DS33Z11 Ethernet Mapper www.maxim-ic.com GENERAL DESCRIPTION FEATURES The DS33Z11 extends a 10/100 Ethernet LAN segment by encapsulating MAC frames in HDLC or X.86 (LAPS) for transmission over a PDH/TDM data stream. The serial link supports bidirectionalsynchronous interconnect up to 52Mbps over xDSL, T1/E1/J1, T3/E3, V.35/Optical, OC-1/EC-1, or SONET/SDH Tributary. The device performs store-and-forward of packets with full wire-speed transport capability. The built-in Committed Information Rate (CIR) controller provides fractional bandwidth allocation up to the line rate in increments of 512kbps. The DS33Z11 can operate with an inexpensive external processor, EEPROM or in a stand-alone hardware mode. FUNCTIONAL DIAGRAM DS33Z11 TRANSCEIVER/ SERIAL DRIVER SERIAL PORT CONFIG LOADER BERT SDRAM 10/100 MAC MII/RMII 10/100 IEEE 802.3 Ethernet MAC (MII and RMII) Half/Full Duplex with Automatic Flow Control § 52Mbps Synchronous TDM Serial Port with Independent Transmit and Receive Timing § HDLC/LAPS Encapsulation with Programmable FCS and Interframe Fill § Committed Information Rate Controller Provides Fractional Allocations in 512kbps Increments § § § § Programmable BERT for Serial (TDM) Interface § Also Available in a 100-Ball, 10mm CSBGA—the Hardware/SPI Mode-Only DS33ZH11 § § 1.8V Operation with 3.3V Tolerant I/O External 16MB, 100MHz SDRAM Buffering Parallel Microprocessor Interface SPI Interface and Hardware Mode for Operation Without a Host Processor IEEE 1149.1 JTAG Support Feature Highlights continued on page 8. APPLICATIONS PROM OR mC HDLC/X.86 MAPPER § 10/100 ETHERNET PHY Transparent LAN Service LAN Extension Ethernet Delivery Over T1/E1/J1, T3/E3, OC-1/EC-1, G.SHDSL, or HDSL2/4 ORDERING INFORMATION PART TEMP RANGE PIN-PACKAGE DS33Z11 -40°C to +85°C 169 CSBGA DS33ZH11 -40°C to +85°C 100 CSBGA Note: Some revisions of this device may incorporate deviations from published specifications known as errata. Multiple revisions of any device may be simultaneously available through various sales channels. For information about device errata, click here: www.maxim-ic.com/errata. 1 of 169 REV: 021805 DS33Z11 Ethernet Mapper TABLE OF CONTENTS 1 DESCRIPTION .............................................................................................................................. 7 2 FEATURE HIGHLIGHTS ............................................................................................................... 8 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 2.10 2.11 2.12 GENERAL .......................................................................................................................................................8 SERIAL INTERFACE .........................................................................................................................................8 HDLC ...........................................................................................................................................................8 COMMITTED INFORMATION RATE (CIR) CONTROLLER ......................................................................................8 X.86 SUPPORT ..............................................................................................................................................8 SDRAM INTERFACE.......................................................................................................................................9 MAC INTERFACE............................................................................................................................................9 MICROPROCESSOR INTERFACE .......................................................................................................................9 SERIAL SPI INTERFACE—MASTER MODE ONLY ..............................................................................................9 DEFAULT CONFIGURATIONS ............................................................................................................................9 TEST AND DIAGNOSTICS .................................................................................................................................9 SPECIFICATIONS COMPLIANCE ......................................................................................................................10 3 APPLICATIONS........................................................................................................................... 11 4 ACRONYMS AND GLOSSARY................................................................................................... 14 5 MAJOR OPERATING MODES .................................................................................................... 15 6 BLOCK DIAGRAMS .................................................................................................................... 16 7 PIN DESCRIPTIONS ................................................................................................................... 17 7.1 8 PIN FUNCTIONAL DESCRIPTION .....................................................................................................................17 FUNCTIONAL DESCRIPTION..................................................................................................... 29 8.1 PROCESSOR INTERFACE ...............................................................................................................................29 8.1.1 Read-Write/Data Strobe Modes ..........................................................................................................30 8.1.2 Clear on Read .....................................................................................................................................30 8.1.3 Interrupt and Pin Modes......................................................................................................................30 8.2 SPI SERIAL EEPROM INTERFACE................................................................................................................30 8.3 CLOCK STRUCTURE ...............................................................................................................................31 8.3.1 Serial Interface Clock Modes ..............................................................................................................33 8.3.2 Ethernet Interface Clock Modes..........................................................................................................33 8.4 RESETS AND LOW POWER MODES ...............................................................................................................34 8.5 INITIALIZATION AND CONFIGURATION .............................................................................................................35 8.6 GLOBAL RESOURCES ...................................................................................................................................35 8.7 PER-PORT RESOURCES ...............................................................................................................................35 8.8 DEVICE INTERRUPTS ....................................................................................................................................36 8.9 SERIAL INTERFACE .......................................................................................................................................38 8.10 CONNECTIONS AND QUEUES.........................................................................................................................38 8.11 ARBITER ......................................................................................................................................................39 8.12 FLOW CONTROL ...........................................................................................................................................40 8.12.1 Full-Duplex Flow Control.....................................................................................................................41 8.12.2 Half Duplex Flow control .....................................................................................................................42 8.12.3 Host-Managed Flow control ................................................................................................................42 8.13 ETHERNET INTERFACE PORT .....................................................................................................................43 8.13.1 DTE and DCE Mode ...........................................................................................................................45 8.14 ETHERNET MAC ..........................................................................................................................................46 8.14.1 MII Mode Options ................................................................................................................................48 8.14.2 RMII Mode...........................................................................................................................................48 8.14.3 PHY MII Management Block and MDIO Interface...............................................................................49 8.15 BERT..........................................................................................................................................................50 8.15.1 Receive Data Interface........................................................................................................................50 8.15.2 Repetitive Pattern Synchronization .....................................................................................................51 2 of 169 DS33Z11 Ethernet Mapper 8.15.3 Pattern Monitoring...............................................................................................................................52 8.15.4 Pattern Generation..............................................................................................................................52 8.16 TRANSMIT PACKET PROCESSOR ...................................................................................................................53 8.17 RECEIVE PACKET PROCESSOR .....................................................................................................................54 8.18 X.86 ENCODING AND DECODING ...................................................................................................................56 8.19 COMMITTED INFORMATION RATE CONTROLLER..............................................................................................59 8.20 HARDWARE MODE........................................................................................................................................61 9 DEVICE REGISTERS .................................................................................................................. 65 9.1 REGISTER BIT MAPS ....................................................................................................................................66 9.1.1 Global Register Bit Map ......................................................................................................................66 9.1.2 Arbiter Register Bit Map ......................................................................................................................67 9.1.3 BERT Register Bit Map .......................................................................................................................67 9.1.4 Serial Interface Register Bit Map ........................................................................................................68 9.1.5 Ethernet Interface Register Bit Map ....................................................................................................70 9.1.6 MAC Register Bit Map.........................................................................................................................71 9.2 GLOBAL REGISTER DEFINITIONS ...................................................................................................................73 9.3 ARBITER REGISTERS ....................................................................................................................................80 9.3.1 Arbiter Register Bit Descriptions .........................................................................................................80 9.4 BERT REGISTERS .......................................................................................................................................81 9.5 SERIAL INTERFACE REGISTERS .....................................................................................................................88 9.5.1 Serial Interface Transmit and Common Registers ..............................................................................88 9.5.2 Serial Interface Transmit Register Bit Descriptions ............................................................................88 9.5.3 Transmit HDLC Processor Registers..................................................................................................89 9.5.4 X.86 Registers.....................................................................................................................................96 9.5.5 Receive Serial Interface ......................................................................................................................98 9.6 ETHERNET INTERFACE REGISTERS .............................................................................................................111 9.6.1 Ethernet Interface Register Bit Descriptions .....................................................................................111 9.6.2 MAC Registers ..................................................................................................................................123 10 FUNCTIONAL TIMING .............................................................................................................. 139 10.1 FUNCTIONAL SERIAL I/O TIMING .................................................................................................................139 10.2 MII AND RMII INTERFACES .........................................................................................................................140 10.3 SPI INTERFACE MODE AND EEPROM PROGRAM SEQUENCE ......................................................................142 11 OPERATING PARAMETERS .................................................................................................... 144 11.1 11.2 11.3 11.4 11.5 11.6 11.7 11.8 11.9 11.10 11.11 11.12 11.13 12 THERMAL CHARACTERISTICS ......................................................................................................................145 THETA-JA VS. AIRFLOW .............................................................................................................................145 TRANSMIT MII INTERFACE ..........................................................................................................................146 RECEIVE MII INTERFACE ............................................................................................................................147 TRANSMIT RMII INTERFACE ........................................................................................................................148 RECEIVE RMII INTERFACE ..........................................................................................................................149 MDIO INTERFACE ......................................................................................................................................150 TRANSMIT WAN INTERFACE .......................................................................................................................151 RECEIVE WAN INTERFACE .........................................................................................................................152 SDRAM TIMING.........................................................................................................................................153 AC CHARACTERISTICS—MICROPROCESSOR BUS TIMING ............................................................................155 EEPROM INTERFACE TIMING ....................................................................................................................158 JTAG INTERFACE TIMING ...........................................................................................................................159 JTAG INFORMATION ............................................................................................................... 160 12.1 JTAG TAP CONTROLLER STATE MACHINE DESCRIPTION ............................................................................160 12.2 INSTRUCTION REGISTER .............................................................................................................................163 12.2.1 SAMPLE:PRELOAD .........................................................................................................................164 12.2.2 BYPASS............................................................................................................................................164 12.2.3 EXTEST ............................................................................................................................................164 12.2.4 CLAMP..............................................................................................................................................164 12.2.5 HIGHZ ...............................................................................................................................................164 12.2.6 IDCODE ............................................................................................................................................164 3 of 169 DS33Z11 Ethernet Mapper 12.3 12.4 12.5 12.6 12.7 12.8 13 JTAG ID CODES .......................................................................................................................................165 TEST REGISTERS .......................................................................................................................................165 BOUNDARY SCAN REGISTER .......................................................................................................................165 BYPASS REGISTER .....................................................................................................................................165 IDENTIFICATION REGISTER ..........................................................................................................................165 JTAG FUNCTIONAL TIMING ........................................................................................................................165 PACKAGE INFORMATION ....................................................................................................... 167 13.1 PACKAGE OUTLINE DRAWING OF 169-BALL CSBGA (VIEW FROM BOTTOM OF DEVICE) .................................167 13.2 PACKAGE OUTLINE DRAWING OF 100-BALL CSBGA (DS33ZH11 ONLY).....................................................168 14 REVISION HISTORY ................................................................................................................. 169 4 of 169 DS33Z11 Ethernet Mapper LIST OF FIGURES Figure 3-1 Ethernet to WAN Extension (No Framing) ..............................................................................................11 Figure 3-2 Ethernet to WAN Extension (T1E1 Framing and LIU) ............................................................................12 Figure 3-3 Ethernet to WAN Extension with T3/E3 Framing ....................................................................................12 Figure 3-4 Ethernet over DSL ...................................................................................................................................13 Figure 3-5 Copper to Fiber Connection ....................................................................................................................13 Figure 6-1 Detailed Block Diagram...........................................................................................................................16 Figure 7-1 DS33Z11 169-Ball CSBGA Pinout ..........................................................................................................27 Figure 7-2 DS33ZH11 100-Ball CSBGA Pinout (Hardware or SPI Mode Only) .......................................................28 Figure 8-1 Clocking for the DS33Z11 .......................................................................................................................32 Figure 8-2 Device Interrupt Information Flow Diagram.............................................................................................37 Figure 8-3 Flow Control Using Pause Control Frame...............................................................................................42 Figure 8-4 IEEE 802.3 Ethernet Frame ....................................................................................................................43 Figure 8-5 Configured as DTE Connected to an Ethernet PHY in MII Mode............................................................45 Figure 8-6 DS33Z11 Configured as a DCE in MII Mode ..........................................................................................46 Figure 8-7 RMII Interface..........................................................................................................................................48 Figure 8-8 MII Management Frame ..........................................................................................................................49 Figure 8-9 PRBS Synchronization State Diagram ....................................................................................................51 Figure 8-10 Repetitive Pattern Synchronization State Diagram ...............................................................................52 Figure 8-11 LAPS Encoding of MAC Frames Concept.............................................................................................56 Figure 8-12 X.86 Encapsulation of the MAC field.....................................................................................................57 Figure 8-13 CIR in the WAN Transmit Path .............................................................................................................60 Figure 10-1 TX Serial Interface Functional Timing .................................................................................................139 Figure 10-2 RX Serial Interface Functional Timing.................................................................................................139 Figure 10-3 Transmit Byte Sync Functional timing .................................................................................................140 Figure 10-4 Receive Byte Sync Functional Timing .................................................................................................140 Figure 10-5 MII Transmit Functional Timing...........................................................................................................141 Figure 10-6 MII Transmit Half Duplex with a Collision Functional Timing ..............................................................141 Figure 10-7 MII Receive Functional Timing ............................................................................................................141 Figure 10-8 RMII Transmit Interface Functional Timing .........................................................................................141 Figure 10-9 RMII Receive Interface Functional Timing ..........................................................................................142 Figure 10-10 SPI Master Functional Timing ...........................................................................................................142 Figure 11-1 Transmit MII Interface .........................................................................................................................146 Figure 11-2 Receive MII Interface Timing...............................................................................................................147 Figure 11-3 Transmit RMII Interface.......................................................................................................................148 Figure 11-4 Receive RMII Interface Timing ............................................................................................................149 Figure 11-5 MDIO Timing .......................................................................................................................................150 Figure 11-6 Transmit WAN Timing.........................................................................................................................151 Figure 11-7 Receive WAN timing ...........................................................................................................................152 Figure 11-8 SDRAM Interface Timing.....................................................................................................................154 Figure 11-9 Intel Bus Read Timing (HWMODE = 0, MODEC = 00) .......................................................................156 Figure 11-10 Intel Bus Write Timing (HWMODE = 0, MODEC = 00) .....................................................................156 Figure 11-11 Motorola Bus Read Timing (HWMODE = 0, MODEC = 01)..............................................................157 Figure 11-12 Motorola Bus Write Timing (HWMODE = 0, MODEC = 01)..............................................................157 Figure 11-13 EEPROM Interface Timing ................................................................................................................158 Figure 11-14 JTAG Interface Timing Diagram........................................................................................................159 Figure 12-1 JTAG Functional Block Diagram .........................................................................................................160 Figure 12-2 TAP Controller State Diagram.............................................................................................................163 Figure 12-3 JTAG Functional Timing......................................................................................................................166 5 of 169 DS33Z11 Ethernet Mapper LIST OF TABLES Table 2-1 T1-Related Telecommunications Specifications ......................................................................................10 Table 7-1 Detailed Pin Descriptions .........................................................................................................................17 Table 8-1 Clocking Options for the Ethernet Interface .............................................................................................31 Table 8-2 Reset Functions........................................................................................................................................34 Table 8-3 Registers Related to Connections and Queues .......................................................................................39 Table 8-4 Options for Flow Control...........................................................................................................................40 Table 8-5 Registers Related to Setting the Ethernet Port.........................................................................................44 Table 8-6 MAC Control Registers.............................................................................................................................47 Table 8-7 MAC Status Registers ..............................................................................................................................47 Table 8-8 Hardware Mode and Typical Applications ................................................................................................61 Table 8-9 Specific Functional Default Values for Hardware Mode ...........................................................................62 Table 8-10 Hardware Mode Pins ..............................................................................................................................64 Table 9-1 Register Address Map ..............................................................................................................................65 Table 9-2 Global Register Bit Map............................................................................................................................66 Table 9-3 Arbiter Register Bit Map ...........................................................................................................................67 Table 9-4 BERT Register Bit Map ............................................................................................................................67 Table 9-5 Serial Interface Register Bit Map..............................................................................................................68 Table 9-6 Ethernet Interface Register Bit Map .........................................................................................................70 Table 9-7 MAC Indirect Register Bit Map .................................................................................................................71 Table 10-1 EEPROM Program Memory Map .........................................................................................................143 Table 10-2 EEPROM Program Sequence and Example for Indirect MAC Registers.............................................143 Table 11-1 Recommended DC Operating Conditions ............................................................................................144 Table 11-2 DC Electrical Characteristics ................................................................................................................144 Table 11-3 SDRAM Interface Timing......................................................................................................................153 Table 12-1 Instruction Codes for IEEE 1149.1 Architecture ...................................................................................164 Table 12-2 ID Code Structure.................................................................................................................................165 6 of 169 DS33Z11 Ethernet Mapper 1 DESCRIPTION The DS33Z11 provides interconnection and mapping functionality between Ethernet Packet Systems and WAN Time-Division Multiplexed (TDM) systems such as T1/E1/J1, HDSL, and T3/E3. The device is composed of a 10/100 Ethernet MAC, Packet Arbiter, Committed Information Rate controller (CIR), HDLC/X.86 (LAPS) mapper, SDRAM interface, control ports, and bit error-rate tester (BERT). The packet interface consists of an Ethernet interface using several physical-layer protocols. The Ethernet interface can be configured for 10 Mbps or 100 Mbps service. The DS33Z11 encapsulates Ethernet traffic with HDLC or X.86 (LAPS) to be transmitted over the WAN interface. The WAN interface also receives encapsulated Ethernet packets and transmits the extracted packets over the Ethernet port. The WAN physical interface supports a serial data stream up to 52 Mbps. The WAN interface can be seamlessly connected to the Dallas Semiconductor/Maxim T1/E1/J1 framers, line interface units (LIUs), and single-chip transceivers (SCTs). The WAN interface can also be seamlessly connected to the Dallas Semiconductor/Maxim T3/E3/STS-1 framers, LIUs, and SCTs to provide T3, E3, and STS1 connectivity. Refer to Application Note 3411: DS33Z11—Ethernet LAN to Unframed T1/E1 WAN Bridge for an example of a complete LAN to WAN solution. The DS33Z11 is controlled through an 8-bit microcontroller port. A serial EEPROM (SPI) interface and hardware mode are also included for applications without a host processor. The DS33Z11 has a 100MHz SDRAM controller and interfaces to a 32-bit wide 128 Mbit SDRAM. The SDRAM is used to buffer the data from the Ethernet and WAN ports for transport. The external SDRAM can accommodate up to 8192 frames with a maximum frame size of 2016 bytes. Operation without an external host simplifies and reduces the cost of typical applications such as connectivity to T1/T3 and E1/E3 front ends. The DS33Z11 operates with a 1.8V core supply and 3.3V I/O supply. 7 of 169 DS33Z11 Ethernet Mapper 2 2.1 FEATURE HIGHLIGHTS General · · · · · · 2.2 Serial Interface · · · 2.3 One HDLC controller engine Compatible with polled or interrupt driven environments Programmable FCS insertion and extraction Programmable FCS type Supports FCS error insertion Programmable packet size limits (minimum 64 bytes and maximum 2016 bytes) Supports bit stuffing/destuffing 43 Selectable packet scrambling/descrambling (X + 1) Separate FCS errored packet and aborted packet counts Programmable inter-frame fill for transmit HDLC Committed Information Rate (CIR) Controller · · · 2.5 Supports line speeds up to 52 Mbps Supports data enable and gapped clocking Supports byte synchronization input and output for X.86 applications HDLC · · · · · · · · · · 2.4 169-pin CSBGA package (DS33Z11) 100-pin CSBGA package for hardware/SPI modes only (DS33ZH11) 1.8V supply with 3.3V tolerant inputs and outputs IEEE 1149.1 JTAG boundary scan Software access to device ID and silicon revision Development support includes evaluation kit, driver source code, and reference designs CIR rate controller limits transmission of data from the Ethernet interface to the serial interface CIR granularity at 512 kbps CIR Averaging for smoothing traffic peaks X.86 Support · · · · · · · · · · · Programmable X.86 address/control fields for transmit and receive Programmable 2-byte protocol (SAPI) field for transmit and receive 32 bit FCS Transmit Transparency processing—7E is replaced by 7D, 5E Transmit Transparency processing—7D replaced by 7D, 5D Receive rate adaptation (7D, DD) is deleted Receive Transparency processing—7D, 5E is replaced by 7E Receive Transparency processing—7D, 5D is replaced by 7D Receive Abort Sequence the LAPS packet is dropped if 7D7E is detect 43 Self-synchronizing X + 1 payload scrambling. Frame indication due to bad address/control/SAPI, FCS error, abort sequence, or frame size longer than preset max 8 of 169 DS33Z11 Ethernet Mapper 2.6 SDRAM Interface · · · · · · 2.7 MAC Interface · · · · · · · · · · · · 2.8 MAC port with standard MII (less TX_ER) or RMII 10 Mbps and 100 Mbps Data rates Configurable DTE or DCE modes Facilitates auto-negotiation by host microprocessor Programmable half and full-duplex modes Flow control for both half-duplex (back-pressure) and full-duplex (PAUSE) modes Programmable Maximum MAC frame size up to 2016 bytes Minimum MAC frame size: 64 bytes Discards frames greater than Programmed Maximum MAC frame size and Runt, non-octet bounded, or bad-FCS frames upon reception Configurable for promiscuous broadcast-discard mode. Programmable threshold for SDRAM queues to initiate flow control and status indication MAC loopback support for transmit data looped to Receive Data at the MII/RMII interface Microprocessor Interface · · · · 2.9 Interface for 128 Mb, 32-bit wide SDRAM SDRAM Interface speed up to 100 MHz Auto refresh timing Automatic precharge Master clock provided to the SDRAM No external components required for SDRAM connectivity 8-bit data bus Nonmultiplexed Intel and Motorola timing modes Internal software reset and external hardware reset-input pin Global interrupt output pin Serial SPI Interface—Master Mode Only · · · Provides chip select and clock for external EEPROM Operation up to 8.33 MHz 4-signal interface 2.10 Default Configurations · · · Default Hardware Configuration for operation without an external microprocessor Hardware modes set for easy connection to T1/T3 E1/E3 WAN systems Hardware pins provide some flexibility for configuration 2.11 Test and Diagnostics · · · · IEEE 1149.1 support Programmable on-chip BERT Patterns include pseudorandom QRSS, Daly, and user-defined repetitive patterns Loopbacks (remote, local, analog, and per-channel loopback) 9 of 169 DS33Z11 Ethernet Mapper 2.12 Specifications Compliance The DS33Z11 meets relevant telecommunications specifications. The following table provides the specifications and relevant sections that are applicable to the DS33Z11. Table 2-1 T1-Related Telecommunications Specifications IEEE 802.3-2002—CSMA/CD access method and physical layer specifications RFC1662—PPP in HDLC-like framing RFC2615—PPP over SONET/SDH X.86—Ethernet over LAPS RMII—Industry Implementation Agreement for “Reduced MII Interface,” Sept 1997 10 of 169 DS33Z11 Ethernet Mapper 3 APPLICATIONS The DS33Z11 is designed for use in the following applications: § § § Transparent LAN Service LAN Extension Ethernet Delivery Over T1/E1/J1, T3/E3, OC-1/EC-1, G.SHDSL, or HDSL2/4 Refer also to Application Note 3411: DS33Z11—Ethernet LAN to Unframed T1/E1 WAN Bridge for an example of a complete LAN to WAN design. Figure 3-1 Ethernet to WAN Extension (No Framing) HDLC Serial Stream T1/T3 LIU DS21Q48 DS3154 Port RMII, MII 10 Base T 100 Base T DS33Z11 Ethernet Clock Sources SDRAM 11 of 169 DS33Z11 Ethernet Mapper Figure 3-2 Ethernet to WAN Extension (T1E1 Framing and LIU) T1 Framer/LIU DS21Q55 DS26528 Port HDLC Serial Stream RMII, MII 10 Base T 100 Base T DS33Z11 Ethernet Clock Sources SDRAM Figure 3-3 Ethernet to WAN Extension with T3/E3 Framing T3 Framer/LIU DS3154 DS3144 Port HDLC Serial Streams RMII, MII 10 Base T 100 Base T DS33Z11 Ethernet Clock Sources SDRAM 12 of 169 DS33Z11 Ethernet Mapper Figure 3-4 Ethernet over DSL HDLC Serial Streams RMII, MII 10 Base T 100 Base T DSL DS33Z11 Ethernet Clock Sources SDRAM Figure 3-5 Copper to Fiber Connection HDLC Serial Streams Optical I/F & connector Fiber Phy RMII MII DS33Z11 Ethernet Clock Sources SDRAM 13 of 169 DS33Z11 Ethernet Mapper 4 ACRONYMS AND GLOSSARY · · · · · · · · · BERT: Bit Error-Rate Tester DCE: Data Communication Interface DTE: Data Terminating Interface FCS: Frame Check Sequence HDLC: High-Level Data Link Control MAC: Media Access Control MII: Media Independent Interface RMII: Reduced Media Independent Interface WAN: Wide Area Network Note 1: Previous versions of this document used the term “Subscriber” to refer to the Ethernet Interface function. The register names have been allowed to remain with a “SU.” prefix to avoid register renaming. Note 2: Previous versions of this document used the term “Line” to refer to the Serial Interface. The register names have been allowed to remain with a “LI.” prefix to avoid register renaming. Note 3: The terms “Transmit Queue” and “Receive Queue” are with respect to the Ethernet Interface. The Receive Queue is the queue for the data that arrives on the MII/RMII interface, is processed by the MAC and stored in the SDRAM. Transmit queue is for data that arrives from the Serial port, is processed by the HDLC and stored in the SDRAM to be sent to the MAC transmitter. 14 of 169 DS33Z11 Ethernet Mapper 5 MAJOR OPERATING MODES The DS33Z11 has three major modes of operation: microprocessor controlled, EEPROM initialized, and Hardware mode. Microprocessor control is possible through the 8-bit parallel control port. More information on microprocessor control is available in Section 8.1. EEPROM initialization is enabled by the built-in SPI master that reads a serial EEPROM connected to the SPI port after device reset and initializes the device. More information on EEPROM operation is available in Section 8.2. Hardware mode allows configuration of the device without a host microprocessor or EEPROM. More information on Hardware mode is available in Section 8.20. 15 of 169 DS33Z11 Ethernet Mapper 6 BLOCK DIAGRAMS Figure 6-1 Detailed Block Diagram Eprom SPI_SCLK (max 8.33Mhz) 50 or 25 Mhz Oscillator Buffer Dev Div by 1,2,4,10 Output clocks: 50,25 Mhz,2.5 Mhz Microport REF_CLKI TSER TCLKI1 Line 1 RCLKI1 RSER HDLC + Serial Interface TX_CLK1 CIR MAC RMII MII Arbiter RXD RX_CLK1 TXD X.86 MDC 100 Mhz Oscillator JTAG Buffer Dev Div by 2,4,12 Output Clocks 25,50 Mhz SDRAM Interface SDCLKO REF_CLKO 50 or 25 Mhz SDRAM 16 of 169 SYSCLKI DS33Z11 Ethernet Mapper 7 PIN DESCRIPTIONS 7.1 Pin Functional Description Note that all digital pins are IO pins in JTAG mode. This feature increases the effectiveness of board level ATPG patterns. JTAG pins are not available on the Hardware mode/SPI-only DS33ZH11 (10mm CSBGA) Note: I = Input; O = Output; Ipu = Input, with pullup; Oz = Output, with tri-state; IO = Bidirectional pin; IOz = Bidirectional pin, with tri-state Table 7-1 Detailed Pin Descriptions NAME PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) TCLKI F1 B1 TSER F2 A2 TDEN/ TBSYNC TYPE FUNCTION SERIAL INTERFACE IO PINS Serial Interface Transmit Clock Input: The clock reference for TSER, which is output on the rising edge of I the clock. TCLKI supports gapped clocking, up to a maximum frequency of 52 MHz. Transmit Serial Data Output: Output on the rising edge of TCLKI. Selective clock periods can be skipped for O output of TSER dependent on the TDEN settings or gapped clock input (TCLKI). The maximum data rate is 52 Mbps. Transmit Data Enable (Input): The transmit data enable is programmable to selectively block/enable the transmit data. The TDEN signal must occur one clock edge prior to the affected data bit. The active polarity of TDEN is programmable in register LI.TSLCR. It is recommended for both T1/E1 and T3/E3 applications that use gapped clocks. The TDEN signal is provided for interfacing to framers that do not have a gapped clock facility. F5 — IO Transmit Byte Sync (Output): This output can be used by an external Serial to Parallel to convert TSER stream to byte wide data. This output indicates the last bit of the byte data sent serially on TSER. This signal is only active in the X.86 Mode. Note that while in Hardware mode with HDLC (non X.86) operation, this pin must be tied high. RCLKI G2 B2 I RSER H1 B3 I Serial Interface Receive Clock Input: Reference clock for receive serial data on RSER. Gapped clocking is supported, up to the maximum RCLKI frequency of 52 MHz. Receive Serial Data Input: Receive Serial data arrives on the rising edge of the clock. 17 of 169 DS33Z11 Ethernet Mapper NAME PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) TYPE FUNCTION Receive Data Enable: The receive data enable is programmable to block the receive data. The RDEN must be coincident with the RSER data bit to be blocked or enabled. The active polarity of RDEN is programmable in register LI.RSLCR. It is recommended for both T1/E1 and T3/E3 applications that use gapped clocks. The RDEN signal is provided for interfacing to framers that do not have a gapped clock facility. RDEN/ RBSYNC H2 — Receive Byte Synchronization Input: Provides byte synchronization input to X.86 decoder. This signal will go high at the first bit of the byte as it arrives. This signal can occur at maximum rate every 8 bits. Note that a long as the Z11 receives one RBSYNC indicator. The X.86 receiver will determine the byte boundary. Hence the Z11 does not require a continuous 8-bit sync indicator. A new sync pulse is required if the byte boundary changes. I Note that while in Hardware mode with HDLC (non X.86) operation, this pin must be tied high. MII/RMII PORT Reference Clock (RMII and MII): When in RMII mode, all signals from the PHY are synchronous to this clock input for both transmit and receive. This required clock can be up to 50 MHz and should have ±100 ppm accuracy. REF_CLK D13 — I REF_CLKO E13 G10 O TX_CLK A8 A6 IO When in MII mode in DCE operation, the DS33Z11 uses this input to generate the RX_CLK and TX_CLK outputs as required for the Ethernet PHY interface. When the MII interface is used with DTE operation, this clock is not required and should be tied low. Reference Clock Output (RMII and MII): A derived clock output up to 50 MHz, generated by internal division of the SYSCLKI signal. Frequency accuracy of the REF_CLKO signal will be proportional to the accuracy of the usersupplied SYSCLKI signal. This output can be used for the RMII/MII interface clock by external connection to REF_CLK. This capability eliminates the need for an additional 50 MHz (RMII) or 25 MHz (MII) PHY reference oscillator. See Section 8.3.2 for more information. Transmit Clock (MII): Timing reference for TX_EN and TXD[3:0]. The TX_CLK frequency is 25 MHz for 100 Mbps operation and 2.5 MHz for 10 Mbps operation. In DTE mode, this is a clock input provided by the PHY. In DCE mode, this is an output derived from REF_CLK providing 2.5 MHz (10 Mbps operation) or 25 MHz (100 Mbps operation). 18 of 169 DS33Z11 Ethernet Mapper NAME TX_EN PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) E10 B6 TYPE O FUNCTION Transmit Enable (MII): This pin is asserted high when data TXD [3:0] is being provided by the DS33Z11. The signal is deasserted prior to the first nibble of the next frame. This signal is synchronous with the rising edge TX_CLK. It is asserted with the first bit of the preamble. Transmit Enable (RMII): When this signal is asserted, the data on TXD [1:0] is valid. This signal is synchronous to the REF_CLK. TXD[0] B9 A8 TXD[1] C9 B7 TXD[2] D9 B8 TXD[3] E9 A9 O RX_CLK A10 B10 RXD[0] B11 D9 RXD[1] C11 D10 Transmit Data 0 through 3(MII): TXD [3:0] is presented synchronously with the rising edge of TX_CLK. TXD [0] is the least significant bit of the data. When TX_EN is low the data on TXD should be ignored. Transmit Data 0 through 1(RMII): Two bits of data TXD [1:0] presented synchronously with the rising edge of REF_CLK. IO Receive Clock (MII): Timing reference for RX_DV, RX_ERR and RXD[3:0], which are clocked on the rising edge. RX_CLK frequency is 25 MHz for 100 Mbps operation and 2.5 MHz for 10 Mbps operation. In DTE mode, this is a clock input provided by the PHY. In DCE mode, this is an output derived from REF_CLK providing 2.5 MHz (10 Mbps operation) or 25 MHz (100 Mbps operation). Receive Data 0 through 3(MII): Four bits of received data, sampled synchronously with the rising edge of RX_CLK. For every clock cycle, the PHY transfers 4 bits to the DS33Z11. RXD[0] is the least significant bit of the data. Data is not considered valid when RX_DV is low. I RXD[2] D11 C9 RXD[3] A11 C10 RX_DV D10 A10 RX_CRS/ CRS_DV Receive Data 0 through 1(RMII): Two bits of received data, sampled synchronously with REF_CLK with 100 Mbps Mode. Accepted when CRS_DV is asserted. When configured for 10 Mbps Mode, the data is sampled once every 10 clock periods. I Receive Data Valid (MII): This active high signal indicates valid data from the PHY. The data RXD is ignored if RX_DV is not asserted high. Receive Carrier Sense (MII): Should be asserted (high) when data from the PHY (RXD[3:0) is valid. For each clock pulse 4 bits arrive from the PHY. Bit 0 is the least significant bit. In DCE mode, connect to VDD. C8 C8 I Carrier Sense/Receive Data Valid (RMII): This signal is asserted (high) when data is valid from the PHY. For each clock pulse 2 bits arrive from the PHY. In DCE mode, this signal must be grounded. 19 of 169 DS33Z11 Ethernet Mapper NAME RX_ERR PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) B12 B9 TYPE I FUNCTION Receive Error (MII): Asserted by the MAC PHY for one or more RX_CLK periods indicating that an error has occurred. Active High indicates Receive code group is invalid. If CRS_DV is low, RX_ERR has no effect. This is synchronous with RX_CLK. In DCE mode, this signal must be grounded. Receive Error (RMII): Signal is synchronous to REF_CLK. COL_DET B13 — I MDC C12 — O MDIO C13 — IO Collision Detect (MII): Asserted by the MAC PHY to indicate that a collision is occurring. In DCE Mode this signal should be connected to ground. This signal is only valid in half duplex mode, and is ignored in full duplex mode Management Data Clock (MII): Clocks management data between the PHY and DS33Z11. The clock is derived from the REF_CLK, with a maximum frequency is 1.67 MHz. The user must leave this pin unconnected in the DCE Mode. MII Management Data IO (MII): Data path for control information between the PHY and DS33Z11. When not used, pull to logic high externally through a 10kW resistor. The MDC and MDIO pins are used to write or read up to 32 Control and Status Registers in 32 PHY Controllers. This port can also be used to initiate Auto-Negotiation for the PHY. The user must leave this pin unconnected in the DCE Mode. MICRO PORT/SPI Address Bit 0: Address bit 0 of the microprocessor interface. Least Significant Bit A0/BREO A1 Potential future revision to add on ball A5 I BREO (Hardware Mode): Used in Hardware Mode to reverse the ordering of HDLC transmit and receive functions. Active high input. When 0, the first bit received is the MSB. When 1, bit the first bit received is the LSB. The software registers used for control of this function are LI.RPPCL and LI.TPPCL. Address Bit 1: Address bit 1 of the microprocessor interface. A1/SCD B1 Potential future revision to add on ball D8 — SCD (Hardware Mode): Used in Hardware Mode to 43 disable X +1 bit scrambling for both the transmit and receive paths. Applies to HDLC and X.86 transport. When 43 43 1, X +1 scrambling is disabled. When 0, X +1 scrambling is enabled. The software registers used for control of this function are LI.RPPCL and LI.TPPCL. 20 of 169 DS33Z11 Ethernet Mapper NAME PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) TYPE FUNCTION Address Bit 2: Address bit 2 of the microprocessor interface. A2/X86ED A2 Potential future revision to add on ball B4 A3 B2 — — A4 C2 — — A5 A3 — — A6 B3 — — A7 C3 — — A8 A4 — — A9 B4 — — D0/MOSI A5 E8 IOZ — X86ED (Hardware Mode): When in Hardware Mode, setting this pin high enables X.86 encapsulation for both the transmit and receive data. When 0, HDLC encapsulation is used. The register used to control this function in Software Mode is LI.TX86EDE. Address Bit 3: Address bit 3 of the microprocessor interface. Address Bit 4: Address bit 4 of the microprocessor interface. Address Bit 5: Address bit 5 of the microprocessor interface. Address Bit 6: Address bit 6 of the microprocessor interface. Address Bit 7: Address bit 7 of the microprocessor interface. Address Bit 8: Address bit 8 of the microprocessor interface. Address Bit 9: Address bit 9 of the microprocessor interface. Most Significant Bit. Data Bit 0: Bi-directional data bit 0 of the microprocessor interface. Least Significant Bit. Not driven when CS = 1 or RST = 0. Master Out Slave In (SPI Mode): Data stream that provides the instruction and address information to the external EEPROM when in SPI Master Mode. MOSI is updated on the rising edge when CKPHA is set high, and on the falling edge when set low. Data Bit 1: Bidirectional data bit 1 of the microprocessor interface. Not driven when CS = 1 or RST = 0. D1/MISO D2/SPICK A6 A7 E9 E10 IOZ IOZ Master In Slave Out (SPI Mode): Data path from the SPI EEPROM to the DS33Z11. Must be synchronous with SPICK. The Serial EEPROM SPI Interface will provide data to the DS33Z11, MSB first. MISO is sampled on the falling edge when CKPHA is set high, and on the rising edge when set low. Data Bit 2: Bidirectional data bit 2 of the microprocessor interface. Not driven when CS = 1 or RST = 0. SPICK: Provides clocking for SPI transactions. D3 B5 — IOZ Data Bit 3: Bidirectional data bit 3 of the microprocessor interface. Not driven when CS = 1 or RST = 0. D4 B6 — IOZ Data Bit 4: Bidirectional data bit 4 of the microprocessor interface. Not driven when CS = 1 or RST = 0. D5 B7 — IOZ Data Bit 5: Bidirectional data bit 5 of the microprocessor interface. Not driven when CS = 1 or RST = 0. 21 of 169 DS33Z11 Ethernet Mapper PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) D6 C5 — IOZ Data Bit 6: Bidirectional data bit 6 of the microprocessor interface. Not driven when CS = 1 or RST = 0. D7 C6 — IOZ Data Bit 7: Bidirectional data bit 7 of the microprocessor interface. Most Significant Bit. CS = 1 or RST = 0. SPI_CS B8 B5 O Active-Low SPI Chip Select: Provides the chip select to the external EEPROM, when the SPI port is in master mode. NAME CKPHA F6 — TYPE I FUNCTION SPI Clock Phase: MISO is sampled on the falling edge when CKPHA is set high, and on the rising edge when set low. MOSI is updated on the rising edge when CKPHA is set high, and on the falling edge when set low. CS RD/DS WR/RW C1 — I Active-Low Chip Select: This pin must be taken low for read/write operations. When CS is high, the RD/DS and WR signals are ignored. Active-Low Read-Data Strobe (Intel Mode): The DS33Z11 drives the data bus (D0-D7) with the contents of the addressed register while RD and CS are both low. E1 E2 — — I I Active-Low Data Strobe (Motorola Mode): Used to latch data through the microprocessor interface. DS must be low during read and write operations. Active-Low Write (Intel Mode): The DS33Z11 captures the contents of the data bus (D0-D7) on the rising edge of WR and writes them to the addressed register location. CS must be held low during write operations. Read Write (Motorola Mode): Used to indicate read or write operation. RW must be set high for a register read cycle and low for a register write cycle. INT RST HWMODE F3 D8 D5 — C1 A3 OZ Active-Low Interrupt Output: Outputs a logic zero when an unmasked interrupt event is detected. INT is deasserted when all interrupts have been acknowledged and serviced. Inactive state is programmable in register GL.CR1. I Active-Low Reset: An active low signal on this pin resets the internal registers and logic. This pin should remain low until power, SYSCLKI, RX_CLK, and TX_CLK are stable, then set high for normal operation. This input requires a clean edge with a rise time of 25ns or less to properly reset the device. I Hardware Mode: Connect to VDD to place the device in Hardware Mode. MODEC[1:0] determines the default hardware setting to be used. This pin must be held low for control by a microprocessor or an external EEPROM. 22 of 169 DS33Z11 Ethernet Mapper NAME MODEC[0] PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) D6 TYPE Mode Control: Software Mode Options (HWMODE = 0) 00 = Read/Write Strobe Used (Intel Mode) 01 = Data Strobe Used (Motorola Mode) 10 –SPI Master Mode (External EEPROM) 11- Reserved. Do not use. — I MODEC[1] DCEDTES D7 A13 A4 — FUNCTION I Hardware Mode Options (HWMODE = 1) 00 = Default Hardware Mode. See Table 8-8. 01 = Reserved. Do not use. 10 = Reserved. Do not use. 11 = Reserved. Do not use. Note that in the 100-pin CSBGA (DS33ZH11) package, only MODEC[1] is available to the user. MODEC[0] is internally connected to VSS. DCE or DTE Selection: The user must set this pin high for DCE Mode selection or low for DTE Mode. This input affects operation in both software and hardware mode. In DCE Mode, the DS33Z11 MAC port can be directly connected to another MAC. In DCE Mode, the Transmit clock (TX_CLK) and Receive clock (RX_CLK) are output by the DS33Z11. Note that there is no software bit selection of DCEDTES. Note that DCE Mode is only relevant when the MAC interface is in MII mode. RMIIMIIS FULLDS H10S AFCS C4 A9 B10 C10 — — — — I RMII or MII Selection: Set high to configure the MAC for RMII interfacing. Set low for MII interfacing. I Full Duplex Selection (Hardware Mode): When in Hardware Mode, this pin selects full duplex MAC operation when set high. If low, the MAC will operate in half duplex mode. In software mode, this pin has no effect and duplex selection is controlled in the SU.GCR register. I I 100Mb/10Mb (Hardware Mode): When in Hardware Mode, this pin selects the packet PHY data rate. Set high for 100 Mbps. Set low for the MII/RMII interface to run at 10 Mbps. In the software mode this pin has no effect and the rate selection is controlled in the SU.GCR register. Note that in the 100-pin CSBGA (DS33ZH11) package, this pin is internally tied to VDD. Automatic Flow Control (Hardware Mode): When in Hardware Mode, set high to enable automatic flow control pause and backpressure application. In the software mode this pin has no effect and the rate selection is controlled by the SU.GCR register. Note that in the 100-pin CSBGA (DS33ZH11) package, this pin is internally tied to VDD. 23 of 169 DS33Z11 Ethernet Mapper PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) SDATA[0] SDATA[1] SDATA[2] SDATA[3] SDATA[4] SDATA[5] SDATA[6] SDATA[7] SDATA[8] SDATA[9] SDATA[10] SDATA[11] SDATA[12] SDATA[13] SDATA[14] SDATA[15] SDATA[16] SDATA[17] SDATA[18] SDATA[19] SDATA[20] SDATA[21] SDATA[22] SDATA[23] SDATA[24] SDATA[25] SDATA[26] SDATA[27] SDATA[28] SDATA[29] SDATA[30] SDATA[31] M1 L2 N1 M2 N2 N4 N3 L4 J3 M3 H3 J1 J2 K1 K2 L1 M12 H11 M11 N13 N11 L13 N12 K13 J13 J12 H13 H12 G12 F11 G11 L10 H1 F2 J1 D2 K1 K2 J2 C3 D3 E2 C2 F1 G1 D1 D2 E1 K6 G7 J7 K8 K7 J8 H7 K9 J9 H8 H9 C7 G9 G8 G6 C6 SDA[0] N9 J5 SDA[1] N10 K5 SDA[2] L11 H6 SDA[3] K11 F9 SDA[4] L7 C4 SDA[5] L8 H4 SDA[6] L9 G5 SDA[7] L5 G4 SDA[8] M5 F8 SDA[9] M7 F5 SDA[10] M8 H5 SDA[11] N8 K4 NAME TYPE FUNCTION SDRAM CONTROLLER IOZ SDRAM Data Bus (Bits 0 through 31): The 32 pins of the SDRAM data bus are inputs for read operations and outputs for write operations. At all other times, these pins are high-impedance. Note: All SDRAM operations are controlled entirely by the DS33Z11. No user programming for SDRAM buffering is required. O SDRAM Address Bus 0 through 11: The 12 pins of the SDRAM address bus output the row address first, followed by the column address. The row address is determined by SDA0 to SDA11 at the rising edge of clock. Column address is determined by SDA0-SDA9 and SDA11 at the rising edge of the clock. SDA10 is used as an autoprecharge signal. Note: All SDRAM operations are controlled entirely by the DS33Z11. No user programming for SDRAM buffering is required. 24 of 169 DS33Z11 Ethernet Mapper NAME SBA[0] PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) M6 F7 TYPE FUNCTION SDRAM Bank Select: These two bits select 1 of 4 banks for the read/write/precharge operations. I SBA[1] N7 J4 SRAS K6 K3 O SCAS H4 F4 O SWE M4 G3 O SDMASK[0] N6 F3 SDMASK[1] G4 E3 SDMASK[2] M10 J6 SDMASK[3] M9 C5 SDCLKO N5 J3 O (4mA) SYSCLKI G13 K10 I SDCS L6 H3 O O Note: All SDRAM operations are controlled entirely by the DS33Z11. No user programming for SDRAM buffering is required. Active-Low SDRAM Row Address Strobe: Used to latch the row address on rising edge of SDCLKO. It is used with commands for Bank Activate, Precharge, and Mode Register Write. Active-Low SDRAM Column Address Strobe: Used to latch the column address on the rising edge of SDCLKO. It is used with commands for Bank Activate, Precharge, and Mode Register Write. Active-Low SDRAM Write Enable: This output enables write operation and auto precharge. SDRAM Mask 0 through 3: When high, a write is done for that byte. The least significant byte is SDATA7 to SDATA0. The most significant byte is SDATA31 to SDATA24. SDRAM CLK Out: System clock output to the SDRAM. This clock is a buffered version of SYSCLKI. System Clock In: 100MHz System Clock input to the DS33Z11, used for internal operation. This clock is buffered and provided at SDCLKO for the SDRAM interface. The DS33Z11 also provides a divided version output at the REF_CLKO pin. A clock supply with ±100 ppm frequency accuracy is suggested. Active-Low SDRAM Chip Select: This output enables SDRAM access. QUEUE STATUS QOVF C7 — O Queue Overflow: This pin goes high when the transmit or receive queue has overflowed. This pin goes low when the high watermark is reached again. This pin functions in both software and hardware mode. 25 of 169 DS33Z11 Ethernet Mapper NAME PIN # DS33Z11 PIN # DS33ZH11 CSBGA (169) BGA(100) TYPE FUNCTION JTAG INTERFACE JTRST E6 — Ipu Active-Low JTAG Reset: JTRST is used to asynchronously reset the test access port controller. After power-up, a rising edge on JTRST will reset the test port and cause the device IO enter the JTAG DEVICE ID mode. Pulling JTRST low restores normal device operation. JTRST is pulled HIGH internally via a 10kW resistor operation. If boundary scan is not used, this pin should be held low. JTCLK D4 — Ipu JTAG Clock: This signal is used to shift data into JTDI on the rising edge and out of JTDO on the falling edge. JTDO E5 — Oz JTAG Data Out: Test instructions and data are clocked out of this pin on the falling edge of JTCLK. If not used, this pin should be left unconnected. JTDI E4 — Ipu JTAG Data In: Test instructions and data are clocked into this pin on the rising edge of JTCLK. This pin has a 10kW pullup resistor. Ipu JTAG Mode Select: This pin is sampled on the rising edge of JTCLK and is used to place the test access port into the various defined IEEE 1149.1 states. This pin has a 10kW pullup resistor. JTMS F7 — POWER SUPPLIES VDD3.3 VDD1.8 VSS G5–G10, H5–H10 D2, D3, D12, E3, E11, E12, F4, F10, J4, K4, L3, L12, M13 A12, D1, E7, E8, F8, F9, F12, F13, J5–J11, K3, K5, K7, K8, K9, K10, K12 A7, D4– D8, H10 I Connect to 3.3V Power Supply A1, F6, F10, H2, J10 I Connect to 1.8V Power Supply A5, B4, E4–E7 I Connect to the Common Supply Ground 26 of 169 DS33Z11 Ethernet Mapper Figure 7-1 DS33Z11 169-Ball CSBGA Pinout 1 2 3 4 5 6 7 8 9 10 11 12 13 A A0 A2 A5 A8 D0 D1 D2 TX_CLK FULLDS RX_CLK RXD3 VSS DCEDTES B A1 A3 A6 A9 D3 D4 D5 SPI_CS TXD0 H10S RXD0 RX_ERR COL_DET C CS A4 A7 RMIIMIIS D6 D7 QOVF RX_CRS TXD1 AFCS RXD1 MDC MDIO D VSS VDD1.8 VDD1.8 JTCLK HWMODE MODEC0 MODEC1 RST TXD2 RX_DV RXD2 VDD1.8 REF_CLK E RD/DS WR/RW VDD1.8 JTDI JTDO JTRST VSS VSS TXD3 TX_EN VDD1.8 VDD1.8 REF_CLKO F TCLKI TSER INT VDD1.8 TDEN CKPHA JTMS VSS VSS VDD1.8 SDATA29 VSS VSS G N.C. RCLKI N.C. SDMASK1 VDD3 VDD3 VDD3 VDD3 VDD3 VDD3 SDATA30 SDATA28 SYSCLKI H RSER RDEN SDATA10 SCAS VDD3 VDD3 VDD3 VDD3 VDD3 VDD3 SDATA17 SDATA27 SDATA26 J SDATA11 SDATA12 SDATA8 VDD1.8 VSS VSS VSS VSS VSS VSS VSS SDATA25 SDATA24 K SDATA13 SDATA14 VSS VDD1.8 VSS SRAS VSS VSS VSS VSS SDA3 VSS SDATA23 L SDATA15 SDATA1 VDD1.8 SDATA7 SDA7 SDCS SDA4 SDA5 SDA6 SDATA31 SDA2 VDD1.8 SDATA21 M SDATA0 SDATA3 SDATA9 SWE SDA8 SBA0 SDA9 SDA10 SDATA16 VDD1.8 N SDATA2 SDATA4 SDATA6 SDATA5 SDCLKO SDMASK0 SBA1 SDA11 SDATA22 SDATA19 27 of 169 SDMASK3 SDMASK2 SDATA18 SDA0 SDA1 SDATA20 DS33Z11 Ethernet Mapper Figure 7-2 DS33ZH11 100-Ball CSBGA Pinout (Hardware or SPI Mode Only) 1 2 3 4 5 6 7 8 9 10 A VDD1.8 TSER HWMODE MODEC1 VSS (Future A0) TX_CLK VDD3 TXD0 TXD3 RX_DV B TCLKI RCLKI RSER VSS (Future A2) SPI_CS TX_EN TXD1 TXD2 RX_ERR RX_CLK C RST SDATA10 SDATA7 SDA4 SDMASK3 SDATA31 SDATA27 RX_CRS RXD2 RXD3 D SDATA13 SDATA14 SDATA8 VDD3 VDD3 VDD3 VDD3 VDD3 (Future A1) RXD0 RXD1 E SDATA15 SDATA9 SDMASK1 VSS VSS VSS VSS MOSI MISO SPICK F SDATA11 SDATA1 SDMASK0 SCAS SDA9 VDD1.8 SBA0 SDA8 SDA3 VDD1.8 G SDATA12 SDATA3 SWE SDA7 SDA6 SDATA30 SDATA17 SDATA29 SDATA28 REF_CLKO H SDATA0 VDD1.8 SDCS SDA5 SDA10 SDA2 SDATA22 SDATA25 SDATA26 VDD3 J SDATA2 SDATA6 SDCLKO SBA1 SDA0 SDMASK2 SDATA18 SDATA21 SDATA24 VDD1.8 K SDATA4 SDATA5 SRAS SDA11 SDA1 SDATA16 SDATA20 SDATA19 SDATA23 SYSCLKI Note that pins A5, D8, and B4 have been reserved for future device enhancements for addition of the signals A0, A1, and A2. These ball assignments will allow for the potential future revision to be placed in application designed for the initial device and maintain the same functionality. Note that the JTAG pins are not available for use in the DS33ZH11 100-pin package. 28 of 169 DS33Z11 Ethernet Mapper 8 FUNCTIONAL DESCRIPTION The DS33Z11 provides interconnection and mapping functionality between Ethernet Packet Systems and WAN Time-Division Multiplexed (TDM) systems such as T1/E1/J1, HDSL, and T3/E3. The device is composed of a 10/100 Ethernet MAC, Packet Arbiter, Committed Information Rate controller (CIR), HDLC/X.86(LAPS) Mapper, SDRAM interface, control ports, and Bit Error Rate Tester (BERT). The Ethernet Packet interface supports MII and RMII interfaces allowing DSZ33Z11 to connect to commercially available Ethernet PHY and MAC devices. The Ethernet interface can be configured for 10 Mbps or 100 Mbps service, in DTE and DCE configurations. The DS33Z11 MAC interface rejects frames with bad FCS and short frames (less than 64 bytes). Ethernet frames are queued and stored in external 32-bit SDRAM. The DS33Z11 SDRAM controller enables connection to a 128Mbit SDRAM without external glue logic, at clock frequencies up to 100 MHz. The SDRAM is used for both the Transmit and Receive Data Queues. The Receive Queue stores data to be sent from the Packet interface to the WAN interface. The Transmit Queue stores data to be sent from the WAN interface to the Packet interface. The external SDRAM can accommodate up to 8192 frames with a maximum frame size of 2016 bytes. The sizing of the queues can be adjusted by software. The user can also program high and low watermarks for each queue that can be used for automatic or manual flow control. The packet data stored in the SDRAM is encapsulated in HDLC or X.86 (LAPS) to be transmitted over the WAN interface. The device also provides the capability for bit and packet scrambling. The WAN interface also receives encapsulated Ethernet packets and transmits the extracted packets over the Ethernet port. The WAN physical interface supports serial data streams up to 52 Mbps. The WAN serial port can operate with a gapped clock, and can be connected to a framer, electrical LIU, optical transceiver, or T/E-Carrier transceiver for transmission to the WAN. The WAN interface can be seamlessly connected to the Dallas Semiconductor/Maxim T1/E1/J1 framers, LIUs, and SCTs. The WAN interface can also be seamlessly connected to the Dallas Semiconductor/Maxim T3/E3/STS-1 framers, LIUs, and SCTs to provide T3, E3, and STS1 connectivity. The DS33Z11 can be configured through an 8-bit microprocessor interface port. A serial EEPROM (SPI) interface and hardware mode are also included for applications without a host microprocessor. Operation without an external host simplifies and reduces the cost of typical applications such as connectivity to T1/T3 and E1/E3 front ends. The DS33Z11 also provides two on-board clock dividers for the System Clock input and Reference Clock Input for the 802.3 interfaces, further reducing the need for ancillary devices. 8.1 Processor Interface Microprocessor control of the DS33Z11 is accomplished through the 20 interface pins of the microprocessor port. The 8-bit parallel data bus can be configured for Intel or Motorola modes of operation with the two MODEC[1:0] pins. When MODEC[1:0] = 00 and HWMODE = 0, bus timing is in Intel mode, as shown in Figure 11-9 and Figure 11-10. When MODEC[1:0] = 01 and HWMODE = 0, bus timing is in Motorola mode, as shown in Figure 11-11 and Figure 11-12. The address space is mapped through the use of 8 address lines, A0-A7. Multiplexed Mode is not supported on the processor interface. The Chip Select (CS) pin must be brought to a logic low level to gain read and write access to the microprocessor port. With Intel timing selected, the Read (RD) and Write (WR) pins are used to indicate read and write operations and latch data through the interface. With Motorola timing selected, the Read-Write (RW) pin is used to indicate read and write operations while the Data Strobe (DS) pin is used to latch data through the interface. The interrupt output pin (INT) is an open-drain output that will assert a logic-low level upon a number of software maskable interrupt conditions. This pin is normally connected to the microprocessor interrupt input. The register map is shown in Table 9-1. 29 of 169 DS33Z11 Ethernet Mapper 8.1.1 Read-Write/Data Strobe Modes The processor interface can operate in either read-write strobe mode or data strobe mode. When MODEC[1:0] = 00 and HWMODE pin = 0 the read-write strobe mode is enabled and a negative pulse on RD performs a read cycle, and a negative pulse on WR performs a write cycle. When MODEC[1:0] pins = 01 and HWMODE pin = 0 the data strobe mode is enabled and a negative pulse on DS when RW is high performs a read cycle, and a negative pulse on DS when RW is low performs a write cycle. The read-write strobe mode is commonly called the “Intel” mode, and the data strobe mode is commonly called the “Motorola” mode. 8.1.2 Clear on Read The latched status registers will clear on a read access. It is important to note that in a multi-task software environment, the user should handle all status conditions of each register at the same time to avoid inadvertently clearing status conditions. The latched status register bits are carefully designed so that an event occurrence cannot collide with a user read access. 8.1.3 Interrupt and Pin Modes The interrupt (INT) pin is configurable to drive high or float when not active. The INTM bit controls the pin configuration, when it is set the INT pin will drive high when not active. After reset, the INT pin is in high-impedance mode until an interrupt source is active and enabled to drive the interrupt pin. 8.2 SPI Serial EEPROM Interface The SPI interface is a 4 signal serial interface that allows connection to a serial EEPROM for initialization information. The DS33Z11 will act as an SPI Master when configured with MODEC[1:0] to read from an external Serial EEPROM. The reading sequence is commenced upon initial reset or rising edge of the RST input pin. The CKPHA pin controls the sampling and update edges of the MISO and MOSI signals. The MISO data can be sampled on rising or falling edge of SPICK. The MOSI (Master Out Slave In) can be selectively output on the rising or falling edge of SPICK. The SPICK is generated by the DS33Z11 at a frequency of 8.33 MHz. This frequency is derived from an external SYSCLKI (100 MHz). The instruction to initiate a read is 0000x011; this is followed by the address location 0. The SPI_CS is low till the data addressed (Table 10-1) is read and latched. The DS33Z11 will provide the starting address (0000000) and the data is sequentially latched till the last data is read and latched. The MAC specific registers, which are addressed indirectly, are written at the end of the normal control registers. More details of the programming sequence an functional timing information can be found in Section 10.3. The indirect registers related to the MAC are programmed using a special command format as shown in Table 10-2. 30 of 169 DS33Z11 Ethernet Mapper 8.3 CLOCK STRUCTURE The DS33Z11 clocks sources and functions are as follows: · Serial Transmit Data (TCLKI) and Serial Receive Data (RCLKI) clock inputs are used to transfer data from the serial interface. These clocks can be continuous or gapped. · System Clock (SYSCLKI) input. Used for internal operation. This clock input cannot be a gapped clock. A clock supply with ±100 ppm frequency accuracy is suggested. A buffered version of this clock is provided on the SDCLKO pin for the operation of the SDRAM. A divided and buffered version of this clock is provided on the SPICK pin for Serial EEPROM operation. A divided and buffered version of this clock is provided on REF_CLKO for the RMII/MII interface. · Packet Interface Reference clock (REF_CLK) input that can be 25 or 50 MHz. This clock is used as the timing reference for the RMII/MII interface. The user can utilize the built-in REF_CLKO output clock to drive this input. · The Transmit and Receive clocks for the MII Interface (TX_CLK and RX_CLK). In DTE mode, these are input pins and accept clocks provided by an Ethernet PHY. In the DCE mode, these are output pins and will output an internally generated clock to the Ethernet PHY. The output clocks are generated by internal division of REF_CLK. In RMII mode, only the REF_CLK input is used. · REF_CLKO is an output clock that is generated by dividing the 100 MHz System clock (SYSCLKI) by 2 or 4. This output clock can be used as an input to REF_CLK, allowing the user to have one less oscillator for the system. · A Management Data Clock (MDC) output is derived from SYSCLKI and is used for information transfer between the internal Ethernet MAC and external PHY. The MDC clock frequency is 1.67 MHz. The following table provides the different clocking options for the Ethernet interface. Table 8-1 Clocking Options for the Ethernet Interface RMIIMIIS Pin 0 (MII) 0 (MII) 0 (MII) 1 (RMII) 1 (RMII) Speed 10 Mbps 10 Mbps 100 Mbps 10 Mbps 100 Mbps DCE/ DTE REF_CLKO Output DTE 25 MHz DCE 25 MHz DCE 25 MHz - 50 MHz - 50 MHz REF_CLK Input 25 MHz +/- 100 ppm 25 MHz +/- 100 ppm 25 MHz +/- 100 ppm 50 MHz +/- 100 ppm 50 MHz +/- 100 ppm 31 of 169 MDC Output RX_CLK TX_CLK Input from PHY 2.5 MHz (Output) 25 MHz (Output) Input from PHY 2.5 MHz (Output) 25 MHz (Output) Not Applicable Not Applicable 1.67 MHz Not Applicable Not Applicable 1.67 MHz 1.67 MHz 1.67 MHz 1.67 MHz DS33Z11 Ethernet Mapper Figure 8-1 Clocking for the DS33Z11 Eprom SPI_SCLK (max 8.33Mhz) 50 or 25 Mhz Oscillator Buffer Dev Div by 1,2,4,8,10 Output clocks: 50,25 Mhz,2.5 Mhz Microport REF_CLKI TSER TCLKI1 Line 1 RCLKI1 RSER HDLC + Serial Interface TX_CLK1 MAC RMII MII CIR Arbiter RXD RX_CLK1 TXD X.86 MDC 100 Mhz Oscillator JTAG Buffer Dev Div by 2,4,12 Output Clocks 25,50 Mhz SDRAM Interface SDCLKO REF_CLKO 50 or 25 Mhz SDRAM 32 of 169 SYSCLKI DS33Z11 Ethernet Mapper 8.3.1 Serial Interface Clock Modes The Serial Interface timing is determined by the line clocks. Both the transmit and receive clocks (TCLKI and RCLKI) are inputs, and can be gapped. 8.3.2 Ethernet Interface Clock Modes The Ethernet PHY interface has several different clocking requirements, depending on the mode of operation. The user has the option of using the internally generated REF_CLKO output to simplify the system design. Table 8-1 outlines the possible clocking modes for the Ethernet Interface. The buffered REF_CLKO output is generated by division of the 100 MHz system clock input by the user on SYSCLKI. The frequency of the REF_CLKO pin is automatically determined by the DS33Z11 based on the state of the RMIIMIIS pin. The REF_CLKO output can be used as a REF_CLK for the Ethernet Interface by connecting REF_CLKO to REF_CLK. The REF_CLKO function can be turned off with the GL.CR1.RFOO bit. In RMII mode, receive and transmit timing is always synchronous to a 50 MHz clock input on the REF_CLK pin. The source of REF_CLK is expected to be the external PHY. The user has the option of using the 50MHz REF_CLKO output as the timing source for the PHY. More information on RMII mode can be found in Section 8.14.2. While using MII mode with DTE operation, the MII clocks (RX_CLK and TX_CLK) are inputs that are expected to be provided by the external PHY. While using MII mode with DCE operation, the MII clocks (TX_CLK and RX_CLK) are output by the DS33Z11, and are derived from the 25 MHz REF_CLK input. Any 25 MHz reference may be used, but the user may choose to use the REF_CLKO output to avoid adding another system clock. More information on MII mode can be found in Section 8.14.1. 33 of 169 DS33Z11 Ethernet Mapper 8.4 Resets And Low Power Modes The external RST pin and the global reset bit in GL.CR1 create an internal global reset signal. The global reset signal resets the status and control registers on the chip (except the GL.CR1. RST bit) to their default values and resets all the other flops to their reset values. The processor bus output signals are also placed in high-impedance mode when the RST pin is active (low). The global reset bit (GL.CR1. RST) stays set after a one is written to it, but is reset to zero when the external RST pin is active or when a zero is written to it. Allow 5 milliseconds after initiating a reset condition for the reset operation to complete. The Serial Interface reset bit in LI.RSTPD resets all the status and control registers on the Serial interface to their default values, except for the LI.RSTPD.RST bit. The Serial Interface includes the HDLC encoder/decoder, X86 encoder and decoder and the corresponding serial port. The Serial Interface reset bit (LI.RSTPD.RST) stays set after a one is written to it, but is reset to zero when the global reset signal is active or when a zero is written to it. If DS33Z11 is configured to use an external EEPROM, the DS33Z11 will provide the startup sequence to read the device settings upon the rising edge of the external RST pin. When using the external EEPROM the device is configured within 5 ms. This is dependent on an EEPROM clock of 8.33 MHz. The functional timing is provided by Figure 10-10. Table 8-2 Reset Functions RESET FUNCTION LOCATION COMMENTS Hardware Device Reset RST Pin Transition from a logic 0 to a logic 1 resets the device. Hardware JTAG Reset JTRST Pin Resets the JTAG test port. Global Software Reset GL.CR1 Writing to this bit resets the device. Serial interface Reset LI.RSTPD Writing to this bit resets the Serial Interface. Queue Pointer Reset GL.C1QPR Writing to this bit resets the Queue Pointers There are several features in the DS33Z11 to reduce power consumption. The reset bit in the LI.RSTPD and register also place the Serial interface in a low-power mode. Additionally, the RST pin may be held low indefinitely to keep the entire device in a low-power mode. Note that exiting the low-power condition requires re-initialization and configuration. 34 of 169 DS33Z11 Ethernet Mapper 8.5 Initialization and Configuration EXAMPLE DEVICE INITIALIZATION SEQUENCE: STEP 1: Reset the device by pulling the RST pin low or by using the software reset bits outlined in Section 8.4. Clear all reset bits. Allow 5 milliseconds for the reset recovery. STEP 2: Check the Device ID in the GL.IDRL and GL.IDRH registers. STEP 3: Configure the system clocks. Allow the clock system to properly adjust. STEP 4: Initialize the entire remainder of the register space with 00h (or otherwise if specifically noted in the register’s definition), including the reserved bits and reserved register locations. STEP 5: Write FFFFFFFFh to the MAC indirect addresses 010Ch through 010Fh. STEP 6: Setup connection in the GL.CON1 register. STEP 7: Configure the Serial Port register space as needed. STEP 8: Configure the Ethernet Port register space as needed. STEP 9: Configure the Ethernet MAC indirect registers as needed. STEP 10: Configure the external Ethernet PHY through the MDIO interface. STEP 11: Clear all counters and latched status bits. STEP 12: Set the queue size in the Arbiter and reset the queue pointers for the Ethernet and Serial interfaces. STEP 13: Enable Interrupts as needed. STEP 14: Begin handling interrupts and latched status events. 8.6 Global Resources In order to maintain software compatibility with the multiport devices in the product family, a set of Global registers are located at 0F0h-0FFh. The global registers include Global resets, global interrupt status, interrupt masking, clock configuration, and the Device ID registers. See the Global Register Definitions in Table 9-2. 8.7 Per-Port Resources Multi-port devices in this product family share a common set of global registers, BERT, and Arbiter. All other resources are per-port. 35 of 169 DS33Z11 Ethernet Mapper 8.8 Device Interrupts Figure 8-2 diagrams the flow of interrupt conditions from their source status bits through the multiple levels of information registers and mask bits to the interrupt pin. When an interrupt occurs, the host can read the Global Latched Status registers GL.LIS, GL.SIS, GL.BIS, and GL.TRQIS to initially determine the source of the interrupt. The host can then read the LI.TQCTLS, LI.TPPSRL, LI.RPPSRL, LI.RX86S, SU.QCRLS, or BSRL registers to further identify the source of the interrupt(s). In order to maintain software compatibility with the multiport devices in the product family, the global interrupt status and interrupt enable registers have been preserved, but do not need to be used. If GL.TRQIS is determined to be the interrupt source, the host will then read the LI.TPPSRL and LI.RPPSRL registers for the cause of the interrupt. If GL.LIS is determined to be the interrupt source, the host will then read the LI.TQCTLS, LI.TPPSRL, LI.RPPSRL, and LI.RX86S registers for the source of the interrupt. If GL.SIS is the source, the host will then read the SU.QCRLS register for the source of the interrupt. If GL.BIS is the source, the host will then read the BSRL register for the source of the interrupt. All Global Interrupt Status Register bits are real-time bits that will clear once the appropriate interrupt has been serviced and cleared, as long as no additional, enabled interrupt conditions are present in the associated status register. All Latched Status bits must be cleared by the host writing a “1” to the bit location of the interrupt condition that has been serviced. In order for individual status conditions to transmit their status to the next level of interrupt logic, they must be enabled by placing a “1” in the associated bit location of the correct Interrupt Enable Register. The Interrupt enable registers are LI.TPPSRIE, LI.RPPSRIE, LI.RX86LSIE, BSRIE, SU.QRIE, GL.LIE, GL.SIE, GL.BIE, and GL.TRQIE. Latched Status bits that have been enabled via Interrupt Enable registers are allowed to pass their interrupt conditions to the Global Interrupt Status Registers. The Interrupt enable registers allow individual Latched Status conditions to generate an interrupt, but when set to zero, they do not prevent the Latched Status bits from being set. Therefore, when servicing interrupts, the user should AND the Latched Status with the associated Interrupt Enable Register in order to exclude bits for which the user wished to prevent interrupt service. This architecture allows the application host to periodically poll the latched status bits for non-interrupt conditions, while using only one set of registers. Note the bit-orders of SU.QRIE and SU.QCRLS are different. Note that the inactive state of the interrupt output pin is configurable. The INTM bit in GL.CR1 controls the inactive state of the interrupt pin, allowing selection of a pull-up resistor or active driver. The interrupt structure is designed to efficiently guide the user to the source of an enabled interrupt source. The latched status bits for the interrupting entity must be read to clear the interrupt. Also reading the latched status bit will reset all bits in that register. During a reset condition, interrupts cannot be generated. The interrupts from any source can be blocked at a global level by the placing a zero in the global interrupt enable registers (GL.LIE, GL.SIE, GL.BIE, and GL.TRQIE). Reading the Latched Status bit for all interrupt generating events will clear the interrupt status bit and Interrupt signal will be de-asserted. 36 of 169 DS33Z11 Ethernet Mapper <Reserved> SAPI High is not equal to LI.TRX86SAPIH SAPI Low is not equal to LI.TRX86SAPIL Control is not equal to LI.TRX8C Address is not equal to LI.TRX86A <Reserved> <Reserved> <Reserved> <Reserved> Transmit Queue FIFO Overflowed Transmit Queue Overflow Transmit Queue for Connection Exceeded Low Threshold Transmit Queue for Connection Exceeded High Threshold <Reserved> <Reserved> <Reserved> <Reserved> Receive Queue FIFO Overflowed Receive Queue Overflow Receive Queue for Connection Exceeded Low Threshold Receive Queue for Connection Exceeded High Threshold <Reserved> <Reserved> <Reserved> <Reserved> Performance Monitor Update Bit Error Detected Bit Error Count Out Of Synchronization 7 6 5 4 3 2 1 LI.RPPSRIE 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 37 of 169 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 Interrupt Pin <Reserved> 7 6 5 4 3 2 1 0 GL.TRQIE <Reserved> GL.LIE <Reserved> 7 6 5 4 3 2 1 0 GL.SIE Transmit Errored Packet Insertion Finished Register Name GL.BIE <Reserved> Interrupt Enable Registers GL.TRQIS <Reserved> Register Name GL.LIS <Reserved> Interrupt Status Registers GL.SIS <Reserved> Drawing Legend: GL.BIS <Reserved> LI.TPPSRIE <Reserved> 7 6 5 4 3 2 1 0 LI.RX86LSIE <Reserved> LI.TQTIE Receive Size Violation Packet Count SU.QRIE Receive Aborted Packet Count BSRIE Receive FCS Errored Packet Count LI.TPPSRL Receive Large Packet Detected LI.RX86S Receive Small Packet Detected LI.TQCTLS Receive Invalid Packet Detected 7 6 5 4 3 2 1 0 SU.QCRLS Receive Aborted Packet BSRL Receive FCS Errored Packet LI.RPPSL Figure 8-2 Device Interrupt Information Flow Diagram DS33Z11 Ethernet Mapper 8.9 Serial Interface The Serial (WAN) interface supports time-division multiplexed, serial data input and output up to 52 Mbps. The Serial interface receives and transmits encapsulated Ethernet packets. The Serial Interface block consists of the physical serial port and HDLC / X.86 engine. The physical interface consists of a Transmit Data, Transmit Clock, Transmit Enable, Receive Data, Receive Clock, and Receive Enable. The WAN serial port can operate with a gapped clock, and can be connected to a framer, electrical LIU, optical transceiver, or T/E-Carrier transceiver for transmission to the WAN. The WAN interface can be seamlessly connected to the Dallas Semiconductor/Maxim T1/E1/J1 framers, LIUs, and SCTs such as the DS26401, DS21348, and DS2155. The WAN interface can also be seamlessly connected to the Dallas Semiconductor/Maxim T3/E3/STS-1 framers, LIUs, and SCTs such as the DS3144 or DS3154 to provide T3, E3, and STS1 connectivity. 8.10 Connections and Queues The multiport devices in this product family provide bidirectional cross-connections between the multiple Ethernet ports and Serial ports when operating in software mode. A single connection is preserved in this single-port device to provide software compatibility with multi-port devices. The connection will have an associated transmit and receive queue. Note that the terms “Transmit Queue” and “Receive Queue” are with respect to the Ethernet Interface. The Receive queue is for data arriving from Ethernet interface to be transmitted to the WAN interface. The Transmit queue is for data arriving from the WAN to be transmitted to the Ethernet interface. Hence the transmit and receive direction terminology is the same as is used for the Ethernet MAC port. The user can define the connection and the size of the transmit and receive queues. The size is adjustable in units of 32(by 2048 byte) packets. The external SDRAM can hold up to 8192 packets of data. The user must ensure that all the connection queues do no exceed this limit. The user also must ensure that the transmit and receive queues do not overlap each other. Unidirectional connections are not supported. When the user changes the queue sizes, the connection must be torn down and re-established. When a connection is disconnected all transmit and receive queues associated with the connection are flushed and a “1’ is sourced towards the Serial transmit and the HDLC receiver. The clocks to the HDLC are sourced a “0.” The user can also program High and Low watermarks. If the queue size grows past the High watermark, an interrupt is generated if enabled. The registers of relevance are described in Table 8-3. The AR.TQSC1 size provides the size of the transmit queue for the connection. The High Watermark will set a latched status bit. The latched status bit will clear when the register is read. The status bit is indicated by LI.TQCTLS.TQHTS. Interrupts can be enabled on the latched bit events by LI.TQTIE. A latched status bit (LI.TQCTLS.TQLTS) is also set when the queue crosses a low watermark. The Receive Queue functions in a similar manner. Note that the user must ensure that sizes and watermarks are set in accordance with the configuration speed of the Ethernet and Serial interfaces. The DS33Z11 does not provide error indication if the user creates a connection and queue that overwrites data for another connection queue. The user must take care in setting the queue sizes and watermarks. The registers of relevance are AR.RQSC1and SU.QCRLS. Queue size should never be set to 0. 38 of 169 DS33Z11 Ethernet Mapper It is recommended that the user reset the queue pointers for the connection after disconnection. The pointers must be reset before a connection is made. If this disconnect/connect procedure is not followed, incorrect data may be transmitted. The proper procedure for setting up a connection follows: · Set up the queue sizes for both transmit and receive queue (AR.TQSC1 and AR.RQSC1). · Set up the high/low thresholds and interrupt enables if desired (GL.TRQIE, LI.TQTIE, SU.QRIE) · Reset all the pointers for the connection desired (GL.C1QPR) · Set up the connections (GL.CON1) · If a connection is disconnected, reset the queue pointers after the disconnection. Table 8-3 Registers Related to Connections and Queues Register GL.CON1 Enables connection between the Ethernet Interface and the Serial Interface. Note that once connection is set up, then the queues and thresholds can be setup for that connection. AR.TQSC1 Size for the Transmit Queue in Number of 32—2K packets. AR.RQSC1 Size for the Receive Queue in Number of 32—2K packets. GL.TRQIE Interrupt enable for items related to the connections at the global level GL.TRQIS Interrupt enable status for items related to the connections at the global level LI.TQTIE Enables for the Transmit queue crossing high and low thresholds LI.TQCTLS Latched status bits for connection high and low thresholds for the transmit queue. SU.QRIE Enables for the receive queue crossing high and low thresholds SU.QCRLS Latched status bits for receive queue high and low thresholds. GL.C1QPR Resets the connection pointer. 8.11 Arbiter The Arbiter manages the transport between the Ethernet port and the Serial port. It is responsible for queuing and dequeuing packets to a single external SDRAM. The arbiter handles requests from the HDLC and MAC to transfer data to and from the SDRAM. 39 of 169 DS33Z11 Ethernet Mapper 8.12 Flow Control Flow control may be required to ensure that data queues do not overflow and packets are not lost. The DS33Z11 allows for optional flow control based on the queue high watermark or through host processor intervention. There are 2 basic mechanisms that are used for flow control: · In half duplex mode, a jam sequence is sent that causes collisions at the far end. The collisions cause the transmitting node to reduce the rate of transmission. · In full duplex mode, flow control is initiated by the receiving node sending a pause frame. The pause frame has a timer parameter that determines the pause timeout to be used by the transmitting node. Note that the terms “transmit queue” and “receive queue” are with respect to the Ethernet Interface. The Receive Queue is the queue for the data that arrives on the MII/RMII interface, is processed by the MAC and stored in the SDRAM. Transmit queue is for data that arrives from the Serial port, is processed by the HDLC and stored in the SDRAM to be sent to the MAC transmitter. The following flow control options are possible: · Automatic flow control can be enabled in hardware mode by the AFCS and FULLDS pins · Automatic flow control can be enabled in software mode with the SU.GCR.ATFLOW bit. Note that the user does not have control over SU.MACFCR.FCE and FCB bits if ATFLOW is set. The mechanism of sending pause or jam is dependent only on the receive queue high threshold. · Manual flow control can be performed through software when SU.GCR.ATFLOW = 0. The host processor must monitor the receive queues and generate pause frames (full duplex) and/or jam bytes through the SU.MACFCR.FCB, SU.GCR.JAME, and SU.MACFCR.FCE bits. Note that in order to use flow control, the receive queue size (in AR.RQSC1) must be 02h or greater. The receive queue high threshold (in SU.RQHT) must be set to 01h or greater, but must be less than the queue size. If the high threshold is set to the same value as the queue size, automatic flow control will not be effective. The high threshold must always be set to less than the corresponding queue size. The following table provides all the options on flow control mechanism for DS33Z11. Table 8-4 Options for Flow Control Configuration HWMODE Pin AFCS Pin FULLDS Pin ATFLOW Bit JAME Bit FCB Bit (Pause) FCE Bit Pause Timer 1 0 0 N/A HARDWARE MODE Half duplex, Flow control With respect to SU.RQHT 1 1 0 N/A Full duplex, Flow control With respect to SU.RQHT 1 1 1 N/A SOFTWARE MODE N/A N/A N/A Half Duplex; Manual Flow Control Half Duplex; Automatic Flow Control Full Duplex; Manual Flow Control Full Duplex; Automatic Flow Control 0 N/A 0 0 0 N/A 0 1 0 N/A 1 0 0 N/A 1 1 N/A Controlled By User Controlled Automatically N/A N/A N/A Controlled Automatically N/A N/A Controlled by User Controlled Automatically N/A Set to AFCS pin = Low Set to AFCS pin = High Controlled By User Controlled Automatically Controlled By User Controlled Automatically N/A N/A Set to 140h N/A N/A Programmed by User Programmed by User No flow control 40 of 169 DS33Z11 Ethernet Mapper 8.12.1 Full-Duplex Flow Control In the software mode automatic flow control is enabled by default. The host processor can disable this functionality with SU.GCR.ATFLOW. In hardware mode, the user must apply a logic high level to the AFCS pin to enable automatic flow control. The flow control mechanism is governed by the high watermarks (SU.RQHT). The SU.RQLT low threshold can be used as indication that the network congestion is clearing up. The value of SU.RQLT does not affect the flow control. When the connection queue high threshold is exceeded the DS33Z11 will send a pause frame with the timer value programmed by the user. See Table 8-6 for more information. It is recommended that 80 slots (80 by 64 bytes or 5120 bytes) be used as the standard timer value. The pause frame causes the distant transmitter to “pause for a time” before starting transmission again. The pause command has a multicast address 01-80-62-00-00-01. The high and low thresholds for the receive queue are configurable by the user but it is recommended that the high threshold be set approximately 96 packets from the maximum size of the queue and the low threshold 96 packets lower than the high threshold. The DS33Z11 will send a pause frame as the queue has crossed the high threshold and a frame is received. Pause is sent every time a frame is received in the “high threshold state”. Pause control will only take care of temporary congestion. Pause control does not take care of systems where the traffic throughput is too high for the queue sizes selected. If the flow control is not effective the receive queue will eventually overflow. This is indicated by SU.QCRLS.RQOVFL latched bit. If the receive queue is overflowed any new frames will not be received. The user has the option of not enabling automatic flow control. In this case the thresholds and corresponding interrupt mechanism to send pause frame by writing to flow control busy bit in the MAC flow control registers SU.MACFCR.FCB, SU.GCR.JAME, and SU.MACFCR. This allows the user to set not only the watermarks but also to decide when to send a pause frame or not based on watermark crossings. On the receive side the user has control over whether to respond to the pause frame sent by the distant end (PCF bit). Note that if automatic flow control is enabled the user cannot modify the FCE bit in the MAC flow control register. On the Transmit queue the user has the option of setting high and low thresholds and corresponding interrupts. There is no automatic flow control mechanism for data received from the Serial side waiting for transmission over the Ethernet interface during times of heavy Ethernet congestion. 41 of 169 DS33Z11 Ethernet Mapper Figure 8-3 Flow Control Using Pause Control Frame 8 Receive Queue Low Water Rx Data Receive Queue Growth Receive Queue High Water Mark Initiate Flow control 8.12.2 Half Duplex Flow control Half duplex flow control uses a jamming sequence to exert backpressure on the transmitting node. The receiving node jams the first 4 bytes of a packet that are received from the MAC in order to cause collisions at the distant end. In both 100 Mbps and 10 Mbps MII/RMII modes, 4 bytes are jammed upon reception of a new frame. Note that the jamming mechanism does not jam the current frame that is being received during the watermark crossing, but will wait to jam the next frame after the SU.RQHT bit is set. If the queue remains above the high threshold, received frames will continue to be jammed. This jam sequence is stopped when the queue falls below the high threshold. 8.12.3 Host-Managed Flow control Although automatic flow control is recommended, flow control by the host processor is also possible. By utilizing the high watermark interrupts, the host processor can manually issue pause frames or jam incoming packets to exert backpressure on the transmitting node. Pause frames can be initiated with SU.MACFCR.FCB bit. Jam sequences can be initiated be setting SU.GCR.JAME. The host can detect pause frames by monitoring SU.RFSB3.UF and SU.RFSB3.CF. Jammed frames will be indistinguishable from packet collisions. 42 of 169 DS33Z11 Ethernet Mapper 8.13 ETHERNET Interface Port The Ethernet port interface allows for direct connection to an Ethernet PHY. The interface consists of a 10/100 Mbps MII/RMII interface and an Ethernet MAC. In RMII operation, the interface contains 7 signals with a reference clock of 50 MHz. In MII operation, the interface contains 17 signals and a clock reference of 25 MHz. The DS33Z11 can be configured to RMII or MII interface by the Hardware pin RMIIMIIS. The REF_CLKO output can be used to source the REF_CLK input. If the port is configured for MII in DCE mode, REF_CLK must be 25 MHz. The DS33Z11 will internally generate the TX_CLK and RX_CLK outputs (at 25 MHz for 100Mbps, 2.5 MHz for 10Mbps) required for DCE mode from the REF_CLK input. In MII mode with DTE operation, the TX_CLK and RX_CLK signals are generated by the PHY and are inputs to the DS33Z11. For more information on clocking the Ethernet Interface, see Section 8.3. The data received from the MII or RMII interface is processed by the internal IEEE 802.3 complaint Ethernet MAC. The user can select the maximum frame size (up to 2016 bytes) that is received with the SU.RMFSRH and SU.RMFSRL registers. The maximum frame length (in bits) is the number specified in SU.RMFSRH and SU.RMFSRL multiplied by 8. Any programmed value greater than 2016 bytes will result in unpredictable behavior and should be avoided. The maximum frame size is shown in Figure 8-4. The length includes only destination address, source address, VLAN tag (2 bytes), type length field, data and CRC32. The frame size is different than the 802.3 “type length field”. Frames coming from the Ethernet PHY or received from the packet processor are rejected if greater than the maximum frame size specified. Each Ethernet frame sent or received generates status bits (SU.TFSH and SU.TFSL and SU.RFSB0 to SU.RFSB3). These are real time status registers and will change as each frame is sent or received. Hence they are useful to the user only when one frame is sent or received and the status is associated with the frame sent or received. Figure 8-4 IEEE 802.3 Ethernet Frame Preamble SFD Destination Adrs Source Address Type Lenght Data CRC32 7 1 6 6 2 46-1500 4 Max Frame Length The distant end will normally reject the sent frames if jabber timeout, Loss of carrier, excessive deferral, late collisions, excessive collisions, under run, deferred or collision errors occur. Transmission of a frame under any of theses errors will generate a status bit in SU.TFSL, SU.TFSH. The DS33Z11 provides user the option to automatically retransmit the frame if any of the errors have occurred through the bit settings in SU.TFRC. Deferred frames and heartbeat fail have separate resend control bits (SU.TFRC.TFBFCB and SU.TFRC.TPRHBC). If there is no carrier (indicated by the MAC Transmit Packet Status), the transmit queue (data from the Serial Interface to the SDRAM to Ethernet Interface) can be selectively flushed. This is controlled by SU.TFRC.NCFQ. 43 of 169 DS33Z11 Ethernet Mapper The MAC circuitry generates a frame status for every frame that is received. This real time status can be read by SU.RFSB0 to SU.RFSB3. Note the frame status is the “real time” status and hence the value will change as new frames are received. Hence the real time status reflects the status in time and may not correspond to the current received frame being processed. This is also true for the transmitted frames. Frames with errors are usually rejected by the DS33Z11. The user has the option of accepting frames by settings in Receive Frame Rejection Control register (SU.RFRC). The user can program whether to reject or accept frames with the following errors: · MII error asserted during the reception of the frame · Dribbling bits occurred in the frame · CRC error occurred · Length error occurred—the length indicated by the frame length is inconsistent with the number of bytes received · Control frame was received. The mode must be full duplex · Unsupported control frame was received Note that frames received that are runt frames or frames with collision will automatically be rejected. In Hardware Mode any frame received with errors is rejected and any frame transmitted with an error is retransmitted Table 8-5 Registers Related to Setting the Ethernet Port Register Comment SU.TFRC This register determines if the current frame is retransmitted due to various transmit errors SU.TFSL and SU.TFSH These 2 registers provide the real time status of the transmit frame. Only apply to the last frame transmitted. SU.RFSB0 to 3 These registers provide the real time status for the received frame. Only apply to the last frame received. SU.RFRC This register provides settings for reception or rejection of frame based on errors detected by the MAC. SU.RMFSRH and SU.RMFSRL The settings for this register provide the maximum size of frames to be accepted from the MII/RMII receive interface. SU.MACCR This register provides configuration control for the MAC 44 of 169 DS33Z11 Ethernet Mapper 8.13.1 DTE and DCE Mode The Ethernet MII/RMII port can be configured for DCE or DTE Mode. When the port is configured for the DTE Mode it can be connected to an Ethernet PHY. In DCE mode, the port can be connected to MII/RMII MAC devices other than an Ethernet PHY. The DTE/DCE connections for the DS33Z11 in MII mode are shown in the following 2 figures. In DCE Mode, the DS33Z11 transmitter is connected to an external receiver and DS33Z11 receiver is connected to an external MAC transmitter. The selection of DTE or DCE mode is done by the hardware pin DCEDTES. Figure 8-5 Configured as DTE Connected to an Ethernet PHY in MII Mode DS33Z11 Rx Ethernet Phy RXD[3:0] DTE Arbiter WAN MAC RXD[3:0] RXDV RX_CLK RXDV RX_CLK RX_ERR RX_ERR RX_CRS RX_CRS COL_DET COL_DET TXD[3:0] TXD[3:0] TX_CLK TX_CLK TX_EN Rx DCE Tx Tx TX_EN MDIO MDC 45 of 169 MDIO MDC DS33Z11 Ethernet Mapper Figure 8-6 DS33Z11 Configured as a DCE in MII Mode DS33Z11 DTE DCE Rx Tx RXD[3:0] WAN Arbiter MAC Tx TXD[3:0] RXDV RX_CLK TX_EN TX_CLK RX_ERR TX_ERR RX_CRS RX_CRS COL_DET COL_DET TXD[3:0] RXD[3:0] TX_CLK RX_CLK MAC Rx TX_EN MDIO MDC RXDV MDIO MDC 8.14 Ethernet MAC Indirect addressing is required to access the MAC register settings. Writing to the MAC registers requires the SU.MACWD0-3 registers to be written with 4 bytes of data. The address must be written to SU.MACAWL and SU.MACAWH. A write command is issued by writing a zero to SU.MACRWC.MCRW and a one to SU.MACRWC.MCS (MAC command status). MCS is cleared by the DS33Z11 when the operation is complete. Reading from the MAC registers requires the SU.MACRADH and SU.MACRADL registers to be written with the address for the read operation. A read command is issued by writing a one to SU.MACRWC.MCRW and a zero to SU.MACRWC.MCS. SU.MACRWC.MCS is cleared by the DS33Z11 when the operation is complete. After MCS is clear, valid data is available in SU.MACRD0-SU.MACRD3. Note that only one operation can be initiated (read or write) at one time. Data cannot be written or read from the MAC registers until the MCS bit has been cleared by the device. The MAC Registers are detailed in the following table. 46 of 169 DS33Z11 Ethernet Mapper Table 8-6 MAC Control Registers Address Register 0000h-0003h SU.MACCR 0004h-0007h SU.MACAH 0008h-000Bh SU.MACAL 0014h-0017h SU.MACMIIA 0018h-001Bh SU.MACMIID 001Ch-001Fh 0100h-0103h SU.MACFCR SU.MMCCTRL Register Description MAC Control Register. This register is used for programming full duplex, half duplex, promiscuous mode, and back-off limit for half duplex. The transmit and receive enable bits must be set for the MAC to operate. MAC Address High Register. This provides the physical address for this MAC. MAC Address Low Register. This provides the physical address for this MAC. MII Address Register. The address for PHY access through the MDIO interface. MII Data Register. Data to be written to (or read from) the PHY through MDIO interface. Flow Control Register MMC Control Register bit 0 for resetting the status counters Table 8-7 MAC Status Registers Address 0200h-0203h 0204h-0207h 0300h-0303h 0308h-030Bh 030Ch-030Fh 0334h-0337h 0338h-033Bh Register SU.RxFrmCntr SU.RxFrmOKCtr SU.TxFrmCtr SU.TxBytesCtr SU.TxBytesOkCtr SU.TxFrmUndr SU.TxBdFrmsCtr Register Description All Frames Received counter Number of Received Frames that are Good Number of Frames Transmitted Number of Bytes Transmitted Number of Bytes Transmitted with good frames Transmit FIFO underflow counter Transmit Number of Frames Aborted 47 of 169 DS33Z11 Ethernet Mapper 8.14.1 MII Mode Options The Ethernet interface can be configured for MII operation by setting the hardware pin RMIIMIIS low. The MII interface consists of 17 pins. For instructions on clocking the Ethernet Interface while in MII mode, see Section 8.3. Diagrams of system connections for MII operation are shown in Figure 8-5 and Figure 8-6. 8.14.2 RMII Mode The Ethernet interface can be configured for RMII operation by setting the hardware pin RMIIMIIS high. RMII interface operates synchronously from the external 50 MHz reference (REF_CLK). Only 7 signals are required. The following figure shows the RMII architecture. Note that DCE mode is not supported for RMII mode and RMII is valid only for full duplex operation. Figure 8-7 RMII Interface MAC MII to RMII PHY RMII to MII TX_EN TX_EN TXD[1:0] TXD[3:0] TX_EN TXD[3:0] TX_ERR TX_ERR TX_CLK TX_CLK CRS RX_CRS CRS_DV RX_DV RX_DV RXD[1:0] RXD[3:0] RX_CRS REF_CLK RX_ER RX_CLK RX_CLK 48 of 169 DS33Z11 Ethernet Mapper 8.14.3 PHY MII Management Block and MDIO Interface The MII Management Block allows for the host to control up to 32 PHYs, each with 32 registers. The MII block communicates with the external PHY using 2-wire serial interface composed of MDC (serial clock) and MDIO for data. The MDIO data is valid on the rising edge of the MDC clock. The Frame format for the MII Management Interface is shown Figure 8-8. The read/write control of the MII Management is accomplished through the indirect SU.MACMIIA MII Management Address Register and data is passed through the indirect SU.MACMIID Data Register. These indirect registers are accessed through the MAC Control Registers defined in Table 8-6. The MDC clock is internally generated and runs at 1.67 MHz. Figure 8-8 MII Management Frame Preamble Start Opco de 32 bits 2 bits 2 bits READ 111...111 01 10 WRITE 111...111 01 01 5 bits Turn Aroun d 2 bits PHYA[4:0] PHYR[4:0] ZZ ZZZZZZZZZ Z PHYA[4:0] PHYR[4:0] 10 PHYD[15:0] Z Phy Adrs 5 bits Phy Reg 49 of 169 Data Idle 16 bits 1 Bit DS33Z11 Ethernet Mapper 8.15 BERT The BERT can be used for generation and detection of BERT patterns. The BERT is a software programmable test pattern generator and monitor capable of meeting most error performance requirements for digital transmission equipment. The following restrictions are related to the BERT: · The RDEN and TDEN are inputs that can be used to “gap” bits. · BERT will transmit even when the device is set for X.86 mode and TDEN is configured as an output. · The normal traffic flow is halted while the BERT is in operation. · If the BERT is enabled for a Serial port, it will override the normal connection. · If there is a connection overridden by the BERT, when BERT operation is terminated the normal operation is restored. The transmit direction generates the programmable test pattern, and inserts the test pattern payload into the data stream. The receive direction extracts the test pattern payload from the receive data stream, and monitors the test pattern payload for the programmable test pattern. BERT Features · · · · 9 15 23 PRBS and QRSS patterns of 2 -1, 2 -1 2 -1 and QRSS pattern support Programmable repetitive pattern. The repetitive pattern length and pattern are programmable n (length n = 1 to 32 and pattern = 0 to (2 – 1)). 24-bit error count and 32-bit bit count registers Programmable bit error insertion. Errors can be inserted individually 8.15.1 Receive Data Interface 8.15.1.1 Receive Pattern Detection The Receive BERT receives only the payload data and synchronizes the receive pattern generator to the incoming pattern. The receive pattern generator is a 32-bit shift register that shifts data from the least significant bit (LSB) or bit 1 to the most significant bit (MSB) or bit 32. The input to bit 1 is the feedback. For a PRBS pattern (generating n y polynomial x + x + 1), the feedback is an XOR of bit n and bit y. For a repetitive pattern (length n), the feedback is bit n. The values for n and y are individually programmable (1 to 32). The output of the receive pattern generator is the feedback. If QRSS is enabled, the feedback is an XOR of bits 17 and 20, and the output is forced to one if the next 14 bits are all zeros. QRSS is programmable (on or off). For PRBS and QRSS patterns, the feedback is forced to one if bits 1 through 31 are all zeros. Depending on the type of pattern programmed, pattern detection performs either PRBS synchronization or repetitive pattern synchronization. 8.15.1.2 PRBS Synchronization PRBS synchronization synchronizes the receive pattern generator to the incoming PRBS or QRSS pattern. The receive pattern generator is synchronized by loading 32 data stream bits into the receive pattern generator, and then checking the next 32 data stream bits. Synchronization is achieved if all 32 bits match the incoming pattern. If at least is incoming bits in the current 64-bit window do not match the receive pattern generator, automatic pattern resynchronization is initiated. Automatic pattern resynchronization can be disabled. 50 of 169 DS33Z11 Ethernet Mapper Figure 8-9 PRBS Synchronization State Diagram Sync f6 err ors 6o 32 ors err ith bi t sw ith w its out 4b 1 bit error Verify Load 32 bits loaded 8.15.2 Repetitive Pattern Synchronization Repetitive pattern synchronization synchronizes the receive pattern generator to the incoming repetitive pattern. The receive pattern generator is synchronized by searching each incoming data stream bit position for the repetitive pattern, and then checking the next 32 data stream bits. Synchronization is achieved if all 32 bits match the incoming pattern. If at least sis incoming bits in the current 64-bit window do not match the receive PRBS pattern generator, automatic pattern resynchronization is initiated. Automatic pattern resynchronization can be disabled. 51 of 169 DS33Z11 Ethernet Mapper Figure 8-10 Repetitive Pattern Synchronization State Diagram Sync f6 err ors 6o 32 ors err ith bi t sw ith w its out 4b 1 bit error Verify Match Pattern Matches 8.15.3 Pattern Monitoring Pattern monitoring monitors the incoming data stream for Out Of Synchronization (OOS) condition, bit errors, and counts the incoming bits. An OOS condition is declared when the synchronization state machine is not in the “Sync” state. An OOS condition is terminated when the synchronization state machine is in the “Sync” state. Bit errors are determined by comparing the incoming data stream bit to the receive pattern generator output. If they do not match, a bit error is declared, and the bit error and bit counts are incremented. If they match, only the bit count is incremented. The bit count and bit error count are not incremented when an OOS condition exists. 8.15.4 Pattern Generation Pattern Generation generates the outgoing test pattern, and passes it onto Error Insertion. The transmit pattern generator is a 32-bit shift register that shifts data from the least significant bit (LSB) or bit 1 to the most significant n y bit (MSB) or bit 32. The input to bit 1 is the feedback. For a PRBS pattern (generating polynomial x + x + 1), the feedback is an XOR of bit n and bit y. For a repetitive pattern (length n), the feedback is bit n. The values for n and y are individually programmable. The output of the receive pattern generator is the feedback. If QRSS is enabled, the feedback is an XOR of bits 17 and 20, and the output is forced to one if the next 14 bits are all zeros. QRSS is programmable (on or off). For PRBS and QRSS patterns, the feedback is forced to one if bits 1 through 31 are all zeros. When a new pattern is loaded, the pattern generator is loaded with a pattern value before pattern n generation starts. The pattern value is programmable (0 – 2 - 1). When PRBS and QRSS patterns are generated the seed value is all ones. 52 of 169 DS33Z11 Ethernet Mapper 8.15.4.1 Error Insertion Error insertion inserts errors into the outgoing pattern data stream. Errors are inserted one at a time Single bit error insertion can be initiated from the microprocessor interface. If pattern inversion is enabled, the data stream is inverted before the overhead/stuff bits are inserted. Pattern inversion is programmable (on or off). 8.15.4.2 Performance Monitoring Update All counters stop counting at their maximum count. A counter register is updated by asserting (low to high transition) the performance monitoring update signal (PMU). During the counter register update process, the performance monitoring status signal (PMS) is de-asserted. The counter register update process consists of loading the counter register with the current count, resetting the counter, forcing the zero count status indication low for one clock cycle, and then asserting PMS. No events shall be missed during an update procedure. 8.16 Transmit Packet Processor The Transmit Packet Processor accepts data from the Transmit FIFO, performs bit reordering, FCS processing, packet error insertion, stuffing, packet abort sequence insertion, inter-frame padding, and packet scrambling. The data output from the Transmit Packet Processor to the Transmit Serial Interface is a serial data stream (bit synchronous mode). HDLC processing can be disabled (clear channel enable). Disabling HDLC processing disables FCS processing, packet error insertion, stuffing, packet abort sequence insertion, and inter-frame padding. Only bit reordering and packet scrambling are not disabled. Bit reordering changes the bit order of each byte. If bit reordering is disabled, the outgoing 8-bit data stream DT[1:8] with DT[1] being the MSB and DT[8] being the LSB is output from the Transmit FIFO with the MSB in TFD[7] (or 15, 23, or 31) and the LSB in TFD[0] (or 8, 16, or 24) of the transmit FIFO data TFD[7:0] 15:8, 23:16, or 31:24). If bit reordering is enabled, the outgoing 8-bit data stream DT[1:8] is output from the Transmit FIFO with the MSB in TFD[0] and the LSB in TFD[7] of the transmit FIFO data TFD[7:0]. In bit synchronous mode, DT [1] is the first bit transmitted. Bit Reordering can be controlled by address pin A0 in Hardware Mode. FCS processing calculates an FCS and appends it to the packet. FCS calculation is a CRC-16 or CRC-32 16 12 5 calculation over the entire packet. The polynomial used for FCS-16 is x + x + x + 1. The polynomial used for 32 26 23 22 16 12 11 10 8 7 5 4 2 FCS-32 is x + x + x + x + x + x + x + x + x + x + x + x + x + x + 1. The FCS is inverted after calculation. The FCS type is programmable. If FCS append is enabled, the calculated FCS is appended to the packet. If FCS append is disabled, the packet is transmitted without an FCS. The FCS append mode is programmable. If packet processing is disabled, FCS processing is not performed. Packet error insertion inserts errors into the FCS bytes. A single FCS bit is corrupted in each errored packet. The FCS bit corrupted is changed from errored packet to errored packet. Error insertion can be controlled by a register or by the manual error insertion input (LI.TMEI.TMEI). The error insertion initiation type (register or input) is programmable. If a register controls error insertion, the number and frequency of the errors are programmable. If FCS append is disabled, packet error insertion will not be performed. If packet processing is disabled, packet error insertion is not performed. Stuffing inserts control data into the packet to prevent packet data from mimicking flags. A packet start indication is received, and stuffing is performed until, a packet end indication is received. Bit stuffing consists of inserting a '0' directly following any five contiguous '1's. If packet processing is disabled, stuffing is not performed. There is at least one flag plus a programmable number of additional flags between packets. The inter-frame fill can be flags or all '1's followed by a start flag. If the inter-frame fill is all '1's, the number of '1's between the end and start flags does not need to be an integer number of bytes, however, there must be at least 15 consecutive '1's between the end and start flags. The inter-frame padding type is programmable. If packet processing is disabled, inter-frame padding is not performed. Packet abort insertion inserts a packet abort sequences as necessary. If a packet abort indication is detected, a packet abort sequence is inserted and inter-frame padding is done until a packet start flag is detected. The abort sequence is FFh. If packet processing is disabled, packet abort insertion is not performed. 43 The packet scrambler is a x + 1 scrambler that scrambles the entire packet data stream. The packet scrambler runs continuously, and is never reset. In bit synchronous mode, scrambling is performed one bit at a time. In byte 53 of 169 DS33Z11 Ethernet Mapper synchronous mode, scrambling is performed 8 bits at a time. Packet scrambling is programmable. Note in Hardware Mode, the scrambling is controlled by A1/SD. Once all packet processing has been completed serial data stream is passed on to the Transmit Serial Interface. 8.17 Receive Packet Processor The Receive Packet Processor accepts data from the Receive Serial Interface performs packet descrambling, packet delineation, inter-frame fill filtering, packet abort detection, destuffing, packet size checking, FCS error monitoring, FCS byte extraction, and bit reordering. The data coming from the Receive Serial Interface is a serial data stream. Packet processing can be disabled (clear channel enable). Disabling packet processing disables packet delineation, inter-frame fill filtering, packet abort detection, destuffing, packet size checking, FCS error monitoring, and FCS byte extraction. Only packet descrambling and bit reordering are not disabled. 43 The packet descrambler is a self-synchronous x + 1 descrambler that descrambles the entire packet data stream. Packet descrambling is programmable. The descrambler runs continuously, and is never reset. The descrambling is performed one bit at a time. Packet descrambling is programmable. If packet processing is disabled, the serial data stream is demultiplexed in to an 8-bit data stream before being passed on. Note in Hardware Mode, the scrambling is controlled by A1/SD. If packet processing is disabled, a packet boundary is arbitrarily chosen and the data is divided into "packets" of programmable size (dependent on maximum packet size setting). These packets are then passed on to bit reordering with packet start and packet end indications. Data then bypasses packet delineation, inter-frame fill filtering, packet abort detection, destuffing, packet size checking, FCS error monitoring, and FCS byte extraction. Packet delineation determines the packet boundary by identifying a packet start or end flag. Each time slot is checked for a flag sequence (7Eh). Once a flag is found, it is identified as a start/end flag and the packet boundary is set. The flag check is performed one bit at a time. If packet processing is disabled, packet delineation is not performed. Inter-frame fill filtering removes the inter-frame fill between packets. When a packet end flag is detected, all data is discarded until a packet start flag is detected. The inter-frame fill can be flags or all '1's. The number of '1's between flags does not need to be an integer number of bytes, and if at least 7 '1's are detected in the first 16 bits after a flag, all data after the flag is discarded until a start flag is detected. There may be only one flag between packets. When the inter-frame fill is flags, the flags may have a shared zero (011111101111110). If there is less than 16 bits between two flags, the data is discarded. If packet processing is disabled, inter-frame fill filtering is not performed. Packet abort detection searches for a packet abort sequence. Between a packet start flag and a packet end flag, if an abort sequence is detected, the packet is marked with an abort indication, the aborted packet count is incremented, and all subsequent data is discarded until a packet start flag is detected. The abort sequence is seven consecutive ones. If packet processing is disabled, packet abort detection is not performed. Destuffing removes the extra data inserted to prevent data from mimicking a flag or an abort sequence. A start flag is detected, a packet start is set, the flag is discarded, destuffing is performed until an end flag is detected, a packet end is set, and the flag is discarded. In bit synchronous mode, bit destuffing is performed. Bit destuffing consists of discarding any '0' that directly follows five contiguous '1's. After destuffing is completed, the serial bit stream is demultiplexed into an 8-bit parallel data stream and passed on with packet start, packet end, and packet abort indications. If there is less than eight bits in the last byte, an invalid packet flag is raised, the packet is tagged with an abort indication, and the packet size violation count is incremented. If packet processing is disabled, destuffing is not performed. Packet size checking checks each packet for a programmable maximum and programmable minimum size. As the packet data comes in, the total number of bytes is counted. If the packet length is below the minimum size limit, the packet is marked with an aborted indication, and the packet size violation count is incremented. If the packet length is above the maximum size limit, the packet is marked with an aborted indication, the packet size violation count is incremented, and all packet data is discarded until a packet start is received. The minimum and maximum lengths include the FCS bytes, and are determined after destuffing has occurred. If packet processing is disabled, packet size checking is not performed. FCS error monitoring checks the FCS and aborts errored packets. If an FCS error is detected, the FCS errored packet count is incremented and the packet is marked with an aborted indication. If an FCS error is not detected, 54 of 169 DS33Z11 Ethernet Mapper the receive packet count is incremented. The FCS type (16-bit or 32-bit) is programmable. If FCS processing or packet processing is disabled, FCS error monitoring is not performed. FCS byte extraction discards the FCS bytes. If FCS extraction is enabled, the FCS bytes are extracted from the packet and discarded. If FCS extraction is disabled, the FCS bytes are stored in the receive FIFO with the packet. If FCS processing or packet processing is disabled, FCS byte extraction is not performed. Bit reordering changes the bit order of each byte. If bit reordering is disabled, the incoming 8-bit data stream DT[1:8] with DT[1] being the MSB and DT[8] being the LSB is output to the Receive FIFO with the MSB in RFD[7] (or 15, 23, or 31) and the LSB in RFD[0] (or 8, 16, or 24) of the receive FIFO data RFD[7:0] (or 15:8, 23:16, or 31:24). If bit reordering is enabled, the incoming 8-bit data stream DT[1:8] is output to the Receive FIFO with the MSB in RFD[0] and the LSB in RFD[7] of the receive FIFO data RFD[7:0]. DT[1] is the first bit received from the incoming data stream. Bit reordering can be controlled by pin A0 in Hardware Mode. Once all of the packet processing has been completed, The 8-bit parallel data stream is demultiplexed into a 32-bit parallel data stream. The Receive FIFO data is passed on to the Receive FIFO with packet start, packet end, packet abort, and modulus indications. At a packet end, the 32-bit word may contain 1, 2, 3, or 4 bytes of data depending on the number of bytes in the packet. The modulus indications indicate the number of bytes in the last data word of the packet. 55 of 169 DS33Z11 Ethernet Mapper 8.18 X.86 Encoding and Decoding X.86 protocol provides a method for encapsulating Ethernet Frame onto LAPS. LAPS provides HDLC type framing structure for encapsulation of Ethernet frames. LAPS encapsulated frames can be used to send data onto a SONET/SDH network. The DS33Z11 expects a byte synchronization signal to provide the byte boundary for the X.86 receiver. This is provided by the RBSYNC pin. The functional timing is shown in Figure 10-4. The X.86 transmitter provides a byte boundary indicator with the signal TBSYNC. The functional timing is shown in Figure 10-3. Figure 8-11 LAPS Encoding of MAC Frames Concept IEEE 802.3 MAC Frame LAPS Rate Adaption SDH 56 of 169 DS33Z11 Ethernet Mapper Figure 8-12 X.86 Encapsulation of the MAC field Number of Bytes Flag(0x7E) 1 Address(0x04) 1 Control(0x03) 1 1st Octect of SAPI(0xfe) 1 2nd Octect of SAPI(0x01) 1 Destination Adrs(DA) 6 Source Adrs(SA) 6 Length/Type 2 MAC Client Data 46-1500 PAD FCS for MAC 4 FCS for LAPS 4 Flag(0x7E) MSB LSB The DS33Z11 will encode the MAC Frame with the LAPS encapsulation on a complete serial stream if configured for X.86 mode in the register LI.TX86E. The DS33Z11 provides the following functions: · · · Control Registers for Address, SAPI, Destination Address, Source Address 32 bit FCS enabled 43 Programmable X +1 scrambling The sequence of processing performed by the receiver is as follows: · · · · · · · 43 Programmable octets X +1 descrambling Detect the Start Flag (7E) Remove Rate adaptation octets 7d, dd. Perform transparency-processing 7d, 5e is converted to 7e and 7d, 5d is converted to 7d. Check for a valid Address, Control and SAPI fields (LI.TRX86A to LI.TRX86SAPIL) Perform FCS checking Detect the closing flag. 57 of 169 DS33Z11 Ethernet Mapper The X86 received frame is aborted if: · · · · · If 7d,7E is detected. This is an abort packet sequence in X.86 Invalid FCS is detected The received frame has less than 6 octets Control, SAPI and address field are mismatched to the programmed value Octet 7d and octet other than 5d, 5e, 7e, or dd is detected For the transmitter if X.86 is enabled the sequence of processing is as follows: · · · · · Construct frame including start flag SAPI, Control and MAC frame Calculate FCS Perform transparency processing - 7E is translated to 7D5E, 7D is translated to 7D5D Append the end flag(7E) 43 Scramble the sequence X +1 Note that the Serial transmit and receive registers apply to the X.86 implementations with specific exceptions. The exceptions are outlined in the Serial Interface transmit and receive register sections. 58 of 169 DS33Z11 Ethernet Mapper 8.19 Committed Information Rate Controller The DS33Z11 provides a CIR provisioning facility. The CIR can be used restricts the transport of received MAC data to a programmable rate. This is shown in Figure 8-13. The CIR will restrict the data flow from the Receive MAC to Transmit HDLC. This can be used for provisioning and billing functions towards the WAN. The user must set the CIR register to control the amount of data throughput from the MAC to HDLC transmit. The CIR register is in granularity of 500 kbps with a range of 0 to 52 Mbps. The operation of the CIR is as follows: · The CIR block counts the credits that are accumulated at the end of every 125 ms · If data is received and stored in the SDRAM to be sent to the Serial Interface, the interface will request the data if there is a positive credit balance. If the credit balance is negative, transmit interface does not request data · New credit balance is calculated credit balance = old credit balance – frame size in bytes after the frame is sent · The credit balance is incremented every 125 milliseconds by CIR/8 · Credit balances not used in 250 milliseconds are reset to 0 · The maximum value of CIR can not exceed the transmit line rate · If the data rate received from the Ethernet interface is higher than the CIR, the receive queue buffers will fill and the high threshold watermark will invoke flow control to reduce the incoming traffic rate. · The CIR function is only available for software mode of operation only · CIR function is only available in data received at the Ethernet Interface to be sent to WAN. There is not CIR functionality for data arriving from the WAN to be sent to the Ethernet Interface · Negative credits are not allowed, if there is not a credit balance, no frames are sent until there is a credit balance again. 59 of 169 DS33Z11 Ethernet Mapper Figure 8-13 CIR in the WAN Transmit Path Eprom SPI_SCLK (max 8.33Mhz) Buffer Dev Div by 1,2,4,10 Output clocks: 50,25 Mhz,2.5 Mhz 50 or 25 Mhz Oscillator REF_CLKI TSER TCLKI1 Line 1 RCLKI1 RSER HDLC + Serial Interface TX_CLK1 CIR MAC RMII MII Arbiter X.86 RXD RX_CLK1 TXD MDC Buffer Dev Div by 2,4,12 Output Clocks 25,50 Mhz SDRAM Interface SDCLKO REF_CLKO 50 or 25 Mhz SDRAM 60 of 169 100 Mhz Oscillator SYSCLKI DS33Z11 Ethernet Mapper 8.20 Hardware Mode The hardware mode settings are provided for users who do not want to utilize a Microprocessor or EEPROM. The hardware mode default queue sizes and watermark thresholds can be selected for various line rates using the MODEC pins. The user can control the DTE/DCE, RMII/MII and Half Duplex/Full Duplex and setting with hardware pins DCEDTES, RMIIMIIS, and FULLDS selection. The flow control (pause and back pressure) can be configured with the AFCS hardware pins. The user can also control bit order, data scrambling, and X.86 encapsulation using the A0, A1, and A2 pins respectively. Note that in the 100-pin CSBGA package option (DS33ZH11), three pins are reserved for these three signals in future package revisions, but may not be included in the current version. Contact the factory at [email protected] for more details. The DS33Z11 has 3 different default hardware settings. This is outlined in the following tables. The typical applications for each of the Hardware Modes are outlined in following tables. Note that in the hardware only mode the following restrictions apply: · The ports are powered up and ready to transmit/receive after reset · BERT functionality is not supported in Hardware Mode. · Queue size and watermarks are fixed · Receive and Transmit HDLC FCS are 16 bits · Transmit Packets are resent if errors occur, Receive Packets are rejected if errors occur · MII, RMII, Full and Half Duplex, Automatic flow control, DTE, DCE, 100 or 10 Mbps can be selected through Hardware Pins · TDEN and RDEN are not supported and should be tied high · CIR function is not supported in Hardware Mode. Table 8-8 Hardware Mode and Typical Applications Modec Pin Settings Applications 00 Serial Interface connected to a T1/E1 Line, Ethernet Interface set to 10 Mbps or 100 Mbps MII/RMII. Transmitter and receiver are enabled for communication. 10 Serial Interface connected to a T3/E3 line, Ethernet Interface set to 10 Mbps or 100 Mbps MII/RMII. Transmitter and receiver are enabled for communication. The specific registers and detailed functions for each of the hardware modes are detailed in the following tables. 61 of 169 DS33Z11 Ethernet Mapper Table 8-9 Specific Functional Default Values for Hardware Mode Functional Block Register Reference Default Value in Hardware Mode Description Global Connection between Serial and Ethernet Interfaces GL.CON1 0000 0001b Connection established for Serial 1 to Ethernet 1. Transmit Serial Interface Configuration LI.TSLCR 0000 0000b Transmit Data enable is not supported and should be tied high. The user must provide gapped clocks to mask bits if needed. The Transmit Serial data will output on the rising edge of TCLKI1-4. Serial Interface Reset and Power-down LI.RSTPD 0000 0000b In default hardware mode the Serial Interface Transmitter is powered up and ready to go. Transmit FCS LI.TPPCL 0001 0000b* FCS is set to 16 bits for the HDLC Transmitter. Transmit Inter Frame Gap LI.TIFGC 0000 0001b Transmit inter frame gap is one byte. The value is 7E. Receive FCS LI.RPPCL 0001 0000b* Receive HDLC FCS is set to 16 bits. Receive scrambling and bit ordering controlled by hardware pins Receive Maximum Packet Length LI.RMPSC 2016 bytes The receive maximum packet length is set to 2016 bytes not including the HDLC FCS. Serial Data Any packets greater than 2016 bytes are rejected. Receive Serial Port Configuration LI.RSLCR 0000 0000b Receive RDEN enable will not be supported and should be tied high. The Received data is sampled on the falling edge and gapped clock is supported. Transmit packet Resend Criteria SU.TFRC 0000 0000b Any error: Jabber timeout, Loss of carrier, Excessive deferral, Late collision, Excessive collisions, Under run, collision, deferred, heartbeat fail will result in resending of packets Receive Packet Rejection Control SU.RFRC 0000 0000b Broadcast frames, Control frames, and Errored packets are rejected. Receiver Maximum Size SU.RMFSR 0111 1110b The maximum receiver packet size is 2016 bytes including the MAC FCS. Any packet larger that 2016 is rejected SU.MACCR 0000 0000 Duplex mode(bit 20) is determined by the FULLDS pin 0000 0100 (MSB to LSB) Ethernet MAC Control Register 0000 0000 0000 1100b* MAC Flow Control Register SU.MACFCR 0000 0001 Flow control is determined by the AFCS pin. 0100 0000 Pause Timer = 320 (140h) Slots 0000 0000 (MSB to LSB) 0000 0000b* 62 of 169 DS33Z11 Ethernet Mapper Functional Block Register Reference Default Value in Hardware Mode Description Queue Size and thresholds Transmit Queue Size AR.TQSC1 0001 0100b 640 packets, Modec[1:0] = 00 AR.TQSC1 0001 1000b 768 packets, Modec[1:0] = 10 Transmit Queue High Threshold LI.TQHT 0000 1100b 384 packets, Modec[1:0] = 00 LI.TQHT 0000 1100b 384 packets, Modec[1:0] = 01 Transmit Queue Low Threshold LI.TQLT 0000 0110b 192 packets*, Modec[1:0] = 00 LI.TQLT 0000 0110b 192 packets*, Modec[1:0] = 10 AR.RQSC1 0010 1100b 1408 packets*, Modec[1:0] = 00 AR.RQSC1 0010 1000b 1280 packets*, Modec[1:0] = 10 Receive Queue Size Receive Queue Low Threshold Receive Queue High Threshold SU.RQLT 0000 1111b 480 packets*, Modec[1:0] = 00 SU.RQLT 0000 1100b 384 packets*, Modec[1:0] = 10 SU.RQHT 0001 1110b 960 packets*, Modec[1:0] = 00 SU.RQHT 0001 1000b 768 packets*, Modec[1:0] = 10 * The default values for these registers are different than in the Software mode. Note: Each “packet” above is 2048 bytes. 63 of 169 DS33Z11 Ethernet Mapper Table 8-10 Hardware Mode Pins PIN HARDWARE MODE FUNCTION HWMODE 0 = Hardware Mode disabled. 1 = Hardware Mode enabled. MODEC[1:0] Select the hardware mode default settings. RMIIMIIS 0 = MII Operation. 1 = RMII operation. DCEDTES 1 = DCE Operation 0 = DTE Operation FULLDS A2/X86ED A1/SCD A0/BREO 0 = Half Duplex Mode. 1 = Full Duplex Mode. 0 = X.86 mode is disabled. 1 = X.86 mode is enabled for transmit and receive. 43 0 = X +1 scrambling/descrambling is enabled. 43 1 = X +1 scrambling/descrambling is disabled. 0 = HDLC transmit and receive bits are normal. The MSB is transmitted and received first. 1 = HDLC transmit and receive bits are reversed. The LSB is transmitted and received first. 64 of 169 DS33Z11 Ethernet Mapper 9 DEVICE REGISTERS Ten address lines are used to address the register space. Table 9-1 shows the register map for the DS33Z11 is shown in. The addressable range for the device is 0000h to 08FFh. Each register section is 64 bytes deep. Global Registers are preserved for software compatibility with multiport devices. The Serial Interface (Line) Registers are used to configure the serial port and the associated transport protocol. The Ethernet Interface (Subscriber) registers are used to control and observe each of the Ethernet ports. The registers associated with the MAC must be configured through indirect register write /read access due to the architecture of the device. When writing to a register input values for unused bits and registers (those designated with “-“) should be zero, as these bits and registers are reserved. When a register is read from, the values of the unused bits and registers should be ignored. A latched status bit is set when an event happens and is cleared when read. The register details are provided in the following tables. Table 9-1 Register Address Map Global Registers 0000h – 003Fh Port 1 Arbiter 0040h – 007Fh - - BERT 0080h – 00BFh - Unused address space: 180h - 7FFh 65 of 169 Serial Interface Ethernet Interface - - 00C0h – 013Fh 0140h – 017Fh DS33Z11 Ethernet Mapper 9.1 Register Bit Maps Table 9-2, Table 9-3, Table 9-4, Table 9-5, Table 9-6, and Table 9-7 contain the registers of the DS33Z11. Bits that are reserved are noted with a single dash “-“. All registers not listed are reserved and should be initialized with a value of 00h for proper operation, unless otherwise noted. 9.1.1 Global Register Bit Map Table 9-2 Global Register Bit Map ADDR Name GL.IDRL 00h BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 ID07 ID06 ID05 ID04 ID03 ID02 ID01 ID00 01h GL.IDRH ID15 ID14 ID13 ID12 ID11 ID10 ID09 ID08 02h GL.CR1 - - - - - REF_CLKO INTM RST 03h GL.BLR - - - - - - - GL.BLC1 04h GL.RTCAL - - - RLCALS1 - - - TLCALS1 05h GL.SRCALS - - - - - - REFCLKS SYSCLS 06h GL.LIE - - - LIN1TIE - - - LIN1RIE 07h GL.LIS - - - LIN1TIS - - - LIN1RIS 08h GL.SIE - - - - - - - SUB1IE 09h GL.SIS - - - - - - - SUB1IS 0Ah GL.TRQIE - - - TQ1IE - - - RQ1IE 0Bh GL.TRQIS - - - TQ1IS - - - RQ1IS 0Ch GL.BIE - - - - - - - BIE 0Dh GL.BIS - - - - - - - BIS 0Eh GL.CON1 - - - - - - - LINE0 0Fh Reserved - - - - - - - - 10h Reserved - - - - - - - - 11h Reserved - - - - - - - - 12h GL.C1QPR - - - - C1MRPRR C1HWPRR C1MHPR C1HRPR 13h Reserved - - - - - - - - 14h Reserved - - - - - - - - 15h Reserved - - - - - - - - 20h GL.BISTEN - - - - - - - BISTE 21h GL.BISTPF - - - - - - BISTDN BISTPF 22h - 3Fh are reserved. 66 of 169 DS33Z11 Ethernet Mapper 9.1.2 Arbiter Register Bit Map Table 9-3 Arbiter Register Bit Map ADDR NAME AR.RQSC1 40h 41h 9.1.3 AR.TQSC1 BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 RQSC7 RQSC6 RQSC5 RQSC4 RQSC3 RQSC2 RQSC1 RQSC0 TQSC7 TQSC6 TQSC5 TQSC4 TQSC3 TQSC2 TQSC1 TQSC0 BERT Register Bit Map Table 9-4 BERT Register Bit Map ADDR 080h 081h 082h 083h 084h 085h 086h 087h 088h 08Ah 08Bh 08Ch 08Dh 08Eh 08Fh 90h 91h 92h 93h 94h 95h 96h 97h 98h 99h 9Ah 9Bh 9Ch 9Dh 9Eh 9Fh NAME BCR Reserved BPCLR BPCHR BSPB0R BSPB1R BSPB2R BSPB3R TEICR Reserved Reserved BSR Reserved BSRL Reserved BSRIE Reserved Reserved Reserved RBECB0R RBECB1R RBECB2R Reserved RBCB0 RBCB1 RBCB2 RBCB3 Reserved Reserved Reserved Reserved BIT 7 BSP7 BSP15 BSP23 BSP31 BEC7 BEC15 BEC23 BC7 BC15 BC23 BC31 - BIT 6 PMU QRSS BSP6 BSP14 BSP22 BSP30 BEC6 BEC14 BEC22 BC6 BC14 BC22 BC30 - BIT 5 BIT 4 RNPL PTS BSP5 BSP13 BSP21 BSP29 TIER2 BEC5 BEC13 BEC21 BC5 BC13 BC21 BC29 - RPIC PLF4 PTF4 BSP4 BSP12 BSP20 BSP28 TIER1 BEC4 BEC12 BEC20 BC4 BC12 BC20 BC28 - 67 of 169 BIT 3 MPR PLF3 PTF3 BSP3 BSP11 BSP19 BSP27 TIER0 PMS PMSL PMSIE BEC3 BEC11 BEC19 BC3 BC11 BC19 BC27 - BIT 2 APRD PLF2 PTF2 BSP2 BSP10 BSP18 BSP26 BEI BEL BEIE BEC2 BEC10 BEC18 BC2 BC10 BC18 BC26 - BIT 1 TNPL PLF1 PTF1 BSP1 BSP9 BSP17 BSP25 TSEI BEC BECL BECIE BEC1 BEC9 BEC17 BC1 BC9 BC17 BC25 - BIT 0 TPIC PLF0 PTF0 BSP0 BSP8 BSP16 BSP24 OOS OOSL OOSIE BEC0 BEC8 BEC16 BC0 BC8 BC16 BC24 - DS33Z11 Ethernet Mapper 9.1.4 Serial Interface Register Bit Map Table 9-5 Serial Interface Register Bit Map ADDR 0C0h 0C1h 0C2h 0C3h 0C4h 0C5h 0C6h 0C7h 0C8h 0C9h 0CAh 0CBh 0CCh 0CDh 0CEh 0CFh 0D0h 0D1h 0D2h 0D3h 0D4h 0D5h 0D6h NAME BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 LI.TSLCR LI.RSTPD LI.LPBK Reserved LI.TPPCL LI.TIFGC LI.TEPLC LI.TEPHC LI.TPPSR LI.TPPSRL LI.TPPSRIE Reserved LI.TPCR0 LI.TPCR1 LI.TPCR2 Reserved LI.TBCR0 LI.TBCR1 LI.TBCR2 LI.TBCR3 LI.TMEI Reserved TIFG7 TPEN7 MEIMS TPC7 TPC15 TPC23 TBC7 TBC15 TBC23 TBC31 - TIFG6 TPEN6 TPER6 TPC6 TPC14 TPC22 TBC6 TBC14 TBC22 TBC30 - TFAD TIFG5 TPEN5 TPER5 TPC5 TPC13 TPC21 TBC5 TBC13 TBC21 TBC29 - TF16 TIFG4 TPEN4 TPER4 TPC4 TPC12 TPC20 TBC4 TBC12 TBC20 TBC28 - TIFV TIFG3 TPEN3 TPER3 TPC3 TPC11 TPC19 TBC3 TBC11 TBC19 TBC27 - TSD TIFG2 TPEN2 TPER2 TPC2 TPC10 TPC18 TBC2 TBC10 TBC18 TBC26 - RESET TBRE TIFG1 TPEN1 TPER1 TPC1 TPC9 TPC17 TBC1 TBC9 TBC17 TBC25 - TDENPLT QLP TIFG0 TPEN0 TPER0 TEPF TEPFL TEPFIE TPC0 TPC8 TPC16 TBC0 TBC8 TBC16 TBC24 TMEI - LI.THPMUU - - - - - - - TPMUU 0D7h LI.THPMUS 0D8h LI.TX86EDE - - - - - - - TPMUS 0D9h 0DAh 0DBh 0DCh 0DDh 100h 101h 102h 103h 104h 105h 106h 107h 108h 109h 10Ah 10Ch 10Dh 10Eh 10Fh 110h 111h 112h - LI.TRX86A X86TRA7 LI.TRX8C X86TRC7 LI.TRX86SAPIH TRSAPIH7 LI.TRX86SAPIL TRSAPIL7 LI.CIR CIRE LI.RSLCR LI.RPPCL LI.RMPSCL RMX7 LI.RMPSCH RMX15 LI.RPPSR LI.RPPSRL REPL LI.RPPSRIE REPIE Reserved LI.RPCB0 RPC7 LI.RPCB1 RPC15 LI.RPCB2 RPC23 - - - - - - X86ED X86TRA6 X86TRC6 TRSAPIH6 TRSAPIL6 CIR6 RMX6 RMX14 RAPL RAPIE X86TRA5 X86TRC5 TRSAPIH5 TRSAPIL5 CIR5 RFPD RMX5 RMX13 RIPDL RIPDIE X86TRA4 X86TRC4 TRSAPIH4 TRSAPIL4 CIR4 RF16 RMX4 RMX12 RSPDL RSPDIE X86TRA3 X86TRC3 TRSAPIH3 TRSAPIL3 CIR3 RFED RMX3 RMX11 RLPDL RLPDIE X86TRA2 X86TRC2 TRSAPIH2 TRSAPIL2 CIR2 RDD RMX2 RMX10 REPC REPCL REPCIE X86TRA1 X86TRC1 TRSAPIH1 TRSAPIL1 CIR1 RBRE RMX1 RMX9 RAPC RAPCL RAPCIE X86TRA0 X86TRC0 TRSAPIH0 TRSAPIL0 CIR0 RDENPLT RCCE RMX0 RMX8 RSPC RSPCL RSPCIE RPC6 RPC14 RPC22 RPC5 RPC13 RPC21 RPC4 RPC12 RPC20 RPC3 RPC11 RPC19 RPC2 RPC10 RPC18 RPC1 RPC09 RPC17 RPC0 RPC08 RPC16 LI.RFPCB0 RFPC7 RFPC6 RFPC5 RFPC4 RFPC3 RFPC2 RFPC1 RFPC0 LI.RFPCB1 LI.RFPCB2 Reserved LI.RAPCB0 LI.RAPCB1 LI.RAPCB2 RFPC15 RFPC23 RFPC14 RFPC22 RFPC13 RFPC21 RFPC12 RFPC20 RFPC11 RFPC19 RFPC10 RFPC18 RFPC9 RFPC17 RFPC8 RFPC16 RAPC7 RAPC15 RAPC23 RAPC6 RAPC14 RAPC22 RAPC5 RAPC13 RAPC21 RAPC4 RAPC12 RAPC20 RAPC3 RAPC11 RAPC19 RAPC2 RAPC10 RAPC18 RAPC1 RAPC9 RAPC17 RAPC0 RAPC8 RAPC16 68 of 169 DS33Z11 Ethernet Mapper ADDR 113h 114h 115h 116h 118h 119h 11Ah 11Bh 11Ch 11Dh 11Eh 11Fh 120h NAME BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 Reserved LI.RSPCB0 LI.RSPCB1 LI.RSPCB2 LI.RBC0 LI.RBC1 LI.RBC2 LI.RBC3 LI.RAC0 LI.RAC1 LI.RAC2 LI.RAC3 RSPC7 RSPC15 RSPC23 RBC7 RBC15 RBC23 RBC31 REBC7 REBC15 REBC23 REBC31 RSPC6 RSPC14 RSPC22 RBC6 RBC14 RBC22 RBC30 REBC6 REBC14 REBC22 REBC30 RSPC5 RSPC13 RSPC21 RBC5 RBC13 RBC21 RBC29 REBC5 REBC13 REBC21 REBC29 RSPC4 RSPC12 RSPC20 RBC4 RBC12 RBC20 RBC28 REBC4 REBC12 REBC20 REBC28 RSPC3 RSPC11 RSPC19 RBC3 RBC11 RBC19 RBC27 REBC3 REBC11 REBC19 REBC27 RSPC2 RSPC10 RSPC18 RBC2 RBC10 RBC18 RBC26 REBC2 REBC10 REBC18 REBC26 RSPC1 RSPC9 RSPC17 RBC1 RBC9 RBC17 RBC25 REBC1 REBC9 REBC17 REBC25 RSPC0 RSPC8 RSPC16 RBC0 RBC8 RBC16 RBC24 REBC0 REBC8 REBC16 REBC24 LI.RHPMUU - - - - - - - RPMUU - - - - - RPMUUS TQLT5 TQHT5 - TQLT4 TQHT4 - SAPIHNE SAPILNE SAPINE01IM SAPINEFEIM TQLT3 TQHT3 TFOVFIE TFOVFLS TQLT2 TQHT2 TQOVFIE TQOVFLS CNE CNE3LIM TQLT1 TQHT1 TQHTIE TQHTLS ANE ANE4IM TQLT0 TQHT0 TQLTIE TQLTLS 121h LI.RHPMUS LI.RX86S 122h LI.RX86LSIE 123h TQLT7 TQLT6 124h LI.TQLT TQHT7 TQHT6 125h LI.TQHT 126h LI.TQTIE 127h LI.TQCTLS 0DEh – 0FFh, 128h – 13Fh are reserved. 69 of 169 DS33Z11 Ethernet Mapper 9.1.5 Ethernet Interface Register Bit Map Table 9-6 Ethernet Interface Register Bit Map BIT 7 ADDR NAME MACRA7 140h SU.MACRADL SU.MACRADH MACRA15 141h MACRD7 142h SU.MACRD0 SU.MACRD1 MACRD15 143h MACRD23 144h SU.MACRD2 MACRD31 145h SU.MACRD3 MACWD7 146h SU.MACWD0 MACWD15 147h SU.MACWD1 MACWD23 148h SU.MACWD2 MACD31 149h SU.MACWD3 MACAW 7 14Ah SU.MACAWL 14Bh SU.MACAWH MACAW 15 14Ch SU.MACRWC 14Eh RESERVED 14Fh SU.LPBK 150h SU.GCR 151h SU.TFRC UR 152h SU.TFSL PR 153h SU.TFSH FL7 154h SU.RFSB0 RF 155h SU.RFSB1 156h SU.RFSB2 MF 157h SU.RFSB3 RMPS7 158h SU.RMFSRL RMPS15 159h SU.RMFSRH RQLT7 15Ah SU.RQLT RQHT7 15Bh SU.RQHT 15Ch SU.QRIE 15Dh SU.QCRLS 15Eh SU.RFRC 15Fh – 17Fh are reserved. BIT 6 BIT 5 MACRA6 MACRA5 MACRA14 MACRA13 MACRD6 MACRD5 MACRD14 MACRD13 MACRD22 MACRD21 MACRD30 MACRD29 MACWD6 MACWD5 MACWD14 MACWD13 MACWD22 MACWD21 MACD30 MACD29 MACAW 6 MACAW 5 MACAW 14 MACAW 13 EC LC HBF CC3 FL6 FL5 WT FL13 CRCE RMPS6 RMPS5 RMPS14 RMPS13 RQLT6 RQLT5 RQHT6 RQHT5 UCFR CFRR BIT 4 MACRA4 MACRA12 MACRD4 MACRD12 MACRD20 MACRD28 MACWD4 MACWD12 MACWD20 MACD28 MACAW4 MACAW12 ED CC2 FL4 FL12 DB BF RMPS4 RMPS12 RQLT4 RQHT4 LERR 70 of 169 BIT 3 MACRA3 MACRA11 MACRD3 MACRD11 MACRD19 MACRD27 MACWD3 MACWD11 MACWD19 MACD27 MACAW3 MACAW11 CRCS NCFQ LOC CC1 FL3 FL11 MIIE MCF RMPS3 RMPS11 RQLT3 RQHT3 RFOVFIE RFOVFLS CRCERR BIT 2 MACRA2 MACRA10 MACRD2 MACRD10 MACRD18 MACRD26 MACWD2 MACWD10 MACWD18 MACD26 MACAW2 MACAW10 H10S TPDFCB NOC CC0 FL2 FL10 FT UF RMPS2 RMPS10 RQLT2 RQHT2 RQVFIE RQOVFLS DBR BIT 1 MACRA1 MACRA09 MACRD1 MACRD9 MACRD17 MACRD25 MACWD1 MACWD09 MACWD17 MACD25 MACAW1 MACAW9 MCRW ATFLOW TPRHBC LCO FL1 FL9 CS CF RMPS1 RMPS09 RQLT1 RQHT1 RQLTIE RQHTLS MIIER BIT 0 MACRA0 MACRA08 MACRD0 MACRD8 MACRD16 MACRD24 MACWD0 MACWD08 MACWD16 MACD24 MACAW0 MACAW8 MCS QLP JAME TPRCB FABORT DEF Fl0 Fl8 FTL LE RMPS0 RMPS08 RQLT0 RQHT0 RQHTIE RQLTLS BFR DS33Z11 Ethernet Mapper 9.1.6 MAC Register Bit Map Table 9-7 MAC Indirect Register Bit Map ADDR 0000h 0001h 0002h 0003h 0004h 0005h 0006h 0007h 0008h 0009h 000Ah 000Bh 000Ch 000Dh 000Eh 000Fh 0010h 0011h 0012h 0013h 0014h 0015h 0016h 0017h 0018h 0019h 001Ah 001Bh 001Ch 001Dh 001Eh 001Fh 100h 101h 102h 103h 10Ch 10Dh 10Eh 10Fh NAME SU.MACCR 31:24 23:16 15:8 7:0 SU.MACAH 31:24 23:16 15:8 7:0 SU.MACAL 31:24 23:16 15:8 7:0 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved SU.MACMIIA 31:24 23:16 15:8 7:0 SU.MACMIID 31:24 23:16 15:8 7:0 SU.MACFCR 31:24 23:16 15:8 7:0 SU.MMCCTRL 31:24 23:16 15:8 7:0 RESERVED – initialize to FF RESERVED – initialize to FF RESERVED – initialize to FF RESERVED – initialize to FF BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 Reserved Reserved Reserved HDB PS Reserved Reserved Reserved DRO Reserved BOLMT1 OML1 Reserved BOLMT0 OML0 Reserved DC F LCC Reserved Reserved Reserved TE Reserved DRTY RE Reserved Reserved Reserved Reserved ASTP Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR47 PADR39 Reserved PADR46 PADR38 Reserved PADR45 PADR37 Reserved PADR44 PADR36 Reserved PADR43 PADR35 Reserved PADR42 PADR34 Reserved PADR41 PADR33 Reserved PADR40 PADR32 PADR31 PADR30 PADR29 PADR28 PADR27 PADR26 PADR25 PADR24 PADR23 PADR15 PADR07 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR22 PADR14 PADR06 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR21 PADR13 PADR05 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR20 PADR12 PADR04 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR19 PADR11 PADR03 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR18 PADR10 PADR02 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR17 PADR09 PADR01 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PADR16 PADR08 PADR00 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PHYA4 MIIA1 Reserved PHYA3 MIIA0 Reserved PHYA2 Reserved Reserved PHYA1 Reserved Reserved PHYA0 Reserved Reserved MIIA4 Reserved Reserved MIIA3 MIIW Reserved MIIA2 MIIB Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved MIID15 MIID07 Reserved MIID14 MIID06 Reserved MIID13 MIID05 Reserved MIID12 MIID04 Reserved MIID11 MIID03 Reserved MIID10 MIID02 Reserved MIID09 MIID01 Reserved MIID08 MIID00 PT15 PT14 PT13 PT12 PT11 PT10 PT09 PT08 PT07 Reserved Reserved PT06 Reserved Reserved PT05 Reserved Reserved PT04 Reserved Reserved PT03 Reserved Reserved PT02 Reserved PCF PT01 Reserved FCE PT00 Reserved FCB Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved MXFRM4 Reserved Reserved MXFRM3 Reserved MXFRM10 MXFRM2 Reserved MXFRM9 MXFRM1 Reserved MXFRM8 MXFRM0 Reserved MXFRM7 Reserved Reserved MXFRM6 Reserved Reserved MXFRM5 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved 71 of 169 DS33Z11 Ethernet Mapper ADDR 110h 111h 112h 113h 200h 201h 202h 203h 204h 205h 206h 207h 300h 301h 302h 303h 308h 309h 30Ah 30Bh 30Ch 30Dh 30Eh 30Fh 334h 335h 336h 337h 338h 339h 33Ah 33Bh NAME BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 RESERVED – Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved initialize to FF RESERVED – Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved initialize to FF RESERVED – Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved initialize to FF RESERVED – Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved initialize to FF SU.RxFrmCtr RXFRMC31 RXFRMC30 RXFRMC29 RXFRMC28 RXFRMC27 RXFRMC26 RXFRMC25 RXFRMC24 31:24 23:16 RXFRMC23 RXFRMC22 RXFRMC21 RXFRMC20 RXFRMC19 RXFRMC18 RXFRMC17 RXFRMC16 15:8 RXFRMC15 RXFRMC14 RXFRMC13 RXFRMC12 RXFRMC11 RXFRMC10 RXFRMC9 RXFRMC8 7:0 RXFRMC7 RXFRMC6 RXFRMC5 RXFRMC4 RXFRMC3 RXFRMC2 RXFRMC1 RXFRMC0 SU.RxFrmOKCtr 31:24 23:16 15:8 7:0 SU.TxFrmCtr 23:16 15:8 7:0 SU.TxBytesCtr 23:16 15:8 7:0 RXFRMOK31 RXFRMOK30 RXFRMOK29 RXFRMOK28 RXFRMOK27 RXFRMOK26 RXFRMOK25 RXFRMOK24 RXFRMOK23 RXFRMOK22 RXFRMOK21 RXFRMOK20 RXFRMOK19 RXFRMOK18 RXFRMOK17 RXFRMOK16 RXFRMOK15 RXFRMOK14 RXFRMOK13 RXFRMOK12 RXFRMOK11 RXFRMOK10 RXFRMOK9 RXFRMOK8 RXFRMOK7 RXFRMOK6 RXFRMOK5 RXFRMOK4 RXFRMOK3 RXFRMOK2 RXFRMOK1 RXFRMOK0 TXFRMC31 TXFRMC30 TXFRMC29 TXFRMC28 TXFRMC27 TXFRMC26 TXFRMC25 TXFRMC24 TXFRMC23 TXFRMC22 TXFRMC21 TXFRMC20 TXFRMC19 TXFRMC18 TXFRMC17 TXFRMC16 TXFRMC15 TXFRMC14 TXFRMC13 TXFRMC12 TXFRMC11 TXFRMC10 TXFRMC9 TXFRMC8 TXFRMC7 TXFRMC6 TXFRMC5 TXFRMC4 TXFRMC3 TXFRMC2 TXFRMC1 TXFRMC0 TXBYTEC31 TXBYTEC30 TXBYTEC29 TXBYTEC28 TXBYTEC27 TXBYTEC26 TXBYTEC25 TXBYTEC24 TXBYTEC23 TXBYTEC22 TXBYTEC21 TXBYTEC20 TXBYTEC19 TXBYTEC18 TXBYTEC17 TXBYTEC16 TXBYTEC15 TXBYTEC14 TXBYTEC13 TXBYTEC12 TXBYTEC11 TXBYTEC10 TXBYTEC9 TXBYTEC8 TXBYTEC7 TXBYTEC6 TXBYTEC5 TXBYTEC4 TXBYTEC3 TXBYTEC2 TXBYTEC1 TXBYTEC0 SU.TxBytesOkCtr TXBYTEOK31 TXBYTEOK30 TXBYTEOK29 TXBYTEOK28 TXBYTEOK27 TXBYTEOK26 TXBYTEOK25 TXBYTEOK24 23:16 TXBYTEOK23 TXBYTEOK22 TXBYTEOK21 TXBYTEOK20 TXBYTEOK19 TXBYTEOK18 TXBYTEOK17 TXBYTEOK16 15:8 TXBYTEOK15 TXBYTEOK14 TXBYTEOK13 TXBYTEOK12 TXBYTEOK11 TXBYTEOK10 TXBYTEOK9 TXBYTEOK8 7:0 TXBYTEOK7 TXBYTEOK6 TXBYTEOK5 TXBYTEOK4 TXBYTEOK3 TXBYTEOK2 TXBYTEOK1 TXBYTEOK0 SU.TxFrmUndr TXFRMU31 TXFRMU30 TXFRMU29 TXFRMU28 TXFRMU27 TXFRMU26 TXFRMU25 TXFRMU24 23:16 TXFRMU23 TXFRMU22 TXFRMU21 TXFRMU20 TXFRMU19 TXFRMU18 TXFRMU17 TXFRMU16 15:8 TXFRMU15 TXFRMU14 TXFRMU13 TXFRMU12 TXFRMU11 TXFRMU10 TXFRMU9 TXFRMU8 7:0 TXFRMU7 TXFRMU6 TXFRMU5 TXFRMU4 TXFRMU3 TXFRMU2 TXFRMU1 TXFRMU0 SU.TxBdFrmCtr 23:16 15:8 7:0 TXFRMBD31 TXFRMBD30 TXFRMBD29 TXFRMBD28 TXFRMBD27 TXFRMBD26 TXFRMBD25 TXFRMBD24 TXFRMBD23 TXFRMBD22 TXFRMBD21 TXFRMBD20 TXFRMBD19 TXFRMBD18 TXFRMBD17 TXFRMBD16 TXFRMBD15 TXFRMBD14 TXFRMBD13 TXFRMBD12 TXFRMBD11 TXFRMBD10 TXFRMBD9 TXFRMBD8 TXFRMBD7 TXFRMBD6 TXFRMBD5 TXFRMBD4 TXFRMBD3 TXFRMBD2 TXFRMBD1 TXFRMBD0 Note that the addresses in the table above are the indirect addresses that must be provided to the SU.MACAWH and SU.MACAWL. All unused and reserved locations must be initialized to zero for proper operation. 72 of 169 DS33Z11 Ethernet Mapper 9.2 Global Register Definitions Functions contained in the global registers include: framer reset, LIU reset, device ID, BERT interrupt status, framer interrupt status, MCLK configuration, and BPCLK configuration. These registers are preserved to provide code compatibility with the multiport devices in this product family. The global registers bit descriptions are presented below. Register Name: Register Description: Register Address: Bit # Name Default 7 ID07 0 GL.IDRL Global ID Low Register 00h 6 ID06 0 5 ID05 1 4 ID04 1 3 ID03 0 2 ID02 0 1 ID01 0 0 ID00 0 Bit 7: ID07 Reserved for future use Bit 6: ID06 Reserved for future use Bit 5: ID05 If this bit is set the device contains a RMII interface Bit 4: ID04 If this bit is set the device contains a MII interface Bit 3: ID03 If this bit is set the device contains an Ethernet PHY Bits 0-2: ID00-ID02 A three-bit count that is equal to 000b for the first die revision, and is incremented with each successive die revision. May not match the two-letter die revision code on the top brand of the device. Register Name: Register Description: Register Address: Bit # Name Default 7 ID15 0 GL.IDRH Global ID High Register 01h 6 ID14 0 5 ID13 0 4 ID12 0 3 ID11 0 Bits 5-7: ID13-15 Number of ports in the device – 1. (i.e. 000 = 1 port) Bit 4: ID12 If this bit is set the device has LIU functionality Bit 3: ID11 If this bit is set the device has a framer Bit 2: ID10 Reserved for future use Bit 1: ID09 If this bit is set the device has HDLC or X.86 encapsulation Bit 0: ID08 If this bit is set the device has inverse multiplexing functionality 73 of 169 2 ID10 0 1 ID09 1 0 ID08 0 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 - GL.CR1 Global Control Register 1 02h 6 - 5 - 4 - 3 - 2 REF_CLKO 0 1 INTM 0 0 RST 0 Bit 2: REF_CLKO OFF (REF_CLKO) This bit determines if the REF_CLKO is turned off 1 = REF_CLKO is disabled and outputs an active low signal. 0 = REF_CLKO is active and in accordance with RMII/MII Selection Bit 1: INT pin mode (INTM) This bit determines the inactive mode of the INT pin. The INT pin always drives low when active. 1 = Pin is high impedance when not active 0 = Pin drives high when not active Bit 0: Reset (RST). When this bit is set to 1, all of the internal data path and status and control registers (except this RST bit), on all ports, are reset to their default state. This bit must be set high for a minimum of 100ns. 0 = Normal operation 1 = Reset and force all internal registers to their default values Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.BLR Global BERT Connect Register 03h 6 0 5 0 4 0 3 0 2 0 1 0 0 BLC1 0 Bit 0: BERT Connect 1 (BLC1) If this bit is set to 1, the BERT is connected to Serial Interface 1. The BERT transmitter is connected to the transmit serial port and receive to receive serial port. When the BERT is connected, normal data transfer is interrupted. Note that connecting the BERT overrides a connection to the Serial Interface, if a connection exists. When the BERT is disconnected, the connection is restored. The BERT is unavailable in Hardware Mode. 74 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 - GL.RTCAL Global Receive and Transmit Serial Port Clock Activity Latched Status 04h 6 - 5 - 4 RLCALS1 - 3 - 2 - 1 - 0 TLCALS1 - Bit 4: Receive Serial Interface Clock Activity Latched Status 1 (RLCALS1) This bit is set to 1 if the receive clock for Serial Interface 1 has activity. This bit is cleared upon read. Bit 0: Transmit Serial Interface Clock Activity Latched Status 1 (TSCALS1) This bit is set to 1 if the transmit clock for Serial Interface 1 has activity. This bit is cleared upon read. Register Name: Register Description: Register Address: Bit # Name Default 7 - GL.SRCALS Global SDRAM Reference Clock Activity Latched Status 05h 6 - 5 - 4 - 3 - 2 - 1 REFCLKS - 0 SYSCLS - Bit 1: Reference Clock Activity Latched Status (REFCLKS) This bit is set to 1 if REF_CLK has activity. This bit is cleared upon read. Bit 0: System Clock Input Latched Status (SYSCLS) This bit is set to 1 if SYSCLKI has activity. This bit is cleared upon read. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.LIE Global Serial Interface Interrupt Enable 06h 6 0 5 0 4 LIN1TIE 0 3 0 2 0 1 0 0 LIN1RIE 0 Bit 4: Serial Interface 1 TX Interrupt Enable (LINE1TIE) Setting this bit to 1 enables an interrupt on LIN1TIS Bit 0: Serial Interface 1 RX Interrupt Enable (LINE1RIE) Setting this bit to 1 enables an interrupt on LIN1RIS 75 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.LIS Global Serial Interface Interrupt Status 07h 6 0 5 0 4 LIN1TIS 0 3 0 2 0 1 0 0 LIN1RIS 0 Bit 4: Serial Interface 1 TX Interrupt Status (LINE1TIS) This bit is set if Serial Interface 1 Transmit has an enabled interrupt generating event. Serial Interface interrupts consist of HDLC interrupts and X.86 interrupts. Bit 0: Serial Interface 1 RX Interrupt Status (LINER1IS) This bit is set if Serial Interface 1 Receive has an enabled interrupt generating event. Serial Interface interrupts consist of HDLC interrupts and X.86 interrupts. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.SIE Global Ethernet Interface Interrupt Enable 08h 6 0 5 0 4 0 3 0 2 0 1 0 0 SUB1IE 0 Bit 0: Ethernet Interface 1 Interrupt Enable (SUB1IE) Setting this bit to 1 enables an interrupt on SUB1S. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.SIS Global Ethernet Interface Interrupt Status 09h 6 0 5 0 4 0 3 0 2 0 1 0 0 SUB1IS 0 Bit 0: Ethernet Interface 1 Interrupt Status (SUB1IS) This bit is set to 1 if Ethernet Interface 1 has an enabled interrupt generating event. The Ethernet Interface consists of the MAC and The RMII/MII port. 76 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.TRQIE Global Transmit Receive Queue Interrupt Enable 0Ah 6 0 5 0 4 TQ1IE 0 3 0 2 0 1 0 0 RQ1IE 0 Bit 4: Transmit Queue 1 Interrupt Enable (TQ1IE) Setting this bit to 1 enables an interrupt on TQ1IS. Bit 0: Receive Queue 1 Interrupt Enable (RQ1IE) Setting this bit to 1 enables an interrupt on RQ1IS. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.TRQIS Global Transmit Receive Queue Interrupt Status 0Bh 6 0 5 0 4 TQ1IS 0 3 0 2 0 1 0 0 RQ1IS 0 Bit 4: Transmit Queue 1 Interrupt Enable (TQ1IS) If this bit is set to 1, the Transmit Queue 1 has interrupt status event. Transmit queue events are transmit queue-crossing thresholds and queue overflows. Bit 0: Receive Queue 1 Interrupt Status (RQ1IS) If this bit is set to 1, the Receive Queue 1 has interrupt status event. Receive queue events are transmit queue-crossing thresholds and queue overflows. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.BIE Global BERT Interrupt Enable 0Ch 6 0 5 0 4 0 3 0 2 0 Bit 0: BERT Interrupt Enable (BIE) Setting this bit to 1 enables an interrupt on BIS. 77 of 169 1 0 0 BIE 0 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default GL.BIS Global BERT Interrupt Status 0Dh 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 BIS 0 Bit 0: BERT Interrupt Status (BIS) This bit is set to 1 if the BERT has an enabled interrupt generating event. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.CON1 Connection Register for Ethernet Interface 1 0Eh 6 0 5 0 4 0 3 0 2 0 1 0 0 LINE1[0] 1 Bit 0: LINE1[0] This bit is preserved to provide software compatibility with multiport devices. The LINE1[0] bit selects the Ethernet port that is to be connected to the Serial Interface. Note that Bi-directional connection is assumed between the Serial and Ethernet Interfaces. The connection register and corresponding queue size must be defined for proper operation. Writing a 0 to this register will disconnect the connection. When a connection is disconnected, “1”s are sourced to the Serial Interface transmit and to the HDLC receiver and the clocks to the HDLC transmitter/receiver are disabled. 78 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.C1QPR Connection 1 Queue Pointer Reset 12h 6 0 5 0 4 0 3 C1MRPRR 0 2 C1HWPRR 0 1 C1MHPR 0 0 C1HRPR 0 Bit 3: MAC Read Pointer Reset (C1MRPRR) If this bit is set to 1, the receive queue read pointer is reset for connection 1. The queue pointer must be reset after a disconnect and before a connection. Bit 2: HDLC Write Pointer Reset (C1HWPRR) If this bit is set to 1, the receive queue write pointer is reset for connection 1. The queue pointer must be reset after a disconnect and before a connection. Bit 1: HDLC Read Pointer Reset (C1MHPR) If this bit is set to 1, the receive queue read pointer is reset for connection 1. The queue pointer must be reset after a disconnect and before a connection. Bit 0: MAC Transmit Write Pointer Reset (C1HRPR) If this bit is set to 1, the receive queue write pointer is reset for connection 1. The queue pointer must be reset after a disconnect and before a connection. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.BISTEN BIST Enable 20h 6 0 5 0 4 0 3 0 2 0 1 0 0 BISTE 0 Bit 0: BIST Enable (BISTE) If this bit is set the DS33Z11 performs BIST test on the SDRAM. Normal data communication is halted while BIST enable is high. The user must reset the DS33Z11 after completion of BIST test before normal dataflow can begin. Register Name: Register Description: Register Address: Bit # Name Default 7 0 GL.BISTPF BIST PassFail 21h 6 0 5 0 4 0 3 0 2 0 1 BISTDN 0 0 BISTPF 0 Bit 1: BIST DONE (BISTDN) If this bit is set to 1, the DS33Z11 has completed the BIST Test initiated by BISTE. The pass fail result is available in BISTPF. Bit 0: BIST PassFail (BISTPF) This bit is equal to 0 after the DS33Z11 performs BIST testing on the SDRAM and the test passes. This bit is set to 1 if the test failed. This bit is valid only after the BIST test is complete and the BIST DN bit is set. If set this bit can only be cleared by resetting the DS33Z11. 79 of 169 DS33Z11 Ethernet Mapper 9.3 Arbiter Registers The Arbiter manages the transport between the Ethernet port and the Serial Interface. It is responsible for queuing and dequeuing data to an external SDRAM. The arbiter handles requests from the HDLC and MAC to transfer data to/from the SDRAM. The base address of the Arbiter register space is 0040h. 9.3.1 Arbiter Register Bit Descriptions Register Name: Register Description: Register Address: Bit # Name Default 7 RQSC7 0 AR.RQSC1 Arbiter Receive Queue Size Connection 40h 6 RQSC6 0 5 RQSC5 1 4 RQSC4 1 3 RQSC3 1 2 RQSC2 1 1 RQSC1 0 0 RQSC0 1 Bits 0-7: Receive Queue Size (RQSC[0:7]) These 7 bits of the size of receive queue associated with the connection. Receive queue is for data arriving from the MAC to be sent to the WAN. The Queue address size is defined in increments of 32 x 2048 bytes. The queue size is AR.RQSC1 multiplied by 32 to determine the number of 2048 byte packets that can be stored in the queue. This queue is constructed in the external SDRAM. Note: Queue size of 0 is not allowed and should never be set. Register Name: Register Description: Register Address: Bit # Name Default 7 TQSC7 0 AR.TQSC1 Arbiter Transmit Queue Size Connection 1 41h 6 TQSC6 0 5 TQSC5 0 4 TQSC4 0 3 TQSC3 0 2 TQSC2 0 1 TQSC1 1 0 TQSC0 1 Bits 0-7: Transmit Queue Size (TQSC[0:7]) This is size of transmit queue associated with the connection. The queue address size is defined in increments of 32 packets. The range of bytes will depend on the external SDRAM connected to the DS33Z11. Transmit queue is the data queue for data arriving on the WAN that is sent to the MAC. Note that queue size of 0 is not allowed and should never be set. 80 of 169 DS33Z11 Ethernet Mapper 9.4 BERT Registers Register Name: Register Description: Register Address: Bit # Name Default 7 0 BCR BERT Control Register 80h 6 PMU 0 5 RNPL 0 4 RPIC 0 3 MPR 0 2 APRD 0 1 TNPL 0 0 TPIC 0 Bit 7: This bit must be kept low for proper operation. Bit 6: Performance Monitoring Update (PMU) This bit causes a performance monitoring update to be initiated. A 0 to 1 transition causes the performance monitoring registers to be updated with the latest data, and the counters reset (0 or 1). For a second performance monitoring update to be initiated, this bit must be set to 0, and back to 1. If PMU goes low before the PMS bit goes high, an update might not be performed. Bit 5: Receive New Pattern Load (RNPL) A zero to one transition of this bit will cause the programmed test pattern (QRSS, PTS, PLF [4:0}, PTF [4:0], and BSP [31:0]) to be loaded in to the receive pattern generator. This bit must be changed to zero and back to one for another pattern to be loaded. Loading a new pattern will forces the receive pattern generator out of the “Sync” state which causes a resynchronization to be initiated. Note: QRSS, PTS, PLF [4:0}, PTF [4:0], and BSP [31:0] must not change from the time this bit transitions from 0 to 1 until four RCLKI clock cycles after this bit transitions from 0 to 1. Bit 4: Receive Pattern Inversion Control (RPIC) When 0, the receive incoming data stream is not altered. When 1, the receive incoming data stream is inverted. Bit 3: Manual Pattern Resynchronization (MPR) A zero to one transition of this bit will cause the receive pattern generator to resynchronize to the incoming pattern. This bit must be changed to zero and back to one for another resynchronization to be initiated. Note: A manual resynchronization forces the receive pattern generator out of the “Sync” state. Bit 2: Automatic Pattern Resynchronization Disable (APRD) When 0, the receive pattern generator will automatically resynchronize to the incoming pattern if six or more times during the current 64-bit window the incoming data stream bit and the receive pattern generator output bit did not match. When 1, the receive pattern generator will not automatically resynchronize to the incoming pattern. Note: Automatic synchronization is prevented by not allowing the receive pattern generator to automatically exit the “Sync” state. Bit 1: Transmit New Pattern Load (TNPL) A zero to one transition of this bit will cause the programmed test pattern (QRSS, PTS, PLF[4:0}, PTF[4:0], and BSP[31:0]) to be loaded in to the transmit pattern generator. This bit must be changed to zero and back to one for another pattern to be loaded. Note: QRSS, PTS, PLF[4:0}, PTF[4:0], and BSP[31:0] must not change from the time this bit transitions from 0 to 1 until four TCLKI clock cycles after this bit transitions from 0 to 1. Bit 0: Transmit Pattern Inversion Control (TPIC) When 0, the transmit outgoing data stream is not altered. When 1, the transmit outgoing data stream is inverted. 81 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 BPCLR BERT Pattern Configuration Low Register 82h 6 QRSS 0 5 PTS 0 4 PLF4 0 3 PLF3 0 2 PLF2 0 1 PLF1 0 0 PLF0 0 Bit 6: QRSS Enable (QRSS) When 0, the pattern generator configuration is controlled by PTS, PLF[0:4], and PTF[0:4], and BSP[0:31]. When 1, the pattern generator configuration is forced to a QRSS pattern with a 20 17 generating polynomial of x + x + 1. The output of the pattern generator is forced to one if the next fourteen output bits are all zero. Bit 5: Pattern Type Select (PTS) When 0, the pattern is a PRBS pattern. When 1, the pattern is a repetitive pattern. Register Name: Register Description: Register Address: Bit # Name Default 7 0 BPCHR BERT Pattern Configuration High Register 83h 6 0 5 0 4 PTF4 0 3 PTF3 0 2 PTF2 0 1 PTF1 0 0 PTF0 0 Bits 4 to 0: Pattern Tap Feedback (PTF[4:0]) These five bits control the PRBS “tap” feedback of the pattern generator. The “tap” feedback is from bit y of the pattern generator (y = PTF[4:0] +1). These bits are ignored when programmed for a repetitive pattern. For a PRBS signal, the feedback is an XOR of bit n and bit y. The values possible are outlined in Section 8.15. 82 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 BSP7 0 BSPB0R BERT Pattern Byte0 Register 84h 6 BSP6 0 5 BSP5 0 4 BSP4 0 3 BSP3 0 2 BSP2 0 1 BSP1 0 0 BSP0 0 Bits 0 to 7: BERT Pattern (BSP[7:0]) Lower eight bits of 32 bits. Register description follows next register. Register Name: Register Description: Register Address: Bit # Name Default 7 BSP15 0 BSPB1R BERT Pattern Byte 1 Register 85h 6 BSP14 0 5 BSP13 0 4 BSP12 0 3 BSP11 0 2 BSP10 0 1 BSP9 0 0 BSP8 0 1 BSP17 0 0 BSP16 0 1 BSP25 0 0 BSP24 0 Bits 0 to 7: BERT Pattern (BSP[15:8]) 8 bits of 32 bits. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 BSP23 0 BSPB2R BERT Pattern Byte2 Register 86h 6 BSP22 0 5 BSP21 0 4 BSP20 0 3 BSP19 0 2 BSP18 0 Bits 0 to 7: BERT Pattern (BSP[23:16]) 8 bits of 32 bits. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 BSP31 0 BSPB3R BERT Seed/Pattern Byte3 Register 87h 6 BSP30 0 5 BSP29 0 4 BSP28 0 3 BSP27 0 2 BSP26 0 Bits 0 to 8: BERT Pattern (BSP[31:24]) Upper 8 bits of 32 bits. Register description below. BERT Pattern (BSP[31:0]) These 32 bits are the programmable seed for a transmit PRBS pattern, or the programmable pattern for a transmit or receive repetitive pattern. BSP(31) is the first bit output on the transmit side for a 32-bit repetitive pattern or 32-bit length PRBS. BSP(31) is the first bit input on the receive side for a 32bit repetitive pattern. 83 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 TEICR Transmit Error Insertion Control Register 88h 6 0 5 TIER2 0 4 TIER1 0 3 TIER0 0 2 BEI 0 1 TSEI 0 0 0 Bits 3 – 5: Transmit Error Insertion Rate (TEIR[2:0]) These three bits indicate the rate at which errors are n inserted in the output data stream. One out of every 10 bits is inverted. TEIR[2:0] is the value n. A TEIR[2:0] value th of 0 disables error insertion at a specific rate. A TEIR[2:0] value of 1 result in every 10 bit being inverted. A th TEIR[2:0] value of 2 results in every 100 bit being inverted. Error insertion starts when this register is written to with a TEIR[2:0] value that is non-zero. If this register is written to during the middle of an error insertion process, the new error rate is started after the next error is inserted. Bit 2: Bit Error Insertion Enable (BEI) When 0, single bit error insertion is disabled. When 1, single bit error insertion is enabled. Bit 1: Transmit Single Error Insert (TSEI) This bit causes a bit error to be inserted in the transmit data stream if and single bit error insertion is enabled. A 0 to 1 transition causes a single bit error to be inserted. For a second bit error to be inserted, this bit must be set to 0, and back to 1. Note: If this bit transitions more than once between error insertion opportunities, only one error is inserted. All other bits in this register besides BEI and TSEI and TIER must be reset to 0 for proper operation. Register Name: Register Description: Register Address: Bit # Name Default 7 0 BSR BERT Status Register 8Ch 6 0 5 0 4 0 3 PMS 0 2 0 1 BEC 0 0 OOS 0 Bit 3: Performance Monitoring Update Status (PMS) This bit indicates the status of the receive performance monitoring register (counters) update. This bit will transition from low to high when the update is completed. PMS is asynchronously forced low when the PMU bit goes low. TCLKI and RCLKI must be present. Bit 1: Bit Error Count (BEC) When 0, the bit error count is zero. When 1, the bit error count is one or more. Bit 0: Out Of Synchronization (OOS) When 0, the receive pattern generator is synchronized to the incoming pattern. When 1, the receive pattern generator is not synchronized to the incoming pattern. 84 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 - BSRL BERT Status Register Latched 8Eh 6 - 5 - 4 - 3 PMSL - 2 BEL - 1 BECL - 0 OOSL - Bit 3: Performance Monitor Update Status Latched (PMSL) This bit is set when the PMS bit transitions from 0 to 1. Bit 2: Bit Error Detected Latched (BEL) This bit is set when a bit error is detected. Bit 1: Bit Error Count Latched (BECL) This bit is set when the BEC bit transitions from 0 to 1. Bit 0: Out Of Synchronization Latched (OOSL) This bit is set when the OOS bit changes state. Register Name: Register Description: Register Address: Bit # Name Default 7 0 BSRIE BERT Status Register Interrupt Enable 90h 6 0 5 0 4 0 3 PMSIE 0 2 BEIE 0 1 BECIE 0 0 OOSIE 0 Bit 3: Performance Monitoring Update Status Interrupt Enable (PMSIE) This bit enables an interrupt if the PMSL bit is set. 0 = interrupt disabled 1 = interrupt enabled Bit 2: Bit Error Interrupt Enable (BEIE) This bit enables an interrupt if the BEL bit is set. 0 = interrupt disabled 1 = interrupt enabled Bit 1: Bit Error Count Interrupt Enable (BECIE) This bit enables an interrupt if the BECL bit is set. 0 = interrupt disabled 1 = interrupt enabled Bit 0: Out Of Synchronization Interrupt Enable (OOSIE) This bit enables an interrupt if the OOSL bit is set. 0 = interrupt disabled 1 = interrupt enabled 85 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 BEC7 0 RBECB0R Receive Bit Error Count Byte 0 Register 94h 6 BEC6 0 5 BEC5 0 4 BEC4 0 3 BEC3 0 2 BEC2 0 1 BEC1 0 0 BEC0 0 Bits 0 - 7: Bit Error Count (BEC[0:7]) Lower eight bits of 24 bits. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 BEC15 0 RBECB1R Receive Bit Error Count Byte 1 Register 95h 6 BEC14 0 5 BEC13 0 4 BEC12 0 3 BEC11 0 2 BEC10 0 1 BEC9 0 0 BEC8 0 Bits 0 - 7: Bit Error Count (BEC[8:15]) Eight bits of a 24 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 BEC23 0 RBECR2 Receive Bit Error Count Byte 2 Register 96h 6 BEC22 0 5 BEC21 0 4 BEC20 0 3 BEC19 0 2 BEC18 0 1 BEC17 0 0 BEC16 0 Bits 0 - 7: Bit Error Count (BEC[16:23]) Upper 8-bits of the register. Bit Error Count (BEC[0:23]) These twenty-four bits indicate the number of bit errors detected in the incoming data stream. This count stops incrementing when it reaches a count of FF FFFFh. The associated bit error counter will not incremented when an OOS condition exists. Register Name: Register Description: Register Address: Bit # Name Default 7 BC7 0 RBCB0 Receive Bit Count Byte 0 Register 98h 6 BC6 0 5 BC5 0 4 BC4 0 3 BC3 0 2 BC2 0 Bits 0 - 7: Bit Count (BC[0:7]) Eight bits of a 32 bit value. Register description below. Register Name: Register Description: Register Address: RBCB1 Receive Bit Count Byte 1 Register #1 99h 86 of 169 1 BC1 0 0 BC0 0 DS33Z11 Ethernet Mapper Bit # Name Default 7 BC15 0 6 BC14 0 5 BC13 0 4 BC12 0 3 BC11 0 2 BC10 0 1 BC9 0 0 BC8 0 1 BC17 0 0 BC16 0 Bits 0 - 7: Bit Count (BC[8:15]) Eight bits of a 32 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 BC23 0 RBCB2 Receive Bit Count Byte 2 Register 9Ah 6 BC22 0 5 BC21 0 4 BC20 0 3 BC19 0 2 BC18 0 Bits 0 - 7: Bit Count (BC[16:23]) Eight bits of a 32 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 BC31 0 RBCB3 Receive Bit Count Byte 3 Register 9Bh 6 BC30 0 5 BC29 0 4 BC28 0 3 BC27 0 2 BC26 0 1 BC25 0 0 BC24 0 Bits 0 - 7: Bit Count (BC[24:31]) Upper 8-bits of the register. Bit Count (BC[0:31]) These thirty-two bits indicate the number of bits in the incoming data stream. This count stops incrementing when it reaches a count of FFFF FFFFh. The associated bit counter will not incremented when an OOS condition exists. 87 of 169 DS33Z11 Ethernet Mapper 9.5 Serial Interface Registers The Serial Interface contains the Serial HDLC transport circuitry and the associated serial port. The Serial Interface register map consists of registers that are common functions, transmit functions, and receive functions. Bits that are underlined are read-only; all other bits can be written. All reserved registers and bits with “-“ designation should be written to zero, unless specifically noted in the register definition. When read, the information from reserved registers and bits designated with “-“ should be discarded. Counter registers are updated by asserting (low to high transition) the associated performance monitoring update signal (xxPMU). During the counter register update process, the associated performance monitoring status signal (xxPMS) is deasserted. The counter register update process consists of loading the counter register with the current count, resetting the counter, forcing the zero count status indication low for one clock cycle, and then asserting xxPMS. No events are missed during this update procedure. A latched bit is set when the associated event occurs, and remains set until it is cleared by reading. Once cleared, a latched bit will not be set again until the associated event occurs again. Reserved configuration bits and registers should be written to zero. 9.5.1 Serial Interface Transmit and Common Registers Serial Interface Transmit Registers are used to control the HDLC transmitter associated with each Serial Interface. The register map is shown in the following table. Note that throughout this document the HDLC processor is also referred to as a “packet processor.” 9.5.2 Serial Interface Transmit Register Bit Descriptions Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.TSLCR Transmit Serial Interface Configuration Register 0C0h 6 0 5 0 4 0 3 0 2 0 1 0 0 TDENPLT 0 Bit 0: Transmit Data Enable Polarity (TDENPLT) If set to 1, TDEN is active low for enable. In the default mode, when TDEN is logic high, the data is enabled and output by the DS33Z11. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.RSTPD Serial Interface Reset Register 0C1h 6 0 5 0 4 0 3 0 2 0 1 RESET 0 0 0 Bit 1: RESET If this bit set to 1, the Data Path and Control and Status for this interface are reset. The Serial Interface is held in Reset as long as this bit is high. This bit must be high for a minimum of 200 nsec for a valid reset to occur. 88 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.LPBK Serial Interface Loopback Control Register 0C2h 6 0 5 0 4 0 3 0 2 0 1 0 0 QLP 0 Bit 0: Queue Loopback Enable (QLP) If this bit set to 1, data received on the Serial Interface is looped back to the Serial Interface transmitter. Received data will not be sent from the Serial Interface to the Ethernet Interface. Buffered packet data will remain in queue until the loopback is removed. 9.5.3 Transmit HDLC Processor Registers Register Name: Register Description: Register Address: LI.TPPCL Transmit Packet Processor Control Low Register 0C4h Bit # 7 6 5 4 3 2 1 Name TFAD TF16 TIFV TSD TBRE Default 0 0 0 0 0 0 0 Note: The user should take care not to modify this register value during packet error insertion. 0 TIAEI 0 Bits 5 - 6: Transmit FCS Append Disable (TFAD) – This bit controls whether or not an FCS is appended to the end of each packet. When equal to 0, the calculated FCS bytes are appended to packets. When set to 1, packets are transmitted without FCS. In X.86 Mode, FCS is always 32 bits and is always appended to the packet. Bit 4: Transmit FCS-16 Enable (TF16) – When 0, the FCS processing uses a 32-bit FCS. When 1, the FCS processing uses a 16-bit FCS. In X.86 Mode, 32-bit FCS processing is enabled. Bit 3: Transmit Bit Synchronous Inter-frame Fill Value (TIFV) – When 0, inter-frame fill is done with the flag sequence (7Eh). When 1, inter-frame fill is done with all '1's. This bit is ignored in byte synchronous mode. In X.86 mode the interframe flag is always 7E. 43 Bit 2: Transmit Scrambling Disable (TSD) – When equal to 0, X +1 scrambling is performed. When set to 1, scrambling is disabled. Note that in hardware mode, transmit scrambling is controlled by the SCD hardware pin. Bit 1: Transmit Bit Reordering Enable (TBRE) – When equal to 0, bit reordering is disabled (The first bit transmitted is from the MSB of the transmit FIFO byte TFD [7]). When set to 1, bit reordering is enabled (The first bit transmitted is from the LSB of the transmit FIFO byte TFD [0]). Note that this function can be controlled in Hardware mode with the BREO hardware pin. Bit 0: Transmit Initiate Automatic Error Insertion (TIAEI) – This write-only bit initiates error insertion. See the LI.TEPHC register definition for details of usage. 89 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 TIFG7 0 LI.TIFGC Transmit Inter-Frame Gapping Control Register 0C5h 6 TIFG6 0 5 TIFG5 0 4 TIFG4 0 3 TIFG3 0 2 TIFG2 0 1 TIFG1 0 0 TIFG0 1 Bits 0 - 7: Transmit Inter-Frame Gapping (TIFG[7:0]) – These eight bits indicate the number of additional flags and bytes of inter-frame fill to be inserted between packets. The number of flags and bytes of inter-frame fill between packets is at least the value of TIFG[7:0] plus 1. Note: If inter-frame fill is set to all 1’s, a TFIG value of 2 or 3 will result in a flag, two bytes of 1’s, and an additional flag between packets. Register Name: Register Description: Register Address: Bit # Name Default 7 TPEN7 0 LI.TEPLC Transmit Errored Packet Low Control Register 0C6h 6 TPEN6 0 5 TPEN5 0 4 TPEN4 0 3 TPEN3 0 2 TPEN2 0 1 TPEN1 0 0 TPEN0 0 Bits 0 – 7: Transmit Errored Packet Insertion Number (TPEN[7:0]) – These eight bits indicate the total number of errored packets to be transmitted when triggered by TIAEI. Error insertion will end after this number of errored packets have been transmitted. A value of FFh results in continuous errored packet insertion at the specified rate. 90 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 MEIMS 0 LI.TEPHC Transmit Errored Packet High Control Register 0C7h 6 TPER6 0 5 TPER5 0 4 TPER4 0 3 TPER3 0 2 TPER2 0 1 TPER1 0 0 TPER0 0 Bit 7: Manual Error Insert Mode Select (MEIMS) – When 0, the transmit manual error insertion signal (TMEI) will not cause errors to be inserted. When 1, TMEI will cause an error to be inserted when it transitions from a 0 to a 1. Note: Enabling TMEI does not disable error insertion using TCER[6:0] and TCEN[7:0]. Bits 0 – 6: Transmit Errored Packet Insertion Rate (TPER[6:0]) – These seven bits indicate the rate at which y errored packets are to be output. One out of every x * 10 packets is to be an errored packet. TPER[3:0] is the value x, and TPER[6:4] is the value y which has a maximum value of 6. If TPER[3:0] has a value of 0h errored 6 packet insertion is disabled. If TPER[6:4] has a value of 6xh or 7xh the errored packet rate is x * 10 . A TPER[6:0] th value of 01h results in every packet being errored. A TPER[6:0] value of 0Fh results in every 15 packet being th errored. A TPER[6:0] value of 11h results in every 10 packet being errored. To initiate automatic error insertion, use the following routine: 1) Configure LI.TEPLC and LI.TEPHC for the desired error insertion mode. 2) Write the LI.TPPCL.TIAEI bit to 1. Note that this bit is write-only. 3) If not using continuous error insertion (LI.TPELC is not equal to FFh), the user should monitor the LI.TPPSR.TEPF bit for completion of the error insertion. If interrupt on completion of error insertion is enabled (LI.TPPSRIE.TEPFIE = 1), the user only needs to wait for the interrupt condition. 4) Proceed with the cleanup routine listed below. Cleanup routine: 1) Write LI.TEPLC and LI.TEPHC each to 00h. 2) Write the LI.TPPCL.TIAEI bit to 0. 91 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.TPPSR Transmit Packet Processor Status Register 0C8h 6 0 5 0 4 0 3 0 2 0 1 0 0 TEPF 0 Bit 0: Transmit Errored Packet Insertion Finished (TEPF) – This bit is set when the number of errored packets indicated by the TPEN[7:0] bits in the TEPC register have been transmitted. This bit is cleared when errored packet insertion is disabled, or a new errored packet insertion process is initiated. Register Name: Register Description: Register Address: Bit # Name Default 7 - LI.TPPSRL Transmit Packet Processor Status Register Latched 0C9h 6 - 5 - 4 - 3 - 2 - 1 - 0 TEPFL - Bit 0: Transmit Errored Packet Insertion Finished Latched (TEPFL) – This bit is set when the TEPF bit in the TPPSR register transitions from zero to one. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.TPPSRIE Transmit Packet Processor Status Register Interrupt Enable 0CAh 6 0 5 0 4 0 3 0 2 0 1 0 0 TEPFIE 0 Bit 0: Transmit Errored Packet Insertion Finished Interrupt Enable (TEPFIE) – This bit enables an interrupt if the TEPFL bit in the LI.TPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled 92 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 TPC7 0 LI.TPCR0 Transmit Packet Count Byte 0 0CCh 6 TPC6 0 5 TPC5 0 4 TPC4 0 3 TPC3 0 2 TPC2 0 1 TPC1 0 0 TPC0 0 Bits 0 – 7: Transmit Packet Count (TPC[7:0]) – Eight bits of 24 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 TPC15 0 LI.TPCR1 Transmit Packet Count Byte 1 0CDh 6 TPC14 0 5 TPC13 0 4 TPC12 0 3 TPC11 0 2 TPC10 0 1 TPC9 0 0 TPC8 0 Bits 0 – 7: Transmit Packet Count (TPC[15:8]) – Eight bits of 24 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 TPC23 0 LI.TPCR2 Transmit Packet Count Byte 2 0CEh 6 TPC22 0 5 TPC21 0 4 TPC20 0 3 TPC19 0 2 TPC18 0 1 TPC17 0 0 TPC16 0 Bits 0 – 7: Transmit Packet Count (TPC[23:16]) – These twenty-four bits indicate the number of packets extracted from the Transmit FIFO and output in the outgoing data stream. 93 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 TBC7 0 LI.TBCR0 Transmit Byte Count Byte 0 0D0h 6 TBC6 0 5 TBC5 0 4 TBC4 0 3 TBC3 0 2 TBC2 0 1 TBC1 0 0 TBC0 0 Bits 0 – 7: Transmit Byte Count (TBC[0:7]) – Eight bits of 32 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 TBC15 0 LI.TBCR1 Transmit Byte Count Byte 1 0D1h 6 TBC14 0 5 TBC13 0 4 TBC12 0 3 TBC11 0 2 TBC10 0 1 TBC9 0 0 TBC8 0 Bits 0 – 7: Transmit Byte Count (TBC[15:8]) - Eight bits of 32 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 TBC23 0 LI.TBCR2 Transmit Byte Count Byte 2 0D2h 6 TBC22 0 5 TBC21 0 4 TBC20 0 3 TBC19 0 2 TBC18 0 1 TBC17 0 0 TBC16 0 Bits 0 – 7: Transmit Byte Count (TBC[23:16]) - Eight bits of 32 bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 TBC31 0 LI.TBCR3 Transmit Byte Count Byte 3 0D3h 6 TBC30 0 5 TBC29 0 4 TBC28 0 3 TBC27 0 2 TBC26 0 1 TBC25 0 0 TBC24 0 Bits 0 – 7: Transmit Byte Count (TBC[31:24]) – These thirty-two bits indicate the number of packet bytes inserted in the outgoing data stream. 94 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.TMEI Transmit Manual Error Insertion 0D4h 6 0 5 0 4 0 3 0 2 0 1 0 0 TMEI 0 Bit 0: Transmit Manual Error Insertion (TMEI) A zero to one transition will insert a single error in the Transmit direction. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.THPMUU Serial Interface Transmit HDLC PMU Update Register 0D6h 6 0 5 0 4 0 3 0 2 0 1 0 0 TPMUU 0 Bit 0: Transmit PMU Update (TPMUU) This signal causes the transmit cell/packet processor block performance monitoring registers (counters) to be updated. A 0 to 1 transition causes the performance monitoring registers to be updated with the latest data, and the counters reset (0 or 1). This update updates performance monitoring counters for the Serial Interface. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.THPMUS Serial Interface Transmit HDLC PMU Update Status Register 0D7h 6 0 5 0 4 0 3 0 2 0 1 0 0 TPMUS 0 Bit 0: Transmit PMU Update Status (TPMUS) This bit is set when the Transmit PMU Update is completed. This bit is cleared when TPMUU is reset. 95 of 169 DS33Z11 Ethernet Mapper 9.5.4 X.86 Registers X.86 Transmit and common Registers are used to control the operation of the X.86 encoder and decoder. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.TX86EDE X.86 Encoding Decoding Enable 0D8h 6 0 5 0 4 0 3 0 2 0 1 0 0 X86ED 0 Bit 0: X.86 Encoding Decoding (X86ED) If this bit is set to 1, X.86 encoding and decoding is enabled for the Transmit and Receive paths. The MAC Frame is encapsulated in the X.86 Frame for Transmit and the X.86 headers are checked for in the received data. If X.86 functionality is selected, the X.86 receiver byte boundary is provided by the RBSYNC signal and the DS33Z11 provides the transmit byte synchronization TBSYNC. No HDLC encapsulation is performed. Register Name: Register Description: Register Address: Bit # Name Default 7 X86TRA7 0 LI.TRX86A Transmit Receive X.86 Address 0D9h 6 X86TRA6 0 5 X86TRA5 0 4 X86TRA4 0 3 X86TRA3 0 2 X86TRA2 1 1 X86TRA1 0 0 X86TRA0 0 Bits 0 - 7: X86 Transmit Receive Address (X86TRA0-7) This is the address field for the X.86 transmitter and for the receiver. The register default value is 0x04. Register Name: Register Description: Register Address: Bit # Name Default 7 X86TRC7 0 LI.TRX8C Transmit Receive X.86 Control 0DAh 6 X86TRC6 0 5 X86TRC5 0 4 X86TRC4 0 3 X86TRC3 0 2 X86TRC2 0 1 X86TRC1 1 0 X86TRC0 1 Bits 0 - 7: X86 Transmit Receive Control (X86TRC0-7) This is the control field for the X.86 transmitter and expected value for the receiver. The register is reset to 0x03 Register Name: Register Description: Register Address: Bit # Name Default LI.TRX86SAPIH Transmit Receive X.86 SAPIH 0DBh 7 6 5 4 3 2 1 0 TRSAPIH7 TRSAPIH6 TRSAPIH5 TRSAPIH4 TRSAPIH3 TRSAPIH2 TRSAPIH1 TRSAPIH0 1 1 1 1 1 1 1 0 Bits 0 - 7: X86 Transmit Receive Address (TRSAPIH0-7) This is the address field for the X.86 transmitter and expected for the receiver. The register is reset to 0xfe. 96 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default LI.TRX86SAPIL Transmit Receive X.86 SAPIL 0DCh 7 6 5 4 3 2 1 0 TRSAPIL7 TRSAPIL6 TRSAPIL5 TRSAPIL4 TRSAPIL3 TRSAPIL2 TRSAPIL1 TRSAPIL0 0 0 0 0 0 0 0 1 Bits 0 – 7: X86 Transmit Receive Control (TRSAPIL0-7) This is the address field for the X.86 transmitter and expected value for the receiver. The register is reset to 0x01 Register Name: Register Description: Register Address: Bit # Name Default 7 CIRE 0 LI.CIR Committed Information Rate 0DDh 6 CIR6 0 5 CIR5 0 4 CIR4 0 3 CIR3 0 2 CIR2 0 1 CIR1 0 0 CIR0 1 Bit 7: Committed Information Rate Enable (CIRE) Set this bit to 1 to enable the Committed Information Rate Controller feature. Bits 0 – 6: Committed Information Rate (CIR0-6) These bits provide the value for the committed information rate. The value is multiplied by 500 kbps to get the CIR value. The user must ensure that the CIR value is less than or equal to the maximum Serial Interface transmit rate. The valid range is from 1 to 104. Any values outside this range will result in unpredictable behavior. Note that a value of 104 translates to a 52 Mbps line rate. Hence if the CIR is above the line rate, the rate is not restricted by the CIR. For instance, if using a T1 line and the CIR is programmed with a value of 104, it has no effect in restricting the rate. 97 of 169 DS33Z11 Ethernet Mapper 9.5.5 Receive Serial Interface Serial Receive Registers are used to control the HDLC Receiver associated with each Serial Interface. Note that throughout this document HDLC Processor is also referred to as “Packet Processor”. The receive packet processor block has seventeen registers. 9.5.5.1 Register Bit Descriptions Register Name: LI.RSLCR Register Description: Receive Serial Interface Configuration Register Register Address: 100h Bit # Name Default 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 RDENPLT 0 Bit 0: Receive Data Enable Polarity (RDENPLT) Receive Data Enable Polarity. If set to 1, RDEN Low enables reception of the bit. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.RPPCL Receive Packet Processor Control Low Register 101h 6 0 5 RFPD 0 4 RF16 0 3 RFED 0 2 RDD 0 1 RBRE 0 0 RCCE 0 Bit 5: Receive FCS Processing Disable (RFPD) – When equal to 0, FCS processing is performed and FCS is appended to packets. When set to 1, FCS processing is disabled (the packets do not have an FCS appended). In X.86 mode, FCS processing is always enabled. Bit 4: Receive FCS-16 Enable (RF16) – When 0, the error checking circuit uses a 32-bit FCS. When 1, the error checking circuit uses a 16-bit FCS. This bit is ignored when FCS processing is disabled. In X.86 mode, the FCS is always 32 bits. Bit 3: Receive FCS Extraction Disable (RFED) – When 0, the FCS bytes are discarded. When 1, the FCS bytes are passed on. This bit is ignored when FCS processing is disabled. In X.86 mode, FCS bytes are discarded. 43 Bit 2: Receive Descrambling Disable (RDD) – When equal to 0, X +1 descrambling is performed. When set to 1, descrambling is disabled. Bit 1: Receive Bit Reordering Enable (RBRE) – When equal to 0, reordering is disabled and the first bit received is expected to be the MSB DT [7] of the byte. When set to 1, bit reordering is enabled and the first bit received is expected to be the LSB DT [0] of the byte. Note that function is controlled by the BREO in Hardware Mode. Bit 0: Receive Clear Channel Enable (RCCE) – When equal to 0, packet processing is enabled. When set to 1, the device is in clear channel mode and all packet-processing functions except descrambling and bit reordering are disabled. 98 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 RMX7 1 LI.RMPSCL Receive Maximum Packet Size Control Low Register 102h 6 RMX6 1 5 RMX5 1 4 RMX4 0 3 RMX3 0 2 RMX2 0 1 RMX1 0 0 RMX0 0 Bits 0 - 7: Receive Maximum Packet Size (RMX[7:0]) Eight bits of a sixteen bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RMX15 0 LI.RMPSCH Receive Maximum Packet Size Control High Register 103h 6 RMX14 0 5 RMX13 0 4 RMX12 0 3 RMX11 0 2 RMX10 1 1 RMX9 1 0 RMX8 1 Bits 0-7: Receive Maximum Packet Size (RMX[8:15]) These sixteen bits indicate the maximum allowable packet size in bytes. The size includes the FCS bytes, but excludes bit/byte stuffing. Note: If the maximum packet size is less than the minimum packet size, all packets are discarded. When packet processing is disabled, these sixteen bits indicate the "packet" size the incoming data is to be broken into. The maximum packet size allowable is 2016 bytes plus the FCS bytes. Any values programmed that are greater than 2016 + FCS will have the same effect as 2016+ FCS value. In X.86 mode, the X.86 encapsulation bytes are included in maximum size control. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.RPPSR Receive Packet Processor Status Register 104h 6 0 5 0 4 0 3 0 2 REPC 0 1 RAPC 0 0 RSPC 0 Bit 2: Receive FCS Errored Packet Count (REPC) This read only bit indicates that the receive FCS errored packet count is non-zero. Bit 1: Receive Aborted Packet Count (RAPC) This read only bit indicates that the receive aborted packet count is non-zero. Bit 0: Receive Size Violation Packet Count (RSPC) This read only bit indicates that the receive size violation packet count is non-zero. 99 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 REPL - LI.RPPSRL Receive Packet Processor Status Register Latched 105h 6 RAPL - 5 RIPDL - 4 RSPDL - 3 RLPDL - 2 REPCL - 1 RAPCL - 0 RSPCL - Bit 7: Receive FCS Errored Packet Latched (REPL) This bit is set when a packet with an errored FCS is detected. Bit 6: Receive Aborted Packet Latched (RAPL) This bit is set when a packet with an abort indication is detected. Bit 5: Receive Invalid Packet Detected Latched (RIPDL) This bit is set when a packet with a non-integer number of bytes is detected. Bit 4: Receive Small Packet Detected Latched (RSPDL) This bit is set when a packet smaller than the minimum packet size is detected. Bit 3: Receive Large Packet Detected Latched (RLPDL) This bit is set when a packet larger than the maximum packet size is detected. Bit 2: Receive FCS Errored Packet Count Latched (REPCL) This bit is set when the REPC bit in the RPPSR register transitions from zero to one. Bit 1: Receive Aborted Packet Count Latched (RAPCL) This bit is set when the RAPC bit in the RPPSR register transitions from zero to one. Bit 0: Receive Size Violation Packet Count Latched (RSPCL) This bit is set when the RSPC bit in the RPPSR register transitions from zero to one. 100 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 REPIE 0 LI.RPPSRIE Receive Packet Processor Status Register Interrupt Enable 106h 6 RAPIE 0 5 RIPDIE 0 4 RSPDIE 0 3 RLPDIE 0 2 REPCIE 0 1 RAPCIE 0 0 RSPCIE 0 Bit 7: Receive FCS Errored Packet Interrupt Enable (REPIE) This bit enables an interrupt if the REPL bit in the LI.RPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled Bit 6: Receive Aborted Packet Interrupt Enable (RAPIE) This bit enables an interrupt if the RAPL bit in the LI.RPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled Bit 5: Receive Invalid Packet Detected Interrupt Enable (RIPDIE) This bit enables an interrupt if the RIPDL bit in the LI.RPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled Bit 4: Receive Small Packet Detected Interrupt Enable (RSPDIE) This bit enables an interrupt if the RSPDL bit in the LI.RPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled Bit 3: Receive Large Packet Detected Interrupt Enable (RLPDIE) This bit enables an interrupt if the RLPDL bit in the LI.RPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled Bit 2: Receive FCS Errored Packet Count Interrupt Enable (REPCIE) This bit enables an interrupt if the REPCL bit in the LI.RPPSRL register is set. Must be set low when the packets do not have an FCS appended. 0 = interrupt disabled 1 = interrupt enabled Bit 1: Receive Aborted Packet Count Interrupt Enable (RAPCIE) This bit enables an interrupt if the RAPCL bit in the LI.RPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled Bit 0: Receive Size Violation Packet Count Interrupt Enable (RSPCIE) This bit enables an interrupt if the RSPCL bit in the LI.RPPSRL register is set. 0 = interrupt disabled 1 = interrupt enabled 101 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 RPC7 0 LI.RPCB0 Receive Packet Count Byte 0 Register 108h 6 RPC6 0 5 RPC5 0 4 RPC4 0 3 RPC3 0 2 RPC2 0 1 RPC1 0 0 RPC0 0 Bits 0 - 7: Receive Packet Count (RPC [7:0]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RPC15 0 LI.RPCB1 Receive Packet Count Byte 1 Register 109h 6 RPC14 0 5 RPC13 0 4 RPC12 0 3 RPC11 0 2 RPC10 0 1 RPC09 0 0 RPC08 0 Bits 0 - 7: Receive Packet Count (RPC [15:8]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RPC23 0 LI.RPCB2 Receive Packet Count Byte 2 Register 10Ah 6 RPC22 0 5 RPC21 0 4 RPC20 0 3 RPC19 0 2 RPC18 0 1 RPC17 0 0 RPC16 0 Bits 0 – 7: Receive Packet Count (RPC [23:16]) These twenty-four bits indicate the number of packets stored in the receive FIFO without an abort indication. Note: Packets discarded due to system loopback or an overflow condition are included in this count. This register is valid when clear channel is enabled. 102 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 RFPC7 0 LI.RFPCB0 Receive FCS Errored Packet Count Byte 0 Register 10Ch 6 RFPC6 0 5 RFPC5 0 4 RFPC4 0 3 RFPC3 0 2 RFPC2 0 1 RFPC1 0 0 RFPC0 0 Bits 0 – 7: Receive FCS Errored Packet Count (RFPC[7:0]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RFPC15 0 LI.RFPCB1 Receive FCS Errored Packet Count Byte 1 Register 10Dh 6 RFPC14 0 5 RFPC13 0 4 RFPC12 0 3 RFPC11 0 2 RFPC10 0 1 RFPC9 0 0 RFPC8 0 Bits 0 – 7: Receive FCS Errored Packet Count (RFPC[15:8]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RFPC23 0 LI.RFPCB2 Receive FCS Errored Packet Count Byte 2 Register 10Eh 6 RFPC22 0 5 RFPC21 0 4 RFPC20 0 3 RFPC19 0 2 RFPC18 0 1 RFPC17 0 0 RFPC16 0 Receive FCS Errored Packet Count (RFPC[23:16]) These twenty-four bits indicate the number of packets received with an FCS error. The byte count for these packets is included in the receive aborted byte count register REBCR. 103 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 RAPC7 0 LI.RAPCB0 Receive Aborted Packet Count Byte 0 Register 110h 6 RAPC6 0 5 RAPC5 0 4 RAPC4 0 3 RAPC3 0 2 RAPC2 0 1 RAPC1 0 0 RAPC0 0 Bits 0 - 7: Receive Aborted Packet Count (RAPC [7:0]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RAPC15 0 LI.RAPCB1 Receive Aborted Packet Count Byte 1 Register 111h 6 RAPC14 0 5 RAPC13 0 4 RAPC12 0 3 RAPC11 0 2 RAPC10 0 1 RAPC9 0 0 RAPC8 0 Bits 0 - 7: Receive Aborted Packet Count (RAPC[15:8]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RAPC23 0 LI.RAPCB2 Receive Aborted Packet Count Byte 2 Register 112h 6 RAPC22 0 5 RAPC21 0 4 RAPC20 0 3 RAPC19 0 2 RAPC18 0 1 RAPC17 0 0 RAPC16 0 Bits 0 – 7: Receive Aborted Packet Count (RAPC [23:16]) The twenty-four bit value from these three registers indicates the number of packets received with a packet abort indication. The byte count for these packets is included in the receive aborted byte count register REBCR. 104 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 RSPC7 0 LI.RSPCB0 Receive Size Violation Packet Count Byte 0 Register 114h 6 RSPC6 0 5 RSPC5 0 4 RSPC4 0 3 RSPC3 0 2 RSPC2 0 1 RSPC1 0 0 RSPC0 0 Bits 0 - 7: Receive Size Violation Packet Count (RSPC [7:0]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RSPC15 0 LI.RSPCB1 Receive Size Violation Packet Count Byte 1 Register 115h 6 RSPC14 0 5 RSPC13 0 4 RSPC12 0 3 RSPC11 0 2 RSPC10 0 1 RSPC9 0 0 RSPC8 0 Bits 0 - 7: Receive Size Violation Packet Count (RSPC [15:8]) Eight bits of a 24-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RSPC23 0 LI.RSPCB2 Receive Size Violation Packet Count Byte 2 Registers 116h 6 RSPC22 0 5 RSPC21 0 4 RSPC20 0 3 RSPC19 0 2 RSPC18 0 1 RSPC17 0 0 RSPC16 0 Bits 0 – 7: Receive Size Violation Packet Count (RSPC [23:16]) These twenty-four bits indicate the number of packets received with a packet size violation (below minimum, above maximum, or non-integer number of bytes). The byte count for these packets is included in the receive aborted byte count register REBCR. 105 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 RBC7 0 LI.RBC0 Receive Byte Count 0 Register 118h 6 RBC6 0 5 RBC5 0 4 RBC4 0 3 RBC3 0 2 RBC2 0 1 RBC1 0 0 RBC0 0 Bits 0 - 7: Receive Byte Count (RBC [7:0]) Eight bits of a 32-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RBC15 0 LI.RBC1 Receive Byte Count 1 Register 119h 6 RBC14 0 5 RBC13 0 4 RBC12 0 3 RBC11 0 2 RBC10 0 1 RBC9 0 0 RBC8 0 Bits 0 - 7: Receive Byte Count (RBC [15:8]) Eight bits of a 32-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RBC23 0 LI.RBC2 Receive Byte Count 2 Register 11Ah 6 RBC22 0 5 RBC21 0 4 RBC20 0 3 RBC19 0 2 RBC18 0 1 RBC17 0 0 RBC16 0 Bits 0 - 7: Receive Byte Count (RBC [23:16]) Eight bits of a 32-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RBC31 0 LI.RBC3 Receive Byte Count 3 Register 11Bh 6 RBC30 0 5 RBC29 0 4 RBC28 0 3 RBC27 0 2 RBC26 0 1 RBC25 0 0 RBC24 0 Bits 0 – 7: Receive Byte Count (RBC [31:24]) These thirty-two bits indicate the number of bytes contained in packets stored in the receive FIFO without an abort indication. Note: Bytes discarded due to FCS extraction, system loopback, FIFO reset, or an overflow condition may be included in this count. 106 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 REBC7 0 LI.RAC0 Receive Aborted Byte Count 0 Register 11Ch 6 REBC6 0 5 REBC5 0 4 REBC4 0 3 REBC3 0 2 REBC2 0 1 REBC1 0 0 REBC0 0 Bits 0 - 7: Receive Aborted Byte Count (RBC [7:0]) Eight bits of a 32-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 REBC15 0 LI.RAC1 Receive Aborted Byte Count 1 Register 11Dh 6 REBC14 0 5 REBC13 0 4 REBC12 0 3 REBC11 0 2 REBC10 0 1 REBC9 0 0 REBC8 0 Bits 0 - 7: Receive Aborted Byte Count (RBC [15:8]) Eight bits of a 32-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 REBC23 0 LI.RAC2 Receive Aborted Byte Count 2 Register 11Eh 6 REBC22 0 5 REBC21 0 4 REBC20 0 3 REBC19 0 2 REBC18 0 1 REBC17 0 0 REBC16 0 Bits 0 - 7: Receive Aborted Byte Count (RBC [16:23]) Eight bits of a 32-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 REBC31 0 LI.RAC3 Receive Aborted Byte Count 3 Register 11Fh 6 REBC30 0 5 REBC29 0 4 REBC28 0 3 REBC27 0 2 REBC26 0 1 REBC25 0 0 REBC24 0 Bits 0 – 7: Receive Aborted Byte Count (REBC[31:24]) These thirty-two bits indicate the number of bytes contained in packets stored in the receive FIFO with an abort indication. Note: Bytes discarded due to FCS extraction, system loopback, FIFO reset, or an overflow condition may be included in this count. 107 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default LI.RHPMUU Serial Interface Receive HDLC PMU Update Register 120h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 RPMUU 0 Bit 0: Receive PMU Update (RPMUU) This signal causes the receive cell/packet processor block performance monitoring registers (counters) to be updated. A 0 to 1 transition causes the performance monitoring registers to be updated with the latest data, and the counters reset (0 or 1). This update updates performance-monitoring counters for the Serial Interface. Register Name: Register Description: Register Address: Bit # Name Default LI.RHPMUS Serial Interface Receive HDLC PMU Update Status Register 121h 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 RPMUUS 0 Bit 0: Receive PMU Update Status (RPMUUS) This bit is set when the Transmit PMU Update is completed. This bit is cleared when RPMUU is set to 0. Register Name: Register Description: Register Address: Bit # Name Default 7 - LI.RX86S Receive X.86 Latched Status Register 122h 6 - 5 - 4 - 3 SAPIHNE - 2 SAPILNE - 1 CNE - 0 ANE - Bit 3: SAPI High is not equal to LI.TRX86SAPIH Latched Status (SAPIHNE) This latched status bit is set if SAPIH is not equal to LI.TRX86SAPIH. This latched status bit is cleared upon read. Bit 2: SAPI Low is not equal to LI.TRX86SAPIL Latched Status (SAPILNE) This latched status bit is set if SAPIL is not equal to LI.TRX86SAPIL. This latched status bit is cleared upon read. Bit 1: Control is not equal to LI.TRX8C (CNE) This latched status bit is set if the control field is not equal to LI.TRX8C. This latched status bit is cleared upon read. Bit 0: Address is not equal to LI.TRX86A (ANE) This latched status bit is set if the X.86 Address field is not equal to LI.TRX86A. This latched status bit is cleared upon read. 108 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.RX86LSIE Receive X.86 Interrupt Enable 123h 6 0 5 0 4 0 3 SAPINE01IM 0 2 SAPINEFEIM 0 1 CNE3LIM 0 0 ANE4IM 0 Bit 3: SAPI Octet not equal to LI.TRX86SAPIH Interrupt Enable (SAPINE01IM) If this bit is set to 1, LI.RX86S.SAPIHNE will generate an interrupt. Bit 2: SAPI Octet not equal to LI.TRX86SAPIL Interrupt Enable (SAPINEFEIM) If this bit is set to 1, LI.RX86S.SAPILNE will generate an interrupt. Bit 1: Control not equal to LI.TRX8C Interrupt Enable (CNE3LIM) If this bit is set to 1, LI.RX86S.CNE will generate an interrupt. Bit 0: Address not equal to LI.TRX86A Interrupt Enable (ANE4IM) If this bit is set to 1, LI.RX86S.ANE will generate an interrupt. Register Name: Register Description: Register Address: Bit # Name Default 7 TQLT7 0 LI.TQLT Serial Interface Transmit Queue Low Threshold (Watermark) 124h 6 TQLT6 0 5 TQLT5 0 4 TQLT4 0 3 TQLT3 0 2 TQLT2 0 1 TQLT1 0 0 TQLT0 0 Bits 0 - 7: Transmit Queue Low Threshold (TQLT[0:7]) The transmit queue low threshold for the connection, in increments of 32 packets of 2048 bytes each. The value of this register is multiplied by 32 * 2048 bytes to determine the byte location of the threshold. Note that the transmit queue is for data that was received from the Serial Interface to be sent to the Ethernet Interface. 109 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 TQHT7 0 LI.TQHT Serial Interface Transmit Queue High Threshold (Watermark) 125h 6 TQHT6 0 5 TQHT5 0 4 TQHT4 0 3 TQHT3 0 2 TQHT2 0 1 TQHT1 0 0 TQHT0 0 Bits 0 – 7: Transmit Queue High Threshold (TQHT[0:7]) The transmit queue high threshold for the connection, in increments of 32 packets of 2048 bytes each. The value of this register is multiplied by 32 * 2048 bytes to determine the byte location of the threshold. Note that the transmit queue is for data that was received from the Serial Interface to be sent to the Ethernet Interface. Register Name: Register Description: Register Address: Bit # Name Default 7 0 LI.TQTIE Serial Interface Transmit Queue Cross Threshold Interrupt Enable 126h 6 0 5 0 4 0 3 TFOVFIE 0 2 TQOVFIE 0 1 TQHTIE 0 0 TQLTIE 0 Bit 3: Transmit FIFO Overflow for Connection Interrupt Enable (TFOVFIE) If this bit is set, the watermark interrupt is enabled for TFOVFLS. Bit 2: Transmit Queue Overflow for Connection Interrupt Enable (TQOVFIE) If this bit is set, the watermark interrupt is enabled for TQOVFLS. Bit 1: Transmit Queue for Connection High Threshold Interrupt Enable (TQHTIE) If this bit is set, the watermark interrupt is enabled for TQHTS. Bit 0: Transmit Queue for Connection Low Threshold Interrupt Enable (TQLTIE) If this bit is set, the watermark interrupt is enabled for TQLTS. Register Name: Register Description: Register Address: Bit # Name Default 7 - LI.TQCTLS Serial Interface Transmit Queue Cross Threshold Latched Status 127h 6 - 5 - 4 - 3 TFOVFLS - 2 TQOVFLS - 1 TQHTLS - 0 TQLTLS - Bit 3: Transmit Queue FIFO Overflowed Latched Status (TFOVFLS) This bit is set if the transmit queue FIFO has overflowed. This register is cleared after a read. This FIFO is for data to be transmitted from the HDLC to be sent to the SDRAM. Bit 2: Transmit Queue Overflow Latched Status (TQOVFLS) This bit is set if the transmit queue has overflowed. This register is cleared after a read. Bit 1: Transmit Queue for Connection Exceeded High Threshold Latched Status (TQHTLS) This bit is set if the transmit queue crosses the High Watermark. This register is cleared after a read. Bit 0: Transmit Queue for Connection Exceeded Low Threshold Latched Status (TQLTLS) This bit is set if the transmit queue crosses the Low Watermark. This register is cleared after a read. 110 of 169 DS33Z11 Ethernet Mapper 9.6 Ethernet Interface Registers The Ethernet Interface registers are used to configure RMII/MII bus operation and establish the MAC parameters as required by the user. The MAC Registers cannot be addressed directly from the Processor port. The registers below are used to perform indirect read or write operations to the MAC registers. The MAC Status Registers are shown in Table 9-7. Accessing the MAC Registers is described in the Section 8.14. 9.6.1 Ethernet Interface Register Bit Descriptions Register Name: Register Description: Register Address: Bit # Name 7 MACRA7 0 SU.MACRADL MAC Read Address Low Register 140h 6 MACRA6 0 5 MACRA5 0 4 MACRA4 0 3 MACRA3 0 2 MACRA2 0 1 MACRA1 0 0 MACRA0 0 Bits 0 – 7: MAC Read Address (MACRA0-7) Low byte of the MAC address. Used only for read operations. Register Name: Register Description: Register Address: Bit # Name 7 MACRA15 0 SU.MACRADH MAC Read Address High Register 141h 6 MACRA14 0 5 MACRA13 0 4 MACRA12 0 3 MACRA11 0 2 MACRA10 0 1 MACRA9 0 0 MACRA8 0 Bits 0 – 7: MAC Read Address (MACRA8-15) High byte of the MAC address. Used only for read operations. Register Name: Register Description: Register Address: Bit # Name 7 MACRD7 0 SU.MACRD0 MAC Read Data Byte 0 142h 6 MACRD6 0 5 MACRD5 0 4 MACRD4 0 3 MACRD3 0 2 MACRD2 0 1 MACRD1 0 0 MACRD0 0 Bits 0 – 7: MAC Read Data 0 (MACRD0-7) One of four bytes of data read from the MAC. Valid after a read command has been issued and the SU.MACRWC.MCS bit is zero. 111 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name 7 MACRD15 0 SU.MACRD1 MAC Read Data Byte 1 143h 6 MACRD14 0 5 MACRD13 0 4 MACRD12 0 3 MACRD11 0 2 MACRD10 0 1 MACRD9 0 0 MACRD8 0 Bits 0 - 7: MAC Read Data 1 (MACRD8-15) One of four bytes of data read from the MAC. Valid after a read command has been issued and the SU.MACRWC.MCS bit is zero. Register Name: Register Description: Register Address: Bit # Name 7 MACRD23 0 SU.MACRD2 MAC Read Data Byte 2 144h 6 MACRD22 0 5 MACRD21 0 4 MACRD20 0 3 MACRD19 0 2 MACRD18 0 1 MACRD17 0 0 MACRD16 0 Bits 0 – 7: MAC Read Data 2 (MACRD16-23) One of four bytes of data read from the MAC. Valid after a read command has been issued and the SU.MACRWC.MCS bit is zero. Register Name: Register Description: Register Address: Bit # Name 7 MACRD31 0 SU.MACRD3 MAC Read Data byte 3 145h 6 MACRD30 0 5 MACRD29 0 4 MACRD28 0 3 MACRD27 0 2 MACRD26 0 1 MACRD25 0 0 MACRD24 0 Bits 0 – 7: MAC Read Data 3 (MACRD24-31) One of four bytes of data read from the MAC. Valid after a read command has been issued and the SU.MACRWC.MCS bit is zero. Register Name: Register Description: Register Address: Bit # Name 7 MACWD7 0 SU.MACWD0 MAC Write Data 0 146h 6 MACWD6 0 5 MACWD5 0 4 MACWD4 0 3 MACWD3 0 2 MACWD2 0 1 MACWD1 0 0 MACWD0 0 Bits 0 – 7: MAC Write Data 0 (MACWD0-7) One of four bytes of data to be written to the MAC. Data has been written after a write command has been issued and the SU.MACRWC.MCS bit is zero. Register Name: Register Description: Register Address: SU.MACWD1 MAC Write Data 1 147h 112 of 169 DS33Z11 Ethernet Mapper Bit # Name Default 7 6 5 4 3 2 1 0 MACWD15 MACWD14 MACWD13 MACWD12 MACWD11 MACWD10 MACWD09 MACWD08 0 0 0 0 0 0 0 0 Bits 0 – 7: MAC Write Data 1 (MACWD8-15) One of four bytes of data to be written to the MAC. Data has been written after a write command has been issued and the SU.MACRWC.MCS bit is zero. Register Name: Register Description: Register Address: Bit # Name SU.MACWD2 MAC Write Data Register 2 148h 7 6 5 4 3 2 1 0 MACWD23 MACWD22 MACWD21 MACWD20 MACWD19 MACWD18 MACWD17 MACWD16 0 0 0 0 0 0 0 0 Bits 0 - 7: MAC Write Data 2 (MACWD16-23) One of four bytes of data to be written to the MAC. Data has been written after a write command has been issued and the SU.MACRWC.MCS bit is zero. Register Name: Register Description: Register Address: Bit # Name 7 MACD31 0 SU.MACWD3 MAC Write Data 3 149h 6 MACD30 0 5 MACD29 0 4 MACD28 0 3 MACD27 0 2 MACD26 0 1 MACD25 0 0 MACD24 0 Bits 0 – 7: MAC Write Data 3 (MACD24-31) One of four bytes of data to be written to the MAC. Data has been written after a write command has been issued and the SU.MACRWC.MCS bit is zero. Register Name: Register Description: Register Address: Bit # Name 7 MACAW 7 0 SU.MACAWL MAC Address Write Low 14Ah 6 MACAW 6 0 5 MACAW 5 0 4 MACAW4 0 3 MACAW3 0 2 MACAW2 0 1 MACAW1 0 0 MACAW0 0 Bits 0 -7: MAC Write Address (MACAW0-7) Low byte of the MAC address. Used only for write operations. Register Name: SU.MACAWH Register Description: MAC Address Write High Register Address: 14Bh Bit # Name 7 6 5 4 3 2 MACAW 15 MACAW 14 MACAW 13 MACAW12 MACAW11 MACAW10 0 0 0 0 0 0 1 MACAW9 0 0 MACAW8 0 Bits 0 – 7: MAC Write Address (MACAW8-15) High byte of the MAC address. Used only for write operations. 113 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 SU.MACRWC MAC Read Write Command Status 14Ch 6 0 5 0 4 0 3 0 2 0 1 MCRW 0 0 MCS 0 Bit 1: MAC Command RW (MCRW) If this bit is written to 1, a read is performed from the MAC. If this bit is written to 0, a write operation is performed. Address information for write operations must be located in SU.MACAWH and SU.MACAWL. Address information for read operations must be located in SU.MACRADH and SU.MACRADL. The user must also write a 1 to the MCS bit, and the DS33Z11 will clear MCS when the operation is complete. Bit 0: MAC Command Status (MCS) Setting MCS in conjunction with MCRW will initiate a read or write to the MAC registers. Upon completion of the read or write this bit is cleared. Once a read or write command has been initiated the host must poll this bit to see when the operation is complete. 114 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 SU.LPBK Ethernet Interface Loopback Control Register 14Fh 6 0 5 0 4 0 3 0 2 0 1 0 0 QLP 0 Bit 0: Queue Loopback Enable (QLP) If this bit is set to 1, data from the Ethernet Interface receive queue is looped back to the transmit queue. Buffered data from the serial interface will remain until the loopback is removed. Register Name: Register Description: Register Address: Bit # Name Default 7 0 SU.GCR Ethernet Interface General Control Register 150h 6 0 5 0 4 0 3 CRCS 0 2 H10S 0 1 ATFLOW 1 0 JAME 0 Bit 3: CRCS If this bit is zero (default), the received MAC or Ethernet Frame CRC is stripped before the data is encapsulated and transmitted on the serial interface. Data received from the serial interface is decapsulated, a CRC is recalculated and appended to the packet for transmission to the Ethernet interface. If this bit is set to 1, the CRC is not stripped from received packets prior to encapsulation and transmission to the serial interface, and data received from the serial interface is decapsulated directly. No CRC recalculation is performed on data received from the serial interface. Note that the maximum packet size supported by the Ethernet interface is still 2016 (this includes the 4 bytes of CRC). Bit 2: H10S If this bit is set the MAC will operate at 100 Mbps. If this bit is zero, the MAC will operate at 10 Mbps. This bit controls the 10/100 selection for RMII and DCE Mode. In DTE and MII mode, the MAC determines the data rate from the incoming TX_CLK and RX_CLK. Bit 1: Automatic Flow Control Enable (ATFLOW) If this bit is set to 1, automatic flow control is enabled based on the connection receive queue size and high watermarks. Pause frames are sent automatically in full duplex mode. The pause time must be programmed through SU.MACFCR. The jam sequence will not be sent automatically in half duplex mode unless the JAME bit is set. This bit is applicable only in software mode. Bit 0: Jam Enable (JAME) If this bit is set to 1, a Jam sequence is sent for a duration of 4 bytes. This function is only valid in half duplex mode, and will only function if Automatic Flow Control is disabled. Note that if the receive queue size is less than receive high threshold, setting a JAME will JAM one received frame. If JAME is set and the receiver queue size is higher than the high threshold, all received frames are jammed until the queue empties below the threshold. Note that SU.GCR is only valid in the software mode. In hardware mode, pins are used to control Automatic flow control and 100/10-speed selection. 115 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 SU.TFRC Transmit Frame Resend Control 151h 6 0 5 0 4 0 3 NCFQ 0 2 TPDFCB 0 1 TPRHBC 0 0 TPRCB 0 Bit 3: No Carrier Queue Flush Bar (NCFQ) If this bit is set to 1, the queue for data passing from Serial Interface to Ethernet Interface will not be flushed when loss of carrier is detected. Bit 2: Transmit Packet Deferred Fail Control Enable (TPDFCB) If this bit if set to 1, the current frame is transmitted immediately instead of being deferred. If this bit is set to 0, the frame is deferred if CRS is asserted and sent when the CRS is unasserted indicating the media is idle. Bit 1: Transmit Packet HB Fail Control Bar (TPRHBC) If this bit is set to 1, the current frame will not be retransmitted if a heartbeat failure is detected. Bit 0: Transmit Packet Resend Control Bar (TPRCB) If this bit is set to 1, the current frame will not be retransmitted if any of the following errors have occurred: · Jabber time out · Loss of carrier · Excessive deferral · Late collision · Excessive collisions · Under run · Collision Note that blocking retransmission due to collision (applicable in MIII/Half Duplex Mode) can result in unpredictable system level behavior. 116 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 UR 0 SU.TFSL Transmit Frame Status Low 152h 6 EC 0 5 LC 0 4 ED 0 3 LOC 0 2 NOC 0 1 0 0 FABORT 0 Bit 7: Under Run (UR) When this bit is set to 1, the frame was aborted due to a data under run condition of the transmit buffer. Bit 6: Excessive Collisions (EC) When this bit is set to 1, a frame has been aborted after 16 successive collisions while attempting to transmit the current frame. If the Disable Retry bit is set to 1, then Excessive Collisions will be set to 1 after the first collision. Bit 5: Late Collision (LC) When this bit is set to 1, a frame was aborted by collision after the 64-bit collision window. Not valid if an under run has occurred. Bit 4: Excessive Deferral (ED) When this bit is set to 1, a frame was aborted due to excessive deferral. Bit 3: Loss Of Carrier (LOC) When this bit is set to 1, a frame was aborted due to loss of carrier for one or more bit times. Valid only for non-collided frames. Valid only in half-duplex operation. Bit 2: No Carrier (NOC) When this bit is set to 1, a frame was aborted because no carrier was found for transmission. Bit 1: Reserved Bit 0: Frame Abort (FABORT) When this bit is set to 1, the MAC has aborted a frame for one of the above reasons. When this bit is clear, the previous frame has been transmitted successfully. Register Name: Register Description: Register Address: Bit # Name Default 7 PR 0 SU.TFSH Transmit Frame Status High 153h 6 HBF 0 5 CC3 0 4 CC2 0 3 CC1 0 2 CC0 0 1 LCO 0 0 DEF 0 Bit 7: Packet Resend (PR) When this bit is set, the current packet must be retransmitted due to a collision. Bit 6: Heartbeat Failure (HBF) When this bit is set, the device failed to detect a heart beat after transmission. This bit is not valid if an under run has occurred. Bits 2-5: Collision Count (CC0-3) These 4 bits indicate the number of collisions that occurred prior to successful transmission of the previous frame. Not valid if Excessive Collisions is set to 1. Bit 1: Late Collision (LCO) When set to 1, the MAC observed a collision after the 64-byte collision window. Bit 0: Deferred Frame (DEF) When set to 1, the current frame was deferred due to carrier assertion by another node after being ready to transmit. 117 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 FL7 0 SU.RFSB0 Receive Frame Status Byte 0 154h 6 FL6 0 5 FL5 0 4 FL4 0 3 FL3 0 2 FL2 0 1 FL1 0 0 FL0 0 Bits 0 - 7: Frame Length (FL[0:7]) These 8 bits are the low byte of the length (in bytes) of the received frame, with FCS and Padding. If Automatic Pad Stripping is enabled, this value is the length of the received packet without PCS or Pad bytes. The upper 6 bits are contained in SU.RFSB1. Register Name: Register Description: Register Address: Bit # Name Default 7 RF 0 SU.RFSB1 Receive Frame Status Byte 1 155h 6 WT 0 5 FL13 0 4 FL12 0 3 FL11 0 2 FL10 0 1 FL9 0 0 FL8 0 Bit 7: Runt Frame (RF) This bit is set to 1 if the received frame was altered by a collision or terminated within the collision window. Bit 6: Watchdog Timeout (WT) This bit is set to 1 if a packet receive time exceeds 2048 byte times. After 2048 byte times the receiver is disabled and the received frame will fail CRC check. Bits 0-5: Frame Length (FL[8:13]) These 6 bits are the upper bits of the length (in bytes) of the received frame, with FCS and Padding. If Automatic Pad Stripping is enabled, this value is the length of the received packet without PCS or Pad bytes. Register Name: Register Description: Register Address: Bit # Name Default 7 0 SU.RFSB2 Receive Frame Status Byte 2 156h 6 0 5 CRCE 0 4 DB 0 3 MIIE 0 2 FT 0 1 CS 0 0 FTL 0 Bit 5: CRC Error (CRCE) This bit is set to 1 if the received frame does not contain a valid CRC value. Bit 4: Dribbling Bit (DB) This bit is set to 1 if the received frame contains a non-integer multiple of 8 bits. It does not indicate that the frame is invalid. This bit is not valid for runt or collided frames. Bit 3: MII Error (MIIE) This bit is set to 1 if an error was found on the MII bus. Bit 2: Frame Type (FT) This bit is set to 1 if the received frame exceeds 1536 bytes. It is equal to zero if the received frame is an 802.3 frame. This bit is not valid for runt frames. Bit 1: Collision Seen (CS) This bit is set to 1 if a late collision occurred on the received packet. A late collision is one that occurs after the 64-byte collision window. Bit 0: Frame Too Long (FTL) This bit is set to 1 if a frame exceeds the 1518 byte maximum standard Ethernet frame. This bit is only an indication, and causes no frame truncation. 118 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 MF 0 SU.RFSB3 Receive Frame Status Byte 3 157h 6 0 5 0 4 BF 0 3 MCF 0 2 UF 0 1 CF 0 0 LE 0 Bit 7: Missed Frame (MF) This bit is set to 1 if the packet is not successfully received from the MAC by the packet Arbiter. Bit 4: Broadcast Frame (BF) This bit is set to 1 if the current frame is a broadcast frame. Bit 3: Multicast Frame (MCF) This bit is set to 1 if the current frame is a multicast frame. Bit 2: Unsupported Control Frame (UF) This bit is set to 1 if the frame received is a control frame with an opcode that is not supported. If the Control Frame bit is set, and the Unsupported Control Frame bit is clear, then a pause frame has been received and the transmitter is paused. Bit 1: Control Frame (CF) This bit is set to 1 when the current frame is a control frame. This bit is only valid in full-duplex mode. Bit 0: Length Error (LE) This bit is set to 1 when the frames length field and the actual byte count are unequal. This bit is only valid for 802.3 frames. 119 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 RMPS7 1 SU.RMFSRL Receiver Maximum Frame Low Register 158h 6 RMPS6 1 5 RMPS5 1 4 RMPS4 0 3 RMPS3 0 2 RMPS2 0 1 RMPS1 1 0 RMPS0 0 Bits 7- 0: Receiver Maximum Frame (RMPS[0:7]) Eight bits of sixteen-bit value. Register description below. Register Name: Register Description: Register Address: Bit # Name Default 7 RMPS15 0 SU.RMFSRH Receiver Maximum Frame High Register 159h 6 RMPS14 0 5 RMPS13 0 4 RMPS12 0 3 RMPS11 0 2 RMPS10 1 1 RMPS9 1 0 RMPS8 1 Bits 7- 0: Receiver Maximum Frame (RMPS[8:15]) This value is the receiver’s maximum frame size (in bytes), up to a maximum of 2016 bytes. Any frame received greater than this value is rejected. The frame size includes destination address, source address, type/length, data and crc-32. The frame size is not the same as the frame length encoded within the IEEE 802.3 frame. Any values programmed that are greater than 2016 will have unpredictable behavior and should be avoided. Register Name: Register Description: Register Address: Bit # Name Default 7 RQLT7 0 SU.RQLT Receive Queue Low Threshold (Watermark) 15Ah 6 RQLT6 0 5 RQLT5 1 4 RQLT4 1 3 RQLT3 0 2 RQLT2 1 1 RQLT1 1 0 RQLT0 1 Bits 0 - 7: Receive Queue Low Threshold (RQLT[0:7]) The receive queue low threshold for the connection, in increments of 32 packets of 2048 bytes each. The value of this register is multiplied by 32 * 2048 bytes to determine the byte location of the threshold. Note that the receive queue is for data that was received from the Ethernet Interface to be sent to the Serial Interface. Register Name: Register Description: Register Address: Bit # Name Default 7 RQHT7 0 SU.RQHT Receive Queue High Threshold (Watermark) 15Bh 6 RQHT6 0 5 RQHT5 1 4 RQHT4 1 3 RQHT3 1 2 RQHT2 0 1 RQHT1 1 0 RQHT0 0 Bits 0 – 7: Receive Queue High Threshold (RQTH[0:7]) The receive queue high threshold for the connection, in increments of 32 packets of 2048 bytes each. The value of this register is multiplied by 32 * 2048 bytes to 120 of 169 DS33Z11 Ethernet Mapper determine the byte location of the threshold. Note that the receive queue is for data that was received from the Ethernet Interface to be sent to the Serial Interface. Register Name: Register Description: Register Address: Bit # Name Default SU.QRIE Receive Queue Cross Threshold enable 15Ch 7 0 6 0 5 0 4 0 3 RFOVFIE 0 2 RQVFIE 0 1 RQLTIE 0 0 RQHTIE 0 Bit 3: Receive FIFO Overflow Interrupt Enable (RFOVFIE) If this bit is set, the interrupt is enabled for RFOVFLS. Bit 2: Receive Queue Overflow Interrupt Enable (RQVFIE) If this bit is set, the interrupt is enabled for RQOVFLS. Bit 1: Receive Queue Crosses Low Threshold Interrupt Enable (RQLTIE) If this bit is set, the watermark interrupt is enabled for RQLTS. Bit 0: Receive Queue Crosses High Threshold Interrupt Enable (RQHTIE) If this bit is set, the watermark interrupt is enabled for RQHTS. Register Name: Register Description: Register Address: Bit # Name Default 7 - SU.QCRLS Queue Cross Threshold Latched Status 15Dh 6 - 5 - 4 - 3 RFOVFLS - 2 RQOVFLS - 1 RQHTLS - 0 RQLTLS - Bit 3: Receive FIFO Overflow latched Status (RFOVFLS) This bit is set if the receive FIFO overflows for the data to be transmitted from the MAC to the SDRAM. Bit 2: Receive Queue Overflow Latched Status (RQOVFLS) This bit is set if the receive queue has overflowed. This register is cleared after a read. Bit 1: Receive Queue for Connection Crossed High Threshold Latched Status (RQHTLS) This bit is set if the receive queue crosses the high Watermark. This register is cleared after a read. Bit 0: Receive Queue for Connection Crossed Low Threshold latched status (RQLTLS) This bit is set if the receive queue crosses the low Watermark. This register is cleared after a read. Note the bit order differences in the high/low threshold indications in SU.QCRLS and the interrupt enables in SU.QRIE. 121 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Bit # Name Default 7 0 SU.RFRC Receive Frame Rejection Control 15Eh 6 UCFR 0 5 CFRR 0 4 LERR 0 3 CRCERR 0 2 DBR 0 1 MIIER 0 0 BFR 0 Bit 6: Uncontrolled Control Frame Reject (UCFR) When set to 1, Control Frames other than Pause Frames are allowed. When this bit is equal to zero, non-pause control frames are rejected. Bit 5: Control Frame Reject (CFRR) When set to 1, control frames are allowed. When this bit is equal to zero, all control frames are rejected. Bit 4: Length Error Reject (LERR) When set to 1, frames with an unmatched frame length field and actual number of bytes received are allowed. When equal to zero, only frames with matching length fields and actual bytes received will be allowed. Bit 3: CRC Error Reject (CRCERR) When set to 1, frames received with a CRC error or MII error are allowed. When equal to zero, frames with CRC or MII errors are rejected. Bit 2: Dribbling Bit Reject (DBR) When set to 1, frames with lengths of non-integer multiples of 8 bits are allowed. When equal to zero, frames with dribbling bits are rejected. The dribbling bit setting is only valid only if there is not a collision or runt frame. Bit 1: MII Error Reject (MIIER) When set to 1, frames are allowed with MII Receive Errors. When equal to zero, frames with MII errors are rejected. Bit 0: Broadcast Frame Reject (BFR) When set to 1, broadcast frames are allowed. When equal to zero, broadcast frames are rejected. 122 of 169 DS33Z11 Ethernet Mapper 9.6.2 MAC Registers The control Registers related to the control of the individual Mac’s are shown in the following table. The DS33Z11 keeps statistics for the packet traffic sent and received. The register address map is shown in the following table. Note that the addresses listed are the indirect addresses that must be provided to SU.MACRADH/SU.MACRADL or SU.MACAWH/SU.MACAWL. Register Name: Register Description: Register Address: SU.MACCR MAC Control Register 0000h (indirect) 0000h: Bit # Name Default 31 Reserved 0 30 Reserved 0 29 Reserved 0 28 HDB 0 27 PS 0 26 Reserved 0 25 Reserved 0 24 Reserved 0 0001h: Bit # Name Default 23 DRO 0 22 Reserved 0 21 OML0 0 20 F 0 19 Reserved 0 18 Reserved 0 17 Reserved 0 16 Reserved 0 0002h: Bit # Name Default 15 Reserved 0 14 Reserved 0 13 Reserved 0 12 LCC 0 11 Reserved 0 10 DRTY 0 09 Reserved 0 08 ASTP 0 0003h: Bit # Name Default 07 BOLMT1 0 06 BOLMT0 0 05 DC 0 04 Reserved 0 03 TE 0 02 RE 0 01 Reserved 0 00 Reserved 0 Bit 28: Heartbeat Disable (HDB) When set to 1, the heartbeat (SQE) function is disabled. This bit should be set to 1 when operating in MII mode. Bit 27: Port Select (PS) This bit should be equal to 0 for proper operation. Bit 23: Disable Receive Own (DRO) When set to 1, the MAC disables the reception of frames while TX_EN is asserted. When this bit equals zero, transmitted frames are also received by the MAC. This bit should be cleared when operating in full-duplex mode. Bit 21: Loopback Operating Mode (OMLO) When set to 1, data is looped from the transmit side, back to the receive side, without being transmitted to the PHY. Bit 20: Full-Duplex Mode Select (F) When set to 1, the MAC transmits and receives data simultaneously. When in full-duplex mode, the heartbeat check is disabled and the heartbeat fail status should be ignored. 123 of 169 DS33Z11 Ethernet Mapper Bit 12: Late Collision Control (LCC) When set to 1, enables retransmission of a collided packet even after the collision period. When this bit is clear, retransmission of late collisions is disabled. Bit 10: Disable Retry (DRTY) When set to 1, the MAC makes only a single attempt to transmit each frame. If a collision occurs, the MAC ignores the current frame and proceeds to the next frame. When this bit equals 0, the MAC will retry collided packets 16 times before signaling a retry error. Bit 8: Automatic Pad Stripping (ASTP) When set to 1, all incoming frames with less than 46 byte length are automatically stripped of the pad characters and FCS. Bits 6 - 7: Back-Off Limit (BOLMT[0:1]) These two bits allow the user to set the back-off limit used for the maximum retransmission delay for collided packets. Default operation limits the maximum delay for retransmission to a countdown of 10 bits from a random number generator. The user can reduce the maximum number of counter bits as described in the table below. See IEEE 802.3 for details of the back-off algorithm. Bit 7 0 0 1 1 Bit 6 0 1 0 1 Random Number Generator Bits Used 10 8 4 1 Bit 5: Deferral Check (DC) When set to 1, the MAC will abort packet transmission if it has deferred for more than 24,288 bit times. The deferral counter starts when the transmitter is ready to transmit a packet, but is prevented from transmission because CRS is active. If the MAC begins transmission but a collision occurs after the beginning of transmission, the deferral counter is reset again. If this bit is equal to zero, then the MAC will defer indefinitely. Bit 3: Transmitter Enable (TE) When set to 1, packet transmission is enabled. When equal to zero, transmission is disabled. Bit 2: Receiver Enable (RE) When set to 1, packet reception is enabled. When equal to zero, packets are not received. 124 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: SU.MACAH MAC Address High Register 0004h (indirect) 0004h: Bit # Name Default 31 Reserved 1 30 Reserved 1 29 Reserved 1 28 Reserved 1 27 Reserved 1 0005h: Bit # Name Default 23 Reserved 1 22 Reserved 1 21 Reserved 1 20 Reserved 1 19 Reserved 1 0006h: Bit # Name Default 15 PADR47 1 14 PADR46 1 13 PADR45 1 12 PADR44 1 0007h: Bit # Name Default 07 PADR39 1 04 PADR36 1 06 PADR38 1 05 PADR37 1 26 Reserved 1 25 Reserved 1 24 Reserved 1 18 Reserved 1 17 Reserved 1 16 Reserved 1 11 PADR43 1 10 PADR42 1 09 PADR41 1 08 PADR40 1 03 PADR35 1 02 PADR34 1 01 PADR33 1 00 PADR32 1 Bits 00 – 31: PADR[32:47] These 32 bits should be initialized with the upper 4 bytes of the Physical Address for this MAC device. Register Name: Register Description: Register Address: SU.MACAL MAC Address Low Register 0008h (indirect) 0008h: Bit # Name Default 31 PADR31 1 30 PADR30 1 29 PADR29 1 28 PADR28 1 27 PADR27 1 26 PADR26 1 25 PADR25 1 24 PADR24 1 0009h: Bit # Name Default 23 PADR23 1 22 PADR22 1 21 PADR21 1 20 PADR20 1 19 PADR19 1 18 PADR18 1 17 PADR17 1 16 PADR16 1 000Ah: Bit # Name Default 15 PADR15 1 14 PADR14 1 13 PADR13 1 12 PADR12 1 11 PADR11 1 10 PADR10 1 09 PADR09 1 08 PADR08 1 000Bh: Bit # Name Default 07 PADR07 1 04 PADR04 1 03 PADR03 1 02 PADR02 1 01 PADR01 1 06 PADR06 1 05 PADR05 1 00 PADR00 1 Bits 00 – 31: PADR[00:31] These 32 bits should be initialized with the lower 4 bytes of the Physical Address for this MAC device. 125 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: SU.MACMIIA MAC MII Management (MDIO) Address Register 0014h (indirect) 0014h: Bit # Name Default 31 Reserved 0 30 Reserved 0 29 Reserved 0 28 Reserved 0 27 Reserved 0 26 Reserved 0 25 Reserved 0 24 Reserved 0 0015h: Bit # Name Default 23 Reserved 0 22 Reserved 0 21 Reserved 0 20 Reserved 0 19 Reserved 0 18 Reserved 0 17 Reserved 0 16 Reserved 0 0016h: Bit # Name Default 15 PHYA4 0 14 PHYA3 1 13 PHYA2 0 12 PHYA1 1 11 PHYA0 1 10 MIIA4 0 09 MIIA3 1 08 MIIA2 0 0017h: Bit # Name Default 07 MIIA1 1 06 MIIA0 1 04 Reserved 0 03 Reserved 0 02 Reserved 0 01 MIIW 0 00 MIIB 0 05 Reserved 0 Bits 11 - 15: PHY Address (PHYA[0:4]) These 5 bits select one of the 32 available PHY address locations to access through the PHY management (MDIO) bus. Bits 6 - 10: MII Address (MIIA[0:4]) - These 5 bits are the address location within the PHY that is being accessed. Bit 1: MII Write (MIIW) Write this bit to 1 in order to execute a write instruction over the MDIO interface. Write the bit to zero to execute a read instruction. Bit 0: MII Busy (MIIB) This bit is set to 1 by the DS33Z11 during execution of a MII management instruction through the MDIO interface, and is set to zero when the DS33Z11 has completed the instruction. The user should read this bit and ensure that it is equal to zero prior to beginning a MDIO instruction. 126 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: SU.MACMIID MAC MII (MDIO) Data Register 0018h (indirect) 0018h: Bit # Name Default 31 Reserved 0 30 Reserved 0 29 Reserved 0 28 Reserved 0 27 Reserved 0 26 Reserved 0 25 Reserved 0 24 Reserved 0 0019h: Bit # Name Default 23 Reserved 0 22 Reserved 0 21 Reserved 0 20 Reserved 0 19 Reserved 0 18 Reserved 0 17 Reserved 0 16 Reserved 0 001Ah: Bit # Name Default 15 MIID15 0 14 MIID14 0 13 MIID13 0 12 MIID12 0 11 MIID11 0 10 MIID10 0 09 MIID09 0 08 MIID08 0 001Bh: Bit # Name Default 07 MIID07 0 04 MIID04 0 03 MIID03 0 02 MIID02 0 01 MIID01 0 00 MIID00 0 06 MIID06 0 05 MIID05 0 Bits 0 – 15: MII (MDIO) Data (MIID[00:15]) These two bytes contain the data to be written to or the data read from the MII management interface (MDIO). 127 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: SU.MACFCR MAC Flow Control Register 001Ch (indirect) 001Ch: Bit # Name Default 31 PT15 0 30 PT14 0 29 PT13 0 28 PT12 0 27 PT11 0 26 PT10 0 25 PT09 0 24 PT08 0 001Dh: Bit # Name Default 23 PT07 0 22 PT06 1 21 PT05 0 20 PT04 1 19 PT03 0 18 PT02 0 17 PT01 0 16 PT00 0 001Eh: Bit # Name Default 15 Reserved 0 14 Reserved 0 13 Reserved 0 12 Reserved 0 11 Reserved 0 10 Reserved 0 09 Reserved 0 08 Reserved 0 001Fh: Bit # Name Default 07 Reserved 0 04 Reserved 0 03 Reserved 0 02 Reserved 0 01 FCE 1 00 FCB 0 06 Reserved 0 05 Reserved 0 Bits 16 - 31: Pause Time (PT[00:15]) These bits are used for the Pause Time Field in transmitted Pause Frames. This value is the number of time slots the remote node should wait prior to transmission. Bit 1: Flow Control Enable (FCE) When set to 1, the MAC automatically detects pause frames and will disable the transmitter for the requested pause time. Bit 0: Flow Control Busy (FCB) The host can set this bit to 1 in order to initiate transmission of a pause frame. During transmission of a pause frame, this bit remains set. The DS33Z11 will clear this bit when transmission of the pause frame has been completed. The user should read this bit and ensure that this bit is equal to zero prior to initiating a pause frame. 128 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: SU.MMCCTRL MAC MMC Control Register 0100h (indirect) 0100h: Bit # Name Default 31 Reserved 0 30 Reserved 0 29 Reserved 0 28 Reserved 0 27 Reserved 0 26 Reserved 0 25 Reserved 0 24 Reserved 0 0101h: Bit # Name Default 23 Reserved 0 22 Reserved 0 21 Reserved 0 20 Reserved 0 19 Reserved 0 18 Reserved 0 17 Reserved 0 16 Reserved 0 0102h: Bit # Name Default 15 Reserved 0 14 Reserved 0 13 MXFRM10 1 12 MXFRM9 0 11 MXFRM8 1 10 MXFRM7 1 09 MXFRM6 1 08 MXFRM5 1 0103h: Bit # Name Default 07 MXFRM4 0 06 MXFRM3 1 05 MXFRM2 1 04 MXFRM1 1 03 MXFRM0 0 02 Reserved 0 01 Reserved 1 00 Reserved 0 Bits 3 - 13: Maximum Frame Size (MXFRM[0:10]) These bits indicate the maximum packet size value. All transmitted frames larger than this value are counted as long frames. Bit 1: Reserved - Note that this bit must be written to a “1” for proper operation. 129 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Reserved MAC Reserved Control Register 010Ch (indirect) 010Ch: Bit # Name Default 31 Reserved 0 30 Reserved 0 29 Reserved 0 28 Reserved 0 27 Reserved 0 26 Reserved 0 25 Reserved 0 24 Reserved 0 010Dh: Bit # Name Default 23 Reserved 0 22 Reserved 0 21 Reserved 0 20 Reserved 0 19 Reserved 0 18 Reserved 0 17 Reserved 0 16 Reserved 0 010Eh: Bit # Name Default 15 Reserved 0 14 Reserved 0 13 Reserved 0 12 Reserved 0 11 Reserved 0 10 Reserved 0 09 Reserved 0 08 Reserved 0 010Fh: Bit # Name Default 07 Reserved 0 04 Reserved 0 03 Reserved 0 02 Reserved 0 01 Reserved 0 00 Reserved 0 06 Reserved 0 05 Reserved 0 Note – Addresses 10Ch through 10Fh must each be initialized with all 1’s (FFh) for proper software-mode operation. 130 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: Reserved MAC Reserved Control Register 0110h (indirect) 0110h: Bit # Name Default 31 Reserved 0 30 Reserved 0 29 Reserved 0 28 Reserved 0 27 Reserved 0 26 Reserved 0 25 Reserved 0 24 Reserved 0 0111h: Bit # Name Default 23 Reserved 0 22 Reserved 0 21 Reserved 0 20 Reserved 0 19 Reserved 0 18 Reserved 0 17 Reserved 0 16 Reserved 0 0112h: Bit # Name Default 15 Reserved 0 14 Reserved 0 13 Reserved 0 12 Reserved 0 11 Reserved 0 10 Reserved 0 09 Reserved 0 08 Reserved 0 0113h: Bit # Name Default 07 Reserved 0 04 Reserved 0 03 Reserved 0 02 Reserved 0 01 Reserved 0 00 Reserved 0 06 Reserved 0 05 Reserved 0 Note – Addresses 110h through 113h must each be initialized with all 1’s (FFh) for proper software-mode operation. 131 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: 0200h: Bit # Name Default 0201h: Bit # Name Default 0202h: Bit # Name Default 0203h: Bit # Name Default SU.RxFrmCtr MAC All Frames Received Counter 0200h (indirect) 31 30 29 28 27 26 25 24 RXFRMC31 RXFRMC30 RXFRMC29 RXFRMC28 RXFRMC27 RXFRMC26 RXFRMC25 RXFRMC24 0 0 0 0 0 0 0 0 23 22 21 20 19 18 17 16 RXFRMC23 RXFRMC22 RXFRMC21 RXFRMC20 RXFRMC19 RXFRMC18 RXFRMC17 RXFRMC16 0 0 0 0 0 0 0 0 15 14 13 12 11 10 09 08 RXFRMC15 RXFRMC14 RXFRMC13 RXFRMC12 RXFRMC11 RXFRMC10 RXFRMC9 RXFRMC8 0 0 0 0 0 0 0 0 07 06 05 04 03 02 01 00 RXFRMC7 RXFRMC6 RXFRMC5 RXFRMC4 RXFRMC3 RXFRMC2 RXFRMC1 RXFRMC0 0 0 0 0 0 0 0 0 Bits 0 - 31: All Frames Received Counter (RXFRMC[0:31]) 32 bit value indicating the number of frames received. Each time a frame is received, this counter is incremented by 1. This counter resets only upon device reset, does not saturate, and rolls-over to zero upon reaching the maximum value. The user should ensure that the measurement period is less than the minimum length of time required for the counter to increment 2^32-1 times at the maximum frame rate. The user should store the value from the beginning of the measurement period for later calculations, and take into account the possibility of a rollover to occurring. 132 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: 0204h: Bit # Name Default 0205h: Bit # Name Default 0206h: Bit # Name Default 0207h: Bit # Name Default 31 SU.RxFrmOkCtr MAC Frames Received OK Counter 0204h (indirect) 30 29 28 27 26 25 24 RXFRMOK31 RXFRMOK30 RXFRMOK29 RXFRMOK28 RXFRMOK27 RXFRMOK26 RXFRMOK25 RXFRMOK24 0 0 0 0 0 0 0 0 23 22 21 20 19 18 17 16 RXFRMOK23 RXFRMOK22 RXFRMOK21 RXFRMOK20 RXFRMOK19 RXFRMOK18 RXFRMOK17 RXFRMOK16 0 0 0 0 0 0 0 0 15 14 13 12 11 10 09 08 RXFRMOK15 RXFRMOK14 RXFRMOK13 RXFRMOK12 RXFRMOK11 RXFRMOK10 RXFRMOK9 RXFRMOK8 0 0 0 0 0 0 0 0 07 06 05 04 03 02 01 00 RXFRMOK7 RXFRMOK6 RXFRMOK5 RXFRMOK4 RXFRMOK3 RXFRMOK2 RXFRMOK1 RXFRMOK0 0 0 0 0 0 0 0 0 Bits 0 - 31: Frames Received OK Counter (RXFRMOK[0:31]) 32 bit value indicating the number of frames received and determined to be valid. Each time a valid frame is received, this counter is incremented by 1. This counter resets only upon device reset, does not saturate, and rolls-over to zero upon reaching the maximum value. The user should ensure that the measurement period is less than the minimum length of time required for the counter to increment 2^32-1 times at the maximum frame rate. The user should store the value from the beginning of the measurement period for later calculations, and take into account the possibility of a rollover to occurring. 133 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: 0300h: Bit # Name Default 0301h: Bit # Name Default 0302h: Bit # Name Default 0303h: Bit # Name Default SU.TxFrmCtr MAC All Frames Transmitted Counter 0300h (indirect) 31 30 29 28 27 26 25 24 TXFRMC31 TXFRMC30 TXFRMC29 TXFRMC28 TXFRMC27 TXFRMC26 TXFRMC25 TXFRMC24 0 0 0 0 0 0 0 0 23 22 21 20 19 18 17 16 TXFRMC23 TXFRMC22 TXFRMC21 TXFRMC20 TXFRMC19 TXFRMC18 TXFRMC17 TXFRMC16 0 0 0 0 0 0 0 0 15 14 13 12 11 10 09 08 TXFRMC15 TXFRMC14 TXFRMC13 TXFRMC12 TXFRMC11 TXFRMC10 TXFRMC9 TXFRMC8 0 0 0 0 0 0 0 0 07 06 05 04 03 02 01 00 TXFRMC7 TXFRMC6 TXFRMC5 TXFRMC4 TXFRMC3 TXFRMC2 TXFRMC1 TXFRMC0 0 0 0 0 0 0 0 0 Bits 0 - 31: All Frames Transmitted Counter (TXFRMC[0:31]) 32 bit value indicating the number of frames transmitted. Each time a frame is transmitted, this counter is incremented by 1. This counter resets only upon device reset, does not saturate, and rolls-over to zero upon reaching the maximum value. The user should ensure that the measurement period is less than the minimum length of time required for the counter to increment 2^32-1 times at the maximum frame rate. The user should store the value from the beginning of the measurement period for later calculations, and take into account the possibility of a rollover to occurring. 134 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: 0308h: Bit # Name Default 0309h: Bit # Name Default 030Ah: Bit # Name Default 030Bh: Bit # Name Default 31 SU.TxBytesCtr MAC All Bytes Transmitted Counter 0308h (indirect) 30 29 28 27 26 25 24 TXBYTEC31 TXBYTEC30 TXBYTEC29 TXBYTEC28 TXBYTEC27 TXBYTEC26 TXBYTEC25 TXBYTEC24 0 0 0 0 0 0 0 0 23 22 21 20 19 18 17 16 TXBYTEC23 TXBYTEC22 TXBYTEC21 TXBYTEC20 TXBYTEC19 TXBYTEC18 TXBYTEC17 TXBYTEC16 0 0 0 0 0 0 15 14 13 12 11 10 TXBYTEC15 TXBYTEC14 TXBYTEC13 TXBYTEC12 TXBYTEC11 TXBYTEC10 0 0 0 0 0 0 0 0 09 08 TXBYTEC9 TXBYTEC8 0 0 07 06 05 04 03 02 01 00 TXBYTEC7 TXBYTEC6 TXBYTEC5 TXBYTEC4 TXBYTEC3 TXBYTEC2 TXBYTEC1 TXBYTEC0 0 0 0 0 0 0 0 0 Bits 0 - 31: All Bytes Transmitted Counter (TXBYTEC[0:31]) 32 bit value indicating the number of bytes transmitted. Each time a byte is transmitted, this counter is incremented by 1. This counter resets only upon device reset, does not saturate, and rolls-over to zero upon reaching the maximum value. The user should ensure that the measurement period is less than the minimum length of time required for the counter to increment 2^32-1 times at the maximum data rate. The user should store the value from the beginning of the measurement period for later calculations, and take into account the possibility of a rollover to occurring. 135 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: 030Ch: Bit # Name Default 030Dh: Bit # Name Default 030Eh: Bit # Name Default 030Fh: Bit # Name Default 31 SU.TxBytesOkCtr MAC Bytes Transmitted OK Counter 030Ch (indirect) 30 29 28 27 26 25 24 TXBYTEOK31 TXBYTEOK30 TXBYTEOK29 TXBYTEOK28 TXBYTEOK27 TXBYTEOK26 TXBYTEOK25 TXBYTEOK24 0 0 0 0 0 0 0 0 23 22 21 20 19 18 17 16 TXBYTEOK23 TXBYTEOK22 TXBYTEOK21 TXBYTEOK20 TXBYTEOK19 TXBYTEOK18 TXBYTEOK17 TXBYTEOK16 0 0 0 0 0 0 0 15 14 13 12 11 10 09 TXBYTEOK15 TXBYTEOK14 TXBYTEOK13 TXBYTEOK12 TXBYTEOK11 TXBYTEOK10 TXBYTEOK9 0 0 0 0 0 0 0 0 08 TXBYTEOK8 0 07 06 05 04 03 02 01 00 TXBYTEOK7 TXBYTEOK6 TXBYTEOK5 TXBYTEOK4 TXBYTEOK3 TXBYTEOK2 TXBYTEOK1 TXBYTEOK0 0 0 0 0 0 0 0 0 Bits 0 - 31: Bytes Transmitted OK Counter (TXBYTEOK[0:31]) 32 bit value indicating the number of bytes transmitted and determined to be valid. Each time a valid byte is transmitted, this counter is incremented by 1. This counter resets only upon device reset, does not saturate, and rolls-over to zero upon reaching the maximum value. The user should ensure that the measurement period is less than the minimum length of time required for the counter to increment 2^32-1 times at the maximum frame rate. The user should store the value from the beginning of the measurement period for later calculations, and take into account the possibility of a rollover to occurring. 136 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: 0334h: Bit # Name Default 0335h: Bit # Name Default 0336h: Bit # Name Default 0337h: Bit # Name Default SU.TXFRMUNDR MAC Transmit Frame Under Run Counter 0334h (indirect) 31 30 29 28 27 26 25 24 TXFRMU31 TXFRMU30 TXFRMU29 TXFRMU28 TXFRMU27 TXFRMU26 TXFRMU25 TXFRMU24 0 0 0 0 0 0 0 0 23 22 21 20 19 18 17 16 TXFRMU23 TXFRMU22 TXFRMU21 TXFRMU20 TXFRMU19 TXFRMU18 TXFRMU17 TXFRMU16 0 0 0 0 0 0 0 0 15 14 13 12 11 10 09 08 TXFRMU15 TXFRMU14 TXFRMU13 TXFRMU12 TXFRMU11 TXFRMU10 TXFRMU9 TXFRMU8 0 0 0 0 0 0 0 0 07 06 05 04 03 02 01 00 TXFRMU7 TXFRMU6 TXFRMU5 TXFRMU4 TXFRMU3 TXFRMU2 TXFRMU1 TXFRMU0 0 0 0 0 0 0 0 0 Bits 0 - 31: Frames Aborted Due to FIFO Under Run Counter (TXFRMU[0:31]) 32 bit value indicating the number of frames aborted due to FIFO under run. Each time a frame is aborted due to FIFO under run, this counter is incremented by 1. This counter resets only upon device reset, does not saturate, and rolls-over to zero upon reaching the maximum value. The user should ensure that the measurement period is less than the minimum length of time required for the counter to increment 2^32-1 times at the maximum frame rate. The user should store the value from the beginning of the measurement period for later calculations, and take into account the possibility of a rollover to occurring. 137 of 169 DS33Z11 Ethernet Mapper Register Name: Register Description: Register Address: 0338h: Bit # Name Default 0339h: Bit # Name Default 033Ah: Bit # Name Default 033Bh: Bit # Name Default 31 SU.TxBdFrmCtr MAC All Frames Aborted Counter 0338h (indirect) 30 29 28 27 26 25 24 TXFRMBD31 TXFRMBD30 TXFRMBD29 TXFRMBD28 TXFRMBD27 TXFRMBD26 TXFRMBD25 TXFRMBD24 0 0 0 0 0 0 0 0 23 22 21 20 19 18 17 16 TXFRMBD23 TXFRMBD22 TXFRMBD21 TXFRMBD20 TXFRMBD19 TXFRMBD18 TXFRMBD17 TXFRMBD16 0 0 0 0 0 0 0 15 14 13 12 11 10 09 TXFRMBD15 TXFRMBD14 TXFRMBD13 TXFRMBD12 TXFRMBD11 TXFRMBD10 TXFRMBD9 0 0 0 0 0 0 0 0 08 TXFRMBD8 0 07 06 05 04 03 02 01 00 TXFRMBD7 TXFRMBD6 TXFRMBD5 TXFRMBD4 TXFRMBD3 TXFRMBD2 TXFRMBD1 TXFRMBD0 0 0 0 0 0 0 0 0 Bits 0 to 31: All Frames Aborted Counter (TXFRMBD[0:31]) 32 bit value indicating the number of frames aborted due to any reason. Each time a frame is aborted, this counter is incremented by 1. This counter resets only upon device reset, does not saturate, and rolls-over to zero upon reaching the maximum value. The user should ensure that the measurement period is less than the minimum length of time required for the counter to increment 2^32-1 times at the maximum frame rate. The user should store the value from the beginning of the measurement period for later calculations, and take into account the possibility of a rollover to occurring. 138 of 169 DS33Z11 Ethernet Mapper 10 FUNCTIONAL TIMING 10.1 Functional Serial I/O Timing The Serial Interface provides flexible timing to interconnect with a wide variety of serial interfaces. TDEN is an input signal that can be used to enable or block the TSER data. The “shaded bits” are not clocked by the DS33Z11. The TDEN must occur one bit before the effected bit in the TSER stream. Note that polarity of the TDEN is selectable through LI.TSLCR. In the figure below, TDEN is active low , allowing the bits to clock and inactive high, causing the next data bit not be clocked. TCLK can be gapped as shown in the following figure. Similarly, the receiver function is governed by RCLKI, RDEN and RSER. RSER data will not be provided to the receiver for the bits blocked when RDEN is inactive. The RDEN polarity can be programmed by LI.RSLCR. The RDEN signal must be coincident with the RSER bit that needs to be blocked. Figure 10-1 TX Serial Interface Functional Timing TCLKI TDEN TCLK gapped TSER TCLK Gapped TSER TSER Figure 10-2 RX Serial Interface Functional Timing RCLKI RDEN RSER RCLK Gapped RSER TSER 139 of 169 DS33Z11 Ethernet Mapper The DS33Z11 provides the TBSYNC signal as a byte boundary indication to an external interface when X.86 (LAPS) functionality is selected. The functional timing of TBSYNC is shown in the following figure. TBSYNC is active high on the last bit of the byte being shifted out, and occurs every 8 bits. For the serial receiver interface, RBSYNC is used to provide byte boundary indication to the DS33Z11 when X.86 (LAPS) mode is used. The functional timing is shown in Figure 10-3. In X.86 Mode, the receiver expects the RBSYNC byte indicator as shown in Figure 10-4. Figure 10-3 Transmit Byte Sync Functional timing TCLKI TBYSYNC TSER last bit 1st bit Figure 10-4 Receive Byte Sync Functional Timing RCLKI RBYSYNC RSER last bit 1st bit 10.2 MII and RMII Interfaces The MII Interface Transmit Port has its own TX_CLK and data interface. The data TXD [3:0] operates synchronously with TX_CLK. The LSB is presented first. TX_CLK should be 2.5 MHz for 10 Mbps operation and 25 MHz for 100 Mbps operation. TX_EN is valid at the same time as the first byte of the preamble. In DTE Mode TX_CLK is input from the external PHY. In DCE Mode, the DS33Z11 provides TX_CLK, derived from an external reference (SYSCLKI). In Half-Duplex (DTE) Mode, the DS33Z11 supports CRS and COL signals. CRS is active when the PHY detects transmit or receive activity. If there is a collision as indicated by the COL input, the DS33Z11 will replace the data nibbles with jam nibbles. After a “random“ time interval, the packet is retransmitted. The MAC will try to send the packet a maximum of 16 times. The jam sequence consists of 55555555h. Note that the COL signal and CRS can be asynchronous to the TX_CLK and are only valid in half duplex mode. 140 of 169 DS33Z11 Ethernet Mapper Figure 10-5 MII Transmit Functional Timing TX_CLK P TXD[3:0] R E A E M B L F E C S TX_EN Figure 10-6 MII Transmit Half Duplex with a Collision Functional Timing TX_CLK TXD[3:0] P R E A M B L E J J J J J J J J TX_EN CRS COL Receive Data (RXD[3:0]) is clocked from the external PHY synchronously with RX_CLK. The RX_CLK signal is 2.5 MHz for 10 Mbps operation and 25 MHz for 100 Mbps operation. RX_DV is asserted by the PHY from the first nibble of the preamble in 100 Mbps operation or first nibble of SFD for 10 Mbps operation. The data on RXD[3:0] is not accepted by the MAC if RX_DV is low or RX_ERR is high (in DTE mode). RX_ERR should be tied low when in DCE Mode. Figure 10-7 MII Receive Functional Timing RX_CLK P RXD[3:0] R E A E M B L E F C S In RMII Mode, TX_EN is high with the first bit of the preamble. The TXD[1:0] is synchronous with the 50 MHz REF_CLK. For 10 Mbps operation, the data bit outputs are updated every 10 clocks. Figure 10-8 RMII Transmit Interface Functional Timing REFCLK TXD[1:0] P R E A M B L E F TX_EN 141 of 169 C S DS33Z11 Ethernet Mapper RMII Receive data on RXD[1:0] is expected to be synchronous with the rising edge of the 50 MHz REF_CLK. The data is only valid if CRS_DV is high. The external PHY asynchronously drives CRS_DV low during carrier loss. Figure 10-9 RMII Receive Interface Functional Timing REFCLK RXD[1:0] P R E A M B L E F C S CRS_DV 10.3 SPI Interface Mode and EEPROM Program Sequence The DS33Z11 will act as an SPI Master when configured with MODEC[1:0] to read the configuration from an external Serial EEPROM, such as the Atmel AT25160A. The EEPROM must be programmed with the data structure shown in Table 10-1. The MOSI (Master Out Slave In) signal can be selectively output on the rising or falling edge of SPICK. The MISO data can be sampled on rising or falling edge of SPICK based on the CKPHA pin input. The SPICK is generated by the DS33Z11 at a frequency of 8.33 MHz, derived from an external SYSCLKI of 100 MHz. The initialization sequence is commenced immediately after power up reset or a rising edge of the RST input pin. The SPI master initiates a read with the instruction code 0000x011b; followed by the address location. The SPI_CS is held low until the data addressed is read and latched. The DS33Z11 begins reading the EEPROM at address 0000h. Data is sequentially latched until the last data byte is read and latched. The indirect MAC registers require a special program sequence at the end of the EEPROM file. Four MAC registers can be programmed in the EEPROM Mode: SU.MACCR, SU.MACMIIA, SU.MACMIID, and SU.MACFCR. All other indirect MAC registers do not need to be initialized for EEPROM mode operation. The indirect MAC registers are programmed using four separate seven-byte records from the EEPROM. An example is shown in Table 10-2. Figure 10-10 SPI Master Functional Timing 0 1 2 3 4 5 6 7 8 9 10 11 20 21 22 23 0 0 00 X 0 1 1 0 0 0 0 0 0 0 0 24 25 26 27 7 6 5 4 28 29 30 31 SPI_CS* SPICK CKPHA=0 SPICK CKPHA=1 MOSI 0 MISO 142 of 169 3 2 1 0 DS33Z11 Ethernet Mapper Table 10-1 EEPROM Program Memory Map Functional Block Address Range for Data in EEPROM (in hex) Global Registers 000 to 03F Arbiter Registers 040 to 07F BERT Registers 080 to 0BF Serial Interface Tx Registers 0C0 to 0FF Serial Interface Rx Registers 100 to 13F Ethernet Interface Registers 140 to 17F MAC Register Write 1 180 to 186 (special for indirect addresses) MAC Register Write 2 187 to 18D (special for indirect addresses) MAC Register Write 3 18E to 194 (special for indirect addresses) MAC Register Write 4 195 to 19B (special for indirect addresses) Table 10-2 EEPROM Program Sequence and Example for Indirect MAC Registers EEPROM File Byte function EEPROM Memory Location Example EEPROM Address Location Example Data, using MAC Register Write 1 to initialize MACCR MAC Data Byte 1 Base + 00h 180h 2Ch - written to SU.MACWD0 MAC Data Byte 2 Base + 01h 181h 00h - written to SU.MACWD1 MAC Data Byte 3 Base + 02h 182h 04h - written to SU.MACWD2 MAC Data Byte 4 Base + 03h 183h 90h - written to SU.MACWD3 MAC Address Low Base + 04h 184h 00h - written to SU.MACAWL MAC Address High Base + 05h 185h 00h - written to SU.MACAWH MAC Write Command Base + 06h 186h 01h - written to SU.MACRWC to initiate the indirect write Note: Base EEPROM address of MAC instructions = 180h 143 of 169 DS33Z11 Ethernet Mapper 11 OPERATING PARAMETERS ABSOLUTE MAXIMUM RATINGS Voltage Range on Any Lead with Respect to VSS (except VDD)…………………………………………..–0.5V to +5.5V Supply Voltage Range (VDD3.3) with Respect to VSS……………………………………………………..–0.3V to +3.6V Supply Voltage Range (VDD1.8) with Respect to VSS……………………………………………………..–0.3V to +2.0V Ambient Operating Temperature Range…………………………………………………………………...–40°C to +85°C Junction Operating Temperature Range………………………………………………………………….–40°C to +125°C Storage Temperature Range……………………………………………………………………………….–55°C to +125°C Soldering Temperature…………………………………………………………See IPC/JEDEC J-STD-020 Specification These are stress ratings only and functional operation of the device at these or any other conditions beyond those indicated in the operation sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time can affect reliability. Ambient Operating Temperature Range is assuming the device is mounted on a JEDEC standard test board in a convection-cooled JEDEC test enclosure. Note: The “typ” values listed below are not production tested. Table 11-1 Recommended DC Operating Conditions (VDD3.3 = 3.3V ±5%,VDD1.8 = 1.8 ± 5% Tj = -40°C to +85°C.) PARAMETER Logic 1 Logic 0 Supply (VDD3.3) ±5% Supply (VDD1.8) ±5% SYMBOL CONDITIONS VIH VIL VDD3.3 VDD1.8 MIN TYP MAX UNITS 2.0 -0.3 3.135 1.71 3.300 1.8 3.465 +0.8 3.465 1.89 V V V V MIN TYP MAX UNITS Table 11-2 DC Electrical Characteristics (VDD3.3 = 3.3V ±5%,VDD1.8 = 1.8 ± 5% Tj = -40°C to +85°C.) PARAMETER SYMBOL CONDITIONS I/O Supply Current (VDD3.3 = 3.465V) Core Supply Current (VDD1.8 = 1.89) Power-Down Current (All DISABLE and Power-Down Bits Set) Lead Capacitance Input Leakage Input Leakage Output Leakage (when Hi-Z) Output Voltage (IOH = -4.0mA) Output Voltage (IOL = +4.0mA) Output Voltage (IOH = -8.0mA) Output Voltage (IOL = +12.0mA) Input Voltage IDDIO (Notes 1, 2) 25 mA IDDCORE (Notes 1, 2) 30 mA IDDD CIO IIL IILP ILO VOH VOL VOH VOL VIL (Note 2) 90 mA 7 All Outputs All Outputs REF_CLKO TSER VIH -10 -50 -10 2.4 +10 -10 +10 0.4 2.4 0.4 0.8 2.0 Note 1: Typical power is 145mW. Note 2: All outputs loaded with rated capacitance; all inputs between VDD and VSS; inputs with pullups connected to VDD. 144 of 169 pF mA mA mA V V V V V V DS33Z11 Ethernet Mapper 11.1 Thermal Characteristics PARAMETER MIN Ambient Temperature (Note 1) TYP -40°C MAX +85°C Junction Temperature +125°C Theta-JA (qJA) in Still Air for 169-pin 14mm CSBGA (Note 2) Theta-JA (qJA) in Still Air for 100-pin 10mm CSBGA (Note 2) +52.7°C/W +47.1°C/W Note 1: The package is mounted on a four-layer JEDEC standard test board. Note 2: Theta-JA (qJA) is the junction-to-ambient thermal resistance, when the package is mounted on a four-layer JEDEC standard test board. 11.2 Theta-JA vs. Airflow AIR FLOW (m/s) 0 1 2.5 THETA-JA 169-Pin 14mm CSBGA (°C/W) 52.7 45.8 43.8 100-Pin 10mm CSBGA (°C/W) 47.1 40.8 38.4 145 of 169 DS33Z11 Ethernet Mapper 11.3 Transmit MII Interface PARAMETER 10 Mbps SYMBOL MIN TYP 100 Mbps MAX MIN TYP 400 MAX 40 UNITS TX_CLK Period t1 TX_CLK Low Time t2 140 260 14 26 ns TX_CLK High Time t3 140 260 14 26 ns TX_CLK to TXD, TX_EN Delay t4 0 20 0 20 ns Figure 11-1 Transmit MII Interface t1 TX_CLK t2 t3 t4 TXD[3:0] t4 TX_EN 146 of 169 ns DS33Z11 Ethernet Mapper 11.4 Receive MII Interface PARAMETER 10 Mbps SYMBOL MIN TYP 100 Mbps MAX MIN TYP 400 MAX 40 UNITS RX_CLK Period t5 ns RX_CLK Low Time t6 140 260 14 26 ns RX_CLK High Time t7 140 260 14 26 ns RXD, RX_DV to RX_CLK Setup Time t8 5 5 ns RX_CLK to RXD, RX_DV Hold Time t9 5 5 ns Figure 11-2 Receive MII Interface Timing t5 t7 RX_CLK t6 t8 t9 RXD[3:0] t9 t8 RX_DV 147 of 169 DS33Z11 Ethernet Mapper 11.5 Transmit RMII Interface PARAMETER SYMBOL 10 Mbps MIN REF_CLK Frequency 100 Mbps TYP MAX MIN TYP 50MHz, ±50ppm 50MHz, ±50ppm 20 20 MAX UNITS REF_CLK Period t1 REF_CLK Low Time t2 7 13 7 13 ns REF_CLK High Time t3 7 13 7 13 ns REF_CLK to TXD, TX_EN Delay t4 5 10 5 10 ns Figure 11-3 Transmit RMII Interface t1 REF_CLK t2 t3 t4 TXD[1:0] t4 TX_EN 148 of 169 ns DS33Z11 Ethernet Mapper 11.6 Receive RMII Interface PARAMETER 10 Mbps SYMBOL MIN REF_CLK Frequency TYP 100 Mbps MAX MIN TYP 50MHz, ±50ppm 50MHz, ±50ppm 20 20 MAX UNITS REF_CLK Period t1 ns REF_CLK Low Time t2 7 13 7 13 ns REF_CLK High Time t3 7 13 7 13 ns RXD, CRS_DV to REF_CLK Setup Time t8 5 5 ns REF_CLK to RXD, CRS_DV Hold Time t9 5 5 ns Figure 11-4 Receive RMII Interface Timing t5 t7 REF_CLK t6 t8 t9 RXD[3:0] t9 t8 CRS_DV 149 of 169 DS33Z11 Ethernet Mapper 11.7 MDIO Interface PARAMETER SYMBOL MIN MDC Frequency TYP MAX UNITS 1.67 MHz MDC Period t1 540 600 660 ns MDC Low Time t2 270 300 330 ns MDC High Time t3 270 300 330 ns MDC to MDIO Output Delay t4 20 10 ns MDIO Setup Time t5 10 ns MDIO Hold Time t6 20 ns Figure 11-5 MDIO Timing t1 MDC t2 t3 t4 MDIO MDC t5 t6 MDIO 150 of 169 DS33Z11 Ethernet Mapper 11.8 Transmit WAN Interface PARAMETER SYMBOL MIN TYP TCLKI Frequency MAX UNITS 52 MHz TCLKI Period t1 19.2 ns TCLKI Low Time t2 8 ns TCLKI High Time t3 8 ns TCLKI to TSER Output Delay t4 TSYNC Setup Time t5 7 ns TSYNC Hold Time t6 7 ns 10 ns Figure 11-6 Transmit WAN Timing t1 TCLKI t2 t3 t4 TSER t5 Tsync t6 151 of 169 DS33Z11 Ethernet Mapper 11.9 Receive WAN Interface PARAMETER SYMBOL MIN TYP RCLKI Frequency MAX UNITS 52 MHz RCLKI Period t1 19.2 ns RCLKI Low Time t2 8 ns RCLKI High Time t3 8 ns RSER Setup Time t4 7 ns RDEN Setup Time t4 7 ns RBSYNC Setup Time t4 7 ns RDEN Setup Time t4 7 ns RBSYNC Setup Time t4 7 ns RSER Hold Time t5 2 ns RBSYNC Hold Time t5 2 ns RDEN Hold Time t5 2 ns RBSYNC Hold Time t5 2 ns Figure 11-7 Receive WAN Timing t1 RCLKI t2 t3 t4 t5 RSER t4 t5 RDEN t4 t5 RBSYNC 152 of 169 DS33Z11 Ethernet Mapper 11.10 SDRAM Timing Table 11-3 SDRAM Interface Timing PARAMETER SYMBOL 100 MHz TYP 10 MAX 10.3 UNITS SDCLKO Period t1 MIN 9.7 SDCLKO Duty Cycle t2 4 SDCLKO to SDATA Valid; Write to SDRAM t3 SDCLKO to SDATA Drive On; Write to SDRAM t4 4 ns SDCLKO to SDATA Invalid; Write to SDRAM t5 3 ns SDCLKO to SDATA Drive Off; Write to SDRAM t6 SDATA to SDCLKO Setup Time; Read from SDRAM t7 SDCLKO to SDATA Hold Time; Read from SDRAM t8 2 ns SDCLKO to SRAS, SCAS, SWE, SDCS Active; Read or Write to SDRAM t9 5 ns SDCLKO to SRAS, SCAS, SWE, SDCS Inactive; Read or Write to SDRAM t10 SDCLKO to SDA, SBA Valid; Read or Write to SDRAM t11 SDCLKO to SDA, SBA Invalid; Read or Write to SDRAM t12 SDCLKO to SDMASK Valid; Read or Write to SDRAM t13 SDCLKO to SDMASK Invalid; Read or Write to SDRAM t14 6 ns 7 ns 4 2 ns 7 2 ns ns 5 153 of 169 ns ns 2 2 ns ns ns DS33Z11 Ethernet Mapper Figure 11-8 SDRAM Interface Timing t1 SDCLKO (output) t2 t3 t5 SDATA (output) t4 t6 t7 t8 SDATA (input) SRAS, SCAS, SWE, SDCS (output) t9 t10 t11 t12 t13 t14 SDA, SBA (output) SDMASK (output) 154 of 169 DS33Z11 Ethernet Mapper 11.11 AC Characteristics—Microprocessor Bus Timing (VDD3.3 = 3.3V ±5%, VDD1.8 = 1.8 ±5%; Tj = -40°C to +85°C.) PARAMETER SYMBOL MIN TYP MAX Setup Time for A[12:0] Valid to CS Active t1 0 ns Setup Time for CS Active to Either RD or WR Active t2 0 ns Delay Time from Either RD or DS Active to DATA[7:0] Valid t3 Hold Time from Either RD or WR Inactive to CS Inactive t4 0 Hold Time from CS or RD or DS Inactive to DATA[7:0] Tri-state t5 5 Wait Time from RW Active to Latch Data t6 80 ns Data Setup Time to DS Active t7 10 ns Data Hold Time from RW Inactive t8 2 ns Address Hold from RW Inactive t9 0 ns Write Access to Subsequent Write/Read Access Delay Time t10 80 ns 75 155 of 169 UNITS ns ns 20 ns DS33Z11 Ethernet Mapper Figure 11-9 Intel Bus Read Timing (HWMODE = 0, MODEC = 00) t9 ADDR[12:0] Address Valid DATA[7:0] Data Valid t5 WR t1 CS t2 t3 t4 RD t10 Figure 11-10 Intel Bus Write Timing (HWMODE = 0, MODEC = 00) t9 ADDR[12:0] Address Valid DATA[7:0] t7 t8 RD t1 CS t2 t6 t4 WR t10 156 of 169 DS33Z11 Ethernet Mapper Figure 11-11 Motorola Bus Read Timing (HWMODE = 0, MODEC = 01) t9 ADDR[12:0] Address Valid DATA[7:0] Data Valid t5 RW t1 CS t2 t3 t4 DS t10 Figure 11-12 Motorola Bus Write Timing (HWMODE = 0, MODEC = 01) t9 ADDR[12:0] Address Valid DATA[7:0] t7 t8 RW t1 CS t2 t6 t4 DS t10 157 of 169 DS33Z11 Ethernet Mapper 11.12 EEPROM Interface Timing PARAMETER SYMBOL MIN TYP MAX 120 UNITS SPICK Period t1 ns SPICK Low Time t2 55 65 ns SPICK High Time t3 55 65 ns MOSI Setup Delay t4 50 ns MISO Hold t5 50 ns MISO Setup T6 10 ns MISO Hold T7 10 ns SPI_CS Hold T8 60 ns Figure 11-13 EEPROM Interface Timing – t2 SPI_CS t3 t1 t8 t4 t5 MOSI t6 MISO t7 158 of 169 DS33Z11 Ethernet Mapper 11.13 JTAG Interface Timing (VDD3.3 = 3.3V ±5%, VDD1.8 = 1.8 ±5%; Tj = -40°C to +85°C.) PARAMETER SYMBOL JTCLK Clock Period MIN TYP t1 JTCLK Clock High: Low Time (Note 1) MAX UNITS 1000 ns 500 ns t2:t3 50 JTCLK to JTDI, JTMS Setup Time t4 2 ns JTCLK to JTDI, JTMS Hold Time t5 2 ns JTCLK to JTDO Delay t6 2 50 ns JTCLK to JTDO HIZ Delay t7 2 50 ns JTRST Width Low Time t8 100 ns Note 1: Clock can be stopped high or low. Figure 11-14 JTAG Interface Timing Diagram t1 t3 t2 JTCLK t4 t5 JTDI, JTMS t6 t7 JTD0 t8 JTRST 159 of 169 DS33Z11 Ethernet Mapper 12 JTAG INFORMATION The device supports the standard instruction codes SAMPLE:PRELOAD, BYPASS, and EXTEST. Optional public instructions included are HIGHZ, CLAMP, and IDCODE. See Table 12-1. The DS33Z11 contains the following as required by IEEE 1149.1 Standard Test Access Port and Boundary Scan Architecture. Test Access Port (TAP) TAP Controller Instruction Register Bypass Register Boundary Scan Register Device Identification Register The Test Access Port has the necessary interface pins: JTRST, JTCLK, JTMS, JTDI, and JTDO. See the pin descriptions for details. Refer to IEEE 1149.1-1990, IEEE 1149.1a-1993, and IEEE 1149.1b-1994 for details about the Boundary Scan Architecture and the Test Access Port. Figure 12-1 JTAG Functional Block Diagram Boundary Scan Register Identification Register Mux Bypass Register Instruction Register Select Test Access Port Controller 10K 10K JTDI JTMS Tri-State 10K JTCLK JTRST JTDO 12.1 JTAG TAP Controller State Machine Description This section covers the details on the operation of the Test Access Port (TAP) Controller State Machine. The TAP controller is a finite state machine that responds to the logic level at JTMS on the rising edge of JTCLK. 160 of 169 DS33Z11 Ethernet Mapper TAP Controller State Machine The TAP controller is a finite state machine that responds to the logic level at JTMS on the rising edge of JTCLK. See Figure 12-2 for a diagram of the state machine operation. Test-Logic-Reset Upon power-up, the TAP Controller is in the Test-Logic-Reset state. The Instruction register will contain the IDCODE instruction. All system logic of the device will operate normally. Run-Test-Idle The Run-Test-Idle is used between scan operations or during specific tests. The Instruction register and test registers will remain idle. Select-DR-Scan All test registers retain their previous state. With JTMS LOW, a rising edge of JTCLK moves the controller into the Capture-DR state and will initiate a scan sequence. JTMS HIGH during a rising edge on JTCLK moves the controller to the Select-IR-Scan state. Capture-DR Data may be parallel-loaded into the test data registers selected by the current instruction. If the instruction does not call for a parallel load or the selected register does not allow parallel loads, the test register will remain at its current value. On the rising edge of JTCLK, the controller will go to the Shift-DR state if JTMS is LOW or it will go to the Exit1-DR state if JTMS is HIGH. Shift-DR The test data register selected by the current instruction is connected between JTDI and JTDO and will shift data one stage towards its serial output on each rising edge of JTCLK. If a test register selected by the current instruction is not placed in the serial path, it will maintain its previous state. Exit1-DR While in this state, a rising edge on JTCLK will put the controller in the Update-DR state, which terminates the scanning process, if JTMS is HIGH. A rising edge on JTCLK with JTMS LOW will put the controller in the PauseDR state. Pause-DR Shifting of the test registers is halted while in this state. All test registers selected by the current instruction will retain their previous state. The controller will remain in this state while JTMS is LOW. A rising edge on JTCLK with JTMS HIGH will put the controller in the Exit2-DR state. Exit2-DR A rising edge on JTCLK with JTMS HIGH while in this state will put the controller in the Update-DR state and terminate the scanning process. A rising edge on JTCLK with JTMS LOW will enter the Shift-DR state. 161 of 169 DS33Z11 Ethernet Mapper Update-DR A falling edge on JTCLK while in the Update-DR state will latch the data from the shift register path of the test registers into the data output latches. This prevents changes at the parallel output due to changes in the shift register. Select-IR-Scan All test registers retain their previous state. The instruction register will remain unchanged during this state. With JTMS LOW, a rising edge on JTCLK moves the controller into the Capture-IR state and will initiate a scan sequence for the instruction register. JTMS HIGH during a rising edge on JTCLK puts the controller back into the Test-Logic-Reset state. Capture-IR The Capture-IR state is used to load the shift register in the instruction register with a fixed value. This value is loaded on the rising edge of JTCLK. If JTMS is HIGH on the rising edge of JTCLK, the controller will enter the Exit1-IR state. If JTMS is LOW on the rising edge of JTCLK, the controller will enter the Shift-IR state. Shift-IR In this state, the shift register in the instruction register is connected between JTDI and JTDO and shifts data one stage for every rising edge of JTCLK towards the serial output. The parallel register, as well as all test registers, remains at their previous states. A rising edge on JTCLK with JTMS HIGH will move the controller to the Exit1-IR state. A rising edge on JTCLK with JTMS LOW will keep the controller in the Shift-IR state while moving data one stage thorough the instruction shift register. Exit1-IR A rising edge on JTCLK with JTMS LOW will put the controller in the Pause-IR state. If JTMS is HIGH on the rising edge of JTCLK, the controller will enter the Update-IR state and terminate the scanning process. Pause-IR Shifting of the instruction shift register is halted temporarily. With JTMS HIGH, a rising edge on JTCLK will put the controller in the Exit2-IR state. The controller will remain in the Pause-IR state if JTMS is LOW during a rising edge on JTCLK. Exit2-IR A rising edge on JTCLK with JTMS LOW will put the controller in the Update-IR state. The controller will loop back to Shift-IR if JTMS is HIGH during a rising edge of JTCLK in this state. Update-IR The instruction code shifted into the instruction shift register is latched into the parallel output on the falling edge of JTCLK as the controller enters this state. Once latched, this instruction becomes the current instruction. A rising edge on JTCLK with JTMS held low will put the controller in the Run-Test-Idle state. With JTMS HIGH, the controller will enter the Select-DR-Scan state. 162 of 169 DS33Z11 Ethernet Mapper Figure 12-2 TAP Controller State Diagram 1 Test Logic Reset 0 0 Run Test/ Idle 1 Select DR-Scan 1 Select IR-Scan 0 1 0 1 Capture DR Capture IR 0 Shift DR 0 Shift IR 0 1 Exit DR Exit IR Exit2 DR Pause IR 0 0 1 0 Exit2 IR 1 1 Update DR 1 1 0 1 0 0 1 1 0 Pause DR 1 Update IR 0 1 0 12.2 Instruction Register The instruction register contains a shift register as well as a latched parallel output and is 3 bits in length. When the TAP controller enters the Shift-IR state, the instruction shift register is connected between JTDI and JTDO. While in the Shift-IR state, a rising edge on JTCLK with JTMS LOW will shift the data one stage towards the serial output at JTDO. A rising edge on JTCLK in the Exit1-IR state or the Exit2-IR state with JTMS HIGH will move the controller to the Update-IR state. The falling edge of that same JTCLK will latch the data in the instruction shift register to the instruction parallel output. Instructions supported by the DS33Z11 and its respective operational binary codes are shown in Table 12-1. 163 of 169 DS33Z11 Ethernet Mapper Table 12-1 Instruction Codes for IEEE 1149.1 Architecture INSTRUCTION SAMPLE:PRELOAD BYPASS EXTEST CLAMP HIGHZ IDCODE SELECTED REGISTER Boundary Scan Bypass Boundary Scan Bypass Bypass Device Identification INSTRUCTION CODES 010 111 000 011 100 001 12.2.1 SAMPLE:PRELOAD This is a mandatory instruction for the IEEE 1149.1 specification. This instruction supports two functions. The digital I/Os of the device can be sampled at the boundary scan register without interfering with the normal operation of the device by using the Capture-DR state. SAMPLE:PRELOAD also allows the device to shift data into the boundary scan register via JTDI using the Shift-DR state. 12.2.2 BYPASS When the BYPASS instruction is latched into the parallel instruction register, JTDI connects to JTDO through the one-bit bypass test register. This allows data to pass from JTDI to JTDO not affecting the device’s normal operation. 12.2.3 EXTEST This allows testing of all interconnections to the device. When the EXTEST instruction is latched in the instruction register, the following actions occur. Once enabled via the Update-IR state, the parallel outputs of all digital output pins are driven. The boundary scan register is connected between JTDI and JTDO. The Capture-DR will sample all digital inputs into the boundary scan register. 12.2.4 CLAMP All digital outputs of the device will output data from the boundary scan parallel output while connecting the bypass register between JTDI and JTDO. The outputs will not change during the CLAMP instruction. 12.2.5 HIGHZ All digital outputs of the device are placed in a high-impedance state. The BYPASS register is connected between JTDI and JTDO. 12.2.6 IDCODE When the IDCODE instruction is latched into the parallel instruction register, the identification test register is selected. The device identification code is loaded into the identification register on the rising edge of JTCLK following entry into the Capture-DR state. Shift-DR can be used to shift the identification code out serially via JTDO. During Test-Logic-Reset, the identification code is forced into the instruction register’s parallel output. The ID code will always have a ‘1’ in the LSB position. The next 11 bits identify the manufacturer’s JEDEC number and number of continuation bytes followed by 16 bits for the device and 4 bits for the version. 164 of 169 DS33Z11 Ethernet Mapper 12.3 JTAG ID Codes Table 12-2 ID Code Structure DEVICE REVISION ID[31:28] DEVICE CODE ID[27:12] MANUFACTURER’S CODE ID[11:1] REQUIRED ID[0] DS33Z11 0000 0000 0000 0110 0001 000 1010 0001 1 12.4 Test Registers IEEE 1149.1 requires a minimum of two test registers; the bypass register and the boundary scan register. An optional test register has been included with the DS33Z11 design. This test register is the identification register and is used in conjunction with the IDCODE instruction and the Test-Logic-Reset state of the TAP controller. 12.5 Boundary Scan Register This register contains both a shift register path and a latched parallel output for all control cells and digital I/O cells and is n bits in length. 12.6 Bypass Register This is a single one-bit shift register used in conjunction with the BYPASS, CLAMP, and HIGHZ instructions, which provides a short path between JTDI and JTDO. 12.7 Identification Register The identification register contains a 32-bit shift register and a 32-bit latched parallel output. This register is selected during the IDCODE instruction and when the TAP controller is in the Test-Logic-Reset state. 12.8 JTAG Functional Timing This functional timing for the JTAG circuits shows: · The JTAG controller starting from reset state · Shifting out the first 4 LSB bits of the IDCODE · Shifting in the BYPASS instruction (111) while shifting out the mandatory X01 pattern · Shifting the TDI pin to the TDO pin through the bypass shift register · An asynchronous reset occurs while shifting 165 of 169 DS33Z11 Ethernet Mapper Figure 12-3 JTAG Functional Timing (INST) (STATE) IDCODE Run Test Idle Reset Select DR Scan Capture DR Shift DR IDCODE BYPASS Exit1 DR Update DR Select DR Scan Select IR Scan Capture IR Shift IR Exit1 IR Update IR Select DR Scan Capture DR Shift DR Test Logic Idle JTCLK JTRST JTMS JTDI X X X X JTDO Output Pin X Output pin level change if in "EXTEST" instruction mode 166 of 169 X DS33Z11 Ethernet Mapper 13 PACKAGE INFORMATION (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information, go to www.maxim-ic.com/DallasPackInfo.) 13.1 Package Outline Drawing of 169-Ball CSBGA (view from bottom of device) BOTTOM VIEW 167 of 169 DS33Z11 Ethernet Mapper 13.2 Package Outline Drawing of 100-Ball CSBGA (DS33ZH11 Only) 1.42 0.70 ± 0.05 0.36 ± 0.05 0.36 ± 0.05 168 of 169 DS33Z11 Ethernet Mapper 14 REVISION HISTORY REVISION 021805 DESCRIPTION New Product Release 169 of 169 Maxim/Dallas Semiconductor cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim/Dallas Semiconductor product. No circuit patent licenses are implied. Maxim/Dallas Semiconductor reserves the right to change the circuitry and specifications without notice at any time. Ma x i m I n t e g r a t e d P r o d u c t s , 1 2 0 S a n G a b r i e l D r i v e , S u n n y v a l e , C A 9 4 0 8 6 4 0 8 - 7 3 7 - 7 6 0 0 © 2005 Maxim Integrated Products · Printed USA are registered trademarks of Maxim Integrated Products, Inc., and Dallas Semiconductor Corporation.