High Impedance (Note 2)
Notes: 1. PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). 2. This pin should be externally terminated, if unused, to reduce power consumption.
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EAM/R
External Address Match/Reject (Input) The incoming frame will be received dependent on the receive operational mode of the MACE device, and the polarity of the EAM/R pin. The EAM/R pin function is programmed by use of the M/R bit in the Receive Frame Control register. If the bit is set, the pin is configured as EAM. If the bit is reset, the pin is configured as EAR. EAM/R can be asserted during packet reception to accept or reject packets based on an external address comparison.
SRDCLK
Serial Receive Data Clock (Input/Output) The Serial Receive Data (SRD) output is synchronous to SRDCLK running at the 10MHz receive data clock frequency. The pin is configured as an input, only when the GPSI port is selected. Note that when the 10BASE-T port is selected, transition on SRDCLK will only occur during receive activity. When the AUI or DAI port is selected, transition on SRDCLK will occur during both transmit and receive activity.
SRD Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance SRD Output SRD Output SRD Output SRD Output High Impedance
Note: PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14).
SRDCLK Configuration
SLEEP 0 1 1 1 1 1 PORTSEL [1-0] XX 00 01 10 11 XX ENPLSIO X 1 1 1 1 0 Interface Description Sleep Mode AUI 10BASE-T DAI Port GPSI Status Disabled Pin Function High Impedance SRDCLK Output SRDCLK Output SRDCLK Output SRDCLK Input High Impedance (Note 2)
Notes: 1. PORTSEL [1-0] and ENPLSIO are located in the PLS Configuration Control register (REG ADDR 14). 2. This pin should be externally terminated, if unused, to reduce power consumption.
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HOST SYSTEM INTERFACE DBUS15-0
Data Bus (Input/Output/3-state) DBUS contains read and write data to and from internal registers and the Transmit and Receive FIFOs.
asserted only when Enable Transmit (ENXMT) is set in the MAC Configuration Control register.
FDS
FIFO Data Select (Input) FIFO Data Select allows direct access to the transmit or Receive FIFO without use of the ADD address bus. FDS must be activated in conjunction with R/W. When the MACE device samples R/W as high and FDS low, a read cycle from the Receive FIFO will be initiated. When the MACE chip samples R/W and FDS low, a write cycle to the Transmit FIFO will be initiated. The CS line should be inactive (high) when FIFO access is requested using the FDS pin. If the MACE device samples both CS and FDS as active simultaneously, no cycle will be executed, and DTV will remain inactive.
ADD4-0
Address Bus (Input) ADD is used to access the internal registers and FIFOs to be read or written.
R/W
Read/Write (Input) Indicates the direction of data flow during the MACE device register, Transmit FIFO, or Receive FIFO accesses.
DTV
Data Transfer Valid (Output/3-state) When asserted, indicates that the read or write operation has completed successfully. The absence of DTV at the termination of a host access cycle on the MACE device indicates that the data transfer was unsuccessful. DTV need not be used if the system interface can guarantee that the latency to TDTREQ and RDTREQ assertion and de-assertion will not cause the Transmit FIFO to be over-written or the Receive FIFO to be over-read. In this case, the latching or strobing of read or write data can be synchronized to the SCLK input rather than to the DTV output.
RDTREQ
Receive Data Transfer Request (Output) Receive Data Transfer Request indicates that there is data in the Receive FIFO to be read. When RDTREQ is asserted there will be a minimum of 16 bytes to be read except at the completion of the frame, in which case EOF will be asserted. RDTREQ can be programmed to request receive data transfer when 16, 32 or 64 bytes are available in the Receive FIFO, by programming the Receive FIFO Watermark (RCVFW bits) in the FIFO Configuration Control register. The first assertion of RDTREQ will not occur until at least 64 bytes have been received, and the frame has been verified as non runt. Runt packets will normally be deleted from the Receive FIFO with no external activity on RDTREQ. When Runt Packet Accept is enabled (RPA bit) in the User Test Register, RDTREQ will be asserted when the runt packet completes, and the entire frame resides in the Receive FIFO. RDTREQ will be asserted only when Enable Receive (ENRCV) is set in the MAC Configuration Control register. The RCVFW can be overridden by enabling the Low Latency Receive function (setting LLRCV bit) in the Receive Frame Control register, which allows RDTREQ to be asserted after only 12 bytes have been received. Note that use of this function exposes the system interface to premature termination of the receive frame, due to network events such as collisions or runt packets. It is the responsibility of the system designer to provide adequate recovery mechanisms for these conditions.
EOF
End Of Frame (Input/Output/3-state) End Of Frame will be asserted by the MACE device when the last byte/word of frame data is read from the Receive FIFO, indicating the completion of the frame data field for the receive message. End Of Frame must be asserted low to the MACE device when the last byte/ word of the frame is written into the Transmit FIFO.
BE1-0
Byte Enable (Input) Used to indicate the active portion of the data transfer to or from the internal FIFOs. For word (16-bit) transfers, both BE0 and BE1 should be activated by the external host/controller. Single byte transfers are performed by identifying the active data bus byte and activating only one of the two signals. The function of the BE1-0 pins is programmed using the BSWP bit (BIU Configuration Control register, bit 6). BE1-0 are not required for accesses to MACE device registers.
TDTREQ
Transmit Data Transfer Request (Output) Transmit Data Transfer Request indicates there is room in the Transmit FIFO for more data. TDTREQ is asserted when there are a minimum of 16 empty bytes in the Transmit FIFO. TDTREQ can be programmed to request transmit data transfer when 16, 32 or 64 bytes are available in the Transmit FIFO, by programming the Transmit FIFO Watermark (XMTFW bits) in the FIFO Configuration Control register. TDTREQ will be
CS
Chip Select (Input) Used to access the MACE device FIFOs and internal registers locations using the ADD address bus. The FIFOs may alternatively be directly accessed without supplying the FIFO address, by using the FDS and R/W pins.
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INTR
Interrupt (Output, Open Drain) An attention signal indicating that one or more of the following status flags are set: XMTINT, RCVINT, MPCO, RPCO, RCVCCO, CERR, BABL or JAB. Each interrupt source can be individually masked. No interrupt condition can take place in the MACE device immediately after a hardware or software reset.
IEEE 1149.1 TEST ACCESS PORT (TAP) INTERFACE TCK
Test Clock (Input) The clock input for the boundary scan test mode operation. TCK can operate up to 10 MHz. TCK has an internal (not SLEEP disabled) pull up.
RESET
Reset (Input) Reset clears the internal logic. Reset can be asynchronous to SCLK, but must be asserted for a minimum duration of 15 SCLK cycles.
TMS
Test Mode Select (Input) A serial input bit stream used to define the specific boundary scan test to be executed. TMS has an internal (not SLEEP disabled) pull up.
SCLK
System Clock (Input) The system clock input controls the operational frequency of the slave interface to the MACE device and the internal processing of frames. SCLK is unrelated to the 20 MHz clock frequency required for the 802.3/Ethernet interface. The SCLK frequency range is 1 MHz-25 MHz.
TDI
Test Data Input (Input) The test data input path to the MACE device. TDI has an internal (not SLEEP disabled) pull up.
TDO
Test Data Out (Output) The test data output path from the MACE device.
EDSEL
System Clock Edge Select (Input) EDSEL is a static input that allows System Clock (SCLK) edge selection. If EDSEL is tied high, the bus interface unit will assume falling edge timing. If EDSEL is tied low, the bus interface unit will assume rising edge timing, which will effectively invert the SCLK as it enters the MACE device, i.e., the address, control lines (CS, R/W, FDS, etc) and data are all latched on the rising edge of SCLK, and data out is driven off the rising edge of SCLK.
GENERAL INTERFACE XTAL1
Crystal Connection (Input) The internal clock generator uses a 20 MHz crystal that is attached to pins XTAL1 and XTAL2. Internally, the 20 MHz crystal frequency is divided by two which determines the network data rate. Alternatively, an external 20 MHz CMOS-compatible clock signal can be used to drive this pin. The MACE device supports the use of 50 pF crystals to generate a 20 MHz frequency which is compatible with the IEEE 802.3 network frequency tolerance and jitter specifications.
TC
Timing Control (Input) The Timing Control input conditions the minimum number of System Clocks (SCLK) cycles taken to read or write the internal registers and FIFOs. TC can be used as a wait state generator, to allow additional time for data to be presented by the host during a write cycle, or allow additional time for the data to be latched during a read cycle. TC has an internal (SLEEP disabled) pull up. Timing Control
TC 1 0 Number of Clocks 2 3
XTAL2
Crystal Connection (Output) The internal clock generator uses a 20 MHz crystal that is attached to pins XTAL1 and XTAL2. If an external clock generator is used on XTAL1, then XTAL2 should be left unconnected.
SLEEP
Sleep Mode (Input) The optimal power savings made is extracted by asserting the SLEEP pin with both the Auto Wake (AWAKE bit) and Remote Wake (RWAKE bit) functions disabled. In this "deep sleep" mode, all outputs will be forced into their inactive or high impedance state, and all inputs will be ignored except for the SLEEP, RESET, SCLK, TCK,
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AMD TMS, and TDI pins. SCLK must run for 5 cycles after the assertion of SLEEP. During the "Deep Sleep", the SCLK input can be optionally suspended for maximum power savings. Upon exiting "Deep Sleep", the hardware RESET pin must be asserted and the SCLK restored. The system must delay the setting of the bits in the MAC configuration Control Register of the internal analog circuits by 1 ns to allow for stabilization. If the AWAKE bit is set prior to the activation of SLEEP, the 10BASE-T receiver and the LNKST output pin remain operational. If the RWAKE bit is set prior to SLEEP being asserted, the Manchester encoder/decoder, AUI and 10BASE-T cells remain operational, as do the SRD, SRDCLK and SF/BD outputs. The input on XTAL1 must remain active for the AWAKE or RWAKE features to operate. After exit from the Auto Wake or Remote Wake modes, activation of hardware RESET is not required when SLEEP is reasserted. On deassertion of SLEEP, the MACE device will go through an internally generated hardware reset sequence, requiring re-initialization of MACE registers.
PIN FUNCTIONS NOT AVAILABLE WITH THE 80-PIN TQFP PACKAGE
In the 84-pin PLCC configuration, ALL the pins are used while in the 100-pin PQFP version, 16 pins are specified as No Connects. Moving to the 80-pin TQFP configuration requires the removal of 4 pins. Since Ethernet controllers with integrated 10BASE-T have analog portions which are very sensitive to noise, power and ground pins are not deleted. The MACE device does have several sets of media interfaces which typically go unused in most designs, however. Pins from some of these interfaces are deleted instead. Removed are the following: s TXDAT- (previously used for the DAI interface) s SRD (previously used for the EADI interface) s DTV (previously used for the host interface) s RXPOL (previously used as a receive frame polarity LED driver) Note that pins from four separate interfaces are removed rather than removing all the pins from a single interface. Each of these pins comes from one of the four sides of the device. This is done to maintain symmetry, thus avoiding bond out problems. In general, the most critical of the four removed pins are TXDAT- and SRD. Depending on the application, either the DAI or the EADI interface may be important. In most designs, however, this will not be the case.
Power Supply DVDD
Digital Power There are four Digital VDD pins.
DVSS
Digital Ground There are six Digital VSS pins.
PINS REMOVED AND THEIR EFFECTS TXDAT-
The removal of TXDAT- means that the DAI interface is no longer usable. The DAI interface was designed to be used with media types that do not require DC isolation between the MAU and the DTE. Media which do not require DC isolation can be implemented more simply using the DAI interface, rather than the AUI interface. In most designs this is not a problem because most media requires DC isolation (10BASE-T, 10BASE2, 10BASE5) and will use the AUI port. About the only media which does not require DC isolation is 10BASE-F.
AVDD
Analog Power There are four analog VDD pins. Special attention should be paid to the printed circuit board layout to avoid excessive noise on the supply to the PLL in the Manchester encoder/decoder (pins 66 and 83 in PLCC, pins 67 and 88 in PQFP). These supply lines should be kept separate from the DVDD lines as far back to the power supply as is practically possible.
SRD
The SRD pin is an output pin used by the MACE device to transfer a receive data stream to external address detection logic. It is part of the EADI interface. This pin is used to help interface the MACE device to an external CAM device. Use of an external CAM is typically required when an application will operate in promiscuous mode and will need perfect filtering (i.e., the internal hash filter will not suffice). Example applications for this
AVSS
Analog Ground There are two analog VSS pins. Special attention should be paid to the printed circuit board layout to avoid excessive noise on the PLL supply in Manchester encoder/decoder (pin 73 in PLCC, pin 74 in PQFP). These supply lines should be kept separate from the DVSS lines as far back to the power supply as is practically possible.
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AMD sort of operation are bridges and routers. Lack of perfect filtering in these applications forces the CPU to be more involved in filtering and thus either slows the forwarding rates achieved or forces the use of a more powerful CPU. there are ways to ensure that a transfer is always valid and so this pin is not required in many designs. For instance, the TDTREQ and RDTREQ pins can be used to monitor the state of the FIFOs to ensure that data transfer only occurs at the correct times.
DTV
The DTV pin is part of the host interface to the MACE device. It is used to indicate that a read or write cycle to the MACE device was successful. If DTV is not asserted at the end of a cycle, the data transfer was not successful. Basically, this will happen on a write to a full transmit FIFO or a read from an empty receive FIFO. In general,
RXPOL
RXPOL is typically used to drive an LED indicating the polarity of receive frames. This function is not necessary for correct operation of the Ethernet and serves strictly as a status indication to a user. The status of the receive polarity is still available through the PHYCC register.
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FUNCTIONAL DESCRIPTION
The Media Access Controller for Ethernet (MACE) chip embodies the Media Access Control (MAC) and Physical Signaling (PLS) sub-layers of the 802.3 Standard. The MACE device provides the IEEE defined Attachment Unit Interface (AUI) for coupling to remote Media Attachment Units (MAUs) or on-board transceivers. The MACE device also provides a Digital Attachment Interface (DAI), by-passing the differential AUI interface. The system interface provides a fundamental data conduit to and from an 802.3 network. The MACE device in conjunction with a user defined DMA engine, provides an 802.3 interface tailored to a specific application. In addition, the MACE device can be combined with similarly architected peripheral devices and a multichannel DMA controller, thereby providing the system with access to multiple peripheral devices with a single master interface to memory.
Receive FIFO is read (R/W high) or the Transmit FIFO written (R/W low). The MACE device system interface permits interleaved transmit and receive bus transfers, allowing the Transmit FIFO to be filled (primed) while a frame is being received from the network and/or read from the Receive FIFO. In receive operation, the MACE device asserts Receive Data Transfer Request (RDTREQ) when the FIFO contains adequate data. For the first indication of a new receive frame, 64 bytes must be received, assuming normal operation. Once the initial 64 byte threshold has been reached, RDTREQ assertion and de-assertion is dependent on the programming of the Receive FIFO Watermark (RCVFW bits in the BIU Configuration Control register). The RDTREQ can be programmed to activate when there are 16, 32 or 64 bytes of data available in the Receive FIFO. Enable Receive (ENRCV bit in MAC Configuration Control register) must be set to assert RDTREQ. If the Runt Packet Accept feature is invoked (RPA bit in User Test Register), RDTREQ will be asserted for receive frames of less than 64 bytes on the basis of internal and/or external address match only. When RPA is set, RDTREQ will be asserted when the entire frame has been received or when the initial 64 byte threshold has been exceeded. See the FIFO SubSystems section for further details. Note that the Receive FIFO may not contain 64 data bytes at the time RDTREQ is asserted, if the automatic pad stripping feature has been enabled (ASTRP RCV bit in the Receive Frame Control register) and a minimum length packet with pad is received. The MACE device will check for the minimum received length from the network, strip the pad characters, and pass only the data frame through the Receive FIFO. If the Low Latency Receive feature is enabled (LLRCV bit set in Receive Frame Control Register), RDTREQ will be asserted once a low watermark threshold has been reached (12 bytes plus some additional synchronization time). Note that the system interface will therefore be exposed to potential disruption of the receive frame due to a network condition (see the FIFO SubSystem description for additional details). In transmit operation, the MACE device asserts Transmit Data Transfer Request (TDTREQ) dependent on the programming of the Transmit FIFO Watermark (XMTFW bits in the BIU Configuration Control register). TDTREQ will be permanently asserted when the Transmit FIFO is empty. The TDTREQ can be programmed to activate when there are 16, 32 or 64 bytes of space available in the Transmit FIFO. Enable Transmit (ENXMT bit in MAC Configuration Control register) must be set to assert TDTREQ. Write cycles to the Transmit FIFO will not return DTV if ENXMT is disabled, and no data will be written. The MACE device will commence the preamble sequence once the Transmit Start Point (XMTSP bits in BIU Configuration Control register) threshold is reached in the Transmit FIFO. 29
Network Interfaces
The MACE device can be connected to an 802.3 network using any one of the AUI, 10 BASE-T, DAI and GPSI network interfaces. The Attachment Unit Interface (AUI) provides an IEEE compliant differential interface to a remote MAU or an on-board transceiver. An integrated 10BASE-T MAU provides a direct interface for twisted pair Ethernet networks. The DAI port can connect to local transceiver devices for 10BASE2, 10BASE-T or 10BASE-F connections. A General Purpose Serial Interface (GPSI) is supported, which effectively bypasses the integrated Manchester encoder/decoder, and allows direct access to/from the integral 802.3 Media Access Controller (MAC) to provide support for external encoding/decoding schemes. The interface in use is determined by the PORTSEL [1-0] bits in the PLS Configuration Control register. The EADI port does not provide network connectivity, but allows an optional external circuit to assist in receive packet accept/reject.
System Interface
The MACE device is a slave register based peripheral. All transfers to and from the device, including data, are performed using simple memory or I/O read and write commands. Access to all registers, including the Transmit and Receive FIFOs, are performed with identical read or write timing. All information on the system interface is synchronous to the system clock (SCLK), which allows simple external logic to be designed to interrogate the device status and control the network data flow. The Receive and Transmit FIFOs can be read or written by driving the appropriate address lines and asserting CS and R/W. An alternative FIFO access mechanism allows the use of the FDS and the R/W lines, ignoring the address lines (ADD4-0). The state of the R/W line in conjunction with the FDS input determines whether the
AM79C940
AMD The Transmit FIFO data will not be overwritten until at least 512 data bits have been transmitted onto the network. If a collision occurs within the slot time (512 bit time) window, the MACE device will generate a jam sequence (a 32-bit all zeroes pattern) before ceasing the transmission. The Transmit FIFO will be reset to point at the start of the transmit data field, and the message will be retried after the random back-off interval has expired. and by asserting BE0. For BSWP = 1, reading from or writing to DBUS15-8 is accomplished by asserting BE0, and allows the byte stream to be transferred in byte order. When word operations are required, BSWP ensures that the byte ordering of the target memory is compatible with the 802.3 requirement to send/receive the data stream in byte ascending order. With BSWP = 0, the data transferred to/from the FIFO assumes that byte n will be on DBUS7-0 (activated by BE0) and byte n+1 will be on DBUS15-8 (activated by BE1). With BSWP = 1, the data transferred to/from the FIFO assumes that byte n will be presented on DBUS15-8 (activated by BE0), and byte n+1 will be on DBUS7-0 (activated by BE1). There are some additional special cases to the above generalized rules, which are as follows: (a) When performing byte read operations, both halves of the data bus are driven with identical data, effectively allowing the user to arbitrarily read from either the upper or lower data bus, when only one of the byte enables is activated. (b) When byte write operations are performed, the Transmit FIFO latency is affected. See the FIFO Sub-System section for additional details. (c) If a word read is performed on the last data byte of a receive frame (EOF is asserted), and the message contained an odd number of bytes but the host requested a word operation by asserting both BE0 and BE1, then the MACE device will present one valid and one non-valid byte on the data bus. The placement of valid data for the data byte is dependent on the target memory architecture. Regardless of BSWP, the single valid byte will be read from the BE0 memory bank. If BSWP = 0, BE0 corresponds to DBUS7-0; if BSWP = 1, BE0 corresponds to DBUS15-8. (d) If a byte read is performed when the last data byte is read for a receive frame (when the MACE device activates the EOF signal), then the same byte will be presented on both the upper and lower byte of the data bus, regardless of which byte enable was activated (as is the case for all byte read operations). (e) When writing the last byte in a transmit message to the Transmit FIFO, the portion of the data bus that the last byte is transferred over is irrelevant, providing the appropriate byte enable is used. For BSWP = 0, data can be presented on DBUS7-0 using BE0 or DBUS15-8 using BE1. For BSWP = 1, data can be presented on DBUS7-0 using BE1 or DBUS15-8 using BE0.
DETAILED FUNCTIONS Block Level Description
The following sections describe the major sub-blocks of and the external interfaces to the MACE device.
Bus Interface Unit (BIU)
The BIU performs the interface between the host or system bus and the Transmit and Receive FIFOs, as well as all chip control and status registers. The BIU can be configured to accept data presented in either little-endian or big endian format, minimizing the external logic required to access the MACE device internal FIFOs and registers. In addition, the BIU directly supports 8-bit transfers and incorporates features to simplify interfacing to 32-bit systems using external latches. Externally, the FIFOs appear as two independent registers located at individual addresses. The remainder of the internal registers occupy 30 additional consecutive addresses, and appear as 8-bits wide.
BIU to FIFO Data Path
The BIU operates assuming that the 16-bit data path to/ from the internal FIFOs is configured as two independent byte paths, activated by the Byte Enable signals BE0 and BE1. BE0 and BE1 are only used during accesses to the 16-bit wide Transmit and Receive FIFOs. After hardware or software reset, the BSWP bit will be cleared. FIFO accesses to the MACE device will operate assuming an Intel 80x86 type memory convention (most significant byte of a word stored in the higher addressed byte). Word data transfers to/from the FIFOs over the DBUS15-0 lines will have the least significant byte located on DBUS7-0 (activated by BE0) and the most significant byte located on DBUS15-8 (activated by BE1). FIFO data can be read or written using either byte and/or word operations. If byte operation is required, read/write transfers can be performed on either the upper or lower data bus by asserting the appropriate byte enable. For instance with BSWP = 0, reading from or writing to DBUS15-8 is accomplished by asserting BE1, and allows the data stream to be read from or written to the appropriate FIFO in byte order (byte 0, byte 1,....byte n). It is equally valid to read or write the data stream using DBUS7-0
30
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AMD (f) When neither BE0 nor BE1 are asserted, no data transfer will take place. DTV will not be asserted. Byte Alignment For FIFO Read Operations
BE0 0 0 1 1 0 0 1 1 BE1 0 1 0 1 0 1 0 1 BSWP 0 0 0 0 1 1 1 1 DBUS7-0 n n n X n+1 n n X DBUS15-8 n+1 n n X n n n X
FIFO Sub-System
The MACE device has two independent FIFOs, with 128-bytes for receive and 136-bytes for transmit operations. The FIFO sub-system contains both the FIFOs, and the control logic to handle normal and exception related conditions. The Transmit and Receive FIFOs interface on the network side with the serializer/de-serializer in the MAC engine. The BIU provides access between the FIFOs and the host system to enable the movement of data to and from the network. Internally, the FIFOs appear to the BIU as independent 16-bit wide registers. Bytes or words can be written to the Transmit FIFO (XMTFIFO), or read from the Receive FIFO (RCVFIFO). Byte and word transfers can be mixed in any order. The BIU will ensure correct byte ordering dependent on the target host system, as determined by the programming of the BSWP bit in the BIU Configuration Control register. The XMTFIFO and RCVFIFO have three different modes of operation. These are Normal (Default), Burst and Low Latency Receive. Default operation will be used after the hardware RESET pin or software SWRST bit have been activated. The remainder of this general description applies to all modes except where specific differences are noted. Transmit FIFO--General Operation: When writing bytes to the XMTFIFO, certain restrictions apply. These restrictions have a direct influence on the latency provided by the FIFO to the host system. When a byte is written to the FIFO location, the entire word location is used. The unused byte is marked as a hole in the XMTFIFO. These holes are skipped during the serialization process performed by the MAC engine, when the bytes are unloaded from the XMTFIFO. For instance, assume the Transmit FIFO Watermark (XMTFW) is set for 32 write cycles. If the host writes byte wide data to the XMTFIFO, after 36 write cycles there will be space left in the XMTFIFO for only 32 more write cycles. Therefore TDTREQ will de-assert even though only 36-bytes of data have been loaded into the XMTFIFO. Transmission will not commence until 64-bytes or the End-of-Frame are available in the XMFIFO, so transmission would not start, and TDTREQ would remain de-asserted. Hence for byte wide data transfers, the XMTFW should be programmed to the 8 or 16 write cycle limit, or the host should ensure that sufficient data will be written to the XMTFIFO after TDTREQ has been de-asserted (which is permitted), to guarantee that the transmission will commence. A third alternative is to program the Transmit Start Point (XMTSP) in the BIU Configuration Control register to below the 64-byte default; thereby imposing a lower latency to the host system requiring additional data to
Byte Alignment For FIFO Write Operations
BE0 0 0 1 1 0 0 1 1 BE1 0 1 0 1 0 1 0 1 BSWP 0 0 0 0 1 1 1 1 DBUS7-0 n n X X n+1 X n X DBUS15-8 n+1 X n X n n X X
BIU to Control and Status Register Data Path
All registers in the address range 2-31 are 8-bits wide. When a read cycle is executed on any of these registers, the MACE device will drive data on both bytes of the data bus, regardless of the programming of BSWP. When a write cycle is executed, the MACE device strobes in data based on the programming of BSWP as shown in the tables below. All accesses to addresses 2-31 are independent of the BE0 and BE1 pins. Byte Alignment For Register Read Operations
BE0 X X BE1 X X BSWP 0 1 DBUS7-0 Read Data Read Data DBUS15-8 Read Data Read Data
Byte Alignment For Register Write Operations
BE0 X X BE1 X X BSWP 0 1 DBUS7-0 Write Data X DBUS15-8 X Write Data
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AMD ensure the XMTFIFO does not underflow during the transmit process, versus using the default XMTSP value. Note that if 64 single byte writes are executed on the XMTFIFO, and the XMTSP is set to 64-bytes, the transmission will commence, and all 64-bytes of information will be accepted by the XMTFIFO. The number of write cycles that the host uses to write the packet into the Transmit FIFO will also directly influence the amount of space utilized by the transmit message. If the number of write cycles (n) required to transfer a packet to the Transmit FIFO is even, the number of bytes used in the Transmit FIFO will be 2*n. If the number of write cycles required to transfer a packet to the Transmit FIFO is odd, the number of bytes used in the Transmit FIFO will be 2*n + 2 because the End Of Frame indication in the XMTFIFO is always placed at the end of a 4-byte boundary. For example, a 32-byte message written as bytes (n = 32 cycles) will use 64-bytes of space in the Transmit FIFO (2*n = 64), whereas a 65-byte message written as 32 words and 1 byte (n = 33 cycles) would use 68-bytes (2*n + 2 = 68) . The Transmit FIFO has been sized appropriately to minimize the system interface overhead. However, consideration must be given to overall system design if byte writes are supported. In order to guarantee that sufficient space is present in the XMTFIFO to accept the number of write cycles programmed by the XMTFW (including an End Of Frame delimiter), TDTREQ may go inactive before the XMTSP threshold is reached when using the non burst mode (XMTBRST = 0). For instance, assume that the XMTFW is programmed to allow 32 write cycles (default), and XMTSP is programmed to require 64 bytes (default) before starting transmission. Assuming that the host bursts the transmit data in a 32 cycle block, writing a single byte anywhere within this block will mean that XMTSP will not have been reached. This would be a typical scenario if the transmit data buffer was not aligned to a word boundary. The MACE device will continue to assert TDTREQ since an additional 36 write cycles can still be executed. If the host starts a second burst, the XMTSP will be reached, and TDTREQ will deassert when less that 32 write cycle can be performed although the data written by the host will continue to be accepted. The host must be aware that additional space exists in the XMTFIFO although TDTREQ becomes inactive, and must continue to write data to ensure the XMTSP threshold is achieved. No transmit activity will commence until the XMTSP threshold is reached. Once 36 write cycles have been executed. Note that write cycles can be performed to the XMTFIFO even if the TDTREQ is inactive. When TDTREQ is asserted, it guarantees that a minimum amount of space exists, when TDTREQ is deasserted, it does not necessarily indicate that there is no space in the XMTFIFO. The DTV pin will indicate the successful acceptance of data by the Transmit FIFO. As another example, assume again that the XMTFW is programmed for 32 write cycles. If the host writes word wide data continuously to the XMTFIFO, the TDTREQ will deassert when 36 writes have executed on the XMTFIFO, at which point 72-bytes will have been written to the XMTFIFO, the 64-byte XMTSP will have been exceeded and the transmission of preamble will have commenced. TDTREQ will not re-assert until the transmission of the packet data has commenced and the possibility of losing data due to a collision within the slot time is removed (512 bits have been transmitted without a collision indication). Assuming that the host actually stopped writing data after the initial 72-bytes, there will be only 16-bytes of data remaining in the XMTFIFO (8-bytes of preamble/SFD plus 56-bytes of data have been transmitted), corresponding to 12.8 s of latency before an XMTFIFO underrun occurs. This latency is considerably less than the maximum possible 57.6 s the system may have assumed. If the host had continued with the block transfer until 64 write cycles had been performed, 128-bytes would have been written to the XMTFIFO, and 72-bytes of latency would remain (57.6 s) when TDTREQ was re-asserted. Transmit FIFO--Burst Operation: The XMTFIFO burst mode, programmed by the XMTBRST bit in the FIFO Configuration Control register, modifies TDTREQ behavior. The assertion of TDTREQ is controlled by the programming of the XMTFW bits, such that when the specified number of write cycles can be guaranteed (8, 16 or 32), TDTREQ will be asserted. TDTREQ will be de-asserted when the XMTFIFO can only accept a single write cycle (one word write including an End Of Frame delimiter) allowing the external device to burst data into the XMTFIFO when TDTREQ is asserted, and stop when TDTREQ is deasserted. Receive FIFO--General Operation: The Receive FIFO contains additional logic to ensure that sufficient data is present in the RCVFIFO to allow the specified number of bytes to be read, regardless of the ordering of byte/word read accesses. This has an impact on the perceived latency that the Receive FIFO provides to the host system. The description and table below outline the point at which RDTREQ will be asserted when the first duration of the packet has been received and when any subsequent transfer of the packet to the host system is required. No preamble/SFD bytes are loaded into the Receive FIFO. All references to bytes pass through the receive FIFO. These references are received after the preamble/SFD sequence.
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AMD The first assertion of RDTREQ for a packet will occur after the longer of the following two conditions is met: s 64-bytes have been received (to assure runt packets and packets experiencing collision within the slot time will be rejected). s The RCVFW threshold is reached plus an additional 12 bytes. The additional 12 bytes are necessary to ensure that any permutation of byte/word read access is guaranteed. They are required for all threshold values, but in the case of the 16 and 32-byte thresholds, the requirement that the slot time criteria is met dominates. Any subsequent assertion of RDTREQ necessary to complete the transfer of the packet will occur after the RCVFW threshold is reached plus an additional 12 bytes. The table below also outlines the latency provided by the MACE device when the RDTREQ is asserted.
Receive FIFO Watermarks, RDTREQ Assertion and Latency
RCVFW [1-0] 00 01 10 11 Bytes Required for First Assertion of RDTREQ 64 64 76 XX Bytes of Latency After First Assertion of RDTREQ 64 64 52 XX Bytes Required for Subsequent Assertion of RDTREQ 28 44 76 XX Bytes of Latency After Subsequent Assertion of RDTREQ 100 84 52 XX
Receive FIFO--Burst Operation: The RCVFIFO also provides a burst mode capability, programmed by the RCVBRST bit in the FIFO Configuration Control register, to modify the operation of RDTREQ.The assertion of RDTREQ will occur according to the programming of the RCVFW bits. RDTREQ will be de-asserted when the RCVFIFO can only provide a single read cycle (one word read). This allows the external device to burst data from the RCVFIFO once RDTREQ is asserted, and stop when RDTREQ is deasserted. Receive FIFO--Low Latency Receive Operation: The LOW Latency Receive mode can be programmed using the Low Latency Receive bit (LLRCV in the Receive Frame Control register). This effectively causes the assertion of RDTREQ to be directly coupled to the low watermark of 12 bytes in the RCVFIFO. Once the 12-byte threshold is reached (plus some internal synchronization delay of less than 1 byte), RDTREQ will be asserted, and will remain active until the RCVFIFO can support only one read cycle (one word of data), as in the burst operation described earlier. The intended use for the Low Latency Receive mode is to allow fast forwarding of a received packet in a bridge application. In this case, the receiving process is made aware of the receive packet after only 9.6 s, instead of waiting up to 60.8 s (76-bytes) necessary for the initial assertion of RDTREQ. An Ethernet-to-Ethernet bridge employing the MACE device (on all the Ethernet connections) with the XMTSP of all MACE controller XMTFIFOs set to the minimum (4-bytes), forwarding of a receive packet can be achieved within a sub 20 s delay including processing overhead.
Note however that this mode places significant burden on the host processor. The receiving MACE device will no longer delete runt packets. A runt packet will have the Receive Frame Status appended to the receive data which the host must read as normal. The MACE device will not attempt to delete runt packets from the RCVFIFO in the Low Latency Receive mode. Collision fragments will also be passed to the host if they are detected after the 12-byte threshold has been reached. If a collision occurs, the Receive Frame Status (RCVFS) will be appended to the data successfully received in the RCVFIFO up to the point the collision was detected. No additional receive data will be written to the RCVFIFO. Note that the RCVFS will not become available until after the receive activity ceases. The collision indication (CLSN) in the Receive Status (RCVSTS) will be set, and the Receive Message Byte Count (RCVCNT) will be the correct count of the total duration of activity, including the period that collision was detected. The detection of normal (slot time) collisions versus late collisions can only be made by counting the number of bytes that were successfully received prior to the termination of the packet data. In all cases where the reception ends prematurely (runt or collision), the data that was successfully received prior to the termination of reception must be read from the RCVFIFO before the RCVFS bytes are available.
Media Access Control (MAC)
The Media Access Control engine is the heart of the MACE device, incorporating the essential protocol requirements for operation of a compliant Ethernet/802.3 node, and providing the interface between the FIFO
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AMD sub-system and the Manchester Encoder/Decoder (MENDEC). The MAC engine is fully compliant to Section 4 of ISO/ IEC 8802-3 (ANSI/IEEE Standard 1990 Second edition) and ANSI/IEEE 802.3 (1985). The MAC engine provides enhanced features, programmed through the Transmit Frame Control and Receive Frame Control registers, designed to minimize host supervision and pre or post message processing. These features include the ability to disable retries after a collision, dynamic FCS generation on a packet-bypacket basis, and automatic pad field insertion and deletion to enforce minimum frame size attributes. The two primary attributes of the MAC engine are: s Transmit and receive message data encapsulation - - - s Framing (frame boundary delimitation, frame synchronization) Addressing (source and destination address handling) Error detection (physical medium transmission errors) rently permitted, the MACE device will commence the 7 byte preamble sequence (10101010b, where first bit transmitted is a 1). The MACE device will subsequently append the Start Frame Delimiter (SFD) byte (10101011) followed by the serialized data from the Transmit FIFO. Once the data has been completed, the MACE device will append the FCS (most significant bit first) computed on the entire data portion of the message. Note that the user is responsible for the correct ordering and content in each of the fields in the frame, including the destination address, source address, length/type and packet data. The receive section of the MACE device will detect an incoming preamble sequence and lock to the encoded clock. The internal MENDEC will decode the serial bit stream and present this to the MAC engine. The MAC will discard the first 8-bits of information before searching for the SFD sequence. Once the SFD is detected, all subsequent bits are treated as part of the frame. The MACE device will inspect the length field to ensure minimum frame size, strip unnecessary pad characters (if enabled), and pass the remaining bytes through the Receive FIFO to the host. If pad stripping is performed, the MACE device will also strip the received FCS bytes, although the normal FCS computation and checking will occur. Note that apart from pad stripping, the frame will be passed unmodified to the host. If the length field has a value of 46 or greater, the MACE device will not attempt to validate the length against the number of bytes contained in the message. If the frame terminates or suffers a collision before 64-bytes of information (after SFD) have been received, the MACE device will automatically delete the frame from the Receive FIFO, without host intervention. Note however, that if the Low Latency Receive option has been enabled (LLRCV = 1 in the Receive Frame Control register), the MACE device will not delete receive frames which experience a collision once the 12-byte low watermark has been reached (see the FIFO SubSystem section for additional details).
Media access management - - Medium allocation (collision avoidance) Contention resolution (collision handling)
Transmit and Receive Message Data Encapsulation Data passed to the MACE device Transmit FIFO will be assumed to be correctly formatted for transmission over the network as a valid packet. The user is required to pass the data stream for transmission to the MACE chip in the correct order, according to the byte ordering convention programmed for the BIU. The MACE device provides minimum frame size enforcement for transmit and receive packets. When APAD XMT = 1 (default), transmit messages will be padded with sufficient bytes (containing 00h) to ensure that the receiving station will observe an information field (destination address, source address, length/type, data and FCS) of 64-bytes. When ASTRP RCV = 1 (default), the receiver will automatically strip pad and FCS bytes from the received message if the value in the length field is below the minimum data size (46-bytes). Both features can be independently over-ridden to allow illegally short (less than 64-bytes of packet data) messages to be transmitted and/or received.
Addressing (Source and Destination Address Handling)
The first 6-bytes of information after SFD will be interpreted as the destination address field. The MACE device provides facilities for physical, logical and broadcast address reception. In addition, multiple physical addresses can be constructed (perfect address filtering) using external logic in conjunction with the EADI interface.
Framing (Frame Boundary Delimitation, Frame Synchronization)
The MACE device will autonomously handle the construction of the transmit frame. When the Transmit FIFO has been filled to the predetermined threshold (set by XMTSP), and providing access to the channel is cur34
Error Detection (Physical Medium Transmission Errors)
The MACE device provides several facilities which report and recover from errors on the medium. In addition, the network is protected from gross errors due to
AM79C940
AMD inability of the host to keep pace with the MACE device activity. On completion of transmission, the MACE device will report the Transmit Frame Status for the frame. The exact number of transmission retry attempts is reported (ONE, MORE used with XMTRC, or RTRY), and whether the MACE device had to Defer (DEFER) due to channel activity. In addition, Loss of Carrier is reported, indicting that there was an interruption in the ability of the MACE device to monitor its own transmission. Repeated LCAR errors indicate a potentially faulty transceiver or network connection. Excessive Defer (EXDEF) will be reported in the Transmit Retry Count register if the transmit frame had to wait for an abnormally long period before transmission. Additional transmit error conditions are reported through the Interrupt Register. The Late Collision (LCOL) error indicates that the transmission suffered a collision after the slot time. This is indicative of a badly configured network. Late collisions should not occur in normal operating network. The Collision Error (CERR) indicates that the transceiver did not respond with an SQE Test message within the predetermined time after a transmission completed. This may be due to a failed transceiver, disconnected or faulty transceiver drop cable, or the fact the transceiver does not support this feature (or it is disabled). In addition to the reporting of network errors, the MACE device will also attempt to prevent the creation of any network error caused by inability of the host to service the MACE device. During transmission, if the host fails to keep the Transmit FIFO filled sufficiently, causing an underflow, the MACE device will guarantee the message is either sent as a runt packet (which will be deleted by the receiving station) or has an invalid FCS (which will also allow the receiving station to reject the message). The status of each receive message is passed via the Receive Frame Status bytes. FCS and Framing errors (FRAM) are reported, although the received frame is still passed to the host. The FRAM error will only be reported if an FCS error is detected and there are a non integral number of bytes in the message. The MACE device will ignore up to seven additional bits at the end of a message (dribbling bits), which can occur under normal network operating conditions. The reception of eight additional bits will cause the MACE device to de-serialize the entire byte, and will result in the received message and FCS being modified. Received messages which suffer a collision after 64-byte times (after SFD) will be marked to indicate they have suffered a late collision (CLSN). Additional counters are provided to report the Receive Collision Count and Runt Packet Count to be used for network statistics and utilization calculations. Note that if the MACE device detects a received packet which has a 00b pattern in the preamble (after the first 8-bits which are ignored), the entire packet will be ignored. The MACE device will wait for the network to go inactive before attempting to receive additional frames. Media Access Management The basic requirement for all stations on the network is to provide fairness of channel allocation. The 802.3/Ethernet protocols define a media access mechanism which permits all stations to access the channel with equality. Any node can attempt to contend for the channel by waiting for a predetermined time (Inter Packet Gap interval) after the last activity, before transmitting on the media. The channel is a bus or multidrop communications medium (with various topological configurations permitted) which allows a single station to transmit and all other stations to receive. If two nodes simultaneously contend for the channel, their signals will interact causing loss of data, defined as a collision. It is the responsibility of the MAC to attempt to avoid and recover from a collision, to guarantee data integrity for the endto-end transmission to the receiving station.
Medium Allocation (Collision Avoidance)
The IEEE 802.3 Standard (ISO/IEC 8802-3 1990) requires that the CSMA/CD MAC monitors the medium for traffic by watching for carrier activity. When carrier is detected, the media is considered busy, and the MAC should defer to the existing message. The IEEE 802.3 Standard also allows optional two part deferral after a receive message.
See ANSI/IEEE Std 802.3-1990 Edition, 4.2.3.2.1: "NOTE : It is possible for the PLS carrier sense indication to fail to be asserted during a collision on the media. If the deference process simply times the interFrame gap based on this indication it is possible for a short interFrame gap to be generated, leading to a potential reception failure of a subsequent frame. To enhance system robustness the following optional measures, as specified in 4.2.8, are recommended when interFrameSpacingPart1 is other than zero:"
(1) Upon completing a transmission, start timing the interpacket gap, as soon as transmitting and carrierSense are both false. (2) When timing an interFrame gap following reception, reset the interFrame gap timing if carrierSense becomes true during the first 2/3 of the interFrame gap timing interval. During the final 1/3 of the interval the timer shall not be reset to ensure fair access to the me-
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AMD dium. An initial period shorter than 2/3 of the interval is permissible including zero." The MAC engine implements the optional receive two part deferral algorithm, with a first part inter-framespacing time of 6.0 s. The second part of the interframe-spacing interval is therefore 3.6 s. The MACE device will perform the two part deferral algorithm as specified in Section 4.2.8 (Process Deference). The Inter Packet Gap (IPG) timer will start timing the 9.6 s InterFrameSpacing after the receive carrier is de-asserted. During the first part deferral (InterFrameSpacingPart1-IFS1) the MACE device will defer any pending transmit frame and respond to the receive message. The IPG counter will be reset to zero continuously until the carrier deasserts, at which point the IPG counter will resume the 9.6 s count once again. Once the IFS1 period of 6.0s has elapsed, the MACE device will begin timing the second part deferral (InterFrameSpacingPart2-IFS2) of 3.6 s. Once IFS1 has completed, and IFS2 has commenced, the MACE chip will not defer to a receive packet if a transmit packet is pending. This means that the MACE device will not attempt to receive an incoming packet, and it will start to transmit at 9.6 s regardless of network activity, forcing a collision if an existing transmission is in progress. The MACE device will guarantee to complete the preamble (64-bit) and jam (32-bit) sequence before ceasing transmission and invoking the random backoff algorithm. In addition to the deferral after receive process, the MACE device also allows transmit two part deferral to be implemented as an option. The option can be disabled using the DXMT2PD bit in the MAC Configuration Control register. Two part deferral after transmission is useful for ensuring that severe IPG shrinkage cannot occur in specific circumstances, causing a transmit message to follow a receive message so closely, as to make them indistinguishable. During the time period immediately after a transmission has been completed, the external transceiver (in the case of a standard AUI connected device), should generate the SQE Test message (a nominal 10 MHz burst of 5-15 BT duration) on the CI pair (within 0.6-1.6 s after the transmission ceases). During the time period in which the SQE Test message is expected the MACE device will not respond to receive carrier sense. to occur, no SQE test occurs in the DTE. The duration of the window shall be at least 4.0 s but no more than 8.0 s. During the time window the Carrier Sense Function is inhibited." The MACE device implements a carrier sense blinding period within 0 s-4.0 s from deassertion of carrier sense after transmission. This effectively means that when transmit two part deferral is enabled (DXMT2PD in the MAC Configuration Control register is cleared) the IFS1 time is from 4 s to 6 s after a transmission. However, since IPG shrinkage below 4 s will not be encountered on correctly configured networks, and since the fragment size will be larger than the 4 s blinding window, then the IPG counter will be reset by a worst case IPG shrinkage/fragment scenario and the MACE device will defer its transmission. The MACE chip will not restart the carrier sense blinding period if carrier is detected within the 4.0-6.0 s portion of IFS1, but will restart timing of the entire IFS1 period.
Contention Resolution (Collision Handling)
Collision detection is performed and reported to the MAC engine either by the integrated Manchester Encoder/Decoder (MENDEC), or by use of an external function (e.g. Serial Interface Adaptor, Am7992B) utilizing the GPSI. If a collision is detected before the complete preamble/ SFD sequence has been transmitted, the MACE device will complete the preamble/SFD before appending the jam sequence. If a collision is detected after the preamble/SFD has been completed, but prior to 512 bits being transmitted, the MACE device will abort the transmission, and append the jam sequence immediately. The jam sequence is a 32-bit all zeroes pattern. The MACE device will attempt to transmit a frame a total of 16 times (initial attempt plus 15 retries) due to normal collisions (those within the slot time). Detection of collision will cause the transmission to be re-scheduled, dependent on the backoff time that the MACE device computes. Each collision which occurs during the transmission process will cause the value of XMTRC in the Transmit Retry Count register to be updated. If a single retry was required, the ONE bit will be set in the Transmit Frame Status. If more than one retry was required, the MORE bit will be set, and the exact number of attempts can be determined (XMTRC+1). If all 16 attempts experienced collisions, the RTRY bit will be set (ONE and MORE will be clear), and the transmit message will be flushed from the XMTFIFO, either by resetting the XMTFIFO (if no End-of-Frame tag exists) or by moving the XMTFIFO read pointer to the next free location (If an End-of-Frame tag is present). If retries have been disabled by setting the DRTRY bit, the MACE device will abandon transmission of the frame on detection of the first collision. In this case, only the RTRY bit
See ANSI/IEEE Std 802.3-1990 Edition, 7.2.4.6 (1)):
"At the conclusion of the output function, the DTE opens a time window during which it expects to see the signal_quality_error signal asserted on the Control In circuit. The time window begins when the CARRIER_STATUS becomes CARRIER_OFF. If execution of the output function does not cause CARRIER_ON
36
AM79C940
AMD will be set and the transmit message will be flushed from the XMTFIFO. The RTRY condition will cause the deassertion of TDTREQ, and the assertion of the INTR pin, providing the XMTINTM bit is cleared. If a collision is detected after 512 bit times have been transmitted, the collision is termed a late collision. The MACE device will abort the transmission, append the jam sequence and set the LCOL bit in the Transmit Frame Status. No retry attempt will be scheduled on detection of a late collision, and the XMTFIFO will be flushed. The late collision condition will cause the de-assertion of TDTREQ, and the assertion of the INTR pin, providing the XMTINTM bit is cleared. The IEEE 802.3 Standard requires use of a truncated binary exponential backoff algorithm which provides a controlled pseudo random mechanism to enforce the collision backoff interval, before re-transmission is attempted. or it will be marked as a receive late collision, using the CLSN bit in the Receive Frame Status register. All frames which suffer a collision within the slot time will be deleted in the Receive FIFO without requesting host intervention, providing that the LLRCV bit (Receive Frame Control) is not set. Runt packets which suffer a collision will be aborted regardless of the state of the RPA bit (User Test Register). If the collision commences after the slot time, the MACE device receiver will stop sending collided packet data to the Receive FIFO and the packet data read by the system will contain the amount of data received to the point of collision; the CLSN bit in the Receive Frame Status register will indicate the receive late collision. Note that the Receive Message Byte Count will report the total number of bytes during the receive activity, including the collision. In all normal receive collision cases, the MACE device eliminates the transfer of packet data across the host bus. In a receive late collision condition, the MACE chip minimizes the amount transferred. These functions preserve bus bandwidth utilization.
See ANSI/IEEE Std 802.3-1990 Edition, 4.2.3.2.5:
"At the end of enforcing a collision (jamming), the CSMA/CD sublayer delays before attempting to re-transmit the frame. The delay is an integer multiple of slotTime. The number of slot times to delay before the nth re-transmission attempt is chosen as a uniformly distributed random integer r in the range: 0 r 2k, where k = min (n,10)." The MACE device implements a random number generator, configured to ensure that nodes experiencing a collision, will not have their retry intervals track identically, causing retry errors. The MACE device provides an alternative algorithm, which suspends the counting of the slot time/IPG during the time that receive carrier sense is detected. This aids in networks where large numbers of nodes are present, and numerous nodes can be in collision. It effectively accelerates the increase in the backoff time in busy networks, and allows nodes not involved in the collision to access the channel whilst the colliding nodes await a reduction in channel activity. Once channel activity is reduced, the nodes resolving the collision time-out their slot time counters as normal. If a receive message suffers a collision, it will be either a runt, in which case it will be deleted in the Receive FIFO,
Manchester Encoder/Decoder (MENDEC)
The integrated Manchester Encoder/Decoder provides the PLS (Physical Signaling) functions required for a fully compliant IEEE 802.3 station. The MENDEC block contains the AUI, DAI interfaces, and supports the 10BASE-T interface; all of which transfer data to appropriate transceiver devices in Manchester encoded format. The MENDEC provides the encoding function for data to be transmitted on the network using the high accuracy on-board oscillator, driven by either the crystal oscillator or an external CMOS level compatible clock generator. The MENDEC also provides the decoding function from data received from the network. The MENDEC contains a Power On Reset (POR) circuit, which ensures that all analog portions of the MACE device are forced into their correct state during power up, and prevents erroneous data transmission and/or reception during this time. External Crystal Characteristics When using a crystal to drive the oscillator, the following crystal specification should be used to ensure less than 0.5 ns jitter at DO:
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AMD
Parameter 1. Parallel Resonant Frequency 2. Resonant Frequency Error (CL = 20 pF) 3. Change in Resonant Frequency With Respect To Temperature (CL = 20 pF)* 4. Crystal Capacitance 5. Motional Crystal Capacitance (C1) 6. Series Resistance 7. Shunt Capacitance 0.022 35 7 -50 -40 Min Nom 20 +50 +40 20 Max Units MHz PPM PPM pF pF ohm pF
* Requires trimming crystal spec; no trim is 50 ppm total
External Clock Drive Characteristics When driving the oscillator from an external clock source, XTAL2 must be left floating (unconnected). An external clock having the following characteristics must be used to ensure less than 0.5 ns jitter at DO.
Clock Frequency: Rise/Fall Time (tR/tF): XTAL1 HIGH/LOW Time (tHIGH/tLOW): XTAL1 Falling Edge to Falling Edge Jitter: 20 MHz 0.01% < 6 ns from 0.5 V to VDD-0.5 40 - 60% duty cycle < 0.2 ns at 2.5 V input (VDD/2)
also used as a stable bit rate clock by the receive section of the SIA and controller. The oscillator requires an external 0.005% crystal, or an external 0.01% CMOS-level input as a reference. The accuracy requirements if an external crystal is used are tighter because allowance for the on-chip oscillator must be made to deliver a final accuracy of 0.01%. Transmission is enabled by the controller. As long as the ITENA request remains active, the serial output of the controller will be Manchester encoded and appear at DO. When the internal request is dropped by the controller, the differential transmit outputs go to one of two idle states, dependent on TSEL in the Mode Register (CSR15, bit 9):
TSEL LOW: The idle state of DO yields "zero" differential to operate transformercoupled loads. In this idle state, DO+ is positive with respect to DO- (logical\HIGH).
MENDEC Transmit Path The transmit section encodes separate clock and NRZ data input signals into a standard Manchester encoded serial bit stream. The transmit outputs (DO) are designed to operate into terminated transmission lines. When operating into a 78 ohm terminated transmission line, signaling meets the required output levels and skew for Cheapernet, Ethernet and IEEE-802.3. Transmitter Timing and Operation A 20 MHz fundamental mode crystal oscillator provides the basic timing reference for the SIA portion of the MACE device. It is divided by two, to create the internal transmit clock reference. Both clocks are fed into the SIA's Manchester Encoder to generate the transitions in the encoded data stream. The internal transmit clock is used by the SIA to internally synchronize the Internal Transmit Data (ITXD) from the controller and Internal Transmit Enable (ITENA). The internal transmit clock is
TSEL HIGH:
Receive Path The principal functions of the Receiver are to signal the MACE device that there is information on the receive pair, and separate the incoming Manchester encoded data stream into clock and NRZ data. The Receiver section (see Receiver Block Diagram) consists of two parallel paths. The receive data path is a zero threshold, wide bandwidth line receiver. The carrier path is an offset threshold bandpass detecting line receiver. Both receivers share common bias networks to allow operation over a wide input common mode range.
38
AM79C940
AMD
SRD SRDCLK
DI
Data Receiver
Manchester Decoder
Noise Reject Filter
Carrier Detect Circuit
RXCRS
16235C-5 16907A-008A
Receiver Block Diagram Input Signal Conditioning Transient noise pulses at the input data stream are rejected by the Noise Rejection Filter. Pulse width rejection is proportional to transmit data rate. DC inputs more negative than minus 100 mV are also suppressed. The Carrier Detection circuitry detects the presence of an incoming data packet by discerning and rejecting noise from expected Manchester data, and controls the stop and start of the phase-lock loop during clock acquisition. Clock acquisition requires a valid Manchester bit pattern of 1010 to lock onto the incoming message. When input amplitude and pulse width conditions are met at DI, the internal enable signal from the SIA to controller (RXCRS) is asserted and a clock acquisition cycle is initiated. Clock Acquisition When there is no activity at DI (receiver is idle), the receive oscillator is phase locked to TCK. The first negative clock transition (bit cell center of first valid Manchester "0") after RXCRS is asserted interrupts the receive oscillator. The oscillator is then restarted at the second Manchester "0" (bit time 4) and is phase locked to it. As a result, the SIA acquires the clock from the incoming Manchester bit pattern in 4 bit times with a "1010" Manchester bit pattern. SRDCLK and SRD are enabled 1/4 bit time after clock acquisition in bit cell 5 if the ENPLSIO bit is set in the PLS configuration control register. SRD is at a HIGH state when the receiver is idle (no SRDCLK). SRD however, is undefined when clock is acquired and may remain HIGH or change to LOW state whenever SRDCLK is enabled. At 1/4 bit time through bit cell 5, the controller portion of the MACE device sees the first SRDCLK transition. This also strobes in the incoming fifth bit to the SIA as Manchester "1". SRD may make a transition after the SRDCLK rising edge bit cell 5, but its state is still undefined. The Manchester "1" at bit 5 is clocked to SRD output at 1/4 bit time in bit cell 6. PLL Tracking After clock acquisition, the phase-locked clock is compared to the incoming transition at the bit cell center (BCC) and the resulting phase error is applied to a correction circuit. This circuit ensures that the phaselocked clock remains locked on the received signal. Individual bit cell phase corrections of the Voltage Controlled Oscillator (VCO) are limited to 10% of the phase difference between BCC and phase-locked clock. Carrier Tracking and End of Message The carrier detection circuit monitors the DI inputs after RXCRS is asserted for an end of message. RXCRS deasserts 1 to 2 bit times after the last positive transition on the incoming message. This initiates the end of reception cycle. The time delay from the last rising edge of the message to RXCRS deassert allows the last bit to be strobed by SRDCLK and transferred to the controller section, but prevents any extra bit(s) at the end of message. When IRENA de-asserts (see Receive TimingEnd of Reception (Last Bit = 0) and Receive Timing-End of Reception (Last Bit = 1) waveform diagrams) an RXCRS hold off timer inhibits RXCRS assertion for at least 2 bit times. Data Decoding The data receiver is a comparator with clocked output to minimize noise sensitivity to the DI inputs. Input error is less than 35 mV to minimize sensitivity to input rise and fall time. SRDCLK strobes the data receiver output at 1/4 bit time to determine the value of the Manchester bit, and clocks the data out on SRD on the following SRDCLK. The data receiver also generates the signal used for phase detector comparison to the internal SIA voltage controlled oscillator (VCO). Differential Input Terminations The differential input for the Manchester data (DI) is externally terminated by two 40.2 ohm 1% resistors and one optional common-mode bypass capacitor, as shown in the Differential Input Termination diagram
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AMD below. The differential input impedance, ZIDF, and the common-mode input impedance, ZICM, are specified so that the Ethernet specification for cable termination impedance is met using standard 1% resistor terminators. If SIP devices are used, 39 ohms is also a suitable value. The CI differential inputs are terminated in exactly the same way as the DI pair.
AUI Isolation Transformer DI+ MACE DI-
40.2
40.2
0.01F
16235C-6 16907A-009A
Differential Input Termination Collision Detection A transceiver detects the collision condition on the network and generates a differential signal at the CI inputs. This collision signal passes through an input stage which detects signal levels and pulse duration. When the signal is detected by the MENDEC it sets the CLSN line HIGH. The condition continues for approximately 1.5 bit times after the last LOW-to-HIGH transition on CI. Jitter Tolerance Definition The Receive Timing-Start of Reception Clock Acquisition waveform diagram shows the internal timing relationships implemented for decoding Manchester data in the SIA module. The SIA utilizes a clock capture circuit to align its internal data strobe with an incoming bit stream. The clock acquisition circuitry requires four valid bits with the values 1010. Clock is phase locked to the negative transition at the bit cell center of the second "0" in the pattern. Since data is strobed at 1/4 bit time, Manchester transitions which shift from their nominal placement through 1/4 bit time will result in improperly decoded data. With this as the criteria for an error, a definition of "Jitter Handling" is: The peak deviation approaching or crossing 1/4 bit cell position from nominal input transition, for which the SIA section will properly decode data. After the MACE device initiates a transmission it will expect to see data looped-back on the DI pair (AUI port selected). This will internally generate a carrier sense, indicating that the integrity of the data path to and from the MAU is intact, and that the MAU is operating correctly. This carrier sense signal must be asserted during the transmission when using the AUI port (DO transmitting). If carrier sense does not become active in response to the data transmission, or becomes inactive before the end of transmission, the loss of carrier (LCAR) error bit will be set in the Transmit Frame Status (bit 7) after the packet has been transmitted.
Digital Attachment Interface (DAI )
The Digital Attachment Interface is a simplified electrical attachment specification which allows MAUs which do not require the DC isolation between the MAU and DTE (e.g. devices compatible with the 10BASE-T Standard and 10BASE-FL Draft document) to be implemented. All data transferred across the DAI port is Manchester Encoded. Decoding and encoding is performed by the MENDEC. The DAI port will accept receive data on the basis that the RXCRS input is active, and will take the data presented on the RXDAT input as valid Manchester data. Transmit data is sent to the external transceiver by the MACE device asserting TXEN and presenting complimentary data on the TXDAT pair. During idle, the MACE device will assert the TXDAT+ line high, and the TXDAT line low, while TXEN is maintained inactive (high). The MACE device implements logical collision detection and will use the simultaneous assertion of TXEN and RXCRS to internally detect a collision condition, take appropriate internal action (such as abort the current transmit or receive activity), and provide external indication using the CLSN pin. Any external
Attachment Unit Interface (AUI)
The AUI is the PLS (Physical Signaling) to PMA (Physical Medium Attachment) interface which effectively connects the DTE to the MAU. The differential interface provided by the MACE device is fully compliant to Section 7 of ISO 8802-3 (ANSI/IEEE 802.3). 40
AM79C940
AMD transceiver utilized for the DAI interface must not loop back the transmit data (presented by the MACE device) on the TXDAT pins to the RXDAT pin. Neither should the transceiver assert the RXCRS pin when transmitting data to the network. Duplication of these functions by the external transceiver (unless the MACE device is in the external loop back test configuration) will cause false collision indications to be detected. In order to provide an integrity test of the connectivity between the MACE device and the external transceiver similar to the SQE Test Message provided as a part of the AUI functionality, the MACE device can be programmed to operate the DAI port in an external loopback test. In this case, the external transceiver is assumed to loopback the TXDAT data stream to the RXDAT pin, and assert RXCRS in response to the TXEN request. When in the external loopback mode of operation (programmed by LOOP [1-0] = 01), the MACE device will not internally detect a collision condition. The external transceiver is assumed to take action to ensure that this test will not disrupt the network. This type of test is intended to be operated for a very limited period (e.g. after power up), since the transceiver is assumed to be located physically close to the MACE device and with minimal risk of disconnection (e.g. connected via printed circuit board traces). Note that when the DAI port is selected, LCAR errors will not occur, since the MACE device will internally loop back the transmit data path to the receiver. This loop back function must not be duplicated by a transceiver which is externally connected via the DAI port, since this will result in a condition where a collision is generated during any transmit activity. The transmit function of the DAI port is protected by a jabber mechanism which will be invoked if the TXDAT and TXEN circuit is active for an excessive period (20 - 150 ms). This prevents a single node from disrupting the network due to a stuck-on or faulty transmitter. If this maximum transmit time is exceeded, the DAI port transmitter circuitry is disabled, the CLSN pin is asserted, the Jabber bit (JAB in the Interrupt Register) is set and the INTR pin will be asserted providing the JABM bit (Interrupt Mask Register) is cleared. Once the internal transmit data stream from the MENDEC stops (TXEN deasserts), an unjab time of 250 ms-750 ms will elapse before the MACE device deasserts the CLSN indication and re-enables the transmit circuitry. When jabber is detected, the MACE device will assert the CLSN pin, de-assert the TXEN pin (regardless of internal MENDEC activity) and set the TXDAT+ and TXDAT pins to their inactive state.
10BASE-T Interface Twisted Pair Transmit Function
Data transmission over the 10BASE-T medium requires use of the integrated 10BASE-T MAU, and uses the differential driver circuitry in the TXD and TXP pins. The driver circuitry provides the necessary electrical driving capability and the pre-distortion control for transmitting signals over maximum length Twisted Pair cable, as specified by the 10BASE-T supplement to the IEEE 802.3 Standard. The transmit function for data output meets the propagation delays and jitter specified by the standard. During normal transmission, and providing that the 10BASE-T MAU is not in a Link Fail or jabber state, the TXEN pin will be driven LOW and can be used indirectly to drive a status LED.
Twisted Pair Receive Function
The receiver complies with the receiver specifications of the IEEE 802.3 10BASE-T Standard, including noise immunity and received signal rejection criteria (Smart Squelch). Signals meeting this criteria appearing at the RXD differential input pair are routed to the internal MENDEC. The receiver function meets the propagation delays and jitter requirements specified by the 10BASE-T Standard. The receiver squelch level drops to half its threshold value after unsquelch to allow reception of minimum amplitude signals and to mitigate carrier fade in the event of worst case signal attenuation and crosstalk noise conditions. During receive, the RXCRS pin is driven HIGH and can be used indirectly to drive a status LED. Note that the 10BASE-T Standard defines the receive input amplitude at the external Media Dependent Interface (MDI). Filter and transformer loss are not specified. The 10BASE-T MAU receiver squelch levels are defined to account for a 1dB insertion loss at 10 MHz, which is typical for the type of receive filters/transformers recommended (see the Appendix for additional details). Normal 10BASE-T compatible receive thresholds are employed when the LRT bit is inactive (PHY Configuration Control register). When the LRT bit is set, the Low Receive Threshold option is invoked, and the sensitivity of the 10BASE-T MAU receiver is increased. This allows longer line lengths to be employed, exceeding the 100m target distance of normal 10BASE-T (assuming typical 24 AWG cable). The additional cable distance attributes directly to increased signal attenuation and reduced signal amplitude at the 10BASE-T MAU receiver. However, from a system perspective, making the receiver more sensitive means that it is also more susceptible to
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AMD extraneous noise, primarily caused by coupling from coresident services (crosstalk). For this reason, it is recommended that when using the Low Receive Threshold option that the service should be installed on 4-pair cable only. Multi-pair cables within the same outer sheath have lower crosstalk attenuation, and may allow noise emitted from adjacent pairs to couple into the receive pair, and be of sufficient amplitude to falsely unsquelch the 10BASE-T MAU receiver. If the RWAKE bit is set in the PHY Configuration Control register prior to the assertion of the hardware SLEEP pin, the 10BASE-T receiver and transmitter functions remain active, the LNKST output is disabled, and the EADI output pins are enabled. In addition the AUI port (transmit and receive) remains active. Note that since the MAC core will be in a sleep mode, no transmit activity is possible, and the transmission of Link Test pulses is also suspended to reduce power consumption.
Link Test Function
The link test function is implemented as specified by 10BASE-T standard. During periods of transmit pair inactivity, Link Test pulses will be periodically sent over the twisted pair medium to constantly monitor medium integrity. When the link test function is enabled, the absence of Link Test pulses and receive data on the RXD pair will cause the 10BASE-T MAU to go into a Link Fail state. In the Link Fail state, data transmission, data reception, data loopback and the collision detection functions are disabled, and remain disabled until valid data or >5 consecutive link pulses appear on the RXD pair. During Link Fail, the LNKST pin is inactive (externally pulled HIGH), and the Link Fail bit (LNKFL in the PHY Configuration Control register) will be set. When the link is identified as functional, the LNKST pin is driven LOW (capable of directly driving a Link OK LED using an integrated 12 mA driver) and the LNKFL bit will be cleared. In order to inter-operate with systems which do not implement link test, this function can be disabled by setting the the Disable Link Test bit (DLNKTST in the PHY Configuration Control register). With link test disabled, the data driver, receiver and loopback functions as well as collision detection remain enabled irrespective of the presence or absence of data or link pulses on the RXD pair. The MACE devices integrated 10BASE-T transceiver will mimic the performance of an externally connected device (such as a 10BASE-T MAU connected using an AUI). When the 10BASE-T transceiver is in link fail, the receive data path of the transceiver must be disabled. The MACE device will report a Loss of Carrier error (LCAR bit in the Transmit Frame Status register) due to the absence of the normal loopback path, for every packet transmitted during the link fail condition. In addition, a Collision Error (CERR bit in the Transmit Frame Status register) will also be reported (see the section on Signal Quality Error Test Function for additional details). If the AWAKE bit is set in the PHY Configuration Control register prior to the assertion of the hardware SLEEP pin, the 10BASE-T receiver remains operable, and is able to detect and indicate (using the LNKST output) the presence of legitimate Link Test pulses or receive activity. The transmission of Link Test pulses is suspended to reduce power consumption. 42
Polarity Detection and Reversal
The Twisted Pair receive function includes the ability to invert the polarity of the signals appearing at the RXD pair if the polarity of the received signal is reversed (such as in the case of a wiring error). This feature allows data packets received from a reverse wired RXD input pair to be corrected in the 10BASE-T MAU prior to transfer to the MENDEC. The polarity detection function is activated following reset or Link Fail, and will reverse the receive polarity based on both the polarity of any previous Link Test pulses and the polarity of subsequent packets with a valid End Transmit Delimiter (ETD). When in the Link Fail state, the internal 10BASE-T receiver will recognize Link Test pulses of either positive or negative polarity. Exit from the Link Fail state is made due to the reception of five to six consecutive Link Test pulses of identical polarity. On entry to the Link Pass state, the polarity of the last five Link Test pulses is used to determine the initial receive polarity configuration and the receiver is reconfigured to subsequently recognize only Link Test pulses of the previously recognized polarity. This link pulse algorithm is employed only until ETD polarity determination is made as described later in this section. Positive Link Test pulses are defined as received signal with a positive amplitude greater than 520 mV (LRT = LOW) with a pulse width of 60 ns-200 ns. This positive excursion may be followed by a negative excursion. This definition is consistent with the expected received signal at a correctly wired receiver, when a Link Test pulse which fits the template of Figure 14-12 in the 10BASE-T Standard is generated at a transmitter and passed through 100 m of twisted pair cable. Negative Link Test pulses are defined as received signals with a negative amplitude greater than 520 mV (LRT = LOW) with a pulse width of 60 ns-200 ns. This negative excursion may be followed by a positive excursion. This definition is consistent with the expected received signal at a reverse wired receiver, when a Link Test pulse which fits the template of Figure 14-12 in the 10BASE-T Standard is generated at a transmitter and passed through 100 m of twisted pair cable. The polarity detection/correction algorithm will remain armed until two consecutive packets with valid ETD of identical polarity are detected. When armed, the
AM79C940
AMD receiver is capable of changing the initial or previous polarity configuration based on the most recent ETD polarity. On receipt of the first packet with valid ETD following reset or Link Fail, the MACE device will utilize the inferred polarity information to configure its RXD input, regardless of its previous state. On receipt of a second packet with a valid ETD with correct polarity, the detection/correction algorithm will lock-in the received polarity. If the second (or subsequent) packet is not detected as confirming the previous polarity decision, the most recently detected ETD polarity will be used as the default. Note that packets with invalid ETD have no effect on updating the previous polarity decision. Once two consecutive packets with valid ETD have been received, the MACE device will disable the detection/correction algorithm until either a Link Fail condition occurs or a hardware or software reset occurs. During polarity reversal, the RXPOL pin should be externally pulled HIGH and the Reversed Polarity bit (REVPOL in the PHY Configuration Control register) will be set. During normal polarity conditions, the RXPOL pin is driven LOW (capable of directly driving a Polarity OK LED using an integrated 12 mA driver) and the REVPOL bit will be cleared. If desired, the polarity correction function can be disabled by setting the Disable Auto Polarity Correction bit (DAPC bit in the PHY Configuration Control register). However, the polarity detection portion of the algorithm continues to operate independently, and the RXPOL pin and the REVPOL bits will reflect the polarity state of the receiver. In jabber detect mode, the MACE device will activate the CLSN pin, disable TXEN (regardless of Manchester data output from the MENDEC), and allow the RXCRS pin to indicate the current state of the RXD pair. If there is no receive activity on RXD, only CLSN will be active during jabber detect. If there is RXD activity, both CLSN and RXCRS will be active. If the SLEEP pin is asserted (regardless of the programming of the AWAKE or RWAKE bits in the PHY Configuration Control register), the TXEN, RXCRS and CLSN outputs will be placed in a high impedance state.
Collision Detect Function
Simultaneous activity (presence of valid data signals) from both the internal MENDEC transmit function (indicated externally by TXEN active) and the twisted pair RXD pins constitutes a collision, thereby causing an external indication on the CLSN pin, and an internal indication which is returned to the MAC core. The TXEN, RXCRS and CLSN pins are driven high during collision.
Signal Quality Error (SQE) Test (Heartbeat) Function
The SQE Test message (a 10 MHz burst normally returned on the AUI CI pair at the end of every transmission) is intended to be a self-test indication to the DTE that the MAU collision circuitry is functional and the AUI cable/connection is intact. This has minimal relevance when the 10BASE-T MAU is embedded in the LAN controller. A Collision Error (CERR bit in the Interrupt Register) will be reported only when the 10BASE-T port is in the link fail state, since the collision circuit of the MAU will be disabled, causing the absence of the SQE Test message. In GPSI mode the external encoder/decoder is responsible for asserting the CLSN pin after each transmission. In DAI mode SEQ Test has no relevance.
Twisted Pair Interface Status
Three outputs (TXEN, RXCRS and CLSN) indicate whether the MACE device is transmitting (MENDEC to Twisted Pair), receiving (Twisted Pair to MENDEC), or in a collision state with both functions active simultaneously. The MACE device will power up in the Link Fail state. The normal algorithm will apply to allow it to enter the Link Pass state. On power up, the TXEN, RXCRS and CLSN) pins will be in a high impedance state until they are enabled by setting the Enable PLS I/O bit (ENPLSIO in the PLS Configuration Control register) and the 10BASE-T port enters the Link Pass state. In the Link Pass state, transmit or receive activity which passes the pulse width/amplitude requirements of the DO or RXD inputs, will be indicated by the TXEN or RXCRS pin respectively going active. TXEN, RXCRS and CLSN are all asserted during a collision. In the Link Fail state, TXEN, RXCRS and CLSN are inactive.
Jabber Function
The Jabber function inhibits the twisted pair transmit function of the MACE device if the TXD/TXP circuits are active for an excessive period (20-150 ms). This prevents any one node from disrupting the network due to a stuck-on or faulty transmitter. If this maximum transmit time is exceeded, the data path through the 10BASE-T transmitter circuitry is disabled (although Link Test pulses will continue to be sent), the CLSN pin is asserted, the Jabber bit (JAB in the Interrupt Register) is set and the INTR pin will be asserted providing the JABM bit (Interrupt Mask Register) is cl eared. Once the internal transmit data stream from the MENDEC stops (TXEN deasserts), an unjab time of 250-750 ms will elapse before the MACE device deasserts the CLSN indication and re-enables the transmit circuitry. When jabber is detected, the MACE device will assert the CLSN pin, de-assert the TXEN pin (regardless of
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AMD internal MENDEC activity), and allow the RXCRS pin to indicate the current state of the RXD pair. If there is no receive activity on RXD, only CLSN will be active during jabber detect. If there is RXD activity, both CLSN and RXCRS will be active. alternate methods are programmed using the Match/ Reject (M/R) bit in the Receive Frame Control register. If the M/R bit is set, the pin is configured as EAM (External Address Match). The MACE device can be configured with Physical, Logical or Broadcast Address comparison operational. If an internal address match is detected, the packet will be accepted regardless of the condition of EAM. Additional addresses can be located in the external address detection logic. If a match is detected, EAM must go active within 600 ns of the last bit in the destination address field (end of byte 6) being presented on the SRD output, to guarantee frame reception. In addition, EAM must go inactive after a match has been detected on a previous packet, before the next match can take place on any subsequent packet. EAM must be asserted for a minimum pulse width of 200 ns. If the M/R bit is clear (default state after either the RESET pin or SWRST bit have been activated), the pin is configured as EAR (External Address Reject). The MACE device can be configured with Physical, Logical or Broadcast Address comparison operational. If an internal address match is detected, the packet will be accepted regardless of the condition of EAR. Incoming packets which do not pass the internal address comparison will continue to be received by the MACE device. EAR must be externally presented to the MACE chip prior to the first assertion of RDTREQ, to guarantee rejection of unwanted packets. This allows approximately 58 byte times after the last destination address bit is available to generate the EAR signal, assuming the MACE device is not configured to accept runt packets. EAR will be ignored by the MACE device from 64 byte times after the SFD, and the packet will be accepted if EAR has not been asserted before this time. If the MACE device is configured to accept runt packets, the EAR signal must be generated prior to the receive message completion, which could be as short as 12 byte times (assuming six bytes for source address, two bytes for length, no data, four bytes for FCS) after the last bit of the destination address is available. EAR must have a pulse width of at least 200 ns. Note that setting the PROM bit (MAC Configuration Control) will cause all receive packets to be received, regardless of the programming of M/R or the state of the EAM/R input. The following table summarizes the operation of the EADI features.
External Address Detection Interface (EADI)
This interface is provided to allow external perfect address filtering. This feature is typically utilized for terminal server, bridge and/or router type products. The use of external logic is required, to capture the serial bit stream from the MACE device, and compare this with a table of stored addresses or identifiers. See the EADI port diagram in the Systems Applications section, Network Interfaces sub-section, for details. The EADI interface operates directly from the NRZ decoded data and clock recovered by the Manchester decoder. This allows the external address detection to be performed in parallel with frame reception and address comparison in the MAC Station Address Detection (SAD) block. SRDCLK is provided to allow clocking of the receive bit stream from the MACE device, into the external address detection logic. Once a received packet commences and data and clock are available from the decoder, the EADI interface logic will monitor the alternating (1,0) preamble pattern until the two ones of the Start Frame Delimiter (1,0,1,0,1,0,1,1) are detected, at which point the SF/BD output will be driven high. After SF/BD is asserted the serial data from SRD should be de-serialized and sent to a Content Addressable Memory (CAM) or other address detection device. To allow simple serial to parallel conversion, SF/BD is provided as a strobe and/or marker to indicate the delineation of bytes, subsequent to the SFD. This feature provides a mechanism to allow not only capture and/or decoding of the physical or logical (group) address, but also facilitates the capture of header information to determine protocol and or inter-networking information. The EAM/R pin is driven by the external address comparison logic, to either reject or accept the packet. Two alternative modes are permitted, allowing the external logic to either accept the packet based on address match, or reject the packet if there is no match. The two
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AMD Internal/External Address Recognition Capabilities
PROM 1 0 0 0 0 M/R X 0 0 1 1 EAM/R X H Required Timing No timing requirements No timing requirements Low for 200 ns within 512-bits after SFD No timing requirements Low for 200 ns within 8-bits after DA field Received Messages All Received Frames All Received Frames Physical/Logical/Broadcast Matches Physical/Logical/Broadcast Matches All Received Frames
H
General Purpose Serial Interface (GPSI)
The GPSI port provides the signals necessary to present an interface consistent with the non encoded data functions observed to/from a LAN controller such as the Am7990 Local Area Network Controller for Ethernet (LANCE). The actual GPSI pins are functionally identical to some of the pins from the DAI and the EADI ports, the GPSI replicates this type of interface. The GPSI allows use of an external Manchester encoder/decoder, such as the Am7992B Serial Interface Adapter (SIA). In addition, it allows the MACE device to be used as a MAC sublayer engine in a repeater based on the Am79C980 Integrated Multiport Repeater (IMR). Simple connection to the IMR Expansion Bus allows the MAC to view all packet data passing through a number of interconnected IMRs, allowing statistics and network management information to be collected. The GPSI functional pins are duplicated as follows: Pin Configuration for GPSI Function
Function Receive Data Receive Clock Receive Carrier Sense Collision Transmit Data Transmit Clock Transmit Enable Type I I I I O I O LANCE Pin RX RCLK RENA CLSN TX TCK TENA MACE Pin RXDAT SRDCLK RXCRS CLSN TXDAT+ STDCLK TXEN
The boundary scan test circuit requires four pins (TCK, TMS, TDI and TDO ), defined as the Test Access Port (TAP). It includes a finite state machine (FSM), an instruction register, a data register array and a power on reset circuit. Internal pull-up resistors are provided for the TCK, TDI and TMS pins. The TAP engine is a 16 state FSM, driven by the Test Clock (TCK) and the Test Mode Select (TMS) pins. An independent power on reset circuit is provided to ensure the FSM is in the TEST_LOGIC_RESET state at power up. In addition to the minimum IEEE 1149.1 instruction requirements (EXTEST, SAMPLE and BYPASS), three additional instructions (IDCODE, TRI_ST and SET_I/O) are provided to further ease board level testing. All unused instruction codes are reserved. IEEE 1149.1 Supported Instruction Summary
Inst Name Description Selected Data Reg BSR ID Reg BSR Bypass Bypass Bypass Reg Mode Test Normal Normal Normal Test Normal Inst Code 0000 0001 0010 0011 0100 1111
EXTEST External Test ID Code ID Code Inspection Sample TRI_ST Bypass Sample Boundary Force Tristate Bypass Scan
SET_I/0 Control Boundary To I/0
After hardware or software reset, the IDCODE instruction is always invoked. The decoding logic provides signals to control the data flow in the DATA registers according to the current instruction. Each Boundary Scan Register (BSR) cell also has two stages. A flip-flop and a latch are used in the SERIAL SHIFT STAGE and the PARALLEL OUTPUT STAGE respectively. There are four possible operational modes in the BSR cell: (1) CAPTURE (2) SHIFT (3) UPDATE (4) SYSTEM FUNCTION
IEEE 1149.1 Test Access Port Interface
An IEEE 1149.1 compatible boundary scan Test Access Port is provided for board level continuity test and diagnostics. All digital input, output and input/output and input/output pins are tested. Analog pins, including the AUI differential driver (DO) and receivers DI, CI), and the crystal input (XTAL1/XTAL2) pins, are not tested. The following is a brief summary of the IEEE 1149.1 compatible test functions implemented in the MACE device. For additional details, consult the IEEE Standard Test Access Port and Boundary-Scan Architecture document (IEEE Std 1149.1-1990).
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AMD Other Data Registers s s BYPASS REG (1 bit) Device Identification Register (32 bits) Bits 31-28: Version (4 bits) Bits 27-12: Part number (16 bits) is 9400H Bits 11-1: Manufacturer ID (11 bits). The manufacturer ID code for AMD is 00000000001 in accordance with JEDEC Publication 106-A. Bit 0: Always a logic 1 If FDS is low, a FIFO Direct read will take place from the RCVFIFO. The state of the ADD4-0 bus is irrelevant for the FIFO Direct mode. With either the CS or FDS input active, the state of the ADD0-4 (for Register Address reads), R/W (high to indicate a read cycle), BE0 and BE1 will also be latched on the falling (EDSEL = HIGH) edge of SCLK at S0. From the falling edge of SCLK in S1 (EDSEL = HIGH), the MACE device will drive data on DBUS15-0 and activate the DTV output (providing the read cycle completed successfully). If the cycle read the last byte/word of data for a specific frame from the RCVFIFO, the MACE device will also assert the EOF signal. DBUS15-0, DTV and EOF will be guaranteed valid and can be sampled on the falling (EDSEL = HIGH) edge of SCLK at S2. If the Register Address mode is being used to access the RCVFIFO, once EOF is asserted during the last byte/word read for the frame, the Receive Frame Status can be read in one of two ways. The Register Address mode can be continued, by placing the appropriate address (00110b) on the address bus and executing four read cycles (CS active) on the Receive Frame Status location. In this case, additional Register Address read requests from the RCVFIFO will be ignored, and no DTV returned, until all four bytes of the Receive Frame Status register have been read. Alternatively, a FIFO Direct read can be performed, which will effectively route the Receive Frame Status through the RCVFIFO location. This mechanism is explained in more detail below. If the FIFO Direct mode is used, the Receive Frame Status can be read directly from the RCVFIFO by continuing to execute read cycles (by asserting FDS low and R/W high) after EOF is asserted indicating the last byte/word read for the frame. Each of the four bytes of Receive Frame Status will appear on both halves of the data bus, as if the actual Receive Frame Status register were being accessed. Alternatively, the status can be read as normal using the Register Address mode by placing the appropriate address (00110b) on the address bus and executing four read cycles (CS active). Either the FIFO Direct or Register Address modes can be interleaved at any time to read the Receive Frame Status, although this is considered unlikely due to the additional overhead it requires. In either case, no additional data will be read from the RCVFIFO until the Receive Frame Status has been read, as four bytes appended to the end of the packet when using the FIFO Direct mode, or as four bytes from the Receive Frame Status location when using the Register Address mode. EOF will only be driven by the MACE device when reading received packet data from the RCVFIFO. At all other times, including reading the Receive Frame Status
SLAVE ACCESS OPERATION
Internal register accesses are based on a 2 or 3 SCLK cycle duration, dependent on the state of the TC input pin. TC must be externally pulled low to force the MACE device to perform a 3-cycle access. TC is internally pulled high if left unconnected, to configure the 2-cycle access by default. All register accesses are byte wide with the exception of the data path to and from the internal FIFOs. Data exchanges to/from register locations will take place over the appropriate half of the data bus to suit the host memory organization (as programmed by the BSWP bit in the BIU Configuration Control register). The BE0, BE1 and EOF signals are provided to allow control of the data flow to and from the FIFOs. Byte read operations from the Receive FIFO cause data to be duplicated on both the upper and lower bytes of the data bus. Byte write operations to the Transmit FIFO must use the BE0 and BE1 inputs to define the active data byte to the MACE device.
Read Access
Details of the read access timing are located in the AC Waveforms section, Host System Interface, figures: Two-Cycle Receive FIFO/Register Read Timing and Three-Cycle Receive FIFO/Register Read Timing. TC can be dynamically changed on a cycle by cycle basis to program the slave cycle execution for two (TC = HIGH) or three (TC = LOW) SCLK cycles. TC must be stable by the falling edge of SCLK (EDSEL = High) in S0 at the start of a cycle, and should only be changed in S0 in a multiple cycle burst. A read cycle is initiated when either CS or FDS is sampled low on the falling edge of SCLK at S0. FDS and CS must be asserted exclusively. If they are active simultaneously when sampled, the MACE device will not execute any read or write cycle. If CS is low, a Register Address read will take place. The state of the ADD4-0 will be used to commence decoding of the appropriate internal register/FIFO.
46
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AMD using the FIFO Direct mode, the MACE device will place EOF in a high impedance state. RDTREQ should be sampled on the falling edge of SCLK. The assertion of RDTREQ is programmed by RCVFW, and the de-assertion is modified dependent on the state of the RCVBRST bit (both in the FIFO Configuration Control register). See the section Receive FIFO Read for additional details. Write the PHY Configuration Control (PHYCC) register to configure any non-default mode if the 10BASE-T interface is used. Program the Logical Address Filter (LADRF) register or the Physical Address Register (PADR). The Internal Address Configuration (IAC) register must be accessed first. Set the Address Change (ADDRCHG) bit to request access to the internal address RAM. Poll the bit until it is cleared by the MACE device indicating that access to the internal address RAM is permitted. In the case of an address RAM access after hardware or software reset (ENRCV has not been set), the MACE device will return ADDRCHG = 0 right away. Set the LOGADDR bit in the IAC register to select writing to the Logical Address Filter register. Set the PHYADDR bit in the IAC register to select writing to the Physical Address Register. Either bit can be set together with writing the ADDRCHG bit. Initializing the Logical Address Filter register requires 8 write cycles. Initializing the Physical Address Register requires 6 write cycles. Write the User Test Register (UTR) to set the MACE device into any of the user diagnostic modes such as loopback. Write the MAC Configuration Control (MACCC) register as the last step in the initialization sequence to enable the receiver and transmitter. Note that the system must guarantee a delay of 1 ms after power-up before enabling the receiver and transmitter to allow the MACE phase lock loop to stabilize. The Transmit Frame Control (XMTFC) and the Receive Frame Control (RCVFC) registers can be programmed on a per packet basis.
Write Access
Details of the write access timing are located in the AC Waveforms section, Host System Interface, figures: Two-Cycle Transmit FIFO/Register Write Timing and Three-Cycle Transmit FIFO/Register Write Timing. Write cycles are executed in a similar manner as the read cycle previously described, but with the R/W input low, and the host responsible to provide the data with sufficient set up to the falling edge of SCLK after S2. After a FIFO write, TDTREQ should be sampled on or after the falling (EDSEL = HIGH) edge of SCLK after S3 of the FIFO write. The state of TDTREQ at this time will reflect the state of the XMTFIFO. After going active (low), TDTREQ will remain low for two or more XMTFIFO writes. The minimum high (inactive) time of TDTREQ is one SCLK cycle. When EOF is written to the Transmit FIFO, TDTREQ will go inactive after one SCLK cycle, for a minimum of one SCLK cycle.
Initialization
After power-up, RESET should be asserted for a minimum of 15 SCLK cycles to set the MACE device into a defined state. This will set all MACE registers to their default values. The receive and transmit functions will be turned off. A typical sequence to initialize the MACE device could look like this: Write the BIU Configuration Control (BIUCC) register to change the Byte Swap mode to big endian or to change the Transmit Start Point. Write the FIFO Configuration Control (FIFOCC) register to change the FIFO watermarks or to enable the FIFO Burst Mode. Write the Interrupt Mask Register (IMR) to disable unwanted interrupt sources. Write the PLS Configuration Control (PLSCC) register to enable the active network port. If the GPSI interface is used, the register must be written twice. The first write access should only set PORTSEL[1-0] = 11. The second access must write again PORTSEL[1-0] = 11 and additionally set ENPLSIO = 1. This sequence is required to avoid contention on the clock, data and/or carrier indication signals.
Reinitialization
The SWRST bit in the BIU Configuration Control (BIUCC) register can be set to reset the MACE device into a defined state for reinitialization. The same sequence described in the initialization section can be used. The 1 ms delay for the MACE phase lock loop stabilization need not to be observed as it only applies to a power-up situation.
TRANSMIT OPERATION
The transmit operation and features of the MACE device are controlled by programmable options. These options are programmed through the BIU, FIFO and MAC Configuration Control registers. Parameters controlled by the MAC Configuration Control register are generally programmed only once, during initialization, and are therefore static during the normal operation of the MACE device (see the Media Access Control section for a detailed description). The features controlled by the FIFO Configuration Control
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AMD register and the Transmit Frame Control register can be re-programmed if the MACE device is not transmitting. and ENXMT set to restart the transmit process with the new parameters. APAD XMT is sampled if there are less than 60 bytes in the transmit packet when the last bit of the last byte is transmitted. If APAD XMT is set, a pad field of pattern 00h is added until the minimum frame size of 64 bytes (excluding preamble and SFD) is achieved. If APAD XMT is clear, no pad field insertion will take place and runt packet transmission is possible. When APAD XMT is enabled, the DXMTFCS feature is over-ridden and the four byte FCS will be added to the transmitted packet unconditionally. The disable FCS generation/transmission feature can be programmed dynamically on a packet by packet basis. The current state of the DXMTFCS bit is internally latched on the last write to the Transmit FIFO, when the EOF indication is asserted by the host/controller. The programming of static transmit attributes are distributed between the BIU, FIFO and MAC Configuration Control registers. The point at which transmission begins in relation to the number of bytes of a frame in the FIFO is controlled by the XMTSP bits in the BIU Configuration Control register. Depending on the bus latency of the system, XMTSP can be set to ensure that the Transmit FIFO does not underflow before more data is written to the FIFO. When the entire frame is in the FIFO, or the FIFO becomes full before the threshold is reached, transmission of preamble will commence regardless of the value in XMTSP. The default value of XMTSP is 64 bytes after reset. The point at which TDTREQ is asserted in relation to the number of empty bytes present in the Transmit FIFO is controlled by the XMTFW bits in the FIFO Configuration Control register. TDTREQ will be asserted when one of the following conditions is true: s The number of bytes free in the Transmit FIFO relative to the current Saved Read Pointer value is greater than or equal to the threshold set by the XMTFW (16, 32 or 64 bytes). The Saved Read Pointer is the first byte of the current transmit frame, either in progress or awaiting channel availability. s The number of bytes free in the Transmit FIFO relative to the current Read Pointer value is greater than or equal to the threshold set by the XMTFW (16, 32 or 64 bytes). The Read Pointer becomes available only after a minimum of 64 byte frame length has been transmitted on the network (eight bytes of preamble plus 56 bytes of data), and points to the current byte of the frame being transmitted.
Transmit FIFO Write
The Transmit FIFO is accessed by performing a host generated write sequence on the MACE device. See the Slave Access Operation-Write Access section and the AC Waveforms section, Host System Interface, figures: Two-Cycle Transmit FIFO/Register Write Timing and Three-Cycle Transmit FIFO/Register Write Timing for details of the write access timing. There are two fundamentally different access methods to write data into the FIFO. Using the Register Address mode, the FIFO can be addressed using the ADD0-4 lines, (address 00001b), initiating the cycle with the CS and R/W (low) signals. The FIFO Direct mode allows write access to the Transmit FIFO without use of the address lines, and using only the FDS and R/W lines. If the MACE device detects both signals active, it will not execute a write cycle. The write cycle timing for the Register Address or Direct FIFO modes are identical. FDS and CS should be mutually exclusive. The data stream to the Transmit FIFO is written using multiple byte and/or word writes. CS or FDS does not have to be returned inactive to commence execution of the next write cycle. If CS/FDS is detected low at the falling edge of S0, a write cycle will commence. Note that EOF must be asserted by the host/controller during the last byte/word transfer.
Transmit Function Programming
The Transmit Frame Control register allows programming of dynamic transmit attributes. Automatic transmit features such as retry on collision, FCS generation/ transmission and pad field insertion can all be programmed, to provide flexibility in the (re-)transmission of messages. The disable retry on collision (DRTRY bit) and automatic pad field insertion (APAD XMT bit) features should not be changed while data remains in the Transmit FIFO. Writing to either the DRTRY or APAD XMT bits in this case may have unpredictable results. These bits are not internally latched or protected. When writing to the Transmit Frame Control register the DRTRY and APAD XMT bits should be programmed consistently. Once the Transmit FIFO is empty, DRTRY and APAD XMT can be reprogrammed. This can be achieved with no risk of transmit data loss or corruption by clearing ENXMT after the packet data for the current frame has been completely loaded. The transmission will complete normally and the activation of the INTR pin can be used to determine if the transmit frame has completed (XMTINT will be set in the Interrupt Register). Once the Transmit Frame Status has been read, APAD XMT and/or DRTRY can be changed 48
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AMD Depending on the bus latency of the system, XMTFW can be set to ensure that the Transmit FIFO does not underflow before more data is written into the FIFO. When the entire frame is in the FIFO, TDTREQ will remain asserted if sufficient bytes remain empty. The default value of XMTFW is 64 bytes after hardware or software reset. Note that if the XMTFW is set below the 64 byte limit, the transmit latency for the host to service the MACE device is effectively increased, since TDTREQ will occur earlier in the transmit sequence and more bytes will be present in the Transmit FIFO when the TDTREQ is de-asserted. The transmit operation of the MACE device can be halted at any time by clearing the ENXMT bit (bit 1) in the MAC Configuration Control register. Note that any complete transmit frame that is in the Transmit FIFO and is currently in progress will complete, prior to the transmit function halting. Transmit frames in the FIFO which have not commenced will not be started. Transmit frames which have commenced but which have not been fully transferred into the Transmit FIFO will be aborted, in one of two ways. If less than 544 bits (68 bytes) have been transmitted onto the network, the transmission will be terminated immediately, generating a runt packet which can be deleted at the receiving station. If greater than 544 bits have been transmitted, the messages will have the current CRC inverted and appended at the next byte boundary, to guarantee an error is detected at the receiving station. This feature ensures that packets will not be generated with potential undetected data corruption. An explanation of the 544 bit
Preamble 1010....1010 56 Bits SFD 10101011 8 Bits Dest Addr 6 Bytes
derivation appears in the "Automatic Pad Generation" section.
Automatic Pad Generation
Transmit frames can be automatically padded to extend them to 64 data bytes (excluding preamble) permitting the minimum frame size of 64 bytes (512 bits) for 802.3/Ethernet to be guaranteed, with no software intervention from the host system. APAD XMT = 1 enables the automatic padding feature. The pad is placed between the LLC Data field and FCS field in the 802.3 frame. The FCS is always added if APAD XMT = 1, regardless of the state of DXMTFCS. The transmit frame will be padded by bytes with the value of 00h. The default value of APAD XMT will enable auto pad generation after hardware or software reset. It is the responsibility of upper layer software to correctly define the actual length field contained in the message to correspond to the total number of LLC Data bytes encapsulated in the packet (length field as defined in the IEEE 802.3 standard). The length value contained in the message is not used by the MACE device to compute the actual number of pad bytes to be inserted. The MACE chip will append pad bytes dependent on the actual number of bits transmitted onto the network. Once the last data byte of the frame has completed, prior to appending the FCS, the MACE device will check to ensure that 544 bits have been transmitted. If not, pad bytes are added to extend the frame size to this value, and the FCS is then added.
Srce Addr 6 Bytes Length LLC Data Pad FCS
2 Bytes
46--1500 Bytes
4 Bytes
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IEEE 802.3 Format Data Frame The 544 bit count is derived from the following: Minimum frame size (excluding preamble, including FCS) 64 bytes 512 bits Preamble/SFD size FCS size 8 bytes 4 bytes 64 bits 32bits At the point that FCS is to be appended, the transmitted frame should contain: Preamble + 64 + (Min Frame Size - FCS) bits (512 - 32) bits
To be classed as a minimum size frame at the receiver, the transmitted frame must contain: Preamble + (Min Frame Size + FCS) bits
A minimum length transmit frame from the MACE device will therefore be 576 bits, after the FCS is appended. The Ethernet specification makes no use of the LLC pad field, and assumes that minimum length messages will be at least 64 bytes in length.
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Preamble 1010....1010 62 Bits SYNCH 11 2 Bits Dest Addr 6 Bytes Srce Addr 6 Bytes Type Data FCS
2 Bytes
46--1500 Bytes
4 Bytes
16235C-8
Ethernet Format Data Frame
Transmit FCS Generation
Automatic generation and transmission of FCS for a transmit frame depends on the value of DXMTFCS (Disable Transmit FCS) when the EOF is asserted indicating the last byte/word of data for the transmit frame is being written to the FIFO. The action of writing the last data byte/word of the transmit frame, latches the current contents of the Transmit Frame Control register, and therefore determines the programming of DXMTFCS for the transmit frame. When DXMTFCS = 0 the transmitter will generate and append the FCS to the transmitted frame. If the automatic padding feature is invoked (APAD XMT in Transmit Frame Control), the FCS will be appended regardless of the state of DXMTFCS. Note that the calculated FCS is transmitted most significant bit first. The default value of DXMTFCS is 0 after hardware or software reset.
Normal events which may occur and which are handled autonomously by the MACE device are: (a) Collisions within the slot time with automatic retry (b) Deletion of packets due to excessive transmission attempts. (a) The MACE device will ensure that collisions which occur within 512 bit times from the start of transmission (including preamble) will be automatically retried with no host intervention. The Transmit FIFO ensures this by guaranteeing that data contained within the Transmit FIFO will not be overwritten until at least 64 bytes (512 bits) of data have been successfully transmitted onto the network. This criteria will be met, regardless of whether the transmit frame was the first (or only) frame in the Transmit FIFO, or if the transmit frame was queued pending completion of the preceding frame. (b) If 16 total attempts (initial attempt plus 15 retries) have been made to transmit the frame, the MACE device will abandon the transmit process for the particular frame, de-assert the TDTREQ pin, report a Retry Error (RTRY) in the Transmit Frame Status, and set the XMTINT bit in the Interrupt Register, causing activation of the external INTR pin providing the interrupt is unmasked. Once the XMTINT condition has been externally recognized, the Transmit Frame Counter (XMTFC) can be read to determine whether the tail end of the frame that suffers the RTRY error is still in the host memory (i.e., when XMTFC = 0). This XMTFC read should be requested before the Transmit Frame Status read since reading the XMTFS would cause the XMTFC to decrement. If the tail end of the frame is indeed still in the host memory, the host is responsible for ensuring that the tail end of the frame does not get written into the FIFO and does not get transmitted as a whole frame. It is recommended that the host clear the tail end of the frame from the host memory before requesting the XMTFS read so that after the XMTFS read, when MACE device re-asserts TDTREQ, the tail end of the frame does not get written into the FIFO. The Transmit Frame Status read will indicate that the RTRY error occurred. The read operation on the Transmit Frame Status will update the FIFO read and write pointers. If no End-of-Frame write (EOF pin assertion) had occurred during the FIFO write sequence, the entire transmit path will be reset (which will update the Transmit FIFO watermark with the
Transmit Status Information
Although multiple transmit frames can be queued in the Transmit FIFO, the MACE device will not permit loss of Transmit Frame Status information. The Transmit Frame Status and Transmit Retry Count can only be buffered internally for a maximum of two frames. The MACE device will therefore not commence a third transmit frame, until the status from the first frame is read. Once the Transmit Retry Count and Transmit Frame Status for the first transmit packet is read, the MACE device will autonomously begin the next transmit frame, provided that a transmit frame is pending, the XMTSP threshold has been exceeded (or the XMTFIFO is full), the network medium is free, and the IPG time has elapsed. Indication of valid Transmit Frame Status can be obtained by servicing the hardware interrupt and testing the XMTINT bit in the Interrupt Register, or by polling the XMTSV bit in the Poll register if a continuous polling mechanism is required. If the Transmit Retry Count data is required (for loading, diagnostic, or management information), XMTRC must be read prior to XMTFS. Reading the XMTFS register when the XMTSV bit is set will clear both the XMTRC and XMTFS values.
Transmit Exception Conditions
Exception conditions for frame transmission fall into two distinct categories; those which are the result of normal network operation and those which occur due to abnormal network and/or host related events. 50
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AMD current XMTFW value in the FIFO Configuration Control register). If a whole frame does reside in the FIFO, the read pointer will be moved to the start of the next frame or free location in the FIFO, and the write pointer will be unaffected. TDTREQ will not be re-asserted until the Transmit Frame Status has been read. After a RTRY error, all further packet transmission will be suspended until the Transmit Frame Status is read, regardless of whether additional packet data exists in the FIFO to be transmitted. Receive FIFO read operations are not impaired. Packets experiencing 16 unsuccessful attempt to transmit will not be re-tried. Recovery from this condition must be performed by upper layer software. Abnormal network conditions include: (a) Loss of carrier. (b) Late collision. (c) SQE Test Error. These should not occur on a correctly configured 802.3 network, but will be reported if the network has been incorrectly configured or a fault condition exists. (a) A loss of carrier condition will be reported if the MACE device cannot observe receive activity while it is transmitting. After the MACE device initiates a transmission it will expect to see data looped-back on the receive input path. This will internally generate a carrier sense, indicating that the integrity of the data path to and from the external MAU is intact, and that the MAU is operating correctly. When the AUI port is selected, if carrier sense does not become active in response to the data transmission, or becomes inactive before the end of transmission, the loss of carrier (LCAR) error bit will be set in the Transmit Frame Status (bit 7) after the packet has been transmitted. The packet will not be re-tried on the basis of an LCAR error. When the 10BASE-T port is selected, LCAR will be reported for every packet transmitted during the Link fail condition. When the GPSI port is selected, LCAR will be reported if the RXCRS input pin fails to become active during a transmission, or once active, goes inactive before the end of transmission. When the DAI port is selected, LCAR errors will not occur, since the MACE device will internally loop back the transmit data path to the receiver. The loop back feature must not be performed by the external transceiver when the DAI port is used. During internal loopback, LCAR will not be set, since the MACE device has direct control of the transmit and receive path integrity. When in external loopback, LCAR will operate normally according to the specific port which has been selected. (b) A late collision will be reported if a collision condition exists or commences 64 byte times (512 bit times) after the transmit process was initiated (first bit of preamble commenced). The MACE device will abandon the transmit process for the particular frame, complete transmission of the jam sequence (32-bit all zeroes pattern), de-assert the TDTREQ pin, report the Late Collision (LCOL) and Transmit Status Valid (XMTSV) in the Transmit Frame Status, and set the XMTINT bit in the Interrupt Register, causing activation of the external INTR pin providing the interrupt is unmasked. Once the XMTINT condition has been externally recognized, the Transmit Frame Counter (XMTFC) can be read to determine whether the tail end of the frame that suffers the LCOL error is still in the host memory (i.e., when XMTFC = 0). This XMTFC read should be requested before the Transmit Frame Status read since reading the XMTFS would cause the XMTFC to decrement. If the tail end of the frame is indeed still in the host memory, the host is responsible for ensuring that the tail end of the frame does not get written into the FIFO and does not get transmitted as a whole frame. It is recommended that the host clear the tail end of the frame from the host memory before requesting the XMTFS read so that after the XMTFS read,when the MACE device reasserts TDTREQ, the tail end of the frame does not get written into the FIFO. The Transmit Frame Status read will indicate that the LCOL error occurred. The read operation on the Transmit Frame Status will update the FIFO read and write pointers. If no End-of-Frame write (EOF pin assertion) had occurred during the FIFO write sequence, the entire transmit path will be reset (which will update the Transmit FIFO watermark with the current XMTFW value in the FIFO Configuration Control register). If a whole frame resides in the FIFO, the read pointer will be moved to the start of the next frame or free location in the FIFO, and the write pointer will be unaffected. TDTREQ will not be re-asserted until the Transmit Frame Status has been read. After an LCOL error, all further packet transmission will be suspended until the Transmit Frame Status is read, regardless of whether additional packet data exists in the FIFO to be transmitted. Receive FIFO operations are unaffected. Packets experiencing a late collision will not be re-tried. Recovery from this condition must be performed by upper layer software. (c) During the inter packet gap time following the completion of a transmitted message, the AUI CI pair is asserted by some transceivers as a self-test. When the AUI port has been selected, the integral Manchester Encoder/Decoder will expect the SQE Test Message
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AMD (nominal 10 MHz sequence) to be returned via the CI pair, within a 40 network bit time period after DI goes inactive. If the CI input is not asserted within the 40 network bit time period following the completion of transmission, then the MACE device will set the CERR bit (bit 5) in the Interrupt Register. The INTR pin will be activated if the corresponding mask bit CERRM = 0. When the GPSI port is selected, the MACE device will expect the CLSN input pin to be asserted 40 bit times after the transmission has completed (after TXEN output pin has gone inactive). When the DAI port has been selected, the CERR bit will not be reported. A transceiver connected via the DAI port is not expected to support the SQE Test Message feature. Host related transmit exception conditions include: (a) Overflow caused by excessive writes to the Transmit FIFO (DTV will not be issued if the Transmit FIFO is full). (b) Underflow caused by lack of host writes to the Transmit FIFO. (c) Not reading current Transmit Frame Status. (a) The host may continue to write to the Transmit FIFO after the TDTREQ has been de-asserted, and can safely do so on the basis of knowledge of the number of free bytes remaining (set by XMTFW in the FIFO Configuration Control register). If however the host system continues to write data to the point that no additional FIFO space exists, the MACE device will not return the DTV signal and hence will effectively not acknowledge acceptance of the data. It is the host's responsibility to ensure that the data is re-presented at a future time when space exists in the Transmit FIFO, and to track the actual data written into the FIFO. (b) If the host fails to respond to the TDTREQ from the MACE device before the Transmit FIFO is emptied, a FIFO underrun will occur. The MACE device will in this case terminate the network transmission in an orderly sequence. If less than 512 bits have been transmitted onto the network the transmission will be terminated immediately, generating a runt packet. If greater than 512 bits have been transmitted, the message will have the current CRC inverted and appended at the next byte boundary, to guarantee an FCS error is detected at the receiving station. The MACE device will report this condition to the host by de-asserting the TDTREQ pin, setting the UFLO and XMTSV bits (in the Transmit Frame Status) and the XMTINT bit (in the Interrupt Register), and asserting the INTR pin providing the corresponding XMTINTM bit (in the Interrupt Mask Register) is cleared. Once the XMTINT condition has been externally recognized, the Transmit Frame Counter (XMTFC) can be read to determine whether the tail end of the frame that suffers the UFLO error is still in the host memory (i.e., 52 when XMTFC = 0). In the case of FIFO underrun, this will definitely be the case and the host is responsible for ensuring that the tail end of the frame does not get written into the FIFO and does not get transmitted as a whole frame. It is recommended that the host clear the tail end of the frame from the host memory before requesting the XMTFS read so that after the XMTFS read, when the MACE device re-asserts TDTREQ, the tail end of the frame does not get written into the FIFO. The Transmit Frame Status read will indicate that the UFLO error occurred. The read operation on the Transmit Frame Status will update the FIFO read and write pointers and the entire transmit path will be reset (which will update the Transmit FIFO watermark with the current XMTFW value in the FIFO Configuration Control register). TDTREQ will not be re-asserted until the Transmit Frame Status has been read. (c) The MACE device will internally store the Transmit Frame Status for up to two packets. If the host fails to read the Transmit Frame Status and both internal entries become occupied, the MACE device will not commence any subsequent transmit frames to prevent overwriting of the internally stored values. This will occur regardless of the number of bytes written to the Transmit FIFO.
RECEIVE OPERATION
The receive operation and features of the MACE device are controlled by programmable options. These options are programmed through the BIU, FIFO and MAC Configuration Control registers. Parameters controlled by the MAC Configuration Control register are generally programmed only once, during initialization, and are therefore static during the normal operation of the MACE device (see the Media Access Control section for a detailed description). The features controlled by the FIFO Configuration Control register and the Receive Frame Control register can be programmed without performing a reset on the part. The host is responsible for ensuring that no data is present in the Receive FIFO when re-programming the receive attributes.
Receive FIFO Read
The Receive FIFO is accessed by performing a host generated read sequence on the MACE device. See the Slave Access Operation-Read Access section and the AC Waveforms section, Host System Interface, figures: "2 Cycle Receive FIFO/Register Read Timing" and "3 Cycle Receive FIFO/Register Read Timing" for details of the read access timing. Note that EOF will be asserted by the MACE device during the last data byte/word transfer.
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Receive Function Programming
The Receive Frame Control register allows programming of the automatic pad field stripping feature and the configuration of the Match/Reject (M/R) pin. ASTRP RCV and M/R must be static when the receive function is enabled (ENRCV = 1). The receiver should be disabled before (re-) programming these options. The EADI port can be used to permit reception of frames to commence whilst external address decoding takes place. The M/R bit defines the function of the EAM/R pin, and hence whether frames will be accepted or rejected by the external address comparison logic. The programming of additional receive attributes are distributed between the FIFO and MAC Configuration Control registers, and the User Test Register. All receive frames can be accepted by setting the PROM bit (bit 7) in the MAC Configuration Control register. When PROM is set, the MACE device will attempt to receive all messages, subject to minimum frame enforcement. Setting PROM will override the use of the EADI port to force the rejection of unwanted messages. See the sections External Address Detection Interface for more details. The point at which RDTREQ is asserted in relation to the number of bytes of a frame that are present in the Receive FIFO (RCVFIFO) is controlled by the RCVFW bits in the FIFO Configuration Control register, or the LLRCV bit in the Receive Frame Control register. RDTREQ will be asserted when one of the following conditions is true: (i) There are at least 64 bytes in the RCVFIFO. (ii) The received packet has passed the 64 byte minimum criteria, and the number of bytes in the RCVFIFO is greater than or equal to the threshold set by the RCVFW (16 or 32 bytes). (iii) A receive packet has completed, and part or all of it is present in the RCVFIFO. (iv) The LLRCV bit has been set and greater than 12-bytes of at least 8 bytes have been received. Note that if the RCVFW is set below the 64-byte limit, the MACE device will still require 64-bytes of data to be received before the initial assertion of RDTREQ. Subsequently, RDTREQ will be asserted at any time the RCVFW threshold is exceeded. The only times that the RDTREQ will be asserted when there are not at least an initial 64-bytes of data in the RCVFIFO are: (i) When the ASTRP RCV bit has been set in the Receive Frame Control register, and the pad is automatically stripped from a minimum length packet.
(ii) When the RPA bit has been set in the User Test Register, and a runt packet of at least 8 bytes has been received. (iii) When the LLRCV bit has been set in the Receive Frame Control register, and at least 12-bytes (after SFD) has been received. No preamble/SFD bytes are loaded into the Receive FIFO. All references to bytes past through the receive FIFO are received after the preamble/SFD sequence. Depending on the bus latency of the system, RCVFW can be set to ensure that the RCVFIFO does not overflow before more data is read. When the entire frame is in the RCVFIFO, RDTREQ will be asserted regardless of the value in RCVFW. The default value of RCVFW is 64-bytes after hardware or software reset. The receive operation of the MACE device can be halted at any time by clearing the ENRCV bit in the MAC Configuration Control register. Note that any receive frame currently in progress will be accepted normally, and the MACE device will disable the receive process once the message has completed. The Missed Packet Count (MPC) will be incremented for subsequent packets that would have normally been passed to the host, and are now ignored due to the disabled state of the receiver. Note that clearing the ENRCV bit disables the assertion of RDTREQ. If ENRCV is cleared during receive activity and remains cleared for a long time and if the tail end of the receive frame currently in progress is longer than the amount of space available in the Receive FIFO, Receive FIFO overflow will occur. However, even with RDTREQ deasserted, if there is valid data in the Receive FIFO to be read, successful slave reads to the Receive FIFO can be executed (indicated by valid DTV). It is the host's responsibility to avoid the overflow situation.
Automatic Pad Stripping
During reception of a frame the pad field can be stripped automatically. ASTRP RCV = 1 enables the automatic pad stripping feature. The pad field will be stripped before the frame is passed to the FIFO, thus preserving FIFO space for additional frames. The FCS field will also be stripped, since it is computed at the transmitting station based on the data and pad field characters, and will be invalid for a receive frame that has the pad characters stripped. The number of bytes to be stripped is calculated from the embedded length field (as defined in the IEEE 802.3 definition) contained in the packet. The length indicates the actual number of LLC data bytes contained in the message. Any received frame which contains a length field less than 46 bytes will have the pad field stripped.
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AMD Receive frames which have a length field of 46 bytes or greater will be passed to the host unmodified. Since any valid Ethernet Type field value will always be greater than a normal 802.3 Length field, the MACE device will not attempt to strip valid Ethernet frames. Note that for some network protocols, the value passed in the Ethernet Type and/or 802.3 Length field is not compliant with either standard and may cause problems. The diagram below shows the byte/bit ordering of the received length field for an 802.3 compatible frame format.
46-1500 Bytes
56 Bits Preamble 1010....1010
8 Bits SYNCH 10101011
6 Bytes Dest. ADDR.
6 Bytes SRCE. ADDR.
2 Bytes Length
4 Bytes Pad FCS
LLC DATA 1-1500 Bytes
45-0 Bytes
Start of Packet at Time= 0 Bit 0 Bit Bit 70 Bit 7
Increasing Time
Most Significant Byte
Least Significant Byte
16235C-9 16907A-013A
802.3 Packet and Length Field Transmission Order
Receive FCS Checking
Reception and checking of the received FCS is performed automatically by the MACE device. Note that if the Automatic Pad Stripping feature is enabled, the received FCS will be verified against the value computed for the incoming bit stream including pad characters, but it will not be passed through the Receive FIFO to the host. If an FCS error is detected, this will be reported by the FCS bit (bit 4) in the Receive Frame Status.
used to read the Receive Frame Status through the Receive FIFO. In either case, the 4-byte total must be read before additional receive data can be read from the Receive FIFO. However, the RDTREQ indication will continue to reflect the state of the Receive FIFO as normal, regardless of whether the Receive Frame Status has been read. DTV will not be returned when a read operation is performed on the Receive Frame Status location and no valid status is present or ready. Note that the Receive Frame Status can be read using either the Register Address or FIFO Direct modes. For additional details, see the section Receive FIFO Read.
Receive Status Information
The EOF indication signals that the last byte/word of data has been passed from the FIFO for the specific frame. This will be accompanied by a RCVINT indication in the the Interrupt Register signaling that the Receive Frame Status has been updated, and must be read. The Receive Frame Status is a single location which must be read four times to allow the four bytes of status information associated with each frame to be read. Further data read operations from the Receive FIFO using the Register Address mode, will be ignored by the MACE device (indicated by the MACE chip not returning DTV) until all four bytes of the Receive Frame Status have been read. Alternatively, the FIFO Direct access mode may be 54
Receive Exception Conditions
Exception conditions for frame reception fall into two distinct categories; those which are the result of normal network operation, and those which occur due to abnormal network and/or host related events. Normal events which may occur and which are handled autonomously by the MACE device are basically collisions within the slot time and automatic runt packet deletion. The MACE device will ensure that any receive packet which experiences a collision within 512 bit times
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AMD from the start of reception (excluding preamble) will be automatically deleted from the Receive FIFO with no host intervention (the state of the RPA bit in the User Test Register; or the RCVFW bits in the FIFO Configuration Control register have no effect on this). This criteria will be met, regardless of whether the receive frame was the first (or only) frame in the Receive FIFO, or if the receive frame was queued behind a previously received message. Abnormal network conditions include: s s s s FCS errors Framing errors Dribbling bits Late collision the Receive Frame Status through the Receive FIFO, but the host must be aware that the subsequent four cycles will yield the receive status bytes, and not data from the same or a new packet. Only the OFLO bit will be valid in the Receive Frame Status, other error/status and the RCVCNT fields are invalid. While the Receive FIFO is in the overflow condition, it is deaf to additional receive data on the network. However, the MACE device internal address detect logic continues to operate and counts the number of packets that would have been passed to the host under normal (non overflow) conditions. The Missed Packet Count (MPC) is an 8-bit count (in register 24) that maintains the number of packets which pass the address match criteria, and complete without collision. The MPC counter will wrap around when the maximum count of 255 is reached, setting the MPCO (Missed Packet Count Overflow) bit in the Interrupt Register, and asserting the INTR pin providing that MPCOM (Missed Packet Count Overflow Mask) in the Interrupt Mask Register is clear. MPCO will be cleared (the interrupt will be unmasked) after hardware or software reset. However, until the first time that the receiver is enabled, MPC will not increment, hence no interrupt will occur due to missed packets after a reset. (c) Failure to read packet data from the Receive FIFO will eventually cause an overflow condition. The FIFO will maintain any previously completed packet(s), which can be read by the host at its convenience. However, packet data on the network will no longer be received, regardless of destination address, until the overflow is cleared by reading the remaining Receive FIFO data and Receive Status. The MACE device will increment the Missed Packet Count (MPC) register to indicate that a packet which would have been normally passed to the host, was dropped due to the error condition.
These should not occur on a correctly configured 802.3 network, but may be reported if the network has been incorrectly configured or a fault condition exists. Host related receive exception conditions include: (a) Underflow caused by excessive reads from the Receive FIFO (DTV will not be issued if the Receive FIFO is empty) (b) Overflow caused by lack of host reads from the Receive FIFO (c) Missed packets due to lack of host reads from the Receive FIFO and/or the Receive Frame Status (a) Successive read operations from the Receive FIFO after the final byte of data/status has been read, will cause the DTV pin to remain de-asserted during the read operation, indicating that no valid data is present. There will be no adverse effect on the Receive FIFO. (b) Data present in the Receive FIFO from packets which completed before the overflow condition occurred, can be read out by accessing the Receive FIFO normally. Once this data (and the associated Receive Frame Status) has been read, the EOF indication will be asserted by the MACE device during the first read operation takes place from the Receive FIFO, for the packet which suffered the overflow. If there were no other packets in the FIFO when the overflow occurred, the EOF will be asserted on the first read from the FIFO. In either case, the EOF indication will be accompanied by assertion of the INTR pin, providing that the RCVINTM bit in the Interrupt Mask Register is not set. If the Register Address mode is being used, the host is required to access the Receive Frame Status location using four separate read cycles. Further access to the Receive FIFO will be ignored by the MACE device until all four bytes of the Receive Frame Status have been read. DTV will not be returned if a Receive FIFO read is attempted. If the FIFO Direct mode is being used, the host can read
LOOPBACK OPERATION
During loopback, the FCS logic can be allocated to the receiver by setting RCVFCSE = 1 in User Test Register. This permits both the transmit and receive FCS operations to be verified during the loopback process. The state of RCVFCSE is only valid during loopback operation. If RCVFCSE = 0, the MACE device will calculate and append the FCS to the transmitted message. The receive message passed to the host will therefore contain an additional four bytes of FCS. The Receive Frame Status will indicate the result of the loopback operation and the RCVCNT. If RCVFCSE = 1, the last four bytes of the transmit message must contain the FCS computed for the transmit data preceding it. The MACE device will transmit the
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AMD data without addition of an FCS field, and the FCS will be calculated and verified at the receiver. The loopback facilities of the MACE device allow full operation to be verified without disturbance to the network. Loopback operation is also affected by the state of the Loopback Control bits (LOOP [0-1]) in the User Test Register. This affects whether the internal MENDEC is considered part of the internal or external loopback path. When in the loopback mode(s), the multicast address detection feature of the MACE device, programmed by the contents of the Logical Address Filter (LADR [63-0]) can only be tested when RCVFCSE = 1, allocating the CRC generator to the receiver. All other features operate identically in loopback as in normal operation, such as automatic transmit padding and receive pad stripping.
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USER ACCESSIBLE REGISTERS
The following registers are provided for operation of the MACE device. All registers are 8-bits wide unless otherwise stated. Note that all reserved register bits should be written as zero. Receive FIFO (RCVFIFO) RCVFIFO [15-0] This register provides a 16-bit data path from the Receive FIFO. Reading this register will read one word/ byte from the Receive FIFO. The RCVFIFO should only be read when Receive Data Transfer Request (RDTREQ) is asserted. If the RCVFIFO location is read before 64-bytes are available in the RCVFIFO (or 12-bytes in the case that LLRCV is set in the Receive Frame Control register), DTV will not be returned. Once the 64-byte threshold has been achieved and RDTREQ is asserted, the de-assertion of RDTREQ does not prevent additional data from being read from the RCVFIFO, but indicates the number of additional bytes which are present, before the RCVFIFO is emptied, and subsequent reads will not return DTV (see the FIFO Sub-System section for additional details). Write operations to this register will be ignored and DTV will not be returned. Byte transfers from the RCVFIFO are supported, and will be fully aligned to the target memory architecture, defined by the BSWP bit in the BIU Configuration Control register. The Byte Enable inputs (BE1-0) will define which half of the data bus should be used for the transfer. The external host/controller will be informed that the last byte/word of data in a receive frame is being read from the RCVFIFO, when the MACE device asserts the EOF signal. Transmit FIFO (XMTFIFO) XMTFIFO [15-0] This register provides a 16-bit data path to the Transmit FIFO. Byte/word data written to this register will be placed in the Transmit FIFO. The XMTFIFO can be written at any time the Transmit Data Transfer Request (TDTREQ) is asserted. The de-assertion of TDTREQ does not prevent data being written to the XMTFIFO, but indicates the number of additional write cycles which can take place, before the XMTFIFO is filled, and subsequent writes will not return DTV (see the FIFO Sub-System section for additional details). Read operations to this register will be ignored and DTV will not be returned. Byte transfers to the XMTFIFO are supported, and accept data from the source memory architecture to ensure the correct byte ordering for transmission, defined by the BSWP bit in the MAC Configuration Control register. The Byte Enable inputs (BE1-0) will define which half of the data bus should be used for the transfer. The (REG ADDR 1) (REG ADDR 0)
use of byte transfers have implications on the latency time provided by the XMTFIFO (see the FIFO SubSystem section for additional details). The external host/ controller must indicate the last byte/word of data in a transmit frame is being written to the XMTFIFO, by asserting the EOF signal. Transmit Frame Control (XMTFC) (REG ADDR 2)
The Transmit Frame Control register is latched internally on the last write to the Transmit FIFO for each individual packet, when EOF is asserted. This permits automatic transmit padding and FCS generation on a packet-by-packet basis.
DRTRY RES RES RES DXMTFCS RES RES APAD XMT
Bit Bit 7
Name DRTRY
Description
Disable Retry. When DRTRY is set, the MACE device will provide a single transmission attempt for the packet, all further retries will be suspended. In the case of a collision during the attempt, a Retry Error (RTRY) will be reported in the Transmit Status. With DRTRY cleared, the MACE device will attempt up to 15 retries (16 attempts total) before indicating a Retry Error. DRTRY is cleared by activation of the RESET pin or SWRST bit. DRTRY is sampled during the transmit process when a collision occurs. DRTRY should not be changed whilst data remains in the Transmit FIFO since this may cause an unpredictable retry response to a collision. Once the Transmit FIFO is empty, DRTRY can be reprogrammed. Bit 6-4 RES Reserved. Read as zeroes. Always write as zeroes. Bit 3 DXMTFCS Disable Transmit FCS. When DXMTFCS = 0 the transmitter will generate and append an FCS to the transmitted frame. When DXMTFCS = 1, no FCS will be appended to the transmitted frame, providing that APAD XMT is also clear. If APAD XMT is set, the calculated FCS will be appended to the transmitted message regardless of the state of DXMTFCS. The value of DXMTFCS for each frame is programmed when EOF is asserted to transfer the last byte/word for the transmit packet to the FIFO. DXMTFCS is cleared by
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AMD activation of the RESET pin or SWRST bit. DXMTFCS is sampled only when EOF is asserted during a Transmit FIFO write. Bit Name Description Bit 5 LCOL Late Collision. Indicates that a collision occurred after the slot time of the channel elapsed. If LCOL is set, TDTREQ will be deasserted, and will not be re-asserted until the XMTFS has been read. The MACE device does not retry after a late collision. More. Indicates that more than one retry was needed to transmit the frame. ONE, MORE and RTRY are mutually exclusive. One. Indicates that exactly one retry was needed to transmit the frame. ONE, MORE and RTRY are mutually exclusive. Defer. Indicates that MACE device had to defer transmission of the frame. This condition results if the channel is busy when the MACE device is ready to transmit. Loss of Carrier. Indicates that the carrier became false during a transmission. The MACE device does not retry upon Loss of Carrier. LCAR will not be set when the DAI port is selected, when the 10BASE-T port is selected and in the link pass state, or during any internal loopback mode. When the 10BASE-T port is selected and in the link fail state, LCAR will will be reported for any transmission attempt. Retry Error. Indicates that all attempts to transmit the frame were unsuccessful, and that further attempts have been aborted. If Disable Retry (DRTRY in the Transmit Frame Control register) is cleared, RTRY will be set when a total of 16 unsuccessful attempts were made to transmit the frame. If DRTRY is set, RTRY indicates that the first and only attempt to transmit the frame was unsuccessful. ONE, MORE and RTRY are mutually exclusive. If RTRY is set, TDTREQ will be deasserted, and will not be reasserted until the XMTFS has been read.
Bit 2-1 RES Bit 0
Reserved. Read as zeroes. Always write as zeroes. APAD XMT Auto Pad Transmit. APAD XMT enables the automatic padding feature. Transmit frames will be padded to extend them to 64 bytes including FCS. The FCS is calculated for the entire frame including pad, and appended after the pad field. APAD XMT will override the programming of the DXMTFCS bit. APAD XMT is set by activation of the RESET pin or SWRST bit. APAD XMT is sampled only when EOF is asserted during a Transmit FIFO write. (REG ADDR 3)
Bit 4
MORE
Bit 3
ONE
Bit 2
DEFER
Transmit Frame Status (XMTFS)
Bit 1
LCAR
The Transmit Frame Status is valid when the XMTSV bit is set. The register is read only, and is cleared when XMTSV is set and a read operation is performed. The XMTINT bit in the Interrupt Register will be set when any bit is set in this register. Note that if XMTSV is not set, the values in this register can change at any time, including during a read operation. This register should be read after the Transmit Retry Count (XMTRC). See the description of the Transmit Retry Count (XMTRC) for additional details.
XMTSV UFLO LCOL MORE ONE DEFER LCAR RTRY
Bit 0
RTRY
Bit Bit 7
Name XMTSV
Description Transmit Status Valid. Transmit Status Valid indicates that this status is valid for the last frame transmitted. The value of XMTSV will not change during a read operation. Underflow. Indicates that the Transmit FIFO emptied before the end of frame was reached. The transmitted frame is truncated at that point. If UFLO is set, TDTREQ will be de-asserted, and will not be re-asserted until the XMTFS has been read.
Bit 6
UFLO
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AMD Transmit Retry Count (XMTRC) (REG ADDR 4) low threshold (12-bytes after SFD plus synchronization) has been exceeded, causing RDTREQ to be asserted. RDTREQ will remain asserted as long as one read cycle can be performed on the RCVFIFO (identical to the burst mode). Indication of a valid read cycle from the RCVFIFO will return DTV asserted. Reading the RCVFIFO before data is available, or while waiting for additional data once a packet is in progress will not cause the RCVFIFO to underflow, and will be indicated by DTV being invalid. The MACE device will no longer be able to reject runts in this mode, this responsibility is transferred to the host system. In the case of a collided packet (normal slot time collision or late collision), the MACE device will abort the reception, and return the RCVFS. Note that all collisions in this mode will appear as late collisions and be reported by the CLSN bit in the Receive Status (RCVSTS) byte. If the host does not keep up with the incoming receive data, normal RCVFIFO overflow recovery is provided. Match/Reject. The Match/Reject option sets the criteria for the External Address Detection Interface. If set, the EAM/R pin is configured as External Address Match, and is used to signal the acceptance of a receive frame to the MACE device. If cleared, the pin functions as External Address Reject and is used to flush unwanted packets from the Receive FIFO prior to the first assertion of RDTREQ. M/R is cleared by activation of the RESET pin or SWRST bit. When the EADI feature is disabled, the EAM/R pin must be tied active (low) and all normal receive address recognition configurations are supported (physical, logical and promiscuous). See the section "External Address Detection Interface" for additional details. Reserved. Read as zero. Always write as zero.
The Transmit Retry Count should be read only in response to a hardware interrupt request (INTR asserted) when XMTINT is set in the Interrupt Register, or after XMTSV is set in the Poll Register.The register should be read before the Transmit Frame Status register. Reading the Transmit Frame Status with XMTSV set will cause the XMTRC value to be reset. This register is read only.
EXDEF RES RES RES XMTRC[3-0]
Bit Bit 3-0
Name EXDEF
Description Excessive Defer. The EXDEF bit will be set if a transmit frame waited for an excessive period for transmission. An excessive defer time is defined in accordance with the following (from page 34, section 5.2.4.1 of IEEE Std 802.3h-1990 Layer Management):maxDeferTime = {2 x (max frame size x 8)} bits where maxFrameSize = 1518 bytes (from page 68, section 4.4.2.1 of ANSI/IEEE Std 802.3-1990). So, the maxDeferTime = 24288 bits = 214+ 212 + 211+ 210 + 29 +27 +26 +25 Reserved. Read as zeroes. Always write as zeroes. Transmit Retry Count. Contains the count of the number of retry attempts made by the MACE device to transmit the current transmit packet. The value of the counter will be zero if the first transmission attempt was successful, and a maximum of 15 if all retry attempts were utilized. RTRY will be set in Transmit Frame Status if all 16 attempts were unsuccessful. (REG ADDR 5)
RES ASTRPRCV
Bit 6-4 RES Bit 3-0 XMTRC [3-0]
Bit 2
M/R
Receive Frame Control (RCVFC)
RES RES RES RES LLRCV M/R
Bit
Name
Description Reserved. Read as zeroes. Always write as zeroes. Low Latency Receive. A programmable option to allow access to the Receive FIFO before the 64-byte threshold has been reached. When set, data can be read from the RCVFIFO once a
Bit 7-4 RES Bit 3 LLRCV
Bit 1
RES
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AMD Bit 0 ASTRP RCV Auto Strip Receive. ASTRP RCV enables the automatic pad stripping feature. The pad and FCS fields will be stripped from receive frames and not placed in the FIFO. ASTRP RCV is set by activation of the RESET pin or the SWRST bit. (REG ADDR 6) RFS1--Receive Status (RCVSTS) OFLO CLSN FRAM Bit Bit 7 Name OFLO FCS RCVCNT [10:8]
Description Overflow flag. Indicates that the Receive FIFO over flowed due to the inability of the host/controller to read data fast enough to keep pace with the receive serial bit stream and the latency provided by the Receive FIFO itself. OFLO is indicated on the receive frame that caused the overflow condition; complete frames in the Receive FIFO are not affected. While the Receive FIFO is in the overflow condition, it ignores additional receive data on the network. The internal address detect logic will continue to operate and the Missed Packet Count (MPC in register 24) will be incremented for each packet which passes the address match criteria, and complete without collision. Collision Flag. Indicates that the receive operation suffered a collision during reception of the frame. If CLSN is set, it indicates that the receive frame suffered a late collision, since a frame experiencing collision within the slot time will be automatically deleted from the RCVFIFO (providing LLRCV in the Receive Frame Control register is cleared). Note that if the LLRCV bit is enabled, the late collision threshold is effectively moved from the normal 64-byte (512-bit) level to the 12-byte (96-bit) level. Runt packets suffering a collision will be flushed from the RCVFIFO regardless of the state of the RPA bit (User Test Register). CLSN will not be set if OFLO is set. Framing Error flag. Indicates that the received frame contained a non-integer multiple of bytes and an FCS error. If there was no FCS error then FRAM will not be set. FRAM is not valid during internal loopback. FRAM will not be set if OFLO is set. FCS Error flag. Indicates that there is an FCS error in the frame. The receive FCS is computed and checked normally when ASTRP RCV = 1, but is not
Receive Frame Status (RCVFS) RCVFS [31-00]
The Receive Frame Status is a single byte location which must be read by four read cycles to obtain the four bytes (32-bits) of status associated with each receive frame. Receive Frame Status can be read using either the Register Direct or FIFO Direct access modes. In Register Direct mode, access to the Receive FIFO will be denied until all four status bytes for the completed frame have been read from the Receive Frame Status location. In FIFO Direct mode, the Receive Frame Status is read through the Receive FIFO location, by continuing to execute four read cycles after the completion of packet data (and assertion of EOF). The Receive Frame Status can be read using either mode, or a combination of both modes, however each status byte will be presented only once regardless of access method. Other register reads and/or writes can be interleaved at any time, during the Receive Frame Status sequence. The Receive Frame Status consists of the following four bytes of information: RFS0 RFS1 RFS2 RFS3 Receive Message Byte Count (RCVCNT) [7-0] Receive Status, (RCVSTS) [11-8] Runt Packet Count (RNTPC) [7-0] Receive Collision Count (RCVCC) [7-0]
Bit 6
CLSN
RFS0--Receive Message Byte Count (RCVCNT) RCVCNT [7:0] Bit Name Bit 7-0 RCVCNT [7:0] Description The Receive Message Byte Count indicates the number of whole bytes in the received message. If pad bytes were stripped from the received frame, RCVCNT indicates the number of bytes received less the number of pad bytes and less the number of FCS bytes. RCVCNT is 12 bits long. If a late collision is detected (CLSN set in RCVSTS), the count is an indication of the length (in byte times) of the duration of the receive activity including the collision. RCVCNT [10:8] correspond to bits 3-0 in RFS1 of the Receive Frame Status. RCVCNT [11-0] will be invalid when OFLO is set.
Bit 5
FRAM
Bit 4
FCS
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AMD passed to the host. FCS will not be set if OFLO is set. The Receive Message Byte Count indicates the number of whole bytes in the received message from the network. RCVCNT is 12 bits long, and valid (accurate) only when there are no errors reported in the Receive Status (RCVSTS). If a late collision is detected (CLSN set in RCVSTS), the count is an indication of the length (in byte times) of the duration of the receive activity including the collision. RCVCNT [7:0] correspond to bits 7-0 in RFS0 of the Receive Frame Status. RCVCNT [11-0} will be invalid when OFLO is set. RCVFC reaches its maximum value of 15, additional receive frames will be ignored, and the Missed Packet Count (MPC) register will be incremented for frames which match the internal address(es) of the MACE device. Bit 3-0 XMTFC [3-0] Transmit Frame Count. The (read only) count of the frames in the Transmit FIFO. A frame is counted when the last byte is put in the FIFO. The counter is decremented when XMTSV (in the Transmit Frame Status and Poll Register) is set and the Transmit Frame Status read access is performed.
Bit 3-0 RCVCNT [11:8]
RFS2--Runt Packet Count (RNTPC) RNTPC [7-0] Bit Bit 7-0 Name RNTPC [7-0] Description The Runt Packet Count indicates the number of runt packets received, addressed to this node, since the last successfully received packet. The value does not roll over after 255 runt packets have been detected, and will remain frozen at the maximum count.
Interrupt Register (IR) (REG ADDR 8) All status bits are set upon occurrence of an event and cleared when read. The resister is read only. In addition all status bits are cleared by hardware or software reset. Bit assignments for the register are as follows:
JAB BABL CERR RCVCCO RNTPCO MPCO RCVINT XMTINT
Bit Bit 7
Name JAB
Description Jabber Error. JAB indicates that the MACE device attempted to transmit for an excessive time period (20-150 ms), when using either the DAI port or the 10BASE-T port. If the internal jabber timer expires during transmission, the transmit bit stream will be interrupted, until the internal transmission ceases and the unjab timer (0.5 s 0.25 s) expires. The jabber function will be disabled, and JAB will not be set, regardless of transmission length, when either the AUI or GPSI ports have been selected. JAB is READ/CLEAR only, and is set by the MACE device and reset when read. Writing has no effect. It is also cleared by activation of the RESET pin or SWRST bit. Babble Error. BABL is the transmitter time-out error. It indicates that the transmitter has been on the channel longer than the time required to send the maximum packet. It will be set after 1519 bytes (or greater) have been transmitted. The MACE device will continue to transmit until the current packet transmission is over. The INTR pin will be acti61
RFS3--Receive Collision Count (RCVCC) RCVCC [7-0] Bit Name Description The Receive Collision Count indicates the number of collisions detected on the network since the last successfully received packet. The value does not roll over after 255 collisions have been detected, and will remain frozen at the maximum count. (REG ADDR 7) Bit 6 BABL
Bit 7-0 RCVCC [7-0]
FIFO Frame Count (FIFOFC) RCVFC[3-0] Bit Bit 7-4 Name RCVFC [3-0]
XMTFC[3-0] Description Receive Frame Count. The (read only) count of the frames in the Receive FIFO. A frame is counted when the last byte is put in the FIFO. The counter is decremented when the last byte of the frame is read. If the
AM79C940
AMD vated if the corresponding mask bit BABLM = 0. BABL is READ/CLEAR only, and is set by the MACE device and reset when read. Writing has no effect. It is also cleared by activation of the RESET pin or SWRST bit. Collision Error. CERR indicates the absence of the Signal Quality Error Test (SQE Test) message after a packet transmission. The SQE Test message is a transceiver test feature. Detection depends on the MACE network interface selected. In all cases, CERR will be set if the MACE device failed to observe the SQE Test message within 20 network bit times after the packet transmission ended. When CERR is set, the INTR pin will be activated if the corresponding mask bit CERRM = 0. When the AUI port is selected, the SQE Test message is returned over the CI pair as a brief (5-15 bit times) burst of 10 MHz activity. When the 10BASE-T port is selected, CERR will be reported after a transmission only when the internal transceiver is in the link fail state (LNKST pin = HIGH). When the GPSI port is selected, the CLSN pin must be asserted by the external encoder/decoder to provide the SQE Test function. When the DAI port is selected, CERR will not be reported at any time. CERR is READ/CLEAR only. It is set by the MACE and reset when read. Writing has no effect. It is also cleared by activation of the RESET pin or SWRST bit. Receive Collision Count Overflow. Indicates that the Receive Collision Count register rolled over at a value of 255 receive collisions. Receive collisions are defined as received frames which suffered a collision. The INTR pin will be activated if the corresponding mask bit RCVCCOM = 0. Note that the RCVCC value returned in the Receive Frame Status (RFS3) will freeze at a value of 255, whereas this register based version of RCVCC (REG ADDR 27) is free running. RCVCCO is READ/CLEAR only. It is set by the MACE device and reset when read. Writing has no effect. It is also cleared by asserting the RESET pin or SWRST bit. Runt Packet Count Overflow. Indicates that the Runt Packet Count register rolled over at a value of 255 runt packets. Runt packets are defined as received frames which passed the internal address match criteria but did not contain a minimum of 64-bytes of data after SFD. The INTR pin will be activated if the corresponding mask bit RNTPCOM = 0. Note that the RNTPC value returned in the Receive Frame Status (RFS2) will freeze at a value of 255, whereas this register based version of RNTPC (REG ADDR 26) is free running. RNTPCO is READ/CLEAR only. It is set by the MACE device and reset when read. Writing has no effect. It is also cleared by asserting the RESET pin or SWRST bit. Missed Packet Count Overflow. Indicates that the Missed Packet Count register rolled over at a value of 255 missed frames. Missed frames are defined as received frames which passed the internal address match criteria but were missed due to a Receive FIFO overflow, the receiver being disabled (ENRCV = 0) or an excessive receive frame count (RCVFC > 15). The INTR pin will be activated if the corresponding mask bit MPCOM = 0. MPCO is READ/CLEAR only. It is set by the MACE device and reset when read. Writing has no effect. It is also cleared by asserting the RESET pin or SWRST bit. Receive Interrupt. Indicates that the host read the last byte/word of a packet from the Receive FIFO. The Receive Frame Status is available immediately on the next host read operation. The INTR pin will be activated if the corresponding mask bit RCVINTM = 0. RCVINT is READ/CLEAR only. It is set by the MACE device and reset when read. Writing has no effect. It is also cleared by activation of the RESET pin or SWRST bit. Transmit Interrupt. Indicates that the MACE device has completed
Bit 3
RNTPCO
Bit 5
CERR
Bit 2
MPCO
Bit 1
RCVINT
Bit 4
RCVCCO
Bit 0
XMTINT
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AMD the transmission of a packet and updated the Transmit Frame Status. The INTR pin will be activated if the corresponding mask bit XMTINTM = 0. XMTINT is READ/CLEAR only. It is set by the MACE device and reset when read. Writing has no effect. It is also cleared by activation of the RESET pin or SWRST bit. Interrupt Mask Register (IMR) (REG ADDR 9) This register contains the mask bits for the interrupts. Read/write operations are permitted. Writing a one into a bit will mask the corresponding interrupt. Writing a zero to any previously set bit will unmask the corresponding interrupt. Bit assignments for the register are as follows:
RES BABLM CERRM RCVCCOM RNTPCOM MPCOM RCVINTM XMTINTM
Bit 3
Bit 2
Bit 1
Bit Bit 7
Name JABM
Description
Bit 6
Bit 5
Bit 4
Jabber Error Mask. JABM is the mask for JAB. The INTR pin will not be asserted by the MACE device regardless of the state of the JAB bit, if JABM is set. It is cleared by activation of the RESET pin or SWRST bit. BABLM Babble Error Mask. BABLM is the mask for BABL. The INTR pin will not be asserted by the MACE device regardless of the state of the BABL bit, if BABLM is set. It is cleared by activation of the RESET pin or SWRST bit. CERRM Collision Error Mask. CERRM is the mask for CERR. The INTR pin will not be asserted by the MACE device regardless of the state of the CERR bit, if CERRM is set. It is cleared by activation of the RESET pin or SWRST bit. RCVCCOM Receive Collision Count Overflow Mask. RCVCCOM is the mask for RCVCCO(Receive Collision Count Overflow). The INTR pin will not be asserted by the MACE device regardless of the state of the RCVCCO bit, if RCVCCOM is set. It is cleared by activation of the RESET pin or SWRST bit.
Bit 0
RNTPCOM Runt Packet Count Overflow Mask. RNTPCOM is the mask for RNTPCO (Runt Packet Count Overflow). The INTR pin will not be asserted by the MACE device regardless of the state of the RNTPCO bit, if RNTPCOM is set. It is cleared by activation of the RESET pin or SWRST bit. MPCOM Missed Packet Count Overflow Mask. MPCOM is the mask for MPCO (Missed Packet Count Overflow). The INTR pin will not be asserted by the MACE device regardless of the state of the MPCO bit, if MPCOM is set. It is cleared by activation of the RESET pin or SWRST bit. RCVINTM Receive Interrupt Mask. RCVINTM is the mask for RCVINT. The INTR pin will not be asserted by the MACE device regardless of the state of the RCVINT bit, if RCVINTM is set. It is cleared by activation of the RESET pin or SWRST bit. XMTINTM Transmit Interrupt Mask. XMTINTM is the mask for XMTINT. The INTR pin will not be asserted by the MACE device regardless of the state of the XMTINT bit, if XMTINT is set. It is cleared by activation of the RESET pin or SWRST bit. (REG ADDR 10)
Poll Register (PR)
This register contains copies of internal status bits to simplify a host implementation which is non-interrupt driven. The register is read only, and its status is unaffected by read operations. All register bits are cleared by hardware or software reset. Bit assignments are as follows:
XMTSV TDTREQ RDTREQ RES RES RES RES RES
Bit Bit 7
Name XMTSV
Description Transmit Status Valid. Transmit Status Valid indicates that the Transmit Frame Status is valid. Transmit Data Transfer Request. An internal indication of the current request status of the Transmit FIFO. TDTREQ is set when the external TDTREQ signal is asserted.
Bit 6
TDTREQ
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AMD Bit 5 RDTREQ Receive Data Transfer Request. An internal indication of the current request status of the Receive FIFO. RDTREQ is set when the external RDTREQ signal is asserted. Reserved. Read as zeroes. Always write as zeroes. Bit 3-1 Bit 0 RES SWRST Reserved. Read as zeroes. Always write as zeroes. Software Reset. When set, provides an equivalent of the hardware RESET pin function. All register bits will be set to their default values. The MACE device will require re-initialization after SWRST has been activated. The MACE device will clear SWRST during its internal reset sequence. (REG ADDR 12)
Bit 4-0 RES
BIU Configuration Control (BIUCC) (REG ADDR 11) All bits within the BIU Configuration Control register will be set to their default state upon a hardware or software reset. Bit assignments are as follows:
RES BSWP XMTSP [1-0] RES RES RES SWRST
FIFO Configuration Control (FIFOCC)
Bit Bit 7 Bit 6
Name RES
Description
All bits within the FIFO Configuration Control register will be set to their default state upon a hardware or software reset. Bit assignments are as follows:
XMTFW[1-0] RCVFW [1-0] XMTFWU RCVFWU XMTBRST RCVBRST
Bit 5-4
Reserved. Read as zero. Always write as zero. BSWP Byte Swap. The BSWP function allows data to and from the FIFOs to be orientated according to little endian or big endian byte ordering conventions. BSWP is cleared by by activation of the RESET pin or SWRST bit, defaulting to Intel byte ordering. XMTSP Transmit Start Point. XMTSP [1-0] controls the point preamble transmission commences in relation to the number of bytes written to the XMTFIFO. When the entire frame is in the XMTFIFO (or the XMTFIFO becomes full before the threshold is achieved), transmission of preamble will start regardless of the value in XMTSP (once the IPG time has expired). XMTSP is given a value of 10 (64 bytes) after hardware or software reset. Regardless of XMTSP, the FIFO will not internally over write its data until at least 64 bytes, or the entire frame, has been transmitted onto the network. This ensures that for collisions within the slot time window, transmit data need not be re-written to the XMTFIFO, and re-tries will be handled autonomously by the MACE device. Transmit Start Point
XMTSP [1-0] 00 01 10 11 Bytes 4 16 64 112
Bit Bit 7-6
Name XMTFW [1-0]
Description
Transmit FIFO Watermark. XMTFW controls the point TDTREQ is asserted in relation to the number of write cycles to the Transmit FIFO. TDTREQ will be asserted at any time that the number of write cycles specified by XMTFW can be executed. XMTFW is set to a value of 00 (8 cycles) after hardware or software reset. Transmit FIFO Watermarks
Write Cycles 8 16 32 XX
XMTFW [1-0] 00 01 10 11
The XMTFW value will only be updated when the XMTFWU bit is set. To ensure that sufficient space is present in the XMTFIFO to accept the specified number of write cycles (including an EndOf-Frame delimiter), TDTREQ may go inactive before the XMTSP threshold is reached when using the non burst mode (XMTBRST = 0). The host must be aware that despite TDTREQ going inactive, additional space exists in the XMTFIFO, and the data write must continue to ensure the XMTSP threshold is achieved. No transmit activity will commence until the XMTSP
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AMD threshold is reached. When using the burst mode, TDTREQ will not be de-asserted until only a single write cycle can be performed. See the FIFO Sub-system section for additional details. Bit 5-4 RCVFW [1-0] Receive FIFO Watermark. RCVFW controls the point RDTREQ is asserted in relation to the number of bytes available in the RCVFIFO. RCVFW specifies the number of bytes which must be present (once the packet has been verified as a non-runt), before the RDTREQ is asserted. Note however that in order for RDTREQ to be activated for a new frame, at least 64-bytes must have been received. This effectively avoids reacting to receive frames which are runts or suffer a collision during the slot time (512 bit times). If the Runt Packet Accept feature (RPA in Receive Frame Control) is enabled, the RDTREQ pin will be activated as soon as either 64-bytes are received, or a complete valid receive frame is detected (regardless of length). RCVFW is set to a value of 10 (64 bytes) after hardware or software reset. Receive FIFO Watermarks
Bytes 16 32 64 XX
Bit 2
RCVFW [1-0] 00 01 10 11
Bit 1
Bit 3
XMTFWU
The RCVFW value will only be updated when the RCVFWU bit is set. Transmit FIFO Watermark Update. Allows update of the Transmit FIFO Watermark bits. The XMTFW can be written at any point, and will be read back as written. However, the new value in the XMTFW bits will be ignored until XMTFWU is set (or the transmit path is reset due to a
retry failure). The recommended procedure to change the XMTFW is to write the new value with XMTFWU set, in a single write cycle. The XMTFIFO should be empty and all transmit activity complete before attempting a watermark update, since the XMTFIFO will be reset to allow the new pointer values to be loaded. It is recommended that the transmitter be disabled by clearing the ENXMT bit. XMTFWU will be cleared by the MACE device after the new XMTFW value has been loaded, or by activation of the RESET pin or SWRST bit. RCVFWU Receive FIFO Watermark Update. Allows update of the Receive FIFO Watermark bits. The RCVFW bits can be written at any point, and will read back as written. However, the new value in the RCVFW bits will be ignored until RCVFWU is set. The recommended procedure to change the RCVFW is to write the new value with RCVFWU set, in a single write cycle. The RCVFIFO should be empty before attempting a watermark update, since the RCVFIFO will be reset to allow the new pointer values to be loaded. It is recommended that the receiver be disabled by clearing the ENRCV bit. RCVFWU will be cleared by the MACE device after the new RCVFW value has been loaded, or by activation of the RESET pin or SWRST bit. XMTBRST Transmit Burst. When set, the transmit burst mode is selected. The behavior of the Transmit FIFO high watermark, and hence the de-assertion of TDTREQ, will be modified. TDTREQ will be deasserted if there are only two bytes of space available in the XMTFIFO (so that a full word write can still occur) or if four bytes of space exist and the EOF pin is asserted by the host.
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AMD TDTREQ will be asserted identically in both normal and burst modes, when there is sufficient space in the XMTFIFO to allow the specified number of write cycles to occur (programmed by the XMTFW bits). Cleared by activation of the RESET pin or SWRST bit. RCVBRST Receive Burst. When set, the receive burst mode is selected. The behavior of the Receive FIFO low watermark, and hence the deassertion of RDTREQ, will be modified. RDTREQ will de-assert when there are only 2-bytes of data available in the RCVFIFO (so that a full word read can still occur). RDTREQ will be asserted identically in both normal and burst modes, when a minimum of 64-bytes have been received for a new frame (or a runt packet has been received and RPA is set). Once the 64-byte limit has been exceeded, RDTREQ will be asserted providing there is sufficient data in the RCVFIFO to exceed the threshold, as programmed by the RCVFW bits. Cleared by activation of the RESET pin or SWRST bit. (REG ADDR 13) Bit 5 EMBA Enable Modified Back-off Algorithm. When set, enables the modified backoff algorithm. EMBA is cleared by activation of the RESET pin or SWRST bit. Reserved. Read as zeroes. Always write as zeroes. Disable Receive Physical Address. When set, the physical address detection (Station or node ID) of the MACE device will be disabled. Packets addressed to the nodes individual physical address will not be recognized (although the packet may be accepted by the EADI mechanism). DRCVPA is cleared by activation of the RESET pin or SWRST bit. Disable Receive Broadcast. When set, disables the MACE device from responding to broadcast messages. Used for protocols that do not support broadcast addressing, except as a function of multicast. DRCVBC is cleared by activation of the RESET pin or SWRST bit (broadcast messages will be received). Enable Transmit. Setting ENXMT = 1 enables transmission. With ENXMT = 0, no transmission will occur. If ENXMT is written as 0 during frame transmission, a packet transmission which is incomplete will have a guaranteed CRC violation appended before the internal Transmit FIFO is cleared. No subsequent attempts to load the FIFO should be made until ENXMT is set and TDTREQ is asserted. ENXMT is cleared by activation of the RESET pin or SWRST bit. Enable Receive. Setting ENRCV = 1 enables reception of frames. With ENRCV = 0, no frames will be received from the network into the internal FIFO. When ENRCV is written as 0, any receive frame currently in progress will be completed (and valid data contained in the RCVFIFO can be read by the host) and the MACE device will enter the monitoring state for missed packets. Note that clearing the ENRCV bit disables the
Bit 4 Bit 3
RES DRCVPA
Bit 0
Bit 2
DRCVBC
Bit 1
ENXMT
MAC Configuration Control (MACCC)
This register programs the transmit and receive operation and behavior of the internal MAC engine. All bits within the MAC Configuration Control register are cleared upon hardware or software reset. Bit assignments are as follows:
PROM DXMT2PD EMBA RES DRCVPA DRCVBC ENXMT ENRCV
Bit Bit 7
Name PROM
Description
Bit 0
ENRCV
Bit 6
Promiscuous. When PROM is set all incoming frames are received regardless of the destination address. PROM is cleared by activation of the RESET pin or SWRST bit. DXMT2PD Disable Transmit Two Part Deferral. When set, disables the transmit two part deferral option. DXMT2PD is cleared by activation of the RESET pin or SWRST bit.
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AMD assertion of RDTREQ. If ENRCV is cleared during receive activity and remains cleared for a long time and if the tail end of the receive frame currently in progress is longer than the amount of space available in the Receive FIFO, Receive FIFO overflow will occur. However, even with RDTREQ deasserted, if there is valid data in the Receive FIFO to be read, successful slave reads to the Receive FIFO can be executed (indicated by valid DTV). It is the host's responsibility to avoid the overflow situation. ENRCV is cleared by activation of the RESET pin or SWRST bit. PLS Configuration Control (PLSCC) (REG ADDR 14) PORTSEL Interface Definition
PORTSEL [1-0] 00 01 10 11 Active Interface AUI 10BASE-T DAI Port GPSI DXCVR Pin LOW HIGH HIGH LOW
Bit 0
ENPLSIO
All bits within the PLS Configuration Control register are cleared upon a hardware or software reset. Bit assignments are as follows:
RES RES RES RES XMTSEL PORTSEL [1-0] ENPLSIO
Enable PLS I/O. ENPLSIO is used to enable the optional I/O functions from the PLS function. The following pins are affected by the ENPLSIO bit: RXCRS, RXDAT, TXEN, TXDAT+, TXDAT-, CLSN, STDCLK, SRDCLK and SRD. Note that if an external SIA is being utilized via the GPSI, PORTSEL [1-0] = 11 must be programmed before ENPLSIO is set, to avoid contention of clock, data and/or carrier indicator signals. (REG ADDR 15)
PHY Configuration Control (PHYCC)
Bit
Name
Description Reserved. Read as zeroes. Always write as zeroes. Transmit Mode Select. XMTSEL provides control over the AUI DO+ and DO- operation while the MACE device is not transmitting. With XMTSEL = 0, DO+ and DO will be equal during transmit idle state, providing zero differential to operate transformer coupled loads. The turn off and return to zero delays are controlled internally. With XMTSEL = 1, DO+ is positive with respect to DO during the transmit idle state . Port Select. PORTSEL is used to select between the AUI, 10BASE-T, DAI or GPSI ports of the MACE device. PORTSEL is cleared by hardware or software reset. PORTSEL will determine which of the interfaces is used during normal operation, or tested when utilizing the loopback options (LOOP [1-0]) in the User Test Register. Note that the PORTSEL [1-0] programming will be overridden if the ASEL bit in the PHY Configuration Control register is set.
Bit 7-4 RES Bit 3 XMTSEL
All bits within the PHY Configuration Control register with the exception of LNKFL, are cleared by hardware or software reset. Bit assignments are as follows:
LNKFL DLNKTST REVPOL DAPC LRT ASEL RWAKE AWAKE
Bit Bit 7
Name LNKFL
Description Link Fail. Reports the link integrity of the 10BASE-T receiver. When the link test function is enabled (DLNKTST = 0), the absence of link beat pulses on the RXD pair will cause the integrated 10BASE-T transceiver to go into the link fail state. In the link fail state, data transmission, data reception, data loopback and the collision detection functions are disabled, and remain disabled until valid data or >5 consecutive link pulses appear on the RXD pair. During link fail, the LNKFL bit will be set and the LNKST pin should be externally pulled HIGH. When the link is identified as functional, the LNKFL bit will be cleared and the LNKST pin is driven LOW, which is capable of directly driving a Link OK LED. In order to interoperate with systems which do
Bit 2-1 PORTSEL [1-0]
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AMD not implement Link Test, this function can be disabled by setting the DLNKTST bit. With Link Test disabled (DLNKTST = 1), the data driver, receiver and loopback functions as well as collision detection remain enabled irrespective of the presence or absence of data or link pulses on the RXD pair. The transmitter will continue to generate link beat pulses during periods of transmit data inactivity. Set by hardware or software reset. Disable Link Test. When set, the integrated 10BASE-T transceiver will be forced into the link pass state, regardless of receive link test pulses or receive packet activity. Reversed Polarity. Indicates the receive polarity of the RD pair. When normal polarity is detected, the REVPOL bit will be cleared, and the RXPOL pin (capable of driving a Polarity OK LED) will be driven LOW. When reverse polarity is detected, the REVPOL bit will be set, and the RXPOL pin should be externally pulled HIGH. Disable Auto Polarity Correction. When set, the automatic polarity correction will be disabled. Polarity detection and indication will still be possible via the RXPOL pin. Low Receive Threshold. When set, the threshold of the twisted pair receiver will be reduced by 4.5 dB, to allow extended distance operation. Auto Select. When set, the PORTSEL [1-0] bits are overridden, and the MACE device will automatically select the operating media interface port. When the 10BASE-T transceiver is in the link pass state (due to receiving valid packet data and/or Link Test pulses or the DLNKTST bit is set), the 10BASE-T port will be used. When the 10BASE-T port is in the link fail state, the AUI port will be used. Switching between the ports will not occur during transmission in order to avoid any type of fragment generation. Remote Wake. When set prior to the SLEEP pin being activated, the AUI and 10BASE-T receiver sections and the EADI port will continue to operate even during SLEEP. Incoming packet activity will be passed to the EADI port pins permitting detection of specific frame contents used to initiate a wake-up sequence. RWAKE must be programmed prior to SLEEP being asserted for this function to operate. RWAKE is not cleared by SLEEP, only by activation of the SWRST bit or RESET pin. Auto Wake. When set prior to the SLEEP pin being activated, the 10BASE-T receiver section will continue to operate even during SLEEP, and will activate the LNKST pin if Link Pass is detected. AWAKE must be programmed prior to SLEEP being asserted for this function to operate. AWAKE is not cleared by SLEEP, only by activation of the SWRST bit or RESET pin. (REG ADDR 16 &17)
Bit 0
AWAKE
Bit 6
DLNKTST
Bit 5
REVPOL
Chip Identification Register (CHIPID [15-00])
This 16-bit value corresponds to the specific version of the MACE device being used. The value will be programmed to X940h, where X is a value dependent on version. CHIPID [07-00] CHIPID [15-08] Internal Address Configuration (IAC) (REG ADDR 18)
Bit 4
DAPC
Bit 3
LRT
This register allows access to and from the multi-byte Physical Address and Logical Address Filter locations, using only a single byte location. The MACE device will reset the IAC register PHYADDR and LOGADDR bits after the appropriate number of read or write cycles have been executed on the Physical Address Register or the Logical Address Filter. Once the LOGADDR bit is set, the MACE device will reset the bit after 8 read or write operations have been performed. Once the PHYADDR bit is set, the MACE device will reset the bit after 6 read or write operations have been performed. The MACE device makes no distinction between read or write operations, advancing the internal address RAM pointer with each access. If both PHYADDR and LOGADDR bits are set, the MACE device will accept only the LOGADDR bit. If the PHYADDR bit is set and the Logical Address Filter location is accessed, a DTV will not be returned. Similarly, if the LOGADDR bit is set and the Physical Address Register location is accessed, DTV will not be returned. PHYADDR or LOGADDR can be set in the same cycle as ADDRCHG.
Bit 2
ASEL
Bit 1
RWAKE
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ADDRCHG RES RES RES RES PHYADDR LOGADDR RES
Logical Address Filter (LADRF [63-00]) LADRF [63-00]
(REG ADDR 20)
Bit Bit 7
Name
Description
ADDRCHG Address Change. When set, allows the physical and/or logical address to be read or programmed. When ADDRCHG is set, ENRCV will be cleared, the MPC will be stopped, and the last or current in progress receive frame will be received as normal. After the frame completes, access to the internal address RAM will be permitted, indicated by the MACE device clearing the ADDRCHG bit. Please refer to the register description of the ENRCV bit in the MAC Configuration Control register (REG ADDR 13) for the effect of clearing the ENRCV bit. Normal reception can be resumed once the physical/logical address has been changed, by setting ENRCV. Bit 6-3 RES Reserved. Read as zeroes. Always write as zeroes. Bit 2 PHYADDR Physical Address Reset. When set, successive reads or writes to the Physical Address Register will occur in the order PADR [07-00], PADR [15-08],...., PADR [47-40]. Each read or write operation on the PADR location will auto-increment the internal pointer to access the next most significant byte. Bit 1 LOGADDR Logical Address Reset. When set, successive reads or writes to the Logical Address Filter will occur in the order LADRF [07-00], LADRF [15-08],....,LADRF [63-56]. Each read or write operation on the LADRF location will auto-increment the internal pointer to access the next most significant byte. Bit 0 RES Reserved. Read as zero. Always write as zero.
This 64-bit mask is used to accept incoming Logical Addresses. The Logical Address Filter is expected to be programmed at initialization (after hardware or software reset). After a hardware or software reset and before the ENRCV bit in the MAC Configuration Control register has been set, the Logical Address can be accessed by setting the LOG ADDR bit in the Internal Address Configuration register (REG ADDR 18) and then by performing 8 reads or writes to the Logical Address Filter. Once ENRCV has been set, the ADDR CHG bit in the Internal Address Configuration register must be set and be polled until it is cleared by the MACE device before setting the LOGADDR bit and before accessing of the Logical Address Filter is allowed. If the least significant address bit of a received message is set (Destination Address bit 00 = 1), then the address is deemed logical, and passed through the FCS generator. After processing the 48-bit destination address, a 32-bit resultant FCS is produced and strobed into an internal register. The high order 6-bits of this resultant FCS are used to select one of the 64-bit positions in the Logical Address Filter (see diagram). If the selected filter bit is a 1, the address is accepted and the packet will be placed in memory. The first bit of the incoming address must be a 1 for a logical address. If the first bit is a 0, it is a physical address and is compared against the value stored in the Physical Address Register at initialization. The Logical Address Filter is used in multicast addressing schemes. The acceptance of the incoming frame based on the filter value indicates that the message may be intended for the node. It is the user's responsibility to determine if the message is actually intended for the node by comparing the destination address of the stored message with a list of acceptable logical addresses. The Broadcast address, which is all ones, does not go through the Logical Address Filter and is always enabled providing that the Disable Receive Broadcast bit (DRCVBC in the MAC Configuration Control register) is cleared. If the Logical Address Filter is loaded with all zeroes (and PROM = 0), all incoming logical addresses except broadcast will be rejected. Multicast addressing can only be performed when using external loopback (LOOP [1-0] = 0) by programming RCVFCSE = 1 in the User Test Register. The FCS logic is internally allocated to the receiver section, allowing the FCS to be computed on the incoming logical address.
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Received Message Destination Address 47 10 1 CRC GEN SEL 63 32-Bit Resultant CRC 0 26 Logical Address Filter (LADRF)
31
0
64 MUX MATCH*
6
MATCH = 1: Packet Accepted MATCH = 0: Packet Rejected
16235C-10 16907A-015A
Logical Address Match Logic
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AMD Physical Address (PADR [47-00]) PADR [47-00] This 48-bit value represents the unique node value assigned by the IEEE and used for internal address comparison. After a hardware or software reset and before the ENRCV bit in the MAC Configuration Control register has been set, the Physical Address can be accessed by setting the PHYADDR bit in the Internal Address Configuration register (REG ADDR 18) and then by performing 6 reads or writes to the Physical Address. Once ENRCV has been set, the ADDRCHG bit in the Internal Address Configuration register must be set and be polled until it is cleared by the MACE device before setting the PHYADDR bit and before accessing of the Physical Address is allowed. The first bit of the incoming address must be a 0 for a physical address. The incoming address is compared against the value stored in the Physical Address register at initialization provided that the DRCVPA bit in the MAC Configuration Control register is cleared. Missed Packet Count (MPC) MPC [7-0] The Missed Packet Count (MPC) is a read only 8-bit counter. The MPC is incremented when the receiver is unable to respond to a packet which would have normally been passed to the host. The MPC will be reset to zero when read. The MACE device will be deaf to receive traffic due to any of the following conditions : s The host disabled the receive function by clearing the ENRCV bit in the MAC Configuration Control register. A Receive FIFO overflow condition exists, and must be cleared by reading the Receive FIFO and the Receive Frame Status. The Receive Frame Count (RCVFC) in the FIFO Frame Count register exceeds its maximum value, indicating that greater than 15 frames are in the Receive FIFO. (REG ADDR 24) Interrupt Mask Register is clear. MPCOM will be cleared (the interrupt will be unmasked) after a hardware or software reset. Note that the following conditions apply to the MPC: s After hardware or software reset, the MPC will not increment until the first time the receiver is enabled (ENRCV = 1). Once the receiver has been enabled, the MPC will count all missed packet events, regardless of the programming of ENRCV. The packet must pass the internal address match to be counted. Any of the following address match conditions will increment MPC while the receiver is deaf: Physical Address match; Logical Address match; Broadcast reception; Any receive in promiscuous mode (PROM = 1 in the MAC Configuration Control register); EADI feature match mode and EAM is asserted; EADI feature reject mode and EAR is not asserted. Any packet which suffers a collision within the slot time will not be counted. Runt packets will not be counted unless RPA in the User Test Register is enabled. Packets which pass the address match criteria but experience FCS or Framing errors will be counted, since they are normally passed to the host. (REG ADDR 26)
(REG ADDR 21)
s
s s s
Runt Packet Count (RNTPC) RNTPC [7-0]
s
s
If the number of received frames that have been missed exceeds 255, the MPC will roll over and continue counting from zero, the MPCO (Missed Packet Count Overflow) bit in the Interrupt Register will be set (at the value 255), and the INTR pin will be asserted providing that MPCOM (Missed Packet Count Overflow Mask) in the
The Runt Packet Count (RNTPC) is a read only 8-bit counter, incremented when the receiver detects a runt packet that is addressed to this node. Runt packets are defined as received frames which passed the internal address match criteria but did not contain a minimum of 64-bytes of data after SFD. Note that the RNTPC value returned in the Receive Frame Status (RFS2) will freeze at a value of 255, whereas this register based version of RNTPC is free running. The value will roll over after 255 runt packets have been detected, setting the RNTPCO bit (in the Interrupt Register and asserting the INTR pin if the corresponding mask bit (RNTPCOM in the Interrupt Mask Register) is cleared. RNTPC will be reset to zero when read.
71
AM79C940
AMD Receive Collision Count (RCVCC) (REG ADDR 27) RCVCC [7-0] The Receive Collision Count (RCVCC) is a read only 8-bit counter, incremented when the receiver detects a collision on the network. Note that the RCVCC value returned in the Receive Frame Status (RFS3) will freeze at a value of 255, whereas this register based version of RCVCC is free running. The value will roll over after 255 receive collisions have been detected, setting the RCVCCO bit (in the Interrupt Register and asserting the INTR pin if the corresponding mask bit (RCVCCOM in the Interrupt Mask Register ) is cleared. RCVCC will be reset to zero when read. User Test Register (UTR) (REG ADDR 29) The User Test Register is used to put the chip into test configurations. All bits within the Test Register are cleared upon a hardware or software reset. Bit assignments are as follows:
RTRE RTRD RPA FCOLL RCVFCSE LOOP [1-0] RES
Bit 4
Bit Bit 7
Name RTRE
Description Reserved Test Register Enable. Access to the Reserved Test Registers should not be attempted by the user. Note that access to the Reserved Test Register may cause damage to the MACE device if configured in a system board application. Access to the Reserved Test Register is prevented, regardless of the state of RTRE, once RTRD has been set. RTRE is cleared by activation of the RESET pin or SWRST bit. Reserved Test Register Disable. When set, access to the Reserved Test Registers is inhibited, and further writes to the RTRD bit are ignored. Access to the Reserved Test Register is prevented, regardless of the state of RTRE, once RTRD has been set. RTRD can only be cleared by hardware or software reset. Runt Packet Accept. Allows receive packets which are less than the legal minimum as specified by IEEE 802.3/Ethernet, to be passed to the host interface via the Receive FIFO. The receive packets must be at least 8 bytes (after SFD) in length to be accepted. RPA is cleared by activation of the RESET pin or SWRST bit.
Bit 6
RTRD
Bit 5
RPA
Force Collision. Allows the collision logic to be tested. The MACE device should be in an internal loopback test for the FCOLL test. When FCOLL = 1, a collision will be forced during the next transmission attempt. This will result in 16 total transmission attempts (if DRTRY = 0) with the Retry Error reported in the Transmit Frame Status register. FCOLL is cleared by the activation of the RESET pin or SWRST bit. Bit 3 RCVFCSE Receive FCS Enable. Allows the hardware associated with the FCS generation to be allocated to the transmitter or receiver during loopback diagnostics. When clear, the FCS will be generated and appended to the transmit message (providing that DXMTFCS in the Transmit Frame Control is clear), and received after the loopback process through the Receive FIFO. When set, the hardware associated with the FCS generation is allocated to the receiver. A transmit packet will be assumed to contain the FCS in the last four bytes of the frame passed through the Transmit FIFO. The received frame will have the FCS calculated on the data field and compared with the last four bytes contained in the received message. An FCS error will be flagged in the Received Status (RFS1) if the received and calculated values do not match. RCVFCSE is only valid when in any one of the loopback modes as defined by LOOP [0-1]. Note that if the receive frame is expected to be recognized on the basis of a multicast address match, the FCS logic must be allocated to the receiver (RCVFCSE = 1). RCVFCSE is cleared by activation of the RESET pin or SWRST bit. Bit 2-1 LOOP [1-0] Loopback Control. The loopback functions allow the MACE device to receive its own transmitted frames. Three levels of loopback are provided as shown in the following table. During loopback operation a multicast address can only be recognized if RCVFCSE = 1. LOOP [0-1] are cleared by activation of the RESET pin or SWRST bit.
FCOLL
72
AM79C940
AMD Loopback Functions
Loop [1-0] 00 01 10 11 Function No Loopback External Loopback Internal Loopback, excludes MENDEC Internal Loopback, includes MENDEC
Bit 0
RES
Configuration Control register. Using the internal loopback test will ensure that transmission does not disturb the physical medium and will prohibit frame reception from the network. One Internal loopback function includes the MENDEC in the loop. Reserved. Read as zero. Always write as zero. (REG ADDR 30) (REG ADDR 31)
External loopback allow the MACE device to transmit to the physical medium, using either the AUI, 10BASE-T, DAI or GPSI port, dependent on the PORTSEL [1-0] bits in the PLS
Reserved Test Register 1 (RTR1) Reserved for AMD internal use only. Reserved Test Register 2 (RTR2) Reserved for AMD internal use only.
AM79C940
73
AMD
Register Table Summary
Address 0 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 26 27 28 29 30 31 UTR RTR1 RTR2 RNTPC RCVCC MPC LADRF PADR Mnemonic RCVFIFO XMTFIFO XMTFC XMTFS XMTRC RCVFC RCVFS FIFOFC IR IMR PR BIUCC FIFOCC MACCC PLSCC PHYCC CHIPID CHIPID IAC Contents Receive FIFO [15-00] Transmit FIFO [15-00] Transmit Frame Control Transmit Frame Status Transmit Retry Count Receive Frame Control Receive Frame Status (4-bytes) FIFO Frame Count Interrupt Register Interrupt Mask Register Poll Register BIU Configuration Control FIFO Configuration Control MAC Configuration Control PLS Configuration Control PHY Configuration Control Chip Identification Register [07-00] Chip Identification Register [15-08] Internal Address Configuration Reserved Logical Address Filter (8-bytes) Physical Address (6-bytes) Reserved Reserved Missed Packet Count Reserved Runt Packet Count Receive Collision Count Reserved User Test Register Reserved Test Register 1 Reserved Test Register 2 Comments Read only Write only Read/Write Read only Read only Read/Write Read only Read only Read only Read/Write Read only Read/Write Read/Write Read/Write Read/Write Read/Write Read only Read only Read/Write Read/Write as 0 Read/Write Read/Write Read/Write as 0 Read/Write as 0 Read only Read/Write as 0 Read only Read only Read/Write as 0 Read/Write Read/Write as 0 Read/Write as 0
74
AM79C940
AMD
Register Bit Summary
16-Bit Registers
0 1 RCVFIFO [15-0] XMTFIFO [15-0]
8-Bit Registers
Address
2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 RTRE RTRD RPA ADDRCHG RES RES JAB JABM XMTSV RES PROM RES LNKFL RCVFC [3-0] BABL BABLM TDTREQ BSWP DXMT2PD RES DLNKTST CERR CERRM RDTREQ RCVCCO RCVCCOM RES RNTPCO RNTPCOM RES RES XMTFWU DRCVPA XMTSEL LRT DRTRY XMTSV EXDEF RES RES UFLO RES RES RES LCOL RES RES
Mnemonic
RES MORE RES RES LLRCV RCVFS [31-00] XMTFC [3-0] MPCO MPCOM RES RES RCVFWU DRCVBC ASEL RCVINT RCVINTM RES RES XMTBRST ENXMT RWAKE XMTINT XMTINTM RES SWRST RCVBRST ENRCV ENPLSIO AWAKE DXMTFCS ONE RES DEFER M/R RES LCAR RES APADXMT RTRY ASTRPRCV
XMTRC [3-0]
XMTSP [1-0] RCVFW [1-0] EMBA RES REVPOL RES RES DAPC
XMTFW [1-0]
PORTSEL [1-0]
CHIPID [07-00] CHIPID [15-08] RES RES PHYADDR LOGADDR RES RESERVED LADRF [63-00] PADR [47-00] RESERVED RESERVED MPC [7-0] RESERVED RNTPC [7-0] RCVCC [7-0] RESERVED FCOLL RCVFCSE LOOP [1-0] RES RESERVED RESERVED
Receive Frame Status
Address
RFS0 RFS1 RFS2 RFS3 OFLO CLSN FRAM
Mnemonic
RCVCNT [7:0] FCS RNTPC [7-0] RCVCC [7-0] RCVCNT [10:8]
AM79C940
75
AMD
Programmer's Register Model
Addr 0 1 2 Mnemonic RCVFIFO XMTFIFO XMTFC Receive FIFO--16 bits Transmit FIFO--16 bits Transmit Frame Control 80 08 01 3 XMTFS 80 40 20 10 08 04 02 01 4 XMTRC 80 40 20 10 0F 5 RCVFC 08 04 01 6 RCVFS RFS0 RFS1 DRTRY DXMTFCS APADXMT XMTSV UFLO LCOL MORE ONE DEFER LCAR RTRY EXDEF -- -- -- XMTRC [3:0] LLRCV M/R ASTRPRCV 4-bit Transmit Retry Count Low Latency Receive Match/Reject for external address detection Auto Strip Receive--Strips pad and FCS from received frames RO R/W Disable Retry Disable Transmit FCS Auto Pad Transmit RO Transmit Status Valid Underflow Late Collision MORE than one retry was needed Exactly ONE retry occurred Transmission was deferred Loss of Carrier Transmit aborted after 16 attempts Excessive Defer RO R/W Contents R/W RO WO
Transmit Frame Status
Receive Frame Control
Receive Frame Status--4 bytes--read in 4 read cycles RCVCNT [7:0] Receive Message Byte Count RCVSTS, RCVCNT [11:8]--Receive Status & Receive Msg Byte Count MSBs 80 40 20 10 0F RFS2 RFS3 RNTPC [7:0] RCVCC [7:0] RCVFC XMTFC JAB BABL CERR RCVCCO RNTPCO MPCO RCVINT XMTINT OFLO CLSN FRAM FCS RCVCNT [11:8] Receive FIFO Overflow Collision during reception Framing Error FCS (CRC) error 4 MSBs of Receive Msg. Byte Count
Runt Packet Count (since last successful reception) Receive Collision Count (since last successful reception) RO Receive Frame Count--# of RCV frames in FIFO Transmit Frame Count--# of XMT frames in FIFO Jabber Error--Excessive transmit duration (20-150ms) Babble Error1518 bytes transmitted Collision Error--No SQE Test Message Receive Collision Count Overflow--Reg Addr 27 overflow Runt Packet Count Overflow--Reg Addr 26 overflow Missed Packet Count Overflow--Reg Addr 24 overflow Receive Interrupt--Host has read last byte of packet Transmit Interrupt--Transmission is complete RO RO
7
FIFOFC
FIFO Frame Count F0 0F
8
IR
Interrupt Register 80 40 20 10 08 04 02 01
76
AM79C940
AMD
Programmer's Register Model (continued)
Addr 9 Mnemonic IMR Interrupt Mask Register 80 40 20 10 08 04 02 01 10 PR 80 40 20 11 BIUCC 80 40 30 JABM BABLM CERRM RCVCCOM RNTPCOM MPCOM RCVINTM XMTINTM XMTSV TDTREQ RDTREQ -- BSWP 00 01 10 11 01 12 FIFOCC C0 SWRST XMTFW 00 01 10 11 30 RCVFW 00 01 10 11 08 04 02 01 13 MACCC 80 40 20 10 08 04 02 01 XMTFWU RCVFWU XMTBRST RCVBRST PROM DXMT2PD EMBA -- DRCVPA DRCVBC ENXMT ENRCV Disable Receive Physical Address Disable Receive Broadcast Enable Transmit Enable Receive Byte Swap Transmit after 4 bytes have been loaded Transmit after 16 bytes have been loaded Transmit after 64 bytes have been loaded Transmit after 112 bytes have been loaded Software Reset Transmit FIFO Watermark (2 bits) Assert TDTREQ after 8 write cycles can be made Assert TDTREQ after 16 write cycles can be made Assert TDTREQ after 32 write cycles can be made XX Receive FIFO Watermark (2 bits) Assert RDTREQ after 16 bytes are present Assert RDTREQ after 32 bytes are present Assert RDTREQ after 64 bytes are present XX Transmit FIFO Watermark Update--loads XMTFW bits Receive FIFO Watermark Update--loads RCVFW bits Select Transmit Burst mode Select Receive Burst mode Promiscuous mode Disable Transmit Two Part Deferral Enable Modified Back-off Algorithm R/W R/W R/W XMTSP--Transmit Start Point (2 bits) Jabber Error Mask Babble Error Mask Collision Error Mask Receive Collision Count Overflow Mask Runt Packet Count Overflow Mask Missed Packet Count Overflow Mask Receive Interrupt Mask Transmit Interrupt Mask Transmit Status Valid Transmit Data Transfer Request Receive Data Transfer Request RO R/W Contents R/W
Poll Register
Bus Interface Unit Configuration Control
FIFO Configuration Control
Media Access Control (MAC) Configuration Control
AM79C940
77
AMD
Programmer's Register Model (continued)
Addr 14 Mnemonic PLSCC Contents Physical Layer Signalling (PLS) Configuration Control 08 XMTSEL Transmit Mode Select: 1DO = 1 during IDLE 06 PORTSEL [1:0]--Port Select (2 bits) 00 AUI selected 01 10BASE-T selected 10 DAI port selected 11 GPSI selected 01 ENPLSIO Enable Status Physical Layer (PHY) Configuration Control 80 LNKFL Link Fail--Reports 10BASE-T receive inactivity 40 DLNKTST Disable Link Test--Force 10BASE-T port into Link Pass 20 REVPOL Reversed Polarity--Reports 10BASE-T receiver wiring error 10 DAPC Disable Auto Polarity Correction--Detection remains active 08 LRT Low Receive Threshold--Extended distance capability 04 ASEL Auto Select--Select 10BASE-T port when active, otherwise AUI 02 RWAKE Remote Wake--10BASE-T, AUI and EADI features active during sleep 01 AWAKE Auto Wake--10BASE-T receive and LNKST active during sleep Chip Identification Register LSB--CHIPID [7:0] Chip Identification Register MSB--CHIPID [15:8] Internal Address Configuration 80 ADDRCHG Address Change--Write to PHYADDR or LOGADDR after ENRCV 40 -- 20 -- 10 -- 08 -- 04 -- 04 PHYADDR Reset Physical Address pointer 02 LOGADDR Reset Logical Address pointer 01 -- Reserved Logical Address Filter--8 bytes--8 reads or writes--LS Byte first Physical 6 bytes--6 reads or writes--LS Byte first Reserved Reserved Missed Packet Counter--Number of receive packets missed Reserved Runt Packet Count--Number of runt packets addressed to this node Receive Collision Count--Number of receive collision frames on network Reserved User Test Register 80 RTRE Reserved Test Register Enable--must be 0 40 RTRD Reserved Test Register Disable 20 RPA Runt Packet Accept 10 FCOLL Force Collision 08 RCVFCSE Receive FCS Enable 06 LOOP Loopback control (2 bits) 00 No loopback 01 External loopback 10 Internal loopback, excludes MENDEC 11 Internal loopback, includes MENDEC 01 -- R/W
R/W
15
PHYCC
R/W
16 17 18
CHIPID CHIPID IAC
RO RO
R/W
19 20 21 22 23 24 25 26 27 28 29
-- LADRF PADR -- -- MPC -- RNTPC RCVCC -- UTR
R/W as 0 R/W R/W R/W as 0 R/W as 0 RO R/W as 0 RO RO R/W as 0 R/W
R/W
78
AM79C940
AMD
Programmer's Register Model (continued)
Addr 30 31 Mnemonic -- -- Reserved Reserved Contents R/W R/W as 0 R/W as 0
SYSTEM APPLICATIONS Host System Examples
Motherboard DMA Controller The block diagram shows the MACE device interfacing to a 8237 type DMA controller. Two external latches are used to provide a 24 bit address capability. The first latch stores the address bits A [15:8], which the 8237 will output on the data line DB [7:0], while the signal ADSTB is active. The second latch is used as a page register. It extends the addressing capability of the 8237 from 16-bit to 24-bit. This latch must be programmed by the system using an I/0 command to generate the signal LATCHHIGHADR. The MACE device uses two of the four DMA channels. One is dedicated to fill the Transmit FIFO and the other to empty the Receive FIFO. Both DMA channels should be programmed in the following mode: Command Register: Memory to memory disabled DREQ sense active high DACK sense active low Normal timing Late Write
Note: This is the same configuration as used in the IBM PC.
The 8237 and the MACE device run synchronous to the same SCLK. The 8237 is programmed to execute a transfer in three clock cycles This requires an extra wait state in the MACE device during FIFO accesses. A system not using the same configuration as in the IBM PC can minimize the bus bandwidth required by the MACE device by programming the DMA controller in the compressed timing mode. Care must be taken with respect to the number of transfers within a burst. The 8237 will drive the signal EOP low every time the internal counter reaches the zero. The MACE device however only expects EOF asserted on the last byte/word of a packet. This means, that the word counter of the 8237 should be initially loaded with the number of bytes/words in the whole packet. If the application requires that the packet will be constructed from several buffers at transmit time, some extra logic is required to suppress the assertion of EOF at the end of all but the last buffer transferred by the DMA controller. Also note that the DMA controller can only handle either bytes or words at any time. It requires special handling if a packet is transferred to the MACE device Transmit FIFO in word quantities and it ends in an odd byte. The 8237 requires an extra clock cycle to update the external address latch every 256 transfer cycles. This example assumes that an update of the external address latch occurs only at the beginning of the block transfer.
AM79C940
79
AMD
VDD CLK SCLK DREQ0 DREQ1 EOP DACK0 8237 DACK1 SCLK RDTREQ TDTREQ EOF FDS AM79C940 R/W CS TC DBUS[15:0] IOW CSMACE D[7:0] Q[7:0] '373 C CC ADD[4:0]
ADSTB DB[7:0] A[7:0]
D[7:0] Q[7:0] '373 C CC LATCHHIGHADR D[15:0] A[23:0]
16235C-11
System Interface - Motherboard DMA Example
80
AM79C940
AMD
PC/AT Ethernet Adapter Card
SA19-SA0
Remote Boot PROM I S A B U S
IEEE Address PROM AUI DB15
SD7-SD0
D7-D0 AM79C940 TP RJ45
SD15-SD8
D15-D8
CAM
GPSI/DAI Header
16235C-12
System Interface - Simple PC/AT Ethernet Adapter Card Example
AM79C940
81
AMD
NETWORK INTERFACES External Address Detection Interface (EADI)
The External Address Detection Interface can be used to implement alternative address recognition schemes outside the MACE device, to complement the physical, logical and promiscuous detection supported internally.
EADI Pins SRD SRDCLK SF/BD EAM/R
The address matching, and the support logic necessary to capture and present the relevant data to the external table of address is application specific. Note that since the entire 802.3 packet after SFD is made available, recognition is not limited to the destination address and/or type fields (Ethernet only). Inter-networking protocol recognition can be performed on specific header or LLC information fields.
CAM Programming Interface Databus
74LS595 SER SRCK RCK Q H' QH-A
74LS245 A8-A1
B8-B1
74LS595 SER SRCK RCK Q H' QH-A Logic Block D15-D0 MTCH
74LS245 A8-A1 Databus
B8-B1
Am99C10
16235C-13
EADI Feature - Simple External CAM Interface
82
AM79C940
AMD
Attachment Unit Interface (AUI)
The AUI can drive up to 50 m of standard drop cable to allow the transceiver to be remotely located, as is typically the case in IEEE 803.3 10BASE5 or thick Ethernet(R) installations. For a locally mounted transceiver, such as 802.3 10BASE2 or Cheapernet interface, the isolation transformer requirements between the transceiver and the MACE device can be reduced.
When used with the Am79C98 TPEXTM (Twisted Pair Ethernet Transceiver), the isolation requirements of the AUI are completely removed providing that the transceiver is mounted locally. For remote location of the TPEX via an AUI drop cable, the isolation requirement is necessary to meet IEEE 802.3 specifications for fault tolerance and recovery.
DTE 10BASE5/Ethernet
AUI Cable
MAU
Ethernet Coax
Am7996 Transceiver CPU Memory AM79C940
Tap
Local Bus
Power Supply
16235C-14
AUI-10BASE5/Ethernet Example
10BASE2/Cheapernet
System CPU
Local Memory
AM79C940
Am7996 Transceiver
RG58 BNC "T"
DMA Engine
I/O Bus
Power Supply
Cheapernet Coax
16235C-15
AUI-10BASE2/Cheapernet Example
AM79C940
83
AMD
10BASE-T/Twisted-Pair Ethernet RJ45 Other Slave I/O Device(s) i.e. SCSI
System CPU
Am79C9416 AM79C940 MACE Unshielded Twisted-Pair
I/O Processor
Slave Peripheral Bus
16235C-16
AUI-10BASE-T/Unshielded Twisted-Pair Interface
84
AM79C940
AMD
ANLG +5 V 0.1 F 0.1 F
AVDD
AVSS TXD+ TXP+ TXD- TXP- RXD+ RXD-
ANLG GND
61.9 422 61.9 422 1.21K
Filter & Transformer Module 1:1 XMT Filter Note 1 RCV Filter 1:1
RJ45 Connector
TD+ TD- 1 2
Note 2
100
RD+ 3 RD- 6
DGTL +5 V LNKST LINK OK
RXPOL
RX POL OK
AM79C940
Active Low DXCVR Active High Optional
Note 4 Disable 10BASE2 DC/DC Convertor 10BASE2 MAU
Pulse Transformer DO+ DO- DI+ DI- CI+ CI-
40.2 40.2 40.2 40.2
Note 3
Am7996
COAX TAP (BNC)
See Am7996 Data Sheet for component and implementation details
0.1 F Optional ANLG GND
0.1 F
16235C-17
Notes: 1. Compatible filter modules, with a brief description of package type and features are included in the following section. 2. The resistor values are recommended for general purpose use and should allow compliance to the 10BASE-T specification for template fit and jitter performance. However, the overall performance of the transmitter is also affected by the transmit filter configuration. All resistors are 1%. 3. Compatible AUI transformer modules, with a brief description of package type and features are included in the following section. 4. Active High indicates the external convertor should be turned off. The Disable Transceiver (DXCVR) output is used to indicate the active network port. A high level indicates the 10BASE-T port is selected and the AUI port is disabled. A low level indicates the AUI port is selected and the Twisted Pair interface is disabled. Active Low: indicates the external converter should be turned off. The LNKST output can be used to indicate the active network port. A high level indicates the 10BASE-T port is in the Link Fail state, and the external convertor should be on. A low level indicates the 10BASE-T port is in the Link Pass state, and the external convertor should be off.
10BASE-T and 10BASE2 Configuration of AM79C940 AM79C940 85
AMD
ANLG +5 V 0.1F 0.1F Filter & Transformer Module 1:1
1.21K
AVDD
AVSS TXD+ TXP+ TXD- TXP- RXD+ RXD-
ANLG GND
61.9 422 61.9 422
RJ45 Connector
TD+ TD- 1 2
XMT Filter Note 1 RCV Filter 1:1
Note 2
100
RD+ 3 RD- 6
DGTL +5 V LNKST LINK OK
RXPOL
RX POL OK
AM79C940
DGTL GND Pulse Transformer DO+ DO- DI+ DI- CI+ CI-
40.2 40.2
AUI Connector
3
Note 3
10 5 12 2 9
40.2
40.2
0.1F Optional
Notes:
0.1F ANLG GND
16235C-18
1. Compatible filter modules, with a brief description of package type and features are included in the following section. 2. The resistor values are recommended for general purpose use and should allow compliance to the 10BASE-T specification for template fit and jitter performance. However, the overall performance of the transmitter is also affected by the transmit filter configuration. All resistors are 1%. 3. Compatible AUI transformer modules, with a brief description of package type and features are included in the following section.
10BASE-T and AUI Implementation of AM79C940
86
AM79C940
AMD
MACE Compatible 10BASE-T Filters and Transformers
The table below provides a sample list of MACE compatible 10BASE-T filter and transformer modules available from various vendors. Contact the respective manufacturer for a complete and updated listing of components.
Filters and Transformers Filters Transformers and Choke Filters Transformers Dual Chokes Filters Transformers Resistors Dual Chokes
Manufacturer Bel Fuse Bel Fuse Bel Fuse Bel Fuse Halo Electronics Halo Electronics Halo Electronics PCA Electronics PCA Electronics PCA Electronics Pulse Engineering Pulse Engineering Pulse Engineering Pulse Engineering Valor Electronics Valor Electronics
Part # 0556-2006-00 0556-2006-01 0556-6392-00 FD02-101G FD12-101G FD22-101G EPA1990A EPA2013D EPA2162 PE-65421 PE-65434 PE-65445 PE-65467 PT3877 FL1043
Package 14-pin SIP 14-pin SIP 16-pin 0.5 DIL 16-pin 0.3 DIL 16-pin 0.3 DIL 16-pin 0.3 DIL 16-pin 0.3 DIL 16-pin 0.3 DIL 16-pin 0.3 SIP 16-pin 0.3 DIL 16-pin 0.3 SIL 16-pin 0.3 DIL 12-pin 0.5 SMT 16-pin 0.3 DIL 16-pin 0.3 DIL
A556-2006-DE 16-pin 0.3 DIL
MACE Compatible AUI Isolation Transformers
The table below provides a sample list of MACE compatible AUI isolation transformers available from various vendors. Contact the respective manufacturer for a complete and updated listing of components.
Manufacturer Bel Fuse Bel Fuse Halo Electronics Halo Electronics PCA Electronics Pulse Engineering Pulse Engineering Valor Electronics Valor Electronics Part # A553-0506-AB S553-0756-AE TD01-0756K TG01-0756W EP9531-4 PE64106 PE65723 LT6032 ST7032 Package 16-pin 0.3 DIL 16-pin 0.3 SMD 16-pin 0.3 DIL 16-pin 0.3 SMD 16-pin 0.3 DIL 16-pin 0.3 DIL 16-pin 0.3 SMT 16-pin 0.3 DIL 16-pin 0.3 SMD Description 50 H 75 H 75 H 75 H 50 H 50 H 75 H 75 H 75 H
AM79C940
87
AMD
MACE Compatible DC/DC Converters
The table below provides a sample list of MACE compatible DC/DC converters available from various vendors. Contact the respective manufacturer for a complete and updated listing of components.
Manufacturer Halo Electronics Halo Electronics PCA Electronics PCA Electronics PCA Electronics Valor Electronics Valor Electronics Part # DCU0-0509D DCU0-0509E EPC1007P EPC1054P EPC1078 PM7202 PM7222 Package 24-pin DIP 24-pin DIP 24-pin DIP 24-pin DIP 24-pin DIP 24-pin DIP 24-pin DIP Voltage 5/-9 5/-9 5/-9 5/-9 5/-9 5/-9 5/-9 Remote On/Off No Yes No Yes Yes No Yes
MANUFACTURER CONTACT INFORMATION
Contact the following companies for further information on their products.
Company Bel Fuse Halo Electronics PCA Electronics (HPC in Hong Kong) Pulse Engineering Valor Electronics U.S. and Domestic Phone: FAX: Phone: FAX: Phone: FAX: Phone: FAX: Phone: FAX: (201) 432-0463 (201) 432-9542 (415) 969-7313 (415) 367-7158 (818) 892-0761 (818) 894-5791 (619) 674-8100 (619) 675-8262 (619) 537-2500 (619) 537-2525 Asia 852-328-5515 852-352-3706 65-285-1566 65-284-9466 852-553-0165 852-873-1550 852-425-1651 852-480-5974 852-513-8210 852-513-8214 33-1-44894800 33-1-42051579 353-093-24107 353-093-24459 49-89-6923122 49-89-6926542 Europe 33-1-69410402 33-1-69413320
88
AM79C940
AMD
ABSOLUTE MAXIMUM RATINGS
Storage Temperature . . . . . . . . . . . -65C to +150C Ambient Temperature Under Bias . . . . . . . . . . . . . . . . . . . . . . 0C to +70C Supply Voltage to AVSS or DVss (AVDD, DVDD) . . . . . . . . . . . -0.3 V to +6.0 V
Stresses above those listed under Absolute Maximum Ratings may cause permanent device failure. Functionality at or above these limits is not implied. Exposure to Absolute Maximum Ratings for extended periods may affect device reliability. Programming conditions may differ.
OPERATING RANGES
Commercial (C) Devices Temperature (TA) . . . . . . . . . . . . . . 0C to +70C Supply Voltages (AVDD, DVDD) . . . . . . . . . . . . . . . . . . . . . 5 V 5% All inputs within the range: . . AVDD + 0.5 V Vin . . . . . . . . . . . . . . . . . . . . . . . . . . AVSS - 0.5 V, or . . . . . . . . . . . . . . . . . . . . . . DVDD = 0.5 V Vin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DVSS - 0.5 V
Operating ranges define those limits between which the functionality of the device is guaranteed.
DC CHARACTERISTICS over COMMERCIAL operating ranges unless otherwise specified
Parameter Symbol VIL VIH VILX VIHX VOL VOH IIL1 IIL2 IIH IIAXD IIAXC IILXN IIHXN IILXS IIHXS IOZ VAOD VAODOFF IAODOFF Parameter Description Input LOW Voltage Input HIGH Voltage XTAL1 Input LOW Voltage (External Clock Signal) XTAL1 Input HIGH Voltage (External Clock Signal) Output LOW Voltage Output HIGH Voltage Input Leakage Current Input Leakage Current Input Leakage Current Input Current at DI+ and DI- Input current at CI+ and CI- XTAL1 Input LOW Current during normal operation XTAL1 Input HIGH Current during normal operation XTAL1 Input LOW Current during Sleep XTAL1 Input HIGH Current during Sleep Output Leakage Current Differential Output Voltage |(DO+)-(DO-)| Transmit Differential Output Idle Voltage Transmit Differential Output Idle Current VSS = 0.0 V VSS = 0.0 V IOL = 3.2 mA IOH = -0.4 mA (Note 1) VDD = 5 V, VIN = 0 V (Note 2) VDD = 5 V, VIN = 0 V (Note 2) VDD = 5 V, VIN = 2.7 V (Note 3) -1 V < VIN < AVDD + 0.5 V -1 V < VIN < AVDD + 0.5 V VIN = 0 V SLEEP = HIGH VIN = 5.5 V SLEEP = HIGH VIN = 0 V SLEEP = LOW VIN = 5.5 V SLEEP = LOW 0.4 V < VOUT < VDD (Note 4) RL = 78 RL = 78 (Note 5) RL = 78 -10 630 -40 -1 -500 -500 2.4 -10 -200 10 200 -100 +500 +500 2.0 -0.5 VDD - 0.8 0.8 VDD + 0.5 0.45 Test Conditions Min Max 0.8 Unit V V V V V V A A A A A
-92 92 <10 410 10 1200 +40 +1
A A A A A mV mV mA
AM79C940
89
AMD
DC CHARACTERISTICS over COMMERCIAL operating ranges unless otherwise specified (continued)
Parameter Symbol VAOCM VODI VATH VASQ VIRDVD VICM VOPD Parameter Description DO Common Mode Output Voltage DO Differential Output Voltage Imbalance Receive Data Differential Input Threshold DI and CI Differential Input Threshold Squelch DI and CI Differential Mode Input Voltage Range DI and CI Input Bias Voltage DO Undershoot Voltage at Zero Differential on Transmit Return to Zero (ETD) Power Supply Current Power Supply Current Power Supply Current Power Supply Current IIN = 0 mA (Note 5) AVDD-3.0 Test Conditions RL = 78 RL = 78 (Note 6) RL = 78 (Note 6) Min 2.5 -25 -35 -160 RL = 78 (Note 6) 1.5 AVDD-0.8 -100 V V mV Max AVDD 25 35 -275 Unit V mV mV mV
IDD IDDSLEEP IDDSLEEP IDDSLEEP
SCLK = 25 MHz XTAL1 = 20 MHz SLEEP Asserted, AWAKE = 0 RWAKE = 0 (Note 7) SLEEP Asserted, AWAKE = 1 RWAKE = 0 (Note 7) SLEEP Asserted, AWAKE = 0 RWAKE = 1 (Note 7) AVSS < VIN < AVDD (Note 8) IIN = 0 mA AVDD = +5 V Sinusoid 5 MHz f 10 MHz Sinusoid 5 MHz f 10 MHz Sinusoid 5 MHz f 10 MHz Sinusoid 5 MHz f 10 MHz LRT = LOW LRT = LOW LRT = LOW LRT = LOW -500 10 AVDD - 3.0 -3.1
75 100 10 20
mA A mA mA
Twisted Pair Interface IIRXD RRXD VTIVB VTIDV VTSQ+ VTSQVTHS+ VTHSVLTSQ+ VLTSQVLTHS+ VLTHSInput Current at RXD RXD Differential Input Resistance RXD+, RXD- Open Circuit Input Voltage (Bias) Differential Mode Input Voltage Range (RXD) RXD Positive Squelch Threshold (Peak) RXD Negative Squelch Threshold (Peak) RXD Post-Squelch Positive Threshold (Peak) RXD Post-Squelch Negative Threshold (Peak) RXD Positive Squelch Threshold (Peak) RXD Negative Squelch Threshold (Peak) RXD Post-Squelch Positive Threshold (Peak) RXD Post-Squelch Negative Threshold (Peak) 500 A K AVDD - 1.5 +3.1 V V
300 -520 150 -293 180 -312 90 -156
520 -300 293 -150 312 -180 156 -90
mV mV mV mV mV mV mV mV
90
AM79C940
AMD
DC CHARACTERISTICS over COMMERCIAL operating ranges unless otherwise specified (continued)
Parameter Symbol VRXDTH VTXH VTXL VTXI Parameter Description RXD Switching Threshold TXD and TXP Output HIGH Voltage TXD and TXP Output LOW Voltage TXD and TXP Differential Output Voltage Imbalance TXD and TXP Idle Output Voltage TXD Differential Driver Output Impedance TXP Differential Driver Output Impedance DVDD = +5 V (Note 8) (Note 8) Test Conditions (Note 4) DVSS = 0 V DVDD = +5 V Min -35 DVDD - 0.6 DVSS Max 35 DVDD DVSS + 0.6 Unit mV V V
-40
+40 40 40 80
mV mV
VTXOFF RTX
Notes: 1. VOH does not apply to open-drain output pins. 2. IIL1 and IIL2 applies to all input only pins except DI, CI, and XTAL1. IIL1 = ADD4-0, BE1-0, CS, EAM/R, FDS, RESET, RXDAT, R/W, SCLK. IIL2 = TC, TDI, TCK, TMS. 3. Specified for input only pins with internal pull-ups: TC, TDI, TCK, TMS. 4. IOZ applies to all three-state output pins and bi-directional pins. 5. Test not implemented to data sheet specification. 6. Tested, but to values in excess of limits. Test accuracy not sufficient to allow screening guard bands. 7. During the activation of SLEEP: - - - - - - - The following pins are placed in a high impedance state: SRD, SF/BD, TXDAT, DXCVR, DTV, TDTREQ, RDTREQ, NTR and TDO. The following I/O pins are placed in a high impedance mode and have their internal TTL level translators disabled: DBUS15-0, EOF, SRDCLK, RXCRS, RXDAT, CLSN, TXEN, STDCLK and TXDAT+. The following input pin has its internal pull-up and TTL level translator disabled: TC. The following input pins have their internal TTL level translators disabled and do not have internal pull-ups: CS, FDS, R/W, ADD4-0, SCLK, BE0, BE1 and EAM/R. The following pins are pulled low: XTAL1 (XTAL2 feedback is cut off from XTAL1), TXD+, TXD-, TXP+, TXP-, DO+ and DO. The following pins have their input voltage bias disabled: DI+, DI, CI+ and CI. AWAKE and RWAKE are reset to zero. IDDSLEEP, with either AWAKE set or RWAKE set, will be much higher and its value remains to be determined.
8. Parameter not tested.
AM79C940
91
AMD
AC CHARACTERISTICS
No. 1 2 3 4 5 6 7 Parameter Symbol tSCLK tSCLKL tSCLKH tSCLKR tSCLKF tRST tBT Parameter Description SCLK period SCLK LOW pulse width SCLK HIGH pulse width SCLK rise time SCLK fall time RESET pulse width Network Bit Time (BT) =2*tX1 or tSTDC) XTAL1 period XTAL1 HIGH pulse width XTAL1 LOW pulse width XTAL1 rise time XTAL1 fall time Address valid setup to SCLK Address valid hold after SCLK CS or FDS and TC, BE1-0, R/W setup to SCLK CS or FDS and TC, BE1-0, R/W hold after SCLK Data out valid delay from SCLK Data out valid hold after SCLK DTV valid delay from SCLK DTV valid hold after SCLK EOF valid delay from SCLK EOF output valid hold after SCLK CS inactive prior to SCLK EOF input valid setup to SCLK EOF input valid hold after SCLK RDTREQ valid delay from SCLK RDTREQ valid hold after SCLK TDTREQ valid delay from SCLK TDTREQ valid hold after SCLK Data in valid setup to SCLK Data in valid setup after SCLK Data output enable delay from SCLK (Note 3) Data output disable delay from SCLK (Notes 3, 4) CL = 100 pF (Note 2) 6 9 2 0 25 CL = 100 pF (Note 2) 6 32 CL = 100 pF (Note 2) 6 9 9 2 32 CL = 100 pF (Note 2) 6 32 CL = 100 pF (Note 2) 6 32 9 2 9 2 32 15*tSCLK 99 101 Test Conditions Min (ns) 40 0.4*tSCLK 0.4*tSCLK Max (ns) 1000 0.6*tSCLK 0.6*tSCLK 5 5
Clock and Reset Timing
Internal MENDEC Clock Timing 9 11 12 13 14 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 tX1 tX1H tX1L tX1R tX1F tADDS tADDH tSLVS tSLVH tDATD tDATH tDTVD tDTVH tEOFD tEOFH tCSIS tEOFS tEOFH tRDTD tRDTH tTDTD tTDTH tDATS tDATIH tDATE tDATD 49.995 20 20 5 5 50.005
BIU Timing (Note 1)
Notes: 1. The following BIU timing assumes that EDSEL = 1. Therefore, these parameters are specified with respect to the falling edge of SCLK (SCLK). If EDSEL = 0, the same parameters apply but should be referenced to the rising edge of SCLK (SCLK). 2. Tested with CL set at 100 pF and derated to support the Indicated distributed capacitive Load. See the BIU output valid delay vs. Load Chart. 3. Guaranteed by design--not tested. 4. tDATD is defined as the time required for outputs to turn high impedence and is not referred to as output voltage lead.
92
AM79C940
AMD
AC CHARACTERISTICS (continued)
No. 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 79 80 Parameter Symbol tDOTD tDOTR tDOTF tDOETM tDOETD tPWRDI tPWODI tPWMDI tPWKDI tPWRCI tPWOCI tPWMCI tPWKCI tSQED tSQEL tCLSHI tTXH Parameter Description XTAL1 (externally driven) to DO output DO rise time (10% to 90%) DO fall time (10% to 90%) DO rise and fall mismatch DO End of Transmit Delimiter DI pulse width to reject DI pulse width to turn on internal DI carrier sense DI pulse width to maintain internal DI carrier sense on DI pulse width to turn internal DI carier sense off CI pulse width to reject CI pulse width to turn on internal SQE sense CI pulse width to maintain internal SQE sense on CI pulse width to turn internal SQE sense off CI SQE Test delay from O inactive CI SQE Test length CLSN high time TXEN or DO hold time from CLSN STDCLK delay to TXEN STDCLK delay to TXDAT change TXEN or TXDAT hold time from CLSN Mismatch in STDCLK to TXEN and TXDAT change TXDAT rise time TXDAT fall time TXDAT rise and fall mismatch TXEN End of Transmit Delimiter First RXDAT delay to RXCRS Last RXDAT delay to RXCRS RXCRS delay to CLSN (TXEN = 0) See Note 1 See Note 1 See Note 1 250 |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| |input| > |VASQ| tSTDC+30 32*tSTDC 96*tSTDC 26 26 160 90 45 45 200 10 136 200 2.5 2.5 Test Conditions Min (ns) Max (ns)
AUI Timing 100 5.0 5.0 1 375 15
DAI Port Timing 70 72 80 95 96 97 98 99 100 101 102 tTXEND tTXDD tXH tDOTF tTXDTR tTXDTF tTXDTM tTXENETD tFRXDD tLRXDD tCRSCLSD CL = 50 pF CL = 50 pF 32*tSTDC 70 70 96*tSTDC 15 5 5 1 350 100 120 100
AM79C940
93
AMD
AC CHARACTERISTICS (continued)
No. 17 18 19 20 21 22 23 24 25 26 70 71 72 73 74 75 76 77 78 79 80 81 Parameter Symbol tSTDC tSTDCL tSTDCH tSTDCR tSTDCF tSRDC tSRDCH tSRDCL tSRDCR tSRDCF tTXEND tTXENH tTXDD tTXDH tRXDR tRXDF tRXDH tRXDS tCRSL tCLSHI tTXH tCRSH Parameter Description STDCLK period STDCLK low pulse width STDCLK high pulse width STDCLK rise time STDCLK fall time SRDCLK period SRDCLK HIGH pulse width SRDCLK LOW pulse width SRDCLK rise time SRDCLK fall time STDCLK delay to TXEN TXEN hold time from STDCLK STDCLK delay to TXDAT+ change TXDAT+ hold time from STDCLK RXDAT rise time RXDAT fall time RXDAT hold time (SRDCLK to RXDAT change) RXDAT setup time (RXDAT stable to SRDCLK) RXCRS low time CLSN high time TXEN or TXDAT hold time from CLSN RXCRS hold time from SRDCLK SRDCLK delay to SF/BD SRDCLK delay to SF/BD EAM/R invalid setup prior to SRDCLK after SFD EAM setup to SRDCLK at bit 6 of Source Address byte 1 (match packet) EAM/R low time SF/BD high hold from last SRDCLK EAR setup to SRDCLK at bit 6 of message byte 64 (reject normal packet) -150 0 See Note 1 See Note 1 (CL=50 pF) (CL=50 pF) (CL=50 pF) (CL=50 pF) See Note 1 See Note 1 25 0 tSTDC+20 tSTDC+30 32*tSTDC 0 96*tSTDC 5 8 8 5 70 See Note 1 See Note 1 85 38 38 5 5 70 See Note 1 Test Conditions Min (ns) 99 45 45 5 5 115 Max (ns) 101
GPSI Clock Timing
GPSI Timing
EADI Feature Timing 85 86 87 88 tDSFBDR tDSFBDF tEAMRIS tEAMS 20 20
89 90 91
tEAMRL tSFBDHIH tEARS
200 100 0
Note: 1. Not tested but data available upon request.
94
AM79C940
AMD
AC CHARACTERISTICS (continued)
No. 109 110 111 112 113 114 115 125 126 127 128 129 130 131 132 133 134 135 136 Parameter Symbol tTCLK tsu1 tsu2 thd1 thd2 td1 td2 tTETD tTR tTF tTM tXMTON tXMTOFF tPERLP tPWLP tPWPLP tJA tJR tJREC Parameter Description TCK Period, 50% duty cycle (+5%) TMS setup to TCK TDI setup to TCK TMS hold time from TCK TDI hold time from TCK TCK delay to TDO TCK delay to SYSTEM OUTPUT Min 250 (10% to 90%) (90% to 10%) Max 350 5.5 5.5 1 100 TBD 8 (Note 1) (Note 1) 75 45 20 250 1.0 TBD 24 120 55 150 750 Transmit Start of Idle Transmitter Rise Time Transmitter Fall Time Transmitter Rise and Fall Time Mismatch XMT# Asserted Delay XMT# De-asserted Delay Idle Signal Period Idle Link Pulse Width Predistortion Idle Link Pulse Width Transmit Jabber Activation Time Transmit Jabber Reset Time Transmit Jabber Recovery Time (Minimum Time Gap Between Transmitted Packets to Prevent Jabber Activation) RXD Pulse Width Not to Turn Off Internal Carrier Sense RXD Pulse Width to Turn Off VIN > VTHS (min) Receive Start of Idle RCV# Asserted Delay RCV# De-asserted Delay Test Conditions Min 100 8 5 5 10 30 35 Unit ns ns ns ns ns ms ms ns ns ms ms s Max
IEEE 1149.1 Timing
10BASE-T Transmit Timing
10BASE-T Receive Timing 140 tPWNRD
VIN > VTHS (min)
136 200 200
-
ns ns ns ns ms
141 142 143 144
tPWROFF tRETD tRCVON tRCVOFF
tRON-50 tRON+100 TBD TBD
Note: 1. Not tested but data available upon request.
AM79C940
95
AMD
BIU Output Valid Delay vs. Load Chart
nom+4
nom BIU Output Valid Delay from SCLK (ns) nom-4
nom-8 50 75 100 CL (pF)
16235C-19
125
150
KEY TO SWITCHING WAVEFORMS
WAVEFORM INPUTS Must be Steady May Change from H to L May Change from L to H Don't Care, Any Change Permitted Does Not Apply OUTPUTS Will be Steady Will be Changing from H to L Will be Changing from L to H Changing, State Unknown Center Line is HighImpedance "Off" State
KS000010
96
AM79C940
AMD
SWITCHING TEST CIRCUITS
IOL
Sense Point CL
VTHRESHOLD
IOH
16235C-20
Normal and Three-State Outputs
AVDD
52.3 DO+ DO- 100 pF 154 Test Point
AVSS
16235C-21
AUI DO Switching Test Circuit
DVDD
294 TXD+ TXD- 100 pF Includes Test Jig Capacitance 294 Test Point
DVSS
16235C-22
TXD Switching Test Circuit AM79C940 97
AMD
DVDD
715 TXP+ TXP- 100 pF Includes Test Jig Capacitance 715 Test Point
DVSS
16235C-23
TXP Outputs Test Circuit
AC WAVEFORMS
1 3 SCLK 2
4
5
RESET
6
9 11 12
XTAL1 13 14 16235C-24
Clock and Reset Timing
98
AM79C940
AMD
AC WAVEFORMS
SCLK (EDSEL = 0) SCLK (EDSEL = 1) TL TH S0 S1 S2 S3 S0 S1 S2 S3 S0 S1 S2 S3 S0
TL
TH 31
S0
S1
S2
S3
S0
S1
S2
S3
S0
S1
S2
S3
S0
ADD[4:0] 32 R/W 33 CS or FDS 35 DBUS[15:0] 50 Word N Word N+1 DTV 36 Last Byte or Word 51 34
41
38
EOF
37
40
39 BE0-1 34 TC = 1
16235C-25
Host System Interface--2-Cycle Receive FIFO/Register Read Timing
AM79C940
99
AMD
AC WAVEFORMS
SCLK (EDSEL = 0) SCLK (EDSEL = 1) ADD[4:0] 32 R/W 33 CS or FDS 35 DBUS[15:0] 50 DTV 36 Word N 51 Word N+1 Last Byte or Word 38 TL TH S0 S1 W0 W1 S2 S3 S0 S1 W0 W1 S2 S3 S0 S1 W0 W1 S2 S3 S0
TL TH S0 S1 W0 W1 S2 S3 S0 31
S1 W0 W1 S2
S3 S0
S1 W0 W1 S2 S3 S0
34
41
37 EOF 40
39 BE0-1
TC = 0
34
16235C-26
Host System Interface--3-Cycle Receive FIFO/Register Read Timing
100
AM79C940
AMD
AC WAVEFORMS
SCLK (EDSEL = 0) SCLK (EDSEL = 1)
TL
TH
S0
S1
S2
S3
S0
S1
S2
S3
S0
S1
S2
S3
S0
TL
TH 31
S0
S1
S2
S3
S0
S1
S2
S3
S0
S1
S2
S3
S0
ADD4-0 32 R/W 33 CS or FDS
34
41
DBUS15-0
48 Word N Word N+1 Last Byte or Word 38
DTV
49
37 EOF 42 BE0-1
43
34 TC = 1
16235C-27
Host System Interface--2-Cycle Transmit FIFO/Register Write Timing
AM79C940
101
AMD
AC WAVEFORMS
SCLK (EDSEL = 0) SCLK (EDSEL = 1) TL TH S0 S1 W0 W1 S2 S3 S0 S1 W0 W1 S2 S3 S0 S1 W0 W1 S2 S3 S0
TL TH 31
S0 S1 W0 W1 S2 S3
S0 S1 W0 W1 S2 S3
S0
S1 W0 W1 S2
S3 S0
ADD[4:0] 32 R/W 33 CS 34 41
48 DBUS[15:0] Word N 49 DTV 37 EOF 42 BE0-1 34 TC = 0 Word N+1 Last Byte or Word 38
43
16235C-28
Host System Interface--3-Cycle Transmit FIFO/Register Write Timing
SCLK (EDSEL = 0) SCLK (EDSEL = 1)
S2
S3
S0
S1
S2
S0
S1
S2
S3
S0
S0
S1
S2
S3
S2
S3
S0
S1
S2
S0
S1 40
S2
S3
S0
S0
S1
S2
S3
EOF 44 RDTREQ 39 Note 1
45 16235C-29
Note: Once the host detects the EOF output active from the MACE device (S2/S3 edge), if no other receive packet exists in the RCVFIFO which meets the assert conditions for RDTREQ, the MACE device will deassert RDTREQ within 4 SCLK cycles (S0/S1 edge). This is consistent for both 2 or 3 cycle read operations.
Host System Interface--RDTREQ Read Timing
102
AM79C940
AMD
AC WAVEFORMS
SCLK (EDSEL = 0) SCLK (EDSEL = 1) S1 S2 S3 S0 S1 S2 S3 S0 S1 S2 S3 S0 S1 S2 S3 S0
S1
S2
S3
S0
S1
S2
S3
S0
S1 43
S2
S3
S0
S1
S2
S3
S0
EOF 46 TDTREQ Note 1 47 Note 2 Note 3 42
16235C-30
Notes: 1. TDTREQ will be asserted for two write cycles (4 SCLK cycles) minimum. 2. TDTREQ will deassert 1 SCLK cycle after EOF is detected (S2/S3 edge). 3. When EOF is written, TDTREQ will go inactive for 1 SCLK cycle minimum.
Host System Interface--TDTREQ Write Timing
XTAL1
STDCLK
9
TXEN 1 TXDAT+ (Note 1) 0 54 DO+ 55 1 1 0 1
DO-
1 DO
53 16235C-31
Note: TXDAT+ is the internal version of the signal, and is shown for clarification only.
AUI Transmit Timing--Start of Packet
AM79C940
103
AMD
XTAL1
STDCLK
TXEN 1 TXDAT+ (Note 1) DO+ 1 0 0
DO-
DO 1 bit (n-2) 0 bit (n-1) 0 bit (n) 57
> 200 ns 16235C-32
Note: TXDAT+ is the internal version of the signal, and is shown for clarification only.
AUI Transmit Timing--End of Packet (Last Bit = 0)
XTAL1
SRDCLK
TXEN 1 TXDAT+ (Note 1) DO+ 1 0 1
DO-
DO 1 bit (n-2) 0 bit (n-1) bit (n) 57 > 250 ns 16235C-33
Note: TXDAT+ is the internal version of the signal, and is shown for clarification only.
AUI Transmit Timing--End of Packet (Last Bit = 1)
104
AM79C940
AMD
57
DO
40 mV 100 mV Max
0V
80 Bit Times Max 16235C-34
AUI Transmit Timing--End Transmit Delimiter (ETD)
Bit Cell 1 1 DI 59 (Note 1) 60 VASQ BCC RXCRS BCB BCC BCB BCC BCC BCB BCC BCB Bit Cell 2 0 Bit Cell 3 1 Bit Cell 4 0 Bit Cell 5 1 0
IVCO_ENABLE
IVCO
SRDCLK
5 Bit Times Max
SRD (Note 2) (Note 3) 16235C-35
Notes: 1. Minimum pulse width >45 ns with amplitude > -160 mV. 2. SRD first decoded bit might not be defined until bit time 5. 3. First valid data bit. 4. IVCO and VCO ENABLE are internal signals shown for clarification only.
AUI Receive Timing--Start of Packet AM79C940 105
AMD
Bit Cell (n-1) 1 60 DI VASQ BCC RXCRS (Note 1) BCB BCC BCB Bit Cell (n) 0 61
(Note 2)
IVCO
SRDCLK
SRD
bit (n-1)
bit (n) 16235C-36
Notes: 1. RXCRS deasserts in less than 3 bit times after last DI rising edge. 2. Start of next packet reception (2 bit times). 3. IVCO is an internal signal shown for clarification only.
AUI Receive Timing--End of Packet (Last Bit = 0)
Bit Cell (n-1) 0 Bit Cell (n) 1
DI
61 BCC RXCRS (Note 1) BCB BCC
IVCO
SRDCLK
SRD bit (n-1)
bit (n)
16235C-37
Notes: 1. RXCRS deasserts in less than 3 bit times after last DI rising edge. 2. IVCO is an internal signal shown for clarification only.
AUI Receive Timing--End of Packet (Last Bit = 1) 106 AM79C940
AMD
DO
TXEN
CI+
CI-
80
CLSN
79
16235C-38
AUI Collision Timing
DO
66 CI+
CI-
67
CLSN = 0 16235C-39
AUI SQE Test Timing
AM79C940
107
AMD
STDCLK BCB BCB BCB BCB BCB BCB BCB BCB
72 TXDAT
96 TXDAT+
97
99
95 TXDAT-
72 TXEN
16235C-40
DAI Port Transmit Timing
RXDAT
100
101
RXCRS
16235C-41
DAI Port Receive Timing
108
AM79C940
AMD
TXDAT+
TXDAT-
TXEN
RXDAT
RXCRS
102
CLSN
79 16235C-42
DAI Port Collision Timing
Destination Address Byte 1 SRDCLK Destination Address Byte 2
SRD
SFD
BIT 0
BIT 1
BIT 2
BIT 3
BIT 4
BIT 5 86
BIT 6
BIT 7
BIT 0
SF/BD 85 EAM/R 87 89 16235C-43 Note 1
Note: First assertion of EAM/R must occur after bit 2/3 boundary of preamble.
EADI Feature Timing--Start of Address AM79C940 109
AMD
Last Byte of Message SRDCLK
SRD 86 SF/BD 85 16235C-44 90
EADI Feature--End of Packet Timing
Destination Address Byte 6
Source Address Byte 1
Source Address Byte 2
SRDCLK
SRD
BIT 5
BIT 6
BIT 7
BIT 0
BIT 1
BIT 2 86
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 0
SF/BD 85 EAM 89 88
16235C-45
EADI Feature-Match Timing
110
AM79C940
AMD
Byte 64 (Data Byte 51) SRDCLK
Byte 65 (Data Byte 52)
Byte 66 (Data Byte 53)
SRD
BIT 4
BIT 5
BIT 6
BIT 7
BIT 0
BIT 1 85
BIT 2 86
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 0
BIT 1
SF/BD 91 EAR
89
16235C-46
EADI Feature Reject Timing
17 19 STDCLK 72 TXDAT+ 70 TXEN Note 1 71 73 20 21 18
RXCRS
16235C-47
Note: During transmit, the RXCRS input must be asserted (high) and remain active-high after TXEN goes active (high). If RXCRS is deasserted before TXEN is deasserted, LCAR will be reported (Transmit Frame Status) after the transmission is completed by the MACE device.
GPSI Transmit Timing
AM79C940
111
AMD
22 24 SRDCLK 77 RXDAT 76 RXCRS 81 78 74 75 25 26 23
16235C-48
GPSI Receive Timing
STDCLK 72 TXDAT+ 70 TXEN 80 CLSN 79 73
16235C-49
GPSI Collision Timing
112
AM79C940
AMD
TCK
tsu1 thd1
td1
TMS
tsu2 TDI thd2 TDO
td2
System Output 16235C-50
IEEE 1149.1 TAP Timing
tTR TXD+
tTF tTETD
TXP+
TXD-
TXP- tXMTON TXEN Note 1 tXMTOFF
Note: 1. Parameter is internal to the device.
16235C-51
10BASE-T Transmit Timing
AM79C940
113
AMD
RXD tRCVON RXCRS
VTSQ+ VTSQ- tRCVOFF
16235C-52
10BASE-T Receive Timing
TXD
RXD tCOLON CLSN tCOLOFF
16235C-53
10BASE-T Collision Timing
114
AM79C940
AMD
tPWPLP TXD+
TXP+
TXD-
TXP- tPWLP tPERLP
16235C-54
10BASE-T Idle Link Test Pulse
VTSQ+ VTHS+ RXD VTHS- VTSQ-
16235C-55
10BASE-T Receive Thresholds (LRT = 0)
VLTSQ+ VLTHS+ RXD VLTHS- VLTSQ-
16235C-56
10BASE-T Receive Thresholds (LRT = 1)
AM79C940
115
APPENDIX A
Logical Address Filtering For Ethernet
The purpose of logical (or group or multicast) addresses is to allow a group of nodes in a network to receive the same message. Each node can maintain a list of multicast addresses that it will respond to. The logical address filter mechanism in AMD Ethernet controllers is a hardware aide that reduces the average amount of host computer time required to determine whether or not an incoming packet with a multicast destination address should be accepted. The logical address filter hardware is an implementation of a hash code searching technique commonly used by software programmers. If the multicast bit in the destination address of an incoming packet is set, the hardware maps this address into one of 64 categories then accepts or rejects the packet depending on whether or not the bit in the logical address filter register corresponding the selected category is set. For example, if the address maps into category 24, and bit 24 of the logical address filter register is set, the packet is accepted. Since there are more than 1014 possible multicast addresses and only 64 categories, this scheme is far from unambiguous. This means that the software will still have to compare the address of a received packet with its list of acceptable multicast addresses to make the final decision whether to accept or discard the packet. However, the hardware prevents the software from having to deal with the vast majority of the unacceptable packets. The efficiency of this scheme depends on the number of multicast groups that are used on a particular network and the number of groups to which a node belongs. At one extreme if a node happens to belong to 64 groups that map into 64 different categories, the hardware will accept all multicast addresses, and all filtering must be done by software. At the other extreme (which is closer to a practical network), if multicast addresses are assigned by the local administrator, and fewer than 65 groups are set up, the addresses can be assigned so that each address maps into a different category, and no software filtering will be needed at all. In the latter case described above, a node can be made a member of several groups by setting the appropriate bits in the logical address filter register. The administrator can use the table Mapping of Logical Address to Filter Mask to find a multicast address that maps into a particular address filter bit. For example address 0000 0000 00BB maps into bit 15. Therefore, any node that has bit 15 set in its logical address filter register will receive all packets addressed to 0000 0000 00BB. (Addresses in this table are not shown in the standard Ethernet format. In the table the rightmost byte is the first byte to appear on the network with the least significant bit appearing first). Driver software that manages a list of multicast addresses can work as follows. First the multicast address list and the logical address filter must be initialized. Some sort of management function such as the driver initialization routine passes to the driver a list of addresses. For each address in the list the driver uses a subroutine similar to the one listed in the Am7990 LANCE data sheet to set the appropriate bit in a software copy of the logical address filter register. When the complete list of addresses has been processed, the register is loaded. Later, when a packet is received, the driver first looks at the Individual/Group bit of the destination address of the packet to find out whether or not this is a multicast address. If it is, the driver must search the multicast address list to see if this address is in the list. If it is not in the list, the packet is discarded. The broadcast address, which consists of all ones is a special multicast address. Packets addressed to the broadcast address must be received by all nodes. Since broadcast packets are usually more common than other multicast packets, the broadcast address should be the first address in the multicast address list.
AM79C940
A-1
AMD
MAPPING OF LOGICAL ADDRESS TO FILTER MASK
Byte # 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 3 3 3 3 3 3 3 3 Bit # 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 LADRF Bit 0 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 26 27 28 29 30 31 Destination Address Accepted 85 00 00 00 00 00 A5 00 00 00 00 00 E5 00 00 00 00 00 C5 00 00 00 00 00 45 00 00 00 00 00 65 00 00 00 00 00 25 00 00 00 00 00 05 00 00 00 00 00 2B 00 00 00 00 00 0B 00 00 00 00 00 4B 00 00 00 00 00 6B 00 00 00 00 00 EB 00 00 00 00 00 CB 00 00 00 00 00 8B 00 00 00 00 00 BB 00 00 00 00 00 C7 00 00 00 00 00 E7 00 00 00 00 00 A7 00 00 00 00 00 87 00 00 00 00 00 07 00 00 00 00 00 27 00 00 00 00 00 67 00 00 00 00 00 47 00 00 00 00 00 69 00 00 00 00 00 49 00 00 00 00 00 09 00 00 00 00 00 29 00 00 00 00 00 A9 00 00 00 00 00 89 00 00 00 00 00 C9 00 00 00 00 00 E9 00 00 00 00 00 Byte # 4 4 4 4 4 4 4 4 5 5 5 5 5 5 5 5 6 6 6 6 6 6 6 6 7 7 7 7 7 7 7 7 Bit # 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 LADRF Bit 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 Destination Address Accepted 21 00 00 00 00 00 01 00 00 00 00 00 41 00 00 00 00 00 71 00 00 00 00 00 E1 00 00 00 00 00 C1 00 00 00 00 00 81 00 00 00 00 00 A1 00 00 00 00 00 8F 00 00 00 00 00 BF 00 00 00 00 00 EF 00 00 00 00 00 CF 00 00 00 00 00 4F 00 00 00 00 00 6F 00 00 00 00 00 2F 00 00 00 00 00 0F 00 00 00 00 00 63 00 00 00 00 00 43 00 00 00 00 00 03 00 00 00 00 00 23 00 00 00 00 00 A3 00 00 00 00 00 83 00 00 00 00 00 C3 00 00 00 00 00 E3 00 00 00 00 00 CD 00 00 00 00 00 ED 00 00 00 00 00 AD 00 00 00 00 00 8D 00 00 00 00 00 0D 00 00 00 00 00 2D 00 00 00 00 00 6D 00 00 00 00 00 4D 00 00 00 00 00
A-2
AM79C940
APPENDIX B
BSDL Description of AM79C940 MACE JTAG Structure
entity AM79C940 is generic (PHYSICAL_PIN_MAP : string := "undefined"); port ( DO0,DO1,DTV_L,INTR_L,LNKST_L,DXRCV_L,RDTREQ_L,RXPOL_L,SF_BD,SRD, TDO,TDTREQ_L,TXD0,TXD1,TXDAT0,TXP0,TXP1,XTAL2 : out bit; BE0_L,BE1_L,CI0,CI1,CS_L,DI0,DI1,EAM_R_L,EDSEL,FDS_L,RESET_L,RXD0, RXD1,R_W_L,SCLK,SLEEP_L,TCLK,TC_L,TDI,TMS,XTAL1 : in bit; ADD : in bit_vector (4 downto 0); CLSN,EOF_L,RXCRS,RXDAT,SRDCLK,STDCLK,TXDAT1,TXEN_L : inout bit; DBUS : inout bit_vector (15 downto 0); AVDD1,AVDD2,AVDD3,AVDD4,AVSS1,AVSS2, DVDD1,DVDD2,DVDDN,DVDDP,DVSS1,DVSS2,DVSSN1,DVSSN2,DVSSN3,DVSSP : linkage bit ); use STD_1149_1_1990.all; - get std 1149.1 1990 attributes and definitions
attribute PIN_MAP of AM79C940 : entity is PHYSICAL_PIN_MAP; constant PQFP_PACKAGE : PIN_MAP_STRING := "SRDCLK:5, EAM_R_L:6, SRD:7, SF_BD:8, RESET_L:9, SLEEP_L:10," & "DVDDP:11," & "INTR_L:12, TC_L:13," & "DBUS:(36, 35, 33, 32, 31, 29, 25, 24, 23, 22, 21, 19, 18, 17, 16, 14)," & "DVSSN1:15, DVSSN2:20, DVDDN:34, DVSSN3:37," & "EOF_L:38, DTV_L:39, FDS_L:40, BE0_L:41, BE1_L:42, SCLK:43," & "TDTREQ_L:44, RDTREQ_L:45, ADD: (50, 49, 48, 47, 46)," & "R_W_L:55, CS_L:56, RXPOL_L:57, LNKST_L:58," & "TDO:59, TMS:60, TCK:61," & "DVSS1:62," & "TDI:63," & "DVDD1:64," & "RXD0:65, RXD1:66," & "AVDD1:67," & "TXP0:68, TXD0:69, TXP1:70, TXD1:71," & "AVDD2:72," & "XTAL1:73," & "AVSS1:74," & "XTAL2:75," & "AVSS2:79," & "DO0:81, DO1:82," & "AVDD3:83," & "DI0:84, DI1:85, CI0:86, CI1:87," & "AVDD4:88," & "DVDD2:89," & "DXRCV_L:90, EDSEL:91," & AM79C940 B-1
AMD "DVSS2:92," & "TXDAT1:93, TXDAT0:94," & "DVSSP:95," & "STDCLK:96, TXEN_L:97, CLSN:98, RXDAT:99, RXCRS:100); constant PLCC_PACKAGE : PIN_MAP_STRING := "SRDCLK:12, EAM_R_L:13, SRD:14, SF_BD:15, RESET_L:16, SLEEP_L:17," & "DVDDP:18," & "INTR_L:19, TC_L:20," & "DBUS:(39, 38, 36, 35, 34, 33, 32, 31, 30, 29, 28, 26, 25, 24, 23, 21)," & "DVSSN1:22, DVSSN2:27, DVDDN:37, DVSSN3:39," & "EOF_L:41, DTV_L:42, FDS_L:43, BE0_L:44, BE1_L:45, SCLK:46," & "TDTREQ_L:47, RDTREQ_L:48, ADD: (53, 52, 51, 50, 49)," & "R_W_L:54, CS_L:55, RXPOL_L:56, LNKST_L:57," & "TDO:58, TMS:59, TCK:60," & "DVSS1:61," & "TDI:62," & "DVDD1:63," & "RXD0:64, RXD1:65," & "AVDD1:66," & "TXP0:67, TXD0:68, TXP1:69, TXD1:70," & "AVDD2:71," & "XTAL1:72," & "AVSS1:73," & "XTAL2:74," & "AVSS2:75," & "DO0:76, DO1:77," & "AVDD3:78," & "DI0:79, DI1:80, CI0:81, CI1:82," & "AVDD4:83," & "DVDD2:84," & "DXRCV_L:1, EDSEL:2," & "DVSS2:3," & "TXDAT1:4, TXDAT0:5," & "DVSSP:6," & "STDCLK:7, TXEN_L:8, CLSN:9, RXDAT:10, RXCRS:11); attribute attribute attribute attribute TAP_SCAN_IN of TDI : signal is true; TAP_SCAN_MODE of TMS : signal is true; TAP_SCAN_OUT of TDO : signal is true; TAP_SCAN_CLOCK of TCK : signal is (10.0e6, BOTH);
attribute INSTRUCTION_LENGTH of AM79C940 : entity is 4; attribute INSTRUCTION_OPCODE of AM79C940 : entity is "Extest (0000)," & "Idcode (0001)," & "Sample (0010)," & "Tribyp (0011)," & "Setbyp (0100)," & "Selftst (0101)," & "Bypass (0110, 0111, 1000, 1001, 1010, 1011, 1100, 1101, 1110, 1111)"; attribute INSTRUCTION_CAPTURE of AM79C940 : entity is "0001"; attribute INSTRUCTION_DISABLE of AM79C940 : entity is "Tribyp"; B-2 AM79C940
AMD attribute INSTRUCTION_PRIVATE of AM79C940 : entity is "Selftst"; attribute IDCODE_REGISTER of AM79C940 : entity is "0000" & - 4 bit version "1001010000000000" & - 16 bit part number "00000000001" & - 11 bit manufacturer "1"; - mandatory LSB attribute REGISTER_ACCESS of AM79C940 : entity is "Boundary (Extest, Sample, Selftst)," & "Bypass (Bypass, Tribyp, Setbyp)," & "Idcode (Idcode)"; attribute BOUNDARY_CELL of AM79C940 : entity is "BC_1,BC_4"; attribute BOUNDARY_LENGTH of AM79C940 : entity is 99 - num "98 "97 "96 "95 "94 "93 "92 "91 "90 "89 "88 "87 "86 "85 "84 "83 "82 "81 "80 "79 "78 "77 "76 "75 "74 "73 "72 "71 "70 "69 "68 "67 "66 "65 "64 "63 "62 cell port (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, function safe (ccell disval rslt) *, internal, 0)," & - COL_SQL *, internal, 0)," & - AUI_NSQ *, internal, 0)," & - XMTD *, internal, 0)," & - AUIEN *, internal, 0)," & - TXD0L *, internal, 0)," & - TXP0L *, internal, 0)," & - TXEN *, internal, 0)," & - PSQ_O xor FIXPOL *, internal, 0)," & - CLK20 DXRCV_L, output3, X, 88, 0, Z)," & *, control, 0)," & - TRI PWDNBAR EDSEL, input, 1)," & TXDAT1, input, 1)," & TXDAT1, output3, X, 83, 0, Z)," & TXDAT0, output3, X, 83, 0, Z)," & *, control, 0)," & - TRI TXDAT+/TXDAT- STDCLK, input, 0)," & STDCLK, output3, X, 80, 0, Z)," & *, control, 0)," & - TRI STDCLK TXEN_L, input, 0)," & TXEN_L, output3, X, 77, 0, Z)," & *, control, 0)," & - TRI TXEN_L CLSN, input, 0)," & CLSN, output3, X, 74, 0, Z)," & *, control, 0)," & - TRI CLSN RXDAT, input, 0)," & RXDAT, output3, X, 71, 0, Z)," & *, control, 0)," & - TRI RXDAT RXCRS, input, 0)," & RXCRS, output3, X, 68, 0, Z)," & *, control, 0)," & - TRI RXCRS SRDCLK, input, 0)," & SRDCLK, output3, X, 65, 0, Z)," & *, control, 0)," & - TRI SRDCLK EAM_R, input, 0)," & SRD, output3, X, 61, 0, Z)," & SF_BD, output3, X, 61, 0, Z)," & AM79C940 B-3
AMD "61 "60 "59 "58 "57 "56 "55 "54 "53 "52 "51 "50 "49 "48 "47 "46 "45 "44 "43 "42 "41 "40 "39 "38 "37 "36 "35 "34 "33 "32 "31 "30 "29 "28 "27 "26 "25 "24 "23 "22 "21 "20 "19 "18 "17 "16 "15 "14 "13 "12 "11 "10 "9 B-4 (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_4, (BC_1, (BC_1, (BC_1, (BC_1, *, control, 0)," RESET_L, input, SLEEP_L, input, INTR_L, output3, *, control, 0)," TC_L, input, DBUS(0), input, DBUS(0), output3, X, DBUS(1), input, DBUS(1), output3, X, DBUS(2), input, DBUS(2), output3, X, DBUS(3), input, DBUS(3), output3, X, DBUS(4), input, DBUS(4), output3, X, DBUS(5), input, DBUS(5), output3, X, DBUS(6), input, DBUS(6), output3, X, DBUS(7), input, DBUS(7), output3, X, DBUS(8), input, DBUS(8), output3, X, DBUS(9), input, DBUS(9), output3, X, control, 0)," & DBUS(10), input, DBUS(10), output3, X, DBUS(11), input, DBUS(11), output3, X, DBUS(12), input, DBUS(12), output3, X, DBUS(13), input, DBUS(13), output3, X, DBUS(14), input, DBUS(14), output3, X, DBUS(15), input, DBUS(15), output3, X, *, control, 0)," EOF_L, input, EOF_L, output3, *, control, 0)," DTV_L, output3, *, control, 0)," FDS_L, input, BE0_L, input, BE1_L, input, SCLK, clock, TDTREQ_L, output3, X, RDTREQ_L, output3, X, *, control, 0)," ADD(0), input, AM79C940 & - TRI SF_BD/SRD 1)," & 1)," & 1, 57, 0, Weak1)," & & - TRI INTR_L 1)," & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & 0)," & 35, 0, Z); & - TRI DBUS(9:0) 0)," & 22, 0, Z); & 0)," & 22, 0, Z); & 0)," & 22, 0, Z); & 0)," & 22, 0, Z); & 0)," & 22, 0, Z); & 0)," & 22, 0, Z); & & - TRI DBUS(15:10) 1)," & X, 19, 0, Z); & & - TRI EOF_L X, 17, 0, Z); & & - TRI DTV_L 1)," & 1)," & 1)," & 1)," & 10, 0, Z); & 10, 0, Z); & & - TRI TDTREQ_L/RDTREQ_L 0)," &
*,
AMD "8 "7 "6 "5 "4 "3 "2 "1 "0 (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, (BC_1, ADD(1), ADD(2), ADD(3), ADD(4), R_W_L, CS_L, RXPOL_L, LNKST_L, *, input, input, input, input, input, input, output3, output3, control, X, X, 0)"; 0)," 0)," 0)," 0)," 1)," & & & & &
1)," & 0, 0, Weak1)," & 0, 0, Weak1)," & - TRI RXPOL_L/LNKST_L
end AM79C940
AM79C940
B-5

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